common/QuantUtils.cpp - platform/packages/modules/NeuralNetworks - Git at Google

 #include "QuantUtils.h"

 #include <algorithm>
 #include <limits>
 #include <memory>

 namespace android {
 namespace nn {

 void ApplyLayerNorm(const int16_t* input, const int16_t* layer_norm_weights, const int32_t* bias,
                     int32_t layer_norm_scale_a, int32_t layer_norm_scale_b, int32_t variance_limit,
                     int n_batch, int n_input, int16_t* output) {
     static const int kOverflowGuard = 1 << 20;
     for (int i = 0; i < n_batch; ++i) {
         int64_t sum = 0;
         int64_t sum_sq = 0;
         for (int j = 0; j < n_input; ++j) {
             const int32_t index = i * n_input + j;
             int32_t val = static_cast<int32_t>(input[index]);
             sum += val;
             sum_sq += val * val;
         }
         int32_t mean = static_cast<int32_t>(static_cast<int64_t>(sum) * 1024 / n_input);
         // TODO(jianlijianli): Avoids overflow but only works for POT n_input.
         int32_t temp = kOverflowGuard / n_input;
         int64_t variance = sum_sq * temp - static_cast<int64_t>(mean) * static_cast<int64_t>(mean);
         int32_t variance2 = static_cast<int32_t>(variance / kOverflowGuard);
         if (variance2 < 1) {
             variance2 = variance_limit;
         }
         int32_t stddev_inverse_a;
         int stddev_inverse_b;
         GetInvSqrtQuantizedMultiplierExp(variance2, /*reverse_shift*/ -1, &stddev_inverse_a,
                                          &stddev_inverse_b);

         for (int j = 0; j < n_input; ++j) {
             const int32_t index = i * n_input + j;
             int32_t val = static_cast<int32_t>(input[index]);
             int32_t shifted = 1024 * val - mean;
             int32_t rescaled =
                     MultiplyByQuantizedMultiplier(shifted, stddev_inverse_a, stddev_inverse_b);
             // TODO(jianlijianli): Saturate this.
             int64_t val3 = rescaled * layer_norm_weights[j] + bias[j];
             int32_t val4 = static_cast<int32_t>((val3 > 0 ? val3 + 512 : val3 - 512) / 1024);
             int32_t val5 = MultiplyByQuantizedMultiplier(val4, layer_norm_scale_a,
                                                          layer_norm_scale_b + 12);
             val5 = std::min(std::max(INT16_MIN, val5), INT16_MAX);
             output[index] = static_cast<int16_t>(val5);
         }
     }
 }

 void MatrixScalarMultiplyAccumulate(const int8_t* matrix, int32_t scalar, int32_t n_row,
                                     int32_t n_col, int32_t* output) {
     for (int i = 0; i < n_row; ++i) {
         int32_t row_sum = 0;
         for (int j = 0; j < n_col; ++j) {
             row_sum += *matrix++;
         }
         output[i] += row_sum * scalar;
     }
 }

 bool PrecomputeZeroPointTimesWeightWithBias(int32_t zero_point, const int8_t* weight_tensor,
                                             const Shape& weight_shape, const int32_t* bias_tensor,
                                             std::unique_ptr<int32_t[]>* output) {
     if (weight_tensor == nullptr) {
         return true;
     }

     NN_RET_CHECK_EQ(weight_shape.dimensions.size(), 2u);
     const int row = weight_shape.dimensions[0];
     const int col = weight_shape.dimensions[1];
     *output = std::make_unique<int32_t[]>(row);
     if (bias_tensor == nullptr) {
         memset(output->get(), 0, row * sizeof(int32_t));
     } else {
         memcpy(output->get(), bias_tensor, row * sizeof(int32_t));
     }
     if (zero_point != 0) {
         MatrixScalarMultiplyAccumulate(weight_tensor, zero_point, row, col, output->get());
     }
     return true;
 }

 void ApplySigmoid(const int16_t* input, int32_t n_batch, int32_t n_input, int16_t* output) {
     for (int batch = 0; batch < n_batch; ++batch) {
         for (int c = 0; c < n_input; c++) {
             using F3 = gemmlowp::FixedPoint<std::int16_t, 3>;
             using F0 = gemmlowp::FixedPoint<std::int16_t, 0>;
             const int index = batch * n_input + c;
             F3 sigmoid_input = F3::FromRaw(input[index]);
             F0 sigmoid_output = gemmlowp::logistic(sigmoid_input);
             output[index] = sigmoid_output.raw();
         }
     }
 }

 void CwiseMul(const int16_t* input_1, const int16_t* input_2, int n_batch, int n_input, int shift,
               int16_t* output) {
     for (int batch = 0; batch < n_batch; ++batch) {
         for (int i = 0; i < n_input; ++i) {
             const int index = batch * n_input + i;
             const int16_t a = input_1[index];
             const int16_t b = input_2[index];
             const int32_t value = static_cast<int32_t>(a) * static_cast<int32_t>(b);
             output[index] = static_cast<int16_t>(gemmlowp::RoundingDivideByPOT(value, shift));
         }
     }
 }

 void CwiseMul(const int16_t* input_1, const int16_t* input_2, int32_t multiplier, int32_t shift,
               int32_t n_batch, int32_t n_input, int32_t output_zp, int8_t* output) {
     for (int batch = 0; batch < n_batch; ++batch) {
         for (int i = 0; i < n_input; ++i) {
             const int index = batch * n_input + i;
             const int16_t a = input_1[index];
             const int16_t b = input_2[index];
             int32_t value = static_cast<int32_t>(a) * static_cast<int32_t>(b);
             value = MultiplyByQuantizedMultiplier(value, multiplier, shift);
             value -= output_zp;
             value = std::min(std::max(-128, value), 127);

             output[index] = static_cast<int8_t>(value);
         }
     }
 }

 bool CheckedLog2(const float x, int* log2_result) {
     const float x_log2 = std::log(x) * (1.0f / std::log(2.0f));
     const float x_log2_rounded = std::round(x_log2);
     const float x_log2_fracpart = x_log2 - x_log2_rounded;

     *log2_result = static_cast<int>(x_log2_rounded);
     return std::abs(x_log2_fracpart) < 1e-3;
 }

 void CwiseAdd(const int16_t* input_1, const int16_t* input_2, int n_batch, int n_input,
               int16_t* output) {
     for (int batch = 0; batch < n_batch; ++batch) {
         for (int i = 0; i < n_input; ++i) {
             const int index = batch * n_input + i;
             int32_t sum = input_1[index] + input_2[index];
             const int32_t sum_clamped = std::min(INT16_MAX, std::max(INT16_MIN, sum));
             output[index] = static_cast<int16_t>(sum_clamped);
         }
     }
 }

 void CwiseClipping(int16_t* input, const int16_t clipping_value, int32_t n_batch, int32_t n_input) {
     for (int batch = 0; batch < n_batch; ++batch) {
         for (int i = 0; i < n_input; ++i) {
             const int index = batch * n_input + i;
             if (input[index] > clipping_value) {
                 input[index] = clipping_value;
             }
             if (input[index] < -clipping_value) {
                 input[index] = -clipping_value;
             }
         }
     }
 }

 void CwiseClipping(int8_t* input, const int8_t clipping_value, int32_t n_batch, int32_t n_input) {
     for (int batch = 0; batch < n_batch; ++batch) {
         for (int i = 0; i < n_input; ++i) {
             const int index = batch * n_input + i;
             if (input[index] > clipping_value) {
                 input[index] = clipping_value;
             }
             if (input[index] < -clipping_value) {
                 input[index] = -clipping_value;
             }
         }
     }
 }

 void VectorBatchVectorCwiseProductAccumulate(const int16_t* vector, int v_size,
                                              const int16_t* batch_vector, int n_batch,
                                              int32_t multiplier, int shift, int16_t* result) {
     for (int b = 0; b < n_batch; b++) {
         for (int v = 0; v < v_size; v++) {
             int32_t prod = vector[v] * *batch_vector++;
             prod = MultiplyByQuantizedMultiplier(prod, multiplier, shift);
             int32_t output = prod + *result;
             output = std::max(std::min(32767, output), -32768);
             *result++ = output;
         }
     }
 }

 }  // namespace nn
 }  // namespace android
	#include "QuantUtils.h"

	#include <algorithm>
	#include <limits>
	#include <memory>

	namespace android {
	namespace nn {

	void ApplyLayerNorm(const int16_t* input, const int16_t* layer_norm_weights, const int32_t* bias,
	int32_t layer_norm_scale_a, int32_t layer_norm_scale_b, int32_t variance_limit,
	int n_batch, int n_input, int16_t* output) {
	static const int kOverflowGuard = 1 << 20;
	for (int i = 0; i < n_batch; ++i) {
	int64_t sum = 0;
	int64_t sum_sq = 0;
	for (int j = 0; j < n_input; ++j) {
	const int32_t index = i * n_input + j;
	int32_t val = static_cast<int32_t>(input[index]);
	sum += val;
	sum_sq += val * val;
	}
	int32_t mean = static_cast<int32_t>(static_cast<int64_t>(sum) * 1024 / n_input);
	// TODO(jianlijianli): Avoids overflow but only works for POT n_input.
	int32_t temp = kOverflowGuard / n_input;
	int64_t variance = sum_sq * temp - static_cast<int64_t>(mean) * static_cast<int64_t>(mean);
	int32_t variance2 = static_cast<int32_t>(variance / kOverflowGuard);
	if (variance2 < 1) {
	variance2 = variance_limit;
	}
	int32_t stddev_inverse_a;
	int stddev_inverse_b;
	GetInvSqrtQuantizedMultiplierExp(variance2, /reverse_shift/ -1, &stddev_inverse_a,
	&stddev_inverse_b);

	for (int j = 0; j < n_input; ++j) {
	const int32_t index = i * n_input + j;
	int32_t val = static_cast<int32_t>(input[index]);
	int32_t shifted = 1024 * val - mean;
	int32_t rescaled =
	MultiplyByQuantizedMultiplier(shifted, stddev_inverse_a, stddev_inverse_b);
	// TODO(jianlijianli): Saturate this.
	int64_t val3 = rescaled * layer_norm_weights[j] + bias[j];
	int32_t val4 = static_cast<int32_t>((val3 > 0 ? val3 + 512 : val3 - 512) / 1024);
	int32_t val5 = MultiplyByQuantizedMultiplier(val4, layer_norm_scale_a,
	layer_norm_scale_b + 12);
	val5 = std::min(std::max(INT16_MIN, val5), INT16_MAX);
	output[index] = static_cast<int16_t>(val5);
	}
	}
	}

	void MatrixScalarMultiplyAccumulate(const int8_t* matrix, int32_t scalar, int32_t n_row,
	int32_t n_col, int32_t* output) {
	for (int i = 0; i < n_row; ++i) {
	int32_t row_sum = 0;
	for (int j = 0; j < n_col; ++j) {
	row_sum += *matrix++;
	}
	output[i] += row_sum * scalar;
	}
	}

	bool PrecomputeZeroPointTimesWeightWithBias(int32_t zero_point, const int8_t* weight_tensor,
	const Shape& weight_shape, const int32_t* bias_tensor,
	std::unique_ptr<int32_t[]>* output) {
	if (weight_tensor == nullptr) {
	return true;
	}

	NN_RET_CHECK_EQ(weight_shape.dimensions.size(), 2u);
	const int row = weight_shape.dimensions[0];
	const int col = weight_shape.dimensions[1];
	*output = std::make_unique<int32_t[]>(row);
	if (bias_tensor == nullptr) {
	memset(output->get(), 0, row * sizeof(int32_t));
	} else {
	memcpy(output->get(), bias_tensor, row * sizeof(int32_t));
	}
	if (zero_point != 0) {
	MatrixScalarMultiplyAccumulate(weight_tensor, zero_point, row, col, output->get());
	}
	return true;
	}

	void ApplySigmoid(const int16_t* input, int32_t n_batch, int32_t n_input, int16_t* output) {
	for (int batch = 0; batch < n_batch; ++batch) {
	for (int c = 0; c < n_input; c++) {
	using F3 = gemmlowp::FixedPoint<std::int16_t, 3>;
	using F0 = gemmlowp::FixedPoint<std::int16_t, 0>;
	const int index = batch * n_input + c;
	F3 sigmoid_input = F3::FromRaw(input[index]);
	F0 sigmoid_output = gemmlowp::logistic(sigmoid_input);
	output[index] = sigmoid_output.raw();
	}
	}
	}

	void CwiseMul(const int16_t* input_1, const int16_t* input_2, int n_batch, int n_input, int shift,
	int16_t* output) {
	for (int batch = 0; batch < n_batch; ++batch) {
	for (int i = 0; i < n_input; ++i) {
	const int index = batch * n_input + i;
	const int16_t a = input_1[index];
	const int16_t b = input_2[index];
	const int32_t value = static_cast<int32_t>(a) * static_cast<int32_t>(b);
	output[index] = static_cast<int16_t>(gemmlowp::RoundingDivideByPOT(value, shift));
	}
	}
	}

	void CwiseMul(const int16_t* input_1, const int16_t* input_2, int32_t multiplier, int32_t shift,
	int32_t n_batch, int32_t n_input, int32_t output_zp, int8_t* output) {
	for (int batch = 0; batch < n_batch; ++batch) {
	for (int i = 0; i < n_input; ++i) {
	const int index = batch * n_input + i;
	const int16_t a = input_1[index];
	const int16_t b = input_2[index];
	int32_t value = static_cast<int32_t>(a) * static_cast<int32_t>(b);
	value = MultiplyByQuantizedMultiplier(value, multiplier, shift);
	value -= output_zp;
	value = std::min(std::max(-128, value), 127);

	output[index] = static_cast<int8_t>(value);
	}
	}
	}

	bool CheckedLog2(const float x, int* log2_result) {
	const float x_log2 = std::log(x) * (1.0f / std::log(2.0f));
	const float x_log2_rounded = std::round(x_log2);
	const float x_log2_fracpart = x_log2 - x_log2_rounded;

	*log2_result = static_cast<int>(x_log2_rounded);
	return std::abs(x_log2_fracpart) < 1e-3;
	}

	void CwiseAdd(const int16_t* input_1, const int16_t* input_2, int n_batch, int n_input,
	int16_t* output) {
	for (int batch = 0; batch < n_batch; ++batch) {
	for (int i = 0; i < n_input; ++i) {
	const int index = batch * n_input + i;
	int32_t sum = input_1[index] + input_2[index];
	const int32_t sum_clamped = std::min(INT16_MAX, std::max(INT16_MIN, sum));
	output[index] = static_cast<int16_t>(sum_clamped);
	}
	}
	}

	void CwiseClipping(int16_t* input, const int16_t clipping_value, int32_t n_batch, int32_t n_input) {
	for (int batch = 0; batch < n_batch; ++batch) {
	for (int i = 0; i < n_input; ++i) {
	const int index = batch * n_input + i;
	if (input[index] > clipping_value) {
	input[index] = clipping_value;
	}
	if (input[index] < -clipping_value) {
	input[index] = -clipping_value;
	}
	}
	}
	}

	void CwiseClipping(int8_t* input, const int8_t clipping_value, int32_t n_batch, int32_t n_input) {
	for (int batch = 0; batch < n_batch; ++batch) {
	for (int i = 0; i < n_input; ++i) {
	const int index = batch * n_input + i;
	if (input[index] > clipping_value) {
	input[index] = clipping_value;
	}
	if (input[index] < -clipping_value) {
	input[index] = -clipping_value;
	}
	}
	}
	}

	void VectorBatchVectorCwiseProductAccumulate(const int16_t* vector, int v_size,
	const int16_t* batch_vector, int n_batch,
	int32_t multiplier, int shift, int16_t* result) {
	for (int b = 0; b < n_batch; b++) {
	for (int v = 0; v < v_size; v++) {
	int32_t prod = vector[v] * *batch_vector++;
	prod = MultiplyByQuantizedMultiplier(prod, multiplier, shift);
	int32_t output = prod + *result;
	output = std::max(std::min(32767, output), -32768);
	*result++ = output;
	}
	}
	}

	} // namespace nn
	} // namespace android