v8/test/cctest/test-heap-profiler.cc
2011-03-30 14:04:50 +00:00

1324 lines
45 KiB
C++

// Copyright 2009 the V8 project authors. All rights reserved.
//
// Tests for heap profiler
#ifdef ENABLE_LOGGING_AND_PROFILING
#include "v8.h"
#include "heap-profiler.h"
#include "snapshot.h"
#include "string-stream.h"
#include "cctest.h"
#include "zone-inl.h"
#include "../include/v8-profiler.h"
namespace i = v8::internal;
using i::ClustersCoarser;
using i::JSObjectsCluster;
using i::JSObjectsRetainerTree;
using i::JSObjectsClusterTree;
using i::RetainerHeapProfile;
namespace {
class ConstructorHeapProfileTestHelper : public i::ConstructorHeapProfile {
public:
ConstructorHeapProfileTestHelper()
: i::ConstructorHeapProfile(),
f_name_(FACTORY->NewStringFromAscii(i::CStrVector("F"))),
f_count_(0) {
}
void Call(const JSObjectsCluster& cluster,
const i::NumberAndSizeInfo& number_and_size) {
if (f_name_->Equals(cluster.constructor())) {
CHECK_EQ(f_count_, 0);
f_count_ = number_and_size.number();
CHECK_GT(f_count_, 0);
}
}
int f_count() { return f_count_; }
private:
i::Handle<i::String> f_name_;
int f_count_;
};
} // namespace
TEST(ConstructorProfile) {
v8::HandleScope scope;
LocalContext env;
CompileRun(
"function F() {} // A constructor\n"
"var f1 = new F();\n"
"var f2 = new F();\n");
ConstructorHeapProfileTestHelper cons_profile;
i::AssertNoAllocation no_alloc;
i::HeapIterator iterator;
for (i::HeapObject* obj = iterator.next(); obj != NULL; obj = iterator.next())
cons_profile.CollectStats(obj);
CHECK_EQ(0, cons_profile.f_count());
cons_profile.PrintStats();
CHECK_EQ(2, cons_profile.f_count());
}
static JSObjectsCluster AddHeapObjectToTree(JSObjectsRetainerTree* tree,
i::String* constructor,
int instance,
JSObjectsCluster* ref1 = NULL,
JSObjectsCluster* ref2 = NULL,
JSObjectsCluster* ref3 = NULL) {
JSObjectsCluster o(constructor, reinterpret_cast<i::Object*>(instance));
JSObjectsClusterTree* o_tree = new JSObjectsClusterTree();
JSObjectsClusterTree::Locator o_loc;
if (ref1 != NULL) o_tree->Insert(*ref1, &o_loc);
if (ref2 != NULL) o_tree->Insert(*ref2, &o_loc);
if (ref3 != NULL) o_tree->Insert(*ref3, &o_loc);
JSObjectsRetainerTree::Locator loc;
tree->Insert(o, &loc);
loc.set_value(o_tree);
return o;
}
static void AddSelfReferenceToTree(JSObjectsRetainerTree* tree,
JSObjectsCluster* self_ref) {
JSObjectsRetainerTree::Locator loc;
CHECK(tree->Find(*self_ref, &loc));
JSObjectsClusterTree::Locator o_loc;
CHECK_NE(NULL, loc.value());
loc.value()->Insert(*self_ref, &o_loc);
}
static inline void CheckEqualsHelper(const char* file, int line,
const char* expected_source,
const JSObjectsCluster& expected,
const char* value_source,
const JSObjectsCluster& value) {
if (JSObjectsCluster::Compare(expected, value) != 0) {
i::HeapStringAllocator allocator;
i::StringStream stream(&allocator);
stream.Add("# Expected: ");
expected.DebugPrint(&stream);
stream.Add("\n# Found: ");
value.DebugPrint(&stream);
V8_Fatal(file, line, "CHECK_EQ(%s, %s) failed\n%s",
expected_source, value_source,
*stream.ToCString());
}
}
static inline void CheckNonEqualsHelper(const char* file, int line,
const char* expected_source,
const JSObjectsCluster& expected,
const char* value_source,
const JSObjectsCluster& value) {
if (JSObjectsCluster::Compare(expected, value) == 0) {
i::HeapStringAllocator allocator;
i::StringStream stream(&allocator);
stream.Add("# !Expected: ");
expected.DebugPrint(&stream);
stream.Add("\n# Found: ");
value.DebugPrint(&stream);
V8_Fatal(file, line, "CHECK_NE(%s, %s) failed\n%s",
expected_source, value_source,
*stream.ToCString());
}
}
TEST(ClustersCoarserSimple) {
v8::HandleScope scope;
LocalContext env;
i::ZoneScope zn_scope(i::DELETE_ON_EXIT);
JSObjectsRetainerTree tree;
JSObjectsCluster function(HEAP->function_class_symbol());
JSObjectsCluster a(*FACTORY->NewStringFromAscii(i::CStrVector("A")));
JSObjectsCluster b(*FACTORY->NewStringFromAscii(i::CStrVector("B")));
// o1 <- Function
JSObjectsCluster o1 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x100, &function);
// o2 <- Function
JSObjectsCluster o2 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x200, &function);
// o3 <- A, B
JSObjectsCluster o3 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x300, &a, &b);
// o4 <- B, A
JSObjectsCluster o4 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x400, &b, &a);
// o5 <- A, B, Function
JSObjectsCluster o5 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x500,
&a, &b, &function);
ClustersCoarser coarser;
coarser.Process(&tree);
CHECK_EQ(coarser.GetCoarseEquivalent(o1), coarser.GetCoarseEquivalent(o2));
CHECK_EQ(coarser.GetCoarseEquivalent(o3), coarser.GetCoarseEquivalent(o4));
CHECK_NE(coarser.GetCoarseEquivalent(o1), coarser.GetCoarseEquivalent(o3));
CHECK_EQ(JSObjectsCluster(), coarser.GetCoarseEquivalent(o5));
}
TEST(ClustersCoarserMultipleConstructors) {
v8::HandleScope scope;
LocalContext env;
i::ZoneScope zn_scope(i::DELETE_ON_EXIT);
JSObjectsRetainerTree tree;
JSObjectsCluster function(HEAP->function_class_symbol());
// o1 <- Function
JSObjectsCluster o1 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x100, &function);
// a1 <- Function
JSObjectsCluster a1 =
AddHeapObjectToTree(&tree, HEAP->Array_symbol(), 0x1000, &function);
// o2 <- Function
JSObjectsCluster o2 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x200, &function);
// a2 <- Function
JSObjectsCluster a2 =
AddHeapObjectToTree(&tree, HEAP->Array_symbol(), 0x2000, &function);
ClustersCoarser coarser;
coarser.Process(&tree);
CHECK_EQ(coarser.GetCoarseEquivalent(o1), coarser.GetCoarseEquivalent(o2));
CHECK_EQ(coarser.GetCoarseEquivalent(a1), coarser.GetCoarseEquivalent(a2));
}
TEST(ClustersCoarserPathsTraversal) {
v8::HandleScope scope;
LocalContext env;
i::ZoneScope zn_scope(i::DELETE_ON_EXIT);
JSObjectsRetainerTree tree;
// On the following graph:
//
// p
// <- o21 <- o11 <-
// q o
// <- o22 <- o12 <-
// r
//
// we expect that coarser will deduce equivalences: p ~ q ~ r,
// o21 ~ o22, and o11 ~ o12.
JSObjectsCluster o =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x100);
JSObjectsCluster o11 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x110, &o);
JSObjectsCluster o12 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x120, &o);
JSObjectsCluster o21 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x210, &o11);
JSObjectsCluster o22 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x220, &o12);
JSObjectsCluster p =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x300, &o21);
JSObjectsCluster q =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x310, &o21, &o22);
JSObjectsCluster r =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x320, &o22);
ClustersCoarser coarser;
coarser.Process(&tree);
CHECK_EQ(JSObjectsCluster(), coarser.GetCoarseEquivalent(o));
CHECK_NE(JSObjectsCluster(), coarser.GetCoarseEquivalent(o11));
CHECK_EQ(coarser.GetCoarseEquivalent(o11), coarser.GetCoarseEquivalent(o12));
CHECK_EQ(coarser.GetCoarseEquivalent(o21), coarser.GetCoarseEquivalent(o22));
CHECK_NE(coarser.GetCoarseEquivalent(o11), coarser.GetCoarseEquivalent(o21));
CHECK_NE(JSObjectsCluster(), coarser.GetCoarseEquivalent(p));
CHECK_EQ(coarser.GetCoarseEquivalent(p), coarser.GetCoarseEquivalent(q));
CHECK_EQ(coarser.GetCoarseEquivalent(q), coarser.GetCoarseEquivalent(r));
CHECK_NE(coarser.GetCoarseEquivalent(o11), coarser.GetCoarseEquivalent(p));
CHECK_NE(coarser.GetCoarseEquivalent(o21), coarser.GetCoarseEquivalent(p));
}
TEST(ClustersCoarserSelf) {
v8::HandleScope scope;
LocalContext env;
i::ZoneScope zn_scope(i::DELETE_ON_EXIT);
JSObjectsRetainerTree tree;
// On the following graph:
//
// p (self-referencing)
// <- o1 <-
// q (self-referencing) o
// <- o2 <-
// r (self-referencing)
//
// we expect that coarser will deduce equivalences: p ~ q ~ r, o1 ~ o2;
JSObjectsCluster o =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x100);
JSObjectsCluster o1 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x110, &o);
JSObjectsCluster o2 =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x120, &o);
JSObjectsCluster p =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x300, &o1);
AddSelfReferenceToTree(&tree, &p);
JSObjectsCluster q =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x310, &o1, &o2);
AddSelfReferenceToTree(&tree, &q);
JSObjectsCluster r =
AddHeapObjectToTree(&tree, HEAP->Object_symbol(), 0x320, &o2);
AddSelfReferenceToTree(&tree, &r);
ClustersCoarser coarser;
coarser.Process(&tree);
CHECK_EQ(JSObjectsCluster(), coarser.GetCoarseEquivalent(o));
CHECK_NE(JSObjectsCluster(), coarser.GetCoarseEquivalent(o1));
CHECK_EQ(coarser.GetCoarseEquivalent(o1), coarser.GetCoarseEquivalent(o2));
CHECK_NE(JSObjectsCluster(), coarser.GetCoarseEquivalent(p));
CHECK_EQ(coarser.GetCoarseEquivalent(p), coarser.GetCoarseEquivalent(q));
CHECK_EQ(coarser.GetCoarseEquivalent(q), coarser.GetCoarseEquivalent(r));
CHECK_NE(coarser.GetCoarseEquivalent(o1), coarser.GetCoarseEquivalent(p));
}
namespace {
class RetainerProfilePrinter : public RetainerHeapProfile::Printer {
public:
RetainerProfilePrinter() : stream_(&allocator_), lines_(100) {}
void PrintRetainers(const JSObjectsCluster& cluster,
const i::StringStream& retainers) {
cluster.Print(&stream_);
stream_.Add("%s", *(retainers.ToCString()));
stream_.Put('\0');
}
const char* GetRetainers(const char* constructor) {
FillLines();
const size_t cons_len = strlen(constructor);
for (int i = 0; i < lines_.length(); ++i) {
if (strncmp(constructor, lines_[i], cons_len) == 0 &&
lines_[i][cons_len] == ',') {
return lines_[i] + cons_len + 1;
}
}
return NULL;
}
private:
void FillLines() {
if (lines_.length() > 0) return;
stream_.Put('\0');
stream_str_ = stream_.ToCString();
const char* pos = *stream_str_;
while (pos != NULL && *pos != '\0') {
lines_.Add(pos);
pos = strchr(pos, '\0');
if (pos != NULL) ++pos;
}
}
i::HeapStringAllocator allocator_;
i::StringStream stream_;
i::SmartPointer<const char> stream_str_;
i::List<const char*> lines_;
};
} // namespace
TEST(RetainerProfile) {
v8::HandleScope scope;
LocalContext env;
CompileRun(
"function A() {}\n"
"function B(x) { this.x = x; }\n"
"function C(x) { this.x1 = x; this.x2 = x; }\n"
"var a = new A();\n"
"var b1 = new B(a), b2 = new B(a);\n"
"var c = new C(a);");
RetainerHeapProfile ret_profile;
i::AssertNoAllocation no_alloc;
i::HeapIterator iterator;
for (i::HeapObject* obj = iterator.next(); obj != NULL; obj = iterator.next())
ret_profile.CollectStats(obj);
ret_profile.CoarseAndAggregate();
RetainerProfilePrinter printer;
ret_profile.DebugPrintStats(&printer);
const char* retainers_of_a = printer.GetRetainers("A");
// The order of retainers is unspecified, so we check string length, and
// verify each retainer separately.
CHECK_EQ(i::StrLength("(global property);1,B;2,C;2"),
i::StrLength(retainers_of_a));
CHECK(strstr(retainers_of_a, "(global property);1") != NULL);
CHECK(strstr(retainers_of_a, "B;2") != NULL);
CHECK(strstr(retainers_of_a, "C;2") != NULL);
CHECK_EQ("(global property);2", printer.GetRetainers("B"));
CHECK_EQ("(global property);1", printer.GetRetainers("C"));
}
namespace {
class NamedEntriesDetector {
public:
NamedEntriesDetector()
: has_A2(false), has_B2(false), has_C2(false) {
}
void Apply(i::HeapEntry** entry_ptr) {
if (IsReachableNodeWithName(*entry_ptr, "A2")) has_A2 = true;
if (IsReachableNodeWithName(*entry_ptr, "B2")) has_B2 = true;
if (IsReachableNodeWithName(*entry_ptr, "C2")) has_C2 = true;
}
static bool IsReachableNodeWithName(i::HeapEntry* entry, const char* name) {
return strcmp(name, entry->name()) == 0 && entry->painted_reachable();
}
bool has_A2;
bool has_B2;
bool has_C2;
};
} // namespace
static const v8::HeapGraphNode* GetGlobalObject(
const v8::HeapSnapshot* snapshot) {
CHECK_EQ(2, snapshot->GetRoot()->GetChildrenCount());
const v8::HeapGraphNode* global_obj =
snapshot->GetRoot()->GetChild(0)->GetToNode();
CHECK_EQ("Object", const_cast<i::HeapEntry*>(
reinterpret_cast<const i::HeapEntry*>(global_obj))->name());
return global_obj;
}
static const v8::HeapGraphNode* GetProperty(const v8::HeapGraphNode* node,
v8::HeapGraphEdge::Type type,
const char* name) {
for (int i = 0, count = node->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = node->GetChild(i);
v8::String::AsciiValue prop_name(prop->GetName());
if (prop->GetType() == type && strcmp(name, *prop_name) == 0)
return prop->GetToNode();
}
return NULL;
}
static bool HasString(const v8::HeapGraphNode* node, const char* contents) {
for (int i = 0, count = node->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = node->GetChild(i);
const v8::HeapGraphNode* node = prop->GetToNode();
if (node->GetType() == v8::HeapGraphNode::kString) {
v8::String::AsciiValue node_name(node->GetName());
if (strcmp(contents, *node_name) == 0) return true;
}
}
return false;
}
TEST(HeapSnapshot) {
v8::HandleScope scope;
LocalContext env2;
CompileRun(
"function A2() {}\n"
"function B2(x) { return function() { return typeof x; }; }\n"
"function C2(x) { this.x1 = x; this.x2 = x; this[1] = x; }\n"
"var a2 = new A2();\n"
"var b2_1 = new B2(a2), b2_2 = new B2(a2);\n"
"var c2 = new C2(a2);");
const v8::HeapSnapshot* snapshot_env2 =
v8::HeapProfiler::TakeSnapshot(v8::String::New("env2"));
i::HeapSnapshot* i_snapshot_env2 =
const_cast<i::HeapSnapshot*>(
reinterpret_cast<const i::HeapSnapshot*>(snapshot_env2));
const v8::HeapGraphNode* global_env2 = GetGlobalObject(snapshot_env2);
// Paint all nodes reachable from global object.
i_snapshot_env2->ClearPaint();
const_cast<i::HeapEntry*>(
reinterpret_cast<const i::HeapEntry*>(global_env2))->PaintAllReachable();
// Verify, that JS global object of env2 has '..2' properties.
const v8::HeapGraphNode* a2_node =
GetProperty(global_env2, v8::HeapGraphEdge::kShortcut, "a2");
CHECK_NE(NULL, a2_node);
CHECK_NE(
NULL, GetProperty(global_env2, v8::HeapGraphEdge::kShortcut, "b2_1"));
CHECK_NE(
NULL, GetProperty(global_env2, v8::HeapGraphEdge::kShortcut, "b2_2"));
CHECK_NE(NULL, GetProperty(global_env2, v8::HeapGraphEdge::kShortcut, "c2"));
NamedEntriesDetector det;
i_snapshot_env2->IterateEntries(&det);
CHECK(det.has_A2);
CHECK(det.has_B2);
CHECK(det.has_C2);
}
TEST(HeapSnapshotObjectSizes) {
v8::HandleScope scope;
LocalContext env;
// -a-> X1 --a
// x -b-> X2 <-|
CompileRun(
"function X(a, b) { this.a = a; this.b = b; }\n"
"x = new X(new X(), new X());\n"
"(function() { x.a.a = x.b; })();");
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("sizes"));
const v8::HeapGraphNode* global = GetGlobalObject(snapshot);
const v8::HeapGraphNode* x =
GetProperty(global, v8::HeapGraphEdge::kShortcut, "x");
CHECK_NE(NULL, x);
const v8::HeapGraphNode* x1 =
GetProperty(x, v8::HeapGraphEdge::kProperty, "a");
CHECK_NE(NULL, x1);
const v8::HeapGraphNode* x2 =
GetProperty(x, v8::HeapGraphEdge::kProperty, "b");
CHECK_NE(NULL, x2);
// Test approximate sizes.
CHECK_EQ(x->GetSelfSize() * 3, x->GetRetainedSize(false));
CHECK_EQ(x1->GetSelfSize(), x1->GetRetainedSize(false));
CHECK_EQ(x2->GetSelfSize(), x2->GetRetainedSize(false));
// Test exact sizes.
CHECK_EQ(x->GetSelfSize() * 3, x->GetRetainedSize(true));
CHECK_EQ(x1->GetSelfSize(), x1->GetRetainedSize(true));
CHECK_EQ(x2->GetSelfSize(), x2->GetRetainedSize(true));
}
TEST(HeapSnapshotEntryChildren) {
v8::HandleScope scope;
LocalContext env;
CompileRun(
"function A() { }\n"
"a = new A;");
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("children"));
const v8::HeapGraphNode* global = GetGlobalObject(snapshot);
for (int i = 0, count = global->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = global->GetChild(i);
CHECK_EQ(global, prop->GetFromNode());
}
const v8::HeapGraphNode* a =
GetProperty(global, v8::HeapGraphEdge::kProperty, "a");
CHECK_NE(NULL, a);
for (int i = 0, count = a->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = a->GetChild(i);
CHECK_EQ(a, prop->GetFromNode());
}
}
TEST(HeapSnapshotCodeObjects) {
v8::HandleScope scope;
LocalContext env;
CompileRun(
"function lazy(x) { return x - 1; }\n"
"function compiled(x) { return x + 1; }\n"
"var anonymous = (function() { return function() { return 0; } })();\n"
"compiled(1)");
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("code"));
const v8::HeapGraphNode* global = GetGlobalObject(snapshot);
const v8::HeapGraphNode* compiled =
GetProperty(global, v8::HeapGraphEdge::kShortcut, "compiled");
CHECK_NE(NULL, compiled);
CHECK_EQ(v8::HeapGraphNode::kClosure, compiled->GetType());
const v8::HeapGraphNode* lazy =
GetProperty(global, v8::HeapGraphEdge::kShortcut, "lazy");
CHECK_NE(NULL, lazy);
CHECK_EQ(v8::HeapGraphNode::kClosure, lazy->GetType());
const v8::HeapGraphNode* anonymous =
GetProperty(global, v8::HeapGraphEdge::kShortcut, "anonymous");
CHECK_NE(NULL, anonymous);
CHECK_EQ(v8::HeapGraphNode::kClosure, anonymous->GetType());
v8::String::AsciiValue anonymous_name(anonymous->GetName());
CHECK_EQ("", *anonymous_name);
// Find references to code.
const v8::HeapGraphNode* compiled_code =
GetProperty(compiled, v8::HeapGraphEdge::kInternal, "shared");
CHECK_NE(NULL, compiled_code);
const v8::HeapGraphNode* lazy_code =
GetProperty(lazy, v8::HeapGraphEdge::kInternal, "shared");
CHECK_NE(NULL, lazy_code);
// Verify that non-compiled code doesn't contain references to "x"
// literal, while compiled code does. The scope info is stored in FixedArray
// objects attached to the SharedFunctionInfo.
bool compiled_references_x = false, lazy_references_x = false;
for (int i = 0, count = compiled_code->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = compiled_code->GetChild(i);
const v8::HeapGraphNode* node = prop->GetToNode();
if (node->GetType() == v8::HeapGraphNode::kArray) {
if (HasString(node, "x")) {
compiled_references_x = true;
break;
}
}
}
for (int i = 0, count = lazy_code->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = lazy_code->GetChild(i);
const v8::HeapGraphNode* node = prop->GetToNode();
if (node->GetType() == v8::HeapGraphNode::kArray) {
if (HasString(node, "x")) {
lazy_references_x = true;
break;
}
}
}
CHECK(compiled_references_x);
CHECK(!lazy_references_x);
}
TEST(HeapSnapshotHeapNumbers) {
v8::HandleScope scope;
LocalContext env;
CompileRun(
"a = 1; // a is Smi\n"
"b = 2.5; // b is HeapNumber");
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("numbers"));
const v8::HeapGraphNode* global = GetGlobalObject(snapshot);
CHECK_EQ(NULL, GetProperty(global, v8::HeapGraphEdge::kShortcut, "a"));
const v8::HeapGraphNode* b =
GetProperty(global, v8::HeapGraphEdge::kShortcut, "b");
CHECK_NE(NULL, b);
CHECK_EQ(v8::HeapGraphNode::kHeapNumber, b->GetType());
}
TEST(HeapSnapshotInternalReferences) {
v8::HandleScope scope;
v8::Local<v8::ObjectTemplate> global_template = v8::ObjectTemplate::New();
global_template->SetInternalFieldCount(2);
LocalContext env(NULL, global_template);
v8::Handle<v8::Object> global_proxy = env->Global();
v8::Handle<v8::Object> global = global_proxy->GetPrototype().As<v8::Object>();
CHECK_EQ(2, global->InternalFieldCount());
v8::Local<v8::Object> obj = v8::Object::New();
global->SetInternalField(0, v8_num(17));
global->SetInternalField(1, obj);
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("internals"));
const v8::HeapGraphNode* global_node = GetGlobalObject(snapshot);
// The first reference will not present, because it's a Smi.
CHECK_EQ(NULL, GetProperty(global_node, v8::HeapGraphEdge::kInternal, "0"));
// The second reference is to an object.
CHECK_NE(NULL, GetProperty(global_node, v8::HeapGraphEdge::kInternal, "1"));
}
// Trying to introduce a check helper for uint64_t causes many
// overloading ambiguities, so it seems easier just to cast
// them to a signed type.
#define CHECK_EQ_UINT64_T(a, b) \
CHECK_EQ(static_cast<int64_t>(a), static_cast<int64_t>(b))
#define CHECK_NE_UINT64_T(a, b) \
CHECK((a) != (b)) // NOLINT
TEST(HeapEntryIdsAndGC) {
v8::HandleScope scope;
LocalContext env;
CompileRun(
"function A() {}\n"
"function B(x) { this.x = x; }\n"
"var a = new A();\n"
"var b = new B(a);");
const v8::HeapSnapshot* snapshot1 =
v8::HeapProfiler::TakeSnapshot(v8::String::New("s1"));
HEAP->CollectAllGarbage(true); // Enforce compaction.
const v8::HeapSnapshot* snapshot2 =
v8::HeapProfiler::TakeSnapshot(v8::String::New("s2"));
const v8::HeapGraphNode* global1 = GetGlobalObject(snapshot1);
const v8::HeapGraphNode* global2 = GetGlobalObject(snapshot2);
CHECK_NE_UINT64_T(0, global1->GetId());
CHECK_EQ_UINT64_T(global1->GetId(), global2->GetId());
const v8::HeapGraphNode* A1 =
GetProperty(global1, v8::HeapGraphEdge::kProperty, "A");
CHECK_NE(NULL, A1);
const v8::HeapGraphNode* A2 =
GetProperty(global2, v8::HeapGraphEdge::kProperty, "A");
CHECK_NE(NULL, A2);
CHECK_NE_UINT64_T(0, A1->GetId());
CHECK_EQ_UINT64_T(A1->GetId(), A2->GetId());
const v8::HeapGraphNode* B1 =
GetProperty(global1, v8::HeapGraphEdge::kProperty, "B");
CHECK_NE(NULL, B1);
const v8::HeapGraphNode* B2 =
GetProperty(global2, v8::HeapGraphEdge::kProperty, "B");
CHECK_NE(NULL, B2);
CHECK_NE_UINT64_T(0, B1->GetId());
CHECK_EQ_UINT64_T(B1->GetId(), B2->GetId());
const v8::HeapGraphNode* a1 =
GetProperty(global1, v8::HeapGraphEdge::kProperty, "a");
CHECK_NE(NULL, a1);
const v8::HeapGraphNode* a2 =
GetProperty(global2, v8::HeapGraphEdge::kProperty, "a");
CHECK_NE(NULL, a2);
CHECK_NE_UINT64_T(0, a1->GetId());
CHECK_EQ_UINT64_T(a1->GetId(), a2->GetId());
const v8::HeapGraphNode* b1 =
GetProperty(global1, v8::HeapGraphEdge::kProperty, "b");
CHECK_NE(NULL, b1);
const v8::HeapGraphNode* b2 =
GetProperty(global2, v8::HeapGraphEdge::kProperty, "b");
CHECK_NE(NULL, b2);
CHECK_NE_UINT64_T(0, b1->GetId());
CHECK_EQ_UINT64_T(b1->GetId(), b2->GetId());
}
TEST(HeapSnapshotRootPreservedAfterSorting) {
v8::HandleScope scope;
LocalContext env;
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("s"));
const v8::HeapGraphNode* root1 = snapshot->GetRoot();
const_cast<i::HeapSnapshot*>(reinterpret_cast<const i::HeapSnapshot*>(
snapshot))->GetSortedEntriesList();
const v8::HeapGraphNode* root2 = snapshot->GetRoot();
CHECK_EQ(root1, root2);
}
static const v8::HeapGraphNode* GetChild(
const v8::HeapGraphNode* node,
v8::HeapGraphNode::Type type,
const char* name,
const v8::HeapGraphNode* after = NULL) {
bool ignore_child = after == NULL ? false : true;
for (int i = 0, count = node->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = node->GetChild(i);
const v8::HeapGraphNode* child = prop->GetToNode();
v8::String::AsciiValue child_name(child->GetName());
if (!ignore_child
&& child->GetType() == type
&& strcmp(name, *child_name) == 0)
return child;
if (after != NULL && child == after) ignore_child = false;
}
return NULL;
}
static bool IsNodeRetainedAs(const v8::HeapGraphNode* node,
int element) {
for (int i = 0, count = node->GetRetainersCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = node->GetRetainer(i);
if (prop->GetType() == v8::HeapGraphEdge::kElement
&& element == prop->GetName()->Int32Value())
return true;
}
return false;
}
TEST(AggregatedHeapSnapshot) {
v8::HandleScope scope;
LocalContext env;
CompileRun(
"function A() {}\n"
"function B(x) { this.x = x; }\n"
"var a = new A();\n"
"var b = new B(a);");
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(
v8::String::New("agg"), v8::HeapSnapshot::kAggregated);
const v8::HeapGraphNode* strings = GetChild(snapshot->GetRoot(),
v8::HeapGraphNode::kHidden,
"STRING_TYPE");
CHECK_NE(NULL, strings);
CHECK_NE(0, strings->GetSelfSize());
CHECK_NE(0, strings->GetInstancesCount());
const v8::HeapGraphNode* maps = GetChild(snapshot->GetRoot(),
v8::HeapGraphNode::kHidden,
"MAP_TYPE");
CHECK_NE(NULL, maps);
CHECK_NE(0, maps->GetSelfSize());
CHECK_NE(0, maps->GetInstancesCount());
const v8::HeapGraphNode* a = GetChild(snapshot->GetRoot(),
v8::HeapGraphNode::kObject,
"A");
CHECK_NE(NULL, a);
CHECK_NE(0, a->GetSelfSize());
CHECK_EQ(1, a->GetInstancesCount());
const v8::HeapGraphNode* b = GetChild(snapshot->GetRoot(),
v8::HeapGraphNode::kObject,
"B");
CHECK_NE(NULL, b);
CHECK_NE(0, b->GetSelfSize());
CHECK_EQ(1, b->GetInstancesCount());
const v8::HeapGraphNode* glob_prop = GetChild(snapshot->GetRoot(),
v8::HeapGraphNode::kObject,
"(global property)",
b);
CHECK_NE(NULL, glob_prop);
CHECK_EQ(0, glob_prop->GetSelfSize());
CHECK_EQ(0, glob_prop->GetInstancesCount());
CHECK_NE(0, glob_prop->GetChildrenCount());
const v8::HeapGraphNode* a_from_glob_prop = GetChild(
glob_prop,
v8::HeapGraphNode::kObject,
"A");
CHECK_NE(NULL, a_from_glob_prop);
CHECK_EQ(0, a_from_glob_prop->GetSelfSize());
CHECK_EQ(0, a_from_glob_prop->GetInstancesCount());
CHECK_EQ(0, a_from_glob_prop->GetChildrenCount()); // Retains nothing.
CHECK(IsNodeRetainedAs(a_from_glob_prop, 1)); // (global propery) has 1 ref.
const v8::HeapGraphNode* b_with_children = GetChild(
snapshot->GetRoot(),
v8::HeapGraphNode::kObject,
"B",
b);
CHECK_NE(NULL, b_with_children);
CHECK_EQ(0, b_with_children->GetSelfSize());
CHECK_EQ(0, b_with_children->GetInstancesCount());
CHECK_NE(0, b_with_children->GetChildrenCount());
const v8::HeapGraphNode* a_from_b = GetChild(
b_with_children,
v8::HeapGraphNode::kObject,
"A");
CHECK_NE(NULL, a_from_b);
CHECK_EQ(0, a_from_b->GetSelfSize());
CHECK_EQ(0, a_from_b->GetInstancesCount());
CHECK_EQ(0, a_from_b->GetChildrenCount()); // Retains nothing.
CHECK(IsNodeRetainedAs(a_from_b, 1)); // B has 1 ref to A.
}
TEST(HeapEntryDominator) {
// The graph looks like this:
//
// -> node1
// a |^
// -> node5 ba
// a v|
// node6 -> node2
// b a |^
// -> node4 ba
// b v|
// -> node3
//
// The dominator for all nodes is node6.
v8::HandleScope scope;
LocalContext env;
CompileRun(
"function X(a, b) { this.a = a; this.b = b; }\n"
"node6 = new X(new X(new X()), new X(new X(),new X()));\n"
"(function(){\n"
"node6.a.a.b = node6.b.a; // node1 -> node2\n"
"node6.b.a.a = node6.a.a; // node2 -> node1\n"
"node6.b.a.b = node6.b.b; // node2 -> node3\n"
"node6.b.b.a = node6.b.a; // node3 -> node2\n"
"})();");
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("dominators"));
const v8::HeapGraphNode* global = GetGlobalObject(snapshot);
CHECK_NE(NULL, global);
const v8::HeapGraphNode* node6 =
GetProperty(global, v8::HeapGraphEdge::kShortcut, "node6");
CHECK_NE(NULL, node6);
const v8::HeapGraphNode* node5 =
GetProperty(node6, v8::HeapGraphEdge::kProperty, "a");
CHECK_NE(NULL, node5);
const v8::HeapGraphNode* node4 =
GetProperty(node6, v8::HeapGraphEdge::kProperty, "b");
CHECK_NE(NULL, node4);
const v8::HeapGraphNode* node3 =
GetProperty(node4, v8::HeapGraphEdge::kProperty, "b");
CHECK_NE(NULL, node3);
const v8::HeapGraphNode* node2 =
GetProperty(node4, v8::HeapGraphEdge::kProperty, "a");
CHECK_NE(NULL, node2);
const v8::HeapGraphNode* node1 =
GetProperty(node5, v8::HeapGraphEdge::kProperty, "a");
CHECK_NE(NULL, node1);
CHECK_EQ(node6, node1->GetDominatorNode());
CHECK_EQ(node6, node2->GetDominatorNode());
CHECK_EQ(node6, node3->GetDominatorNode());
CHECK_EQ(node6, node4->GetDominatorNode());
CHECK_EQ(node6, node5->GetDominatorNode());
}
namespace {
class TestJSONStream : public v8::OutputStream {
public:
TestJSONStream() : eos_signaled_(0), abort_countdown_(-1) {}
explicit TestJSONStream(int abort_countdown)
: eos_signaled_(0), abort_countdown_(abort_countdown) {}
virtual ~TestJSONStream() {}
virtual void EndOfStream() { ++eos_signaled_; }
virtual WriteResult WriteAsciiChunk(char* buffer, int chars_written) {
if (abort_countdown_ > 0) --abort_countdown_;
if (abort_countdown_ == 0) return kAbort;
CHECK_GT(chars_written, 0);
i::Vector<char> chunk = buffer_.AddBlock(chars_written, '\0');
memcpy(chunk.start(), buffer, chars_written);
return kContinue;
}
void WriteTo(i::Vector<char> dest) { buffer_.WriteTo(dest); }
int eos_signaled() { return eos_signaled_; }
int size() { return buffer_.size(); }
private:
i::Collector<char> buffer_;
int eos_signaled_;
int abort_countdown_;
};
class AsciiResource: public v8::String::ExternalAsciiStringResource {
public:
explicit AsciiResource(i::Vector<char> string): data_(string.start()) {
length_ = string.length();
}
virtual const char* data() const { return data_; }
virtual size_t length() const { return length_; }
private:
const char* data_;
size_t length_;
};
} // namespace
TEST(HeapSnapshotJSONSerialization) {
v8::HandleScope scope;
LocalContext env;
#define STRING_LITERAL_FOR_TEST \
"\"String \\n\\r\\u0008\\u0081\\u0101\\u0801\\u8001\""
CompileRun(
"function A(s) { this.s = s; }\n"
"function B(x) { this.x = x; }\n"
"var a = new A(" STRING_LITERAL_FOR_TEST ");\n"
"var b = new B(a);");
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("json"));
TestJSONStream stream;
snapshot->Serialize(&stream, v8::HeapSnapshot::kJSON);
CHECK_GT(stream.size(), 0);
CHECK_EQ(1, stream.eos_signaled());
i::ScopedVector<char> json(stream.size());
stream.WriteTo(json);
// Verify that snapshot string is valid JSON.
AsciiResource json_res(json);
v8::Local<v8::String> json_string = v8::String::NewExternal(&json_res);
env->Global()->Set(v8::String::New("json_snapshot"), json_string);
v8::Local<v8::Value> snapshot_parse_result = CompileRun(
"var parsed = JSON.parse(json_snapshot); true;");
CHECK(!snapshot_parse_result.IsEmpty());
// Verify that snapshot object has required fields.
v8::Local<v8::Object> parsed_snapshot =
env->Global()->Get(v8::String::New("parsed"))->ToObject();
CHECK(parsed_snapshot->Has(v8::String::New("snapshot")));
CHECK(parsed_snapshot->Has(v8::String::New("nodes")));
CHECK(parsed_snapshot->Has(v8::String::New("strings")));
// Get node and edge "member" offsets.
v8::Local<v8::Value> meta_analysis_result = CompileRun(
"var parsed_meta = parsed.nodes[0];\n"
"var children_count_offset ="
" parsed_meta.fields.indexOf('children_count');\n"
"var children_offset ="
" parsed_meta.fields.indexOf('children');\n"
"var children_meta ="
" parsed_meta.types[children_offset];\n"
"var child_fields_count = children_meta.fields.length;\n"
"var child_type_offset ="
" children_meta.fields.indexOf('type');\n"
"var child_name_offset ="
" children_meta.fields.indexOf('name_or_index');\n"
"var child_to_node_offset ="
" children_meta.fields.indexOf('to_node');\n"
"var property_type ="
" children_meta.types[child_type_offset].indexOf('property');\n"
"var shortcut_type ="
" children_meta.types[child_type_offset].indexOf('shortcut');");
CHECK(!meta_analysis_result.IsEmpty());
// A helper function for processing encoded nodes.
CompileRun(
"function GetChildPosByProperty(pos, prop_name, prop_type) {\n"
" var nodes = parsed.nodes;\n"
" var strings = parsed.strings;\n"
" for (var i = 0,\n"
" count = nodes[pos + children_count_offset] * child_fields_count;\n"
" i < count; i += child_fields_count) {\n"
" var child_pos = pos + children_offset + i;\n"
" if (nodes[child_pos + child_type_offset] === prop_type\n"
" && strings[nodes[child_pos + child_name_offset]] === prop_name)\n"
" return nodes[child_pos + child_to_node_offset];\n"
" }\n"
" return null;\n"
"}\n");
// Get the string index using the path: <root> -> <global>.b.x.s
v8::Local<v8::Value> string_obj_pos_val = CompileRun(
"GetChildPosByProperty(\n"
" GetChildPosByProperty(\n"
" GetChildPosByProperty("
" parsed.nodes[1 + children_offset + child_to_node_offset],"
" \"b\",shortcut_type),\n"
" \"x\", property_type),"
" \"s\", property_type)");
CHECK(!string_obj_pos_val.IsEmpty());
int string_obj_pos =
static_cast<int>(string_obj_pos_val->ToNumber()->Value());
v8::Local<v8::Object> nodes_array =
parsed_snapshot->Get(v8::String::New("nodes"))->ToObject();
int string_index = static_cast<int>(
nodes_array->Get(string_obj_pos + 1)->ToNumber()->Value());
CHECK_GT(string_index, 0);
v8::Local<v8::Object> strings_array =
parsed_snapshot->Get(v8::String::New("strings"))->ToObject();
v8::Local<v8::String> string = strings_array->Get(string_index)->ToString();
v8::Local<v8::String> ref_string =
CompileRun(STRING_LITERAL_FOR_TEST)->ToString();
#undef STRING_LITERAL_FOR_TEST
CHECK_EQ(*v8::String::Utf8Value(ref_string),
*v8::String::Utf8Value(string));
}
TEST(HeapSnapshotJSONSerializationAborting) {
v8::HandleScope scope;
LocalContext env;
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("abort"));
TestJSONStream stream(5);
snapshot->Serialize(&stream, v8::HeapSnapshot::kJSON);
CHECK_GT(stream.size(), 0);
CHECK_EQ(0, stream.eos_signaled());
}
// Must not crash in debug mode.
TEST(AggregatedHeapSnapshotJSONSerialization) {
v8::HandleScope scope;
LocalContext env;
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(
v8::String::New("agg"), v8::HeapSnapshot::kAggregated);
TestJSONStream stream;
snapshot->Serialize(&stream, v8::HeapSnapshot::kJSON);
CHECK_GT(stream.size(), 0);
CHECK_EQ(1, stream.eos_signaled());
}
TEST(HeapSnapshotGetNodeById) {
v8::HandleScope scope;
LocalContext env;
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("id"));
const v8::HeapGraphNode* root = snapshot->GetRoot();
CHECK_EQ(root, snapshot->GetNodeById(root->GetId()));
for (int i = 0, count = root->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphEdge* prop = root->GetChild(i);
CHECK_EQ(
prop->GetToNode(), snapshot->GetNodeById(prop->GetToNode()->GetId()));
}
// Check a big id, which should not exist yet.
CHECK_EQ(NULL, snapshot->GetNodeById(0x1000000UL));
}
namespace {
class TestActivityControl : public v8::ActivityControl {
public:
explicit TestActivityControl(int abort_count)
: done_(0), total_(0), abort_count_(abort_count) {}
ControlOption ReportProgressValue(int done, int total) {
done_ = done;
total_ = total;
return --abort_count_ != 0 ? kContinue : kAbort;
}
int done() { return done_; }
int total() { return total_; }
private:
int done_;
int total_;
int abort_count_;
};
}
TEST(TakeHeapSnapshotAborting) {
v8::HandleScope scope;
LocalContext env;
const int snapshots_count = v8::HeapProfiler::GetSnapshotsCount();
TestActivityControl aborting_control(3);
const v8::HeapSnapshot* no_snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("abort"),
v8::HeapSnapshot::kFull,
&aborting_control);
CHECK_EQ(NULL, no_snapshot);
CHECK_EQ(snapshots_count, v8::HeapProfiler::GetSnapshotsCount());
CHECK_GT(aborting_control.total(), aborting_control.done());
TestActivityControl control(-1); // Don't abort.
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("full"),
v8::HeapSnapshot::kFull,
&control);
CHECK_NE(NULL, snapshot);
CHECK_EQ(snapshots_count + 1, v8::HeapProfiler::GetSnapshotsCount());
CHECK_EQ(control.total(), control.done());
CHECK_GT(control.total(), 0);
}
namespace {
class TestRetainedObjectInfo : public v8::RetainedObjectInfo {
public:
TestRetainedObjectInfo(int hash,
const char* label,
intptr_t element_count = -1,
intptr_t size = -1)
: disposed_(false),
hash_(hash),
label_(label),
element_count_(element_count),
size_(size) {
instances.Add(this);
}
virtual ~TestRetainedObjectInfo() {}
virtual void Dispose() {
CHECK(!disposed_);
disposed_ = true;
}
virtual bool IsEquivalent(RetainedObjectInfo* other) {
return GetHash() == other->GetHash();
}
virtual intptr_t GetHash() { return hash_; }
virtual const char* GetLabel() { return label_; }
virtual intptr_t GetElementCount() { return element_count_; }
virtual intptr_t GetSizeInBytes() { return size_; }
bool disposed() { return disposed_; }
static v8::RetainedObjectInfo* WrapperInfoCallback(
uint16_t class_id, v8::Handle<v8::Value> wrapper) {
if (class_id == 1) {
if (wrapper->IsString()) {
v8::String::AsciiValue ascii(wrapper);
if (strcmp(*ascii, "AAA") == 0)
return new TestRetainedObjectInfo(1, "aaa", 100);
else if (strcmp(*ascii, "BBB") == 0)
return new TestRetainedObjectInfo(1, "aaa", 100);
}
} else if (class_id == 2) {
if (wrapper->IsString()) {
v8::String::AsciiValue ascii(wrapper);
if (strcmp(*ascii, "CCC") == 0)
return new TestRetainedObjectInfo(2, "ccc");
}
}
CHECK(false);
return NULL;
}
static i::List<TestRetainedObjectInfo*> instances;
private:
bool disposed_;
int category_;
int hash_;
const char* label_;
intptr_t element_count_;
intptr_t size_;
};
i::List<TestRetainedObjectInfo*> TestRetainedObjectInfo::instances;
}
static const v8::HeapGraphNode* GetNode(const v8::HeapGraphNode* parent,
v8::HeapGraphNode::Type type,
const char* name) {
for (int i = 0, count = parent->GetChildrenCount(); i < count; ++i) {
const v8::HeapGraphNode* node = parent->GetChild(i)->GetToNode();
if (node->GetType() == type && strcmp(name,
const_cast<i::HeapEntry*>(
reinterpret_cast<const i::HeapEntry*>(node))->name()) == 0) {
return node;
}
}
return NULL;
}
TEST(HeapSnapshotRetainedObjectInfo) {
v8::HandleScope scope;
LocalContext env;
v8::HeapProfiler::DefineWrapperClass(
1, TestRetainedObjectInfo::WrapperInfoCallback);
v8::HeapProfiler::DefineWrapperClass(
2, TestRetainedObjectInfo::WrapperInfoCallback);
v8::Persistent<v8::String> p_AAA =
v8::Persistent<v8::String>::New(v8_str("AAA"));
p_AAA.SetWrapperClassId(1);
v8::Persistent<v8::String> p_BBB =
v8::Persistent<v8::String>::New(v8_str("BBB"));
p_BBB.SetWrapperClassId(1);
v8::Persistent<v8::String> p_CCC =
v8::Persistent<v8::String>::New(v8_str("CCC"));
p_CCC.SetWrapperClassId(2);
CHECK_EQ(0, TestRetainedObjectInfo::instances.length());
const v8::HeapSnapshot* snapshot =
v8::HeapProfiler::TakeSnapshot(v8::String::New("retained"));
CHECK_EQ(3, TestRetainedObjectInfo::instances.length());
for (int i = 0; i < TestRetainedObjectInfo::instances.length(); ++i) {
CHECK(TestRetainedObjectInfo::instances[i]->disposed());
delete TestRetainedObjectInfo::instances[i];
}
const v8::HeapGraphNode* natives = GetNode(
snapshot->GetRoot(), v8::HeapGraphNode::kObject, "(Native objects)");
CHECK_NE(NULL, natives);
CHECK_EQ(2, natives->GetChildrenCount());
const v8::HeapGraphNode* aaa = GetNode(
natives, v8::HeapGraphNode::kNative, "aaa / 100 entries");
CHECK_NE(NULL, aaa);
const v8::HeapGraphNode* ccc = GetNode(
natives, v8::HeapGraphNode::kNative, "ccc");
CHECK_NE(NULL, ccc);
CHECK_EQ(2, aaa->GetChildrenCount());
const v8::HeapGraphNode* n_AAA = GetNode(
aaa, v8::HeapGraphNode::kString, "AAA");
CHECK_NE(NULL, n_AAA);
const v8::HeapGraphNode* n_BBB = GetNode(
aaa, v8::HeapGraphNode::kString, "BBB");
CHECK_NE(NULL, n_BBB);
CHECK_EQ(1, ccc->GetChildrenCount());
const v8::HeapGraphNode* n_CCC = GetNode(
ccc, v8::HeapGraphNode::kString, "CCC");
CHECK_NE(NULL, n_CCC);
CHECK_EQ(aaa, GetProperty(n_AAA, v8::HeapGraphEdge::kInternal, "native"));
CHECK_EQ(aaa, GetProperty(n_BBB, v8::HeapGraphEdge::kInternal, "native"));
CHECK_EQ(ccc, GetProperty(n_CCC, v8::HeapGraphEdge::kInternal, "native"));
}
TEST(DeleteAllHeapSnapshots) {
v8::HandleScope scope;
LocalContext env;
CHECK_EQ(0, v8::HeapProfiler::GetSnapshotsCount());
v8::HeapProfiler::DeleteAllSnapshots();
CHECK_EQ(0, v8::HeapProfiler::GetSnapshotsCount());
CHECK_NE(NULL, v8::HeapProfiler::TakeSnapshot(v8::String::New("1")));
CHECK_EQ(1, v8::HeapProfiler::GetSnapshotsCount());
v8::HeapProfiler::DeleteAllSnapshots();
CHECK_EQ(0, v8::HeapProfiler::GetSnapshotsCount());
CHECK_NE(NULL, v8::HeapProfiler::TakeSnapshot(v8::String::New("1")));
CHECK_NE(NULL, v8::HeapProfiler::TakeSnapshot(v8::String::New("2")));
CHECK_EQ(2, v8::HeapProfiler::GetSnapshotsCount());
v8::HeapProfiler::DeleteAllSnapshots();
CHECK_EQ(0, v8::HeapProfiler::GetSnapshotsCount());
}
TEST(DeleteHeapSnapshot) {
v8::HandleScope scope;
LocalContext env;
CHECK_EQ(0, v8::HeapProfiler::GetSnapshotsCount());
const v8::HeapSnapshot* s1 =
v8::HeapProfiler::TakeSnapshot(v8::String::New("1"));
CHECK_NE(NULL, s1);
CHECK_EQ(1, v8::HeapProfiler::GetSnapshotsCount());
unsigned uid1 = s1->GetUid();
CHECK_EQ(s1, v8::HeapProfiler::FindSnapshot(uid1));
const_cast<v8::HeapSnapshot*>(s1)->Delete();
CHECK_EQ(0, v8::HeapProfiler::GetSnapshotsCount());
CHECK_EQ(NULL, v8::HeapProfiler::FindSnapshot(uid1));
const v8::HeapSnapshot* s2 =
v8::HeapProfiler::TakeSnapshot(v8::String::New("2"));
CHECK_NE(NULL, s2);
CHECK_EQ(1, v8::HeapProfiler::GetSnapshotsCount());
unsigned uid2 = s2->GetUid();
CHECK_NE(static_cast<int>(uid1), static_cast<int>(uid2));
CHECK_EQ(s2, v8::HeapProfiler::FindSnapshot(uid2));
const v8::HeapSnapshot* s3 =
v8::HeapProfiler::TakeSnapshot(v8::String::New("3"));
CHECK_NE(NULL, s3);
CHECK_EQ(2, v8::HeapProfiler::GetSnapshotsCount());
unsigned uid3 = s3->GetUid();
CHECK_NE(static_cast<int>(uid1), static_cast<int>(uid3));
CHECK_EQ(s3, v8::HeapProfiler::FindSnapshot(uid3));
const_cast<v8::HeapSnapshot*>(s2)->Delete();
CHECK_EQ(1, v8::HeapProfiler::GetSnapshotsCount());
CHECK_EQ(NULL, v8::HeapProfiler::FindSnapshot(uid2));
CHECK_EQ(s3, v8::HeapProfiler::FindSnapshot(uid3));
const_cast<v8::HeapSnapshot*>(s3)->Delete();
CHECK_EQ(0, v8::HeapProfiler::GetSnapshotsCount());
CHECK_EQ(NULL, v8::HeapProfiler::FindSnapshot(uid3));
}
#endif // ENABLE_LOGGING_AND_PROFILING