/* mc_diff - Memory snapshooting and comparison */
+#include <array>
+#include <memory>
+#include <utility>
+
#include "src/xbt/ex_interface.h" /* internals of backtrace setup */
#include "mc/mc.h"
#include "xbt/mmalloc.h"
/*********************************** Heap comparison ***********************************/
/***************************************************************************************/
-struct XBT_PRIVATE s_mc_diff {
+namespace simgrid {
+namespace mc {
+
+struct ProcessComparisonState {
+ std::vector<simgrid::mc::IgnoredHeapRegion>* to_ignore = nullptr;
+ std::vector<s_heap_area_t> equals_to;
+ std::vector<simgrid::mc::Type*> types;
+ std::size_t heapsize = 0;
+
+ void initHeapInformation(xbt_mheap_t heap,
+ std::vector<simgrid::mc::IgnoredHeapRegion>* i);
+};
+
+struct StateComparator {
s_xbt_mheap_t std_heap_copy;
std::size_t heaplimit;
- // Number of blocks in the heaps:
- std::size_t heapsize1, heapsize2;
- std::vector<simgrid::mc::IgnoredHeapRegion>* to_ignore1;
- std::vector<simgrid::mc::IgnoredHeapRegion>* to_ignore2;
- s_heap_area_t *equals_to1, *equals_to2;
- simgrid::mc::Type **types1;
- simgrid::mc::Type **types2;
- std::size_t available;
+ std::array<ProcessComparisonState, 2> processStates;
+
+ int initHeapInformation(
+ xbt_mheap_t heap1, xbt_mheap_t heap2,
+ std::vector<simgrid::mc::IgnoredHeapRegion>* i1,
+ std::vector<simgrid::mc::IgnoredHeapRegion>* i2);
+
+ s_heap_area_t& equals_to1_(std::size_t i, std::size_t j)
+ {
+ return processStates[0].equals_to[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+ s_heap_area_t& equals_to2_(std::size_t i, std::size_t j)
+ {
+ return processStates[1].equals_to[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+ Type*& types1_(std::size_t i, std::size_t j)
+ {
+ return processStates[0].types[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+ Type*& types2_(std::size_t i, std::size_t j)
+ {
+ return processStates[1].types[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+
+ s_heap_area_t const& equals_to1_(std::size_t i, std::size_t j) const
+ {
+ return processStates[0].equals_to[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+ s_heap_area_t const& equals_to2_(std::size_t i, std::size_t j) const
+ {
+ return processStates[1].equals_to[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+ Type* const& types1_(std::size_t i, std::size_t j) const
+ {
+ return processStates[0].types[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+ Type* const& types2_(std::size_t i, std::size_t j) const
+ {
+ return processStates[1].types[ MAX_FRAGMENT_PER_BLOCK * i + j];
+ }
+
+ /** Check whether two blocks are known to be matching
+ *
+ * @param state State used
+ * @param b1 Block of state 1
+ * @param b2 Block of state 2
+ * @return if the blocks are known to be matching
+ */
+ bool blocksEqual(int b1, int b2) const
+ {
+ return this->equals_to1_(b1, 0).block == b2
+ && this->equals_to2_(b2, 0).block == b1;
+ }
+
+ /** Check whether two fragments are known to be matching
+ *
+ * @param state State used
+ * @param b1 Block of state 1
+ * @param f1 Fragment of state 1
+ * @param b2 Block of state 2
+ * @param f2 Fragment of state 2
+ * @return if the fragments are known to be matching
+ */
+ int fragmentsEqual(int b1, int f1, int b2, int f2) const
+ {
+ return this->equals_to1_(b1, f1).block == b2
+ && this->equals_to1_(b1, f1).fragment == f2
+ && this->equals_to2_(b2, f2).block == b1
+ && this->equals_to2_(b2, f2).fragment == f1;
+ }
+
+ void match_equals(xbt_dynar_t list);
};
-#define equals_to1_(i,j) equals_to1[ MAX_FRAGMENT_PER_BLOCK*(i) + (j)]
-#define equals_to2_(i,j) equals_to2[ MAX_FRAGMENT_PER_BLOCK*(i) + (j)]
-#define types1_(i,j) types1[ MAX_FRAGMENT_PER_BLOCK*(i) + (j)]
-#define types2_(i,j) types2[ MAX_FRAGMENT_PER_BLOCK*(i) + (j)]
+}
+}
-static __thread struct s_mc_diff *mc_diff_info = nullptr;
+// TODO, make this a field of ModelChecker or something similar
+static std::unique_ptr<simgrid::mc::StateComparator> mc_diff_info;
/*********************************** Free functions ************************************/
int block2, int fragment2)
{
- if (is_new_heap_area_pair(list, block1, fragment1, block2, fragment2)) {
- heap_area_pair_t pair = nullptr;
- pair = xbt_new0(s_heap_area_pair_t, 1);
- pair->block1 = block1;
- pair->fragment1 = fragment1;
- pair->block2 = block2;
- pair->fragment2 = fragment2;
-
- xbt_dynar_push(list, &pair);
-
- return 1;
- }
+ if (!is_new_heap_area_pair(list, block1, fragment1, block2, fragment2))
+ return 0;
- return 0;
+ heap_area_pair_t pair = nullptr;
+ pair = xbt_new0(s_heap_area_pair_t, 1);
+ pair->block1 = block1;
+ pair->fragment1 = fragment1;
+ pair->block2 = block2;
+ pair->fragment2 = fragment2;
+ xbt_dynar_push(list, &pair);
+ return 1;
}
static ssize_t heap_comparison_ignore_size(
return false;
}
-static void match_equals(struct s_mc_diff *state, xbt_dynar_t list)
-{
+namespace simgrid {
+namespace mc {
+void StateComparator::match_equals(xbt_dynar_t list)
+{
unsigned int cursor = 0;
heap_area_pair_t current_pair;
- xbt_dynar_foreach(list, cursor, current_pair)
-
+ xbt_dynar_foreach(list, cursor, current_pair) {
if (current_pair->fragment1 != -1) {
-
- state->equals_to1_(current_pair->block1, current_pair->fragment1) =
+ this->equals_to1_(current_pair->block1, current_pair->fragment1) =
make_heap_area(current_pair->block2, current_pair->fragment2);
- state->equals_to2_(current_pair->block2, current_pair->fragment2) =
+ this->equals_to2_(current_pair->block2, current_pair->fragment2) =
make_heap_area(current_pair->block1, current_pair->fragment1);
-
} else {
-
- state->equals_to1_(current_pair->block1, 0) =
+ this->equals_to1_(current_pair->block1, 0) =
make_heap_area(current_pair->block2, current_pair->fragment2);
- state->equals_to2_(current_pair->block2, 0) =
+ this->equals_to2_(current_pair->block2, 0) =
make_heap_area(current_pair->block1, current_pair->fragment1);
-
}
-
+ }
}
-/** Check whether two blocks are known to be matching
- *
- * @param state State used
- * @param b1 Block of state 1
- * @param b2 Block of state 2
- * @return if the blocks are known to be matching
- */
-static int equal_blocks(struct s_mc_diff *state, int b1, int b2)
+int init_heap_information(xbt_mheap_t heap1, xbt_mheap_t heap2,
+ std::vector<simgrid::mc::IgnoredHeapRegion>* i1,
+ std::vector<simgrid::mc::IgnoredHeapRegion>* i2)
{
-
- if (state->equals_to1_(b1, 0).block == b2
- && state->equals_to2_(b2, 0).block == b1)
- return 1;
-
- return 0;
+ if (mc_diff_info == nullptr)
+ mc_diff_info = std::unique_ptr<StateComparator>(new StateComparator());
+ return mc_diff_info->initHeapInformation(heap1, heap2, i1, i2);
}
-/** Check whether two fragments are known to be matching
- *
- * @param state State used
- * @param b1 Block of state 1
- * @param f1 Fragment of state 1
- * @param b2 Block of state 2
- * @param f2 Fragment of state 2
- * @return if the fragments are known to be matching
- */
-static int equal_fragments(struct s_mc_diff *state, int b1, int f1, int b2,
- int f2)
+void ProcessComparisonState::initHeapInformation(xbt_mheap_t heap,
+ std::vector<simgrid::mc::IgnoredHeapRegion>* i)
{
-
- if (state->equals_to1_(b1, f1).block == b2
- && state->equals_to1_(b1, f1).fragment == f2
- && state->equals_to2_(b2, f2).block == b1
- && state->equals_to2_(b2, f2).fragment == f1)
- return 1;
-
- return 0;
+ auto heaplimit = ((struct mdesc *) heap)->heaplimit;
+ this->heapsize = ((struct mdesc *) heap)->heapsize;
+ this->to_ignore = i;
+ this->equals_to.assign(heaplimit * MAX_FRAGMENT_PER_BLOCK, s_heap_area {0, 0, 0});
+ this->types.assign(heaplimit * MAX_FRAGMENT_PER_BLOCK, nullptr);
}
-namespace simgrid {
-namespace mc {
-
-int init_heap_information(xbt_mheap_t heap1, xbt_mheap_t heap2,
+int StateComparator::initHeapInformation(xbt_mheap_t heap1, xbt_mheap_t heap2,
std::vector<simgrid::mc::IgnoredHeapRegion>* i1,
std::vector<simgrid::mc::IgnoredHeapRegion>* i2)
{
- if (mc_diff_info == nullptr) {
- mc_diff_info = xbt_new0(struct s_mc_diff, 1);
- mc_diff_info->equals_to1 = nullptr;
- mc_diff_info->equals_to2 = nullptr;
- mc_diff_info->types1 = nullptr;
- mc_diff_info->types2 = nullptr;
- }
- struct s_mc_diff *state = mc_diff_info;
-
if ((((struct mdesc *) heap1)->heaplimit !=
((struct mdesc *) heap2)->heaplimit)
||
((((struct mdesc *) heap1)->heapsize !=
((struct mdesc *) heap2)->heapsize)))
return -1;
-
- state->heaplimit = ((struct mdesc *) heap1)->heaplimit;
-
- state->std_heap_copy = *mc_model_checker->process().get_heap();
-
- state->heapsize1 = heap1->heapsize;
- state->heapsize2 = heap2->heapsize;
-
- state->to_ignore1 = i1;
- state->to_ignore2 = i2;
-
- if (state->heaplimit > state->available) {
- state->equals_to1 = (s_heap_area_t*)
- realloc(state->equals_to1,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK *
- sizeof(s_heap_area_t));
- state->types1 = (simgrid::mc::Type**)
- realloc(state->types1,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK *
- sizeof(simgrid::mc::Type*));
- state->equals_to2 = (s_heap_area_t*)
- realloc(state->equals_to2,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK *
- sizeof(s_heap_area_t));
- state->types2 = (simgrid::mc::Type**)
- realloc(state->types2,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK *
- sizeof(simgrid::mc::Type*));
- state->available = state->heaplimit;
- }
-
- memset(state->equals_to1, 0,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK * sizeof(s_heap_area_t));
- memset(state->equals_to2, 0,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK * sizeof(s_heap_area_t));
- memset(state->types1, 0,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK * sizeof(char**));
- memset(state->types2, 0,
- state->heaplimit * MAX_FRAGMENT_PER_BLOCK * sizeof(char**));
-
+ this->heaplimit = ((struct mdesc *) heap1)->heaplimit;
+ this->std_heap_copy = *mc_model_checker->process().get_heap();
+ this->processStates[0].initHeapInformation(heap1, i1);
+ this->processStates[1].initHeapInformation(heap2, i2);
return 0;
-
}
void reset_heap_information()
static inline
mc_mem_region_t MC_get_heap_region(simgrid::mc::Snapshot* snapshot)
{
- size_t n = snapshot->snapshot_regions.size();
- for (size_t i=0; i!=n; ++i) {
- mc_mem_region_t region = snapshot->snapshot_regions[i].get();
+ for (auto& region : snapshot->snapshot_regions)
if (region->region_type() == simgrid::mc::RegionType::Heap)
- return region;
- }
+ return region.get();
xbt_die("No heap region");
}
int mmalloc_compare_heap(simgrid::mc::Snapshot* snapshot1, simgrid::mc::Snapshot* snapshot2)
{
simgrid::mc::Process* process = &mc_model_checker->process();
- struct s_mc_diff *state = mc_diff_info;
+ simgrid::mc::StateComparator *state = mc_diff_info.get();
/* Start comparison */
size_t i1, i2, j1, j2, k;
const malloc_info* heapinfos2 = snapshot2->read<malloc_info*>(
(std::uint64_t)heapinfo_address, simgrid::mc::ProcessIndexMissing);
- while (i1 <= state->heaplimit) {
+ while (i1 < state->heaplimit) {
const malloc_info* heapinfo1 = (const malloc_info*) MC_region_read(heap_region1, &heapinfo_temp1, &heapinfos1[i1], sizeof(malloc_info));
const malloc_info* heapinfo2 = (const malloc_info*) MC_region_read(heap_region2, &heapinfo_temp2, &heapinfos2[i1], sizeof(malloc_info));
res_compare = 0;
/* Try first to associate to same block in the other heap */
- if (heapinfo2->type == heapinfo1->type) {
-
- if (state->equals_to2_(i1, 0).valid == 0) {
-
- addr_block2 = (ADDR2UINT(i1) - 1) * BLOCKSIZE +
- (char *) state->std_heap_copy.heapbase;
-
- res_compare =
- compare_heap_area(simgrid::mc::ProcessIndexMissing, addr_block1, addr_block2, snapshot1, snapshot2,
- nullptr, nullptr, 0);
-
- if (res_compare != 1) {
- for (k = 1; k < heapinfo2->busy_block.size; k++)
- state->equals_to2_(i1 + k, 0) = make_heap_area(i1, -1);
- for (k = 1; k < heapinfo1->busy_block.size; k++)
- state->equals_to1_(i1 + k, 0) = make_heap_area(i1, -1);
- equal = 1;
- i1 += heapinfo1->busy_block.size;
- }
-
+ if (heapinfo2->type == heapinfo1->type
+ && state->equals_to2_(i1, 0).valid == 0) {
+ addr_block2 = (ADDR2UINT(i1) - 1) * BLOCKSIZE +
+ (char *) state->std_heap_copy.heapbase;
+ res_compare =
+ compare_heap_area(simgrid::mc::ProcessIndexMissing, addr_block1, addr_block2, snapshot1, snapshot2,
+ nullptr, nullptr, 0);
+ if (res_compare != 1) {
+ for (k = 1; k < heapinfo2->busy_block.size; k++)
+ state->equals_to2_(i1 + k, 0) = make_heap_area(i1, -1);
+ for (k = 1; k < heapinfo1->busy_block.size; k++)
+ state->equals_to1_(i1 + k, 0) = make_heap_area(i1, -1);
+ equal = 1;
+ i1 += heapinfo1->busy_block.size;
}
-
}
- while (i2 <= state->heaplimit && !equal) {
+ while (i2 < state->heaplimit && !equal) {
addr_block2 = (ADDR2UINT(i2) - 1) * BLOCKSIZE +
(char *) state->std_heap_copy.heapbase;
equal = 0;
/* Try first to associate to same fragment in the other heap */
- if (heapinfo2->type == heapinfo1->type) {
-
- if (state->equals_to2_(i1, j1).valid == 0) {
-
- addr_block2 = (ADDR2UINT(i1) - 1) * BLOCKSIZE +
- (char *) state->std_heap_copy.heapbase;
- addr_frag2 =
- (void *) ((char *) addr_block2 +
- (j1 << heapinfo2->type));
-
- res_compare =
- compare_heap_area(simgrid::mc::ProcessIndexMissing, addr_frag1, addr_frag2, snapshot1, snapshot2,
- nullptr, nullptr, 0);
-
- if (res_compare != 1)
- equal = 1;
+ if (heapinfo2->type == heapinfo1->type
+ && state->equals_to2_(i1, j1).valid == 0) {
+ addr_block2 = (ADDR2UINT(i1) - 1) * BLOCKSIZE +
+ (char *) state->std_heap_copy.heapbase;
+ addr_frag2 =
+ (void *) ((char *) addr_block2 +
+ (j1 << heapinfo2->type));
+ res_compare =
+ compare_heap_area(simgrid::mc::ProcessIndexMissing, addr_frag1, addr_frag2, snapshot1, snapshot2,
+ nullptr, nullptr, 0);
+ if (res_compare != 1)
+ equal = 1;
+ }
- }
- }
- while (i2 <= state->heaplimit && !equal) {
+ while (i2 < state->heaplimit && !equal) {
const malloc_info* heapinfo2b = (const malloc_info*) MC_region_read(
heap_region2, &heapinfo_temp2b, &heapinfos2[i2],
/* All blocks/fragments are equal to another block/fragment ? */
size_t i = 1, j = 0;
- for(i = 1; i <= state->heaplimit; i++) {
+ for(i = 1; i < state->heaplimit; i++) {
const malloc_info* heapinfo1 = (const malloc_info*) MC_region_read(
heap_region1, &heapinfo_temp1, &heapinfos1[i], sizeof(malloc_info));
- if (heapinfo1->type == MMALLOC_TYPE_UNFRAGMENTED) {
- if (i1 == state->heaplimit) {
- if (heapinfo1->busy_block.busy_size > 0) {
- if (state->equals_to1_(i, 0).valid == 0) {
- if (XBT_LOG_ISENABLED(mc_diff, xbt_log_priority_debug)) {
- // TODO, add address
- XBT_DEBUG("Block %zu not found (size used = %zu)", i,
- heapinfo1->busy_block.busy_size);
- //mmalloc_backtrace_block_display((void*)heapinfo1, i);
- }
- nb_diff1++;
- }
- }
- }
+
+ if (heapinfo1->type == MMALLOC_TYPE_UNFRAGMENTED
+ && i1 == state->heaplimit
+ && heapinfo1->busy_block.busy_size > 0
+ && state->equals_to1_(i, 0).valid == 0) {
+ XBT_DEBUG("Block %zu not found (size used = %zu)", i,
+ heapinfo1->busy_block.busy_size);
+ nb_diff1++;
}
- if (heapinfo1->type > 0) {
- for (j = 0; j < (size_t) (BLOCKSIZE >> heapinfo1->type); j++) {
- if (i1 == state->heaplimit) {
- if (heapinfo1->busy_frag.frag_size[j] > 0) {
- if (state->equals_to1_(i, j).valid == 0) {
- if (XBT_LOG_ISENABLED(mc_diff, xbt_log_priority_debug)) {
- // TODO, print fragment address
- XBT_DEBUG
- ("Block %zu, Fragment %zu not found (size used = %zd)",
- i, j,
- heapinfo1->busy_frag.frag_size[j]);
- //mmalloc_backtrace_fragment_display((void*)heapinfo1, i, j);
- }
- nb_diff1++;
- }
- }
- }
+
+ if (heapinfo1->type <= 0)
+ continue;
+ for (j = 0; j < (size_t) (BLOCKSIZE >> heapinfo1->type); j++)
+ if (i1 == state->heaplimit
+ && heapinfo1->busy_frag.frag_size[j] > 0
+ && state->equals_to1_(i, j).valid == 0) {
+ XBT_DEBUG("Block %zu, Fragment %zu not found (size used = %zd)",
+ i, j, heapinfo1->busy_frag.frag_size[j]);
+ nb_diff1++;
}
- }
}
if (i1 == state->heaplimit)
XBT_DEBUG("Number of blocks/fragments not found in heap1 : %d", nb_diff1);
- for (i=1; i <= state->heaplimit; i++) {
+ for (i=1; i < state->heaplimit; i++) {
const malloc_info* heapinfo2 = (const malloc_info*) MC_region_read(
heap_region2, &heapinfo_temp2, &heapinfos2[i], sizeof(malloc_info));
- if (heapinfo2->type == MMALLOC_TYPE_UNFRAGMENTED) {
- if (i1 == state->heaplimit) {
- if (heapinfo2->busy_block.busy_size > 0) {
- if (state->equals_to2_(i, 0).valid == 0) {
- if (XBT_LOG_ISENABLED(mc_diff, xbt_log_priority_debug)) {
- // TODO, print address of the block
- XBT_DEBUG("Block %zu not found (size used = %zu)", i,
- heapinfo2->busy_block.busy_size);
- //mmalloc_backtrace_block_display((void*)heapinfo2, i);
- }
- nb_diff2++;
- }
- }
- }
+ if (heapinfo2->type == MMALLOC_TYPE_UNFRAGMENTED
+ && i1 == state->heaplimit
+ && heapinfo2->busy_block.busy_size > 0
+ && state->equals_to2_(i, 0).valid == 0) {
+ XBT_DEBUG("Block %zu not found (size used = %zu)", i,
+ heapinfo2->busy_block.busy_size);
+ nb_diff2++;
}
- if (heapinfo2->type > 0) {
- for (j = 0; j < (size_t) (BLOCKSIZE >> heapinfo2->type); j++) {
- if (i1 == state->heaplimit) {
- if (heapinfo2->busy_frag.frag_size[j] > 0) {
- if (state->equals_to2_(i, j).valid == 0) {
- if (XBT_LOG_ISENABLED(mc_diff, xbt_log_priority_debug)) {
- // TODO, print address of the block
- XBT_DEBUG
- ("Block %zu, Fragment %zu not found (size used = %zd)",
- i, j,
- heapinfo2->busy_frag.frag_size[j]);
- //mmalloc_backtrace_fragment_display((void*)heapinfo2, i, j);
- }
- nb_diff2++;
- }
- }
- }
+
+ if (heapinfo2->type <= 0)
+ continue;
+
+ for (j = 0; j < (size_t) (BLOCKSIZE >> heapinfo2->type); j++)
+ if (i1 == state->heaplimit
+ && heapinfo2->busy_frag.frag_size[j] > 0
+ && state->equals_to2_(i, j).valid == 0) {
+ XBT_DEBUG("Block %zu, Fragment %zu not found (size used = %zd)",
+ i, j, heapinfo2->busy_frag.frag_size[j]);
+ nb_diff2++;
}
- }
+
}
if (i1 == state->heaplimit)
XBT_DEBUG("Number of blocks/fragments not found in heap2 : %d", nb_diff2);
- return ((nb_diff1 > 0) || (nb_diff2 > 0));
+ return nb_diff1 > 0 || nb_diff2 > 0;
}
/**
* @param size
* @param check_ignore
*/
-static int compare_heap_area_without_type(struct s_mc_diff *state, int process_index,
- const void *real_area1, const void *real_area2,
- simgrid::mc::Snapshot* snapshot1,
- simgrid::mc::Snapshot* snapshot2,
- xbt_dynar_t previous, int size,
- int check_ignore)
+static int compare_heap_area_without_type(
+ simgrid::mc::StateComparator *state, int process_index,
+ const void *real_area1, const void *real_area2,
+ simgrid::mc::Snapshot* snapshot1,
+ simgrid::mc::Snapshot* snapshot2,
+ xbt_dynar_t previous, int size,
+ int check_ignore)
{
simgrid::mc::Process* process = &mc_model_checker->process();
-
- int i = 0;
- const void *addr_pointed1, *addr_pointed2;
- int pointer_align, res_compare;
- ssize_t ignore1, ignore2;
-
mc_mem_region_t heap_region1 = MC_get_heap_region(snapshot1);
mc_mem_region_t heap_region2 = MC_get_heap_region(snapshot2);
- while (i < size) {
+ for (int i = 0; i < size; ) {
if (check_ignore > 0) {
- if ((ignore1 =
- heap_comparison_ignore_size(state->to_ignore1,
- (char *) real_area1 + i)) != -1) {
- if ((ignore2 =
- heap_comparison_ignore_size(state->to_ignore2,
- (char *) real_area2 + i)) == ignore1) {
+ ssize_t ignore1 = heap_comparison_ignore_size(
+ state->processStates[0].to_ignore, (char *) real_area1 + i);
+ if (ignore1 != -1) {
+ ssize_t ignore2 = heap_comparison_ignore_size(
+ state->processStates[1].to_ignore, (char *) real_area2 + i);
+ if (ignore2 == ignore1) {
if (ignore1 == 0) {
check_ignore--;
return 0;
if (MC_snapshot_region_memcmp(((char *) real_area1) + i, heap_region1, ((char *) real_area2) + i, heap_region2, 1) != 0) {
- pointer_align = (i / sizeof(void *)) * sizeof(void *);
- addr_pointed1 = snapshot1->read(
+ int pointer_align = (i / sizeof(void *)) * sizeof(void *);
+ const void* addr_pointed1 = snapshot1->read(
remote((void**)((char *) real_area1 + pointer_align)), process_index);
- addr_pointed2 = snapshot2->read(
+ const void* addr_pointed2 = snapshot2->read(
remote((void**)((char *) real_area2 + pointer_align)), process_index);
if (process->in_maestro_stack(remote(addr_pointed1))
&& process->in_maestro_stack(remote(addr_pointed2))) {
i = pointer_align + sizeof(void *);
continue;
- } else if (addr_pointed1 > state->std_heap_copy.heapbase
- && addr_pointed1 < mc_snapshot_get_heap_end(snapshot1)
- && addr_pointed2 > state->std_heap_copy.heapbase
- && addr_pointed2 < mc_snapshot_get_heap_end(snapshot2)) {
+ }
+
+ if (addr_pointed1 > state->std_heap_copy.heapbase
+ && addr_pointed1 < mc_snapshot_get_heap_end(snapshot1)
+ && addr_pointed2 > state->std_heap_copy.heapbase
+ && addr_pointed2 < mc_snapshot_get_heap_end(snapshot2)) {
// Both addreses are in the heap:
- res_compare =
+ int res_compare =
compare_heap_area(process_index, addr_pointed1, addr_pointed2, snapshot1,
snapshot2, previous, nullptr, 0);
if (res_compare == 1)
return res_compare;
i = pointer_align + sizeof(void *);
continue;
- } else
- return 1;
+ }
+ return 1;
}
i++;
-
}
return 0;
-
}
/**
* @param pointer_level
* @return 0 (same), 1 (different), -1 (unknown)
*/
-static int compare_heap_area_with_type(struct s_mc_diff *state, int process_index,
- const void *real_area1, const void *real_area2,
- simgrid::mc::Snapshot* snapshot1,
- simgrid::mc::Snapshot* snapshot2,
- xbt_dynar_t previous, simgrid::mc::Type* type,
- int area_size, int check_ignore,
- int pointer_level)
+static int compare_heap_area_with_type(
+ simgrid::mc::StateComparator *state, int process_index,
+ const void *real_area1, const void *real_area2,
+ simgrid::mc::Snapshot* snapshot1,
+ simgrid::mc::Snapshot* snapshot2,
+ xbt_dynar_t previous, simgrid::mc::Type* type,
+ int area_size, int check_ignore,
+ int pointer_level)
{
top:
- // HACK: This should not happen but in pratice, there is some
- // DW_TAG_typedef without DW_AT_type. We should fix this somehow.
+
+ // HACK: This should not happen but in pratice, there are some
+ // DW_TAG_typedef without an associated DW_AT_type:
+ //<1><538832>: Abbrev Number: 111 (DW_TAG_typedef)
+ // <538833> DW_AT_name : (indirect string, offset: 0x2292f3): gregset_t
+ // <538837> DW_AT_decl_file : 98
+ // <538838> DW_AT_decl_line : 37
if (type == nullptr)
return 0;
if (is_stack(real_area1) && is_stack(real_area2))
return 0;
- ssize_t ignore1, ignore2;
- if ((check_ignore > 0)
- && ((ignore1 = heap_comparison_ignore_size(state->to_ignore1, real_area1))
- > 0)
- && ((ignore2 = heap_comparison_ignore_size(state->to_ignore2, real_area2))
- == ignore1))
- return 0;
+ if (check_ignore > 0) {
+ ssize_t ignore1 = heap_comparison_ignore_size(
+ state->processStates[0].to_ignore, real_area1);
+ if (ignore1 > 0
+ && heap_comparison_ignore_size(
+ state->processStates[1].to_ignore, real_area2) == ignore1)
+ return 0;
+ }
simgrid::mc::Type *subtype, *subsubtype;
int res, elm_size;
if (real_area1 == real_area2)
return -1;
else
- return (MC_snapshot_region_memcmp(real_area1, heap_region1, real_area2, heap_region2, area_size) != 0);
+ return MC_snapshot_region_memcmp(real_area1, heap_region1, real_area2, heap_region2, area_size) != 0;
} else {
if (area_size != -1 && type->byte_size != area_size)
return -1;
else
- return (MC_snapshot_region_memcmp(real_area1, heap_region1, real_area2, heap_region2, type->byte_size) != 0);
+ return MC_snapshot_region_memcmp(real_area1, heap_region1, real_area2, heap_region2, type->byte_size) != 0;
}
break;
+
case DW_TAG_enumeration_type:
if (area_size != -1 && type->byte_size != area_size)
return -1;
- else
- return (MC_snapshot_region_memcmp(real_area1, heap_region1, real_area2, heap_region2, type->byte_size) != 0);
- break;
+ return MC_snapshot_region_memcmp(real_area1, heap_region1, real_area2, heap_region2, type->byte_size) != 0;
+
case DW_TAG_typedef:
case DW_TAG_const_type:
case DW_TAG_volatile_type:
// Poor man's TCO:
type = type->subtype;
goto top;
- break;
+
case DW_TAG_array_type:
subtype = type->subtype;
switch (subtype->type) {
if (res == 1)
return res;
}
- break;
+ return 0;
+
case DW_TAG_reference_type:
case DW_TAG_rvalue_reference_type:
case DW_TAG_pointer_type:
if (type->subtype && type->subtype->type == DW_TAG_subroutine_type) {
addr_pointed1 = snapshot1->read(remote((void**)real_area1), process_index);
addr_pointed2 = snapshot2->read(remote((void**)real_area2), process_index);
- return (addr_pointed1 != addr_pointed2);;
- } else {
- pointer_level++;
- if (pointer_level > 1) { /* Array of pointers */
- for (size_t i = 0; i < (area_size / sizeof(void *)); i++) {
- addr_pointed1 = snapshot1->read(
- remote((void**)((char*) real_area1 + i * sizeof(void *))),
- process_index);
- addr_pointed2 = snapshot2->read(
- remote((void**)((char*) real_area2 + i * sizeof(void *))),
- process_index);
- if (addr_pointed1 > state->std_heap_copy.heapbase
- && addr_pointed1 < mc_snapshot_get_heap_end(snapshot1)
- && addr_pointed2 > state->std_heap_copy.heapbase
- && addr_pointed2 < mc_snapshot_get_heap_end(snapshot2))
- res =
- compare_heap_area(process_index, addr_pointed1, addr_pointed2, snapshot1,
- snapshot2, previous, type->subtype,
- pointer_level);
- else
- res = (addr_pointed1 != addr_pointed2);
- if (res == 1)
- return res;
- }
- } else {
- addr_pointed1 = snapshot1->read(remote((void**)real_area1), process_index);
- addr_pointed2 = snapshot2->read(remote((void**)real_area2), process_index);
- if (addr_pointed1 > state->std_heap_copy.heapbase
- && addr_pointed1 < mc_snapshot_get_heap_end(snapshot1)
- && addr_pointed2 > state->std_heap_copy.heapbase
- && addr_pointed2 < mc_snapshot_get_heap_end(snapshot2))
- return compare_heap_area(process_index, addr_pointed1, addr_pointed2, snapshot1,
- snapshot2, previous, type->subtype,
- pointer_level);
- else
- return (addr_pointed1 != addr_pointed2);
- }
+ return (addr_pointed1 != addr_pointed2);
}
- break;
+ pointer_level++;
+ if (pointer_level <= 1) {
+ addr_pointed1 = snapshot1->read(remote((void**)real_area1), process_index);
+ addr_pointed2 = snapshot2->read(remote((void**)real_area2), process_index);
+ if (addr_pointed1 > state->std_heap_copy.heapbase
+ && addr_pointed1 < mc_snapshot_get_heap_end(snapshot1)
+ && addr_pointed2 > state->std_heap_copy.heapbase
+ && addr_pointed2 < mc_snapshot_get_heap_end(snapshot2))
+ return compare_heap_area(process_index, addr_pointed1, addr_pointed2, snapshot1,
+ snapshot2, previous, type->subtype,
+ pointer_level);
+ else
+ return (addr_pointed1 != addr_pointed2);
+ }
+ for (size_t i = 0; i < (area_size / sizeof(void *)); i++) {
+ addr_pointed1 = snapshot1->read(
+ remote((void**)((char*) real_area1 + i * sizeof(void *))),
+ process_index);
+ addr_pointed2 = snapshot2->read(
+ remote((void**)((char*) real_area2 + i * sizeof(void *))),
+ process_index);
+ if (addr_pointed1 > state->std_heap_copy.heapbase
+ && addr_pointed1 < mc_snapshot_get_heap_end(snapshot1)
+ && addr_pointed2 > state->std_heap_copy.heapbase
+ && addr_pointed2 < mc_snapshot_get_heap_end(snapshot2))
+ res =
+ compare_heap_area(process_index, addr_pointed1, addr_pointed2, snapshot1,
+ snapshot2, previous, type->subtype,
+ pointer_level);
+ else
+ res = (addr_pointed1 != addr_pointed2);
+ if (res == 1)
+ return res;
+ }
+ return 0;
+
case DW_TAG_structure_type:
case DW_TAG_class_type:
if (type->full_type)
type = type->full_type;
if (area_size != -1 && type->byte_size != area_size) {
- if (area_size > type->byte_size && area_size % type->byte_size == 0) {
- for (size_t i = 0; i < (size_t)(area_size / type->byte_size); i++) {
- res =
- compare_heap_area_with_type(state, process_index,
- (char *) real_area1 + i * type->byte_size,
- (char *) real_area2 + i * type->byte_size,
- snapshot1, snapshot2, previous, type, -1,
- check_ignore, 0);
- if (res == 1)
- return res;
- }
- } else
+ if (area_size <= type->byte_size || area_size % type->byte_size != 0)
return -1;
+ for (size_t i = 0; i < (size_t)(area_size / type->byte_size); i++) {
+ int res = compare_heap_area_with_type(state, process_index,
+ (char *) real_area1 + i * type->byte_size,
+ (char *) real_area2 + i * type->byte_size,
+ snapshot1, snapshot2, previous, type, -1,
+ check_ignore, 0);
+ if (res == 1)
+ return res;
+ }
} else {
for(simgrid::mc::Member& member : type->members) {
// TODO, optimize this? (for the offset case)
real_area1, type, &member, (simgrid::mc::AddressSpace*) snapshot1, process_index);
void *real_member2 = simgrid::dwarf::resolve_member(
real_area2, type, &member, (simgrid::mc::AddressSpace*) snapshot2, process_index);
- res =
- compare_heap_area_with_type(state, process_index, real_member1, real_member2,
- snapshot1, snapshot2,
- previous, member.type, -1,
- check_ignore, 0);
+ int res = compare_heap_area_with_type(
+ state, process_index, real_member1, real_member2,
+ snapshot1, snapshot2,
+ previous, member.type, -1,
+ check_ignore, 0);
if (res == 1)
return res;
}
}
- break;
+ return 0;
+
case DW_TAG_union_type:
return compare_heap_area_without_type(state, process_index, real_area1, real_area2,
snapshot1, snapshot2, previous,
type->byte_size, check_ignore);
- break;
+ return 0;
+
default:
- break;
+ return 0;
}
- return 0;
-
+ xbt_die("Unreachable");
}
/** Infer the type of a part of the block from the type of the block
return type;
switch (type->type) {
+
case DW_TAG_structure_type:
case DW_TAG_class_type:
if (type->full_type)
type = type->full_type;
-
if (area_size != -1 && type->byte_size != area_size) {
if (area_size > type->byte_size && area_size % type->byte_size == 0)
return type;
else
return nullptr;
- } else {
- for(simgrid::mc::Member& member : type->members) {
-
- if (member.has_offset_location()) {
- // We have the offset, use it directly (shortcut):
- if (member.offset() == offset)
- return member.type;
- } else {
- void *real_member = simgrid::dwarf::resolve_member(
- real_base_address, type, &member, snapshot, process_index);
- if ((char*) real_member - (char *) real_base_address == offset)
- return member.type;
- }
+ }
+ for(simgrid::mc::Member& member : type->members) {
+ if (member.has_offset_location()) {
+ // We have the offset, use it directly (shortcut):
+ if (member.offset() == offset)
+ return member.type;
+ } else {
+ void *real_member = simgrid::dwarf::resolve_member(
+ real_base_address, type, &member, snapshot, process_index);
+ if ((char*) real_member - (char *) real_base_address == offset)
+ return member.type;
}
- return nullptr;
}
- break;
+ return nullptr;
+
default:
/* FIXME : other cases ? */
return nullptr;
- break;
+
}
}
{
simgrid::mc::Process* process = &mc_model_checker->process();
- struct s_mc_diff *state = mc_diff_info;
+ simgrid::mc::StateComparator *state = mc_diff_info.get();
int res_compare;
ssize_t block1, frag1, block2, frag2;
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(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return 0;
}
+
// If either block is not in the expected area of memory:
if (((char *) area1 < (char *) state->std_heap_copy.heapbase)
- || (block1 > (ssize_t) state->heapsize1) || (block1 < 1)
+ || (block1 > (ssize_t) state->processStates[0].heapsize) || (block1 < 1)
|| ((char *) area2 < (char *) state->std_heap_copy.heapbase)
- || (block2 > (ssize_t) state->heapsize2) || (block2 < 1)) {
+ || (block2 > (ssize_t) state->processStates[1].heapsize) || (block2 < 1)) {
if (match_pairs)
xbt_dynar_free(&previous);
return 1;
type = type->subtype;
// Find type_size:
- if ((type->type == DW_TAG_pointer_type)
- || ((type->type == DW_TAG_base_type) && !type->name.empty()
+ if (type->type == DW_TAG_pointer_type
+ || (type->type == DW_TAG_base_type && !type->name.empty()
&& type->name == "char"))
type_size = -1;
else
if ((heapinfo1->type == MMALLOC_TYPE_FREE || heapinfo1->type==MMALLOC_TYPE_HEAPINFO)
&& (heapinfo2->type == MMALLOC_TYPE_FREE || heapinfo2->type ==MMALLOC_TYPE_HEAPINFO)) {
-
/* Free block */
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return 0;
+ }
- } else if (heapinfo1->type == MMALLOC_TYPE_UNFRAGMENTED
+ if (heapinfo1->type == MMALLOC_TYPE_UNFRAGMENTED
&& heapinfo2->type == MMALLOC_TYPE_UNFRAGMENTED) {
/* Complete block */
offset2 = (char *) area2 - (char *) real_addr_block2;
if (state->equals_to1_(block1, 0).valid
- && state->equals_to2_(block2, 0).valid) {
- if (equal_blocks(state, block1, block2)) {
- if (match_pairs) {
- match_equals(state, previous);
- xbt_dynar_free(&previous);
- }
- return 0;
+ && state->equals_to2_(block2, 0).valid
+ && state->blocksEqual(block1, block2)) {
+ if (match_pairs) {
+ state->match_equals(previous);
+ xbt_dynar_free(&previous);
}
+ return 0;
}
if (type_size != -1) {
&& type_size != (ssize_t) heapinfo2->busy_block.busy_size
&& (type->name.empty() || type->name == "struct s_smx_context")) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return -1;
}
}
- if (heapinfo1->busy_block.size !=
- heapinfo2->busy_block.size) {
+ if (heapinfo1->busy_block.size != heapinfo2->busy_block.size) {
if (match_pairs)
xbt_dynar_free(&previous);
return 1;
}
- if (heapinfo1->busy_block.busy_size !=
- heapinfo2->busy_block.busy_size) {
+ if (heapinfo1->busy_block.busy_size != heapinfo2->busy_block.busy_size) {
if (match_pairs)
xbt_dynar_free(&previous);
return 1;
if (!add_heap_area_pair(previous, block1, -1, block2, -1)) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return 0;
if (size <= 0) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return 0;
frag1 = -1;
frag2 = -1;
- if ((heapinfo1->busy_block.ignore > 0)
- && (heapinfo2->busy_block.ignore ==
- heapinfo1->busy_block.ignore))
+ if (heapinfo1->busy_block.ignore > 0
+ && heapinfo2->busy_block.ignore == heapinfo1->busy_block.ignore)
check_ignore = heapinfo1->busy_block.ignore;
} else if ((heapinfo1->type > 0) && (heapinfo2->type > 0)) { /* Fragmented block */
if (heapinfo1->busy_frag.frag_size[frag1] == -1
|| heapinfo2->busy_frag.frag_size[frag2] == -1) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return -1;
if (type_size != heapinfo1->busy_frag.frag_size[frag1]
|| type_size != heapinfo2->busy_frag.frag_size[frag2]) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return -1;
// Check if the blocks are already matched together:
if (state->equals_to1_(block1, frag1).valid
&& state->equals_to2_(block2, frag2).valid) {
- if (offset1==offset2 && equal_fragments(state, block1, frag1, block2, frag2)) {
+ if (offset1==offset2 && state->fragmentsEqual(block1, frag1, block2, frag2)) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return 0;
heapinfo2->busy_frag.frag_size[frag2]) {
if (type_size == -1) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return -1;
offset2, size, snapshot2, process_index);
} else {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return -1;
} else {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return -1;
if (offset1 == 0 && offset2 == 0
&& !add_heap_area_pair(previous, block1, frag1, block2, frag2)) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return 0;
if (size <= 0) {
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}
return 0;
check_ignore = heapinfo1->busy_frag.ignore[frag1];
} else {
-
if (match_pairs)
xbt_dynar_free(&previous);
return 1;
-
}
}
if (match_pairs) {
- match_equals(state, previous);
+ state->match_equals(previous);
xbt_dynar_free(&previous);
}