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https://github.com/google/benchmark.git
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308 lines
11 KiB
C++
308 lines
11 KiB
C++
#include <random>
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#include <thread>
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#include "../src/perf_counters.h"
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#include "gmock/gmock.h"
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#include "gtest/gtest.h"
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#ifndef GTEST_SKIP
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struct MsgHandler {
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void operator=(std::ostream&) {}
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};
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#define GTEST_SKIP() return MsgHandler() = std::cout
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#endif
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using benchmark::internal::PerfCounters;
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using benchmark::internal::PerfCountersMeasurement;
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using benchmark::internal::PerfCounterValues;
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using ::testing::AllOf;
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using ::testing::Gt;
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using ::testing::Lt;
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namespace {
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const char kGenericPerfEvent1[] = "CYCLES";
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const char kGenericPerfEvent2[] = "INSTRUCTIONS";
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TEST(PerfCountersTest, Init) {
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EXPECT_EQ(PerfCounters::Initialize(), PerfCounters::kSupported);
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}
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TEST(PerfCountersTest, OneCounter) {
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if (!PerfCounters::kSupported) {
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GTEST_SKIP() << "Performance counters not supported.\n";
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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EXPECT_EQ(PerfCounters::Create({kGenericPerfEvent1}).num_counters(), 1);
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}
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TEST(PerfCountersTest, NegativeTest) {
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if (!PerfCounters::kSupported) {
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EXPECT_FALSE(PerfCounters::Initialize());
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return;
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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// Safety checks
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// Create() will always create a valid object, even if passed no or
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// wrong arguments as the new behavior is to warn and drop unsupported
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// counters
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EXPECT_EQ(PerfCounters::Create({}).num_counters(), 0);
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EXPECT_EQ(PerfCounters::Create({""}).num_counters(), 0);
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EXPECT_EQ(PerfCounters::Create({"not a counter name"}).num_counters(), 0);
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{
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// Try sneaking in a bad egg to see if it is filtered out. The
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// number of counters has to be two, not zero
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auto counter =
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PerfCounters::Create({kGenericPerfEvent2, "", kGenericPerfEvent1});
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EXPECT_EQ(counter.num_counters(), 2);
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EXPECT_EQ(counter.names(), std::vector<std::string>(
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{kGenericPerfEvent2, kGenericPerfEvent1}));
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}
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{
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// Try sneaking in an outrageous counter, like a fat finger mistake
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auto counter = PerfCounters::Create(
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{kGenericPerfEvent2, "not a counter name", kGenericPerfEvent1});
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EXPECT_EQ(counter.num_counters(), 2);
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EXPECT_EQ(counter.names(), std::vector<std::string>(
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{kGenericPerfEvent2, kGenericPerfEvent1}));
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}
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{
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// Finally try a golden input - it should like both of them
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EXPECT_EQ(PerfCounters::Create({kGenericPerfEvent1, kGenericPerfEvent2})
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.num_counters(),
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2);
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}
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{
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// Add a bad apple in the end of the chain to check the edges
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auto counter = PerfCounters::Create(
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{kGenericPerfEvent1, kGenericPerfEvent2, "bad event name"});
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EXPECT_EQ(counter.num_counters(), 2);
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EXPECT_EQ(counter.names(), std::vector<std::string>(
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{kGenericPerfEvent1, kGenericPerfEvent2}));
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}
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}
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TEST(PerfCountersTest, Read1Counter) {
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if (!PerfCounters::kSupported) {
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GTEST_SKIP() << "Test skipped because libpfm is not supported.\n";
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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auto counters = PerfCounters::Create({kGenericPerfEvent1});
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EXPECT_EQ(counters.num_counters(), 1);
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PerfCounterValues values1(1);
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EXPECT_TRUE(counters.Snapshot(&values1));
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EXPECT_GT(values1[0], 0);
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PerfCounterValues values2(1);
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EXPECT_TRUE(counters.Snapshot(&values2));
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EXPECT_GT(values2[0], 0);
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EXPECT_GT(values2[0], values1[0]);
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}
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TEST(PerfCountersTest, Read2Counters) {
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if (!PerfCounters::kSupported) {
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GTEST_SKIP() << "Test skipped because libpfm is not supported.\n";
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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auto counters =
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PerfCounters::Create({kGenericPerfEvent1, kGenericPerfEvent2});
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EXPECT_EQ(counters.num_counters(), 2);
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PerfCounterValues values1(2);
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EXPECT_TRUE(counters.Snapshot(&values1));
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EXPECT_GT(values1[0], 0);
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EXPECT_GT(values1[1], 0);
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PerfCounterValues values2(2);
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EXPECT_TRUE(counters.Snapshot(&values2));
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EXPECT_GT(values2[0], 0);
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EXPECT_GT(values2[1], 0);
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}
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TEST(PerfCountersTest, ReopenExistingCounters) {
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// This test works in recent and old Intel hardware, Pixel 3, and Pixel 6.
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// However we cannot make assumptions beyond 2 HW counters due to Pixel 6.
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if (!PerfCounters::kSupported) {
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GTEST_SKIP() << "Test skipped because libpfm is not supported.\n";
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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std::vector<std::string> kMetrics({kGenericPerfEvent1});
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std::vector<PerfCounters> counters(2);
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for (auto& counter : counters) {
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counter = PerfCounters::Create(kMetrics);
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}
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PerfCounterValues values(1);
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EXPECT_TRUE(counters[0].Snapshot(&values));
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EXPECT_TRUE(counters[1].Snapshot(&values));
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}
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TEST(PerfCountersTest, CreateExistingMeasurements) {
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// The test works (i.e. causes read to fail) for the assumptions
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// about hardware capabilities (i.e. small number (2) hardware
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// counters) at this date,
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// the same as previous test ReopenExistingCounters.
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if (!PerfCounters::kSupported) {
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GTEST_SKIP() << "Test skipped because libpfm is not supported.\n";
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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// This means we will try 10 counters but we can only guarantee
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// for sure at this time that only 3 will work. Perhaps in the future
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// we could use libpfm to query for the hardware limits on this
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// particular platform.
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const int kMaxCounters = 10;
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const int kMinValidCounters = 2;
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// Let's use a ubiquitous counter that is guaranteed to work
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// on all platforms
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const std::vector<std::string> kMetrics{"cycles"};
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// Cannot create a vector of actual objects because the
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// copy constructor of PerfCounters is deleted - and so is
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// implicitly deleted on PerfCountersMeasurement too
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std::vector<std::unique_ptr<PerfCountersMeasurement>>
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perf_counter_measurements;
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perf_counter_measurements.reserve(kMaxCounters);
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for (int j = 0; j < kMaxCounters; ++j) {
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perf_counter_measurements.emplace_back(
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new PerfCountersMeasurement(kMetrics));
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}
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std::vector<std::pair<std::string, double>> measurements;
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// Start all counters together to see if they hold
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size_t max_counters = kMaxCounters;
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for (size_t i = 0; i < kMaxCounters; ++i) {
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auto& counter(*perf_counter_measurements[i]);
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EXPECT_EQ(counter.num_counters(), 1);
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if (!counter.Start()) {
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max_counters = i;
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break;
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};
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}
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ASSERT_GE(max_counters, kMinValidCounters);
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// Start all together
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for (size_t i = 0; i < max_counters; ++i) {
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auto& counter(*perf_counter_measurements[i]);
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EXPECT_TRUE(counter.Stop(measurements) || (i >= kMinValidCounters));
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}
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// Start/stop individually
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for (size_t i = 0; i < max_counters; ++i) {
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auto& counter(*perf_counter_measurements[i]);
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measurements.clear();
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counter.Start();
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EXPECT_TRUE(counter.Stop(measurements) || (i >= kMinValidCounters));
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}
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}
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// We try to do some meaningful work here but the compiler
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// insists in optimizing away our loop so we had to add a
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// no-optimize macro. In case it fails, we added some entropy
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// to this pool as well.
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BENCHMARK_DONT_OPTIMIZE size_t do_work() {
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static std::mt19937 rd{std::random_device{}()};
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static std::uniform_int_distribution<size_t> mrand(0, 10);
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const size_t kNumLoops = 1000000;
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size_t sum = 0;
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for (size_t j = 0; j < kNumLoops; ++j) {
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sum += mrand(rd);
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}
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benchmark::DoNotOptimize(sum);
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return sum;
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}
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void measure(size_t threadcount, PerfCounterValues* before,
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PerfCounterValues* after) {
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BM_CHECK_NE(before, nullptr);
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BM_CHECK_NE(after, nullptr);
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std::vector<std::thread> threads(threadcount);
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auto work = [&]() { BM_CHECK(do_work() > 1000); };
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// We need to first set up the counters, then start the threads, so the
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// threads would inherit the counters. But later, we need to first destroy
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// the thread pool (so all the work finishes), then measure the counters. So
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// the scopes overlap, and we need to explicitly control the scope of the
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// threadpool.
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auto counters =
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PerfCounters::Create({kGenericPerfEvent1, kGenericPerfEvent2});
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for (auto& t : threads) t = std::thread(work);
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counters.Snapshot(before);
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for (auto& t : threads) t.join();
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counters.Snapshot(after);
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}
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TEST(PerfCountersTest, MultiThreaded) {
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if (!PerfCounters::kSupported) {
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GTEST_SKIP() << "Test skipped because libpfm is not supported.";
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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PerfCounterValues before(2);
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PerfCounterValues after(2);
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// Notice that this test will work even if we taskset it to a single CPU
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// In this case the threads will run sequentially
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// Start two threads and measure the number of combined cycles and
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// instructions
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measure(2, &before, &after);
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std::vector<double> Elapsed2Threads{
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static_cast<double>(after[0] - before[0]),
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static_cast<double>(after[1] - before[1])};
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// Start four threads and measure the number of combined cycles and
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// instructions
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measure(4, &before, &after);
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std::vector<double> Elapsed4Threads{
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static_cast<double>(after[0] - before[0]),
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static_cast<double>(after[1] - before[1])};
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// The following expectations fail (at least on a beefy workstation with lots
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// of cpus) - it seems that in some circumstances the runtime of 4 threads
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// can even be better than with 2.
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// So instead of expecting 4 threads to be slower, let's just make sure they
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// do not differ too much in general (one is not more than 10x than the
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// other).
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EXPECT_THAT(Elapsed4Threads[0] / Elapsed2Threads[0], AllOf(Gt(0.1), Lt(10)));
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EXPECT_THAT(Elapsed4Threads[1] / Elapsed2Threads[1], AllOf(Gt(0.1), Lt(10)));
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}
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TEST(PerfCountersTest, HardwareLimits) {
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// The test works (i.e. causes read to fail) for the assumptions
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// about hardware capabilities (i.e. small number (3-4) hardware
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// counters) at this date,
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// the same as previous test ReopenExistingCounters.
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if (!PerfCounters::kSupported) {
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GTEST_SKIP() << "Test skipped because libpfm is not supported.\n";
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}
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EXPECT_TRUE(PerfCounters::Initialize());
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// Taken from `perf list`, but focusses only on those HW events that actually
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// were reported when running `sudo perf stat -a sleep 10`, intersected over
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// several platforms. All HW events listed in the first command not reported
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// in the second seem to not work. This is sad as we don't really get to test
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// the grouping here (groups can contain up to 6 members)...
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std::vector<std::string> counter_names{
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"cycles", // leader
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"instructions", //
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"branch-misses", //
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};
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// In the off-chance that some of these values are not supported,
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// we filter them out so the test will complete without failure
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// albeit it might not actually test the grouping on that platform
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std::vector<std::string> valid_names;
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for (const std::string& name : counter_names) {
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if (PerfCounters::IsCounterSupported(name)) {
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valid_names.push_back(name);
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}
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}
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PerfCountersMeasurement counter(valid_names);
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std::vector<std::pair<std::string, double>> measurements;
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counter.Start();
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EXPECT_TRUE(counter.Stop(measurements));
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}
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} // namespace
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