eval/f32-sqrt-ulp.cc - platform/external/XNNPACK - Gitiles

 // Copyright 2019 Google LLC
 //
 // This source code is licensed under the BSD-style license found in the
 // LICENSE file in the root directory of this source tree.

 #include <algorithm>
 #include <cfloat>
 #include <cmath>
 #include <functional>
 #include <memory>
 #include <numeric>
 #include <random>
 #include <vector>

 #include <cpuinfo.h>
 #include <pthreadpool.h>

 #include <benchmark/benchmark.h>
 #include <fp16/fp16.h>

 #include "bench/utils.h"
 #include <xnnpack/AlignedAllocator.h>
 #include <xnnpack/common.h>
 #include <xnnpack/math-stubs.h>


 struct ComputeErrorContext {
   const float* input;
   const float* output;
   float* error;
 };

 static void ComputeError(
   struct ComputeErrorContext* context,
   size_t start,
   size_t range)
 {
   const float* input = context->input;
   const float* output = context->output;
   float* error = context->error;
   for (size_t i = start; i < start + range; i++) {
     const double output_ref = std::sqrt(double(input[i]));
     const double abs_error = std::abs(output_ref - double(output[i]));
     const float output_abs = std::abs(output_ref);
     const float output_ulp = fp32_from_bits(fp32_to_bits(output_abs) + 1) - output_abs;
     error[i] = float(abs_error / output_ulp);
   }
 }

 static void SqrtError(benchmark::State& state,
   xnn_f32_unary_math_function sqrt,
   benchmark::utils::IsaCheckFunction isa_check = nullptr)
 {
   if (!cpuinfo_initialize()) {
     state.SkipWithError("failed cpuinfo init");
     return;
   }
   if (isa_check && !isa_check(state)) {
     return;
   }

   const uint32_t min_input = 0x3F800000;
   const uint32_t max_input = 0x41800000;
   // Number of elements in one block of inputs/outputs.
   // Combining multiple elements in a block reduce function call overhead.
   const size_t block_size = 16384;
   // Number of elements in one parallelization tile. Worker threads process this many elements in each task.
   const size_t tile_size = 64;

   uint32_t num_threads = cpuinfo_get_cores_count();
   #if XNN_ARCH_ARM || XNN_ARCH_ARM64
     // Use all cores except for the least performant cluster
     if (cpuinfo_get_clusters_count() > 1) {
       num_threads -= cpuinfo_get_cluster(cpuinfo_get_clusters_count() - 1)->core_count;
     }
   #endif  // XNN_ARCH_ARM || XNN_ARCH_ARM64

   std::unique_ptr<pthreadpool, decltype(&pthreadpool_destroy)> threadpool(
     pthreadpool_create(num_threads), pthreadpool_destroy);

   std::vector<float, AlignedAllocator<float, 64>> x(block_size);
   std::vector<float, AlignedAllocator<float, 64>> y(block_size);
   std::vector<float> ulp_error(block_size);
   float max_ulp_error = 0.0f;

   ComputeErrorContext context;
   context.input = x.data();
   context.output = y.data();
   context.error = ulp_error.data();
   for (auto _ : state) {
     for (uint32_t n = min_input; n < max_input; n += block_size) {
       for (uint32_t i = 0; i < block_size; i++) {
         x[i] = fp32_from_bits(std::min<uint32_t>(n + i, max_input));
       }
       std::fill(y.begin(), y.end(), std::nanf(""));

       sqrt(block_size * sizeof(float), x.data(), y.data());

       pthreadpool_parallelize_1d_tile_1d(
           threadpool.get(),
           reinterpret_cast<pthreadpool_task_1d_tile_1d_t>(ComputeError),
           static_cast<void*>(&context),
           block_size, tile_size, 0 /* flags */);

       max_ulp_error = std::accumulate(ulp_error.cbegin(), ulp_error.cend(), max_ulp_error,
         static_cast<const float& (*)(const float&, const float&)>(std::max<float>));
     }
   }

   state.counters["ULPERROR"] = benchmark::Counter(max_ulp_error);
 }

 #if XNN_ARCH_ARM || XNN_ARCH_ARM64
   BENCHMARK_CAPTURE(SqrtError, neonfma_nr1fma,
                     xnn_math_f32_sqrt__neonfma_nr1fma,
                     benchmark::utils::CheckNEONFMA)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, neonfma_nr2fma,
                     xnn_math_f32_sqrt__neonfma_nr2fma,
                     benchmark::utils::CheckNEONFMA)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, neonfma_nr3fma,
                     xnn_math_f32_sqrt__neonfma_nr3fma,
                     benchmark::utils::CheckNEONFMA)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, neonfma_nr2fma1adj,
                     xnn_math_f32_sqrt__neonfma_nr2fma1adj,
                     benchmark::utils::CheckNEONFMA)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, neonfma_nr1rsqrts1fma1adj,
                     xnn_math_f32_sqrt__neonfma_nr1rsqrts1fma1adj,
                     benchmark::utils::CheckNEONFMA)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);

   BENCHMARK_CAPTURE(SqrtError, neon_nr1rsqrts,
                     xnn_math_f32_sqrt__neon_nr1rsqrts,
                     benchmark::utils::CheckNEON)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, neon_nr2rsqrts,
                     xnn_math_f32_sqrt__neon_nr2rsqrts,
                     benchmark::utils::CheckNEON)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, neon_nr3rsqrts,
                     xnn_math_f32_sqrt__neon_nr3rsqrts,
                     benchmark::utils::CheckNEON)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
 #endif  // XNN_ARCH_ARM || XNN_ARCH_ARM64

 #if XNN_ARCH_X86 || XNN_ARCH_X86_64
   BENCHMARK_CAPTURE(SqrtError, avx512f_nr1fma,
                     xnn_math_f32_sqrt__avx512f_nr1fma,
                     benchmark::utils::CheckAVX512F)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, avx512f_nr2fma,
                     xnn_math_f32_sqrt__avx512f_nr2fma,
                     benchmark::utils::CheckAVX512F)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, avx512f_nr1fma1adj,
                     xnn_math_f32_sqrt__avx512f_nr1fma1adj,
                     benchmark::utils::CheckAVX512F)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);

   BENCHMARK_CAPTURE(SqrtError, fma3_nr1fma,
                     xnn_math_f32_sqrt__fma3_nr1fma,
                     benchmark::utils::CheckFMA3)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, fma3_nr2fma,
                     xnn_math_f32_sqrt__fma3_nr2fma,
                     benchmark::utils::CheckFMA3)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, fma3_nr1fma1adj,
                     xnn_math_f32_sqrt__fma3_nr1fma1adj,
                     benchmark::utils::CheckFMA3)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);

   BENCHMARK_CAPTURE(SqrtError, sse_nr1mac,
                     xnn_math_f32_sqrt__sse_nr1mac)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, sse_nr2mac,
                     xnn_math_f32_sqrt__sse_nr2mac)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
   BENCHMARK_CAPTURE(SqrtError, sse_hh1mac,
                     xnn_math_f32_sqrt__sse_hh1mac)
     ->Unit(benchmark::kMillisecond)
     ->Iterations(1);
 #endif  // XNN_ARCH_X86 || XNN_ARCH_X86_64

 #ifndef XNNPACK_BENCHMARK_NO_MAIN
 BENCHMARK_MAIN();
 #endif
	// Copyright 2019 Google LLC
	//
	// This source code is licensed under the BSD-style license found in the
	// LICENSE file in the root directory of this source tree.

	#include <algorithm>
	#include <cfloat>
	#include <cmath>
	#include <functional>
	#include <memory>
	#include <numeric>
	#include <random>
	#include <vector>

	#include <cpuinfo.h>
	#include <pthreadpool.h>

	#include <benchmark/benchmark.h>
	#include <fp16/fp16.h>

	#include "bench/utils.h"
	#include <xnnpack/AlignedAllocator.h>
	#include <xnnpack/common.h>
	#include <xnnpack/math-stubs.h>


	struct ComputeErrorContext {
	const float* input;
	const float* output;
	float* error;
	};

	static void ComputeError(
	struct ComputeErrorContext* context,
	size_t start,
	size_t range)
	{
	const float* input = context->input;
	const float* output = context->output;
	float* error = context->error;
	for (size_t i = start; i < start + range; i++) {
	const double output_ref = std::sqrt(double(input[i]));
	const double abs_error = std::abs(output_ref - double(output[i]));
	const float output_abs = std::abs(output_ref);
	const float output_ulp = fp32_from_bits(fp32_to_bits(output_abs) + 1) - output_abs;
	error[i] = float(abs_error / output_ulp);
	}
	}

	static void SqrtError(benchmark::State& state,
	xnn_f32_unary_math_function sqrt,
	benchmark::utils::IsaCheckFunction isa_check = nullptr)
	{
	if (!cpuinfo_initialize()) {
	state.SkipWithError("failed cpuinfo init");
	return;
	}
	if (isa_check && !isa_check(state)) {
	return;
	}

	const uint32_t min_input = 0x3F800000;
	const uint32_t max_input = 0x41800000;
	// Number of elements in one block of inputs/outputs.
	// Combining multiple elements in a block reduce function call overhead.
	const size_t block_size = 16384;
	// Number of elements in one parallelization tile. Worker threads process this many elements in each task.
	const size_t tile_size = 64;

	uint32_t num_threads = cpuinfo_get_cores_count();
	#if XNN_ARCH_ARM \|\| XNN_ARCH_ARM64
	// Use all cores except for the least performant cluster
	if (cpuinfo_get_clusters_count() > 1) {
	num_threads -= cpuinfo_get_cluster(cpuinfo_get_clusters_count() - 1)->core_count;
	}
	#endif // XNN_ARCH_ARM \|\| XNN_ARCH_ARM64

	std::unique_ptr<pthreadpool, decltype(&pthreadpool_destroy)> threadpool(
	pthreadpool_create(num_threads), pthreadpool_destroy);

	std::vector<float, AlignedAllocator<float, 64>> x(block_size);
	std::vector<float, AlignedAllocator<float, 64>> y(block_size);
	std::vector<float> ulp_error(block_size);
	float max_ulp_error = 0.0f;

	ComputeErrorContext context;
	context.input = x.data();
	context.output = y.data();
	context.error = ulp_error.data();
	for (auto _ : state) {
	for (uint32_t n = min_input; n < max_input; n += block_size) {
	for (uint32_t i = 0; i < block_size; i++) {
	x[i] = fp32_from_bits(std::min<uint32_t>(n + i, max_input));
	}
	std::fill(y.begin(), y.end(), std::nanf(""));

	sqrt(block_size * sizeof(float), x.data(), y.data());

	pthreadpool_parallelize_1d_tile_1d(
	threadpool.get(),
	reinterpret_cast<pthreadpool_task_1d_tile_1d_t>(ComputeError),
	static_cast<void*>(&context),
	block_size, tile_size, 0 /* flags */);

	max_ulp_error = std::accumulate(ulp_error.cbegin(), ulp_error.cend(), max_ulp_error,
	static_cast<const float& (*)(const float&, const float&)>(std::max<float>));
	}
	}

	state.counters["ULPERROR"] = benchmark::Counter(max_ulp_error);
	}

	#if XNN_ARCH_ARM \|\| XNN_ARCH_ARM64
	BENCHMARK_CAPTURE(SqrtError, neonfma_nr1fma,
	xnn_math_f32_sqrt__neonfma_nr1fma,
	benchmark::utils::CheckNEONFMA)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, neonfma_nr2fma,
	xnn_math_f32_sqrt__neonfma_nr2fma,
	benchmark::utils::CheckNEONFMA)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, neonfma_nr3fma,
	xnn_math_f32_sqrt__neonfma_nr3fma,
	benchmark::utils::CheckNEONFMA)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, neonfma_nr2fma1adj,
	xnn_math_f32_sqrt__neonfma_nr2fma1adj,
	benchmark::utils::CheckNEONFMA)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, neonfma_nr1rsqrts1fma1adj,
	xnn_math_f32_sqrt__neonfma_nr1rsqrts1fma1adj,
	benchmark::utils::CheckNEONFMA)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);

	BENCHMARK_CAPTURE(SqrtError, neon_nr1rsqrts,
	xnn_math_f32_sqrt__neon_nr1rsqrts,
	benchmark::utils::CheckNEON)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, neon_nr2rsqrts,
	xnn_math_f32_sqrt__neon_nr2rsqrts,
	benchmark::utils::CheckNEON)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, neon_nr3rsqrts,
	xnn_math_f32_sqrt__neon_nr3rsqrts,
	benchmark::utils::CheckNEON)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	#endif // XNN_ARCH_ARM \|\| XNN_ARCH_ARM64

	#if XNN_ARCH_X86 \|\| XNN_ARCH_X86_64
	BENCHMARK_CAPTURE(SqrtError, avx512f_nr1fma,
	xnn_math_f32_sqrt__avx512f_nr1fma,
	benchmark::utils::CheckAVX512F)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, avx512f_nr2fma,
	xnn_math_f32_sqrt__avx512f_nr2fma,
	benchmark::utils::CheckAVX512F)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, avx512f_nr1fma1adj,
	xnn_math_f32_sqrt__avx512f_nr1fma1adj,
	benchmark::utils::CheckAVX512F)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);

	BENCHMARK_CAPTURE(SqrtError, fma3_nr1fma,
	xnn_math_f32_sqrt__fma3_nr1fma,
	benchmark::utils::CheckFMA3)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, fma3_nr2fma,
	xnn_math_f32_sqrt__fma3_nr2fma,
	benchmark::utils::CheckFMA3)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, fma3_nr1fma1adj,
	xnn_math_f32_sqrt__fma3_nr1fma1adj,
	benchmark::utils::CheckFMA3)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);

	BENCHMARK_CAPTURE(SqrtError, sse_nr1mac,
	xnn_math_f32_sqrt__sse_nr1mac)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, sse_nr2mac,
	xnn_math_f32_sqrt__sse_nr2mac)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	BENCHMARK_CAPTURE(SqrtError, sse_hh1mac,
	xnn_math_f32_sqrt__sse_hh1mac)
	->Unit(benchmark::kMillisecond)
	->Iterations(1);
	#endif // XNN_ARCH_X86 \|\| XNN_ARCH_X86_64

	#ifndef XNNPACK_BENCHMARK_NO_MAIN
	BENCHMARK_MAIN();
	#endif