Commit d937a0bb authored by Seth Brenith's avatar Seth Brenith Committed by V8 LUCI CQ

Add verifier for retaining paths in heap snapshots

The web app owner who notified me about bugs v8:12112 and v8:12126 asked
me a reasonable question: "how am I ever supposed to trust the retaining
paths in the devtools, if the heap snapshot is generated by a different
component than the actual marking code?". This change is my attempt to
answer that question. If verification is enabled, the heap snapshot
generator will visit each heap object with a realistic marking visitor
to find all references from that object. It will then check that those
references match the HeapGraphEdges in the snapshot.

I also considered the idea that we could collect retaining information
during the last GC cycle before taking the heap snapshot, or during an
extra GC cycle immediately after. However, running the full GC provides
the embedder with the opportunity to run arbitrary code (including JS)
both before and after PerformGarbageCollection, so there is no clear
guarantee that the heap state during the snapshot actually matches the
heap state during marking.

Bug: v8:12112, v8:12126
Change-Id: Id29e75ecf9eee19e35daedbdb4a3e1df64785380
Reviewed-on: https://chromium-review.googlesource.com/c/v8/v8/+/3299590Reviewed-by: 's avatarMichael Lippautz <mlippautz@chromium.org>
Reviewed-by: 's avatarCamillo Bruni <cbruni@chromium.org>
Commit-Queue: Seth Brenith <seth.brenith@microsoft.com>
Cr-Commit-Position: refs/heads/main@{#78952}
parent 2ce2c9c7
...@@ -342,6 +342,9 @@ declare_args() { ...@@ -342,6 +342,9 @@ declare_args() {
# When it's disabled, the --turbo-allocation-folding runtime flag will be ignored. # When it's disabled, the --turbo-allocation-folding runtime flag will be ignored.
v8_enable_allocation_folding = true v8_enable_allocation_folding = true
# Enable runtime verification of heap snapshots produced for devtools.
v8_enable_heap_snapshot_verify = ""
# Enable global allocation site tracking. # Enable global allocation site tracking.
v8_allocation_site_tracking = true v8_allocation_site_tracking = true
...@@ -385,6 +388,10 @@ if (v8_enable_test_features == "") { ...@@ -385,6 +388,10 @@ if (v8_enable_test_features == "") {
if (v8_enable_v8_checks == "") { if (v8_enable_v8_checks == "") {
v8_enable_v8_checks = v8_enable_debugging_features v8_enable_v8_checks = v8_enable_debugging_features
} }
if (v8_enable_heap_snapshot_verify == "") {
v8_enable_heap_snapshot_verify =
v8_enable_debugging_features || dcheck_always_on
}
if (v8_enable_snapshot_code_comments) { if (v8_enable_snapshot_code_comments) {
assert(v8_code_comments == true || v8_code_comments == "", assert(v8_code_comments == true || v8_code_comments == "",
"v8_enable_snapshot_code_comments conflicts with v8_code_comments.") "v8_enable_snapshot_code_comments conflicts with v8_code_comments.")
...@@ -891,6 +898,9 @@ config("features") { ...@@ -891,6 +898,9 @@ config("features") {
if (v8_enable_debug_code) { if (v8_enable_debug_code) {
defines += [ "V8_ENABLE_DEBUG_CODE" ] defines += [ "V8_ENABLE_DEBUG_CODE" ]
} }
if (v8_enable_heap_snapshot_verify) {
defines += [ "V8_ENABLE_HEAP_SNAPSHOT_VERIFY" ]
}
if (v8_enable_snapshot_native_code_counters) { if (v8_enable_snapshot_native_code_counters) {
defines += [ "V8_SNAPSHOT_NATIVE_CODE_COUNTERS" ] defines += [ "V8_SNAPSHOT_NATIVE_CODE_COUNTERS" ]
} }
...@@ -3572,6 +3582,10 @@ v8_header_set("v8_internal_headers") { ...@@ -3572,6 +3582,10 @@ v8_header_set("v8_internal_headers") {
] ]
} }
if (v8_enable_heap_snapshot_verify) {
sources += [ "src/heap/reference-summarizer.h" ]
}
if (v8_current_cpu == "x86") { if (v8_current_cpu == "x86") {
sources += [ ### gcmole(arch:ia32) ### sources += [ ### gcmole(arch:ia32) ###
"src/baseline/ia32/baseline-assembler-ia32-inl.h", "src/baseline/ia32/baseline-assembler-ia32-inl.h",
...@@ -4513,6 +4527,10 @@ v8_source_set("v8_base_without_compiler") { ...@@ -4513,6 +4527,10 @@ v8_source_set("v8_base_without_compiler") {
] ]
} }
if (v8_enable_heap_snapshot_verify) {
sources += [ "src/heap/reference-summarizer.cc" ]
}
if (v8_current_cpu == "x86") { if (v8_current_cpu == "x86") {
sources += [ ### gcmole(arch:ia32) ### sources += [ ### gcmole(arch:ia32) ###
"src/codegen/ia32/assembler-ia32.cc", "src/codegen/ia32/assembler-ia32.cc",
......
...@@ -36,6 +36,7 @@ include_rules = [ ...@@ -36,6 +36,7 @@ include_rules = [
"+src/heap/parked-scope.h", "+src/heap/parked-scope.h",
"+src/heap/read-only-heap-inl.h", "+src/heap/read-only-heap-inl.h",
"+src/heap/read-only-heap.h", "+src/heap/read-only-heap.h",
"+src/heap/reference-summarizer.h",
"+src/heap/safepoint.h", "+src/heap/safepoint.h",
"+src/heap/base/stack.h", "+src/heap/base/stack.h",
"+src/heap/conservative-stack-visitor.h", "+src/heap/conservative-stack-visitor.h",
......
...@@ -1618,6 +1618,11 @@ DEFINE_INT(heap_snapshot_string_limit, 1024, ...@@ -1618,6 +1618,11 @@ DEFINE_INT(heap_snapshot_string_limit, 1024,
"truncate strings to this length in the heap snapshot") "truncate strings to this length in the heap snapshot")
DEFINE_BOOL(heap_profiler_show_hidden_objects, false, DEFINE_BOOL(heap_profiler_show_hidden_objects, false,
"use 'native' rather than 'hidden' node type in snapshot") "use 'native' rather than 'hidden' node type in snapshot")
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
DEFINE_BOOL(heap_snapshot_verify, false,
"verify that heap snapshot matches marking visitor behavior")
DEFINE_IMPLICATION(enable_slow_asserts, heap_snapshot_verify)
#endif
// sampling-heap-profiler.cc // sampling-heap-profiler.cc
DEFINE_BOOL(sampling_heap_profiler_suppress_randomness, false, DEFINE_BOOL(sampling_heap_profiler_suppress_randomness, false,
......
...@@ -26,6 +26,7 @@ void MarkingVisitorBase<ConcreteVisitor, MarkingState>::MarkObject( ...@@ -26,6 +26,7 @@ void MarkingVisitorBase<ConcreteVisitor, MarkingState>::MarkObject(
HeapObject host, HeapObject object) { HeapObject host, HeapObject object) {
DCHECK(ReadOnlyHeap::Contains(object) || heap_->Contains(object)); DCHECK(ReadOnlyHeap::Contains(object) || heap_->Contains(object));
concrete_visitor()->SynchronizePageAccess(object); concrete_visitor()->SynchronizePageAccess(object);
AddStrongReferenceForReferenceSummarizer(host, object);
if (concrete_visitor()->marking_state()->WhiteToGrey(object)) { if (concrete_visitor()->marking_state()->WhiteToGrey(object)) {
local_marking_worklists_->Push(object); local_marking_worklists_->Push(object);
if (V8_UNLIKELY(concrete_visitor()->retaining_path_mode() == if (V8_UNLIKELY(concrete_visitor()->retaining_path_mode() ==
...@@ -65,6 +66,7 @@ void MarkingVisitorBase<ConcreteVisitor, MarkingState>::ProcessWeakHeapObject( ...@@ -65,6 +66,7 @@ void MarkingVisitorBase<ConcreteVisitor, MarkingState>::ProcessWeakHeapObject(
// the reference when we know the liveness of the whole transitive // the reference when we know the liveness of the whole transitive
// closure. // closure.
local_weak_objects_->weak_references_local.Push(std::make_pair(host, slot)); local_weak_objects_->weak_references_local.Push(std::make_pair(host, slot));
AddWeakReferenceForReferenceSummarizer(host, heap_object);
} }
} }
...@@ -117,6 +119,7 @@ void MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitEmbeddedPointer( ...@@ -117,6 +119,7 @@ void MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitEmbeddedPointer(
if (host.IsWeakObject(object)) { if (host.IsWeakObject(object)) {
local_weak_objects_->weak_objects_in_code_local.Push( local_weak_objects_->weak_objects_in_code_local.Push(
std::make_pair(object, host)); std::make_pair(object, host));
AddWeakReferenceForReferenceSummarizer(host, object);
} else { } else {
MarkObject(host, object); MarkObject(host, object);
} }
...@@ -244,7 +247,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitFixedArray( ...@@ -244,7 +247,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitFixedArray(
// in the large object space. // in the large object space.
ProgressBar& progress_bar = ProgressBar& progress_bar =
MemoryChunk::FromHeapObject(object)->ProgressBar(); MemoryChunk::FromHeapObject(object)->ProgressBar();
return progress_bar.IsEnabled() return CanUpdateValuesInHeap() && progress_bar.IsEnabled()
? VisitFixedArrayWithProgressBar(map, object, progress_bar) ? VisitFixedArrayWithProgressBar(map, object, progress_bar)
: concrete_visitor()->VisitLeftTrimmableArray(map, object); : concrete_visitor()->VisitLeftTrimmableArray(map, object);
} }
...@@ -344,6 +347,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitEphemeronHashTable( ...@@ -344,6 +347,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitEphemeronHashTable(
concrete_visitor()->SynchronizePageAccess(key); concrete_visitor()->SynchronizePageAccess(key);
concrete_visitor()->RecordSlot(table, key_slot, key); concrete_visitor()->RecordSlot(table, key_slot, key);
AddWeakReferenceForReferenceSummarizer(table, key);
ObjectSlot value_slot = ObjectSlot value_slot =
table.RawFieldOfElementAt(EphemeronHashTable::EntryToValueIndex(i)); table.RawFieldOfElementAt(EphemeronHashTable::EntryToValueIndex(i));
...@@ -357,6 +361,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitEphemeronHashTable( ...@@ -357,6 +361,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitEphemeronHashTable(
HeapObject value = HeapObject::cast(value_obj); HeapObject value = HeapObject::cast(value_obj);
concrete_visitor()->SynchronizePageAccess(value); concrete_visitor()->SynchronizePageAccess(value);
concrete_visitor()->RecordSlot(table, value_slot, value); concrete_visitor()->RecordSlot(table, value_slot, value);
AddWeakReferenceForReferenceSummarizer(table, value);
// Revisit ephemerons with both key and value unreachable at end // Revisit ephemerons with both key and value unreachable at end
// of concurrent marking cycle. // of concurrent marking cycle.
...@@ -387,6 +392,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitJSWeakRef( ...@@ -387,6 +392,7 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitJSWeakRef(
// JSWeakRef points to a potentially dead object. We have to process // JSWeakRef points to a potentially dead object. We have to process
// them when we know the liveness of the whole transitive closure. // them when we know the liveness of the whole transitive closure.
local_weak_objects_->js_weak_refs_local.Push(weak_ref); local_weak_objects_->js_weak_refs_local.Push(weak_ref);
AddWeakReferenceForReferenceSummarizer(weak_ref, target);
} }
} }
return size; return size;
...@@ -417,6 +423,8 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitWeakCell( ...@@ -417,6 +423,8 @@ int MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitWeakCell(
// token. We have to process them when we know the liveness of the whole // token. We have to process them when we know the liveness of the whole
// transitive closure. // transitive closure.
local_weak_objects_->weak_cells_local.Push(weak_cell); local_weak_objects_->weak_cells_local.Push(weak_cell);
AddWeakReferenceForReferenceSummarizer(weak_cell, target);
AddWeakReferenceForReferenceSummarizer(weak_cell, unregister_token);
} }
return size; return size;
} }
...@@ -443,8 +451,11 @@ template <typename ConcreteVisitor, typename MarkingState> ...@@ -443,8 +451,11 @@ template <typename ConcreteVisitor, typename MarkingState>
void MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitDescriptors( void MarkingVisitorBase<ConcreteVisitor, MarkingState>::VisitDescriptors(
DescriptorArray descriptor_array, int number_of_own_descriptors) { DescriptorArray descriptor_array, int number_of_own_descriptors) {
int16_t new_marked = static_cast<int16_t>(number_of_own_descriptors); int16_t new_marked = static_cast<int16_t>(number_of_own_descriptors);
int16_t old_marked = descriptor_array.UpdateNumberOfMarkedDescriptors( int16_t old_marked = 0;
mark_compact_epoch_, new_marked); if (CanUpdateValuesInHeap()) {
old_marked = descriptor_array.UpdateNumberOfMarkedDescriptors(
mark_compact_epoch_, new_marked);
}
if (old_marked < new_marked) { if (old_marked < new_marked) {
VisitPointers( VisitPointers(
descriptor_array, descriptor_array,
......
...@@ -25,6 +25,11 @@ struct EphemeronMarking { ...@@ -25,6 +25,11 @@ struct EphemeronMarking {
template <typename ConcreteState, AccessMode access_mode> template <typename ConcreteState, AccessMode access_mode>
class MarkingStateBase { class MarkingStateBase {
public: public:
// Declares that this marking state is not collecting retainers, so the
// marking visitor may update the heap state to store information about
// progress, and may avoid fully visiting an object if it is safe to do so.
static constexpr bool kCollectRetainers = false;
explicit MarkingStateBase(PtrComprCageBase cage_base) explicit MarkingStateBase(PtrComprCageBase cage_base)
#if V8_COMPRESS_POINTERS #if V8_COMPRESS_POINTERS
: cage_base_(cage_base) : cage_base_(cage_base)
...@@ -102,6 +107,15 @@ class MarkingStateBase { ...@@ -102,6 +107,15 @@ class MarkingStateBase {
static_cast<ConcreteState*>(this)->SetLiveBytes(chunk, 0); static_cast<ConcreteState*>(this)->SetLiveBytes(chunk, 0);
} }
void AddStrongReferenceForReferenceSummarizer(HeapObject host,
HeapObject obj) {
// This is not a reference summarizer, so there is nothing to do here.
}
void AddWeakReferenceForReferenceSummarizer(HeapObject host, HeapObject obj) {
// This is not a reference summarizer, so there is nothing to do here.
}
private: private:
#if V8_COMPRESS_POINTERS #if V8_COMPRESS_POINTERS
const PtrComprCageBase cage_base_; const PtrComprCageBase cage_base_;
...@@ -258,6 +272,23 @@ class MarkingVisitorBase : public HeapVisitor<int, ConcreteVisitor> { ...@@ -258,6 +272,23 @@ class MarkingVisitorBase : public HeapVisitor<int, ConcreteVisitor> {
// Marks the object grey and pushes it on the marking work list. // Marks the object grey and pushes it on the marking work list.
V8_INLINE void MarkObject(HeapObject host, HeapObject obj); V8_INLINE void MarkObject(HeapObject host, HeapObject obj);
V8_INLINE void AddStrongReferenceForReferenceSummarizer(HeapObject host,
HeapObject obj) {
concrete_visitor()
->marking_state()
->AddStrongReferenceForReferenceSummarizer(host, obj);
}
V8_INLINE void AddWeakReferenceForReferenceSummarizer(HeapObject host,
HeapObject obj) {
concrete_visitor()->marking_state()->AddWeakReferenceForReferenceSummarizer(
host, obj);
}
constexpr bool CanUpdateValuesInHeap() {
return !MarkingState::kCollectRetainers;
}
MarkingWorklists::Local* const local_marking_worklists_; MarkingWorklists::Local* const local_marking_worklists_;
WeakObjects::Local* const local_weak_objects_; WeakObjects::Local* const local_weak_objects_;
Heap* const heap_; Heap* const heap_;
......
// Copyright 2022 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 "src/heap/reference-summarizer.h"
#include "src/heap/mark-compact-inl.h"
#include "src/heap/marking-visitor-inl.h"
#include "src/objects/embedder-data-array-inl.h"
#include "src/objects/js-array-buffer-inl.h"
namespace v8 {
namespace internal {
namespace {
// A class which acts as a MarkingState but does not actually update any marking
// bits. It reports all objects as white and all transitions as successful. It
// also tracks which objects are retained by the primary object according to the
// marking visitor.
class ReferenceSummarizerMarkingState final {
public:
// Declares that this marking state is collecting retainers, so the marking
// visitor must fully visit each object and can't update on-heap state.
static constexpr bool kCollectRetainers = true;
explicit ReferenceSummarizerMarkingState(HeapObject object)
: primary_object_(object),
local_marking_worklists_(&marking_worklists_),
local_weak_objects_(&weak_objects_) {}
~ReferenceSummarizerMarkingState() {
// Clean up temporary state.
local_weak_objects_.Publish();
weak_objects_.Clear();
local_marking_worklists_.Publish();
marking_worklists_.Clear();
}
// Retrieves the references that were collected by this marker. This operation
// transfers ownership of the set, so calling it again would yield an empty
// result.
ReferenceSummary DestructivelyRetrieveReferences() {
ReferenceSummary tmp = std::move(references_);
references_.Clear();
return tmp;
}
// Standard marking visitor functions:
bool IsWhite(HeapObject obj) const { return true; }
bool IsBlackOrGrey(HeapObject obj) const { return false; }
bool WhiteToGrey(HeapObject obj) { return true; }
bool GreyToBlack(HeapObject obj) { return true; }
// Adds a retaining relationship found by the marking visitor.
void AddStrongReferenceForReferenceSummarizer(HeapObject host,
HeapObject obj) {
AddReference(host, obj, references_.strong_references());
}
// Adds a non-retaining weak reference found by the marking visitor. The value
// in an ephemeron hash table entry is also included here, since it is not
// known to be strong without further information about the key.
void AddWeakReferenceForReferenceSummarizer(HeapObject host, HeapObject obj) {
AddReference(host, obj, references_.weak_references());
}
// Other member functions, not part of the marking visitor contract:
MarkingWorklists::Local* local_marking_worklists() {
return &local_marking_worklists_;
}
WeakObjects::Local* local_weak_objects() { return &local_weak_objects_; }
private:
void AddReference(
HeapObject host, HeapObject obj,
std::unordered_set<HeapObject, Object::Hasher>& references) {
// It's possible that the marking visitor handles multiple objects at once,
// such as a Map and its DescriptorArray, but we're only interested in
// references from the primary object.
if (host == primary_object_) {
references.insert(obj);
}
}
ReferenceSummary references_;
HeapObject primary_object_;
MarkingWorklists marking_worklists_;
MarkingWorklists::Local local_marking_worklists_;
WeakObjects weak_objects_;
WeakObjects::Local local_weak_objects_;
};
} // namespace
ReferenceSummary ReferenceSummary::SummarizeReferencesFrom(Heap* heap,
HeapObject obj) {
ReferenceSummarizerMarkingState marking_state(obj);
MainMarkingVisitor<ReferenceSummarizerMarkingState> visitor(
&marking_state, marking_state.local_marking_worklists(),
marking_state.local_weak_objects(), heap, 0 /*mark_compact_epoch*/,
{} /*code_flush_mode*/, false /*embedder_tracing_enabled*/,
true /*should_keep_ages_unchanged*/);
visitor.Visit(obj.map(heap->isolate()), obj);
return marking_state.DestructivelyRetrieveReferences();
}
} // namespace internal
} // namespace v8
// Copyright 2022 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.
#ifndef V8_HEAP_REFERENCE_SUMMARIZER_H_
#define V8_HEAP_REFERENCE_SUMMARIZER_H_
#include <unordered_set>
#include "src/objects/heap-object.h"
namespace v8 {
namespace internal {
class Heap;
class ReferenceSummary {
public:
ReferenceSummary() = default;
ReferenceSummary(ReferenceSummary&& other) V8_NOEXCEPT
: strong_references_(std::move(other.strong_references_)),
weak_references_(std::move(other.weak_references_)) {}
// Produces a set of objects referred to by the object. This function uses a
// realistic marking visitor, so its results are likely to match real GC
// behavior. Intended only for verification.
static ReferenceSummary SummarizeReferencesFrom(Heap* heap, HeapObject obj);
// All objects which the chosen object has strong pointers to.
std::unordered_set<HeapObject, Object::Hasher>& strong_references() {
return strong_references_;
}
// All objects which the chosen object has weak pointers to. The values in
// ephemeron hash tables are also included here, even though they aren't
// normal weak pointers.
std::unordered_set<HeapObject, Object::Hasher>& weak_references() {
return weak_references_;
}
void Clear() {
strong_references_.clear();
weak_references_.clear();
}
private:
std::unordered_set<HeapObject, Object::Hasher> strong_references_;
std::unordered_set<HeapObject, Object::Hasher> weak_references_;
DISALLOW_GARBAGE_COLLECTION(no_gc)
};
} // namespace internal
} // namespace v8
#endif // V8_HEAP_REFERENCE_SUMMARIZER_H_
...@@ -42,6 +42,152 @@ ...@@ -42,6 +42,152 @@
namespace v8 { namespace v8 {
namespace internal { namespace internal {
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
class HeapEntryVerifier {
public:
HeapEntryVerifier(HeapSnapshotGenerator* generator, HeapObject obj)
: generator_(generator),
primary_object_(obj),
reference_summary_(
ReferenceSummary::SummarizeReferencesFrom(generator->heap(), obj)) {
generator->set_verifier(this);
}
~HeapEntryVerifier() {
CheckAllReferencesWereChecked();
generator_->set_verifier(nullptr);
}
// Checks that `host` retains `target`, according to the marking visitor. This
// allows us to verify, when adding edges to the snapshot, that they
// correspond to real retaining relationships.
void CheckStrongReference(HeapObject host, HeapObject target) {
// All references should be from the current primary object.
CHECK_EQ(host, primary_object_);
checked_objects_.insert(target);
// Check whether there is a direct strong reference from host to target.
if (reference_summary_.strong_references().find(target) !=
reference_summary_.strong_references().end()) {
return;
}
// There is no direct reference from host to target, but sometimes heap
// snapshots include references that skip one, two, or three objects, such
// as __proto__ on a JSObject referring to its Map's prototype, or a
// property getter that bypasses the property array and accessor info. At
// this point, we must check for those indirect references.
for (size_t level = 0; level < 3; ++level) {
const std::unordered_set<HeapObject, Object::Hasher>& indirect =
GetIndirectStrongReferences(level);
if (indirect.find(target) != indirect.end()) {
return;
}
}
FATAL("Could not find any matching reference");
}
// Checks that `host` has a weak reference to `target`, according to the
// marking visitor.
void CheckWeakReference(HeapObject host, HeapObject target) {
// All references should be from the current primary object.
CHECK_EQ(host, primary_object_);
checked_objects_.insert(target);
CHECK_NE(reference_summary_.weak_references().find(target),
reference_summary_.weak_references().end());
}
// Marks the relationship between `host` and `target` as checked, even if the
// marking visitor found no such relationship. This is necessary for
// ephemerons, where a pair of objects is required to retain the target.
// Use this function with care, since it bypasses verification.
void MarkReferenceCheckedWithoutChecking(HeapObject host, HeapObject target) {
if (host == primary_object_) {
checked_objects_.insert(target);
}
}
// Verifies that all of the references found by the marking visitor were
// checked via a call to CheckStrongReference or CheckWeakReference, or
// deliberately skipped via a call to MarkReferenceCheckedWithoutChecking.
// This ensures that there aren't retaining relationships found by the marking
// visitor which were omitted from the heap snapshot.
void CheckAllReferencesWereChecked() {
// Both loops below skip pointers to read-only objects, because the heap
// snapshot deliberately omits many of those (see IsEssentialObject).
// Read-only objects can't ever retain normal read-write objects, so these
// are fine to skip.
for (HeapObject obj : reference_summary_.strong_references()) {
if (!BasicMemoryChunk::FromHeapObject(obj)->InReadOnlySpace()) {
CHECK_NE(checked_objects_.find(obj), checked_objects_.end());
}
}
for (HeapObject obj : reference_summary_.weak_references()) {
if (!BasicMemoryChunk::FromHeapObject(obj)->InReadOnlySpace()) {
CHECK_NE(checked_objects_.find(obj), checked_objects_.end());
}
}
}
private:
const std::unordered_set<HeapObject, Object::Hasher>&
GetIndirectStrongReferences(size_t level) {
CHECK_GE(indirect_strong_references_.size(), level);
if (indirect_strong_references_.size() == level) {
// Expansion is needed.
indirect_strong_references_.resize(level + 1);
const std::unordered_set<HeapObject, Object::Hasher>& previous =
level == 0 ? reference_summary_.strong_references()
: indirect_strong_references_[level - 1];
for (HeapObject obj : previous) {
if (BasicMemoryChunk::FromHeapObject(obj)->InReadOnlySpace()) {
// Marking visitors don't expect to visit objects in read-only space,
// and will fail DCHECKs if they are used on those objects. Read-only
// objects can never retain anything outside read-only space, so
// skipping those objects doesn't weaken verification.
continue;
}
// Indirect references should only bypass internal structures, not
// user-visible objects or contexts.
if (obj.IsJSReceiver() || obj.IsString() || obj.IsContext()) {
continue;
}
ReferenceSummary summary =
ReferenceSummary::SummarizeReferencesFrom(generator_->heap(), obj);
indirect_strong_references_[level].insert(
summary.strong_references().begin(),
summary.strong_references().end());
}
}
return indirect_strong_references_[level];
}
DISALLOW_GARBAGE_COLLECTION(no_gc)
HeapSnapshotGenerator* generator_;
HeapObject primary_object_;
// All objects referred to by primary_object_, according to a marking visitor.
ReferenceSummary reference_summary_;
// Objects that have been checked via a call to CheckStrongReference or
// CheckWeakReference, or deliberately skipped via a call to
// MarkReferenceCheckedWithoutChecking.
std::unordered_set<HeapObject, Object::Hasher> checked_objects_;
// Objects transitively retained by the primary object. The objects in the set
// at index i are retained by the primary object via a chain of i+1
// intermediate objects.
std::vector<std::unordered_set<HeapObject, Object::Hasher>>
indirect_strong_references_;
};
#endif
HeapGraphEdge::HeapGraphEdge(Type type, const char* name, HeapEntry* from, HeapGraphEdge::HeapGraphEdge(Type type, const char* name, HeapEntry* from,
HeapEntry* to) HeapEntry* to)
: bit_field_(TypeField::encode(type) | : bit_field_(TypeField::encode(type) |
...@@ -78,29 +224,84 @@ HeapEntry::HeapEntry(HeapSnapshot* snapshot, int index, Type type, ...@@ -78,29 +224,84 @@ HeapEntry::HeapEntry(HeapSnapshot* snapshot, int index, Type type,
DCHECK_GE(index, 0); DCHECK_GE(index, 0);
} }
void HeapEntry::SetNamedReference(HeapGraphEdge::Type type, void HeapEntry::VerifyReference(HeapGraphEdge::Type type, HeapEntry* entry,
const char* name, HeapSnapshotGenerator* generator,
HeapEntry* entry) { ReferenceVerification verification) {
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
if (verification == kOffHeapPointer || generator->verifier() == nullptr) {
// Off-heap pointers are outside the scope of this verification; we just
// trust the embedder to provide accurate data. If the verifier is null,
// then verification is disabled.
return;
}
if (verification == kCustomWeakPointer) {
// The caller declared that this is a weak pointer ignored by the marking
// visitor. All we can verify at this point is that the edge type declares
// it to be weak.
CHECK_EQ(type, HeapGraphEdge::kWeak);
return;
}
Address from_address =
reinterpret_cast<Address>(generator->FindHeapThingForHeapEntry(this));
Address to_address =
reinterpret_cast<Address>(generator->FindHeapThingForHeapEntry(entry));
if (from_address == kNullAddress || to_address == kNullAddress) {
// One of these entries doesn't correspond to a real heap object.
// Verification is not possible.
return;
}
HeapObject from_obj = HeapObject::cast(Object(from_address));
HeapObject to_obj = HeapObject::cast(Object(to_address));
if (BasicMemoryChunk::FromHeapObject(to_obj)->InReadOnlySpace()) {
// We can't verify pointers into read-only space, because marking visitors
// might not mark those. For example, every Map has a pointer to the
// MetaMap, but marking visitors don't bother with following that link.
// Read-only objects are immortal and can never point to things outside of
// read-only space, so ignoring these objects is safe from the perspective
// of ensuring accurate retaining paths for normal read-write objects.
// Therefore, do nothing.
} else if (verification == kEphemeron) {
// Ephemerons can't be verified because they aren't marked directly by the
// marking visitor.
generator->verifier()->MarkReferenceCheckedWithoutChecking(from_obj,
to_obj);
} else if (type == HeapGraphEdge::kWeak) {
generator->verifier()->CheckWeakReference(from_obj, to_obj);
} else {
generator->verifier()->CheckStrongReference(from_obj, to_obj);
}
#endif
}
void HeapEntry::SetNamedReference(HeapGraphEdge::Type type, const char* name,
HeapEntry* entry,
HeapSnapshotGenerator* generator,
ReferenceVerification verification) {
++children_count_; ++children_count_;
snapshot_->edges().emplace_back(type, name, this, entry); snapshot_->edges().emplace_back(type, name, this, entry);
VerifyReference(type, entry, generator, verification);
} }
void HeapEntry::SetIndexedReference(HeapGraphEdge::Type type, void HeapEntry::SetIndexedReference(HeapGraphEdge::Type type, int index,
int index, HeapEntry* entry,
HeapEntry* entry) { HeapSnapshotGenerator* generator,
ReferenceVerification verification) {
++children_count_; ++children_count_;
snapshot_->edges().emplace_back(type, index, this, entry); snapshot_->edges().emplace_back(type, index, this, entry);
VerifyReference(type, entry, generator, verification);
} }
void HeapEntry::SetNamedAutoIndexReference(HeapGraphEdge::Type type, void HeapEntry::SetNamedAutoIndexReference(HeapGraphEdge::Type type,
const char* description, const char* description,
HeapEntry* child, HeapEntry* child,
StringsStorage* names) { StringsStorage* names,
HeapSnapshotGenerator* generator,
ReferenceVerification verification) {
int index = children_count_ + 1; int index = children_count_ + 1;
const char* name = description const char* name = description
? names->GetFormatted("%d / %s", index, description) ? names->GetFormatted("%d / %s", index, description)
: names->GetName(index); : names->GetName(index);
SetNamedReference(type, name, child); SetNamedReference(type, name, child, generator, verification);
} }
void HeapEntry::Print(const char* prefix, const char* edge_name, int max_depth, void HeapEntry::Print(const char* prefix, const char* edge_name, int max_depth,
...@@ -1019,9 +1220,11 @@ void V8HeapExplorer::ExtractEphemeronHashTableReferences( ...@@ -1019,9 +1220,11 @@ void V8HeapExplorer::ExtractEphemeronHashTableReferences(
key_entry->name(), key_entry->id(), value_entry->name(), key_entry->name(), key_entry->id(), value_entry->name(),
value_entry->id(), table_entry->id()); value_entry->id(), table_entry->id());
key_entry->SetNamedAutoIndexReference(HeapGraphEdge::kInternal, edge_name, key_entry->SetNamedAutoIndexReference(HeapGraphEdge::kInternal, edge_name,
value_entry, names_); value_entry, names_, generator_,
table_entry->SetNamedAutoIndexReference(HeapGraphEdge::kInternal, HeapEntry::kEphemeron);
edge_name, value_entry, names_); table_entry->SetNamedAutoIndexReference(
HeapGraphEdge::kInternal, edge_name, value_entry, names_, generator_,
HeapEntry::kEphemeron);
} }
} }
} }
...@@ -1082,11 +1285,12 @@ void V8HeapExplorer::ExtractContextReferences(HeapEntry* entry, ...@@ -1082,11 +1285,12 @@ void V8HeapExplorer::ExtractContextReferences(HeapEntry* entry,
SetWeakReference(entry, "optimized_code_list", SetWeakReference(entry, "optimized_code_list",
context.get(Context::OPTIMIZED_CODE_LIST), context.get(Context::OPTIMIZED_CODE_LIST),
Context::OffsetOfElementAt(Context::OPTIMIZED_CODE_LIST)); Context::OffsetOfElementAt(Context::OPTIMIZED_CODE_LIST),
SetWeakReference( HeapEntry::kCustomWeakPointer);
entry, "deoptimized_code_list", SetWeakReference(entry, "deoptimized_code_list",
context.get(Context::DEOPTIMIZED_CODE_LIST), context.get(Context::DEOPTIMIZED_CODE_LIST),
Context::OffsetOfElementAt(Context::DEOPTIMIZED_CODE_LIST)); Context::OffsetOfElementAt(Context::DEOPTIMIZED_CODE_LIST),
HeapEntry::kCustomWeakPointer);
STATIC_ASSERT(Context::OPTIMIZED_CODE_LIST == Context::FIRST_WEAK_SLOT); STATIC_ASSERT(Context::OPTIMIZED_CODE_LIST == Context::FIRST_WEAK_SLOT);
STATIC_ASSERT(Context::NEXT_CONTEXT_LINK + 1 == STATIC_ASSERT(Context::NEXT_CONTEXT_LINK + 1 ==
Context::NATIVE_CONTEXT_SLOTS); Context::NATIVE_CONTEXT_SLOTS);
...@@ -1334,7 +1538,7 @@ void V8HeapExplorer::ExtractJSArrayBufferReferences(HeapEntry* entry, ...@@ -1334,7 +1538,7 @@ void V8HeapExplorer::ExtractJSArrayBufferReferences(HeapEntry* entry,
HeapEntry* data_entry = HeapEntry* data_entry =
generator_->FindOrAddEntry(buffer.backing_store(), &allocator); generator_->FindOrAddEntry(buffer.backing_store(), &allocator);
entry->SetNamedReference(HeapGraphEdge::kInternal, "backing_store", entry->SetNamedReference(HeapGraphEdge::kInternal, "backing_store",
data_entry); data_entry, generator_, HeapEntry::kOffHeapPointer);
} }
void V8HeapExplorer::ExtractJSPromiseReferences(HeapEntry* entry, void V8HeapExplorer::ExtractJSPromiseReferences(HeapEntry* entry,
...@@ -1386,7 +1590,8 @@ void V8HeapExplorer::ExtractNumberReference(HeapEntry* entry, Object number) { ...@@ -1386,7 +1590,8 @@ void V8HeapExplorer::ExtractNumberReference(HeapEntry* entry, Object number) {
SnapshotObjectId id = heap_object_map_->get_next_id(); SnapshotObjectId id = heap_object_map_->get_next_id();
HeapEntry* child_entry = HeapEntry* child_entry =
snapshot_->AddEntry(HeapEntry::kString, name, id, 0, 0); snapshot_->AddEntry(HeapEntry::kString, name, id, 0, 0);
entry->SetNamedReference(HeapGraphEdge::kInternal, "value", child_entry); entry->SetNamedReference(HeapGraphEdge::kInternal, "value", child_entry,
generator_);
} }
void V8HeapExplorer::ExtractFeedbackVectorReferences( void V8HeapExplorer::ExtractFeedbackVectorReferences(
...@@ -1694,6 +1899,18 @@ bool V8HeapExplorer::IterateAndExtractReferences( ...@@ -1694,6 +1899,18 @@ bool V8HeapExplorer::IterateAndExtractReferences(
visited_fields_.resize(max_pointer, false); visited_fields_.resize(max_pointer, false);
} }
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
std::unique_ptr<HeapEntryVerifier> verifier;
// MarkingVisitorBase doesn't expect that we will ever visit read-only
// objects, and fails DCHECKs if we attempt to. Read-only objects can
// never retain read-write objects, so there is no risk in skipping
// verification for them.
if (FLAG_heap_snapshot_verify &&
!BasicMemoryChunk::FromHeapObject(obj)->InReadOnlySpace()) {
verifier = std::make_unique<HeapEntryVerifier>(generator, obj);
}
#endif
HeapEntry* entry = GetEntry(obj); HeapEntry* entry = GetEntry(obj);
ExtractReferences(entry, obj); ExtractReferences(entry, obj);
SetInternalReference(entry, "map", obj.map(cage_base), SetInternalReference(entry, "map", obj.map(cage_base),
...@@ -1757,7 +1974,8 @@ void V8HeapExplorer::SetContextReference(HeapEntry* parent_entry, ...@@ -1757,7 +1974,8 @@ void V8HeapExplorer::SetContextReference(HeapEntry* parent_entry,
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
if (child_entry == nullptr) return; if (child_entry == nullptr) return;
parent_entry->SetNamedReference(HeapGraphEdge::kContextVariable, parent_entry->SetNamedReference(HeapGraphEdge::kContextVariable,
names_->GetName(reference_name), child_entry); names_->GetName(reference_name), child_entry,
generator_);
MarkVisitedField(field_offset); MarkVisitedField(field_offset);
} }
...@@ -1774,15 +1992,15 @@ void V8HeapExplorer::SetNativeBindReference(HeapEntry* parent_entry, ...@@ -1774,15 +1992,15 @@ void V8HeapExplorer::SetNativeBindReference(HeapEntry* parent_entry,
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
if (child_entry == nullptr) return; if (child_entry == nullptr) return;
parent_entry->SetNamedReference(HeapGraphEdge::kShortcut, reference_name, parent_entry->SetNamedReference(HeapGraphEdge::kShortcut, reference_name,
child_entry); child_entry, generator_);
} }
void V8HeapExplorer::SetElementReference(HeapEntry* parent_entry, int index, void V8HeapExplorer::SetElementReference(HeapEntry* parent_entry, int index,
Object child_obj) { Object child_obj) {
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
if (child_entry == nullptr) return; if (child_entry == nullptr) return;
parent_entry->SetIndexedReference(HeapGraphEdge::kElement, index, parent_entry->SetIndexedReference(HeapGraphEdge::kElement, index, child_entry,
child_entry); generator_);
} }
void V8HeapExplorer::SetInternalReference(HeapEntry* parent_entry, void V8HeapExplorer::SetInternalReference(HeapEntry* parent_entry,
...@@ -1794,7 +2012,7 @@ void V8HeapExplorer::SetInternalReference(HeapEntry* parent_entry, ...@@ -1794,7 +2012,7 @@ void V8HeapExplorer::SetInternalReference(HeapEntry* parent_entry,
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
DCHECK_NOT_NULL(child_entry); DCHECK_NOT_NULL(child_entry);
parent_entry->SetNamedReference(HeapGraphEdge::kInternal, reference_name, parent_entry->SetNamedReference(HeapGraphEdge::kInternal, reference_name,
child_entry); child_entry, generator_);
MarkVisitedField(field_offset); MarkVisitedField(field_offset);
} }
...@@ -1806,7 +2024,8 @@ void V8HeapExplorer::SetInternalReference(HeapEntry* parent_entry, int index, ...@@ -1806,7 +2024,8 @@ void V8HeapExplorer::SetInternalReference(HeapEntry* parent_entry, int index,
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
DCHECK_NOT_NULL(child_entry); DCHECK_NOT_NULL(child_entry);
parent_entry->SetNamedReference(HeapGraphEdge::kInternal, parent_entry->SetNamedReference(HeapGraphEdge::kInternal,
names_->GetName(index), child_entry); names_->GetName(index), child_entry,
generator_);
MarkVisitedField(field_offset); MarkVisitedField(field_offset);
} }
...@@ -1822,20 +2041,20 @@ void V8HeapExplorer::SetHiddenReference(HeapObject parent_obj, ...@@ -1822,20 +2041,20 @@ void V8HeapExplorer::SetHiddenReference(HeapObject parent_obj,
DCHECK_NOT_NULL(child_entry); DCHECK_NOT_NULL(child_entry);
if (IsEssentialHiddenReference(parent_obj, field_offset)) { if (IsEssentialHiddenReference(parent_obj, field_offset)) {
parent_entry->SetIndexedReference(HeapGraphEdge::kHidden, index, parent_entry->SetIndexedReference(HeapGraphEdge::kHidden, index,
child_entry); child_entry, generator_);
} }
} }
void V8HeapExplorer::SetWeakReference(HeapEntry* parent_entry, void V8HeapExplorer::SetWeakReference(
const char* reference_name, HeapEntry* parent_entry, const char* reference_name, Object child_obj,
Object child_obj, int field_offset) { int field_offset, HeapEntry::ReferenceVerification verification) {
if (!IsEssentialObject(child_obj)) { if (!IsEssentialObject(child_obj)) {
return; return;
} }
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
DCHECK_NOT_NULL(child_entry); DCHECK_NOT_NULL(child_entry);
parent_entry->SetNamedReference(HeapGraphEdge::kWeak, reference_name, parent_entry->SetNamedReference(HeapGraphEdge::kWeak, reference_name,
child_entry); child_entry, generator_, verification);
MarkVisitedField(field_offset); MarkVisitedField(field_offset);
} }
...@@ -1847,8 +2066,9 @@ void V8HeapExplorer::SetWeakReference(HeapEntry* parent_entry, int index, ...@@ -1847,8 +2066,9 @@ void V8HeapExplorer::SetWeakReference(HeapEntry* parent_entry, int index,
} }
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
DCHECK_NOT_NULL(child_entry); DCHECK_NOT_NULL(child_entry);
parent_entry->SetNamedReference( parent_entry->SetNamedReference(HeapGraphEdge::kWeak,
HeapGraphEdge::kWeak, names_->GetFormatted("%d", index), child_entry); names_->GetFormatted("%d", index),
child_entry, generator_);
if (field_offset.has_value()) { if (field_offset.has_value()) {
MarkVisitedField(*field_offset); MarkVisitedField(*field_offset);
} }
...@@ -1885,25 +2105,25 @@ void V8HeapExplorer::SetPropertyReference(HeapEntry* parent_entry, ...@@ -1885,25 +2105,25 @@ void V8HeapExplorer::SetPropertyReference(HeapEntry* parent_entry,
.get()) .get())
: names_->GetName(reference_name); : names_->GetName(reference_name);
parent_entry->SetNamedReference(type, name, child_entry); parent_entry->SetNamedReference(type, name, child_entry, generator_);
MarkVisitedField(field_offset); MarkVisitedField(field_offset);
} }
void V8HeapExplorer::SetRootGcRootsReference() { void V8HeapExplorer::SetRootGcRootsReference() {
snapshot_->root()->SetIndexedAutoIndexReference(HeapGraphEdge::kElement, snapshot_->root()->SetIndexedAutoIndexReference(
snapshot_->gc_roots()); HeapGraphEdge::kElement, snapshot_->gc_roots(), generator_);
} }
void V8HeapExplorer::SetUserGlobalReference(Object child_obj) { void V8HeapExplorer::SetUserGlobalReference(Object child_obj) {
HeapEntry* child_entry = GetEntry(child_obj); HeapEntry* child_entry = GetEntry(child_obj);
DCHECK_NOT_NULL(child_entry); DCHECK_NOT_NULL(child_entry);
snapshot_->root()->SetNamedAutoIndexReference(HeapGraphEdge::kShortcut, snapshot_->root()->SetNamedAutoIndexReference(
nullptr, child_entry, names_); HeapGraphEdge::kShortcut, nullptr, child_entry, names_, generator_);
} }
void V8HeapExplorer::SetGcRootsReference(Root root) { void V8HeapExplorer::SetGcRootsReference(Root root) {
snapshot_->gc_roots()->SetIndexedAutoIndexReference( snapshot_->gc_roots()->SetIndexedAutoIndexReference(
HeapGraphEdge::kElement, snapshot_->gc_subroot(root)); HeapGraphEdge::kElement, snapshot_->gc_subroot(root), generator_);
} }
void V8HeapExplorer::SetGcSubrootReference(Root root, const char* description, void V8HeapExplorer::SetGcSubrootReference(Root root, const char* description,
...@@ -1921,11 +2141,11 @@ void V8HeapExplorer::SetGcSubrootReference(Root root, const char* description, ...@@ -1921,11 +2141,11 @@ void V8HeapExplorer::SetGcSubrootReference(Root root, const char* description,
HeapGraphEdge::Type edge_type = HeapGraphEdge::Type edge_type =
is_weak ? HeapGraphEdge::kWeak : HeapGraphEdge::kInternal; is_weak ? HeapGraphEdge::kWeak : HeapGraphEdge::kInternal;
if (name != nullptr) { if (name != nullptr) {
snapshot_->gc_subroot(root)->SetNamedReference(edge_type, name, snapshot_->gc_subroot(root)->SetNamedReference(edge_type, name, child_entry,
child_entry); generator_);
} else { } else {
snapshot_->gc_subroot(root)->SetNamedAutoIndexReference( snapshot_->gc_subroot(root)->SetNamedAutoIndexReference(
edge_type, description, child_entry, names_); edge_type, description, child_entry, names_, generator_);
} }
// For full heap snapshots we do not emit user roots but rather rely on // For full heap snapshots we do not emit user roots but rather rely on
...@@ -2222,7 +2442,8 @@ bool NativeObjectsExplorer::IterateAndExtractReferences( ...@@ -2222,7 +2442,8 @@ bool NativeObjectsExplorer::IterateAndExtractReferences(
if (auto* entry = EntryForEmbedderGraphNode(node.get())) { if (auto* entry = EntryForEmbedderGraphNode(node.get())) {
if (node->IsRootNode()) { if (node->IsRootNode()) {
snapshot_->root()->SetIndexedAutoIndexReference( snapshot_->root()->SetIndexedAutoIndexReference(
HeapGraphEdge::kElement, entry); HeapGraphEdge::kElement, entry, generator_,
HeapEntry::kOffHeapPointer);
} }
if (node->WrapperNode()) { if (node->WrapperNode()) {
MergeNodeIntoEntry(entry, node.get(), node->WrapperNode()); MergeNodeIntoEntry(entry, node.get(), node->WrapperNode());
...@@ -2238,10 +2459,13 @@ bool NativeObjectsExplorer::IterateAndExtractReferences( ...@@ -2238,10 +2459,13 @@ bool NativeObjectsExplorer::IterateAndExtractReferences(
HeapEntry* to = EntryForEmbedderGraphNode(edge.to); HeapEntry* to = EntryForEmbedderGraphNode(edge.to);
if (!to) continue; if (!to) continue;
if (edge.name == nullptr) { if (edge.name == nullptr) {
from->SetIndexedAutoIndexReference(HeapGraphEdge::kElement, to); from->SetIndexedAutoIndexReference(HeapGraphEdge::kElement, to,
generator_,
HeapEntry::kOffHeapPointer);
} else { } else {
from->SetNamedReference(HeapGraphEdge::kInternal, from->SetNamedReference(HeapGraphEdge::kInternal,
names_->GetCopy(edge.name), to); names_->GetCopy(edge.name), to, generator_,
HeapEntry::kOffHeapPointer);
} }
} }
} }
...@@ -2250,16 +2474,13 @@ bool NativeObjectsExplorer::IterateAndExtractReferences( ...@@ -2250,16 +2474,13 @@ bool NativeObjectsExplorer::IterateAndExtractReferences(
} }
HeapSnapshotGenerator::HeapSnapshotGenerator( HeapSnapshotGenerator::HeapSnapshotGenerator(
HeapSnapshot* snapshot, HeapSnapshot* snapshot, v8::ActivityControl* control,
v8::ActivityControl* control, v8::HeapProfiler::ObjectNameResolver* resolver, Heap* heap)
v8::HeapProfiler::ObjectNameResolver* resolver,
Heap* heap)
: snapshot_(snapshot), : snapshot_(snapshot),
control_(control), control_(control),
v8_heap_explorer_(snapshot_, this, resolver), v8_heap_explorer_(snapshot_, this, resolver),
dom_explorer_(snapshot_, this), dom_explorer_(snapshot_, this),
heap_(heap) { heap_(heap) {}
}
namespace { namespace {
class V8_NODISCARD NullContextForSnapshotScope { class V8_NODISCARD NullContextForSnapshotScope {
......
...@@ -24,6 +24,10 @@ ...@@ -24,6 +24,10 @@
#include "src/profiler/strings-storage.h" #include "src/profiler/strings-storage.h"
#include "src/strings/string-hasher.h" #include "src/strings/string-hasher.h"
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
#include "src/heap/reference-summarizer.h"
#endif
namespace v8 { namespace v8 {
namespace internal { namespace internal {
...@@ -141,17 +145,40 @@ class HeapEntry { ...@@ -141,17 +145,40 @@ class HeapEntry {
} }
uint8_t detachedness() const { return detachedness_; } uint8_t detachedness() const { return detachedness_; }
void SetIndexedReference( enum ReferenceVerification {
HeapGraphEdge::Type type, int index, HeapEntry* entry); // Verify that the reference can be found via marking, if verification is
void SetNamedReference( // enabled.
HeapGraphEdge::Type type, const char* name, HeapEntry* entry); kVerify,
void SetIndexedAutoIndexReference(HeapGraphEdge::Type type,
HeapEntry* child) { // Skip verifying that the reference can be found via marking, for any of
SetIndexedReference(type, children_count_ + 1, child); // the following reasons:
kEphemeron,
kOffHeapPointer,
kCustomWeakPointer,
};
void VerifyReference(HeapGraphEdge::Type type, HeapEntry* entry,
HeapSnapshotGenerator* generator,
ReferenceVerification verification);
void SetIndexedReference(HeapGraphEdge::Type type, int index,
HeapEntry* entry, HeapSnapshotGenerator* generator,
ReferenceVerification verification = kVerify);
void SetNamedReference(HeapGraphEdge::Type type, const char* name,
HeapEntry* entry, HeapSnapshotGenerator* generator,
ReferenceVerification verification = kVerify);
void SetIndexedAutoIndexReference(
HeapGraphEdge::Type type, HeapEntry* child,
HeapSnapshotGenerator* generator,
ReferenceVerification verification = kVerify) {
SetIndexedReference(type, children_count_ + 1, child, generator,
verification);
} }
void SetNamedAutoIndexReference(HeapGraphEdge::Type type, void SetNamedAutoIndexReference(HeapGraphEdge::Type type,
const char* description, HeapEntry* child, const char* description, HeapEntry* child,
StringsStorage* strings); StringsStorage* strings,
HeapSnapshotGenerator* generator,
ReferenceVerification verification = kVerify);
V8_EXPORT_PRIVATE void Print(const char* prefix, const char* edge_name, V8_EXPORT_PRIVATE void Print(const char* prefix, const char* edge_name,
int max_depth, int indent) const; int max_depth, int indent) const;
...@@ -438,8 +465,10 @@ class V8_EXPORT_PRIVATE V8HeapExplorer : public HeapEntriesAllocator { ...@@ -438,8 +465,10 @@ class V8_EXPORT_PRIVATE V8HeapExplorer : public HeapEntriesAllocator {
int field_offset = -1); int field_offset = -1);
void SetHiddenReference(HeapObject parent_obj, HeapEntry* parent_entry, void SetHiddenReference(HeapObject parent_obj, HeapEntry* parent_entry,
int index, Object child, int field_offset); int index, Object child, int field_offset);
void SetWeakReference(HeapEntry* parent_entry, const char* reference_name, void SetWeakReference(
Object child_obj, int field_offset); HeapEntry* parent_entry, const char* reference_name, Object child_obj,
int field_offset,
HeapEntry::ReferenceVerification verification = HeapEntry::kVerify);
void SetWeakReference(HeapEntry* parent_entry, int index, Object child_obj, void SetWeakReference(HeapEntry* parent_entry, int index, Object child_obj,
base::Optional<int> field_offset); base::Optional<int> field_offset);
void SetPropertyReference(HeapEntry* parent_entry, Name reference_name, void SetPropertyReference(HeapEntry* parent_entry, Name reference_name,
...@@ -511,6 +540,8 @@ class NativeObjectsExplorer { ...@@ -511,6 +540,8 @@ class NativeObjectsExplorer {
friend class GlobalHandlesExtractor; friend class GlobalHandlesExtractor;
}; };
class HeapEntryVerifier;
class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface { class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface {
public: public:
// The HeapEntriesMap instance is used to track a mapping between // The HeapEntriesMap instance is used to track a mapping between
...@@ -539,10 +570,33 @@ class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface { ...@@ -539,10 +570,33 @@ class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface {
} }
HeapEntry* AddEntry(HeapThing ptr, HeapEntriesAllocator* allocator) { HeapEntry* AddEntry(HeapThing ptr, HeapEntriesAllocator* allocator) {
return entries_map_.emplace(ptr, allocator->AllocateEntry(ptr)) HeapEntry* result =
.first->second; entries_map_.emplace(ptr, allocator->AllocateEntry(ptr)).first->second;
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
if (FLAG_heap_snapshot_verify) {
reverse_entries_map_.emplace(result, ptr);
}
#endif
return result;
} }
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
HeapThing FindHeapThingForHeapEntry(HeapEntry* entry) {
// The reverse lookup map is only populated if the verification flag is
// enabled.
DCHECK(FLAG_heap_snapshot_verify);
auto it = reverse_entries_map_.find(entry);
return it == reverse_entries_map_.end() ? nullptr : it->second;
}
HeapEntryVerifier* verifier() const { return verifier_; }
void set_verifier(HeapEntryVerifier* verifier) {
DCHECK_IMPLIES(verifier_, !verifier);
verifier_ = verifier;
}
#endif
HeapEntry* AddEntry(Smi smi, HeapEntriesAllocator* allocator) { HeapEntry* AddEntry(Smi smi, HeapEntriesAllocator* allocator) {
return smis_map_.emplace(smi.value(), allocator->AllocateEntry(smi)) return smis_map_.emplace(smi.value(), allocator->AllocateEntry(smi))
.first->second; .first->second;
...@@ -558,6 +612,8 @@ class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface { ...@@ -558,6 +612,8 @@ class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface {
return entry != nullptr ? entry : AddEntry(smi, allocator); return entry != nullptr ? entry : AddEntry(smi, allocator);
} }
Heap* heap() const { return heap_; }
private: private:
bool FillReferences(); bool FillReferences();
void ProgressStep() override; void ProgressStep() override;
...@@ -575,6 +631,11 @@ class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface { ...@@ -575,6 +631,11 @@ class HeapSnapshotGenerator : public SnapshottingProgressReportingInterface {
uint32_t progress_counter_; uint32_t progress_counter_;
uint32_t progress_total_; uint32_t progress_total_;
Heap* heap_; Heap* heap_;
#ifdef V8_ENABLE_HEAP_SNAPSHOT_VERIFY
std::unordered_map<HeapEntry*, HeapThing> reverse_entries_map_;
HeapEntryVerifier* verifier_ = nullptr;
#endif
}; };
class OutputStreamWriter; class OutputStreamWriter;
......
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