The library provides a memory allocator which relies on huge pages and may
use persistent memory exposed in App Direct mode. It can be used either
directly with dedicated library calls or with a shared library that replaces
malloc(3) calls from the applications or language runtime with allocations
from the library.
Applications with large memory footprints may suffer from a high number of page
faults as well as TLB misses. Although operating systems, like Linux, provide
mechanisms like Transparent Huge Pages (THP), they may either not be able to
provide huge pages on demand due to memory fragmentation or they consume
additional time to defragment the memory to hand out huge pages afterwards.
The allocator presented here uses huge pages reserved for the system before the
application starts. They are mmapd into the address space and serve as
underlying, non-persistent, and anonymous memory range.
Further, an application may decide on which level in the memory hierarchy it
wants data to be stored. In case of storage class (persistent) memory (SCM) this
is possible in the so called App Direct Mode which exposes the persistent
memory as file system. The library mmaps a file on such a device (or any other
path in the file system) with a requested size and provides memory blocks from
this mapping if asked for.
To be convenient for the user, this library provides a call similar to
malloc/calloc for memory allocation. The library can be configured
dynamically to choose the method used for the allocation.
By doing so, both uncontrollable references to persistent memory in Memory Mode
as well as frequent page faults/TLB misses can be avoided.
In principle, the library can be used in two variants: either using its dedicated interface or using it (almost) transparently for legacy applications.
The library offers two memory allocation functions
-
void* hpp_alloc(size_t count, size_t elem_size)This call, with acalloc-like signature, returns a pointer to the allocated memory orNULLif the allocation failed -
void hpp_free(void* ptr)The counterpart for hppalloc. Removes the allocation from memory. It is safe to call this function withNULLas argument. -
int hpp_set_mode(int mode)Set the mode used internally for the memory allocation. The mode steers howhpp_allocbehaves. This mode can be a bitwise OR-combination of the following valuesHPPA_AS_MALLOC- selectmallocas allocation strategy. If active,hpp_allocwill try to call libc'smallocto satisfy the allocation request if every other strategy has failed.HPPA_AS_ANON- memory allocation requests are tried to be satisfied from the huge page memory mapping.HPPA_AS_NAMEDorHPPA_AS_PMEM- same asHPPA_AS_ANONbut instead of the huge page mapping, the named/file mapping is used to satisfy the allocation. This mode effectively disables theHPPA_AS_ANONmode, even when both are specified (this may be subject to change).
The function returns the old operation mode which was active before the function was called.
For all these function, a Fortran (2003+) binding exists.
In order allocate memory from the huge page mapping and use malloc as fallback, the following calls would be required
hpp_set_mode(HPPA_AS_MALLOC | HPPA_AS_ANON);
/* allocate four 1 GB chunks */
buf = hpp_alloc(4, 1 << 30);
To avoid massive rewrites of existing applications, a library is provided that
can be used to replace existing malloc calls. The libhppahook.so library can
be LD_PRELOADed to do so. Allocations larger than a specified threshold are
passed to the internal allocation mechanism, while smaller ones are handed over
to the original libc-implementation.
See below for details on how to control the inner workings of the library.
Environment variables can be used to control options and internals of the library and allocator.
HPPA_BASE_PATH- path to an existing directory in the filesystem that will hold the files used for file-based mappings. This is intended to point to a directory on a persistent memory device (like/mnt/pmem0). However, it can point to any other path as well.HPPA_ALLOC_THRESHOLD- only allocations equal or larger than this value will be passed to internal mmap-based allocator. Allocations smaller than this value are passed to malloc, if enabled in the library mode (see above).HPPA_SIZE_ANONandHPPA_SIZE_NAMED- specify the size of the mmap-pools used by the library/process. For the anonymous/huge page pool, an according number of huge pages should have been allocated before-hand by the operating system. For the named pool, the targeted device needs to have sufficient space left to hold the created files. Note that the files are not listed byls.HPPA_LOGLEVEL- If the library is compiled with debug support (DEBUG symbol), a log level from the following can be chosen: EMERG, ALERT, CRIT, ERR, WARN, NOTE, INFO, DEBUG.HPPA_PRINT_HEAP- if the log level is set to DEBUG and this variable is set to 1 or true, then the internal state of the used heap is printed after each successful allocation and free operation.
When the library should be used in transparent operation mode, i.e. with
LD_PRELOAD, care should be taken to affect the desired processes only.
For example, with MPI, the process launcher should not be affected preloading
the library. Thus, the LD_PRELOAD variable should only be set by the
launcher, but not for it. Thus, using it with MPI should look this:
- MPICH:
mpiexec -n 4 -env LD_PRELOAD /path/to/libhppahook.so ./mybin - Open MPI:
mpiexec -n 4 -x LD_PRELOAD=/path/to/libhppahook.so' ./mybin
In case performance metrics should be obtained from the binary with the tools,
like perf, the performance tool should also be unaffected. In the parallel (MPI)
case it is also undesirable to have memory/huge pages reserved but unused for
every started instance of the performance tool. Using env the problem can be
avoided:
mpiexec -n 4 perf stat env LD_PRELOAD=/path/to/libhppahook.so ./mybin
Note: You probably want a wrapper script for perf to write results in different files.