simpleperf/cmd_record_test.cpp - platform/system/extras - Git at Google

 /*
  * Copyright (C) 2015 The Android Open Source Project
  *
  * Licensed under the Apache License, Version 2.0 (the "License");
  * you may not use this file except in compliance with the License.
  * You may obtain a copy of the License at
  *
  *      http://www.apache.org/licenses/LICENSE-2.0
  *
  * Unless required by applicable law or agreed to in writing, software
  * distributed under the License is distributed on an "AS IS" BASIS,
  * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
  * See the License for the specific language governing permissions and
  * limitations under the License.
  */

 #include <gtest/gtest.h>

 #include <stdio.h>
 #include <stdlib.h>
 #include <unistd.h>

 #include <android-base/file.h>
 #include <android-base/stringprintf.h>
 #include <android-base/test_utils.h>

 #include <map>
 #include <memory>
 #include <thread>

 #include "command.h"
 #include "environment.h"
 #include "event_selection_set.h"
 #include "get_test_data.h"
 #include "record.h"
 #include "record_file.h"
 #include "test_util.h"
 #include "thread_tree.h"

 using namespace PerfFileFormat;

 static std::unique_ptr<Command> RecordCmd() {
   return CreateCommandInstance("record");
 }

 static bool RunRecordCmd(std::vector<std::string> v,
                          const char* output_file = nullptr) {
   std::unique_ptr<TemporaryFile> tmpfile;
   std::string out_file;
   if (output_file != nullptr) {
     out_file = output_file;
   } else {
     tmpfile.reset(new TemporaryFile);
     out_file = tmpfile->path;
   }
   v.insert(v.end(), {"-o", out_file, "sleep", SLEEP_SEC});
   return RecordCmd()->Run(v);
 }

 TEST(record_cmd, no_options) { ASSERT_TRUE(RunRecordCmd({})); }

 TEST(record_cmd, system_wide_option) {
   TEST_IN_ROOT(ASSERT_TRUE(RunRecordCmd({"-a"})));
 }

 void CheckEventType(const std::string& record_file, const std::string event_type,
                     uint64_t sample_period, uint64_t sample_freq) {
   const EventType* type = FindEventTypeByName(event_type);
   ASSERT_TRUE(type != nullptr);
   std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(record_file);
   ASSERT_TRUE(reader);
   std::vector<EventAttrWithId> attrs = reader->AttrSection();
   for (auto& attr : attrs) {
     if (attr.attr->type == type->type && attr.attr->config == type->config) {
       if (attr.attr->freq == 0) {
         ASSERT_EQ(sample_period, attr.attr->sample_period);
         ASSERT_EQ(sample_freq, 0u);
       } else {
         ASSERT_EQ(sample_period, 0u);
         ASSERT_EQ(sample_freq, attr.attr->sample_freq);
       }
       return;
     }
   }
   FAIL();
 }

 TEST(record_cmd, sample_period_option) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({"-c", "100000"}, tmpfile.path));
   CheckEventType(tmpfile.path, "cpu-cycles", 100000u, 0);
 }

 TEST(record_cmd, event_option) {
   ASSERT_TRUE(RunRecordCmd({"-e", "cpu-clock"}));
 }

 TEST(record_cmd, freq_option) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({"-f", "99"}, tmpfile.path));
   CheckEventType(tmpfile.path, "cpu-cycles", 0, 99u);
   ASSERT_TRUE(RunRecordCmd({"-e", "cpu-clock", "-f", "99"}, tmpfile.path));
   CheckEventType(tmpfile.path, "cpu-clock", 0, 99u);
   ASSERT_TRUE(RunRecordCmd({"-f", std::to_string(UINT_MAX)}));
 }

 TEST(record_cmd, multiple_freq_or_sample_period_option) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({"-f", "99", "-e", "cpu-cycles", "-c", "1000000", "-e",
                             "cpu-clock"}, tmpfile.path));
   CheckEventType(tmpfile.path, "cpu-cycles", 0, 99u);
   CheckEventType(tmpfile.path, "cpu-clock", 1000000u, 0u);
 }

 TEST(record_cmd, output_file_option) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "sleep", SLEEP_SEC}));
 }

 TEST(record_cmd, dump_kernel_mmap) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
   std::unique_ptr<RecordFileReader> reader =
       RecordFileReader::CreateInstance(tmpfile.path);
   ASSERT_TRUE(reader != nullptr);
   std::vector<std::unique_ptr<Record>> records = reader->DataSection();
   ASSERT_GT(records.size(), 0U);
   bool have_kernel_mmap = false;
   for (auto& record : records) {
     if (record->type() == PERF_RECORD_MMAP) {
       const MmapRecord* mmap_record =
           static_cast<const MmapRecord*>(record.get());
       if (strcmp(mmap_record->filename, DEFAULT_KERNEL_MMAP_NAME) == 0 ||
           strcmp(mmap_record->filename, DEFAULT_KERNEL_MMAP_NAME_PERF) == 0) {
         have_kernel_mmap = true;
         break;
       }
     }
   }
   ASSERT_TRUE(have_kernel_mmap);
 }

 TEST(record_cmd, dump_build_id_feature) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
   std::unique_ptr<RecordFileReader> reader =
       RecordFileReader::CreateInstance(tmpfile.path);
   ASSERT_TRUE(reader != nullptr);
   const FileHeader& file_header = reader->FileHeader();
   ASSERT_TRUE(file_header.features[FEAT_BUILD_ID / 8] &
               (1 << (FEAT_BUILD_ID % 8)));
   ASSERT_GT(reader->FeatureSectionDescriptors().size(), 0u);
 }

 TEST(record_cmd, tracepoint_event) {
   TEST_IN_ROOT(ASSERT_TRUE(RunRecordCmd({"-a", "-e", "sched:sched_switch"})));
 }

 TEST(record_cmd, branch_sampling) {
   if (IsBranchSamplingSupported()) {
     ASSERT_TRUE(RunRecordCmd({"-b"}));
     ASSERT_TRUE(RunRecordCmd({"-j", "any,any_call,any_ret,ind_call"}));
     ASSERT_TRUE(RunRecordCmd({"-j", "any,k"}));
     ASSERT_TRUE(RunRecordCmd({"-j", "any,u"}));
     ASSERT_FALSE(RunRecordCmd({"-j", "u"}));
   } else {
     GTEST_LOG_(INFO) << "This test does nothing as branch stack sampling is "
                         "not supported on this device.";
   }
 }

 TEST(record_cmd, event_modifier) {
   ASSERT_TRUE(RunRecordCmd({"-e", "cpu-cycles:u"}));
 }

 TEST(record_cmd, fp_callchain_sampling) {
   ASSERT_TRUE(RunRecordCmd({"--call-graph", "fp"}));
 }

 TEST(record_cmd, fp_callchain_sampling_warning_on_arm) {
   if (GetBuildArch() != ARCH_ARM) {
     GTEST_LOG_(INFO) << "This test does nothing as it only tests on arm arch.";
     return;
   }
   ASSERT_EXIT(
       {
         exit(RunRecordCmd({"--call-graph", "fp"}) ? 0 : 1);
       },
       testing::ExitedWithCode(0), "doesn't work well on arm");
 }

 TEST(record_cmd, system_wide_fp_callchain_sampling) {
   TEST_IN_ROOT(ASSERT_TRUE(RunRecordCmd({"-a", "--call-graph", "fp"})));
 }

 bool IsInNativeAbi() {
   static int in_native_abi = -1;
   if (in_native_abi == -1) {
     FILE* fp = popen("uname -m", "re");
     char buf[40];
     memset(buf, '\0', sizeof(buf));
     fgets(buf, sizeof(buf), fp);
     pclose(fp);
     std::string s = buf;
     in_native_abi = 1;
     if (GetBuildArch() == ARCH_X86_32 || GetBuildArch() == ARCH_X86_64) {
       if (s.find("86") == std::string::npos) {
         in_native_abi = 0;
       }
     } else if (GetBuildArch() == ARCH_ARM || GetBuildArch() == ARCH_ARM64) {
       if (s.find("arm") == std::string::npos && s.find("aarch64") == std::string::npos) {
         in_native_abi = 0;
       }
     }
   }
   return in_native_abi == 1;
 }

 TEST(record_cmd, dwarf_callchain_sampling) {
   OMIT_TEST_ON_NON_NATIVE_ABIS();
   ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(1, &workloads);
   std::string pid = std::to_string(workloads[0]->GetPid());
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf"}));
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf,16384"}));
   ASSERT_FALSE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf,65536"}));
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "-g"}));
 }

 TEST(record_cmd, system_wide_dwarf_callchain_sampling) {
   OMIT_TEST_ON_NON_NATIVE_ABIS();
   ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
   TEST_IN_ROOT(RunRecordCmd({"-a", "--call-graph", "dwarf"}));
 }

 TEST(record_cmd, no_unwind_option) {
   OMIT_TEST_ON_NON_NATIVE_ABIS();
   ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
   ASSERT_TRUE(RunRecordCmd({"--call-graph", "dwarf", "--no-unwind"}));
   ASSERT_FALSE(RunRecordCmd({"--no-unwind"}));
 }

 TEST(record_cmd, post_unwind_option) {
   OMIT_TEST_ON_NON_NATIVE_ABIS();
   ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(1, &workloads);
   std::string pid = std::to_string(workloads[0]->GetPid());
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf", "--post-unwind"}));
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf", "--post-unwind=yes"}));
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf", "--post-unwind=no"}));
 }

 TEST(record_cmd, existing_processes) {
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(2, &workloads);
   std::string pid_list = android::base::StringPrintf(
       "%d,%d", workloads[0]->GetPid(), workloads[1]->GetPid());
   ASSERT_TRUE(RunRecordCmd({"-p", pid_list}));
 }

 TEST(record_cmd, existing_threads) {
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(2, &workloads);
   // Process id can also be used as thread id in linux.
   std::string tid_list = android::base::StringPrintf(
       "%d,%d", workloads[0]->GetPid(), workloads[1]->GetPid());
   ASSERT_TRUE(RunRecordCmd({"-t", tid_list}));
 }

 TEST(record_cmd, no_monitored_threads) {
   TemporaryFile tmpfile;
   ASSERT_FALSE(RecordCmd()->Run({"-o", tmpfile.path}));
 }

 TEST(record_cmd, more_than_one_event_types) {
   ASSERT_TRUE(RunRecordCmd({"-e", "cpu-cycles,cpu-clock"}));
   ASSERT_TRUE(RunRecordCmd({"-e", "cpu-cycles", "-e", "cpu-clock"}));
 }

 TEST(record_cmd, mmap_page_option) {
   ASSERT_TRUE(RunRecordCmd({"-m", "1"}));
   ASSERT_FALSE(RunRecordCmd({"-m", "0"}));
   ASSERT_FALSE(RunRecordCmd({"-m", "7"}));
 }

 static void CheckKernelSymbol(const std::string& path, bool need_kallsyms,
                               bool* success) {
   *success = false;
   std::unique_ptr<RecordFileReader> reader =
       RecordFileReader::CreateInstance(path);
   ASSERT_TRUE(reader != nullptr);
   std::vector<std::unique_ptr<Record>> records = reader->DataSection();
   bool has_kernel_symbol_records = false;
   for (const auto& record : records) {
     if (record->type() == SIMPLE_PERF_RECORD_KERNEL_SYMBOL) {
       has_kernel_symbol_records = true;
     }
   }
   bool require_kallsyms = need_kallsyms && CheckKernelSymbolAddresses();
   ASSERT_EQ(require_kallsyms, has_kernel_symbol_records);
   *success = true;
 }

 TEST(record_cmd, kernel_symbol) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({"--no-dump-symbols"}, tmpfile.path));
   bool success;
   CheckKernelSymbol(tmpfile.path, true, &success);
   ASSERT_TRUE(success);
   ASSERT_TRUE(RunRecordCmd({"--no-dump-symbols", "--no-dump-kernel-symbols"}, tmpfile.path));
   CheckKernelSymbol(tmpfile.path, false, &success);
   ASSERT_TRUE(success);
 }

 // Check if the dso/symbol records in perf.data matches our expectation.
 static void CheckDsoSymbolRecords(const std::string& path,
                                   bool can_have_dso_symbol_records,
                                   bool* success) {
   *success = false;
   std::unique_ptr<RecordFileReader> reader =
       RecordFileReader::CreateInstance(path);
   ASSERT_TRUE(reader != nullptr);
   std::vector<std::unique_ptr<Record>> records = reader->DataSection();
   bool has_dso_record = false;
   bool has_symbol_record = false;
   std::map<uint64_t, bool> dso_hit_map;
   for (const auto& record : records) {
     if (record->type() == SIMPLE_PERF_RECORD_DSO) {
       has_dso_record = true;
       uint64_t dso_id = static_cast<const DsoRecord*>(record.get())->dso_id;
       ASSERT_EQ(dso_hit_map.end(), dso_hit_map.find(dso_id));
       dso_hit_map.insert(std::make_pair(dso_id, false));
     } else if (record->type() == SIMPLE_PERF_RECORD_SYMBOL) {
       has_symbol_record = true;
       uint64_t dso_id = static_cast<const SymbolRecord*>(record.get())->dso_id;
       auto it = dso_hit_map.find(dso_id);
       ASSERT_NE(dso_hit_map.end(), it);
       it->second = true;
     }
   }
   if (can_have_dso_symbol_records) {
     // It is possible that there are no samples hitting functions having symbol.
     // In that case, there are no dso/symbol records.
     ASSERT_EQ(has_dso_record, has_symbol_record);
     for (auto& pair : dso_hit_map) {
       ASSERT_TRUE(pair.second);
     }
   } else {
     ASSERT_FALSE(has_dso_record);
     ASSERT_FALSE(has_symbol_record);
   }
   *success = true;
 }

 TEST(record_cmd, no_dump_symbols) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
   bool success;
   CheckDsoSymbolRecords(tmpfile.path, true, &success);
   ASSERT_TRUE(success);
   ASSERT_TRUE(RunRecordCmd({"--no-dump-symbols"}, tmpfile.path));
   CheckDsoSymbolRecords(tmpfile.path, false, &success);
   ASSERT_TRUE(success);
   OMIT_TEST_ON_NON_NATIVE_ABIS();
   ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(1, &workloads);
   std::string pid = std::to_string(workloads[0]->GetPid());
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "-g"}, tmpfile.path));
   CheckDsoSymbolRecords(tmpfile.path, true, &success);
   ASSERT_TRUE(success);
   ASSERT_TRUE(RunRecordCmd({"-p", pid, "-g", "--no-dump-symbols"}, tmpfile.path));
   CheckDsoSymbolRecords(tmpfile.path, false, &success);
   ASSERT_TRUE(success);
 }

 TEST(record_cmd, dump_kernel_symbols) {
   if (!IsRoot()) {
     GTEST_LOG_(INFO) << "Test requires root privilege";
     return;
   }
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({"-a", "-o", tmpfile.path, "sleep", "1"}));
   std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
   ASSERT_TRUE(reader != nullptr);
   std::map<int, SectionDesc> section_map = reader->FeatureSectionDescriptors();
   ASSERT_NE(section_map.find(FEAT_FILE), section_map.end());
   std::string file_path;
   uint32_t file_type;
   uint64_t min_vaddr;
   std::vector<Symbol> symbols;
   std::vector<uint64_t> dex_file_offsets;
   size_t read_pos = 0;
   bool has_kernel_symbols = false;
   while (reader->ReadFileFeature(read_pos, &file_path, &file_type, &min_vaddr, &symbols,
                                  &dex_file_offsets)) {
     if (file_type == DSO_KERNEL && !symbols.empty()) {
       has_kernel_symbols = true;
     }
   }
   ASSERT_TRUE(has_kernel_symbols);
 }

 TEST(record_cmd, group_option) {
   ASSERT_TRUE(RunRecordCmd({"--group", "cpu-cycles,cpu-clock", "-m", "16"}));
   ASSERT_TRUE(RunRecordCmd({"--group", "cpu-cycles,cpu-clock", "--group",
                             "cpu-cycles:u,cpu-clock:u", "--group",
                             "cpu-cycles:k,cpu-clock:k", "-m", "16"}));
 }

 TEST(record_cmd, symfs_option) { ASSERT_TRUE(RunRecordCmd({"--symfs", "/"})); }

 TEST(record_cmd, duration_option) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RecordCmd()->Run({"--duration", "1.2", "-p",
                                 std::to_string(getpid()), "-o", tmpfile.path, "--in-app"}));
   ASSERT_TRUE(
       RecordCmd()->Run({"--duration", "1", "-o", tmpfile.path, "sleep", "2"}));
 }

 TEST(record_cmd, support_modifier_for_clock_events) {
   for (const std::string& e : {"cpu-clock", "task-clock"}) {
     for (const std::string& m : {"u", "k"}) {
       ASSERT_TRUE(RunRecordCmd({"-e", e + ":" + m})) << "event " << e << ":"
                                                      << m;
     }
   }
 }

 TEST(record_cmd, handle_SIGHUP) {
   TemporaryFile tmpfile;
   std::thread thread([]() {
     sleep(1);
     kill(getpid(), SIGHUP);
   });
   thread.detach();
   ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "sleep", "1000000"}));
 }

 TEST(record_cmd, stop_when_no_more_targets) {
   TemporaryFile tmpfile;
   std::atomic<int> tid(0);
   std::thread thread([&]() {
     tid = gettid();
     sleep(1);
   });
   thread.detach();
   while (tid == 0);
   ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "-t", std::to_string(tid), "--in-app"}));
 }

 TEST(record_cmd, donot_stop_when_having_targets) {
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(1, &workloads);
   std::string pid = std::to_string(workloads[0]->GetPid());
   uint64_t start_time_in_ns = GetSystemClock();
   TemporaryFile tmpfile;
   ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "-p", pid, "--duration", "3"}));
   uint64_t end_time_in_ns = GetSystemClock();
   ASSERT_GT(end_time_in_ns - start_time_in_ns, static_cast<uint64_t>(2e9));
 }

 TEST(record_cmd, start_profiling_fd_option) {
   int pipefd[2];
   ASSERT_EQ(0, pipe(pipefd));
   int read_fd = pipefd[0];
   int write_fd = pipefd[1];
   ASSERT_EXIT(
       {
         close(read_fd);
         exit(RunRecordCmd({"--start_profiling_fd", std::to_string(write_fd)}) ? 0 : 1);
       },
       testing::ExitedWithCode(0), "");
   close(write_fd);
   std::string s;
   ASSERT_TRUE(android::base::ReadFdToString(read_fd, &s));
   close(read_fd);
   ASSERT_EQ("STARTED", s);
 }

 TEST(record_cmd, record_meta_info_feature) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
   std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
   ASSERT_TRUE(reader);
   std::unordered_map<std::string, std::string> info_map;
   ASSERT_TRUE(reader->ReadMetaInfoFeature(&info_map));
   ASSERT_NE(info_map.find("simpleperf_version"), info_map.end());
   ASSERT_NE(info_map.find("timestamp"), info_map.end());
 #if defined(__ANDROID__)
   ASSERT_NE(info_map.find("product_props"), info_map.end());
   ASSERT_NE(info_map.find("android_version"), info_map.end());
 #endif
 }

 // See http://b/63135835.
 TEST(record_cmd, cpu_clock_for_a_long_time) {
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(1, &workloads);
   std::string pid = std::to_string(workloads[0]->GetPid());
   TemporaryFile tmpfile;
   ASSERT_TRUE(RecordCmd()->Run(
       {"-e", "cpu-clock", "-o", tmpfile.path, "-p", pid, "--duration", "3"}));
 }

 TEST(record_cmd, dump_regs_for_tracepoint_events) {
   TEST_REQUIRE_HOST_ROOT();
   OMIT_TEST_ON_NON_NATIVE_ABIS();
   // Check if the kernel can dump registers for tracepoint events.
   // If not, probably a kernel patch below is missing:
   // "5b09a094f2 arm64: perf: Fix callchain parse error with kernel tracepoint events"
   ASSERT_TRUE(IsDumpingRegsForTracepointEventsSupported());
 }

 TEST(record_cmd, trace_offcpu_option) {
   // On linux host, we need root privilege to read tracepoint events.
   TEST_REQUIRE_HOST_ROOT();
   OMIT_TEST_ON_NON_NATIVE_ABIS();
   TemporaryFile tmpfile;
   ASSERT_TRUE(RunRecordCmd({"--trace-offcpu", "-f", "1000"}, tmpfile.path));
   std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
   ASSERT_TRUE(reader);
   std::unordered_map<std::string, std::string> info_map;
   ASSERT_TRUE(reader->ReadMetaInfoFeature(&info_map));
   ASSERT_EQ(info_map["trace_offcpu"], "true");
   CheckEventType(tmpfile.path, "sched:sched_switch", 1u, 0u);
 }

 TEST(record_cmd, exit_with_parent_option) {
   ASSERT_TRUE(RunRecordCmd({"--exit-with-parent"}));
 }

 TEST(record_cmd, clockid_option) {
   if (!IsSettingClockIdSupported()) {
     ASSERT_FALSE(RunRecordCmd({"--clockid", "monotonic"}));
   } else {
     TemporaryFile tmpfile;
     ASSERT_TRUE(RunRecordCmd({"--clockid", "monotonic"}, tmpfile.path));
     std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
     ASSERT_TRUE(reader);
     std::unordered_map<std::string, std::string> info_map;
     ASSERT_TRUE(reader->ReadMetaInfoFeature(&info_map));
     ASSERT_EQ(info_map["clockid"], "monotonic");
   }
 }

 TEST(record_cmd, generate_samples_by_hw_counters) {
   std::vector<std::string> events = {"cpu-cycles", "instructions"};
   for (auto& event : events) {
     TemporaryFile tmpfile;
     ASSERT_TRUE(RecordCmd()->Run({"-e", event, "-o", tmpfile.path, "sleep", "1"}));
     std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
     ASSERT_TRUE(reader);
     bool has_sample = false;
     ASSERT_TRUE(reader->ReadDataSection([&](std::unique_ptr<Record> r) {
       if (r->type() == PERF_RECORD_SAMPLE) {
         has_sample = true;
       }
       return true;
     }));
     ASSERT_TRUE(has_sample);
   }
 }

 TEST(record_cmd, callchain_joiner_options) {
   ASSERT_TRUE(RunRecordCmd({"--no-callchain-joiner"}));
   ASSERT_TRUE(RunRecordCmd({"--callchain-joiner-min-matching-nodes", "2"}));
 }

 TEST(record_cmd, dashdash) {
   TemporaryFile tmpfile;
   ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "--", "sleep", "1"}));
 }

 TEST(record_cmd, size_limit_option) {
   std::vector<std::unique_ptr<Workload>> workloads;
   CreateProcesses(1, &workloads);
   std::string pid = std::to_string(workloads[0]->GetPid());
   TemporaryFile tmpfile;
   ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "-p", pid, "--size-limit", "1k", "--duration",
                                 "1"}));
   std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
   ASSERT_TRUE(reader);
   ASSERT_GT(reader->FileHeader().data.size, 1000u);
   ASSERT_LT(reader->FileHeader().data.size, 2000u);
   ASSERT_FALSE(RunRecordCmd({"--size-limit", "0"}));
 }
	/*
	* Copyright (C) 2015 The Android Open Source Project
	*
	* Licensed under the Apache License, Version 2.0 (the "License");
	* you may not use this file except in compliance with the License.
	* You may obtain a copy of the License at
	*
	* http://www.apache.org/licenses/LICENSE-2.0
	*
	* Unless required by applicable law or agreed to in writing, software
	* distributed under the License is distributed on an "AS IS" BASIS,
	* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
	* See the License for the specific language governing permissions and
	* limitations under the License.
	*/

	#include <gtest/gtest.h>

	#include <stdio.h>
	#include <stdlib.h>
	#include <unistd.h>

	#include <android-base/file.h>
	#include <android-base/stringprintf.h>
	#include <android-base/test_utils.h>

	#include <map>
	#include <memory>
	#include <thread>

	#include "command.h"
	#include "environment.h"
	#include "event_selection_set.h"
	#include "get_test_data.h"
	#include "record.h"
	#include "record_file.h"
	#include "test_util.h"
	#include "thread_tree.h"

	using namespace PerfFileFormat;

	static std::unique_ptr<Command> RecordCmd() {
	return CreateCommandInstance("record");
	}

	static bool RunRecordCmd(std::vector<std::string> v,
	const char* output_file = nullptr) {
	std::unique_ptr<TemporaryFile> tmpfile;
	std::string out_file;
	if (output_file != nullptr) {
	out_file = output_file;
	} else {
	tmpfile.reset(new TemporaryFile);
	out_file = tmpfile->path;
	}
	v.insert(v.end(), {"-o", out_file, "sleep", SLEEP_SEC});
	return RecordCmd()->Run(v);
	}

	TEST(record_cmd, no_options) { ASSERT_TRUE(RunRecordCmd({})); }

	TEST(record_cmd, system_wide_option) {
	TEST_IN_ROOT(ASSERT_TRUE(RunRecordCmd({"-a"})));
	}

	void CheckEventType(const std::string& record_file, const std::string event_type,
	uint64_t sample_period, uint64_t sample_freq) {
	const EventType* type = FindEventTypeByName(event_type);
	ASSERT_TRUE(type != nullptr);
	std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(record_file);
	ASSERT_TRUE(reader);
	std::vector<EventAttrWithId> attrs = reader->AttrSection();
	for (auto& attr : attrs) {
	if (attr.attr->type == type->type && attr.attr->config == type->config) {
	if (attr.attr->freq == 0) {
	ASSERT_EQ(sample_period, attr.attr->sample_period);
	ASSERT_EQ(sample_freq, 0u);
	} else {
	ASSERT_EQ(sample_period, 0u);
	ASSERT_EQ(sample_freq, attr.attr->sample_freq);
	}
	return;
	}
	}
	FAIL();
	}

	TEST(record_cmd, sample_period_option) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({"-c", "100000"}, tmpfile.path));
	CheckEventType(tmpfile.path, "cpu-cycles", 100000u, 0);
	}

	TEST(record_cmd, event_option) {
	ASSERT_TRUE(RunRecordCmd({"-e", "cpu-clock"}));
	}

	TEST(record_cmd, freq_option) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({"-f", "99"}, tmpfile.path));
	CheckEventType(tmpfile.path, "cpu-cycles", 0, 99u);
	ASSERT_TRUE(RunRecordCmd({"-e", "cpu-clock", "-f", "99"}, tmpfile.path));
	CheckEventType(tmpfile.path, "cpu-clock", 0, 99u);
	ASSERT_TRUE(RunRecordCmd({"-f", std::to_string(UINT_MAX)}));
	}

	TEST(record_cmd, multiple_freq_or_sample_period_option) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({"-f", "99", "-e", "cpu-cycles", "-c", "1000000", "-e",
	"cpu-clock"}, tmpfile.path));
	CheckEventType(tmpfile.path, "cpu-cycles", 0, 99u);
	CheckEventType(tmpfile.path, "cpu-clock", 1000000u, 0u);
	}

	TEST(record_cmd, output_file_option) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "sleep", SLEEP_SEC}));
	}

	TEST(record_cmd, dump_kernel_mmap) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
	std::unique_ptr<RecordFileReader> reader =
	RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader != nullptr);
	std::vector<std::unique_ptr<Record>> records = reader->DataSection();
	ASSERT_GT(records.size(), 0U);
	bool have_kernel_mmap = false;
	for (auto& record : records) {
	if (record->type() == PERF_RECORD_MMAP) {
	const MmapRecord* mmap_record =
	static_cast<const MmapRecord*>(record.get());
	if (strcmp(mmap_record->filename, DEFAULT_KERNEL_MMAP_NAME) == 0 \|\|
	strcmp(mmap_record->filename, DEFAULT_KERNEL_MMAP_NAME_PERF) == 0) {
	have_kernel_mmap = true;
	break;
	}
	}
	}
	ASSERT_TRUE(have_kernel_mmap);
	}

	TEST(record_cmd, dump_build_id_feature) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
	std::unique_ptr<RecordFileReader> reader =
	RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader != nullptr);
	const FileHeader& file_header = reader->FileHeader();
	ASSERT_TRUE(file_header.features[FEAT_BUILD_ID / 8] &
	(1 << (FEAT_BUILD_ID % 8)));
	ASSERT_GT(reader->FeatureSectionDescriptors().size(), 0u);
	}

	TEST(record_cmd, tracepoint_event) {
	TEST_IN_ROOT(ASSERT_TRUE(RunRecordCmd({"-a", "-e", "sched:sched_switch"})));
	}

	TEST(record_cmd, branch_sampling) {
	if (IsBranchSamplingSupported()) {
	ASSERT_TRUE(RunRecordCmd({"-b"}));
	ASSERT_TRUE(RunRecordCmd({"-j", "any,any_call,any_ret,ind_call"}));
	ASSERT_TRUE(RunRecordCmd({"-j", "any,k"}));
	ASSERT_TRUE(RunRecordCmd({"-j", "any,u"}));
	ASSERT_FALSE(RunRecordCmd({"-j", "u"}));
	} else {
	GTEST_LOG_(INFO) << "This test does nothing as branch stack sampling is "
	"not supported on this device.";
	}
	}

	TEST(record_cmd, event_modifier) {
	ASSERT_TRUE(RunRecordCmd({"-e", "cpu-cycles:u"}));
	}

	TEST(record_cmd, fp_callchain_sampling) {
	ASSERT_TRUE(RunRecordCmd({"--call-graph", "fp"}));
	}

	TEST(record_cmd, fp_callchain_sampling_warning_on_arm) {
	if (GetBuildArch() != ARCH_ARM) {
	GTEST_LOG_(INFO) << "This test does nothing as it only tests on arm arch.";
	return;
	}
	ASSERT_EXIT(
	{
	exit(RunRecordCmd({"--call-graph", "fp"}) ? 0 : 1);
	},
	testing::ExitedWithCode(0), "doesn't work well on arm");
	}

	TEST(record_cmd, system_wide_fp_callchain_sampling) {
	TEST_IN_ROOT(ASSERT_TRUE(RunRecordCmd({"-a", "--call-graph", "fp"})));
	}

	bool IsInNativeAbi() {
	static int in_native_abi = -1;
	if (in_native_abi == -1) {
	FILE* fp = popen("uname -m", "re");
	char buf[40];
	memset(buf, '\0', sizeof(buf));
	fgets(buf, sizeof(buf), fp);
	pclose(fp);
	std::string s = buf;
	in_native_abi = 1;
	if (GetBuildArch() == ARCH_X86_32 \|\| GetBuildArch() == ARCH_X86_64) {
	if (s.find("86") == std::string::npos) {
	in_native_abi = 0;
	}
	} else if (GetBuildArch() == ARCH_ARM \|\| GetBuildArch() == ARCH_ARM64) {
	if (s.find("arm") == std::string::npos && s.find("aarch64") == std::string::npos) {
	in_native_abi = 0;
	}
	}
	}
	return in_native_abi == 1;
	}

	TEST(record_cmd, dwarf_callchain_sampling) {
	OMIT_TEST_ON_NON_NATIVE_ABIS();
	ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(1, &workloads);
	std::string pid = std::to_string(workloads[0]->GetPid());
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf"}));
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf,16384"}));
	ASSERT_FALSE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf,65536"}));
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "-g"}));
	}

	TEST(record_cmd, system_wide_dwarf_callchain_sampling) {
	OMIT_TEST_ON_NON_NATIVE_ABIS();
	ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
	TEST_IN_ROOT(RunRecordCmd({"-a", "--call-graph", "dwarf"}));
	}

	TEST(record_cmd, no_unwind_option) {
	OMIT_TEST_ON_NON_NATIVE_ABIS();
	ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
	ASSERT_TRUE(RunRecordCmd({"--call-graph", "dwarf", "--no-unwind"}));
	ASSERT_FALSE(RunRecordCmd({"--no-unwind"}));
	}

	TEST(record_cmd, post_unwind_option) {
	OMIT_TEST_ON_NON_NATIVE_ABIS();
	ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(1, &workloads);
	std::string pid = std::to_string(workloads[0]->GetPid());
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf", "--post-unwind"}));
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf", "--post-unwind=yes"}));
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "--call-graph", "dwarf", "--post-unwind=no"}));
	}

	TEST(record_cmd, existing_processes) {
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(2, &workloads);
	std::string pid_list = android::base::StringPrintf(
	"%d,%d", workloads[0]->GetPid(), workloads[1]->GetPid());
	ASSERT_TRUE(RunRecordCmd({"-p", pid_list}));
	}

	TEST(record_cmd, existing_threads) {
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(2, &workloads);
	// Process id can also be used as thread id in linux.
	std::string tid_list = android::base::StringPrintf(
	"%d,%d", workloads[0]->GetPid(), workloads[1]->GetPid());
	ASSERT_TRUE(RunRecordCmd({"-t", tid_list}));
	}

	TEST(record_cmd, no_monitored_threads) {
	TemporaryFile tmpfile;
	ASSERT_FALSE(RecordCmd()->Run({"-o", tmpfile.path}));
	}

	TEST(record_cmd, more_than_one_event_types) {
	ASSERT_TRUE(RunRecordCmd({"-e", "cpu-cycles,cpu-clock"}));
	ASSERT_TRUE(RunRecordCmd({"-e", "cpu-cycles", "-e", "cpu-clock"}));
	}

	TEST(record_cmd, mmap_page_option) {
	ASSERT_TRUE(RunRecordCmd({"-m", "1"}));
	ASSERT_FALSE(RunRecordCmd({"-m", "0"}));
	ASSERT_FALSE(RunRecordCmd({"-m", "7"}));
	}

	static void CheckKernelSymbol(const std::string& path, bool need_kallsyms,
	bool* success) {
	*success = false;
	std::unique_ptr<RecordFileReader> reader =
	RecordFileReader::CreateInstance(path);
	ASSERT_TRUE(reader != nullptr);
	std::vector<std::unique_ptr<Record>> records = reader->DataSection();
	bool has_kernel_symbol_records = false;
	for (const auto& record : records) {
	if (record->type() == SIMPLE_PERF_RECORD_KERNEL_SYMBOL) {
	has_kernel_symbol_records = true;
	}
	}
	bool require_kallsyms = need_kallsyms && CheckKernelSymbolAddresses();
	ASSERT_EQ(require_kallsyms, has_kernel_symbol_records);
	*success = true;
	}

	TEST(record_cmd, kernel_symbol) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({"--no-dump-symbols"}, tmpfile.path));
	bool success;
	CheckKernelSymbol(tmpfile.path, true, &success);
	ASSERT_TRUE(success);
	ASSERT_TRUE(RunRecordCmd({"--no-dump-symbols", "--no-dump-kernel-symbols"}, tmpfile.path));
	CheckKernelSymbol(tmpfile.path, false, &success);
	ASSERT_TRUE(success);
	}

	// Check if the dso/symbol records in perf.data matches our expectation.
	static void CheckDsoSymbolRecords(const std::string& path,
	bool can_have_dso_symbol_records,
	bool* success) {
	*success = false;
	std::unique_ptr<RecordFileReader> reader =
	RecordFileReader::CreateInstance(path);
	ASSERT_TRUE(reader != nullptr);
	std::vector<std::unique_ptr<Record>> records = reader->DataSection();
	bool has_dso_record = false;
	bool has_symbol_record = false;
	std::map<uint64_t, bool> dso_hit_map;
	for (const auto& record : records) {
	if (record->type() == SIMPLE_PERF_RECORD_DSO) {
	has_dso_record = true;
	uint64_t dso_id = static_cast<const DsoRecord*>(record.get())->dso_id;
	ASSERT_EQ(dso_hit_map.end(), dso_hit_map.find(dso_id));
	dso_hit_map.insert(std::make_pair(dso_id, false));
	} else if (record->type() == SIMPLE_PERF_RECORD_SYMBOL) {
	has_symbol_record = true;
	uint64_t dso_id = static_cast<const SymbolRecord*>(record.get())->dso_id;
	auto it = dso_hit_map.find(dso_id);
	ASSERT_NE(dso_hit_map.end(), it);
	it->second = true;
	}
	}
	if (can_have_dso_symbol_records) {
	// It is possible that there are no samples hitting functions having symbol.
	// In that case, there are no dso/symbol records.
	ASSERT_EQ(has_dso_record, has_symbol_record);
	for (auto& pair : dso_hit_map) {
	ASSERT_TRUE(pair.second);
	}
	} else {
	ASSERT_FALSE(has_dso_record);
	ASSERT_FALSE(has_symbol_record);
	}
	*success = true;
	}

	TEST(record_cmd, no_dump_symbols) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
	bool success;
	CheckDsoSymbolRecords(tmpfile.path, true, &success);
	ASSERT_TRUE(success);
	ASSERT_TRUE(RunRecordCmd({"--no-dump-symbols"}, tmpfile.path));
	CheckDsoSymbolRecords(tmpfile.path, false, &success);
	ASSERT_TRUE(success);
	OMIT_TEST_ON_NON_NATIVE_ABIS();
	ASSERT_TRUE(IsDwarfCallChainSamplingSupported());
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(1, &workloads);
	std::string pid = std::to_string(workloads[0]->GetPid());
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "-g"}, tmpfile.path));
	CheckDsoSymbolRecords(tmpfile.path, true, &success);
	ASSERT_TRUE(success);
	ASSERT_TRUE(RunRecordCmd({"-p", pid, "-g", "--no-dump-symbols"}, tmpfile.path));
	CheckDsoSymbolRecords(tmpfile.path, false, &success);
	ASSERT_TRUE(success);
	}

	TEST(record_cmd, dump_kernel_symbols) {
	if (!IsRoot()) {
	GTEST_LOG_(INFO) << "Test requires root privilege";
	return;
	}
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({"-a", "-o", tmpfile.path, "sleep", "1"}));
	std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader != nullptr);
	std::map<int, SectionDesc> section_map = reader->FeatureSectionDescriptors();
	ASSERT_NE(section_map.find(FEAT_FILE), section_map.end());
	std::string file_path;
	uint32_t file_type;
	uint64_t min_vaddr;
	std::vector<Symbol> symbols;
	std::vector<uint64_t> dex_file_offsets;
	size_t read_pos = 0;
	bool has_kernel_symbols = false;
	while (reader->ReadFileFeature(read_pos, &file_path, &file_type, &min_vaddr, &symbols,
	&dex_file_offsets)) {
	if (file_type == DSO_KERNEL && !symbols.empty()) {
	has_kernel_symbols = true;
	}
	}
	ASSERT_TRUE(has_kernel_symbols);
	}

	TEST(record_cmd, group_option) {
	ASSERT_TRUE(RunRecordCmd({"--group", "cpu-cycles,cpu-clock", "-m", "16"}));
	ASSERT_TRUE(RunRecordCmd({"--group", "cpu-cycles,cpu-clock", "--group",
	"cpu-cycles:u,cpu-clock:u", "--group",
	"cpu-cycles:k,cpu-clock:k", "-m", "16"}));
	}

	TEST(record_cmd, symfs_option) { ASSERT_TRUE(RunRecordCmd({"--symfs", "/"})); }

	TEST(record_cmd, duration_option) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RecordCmd()->Run({"--duration", "1.2", "-p",
	std::to_string(getpid()), "-o", tmpfile.path, "--in-app"}));
	ASSERT_TRUE(
	RecordCmd()->Run({"--duration", "1", "-o", tmpfile.path, "sleep", "2"}));
	}

	TEST(record_cmd, support_modifier_for_clock_events) {
	for (const std::string& e : {"cpu-clock", "task-clock"}) {
	for (const std::string& m : {"u", "k"}) {
	ASSERT_TRUE(RunRecordCmd({"-e", e + ":" + m})) << "event " << e << ":"
	<< m;
	}
	}
	}

	TEST(record_cmd, handle_SIGHUP) {
	TemporaryFile tmpfile;
	std::thread thread([]() {
	sleep(1);
	kill(getpid(), SIGHUP);
	});
	thread.detach();
	ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "sleep", "1000000"}));
	}

	TEST(record_cmd, stop_when_no_more_targets) {
	TemporaryFile tmpfile;
	std::atomic<int> tid(0);
	std::thread thread([&]() {
	tid = gettid();
	sleep(1);
	});
	thread.detach();
	while (tid == 0);
	ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "-t", std::to_string(tid), "--in-app"}));
	}

	TEST(record_cmd, donot_stop_when_having_targets) {
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(1, &workloads);
	std::string pid = std::to_string(workloads[0]->GetPid());
	uint64_t start_time_in_ns = GetSystemClock();
	TemporaryFile tmpfile;
	ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "-p", pid, "--duration", "3"}));
	uint64_t end_time_in_ns = GetSystemClock();
	ASSERT_GT(end_time_in_ns - start_time_in_ns, static_cast<uint64_t>(2e9));
	}

	TEST(record_cmd, start_profiling_fd_option) {
	int pipefd[2];
	ASSERT_EQ(0, pipe(pipefd));
	int read_fd = pipefd[0];
	int write_fd = pipefd[1];
	ASSERT_EXIT(
	{
	close(read_fd);
	exit(RunRecordCmd({"--start_profiling_fd", std::to_string(write_fd)}) ? 0 : 1);
	},
	testing::ExitedWithCode(0), "");
	close(write_fd);
	std::string s;
	ASSERT_TRUE(android::base::ReadFdToString(read_fd, &s));
	close(read_fd);
	ASSERT_EQ("STARTED", s);
	}

	TEST(record_cmd, record_meta_info_feature) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({}, tmpfile.path));
	std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader);
	std::unordered_map<std::string, std::string> info_map;
	ASSERT_TRUE(reader->ReadMetaInfoFeature(&info_map));
	ASSERT_NE(info_map.find("simpleperf_version"), info_map.end());
	ASSERT_NE(info_map.find("timestamp"), info_map.end());
	#if defined(__ANDROID__)
	ASSERT_NE(info_map.find("product_props"), info_map.end());
	ASSERT_NE(info_map.find("android_version"), info_map.end());
	#endif
	}

	// See http://b/63135835.
	TEST(record_cmd, cpu_clock_for_a_long_time) {
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(1, &workloads);
	std::string pid = std::to_string(workloads[0]->GetPid());
	TemporaryFile tmpfile;
	ASSERT_TRUE(RecordCmd()->Run(
	{"-e", "cpu-clock", "-o", tmpfile.path, "-p", pid, "--duration", "3"}));
	}

	TEST(record_cmd, dump_regs_for_tracepoint_events) {
	TEST_REQUIRE_HOST_ROOT();
	OMIT_TEST_ON_NON_NATIVE_ABIS();
	// Check if the kernel can dump registers for tracepoint events.
	// If not, probably a kernel patch below is missing:
	// "5b09a094f2 arm64: perf: Fix callchain parse error with kernel tracepoint events"
	ASSERT_TRUE(IsDumpingRegsForTracepointEventsSupported());
	}

	TEST(record_cmd, trace_offcpu_option) {
	// On linux host, we need root privilege to read tracepoint events.
	TEST_REQUIRE_HOST_ROOT();
	OMIT_TEST_ON_NON_NATIVE_ABIS();
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({"--trace-offcpu", "-f", "1000"}, tmpfile.path));
	std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader);
	std::unordered_map<std::string, std::string> info_map;
	ASSERT_TRUE(reader->ReadMetaInfoFeature(&info_map));
	ASSERT_EQ(info_map["trace_offcpu"], "true");
	CheckEventType(tmpfile.path, "sched:sched_switch", 1u, 0u);
	}

	TEST(record_cmd, exit_with_parent_option) {
	ASSERT_TRUE(RunRecordCmd({"--exit-with-parent"}));
	}

	TEST(record_cmd, clockid_option) {
	if (!IsSettingClockIdSupported()) {
	ASSERT_FALSE(RunRecordCmd({"--clockid", "monotonic"}));
	} else {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RunRecordCmd({"--clockid", "monotonic"}, tmpfile.path));
	std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader);
	std::unordered_map<std::string, std::string> info_map;
	ASSERT_TRUE(reader->ReadMetaInfoFeature(&info_map));
	ASSERT_EQ(info_map["clockid"], "monotonic");
	}
	}

	TEST(record_cmd, generate_samples_by_hw_counters) {
	std::vector<std::string> events = {"cpu-cycles", "instructions"};
	for (auto& event : events) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RecordCmd()->Run({"-e", event, "-o", tmpfile.path, "sleep", "1"}));
	std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader);
	bool has_sample = false;
	ASSERT_TRUE(reader->ReadDataSection([&](std::unique_ptr<Record> r) {
	if (r->type() == PERF_RECORD_SAMPLE) {
	has_sample = true;
	}
	return true;
	}));
	ASSERT_TRUE(has_sample);
	}
	}

	TEST(record_cmd, callchain_joiner_options) {
	ASSERT_TRUE(RunRecordCmd({"--no-callchain-joiner"}));
	ASSERT_TRUE(RunRecordCmd({"--callchain-joiner-min-matching-nodes", "2"}));
	}

	TEST(record_cmd, dashdash) {
	TemporaryFile tmpfile;
	ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "--", "sleep", "1"}));
	}

	TEST(record_cmd, size_limit_option) {
	std::vector<std::unique_ptr<Workload>> workloads;
	CreateProcesses(1, &workloads);
	std::string pid = std::to_string(workloads[0]->GetPid());
	TemporaryFile tmpfile;
	ASSERT_TRUE(RecordCmd()->Run({"-o", tmpfile.path, "-p", pid, "--size-limit", "1k", "--duration",
	"1"}));
	std::unique_ptr<RecordFileReader> reader = RecordFileReader::CreateInstance(tmpfile.path);
	ASSERT_TRUE(reader);
	ASSERT_GT(reader->FileHeader().data.size, 1000u);
	ASSERT_LT(reader->FileHeader().data.size, 2000u);
	ASSERT_FALSE(RunRecordCmd({"--size-limit", "0"}));
	}