Ubuntu Manpage: ctags-faq - Universal Ctags FAQ

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NAME

       ctags-faq - Universal Ctags FAQ

       This  is  the  Universal Ctags FAQ (Frequently-Asked Questions).  It is based on Exuberant
       Ctags FAQ

   Contents
       · DESCRIPTION

         · What is the difference between Universal Ctags and Exuberant Ctags?

         · How can I avoid having to specify my favorite option every time?

         · What are these strange bits of text beginning with ;" which follow many of  the  lines
           in the tag file?

         · Why can't I jump to class::member?

         · Why do I end up on the wrong line when I jump to a tag?

         · How do I jump to the tag I want instead of the wrong one by the same name?

         · How can I locate all references to a specific function or variable?

         · Why does appending tags to a tag file tag so long?

         · How should I set up tag files for a multi-level directory hierarchy?

         · Does Universal Ctags support Unicode file names?

         · Why does zsh cause "zsh: no matches found" error?

       · SEE ALSO

       · AUTHOR

DESCRIPTION

What is the difference between Universal Ctags and Exuberant Ctags?
Universal Ctags is an unofficial fork of Exuberant Ctags. The differences are summarized
in ctags-incompatibilities(7) man page.

The most notable one is that Universal Ctags doesn't read ~/.ctags file. Instead, it
reads *.ctags under ~/.ctags.d directory.

How can I avoid having to specify my favorite option every time?
Either by setting the environment variable CTAGS to your custom options, or putting them
into a ~/.ctags.d/anyname.ctags file in your home directory.

What are these strange bits of text beginning with ;" which follow many of the lines in the
tag file?
These are extension flags. They are added in order to provide extra information about the
tag that may be utilized by the editor in order to more intelligently handle tags. They
are appended to the EX command part of the tag line in a manner that provides backwards
compatibility with existing implementations of the Vi editor. The semicolon is an EX
command separator and the double quote begins an EX comment. Thus, the extension flags
appear as an EX comment and should be ignored by the editor when it processes the EX
command.

Some non-vi editors, however, implement only the bare minimum of EX commands in order to
process the search command or line number in the third field of the tag file. If you
encounter this problem, use the option --format=1 to generate a tag file without these
extensions (remember that you can set the CTAGS environment variable to any default
arguments you wish to supply). Then ask the supplier of your editor to implement handling
of this feature of EX commands.

Why can't I jump to class::member?
Because, by default, ctags only generates tags for the separate identifiers found in the
source files. If you specify the --extra=+q option, then ctags will also generate a
second, class-qualified tag for each class member (data and function/method) in the form
class::member for C++, and in the form class.method for Eiffel and Java.

Why do I end up on the wrong line when I jump to a tag?
By default, ctags encodes the line number in the file where macro (#define) tags are
found. This was done to remain compatible with the original UNIX version of ctags. If you
change the file containing the tag without rebuilding the tag file, the location of tag in
the tag file may no longer match the current location.

In order to avoid this problem, you can specify the option --excmd=p, which causes ctags
to use a search pattern to locate macro tags. I have never uncovered the reason why the
original UNIX ctags used line numbers exclusively for macro tags, but have so far resisted
changing the default behavior of Exuberant (and Universal) Ctags to behave differently.

How do I jump to the tag I want instead of the wrong one by the same name?
A tag file is simple a list of tag names and where to find them. If there are duplicate
entries, you often end up going to the wrong one because the tag file is sorted and your
editor locates the first one in the tag file.

Standard Vi provides no facilities to alter this behavior. However, Vim has some nice
features to minimize this problem, primarily by examining all matches and choosing the
best one under the circumstances. Vim also provides commands which allow for selection of
the desired matching tag.

How can I locate all references to a specific function or variable?
There are several packages already available which provide this capability. Namely, these
are: GLOBAL source code tag system, GNU id-utils, cscope, and cflow. As of this writing,
they can be found in the following locations:

· GLOBAL: http://www.gnu.org/software/global

· id-utils: http://www.gnu.org/software/idutils/idutils.html

· cscope: http://cscope.sourceforge.net

· cflow: ftp://www.ibiblio.org/pub/Linux/devel/lang/c

Why does appending tags to a tag file tag so long?
Sometimes, in an attempt to build a global tag file for all source files in a large source
tree of many directories, someone will make an attempt to run ctags in append (-a) mode on
every directory in the hierarchy. Each time ctags is invoked, its default behavior is to
sort the tag file once the tags for that execution have been added. As the cumulative tag
file grows, the sort time increases arithmetically.

The best way to avoid this problem (and the most efficient) is to make use of the
--recurse (or -R) option of ctags by executing the following command in the root of the
directory hierarchy (thus running ctags only once):

ctags -R

If you really insist on running ctags separately on each directory, you can avoid the sort
pass each time by specifying the option --sort=no. Once the tag file is completely built,
use the sort command to manually sort the final tag file, or let the final invocation of
ctags sort the file.

How should I set up tag files for a multi-level directory hierarchy?
There are a few ways of approaching this:

1. A local tag file in each directory containing only the tags for source files in that
directory.

2. One single big, global tag file present in the root directory of your hierarchy,
containing all tags present in all source files in the hierarchy.

3. A local tag file in each directory containing only the tags for source files in that
directory, in addition to one single global tag file present in the root directory of
your hierarchy, containing all non-static tags present in all source files in the
hierarchy.

4. A local tag file in each directory of the hierarchy, each one containing all tags
present in source files in that directory and all non-static tags in every directory
below it (note that this implies also having one big tag file in the root directory of
the hierarchy).

Each of these approaches has its own set of advantages and disadvantages, depending upon
your particular conditions. Which approach is deemed best depends upon the following
factors:

A. The ability of your editor to use multiple tag files.

If your editor cannot make use of multiple tag files (original vi implementations could
not), then one large tag file is the only way to go if you ever desire to jump to tags
located in other directories. If you never need to jump to tags in another directory
(i.e. the source in each directory is entirely self-contained), then a local tag file
in each directory will fit your needs.

B. The time is takes for your editor to look up a tag in the tag file.

The significance of this factor depends upon the size of your source tree and on
whether the source files are located on a local or remote file system. For source and
tag files located on a local file system, looking up a tag is not as big a hit as one
might first imagine, since vi implementations typically perform a binary search on a
sorted tag file. This may or may not be true for the editor you use. For files located
on a remote file system, reading a large file is an expensive operation.

C. Whether or not you expect the source code to change and the time it takes to rebuild a
tag file to account for changes to the source code.

While Universal Ctags is particularly fast in scanning source code (around 1-2 MB/sec),
a large project may still result in objectionable delays if one wishes to keep their
tag file(s) up to date on a frequent basis, or if the files are located on a remote
file system.

D. The presence of duplicate tags in the source code and the ability to handle them.

The impact of this factor is influenced by the following three issues:

1. How common are duplicate tags in your project?

2. Does your editor provide any facilities for dealing with duplicate tags?

While standard vi does not, many modern vi implementations, such as Vim have good
facilities for selecting the desired match from the list of duplicates. If your
editor does not support duplicate tags, then it will typically send you to only one
of them, whether or not that is the one you wanted (and not even notifying you that
there are other potential matches).

3. What is the significance of duplicate tags?

For example, if you have two tags of the same name from entirely isolated software
components, jumping first to the match found in component B while working in
component A may be entirely misleading, distracting or inconvenient (to keep having
to choose which one if your editor provides you with a list of matches). However,
if you have two tags of the same name for parallel builds (say two initialization
routines for different hosts), you may always want to specify which one you want.

Of the approaches listed above, I tend to favor Approach 3. My editor of choice is Vim,
which provides a rich set of features for handling multiple tag files, which partly
influences my choice. If you are working with source files on a remote file system, then I
would recommend either Approach 3 or Approach 4, depending upon the hit when reading the
global tag file.

The advantages of Approach 3 are many (assuming that your editor has the ability to
support both multiple tag files and duplicate tags). All lookups of tag located in the
current directory are fast and the local tag file can be quickly and easily regenerated in
one second or less (I have even mapped a keystroke to do this easily). A lookup of a
(necessarily non-static) tag found in another directory fails a lookup in the local tag
file, but is found in the global tag file, which satisfies all cross-directory lookups.
The global tag file can be automatically regenerated periodically with a cron job (and
perhaps the local tag files also).

Now I give an example of how you would implement Approach 3. Means of implementing the
other approaches can be performed in a similar manner.

Here is a visual representation of an example directory hierarchy:

Here is a recommended solution (conceptually) to build the tag files:

1. Within each of the leaf nodes (i.e. hdrs, lib, src, test) build a tag file using "ctags
*.[ch]". This can be easily be done for the whole hierarchy by making a shell script,
call it dirtags, containing the following lines:

#!/bin/sh
cd $1
ctags *

Now execute the following command:

find * -type d -exec dirtags {} \;

These tag files are trivial (and extremely quick) to rebuild while making changes
within a directory. The following Vim key mapping is quite useful to rebuild the tag
file in the directory of the current source file:

:nmap ,t :!(cd %:p:h;ctags *.[ch])&<CR><CR>

2. Build the global tag file:

cd ~/project
ctags --file-scope=no -R

thus constructing a tag file containing only non-static tags for all source files in
all descendent directories.

3. Configure your editor to read the local tag file first, then consult the global tag
file when not found in the local tag file. In Vim, this is done as follows:

:set tags=./tags,tags,~/project/tags

If you wish to implement Approach 4, you would need to replace the dirtags script of step
1 with the following:

#!/bin/sh
cd $1
ctags *
# Now append the non-static tags from descendent directories

find * -type d -prune -print | ctags -aR --file-scope=no -L-
And replace the configuration of step 3 with this:

:set tags=./tags;$HOME,tags

As a caveat, it should be noted that step 2 builds a global tag file whose file names will
be relative to the directory in which the global tag file is being built. This takes
advantage of the Vim tagrelative option, which causes the path to be interpreted a
relative to the location of the tag file instead of the current directory. For standard
vi, which always interprets the paths as relative to the current directory, we need to
build the global tag file with absolute path names. This can be accomplished by replacing
step 2 with the following:

cd ~/project
ctags --file-scope=no -R `pwd`

Does Universal Ctags support Unicode file names?
Yes, Unicode file names are supported on unix-like platforms (Linux, macOS, Cygwin, etc.).

However, on Windows, you need to use Windows 10 version 1903 or later to use Unicode file
names. (This is an experimental feature, though.) On older versions on Windows, Universal
Ctags only support file names represented in the current code page. If you still want to
use Unicode file names on them, use Cygwin or MSYS2 version of Universal Ctags as a
workaround.

Why does zsh cause zsh: no matches found error?
zsh causes error on the following cases;

ctags --extra=+* ...
ctags --exclude=foo/* ...

This is the 2nd most significant incompatibility feature of zsh.

Cited from "Z-Shell Frequently-Asked Questions", "2.1: Differences from sh and ksh";
... The next most classic difference is that unmatched glob patterns cause the command
to abort; set NO_NOMATCH for those.

You may add "setopt nonomatch" on your ~/.zshrc. Or you can escape glob patterns with
backslash;

ctags --extra=+\* ...
ctags --exclude=foo/\* ...

Or quote them;

ctags '--extra=+*' ...
ctags '--exclude=foo/*' ...

AUTHOR

       This   FAQ   is   based   on   Exuberant    Ctags    FAQ    by    Darren    Hiebert    and
       vberthoux@users.sourceforge.net

       Universal Ctags project: https://ctags.io/