Ubuntu Manpage: cmake-modules - CMake Modules Reference

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Provided by: cmake-data_3.22.1-1ubuntu1.22.04.2_all

NAME

       cmake-modules - CMake Modules Reference

       The  modules listed here are part of the CMake distribution.  Projects may provide further modules; their
       location(s) can be specified in the CMAKE_MODULE_PATH variable.

UTILITY MODULES

These modules are loaded using the include() command.

AndroidTestUtilities
New in version 3.7.

Create a test that automatically loads specified data onto an Android device.

Introduction
Use this module to push data needed for testing an Android device behavior onto a connected Android
device. The module will accept files and libraries as well as separate destinations for each. It will
create a test that loads the files into a device object store and link to them from the specified
destination. The files are only uploaded if they are not already in the object store.

For example:

include(AndroidTestUtilities)
android_add_test_data(
example_setup_test
FILES <files>...
LIBS <libs>...
DEVICE_TEST_DIR "/data/local/tests/example"
DEVICE_OBJECT_STORE "/sdcard/.ExternalData/SHA"
)

At build time a test named "example_setup_test" will be created. Run this test on the command line with
ctest(1) to load the data onto the Android device.

Module Functions
android_add_test_data

android_add_test_data(<test-name>
[FILES <files>...] [FILES_DEST <device-dir>]
[LIBS <libs>...] [LIBS_DEST <device-dir>]
[DEVICE_OBJECT_STORE <device-dir>]
[DEVICE_TEST_DIR <device-dir>]
[NO_LINK_REGEX <strings>...]
)

The android_add_test_data function is used to copy files and libraries needed to run
project-specific tests. On the host operating system, this is done at build time. For on-device
testing, the files are loaded onto the device by the manufactured test at run time.

This function accepts the following named parameters:

FILES <files>...
zero or more files needed for testing

LIBS <libs>...
zero or more libraries needed for testing

FILES_DEST <device-dir>
absolute path where the data files are expected to be

LIBS_DEST <device-dir>
absolute path where the libraries are expected to be

DEVICE_OBJECT_STORE <device-dir>
absolute path to the location where the data is stored on-device

DEVICE_TEST_DIR <device-dir>
absolute path to the root directory of the on-device test location

NO_LINK_REGEX <strings>...
list of regex strings matching the names of files that should be copied from the object
store to the testing directory

BundleUtilities
Functions to help assemble a standalone bundle application.

A collection of CMake utility functions useful for dealing with .app bundles on the Mac and bundle-like
directories on any OS.

The following functions are provided by this module:

fixup_bundle
copy_and_fixup_bundle
verify_app
get_bundle_main_executable
get_dotapp_dir
get_bundle_and_executable
get_bundle_all_executables
get_item_key
get_item_rpaths
clear_bundle_keys
set_bundle_key_values
get_bundle_keys
copy_resolved_item_into_bundle
copy_resolved_framework_into_bundle
fixup_bundle_item
verify_bundle_prerequisites
verify_bundle_symlinks

Requires CMake 2.6 or greater because it uses function, break and PARENT_SCOPE. Also depends on
GetPrerequisites.cmake.

DO NOT USE THESE FUNCTIONS AT CONFIGURE TIME (from CMakeLists.txt)! Instead, invoke them from an
install(CODE) or install(SCRIPT) rule.

fixup_bundle(<app> <libs> <dirs>)

Fix up <app> bundle in-place and make it standalone, such that it can be drag-n-drop copied to another
machine and run on that machine as long as all of the system libraries are compatible.

If you pass plugins to fixup_bundle as the libs parameter, you should install them or copy them into the
bundle before calling fixup_bundle. The <libs> parameter is a list of libraries that must be fixed up,
but that cannot be determined by otool output analysis (i.e. plugins).

Gather all the keys for all the executables and libraries in a bundle, and then, for each key, copy each
prerequisite into the bundle. Then fix each one up according to its own list of prerequisites.

Then clear all the keys and call verify_app on the final bundle to ensure that it is truly standalone.

New in version 3.6: As an optional parameter (IGNORE_ITEM) a list of file names can be passed, which are
then ignored (e.g. IGNORE_ITEM "vcredist_x86.exe;vcredist_x64.exe").

copy_and_fixup_bundle(<src> <dst> <libs> <dirs>)

Makes a copy of the bundle <src> at location <dst> and then fixes up the new copied bundle in-place at
<dst>.

verify_app(<app>)

Verifies that an application <app> appears valid based on running analysis tools on it. Calls
message(FATAL_ERROR) if the application is not verified.

New in version 3.6: As an optional parameter (IGNORE_ITEM) a list of file names can be passed, which are
then ignored (e.g. IGNORE_ITEM "vcredist_x86.exe;vcredist_x64.exe")

get_bundle_main_executable(<bundle> <result_var>)

The result will be the full path name of the bundle's main executable file or an error: prefixed string
if it could not be determined.

get_dotapp_dir(<exe> <dotapp_dir_var>)

Returns the nearest parent dir whose name ends with .app given the full path to an executable. If there
is no such parent dir, then simply return the dir containing the executable.

The returned directory may or may not exist.

get_bundle_and_executable(<app> <bundle_var> <executable_var> <valid_var>)

Takes either a .app directory name or the name of an executable nested inside a .app directory and
returns the path to the .app directory in <bundle_var> and the path to its main executable in
<executable_var>.

get_bundle_all_executables(<bundle> <exes_var>)

Scans <bundle> bundle recursively for all <exes_var> executable files and accumulates them into a
variable.

get_item_key(<item> <key_var>)

Given <item> file name, generate <key_var> key that should be unique considering the set of libraries
that need copying or fixing up to make a bundle standalone. This is essentially the file name including
extension with . replaced by _

This key is used as a prefix for CMake variables so that we can associate a set of variables with a given
item based on its key.

clear_bundle_keys(<keys_var>)

Loop over the <keys_var> list of keys, clearing all the variables associated with each key. After the
loop, clear the list of keys itself.

Caller of get_bundle_keys should call clear_bundle_keys when done with list of keys.

set_bundle_key_values(<keys_var> <context> <item> <exepath> <dirs>
<copyflag> [<rpaths>])

Add <keys_var> key to the list (if necessary) for the given item. If added, also set all the variables
associated with that key.

get_bundle_keys(<app> <libs> <dirs> <keys_var>)

Loop over all the executable and library files within <app> bundle (and given as extra <libs>) and
accumulate a list of keys representing them. Set values associated with each key such that we can loop
over all of them and copy prerequisite libs into the bundle and then do appropriate install_name_tool
fixups.

New in version 3.6: As an optional parameter (IGNORE_ITEM) a list of file names can be passed, which are
then ignored (e.g. IGNORE_ITEM "vcredist_x86.exe;vcredist_x64.exe")

copy_resolved_item_into_bundle(<resolved_item> <resolved_embedded_item>)

Copy a resolved item into the bundle if necessary. Copy is not necessary, if the <resolved_item> is "the
same as" the <resolved_embedded_item>.

copy_resolved_framework_into_bundle(<resolved_item> <resolved_embedded_item>)

Copy a resolved framework into the bundle if necessary. Copy is not necessary, if the <resolved_item> is
"the same as" the <resolved_embedded_item>.

By default, BU_COPY_FULL_FRAMEWORK_CONTENTS is not set. If you want full frameworks embedded in your
bundles, set BU_COPY_FULL_FRAMEWORK_CONTENTS to ON before calling fixup_bundle. By default,
COPY_RESOLVED_FRAMEWORK_INTO_BUNDLE copies the framework dylib itself plus the framework Resources
directory.

fixup_bundle_item(<resolved_embedded_item> <exepath> <dirs>)

Get the direct/non-system prerequisites of the <resolved_embedded_item>. For each prerequisite, change
the way it is referenced to the value of the _EMBEDDED_ITEM keyed variable for that prerequisite. (Most
likely changing to an @executable_path style reference.)

This function requires that the <resolved_embedded_item> be inside the bundle already. In other words,
if you pass plugins to fixup_bundle as the libs parameter, you should install them or copy them into the
bundle before calling fixup_bundle. The libs parameter is a list of libraries that must be fixed up, but
that cannot be determined by otool output analysis. (i.e., plugins)

Also, change the id of the item being fixed up to its own _EMBEDDED_ITEM value.

Accumulate changes in a local variable and make one call to install_name_tool at the end of the function
with all the changes at once.

If the BU_CHMOD_BUNDLE_ITEMS variable is set then bundle items will be marked writable before
install_name_tool tries to change them.

verify_bundle_prerequisites(<bundle> <result_var> <info_var>)

Verifies that the sum of all prerequisites of all files inside the bundle are contained within the bundle
or are system libraries, presumed to exist everywhere.

New in version 3.6: As an optional parameter (IGNORE_ITEM) a list of file names can be passed, which are
then ignored (e.g. IGNORE_ITEM "vcredist_x86.exe;vcredist_x64.exe")

verify_bundle_symlinks(<bundle> <result_var> <info_var>)

Verifies that any symlinks found in the <bundle> bundle point to other files that are already also in the
bundle... Anything that points to an external file causes this function to fail the verification.

CheckCCompilerFlag
Check whether the C compiler supports a given flag.

check_c_compiler_flag

check_c_compiler_flag(<flag> <var>)

Check that the <flag> is accepted by the compiler without a diagnostic. Stores the result in an
internal cache entry named <var>.

This command temporarily sets the CMAKE_REQUIRED_DEFINITIONS variable and calls the
check_c_source_compiles macro from the CheckCSourceCompiles module. See documentation of that module for
a listing of variables that can otherwise modify the build.

A positive result from this check indicates only that the compiler did not issue a diagnostic message
when given the flag. Whether the flag has any effect or even a specific one is beyond the scope of this
module.

NOTE:
Since the try_compile() command forwards flags from variables like CMAKE_C_FLAGS, unknown flags in
such variables may cause a false negative for this check.

CheckCompilerFlag
New in version 3.19.

Check whether the compiler supports a given flag.

check_compiler_flag

check_compiler_flag(<lang> <flag> <var>)

Check that the <flag> is accepted by the compiler without a diagnostic. Stores the result in an internal
cache entry named <var>.

This command temporarily sets the CMAKE_REQUIRED_DEFINITIONS variable and calls the
check_source_compiles(<LANG>) function from the CheckSourceCompiles module. See documentation of that
module for a listing of variables that can otherwise modify the build.

NOTE:
Since the try_compile() command forwards flags from variables like CMAKE_<LANG>_FLAGS, unknown flags
in such variables may cause a false negative for this check.

CheckCSourceCompiles
Check if given C source compiles and links into an executable.

check_c_source_compiles

check_c_source_compiles(<code> <resultVar>
[FAIL_REGEX <regex1> [<regex2>...]])

Check that the source supplied in <code> can be compiled as a C source file and linked as an
executable (so it must contain at least a main() function). The result will be stored in the
internal cache variable specified by <resultVar>, with a boolean true value for success and
boolean false for failure. If FAIL_REGEX is provided, then failure is determined by checking if
anything in the output matches any of the specified regular expressions.

The underlying check is performed by the try_compile() command. The compile and link commands can
be influenced by setting any of the following variables prior to calling
check_c_source_compiles():

CMAKE_REQUIRED_FLAGS
Additional flags to pass to the compiler. Note that the contents of CMAKE_C_FLAGS and its
associated configuration-specific variable are automatically added to the compiler command
before the contents of CMAKE_REQUIRED_FLAGS.

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_INCLUDES
A ;-list of header search paths to pass to the compiler. These will be the only header
search paths used by try_compile(), i.e. the contents of the INCLUDE_DIRECTORIES directory
property will be ignored.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14.

A ;-list of options to add to the link command (see try_compile() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_compile() for further details).

CMAKE_REQUIRED_QUIET
New in version 3.1.

If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

The check is only performed once, with the result cached in the variable named by <resultVar>.
Every subsequent CMake run will re-use this cached value rather than performing the check again,
even if the <code> changes. In order to force the check to be re-evaluated, the variable named by
<resultVar> must be manually removed from the cache.

CheckCSourceRuns
Check if given C source compiles and links into an executable and can subsequently be run.

check_c_source_runs

check_c_source_runs(<code> <resultVar>)

Check that the source supplied in <code> can be compiled as a C source file, linked as an
executable and then run. The <code> must contain at least a main() function. If the <code> could
be built and run successfully, the internal cache variable specified by <resultVar> will be set to
1, otherwise it will be set to an value that evaluates to boolean false (e.g. an empty string or
an error message).

The underlying check is performed by the try_run() command. The compile and link commands can be
influenced by setting any of the following variables prior to calling check_c_source_runs():

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_INCLUDES
A ;-list of header search paths to pass to the compiler. These will be the only header
search paths used by try_run(), i.e. the contents of the INCLUDE_DIRECTORIES directory
property will be ignored.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14.

A ;-list of options to add to the link command (see try_run() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_run() for further details).

CMAKE_REQUIRED_QUIET
New in version 3.1.

If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckCXXCompilerFlag
Check whether the CXX compiler supports a given flag.

check_cxx_compiler_flag

check_cxx_compiler_flag(<flag> <var>)

Check that the <flag> is accepted by the compiler without a diagnostic. Stores the result in an
internal cache entry named <var>.

This command temporarily sets the CMAKE_REQUIRED_DEFINITIONS variable and calls the
check_cxx_source_compiles macro from the CheckCXXSourceCompiles module. See documentation of that module
for a listing of variables that can otherwise modify the build.

NOTE:
Since the try_compile() command forwards flags from variables like CMAKE_CXX_FLAGS, unknown flags in
such variables may cause a false negative for this check.

CheckCXXSourceCompiles
Check if given C++ source compiles and links into an executable.

check_cxx_source_compiles

check_cxx_source_compiles(<code> <resultVar>
[FAIL_REGEX <regex1> [<regex2>...]])

Check that the source supplied in <code> can be compiled as a C++ source file and linked as an
executable (so it must contain at least a main() function). The result will be stored in the
internal cache variable specified by <resultVar>, with a boolean true value for success and
boolean false for failure. If FAIL_REGEX is provided, then failure is determined by checking if
anything in the output matches any of the specified regular expressions.

The underlying check is performed by the try_compile() command. The compile and link commands can
be influenced by setting any of the following variables prior to calling
check_cxx_source_compiles():

CMAKE_REQUIRED_FLAGS
Additional flags to pass to the compiler. Note that the contents of CMAKE_CXX_FLAGS and its
associated configuration-specific variable are automatically added to the compiler command
before the contents of CMAKE_REQUIRED_FLAGS.

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14.

A ;-list of options to add to the link command (see try_compile() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_compile() for further details).

CMAKE_REQUIRED_QUIET
New in version 3.1.

If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckCXXSourceRuns
Check if given C++ source compiles and links into an executable and can subsequently be run.

check_cxx_source_runs

check_cxx_source_runs(<code> <resultVar>)

Check that the source supplied in <code> can be compiled as a C++ source file, linked as an
executable and then run. The <code> must contain at least a main() function. If the <code> could
be built and run successfully, the internal cache variable specified by <resultVar> will be set to
1, otherwise it will be set to an value that evaluates to boolean false (e.g. an empty string or
an error message).

The underlying check is performed by the try_run() command. The compile and link commands can be
influenced by setting any of the following variables prior to calling check_cxx_source_runs():

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14.

A ;-list of options to add to the link command (see try_run() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_run() for further details).

CMAKE_REQUIRED_QUIET
New in version 3.1.

If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckCXXSymbolExists
Check if a symbol exists as a function, variable, or macro in C++.

check_cxx_symbol_exists

check_cxx_symbol_exists(<symbol> <files> <variable>)

Check that the <symbol> is available after including given header <files> and store the result in
a <variable>. Specify the list of files in one argument as a semicolon-separated list.
check_cxx_symbol_exists() can be used to check for symbols as seen by the C++ compiler, as opposed
to check_symbol_exists(), which always uses the C compiler.

If the header files define the symbol as a macro it is considered available and assumed to work.
If the header files declare the symbol as a function or variable then the symbol must also be
available for linking. If the symbol is a type, enum value, or C++ template it will not be
recognized: consider using the CheckTypeSize or CheckSourceCompiles module instead.

NOTE:
This command is unreliable when <symbol> is (potentially) an overloaded function. Since there is no
reliable way to predict whether a given function in the system environment may be defined as an
overloaded function or may be an overloaded function on other systems or will become so in the future,
it is generally advised to use the CheckCXXSourceCompiles module for checking any function symbol
(unless somehow you surely know the checked function is not overloaded on other systems or will not be
so in the future).

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
a ;-list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
a ;-list of header search paths to pass to the compiler.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: a ;-list of options to add to the link command.

CMAKE_REQUIRED_LIBRARIES
a ;-list of libraries to add to the link command. See policy CMP0075.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

For example:

include(CheckCXXSymbolExists)

# Check for macro SEEK_SET
check_cxx_symbol_exists(SEEK_SET "cstdio" HAVE_SEEK_SET)
# Check for function std::fopen
check_cxx_symbol_exists(std::fopen "cstdio" HAVE_STD_FOPEN)

CheckFortranCompilerFlag
New in version 3.3.

Check whether the Fortran compiler supports a given flag.

check_fortran_compiler_flag

check_fortran_compiler_flag(<flag> <var>)

Check that the <flag> is accepted by the compiler without a diagnostic. Stores the result in an
internal cache entry named <var>.

This command temporarily sets the CMAKE_REQUIRED_DEFINITIONS variable and calls the
check_fortran_source_compiles macro from the CheckFortranSourceCompiles module. See documentation of
that module for a listing of variables that can otherwise modify the build.

NOTE:
Since the try_compile() command forwards flags from variables like CMAKE_Fortran_FLAGS, unknown flags
in such variables may cause a false negative for this check.

CheckFortranFunctionExists
Check if a Fortran function exists.

CHECK_FORTRAN_FUNCTION_EXISTS

CHECK_FORTRAN_FUNCTION_EXISTS(<function> <result>)

where

<function>
the name of the Fortran function

<result>
variable to store the result; will be created as an internal cache variable.

NOTE:
This command does not detect functions in Fortran modules. In general it is recommended to use
CheckSourceCompiles instead to determine if a Fortran function or subroutine is available.

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: A ;-list of options to add to the link command (see try_compile() for further
details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries or
they can be Imported Targets (see try_compile() for further details).

CheckFortranSourceCompiles
New in version 3.1.

Check if given Fortran source compiles and links into an executable.

check_fortran_source_compiles

check_fortran_source_compiles(<code> <resultVar>
[FAIL_REGEX <regex>...]
[SRC_EXT <extension>]
)

Checks that the source supplied in <code> can be compiled as a Fortran source file and linked as
an executable. The <code> must be a Fortran program containing at least an end statement--for
example:

check_fortran_source_compiles("character :: b; error stop b; end" F2018ESTOPOK SRC_EXT F90)

This command can help avoid costly build processes when a compiler lacks support for a necessary
feature, or a particular vendor library is not compatible with the Fortran compiler version being
used. This generate-time check may advise the user of such before the main build process. See also
the check_fortran_source_runs() command to actually run the compiled code.

The result will be stored in the internal cache variable <resultVar>, with a boolean true value
for success and boolean false for failure.

If FAIL_REGEX is provided, then failure is determined by checking if anything in the output
matches any of the specified regular expressions.

By default, the test source file will be given a .F file extension. The SRC_EXT option can be used
to override this with .<extension> instead-- .F90 is a typical choice.

The underlying check is performed by the try_compile() command. The compile and link commands can
be influenced by setting any of the following variables prior to calling
check_fortran_source_compiles():

CMAKE_REQUIRED_FLAGS
Additional flags to pass to the compiler. Note that the contents of CMAKE_Fortran_FLAGS and
its associated configuration-specific variable are automatically added to the compiler
command before the contents of CMAKE_REQUIRED_FLAGS.

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14.

A ;-list of options to add to the link command (see try_compile() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_compile() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckFortranSourceRuns
New in version 3.14.

Check if given Fortran source compiles and links into an executable and can subsequently be run.

check_fortran_source_runs

check_fortran_source_runs(<code> <resultVar>
[SRC_EXT <extension>])

Check that the source supplied in <code> can be compiled as a Fortran source file, linked as an
executable and then run. The <code> must be a Fortran program containing at least an end
statement--for example:

check_fortran_source_runs("real :: x[*]; call co_sum(x); end" F2018coarrayOK)

This command can help avoid costly build processes when a compiler lacks support for a necessary
feature, or a particular vendor library is not compatible with the Fortran compiler version being
used. Some of these failures only occur at runtime instead of linktime, and a trivial runtime
example can catch the issue before the main build process.

If the <code> could be built and run successfully, the internal cache variable specified by
<resultVar> will be set to 1, otherwise it will be set to an value that evaluates to boolean false
(e.g. an empty string or an error message).

By default, the test source file will be given a .F90 file extension. The SRC_EXT option can be
used to override this with .<extension> instead.

The underlying check is performed by the try_run() command. The compile and link commands can be
influenced by setting any of the following variables prior to calling check_fortran_source_runs():

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
A ;-list of options to add to the link command (see try_run() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_run() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckFunctionExists
Check if a C function can be linked

check_function_exists

check_function_exists(<function> <variable>)

Checks that the <function> is provided by libraries on the system and store the result in a
<variable>, which will be created as an internal cache variable.

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
a ;-list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
a ;-list of header search paths to pass to the compiler.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: a ;-list of options to add to the link command.

CMAKE_REQUIRED_LIBRARIES
a ;-list of libraries to add to the link command. See policy CMP0075.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

NOTE:
Prefer using CheckSymbolExists instead of this module, for the following reasons:

• check_function_exists() can't detect functions that are inlined in headers or specified as a macro.

• check_function_exists() can't detect anything in the 32-bit versions of the Win32 API, because of a
mismatch in calling conventions.

• check_function_exists() only verifies linking, it does not verify that the function is declared in
system headers.

CheckIncludeFileCXX
Provides a macro to check if a header file can be included in CXX.

CHECK_INCLUDE_FILE_CXX

CHECK_INCLUDE_FILE_CXX(<include> <variable> [<flags>])

Check if the given <include> file may be included in a CXX source file and store the result in an
internal cache entry named <variable>. The optional third argument may be used to add compilation
flags to the check (or use CMAKE_REQUIRED_FLAGS below).

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
a ;-list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
a ;-list of header search paths to pass to the compiler.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: a ;-list of options to add to the link command.

CMAKE_REQUIRED_LIBRARIES
a ;-list of libraries to add to the link command. See policy CMP0075.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

See modules CheckIncludeFile and CheckIncludeFiles to check for one or more C headers.

CheckIncludeFile
Provides a macro to check if a header file can be included in C.

CHECK_INCLUDE_FILE

CHECK_INCLUDE_FILE(<include> <variable> [<flags>])

Check if the given <include> file may be included in a C source file and store the result in an
internal cache entry named <variable>. The optional third argument may be used to add compilation
flags to the check (or use CMAKE_REQUIRED_FLAGS below).

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
a ;-list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
a ;-list of header search paths to pass to the compiler.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: a ;-list of options to add to the link command.

CMAKE_REQUIRED_LIBRARIES
a ;-list of libraries to add to the link command. See policy CMP0075.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

See the CheckIncludeFiles module to check for multiple headers at once. See the CheckIncludeFileCXX
module to check for headers using the CXX language.

CheckIncludeFiles
Provides a macro to check if a list of one or more header files can be included together.

CHECK_INCLUDE_FILES

CHECK_INCLUDE_FILES("<includes>" <variable> [LANGUAGE <language>])

Check if the given <includes> list may be included together in a source file and store the result
in an internal cache entry named <variable>. Specify the <includes> argument as a ;-list of
header file names.

If LANGUAGE is set, the specified compiler will be used to perform the check. Acceptable values
are C and CXX. If not set, the C compiler will be used if enabled. If the C compiler is not
enabled, the C++ compiler will be used if enabled.

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
a ;-list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
a ;-list of header search paths to pass to the compiler.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: a ;-list of options to add to the link command.

CMAKE_REQUIRED_LIBRARIES
a ;-list of libraries to add to the link command. See policy CMP0075.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

See modules CheckIncludeFile and CheckIncludeFileCXX to check for a single header file in C or CXX
languages.

CheckIPOSupported
New in version 3.9.

Check whether the compiler supports an interprocedural optimization (IPO/LTO). Use this before enabling
the INTERPROCEDURAL_OPTIMIZATION target property.

check_ipo_supported

check_ipo_supported([RESULT <result>] [OUTPUT <output>]
[LANGUAGES <lang>...])

Options are:

RESULT <result>
Set <result> variable to YES if IPO is supported by the compiler and NO otherwise. If this
option is not given then the command will issue a fatal error if IPO is not supported.

OUTPUT <output>
Set <output> variable with details about any error.

LANGUAGES <lang>...
Specify languages whose compilers to check. Languages C, CXX, and Fortran are supported.

It makes no sense to use this module when CMP0069 is set to OLD so module will return error in this case.
See policy CMP0069 for details.

New in version 3.13: Add support for Visual Studio generators.

Examples
check_ipo_supported() # fatal error if IPO is not supported
set_property(TARGET foo PROPERTY INTERPROCEDURAL_OPTIMIZATION TRUE)

# Optional IPO. Do not use IPO if it's not supported by compiler.
check_ipo_supported(RESULT result OUTPUT output)
if(result)
set_property(TARGET foo PROPERTY INTERPROCEDURAL_OPTIMIZATION TRUE)
else()
message(WARNING "IPO is not supported: ${output}")
endif()

CheckLanguage
Check if a language can be enabled

Usage:

check_language(<lang>)

where <lang> is a language that may be passed to enable_language() such as Fortran. If
CMAKE_<LANG>_COMPILER is already defined the check does nothing. Otherwise it tries enabling the
language in a test project. The result is cached in CMAKE_<LANG>_COMPILER as the compiler that was
found, or NOTFOUND if the language cannot be enabled. For CUDA which can have an explicit host compiler,
the cache CMAKE_CUDA_HOST_COMPILER variable will be set if it was required for compilation (and cleared
if it was not).

Example:

check_language(Fortran)
if(CMAKE_Fortran_COMPILER)
enable_language(Fortran)
else()
message(STATUS "No Fortran support")
endif()

CheckLibraryExists
Check if the function exists.

CHECK_LIBRARY_EXISTS

CHECK_LIBRARY_EXISTS(LIBRARY FUNCTION LOCATION VARIABLE)

LIBRARY - the name of the library you are looking for
FUNCTION - the name of the function
LOCATION - location where the library should be found
VARIABLE - variable to store the result
Will be created as an internal cache variable.

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: list of options to pass to link command.

CMAKE_REQUIRED_LIBRARIES
list of libraries to link.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

CheckLinkerFlag
New in version 3.18.

Check whether the compiler supports a given link flag.

check_linker_flag

check_linker_flag(<lang> <flag> <var>)

Check that the link <flag> is accepted by the <lang> compiler without a diagnostic. Stores the result in
an internal cache entry named <var>.

This command temporarily sets the CMAKE_REQUIRED_LINK_OPTIONS variable and calls the
check_source_compiles() command from the CheckSourceCompiles module. See that module's documentation for
a listing of variables that can otherwise modify the build.

The underlying implementation relies on the LINK_OPTIONS property to check the specified flag. The
LINKER: prefix, as described in the target_link_options() command, can be used as well.

A positive result from this check indicates only that the compiler did not issue a diagnostic message
when given the link flag. Whether the flag has any effect or even a specific one is beyond the scope of
this module.

NOTE:
Since the try_compile() command forwards flags from variables like CMAKE_<LANG>_FLAGS, unknown flags
in such variables may cause a false negative for this check.

CheckOBJCCompilerFlag
New in version 3.16.

Check whether the Objective-C compiler supports a given flag.

check_objc_compiler_flag

check_objc_compiler_flag(<flag> <var>)

Check that the <flag> is accepted by the compiler without a diagnostic. Stores the result in an
internal cache entry named <var>.

This command temporarily sets the CMAKE_REQUIRED_DEFINITIONS variable and calls the
check_objc_source_compiles macro from the CheckOBJCSourceCompiles module. See documentation of that
module for a listing of variables that can otherwise modify the build.

NOTE:
Since the try_compile() command forwards flags from variables like CMAKE_OBJC_FLAGS, unknown flags in
such variables may cause a false negative for this check.

CheckOBJCSourceCompiles
New in version 3.16.

Check if given Objective-C source compiles and links into an executable.

check_objc_source_compiles

check_objc_source_compiles(<code> <resultVar>
[FAIL_REGEX <regex1> [<regex2>...]])

Check that the source supplied in <code> can be compiled as a Objectie-C source file and linked as
an executable (so it must contain at least a main() function). The result will be stored in the
internal cache variable specified by <resultVar>, with a boolean true value for success and
boolean false for failure. If FAIL_REGEX is provided, then failure is determined by checking if
anything in the output matches any of the specified regular expressions.

CMAKE_REQUIRED_FLAGS
Additional flags to pass to the compiler. Note that the contents of CMAKE_OBJC_FLAGS and
its associated configuration-specific variable are automatically added to the compiler
command before the contents of CMAKE_REQUIRED_FLAGS.

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
A ;-list of options to add to the link command (see try_compile() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_compile() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckOBJCSourceRuns
New in version 3.16.

Check if given Objective-C source compiles and links into an executable and can subsequently be run.

check_objc_source_runs

check_objc_source_runs(<code> <resultVar>)

Check that the source supplied in <code> can be compiled as a Objective-C source file, linked as
an executable and then run. The <code> must contain at least a main() function. If the <code>
could be built and run successfully, the internal cache variable specified by <resultVar> will be
set to 1, otherwise it will be set to an value that evaluates to boolean false (e.g. an empty
string or an error message).

The underlying check is performed by the try_run() command. The compile and link commands can be
influenced by setting any of the following variables prior to calling check_objc_source_runs():

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
A ;-list of options to add to the link command (see try_run() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_run() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckOBJCXXCompilerFlag
New in version 3.16.

Check whether the Objective-C++ compiler supports a given flag.

check_objcxx_compiler_flag

check_objcxx_compiler_flag(<flag> <var>)

Check that the <flag> is accepted by the compiler without a diagnostic. Stores the result in an
internal cache entry named <var>.

This command temporarily sets the CMAKE_REQUIRED_DEFINITIONS variable and calls the
check_objcxx_source_compiles macro from the CheckOBJCXXSourceCompiles module. See documentation of that
module for a listing of variables that can otherwise modify the build.

NOTE:
Since the try_compile() command forwards flags from variables like CMAKE_OBJCXX_FLAGS, unknown flags
in such variables may cause a false negative for this check.

CheckOBJCXXSourceCompiles
New in version 3.16.

Check if given Objective-C++ source compiles and links into an executable.

check_objcxx_source_compiles

check_objcxx_source_compiles(<code> <resultVar>
[FAIL_REGEX <regex1> [<regex2>...]])

Check that the source supplied in <code> can be compiled as a Objective-C++ source file and linked
as an executable (so it must contain at least a main() function). The result will be stored in the
internal cache variable specified by <resultVar>, with a boolean true value for success and
boolean false for failure. If FAIL_REGEX is provided, then failure is determined by checking if
anything in the output matches any of the specified regular expressions.

CMAKE_REQUIRED_FLAGS
Additional flags to pass to the compiler. Note that the contents of CMAKE_OBJCXX_FLAGS and
its associated configuration-specific variable are automatically added to the compiler
command before the contents of CMAKE_REQUIRED_FLAGS.

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
A ;-list of options to add to the link command (see try_compile() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_compile() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckOBJCXXSourceRuns
New in version 3.16.

Check if given Objective-C++ source compiles and links into an executable and can subsequently be run.

check_objcxx_source_runs

check_objcxx_source_runs(<code> <resultVar>)

Check that the source supplied in <code> can be compiled as a Objective-C++ source file, linked as
an executable and then run. The <code> must contain at least a main() function. If the <code>
could be built and run successfully, the internal cache variable specified by <resultVar> will be
set to 1, otherwise it will be set to an value that evaluates to boolean false (e.g. an empty
string or an error message).

The underlying check is performed by the try_run() command. The compile and link commands can be
influenced by setting any of the following variables prior to calling check_objcxx_source_runs():

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
A ;-list of options to add to the link command (see try_run() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_run() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckPIESupported
New in version 3.14.

Check whether the linker supports Position Independent Code (PIE) or No Position Independent Code
(NO_PIE) for executables. Use this to ensure that the POSITION_INDEPENDENT_CODE target property for
executables will be honored at link time.

check_pie_supported

check_pie_supported([OUTPUT_VARIABLE <output>]
[LANGUAGES <lang>...])

Options are:

OUTPUT_VARIABLE <output>
Set <output> variable with details about any error.

LANGUAGES <lang>...
Check the linkers used for each of the specified languages. Supported languages are C,
CXX, and Fortran.

It makes no sense to use this module when CMP0083 is set to OLD, so the command will return an error in
this case. See policy CMP0083 for details.

Variables
For each language checked, two boolean cache variables are defined.

CMAKE_<lang>_LINK_PIE_SUPPORTED
Set to YES if PIE is supported by the linker and NO otherwise.

CMAKE_<lang>_LINK_NO_PIE_SUPPORTED
Set to YES if NO_PIE is supported by the linker and NO otherwise.

Examples
check_pie_supported()
set_property(TARGET foo PROPERTY POSITION_INDEPENDENT_CODE TRUE)

# Retrieve any error message.
check_pie_supported(OUTPUT_VARIABLE output LANGUAGES C)
set_property(TARGET foo PROPERTY POSITION_INDEPENDENT_CODE TRUE)
if(NOT CMAKE_C_LINK_PIE_SUPPORTED)
message(WARNING "PIE is not supported at link time: ${output}.\n"
"PIE link options will not be passed to linker.")
endif()

CheckPrototypeDefinition
Check if the prototype we expect is correct.

check_prototype_definition

check_prototype_definition(FUNCTION PROTOTYPE RETURN HEADER VARIABLE)

FUNCTION - The name of the function (used to check if prototype exists)
PROTOTYPE- The prototype to check.
RETURN - The return value of the function.
HEADER - The header files required.
VARIABLE - The variable to store the result.
Will be created as an internal cache variable.

Example:

check_prototype_definition(getpwent_r
"struct passwd *getpwent_r(struct passwd *src, char *buf, int buflen)"
"NULL"
"unistd.h;pwd.h"
SOLARIS_GETPWENT_R)

The following variables may be set before calling this function to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
list of include directories.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: list of options to pass to link command.

CMAKE_REQUIRED_LIBRARIES
list of libraries to link.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

CheckSourceCompiles
New in version 3.19.

Check if given source compiles and links into an executable.

check_source_compiles

check_source_compiles(<lang> <code> <resultVar>
[FAIL_REGEX <regex1> [<regex2>...]]
[SRC_EXT <extension>])

Check that the source supplied in <code> can be compiled as a source file for the requested
language and linked as an executable (so it must contain at least a main() function). The result
will be stored in the internal cache variable specified by <resultVar>, with a boolean true value
for success and boolean false for failure. If FAIL_REGEX is provided, then failure is determined
by checking if anything in the output matches any of the specified regular expressions.

By default, the test source file will be given a file extension that matches the requested
language. The SRC_EXT option can be used to override this with .<extension> instead.

The underlying check is performed by the try_compile() command. The compile and link commands can
be influenced by setting any of the following variables prior to calling check_source_compiles():

CMAKE_REQUIRED_FLAGS
Additional flags to pass to the compiler. Note that the contents of CMAKE_<LANG>_FLAGS and
its associated configuration-specific variable are automatically added to the compiler
command before the contents of CMAKE_REQUIRED_FLAGS.

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
A ;-list of options to add to the link command (see try_compile() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_compile() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckSourceRuns
New in version 3.19.

Check if given source compiles and links into an executable and can subsequently be run.

check_source_runs

check_source_runs(<lang> <code> <resultVar>
[SRC_EXT <extension>])

Check that the source supplied in <code> can be compiled as a source file for the requested
language, linked as an executable and then run. The <code> must contain at least a main()
function. If the <code> could be built and run successfully, the internal cache variable specified
by <resultVar> will be set to 1, otherwise it will be set to an value that evaluates to boolean
false (e.g. an empty string or an error message).

By default, the test source file will be given a file extension that matches the requested
language. The SRC_EXT option can be used to override this with .<extension> instead.

The underlying check is performed by the try_run() command. The compile and link commands can be
influenced by setting any of the following variables prior to calling check_objc_source_runs():

CMAKE_REQUIRED_DEFINITIONS
A ;-list of compiler definitions of the form -DFOO or -DFOO=bar. A definition for the name
specified by <resultVar> will also be added automatically.

CMAKE_REQUIRED_LINK_OPTIONS
A ;-list of options to add to the link command (see try_run() for further details).

CMAKE_REQUIRED_LIBRARIES
A ;-list of libraries to add to the link command. These can be the name of system libraries
or they can be Imported Targets (see try_run() for further details).

CMAKE_REQUIRED_QUIET
If this variable evaluates to a boolean true value, all status messages associated with the
check will be suppressed.

CheckStructHasMember
Check if the given struct or class has the specified member variable

CHECK_STRUCT_HAS_MEMBER

CHECK_STRUCT_HAS_MEMBER(<struct> <member> <header> <variable>
[LANGUAGE <language>])

<struct> - the name of the struct or class you are interested in
<member> - the member which existence you want to check
<header> - the header(s) where the prototype should be declared
<variable> - variable to store the result
<language> - the compiler to use (C or CXX)

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
list of include directories.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: list of options to pass to link command.

CMAKE_REQUIRED_LIBRARIES
list of libraries to link.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

Example:

CHECK_STRUCT_HAS_MEMBER("struct timeval" tv_sec sys/select.h
HAVE_TIMEVAL_TV_SEC LANGUAGE C)

CheckSymbolExists
Provides a macro to check if a symbol exists as a function, variable, or macro in C.

check_symbol_exists

check_symbol_exists(<symbol> <files> <variable>)

Check that the <symbol> is available after including given header <files> and store the result in
a <variable>. Specify the list of files in one argument as a semicolon-separated list.
<variable> will be created as an internal cache variable.

If the header files define the symbol as a macro it is considered available and assumed to work. If the
header files declare the symbol as a function or variable then the symbol must also be available for
linking (so intrinsics may not be detected). If the symbol is a type, enum value, or intrinsic it will
not be recognized (consider using CheckTypeSize or CheckSourceCompiles). If the check needs to be done
in C++, consider using CheckCXXSymbolExists instead.

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
a ;-list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
a ;-list of header search paths to pass to the compiler.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: a ;-list of options to add to the link command.

CMAKE_REQUIRED_LIBRARIES
a ;-list of libraries to add to the link command. See policy CMP0075.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

For example:

include(CheckSymbolExists)

# Check for macro SEEK_SET
check_symbol_exists(SEEK_SET "stdio.h" HAVE_SEEK_SET)
# Check for function fopen
check_symbol_exists(fopen "stdio.h" HAVE_FOPEN)

CheckTypeSize
Check sizeof a type

CHECK_TYPE_SIZE

CHECK_TYPE_SIZE(TYPE VARIABLE [BUILTIN_TYPES_ONLY]
[LANGUAGE <language>])

Check if the type exists and determine its size. On return, HAVE_${VARIABLE} holds the existence
of the type, and ${VARIABLE} holds one of the following:

<size> = type has non-zero size <size>
"0" = type has arch-dependent size (see below)
"" = type does not exist

Both HAVE_${VARIABLE} and ${VARIABLE} will be created as internal cache variables.

Furthermore, the variable ${VARIABLE}_CODE holds C preprocessor code to define the macro
${VARIABLE} to the size of the type, or leave the macro undefined if the type does not exist.

The variable ${VARIABLE} may be 0 when CMAKE_OSX_ARCHITECTURES has multiple architectures for
building OS X universal binaries. This indicates that the type size varies across architectures.
In this case ${VARIABLE}_CODE contains C preprocessor tests mapping from each architecture macro
to the corresponding type size. The list of architecture macros is stored in ${VARIABLE}_KEYS,
and the value for each key is stored in ${VARIABLE}-${KEY}.

If the BUILTIN_TYPES_ONLY option is not given, the macro checks for headers <sys/types.h>,
<stdint.h>, and <stddef.h>, and saves results in HAVE_SYS_TYPES_H, HAVE_STDINT_H, and
HAVE_STDDEF_H. The type size check automatically includes the available headers, thus supporting
checks of types defined in the headers.

If LANGUAGE is set, the specified compiler will be used to perform the check. Acceptable values
are C and CXX.

Despite the name of the macro you may use it to check the size of more complex expressions, too. To
check e.g. for the size of a struct member you can do something like this:

check_type_size("((struct something*)0)->member" SIZEOF_MEMBER)

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_INCLUDES
list of include directories.

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: list of options to pass to link command.

CMAKE_REQUIRED_LIBRARIES
list of libraries to link.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

CMAKE_EXTRA_INCLUDE_FILES
list of extra headers to include.

CheckVariableExists
Check if the variable exists.

CHECK_VARIABLE_EXISTS

CHECK_VARIABLE_EXISTS(VAR VARIABLE)

VAR - the name of the variable
VARIABLE - variable to store the result
Will be created as an internal cache variable.

This macro is only for C variables.

The following variables may be set before calling this macro to modify the way the check is run:

CMAKE_REQUIRED_FLAGS
string of compile command line flags.

CMAKE_REQUIRED_DEFINITIONS
list of macros to define (-DFOO=bar).

CMAKE_REQUIRED_LINK_OPTIONS
New in version 3.14: list of options to pass to link command.

CMAKE_REQUIRED_LIBRARIES
list of libraries to link.

CMAKE_REQUIRED_QUIET
New in version 3.1: execute quietly without messages.

CMakeAddFortranSubdirectory
Add a fortran-only subdirectory, find a fortran compiler, and build.

The cmake_add_fortran_subdirectory function adds a subdirectory to a project that contains a fortran-only
subproject. The module will check the current compiler and see if it can support fortran. If no fortran
compiler is found and the compiler is MSVC, then this module will find the MinGW gfortran. It will then
use an external project to build with the MinGW tools. It will also create imported targets for the
libraries created. This will only work if the fortran code is built into a dll, so BUILD_SHARED_LIBS is
turned on in the project. In addition the CMAKE_GNUtoMS option is set to on, so that Microsoft .lib
files are created. Usage is as follows:

cmake_add_fortran_subdirectory(
<subdir> # name of subdirectory
PROJECT <project_name> # project name in subdir top CMakeLists.txt
ARCHIVE_DIR <dir> # dir where project places .lib files
RUNTIME_DIR <dir> # dir where project places .dll files
LIBRARIES <lib>... # names of library targets to import
LINK_LIBRARIES # link interface libraries for LIBRARIES
[LINK_LIBS <lib> <dep>...]...
CMAKE_COMMAND_LINE ... # extra command line flags to pass to cmake
NO_EXTERNAL_INSTALL # skip installation of external project
)

Relative paths in ARCHIVE_DIR and RUNTIME_DIR are interpreted with respect to the build directory
corresponding to the source directory in which the function is invoked.

Limitations:

NO_EXTERNAL_INSTALL is required for forward compatibility with a future version that supports
installation of the external project binaries during make install.

CMakeBackwardCompatibilityCXX
define a bunch of backwards compatibility variables

CMAKE_ANSI_CXXFLAGS - flag for ansi c++
CMAKE_HAS_ANSI_STRING_STREAM - has <strstream>
include(TestForANSIStreamHeaders)
include(CheckIncludeFileCXX)
include(TestForSTDNamespace)
include(TestForANSIForScope)

CMakeDependentOption
Macro to provide an option dependent on other options.

This macro presents an option to the user only if a set of other conditions are true.

cmake_dependent_option

cmake_dependent_option(<option> "<help_text>" <value> <depends> <force>)

Makes <option> available to the user if <depends> is true. When <option> is available, the given
<help_text> and initial <value> are used. If the <depends> condition is not true, <option> will
not be presented and will always have the value given by <force>. Any value set by the user is
preserved for when the option is presented again. In case <depends> is a semicolon-separated list,
all elements must be true in order to initialize <option> with <value>.

Example invocation:

cmake_dependent_option(USE_FOO "Use Foo" ON "USE_BAR;NOT USE_ZOT" OFF)

If USE_BAR is true and USE_ZOT is false, this provides an option called USE_FOO that defaults to ON.
Otherwise, it sets USE_FOO to OFF and hides the option from the user. If the status of USE_BAR or USE_ZOT
ever changes, any value for the USE_FOO option is saved so that when the option is re-enabled it retains
its old value.

New in version 3.22: Full Condition Syntax is now supported. See policy CMP0127.

CMakeFindDependencyMacro
find_dependency
The find_dependency() macro wraps a find_package() call for a package dependency:

find_dependency(<dep> [...])

It is designed to be used in a Package Configuration File (<PackageName>Config.cmake).
find_dependency forwards the correct parameters for QUIET and REQUIRED which were passed to the
original find_package() call. Any additional arguments specified are forwarded to find_package().

If the dependency could not be found it sets an informative diagnostic message and calls return()
to end processing of the calling package configuration file and return to the find_package()
command that loaded it.

NOTE:
The call to return() makes this macro unsuitable to call from Find Modules.

CMakeFindFrameworks
helper module to find OSX frameworks

This module reads hints about search locations from variables:

CMAKE_FIND_FRAMEWORK_EXTRA_LOCATIONS - Extra directories

CMakeFindPackageMode
This file is executed by cmake when invoked with --find-package. It expects that the following variables
are set using -D:

NAME name of the package

COMPILER_ID
the CMake compiler ID for which the result is, i.e. GNU/Intel/Clang/MSVC, etc.

LANGUAGE
language for which the result will be used, i.e. C/CXX/Fortran/ASM

MODE

EXIST only check for existence of the given package

COMPILE
print the flags needed for compiling an object file which uses the given package

LINK print the flags needed for linking when using the given package

QUIET if TRUE, don't print anything

CMakeGraphVizOptions
The builtin Graphviz support of CMake.

Generating Graphviz files
CMake can generate Graphviz files showing the dependencies between the targets in a project, as well as
external libraries which are linked against.

When running CMake with the --graphviz=foo.dot option, it produces:

• a foo.dot file, showing all dependencies in the project

• a foo.dot.<target> file for each target, showing on which other targets it depends

• a foo.dot.<target>.dependers file for each target, showing which other targets depend on it

Those .dot files can be converted to images using the dot command from the Graphviz package:

dot -Tpng -o foo.png foo.dot

New in version 3.10: The different dependency types PUBLIC, INTERFACE and PRIVATE are represented as
solid, dashed and dotted edges.

Variables specific to the Graphviz support
The resulting graphs can be huge. The look and content of the generated graphs can be controlled using
the file CMakeGraphVizOptions.cmake. This file is first searched in CMAKE_BINARY_DIR, and then in
CMAKE_SOURCE_DIR. If found, the variables set in it are used to adjust options for the generated
Graphviz files.

GRAPHVIZ_GRAPH_NAME
The graph name.

• Mandatory: NO

• Default: value of CMAKE_PROJECT_NAME

GRAPHVIZ_GRAPH_HEADER
The header written at the top of the Graphviz files.

• Mandatory: NO

• Default: "node [ fontsize = "12" ];"

GRAPHVIZ_NODE_PREFIX
The prefix for each node in the Graphviz files.

• Mandatory: NO

• Default: "node"

GRAPHVIZ_EXECUTABLES
Set to FALSE to exclude executables from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_STATIC_LIBS
Set to FALSE to exclude static libraries from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_SHARED_LIBS
Set to FALSE to exclude shared libraries from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_MODULE_LIBS
Set to FALSE to exclude module libraries from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_INTERFACE_LIBS
Set to FALSE to exclude interface libraries from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_OBJECT_LIBS
Set to FALSE to exclude object libraries from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_UNKNOWN_LIBS
Set to FALSE to exclude unknown libraries from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_EXTERNAL_LIBS
Set to FALSE to exclude external libraries from the generated graphs.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_CUSTOM_TARGETS
Set to TRUE to include custom targets in the generated graphs.

• Mandatory: NO

• Default: FALSE

GRAPHVIZ_IGNORE_TARGETS
A list of regular expressions for names of targets to exclude from the generated graphs.

• Mandatory: NO

• Default: empty

GRAPHVIZ_GENERATE_PER_TARGET
Set to FALSE to not generate per-target graphs foo.dot.<target>.

• Mandatory: NO

• Default: TRUE

GRAPHVIZ_GENERATE_DEPENDERS
Set to FALSE to not generate depender graphs foo.dot.<target>.dependers.

• Mandatory: NO

• Default: TRUE

CMakePackageConfigHelpers
Helpers functions for creating config files that can be included by other projects to find and use a
package.

Adds the configure_package_config_file() and write_basic_package_version_file() commands.

Generating a Package Configuration File
configure_package_config_file
Create a config file for a project:

configure_package_config_file(<input> <output>
INSTALL_DESTINATION <path>
[PATH_VARS <var1> <var2> ... <varN>]
[NO_SET_AND_CHECK_MACRO]
[NO_CHECK_REQUIRED_COMPONENTS_MACRO]
[INSTALL_PREFIX <path>]
)

configure_package_config_file() should be used instead of the plain configure_file() command when
creating the <PackageName>Config.cmake or <PackageName>-config.cmake file for installing a project or
library. It helps making the resulting package relocatable by avoiding hardcoded paths in the installed
Config.cmake file.

In a FooConfig.cmake file there may be code like this to make the install destinations know to the using
project:

set(FOO_INCLUDE_DIR "@CMAKE_INSTALL_FULL_INCLUDEDIR@" )
set(FOO_DATA_DIR "@CMAKE_INSTALL_PREFIX@/@RELATIVE_DATA_INSTALL_DIR@" )
set(FOO_ICONS_DIR "@CMAKE_INSTALL_PREFIX@/share/icons" )
#...logic to determine installedPrefix from the own location...
set(FOO_CONFIG_DIR "${installedPrefix}/@CONFIG_INSTALL_DIR@" )

All 4 options shown above are not sufficient, since the first 3 hardcode the absolute directory
locations, and the 4th case works only if the logic to determine the installedPrefix is correct, and if
CONFIG_INSTALL_DIR contains a relative path, which in general cannot be guaranteed. This has the effect
that the resulting FooConfig.cmake file would work poorly under Windows and OSX, where users are used to
choose the install location of a binary package at install time, independent from how
CMAKE_INSTALL_PREFIX was set at build/cmake time.

Using configure_package_config_file helps. If used correctly, it makes the resulting FooConfig.cmake
file relocatable. Usage:

1. write a FooConfig.cmake.in file as you are used to

2. insert a line containing only the string @PACKAGE_INIT@

3. instead of set(FOO_DIR "@SOME_INSTALL_DIR@"), use set(FOO_DIR "@PACKAGE_SOME_INSTALL_DIR@") (this must
be after the @PACKAGE_INIT@ line)

4. instead of using the normal configure_file(), use configure_package_config_file()

The <input> and <output> arguments are the input and output file, the same way as in configure_file().

The <path> given to INSTALL_DESTINATION must be the destination where the FooConfig.cmake file will be
installed to. This path can either be absolute, or relative to the INSTALL_PREFIX path.

The variables <var1> to <varN> given as PATH_VARS are the variables which contain install destinations.
For each of them the macro will create a helper variable PACKAGE_<var...>. These helper variables must
be used in the FooConfig.cmake.in file for setting the installed location. They are calculated by
configure_package_config_file so that they are always relative to the installed location of the package.
This works both for relative and also for absolute locations. For absolute locations it works only if
the absolute location is a subdirectory of INSTALL_PREFIX.

New in version 3.1: If the INSTALL_PREFIX argument is passed, this is used as base path to calculate all
the relative paths. The <path> argument must be an absolute path. If this argument is not passed, the
CMAKE_INSTALL_PREFIX variable will be used instead. The default value is good when generating a
FooConfig.cmake file to use your package from the install tree. When generating a FooConfig.cmake file
to use your package from the build tree this option should be used.

By default configure_package_config_file also generates two helper macros, set_and_check() and
check_required_components() into the FooConfig.cmake file.

set_and_check() should be used instead of the normal set() command for setting directories and file
locations. Additionally to setting the variable it also checks that the referenced file or directory
actually exists and fails with a FATAL_ERROR otherwise. This makes sure that the created FooConfig.cmake
file does not contain wrong references. When using the NO_SET_AND_CHECK_MACRO, this macro is not
generated into the FooConfig.cmake file.

check_required_components(<PackageName>) should be called at the end of the FooConfig.cmake file. This
macro checks whether all requested, non-optional components have been found, and if this is not the case,
sets the Foo_FOUND variable to FALSE, so that the package is considered to be not found. It does that by
testing the Foo_<Component>_FOUND variables for all requested required components. This macro should be
called even if the package doesn't provide any components to make sure users are not specifying
components erroneously. When using the NO_CHECK_REQUIRED_COMPONENTS_MACRO option, this macro is not
generated into the FooConfig.cmake file.

For an example see below the documentation for write_basic_package_version_file().

Generating a Package Version File
write_basic_package_version_file
Create a version file for a project:

write_basic_package_version_file(<filename>
[VERSION <major.minor.patch>]
COMPATIBILITY <AnyNewerVersion|SameMajorVersion|SameMinorVersion|ExactVersion>
[ARCH_INDEPENDENT] )

Writes a file for use as <PackageName>ConfigVersion.cmake file to <filename>. See the documentation of
find_package() for details on this.

<filename> is the output filename, it should be in the build tree. <major.minor.patch> is the version
number of the project to be installed.

If no VERSION is given, the PROJECT_VERSION variable is used. If this hasn't been set, it errors out.

The COMPATIBILITY mode AnyNewerVersion means that the installed package version will be considered
compatible if it is newer or exactly the same as the requested version. This mode should be used for
packages which are fully backward compatible, also across major versions. If SameMajorVersion is used
instead, then the behavior differs from AnyNewerVersion in that the major version number must be the same
as requested, e.g. version 2.0 will not be considered compatible if 1.0 is requested. This mode should
be used for packages which guarantee backward compatibility within the same major version. If
SameMinorVersion is used, the behavior is the same as SameMajorVersion, but both major and minor version
must be the same as requested, e.g version 0.2 will not be compatible if 0.1 is requested. If
ExactVersion is used, then the package is only considered compatible if the requested version matches
exactly its own version number (not considering the tweak version). For example, version 1.2.3 of a
package is only considered compatible to requested version 1.2.3. This mode is for packages without
compatibility guarantees. If your project has more elaborated version matching rules, you will need to
write your own custom ConfigVersion.cmake file instead of using this macro.

New in version 3.11: The SameMinorVersion compatibility mode.

New in version 3.14: If ARCH_INDEPENDENT is given, the installed package version will be considered
compatible even if it was built for a different architecture than the requested architecture. Otherwise,
an architecture check will be performed, and the package will be considered compatible only if the
architecture matches exactly. For example, if the package is built for a 32-bit architecture, the
package is only considered compatible if it is used on a 32-bit architecture, unless ARCH_INDEPENDENT is
given, in which case the package is considered compatible on any architecture.

NOTE:
ARCH_INDEPENDENT is intended for header-only libraries or similar packages with no binaries.

New in version 3.19: COMPATIBILITY_MODE AnyNewerVersion, SameMajorVersion and SameMinorVersion handle the
version range if any is specified (see find_package() command for the details). ExactVersion mode is
incompatible with version ranges and will display an author warning if one is specified.

Internally, this macro executes configure_file() to create the resulting version file. Depending on the
COMPATIBILITY, the corresponding BasicConfigVersion-<COMPATIBILITY>.cmake.in file is used. Please note
that these files are internal to CMake and you should not call configure_file() on them yourself, but
they can be used as starting point to create more sophisticted custom ConfigVersion.cmake files.

Example Generating Package Files
Example using both configure_package_config_file() and write_basic_package_version_file():

CMakeLists.txt:

set(INCLUDE_INSTALL_DIR include/ ... CACHE )
set(LIB_INSTALL_DIR lib/ ... CACHE )
set(SYSCONFIG_INSTALL_DIR etc/foo/ ... CACHE )
#...
include(CMakePackageConfigHelpers)
configure_package_config_file(FooConfig.cmake.in
${CMAKE_CURRENT_BINARY_DIR}/FooConfig.cmake
INSTALL_DESTINATION ${LIB_INSTALL_DIR}/Foo/cmake
PATH_VARS INCLUDE_INSTALL_DIR SYSCONFIG_INSTALL_DIR)
write_basic_package_version_file(
${CMAKE_CURRENT_BINARY_DIR}/FooConfigVersion.cmake
VERSION 1.2.3
COMPATIBILITY SameMajorVersion )
install(FILES ${CMAKE_CURRENT_BINARY_DIR}/FooConfig.cmake
${CMAKE_CURRENT_BINARY_DIR}/FooConfigVersion.cmake
DESTINATION ${LIB_INSTALL_DIR}/Foo/cmake )

FooConfig.cmake.in:

set(FOO_VERSION x.y.z)
...
@PACKAGE_INIT@
...
set_and_check(FOO_INCLUDE_DIR "@PACKAGE_INCLUDE_INSTALL_DIR@")
set_and_check(FOO_SYSCONFIG_DIR "@PACKAGE_SYSCONFIG_INSTALL_DIR@")

check_required_components(Foo)

CMakePrintHelpers
Convenience functions for printing properties and variables, useful e.g. for debugging.

cmake_print_properties([TARGETS target1 .. targetN]
[SOURCES source1 .. sourceN]
[DIRECTORIES dir1 .. dirN]
[TESTS test1 .. testN]
[CACHE_ENTRIES entry1 .. entryN]
PROPERTIES prop1 .. propN )

This function prints the values of the properties of the given targets, source files, directories, tests
or cache entries. Exactly one of the scope keywords must be used. Example:

cmake_print_properties(TARGETS foo bar PROPERTIES
LOCATION INTERFACE_INCLUDE_DIRECTORIES)

This will print the LOCATION and INTERFACE_INCLUDE_DIRECTORIES properties for both targets foo and bar.

cmake_print_variables(var1 var2 .. varN)

This function will print the name of each variable followed by its value. Example:

cmake_print_variables(CMAKE_C_COMPILER CMAKE_MAJOR_VERSION DOES_NOT_EXIST)

Gives:

-- CMAKE_C_COMPILER="/usr/bin/gcc" ; CMAKE_MAJOR_VERSION="2" ; DOES_NOT_EXIST=""

CMakePrintSystemInformation
Print system information.

This module serves diagnostic purposes. Just include it in a project to see various internal CMake
variables.

CMakePushCheckState
This module defines three macros: CMAKE_PUSH_CHECK_STATE() CMAKE_POP_CHECK_STATE() and
CMAKE_RESET_CHECK_STATE() These macros can be used to save, restore and reset (i.e., clear contents) the
state of the variables CMAKE_REQUIRED_FLAGS, CMAKE_REQUIRED_DEFINITIONS, CMAKE_REQUIRED_LINK_OPTIONS,
CMAKE_REQUIRED_LIBRARIES, CMAKE_REQUIRED_INCLUDES and CMAKE_EXTRA_INCLUDE_FILES used by the various
Check-files coming with CMake, like e.g. check_function_exists() etc. The variable contents are pushed
on a stack, pushing multiple times is supported. This is useful e.g. when executing such tests in a
Find-module, where they have to be set, but after the Find-module has been executed they should have the
same value as they had before.

CMAKE_PUSH_CHECK_STATE() macro receives optional argument RESET. Whether it's specified,
CMAKE_PUSH_CHECK_STATE() will set all CMAKE_REQUIRED_* variables to empty values, same as
CMAKE_RESET_CHECK_STATE() call will do.

Usage:

cmake_push_check_state(RESET)
set(CMAKE_REQUIRED_DEFINITIONS -DSOME_MORE_DEF)
check_function_exists(...)
cmake_reset_check_state()
set(CMAKE_REQUIRED_DEFINITIONS -DANOTHER_DEF)
check_function_exists(...)
cmake_pop_check_state()

CMakeVerifyManifest
CMakeVerifyManifest.cmake

This script is used to verify that embedded manifests and side by side manifests for a project match. To
run this script, cd to a directory and run the script with cmake -P. On the command line you can pass in
versions that are OK even if not found in the .manifest files. For example, cmake
-Dallow_versions=8.0.50608.0 -PCmakeVerifyManifest.cmake could be used to allow an embedded manifest of
8.0.50608.0 to be used in a project even if that version was not found in the .manifest file.

CPack
Configure generators for binary installers and source packages.

Introduction
The CPack module generates the configuration files CPackConfig.cmake and CPackSourceConfig.cmake. They
are intended for use in a subsequent run of the cpack program where they steer the generation of
installers or/and source packages.

Depending on the CMake generator, the CPack module may also add two new build targets, package and
package_source. See the packaging targets section below for details.

The generated binary installers will contain all files that have been installed via CMake's install()
command (and the deprecated commands install_files(), install_programs(), and install_targets()). Note
that the DESTINATION option of the install() command must be a relative path; otherwise installed files
are ignored by CPack.

Certain kinds of binary installers can be configured such that users can select individual application
components to install. See the CPackComponent module for further details.

Source packages (configured through CPackSourceConfig.cmake and generated by the CPack Archive Generator)
will contain all source files in the project directory except those specified in
CPACK_SOURCE_IGNORE_FILES.

CPack Generators
The CPACK_GENERATOR variable has different meanings in different contexts. In a CMakeLists.txt file,
CPACK_GENERATOR is a list of generators: and when cpack is run with no other arguments, it will iterate
over that list and produce one package for each generator. In a CPACK_PROJECT_CONFIG_FILE,
CPACK_GENERATOR is a string naming a single generator. If you need per-cpack-generator logic to control
other cpack settings, then you need a CPACK_PROJECT_CONFIG_FILE. If set, the CPACK_PROJECT_CONFIG_FILE
is included automatically on a per-generator basis. It only need contain overrides.

Here's how it works:

• cpack runs

• it includes CPackConfig.cmake

• it iterates over the generators given by the -G command line option, or if no such option was
specified, over the list of generators given by the CPACK_GENERATOR variable set in the
CPackConfig.cmake input file.

• foreach generator, it then

• sets CPACK_GENERATOR to the one currently being iterated

• includes the CPACK_PROJECT_CONFIG_FILE

• produces the package for that generator

This is the key: For each generator listed in CPACK_GENERATOR in CPackConfig.cmake, cpack will reset
CPACK_GENERATOR internally to the one currently being used and then include the
CPACK_PROJECT_CONFIG_FILE.

For a list of available generators, see cpack-generators(7).

Targets package and package_source
If CMake is run with the Makefile, Ninja, or Xcode generator, then include(CPack) generates a target
package. This makes it possible to build a binary installer from CMake, Make, or Ninja: Instead of cpack,
one may call cmake --build . --target package or make package or ninja package. The VS generator creates
an uppercase target PACKAGE.

If CMake is run with the Makefile or Ninja generator, then include(CPack) also generates a target
package_source. To build a source package, instead of cpack -G TGZ --config CPackSourceConfig.cmake one
may call cmake --build . --target package_source, make package_source, or ninja package_source.

Variables common to all CPack Generators
Before including this CPack module in your CMakeLists.txt file, there are a variety of variables that can
be set to customize the resulting installers. The most commonly-used variables are:

CPACK_PACKAGE_NAME
The name of the package (or application). If not specified, it defaults to the project name.

CPACK_PACKAGE_VENDOR
The name of the package vendor. (e.g., "Kitware"). The default is "Humanity".

CPACK_PACKAGE_DIRECTORY
The directory in which CPack is doing its packaging. If it is not set then this will default
(internally) to the build dir. This variable may be defined in a CPack config file or from the
cpack command line option -B. If set, the command line option overrides the value found in the
config file.

CPACK_PACKAGE_VERSION_MAJOR
Package major version. This variable will always be set, but its default value depends on whether
or not version details were given to the project() command in the top level CMakeLists.txt file.
If version details were given, the default value will be CMAKE_PROJECT_VERSION_MAJOR. If no
version details were given, a default version of 0.1.1 will be assumed, leading to
CPACK_PACKAGE_VERSION_MAJOR having a default value of 0.

CPACK_PACKAGE_VERSION_MINOR
Package minor version. The default value is determined based on whether or not version details
were given to the project() command in the top level CMakeLists.txt file. If version details were
given, the default value will be CMAKE_PROJECT_VERSION_MINOR, but if no minor version component
was specified then CPACK_PACKAGE_VERSION_MINOR will be left unset. If no project version was
given at all, a default version of 0.1.1 will be assumed, leading to CPACK_PACKAGE_VERSION_MINOR
having a default value of 1.

CPACK_PACKAGE_VERSION_PATCH
Package patch version. The default value is determined based on whether or not version details
were given to the project() command in the top level CMakeLists.txt file. If version details were
given, the default value will be CMAKE_PROJECT_VERSION_PATCH, but if no patch version component
was specified then CPACK_PACKAGE_VERSION_PATCH will be left unset. If no project version was
given at all, a default version of 0.1.1 will be assumed, leading to CPACK_PACKAGE_VERSION_PATCH
having a default value of 1.

CPACK_PACKAGE_DESCRIPTION
A description of the project, used in places such as the introduction screen of CPack-generated
Windows installers. If not set, the value of this variable is populated from the file named by
CPACK_PACKAGE_DESCRIPTION_FILE.

CPACK_PACKAGE_DESCRIPTION_FILE
A text file used to describe the project when CPACK_PACKAGE_DESCRIPTION is not explicitly set.
The default value for CPACK_PACKAGE_DESCRIPTION_FILE points to a built-in template file
Templates/CPack.GenericDescription.txt.

CPACK_PACKAGE_DESCRIPTION_SUMMARY
Short description of the project (only a few words). If the CMAKE_PROJECT_DESCRIPTION variable is
set, it is used as the default value, otherwise the default will be a string generated by CMake
based on CMAKE_PROJECT_NAME.

CPACK_PACKAGE_HOMEPAGE_URL
Project homepage URL. The default value is taken from the CMAKE_PROJECT_HOMEPAGE_URL variable,
which is set by the top level project() command, or else the default will be empty if no URL was
provided to project().

CPACK_PACKAGE_FILE_NAME
The name of the package file to generate, not including the extension. For example,
cmake-2.6.1-Linux-i686. The default value is:

${CPACK_PACKAGE_NAME}-${CPACK_PACKAGE_VERSION}-${CPACK_SYSTEM_NAME}

CPACK_PACKAGE_INSTALL_DIRECTORY
Installation directory on the target system. This may be used by some CPack generators like NSIS
to create an installation directory e.g., "CMake 2.5" below the installation prefix. All
installed elements will be put inside this directory.

CPACK_PACKAGE_ICON
A branding image that will be displayed inside the installer (used by GUI installers).

CPACK_PACKAGE_CHECKSUM
New in version 3.7.

An algorithm that will be used to generate an additional file with the checksum of the package.
The output file name will be:

${CPACK_PACKAGE_FILE_NAME}.${CPACK_PACKAGE_CHECKSUM}

Supported algorithms are those listed by the string(<HASH>) command.

CPACK_PROJECT_CONFIG_FILE
CPack-time project CPack configuration file. This file is included at cpack time, once per
generator after CPack has set CPACK_GENERATOR to the actual generator being used. It allows
per-generator setting of CPACK_* variables at cpack time.

CPACK_RESOURCE_FILE_LICENSE
License to be embedded in the installer. It will typically be displayed to the user by the
produced installer (often with an explicit "Accept" button, for graphical installers) prior to
installation. This license file is NOT added to the installed files but is used by some CPack
generators like NSIS. If you want to install a license file (may be the same as this one) along
with your project, you must add an appropriate CMake install() command in your CMakeLists.txt.

CPACK_RESOURCE_FILE_README
ReadMe file to be embedded in the installer. It typically describes in some detail the purpose of
the project during the installation. Not all CPack generators use this file.

CPACK_RESOURCE_FILE_WELCOME
Welcome file to be embedded in the installer. It welcomes users to this installer. Typically
used in the graphical installers on Windows and Mac OS X.

CPACK_MONOLITHIC_INSTALL
Disables the component-based installation mechanism. When set, the component specification is
ignored and all installed items are put in a single "MONOLITHIC" package. Some CPack generators
do monolithic packaging by default and may be asked to do component packaging by setting
CPACK_<GENNAME>_COMPONENT_INSTALL to TRUE.

CPACK_GENERATOR
List of CPack generators to use. If not specified, CPack will create a set of options following
the naming pattern CPACK_BINARY_<GENNAME> (e.g. CPACK_BINARY_NSIS) allowing the user to
enable/disable individual generators. If the -G option is given on the cpack command line, it
will override this variable and any CPACK_BINARY_<GENNAME> options.

CPACK_OUTPUT_CONFIG_FILE
The name of the CPack binary configuration file. This file is the CPack configuration generated
by the CPack module for binary installers. Defaults to CPackConfig.cmake.

CPACK_PACKAGE_EXECUTABLES
Lists each of the executables and associated text label to be used to create Start Menu shortcuts.
For example, setting this to the list ccmake;CMake will create a shortcut named "CMake" that will
execute the installed executable ccmake. Not all CPack generators use it (at least NSIS, WIX and
OSXX11 do).

CPACK_STRIP_FILES
List of files to be stripped. Starting with CMake 2.6.0, CPACK_STRIP_FILES will be a boolean
variable which enables stripping of all files (a list of files evaluates to TRUE in CMake, so this
change is compatible).

CPACK_VERBATIM_VARIABLES
New in version 3.4.

If set to TRUE, values of variables prefixed with CPACK_ will be escaped before being written to
the configuration files, so that the cpack program receives them exactly as they were specified.
If not, characters like quotes and backslashes can cause parsing errors or alter the value
received by the cpack program. Defaults to FALSE for backwards compatibility.

CPACK_THREADS
New in version 3.20.

Number of threads to use when performing parallelized operations, such as compressing the
installer package.

Some compression methods used by CPack generators such as Debian or Archive may take advantage of
multiple CPU cores to speed up compression. CPACK_THREADS can be set to specify how many threads
will be used for compression.

A positive integer can be used to specify an exact desired thread count.

When given a negative integer CPack will use the absolute value as the upper limit but may choose
a lower value based on the available hardware concurrency.

Given 0 CPack will try to use all available CPU cores.

By default CPACK_THREADS is set to 1.

Currently only xz compression may take advantage of multiple cores. Other compression methods
ignore this value and use only one thread.

New in version 3.21: Official CMake binaries available on cmake.org now ship with a liblzma that
supports parallel compression. Older versions did not.

Variables for Source Package Generators
The following CPack variables are specific to source packages, and will not affect binary packages:

CPACK_SOURCE_PACKAGE_FILE_NAME
The name of the source package. For example cmake-2.6.1.

CPACK_SOURCE_STRIP_FILES
List of files in the source tree that will be stripped. Starting with CMake 2.6.0,
CPACK_SOURCE_STRIP_FILES will be a boolean variable which enables stripping of all files (a list
of files evaluates to TRUE in CMake, so this change is compatible).

CPACK_SOURCE_GENERATOR
List of generators used for the source packages. As with CPACK_GENERATOR, if this is not
specified then CPack will create a set of options (e.g. CPACK_SOURCE_ZIP) allowing users to select
which packages will be generated.

CPACK_SOURCE_OUTPUT_CONFIG_FILE
The name of the CPack source configuration file. This file is the CPack configuration generated
by the CPack module for source installers. Defaults to CPackSourceConfig.cmake.

CPACK_SOURCE_IGNORE_FILES
Pattern of files in the source tree that won't be packaged when building a source package. This
is a list of regular expression patterns (that must be properly escaped), e.g.,
/CVS/;/\\.svn/;\\.swp$;\\.#;/#;.*~;cscope.*

Variables for Advanced Use
The following variables are for advanced uses of CPack:

CPACK_CMAKE_GENERATOR
What CMake generator should be used if the project is a CMake project. Defaults to the value of
CMAKE_GENERATOR. Few users will want to change this setting.

CPACK_INSTALL_CMAKE_PROJECTS
List of four values that specify what project to install. The four values are: Build directory,
Project Name, Project Component, Directory. If omitted, CPack will build an installer that
installs everything.

CPACK_SYSTEM_NAME
System name, defaults to the value of CMAKE_SYSTEM_NAME, except on Windows where it will be win32
or win64.

CPACK_PACKAGE_VERSION
Package full version, used internally. By default, this is built from
CPACK_PACKAGE_VERSION_MAJOR, CPACK_PACKAGE_VERSION_MINOR, and CPACK_PACKAGE_VERSION_PATCH.

CPACK_TOPLEVEL_TAG
Directory for the installed files.

CPACK_INSTALL_COMMANDS
Extra commands to install components. The environment variable CMAKE_INSTALL_PREFIX is set to the
temporary install directory during execution.

CPACK_INSTALL_SCRIPTS
New in version 3.16.

Extra CMake scripts executed by CPack during its local staging installation. They are executed
before installing the files to be packaged. The scripts are not called by a standalone install
(e.g.: make install). For every script, the following variables will be set:
CMAKE_CURRENT_SOURCE_DIR, CMAKE_CURRENT_BINARY_DIR and CMAKE_INSTALL_PREFIX (which is set to the
staging install directory). The singular form CMAKE_INSTALL_SCRIPT is supported as an alternative
variable for historical reasons, but its value is ignored if CMAKE_INSTALL_SCRIPTS is set and a
warning will be issued.

See also CPACK_PRE_BUILD_SCRIPTS and CPACK_POST_BUILD_SCRIPTS which can be used to specify scripts
to be executed later in the packaging process.

CPACK_PRE_BUILD_SCRIPTS
New in version 3.19.

List of CMake scripts to execute after CPack has installed the files to be packaged into a staging
directory and before producing the package(s) from those files. See also CPACK_INSTALL_SCRIPTS and
CPACK_POST_BUILD_SCRIPTS.

CPACK_POST_BUILD_SCRIPTS
New in version 3.19.

List of CMake scripts to execute after CPack has produced the resultant packages and before
copying them back to the build directory. See also CPACK_INSTALL_SCRIPTS, CPACK_PRE_BUILD_SCRIPTS
and CPACK_PACKAGE_FILES.

CPACK_PACKAGE_FILES
New in version 3.19.

List of package files created in the staging directory, with each file provided as a full absolute
path. This variable is populated by CPack just before invoking the post-build scripts listed in
CPACK_POST_BUILD_SCRIPTS. It is the preferred way for the post-build scripts to know the set of
package files to operate on. Projects should not try to set this variable themselves.

CPACK_INSTALLED_DIRECTORIES
Extra directories to install.

CPACK_PACKAGE_INSTALL_REGISTRY_KEY
Registry key used when installing this project. This is only used by installers for Windows. The
default value is based on the installation directory.

CPACK_CREATE_DESKTOP_LINKS
List of desktop links to create. Each desktop link requires a corresponding start menu shortcut
as created by CPACK_PACKAGE_EXECUTABLES.

CPACK_BINARY_<GENNAME>
CPack generated options for binary generators. The CPack.cmake module generates (when
CPACK_GENERATOR is not set) a set of CMake options (see CMake option() command) which may then be
used to select the CPack generator(s) to be used when building the package target or when running
cpack without the -G option.

CPackComponent
Configure components for binary installers and source packages.

Introduction
This module is automatically included by CPack.

Certain binary installers (especially the graphical installers) generated by CPack allow users to select
individual application components to install. This module allows developers to configure the packaging
of such components.

Contents is assigned to components by the COMPONENT argument of CMake's install() command. Components
can be annotated with user-friendly names and descriptions, inter-component dependencies, etc., and
grouped in various ways to customize the resulting installer, using the commands described below.

To specify different groupings for different CPack generators use a CPACK_PROJECT_CONFIG_FILE.

Variables
The following variables influence the component-specific packaging:

CPACK_COMPONENTS_ALL
The list of component to install.

The default value of this variable is computed by CPack and contains all components defined by the
project. The user may set it to only include the specified components.

Instead of specifying all the desired components, it is possible to obtain a list of all defined
components and then remove the unwanted ones from the list. The get_cmake_property() command can
be used to obtain the COMPONENTS property, then the list(REMOVE_ITEM) command can be used to
remove the unwanted ones. For example, to use all defined components except foo and bar:

get_cmake_property(CPACK_COMPONENTS_ALL COMPONENTS)
list(REMOVE_ITEM CPACK_COMPONENTS_ALL "foo" "bar")

CPACK_<GENNAME>_COMPONENT_INSTALL
Enable/Disable component install for CPack generator <GENNAME>.

Each CPack Generator (RPM, DEB, ARCHIVE, NSIS, DMG, etc...) has a legacy default behavior. e.g.
RPM builds monolithic whereas NSIS builds component. One can change the default behavior by
setting this variable to 0/1 or OFF/ON.

CPACK_COMPONENTS_GROUPING
Specify how components are grouped for multi-package component-aware CPack generators.

Some generators like RPM or ARCHIVE (TGZ, ZIP, ...) may generate several packages files when there
are components, depending on the value of this variable:

• ONE_PER_GROUP (default): create one package per component group

• IGNORE : create one package per component (ignore the groups)

• ALL_COMPONENTS_IN_ONE : create a single package with all requested components

CPACK_COMPONENT_<compName>_DISPLAY_NAME
The name to be displayed for a component.

CPACK_COMPONENT_<compName>_DESCRIPTION
The description of a component.

CPACK_COMPONENT_<compName>_GROUP
The group of a component.

CPACK_COMPONENT_<compName>_DEPENDS
The dependencies (list of components) on which this component depends.

CPACK_COMPONENT_<compName>_HIDDEN
True if this component is hidden from the user.

CPACK_COMPONENT_<compName>_REQUIRED
True if this component is required.

CPACK_COMPONENT_<compName>_DISABLED
True if this component is not selected to be installed by default.

Commands
Add component
cpack_add_component

Describe an installation component.

cpack_add_component(compname
[DISPLAY_NAME name]
[DESCRIPTION description]
[HIDDEN | REQUIRED | DISABLED ]
[GROUP group]
[DEPENDS comp1 comp2 ... ]
[INSTALL_TYPES type1 type2 ... ]
[DOWNLOADED]
[ARCHIVE_FILE filename]
[PLIST filename])

compname is the name of an installation component, as defined by the COMPONENT argument of one or more
CMake install() commands. With the cpack_add_component command one can set a name, a description, and
other attributes of an installation component. One can also assign a component to a component group.

DISPLAY_NAME is the displayed name of the component, used in graphical installers to display the
component name. This value can be any string.

DESCRIPTION is an extended description of the component, used in graphical installers to give the user
additional information about the component. Descriptions can span multiple lines using \n as the line
separator. Typically, these descriptions should be no more than a few lines long.

HIDDEN indicates that this component will be hidden in the graphical installer, so that the user cannot
directly change whether it is installed or not.

REQUIRED indicates that this component is required, and therefore will always be installed. It will be
visible in the graphical installer, but it cannot be unselected. (Typically, required components are
shown greyed out).

DISABLED indicates that this component should be disabled (unselected) by default. The user is free to
select this component for installation, unless it is also HIDDEN.

DEPENDS lists the components on which this component depends. If this component is selected, then each
of the components listed must also be selected. The dependency information is encoded within the
installer itself, so that users cannot install inconsistent sets of components.

GROUP names the component group of which this component is a part. If not provided, the component will
be a standalone component, not part of any component group. Component groups are described with the
cpack_add_component_group command, detailed below.

INSTALL_TYPES lists the installation types of which this component is a part. When one of these
installations types is selected, this component will automatically be selected. Installation types are
described with the cpack_add_install_type command, detailed below.

DOWNLOADED indicates that this component should be downloaded on-the-fly by the installer, rather than
packaged in with the installer itself. For more information, see the cpack_configure_downloads command.

ARCHIVE_FILE provides a name for the archive file created by CPack to be used for downloaded components.
If not supplied, CPack will create a file with some name based on CPACK_PACKAGE_FILE_NAME and the name of
the component. See cpack_configure_downloads for more information.

PLIST gives a filename that is passed to pkgbuild with the --component-plist argument when using the
productbuild generator.

Add component group
cpack_add_component_group

Describes a group of related CPack installation components.

cpack_add_component_group(groupname
[DISPLAY_NAME name]
[DESCRIPTION description]
[PARENT_GROUP parent]
[EXPANDED]
[BOLD_TITLE])

The cpack_add_component_group describes a group of installation components, which will be placed together
within the listing of options. Typically, component groups allow the user to select/deselect all of the
components within a single group via a single group-level option. Use component groups to reduce the
complexity of installers with many options. groupname is an arbitrary name used to identify the group in
the GROUP argument of the cpack_add_component command, which is used to place a component in a group.
The name of the group must not conflict with the name of any component.

DISPLAY_NAME is the displayed name of the component group, used in graphical installers to display the
component group name. This value can be any string.

DESCRIPTION is an extended description of the component group, used in graphical installers to give the
user additional information about the components within that group. Descriptions can span multiple lines
using \n as the line separator. Typically, these descriptions should be no more than a few lines long.

PARENT_GROUP, if supplied, names the parent group of this group. Parent groups are used to establish a
hierarchy of groups, providing an arbitrary hierarchy of groups.

EXPANDED indicates that, by default, the group should show up as "expanded", so that the user immediately
sees all of the components within the group. Otherwise, the group will initially show up as a single
entry.

BOLD_TITLE indicates that the group title should appear in bold, to call the user's attention to the
group.

Add installation type
cpack_add_install_type

Add a new installation type containing a set of predefined component selections to the graphical
installer.

cpack_add_install_type(typename
[DISPLAY_NAME name])

The cpack_add_install_type command identifies a set of preselected components that represents a common
use case for an application. For example, a "Developer" install type might include an application along
with its header and library files, while an "End user" install type might just include the application's
executable. Each component identifies itself with one or more install types via the INSTALL_TYPES
argument to cpack_add_component.

DISPLAY_NAME is the displayed name of the install type, which will typically show up in a drop-down box
within a graphical installer. This value can be any string.

Configure downloads
cpack_configure_downloads

Configure CPack to download selected components on-the-fly as part of the installation process.

cpack_configure_downloads(site
[UPLOAD_DIRECTORY dirname]
[ALL]
[ADD_REMOVE|NO_ADD_REMOVE])

The cpack_configure_downloads command configures installation-time downloads of selected components. For
each downloadable component, CPack will create an archive containing the contents of that component,
which should be uploaded to the given site. When the user selects that component for installation, the
installer will download and extract the component in place. This feature is useful for creating small
installers that only download the requested components, saving bandwidth. Additionally, the installers
are small enough that they will be installed as part of the normal installation process, and the "Change"
button in Windows Add/Remove Programs control panel will allow one to add or remove parts of the
application after the original installation. On Windows, the downloaded-components functionality
requires the ZipDLL plug-in for NSIS, available at:

http://nsis.sourceforge.net/ZipDLL_plug-in

On macOS, installers that download components on-the-fly can only be built and installed on system using
macOS 10.5 or later.

The site argument is a URL where the archives for downloadable components will reside, e.g.,
https://cmake.org/files/2.6.1/installer/ All of the archives produced by CPack should be uploaded to that
location.

UPLOAD_DIRECTORY is the local directory where CPack will create the various archives for each of the
components. The contents of this directory should be uploaded to a location accessible by the URL given
in the site argument. If omitted, CPack will use the directory CPackUploads inside the CMake binary
directory to store the generated archives.

The ALL flag indicates that all components be downloaded. Otherwise, only those components explicitly
marked as DOWNLOADED or that have a specified ARCHIVE_FILE will be downloaded. Additionally, the ALL
option implies ADD_REMOVE (unless NO_ADD_REMOVE is specified).

ADD_REMOVE indicates that CPack should install a copy of the installer that can be called from Windows'
Add/Remove Programs dialog (via the "Modify" button) to change the set of installed components.
NO_ADD_REMOVE turns off this behavior. This option is ignored on Mac OS X.

CPackIFW
New in version 3.1.

This module looks for the location of the command-line utilities supplied with the Qt Installer Framework
(QtIFW).

The module also defines several commands to control the behavior of the CPack IFW Generator.

Commands
The module defines the following commands:

cpack_ifw_configure_component
Sets the arguments specific to the CPack IFW generator.

cpack_ifw_configure_component(<compname> [COMMON] [ESSENTIAL] [VIRTUAL]
[FORCED_INSTALLATION] [REQUIRES_ADMIN_RIGHTS]
[NAME <name>]
[DISPLAY_NAME <display_name>] # Note: Internationalization supported
[DESCRIPTION <description>] # Note: Internationalization supported
[UPDATE_TEXT <update_text>]
[VERSION <version>]
[RELEASE_DATE <release_date>]
[SCRIPT <script>]
[PRIORITY|SORTING_PRIORITY <sorting_priority>] # Note: PRIORITY is deprecated
[DEPENDS|DEPENDENCIES <com_id> ...]
[AUTO_DEPEND_ON <comp_id> ...]
[LICENSES <display_name> <file_path> ...]
[DEFAULT <value>]
[USER_INTERFACES <file_path> <file_path> ...]
[TRANSLATIONS <file_path> <file_path> ...]
[REPLACES <comp_id> ...]
[CHECKABLE <value>])

This command should be called after cpack_add_component() command.

COMMON if set, then the component will be packaged and installed as part of a group to which it
belongs.

ESSENTIAL
New in version 3.6.

if set, then the package manager stays disabled until that component is updated.

VIRTUAL
New in version 3.8.

if set, then the component will be hidden from the installer. It is a equivalent of the
HIDDEN option from the cpack_add_component() command.

FORCED_INSTALLATION
New in version 3.8.

if set, then the component must always be installed. It is a equivalent of the REQUIRED
option from the cpack_add_component() command.

REQUIRES_ADMIN_RIGHTS
New in version 3.8.

set it if the component needs to be installed with elevated permissions.

NAME is used to create domain-like identification for this component. By default used origin
component name.

DISPLAY_NAME
New in version 3.8.

set to rewrite original name configured by cpack_add_component() command.

DESCRIPTION
New in version 3.8.

set to rewrite original description configured by cpack_add_component() command.

UPDATE_TEXT
New in version 3.8.

will be added to the component description if this is an update to the component.

VERSION
is version of component. By default used CPACK_PACKAGE_VERSION.

RELEASE_DATE
New in version 3.8.

keep empty to auto generate.

SCRIPT is a relative or absolute path to operations script for this component.

SORTING_PRIORITY
New in version 3.8.

is priority of the component in the tree.

PRIORITY
Deprecated since version 3.8: Old name for SORTING_PRIORITY.

DEPENDS, DEPENDENCIES
New in version 3.8.

list of dependency component or component group identifiers in QtIFW style.

New in version 3.21.

Component or group names listed as dependencies may contain hyphens. This requires QtIFW
3.1 or later.

AUTO_DEPEND_ON
New in version 3.8.

list of identifiers of component or component group in QtIFW style that this component has
an automatic dependency on.

LICENSES
pair of <display_name> and <file_path> of license text for this component. You can specify
more then one license.

DEFAULT
New in version 3.8.

Possible values are: TRUE, FALSE, and SCRIPT. Set to FALSE to disable the component in the
installer or to SCRIPT to resolved during runtime (don't forget add the file of the script
as a value of the SCRIPT option).

USER_INTERFACES
New in version 3.7.

is a list of <file_path> ('.ui' files) representing pages to load.

TRANSLATIONS
New in version 3.8.

is a list of <file_path> ('.qm' files) representing translations to load.

REPLACES
New in version 3.10.

list of identifiers of component or component group to replace.

CHECKABLE
New in version 3.10.

Possible values are: TRUE, FALSE. Set to FALSE if you want to hide the checkbox for an
item. This is useful when only a few subcomponents should be selected instead of all.

cpack_ifw_configure_component_group
Sets the arguments specific to the CPack IFW generator.

cpack_ifw_configure_component_group(<groupname> [VIRTUAL]
[FORCED_INSTALLATION] [REQUIRES_ADMIN_RIGHTS]
[NAME <name>]
[DISPLAY_NAME <display_name>] # Note: Internationalization supported
[DESCRIPTION <description>] # Note: Internationalization supported
[UPDATE_TEXT <update_text>]
[VERSION <version>]
[RELEASE_DATE <release_date>]
[SCRIPT <script>]
[PRIORITY|SORTING_PRIORITY <sorting_priority>] # Note: PRIORITY is deprecated
[DEPENDS|DEPENDENCIES <com_id> ...]
[AUTO_DEPEND_ON <comp_id> ...]
[LICENSES <display_name> <file_path> ...]
[DEFAULT <value>]
[USER_INTERFACES <file_path> <file_path> ...]
[TRANSLATIONS <file_path> <file_path> ...]
[REPLACES <comp_id> ...]
[CHECKABLE <value>])

This command should be called after cpack_add_component_group() command.

VIRTUAL
New in version 3.8.

if set, then the group will be hidden from the installer. Note that setting this on a root
component does not work.

FORCED_INSTALLATION
New in version 3.8.

if set, then the group must always be installed.

REQUIRES_ADMIN_RIGHTS
New in version 3.8.

set it if the component group needs to be installed with elevated permissions.

NAME is used to create domain-like identification for this component group. By default used
origin component group name.

DISPLAY_NAME
New in version 3.8.

set to rewrite original name configured by cpack_add_component_group() command.

DESCRIPTION
New in version 3.8.

set to rewrite original description configured by cpack_add_component_group() command.

UPDATE_TEXT
New in version 3.8.

will be added to the component group description if this is an update to the component
group.

VERSION
is version of component group. By default used CPACK_PACKAGE_VERSION.

RELEASE_DATE
New in version 3.8.

keep empty to auto generate.

SCRIPT is a relative or absolute path to operations script for this component group.

SORTING_PRIORITY
is priority of the component group in the tree.

PRIORITY
Deprecated since version 3.8: Old name for SORTING_PRIORITY.

DEPENDS, DEPENDENCIES
New in version 3.8.

list of dependency component or component group identifiers in QtIFW style.

New in version 3.21.

Component or group names listed as dependencies may contain hyphens. This requires QtIFW
3.1 or later.

AUTO_DEPEND_ON
New in version 3.8.

list of identifiers of component or component group in QtIFW style that this component
group has an automatic dependency on.

LICENSES
pair of <display_name> and <file_path> of license text for this component group. You can
specify more then one license.

DEFAULT
New in version 3.8.

Possible values are: TRUE, FALSE, and SCRIPT. Set to TRUE to preselect the group in the
installer (this takes effect only on groups that have no visible child components) or to
SCRIPT to resolved during runtime (don't forget add the file of the script as a value of
the SCRIPT option).

USER_INTERFACES
New in version 3.7.

is a list of <file_path> ('.ui' files) representing pages to load.

TRANSLATIONS
New in version 3.8.

is a list of <file_path> ('.qm' files) representing translations to load.

REPLACES
New in version 3.10.

list of identifiers of component or component group to replace.

CHECKABLE
New in version 3.10.

Possible values are: TRUE, FALSE. Set to FALSE if you want to hide the checkbox for an
item. This is useful when only a few subcomponents should be selected instead of all.

cpack_ifw_add_repository
Add QtIFW specific remote repository to binary installer.

cpack_ifw_add_repository(<reponame> [DISABLED]
URL <url>
[USERNAME <username>]
[PASSWORD <password>]
[DISPLAY_NAME <display_name>])

This command will also add the <reponame> repository to a variable CPACK_IFW_REPOSITORIES_ALL.

DISABLED
if set, then the repository will be disabled by default.

URL is points to a list of available components.

USERNAME
is used as user on a protected repository.

PASSWORD
is password to use on a protected repository.

DISPLAY_NAME
is string to display instead of the URL.

cpack_ifw_update_repository
New in version 3.6.

Update QtIFW specific repository from remote repository.

cpack_ifw_update_repository(<reponame>
[[ADD|REMOVE] URL <url>]|
[REPLACE OLD_URL <old_url> NEW_URL <new_url>]]
[USERNAME <username>]
[PASSWORD <password>]
[DISPLAY_NAME <display_name>])

This command will also add the <reponame> repository to a variable CPACK_IFW_REPOSITORIES_ALL.

URL is points to a list of available components.

OLD_URL
is points to a list that will replaced.

NEW_URL
is points to a list that will replace to.

USERNAME
is used as user on a protected repository.

PASSWORD
is password to use on a protected repository.

DISPLAY_NAME
is string to display instead of the URL.

cpack_ifw_add_package_resources
New in version 3.7.

Add additional resources in the installer binary.

cpack_ifw_add_package_resources(<file_path> <file_path> ...)

This command will also add the specified files to a variable CPACK_IFW_PACKAGE_RESOURCES.

CPackIFWConfigureFile
New in version 3.8.

The module defines configure_file() similar command to configure file templates prepared in
QtIFW/SDK/Creator style.

Commands
The module defines the following commands:

cpack_ifw_configure_file
Copy a file to another location and modify its contents.

cpack_ifw_configure_file(<input> <output>)

Copies an <input> file to an <output> file and substitutes variable values referenced as %{VAR} or
%VAR% in the input file content. Each variable reference will be replaced with the current value
of the variable, or the empty string if the variable is not defined.

CSharpUtilities
New in version 3.8.

Functions to make configuration of CSharp/.NET targets easier.

A collection of CMake utility functions useful for dealing with CSharp targets for Visual Studio
generators from version 2010 and later.

The following functions are provided by this module:

Main functions

• csharp_set_windows_forms_properties()

• csharp_set_designer_cs_properties()

• csharp_set_xaml_cs_properties()

Helper functions

• csharp_get_filename_keys()

• csharp_get_filename_key_base()

• csharp_get_dependentupon_name()

Main functions provided by the module
csharp_set_windows_forms_properties
Sets source file properties for use of Windows Forms. Use this, if your CSharp target uses Windows
Forms:

csharp_set_windows_forms_properties([<file1> [<file2> [...]]])

<fileN>
List of all source files which are relevant for setting the VS_CSHARP_<tagname> properties
(including .cs, .resx and .Designer.cs extensions).

In the list of all given files for all files ending with .Designer.cs and .resx is searched. For
every designer or resource file a file with the same base name but only .cs as extension is
searched. If this is found, the VS_CSHARP_<tagname> properties are set as follows:

for the .cs file:

• VS_CSHARP_SubType "Form"

for the .Designer.cs file (if it exists):

• VS_CSHARP_DependentUpon <cs-filename>

• VS_CSHARP_DesignTime "" (delete tag if previously defined)

• VS_CSHARP_AutoGen ""(delete tag if previously defined)

for the .resx file (if it exists):

• VS_RESOURCE_GENERATOR "" (delete tag if previously defined)

• VS_CSHARP_DependentUpon <cs-filename>

• VS_CSHARP_SubType "Designer"

csharp_set_designer_cs_properties
Sets source file properties of .Designer.cs files depending on sibling filenames. Use this, if
your CSharp target does not use Windows Forms (for Windows Forms use
csharp_set_designer_cs_properties() instead):

csharp_set_designer_cs_properties([<file1> [<file2> [...]]])

<fileN>
List of all source files which are relevant for setting the VS_CSHARP_<tagname> properties
(including .cs, .resx, .settings and .Designer.cs extensions).

In the list of all given files for all files ending with .Designer.cs is searched. For every
designer file all files with the same base name but different extensions are searched. If a match
is found, the source file properties of the designer file are set depending on the extension of
the matched file:

if match is .resx file:

• VS_CSHARP_AutoGen "True"

• VS_CSHARP_DesignTime "True"

• VS_CSHARP_DependentUpon <resx-filename>

if match is .cs file:

• VS_CSHARP_DependentUpon <cs-filename>

if match is .settings file:

• VS_CSHARP_AutoGen "True"

• VS_CSHARP_DesignTimeSharedInput "True"

• VS_CSHARP_DependentUpon <settings-filename>

NOTE:
Because the source file properties of the .Designer.cs file are set according to the found matches and
every match sets the VS_CSHARP_DependentUpon property, there should only be one match for each
Designer.cs file.

csharp_set_xaml_cs_properties
Sets source file properties for use of Windows Presentation Foundation (WPF) and XAML. Use this,
if your CSharp target uses WPF/XAML:

csharp_set_xaml_cs_properties([<file1> [<file2> [...]]])

<fileN>
List of all source files which are relevant for setting the VS_CSHARP_<tagname> properties
(including .cs, .xaml, and .xaml.cs extensions).

In the list of all given files for all files ending with .xaml.cs is searched. For every xaml-cs
file, a file with the same base name but extension .xaml is searched. If a match is found, the
source file properties of the .xaml.cs file are set:

• VS_CSHARP_DependentUpon <xaml-filename>

Helper functions which are used by the above ones
csharp_get_filename_keys
Helper function which computes a list of key values to identify source files independently of
relative/absolute paths given in cmake and eliminates case sensitivity:

csharp_get_filename_keys(OUT [<file1> [<file2> [...]]])

OUT Name of the variable in which the list of keys is stored

<fileN>
filename(s) as given to to CSharp target using add_library() or add_executable()

In some way the function applies a canonicalization to the source names. This is necessary to
find file matches if the files have been added to the target with different directory prefixes:

add_library(lib
myfile.cs
${CMAKE_CURRENT_SOURCE_DIR}/myfile.Designer.cs)

set_source_files_properties(myfile.Designer.cs PROPERTIES
VS_CSHARP_DependentUpon myfile.cs)

# this will fail, because in cmake
# - ${CMAKE_CURRENT_SOURCE_DIR}/myfile.Designer.cs
# - myfile.Designer.cs
# are not the same source file. The source file property is not set.

csharp_get_filename_key_base
Returns the full filepath and name without extension of a key. KEY is expected to be a key from
csharp_get_filename_keys. In BASE the value of KEY without the file extension is returned:

csharp_get_filename_key_base(BASE KEY)

BASE Name of the variable with the computed "base" of KEY.

KEY The key of which the base will be computed. Expected to be a upper case full filename.

csharp_get_dependentupon_name
Computes a string which can be used as value for the source file property VS_CSHARP_<tagname> with
target being DependentUpon:

csharp_get_dependentupon_name(NAME FILE)

NAME Name of the variable with the result value

FILE Filename to convert to <DependentUpon> value

Actually this is only the filename without any path given at the moment.

CTest
Configure a project for testing with CTest/CDash

Include this module in the top CMakeLists.txt file of a project to enable testing with CTest and
dashboard submissions to CDash:

project(MyProject)
...
include(CTest)

The module automatically creates a BUILD_TESTING option that selects whether to enable testing support
(ON by default). After including the module, use code like:

if(BUILD_TESTING)
# ... CMake code to create tests ...
endif()

to creating tests when testing is enabled.

To enable submissions to a CDash server, create a CTestConfig.cmake file at the top of the project with
content such as:

set(CTEST_NIGHTLY_START_TIME "01:00:00 UTC")
set(CTEST_SUBMIT_URL "http://my.cdash.org/submit.php?project=MyProject")

(the CDash server can provide the file to a project administrator who configures MyProject). Settings in
the config file are shared by both this CTest module and the ctest(1) command-line Dashboard Client mode
(ctest -S).

While building a project for submission to CDash, CTest scans the build output for errors and warnings
and reports them with surrounding context from the build log. This generic approach works for all build
tools, but does not give details about the command invocation that produced a given problem. One may get
more detailed reports by setting the CTEST_USE_LAUNCHERS variable:

set(CTEST_USE_LAUNCHERS 1)

in the CTestConfig.cmake file.

CTestCoverageCollectGCOV
New in version 3.2.

This module provides the ctest_coverage_collect_gcov function.

This function runs gcov on all .gcda files found in the binary tree and packages the resulting .gcov
files into a tar file. This tarball also contains the following:

• data.json defines the source and build directories for use by CDash.

• Labels.json indicates any LABELS that have been set on the source files.

• The uncovered directory holds any uncovered files found by CTEST_EXTRA_COVERAGE_GLOB.

After generating this tar file, it can be sent to CDash for display with the ctest_submit(CDASH_UPLOAD)
command.

ctest_coverage_collect_gcov

ctest_coverage_collect_gcov(TARBALL <tarfile>
[SOURCE <source_dir>][BUILD <build_dir>]
[GCOV_COMMAND <gcov_command>]
[GCOV_OPTIONS <options>...]
)

Run gcov and package a tar file for CDash. The options are:

TARBALL <tarfile>
Specify the location of the .tar file to be created for later upload to CDash. Relative
paths will be interpreted with respect to the top-level build directory.

TARBALL_COMPRESSION <option>
New in version 3.18.

Specify a compression algorithm for the TARBALL data file. Using this option reduces the
size of the data file before it is submitted to CDash. <option> must be one of GZIP,
BZIP2, XZ, ZSTD, FROM_EXT, or an expression that CMake evaluates as FALSE. The default
value is BZIP2.

If FROM_EXT is specified, the resulting file will be compressed based on the file extension
of the <tarfile> (i.e. .tar.gz will use GZIP compression). File extensions that will
produce compressed output include .tar.gz, .tgz, .tar.bzip2, .tbz, .tar.xz, and .txz.

SOURCE <source_dir>
Specify the top-level source directory for the build. Default is the value of
CTEST_SOURCE_DIRECTORY.

BUILD <build_dir>
Specify the top-level build directory for the build. Default is the value of
CTEST_BINARY_DIRECTORY.

GCOV_COMMAND <gcov_command>
Specify the full path to the gcov command on the machine. Default is the value of
CTEST_COVERAGE_COMMAND.

GCOV_OPTIONS <options>...
Specify options to be passed to gcov. The gcov command is run as gcov <options>... -o
<gcov-dir> <file>.gcda. If not specified, the default option is just -b -x.

GLOB New in version 3.6.

Recursively search for .gcda files in build_dir rather than determining search locations by
reading TargetDirectories.txt.

DELETE New in version 3.6.

Delete coverage files after they've been packaged into the .tar.

QUIET Suppress non-error messages that otherwise would have been printed out by this function.

New in version 3.3: Added support for the CTEST_CUSTOM_COVERAGE_EXCLUDE variable.

CTestScriptMode
This file is read by ctest in script mode (-S)

CTestUseLaunchers
Set the RULE_LAUNCH_* global properties when CTEST_USE_LAUNCHERS is on.

CTestUseLaunchers is automatically included when you include(CTest). However, it is split out into its
own module file so projects can use the CTEST_USE_LAUNCHERS functionality independently.

To use launchers, set CTEST_USE_LAUNCHERS to ON in a ctest -S dashboard script, and then also set it in
the cache of the configured project. Both cmake and ctest need to know the value of it for the launchers
to work properly. CMake needs to know in order to generate proper build rules, and ctest, in order to
produce the proper error and warning analysis.

For convenience, you may set the ENV variable CTEST_USE_LAUNCHERS_DEFAULT in your ctest -S script, too.
Then, as long as your CMakeLists uses include(CTest) or include(CTestUseLaunchers), it will use the value
of the ENV variable to initialize a CTEST_USE_LAUNCHERS cache variable. This cache variable
initialization only occurs if CTEST_USE_LAUNCHERS is not already defined.

New in version 3.8: If CTEST_USE_LAUNCHERS is on in a ctest -S script the ctest_configure command will
add -DCTEST_USE_LAUNCHERS:BOOL=TRUE to the cmake command used to configure the project.

Dart
Configure a project for testing with CTest or old Dart Tcl Client

This file is the backwards-compatibility version of the CTest module. It supports using the old Dart 1
Tcl client for driving dashboard submissions as well as testing with CTest. This module should be
included in the CMakeLists.txt file at the top of a project. Typical usage:

include(Dart)
if(BUILD_TESTING)
# ... testing related CMake code ...
endif()

The BUILD_TESTING option is created by the Dart module to determine whether testing support should be
enabled. The default is ON.

DeployQt4
Functions to help assemble a standalone Qt4 executable.

A collection of CMake utility functions useful for deploying Qt4 executables.

The following functions are provided by this module:

write_qt4_conf
resolve_qt4_paths
fixup_qt4_executable
install_qt4_plugin_path
install_qt4_plugin
install_qt4_executable

Requires CMake 2.6 or greater because it uses function and PARENT_SCOPE. Also depends on
BundleUtilities.cmake.

write_qt4_conf(<qt_conf_dir> <qt_conf_contents>)

Writes a qt.conf file with the <qt_conf_contents> into <qt_conf_dir>.

resolve_qt4_paths(<paths_var> [<executable_path>])

Loop through <paths_var> list and if any don't exist resolve them relative to the <executable_path> (if
supplied) or the CMAKE_INSTALL_PREFIX.

fixup_qt4_executable(<executable>
[<qtplugins> <libs> <dirs> <plugins_dir> <request_qt_conf>])

Copies Qt plugins, writes a Qt configuration file (if needed) and fixes up a Qt4 executable using
BundleUtilities so it is standalone and can be drag-and-drop copied to another machine as long as all of
the system libraries are compatible.

<executable> should point to the executable to be fixed-up.

<qtplugins> should contain a list of the names or paths of any Qt plugins to be installed.

<libs> will be passed to BundleUtilities and should be a list of any already installed plugins, libraries
or executables to also be fixed-up.

<dirs> will be passed to BundleUtilities and should contain and directories to be searched to find
library dependencies.

<plugins_dir> allows an custom plugins directory to be used.

<request_qt_conf> will force a qt.conf file to be written even if not needed.

install_qt4_plugin_path(plugin executable copy installed_plugin_path_var
<plugins_dir> <component> <configurations>)

Install (or copy) a resolved <plugin> to the default plugins directory (or <plugins_dir>) relative to
<executable> and store the result in <installed_plugin_path_var>.

If <copy> is set to TRUE then the plugins will be copied rather than installed. This is to allow this
module to be used at CMake time rather than install time.

If <component> is set then anything installed will use this COMPONENT.

install_qt4_plugin(plugin executable copy installed_plugin_path_var
<plugins_dir> <component>)

Install (or copy) an unresolved <plugin> to the default plugins directory (or <plugins_dir>) relative to
<executable> and store the result in <installed_plugin_path_var>. See documentation of
INSTALL_QT4_PLUGIN_PATH.

install_qt4_executable(<executable>
[<qtplugins> <libs> <dirs> <plugins_dir> <request_qt_conf> <component>])

Installs Qt plugins, writes a Qt configuration file (if needed) and fixes up a Qt4 executable using
BundleUtilities so it is standalone and can be drag-and-drop copied to another machine as long as all of
the system libraries are compatible. The executable will be fixed-up at install time. <component> is
the COMPONENT used for bundle fixup and plugin installation. See documentation of FIXUP_QT4_BUNDLE.

ExternalData
Manage data files stored outside source tree

Introduction
Use this module to unambiguously reference data files stored outside the source tree and fetch them at
build time from arbitrary local and remote content-addressed locations. Functions provided by this
module recognize arguments with the syntax DATA{<name>} as references to external data, replace them with
full paths to local copies of those data, and create build rules to fetch and update the local copies.

For example:

include(ExternalData)
set(ExternalData_URL_TEMPLATES "file:///local/%(algo)/%(hash)"
"file:////host/share/%(algo)/%(hash)"
"http://data.org/%(algo)/%(hash)")
ExternalData_Add_Test(MyData
NAME MyTest
COMMAND MyExe DATA{MyInput.png}
)
ExternalData_Add_Target(MyData)

When test MyTest runs the DATA{MyInput.png} argument will be replaced by the full path to a real instance
of the data file MyInput.png on disk. If the source tree contains a content link such as MyInput.png.md5
then the MyData target creates a real MyInput.png in the build tree.

Module Functions
ExternalData_Expand_Arguments
The ExternalData_Expand_Arguments function evaluates DATA{} references in its arguments and
constructs a new list of arguments:

ExternalData_Expand_Arguments(
<target> # Name of data management target
<outVar> # Output variable
[args...] # Input arguments, DATA{} allowed
)

It replaces each DATA{} reference in an argument with the full path of a real data file on disk
that will exist after the <target> builds.

ExternalData_Add_Test
The ExternalData_Add_Test function wraps around the CMake add_test() command but supports DATA{}
references in its arguments:

ExternalData_Add_Test(
<target> # Name of data management target
... # Arguments of add_test(), DATA{} allowed
)

It passes its arguments through ExternalData_Expand_Arguments and then invokes the add_test()
command using the results.

ExternalData_Add_Target
The ExternalData_Add_Target function creates a custom target to manage local instances of data
files stored externally:

ExternalData_Add_Target(
<target> # Name of data management target
[SHOW_PROGRESS <ON|OFF>] # Show progress during the download
)

It creates custom commands in the target as necessary to make data files available for each DATA{}
reference previously evaluated by other functions provided by this module. Data files may be
fetched from one of the URL templates specified in the ExternalData_URL_TEMPLATES variable, or may
be found locally in one of the paths specified in the ExternalData_OBJECT_STORES variable.

New in version 3.20: The SHOW_PROGRESS argument may be passed to suppress progress information
during the download of objects. If not provided, it defaults to OFF for Ninja and Ninja
Multi-Config generators and ON otherwise.

Typically only one target is needed to manage all external data within a project. Call this
function once at the end of configuration after all data references have been processed.

Module Variables
The following variables configure behavior. They should be set before calling any of the functions
provided by this module.

ExternalData_BINARY_ROOT
The ExternalData_BINARY_ROOT variable may be set to the directory to hold the real data files
named by expanded DATA{} references. The default is CMAKE_BINARY_DIR. The directory layout will
mirror that of content links under ExternalData_SOURCE_ROOT.

ExternalData_CUSTOM_SCRIPT_<key>
New in version 3.2.

Specify a full path to a .cmake custom fetch script identified by <key> in entries of the
ExternalData_URL_TEMPLATES list. See Custom Fetch Scripts.

ExternalData_LINK_CONTENT
The ExternalData_LINK_CONTENT variable may be set to the name of a supported hash algorithm to
enable automatic conversion of real data files referenced by the DATA{} syntax into content links.
For each such <file> a content link named <file><ext> is created. The original file is renamed to
the form .ExternalData_<algo>_<hash> to stage it for future transmission to one of the locations
in the list of URL templates (by means outside the scope of this module). The data fetch rule
created for the content link will use the staged object if it cannot be found using any URL
template.

ExternalData_NO_SYMLINKS
New in version 3.3.

The real data files named by expanded DATA{} references may be made available under
ExternalData_BINARY_ROOT using symbolic links on some platforms. The ExternalData_NO_SYMLINKS
variable may be set to disable use of symbolic links and enable use of copies instead.

ExternalData_OBJECT_STORES
The ExternalData_OBJECT_STORES variable may be set to a list of local directories that store
objects using the layout <dir>/%(algo)/%(hash). These directories will be searched first for a
needed object. If the object is not available in any store then it will be fetched remotely using
the URL templates and added to the first local store listed. If no stores are specified the
default is a location inside the build tree.

ExternalData_SERIES_PARSE

ExternalData_SERIES_PARSE_PREFIX

ExternalData_SERIES_PARSE_NUMBER

ExternalData_SERIES_PARSE_SUFFIX

ExternalData_SERIES_MATCH
See Referencing File Series.

ExternalData_SOURCE_ROOT
The ExternalData_SOURCE_ROOT variable may be set to the highest source directory containing any
path named by a DATA{} reference. The default is CMAKE_SOURCE_DIR. ExternalData_SOURCE_ROOT and
CMAKE_SOURCE_DIR must refer to directories within a single source distribution (e.g. they come
together in one tarball).

ExternalData_TIMEOUT_ABSOLUTE
The ExternalData_TIMEOUT_ABSOLUTE variable sets the download absolute timeout, in seconds, with a
default of 300 seconds. Set to 0 to disable enforcement.

ExternalData_TIMEOUT_INACTIVITY
The ExternalData_TIMEOUT_INACTIVITY variable sets the download inactivity timeout, in seconds,
with a default of 60 seconds. Set to 0 to disable enforcement.

ExternalData_URL_ALGO_<algo>_<key>
New in version 3.3.

Specify a custom URL component to be substituted for URL template placeholders of the form
%(algo:<key>), where <key> is a valid C identifier, when fetching an object referenced via hash
algorithm <algo>. If not defined, the default URL component is just <algo> for any <key>.

ExternalData_URL_TEMPLATES
The ExternalData_URL_TEMPLATES may be set to provide a list of URL templates using the
placeholders %(algo) and %(hash) in each template. Data fetch rules try each URL template in
order by substituting the hash algorithm name for %(algo) and the hash value for %(hash).
Alternatively one may use %(algo:<key>) with ExternalData_URL_ALGO_<algo>_<key> variables to gain
more flexibility in remote URLs.

Referencing Files
Referencing Single Files
The DATA{} syntax is literal and the <name> is a full or relative path within the source tree. The
source tree must contain either a real data file at <name> or a "content link" at <name><ext> containing
a hash of the real file using a hash algorithm corresponding to <ext>. For example, the argument
DATA{img.png} may be satisfied by either a real img.png file in the current source directory or a
img.png.md5 file containing its MD5 sum.

New in version 3.8: Multiple content links of the same name with different hash algorithms are supported
(e.g. img.png.sha256 and img.png.sha1) so long as they all correspond to the same real file. This allows
objects to be fetched from sources indexed by different hash algorithms.

Referencing File Series
The DATA{} syntax can be told to fetch a file series using the form DATA{<name>,:}, where the : is
literal. If the source tree contains a group of files or content links named like a series then a
reference to one member adds rules to fetch all of them. Although all members of a series are fetched,
only the file originally named by the DATA{} argument is substituted for it. The default configuration
recognizes file series names ending with #.ext, _#.ext, .#.ext, or -#.ext where # is a sequence of
decimal digits and .ext is any single extension. Configure it with a regex that parses <number> and
<suffix> parts from the end of <name>:

ExternalData_SERIES_PARSE = regex of the form (<number>)(<suffix>)$

For more complicated cases set:

ExternalData_SERIES_PARSE = regex with at least two () groups
ExternalData_SERIES_PARSE_PREFIX = <prefix> regex group number, if any
ExternalData_SERIES_PARSE_NUMBER = <number> regex group number
ExternalData_SERIES_PARSE_SUFFIX = <suffix> regex group number

Configure series number matching with a regex that matches the <number> part of series members named
<prefix><number><suffix>:

ExternalData_SERIES_MATCH = regex matching <number> in all series members

Note that the <suffix> of a series does not include a hash-algorithm extension.

Referencing Associated Files
The DATA{} syntax can alternatively match files associated with the named file and contained in the same
directory. Associated files may be specified by options using the syntax DATA{<name>,<opt1>,<opt2>,...}.
Each option may specify one file by name or specify a regular expression to match file names using the
syntax REGEX:<regex>. For example, the arguments:

DATA{MyData/MyInput.mhd,MyInput.img} # File pair
DATA{MyData/MyFrames00.png,REGEX:MyFrames[0-9]+\\.png} # Series

will pass MyInput.mha and MyFrames00.png on the command line but ensure that the associated files are
present next to them.

Referencing Directories
The DATA{} syntax may reference a directory using a trailing slash and a list of associated files. The
form DATA{<name>/,<opt1>,<opt2>,...} adds rules to fetch any files in the directory that match one of the
associated file options. For example, the argument DATA{MyDataDir/,REGEX:.*} will pass the full path to
a MyDataDir directory on the command line and ensure that the directory contains files corresponding to
every file or content link in the MyDataDir source directory.

New in version 3.3: In order to match associated files in subdirectories, specify a RECURSE: option, e.g.
DATA{MyDataDir/,RECURSE:,REGEX:.*}.

Hash Algorithms
The following hash algorithms are supported:

%(algo) <ext> Description
------- ----- -----------
MD5 .md5 Message-Digest Algorithm 5, RFC 1321
SHA1 .sha1 US Secure Hash Algorithm 1, RFC 3174
SHA224 .sha224 US Secure Hash Algorithms, RFC 4634
SHA256 .sha256 US Secure Hash Algorithms, RFC 4634
SHA384 .sha384 US Secure Hash Algorithms, RFC 4634
SHA512 .sha512 US Secure Hash Algorithms, RFC 4634
SHA3_224 .sha3-224 Keccak SHA-3
SHA3_256 .sha3-256 Keccak SHA-3
SHA3_384 .sha3-384 Keccak SHA-3
SHA3_512 .sha3-512 Keccak SHA-3

New in version 3.8: Added the SHA3_* hash algorithms.

Note that the hashes are used only for unique data identification and download verification.

Custom Fetch Scripts
New in version 3.2.

When a data file must be fetched from one of the URL templates specified in the
ExternalData_URL_TEMPLATES variable, it is normally downloaded using the file(DOWNLOAD) command. One may
specify usage of a custom fetch script by using a URL template of the form
ExternalDataCustomScript://<key>/<loc>. The <key> must be a C identifier, and the <loc> must contain the
%(algo) and %(hash) placeholders. A variable corresponding to the key, ExternalData_CUSTOM_SCRIPT_<key>,
must be set to the full path to a .cmake script file. The script will be included to perform the actual
fetch, and provided with the following variables:

ExternalData_CUSTOM_LOCATION
When a custom fetch script is loaded, this variable is set to the location part of the URL, which
will contain the substituted hash algorithm name and content hash value.

ExternalData_CUSTOM_FILE
When a custom fetch script is loaded, this variable is set to the full path to a file in which the
script must store the fetched content. The name of the file is unspecified and should not be
interpreted in any way.

The custom fetch script is expected to store fetched content in the file or set a variable:

ExternalData_CUSTOM_ERROR
When a custom fetch script fails to fetch the requested content, it must set this variable to a
short one-line message describing the reason for failure.

ExternalProject
Commands
External Project Definition
ExternalProject_Add
The ExternalProject_Add() function creates a custom target to drive download, update/patch,
configure, build, install and test steps of an external project:

ExternalProject_Add(<name> [<option>...])

The individual steps within the process can be driven independently if required (e.g. for CDash
submission) and extra custom steps can be defined, along with the ability to control the step
dependencies. The directory structure used for the management of the external project can also be
customized. The function supports a large number of options which can be used to tailor the
external project behavior.

Directory Options:
Most of the time, the default directory layout is sufficient. It is largely an
implementation detail that the main project usually doesn't need to change. In some
circumstances, however, control over the directory layout can be useful or necessary. The
directory options are potentially more useful from the point of view that the main build
can use the ExternalProject_Get_Property() command to retrieve their values, thereby
allowing the main project to refer to build artifacts of the external project.

PREFIX <dir>
Root directory for the external project. Unless otherwise noted below, all other
directories associated with the external project will be created under here.

TMP_DIR <dir>
Directory in which to store temporary files.

STAMP_DIR <dir>
Directory in which to store the timestamps of each step. Log files from individual
steps are also created in here unless overridden by LOG_DIR (see Logging Options
below).

LOG_DIR <dir>
New in version 3.14.

Directory in which to store the logs of each step.

DOWNLOAD_DIR <dir>
Directory in which to store downloaded files before unpacking them. This directory
is only used by the URL download method, all other download methods use SOURCE_DIR
directly instead.

SOURCE_DIR <dir>
Source directory into which downloaded contents will be unpacked, or for non-URL
download methods, the directory in which the repository should be checked out,
cloned, etc. If no download method is specified, this must point to an existing
directory where the external project has already been unpacked or cloned/checked
out.

NOTE:
If a download method is specified, any existing contents of the source directory
may be deleted. Only the URL download method checks whether this directory is
either missing or empty before initiating the download, stopping with an error if
it is not empty. All other download methods silently discard any previous
contents of the source directory.

BINARY_DIR <dir>
Specify the build directory location. This option is ignored if BUILD_IN_SOURCE is
enabled.

INSTALL_DIR <dir>
Installation prefix to be placed in the <INSTALL_DIR> placeholder. This does not
actually configure the external project to install to the given prefix. That must be
done by passing appropriate arguments to the external project configuration step,
e.g. using <INSTALL_DIR>.

If any of the above ..._DIR options are not specified, their defaults are computed as
follows. If the PREFIX option is given or the EP_PREFIX directory property is set, then an
external project is built and installed under the specified prefix:

TMP_DIR = <prefix>/tmp
STAMP_DIR = <prefix>/src/<name>-stamp
DOWNLOAD_DIR = <prefix>/src
SOURCE_DIR = <prefix>/src/<name>
BINARY_DIR = <prefix>/src/<name>-build
INSTALL_DIR = <prefix>
LOG_DIR = <STAMP_DIR>

Otherwise, if the EP_BASE directory property is set then components of an external project
are stored under the specified base:

TMP_DIR = <base>/tmp/<name>
STAMP_DIR = <base>/Stamp/<name>
DOWNLOAD_DIR = <base>/Download/<name>
SOURCE_DIR = <base>/Source/<name>
BINARY_DIR = <base>/Build/<name>
INSTALL_DIR = <base>/Install/<name>
LOG_DIR = <STAMP_DIR>

If no PREFIX, EP_PREFIX, or EP_BASE is specified, then the default is to set PREFIX to
<name>-prefix. Relative paths are interpreted with respect to CMAKE_CURRENT_BINARY_DIR at
the point where ExternalProject_Add() is called.

Download Step Options:
A download method can be omitted if the SOURCE_DIR option is used to point to an existing
non-empty directory. Otherwise, one of the download methods below must be specified
(multiple download methods should not be given) or a custom DOWNLOAD_COMMAND provided.

DOWNLOAD_COMMAND <cmd>...
Overrides the command used for the download step (generator expressions are
supported). If this option is specified, all other download options will be ignored.
Providing an empty string for <cmd> effectively disables the download step.

URL Download

URL <url1> [<url2>...]
List of paths and/or URL(s) of the external project's source. When more than
one URL is given, they are tried in turn until one succeeds. A URL may be an
ordinary path in the local file system (in which case it must be the only URL
provided) or any downloadable URL supported by the file(DOWNLOAD) command. A
local filesystem path may refer to either an existing directory or to an
archive file, whereas a URL is expected to point to a file which can be
treated as an archive. When an archive is used, it will be unpacked
automatically unless the DOWNLOAD_NO_EXTRACT option is set to prevent it. The
archive type is determined by inspecting the actual content rather than using
logic based on the file extension.

Changed in version 3.7: Multiple URLs are allowed.

URL_HASH <algo>=<hashValue>
Hash of the archive file to be downloaded. The argument should be of the form
<algo>=<hashValue> where algo can be any of the hashing algorithms supported
by the file() command. Specifying this option is strongly recommended for URL
downloads, as it ensures the integrity of the downloaded content. It is also
used as a check for a previously downloaded file, allowing connection to the
remote location to be avoided altogether if the local directory already has a
file from an earlier download that matches the specified hash.

URL_MD5 <md5>
Equivalent to URL_HASH MD5=<md5>.

DOWNLOAD_NAME <fname>
File name to use for the downloaded file. If not given, the end of the URL is
used to determine the file name. This option is rarely needed, the default
name is generally suitable and is not normally used outside of code internal
to the ExternalProject module.

DOWNLOAD_NO_EXTRACT <bool>
New in version 3.6.

Allows the extraction part of the download step to be disabled by passing a
boolean true value for this option. If this option is not given, the
downloaded contents will be unpacked automatically if required. If extraction
has been disabled, the full path to the downloaded file is available as
<DOWNLOADED_FILE> in subsequent steps or as the property DOWNLOADED_FILE with
the ExternalProject_Get_Property() command.

DOWNLOAD_NO_PROGRESS <bool>
Can be used to disable logging the download progress. If this option is not
given, download progress messages will be logged.

TIMEOUT <seconds>
Maximum time allowed for file download operations.

INACTIVITY_TIMEOUT <seconds>
New in version 3.19.

Terminate the operation after a period of inactivity.

HTTP_USERNAME <username>
New in version 3.7.

Username for the download operation if authentication is required.

HTTP_PASSWORD <password>
New in version 3.7.

Password for the download operation if authentication is required.

HTTP_HEADER <header1> [<header2>...]
New in version 3.7.

Provides an arbitrary list of HTTP headers for the download operation. This
can be useful for accessing content in systems like AWS, etc.

TLS_VERIFY <bool>
Specifies whether certificate verification should be performed for https
URLs. If this option is not provided, the default behavior is determined by
the CMAKE_TLS_VERIFY variable (see file(DOWNLOAD)). If that is also not set,
certificate verification will not be performed. In situations where URL_HASH
cannot be provided, this option can be an alternative verification measure.

Changed in version 3.6: This option also applies to git clone invocations.

TLS_CAINFO <file>
Specify a custom certificate authority file to use if TLS_VERIFY is enabled.
If this option is not specified, the value of the CMAKE_TLS_CAINFO variable
will be used instead (see file(DOWNLOAD))

NETRC <level>
New in version 3.11.

Specify whether the .netrc file is to be used for operation. If this option
is not specified, the value of the CMAKE_NETRC variable will be used instead
(see file(DOWNLOAD)) Valid levels are:

IGNORED
The .netrc file is ignored. This is the default.

OPTIONAL
The .netrc file is optional, and information in the URL is preferred.
The file will be scanned to find which ever information is not
specified in the URL.

REQUIRED
The .netrc file is required, and information in the URL is ignored.

NETRC_FILE <file>
New in version 3.11.

Specify an alternative .netrc file to the one in your home directory if the
NETRC level is OPTIONAL or REQUIRED. If this option is not specified, the
value of the CMAKE_NETRC_FILE variable will be used instead (see
file(DOWNLOAD))

New in version 3.1: Added support for tbz2, .tar.xz, .txz, and .7z extensions.

Git NOTE: A git version of 1.6.5 or later is required if this download method is used.

GIT_REPOSITORY <url>
URL of the git repository. Any URL understood by the git command may be used.

GIT_TAG <tag>
Git branch name, tag or commit hash. Note that branch names and tags should
generally be specified as remote names (i.e. origin/myBranch rather than
simply myBranch). This ensures that if the remote end has its tag moved or
branch rebased or history rewritten, the local clone will still be updated
correctly. In general, however, specifying a commit hash should be preferred
for a number of reasons:

• If the local clone already has the commit corresponding to the hash, no git
fetch needs to be performed to check for changes each time CMake is re-run.
This can result in a significant speed up if many external projects are
being used.

• Using a specific git hash ensures that the main project's own history is
fully traceable to a specific point in the external project's evolution. If
a branch or tag name is used instead, then checking out a specific commit
of the main project doesn't necessarily pin the whole build to a specific
point in the life of the external project. The lack of such deterministic
behavior makes the main project lose traceability and repeatability.

If GIT_SHALLOW is enabled then GIT_TAG works only with branch names and tags.
A commit hash is not allowed.

GIT_REMOTE_NAME <name>
The optional name of the remote. If this option is not specified, it defaults
to origin.

GIT_SUBMODULES <module>...
Specific git submodules that should also be updated. If this option is not
provided, all git submodules will be updated.

Changed in version 3.16: When CMP0097 is set to NEW, if this value is set to
an empty string then no submodules are initialized or updated.

GIT_SUBMODULES_RECURSE <bool>
New in version 3.17.

Specify whether git submodules (if any) should update recursively by passing
the --recursive flag to git submodule update. If not specified, the default
is on.

GIT_SHALLOW <bool>
New in version 3.6.

When this option is enabled, the git clone operation will be given the
--depth 1 option. This performs a shallow clone, which avoids downloading the
whole history and instead retrieves just the commit denoted by the GIT_TAG
option.

GIT_PROGRESS <bool>
New in version 3.8.

When enabled, this option instructs the git clone operation to report its
progress by passing it the --progress option. Without this option, the clone
step for large projects may appear to make the build stall, since nothing
will be logged until the clone operation finishes. While this option can be
used to provide progress to prevent the appearance of the build having
stalled, it may also make the build overly noisy if lots of external projects
are used.

GIT_CONFIG <option1> [<option2>...]
New in version 3.8.

Specify a list of config options to pass to git clone. Each option listed
will be transformed into its own --config <option> on the git clone command
line, with each option required to be in the form key=value.

GIT_REMOTE_UPDATE_STRATEGY <strategy>
New in version 3.18.

When GIT_TAG refers to a remote branch, this option can be used to specify
how the update step behaves. The <strategy> must be one of the following:

CHECKOUT
Ignore the local branch and always checkout the branch specified by
GIT_TAG.

REBASE Try to rebase the current branch to the one specified by GIT_TAG. If
there are local uncommitted changes, they will be stashed first and
popped again after rebasing. If rebasing or popping stashed changes
fail, abort the rebase and halt with an error. When
GIT_REMOTE_UPDATE_STRATEGY is not present, this is the default
strategy unless the default has been overridden with
CMAKE_EP_GIT_REMOTE_UPDATE_STRATEGY (see below).

REBASE_CHECKOUT
Same as REBASE except if the rebase fails, an annotated tag will be
created at the original HEAD position from before the rebase and then
checkout GIT_TAG just like the CHECKOUT strategy. The message stored
on the annotated tag will give information about what was attempted
and the tag name will include a timestamp so that each failed run will
add a new tag. This strategy ensures no changes will be lost, but
updates should always succeed if GIT_TAG refers to a valid ref unless
there are uncommitted changes that cannot be popped successfully.

The variable CMAKE_EP_GIT_REMOTE_UPDATE_STRATEGY can be set to override the
default strategy. This variable should not be set by a project, it is
intended for the user to set. It is primarily intended for use in continuous
integration scripts to ensure that when history is rewritten on a remote
branch, the build doesn't end up with unintended changes or failed builds
resulting from conflicts during rebase operations.

Subversion

SVN_REPOSITORY <url>
URL of the Subversion repository.

SVN_REVISION -r<rev>
Revision to checkout from the Subversion repository.

SVN_USERNAME <username>
Username for the Subversion checkout and update.

SVN_PASSWORD <password>
Password for the Subversion checkout and update.

SVN_TRUST_CERT <bool>
Specifies whether to trust the Subversion server site certificate. If
enabled, the --trust-server-cert option is passed to the svn checkout and
update commands.

Mercurial

HG_REPOSITORY <url>
URL of the mercurial repository.

HG_TAG <tag>
Mercurial branch name, tag or commit id.

CVS

CVS_REPOSITORY <cvsroot>
CVSROOT of the CVS repository.

CVS_MODULE <mod>
Module to checkout from the CVS repository.

CVS_TAG <tag>
Tag to checkout from the CVS repository.

Update/Patch Step Options:
Whenever CMake is re-run, by default the external project's sources will be updated if the
download method supports updates (e.g. a git repository would be checked if the GIT_TAG
does not refer to a specific commit).

UPDATE_COMMAND <cmd>...
Overrides the download method's update step with a custom command. The command may
use generator expressions.

UPDATE_DISCONNECTED <bool>
New in version 3.2.

When enabled, this option causes the update step to be skipped. It does not,
however, prevent the download step. The update step can still be added as a step
target (see ExternalProject_Add_StepTargets()) and called manually. This is useful
if you want to allow developers to build the project when disconnected from the
network (the network may still be needed for the download step though).

When this option is present, it is generally advisable to make the value a cache
variable under the developer's control rather than hard-coding it. If this option is
not present, the default value is taken from the EP_UPDATE_DISCONNECTED directory
property. If that is also not defined, updates are performed as normal. The
EP_UPDATE_DISCONNECTED directory property is intended as a convenience for
controlling the UPDATE_DISCONNECTED behavior for an entire section of a project's
directory hierarchy and may be a more convenient method of giving developers control
over whether or not to perform updates (assuming the project also provides a cache
variable or some other convenient method for setting the directory property).

This may cause a step target to be created automatically for the download step. See
policy CMP0114.

PATCH_COMMAND <cmd>...
Specifies a custom command to patch the sources after an update. By default, no
patch command is defined. Note that it can be quite difficult to define an
appropriate patch command that performs robustly, especially for download methods
such as git where changing the GIT_TAG will not discard changes from a previous
patch, but the patch command will be called again after updating to the new tag.

Configure Step Options:
The configure step is run after the download and update steps. By default, the external
project is assumed to be a CMake project, but this can be overridden if required.

CONFIGURE_COMMAND <cmd>...
The default configure command runs CMake with a few options based on the main
project. The options added are typically only those needed to use the same
generator as the main project, but the CMAKE_GENERATOR option can be given to
override this. The project is responsible for adding any toolchain details, flags
or other settings it wants to re-use from the main project or otherwise specify (see
CMAKE_ARGS, CMAKE_CACHE_ARGS and CMAKE_CACHE_DEFAULT_ARGS below).

For non-CMake external projects, the CONFIGURE_COMMAND option must be used to
override the default configure command (generator expressions are supported). For
projects that require no configure step, specify this option with an empty string as
the command to execute.

CMAKE_COMMAND /.../cmake
Specify an alternative cmake executable for the configure step (use an absolute
path). This is generally not recommended, since it is usually desirable to use the
same CMake version throughout the whole build. This option is ignored if a custom
configure command has been specified with CONFIGURE_COMMAND.

CMAKE_GENERATOR <gen>
Override the CMake generator used for the configure step. Without this option, the
same generator as the main build will be used. This option is ignored if a custom
configure command has been specified with the CONFIGURE_COMMAND option.

CMAKE_GENERATOR_PLATFORM <platform>
New in version 3.1.

Pass a generator-specific platform name to the CMake command (see
CMAKE_GENERATOR_PLATFORM). It is an error to provide this option without the
CMAKE_GENERATOR option.

CMAKE_GENERATOR_TOOLSET <toolset>
Pass a generator-specific toolset name to the CMake command (see
CMAKE_GENERATOR_TOOLSET). It is an error to provide this option without the
CMAKE_GENERATOR option.

CMAKE_GENERATOR_INSTANCE <instance>
New in version 3.11.

Pass a generator-specific instance selection to the CMake command (see
CMAKE_GENERATOR_INSTANCE). It is an error to provide this option without the
CMAKE_GENERATOR option.

CMAKE_ARGS <arg>...
The specified arguments are passed to the cmake command line. They can be any
argument the cmake command understands, not just cache values defined by -D...
arguments (see also CMake Options).

New in version 3.3: Arguments may use generator expressions.

CMAKE_CACHE_ARGS <arg>...
This is an alternate way of specifying cache variables where command line length
issues may become a problem. The arguments are expected to be in the form
-Dvar:STRING=value, which are then transformed into CMake set() commands with the
FORCE option used. These set() commands are written to a pre-load script which is
then applied using the cmake -C command line option.

New in version 3.3: Arguments may use generator expressions.

CMAKE_CACHE_DEFAULT_ARGS <arg>...
New in version 3.2.

This is the same as the CMAKE_CACHE_ARGS option except the set() commands do not
include the FORCE keyword. This means the values act as initial defaults only and
will not override any variables already set from a previous run. Use this option
with care, as it can lead to different behavior depending on whether the build
starts from a fresh build directory or re-uses previous build contents.

New in version 3.15: If the CMake generator is the Green Hills MULTI and not
overridden then the original project's settings for the GHS toolset and target
system customization cache variables are propagated into the external project.

SOURCE_SUBDIR <dir>
New in version 3.7.

When no CONFIGURE_COMMAND option is specified, the configure step assumes the
external project has a CMakeLists.txt file at the top of its source tree (i.e. in
SOURCE_DIR). The SOURCE_SUBDIR option can be used to point to an alternative
directory within the source tree to use as the top of the CMake source tree instead.
This must be a relative path and it will be interpreted as being relative to
SOURCE_DIR.

New in version 3.14: When BUILD_IN_SOURCE option is enabled, the BUILD_COMMAND is
used to point to an alternative directory within the source tree.

CONFIGURE_HANDLED_BY_BUILD <bool>
New in version 3.20.

Enabling this option relaxes the dependencies of the configure step on other
external projects to order-only. This means the configure step will be executed
after its external project dependencies are built but it will not be marked dirty
when one of its external project dependencies is rebuilt. This option can be enabled
when the build step is smart enough to figure out if the configure step needs to be
rerun. CMake and Meson are examples of build systems whose build step is smart
enough to know if the configure step needs to be rerun.

Build Step Options:
If the configure step assumed the external project uses CMake as its build system, the
build step will also. Otherwise, the build step will assume a Makefile-based build and
simply run make with no arguments as the default build step. This can be overridden with
custom build commands if required.

If both the main project and the external project use make as their build tool, the build
step of the external project is invoked as a recursive make using $(MAKE). This will
communicate some build tool settings from the main project to the external project. If
either the main project or external project is not using make, no build tool settings will
be passed to the external project other than those established by the configure step (i.e.
running ninja -v in the main project will not pass -v to the external project's build step,
even if it also uses ninja as its build tool).

BUILD_COMMAND <cmd>...
Overrides the default build command (generator expressions are supported). If this
option is not given, the default build command will be chosen to integrate with the
main build in the most appropriate way (e.g. using recursive make for Makefile
generators or cmake --build if the project uses a CMake build). This option can be
specified with an empty string as the command to make the build step do nothing.

BUILD_IN_SOURCE <bool>
When this option is enabled, the build will be done directly within the external
project's source tree. This should generally be avoided, the use of a separate build
directory is usually preferred, but it can be useful when the external project
assumes an in-source build. The BINARY_DIR option should not be specified if
building in-source.

BUILD_ALWAYS <bool>
Enabling this option forces the build step to always be run. This can be the easiest
way to robustly ensure that the external project's own build dependencies are
evaluated rather than relying on the default success timestamp-based method. This
option is not normally needed unless developers are expected to modify something the
external project's build depends on in a way that is not detectable via the step
target dependencies (e.g. SOURCE_DIR is used without a download method and
developers might modify the sources in SOURCE_DIR).

BUILD_BYPRODUCTS <file>...
New in version 3.2.

Specifies files that will be generated by the build command but which might or might
not have their modification time updated by subsequent builds. These ultimately get
passed through as BYPRODUCTS to the build step's own underlying call to
add_custom_command().

Install Step Options:
If the configure step assumed the external project uses CMake as its build system, the
install step will also. Otherwise, the install step will assume a Makefile-based build and
simply run make install as the default build step. This can be overridden with custom
install commands if required.

INSTALL_COMMAND <cmd>...
The external project's own install step is invoked as part of the main project's
build. It is done after the external project's build step and may be before or after
the external project's test step (see the TEST_BEFORE_INSTALL option below). The
external project's install rules are not part of the main project's install rules,
so if anything from the external project should be installed as part of the main
build, these need to be specified in the main build as additional install()
commands. The default install step builds the install target of the external
project, but this can be overridden with a custom command using this option
(generator expressions are supported). Passing an empty string as the <cmd> makes
the install step do nothing.

NOTE:
If the CMAKE_INSTALL_MODE environment variable is set when the main project is built, it
will only have an effect if the following conditions are met:

• The main project's configure step assumed the external project uses CMake as its build
system.

• The external project's install command actually runs. Note that due to the way
ExternalProject may use timestamps internally, if nothing the install step depends on
needs to be re-executed, the install command might also not need to run.

Note also that ExternalProject does not check whether the CMAKE_INSTALL_MODE environment
variable changes from one run to another.

Test Step Options:
The test step is only defined if at least one of the following TEST_... options are
provided.

TEST_COMMAND <cmd>...
Overrides the default test command (generator expressions are supported). If this
option is not given, the default behavior of the test step is to build the external
project's own test target. This option can be specified with <cmd> as an empty
string, which allows the test step to still be defined, but it will do nothing. Do
not specify any of the other TEST_... options if providing an empty string as the
test command, but prefer to omit all TEST_... options altogether if the test step
target is not needed.

TEST_BEFORE_INSTALL <bool>
When this option is enabled, the test step will be executed before the install step.
The default behavior is for the test step to run after the install step.

TEST_AFTER_INSTALL <bool>
This option is mainly useful as a way to indicate that the test step is desired but
all default behavior is sufficient. Specifying this option with a boolean true value
ensures the test step is defined and that it comes after the install step. If both
TEST_BEFORE_INSTALL and TEST_AFTER_INSTALL are enabled, the latter is silently
ignored.

TEST_EXCLUDE_FROM_MAIN <bool>
New in version 3.2.

If enabled, the main build's default ALL target will not depend on the test step.
This can be a useful way of ensuring the test step is defined but only gets invoked
when manually requested. This may cause a step target to be created automatically
for either the install or build step. See policy CMP0114.

Output Logging Options:
Each of the following LOG_... options can be used to wrap the relevant step in a script to
capture its output to files. The log files will be created in LOG_DIR if supplied or
otherwise the STAMP_DIR directory with step-specific file names.

LOG_DOWNLOAD <bool>
When enabled, the output of the download step is logged to files.

LOG_UPDATE <bool>
When enabled, the output of the update step is logged to files.

LOG_PATCH <bool>
New in version 3.14.

When enabled, the output of the patch step is logged to files.

LOG_CONFIGURE <bool>
When enabled, the output of the configure step is logged to files.

LOG_BUILD <bool>
When enabled, the output of the build step is logged to files.

LOG_INSTALL <bool>
When enabled, the output of the install step is logged to files.

LOG_TEST <bool>
When enabled, the output of the test step is logged to files.

LOG_MERGED_STDOUTERR <bool>
New in version 3.14.

When enabled, stdout and stderr will be merged for any step whose output is being
logged to files.

LOG_OUTPUT_ON_FAILURE <bool>
New in version 3.14.

This option only has an effect if at least one of the other LOG_<step> options is
enabled. If an error occurs for a step which has logging to file enabled, that
step's output will be printed to the console if LOG_OUTPUT_ON_FAILURE is set to
true. For cases where a large amount of output is recorded, just the end of that
output may be printed to the console.

Terminal Access Options:
New in version 3.4.

Steps can be given direct access to the terminal in some cases. Giving a step access to the
terminal may allow it to receive terminal input if required, such as for authentication
details not provided by other options. With the Ninja generator, these options place the
steps in the console job pool. Each step can be given access to the terminal individually
via the following options:

USES_TERMINAL_DOWNLOAD <bool>
Give the download step access to the terminal.

USES_TERMINAL_UPDATE <bool>
Give the update step access to the terminal.

USES_TERMINAL_CONFIGURE <bool>
Give the configure step access to the terminal.

USES_TERMINAL_BUILD <bool>
Give the build step access to the terminal.

USES_TERMINAL_INSTALL <bool>
Give the install step access to the terminal.

USES_TERMINAL_TEST <bool>
Give the test step access to the terminal.

Target Options:

DEPENDS <targets>...
Specify other targets on which the external project depends. The other targets will
be brought up to date before any of the external project's steps are executed.
Because the external project uses additional custom targets internally for each
step, the DEPENDS option is the most convenient way to ensure all of those steps
depend on the other targets. Simply doing add_dependencies(<name> <targets>) will
not make any of the steps dependent on <targets>.

EXCLUDE_FROM_ALL <bool>
When enabled, this option excludes the external project from the default ALL target
of the main build.

STEP_TARGETS <step-target>...
Generate custom targets for the specified steps. This is required if the steps need
to be triggered manually or if they need to be used as dependencies of other
targets. If this option is not specified, the default value is taken from the
EP_STEP_TARGETS directory property. See ExternalProject_Add_StepTargets() below for
further discussion of the effects of this option.

INDEPENDENT_STEP_TARGETS <step-target>...
Deprecated since version 3.19: This is allowed only if policy CMP0114 is not set to
NEW.

Generates custom targets for the specified steps and prevent these targets from
having the usual dependencies applied to them. If this option is not specified, the
default value is taken from the EP_INDEPENDENT_STEP_TARGETS directory property. This
option is mostly useful for allowing individual steps to be driven independently,
such as for a CDash setup where each step should be initiated and reported
individually rather than as one whole build. See ExternalProject_Add_StepTargets()
below for further discussion of the effects of this option.

Miscellaneous Options:

LIST_SEPARATOR <sep>
For any of the various ..._COMMAND options, replace ; with <sep> in the specified
command lines. This can be useful where list variables may be given in commands
where they should end up as space-separated arguments (<sep> would be a single space
character string in this case).

COMMAND <cmd>...
Any of the other ..._COMMAND options can have additional commands appended to them
by following them with as many COMMAND ... options as needed (generator expressions
are supported). For example:

ExternalProject_Add(example
... # Download options, etc.
BUILD_COMMAND ${CMAKE_COMMAND} -E echo "Starting $<CONFIG> build"
COMMAND ${CMAKE_COMMAND} --build <BINARY_DIR> --config $<CONFIG>
COMMAND ${CMAKE_COMMAND} -E echo "$<CONFIG> build complete"
)

It should also be noted that each build step is created via a call to ExternalProject_Add_Step().
See that command's documentation for the automatic substitutions that are supported for some
options.

Obtaining Project Properties
ExternalProject_Get_Property
The ExternalProject_Get_Property() function retrieves external project target properties:

ExternalProject_Get_Property(<name> <prop1> [<prop2>...])

The function stores property values in variables of the same name. Property names correspond to
the keyword argument names of ExternalProject_Add(). For example, the source directory might be
retrieved like so:

ExternalProject_Get_property(myExtProj SOURCE_DIR)
message("Source dir of myExtProj = ${SOURCE_DIR}")

Explicit Step Management
The ExternalProject_Add() function on its own is often sufficient for incorporating an external project
into the main build. Certain scenarios require additional work to implement desired behavior, such as
adding in a custom step or making steps available as manually triggerable targets. The
ExternalProject_Add_Step(), ExternalProject_Add_StepTargets() and ExternalProject_Add_StepDependencies
functions provide the lower level control needed to implement such step-level capabilities.

ExternalProject_Add_Step
The ExternalProject_Add_Step() function specifies an additional custom step for an external
project defined by an earlier call to ExternalProject_Add():

ExternalProject_Add_Step(<name> <step> [<option>...])

<name> is the same as the name passed to the original call to ExternalProject_Add(). The specified
<step> must not be one of the pre-defined steps (mkdir, download, update, patch, configure, build,
install or test). The supported options are:

COMMAND <cmd>...
The command line to be executed by this custom step (generator expressions are supported).
This option can be repeated multiple times to specify multiple commands to be executed in
order.

COMMENT <text>...
Text to be printed when the custom step executes.

DEPENDEES <step>...
Other steps (custom or pre-defined) on which this step depends.

DEPENDERS <step>...
Other steps (custom or pre-defined) that depend on this new custom step.

DEPENDS <file>...
Files on which this custom step depends.

INDEPENDENT <bool>
New in version 3.19.

Specifies whether this step is independent of the external dependencies specified by the
ExternalProject_Add()'s DEPENDS option. The default is FALSE. Steps marked as independent
may depend only on other steps marked independent. See policy CMP0114.

Note that this use of the term "independent" refers only to independence from external
targets specified by the DEPENDS option and is orthogonal to a step's dependencies on other
steps.

If a step target is created for an independent step by the ExternalProject_Add()
STEP_TARGETS option or by the ExternalProject_Add_StepTargets() function, it will not
depend on the external targets, but may depend on targets for other steps.

BYPRODUCTS <file>...
New in version 3.2.

Files that will be generated by this custom step but which might or might not have their
modification time updated by subsequent builds. This list of files will ultimately be
passed through as the BYPRODUCTS option to the add_custom_command() used to implement the
custom step internally.

ALWAYS <bool>
When enabled, this option specifies that the custom step should always be run (i.e. that it
is always considered out of date).

EXCLUDE_FROM_MAIN <bool>
When enabled, this option specifies that the external project's main target does not depend
on the custom step. This may cause step targets to be created automatically for the steps
on which this step depends. See policy CMP0114.

WORKING_DIRECTORY <dir>
Specifies the working directory to set before running the custom step's command. If this
option is not specified, the directory will be the value of the CMAKE_CURRENT_BINARY_DIR at
the point where ExternalProject_Add_Step() was called.

LOG <bool>
If set, this causes the output from the custom step to be captured to files in the external
project's LOG_DIR if supplied or STAMP_DIR.

USES_TERMINAL <bool>
If enabled, this gives the custom step direct access to the terminal if possible.

The command line, comment, working directory and byproducts of every standard and custom step are
processed to replace the tokens <SOURCE_DIR>, <SOURCE_SUBDIR>, <BINARY_DIR>, <INSTALL_DIR>
<TMP_DIR>, <DOWNLOAD_DIR> and <DOWNLOADED_FILE> with their corresponding property values defined
in the original call to ExternalProject_Add().

New in version 3.3: Token replacement is extended to byproducts.

New in version 3.11: The <DOWNLOAD_DIR> substitution token.

ExternalProject_Add_StepTargets
The ExternalProject_Add_StepTargets() function generates targets for the steps listed. The name of
each created target will be of the form <name>-<step>:

ExternalProject_Add_StepTargets(<name> <step1> [<step2>...])

Creating a target for a step allows it to be used as a dependency of another target or to be
triggered manually. Having targets for specific steps also allows them to be driven independently
of each other by specifying targets on build command lines. For example, you may be submitting to
a sub-project based dashboard where you want to drive the configure portion of the build, then
submit to the dashboard, followed by the build portion, followed by tests. If you invoke a custom
target that depends on a step halfway through the step dependency chain, then all the previous
steps will also run to ensure everything is up to date.

Internally, ExternalProject_Add() calls ExternalProject_Add_Step() to create each step. If any
STEP_TARGETS were specified, then ExternalProject_Add_StepTargets() will also be called after
ExternalProject_Add_Step(). Even if a step is not mentioned in the STEP_TARGETS option,
ExternalProject_Add_StepTargets() can still be called later to manually define a target for the
step.

The STEP_TARGETS option for ExternalProject_Add() is generally the easiest way to ensure targets
are created for specific steps of interest. For custom steps, ExternalProject_Add_StepTargets()
must be called explicitly if a target should also be created for that custom step. An alternative
to these two options is to populate the EP_STEP_TARGETS directory property. It acts as a default
for the step target options and can save having to repeatedly specify the same set of step targets
when multiple external projects are being defined.

New in version 3.19: If CMP0114 is set to NEW, step targets are fully responsible for holding the
custom commands implementing their steps. The primary target created by ExternalProject_Add
depends on the step targets, and the step targets depend on each other. The target-level
dependencies match the file-level dependencies used by the custom commands for each step. The
targets for steps created with ExternalProject_Add_Step()'s INDEPENDENT option do not depend on
the external targets specified by ExternalProject_Add()'s DEPENDS option. The predefined steps
mkdir, download, update, and patch are independent.

If CMP0114 is not NEW, the following deprecated behavior is available:

• A deprecated NO_DEPENDS option may be specified immediately after the <name> and before the
first step. If the NO_DEPENDS option is specified, the step target will not depend on the
dependencies of the external project (i.e. on any dependencies of the <name> custom target
created by ExternalProject_Add()). This is usually safe for the download, update and patch
steps, since they do not typically require that the dependencies are updated and built. Using
NO_DEPENDS for any of the other pre-defined steps, however, may break parallel builds. Only use
NO_DEPENDS where it is certain that the named steps genuinely do not have dependencies. For
custom steps, consider whether or not the custom commands require the dependencies to be
configured, built and installed.

• The INDEPENDENT_STEP_TARGETS option for ExternalProject_Add(), or the
EP_INDEPENDENT_STEP_TARGETS directory property, tells the function to call
ExternalProject_Add_StepTargets() internally using the NO_DEPENDS option for the specified
steps.

ExternalProject_Add_StepDependencies
New in version 3.2.

The ExternalProject_Add_StepDependencies() function can be used to add dependencies to a step. The
dependencies added must be targets CMake already knows about (these can be ordinary executable or
library targets, custom targets or even step targets of another external project):

ExternalProject_Add_StepDependencies(<name> <step> <target1> [<target2>...])

This function takes care to set both target and file level dependencies and will ensure that
parallel builds will not break. It should be used instead of add_dependencies() whenever adding a
dependency for some of the step targets generated by the ExternalProject module.

Examples
The following example shows how to download and build a hypothetical project called FooBar from github:

include(ExternalProject)
ExternalProject_Add(foobar
GIT_REPOSITORY git@github.com:FooCo/FooBar.git
GIT_TAG origin/release/1.2.3
)

For the sake of the example, also define a second hypothetical external project called SecretSauce, which
is downloaded from a web server. Two URLs are given to take advantage of a faster internal network if
available, with a fallback to a slower external server. The project is a typical Makefile project with no
configure step, so some of the default commands are overridden. The build is only required to build the
sauce target:

find_program(MAKE_EXE NAMES gmake nmake make)
ExternalProject_Add(secretsauce
URL http://intranet.somecompany.com/artifacts/sauce-2.7.tgz
https://www.somecompany.com/downloads/sauce-2.7.zip
URL_HASH MD5=d41d8cd98f00b204e9800998ecf8427e
CONFIGURE_COMMAND ""
BUILD_COMMAND ${MAKE_EXE} sauce
)

Suppose the build step of secretsauce requires that foobar must already be built. This could be enforced
like so:

ExternalProject_Add_StepDependencies(secretsauce build foobar)

Another alternative would be to create a custom target for foobar's build step and make secretsauce
depend on that rather than the whole foobar project. This would mean foobar only needs to be built, it
doesn't need to run its install or test steps before secretsauce can be built. The dependency can also be
defined along with the secretsauce project:

ExternalProject_Add_StepTargets(foobar build)
ExternalProject_Add(secretsauce
URL http://intranet.somecompany.com/artifacts/sauce-2.7.tgz
https://www.somecompany.com/downloads/sauce-2.7.zip
URL_HASH MD5=d41d8cd98f00b204e9800998ecf8427e
CONFIGURE_COMMAND ""
BUILD_COMMAND ${MAKE_EXE} sauce
DEPENDS foobar-build
)

Instead of calling ExternalProject_Add_StepTargets(), the target could be defined along with the foobar
project itself:

ExternalProject_Add(foobar
GIT_REPOSITORY git@github.com:FooCo/FooBar.git
GIT_TAG origin/release/1.2.3
STEP_TARGETS build
)

If many external projects should have the same set of step targets, setting a directory property may be
more convenient. The build step target could be created automatically by setting the EP_STEP_TARGETS
directory property before creating the external projects with ExternalProject_Add():

set_property(DIRECTORY PROPERTY EP_STEP_TARGETS build)

Lastly, suppose that secretsauce provides a script called makedoc which can be used to generate its own
documentation. Further suppose that the script expects the output directory to be provided as the only
parameter and that it should be run from the secretsauce source directory. A custom step and a custom
target to trigger the script can be defined like so:

ExternalProject_Add_Step(secretsauce docs
COMMAND <SOURCE_DIR>/makedoc <BINARY_DIR>
WORKING_DIRECTORY <SOURCE_DIR>
COMMENT "Building secretsauce docs"
ALWAYS TRUE
EXCLUDE_FROM_MAIN TRUE
)
ExternalProject_Add_StepTargets(secretsauce docs)

The custom step could then be triggered from the main build like so:

cmake --build . --target secretsauce-docs

FeatureSummary
Functions for generating a summary of enabled/disabled features.

These functions can be used to generate a summary of enabled and disabled packages and/or feature for a
build tree such as:

-- The following OPTIONAL packages have been found:
LibXml2 (required version >= 2.4), XML processing lib, <http://xmlsoft.org>
* Enables HTML-import in MyWordProcessor
* Enables odt-export in MyWordProcessor
PNG, A PNG image library., <http://www.libpng.org/pub/png/>
* Enables saving screenshots
-- The following OPTIONAL packages have not been found:
Lua51, The Lua scripting language., <http://www.lua.org>
* Enables macros in MyWordProcessor
Foo, Foo provides cool stuff.

Global Properties
FeatureSummary_PKG_TYPES

The global property FeatureSummary_PKG_TYPES defines the type of packages used by FeatureSummary.

The order in this list is important, the first package type in the list is the least important, the last
is the most important. the of a package can only be changed to higher types.

The default package types are , RUNTIME, OPTIONAL, RECOMMENDED and REQUIRED, and their importance is
RUNTIME < OPTIONAL < RECOMMENDED < REQUIRED.

FeatureSummary_REQUIRED_PKG_TYPES

The global property FeatureSummary_REQUIRED_PKG_TYPES defines which package types are required.

If one or more package in this categories has not been found, CMake will abort when calling
feature_summary() with the 'FATAL_ON_MISSING_REQUIRED_PACKAGES' option enabled.

The default value for this global property is REQUIRED.

FeatureSummary_DEFAULT_PKG_TYPE

The global property FeatureSummary_DEFAULT_PKG_TYPE defines which package type is the default one. When
calling feature_summary(), if the user did not set the package type explicitly, the package will be
assigned to this category.

This value must be one of the types defined in the FeatureSummary_PKG_TYPES global property unless the
package type is set for all the packages.

The default value for this global property is OPTIONAL.

FeatureSummary_<TYPE>_DESCRIPTION

New in version 3.9.

The global property FeatureSummary_<TYPE>_DESCRIPTION can be defined for each type to replace the type
name with the specified string whenever the package type is used in an output string.

If not set, the string "<TYPE> packages" is used.

Functions
feature_summary

The feature_summary() macro can be used to print information about enabled or disabled packages or
features of a project. By default, only the names of the features/packages will be printed and
their required version when one was specified. Use set_package_properties() to add more useful
information, like e.g. a download URL for the respective package or their purpose in the project.

The WHAT option is the only mandatory option. Here you specify what information will be printed:

ALL print everything

ENABLED_FEATURES
the list of all features which are enabled

DISABLED_FEATURES
the list of all features which are disabled

PACKAGES_FOUND
the list of all packages which have been found

PACKAGES_NOT_FOUND
the list of all packages which have not been found

For each package type <TYPE> defined by the FeatureSummary_PKG_TYPES global property, the
following information can also be used:

<TYPE>_PACKAGES_FOUND
only those packages which have been found which have the type <TYPE>

<TYPE>_PACKAGES_NOT_FOUND
only those packages which have not been found which have the type <TYPE>

Changed in version 3.1: With the exception of the ALL value, these values can be combined in order
to customize the output. For example:

feature_summary(WHAT ENABLED_FEATURES DISABLED_FEATURES)

If a FILENAME is given, the information is printed into this file. If APPEND is used, it is
appended to this file, otherwise the file is overwritten if it already existed. If the VAR option
is used, the information is "printed" into the specified variable. If FILENAME is not used, the
information is printed to the terminal. Using the DESCRIPTION option a description or headline
can be set which will be printed above the actual content. If only one type of package was
requested, no title is printed, unless it is explicitly set using either DESCRIPTION to use a
custom string, or DEFAULT_DESCRIPTION to use a default title for the requested type. If
INCLUDE_QUIET_PACKAGES is given, packages which have been searched with find_package(... QUIET)
will also be listed. By default they are skipped. If FATAL_ON_MISSING_REQUIRED_PACKAGES is given,
CMake will abort if a package which is marked as one of the package types listed in the
FeatureSummary_REQUIRED_PKG_TYPES global property has not been found. The default value for the
FeatureSummary_REQUIRED_PKG_TYPES global property is REQUIRED.

New in version 3.9: The DEFAULT_DESCRIPTION option.

The FeatureSummary_DEFAULT_PKG_TYPE global property can be modified to change the default package
type assigned when not explicitly assigned by the user.

New in version 3.8: If the QUIET_ON_EMPTY option is used, if only one type of package was
requested, and no packages belonging to that category were found, then no output (including the
DESCRIPTION) is printed or added to the VAR variable.

Example 1, append everything to a file:

include(FeatureSummary)
feature_summary(WHAT ALL
FILENAME ${CMAKE_BINARY_DIR}/all.log APPEND)

Example 2, print the enabled features into the variable enabledFeaturesText, including QUIET
packages:

include(FeatureSummary)
feature_summary(WHAT ENABLED_FEATURES
INCLUDE_QUIET_PACKAGES
DESCRIPTION "Enabled Features:"
VAR enabledFeaturesText)
message(STATUS "${enabledFeaturesText}")

Example 3, change default package types and print only the categories that are not empty:

include(FeatureSummary)
set_property(GLOBAL APPEND PROPERTY FeatureSummary_PKG_TYPES BUILD)
find_package(FOO)
set_package_properties(FOO PROPERTIES TYPE BUILD)
feature_summary(WHAT BUILD_PACKAGES_FOUND
Description "Build tools found:"
QUIET_ON_EMPTY)
feature_summary(WHAT BUILD_PACKAGES_NOT_FOUND
Description "Build tools not found:"
QUIET_ON_EMPTY)

set_package_properties

set_package_properties(<name> PROPERTIES
[ URL <url> ]
[ DESCRIPTION <description> ]
[ TYPE (RUNTIME|OPTIONAL|RECOMMENDED|REQUIRED) ]
[ PURPOSE <purpose> ]
)

Use this macro to set up information about the named package, which can then be displayed via
FEATURE_SUMMARY(). This can be done either directly in the Find-module or in the project which
uses the module after the find_package() call. The features for which information can be set are
added automatically by the find_package() command.

URL <url>
This should be the homepage of the package, or something similar. Ideally this is set
already directly in the Find-module.

DESCRIPTION <description>
A short description what that package is, at most one sentence. Ideally this is set
already directly in the Find-module.

TYPE <type>
What type of dependency has the using project on that package. Default is OPTIONAL. In
this case it is a package which can be used by the project when available at buildtime, but
it also work without. RECOMMENDED is similar to OPTIONAL, i.e. the project will build if
the package is not present, but the functionality of the resulting binaries will be
severely limited. If a REQUIRED package is not available at buildtime, the project may not
even build. This can be combined with the FATAL_ON_MISSING_REQUIRED_PACKAGES argument for
feature_summary(). Last, a RUNTIME package is a package which is actually not used at all
during the build, but which is required for actually running the resulting binaries. So if
such a package is missing, the project can still be built, but it may not work later on.
If set_package_properties() is called multiple times for the same package with different
TYPEs, the TYPE is only changed to higher TYPEs (RUNTIME < OPTIONAL < RECOMMENDED <
REQUIRED), lower TYPEs are ignored. The TYPE property is project-specific, so it cannot be
set by the Find-module, but must be set in the project. Type accepted can be changed by
setting the FeatureSummary_PKG_TYPES global property.

PURPOSE <purpose>
This describes which features this package enables in the project, i.e. it tells the user
what functionality he gets in the resulting binaries. If set_package_properties() is
called multiple times for a package, all PURPOSE properties are appended to a list of
purposes of the package in the project. As the TYPE property, also the PURPOSE property is
project-specific, so it cannot be set by the Find-module, but must be set in the project.

Example for setting the info for a package:

find_package(LibXml2)
set_package_properties(LibXml2 PROPERTIES
DESCRIPTION "A XML processing library."
URL "http://xmlsoft.org/")
# or
set_package_properties(LibXml2 PROPERTIES
TYPE RECOMMENDED
PURPOSE "Enables HTML-import in MyWordProcessor")
# or
set_package_properties(LibXml2 PROPERTIES
TYPE OPTIONAL
PURPOSE "Enables odt-export in MyWordProcessor")

find_package(DBUS)
set_package_properties(DBUS PROPERTIES
TYPE RUNTIME
PURPOSE "Necessary to disable the screensaver during a presentation")

add_feature_info

add_feature_info(<name> <enabled> <description>)

Use this macro to add information about a feature with the given <name>. <enabled> contains
whether this feature is enabled or not. It can be a variable or a list of conditions.
<description> is a text describing the feature. The information can be displayed using
feature_summary() for ENABLED_FEATURES and DISABLED_FEATURES respectively.

Changed in version 3.8: <enabled> can be a list of conditions.

Example for setting the info for a feature:

option(WITH_FOO "Help for foo" ON)
add_feature_info(Foo WITH_FOO "The Foo feature provides very cool stuff.")

Legacy Macros
The following macros are provided for compatibility with previous CMake versions:

set_package_info

set_package_info(<name> <description> [ <url> [<purpose>] ])

Use this macro to set up information about the named package, which can then be displayed via
feature_summary(). This can be done either directly in the Find-module or in the project which
uses the module after the find_package() call. The features for which information can be set are
added automatically by the find_package() command.

set_feature_info

set_feature_info(<name> <description> [<url>])

Does the same as:

set_package_info(<name> <description> <url>)

print_enabled_features

print_enabled_features()

Does the same as

feature_summary(WHAT ENABLED_FEATURES DESCRIPTION "Enabled features:")

print_disabled_features

print_disabled_features()

Does the same as

feature_summary(WHAT DISABLED_FEATURES DESCRIPTION "Disabled features:")

FetchContent
New in version 3.11.

Overview
This module enables populating content at configure time via any method supported by the ExternalProject
module. Whereas ExternalProject_Add() downloads at build time, the FetchContent module makes content
available immediately, allowing the configure step to use the content in commands like
add_subdirectory(), include() or file() operations.

Content population details should be defined separately from the command that performs the actual
population. This separation ensures that all the dependency details are defined before anything might
try to use them to populate content. This is particularly important in more complex project hierarchies
where dependencies may be shared between multiple projects.

The following shows a typical example of declaring content details for some dependencies and then
ensuring they are populated with a separate call:

FetchContent_Declare(
googletest
GIT_REPOSITORY https://github.com/google/googletest.git
GIT_TAG 703bd9caab50b139428cea1aaff9974ebee5742e # release-1.10.0
)
FetchContent_Declare(
myCompanyIcons
URL https://intranet.mycompany.com/assets/iconset_1.12.tar.gz
URL_HASH MD5=5588a7b18261c20068beabfb4f530b87
)

FetchContent_MakeAvailable(googletest secret_sauce)

The FetchContent_MakeAvailable() command ensures the named dependencies have been populated, either by an
earlier call or by populating them itself. When performing the population, it will also add them to the
main build, if possible, so that the main build can use the populated projects' targets, etc. See the
command's documentation for how these steps are performed.

When using a hierarchical project arrangement, projects at higher levels in the hierarchy are able to
override the declared details of content specified anywhere lower in the project hierarchy. The first
details to be declared for a given dependency take precedence, regardless of where in the project
hierarchy that occurs. Similarly, the first call that tries to populate a dependency "wins", with
subsequent populations reusing the result of the first instead of repeating the population again. See
the Examples which demonstrate this scenario.

In some cases, the main project may need to have more precise control over the population, or it may be
required to explicitly define the population steps in a way that cannot be captured by the declared
details alone. For such situations, the lower level FetchContent_GetProperties() and
FetchContent_Populate() commands can be used. These lack the richer features provided by
FetchContent_MakeAvailable() though, so their direct use should be considered a last resort. The typical
pattern of such custom steps looks like this:

# NOTE: Where possible, prefer to use FetchContent_MakeAvailable()
# instead of custom logic like this

# Check if population has already been performed
FetchContent_GetProperties(depname)
if(NOT depname_POPULATED)
# Fetch the content using previously declared details
FetchContent_Populate(depname)

# Set custom variables, policies, etc.
# ...

# Bring the populated content into the build
add_subdirectory(${depname_SOURCE_DIR} ${depname_BINARY_DIR})
endif()

The FetchContent module also supports defining and populating content in a single call, with no check for
whether the content has been populated elsewhere already. This should not be done in projects, but may
be appropriate for populating content in CMake's script mode. See FetchContent_Populate() for details.

Commands
FetchContent_Declare

FetchContent_Declare(<name> <contentOptions>...)

The FetchContent_Declare() function records the options that describe how to populate the
specified content. If such details have already been recorded earlier in this project (regardless
of where in the project hierarchy), this and all later calls for the same content <name> are
ignored. This "first to record, wins" approach is what allows hierarchical projects to have
parent projects override content details of child projects.

The content <name> can be any string without spaces, but good practice would be to use only
letters, numbers and underscores. The name will be treated case-insensitively and it should be
obvious for the content it represents, often being the name of the child project or the value
given to its top level project() command (if it is a CMake project). For well-known public
projects, the name should generally be the official name of the project. Choosing an unusual name
makes it unlikely that other projects needing that same content will use the same name, leading to
the content being populated multiple times.

The <contentOptions> can be any of the download, update or patch options that the
ExternalProject_Add() command understands. The configure, build, install and test steps are
explicitly disabled and therefore options related to them will be ignored. The SOURCE_SUBDIR
option is an exception, see FetchContent_MakeAvailable() for details on how that affects behavior.

In most cases, <contentOptions> will just be a couple of options defining the download method and
method-specific details like a commit tag or archive hash. For example:

FetchContent_Declare(
googletest
GIT_REPOSITORY https://github.com/google/googletest.git
GIT_TAG 703bd9caab50b139428cea1aaff9974ebee5742e # release-1.10.0
)

FetchContent_Declare(
myCompanyIcons
URL https://intranet.mycompany.com/assets/iconset_1.12.tar.gz
URL_HASH MD5=5588a7b18261c20068beabfb4f530b87
)

FetchContent_Declare(
myCompanyCertificates
SVN_REPOSITORY svn+ssh://svn.mycompany.com/srv/svn/trunk/certs
SVN_REVISION -r12345
)

Where contents are being fetched from a remote location and you do not control that server, it is
advisable to use a hash for GIT_TAG rather than a branch or tag name. A commit hash is more
secure and helps to confirm that the downloaded contents are what you expected.

Changed in version 3.14: Commands for the download, update or patch steps can access the terminal.
This may be needed for things like password prompts or real-time display of command progress.

New in version 3.22: The CMAKE_TLS_VERIFY, CMAKE_TLS_CAINFO, CMAKE_NETRC and CMAKE_NETRC_FILE
variables now provide the defaults for their corresponding content options, just like they do for
ExternalProject_Add(). Previously, these variables were ignored by the FetchContent module.

FetchContent_MakeAvailable
New in version 3.14.

FetchContent_MakeAvailable(<name1> [<name2>...])

This command ensures that each of the named dependencies are populated and potentially added to
the build by the time it returns. It iterates over the list, and for each dependency, the
following logic is applied:

• If the dependency has already been populated earlier in this run, set the
<lowercaseName>_POPULATED, <lowercaseName>_SOURCE_DIR and <lowercaseName>_BINARY_DIR variables
in the same way as a call to FetchContent_GetProperties(), then skip the remaining steps below
and move on to the next dependency in the list.

• Call FetchContent_Populate() to populate the dependency using the details recorded by an earlier
call to FetchContent_Declare(). Halt with a fatal error if no such details have been recorded.
FETCHCONTENT_SOURCE_DIR_<uppercaseName> can be used to override the declared details and use
content provided at the specified location instead.

• If the top directory of the populated content contains a CMakeLists.txt file, call
add_subdirectory() to add it to the main build. It is not an error for there to be no
CMakeLists.txt file, which allows the command to be used for dependencies that make downloaded
content available at a known location, but which do not need or support being added directly to
the build.

New in version 3.18: The SOURCE_SUBDIR option can be given in the declared details to look
somewhere below the top directory instead (i.e. the same way that SOURCE_SUBDIR is used by the
ExternalProject_Add() command). The path provided with SOURCE_SUBDIR must be relative and will
be treated as relative to the top directory. It can also point to a directory that does not
contain a CMakeLists.txt file or even to a directory that doesn't exist. This can be used to
avoid adding a project that contains a CMakeLists.txt file in its top directory.

Projects should aim to declare the details of all dependencies they might use before they call
FetchContent_MakeAvailable() for any of them. This ensures that if any of the dependencies are
also sub-dependencies of one or more of the others, the main project still controls the details
that will be used (because it will declare them first before the dependencies get a chance to).
In the following code samples, assume that the uses_other dependency also uses FetchContent to add
the other dependency internally:

# WRONG: Should declare all details first
FetchContent_Declare(uses_other ...)
FetchContent_MakeAvailable(uses_other)

FetchContent_Declare(other ...) # Will be ignored, uses_other beat us to it
FetchContent_MakeAvailable(other) # Would use details declared by uses_other

# CORRECT: All details declared first, so they will take priority
FetchContent_Declare(uses_other ...)
FetchContent_Declare(other ...)
FetchContent_MakeAvailable(uses_other other)

FetchContent_Populate
NOTE:
Where possible, prefer to use FetchContent_MakeAvailable() instead of implementing population
manually with this command.

FetchContent_Populate(<name>)

In most cases, the only argument given to FetchContent_Populate() is the <name>. When used this
way, the command assumes the content details have been recorded by an earlier call to
FetchContent_Declare(). The details are stored in a global property, so they are unaffected by
things like variable or directory scope. Therefore, it doesn't matter where in the project the
details were previously declared, as long as they have been declared before the call to
FetchContent_Populate(). Those saved details are then used to construct a call to
ExternalProject_Add() in a private sub-build to perform the content population immediately. The
implementation of ExternalProject_Add() ensures that if the content has already been populated in
a previous CMake run, that content will be reused rather than repopulating them again. For the
common case where population involves downloading content, the cost of the download is only paid
once.

An internal global property records when a particular content population request has been
processed. If FetchContent_Populate() is called more than once for the same content name within a
configure run, the second call will halt with an error. Projects can and should check whether
content population has already been processed with the FetchContent_GetProperties() command before
calling FetchContent_Populate().

FetchContent_Populate() will set three variables in the scope of the caller:

<lowercaseName>_POPULATED
This will always be set to TRUE by the call.

<lowercaseName>_SOURCE_DIR
The location where the populated content can be found upon return.

<lowercaseName>_BINARY_DIR
A directory intended for use as a corresponding build directory.

The main use case for the <lowercaseName>_SOURCE_DIR and <lowercaseName>_BINARY_DIR variables is
to call add_subdirectory() immediately after population:

FetchContent_Populate(FooBar)
add_subdirectory(${foobar_SOURCE_DIR} ${foobar_BINARY_DIR})

The values of the three variables can also be retrieved from anywhere in the project hierarchy
using the FetchContent_GetProperties() command.

The FetchContent_Populate() command also supports a syntax allowing the content details to be
specified directly rather than using any saved details. This is more low-level and use of this
form is generally to be avoided in favor of using saved content details as outlined above.
Nevertheless, in certain situations it can be useful to invoke the content population as an
isolated operation (typically as part of implementing some other higher level feature or when
using CMake in script mode):

FetchContent_Populate(
<name>
[QUIET]
[SUBBUILD_DIR <subBuildDir>]
[SOURCE_DIR <srcDir>]
[BINARY_DIR <binDir>]
...
)

This form has a number of key differences to that where only <name> is provided:

• All required population details are assumed to have been provided directly in the call to
FetchContent_Populate(). Any saved details for <name> are ignored.

• No check is made for whether content for <name> has already been populated.

• No global property is set to record that the population has occurred.

• No global properties record the source or binary directories used for the populated content.

• The FETCHCONTENT_FULLY_DISCONNECTED and FETCHCONTENT_UPDATES_DISCONNECTED cache variables are
ignored.

The <lowercaseName>_SOURCE_DIR and <lowercaseName>_BINARY_DIR variables are still returned to the
caller, but since these locations are not stored as global properties when this form is used, they
are only available to the calling scope and below rather than the entire project hierarchy. No
<lowercaseName>_POPULATED variable is set in the caller's scope with this form.

The supported options for FetchContent_Populate() are the same as those for
FetchContent_Declare(). Those few options shown just above are either specific to
FetchContent_Populate() or their behavior is slightly modified from how ExternalProject_Add()
treats them:

QUIET The QUIET option can be given to hide the output associated with populating the specified
content. If the population fails, the output will be shown regardless of whether this
option was given or not so that the cause of the failure can be diagnosed. The global
FETCHCONTENT_QUIET cache variable has no effect on FetchContent_Populate() calls where the
content details are provided directly.

SUBBUILD_DIR
The SUBBUILD_DIR argument can be provided to change the location of the sub-build created
to perform the population. The default value is
${CMAKE_CURRENT_BINARY_DIR}/<lowercaseName>-subbuild and it would be unusual to need to
override this default. If a relative path is specified, it will be interpreted as relative
to CMAKE_CURRENT_BINARY_DIR. This option should not be confused with the SOURCE_SUBDIR
option which only affects the FetchContent_MakeAvailable() command.

SOURCE_DIR, BINARY_DIR
The SOURCE_DIR and BINARY_DIR arguments are supported by ExternalProject_Add(), but
different default values are used by FetchContent_Populate(). SOURCE_DIR defaults to
${CMAKE_CURRENT_BINARY_DIR}/<lowercaseName>-src and BINARY_DIR defaults to
${CMAKE_CURRENT_BINARY_DIR}/<lowercaseName>-build. If a relative path is specified, it
will be interpreted as relative to CMAKE_CURRENT_BINARY_DIR.

In addition to the above explicit options, any other unrecognized options are passed through
unmodified to ExternalProject_Add() to perform the download, patch and update steps. The
following options are explicitly prohibited (they are disabled by the FetchContent_Populate()
command):

• CONFIGURE_COMMAND

• BUILD_COMMAND

• INSTALL_COMMAND

• TEST_COMMAND

If using FetchContent_Populate() within CMake's script mode, be aware that the implementation sets
up a sub-build which therefore requires a CMake generator and build tool to be available. If these
cannot be found by default, then the CMAKE_GENERATOR and/or CMAKE_MAKE_PROGRAM variables will need
to be set appropriately on the command line invoking the script.

New in version 3.18: Added support for the DOWNLOAD_NO_EXTRACT option.

FetchContent_GetProperties
When using saved content details, a call to FetchContent_MakeAvailable() or
FetchContent_Populate() records information in global properties which can be queried at any time.
This information includes the source and binary directories associated with the content and also
whether or not the content population has been processed during the current configure run.

FetchContent_GetProperties(
<name>
[SOURCE_DIR <srcDirVar>]
[BINARY_DIR <binDirVar>]
[POPULATED <doneVar>]
)

The SOURCE_DIR, BINARY_DIR and POPULATED options can be used to specify which properties should be
retrieved. Each option accepts a value which is the name of the variable in which to store that
property. Most of the time though, only <name> is given, in which case the call will then set the
same variables as a call to FetchContent_MakeAvailable(name) or FetchContent_Populate(name).

This command is rarely needed when using FetchContent_MakeAvailable(). It is more commonly used
as part of implementing the following pattern with FetchContent_Populate(), which ensures that the
relevant variables will always be defined regardless of whether or not the population has been
performed elsewhere in the project already:

# Check if population has already been performed
FetchContent_GetProperties(depname)
if(NOT depname_POPULATED)
# Fetch the content using previously declared details
FetchContent_Populate(depname)

# Set custom variables, policies, etc.
# ...

# Bring the populated content into the build
add_subdirectory(${depname_SOURCE_DIR} ${depname_BINARY_DIR})
endif()

Variables
A number of cache variables can influence the behavior where details from a FetchContent_Declare() call
are used to populate content. The variables are all intended for the developer to customize behavior and
should not normally be set by the project.

FETCHCONTENT_BASE_DIR
In most cases, the saved details do not specify any options relating to the directories to use for
the internal sub-build, final source and build areas. It is generally best to leave these
decisions up to the FetchContent module to handle on the project's behalf. The
FETCHCONTENT_BASE_DIR cache variable controls the point under which all content population
directories are collected, but in most cases, developers would not need to change this. The
default location is ${CMAKE_BINARY_DIR}/_deps, but if developers change this value, they should
aim to keep the path short and just below the top level of the build tree to avoid running into
path length problems on Windows.

FETCHCONTENT_QUIET
The logging output during population can be quite verbose, making the configure stage quite noisy.
This cache option (ON by default) hides all population output unless an error is encountered. If
experiencing problems with hung downloads, temporarily switching this option off may help diagnose
which content population is causing the issue.

FETCHCONTENT_FULLY_DISCONNECTED
When this option is enabled, no attempt is made to download or update any content. It is assumed
that all content has already been populated in a previous run or the source directories have been
pointed at existing contents the developer has provided manually (using options described further
below). When the developer knows that no changes have been made to any content details, turning
this option ON can significantly speed up the configure stage. It is OFF by default.

FETCHCONTENT_UPDATES_DISCONNECTED
This is a less severe download/update control compared to FETCHCONTENT_FULLY_DISCONNECTED.
Instead of bypassing all download and update logic, FETCHCONTENT_UPDATES_DISCONNECTED only
disables the update stage. Therefore, if content has not been downloaded previously, it will
still be downloaded when this option is enabled. This can speed up the configure stage, but not
as much as FETCHCONTENT_FULLY_DISCONNECTED. It is OFF by default.

In addition to the above cache variables, the following cache variables are also defined for each content
name:

FETCHCONTENT_SOURCE_DIR_<uppercaseName>
If this is set, no download or update steps are performed for the specified content and the
<lowercaseName>_SOURCE_DIR variable returned to the caller is pointed at this location. This
gives developers a way to have a separate checkout of the content that they can modify freely
without interference from the build. The build simply uses that existing source, but it still
defines <lowercaseName>_BINARY_DIR to point inside its own build area. Developers are strongly
encouraged to use this mechanism rather than editing the sources populated in the default
location, as changes to sources in the default location can be lost when content population
details are changed by the project.

FETCHCONTENT_UPDATES_DISCONNECTED_<uppercaseName>
This is the per-content equivalent of FETCHCONTENT_UPDATES_DISCONNECTED. If the global option or
this option is ON, then updates will be disabled for the named content. Disabling updates for
individual content can be useful for content whose details rarely change, while still leaving
other frequently changing content with updates enabled.

Examples
This first fairly straightforward example ensures that some popular testing frameworks are available to
the main build:

include(FetchContent)
FetchContent_Declare(
googletest
GIT_REPOSITORY https://github.com/google/googletest.git
GIT_TAG 703bd9caab50b139428cea1aaff9974ebee5742e # release-1.10.0
)
FetchContent_Declare(
Catch2
GIT_REPOSITORY https://github.com/catchorg/Catch2.git
GIT_TAG de6fe184a9ac1a06895cdd1c9b437f0a0bdf14ad # v2.13.4
)

# After the following call, the CMake targets defined by googletest and
# Catch2 will be available to the rest of the build
FetchContent_MakeAvailable(googletest Catch2)

If the sub-project's CMakeLists.txt file is not at the top level of its source tree, the SOURCE_SUBDIR
option can be used to tell FetchContent where to find it. The following example shows how to use that
option and it also sets a variable which is meaningful to the subproject before pulling it into the main
build:

include(FetchContent)
FetchContent_Declare(
protobuf
GIT_REPOSITORY https://github.com/protocolbuffers/protobuf.git
GIT_TAG ae50d9b9902526efd6c7a1907d09739f959c6297 # v3.15.0
SOURCE_SUBDIR cmake
)
set(protobuf_BUILD_TESTS OFF)
FetchContent_MakeAvailable(protobuf)

In more complex project hierarchies, the dependency relationships can be more complicated. Consider a
hierarchy where projA is the top level project and it depends directly on projects projB and projC. Both
projB and projC can be built standalone and they also both depend on another project projD. projB
additionally depends on projE. This example assumes that all five projects are available on a company
git server. The CMakeLists.txt of each project might have sections like the following:

projA:

include(FetchContent)
FetchContent_Declare(
projB
GIT_REPOSITORY git@mycompany.com:git/projB.git
GIT_TAG 4a89dc7e24ff212a7b5167bef7ab079d
)
FetchContent_Declare(
projC
GIT_REPOSITORY git@mycompany.com:git/projC.git
GIT_TAG 4ad4016bd1d8d5412d135cf8ceea1bb9
)
FetchContent_Declare(
projD
GIT_REPOSITORY git@mycompany.com:git/projD.git
GIT_TAG origin/integrationBranch
)
FetchContent_Declare(
projE
GIT_REPOSITORY git@mycompany.com:git/projE.git
GIT_TAG v2.3-rc1
)

# Order is important, see notes in the discussion further below
FetchContent_MakeAvailable(projD projB projC)

projB:

include(FetchContent)
FetchContent_Declare(
projD
GIT_REPOSITORY git@mycompany.com:git/projD.git
GIT_TAG 20b415f9034bbd2a2e8216e9a5c9e632
)
FetchContent_Declare(
projE
GIT_REPOSITORY git@mycompany.com:git/projE.git
GIT_TAG 68e20f674a48be38d60e129f600faf7d
)

FetchContent_MakeAvailable(projD projE)

projC:

include(FetchContent)
FetchContent_Declare(
projD
GIT_REPOSITORY git@mycompany.com:git/projD.git
GIT_TAG 7d9a17ad2c962aa13e2fbb8043fb6b8a
)

# This particular version of projD requires workarounds
FetchContent_GetProperties(projD)
if(NOT projd_POPULATED)
FetchContent_Populate(projD)

# Copy an additional/replacement file into the populated source
file(COPY someFile.c DESTINATION ${projd_SOURCE_DIR}/src)

add_subdirectory(${projd_SOURCE_DIR} ${projd_BINARY_DIR})
endif()

A few key points should be noted in the above:

• projB and projC define different content details for projD, but projA also defines a set of content
details for projD. Because projA will define them first, the details from projB and projC will not be
used. The override details defined by projA are not required to match either of those from projB or
projC, but it is up to the higher level project to ensure that the details it does define still make
sense for the child projects.

• In the projA call to FetchContent_MakeAvailable(), projD is listed ahead of projB and projC to ensure
that projA is in control of how projD is populated.

• While projA defines content details for projE, it does not need to explicitly call
FetchContent_MakeAvailable(projE) or FetchContent_Populate(projD) itself. Instead, it leaves that to
the child projB. For higher level projects, it is often enough to just define the override content
details and leave the actual population to the child projects. This saves repeating the same thing at
each level of the project hierarchy unnecessarily.

Projects don't always need to add the populated content to the build. Sometimes the project just wants
to make the downloaded content available at a predictable location. The next example ensures that a set
of standard company toolchain files (and potentially even the toolchain binaries themselves) is available
early enough to be used for that same build.

cmake_minimum_required(VERSION 3.14)

include(FetchContent)
FetchContent_Declare(
mycom_toolchains
URL https://intranet.mycompany.com//toolchains_1.3.2.tar.gz
)
FetchContent_MakeAvailable(mycom_toolchains)

project(CrossCompileExample)

The project could be configured to use one of the downloaded toolchains like so:

cmake -DCMAKE_TOOLCHAIN_FILE=_deps/mycom_toolchains-src/toolchain_arm.cmake /path/to/src

When CMake processes the CMakeLists.txt file, it will download and unpack the tarball into
_deps/mycompany_toolchains-src relative to the build directory. The CMAKE_TOOLCHAIN_FILE variable is not
used until the project() command is reached, at which point CMake looks for the named toolchain file
relative to the build directory. Because the tarball has already been downloaded and unpacked by then,
the toolchain file will be in place, even the very first time that cmake is run in the build directory.

Lastly, the following example demonstrates how one might download and unpack a firmware tarball using
CMake's script mode. The call to FetchContent_Populate() specifies all the content details and the
unpacked firmware will be placed in a firmware directory below the current working directory.

getFirmware.cmake:

# NOTE: Intended to be run in script mode with cmake -P
include(FetchContent)
FetchContent_Populate(
firmware
URL https://mycompany.com/assets/firmware-1.23-arm.tar.gz
URL_HASH MD5=68247684da89b608d466253762b0ff11
SOURCE_DIR firmware
)

FindPackageHandleStandardArgs
This module provides functions intended to be used in Find Modules implementing
find_package(<PackageName>) calls.

find_package_handle_standard_args
This command handles the REQUIRED, QUIET and version-related arguments of find_package(). It also
sets the <PackageName>_FOUND variable. The package is considered found if all variables listed
contain valid results, e.g. valid filepaths.

There are two signatures:

find_package_handle_standard_args(<PackageName>
(DEFAULT_MSG|<custom-failure-message>)
<required-var>...
)

find_package_handle_standard_args(<PackageName>
[FOUND_VAR <result-var>]
[REQUIRED_VARS <required-var>...]
[VERSION_VAR <version-var>]
[HANDLE_VERSION_RANGE]
[HANDLE_COMPONENTS]
[CONFIG_MODE]
[NAME_MISMATCHED]
[REASON_FAILURE_MESSAGE <reason-failure-message>]
[FAIL_MESSAGE <custom-failure-message>]
)

The <PackageName>_FOUND variable will be set to TRUE if all the variables <required-var>... are
valid and any optional constraints are satisfied, and FALSE otherwise. A success or failure
message may be displayed based on the results and on whether the REQUIRED and/or QUIET option was
given to the find_package() call.

The options are:

(DEFAULT_MSG|<custom-failure-message>)
In the simple signature this specifies the failure message. Use DEFAULT_MSG to ask for a
default message to be computed (recommended). Not valid in the full signature.

FOUND_VAR <result-var>
Deprecated since version 3.3.

Specifies either <PackageName>_FOUND or <PACKAGENAME>_FOUND as the result variable. This
exists only for compatibility with older versions of CMake and is now ignored. Result
variables of both names are always set for compatibility.

REQUIRED_VARS <required-var>...
Specify the variables which are required for this package. These may be named in the
generated failure message asking the user to set the missing variable values. Therefore
these should typically be cache entries such as FOO_LIBRARY and not output variables like
FOO_LIBRARIES.

Changed in version 3.18: If HANDLE_COMPONENTS is specified, this option can be omitted.

VERSION_VAR <version-var>
Specify the name of a variable that holds the version of the package that has been found.
This version will be checked against the (potentially) specified required version given to
the find_package() call, including its EXACT option. The default messages include
information about the required version and the version which has been actually found, both
if the version is ok or not.

HANDLE_VERSION_RANGE
New in version 3.19.

Enable handling of a version range, if one is specified. Without this option, a developer
warning will be displayed if a version range is specified.

HANDLE_COMPONENTS
Enable handling of package components. In this case, the command will report which
components have been found and which are missing, and the <PackageName>_FOUND variable will
be set to FALSE if any of the required components (i.e. not the ones listed after the
OPTIONAL_COMPONENTS option of find_package()) are missing.

CONFIG_MODE
Specify that the calling find module is a wrapper around a call to
find_package(<PackageName> NO_MODULE). This implies a VERSION_VAR value of
<PackageName>_VERSION. The command will automatically check whether the package
configuration file was found.

REASON_FAILURE_MESSAGE <reason-failure-message>
New in version 3.16.

Specify a custom message of the reason for the failure which will be appended to the
default generated message.

FAIL_MESSAGE <custom-failure-message>
Specify a custom failure message instead of using the default generated message. Not
recommended.

NAME_MISMATCHED
New in version 3.17.

Indicate that the <PackageName> does not match ${CMAKE_FIND_PACKAGE_NAME}. This is usually
a mistake and raises a warning, but it may be intentional for usage of the command for
components of a larger package.

Example for the simple signature:

find_package_handle_standard_args(LibXml2 DEFAULT_MSG
LIBXML2_LIBRARY LIBXML2_INCLUDE_DIR)

The LibXml2 package is considered to be found if both LIBXML2_LIBRARY and LIBXML2_INCLUDE_DIR are valid.
Then also LibXml2_FOUND is set to TRUE. If it is not found and REQUIRED was used, it fails with a
message(FATAL_ERROR), independent whether QUIET was used or not. If it is found, success will be
reported, including the content of the first <required-var>. On repeated CMake runs, the same message
will not be printed again.

NOTE:
If <PackageName> does not match CMAKE_FIND_PACKAGE_NAME for the calling module, a warning that there
is a mismatch is given. The FPHSA_NAME_MISMATCHED variable may be set to bypass the warning if using
the old signature and the NAME_MISMATCHED argument using the new signature. To avoid forcing the
caller to require newer versions of CMake for usage, the variable's value will be used if defined when
the NAME_MISMATCHED argument is not passed for the new signature (but using both is an error)..

Example for the full signature:

find_package_handle_standard_args(LibArchive
REQUIRED_VARS LibArchive_LIBRARY LibArchive_INCLUDE_DIR
VERSION_VAR LibArchive_VERSION)

In this case, the LibArchive package is considered to be found if both LibArchive_LIBRARY and
LibArchive_INCLUDE_DIR are valid. Also the version of LibArchive will be checked by using the version
contained in LibArchive_VERSION. Since no FAIL_MESSAGE is given, the default messages will be printed.

Another example for the full signature:

find_package(Automoc4 QUIET NO_MODULE HINTS /opt/automoc4)
find_package_handle_standard_args(Automoc4 CONFIG_MODE)

In this case, a FindAutmoc4.cmake module wraps a call to find_package(Automoc4 NO_MODULE) and adds an
additional search directory for automoc4. Then the call to find_package_handle_standard_args produces a
proper success/failure message.

find_package_check_version
New in version 3.19.

Helper function which can be used to check if a <version> is valid against version-related
arguments of find_package().

find_package_check_version(<version> <result-var>
[HANDLE_VERSION_RANGE]
[RESULT_MESSAGE_VARIABLE <message-var>]
)

The <result-var> will hold a boolean value giving the result of the check.

The options are:

HANDLE_VERSION_RANGE
Enable handling of a version range, if one is specified. Without this option, a developer
warning will be displayed if a version range is specified.

RESULT_MESSAGE_VARIABLE <message-var>
Specify a variable to get back a message describing the result of the check.

Example for the usage:

find_package_check_version(1.2.3 result HANDLE_VERSION_RANGE
RESULT_MESSAGE_VARIABLE reason)
if (result)
message (STATUS "${reason}")
else()
message (FATAL_ERROR "${reason}")
endif()

FindPackageMessage
find_package_message(<name> "message for user" "find result details")

This function is intended to be used in FindXXX.cmake modules files. It will print a message once for
each unique find result. This is useful for telling the user where a package was found. The first
argument specifies the name (XXX) of the package. The second argument specifies the message to display.
The third argument lists details about the find result so that if they change the message will be
displayed again. The macro also obeys the QUIET argument to the find_package command.

Example:

if(X11_FOUND)
find_package_message(X11 "Found X11: ${X11_X11_LIB}"
"[${X11_X11_LIB}][${X11_INCLUDE_DIR}]")
else()
...
endif()

FortranCInterface
Fortran/C Interface Detection

This module automatically detects the API by which C and Fortran languages interact.

Module Variables
Variables that indicate if the mangling is found:

FortranCInterface_GLOBAL_FOUND
Global subroutines and functions.

FortranCInterface_MODULE_FOUND
Module subroutines and functions (declared by "MODULE PROCEDURE").

This module also provides the following variables to specify the detected mangling, though a typical use
case does not need to reference them and can use the Module Functions below.

FortranCInterface_GLOBAL_PREFIX
Prefix for a global symbol without an underscore.

FortranCInterface_GLOBAL_SUFFIX
Suffix for a global symbol without an underscore.

FortranCInterface_GLOBAL_CASE
The case for a global symbol without an underscore, either UPPER or LOWER.

FortranCInterface_GLOBAL__PREFIX
Prefix for a global symbol with an underscore.

FortranCInterface_GLOBAL__SUFFIX
Suffix for a global symbol with an underscore.

FortranCInterface_GLOBAL__CASE
The case for a global symbol with an underscore, either UPPER or LOWER.

FortranCInterface_MODULE_PREFIX
Prefix for a module symbol without an underscore.

FortranCInterface_MODULE_MIDDLE
Middle of a module symbol without an underscore that appears between the name of the module and
the name of the symbol.

FortranCInterface_MODULE_SUFFIX
Suffix for a module symbol without an underscore.

FortranCInterface_MODULE_CASE
The case for a module symbol without an underscore, either UPPER or LOWER.

FortranCInterface_MODULE__PREFIX
Prefix for a module symbol with an underscore.

FortranCInterface_MODULE__MIDDLE
Middle of a module symbol with an underscore that appears between the name of the module and the
name of the symbol.

FortranCInterface_MODULE__SUFFIX
Suffix for a module symbol with an underscore.

FortranCInterface_MODULE__CASE
The case for a module symbol with an underscore, either UPPER or LOWER.

Module Functions
FortranCInterface_HEADER
The FortranCInterface_HEADER function is provided to generate a C header file containing macros to
mangle symbol names:

FortranCInterface_HEADER(<file>
[MACRO_NAMESPACE <macro-ns>]
[SYMBOL_NAMESPACE <ns>]
[SYMBOLS [<module>:]<function> ...])

It generates in <file> definitions of the following macros:

#define FortranCInterface_GLOBAL (name,NAME) ...
#define FortranCInterface_GLOBAL_(name,NAME) ...
#define FortranCInterface_MODULE (mod,name, MOD,NAME) ...
#define FortranCInterface_MODULE_(mod,name, MOD,NAME) ...

These macros mangle four categories of Fortran symbols, respectively:

• Global symbols without '_': call mysub()

• Global symbols with '_' : call my_sub()

• Module symbols without '_': use mymod; call mysub()

• Module symbols with '_' : use mymod; call my_sub()

If mangling for a category is not known, its macro is left undefined. All macros require raw
names in both lower case and upper case.

The options are:

MACRO_NAMESPACE
Replace the default FortranCInterface_ prefix with a given namespace <macro-ns>.

SYMBOLS
List symbols to mangle automatically with C preprocessor definitions:

<function> ==> #define <ns><function> ...
<module>:<function> ==> #define <ns><module>_<function> ...

If the mangling for some symbol is not known then no preprocessor definition is created,
and a warning is displayed.

SYMBOL_NAMESPACE
Prefix all preprocessor definitions generated by the SYMBOLS option with a given namespace
<ns>.

FortranCInterface_VERIFY
The FortranCInterface_VERIFY function is provided to verify that the Fortran and C/C++ compilers
work together:

FortranCInterface_VERIFY([CXX] [QUIET])

It tests whether a simple test executable using Fortran and C (and C++ when the CXX option is
given) compiles and links successfully. The result is stored in the cache entry
FortranCInterface_VERIFIED_C (or FortranCInterface_VERIFIED_CXX if CXX is given) as a boolean. If
the check fails and QUIET is not given the function terminates with a fatal error message
describing the problem. The purpose of this check is to stop a build early for incompatible
compiler combinations. The test is built in the Release configuration.

Example Usage
include(FortranCInterface)
FortranCInterface_HEADER(FC.h MACRO_NAMESPACE "FC_")

This creates a "FC.h" header that defines mangling macros FC_GLOBAL(), FC_GLOBAL_(), FC_MODULE(), and
FC_MODULE_().

include(FortranCInterface)
FortranCInterface_HEADER(FCMangle.h
MACRO_NAMESPACE "FC_"
SYMBOL_NAMESPACE "FC_"
SYMBOLS mysub mymod:my_sub)

This creates a "FCMangle.h" header that defines the same FC_*() mangling macros as the previous example
plus preprocessor symbols FC_mysub and FC_mymod_my_sub.

Additional Manglings
FortranCInterface is aware of possible GLOBAL and MODULE manglings for many Fortran compilers, but it
also provides an interface to specify new possible manglings. Set the variables:

FortranCInterface_GLOBAL_SYMBOLS
FortranCInterface_MODULE_SYMBOLS

before including FortranCInterface to specify manglings of the symbols MySub, My_Sub, MyModule:MySub, and
My_Module:My_Sub. For example, the code:

set(FortranCInterface_GLOBAL_SYMBOLS mysub_ my_sub__ MYSUB_)
# ^^^^^ ^^^^^^ ^^^^^
set(FortranCInterface_MODULE_SYMBOLS
__mymodule_MOD_mysub __my_module_MOD_my_sub)
# ^^^^^^^^ ^^^^^ ^^^^^^^^^ ^^^^^^
include(FortranCInterface)

tells FortranCInterface to try given GLOBAL and MODULE manglings. (The carets point at raw symbol names
for clarity in this example but are not needed.)

GenerateExportHeader
Function for generation of export macros for libraries

This module provides the function GENERATE_EXPORT_HEADER().

New in version 3.12: Added support for C projects. Previous versions supported C++ project only.

The GENERATE_EXPORT_HEADER function can be used to generate a file suitable for preprocessor inclusion
which contains EXPORT macros to be used in library classes:

GENERATE_EXPORT_HEADER( LIBRARY_TARGET
[BASE_NAME <base_name>]
[EXPORT_MACRO_NAME <export_macro_name>]
[EXPORT_FILE_NAME <export_file_name>]
[DEPRECATED_MACRO_NAME <deprecated_macro_name>]
[NO_EXPORT_MACRO_NAME <no_export_macro_name>]
[INCLUDE_GUARD_NAME <include_guard_name>]
[STATIC_DEFINE <static_define>]
[NO_DEPRECATED_MACRO_NAME <no_deprecated_macro_name>]
[DEFINE_NO_DEPRECATED]
[PREFIX_NAME <prefix_name>]
[CUSTOM_CONTENT_FROM_VARIABLE <variable>]
)

The target properties CXX_VISIBILITY_PRESET and VISIBILITY_INLINES_HIDDEN can be used to add the
appropriate compile flags for targets. See the documentation of those target properties, and the
convenience variables CMAKE_CXX_VISIBILITY_PRESET and CMAKE_VISIBILITY_INLINES_HIDDEN.

By default GENERATE_EXPORT_HEADER() generates macro names in a file name determined by the name of the
library. This means that in the simplest case, users of GenerateExportHeader will be equivalent to:

set(CMAKE_CXX_VISIBILITY_PRESET hidden)
set(CMAKE_VISIBILITY_INLINES_HIDDEN 1)
add_library(somelib someclass.cpp)
generate_export_header(somelib)
install(TARGETS somelib DESTINATION ${LIBRARY_INSTALL_DIR})
install(FILES
someclass.h
${PROJECT_BINARY_DIR}/somelib_export.h DESTINATION ${INCLUDE_INSTALL_DIR}
)

And in the ABI header files:

#include "somelib_export.h"
class SOMELIB_EXPORT SomeClass {
...
};

The CMake fragment will generate a file in the ${CMAKE_CURRENT_BINARY_DIR} called somelib_export.h
containing the macros SOMELIB_EXPORT, SOMELIB_NO_EXPORT, SOMELIB_DEPRECATED, SOMELIB_DEPRECATED_EXPORT
and SOMELIB_DEPRECATED_NO_EXPORT. They will be followed by content taken from the variable specified by
the CUSTOM_CONTENT_FROM_VARIABLE option, if any. The resulting file should be installed with other
headers in the library.

The BASE_NAME argument can be used to override the file name and the names used for the macros:

add_library(somelib someclass.cpp)
generate_export_header(somelib
BASE_NAME other_name
)

Generates a file called other_name_export.h containing the macros OTHER_NAME_EXPORT, OTHER_NAME_NO_EXPORT
and OTHER_NAME_DEPRECATED etc.

The BASE_NAME may be overridden by specifying other options in the function. For example:

add_library(somelib someclass.cpp)
generate_export_header(somelib
EXPORT_MACRO_NAME OTHER_NAME_EXPORT
)

creates the macro OTHER_NAME_EXPORT instead of SOMELIB_EXPORT, but other macros and the generated file
name is as default:

add_library(somelib someclass.cpp)
generate_export_header(somelib
DEPRECATED_MACRO_NAME KDE_DEPRECATED
)

creates the macro KDE_DEPRECATED instead of SOMELIB_DEPRECATED.

If LIBRARY_TARGET is a static library, macros are defined without values.

If the same sources are used to create both a shared and a static library, the uppercased symbol
${BASE_NAME}_STATIC_DEFINE should be used when building the static library:

add_library(shared_variant SHARED ${lib_SRCS})
add_library(static_variant ${lib_SRCS})
generate_export_header(shared_variant BASE_NAME libshared_and_static)
set_target_properties(static_variant PROPERTIES
COMPILE_FLAGS -DLIBSHARED_AND_STATIC_STATIC_DEFINE)

This will cause the export macros to expand to nothing when building the static library.

If DEFINE_NO_DEPRECATED is specified, then a macro ${BASE_NAME}_NO_DEPRECATED will be defined This macro
can be used to remove deprecated code from preprocessor output:

option(EXCLUDE_DEPRECATED "Exclude deprecated parts of the library" FALSE)
if (EXCLUDE_DEPRECATED)
set(NO_BUILD_DEPRECATED DEFINE_NO_DEPRECATED)
endif()
generate_export_header(somelib ${NO_BUILD_DEPRECATED})

And then in somelib:

class SOMELIB_EXPORT SomeClass
{
public:
#ifndef SOMELIB_NO_DEPRECATED
SOMELIB_DEPRECATED void oldMethod();
#endif
};

#ifndef SOMELIB_NO_DEPRECATED
void SomeClass::oldMethod() { }
#endif

If PREFIX_NAME is specified, the argument will be used as a prefix to all generated macros.

For example:

generate_export_header(somelib PREFIX_NAME VTK_)

Generates the macros VTK_SOMELIB_EXPORT etc.

New in version 3.1: Library target can be an OBJECT library.

New in version 3.7: Added the CUSTOM_CONTENT_FROM_VARIABLE option.

New in version 3.11: Added the INCLUDE_GUARD_NAME option.

ADD_COMPILER_EXPORT_FLAGS( [<output_variable>] )

Deprecated since version 3.0: Set the target properties CXX_VISIBILITY_PRESET and
VISIBILITY_INLINES_HIDDEN instead.

The ADD_COMPILER_EXPORT_FLAGS function adds -fvisibility=hidden to CMAKE_CXX_FLAGS if supported, and is a
no-op on Windows which does not need extra compiler flags for exporting support. You may optionally pass
a single argument to ADD_COMPILER_EXPORT_FLAGS that will be populated with the CXX_FLAGS required to
enable visibility support for the compiler/architecture in use.

GetPrerequisites
Deprecated since version 3.16: Use file(GET_RUNTIME_DEPENDENCIES) instead.

Functions to analyze and list executable file prerequisites.

This module provides functions to list the .dll, .dylib or .so files that an executable or shared library
file depends on. (Its prerequisites.)

It uses various tools to obtain the list of required shared library files:

dumpbin (Windows)
objdump (MinGW on Windows)
ldd (Linux/Unix)
otool (Mac OSX)

Changed in version 3.16: The tool specified by CMAKE_OBJDUMP will be used, if set.

The following functions are provided by this module:

get_prerequisites
list_prerequisites
list_prerequisites_by_glob
gp_append_unique
is_file_executable
gp_item_default_embedded_path
(projects can override with gp_item_default_embedded_path_override)
gp_resolve_item
(projects can override with gp_resolve_item_override)
gp_resolved_file_type
(projects can override with gp_resolved_file_type_override)
gp_file_type

GET_PREREQUISITES(<target> <prerequisites_var> <exclude_system> <recurse>
<exepath> <dirs> [<rpaths>])

Get the list of shared library files required by <target>. The list in the variable named
<prerequisites_var> should be empty on first entry to this function. On exit, <prerequisites_var> will
contain the list of required shared library files.

<target> is the full path to an executable file. <prerequisites_var> is the name of a CMake variable to
contain the results. <exclude_system> must be 0 or 1 indicating whether to include or exclude "system"
prerequisites. If <recurse> is set to 1 all prerequisites will be found recursively, if set to 0 only
direct prerequisites are listed. <exepath> is the path to the top level executable used for
@executable_path replacement on the Mac. <dirs> is a list of paths where libraries might be found: these
paths are searched first when a target without any path info is given. Then standard system locations
are also searched: PATH, Framework locations, /usr/lib...

New in version 3.14: The variable GET_PREREQUISITES_VERBOSE can be set to true to enable verbose output.

LIST_PREREQUISITES(<target> [<recurse> [<exclude_system> [<verbose>]]])

Print a message listing the prerequisites of <target>.

<target> is the name of a shared library or executable target or the full path to a shared library or
executable file. If <recurse> is set to 1 all prerequisites will be found recursively, if set to 0 only
direct prerequisites are listed. <exclude_system> must be 0 or 1 indicating whether to include or
exclude "system" prerequisites. With <verbose> set to 0 only the full path names of the prerequisites
are printed, set to 1 extra information will be displayed.

LIST_PREREQUISITES_BY_GLOB(<glob_arg> <glob_exp>)

Print the prerequisites of shared library and executable files matching a globbing pattern. <glob_arg>
is GLOB or GLOB_RECURSE and <glob_exp> is a globbing expression used with "file(GLOB" or
"file(GLOB_RECURSE" to retrieve a list of matching files. If a matching file is executable, its
prerequisites are listed.

Any additional (optional) arguments provided are passed along as the optional arguments to the
list_prerequisites calls.

GP_APPEND_UNIQUE(<list_var> <value>)

Append <value> to the list variable <list_var> only if the value is not already in the list.

IS_FILE_EXECUTABLE(<file> <result_var>)

Return 1 in <result_var> if <file> is a binary executable, 0 otherwise.

GP_ITEM_DEFAULT_EMBEDDED_PATH(<item> <default_embedded_path_var>)

Return the path that others should refer to the item by when the item is embedded inside a bundle.

Override on a per-project basis by providing a project-specific gp_item_default_embedded_path_override
function.

GP_RESOLVE_ITEM(<context> <item> <exepath> <dirs> <resolved_item_var>
[<rpaths>])

Resolve an item into an existing full path file.

Override on a per-project basis by providing a project-specific gp_resolve_item_override function.

GP_RESOLVED_FILE_TYPE(<original_file> <file> <exepath> <dirs> <type_var>
[<rpaths>])

Return the type of <file> with respect to <original_file>. String describing type of prerequisite is
returned in variable named <type_var>.

Use <exepath> and <dirs> if necessary to resolve non-absolute <file> values -- but only for non-embedded
items.

Possible types are:

system
local
embedded
other

Override on a per-project basis by providing a project-specific gp_resolved_file_type_override function.

GP_FILE_TYPE(<original_file> <file> <type_var>)

Return the type of <file> with respect to <original_file>. String describing type of prerequisite is
returned in variable named <type_var>.

Possible types are:

system
local
embedded
other

GNUInstallDirs
Define GNU standard installation directories

Provides install directory variables as defined by the GNU Coding Standards.

Result Variables
Inclusion of this module defines the following variables:

CMAKE_INSTALL_<dir>
Destination for files of a given type. This value may be passed to the DESTINATION options of
install() commands for the corresponding file type. It should typically be a path relative to the
installation prefix so that it can be converted to an absolute path in a relocatable way (see
CMAKE_INSTALL_FULL_<dir>). However, an absolute path is also allowed.

CMAKE_INSTALL_FULL_<dir>
The absolute path generated from the corresponding CMAKE_INSTALL_<dir> value. If the value is not
already an absolute path, an absolute path is constructed typically by prepending the value of the
CMAKE_INSTALL_PREFIX variable. However, there are some special cases as documented below.

where <dir> is one of:

BINDIR user executables (bin)

SBINDIR
system admin executables (sbin)

LIBEXECDIR
program executables (libexec)

SYSCONFDIR
read-only single-machine data (etc)

SHAREDSTATEDIR
modifiable architecture-independent data (com)

LOCALSTATEDIR
modifiable single-machine data (var)

RUNSTATEDIR
New in version 3.9: run-time variable data (LOCALSTATEDIR/run)

LIBDIR object code libraries (lib or lib64 or lib/<multiarch-tuple> on Debian)

INCLUDEDIR
C header files (include)

OLDINCLUDEDIR
C header files for non-gcc (/usr/include)

DATAROOTDIR
read-only architecture-independent data root (share)

DATADIR
read-only architecture-independent data (DATAROOTDIR)

INFODIR
info documentation (DATAROOTDIR/info)

LOCALEDIR
locale-dependent data (DATAROOTDIR/locale)

MANDIR man documentation (DATAROOTDIR/man)

DOCDIR documentation root (DATAROOTDIR/doc/PROJECT_NAME)

If the includer does not define a value the above-shown default will be used and the value will appear in
the cache for editing by the user.

Special Cases
New in version 3.4.

The following values of CMAKE_INSTALL_PREFIX are special:

/
For <dir> other than the SYSCONFDIR, LOCALSTATEDIR and RUNSTATEDIR, the value of CMAKE_INSTALL_<dir>
is prefixed with usr/ if it is not user-specified as an absolute path. For example, the INCLUDEDIR
value include becomes usr/include. This is required by the GNU Coding Standards, which state:
When building the complete GNU system, the prefix will be empty and /usr will be a symbolic link
to /.

/usr
For <dir> equal to SYSCONFDIR, LOCALSTATEDIR or RUNSTATEDIR, the CMAKE_INSTALL_FULL_<dir> is computed
by prepending just / to the value of CMAKE_INSTALL_<dir> if it is not user-specified as an absolute
path. For example, the SYSCONFDIR value etc becomes /etc. This is required by the GNU Coding
Standards.

/opt/...
For <dir> equal to SYSCONFDIR, LOCALSTATEDIR or RUNSTATEDIR, the CMAKE_INSTALL_FULL_<dir> is computed
by appending the prefix to the value of CMAKE_INSTALL_<dir> if it is not user-specified as an absolute
path. For example, the SYSCONFDIR value etc becomes /etc/opt/.... This is defined by the Filesystem
Hierarchy Standard.

Macros
GNUInstallDirs_get_absolute_install_dir

GNUInstallDirs_get_absolute_install_dir(absvar var dirname)

New in version 3.7.

Set the given variable absvar to the absolute path contained within the variable var. This is to
allow the computation of an absolute path, accounting for all the special cases documented above.
While this macro is used to compute the various CMAKE_INSTALL_FULL_<dir> variables, it is exposed
publicly to allow users who create additional path variables to also compute absolute paths where
necessary, using the same logic. dirname is the directory name to get, e.g. BINDIR.

Changed in version 3.20: Added the <dirname> parameter. Previous versions of CMake passed this
value through the variable ${dir}.

GoogleTest
New in version 3.9.

This module defines functions to help use the Google Test infrastructure. Two mechanisms for adding
tests are provided. gtest_add_tests() has been around for some time, originally via find_package(GTest).
gtest_discover_tests() was introduced in CMake 3.10.

The (older) gtest_add_tests() scans source files to identify tests. This is usually effective, with some
caveats, including in cross-compiling environments, and makes setting additional properties on tests more
convenient. However, its handling of parameterized tests is less comprehensive, and it requires
re-running CMake to detect changes to the list of tests.

The (newer) gtest_discover_tests() discovers tests by asking the compiled test executable to enumerate
its tests. This is more robust and provides better handling of parameterized tests, and does not require
CMake to be re-run when tests change. However, it may not work in a cross-compiling environment, and
setting test properties is less convenient.

More details can be found in the documentation of the respective functions.

Both commands are intended to replace use of add_test() to register tests, and will create a separate
CTest test for each Google Test test case. Note that this is in some cases less efficient, as common
set-up and tear-down logic cannot be shared by multiple test cases executing in the same instance.
However, it provides more fine-grained pass/fail information to CTest, which is usually considered as
more beneficial. By default, the CTest test name is the same as the Google Test name (i.e.
suite.testcase); see also TEST_PREFIX and TEST_SUFFIX.

gtest_add_tests
Automatically add tests with CTest by scanning source code for Google Test macros:

gtest_add_tests(TARGET target
[SOURCES src1...]
[EXTRA_ARGS arg1...]
[WORKING_DIRECTORY dir]
[TEST_PREFIX prefix]
[TEST_SUFFIX suffix]
[SKIP_DEPENDENCY]
[TEST_LIST outVar]
)

gtest_add_tests attempts to identify tests by scanning source files. Although this is generally
effective, it uses only a basic regular expression match, which can be defeated by atypical test
declarations, and is unable to fully "split" parameterized tests. Additionally, it requires that
CMake be re-run to discover any newly added, removed or renamed tests (by default, this means that
CMake is re-run when any test source file is changed, but see SKIP_DEPENDENCY). However, it has
the advantage of declaring tests at CMake time, which somewhat simplifies setting additional
properties on tests, and always works in a cross-compiling environment.

The options are:

TARGET target
Specifies the Google Test executable, which must be a known CMake executable target. CMake
will substitute the location of the built executable when running the test.

SOURCES src1...
When provided, only the listed files will be scanned for test cases. If this option is not
given, the SOURCES property of the specified target will be used to obtain the list of
sources.

EXTRA_ARGS arg1...
Any extra arguments to pass on the command line to each test case.

WORKING_DIRECTORY dir
Specifies the directory in which to run the discovered test cases. If this option is not
provided, the current binary directory is used.

TEST_PREFIX prefix
Specifies a prefix to be prepended to the name of each discovered test case. This can be
useful when the same source files are being used in multiple calls to gtest_add_test() but
with different EXTRA_ARGS.

TEST_SUFFIX suffix
Similar to TEST_PREFIX except the suffix is appended to the name of every discovered test
case. Both TEST_PREFIX and TEST_SUFFIX may be specified.

SKIP_DEPENDENCY
Normally, the function creates a dependency which will cause CMake to be re-run if any of
the sources being scanned are changed. This is to ensure that the list of discovered tests
is updated. If this behavior is not desired (as may be the case while actually writing the
test cases), this option can be used to prevent the dependency from being added.

TEST_LIST outVar
The variable named by outVar will be populated in the calling scope with the list of
discovered test cases. This allows the caller to do things like manipulate test properties
of the discovered tests.

Usage example:

include(GoogleTest)
add_executable(FooTest FooUnitTest.cxx)
gtest_add_tests(TARGET FooTest
TEST_SUFFIX .noArgs
TEST_LIST noArgsTests
)
gtest_add_tests(TARGET FooTest
EXTRA_ARGS --someArg someValue
TEST_SUFFIX .withArgs
TEST_LIST withArgsTests
)
set_tests_properties(${noArgsTests} PROPERTIES TIMEOUT 10)
set_tests_properties(${withArgsTests} PROPERTIES TIMEOUT 20)

For backward compatibility, the following form is also supported:

gtest_add_tests(exe args files...)

exe The path to the test executable or the name of a CMake target.

args A ;-list of extra arguments to be passed to executable. The entire list must be passed as
a single argument. Enclose it in quotes, or pass "" for no arguments.

files...
A list of source files to search for tests and test fixtures. Alternatively, use AUTO to
specify that exe is the name of a CMake executable target whose sources should be scanned.

include(GoogleTest)
set(FooTestArgs --foo 1 --bar 2)
add_executable(FooTest FooUnitTest.cxx)
gtest_add_tests(FooTest "${FooTestArgs}" AUTO)

gtest_discover_tests
Automatically add tests with CTest by querying the compiled test executable for available tests:

gtest_discover_tests(target
[EXTRA_ARGS arg1...]
[WORKING_DIRECTORY dir]
[TEST_PREFIX prefix]
[TEST_SUFFIX suffix]
[TEST_FILTER expr]
[NO_PRETTY_TYPES] [NO_PRETTY_VALUES]
[PROPERTIES name1 value1...]
[TEST_LIST var]
[DISCOVERY_TIMEOUT seconds]
[XML_OUTPUT_DIR dir]
[DISCOVERY_MODE <POST_BUILD|PRE_TEST>]
)

New in version 3.10.

gtest_discover_tests() sets up a post-build command on the test executable that generates the list
of tests by parsing the output from running the test with the --gtest_list_tests argument.
Compared to the source parsing approach of gtest_add_tests(), this ensures that the full list of
tests, including instantiations of parameterized tests, is obtained. Since test discovery occurs
at build time, it is not necessary to re-run CMake when the list of tests changes. However, it
requires that CROSSCOMPILING_EMULATOR is properly set in order to function in a cross-compiling
environment.

Additionally, setting properties on tests is somewhat less convenient, since the tests are not
available at CMake time. Additional test properties may be assigned to the set of tests as a
whole using the PROPERTIES option. If more fine-grained test control is needed, custom content
may be provided through an external CTest script using the TEST_INCLUDE_FILES directory property.
The set of discovered tests is made accessible to such a script via the <target>_TESTS variable.

The options are:

target Specifies the Google Test executable, which must be a known CMake executable target. CMake
will substitute the location of the built executable when running the test.

EXTRA_ARGS arg1...
Any extra arguments to pass on the command line to each test case.

WORKING_DIRECTORY dir
Specifies the directory in which to run the discovered test cases. If this option is not
provided, the current binary directory is used.

TEST_PREFIX prefix
Specifies a prefix to be prepended to the name of each discovered test case. This can be
useful when the same test executable is being used in multiple calls to
gtest_discover_tests() but with different EXTRA_ARGS.

TEST_SUFFIX suffix
Similar to TEST_PREFIX except the suffix is appended to the name of every discovered test
case. Both TEST_PREFIX and TEST_SUFFIX may be specified.

TEST_FILTER expr
New in version 3.22.

Filter expression to pass as a --gtest_filter argument during test discovery. Note that
the expression is a wildcard-based format that matches against the original test names as
used by gtest. For type or value-parameterized tests, these names may be different to the
potentially pretty-printed test names that ctest uses.

NO_PRETTY_TYPES
By default, the type index of type-parameterized tests is replaced by the actual type name
in the CTest test name. If this behavior is undesirable (e.g. because the type names are
unwieldy), this option will suppress this behavior.

NO_PRETTY_VALUES
By default, the value index of value-parameterized tests is replaced by the actual value in
the CTest test name. If this behavior is undesirable (e.g. because the value strings are
unwieldy), this option will suppress this behavior.

PROPERTIES name1 value1...
Specifies additional properties to be set on all tests discovered by this invocation of
gtest_discover_tests().

TEST_LIST var
Make the list of tests available in the variable var, rather than the default
<target>_TESTS. This can be useful when the same test executable is being used in multiple
calls to gtest_discover_tests(). Note that this variable is only available in CTest.

DISCOVERY_TIMEOUT num
New in version 3.10.3.

Specifies how long (in seconds) CMake will wait for the test to enumerate available tests.
If the test takes longer than this, discovery (and your build) will fail. Most test
executables will enumerate their tests very quickly, but under some exceptional
circumstances, a test may require a longer timeout. The default is 5. See also the
TIMEOUT option of execute_process().

NOTE:
In CMake versions 3.10.1 and 3.10.2, this option was called TIMEOUT. This clashed with
the TIMEOUT test property, which is one of the common properties that would be set with
the PROPERTIES keyword, usually leading to legal but unintended behavior. The keyword
was changed to DISCOVERY_TIMEOUT in CMake 3.10.3 to address this problem. The ambiguous
behavior of the TIMEOUT keyword in 3.10.1 and 3.10.2 has not been preserved.

XML_OUTPUT_DIR dir
New in version 3.18.

If specified, the parameter is passed along with --gtest_output=xml: to test executable.
The actual file name is the same as the test target, including prefix and suffix. This
should be used instead of EXTRA_ARGS --gtest_output=xml to avoid race conditions writing
the XML result output when using parallel test execution.

DISCOVERY_MODE
New in version 3.18.

Provides greater control over when gtest_discover_tests() performs test discovery. By
default, POST_BUILD sets up a post-build command to perform test discovery at build time.
In certain scenarios, like cross-compiling, this POST_BUILD behavior is not desirable. By
contrast, PRE_TEST delays test discovery until just prior to test execution. This way test
discovery occurs in the target environment where the test has a better chance at finding
appropriate runtime dependencies.

DISCOVERY_MODE defaults to the value of the CMAKE_GTEST_DISCOVER_TESTS_DISCOVERY_MODE
variable if it is not passed when calling gtest_discover_tests(). This provides a mechanism
for globally selecting a preferred test discovery behavior without having to modify each
call site.

InstallRequiredSystemLibraries
Include this module to search for compiler-provided system runtime libraries and add install rules for
them. Some optional variables may be set prior to including the module to adjust behavior:

CMAKE_INSTALL_SYSTEM_RUNTIME_LIBS
Specify additional runtime libraries that may not be detected. After inclusion any detected
libraries will be appended to this.

CMAKE_INSTALL_SYSTEM_RUNTIME_LIBS_SKIP
Set to TRUE to skip calling the install(PROGRAMS) command to allow the includer to specify its own
install rule, using the value of CMAKE_INSTALL_SYSTEM_RUNTIME_LIBS to get the list of libraries.

CMAKE_INSTALL_DEBUG_LIBRARIES
Set to TRUE to install the debug runtime libraries when available with MSVC tools.

CMAKE_INSTALL_DEBUG_LIBRARIES_ONLY
Set to TRUE to install only the debug runtime libraries with MSVC tools even if the release
runtime libraries are also available.

CMAKE_INSTALL_UCRT_LIBRARIES
New in version 3.6.

Set to TRUE to install the Windows Universal CRT libraries for app-local deployment (e.g. to
Windows XP). This is meaningful only with MSVC from Visual Studio 2015 or higher.

New in version 3.9: One may set a CMAKE_WINDOWS_KITS_10_DIR environment variable to an absolute
path to tell CMake to look for Windows 10 SDKs in a custom location. The specified directory is
expected to contain Redist/ucrt/DLLs/* directories.

CMAKE_INSTALL_MFC_LIBRARIES
Set to TRUE to install the MSVC MFC runtime libraries.

CMAKE_INSTALL_OPENMP_LIBRARIES
Set to TRUE to install the MSVC OpenMP runtime libraries

CMAKE_INSTALL_SYSTEM_RUNTIME_DESTINATION
Specify the install(PROGRAMS) command DESTINATION option. If not specified, the default is bin on
Windows and lib elsewhere.

CMAKE_INSTALL_SYSTEM_RUNTIME_LIBS_NO_WARNINGS
Set to TRUE to disable warnings about required library files that do not exist. (For example,
Visual Studio Express editions may not provide the redistributable files.)

CMAKE_INSTALL_SYSTEM_RUNTIME_COMPONENT
New in version 3.3.

Specify the install(PROGRAMS) command COMPONENT option. If not specified, no such option will be
used.

New in version 3.10: Support for installing Intel compiler runtimes.

ProcessorCount
ProcessorCount(var)

Determine the number of processors/cores and save value in ${var}

Sets the variable named ${var} to the number of physical cores available on the machine if the
information can be determined. Otherwise it is set to 0. Currently this functionality is implemented
for AIX, cygwin, FreeBSD, HPUX, Linux, macOS, QNX, Sun and Windows.

Changed in version 3.15: On Linux, returns the container CPU count instead of the host CPU count.

This function is guaranteed to return a positive integer (>=1) if it succeeds. It returns 0 if there's a
problem determining the processor count.

Example use, in a ctest -S dashboard script:

include(ProcessorCount)
ProcessorCount(N)
if(NOT N EQUAL 0)
set(CTEST_BUILD_FLAGS -j${N})
set(ctest_test_args ${ctest_test_args} PARALLEL_LEVEL ${N})
endif()

This function is intended to offer an approximation of the value of the number of compute cores available
on the current machine, such that you may use that value for parallel building and parallel testing. It
is meant to help utilize as much of the machine as seems reasonable. Of course, knowledge of what else
might be running on the machine simultaneously should be used when deciding whether to request a
machine's full capacity all for yourself.

SelectLibraryConfigurations
select_library_configurations(basename)

This macro takes a library base name as an argument, and will choose good values for the variables

basename_LIBRARY
basename_LIBRARIES
basename_LIBRARY_DEBUG
basename_LIBRARY_RELEASE

depending on what has been found and set.

If only basename_LIBRARY_RELEASE is defined, basename_LIBRARY will be set to the release value, and
basename_LIBRARY_DEBUG will be set to basename_LIBRARY_DEBUG-NOTFOUND. If only basename_LIBRARY_DEBUG is
defined, then basename_LIBRARY will take the debug value, and basename_LIBRARY_RELEASE will be set to
basename_LIBRARY_RELEASE-NOTFOUND.

If the generator supports configuration types, then basename_LIBRARY and basename_LIBRARIES will be set
with debug and optimized flags specifying the library to be used for the given configuration. If no
build type has been set or the generator in use does not support configuration types, then
basename_LIBRARY and basename_LIBRARIES will take only the release value, or the debug value if the
release one is not set.

SquishTestScript
This script launches a GUI test using Squish. You should not call the script directly; instead, you
should access it via the SQUISH_ADD_TEST macro that is defined in FindSquish.cmake.

This script starts the Squish server, launches the test on the client, and finally stops the squish
server. If any of these steps fail (including if the tests do not pass) then a fatal error is raised.

TestBigEndian
Deprecated since version 3.20: Supserseded by the CMAKE_<LANG>_BYTE_ORDER variable.

Check if the target architecture is big endian or little endian.

test_big_endian

test_big_endian(<var>)

Stores in variable <var> either 1 or 0 indicating whether the target architecture is big or little
endian.

TestForANSIForScope
Check for ANSI for scope support

Check if the compiler restricts the scope of variables declared in a for-init-statement to the loop body.

CMAKE_NO_ANSI_FOR_SCOPE - holds result

TestForANSIStreamHeaders
Test for compiler support of ANSI stream headers iostream, etc.

check if the compiler supports the standard ANSI iostream header (without the .h)

CMAKE_NO_ANSI_STREAM_HEADERS - defined by the results

TestForSSTREAM
Test for compiler support of ANSI sstream header

check if the compiler supports the standard ANSI sstream header

CMAKE_NO_ANSI_STRING_STREAM - defined by the results

TestForSTDNamespace
Test for std:: namespace support

check if the compiler supports std:: on stl classes

CMAKE_NO_STD_NAMESPACE - defined by the results

UseEcos
This module defines variables and macros required to build eCos application.

This file contains the following macros: ECOS_ADD_INCLUDE_DIRECTORIES() - add the eCos include dirs
ECOS_ADD_EXECUTABLE(name source1 ... sourceN ) - create an eCos executable ECOS_ADJUST_DIRECTORY(VAR
source1 ... sourceN ) - adjusts the path of the source files and puts the result into VAR

Macros for selecting the toolchain: ECOS_USE_ARM_ELF_TOOLS() - enable the ARM ELF toolchain for the
directory where it is called ECOS_USE_I386_ELF_TOOLS() - enable the i386 ELF toolchain for the directory
where it is called ECOS_USE_PPC_EABI_TOOLS() - enable the PowerPC toolchain for the directory where it is
called

It contains the following variables: ECOS_DEFINITIONS ECOSCONFIG_EXECUTABLE ECOS_CONFIG_FILE - defaults
to ecos.ecc, if your eCos configuration file has a different name, adjust this variable for internal use
only:

ECOS_ADD_TARGET_LIB

UseJava
This file provides support for Java. It is assumed that FindJava has already been loaded. See FindJava
for information on how to load Java into your CMake project.

Synopsis
Creating and Installing JARS
add_jar (<target_name> [SOURCES] <source1> [<source2>...] ...)
install_jar (<target_name> DESTINATION <destination> [COMPONENT <component>])
install_jni_symlink (<target_name> DESTINATION <destination> [COMPONENT <component>])

Header Generation
create_javah ((TARGET <target> | GENERATED_FILES <VAR>) CLASSES <class>... ...)

Exporting JAR Targets
install_jar_exports (TARGETS <jars>... FILE <filename> DESTINATION <destination> ...)
export_jars (TARGETS <jars>... [NAMESPACE <namespace>] FILE <filename>)

Finding JARs
find_jar (<VAR> NAMES <name1> [<name2>...] [PATHS <path1> [<path2>... ENV <var>]] ...)

Creating Java Documentation
create_javadoc (<VAR> (PACKAGES <pkg1> [<pkg2>...] | FILES <file1> [<file2>...]) ...)

Creating And Installing JARs
add_jar
Creates a jar file containing java objects and, optionally, resources:

add_jar(<target_name>
[SOURCES] <source1> [<source2>...] [<resource1>...]
[RESOURCES NAMESPACE <ns1> <resource1>... [NAMESPACE <nsX> <resourceX>...]... ]
[INCLUDE_JARS <jar1> [<jar2>...]]
[ENTRY_POINT <entry>]
[VERSION <version>]
[MANIFEST <manifest>]
[OUTPUT_NAME <name>]
[OUTPUT_DIR <dir>]
[GENERATE_NATIVE_HEADERS <target>
[DESTINATION (<dir>|INSTALL <dir> [BUILD <dir>])]]
)

This command creates a <target_name>.jar. It compiles the given <source> files and adds the given
<resource> files to the jar file. Source files can be java files or listing files (prefixed by
@). If only resource files are given then just a jar file is created.

SOURCES
Compiles the specified source files and adds the result in the jar file.

New in version 3.4: Support for response files, prefixed by @.

RESOURCES
New in version 3.21.

Adds the named <resource> files to the jar by stripping the source file path and placing
the file beneath <ns> within the jar.

For example:

RESOURCES NAMESPACE "/com/my/namespace" "a/path/to/resource.txt"

results in a resource accessible via /com/my/namespace/resource.txt within the jar.

Resources may be added without adjusting the namespace by adding them to the list of
SOURCES (original behavior), in this case, resource paths must be relative to
CMAKE_CURRENT_SOURCE_DIR. Adding resources without using the RESOURCES parameter in out of
source builds will almost certainly result in confusion.

NOTE:
Adding resources via the SOURCES parameter relies upon a hard-coded list of file
extensions which are tested to determine whether they compile (e.g. File.java). SOURCES
files which match the extensions are compiled. Files which do not match are treated as
resources. To include uncompiled resources matching those file extensions use the
RESOURCES parameter.

INCLUDE_JARS
The list of jars are added to the classpath when compiling the java sources and also to the
dependencies of the target. INCLUDE_JARS also accepts other target names created by
add_jar(). For backwards compatibility, jar files listed as sources are ignored (as they
have been since the first version of this module).

ENTRY_POINT
Defines an entry point in the jar file.

VERSION
Adds a version to the target output name.

The following example will create a jar file with the name shibboleet-1.2.0.jar and will
create a symlink shibboleet.jar pointing to the jar with the version information.

add_jar(shibboleet shibbotleet.java VERSION 1.2.0)

MANIFEST
Defines a custom manifest for the jar.

OUTPUT_NAME
Specify a different output name for the target.

OUTPUT_DIR
Sets the directory where the jar file will be generated. If not specified,
CMAKE_CURRENT_BINARY_DIR is used as the output directory.

GENERATE_NATIVE_HEADERS
New in version 3.11.

Generates native header files for methods declared as native. These files provide the
connective glue that allow your Java and C code to interact. An INTERFACE target will be
created for an easy usage of generated files. Sub-option DESTINATION can be used to
specify the output directory for generated header files.

This option requires, at least, version 1.8 of the JDK.

For an optimum usage of this option, it is recommended to include module JNI before any
call to add_jar(). The produced target for native headers can then be used to compile C/C++
sources with the target_link_libraries() command.

find_package(JNI)
add_jar(foo foo.java GENERATE_NATIVE_HEADERS foo-native)
add_library(bar bar.cpp)
target_link_libraries(bar PRIVATE foo-native)

New in version 3.20: DESTINATION sub-option now supports the possibility to specify
different output directories for BUILD and INSTALL steps. If BUILD directory is not
specified, a default directory will be used.

To export the interface target generated by GENERATE_NATIVE_HEADERS option, sub-option
INSTALL of DESTINATION is required:

add_jar(foo foo.java GENERATE_NATIVE_HEADERS foo-native
DESTINATION INSTALL include)
install(TARGETS foo-native EXPORT native)
install(DIRECTORY "$<TARGET_PROPERTY:foo-native,NATIVE_HEADERS_DIRECTORY>/"
DESTINATION include)
install(EXPORT native DESTINATION /to/export NAMESPACE foo)

Some variables can be set to customize the behavior of add_jar() as well as the java compiler:

CMAKE_JAVA_COMPILE_FLAGS
Specify additional flags to java compiler.

CMAKE_JAVA_INCLUDE_PATH
Specify additional paths to the class path.

CMAKE_JNI_TARGET
If the target is a JNI library, sets this boolean variable to TRUE to enable creation of a
JNI symbolic link (see also install_jni_symlink()).

CMAKE_JAR_CLASSES_PREFIX
If multiple jars should be produced from the same java source filetree, to prevent the
accumulation of duplicate class files in subsequent jars, set/reset
CMAKE_JAR_CLASSES_PREFIX prior to calling the add_jar():

set(CMAKE_JAR_CLASSES_PREFIX com/redhat/foo)
add_jar(foo foo.java)

set(CMAKE_JAR_CLASSES_PREFIX com/redhat/bar)
add_jar(bar bar.java)

The add_jar() function sets the following target properties on <target_name>:

INSTALL_FILES
The files which should be installed. This is used by install_jar().

JNI_SYMLINK
The JNI symlink which should be installed. This is used by install_jni_symlink().

JAR_FILE
The location of the jar file so that you can include it.

CLASSDIR
The directory where the class files can be found. For example to use them with javah.

NATIVE_HEADERS_DIRECTORY
New in version 3.20.

The directory where native headers are generated. Defined when option
GENERATE_NATIVE_HEADERS is specified.

install_jar
This command installs the jar file to the given destination:

install_jar(<target_name> <destination>)
install_jar(<target_name> DESTINATION <destination> [COMPONENT <component>])

This command installs the <target_name> file to the given <destination>. It should be called in
the same scope as add_jar() or it will fail.

New in version 3.4: The second signature with DESTINATION and COMPONENT options.

DESTINATION
Specify the directory on disk to which a file will be installed.

COMPONENT
Specify an installation component name with which the install rule is associated, such as
"runtime" or "development".

The install_jar() command sets the following target properties on <target_name>:

INSTALL_DESTINATION
Holds the <destination> as described above, and is used by install_jar_exports().

install_jni_symlink
Installs JNI symlinks for target generated by add_jar():

install_jni_symlink(<target_name> <destination>)
install_jni_symlink(<target_name> DESTINATION <destination> [COMPONENT <component>])

This command installs the <target_name> JNI symlinks to the given <destination>. It should be
called in the same scope as add_jar() or it will fail.

New in version 3.4: The second signature with DESTINATION and COMPONENT options.

DESTINATION
Specify the directory on disk to which a file will be installed.

COMPONENT
Specify an installation component name with which the install rule is associated, such as
"runtime" or "development".

Utilize the following commands to create a JNI symbolic link:

set(CMAKE_JNI_TARGET TRUE)
add_jar(shibboleet shibbotleet.java VERSION 1.2.0)
install_jar(shibboleet ${LIB_INSTALL_DIR}/shibboleet)
install_jni_symlink(shibboleet ${JAVA_LIB_INSTALL_DIR})

Header Generation
create_javah
New in version 3.4.

Generates C header files for java classes:

create_javah(TARGET <target> | GENERATED_FILES <VAR>
CLASSES <class>...
[CLASSPATH <classpath>...]
[DEPENDS <depend>...]
[OUTPUT_NAME <path>|OUTPUT_DIR <path>]
)

Deprecated since version 3.11: This command will no longer be supported starting with version 10
of the JDK due to the suppression of javah tool. The add_jar(GENERATE_NATIVE_HEADERS) command
should be used instead.

Create C header files from java classes. These files provide the connective glue that allow your
Java and C code to interact.

There are two main signatures for create_javah(). The first signature returns generated files
through variable specified by the GENERATED_FILES option. For example:

create_javah(GENERATED_FILES files_headers
CLASSES org.cmake.HelloWorld
CLASSPATH hello.jar
)

The second signature for create_javah() creates a target which encapsulates header files
generation. E.g.

create_javah(TARGET target_headers
CLASSES org.cmake.HelloWorld
CLASSPATH hello.jar
)

Both signatures share same options.

CLASSES
Specifies Java classes used to generate headers.

CLASSPATH
Specifies various paths to look up classes. Here .class files, jar files or targets created
by command add_jar can be used.

DEPENDS
Targets on which the javah target depends.

OUTPUT_NAME
Concatenates the resulting header files for all the classes listed by option CLASSES into
<path>. Same behavior as option -o of javah tool.

OUTPUT_DIR
Sets the directory where the header files will be generated. Same behavior as option -d of
javah tool. If not specified, CMAKE_CURRENT_BINARY_DIR is used as the output directory.

Exporting JAR Targets
install_jar_exports
New in version 3.7.

Installs a target export file:

install_jar_exports(TARGETS <jars>...
[NAMESPACE <namespace>]
FILE <filename>
DESTINATION <destination> [COMPONENT <component>])

This command installs a target export file <filename> for the named jar targets to the given
<destination> directory. Its function is similar to that of install(EXPORT).

TARGETS
List of targets created by add_jar() command.

NAMESPACE
New in version 3.9.

The <namespace> value will be prepend to the target names as they are written to the import
file.

FILE Specify name of the export file.

DESTINATION
Specify the directory on disk to which a file will be installed.

COMPONENT
Specify an installation component name with which the install rule is associated, such as
"runtime" or "development".

export_jars
New in version 3.7.

Writes a target export file:

export_jars(TARGETS <jars>...
[NAMESPACE <namespace>]
FILE <filename>)

This command writes a target export file <filename> for the named <jars> targets. Its function is
similar to that of export().

TARGETS
List of targets created by add_jar() command.

NAMESPACE
New in version 3.9.

The <namespace> value will be prepend to the target names as they are written to the import
file.

FILE Specify name of the export file.

Finding JARs
find_jar
Finds the specified jar file:

find_jar(<VAR>
<name> | NAMES <name1> [<name2>...]
[PATHS <path1> [<path2>... ENV <var>]]
[VERSIONS <version1> [<version2>]]
[DOC "cache documentation string"]
)

This command is used to find a full path to the named jar. A cache entry named by <VAR> is
created to store the result of this command. If the full path to a jar is found the result is
stored in the variable and the search will not repeated unless the variable is cleared. If
nothing is found, the result will be <VAR>-NOTFOUND, and the search will be attempted again next
time find_jar() is invoked with the same variable.

NAMES Specify one or more possible names for the jar file.

PATHS Specify directories to search in addition to the default locations. The ENV var sub-option
reads paths from a system environment variable.

VERSIONS
Specify jar versions.

DOC Specify the documentation string for the <VAR> cache entry.

Creating Java Documentation
create_javadoc
Creates java documentation based on files and packages:

create_javadoc(<VAR>
(PACKAGES <pkg1> [<pkg2>...] | FILES <file1> [<file2>...])
[SOURCEPATH <sourcepath>]
[CLASSPATH <classpath>]
[INSTALLPATH <install path>]
[DOCTITLE <the documentation title>]
[WINDOWTITLE <the title of the document>]
[AUTHOR (TRUE|FALSE)]
[USE (TRUE|FALSE)]
[VERSION (TRUE|FALSE)]
)

The create_javadoc() command can be used to create java documentation. There are two main
signatures for create_javadoc().

The first signature works with package names on a path with source files:

create_javadoc(my_example_doc
PACKAGES com.example.foo com.example.bar
SOURCEPATH "${CMAKE_CURRENT_SOURCE_DIR}"
CLASSPATH ${CMAKE_JAVA_INCLUDE_PATH}
WINDOWTITLE "My example"
DOCTITLE "<h1>My example</h1>"
AUTHOR TRUE
USE TRUE
VERSION TRUE
)

The second signature for create_javadoc() works on a given list of files:

create_javadoc(my_example_doc
FILES java/A.java java/B.java
CLASSPATH ${CMAKE_JAVA_INCLUDE_PATH}
WINDOWTITLE "My example"
DOCTITLE "<h1>My example</h1>"
AUTHOR TRUE
USE TRUE
VERSION TRUE
)

Both signatures share most of the options. For more details please read the javadoc manpage.

PACKAGES
Specify java packages.

FILES Specify java source files. If relative paths are specified, they are relative to
CMAKE_CURRENT_SOURCE_DIR.

SOURCEPATH
Specify the directory where to look for packages. By default, CMAKE_CURRENT_SOURCE_DIR
directory is used.

CLASSPATH
Specify where to find user class files. Same behavior as option -classpath of javadoc tool.

INSTALLPATH
Specify where to install the java documentation. If you specified, the documentation will
be installed to ${CMAKE_INSTALL_PREFIX}/share/javadoc/<VAR>.

DOCTITLE
Specify the title to place near the top of the overview summary file. Same behavior as
option -doctitle of javadoc tool.

WINDOWTITLE
Specify the title to be placed in the HTML <title> tag. Same behavior as option
-windowtitle of javadoc tool.

AUTHOR When value TRUE is specified, includes the @author text in the generated docs. Same
behavior as option -author of javadoc tool.

USE When value TRUE is specified, creates class and package usage pages. Includes one Use page
for each documented class and package. Same behavior as option -use of javadoc tool.

VERSION
When value TRUE is specified, includes the version text in the generated docs. Same
behavior as option -version of javadoc tool.

UseSWIG
This file provides support for SWIG. It is assumed that FindSWIG module has already been loaded.

Defines the following command for use with SWIG:

swig_add_library
New in version 3.8.

Define swig module with given name and specified language:

swig_add_library(<name>
[TYPE <SHARED|MODULE|STATIC|USE_BUILD_SHARED_LIBS>]
LANGUAGE <language>
[NO_PROXY]
[OUTPUT_DIR <directory>]
[OUTFILE_DIR <directory>]
SOURCES <file>...
)

Targets created with the swig_add_library command have the same capabilities as targets created
with the add_library() command, so those targets can be used with any command expecting a target
(e.g. target_link_libraries()).

Changed in version 3.13: This command creates a target with the specified <name> when policy
CMP0078 is set to NEW. Otherwise, the legacy behavior will choose a different target name and
store it in the SWIG_MODULE_<name>_REAL_NAME variable.

Changed in version 3.15: Alternate library name (set with the OUTPUT_NAME property, for example)
will be passed on to Python and CSharp wrapper libraries.

Changed in version 3.21: Generated library use standard naming conventions for CSharp language
when policy CMP0122 is set to NEW. Otherwise, the legacy behavior is applied.

NOTE:
For multi-config generators, this module does not support configuration-specific files
generated by SWIG. All build configurations must result in the same generated source file.

NOTE:
For Makefile Generators, if, for some sources, the USE_SWIG_DEPENDENCIES property is FALSE,
swig_add_library does not track file dependencies, so depending on the <name>_swig_compilation
custom target is required for targets which require the swig-generated files to exist. Other
generators may depend on the source files that would be generated by SWIG.

TYPE SHARED, MODULE and STATIC have the same semantic as for the add_library() command. If
USE_BUILD_SHARED_LIBS is specified, the library type will be STATIC or SHARED based on
whether the current value of the BUILD_SHARED_LIBS variable is ON. If no type is specified,
MODULE will be used.

LANGUAGE
Specify the target language.

New in version 3.1: Go and Lua language support.

New in version 3.2: R language support.

New in version 3.18: Fortran language support.

NO_PROXY
New in version 3.12.

Prevent the generation of the wrapper layer (swig -noproxy option).

OUTPUT_DIR
New in version 3.12.

Specify where to write the language specific files (swig -outdir option). If not given, the
CMAKE_SWIG_OUTDIR variable will be used. If neither is specified, the default depends on
the value of the UseSWIG_MODULE_VERSION variable as follows:

• If UseSWIG_MODULE_VERSION is 1 or is undefined, output is written to the
CMAKE_CURRENT_BINARY_DIR directory.

• If UseSWIG_MODULE_VERSION is 2, a dedicated directory will be used. The path of this
directory can be retrieved from the SWIG_SUPPORT_FILES_DIRECTORY target property.

OUTFILE_DIR
New in version 3.12.

Specify an output directory name where the generated source file will be placed (swig -o
option). If not specified, the SWIG_OUTFILE_DIR variable will be used. If neither is
specified, OUTPUT_DIR or CMAKE_SWIG_OUTDIR is used instead.

SOURCES
List of sources for the library. Files with extension .i will be identified as sources for
the SWIG tool. Other files will be handled in the standard way.

New in version 3.14: This behavior can be overridden by specifying the variable
SWIG_SOURCE_FILE_EXTENSIONS.

NOTE:
If UseSWIG_MODULE_VERSION is set to 2, it is strongly recommended to use a dedicated directory
unique to the target when either the OUTPUT_DIR option or the CMAKE_SWIG_OUTDIR variable are
specified. The output directory contents are erased as part of the target build, so to prevent
interference between targets or losing other important files, each target should have its own
dedicated output directory.

swig_link_libraries
Link libraries to swig module:

swig_link_libraries(<name> <item>...)

This command has same capabilities as target_link_libraries() command.

NOTE:
If variable UseSWIG_TARGET_NAME_PREFERENCE is set to STANDARD, this command is deprecated and
target_link_libraries() command must be used instead.

Source file properties on module files must be set before the invocation of the swig_add_library command
to specify special behavior of SWIG and ensure generated files will receive the required settings.

CPLUSPLUS
Call SWIG in c++ mode. For example:

set_property(SOURCE mymod.i PROPERTY CPLUSPLUS ON)
swig_add_library(mymod LANGUAGE python SOURCES mymod.i)

SWIG_FLAGS
Deprecated since version 3.12: Replaced with the fine-grained properties that follow.

Pass custom flags to the SWIG executable.

INCLUDE_DIRECTORIES, COMPILE_DEFINITIONS and COMPILE_OPTIONS
New in version 3.12.

Add custom flags to SWIG compiler and have same semantic as properties INCLUDE_DIRECTORIES,
COMPILE_DEFINITIONS and COMPILE_OPTIONS.

USE_TARGET_INCLUDE_DIRECTORIES
New in version 3.13.

If set to TRUE, contents of target property INCLUDE_DIRECTORIES will be forwarded to SWIG
compiler. If set to FALSE target property INCLUDE_DIRECTORIES will be ignored. If not set, target
property SWIG_USE_TARGET_INCLUDE_DIRECTORIES will be considered.

GENERATED_INCLUDE_DIRECTORIES, GENERATED_COMPILE_DEFINITIONS and GENERATED_COMPILE_OPTIONS
New in version 3.12.

Add custom flags to the C/C++ generated source. They will fill, respectively, properties
INCLUDE_DIRECTORIES, COMPILE_DEFINITIONS and COMPILE_OPTIONS of generated C/C++ file.

DEPENDS
New in version 3.12.

Specify additional dependencies to the source file.

USE_SWIG_DEPENDENCIES
New in version 3.20.

If set to TRUE, implicit dependencies are generated by the swig tool itself. This property is only
meaningful for Makefile, Ninja, Xcode, and Visual Studio (Visual Studio 11 2012 and above)
generators. Default value is FALSE.

New in version 3.21: Added the support of Xcode generator.

New in version 3.22: Added the support of Visual Studio Generators.

SWIG_MODULE_NAME
Specify the actual import name of the module in the target language. This is required if it
cannot be scanned automatically from source or different from the module file basename. For
example:

set_property(SOURCE mymod.i PROPERTY SWIG_MODULE_NAME mymod_realname)

Changed in version 3.14: If policy CMP0086 is set to NEW, -module <module_name> is passed to SWIG
compiler.

OUTPUT_DIR
New in version 3.19.

Specify where to write the language specific files (swig -outdir option) for the considered source
file. If not specified, the other ways to define the output directory applies (see OUTPUT_DIR
option of swig_add_library() command).

OUTFILE_DIR
New in version 3.19.

Specify an output directory where the generated source file will be placed (swig -o option) for
the considered source file. If not specified, OUTPUT_DIR source property will be used. If neither
are specified, the other ways to define output file directory applies (see OUTFILE_DIR option of
swig_add_library() command).

Target library properties can be set to apply same configuration to all SWIG input files.

SWIG_INCLUDE_DIRECTORIES, SWIG_COMPILE_DEFINITIONS and SWIG_COMPILE_OPTIONS
New in version 3.12.

These properties will be applied to all SWIG input files and have same semantic as target
properties INCLUDE_DIRECTORIES, COMPILE_DEFINITIONS and COMPILE_OPTIONS.

set (UseSWIG_TARGET_NAME_PREFERENCE STANDARD)
swig_add_library(mymod LANGUAGE python SOURCES mymod.i)
set_property(TARGET mymod PROPERTY SWIG_COMPILE_DEFINITIONS MY_DEF1 MY_DEF2)
set_property(TARGET mymod PROPERTY SWIG_COMPILE_OPTIONS -bla -blb)

SWIG_USE_TARGET_INCLUDE_DIRECTORIES
New in version 3.13.

If set to TRUE, contents of target property INCLUDE_DIRECTORIES will be forwarded to SWIG
compiler. If set to FALSE or not defined, target property INCLUDE_DIRECTORIES will be ignored.
This behavior can be overridden by specifying source property USE_TARGET_INCLUDE_DIRECTORIES.

SWIG_GENERATED_INCLUDE_DIRECTORIES, SWIG_GENERATED_COMPILE_DEFINITIONS and SWIG_GENERATED_COMPILE_OPTIONS
New in version 3.12.

These properties will populate, respectively, properties INCLUDE_DIRECTORIES, COMPILE_DEFINITIONS
and COMPILE_FLAGS of all generated C/C++ files.

SWIG_DEPENDS
New in version 3.12.

Add dependencies to all SWIG input files.

The following target properties are output properties and can be used to get information about support
files generated by SWIG interface compilation.

SWIG_SUPPORT_FILES
New in version 3.12.

This output property list of wrapper files generated during SWIG compilation.

set (UseSWIG_TARGET_NAME_PREFERENCE STANDARD)
swig_add_library(mymod LANGUAGE python SOURCES mymod.i)
get_property(support_files TARGET mymod PROPERTY SWIG_SUPPORT_FILES)

NOTE:
Only most principal support files are listed. In case some advanced features of SWIG are used
(for example %template), associated support files may not be listed. Prefer to use the
SWIG_SUPPORT_FILES_DIRECTORY property to handle support files.

SWIG_SUPPORT_FILES_DIRECTORY
New in version 3.12.

This output property specifies the directory where support files will be generated.

NOTE:
When source property OUTPUT_DIR is defined, multiple directories can be specified as part of
SWIG_SUPPORT_FILES_DIRECTORY.

Some variables can be set to customize the behavior of swig_add_library as well as SWIG:

UseSWIG_MODULE_VERSION
New in version 3.12.

Specify different behaviors for UseSWIG module.

• Set to 1 or undefined: Legacy behavior is applied.

• Set to 2: A new strategy is applied regarding support files: the output directory of support
files is erased before SWIG interface compilation.

CMAKE_SWIG_FLAGS
Add flags to all swig calls.

CMAKE_SWIG_OUTDIR
Specify where to write the language specific files (swig -outdir option).

SWIG_OUTFILE_DIR
New in version 3.8.

Specify an output directory name where the generated source file will be placed. If not
specified, CMAKE_SWIG_OUTDIR is used.

SWIG_MODULE_<name>_EXTRA_DEPS
Specify extra dependencies for the generated module for <name>.

SWIG_SOURCE_FILE_EXTENSIONS
New in version 3.14.

Specify a list of source file extensions to override the default behavior of considering only .i
files as sources for the SWIG tool. For example:

set(SWIG_SOURCE_FILE_EXTENSIONS ".i" ".swg")

SWIG_USE_SWIG_DEPENDENCIES
New in version 3.20.

If set to TRUE, implicit dependencies are generated by the swig tool itself. This variable is only
meaningful for Makefile, Ninja, Xcode, and Visual Studio (Visual Studio 11 2012 and above)
generators. Default value is FALSE.

Source file property USE_SWIG_DEPENDENCIES, if not defined, will be initialized with the value of
this variable.

New in version 3.21: Added the support of Xcode generator.

New in version 3.22: Added the support of Visual Studio Generators.

UsewxWidgets
Convenience include for using wxWidgets library.

Determines if wxWidgets was FOUND and sets the appropriate libs, incdirs, flags, etc.
INCLUDE_DIRECTORIES and LINK_DIRECTORIES are called.

USAGE

# Note that for MinGW users the order of libs is important!
find_package(wxWidgets REQUIRED net gl core base)
include(${wxWidgets_USE_FILE})
# and for each of your dependent executable/library targets:
target_link_libraries(<YourTarget> ${wxWidgets_LIBRARIES})

DEPRECATED

LINK_LIBRARIES is not called in favor of adding dependencies per target.

AUTHOR

Jan Woetzel <jw -at- mip.informatik.uni-kiel.de>

FIND MODULES

These modules search for third-party software. They are normally called through the find_package()
command.

FindALSA
Find Advanced Linux Sound Architecture (ALSA)

Find the alsa libraries (asound)

IMPORTED Targets
New in version 3.12.

This module defines IMPORTED target ALSA::ALSA, if ALSA has been found.

Result Variables
This module defines the following variables:

ALSA_FOUND
True if ALSA_INCLUDE_DIR & ALSA_LIBRARY are found

ALSA_LIBRARIES
List of libraries when using ALSA.

ALSA_INCLUDE_DIRS
Where to find the ALSA headers.

Cache variables
The following cache variables may also be set:

ALSA_INCLUDE_DIR
the ALSA include directory

ALSA_LIBRARY
the absolute path of the asound library

FindArmadillo
Find the Armadillo C++ library. Armadillo is a library for linear algebra & scientific computing.

New in version 3.18: Support for linking wrapped libraries directly (ARMA_DONT_USE_WRAPPER).

Using Armadillo:

find_package(Armadillo REQUIRED)
include_directories(${ARMADILLO_INCLUDE_DIRS})
add_executable(foo foo.cc)
target_link_libraries(foo ${ARMADILLO_LIBRARIES})

This module sets the following variables:

ARMADILLO_FOUND - set to true if the library is found
ARMADILLO_INCLUDE_DIRS - list of required include directories
ARMADILLO_LIBRARIES - list of libraries to be linked
ARMADILLO_VERSION_MAJOR - major version number
ARMADILLO_VERSION_MINOR - minor version number
ARMADILLO_VERSION_PATCH - patch version number
ARMADILLO_VERSION_STRING - version number as a string (ex: "1.0.4")
ARMADILLO_VERSION_NAME - name of the version (ex: "Antipodean Antileech")

FindASPELL
Try to find ASPELL

Once done this will define

ASPELL_FOUND - system has ASPELL
ASPELL_EXECUTABLE - the ASPELL executable
ASPELL_INCLUDE_DIR - the ASPELL include directory
ASPELL_LIBRARIES - The libraries needed to use ASPELL
ASPELL_DEFINITIONS - Compiler switches required for using ASPELL

FindAVIFile
Locate AVIFILE library and include paths

AVIFILE (http://avifile.sourceforge.net/) is a set of libraries for i386 machines to use various AVI
codecs. Support is limited beyond Linux. Windows provides native AVI support, and so doesn't need this
library. This module defines

AVIFILE_INCLUDE_DIR, where to find avifile.h , etc.
AVIFILE_LIBRARIES, the libraries to link against
AVIFILE_DEFINITIONS, definitions to use when compiling
AVIFILE_FOUND, If false, don't try to use AVIFILE

FindBacktrace
Find provider for backtrace(3).

Checks if OS supports backtrace(3) via either libc or custom library. This module defines the following
variables:

Backtrace_HEADER
The header file needed for backtrace(3). Cached. Could be forcibly set by user.

Backtrace_INCLUDE_DIRS
The include directories needed to use backtrace(3) header.

Backtrace_LIBRARIES
The libraries (linker flags) needed to use backtrace(3), if any.

Backtrace_FOUND
Is set if and only if backtrace(3) support detected.

The following cache variables are also available to set or use:

Backtrace_LIBRARY
The external library providing backtrace, if any.

Backtrace_INCLUDE_DIR
The directory holding the backtrace(3) header.

Typical usage is to generate of header file using configure_file() with the contents like the following:

#cmakedefine01 Backtrace_FOUND
#if Backtrace_FOUND
# include <${Backtrace_HEADER}>
#endif

And then reference that generated header file in actual source.

FindBISON
Find bison executable and provide a macro to generate custom build rules.

The module defines the following variables:

BISON_EXECUTABLE
path to the bison program

BISON_VERSION
version of bison

BISON_FOUND
"True" if the program was found

The minimum required version of bison can be specified using the standard CMake syntax, e.g.
find_package(BISON 2.1.3).

If bison is found, the module defines the macro:

BISON_TARGET(<Name> <YaccInput> <CodeOutput>
[COMPILE_FLAGS <flags>]
[DEFINES_FILE <file>]
[VERBOSE [<file>]]
[REPORT_FILE <file>]
)

which will create a custom rule to generate a parser. <YaccInput> is the path to a yacc file.
<CodeOutput> is the name of the source file generated by bison. A header file is also be generated, and
contains the token list.

Changed in version 3.14: When CMP0088 is set to NEW, bison runs in the CMAKE_CURRENT_BINARY_DIR
directory.

The options are:

COMPILE_FLAGS <flags>
Specify flags to be added to the bison command line.

DEFINES_FILE <file>
New in version 3.4.

Specify a non-default header <file> to be generated by bison.

VERBOSE [<file>]
Tell bison to write a report file of the grammar and parser.

Deprecated since version 3.7: If <file> is given, it specifies path the report file is copied to.
[<file>] is left for backward compatibility of this module. Use VERBOSE REPORT_FILE <file>.

REPORT_FILE <file>
New in version 3.7.

Specify a non-default report <file>, if generated.

The macro defines the following variables:

BISON_<Name>_DEFINED
True is the macro ran successfully

BISON_<Name>_INPUT
The input source file, an alias for <YaccInput>

BISON_<Name>_OUTPUT_SOURCE
The source file generated by bison

BISON_<Name>_OUTPUT_HEADER
The header file generated by bison

BISON_<Name>_OUTPUTS
All files generated by bison including the source, the header and the report

BISON_<Name>_COMPILE_FLAGS
Options used in the bison command line

Example usage:

find_package(BISON)
BISON_TARGET(MyParser parser.y ${CMAKE_CURRENT_BINARY_DIR}/parser.cpp
DEFINES_FILE ${CMAKE_CURRENT_BINARY_DIR}/parser.h)
add_executable(Foo main.cpp ${BISON_MyParser_OUTPUTS})

FindBLAS
Find Basic Linear Algebra Subprograms (BLAS) library

This module finds an installed Fortran library that implements the BLAS linear-algebra interface.

At least one of the C, CXX, or Fortran languages must be enabled.

Input Variables
The following variables may be set to influence this module's behavior:

BLA_STATIC
if ON use static linkage

BLA_VENDOR
Set to one of the BLAS/LAPACK Vendors to search for BLAS only from the specified vendor. If not
set, all vendors are considered.

BLA_F95
if ON tries to find the BLAS95 interfaces

BLA_PREFER_PKGCONFIG
New in version 3.11.

if set pkg-config will be used to search for a BLAS library first and if one is found that is
preferred

BLA_SIZEOF_INTEGER
New in version 3.22.

Specify the BLAS/LAPACK library integer size:

4 Search for a BLAS/LAPACK with 32-bit integer interfaces.

8 Search for a BLAS/LAPACK with 64-bit integer interfaces.

ANY Search for any BLAS/LAPACK. Most likely, a BLAS/LAPACK with 32-bit integer interfaces will
be found.

Imported targets
This module defines the following IMPORTED targets:

BLAS::BLAS
New in version 3.18.

The libraries to use for BLAS, if found.

Result Variables
This module defines the following variables:

BLAS_FOUND
library implementing the BLAS interface is found

BLAS_LINKER_FLAGS
uncached list of required linker flags (excluding -l and -L).

BLAS_LIBRARIES
uncached list of libraries (using full path name) to link against to use BLAS (may be empty if
compiler implicitly links BLAS)

BLAS95_LIBRARIES
uncached list of libraries (using full path name) to link against to use BLAS95 interface

BLAS95_FOUND
library implementing the BLAS95 interface is found

BLAS/LAPACK Vendors
Generic
Generic reference implementation

ACML, ACML_MP, ACML_GPU
AMD Core Math Library

Apple, NAS
Apple BLAS (Accelerate), and Apple NAS (vecLib)

Arm, Arm_mp, Arm_ilp64, Arm_ilp64_mp
New in version 3.18.

Arm Performance Libraries

ATLAS Automatically Tuned Linear Algebra Software

CXML, DXML
Compaq/Digital Extended Math Library

EML, EML_mt
New in version 3.20.

Elbrus Math Library

FLAME New in version 3.11.

BLIS Framework

FlexiBLAS
New in version 3.19.

Fujitsu_SSL2, Fujitsu_SSL2BLAMP, Fujitsu_SSL2SVE, Fujitsu_SSL2BLAMPSVE
New in version 3.20.

Fujitsu SSL2 serial and parallel blas/lapack with SVE instructions

Goto GotoBLAS

IBMESSL, IBMESSL_SMP
IBM Engineering and Scientific Subroutine Library

Intel Intel MKL 32 bit and 64 bit obsolete versions

Intel10_32
Intel MKL v10 32 bit, threaded code

Intel10_64lp
Intel MKL v10+ 64 bit, threaded code, lp64 model

Intel10_64lp_seq
Intel MKL v10+ 64 bit, sequential code, lp64 model

Intel10_64ilp
New in version 3.13.

Intel MKL v10+ 64 bit, threaded code, ilp64 model

Intel10_64ilp_seq
New in version 3.13.

Intel MKL v10+ 64 bit, sequential code, ilp64 model

Intel10_64_dyn
New in version 3.17.

Intel MKL v10+ 64 bit, single dynamic library

NVHPC New in version 3.21.

NVIDIA HPC SDK

OpenBLAS
New in version 3.6.

PhiPACK
Portable High Performance ANSI C (PHiPAC)

SCSL, SCSL_mp
Scientific Computing Software Library

SGIMATH
SGI Scientific Mathematical Library

SunPerf
Sun Performance Library

Intel MKL
To use the Intel MKL implementation of BLAS, a project must enable at least one of the C or CXX
languages. Set BLA_VENDOR to an Intel MKL variant either on the command-line as
-DBLA_VENDOR=Intel10_64lp or in project code:

set(BLA_VENDOR Intel10_64lp)
find_package(BLAS)

In order to build a project using Intel MKL, and end user must first establish an Intel MKL environment:

Intel oneAPI
Source the full Intel environment script:

. /opt/intel/oneapi/setvars.sh

Or, source the MKL component environment script:

. /opt/intel/oneapi/mkl/latest/env/vars.sh

Intel Classic
Source the full Intel environment script:

. /opt/intel/bin/compilervars.sh intel64

Or, source the MKL component environment script:

. /opt/intel/mkl/bin/mklvars.sh intel64

The above environment scripts set the MKLROOT environment variable to the top of the MKL installation.
They also add the location of the runtime libraries to the dynamic library loader environment variable
for your platform (e.g. LD_LIBRARY_PATH). This is necessary for programs linked against MKL to run.

NOTE:
As of Intel oneAPI 2021.2, loading only the MKL component does not make all of its dependencies
available. In particular, the iomp5 library must be available separately, or provided by also loading
the compiler component environment:

. /opt/intel/oneapi/compiler/latest/env/vars.sh

FindBoost
Find Boost include dirs and libraries

Use this module by invoking find_package() with the form:

find_package(Boost
[version] [EXACT] # Minimum or EXACT version e.g. 1.67.0
[REQUIRED] # Fail with error if Boost is not found
[COMPONENTS <libs>...] # Boost libraries by their canonical name
# e.g. "date_time" for "libboost_date_time"
[OPTIONAL_COMPONENTS <libs>...]
# Optional Boost libraries by their canonical name)
) # e.g. "date_time" for "libboost_date_time"

This module finds headers and requested component libraries OR a CMake package configuration file
provided by a "Boost CMake" build. For the latter case skip to the Boost CMake section below.

New in version 3.7: bzip2 and zlib components (Windows only).

New in version 3.11: The OPTIONAL_COMPONENTS option.

New in version 3.13: stacktrace_* components.

New in version 3.19: bzip2 and zlib components on all platforms.

Result Variables
This module defines the following variables:

Boost_FOUND
True if headers and requested libraries were found.

Boost_INCLUDE_DIRS
Boost include directories.

Boost_LIBRARY_DIRS
Link directories for Boost libraries.

Boost_LIBRARIES
Boost component libraries to be linked.

Boost_<COMPONENT>_FOUND
True if component <COMPONENT> was found (<COMPONENT> name is upper-case).

Boost_<COMPONENT>_LIBRARY
Libraries to link for component <COMPONENT> (may include target_link_libraries() debug/optimized
keywords).

Boost_VERSION_MACRO
BOOST_VERSION value from boost/version.hpp.

Boost_VERSION_STRING
Boost version number in X.Y.Z format.

Boost_VERSION
Boost version number in X.Y.Z format (same as Boost_VERSION_STRING).

Changed in version 3.15: In previous CMake versions, this variable used the raw version string
from the Boost header (same as Boost_VERSION_MACRO). See policy CMP0093.

Boost_LIB_VERSION
Version string appended to library filenames.

Boost_VERSION_MAJOR, Boost_MAJOR_VERSION
Boost major version number (X in X.Y.Z).

Boost_VERSION_MINOR, Boost_MINOR_VERSION
Boost minor version number (Y in X.Y.Z).

Boost_VERSION_PATCH, Boost_SUBMINOR_VERSION
Boost subminor version number (Z in X.Y.Z).

Boost_VERSION_COUNT
Amount of version components (3).

Boost_LIB_DIAGNOSTIC_DEFINITIONS (Windows-specific)
Pass to add_definitions() to have diagnostic information about Boost's automatic linking displayed
during compilation

New in version 3.15: The Boost_VERSION_<PART> variables.

Cache variables
Search results are saved persistently in CMake cache entries:

Boost_INCLUDE_DIR
Directory containing Boost headers.

Boost_LIBRARY_DIR_RELEASE
Directory containing release Boost libraries.

Boost_LIBRARY_DIR_DEBUG
Directory containing debug Boost libraries.

Boost_<COMPONENT>_LIBRARY_DEBUG
Component <COMPONENT> library debug variant.

Boost_<COMPONENT>_LIBRARY_RELEASE
Component <COMPONENT> library release variant.

New in version 3.3: Per-configuration variables Boost_LIBRARY_DIR_RELEASE and Boost_LIBRARY_DIR_DEBUG.

Hints
This module reads hints about search locations from variables:

BOOST_ROOT, BOOSTROOT
Preferred installation prefix.

BOOST_INCLUDEDIR
Preferred include directory e.g. <prefix>/include.

BOOST_LIBRARYDIR
Preferred library directory e.g. <prefix>/lib.

Boost_NO_SYSTEM_PATHS
Set to ON to disable searching in locations not specified by these hint variables. Default is OFF.

Boost_ADDITIONAL_VERSIONS
List of Boost versions not known to this module. (Boost install locations may contain the
version).

Users may set these hints or results as CACHE entries. Projects should not read these entries directly
but instead use the above result variables. Note that some hint names start in upper-case BOOST. One
may specify these as environment variables if they are not specified as CMake variables or cache entries.

This module first searches for the Boost header files using the above hint variables (excluding
BOOST_LIBRARYDIR) and saves the result in Boost_INCLUDE_DIR. Then it searches for requested component
libraries using the above hints (excluding BOOST_INCLUDEDIR and Boost_ADDITIONAL_VERSIONS), "lib"
directories near Boost_INCLUDE_DIR, and the library name configuration settings below. It saves the
library directories in Boost_LIBRARY_DIR_DEBUG and Boost_LIBRARY_DIR_RELEASE and individual library
locations in Boost_<COMPONENT>_LIBRARY_DEBUG and Boost_<COMPONENT>_LIBRARY_RELEASE. When one changes
settings used by previous searches in the same build tree (excluding environment variables) this module
discards previous search results affected by the changes and searches again.

Imported Targets
New in version 3.5.

This module defines the following IMPORTED targets:

Boost::boost
Target for header-only dependencies. (Boost include directory).

Boost::headers
New in version 3.15: Alias for Boost::boost.

Boost::<component>
Target for specific component dependency (shared or static library); <component> name is
lower-case.

Boost::diagnostic_definitions
Interface target to enable diagnostic information about Boost's automatic linking during
compilation (adds -DBOOST_LIB_DIAGNOSTIC).

Boost::disable_autolinking
Interface target to disable automatic linking with MSVC (adds -DBOOST_ALL_NO_LIB).

Boost::dynamic_linking
Interface target to enable dynamic linking with MSVC (adds -DBOOST_ALL_DYN_LINK).

Implicit dependencies such as Boost::filesystem requiring Boost::system will be automatically detected
and satisfied, even if system is not specified when using find_package() and if Boost::system is not
added to target_link_libraries(). If using Boost::thread, then Threads::Threads will also be added
automatically.

It is important to note that the imported targets behave differently than variables created by this
module: multiple calls to find_package(Boost) in the same directory or sub-directories with different
options (e.g. static or shared) will not override the values of the targets created by the first call.

Other Variables
Boost libraries come in many variants encoded in their file name. Users or projects may tell this module
which variant to find by setting variables:

Boost_USE_DEBUG_LIBS
New in version 3.10.

Set to ON or OFF to specify whether to search and use the debug libraries. Default is ON.

Boost_USE_RELEASE_LIBS
New in version 3.10.

Set to ON or OFF to specify whether to search and use the release libraries. Default is ON.

Boost_USE_MULTITHREADED
Set to OFF to use the non-multithreaded libraries ("mt" tag). Default is ON.

Boost_USE_STATIC_LIBS
Set to ON to force the use of the static libraries. Default is OFF.

Boost_USE_STATIC_RUNTIME
Set to ON or OFF to specify whether to use libraries linked statically to the C++ runtime ("s"
tag). Default is platform dependent.

Boost_USE_DEBUG_RUNTIME
Set to ON or OFF to specify whether to use libraries linked to the MS debug C++ runtime ("g" tag).
Default is ON.

Boost_USE_DEBUG_PYTHON
Set to ON to use libraries compiled with a debug Python build ("y" tag). Default is OFF.

Boost_USE_STLPORT
Set to ON to use libraries compiled with STLPort ("p" tag). Default is OFF.

Boost_USE_STLPORT_DEPRECATED_NATIVE_IOSTREAMS
Set to ON to use libraries compiled with STLPort deprecated "native iostreams" ("n" tag). Default
is OFF.

Boost_COMPILER
Set to the compiler-specific library suffix (e.g. -gcc43). Default is auto-computed for the C++
compiler in use.

Changed in version 3.9: A list may be used if multiple compatible suffixes should be tested for,
in decreasing order of preference.

Boost_LIB_PREFIX
New in version 3.18.

Set to the platform-specific library name prefix (e.g. lib) used by Boost static libs. This is
needed only on platforms where CMake does not know the prefix by default.

Boost_ARCHITECTURE
New in version 3.13.

Set to the architecture-specific library suffix (e.g. -x64). Default is auto-computed for the C++
compiler in use.

Boost_THREADAPI
Suffix for thread component library name, such as pthread or win32. Names with and without this
suffix will both be tried.

Boost_NAMESPACE
Alternate namespace used to build boost with e.g. if set to myboost, will search for
myboost_thread instead of boost_thread.

Other variables one may set to control this module are:

Boost_DEBUG
Set to ON to enable debug output from FindBoost. Please enable this before filing any bug report.

Boost_REALPATH
Set to ON to resolve symlinks for discovered libraries to assist with packaging. For example, the
"system" component library may be resolved to /usr/lib/libboost_system.so.1.67.0 instead of
/usr/lib/libboost_system.so. This does not affect linking and should not be enabled unless the
user needs this information.

Boost_LIBRARY_DIR
Default value for Boost_LIBRARY_DIR_RELEASE and Boost_LIBRARY_DIR_DEBUG.

Boost_NO_WARN_NEW_VERSIONS
New in version 3.20.

Set to ON to suppress the warning about unknown dependencies for new Boost versions.

On Visual Studio and Borland compilers Boost headers request automatic linking to corresponding
libraries. This requires matching libraries to be linked explicitly or available in the link library
search path. In this case setting Boost_USE_STATIC_LIBS to OFF may not achieve dynamic linking. Boost
automatic linking typically requests static libraries with a few exceptions (such as Boost.Python). Use:

add_definitions(${Boost_LIB_DIAGNOSTIC_DEFINITIONS})

to ask Boost to report information about automatic linking requests.

Examples
Find Boost headers only:

find_package(Boost 1.36.0)
if(Boost_FOUND)
include_directories(${Boost_INCLUDE_DIRS})
add_executable(foo foo.cc)
endif()

Find Boost libraries and use imported targets:

find_package(Boost 1.56 REQUIRED COMPONENTS
date_time filesystem iostreams)
add_executable(foo foo.cc)
target_link_libraries(foo Boost::date_time Boost::filesystem
Boost::iostreams)

Find Boost Python 3.6 libraries and use imported targets:

find_package(Boost 1.67 REQUIRED COMPONENTS
python36 numpy36)
add_executable(foo foo.cc)
target_link_libraries(foo Boost::python36 Boost::numpy36)

Find Boost headers and some static (release only) libraries:

set(Boost_USE_STATIC_LIBS ON) # only find static libs
set(Boost_USE_DEBUG_LIBS OFF) # ignore debug libs and
set(Boost_USE_RELEASE_LIBS ON) # only find release libs
set(Boost_USE_MULTITHREADED ON)
set(Boost_USE_STATIC_RUNTIME OFF)
find_package(Boost 1.66.0 COMPONENTS date_time filesystem system ...)
if(Boost_FOUND)
include_directories(${Boost_INCLUDE_DIRS})
add_executable(foo foo.cc)
target_link_libraries(foo ${Boost_LIBRARIES})
endif()

Boost CMake
If Boost was built using the boost-cmake project or from Boost 1.70.0 on it provides a package
configuration file for use with find_package's config mode. This module looks for the package
configuration file called BoostConfig.cmake or boost-config.cmake and stores the result in CACHE entry
Boost_DIR. If found, the package configuration file is loaded and this module returns with no further
action. See documentation of the Boost CMake package configuration for details on what it provides.

Set Boost_NO_BOOST_CMAKE to ON, to disable the search for boost-cmake.

FindBullet
Try to find the Bullet physics engine

This module defines the following variables

BULLET_FOUND - Was bullet found
BULLET_INCLUDE_DIRS - the Bullet include directories
BULLET_LIBRARIES - Link to this, by default it includes
all bullet components (Dynamics,
Collision, LinearMath, & SoftBody)

This module accepts the following variables

BULLET_ROOT - Can be set to bullet install path or Windows build path

FindBZip2
Try to find BZip2

IMPORTED Targets
New in version 3.12.

This module defines IMPORTED target BZip2::BZip2, if BZip2 has been found.

Result Variables
This module defines the following variables:

BZIP2_FOUND
system has BZip2

BZIP2_INCLUDE_DIRS
New in version 3.12: the BZip2 include directories

BZIP2_LIBRARIES
Link these to use BZip2

BZIP2_NEED_PREFIX
this is set if the functions are prefixed with BZ2_

BZIP2_VERSION_STRING
the version of BZip2 found

Cache variables
The following cache variables may also be set:

BZIP2_INCLUDE_DIR
the BZip2 include directory

FindCABLE
Find CABLE

This module finds if CABLE is installed and determines where the include files and libraries are. This
code sets the following variables:

CABLE the path to the cable executable
CABLE_TCL_LIBRARY the path to the Tcl wrapper library
CABLE_INCLUDE_DIR the path to the include directory

To build Tcl wrappers, you should add shared library and link it to ${CABLE_TCL_LIBRARY}. You should
also add ${CABLE_INCLUDE_DIR} as an include directory.

FindCoin3D
Find Coin3D (Open Inventor)

Coin3D is an implementation of the Open Inventor API. It provides data structures and algorithms for 3D
visualization.

This module defines the following variables

COIN3D_FOUND - system has Coin3D - Open Inventor
COIN3D_INCLUDE_DIRS - where the Inventor include directory can be found
COIN3D_LIBRARIES - Link to this to use Coin3D

FindCUDAToolkit
New in version 3.17.

This script locates the NVIDIA CUDA toolkit and the associated libraries, but does not require the CUDA
language be enabled for a given project. This module does not search for the NVIDIA CUDA Samples.

New in version 3.19: QNX support.

Search Behavior
The CUDA Toolkit search behavior uses the following order:

1. If the CUDA language has been enabled we will use the directory containing the compiler as the first
search location for nvcc.

2. If the CUDAToolkit_ROOT cmake configuration variable (e.g., -DCUDAToolkit_ROOT=/some/path) or
environment variable is defined, it will be searched. If both an environment variable and a
configuration variable are specified, the configuration variable takes precedence.

The directory specified here must be such that the executable nvcc or the appropriate version.txt file
can be found underneath the specified directory.

3. If the CUDA_PATH environment variable is defined, it will be searched for nvcc.

4. The user's path is searched for nvcc using find_program(). If this is found, no subsequent search
attempts are performed. Users are responsible for ensuring that the first nvcc to show up in the path
is the desired path in the event that multiple CUDA Toolkits are installed.

5. On Unix systems, if the symbolic link /usr/local/cuda exists, this is used. No subsequent search
attempts are performed. No default symbolic link location exists for the Windows platform.

6. The platform specific default install locations are searched. If exactly one candidate is found, this
is used. The default CUDA Toolkit install locations searched are:

┌───────────┬───────────────────────────────────────┐
│Platform │ Search Pattern │
├───────────┼───────────────────────────────────────┤
│macOS │ /Developer/NVIDIA/CUDA-X.Y │
├───────────┼───────────────────────────────────────┤
│Other Unix │ /usr/local/cuda-X.Y │
├───────────┼───────────────────────────────────────┤
│Windows │ C:\Program Files\NVIDIA GPU Computing │
│ │ Toolkit\CUDA\vX.Y │
└───────────┴───────────────────────────────────────┘

Where X.Y would be a specific version of the CUDA Toolkit, such as /usr/local/cuda-9.0 or C:\Program
Files\NVIDIA GPU Computing Toolkit\CUDA\v9.0

NOTE:
When multiple CUDA Toolkits are installed in the default location of a system (e.g., both
/usr/local/cuda-9.0 and /usr/local/cuda-10.0 exist but the /usr/local/cuda symbolic link does not
exist), this package is marked as not found.

There are too many factors involved in making an automatic decision in the presence of multiple
CUDA Toolkits being installed. In this situation, users are encouraged to either (1) set
CUDAToolkit_ROOT or (2) ensure that the correct nvcc executable shows up in $PATH for
find_program() to find.

Arguments
[<version>]
The [<version>] argument requests a version with which the package found should be compatible. See
find_package version format for more details.

Options
REQUIRED
If specified, configuration will error if a suitable CUDA Toolkit is not found.

QUIET If specified, the search for a suitable CUDA Toolkit will not produce any messages.

EXACT If specified, the CUDA Toolkit is considered found only if the exact VERSION specified is
recovered.

Imported targets
An imported target named CUDA::toolkit is provided.

This module defines IMPORTED targets for each of the following libraries that are part of the
CUDAToolkit:

• CUDA Runtime Library

• CUDA Driver Library

• cuBLAS

• cuFFT

• cuRAND

• cuSOLVER

• cuSPARSE

• cuPTI

• NPP

• nvBLAS

• nvGRAPH

• nvJPEG

• nvidia-ML

• nvRTC

• nvToolsExt

• OpenCL

• cuLIBOS

CUDA Runtime Library
The CUDA Runtime library (cudart) are what most applications will typically need to link against to make
any calls such as cudaMalloc, and cudaFree.

Targets Created:

• CUDA::cudart

• CUDA::cudart_static

CUDA Driver Library
The CUDA Driver library (cuda) are used by applications that use calls such as cuMemAlloc, and cuMemFree.
This is generally used by advanced

Targets Created:

• CUDA::cuda_driver

cuBLAS
The cuBLAS library.

Targets Created:

• CUDA::cublas

• CUDA::cublas_static

• CUDA::cublasLt starting in CUDA 10.1

• CUDA::cublasLt_static starting in CUDA 10.1

cuFFT
The cuFFT library.

Targets Created:

• CUDA::cufft

• CUDA::cufftw

• CUDA::cufft_static

• CUDA::cufftw_static

cuRAND
The cuRAND library.

Targets Created:

• CUDA::curand

• CUDA::curand_static

cuSOLVER
The cuSOLVER library.

Targets Created:

• CUDA::cusolver

• CUDA::cusolver_static

cuSPARSE
The cuSPARSE library.

Targets Created:

• CUDA::cusparse

• CUDA::cusparse_static

cupti
The NVIDIA CUDA Profiling Tools Interface.

Targets Created:

• CUDA::cupti

• CUDA::cupti_static

NPP
The NPP libraries.

Targets Created:

• nppc:

• CUDA::nppc

• CUDA::nppc_static

• nppial: Arithmetic and logical operation functions in nppi_arithmetic_and_logical_operations.h

• CUDA::nppial

• CUDA::nppial_static

• nppicc: Color conversion and sampling functions in nppi_color_conversion.h

• CUDA::nppicc

• CUDA::nppicc_static

• nppicom: JPEG compression and decompression functions in nppi_compression_functions.h Removed starting
in CUDA 11.0, use nvJPEG instead.

• CUDA::nppicom

• CUDA::nppicom_static

• nppidei: Data exchange and initialization functions in nppi_data_exchange_and_initialization.h

• CUDA::nppidei

• CUDA::nppidei_static

• nppif: Filtering and computer vision functions in nppi_filter_functions.h

• CUDA::nppif

• CUDA::nppif_static

• nppig: Geometry transformation functions found in nppi_geometry_transforms.h

• CUDA::nppig

• CUDA::nppig_static

• nppim: Morphological operation functions found in nppi_morphological_operations.h

• CUDA::nppim

• CUDA::nppim_static

• nppist: Statistics and linear transform in nppi_statistics_functions.h and nppi_linear_transforms.h

• CUDA::nppist

• CUDA::nppist_static

• nppisu: Memory support functions in nppi_support_functions.h

• CUDA::nppisu

• CUDA::nppisu_static

• nppitc: Threshold and compare operation functions in nppi_threshold_and_compare_operations.h

• CUDA::nppitc

• CUDA::nppitc_static

• npps:

• CUDA::npps

• CUDA::npps_static

nvBLAS
The nvBLAS libraries. This is a shared library only.

Targets Created:

• CUDA::nvblas

nvGRAPH
The nvGRAPH library. Removed starting in CUDA 11.0

Targets Created:

• CUDA::nvgraph

• CUDA::nvgraph_static

nvJPEG
The nvJPEG library. Introduced in CUDA 10.

Targets Created:

• CUDA::nvjpeg

• CUDA::nvjpeg_static

nvRTC
The nvRTC (Runtime Compilation) library. This is a shared library only.

Targets Created:

• CUDA::nvrtc

nvidia-ML
The NVIDIA Management Library. This is a shared library only.

Targets Created:

• CUDA::nvml

nvToolsExt
The NVIDIA Tools Extension. This is a shared library only.

Targets Created:

• CUDA::nvToolsExt

OpenCL
The NVIDIA OpenCL Library. This is a shared library only.

Targets Created:

• CUDA::OpenCL

cuLIBOS
The cuLIBOS library is a backend thread abstraction layer library which is static only. The
CUDA::cublas_static, CUDA::cusparse_static, CUDA::cufft_static, CUDA::curand_static, and (when
implemented) NPP libraries all automatically have this dependency linked.

Target Created:

• CUDA::culibos

Note: direct usage of this target by consumers should not be necessary.

Result variables
CUDAToolkit_FOUND
A boolean specifying whether or not the CUDA Toolkit was found.

CUDAToolkit_VERSION
The exact version of the CUDA Toolkit found (as reported by nvcc --version or version.txt).

CUDAToolkit_VERSION_MAJOR
The major version of the CUDA Toolkit.

CUDAToolkit_VERSION_MINOR
The minor version of the CUDA Toolkit.

CUDAToolkit_VERSION_PATCH
The patch version of the CUDA Toolkit.

CUDAToolkit_BIN_DIR
The path to the CUDA Toolkit library directory that contains the CUDA executable nvcc.

CUDAToolkit_INCLUDE_DIRS
The path to the CUDA Toolkit include folder containing the header files required to compile a
project linking against CUDA.

CUDAToolkit_LIBRARY_DIR
The path to the CUDA Toolkit library directory that contains the CUDA Runtime library cudart.

CUDAToolkit_LIBRARY_ROOT
New in version 3.18.

The path to the CUDA Toolkit directory containing the nvvm directory and version.txt.

CUDAToolkit_TARGET_DIR
The path to the CUDA Toolkit directory including the target architecture when cross-compiling.
When not cross-compiling this will be equivalent to the parent directory of CUDAToolkit_BIN_DIR.

CUDAToolkit_NVCC_EXECUTABLE
The path to the NVIDIA CUDA compiler nvcc. Note that this path may not be the same as
CMAKE_CUDA_COMPILER. nvcc must be found to determine the CUDA Toolkit version as well as
determining other features of the Toolkit. This variable is set for the convenience of modules
that depend on this one.

FindCups
Find the Common UNIX Printing System (CUPS).

Set CUPS_REQUIRE_IPP_DELETE_ATTRIBUTE to TRUE if you need a version which features this function (i.e. at
least 1.1.19)

Imported targets
New in version 3.15.

This module defines IMPORTED target Cups::Cups, if Cups has been found.

Result variables
This module will set the following variables in your project:

CUPS_FOUND
true if CUPS headers and libraries were found

CUPS_INCLUDE_DIRS
the directory containing the Cups headers

CUPS_LIBRARIES
the libraries to link against to use CUPS.

CUPS_VERSION_STRING
the version of CUPS found (since CMake 2.8.8)

Cache variables
The following cache variables may also be set:

CUPS_INCLUDE_DIR
the directory containing the Cups headers

FindCURL
Find the native CURL headers and libraries.

New in version 3.14: This module accept optional COMPONENTS to check supported features and protocols:

PROTOCOLS: ICT FILE FTP FTPS GOPHER HTTP HTTPS IMAP IMAPS LDAP LDAPS POP3
POP3S RTMP RTSP SCP SFTP SMB SMBS SMTP SMTPS TELNET TFTP
FEATURES: SSL IPv6 UnixSockets libz AsynchDNS IDN GSS-API PSL SPNEGO
Kerberos NTLM NTLM_WB TLS-SRP HTTP2 HTTPS-proxy

IMPORTED Targets
New in version 3.12.

This module defines IMPORTED target CURL::libcurl, if curl has been found.

Result Variables
This module defines the following variables:

CURL_FOUND
"True" if curl found.

CURL_INCLUDE_DIRS
where to find curl/curl.h, etc.

CURL_LIBRARIES
List of libraries when using curl.

CURL_VERSION_STRING
The version of curl found.

New in version 3.13: Debug and Release variants are found separately.

CURL CMake
New in version 3.17.

If CURL was built using the CMake buildsystem then it provides its own CURLConfig.cmake file for use with
the find_package() command's config mode. This module looks for this file and, if found, returns its
results with no further action.

Set CURL_NO_CURL_CMAKE to ON to disable this search.

FindCurses
Find the curses or ncurses include file and library.

Result Variables
This module defines the following variables:

CURSES_FOUND
True if Curses is found.

CURSES_INCLUDE_DIRS
The include directories needed to use Curses.

CURSES_LIBRARIES
The libraries needed to use Curses.

CURSES_CFLAGS
New in version 3.16.

Parameters which ought be given to C/C++ compilers when using Curses.

CURSES_HAVE_CURSES_H
True if curses.h is available.

CURSES_HAVE_NCURSES_H
True if ncurses.h is available.

CURSES_HAVE_NCURSES_NCURSES_H
True if ncurses/ncurses.h is available.

CURSES_HAVE_NCURSES_CURSES_H
True if ncurses/curses.h is available.

Set CURSES_NEED_NCURSES to TRUE before the find_package(Curses) call if NCurses functionality is
required.

New in version 3.10: Set CURSES_NEED_WIDE to TRUE before the find_package(Curses) call if unicode
functionality is required.

Backward Compatibility
The following variable are provided for backward compatibility:

CURSES_INCLUDE_DIR
Path to Curses include. Use CURSES_INCLUDE_DIRS instead.

CURSES_LIBRARY
Path to Curses library. Use CURSES_LIBRARIES instead.

FindCVS
Find the Concurrent Versions System (CVS).

The module defines the following variables:

CVS_EXECUTABLE - path to cvs command line client
CVS_FOUND - true if the command line client was found

Example usage:

find_package(CVS)
if(CVS_FOUND)
message("CVS found: ${CVS_EXECUTABLE}")
endif()

FindCxxTest
Find CxxTest unit testing framework.

Find the CxxTest suite and declare a helper macro for creating unit tests and integrating them with
CTest. For more details on CxxTest see http://cxxtest.tigris.org

INPUT Variables

CXXTEST_USE_PYTHON [deprecated since 1.3]
Only used in the case both Python & Perl
are detected on the system to control
which CxxTest code generator is used.
Valid only for CxxTest version 3.

NOTE: In older versions of this Find Module,
this variable controlled if the Python test
generator was used instead of the Perl one,
regardless of which scripting language the
user had installed.

CXXTEST_TESTGEN_ARGS (since CMake 2.8.3)
Specify a list of options to pass to the CxxTest code
generator. If not defined, --error-printer is
passed.

OUTPUT Variables

CXXTEST_FOUND
True if the CxxTest framework was found
CXXTEST_INCLUDE_DIRS
Where to find the CxxTest include directory
CXXTEST_PERL_TESTGEN_EXECUTABLE
The perl-based test generator
CXXTEST_PYTHON_TESTGEN_EXECUTABLE
The python-based test generator
CXXTEST_TESTGEN_EXECUTABLE (since CMake 2.8.3)
The test generator that is actually used (chosen using user preferences
and interpreters found in the system)
CXXTEST_TESTGEN_INTERPRETER (since CMake 2.8.3)
The full path to the Perl or Python executable on the system, on
platforms where the script cannot be executed using its shebang line.

MACROS for optional use by CMake users:

CXXTEST_ADD_TEST(<test_name> <gen_source_file> <input_files_to_testgen...>)
Creates a CxxTest runner and adds it to the CTest testing suite
Parameters:
test_name The name of the test
gen_source_file The generated source filename to be
generated by CxxTest
input_files_to_testgen The list of header files containing the
CxxTest::TestSuite's to be included in
this runner

#==============
Example Usage:

find_package(CxxTest)
if(CXXTEST_FOUND)
include_directories(${CXXTEST_INCLUDE_DIR})
enable_testing()

CXXTEST_ADD_TEST(unittest_foo foo_test.cc
${CMAKE_CURRENT_SOURCE_DIR}/foo_test.h)
target_link_libraries(unittest_foo foo) # as needed
endif()

This will (if CxxTest is found):
1. Invoke the testgen executable to autogenerate foo_test.cc in the
binary tree from "foo_test.h" in the current source directory.
2. Create an executable and test called unittest_foo.

#=============
Example foo_test.h:

#include <cxxtest/TestSuite.h>

class MyTestSuite : public CxxTest::TestSuite
{
public:
void testAddition( void )
{
TS_ASSERT( 1 + 1 > 1 );
TS_ASSERT_EQUALS( 1 + 1, 2 );
}
};

FindCygwin
Find Cygwin, a POSIX-compatible environment that runs natively on Microsoft Windows

FindDart
Find DART

This module looks for the dart testing software and sets DART_ROOT to point to where it found it.

FindDCMTK
Find DICOM ToolKit (DCMTK) libraries and applications

The module defines the following variables:

DCMTK_INCLUDE_DIRS - Directories to include to use DCMTK
DCMTK_LIBRARIES - Files to link against to use DCMTK
DCMTK_FOUND - If false, don't try to use DCMTK
DCMTK_DIR - (optional) Source directory for DCMTK

Compatibility
This module is able to find a version of DCMTK that does or does not export a DCMTKConfig.cmake file. It
applies a two step process:

• Step 1: Attempt to find DCMTK version providing a DCMTKConfig.cmake file.

• Step 2: If step 1 failed, rely on FindDCMTK.cmake to set DCMTK_* variables details below.

Recent DCMTK provides a DCMTKConfig.cmake package configuration file. To exclusively use the package
configuration file (recommended when possible), pass the NO_MODULE option to find_package(). For example,
find_package(DCMTK NO_MODULE). This requires official DCMTK snapshot 3.6.1_20140617 or newer.

Until all clients update to the more recent DCMTK, build systems will need to support different versions
of DCMTK.

On any given system, the following combinations of DCMTK versions could be considered:

┌───────┬─────────────────┬─────────────────┬─────────────┐
│ │ SYSTEM DCMTK │ LOCAL DCMTK │ Supported ? │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case A │ NA │ [ ] DCMTKConfig │ YES │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case B │ NA │ [X] DCMTKConfig │ YES │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case C │ [ ] DCMTKConfig │ NA │ YES │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case D │ [X] DCMTKConfig │ NA │ YES │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case E │ [ ] DCMTKConfig │ [ ] DCMTKConfig │ YES (*) │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case F │ [X] DCMTKConfig │ [ ] DCMTKConfig │ NO │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case G │ [ ] DCMTKConfig │ [X] DCMTKConfig │ YES │
├───────┼─────────────────┼─────────────────┼─────────────┤
│Case H │ [X] DCMTKConfig │ [X] DCMTKConfig │ YES │
└───────┴─────────────────┴─────────────────┴─────────────┘
(*) See Troubleshooting section.

Legend:
NA ...............: Means that no System or Local DCMTK is available

[ ] DCMTKConfig ..: Means that the version of DCMTK does NOT export a DCMTKConfig.cmake file.

[X] DCMTKConfig ..: Means that the version of DCMTK exports a DCMTKConfig.cmake file.

Troubleshooting
What to do if my project finds a different version of DCMTK?

Remove DCMTK entry from the CMake cache per find_package() documentation.

FindDevIL
This module locates the developer's image library. http://openil.sourceforge.net/

IMPORTED Targets
New in version 3.21.

This module defines the IMPORTED targets:

DevIL::IL
Defined if the system has DevIL.

DevIL::ILU
Defined if the system has DevIL Utilities.

DevIL::ILUT
Defined if the system has DevIL Utility Toolkit.

Result Variables
This module sets:

IL_LIBRARIES
The name of the IL library. These include the full path to the core DevIL library. This one has to
be linked into the application.

ILU_LIBRARIES
The name of the ILU library. Again, the full path. This library is for filters and effects, not
actual loading. It doesn't have to be linked if the functionality it provides is not used.

ILUT_LIBRARIES
The name of the ILUT library. Full path. This part of the library interfaces with OpenGL. It is
not strictly needed in applications.

IL_INCLUDE_DIR
where to find the il.h, ilu.h and ilut.h files.

DevIL_FOUND
This is set to TRUE if all the above variables were set. This will be set to false if ILU or ILUT
are not found, even if they are not needed. In most systems, if one library is found all the
others are as well. That's the way the DevIL developers release it.

DevIL_ILUT_FOUND
New in version 3.21.

This is set to TRUE if the ILUT library is found.

FindDoxygen
Doxygen is a documentation generation tool (see http://www.doxygen.org). This module looks for Doxygen
and some optional tools it supports:

dot Graphviz dot utility used to render various graphs.

mscgen Message Chart Generator utility used by Doxygen's \msc and \mscfile commands.

dia Dia the diagram editor used by Doxygen's \diafile command.

New in version 3.9: These tools are available as components in the find_package() command. For example:

# Require dot, treat the other components as optional
find_package(Doxygen
REQUIRED dot
OPTIONAL_COMPONENTS mscgen dia)

The following variables are defined by this module:

DOXYGEN_FOUND
True if the doxygen executable was found.

DOXYGEN_VERSION
The version reported by doxygen --version.

New in version 3.9: The module defines IMPORTED targets for Doxygen and each component found. These can
be used as part of custom commands, etc. and should be preferred over old-style (and now deprecated)
variables like DOXYGEN_EXECUTABLE. The following import targets are defined if their corresponding
executable could be found (the component import targets will only be defined if that component was
requested):

Doxygen::doxygen
Doxygen::dot
Doxygen::mscgen
Doxygen::dia

Functions
doxygen_add_docs
New in version 3.9.

This function is intended as a convenience for adding a target for generating documentation with
Doxygen. It aims to provide sensible defaults so that projects can generally just provide the
input files and directories and that will be sufficient to give sensible results. The function
supports the ability to customize the Doxygen configuration used to build the documentation.

doxygen_add_docs(targetName
[filesOrDirs...]
[ALL]
[USE_STAMP_FILE]
[WORKING_DIRECTORY dir]
[COMMENT comment])

The function constructs a Doxyfile and defines a custom target that runs Doxygen on that generated
file. The listed files and directories are used as the INPUT of the generated Doxyfile and they
can contain wildcards. Any files that are listed explicitly will also be added as SOURCES of the
custom target so they will show up in an IDE project's source list.

So that relative input paths work as expected, by default the working directory of the Doxygen
command will be the current source directory (i.e. CMAKE_CURRENT_SOURCE_DIR). This can be
overridden with the WORKING_DIRECTORY option to change the directory used as the relative base
point. Note also that Doxygen's default behavior is to strip the working directory from relative
paths in the generated documentation (see the STRIP_FROM_PATH Doxygen config option for details).

If provided, the optional comment will be passed as the COMMENT for the add_custom_target()
command used to create the custom target internally.

New in version 3.12: If ALL is set, the target will be added to the default build target.

New in version 3.16: If USE_STAMP_FILE is set, the custom command defined by this function will
create a stamp file with the name <targetName>.stamp in the current binary directory whenever
doxygen is re-run. With this option present, all items in <filesOrDirs> must be files (i.e. no
directories, symlinks or wildcards) and each of the files must exist at the time
doxygen_add_docs() is called. An error will be raised if any of the items listed is missing or is
not a file when USE_STAMP_FILE is given. A dependency will be created on each of the files so
that doxygen will only be re-run if one of the files is updated. Without the USE_STAMP_FILE
option, doxygen will always be re-run if the <targetName> target is built regardless of whether
anything listed in <filesOrDirs> has changed.

The contents of the generated Doxyfile can be customized by setting CMake variables before calling
doxygen_add_docs(). Any variable with a name of the form DOXYGEN_<tag> will have its value
substituted for the corresponding <tag> configuration option in the Doxyfile. See the Doxygen
documentation for the full list of supported configuration options.

Some of Doxygen's defaults are overridden to provide more appropriate behavior for a CMake
project. Each of the following will be explicitly set unless the variable already has a value
before doxygen_add_docs() is called (with some exceptions noted):

DOXYGEN_HAVE_DOT
Set to YES if the dot component was requested and it was found, NO otherwise. Any existing
value of DOXYGEN_HAVE_DOT is ignored.

DOXYGEN_DOT_MULTI_TARGETS
Set to YES by this module (note that this requires a dot version newer than 1.8.10). This
option is only meaningful if DOXYGEN_HAVE_DOT is also set to YES.

DOXYGEN_GENERATE_LATEX
Set to NO by this module.

DOXYGEN_WARN_FORMAT
For Visual Studio based generators, this is set to the form recognized by the Visual Studio
IDE: $file($line) : $text. For all other generators, Doxygen's default value is not
overridden.

DOXYGEN_PROJECT_NAME
Populated with the name of the current project (i.e. PROJECT_NAME).

DOXYGEN_PROJECT_NUMBER
Populated with the version of the current project (i.e. PROJECT_VERSION).

DOXYGEN_PROJECT_BRIEF
Populated with the description of the current project (i.e. PROJECT_DESCRIPTION).

DOXYGEN_INPUT
Projects should not set this variable. It will be populated with the set of files and
directories passed to doxygen_add_docs(), thereby providing consistent behavior with the
other built-in commands like add_executable(), add_library() and add_custom_target(). If a
variable named DOXYGEN_INPUT is set by the project, it will be ignored and a warning will
be issued.

DOXYGEN_RECURSIVE
Set to YES by this module.

DOXYGEN_EXCLUDE_PATTERNS
If the set of inputs includes directories, this variable will specify patterns used to
exclude files from them. The following patterns are added by doxygen_add_docs() to ensure
CMake-specific files and directories are not included in the input. If the project sets
DOXYGEN_EXCLUDE_PATTERNS, those contents are merged with these additional patterns rather
than replacing them:

*/.git/*
*/.svn/*
*/.hg/*
*/CMakeFiles/*
*/_CPack_Packages/*
DartConfiguration.tcl
CMakeLists.txt
CMakeCache.txt

DOXYGEN_OUTPUT_DIRECTORY
Set to CMAKE_CURRENT_BINARY_DIR by this module. Note that if the project provides its own
value for this and it is a relative path, it will be converted to an absolute path relative
to the current binary directory. This is necessary because doxygen will normally be run
from a directory within the source tree so that relative source paths work as expected. If
this directory does not exist, it will be recursively created prior to executing the
doxygen commands.

To change any of these defaults or override any other Doxygen config option, set relevant variables
before calling doxygen_add_docs(). For example:

set(DOXYGEN_GENERATE_HTML NO)
set(DOXYGEN_GENERATE_MAN YES)

doxygen_add_docs(
doxygen
${PROJECT_SOURCE_DIR}
COMMENT "Generate man pages"
)

A number of Doxygen config options accept lists of values, but Doxygen requires them to be separated by
whitespace. CMake variables hold lists as a string with items separated by semi-colons, so a conversion
needs to be performed. The doxygen_add_docs() command specifically checks the following Doxygen config
options and will convert their associated CMake variable's contents into the required form if set. CMake
variables are named DOXYGEN_<name> for the Doxygen settings specified here.

ABBREVIATE_BRIEF
ALIASES
CITE_BIB_FILES
DIAFILE_DIRS
DOTFILE_DIRS
DOT_FONTPATH
ENABLED_SECTIONS
EXAMPLE_PATH
EXAMPLE_PATTERNS
EXCLUDE
EXCLUDE_PATTERNS
EXCLUDE_SYMBOLS
EXPAND_AS_DEFINED
EXTENSION_MAPPING
EXTRA_PACKAGES
EXTRA_SEARCH_MAPPINGS
FILE_PATTERNS
FILTER_PATTERNS
FILTER_SOURCE_PATTERNS
HTML_EXTRA_FILES
HTML_EXTRA_STYLESHEET
IGNORE_PREFIX
IMAGE_PATH
INCLUDE_FILE_PATTERNS
INCLUDE_PATH
INPUT
LATEX_EXTRA_FILES
LATEX_EXTRA_STYLESHEET
MATHJAX_EXTENSIONS
MSCFILE_DIRS
PLANTUML_INCLUDE_PATH
PREDEFINED
QHP_CUST_FILTER_ATTRS
QHP_SECT_FILTER_ATTRS
STRIP_FROM_INC_PATH
STRIP_FROM_PATH
TAGFILES
TCL_SUBST

The following single value Doxygen options will be quoted automatically if they contain at least one
space:

CHM_FILE
DIA_PATH
DOCBOOK_OUTPUT
DOCSET_FEEDNAME
DOCSET_PUBLISHER_NAME
DOT_FONTNAME
DOT_PATH
EXTERNAL_SEARCH_ID
FILE_VERSION_FILTER
GENERATE_TAGFILE
HHC_LOCATION
HTML_FOOTER
HTML_HEADER
HTML_OUTPUT
HTML_STYLESHEET
INPUT_FILTER
LATEX_FOOTER
LATEX_HEADER
LATEX_OUTPUT
LAYOUT_FILE
MAN_OUTPUT
MAN_SUBDIR
MATHJAX_CODEFILE
MSCGEN_PATH
OUTPUT_DIRECTORY
PERL_PATH
PLANTUML_JAR_PATH
PROJECT_BRIEF
PROJECT_LOGO
PROJECT_NAME
QCH_FILE
QHG_LOCATION
QHP_CUST_FILTER_NAME
QHP_VIRTUAL_FOLDER
RTF_EXTENSIONS_FILE
RTF_OUTPUT
RTF_STYLESHEET_FILE
SEARCHDATA_FILE
USE_MDFILE_AS_MAINPAGE
WARN_FORMAT
WARN_LOGFILE
XML_OUTPUT

New in version 3.11: There are situations where it may be undesirable for a particular config option to
be automatically quoted by doxygen_add_docs(), such as ALIASES which may need to include its own embedded
quoting. The DOXYGEN_VERBATIM_VARS variable can be used to specify a list of Doxygen variables
(including the leading DOXYGEN_ prefix) which should not be quoted. The project is then responsible for
ensuring that those variables' values make sense when placed directly in the Doxygen input file. In the
case of list variables, list items are still separated by spaces, it is only the automatic quoting that
is skipped. For example, the following allows doxygen_add_docs() to apply quoting to
DOXYGEN_PROJECT_BRIEF, but not each item in the DOXYGEN_ALIASES list (bracket syntax can also be used to
make working with embedded quotes easier):

set(DOXYGEN_PROJECT_BRIEF "String with spaces")
set(DOXYGEN_ALIASES
[[somealias="@some_command param"]]
"anotherAlias=@foobar"
)
set(DOXYGEN_VERBATIM_VARS DOXYGEN_ALIASES)

The resultant Doxyfile will contain the following lines:

PROJECT_BRIEF = "String with spaces"
ALIASES = somealias="@some_command param" anotherAlias=@foobar

Deprecated Result Variables
Deprecated since version 3.9.

For compatibility with previous versions of CMake, the following variables are also defined but they are
deprecated and should no longer be used:

DOXYGEN_EXECUTABLE
The path to the doxygen command. If projects need to refer to the doxygen executable directly,
they should use the Doxygen::doxygen import target instead.

DOXYGEN_DOT_FOUND
True if the dot executable was found.

DOXYGEN_DOT_EXECUTABLE
The path to the dot command. If projects need to refer to the dot executable directly, they should
use the Doxygen::dot import target instead.

DOXYGEN_DOT_PATH
The path to the directory containing the dot executable as reported in DOXYGEN_DOT_EXECUTABLE. The
path may have forward slashes even on Windows and is not suitable for direct substitution into a
Doxyfile.in template. If you need this value, get the IMPORTED_LOCATION property of the
Doxygen::dot target and use get_filename_component() to extract the directory part of that path.
You may also want to consider using file(TO_NATIVE_PATH) to prepare the path for a Doxygen
configuration file.

Deprecated Hint Variables
Deprecated since version 3.9.

DOXYGEN_SKIP_DOT
This variable has no effect for the component form of find_package. In backward compatibility
mode (i.e. without components list) it prevents the finder module from searching for Graphviz's
dot utility.

FindEnvModules
New in version 3.15.

Locate an environment module implementation and make commands available to CMake scripts to use them.
This is compatible with both Lua-based Lmod and TCL-based EnvironmentModules.

This module is intended for the use case of setting up the compiler and library environment within a
CTest Script (ctest -S). It can also be used in a CMake Script (cmake -P).

NOTE:
The loaded environment will not survive past the end of the calling process. Do not use this module
in project code (CMakeLists.txt files) to load a compiler environment; it will not be available during
the build. Instead load the environment manually before running CMake or using the generated build
system.

Example Usage
set(CTEST_BUILD_NAME "CrayLinux-CrayPE-Cray-dynamic")
set(CTEST_BUILD_CONFIGURATION Release)
set(CTEST_BUILD_FLAGS "-k -j8")
set(CTEST_CMAKE_GENERATOR "Unix Makefiles")

...

find_package(EnvModules REQUIRED)

env_module(purge)
env_module(load modules)
env_module(load craype)
env_module(load PrgEnv-cray)
env_module(load craype-knl)
env_module(load cray-mpich)
env_module(load cray-libsci)

set(ENV{CRAYPE_LINK_TYPE} dynamic)

...

Result Variables
This module will set the following variables in your project:

EnvModules_FOUND
True if a compatible environment modules framework was found.

Cache Variables
The following cache variable will be set:

EnvModules_COMMAND
The low level module command to use. Currently supported implementations are the Lua based Lmod
and TCL based EnvironmentModules.

Environment Variables
ENV{MODULESHOME}
Usually set by the module environment implementation, used as a hint to locate the module command
to execute.

Provided Functions
This defines the following CMake functions for interacting with environment modules:

env_module
Execute an aribitrary module command:

env_module(cmd arg1 ... argN)
env_module(
COMMAND cmd arg1 ... argN
[OUTPUT_VARIABLE <out-var>]
[RESULT_VARIABLE <ret-var>]
)

The options are:

cmd arg1 ... argN
The module sub-command and arguments to execute as if they were passed directly to the
module command in your shell environment.

OUTPUT_VARIABLE <out-var>
The standard output from executing the module command.

RESULT_VARIABLE <ret-var>
The return code from executing the module command.

env_module_swap
Swap one module for another:

env_module_swap(out_mod in_mod
[OUTPUT_VARIABLE <out-var>]
[RESULT_VARIABLE <ret-var>]
)

This is functionally equivalent to the module swap out_mod in_mod shell command. The options are:

OUTPUT_VARIABLE <out-var>
The standard output from executing the module command.

RESULT_VARIABLE <ret-var>
The return code from executing the module command.

env_module_list
Retrieve the list of currently loaded modules:

env_module_list(<out-var>)

This is functionally equivalent to the module list shell command. The result is stored in
<out-var> as a properly formatted CMake semicolon-separated list variable.

env_module_avail
Retrieve the list of available modules:

env_module_avail([<mod-prefix>] <out-var>)

This is functionally equivalent to the module avail <mod-prefix> shell command. The result is
stored in <out-var> as a properly formatted CMake semicolon-separated list variable.

FindEXPAT
Find the native Expat headers and library. Expat is a stream-oriented XML parser library written in C.

Imported Targets
New in version 3.10.

This module defines the following IMPORTED targets:

EXPAT::EXPAT
The Expat expat library, if found.

Result Variables
This module will set the following variables in your project:

EXPAT_INCLUDE_DIRS
where to find expat.h, etc.

EXPAT_LIBRARIES
the libraries to link against to use Expat.

EXPAT_FOUND
true if the Expat headers and libraries were found.

FindFLEX
Find Fast Lexical Analyzer (Flex) executable and provides a macro to generate custom build rules

The module defines the following variables:

FLEX_FOUND - True is flex executable is found
FLEX_EXECUTABLE - the path to the flex executable
FLEX_VERSION - the version of flex
FLEX_LIBRARIES - The flex libraries
FLEX_INCLUDE_DIRS - The path to the flex headers

The minimum required version of flex can be specified using the standard syntax, e.g. find_package(FLEX
2.5.13)

If flex is found on the system, the module provides the macro:

FLEX_TARGET(Name FlexInput FlexOutput
[COMPILE_FLAGS <string>]
[DEFINES_FILE <string>]
)

which creates a custom command to generate the FlexOutput file from the FlexInput file. Name is an alias
used to get details of this custom command. If COMPILE_FLAGS option is specified, the next parameter is
added to the flex command line.

New in version 3.5: If flex is configured to output a header file, the DEFINES_FILE option may be used to
specify its name.

Changed in version 3.17: When CMP0098 is set to NEW, flex runs in the CMAKE_CURRENT_BINARY_DIR directory.

The macro defines the following variables:

FLEX_${Name}_DEFINED - true is the macro ran successfully
FLEX_${Name}_OUTPUTS - the source file generated by the custom rule, an
alias for FlexOutput
FLEX_${Name}_INPUT - the flex source file, an alias for ${FlexInput}
FLEX_${Name}_OUTPUT_HEADER - the header flex output, if any.

Flex scanners often use tokens defined by Bison: the code generated by Flex depends of the header
generated by Bison. This module also defines a macro:

ADD_FLEX_BISON_DEPENDENCY(FlexTarget BisonTarget)

which adds the required dependency between a scanner and a parser where FlexTarget and BisonTarget are
the first parameters of respectively FLEX_TARGET and BISON_TARGET macros.

====================================================================
Example:

find_package(BISON)
find_package(FLEX)

BISON_TARGET(MyParser parser.y ${CMAKE_CURRENT_BINARY_DIR}/parser.cpp)
FLEX_TARGET(MyScanner lexer.l ${CMAKE_CURRENT_BINARY_DIR}/lexer.cpp)
ADD_FLEX_BISON_DEPENDENCY(MyScanner MyParser)

include_directories(${CMAKE_CURRENT_BINARY_DIR})
add_executable(Foo
Foo.cc
${BISON_MyParser_OUTPUTS}
${FLEX_MyScanner_OUTPUTS}
)
target_link_libraries(Foo ${FLEX_LIBRARIES})
====================================================================

FindFLTK
Find the Fast Light Toolkit (FLTK) library

Input Variables
By default this module will search for all of the FLTK components and add them to the FLTK_LIBRARIES
variable. You can limit the components which get placed in FLTK_LIBRARIES by defining one or more of the
following three options:

FLTK_SKIP_OPENGL
Set to true to disable searching for the FLTK GL library

FLTK_SKIP_FORMS
Set to true to disable searching for the FLTK Forms library

FLTK_SKIP_IMAGES
Set to true to disable searching for the FLTK Images library

FLTK is composed also by a binary tool. You can set the following option:

FLTK_SKIP_FLUID
Set to true to not look for the FLUID binary

Result Variables
The following variables will be defined:

FLTK_FOUND
True if all components not skipped were found

FLTK_INCLUDE_DIR
Path to the include directory for FLTK header files

FLTK_LIBRARIES
List of the FLTK libraries found

FLTK_FLUID_EXECUTABLE
Path to the FLUID binary tool

FLTK_WRAP_UI
True if FLUID is found, used to enable the FLTK_WRAP_UI command

Cache Variables
The following cache variables are also available to set or use:

FLTK_BASE_LIBRARY_RELEASE
The FLTK base library (optimized)

FLTK_BASE_LIBRARY_DEBUG
The FLTK base library (debug)

FLTK_GL_LIBRARY_RELEASE
The FLTK GL library (optimized)

FLTK_GL_LIBRARY_DEBUG
The FLTK GL library (debug)

FLTK_FORMS_LIBRARY_RELEASE
The FLTK Forms library (optimized)

FLTK_FORMS_LIBRARY_DEBUG
The FLTK Forms library (debug)

FLTK_IMAGES_LIBRARY_RELEASE
The FLTK Images protobuf library (optimized)

FLTK_IMAGES_LIBRARY_DEBUG
The FLTK Images library (debug)

New in version 3.11: Debug and Release variants are found separately and use per-configuration variables.

FindFLTK2
Find the native FLTK 2.0 includes and library

The following settings are defined

FLTK2_FLUID_EXECUTABLE, where to find the Fluid tool
FLTK2_WRAP_UI, This enables the FLTK2_WRAP_UI command
FLTK2_INCLUDE_DIR, where to find include files
FLTK2_LIBRARIES, list of fltk2 libraries
FLTK2_FOUND, Don't use FLTK2 if false.

The following settings should not be used in general.

FLTK2_BASE_LIBRARY = the full path to fltk2.lib
FLTK2_GL_LIBRARY = the full path to fltk2_gl.lib
FLTK2_IMAGES_LIBRARY = the full path to fltk2_images.lib

FindFontconfig
New in version 3.14.

Find Fontconfig headers and library.

Imported Targets
Fontconfig::Fontconfig
The Fontconfig library, if found.

Result Variables
This will define the following variables in your project:

Fontconfig_FOUND
true if (the requested version of) Fontconfig is available.

Fontconfig_VERSION
the version of Fontconfig.

Fontconfig_LIBRARIES
the libraries to link against to use Fontconfig.

Fontconfig_INCLUDE_DIRS
where to find the Fontconfig headers.

Fontconfig_COMPILE_OPTIONS
this should be passed to target_compile_options(), if the target is not used for linking

FindFreetype
Find the FreeType font renderer includes and library.

Imported Targets
New in version 3.10.

This module defines the following IMPORTED target:

Freetype::Freetype
The Freetype freetype library, if found

Result Variables
This module will set the following variables in your project:

FREETYPE_FOUND
true if the Freetype headers and libraries were found

FREETYPE_INCLUDE_DIRS
directories containing the Freetype headers. This is the concatenation of the variables:

FREETYPE_INCLUDE_DIR_ft2build
directory holding the main Freetype API configuration header

FREETYPE_INCLUDE_DIR_freetype2
directory holding Freetype public headers

FREETYPE_LIBRARIES
the library to link against

FREETYPE_VERSION_STRING
the version of freetype found

New in version 3.7: Debug and Release variants are found separately.

Hints
The user may set the environment variable FREETYPE_DIR to the root directory of a Freetype installation.

FindGCCXML
Find the GCC-XML front-end executable.

This module will define the following variables:

GCCXML - the GCC-XML front-end executable.

FindGDAL
Find Geospatial Data Abstraction Library (GDAL).

IMPORTED Targets
New in version 3.14.

This module defines IMPORTED target GDAL::GDAL if GDAL has been found.

Result Variables
This module will set the following variables in your project:

GDAL_FOUND
True if GDAL is found.

GDAL_INCLUDE_DIRS
Include directories for GDAL headers.

GDAL_LIBRARIES
Libraries to link to GDAL.

GDAL_VERSION
New in version 3.14: The version of GDAL found.

Cache variables
The following cache variables may also be set:

GDAL_LIBRARY
The libgdal library file.

GDAL_INCLUDE_DIR
The directory containing gdal.h.

Hints
Set GDAL_DIR or GDAL_ROOT in the environment to specify the GDAL installation prefix.

The following variables may be set to modify the search strategy:

FindGDAL_SKIP_GDAL_CONFIG
If set, gdal-config will not be used. This can be useful if there are GDAL libraries built with
autotools (which provide the tool) and CMake (which do not) in the same environment.

GDAL_ADDITIONAL_LIBRARY_VERSIONS
Extra versions of library names to search for.

FindGettext
Find GNU gettext tools

This module looks for the GNU gettext tools. This module defines the following values:

GETTEXT_MSGMERGE_EXECUTABLE: the full path to the msgmerge tool.
GETTEXT_MSGFMT_EXECUTABLE: the full path to the msgfmt tool.
GETTEXT_FOUND: True if gettext has been found.
GETTEXT_VERSION_STRING: the version of gettext found (since CMake 2.8.8)

Additionally it provides the following macros:

GETTEXT_CREATE_TRANSLATIONS ( outputFile [ALL] file1 ... fileN )

This will create a target "translations" which will convert the
given input po files into the binary output mo file. If the
ALL option is used, the translations will also be created when
building the default target.

GETTEXT_PROCESS_POT_FILE( <potfile> [ALL] [INSTALL_DESTINATION <destdir>] LANGUAGES <lang1> <lang2> ...
)

Process the given pot file to mo files.
If INSTALL_DESTINATION is given then automatically install rules will
be created, the language subdirectory will be taken into account
(by default use share/locale/).
If ALL is specified, the pot file is processed when building the all target.
It creates a custom target "potfile".

GETTEXT_PROCESS_PO_FILES( <lang> [ALL] [INSTALL_DESTINATION <dir>] PO_FILES <po1> <po2> ... )

Process the given po files to mo files for the given language.
If INSTALL_DESTINATION is given then automatically install rules will
be created, the language subdirectory will be taken into account
(by default use share/locale/).
If ALL is specified, the po files are processed when building the all target.
It creates a custom target "pofiles".

New in version 3.2: If you wish to use the Gettext library (libintl), use FindIntl.

FindGIF
This finds the Graphics Interchange Format (GIF) library (giflib)

Imported targets
This module defines the following IMPORTED target:

GIF::GIF
The giflib library, if found.

Result variables
This module will set the following variables in your project:

GIF_FOUND
If false, do not try to use GIF.

GIF_INCLUDE_DIRS
where to find gif_lib.h, etc.

GIF_LIBRARIES
the libraries needed to use GIF.

GIF_VERSION
3, 4 or a full version string (eg 5.1.4) for versions >= 4.1.6.

Cache variables
The following cache variables may also be set:

GIF_INCLUDE_DIR
where to find the GIF headers.

GIF_LIBRARY
where to find the GIF library.

Hints
GIF_DIR is an environment variable that would correspond to the ./configure --prefix=$GIF_DIR.

FindGit
The module defines the following variables:

GIT_EXECUTABLE
Path to Git command-line client.

Git_FOUND, GIT_FOUND
True if the Git command-line client was found.

GIT_VERSION_STRING
The version of Git found.

New in version 3.14: The module defines the following IMPORTED targets (when CMAKE_ROLE is PROJECT):

Git::Git
Executable of the Git command-line client.

Example usage:

find_package(Git)
if(Git_FOUND)
message("Git found: ${GIT_EXECUTABLE}")
endif()

FindGLEW
Find the OpenGL Extension Wrangler Library (GLEW)

Input Variables
The following variables may be set to influence this module's behavior:

GLEW_USE_STATIC_LIBS
to find and create IMPORTED target for static linkage.

GLEW_VERBOSE
to output a detailed log of this module.

Imported Targets
New in version 3.1.

This module defines the following Imported Targets:

GLEW::glew
The GLEW shared library.

GLEW::glew_s
The GLEW static library, if GLEW_USE_STATIC_LIBS is set to TRUE.

GLEW::GLEW
Duplicates either GLEW::glew or GLEW::glew_s based on availability.

Result Variables
This module defines the following variables:

GLEW_INCLUDE_DIRS
include directories for GLEW

GLEW_LIBRARIES
libraries to link against GLEW

GLEW_SHARED_LIBRARIES
libraries to link against shared GLEW

GLEW_STATIC_LIBRARIES
libraries to link against static GLEW

GLEW_FOUND
true if GLEW has been found and can be used

GLEW_VERSION
GLEW version

GLEW_VERSION_MAJOR
GLEW major version

GLEW_VERSION_MINOR
GLEW minor version

GLEW_VERSION_MICRO
GLEW micro version

New in version 3.7: Debug and Release variants are found separately.

FindGLUT
Find OpenGL Utility Toolkit (GLUT) library and include files.

IMPORTED Targets
New in version 3.1.

This module defines the IMPORTED targets:

GLUT::GLUT
Defined if the system has GLUT.

Result Variables
This module sets the following variables:

GLUT_INCLUDE_DIR, where to find GL/glut.h, etc.
GLUT_LIBRARIES, the libraries to link against
GLUT_FOUND, If false, do not try to use GLUT.

Also defined, but not for general use are:

GLUT_glut_LIBRARY = the full path to the glut library.
GLUT_Xmu_LIBRARY = the full path to the Xmu library.
GLUT_Xi_LIBRARY = the full path to the Xi Library.

New in version 3.13: Debug and Release variants are found separately.

FindGnuplot
this module looks for gnuplot

Once done this will define

GNUPLOT_FOUND - system has Gnuplot
GNUPLOT_EXECUTABLE - the Gnuplot executable
GNUPLOT_VERSION_STRING - the version of Gnuplot found (since CMake 2.8.8)

GNUPLOT_VERSION_STRING will not work for old versions like 3.7.1.

FindGnuTLS
Find the GNU Transport Layer Security library (gnutls)

IMPORTED Targets
New in version 3.16.

This module defines IMPORTED target GnuTLS::GnuTLS, if gnutls has been found.

Result Variables
GNUTLS_FOUND
System has gnutls

GNUTLS_INCLUDE_DIR
The gnutls include directory

GNUTLS_LIBRARIES
The libraries needed to use gnutls

GNUTLS_DEFINITIONS
Compiler switches required for using gnutls

GNUTLS_VERSION
version of gnutls.

FindGSL
New in version 3.2.

Find the native GNU Scientific Library (GSL) includes and libraries.

The GNU Scientific Library (GSL) is a numerical library for C and C++ programmers. It is free software
under the GNU General Public License.

Imported Targets
If GSL is found, this module defines the following IMPORTED targets:

GSL::gsl - The main GSL library.
GSL::gslcblas - The CBLAS support library used by GSL.

Result Variables
This module will set the following variables in your project:

GSL_FOUND - True if GSL found on the local system
GSL_INCLUDE_DIRS - Location of GSL header files.
GSL_LIBRARIES - The GSL libraries.
GSL_VERSION - The version of the discovered GSL install.

Hints
Set GSL_ROOT_DIR to a directory that contains a GSL installation.

This script expects to find libraries at $GSL_ROOT_DIR/lib and the GSL headers at
$GSL_ROOT_DIR/include/gsl. The library directory may optionally provide Release and Debug folders. If
available, the libraries named gsld, gslblasd or cblasd are recognized as debug libraries. For Unix-like
systems, this script will use $GSL_ROOT_DIR/bin/gsl-config (if found) to aid in the discovery of GSL.

Cache Variables
This module may set the following variables depending on platform and type of GSL installation
discovered. These variables may optionally be set to help this module find the correct files:

GSL_CBLAS_LIBRARY - Location of the GSL CBLAS library.
GSL_CBLAS_LIBRARY_DEBUG - Location of the debug GSL CBLAS library (if any).
GSL_CONFIG_EXECUTABLE - Location of the ``gsl-config`` script (if any).
GSL_LIBRARY - Location of the GSL library.
GSL_LIBRARY_DEBUG - Location of the debug GSL library (if any).

FindGTest
Locate the Google C++ Testing Framework.

New in version 3.20: Upstream GTestConfig.cmake is used if possible.

Imported targets
New in version 3.20: This module defines the following IMPORTED targets:

GTest::gtest
The Google Test gtest library, if found; adds Thread::Thread automatically

GTest::gtest_main
The Google Test gtest_main library, if found

New in version 3.23.

GTest::gmock
The Google Mock gmock library, if found; adds Thread::Thread automatically

GTest::gmock_main
The Google Mock gmock_main library, if found

Deprecated since version 3.20: For backwards compatibility, this module defines additionally the
following deprecated IMPORTED targets (available since 3.5):

GTest::GTest
The Google Test gtest library, if found; adds Thread::Thread automatically

GTest::Main
The Google Test gtest_main library, if found

Result variables
This module will set the following variables in your project:

GTest_FOUND
Found the Google Testing framework

GTEST_INCLUDE_DIRS
the directory containing the Google Test headers

The library variables below are set as normal variables. These contain debug/optimized keywords when a
debugging library is found.

GTEST_LIBRARIES
The Google Test gtest library; note it also requires linking with an appropriate thread library

GTEST_MAIN_LIBRARIES
The Google Test gtest_main library

GTEST_BOTH_LIBRARIES
Both gtest and gtest_main

Cache variables
The following cache variables may also be set:

GTEST_ROOT
The root directory of the Google Test installation (may also be set as an environment variable)

GTEST_MSVC_SEARCH
If compiling with MSVC, this variable can be set to MT or MD (the default) to enable searching a
GTest build tree

Example usage
enable_testing()
find_package(GTest REQUIRED)

add_executable(foo foo.cc)
target_link_libraries(foo GTest::gtest GTest::gtest_main)

add_test(AllTestsInFoo foo)

Deeper integration with CTest
See GoogleTest for information on the gtest_add_tests() and gtest_discover_tests() commands.

Changed in version 3.9: Previous CMake versions defined gtest_add_tests() macro in this module.

FindGTK
Find GTK, glib and GTKGLArea

GTK_INCLUDE_DIR - Directories to include to use GTK
GTK_LIBRARIES - Files to link against to use GTK
GTK_FOUND - GTK was found
GTK_GL_FOUND - GTK's GL features were found

FindGTK2
Find the GTK2 widget libraries and several of its other optional components like gtkmm, glade, and
glademm.

Specify one or more of the following components as you call this find module. See example below.

• gtk

• gtkmm

• glade

• glademm

Imported Targets
This module defines the following IMPORTED targets (subject to component selection):

GTK2::atk, GTK2::atkmm, GTK2::cairo, GTK2::cairomm, GTK2::gdk_pixbuf, GTK2::gdk, GTK2::gdkmm, GTK2::gio,
GTK2::giomm, GTK2::glade, GTK2::glademm, GTK2::glib, GTK2::glibmm, GTK2::gmodule, GTK2::gobject,
GTK2::gthread, GTK2::gtk, GTK2::gtkmm, GTK2::harfbuzz, GTK2::pango, GTK2::pangocairo, GTK2::pangoft2,
GTK2::pangomm, GTK2::pangoxft, GTK2::sigc.

New in version 3.16.7: Added the GTK2::harfbuzz target.

Result Variables
The following variables will be defined for your use

GTK2_FOUND
Were all of your specified components found?

GTK2_INCLUDE_DIRS
All include directories

GTK2_LIBRARIES
All libraries

GTK2_TARGETS
New in version 3.5: All imported targets

GTK2_DEFINITIONS
Additional compiler flags

GTK2_VERSION
The version of GTK2 found (x.y.z)

GTK2_MAJOR_VERSION
The major version of GTK2

GTK2_MINOR_VERSION
The minor version of GTK2

GTK2_PATCH_VERSION
The patch version of GTK2

New in version 3.5: When GTK2_USE_IMPORTED_TARGETS is set to TRUE, GTK2_LIBRARIES will list imported
targets instead of library paths.

Input Variables
Optional variables you can define prior to calling this module:

GTK2_DEBUG
Enables verbose debugging of the module

GTK2_ADDITIONAL_SUFFIXES
Allows defining additional directories to search for include files

Example Usage
Call find_package() once. Here are some examples to pick from:

Require GTK 2.6 or later:

find_package(GTK2 2.6 REQUIRED gtk)

Require GTK 2.10 or later and Glade:

find_package(GTK2 2.10 REQUIRED gtk glade)

Search for GTK/GTKMM 2.8 or later:

find_package(GTK2 2.8 COMPONENTS gtk gtkmm)

Use the results:

if(GTK2_FOUND)
include_directories(${GTK2_INCLUDE_DIRS})
add_executable(mygui mygui.cc)
target_link_libraries(mygui ${GTK2_LIBRARIES})
endif()

FindHDF5
Find Hierarchical Data Format (HDF5), a library for reading and writing self describing array data.

This module invokes the HDF5 wrapper compiler that should be installed alongside HDF5. Depending upon
the HDF5 Configuration, the wrapper compiler is called either h5cc or h5pcc. If this succeeds, the
module will then call the compiler with the show argument to see what flags are used when compiling an
HDF5 client application.

The module will optionally accept the COMPONENTS argument. If no COMPONENTS are specified, then the find
module will default to finding only the HDF5 C library. If one or more COMPONENTS are specified, the
module will attempt to find the language bindings for the specified components. The valid components are
C, CXX, Fortran, HL. HL refers to the "high-level" HDF5 functions for C and Fortran. If the COMPONENTS
argument is not given, the module will attempt to find only the C bindings. For example, to use Fortran
HDF5 and HDF5-HL functions, do: find_package(HDF5 COMPONENTS Fortran HL).

This module will read the variable HDF5_USE_STATIC_LIBRARIES to determine whether or not to prefer a
static link to a dynamic link for HDF5 and all of it's dependencies. To use this feature, make sure that
the HDF5_USE_STATIC_LIBRARIES variable is set before the call to find_package.

New in version 3.10: Support for HDF5_USE_STATIC_LIBRARIES on Windows.

Both the serial and parallel HDF5 wrappers are considered and the first directory to contain either one
will be used. In the event that both appear in the same directory the serial version is preferentially
selected. This behavior can be reversed by setting the variable HDF5_PREFER_PARALLEL to TRUE.

In addition to finding the includes and libraries required to compile an HDF5 client application, this
module also makes an effort to find tools that come with the HDF5 distribution that may be useful for
regression testing.

Result Variables
This module will set the following variables in your project:

HDF5_FOUND
HDF5 was found on the system

HDF5_VERSION
New in version 3.3: HDF5 library version

HDF5_INCLUDE_DIRS
Location of the HDF5 header files

HDF5_DEFINITIONS
Required compiler definitions for HDF5

HDF5_LIBRARIES
Required libraries for all requested bindings

HDF5_HL_LIBRARIES
Required libraries for the HDF5 high level API for all bindings, if the HL component is enabled

Available components are: C CXX Fortran and HL. For each enabled language binding, a corresponding
HDF5_${LANG}_LIBRARIES variable, and potentially HDF5_${LANG}_DEFINITIONS, will be defined. If the HL
component is enabled, then an HDF5_${LANG}_HL_LIBRARIES will also be defined. With all components
enabled, the following variables will be defined:

HDF5_C_DEFINITIONS
Required compiler definitions for HDF5 C bindings

HDF5_CXX_DEFINITIONS
Required compiler definitions for HDF5 C++ bindings

HDF5_Fortran_DEFINITIONS
Required compiler definitions for HDF5 Fortran bindings

HDF5_C_INCLUDE_DIRS
Required include directories for HDF5 C bindings

HDF5_CXX_INCLUDE_DIRS
Required include directories for HDF5 C++ bindings

HDF5_Fortran_INCLUDE_DIRS
Required include directories for HDF5 Fortran bindings

HDF5_C_LIBRARIES
Required libraries for the HDF5 C bindings

HDF5_CXX_LIBRARIES
Required libraries for the HDF5 C++ bindings

HDF5_Fortran_LIBRARIES
Required libraries for the HDF5 Fortran bindings

HDF5_C_HL_LIBRARIES
Required libraries for the high level C bindings

HDF5_CXX_HL_LIBRARIES
Required libraries for the high level C++ bindings

HDF5_Fortran_HL_LIBRARIES
Required libraries for the high level Fortran bindings.

HDF5_IS_PARALLEL
HDF5 library has parallel IO support

HDF5_C_COMPILER_EXECUTABLE
path to the HDF5 C wrapper compiler

HDF5_CXX_COMPILER_EXECUTABLE
path to the HDF5 C++ wrapper compiler

HDF5_Fortran_COMPILER_EXECUTABLE
path to the HDF5 Fortran wrapper compiler

HDF5_C_COMPILER_EXECUTABLE_NO_INTERROGATE
path to the primary C compiler which is also the HDF5 wrapper

HDF5_CXX_COMPILER_EXECUTABLE_NO_INTERROGATE
path to the primary C++ compiler which is also the HDF5 wrapper

HDF5_Fortran_COMPILER_EXECUTABLE_NO_INTERROGATE
path to the primary Fortran compiler which is also the HDF5 wrapper

HDF5_DIFF_EXECUTABLE
path to the HDF5 dataset comparison tool

With all components enabled, the following targets will be defined:

HDF5::HDF5
All detected HDF5_LIBRARIES.

hdf5::hdf5
C library.

hdf5::hdf5_cpp
C++ library.

hdf5::hdf5_fortran
Fortran library.

hdf5::hdf5_hl
High-level C library.

hdf5::hdf5_hl_cpp
High-level C++ library.

hdf5::hdf5_hl_fortran
High-level Fortran library.

hdf5::h5diff
h5diff executable.

Hints
The following variables can be set to guide the search for HDF5 libraries and includes:

HDF5_PREFER_PARALLEL
New in version 3.4.

set true to prefer parallel HDF5 (by default, serial is preferred)

HDF5_FIND_DEBUG
New in version 3.9.

Set true to get extra debugging output.

HDF5_NO_FIND_PACKAGE_CONFIG_FILE
New in version 3.8.

Set true to skip trying to find hdf5-config.cmake.

FindHg
Extract information from a mercurial working copy.

The module defines the following variables:

HG_EXECUTABLE - path to mercurial command line client (hg)
HG_FOUND - true if the command line client was found
HG_VERSION_STRING - the version of mercurial found

New in version 3.1: If the command line client executable is found the following macro is defined:

HG_WC_INFO(<dir> <var-prefix>)

Hg_WC_INFO extracts information of a mercurial working copy at a given location. This macro defines the
following variables:

<var-prefix>_WC_CHANGESET - current changeset
<var-prefix>_WC_REVISION - current revision

Example usage:

find_package(Hg)
if(HG_FOUND)
message("hg found: ${HG_EXECUTABLE}")
HG_WC_INFO(${PROJECT_SOURCE_DIR} Project)
message("Current revision is ${Project_WC_REVISION}")
message("Current changeset is ${Project_WC_CHANGESET}")
endif()

FindHSPELL
Try to find Hebrew spell-checker (Hspell) and morphology engine.

Once done this will define

HSPELL_FOUND - system has Hspell
HSPELL_INCLUDE_DIR - the Hspell include directory
HSPELL_LIBRARIES - The libraries needed to use Hspell
HSPELL_DEFINITIONS - Compiler switches required for using Hspell

HSPELL_VERSION_STRING - The version of Hspell found (x.y)
HSPELL_MAJOR_VERSION - the major version of Hspell
HSPELL_MINOR_VERSION - The minor version of Hspell

FindHTMLHelp
This module looks for Microsoft HTML Help Compiler

It defines:

HTML_HELP_COMPILER : full path to the Compiler (hhc.exe)
HTML_HELP_INCLUDE_PATH : include path to the API (htmlhelp.h)
HTML_HELP_LIBRARY : full path to the library (htmlhelp.lib)

FindIce
New in version 3.1.

Find the ZeroC Internet Communication Engine (ICE) programs, libraries and datafiles.

This module supports multiple components. Components can include any of: Freeze, Glacier2, Ice, IceBox,
IceDB, IceDiscovery, IceGrid, IceLocatorDiscovery, IcePatch, IceSSL, IceStorm, IceUtil, IceXML, or Slice.

Ice 3.7 and later also include C++11-specific components: Glacier2++11, Ice++11, IceBox++11,
IceDiscovery++11 IceGrid, IceLocatorDiscovery++11, IceSSL++11, IceStorm++11

Note that the set of supported components is Ice version-specific.

New in version 3.4: Imported targets for components and most EXECUTABLE variables.

New in version 3.7: Debug and Release variants are found separately.

New in version 3.10: Ice 3.7 support, including new components, programs and the Nuget package.

This module reports information about the Ice installation in several variables. General variables:

Ice_VERSION - Ice release version
Ice_FOUND - true if the main programs and libraries were found
Ice_LIBRARIES - component libraries to be linked
Ice_INCLUDE_DIRS - the directories containing the Ice headers
Ice_SLICE_DIRS - the directories containing the Ice slice interface
definitions

Imported targets:

Ice::<C>

Where <C> is the name of an Ice component, for example Ice::Glacier2 or Ice++11.

Ice slice programs are reported in:

Ice_SLICE2CONFLUENCE_EXECUTABLE - path to slice2confluence executable
Ice_SLICE2CPP_EXECUTABLE - path to slice2cpp executable
Ice_SLICE2CS_EXECUTABLE - path to slice2cs executable
Ice_SLICE2FREEZEJ_EXECUTABLE - path to slice2freezej executable
Ice_SLICE2FREEZE_EXECUTABLE - path to slice2freeze executable
Ice_SLICE2HTML_EXECUTABLE - path to slice2html executable
Ice_SLICE2JAVA_EXECUTABLE - path to slice2java executable
Ice_SLICE2JS_EXECUTABLE - path to slice2js executable
Ice_SLICE2MATLAB_EXECUTABLE - path to slice2matlab executable
Ice_SLICE2OBJC_EXECUTABLE - path to slice2objc executable
Ice_SLICE2PHP_EXECUTABLE - path to slice2php executable
Ice_SLICE2PY_EXECUTABLE - path to slice2py executable
Ice_SLICE2RB_EXECUTABLE - path to slice2rb executable

New in version 3.14: Variables for slice2confluence and slice2matlab.

Ice programs are reported in:

Ice_GLACIER2ROUTER_EXECUTABLE - path to glacier2router executable
Ice_ICEBOX_EXECUTABLE - path to icebox executable
Ice_ICEBOXXX11_EXECUTABLE - path to icebox++11 executable
Ice_ICEBOXADMIN_EXECUTABLE - path to iceboxadmin executable
Ice_ICEBOXD_EXECUTABLE - path to iceboxd executable
Ice_ICEBOXNET_EXECUTABLE - path to iceboxnet executable
Ice_ICEBRIDGE_EXECUTABLE - path to icebridge executable
Ice_ICEGRIDADMIN_EXECUTABLE - path to icegridadmin executable
Ice_ICEGRIDDB_EXECUTABLE - path to icegriddb executable
Ice_ICEGRIDNODE_EXECUTABLE - path to icegridnode executable
Ice_ICEGRIDNODED_EXECUTABLE - path to icegridnoded executable
Ice_ICEGRIDREGISTRY_EXECUTABLE - path to icegridregistry executable
Ice_ICEGRIDREGISTRYD_EXECUTABLE - path to icegridregistryd executable
Ice_ICEPATCH2CALC_EXECUTABLE - path to icepatch2calc executable
Ice_ICEPATCH2CLIENT_EXECUTABLE - path to icepatch2client executable
Ice_ICEPATCH2SERVER_EXECUTABLE - path to icepatch2server executable
Ice_ICESERVICEINSTALL_EXECUTABLE - path to iceserviceinstall executable
Ice_ICESTORMADMIN_EXECUTABLE - path to icestormadmin executable
Ice_ICESTORMDB_EXECUTABLE - path to icestormdb executable
Ice_ICESTORMMIGRATE_EXECUTABLE - path to icestormmigrate executable

Ice db programs (Windows only; standard system versions on all other platforms) are reported in:

Ice_DB_ARCHIVE_EXECUTABLE - path to db_archive executable
Ice_DB_CHECKPOINT_EXECUTABLE - path to db_checkpoint executable
Ice_DB_DEADLOCK_EXECUTABLE - path to db_deadlock executable
Ice_DB_DUMP_EXECUTABLE - path to db_dump executable
Ice_DB_HOTBACKUP_EXECUTABLE - path to db_hotbackup executable
Ice_DB_LOAD_EXECUTABLE - path to db_load executable
Ice_DB_LOG_VERIFY_EXECUTABLE - path to db_log_verify executable
Ice_DB_PRINTLOG_EXECUTABLE - path to db_printlog executable
Ice_DB_RECOVER_EXECUTABLE - path to db_recover executable
Ice_DB_STAT_EXECUTABLE - path to db_stat executable
Ice_DB_TUNER_EXECUTABLE - path to db_tuner executable
Ice_DB_UPGRADE_EXECUTABLE - path to db_upgrade executable
Ice_DB_VERIFY_EXECUTABLE - path to db_verify executable
Ice_DUMPDB_EXECUTABLE - path to dumpdb executable
Ice_TRANSFORMDB_EXECUTABLE - path to transformdb executable

Ice component libraries are reported in:

Ice_<C>_FOUND - ON if component was found
Ice_<C>_LIBRARIES - libraries for component

Note that <C> is the uppercased name of the component.

This module reads hints about search results from:

Ice_HOME - the root of the Ice installation

The environment variable ICE_HOME may also be used; the Ice_HOME variable takes precedence.

NOTE:
On Windows, Ice 3.7.0 and later provide libraries via the NuGet package manager. Appropriate NuGet
packages will be searched for using CMAKE_PREFIX_PATH, or alternatively Ice_HOME may be set to the
location of a specific NuGet package to restrict the search.

The following cache variables may also be set:

Ice_<P>_EXECUTABLE - the path to executable <P>
Ice_INCLUDE_DIR - the directory containing the Ice headers
Ice_SLICE_DIR - the directory containing the Ice slice interface
definitions
Ice_<C>_LIBRARY - the library for component <C>

NOTE:
In most cases none of the above variables will require setting, unless multiple Ice versions are
available and a specific version is required. On Windows, the most recent version of Ice will be
found through the registry. On Unix, the programs, headers and libraries will usually be in standard
locations, but Ice_SLICE_DIRS might not be automatically detected (commonly known locations are
searched). All the other variables are defaulted using Ice_HOME, if set. It's possible to set
Ice_HOME and selectively specify alternative locations for the other components; this might be
required for e.g. newer versions of Visual Studio if the heuristics are not sufficient to identify the
correct programs and libraries for the specific Visual Studio version.

Other variables one may set to control this module are:

Ice_DEBUG - Set to ON to enable debug output from FindIce.

FindIconv
New in version 3.11.

This module finds the iconv() POSIX.1 functions on the system. These functions might be provided in the
regular C library or externally in the form of an additional library.

The following variables are provided to indicate iconv support:

Iconv_FOUND
Variable indicating if the iconv support was found.

Iconv_INCLUDE_DIRS
The directories containing the iconv headers.

Iconv_LIBRARIES
The iconv libraries to be linked.

Iconv_VERSION
New in version 3.21.

The version of iconv found (x.y)

Iconv_VERSION_MAJOR
New in version 3.21.

The major version of iconv

Iconv_VERSION_MINOR
New in version 3.21.

The minor version of iconv

Iconv_IS_BUILT_IN
A variable indicating whether iconv support is stemming from the C library or not. Even if the C
library provides iconv(), the presence of an external libiconv implementation might lead to this
being false.

Additionally, the following IMPORTED target is being provided:

Iconv::Iconv
Imported target for using iconv.

The following cache variables may also be set:

Iconv_INCLUDE_DIR
The directory containing the iconv headers.

Iconv_LIBRARY
The iconv library (if not implicitly given in the C library).

NOTE:
On POSIX platforms, iconv might be part of the C library and the cache variables Iconv_INCLUDE_DIR and
Iconv_LIBRARY might be empty.

NOTE:
Some libiconv implementations don't embed the version number in their header files. In this case the
variables Iconv_VERSION* will be empty.

FindIcotool
Find icotool

This module looks for icotool. Convert and create Win32 icon and cursor files. This module defines the
following values:

ICOTOOL_EXECUTABLE: the full path to the icotool tool.
ICOTOOL_FOUND: True if icotool has been found.
ICOTOOL_VERSION_STRING: the version of icotool found.

FindICU
New in version 3.7.

Find the International Components for Unicode (ICU) libraries and programs.

This module supports multiple components. Components can include any of: data, i18n, io, le, lx, test,
tu and uc.

Note that on Windows data is named dt and i18n is named in; any of the names may be used, and the
appropriate platform-specific library name will be automatically selected.

New in version 3.11: Added support for static libraries on Windows.

This module reports information about the ICU installation in several variables. General variables:

ICU_VERSION - ICU release version
ICU_FOUND - true if the main programs and libraries were found
ICU_LIBRARIES - component libraries to be linked
ICU_INCLUDE_DIRS - the directories containing the ICU headers

Imported targets:

ICU::<C>

Where <C> is the name of an ICU component, for example ICU::i18n; <C> is lower-case.

ICU programs are reported in:

ICU_GENCNVAL_EXECUTABLE - path to gencnval executable
ICU_ICUINFO_EXECUTABLE - path to icuinfo executable
ICU_GENBRK_EXECUTABLE - path to genbrk executable
ICU_ICU-CONFIG_EXECUTABLE - path to icu-config executable
ICU_GENRB_EXECUTABLE - path to genrb executable
ICU_GENDICT_EXECUTABLE - path to gendict executable
ICU_DERB_EXECUTABLE - path to derb executable
ICU_PKGDATA_EXECUTABLE - path to pkgdata executable
ICU_UCONV_EXECUTABLE - path to uconv executable
ICU_GENCFU_EXECUTABLE - path to gencfu executable
ICU_MAKECONV_EXECUTABLE - path to makeconv executable
ICU_GENNORM2_EXECUTABLE - path to gennorm2 executable
ICU_GENCCODE_EXECUTABLE - path to genccode executable
ICU_GENSPREP_EXECUTABLE - path to gensprep executable
ICU_ICUPKG_EXECUTABLE - path to icupkg executable
ICU_GENCMN_EXECUTABLE - path to gencmn executable

ICU component libraries are reported in:

ICU_<C>_FOUND - ON if component was found; ``<C>`` is upper-case.
ICU_<C>_LIBRARIES - libraries for component; ``<C>`` is upper-case.

ICU datafiles are reported in:

ICU_MAKEFILE_INC - Makefile.inc
ICU_PKGDATA_INC - pkgdata.inc

This module reads hints about search results from:

ICU_ROOT - the root of the ICU installation

The environment variable ICU_ROOT may also be used; the ICU_ROOT variable takes precedence.

The following cache variables may also be set:

ICU_<P>_EXECUTABLE - the path to executable <P>; ``<P>`` is upper-case.
ICU_INCLUDE_DIR - the directory containing the ICU headers
ICU_<C>_LIBRARY - the library for component <C>; ``<C>`` is upper-case.

NOTE:
In most cases none of the above variables will require setting, unless multiple ICU versions are
available and a specific version is required.

Other variables one may set to control this module are:

ICU_DEBUG - Set to ON to enable debug output from FindICU.

FindImageMagick
Find ImageMagick binary suite.

New in version 3.9: Added support for ImageMagick 7.

This module will search for a set of ImageMagick tools specified as components in the find_package()
call. Typical components include, but are not limited to (future versions of ImageMagick might have
additional components not listed here):

animate
compare
composite
conjure
convert
display
identify
import
mogrify
montage
stream

If no component is specified in the find_package() call, then it only searches for the ImageMagick
executable directory. This code defines the following variables:

ImageMagick_FOUND - TRUE if all components are found.
ImageMagick_EXECUTABLE_DIR - Full path to executables directory.
ImageMagick_<component>_FOUND - TRUE if <component> is found.
ImageMagick_<component>_EXECUTABLE - Full path to <component> executable.
ImageMagick_VERSION_STRING - the version of ImageMagick found
(since CMake 2.8.8)

ImageMagick_VERSION_STRING will not work for old versions like 5.2.3.

There are also components for the following ImageMagick APIs:

Magick++
MagickWand
MagickCore

For these components the following variables are set:

ImageMagick_FOUND - TRUE if all components are found.
ImageMagick_INCLUDE_DIRS - Full paths to all include dirs.
ImageMagick_LIBRARIES - Full paths to all libraries.
ImageMagick_<component>_FOUND - TRUE if <component> is found.
ImageMagick_<component>_INCLUDE_DIRS - Full path to <component> include dirs.
ImageMagick_<component>_LIBRARIES - Full path to <component> libraries.

Example Usages:

find_package(ImageMagick)
find_package(ImageMagick COMPONENTS convert)
find_package(ImageMagick COMPONENTS convert mogrify display)
find_package(ImageMagick COMPONENTS Magick++)
find_package(ImageMagick COMPONENTS Magick++ convert)

Note that the standard find_package() features are supported (i.e., QUIET, REQUIRED, etc.).

FindIntl
New in version 3.2.

Find the Gettext libintl headers and libraries.

This module reports information about the Gettext libintl installation in several variables.

Intl_FOUND
True if libintl is found.

Intl_INCLUDE_DIRS
The directory containing the libintl headers.

Intl_LIBRARIES
The intl libraries to be linked.

Intl_VERSION
New in version 3.21.

The version of intl found (x.y.z)

Intl_VERSION_MAJOR
New in version 3.21.

The major version of intl

Intl_VERSION_MINOR
New in version 3.21.

The minor version of intl

Intl_VERSION_PATCH
New in version 3.21.

The patch version of intl

New in version 3.20: This module defines IMPORTED target Intl::Intl.

The following cache variables may also be set:

Intl_INCLUDE_DIR
The directory containing the libintl headers

Intl_LIBRARY
The libintl library (if any)

Intl_IS_BUILT_IN
New in version 3.20.

whether intl is a part of the C library.

NOTE:
On some platforms, such as Linux with GNU libc, the gettext functions are present in the C standard
library and libintl is not required. Intl_LIBRARIES will be empty in this case.

NOTE:
Some libintl implementations don't embed the version number in their header files. In this case the
variables Intl_VERSION* will be empty.

NOTE:
If you wish to use the Gettext tools (msgmerge, msgfmt, etc.), use FindGettext.

FindITK
This module no longer exists.

This module existed in versions of CMake prior to 3.1, but became only a thin wrapper around
find_package(ITK NO_MODULE) to provide compatibility for projects using long-outdated conventions. Now
find_package(ITK) will search for ITKConfig.cmake directly.

FindJasper
Find the Jasper JPEG2000 library.

IMPORTED Targets
Jasper::Jasper
The jasper library, if found.

Result Variables
This module defines the following variables:

JASPER_FOUND
system has Jasper

JASPER_INCLUDE_DIRS
New in version 3.22.

the Jasper include directory

JASPER_LIBRARIES
the libraries needed to use Jasper

JASPER_VERSION_STRING
the version of Jasper found

Cache variables
The following cache variables may also be set:

JASPER_INCLUDE_DIR
where to find jasper/jasper.h, etc.

JASPER_LIBRARY_RELEASE
where to find the Jasper library (optimized).

JASPER_LIBARRY_DEBUG
where to find the Jasper library (debug).

FindJava
Find Java

This module finds if Java is installed and determines where the include files and libraries are. The
caller may set variable JAVA_HOME to specify a Java installation prefix explicitly.

See also the FindJNI module to find Java Native Interface (JNI).

New in version 3.10: Added support for Java 9+ version parsing.

Specify one or more of the following components as you call this find module. See example below.

Runtime = Java Runtime Environment used to execute Java byte-compiled applications
Development = Development tools (java, javac, javah, jar and javadoc), includes Runtime component
IdlJ = Interface Description Language (IDL) to Java compiler
JarSigner = Signer and verifier tool for Java Archive (JAR) files

This module sets the following result variables:

Java_JAVA_EXECUTABLE = the full path to the Java runtime
Java_JAVAC_EXECUTABLE = the full path to the Java compiler
Java_JAVAH_EXECUTABLE = the full path to the Java header generator
Java_JAVADOC_EXECUTABLE = the full path to the Java documentation generator
Java_IDLJ_EXECUTABLE = the full path to the Java idl compiler
Java_JAR_EXECUTABLE = the full path to the Java archiver
Java_JARSIGNER_EXECUTABLE = the full path to the Java jar signer
Java_VERSION_STRING = Version of java found, eg. 1.6.0_12
Java_VERSION_MAJOR = The major version of the package found.
Java_VERSION_MINOR = The minor version of the package found.
Java_VERSION_PATCH = The patch version of the package found.
Java_VERSION_TWEAK = The tweak version of the package found (after '_')
Java_VERSION = This is set to: $major[.$minor[.$patch[.$tweak]]]

New in version 3.4: Added the Java_IDLJ_EXECUTABLE and Java_JARSIGNER_EXECUTABLE variables.

The minimum required version of Java can be specified using the find_package() syntax, e.g.

find_package(Java 1.8)

NOTE: ${Java_VERSION} and ${Java_VERSION_STRING} are not guaranteed to be identical. For example some
java version may return: Java_VERSION_STRING = 1.8.0_17 and Java_VERSION = 1.8.0.17

another example is the Java OEM, with: Java_VERSION_STRING = 1.8.0-oem and Java_VERSION = 1.8.0

For these components the following variables are set:

Java_FOUND - TRUE if all components are found.
Java_<component>_FOUND - TRUE if <component> is found.

Example Usages:

find_package(Java)
find_package(Java 1.8 REQUIRED)
find_package(Java COMPONENTS Runtime)
find_package(Java COMPONENTS Development)

FindJNI
Find Java Native Interface (JNI) libraries.

JNI enables Java code running in a Java Virtual Machine (JVM) to call and be called by native
applications and libraries written in other languages such as C, C++.

This module finds if Java is installed and determines where the include files and libraries are. It also
determines what the name of the library is. The caller may set variable JAVA_HOME to specify a Java
installation prefix explicitly.

Result Variables
This module sets the following result variables:

JNI_INCLUDE_DIRS
the include dirs to use

JNI_LIBRARIES
the libraries to use (JAWT and JVM)

JNI_FOUND
TRUE if JNI headers and libraries were found.

Cache Variables
The following cache variables are also available to set or use:

JAVA_AWT_LIBRARY
the path to the Java AWT Native Interface (JAWT) library

JAVA_JVM_LIBRARY
the path to the Java Virtual Machine (JVM) library

JAVA_INCLUDE_PATH
the include path to jni.h

JAVA_INCLUDE_PATH2
the include path to jni_md.h and jniport.h

JAVA_AWT_INCLUDE_PATH
the include path to jawt.h

FindJPEG
Find the Joint Photographic Experts Group (JPEG) library (libjpeg)

Imported targets
New in version 3.12.

This module defines the following IMPORTED targets:

JPEG::JPEG
The JPEG library, if found.

Result variables
This module will set the following variables in your project:

JPEG_FOUND
If false, do not try to use JPEG.

JPEG_INCLUDE_DIRS
where to find jpeglib.h, etc.

JPEG_LIBRARIES
the libraries needed to use JPEG.

JPEG_VERSION
New in version 3.12: the version of the JPEG library found

Cache variables
The following cache variables may also be set:

JPEG_INCLUDE_DIRS
where to find jpeglib.h, etc.

JPEG_LIBRARY_RELEASE
where to find the JPEG library (optimized).

JPEG_LIBRARY_DEBUG
where to find the JPEG library (debug).

New in version 3.12: Debug and Release variand are found separately.

Obsolete variables
JPEG_INCLUDE_DIR
where to find jpeglib.h, etc. (same as JPEG_INCLUDE_DIRS)

JPEG_LIBRARY
where to find the JPEG library.

FindKDE3
Find the KDE3 include and library dirs, KDE preprocessors and define a some macros

This module defines the following variables:

KDE3_DEFINITIONS
compiler definitions required for compiling KDE software

KDE3_INCLUDE_DIR
the KDE include directory

KDE3_INCLUDE_DIRS
the KDE and the Qt include directory, for use with include_directories()

KDE3_LIB_DIR
the directory where the KDE libraries are installed, for use with link_directories()

QT_AND_KDECORE_LIBS
this contains both the Qt and the kdecore library

KDE3_DCOPIDL_EXECUTABLE
the dcopidl executable

KDE3_DCOPIDL2CPP_EXECUTABLE
the dcopidl2cpp executable

KDE3_KCFGC_EXECUTABLE
the kconfig_compiler executable

KDE3_FOUND
set to TRUE if all of the above has been found

The following user adjustable options are provided:

KDE3_BUILD_TESTS
enable this to build KDE testcases

It also adds the following macros (from KDE3Macros.cmake) SRCS_VAR is always the variable which contains
the list of source files for your application or library.

KDE3_AUTOMOC(file1 ... fileN)

Call this if you want to have automatic moc file handling.
This means if you include "foo.moc" in the source file foo.cpp
a moc file for the header foo.h will be created automatically.
You can set the property SKIP_AUTOMAKE using set_source_files_properties()
to exclude some files in the list from being processed.

KDE3_ADD_MOC_FILES(SRCS_VAR file1 ... fileN )

If you don't use the KDE3_AUTOMOC() macro, for the files
listed here moc files will be created (named "foo.moc.cpp")

KDE3_ADD_DCOP_SKELS(SRCS_VAR header1.h ... headerN.h )

Use this to generate DCOP skeletions from the listed headers.

KDE3_ADD_DCOP_STUBS(SRCS_VAR header1.h ... headerN.h )

Use this to generate DCOP stubs from the listed headers.

KDE3_ADD_UI_FILES(SRCS_VAR file1.ui ... fileN.ui )

Use this to add the Qt designer ui files to your application/library.

KDE3_ADD_KCFG_FILES(SRCS_VAR file1.kcfgc ... fileN.kcfgc )

Use this to add KDE kconfig compiler files to your application/library.

KDE3_INSTALL_LIBTOOL_FILE(target)

This will create and install a simple libtool file for the given target.

KDE3_ADD_EXECUTABLE(name file1 ... fileN )

Currently identical to add_executable(), may provide some advanced
features in the future.

KDE3_ADD_KPART(name [WITH_PREFIX] file1 ... fileN )

Create a KDE plugin (KPart, kioslave, etc.) from the given source files.
If WITH_PREFIX is given, the resulting plugin will have the prefix "lib",
otherwise it won't.
It creates and installs an appropriate libtool la-file.

KDE3_ADD_KDEINIT_EXECUTABLE(name file1 ... fileN )

Create a KDE application in the form of a module loadable via kdeinit.
A library named kdeinit_<name> will be created and a small executable
which links to it.

The option KDE3_ENABLE_FINAL to enable all-in-one compilation is no longer supported.

Author: Alexander Neundorf <neundorf@kde.org>

FindKDE4
Find KDE4 and provide all necessary variables and macros to compile software for it. It looks for KDE 4
in the following directories in the given order:

CMAKE_INSTALL_PREFIX
KDEDIRS
/opt/kde4

Please look in FindKDE4Internal.cmake and KDE4Macros.cmake for more information. They are installed with
the KDE 4 libraries in $KDEDIRS/share/apps/cmake/modules/.

Author: Alexander Neundorf <neundorf@kde.org>

FindLAPACK
Find Linear Algebra PACKage (LAPACK) library

This module finds an installed Fortran library that implements the LAPACK linear-algebra interface.

At least one of the C, CXX, or Fortran languages must be enabled.

Input Variables
The following variables may be set to influence this module's behavior:

BLA_STATIC
if ON use static linkage

BLA_VENDOR
Set to one of the BLAS/LAPACK Vendors to search for BLAS only from the specified vendor. If not
set, all vendors are considered.

BLA_F95
if ON tries to find the BLAS95/LAPACK95 interfaces

BLA_PREFER_PKGCONFIG
New in version 3.20.

if set pkg-config will be used to search for a LAPACK library first and if one is found that is
preferred

BLA_SIZEOF_INTEGER
New in version 3.22.

Specify the BLAS/LAPACK library integer size:

4 Search for a BLAS/LAPACK with 32-bit integer interfaces.

8 Search for a BLAS/LAPACK with 64-bit integer interfaces.

ANY Search for any BLAS/LAPACK. Most likely, a BLAS/LAPACK with 32-bit integer interfaces will
be found.

Imported targets
This module defines the following IMPORTED targets:

LAPACK::LAPACK
New in version 3.18.

The libraries to use for LAPACK, if found.

Result Variables
This module defines the following variables:

LAPACK_FOUND
library implementing the LAPACK interface is found

LAPACK_LINKER_FLAGS
uncached list of required linker flags (excluding -l and -L).

LAPACK_LIBRARIES
uncached list of libraries (using full path name) to link against to use LAPACK

LAPACK95_LIBRARIES
uncached list of libraries (using full path name) to link against to use LAPACK95

LAPACK95_FOUND
library implementing the LAPACK95 interface is found

Intel MKL
To use the Intel MKL implementation of LAPACK, a project must enable at least one of the C or CXX
languages. Set BLA_VENDOR to an Intel MKL variant either on the command-line as
-DBLA_VENDOR=Intel10_64lp or in project code:

set(BLA_VENDOR Intel10_64lp)
find_package(LAPACK)

In order to build a project using Intel MKL, and end user must first establish an Intel MKL environment.
See the FindBLAS module section on Intel MKL for details.

FindLATEX
Find LaTeX

This module finds an installed LaTeX and determines the location of the compiler. Additionally the
module looks for Latex-related software like BibTeX.

New in version 3.2: Component processing; support for htlatex, pdftops, Biber, xindy, XeLaTeX, LuaLaTeX.

This module sets the following result variables:

LATEX_FOUND: whether found Latex and requested components
LATEX_<component>_FOUND: whether found <component>
LATEX_COMPILER: path to the LaTeX compiler
PDFLATEX_COMPILER: path to the PdfLaTeX compiler
XELATEX_COMPILER: path to the XeLaTeX compiler
LUALATEX_COMPILER: path to the LuaLaTeX compiler
BIBTEX_COMPILER: path to the BibTeX compiler
BIBER_COMPILER: path to the Biber compiler
MAKEINDEX_COMPILER: path to the MakeIndex compiler
XINDY_COMPILER: path to the xindy compiler
DVIPS_CONVERTER: path to the DVIPS converter
DVIPDF_CONVERTER: path to the DVIPDF converter
PS2PDF_CONVERTER: path to the PS2PDF converter
PDFTOPS_CONVERTER: path to the pdftops converter
LATEX2HTML_CONVERTER: path to the LaTeX2Html converter
HTLATEX_COMPILER: path to the htlatex compiler

Possible components are:

PDFLATEX
XELATEX
LUALATEX
BIBTEX
BIBER
MAKEINDEX
XINDY
DVIPS
DVIPDF
PS2PDF
PDFTOPS
LATEX2HTML
HTLATEX

Example Usages:

find_package(LATEX)
find_package(LATEX COMPONENTS PDFLATEX)
find_package(LATEX COMPONENTS BIBTEX PS2PDF)

FindLibArchive
Find libarchive library and headers. Libarchive is multi-format archive and compression library.

The module defines the following variables:

LibArchive_FOUND - true if libarchive was found
LibArchive_INCLUDE_DIRS - include search path
LibArchive_LIBRARIES - libraries to link
LibArchive_VERSION - libarchive 3-component version number

The module defines the following IMPORTED targets:

LibArchive::LibArchive - target for linking against libarchive

New in version 3.6: Support for new libarchive 3.2 version string format.

FindLibinput
New in version 3.14.

Find libinput headers and library.

Imported Targets
Libinput::Libinput
The libinput library, if found.

Result Variables
This will define the following variables in your project:

Libinput_FOUND
true if (the requested version of) libinput is available.

Libinput_VERSION
the version of libinput.

Libinput_LIBRARIES
the libraries to link against to use libinput.

Libinput_INCLUDE_DIRS
where to find the libinput headers.

Libinput_COMPILE_OPTIONS
this should be passed to target_compile_options(), if the target is not used for linking

FindLibLZMA
Find LZMA compression algorithm headers and library.

Imported Targets
New in version 3.14.

This module defines IMPORTED target LibLZMA::LibLZMA, if liblzma has been found.

Result variables
This module will set the following variables in your project:

LIBLZMA_FOUND
True if liblzma headers and library were found.

LIBLZMA_INCLUDE_DIRS
Directory where liblzma headers are located.

LIBLZMA_LIBRARIES
Lzma libraries to link against.

LIBLZMA_HAS_AUTO_DECODER
True if lzma_auto_decoder() is found (required).

LIBLZMA_HAS_EASY_ENCODER
True if lzma_easy_encoder() is found (required).

LIBLZMA_HAS_LZMA_PRESET
True if lzma_lzma_preset() is found (required).

LIBLZMA_VERSION_MAJOR
The major version of lzma

LIBLZMA_VERSION_MINOR
The minor version of lzma

LIBLZMA_VERSION_PATCH
The patch version of lzma

LIBLZMA_VERSION_STRING
version number as a string (ex: "5.0.3")

FindLibXml2
Find the XML processing library (libxml2).

IMPORTED Targets
New in version 3.12.

The following IMPORTED targets may be defined:

LibXml2::LibXml2
libxml2 library.

LibXml2::xmllint
New in version 3.17.

xmllint command-line executable.

Result variables
This module will set the following variables in your project:

LibXml2_FOUND
true if libxml2 headers and libraries were found

LIBXML2_INCLUDE_DIR
the directory containing LibXml2 headers

LIBXML2_INCLUDE_DIRS
list of the include directories needed to use LibXml2

LIBXML2_LIBRARIES
LibXml2 libraries to be linked

LIBXML2_DEFINITIONS
the compiler switches required for using LibXml2

LIBXML2_XMLLINT_EXECUTABLE
path to the XML checking tool xmllint coming with LibXml2

LIBXML2_VERSION_STRING
the version of LibXml2 found (since CMake 2.8.8)

Cache variables
The following cache variables may also be set:

LIBXML2_INCLUDE_DIR
the directory containing LibXml2 headers

LIBXML2_LIBRARY
path to the LibXml2 library

FindLibXslt
Find the XSL Transformations, Extensible Stylesheet Language Transformations (XSLT) library (LibXslt)

IMPORTED Targets
New in version 3.18.

The following IMPORTED targets may be defined:

LibXslt::LibXslt
If the libxslt library has been found

LibXslt::LibExslt
If the libexslt library has been found

LibXslt::xsltproc
If the xsltproc command-line executable has been found

Result variables
This module will set the following variables in your project:
LIBXSLT_FOUND - system has LibXslt LIBXSLT_INCLUDE_DIR - the LibXslt include directory
LIBXSLT_LIBRARIES - Link these to LibXslt LIBXSLT_DEFINITIONS - Compiler switches required for using
LibXslt LIBXSLT_VERSION_STRING - version of LibXslt found (since CMake 2.8.8)

Additionally, the following two variables are set (but not required for using xslt):

LIBXSLT_EXSLT_INCLUDE_DIR
New in version 3.18: The include directory for exslt.

LIBXSLT_EXSLT_LIBRARIES
Link to these if you need to link against the exslt library.

LIBXSLT_XSLTPROC_EXECUTABLE
Contains the full path to the xsltproc executable if found.

FindLTTngUST
New in version 3.6.

Find Linux Trace Toolkit Next Generation (LTTng-UST) library.

Imported target
This module defines the following IMPORTED target:

LTTng::UST
The LTTng-UST library, if found

Result variables
This module sets the following

LTTNGUST_FOUND
TRUE if system has LTTng-UST

LTTNGUST_INCLUDE_DIRS
The LTTng-UST include directories

LTTNGUST_LIBRARIES
The libraries needed to use LTTng-UST

LTTNGUST_VERSION_STRING
The LTTng-UST version

LTTNGUST_HAS_TRACEF
TRUE if the tracef() API is available in the system's LTTng-UST

LTTNGUST_HAS_TRACELOG
TRUE if the tracelog() API is available in the system's LTTng-UST

FindLua
Locate Lua library.

New in version 3.18: Support for Lua 5.4.

This module defines:

::
LUA_FOUND - if false, do not try to link to Lua LUA_LIBRARIES - both lua and lualib
LUA_INCLUDE_DIR - where to find lua.h LUA_VERSION_STRING - the version of Lua found
LUA_VERSION_MAJOR - the major version of Lua LUA_VERSION_MINOR - the minor version of Lua
LUA_VERSION_PATCH - the patch version of Lua

Note that the expected include convention is

#include "lua.h"

and not

#include <lua/lua.h>

This is because, the lua location is not standardized and may exist in locations other than lua/

FindLua50
Locate Lua library. This module defines:

::
LUA50_FOUND, if false, do not try to link to Lua LUA_LIBRARIES, both lua and lualib LUA_INCLUDE_DIR,
where to find lua.h and lualib.h (and probably lauxlib.h)

Note that the expected include convention is

#include "lua.h"

and not

#include <lua/lua.h>

This is because, the lua location is not standardized and may exist in locations other than lua/

FindLua51
Locate Lua library. This module defines:

::
LUA51_FOUND, if false, do not try to link to Lua LUA_LIBRARIES LUA_INCLUDE_DIR, where to find lua.h
LUA_VERSION_STRING, the version of Lua found (since CMake 2.8.8)

Note that the expected include convention is

#include "lua.h"

and not

#include <lua/lua.h>

This is because, the lua location is not standardized and may exist in locations other than lua/

FindMatlab
Finds Matlab or Matlab Compiler Runtime (MCR) and provides Matlab tools, libraries and compilers to
CMake.

This package primary purpose is to find the libraries associated with Matlab or the MCR in order to be
able to build Matlab extensions (mex files). It can also be used:

• to run specific commands in Matlab in case Matlab is available

• for declaring Matlab unit test

• to retrieve various information from Matlab (mex extensions, versions and release queries, ...)

New in version 3.12: Added Matlab Compiler Runtime (MCR) support.

The module supports the following components:

• ENG_LIBRARY and MAT_LIBRARY: respectively the ENG and MAT libraries of Matlab

• MAIN_PROGRAM the Matlab binary program. Note that this component is not available on the MCR version,
and will yield an error if the MCR is found instead of the regular Matlab installation.

• MEX_COMPILER the MEX compiler.

• MCC_COMPILER the MCC compiler, included with the Matlab Compiler add-on.

• SIMULINK the Simulink environment.

New in version 3.7: Added the MAT_LIBRARY component.

New in version 3.13: Added the ENGINE_LIBRARY, DATAARRAY_LIBRARY and MCC_COMPILER components.

Changed in version 3.14: Removed the MX_LIBRARY, ENGINE_LIBRARY and DATAARRAY_LIBRARY components. These
libraries are found unconditionally.

NOTE:
The version given to the find_package() directive is the Matlab version, which should not be confused
with the Matlab release name (eg. R2014). The matlab_get_version_from_release_name() and
matlab_get_release_name_from_version() provide a mapping between the release name and the version.

The variable Matlab_ROOT_DIR may be specified in order to give the path of the desired Matlab version.
Otherwise, the behavior is platform specific:

• Windows: The installed versions of Matlab/MCR are retrieved from the Windows registry

• OS X: The installed versions of Matlab/MCR are given by the MATLAB default installation paths in
/Application. If no such application is found, it falls back to the one that might be accessible from
the PATH.

• Unix: The desired Matlab should be accessible from the PATH. This does not work for MCR installation
and Matlab_ROOT_DIR should be specified on this platform.

Additional information is provided when MATLAB_FIND_DEBUG is set. When a Matlab/MCR installation is
found automatically and the MATLAB_VERSION is not given, the version is queried from Matlab directly (on
Windows this may pop up a Matlab window) or from the MCR installation.

The mapping of the release names and the version of Matlab is performed by defining pairs (name,
version). The variable MATLAB_ADDITIONAL_VERSIONS may be provided before the call to the find_package()
in order to handle additional versions.

A Matlab scripts can be added to the set of tests using the matlab_add_unit_test(). By default, the
Matlab unit test framework will be used (>= 2013a) to run this script, but regular .m files returning an
exit code can be used as well (0 indicating a success).

Module Input Variables
Users or projects may set the following variables to configure the module behavior:

Matlab_ROOT_DIR
the root of the Matlab installation.

MATLAB_FIND_DEBUG
outputs debug information

MATLAB_ADDITIONAL_VERSIONS
additional versions of Matlab for the automatic retrieval of the installed versions.

Imported targets
New in version 3.22.

This module defines the following IMPORTED targets:

Matlab::mex
The mex library, always available.

Matlab::mx
The mx library of Matlab (arrays), always available.

Matlab::eng
Matlab engine library. Available only if the ENG_LIBRARY component is requested.

Matlab::mat
Matlab matrix library. Available only if the MAT_LIBRARY component is requested.

Matlab::MatlabEngine
Matlab C++ engine library, always available for R2018a and newer.

Matlab::MatlabDataArray
Matlab C++ data array library, always available for R2018a and newer.

Variables defined by the module
Result variables
Matlab_FOUND
TRUE if the Matlab installation is found, FALSE otherwise. All variable below are defined if
Matlab is found.

Matlab_ROOT_DIR
the final root of the Matlab installation determined by the FindMatlab module.

Matlab_MAIN_PROGRAM
the Matlab binary program. Available only if the component MAIN_PROGRAM is given in the
find_package() directive.

Matlab_INCLUDE_DIRS
the path of the Matlab libraries headers

Matlab_MEX_LIBRARY
library for mex, always available.

Matlab_MX_LIBRARY
mx library of Matlab (arrays), always available.

Matlab_ENG_LIBRARY
Matlab engine library. Available only if the component ENG_LIBRARY is requested.

Matlab_MAT_LIBRARY
Matlab matrix library. Available only if the component MAT_LIBRARY is requested.

Matlab_ENGINE_LIBRARY
New in version 3.13.

Matlab C++ engine library, always available for R2018a and newer.

Matlab_DATAARRAY_LIBRARY
New in version 3.13.

Matlab C++ data array library, always available for R2018a and newer.

Matlab_LIBRARIES
the whole set of libraries of Matlab

Matlab_MEX_COMPILER
the mex compiler of Matlab. Currently not used. Available only if the component MEX_COMPILER is
requested.

Matlab_MCC_COMPILER
New in version 3.13.

the mcc compiler of Matlab. Included with the Matlab Compiler add-on. Available only if the
component MCC_COMPILER is requested.

Cached variables
Matlab_MEX_EXTENSION
the extension of the mex files for the current platform (given by Matlab).

Matlab_ROOT_DIR
the location of the root of the Matlab installation found. If this value is changed by the user,
the result variables are recomputed.

Provided macros
matlab_get_version_from_release_name()
returns the version from the release name

matlab_get_release_name_from_version()
returns the release name from the Matlab version

Provided functions
matlab_add_mex()
adds a target compiling a MEX file.

matlab_add_unit_test()
adds a Matlab unit test file as a test to the project.

matlab_extract_all_installed_versions_from_registry()
parses the registry for all Matlab versions. Available on Windows only. The part of the registry
parsed is dependent on the host processor

matlab_get_all_valid_matlab_roots_from_registry()
returns all the possible Matlab or MCR paths, according to a previously given list. Only the
existing/accessible paths are kept. This is mainly useful for the searching all possible Matlab
installation.

matlab_get_mex_suffix()
returns the suffix to be used for the mex files (platform/architecture dependent)

matlab_get_version_from_matlab_run()
returns the version of Matlab/MCR, given the full directory of the Matlab/MCR installation path.

Known issues
Symbol clash in a MEX target
By default, every symbols inside a MEX file defined with the command matlab_add_mex() have hidden
visibility, except for the entry point. This is the default behavior of the MEX compiler, which
lowers the risk of symbol collision between the libraries shipped with Matlab, and the libraries
to which the MEX file is linking to. This is also the default on Windows platforms.

However, this is not sufficient in certain case, where for instance your MEX file is linking
against libraries that are already loaded by Matlab, even if those libraries have different
SONAMES. A possible solution is to hide the symbols of the libraries to which the MEX target is
linking to. This can be achieved in GNU GCC compilers with the linker option
-Wl,--exclude-libs,ALL.

Tests using GPU resources
in case your MEX file is using the GPU and in order to be able to run unit tests on this MEX file,
the GPU resources should be properly released by Matlab. A possible solution is to make Matlab
aware of the use of the GPU resources in the session, which can be performed by a command such as
D = gpuDevice() at the beginning of the test script (or via a fixture).

Reference
Matlab_ROOT_DIR
The root folder of the Matlab installation. If set before the call to find_package(), the module
will look for the components in that path. If not set, then an automatic search of Matlab will be
performed. If set, it should point to a valid version of Matlab.

MATLAB_FIND_DEBUG
If set, the lookup of Matlab and the intermediate configuration steps are outputted to the
console.

MATLAB_ADDITIONAL_VERSIONS
If set, specifies additional versions of Matlab that may be looked for. The variable should be a
list of strings, organized by pairs of release name and versions, such as follows:

set(MATLAB_ADDITIONAL_VERSIONS
"release_name1=corresponding_version1"
"release_name2=corresponding_version2"
...
)

Example:

set(MATLAB_ADDITIONAL_VERSIONS
"R2013b=8.2"
"R2013a=8.1"
"R2012b=8.0")

The order of entries in this list matters when several versions of Matlab are installed. The
priority is set according to the ordering in this list.

matlab_get_version_from_release_name
Returns the version of Matlab (17.58) from a release name (R2017k)

matlab_get_release_name_from_version
Returns the release name (R2017k) from the version of Matlab (17.58)

matlab_extract_all_installed_versions_from_registry
This function parses the registry and founds the Matlab versions that are installed. The found
versions are returned in matlab_versions. Set win64 to TRUE if the 64 bit version of Matlab
should be looked for The returned list contains all versions under
HKLM\\SOFTWARE\\Mathworks\\MATLAB and HKLM\\SOFTWARE\\Mathworks\\MATLAB Runtime or an empty list
in case an error occurred (or nothing found).

NOTE:
Only the versions are provided. No check is made over the existence of the installation
referenced in the registry,

matlab_get_all_valid_matlab_roots_from_registry
Populates the Matlab root with valid versions of Matlab or Matlab Runtime (MCR). The returned
matlab_roots is organized in triplets (type,version_number,matlab_root_path), where type indicates
either MATLAB or MCR.

matlab_get_all_valid_matlab_roots_from_registry(
matlab_versions
matlab_roots)

matlab_versions
the versions of each of the Matlab or MCR installations

matlab_roots
the location of each of the Matlab or MCR installations

matlab_get_mex_suffix
Returns the extension of the mex files (the suffixes). This function should not be called before
the appropriate Matlab root has been found.

matlab_get_mex_suffix(
matlab_root
mex_suffix)

matlab_root
the root of the Matlab/MCR installation

mex_suffix
the variable name in which the suffix will be returned.

matlab_get_version_from_matlab_run
This function runs Matlab program specified on arguments and extracts its version. If the path
provided for the Matlab installation points to an MCR installation, the version is extracted from
the installed files.

matlab_get_version_from_matlab_run(
matlab_binary_path
matlab_list_versions)

matlab_binary_path
the location of the matlab binary executable

matlab_list_versions
the version extracted from Matlab

matlab_add_unit_test
Adds a Matlab unit test to the test set of cmake/ctest. This command requires the component
MAIN_PROGRAM and hence is not available for an MCR installation.

The unit test uses the Matlab unittest framework (default, available starting Matlab 2013b+)
except if the option NO_UNITTEST_FRAMEWORK is given.

The function expects one Matlab test script file to be given. In the case NO_UNITTEST_FRAMEWORK
is given, the unittest script file should contain the script to be run, plus an exit command with
the exit value. This exit value will be passed to the ctest framework (0 success, non 0 failure).
Additional arguments accepted by add_test() can be passed through TEST_ARGS (eg. CONFIGURATION
<config> ...).

matlab_add_unit_test(
NAME <name>
UNITTEST_FILE matlab_file_containing_unittest.m
[CUSTOM_TEST_COMMAND matlab_command_to_run_as_test]
[UNITTEST_PRECOMMAND matlab_command_to_run]
[TIMEOUT timeout]
[ADDITIONAL_PATH path1 [path2 ...]]
[MATLAB_ADDITIONAL_STARTUP_OPTIONS option1 [option2 ...]]
[TEST_ARGS arg1 [arg2 ...]]
[NO_UNITTEST_FRAMEWORK]
)

The function arguments are:

NAME name of the unittest in ctest.

UNITTEST_FILE
the matlab unittest file. Its path will be automatically added to the Matlab path.

CUSTOM_TEST_COMMAND
Matlab script command to run as the test. If this is not set, then the following is run:
runtests('matlab_file_name'), exit(max([ans(1,:).Failed])) where matlab_file_name is the
UNITTEST_FILE without the extension.

UNITTEST_PRECOMMAND
Matlab script command to be ran before the file containing the test (eg. GPU device
initialization based on CMake variables).

TIMEOUT
the test timeout in seconds. Defaults to 180 seconds as the Matlab unit test may hang.

ADDITIONAL_PATH
a list of paths to add to the Matlab path prior to running the unit test.

MATLAB_ADDITIONAL_STARTUP_OPTIONS
a list of additional option in order to run Matlab from the command line. -nosplash
-nodesktop -nodisplay are always added.

TEST_ARGS
Additional options provided to the add_test command. These options are added to the default
options (eg. "CONFIGURATIONS Release")

NO_UNITTEST_FRAMEWORK
when set, indicates that the test should not use the unittest framework of Matlab
(available for versions >= R2013a).

WORKING_DIRECTORY
This will be the working directory for the test. If specified it will also be the output
directory used for the log file of the test run. If not specified the temporary directory
${CMAKE_BINARY_DIR}/Matlab will be used as the working directory and the log location.

matlab_add_mex
Adds a Matlab MEX target. This commands compiles the given sources with the current tool-chain in
order to produce a MEX file. The final name of the produced output may be specified, as well as
additional link libraries, and a documentation entry for the MEX file. Remaining arguments of the
call are passed to the add_library() or add_executable() command.

matlab_add_mex(
NAME <name>
[EXECUTABLE | MODULE | SHARED]
SRC src1 [src2 ...]
[OUTPUT_NAME output_name]
[DOCUMENTATION file.txt]
[LINK_TO target1 target2 ...]
[R2017b | R2018a]
[EXCLUDE_FROM_ALL]
[...]
)

NAME name of the target.

SRC list of source files.

LINK_TO
a list of additional link dependencies. The target links to libmex and libmx by default.

OUTPUT_NAME
if given, overrides the default name. The default name is the name of the target without
any prefix and with Matlab_MEX_EXTENSION suffix.

DOCUMENTATION
if given, the file file.txt will be considered as being the documentation file for the MEX
file. This file is copied into the same folder without any processing, with the same name
as the final mex file, and with extension .m. In that case, typing help <name> in Matlab
prints the documentation contained in this file.

R2017b or R2018a
New in version 3.14.

May be given to specify the version of the C API to use: R2017b specifies the traditional
(separate complex) C API, and corresponds to the -R2017b flag for the mex command. R2018a
specifies the new interleaved complex C API, and corresponds to the -R2018a flag for the
mex command. Ignored if MATLAB version prior to R2018a. Defaults to R2017b.

MODULE or SHARED
New in version 3.7.

May be given to specify the type of library to be created.

EXECUTABLE
New in version 3.7.

May be given to create an executable instead of a library. If no type is given explicitly,
the type is SHARED.

EXCLUDE_FROM_ALL
This option has the same meaning as for EXCLUDE_FROM_ALL and is forwarded to add_library()
or add_executable() commands.

The documentation file is not processed and should be in the following format:

% This is the documentation
function ret = mex_target_output_name(input1)

FindMFC
Find Microsoft Foundation Class Library (MFC) on Windows

Find the native MFC - i.e. decide if an application can link to the MFC libraries.

MFC_FOUND - Was MFC support found

You don't need to include anything or link anything to use it.

FindMotif
Try to find Motif (or lesstif)

Once done this will define:

MOTIF_FOUND - system has MOTIF
MOTIF_INCLUDE_DIR - include paths to use Motif
MOTIF_LIBRARIES - Link these to use Motif

FindMPEG
Find the native MPEG includes and library

This module defines

MPEG_INCLUDE_DIR, where to find MPEG.h, etc.
MPEG_LIBRARIES, the libraries required to use MPEG.
MPEG_FOUND, If false, do not try to use MPEG.

also defined, but not for general use are

MPEG_mpeg2_LIBRARY, where to find the MPEG library.
MPEG_vo_LIBRARY, where to find the vo library.

FindMPEG2
Find the native MPEG2 includes and library

This module defines

MPEG2_INCLUDE_DIR, path to mpeg2dec/mpeg2.h, etc.
MPEG2_LIBRARIES, the libraries required to use MPEG2.
MPEG2_FOUND, If false, do not try to use MPEG2.

also defined, but not for general use are

MPEG2_mpeg2_LIBRARY, where to find the MPEG2 library.
MPEG2_vo_LIBRARY, where to find the vo library.

FindMPI
Find a Message Passing Interface (MPI) implementation.

The Message Passing Interface (MPI) is a library used to write high-performance distributed-memory
parallel applications, and is typically deployed on a cluster. MPI is a standard interface (defined by
the MPI forum) for which many implementations are available.

New in version 3.10: Major overhaul of the module: many new variables, per-language components, support
for a wider variety of runtimes.

Variables for using MPI
The module exposes the components C, CXX, MPICXX and Fortran. Each of these controls the various MPI
languages to search for. The difference between CXX and MPICXX is that CXX refers to the MPI C API being
usable from C++, whereas MPICXX refers to the MPI-2 C++ API that was removed again in MPI-3.

Depending on the enabled components the following variables will be set:

MPI_FOUND
Variable indicating that MPI settings for all requested languages have been found. If no
components are specified, this is true if MPI settings for all enabled languages were detected.
Note that the MPICXX component does not affect this variable.

MPI_VERSION
Minimal version of MPI detected among the requested languages, or all enabled languages if no
components were specified.

This module will set the following variables per language in your project, where <lang> is one of C, CXX,
or Fortran:

MPI_<lang>_FOUND
Variable indicating the MPI settings for <lang> were found and that simple MPI test programs
compile with the provided settings.

MPI_<lang>_COMPILER
MPI compiler for <lang> if such a program exists.

MPI_<lang>_COMPILE_OPTIONS
Compilation options for MPI programs in <lang>, given as a ;-list.

MPI_<lang>_COMPILE_DEFINITIONS
Compilation definitions for MPI programs in <lang>, given as a ;-list.

MPI_<lang>_INCLUDE_DIRS
Include path(s) for MPI header.

MPI_<lang>_LINK_FLAGS
Linker flags for MPI programs.

MPI_<lang>_LIBRARIES
All libraries to link MPI programs against.

New in version 3.9: Additionally, the following IMPORTED targets are defined:

MPI::MPI_<lang>
Target for using MPI from <lang>.

The following variables indicating which bindings are present will be defined:

MPI_MPICXX_FOUND
Variable indicating whether the MPI-2 C++ bindings are present (introduced in MPI-2, removed with
MPI-3).

MPI_Fortran_HAVE_F77_HEADER
True if the Fortran 77 header mpif.h is available.

MPI_Fortran_HAVE_F90_MODULE
True if the Fortran 90 module mpi can be used for accessing MPI (MPI-2 and higher only).

MPI_Fortran_HAVE_F08_MODULE
True if the Fortran 2008 mpi_f08 is available to MPI programs (MPI-3 and higher only).

If possible, the MPI version will be determined by this module. The facilities to detect the MPI version
were introduced with MPI-1.2, and therefore cannot be found for older MPI versions.

MPI_<lang>_VERSION_MAJOR
Major version of MPI implemented for <lang> by the MPI distribution.

MPI_<lang>_VERSION_MINOR
Minor version of MPI implemented for <lang> by the MPI distribution.

MPI_<lang>_VERSION
MPI version implemented for <lang> by the MPI distribution.

Note that there's no variable for the C bindings being accessible through mpi.h, since the MPI standards
always have required this binding to work in both C and C++ code.

For running MPI programs, the module sets the following variables

MPIEXEC_EXECUTABLE
Executable for running MPI programs, if such exists.

MPIEXEC_NUMPROC_FLAG
Flag to pass to mpiexec before giving it the number of processors to run on.

MPIEXEC_MAX_NUMPROCS
Number of MPI processors to utilize. Defaults to the number of processors detected on the host
system.

MPIEXEC_PREFLAGS
Flags to pass to mpiexec directly before the executable to run.

MPIEXEC_POSTFLAGS
Flags to pass to mpiexec after other flags.

Variables for locating MPI
This module performs a four step search for an MPI implementation:

1. Search for MPIEXEC_EXECUTABLE and, if found, use its base directory.

2. Check if the compiler has MPI support built-in. This is the case if the user passed a compiler wrapper
as CMAKE_<LANG>_COMPILER or if they use Cray system compiler wrappers.

3. Attempt to find an MPI compiler wrapper and determine the compiler information from it.

4. Try to find an MPI implementation that does not ship such a wrapper by guessing settings. Currently,
only Microsoft MPI and MPICH2 on Windows are supported.

For controlling the MPIEXEC_EXECUTABLE step, the following variables may be set:

MPIEXEC_EXECUTABLE
Manually specify the location of mpiexec.

MPI_HOME
Specify the base directory of the MPI installation.

ENV{MPI_HOME}
Environment variable to specify the base directory of the MPI installation.

ENV{I_MPI_ROOT}
Environment variable to specify the base directory of the MPI installation.

For controlling the compiler wrapper step, the following variables may be set:

MPI_<lang>_COMPILER
Search for the specified compiler wrapper and use it.

MPI_<lang>_COMPILER_FLAGS
Flags to pass to the MPI compiler wrapper during interrogation. Some compiler wrappers support
linking debug or tracing libraries if a specific flag is passed and this variable may be used to
obtain them.

MPI_COMPILER_FLAGS
Used to initialize MPI_<lang>_COMPILER_FLAGS if no language specific flag has been given. Empty
by default.

MPI_EXECUTABLE_SUFFIX
A suffix which is appended to all names that are being looked for. For instance you may set this
to .mpich or .openmpi to prefer the one or the other on Debian and its derivatives.

In order to control the guessing step, the following variable may be set:

MPI_GUESS_LIBRARY_NAME
Valid values are MSMPI and MPICH2. If set, only the given library will be searched for. By
default, MSMPI will be preferred over MPICH2 if both are available. This also sets
MPI_SKIP_COMPILER_WRAPPER to true, which may be overridden.

Each of the search steps may be skipped with the following control variables:

MPI_ASSUME_NO_BUILTIN_MPI
If true, the module assumes that the compiler itself does not provide an MPI implementation and
skips to step 2.

MPI_SKIP_COMPILER_WRAPPER
If true, no compiler wrapper will be searched for.

MPI_SKIP_GUESSING
If true, the guessing step will be skipped.

Additionally, the following control variable is available to change search behavior:

MPI_CXX_SKIP_MPICXX
Add some definitions that will disable the MPI-2 C++ bindings. Currently supported are MPICH,
Open MPI, Platform MPI and derivatives thereof, for example MVAPICH or Intel MPI.

If the find procedure fails for a variable MPI_<lang>_WORKS, then the settings detected by or passed to
the module did not work and even a simple MPI test program failed to compile.

If all of these parameters were not sufficient to find the right MPI implementation, a user may disable
the entire autodetection process by specifying both a list of libraries in MPI_<lang>_LIBRARIES and a
list of include directories in MPI_<lang>_ADDITIONAL_INCLUDE_DIRS. Any other variable may be set in
addition to these two. The module will then validate the MPI settings and store the settings in the
cache.

Cache variables for MPI
The variable MPI_<lang>_INCLUDE_DIRS will be assembled from the following variables. For C and CXX:

MPI_<lang>_HEADER_DIR
Location of the mpi.h header on disk.

For Fortran:

MPI_Fortran_F77_HEADER_DIR
Location of the Fortran 77 header mpif.h, if it exists.

MPI_Fortran_MODULE_DIR
Location of the mpi or mpi_f08 modules, if available.

For all languages the following variables are additionally considered:

MPI_<lang>_ADDITIONAL_INCLUDE_DIRS
A ;-list of paths needed in addition to the normal include directories.

MPI_<include_name>_INCLUDE_DIR
Path variables for include folders referred to by <include_name>.

MPI_<lang>_ADDITIONAL_INCLUDE_VARS
A ;-list of <include_name> that will be added to the include locations of <lang>.

The variable MPI_<lang>_LIBRARIES will be assembled from the following variables:

MPI_<lib_name>_LIBRARY
The location of a library called <lib_name> for use with MPI.

MPI_<lang>_LIB_NAMES
A ;-list of <lib_name> that will be added to the include locations of <lang>.

Usage of mpiexec
When using MPIEXEC_EXECUTABLE to execute MPI applications, you should typically use all of the
MPIEXEC_EXECUTABLE flags as follows:

${MPIEXEC_EXECUTABLE} ${MPIEXEC_NUMPROC_FLAG} ${MPIEXEC_MAX_NUMPROCS}
${MPIEXEC_PREFLAGS} EXECUTABLE ${MPIEXEC_POSTFLAGS} ARGS

where EXECUTABLE is the MPI program, and ARGS are the arguments to pass to the MPI program.

Advanced variables for using MPI
The module can perform some advanced feature detections upon explicit request.

Important notice: The following checks cannot be performed without executing an MPI test program.
Consider the special considerations for the behavior of try_run() during cross compilation. Moreover,
running an MPI program can cause additional issues, like a firewall notification on some systems. You
should only enable these detections if you absolutely need the information.

If the following variables are set to true, the respective search will be performed:

MPI_DETERMINE_Fortran_CAPABILITIES
Determine for all available Fortran bindings what the values of MPI_SUBARRAYS_SUPPORTED and
MPI_ASYNC_PROTECTS_NONBLOCKING are and make their values available as
MPI_Fortran_<binding>_SUBARRAYS and MPI_Fortran_<binding>_ASYNCPROT, where <binding> is one of
F77_HEADER, F90_MODULE and F08_MODULE.

MPI_DETERMINE_LIBRARY_VERSION
For each language, find the output of MPI_Get_library_version and make it available as
MPI_<lang>_LIBRARY_VERSION_STRING. This information is usually tied to the runtime component of
an MPI implementation and might differ depending on <lang>. Note that the return value is
entirely implementation defined. This information might be used to identify the MPI vendor and for
example pick the correct one of multiple third party binaries that matches the MPI vendor.

Backward Compatibility
Deprecated since version 3.10.

For backward compatibility with older versions of FindMPI, these variables are set:

MPI_COMPILER MPI_LIBRARY MPI_EXTRA_LIBRARY
MPI_COMPILE_FLAGS MPI_INCLUDE_PATH MPI_LINK_FLAGS
MPI_LIBRARIES

In new projects, please use the MPI_<lang>_XXX equivalents. Additionally, the following variables are
deprecated:

MPI_<lang>_COMPILE_FLAGS
Use MPI_<lang>_COMPILE_OPTIONS and MPI_<lang>_COMPILE_DEFINITIONS instead.

MPI_<lang>_INCLUDE_PATH
For consumption use MPI_<lang>_INCLUDE_DIRS and for specifying folders use
MPI_<lang>_ADDITIONAL_INCLUDE_DIRS instead.

MPIEXEC
Use MPIEXEC_EXECUTABLE instead.

FindMsys
New in version 3.21.

Find MSYS, a POSIX-compatible environment that runs natively on Microsoft Windows

FindODBC
New in version 3.12.

Find an Open Database Connectivity (ODBC) include directory and library.

On Windows, when building with Visual Studio, this module assumes the ODBC library is provided by the
available Windows SDK.

On Unix, this module allows to search for ODBC library provided by unixODBC or iODBC implementations of
ODBC API. This module reads hint about location of the config program:

ODBC_CONFIG
Location of odbc_config or iodbc-config program

Otherwise, this module tries to find the config program, first from unixODBC, then from iODBC. If no
config program found, this module searches for ODBC header and library in list of known locations.

Imported targets
This module defines the following IMPORTED targets:

ODBC::ODBC
Imported target for using the ODBC library, if found.

Result variables
ODBC_FOUND
Set to true if ODBC library found, otherwise false or undefined.

ODBC_INCLUDE_DIRS
Paths to include directories listed in one variable for use by ODBC client. May be empty on
Windows, where the include directory corresponding to the expected Windows SDK is already
available in the compilation environment.

ODBC_LIBRARIES
Paths to libraries to linked against to use ODBC. May just a library name on Windows, where the
library directory corresponding to the expected Windows SDK is already available in the
compilation environment.

ODBC_CONFIG
Path to unixODBC or iODBC config program, if found or specified.

Cache variables
For users who wish to edit and control the module behavior, this module reads hints about search
locations from the following variables:

ODBC_INCLUDE_DIR
Path to ODBC include directory with sql.h header.

ODBC_LIBRARY
Path to ODBC library to be linked.

These variables should not be used directly by project code.

Limitations
On Windows, this module does not search for iODBC. On Unix, there is no way to prefer unixODBC over
iODBC, or vice versa, other than providing the config program location using the ODBC_CONFIG. This
module does not allow to search for a specific ODBC driver.

FindOpenACC
New in version 3.10.

Detect OpenACC support by the compiler.

This module can be used to detect OpenACC support in a compiler. If the compiler supports OpenACC, the
flags required to compile with OpenACC support are returned in variables for the different languages.
Currently, only NVHPC, PGI, GNU and Cray compilers are supported.

Imported Targets
New in version 3.16.

The module provides IMPORTED targets:

OpenACC::OpenACC_<lang>
Target for using OpenACC from <lang>.

Variables
This module will set the following variables per language in your project, where <lang> is one of C, CXX,
or Fortran:

OpenACC_<lang>_FOUND
Variable indicating if OpenACC support for <lang> was detected.

OpenACC_<lang>_FLAGS
OpenACC compiler flags for <lang>, separated by spaces.

OpenACC_<lang>_OPTIONS
New in version 3.16.

OpenACC compiler flags for <lang>, as a list. Suitable for usage with target_compile_options or
target_link_options.

The module will also try to provide the OpenACC version variables:

OpenACC_<lang>_SPEC_DATE
Date of the OpenACC specification implemented by the <lang> compiler.

OpenACC_<lang>_VERSION_MAJOR
Major version of OpenACC implemented by the <lang> compiler.

OpenACC_<lang>_VERSION_MINOR
Minor version of OpenACC implemented by the <lang> compiler.

OpenACC_<lang>_VERSION
OpenACC version implemented by the <lang> compiler.

The specification date is formatted as given in the OpenACC standard: yyyymm where yyyy and mm represents
the year and month of the OpenACC specification implemented by the <lang> compiler.

Input Variables
OpenACC_ACCEL_TARGET=<target> If set, will the correct target accelerator flag set to the <target> will
be returned with OpenACC_<lang>_FLAGS.

FindOpenAL
Finds Open Audio Library (OpenAL).

Projects using this module should use #include "al.h" to include the OpenAL header file, not #include
<AL/al.h>. The reason for this is that the latter is not entirely portable. Windows/Creative Labs does
not by default put their headers in AL/ and macOS uses the convention <OpenAL/al.h>.

Hints
Environment variable $OPENALDIR can be used to set the prefix of OpenAL installation to be found.

By default on macOS, system framework is search first. In other words, OpenAL is searched in the
following order:

1. System framework: /System/Library/Frameworks, whose priority can be changed via setting the
CMAKE_FIND_FRAMEWORK variable.

2. Environment variable $OPENALDIR.

3. System paths.

4. User-compiled framework: ~/Library/Frameworks.

5. Manually compiled framework: /Library/Frameworks.

6. Add-on package: /opt.

Result Variables
This module defines the following variables:

OPENAL_FOUND
If false, do not try to link to OpenAL

OPENAL_INCLUDE_DIR
OpenAL include directory

OPENAL_LIBRARY
Path to the OpenAL library

OPENAL_VERSION_STRING
Human-readable string containing the version of OpenAL

FindOpenCL
New in version 3.1.

Finds Open Computing Language (OpenCL)

New in version 3.10: Detection of OpenCL 2.1 and 2.2.

IMPORTED Targets
New in version 3.7.

This module defines IMPORTED target OpenCL::OpenCL, if OpenCL has been found.

Result Variables
This module defines the following variables:

OpenCL_FOUND - True if OpenCL was found
OpenCL_INCLUDE_DIRS - include directories for OpenCL
OpenCL_LIBRARIES - link against this library to use OpenCL
OpenCL_VERSION_STRING - Highest supported OpenCL version (eg. 1.2)
OpenCL_VERSION_MAJOR - The major version of the OpenCL implementation
OpenCL_VERSION_MINOR - The minor version of the OpenCL implementation

The module will also define two cache variables:

OpenCL_INCLUDE_DIR - the OpenCL include directory
OpenCL_LIBRARY - the path to the OpenCL library

FindOpenGL
FindModule for OpenGL and OpenGL Utility Library (GLU).

Changed in version 3.2: X11 is no longer added as a dependency on Unix/Linux systems.

New in version 3.10: GLVND support on Linux. See the Linux-specific section below.

Optional COMPONENTS
New in version 3.10.

This module respects several optional COMPONENTS: EGL, GLX, and OpenGL. There are corresponding import
targets for each of these flags.

IMPORTED Targets
New in version 3.8.

This module defines the IMPORTED targets:

OpenGL::GL
Defined to the platform-specific OpenGL libraries if the system has OpenGL.

OpenGL::GLU
Defined if the system has OpenGL Utility Library (GLU).

New in version 3.10: Additionally, the following GLVND-specific library targets are defined:

OpenGL::OpenGL
Defined to libOpenGL if the system is GLVND-based.

OpenGL::GLX
Defined if the system has OpenGL Extension to the X Window System (GLX).

OpenGL::EGL
Defined if the system has EGL.

Result Variables
This module sets the following variables:

OPENGL_FOUND
True, if the system has OpenGL and all components are found.

OPENGL_XMESA_FOUND
True, if the system has XMESA.

OPENGL_GLU_FOUND
True, if the system has GLU.

OpenGL_OpenGL_FOUND
True, if the system has an OpenGL library.

OpenGL_GLX_FOUND
True, if the system has GLX.

OpenGL_EGL_FOUND
True, if the system has EGL.

OPENGL_INCLUDE_DIR
Path to the OpenGL include directory.

OPENGL_EGL_INCLUDE_DIRS
Path to the EGL include directory.

OPENGL_LIBRARIES
Paths to the OpenGL library, windowing system libraries, and GLU libraries. On Linux, this
assumes GLX and is never correct for EGL-based targets. Clients are encouraged to use the
OpenGL::* import targets instead.

New in version 3.10: Variables for GLVND-specific libraries OpenGL, EGL and GLX.

Cache variables
The following cache variables may also be set:

OPENGL_egl_LIBRARY
Path to the EGL library.

OPENGL_glu_LIBRARY
Path to the GLU library.

OPENGL_glx_LIBRARY
Path to the GLVND 'GLX' library.

OPENGL_opengl_LIBRARY
Path to the GLVND 'OpenGL' library

OPENGL_gl_LIBRARY
Path to the OpenGL library. New code should prefer the OpenGL::* import targets.

New in version 3.10: Variables for GLVND-specific libraries OpenGL, EGL and GLX.

Linux-specific
Some Linux systems utilize GLVND as a new ABI for OpenGL. GLVND separates context libraries from OpenGL
itself; OpenGL lives in "libOpenGL", and contexts are defined in "libGLX" or "libEGL". GLVND is
currently the only way to get OpenGL 3+ functionality via EGL in a manner portable across vendors.
Projects may use GLVND explicitly with target OpenGL::OpenGL and either OpenGL::GLX or OpenGL::EGL.

Projects may use the OpenGL::GL target (or OPENGL_LIBRARIES variable) to use legacy GL interfaces. These
will use the legacy GL library located by OPENGL_gl_LIBRARY, if available. If OPENGL_gl_LIBRARY is empty
or not found and GLVND is available, the OpenGL::GL target will use GLVND OpenGL::OpenGL and OpenGL::GLX
(and the OPENGL_LIBRARIES variable will use the corresponding libraries). Thus, for non-EGL-based Linux
targets, the OpenGL::GL target is most portable.

A OpenGL_GL_PREFERENCE variable may be set to specify the preferred way to provide legacy GL interfaces
in case multiple choices are available. The value may be one of:

GLVND If the GLVND OpenGL and GLX libraries are available, prefer them. This forces OPENGL_gl_LIBRARY
to be empty.

Changed in version 3.11: This is the default, unless policy CMP0072 is set to OLD and no
components are requeted (since components correspond to GLVND libraries).

LEGACY Prefer to use the legacy libGL library, if available.

For EGL targets the client must rely on GLVND support on the user's system. Linking should use the
OpenGL::OpenGL OpenGL::EGL targets. Using GLES* libraries is theoretically possible in place of
OpenGL::OpenGL, but this module does not currently support that; contributions welcome.

OPENGL_egl_LIBRARY and OPENGL_EGL_INCLUDE_DIRS are defined in the case of GLVND. For non-GLVND Linux and
other systems these are left undefined.

macOS-Specific
On OSX FindOpenGL defaults to using the framework version of OpenGL. People will have to change the cache
values of OPENGL_glu_LIBRARY and OPENGL_gl_LIBRARY to use OpenGL with X11 on OSX.

FindOpenMP
Finds Open Multi-Processing (OpenMP) support.

This module can be used to detect OpenMP support in a compiler. If the compiler supports OpenMP, the
flags required to compile with OpenMP support are returned in variables for the different languages. The
variables may be empty if the compiler does not need a special flag to support OpenMP.

New in version 3.5: Clang support.

Variables
New in version 3.10: The module exposes the components C, CXX, and Fortran. Each of these controls the
various languages to search OpenMP support for.

Depending on the enabled components the following variables will be set:

OpenMP_FOUND
Variable indicating that OpenMP flags for all requested languages have been found. If no
components are specified, this is true if OpenMP settings for all enabled languages were detected.

OpenMP_VERSION
Minimal version of the OpenMP standard detected among the requested languages, or all enabled
languages if no components were specified.

This module will set the following variables per language in your project, where <lang> is one of C, CXX,
or Fortran:

OpenMP_<lang>_FOUND
Variable indicating if OpenMP support for <lang> was detected.

OpenMP_<lang>_FLAGS
OpenMP compiler flags for <lang>, separated by spaces.

OpenMP_<lang>_INCLUDE_DIRS
Directories that must be added to the header search path for <lang> when using OpenMP.

For linking with OpenMP code written in <lang>, the following variables are provided:

OpenMP_<lang>_LIB_NAMES
;-list of libraries for OpenMP programs for <lang>.

OpenMP_<libname>_LIBRARY
Location of the individual libraries needed for OpenMP support in <lang>.

OpenMP_<lang>_LIBRARIES
A list of libraries needed to link with OpenMP code written in <lang>.

Additionally, the module provides IMPORTED targets:

OpenMP::OpenMP_<lang>
Target for using OpenMP from <lang>.

Specifically for Fortran, the module sets the following variables:

OpenMP_Fortran_HAVE_OMPLIB_HEADER
Boolean indicating if OpenMP is accessible through omp_lib.h.

OpenMP_Fortran_HAVE_OMPLIB_MODULE
Boolean indicating if OpenMP is accessible through the omp_lib Fortran module.

The module will also try to provide the OpenMP version variables:

OpenMP_<lang>_SPEC_DATE
New in version 3.7.

Date of the OpenMP specification implemented by the <lang> compiler.

OpenMP_<lang>_VERSION_MAJOR
Major version of OpenMP implemented by the <lang> compiler.

OpenMP_<lang>_VERSION_MINOR
Minor version of OpenMP implemented by the <lang> compiler.

OpenMP_<lang>_VERSION
OpenMP version implemented by the <lang> compiler.

The specification date is formatted as given in the OpenMP standard: yyyymm where yyyy and mm represents
the year and month of the OpenMP specification implemented by the <lang> compiler.

For some compilers, it may be necessary to add a header search path to find the relevant OpenMP headers.
This location may be language-specific. Where this is needed, the module may attempt to find the
location, but it can be provided directly by setting the OpenMP_<lang>_INCLUDE_DIR cache variable. Note
that this variable is an _input_ control to the module. Project code should use the
OpenMP_<lang>_INCLUDE_DIRS _output_ variable if it needs to know what include directories are needed.

FindOpenSceneGraph
Find OpenSceneGraph (3D graphics application programming interface)

This module searches for the OpenSceneGraph core "osg" library as well as FindOpenThreads, and whatever
additional COMPONENTS (nodekits) that you specify.

See http://www.openscenegraph.org

NOTE: To use this module effectively you must either require CMake >= 2.6.3 with
cmake_minimum_required(VERSION 2.6.3) or download and place FindOpenThreads, Findosg functions, Findosg
and Find<etc>.cmake files into your CMAKE_MODULE_PATH.

----

This module accepts the following variables (note mixed case)

OpenSceneGraph_DEBUG - Enable debugging output

OpenSceneGraph_MARK_AS_ADVANCED - Mark cache variables as advanced
automatically

The following environment variables are also respected for finding the OSG and it's various components.
CMAKE_PREFIX_PATH can also be used for this (see find_library() CMake documentation).

<MODULE>_DIR
(where MODULE is of the form "OSGVOLUME" and there is a FindosgVolume.cmake` file)

OSG_DIR

OSGDIR

OSG_ROOT

[CMake 2.8.10]: The CMake variable OSG_DIR can now be used as well to influence detection, instead of
needing to specify an environment variable.

This module defines the following output variables:

OPENSCENEGRAPH_FOUND - Was the OSG and all of the specified components found?

OPENSCENEGRAPH_VERSION - The version of the OSG which was found

OPENSCENEGRAPH_INCLUDE_DIRS - Where to find the headers

OPENSCENEGRAPH_LIBRARIES - The OSG libraries

================================== Example Usage:

find_package(OpenSceneGraph 2.0.0 REQUIRED osgDB osgUtil)
# libOpenThreads & libosg automatically searched
include_directories(${OPENSCENEGRAPH_INCLUDE_DIRS})

add_executable(foo foo.cc)
target_link_libraries(foo ${OPENSCENEGRAPH_LIBRARIES})

FindOpenSSL
Find the OpenSSL encryption library.

This module finds an installed OpenSSL library and determines its version.

New in version 3.19: When a version is requested, it can be specified as a simple value or as a range.
For a detailed description of version range usage and capabilities, refer to the find_package() command.

New in version 3.18: Support for OpenSSL 3.0.

Optional COMPONENTS
New in version 3.12.

This module supports two optional COMPONENTS: Crypto and SSL. Both components have associated imported
targets, as described below.

Imported Targets
New in version 3.4.

This module defines the following IMPORTED targets:

OpenSSL::SSL
The OpenSSL ssl library, if found.

OpenSSL::Crypto
The OpenSSL crypto library, if found.

OpenSSL::applink
New in version 3.18.

The OpenSSL applink components that might be need to be compiled into projects under MSVC. This
target is available only if found OpenSSL version is not less than 0.9.8. By linking this target
the above OpenSSL targets can be linked even if the project has different MSVC runtime
configurations with the above OpenSSL targets. This target has no effect on platforms other than
MSVC.

NOTE: Due to how INTERFACE_SOURCES are consumed by the consuming target, unless you certainly know what
you are doing, it is always preferred to link OpenSSL::applink target as PRIVATE and to make sure that
this target is linked at most once for the whole dependency graph of any library or executable:

target_link_libraries(myTarget PRIVATE OpenSSL::applink)

Otherwise you would probably encounter unexpected random problems when building and linking, as both the
ISO C and the ISO C++ standard claims almost nothing about what a link process should be.

Result Variables
This module will set the following variables in your project:

OPENSSL_FOUND
System has the OpenSSL library. If no components are requested it only requires the crypto
library.

OPENSSL_INCLUDE_DIR
The OpenSSL include directory.

OPENSSL_CRYPTO_LIBRARY
The OpenSSL crypto library.

OPENSSL_CRYPTO_LIBRARIES
The OpenSSL crypto library and its dependencies.

OPENSSL_SSL_LIBRARY
The OpenSSL SSL library.

OPENSSL_SSL_LIBRARIES
The OpenSSL SSL library and its dependencies.

OPENSSL_LIBRARIES
All OpenSSL libraries and their dependencies.

OPENSSL_VERSION
This is set to $major.$minor.$revision$patch (e.g. 0.9.8s).

OPENSSL_APPLINK_SOURCE
The sources in the target OpenSSL::applink that is mentioned above. This variable shall always be
undefined if found openssl version is less than 0.9.8 or if platform is not MSVC.

Hints
Set OPENSSL_ROOT_DIR to the root directory of an OpenSSL installation.

New in version 3.4: Set OPENSSL_USE_STATIC_LIBS to TRUE to look for static libraries.

New in version 3.5: Set OPENSSL_MSVC_STATIC_RT set TRUE to choose the MT version of the lib.

FindOpenThreads
OpenThreads is a C++ based threading library. Its largest userbase seems to OpenSceneGraph so you might
notice I accept OSGDIR as an environment path. I consider this part of the Findosg* suite used to find
OpenSceneGraph components. Each component is separate and you must opt in to each module.

Locate OpenThreads This module defines OPENTHREADS_LIBRARY OPENTHREADS_FOUND, if false, do not try to
link to OpenThreads OPENTHREADS_INCLUDE_DIR, where to find the headers

$OPENTHREADS_DIR is an environment variable that would correspond to the ./configure
--prefix=$OPENTHREADS_DIR used in building osg.

[CMake 2.8.10]: The CMake variables OPENTHREADS_DIR or OSG_DIR can now be used as well to influence
detection, instead of needing to specify an environment variable.

Created by Eric Wing.

Findosg
NOTE: It is highly recommended that you use the new FindOpenSceneGraph.cmake introduced in CMake 2.6.3
and not use this Find module directly.

This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osg This module defines

OSG_FOUND - Was the Osg found? OSG_INCLUDE_DIR - Where to find the headers OSG_LIBRARIES - The libraries
to link against for the OSG (use this)

OSG_LIBRARY - The OSG library OSG_LIBRARY_DEBUG - The OSG debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

Findosg_functions
This CMake file contains two macros to assist with searching for OSG libraries and nodekits. Please see
FindOpenSceneGraph.cmake for full documentation.

FindosgAnimation
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgAnimation This module defines

OSGANIMATION_FOUND - Was osgAnimation found? OSGANIMATION_INCLUDE_DIR - Where to find the headers
OSGANIMATION_LIBRARIES - The libraries to link against for the OSG (use this)

OSGANIMATION_LIBRARY - The OSG library OSGANIMATION_LIBRARY_DEBUG - The OSG debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgDB
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL module doesn't work with your system as an example). If
you want to use a more convenient module that includes everything, use the FindOpenSceneGraph instead of
the Findosg*.cmake modules.

Locate osgDB This module defines:

OSGDB_FOUND
Was osgDB found?

OSGDB_INCLUDE_DIR
Where to find the headers

OSGDB_LIBRARIES
The libraries to link against for the osgDB

OSGDB_LIBRARY
The osgDB library

OSGDB_LIBRARY_DEBUG
The osgDB debug library

$OSGDIR is an environment variable that would correspond to:

./configure --prefix=$OSGDIR used in building osg.

FindosgFX
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgFX This module defines

OSGFX_FOUND - Was osgFX found? OSGFX_INCLUDE_DIR - Where to find the headers OSGFX_LIBRARIES - The
libraries to link against for the osgFX (use this)

OSGFX_LIBRARY - The osgFX library OSGFX_LIBRARY_DEBUG - The osgFX debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgGA
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgGA This module defines

OSGGA_FOUND - Was osgGA found? OSGGA_INCLUDE_DIR - Where to find the headers OSGGA_LIBRARIES - The
libraries to link against for the osgGA (use this)

OSGGA_LIBRARY - The osgGA library OSGGA_LIBRARY_DEBUG - The osgGA debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgIntrospection
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgINTROSPECTION This module defines

OSGINTROSPECTION_FOUND - Was osgIntrospection found? OSGINTROSPECTION_INCLUDE_DIR - Where to find the
headers OSGINTROSPECTION_LIBRARIES - The libraries to link for osgIntrospection (use this)

OSGINTROSPECTION_LIBRARY - The osgIntrospection library OSGINTROSPECTION_LIBRARY_DEBUG - The
osgIntrospection debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgManipulator
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgManipulator This module defines

OSGMANIPULATOR_FOUND - Was osgManipulator found? OSGMANIPULATOR_INCLUDE_DIR - Where to find the headers
OSGMANIPULATOR_LIBRARIES - The libraries to link for osgManipulator (use this)

OSGMANIPULATOR_LIBRARY - The osgManipulator library OSGMANIPULATOR_LIBRARY_DEBUG - The osgManipulator
debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgParticle
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgParticle This module defines

OSGPARTICLE_FOUND - Was osgParticle found? OSGPARTICLE_INCLUDE_DIR - Where to find the headers
OSGPARTICLE_LIBRARIES - The libraries to link for osgParticle (use this)

OSGPARTICLE_LIBRARY - The osgParticle library OSGPARTICLE_LIBRARY_DEBUG - The osgParticle debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgPresentation
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgPresentation This module defines

OSGPRESENTATION_FOUND - Was osgPresentation found? OSGPRESENTATION_INCLUDE_DIR - Where to find the
headers OSGPRESENTATION_LIBRARIES - The libraries to link for osgPresentation (use this)

OSGPRESENTATION_LIBRARY - The osgPresentation library OSGPRESENTATION_LIBRARY_DEBUG - The osgPresentation
debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing. Modified to work with osgPresentation by Robert Osfield, January 2012.

FindosgProducer
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgProducer This module defines

OSGPRODUCER_FOUND - Was osgProducer found? OSGPRODUCER_INCLUDE_DIR - Where to find the headers
OSGPRODUCER_LIBRARIES - The libraries to link for osgProducer (use this)

OSGPRODUCER_LIBRARY - The osgProducer library OSGPRODUCER_LIBRARY_DEBUG - The osgProducer debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgQt
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgQt This module defines

OSGQT_FOUND - Was osgQt found? OSGQT_INCLUDE_DIR - Where to find the headers OSGQT_LIBRARIES - The
libraries to link for osgQt (use this)

OSGQT_LIBRARY - The osgQt library OSGQT_LIBRARY_DEBUG - The osgQt debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing. Modified to work with osgQt by Robert Osfield, January 2012.

FindosgShadow
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgShadow This module defines

OSGSHADOW_FOUND - Was osgShadow found? OSGSHADOW_INCLUDE_DIR - Where to find the headers
OSGSHADOW_LIBRARIES - The libraries to link for osgShadow (use this)

OSGSHADOW_LIBRARY - The osgShadow library OSGSHADOW_LIBRARY_DEBUG - The osgShadow debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgSim
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgSim This module defines

OSGSIM_FOUND - Was osgSim found? OSGSIM_INCLUDE_DIR - Where to find the headers OSGSIM_LIBRARIES - The
libraries to link for osgSim (use this)

OSGSIM_LIBRARY - The osgSim library OSGSIM_LIBRARY_DEBUG - The osgSim debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgTerrain
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgTerrain This module defines

OSGTERRAIN_FOUND - Was osgTerrain found? OSGTERRAIN_INCLUDE_DIR - Where to find the headers
OSGTERRAIN_LIBRARIES - The libraries to link for osgTerrain (use this)

OSGTERRAIN_LIBRARY - The osgTerrain library OSGTERRAIN_LIBRARY_DEBUG - The osgTerrain debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgText
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgText This module defines

OSGTEXT_FOUND - Was osgText found? OSGTEXT_INCLUDE_DIR - Where to find the headers OSGTEXT_LIBRARIES -
The libraries to link for osgText (use this)

OSGTEXT_LIBRARY - The osgText library OSGTEXT_LIBRARY_DEBUG - The osgText debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgUtil
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgUtil This module defines

OSGUTIL_FOUND - Was osgUtil found? OSGUTIL_INCLUDE_DIR - Where to find the headers OSGUTIL_LIBRARIES -
The libraries to link for osgUtil (use this)

OSGUTIL_LIBRARY - The osgUtil library OSGUTIL_LIBRARY_DEBUG - The osgUtil debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgViewer
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgViewer This module defines

OSGVIEWER_FOUND - Was osgViewer found? OSGVIEWER_INCLUDE_DIR - Where to find the headers
OSGVIEWER_LIBRARIES - The libraries to link for osgViewer (use this)

OSGVIEWER_LIBRARY - The osgViewer library OSGVIEWER_LIBRARY_DEBUG - The osgViewer debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgVolume
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgVolume This module defines

OSGVOLUME_FOUND - Was osgVolume found? OSGVOLUME_INCLUDE_DIR - Where to find the headers
OSGVOLUME_LIBRARIES - The libraries to link for osgVolume (use this)

OSGVOLUME_LIBRARY - The osgVolume library OSGVOLUME_LIBRARY_DEBUG - The osgVolume debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

Created by Eric Wing.

FindosgWidget
This is part of the Findosg* suite used to find OpenSceneGraph components. Each component is separate
and you must opt in to each module. You must also opt into OpenGL and OpenThreads (and Producer if
needed) as these modules won't do it for you. This is to allow you control over your own system piece by
piece in case you need to opt out of certain components or change the Find behavior for a particular
module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as an example).
If you want to use a more convenient module that includes everything, use the FindOpenSceneGraph.cmake
instead of the Findosg*.cmake modules.

Locate osgWidget This module defines

OSGWIDGET_FOUND - Was osgWidget found? OSGWIDGET_INCLUDE_DIR - Where to find the headers
OSGWIDGET_LIBRARIES - The libraries to link for osgWidget (use this)

OSGWIDGET_LIBRARY - The osgWidget library OSGWIDGET_LIBRARY_DEBUG - The osgWidget debug library

$OSGDIR is an environment variable that would correspond to the ./configure --prefix=$OSGDIR used in
building osg.

FindosgWidget.cmake tweaked from Findosg* suite as created by Eric Wing.

FindPatch
New in version 3.10.

The module defines the following variables:

Patch_EXECUTABLE
Path to patch command-line executable.

Patch_FOUND
True if the patch command-line executable was found.

The following IMPORTED targets are also defined:

Patch::patch
The command-line executable.

Example usage:

find_package(Patch)
if(Patch_FOUND)
message("Patch found: ${Patch_EXECUTABLE}")
endif()

FindPerl
Find perl

this module looks for Perl

PERL_EXECUTABLE - the full path to perl
PERL_FOUND - If false, don't attempt to use perl.
PERL_VERSION_STRING - version of perl found (since CMake 2.8.8)

FindPerlLibs
Find Perl libraries

This module finds if PERL is installed and determines where the include files and libraries are. It also
determines what the name of the library is. This code sets the following variables:

PERLLIBS_FOUND = True if perl.h & libperl were found
PERL_INCLUDE_PATH = path to where perl.h is found
PERL_LIBRARY = path to libperl
PERL_EXECUTABLE = full path to the perl binary

The minimum required version of Perl can be specified using the standard syntax, e.g.
find_package(PerlLibs 6.0)

The following variables are also available if needed
(introduced after CMake 2.6.4)

PERL_SITESEARCH = path to the sitesearch install dir (-V:installsitesearch)
PERL_SITEARCH = path to the sitelib install directory (-V:installsitearch)
PERL_SITELIB = path to the sitelib install directory (-V:installsitelib)
PERL_VENDORARCH = path to the vendor arch install directory (-V:installvendorarch)
PERL_VENDORLIB = path to the vendor lib install directory (-V:installvendorlib)
PERL_ARCHLIB = path to the core arch lib install directory (-V:archlib)
PERL_PRIVLIB = path to the core priv lib install directory (-V:privlib)
PERL_UPDATE_ARCHLIB = path to the update arch lib install directory (-V:installarchlib)
PERL_UPDATE_PRIVLIB = path to the update priv lib install directory (-V:installprivlib)
PERL_EXTRA_C_FLAGS = Compilation flags used to build perl

FindPHP4
Find PHP4

This module finds if PHP4 is installed and determines where the include files and libraries are. It also
determines what the name of the library is. This code sets the following variables:

PHP4_INCLUDE_PATH = path to where php.h can be found
PHP4_EXECUTABLE = full path to the php4 binary

FindPhysFS
Locate PhysFS library This module defines PHYSFS_LIBRARY, the name of the library to link against
PHYSFS_FOUND, if false, do not try to link to PHYSFS PHYSFS_INCLUDE_DIR, where to find physfs.h

$PHYSFSDIR is an environment variable that would correspond to the ./configure --prefix=$PHYSFSDIR used
in building PHYSFS.

Created by Eric Wing.

FindPike
Find Pike

This module finds if PIKE is installed and determines where the include files and libraries are. It also
determines what the name of the library is. This code sets the following variables:

PIKE_INCLUDE_PATH = path to where program.h is found
PIKE_EXECUTABLE = full path to the pike binary

FindPkgConfig
A pkg-config module for CMake.

Finds the pkg-config executable and adds the pkg_get_variable(), pkg_check_modules() and
pkg_search_module() commands. The following variables will also be set:

PKG_CONFIG_FOUND
True if a pkg-config executable was found.

PKG_CONFIG_VERSION_STRING
New in version 2.8.8.

The version of pkg-config that was found.

PKG_CONFIG_EXECUTABLE
The pathname of the pkg-config program.

PKG_CONFIG_ARGN
New in version 3.22.

A list of arguments to pass to pkg-config.

Both PKG_CONFIG_EXECUTABLE and PKG_CONFIG_ARGN are initialized by the module, but may be overridden by
the user. See Variables Affecting Behavior for how these variables are initialized.

pkg_check_modules
Checks for all the given modules, setting a variety of result variables in the calling scope.

pkg_check_modules(<prefix>
[REQUIRED] [QUIET]
[NO_CMAKE_PATH]
[NO_CMAKE_ENVIRONMENT_PATH]
[IMPORTED_TARGET [GLOBAL]]
<moduleSpec> [<moduleSpec>...])

When the REQUIRED argument is given, the command will fail with an error if module(s) could not be
found.

When the QUIET argument is given, no status messages will be printed.

New in version 3.1: The CMAKE_PREFIX_PATH, CMAKE_FRAMEWORK_PATH, and CMAKE_APPBUNDLE_PATH cache
and environment variables will be added to the pkg-config search path. The NO_CMAKE_PATH and
NO_CMAKE_ENVIRONMENT_PATH arguments disable this behavior for the cache variables and environment
variables respectively. The PKG_CONFIG_USE_CMAKE_PREFIX_PATH variable set to FALSE disables this
behavior globally.

New in version 3.6: The IMPORTED_TARGET argument will create an imported target named
PkgConfig::<prefix> that can be passed directly as an argument to target_link_libraries().

New in version 3.13: The GLOBAL argument will make the imported target available in global scope.

New in version 3.15: Non-library linker options reported by pkg-config are stored in the
INTERFACE_LINK_OPTIONS target property.

Changed in version 3.18: Include directories specified with -isystem are stored in the
INTERFACE_INCLUDE_DIRECTORIES target property. Previous versions of CMake left them in the
INTERFACE_COMPILE_OPTIONS property.

Each <moduleSpec> can be either a bare module name or it can be a module name with a version
constraint (operators =, <, >, <= and >= are supported). The following are examples for a module
named foo with various constraints:

• foo matches any version.

• foo<2 only matches versions before 2.

• foo>=3.1 matches any version from 3.1 or later.

• foo=1.2.3 requires that foo must be exactly version 1.2.3.

The following variables may be set upon return. Two sets of values exist: One for the common case
(<XXX> = <prefix>) and another for the information pkg-config provides when called with the
--static option (<XXX> = <prefix>_STATIC).

<XXX>_FOUND
set to 1 if module(s) exist

<XXX>_LIBRARIES
only the libraries (without the '-l')

<XXX>_LINK_LIBRARIES
the libraries and their absolute paths

<XXX>_LIBRARY_DIRS
the paths of the libraries (without the '-L')

<XXX>_LDFLAGS
all required linker flags

<XXX>_LDFLAGS_OTHER
all other linker flags

<XXX>_INCLUDE_DIRS
the '-I' preprocessor flags (without the '-I')

<XXX>_CFLAGS
all required cflags

<XXX>_CFLAGS_OTHER
the other compiler flags

All but <XXX>_FOUND may be a ;-list if the associated variable returned from pkg-config has
multiple values.

Changed in version 3.18: Include directories specified with -isystem are stored in the
<XXX>_INCLUDE_DIRS variable. Previous versions of CMake left them in <XXX>_CFLAGS_OTHER.

There are some special variables whose prefix depends on the number of <moduleSpec> given. When
there is only one <moduleSpec>, <YYY> will simply be <prefix>, but if two or more <moduleSpec>
items are given, <YYY> will be <prefix>_<moduleName>.

<YYY>_VERSION
version of the module

<YYY>_PREFIX
prefix directory of the module

<YYY>_INCLUDEDIR
include directory of the module

<YYY>_LIBDIR
lib directory of the module

Changed in version 3.8: For any given <prefix>, pkg_check_modules() can be called multiple times
with different parameters. Previous versions of CMake cached and returned the first successful
result.

Changed in version 3.16: If a full path to the found library can't be determined, but it's still
visible to the linker, pass it through as -l<name>. Previous versions of CMake failed in this
case.

Examples:

pkg_check_modules (GLIB2 glib-2.0)

Looks for any version of glib2. If found, the output variable GLIB2_VERSION will hold the actual
version found.

pkg_check_modules (GLIB2 glib-2.0>=2.10)

Looks for at least version 2.10 of glib2. If found, the output variable GLIB2_VERSION will hold
the actual version found.

pkg_check_modules (FOO glib-2.0>=2.10 gtk+-2.0)

Looks for both glib2-2.0 (at least version 2.10) and any version of gtk2+-2.0. Only if both are
found will FOO be considered found. The FOO_glib-2.0_VERSION and FOO_gtk+-2.0_VERSION variables
will be set to their respective found module versions.

pkg_check_modules (XRENDER REQUIRED xrender)

Requires any version of xrender. Example output variables set by a successful call:

XRENDER_LIBRARIES=Xrender;X11
XRENDER_STATIC_LIBRARIES=Xrender;X11;pthread;Xau;Xdmcp

pkg_search_module
The behavior of this command is the same as pkg_check_modules(), except that rather than checking
for all the specified modules, it searches for just the first successful match.

pkg_search_module(<prefix>
[REQUIRED] [QUIET]
[NO_CMAKE_PATH]
[NO_CMAKE_ENVIRONMENT_PATH]
[IMPORTED_TARGET [GLOBAL]]
<moduleSpec> [<moduleSpec>...])

New in version 3.16: If a module is found, the <prefix>_MODULE_NAME variable will contain the name
of the matching module. This variable can be used if you need to run pkg_get_variable().

Example:

pkg_search_module (BAR libxml-2.0 libxml2 libxml>=2)

pkg_get_variable
New in version 3.4.

Retrieves the value of a pkg-config variable varName and stores it in the result variable
resultVar in the calling scope.

pkg_get_variable(<resultVar> <moduleName> <varName>)

If pkg-config returns multiple values for the specified variable, resultVar will contain a ;-list.

For example:

pkg_get_variable(GI_GIRDIR gobject-introspection-1.0 girdir)

Variables Affecting Behavior
PKG_CONFIG_EXECUTABLE
This cache variable can be set to the path of the pkg-config executable. find_program() is called
internally by the module with this variable.

New in version 3.1: The PKG_CONFIG environment variable can be used as a hint if
PKG_CONFIG_EXECUTABLE has not yet been set.

Changed in version 3.22: If the PKG_CONFIG environment variable is set, only the first argument is
taken from it when using it as a hint.

PKG_CONFIG_ARGN
New in version 3.22.

This cache variable can be set to a list of arguments to additionally pass to pkg-config if
needed. If not provided, it will be initialized from the PKG_CONFIG environment variable, if set.
The first argument in that environment variable is assumed to be the pkg-config program, while all
remaining arguments after that are used to initialize PKG_CONFIG_ARGN. If no such environment
variable is defined, PKG_CONFIG_ARGN is initialized to an empty string. The module does not update
the variable once it has been set in the cache.

PKG_CONFIG_USE_CMAKE_PREFIX_PATH
New in version 3.1.

Specifies whether pkg_check_modules() and pkg_search_module() should add the paths in the
CMAKE_PREFIX_PATH, CMAKE_FRAMEWORK_PATH and CMAKE_APPBUNDLE_PATH cache and environment variables
to the pkg-config search path.

If this variable is not set, this behavior is enabled by default if CMAKE_MINIMUM_REQUIRED_VERSION
is 3.1 or later, disabled otherwise.

FindPNG
Find libpng, the official reference library for the PNG image format.

Imported targets
New in version 3.5.

This module defines the following IMPORTED target:

PNG::PNG
The libpng library, if found.

Result variables
This module will set the following variables in your project:

PNG_INCLUDE_DIRS
where to find png.h, etc.

PNG_LIBRARIES
the libraries to link against to use PNG.

PNG_DEFINITIONS
You should add_definitions(${PNG_DEFINITIONS}) before compiling code that includes png library
files.

PNG_FOUND
If false, do not try to use PNG.

PNG_VERSION_STRING
the version of the PNG library found (since CMake 2.8.8)

Obsolete variables
The following variables may also be set, for backwards compatibility:

PNG_LIBRARY
where to find the PNG library.

PNG_INCLUDE_DIR
where to find the PNG headers (same as PNG_INCLUDE_DIRS)

Since PNG depends on the ZLib compression library, none of the above will be defined unless ZLib can be
found.

FindPostgreSQL
Find the PostgreSQL installation.

IMPORTED Targets
New in version 3.14.

This module defines IMPORTED target PostgreSQL::PostgreSQL if PostgreSQL has been found.

Result Variables
This module will set the following variables in your project:

PostgreSQL_FOUND
True if PostgreSQL is found.

PostgreSQL_LIBRARIES
the PostgreSQL libraries needed for linking

PostgreSQL_INCLUDE_DIRS
the directories of the PostgreSQL headers

PostgreSQL_LIBRARY_DIRS
the link directories for PostgreSQL libraries

PostgreSQL_VERSION_STRING
the version of PostgreSQL found

PostgreSQL_TYPE_INCLUDE_DIR
the directories of the PostgreSQL server headers

Components
This module contains additional Server component, that forcibly checks for the presence of server
headers. Note that PostgreSQL_TYPE_INCLUDE_DIR is set regardless of the presence of the Server component
in find_package call.

FindProducer
Though Producer isn't directly part of OpenSceneGraph, its primary user is OSG so I consider this part of
the Findosg* suite used to find OpenSceneGraph components. You'll notice that I accept OSGDIR as an
environment path.

Each component is separate and you must opt in to each module. You must also opt into OpenGL (and
OpenThreads?) as these modules won't do it for you. This is to allow you control over your own system
piece by piece in case you need to opt out of certain components or change the Find behavior for a
particular module (perhaps because the default FindOpenGL.cmake module doesn't work with your system as
an example). If you want to use a more convenient module that includes everything, use the
FindOpenSceneGraph.cmake instead of the Findosg*.cmake modules.

Locate Producer This module defines PRODUCER_LIBRARY PRODUCER_FOUND, if false, do not try to link to
Producer PRODUCER_INCLUDE_DIR, where to find the headers

$PRODUCER_DIR is an environment variable that would correspond to the ./configure --prefix=$PRODUCER_DIR
used in building osg.

Created by Eric Wing.

FindProtobuf
Locate and configure the Google Protocol Buffers library.

New in version 3.6: Support for find_package() version checks.

Changed in version 3.6: All input and output variables use the Protobuf_ prefix. Variables with
PROTOBUF_ prefix are still supported for compatibility.

The following variables can be set and are optional:

Protobuf_SRC_ROOT_FOLDER
When compiling with MSVC, if this cache variable is set the protobuf-default VS project build
locations (vsprojects/Debug and vsprojects/Release or vsprojects/x64/Debug and
vsprojects/x64/Release) will be searched for libraries and binaries.

Protobuf_IMPORT_DIRS
List of additional directories to be searched for imported .proto files.

Protobuf_DEBUG
New in version 3.6.

Show debug messages.

Protobuf_USE_STATIC_LIBS
New in version 3.9.

Set to ON to force the use of the static libraries. Default is OFF.

Defines the following variables:

Protobuf_FOUND
Found the Google Protocol Buffers library (libprotobuf & header files)

Protobuf_VERSION
New in version 3.6.

Version of package found.

Protobuf_INCLUDE_DIRS
Include directories for Google Protocol Buffers

Protobuf_LIBRARIES
The protobuf libraries

Protobuf_PROTOC_LIBRARIES
The protoc libraries

Protobuf_LITE_LIBRARIES
The protobuf-lite libraries

New in version 3.9: The following IMPORTED targets are also defined:

protobuf::libprotobuf
The protobuf library.

protobuf::libprotobuf-lite
The protobuf lite library.

protobuf::libprotoc
The protoc library.

protobuf::protoc
New in version 3.10: The protoc compiler.

The following cache variables are also available to set or use:

Protobuf_LIBRARY
The protobuf library

Protobuf_PROTOC_LIBRARY
The protoc library

Protobuf_INCLUDE_DIR
The include directory for protocol buffers

Protobuf_PROTOC_EXECUTABLE
The protoc compiler

Protobuf_LIBRARY_DEBUG
The protobuf library (debug)

Protobuf_PROTOC_LIBRARY_DEBUG
The protoc library (debug)

Protobuf_LITE_LIBRARY
The protobuf lite library

Protobuf_LITE_LIBRARY_DEBUG
The protobuf lite library (debug)

Example:

find_package(Protobuf REQUIRED)
include_directories(${Protobuf_INCLUDE_DIRS})
include_directories(${CMAKE_CURRENT_BINARY_DIR})
protobuf_generate_cpp(PROTO_SRCS PROTO_HDRS foo.proto)
protobuf_generate_cpp(PROTO_SRCS PROTO_HDRS EXPORT_MACRO DLL_EXPORT foo.proto)
protobuf_generate_cpp(PROTO_SRCS PROTO_HDRS DESCRIPTORS PROTO_DESCS foo.proto)
protobuf_generate_python(PROTO_PY foo.proto)
add_executable(bar bar.cc ${PROTO_SRCS} ${PROTO_HDRS})
target_link_libraries(bar ${Protobuf_LIBRARIES})

NOTE:
The protobuf_generate_cpp and protobuf_generate_python functions and add_executable() or add_library()
calls only work properly within the same directory.

protobuf_generate_cpp
Add custom commands to process .proto files to C++:

protobuf_generate_cpp (<SRCS> <HDRS>
[DESCRIPTORS <DESC>] [EXPORT_MACRO <MACRO>] [<ARGN>...])

SRCS Variable to define with autogenerated source files

HDRS Variable to define with autogenerated header files

DESCRIPTORS
New in version 3.10: Variable to define with autogenerated descriptor files, if requested.

EXPORT_MACRO
is a macro which should expand to __declspec(dllexport) or __declspec(dllimport) depending
on what is being compiled.

ARGN .proto files

protobuf_generate_python
New in version 3.4.

Add custom commands to process .proto files to Python:

protobuf_generate_python (<PY> [<ARGN>...])

PY Variable to define with autogenerated Python files

ARGN .proto files

FindPython
New in version 3.12.

Find Python interpreter, compiler and development environment (include directories and libraries).

The following components are supported:

• Interpreter: search for Python interpreter.

• Compiler: search for Python compiler. Only offered by IronPython.

• Development: search for development artifacts (include directories and libraries).

New in version 3.18: This component includes two sub-components which can be specified independently:

• Development.Module: search for artifacts for Python module developments.

• Development.Embed: search for artifacts for Python embedding developments.

• NumPy: search for NumPy include directories.

New in version 3.14: Added the NumPy component.

If no COMPONENTS are specified, Interpreter is assumed.

If component Development is specified, it implies sub-components Development.Module and
Development.Embed.

To ensure consistent versions between components Interpreter, Compiler, Development (or one of its
sub-components) and NumPy, specify all components at the same time:

find_package (Python COMPONENTS Interpreter Development)

This module looks preferably for version 3 of Python. If not found, version 2 is searched. To manage
concurrent versions 3 and 2 of Python, use FindPython3 and FindPython2 modules rather than this one.

NOTE:
If components Interpreter and Development (or one of its sub-components) are both specified, this
module search only for interpreter with same platform architecture as the one defined by CMake
configuration. This constraint does not apply if only Interpreter component is specified.

Imported Targets
This module defines the following Imported Targets:

Changed in version 3.14: Imported Targets are only created when CMAKE_ROLE is PROJECT.

Python::Interpreter
Python interpreter. Target defined if component Interpreter is found.

Python::Compiler
Python compiler. Target defined if component Compiler is found.

Python::Module
New in version 3.15.

Python library for Python module. Target defined if component Development.Module is found.

Python::Python
Python library for Python embedding. Target defined if component Development.Embed is found.

Python::NumPy
New in version 3.14.

NumPy Python library. Target defined if component NumPy is found.

Result Variables
This module will set the following variables in your project (see Standard Variable Names):

Python_FOUND
System has the Python requested components.

Python_Interpreter_FOUND
System has the Python interpreter.

Python_EXECUTABLE
Path to the Python interpreter.

Python_INTERPRETER_ID

A short string unique to the interpreter. Possible values include:

• Python

• ActivePython

• Anaconda

• Canopy

• IronPython

• PyPy

Python_STDLIB
Standard platform independent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=False,standard_lib=True)
or else sysconfig.get_path('stdlib').

Python_STDARCH
Standard platform dependent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=True,standard_lib=True)
or else sysconfig.get_path('platstdlib').

Python_SITELIB
Third-party platform independent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=False,standard_lib=False)
or else sysconfig.get_path('purelib').

Python_SITEARCH
Third-party platform dependent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=True,standard_lib=False)
or else sysconfig.get_path('platlib').

Python_SOABI
New in version 3.17.

Extension suffix for modules.

Information returned by distutils.sysconfig.get_config_var('SOABI') or computed from
distutils.sysconfig.get_config_var('EXT_SUFFIX') or python-config --extension-suffix. If package
distutils.sysconfig is not available, sysconfig.get_config_var('SOABI') or
sysconfig.get_config_var('EXT_SUFFIX') are used.

Python_Compiler_FOUND
System has the Python compiler.

Python_COMPILER
Path to the Python compiler. Only offered by IronPython.

Python_COMPILER_ID

A short string unique to the compiler. Possible values include:

• IronPython

Python_DOTNET_LAUNCHER
New in version 3.18.

The .Net interpreter. Only used by IronPython implementation.

Python_Development_FOUND
System has the Python development artifacts.

Python_Development.Module_FOUND
New in version 3.18.

System has the Python development artifacts for Python module.

Python_Development.Embed_FOUND
New in version 3.18.

System has the Python development artifacts for Python embedding.

Python_INCLUDE_DIRS
The Python include directories.

Python_LINK_OPTIONS
New in version 3.19.

The Python link options. Some configurations require specific link options for a correct build and
execution.

Python_LIBRARIES
The Python libraries.

Python_LIBRARY_DIRS
The Python library directories.

Python_RUNTIME_LIBRARY_DIRS
The Python runtime library directories.

Python_VERSION
Python version.

Python_VERSION_MAJOR
Python major version.

Python_VERSION_MINOR
Python minor version.

Python_VERSION_PATCH
Python patch version.

Python_PyPy_VERSION
New in version 3.18.

Python PyPy version.

Python_NumPy_FOUND
New in version 3.14.

System has the NumPy.

Python_NumPy_INCLUDE_DIRS
New in version 3.14.

The NumPy include directories.

Python_NumPy_VERSION
New in version 3.14.

The NumPy version.

Hints
Python_ROOT_DIR
Define the root directory of a Python installation.

Python_USE_STATIC_LIBS

• If not defined, search for shared libraries and static libraries in that order.

• If set to TRUE, search only for static libraries.

• If set to FALSE, search only for shared libraries.

NOTE:
This hint will be ignored on Windows because static libraries are not available on this
platform.

Python_FIND_ABI
New in version 3.16.

This variable defines which ABIs, as defined in PEP 3149, should be searched.

NOTE:
This hint will be honored only when searched for Python version 3.

NOTE:
If Python_FIND_ABI is not defined, any ABI will be searched.

The Python_FIND_ABI variable is a 3-tuple specifying, in that order, pydebug (d), pymalloc (m) and
unicode (u) flags. Each element can be set to one of the following:

• ON: Corresponding flag is selected.

• OFF: Corresponding flag is not selected.

• ANY: The two possibilities (ON and OFF) will be searched.

From this 3-tuple, various ABIs will be searched starting from the most specialized to the most
general. Moreover, debug versions will be searched after non-debug ones.

For example, if we have:

set (Python_FIND_ABI "ON" "ANY" "ANY")

The following flags combinations will be appended, in that order, to the artifact names: dmu, dm,
du, and d.

And to search any possible ABIs:

set (Python_FIND_ABI "ANY" "ANY" "ANY")

The following combinations, in that order, will be used: mu, m, u, <empty>, dmu, dm, du and d.

NOTE:
This hint is useful only on POSIX systems. So, on Windows systems, when Python_FIND_ABI is
defined, Python distributions from python.org will be found only if value for each flag is OFF
or ANY.

Python_FIND_STRATEGY
New in version 3.15.

This variable defines how lookup will be done. The Python_FIND_STRATEGY variable can be set to
one of the following:

• VERSION: Try to find the most recent version in all specified locations. This is the default if
policy CMP0094 is undefined or set to OLD.

• LOCATION: Stops lookup as soon as a version satisfying version constraints is founded. This is
the default if policy CMP0094 is set to NEW.

Python_FIND_REGISTRY
New in version 3.13.

On Windows the Python_FIND_REGISTRY variable determine the order of preference between registry
and environment variables. the Python_FIND_REGISTRY variable can be set to one of the following:

• FIRST: Try to use registry before environment variables. This is the default.

• LAST: Try to use registry after environment variables.

• NEVER: Never try to use registry.

Python_FIND_FRAMEWORK
New in version 3.15.

On macOS the Python_FIND_FRAMEWORK variable determine the order of preference between Apple-style
and unix-style package components. This variable can take same values as CMAKE_FIND_FRAMEWORK
variable.

NOTE:
Value ONLY is not supported so FIRST will be used instead.

If Python_FIND_FRAMEWORK is not defined, CMAKE_FIND_FRAMEWORK variable will be used, if any.

Python_FIND_VIRTUALENV
New in version 3.15.

This variable defines the handling of virtual environments managed by virtualenv or conda. It is
meaningful only when a virtual environment is active (i.e. the activate script has been
evaluated). In this case, it takes precedence over Python_FIND_REGISTRY and CMAKE_FIND_FRAMEWORK
variables. The Python_FIND_VIRTUALENV variable can be set to one of the following:

• FIRST: The virtual environment is used before any other standard paths to look-up for the
interpreter. This is the default.

• ONLY: Only the virtual environment is used to look-up for the interpreter.

• STANDARD: The virtual environment is not used to look-up for the interpreter but environment
variable PATH is always considered. In this case, variable Python_FIND_REGISTRY (Windows) or
CMAKE_FIND_FRAMEWORK (macOS) can be set with value LAST or NEVER to select preferably the
interpreter from the virtual environment.

New in version 3.17: Added support for conda environments.

NOTE:
If the component Development is requested, it is strongly recommended to also include the
component Interpreter to get expected result.

Python_FIND_IMPLEMENTATIONS
New in version 3.18.

This variable defines, in an ordered list, the different implementations which will be searched.
The Python_FIND_IMPLEMENTATIONS variable can hold the following values:

• CPython: this is the standard implementation. Various products, like Anaconda or ActivePython,
rely on this implementation.

• IronPython: This implementation use the CSharp language for .NET Framework on top of the Dynamic
Language Runtime (DLR). See IronPython.

• PyPy: This implementation use RPython language and RPython translation toolchain to produce the
python interpreter. See PyPy.

The default value is:

• Windows platform: CPython, IronPython

• Other platforms: CPython

NOTE:
This hint has the lowest priority of all hints, so even if, for example, you specify IronPython
first and CPython in second, a python product based on CPython can be selected because, for
example with Python_FIND_STRATEGY=LOCATION, each location will be search first for IronPython
and second for CPython.

NOTE:
When IronPython is specified, on platforms other than Windows, the .Net interpreter (i.e. mono
command) is expected to be available through the PATH variable.

Python_FIND_UNVERSIONED_NAMES
New in version 3.20.

This variable defines how the generic names will be searched. Currently, it only applies to the
generic names of the interpreter, namely, python3 or python2 and python. The
Python_FIND_UNVERSIONED_NAMES variable can be set to one of the following values:

• FIRST: The generic names are searched before the more specialized ones (such as python2.5 for
example).

• LAST: The generic names are searched after the more specialized ones. This is the default.

• NEVER: The generic name are not searched at all.

Artifacts Specification
New in version 3.16.

To solve special cases, it is possible to specify directly the artifacts by setting the following
variables:

Python_EXECUTABLE
The path to the interpreter.

Python_COMPILER
The path to the compiler.

Python_DOTNET_LAUNCHER
New in version 3.18.

The .Net interpreter. Only used by IronPython implementation.

Python_LIBRARY
The path to the library. It will be used to compute the variables Python_LIBRARIES,
Python_LIBRARY_DIRS and Python_RUNTIME_LIBRARY_DIRS.

Python_INCLUDE_DIR
The path to the directory of the Python headers. It will be used to compute the variable
Python_INCLUDE_DIRS.

Python_NumPy_INCLUDE_DIR
The path to the directory of the NumPy headers. It will be used to compute the variable
Python_NumPy_INCLUDE_DIRS.

NOTE:
All paths must be absolute. Any artifact specified with a relative path will be ignored.

NOTE:
When an artifact is specified, all HINTS will be ignored and no search will be performed for this
artifact.

If more than one artifact is specified, it is the user's responsibility to ensure the consistency of
the various artifacts.

By default, this module supports multiple calls in different directories of a project with different
version/component requirements while providing correct and consistent results for each call. To support
this behavior, CMake cache is not used in the traditional way which can be problematic for interactive
specification. So, to enable also interactive specification, module behavior can be controlled with the
following variable:

Python_ARTIFACTS_INTERACTIVE
New in version 3.18.

Selects the behavior of the module. This is a boolean variable:

• If set to TRUE: Create CMake cache entries for the above artifact specification variables so
that users can edit them interactively. This disables support for multiple version/component
requirements.

• If set to FALSE or undefined: Enable multiple version/component requirements.

Commands
This module defines the command Python_add_library (when CMAKE_ROLE is PROJECT), which has the same
semantics as add_library() and adds a dependency to target Python::Python or, when library type is
MODULE, to target Python::Module and takes care of Python module naming rules:

Python_add_library (<name> [STATIC | SHARED | MODULE [WITH_SOABI]]
<source1> [<source2> ...])

If the library type is not specified, MODULE is assumed.

New in version 3.17: For MODULE library type, if option WITH_SOABI is specified, the module suffix will
include the Python_SOABI value, if any.

FindPython2
New in version 3.12.

Find Python 2 interpreter, compiler and development environment (include directories and libraries).

The following components are supported:

• Interpreter: search for Python 2 interpreter

• Compiler: search for Python 2 compiler. Only offered by IronPython.

• Development: search for development artifacts (include directories and libraries).

New in version 3.18: This component includes two sub-components which can be specified independently:

• Development.Module: search for artifacts for Python 2 module developments.

• Development.Embed: search for artifacts for Python 2 embedding developments.

• NumPy: search for NumPy include directories.

New in version 3.14: Added the NumPy component.

If no COMPONENTS are specified, Interpreter is assumed.

If component Development is specified, it implies sub-components Development.Module and
Development.Embed.

To ensure consistent versions between components Interpreter, Compiler, Development (or one of its
sub-components) and NumPy, specify all components at the same time:

find_package (Python2 COMPONENTS Interpreter Development)

This module looks only for version 2 of Python. This module can be used concurrently with FindPython3
module to use both Python versions.

The FindPython module can be used if Python version does not matter for you.

Imported Targets
This module defines the following Imported Targets:

Changed in version 3.14: Imported Targets are only created when CMAKE_ROLE is PROJECT.

Python2::Interpreter
Python 2 interpreter. Target defined if component Interpreter is found.

Python2::Compiler
Python 2 compiler. Target defined if component Compiler is found.

Python2::Module
New in version 3.15.

Python 2 library for Python module. Target defined if component Development.Module is found.

Python2::Python
Python 2 library for Python embedding. Target defined if component Development.Embed is found.

Python2::NumPy
New in version 3.14.

NumPy library for Python 2. Target defined if component NumPy is found.

Result Variables
This module will set the following variables in your project (see Standard Variable Names):

Python2_FOUND
System has the Python 2 requested components.

Python2_Interpreter_FOUND
System has the Python 2 interpreter.

Python2_EXECUTABLE
Path to the Python 2 interpreter.

Python2_INTERPRETER_ID

A short string unique to the interpreter. Possible values include:

• Python

• ActivePython

• Anaconda

• Canopy

• IronPython

• PyPy

Python2_STDLIB
Standard platform independent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=False,standard_lib=True)
or else sysconfig.get_path('stdlib').

Python2_STDARCH
Standard platform dependent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=True,standard_lib=True)
or else sysconfig.get_path('platstdlib').

Python2_SITELIB
Third-party platform independent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=False,standard_lib=False)
or else sysconfig.get_path('purelib').

Python2_SITEARCH
Third-party platform dependent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=True,standard_lib=False)
or else sysconfig.get_path('platlib').

Python2_Compiler_FOUND
System has the Python 2 compiler.

Python2_COMPILER
Path to the Python 2 compiler. Only offered by IronPython.

Python2_COMPILER_ID

A short string unique to the compiler. Possible values include:

• IronPython

Python2_DOTNET_LAUNCHER
New in version 3.18.

The .Net interpreter. Only used by IronPython implementation.

Python2_Development_FOUND
System has the Python 2 development artifacts.

Python2_Development.Module_FOUND
New in version 3.18.

System has the Python 2 development artifacts for Python module.

Python2_Development.Embed_FOUND
New in version 3.18.

System has the Python 2 development artifacts for Python embedding.

Python2_INCLUDE_DIRS
The Python 2 include directories.

Python2_LINK_OPTIONS
New in version 3.19.

The Python 2 link options. Some configurations require specific link options for a correct build
and execution.

Python2_LIBRARIES
The Python 2 libraries.

Python2_LIBRARY_DIRS
The Python 2 library directories.

Python2_RUNTIME_LIBRARY_DIRS
The Python 2 runtime library directories.

Python2_VERSION
Python 2 version.

Python2_VERSION_MAJOR
Python 2 major version.

Python2_VERSION_MINOR
Python 2 minor version.

Python2_VERSION_PATCH
Python 2 patch version.

Python2_PyPy_VERSION
New in version 3.18.

Python 2 PyPy version.

Python2_NumPy_FOUND
New in version 3.14.

System has the NumPy.

Python2_NumPy_INCLUDE_DIRS
New in version 3.14.

The NumPy include directories.

Python2_NumPy_VERSION
New in version 3.14.

The NumPy version.

Hints
Python2_ROOT_DIR
Define the root directory of a Python 2 installation.

Python2_USE_STATIC_LIBS

• If not defined, search for shared libraries and static libraries in that order.

• If set to TRUE, search only for static libraries.

• If set to FALSE, search only for shared libraries.

NOTE:
This hint will be ignored on Windows because static libraries are not available on this
platform.

Python2_FIND_STRATEGY
New in version 3.15.

This variable defines how lookup will be done. The Python2_FIND_STRATEGY variable can be set to
one of the following:

• VERSION: Try to find the most recent version in all specified locations. This is the default if
policy CMP0094 is undefined or set to OLD.

• LOCATION: Stops lookup as soon as a version satisfying version constraints is founded. This is
the default if policy CMP0094 is set to NEW.

Python2_FIND_REGISTRY
New in version 3.13.

On Windows the Python2_FIND_REGISTRY variable determine the order of preference between registry
and environment variables. the Python2_FIND_REGISTRY variable can be set to one of the following:

• FIRST: Try to use registry before environment variables. This is the default.

• LAST: Try to use registry after environment variables.

• NEVER: Never try to use registry.

Python2_FIND_FRAMEWORK
New in version 3.15.

On macOS the Python2_FIND_FRAMEWORK variable determine the order of preference between Apple-style
and unix-style package components. This variable can take same values as CMAKE_FIND_FRAMEWORK
variable.

NOTE:
Value ONLY is not supported so FIRST will be used instead.

If Python2_FIND_FRAMEWORK is not defined, CMAKE_FIND_FRAMEWORK variable will be used, if any.

Python2_FIND_VIRTUALENV
New in version 3.15.

This variable defines the handling of virtual environments managed by virtualenv or conda. It is
meaningful only when a virtual environment is active (i.e. the activate script has been
evaluated). In this case, it takes precedence over Python2_FIND_REGISTRY and CMAKE_FIND_FRAMEWORK
variables. The Python2_FIND_VIRTUALENV variable can be set to one of the following:

• FIRST: The virtual environment is used before any other standard paths to look-up for the
interpreter. This is the default.

• ONLY: Only the virtual environment is used to look-up for the interpreter.

• STANDARD: The virtual environment is not used to look-up for the interpreter but environment
variable PATH is always considered. In this case, variable Python2_FIND_REGISTRY (Windows) or
CMAKE_FIND_FRAMEWORK (macOS) can be set with value LAST or NEVER to select preferably the
interpreter from the virtual environment.

New in version 3.17: Added support for conda environments.

NOTE:
If the component Development is requested, it is strongly recommended to also include the
component Interpreter to get expected result.

Python2_FIND_IMPLEMENTATIONS
New in version 3.18.

This variable defines, in an ordered list, the different implementations which will be searched.
The Python2_FIND_IMPLEMENTATIONS variable can hold the following values:

• CPython: this is the standard implementation. Various products, like Anaconda or ActivePython,
rely on this implementation.

• IronPython: This implementation use the CSharp language for .NET Framework on top of the Dynamic
Language Runtime (DLR). See IronPython.

• PyPy: This implementation use RPython language and RPython translation toolchain to produce the
python interpreter. See PyPy.

The default value is:

• Windows platform: CPython, IronPython

• Other platforms: CPython

NOTE:
This hint has the lowest priority of all hints, so even if, for example, you specify IronPython
first and CPython in second, a python product based on CPython can be selected because, for
example with Python2_FIND_STRATEGY=LOCATION, each location will be search first for IronPython
and second for CPython.

NOTE:
When IronPython is specified, on platforms other than Windows, the .Net interpreter (i.e. mono
command) is expected to be available through the PATH variable.

Python2_FIND_UNVERSIONED_NAMES
New in version 3.20.

This variable defines how the generic names will be searched. Currently, it only applies to the
generic names of the interpreter, namely, python2 and python. The Python2_FIND_UNVERSIONED_NAMES
variable can be set to one of the following values:

• FIRST: The generic names are searched before the more specialized ones (such as python2.5 for
example).

• LAST: The generic names are searched after the more specialized ones. This is the default.

• NEVER: The generic name are not searched at all.

Artifacts Specification
New in version 3.16.

To solve special cases, it is possible to specify directly the artifacts by setting the following
variables:

Python2_EXECUTABLE
The path to the interpreter.

Python2_COMPILER
The path to the compiler.

Python2_DOTNET_LAUNCHER
New in version 3.18.

The .Net interpreter. Only used by IronPython implementation.

Python2_LIBRARY
The path to the library. It will be used to compute the variables Python2_LIBRARIES,
Python2_LIBRARY_DIRS and Python2_RUNTIME_LIBRARY_DIRS.

Python2_INCLUDE_DIR
The path to the directory of the Python headers. It will be used to compute the variable
Python2_INCLUDE_DIRS.

Python2_NumPy_INCLUDE_DIR
The path to the directory of the NumPy headers. It will be used to compute the variable
Python2_NumPy_INCLUDE_DIRS.

NOTE:
All paths must be absolute. Any artifact specified with a relative path will be ignored.

NOTE:
When an artifact is specified, all HINTS will be ignored and no search will be performed for this
artifact.

If more than one artifact is specified, it is the user's responsibility to ensure the consistency of
the various artifacts.

Python2_ARTIFACTS_INTERACTIVE
New in version 3.18.

Selects the behavior of the module. This is a boolean variable:

• If set to FALSE or undefined: Enable multiple version/component requirements.

Commands
This module defines the command Python2_add_library (when CMAKE_ROLE is PROJECT), which has the same
semantics as add_library() and adds a dependency to target Python2::Python or, when library type is
MODULE, to target Python2::Module and takes care of Python module naming rules:

Python2_add_library (<name> [STATIC | SHARED | MODULE]
<source1> [<source2> ...])

If library type is not specified, MODULE is assumed.

FindPython3
New in version 3.12.

Find Python 3 interpreter, compiler and development environment (include directories and libraries).

The following components are supported:

• Interpreter: search for Python 3 interpreter

• Compiler: search for Python 3 compiler. Only offered by IronPython.

• Development: search for development artifacts (include directories and libraries).

New in version 3.18: This component includes two sub-components which can be specified independently:

• Development.Module: search for artifacts for Python 3 module developments.

• Development.Embed: search for artifacts for Python 3 embedding developments.

• NumPy: search for NumPy include directories.

New in version 3.14: Added the NumPy component.

If no COMPONENTS are specified, Interpreter is assumed.

If component Development is specified, it implies sub-components Development.Module and
Development.Embed.

To ensure consistent versions between components Interpreter, Compiler, Development (or one of its
sub-components) and NumPy, specify all components at the same time:

find_package (Python3 COMPONENTS Interpreter Development)

This module looks only for version 3 of Python. This module can be used concurrently with FindPython2
module to use both Python versions.

The FindPython module can be used if Python version does not matter for you.

Imported Targets
This module defines the following Imported Targets:

Changed in version 3.14: Imported Targets are only created when CMAKE_ROLE is PROJECT.

Python3::Interpreter
Python 3 interpreter. Target defined if component Interpreter is found.

Python3::Compiler
Python 3 compiler. Target defined if component Compiler is found.

Python3::Module
New in version 3.15.

Python 3 library for Python module. Target defined if component Development.Module is found.

Python3::Python
Python 3 library for Python embedding. Target defined if component Development.Embed is found.

Python3::NumPy
New in version 3.14.

NumPy library for Python 3. Target defined if component NumPy is found.

Result Variables
This module will set the following variables in your project (see Standard Variable Names):

Python3_FOUND
System has the Python 3 requested components.

Python3_Interpreter_FOUND
System has the Python 3 interpreter.

Python3_EXECUTABLE
Path to the Python 3 interpreter.

Python3_INTERPRETER_ID

A short string unique to the interpreter. Possible values include:

• Python

• ActivePython

• Anaconda

• Canopy

• IronPython

• PyPy

Python3_STDLIB
Standard platform independent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=False,standard_lib=True)
or else sysconfig.get_path('stdlib').

Python3_STDARCH
Standard platform dependent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=True,standard_lib=True)
or else sysconfig.get_path('platstdlib').

Python3_SITELIB
Third-party platform independent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=False,standard_lib=False)
or else sysconfig.get_path('purelib').

Python3_SITEARCH
Third-party platform dependent installation directory.

Information returned by distutils.sysconfig.get_python_lib(plat_specific=True,standard_lib=False)
or else sysconfig.get_path('platlib').

Python3_SOABI
New in version 3.17.

Extension suffix for modules.

Information returned by distutils.sysconfig.get_config_var('SOABI') or computed from
distutils.sysconfig.get_config_var('EXT_SUFFIX') or python3-config --extension-suffix. If package
distutils.sysconfig is not available, sysconfig.get_config_var('SOABI') or
sysconfig.get_config_var('EXT_SUFFIX') are used.

Python3_Compiler_FOUND
System has the Python 3 compiler.

Python3_COMPILER
Path to the Python 3 compiler. Only offered by IronPython.

Python3_COMPILER_ID

A short string unique to the compiler. Possible values include:

• IronPython

Python3_DOTNET_LAUNCHER
New in version 3.18.

The .Net interpreter. Only used by IronPython implementation.

Python3_Development_FOUND
System has the Python 3 development artifacts.

Python3_Development.Module_FOUND
New in version 3.18.

System has the Python 3 development artifacts for Python module.

Python3_Development.Embed_FOUND
New in version 3.18.

System has the Python 3 development artifacts for Python embedding.

Python3_INCLUDE_DIRS
The Python 3 include directories.

Python3_LINK_OPTIONS
New in version 3.19.

The Python 3 link options. Some configurations require specific link options for a correct build
and execution.

Python3_LIBRARIES
The Python 3 libraries.

Python3_LIBRARY_DIRS
The Python 3 library directories.

Python3_RUNTIME_LIBRARY_DIRS
The Python 3 runtime library directories.

Python3_VERSION
Python 3 version.

Python3_VERSION_MAJOR
Python 3 major version.

Python3_VERSION_MINOR
Python 3 minor version.

Python3_VERSION_PATCH
Python 3 patch version.

Python3_PyPy_VERSION
New in version 3.18.

Python 3 PyPy version.

Python3_NumPy_FOUND
New in version 3.14.

System has the NumPy.

Python3_NumPy_INCLUDE_DIRS
New in version 3.14.

The NumPy include directories.

Python3_NumPy_VERSION
New in version 3.14.

The NumPy version.

Hints
Python3_ROOT_DIR
Define the root directory of a Python 3 installation.

Python3_USE_STATIC_LIBS

• If not defined, search for shared libraries and static libraries in that order.

• If set to TRUE, search only for static libraries.

• If set to FALSE, search only for shared libraries.

NOTE:
This hint will be ignored on Windows because static libraries are not available on this
platform.

Python3_FIND_ABI
New in version 3.16.

This variable defines which ABIs, as defined in PEP 3149, should be searched.

NOTE:
If Python3_FIND_ABI is not defined, any ABI will be searched.

The Python3_FIND_ABI variable is a 3-tuple specifying, in that order, pydebug (d), pymalloc (m)
and unicode (u) flags. Each element can be set to one of the following:

• ON: Corresponding flag is selected.

• OFF: Corresponding flag is not selected.

• ANY: The two possibilities (ON and OFF) will be searched.

From this 3-tuple, various ABIs will be searched starting from the most specialized to the most
general. Moreover, debug versions will be searched after non-debug ones.

For example, if we have:

set (Python3_FIND_ABI "ON" "ANY" "ANY")

The following flags combinations will be appended, in that order, to the artifact names: dmu, dm,
du, and d.

And to search any possible ABIs:

set (Python3_FIND_ABI "ANY" "ANY" "ANY")

The following combinations, in that order, will be used: mu, m, u, <empty>, dmu, dm, du and d.

NOTE:
This hint is useful only on POSIX systems. So, on Windows systems, when Python3_FIND_ABI is
defined, Python distributions from python.org will be found only if value for each flag is OFF
or ANY.

Python3_FIND_STRATEGY
New in version 3.15.

This variable defines how lookup will be done. The Python3_FIND_STRATEGY variable can be set to
one of the following:

• VERSION: Try to find the most recent version in all specified locations. This is the default if
policy CMP0094 is undefined or set to OLD.

• LOCATION: Stops lookup as soon as a version satisfying version constraints is founded. This is
the default if policy CMP0094 is set to NEW.

Python3_FIND_REGISTRY
New in version 3.13.

On Windows the Python3_FIND_REGISTRY variable determine the order of preference between registry
and environment variables. The Python3_FIND_REGISTRY variable can be set to one of the following:

• FIRST: Try to use registry before environment variables. This is the default.

• LAST: Try to use registry after environment variables.

• NEVER: Never try to use registry.

Python3_FIND_FRAMEWORK
New in version 3.15.

On macOS the Python3_FIND_FRAMEWORK variable determine the order of preference between Apple-style
and unix-style package components. This variable can take same values as CMAKE_FIND_FRAMEWORK
variable.

NOTE:
Value ONLY is not supported so FIRST will be used instead.

If Python3_FIND_FRAMEWORK is not defined, CMAKE_FIND_FRAMEWORK variable will be used, if any.

Python3_FIND_VIRTUALENV
New in version 3.15.

This variable defines the handling of virtual environments managed by virtualenv or conda. It is
meaningful only when a virtual environment is active (i.e. the activate script has been
evaluated). In this case, it takes precedence over Python3_FIND_REGISTRY and CMAKE_FIND_FRAMEWORK
variables. The Python3_FIND_VIRTUALENV variable can be set to one of the following:

• FIRST: The virtual environment is used before any other standard paths to look-up for the
interpreter. This is the default.

• ONLY: Only the virtual environment is used to look-up for the interpreter.

• STANDARD: The virtual environment is not used to look-up for the interpreter but environment
variable PATH is always considered. In this case, variable Python3_FIND_REGISTRY (Windows) or
CMAKE_FIND_FRAMEWORK (macOS) can be set with value LAST or NEVER to select preferably the
interpreter from the virtual environment.

New in version 3.17: Added support for conda environments.

NOTE:
If the component Development is requested, it is strongly recommended to also include the
component Interpreter to get expected result.

Python3_FIND_IMPLEMENTATIONS
New in version 3.18.

This variable defines, in an ordered list, the different implementations which will be searched.
The Python3_FIND_IMPLEMENTATIONS variable can hold the following values:

• CPython: this is the standard implementation. Various products, like Anaconda or ActivePython,
rely on this implementation.

• IronPython: This implementation use the CSharp language for .NET Framework on top of the Dynamic
Language Runtime (DLR). See IronPython.

• PyPy: This implementation use RPython language and RPython translation toolchain to produce the
python interpreter. See PyPy.

The default value is:

• Windows platform: CPython, IronPython

• Other platforms: CPython

NOTE:
This hint has the lowest priority of all hints, so even if, for example, you specify IronPython
first and CPython in second, a python product based on CPython can be selected because, for
example with Python3_FIND_STRATEGY=LOCATION, each location will be search first for IronPython
and second for CPython.

NOTE:
When IronPython is specified, on platforms other than Windows, the .Net interpreter (i.e. mono
command) is expected to be available through the PATH variable.

Python3_FIND_UNVERSIONED_NAMES
New in version 3.20.

This variable defines how the generic names will be searched. Currently, it only applies to the
generic names of the interpreter, namely, python3 and python. The Python3_FIND_UNVERSIONED_NAMES
variable can be set to one of the following values:

• FIRST: The generic names are searched before the more specialized ones (such as python3.5 for
example).

• LAST: The generic names are searched after the more specialized ones. This is the default.

• NEVER: The generic name are not searched at all.

Artifacts Specification
New in version 3.16.

To solve special cases, it is possible to specify directly the artifacts by setting the following
variables:

Python3_EXECUTABLE
The path to the interpreter.

Python3_COMPILER
The path to the compiler.

Python3_DOTNET_LAUNCHER
New in version 3.18.

The .Net interpreter. Only used by IronPython implementation.

Python3_LIBRARY
The path to the library. It will be used to compute the variables Python3_LIBRARIES,
Python3_LIBRARY_DIRS and Python3_RUNTIME_LIBRARY_DIRS.

Python3_INCLUDE_DIR
The path to the directory of the Python headers. It will be used to compute the variable
Python3_INCLUDE_DIRS.

Python3_NumPy_INCLUDE_DIR
The path to the directory of the NumPy headers. It will be used to compute the variable
Python3_NumPy_INCLUDE_DIRS.

NOTE:
All paths must be absolute. Any artifact specified with a relative path will be ignored.

NOTE:
When an artifact is specified, all HINTS will be ignored and no search will be performed for this
artifact.

If more than one artifact is specified, it is the user's responsibility to ensure the consistency of
the various artifacts.

Python3_ARTIFACTS_INTERACTIVE
New in version 3.18.

Selects the behavior of the module. This is a boolean variable:

• If set to FALSE or undefined: Enable multiple version/component requirements.

Commands
This module defines the command Python3_add_library (when CMAKE_ROLE is PROJECT), which has the same
semantics as add_library() and adds a dependency to target Python3::Python or, when library type is
MODULE, to target Python3::Module and takes care of Python module naming rules:

Python3_add_library (<name> [STATIC | SHARED | MODULE [WITH_SOABI]]
<source1> [<source2> ...])

If the library type is not specified, MODULE is assumed.

New in version 3.17: For MODULE library type, if option WITH_SOABI is specified, the module suffix will
include the Python3_SOABI value, if any.

FindQt3
Locate Qt include paths and libraries

This module defines:

QT_INCLUDE_DIR - where to find qt.h, etc.
QT_LIBRARIES - the libraries to link against to use Qt.
QT_DEFINITIONS - definitions to use when
compiling code that uses Qt.
QT_FOUND - If false, don't try to use Qt.
QT_VERSION_STRING - the version of Qt found

If you need the multithreaded version of Qt, set QT_MT_REQUIRED to TRUE

Also defined, but not for general use are:

QT_MOC_EXECUTABLE, where to find the moc tool.
QT_UIC_EXECUTABLE, where to find the uic tool.
QT_QT_LIBRARY, where to find the Qt library.
QT_QTMAIN_LIBRARY, where to find the qtmain
library. This is only required by Qt3 on Windows.

FindQt4
Finding and Using Qt4
This module can be used to find Qt4. The most important issue is that the Qt4 qmake is available via the
system path. This qmake is then used to detect basically everything else. This module defines a number
of IMPORTED targets, macros and variables.

Typical usage could be something like:

set(CMAKE_AUTOMOC ON)
set(CMAKE_INCLUDE_CURRENT_DIR ON)
find_package(Qt4 4.4.3 REQUIRED QtGui QtXml)
add_executable(myexe main.cpp)
target_link_libraries(myexe Qt4::QtGui Qt4::QtXml)

NOTE:
When using IMPORTED targets, the qtmain.lib static library is automatically linked on Windows for
WIN32 executables. To disable that globally, set the QT4_NO_LINK_QTMAIN variable before finding Qt4.
To disable that for a particular executable, set the QT4_NO_LINK_QTMAIN target property to TRUE on the
executable.

Qt Build Tools
Qt relies on some bundled tools for code generation, such as moc for meta-object code generation,``uic``
for widget layout and population, and rcc for virtual filesystem content generation. These tools may be
automatically invoked by cmake(1) if the appropriate conditions are met. See cmake-qt(7) for more.

Qt Macros
In some cases it can be necessary or useful to invoke the Qt build tools in a more-manual way. Several
macros are available to add targets for such uses.

macro QT4_WRAP_CPP(outfiles inputfile ... [TARGET tgt] OPTIONS ...)
create moc code from a list of files containing Qt class with
the Q_OBJECT declaration. Per-directory preprocessor definitions
are also added. If the <tgt> is specified, the
INTERFACE_INCLUDE_DIRECTORIES and INTERFACE_COMPILE_DEFINITIONS from
the <tgt> are passed to moc. Options may be given to moc, such as
those found when executing "moc -help".

macro QT4_WRAP_UI(outfiles inputfile ... OPTIONS ...)
create code from a list of Qt designer ui files.
Options may be given to uic, such as those found
when executing "uic -help"

macro QT4_ADD_RESOURCES(outfiles inputfile ... OPTIONS ...)
create code from a list of Qt resource files.
Options may be given to rcc, such as those found
when executing "rcc -help"

macro QT4_GENERATE_MOC(inputfile outputfile [TARGET tgt])
creates a rule to run moc on infile and create outfile.
Use this if for some reason QT4_WRAP_CPP() isn't appropriate, e.g.
because you need a custom filename for the moc file or something
similar. If the <tgt> is specified, the
INTERFACE_INCLUDE_DIRECTORIES and INTERFACE_COMPILE_DEFINITIONS from
the <tgt> are passed to moc.

macro QT4_ADD_DBUS_INTERFACE(outfiles interface basename)
Create the interface header and implementation files with the
given basename from the given interface xml file and add it to
the list of sources.

You can pass additional parameters to the qdbusxml2cpp call by setting
properties on the input file:

INCLUDE the given file will be included in the generate interface header

CLASSNAME the generated class is named accordingly

NO_NAMESPACE the generated class is not wrapped in a namespace

macro QT4_ADD_DBUS_INTERFACES(outfiles inputfile ... )
Create the interface header and implementation files
for all listed interface xml files.
The basename will be automatically determined from the name
of the xml file.

The source file properties described for
QT4_ADD_DBUS_INTERFACE also apply here.

macro QT4_ADD_DBUS_ADAPTOR(outfiles xmlfile parentheader parentclassname
[basename] [classname])
create a dbus adaptor (header and implementation file) from the xml file
describing the interface, and add it to the list of sources. The adaptor
forwards the calls to a parent class, defined in parentheader and named
parentclassname. The name of the generated files will be
<basename>adaptor.{cpp,h} where basename defaults to the basename of the
xml file.
If <classname> is provided, then it will be used as the classname of the
adaptor itself.

macro QT4_GENERATE_DBUS_INTERFACE( header [interfacename] OPTIONS ...)
generate the xml interface file from the given header.
If the optional argument interfacename is omitted, the name of the
interface file is constructed from the basename of the header with
the suffix .xml appended.
Options may be given to qdbuscpp2xml, such as those found when
executing "qdbuscpp2xml --help"

macro QT4_CREATE_TRANSLATION( qm_files directories ... sources ...
ts_files ... OPTIONS ...)
out: qm_files
in: directories sources ts_files
options: flags to pass to lupdate, such as -extensions to specify
extensions for a directory scan.
generates commands to create .ts (via lupdate) and .qm
(via lrelease) - files from directories and/or sources. The ts files are
created and/or updated in the source tree (unless given with full paths).
The qm files are generated in the build tree.
Updating the translations can be done by adding the qm_files
to the source list of your library/executable, so they are
always updated, or by adding a custom target to control when
they get updated/generated.

macro QT4_ADD_TRANSLATION( qm_files ts_files ... )
out: qm_files
in: ts_files
generates commands to create .qm from .ts - files. The generated
filenames can be found in qm_files. The ts_files
must exist and are not updated in any way.

macro QT4_AUTOMOC(sourcefile1 sourcefile2 ... [TARGET tgt])
The qt4_automoc macro is obsolete. Use the CMAKE_AUTOMOC feature instead.
This macro is still experimental.
It can be used to have moc automatically handled.
So if you have the files foo.h and foo.cpp, and in foo.h a
a class uses the Q_OBJECT macro, moc has to run on it. If you don't
want to use QT4_WRAP_CPP() (which is reliable and mature), you can insert
#include "foo.moc"
in foo.cpp and then give foo.cpp as argument to QT4_AUTOMOC(). This will
scan all listed files at cmake-time for such included moc files and if it
finds them cause a rule to be generated to run moc at build time on the
accompanying header file foo.h.
If a source file has the SKIP_AUTOMOC property set it will be ignored by
this macro.
If the <tgt> is specified, the INTERFACE_INCLUDE_DIRECTORIES and
INTERFACE_COMPILE_DEFINITIONS from the <tgt> are passed to moc.

function QT4_USE_MODULES( target [link_type] modules...)
This function is obsolete. Use target_link_libraries with IMPORTED targets
instead.
Make <target> use the <modules> from Qt. Using a Qt module means
to link to the library, add the relevant include directories for the
module, and add the relevant compiler defines for using the module.
Modules are roughly equivalent to components of Qt4, so usage would be
something like:
qt4_use_modules(myexe Core Gui Declarative)
to use QtCore, QtGui and QtDeclarative. The optional <link_type> argument
can be specified as either LINK_PUBLIC or LINK_PRIVATE to specify the
same argument to the target_link_libraries call.

IMPORTED Targets
A particular Qt library may be used by using the corresponding IMPORTED target with the
target_link_libraries() command:

target_link_libraries(myexe Qt4::QtGui Qt4::QtXml)

Using a target in this way causes :cmake(1)` to use the appropriate include directories and compile
definitions for the target when compiling myexe.

Targets are aware of their dependencies, so for example it is not necessary to list Qt4::QtCore if
another Qt library is listed, and it is not necessary to list Qt4::QtGui if Qt4::QtDeclarative is listed.
Targets may be tested for existence in the usual way with the if(TARGET) command.

The Qt toolkit may contain both debug and release libraries. cmake(1) will choose the appropriate
version based on the build configuration.

Qt4::QtCore
The QtCore target

Qt4::QtGui
The QtGui target

Qt4::Qt3Support
The Qt3Support target

Qt4::QtAssistant
The QtAssistant target

Qt4::QtAssistantClient
The QtAssistantClient target

Qt4::QAxContainer
The QAxContainer target (Windows only)

Qt4::QAxServer
The QAxServer target (Windows only)

Qt4::QtDBus
The QtDBus target

Qt4::QtDeclarative
The QtDeclarative target

Qt4::QtDesigner
The QtDesigner target

Qt4::QtDesignerComponents
The QtDesignerComponents target

Qt4::QtHelp
The QtHelp target

Qt4::QtMotif
The QtMotif target

Qt4::QtMultimedia
The QtMultimedia target

Qt4::QtNetwork
The QtNetwork target

Qt4::QtNsPLugin
The QtNsPLugin target

Qt4::QtOpenGL
The QtOpenGL target

Qt4::QtScript
The QtScript target

Qt4::QtScriptTools
The QtScriptTools target

Qt4::QtSql
The QtSql target

Qt4::QtSvg
The QtSvg target

Qt4::QtTest
The QtTest target

Qt4::QtUiTools
The QtUiTools target

Qt4::QtWebKit
The QtWebKit target

Qt4::QtXml
The QtXml target

Qt4::QtXmlPatterns
The QtXmlPatterns target

Qt4::phonon
The phonon target

Result Variables
Below is a detailed list of variables that FindQt4.cmake sets.

Qt4_FOUND
If false, don't try to use Qt 4.

QT_FOUND
If false, don't try to use Qt. This variable is for compatibility only.

QT4_FOUND
If false, don't try to use Qt 4. This variable is for compatibility only.

QT_VERSION_MAJOR
The major version of Qt found.

QT_VERSION_MINOR
The minor version of Qt found.

QT_VERSION_PATCH
The patch version of Qt found.

FindQuickTime
Locate QuickTime This module defines QUICKTIME_LIBRARY QUICKTIME_FOUND, if false, do not try to link to
gdal QUICKTIME_INCLUDE_DIR, where to find the headers

$QUICKTIME_DIR is an environment variable that would correspond to the ./configure
--prefix=$QUICKTIME_DIR

Created by Eric Wing.

FindRTI
Try to find M&S HLA RTI libraries

This module finds if any HLA RTI is installed and locates the standard RTI include files and libraries.

RTI is a simulation infrastructure standardized by IEEE and SISO. It has a well defined C++ API that
assures that simulation applications are independent on a particular RTI implementation.

http://en.wikipedia.org/wiki/Run-Time_Infrastructure_(simulation)

This code sets the following variables:

RTI_INCLUDE_DIR = the directory where RTI includes file are found
RTI_LIBRARIES = The libraries to link against to use RTI
RTI_DEFINITIONS = -DRTI_USES_STD_FSTREAM
RTI_FOUND = Set to FALSE if any HLA RTI was not found

Report problems to <certi-devel@nongnu.org>

FindRuby
Find Ruby

This module finds if Ruby is installed and determines where the include files and libraries are. Ruby
1.8 through 2.7 are supported.

The minimum required version of Ruby can be specified using the standard syntax, e.g.

find_package(Ruby 2.5.1 EXACT REQUIRED)
# OR
find_package(Ruby 2.4)

It also determines what the name of the library is.

Virtual environments such as RVM are handled as well, by passing the argument Ruby_FIND_VIRTUALENV

Result Variables
This module will set the following variables in your project:

Ruby_FOUND
set to true if ruby was found successfully

Ruby_EXECUTABLE
full path to the ruby binary

Ruby_INCLUDE_DIRS
include dirs to be used when using the ruby library

Ruby_LIBRARIES
New in version 3.18: libraries needed to use ruby from C.

Ruby_VERSION
the version of ruby which was found, e.g. "1.8.7"

Ruby_VERSION_MAJOR
Ruby major version.

Ruby_VERSION_MINOR
Ruby minor version.

Ruby_VERSION_PATCH
Ruby patch version.

Changed in version 3.18: Previous versions of CMake used the RUBY_ prefix for all variables. The
following variables are provided for compatibility reasons, don't use them in new code:

RUBY_EXECUTABLE
same as Ruby_EXECUTABLE.

RUBY_INCLUDE_DIRS
same as Ruby_INCLUDE_DIRS.

RUBY_INCLUDE_PATH
same as Ruby_INCLUDE_DIRS.

RUBY_LIBRARY
same as Ruby_LIBRARY.

RUBY_VERSION
same as Ruby_VERSION.

RUBY_FOUND
same as Ruby_FOUND.

Hints
New in version 3.18.

Ruby_ROOT_DIR
Define the root directory of a Ruby installation.

Ruby_FIND_VIRTUALENV
This variable defines the handling of virtual environments managed by rvm. It is meaningful only
when a virtual environment is active (i.e. the rvm script has been evaluated or at least the
MY_RUBY_HOME environment variable is set). The Ruby_FIND_VIRTUALENV variable can be set to empty
or one of the following:

• FIRST: The virtual environment is used before any other standard paths to look-up for the
interpreter. This is the default.

• ONLY: Only the virtual environment is used to look-up for the interpreter.

• STANDARD: The virtual environment is not used to look-up for the interpreter (assuming it isn't
still in the PATH...)

FindSDL
Locate the SDL library

Imported targets
New in version 3.19.

This module defines the following IMPORTED target:

SDL::SDL
The SDL library, if found

Result variables
This module will set the following variables in your project:

SDL_INCLUDE_DIRS
where to find SDL.h

SDL_LIBRARIES
the name of the library to link against

SDL_FOUND
if false, do not try to link to SDL

SDL_VERSION
the human-readable string containing the version of SDL if found

SDL_VERSION_MAJOR
SDL major version

SDL_VERSION_MINOR
SDL minor version

SDL_VERSION_PATCH
SDL patch version

New in version 3.19: Added the SDL_INCLUDE_DIRS, SDL_LIBRARIES and SDL_VERSION[_<PART>] variables.

Cache variables
These variables may optionally be set to help this module find the correct files:

SDL_INCLUDE_DIR
where to find SDL.h

SDL_LIBRARY
the name of the library to link against

Variables for locating SDL
This module responds to the flag:

SDL_BUILDING_LIBRARY
If this is defined, then no SDL_main will be linked in because only applications need main().
Otherwise, it is assumed you are building an application and this module will attempt to locate
and set the proper link flags as part of the returned SDL_LIBRARY variable.

Obsolete variables
Deprecated since version 3.19.

These variables are obsolete and provided for backwards compatibility:

SDL_VERSION_STRING
the human-readable string containing the version of SDL if found. Identical to SDL_VERSION

Don't forget to include SDLmain.h and SDLmain.m your project for the OS X framework based version.
(Other versions link to -lSDLmain which this module will try to find on your behalf.) Also for OS X, this
module will automatically add the -framework Cocoa on your behalf.

Additional Note: If you see an empty SDL_LIBRARY_TEMP in your configuration and no SDL_LIBRARY, it means
CMake did not find your SDL library (SDL.dll, libsdl.so, SDL.framework, etc). Set SDL_LIBRARY_TEMP to
point to your SDL library, and configure again. Similarly, if you see an empty SDLMAIN_LIBRARY, you
should set this value as appropriate. These values are used to generate the final SDL_LIBRARY variable,
but when these values are unset, SDL_LIBRARY does not get created.

$SDLDIR is an environment variable that would correspond to the ./configure --prefix=$SDLDIR used in
building SDL. l.e.galup 9-20-02

On OSX, this will prefer the Framework version (if found) over others. People will have to manually
change the cache values of SDL_LIBRARY to override this selection or set the CMake environment
CMAKE_INCLUDE_PATH to modify the search paths.

Note that the header path has changed from SDL/SDL.h to just SDL.h This needed to change because "proper"
SDL convention is #include "SDL.h", not <SDL/SDL.h>. This is done for portability reasons because not
all systems place things in SDL/ (see FreeBSD).

FindSDL_image
Locate SDL_image library

This module defines:

SDL_IMAGE_LIBRARIES, the name of the library to link against
SDL_IMAGE_INCLUDE_DIRS, where to find the headers
SDL_IMAGE_FOUND, if false, do not try to link against
SDL_IMAGE_VERSION_STRING - human-readable string containing the
version of SDL_image

For backward compatibility the following variables are also set:

SDLIMAGE_LIBRARY (same value as SDL_IMAGE_LIBRARIES)
SDLIMAGE_INCLUDE_DIR (same value as SDL_IMAGE_INCLUDE_DIRS)
SDLIMAGE_FOUND (same value as SDL_IMAGE_FOUND)

$SDLDIR is an environment variable that would correspond to the ./configure --prefix=$SDLDIR used in
building SDL.

Created by Eric Wing. This was influenced by the FindSDL.cmake module, but with modifications to
recognize OS X frameworks and additional Unix paths (FreeBSD, etc).

FindSDL_mixer
Locate SDL_mixer library

This module defines:

SDL_MIXER_LIBRARIES, the name of the library to link against
SDL_MIXER_INCLUDE_DIRS, where to find the headers
SDL_MIXER_FOUND, if false, do not try to link against
SDL_MIXER_VERSION_STRING - human-readable string containing the
version of SDL_mixer

For backward compatibility the following variables are also set:

SDLMIXER_LIBRARY (same value as SDL_MIXER_LIBRARIES)
SDLMIXER_INCLUDE_DIR (same value as SDL_MIXER_INCLUDE_DIRS)
SDLMIXER_FOUND (same value as SDL_MIXER_FOUND)

$SDLDIR is an environment variable that would correspond to the ./configure --prefix=$SDLDIR used in
building SDL.

Created by Eric Wing. This was influenced by the FindSDL.cmake module, but with modifications to
recognize OS X frameworks and additional Unix paths (FreeBSD, etc).

FindSDL_net
Locate SDL_net library

This module defines:

SDL_NET_LIBRARIES, the name of the library to link against
SDL_NET_INCLUDE_DIRS, where to find the headers
SDL_NET_FOUND, if false, do not try to link against
SDL_NET_VERSION_STRING - human-readable string containing the version of SDL_net

For backward compatibility the following variables are also set:

SDLNET_LIBRARY (same value as SDL_NET_LIBRARIES)
SDLNET_INCLUDE_DIR (same value as SDL_NET_INCLUDE_DIRS)
SDLNET_FOUND (same value as SDL_NET_FOUND)

$SDLDIR is an environment variable that would correspond to the ./configure --prefix=$SDLDIR used in
building SDL.

Created by Eric Wing. This was influenced by the FindSDL.cmake module, but with modifications to
recognize OS X frameworks and additional Unix paths (FreeBSD, etc).

FindSDL_sound
Locates the SDL_sound library

This module depends on SDL being found and must be called AFTER FindSDL.cmake is called.

This module defines

SDL_SOUND_INCLUDE_DIR, where to find SDL_sound.h
SDL_SOUND_FOUND, if false, do not try to link to SDL_sound
SDL_SOUND_LIBRARIES, this contains the list of libraries that you need
to link against.
SDL_SOUND_EXTRAS, this is an optional variable for you to add your own
flags to SDL_SOUND_LIBRARIES. This is prepended to SDL_SOUND_LIBRARIES.
This is available mostly for cases this module failed to anticipate for
and you must add additional flags. This is marked as ADVANCED.
SDL_SOUND_VERSION_STRING, human-readable string containing the
version of SDL_sound

This module also defines (but you shouldn't need to use directly)

SDL_SOUND_LIBRARY, the name of just the SDL_sound library you would link
against. Use SDL_SOUND_LIBRARIES for you link instructions and not this one.

And might define the following as needed

MIKMOD_LIBRARY
MODPLUG_LIBRARY
OGG_LIBRARY
VORBIS_LIBRARY
SMPEG_LIBRARY
FLAC_LIBRARY
SPEEX_LIBRARY

Typically, you should not use these variables directly, and you should use SDL_SOUND_LIBRARIES which
contains SDL_SOUND_LIBRARY and the other audio libraries (if needed) to successfully compile on your
system.

Created by Eric Wing. This module is a bit more complicated than the other FindSDL* family modules. The
reason is that SDL_sound can be compiled in a large variety of different ways which are independent of
platform. SDL_sound may dynamically link against other 3rd party libraries to get additional codec
support, such as Ogg Vorbis, SMPEG, ModPlug, MikMod, FLAC, Speex, and potentially others. Under some
circumstances which I don't fully understand, there seems to be a requirement that dependent libraries of
libraries you use must also be explicitly linked against in order to successfully compile. SDL_sound
does not currently have any system in place to know how it was compiled. So this CMake module does the
hard work in trying to discover which 3rd party libraries are required for building (if any). This
module uses a brute force approach to create a test program that uses SDL_sound, and then tries to build
it. If the build fails, it parses the error output for known symbol names to figure out which libraries
are needed.

Responds to the $SDLDIR and $SDLSOUNDDIR environmental variable that would correspond to the ./configure
--prefix=$SDLDIR used in building SDL.

On OSX, this will prefer the Framework version (if found) over others. People will have to manually
change the cache values of SDL_LIBRARY to override this selectionor set the CMake environment
CMAKE_INCLUDE_PATH to modify the search paths.

FindSDL_ttf
Locate SDL_ttf library

This module defines:

SDL_TTF_LIBRARIES, the name of the library to link against
SDL_TTF_INCLUDE_DIRS, where to find the headers
SDL_TTF_FOUND, if false, do not try to link against
SDL_TTF_VERSION_STRING - human-readable string containing the version of SDL_ttf

For backward compatibility the following variables are also set:

SDLTTF_LIBRARY (same value as SDL_TTF_LIBRARIES)
SDLTTF_INCLUDE_DIR (same value as SDL_TTF_INCLUDE_DIRS)
SDLTTF_FOUND (same value as SDL_TTF_FOUND)

$SDLDIR is an environment variable that would correspond to the ./configure --prefix=$SDLDIR used in
building SDL.

Created by Eric Wing. This was influenced by the FindSDL.cmake module, but with modifications to
recognize OS X frameworks and additional Unix paths (FreeBSD, etc).

FindSelfPackers
Find upx

This module looks for some executable packers (i.e. software that compress executables or shared libs
into on-the-fly self-extracting executables or shared libs. Examples:

UPX: http://wildsau.idv.uni-linz.ac.at/mfx/upx.html

FindSquish
-- Typical Use

This module can be used to find Squish.

SQUISH_FOUND If false, don't try to use Squish
SQUISH_VERSION The full version of Squish found
SQUISH_VERSION_MAJOR The major version of Squish found
SQUISH_VERSION_MINOR The minor version of Squish found
SQUISH_VERSION_PATCH The patch version of Squish found

SQUISH_INSTALL_DIR The Squish installation directory
(containing bin, lib, etc)
SQUISH_SERVER_EXECUTABLE The squishserver executable
SQUISH_CLIENT_EXECUTABLE The squishrunner executable

SQUISH_INSTALL_DIR_FOUND Was the install directory found?
SQUISH_SERVER_EXECUTABLE_FOUND Was the server executable found?
SQUISH_CLIENT_EXECUTABLE_FOUND Was the client executable found?

It provides the function squish_add_test() for adding a squish test to cmake using Squish >= 4.x:

squish_add_test(cmakeTestName
AUT targetName SUITE suiteName TEST squishTestName
[SETTINGSGROUP group] [PRE_COMMAND command] [POST_COMMAND command] )

Changed in version 3.18: In previous CMake versions, this function was named squish_v4_add_test.

The arguments have the following meaning:

cmakeTestName
this will be used as the first argument for add_test()

AUT targetName
the name of the cmake target which will be used as AUT, i.e. the executable which will be tested.

SUITE suiteName
this is either the full path to the squish suite, or just the last directory of the suite, i.e.
the suite name. In this case the CMakeLists.txt which calls squish_add_test() must be located in
the parent directory of the suite directory.

TEST squishTestName
the name of the squish test, i.e. the name of the subdirectory of the test inside the suite
directory.

SETTINGSGROUP group
deprecated, this argument will be ignored.

PRE_COMMAND command
if specified, the given command will be executed before starting the squish test.

POST_COMMAND command
same as PRE_COMMAND, but after the squish test has been executed.

enable_testing()
find_package(Squish 6.5)
if (SQUISH_FOUND)
squish_add_test(myTestName
AUT myApp
SUITE ${CMAKE_SOURCE_DIR}/tests/mySuite
TEST someSquishTest
)
endif ()

For users of Squish version 3.x the macro squish_v3_add_test() is provided:

squish_v3_add_test(testName applicationUnderTest testCase envVars testWrapper)
Use this macro to add a test using Squish 3.x.

enable_testing()
find_package(Squish 3.0)
if (SQUISH_FOUND)
squish_v3_add_test(myTestName myApplication testCase envVars testWrapper)
endif ()

FindSQLite3
New in version 3.14.

Find the SQLite libraries, v3

IMPORTED targets
This module defines the following IMPORTED target:

SQLite::SQLite3

Result variables
This module will set the following variables if found:

SQLite3_INCLUDE_DIRS
where to find sqlite3.h, etc.

SQLite3_LIBRARIES
the libraries to link against to use SQLite3.

SQLite3_VERSION
version of the SQLite3 library found

SQLite3_FOUND
TRUE if found

FindSubversion
Extract information from a subversion working copy

The module defines the following variables:

Subversion_SVN_EXECUTABLE - path to svn command line client
Subversion_VERSION_SVN - version of svn command line client
Subversion_FOUND - true if the command line client was found
SUBVERSION_FOUND - same as Subversion_FOUND, set for compatibility reasons

The minimum required version of Subversion can be specified using the standard syntax, e.g.
find_package(Subversion 1.4).

If the command line client executable is found two macros are defined:

Subversion_WC_INFO(<dir> <var-prefix> [IGNORE_SVN_FAILURE])
Subversion_WC_LOG(<dir> <var-prefix>)

Subversion_WC_INFO extracts information of a subversion working copy at a given location. This macro
defines the following variables if running Subversion's info command on <dir> succeeds; otherwise a
SEND_ERROR message is generated.

New in version 3.13: The error can be ignored by providing the IGNORE_SVN_FAILURE option, which causes
these variables to remain undefined.

<var-prefix>_WC_URL - url of the repository (at <dir>)
<var-prefix>_WC_ROOT - root url of the repository
<var-prefix>_WC_REVISION - current revision
<var-prefix>_WC_LAST_CHANGED_AUTHOR - author of last commit
<var-prefix>_WC_LAST_CHANGED_DATE - date of last commit
<var-prefix>_WC_LAST_CHANGED_REV - revision of last commit
<var-prefix>_WC_INFO - output of command `svn info <dir>'

Subversion_WC_LOG retrieves the log message of the base revision of a subversion working copy at a given
location. This macro defines the variable:

<var-prefix>_LAST_CHANGED_LOG - last log of base revision

Example usage:

find_package(Subversion)
if(SUBVERSION_FOUND)
Subversion_WC_INFO(${PROJECT_SOURCE_DIR} Project)
message("Current revision is ${Project_WC_REVISION}")
Subversion_WC_LOG(${PROJECT_SOURCE_DIR} Project)
message("Last changed log is ${Project_LAST_CHANGED_LOG}")
endif()

FindSWIG
Find the Simplified Wrapper and Interface Generator (SWIG) executable.

This module finds an installed SWIG and determines its version.

New in version 3.18: If a COMPONENTS or OPTIONAL_COMPONENTS argument is given to the find_package()
command, it will also determine supported target languages.

The module defines the following variables:

SWIG_FOUND
Whether SWIG and any required components were found on the system.

SWIG_EXECUTABLE
Path to the SWIG executable.

SWIG_DIR
Path to the installed SWIG Lib directory (result of swig -swiglib).

SWIG_VERSION
SWIG executable version (result of swig -version).

SWIG_<lang>_FOUND
If COMPONENTS or OPTIONAL_COMPONENTS are requested, each available target language <lang>
(lowercase) will be set to TRUE.

Any COMPONENTS given to find_package should be the names of supported target languages as provided to the
LANGUAGE argument of swig_add_library, such as python or perl5. Language names must be lowercase.

All information is collected from the SWIG_EXECUTABLE, so the version to be found can be changed from the
command line by means of setting SWIG_EXECUTABLE.

Example usage requiring SWIG 4.0 or higher and Python language support, with optional Fortran support:

find_package(SWIG 4.0 COMPONENTS python OPTIONAL_COMPONENTS fortran)
if(SWIG_FOUND)
message("SWIG found: ${SWIG_EXECUTABLE}")
if(NOT SWIG_fortran_FOUND)
message(WARNING "SWIG Fortran bindings cannot be generated")
endif()
endif()

FindTCL
TK_INTERNAL_PATH was removed.

This module finds if Tcl is installed and determines where the include files and libraries are. It also
determines what the name of the library is. This code sets the following variables:

TCL_FOUND = Tcl was found
TK_FOUND = Tk was found
TCLTK_FOUND = Tcl and Tk were found
TCL_LIBRARY = path to Tcl library (tcl tcl80)
TCL_INCLUDE_PATH = path to where tcl.h can be found
TCL_TCLSH = path to tclsh binary (tcl tcl80)
TK_LIBRARY = path to Tk library (tk tk80 etc)
TK_INCLUDE_PATH = path to where tk.h can be found
TK_WISH = full path to the wish executable

In an effort to remove some clutter and clear up some issues for people who are not necessarily Tcl/Tk
gurus/developers, some variables were moved or removed. Changes compared to CMake 2.4 are:

=> they were only useful for people writing Tcl/Tk extensions.
=> these libs are not packaged by default with Tcl/Tk distributions.
Even when Tcl/Tk is built from source, several flavors of debug libs
are created and there is no real reason to pick a single one
specifically (say, amongst tcl84g, tcl84gs, or tcl84sgx).
Let's leave that choice to the user by allowing him to assign
TCL_LIBRARY to any Tcl library, debug or not.
=> this ended up being only a Win32 variable, and there is a lot of
confusion regarding the location of this file in an installed Tcl/Tk
tree anyway (see 8.5 for example). If you need the internal path at
this point it is safer you ask directly where the *source* tree is
and dig from there.

FindTclsh
Find tclsh

This module finds if TCL is installed and determines where the include files and libraries are. It also
determines what the name of the library is. This code sets the following variables:

TCLSH_FOUND = TRUE if tclsh has been found
TCL_TCLSH = the path to the tclsh executable

FindTclStub
TCL_STUB_LIBRARY_DEBUG and TK_STUB_LIBRARY_DEBUG were removed.

This module finds Tcl stub libraries. It first finds Tcl include files and libraries by calling
FindTCL.cmake. How to Use the Tcl Stubs Library:

http://tcl.activestate.com/doc/howto/stubs.html

Using Stub Libraries:

http://safari.oreilly.com/0130385603/ch48lev1sec3

This code sets the following variables:

TCL_STUB_LIBRARY = path to Tcl stub library
TK_STUB_LIBRARY = path to Tk stub library
TTK_STUB_LIBRARY = path to ttk stub library

In an effort to remove some clutter and clear up some issues for people who are not necessarily Tcl/Tk
gurus/developers, some variables were moved or removed. Changes compared to CMake 2.4 are:

=> these libs are not packaged by default with Tcl/Tk distributions.
Even when Tcl/Tk is built from source, several flavors of debug libs
are created and there is no real reason to pick a single one
specifically (say, amongst tclstub84g, tclstub84gs, or tclstub84sgx).
Let's leave that choice to the user by allowing him to assign
TCL_STUB_LIBRARY to any Tcl library, debug or not.

FindThreads
This module determines the thread library of the system.

Imported Targets
New in version 3.1.

This module defines the following IMPORTED target:

Threads::Threads
The thread library, if found.

Result Variables
The following variables are set:

Threads_FOUND
If a supported thread library was found.

CMAKE_THREAD_LIBS_INIT
The thread library to use. This may be empty if the thread functions are provided by the system
libraries and no special flags are needed to use them.

CMAKE_USE_WIN32_THREADS_INIT
If the found thread library is the win32 one.

CMAKE_USE_PTHREADS_INIT
If the found thread library is pthread compatible.

CMAKE_HP_PTHREADS_INIT
If the found thread library is the HP thread library.

Variables Affecting Behavior
THREADS_PREFER_PTHREAD_FLAG
New in version 3.1.

If the use of the -pthread compiler and linker flag is preferred then the caller can set this
variable to TRUE. The compiler flag can only be used with the imported target. Use of both the
imported target as well as this switch is highly recommended for new code.

This variable has no effect if the system libraries provide the thread functions, i.e. when
CMAKE_THREAD_LIBS_INIT will be empty.

FindTIFF
Find the TIFF library (libtiff, https://libtiff.gitlab.io/libtiff/).

Optional COMPONENTS
This module supports the optional component CXX, for use with the COMPONENTS argument of the
find_package() command. This component has an associated imported target, as described below.

Imported targets
New in version 3.5.

This module defines the following IMPORTED targets:

TIFF::TIFF
The TIFF library, if found.

TIFF::CXX
New in version 3.19.

The C++ wrapper libtiffxx, if requested by the COMPONENTS CXX option, if the compiler is not MSVC
(which includes the C++ wrapper in libtiff), and if found.

Result variables
This module will set the following variables in your project:

TIFF_FOUND
true if the TIFF headers and libraries were found

TIFF_INCLUDE_DIR
the directory containing the TIFF headers

TIFF_INCLUDE_DIRS
the directory containing the TIFF headers

TIFF_LIBRARIES
TIFF libraries to be linked

Cache variables
The following cache variables may also be set:

TIFF_INCLUDE_DIR
the directory containing the TIFF headers

TIFF_LIBRARY_RELEASE
the path to the TIFF library for release configurations

TIFF_LIBRARY_DEBUG
the path to the TIFF library for debug configurations

TIFFXX_LIBRARY_RELEASE
the path to the TIFFXX library for release configurations

TIFFXX_LIBRARY_DEBUG
the path to the TIFFXX library for debug configurations

New in version 3.4: Debug and Release variants are found separately.

FindUnixCommands
Find Unix commands, including the ones from Cygwin

This module looks for the Unix commands bash, cp, gzip, mv, rm, and tar and stores the result in the
variables BASH, CP, GZIP, MV, RM, and TAR.

FindVTK
This module no longer exists.

This module existed in versions of CMake prior to 3.1, but became only a thin wrapper around
find_package(VTK NO_MODULE) to provide compatibility for projects using long-outdated conventions. Now
find_package(VTK) will search for VTKConfig.cmake directly.

FindVulkan
New in version 3.7.

Find Vulkan, which is a low-overhead, cross-platform 3D graphics and computing API.

IMPORTED Targets
This module defines IMPORTED targets if Vulkan has been found:

Vulkan::Vulkan
The main Vulkan library.

Vulkan::glslc
New in version 3.19.

The GLSLC SPIR-V compiler, if it has been found.

Vulkan::Headers
New in version 3.21.

Provides just Vulkan headers include paths, if found. No library is included in this target.
This can be useful for applications that load Vulkan library dynamically.

Vulkan::glslangValidator
New in version 3.21.

The glslangValidator tool, if found. It is used to compile GLSL and HLSL shaders into SPIR-V.

Result Variables
This module defines the following variables:

Vulkan_FOUND - "True" if Vulkan was found
Vulkan_INCLUDE_DIRS - include directories for Vulkan
Vulkan_LIBRARIES - link against this library to use Vulkan

The module will also define three cache variables:

Vulkan_INCLUDE_DIR - the Vulkan include directory
Vulkan_LIBRARY - the path to the Vulkan library
Vulkan_GLSLC_EXECUTABLE - the path to the GLSL SPIR-V compiler
Vulkan_GLSLANG_VALIDATOR_EXECUTABLE - the path to the glslangValidator tool

Hints
New in version 3.18.

The VULKAN_SDK environment variable optionally specifies the location of the Vulkan SDK root directory
for the given architecture. It is typically set by sourcing the toplevel setup-env.sh script of the
Vulkan SDK directory into the shell environment.

FindWget
Find wget

This module looks for wget. This module defines the following values:

WGET_EXECUTABLE: the full path to the wget tool.
WGET_FOUND: True if wget has been found.

FindWish
Find wish installation

This module finds if TCL is installed and determines where the include files and libraries are. It also
determines what the name of the library is. This code sets the following variables:

TK_WISH = the path to the wish executable

if UNIX is defined, then it will look for the cygwin version first

FindwxWidgets
Find a wxWidgets (a.k.a., wxWindows) installation.

This module finds if wxWidgets is installed and selects a default configuration to use. wxWidgets is a
modular library. To specify the modules that you will use, you need to name them as components to the
package:

find_package(wxWidgets COMPONENTS core base ... OPTIONAL_COMPONENTS net ...)

New in version 3.4: Support for find_package() version argument; webview component.

New in version 3.14: OPTIONAL_COMPONENTS support.

There are two search branches: a windows style and a unix style. For windows, the following variables
are searched for and set to defaults in case of multiple choices. Change them if the defaults are not
desired (i.e., these are the only variables you should change to select a configuration):

wxWidgets_ROOT_DIR - Base wxWidgets directory
(e.g., C:/wxWidgets-2.6.3).
wxWidgets_LIB_DIR - Path to wxWidgets libraries
(e.g., C:/wxWidgets-2.6.3/lib/vc_lib).
wxWidgets_CONFIGURATION - Configuration to use
(e.g., msw, mswd, mswu, mswunivud, etc.)
wxWidgets_EXCLUDE_COMMON_LIBRARIES
- Set to TRUE to exclude linking of
commonly required libs (e.g., png tiff
jpeg zlib regex expat).

For unix style it uses the wx-config utility. You can select between debug/release, unicode/ansi,
universal/non-universal, and static/shared in the QtDialog or ccmake interfaces by turning ON/OFF the
following variables:

wxWidgets_USE_DEBUG
wxWidgets_USE_UNICODE
wxWidgets_USE_UNIVERSAL
wxWidgets_USE_STATIC

There is also a wxWidgets_CONFIG_OPTIONS variable for all other options that need to be passed to the
wx-config utility. For example, to use the base toolkit found in the /usr/local path, set the variable
(before calling the FIND_PACKAGE command) as such:

set(wxWidgets_CONFIG_OPTIONS --toolkit=base --prefix=/usr)

The following are set after the configuration is done for both windows and unix style:

wxWidgets_FOUND - Set to TRUE if wxWidgets was found.
wxWidgets_INCLUDE_DIRS - Include directories for WIN32
i.e., where to find "wx/wx.h" and
"wx/setup.h"; possibly empty for unices.
wxWidgets_LIBRARIES - Path to the wxWidgets libraries.
wxWidgets_LIBRARY_DIRS - compile time link dirs, useful for
rpath on UNIX. Typically an empty string
in WIN32 environment.
wxWidgets_DEFINITIONS - Contains defines required to compile/link
against WX, e.g. WXUSINGDLL
wxWidgets_DEFINITIONS_DEBUG- Contains defines required to compile/link
against WX debug builds, e.g. __WXDEBUG__
wxWidgets_CXX_FLAGS - Include dirs and compiler flags for
unices, empty on WIN32. Essentially
"`wx-config --cxxflags`".
wxWidgets_USE_FILE - Convenience include file.

New in version 3.11: The following environment variables can be used as hints: WX_CONFIG, WXRC_CMD.

Sample usage:

# Note that for MinGW users the order of libs is important!
find_package(wxWidgets COMPONENTS gl core base OPTIONAL_COMPONENTS net)
if(wxWidgets_FOUND)
include(${wxWidgets_USE_FILE})
# and for each of your dependent executable/library targets:
target_link_libraries(<YourTarget> ${wxWidgets_LIBRARIES})
endif()

If wxWidgets is required (i.e., not an optional part):

find_package(wxWidgets REQUIRED gl core base OPTIONAL_COMPONENTS net)
include(${wxWidgets_USE_FILE})
# and for each of your dependent executable/library targets:
target_link_libraries(<YourTarget> ${wxWidgets_LIBRARIES})

FindX11
Find X11 installation

Try to find X11 on UNIX systems. The following values are defined

X11_FOUND - True if X11 is available
X11_INCLUDE_DIR - include directories to use X11
X11_LIBRARIES - link against these to use X11

and also the following more fine grained variables and targets:

New in version 3.14: Imported targets.

X11_ICE_INCLUDE_PATH, X11_ICE_LIB, X11_ICE_FOUND, X11::ICE
X11_SM_INCLUDE_PATH, X11_SM_LIB, X11_SM_FOUND, X11::SM
X11_X11_INCLUDE_PATH, X11_X11_LIB, X11::X11
X11_Xaccessrules_INCLUDE_PATH,
X11_Xaccessstr_INCLUDE_PATH, X11_Xaccess_FOUND
X11_Xau_INCLUDE_PATH, X11_Xau_LIB, X11_Xau_FOUND, X11::Xau
X11_xcb_INCLUDE_PATH, X11_xcb_LIB, X11_xcb_FOUND, X11::xcb
X11_X11_xcb_INCLUDE_PATH, X11_X11_xcb_LIB, X11_X11_xcb_FOUND, X11::X11_xcb
X11_xcb_icccm_INCLUDE_PATH, X11_xcb_icccm_LIB, X11_xcb_icccm_FOUND, X11::xcb_icccm
X11_xcb_util_INCLUDE_PATH, X11_xcb_util_LIB, X11_xcb_util_FOUND, X11::xcb_util
X11_xcb_xfixes_INCLUDE_PATH, X11_xcb_xfixes_LIB, X11_xcb_xfixes_FOUND, X11::xcb_xfixes
X11_xcb_xkb_INCLUDE_PATH, X11_xcb_xkb_LIB, X11_xcb_xkb_FOUND, X11::xcb_xkb
X11_Xcomposite_INCLUDE_PATH, X11_Xcomposite_LIB, X11_Xcomposite_FOUND, X11::Xcomposite
X11_Xcursor_INCLUDE_PATH, X11_Xcursor_LIB, X11_Xcursor_FOUND, X11::Xcursor
X11_Xdamage_INCLUDE_PATH, X11_Xdamage_LIB, X11_Xdamage_FOUND, X11::Xdamage
X11_Xdmcp_INCLUDE_PATH, X11_Xdmcp_LIB, X11_Xdmcp_FOUND, X11::Xdmcp
X11_Xext_INCLUDE_PATH, X11_Xext_LIB, X11_Xext_FOUND, X11::Xext
X11_Xxf86misc_INCLUDE_PATH, X11_Xxf86misc_LIB, X11_Xxf86misc_FOUND, X11::Xxf86misc
X11_Xxf86vm_INCLUDE_PATH, X11_Xxf86vm_LIB X11_Xxf86vm_FOUND, X11::Xxf86vm
X11_Xfixes_INCLUDE_PATH, X11_Xfixes_LIB, X11_Xfixes_FOUND, X11::Xfixes
X11_Xft_INCLUDE_PATH, X11_Xft_LIB, X11_Xft_FOUND, X11::Xft
X11_Xi_INCLUDE_PATH, X11_Xi_LIB, X11_Xi_FOUND, X11::Xi
X11_Xinerama_INCLUDE_PATH, X11_Xinerama_LIB, X11_Xinerama_FOUND, X11::Xinerama
X11_Xkb_INCLUDE_PATH,
X11_Xkblib_INCLUDE_PATH, X11_Xkb_FOUND, X11::Xkb
X11_xkbcommon_INCLUDE_PATH, X11_xkbcommon_LIB, X11_xkbcommon_FOUND, X11::xkbcommon
X11_xkbcommon_X11_INCLUDE_PATH,X11_xkbcommon_X11_LIB,X11_xkbcommon_X11_FOUND,X11::xkbcommon_X11
X11_xkbfile_INCLUDE_PATH, X11_xkbfile_LIB, X11_xkbfile_FOUND, X11::xkbfile
X11_Xmu_INCLUDE_PATH, X11_Xmu_LIB, X11_Xmu_FOUND, X11::Xmu
X11_Xpm_INCLUDE_PATH, X11_Xpm_LIB, X11_Xpm_FOUND, X11::Xpm
X11_Xtst_INCLUDE_PATH, X11_Xtst_LIB, X11_Xtst_FOUND, X11::Xtst
X11_Xrandr_INCLUDE_PATH, X11_Xrandr_LIB, X11_Xrandr_FOUND, X11::Xrandr
X11_Xrender_INCLUDE_PATH, X11_Xrender_LIB, X11_Xrender_FOUND, X11::Xrender
X11_XRes_INCLUDE_PATH, X11_XRes_LIB, X11_XRes_FOUND, X11::XRes
X11_Xss_INCLUDE_PATH, X11_Xss_LIB, X11_Xss_FOUND, X11::Xss
X11_Xt_INCLUDE_PATH, X11_Xt_LIB, X11_Xt_FOUND, X11::Xt
X11_Xutil_INCLUDE_PATH, X11_Xutil_FOUND, X11::Xutil
X11_Xv_INCLUDE_PATH, X11_Xv_LIB, X11_Xv_FOUND, X11::Xv
X11_dpms_INCLUDE_PATH, (in X11_Xext_LIB), X11_dpms_FOUND
X11_XShm_INCLUDE_PATH, (in X11_Xext_LIB), X11_XShm_FOUND
X11_Xshape_INCLUDE_PATH, (in X11_Xext_LIB), X11_Xshape_FOUND
X11_XSync_INCLUDE_PATH, (in X11_Xext_LIB), X11_XSync_FOUND
X11_Xaw_INCLUDE_PATH, X11_Xaw_LIB X11_Xaw_FOUND X11::Xaw

New in version 3.14: Renamed Xxf86misc, X11_Xxf86misc, X11_Xxf86vm, X11_xkbfile, X11_Xtst, and X11_Xss
libraries to match their file names. Deprecated the X11_Xinput library. Old names are still available
for compatibility.

New in version 3.14: Added the X11_Xext_INCLUDE_PATH variable.

New in version 3.18: Added the xcb, X11-xcb, xcb-icccm, xcb-xkb, xkbcommon, and xkbcommon-X11 libraries.

New in version 3.19: Added the Xaw, xcb_util, and xcb_xfixes libraries.

FindXalanC
New in version 3.5.

Find the Apache Xalan-C++ XSL transform processor headers and libraries.

Imported targets
This module defines the following IMPORTED targets:

XalanC::XalanC
The Xalan-C++ xalan-c library, if found.

Result variables
This module will set the following variables in your project:

XalanC_FOUND
true if the Xalan headers and libraries were found

XalanC_VERSION
Xalan release version

XalanC_INCLUDE_DIRS
the directory containing the Xalan headers; note XercesC_INCLUDE_DIRS is also required

XalanC_LIBRARIES
Xalan libraries to be linked; note XercesC_LIBRARIES is also required

Cache variables
The following cache variables may also be set:

XalanC_INCLUDE_DIR
the directory containing the Xalan headers

XalanC_LIBRARY
the Xalan library

FindXCTest
New in version 3.3.

Functions to help creating and executing XCTest bundles.

An XCTest bundle is a CFBundle with a special product-type and bundle extension. The Mac Developer
Library provides more information in the Testing with Xcode document.

Module Functions
xctest_add_bundle
The xctest_add_bundle function creates a XCTest bundle named <target> which will test the target
<testee>. Supported target types for testee are Frameworks and App Bundles:

xctest_add_bundle(
<target> # Name of the XCTest bundle
<testee> # Target name of the testee
)

xctest_add_test
The xctest_add_test function adds an XCTest bundle to the project to be run by ctest(1). The test
will be named <name> and tests <bundle>:

xctest_add_test(
<name> # Test name
<bundle> # Target name of XCTest bundle
)

Module Variables
The following variables are set by including this module:

XCTest_FOUND
True if the XCTest Framework and executable were found.

XCTest_EXECUTABLE
The path to the xctest command line tool used to execute XCTest bundles.

XCTest_INCLUDE_DIRS
The directory containing the XCTest Framework headers.

XCTest_LIBRARIES
The location of the XCTest Framework.

FindXercesC
New in version 3.1.

Find the Apache Xerces-C++ validating XML parser headers and libraries.

Imported targets
New in version 3.5.

This module defines the following IMPORTED targets:

XercesC::XercesC
The Xerces-C++ xerces-c library, if found.

Result variables
This module will set the following variables in your project:

XercesC_FOUND
true if the Xerces headers and libraries were found

XercesC_VERSION
Xerces release version

XercesC_INCLUDE_DIRS
the directory containing the Xerces headers

XercesC_LIBRARIES
Xerces libraries to be linked

Cache variables
The following cache variables may also be set:

XercesC_INCLUDE_DIR
the directory containing the Xerces headers

XercesC_LIBRARY
the Xerces library

New in version 3.4: Debug and Release variants are found separately.

FindXMLRPC
Find xmlrpc

Find the native XMLRPC headers and libraries.

XMLRPC_INCLUDE_DIRS - where to find xmlrpc.h, etc.
XMLRPC_LIBRARIES - List of libraries when using xmlrpc.
XMLRPC_FOUND - True if xmlrpc found.

XMLRPC modules may be specified as components for this find module. Modules may be listed by running
"xmlrpc-c-config". Modules include:

c++ C++ wrapper code
libwww-client libwww-based client
cgi-server CGI-based server
abyss-server ABYSS-based server

Typical usage:

find_package(XMLRPC REQUIRED libwww-client)

FindZLIB
Find the native ZLIB includes and library.

IMPORTED Targets
New in version 3.1.

This module defines IMPORTED target ZLIB::ZLIB, if ZLIB has been found.

Result Variables
This module defines the following variables:

ZLIB_INCLUDE_DIRS - where to find zlib.h, etc.
ZLIB_LIBRARIES - List of libraries when using zlib.
ZLIB_FOUND - True if zlib found.

ZLIB_VERSION_STRING - The version of zlib found (x.y.z)
ZLIB_VERSION_MAJOR - The major version of zlib
ZLIB_VERSION_MINOR - The minor version of zlib
ZLIB_VERSION_PATCH - The patch version of zlib
ZLIB_VERSION_TWEAK - The tweak version of zlib

New in version 3.4: Debug and Release variants are found separately.

Backward Compatibility
The following variable are provided for backward compatibility

ZLIB_MAJOR_VERSION - The major version of zlib
ZLIB_MINOR_VERSION - The minor version of zlib
ZLIB_PATCH_VERSION - The patch version of zlib

Hints
A user may set ZLIB_ROOT to a zlib installation root to tell this module where to look.

DEPRECATED MODULES

Deprecated Utility Modules
AddFileDependencies
Deprecated since version 3.20.

Add dependencies to a source file.

add_file_dependencies(<source> <files>...)

Adds the given <files> to the dependencies of file <source>.

Do not use this command in new code. It is just a wrapper around:

set_property(SOURCE <source> APPEND PROPERTY OBJECT_DEPENDS <files>...)

Instead use the set_property() command to append to the OBJECT_DEPENDS source file property directly.

CMakeDetermineVSServicePack
Deprecated since version 3.0: Do not use.

The functionality of this module has been superseded by the CMAKE_<LANG>_COMPILER_VERSION variable that
contains the compiler version number.

Determine the Visual Studio service pack of the 'cl' in use.

Usage:

if(MSVC)
include(CMakeDetermineVSServicePack)
DetermineVSServicePack( my_service_pack )
if( my_service_pack )
message(STATUS "Detected: ${my_service_pack}")
endif()
endif()

Function DetermineVSServicePack sets the given variable to one of the following values or an empty string
if unknown:

vc80, vc80sp1
vc90, vc90sp1
vc100, vc100sp1
vc110, vc110sp1, vc110sp2, vc110sp3, vc110sp4

CMakeExpandImportedTargets
Deprecated since version 3.4: Do not use.

This module was once needed to expand imported targets to the underlying libraries they reference on disk
for use with the try_compile() and try_run() commands. These commands now support imported libraries in
their LINK_LIBRARIES options (since CMake 2.8.11 for try_compile() and since CMake 3.2 for try_run()).

This module does not support the policy CMP0022 NEW behavior or use of the INTERFACE_LINK_LIBRARIES
property because generator expressions cannot be evaluated during configuration.

CMAKE_EXPAND_IMPORTED_TARGETS(<var> LIBRARIES lib1 lib2...libN
[CONFIGURATION <config>])

CMAKE_EXPAND_IMPORTED_TARGETS() takes a list of libraries and replaces all imported targets contained in
this list with their actual file paths of the referenced libraries on disk, including the libraries from
their link interfaces. If a CONFIGURATION is given, it uses the respective configuration of the imported
targets if it exists. If no CONFIGURATION is given, it uses the first configuration from
${CMAKE_CONFIGURATION_TYPES} if set, otherwise ${CMAKE_BUILD_TYPE}.

cmake_expand_imported_targets(expandedLibs
LIBRARIES ${CMAKE_REQUIRED_LIBRARIES}
CONFIGURATION "${CMAKE_TRY_COMPILE_CONFIGURATION}" )

CMakeForceCompiler
Deprecated since version 3.6: Do not use.

The macros provided by this module were once intended for use by cross-compiling toolchain files when
CMake was not able to automatically detect the compiler identification. Since the introduction of this
module, CMake's compiler identification capabilities have improved and can now be taught to recognize any
compiler. Furthermore, the suite of information CMake detects from a compiler is now too extensive to be
provided by toolchain files using these macros.

One common use case for this module was to skip CMake's checks for a working compiler when using a
cross-compiler that cannot link binaries without special flags or custom linker scripts. This case is
now supported by setting the CMAKE_TRY_COMPILE_TARGET_TYPE variable in the toolchain file instead.

----

Macro CMAKE_FORCE_C_COMPILER has the following signature:

CMAKE_FORCE_C_COMPILER(<compiler> <compiler-id>)

It sets CMAKE_C_COMPILER to the given compiler and the cmake internal variable CMAKE_C_COMPILER_ID to the
given compiler-id. It also bypasses the check for working compiler and basic compiler information tests.

Macro CMAKE_FORCE_CXX_COMPILER has the following signature:

CMAKE_FORCE_CXX_COMPILER(<compiler> <compiler-id>)

It sets CMAKE_CXX_COMPILER to the given compiler and the cmake internal variable CMAKE_CXX_COMPILER_ID to
the given compiler-id. It also bypasses the check for working compiler and basic compiler information
tests.

Macro CMAKE_FORCE_Fortran_COMPILER has the following signature:

CMAKE_FORCE_Fortran_COMPILER(<compiler> <compiler-id>)

It sets CMAKE_Fortran_COMPILER to the given compiler and the cmake internal variable
CMAKE_Fortran_COMPILER_ID to the given compiler-id. It also bypasses the check for working compiler and
basic compiler information tests.

So a simple toolchain file could look like this:

include (CMakeForceCompiler)
set(CMAKE_SYSTEM_NAME Generic)
CMAKE_FORCE_C_COMPILER (chc12 MetrowerksHicross)
CMAKE_FORCE_CXX_COMPILER (chc12 MetrowerksHicross)

CMakeParseArguments
This module once implemented the cmake_parse_arguments() command that is now implemented natively by
CMake. It is now an empty placeholder for compatibility with projects that include it to get the command
from CMake 3.4 and lower.

Documentation
Deprecated since version 3.18: This module does nothing, unless policy CMP0106 is set to OLD.

This module provides support for the VTK documentation framework. It relies on several tools (Doxygen,
Perl, etc).

MacroAddFileDependencies
Deprecated since version 3.14.

MACRO_ADD_FILE_DEPENDENCIES(<source> <files>...)

Do not use this command in new code. It is just a wrapper around:

set_property(SOURCE <source> APPEND PROPERTY OBJECT_DEPENDS <files>...)

Instead use the set_property() command to append to the OBJECT_DEPENDS source file property directly.

TestCXXAcceptsFlag
Deprecated since version 3.0: See CheckCXXCompilerFlag.

Check if the CXX compiler accepts a flag.

CHECK_CXX_ACCEPTS_FLAG(<flags> <variable>)

<flags>
the flags to try

<variable>
variable to store the result

UseJavaClassFilelist
Changed in version 3.20: This module was previously documented by mistake and was never meant for direct
inclusion by project code. See the UseJava module.

UseJavaSymlinks
Changed in version 3.20: This module was previously documented by mistake and was never meant for direct
inclusion by project code. See the UseJava module.

UsePkgConfig
Obsolete pkg-config module for CMake, use FindPkgConfig instead.

This module defines the following macro:

PKGCONFIG(package includedir libdir linkflags cflags)

Calling PKGCONFIG will fill the desired information into the 4 given arguments, e.g.
PKGCONFIG(libart-2.0 LIBART_INCLUDE_DIR LIBART_LINK_DIR LIBART_LINK_FLAGS LIBART_CFLAGS) if pkg-config
was NOT found or the specified software package doesn't exist, the variable will be empty when the
function returns, otherwise they will contain the respective information

Use_wxWindows
Deprecated since version 2.8.10: Use find_package(wxWidgets) and include(${wxWidgets_USE_FILE}) instead.

This convenience include finds if wxWindows is installed and set the appropriate libs, incdirs, flags
etc. author Jan Woetzel <jw -at- mip.informatik.uni-kiel.de> (07/2003)

USAGE:

just include Use_wxWindows.cmake
in your projects CMakeLists.txt

include( ${CMAKE_MODULE_PATH}/Use_wxWindows.cmake)

if you are sure you need GL then

set(WXWINDOWS_USE_GL 1)

*before* you include this file.

WriteBasicConfigVersionFile
Deprecated since version 3.0: Use the identical command write_basic_package_version_file() from module
CMakePackageConfigHelpers.

WRITE_BASIC_CONFIG_VERSION_FILE( filename
[VERSION major.minor.patch]
COMPATIBILITY (AnyNewerVersion|SameMajorVersion|SameMinorVersion|ExactVersion)
[ARCH_INDEPENDENT]
)

WriteCompilerDetectionHeader
Deprecated since version 3.20: This module is available only if policy CMP0120 is not set to NEW. Do not
use it in new code.

New in version 3.1.

This module provides the function write_compiler_detection_header().

This function can be used to generate a file suitable for preprocessor inclusion which contains macros to
be used in source code:

write_compiler_detection_header(
FILE <file>
PREFIX <prefix>
[OUTPUT_FILES_VAR <output_files_var> OUTPUT_DIR <output_dir>]
COMPILERS <compiler> [...]
FEATURES <feature> [...]
[BARE_FEATURES <feature> [...]]
[VERSION <version>]
[PROLOG <prolog>]
[EPILOG <epilog>]
[ALLOW_UNKNOWN_COMPILERS]
[ALLOW_UNKNOWN_COMPILER_VERSIONS]
)

This generates the file <file> with macros which all have the prefix <prefix>.

By default, all content is written directly to the <file>. The OUTPUT_FILES_VAR may be specified to
cause the compiler-specific content to be written to separate files. The separate files are then
available in the <output_files_var> and may be consumed by the caller for installation for example. The
OUTPUT_DIR specifies a relative path from the main <file> to the compiler-specific files. For example:

write_compiler_detection_header(
FILE climbingstats_compiler_detection.h
PREFIX ClimbingStats
OUTPUT_FILES_VAR support_files
OUTPUT_DIR compilers
COMPILERS GNU Clang MSVC Intel
FEATURES cxx_variadic_templates
)
install(FILES
${CMAKE_CURRENT_BINARY_DIR}/climbingstats_compiler_detection.h
DESTINATION include
)
install(FILES
${support_files}
DESTINATION include/compilers
)

VERSION may be used to specify the API version to be generated. Future versions of CMake may introduce
alternative APIs. A given API is selected by any <version> value greater than or equal to the version of
CMake that introduced the given API and less than the version of CMake that introduced its succeeding
API. The value of the CMAKE_MINIMUM_REQUIRED_VERSION variable is used if no explicit version is
specified. (As of CMake version 3.22.1 there is only one API version.)

PROLOG may be specified as text content to write at the start of the header. EPILOG may be specified as
text content to write at the end of the header

At least one <compiler> and one <feature> must be listed. Compilers which are known to CMake, but not
specified are detected and a preprocessor #error is generated for them. A preprocessor macro matching
<PREFIX>_COMPILER_IS_<compiler> is generated for each compiler known to CMake to contain the value 0 or
1.

Possible compiler identifiers are documented with the CMAKE_<LANG>_COMPILER_ID variable. Available
features in this version of CMake are listed in the CMAKE_C_KNOWN_FEATURES and CMAKE_CXX_KNOWN_FEATURES
global properties. See the cmake-compile-features(7) manual for information on compile features.

New in version 3.2: Added MSVC and AppleClang compiler support.

New in version 3.6: Added Intel compiler support.

Changed in version 3.8: The {c,cxx}_std_* meta-features are ignored if requested.

New in version 3.8: ALLOW_UNKNOWN_COMPILERS and ALLOW_UNKNOWN_COMPILER_VERSIONS cause the module to
generate conditions that treat unknown compilers as simply lacking all features. Without these options
the default behavior is to generate a #error for unknown compilers and versions.

New in version 3.12: BARE_FEATURES will define the compatibility macros with the name used in newer
versions of the language standard, so the code can use the new feature name unconditionally.

Feature Test Macros
For each compiler, a preprocessor macro is generated matching <PREFIX>_COMPILER_IS_<compiler> which has
the content either 0 or 1, depending on the compiler in use. Preprocessor macros for compiler version
components are generated matching <PREFIX>_COMPILER_VERSION_MAJOR <PREFIX>_COMPILER_VERSION_MINOR and
<PREFIX>_COMPILER_VERSION_PATCH containing decimal values for the corresponding compiler version
components, if defined.

A preprocessor test is generated based on the compiler version denoting whether each feature is enabled.
A preprocessor macro matching <PREFIX>_COMPILER_<FEATURE>, where <FEATURE> is the upper-case <feature>
name, is generated to contain the value 0 or 1 depending on whether the compiler in use supports the
feature:

write_compiler_detection_header(
FILE climbingstats_compiler_detection.h
PREFIX ClimbingStats
COMPILERS GNU Clang AppleClang MSVC Intel
FEATURES cxx_variadic_templates
)

#if ClimbingStats_COMPILER_CXX_VARIADIC_TEMPLATES
template<typename... T>
void someInterface(T t...) { /* ... */ }
#else
// Compatibility versions
template<typename T1>
void someInterface(T1 t1) { /* ... */ }
template<typename T1, typename T2>
void someInterface(T1 t1, T2 t2) { /* ... */ }
template<typename T1, typename T2, typename T3>
void someInterface(T1 t1, T2 t2, T3 t3) { /* ... */ }
#endif

Symbol Macros
Some additional symbol-defines are created for particular features for use as symbols which may be
conditionally defined empty:

class MyClass ClimbingStats_FINAL
{
ClimbingStats_CONSTEXPR int someInterface() { return 42; }
};

The ClimbingStats_FINAL macro will expand to final if the compiler (and its flags) support the cxx_final
feature, and the ClimbingStats_CONSTEXPR macro will expand to constexpr if cxx_constexpr is supported.

If BARE_FEATURES cxx_final was given as argument the final keyword will be defined for old compilers,
too.

The following features generate corresponding symbol defines and if they are available as BARE_FEATURES:

┌──────────────────────┬───────────────────────────┬─────────────┬──────┐
│Feature │ Define │ Symbol │ bare │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│c_restrict │ <PREFIX>_RESTRICT │ restrict │ yes │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│cxx_constexpr │ <PREFIX>_CONSTEXPR │ constexpr │ yes │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│cxx_deleted_functions │ <PREFIX>_DELETED_FUNCTION │ = delete │ │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│cxx_extern_templates │ <PREFIX>_EXTERN_TEMPLATE │ extern │ │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│cxx_final │ <PREFIX>_FINAL │ final │ yes │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│cxx_noexcept │ <PREFIX>_NOEXCEPT │ noexcept │ yes │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│cxx_noexcept │ <PREFIX>_NOEXCEPT_EXPR(X) │ noexcept(X) │ │
├──────────────────────┼───────────────────────────┼─────────────┼──────┤
│cxx_override │ <PREFIX>_OVERRIDE │ override │ yes │
└──────────────────────┴───────────────────────────┴─────────────┴──────┘

Compatibility Implementation Macros
Some features are suitable for wrapping in a macro with a backward compatibility implementation if the
compiler does not support the feature.

When the cxx_static_assert feature is not provided by the compiler, a compatibility implementation is
available via the <PREFIX>_STATIC_ASSERT(COND) and <PREFIX>_STATIC_ASSERT_MSG(COND, MSG) function-like
macros. The macros expand to static_assert where that compiler feature is available, and to a
compatibility implementation otherwise. In the first form, the condition is stringified in the message
field of static_assert. In the second form, the message MSG is passed to the message field of
static_assert, or ignored if using the backward compatibility implementation.

The cxx_attribute_deprecated feature provides a macro definition <PREFIX>_DEPRECATED, which expands to
either the standard [[deprecated]] attribute or a compiler-specific decorator such as
__attribute__((__deprecated__)) used by GNU compilers.

The cxx_alignas feature provides a macro definition <PREFIX>_ALIGNAS which expands to either the standard
alignas decorator or a compiler-specific decorator such as __attribute__ ((__aligned__)) used by GNU
compilers.

The cxx_alignof feature provides a macro definition <PREFIX>_ALIGNOF which expands to either the standard
alignof decorator or a compiler-specific decorator such as __alignof__ used by GNU compilers.

┌─────────────────────────┬────────────────────────────┬────────────────┬──────┐
│Feature │ Define │ Symbol │ bare │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_alignas │ <PREFIX>_ALIGNAS │ alignas │ │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_alignof │ <PREFIX>_ALIGNOF │ alignof │ │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_nullptr │ <PREFIX>_NULLPTR │ nullptr │ yes │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_static_assert │ <PREFIX>_STATIC_ASSERT │ static_assert │ │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_static_assert │ <PREFIX>_STATIC_ASSERT_MSG │ static_assert │ │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_attribute_deprecated │ <PREFIX>_DEPRECATED │ [[deprecated]] │ │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_attribute_deprecated │ <PREFIX>_DEPRECATED_MSG │ [[deprecated]] │ │
├─────────────────────────┼────────────────────────────┼────────────────┼──────┤
│cxx_thread_local │ <PREFIX>_THREAD_LOCAL │ thread_local │ │
└─────────────────────────┴────────────────────────────┴────────────────┴──────┘

A use-case which arises with such deprecation macros is the deprecation of an entire library. In that
case, all public API in the library may be decorated with the <PREFIX>_DEPRECATED macro. This results in
very noisy build output when building the library itself, so the macro may be may be defined to empty in
that case when building the deprecated library:

add_library(compat_support ${srcs})
target_compile_definitions(compat_support
PRIVATE
CompatSupport_DEPRECATED=
)

Example Usage
NOTE:
This section was migrated from the cmake-compile-features(7) manual since it relies on the
WriteCompilerDetectionHeader module which is removed by policy CMP0120.

Compile features may be preferred if available, without creating a hard requirement. For example, a
library may provide alternative implementations depending on whether the cxx_variadic_templates feature
is available:

#if Foo_COMPILER_CXX_VARIADIC_TEMPLATES
template<int I, int... Is>
struct Interface;

template<int I>
struct Interface<I>
{
static int accumulate()
{
return I;
}
};

template<int I, int... Is>
struct Interface
{
static int accumulate()
{
return I + Interface<Is...>::accumulate();
}
};
#else
template<int I1, int I2 = 0, int I3 = 0, int I4 = 0>
struct Interface
{
static int accumulate() { return I1 + I2 + I3 + I4; }
};
#endif

Such an interface depends on using the correct preprocessor defines for the compiler features. CMake can
generate a header file containing such defines using the WriteCompilerDetectionHeader module. The module
contains the write_compiler_detection_header function which accepts parameters to control the content of
the generated header file:

write_compiler_detection_header(
FILE "${CMAKE_CURRENT_BINARY_DIR}/foo_compiler_detection.h"
PREFIX Foo
COMPILERS GNU
FEATURES
cxx_variadic_templates
)

Such a header file may be used internally in the source code of a project, and it may be installed and
used in the interface of library code.

For each feature listed in FEATURES, a preprocessor definition is created in the header file, and defined
to either 1 or 0.

Additionally, some features call for additional defines, such as the cxx_final and cxx_override features.
Rather than being used in #ifdef code, the final keyword is abstracted by a symbol which is defined to
either final, a compiler-specific equivalent, or to empty. That way, C++ code can be written to
unconditionally use the symbol, and compiler support determines what it is expanded to:

struct Interface {
virtual void Execute() = 0;
};

struct Concrete Foo_FINAL {
void Execute() Foo_OVERRIDE;
};

In this case, Foo_FINAL will expand to final if the compiler supports the keyword, or to empty otherwise.

In this use-case, the project code may wish to enable a particular language standard if available from
the compiler. The CXX_STANDARD target property may be set to the desired language standard for a
particular target, and the CMAKE_CXX_STANDARD variable may be set to influence all following targets:

write_compiler_detection_header(
FILE "${CMAKE_CURRENT_BINARY_DIR}/foo_compiler_detection.h"
PREFIX Foo
COMPILERS GNU
FEATURES
cxx_final cxx_override
)

# Includes foo_compiler_detection.h and uses the Foo_FINAL symbol
# which will expand to 'final' if the compiler supports the requested
# CXX_STANDARD.
add_library(foo foo.cpp)
set_property(TARGET foo PROPERTY CXX_STANDARD 11)

# Includes foo_compiler_detection.h and uses the Foo_FINAL symbol
# which will expand to 'final' if the compiler supports the feature,
# even though CXX_STANDARD is not set explicitly. The requirement of
# cxx_constexpr causes CMake to set CXX_STANDARD internally, which
# affects the compile flags.
add_library(foo_impl foo_impl.cpp)
target_compile_features(foo_impl PRIVATE cxx_constexpr)

The write_compiler_detection_header function also creates compatibility code for other features which
have standard equivalents. For example, the cxx_static_assert feature is emulated with a template and
abstracted via the <PREFIX>_STATIC_ASSERT and <PREFIX>_STATIC_ASSERT_MSG function-macros.

Deprecated Find Modules
FindCUDA
WARNING:
Deprecated since version 3.10.

It is no longer necessary to use this module or call find_package(CUDA) for compiling CUDA code. Instead,
list CUDA among the languages named in the top-level call to the project() command, or call the
enable_language() command with CUDA. Then one can add CUDA (.cu) sources directly to targets similar to
other languages.

New in version 3.17: To find and use the CUDA toolkit libraries manually, use the FindCUDAToolkit module
instead. It works regardless of the CUDA language being enabled.

Documentation of Deprecated Usage
Tools for building CUDA C files: libraries and build dependencies.

This script locates the NVIDIA CUDA C tools. It should work on Linux, Windows, and macOS and should be
reasonably up to date with CUDA C releases.

New in version 3.19: QNX support.

This script makes use of the standard find_package() arguments of <VERSION>, REQUIRED and QUIET.
CUDA_FOUND will report if an acceptable version of CUDA was found.

The script will prompt the user to specify CUDA_TOOLKIT_ROOT_DIR if the prefix cannot be determined by
the location of nvcc in the system path and REQUIRED is specified to find_package(). To use a different
installed version of the toolkit set the environment variable CUDA_BIN_PATH before running cmake (e.g.
CUDA_BIN_PATH=/usr/local/cuda1.0 instead of the default /usr/local/cuda) or set CUDA_TOOLKIT_ROOT_DIR
after configuring. If you change the value of CUDA_TOOLKIT_ROOT_DIR, various components that depend on
the path will be relocated.

It might be necessary to set CUDA_TOOLKIT_ROOT_DIR manually on certain platforms, or to use a CUDA
runtime not installed in the default location. In newer versions of the toolkit the CUDA library is
included with the graphics driver -- be sure that the driver version matches what is needed by the CUDA
runtime version.

Input Variables
The following variables affect the behavior of the macros in the script (in alphabetical order). Note
that any of these flags can be changed multiple times in the same directory before calling
cuda_add_executable(), cuda_add_library(), cuda_compile(), cuda_compile_ptx(), cuda_compile_fatbin(),
cuda_compile_cubin() or cuda_wrap_srcs():

CUDA_64_BIT_DEVICE_CODE (Default: host bit size)
Set to ON to compile for 64 bit device code, OFF for 32 bit device code. Note that making this
different from the host code when generating object or C files from CUDA code just won't work,
because size_t gets defined by nvcc in the generated source. If you compile to PTX and then load
the file yourself, you can mix bit sizes between device and host.

CUDA_ATTACH_VS_BUILD_RULE_TO_CUDA_FILE (Default: ON)
Set to ON if you want the custom build rule to be attached to the source file in Visual Studio.
Turn OFF if you add the same cuda file to multiple targets.

This allows the user to build the target from the CUDA file; however, bad things can happen if the
CUDA source file is added to multiple targets. When performing parallel builds it is possible for
the custom build command to be run more than once and in parallel causing cryptic build errors.
VS runs the rules for every source file in the target, and a source can have only one rule no
matter how many projects it is added to. When the rule is run from multiple targets race
conditions can occur on the generated file. Eventually everything will get built, but if the user
is unaware of this behavior, there may be confusion. It would be nice if this script could detect
the reuse of source files across multiple targets and turn the option off for the user, but no
good solution could be found.

CUDA_BUILD_CUBIN (Default: OFF)
Set to ON to enable and extra compilation pass with the -cubin option in Device mode. The output
is parsed and register, shared memory usage is printed during build.

CUDA_BUILD_EMULATION (Default: OFF for device mode)
Set to ON for Emulation mode. -D_DEVICEEMU is defined for CUDA C files when CUDA_BUILD_EMULATION
is TRUE.

CUDA_LINK_LIBRARIES_KEYWORD (Default: "")
New in version 3.9.

The <PRIVATE|PUBLIC|INTERFACE> keyword to use for internal target_link_libraries() calls. The
default is to use no keyword which uses the old "plain" form of target_link_libraries(). Note that
is matters because whatever is used inside the FindCUDA module must also be used outside - the two
forms of target_link_libraries() cannot be mixed.

CUDA_GENERATED_OUTPUT_DIR (Default: CMAKE_CURRENT_BINARY_DIR)
Set to the path you wish to have the generated files placed. If it is blank output files will be
placed in CMAKE_CURRENT_BINARY_DIR. Intermediate files will always be placed in
CMAKE_CURRENT_BINARY_DIR/CMakeFiles.

CUDA_HOST_COMPILATION_CPP (Default: ON)
Set to OFF for C compilation of host code.

CUDA_HOST_COMPILER (Default: CMAKE_C_COMPILER)
Set the host compiler to be used by nvcc. Ignored if -ccbin or --compiler-bindir is already
present in the CUDA_NVCC_FLAGS or CUDA_NVCC_FLAGS_<CONFIG> variables. For Visual Studio targets,
the host compiler is constructed with one or more visual studio macros such as $(VCInstallDir),
that expands out to the path when the command is run from within VS.

New in version 3.13: If the CUDAHOSTCXX environment variable is set it will be used as the
default.

CUDA_NVCC_FLAGS, CUDA_NVCC_FLAGS_<CONFIG>
Additional NVCC command line arguments. NOTE: multiple arguments must be semi-colon delimited
(e.g. --compiler-options;-Wall)

New in version 3.6: Contents of these variables may use generator expressions.

CUDA_PROPAGATE_HOST_FLAGS (Default: ON)
Set to ON to propagate CMAKE_{C,CXX}_FLAGS and their configuration dependent counterparts (e.g.
CMAKE_C_FLAGS_DEBUG) automatically to the host compiler through nvcc's -Xcompiler flag. This
helps make the generated host code match the rest of the system better. Sometimes certain flags
give nvcc problems, and this will help you turn the flag propagation off. This does not affect
the flags supplied directly to nvcc via CUDA_NVCC_FLAGS or through the OPTION flags specified
through cuda_add_library(), cuda_add_executable(), or cuda_wrap_srcs(). Flags used for shared
library compilation are not affected by this flag.

CUDA_SEPARABLE_COMPILATION (Default: OFF)
If set this will enable separable compilation for all CUDA runtime object files. If used outside
of cuda_add_executable() and cuda_add_library() (e.g. calling cuda_wrap_srcs() directly),
cuda_compute_separable_compilation_object_file_name() and
cuda_link_separable_compilation_objects() should be called.

CUDA_SOURCE_PROPERTY_FORMAT
New in version 3.3.

If this source file property is set, it can override the format specified to cuda_wrap_srcs()
(OBJ, PTX, CUBIN, or FATBIN). If an input source file is not a .cu file, setting this file will
cause it to be treated as a .cu file. See documentation for set_source_files_properties on how to
set this property.

CUDA_USE_STATIC_CUDA_RUNTIME (Default: ON)
New in version 3.3.

When enabled the static version of the CUDA runtime library will be used in CUDA_LIBRARIES. If
the version of CUDA configured doesn't support this option, then it will be silently disabled.

CUDA_VERBOSE_BUILD (Default: OFF)
Set to ON to see all the commands used when building the CUDA file. When using a Makefile
generator the value defaults to VERBOSE (run make VERBOSE=1 to see output), although setting
CUDA_VERBOSE_BUILD to ON will always print the output.

Commands
The script creates the following functions and macros (in alphabetical order):

cuda_add_cufft_to_target(<cuda_target>)

Adds the cufft library to the target (can be any target). Handles whether you are in emulation mode or
not.

cuda_add_cublas_to_target(<cuda_target>)

Adds the cublas library to the target (can be any target). Handles whether you are in emulation mode or
not.

cuda_add_executable(<cuda_target> <file>...
[WIN32] [MACOSX_BUNDLE] [EXCLUDE_FROM_ALL] [OPTIONS ...])

Creates an executable <cuda_target> which is made up of the files specified. All of the non CUDA C files
are compiled using the standard build rules specified by CMake and the CUDA files are compiled to object
files using nvcc and the host compiler. In addition CUDA_INCLUDE_DIRS is added automatically to
include_directories(). Some standard CMake target calls can be used on the target after calling this
macro (e.g. set_target_properties() and target_link_libraries()), but setting properties that adjust
compilation flags will not affect code compiled by nvcc. Such flags should be modified before calling
cuda_add_executable(), cuda_add_library() or cuda_wrap_srcs().

cuda_add_library(<cuda_target> <file>...
[STATIC | SHARED | MODULE] [EXCLUDE_FROM_ALL] [OPTIONS ...])

Same as cuda_add_executable() except that a library is created.

cuda_build_clean_target()

Creates a convenience target that deletes all the dependency files generated. You should make clean
after running this target to ensure the dependency files get regenerated.

cuda_compile(<generated_files> <file>... [STATIC | SHARED | MODULE]
[OPTIONS ...])

Returns a list of generated files from the input source files to be used with add_library() or
add_executable().

cuda_compile_ptx(<generated_files> <file>... [OPTIONS ...])

Returns a list of PTX files generated from the input source files.

cuda_compile_fatbin(<generated_files> <file>... [OPTIONS ...])

New in version 3.1.

Returns a list of FATBIN files generated from the input source files.

cuda_compile_cubin(<generated_files> <file>... [OPTIONS ...])

New in version 3.1.

Returns a list of CUBIN files generated from the input source files.

cuda_compute_separable_compilation_object_file_name(<output_file_var>
<cuda_target>
<object_files>)

Compute the name of the intermediate link file used for separable compilation. This file name is
typically passed into CUDA_LINK_SEPARABLE_COMPILATION_OBJECTS. output_file_var is produced based on
cuda_target the list of objects files that need separable compilation as specified by <object_files>. If
the <object_files> list is empty, then <output_file_var> will be empty. This function is called
automatically for cuda_add_library() and cuda_add_executable(). Note that this is a function and not a
macro.

cuda_include_directories(path0 path1 ...)

Sets the directories that should be passed to nvcc (e.g. nvcc -Ipath0 -Ipath1 ...). These paths usually
contain other .cu files.

cuda_link_separable_compilation_objects(<output_file_var> <cuda_target>
<nvcc_flags> <object_files>)

Generates the link object required by separable compilation from the given object files. This is called
automatically for cuda_add_executable() and cuda_add_library(), but can be called manually when using
cuda_wrap_srcs() directly. When called from cuda_add_library() or cuda_add_executable() the <nvcc_flags>
passed in are the same as the flags passed in via the OPTIONS argument. The only nvcc flag added
automatically is the bitness flag as specified by CUDA_64_BIT_DEVICE_CODE. Note that this is a function
instead of a macro.

cuda_select_nvcc_arch_flags(<out_variable> [<target_CUDA_architecture> ...])

Selects GPU arch flags for nvcc based on target_CUDA_architecture.

Values for target_CUDA_architecture:

• Auto: detects local machine GPU compute arch at runtime.

• Common and All: cover common and entire subsets of architectures.

• <name>: one of Fermi, Kepler, Maxwell, Kepler+Tegra, Kepler+Tesla, Maxwell+Tegra, Pascal.

• <ver>, <ver>(<ver>), <ver>+PTX, where <ver> is one of 2.0, 2.1, 3.0, 3.2, 3.5, 3.7, 5.0, 5.2, 5.3, 6.0,
6.2.

Returns list of flags to be added to CUDA_NVCC_FLAGS in <out_variable>. Additionally, sets
<out_variable>_readable to the resulting numeric list.

Example:

cuda_select_nvcc_arch_flags(ARCH_FLAGS 3.0 3.5+PTX 5.2(5.0) Maxwell)
list(APPEND CUDA_NVCC_FLAGS ${ARCH_FLAGS})

More info on CUDA architectures: https://en.wikipedia.org/wiki/CUDA. Note that this is a function
instead of a macro.

cuda_wrap_srcs(<cuda_target> <format> <generated_files> <file>...
[STATIC | SHARED | MODULE] [OPTIONS ...])

This is where all the magic happens. cuda_add_executable(), cuda_add_library(), cuda_compile(), and
cuda_compile_ptx() all call this function under the hood.

Given the list of files <file>... this macro generates custom commands that generate either PTX or
linkable objects (use PTX or OBJ for the <format> argument to switch). Files that don't end with .cu or
have the HEADER_FILE_ONLY property are ignored.

The arguments passed in after OPTIONS are extra command line options to give to nvcc. You can also
specify per configuration options by specifying the name of the configuration followed by the options.
General options must precede configuration specific options. Not all configurations need to be
specified, only the ones provided will be used. For example:

cuda_add_executable(...
OPTIONS -DFLAG=2 "-DFLAG_OTHER=space in flag"
DEBUG -g
RELEASE --use_fast_math
RELWITHDEBINFO --use_fast_math;-g
MINSIZEREL --use_fast_math)

For certain configurations (namely VS generating object files with CUDA_ATTACH_VS_BUILD_RULE_TO_CUDA_FILE
set to ON), no generated file will be produced for the given cuda file. This is because when you add the
cuda file to Visual Studio it knows that this file produces an object file and will link in the resulting
object file automatically.

This script will also generate a separate cmake script that is used at build time to invoke nvcc. This
is for several reasons:

• nvcc can return negative numbers as return values which confuses Visual Studio into thinking that the
command succeeded. The script now checks the error codes and produces errors when there was a problem.

• nvcc has been known to not delete incomplete results when it encounters problems. This confuses build
systems into thinking the target was generated when in fact an unusable file exists. The script now
deletes the output files if there was an error.

• By putting all the options that affect the build into a file and then make the build rule dependent on
the file, the output files will be regenerated when the options change.

This script also looks at optional arguments STATIC, SHARED, or MODULE to determine when to target the
object compilation for a shared library. BUILD_SHARED_LIBS is ignored in cuda_wrap_srcs(), but it is
respected in cuda_add_library(). On some systems special flags are added for building objects intended
for shared libraries. A preprocessor macro, <target_name>_EXPORTS is defined when a shared library
compilation is detected.

Flags passed into add_definitions with -D or /D are passed along to nvcc.

Result Variables
The script defines the following variables:

CUDA_VERSION_MAJOR
The major version of cuda as reported by nvcc.

CUDA_VERSION_MINOR
The minor version.

CUDA_VERSION, CUDA_VERSION_STRING
Full version in the X.Y format.

CUDA_HAS_FP16
New in version 3.6: Whether a short float (float16, fp16) is supported.

CUDA_TOOLKIT_ROOT_DIR
Path to the CUDA Toolkit (defined if not set).

CUDA_SDK_ROOT_DIR
Path to the CUDA SDK. Use this to find files in the SDK. This script will not directly support
finding specific libraries or headers, as that isn't supported by NVIDIA. If you want to change
libraries when the path changes see the FindCUDA.cmake script for an example of how to clear these
variables. There are also examples of how to use the CUDA_SDK_ROOT_DIR to locate headers or
libraries, if you so choose (at your own risk).

CUDA_INCLUDE_DIRS
Include directory for cuda headers. Added automatically for cuda_add_executable() and
cuda_add_library().

CUDA_LIBRARIES
Cuda RT library.

CUDA_CUFFT_LIBRARIES
Device or emulation library for the Cuda FFT implementation (alternative to
cuda_add_cufft_to_target() macro)

CUDA_CUBLAS_LIBRARIES
Device or emulation library for the Cuda BLAS implementation (alternative to
cuda_add_cublas_to_target() macro).

CUDA_cudart_static_LIBRARY
Statically linkable cuda runtime library. Only available for CUDA version 5.5+.

CUDA_cudadevrt_LIBRARY
New in version 3.7: Device runtime library. Required for separable compilation.

CUDA_cupti_LIBRARY
CUDA Profiling Tools Interface library. Only available for CUDA version 4.0+.

CUDA_curand_LIBRARY
CUDA Random Number Generation library. Only available for CUDA version 3.2+.

CUDA_cusolver_LIBRARY
New in version 3.2: CUDA Direct Solver library. Only available for CUDA version 7.0+.

CUDA_cusparse_LIBRARY
CUDA Sparse Matrix library. Only available for CUDA version 3.2+.

CUDA_npp_LIBRARY
NVIDIA Performance Primitives lib. Only available for CUDA version 4.0+.

CUDA_nppc_LIBRARY
NVIDIA Performance Primitives lib (core). Only available for CUDA version 5.5+.

CUDA_nppi_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 5.5 - 8.0.

CUDA_nppial_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppicc_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppicom_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0 - 10.2.
Replaced by nvjpeg.

CUDA_nppidei_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppif_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppig_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppim_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppist_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppisu_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_nppitc_LIBRARY
NVIDIA Performance Primitives lib (image processing). Only available for CUDA version 9.0.

CUDA_npps_LIBRARY
NVIDIA Performance Primitives lib (signal processing). Only available for CUDA version 5.5+.

CUDA_nvcuvenc_LIBRARY
CUDA Video Encoder library. Only available for CUDA version 3.2+. Windows only.

CUDA_nvcuvid_LIBRARY
CUDA Video Decoder library. Only available for CUDA version 3.2+. Windows only.

CUDA_nvToolsExt_LIBRARY
New in version 3.16: NVIDA CUDA Tools Extension library. Available for CUDA version 5+.

CUDA_OpenCL_LIBRARY
New in version 3.16: NVIDA CUDA OpenCL library. Available for CUDA version 5+.

FindPythonInterp
Deprecated since version 3.12: Use FindPython3, FindPython2 or FindPython instead.

Find python interpreter

This module finds if Python interpreter is installed and determines where the executables are. This code
sets the following variables:

PYTHONINTERP_FOUND - Was the Python executable found
PYTHON_EXECUTABLE - path to the Python interpreter

PYTHON_VERSION_STRING - Python version found e.g. 2.5.2
PYTHON_VERSION_MAJOR - Python major version found e.g. 2
PYTHON_VERSION_MINOR - Python minor version found e.g. 5
PYTHON_VERSION_PATCH - Python patch version found e.g. 2

The Python_ADDITIONAL_VERSIONS variable can be used to specify a list of version numbers that should be
taken into account when searching for Python. You need to set this variable before calling
find_package(PythonInterp).

If calling both find_package(PythonInterp) and find_package(PythonLibs), call find_package(PythonInterp)
first to get the currently active Python version by default with a consistent version of
PYTHON_LIBRARIES.

NOTE:
A call to find_package(PythonInterp ${V}) for python version V may find a python executable with no
version suffix. In this case no attempt is made to avoid python executables from other versions. Use
FindPython3, FindPython2 or FindPython instead.

FindPythonLibs
Deprecated since version 3.12: Use FindPython3, FindPython2 or FindPython instead.

Find python libraries

This module finds if Python is installed and determines where the include files and libraries are. It
also determines what the name of the library is. This code sets the following variables:

PYTHONLIBS_FOUND - have the Python libs been found
PYTHON_LIBRARIES - path to the python library
PYTHON_INCLUDE_PATH - path to where Python.h is found (deprecated)
PYTHON_INCLUDE_DIRS - path to where Python.h is found
PYTHON_DEBUG_LIBRARIES - path to the debug library (deprecated)
PYTHONLIBS_VERSION_STRING - version of the Python libs found (since CMake 2.8.8)

If you'd like to specify the installation of Python to use, you should modify the following cache
variables:

PYTHON_LIBRARY - path to the python library
PYTHON_INCLUDE_DIR - path to where Python.h is found

FindQt
Deprecated since version 3.14: This module is available only if policy CMP0084 is not set to NEW.

Searches for all installed versions of Qt3 or Qt4.

This module cannot handle Qt5 or any later versions. For those, see cmake-qt(7).

This module should only be used if your project can work with multiple versions of Qt. If not, you
should just directly use FindQt4 or FindQt3. If multiple versions of Qt are found on the machine, then
The user must set the option DESIRED_QT_VERSION to the version they want to use. If only one version of
qt is found on the machine, then the DESIRED_QT_VERSION is set to that version and the matching FindQt3
or FindQt4 module is included. Once the user sets DESIRED_QT_VERSION, then the FindQt3 or FindQt4 module
is included.

QT_REQUIRED if this is set to TRUE then if CMake can
not find Qt4 or Qt3 an error is raised
and a message is sent to the user.

DESIRED_QT_VERSION OPTION is created
QT4_INSTALLED is set to TRUE if qt4 is found.
QT3_INSTALLED is set to TRUE if qt3 is found.

FindwxWindows
Deprecated since version 3.0: Replaced by FindwxWidgets.

Find wxWindows (wxWidgets) installation

This module finds if wxWindows/wxWidgets is installed and determines where the include files and
libraries are. It also determines what the name of the library is. This code sets the following
variables:

WXWINDOWS_FOUND = system has WxWindows
WXWINDOWS_LIBRARIES = path to the wxWindows libraries
on Unix/Linux with additional
linker flags from
"wx-config --libs"
CMAKE_WXWINDOWS_CXX_FLAGS = Compiler flags for wxWindows,
essentially "`wx-config --cxxflags`"
on Linux
WXWINDOWS_INCLUDE_DIR = where to find "wx/wx.h" and "wx/setup.h"
WXWINDOWS_LINK_DIRECTORIES = link directories, useful for rpath on
Unix
WXWINDOWS_DEFINITIONS = extra defines

OPTIONS If you need OpenGL support please

set(WXWINDOWS_USE_GL 1)

in your CMakeLists.txt before you include this file.

HAVE_ISYSTEM - true required to replace -I by -isystem on g++

For convenience include Use_wxWindows.cmake in your project's CMakeLists.txt using
include(${CMAKE_CURRENT_LIST_DIR}/Use_wxWindows.cmake).

USAGE

set(WXWINDOWS_USE_GL 1)
find_package(wxWindows)

NOTES wxWidgets 2.6.x is supported for monolithic builds e.g. compiled in wx/build/msw dir as:

nmake -f makefile.vc BUILD=debug SHARED=0 USE_OPENGL=1 MONOLITHIC=1

DEPRECATED

CMAKE_WX_CAN_COMPILE
WXWINDOWS_LIBRARY
CMAKE_WX_CXX_FLAGS
WXWINDOWS_INCLUDE_PATH

AUTHOR Jan Woetzel <http://www.mip.informatik.uni-kiel.de/~jw> (07/2003-01/2006)

Legacy CPack Modules
These modules used to be mistakenly exposed to the user, and have been moved out of user visibility. They
are for CPack internal use, and should never be used directly.

CPackArchive
New in version 3.9.

The documentation for the CPack Archive generator has moved here: CPack Archive Generator

CPackBundle
The documentation for the CPack Bundle generator has moved here: CPack Bundle Generator

CPackCygwin
The documentation for the CPack Cygwin generator has moved here: CPack Cygwin Generator

CPackDeb
The documentation for the CPack DEB generator has moved here: CPack DEB Generator

CPackDMG
The documentation for the CPack DragNDrop generator has moved here: CPack DragNDrop Generator

CPackFreeBSD
New in version 3.10.

The documentation for the CPack FreeBSD generator has moved here: CPack FreeBSD Generator

CPackNSIS
The documentation for the CPack NSIS generator has moved here: CPack NSIS Generator

CPackNuGet
New in version 3.12.

The documentation for the CPack NuGet generator has moved here: CPack NuGet Generator

CPackPackageMaker
The documentation for the CPack PackageMaker generator has moved here: CPack PackageMaker Generator

CPackProductBuild
New in version 3.7.

The documentation for the CPack productbuild generator has moved here: CPack productbuild Generator

CPackRPM
The documentation for the CPack RPM generator has moved here: CPack RPM Generator

CPackWIX
The documentation for the CPack WIX generator has moved here: CPack WIX Generator

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