snapshot2.read<malloc_info*>(RemotePtr<malloc_info*>((std::uint64_t)heapinfo_address));
while (i1 < state.heaplimit) {
- const malloc_info* heapinfo1 =
- (const malloc_info*)heap_region1->read(&heapinfo_temp1, &heapinfos1[i1], sizeof(malloc_info));
- const malloc_info* heapinfo2 =
- (const malloc_info*)heap_region2->read(&heapinfo_temp2, &heapinfos2[i1], sizeof(malloc_info));
+ const auto* heapinfo1 =
+ static_cast<malloc_info*>(heap_region1->read(&heapinfo_temp1, &heapinfos1[i1], sizeof(malloc_info)));
+ const auto* heapinfo2 =
+ static_cast<malloc_info*>(heap_region2->read(&heapinfo_temp2, &heapinfos2[i1], sizeof(malloc_info)));
if (heapinfo1->type == MMALLOC_TYPE_FREE || heapinfo1->type == MMALLOC_TYPE_HEAPINFO) { /* Free block */
i1 ++;
continue;
}
- xbt_assert(heapinfo1->type >= 0, "Unkown mmalloc block type: %d", heapinfo1->type);
+ xbt_assert(heapinfo1->type >= 0, "Unknown mmalloc block type: %d", heapinfo1->type);
void* addr_block1 = ((void*)(((ADDR2UINT(i1)) - 1) * BLOCKSIZE + (char*)state.std_heap_copy.heapbase));
continue;
}
- const malloc_info* heapinfo2b =
- (const malloc_info*)heap_region2->read(&heapinfo_temp2b, &heapinfos2[i2], sizeof(malloc_info));
+ const auto* heapinfo2b =
+ static_cast<malloc_info*>(heap_region2->read(&heapinfo_temp2b, &heapinfos2[i2], sizeof(malloc_info)));
if (heapinfo2b->type != MMALLOC_TYPE_UNFRAGMENTED) {
i2++;
if (state.equals_to_<1>(i1, j1).valid_)
continue;
- void* addr_frag1 = (void*)((char*)addr_block1 + (j1 << heapinfo1->type));
+ void* addr_frag1 = (char*)addr_block1 + (j1 << heapinfo1->type);
size_t i2 = 1;
bool equal = false;
}
while (i2 < state.heaplimit && not equal) {
- const malloc_info* heapinfo2b =
- (const malloc_info*)heap_region2->read(&heapinfo_temp2b, &heapinfos2[i2], sizeof(malloc_info));
+ const auto* heapinfo2b =
+ static_cast<malloc_info*>(heap_region2->read(&heapinfo_temp2b, &heapinfos2[i2], sizeof(malloc_info)));
if (heapinfo2b->type == MMALLOC_TYPE_FREE || heapinfo2b->type == MMALLOC_TYPE_HEAPINFO) {
i2 ++;
continue;
}
- xbt_assert(heapinfo2b->type >= 0, "Unkown mmalloc block type: %d", heapinfo2b->type);
+ xbt_assert(heapinfo2b->type >= 0, "Unknown mmalloc block type: %d", heapinfo2b->type);
for (size_t j2 = 0; j2 < (size_t)(BLOCKSIZE >> heapinfo2b->type); j2++) {
if (i2 == i1 && j2 == j1)
/* All blocks/fragments are equal to another block/fragment_ ? */
for (size_t i = 1; i < state.heaplimit; i++) {
- const malloc_info* heapinfo1 =
- (const malloc_info*)heap_region1->read(&heapinfo_temp1, &heapinfos1[i], sizeof(malloc_info));
+ const auto* heapinfo1 =
+ static_cast<malloc_info*>(heap_region1->read(&heapinfo_temp1, &heapinfos1[i], sizeof(malloc_info)));
if (heapinfo1->type == MMALLOC_TYPE_UNFRAGMENTED && i1 == state.heaplimit && heapinfo1->busy_block.busy_size > 0 &&
not state.equals_to_<1>(i, 0).valid_) {
}
for (size_t i = 1; i < state.heaplimit; i++) {
- const malloc_info* heapinfo2 =
- (const malloc_info*)heap_region2->read(&heapinfo_temp2, &heapinfos2[i], sizeof(malloc_info));
+ const auto* heapinfo2 =
+ static_cast<malloc_info*>(heap_region2->read(&heapinfo_temp2, &heapinfos2[i], sizeof(malloc_info)));
if (heapinfo2->type == MMALLOC_TYPE_UNFRAGMENTED && i1 == state.heaplimit && heapinfo2->busy_block.busy_size > 0 &&
not state.equals_to_<2>(i, 0).valid_) {
XBT_DEBUG("Block %zu not found (size used = %zu)", i,
const Region* heap_region1 = MC_get_heap_region(snapshot1);
const Region* heap_region2 = MC_get_heap_region(snapshot2);
- const malloc_info* heapinfo1 =
- (const malloc_info*)heap_region1->read(&heapinfo_temp1, &heapinfos1[block1], sizeof(malloc_info));
- const malloc_info* heapinfo2 =
- (const malloc_info*)heap_region2->read(&heapinfo_temp2, &heapinfos2[block2], sizeof(malloc_info));
+ const auto* heapinfo1 =
+ static_cast<malloc_info*>(heap_region1->read(&heapinfo_temp1, &heapinfos1[block1], sizeof(malloc_info)));
+ const auto* heapinfo2 =
+ static_cast<malloc_info*>(heap_region2->read(&heapinfo_temp2, &heapinfos2[block2], sizeof(malloc_info)));
if ((heapinfo1->type == MMALLOC_TYPE_FREE || heapinfo1->type==MMALLOC_TYPE_HEAPINFO)
&& (heapinfo2->type == MMALLOC_TYPE_FREE || heapinfo2->type ==MMALLOC_TYPE_HEAPINFO)) {
} else if ((heapinfo1->type > 0) && (heapinfo2->type > 0)) { /* Fragmented block */
// Fragment number:
- ssize_t frag1 = ((uintptr_t)(ADDR2UINT(area1) % (BLOCKSIZE))) >> heapinfo1->type;
- ssize_t frag2 = ((uintptr_t)(ADDR2UINT(area2) % (BLOCKSIZE))) >> heapinfo2->type;
+ ssize_t frag1 = (ADDR2UINT(area1) % BLOCKSIZE) >> heapinfo1->type;
+ ssize_t frag2 = (ADDR2UINT(area2) % BLOCKSIZE) >> heapinfo2->type;
// Process address of the fragment_:
- void* real_addr_frag1 = (void*)((char*)real_addr_block1 + (frag1 << heapinfo1->type));
- void* real_addr_frag2 = (void*)((char*)real_addr_block2 + (frag2 << heapinfo2->type));
+ void* real_addr_frag1 = (char*)real_addr_block1 + (frag1 << heapinfo1->type);
+ void* real_addr_frag2 = (char*)real_addr_block2 + (frag2 << heapinfo2->type);
// Check the size of the fragments against the size of the type:
if (type_size != -1) {
const simgrid::mc::Type* subtype;
const simgrid::mc::Type* subsubtype;
int elm_size;
- int i;
xbt_assert(type != nullptr);
switch (type->type) {
default:
return false;
}
- for (i = 0; i < type->element_count; i++) {
+ for (int i = 0; i < type->element_count; i++) {
size_t off = i * elm_size;
if (areas_differ_with_type(state, (const char*)real_area1 + off, snapshot1, region1,
(const char*)real_area2 + off, snapshot2, region2, type->subtype, pointer_level))
// If the variable is not in this object, skip it:
// We do not expect to find a pointer to something which is not reachable
// by the global variables.
- if ((char *) current_var.address < (char *) object_info->start_rw
- || (char *) current_var.address > (char *) object_info->end_rw)
+ if ((char*)current_var.address < object_info->start_rw || (char*)current_var.address > object_info->end_rw)
continue;
const simgrid::mc::Type* bvariable_type = current_var.type;