benchmark/test/complexity_test.cc
Roman Lebedev 58588476ce
Track two more details about runs - the aggregate name, and run name. (#675)
This is related to @BaaMeow's work in https://github.com/google/benchmark/pull/616 but is not based on it.

Two new fields are tracked, and dumped into JSON:
* If the run is an aggregate, the aggregate's name is stored.
  It can be RMS, BigO, mean, median, stddev, or any custom stat name.
* The aggregate-name-less run name is additionally stored.
  I.e. not some name of the benchmark function, but the actual
  name, but without the 'aggregate name' suffix.

This way one can group/filter all the runs,
and filter by the particular aggregate type.

I *might* need this for further tooling improvement.
Or maybe not.
But this is certainly worthwhile for custom tooling.
2018-09-13 15:08:15 +03:00

184 lines
6.9 KiB
C++

#undef NDEBUG
#include <algorithm>
#include <cassert>
#include <cmath>
#include <cstdlib>
#include <vector>
#include "benchmark/benchmark.h"
#include "output_test.h"
namespace {
#define ADD_COMPLEXITY_CASES(...) \
int CONCAT(dummy, __LINE__) = AddComplexityTest(__VA_ARGS__)
int AddComplexityTest(std::string test_name, std::string big_o_test_name,
std::string rms_test_name, std::string big_o) {
SetSubstitutions({{"%name", test_name},
{"%bigo_name", big_o_test_name},
{"%rms_name", rms_test_name},
{"%bigo_str", "[ ]* %float " + big_o},
{"%bigo", big_o},
{"%rms", "[ ]*[0-9]+ %"}});
AddCases(
TC_ConsoleOut,
{{"^%bigo_name %bigo_str %bigo_str[ ]*$"},
{"^%bigo_name", MR_Not}, // Assert we we didn't only matched a name.
{"^%rms_name %rms %rms[ ]*$", MR_Next}});
AddCases(TC_JSONOut, {{"\"name\": \"%bigo_name\",$"},
{"\"run_name\": \"%name\",$", MR_Next},
{"\"run_type\": \"aggregate\",$", MR_Next},
{"\"aggregate_name\": \"BigO\",$", MR_Next},
{"\"cpu_coefficient\": %float,$", MR_Next},
{"\"real_coefficient\": %float,$", MR_Next},
{"\"big_o\": \"%bigo\",$", MR_Next},
{"\"time_unit\": \"ns\"$", MR_Next},
{"}", MR_Next},
{"\"name\": \"%rms_name\",$"},
{"\"run_name\": \"%name\",$", MR_Next},
{"\"run_type\": \"aggregate\",$", MR_Next},
{"\"aggregate_name\": \"RMS\",$", MR_Next},
{"\"rms\": %float$", MR_Next},
{"}", MR_Next}});
AddCases(TC_CSVOut, {{"^\"%bigo_name\",,%float,%float,%bigo,,,,,$"},
{"^\"%bigo_name\"", MR_Not},
{"^\"%rms_name\",,%float,%float,,,,,,$", MR_Next}});
return 0;
}
} // end namespace
// ========================================================================= //
// --------------------------- Testing BigO O(1) --------------------------- //
// ========================================================================= //
void BM_Complexity_O1(benchmark::State& state) {
for (auto _ : state) {
for (int i = 0; i < 1024; ++i) {
benchmark::DoNotOptimize(&i);
}
}
state.SetComplexityN(state.range(0));
}
BENCHMARK(BM_Complexity_O1)->Range(1, 1 << 18)->Complexity(benchmark::o1);
BENCHMARK(BM_Complexity_O1)->Range(1, 1 << 18)->Complexity();
BENCHMARK(BM_Complexity_O1)->Range(1, 1 << 18)->Complexity([](int64_t) {
return 1.0;
});
const char *one_test_name = "BM_Complexity_O1";
const char *big_o_1_test_name = "BM_Complexity_O1_BigO";
const char *rms_o_1_test_name = "BM_Complexity_O1_RMS";
const char *enum_big_o_1 = "\\([0-9]+\\)";
// FIXME: Tolerate both '(1)' and 'lgN' as output when the complexity is auto
// deduced.
// See https://github.com/google/benchmark/issues/272
const char *auto_big_o_1 = "(\\([0-9]+\\))|(lgN)";
const char *lambda_big_o_1 = "f\\(N\\)";
// Add enum tests
ADD_COMPLEXITY_CASES(one_test_name, big_o_1_test_name, rms_o_1_test_name,
enum_big_o_1);
// Add auto enum tests
ADD_COMPLEXITY_CASES(one_test_name, big_o_1_test_name, rms_o_1_test_name,
auto_big_o_1);
// Add lambda tests
ADD_COMPLEXITY_CASES(one_test_name, big_o_1_test_name, rms_o_1_test_name,
lambda_big_o_1);
// ========================================================================= //
// --------------------------- Testing BigO O(N) --------------------------- //
// ========================================================================= //
std::vector<int> ConstructRandomVector(int64_t size) {
std::vector<int> v;
v.reserve(static_cast<int>(size));
for (int i = 0; i < size; ++i) {
v.push_back(static_cast<int>(std::rand() % size));
}
return v;
}
void BM_Complexity_O_N(benchmark::State& state) {
auto v = ConstructRandomVector(state.range(0));
// Test worst case scenario (item not in vector)
const int64_t item_not_in_vector = state.range(0) * 2;
for (auto _ : state) {
benchmark::DoNotOptimize(std::find(v.begin(), v.end(), item_not_in_vector));
}
state.SetComplexityN(state.range(0));
}
BENCHMARK(BM_Complexity_O_N)
->RangeMultiplier(2)
->Range(1 << 10, 1 << 16)
->Complexity(benchmark::oN);
BENCHMARK(BM_Complexity_O_N)
->RangeMultiplier(2)
->Range(1 << 10, 1 << 16)
->Complexity([](int64_t n) -> double { return static_cast<double>(n); });
BENCHMARK(BM_Complexity_O_N)
->RangeMultiplier(2)
->Range(1 << 10, 1 << 16)
->Complexity();
const char *n_test_name = "BM_Complexity_O_N";
const char *big_o_n_test_name = "BM_Complexity_O_N_BigO";
const char *rms_o_n_test_name = "BM_Complexity_O_N_RMS";
const char *enum_auto_big_o_n = "N";
const char *lambda_big_o_n = "f\\(N\\)";
// Add enum tests
ADD_COMPLEXITY_CASES(n_test_name, big_o_n_test_name, rms_o_n_test_name,
enum_auto_big_o_n);
// Add lambda tests
ADD_COMPLEXITY_CASES(n_test_name, big_o_n_test_name, rms_o_n_test_name,
lambda_big_o_n);
// ========================================================================= //
// ------------------------- Testing BigO O(N*lgN) ------------------------- //
// ========================================================================= //
static void BM_Complexity_O_N_log_N(benchmark::State& state) {
auto v = ConstructRandomVector(state.range(0));
for (auto _ : state) {
std::sort(v.begin(), v.end());
}
state.SetComplexityN(state.range(0));
}
static const double kLog2E = 1.44269504088896340736;
BENCHMARK(BM_Complexity_O_N_log_N)
->RangeMultiplier(2)
->Range(1 << 10, 1 << 16)
->Complexity(benchmark::oNLogN);
BENCHMARK(BM_Complexity_O_N_log_N)
->RangeMultiplier(2)
->Range(1 << 10, 1 << 16)
->Complexity([](int64_t n) { return kLog2E * n * log(static_cast<double>(n)); });
BENCHMARK(BM_Complexity_O_N_log_N)
->RangeMultiplier(2)
->Range(1 << 10, 1 << 16)
->Complexity();
const char *n_lg_n_test_name = "BM_Complexity_O_N_log_N";
const char *big_o_n_lg_n_test_name = "BM_Complexity_O_N_log_N_BigO";
const char *rms_o_n_lg_n_test_name = "BM_Complexity_O_N_log_N_RMS";
const char *enum_auto_big_o_n_lg_n = "NlgN";
const char *lambda_big_o_n_lg_n = "f\\(N\\)";
// Add enum tests
ADD_COMPLEXITY_CASES(n_lg_n_test_name, big_o_n_lg_n_test_name,
rms_o_n_lg_n_test_name, enum_auto_big_o_n_lg_n);
// Add lambda tests
ADD_COMPLEXITY_CASES(n_lg_n_test_name, big_o_n_lg_n_test_name,
rms_o_n_lg_n_test_name, lambda_big_o_n_lg_n);
// ========================================================================= //
// --------------------------- TEST CASES END ------------------------------ //
// ========================================================================= //
int main(int argc, char *argv[]) { RunOutputTests(argc, argv); }