v8/test/cctest/test-profile-generator.cc
danno@chromium.org ed3809c318 Maintain API compatibility with older versions of V8.
Revert "Allow recording individual samples in addition to the aggregated CPU profiles"
Revert "Isolatify CPU profiler"
Revert "Isolatify HeapProfiler"
Revert "Deprecate HeapSnapshot type"
Revert "Isolatify CPU profiler public API"
Revert "MSVS compilation fix after r14006"
Revert "Add methods to allow resuming execution after calling TerminateExecution()."

R=jkummerow@chromium.org,mstarzinger@chromium.org

Review URL: https://codereview.chromium.org/12475016

git-svn-id: http://v8.googlecode.com/svn/branches/bleeding_edge@14031 ce2b1a6d-e550-0410-aec6-3dcde31c8c00
2013-03-21 14:42:17 +00:00

849 lines
32 KiB
C++

// Copyright 2010 the V8 project authors. All rights reserved.
// Redistribution and use in source and binary forms, with or without
// modification, are permitted provided that the following conditions are
// met:
//
// * Redistributions of source code must retain the above copyright
// notice, this list of conditions and the following disclaimer.
// * Redistributions in binary form must reproduce the above
// copyright notice, this list of conditions and the following
// disclaimer in the documentation and/or other materials provided
// with the distribution.
// * Neither the name of Google Inc. nor the names of its
// contributors may be used to endorse or promote products derived
// from this software without specific prior written permission.
//
// THIS SOFTWARE IS PROVIDED BY THE COPYRIGHT HOLDERS AND CONTRIBUTORS
// "AS IS" AND ANY EXPRESS OR IMPLIED WARRANTIES, INCLUDING, BUT NOT
// LIMITED TO, THE IMPLIED WARRANTIES OF MERCHANTABILITY AND FITNESS FOR
// A PARTICULAR PURPOSE ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT
// OWNER OR CONTRIBUTORS BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL,
// SPECIAL, EXEMPLARY, OR CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT
// LIMITED TO, PROCUREMENT OF SUBSTITUTE GOODS OR SERVICES; LOSS OF USE,
// DATA, OR PROFITS; OR BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY
// THEORY OF LIABILITY, WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT
// (INCLUDING NEGLIGENCE OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE
// OF THIS SOFTWARE, EVEN IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
//
// Tests of profiles generator and utilities.
#include "v8.h"
#include "profile-generator-inl.h"
#include "cctest.h"
#include "../include/v8-profiler.h"
using i::CodeEntry;
using i::CodeMap;
using i::CpuProfile;
using i::CpuProfiler;
using i::CpuProfilesCollection;
using i::ProfileNode;
using i::ProfileTree;
using i::ProfileGenerator;
using i::SampleRateCalculator;
using i::TickSample;
using i::TokenEnumerator;
using i::Vector;
namespace v8 {
namespace internal {
class TokenEnumeratorTester {
public:
static i::List<bool>* token_removed(TokenEnumerator* te) {
return &te->token_removed_;
}
};
} } // namespace v8::internal
TEST(TokenEnumerator) {
TokenEnumerator te;
CHECK_EQ(TokenEnumerator::kNoSecurityToken, te.GetTokenId(NULL));
v8::HandleScope hs(v8::Isolate::GetCurrent());
v8::Local<v8::String> token1(v8::String::New("1x"));
CHECK_EQ(0, te.GetTokenId(*v8::Utils::OpenHandle(*token1)));
CHECK_EQ(0, te.GetTokenId(*v8::Utils::OpenHandle(*token1)));
v8::Local<v8::String> token2(v8::String::New("2x"));
CHECK_EQ(1, te.GetTokenId(*v8::Utils::OpenHandle(*token2)));
CHECK_EQ(1, te.GetTokenId(*v8::Utils::OpenHandle(*token2)));
CHECK_EQ(0, te.GetTokenId(*v8::Utils::OpenHandle(*token1)));
{
v8::HandleScope hs(v8::Isolate::GetCurrent());
v8::Local<v8::String> token3(v8::String::New("3x"));
CHECK_EQ(2, te.GetTokenId(*v8::Utils::OpenHandle(*token3)));
CHECK_EQ(1, te.GetTokenId(*v8::Utils::OpenHandle(*token2)));
CHECK_EQ(0, te.GetTokenId(*v8::Utils::OpenHandle(*token1)));
}
CHECK(!i::TokenEnumeratorTester::token_removed(&te)->at(2));
HEAP->CollectAllGarbage(i::Heap::kNoGCFlags);
CHECK(i::TokenEnumeratorTester::token_removed(&te)->at(2));
CHECK_EQ(1, te.GetTokenId(*v8::Utils::OpenHandle(*token2)));
CHECK_EQ(0, te.GetTokenId(*v8::Utils::OpenHandle(*token1)));
}
TEST(ProfileNodeFindOrAddChild) {
ProfileNode node(NULL, NULL);
CodeEntry entry1(i::Logger::FUNCTION_TAG, "", "aaa", "", 0,
TokenEnumerator::kNoSecurityToken);
ProfileNode* childNode1 = node.FindOrAddChild(&entry1);
CHECK_NE(NULL, childNode1);
CHECK_EQ(childNode1, node.FindOrAddChild(&entry1));
CodeEntry entry2(i::Logger::FUNCTION_TAG, "", "bbb", "", 0,
TokenEnumerator::kNoSecurityToken);
ProfileNode* childNode2 = node.FindOrAddChild(&entry2);
CHECK_NE(NULL, childNode2);
CHECK_NE(childNode1, childNode2);
CHECK_EQ(childNode1, node.FindOrAddChild(&entry1));
CHECK_EQ(childNode2, node.FindOrAddChild(&entry2));
CodeEntry entry3(i::Logger::FUNCTION_TAG, "", "ccc", "", 0,
TokenEnumerator::kNoSecurityToken);
ProfileNode* childNode3 = node.FindOrAddChild(&entry3);
CHECK_NE(NULL, childNode3);
CHECK_NE(childNode1, childNode3);
CHECK_NE(childNode2, childNode3);
CHECK_EQ(childNode1, node.FindOrAddChild(&entry1));
CHECK_EQ(childNode2, node.FindOrAddChild(&entry2));
CHECK_EQ(childNode3, node.FindOrAddChild(&entry3));
}
TEST(ProfileNodeFindOrAddChildForSameFunction) {
const char* empty = "";
const char* aaa = "aaa";
ProfileNode node(NULL, NULL);
CodeEntry entry1(i::Logger::FUNCTION_TAG, empty, aaa, empty, 0,
TokenEnumerator::kNoSecurityToken);
ProfileNode* childNode1 = node.FindOrAddChild(&entry1);
CHECK_NE(NULL, childNode1);
CHECK_EQ(childNode1, node.FindOrAddChild(&entry1));
// The same function again.
CodeEntry entry2(i::Logger::FUNCTION_TAG, empty, aaa, empty, 0,
TokenEnumerator::kNoSecurityToken);
CHECK_EQ(childNode1, node.FindOrAddChild(&entry2));
// Now with a different security token.
CodeEntry entry3(i::Logger::FUNCTION_TAG, empty, aaa, empty, 0,
TokenEnumerator::kNoSecurityToken + 1);
CHECK_EQ(childNode1, node.FindOrAddChild(&entry3));
}
namespace {
class ProfileTreeTestHelper {
public:
explicit ProfileTreeTestHelper(const ProfileTree* tree)
: tree_(tree) { }
ProfileNode* Walk(CodeEntry* entry1,
CodeEntry* entry2 = NULL,
CodeEntry* entry3 = NULL) {
ProfileNode* node = tree_->root();
node = node->FindChild(entry1);
if (node == NULL) return NULL;
if (entry2 != NULL) {
node = node->FindChild(entry2);
if (node == NULL) return NULL;
}
if (entry3 != NULL) {
node = node->FindChild(entry3);
}
return node;
}
private:
const ProfileTree* tree_;
};
} // namespace
TEST(ProfileTreeAddPathFromStart) {
CodeEntry entry1(i::Logger::FUNCTION_TAG, "", "aaa", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry2(i::Logger::FUNCTION_TAG, "", "bbb", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry3(i::Logger::FUNCTION_TAG, "", "ccc", "", 0,
TokenEnumerator::kNoSecurityToken);
ProfileTree tree;
ProfileTreeTestHelper helper(&tree);
CHECK_EQ(NULL, helper.Walk(&entry1));
CHECK_EQ(NULL, helper.Walk(&entry2));
CHECK_EQ(NULL, helper.Walk(&entry3));
CodeEntry* path[] = {NULL, &entry1, NULL, &entry2, NULL, NULL, &entry3, NULL};
Vector<CodeEntry*> path_vec(path, sizeof(path) / sizeof(path[0]));
tree.AddPathFromStart(path_vec);
CHECK_EQ(NULL, helper.Walk(&entry2));
CHECK_EQ(NULL, helper.Walk(&entry3));
ProfileNode* node1 = helper.Walk(&entry1);
CHECK_NE(NULL, node1);
CHECK_EQ(0, node1->total_ticks());
CHECK_EQ(0, node1->self_ticks());
CHECK_EQ(NULL, helper.Walk(&entry1, &entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry3));
ProfileNode* node2 = helper.Walk(&entry1, &entry2);
CHECK_NE(NULL, node2);
CHECK_NE(node1, node2);
CHECK_EQ(0, node2->total_ticks());
CHECK_EQ(0, node2->self_ticks());
CHECK_EQ(NULL, helper.Walk(&entry1, &entry2, &entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry2, &entry2));
ProfileNode* node3 = helper.Walk(&entry1, &entry2, &entry3);
CHECK_NE(NULL, node3);
CHECK_NE(node1, node3);
CHECK_NE(node2, node3);
CHECK_EQ(0, node3->total_ticks());
CHECK_EQ(1, node3->self_ticks());
tree.AddPathFromStart(path_vec);
CHECK_EQ(node1, helper.Walk(&entry1));
CHECK_EQ(node2, helper.Walk(&entry1, &entry2));
CHECK_EQ(node3, helper.Walk(&entry1, &entry2, &entry3));
CHECK_EQ(0, node1->total_ticks());
CHECK_EQ(0, node1->self_ticks());
CHECK_EQ(0, node2->total_ticks());
CHECK_EQ(0, node2->self_ticks());
CHECK_EQ(0, node3->total_ticks());
CHECK_EQ(2, node3->self_ticks());
CodeEntry* path2[] = {&entry1, &entry2, &entry2};
Vector<CodeEntry*> path2_vec(path2, sizeof(path2) / sizeof(path2[0]));
tree.AddPathFromStart(path2_vec);
CHECK_EQ(NULL, helper.Walk(&entry2));
CHECK_EQ(NULL, helper.Walk(&entry3));
CHECK_EQ(node1, helper.Walk(&entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry3));
CHECK_EQ(node2, helper.Walk(&entry1, &entry2));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry2, &entry1));
CHECK_EQ(node3, helper.Walk(&entry1, &entry2, &entry3));
CHECK_EQ(0, node3->total_ticks());
CHECK_EQ(2, node3->self_ticks());
ProfileNode* node4 = helper.Walk(&entry1, &entry2, &entry2);
CHECK_NE(NULL, node4);
CHECK_NE(node3, node4);
CHECK_EQ(0, node4->total_ticks());
CHECK_EQ(1, node4->self_ticks());
}
TEST(ProfileTreeAddPathFromEnd) {
CodeEntry entry1(i::Logger::FUNCTION_TAG, "", "aaa", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry2(i::Logger::FUNCTION_TAG, "", "bbb", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry3(i::Logger::FUNCTION_TAG, "", "ccc", "", 0,
TokenEnumerator::kNoSecurityToken);
ProfileTree tree;
ProfileTreeTestHelper helper(&tree);
CHECK_EQ(NULL, helper.Walk(&entry1));
CHECK_EQ(NULL, helper.Walk(&entry2));
CHECK_EQ(NULL, helper.Walk(&entry3));
CodeEntry* path[] = {NULL, &entry3, NULL, &entry2, NULL, NULL, &entry1, NULL};
Vector<CodeEntry*> path_vec(path, sizeof(path) / sizeof(path[0]));
tree.AddPathFromEnd(path_vec);
CHECK_EQ(NULL, helper.Walk(&entry2));
CHECK_EQ(NULL, helper.Walk(&entry3));
ProfileNode* node1 = helper.Walk(&entry1);
CHECK_NE(NULL, node1);
CHECK_EQ(0, node1->total_ticks());
CHECK_EQ(0, node1->self_ticks());
CHECK_EQ(NULL, helper.Walk(&entry1, &entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry3));
ProfileNode* node2 = helper.Walk(&entry1, &entry2);
CHECK_NE(NULL, node2);
CHECK_NE(node1, node2);
CHECK_EQ(0, node2->total_ticks());
CHECK_EQ(0, node2->self_ticks());
CHECK_EQ(NULL, helper.Walk(&entry1, &entry2, &entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry2, &entry2));
ProfileNode* node3 = helper.Walk(&entry1, &entry2, &entry3);
CHECK_NE(NULL, node3);
CHECK_NE(node1, node3);
CHECK_NE(node2, node3);
CHECK_EQ(0, node3->total_ticks());
CHECK_EQ(1, node3->self_ticks());
tree.AddPathFromEnd(path_vec);
CHECK_EQ(node1, helper.Walk(&entry1));
CHECK_EQ(node2, helper.Walk(&entry1, &entry2));
CHECK_EQ(node3, helper.Walk(&entry1, &entry2, &entry3));
CHECK_EQ(0, node1->total_ticks());
CHECK_EQ(0, node1->self_ticks());
CHECK_EQ(0, node2->total_ticks());
CHECK_EQ(0, node2->self_ticks());
CHECK_EQ(0, node3->total_ticks());
CHECK_EQ(2, node3->self_ticks());
CodeEntry* path2[] = {&entry2, &entry2, &entry1};
Vector<CodeEntry*> path2_vec(path2, sizeof(path2) / sizeof(path2[0]));
tree.AddPathFromEnd(path2_vec);
CHECK_EQ(NULL, helper.Walk(&entry2));
CHECK_EQ(NULL, helper.Walk(&entry3));
CHECK_EQ(node1, helper.Walk(&entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry1));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry3));
CHECK_EQ(node2, helper.Walk(&entry1, &entry2));
CHECK_EQ(NULL, helper.Walk(&entry1, &entry2, &entry1));
CHECK_EQ(node3, helper.Walk(&entry1, &entry2, &entry3));
CHECK_EQ(0, node3->total_ticks());
CHECK_EQ(2, node3->self_ticks());
ProfileNode* node4 = helper.Walk(&entry1, &entry2, &entry2);
CHECK_NE(NULL, node4);
CHECK_NE(node3, node4);
CHECK_EQ(0, node4->total_ticks());
CHECK_EQ(1, node4->self_ticks());
}
TEST(ProfileTreeCalculateTotalTicks) {
ProfileTree empty_tree;
CHECK_EQ(0, empty_tree.root()->total_ticks());
CHECK_EQ(0, empty_tree.root()->self_ticks());
empty_tree.CalculateTotalTicks();
CHECK_EQ(0, empty_tree.root()->total_ticks());
CHECK_EQ(0, empty_tree.root()->self_ticks());
empty_tree.root()->IncrementSelfTicks();
CHECK_EQ(0, empty_tree.root()->total_ticks());
CHECK_EQ(1, empty_tree.root()->self_ticks());
empty_tree.CalculateTotalTicks();
CHECK_EQ(1, empty_tree.root()->total_ticks());
CHECK_EQ(1, empty_tree.root()->self_ticks());
CodeEntry entry1(i::Logger::FUNCTION_TAG, "", "aaa", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry* e1_path[] = {&entry1};
Vector<CodeEntry*> e1_path_vec(
e1_path, sizeof(e1_path) / sizeof(e1_path[0]));
ProfileTree single_child_tree;
single_child_tree.AddPathFromStart(e1_path_vec);
single_child_tree.root()->IncrementSelfTicks();
CHECK_EQ(0, single_child_tree.root()->total_ticks());
CHECK_EQ(1, single_child_tree.root()->self_ticks());
ProfileTreeTestHelper single_child_helper(&single_child_tree);
ProfileNode* node1 = single_child_helper.Walk(&entry1);
CHECK_NE(NULL, node1);
CHECK_EQ(0, node1->total_ticks());
CHECK_EQ(1, node1->self_ticks());
single_child_tree.CalculateTotalTicks();
CHECK_EQ(2, single_child_tree.root()->total_ticks());
CHECK_EQ(1, single_child_tree.root()->self_ticks());
CHECK_EQ(1, node1->total_ticks());
CHECK_EQ(1, node1->self_ticks());
CodeEntry entry2(i::Logger::FUNCTION_TAG, "", "bbb", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry* e1_e2_path[] = {&entry1, &entry2};
Vector<CodeEntry*> e1_e2_path_vec(
e1_e2_path, sizeof(e1_e2_path) / sizeof(e1_e2_path[0]));
ProfileTree flat_tree;
ProfileTreeTestHelper flat_helper(&flat_tree);
flat_tree.AddPathFromStart(e1_path_vec);
flat_tree.AddPathFromStart(e1_path_vec);
flat_tree.AddPathFromStart(e1_e2_path_vec);
flat_tree.AddPathFromStart(e1_e2_path_vec);
flat_tree.AddPathFromStart(e1_e2_path_vec);
// Results in {root,0,0} -> {entry1,0,2} -> {entry2,0,3}
CHECK_EQ(0, flat_tree.root()->total_ticks());
CHECK_EQ(0, flat_tree.root()->self_ticks());
node1 = flat_helper.Walk(&entry1);
CHECK_NE(NULL, node1);
CHECK_EQ(0, node1->total_ticks());
CHECK_EQ(2, node1->self_ticks());
ProfileNode* node2 = flat_helper.Walk(&entry1, &entry2);
CHECK_NE(NULL, node2);
CHECK_EQ(0, node2->total_ticks());
CHECK_EQ(3, node2->self_ticks());
flat_tree.CalculateTotalTicks();
// Must calculate {root,5,0} -> {entry1,5,2} -> {entry2,3,3}
CHECK_EQ(5, flat_tree.root()->total_ticks());
CHECK_EQ(0, flat_tree.root()->self_ticks());
CHECK_EQ(5, node1->total_ticks());
CHECK_EQ(2, node1->self_ticks());
CHECK_EQ(3, node2->total_ticks());
CHECK_EQ(3, node2->self_ticks());
CodeEntry* e2_path[] = {&entry2};
Vector<CodeEntry*> e2_path_vec(
e2_path, sizeof(e2_path) / sizeof(e2_path[0]));
CodeEntry entry3(i::Logger::FUNCTION_TAG, "", "ccc", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry* e3_path[] = {&entry3};
Vector<CodeEntry*> e3_path_vec(
e3_path, sizeof(e3_path) / sizeof(e3_path[0]));
ProfileTree wide_tree;
ProfileTreeTestHelper wide_helper(&wide_tree);
wide_tree.AddPathFromStart(e1_path_vec);
wide_tree.AddPathFromStart(e1_path_vec);
wide_tree.AddPathFromStart(e1_e2_path_vec);
wide_tree.AddPathFromStart(e2_path_vec);
wide_tree.AddPathFromStart(e2_path_vec);
wide_tree.AddPathFromStart(e2_path_vec);
wide_tree.AddPathFromStart(e3_path_vec);
wide_tree.AddPathFromStart(e3_path_vec);
wide_tree.AddPathFromStart(e3_path_vec);
wide_tree.AddPathFromStart(e3_path_vec);
// Results in -> {entry1,0,2} -> {entry2,0,1}
// {root,0,0} -> {entry2,0,3}
// -> {entry3,0,4}
CHECK_EQ(0, wide_tree.root()->total_ticks());
CHECK_EQ(0, wide_tree.root()->self_ticks());
node1 = wide_helper.Walk(&entry1);
CHECK_NE(NULL, node1);
CHECK_EQ(0, node1->total_ticks());
CHECK_EQ(2, node1->self_ticks());
ProfileNode* node1_2 = wide_helper.Walk(&entry1, &entry2);
CHECK_NE(NULL, node1_2);
CHECK_EQ(0, node1_2->total_ticks());
CHECK_EQ(1, node1_2->self_ticks());
node2 = wide_helper.Walk(&entry2);
CHECK_NE(NULL, node2);
CHECK_EQ(0, node2->total_ticks());
CHECK_EQ(3, node2->self_ticks());
ProfileNode* node3 = wide_helper.Walk(&entry3);
CHECK_NE(NULL, node3);
CHECK_EQ(0, node3->total_ticks());
CHECK_EQ(4, node3->self_ticks());
wide_tree.CalculateTotalTicks();
// Calculates -> {entry1,3,2} -> {entry2,1,1}
// {root,10,0} -> {entry2,3,3}
// -> {entry3,4,4}
CHECK_EQ(10, wide_tree.root()->total_ticks());
CHECK_EQ(0, wide_tree.root()->self_ticks());
CHECK_EQ(3, node1->total_ticks());
CHECK_EQ(2, node1->self_ticks());
CHECK_EQ(1, node1_2->total_ticks());
CHECK_EQ(1, node1_2->self_ticks());
CHECK_EQ(3, node2->total_ticks());
CHECK_EQ(3, node2->self_ticks());
CHECK_EQ(4, node3->total_ticks());
CHECK_EQ(4, node3->self_ticks());
}
TEST(ProfileTreeFilteredClone) {
ProfileTree source_tree;
const int token0 = 0, token1 = 1, token2 = 2;
CodeEntry entry1(i::Logger::FUNCTION_TAG, "", "aaa", "", 0, token0);
CodeEntry entry2(i::Logger::FUNCTION_TAG, "", "bbb", "", 0, token1);
CodeEntry entry3(i::Logger::FUNCTION_TAG, "", "ccc", "", 0, token0);
CodeEntry entry4(
i::Logger::FUNCTION_TAG, "", "ddd", "", 0,
TokenEnumerator::kInheritsSecurityToken);
{
CodeEntry* e1_e2_path[] = {&entry1, &entry2};
Vector<CodeEntry*> e1_e2_path_vec(
e1_e2_path, sizeof(e1_e2_path) / sizeof(e1_e2_path[0]));
source_tree.AddPathFromStart(e1_e2_path_vec);
CodeEntry* e2_e4_path[] = {&entry2, &entry4};
Vector<CodeEntry*> e2_e4_path_vec(
e2_e4_path, sizeof(e2_e4_path) / sizeof(e2_e4_path[0]));
source_tree.AddPathFromStart(e2_e4_path_vec);
CodeEntry* e3_e1_path[] = {&entry3, &entry1};
Vector<CodeEntry*> e3_e1_path_vec(
e3_e1_path, sizeof(e3_e1_path) / sizeof(e3_e1_path[0]));
source_tree.AddPathFromStart(e3_e1_path_vec);
CodeEntry* e3_e2_path[] = {&entry3, &entry2};
Vector<CodeEntry*> e3_e2_path_vec(
e3_e2_path, sizeof(e3_e2_path) / sizeof(e3_e2_path[0]));
source_tree.AddPathFromStart(e3_e2_path_vec);
source_tree.CalculateTotalTicks();
// Results in -> {entry1,0,1,0} -> {entry2,1,1,1}
// {root,0,4,-1} -> {entry2,0,1,1} -> {entry4,1,1,inherits}
// -> {entry3,0,2,0} -> {entry1,1,1,0}
// -> {entry2,1,1,1}
CHECK_EQ(4, source_tree.root()->total_ticks());
CHECK_EQ(0, source_tree.root()->self_ticks());
}
{
ProfileTree token0_tree;
token0_tree.FilteredClone(&source_tree, token0);
// Should be -> {entry1,1,1,0}
// {root,1,4,-1} -> {entry3,1,2,0} -> {entry1,1,1,0}
// [self ticks from filtered nodes are attributed to their parents]
CHECK_EQ(4, token0_tree.root()->total_ticks());
CHECK_EQ(1, token0_tree.root()->self_ticks());
ProfileTreeTestHelper token0_helper(&token0_tree);
ProfileNode* node1 = token0_helper.Walk(&entry1);
CHECK_NE(NULL, node1);
CHECK_EQ(1, node1->total_ticks());
CHECK_EQ(1, node1->self_ticks());
CHECK_EQ(NULL, token0_helper.Walk(&entry2));
ProfileNode* node3 = token0_helper.Walk(&entry3);
CHECK_NE(NULL, node3);
CHECK_EQ(2, node3->total_ticks());
CHECK_EQ(1, node3->self_ticks());
ProfileNode* node3_1 = token0_helper.Walk(&entry3, &entry1);
CHECK_NE(NULL, node3_1);
CHECK_EQ(1, node3_1->total_ticks());
CHECK_EQ(1, node3_1->self_ticks());
CHECK_EQ(NULL, token0_helper.Walk(&entry3, &entry2));
}
{
ProfileTree token1_tree;
token1_tree.FilteredClone(&source_tree, token1);
// Should be
// {root,1,4,-1} -> {entry2,2,3,1} -> {entry4,1,1,inherits}
// [child nodes referring to the same entry get merged and
// their self times summed up]
CHECK_EQ(4, token1_tree.root()->total_ticks());
CHECK_EQ(1, token1_tree.root()->self_ticks());
ProfileTreeTestHelper token1_helper(&token1_tree);
CHECK_EQ(NULL, token1_helper.Walk(&entry1));
CHECK_EQ(NULL, token1_helper.Walk(&entry3));
ProfileNode* node2 = token1_helper.Walk(&entry2);
CHECK_NE(NULL, node2);
CHECK_EQ(3, node2->total_ticks());
CHECK_EQ(2, node2->self_ticks());
ProfileNode* node2_4 = token1_helper.Walk(&entry2, &entry4);
CHECK_NE(NULL, node2_4);
CHECK_EQ(1, node2_4->total_ticks());
CHECK_EQ(1, node2_4->self_ticks());
}
{
ProfileTree token2_tree;
token2_tree.FilteredClone(&source_tree, token2);
// Should be
// {root,4,4,-1}
// [no nodes, all ticks get migrated into root node]
CHECK_EQ(4, token2_tree.root()->total_ticks());
CHECK_EQ(4, token2_tree.root()->self_ticks());
ProfileTreeTestHelper token2_helper(&token2_tree);
CHECK_EQ(NULL, token2_helper.Walk(&entry1));
CHECK_EQ(NULL, token2_helper.Walk(&entry2));
CHECK_EQ(NULL, token2_helper.Walk(&entry3));
}
}
static inline i::Address ToAddress(int n) {
return reinterpret_cast<i::Address>(n);
}
TEST(CodeMapAddCode) {
CodeMap code_map;
CodeEntry entry1(i::Logger::FUNCTION_TAG, "", "aaa", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry2(i::Logger::FUNCTION_TAG, "", "bbb", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry3(i::Logger::FUNCTION_TAG, "", "ccc", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry4(i::Logger::FUNCTION_TAG, "", "ddd", "", 0,
TokenEnumerator::kNoSecurityToken);
code_map.AddCode(ToAddress(0x1500), &entry1, 0x200);
code_map.AddCode(ToAddress(0x1700), &entry2, 0x100);
code_map.AddCode(ToAddress(0x1900), &entry3, 0x50);
code_map.AddCode(ToAddress(0x1950), &entry4, 0x10);
CHECK_EQ(NULL, code_map.FindEntry(0));
CHECK_EQ(NULL, code_map.FindEntry(ToAddress(0x1500 - 1)));
CHECK_EQ(&entry1, code_map.FindEntry(ToAddress(0x1500)));
CHECK_EQ(&entry1, code_map.FindEntry(ToAddress(0x1500 + 0x100)));
CHECK_EQ(&entry1, code_map.FindEntry(ToAddress(0x1500 + 0x200 - 1)));
CHECK_EQ(&entry2, code_map.FindEntry(ToAddress(0x1700)));
CHECK_EQ(&entry2, code_map.FindEntry(ToAddress(0x1700 + 0x50)));
CHECK_EQ(&entry2, code_map.FindEntry(ToAddress(0x1700 + 0x100 - 1)));
CHECK_EQ(NULL, code_map.FindEntry(ToAddress(0x1700 + 0x100)));
CHECK_EQ(NULL, code_map.FindEntry(ToAddress(0x1900 - 1)));
CHECK_EQ(&entry3, code_map.FindEntry(ToAddress(0x1900)));
CHECK_EQ(&entry3, code_map.FindEntry(ToAddress(0x1900 + 0x28)));
CHECK_EQ(&entry4, code_map.FindEntry(ToAddress(0x1950)));
CHECK_EQ(&entry4, code_map.FindEntry(ToAddress(0x1950 + 0x7)));
CHECK_EQ(&entry4, code_map.FindEntry(ToAddress(0x1950 + 0x10 - 1)));
CHECK_EQ(NULL, code_map.FindEntry(ToAddress(0x1950 + 0x10)));
CHECK_EQ(NULL, code_map.FindEntry(ToAddress(0xFFFFFFFF)));
}
TEST(CodeMapMoveAndDeleteCode) {
CodeMap code_map;
CodeEntry entry1(i::Logger::FUNCTION_TAG, "", "aaa", "", 0,
TokenEnumerator::kNoSecurityToken);
CodeEntry entry2(i::Logger::FUNCTION_TAG, "", "bbb", "", 0,
TokenEnumerator::kNoSecurityToken);
code_map.AddCode(ToAddress(0x1500), &entry1, 0x200);
code_map.AddCode(ToAddress(0x1700), &entry2, 0x100);
CHECK_EQ(&entry1, code_map.FindEntry(ToAddress(0x1500)));
CHECK_EQ(&entry2, code_map.FindEntry(ToAddress(0x1700)));
code_map.MoveCode(ToAddress(0x1500), ToAddress(0x1700)); // Deprecate bbb.
CHECK_EQ(NULL, code_map.FindEntry(ToAddress(0x1500)));
CHECK_EQ(&entry1, code_map.FindEntry(ToAddress(0x1700)));
CodeEntry entry3(i::Logger::FUNCTION_TAG, "", "ccc", "", 0,
TokenEnumerator::kNoSecurityToken);
code_map.AddCode(ToAddress(0x1750), &entry3, 0x100);
CHECK_EQ(NULL, code_map.FindEntry(ToAddress(0x1700)));
CHECK_EQ(&entry3, code_map.FindEntry(ToAddress(0x1750)));
}
namespace {
class TestSetup {
public:
TestSetup()
: old_flag_prof_browser_mode_(i::FLAG_prof_browser_mode) {
i::FLAG_prof_browser_mode = false;
}
~TestSetup() {
i::FLAG_prof_browser_mode = old_flag_prof_browser_mode_;
}
private:
bool old_flag_prof_browser_mode_;
};
} // namespace
TEST(RecordTickSample) {
TestSetup test_setup;
CpuProfilesCollection profiles;
profiles.StartProfiling("", 1);
ProfileGenerator generator(&profiles);
CodeEntry* entry1 = generator.NewCodeEntry(i::Logger::FUNCTION_TAG, "aaa");
CodeEntry* entry2 = generator.NewCodeEntry(i::Logger::FUNCTION_TAG, "bbb");
CodeEntry* entry3 = generator.NewCodeEntry(i::Logger::FUNCTION_TAG, "ccc");
generator.code_map()->AddCode(ToAddress(0x1500), entry1, 0x200);
generator.code_map()->AddCode(ToAddress(0x1700), entry2, 0x100);
generator.code_map()->AddCode(ToAddress(0x1900), entry3, 0x50);
// We are building the following calls tree:
// -> aaa - sample1
// aaa -> bbb -> ccc - sample2
// -> ccc -> aaa - sample3
TickSample sample1;
sample1.pc = ToAddress(0x1600);
sample1.tos = ToAddress(0x1500);
sample1.stack[0] = ToAddress(0x1510);
sample1.frames_count = 1;
generator.RecordTickSample(sample1);
TickSample sample2;
sample2.pc = ToAddress(0x1925);
sample2.tos = ToAddress(0x1900);
sample2.stack[0] = ToAddress(0x1780);
sample2.stack[1] = ToAddress(0x10000); // non-existent.
sample2.stack[2] = ToAddress(0x1620);
sample2.frames_count = 3;
generator.RecordTickSample(sample2);
TickSample sample3;
sample3.pc = ToAddress(0x1510);
sample3.tos = ToAddress(0x1500);
sample3.stack[0] = ToAddress(0x1910);
sample3.stack[1] = ToAddress(0x1610);
sample3.frames_count = 2;
generator.RecordTickSample(sample3);
CpuProfile* profile =
profiles.StopProfiling(TokenEnumerator::kNoSecurityToken, "", 1);
CHECK_NE(NULL, profile);
ProfileTreeTestHelper top_down_test_helper(profile->top_down());
CHECK_EQ(NULL, top_down_test_helper.Walk(entry2));
CHECK_EQ(NULL, top_down_test_helper.Walk(entry3));
ProfileNode* node1 = top_down_test_helper.Walk(entry1);
CHECK_NE(NULL, node1);
CHECK_EQ(entry1, node1->entry());
ProfileNode* node2 = top_down_test_helper.Walk(entry1, entry1);
CHECK_NE(NULL, node2);
CHECK_EQ(entry1, node2->entry());
ProfileNode* node3 = top_down_test_helper.Walk(entry1, entry2, entry3);
CHECK_NE(NULL, node3);
CHECK_EQ(entry3, node3->entry());
ProfileNode* node4 = top_down_test_helper.Walk(entry1, entry3, entry1);
CHECK_NE(NULL, node4);
CHECK_EQ(entry1, node4->entry());
}
TEST(SampleRateCalculator) {
const double kSamplingIntervalMs = i::Logger::kSamplingIntervalMs;
// Verify that ticking exactly in query intervals results in the
// initial sampling interval.
double time = 0.0;
SampleRateCalculator calc1;
CHECK_EQ(kSamplingIntervalMs, calc1.ticks_per_ms());
calc1.UpdateMeasurements(time);
CHECK_EQ(kSamplingIntervalMs, calc1.ticks_per_ms());
time += SampleRateCalculator::kWallTimeQueryIntervalMs;
calc1.UpdateMeasurements(time);
CHECK_EQ(kSamplingIntervalMs, calc1.ticks_per_ms());
time += SampleRateCalculator::kWallTimeQueryIntervalMs;
calc1.UpdateMeasurements(time);
CHECK_EQ(kSamplingIntervalMs, calc1.ticks_per_ms());
time += SampleRateCalculator::kWallTimeQueryIntervalMs;
calc1.UpdateMeasurements(time);
CHECK_EQ(kSamplingIntervalMs, calc1.ticks_per_ms());
SampleRateCalculator calc2;
time = 0.0;
CHECK_EQ(kSamplingIntervalMs, calc2.ticks_per_ms());
calc2.UpdateMeasurements(time);
CHECK_EQ(kSamplingIntervalMs, calc2.ticks_per_ms());
time += SampleRateCalculator::kWallTimeQueryIntervalMs * 0.5;
calc2.UpdateMeasurements(time);
// (1.0 + 2.0) / 2
CHECK_EQ(kSamplingIntervalMs * 1.5, calc2.ticks_per_ms());
time += SampleRateCalculator::kWallTimeQueryIntervalMs * 0.75;
calc2.UpdateMeasurements(time);
// (1.0 + 2.0 + 2.0) / 3
CHECK_EQ(kSamplingIntervalMs * 5.0, floor(calc2.ticks_per_ms() * 3.0 + 0.5));
SampleRateCalculator calc3;
time = 0.0;
CHECK_EQ(kSamplingIntervalMs, calc3.ticks_per_ms());
calc3.UpdateMeasurements(time);
CHECK_EQ(kSamplingIntervalMs, calc3.ticks_per_ms());
time += SampleRateCalculator::kWallTimeQueryIntervalMs * 2;
calc3.UpdateMeasurements(time);
// (1.0 + 0.5) / 2
CHECK_EQ(kSamplingIntervalMs * 0.75, calc3.ticks_per_ms());
time += SampleRateCalculator::kWallTimeQueryIntervalMs * 1.5;
calc3.UpdateMeasurements(time);
// (1.0 + 0.5 + 0.5) / 3
CHECK_EQ(kSamplingIntervalMs * 2.0, floor(calc3.ticks_per_ms() * 3.0 + 0.5));
}
// --- P r o f i l e r E x t e n s i o n ---
class ProfilerExtension : public v8::Extension {
public:
ProfilerExtension() : v8::Extension("v8/profiler", kSource) { }
virtual v8::Handle<v8::FunctionTemplate> GetNativeFunction(
v8::Handle<v8::String> name);
static v8::Handle<v8::Value> StartProfiling(const v8::Arguments& args);
static v8::Handle<v8::Value> StopProfiling(const v8::Arguments& args);
private:
static const char* kSource;
};
const char* ProfilerExtension::kSource =
"native function startProfiling();"
"native function stopProfiling();";
v8::Handle<v8::FunctionTemplate> ProfilerExtension::GetNativeFunction(
v8::Handle<v8::String> name) {
if (name->Equals(v8::String::New("startProfiling"))) {
return v8::FunctionTemplate::New(ProfilerExtension::StartProfiling);
} else if (name->Equals(v8::String::New("stopProfiling"))) {
return v8::FunctionTemplate::New(ProfilerExtension::StopProfiling);
} else {
CHECK(false);
return v8::Handle<v8::FunctionTemplate>();
}
}
v8::Handle<v8::Value> ProfilerExtension::StartProfiling(
const v8::Arguments& args) {
if (args.Length() > 0)
v8::CpuProfiler::StartProfiling(args[0].As<v8::String>());
else
v8::CpuProfiler::StartProfiling(v8::String::New(""));
return v8::Undefined();
}
v8::Handle<v8::Value> ProfilerExtension::StopProfiling(
const v8::Arguments& args) {
if (args.Length() > 0)
v8::CpuProfiler::StopProfiling(args[0].As<v8::String>());
else
v8::CpuProfiler::StopProfiling(v8::String::New(""));
return v8::Undefined();
}
static ProfilerExtension kProfilerExtension;
v8::DeclareExtension kProfilerExtensionDeclaration(&kProfilerExtension);
static v8::Persistent<v8::Context> env;
static const ProfileNode* PickChild(const ProfileNode* parent,
const char* name) {
for (int i = 0; i < parent->children()->length(); ++i) {
const ProfileNode* child = parent->children()->at(i);
if (strcmp(child->entry()->name(), name) == 0) return child;
}
return NULL;
}
TEST(RecordStackTraceAtStartProfiling) {
// This test does not pass with inlining enabled since inlined functions
// don't appear in the stack trace.
i::FLAG_use_inlining = false;
if (env.IsEmpty()) {
v8::HandleScope scope(v8::Isolate::GetCurrent());
const char* extensions[] = { "v8/profiler" };
v8::ExtensionConfiguration config(1, extensions);
env = v8::Context::New(&config);
}
v8::HandleScope scope(v8::Isolate::GetCurrent());
env->Enter();
CHECK_EQ(0, CpuProfiler::GetProfilesCount());
CompileRun(
"function c() { startProfiling(); }\n"
"function b() { c(); }\n"
"function a() { b(); }\n"
"a();\n"
"stopProfiling();");
CHECK_EQ(1, CpuProfiler::GetProfilesCount());
CpuProfile* profile =
CpuProfiler::GetProfile(NULL, 0);
const ProfileTree* topDown = profile->top_down();
const ProfileNode* current = topDown->root();
const_cast<ProfileNode*>(current)->Print(0);
// The tree should look like this:
// (root)
// (anonymous function)
// a
// b
// c
// There can also be:
// startProfiling
// if the sampler managed to get a tick.
current = PickChild(current, "(anonymous function)");
CHECK_NE(NULL, const_cast<ProfileNode*>(current));
current = PickChild(current, "a");
CHECK_NE(NULL, const_cast<ProfileNode*>(current));
current = PickChild(current, "b");
CHECK_NE(NULL, const_cast<ProfileNode*>(current));
current = PickChild(current, "c");
CHECK_NE(NULL, const_cast<ProfileNode*>(current));
CHECK(current->children()->length() == 0 ||
current->children()->length() == 1);
if (current->children()->length() == 1) {
current = PickChild(current, "startProfiling");
CHECK_EQ(0, current->children()->length());
}
}
TEST(Issue51919) {
CpuProfilesCollection collection;
i::EmbeddedVector<char*,
CpuProfilesCollection::kMaxSimultaneousProfiles> titles;
for (int i = 0; i < CpuProfilesCollection::kMaxSimultaneousProfiles; ++i) {
i::Vector<char> title = i::Vector<char>::New(16);
i::OS::SNPrintF(title, "%d", i);
CHECK(collection.StartProfiling(title.start(), i + 1)); // UID must be > 0.
titles[i] = title.start();
}
CHECK(!collection.StartProfiling(
"maximum", CpuProfilesCollection::kMaxSimultaneousProfiles + 1));
for (int i = 0; i < CpuProfilesCollection::kMaxSimultaneousProfiles; ++i)
i::DeleteArray(titles[i]);
}