Merge #11562: bench: use std::chrono rather than gettimeofday

24a0bdd bench: prefer a steady clock if the resolution is no worse (Cory Fields) c515d26 bench: switch to std::chrono for time measurements (Cory Fields) Pull request description: gettimeofday has portability issues, see for example #11558. Regardless of large-scale clock refactors in the future, I think it's fine for bench to just use std::chrono itself. Note that this may slightly improve bench accuracy and changes the display from tiny floats to nanosecond counts instead. Tree-SHA512: 122355456d01ec6cfcf6867991715cf3a95eabbf5a4f2adc26a059b50382ffb318b7639cdd575197fc4ee5be8b967c0404f1f920d6f5bd4ddd0bd63b5e5c5632
2017-11-08 08:32:54 +01:00 · 2017-11-08 08:32:54 +01:00 · 5776582b7f
commit 5776582b7f
parent dd561667cb 24a0bddf4a
3 changed files with 38 additions and 29 deletions
--- a/src/bench/bench.cpp
+++ b/src/bench/bench.cpp
@ -8,29 +8,22 @@
 #include <assert.h>
 #include <iostream>
 #include <iomanip>
-#include <sys/time.h>

 benchmark::BenchRunner::BenchmarkMap &benchmark::BenchRunner::benchmarks() {
    static std::map<std::string, benchmark::BenchFunction> benchmarks_map;
    return benchmarks_map;
 }

-static double gettimedouble(void) {
-    struct timeval tv;
-    gettimeofday(&tv, nullptr);
-    return tv.tv_usec * 0.000001 + tv.tv_sec;
-}
-
 benchmark::BenchRunner::BenchRunner(std::string name, benchmark::BenchFunction func)
 {
    benchmarks().insert(std::make_pair(name, func));
 }

 void
-benchmark::BenchRunner::RunAll(double elapsedTimeForOne)
+benchmark::BenchRunner::RunAll(benchmark::duration elapsedTimeForOne)
 {
    perf_init();
-    std::cout << "#Benchmark" << "," << "count" << "," << "min" << "," << "max" << "," << "average" << ","
+    std::cout << "#Benchmark" << "," << "count" << "," << "min(ns)" << "," << "max(ns)" << "," << "average(ns)" << ","
              << "min_cycles" << "," << "max_cycles" << "," << "average_cycles" << "\n";

    for (const auto &p: benchmarks()) {
@ -46,16 +39,17 @@ bool benchmark::State::KeepRunning()
      ++count;
      return true;
    }
-    double now;
+    time_point now;
+
    uint64_t nowCycles;
    if (count == 0) {
-        lastTime = beginTime = now = gettimedouble();
+        lastTime = beginTime = now = clock::now();
        lastCycles = beginCycles = nowCycles = perf_cpucycles();
    }
    else {
-        now = gettimedouble();
-        double elapsed = now - lastTime;
-        double elapsedOne = elapsed / (countMask + 1);
+        now = clock::now();
+        auto elapsed = now - lastTime;
+        auto elapsedOne = elapsed / (countMask + 1);
        if (elapsedOne < minTime) minTime = elapsedOne;
        if (elapsedOne > maxTime) maxTime = elapsedOne;

@ -70,8 +64,8 @@ bool benchmark::State::KeepRunning()
          // The restart avoids including the overhead of this code in the measurement.
          countMask = ((countMask<<3)|7) & ((1LL<<60)-1);
          count = 0;
-          minTime = std::numeric_limits<double>::max();
-          maxTime = std::numeric_limits<double>::min();
+          minTime = duration::max();
+          maxTime = duration::zero();
          minCycles = std::numeric_limits<uint64_t>::max();
          maxCycles = std::numeric_limits<uint64_t>::min();
          return true;
@ -94,9 +88,13 @@ bool benchmark::State::KeepRunning()
    assert(count != 0 && "count == 0 => (now == 0 && beginTime == 0) => return above");

    // Output results
-    double average = (now-beginTime)/count;
+    // Duration casts are only necessary here because hardware with sub-nanosecond clocks
+    // will lose precision.
+    int64_t min_elapsed = std::chrono::duration_cast<std::chrono::nanoseconds>(minTime).count();
+    int64_t max_elapsed = std::chrono::duration_cast<std::chrono::nanoseconds>(maxTime).count();
+    int64_t avg_elapsed = std::chrono::duration_cast<std::chrono::nanoseconds>((now-beginTime)/count).count();
    int64_t averageCycles = (nowCycles-beginCycles)/count;
-    std::cout << std::fixed << std::setprecision(15) << name << "," << count << "," << minTime << "," << maxTime << "," << average << ","
+    std::cout << std::fixed << std::setprecision(15) << name << "," << count << "," << min_elapsed << "," << max_elapsed << "," << avg_elapsed << ","
              << minCycles << "," << maxCycles << "," << averageCycles << "\n";
    std::cout.copyfmt(std::ios(nullptr));

--- a/src/bench/bench.h
+++ b/src/bench/bench.h
@ -9,6 +9,7 @@
 #include <limits>
 #include <map>
 #include <string>
+#include <chrono>

 #include <boost/preprocessor/cat.hpp>
 #include <boost/preprocessor/stringize.hpp>
@ -36,12 +37,23 @@ BENCHMARK(CODE_TO_TIME);
 */
 
 namespace benchmark {
+    // On many systems, the high_resolution_clock offers no better resolution than the steady_clock.
+    // If that's the case, prefer the steady_clock.
+    struct best_clock {
+        using hi_res_clock = std::chrono::high_resolution_clock;
+        using steady_clock = std::chrono::steady_clock;
+        static constexpr bool steady_is_high_res = std::ratio_less_equal<steady_clock::period, hi_res_clock::period>::value;
+        using type = std::conditional<steady_is_high_res, steady_clock, hi_res_clock>::type;
+    };
+    using clock = best_clock::type;
+    using time_point = clock::time_point;
+    using duration = clock::duration;

    class State {
        std::string name;
-        double maxElapsed;
-        double beginTime;
-        double lastTime, minTime, maxTime;
+        duration maxElapsed;
+        time_point beginTime, lastTime;
+        duration minTime, maxTime;
        uint64_t count;
        uint64_t countMask;
        uint64_t beginCycles;
@ -49,9 +61,9 @@ namespace benchmark {
        uint64_t minCycles;
        uint64_t maxCycles;
    public:
-        State(std::string _name, double _maxElapsed) : name(_name), maxElapsed(_maxElapsed), count(0) {
-            minTime = std::numeric_limits<double>::max();
-            maxTime = std::numeric_limits<double>::min();
+        State(std::string _name, duration _maxElapsed) : name(_name), maxElapsed(_maxElapsed), count(0) {
+            minTime = duration::max();
+            maxTime = duration::zero();
            minCycles = std::numeric_limits<uint64_t>::max();
            maxCycles = std::numeric_limits<uint64_t>::min();
            countMask = 1;
@ -69,7 +81,7 @@ namespace benchmark {
    public:
        BenchRunner(std::string name, BenchFunction func);

-        static void RunAll(double elapsedTimeForOne=1.0);
+        static void RunAll(duration elapsedTimeForOne = std::chrono::seconds(1));
    };
 }

--- a/src/bench/rollingbloom.cpp
+++ b/src/bench/rollingbloom.cpp
@ -6,7 +6,6 @@

 #include "bench.h"
 #include "bloom.h"
-#include "utiltime.h"

 static void RollingBloom(benchmark::State& state)
 {
@ -23,10 +22,10 @@ static void RollingBloom(benchmark::State& state)
        data[2] = count >> 16;
        data[3] = count >> 24;
        if (countnow == nEntriesPerGeneration) {
-            int64_t b = GetTimeMicros();
+            auto b = benchmark::clock::now();
            filter.insert(data);
-            int64_t e = GetTimeMicros();
-            std::cout << "RollingBloom-refresh,1," << (e-b)*0.000001 << "," << (e-b)*0.000001 << "," << (e-b)*0.000001 << "\n";
+            auto total = std::chrono::duration_cast<std::chrono::nanoseconds>(benchmark::clock::now() - b).count();
+            std::cout << "RollingBloom-refresh,1," << total << "," << total << "," << total << "\n";
            countnow = 0;
        } else {
            filter.insert(data);