Provided by: libpmem2-dev_1.13.1-1.1_amd64 
NAME
libpmem2 - persistent memory support library
NOTE: Support for Windows and FreeBSD deprecated since PMDK 1.13.0 release and will
be removed in the PMDK 1.14.0 release.
SYNOPSIS
#include <libpmem2.h>
cc ... -lpmem2
DESCRIPTION
libpmem2 provides low-level persistent memory (pmem) support for applications using direct
access storage (DAX), which is storage that supports load/store access without paging
blocks from a block storage device. Some types of non-volatile memory DIMMs (NVDIMMs)
provide this type of byte addressable access to storage. A persistent memory aware file
system is typically used to expose the direct access to applications. Memory mapping a
file from this type of file system results in the load/store, non-paged access to pmem.
This library is for applications that use persistent memory directly, without the help of
any library-supplied transactions or memory allocation. Higher-level libraries that
currently build on libpmem (previous variation of libpmem2) are available and are
recommended for most applications, see:
• libpmemobj(7), a general use persistent memory API, providing memory allocation and
transactional operations on variable-sized objects.
• libpmemblk(7), providing pmem-resident arrays of fixed-sized blocks with atomic updates.
• libpmemlog(7), providing a pmem-resident log file.
The libpmem2 library provides a comprehensive set of functions for robust use of
Persistent Memory. It relies on three core concepts: struct pmem2_src source, struct
pmem2_config config and struct pmem2_map map:
• source - an object describing the data source for mapping. The data source can be a
file descriptor, a file handle, or an anonymous mapping. APIs dedicated for creating
source are: pmem2_source_from_fd(3), pmem2_source_from_handle(3),
pmem2_source_from_anon(3).
• config - an object containing parameters that are used to create a mapping from a
source. The configuration structure must always be provided to create a mapping, but
the only required parameter to set in the config is granularity. The granularity should
by set using dedicated libpmem2 function pmem2_config_set_required_store_granularity(3)
which defines a maximum permitted granularity requested by the user. For more
information about the granularity concept read GRANULARITY section below.
In addition to the granularity setting, libpmem2 provides multiple optional functions to
configure target mapping, e.g., pmem2_config_set_length(3) to set length which will be
used for mapping, or pmem2_config_set_offset(3) which will be used to map the contents
from the specified location of the source, pmem2_config_set_sharing(3) which defines the
behavior and visibility of writes to the mapping’s pages.
• map - an object created by pmem2_map_new(3) using source and config as an input
parameters. The map structure can be then used to directly operate on the created
mapping through the use of its associated set of functions: pmem2_map_get_address(3),
pmem2_map_get_size(3), pmem2_map_get_store_granularity(3) - for getting address, size
and effective mapping granularity.
In addition to the basic functionality of managing the virtual address mapping, libpmem2
also provides optimized functions for modifying the mapped data. This includes data
flushing as well as memory copying.
To get proper function for data flushing use: pmem2_get_flush_fn(3),
pmem2_get_persist_fn(3) or pmem2_get_drain_fn(3). To get proper function for copying to
persistent memory, use map getters: pmem2_get_memcpy_fn(3), pmem2_get_memset_fn(3),
pmem2_get_memmove_fn(3).
The libpmem2 API also provides support for the badblock and unsafe shutdown state
handling.
To read or clear badblocks, the following functions are provided:
pmem2_badblock_context_new(3), pmem2_badblock_context_delete(3), pmem2_badblock_next(3)
and pmem2_badblock_clear(3).
To handle unsafe shutdown in the application, the following functions are provided:
pmem2_source_device_id(3), pmem2_source_device_usc(3). More detailed information about
unsafe shutdown detection and unsafe shutdown count can be found in the
libpmem2_unsafe_shutdown(7) man page.
GRANULARITY
The libpmem2 library introduces the concept of granularity through which you may easily
distinguish between different levels of storage performance capabilities available to the
application as related to power-fail protected domain. The way data reaches this
protected domain differs based on the platform and storage device capabilities.
Traditional block storage devices (SSD, HDD) must use system API calls such as msync(),
fsync() on Linux, or FlushFileBuffers(),FlushViewOfFile() on Windows to write data
reliably. Invoking these functions flushes the data to the medium with page granularity.
In the libpmem2 library, this type of flushing behavior is called PMEM2_GRANULARITY_PAGE.
In systems with persistent memory support, a power-fail protected domain may cover
different sets of resources: either the memory controller or the memory controller and CPU
caches. For this reason, libpmem2 distinguishes two types of granularity for persistent
memory: PMEM2_GRANULARITY_CACHE_LINE and PMEM2_GRANULARITY_BYTE.
If the power-fail protected domain covers only the memory controller, the CPU appropriate
cache lines must be flushed for the data to be considered persistent. This granularity
type is called PMEM2_GRANULARITY_CACHE_LINE. Depending on the architecture, there are
different types of machine instructions for flushing cache lines (e.g., CLWB, CLFLUSHOPT,
CLFLUSH for Intel x86_64 architecture). Usually, to ensure the ordering of stores, such
instructions must be followed by a barrier (e.g., SFENCE).
The third type of granularity PMEM2_GRANULARITY_BYTE applies to platforms where power-fail
protected domain covers both the memory controller and CPU caches. In such cases, cache
flush instructions are no longer needed, and the platform itself guarantees the
persistence of data. But barriers might still be required for ordering.
The library declares these granularity level in pmem2_granularity enum, which the
application must set in pmem2_config to the appropriate level for a mapping to succeed.
The software should set this config parameter to a value that most accurately represents
the target hardware characteristics and the storage patterns of the application. For
example, a database storage engine that operates on large logical pages that reside either
on SSDs or PMEM should set this value to PMEM2_GRANULARITY_PAGE. The library will create
mappings where the new map granularity is lower or equal to the requested one. For
example, a mapping with PMEM2_GRANULARITY_CACHE_LINE can be created for the required
granularity PMEM2_GRANULARITY_PAGE, but not vice versa.
CAVEATS
libpmem2 relies on the library destructor being called from the main thread. For this
reason, all functions that might trigger destruction (e.g. dlclose(3)) should be called in
the main thread. Otherwise some of the resources associated with that thread might not be
cleaned up properly.
ENVIRONMENT
libpmem2 can change its default behavior based on the following environment variables.
These are primarily intended for testing and are generally not required.
• PMEM2_FORCE_GRANULARITY=val
Setting this environment variable to val forces libpmem2 to use persist method specific
for forced granularity and skip granularity autodetecting mechanism. The concept of the
granularity is described in GRANULARITY section above. This variable is intended for use
during library testing.
The val argument accepts following text values:
• BYTE - force byte granularity.
• CACHE_LINE - force cache line granularity.
• PAGE - force page granularity.
Granularity values listed above are case-insensitive.
NOTE: The value of PMEM2_FORCE_GRANULARITY is not queried (and cached) at library
initialization time, but read during each pmem2_map_new(3) call.
This means that PMEM2_FORCE_GRANULARITY may still be set or modified by the program until
the first attempt to map a file.
• PMEM_NO_CLWB=1
Setting this environment variable to 1 forces libpmem2 to never issue the CLWB instruction
on Intel hardware, falling back to other cache flush instructions on that hardware instead
(CLFLUSHOPT or CLFLUSH). Without this setting, libpmem2 will always use the CLWB
instruction for flushing processor caches on platforms that support this instruction.
This variable is intended for use during library testing, but may be required for some
rare cases when using CLWB has a negative impact on performance.
• PMEM_NO_CLFLUSHOPT=1
Setting this environment variable to 1 forces libpmem2 to never issue the CLFLUSHOPT
instruction on Intel hardware, falling back to the CLFLUSH instructions instead. Without
this environment variable, libpmem2 will always use the CLFLUSHOPT instruction for
flushing processor caches on platforms that support the instruction, but where CLWB is not
available. This variable is intended for use during library testing.
• PMEM_NO_MOVNT=1
Setting this environment variable to 1 forces libpmem2 to never use the non-temporal move
instructions on Intel hardware. Without this environment variable, libpmem2 will use the
non-temporal instructions for copying larger ranges to persistent memory on platforms that
support these instructions. This variable is intended for use during library testing.
• PMEM_MOVNT_THRESHOLD=val
This environment variable allows overriding the minimum length of the pmem2_memmove_fn
operations, for which libpmem2 uses non-temporal move instructions. Setting this
environment variable to 0 forces libpmem2 to always use the non-temporal move instructions
if available. It has no effect if PMEM_NO_MOVNT is set to 1. This variable is intended
for use during library testing.
DEBUGGING
Two versions of libpmem2 are typically available on a development system. The normal
version, accessed when a program is linked using the -lpmem2 option, is optimized for
performance. That version skips checks that impact performance and never logs any trace
information or performs any run-time assertions.
A second version of libpmem2, accessed when a program uses the libraries under
/usr/lib/pmdk_debug, contains run-time assertions and trace points. The typical way to
access the debug version is to set the environment variable LD_LIBRARY_PATH to
/usr/lib/pmdk_debug or /usr/lib64/pmdk_debug, as appropriate. Debugging output is
controlled using the following environment variables. These variables have no effect on
the non-debug version of the library.
NOTE: On Debian/Ubuntu systems, this extra debug version of the library is shipped
in the respective -debug Debian package and placed in the /usr/lib/$ARCH/pmdk_dbg/
directory.
• PMEM2_LOG_LEVEL
The value of PMEM2_LOG_LEVEL enables trace points in the debug version of the library, as
follows:
• 0 - This is the default level when PMEM2_LOG_LEVEL is not set. No log messages are
emitted at this level.
• 1 - Additional details on any errors detected are logged, in addition to returning the
errno-based errors as usual. The same information may be retrieved using
pmem2_errormsg().
• 2 - A trace of basic operations is logged.
• 3 - Enables a very verbose amount of function call tracing in the library.
• 4 - Enables voluminous and fairly obscure tracing information that is likely only useful
to the libpmem2 developers.
Unless PMEM2_LOG_FILE is set, debugging output is written to stderr.
• PMEM2_LOG_FILE
Specifies the name of a file where all logging information should be written. If the last
character in the name is “-”, the PID of the current process will be appended to the file
name when the log file is created. If PMEM2_LOG_FILE is not set, output is written to
stderr.
EXAMPLE
The following example uses libpmem2 to flush changes made to raw, memory-mapped persistent
memory.
WARNING: There is nothing transactional about the persist from
pmem2_get_persist_fn(3) call in this example. Interrupting the program may result
in a partial write to pmem. Use a transactional library such as libpmemobj(7) to
avoid torn updates.
The basic example can be found in the repository under path
src/examples/libpmem2/basic/basic.c
(https://github.com/pmem/pmdk/blob/master/src/examples/libpmem2/basic/basic.c). It is
described in detail here (https://pmem.io/pmdk/libpmem2/).
ACKNOWLEDGEMENTS
libpmem2 builds on the persistent memory programming model recommended by the SNIA NVM
Programming Technical Work Group: <https://snia.org/nvmp>
SEE ALSO
FlushFileBuffers(), fsync(2), msync(2), pmem2_config_set_length(3),
pmem2_config_set_offset(3), pmem2_config_set_required_store_granularity(3),
pmem2_config_set_sharing(3),pmem2_get_drain_fn(3), pmem2_get_flush_fn(3),
pmem2_get_memcpy_fn(3), pmem2_get_memmove_fn(3), pmem2_get_memset_fn(3),
pmem2_get_persist_fn(3),pmem2_map_get_store_granularity(3), pmem2_map_new(3),
pmem2_source_from_anon(3), pmem2_source_from_fd(3), pmem2_source_from_handle(3),
libpmem2_unsafe_shutdown(7), libpmemblk(7), libpmemlog(7), libpmemobj(7) and
<https://pmem.io>