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openmpi/ompi/mca/allocator/basic/allocator_basic.c
Galen Shipman 18dda70fd0 make ompi_free_list_item_t a class..
This will go to the 1.1 branch but will probably require a few changes as
ompi_free_list_t is different in the branch.. 

This commit was SVN r10306.
2006-06-12 16:44:00 +00:00

381 строка
12 KiB
C

/*
* Copyright (c) 2004-2005 The Trustees of Indiana University and Indiana
* University Research and Technology
* Corporation. All rights reserved.
* Copyright (c) 2004-2005 The University of Tennessee and The University
* of Tennessee Research Foundation. All rights
* reserved.
* Copyright (c) 2004-2005 High Performance Computing Center Stuttgart,
* University of Stuttgart. All rights reserved.
* Copyright (c) 2004-2005 The Regents of the University of California.
* All rights reserved.
* $COPYRIGHT$
*
* Additional copyrights may follow
*
* $HEADER$
*/
#include "ompi_config.h"
#include "opal/util/output.h"
#include "allocator_basic.h"
#include "ompi/constants.h"
mca_allocator_base_component_t mca_allocator_basic_component = {
/* First, the mca_base_module_t struct containing meta information
about the module itself */
{
/* Indicate that we are a allocator v1.0.0 module (which also implies a
specific MCA version) */
MCA_ALLOCATOR_BASE_VERSION_1_0_0,
"basic", /* MCA module name */
1, /* MCA module major version */
0, /* MCA module minor version */
0, /* MCA module release version */
mca_allocator_basic_component_open, /* module open */
mca_allocator_basic_component_close /* module close */
},
/* Next the MCA v1.0.0 module meta data */
{
/* Whether the module is checkpointable or not */
false
},
mca_allocator_basic_component_init
};
OBJ_CLASS_INSTANCE(
mca_allocator_basic_segment_t,
ompi_free_list_item_t,
NULL,
NULL);
int mca_allocator_basic_component_open(void)
{
return OMPI_SUCCESS;
}
int mca_allocator_basic_component_close(void)
{
return OMPI_SUCCESS;
}
/**
*
*/
mca_allocator_base_module_t* mca_allocator_basic_component_init(
bool enable_mpi_threads,
mca_allocator_base_component_segment_alloc_fn_t segment_alloc,
mca_allocator_base_component_segment_free_fn_t segment_free,
struct mca_mpool_base_module_t* mpool)
{
mca_allocator_basic_module_t *module = (mca_allocator_basic_module_t *)
malloc(sizeof(mca_allocator_basic_module_t));
if (NULL == module) {
return NULL;
}
module->super.alc_alloc = mca_allocator_basic_alloc;
module->super.alc_realloc = mca_allocator_basic_realloc;
module->super.alc_free = mca_allocator_basic_free;
module->super.alc_compact = mca_allocator_basic_compact;
module->super.alc_finalize = mca_allocator_basic_finalize;
module->super.alc_mpool = mpool;
module->seg_alloc = segment_alloc;
module->seg_free = segment_free;
OBJ_CONSTRUCT(&module->seg_list, opal_list_t);
OBJ_CONSTRUCT(&module->seg_lock, opal_mutex_t);
OBJ_CONSTRUCT(&module->seg_descriptors, ompi_free_list_t);
ompi_free_list_init(&module->seg_descriptors,
sizeof(mca_allocator_basic_segment_t),
OBJ_CLASS(mca_allocator_basic_segment_t),
0, /* initial size */
-1, /* maximum size */
16, /* increment to grow by */
NULL);
return &module->super;
}
/**
* Combine adjacent segments together.
*/
static void mca_allocator_basic_combine_prev(
mca_allocator_basic_module_t* module,
mca_allocator_basic_segment_t* seg)
{
opal_list_item_t* item = opal_list_get_prev(seg);
if(item != opal_list_get_begin(&module->seg_list)) {
mca_allocator_basic_segment_t *prev = (mca_allocator_basic_segment_t*)item;
if(prev->seg_addr + prev->seg_size == seg->seg_addr) {
prev->seg_size += seg->seg_size;
opal_list_remove_item(&module->seg_list, &seg->seg_item.super);
OMPI_FREE_LIST_RETURN(&module->seg_descriptors, &seg->seg_item);
return;
}
}
}
static void mca_allocator_basic_combine_next(
mca_allocator_basic_module_t* module,
mca_allocator_basic_segment_t* seg)
{
opal_list_item_t *item = opal_list_get_next(seg);
if(item != opal_list_get_end(&module->seg_list)) {
mca_allocator_basic_segment_t *next = (mca_allocator_basic_segment_t*)item;
if(seg->seg_addr + seg->seg_size == next->seg_addr) {
next->seg_addr = seg->seg_addr;
next->seg_size += seg->seg_size;
opal_list_remove_item(&module->seg_list, &seg->seg_item.super);
OMPI_FREE_LIST_RETURN(&module->seg_descriptors, &seg->seg_item);
return;
}
}
}
/**
* Accepts a request for memory in a specific region defined by the
* mca_allocator_basic_options_t struct and returns a pointer to memory in that
* region or NULL if there was an error
*
* @param mem A pointer to the appropriate struct for the area of memory.
* @param size The size of the requested area of memory
*
* @retval Pointer to the area of memory if the allocation was successful
* @retval NULL if the allocation was unsuccessful
*/
void *mca_allocator_basic_alloc(
mca_allocator_base_module_t * base,
size_t size,
size_t align,
mca_mpool_base_registration_t** registration)
{
mca_allocator_basic_module_t* module = (mca_allocator_basic_module_t*)base;
mca_allocator_basic_segment_t* seg;
ompi_free_list_item_t* item;
unsigned char* addr;
size_t allocated_size;
OPAL_THREAD_LOCK(&module->seg_lock);
/* search the list for a segment of the required size */
size += sizeof(size_t);
for(item = (ompi_free_list_item_t*) opal_list_get_first(&module->seg_list);
item != (ompi_free_list_item_t*) opal_list_get_end(&module->seg_list);
item = (ompi_free_list_item_t*) opal_list_get_next(&item->super)) {
seg = (mca_allocator_basic_segment_t*)item;
/* split the segment */
if(seg->seg_size > size) {
addr = seg->seg_addr;
seg->seg_addr += size;
seg->seg_size -= size;
OPAL_THREAD_UNLOCK(&module->seg_lock);
*(size_t*)addr = size;
return addr+sizeof(size_t);
} else if (seg->seg_size == size) {
addr = seg->seg_addr;
opal_list_remove_item(&module->seg_list, &item->super);
OMPI_FREE_LIST_RETURN(&module->seg_descriptors, item);
OPAL_THREAD_UNLOCK(&module->seg_lock);
*(size_t*)addr = size;
return addr+sizeof(size_t);
}
}
/* request additional block */
allocated_size = (unsigned char)size;
if(NULL == (addr = (unsigned char *)module->seg_alloc(module->super.alc_mpool, &allocated_size, registration))) {
OPAL_THREAD_UNLOCK(&module->seg_lock);
return NULL;
}
/* create a segment for any extra allocation */
if(allocated_size > size) {
int rc;
OMPI_FREE_LIST_GET(&module->seg_descriptors, item, rc);
if(rc != OMPI_SUCCESS) {
OPAL_THREAD_UNLOCK(&module->seg_lock);
return NULL;
}
seg = (mca_allocator_basic_segment_t*)item;
seg->seg_addr = addr + size;
seg->seg_size = allocated_size - size;
opal_list_append(&module->seg_list, &item->super);
}
*(size_t*)addr = size;
OPAL_THREAD_UNLOCK(&module->seg_lock);
return addr+sizeof(size_t);
}
/**
* Attempts to resize the passed region of memory into a larger or a smaller
* region. If it is unsuccessful, it will return NULL and the passed area of
* memory will be untouched.
*
* @param mem A pointer to the appropriate struct for the area of
* memory.
* @param size The size of the requested area of memory
* @param ptr A pointer to the region of memory to be resized
*
* @retval Pointer to the area of memory if the reallocation was successful
* @retval NULL if the allocation was unsuccessful
*
*/
void * mca_allocator_basic_realloc(
mca_allocator_base_module_t * base,
void * ptr,
size_t size,
mca_mpool_base_registration_t** registration)
{
unsigned char* addr = ((unsigned char*)ptr) - sizeof(size_t);
size_t alloc_size = *(size_t*)addr;
if(size <= alloc_size)
return ptr;
addr = (unsigned char *)mca_allocator_basic_alloc(base,size,0,registration);
if(addr == NULL)
return addr;
memcpy(addr,ptr,alloc_size);
mca_allocator_basic_free(base,ptr);
return addr;
}
/**
* Frees the passed region of memory
*
* @param mem A pointer to the appropriate struct for the area of
* memory.
* @param ptr A pointer to the region of memory to be freed
*
* @retval None
*
*/
void mca_allocator_basic_free(
mca_allocator_base_module_t * base,
void * ptr)
{
mca_allocator_basic_module_t* module = (mca_allocator_basic_module_t*)base;
mca_allocator_basic_segment_t* seg;
ompi_free_list_item_t *item;
unsigned char* addr = (unsigned char*)ptr - sizeof(size_t);
size_t size = *(size_t*)addr;
int rc;
OPAL_THREAD_LOCK(&module->seg_lock);
/* maintain the free list in sorted order by address */
for(item = (ompi_free_list_item_t*) opal_list_get_first(&module->seg_list);
item != (ompi_free_list_item_t*) opal_list_get_end(&module->seg_list);
item = (ompi_free_list_item_t*) opal_list_get_next((&item->super))) {
seg = (mca_allocator_basic_segment_t*)item;
if (seg->seg_addr < addr) {
/* can we grow the current entry */
if(seg->seg_addr + seg->seg_size == addr) {
seg->seg_size += size;
mca_allocator_basic_combine_next(module, seg);
OPAL_THREAD_UNLOCK(&module->seg_lock);
return;
}
/* otherwise continue to check next larger entry */
} else {
/* can this be combined with current entry */
if(addr + size == seg->seg_addr) {
seg->seg_addr = addr;
seg->seg_size += size;
mca_allocator_basic_combine_prev(module, seg);
OPAL_THREAD_UNLOCK(&module->seg_lock);
return;
/* insert before larger entry */
} else {
mca_allocator_basic_segment_t* new_seg;
OMPI_FREE_LIST_GET(&module->seg_descriptors, item, rc);
if(rc != OMPI_SUCCESS) {
OPAL_THREAD_UNLOCK(&module->seg_lock);
return;
}
new_seg = (
mca_allocator_basic_segment_t*)item;
new_seg->seg_addr = addr;
new_seg->seg_size = size;
opal_list_insert_pos(&module->seg_list, &seg->seg_item.super, &item->super);
OPAL_THREAD_UNLOCK(&module->seg_lock);
return;
}
}
}
/* append to the end of the list */
OMPI_FREE_LIST_GET(&module->seg_descriptors, item, rc);
if(rc != OMPI_SUCCESS) {
OPAL_THREAD_UNLOCK(&module->seg_lock);
return;
}
seg = (mca_allocator_basic_segment_t*)item;
seg->seg_addr = addr;
seg->seg_size = size;
opal_list_append(&module->seg_list, &item->super);
OPAL_THREAD_UNLOCK(&module->seg_lock);
}
/**
* Frees all the memory from all the basics back to the system. Note that
* this function only frees memory that was previously freed with
* mca_allocator_basic_free().
*
* @param mem A pointer to the appropriate struct for the area of
* memory.
*
* @retval None
*
*/
int mca_allocator_basic_compact(mca_allocator_base_module_t * mem)
{
return OMPI_SUCCESS;
}
/**
* Cleanup all resources held by this allocator.
*
* @param mem A pointer to the appropriate struct for the area of
* memory.
*
* @retval None
*
*/
int mca_allocator_basic_finalize(mca_allocator_base_module_t * base)
{
mca_allocator_basic_module_t* module = (mca_allocator_basic_module_t*)base;
OBJ_DESTRUCT(&module->seg_list);
OBJ_DESTRUCT(&module->seg_lock);
OBJ_DESTRUCT(&module->seg_descriptors);
free(module);
return OMPI_SUCCESS;
}