// Support for registering benchmarks for functions. /* Example usage: // Define a function that executes the code to be measured a // specified number of times: static void BM_StringCreation(benchmark::State& state) { while (state.KeepRunning()) std::string empty_string; } // Register the function as a benchmark BENCHMARK(BM_StringCreation); // Define another benchmark static void BM_StringCopy(benchmark::State& state) { std::string x = "hello"; while (state.KeepRunning()) std::string copy(x); } BENCHMARK(BM_StringCopy); // Augment the main() program to invoke benchmarks if specified // via the --benchmarks command line flag. E.g., // my_unittest --benchmark_filter=all // my_unittest --benchmark_filter=BM_StringCreation // my_unittest --benchmark_filter=String // my_unittest --benchmark_filter='Copy|Creation' int main(int argc, char** argv) { benchmark::Initialize(&argc, argv); benchmark::RunSpecifiedBenchmarks(); return 0; } // Sometimes a family of microbenchmarks can be implemented with // just one routine that takes an extra argument to specify which // one of the family of benchmarks to run. For example, the following // code defines a family of microbenchmarks for measuring the speed // of memcpy() calls of different lengths: static void BM_memcpy(benchmark::State& state) { char* src = new char[state.range_x()]; char* dst = new char[state.range_x()]; memset(src, 'x', state.range_x()); while (state.KeepRunning()) memcpy(dst, src, state.range_x()); state.SetBytesProcessed(int64_t_t(state.iterations) * int64(state.range_x())); delete[] src; delete[] dst; } BENCHMARK(BM_memcpy)->Arg(8)->Arg(64)->Arg(512)->Arg(1<<10)->Arg(8<<10); // The preceding code is quite repetitive, and can be replaced with the // following short-hand. The following invocation will pick a few // appropriate arguments in the specified range and will generate a // microbenchmark for each such argument. BENCHMARK(BM_memcpy)->Range(8, 8<<10); // You might have a microbenchmark that depends on two inputs. For // example, the following code defines a family of microbenchmarks for // measuring the speed of set insertion. static void BM_SetInsert(benchmark::State& state) { while (state.KeepRunning()) { state.PauseTiming(); set data = ConstructRandomSet(state.range_x()); state.ResumeTiming(); for (int j = 0; j < state.rangeY; ++j) data.insert(RandomNumber()); } } BENCHMARK(BM_SetInsert) ->ArgPair(1<<10, 1) ->ArgPair(1<<10, 8) ->ArgPair(1<<10, 64) ->ArgPair(1<<10, 512) ->ArgPair(8<<10, 1) ->ArgPair(8<<10, 8) ->ArgPair(8<<10, 64) ->ArgPair(8<<10, 512); // The preceding code is quite repetitive, and can be replaced with // the following short-hand. The following macro will pick a few // appropriate arguments in the product of the two specified ranges // and will generate a microbenchmark for each such pair. BENCHMARK(BM_SetInsert)->RangePair(1<<10, 8<<10, 1, 512); // For more complex patterns of inputs, passing a custom function // to Apply allows programmatic specification of an // arbitrary set of arguments to run the microbenchmark on. // The following example enumerates a dense range on // one parameter, and a sparse range on the second. static benchmark::internal::Benchmark* CustomArguments( benchmark::internal::Benchmark* b) { for (int i = 0; i <= 10; ++i) for (int j = 32; j <= 1024*1024; j *= 8) b = b->ArgPair(i, j); return b; } BENCHMARK(BM_SetInsert)->Apply(CustomArguments); // Templated microbenchmarks work the same way: // Produce then consume 'size' messages 'iters' times // Measures throughput in the absence of multiprogramming. template int BM_Sequential(benchmark::State& state) { Q q; typename Q::value_type v; while (state.KeepRunning()) { for (int i = state.range_x(); i--; ) q.push(v); for (int e = state.range_x(); e--; ) q.Wait(&v); } // actually messages, not bytes: state.SetBytesProcessed( static_cast(state.iterations())*state.range_x()); } BENCHMARK_TEMPLATE(BM_Sequential, WaitQueue)->Range(1<<0, 1<<10); Use `Benchmark::MinTime(double t)` to set the minimum time used to run the benchmark. This option overrides the `benchmark_min_time` flag. void BM_test(benchmark::State& state) { ... body ... } BENCHMARK(BM_test)->MinTime(2.0); // Run for at least 2 seconds. In a multithreaded test, it is guaranteed that none of the threads will start until all have called KeepRunning, and all will have finished before KeepRunning returns false. As such, any global setup or teardown you want to do can be wrapped in a check against the thread index: static void BM_MultiThreaded(benchmark::State& state) { if (state.thread_index == 0) { // Setup code here. } while (state.KeepRunning()) { // Run the test as normal. } if (state.thread_index == 0) { // Teardown code here. } } BENCHMARK(BM_MultiThreaded)->Threads(4); */ #ifndef BENCHMARK_BENCHMARK_API_H_ #define BENCHMARK_BENCHMARK_API_H_ #include #include #include #include "macros.h" namespace benchmark { class BenchmarkReporter; void Initialize(int* argc, const char** argv); // Otherwise, run all benchmarks specified by the --benchmark_filter flag, // and exit after running the benchmarks. void RunSpecifiedBenchmarks(); void RunSpecifiedBenchmarks(BenchmarkReporter* reporter); // If this routine is called, peak memory allocation past this point in the // benchmark is reported at the end of the benchmark report line. (It is // computed by running the benchmark once with a single iteration and a memory // tracer.) // TODO(dominic) // void MemoryUsage(); namespace internal { class Benchmark; class BenchmarkImp; template struct Voider { typedef void type; }; template struct EnableIfString {}; template struct EnableIfString::type> { typedef int type; }; void UseCharPointer(char const volatile*); } // end namespace internal // The DoNotOptimize(...) function can be used to prevent a value or // expression from being optimized away by the compiler. This function is // intented to add little to no overhead. // See: http://stackoverflow.com/questions/28287064 #if defined(__clang__) && defined(__GNUC__) // TODO(ericwf): Clang has a bug where it tries to always use a register // even if value must be stored in memory. This causes codegen to fail. // To work around this we remove the "r" modifier so the operand is always // loaded into memory. template inline BENCHMARK_ALWAYS_INLINE void DoNotOptimize(Tp const& value) { asm volatile("" : "+m" (const_cast(value))); } #elif defined(__GNUC__) template inline BENCHMARK_ALWAYS_INLINE void DoNotOptimize(Tp const& value) { asm volatile("" : "+rm" (const_cast(value))); } #else template inline BENCHMARK_ALWAYS_INLINE void DoNotOptimize(Tp const& value) { internal::UseCharPointer(&reinterpret_cast(value)); } #endif // State is passed to a running Benchmark and contains state for the // benchmark to use. class State { public: State(size_t max_iters, bool has_x, int x, bool has_y, int y, int thread_i); // Returns true iff the benchmark should continue through another iteration. // NOTE: A benchmark may not return from the test until KeepRunning() has // returned false. bool KeepRunning() { if (BENCHMARK_BUILTIN_EXPECT(!started_, false)) { ResumeTiming(); started_ = true; } bool const res = total_iterations_++ < max_iterations; if (BENCHMARK_BUILTIN_EXPECT(!res, false)) { assert(started_); PauseTiming(); // Total iterations now is one greater than max iterations. Fix this. total_iterations_ = max_iterations; } return res; } // REQUIRES: timer is running // Stop the benchmark timer. If not called, the timer will be // automatically stopped after KeepRunning() returns false for the first time. // // For threaded benchmarks the PauseTiming() function acts // like a barrier. I.e., the ith call by a particular thread to this // function will block until all threads have made their ith call. // The timer will stop when the last thread has called this function. // // NOTE: PauseTiming()/ResumeTiming() are relatively // heavyweight, and so their use should generally be avoided // within each benchmark iteration, if possible. void PauseTiming(); // REQUIRES: timer is not running // Start the benchmark timer. The timer is NOT running on entrance to the // benchmark function. It begins running after the first call to KeepRunning() // // For threaded benchmarks the ResumeTiming() function acts // like a barrier. I.e., the ith call by a particular thread to this // function will block until all threads have made their ith call. // The timer will start when the last thread has called this function. // // NOTE: PauseTiming()/ResumeTiming() are relatively // heavyweight, and so their use should generally be avoided // within each benchmark iteration, if possible. void ResumeTiming(); // Set the number of bytes processed by the current benchmark // execution. This routine is typically called once at the end of a // throughput oriented benchmark. If this routine is called with a // value > 0, the report is printed in MB/sec instead of nanoseconds // per iteration. // // REQUIRES: a benchmark has exited its KeepRunning loop. BENCHMARK_ALWAYS_INLINE void SetBytesProcessed(size_t bytes) { bytes_processed_ = bytes; } BENCHMARK_ALWAYS_INLINE size_t bytes_processed() const { return bytes_processed_; } // If this routine is called with items > 0, then an items/s // label is printed on the benchmark report line for the currently // executing benchmark. It is typically called at the end of a processing // benchmark where a processing items/second output is desired. // // REQUIRES: a benchmark has exited its KeepRunning loop. BENCHMARK_ALWAYS_INLINE void SetItemsProcessed(size_t items) { items_processed_ = items; } BENCHMARK_ALWAYS_INLINE size_t items_processed() const { return items_processed_; } // If this routine is called, the specified label is printed at the // end of the benchmark report line for the currently executing // benchmark. Example: // static void BM_Compress(int iters) { // ... // double compress = input_size / output_size; // benchmark::SetLabel(StringPrintf("compress:%.1f%%", 100.0*compression)); // } // Produces output that looks like: // BM_Compress 50 50 14115038 compress:27.3% // // REQUIRES: a benchmark has exited its KeepRunning loop. void SetLabel(const char* label); // Allow the use of std::string without actually including . // This function does not participate in overload resolution unless StringType // has the nested typename `basic_string`. This typename should be provided // as an injected class name in the case of std::string. template void SetLabel(StringType const & str, typename internal::EnableIfString::type = 1) { this->SetLabel(str.c_str()); } // Range arguments for this run. CHECKs if the argument has been set. BENCHMARK_ALWAYS_INLINE int range_x() const { assert(has_range_x_); ((void)has_range_x_); // Prevent unused warning. return range_x_; } BENCHMARK_ALWAYS_INLINE int range_y() const { assert(has_range_y_); ((void)has_range_y_); // Prevent unused warning. return range_y_; } BENCHMARK_ALWAYS_INLINE size_t iterations() const { return total_iterations_; } private: bool started_; size_t total_iterations_; bool has_range_x_; int range_x_; bool has_range_y_; int range_y_; size_t bytes_processed_; size_t items_processed_; public: const int thread_index; const size_t max_iterations; private: BENCHMARK_DISALLOW_COPY_AND_ASSIGN(State); }; namespace internal { typedef void(Function)(State&); // ------------------------------------------------------ // Benchmark registration object. The BENCHMARK() macro expands // into an internal::Benchmark* object. Various methods can // be called on this object to change the properties of the benchmark. // Each method returns "this" so that multiple method calls can // chained into one expression. class Benchmark { public: Benchmark(const char* name, Function* f); ~Benchmark(); // Note: the following methods all return "this" so that multiple // method calls can be chained together in one expression. // Run this benchmark once with "x" as the extra argument passed // to the function. // REQUIRES: The function passed to the constructor must accept an arg1. Benchmark* Arg(int x); // Run this benchmark once for a number of values picked from the // range [start..limit]. (start and limit are always picked.) // REQUIRES: The function passed to the constructor must accept an arg1. Benchmark* Range(int start, int limit); // Run this benchmark once for every value in the range [start..limit] // REQUIRES: The function passed to the constructor must accept an arg1. Benchmark* DenseRange(int start, int limit); // Run this benchmark once with "x,y" as the extra arguments passed // to the function. // REQUIRES: The function passed to the constructor must accept arg1,arg2. Benchmark* ArgPair(int x, int y); // Pick a set of values A from the range [lo1..hi1] and a set // of values B from the range [lo2..hi2]. Run the benchmark for // every pair of values in the cartesian product of A and B // (i.e., for all combinations of the values in A and B). // REQUIRES: The function passed to the constructor must accept arg1,arg2. Benchmark* RangePair(int lo1, int hi1, int lo2, int hi2); // Pass this benchmark object to *func, which can customize // the benchmark by calling various methods like Arg, ArgPair, // Threads, etc. Benchmark* Apply(void (*func)(Benchmark* benchmark)); // Set the minimum amount of time to use when running this benchmark. This // option overrides the `benchmark_min_time` flag. Benchmark* MinTime(double t); // If a particular benchmark is I/O bound, or if for some reason CPU // timings are not representative, call this method. If called, the elapsed // time will be used to control how many iterations are run, and in the // printing of items/second or MB/seconds values. If not called, the cpu // time used by the benchmark will be used. Benchmark* UseRealTime(); // Support for running multiple copies of the same benchmark concurrently // in multiple threads. This may be useful when measuring the scaling // of some piece of code. // Run one instance of this benchmark concurrently in t threads. Benchmark* Threads(int t); // Pick a set of values T from [min_threads,max_threads]. // min_threads and max_threads are always included in T. Run this // benchmark once for each value in T. The benchmark run for a // particular value t consists of t threads running the benchmark // function concurrently. For example, consider: // BENCHMARK(Foo)->ThreadRange(1,16); // This will run the following benchmarks: // Foo in 1 thread // Foo in 2 threads // Foo in 4 threads // Foo in 8 threads // Foo in 16 threads Benchmark* ThreadRange(int min_threads, int max_threads); // Equivalent to ThreadRange(NumCPUs(), NumCPUs()) Benchmark* ThreadPerCpu(); // Used inside the benchmark implementation struct Instance; private: BenchmarkImp* imp_; BENCHMARK_DISALLOW_COPY_AND_ASSIGN(Benchmark); }; } // end namespace internal } // end namespace benchmark // ------------------------------------------------------ // Macro to register benchmarks // Check that __COUNTER__ is defined and that __COUNTER__ increases by 1 // every time it is expanded. X + 1 == X + 0 is used in case X is defined to be // empty. If X is empty the expression becomes (+1 == +0). #if defined(__COUNTER__) && (__COUNTER__ + 1 == __COUNTER__ + 0) #define BENCHMARK_PRIVATE_UNIQUE_ID __COUNTER__ #else #define BENCHMARK_PRIVATE_UNIQUE_ID __LINE__ #endif // Helpers for generating unique variable names #define BENCHMARK_PRIVATE_NAME(n) \ BENCHMARK_PRIVATE_CONCAT(_benchmark_, BENCHMARK_PRIVATE_UNIQUE_ID, n) #define BENCHMARK_PRIVATE_CONCAT(a, b, c) BENCHMARK_PRIVATE_CONCAT2(a, b, c) #define BENCHMARK_PRIVATE_CONCAT2(a, b, c) a##b##c #define BENCHMARK_PRIVATE_DECLARE(n) \ static ::benchmark::internal::Benchmark* \ BENCHMARK_PRIVATE_NAME(n) BENCHMARK_UNUSED #define BENCHMARK(n) \ BENCHMARK_PRIVATE_DECLARE(n) = (new ::benchmark::internal::Benchmark(#n, n)) // Old-style macros #define BENCHMARK_WITH_ARG(n, a) BENCHMARK(n)->Arg((a)) #define BENCHMARK_WITH_ARG2(n, a1, a2) BENCHMARK(n)->ArgPair((a1), (a2)) #define BENCHMARK_RANGE(n, lo, hi) BENCHMARK(n)->Range((lo), (hi)) #define BENCHMARK_RANGE2(n, l1, h1, l2, h2) \ BENCHMARK(n)->RangePair((l1), (h1), (l2), (h2)) // This will register a benchmark for a templatized function. For example: // // template // void BM_Foo(int iters); // // BENCHMARK_TEMPLATE(BM_Foo, 1); // // will register BM_Foo<1> as a benchmark. #define BENCHMARK_TEMPLATE1(n, a) \ BENCHMARK_PRIVATE_DECLARE(n) = \ (new ::benchmark::internal::Benchmark(#n "<" #a ">", n)) #define BENCHMARK_TEMPLATE2(n, a, b) \ BENCHMARK_PRIVATE_DECLARE(n) = \ (new ::benchmark::internal::Benchmark(#n "<" #a "," #b ">", n)) #if __cplusplus >= 201103L #define BENCHMARK_TEMPLATE(n, ...) \ BENCHMARK_PRIVATE_DECLARE(n) = \ (new ::benchmark::internal::Benchmark( \ #n "<" #__VA_ARGS__ ">", n<__VA_ARGS__>)) #else #define BENCHMARK_TEMPLATE(n, a) BENCHMARK_TEMPLATE1(n, a) #endif // Helper macro to create a main routine in a test that runs the benchmarks #define BENCHMARK_MAIN() \ int main(int argc, const char** argv) { \ ::benchmark::Initialize(&argc, argv); \ ::benchmark::RunSpecifiedBenchmarks(); \ } #endif // BENCHMARK_BENCHMARK_API_H_