pmlpp/mlpp/wgan/wgan.cpp

713 lines
30 KiB
C++

//
// WGAN.cpp
//
// Created by Marc Melikyan on 11/4/20.
//
#include "wgan.h"
#include "../activation/activation.h"
#include "../cost/cost.h"
#include "../lin_alg/lin_alg.h"
#include "../regularization/reg.h"
#include "../utilities/utilities.h"
#include "core/object/method_bind_ext.gen.inc"
#include <cmath>
#include <iostream>
Ref<MLPPMatrix> MLPPWGAN::get_output_set() {
return output_set;
}
void MLPPWGAN::set_output_set(const Ref<MLPPMatrix> &val) {
output_set = val;
n = 0;
if (output_set.is_valid()) {
n = output_set->size().y;
}
}
int MLPPWGAN::get_k() const {
return k;
}
void MLPPWGAN::set_k(const int val) {
k = val;
}
Ref<MLPPMatrix> MLPPWGAN::generate_example(int n) {
MLPPLinAlg alg;
return model_set_test_generator(alg.gaussian_noise(n, k));
}
void MLPPWGAN::gradient_descent(real_t learning_rate, int max_epoch, bool ui) {
//MLPPCost mlpp_cost;
MLPPLinAlg alg;
real_t cost_prev = 0;
int epoch = 1;
forward_pass();
const int CRITIC_INTERATIONS = 5; // Wasserstein GAN specific parameter.
while (true) {
cost_prev = cost(y_hat, alg.onevecv(n));
Ref<MLPPMatrix> generator_input_set;
Ref<MLPPMatrix> discriminator_input_set;
discriminator_input_set.instance();
Ref<MLPPVector> ly_hat;
Ref<MLPPVector> loutput_set;
// Training of the discriminator.
for (int i = 0; i < CRITIC_INTERATIONS; i++) {
generator_input_set = alg.gaussian_noise(n, k);
discriminator_input_set->set_from_mlpp_matrix(model_set_test_generator(generator_input_set));
discriminator_input_set->add_rows_mlpp_matrix(output_set); // Fake + real inputs.
ly_hat = model_set_test_discriminator(discriminator_input_set);
loutput_set = alg.scalar_multiplynv(-1, alg.onevecv(n)); // WGAN changes y_i = 1 and y_i = 0 to y_i = 1 and y_i = -1
Ref<MLPPVector> output_set_real = alg.onevecv(n);
loutput_set->add_mlpp_vector(output_set_real); // Fake + real output scores.
DiscriminatorGradientResult discriminator_gradient_results = compute_discriminator_gradients(ly_hat, loutput_set);
Vector<Ref<MLPPMatrix>> cumulative_discriminator_hidden_layer_w_grad = discriminator_gradient_results.cumulative_hidden_layer_w_grad;
Ref<MLPPVector> output_discriminator_w_grad = discriminator_gradient_results.output_w_grad;
cumulative_discriminator_hidden_layer_w_grad = alg.scalar_multiply_vm(learning_rate / n, cumulative_discriminator_hidden_layer_w_grad);
output_discriminator_w_grad = alg.scalar_multiplynv(learning_rate / n, output_discriminator_w_grad);
update_discriminator_parameters(cumulative_discriminator_hidden_layer_w_grad, output_discriminator_w_grad, learning_rate);
}
// Training of the generator.
generator_input_set = alg.gaussian_noise(n, k);
discriminator_input_set->set_from_mlpp_matrix(model_set_test_generator(generator_input_set));
ly_hat = model_set_test_discriminator(discriminator_input_set);
loutput_set = alg.onevecv(n);
Vector<Ref<MLPPMatrix>> cumulative_generator_hidden_layer_w_grad = compute_generator_gradients(y_hat, loutput_set);
cumulative_generator_hidden_layer_w_grad = alg.scalar_multiply_vm(learning_rate / n, cumulative_generator_hidden_layer_w_grad);
update_generator_parameters(cumulative_generator_hidden_layer_w_grad, learning_rate);
forward_pass();
if (ui) {
handle_ui(epoch, cost_prev, y_hat, alg.onevecv(n));
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
}
real_t MLPPWGAN::score() {
MLPPLinAlg alg;
MLPPUtilities util;
forward_pass();
return util.performance_vec(y_hat, alg.onevecv(n));
}
void MLPPWGAN::save(const String &file_name) {
MLPPUtilities util;
/*
if (!network.empty()) {
util.saveParameters(file_name, network[0].weights, network[0].bias, 0, 1);
for (uint32_t i = 1; i < network.size(); i++) {
util.saveParameters(fileName, network[i].weights, network[i].bias, 1, i + 1);
}
util.saveParameters(file_name, outputLayer->weights, outputLayer->bias, 1, network.size() + 1);
} else {
util.saveParameters(file_name, outputLayer->weights, outputLayer->bias, 0, network.size() + 1);
}
*/
}
void MLPPWGAN::add_layer(int n_hidden, MLPPActivation::ActivationFunction activation, MLPPUtilities::WeightDistributionType weight_init, MLPPReg::RegularizationType reg, real_t lambda, real_t alpha) {
MLPPLinAlg alg;
Ref<MLPPHiddenLayer> layer;
layer.instance();
layer->set_n_hidden(n_hidden);
layer->set_activation(activation);
layer->set_weight_init(weight_init);
layer->set_reg(reg);
layer->set_lambda(lambda);
layer->set_alpha(alpha);
if (network.empty()) {
layer->set_input(alg.gaussian_noise(n, k));
} else {
layer->set_input(network.write[network.size() - 1]->get_a());
}
network.push_back(layer);
layer->forward_pass();
}
void MLPPWGAN::add_output_layer(MLPPUtilities::WeightDistributionType weight_init, MLPPReg::RegularizationType reg, real_t lambda, real_t alpha) {
ERR_FAIL_COND(network.empty());
if (!output_layer.is_valid()) {
output_layer.instance();
}
output_layer->set_n_hidden(network[network.size() - 1]->get_n_hidden());
output_layer->set_activation(MLPPActivation::ACTIVATION_FUNCTION_LINEAR);
output_layer->set_cost(MLPPCost::COST_TYPE_WASSERSTEIN_LOSS);
output_layer->set_input(network.write[network.size() - 1]->get_a());
output_layer->set_weight_init(weight_init);
output_layer->set_lambda(lambda);
output_layer->set_alpha(alpha);
}
MLPPWGAN::MLPPWGAN(real_t p_k, const Ref<MLPPMatrix> &p_output_set) {
output_set = p_output_set;
n = p_output_set->size().y;
k = p_k;
y_hat.instance();
}
MLPPWGAN::MLPPWGAN() {
n = 0;
k = 0;
y_hat.instance();
}
MLPPWGAN::~MLPPWGAN() {
}
Ref<MLPPMatrix> MLPPWGAN::model_set_test_generator(const Ref<MLPPMatrix> &X) {
if (!network.empty()) {
network.write[0]->set_input(X);
network.write[0]->forward_pass();
for (int i = 1; i <= network.size() / 2; ++i) {
network.write[i]->set_input(network.write[i - 1]->get_a());
network.write[i]->forward_pass();
}
}
return network.write[network.size() / 2]->get_a();
}
Ref<MLPPVector> MLPPWGAN::model_set_test_discriminator(const Ref<MLPPMatrix> &X) {
if (!network.empty()) {
for (int i = network.size() / 2 + 1; i < network.size(); i++) {
if (i == network.size() / 2 + 1) {
network.write[i]->set_input(X);
} else {
network.write[i]->set_input(network.write[i - 1]->get_a());
}
network.write[i]->forward_pass();
}
output_layer->set_input(network.write[network.size() - 1]->get_a());
}
output_layer->forward_pass();
return output_layer->get_a();
}
real_t MLPPWGAN::cost(const Ref<MLPPVector> &y_hat, const Ref<MLPPVector> &y) {
MLPPReg regularization;
MLPPCost mlpp_cost;
real_t total_reg_term = 0;
for (int i = 0; i < network.size() - 1; ++i) {
Ref<MLPPHiddenLayer> layer = network[i];
total_reg_term += regularization.reg_termm(layer->get_weights(), layer->get_lambda(), layer->get_alpha(), layer->get_reg());
}
total_reg_term += regularization.reg_termv(output_layer->get_weights(), output_layer->get_lambda(), output_layer->get_alpha(), output_layer->get_reg());
return mlpp_cost.run_cost_norm_vector(output_layer->get_cost(), y_hat, y) + total_reg_term;
}
void MLPPWGAN::forward_pass() {
MLPPLinAlg alg;
if (!network.empty()) {
Ref<MLPPHiddenLayer> layer = network[0];
layer->set_input(alg.gaussian_noise(n, k));
layer->forward_pass();
for (int i = 1; i < network.size(); i++) {
layer = network[i];
layer->set_input(network.write[i - 1]->get_a());
layer->forward_pass();
}
output_layer->set_input(network.write[network.size() - 1]->get_a());
} else { // Should never happen, though.
output_layer->set_input(alg.gaussian_noise(n, k));
}
output_layer->forward_pass();
y_hat->set_from_mlpp_vector(output_layer->get_a());
}
void MLPPWGAN::update_discriminator_parameters(Vector<Ref<MLPPMatrix>> hidden_layer_updations, const Ref<MLPPVector> &output_layer_updation, real_t learning_rate) {
MLPPLinAlg alg;
output_layer->set_weights(alg.subtractionnv(output_layer->get_weights(), output_layer_updation));
output_layer->set_bias(output_layer->get_bias() - learning_rate * alg.sum_elementsv(output_layer->get_delta()) / n);
if (!network.empty()) {
Ref<MLPPHiddenLayer> layer = network[network.size() - 1];
layer->set_weights(alg.subtractionm(layer->get_weights(), hidden_layer_updations[0]));
layer->set_bias(alg.subtract_matrix_rows(layer->get_bias(), alg.scalar_multiplym(learning_rate / n, layer->get_delta())));
for (int i = network.size() - 2; i > network.size() / 2; i--) {
layer = network[i];
layer->set_weights(alg.subtractionm(layer->get_weights(), hidden_layer_updations[(network.size() - 2) - i + 1]));
layer->set_bias(alg.subtract_matrix_rows(layer->get_bias(), alg.scalar_multiplym(learning_rate / n, layer->get_delta())));
}
}
}
void MLPPWGAN::update_generator_parameters(Vector<Ref<MLPPMatrix>> hidden_layer_updations, real_t learning_rate) {
MLPPLinAlg alg;
if (!network.empty()) {
for (int i = network.size() / 2; i >= 0; i--) {
Ref<MLPPHiddenLayer> layer = network[i];
//std::cout << network[i].weights.size() << "x" << network[i].weights[0].size() << std::endl;
//std::cout << hiddenLayerUpdations[(network.size() - 2) - i + 1].size() << "x" << hiddenLayerUpdations[(network.size() - 2) - i + 1][0].size() << std::endl;
layer->set_weights(alg.subtractionm(layer->get_weights(), hidden_layer_updations[(network.size() - 2) - i + 1]));
layer->set_bias(alg.subtract_matrix_rows(layer->get_bias(), alg.scalar_multiplym(learning_rate / n, layer->get_delta())));
}
}
}
MLPPWGAN::DiscriminatorGradientResult MLPPWGAN::compute_discriminator_gradients(const Ref<MLPPVector> &y_hat, const Ref<MLPPVector> &output_set) {
MLPPCost mlpp_cost;
MLPPActivation avn;
MLPPLinAlg alg;
MLPPReg regularization;
DiscriminatorGradientResult data;
output_layer->set_delta(alg.hadamard_productnv(mlpp_cost.run_cost_deriv_vector(output_layer->get_cost(), y_hat, output_set), avn.run_activation_deriv_vector(output_layer->get_activation(), output_layer->get_z())));
data.output_w_grad = alg.mat_vec_multv(alg.transposem(output_layer->get_input()), output_layer->get_delta());
data.output_w_grad = alg.additionnv(data.output_w_grad, regularization.reg_deriv_termv(output_layer->get_weights(), output_layer->get_lambda(), output_layer->get_alpha(), output_layer->get_reg()));
if (!network.empty()) {
Ref<MLPPHiddenLayer> layer = network[network.size() - 1];
layer->set_delta(alg.hadamard_productm(alg.outer_product(output_layer->get_delta(), output_layer->get_weights()), avn.run_activation_deriv_matrix(layer->get_activation(), layer->get_z())));
Ref<MLPPMatrix> hidden_layer_w_grad = alg.matmultm(alg.transposem(layer->get_input()), layer->get_delta());
data.cumulative_hidden_layer_w_grad.push_back(alg.additionm(hidden_layer_w_grad, regularization.reg_deriv_termm(layer->get_weights(), layer->get_lambda(), layer->get_alpha(), layer->get_reg()))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
//std::cout << "HIDDENLAYER FIRST:" << hiddenLayerWGrad.size() << "x" << hiddenLayerWGrad[0].size() << std::endl;
//std::cout << "WEIGHTS SECOND:" << layer.weights.size() << "x" << layer.weights[0].size() << std::endl;
for (int i = network.size() - 2; i > network.size() / 2; i--) {
layer = network[i];
Ref<MLPPHiddenLayer> next_layer = network[i + 1];
layer->set_delta(alg.hadamard_productm(alg.matmultm(next_layer->get_delta(), alg.transposem(next_layer->get_weights())), avn.run_activation_deriv_matrix(layer->get_activation(), layer->get_z())));
hidden_layer_w_grad = alg.matmultm(alg.transposem(layer->get_input()), layer->get_delta());
data.cumulative_hidden_layer_w_grad.push_back(alg.additionm(hidden_layer_w_grad, regularization.reg_deriv_termm(layer->get_weights(), layer->get_lambda(), layer->get_alpha(), layer->get_reg()))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
}
}
return data;
}
Vector<Ref<MLPPMatrix>> MLPPWGAN::compute_generator_gradients(const Ref<MLPPVector> &y_hat, const Ref<MLPPVector> &output_set) {
class MLPPCost cost;
MLPPActivation avn;
MLPPLinAlg alg;
MLPPReg regularization;
Vector<Ref<MLPPMatrix>> cumulative_hidden_layer_w_grad; // Tensor containing ALL hidden grads.
Ref<MLPPVector> cost_deriv_vector = cost.run_cost_deriv_vector(output_layer->get_cost(), y_hat, output_set);
Ref<MLPPVector> activation_deriv_vector = avn.run_activation_deriv_vector(output_layer->get_activation(), output_layer->get_z());
output_layer->set_delta(alg.hadamard_productnv(cost_deriv_vector, activation_deriv_vector));
Ref<MLPPVector> output_w_grad = alg.mat_vec_multv(alg.transposem(output_layer->get_input()), output_layer->get_delta());
output_w_grad = alg.additionnv(output_w_grad, regularization.reg_deriv_termv(output_layer->get_weights(), output_layer->get_lambda(), output_layer->get_alpha(), output_layer->get_reg()));
if (!network.empty()) {
Ref<MLPPHiddenLayer> layer = network[network.size() - 1];
Ref<MLPPMatrix> activation_deriv_matrix = avn.run_activation_deriv_matrix(layer->get_activation(), layer->get_z());
layer->set_delta(alg.hadamard_productm(alg.outer_product(output_layer->get_delta(), output_layer->get_weights()), activation_deriv_matrix));
Ref<MLPPMatrix> hidden_layer_w_grad = alg.matmultm(alg.transposem(layer->get_input()), layer->get_delta());
cumulative_hidden_layer_w_grad.push_back(alg.additionm(hidden_layer_w_grad, regularization.reg_deriv_termm(layer->get_weights(), layer->get_lambda(), layer->get_alpha(), layer->get_reg()))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
for (int i = network.size() - 2; i >= 0; i--) {
layer = network[i];
Ref<MLPPHiddenLayer> next_layer = network[i + 1];
activation_deriv_matrix = avn.run_activation_deriv_matrix(layer->get_activation(), layer->get_z());
layer->set_delta(alg.hadamard_productm(alg.matmultm(next_layer->get_delta(), alg.transposem(next_layer->get_weights())), activation_deriv_matrix));
hidden_layer_w_grad = alg.matmultm(alg.transposem(layer->get_input()), layer->get_delta());
cumulative_hidden_layer_w_grad.push_back(alg.additionm(hidden_layer_w_grad, regularization.reg_deriv_termm(layer->get_weights(), layer->get_lambda(), layer->get_alpha(), layer->get_reg()))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
}
}
return cumulative_hidden_layer_w_grad;
}
void MLPPWGAN::handle_ui(int epoch, real_t cost_prev, const Ref<MLPPVector> &y_hat, const Ref<MLPPVector> &output_set) {
MLPPUtilities::cost_info(epoch, cost_prev, cost(y_hat, output_set));
std::cout << "Layer " << network.size() + 1 << ": " << std::endl;
MLPPUtilities::print_ui_vb(output_layer->get_weights(), output_layer->get_bias());
if (!network.empty()) {
for (int i = network.size() - 1; i >= 0; i--) {
Ref<MLPPHiddenLayer> layer = network[i];
std::cout << "Layer " << i + 1 << ": " << std::endl;
MLPPUtilities::print_ui_vib(layer->get_weights(), layer->get_bias(), 0);
}
}
}
void MLPPWGAN::_bind_methods() {
ClassDB::bind_method(D_METHOD("get_output_set"), &MLPPWGAN::get_output_set);
ClassDB::bind_method(D_METHOD("set_output_set", "val"), &MLPPWGAN::set_output_set);
ADD_PROPERTY(PropertyInfo(Variant::OBJECT, "output_set", PROPERTY_HINT_RESOURCE_TYPE, "MLPPMatrix"), "set_output_set", "get_output_set");
ClassDB::bind_method(D_METHOD("get_k"), &MLPPWGAN::get_k);
ClassDB::bind_method(D_METHOD("set_k", "val"), &MLPPWGAN::set_k);
ADD_PROPERTY(PropertyInfo(Variant::INT, "k"), "set_k", "get_k");
ClassDB::bind_method(D_METHOD("generate_example", "n"), &MLPPWGAN::generate_example);
ClassDB::bind_method(D_METHOD("gradient_descent", "learning_rate", "max_epoch", "ui"), &MLPPWGAN::gradient_descent, false);
ClassDB::bind_method(D_METHOD("score"), &MLPPWGAN::score);
ClassDB::bind_method(D_METHOD("save", "file_name"), &MLPPWGAN::save);
ClassDB::bind_method(D_METHOD("add_layer", "activation", "weight_init", "reg", "lambda", "alpha"), &MLPPWGAN::add_layer, MLPPUtilities::WEIGHT_DISTRIBUTION_TYPE_DEFAULT, MLPPReg::REGULARIZATION_TYPE_NONE, 0.5, 0.5);
ClassDB::bind_method(D_METHOD("add_output_layer", "weight_init", "reg", "lambda", "alpha"), &MLPPWGAN::add_output_layer, MLPPUtilities::WEIGHT_DISTRIBUTION_TYPE_DEFAULT, MLPPReg::REGULARIZATION_TYPE_NONE, 0.5, 0.5);
}
// ======== OLD ==========
MLPPWGANOld::MLPPWGANOld(real_t k, std::vector<std::vector<real_t>> outputSet) :
outputSet(outputSet), n(outputSet.size()), k(k) {
}
MLPPWGANOld::~MLPPWGANOld() {
delete outputLayer;
}
std::vector<std::vector<real_t>> MLPPWGANOld::generateExample(int n) {
MLPPLinAlg alg;
return modelSetTestGenerator(alg.gaussianNoise(n, k));
}
void MLPPWGANOld::gradientDescent(real_t learning_rate, int max_epoch, bool UI) {
class MLPPCost cost;
MLPPLinAlg alg;
real_t cost_prev = 0;
int epoch = 1;
forwardPass();
const int CRITIC_INTERATIONS = 5; // Wasserstein GAN specific parameter.
while (true) {
cost_prev = Cost(y_hat, alg.onevec(n));
std::vector<std::vector<real_t>> generatorInputSet;
std::vector<std::vector<real_t>> discriminatorInputSet;
std::vector<real_t> y_hat;
std::vector<real_t> outputSet;
// Training of the discriminator.
for (int i = 0; i < CRITIC_INTERATIONS; i++) {
generatorInputSet = alg.gaussianNoise(n, k);
discriminatorInputSet = modelSetTestGenerator(generatorInputSet);
discriminatorInputSet.insert(discriminatorInputSet.end(), MLPPWGANOld::outputSet.begin(), MLPPWGANOld::outputSet.end()); // Fake + real inputs.
y_hat = modelSetTestDiscriminator(discriminatorInputSet);
outputSet = alg.scalarMultiply(-1, alg.onevec(n)); // WGAN changes y_i = 1 and y_i = 0 to y_i = 1 and y_i = -1
std::vector<real_t> outputSetReal = alg.onevec(n);
outputSet.insert(outputSet.end(), outputSetReal.begin(), outputSetReal.end()); // Fake + real output scores.
auto discriminator_gradient_results = computeDiscriminatorGradients(y_hat, outputSet);
auto cumulativeDiscriminatorHiddenLayerWGrad = std::get<0>(discriminator_gradient_results);
auto outputDiscriminatorWGrad = std::get<1>(discriminator_gradient_results);
cumulativeDiscriminatorHiddenLayerWGrad = alg.scalarMultiply(learning_rate / n, cumulativeDiscriminatorHiddenLayerWGrad);
outputDiscriminatorWGrad = alg.scalarMultiply(learning_rate / n, outputDiscriminatorWGrad);
updateDiscriminatorParameters(cumulativeDiscriminatorHiddenLayerWGrad, outputDiscriminatorWGrad, learning_rate);
}
// Training of the generator.
generatorInputSet = alg.gaussianNoise(n, k);
discriminatorInputSet = modelSetTestGenerator(generatorInputSet);
y_hat = modelSetTestDiscriminator(discriminatorInputSet);
outputSet = alg.onevec(n);
std::vector<std::vector<std::vector<real_t>>> cumulativeGeneratorHiddenLayerWGrad = computeGeneratorGradients(y_hat, outputSet);
cumulativeGeneratorHiddenLayerWGrad = alg.scalarMultiply(learning_rate / n, cumulativeGeneratorHiddenLayerWGrad);
updateGeneratorParameters(cumulativeGeneratorHiddenLayerWGrad, learning_rate);
forwardPass();
if (UI) {
MLPPWGANOld::UI(epoch, cost_prev, MLPPWGANOld::y_hat, alg.onevec(n));
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
}
real_t MLPPWGANOld::score() {
MLPPLinAlg alg;
MLPPUtilities util;
forwardPass();
return util.performance(y_hat, alg.onevec(n));
}
void MLPPWGANOld::save(std::string fileName) {
MLPPUtilities util;
if (!network.empty()) {
util.saveParameters(fileName, network[0].weights, network[0].bias, 0, 1);
for (uint32_t i = 1; i < network.size(); i++) {
util.saveParameters(fileName, network[i].weights, network[i].bias, 1, i + 1);
}
util.saveParameters(fileName, outputLayer->weights, outputLayer->bias, 1, network.size() + 1);
} else {
util.saveParameters(fileName, outputLayer->weights, outputLayer->bias, 0, network.size() + 1);
}
}
void MLPPWGANOld::addLayer(int n_hidden, std::string activation, std::string weightInit, std::string reg, real_t lambda, real_t alpha) {
MLPPLinAlg alg;
if (network.empty()) {
network.push_back(MLPPOldHiddenLayer(n_hidden, activation, alg.gaussianNoise(n, k), weightInit, reg, lambda, alpha));
network[0].forwardPass();
} else {
network.push_back(MLPPOldHiddenLayer(n_hidden, activation, network[network.size() - 1].a, weightInit, reg, lambda, alpha));
network[network.size() - 1].forwardPass();
}
}
void MLPPWGANOld::addOutputLayer(std::string weightInit, std::string reg, real_t lambda, real_t alpha) {
MLPPLinAlg alg;
if (!network.empty()) {
outputLayer = new MLPPOldOutputLayer(network[network.size() - 1].n_hidden, "Linear", "WassersteinLoss", network[network.size() - 1].a, weightInit, "WeightClipping", -0.01, 0.01);
} else { // Should never happen.
outputLayer = new MLPPOldOutputLayer(k, "Linear", "WassersteinLoss", alg.gaussianNoise(n, k), weightInit, "WeightClipping", -0.01, 0.01);
}
}
std::vector<std::vector<real_t>> MLPPWGANOld::modelSetTestGenerator(std::vector<std::vector<real_t>> X) {
if (!network.empty()) {
network[0].input = X;
network[0].forwardPass();
for (uint32_t i = 1; i <= network.size() / 2; i++) {
network[i].input = network[i - 1].a;
network[i].forwardPass();
}
}
return network[network.size() / 2].a;
}
std::vector<real_t> MLPPWGANOld::modelSetTestDiscriminator(std::vector<std::vector<real_t>> X) {
if (!network.empty()) {
for (uint32_t i = network.size() / 2 + 1; i < network.size(); i++) {
if (i == network.size() / 2 + 1) {
network[i].input = X;
} else {
network[i].input = network[i - 1].a;
}
network[i].forwardPass();
}
outputLayer->input = network[network.size() - 1].a;
}
outputLayer->forwardPass();
return outputLayer->a;
}
real_t MLPPWGANOld::Cost(std::vector<real_t> y_hat, std::vector<real_t> y) {
MLPPReg regularization;
class MLPPCost cost;
real_t totalRegTerm = 0;
auto cost_function = outputLayer->cost_map[outputLayer->cost];
if (!network.empty()) {
for (uint32_t i = 0; i < network.size() - 1; i++) {
totalRegTerm += regularization.regTerm(network[i].weights, network[i].lambda, network[i].alpha, network[i].reg);
}
}
return (cost.*cost_function)(y_hat, y) + totalRegTerm + regularization.regTerm(outputLayer->weights, outputLayer->lambda, outputLayer->alpha, outputLayer->reg);
}
void MLPPWGANOld::forwardPass() {
MLPPLinAlg alg;
if (!network.empty()) {
network[0].input = alg.gaussianNoise(n, k);
network[0].forwardPass();
for (uint32_t i = 1; i < network.size(); i++) {
network[i].input = network[i - 1].a;
network[i].forwardPass();
}
outputLayer->input = network[network.size() - 1].a;
} else { // Should never happen, though.
outputLayer->input = alg.gaussianNoise(n, k);
}
outputLayer->forwardPass();
y_hat = outputLayer->a;
}
void MLPPWGANOld::updateDiscriminatorParameters(std::vector<std::vector<std::vector<real_t>>> hiddenLayerUpdations, std::vector<real_t> outputLayerUpdation, real_t learning_rate) {
MLPPLinAlg alg;
outputLayer->weights = alg.subtraction(outputLayer->weights, outputLayerUpdation);
outputLayer->bias -= learning_rate * alg.sum_elements(outputLayer->delta) / n;
if (!network.empty()) {
network[network.size() - 1].weights = alg.subtraction(network[network.size() - 1].weights, hiddenLayerUpdations[0]);
network[network.size() - 1].bias = alg.subtractMatrixRows(network[network.size() - 1].bias, alg.scalarMultiply(learning_rate / n, network[network.size() - 1].delta));
for (uint32_t i = network.size() - 2; i > network.size() / 2; i--) {
network[i].weights = alg.subtraction(network[i].weights, hiddenLayerUpdations[(network.size() - 2) - i + 1]);
network[i].bias = alg.subtractMatrixRows(network[i].bias, alg.scalarMultiply(learning_rate / n, network[i].delta));
}
}
}
void MLPPWGANOld::updateGeneratorParameters(std::vector<std::vector<std::vector<real_t>>> hiddenLayerUpdations, real_t learning_rate) {
MLPPLinAlg alg;
if (!network.empty()) {
for (int ii = network.size() / 2; ii >= 0; ii--) {
uint32_t i = static_cast<uint32_t>(ii);
//std::cout << network[i].weights.size() << "x" << network[i].weights[0].size() << std::endl;
//std::cout << hiddenLayerUpdations[(network.size() - 2) - i + 1].size() << "x" << hiddenLayerUpdations[(network.size() - 2) - i + 1][0].size() << std::endl;
network[i].weights = alg.subtraction(network[i].weights, hiddenLayerUpdations[(network.size() - 2) - i + 1]);
network[i].bias = alg.subtractMatrixRows(network[i].bias, alg.scalarMultiply(learning_rate / n, network[i].delta));
}
}
}
std::tuple<std::vector<std::vector<std::vector<real_t>>>, std::vector<real_t>> MLPPWGANOld::computeDiscriminatorGradients(std::vector<real_t> y_hat, std::vector<real_t> outputSet) {
class MLPPCost cost;
MLPPActivation avn;
MLPPLinAlg alg;
MLPPReg regularization;
std::vector<std::vector<std::vector<real_t>>> cumulativeHiddenLayerWGrad; // Tensor containing ALL hidden grads.
auto costDeriv = outputLayer->costDeriv_map[outputLayer->cost];
auto outputAvn = outputLayer->activation_map[outputLayer->activation];
outputLayer->delta = alg.hadamard_product((cost.*costDeriv)(y_hat, outputSet), (avn.*outputAvn)(outputLayer->z, 1));
std::vector<real_t> outputWGrad = alg.mat_vec_mult(alg.transpose(outputLayer->input), outputLayer->delta);
outputWGrad = alg.addition(outputWGrad, regularization.regDerivTerm(outputLayer->weights, outputLayer->lambda, outputLayer->alpha, outputLayer->reg));
if (!network.empty()) {
auto hiddenLayerAvn = network[network.size() - 1].activation_map[network[network.size() - 1].activation];
//std::cout << "=-------=--==-=-=-=" << std::endl;
//alg.printVector(outputLayer->delta);
//std::cout << "=-------=--==-=-=-=" << std::endl;
//alg.printVector(outputLayer->weights);
//std::cout << "=-------=--==-=-=-=" << std::endl;
//alg.printMatrix(alg.outerProduct(outputLayer->delta, outputLayer->weights));
//std::cout << "=-------=--==-=-=-=" << std::endl;
//alg.printMatrix((avn.*hiddenLayerAvn)(network[network.size() - 1].z, 1));
//CRASH_NOW();
network[network.size() - 1].delta = alg.hadamard_product(alg.outerProduct(outputLayer->delta, outputLayer->weights), (avn.*hiddenLayerAvn)(network[network.size() - 1].z, 1));
std::vector<std::vector<real_t>> hiddenLayerWGrad = alg.matmult(alg.transpose(network[network.size() - 1].input), network[network.size() - 1].delta);
cumulativeHiddenLayerWGrad.push_back(alg.addition(hiddenLayerWGrad, regularization.regDerivTerm(network[network.size() - 1].weights, network[network.size() - 1].lambda, network[network.size() - 1].alpha, network[network.size() - 1].reg))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
//std::cout << "HIDDENLAYER FIRST:" << hiddenLayerWGrad.size() << "x" << hiddenLayerWGrad[0].size() << std::endl;
//std::cout << "WEIGHTS SECOND:" << network[network.size() - 1].weights.size() << "x" << network[network.size() - 1].weights[0].size() << std::endl;
for (uint32_t i = network.size() - 2; i > network.size() / 2; i--) {
auto hiddenLayerAvnl = network[i].activation_map[network[i].activation];
network[i].delta = alg.hadamard_product(alg.matmult(network[i + 1].delta, alg.transpose(network[i + 1].weights)), (avn.*hiddenLayerAvnl)(network[i].z, 1));
std::vector<std::vector<real_t>> hiddenLayerWGradl = alg.matmult(alg.transpose(network[i].input), network[i].delta);
cumulativeHiddenLayerWGrad.push_back(alg.addition(hiddenLayerWGradl, regularization.regDerivTerm(network[i].weights, network[i].lambda, network[i].alpha, network[i].reg))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
}
}
return { cumulativeHiddenLayerWGrad, outputWGrad };
}
std::vector<std::vector<std::vector<real_t>>> MLPPWGANOld::computeGeneratorGradients(std::vector<real_t> y_hat, std::vector<real_t> outputSet) {
class MLPPCost cost;
MLPPActivation avn;
MLPPLinAlg alg;
MLPPReg regularization;
std::vector<std::vector<std::vector<real_t>>> cumulativeHiddenLayerWGrad; // Tensor containing ALL hidden grads.
auto costDeriv = outputLayer->costDeriv_map[outputLayer->cost];
auto outputAvn = outputLayer->activation_map[outputLayer->activation];
outputLayer->delta = alg.hadamard_product((cost.*costDeriv)(y_hat, outputSet), (avn.*outputAvn)(outputLayer->z, 1));
std::vector<real_t> outputWGrad = alg.mat_vec_mult(alg.transpose(outputLayer->input), outputLayer->delta);
outputWGrad = alg.addition(outputWGrad, regularization.regDerivTerm(outputLayer->weights, outputLayer->lambda, outputLayer->alpha, outputLayer->reg));
if (!network.empty()) {
auto hiddenLayerAvn = network[network.size() - 1].activation_map[network[network.size() - 1].activation];
network[network.size() - 1].delta = alg.hadamard_product(alg.outerProduct(outputLayer->delta, outputLayer->weights), (avn.*hiddenLayerAvn)(network[network.size() - 1].z, 1));
std::vector<std::vector<real_t>> hiddenLayerWGrad = alg.matmult(alg.transpose(network[network.size() - 1].input), network[network.size() - 1].delta);
cumulativeHiddenLayerWGrad.push_back(alg.addition(hiddenLayerWGrad, regularization.regDerivTerm(network[network.size() - 1].weights, network[network.size() - 1].lambda, network[network.size() - 1].alpha, network[network.size() - 1].reg))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
for (int ii = network.size() - 2; ii >= 0; ii--) {
uint32_t i = static_cast<uint32_t>(ii);
auto hiddenLayerAvnl = network[i].activation_map[network[i].activation];
network[i].delta = alg.hadamard_product(alg.matmult(network[i + 1].delta, alg.transpose(network[i + 1].weights)), (avn.*hiddenLayerAvnl)(network[i].z, 1));
std::vector<std::vector<real_t>> hiddenLayerWGradl = alg.matmult(alg.transpose(network[i].input), network[i].delta);
cumulativeHiddenLayerWGrad.push_back(alg.addition(hiddenLayerWGradl, regularization.regDerivTerm(network[i].weights, network[i].lambda, network[i].alpha, network[i].reg))); // Adding to our cumulative hidden layer grads. Maintain reg terms as well.
}
}
return cumulativeHiddenLayerWGrad;
}
void MLPPWGANOld::UI(int epoch, real_t cost_prev, std::vector<real_t> y_hat, std::vector<real_t> outputSet) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputSet));
std::cout << "Layer " << network.size() + 1 << ": " << std::endl;
MLPPUtilities::UI(outputLayer->weights, outputLayer->bias);
if (!network.empty()) {
for (int ii = network.size() - 1; ii >= 0; ii--) {
uint32_t i = static_cast<uint32_t>(ii);
std::cout << "Layer " << i + 1 << ": " << std::endl;
MLPPUtilities::UI(network[i].weights, network[i].bias);
}
}
}