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527 lines
15 KiB
C++
527 lines
15 KiB
C++
/**************************************************************************************************
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* LibNeural++ v.0.4 - All-purpose library for managing neural networks *
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* Copyright (C) 2009, BlackLight *
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* *
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* This program is free software: you can redistribute it and/or modify it under the terms of the *
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* GNU General Public License as published by the Free Software Foundation, either version 3 of *
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* the License, or (at your option) any later version. This program is distributed in the hope *
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* that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of *
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* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for *
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* more details. You should have received a copy of the GNU General Public License along with *
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* this program. If not, see <http://www.gnu.org/licenses/>. *
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**************************************************************************************************/
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#ifndef __cplusplus
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#error "This is a C++ library, you know, so you'd better use a C++ compiler to compile it"
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#else
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#ifndef __NEURALPP
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#define __NEURALPP
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#include <vector>
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#include <string>
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#include <cmath>
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#include "neural++_exception.hpp"
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//! Default rand value: |sin(rand)|, always >= 0 and <= 1
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#define RAND (double) ( (rand() / (RAND_MAX/2)) - 1)
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//! Initial value for the inertial momentum of the synapses
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#define BETA0 0.8
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/**
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* @namespace neuralpp
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* @brief Main namespace for the library
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*/
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namespace neuralpp {
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class Synapsis;
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class Neuron;
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class Layer;
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class NeuralNet;
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double df (double (*f)(double), double x);
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/**
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* @class NeuralNet
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* @brief Main project's class. Use *ONLY* this class, unless you know what you're doing
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*/
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class NeuralNet {
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int epochs;
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int ref_epochs;
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double l_rate;
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//double ex;
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std::vector<double> ex;
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/**
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* @brief It updates the weights of the net's synapsis through back-propagation.
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* In-class use only
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*/
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void updateWeights();
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/**
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* @brief It commits the changes made by updateWeights() to the layer l.
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* In-class use only
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* @param l Layer to commit the changes
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*/
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void commitChanges (Layer& l);
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/**
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* @brief Get the error made on the expected result as squared deviance
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* @param ex Expected value
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* @return Mean error
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*/
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double error(double ex) const;
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/**
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* @brief Private pointer to function, containing the function to
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* be used as activation function
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*/
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double (*actv_f)(double);
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public:
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Layer* input;
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Layer* hidden;
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Layer* output;
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/**
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* @brief Enum to choose the eventual training source for our network (XML from a file or from a string)
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*/
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typedef enum { file, str } source;
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/**
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* @brief Empty constructor for the class - it just makes nothing
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*/
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NeuralNet() {}
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/**
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* @brief Constructor
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* @param in_size Size of the input layer
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* @param hidden_size Size of the hidden layer
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* @param out_size Size of the output layer
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* @param l learn rate (get it after doing some experiments, but generally try to
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* keep its value quite low to be more accurate)
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* @param e Epochs (cycles) to execute (the most you execute, the most the network
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* can be accurate for its purpose)
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*/
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NeuralNet (size_t in_size, size_t hidden_size, size_t out_size, double l, int e);
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/**
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* @brief Constructor
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* @param file Binary file containing a neural network previously saved by save() method
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* @throw NetworkFileNotFoundException
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*/
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NeuralNet (const std::string file) throw(NetworkFileNotFoundException);
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/**
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* @brief Constructor
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* @param in_size Size of the input layer
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* @param hidden_size Size of the hidden layer
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* @param out_size Size of the output layer
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* @param actv Activation function to use (default: f(x)=x)
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* @param l learn rate (get it after doing some experiments, but generally try to
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* keep its value quite low to be more accurate)
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* @param e Epochs (cycles) to execute (the most you execute, the most the network
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* can be accurate for its purpose)
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*/
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NeuralNet (size_t in_size, size_t hidden_size, size_t out_size,
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double(*actv)(double), double l, int e);
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/**
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* @brief It gets the output of the network (note: the layer output should contain
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* an only neuron)
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* @return The output value of the network
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*/
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double getOutput() const;
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/**
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* @brief It gets the output of the network in case the output layer contains more neurons
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* @return A vector containing the output values of the network
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*/
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std::vector<double> getOutputs();
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/**
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* @brief Get the expected value (in case you have an only neuron in output layer). Of course you should specify this when you
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* build your network by using setExpected.
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* @return The expected output value for a certain training phase
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*/
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double expected() const;
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/**
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* @brief Get the expected value (in case you have an only neuron in output layer). Of course you should specify this when you
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* build your network by using setExpected.
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* @return The expected output value for a certain training phase
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*/
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std::vector<double> getExpected() const;
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/**
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* @brief It sets the value you expect from your network (in case the network has an only neuron in its output layer)
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* @param ex Expected output value
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*/
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void setExpected(double ex);
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/**
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* @brief Set the values you expect from your network
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* @param ex Expected output values
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*/
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void setExpected(std::vector<double> ex);
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/**
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* @brief It updates through back-propagation the weights of the synapsis and
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* computes again the output value for <i>epochs</i> times, calling back
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* updateWeights and commitChanges functions
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*/
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void update();
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/**
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* @brief It propagates values through the network. Use this when you want to give
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* an already trained network some new values the get to the output
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*/
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void propagate();
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/**
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* @brief It sets the input for the network
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* @param v Vector of doubles, containing the values to give to your network
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*/
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void setInput (std::vector<double> v);
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/**
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* @brief It links the layers of the network (input, hidden, output). Don't use unless
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* you exactly know what you're doing, it is already called by the constructor
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*/
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void link();
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/**
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* @brief Save a trained neural network to a binary file
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* @param fname Binary file where you're going to save your network
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* @throws NetworkFileWriteException When you get an error writing the network's information to
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* a file
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*/
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void save (const char* fname) throw(NetworkFileWriteException);
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/**
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* @brief Train a network using a training set loaded from an XML file. A sample XML file
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* is available in examples/adder.xml
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* @param xml XML file containing our training set
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* @param src Source type from which the XML will be loaded (from a file [default] or from a string)
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* @throw InvalidXMLException
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*/
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void train (std::string xml, source src) throw(InvalidXMLException);
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/**
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* @brief Initialize the training XML for the neural network
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* @param xml String that will contain the XML
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*/
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static void initXML (std::string& xml);
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/**
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* @brief Splits a string into a vector of doubles, given a delimitator
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* @param delim Delimitator
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* @param str String to be splitted
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* @return Vector of doubles containing splitted values
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*/
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static std::vector<double> split (char delim, std::string str);
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/**
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* @brief Get a training set from a string and copies it to an XML
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* For example, these strings could be training sets for making sums:
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* "2,3;5" - "5,6;11" - "2,2;4" - "4,5:9"
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* This method called on the first string will return an XML such this:
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* '<training id="0"><input id="0">2</input><input id="1">3</input><output id="0">5</output>
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* </training>'
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*
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* @param id ID for the given training set (0,1,..,n)
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* @param set String containing input values and expected outputs
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* @return XML string
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*/
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static std::string XMLFromSet (int id, std::string set);
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/**
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* @brief Closes an open XML document generated by "initXML" and "XMLFromSet"
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* @param xml XML string to be closed
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*/
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static void closeXML(std::string& xml);
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};
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/**
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* @class Synapsis
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* @brief Class for managing synapsis. Don't use this class directly unless you know what
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* you're doing, use NeuralNet instead
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*/
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class Synapsis {
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double delta;
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double prev_delta;
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double weight;
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Neuron *in;
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Neuron *out;
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double (*actv_f)(double);
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public:
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/**
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* @brief Constructor
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* @param i Input neuron
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* @param o Output neuron
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* @param w Weight for the synapsis
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* @param d Delta for the synapsis
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*/
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Synapsis(Neuron* i, Neuron* o, double w, double d);
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/**
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* @brief Constructor
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* @param i Input neuron
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* @param o Output neuron
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* @param a Activation function
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*/
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Synapsis (Neuron* i, Neuron* o, double(*a)(double));
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/**
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* @brief Constructor
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* @param i Input neuron
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* @param o Output neuron
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* @param w Weight for the synapsis (default: random)
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* @param a Activation function
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*/
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Synapsis (Neuron* i, Neuron* o,
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double w, double(*a)(double));
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/**
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* @return Reference to input neuron of the synapsis
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*/
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Neuron* getIn();
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/**
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* @return Reference to output neuron of the synapsis
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*/
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Neuron* getOut();
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/**
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* @brief Set the weight of the synapsis
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* @param w Weight to be set
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*/
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void setWeight(double w) throw(InvalidSynapticalWeightException);
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/**
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* @brief It sets the delta (how much to change the weight after an update)
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* of the synapsis
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* @param d Delta to be set
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*/
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void setDelta(double d) throw(InvalidSynapticalWeightException);
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/**
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* @brief Return the weight of the synapsis
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* @return Weight of the synapsis
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*/
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double getWeight();
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/**
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* @brief Return the delta of the synapsis
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* @return Delta of the synapsis
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*/
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double getDelta();
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/**
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* @brief Get the delta of the synapsis at the previous iteration
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* @return The previous delta
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*/
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double getPrevDelta();
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/**
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* @brief Get the inertial momentum of a synapsis. This value is inversely proportional
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* to the number of steps done in the learning phase (quite high at the beginning, decreasing
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* to zero towards the end of the learning algorithm), and is needed to avoid strong
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* oscillations in output values at the beginning, caused by the random values assigned to
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* the synaptical weights
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* @param N The number of iterations the network must have to adjust the output values
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* @param x The number of iterations already taken
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* @return The inertial momentum of the synapsis
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*/
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double momentum (int N, int x);
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};
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/**
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* @class Neuron
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* @brief Class for managing neurons. Don't use this class directly unless you know what
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* you're doing, use NeuralNet instead
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*/
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class Neuron {
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double actv_val;
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double prop_val;
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std::vector< Synapsis > in;
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std::vector< Synapsis > out;
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double (*actv_f)(double);
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public:
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/**
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* @brief Constructor
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* @param a Activation function
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*/
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Neuron (double (*a)(double));
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/**
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* @brief Alternative constructor, that gets also the synapsis linked to the neuron
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* @param in Input synapses
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* @param out Output synapses
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* @param a Activation function
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*/
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Neuron (std::vector<Synapsis> in, std::vector<Synapsis> out,
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double (*a)(double));
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/**
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* @brief Get the i-th synapsis connected on the input of the neuron
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* @param i Index of the input synapsis to get
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* @return Reference to the i-th synapsis
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*/
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Synapsis& synIn (size_t i);
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/**
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* @brief Get the i-th synapsis connected on the output of the neuron
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* @param i Index of the output synapsis to get
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* @return Reference to the i-th synapsis
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*/
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Synapsis& synOut (size_t i);
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/**
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* @brief It pushes a new input synapsis
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* @param s Synapsis to be pushed
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*/
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void push_in (Synapsis s);
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/**
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* @brief It pushes a new output synapsis
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* @param s Synapsis to be pushed
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*/
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void push_out (Synapsis s);
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/**
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* @brief Change the activation value of the neuron
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* @param a Activation value
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*/
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void setActv (double a);
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/**
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* @brief Change the propagation value of the neuron
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* @param p Propagation value
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*/
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void setProp (double p);
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/**
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* @brief Get the activation value of the neuron
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* @return Activation value for the neuron
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*/
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double getActv();
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/**
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* @brief Get the propagation value of the neuron
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* @return Propagation value for the neuron
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*/
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double getProp();
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/**
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* @brief Compute the propagation value of the neuron and set it
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*/
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void propagate();
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/**
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* @brief Get the number of input synapsis for the neuron
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* @return Number of input synapsis
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*/
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size_t nIn();
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/**
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* @brief Get the number of output synapsis for the neuron
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* @return Number of output synapsis
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*/
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size_t nOut();
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/**
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* @brief Remove input and output synapsis from a neuron
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*/
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void synClear();
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};
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/**
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* @class Layer
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* @brief Class for managing layers of neurons. Don't use this class directly unless you know what
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* you're doing, use NeuralNet instead
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*/
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class Layer {
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std::vector<Neuron> elements;
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void (*update_weights)();
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double (*actv_f)(double);
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public:
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/**
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* @brief Constructor
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* @param sz Size of the layer
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* @param a Activation function
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*/
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Layer (size_t sz, double (*a)(double));
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/**
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* @brief Alternative constructor. It directly gets a vector of neurons to build
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* the layer
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* @param neurons Vector of neurons to be included in the layer
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* @param a Activation function
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*/
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Layer (std::vector<Neuron>& neurons, double(*a)(double));
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/**
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* @brief Redefinition for operator []. It gets the neuron at <i>i</i>
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* @param i Index of the neuron to get in the layer
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* @return Reference to the i-th neuron
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*/
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Neuron& operator[] (size_t i) throw(NetworkIndexOutOfBoundsException);
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/**
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* @brief It links a layer to another
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* @param l Layer to connect to the current as input layer
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*/
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void link (Layer& l);
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/**
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* @brief Set the input values for the neurons of the layer (just use it for the input layer)
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* @param v Vector containing the input values
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*/
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void setInput (std::vector<double> v);
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/**
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* @brief It propagates its activation values to the output layers
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*/
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void propagate();
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/**
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* @return Number of neurons in the layer
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*/
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size_t size() const;
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};
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struct netrecord {
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int input_size;
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int hidden_size;
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int output_size;
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int epochs;
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double l_rate;
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double ex;
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};
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struct neuronrecord {
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double prop;
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double actv;
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};
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struct synrecord {
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double w;
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double d;
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};
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}
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#endif
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#endif
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