av1/encoder/ml.c - aom - Git at Google

 /*
  * Copyright (c) 2016, Alliance for Open Media. All rights reserved
  *
  * This source code is subject to the terms of the BSD 2 Clause License and
  * the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
  * was not distributed with this source code in the LICENSE file, you can
  * obtain it at www.aomedia.org/license/software. If the Alliance for Open
  * Media Patent License 1.0 was not distributed with this source code in the
  * PATENTS file, you can obtain it at www.aomedia.org/license/patent.
  */

 #include <assert.h>
 #include <math.h>

 #include "aom_dsp/aom_dsp_common.h"
 #include "av1/encoder/ml.h"

 void av1_nn_output_prec_reduce(float *const output, int num_output) {
   const int prec_bits = 11;
   const int prec = 1 << prec_bits;
   const float inv_prec = (float)(1.0 / prec);
   for (int i = 0; i < num_output; i++) {
     output[i] = ((int)(output[i] * prec + 0.5)) * inv_prec;
   }
 }

 // Calculate prediction based on the given input features and neural net config.
 // Assume there are no more than NN_MAX_NODES_PER_LAYER nodes in each hidden
 // layer.
 void av1_nn_predict_c(const float *input_nodes,
                       const NN_CONFIG *const nn_config, int reduce_prec,
                       float *const output) {
   int num_input_nodes = nn_config->num_inputs;
   int buf_index = 0;
   float buf[2][NN_MAX_NODES_PER_LAYER];

   // Propagate hidden layers.
   const int num_layers = nn_config->num_hidden_layers;
   assert(num_layers <= NN_MAX_HIDDEN_LAYERS);
   for (int layer = 0; layer < num_layers; ++layer) {
     const float *layer_weights = nn_config->weights[layer];
     const float *layer_bias = nn_config->bias[layer];
     float *output_nodes = buf[buf_index];
     const int num_output_nodes = nn_config->num_hidden_nodes[layer];
     assert(num_output_nodes < NN_MAX_NODES_PER_LAYER);
     for (int node = 0; node < num_output_nodes; ++node) {
       float val = layer_bias[node];
       for (int i = 0; i < num_input_nodes; ++i)
         val += layer_weights[node * num_input_nodes + i] * input_nodes[i];
       // ReLU as activation function.
       val = val > 0.0f ? val : 0.0f;  // Could use AOMMAX().
       output_nodes[node] = val;
     }
     num_input_nodes = num_output_nodes;
     input_nodes = output_nodes;
     buf_index = 1 - buf_index;
   }

   // Final output layer.
   const float *layer_weights = nn_config->weights[num_layers];
   const float *layer_bias = nn_config->bias[num_layers];
   for (int node = 0; node < nn_config->num_outputs; ++node) {
     float val = layer_bias[node];
     for (int i = 0; i < num_input_nodes; ++i)
       val += layer_weights[node * num_input_nodes + i] * input_nodes[i];
     output[node] = val;
   }
   if (reduce_prec) av1_nn_output_prec_reduce(output, nn_config->num_outputs);
 }

 #if CONFIG_NN_V2
 // Applies the ReLu activation to one fc layer
 // output[i] = Max(input[i],0.0f)
 static float *nn_relu(const float *input, FC_LAYER *layer) {
   for (int i = 0; i < layer->num_outputs; ++i) {
     layer->output[i] = AOMMAX(input[i], 0.0f);
   }

   return layer->output;
 }

 // Applies the Sigmoid activation to one fc layer
 // output[i] = 1/(1+exp(input[i]))
 static float *nn_sigmoid(const float *input, FC_LAYER *layer) {
   for (int i = 0; i < layer->num_outputs; ++i) {
     const float tmp = AOMMIN(AOMMAX(input[i], -10.0f), 10.0f);
     layer->output[i] = 1.0f / (1.0f + expf(-tmp));
   }

   return layer->output;
 }

 // Forward prediction in one fc layer, used in function av1_nn_predict_V2
 static float *nn_fc_forward(const float *input, FC_LAYER *layer) {
   const float *weights = layer->weights;
   const float *bias = layer->bias;
   assert(layer->num_outputs < NN_MAX_NODES_PER_LAYER);
   // fc
   for (int node = 0; node < layer->num_outputs; ++node) {
     float val = bias[node];
     for (int i = 0; i < layer->num_inputs; ++i) val += weights[i] * input[i];
     layer->output[node] = val;
     weights += layer->num_inputs;
   }

   // activation
   switch (layer->activation) {
     case NONE: return layer->output;
     case RELU: return nn_relu(layer->output, layer);
     case SIGMOID: return nn_sigmoid(layer->output, layer);
     case SOFTSIGN:
       assert(0 && "Softsign has not been supported in NN.");  // TO DO
       return NULL;
     default:
       assert(0 && "Unknown activation");  // Unknown activation
       return NULL;
   }
 }

 void av1_nn_predict_v2(const float *feature, NN_CONFIG_V2 *nn_config,
                        int reduce_prec, float *output) {
   const float *input_nodes = feature;

   // Propagate the layers.
   const int num_layers = nn_config->num_hidden_layers;
   assert(num_layers <= NN_MAX_HIDDEN_LAYERS);
   for (int i = 0; i < num_layers; ++i) {
     input_nodes = nn_fc_forward(input_nodes, nn_config->layer + i);
     assert(nn_config->layer[i + 1].num_inputs ==
            nn_config->layer[i].num_outputs);
   }

   // Final layer
   input_nodes = nn_fc_forward(input_nodes, nn_config->layer + num_layers);
   assert(nn_config->layer[num_layers].num_outputs == nn_config->num_logits);
   // Copy the final layer output
   memcpy(output, input_nodes, sizeof(*input_nodes) * nn_config->num_logits);
   if (reduce_prec) av1_nn_output_prec_reduce(output, nn_config->num_logits);
 }
 #endif  // CONFIG_NN_V2

 void av1_nn_softmax(const float *input, float *output, int n) {
   // Softmax function is invariant to adding the same constant
   // to all input values, so we subtract the maximum input to avoid
   // possible overflow.
   float max_inp = input[0];
   for (int i = 1; i < n; i++) max_inp = AOMMAX(max_inp, input[i]);
   float sum_out = 0.0f;
   for (int i = 0; i < n; i++) {
     // Clamp to range [-10.0, 0.0] to prevent FE_UNDERFLOW errors.
     const float normalized_input = AOMMAX(input[i] - max_inp, -10.0f);
     output[i] = (float)exp(normalized_input);
     sum_out += output[i];
   }
   for (int i = 0; i < n; i++) output[i] /= sum_out;
 }
	/*
	* Copyright (c) 2016, Alliance for Open Media. All rights reserved
	*
	* This source code is subject to the terms of the BSD 2 Clause License and
	* the Alliance for Open Media Patent License 1.0. If the BSD 2 Clause License
	* was not distributed with this source code in the LICENSE file, you can
	* obtain it at www.aomedia.org/license/software. If the Alliance for Open
	* Media Patent License 1.0 was not distributed with this source code in the
	* PATENTS file, you can obtain it at www.aomedia.org/license/patent.
	*/

	#include <assert.h>
	#include <math.h>

	#include "aom_dsp/aom_dsp_common.h"
	#include "av1/encoder/ml.h"

	void av1_nn_output_prec_reduce(float *const output, int num_output) {
	const int prec_bits = 11;
	const int prec = 1 << prec_bits;
	const float inv_prec = (float)(1.0 / prec);
	for (int i = 0; i < num_output; i++) {
	output[i] = ((int)(output[i] * prec + 0.5)) * inv_prec;
	}
	}

	// Calculate prediction based on the given input features and neural net config.
	// Assume there are no more than NN_MAX_NODES_PER_LAYER nodes in each hidden
	// layer.
	void av1_nn_predict_c(const float *input_nodes,
	const NN_CONFIG *const nn_config, int reduce_prec,
	float *const output) {
	int num_input_nodes = nn_config->num_inputs;
	int buf_index = 0;
	float buf[2][NN_MAX_NODES_PER_LAYER];

	// Propagate hidden layers.
	const int num_layers = nn_config->num_hidden_layers;
	assert(num_layers <= NN_MAX_HIDDEN_LAYERS);
	for (int layer = 0; layer < num_layers; ++layer) {
	const float *layer_weights = nn_config->weights[layer];
	const float *layer_bias = nn_config->bias[layer];
	float *output_nodes = buf[buf_index];
	const int num_output_nodes = nn_config->num_hidden_nodes[layer];
	assert(num_output_nodes < NN_MAX_NODES_PER_LAYER);
	for (int node = 0; node < num_output_nodes; ++node) {
	float val = layer_bias[node];
	for (int i = 0; i < num_input_nodes; ++i)
	val += layer_weights[node * num_input_nodes + i] * input_nodes[i];
	// ReLU as activation function.
	val = val > 0.0f ? val : 0.0f; // Could use AOMMAX().
	output_nodes[node] = val;
	}
	num_input_nodes = num_output_nodes;
	input_nodes = output_nodes;
	buf_index = 1 - buf_index;
	}

	// Final output layer.
	const float *layer_weights = nn_config->weights[num_layers];
	const float *layer_bias = nn_config->bias[num_layers];
	for (int node = 0; node < nn_config->num_outputs; ++node) {
	float val = layer_bias[node];
	for (int i = 0; i < num_input_nodes; ++i)
	val += layer_weights[node * num_input_nodes + i] * input_nodes[i];
	output[node] = val;
	}
	if (reduce_prec) av1_nn_output_prec_reduce(output, nn_config->num_outputs);
	}

	#if CONFIG_NN_V2
	// Applies the ReLu activation to one fc layer
	// output[i] = Max(input[i],0.0f)
	static float nn_relu(const float input, FC_LAYER *layer) {
	for (int i = 0; i < layer->num_outputs; ++i) {
	layer->output[i] = AOMMAX(input[i], 0.0f);
	}

	return layer->output;
	}

	// Applies the Sigmoid activation to one fc layer
	// output[i] = 1/(1+exp(input[i]))
	static float nn_sigmoid(const float input, FC_LAYER *layer) {
	for (int i = 0; i < layer->num_outputs; ++i) {
	const float tmp = AOMMIN(AOMMAX(input[i], -10.0f), 10.0f);
	layer->output[i] = 1.0f / (1.0f + expf(-tmp));
	}

	return layer->output;
	}

	// Forward prediction in one fc layer, used in function av1_nn_predict_V2
	static float nn_fc_forward(const float input, FC_LAYER *layer) {
	const float *weights = layer->weights;
	const float *bias = layer->bias;
	assert(layer->num_outputs < NN_MAX_NODES_PER_LAYER);
	// fc
	for (int node = 0; node < layer->num_outputs; ++node) {
	float val = bias[node];
	for (int i = 0; i < layer->num_inputs; ++i) val += weights[i] * input[i];
	layer->output[node] = val;
	weights += layer->num_inputs;
	}

	// activation
	switch (layer->activation) {
	case NONE: return layer->output;
	case RELU: return nn_relu(layer->output, layer);
	case SIGMOID: return nn_sigmoid(layer->output, layer);
	case SOFTSIGN:
	assert(0 && "Softsign has not been supported in NN."); // TO DO
	return NULL;
	default:
	assert(0 && "Unknown activation"); // Unknown activation
	return NULL;
	}
	}

	void av1_nn_predict_v2(const float feature, NN_CONFIG_V2 nn_config,
	int reduce_prec, float *output) {
	const float *input_nodes = feature;

	// Propagate the layers.
	const int num_layers = nn_config->num_hidden_layers;
	assert(num_layers <= NN_MAX_HIDDEN_LAYERS);
	for (int i = 0; i < num_layers; ++i) {
	input_nodes = nn_fc_forward(input_nodes, nn_config->layer + i);
	assert(nn_config->layer[i + 1].num_inputs ==
	nn_config->layer[i].num_outputs);
	}

	// Final layer
	input_nodes = nn_fc_forward(input_nodes, nn_config->layer + num_layers);
	assert(nn_config->layer[num_layers].num_outputs == nn_config->num_logits);
	// Copy the final layer output
	memcpy(output, input_nodes, sizeof(input_nodes) nn_config->num_logits);
	if (reduce_prec) av1_nn_output_prec_reduce(output, nn_config->num_logits);
	}
	#endif // CONFIG_NN_V2

	void av1_nn_softmax(const float input, float output, int n) {
	// Softmax function is invariant to adding the same constant
	// to all input values, so we subtract the maximum input to avoid
	// possible overflow.
	float max_inp = input[0];
	for (int i = 1; i < n; i++) max_inp = AOMMAX(max_inp, input[i]);
	float sum_out = 0.0f;
	for (int i = 0; i < n; i++) {
	// Clamp to range [-10.0, 0.0] to prevent FE_UNDERFLOW errors.
	const float normalized_input = AOMMAX(input[i] - max_inp, -10.0f);
	output[i] = (float)exp(normalized_input);
	sum_out += output[i];
	}
	for (int i = 0; i < n; i++) output[i] /= sum_out;
	}