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sglang_v0.5.2/pytorch_2.8.0/third_party/XNNPACK/test/convert-nc.cc

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// Copyright 2021 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 <cassert>
#include <cmath>
#include <cstddef>
#include <cstdint>
#include <cstdlib>
#include <limits>
#include <memory>
#include <random>
#include <vector>
#include <gtest/gtest.h>
#include "xnnpack.h"
#include "xnnpack/config-types.h"
#include "xnnpack/config.h"
#include "xnnpack/internal.h"
#include "xnnpack/math.h"
#include "xnnpack/packq.h"
#include "xnnpack/buffer.h"
#include "replicable_random_device.h"
class ConvertOperatorTester {
public:
ConvertOperatorTester& channels(size_t channels) {
assert(channels != 0);
this->channels_ = channels;
return *this;
}
size_t channels() const {
return this->channels_;
}
ConvertOperatorTester& input_stride(size_t input_stride) {
assert(input_stride != 0);
this->input_stride_ = input_stride;
return *this;
}
size_t input_stride() const {
if (this->input_stride_ == 0) {
return this->channels_;
} else {
assert(this->input_stride_ >= this->channels_);
return this->input_stride_;
}
}
ConvertOperatorTester& output_stride(size_t output_stride) {
assert(output_stride != 0);
this->output_stride_ = output_stride;
return *this;
}
size_t output_stride() const {
if (this->output_stride_ == 0) {
return this->channels_;
} else {
assert(this->output_stride_ >= this->channels_);
return this->output_stride_;
}
}
ConvertOperatorTester& batch_size(size_t batch_size) {
assert(batch_size != 0);
this->batch_size_ = batch_size;
return *this;
}
size_t batch_size() const {
return this->batch_size_;
}
ConvertOperatorTester& input_scale(float input_scale) {
assert(input_scale >= 0.0f);
assert(std::isnormal(input_scale));
this->input_scale_ = input_scale;
return *this;
}
float input_scale() const {
return this->input_scale_;
}
ConvertOperatorTester& output_scale(float output_scale) {
assert(output_scale >= 0.0f);
assert(std::isnormal(output_scale));
this->output_scale_ = output_scale;
return *this;
}
float output_scale() const {
return this->output_scale_;
}
ConvertOperatorTester& zero_point(int16_t zero_point) {
this->zero_point_ = zero_point;
return *this;
}
int16_t zero_point() const {
return this->zero_point_;
}
ConvertOperatorTester& iterations(size_t iterations) {
this->iterations_ = iterations;
return *this;
}
size_t iterations() const {
return this->iterations_;
}
void TestF16toQD8() const {
xnnpack::ReplicableRandomDevice rng;
xnnpack::Buffer<float> input_float((batch_size() - 1) * input_stride() +
channels());
xnnpack::Buffer<xnn_float16> input(XNN_EXTRA_BYTES / sizeof(xnn_float16) +
(batch_size() - 1) * input_stride() +
channels());
xnnpack::Buffer<int8_t> output((batch_size() - 1) * output_stride() +
channels());
xnnpack::Buffer<xnn_quantization_params> quantization_params(
batch_size() + XNN_EXTRA_QUANTIZATION_PARAMS);
std::uniform_real_distribution<float> range_dist(-10, 10);
for (size_t iteration = 0; iteration < iterations(); iteration++) {
const float min_val = std::min(range_dist(rng), range_dist(rng));
const float max_val = std::uniform_real_distribution<float>(
min_val *
(1.0f + std::numeric_limits<uint8_t>::max() * 6.103515625e-5f),
10.0f)(rng);
std::uniform_real_distribution<float> f32dist(min_val, max_val);
std::generate(input_float.begin(), input_float.end(),
[&]() { return f32dist(rng); });
std::copy(input_float.begin(), input_float.end(), input.begin());
std::copy(input.begin(), input.begin() + channels(),
input_float.begin());
// Create, setup, run, and destroy Convert operator.
ASSERT_EQ(xnn_status_success, xnn_initialize(nullptr /* allocator */));
xnn_operator_t convert_op = nullptr;
xnn_status status = xnn_create_convert_nc_f16_qd8(0, &convert_op);
if (status == xnn_status_unsupported_hardware) {
GTEST_SKIP();
}
ASSERT_EQ(xnn_status_success, status);
ASSERT_NE(nullptr, convert_op);
// Smart pointer to automatically delete convert op.
std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)>
auto_convert_op(convert_op, xnn_delete_operator);
ASSERT_EQ(xnn_status_success,
xnn_reshape_convert_nc_f16_qd8(
convert_op, batch_size(), channels(), input_stride(),
output_stride(), /*threadpool=*/nullptr));
ASSERT_EQ(xnn_status_success, xnn_setup_convert_nc_f16_qd8(
convert_op, input.data(), output.data(),
quantization_params.data()));
ASSERT_EQ(xnn_status_success,
xnn_run_operator(convert_op, /*threadpool=*/nullptr));
// Verify results.
for (size_t i = 0; i < batch_size(); i++) {
const float* input_ptr = &input_float[i * input_stride()];
const auto minmax =
std::minmax_element(input_ptr, input_ptr + channels());
const float rmin = math_min_f32(0.0f, *minmax.first);
const float rmax = math_max_f32(0.0f, *minmax.second);
const float max_acceptable_error =
0.8f * (rmax - rmin) / std::numeric_limits<uint8_t>::max();
for (size_t c = 0; c < channels(); c++) {
float expected = input_float[i * input_stride() + c];
int8_t quantized_val = (int)output[i * output_stride() + c];
float dequantized_val =
static_cast<float>(quantized_val -
quantization_params[i].zero_point) *
quantization_params[i].scale;
ASSERT_NEAR(expected, dequantized_val, max_acceptable_error)
<< "at batch " << i << " / " << batch_size() << ", channel " << c
<< " / " << channels() << ", rmin=" << rmin << ", rmax=" << rmax
<< ", quantization_params={zero_point="
<< quantization_params[i].zero_point
<< ", scale=" << quantization_params[i].scale << "}";
}
}
}
}
void TestF32toQD8() const {
xnnpack::ReplicableRandomDevice rng;
xnnpack::Buffer<float> input(XNN_EXTRA_BYTES / sizeof(float) +
(batch_size() - 1) * input_stride() + channels());
xnnpack::Buffer<int8_t> output((batch_size() - 1) * output_stride() + channels());
xnnpack::Buffer<xnn_quantization_params> quantization_params(batch_size() + XNN_EXTRA_QUANTIZATION_PARAMS);
std::uniform_real_distribution<float> range_dist(-100000, 100000);
for (size_t iteration = 0; iteration < iterations(); iteration++) {
const float first_val = range_dist(rng);
const float second_val = range_dist(rng);
std::uniform_real_distribution<float> f32dist(std::min(first_val, second_val), std::max(first_val, second_val));
std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); });
// Create, setup, run, and destroy Convert operator.
ASSERT_EQ(xnn_status_success, xnn_initialize(nullptr /* allocator */));
xnn_operator_t convert_op = nullptr;
ASSERT_EQ(xnn_status_success,
xnn_create_convert_nc_f32_qd8(
/*flags=*/0, &convert_op));
ASSERT_NE(nullptr, convert_op);
// Smart pointer to automatically delete convert op.
std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)> auto_convert_op(convert_op, xnn_delete_operator);
ASSERT_EQ(xnn_status_success, xnn_reshape_convert_nc_f32_qd8(convert_op, batch_size(),
channels(), input_stride(), output_stride(), /*threadpool=*/nullptr));
ASSERT_EQ(xnn_status_success, xnn_setup_convert_nc_f32_qd8(convert_op, input.data(), output.data(), quantization_params.data()));
ASSERT_EQ(xnn_status_success, xnn_run_operator(convert_op, /*threadpool=*/nullptr));
// Verify results.
for (size_t i = 0; i < batch_size(); i++) {
const float* input_ptr = &input[i * input_stride()];
const auto minmax = std::minmax_element(input_ptr, input_ptr + channels());
const float rmin = math_min_f32(0.0f, *minmax.first);
const float rmax = math_max_f32(0.0f, *minmax.second);
const float max_acceptable_error = 0.5001f * (rmax - rmin) / std::numeric_limits<uint8_t>::max();
for (size_t c = 0; c < channels(); c++) {
float expected = input[i * input_stride() + c];
int8_t quantized_val = output[i * output_stride() + c];
float dequantized_val =
float((int)quantized_val - quantization_params[i].zero_point) *
quantization_params[i].scale;
EXPECT_NEAR(expected, dequantized_val, max_acceptable_error)
<< "at batch " << i << " / " << batch_size() << ", channel " << c
<< " / " << channels() << " scale "
<< quantization_params[i].scale << " zp "
<< quantization_params[i].zero_point << " int "
<< (int)quantized_val;
}
}
}
}
void TestF32toQDU8() const {
xnnpack::ReplicableRandomDevice rng;
xnnpack::Buffer<float> input(XNN_EXTRA_BYTES / sizeof(float) +
(batch_size() - 1) * input_stride() +
channels());
xnnpack::Buffer<uint8_t> output((batch_size() - 1) * output_stride() +
channels());
xnnpack::Buffer<xnn_quantization_params> quantization_params(
batch_size() + XNN_EXTRA_QUANTIZATION_PARAMS);
// std::uniform_real_distribution<float> range_dist(-100000, 100000);
// std::uniform_real_distribution<float> range_dist(-1, 1);
for (size_t iteration = 0; iteration < iterations(); iteration++) {
// const float first_val = range_dist(rng);
// const float second_val = range_dist(rng);
// std::uniform_real_distribution<float> f32dist(std::min(first_val,
// second_val), std::max(first_val, second_val));
std::uniform_real_distribution<float> f32dist(-1.f, 1.f);
std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); });
// Create, setup, run, and destroy Convert operator.
ASSERT_EQ(xnn_status_success, xnn_initialize(nullptr /* allocator */));
xnn_operator_t convert_op = nullptr;
ASSERT_EQ(xnn_status_success, xnn_create_convert_nc_f32_qdu8(
/*flags=*/0, &convert_op));
ASSERT_NE(nullptr, convert_op);
// Smart pointer to automatically delete convert op.
std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)>
auto_convert_op(convert_op, xnn_delete_operator);
ASSERT_EQ(xnn_status_success,
xnn_reshape_convert_nc_f32_qdu8(
convert_op, batch_size(), channels(), input_stride(),
output_stride(), /*threadpool=*/nullptr));
ASSERT_EQ(xnn_status_success, xnn_setup_convert_nc_f32_qdu8(
convert_op, input.data(), output.data(),
quantization_params.data()));
ASSERT_EQ(xnn_status_success,
xnn_run_operator(convert_op, /*threadpool=*/nullptr));
// Verify results.
for (size_t i = 0; i < batch_size(); i++) {
const float* input_ptr = &input[i * input_stride()];
const auto minmax =
std::minmax_element(input_ptr, input_ptr + channels());
const float rmin = math_min_f32(0.0f, *minmax.first);
const float rmax = math_max_f32(0.0f, *minmax.second);
const float max_acceptable_error =
0.5001f * (rmax - rmin) / std::numeric_limits<uint8_t>::max();
for (size_t c = 0; c < channels(); c++) {
float expected = input[i * input_stride() + c];
uint8_t quantized_val = output[i * output_stride() + c];
float dequantized_val = float(quantized_val - quantization_params[i].zero_point) * quantization_params[i].scale;
EXPECT_NEAR(expected, dequantized_val, max_acceptable_error)
<< "at batch " << i << " / " << batch_size() << ", channel " << c << " / " << channels();
}
}
}
}
void TestF32toQP8() const {
xnnpack::ReplicableRandomDevice rng;
// The parameters of the GEMM config are used as packing parameters.
const struct xnn_gemm_config* gemm_config = xnn_init_f32_gemm_nr2_config();
xnnpack::Buffer<float> input(XNN_EXTRA_BYTES / sizeof(float) +
(batch_size() - 1) * input_stride() + channels());
xnnpack::Buffer<int8_t> output(xnn_x8_packq_f32qp8_packed_size(
batch_size(), channels(), gemm_config->mr, 1 << gemm_config->log2_kr,
1 << gemm_config->log2_sr));
std::uniform_real_distribution<float> range_dist(-100000, 100000);
for (size_t iteration = 0; iteration < iterations(); iteration++) {
const float first_val = range_dist(rng);
const float second_val = range_dist(rng);
std::uniform_real_distribution<float> f32dist(
std::min(first_val, second_val), std::max(first_val, second_val));
std::generate(input.begin(), input.end(), [&]() { return f32dist(rng); });
// Create, setup, run, and destroy Convert operator.
ASSERT_EQ(xnn_status_success, xnn_initialize(nullptr /* allocator */));
xnn_operator_t convert_op = nullptr;
ASSERT_EQ(xnn_status_success,
xnn_create_convert_nc_f32_qp8(0, &convert_op));
ASSERT_NE(nullptr, convert_op);
// Smart pointer to automatically delete convert op.
std::unique_ptr<xnn_operator, decltype(&xnn_delete_operator)>
auto_convert_op(convert_op, xnn_delete_operator);
ASSERT_EQ(xnn_status_success,
xnn_reshape_convert_nc_f32_qp8(convert_op, batch_size(),
channels(), input_stride(),
/*threadpool=*/nullptr));
ASSERT_EQ(xnn_status_success,
xnn_setup_convert_nc_f32_qp8(convert_op, input.data(),
output.data()));
ASSERT_EQ(xnn_status_success,
xnn_run_operator(convert_op, /*threadpool=*/nullptr));
// Verify results.
for (size_t i = 0; i < batch_size(); i++) {
// const float* input_ptr = &input[i * input_stride()];
// const auto minmax =
// std::minmax_element(input_ptr, input_ptr + channels());
// const float rmin = math_min_f32(0.0f, *minmax.first);
// const float rmax = math_max_f32(0.0f, *minmax.second);
// const float max_acceptable_error =
// 0.5001f * (rmax - rmin) / std::numeric_limits<uint8_t>::max();
// TODO(b/340399245) - Find a way to extract individual quantized values
// from the packing?
ASSERT_TRUE(true);
}
}
}
private:
size_t batch_size_{1};
size_t channels_{1};
size_t input_stride_{0};
size_t output_stride_{0};
float input_scale_{150.0f};
float output_scale_{3.0f};
int16_t zero_point_{1};
size_t iterations_{15};
};
TEST(CONVERT_NC_F16_QD8, unit_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(1)
.channels(channels)
.iterations(3)
.TestF16toQD8();
}
}
TEST(CONVERT_NC_F16_QD8, small_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.iterations(3)
.TestF16toQD8();
}
}
TEST(CONVERT_NC_F16_QD8, small_batch_with_input_stride) {
for (size_t channels = 10; channels < 11; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.input_stride(129)
.iterations(3)
.TestF16toQD8();
}
}
TEST(CONVERT_NC_F16_QD8, small_batch_with_output_stride) {
for (size_t channels = 1; channels < 100; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.output_stride(117)
.iterations(3)
.TestF16toQD8();
}
}
TEST(CONVERT_NC_F16_QD8, small_batch_with_input_and_output_stride) {
for (size_t channels = 1; channels < 100; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.input_stride(129)
.output_stride(117)
.iterations(3)
.TestF16toQD8();
}
}
TEST(CONVERT_NC_F32_QD8, unit_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(1)
.channels(channels)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QD8, small_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QD8, small_batch_with_input_stride) {
for (size_t channels = 10; channels < 11; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.input_stride(129)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QD8, small_batch_with_output_stride) {
for (size_t channels = 1; channels < 100; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.output_stride(117)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QD8, small_batch_with_input_and_output_stride) {
for (size_t channels = 1; channels < 100; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.input_stride(129)
.output_stride(117)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QP8, unit_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(1)
.channels(channels)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QP8, small_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QP8, small_batch_with_input_stride) {
for (size_t channels = 10; channels < 11; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.input_stride(129)
.iterations(3)
.TestF32toQD8();
}
}
TEST(CONVERT_NC_F32_QDU8, unit_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(1)
.channels(channels)
.iterations(3)
.TestF32toQDU8();
}
}
TEST(CONVERT_NC_F32_QDU8, small_batch) {
for (size_t channels = 1; channels < 100; channels++) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.iterations(3)
.TestF32toQDU8();
}
}
TEST(CONVERT_NC_F32_QDU8, small_batch_with_input_stride) {
for (size_t channels = 10; channels < 11; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.input_stride(129)
.iterations(3)
.TestF32toQDU8();
}
}
TEST(CONVERT_NC_F32_QDU8, small_batch_with_output_stride) {
for (size_t channels = 1; channels < 100; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.output_stride(117)
.iterations(3)
.TestF32toQDU8();
}
}
TEST(CONVERT_NC_F32_QDU8, small_batch_with_input_and_output_stride) {
for (size_t channels = 1; channels < 100; channels += 15) {
ConvertOperatorTester()
.batch_size(3)
.channels(channels)
.input_stride(129)
.output_stride(117)
.iterations(3)
.TestF32toQDU8();
}
}
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