C NN added
aaaa
5 years ago
parent
9aa0c85221
commit
afaf44fc06
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#include <stdio.h>
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main() {
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for(int i=0; i<1000000; i++){
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printf("number %d\n", i);
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}
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}
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#include <stdio.h>
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#include <stdlib.h>
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#include <time.h>
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#include <math.h>
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#include <fcntl.h>
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#define NUMPAT 4
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#define NUMIN 2
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#define NUMHID 2
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#define NUMOUT 1
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#define rando() ((double)rand()/((double)RAND_MAX+1))
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main() {
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int i, j, k, p, np, op, ranpat[NUMPAT+1], epoch;
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int NumPattern = NUMPAT, NumInput = NUMIN, NumHidden = NUMHID, NumOutput = NUMOUT;
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double Input[NUMPAT+1][NUMIN+1] = { 0, 0, 0, 0, 0, 0, 0, 1, 0, 0, 0, 1, 0, 1, 1 };
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double Target[NUMPAT+1][NUMOUT+1] = { 0, 0, 0, 0, 0, 1, 0, 1, 0, 0 };
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double SumH[NUMPAT+1][NUMHID+1], WeightIH[NUMIN+1][NUMHID+1], Hidden[NUMPAT+1][NUMHID+1];
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double SumO[NUMPAT+1][NUMOUT+1], WeightHO[NUMHID+1][NUMOUT+1], Output[NUMPAT+1][NUMOUT+1];
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double DeltaO[NUMOUT+1], SumDOW[NUMHID+1], DeltaH[NUMHID+1];
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double DeltaWeightIH[NUMIN+1][NUMHID+1], DeltaWeightHO[NUMHID+1][NUMOUT+1];
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double Error, eta = 0.5, alpha = 0.9, smallwt = 0.5;
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/*random values for the networks weights*/
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for( j = 1 ; j <= NumHidden ; j++ ) { /* initialize WeightIH and DeltaWeightIH */
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for( i = 0 ; i <= NumInput ; i++ ) {
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DeltaWeightIH[i][j] = 0.0 ;
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WeightIH[i][j] = 2.0 * ( rando() - 0.5 ) * smallwt ;
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}
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}
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for( k = 1 ; k <= NumOutput ; k ++ ) { /* initialize WeightHO and DeltaWeightHO */
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for( j = 0 ; j <= NumHidden ; j++ ) {
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DeltaWeightHO[j][k] = 0.0 ;
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WeightHO[j][k] = 2.0 * ( rando() - 0.5 ) * smallwt ;
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}
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}
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for( epoch = 0 ; epoch < 10000000 ; epoch++) { /* iterate weight updates */
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for( p = 1 ; p <= NumPattern ; p++ ) { /* randomize order of individuals */
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ranpat[p] = p ;
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}
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for( p = 1 ; p <= NumPattern ; p++) {
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np = p + rando() * ( NumPattern + 1 - p ) ;
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op = ranpat[p] ; ranpat[p] = ranpat[np] ; ranpat[np] = op ;
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}
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Error = 0.0 ;
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for( np = 1 ; np <= NumPattern ; np++ ) { /* repeat for all the training patterns */
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p = ranpat[np];
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for( j = 1 ; j <= NumHidden ; j++ ) { /* compute hidden unit activations */
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SumH[p][j] = WeightIH[0][j] ;
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for( i = 1 ; i <= NumInput ; i++ ) {
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SumH[p][j] += Input[p][i] * WeightIH[i][j] ;
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}
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/*Thats the sigmoid function*/
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Hidden[p][j] = 1.0/(1.0 + exp(-SumH[p][j])) ;
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}
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for( k = 1 ; k <= NumOutput ; k++ ) { /* compute output unit activations and errors */
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SumO[p][k] = WeightHO[0][k] ;
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for( j = 1 ; j <= NumHidden ; j++ ) {
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SumO[p][k] += Hidden[p][j] * WeightHO[j][k] ;
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}
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Output[p][k] = 1.0/(1.0 + exp(-SumO[p][k])) ; /* Sigmoidal Outputs */
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/* Output[p][k] = SumO[p][k]; Linear Outputs */
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Error += 0.5 * (Target[p][k] - Output[p][k]) * (Target[p][k] - Output[p][k]) ; /* SSE */
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/* Error -= ( Target[p][k] * log( Output[p][k] ) + ( 1.0 - Target[p][k] ) * log( 1.0 - Output[p][k] ) ) ; Cross-Entropy Error */
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DeltaO[k] = (Target[p][k] - Output[p][k]) * Output[p][k] * (1.0 - Output[p][k]) ; /* Sigmoidal Outputs, SSE */
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/* DeltaO[k] = Target[p][k] - Output[p][k]; Sigmoidal Outputs, Cross-Entropy Error */
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/* DeltaO[k] = Target[p][k] - Output[p][k]; Linear Outputs, SSE */
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}
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for( j = 1 ; j <= NumHidden ; j++ ) { /* 'back-propagate' errors to hidden layer */
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SumDOW[j] = 0.0 ;
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for( k = 1 ; k <= NumOutput ; k++ ) {
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SumDOW[j] += WeightHO[j][k] * DeltaO[k] ;
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}
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DeltaH[j] = SumDOW[j] * Hidden[p][j] * (1.0 - Hidden[p][j]) ;
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}
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for( j = 1 ; j <= NumHidden ; j++ ) { /* update weights WeightIH */
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DeltaWeightIH[0][j] = eta * DeltaH[j] + alpha * DeltaWeightIH[0][j] ;
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WeightIH[0][j] += DeltaWeightIH[0][j] ;
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for( i = 1 ; i <= NumInput ; i++ ) {
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DeltaWeightIH[i][j] = eta * Input[p][i] * DeltaH[j] + alpha * DeltaWeightIH[i][j];
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WeightIH[i][j] += DeltaWeightIH[i][j] ;
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}
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}
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for( k = 1 ; k <= NumOutput ; k ++ ) { /* update weights WeightHO */
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DeltaWeightHO[0][k] = eta * DeltaO[k] + alpha * DeltaWeightHO[0][k] ;
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WeightHO[0][k] += DeltaWeightHO[0][k] ;
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for( j = 1 ; j <= NumHidden ; j++ ) {
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DeltaWeightHO[j][k] = eta * Hidden[p][j] * DeltaO[k] + alpha * DeltaWeightHO[j][k] ;
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WeightHO[j][k] += DeltaWeightHO[j][k] ;
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}
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}
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}
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if( epoch%100 == 0 ) fprintf(stdout, "\nEpoch %-5d : Error = %f", epoch, Error) ;
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if( Error < 0.0004 ) break ; /* stop learning when 'near enough' */
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}
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fprintf(stdout, "\n\nNETWORK DATA - EPOCH %d\n\nPat\t", epoch) ; /* print network outputs */
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for( i = 1 ; i <= NumInput ; i++ ) {
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fprintf(stdout, "Input%-4d\t", i) ;
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}
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for( k = 1 ; k <= NumOutput ; k++ ) {
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fprintf(stdout, "Target%-4d\tOutput%-4d\t", k, k) ;
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}
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for( p = 1 ; p <= NumPattern ; p++ ) {
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fprintf(stdout, "\n%d\t", p) ;
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for( i = 1 ; i <= NumInput ; i++ ) {
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fprintf(stdout, "%f\t", Input[p][i]) ;
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}
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for( k = 1 ; k <= NumOutput ; k++ ) {
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fprintf(stdout, "%f\t%f\t", Target[p][k], Output[p][k]) ;
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}
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}
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fprintf(stdout, "\n\nDONE\n\n") ;
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return 1 ;
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}
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/*******************************************************************************/
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