bench/f32-conv-hwc2spchw.cc - platform/external/XNNPACK - Git at Google

 // 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 <random>
 #include <vector>

 #include <cpuinfo.h>

 #include <benchmark/benchmark.h>
 #include "bench/dconv.h"
 #include "bench/utils.h"
 #include <xnnpack/AlignedAllocator.h>
 #include <xnnpack/common.h>
 #include <xnnpack/conv.h>
 #include <xnnpack/pack.h>
 #include <xnnpack/params-init.h>
 #include <xnnpack/params.h>


 static void DConvHWC2SpCHW3X3S2P1Benchmark(benchmark::State& state,
   xnn_f32_conv_hwc2spchw_ukernel_function conv,
   uint32_t output_channels_tile)
 {
   if (!cpuinfo_initialize()) {
     state.SkipWithError("cpuinfo initialization failed");
   }

   const size_t input_height = state.range(0);
   const size_t input_width = state.range(1);
   const size_t output_channels = state.range(2);

   std::random_device random_device;
   auto rng = std::mt19937(random_device());
   auto f32rng = std::bind(std::uniform_real_distribution<float>(0.0f, 1.0f), rng);

   const size_t input_channels = 3;
   const size_t kernel_size = 3;
   const size_t padding = 1;
   const size_t subsampling = 2;

   const size_t output_height = (input_height + 2 * padding - kernel_size) / subsampling + 1;
   const size_t output_width = (input_width + 2 * padding - kernel_size) / subsampling + 1;

   std::vector<float> input(input_height * input_width * input_channels + XNN_EXTRA_BYTES / sizeof(float));
   std::generate(input.begin(), input.end(), std::ref(f32rng));
   std::vector<float> kernel(output_channels * kernel_size * kernel_size * input_channels);
   std::generate(kernel.begin(), kernel.end(), std::ref(f32rng));
   std::vector<float> bias(output_channels);
   std::generate(bias.begin(), bias.end(), std::ref(f32rng));

   std::vector<float, AlignedAllocator<float, 32>> zero(input_channels * input_width + XNN_EXTRA_BYTES / sizeof(float));

   const size_t weights_elements = (kernel_size * kernel_size * input_channels + 1) *
     benchmark::utils::RoundUp<size_t>(output_channels, output_channels_tile);
   const size_t output_elements = output_height * output_width * output_channels;
   const size_t num_buffers = 1 +
     benchmark::utils::DivideRoundUp<size_t>(benchmark::utils::GetMaxCacheSize(),
       sizeof(float) * (weights_elements + output_elements));

   std::vector<float, AlignedAllocator<float, 32>> packed_weights(weights_elements * num_buffers);
   std::fill(packed_weights.begin(), packed_weights.end(), 0.0f);
   xnn_pack_f32_dconv_oki_w(
     output_channels, input_channels, output_channels_tile,
     kernel_size /* kernel height */, kernel_size /* kernel width */,
     kernel.data(), bias.data(), packed_weights.data());
   for (size_t n = 1; n < num_buffers; n++) {
     std::copy(packed_weights.cbegin(),
       packed_weights.cbegin() + weights_elements,
       packed_weights.begin() + n * weights_elements);
   }

   std::vector<float> output(output_elements * num_buffers);
   std::fill(output.begin(), output.end(), std::nanf(""));

   xnn_f32_output_params output_params =
     xnn_init_f32_output_params(-std::numeric_limits<float>::infinity(), +std::numeric_limits<float>::infinity());

   size_t buffer_index = 0;
   for (auto _ : state) {
     state.PauseTiming();
     benchmark::utils::PrefetchToL1(input.data(), input.size() * sizeof(float));
     buffer_index = (buffer_index + 1) % num_buffers;
     state.ResumeTiming();

     conv(
       input_height, input_width,
       0 /* output_y_start */, output_height /* output_y_end */,
       input.data(), zero.data(),
       packed_weights.data() + buffer_index * weights_elements,
       output.data() + buffer_index * output_elements,
       padding, output_channels,
       output_channels * output_width * sizeof(float),
       output_channels * sizeof(float),
       &output_params);
   }

   state.counters["Freq"] = benchmark::utils::GetCurrentCpuFrequency();
   state.counters["FLOPS"] = benchmark::Counter(
     uint64_t(state.iterations()) * 2 *
       output_height * output_width *
       input_channels * output_channels *
       kernel_size * kernel_size,
     benchmark::Counter::kIsRate);
 }

 #if XNN_ARCH_ARM64
   static void f32_conv_hwc2spchw_3x3s2p1c3x4__neonfma_2x2(benchmark::State& state, const char* net) {
     DConvHWC2SpCHW3X3S2P1Benchmark(state, xnn_f32_conv_hwc2spchw_ukernel_3x3s2p1c3x4__neonfma_2x2, 4);
   }

   BENCHMARK_DCONV(f32_conv_hwc2spchw_3x3s2p1c3x4__neonfma_2x2);
 #endif
   static void f32_conv_hwc2spchw_3x3s2p1c3x4__scalar_1x1(benchmark::State& state, const char* net) {
     DConvHWC2SpCHW3X3S2P1Benchmark(state, xnn_f32_conv_hwc2spchw_ukernel_3x3s2p1c3x4__scalar_1x1, 4);
   }

   BENCHMARK_DCONV(f32_conv_hwc2spchw_3x3s2p1c3x4__scalar_1x1);

 #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 <random>
	#include <vector>

	#include <cpuinfo.h>

	#include <benchmark/benchmark.h>
	#include "bench/dconv.h"
	#include "bench/utils.h"
	#include <xnnpack/AlignedAllocator.h>
	#include <xnnpack/common.h>
	#include <xnnpack/conv.h>
	#include <xnnpack/pack.h>
	#include <xnnpack/params-init.h>
	#include <xnnpack/params.h>


	static void DConvHWC2SpCHW3X3S2P1Benchmark(benchmark::State& state,
	xnn_f32_conv_hwc2spchw_ukernel_function conv,
	uint32_t output_channels_tile)
	{
	if (!cpuinfo_initialize()) {
	state.SkipWithError("cpuinfo initialization failed");
	}

	const size_t input_height = state.range(0);
	const size_t input_width = state.range(1);
	const size_t output_channels = state.range(2);

	std::random_device random_device;
	auto rng = std::mt19937(random_device());
	auto f32rng = std::bind(std::uniform_real_distribution<float>(0.0f, 1.0f), rng);

	const size_t input_channels = 3;
	const size_t kernel_size = 3;
	const size_t padding = 1;
	const size_t subsampling = 2;

	const size_t output_height = (input_height + 2 * padding - kernel_size) / subsampling + 1;
	const size_t output_width = (input_width + 2 * padding - kernel_size) / subsampling + 1;

	std::vector<float> input(input_height * input_width * input_channels + XNN_EXTRA_BYTES / sizeof(float));
	std::generate(input.begin(), input.end(), std::ref(f32rng));
	std::vector<float> kernel(output_channels * kernel_size * kernel_size * input_channels);
	std::generate(kernel.begin(), kernel.end(), std::ref(f32rng));
	std::vector<float> bias(output_channels);
	std::generate(bias.begin(), bias.end(), std::ref(f32rng));

	std::vector<float, AlignedAllocator<float, 32>> zero(input_channels * input_width + XNN_EXTRA_BYTES / sizeof(float));

	const size_t weights_elements = (kernel_size * kernel_size * input_channels + 1) *
	benchmark::utils::RoundUp<size_t>(output_channels, output_channels_tile);
	const size_t output_elements = output_height * output_width * output_channels;
	const size_t num_buffers = 1 +
	benchmark::utils::DivideRoundUp<size_t>(benchmark::utils::GetMaxCacheSize(),
	sizeof(float) * (weights_elements + output_elements));

	std::vector<float, AlignedAllocator<float, 32>> packed_weights(weights_elements * num_buffers);
	std::fill(packed_weights.begin(), packed_weights.end(), 0.0f);
	xnn_pack_f32_dconv_oki_w(
	output_channels, input_channels, output_channels_tile,
	kernel_size /* kernel height /, kernel_size / kernel width */,
	kernel.data(), bias.data(), packed_weights.data());
	for (size_t n = 1; n < num_buffers; n++) {
	std::copy(packed_weights.cbegin(),
	packed_weights.cbegin() + weights_elements,
	packed_weights.begin() + n * weights_elements);
	}

	std::vector<float> output(output_elements * num_buffers);
	std::fill(output.begin(), output.end(), std::nanf(""));

	xnn_f32_output_params output_params =
	xnn_init_f32_output_params(-std::numeric_limits<float>::infinity(), +std::numeric_limits<float>::infinity());

	size_t buffer_index = 0;
	for (auto _ : state) {
	state.PauseTiming();
	benchmark::utils::PrefetchToL1(input.data(), input.size() * sizeof(float));
	buffer_index = (buffer_index + 1) % num_buffers;
	state.ResumeTiming();

	conv(
	input_height, input_width,
	0 /* output_y_start /, output_height / output_y_end */,
	input.data(), zero.data(),
	packed_weights.data() + buffer_index * weights_elements,
	output.data() + buffer_index * output_elements,
	padding, output_channels,
	output_channels * output_width * sizeof(float),
	output_channels * sizeof(float),
	&output_params);
	}

	state.counters["Freq"] = benchmark::utils::GetCurrentCpuFrequency();
	state.counters["FLOPS"] = benchmark::Counter(
	uint64_t(state.iterations()) * 2 *
	output_height * output_width *
	input_channels * output_channels *
	kernel_size * kernel_size,
	benchmark::Counter::kIsRate);
	}

	#if XNN_ARCH_ARM64
	static void f32_conv_hwc2spchw_3x3s2p1c3x4__neonfma_2x2(benchmark::State& state, const char* net) {
	DConvHWC2SpCHW3X3S2P1Benchmark(state, xnn_f32_conv_hwc2spchw_ukernel_3x3s2p1c3x4__neonfma_2x2, 4);
	}

	BENCHMARK_DCONV(f32_conv_hwc2spchw_3x3s2p1c3x4__neonfma_2x2);
	#endif
	static void f32_conv_hwc2spchw_3x3s2p1c3x4__scalar_1x1(benchmark::State& state, const char* net) {
	DConvHWC2SpCHW3X3S2P1Benchmark(state, xnn_f32_conv_hwc2spchw_ukernel_3x3s2p1c3x4__scalar_1x1, 4);
	}

	BENCHMARK_DCONV(f32_conv_hwc2spchw_3x3s2p1c3x4__scalar_1x1);

	#ifndef XNNPACK_BENCHMARK_NO_MAIN
	BENCHMARK_MAIN();
	#endif