// Copyright (c) 2012 The Chromium 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 <math.h> #include <stddef.h> #include <stdint.h> #include <cstdlib> #include "base/bind.h" #include "base/command_line.h" #include "base/json/json_reader.h" #include "base/json/json_writer.h" #include "base/location.h" #include "base/macros.h" #include "base/memory/ref_counted_memory.h" #include "base/memory/scoped_ptr.h" #include "base/memory/singleton.h" #include "base/process/process_handle.h" #include "base/single_thread_task_runner.h" #include "base/stl_util.h" #include "base/strings/pattern.h" #include "base/strings/stringprintf.h" #include "base/synchronization/waitable_event.h" #include "base/threading/platform_thread.h" #include "base/threading/thread.h" #include "base/time/time.h" #include "base/trace_event/trace_buffer.h" #include "base/trace_event/trace_event.h" #include "base/trace_event/trace_event_synthetic_delay.h" #include "base/values.h" #include "testing/gmock/include/gmock/gmock.h" #include "testing/gtest/include/gtest/gtest.h" namespace base { namespace trace_event { namespace { enum CompareOp { IS_EQUAL, IS_NOT_EQUAL, }; struct JsonKeyValue { const char* key; const char* value; CompareOp op; }; const int kThreadId = 42; const int kAsyncId = 5; const char kAsyncIdStr[] = "0x5"; const int kAsyncId2 = 6; const char kAsyncId2Str[] = "0x6"; const int kFlowId = 7; const char kFlowIdStr[] = "0x7"; const char kRecordAllCategoryFilter[] = "*"; class TraceEventTestFixture : public testing::Test { public: void OnTraceDataCollected( WaitableEvent* flush_complete_event, const scoped_refptr<base::RefCountedString>& events_str, bool has_more_events); void OnWatchEventMatched() { ++event_watch_notification_; } DictionaryValue* FindMatchingTraceEntry(const JsonKeyValue* key_values); DictionaryValue* FindNamePhase(const char* name, const char* phase); DictionaryValue* FindNamePhaseKeyValue(const char* name, const char* phase, const char* key, const char* value); void DropTracedMetadataRecords(); bool FindMatchingValue(const char* key, const char* value); bool FindNonMatchingValue(const char* key, const char* value); void Clear() { trace_parsed_.Clear(); json_output_.json_output.clear(); } void BeginTrace() { BeginSpecificTrace("*"); } void BeginSpecificTrace(const std::string& filter) { event_watch_notification_ = 0; TraceLog::GetInstance()->SetEnabled(TraceConfig(filter, ""), TraceLog::RECORDING_MODE); } void CancelTrace() { WaitableEvent flush_complete_event(false, false); CancelTraceAsync(&flush_complete_event); flush_complete_event.Wait(); } void EndTraceAndFlush() { num_flush_callbacks_ = 0; WaitableEvent flush_complete_event(false, false); EndTraceAndFlushAsync(&flush_complete_event); flush_complete_event.Wait(); } // Used when testing thread-local buffers which requires the thread initiating // flush to have a message loop. void EndTraceAndFlushInThreadWithMessageLoop() { WaitableEvent flush_complete_event(false, false); Thread flush_thread("flush"); flush_thread.Start(); flush_thread.task_runner()->PostTask( FROM_HERE, base::Bind(&TraceEventTestFixture::EndTraceAndFlushAsync, base::Unretained(this), &flush_complete_event)); flush_complete_event.Wait(); } void CancelTraceAsync(WaitableEvent* flush_complete_event) { TraceLog::GetInstance()->CancelTracing( base::Bind(&TraceEventTestFixture::OnTraceDataCollected, base::Unretained(static_cast<TraceEventTestFixture*>(this)), base::Unretained(flush_complete_event))); } void EndTraceAndFlushAsync(WaitableEvent* flush_complete_event) { TraceLog::GetInstance()->SetDisabled(); TraceLog::GetInstance()->Flush( base::Bind(&TraceEventTestFixture::OnTraceDataCollected, base::Unretained(static_cast<TraceEventTestFixture*>(this)), base::Unretained(flush_complete_event))); } void FlushMonitoring() { WaitableEvent flush_complete_event(false, false); FlushMonitoring(&flush_complete_event); flush_complete_event.Wait(); } void FlushMonitoring(WaitableEvent* flush_complete_event) { TraceLog::GetInstance()->FlushButLeaveBufferIntact( base::Bind(&TraceEventTestFixture::OnTraceDataCollected, base::Unretained(static_cast<TraceEventTestFixture*>(this)), base::Unretained(flush_complete_event))); } void SetUp() override { const char* name = PlatformThread::GetName(); old_thread_name_ = name ? strdup(name) : NULL; TraceLog::DeleteForTesting(); TraceLog* tracelog = TraceLog::GetInstance(); ASSERT_TRUE(tracelog); ASSERT_FALSE(tracelog->IsEnabled()); trace_buffer_.SetOutputCallback(json_output_.GetCallback()); event_watch_notification_ = 0; num_flush_callbacks_ = 0; } void TearDown() override { if (TraceLog::GetInstance()) EXPECT_FALSE(TraceLog::GetInstance()->IsEnabled()); PlatformThread::SetName(old_thread_name_ ? old_thread_name_ : ""); free(old_thread_name_); old_thread_name_ = NULL; // We want our singleton torn down after each test. TraceLog::DeleteForTesting(); } char* old_thread_name_; ListValue trace_parsed_; TraceResultBuffer trace_buffer_; TraceResultBuffer::SimpleOutput json_output_; int event_watch_notification_; size_t num_flush_callbacks_; private: // We want our singleton torn down after each test. ShadowingAtExitManager at_exit_manager_; Lock lock_; }; void TraceEventTestFixture::OnTraceDataCollected( WaitableEvent* flush_complete_event, const scoped_refptr<base::RefCountedString>& events_str, bool has_more_events) { num_flush_callbacks_++; if (num_flush_callbacks_ > 1) { EXPECT_FALSE(events_str->data().empty()); } AutoLock lock(lock_); json_output_.json_output.clear(); trace_buffer_.Start(); trace_buffer_.AddFragment(events_str->data()); trace_buffer_.Finish(); scoped_ptr<Value> root = base::JSONReader::Read( json_output_.json_output, JSON_PARSE_RFC | JSON_DETACHABLE_CHILDREN); if (!root.get()) { LOG(ERROR) << json_output_.json_output; } ListValue* root_list = NULL; ASSERT_TRUE(root.get()); ASSERT_TRUE(root->GetAsList(&root_list)); // Move items into our aggregate collection while (root_list->GetSize()) { scoped_ptr<Value> item; root_list->Remove(0, &item); trace_parsed_.Append(item.release()); } if (!has_more_events) flush_complete_event->Signal(); } static bool CompareJsonValues(const std::string& lhs, const std::string& rhs, CompareOp op) { switch (op) { case IS_EQUAL: return lhs == rhs; case IS_NOT_EQUAL: return lhs != rhs; default: CHECK(0); } return false; } static bool IsKeyValueInDict(const JsonKeyValue* key_value, DictionaryValue* dict) { Value* value = NULL; std::string value_str; if (dict->Get(key_value->key, &value) && value->GetAsString(&value_str) && CompareJsonValues(value_str, key_value->value, key_value->op)) return true; // Recurse to test arguments DictionaryValue* args_dict = NULL; dict->GetDictionary("args", &args_dict); if (args_dict) return IsKeyValueInDict(key_value, args_dict); return false; } static bool IsAllKeyValueInDict(const JsonKeyValue* key_values, DictionaryValue* dict) { // Scan all key_values, they must all be present and equal. while (key_values && key_values->key) { if (!IsKeyValueInDict(key_values, dict)) return false; ++key_values; } return true; } DictionaryValue* TraceEventTestFixture::FindMatchingTraceEntry( const JsonKeyValue* key_values) { // Scan all items size_t trace_parsed_count = trace_parsed_.GetSize(); for (size_t i = 0; i < trace_parsed_count; i++) { Value* value = NULL; trace_parsed_.Get(i, &value); if (!value || value->GetType() != Value::TYPE_DICTIONARY) continue; DictionaryValue* dict = static_cast<DictionaryValue*>(value); if (IsAllKeyValueInDict(key_values, dict)) return dict; } return NULL; } void TraceEventTestFixture::DropTracedMetadataRecords() { scoped_ptr<ListValue> old_trace_parsed(trace_parsed_.DeepCopy()); size_t old_trace_parsed_size = old_trace_parsed->GetSize(); trace_parsed_.Clear(); for (size_t i = 0; i < old_trace_parsed_size; i++) { Value* value = NULL; old_trace_parsed->Get(i, &value); if (!value || value->GetType() != Value::TYPE_DICTIONARY) { trace_parsed_.Append(value->DeepCopy()); continue; } DictionaryValue* dict = static_cast<DictionaryValue*>(value); std::string tmp; if (dict->GetString("ph", &tmp) && tmp == "M") continue; trace_parsed_.Append(value->DeepCopy()); } } DictionaryValue* TraceEventTestFixture::FindNamePhase(const char* name, const char* phase) { JsonKeyValue key_values[] = { {"name", name, IS_EQUAL}, {"ph", phase, IS_EQUAL}, {0, 0, IS_EQUAL} }; return FindMatchingTraceEntry(key_values); } DictionaryValue* TraceEventTestFixture::FindNamePhaseKeyValue( const char* name, const char* phase, const char* key, const char* value) { JsonKeyValue key_values[] = { {"name", name, IS_EQUAL}, {"ph", phase, IS_EQUAL}, {key, value, IS_EQUAL}, {0, 0, IS_EQUAL} }; return FindMatchingTraceEntry(key_values); } bool TraceEventTestFixture::FindMatchingValue(const char* key, const char* value) { JsonKeyValue key_values[] = { {key, value, IS_EQUAL}, {0, 0, IS_EQUAL} }; return FindMatchingTraceEntry(key_values); } bool TraceEventTestFixture::FindNonMatchingValue(const char* key, const char* value) { JsonKeyValue key_values[] = { {key, value, IS_NOT_EQUAL}, {0, 0, IS_EQUAL} }; return FindMatchingTraceEntry(key_values); } bool IsStringInDict(const char* string_to_match, const DictionaryValue* dict) { for (DictionaryValue::Iterator it(*dict); !it.IsAtEnd(); it.Advance()) { if (it.key().find(string_to_match) != std::string::npos) return true; std::string value_str; it.value().GetAsString(&value_str); if (value_str.find(string_to_match) != std::string::npos) return true; } // Recurse to test arguments const DictionaryValue* args_dict = NULL; dict->GetDictionary("args", &args_dict); if (args_dict) return IsStringInDict(string_to_match, args_dict); return false; } const DictionaryValue* FindTraceEntry( const ListValue& trace_parsed, const char* string_to_match, const DictionaryValue* match_after_this_item = NULL) { // Scan all items size_t trace_parsed_count = trace_parsed.GetSize(); for (size_t i = 0; i < trace_parsed_count; i++) { const Value* value = NULL; trace_parsed.Get(i, &value); if (match_after_this_item) { if (value == match_after_this_item) match_after_this_item = NULL; continue; } if (!value || value->GetType() != Value::TYPE_DICTIONARY) continue; const DictionaryValue* dict = static_cast<const DictionaryValue*>(value); if (IsStringInDict(string_to_match, dict)) return dict; } return NULL; } std::vector<const DictionaryValue*> FindTraceEntries( const ListValue& trace_parsed, const char* string_to_match) { std::vector<const DictionaryValue*> hits; size_t trace_parsed_count = trace_parsed.GetSize(); for (size_t i = 0; i < trace_parsed_count; i++) { const Value* value = NULL; trace_parsed.Get(i, &value); if (!value || value->GetType() != Value::TYPE_DICTIONARY) continue; const DictionaryValue* dict = static_cast<const DictionaryValue*>(value); if (IsStringInDict(string_to_match, dict)) hits.push_back(dict); } return hits; } const char kControlCharacters[] = "\001\002\003\n\r"; void TraceWithAllMacroVariants(WaitableEvent* task_complete_event) { { TRACE_EVENT0("all", "TRACE_EVENT0 call"); TRACE_EVENT1("all", "TRACE_EVENT1 call", "name1", "value1"); TRACE_EVENT2("all", "TRACE_EVENT2 call", "name1", "\"value1\"", "name2", "value\\2"); TRACE_EVENT_INSTANT0("all", "TRACE_EVENT_INSTANT0 call", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT1("all", "TRACE_EVENT_INSTANT1 call", TRACE_EVENT_SCOPE_PROCESS, "name1", "value1"); TRACE_EVENT_INSTANT2("all", "TRACE_EVENT_INSTANT2 call", TRACE_EVENT_SCOPE_THREAD, "name1", "value1", "name2", "value2"); TRACE_EVENT_BEGIN0("all", "TRACE_EVENT_BEGIN0 call"); TRACE_EVENT_BEGIN1("all", "TRACE_EVENT_BEGIN1 call", "name1", "value1"); TRACE_EVENT_BEGIN2("all", "TRACE_EVENT_BEGIN2 call", "name1", "value1", "name2", "value2"); TRACE_EVENT_END0("all", "TRACE_EVENT_END0 call"); TRACE_EVENT_END1("all", "TRACE_EVENT_END1 call", "name1", "value1"); TRACE_EVENT_END2("all", "TRACE_EVENT_END2 call", "name1", "value1", "name2", "value2"); TRACE_EVENT_ASYNC_BEGIN0("all", "TRACE_EVENT_ASYNC_BEGIN0 call", kAsyncId); TRACE_EVENT_ASYNC_BEGIN1("all", "TRACE_EVENT_ASYNC_BEGIN1 call", kAsyncId, "name1", "value1"); TRACE_EVENT_ASYNC_BEGIN2("all", "TRACE_EVENT_ASYNC_BEGIN2 call", kAsyncId, "name1", "value1", "name2", "value2"); TRACE_EVENT_ASYNC_STEP_INTO0("all", "TRACE_EVENT_ASYNC_STEP_INTO0 call", kAsyncId, "step_begin1"); TRACE_EVENT_ASYNC_STEP_INTO1("all", "TRACE_EVENT_ASYNC_STEP_INTO1 call", kAsyncId, "step_begin2", "name1", "value1"); TRACE_EVENT_ASYNC_END0("all", "TRACE_EVENT_ASYNC_END0 call", kAsyncId); TRACE_EVENT_ASYNC_END1("all", "TRACE_EVENT_ASYNC_END1 call", kAsyncId, "name1", "value1"); TRACE_EVENT_ASYNC_END2("all", "TRACE_EVENT_ASYNC_END2 call", kAsyncId, "name1", "value1", "name2", "value2"); TRACE_EVENT_FLOW_BEGIN0("all", "TRACE_EVENT_FLOW_BEGIN0 call", kFlowId); TRACE_EVENT_FLOW_STEP0("all", "TRACE_EVENT_FLOW_STEP0 call", kFlowId, "step1"); TRACE_EVENT_FLOW_END_BIND_TO_ENCLOSING0("all", "TRACE_EVENT_FLOW_END_BIND_TO_ENCLOSING0 call", kFlowId); TRACE_COUNTER1("all", "TRACE_COUNTER1 call", 31415); TRACE_COUNTER2("all", "TRACE_COUNTER2 call", "a", 30000, "b", 1415); TRACE_COUNTER_WITH_TIMESTAMP1("all", "TRACE_COUNTER_WITH_TIMESTAMP1 call", 42, 31415); TRACE_COUNTER_WITH_TIMESTAMP2("all", "TRACE_COUNTER_WITH_TIMESTAMP2 call", 42, "a", 30000, "b", 1415); TRACE_COUNTER_ID1("all", "TRACE_COUNTER_ID1 call", 0x319009, 31415); TRACE_COUNTER_ID2("all", "TRACE_COUNTER_ID2 call", 0x319009, "a", 30000, "b", 1415); TRACE_EVENT_COPY_BEGIN_WITH_ID_TID_AND_TIMESTAMP0("all", "TRACE_EVENT_COPY_BEGIN_WITH_ID_TID_AND_TIMESTAMP0 call", kAsyncId, kThreadId, 12345); TRACE_EVENT_COPY_END_WITH_ID_TID_AND_TIMESTAMP0("all", "TRACE_EVENT_COPY_END_WITH_ID_TID_AND_TIMESTAMP0 call", kAsyncId, kThreadId, 23456); TRACE_EVENT_BEGIN_WITH_ID_TID_AND_TIMESTAMP0("all", "TRACE_EVENT_BEGIN_WITH_ID_TID_AND_TIMESTAMP0 call", kAsyncId2, kThreadId, 34567); TRACE_EVENT_ASYNC_STEP_PAST0("all", "TRACE_EVENT_ASYNC_STEP_PAST0 call", kAsyncId2, "step_end1"); TRACE_EVENT_ASYNC_STEP_PAST1("all", "TRACE_EVENT_ASYNC_STEP_PAST1 call", kAsyncId2, "step_end2", "name1", "value1"); TRACE_EVENT_END_WITH_ID_TID_AND_TIMESTAMP0("all", "TRACE_EVENT_END_WITH_ID_TID_AND_TIMESTAMP0 call", kAsyncId2, kThreadId, 45678); TRACE_EVENT_OBJECT_CREATED_WITH_ID("all", "tracked object 1", 0x42); TRACE_EVENT_OBJECT_SNAPSHOT_WITH_ID( "all", "tracked object 1", 0x42, "hello"); TRACE_EVENT_OBJECT_DELETED_WITH_ID("all", "tracked object 1", 0x42); TraceScopedTrackableObject<int> trackable("all", "tracked object 2", 0x2128506); trackable.snapshot("world"); TRACE_EVENT1(kControlCharacters, kControlCharacters, kControlCharacters, kControlCharacters); } // Scope close causes TRACE_EVENT0 etc to send their END events. if (task_complete_event) task_complete_event->Signal(); } void ValidateAllTraceMacrosCreatedData(const ListValue& trace_parsed) { const DictionaryValue* item = NULL; #define EXPECT_FIND_(string) \ item = FindTraceEntry(trace_parsed, string); \ EXPECT_TRUE(item); #define EXPECT_NOT_FIND_(string) \ item = FindTraceEntry(trace_parsed, string); \ EXPECT_FALSE(item); #define EXPECT_SUB_FIND_(string) \ if (item) \ EXPECT_TRUE(IsStringInDict(string, item)); EXPECT_FIND_("TRACE_EVENT0 call"); { std::string ph; std::string ph_end; EXPECT_TRUE((item = FindTraceEntry(trace_parsed, "TRACE_EVENT0 call"))); EXPECT_TRUE((item && item->GetString("ph", &ph))); EXPECT_EQ("X", ph); item = FindTraceEntry(trace_parsed, "TRACE_EVENT0 call", item); EXPECT_FALSE(item); } EXPECT_FIND_("TRACE_EVENT1 call"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_FIND_("TRACE_EVENT2 call"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("\"value1\""); EXPECT_SUB_FIND_("name2"); EXPECT_SUB_FIND_("value\\2"); EXPECT_FIND_("TRACE_EVENT_INSTANT0 call"); { std::string scope; EXPECT_TRUE((item && item->GetString("s", &scope))); EXPECT_EQ("g", scope); } EXPECT_FIND_("TRACE_EVENT_INSTANT1 call"); { std::string scope; EXPECT_TRUE((item && item->GetString("s", &scope))); EXPECT_EQ("p", scope); } EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_FIND_("TRACE_EVENT_INSTANT2 call"); { std::string scope; EXPECT_TRUE((item && item->GetString("s", &scope))); EXPECT_EQ("t", scope); } EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_SUB_FIND_("name2"); EXPECT_SUB_FIND_("value2"); EXPECT_FIND_("TRACE_EVENT_BEGIN0 call"); EXPECT_FIND_("TRACE_EVENT_BEGIN1 call"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_FIND_("TRACE_EVENT_BEGIN2 call"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_SUB_FIND_("name2"); EXPECT_SUB_FIND_("value2"); EXPECT_FIND_("TRACE_EVENT_END0 call"); EXPECT_FIND_("TRACE_EVENT_END1 call"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_FIND_("TRACE_EVENT_END2 call"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_SUB_FIND_("name2"); EXPECT_SUB_FIND_("value2"); EXPECT_FIND_("TRACE_EVENT_ASYNC_BEGIN0 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_FIND_("TRACE_EVENT_ASYNC_BEGIN1 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_FIND_("TRACE_EVENT_ASYNC_BEGIN2 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_SUB_FIND_("name2"); EXPECT_SUB_FIND_("value2"); EXPECT_FIND_("TRACE_EVENT_ASYNC_STEP_INTO0 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_SUB_FIND_("step_begin1"); EXPECT_FIND_("TRACE_EVENT_ASYNC_STEP_INTO1 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_SUB_FIND_("step_begin2"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_FIND_("TRACE_EVENT_ASYNC_END0 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_FIND_("TRACE_EVENT_ASYNC_END1 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_FIND_("TRACE_EVENT_ASYNC_END2 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncIdStr); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); EXPECT_SUB_FIND_("name2"); EXPECT_SUB_FIND_("value2"); EXPECT_FIND_("TRACE_EVENT_FLOW_BEGIN0 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kFlowIdStr); EXPECT_FIND_("TRACE_EVENT_FLOW_STEP0 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kFlowIdStr); EXPECT_SUB_FIND_("step1"); EXPECT_FIND_("TRACE_EVENT_FLOW_END_BIND_TO_ENCLOSING0 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kFlowIdStr); EXPECT_FIND_("TRACE_COUNTER1 call"); { std::string ph; EXPECT_TRUE((item && item->GetString("ph", &ph))); EXPECT_EQ("C", ph); int value; EXPECT_TRUE((item && item->GetInteger("args.value", &value))); EXPECT_EQ(31415, value); } EXPECT_FIND_("TRACE_COUNTER2 call"); { std::string ph; EXPECT_TRUE((item && item->GetString("ph", &ph))); EXPECT_EQ("C", ph); int value; EXPECT_TRUE((item && item->GetInteger("args.a", &value))); EXPECT_EQ(30000, value); EXPECT_TRUE((item && item->GetInteger("args.b", &value))); EXPECT_EQ(1415, value); } EXPECT_FIND_("TRACE_COUNTER_WITH_TIMESTAMP1 call"); { std::string ph; EXPECT_TRUE((item && item->GetString("ph", &ph))); EXPECT_EQ("C", ph); int value; EXPECT_TRUE((item && item->GetInteger("args.value", &value))); EXPECT_EQ(31415, value); int ts; EXPECT_TRUE((item && item->GetInteger("ts", &ts))); EXPECT_EQ(42, ts); } EXPECT_FIND_("TRACE_COUNTER_WITH_TIMESTAMP2 call"); { std::string ph; EXPECT_TRUE((item && item->GetString("ph", &ph))); EXPECT_EQ("C", ph); int value; EXPECT_TRUE((item && item->GetInteger("args.a", &value))); EXPECT_EQ(30000, value); EXPECT_TRUE((item && item->GetInteger("args.b", &value))); EXPECT_EQ(1415, value); int ts; EXPECT_TRUE((item && item->GetInteger("ts", &ts))); EXPECT_EQ(42, ts); } EXPECT_FIND_("TRACE_COUNTER_ID1 call"); { std::string id; EXPECT_TRUE((item && item->GetString("id", &id))); EXPECT_EQ("0x319009", id); std::string ph; EXPECT_TRUE((item && item->GetString("ph", &ph))); EXPECT_EQ("C", ph); int value; EXPECT_TRUE((item && item->GetInteger("args.value", &value))); EXPECT_EQ(31415, value); } EXPECT_FIND_("TRACE_COUNTER_ID2 call"); { std::string id; EXPECT_TRUE((item && item->GetString("id", &id))); EXPECT_EQ("0x319009", id); std::string ph; EXPECT_TRUE((item && item->GetString("ph", &ph))); EXPECT_EQ("C", ph); int value; EXPECT_TRUE((item && item->GetInteger("args.a", &value))); EXPECT_EQ(30000, value); EXPECT_TRUE((item && item->GetInteger("args.b", &value))); EXPECT_EQ(1415, value); } EXPECT_FIND_("TRACE_EVENT_COPY_BEGIN_WITH_ID_TID_AND_TIMESTAMP0 call"); { int val; EXPECT_TRUE((item && item->GetInteger("ts", &val))); EXPECT_EQ(12345, val); EXPECT_TRUE((item && item->GetInteger("tid", &val))); EXPECT_EQ(kThreadId, val); std::string id; EXPECT_TRUE((item && item->GetString("id", &id))); EXPECT_EQ(kAsyncIdStr, id); } EXPECT_FIND_("TRACE_EVENT_COPY_END_WITH_ID_TID_AND_TIMESTAMP0 call"); { int val; EXPECT_TRUE((item && item->GetInteger("ts", &val))); EXPECT_EQ(23456, val); EXPECT_TRUE((item && item->GetInteger("tid", &val))); EXPECT_EQ(kThreadId, val); std::string id; EXPECT_TRUE((item && item->GetString("id", &id))); EXPECT_EQ(kAsyncIdStr, id); } EXPECT_FIND_("TRACE_EVENT_BEGIN_WITH_ID_TID_AND_TIMESTAMP0 call"); { int val; EXPECT_TRUE((item && item->GetInteger("ts", &val))); EXPECT_EQ(34567, val); EXPECT_TRUE((item && item->GetInteger("tid", &val))); EXPECT_EQ(kThreadId, val); std::string id; EXPECT_TRUE((item && item->GetString("id", &id))); EXPECT_EQ(kAsyncId2Str, id); } EXPECT_FIND_("TRACE_EVENT_ASYNC_STEP_PAST0 call"); { EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncId2Str); EXPECT_SUB_FIND_("step_end1"); EXPECT_FIND_("TRACE_EVENT_ASYNC_STEP_PAST1 call"); EXPECT_SUB_FIND_("id"); EXPECT_SUB_FIND_(kAsyncId2Str); EXPECT_SUB_FIND_("step_end2"); EXPECT_SUB_FIND_("name1"); EXPECT_SUB_FIND_("value1"); } EXPECT_FIND_("TRACE_EVENT_END_WITH_ID_TID_AND_TIMESTAMP0 call"); { int val; EXPECT_TRUE((item && item->GetInteger("ts", &val))); EXPECT_EQ(45678, val); EXPECT_TRUE((item && item->GetInteger("tid", &val))); EXPECT_EQ(kThreadId, val); std::string id; EXPECT_TRUE((item && item->GetString("id", &id))); EXPECT_EQ(kAsyncId2Str, id); } EXPECT_FIND_("tracked object 1"); { std::string phase; std::string id; std::string snapshot; EXPECT_TRUE((item && item->GetString("ph", &phase))); EXPECT_EQ("N", phase); EXPECT_TRUE((item && item->GetString("id", &id))); EXPECT_EQ("0x42", id); item = FindTraceEntry(trace_parsed, "tracked object 1", item); EXPECT_TRUE(item); EXPECT_TRUE(item && item->GetString("ph", &phase)); EXPECT_EQ("O", phase); EXPECT_TRUE(item && item->GetString("id", &id)); EXPECT_EQ("0x42", id); EXPECT_TRUE(item && item->GetString("args.snapshot", &snapshot)); EXPECT_EQ("hello", snapshot); item = FindTraceEntry(trace_parsed, "tracked object 1", item); EXPECT_TRUE(item); EXPECT_TRUE(item && item->GetString("ph", &phase)); EXPECT_EQ("D", phase); EXPECT_TRUE(item && item->GetString("id", &id)); EXPECT_EQ("0x42", id); } EXPECT_FIND_("tracked object 2"); { std::string phase; std::string id; std::string snapshot; EXPECT_TRUE(item && item->GetString("ph", &phase)); EXPECT_EQ("N", phase); EXPECT_TRUE(item && item->GetString("id", &id)); EXPECT_EQ("0x2128506", id); item = FindTraceEntry(trace_parsed, "tracked object 2", item); EXPECT_TRUE(item); EXPECT_TRUE(item && item->GetString("ph", &phase)); EXPECT_EQ("O", phase); EXPECT_TRUE(item && item->GetString("id", &id)); EXPECT_EQ("0x2128506", id); EXPECT_TRUE(item && item->GetString("args.snapshot", &snapshot)); EXPECT_EQ("world", snapshot); item = FindTraceEntry(trace_parsed, "tracked object 2", item); EXPECT_TRUE(item); EXPECT_TRUE(item && item->GetString("ph", &phase)); EXPECT_EQ("D", phase); EXPECT_TRUE(item && item->GetString("id", &id)); EXPECT_EQ("0x2128506", id); } EXPECT_FIND_(kControlCharacters); EXPECT_SUB_FIND_(kControlCharacters); } void TraceManyInstantEvents(int thread_id, int num_events, WaitableEvent* task_complete_event) { for (int i = 0; i < num_events; i++) { TRACE_EVENT_INSTANT2("all", "multi thread event", TRACE_EVENT_SCOPE_THREAD, "thread", thread_id, "event", i); } if (task_complete_event) task_complete_event->Signal(); } void ValidateInstantEventPresentOnEveryThread(const ListValue& trace_parsed, int num_threads, int num_events) { std::map<int, std::map<int, bool> > results; size_t trace_parsed_count = trace_parsed.GetSize(); for (size_t i = 0; i < trace_parsed_count; i++) { const Value* value = NULL; trace_parsed.Get(i, &value); if (!value || value->GetType() != Value::TYPE_DICTIONARY) continue; const DictionaryValue* dict = static_cast<const DictionaryValue*>(value); std::string name; dict->GetString("name", &name); if (name != "multi thread event") continue; int thread = 0; int event = 0; EXPECT_TRUE(dict->GetInteger("args.thread", &thread)); EXPECT_TRUE(dict->GetInteger("args.event", &event)); results[thread][event] = true; } EXPECT_FALSE(results[-1][-1]); for (int thread = 0; thread < num_threads; thread++) { for (int event = 0; event < num_events; event++) { EXPECT_TRUE(results[thread][event]); } } } } // namespace // Simple Test for emitting data and validating it was received. TEST_F(TraceEventTestFixture, DataCaptured) { TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); TraceWithAllMacroVariants(NULL); EndTraceAndFlush(); ValidateAllTraceMacrosCreatedData(trace_parsed_); } // Emit some events and validate that only empty strings are received // if we tell Flush() to discard events. TEST_F(TraceEventTestFixture, DataDiscarded) { TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); TraceWithAllMacroVariants(NULL); CancelTrace(); EXPECT_TRUE(trace_parsed_.empty()); } class MockEnabledStateChangedObserver : public TraceLog::EnabledStateObserver { public: MOCK_METHOD0(OnTraceLogEnabled, void()); MOCK_METHOD0(OnTraceLogDisabled, void()); }; TEST_F(TraceEventTestFixture, EnabledObserverFiresOnEnable) { MockEnabledStateChangedObserver observer; TraceLog::GetInstance()->AddEnabledStateObserver(&observer); EXPECT_CALL(observer, OnTraceLogEnabled()) .Times(1); TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); testing::Mock::VerifyAndClear(&observer); EXPECT_TRUE(TraceLog::GetInstance()->IsEnabled()); // Cleanup. TraceLog::GetInstance()->RemoveEnabledStateObserver(&observer); TraceLog::GetInstance()->SetDisabled(); } TEST_F(TraceEventTestFixture, EnabledObserverDoesntFireOnSecondEnable) { TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); testing::StrictMock<MockEnabledStateChangedObserver> observer; TraceLog::GetInstance()->AddEnabledStateObserver(&observer); EXPECT_CALL(observer, OnTraceLogEnabled()) .Times(0); EXPECT_CALL(observer, OnTraceLogDisabled()) .Times(0); TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); testing::Mock::VerifyAndClear(&observer); EXPECT_TRUE(TraceLog::GetInstance()->IsEnabled()); // Cleanup. TraceLog::GetInstance()->RemoveEnabledStateObserver(&observer); TraceLog::GetInstance()->SetDisabled(); TraceLog::GetInstance()->SetDisabled(); } TEST_F(TraceEventTestFixture, EnabledObserverFiresOnFirstDisable) { TraceConfig tc_inc_all("*", ""); TraceLog::GetInstance()->SetEnabled(tc_inc_all, TraceLog::RECORDING_MODE); TraceLog::GetInstance()->SetEnabled(tc_inc_all, TraceLog::RECORDING_MODE); testing::StrictMock<MockEnabledStateChangedObserver> observer; TraceLog::GetInstance()->AddEnabledStateObserver(&observer); EXPECT_CALL(observer, OnTraceLogEnabled()) .Times(0); EXPECT_CALL(observer, OnTraceLogDisabled()) .Times(1); TraceLog::GetInstance()->SetDisabled(); testing::Mock::VerifyAndClear(&observer); // Cleanup. TraceLog::GetInstance()->RemoveEnabledStateObserver(&observer); TraceLog::GetInstance()->SetDisabled(); } TEST_F(TraceEventTestFixture, EnabledObserverFiresOnDisable) { TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); MockEnabledStateChangedObserver observer; TraceLog::GetInstance()->AddEnabledStateObserver(&observer); EXPECT_CALL(observer, OnTraceLogDisabled()) .Times(1); TraceLog::GetInstance()->SetDisabled(); testing::Mock::VerifyAndClear(&observer); // Cleanup. TraceLog::GetInstance()->RemoveEnabledStateObserver(&observer); } // Tests the IsEnabled() state of TraceLog changes before callbacks. class AfterStateChangeEnabledStateObserver : public TraceLog::EnabledStateObserver { public: AfterStateChangeEnabledStateObserver() {} ~AfterStateChangeEnabledStateObserver() override {} // TraceLog::EnabledStateObserver overrides: void OnTraceLogEnabled() override { EXPECT_TRUE(TraceLog::GetInstance()->IsEnabled()); } void OnTraceLogDisabled() override { EXPECT_FALSE(TraceLog::GetInstance()->IsEnabled()); } }; TEST_F(TraceEventTestFixture, ObserversFireAfterStateChange) { AfterStateChangeEnabledStateObserver observer; TraceLog::GetInstance()->AddEnabledStateObserver(&observer); TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); EXPECT_TRUE(TraceLog::GetInstance()->IsEnabled()); TraceLog::GetInstance()->SetDisabled(); EXPECT_FALSE(TraceLog::GetInstance()->IsEnabled()); TraceLog::GetInstance()->RemoveEnabledStateObserver(&observer); } // Tests that a state observer can remove itself during a callback. class SelfRemovingEnabledStateObserver : public TraceLog::EnabledStateObserver { public: SelfRemovingEnabledStateObserver() {} ~SelfRemovingEnabledStateObserver() override {} // TraceLog::EnabledStateObserver overrides: void OnTraceLogEnabled() override {} void OnTraceLogDisabled() override { TraceLog::GetInstance()->RemoveEnabledStateObserver(this); } }; TEST_F(TraceEventTestFixture, SelfRemovingObserver) { ASSERT_EQ(0u, TraceLog::GetInstance()->GetObserverCountForTest()); SelfRemovingEnabledStateObserver observer; TraceLog::GetInstance()->AddEnabledStateObserver(&observer); EXPECT_EQ(1u, TraceLog::GetInstance()->GetObserverCountForTest()); TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); TraceLog::GetInstance()->SetDisabled(); // The observer removed itself on disable. EXPECT_EQ(0u, TraceLog::GetInstance()->GetObserverCountForTest()); } bool IsNewTrace() { bool is_new_trace; TRACE_EVENT_IS_NEW_TRACE(&is_new_trace); return is_new_trace; } TEST_F(TraceEventTestFixture, NewTraceRecording) { ASSERT_FALSE(IsNewTrace()); TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); // First call to IsNewTrace() should succeed. But, the second shouldn't. ASSERT_TRUE(IsNewTrace()); ASSERT_FALSE(IsNewTrace()); EndTraceAndFlush(); // IsNewTrace() should definitely be false now. ASSERT_FALSE(IsNewTrace()); // Start another trace. IsNewTrace() should become true again, briefly, as // before. TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); ASSERT_TRUE(IsNewTrace()); ASSERT_FALSE(IsNewTrace()); // Cleanup. EndTraceAndFlush(); } TEST_F(TraceEventTestFixture, TestTraceFlush) { size_t min_traces = 1; size_t max_traces = 1; do { max_traces *= 2; TraceLog::GetInstance()->SetEnabled(TraceConfig(), TraceLog::RECORDING_MODE); for (size_t i = 0; i < max_traces; i++) { TRACE_EVENT_INSTANT0("x", "y", TRACE_EVENT_SCOPE_THREAD); } EndTraceAndFlush(); } while (num_flush_callbacks_ < 2); while (min_traces + 50 < max_traces) { size_t traces = (min_traces + max_traces) / 2; TraceLog::GetInstance()->SetEnabled(TraceConfig(), TraceLog::RECORDING_MODE); for (size_t i = 0; i < traces; i++) { TRACE_EVENT_INSTANT0("x", "y", TRACE_EVENT_SCOPE_THREAD); } EndTraceAndFlush(); if (num_flush_callbacks_ < 2) { min_traces = traces - 10; } else { max_traces = traces + 10; } } for (size_t traces = min_traces; traces < max_traces; traces++) { TraceLog::GetInstance()->SetEnabled(TraceConfig(), TraceLog::RECORDING_MODE); for (size_t i = 0; i < traces; i++) { TRACE_EVENT_INSTANT0("x", "y", TRACE_EVENT_SCOPE_THREAD); } EndTraceAndFlush(); } } TEST_F(TraceEventTestFixture, AddMetadataEvent) { int num_calls = 0; class Convertable : public ConvertableToTraceFormat { public: explicit Convertable(int* num_calls) : num_calls_(num_calls) {} void AppendAsTraceFormat(std::string* out) const override { (*num_calls_)++; out->append("\"metadata_value\""); } private: ~Convertable() override {} int* num_calls_; }; scoped_refptr<ConvertableToTraceFormat> convertable = new Convertable(&num_calls); BeginTrace(); TRACE_EVENT_API_ADD_METADATA_EVENT("metadata_event_name", "metadata_arg_name", convertable); // |AppendAsTraceFormat| should only be called on flush, not when the event // is added. ASSERT_EQ(0, num_calls); EndTraceAndFlush(); ASSERT_EQ(1, num_calls); EXPECT_TRUE(FindNamePhaseKeyValue("metadata_event_name", "M", "metadata_arg_name", "metadata_value")); // The metadata event should only be adde to the current trace. In this new // trace, the event should not appear. BeginTrace(); EndTraceAndFlush(); ASSERT_EQ(1, num_calls); // Flushing should cause |AppendAsTraceFormat| to be called, but if the buffer // is left intact, it the flush at the end of the trace should still call it; // the metadata event should not be removed. TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, "record-until-full,enable-sampling"), TraceLog::MONITORING_MODE); TRACE_EVENT_API_ADD_METADATA_EVENT("metadata_event_name", "metadata_arg_name", convertable); FlushMonitoring(); ASSERT_EQ(2, num_calls); // Flushing the trace at this point will case |AppendAsTraceFormat| to be // called twice: once for the event that was added by the monitoring flush, // and once for the end trace flush; the metadata event will be duplicated. // This is consistent with the other metadata events. EndTraceAndFlush(); ASSERT_EQ(4, num_calls); } // Test that categories work. TEST_F(TraceEventTestFixture, Categories) { // Test that categories that are used can be retrieved whether trace was // enabled or disabled when the trace event was encountered. TRACE_EVENT_INSTANT0("c1", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("c2", "name", TRACE_EVENT_SCOPE_THREAD); BeginTrace(); TRACE_EVENT_INSTANT0("c3", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("c4", "name", TRACE_EVENT_SCOPE_THREAD); // Category groups containing more than one category. TRACE_EVENT_INSTANT0("c5,c6", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("c7,c8", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0(TRACE_DISABLED_BY_DEFAULT("c9"), "name", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); std::vector<std::string> cat_groups; TraceLog::GetInstance()->GetKnownCategoryGroups(&cat_groups); EXPECT_TRUE(ContainsValue(cat_groups, "c1")); EXPECT_TRUE(ContainsValue(cat_groups, "c2")); EXPECT_TRUE(ContainsValue(cat_groups, "c3")); EXPECT_TRUE(ContainsValue(cat_groups, "c4")); EXPECT_TRUE(ContainsValue(cat_groups, "c5,c6")); EXPECT_TRUE(ContainsValue(cat_groups, "c7,c8")); EXPECT_TRUE(ContainsValue(cat_groups, "disabled-by-default-c9")); // Make sure metadata isn't returned. EXPECT_FALSE(ContainsValue(cat_groups, "__metadata")); const std::vector<std::string> empty_categories; std::vector<std::string> included_categories; std::vector<std::string> excluded_categories; // Test that category filtering works. // Include nonexistent category -> no events Clear(); included_categories.clear(); TraceLog::GetInstance()->SetEnabled(TraceConfig("not_found823564786", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("cat1", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("cat2", "name", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); DropTracedMetadataRecords(); EXPECT_TRUE(trace_parsed_.empty()); // Include existent category -> only events of that category Clear(); included_categories.clear(); TraceLog::GetInstance()->SetEnabled(TraceConfig("inc", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("inc", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc2", "name", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); DropTracedMetadataRecords(); EXPECT_TRUE(FindMatchingValue("cat", "inc")); EXPECT_FALSE(FindNonMatchingValue("cat", "inc")); // Include existent wildcard -> all categories matching wildcard Clear(); included_categories.clear(); TraceLog::GetInstance()->SetEnabled( TraceConfig("inc_wildcard_*,inc_wildchar_?_end", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("inc_wildcard_abc", "included", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc_wildcard_", "included", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc_wildchar_x_end", "included", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc_wildchar_bla_end", "not_inc", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("cat1", "not_inc", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("cat2", "not_inc", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc_wildcard_category,other_category", "included", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0( "non_included_category,inc_wildcard_category", "included", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_TRUE(FindMatchingValue("cat", "inc_wildcard_abc")); EXPECT_TRUE(FindMatchingValue("cat", "inc_wildcard_")); EXPECT_TRUE(FindMatchingValue("cat", "inc_wildchar_x_end")); EXPECT_FALSE(FindMatchingValue("name", "not_inc")); EXPECT_TRUE(FindMatchingValue("cat", "inc_wildcard_category,other_category")); EXPECT_TRUE(FindMatchingValue("cat", "non_included_category,inc_wildcard_category")); included_categories.clear(); // Exclude nonexistent category -> all events Clear(); TraceLog::GetInstance()->SetEnabled(TraceConfig("-not_found823564786", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("cat1", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("cat2", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("category1,category2", "name", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_TRUE(FindMatchingValue("cat", "cat1")); EXPECT_TRUE(FindMatchingValue("cat", "cat2")); EXPECT_TRUE(FindMatchingValue("cat", "category1,category2")); // Exclude existent category -> only events of other categories Clear(); TraceLog::GetInstance()->SetEnabled(TraceConfig("-inc", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("inc", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc2", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc2,inc", "name", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc,inc2", "name", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_TRUE(FindMatchingValue("cat", "inc2")); EXPECT_FALSE(FindMatchingValue("cat", "inc")); EXPECT_TRUE(FindMatchingValue("cat", "inc2,inc")); EXPECT_TRUE(FindMatchingValue("cat", "inc,inc2")); // Exclude existent wildcard -> all categories not matching wildcard Clear(); TraceLog::GetInstance()->SetEnabled( TraceConfig("-inc_wildcard_*,-inc_wildchar_?_end", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("inc_wildcard_abc", "not_inc", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc_wildcard_", "not_inc", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc_wildchar_x_end", "not_inc", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("inc_wildchar_bla_end", "included", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("cat1", "included", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("cat2", "included", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_TRUE(FindMatchingValue("cat", "inc_wildchar_bla_end")); EXPECT_TRUE(FindMatchingValue("cat", "cat1")); EXPECT_TRUE(FindMatchingValue("cat", "cat2")); EXPECT_FALSE(FindMatchingValue("name", "not_inc")); } // Test EVENT_WATCH_NOTIFICATION TEST_F(TraceEventTestFixture, EventWatchNotification) { // Basic one occurrence. BeginTrace(); TraceLog::WatchEventCallback callback = base::Bind(&TraceEventTestFixture::OnWatchEventMatched, base::Unretained(this)); TraceLog::GetInstance()->SetWatchEvent("cat", "event", callback); TRACE_EVENT_INSTANT0("cat", "event", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_EQ(event_watch_notification_, 1); // Auto-reset after end trace. BeginTrace(); TraceLog::GetInstance()->SetWatchEvent("cat", "event", callback); EndTraceAndFlush(); BeginTrace(); TRACE_EVENT_INSTANT0("cat", "event", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_EQ(event_watch_notification_, 0); // Multiple occurrence. BeginTrace(); int num_occurrences = 5; TraceLog::GetInstance()->SetWatchEvent("cat", "event", callback); for (int i = 0; i < num_occurrences; ++i) TRACE_EVENT_INSTANT0("cat", "event", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_EQ(event_watch_notification_, num_occurrences); // Wrong category. BeginTrace(); TraceLog::GetInstance()->SetWatchEvent("cat", "event", callback); TRACE_EVENT_INSTANT0("wrong_cat", "event", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_EQ(event_watch_notification_, 0); // Wrong name. BeginTrace(); TraceLog::GetInstance()->SetWatchEvent("cat", "event", callback); TRACE_EVENT_INSTANT0("cat", "wrong_event", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_EQ(event_watch_notification_, 0); // Canceled. BeginTrace(); TraceLog::GetInstance()->SetWatchEvent("cat", "event", callback); TraceLog::GetInstance()->CancelWatchEvent(); TRACE_EVENT_INSTANT0("cat", "event", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); EXPECT_EQ(event_watch_notification_, 0); } // Test ASYNC_BEGIN/END events TEST_F(TraceEventTestFixture, AsyncBeginEndEvents) { BeginTrace(); unsigned long long id = 0xfeedbeeffeedbeefull; TRACE_EVENT_ASYNC_BEGIN0("cat", "name1", id); TRACE_EVENT_ASYNC_STEP_INTO0("cat", "name1", id, "step1"); TRACE_EVENT_ASYNC_END0("cat", "name1", id); TRACE_EVENT_BEGIN0("cat", "name2"); TRACE_EVENT_ASYNC_BEGIN0("cat", "name3", 0); TRACE_EVENT_ASYNC_STEP_PAST0("cat", "name3", 0, "step2"); EndTraceAndFlush(); EXPECT_TRUE(FindNamePhase("name1", "S")); EXPECT_TRUE(FindNamePhase("name1", "T")); EXPECT_TRUE(FindNamePhase("name1", "F")); std::string id_str; StringAppendF(&id_str, "0x%llx", id); EXPECT_TRUE(FindNamePhaseKeyValue("name1", "S", "id", id_str.c_str())); EXPECT_TRUE(FindNamePhaseKeyValue("name1", "T", "id", id_str.c_str())); EXPECT_TRUE(FindNamePhaseKeyValue("name1", "F", "id", id_str.c_str())); EXPECT_TRUE(FindNamePhaseKeyValue("name3", "S", "id", "0x0")); EXPECT_TRUE(FindNamePhaseKeyValue("name3", "p", "id", "0x0")); // BEGIN events should not have id EXPECT_FALSE(FindNamePhaseKeyValue("name2", "B", "id", "0")); } // Test ASYNC_BEGIN/END events TEST_F(TraceEventTestFixture, AsyncBeginEndPointerMangling) { void* ptr = this; TraceLog::GetInstance()->SetProcessID(100); BeginTrace(); TRACE_EVENT_ASYNC_BEGIN0("cat", "name1", ptr); TRACE_EVENT_ASYNC_BEGIN0("cat", "name2", ptr); EndTraceAndFlush(); TraceLog::GetInstance()->SetProcessID(200); BeginTrace(); TRACE_EVENT_ASYNC_END0("cat", "name1", ptr); EndTraceAndFlush(); DictionaryValue* async_begin = FindNamePhase("name1", "S"); DictionaryValue* async_begin2 = FindNamePhase("name2", "S"); DictionaryValue* async_end = FindNamePhase("name1", "F"); EXPECT_TRUE(async_begin); EXPECT_TRUE(async_begin2); EXPECT_TRUE(async_end); Value* value = NULL; std::string async_begin_id_str; std::string async_begin2_id_str; std::string async_end_id_str; ASSERT_TRUE(async_begin->Get("id", &value)); ASSERT_TRUE(value->GetAsString(&async_begin_id_str)); ASSERT_TRUE(async_begin2->Get("id", &value)); ASSERT_TRUE(value->GetAsString(&async_begin2_id_str)); ASSERT_TRUE(async_end->Get("id", &value)); ASSERT_TRUE(value->GetAsString(&async_end_id_str)); EXPECT_STREQ(async_begin_id_str.c_str(), async_begin2_id_str.c_str()); EXPECT_STRNE(async_begin_id_str.c_str(), async_end_id_str.c_str()); } // Test that static strings are not copied. TEST_F(TraceEventTestFixture, StaticStringVsString) { TraceLog* tracer = TraceLog::GetInstance(); // Make sure old events are flushed: EXPECT_EQ(0u, tracer->GetStatus().event_count); const unsigned char* category_group_enabled = TRACE_EVENT_API_GET_CATEGORY_GROUP_ENABLED("cat"); { BeginTrace(); // Test that string arguments are copied. TraceEventHandle handle1 = trace_event_internal::AddTraceEvent( TRACE_EVENT_PHASE_INSTANT, category_group_enabled, "name1", 0, 0, trace_event_internal::kNoId, "arg1", std::string("argval"), "arg2", std::string("argval")); // Test that static TRACE_STR_COPY string arguments are copied. TraceEventHandle handle2 = trace_event_internal::AddTraceEvent( TRACE_EVENT_PHASE_INSTANT, category_group_enabled, "name2", 0, 0, trace_event_internal::kNoId, "arg1", TRACE_STR_COPY("argval"), "arg2", TRACE_STR_COPY("argval")); EXPECT_GT(tracer->GetStatus().event_count, 1u); const TraceEvent* event1 = tracer->GetEventByHandle(handle1); const TraceEvent* event2 = tracer->GetEventByHandle(handle2); ASSERT_TRUE(event1); ASSERT_TRUE(event2); EXPECT_STREQ("name1", event1->name()); EXPECT_STREQ("name2", event2->name()); EXPECT_TRUE(event1->parameter_copy_storage() != NULL); EXPECT_TRUE(event2->parameter_copy_storage() != NULL); EXPECT_GT(event1->parameter_copy_storage()->size(), 0u); EXPECT_GT(event2->parameter_copy_storage()->size(), 0u); EndTraceAndFlush(); } { BeginTrace(); // Test that static literal string arguments are not copied. TraceEventHandle handle1 = trace_event_internal::AddTraceEvent( TRACE_EVENT_PHASE_INSTANT, category_group_enabled, "name1", 0, 0, trace_event_internal::kNoId, "arg1", "argval", "arg2", "argval"); // Test that static TRACE_STR_COPY NULL string arguments are not copied. const char* str1 = NULL; const char* str2 = NULL; TraceEventHandle handle2 = trace_event_internal::AddTraceEvent( TRACE_EVENT_PHASE_INSTANT, category_group_enabled, "name2", 0, 0, trace_event_internal::kNoId, "arg1", TRACE_STR_COPY(str1), "arg2", TRACE_STR_COPY(str2)); EXPECT_GT(tracer->GetStatus().event_count, 1u); const TraceEvent* event1 = tracer->GetEventByHandle(handle1); const TraceEvent* event2 = tracer->GetEventByHandle(handle2); ASSERT_TRUE(event1); ASSERT_TRUE(event2); EXPECT_STREQ("name1", event1->name()); EXPECT_STREQ("name2", event2->name()); EXPECT_TRUE(event1->parameter_copy_storage() == NULL); EXPECT_TRUE(event2->parameter_copy_storage() == NULL); EndTraceAndFlush(); } } // Test that data sent from other threads is gathered TEST_F(TraceEventTestFixture, DataCapturedOnThread) { BeginTrace(); Thread thread("1"); WaitableEvent task_complete_event(false, false); thread.Start(); thread.task_runner()->PostTask( FROM_HERE, base::Bind(&TraceWithAllMacroVariants, &task_complete_event)); task_complete_event.Wait(); thread.Stop(); EndTraceAndFlush(); ValidateAllTraceMacrosCreatedData(trace_parsed_); } // Test that data sent from multiple threads is gathered TEST_F(TraceEventTestFixture, DataCapturedManyThreads) { BeginTrace(); const int num_threads = 4; const int num_events = 4000; Thread* threads[num_threads]; WaitableEvent* task_complete_events[num_threads]; for (int i = 0; i < num_threads; i++) { threads[i] = new Thread(StringPrintf("Thread %d", i)); task_complete_events[i] = new WaitableEvent(false, false); threads[i]->Start(); threads[i]->task_runner()->PostTask( FROM_HERE, base::Bind(&TraceManyInstantEvents, i, num_events, task_complete_events[i])); } for (int i = 0; i < num_threads; i++) { task_complete_events[i]->Wait(); } // Let half of the threads end before flush. for (int i = 0; i < num_threads / 2; i++) { threads[i]->Stop(); delete threads[i]; delete task_complete_events[i]; } EndTraceAndFlushInThreadWithMessageLoop(); ValidateInstantEventPresentOnEveryThread(trace_parsed_, num_threads, num_events); // Let the other half of the threads end after flush. for (int i = num_threads / 2; i < num_threads; i++) { threads[i]->Stop(); delete threads[i]; delete task_complete_events[i]; } } // Test that thread and process names show up in the trace TEST_F(TraceEventTestFixture, ThreadNames) { // Create threads before we enable tracing to make sure // that tracelog still captures them. const int kNumThreads = 4; const int kNumEvents = 10; Thread* threads[kNumThreads]; PlatformThreadId thread_ids[kNumThreads]; for (int i = 0; i < kNumThreads; i++) threads[i] = new Thread(StringPrintf("Thread %d", i)); // Enable tracing. BeginTrace(); // Now run some trace code on these threads. WaitableEvent* task_complete_events[kNumThreads]; for (int i = 0; i < kNumThreads; i++) { task_complete_events[i] = new WaitableEvent(false, false); threads[i]->Start(); thread_ids[i] = threads[i]->GetThreadId(); threads[i]->task_runner()->PostTask( FROM_HERE, base::Bind(&TraceManyInstantEvents, i, kNumEvents, task_complete_events[i])); } for (int i = 0; i < kNumThreads; i++) { task_complete_events[i]->Wait(); } // Shut things down. for (int i = 0; i < kNumThreads; i++) { threads[i]->Stop(); delete threads[i]; delete task_complete_events[i]; } EndTraceAndFlush(); std::string tmp; int tmp_int; const DictionaryValue* item; // Make sure we get thread name metadata. // Note, the test suite may have created a ton of threads. // So, we'll have thread names for threads we didn't create. std::vector<const DictionaryValue*> items = FindTraceEntries(trace_parsed_, "thread_name"); for (int i = 0; i < static_cast<int>(items.size()); i++) { item = items[i]; ASSERT_TRUE(item); EXPECT_TRUE(item->GetInteger("tid", &tmp_int)); // See if this thread name is one of the threads we just created for (int j = 0; j < kNumThreads; j++) { if (static_cast<int>(thread_ids[j]) != tmp_int) continue; std::string expected_name = StringPrintf("Thread %d", j); EXPECT_TRUE(item->GetString("ph", &tmp) && tmp == "M"); EXPECT_TRUE(item->GetInteger("pid", &tmp_int) && tmp_int == static_cast<int>(base::GetCurrentProcId())); // If the thread name changes or the tid gets reused, the name will be // a comma-separated list of thread names, so look for a substring. EXPECT_TRUE(item->GetString("args.name", &tmp) && tmp.find(expected_name) != std::string::npos); } } } TEST_F(TraceEventTestFixture, ThreadNameChanges) { BeginTrace(); PlatformThread::SetName(""); TRACE_EVENT_INSTANT0("drink", "water", TRACE_EVENT_SCOPE_THREAD); PlatformThread::SetName("cafe"); TRACE_EVENT_INSTANT0("drink", "coffee", TRACE_EVENT_SCOPE_THREAD); PlatformThread::SetName("shop"); // No event here, so won't appear in combined name. PlatformThread::SetName("pub"); TRACE_EVENT_INSTANT0("drink", "beer", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("drink", "wine", TRACE_EVENT_SCOPE_THREAD); PlatformThread::SetName(" bar"); TRACE_EVENT_INSTANT0("drink", "whisky", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); std::vector<const DictionaryValue*> items = FindTraceEntries(trace_parsed_, "thread_name"); EXPECT_EQ(1u, items.size()); ASSERT_GT(items.size(), 0u); const DictionaryValue* item = items[0]; ASSERT_TRUE(item); int tid; EXPECT_TRUE(item->GetInteger("tid", &tid)); EXPECT_EQ(PlatformThread::CurrentId(), static_cast<PlatformThreadId>(tid)); std::string expected_name = "cafe,pub, bar"; std::string tmp; EXPECT_TRUE(item->GetString("args.name", &tmp)); EXPECT_EQ(expected_name, tmp); } // Test that the disabled trace categories are included/excluded from the // trace output correctly. TEST_F(TraceEventTestFixture, DisabledCategories) { BeginTrace(); TRACE_EVENT_INSTANT0(TRACE_DISABLED_BY_DEFAULT("cc"), "first", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("included", "first", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); { const DictionaryValue* item = NULL; ListValue& trace_parsed = trace_parsed_; EXPECT_NOT_FIND_("disabled-by-default-cc"); EXPECT_FIND_("included"); } Clear(); BeginSpecificTrace("disabled-by-default-cc"); TRACE_EVENT_INSTANT0(TRACE_DISABLED_BY_DEFAULT("cc"), "second", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("other_included", "second", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); { const DictionaryValue* item = NULL; ListValue& trace_parsed = trace_parsed_; EXPECT_FIND_("disabled-by-default-cc"); EXPECT_FIND_("other_included"); } Clear(); BeginSpecificTrace("other_included"); TRACE_EVENT_INSTANT0(TRACE_DISABLED_BY_DEFAULT("cc") ",other_included", "first", TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_INSTANT0("other_included," TRACE_DISABLED_BY_DEFAULT("cc"), "second", TRACE_EVENT_SCOPE_THREAD); EndTraceAndFlush(); { const DictionaryValue* item = NULL; ListValue& trace_parsed = trace_parsed_; EXPECT_FIND_("disabled-by-default-cc,other_included"); EXPECT_FIND_("other_included,disabled-by-default-cc"); } } TEST_F(TraceEventTestFixture, NormallyNoDeepCopy) { // Test that the TRACE_EVENT macros do not deep-copy their string. If they // do so it may indicate a performance regression, but more-over it would // make the DEEP_COPY overloads redundant. std::string name_string("event name"); BeginTrace(); TRACE_EVENT_INSTANT0("category", name_string.c_str(), TRACE_EVENT_SCOPE_THREAD); // Modify the string in place (a wholesale reassignment may leave the old // string intact on the heap). name_string[0] = '@'; EndTraceAndFlush(); EXPECT_FALSE(FindTraceEntry(trace_parsed_, "event name")); EXPECT_TRUE(FindTraceEntry(trace_parsed_, name_string.c_str())); } TEST_F(TraceEventTestFixture, DeepCopy) { static const char kOriginalName1[] = "name1"; static const char kOriginalName2[] = "name2"; static const char kOriginalName3[] = "name3"; std::string name1(kOriginalName1); std::string name2(kOriginalName2); std::string name3(kOriginalName3); std::string arg1("arg1"); std::string arg2("arg2"); std::string val1("val1"); std::string val2("val2"); BeginTrace(); TRACE_EVENT_COPY_INSTANT0("category", name1.c_str(), TRACE_EVENT_SCOPE_THREAD); TRACE_EVENT_COPY_BEGIN1("category", name2.c_str(), arg1.c_str(), 5); TRACE_EVENT_COPY_END2("category", name3.c_str(), arg1.c_str(), val1, arg2.c_str(), val2); // As per NormallyNoDeepCopy, modify the strings in place. name1[0] = name2[0] = name3[0] = arg1[0] = arg2[0] = val1[0] = val2[0] = '@'; EndTraceAndFlush(); EXPECT_FALSE(FindTraceEntry(trace_parsed_, name1.c_str())); EXPECT_FALSE(FindTraceEntry(trace_parsed_, name2.c_str())); EXPECT_FALSE(FindTraceEntry(trace_parsed_, name3.c_str())); const DictionaryValue* entry1 = FindTraceEntry(trace_parsed_, kOriginalName1); const DictionaryValue* entry2 = FindTraceEntry(trace_parsed_, kOriginalName2); const DictionaryValue* entry3 = FindTraceEntry(trace_parsed_, kOriginalName3); ASSERT_TRUE(entry1); ASSERT_TRUE(entry2); ASSERT_TRUE(entry3); int i; EXPECT_FALSE(entry2->GetInteger("args.@rg1", &i)); EXPECT_TRUE(entry2->GetInteger("args.arg1", &i)); EXPECT_EQ(5, i); std::string s; EXPECT_TRUE(entry3->GetString("args.arg1", &s)); EXPECT_EQ("val1", s); EXPECT_TRUE(entry3->GetString("args.arg2", &s)); EXPECT_EQ("val2", s); } // Test that TraceResultBuffer outputs the correct result whether it is added // in chunks or added all at once. TEST_F(TraceEventTestFixture, TraceResultBuffer) { Clear(); trace_buffer_.Start(); trace_buffer_.AddFragment("bla1"); trace_buffer_.AddFragment("bla2"); trace_buffer_.AddFragment("bla3,bla4"); trace_buffer_.Finish(); EXPECT_STREQ(json_output_.json_output.c_str(), "[bla1,bla2,bla3,bla4]"); Clear(); trace_buffer_.Start(); trace_buffer_.AddFragment("bla1,bla2,bla3,bla4"); trace_buffer_.Finish(); EXPECT_STREQ(json_output_.json_output.c_str(), "[bla1,bla2,bla3,bla4]"); } // Test that trace_event parameters are not evaluated if the tracing // system is disabled. TEST_F(TraceEventTestFixture, TracingIsLazy) { BeginTrace(); int a = 0; TRACE_EVENT_INSTANT1("category", "test", TRACE_EVENT_SCOPE_THREAD, "a", a++); EXPECT_EQ(1, a); TraceLog::GetInstance()->SetDisabled(); TRACE_EVENT_INSTANT1("category", "test", TRACE_EVENT_SCOPE_THREAD, "a", a++); EXPECT_EQ(1, a); EndTraceAndFlush(); } TEST_F(TraceEventTestFixture, TraceEnableDisable) { TraceLog* trace_log = TraceLog::GetInstance(); TraceConfig tc_inc_all("*", ""); trace_log->SetEnabled(tc_inc_all, TraceLog::RECORDING_MODE); EXPECT_TRUE(trace_log->IsEnabled()); trace_log->SetDisabled(); EXPECT_FALSE(trace_log->IsEnabled()); trace_log->SetEnabled(tc_inc_all, TraceLog::RECORDING_MODE); EXPECT_TRUE(trace_log->IsEnabled()); const std::vector<std::string> empty; trace_log->SetEnabled(TraceConfig(), TraceLog::RECORDING_MODE); EXPECT_TRUE(trace_log->IsEnabled()); trace_log->SetDisabled(); EXPECT_FALSE(trace_log->IsEnabled()); trace_log->SetDisabled(); EXPECT_FALSE(trace_log->IsEnabled()); } TEST_F(TraceEventTestFixture, TraceCategoriesAfterNestedEnable) { TraceLog* trace_log = TraceLog::GetInstance(); trace_log->SetEnabled(TraceConfig("foo,bar", ""), TraceLog::RECORDING_MODE); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("foo")); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("bar")); EXPECT_FALSE(*trace_log->GetCategoryGroupEnabled("baz")); trace_log->SetEnabled(TraceConfig("foo2", ""), TraceLog::RECORDING_MODE); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("foo2")); EXPECT_FALSE(*trace_log->GetCategoryGroupEnabled("baz")); // The "" becomes the default catergory set when applied. trace_log->SetEnabled(TraceConfig(), TraceLog::RECORDING_MODE); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("foo")); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("baz")); EXPECT_STREQ( "-*Debug,-*Test", trace_log->GetCurrentTraceConfig().ToCategoryFilterString().c_str()); trace_log->SetDisabled(); trace_log->SetDisabled(); trace_log->SetDisabled(); EXPECT_FALSE(*trace_log->GetCategoryGroupEnabled("foo")); EXPECT_FALSE(*trace_log->GetCategoryGroupEnabled("baz")); trace_log->SetEnabled(TraceConfig("-foo,-bar", ""), TraceLog::RECORDING_MODE); EXPECT_FALSE(*trace_log->GetCategoryGroupEnabled("foo")); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("baz")); trace_log->SetEnabled(TraceConfig("moo", ""), TraceLog::RECORDING_MODE); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("baz")); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("moo")); EXPECT_FALSE(*trace_log->GetCategoryGroupEnabled("foo")); EXPECT_STREQ( "-foo,-bar", trace_log->GetCurrentTraceConfig().ToCategoryFilterString().c_str()); trace_log->SetDisabled(); trace_log->SetDisabled(); // Make sure disabled categories aren't cleared if we set in the second. trace_log->SetEnabled(TraceConfig("disabled-by-default-cc,foo", ""), TraceLog::RECORDING_MODE); EXPECT_FALSE(*trace_log->GetCategoryGroupEnabled("bar")); trace_log->SetEnabled(TraceConfig("disabled-by-default-gpu", ""), TraceLog::RECORDING_MODE); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("disabled-by-default-cc")); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("disabled-by-default-gpu")); EXPECT_TRUE(*trace_log->GetCategoryGroupEnabled("bar")); EXPECT_STREQ( "disabled-by-default-cc,disabled-by-default-gpu", trace_log->GetCurrentTraceConfig().ToCategoryFilterString().c_str()); trace_log->SetDisabled(); trace_log->SetDisabled(); } TEST_F(TraceEventTestFixture, TraceSampling) { TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, "record-until-full,enable-sampling"), TraceLog::RECORDING_MODE); TRACE_EVENT_SET_SAMPLING_STATE_FOR_BUCKET(1, "cc", "Stuff"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); TRACE_EVENT_SET_SAMPLING_STATE_FOR_BUCKET(1, "cc", "Things"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); EndTraceAndFlush(); // Make sure we hit at least once. EXPECT_TRUE(FindNamePhase("Stuff", "P")); EXPECT_TRUE(FindNamePhase("Things", "P")); } TEST_F(TraceEventTestFixture, TraceSamplingScope) { TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, "record-until-full,enable-sampling"), TraceLog::RECORDING_MODE); TRACE_EVENT_SCOPED_SAMPLING_STATE("AAA", "name"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); { EXPECT_STREQ(TRACE_EVENT_GET_SAMPLING_STATE(), "AAA"); TRACE_EVENT_SCOPED_SAMPLING_STATE("BBB", "name"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); EXPECT_STREQ(TRACE_EVENT_GET_SAMPLING_STATE(), "BBB"); } TraceLog::GetInstance()->WaitSamplingEventForTesting(); { EXPECT_STREQ(TRACE_EVENT_GET_SAMPLING_STATE(), "AAA"); TRACE_EVENT_SCOPED_SAMPLING_STATE("CCC", "name"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); EXPECT_STREQ(TRACE_EVENT_GET_SAMPLING_STATE(), "CCC"); } TraceLog::GetInstance()->WaitSamplingEventForTesting(); { EXPECT_STREQ(TRACE_EVENT_GET_SAMPLING_STATE(), "AAA"); TRACE_EVENT_SET_SAMPLING_STATE("DDD", "name"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); EXPECT_STREQ(TRACE_EVENT_GET_SAMPLING_STATE(), "DDD"); } TraceLog::GetInstance()->WaitSamplingEventForTesting(); EXPECT_STREQ(TRACE_EVENT_GET_SAMPLING_STATE(), "DDD"); EndTraceAndFlush(); } TEST_F(TraceEventTestFixture, TraceContinuousSampling) { TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, "record-until-full,enable-sampling"), TraceLog::MONITORING_MODE); TRACE_EVENT_SET_SAMPLING_STATE_FOR_BUCKET(1, "category", "AAA"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); TRACE_EVENT_SET_SAMPLING_STATE_FOR_BUCKET(1, "category", "BBB"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); FlushMonitoring(); // Make sure we can get the profiled data. EXPECT_TRUE(FindNamePhase("AAA", "P")); EXPECT_TRUE(FindNamePhase("BBB", "P")); Clear(); TraceLog::GetInstance()->WaitSamplingEventForTesting(); TRACE_EVENT_SET_SAMPLING_STATE_FOR_BUCKET(1, "category", "CCC"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); TRACE_EVENT_SET_SAMPLING_STATE_FOR_BUCKET(1, "category", "DDD"); TraceLog::GetInstance()->WaitSamplingEventForTesting(); FlushMonitoring(); // Make sure the profiled data is accumulated. EXPECT_TRUE(FindNamePhase("AAA", "P")); EXPECT_TRUE(FindNamePhase("BBB", "P")); EXPECT_TRUE(FindNamePhase("CCC", "P")); EXPECT_TRUE(FindNamePhase("DDD", "P")); Clear(); TraceLog::GetInstance()->SetDisabled(); // Make sure disabling the continuous sampling thread clears // the profiled data. EXPECT_FALSE(FindNamePhase("AAA", "P")); EXPECT_FALSE(FindNamePhase("BBB", "P")); EXPECT_FALSE(FindNamePhase("CCC", "P")); EXPECT_FALSE(FindNamePhase("DDD", "P")); Clear(); } class MyData : public ConvertableToTraceFormat { public: MyData() {} void AppendAsTraceFormat(std::string* out) const override { out->append("{\"foo\":1}"); } private: ~MyData() override {} DISALLOW_COPY_AND_ASSIGN(MyData); }; TEST_F(TraceEventTestFixture, ConvertableTypes) { TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); scoped_refptr<ConvertableToTraceFormat> data(new MyData()); scoped_refptr<ConvertableToTraceFormat> data1(new MyData()); scoped_refptr<ConvertableToTraceFormat> data2(new MyData()); TRACE_EVENT1("foo", "bar", "data", data); TRACE_EVENT2("foo", "baz", "data1", data1, "data2", data2); scoped_refptr<ConvertableToTraceFormat> convertData1(new MyData()); scoped_refptr<ConvertableToTraceFormat> convertData2(new MyData()); TRACE_EVENT2( "foo", "string_first", "str", "string value 1", "convert", convertData1); TRACE_EVENT2( "foo", "string_second", "convert", convertData2, "str", "string value 2"); EndTraceAndFlush(); // One arg version. DictionaryValue* dict = FindNamePhase("bar", "X"); ASSERT_TRUE(dict); const DictionaryValue* args_dict = NULL; dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); const Value* value = NULL; const DictionaryValue* convertable_dict = NULL; EXPECT_TRUE(args_dict->Get("data", &value)); ASSERT_TRUE(value->GetAsDictionary(&convertable_dict)); int foo_val; EXPECT_TRUE(convertable_dict->GetInteger("foo", &foo_val)); EXPECT_EQ(1, foo_val); // Two arg version. dict = FindNamePhase("baz", "X"); ASSERT_TRUE(dict); args_dict = NULL; dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); value = NULL; convertable_dict = NULL; EXPECT_TRUE(args_dict->Get("data1", &value)); ASSERT_TRUE(value->GetAsDictionary(&convertable_dict)); value = NULL; convertable_dict = NULL; EXPECT_TRUE(args_dict->Get("data2", &value)); ASSERT_TRUE(value->GetAsDictionary(&convertable_dict)); // Convertable with other types. dict = FindNamePhase("string_first", "X"); ASSERT_TRUE(dict); args_dict = NULL; dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); std::string str_value; EXPECT_TRUE(args_dict->GetString("str", &str_value)); EXPECT_STREQ("string value 1", str_value.c_str()); value = NULL; convertable_dict = NULL; foo_val = 0; EXPECT_TRUE(args_dict->Get("convert", &value)); ASSERT_TRUE(value->GetAsDictionary(&convertable_dict)); EXPECT_TRUE(convertable_dict->GetInteger("foo", &foo_val)); EXPECT_EQ(1, foo_val); dict = FindNamePhase("string_second", "X"); ASSERT_TRUE(dict); args_dict = NULL; dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetString("str", &str_value)); EXPECT_STREQ("string value 2", str_value.c_str()); value = NULL; convertable_dict = NULL; foo_val = 0; EXPECT_TRUE(args_dict->Get("convert", &value)); ASSERT_TRUE(value->GetAsDictionary(&convertable_dict)); EXPECT_TRUE(convertable_dict->GetInteger("foo", &foo_val)); EXPECT_EQ(1, foo_val); } TEST_F(TraceEventTestFixture, PrimitiveArgs) { TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); TRACE_EVENT1("foo", "event1", "int_one", 1); TRACE_EVENT1("foo", "event2", "int_neg_ten", -10); TRACE_EVENT1("foo", "event3", "float_one", 1.0f); TRACE_EVENT1("foo", "event4", "float_half", .5f); TRACE_EVENT1("foo", "event5", "float_neghalf", -.5f); TRACE_EVENT1("foo", "event6", "float_infinity", std::numeric_limits<float>::infinity()); TRACE_EVENT1("foo", "event6b", "float_neg_infinity", -std::numeric_limits<float>::infinity()); TRACE_EVENT1("foo", "event7", "double_nan", std::numeric_limits<double>::quiet_NaN()); void* p = 0; TRACE_EVENT1("foo", "event8", "pointer_null", p); p = reinterpret_cast<void*>(0xbadf00d); TRACE_EVENT1("foo", "event9", "pointer_badf00d", p); TRACE_EVENT1("foo", "event10", "bool_true", true); TRACE_EVENT1("foo", "event11", "bool_false", false); TRACE_EVENT1("foo", "event12", "time_null", base::Time()); TRACE_EVENT1("foo", "event13", "time_one", base::Time::FromInternalValue(1)); TRACE_EVENT1("foo", "event14", "timeticks_null", base::TimeTicks()); TRACE_EVENT1("foo", "event15", "timeticks_one", base::TimeTicks::FromInternalValue(1)); EndTraceAndFlush(); const DictionaryValue* args_dict = NULL; DictionaryValue* dict = NULL; const Value* value = NULL; std::string str_value; int int_value; double double_value; bool bool_value; dict = FindNamePhase("event1", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetInteger("int_one", &int_value)); EXPECT_EQ(1, int_value); dict = FindNamePhase("event2", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetInteger("int_neg_ten", &int_value)); EXPECT_EQ(-10, int_value); // 1f must be serlized to JSON as "1.0" in order to be a double, not an int. dict = FindNamePhase("event3", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->Get("float_one", &value)); EXPECT_TRUE(value->IsType(Value::TYPE_DOUBLE)); EXPECT_TRUE(value->GetAsDouble(&double_value)); EXPECT_EQ(1, double_value); // .5f must be serlized to JSON as "0.5". dict = FindNamePhase("event4", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->Get("float_half", &value)); EXPECT_TRUE(value->IsType(Value::TYPE_DOUBLE)); EXPECT_TRUE(value->GetAsDouble(&double_value)); EXPECT_EQ(0.5, double_value); // -.5f must be serlized to JSON as "-0.5". dict = FindNamePhase("event5", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->Get("float_neghalf", &value)); EXPECT_TRUE(value->IsType(Value::TYPE_DOUBLE)); EXPECT_TRUE(value->GetAsDouble(&double_value)); EXPECT_EQ(-0.5, double_value); // Infinity is serialized to JSON as a string. dict = FindNamePhase("event6", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetString("float_infinity", &str_value)); EXPECT_STREQ("Infinity", str_value.c_str()); dict = FindNamePhase("event6b", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetString("float_neg_infinity", &str_value)); EXPECT_STREQ("-Infinity", str_value.c_str()); // NaN is serialized to JSON as a string. dict = FindNamePhase("event7", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetString("double_nan", &str_value)); EXPECT_STREQ("NaN", str_value.c_str()); // NULL pointers should be serialized as "0x0". dict = FindNamePhase("event8", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetString("pointer_null", &str_value)); EXPECT_STREQ("0x0", str_value.c_str()); // Other pointers should be serlized as a hex string. dict = FindNamePhase("event9", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetString("pointer_badf00d", &str_value)); EXPECT_STREQ("0xbadf00d", str_value.c_str()); dict = FindNamePhase("event10", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetBoolean("bool_true", &bool_value)); EXPECT_TRUE(bool_value); dict = FindNamePhase("event11", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetBoolean("bool_false", &bool_value)); EXPECT_FALSE(bool_value); dict = FindNamePhase("event12", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetInteger("time_null", &int_value)); EXPECT_EQ(0, int_value); dict = FindNamePhase("event13", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetInteger("time_one", &int_value)); EXPECT_EQ(1, int_value); dict = FindNamePhase("event14", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetInteger("timeticks_null", &int_value)); EXPECT_EQ(0, int_value); dict = FindNamePhase("event15", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetInteger("timeticks_one", &int_value)); EXPECT_EQ(1, int_value); } namespace { bool IsArgNameWhitelisted(const char* arg_name) { return base::MatchPattern(arg_name, "granular_arg_whitelisted"); } bool IsTraceEventArgsWhitelisted(const char* category_group_name, const char* event_name, ArgumentNameFilterPredicate* arg_filter) { if (base::MatchPattern(category_group_name, "toplevel") && base::MatchPattern(event_name, "*")) { return true; } if (base::MatchPattern(category_group_name, "benchmark") && base::MatchPattern(event_name, "granularly_whitelisted")) { *arg_filter = base::Bind(&IsArgNameWhitelisted); return true; } return false; } } // namespace TEST_F(TraceEventTestFixture, ArgsWhitelisting) { TraceLog::GetInstance()->SetArgumentFilterPredicate( base::Bind(&IsTraceEventArgsWhitelisted)); TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, "enable-argument-filter"), TraceLog::RECORDING_MODE); TRACE_EVENT1("toplevel", "event1", "int_one", 1); TRACE_EVENT1("whitewashed", "event2", "int_two", 1); TRACE_EVENT2("benchmark", "granularly_whitelisted", "granular_arg_whitelisted", "whitelisted_value", "granular_arg_blacklisted", "blacklisted_value"); EndTraceAndFlush(); const DictionaryValue* args_dict = NULL; DictionaryValue* dict = NULL; int int_value; dict = FindNamePhase("event1", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetInteger("int_one", &int_value)); EXPECT_EQ(1, int_value); dict = FindNamePhase("event2", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_FALSE(args_dict->GetInteger("int_two", &int_value)); std::string args_string; EXPECT_TRUE(dict->GetString("args", &args_string)); EXPECT_EQ(args_string, "__stripped__"); dict = FindNamePhase("granularly_whitelisted", "X"); ASSERT_TRUE(dict); dict->GetDictionary("args", &args_dict); ASSERT_TRUE(args_dict); EXPECT_TRUE(args_dict->GetString("granular_arg_whitelisted", &args_string)); EXPECT_EQ(args_string, "whitelisted_value"); EXPECT_TRUE(args_dict->GetString("granular_arg_blacklisted", &args_string)); EXPECT_EQ(args_string, "__stripped__"); } class TraceEventCallbackTest : public TraceEventTestFixture { public: void SetUp() override { TraceEventTestFixture::SetUp(); ASSERT_EQ(NULL, s_instance); s_instance = this; } void TearDown() override { TraceLog::GetInstance()->SetDisabled(); ASSERT_TRUE(s_instance); s_instance = NULL; TraceEventTestFixture::TearDown(); } protected: // For TraceEventCallbackAndRecordingX tests. void VerifyCallbackAndRecordedEvents(size_t expected_callback_count, size_t expected_recorded_count) { // Callback events. EXPECT_EQ(expected_callback_count, collected_events_names_.size()); for (size_t i = 0; i < collected_events_names_.size(); ++i) { EXPECT_EQ("callback", collected_events_categories_[i]); EXPECT_EQ("yes", collected_events_names_[i]); } // Recorded events. EXPECT_EQ(expected_recorded_count, trace_parsed_.GetSize()); EXPECT_TRUE(FindTraceEntry(trace_parsed_, "recording")); EXPECT_FALSE(FindTraceEntry(trace_parsed_, "callback")); EXPECT_TRUE(FindTraceEntry(trace_parsed_, "yes")); EXPECT_FALSE(FindTraceEntry(trace_parsed_, "no")); } void VerifyCollectedEvent(size_t i, unsigned phase, const std::string& category, const std::string& name) { EXPECT_EQ(phase, collected_events_phases_[i]); EXPECT_EQ(category, collected_events_categories_[i]); EXPECT_EQ(name, collected_events_names_[i]); } std::vector<std::string> collected_events_categories_; std::vector<std::string> collected_events_names_; std::vector<unsigned char> collected_events_phases_; std::vector<TimeTicks> collected_events_timestamps_; static TraceEventCallbackTest* s_instance; static void Callback(TimeTicks timestamp, char phase, const unsigned char* category_group_enabled, const char* name, unsigned long long id, int num_args, const char* const arg_names[], const unsigned char arg_types[], const unsigned long long arg_values[], unsigned int flags) { s_instance->collected_events_phases_.push_back(phase); s_instance->collected_events_categories_.push_back( TraceLog::GetCategoryGroupName(category_group_enabled)); s_instance->collected_events_names_.push_back(name); s_instance->collected_events_timestamps_.push_back(timestamp); } }; TraceEventCallbackTest* TraceEventCallbackTest::s_instance; TEST_F(TraceEventCallbackTest, TraceEventCallback) { TRACE_EVENT_INSTANT0("all", "before enable", TRACE_EVENT_SCOPE_THREAD); TraceLog::GetInstance()->SetEventCallbackEnabled( TraceConfig(kRecordAllCategoryFilter, ""), Callback); TRACE_EVENT_INSTANT0("all", "event1", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("all", "event2", TRACE_EVENT_SCOPE_GLOBAL); { TRACE_EVENT0("all", "duration"); TRACE_EVENT_INSTANT0("all", "event3", TRACE_EVENT_SCOPE_GLOBAL); } TraceLog::GetInstance()->SetEventCallbackDisabled(); TRACE_EVENT_INSTANT0("all", "after callback removed", TRACE_EVENT_SCOPE_GLOBAL); ASSERT_EQ(5u, collected_events_names_.size()); EXPECT_EQ("event1", collected_events_names_[0]); EXPECT_EQ(TRACE_EVENT_PHASE_INSTANT, collected_events_phases_[0]); EXPECT_EQ("event2", collected_events_names_[1]); EXPECT_EQ(TRACE_EVENT_PHASE_INSTANT, collected_events_phases_[1]); EXPECT_EQ("duration", collected_events_names_[2]); EXPECT_EQ(TRACE_EVENT_PHASE_BEGIN, collected_events_phases_[2]); EXPECT_EQ("event3", collected_events_names_[3]); EXPECT_EQ(TRACE_EVENT_PHASE_INSTANT, collected_events_phases_[3]); EXPECT_EQ("duration", collected_events_names_[4]); EXPECT_EQ(TRACE_EVENT_PHASE_END, collected_events_phases_[4]); for (size_t i = 1; i < collected_events_timestamps_.size(); i++) { EXPECT_LE(collected_events_timestamps_[i - 1], collected_events_timestamps_[i]); } } TEST_F(TraceEventCallbackTest, TraceEventCallbackWhileFull) { TraceLog::GetInstance()->SetEnabled(TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); do { TRACE_EVENT_INSTANT0("all", "badger badger", TRACE_EVENT_SCOPE_GLOBAL); } while (!TraceLog::GetInstance()->BufferIsFull()); TraceLog::GetInstance()->SetEventCallbackEnabled( TraceConfig(kRecordAllCategoryFilter, ""), Callback); TRACE_EVENT_INSTANT0("all", "a snake", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackDisabled(); ASSERT_EQ(1u, collected_events_names_.size()); EXPECT_EQ("a snake", collected_events_names_[0]); } // 1: Enable callback, enable recording, disable callback, disable recording. TEST_F(TraceEventCallbackTest, TraceEventCallbackAndRecording1) { TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackEnabled(TraceConfig("callback", ""), Callback); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEnabled(TraceConfig("recording", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackDisabled(); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); EndTraceAndFlush(); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); DropTracedMetadataRecords(); VerifyCallbackAndRecordedEvents(2, 2); } // 2: Enable callback, enable recording, disable recording, disable callback. TEST_F(TraceEventCallbackTest, TraceEventCallbackAndRecording2) { TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackEnabled(TraceConfig("callback", ""), Callback); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEnabled(TraceConfig("recording", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); EndTraceAndFlush(); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackDisabled(); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); DropTracedMetadataRecords(); VerifyCallbackAndRecordedEvents(3, 1); } // 3: Enable recording, enable callback, disable callback, disable recording. TEST_F(TraceEventCallbackTest, TraceEventCallbackAndRecording3) { TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEnabled(TraceConfig("recording", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackEnabled(TraceConfig("callback", ""), Callback); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackDisabled(); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); EndTraceAndFlush(); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); DropTracedMetadataRecords(); VerifyCallbackAndRecordedEvents(1, 3); } // 4: Enable recording, enable callback, disable recording, disable callback. TEST_F(TraceEventCallbackTest, TraceEventCallbackAndRecording4) { TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEnabled(TraceConfig("recording", ""), TraceLog::RECORDING_MODE); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackEnabled(TraceConfig("callback", ""), Callback); TRACE_EVENT_INSTANT0("recording", "yes", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); EndTraceAndFlush(); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "yes", TRACE_EVENT_SCOPE_GLOBAL); TraceLog::GetInstance()->SetEventCallbackDisabled(); TRACE_EVENT_INSTANT0("recording", "no", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_INSTANT0("callback", "no", TRACE_EVENT_SCOPE_GLOBAL); DropTracedMetadataRecords(); VerifyCallbackAndRecordedEvents(2, 2); } TEST_F(TraceEventCallbackTest, TraceEventCallbackAndRecordingDuration) { TraceLog::GetInstance()->SetEventCallbackEnabled( TraceConfig(kRecordAllCategoryFilter, ""), Callback); { TRACE_EVENT0("callback", "duration1"); TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); TRACE_EVENT0("callback", "duration2"); EndTraceAndFlush(); TRACE_EVENT0("callback", "duration3"); } TraceLog::GetInstance()->SetEventCallbackDisabled(); ASSERT_EQ(6u, collected_events_names_.size()); VerifyCollectedEvent(0, TRACE_EVENT_PHASE_BEGIN, "callback", "duration1"); VerifyCollectedEvent(1, TRACE_EVENT_PHASE_BEGIN, "callback", "duration2"); VerifyCollectedEvent(2, TRACE_EVENT_PHASE_BEGIN, "callback", "duration3"); VerifyCollectedEvent(3, TRACE_EVENT_PHASE_END, "callback", "duration3"); VerifyCollectedEvent(4, TRACE_EVENT_PHASE_END, "callback", "duration2"); VerifyCollectedEvent(5, TRACE_EVENT_PHASE_END, "callback", "duration1"); } TEST_F(TraceEventTestFixture, TraceBufferVectorReportFull) { TraceLog* trace_log = TraceLog::GetInstance(); trace_log->SetEnabled( TraceConfig(kRecordAllCategoryFilter, ""), TraceLog::RECORDING_MODE); trace_log->logged_events_.reset( TraceBuffer::CreateTraceBufferVectorOfSize(100)); do { TRACE_EVENT_BEGIN_WITH_ID_TID_AND_TIMESTAMP0( "all", "with_timestamp", 0, 0, TimeTicks::Now().ToInternalValue()); TRACE_EVENT_END_WITH_ID_TID_AND_TIMESTAMP0( "all", "with_timestamp", 0, 0, TimeTicks::Now().ToInternalValue()); } while (!trace_log->BufferIsFull()); EndTraceAndFlush(); const DictionaryValue* trace_full_metadata = NULL; trace_full_metadata = FindTraceEntry(trace_parsed_, "overflowed_at_ts"); std::string phase; double buffer_limit_reached_timestamp = 0; EXPECT_TRUE(trace_full_metadata); EXPECT_TRUE(trace_full_metadata->GetString("ph", &phase)); EXPECT_EQ("M", phase); EXPECT_TRUE(trace_full_metadata->GetDouble( "args.overflowed_at_ts", &buffer_limit_reached_timestamp)); EXPECT_DOUBLE_EQ( static_cast<double>( trace_log->buffer_limit_reached_timestamp_.ToInternalValue()), buffer_limit_reached_timestamp); // Test that buffer_limit_reached_timestamp's value is between the timestamp // of the last trace event and current time. DropTracedMetadataRecords(); const DictionaryValue* last_trace_event = NULL; double last_trace_event_timestamp = 0; EXPECT_TRUE(trace_parsed_.GetDictionary(trace_parsed_.GetSize() - 1, &last_trace_event)); EXPECT_TRUE(last_trace_event->GetDouble("ts", &last_trace_event_timestamp)); EXPECT_LE(last_trace_event_timestamp, buffer_limit_reached_timestamp); EXPECT_LE(buffer_limit_reached_timestamp, trace_log->OffsetNow().ToInternalValue()); } TEST_F(TraceEventTestFixture, TraceBufferRingBufferGetReturnChunk) { TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, RECORD_CONTINUOUSLY), TraceLog::RECORDING_MODE); TraceBuffer* buffer = TraceLog::GetInstance()->trace_buffer(); size_t capacity = buffer->Capacity(); size_t num_chunks = capacity / TraceBufferChunk::kTraceBufferChunkSize; uint32_t last_seq = 0; size_t chunk_index; EXPECT_EQ(0u, buffer->Size()); scoped_ptr<TraceBufferChunk*[]> chunks(new TraceBufferChunk*[num_chunks]); for (size_t i = 0; i < num_chunks; ++i) { chunks[i] = buffer->GetChunk(&chunk_index).release(); EXPECT_TRUE(chunks[i]); EXPECT_EQ(i, chunk_index); EXPECT_GT(chunks[i]->seq(), last_seq); EXPECT_EQ((i + 1) * TraceBufferChunk::kTraceBufferChunkSize, buffer->Size()); last_seq = chunks[i]->seq(); } // Ring buffer is never full. EXPECT_FALSE(buffer->IsFull()); // Return all chunks in original order. for (size_t i = 0; i < num_chunks; ++i) buffer->ReturnChunk(i, scoped_ptr<TraceBufferChunk>(chunks[i])); // Should recycle the chunks in the returned order. for (size_t i = 0; i < num_chunks; ++i) { chunks[i] = buffer->GetChunk(&chunk_index).release(); EXPECT_TRUE(chunks[i]); EXPECT_EQ(i, chunk_index); EXPECT_GT(chunks[i]->seq(), last_seq); last_seq = chunks[i]->seq(); } // Return all chunks in reverse order. for (size_t i = 0; i < num_chunks; ++i) { buffer->ReturnChunk( num_chunks - i - 1, scoped_ptr<TraceBufferChunk>(chunks[num_chunks - i - 1])); } // Should recycle the chunks in the returned order. for (size_t i = 0; i < num_chunks; ++i) { chunks[i] = buffer->GetChunk(&chunk_index).release(); EXPECT_TRUE(chunks[i]); EXPECT_EQ(num_chunks - i - 1, chunk_index); EXPECT_GT(chunks[i]->seq(), last_seq); last_seq = chunks[i]->seq(); } for (size_t i = 0; i < num_chunks; ++i) buffer->ReturnChunk(i, scoped_ptr<TraceBufferChunk>(chunks[i])); TraceLog::GetInstance()->SetDisabled(); } TEST_F(TraceEventTestFixture, TraceBufferRingBufferHalfIteration) { TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, RECORD_CONTINUOUSLY), TraceLog::RECORDING_MODE); TraceBuffer* buffer = TraceLog::GetInstance()->trace_buffer(); size_t capacity = buffer->Capacity(); size_t num_chunks = capacity / TraceBufferChunk::kTraceBufferChunkSize; size_t chunk_index; EXPECT_EQ(0u, buffer->Size()); EXPECT_FALSE(buffer->NextChunk()); size_t half_chunks = num_chunks / 2; scoped_ptr<TraceBufferChunk*[]> chunks(new TraceBufferChunk*[half_chunks]); for (size_t i = 0; i < half_chunks; ++i) { chunks[i] = buffer->GetChunk(&chunk_index).release(); EXPECT_TRUE(chunks[i]); EXPECT_EQ(i, chunk_index); } for (size_t i = 0; i < half_chunks; ++i) buffer->ReturnChunk(i, scoped_ptr<TraceBufferChunk>(chunks[i])); for (size_t i = 0; i < half_chunks; ++i) EXPECT_EQ(chunks[i], buffer->NextChunk()); EXPECT_FALSE(buffer->NextChunk()); TraceLog::GetInstance()->SetDisabled(); } TEST_F(TraceEventTestFixture, TraceBufferRingBufferFullIteration) { TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, RECORD_CONTINUOUSLY), TraceLog::RECORDING_MODE); TraceBuffer* buffer = TraceLog::GetInstance()->trace_buffer(); size_t capacity = buffer->Capacity(); size_t num_chunks = capacity / TraceBufferChunk::kTraceBufferChunkSize; size_t chunk_index; EXPECT_EQ(0u, buffer->Size()); EXPECT_FALSE(buffer->NextChunk()); scoped_ptr<TraceBufferChunk*[]> chunks(new TraceBufferChunk*[num_chunks]); for (size_t i = 0; i < num_chunks; ++i) { chunks[i] = buffer->GetChunk(&chunk_index).release(); EXPECT_TRUE(chunks[i]); EXPECT_EQ(i, chunk_index); } for (size_t i = 0; i < num_chunks; ++i) buffer->ReturnChunk(i, scoped_ptr<TraceBufferChunk>(chunks[i])); for (size_t i = 0; i < num_chunks; ++i) EXPECT_TRUE(chunks[i] == buffer->NextChunk()); EXPECT_FALSE(buffer->NextChunk()); TraceLog::GetInstance()->SetDisabled(); } TEST_F(TraceEventTestFixture, TraceRecordAsMuchAsPossibleMode) { TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, RECORD_AS_MUCH_AS_POSSIBLE), TraceLog::RECORDING_MODE); TraceBuffer* buffer = TraceLog::GetInstance()->trace_buffer(); EXPECT_EQ(512000000UL, buffer->Capacity()); TraceLog::GetInstance()->SetDisabled(); } void BlockUntilStopped(WaitableEvent* task_start_event, WaitableEvent* task_stop_event) { task_start_event->Signal(); task_stop_event->Wait(); } TEST_F(TraceEventTestFixture, SetCurrentThreadBlocksMessageLoopBeforeTracing) { BeginTrace(); Thread thread("1"); WaitableEvent task_complete_event(false, false); thread.Start(); thread.task_runner()->PostTask( FROM_HERE, Bind(&TraceLog::SetCurrentThreadBlocksMessageLoop, Unretained(TraceLog::GetInstance()))); thread.task_runner()->PostTask( FROM_HERE, Bind(&TraceWithAllMacroVariants, &task_complete_event)); task_complete_event.Wait(); WaitableEvent task_start_event(false, false); WaitableEvent task_stop_event(false, false); thread.task_runner()->PostTask( FROM_HERE, Bind(&BlockUntilStopped, &task_start_event, &task_stop_event)); task_start_event.Wait(); EndTraceAndFlush(); ValidateAllTraceMacrosCreatedData(trace_parsed_); task_stop_event.Signal(); thread.Stop(); } TEST_F(TraceEventTestFixture, ConvertTraceConfigToInternalOptions) { TraceLog* trace_log = TraceLog::GetInstance(); EXPECT_EQ(TraceLog::kInternalRecordUntilFull, trace_log->GetInternalOptionsFromTraceConfig( TraceConfig(kRecordAllCategoryFilter, RECORD_UNTIL_FULL))); EXPECT_EQ(TraceLog::kInternalRecordContinuously, trace_log->GetInternalOptionsFromTraceConfig( TraceConfig(kRecordAllCategoryFilter, RECORD_CONTINUOUSLY))); EXPECT_EQ(TraceLog::kInternalEchoToConsole, trace_log->GetInternalOptionsFromTraceConfig( TraceConfig(kRecordAllCategoryFilter, ECHO_TO_CONSOLE))); EXPECT_EQ( TraceLog::kInternalRecordUntilFull | TraceLog::kInternalEnableSampling, trace_log->GetInternalOptionsFromTraceConfig( TraceConfig(kRecordAllCategoryFilter, "record-until-full,enable-sampling"))); EXPECT_EQ( TraceLog::kInternalRecordContinuously | TraceLog::kInternalEnableSampling, trace_log->GetInternalOptionsFromTraceConfig( TraceConfig(kRecordAllCategoryFilter, "record-continuously,enable-sampling"))); EXPECT_EQ( TraceLog::kInternalEchoToConsole | TraceLog::kInternalEnableSampling, trace_log->GetInternalOptionsFromTraceConfig( TraceConfig(kRecordAllCategoryFilter, "trace-to-console,enable-sampling"))); EXPECT_EQ( TraceLog::kInternalEchoToConsole | TraceLog::kInternalEnableSampling, trace_log->GetInternalOptionsFromTraceConfig( TraceConfig("*", "trace-to-console,enable-sampling,enable-systrace"))); } void SetBlockingFlagAndBlockUntilStopped(WaitableEvent* task_start_event, WaitableEvent* task_stop_event) { TraceLog::GetInstance()->SetCurrentThreadBlocksMessageLoop(); BlockUntilStopped(task_start_event, task_stop_event); } TEST_F(TraceEventTestFixture, SetCurrentThreadBlocksMessageLoopAfterTracing) { BeginTrace(); Thread thread("1"); WaitableEvent task_complete_event(false, false); thread.Start(); thread.task_runner()->PostTask( FROM_HERE, Bind(&TraceWithAllMacroVariants, &task_complete_event)); task_complete_event.Wait(); WaitableEvent task_start_event(false, false); WaitableEvent task_stop_event(false, false); thread.task_runner()->PostTask( FROM_HERE, Bind(&SetBlockingFlagAndBlockUntilStopped, &task_start_event, &task_stop_event)); task_start_event.Wait(); EndTraceAndFlush(); ValidateAllTraceMacrosCreatedData(trace_parsed_); task_stop_event.Signal(); thread.Stop(); } TEST_F(TraceEventTestFixture, ThreadOnceBlocking) { BeginTrace(); Thread thread("1"); WaitableEvent task_complete_event(false, false); thread.Start(); thread.task_runner()->PostTask( FROM_HERE, Bind(&TraceWithAllMacroVariants, &task_complete_event)); task_complete_event.Wait(); task_complete_event.Reset(); WaitableEvent task_start_event(false, false); WaitableEvent task_stop_event(false, false); thread.task_runner()->PostTask( FROM_HERE, Bind(&BlockUntilStopped, &task_start_event, &task_stop_event)); task_start_event.Wait(); // The thread will timeout in this flush. EndTraceAndFlushInThreadWithMessageLoop(); Clear(); // Let the thread's message loop continue to spin. task_stop_event.Signal(); // The following sequence ensures that the FlushCurrentThread task has been // executed in the thread before continuing. task_start_event.Reset(); task_stop_event.Reset(); thread.task_runner()->PostTask( FROM_HERE, Bind(&BlockUntilStopped, &task_start_event, &task_stop_event)); task_start_event.Wait(); task_stop_event.Signal(); Clear(); // TraceLog should discover the generation mismatch and recover the thread // local buffer for the thread without any error. BeginTrace(); thread.task_runner()->PostTask( FROM_HERE, Bind(&TraceWithAllMacroVariants, &task_complete_event)); task_complete_event.Wait(); task_complete_event.Reset(); EndTraceAndFlushInThreadWithMessageLoop(); ValidateAllTraceMacrosCreatedData(trace_parsed_); } std::string* g_log_buffer = NULL; bool MockLogMessageHandler(int, const char*, int, size_t, const std::string& str) { if (!g_log_buffer) g_log_buffer = new std::string(); g_log_buffer->append(str); return false; } TEST_F(TraceEventTestFixture, EchoToConsole) { logging::LogMessageHandlerFunction old_log_message_handler = logging::GetLogMessageHandler(); logging::SetLogMessageHandler(MockLogMessageHandler); TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, ECHO_TO_CONSOLE), TraceLog::RECORDING_MODE); TRACE_EVENT_BEGIN0("a", "begin_end"); { TRACE_EVENT0("b", "duration"); TRACE_EVENT0("b1", "duration1"); } TRACE_EVENT_INSTANT0("c", "instant", TRACE_EVENT_SCOPE_GLOBAL); TRACE_EVENT_END0("a", "begin_end"); EXPECT_NE(std::string::npos, g_log_buffer->find("begin_end[a]\x1b")); EXPECT_NE(std::string::npos, g_log_buffer->find("| duration[b]\x1b")); EXPECT_NE(std::string::npos, g_log_buffer->find("| | duration1[b1]\x1b")); EXPECT_NE(std::string::npos, g_log_buffer->find("| | duration1[b1] (")); EXPECT_NE(std::string::npos, g_log_buffer->find("| duration[b] (")); EXPECT_NE(std::string::npos, g_log_buffer->find("| instant[c]\x1b")); EXPECT_NE(std::string::npos, g_log_buffer->find("begin_end[a] (")); EndTraceAndFlush(); delete g_log_buffer; logging::SetLogMessageHandler(old_log_message_handler); g_log_buffer = NULL; } bool LogMessageHandlerWithTraceEvent(int, const char*, int, size_t, const std::string&) { TRACE_EVENT0("log", "trace_event"); return false; } TEST_F(TraceEventTestFixture, EchoToConsoleTraceEventRecursion) { logging::LogMessageHandlerFunction old_log_message_handler = logging::GetLogMessageHandler(); logging::SetLogMessageHandler(LogMessageHandlerWithTraceEvent); TraceLog::GetInstance()->SetEnabled( TraceConfig(kRecordAllCategoryFilter, ECHO_TO_CONSOLE), TraceLog::RECORDING_MODE); { // This should not cause deadlock or infinite recursion. TRACE_EVENT0("b", "duration"); } EndTraceAndFlush(); logging::SetLogMessageHandler(old_log_message_handler); } TEST_F(TraceEventTestFixture, TimeOffset) { BeginTrace(); // Let TraceLog timer start from 0. TimeDelta time_offset = TimeTicks::Now() - TimeTicks(); TraceLog::GetInstance()->SetTimeOffset(time_offset); { TRACE_EVENT0("all", "duration1"); TRACE_EVENT0("all", "duration2"); } TRACE_EVENT_BEGIN_WITH_ID_TID_AND_TIMESTAMP0( "all", "with_timestamp", 0, 0, TimeTicks::Now().ToInternalValue()); TRACE_EVENT_END_WITH_ID_TID_AND_TIMESTAMP0( "all", "with_timestamp", 0, 0, TimeTicks::Now().ToInternalValue()); EndTraceAndFlush(); DropTracedMetadataRecords(); double end_time = static_cast<double>( (TimeTicks::Now() - time_offset).ToInternalValue()); double last_timestamp = 0; for (size_t i = 0; i < trace_parsed_.GetSize(); ++i) { const DictionaryValue* item; EXPECT_TRUE(trace_parsed_.GetDictionary(i, &item)); double timestamp; EXPECT_TRUE(item->GetDouble("ts", ×tamp)); EXPECT_GE(timestamp, last_timestamp); EXPECT_LE(timestamp, end_time); last_timestamp = timestamp; } } TEST_F(TraceEventTestFixture, ConfigureSyntheticDelays) { BeginSpecificTrace("DELAY(test.Delay;0.05)"); base::TimeTicks start = base::TimeTicks::Now(); { TRACE_EVENT_SYNTHETIC_DELAY("test.Delay"); } base::TimeDelta duration = base::TimeTicks::Now() - start; EXPECT_GE(duration.InMilliseconds(), 50); EndTraceAndFlush(); } TEST_F(TraceEventTestFixture, BadSyntheticDelayConfigurations) { const char* const filters[] = { "", "DELAY(", "DELAY(;", "DELAY(;)", "DELAY(test.Delay)", "DELAY(test.Delay;)" }; for (size_t i = 0; i < arraysize(filters); i++) { BeginSpecificTrace(filters[i]); EndTraceAndFlush(); TraceConfig trace_config = TraceLog::GetInstance()->GetCurrentTraceConfig(); EXPECT_EQ(0u, trace_config.GetSyntheticDelayValues().size()); } } TEST_F(TraceEventTestFixture, SyntheticDelayConfigurationMerging) { TraceConfig config1("DELAY(test.Delay1;16)", ""); TraceConfig config2("DELAY(test.Delay2;32)", ""); config1.Merge(config2); EXPECT_EQ(2u, config1.GetSyntheticDelayValues().size()); } TEST_F(TraceEventTestFixture, SyntheticDelayConfigurationToString) { const char filter[] = "DELAY(test.Delay;16;oneshot)"; TraceConfig config(filter, ""); EXPECT_EQ(filter, config.ToCategoryFilterString()); } } // namespace trace_event } // namespace base