pmlpp/mlpp/lin_reg/lin_reg_old.cpp

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//
// LinReg.cpp
//
// Created by Marc Melikyan on 10/2/20.
//
#include "lin_reg_old.h"
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#include "../cost/cost_old.h"
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#include "../lin_alg/lin_alg_old.h"
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#include "../regularization/reg_old.h"
#include "../stat/stat_old.h"
#include "../utilities/utilities.h"
#include <cmath>
#include <iostream>
#include <random>
MLPPLinRegOld::MLPPLinRegOld(std::vector<std::vector<real_t>> p_inputSet, std::vector<real_t> p_outputSet, std::string p_reg, real_t p_lambda, real_t p_alpha) {
inputSet = p_inputSet;
outputSet = p_outputSet;
n = p_inputSet.size();
k = p_inputSet[0].size();
reg = p_reg;
lambda = p_lambda;
alpha = p_alpha;
y_hat.resize(n);
weights = MLPPUtilities::weightInitialization(k);
bias = MLPPUtilities::biasInitialization();
}
std::vector<real_t> MLPPLinRegOld::modelSetTest(std::vector<std::vector<real_t>> X) {
return Evaluate(X);
}
real_t MLPPLinRegOld::modelTest(std::vector<real_t> x) {
return Evaluate(x);
}
void MLPPLinRegOld::NewtonRaphson(real_t learning_rate, int max_epoch, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
forwardPass();
while (true) {
cost_prev = Cost(y_hat, outputSet);
std::vector<real_t> error = alg.subtraction(y_hat, outputSet);
// Calculating the weight gradients (2nd derivative)
std::vector<real_t> first_derivative = alg.mat_vec_mult(alg.transpose(inputSet), error);
std::vector<std::vector<real_t>> second_derivative = alg.matmult(alg.transpose(inputSet), inputSet);
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate / n, alg.mat_vec_mult(alg.transpose(alg.inverse(second_derivative)), first_derivative)));
weights = regularization.regWeights(weights, lambda, alpha, reg);
// Calculating the bias gradients (2nd derivative)
bias -= learning_rate * alg.sum_elements(error) / n; // We keep this the same. The 2nd derivative is just [1].
forwardPass();
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputSet));
MLPPUtilities::UI(weights, bias);
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
}
void MLPPLinRegOld::gradientDescent(real_t learning_rate, int max_epoch, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
forwardPass();
while (true) {
cost_prev = Cost(y_hat, outputSet);
std::vector<real_t> error = alg.subtraction(y_hat, outputSet);
// Calculating the weight gradients
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate / n, alg.mat_vec_mult(alg.transpose(inputSet), error)));
weights = regularization.regWeights(weights, lambda, alpha, reg);
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / n;
forwardPass();
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputSet));
MLPPUtilities::UI(weights, bias);
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
}
void MLPPLinRegOld::SGD(real_t learning_rate, int max_epoch, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
while (true) {
std::random_device rd;
std::default_random_engine generator(rd());
std::uniform_int_distribution<int> distribution(0, int(n - 1));
int outputIndex = distribution(generator);
real_t y_hat = Evaluate(inputSet[outputIndex]);
cost_prev = Cost({ y_hat }, { outputSet[outputIndex] });
real_t error = y_hat - outputSet[outputIndex];
// Weight updation
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate * error, inputSet[outputIndex]));
weights = regularization.regWeights(weights, lambda, alpha, reg);
// Bias updation
bias -= learning_rate * error;
y_hat = Evaluate({ inputSet[outputIndex] });
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost({ y_hat }, { outputSet[outputIndex] }));
MLPPUtilities::UI(weights, bias);
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::MBGD(real_t learning_rate, int max_epoch, int mini_batch_size, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error)));
weights = regularization.regWeights(weights, lambda, alpha, reg);
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size();
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::Momentum(real_t learning_rate, int max_epoch, int mini_batch_size, real_t gamma, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
// Initializing necessary components for Momentum.
std::vector<real_t> v = alg.zerovec(weights.size());
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
std::vector<real_t> gradient = alg.scalarMultiply(1 / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error));
std::vector<real_t> RegDerivTerm = regularization.regDerivTerm(weights, lambda, alpha, reg);
std::vector<real_t> weight_grad = alg.addition(gradient, RegDerivTerm); // Weight_grad_final
v = alg.addition(alg.scalarMultiply(gamma, v), alg.scalarMultiply(learning_rate, weight_grad));
weights = alg.subtraction(weights, v);
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size(); // As normal
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::NAG(real_t learning_rate, int max_epoch, int mini_batch_size, real_t gamma, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
// Initializing necessary components for Momentum.
std::vector<real_t> v = alg.zerovec(weights.size());
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
weights = alg.subtraction(weights, alg.scalarMultiply(gamma, v)); // "Aposterori" calculation
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
std::vector<real_t> gradient = alg.scalarMultiply(1 / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error));
std::vector<real_t> RegDerivTerm = regularization.regDerivTerm(weights, lambda, alpha, reg);
std::vector<real_t> weight_grad = alg.addition(gradient, RegDerivTerm); // Weight_grad_final
v = alg.addition(alg.scalarMultiply(gamma, v), alg.scalarMultiply(learning_rate, weight_grad));
weights = alg.subtraction(weights, v);
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size(); // As normal
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::Adagrad(real_t learning_rate, int max_epoch, int mini_batch_size, real_t e, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
// Initializing necessary components for Adagrad.
std::vector<real_t> v = alg.zerovec(weights.size());
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
std::vector<real_t> gradient = alg.scalarMultiply(1 / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error));
std::vector<real_t> RegDerivTerm = regularization.regDerivTerm(weights, lambda, alpha, reg);
std::vector<real_t> weight_grad = alg.addition(gradient, RegDerivTerm); // Weight_grad_final
v = alg.hadamard_product(weight_grad, weight_grad);
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate, alg.elementWiseDivision(weight_grad, alg.sqrt(alg.scalarAdd(e, v)))));
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size(); // As normal
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::Adadelta(real_t learning_rate, int max_epoch, int mini_batch_size, real_t b1, real_t e, bool UI) {
// Adagrad upgrade. Momentum is applied.
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
// Initializing necessary components for Adagrad.
std::vector<real_t> v = alg.zerovec(weights.size());
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
std::vector<real_t> gradient = alg.scalarMultiply(1 / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error));
std::vector<real_t> RegDerivTerm = regularization.regDerivTerm(weights, lambda, alpha, reg);
std::vector<real_t> weight_grad = alg.addition(gradient, RegDerivTerm); // Weight_grad_final
v = alg.addition(alg.scalarMultiply(b1, v), alg.scalarMultiply(1 - b1, alg.hadamard_product(weight_grad, weight_grad)));
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate, alg.elementWiseDivision(weight_grad, alg.sqrt(alg.scalarAdd(e, v)))));
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size(); // As normal
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::Adam(real_t learning_rate, int max_epoch, int mini_batch_size, real_t b1, real_t b2, real_t e, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
// Initializing necessary components for Adam.
std::vector<real_t> m = alg.zerovec(weights.size());
std::vector<real_t> v = alg.zerovec(weights.size());
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
std::vector<real_t> gradient = alg.scalarMultiply(1 / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error));
std::vector<real_t> RegDerivTerm = regularization.regDerivTerm(weights, lambda, alpha, reg);
std::vector<real_t> weight_grad = alg.addition(gradient, RegDerivTerm); // Weight_grad_final
m = alg.addition(alg.scalarMultiply(b1, m), alg.scalarMultiply(1 - b1, weight_grad));
v = alg.addition(alg.scalarMultiply(b2, v), alg.scalarMultiply(1 - b2, alg.exponentiate(weight_grad, 2)));
std::vector<real_t> m_hat = alg.scalarMultiply(1 / (1 - pow(b1, epoch)), m);
std::vector<real_t> v_hat = alg.scalarMultiply(1 / (1 - pow(b2, epoch)), v);
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate, alg.elementWiseDivision(m_hat, alg.scalarAdd(e, alg.sqrt(v_hat)))));
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size(); // As normal
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::Adamax(real_t learning_rate, int max_epoch, int mini_batch_size, real_t b1, real_t b2, real_t e, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
std::vector<real_t> m = alg.zerovec(weights.size());
std::vector<real_t> u = alg.zerovec(weights.size());
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
std::vector<real_t> gradient = alg.scalarMultiply(1 / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error));
std::vector<real_t> RegDerivTerm = regularization.regDerivTerm(weights, lambda, alpha, reg);
std::vector<real_t> weight_grad = alg.addition(gradient, RegDerivTerm); // Weight_grad_final
m = alg.addition(alg.scalarMultiply(b1, m), alg.scalarMultiply(1 - b1, weight_grad));
u = alg.max(alg.scalarMultiply(b2, u), alg.abs(weight_grad));
std::vector<real_t> m_hat = alg.scalarMultiply(1 / (1 - pow(b1, epoch)), m);
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate, alg.elementWiseDivision(m_hat, u)));
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size(); // As normal
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::Nadam(real_t learning_rate, int max_epoch, int mini_batch_size, real_t b1, real_t b2, real_t e, bool UI) {
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MLPPLinAlgOld alg;
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MLPPRegOld regularization;
real_t cost_prev = 0;
int epoch = 1;
// Creating the mini-batches
int n_mini_batch = n / mini_batch_size;
auto batches = MLPPUtilities::createMiniBatches(inputSet, outputSet, n_mini_batch);
auto inputMiniBatches = std::get<0>(batches);
auto outputMiniBatches = std::get<1>(batches);
// Initializing necessary components for Adam.
std::vector<real_t> m = alg.zerovec(weights.size());
std::vector<real_t> v = alg.zerovec(weights.size());
std::vector<real_t> m_final = alg.zerovec(weights.size());
while (true) {
for (int i = 0; i < n_mini_batch; i++) {
std::vector<real_t> y_hat = Evaluate(inputMiniBatches[i]);
cost_prev = Cost(y_hat, outputMiniBatches[i]);
std::vector<real_t> error = alg.subtraction(y_hat, outputMiniBatches[i]);
// Calculating the weight gradients
std::vector<real_t> gradient = alg.scalarMultiply(1 / outputMiniBatches[i].size(), alg.mat_vec_mult(alg.transpose(inputMiniBatches[i]), error));
std::vector<real_t> RegDerivTerm = regularization.regDerivTerm(weights, lambda, alpha, reg);
std::vector<real_t> weight_grad = alg.addition(gradient, RegDerivTerm); // Weight_grad_final
m = alg.addition(alg.scalarMultiply(b1, m), alg.scalarMultiply(1 - b1, weight_grad));
v = alg.addition(alg.scalarMultiply(b2, v), alg.scalarMultiply(1 - b2, alg.exponentiate(weight_grad, 2)));
m_final = alg.addition(alg.scalarMultiply(b1, m), alg.scalarMultiply((1 - b1) / (1 - pow(b1, epoch)), weight_grad));
std::vector<real_t> m_hat = alg.scalarMultiply(1 / (1 - pow(b1, epoch)), m);
std::vector<real_t> v_hat = alg.scalarMultiply(1 / (1 - pow(b2, epoch)), v);
weights = alg.subtraction(weights, alg.scalarMultiply(learning_rate, alg.elementWiseDivision(m_final, alg.scalarAdd(e, alg.sqrt(v_hat)))));
// Calculating the bias gradients
bias -= learning_rate * alg.sum_elements(error) / outputMiniBatches[i].size(); // As normal
y_hat = Evaluate(inputMiniBatches[i]);
if (UI) {
MLPPUtilities::CostInfo(epoch, cost_prev, Cost(y_hat, outputMiniBatches[i]));
MLPPUtilities::UI(weights, bias);
}
}
epoch++;
if (epoch > max_epoch) {
break;
}
}
forwardPass();
}
void MLPPLinRegOld::normalEquation() {
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MLPPLinAlgOld alg;
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MLPPStatOld stat;
std::vector<real_t> x_means;
std::vector<std::vector<real_t>> inputSetT = alg.transpose(inputSet);
x_means.resize(inputSetT.size());
for (uint32_t i = 0; i < inputSetT.size(); i++) {
x_means[i] = (stat.mean(inputSetT[i]));
}
//try {
std::vector<real_t> temp;
temp.resize(k);
temp = alg.mat_vec_mult(alg.inverse(alg.matmult(alg.transpose(inputSet), inputSet)), alg.mat_vec_mult(alg.transpose(inputSet), outputSet));
if (std::isnan(temp[0])) {
//throw 99;
//TODO ERR_FAIL_COND
std::cout << "ERR: Resulting matrix was noninvertible/degenerate, and so the normal equation could not be performed. Try utilizing gradient descent." << std::endl;
return;
} else {
if (reg == "Ridge") {
weights = alg.mat_vec_mult(alg.inverse(alg.addition(alg.matmult(alg.transpose(inputSet), inputSet), alg.scalarMultiply(lambda, alg.identity(k)))), alg.mat_vec_mult(alg.transpose(inputSet), outputSet));
} else {
weights = alg.mat_vec_mult(alg.inverse(alg.matmult(alg.transpose(inputSet), inputSet)), alg.mat_vec_mult(alg.transpose(inputSet), outputSet));
}
bias = stat.mean(outputSet) - alg.dot(weights, x_means);
forwardPass();
}
//} catch (int err_num) {
// std::cout << "ERR " << err_num << ": Resulting matrix was noninvertible/degenerate, and so the normal equation could not be performed. Try utilizing gradient descent." << std::endl;
//}
}
real_t MLPPLinRegOld::score() {
MLPPUtilities util;
return util.performance(y_hat, outputSet);
}
void MLPPLinRegOld::save(std::string fileName) {
MLPPUtilities util;
util.saveParameters(fileName, weights, bias);
}
real_t MLPPLinRegOld::Cost(std::vector<real_t> y_hat, std::vector<real_t> y) {
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MLPPRegOld regularization;
class MLPPCostOld cost;
return cost.MSE(y_hat, y) + regularization.regTerm(weights, lambda, alpha, reg);
}
std::vector<real_t> MLPPLinRegOld::Evaluate(std::vector<std::vector<real_t>> X) {
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MLPPLinAlgOld alg;
return alg.scalarAdd(bias, alg.mat_vec_mult(X, weights));
}
real_t MLPPLinRegOld::Evaluate(std::vector<real_t> x) {
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MLPPLinAlgOld alg;
return alg.dot(weights, x) + bias;
}
// wTx + b
void MLPPLinRegOld::forwardPass() {
y_hat = Evaluate(inputSet);
}