// Copyright 2012 the V8 project authors. All rights reserved. // Use of this source code is governed by a BSD-style license that can be // found in the LICENSE file. #include #include "include/libplatform/libplatform.h" #include "include/v8.h" #include "src/execution/frames.h" #include "src/execution/isolate.h" #include "src/heap/heap-inl.h" #include "src/heap/paged-spaces-inl.h" #include "src/heap/read-only-heap.h" #include "src/heap/spaces.h" #include "src/objects/objects-inl.h" namespace v8 { static const char* kHeader = "# Copyright 2019 the V8 project authors. All rights reserved.\n" "# Use of this source code is governed by a BSD-style license that can\n" "# be found in the LICENSE file.\n" "\n" "# This file is automatically generated by mkgrokdump and should not\n" "# be modified manually.\n" "\n" "# List of known V8 instance types.\n"; // Debug builds emit debug code, affecting code object sizes. #ifndef DEBUG static const char* kBuild = "shipping"; #else static const char* kBuild = "non-shipping"; #endif class MockArrayBufferAllocator : public v8::ArrayBuffer::Allocator { public: void* Allocate(size_t length) override { return nullptr; } void* AllocateUninitialized(size_t length) override { return nullptr; } void Free(void* p, size_t) override {} }; static void DumpKnownMap(FILE* out, i::Heap* heap, const char* space_name, i::HeapObject object) { #define RO_ROOT_LIST_CASE(type, name, CamelName) \ if (root_name == nullptr && object == roots.name()) root_name = #CamelName; #define MUTABLE_ROOT_LIST_CASE(type, name, CamelName) \ if (root_name == nullptr && object == heap->name()) root_name = #CamelName; i::ReadOnlyRoots roots(heap); const char* root_name = nullptr; i::Map map = i::Map::cast(object); intptr_t root_ptr = static_cast(map.ptr()) & (i::Page::kPageSize - 1); READ_ONLY_ROOT_LIST(RO_ROOT_LIST_CASE) MUTABLE_ROOT_LIST(MUTABLE_ROOT_LIST_CASE) if (root_name == nullptr) return; i::PrintF(out, " (\"%s\", 0x%05" V8PRIxPTR "): (%d, \"%s\"),\n", space_name, root_ptr, map.instance_type(), root_name); #undef MUTABLE_ROOT_LIST_CASE #undef RO_ROOT_LIST_CASE } static void DumpKnownObject(FILE* out, i::Heap* heap, const char* space_name, i::HeapObject object) { #define RO_ROOT_LIST_CASE(type, name, CamelName) \ if (root_name == nullptr && object == roots.name()) { \ root_name = #CamelName; \ root_index = i::RootIndex::k##CamelName; \ } #define ROOT_LIST_CASE(type, name, CamelName) \ if (root_name == nullptr && object == heap->name()) { \ root_name = #CamelName; \ root_index = i::RootIndex::k##CamelName; \ } i::ReadOnlyRoots roots(heap); const char* root_name = nullptr; i::RootIndex root_index = i::RootIndex::kFirstSmiRoot; intptr_t root_ptr = object.ptr() & (i::Page::kPageSize - 1); STRONG_READ_ONLY_ROOT_LIST(RO_ROOT_LIST_CASE) MUTABLE_ROOT_LIST(ROOT_LIST_CASE) if (root_name == nullptr) return; if (!i::RootsTable::IsImmortalImmovable(root_index)) return; i::PrintF(out, " (\"%s\", 0x%05" V8PRIxPTR "): \"%s\",\n", space_name, root_ptr, root_name); #undef ROOT_LIST_CASE #undef RO_ROOT_LIST_CASE } static void DumpSpaceFirstPageAddress(FILE* out, i::BaseSpace* space, i::Address first_page) { const char* name = space->name(); i::Tagged_t compressed = i::CompressTagged(first_page); uintptr_t unsigned_compressed = static_cast(compressed); i::PrintF(out, " 0x%08" V8PRIxPTR ": \"%s\",\n", unsigned_compressed, name); } template static void DumpSpaceFirstPageAddress(FILE* out, SpaceT* space) { i::Address first_page = space->FirstPageAddress(); DumpSpaceFirstPageAddress(out, space, first_page); } static int DumpHeapConstants(FILE* out, const char* argv0) { // Start up V8. std::unique_ptr platform = v8::platform::NewDefaultPlatform(); v8::V8::InitializePlatform(platform.get()); v8::V8::Initialize(); v8::V8::InitializeExternalStartupData(argv0); Isolate::CreateParams create_params; MockArrayBufferAllocator mock_arraybuffer_allocator; create_params.array_buffer_allocator = &mock_arraybuffer_allocator; Isolate* isolate = Isolate::New(create_params); { Isolate::Scope scope(isolate); i::Heap* heap = reinterpret_cast(isolate)->heap(); i::ReadOnlyHeap* read_only_heap = reinterpret_cast(isolate)->read_only_heap(); i::PrintF(out, "%s", kHeader); #define DUMP_TYPE(T) i::PrintF(out, " %d: \"%s\",\n", i::T, #T); i::PrintF(out, "INSTANCE_TYPES = {\n"); INSTANCE_TYPE_LIST(DUMP_TYPE) i::PrintF(out, "}\n"); #undef DUMP_TYPE { // Dump the KNOWN_MAP table to the console. i::PrintF(out, "\n# List of known V8 maps.\n"); i::PrintF(out, "KNOWN_MAPS = {\n"); i::ReadOnlyHeapObjectIterator ro_iterator(read_only_heap); for (i::HeapObject object = ro_iterator.Next(); !object.is_null(); object = ro_iterator.Next()) { if (!object.IsMap()) continue; DumpKnownMap(out, heap, i::BaseSpace::GetSpaceName(i::RO_SPACE), object); } i::PagedSpaceObjectIterator iterator(heap, heap->map_space()); for (i::HeapObject object = iterator.Next(); !object.is_null(); object = iterator.Next()) { if (!object.IsMap()) continue; DumpKnownMap(out, heap, i::BaseSpace::GetSpaceName(i::MAP_SPACE), object); } i::PrintF(out, "}\n"); } { // Dump the KNOWN_OBJECTS table to the console. i::PrintF(out, "\n# List of known V8 objects.\n"); i::PrintF(out, "KNOWN_OBJECTS = {\n"); i::ReadOnlyHeapObjectIterator ro_iterator(read_only_heap); for (i::HeapObject object = ro_iterator.Next(); !object.is_null(); object = ro_iterator.Next()) { // Skip read-only heap maps, they will be reported elsewhere. if (object.IsMap()) continue; DumpKnownObject(out, heap, i::BaseSpace::GetSpaceName(i::RO_SPACE), object); } i::PagedSpaceIterator spit(heap); for (i::PagedSpace* s = spit.Next(); s != nullptr; s = spit.Next()) { i::PagedSpaceObjectIterator it(heap, s); // Code objects are generally platform-dependent. if (s->identity() == i::CODE_SPACE || s->identity() == i::MAP_SPACE) continue; const char* sname = s->name(); for (i::HeapObject o = it.Next(); !o.is_null(); o = it.Next()) { DumpKnownObject(out, heap, sname, o); } } i::PrintF(out, "}\n"); } if (COMPRESS_POINTERS_BOOL) { // Dump a list of addresses for the first page of each space that contains // objects in the other tables above. This is only useful if two // assumptions hold: // 1. Those pages are positioned deterministically within the heap // reservation block during snapshot deserialization. // 2. Those pages cannot ever be moved (such as by compaction). i::PrintF(out, "\n# Lower 32 bits of first page addresses for various heap " "spaces.\n"); i::PrintF(out, "HEAP_FIRST_PAGES = {\n"); i::PagedSpaceIterator it(heap); for (i::PagedSpace* s = it.Next(); s != nullptr; s = it.Next()) { // Code page is different on Windows vs Linux (bug v8:9844), so skip it. if (s->identity() == i::CODE_SPACE) { continue; } DumpSpaceFirstPageAddress(out, s); } DumpSpaceFirstPageAddress(out, read_only_heap->read_only_space()); i::PrintF(out, "}\n"); } // Dump frame markers i::PrintF(out, "\n# List of known V8 Frame Markers.\n"); #define DUMP_MARKER(T, class) i::PrintF(out, " \"%s\",\n", #T); i::PrintF(out, "FRAME_MARKERS = (\n"); STACK_FRAME_TYPE_LIST(DUMP_MARKER) i::PrintF(out, ")\n"); #undef DUMP_MARKER } i::PrintF(out, "\n# This set of constants is generated from a %s build.\n", kBuild); // Teardown. isolate->Dispose(); v8::V8::ShutdownPlatform(); return 0; } } // namespace v8 int main(int argc, char* argv[]) { FILE* out = stdout; if (argc > 2 && strcmp(argv[1], "--outfile") == 0) { out = fopen(argv[2], "wb"); } return v8::DumpHeapConstants(out, argv[0]); }