xbt_dynar_t mc_heap_comparison_ignore;
xbt_dynar_t stacks_areas;
+void *maestro_stack_start, *maestro_stack_end;
static void heap_area_pair_free(heap_area_pair_t pair);
static void heap_area_pair_free_voidp(void *d);
static int is_new_heap_area_pair(xbt_dynar_t list, int block1, int fragment1, int block2, int fragment2);
static heap_area_t new_heap_area(int block, int fragment);
-static size_t heap_comparison_ignore_size(void *address);
+static size_t heap_comparison_ignore_size(xbt_dynar_t list, void *address);
static void add_heap_equality(xbt_dynar_t equals, void *a1, void *a2);
static void remove_heap_equality(xbt_dynar_t equals, int address, void *a);
-static char* is_stack(void *address);
+static int is_stack(void *address);
+static int is_block_stack(int block);
+static int equal_blocks(int b1, int b2);
+static int equal_fragments(int b1, int f1, int b2, int f2);
void mmalloc_backtrace_block_display(void* heapinfo, int block){
void *s_heap = NULL, *heapbase1 = NULL, *heapbase2 = NULL;
malloc_info *heapinfo1 = NULL, *heapinfo2 = NULL;
size_t heaplimit = 0, heapsize1 = 0, heapsize2 = 0;
+xbt_dynar_t to_ignore1 = NULL, to_ignore2 = NULL;
-int ignore_done = 0;
-
-void init_heap_information(xbt_mheap_t heap1, xbt_mheap_t heap2){
+void init_heap_information(xbt_mheap_t heap1, xbt_mheap_t heap2, xbt_dynar_t i1, xbt_dynar_t i2){
heaplimit = ((struct mdesc *)heap1)->heaplimit;
heapbase1 = (char *)heap1 + BLOCKSIZE;
heapbase2 = (char *)heap2 + BLOCKSIZE;
- heapinfo1 = (malloc_info *)((char *)heap1 + ((uintptr_t)((char *)heap1->heapinfo - (char *)s_heap)));
- heapinfo2 = (malloc_info *)((char *)heap2 + ((uintptr_t)((char *)heap2->heapinfo - (char *)s_heap)));
+ heapinfo1 = (malloc_info *)((char *)heap1 + ((uintptr_t)((char *)((struct mdesc *)heap1)->heapinfo - (char *)s_heap)));
+ heapinfo2 = (malloc_info *)((char *)heap2 + ((uintptr_t)((char *)((struct mdesc *)heap2)->heapinfo - (char *)s_heap)));
heapsize1 = heap1->heapsize;
heapsize2 = heap2->heapsize;
-
+
+ to_ignore1 = i1;
+ to_ignore2 = i2;
+
+ if(MC_is_active()){
+ MC_ignore_data_bss(&heaplimit, sizeof(heaplimit));
+ MC_ignore_data_bss(&s_heap, sizeof(s_heap));
+ MC_ignore_data_bss(&heapbase1, sizeof(heapbase1));
+ MC_ignore_data_bss(&heapbase2, sizeof(heapbase2));
+ MC_ignore_data_bss(&heapinfo1, sizeof(heapinfo1));
+ MC_ignore_data_bss(&heapinfo2, sizeof(heapinfo2));
+ MC_ignore_data_bss(&heapsize1, sizeof(heapsize1));
+ MC_ignore_data_bss(&heapsize2, sizeof(heapsize2));
+ MC_ignore_data_bss(&to_ignore1, sizeof(to_ignore1));
+ MC_ignore_data_bss(&to_ignore2, sizeof(to_ignore2));
+ }
}
-int mmalloc_compare_heap(xbt_mheap_t heap1, xbt_mheap_t heap2, xbt_dynar_t *stack1, xbt_dynar_t *stack2, xbt_dynar_t equals){
+int mmalloc_compare_heap(xbt_mheap_t heap1, xbt_mheap_t heap2){
if(heap1 == NULL && heap1 == NULL){
XBT_DEBUG("Malloc descriptors null");
size_t current_block = -1; /* avoid "maybe uninitialized" warning */
size_t current_fragment;
void *addr_block1, *addr_block2, *addr_frag1, *addr_frag2;
- void *snap_addr_block1, *snap_addr_block2;
- char *stack_name;
int nb_diff1 = 0, nb_diff2 = 0;
xbt_dynar_t previous = xbt_dynar_new(sizeof(heap_area_pair_t), heap_area_pair_free_voidp);
}
addr_block1 = ((void*) (((ADDR2UINT(i1)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
- snap_addr_block1 = ((void*) (((ADDR2UINT(i1)) - 1) * BLOCKSIZE + (char*)heapbase1));
if(heapinfo1[i1].type == 0){ /* Large block */
- if((xbt_dynar_length(*stack1) < xbt_dynar_length(stacks_areas)) && ((stack_name = is_stack(addr_block1)) != NULL)){
- stack_region_t stack = xbt_new0(s_stack_region_t, 1);
- stack->address = snap_addr_block1;
- stack->process_name = strdup(stack_name);
- stack->size = heapinfo1[i1].busy_block.busy_size;
- xbt_dynar_push(*stack1, &stack);
- res_compare = -1;
+ if(is_stack(addr_block1)){
+ for(k=0; k < heapinfo1[i1].busy_block.size; k++)
+ heapinfo1[i1+k].busy_block.equal_to = new_heap_area(i1, -1);
+ for(k=0; k < heapinfo2[i1].busy_block.size; k++)
+ heapinfo2[i1+k].busy_block.equal_to = new_heap_area(i1, -1);
+ i1 = i1 + heapinfo1[current_block].busy_block.size;
+ continue;
}
if(heapinfo1[i1].busy_block.equal_to != NULL){
if(heapinfo2[current_block].busy_block.equal_to == NULL){
addr_block2 = ((void*) (((ADDR2UINT(current_block)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
- snap_addr_block2 = ((void*) (((ADDR2UINT(current_block)) - 1) * BLOCKSIZE + (char*)heapbase2));
-
- if((xbt_dynar_length(*stack2) < xbt_dynar_length(stacks_areas)) && ((stack_name = is_stack(addr_block2)) != NULL)){
- stack_region_t stack = xbt_new0(s_stack_region_t, 1);
- stack->address = snap_addr_block2;
- stack->process_name = strdup(stack_name);
- stack->size = heapinfo2[current_block].busy_block.busy_size;
- xbt_dynar_push(*stack2, &stack);
- res_compare = -1;
- }
- res_compare = compare_area(addr_block1, addr_block2, previous, equals);
+ res_compare = compare_area(addr_block1, addr_block2, NULL);
- if(res_compare == 0 || res_compare == -1){
+ if(res_compare == 0){
for(k=1; k < heapinfo2[current_block].busy_block.size; k++)
heapinfo2[current_block+k].busy_block.equal_to = new_heap_area(i1, -1);
for(k=1; k < heapinfo1[current_block].busy_block.size; k++)
heapinfo1[current_block+k].busy_block.equal_to = new_heap_area(i1, -1);
equal = 1;
- match_equals(previous, equals);
i1 = i1 + heapinfo1[current_block].busy_block.size;
}
while(i2 <= heaplimit && !equal){
addr_block2 = ((void*) (((ADDR2UINT(i2)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
- snap_addr_block2 = ((void*) (((ADDR2UINT(i2)) - 1) * BLOCKSIZE + (char*)heapbase2));
-
- if((xbt_dynar_length(*stack2) < xbt_dynar_length(stacks_areas)) && ((stack_name = is_stack(addr_block2)) != NULL)){
- stack_region_t stack = xbt_new0(s_stack_region_t, 1);
- stack->address = snap_addr_block2;
- stack->process_name = strdup(stack_name);
- stack->size = heapinfo2[i2].busy_block.busy_size;
- xbt_dynar_push(*stack2, &stack);
- res_compare = -1;
- }
if(i2 == current_block){
i2++;
i2++;
continue;
}
+
+ res_compare = compare_area(addr_block1, addr_block2, NULL);
- res_compare = compare_area(addr_block1, addr_block2, previous, equals);
-
- if(res_compare == 0 || res_compare == -1){
+ if(res_compare == 0){
for(k=1; k < heapinfo2[i2].busy_block.size; k++)
heapinfo2[i2+k].busy_block.equal_to = new_heap_area(i1, -1);
for(k=1; k < heapinfo1[i1].busy_block.size; k++)
heapinfo1[i1+k].busy_block.equal_to = new_heap_area(i2, -1);
equal = 1;
- match_equals(previous, equals);
i1 = i1 + heapinfo1[i1].busy_block.size;
}
}
if(!equal){
- XBT_DEBUG("Block %zu not found (size_used = %zu)", i1, heapinfo1[i1].busy_block.busy_size);
+ /*XBT_DEBUG("Block %zu not found (size_used = %zu, addr = %p)", i1, heapinfo1[i1].busy_block.busy_size, addr_block1);
i1 = heaplimit + 1;
- nb_diff1++;
+ nb_diff1++;*/
+ i1++;
}
}else{ /* Fragmented block */
addr_block2 = ((void*) (((ADDR2UINT(current_block)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
addr_frag2 = (void*) ((char *)addr_block2 + (current_fragment << ((xbt_mheap_t)s_heap)->heapinfo[current_block].type));
- res_compare = compare_area(addr_frag1, addr_frag2, previous, equals);
+ res_compare = compare_area(addr_frag1, addr_frag2, NULL);
- if(res_compare == 0){
+ if(res_compare == 0)
equal = 1;
- match_equals(previous, equals);
- }
xbt_dynar_reset(previous);
- }
+ }
+
}
while(i2 <= heaplimit && !equal){
for(j2=0; j2 < (size_t) (BLOCKSIZE >> heapinfo2[i2].type); j2++){
- if(heapinfo2[i2].type == heapinfo1[i1].type && i2 == current_block && j2 == current_fragment)
+ if(i2 == current_block && j2 == current_fragment)
continue;
if(heapinfo2[i2].busy_frag.equal_to[j2] != NULL)
- continue;
+ continue;
addr_block2 = ((void*) (((ADDR2UINT(i2)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
addr_frag2 = (void*) ((char *)addr_block2 + (j2 << ((xbt_mheap_t)s_heap)->heapinfo[i2].type));
- res_compare = compare_area(addr_frag1, addr_frag2, previous, equals);
+ res_compare = compare_area(addr_frag1, addr_frag2, NULL);
if(res_compare == 0){
equal = 1;
- match_equals(previous, equals);
xbt_dynar_reset(previous);
break;
}
}
- if(heapinfo1[i1].busy_frag.equal_to[j1] == NULL){
- XBT_DEBUG("Block %zu, fragment %zu not found (size_used = %d)", i1, j1, heapinfo1[i1].busy_frag.frag_size[j1]);
+ /*if(heapinfo1[i1].busy_frag.equal_to[j1] == NULL){
+ fprintf(stderr,"Block %zu, fragment %zu not found (size_used = %zd, address = %p, ignore %d)\n", i1, j1, heapinfo1[i1].busy_frag.frag_size[j1], addr_frag1, heapinfo1[i1].busy_frag.ignore[j1]);
i2 = heaplimit + 1;
i1 = heaplimit + 1;
nb_diff1++;
break;
- }
+ }*/
}
/* All blocks/fragments are equal to another block/fragment ? */
size_t i = 1, j = 0;
+ void *real_addr_frag1 = NULL, *real_addr_block1 = NULL, *real_addr_block2 = NULL, *real_addr_frag2 = NULL;
while(i<=heaplimit){
if(heapinfo1[i].type == 0){
}
}
}
- xbt_free(heapinfo1[i].busy_block.equal_to);
- heapinfo1[i].busy_block.equal_to = NULL;
}
if(heapinfo1[i].type > 0){
addr_block1 = ((void*) (((ADDR2UINT(i)) - 1) * BLOCKSIZE + (char*)heapbase1));
+ real_addr_block1 = ((void*) (((ADDR2UINT(i)) - 1) * BLOCKSIZE + (char*)((struct mdesc *)s_heap)->heapbase));
for(j=0; j < (size_t) (BLOCKSIZE >> heapinfo1[i].type); j++){
if(current_block == heaplimit){
if(heapinfo1[i].busy_frag.frag_size[j] > 0){
if(heapinfo1[i].busy_frag.equal_to[j] == NULL){
if(XBT_LOG_ISENABLED(mm_diff, xbt_log_priority_debug)){
addr_frag1 = (void*) ((char *)addr_block1 + (j << heapinfo1[i].type));
- XBT_DEBUG("Block %zu, Fragment %zu (%p) not found (size used = %d)", i, j, addr_frag1, heapinfo1[i].busy_frag.frag_size[j]);
+ real_addr_frag1 = (void*) ((char *)real_addr_block1 + (j << ((struct mdesc *)s_heap)->heapinfo[i].type));
+ XBT_DEBUG("Block %zu, Fragment %zu (%p - %p) not found (size used = %zd)", i, j, addr_frag1, real_addr_frag1, heapinfo1[i].busy_frag.frag_size[j]);
//mmalloc_backtrace_fragment_display((void*)heapinfo1, i, j);
}
nb_diff1++;
}
}
}
- xbt_free(heapinfo1[i].busy_frag.equal_to[j]);
- heapinfo1[i].busy_frag.equal_to[j] = NULL;
}
}
i++;
}
+ if(current_block == heaplimit)
+ XBT_DEBUG("Number of blocks/fragments not found in heap1 : %d", nb_diff1);
+
i = 1;
while(i<=heaplimit){
}
}
}
- xbt_free(heapinfo2[i].busy_block.equal_to);
- heapinfo2[i].busy_block.equal_to = NULL;
}
if(heapinfo2[i].type > 0){
addr_block2 = ((void*) (((ADDR2UINT(i)) - 1) * BLOCKSIZE + (char*)heapbase2));
+ real_addr_block2 = ((void*) (((ADDR2UINT(i)) - 1) * BLOCKSIZE + (char*)((struct mdesc *)s_heap)->heapbase));
for(j=0; j < (size_t) (BLOCKSIZE >> heapinfo2[i].type); j++){
if(current_block == heaplimit){
if(heapinfo2[i].busy_frag.frag_size[j] > 0){
if(heapinfo2[i].busy_frag.equal_to[j] == NULL){
if(XBT_LOG_ISENABLED(mm_diff, xbt_log_priority_debug)){
addr_frag2 = (void*) ((char *)addr_block2 + (j << heapinfo2[i].type));
- XBT_DEBUG( "Block %zu, Fragment %zu (%p) not found (size used = %d)", i, j, addr_frag2, heapinfo2[i].busy_frag.frag_size[j]);
+ real_addr_frag2 = (void*) ((char *)real_addr_block2 + (j << ((struct mdesc *)s_heap)->heapinfo[i].type));
+ XBT_DEBUG( "Block %zu, Fragment %zu (%p - %p) not found (size used = %zd)", i, j, addr_frag2, real_addr_frag2, heapinfo2[i].busy_frag.frag_size[j]);
//mmalloc_backtrace_fragment_display((void*)heapinfo2, i, j);
}
nb_diff2++;
}
}
}
+ }
+ }
+ i++;
+ }
+
+ if(current_block == heaplimit)
+ XBT_DEBUG("Number of blocks/fragments not found in heap2 : %d", nb_diff2);
+
+ xbt_dynar_free(&previous);
+ real_addr_frag1 = NULL, real_addr_block1 = NULL, real_addr_block2 = NULL, real_addr_frag2 = NULL;
+
+ return ((nb_diff1 > 0) || (nb_diff2 > 0));
+}
+
+void reset_heap_information(){
+
+ size_t i = 0, j;
+
+ while(i<=heaplimit){
+ if(heapinfo1[i].type == 0){
+ xbt_free(heapinfo1[i].busy_block.equal_to);
+ heapinfo1[i].busy_block.equal_to = NULL;
+ }
+ if(heapinfo1[i].type > 0){
+ for(j=0; j < (size_t) (BLOCKSIZE >> heapinfo1[i].type); j++){
+ xbt_free(heapinfo1[i].busy_frag.equal_to[j]);
+ heapinfo1[i].busy_frag.equal_to[j] = NULL;
+ }
+ }
+ i++;
+ }
+
+ i = 0;
+
+ while(i<=heaplimit){
+ if(heapinfo2[i].type == 0){
+ xbt_free(heapinfo2[i].busy_block.equal_to);
+ heapinfo2[i].busy_block.equal_to = NULL;
+ }
+ if(heapinfo2[i].type > 0){
+ for(j=0; j < (size_t) (BLOCKSIZE >> heapinfo2[i].type); j++){
xbt_free(heapinfo2[i].busy_frag.equal_to[j]);
heapinfo2[i].busy_frag.equal_to[j] = NULL;
}
i++;
}
- xbt_dynar_free(&previous);
- ignore_done = 0;
s_heap = NULL, heapbase1 = NULL, heapbase2 = NULL;
heapinfo1 = NULL, heapinfo2 = NULL;
heaplimit = 0, heapsize1 = 0, heapsize2 = 0;
+ to_ignore1 = NULL, to_ignore2 = NULL;
- return ((nb_diff1 > 0) || (nb_diff2 > 0));
}
static heap_area_t new_heap_area(int block, int fragment){
}
-static size_t heap_comparison_ignore_size(void *address){
+static size_t heap_comparison_ignore_size(xbt_dynar_t ignore_list, void *address){
unsigned int cursor = 0;
int start = 0;
- int end = xbt_dynar_length(mc_heap_comparison_ignore) - 1;
+ int end = xbt_dynar_length(ignore_list) - 1;
mc_heap_ignore_region_t region;
while(start <= end){
cursor = (start + end) / 2;
- region = (mc_heap_ignore_region_t)xbt_dynar_get_as(mc_heap_comparison_ignore, cursor, mc_heap_ignore_region_t);
+ region = (mc_heap_ignore_region_t)xbt_dynar_get_as(ignore_list, cursor, mc_heap_ignore_region_t);
if(region->address == address)
return region->size;
if(region->address < address)
}
-int compare_area(void *area1, void* area2, xbt_dynar_t previous, xbt_dynar_t equals){
+int compare_area(void *area1, void* area2, xbt_dynar_t previous){
size_t i = 0, pointer_align = 0, ignore1 = 0, ignore2 = 0;
- void *address_pointed1, *address_pointed2;
+ void *addr_pointed1, *addr_pointed2;
int res_compare;
- size_t block1, frag1, block2, frag2, size;
+ ssize_t block1, frag1, block2, frag2;
+ ssize_t size;
int check_ignore = 0;
void *addr_block1, *addr_block2, *addr_frag1, *addr_frag2;
block1 = ((char*)area1 - (char*)((xbt_mheap_t)s_heap)->heapbase) / BLOCKSIZE + 1;
block2 = ((char*)area2 - (char*)((xbt_mheap_t)s_heap)->heapbase) / BLOCKSIZE + 1;
- if(((char *)area1 < (char*)((xbt_mheap_t)s_heap)->heapbase) || (block1 > heapsize1) || (block1 < 1) || ((char *)area2 < (char*)((xbt_mheap_t)s_heap)->heapbase) || (block2 > heapsize2) || (block2 < 1))
+ if(is_block_stack((int)block1) && is_block_stack((int)block2)){
+ add_heap_area_pair(previous, block1, -1, block2, -1);
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
+ return 0;
+ }
+
+ if(((char *)area1 < (char*)((xbt_mheap_t)s_heap)->heapbase) || (block1 > heapsize1) || (block1 < 1) || ((char *)area2 < (char*)((xbt_mheap_t)s_heap)->heapbase) || (block2 > heapsize2) || (block2 < 1)){
+ if(match_pairs){
+ xbt_dynar_free(&previous);
+ }
return 1;
+ }
addr_block1 = ((void*) (((ADDR2UINT(block1)) - 1) * BLOCKSIZE + (char*)heapbase1));
addr_block2 = ((void*) (((ADDR2UINT(block2)) - 1) * BLOCKSIZE + (char*)heapbase2));
if(heapinfo1[block1].type == heapinfo2[block2].type){
- if(heapinfo1[block1].type == -1){
+ if(heapinfo1[block1].type == -1){ /* Free block */
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
return 0;
- }else if(heapinfo1[block1].type == 0){
- if(heapinfo1[block1].busy_block.size != heapinfo2[block2].busy_block.size)
+
+ }else if(heapinfo1[block1].type == 0){ /* Complete block */
+
+ if(heapinfo1[block1].busy_block.equal_to != NULL && heapinfo2[block2].busy_block.equal_to != NULL){
+ if(equal_blocks(block1, block2)){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
+ return 0;
+ }
+ }
+
+ if(heapinfo1[block1].busy_block.size != heapinfo2[block2].busy_block.size){
+ if(match_pairs){
+ xbt_dynar_free(&previous);
+ }
return 1;
- if(heapinfo1[block1].busy_block.busy_size != heapinfo2[block2].busy_block.busy_size)
+ }
+
+ if(heapinfo1[block1].busy_block.busy_size != heapinfo2[block2].busy_block.busy_size){
+ if(match_pairs){
+ xbt_dynar_free(&previous);
+ }
return 1;
- if(!add_heap_area_pair(previous, block1, -1, block2, -1))
- return 0;
+ }
+ if(!add_heap_area_pair(previous, block1, -1, block2, -1)){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
+ return 0;
+ }
+
size = heapinfo1[block1].busy_block.busy_size;
+
+ if(size <= 0){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
+ return 0;
+ }
+
frag1 = -1;
frag2 = -1;
area1_to_compare = addr_block1;
area2_to_compare = addr_block2;
- if((ignore_done < xbt_dynar_length(mc_heap_comparison_ignore)) && heapinfo1[block1].busy_block.ignore == 1)
- check_ignore = 1;
+ if((heapinfo1[block1].busy_block.ignore > 0) && (heapinfo2[block2].busy_block.ignore == heapinfo1[block1].busy_block.ignore))
+ check_ignore = heapinfo1[block1].busy_block.ignore;
+
}else{
frag1 = ((uintptr_t) (ADDR2UINT (area1) % (BLOCKSIZE))) >> heapinfo1[block1].type;
frag2 = ((uintptr_t) (ADDR2UINT (area2) % (BLOCKSIZE))) >> heapinfo2[block2].type;
-
- if(heapinfo1[block1].busy_frag.frag_size[frag1] != heapinfo2[block2].busy_frag.frag_size[frag2])
- return 1;
- if(!add_heap_area_pair(previous, block1, frag1, block2, frag2))
- return 0;
-
+
addr_frag1 = (void*) ((char *)addr_block1 + (frag1 << heapinfo1[block1].type));
addr_frag2 = (void*) ((char *)addr_block2 + (frag2 << heapinfo2[block2].type));
-
+
area1_to_compare = addr_frag1;
area2_to_compare = addr_frag2;
+
+ if(heapinfo1[block1].busy_frag.equal_to[frag1] != NULL && heapinfo2[block2].busy_frag.equal_to[frag2] != NULL){
+ if(equal_fragments(block1, frag1, block2, frag2)){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
+ return 0;
+ }
+ }
+
+ if(heapinfo1[block1].busy_frag.frag_size[frag1] != heapinfo2[block2].busy_frag.frag_size[frag2]){
+ if(match_pairs){
+ xbt_dynar_free(&previous);
+ }
+ return 1;
+ }
+ if(!add_heap_area_pair(previous, block1, frag1, block2, frag2)){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
+ return 0;
+ }
+
size = heapinfo1[block1].busy_frag.frag_size[frag1];
- if(size == 0)
+ if(size <= 0){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
return 0;
-
- if((ignore_done < xbt_dynar_length(mc_heap_comparison_ignore)) && heapinfo1[block1].busy_frag.ignore[frag1] == 1)
- check_ignore = 1;
+ }
+
+ if((heapinfo1[block1].busy_frag.ignore[frag1] > 0) && ( heapinfo2[block2].busy_frag.ignore[frag2] == heapinfo1[block1].busy_frag.ignore[frag1]))
+ check_ignore = heapinfo1[block1].busy_frag.ignore[frag1];
+
}
+
}else if((heapinfo1[block1].type > 0) && (heapinfo2[block2].type > 0)){
+
frag1 = ((uintptr_t) (ADDR2UINT (area1) % (BLOCKSIZE))) >> heapinfo1[block1].type;
frag2 = ((uintptr_t) (ADDR2UINT (area2) % (BLOCKSIZE))) >> heapinfo2[block2].type;
- if(heapinfo1[block1].busy_frag.frag_size[frag1] != heapinfo2[block2].busy_frag.frag_size[frag2])
- return 1;
- if(!add_heap_area_pair(previous, block1, frag1, block2, frag2))
+ if(heapinfo1[block1].busy_frag.equal_to[frag1] != NULL || heapinfo2[block2].busy_frag.equal_to[frag2] != NULL){
+ if(equal_fragments(block1, frag1, block2, frag2)){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
+ return 0;
+ }
+ }
+
+ if(heapinfo1[block1].busy_frag.frag_size[frag1] != heapinfo2[block2].busy_frag.frag_size[frag2]){
+ if(match_pairs){
+ xbt_dynar_free(&previous);
+ }
+ return 1;
+ }
+
+ if(!add_heap_area_pair(previous, block1, frag1, block2, frag2)){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
return 0;
+ }
addr_frag1 = (void*) ((char *)addr_block1 + (frag1 << heapinfo1[block1].type));
addr_frag2 = (void*) ((char *)addr_block2 + (frag2 << heapinfo2[block2].type));
size = heapinfo1[block1].busy_frag.frag_size[frag1];
- if(size == 0)
+ if(size <= 0){
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
return 0;
+ }
- if((ignore_done < xbt_dynar_length(mc_heap_comparison_ignore)) && heapinfo1[block1].busy_frag.ignore[frag1] == 1)
- check_ignore = 1;
+ if((heapinfo1[block1].busy_frag.ignore[frag1] > 0) && (heapinfo2[block2].busy_frag.ignore[frag2] == heapinfo1[block1].busy_frag.ignore[frag1]))
+ check_ignore = heapinfo1[block1].busy_frag.ignore[frag1];
+
}else{
+ if(match_pairs){
+ xbt_dynar_free(&previous);
+ }
return 1;
}
while(i<size){
- if((ignore_done < xbt_dynar_length(mc_heap_comparison_ignore)) && check_ignore){
-
- if((ignore1 = heap_comparison_ignore_size((char *)area1 + i)) > 0){
- if((ignore2 = heap_comparison_ignore_size((char *)area2 + i)) == ignore1){
+ if(check_ignore > 0){
+ if((ignore1 = heap_comparison_ignore_size(to_ignore1, (char *)area1 + i)) > 0){
+ if((ignore2 = heap_comparison_ignore_size(to_ignore2, (char *)area2 + i)) == ignore1){
i = i + ignore2;
- ignore_done++;
+ check_ignore--;
continue;
}
}
}
-
+
if(memcmp(((char *)area1_to_compare) + i, ((char *)area2_to_compare) + i, 1) != 0){
- /* Check pointer difference */
pointer_align = (i / sizeof(void*)) * sizeof(void*);
- address_pointed1 = *((void **)((char *)area1_to_compare + pointer_align));
- address_pointed2 = *((void **)((char *)area2_to_compare + pointer_align));
-
- res_compare = compare_area(address_pointed1, address_pointed2, previous, equals);
+ addr_pointed1 = *((void **)((char *)area1_to_compare + pointer_align));
+ addr_pointed2 = *((void **)((char *)area2_to_compare + pointer_align));
- if(res_compare == 1)
- return 1;
-
- i = pointer_align + sizeof(void *);
+ if(addr_pointed1 > maestro_stack_start && addr_pointed1 < maestro_stack_end && addr_pointed2 > maestro_stack_start && addr_pointed2 < maestro_stack_end){
+ i = pointer_align + sizeof(void *);
+ continue;
+ }else if((addr_pointed1 > s_heap) && ((char *)addr_pointed1 < (char *)s_heap + STD_HEAP_SIZE)
+ && (addr_pointed2 > s_heap) && ((char *)addr_pointed2 < (char *)s_heap + STD_HEAP_SIZE)){
+ res_compare = compare_area(addr_pointed1, addr_pointed2, previous);
+ if(res_compare != 0){
+ if(match_pairs)
+ xbt_dynar_free(&previous);
+ return res_compare;
+ }
+ i = pointer_align + sizeof(void *);
+ continue;
+ }else{
+ if(match_pairs)
+ xbt_dynar_free(&previous);
+ return 1;
+ }
- }else{
-
- i++;
-
}
+
+ i++;
+
}
- if(match_pairs)
- match_equals(previous, equals);
+ if(match_pairs){
+ match_equals(previous);
+ xbt_dynar_free(&previous);
+ }
return 0;
}
static void heap_area_pair_free(heap_area_pair_t pair){
- if (pair){
- xbt_free(pair);
- pair = NULL;
- }
+ xbt_free(pair);
+ pair = NULL;
}
static void heap_area_pair_free_voidp(void *d)
return 1;
}
-void match_equals(xbt_dynar_t list, xbt_dynar_t equals){
+
+void match_equals(xbt_dynar_t list){
unsigned int cursor = 0;
heap_area_pair_t current_pair;
heap_area_t previous_area;
- void *real_addr_block1, *real_addr_block2, *real_addr_frag1, *real_addr_frag2;
-
xbt_dynar_foreach(list, cursor, current_pair){
if(current_pair->fragment1 != -1){
-
- real_addr_block1 = ((void*) (((ADDR2UINT((size_t)current_pair->block1)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
- real_addr_frag1 = (void*) ((char *)real_addr_block1 + (current_pair->fragment1 << heapinfo1[current_pair->block1].type));
- real_addr_block2 = ((void*) (((ADDR2UINT((size_t)current_pair->block2)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
- real_addr_frag2 = (void*) ((char *)real_addr_block2 + (current_pair->fragment2 << heapinfo2[current_pair->block2].type));
-
+
if(heapinfo1[current_pair->block1].busy_frag.equal_to[current_pair->fragment1] != NULL){
- remove_heap_equality(equals, 1, real_addr_frag1);
previous_area = heapinfo1[current_pair->block1].busy_frag.equal_to[current_pair->fragment1];
xbt_free(heapinfo2[previous_area->block].busy_frag.equal_to[previous_area->fragment]);
heapinfo2[previous_area->block].busy_frag.equal_to[previous_area->fragment] = NULL;
xbt_free(previous_area);
}
if(heapinfo2[current_pair->block2].busy_frag.equal_to[current_pair->fragment2] != NULL){
- remove_heap_equality(equals, 2, real_addr_frag2);
previous_area = heapinfo2[current_pair->block2].busy_frag.equal_to[current_pair->fragment2];
xbt_free(heapinfo1[previous_area->block].busy_frag.equal_to[previous_area->fragment]);
heapinfo1[previous_area->block].busy_frag.equal_to[previous_area->fragment] = NULL;
xbt_free(previous_area);
}
-
- if(real_addr_frag1 != real_addr_frag2)
- add_heap_equality(equals, real_addr_frag1, real_addr_frag2);
heapinfo1[current_pair->block1].busy_frag.equal_to[current_pair->fragment1] = new_heap_area(current_pair->block2, current_pair->fragment2);
heapinfo2[current_pair->block2].busy_frag.equal_to[current_pair->fragment2] = new_heap_area(current_pair->block1, current_pair->fragment1);
}else{
- real_addr_block1 = ((void*) (((ADDR2UINT((size_t)current_pair->block1)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
- real_addr_block2 = ((void*) (((ADDR2UINT((size_t)current_pair->block2)) - 1) * BLOCKSIZE + (char*)((xbt_mheap_t)s_heap)->heapbase));
-
if(heapinfo1[current_pair->block1].busy_block.equal_to != NULL){
- remove_heap_equality(equals, 1, real_addr_block1);
previous_area = heapinfo1[current_pair->block1].busy_block.equal_to;
xbt_free(heapinfo2[previous_area->block].busy_block.equal_to);
heapinfo2[previous_area->block].busy_block.equal_to = NULL;
xbt_free(previous_area);
}
if(heapinfo2[current_pair->block2].busy_block.equal_to != NULL){
- remove_heap_equality(equals, 2, real_addr_block2);
previous_area = heapinfo2[current_pair->block2].busy_block.equal_to;
xbt_free(heapinfo1[previous_area->block].busy_block.equal_to);
heapinfo1[previous_area->block].busy_block.equal_to = NULL;
xbt_free(previous_area);
}
-
- if(real_addr_block1 != real_addr_block2)
- add_heap_equality(equals, real_addr_block1, real_addr_block2);
heapinfo1[current_pair->block1].busy_block.equal_to = new_heap_area(current_pair->block2, current_pair->fragment2);
heapinfo2[current_pair->block2].busy_block.equal_to = new_heap_area(current_pair->block1, current_pair->fragment1);
}
}
-
}
#ifndef max
}
-static char* is_stack(void *address){
+static int is_stack(void *address){
unsigned int cursor = 0;
stack_region_t stack;
xbt_dynar_foreach(stacks_areas, cursor, stack){
if(address == stack->address)
- return stack->process_name;
+ return 1;
}
- return NULL;
+ return 0;
+}
+
+static int is_block_stack(int block){
+ unsigned int cursor = 0;
+ stack_region_t stack;
+
+ xbt_dynar_foreach(stacks_areas, cursor, stack){
+ if(block == stack->block)
+ return 1;
+ }
+
+ return 0;
}
static void add_heap_equality(xbt_dynar_t equals, void *a1, void *a2){
}
return 0;
-
+
+}
+static int equal_blocks(int b1, int b2){
+ if(heapinfo1[b1].busy_block.equal_to != NULL){
+ if(heapinfo2[b2].busy_block.equal_to != NULL){
+ if(((heap_area_t)(heapinfo1[b1].busy_block.equal_to))->block == b2 && ((heap_area_t)(heapinfo2[b2].busy_block.equal_to))->block == b1)
+ return 1;
+ }
+ }
+ return 0;
+}
+static int equal_fragments(int b1, int f1, int b2, int f2){
+ if(heapinfo1[b1].busy_frag.equal_to[f1] != NULL){
+ if(heapinfo2[b2].busy_frag.equal_to[f2] != NULL){
+ if(((heap_area_t)(heapinfo1[b1].busy_frag.equal_to[f1]))->block == b2 && ((heap_area_t)(heapinfo2[b2].busy_frag.equal_to[f2]))->block == b1 && ((heap_area_t)(heapinfo1[b1].busy_frag.equal_to[f1]))->fragment == f2 && ((heap_area_t)(heapinfo2[b2].busy_frag.equal_to[f2]))->fragment == f1)
+ return 1;
+ }
+ }
+ return 0;
}