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Issue 2176133002: Revert of [heap] Remove black pages and use black areas instead. (Closed) Base URL: https://chromium.googlesource.com/v8/v8.git@master
Patch Set: Created 4 years, 4 months ago
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1 // Copyright 2011 the V8 project authors. All rights reserved. 1 // Copyright 2011 the V8 project authors. All rights reserved.
2 // Use of this source code is governed by a BSD-style license that can be 2 // Use of this source code is governed by a BSD-style license that can be
3 // found in the LICENSE file. 3 // found in the LICENSE file.
4 4
5 #include "src/heap/spaces.h" 5 #include "src/heap/spaces.h"
6 6
7 #include "src/base/bits.h" 7 #include "src/base/bits.h"
8 #include "src/base/platform/platform.h" 8 #include "src/base/platform/platform.h"
9 #include "src/base/platform/semaphore.h" 9 #include "src/base/platform/semaphore.h"
10 #include "src/full-codegen/full-codegen.h" 10 #include "src/full-codegen/full-codegen.h"
(...skipping 1211 matching lines...) Expand 10 before | Expand all | Expand 10 after
1222 if (!heap()->CanExpandOldGeneration(size)) return false; 1222 if (!heap()->CanExpandOldGeneration(size)) return false;
1223 1223
1224 Page* p = heap()->memory_allocator()->AllocatePage(size, this, executable()); 1224 Page* p = heap()->memory_allocator()->AllocatePage(size, this, executable());
1225 if (p == nullptr) return false; 1225 if (p == nullptr) return false;
1226 1226
1227 AccountCommitted(static_cast<intptr_t>(p->size())); 1227 AccountCommitted(static_cast<intptr_t>(p->size()));
1228 1228
1229 // Pages created during bootstrapping may contain immortal immovable objects. 1229 // Pages created during bootstrapping may contain immortal immovable objects.
1230 if (!heap()->deserialization_complete()) p->MarkNeverEvacuate(); 1230 if (!heap()->deserialization_complete()) p->MarkNeverEvacuate();
1231 1231
1232 // When incremental marking was activated, old space pages are allocated
1233 // black.
1234 if (heap()->incremental_marking()->black_allocation() &&
1235 identity() == OLD_SPACE) {
1236 p->markbits()->SetAllBits();
1237 p->SetFlag(Page::BLACK_PAGE);
1238 if (FLAG_trace_incremental_marking) {
1239 PrintIsolate(heap()->isolate(), "Added black page %p\n",
1240 static_cast<void*>(p));
1241 }
1242 }
1243
1232 DCHECK(Capacity() <= heap()->MaxOldGenerationSize()); 1244 DCHECK(Capacity() <= heap()->MaxOldGenerationSize());
1233 1245
1234 p->InsertAfter(anchor_.prev_page()); 1246 p->InsertAfter(anchor_.prev_page());
1235 1247
1236 return true; 1248 return true;
1237 } 1249 }
1238 1250
1239 1251
1240 int PagedSpace::CountTotalPages() { 1252 int PagedSpace::CountTotalPages() {
1241 int count = 0; 1253 int count = 0;
1242 for (Page* page : *this) { 1254 for (Page* page : *this) {
1243 count++; 1255 count++;
1244 USE(page); 1256 USE(page);
1245 } 1257 }
1246 return count; 1258 return count;
1247 } 1259 }
1248 1260
1249 1261
1250 void PagedSpace::ResetFreeListStatistics() { 1262 void PagedSpace::ResetFreeListStatistics() {
1251 for (Page* page : *this) { 1263 for (Page* page : *this) {
1252 page->ResetFreeListStatistics(); 1264 page->ResetFreeListStatistics();
1253 } 1265 }
1254 } 1266 }
1255 1267
1256 void PagedSpace::SetAllocationInfo(Address top, Address limit) {
1257 SetTopAndLimit(top, limit);
1258 if (top != nullptr && top != limit &&
1259 heap()->incremental_marking()->black_allocation()) {
1260 Page* page = Page::FromAddress(top);
1261 page->markbits()->SetRange(page->AddressToMarkbitIndex(top),
1262 page->AddressToMarkbitIndex(limit));
1263 page->IncrementLiveBytes(static_cast<int>(limit - top));
1264 }
1265 }
1266
1267 void PagedSpace::MarkAllocationInfoBlack() {
1268 DCHECK(heap()->incremental_marking()->black_allocation());
1269 Address current_top = top();
1270 Address current_limit = limit();
1271 if (current_top != nullptr && current_top != current_limit) {
1272 Page* page = Page::FromAddress(current_top);
1273 page->markbits()->SetRange(page->AddressToMarkbitIndex(current_top),
1274 page->AddressToMarkbitIndex(current_limit));
1275 page->IncrementLiveBytes(static_cast<int>(current_limit - current_top));
1276 }
1277 }
1278
1279 // Empty space allocation info, returning unused area to free list.
1280 void PagedSpace::EmptyAllocationInfo() {
1281 // Mark the old linear allocation area with a free space map so it can be
1282 // skipped when scanning the heap.
1283 Address current_top = top();
1284 Address current_limit = limit();
1285 if (current_top == nullptr) {
1286 DCHECK(current_limit == nullptr);
1287 return;
1288 }
1289 int old_linear_size = static_cast<int>(current_limit - current_top);
1290 SetTopAndLimit(NULL, NULL);
1291 if (current_top != current_limit &&
1292 heap()->incremental_marking()->black_allocation()) {
1293 Page* page = Page::FromAddress(current_top);
1294 page->markbits()->ClearRange(page->AddressToMarkbitIndex(current_top),
1295 page->AddressToMarkbitIndex(current_limit));
1296 page->IncrementLiveBytes(-static_cast<int>(current_limit - current_top));
1297 }
1298 Free(current_top, old_linear_size);
1299 }
1300 1268
1301 void PagedSpace::IncreaseCapacity(int size) { 1269 void PagedSpace::IncreaseCapacity(int size) {
1302 accounting_stats_.ExpandSpace(size); 1270 accounting_stats_.ExpandSpace(size);
1303 } 1271 }
1304 1272
1305 void PagedSpace::ReleasePage(Page* page) { 1273 void PagedSpace::ReleasePage(Page* page) {
1306 DCHECK_EQ(page->LiveBytes(), 0); 1274 DCHECK_EQ(page->LiveBytes(), 0);
1307 DCHECK_EQ(AreaSize(), page->area_size()); 1275 DCHECK_EQ(AreaSize(), page->area_size());
1308 DCHECK_EQ(page->owner(), this); 1276 DCHECK_EQ(page->owner(), this);
1309 1277
(...skipping 46 matching lines...) Expand 10 before | Expand all | Expand 10 after
1356 1324
1357 // Perform space-specific object verification. 1325 // Perform space-specific object verification.
1358 VerifyObject(object); 1326 VerifyObject(object);
1359 1327
1360 // The object itself should look OK. 1328 // The object itself should look OK.
1361 object->ObjectVerify(); 1329 object->ObjectVerify();
1362 1330
1363 // All the interior pointers should be contained in the heap. 1331 // All the interior pointers should be contained in the heap.
1364 int size = object->Size(); 1332 int size = object->Size();
1365 object->IterateBody(map->instance_type(), size, visitor); 1333 object->IterateBody(map->instance_type(), size, visitor);
1366 if (Marking::IsBlack(ObjectMarking::MarkBitFrom(object))) { 1334 if (!page->IsFlagSet(Page::BLACK_PAGE) &&
1335 Marking::IsBlack(ObjectMarking::MarkBitFrom(object))) {
1367 black_size += size; 1336 black_size += size;
1368 } 1337 }
1369 1338
1370 CHECK(object->address() + size <= top); 1339 CHECK(object->address() + size <= top);
1371 end_of_previous_object = object->address() + size; 1340 end_of_previous_object = object->address() + size;
1372 } 1341 }
1373 CHECK_LE(black_size, page->LiveBytes()); 1342 CHECK_LE(black_size, page->LiveBytes());
1374 } 1343 }
1375 CHECK(allocation_pointer_found_in_space); 1344 CHECK(allocation_pointer_found_in_space);
1376 } 1345 }
(...skipping 1076 matching lines...) Expand 10 before | Expand all | Expand 10 after
2453 DCHECK(0 < size_in_bytes); 2422 DCHECK(0 < size_in_bytes);
2454 DCHECK(size_in_bytes <= kMaxBlockSize); 2423 DCHECK(size_in_bytes <= kMaxBlockSize);
2455 DCHECK(IsAligned(size_in_bytes, kPointerSize)); 2424 DCHECK(IsAligned(size_in_bytes, kPointerSize));
2456 // Don't free list allocate if there is linear space available. 2425 // Don't free list allocate if there is linear space available.
2457 DCHECK(owner_->limit() - owner_->top() < size_in_bytes); 2426 DCHECK(owner_->limit() - owner_->top() < size_in_bytes);
2458 2427
2459 int old_linear_size = static_cast<int>(owner_->limit() - owner_->top()); 2428 int old_linear_size = static_cast<int>(owner_->limit() - owner_->top());
2460 // Mark the old linear allocation area with a free space map so it can be 2429 // Mark the old linear allocation area with a free space map so it can be
2461 // skipped when scanning the heap. This also puts it back in the free list 2430 // skipped when scanning the heap. This also puts it back in the free list
2462 // if it is big enough. 2431 // if it is big enough.
2463 owner_->EmptyAllocationInfo(); 2432 owner_->Free(owner_->top(), old_linear_size);
2433 owner_->SetTopAndLimit(nullptr, nullptr);
2464 2434
2465 owner_->heap()->incremental_marking()->OldSpaceStep(size_in_bytes - 2435 owner_->heap()->incremental_marking()->OldSpaceStep(size_in_bytes -
2466 old_linear_size); 2436 old_linear_size);
2467 2437
2468 int new_node_size = 0; 2438 int new_node_size = 0;
2469 FreeSpace* new_node = FindNodeFor(size_in_bytes, &new_node_size); 2439 FreeSpace* new_node = FindNodeFor(size_in_bytes, &new_node_size);
2470 if (new_node == nullptr) return nullptr; 2440 if (new_node == nullptr) return nullptr;
2471 2441
2472 int bytes_left = new_node_size - size_in_bytes; 2442 int bytes_left = new_node_size - size_in_bytes;
2473 DCHECK(bytes_left >= 0); 2443 DCHECK(bytes_left >= 0);
(...skipping 13 matching lines...) Expand all
2487 const int kThreshold = IncrementalMarking::kAllocatedThreshold; 2457 const int kThreshold = IncrementalMarking::kAllocatedThreshold;
2488 2458
2489 // Memory in the linear allocation area is counted as allocated. We may free 2459 // Memory in the linear allocation area is counted as allocated. We may free
2490 // a little of this again immediately - see below. 2460 // a little of this again immediately - see below.
2491 owner_->Allocate(new_node_size); 2461 owner_->Allocate(new_node_size);
2492 2462
2493 if (owner_->heap()->inline_allocation_disabled()) { 2463 if (owner_->heap()->inline_allocation_disabled()) {
2494 // Keep the linear allocation area empty if requested to do so, just 2464 // Keep the linear allocation area empty if requested to do so, just
2495 // return area back to the free list instead. 2465 // return area back to the free list instead.
2496 owner_->Free(new_node->address() + size_in_bytes, bytes_left); 2466 owner_->Free(new_node->address() + size_in_bytes, bytes_left);
2497 owner_->SetAllocationInfo(new_node->address() + size_in_bytes, 2467 owner_->SetTopAndLimit(new_node->address() + size_in_bytes,
2498 new_node->address() + size_in_bytes); 2468 new_node->address() + size_in_bytes);
2499 } else if (bytes_left > kThreshold && 2469 } else if (bytes_left > kThreshold &&
2500 owner_->heap()->incremental_marking()->IsMarkingIncomplete() && 2470 owner_->heap()->incremental_marking()->IsMarkingIncomplete() &&
2501 FLAG_incremental_marking) { 2471 FLAG_incremental_marking) {
2502 int linear_size = owner_->RoundSizeDownToObjectAlignment(kThreshold); 2472 int linear_size = owner_->RoundSizeDownToObjectAlignment(kThreshold);
2503 // We don't want to give too large linear areas to the allocator while 2473 // We don't want to give too large linear areas to the allocator while
2504 // incremental marking is going on, because we won't check again whether 2474 // incremental marking is going on, because we won't check again whether
2505 // we want to do another increment until the linear area is used up. 2475 // we want to do another increment until the linear area is used up.
2506 owner_->Free(new_node->address() + size_in_bytes + linear_size, 2476 owner_->Free(new_node->address() + size_in_bytes + linear_size,
2507 new_node_size - size_in_bytes - linear_size); 2477 new_node_size - size_in_bytes - linear_size);
2508 owner_->SetAllocationInfo( 2478 owner_->SetTopAndLimit(new_node->address() + size_in_bytes,
2509 new_node->address() + size_in_bytes, 2479 new_node->address() + size_in_bytes + linear_size);
2510 new_node->address() + size_in_bytes + linear_size);
2511 } else { 2480 } else {
2512 DCHECK(bytes_left >= 0); 2481 DCHECK(bytes_left >= 0);
2513 // Normally we give the rest of the node to the allocator as its new 2482 // Normally we give the rest of the node to the allocator as its new
2514 // linear allocation area. 2483 // linear allocation area.
2515 owner_->SetAllocationInfo(new_node->address() + size_in_bytes, 2484 owner_->SetTopAndLimit(new_node->address() + size_in_bytes,
2516 new_node->address() + new_node_size); 2485 new_node->address() + new_node_size);
2517 } 2486 }
2518 2487
2519 owner_->AllocationStep(new_node->address(), size_in_bytes); 2488 owner_->AllocationStep(new_node->address(), size_in_bytes);
2520 2489
2521 return new_node; 2490 return new_node;
2522 } 2491 }
2523 2492
2524 intptr_t FreeList::EvictFreeListItems(Page* page) { 2493 intptr_t FreeList::EvictFreeListItems(Page* page) {
2525 intptr_t sum = 0; 2494 intptr_t sum = 0;
2526 page->ForAllFreeListCategories( 2495 page->ForAllFreeListCategories(
(...skipping 369 matching lines...) Expand 10 before | Expand all | Expand 10 after
2896 if (Heap::ShouldZapGarbage()) { 2865 if (Heap::ShouldZapGarbage()) {
2897 // Make the object consistent so the heap can be verified in OldSpaceStep. 2866 // Make the object consistent so the heap can be verified in OldSpaceStep.
2898 // We only need to do this in debug builds or if verify_heap is on. 2867 // We only need to do this in debug builds or if verify_heap is on.
2899 reinterpret_cast<Object**>(object->address())[0] = 2868 reinterpret_cast<Object**>(object->address())[0] =
2900 heap()->fixed_array_map(); 2869 heap()->fixed_array_map();
2901 reinterpret_cast<Object**>(object->address())[1] = Smi::FromInt(0); 2870 reinterpret_cast<Object**>(object->address())[1] = Smi::FromInt(0);
2902 } 2871 }
2903 2872
2904 heap()->incremental_marking()->OldSpaceStep(object_size); 2873 heap()->incremental_marking()->OldSpaceStep(object_size);
2905 AllocationStep(object->address(), object_size); 2874 AllocationStep(object->address(), object_size);
2906
2907 if (heap()->incremental_marking()->black_allocation()) {
2908 Marking::MarkBlack(ObjectMarking::MarkBitFrom(object));
2909 MemoryChunk::IncrementLiveBytesFromGC(object, object_size);
2910 }
2911 return object; 2875 return object;
2912 } 2876 }
2913 2877
2914 2878
2915 size_t LargeObjectSpace::CommittedPhysicalMemory() { 2879 size_t LargeObjectSpace::CommittedPhysicalMemory() {
2916 // On a platform that provides lazy committing of memory, we over-account 2880 // On a platform that provides lazy committing of memory, we over-account
2917 // the actually committed memory. There is no easy way right now to support 2881 // the actually committed memory. There is no easy way right now to support
2918 // precise accounting of committed memory in large object space. 2882 // precise accounting of committed memory in large object space.
2919 return CommittedMemory(); 2883 return CommittedMemory();
2920 } 2884 }
(...skipping 213 matching lines...) Expand 10 before | Expand all | Expand 10 after
3134 object->ShortPrint(); 3098 object->ShortPrint();
3135 PrintF("\n"); 3099 PrintF("\n");
3136 } 3100 }
3137 printf(" --------------------------------------\n"); 3101 printf(" --------------------------------------\n");
3138 printf(" Marked: %x, LiveCount: %x\n", mark_size, LiveBytes()); 3102 printf(" Marked: %x, LiveCount: %x\n", mark_size, LiveBytes());
3139 } 3103 }
3140 3104
3141 #endif // DEBUG 3105 #endif // DEBUG
3142 } // namespace internal 3106 } // namespace internal
3143 } // namespace v8 3107 } // namespace v8
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