Merge branch 'Delta-Error-Test' into 'main'

HolyFuckItsAlive See merge request jastornig/c-net!6
2023-09-23 20:27:53 +00:00 · 2023-09-23 20:27:53 +00:00 · dce3e264d9
commit dce3e264d9
parent 7abc600076 411e4db3db
19 changed files with 109466 additions and 0 deletions
--- a/.gitignore
+++ b/.gitignore
@ -0,0 +1,60 @@
 CLion Tings
 cmake-build-debug
 .idea/workspace.xml
 Prerequisites
 *.d
 Object files
 *.o
 *.ko
 *.obj
 *.elf
 Linker output
 *.ilk
 *.map
 *.exp
 Precompiled Headers
 *.gch
 *.pch
 Libraries
 *.lib
 *.a
 *.la
 *.lo
 Shared objects (inc. Windows DLLs)
 *.dll
 *.so
 .so.
 *.dylib
 Executables
 *.exe
 *.out
 *.app
 .i86
 *.x86_64
 *.hex
 Debug files
 *.dSYM/
 *.su
 *.idb
 *.pdb
 Kernel Module Compile Results
 .mod
 *.cmd
 .tmp_versions/
 modules.order
 Module.symvers
 Mkfile.old
 dkms.conf
 /.idea/.name
 /.idea/misc.xml
 /.idea/shelf/Uncommitted_changes_before_Update_at_21_09_23,_09_38_[Changes]/shelved.patch
 /.idea/shelf/Uncommitted_changes_before_Update_at_21_09_23,_09_38_[Changes]/shelved.patch
--- a/.idea/.gitignore
+++ b/.idea/.gitignore
@ -0,0 +1,8 @@
 # Default ignored files
 /shelf/
 /workspace.xml
 # Editor-based HTTP Client requests
 /httpRequests/
 # Datasource local storage ignored files
 /dataSources/
 /dataSources.local.xml
--- a/.idea/c-net.iml
+++ b/.idea/c-net.iml
@ -0,0 +1,2 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <module classpath="CMake" type="CPP_MODULE" version="4" />
--- a/.idea/modules.xml
+++ b/.idea/modules.xml
@ -0,0 +1,8 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="ProjectModuleManager">
    <modules>
      <module fileurl="file://$PROJECT_DIR$/.idea/c-net.iml" filepath="$PROJECT_DIR$/.idea/c-net.iml" />
    </modules>
  </component>
 </project>
--- a/.idea/vcs.xml
+++ b/.idea/vcs.xml
@ -0,0 +1,6 @@
 <?xml version="1.0" encoding="UTF-8"?>
 <project version="4">
  <component name="VcsDirectoryMappings">
    <mapping directory="" vcs="Git" />
  </component>
 </project>
--- a/CMakeLists.txt
+++ b/CMakeLists.txt
@ -0,0 +1,7 @@
 cmake_minimum_required(VERSION 3.22)
 project(c_net C)
 set(CMAKE_C_STANDARD 11)
 add_executable(c_net main.c matrix.c image.c neuronal_network.c util.c util.h)
 target_link_libraries(c_net m)
--- a/data/train-images.idx3-ubyte
+++ b/data/train-images.idx3-ubyte
--- a/data/train-labels.idx1-ubyte
+++ b/data/train-labels.idx1-ubyte
--- a/image.c
+++ b/image.c
@ -0,0 +1,193 @@
 #include <stdio.h>
 #include <stdlib.h>
 #include "image.h"
 #include "matrix.h"
 #include "util.h"
 void big_endian_to_c_uint(const char * bytes, void * target, int size) {
    char* helper = (char*)target;
    for(int i = 0; i < size; i++){
        *(helper+i) = *(bytes+size-i-1);
    }
 }
 void read_until_space_or_newline(char * buff, int maxCount, FILE * fptr){
    int bufferOffset = 0;
    char c = -1;
    do{
        c = (char)getc(fptr);
        buff[bufferOffset++] = c;
    }while(!feof(fptr) && c != 0 && c != ' ' && c !='\n');
    buff[bufferOffset-1] = 0;
 }
 Image * load_pgm_image(char * image_file_string){
    FILE * fptr = fopen(image_file_string, "r");
    Image *image = malloc(sizeof(Image));
    image->label = -1;
    char buffer[100];
    int magic_number = 0;
    fgets(buffer, 4, fptr);
    if(buffer[0] != 'P' || buffer[1] != '5'){
        printf("Wrong file Format");
        exit(1);
    }
    if(fgetc(fptr) ==  '#'){
        fgets(buffer, 1024, fptr);
    }
    int image_width, image_height, image_length, image_white ;
    read_until_space_or_newline(buffer, 10, fptr);
    image_width = strtol(buffer, NULL, 10);
    read_until_space_or_newline(buffer, 10, fptr);
    image_height = strtol(buffer, NULL, 10);
    read_until_space_or_newline(buffer, 10, fptr);
    image_white = strtol(buffer, NULL, 10);
    image_length = image_width * image_height;
    image->pixel_values = matrix_create(image_height, image_width);
    for(int i = 0; i < image_height; i++){
        fread(buffer, 1, 28, fptr);
        for(int j = 0; j < image_width;  j++){
            image->pixel_values->numbers[i][j] = (image_white - (unsigned char)buffer[j]) / 255.0;
        }
    }
    fclose(fptr);
    return image;
 }
 Image** import_images(char* image_file_string, char* label_file_string, int* _number_imported, int count) {
    printf("Loading Images\n");
    // create file pointer for the image and label data
    FILE* image_file = fopen(image_file_string, "r");
    FILE* label_file = fopen(label_file_string, "r");
    // check if the file could be opened
    if(image_file == NULL || label_file == NULL) {
        printf("ERROR: File could not be opened! (import_images)");
        exit(1);
    }
    // check magic number of the files
    char word_buffer[4];
    int buffer_size = sizeof(word_buffer);
    int magic_number_label, magic_number_images, label_count, image_count;
    //Read description of label file
    fread(word_buffer, buffer_size, 1, label_file);
    big_endian_to_c_uint(word_buffer, &magic_number_label, buffer_size);
    fread(word_buffer, 4, 1, label_file);
    big_endian_to_c_uint(word_buffer, &label_count, buffer_size);
    //Read description of file
    fread(word_buffer, 4, 1, image_file);
    big_endian_to_c_uint(word_buffer, &magic_number_images, buffer_size);
    fread(word_buffer, 4, 1, image_file);
    big_endian_to_c_uint(word_buffer, &image_count, buffer_size);
    // compare magic numbers with pre-defined value
    if(magic_number_label != MAGIC_NUMBER_LABEL || magic_number_images != MAGIC_NUMBER_IMAGES) {
        printf("TrainingData or Labels are malformed. Exiting...");
        exit(1);
    }
    if(label_count != image_count){
        printf("Number of images and labels does not match. Exiting...");
        exit(1);
    }
    if(count <= 0){
        count = image_count;
    }
    if(count > image_count){
        count = image_count;
        printf("Number of images exceeds number of available images. Loading all available images");
    }
    int image_height, image_width, image_length;
    //read image dimensions;
    fread(word_buffer, 4, 1, image_file);
    big_endian_to_c_uint(word_buffer, &image_height, buffer_size);
    fread(word_buffer, 4, 1, image_file);
    big_endian_to_c_uint(word_buffer, &image_width, 4);
    image_length = image_height*image_width;
    // allocate memory for the storage of images
    Image** images = malloc(sizeof(Image*) * count);
    if(!images){
        printf("not enough memory");
        exit(1);
    }
    unsigned char byteBuffer[image_length];
    for(int i = 0; i < count; i++){
        if(i%1000 == 0){
            updateBar(i*100/count);
        }
        images[i] = malloc(sizeof(Image));
        fread(&images[i]->label, 1, 1, label_file);
        fread(&byteBuffer, image_width*image_height, 1, image_file);
        images[i]->pixel_values = matrix_create(image_height, image_width);
        for(int j = 0; j < image_length; j++) {
            images[i]->pixel_values->numbers[j / image_width][j % image_width] = byteBuffer[j] / 255.0;
        }
    }
    if(_number_imported != NULL)*_number_imported = count;
    fclose(image_file);
    fclose(label_file);
    updateBar(100);
    printf("\n");
    return images;
 }
 void img_print (Image* img) {
    //print the image
    matrix_print(img->pixel_values);
    //print the number of the image
    printf("Number it is supposed to be: %d\n", img->label);
 }
 void img_visualize(Image* img){
    for(int i = 0; i < img->pixel_values->rows; i++){
        for(int j = 0; j < img->pixel_values->columns; j++){
            img->pixel_values->numbers[i][j] > 0.5 ? putc('#', stdout) : putc(' ', stdout);
        }
        putc('\n', stdout);
    }
    printf("Should be %d\n", img->label);
 }
 void img_free (Image* img) {
    //frees the matrix of image (deep free)
    matrix_free(img->pixel_values);
    //frees the rest of img
    free(img);
 }
 void images_free (Image** images, int quantity){
    //frees every single image
    for(int i=0;i<quantity;i++){
        img_free(images[i]);
    }
    //frees the rest of images
    free(images);
 }
--- a/image.h
+++ b/image.h
@ -0,0 +1,32 @@
 #pragma once
 #include "matrix.h"
 #include "matrix.h"
 typedef struct {
    Matrix* pixel_values;
    char label;
 } Image;
 typedef struct {
    const Image* image;
    const size_t size;
 } Image_Container;
 static const int MAGIC_NUMBER_LABEL = 2049;
 static const int MAGIC_NUMBER_IMAGES = 2051;
 /**
 * reads a specified number of images out of the training dataset
 * @param image_file_string Path to the file containing the image data
 * @param label_file_string Path to the file containing the image labels
 * @param ptr via this pointer, the images can be accessed
 * @param count maximum number of images to be loaded. If it is 0, all available images are loaded.
 * @return
 */
 Image ** import_images(char* image_file_string, char* label_file_string, int* number_imported, int count);
 Image * load_pgm_image(char * image_file_string);
 void img_print (Image* image);
 void img_visualize(Image*image);
 void img_free (Image* image);
--- a/main.c
+++ b/main.c
@ -0,0 +1,29 @@
 #include <stdio.h>
 #include "image.h"
 #include "neuronal_network.h"
 int main() {
    Image** images = import_images("../data/train-images.idx3-ubyte", "../data/train-labels.idx1-ubyte", NULL, 60000);
 //    img_visualize(images[0]);
 //    img_visualize(images[1]);
 //    matrix_print(images[0]->pixel_values);
 //    matrix_print(images[1]->pixel_values);
    Neural_Network* nn = new_network(28*28, 40, 5, 10, 0.08);
    randomize_network(nn, 1);
 //        Neural_Network* nn = load_network("../networks/newest_network.txt");
 //    printf("Done loading!\n");
 //    batch_train(nn, images, 20000, 20);
    for (int i = 0; i < 30000; ++i) {
        train_network(nn, images[i], images[i]->label);
    }
    save_network(nn);
    printf("%lf\n", measure_network_accuracy(nn, images, 10000));
 }
--- a/matrix.c
+++ b/matrix.c
@ -0,0 +1,402 @@
 #include "matrix.h"
 #include <stdlib.h>
 #include <stdio.h>
 #include <math.h>
 #include <time.h>
 #define MAX_BYTES 100
 static int RANDOMIZED = 0;
 // operational functions
 Matrix* matrix_create(int rows, int columns) {
    // allocate memory for the matrix
    Matrix* matrix = malloc(sizeof(Matrix));
    // set size variables to the correct size
    matrix->rows = rows;
    matrix->columns = columns;
    // allocate memory for the numbers (2D-Array)
    matrix->numbers = malloc(sizeof(double*) * rows);
    for (int i = 0; i < rows; i++) {
        matrix->numbers[i] = calloc(sizeof(double), columns);
    }
    // return the pointer to the allocated memory
    return matrix;
 }
 void matrix_fill(Matrix* matrix, double value) {
    // simple for loop to populate the 2D-array with a value
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            matrix->numbers[i][j] = value;
        }
    }
 }
 void matrix_free(Matrix* matrix) {
    // de-allocate every column
    for (int i = 0; i < matrix->rows; i++) {
        free(matrix->numbers[i]);
    }
    // de-allocate the rows
    free(matrix->numbers);
    // de-allocate the matrix
    free(matrix);
 }
 void matrix_print(Matrix *matrix) {
    // print the dimensions of the matrix
    printf("Rows: %d, Columns: %d\n", matrix->rows, matrix->columns);
    // loop through all values and format them into the correct matrix representation
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            printf("%lf ", matrix->numbers[i][j]);
        }
        printf("\n");
    }
 }
 Matrix* matrix_copy(Matrix *matrix) {
    // create another matrix of the same size
    Matrix* copy_of_matrix = matrix_create(matrix->rows, matrix->columns);
    // copy the values from the original matrix into the copy
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            copy_of_matrix->numbers[i][j] = matrix->numbers[i][j];
        }
    }
    // return the pointer to the copy
    return copy_of_matrix;
 }
 // mathematical functions
 /*
 * These methods won't change or free the input matrix.
 * It creates a new matrix, which is modified and then returned.
 * If we don't need the original matrix, we should consider just changing the original matrix and changing the method signature to void.
 */
 Matrix* multiply(Matrix* matrix1, Matrix* matrix2) {
    // check if the two matrices are of the same size
    if(matrix1->rows != matrix2->rows || matrix1->columns != matrix2->columns) {
        printf("ERROR: Size of matrices are not compatible! (Multiply)");
        exit(1);
    }
    // create result matrix
    Matrix* result_matrix = matrix_create(matrix1->rows, matrix1->columns);
    // multiply the values and save them into the result matrix
    for (int i = 0; i < matrix1->rows; i++) {
        for (int j = 0; j < matrix1->columns; j++) {
            result_matrix->numbers[i][j] = matrix1->numbers[i][j] * matrix2->numbers[i][j];
        }
    }
    // return resulting matrix
    return  result_matrix;
 }
 Matrix* add(Matrix* matrix1, Matrix* matrix2) {
    // check if the two matrices are of the same size
    if(matrix1->rows != matrix2->rows || matrix1->columns != matrix2->columns) {
        printf("ERROR: Size of matrices are not compatible! (Add)");
        exit(1);
    }
    // create result matrix
    Matrix* result_matrix = matrix_create(matrix1->rows, matrix1->columns);
    // add the value of the number in matrix 1 to the value of the number in matrix 2
    for (int i = 0; i < matrix1->rows; i++) {
        for (int j = 0; j < matrix1->columns; j++) {
            result_matrix->numbers[i][j] = matrix1->numbers[i][j] + matrix2->numbers[i][j];
        }
    }
    // return the result matrix
    return result_matrix;
 }
 Matrix* subtract(Matrix* matrix1, Matrix* matrix2) {
    // check if the two matrices are of the same size
    if(matrix1->rows != matrix2->rows || matrix1->columns != matrix2->columns) {
        printf("ERROR: Size of matrices are not compatible! (Subtract)");
        exit(1);
    }
    // create result matrix
    Matrix* result_matrix = matrix_create(matrix1->rows, matrix1->columns);
    // subtract the value of the number in matrix 2 from the value of the number in matrix 1
    for (int i = 0; i < matrix1->rows; i++) {
        for (int j = 0; j < matrix1->columns; j++) {
            result_matrix->numbers[i][j] = matrix1->numbers[i][j] - matrix2->numbers[i][j];
        }
    }
    // return the resulting matrix
    return result_matrix;
 }
 Matrix* dot(Matrix* matrix1, Matrix* matrix2) {
    // check if the dimensions of the matrices are compatible to calculate the dot product
    if(matrix1->columns != matrix2->rows) {
        printf("ERROR: Size of matrices are not compatible! (Dot-Product)");
        exit(1);
    }
    // create a new matrix with the dimensions of the dot product;
    Matrix* result_matrix = matrix_create(matrix1->rows, matrix2->columns);
    // iterate through all rows of matrix 1
    for (int i = 0; i < matrix1->rows; i++) {
        // iterate though all columns of matrix 2
        for (int j = 0; j < matrix2->columns; j++) {
            // sum up the products and save them into the result matrix
            result_matrix->numbers[i][j] = 0;
            for (int k = 0; k < matrix2->rows; k++) {
                result_matrix->numbers[i][j] += matrix1->numbers[i][k] * matrix2->numbers[k][j];
            }
        }
    }
    // return result
    return result_matrix;
 }
 Matrix* apply(double (*function)(double), Matrix* matrix) {
    // create a new matrix used to calculate the result
    Matrix* result_matrix = matrix_create(matrix->rows, matrix->columns);
    // apply the function to all values in the matrix
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            result_matrix->numbers[i][j] = (*function)(matrix->numbers[i][j]);
            int k = 0;
        }
    }
    // return resulting matrix
    return result_matrix;
 }
 Matrix* scale(Matrix* matrix, double value) {
    // create a copy of the original matrix
    Matrix* result_matrix = matrix_copy(matrix);
    // iterate over all numbers in the matrix and multiply by the scalar value
    for (int i = 0; i < result_matrix->rows; i++) {
        for (int j = 0; j < result_matrix->columns; j++) {
            result_matrix->numbers[i][j] *= value;
        }
    }
    // return the copy
    return result_matrix;
 }
 Matrix* addScalar(Matrix* matrix, double value) {
    // create a copy of the original matrix
    Matrix* result_matrix = matrix_copy(matrix);
    // iterate over all numbers in the matrix and add the scalar value
    for (int i = 0; i < result_matrix->rows; i++) {
        for (int j = 0; j < result_matrix->columns; j++) {
            result_matrix->numbers[i][j] += value;
        }
    }
    // return the copy
    return result_matrix;
 }
 Matrix* transpose(Matrix* matrix) {
    // create a new matrix of the size n-m, based on the original matrix of size m-n
    Matrix* result_matrix = matrix_create(matrix->columns, matrix->rows);
    // copy the values from the original into the correct place in the copy
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            result_matrix->numbers[j][i] = matrix->numbers[i][j];
        }
    }
    // return the result matrix
    return result_matrix;
 }
 double matrix_sum(Matrix* matrix) {
    double sum = 0;
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            sum += matrix->numbers[i][j];
        }
    }
    return sum;
 }
 void matrix_save(Matrix* matrix, char* file_string){
    // open the file in append mode
    FILE *file = fopen(file_string, "a");
    // check if the file could be found
    if(file == NULL) {
        printf("ERROR: Unable to get handle for \"%s\"! (matrix_save)", file_string);
        exit(1);
    }
    // save the size of the matrix
    fprintf(file, "%d\n", matrix->rows);
    fprintf(file, "%d\n", matrix->columns);
    // save all the numbers of the matrix into the file
    for(int i = 0; i < matrix->rows; i++){
        for(int j = 0; j < matrix->columns; j++){
            fprintf(file, "%.10f\n", matrix->numbers[i][j]);
        }
    }
    // close the file
    fclose(file);
 }
 Matrix* matrix_load(char* file_string){
    FILE *fptr = fopen(file_string, "r");
    if(!fptr){
        printf("Could not open \"%s\"", file_string);
        exit(1);
    }
    Matrix * m = load_next_matrix(fptr);
    fclose(fptr);
    return m;
 }
 Matrix* load_next_matrix(FILE *save_file){
    char buffer[MAX_BYTES];
    fgets(buffer, MAX_BYTES, save_file);
    int rows = (int)strtol(buffer, NULL, 10);
    fgets(buffer, MAX_BYTES, save_file);
    int cols = (int)strtol(buffer, NULL, 10);
    Matrix *matrix = matrix_create(rows, cols);
    for(int i = 0; i < rows; i++){
        for(int j = 0; j < cols; j++){
            fgets(buffer, MAX_BYTES, save_file);
            matrix->numbers[i][j] = strtod(buffer, NULL);
        }
    }
    return matrix;
 }
 Matrix* matrix_flatten(Matrix* matrix, int axis) {
    // Axis = 0 -> Column Vector, Axis = 1 -> Row Vector
    Matrix* result_matrix;
    // Column Vector
    if (axis == 0) {
        result_matrix = matrix_create(matrix -> rows * matrix -> columns, 1);
    }
    // Row Vector
    else if (axis == 1) {
        result_matrix = matrix_create(1, matrix -> rows * matrix -> columns);
    } else {
        printf("ERROR: Argument must be 1 or 0 (matrix_flatten)");
        exit(EXIT_FAILURE);
    }
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            if (axis == 0) result_matrix->numbers[i * matrix->columns + j][0] = matrix->numbers[i][j];
            else if (axis == 1) result_matrix->numbers[0][i * matrix->columns + j] = matrix->numbers[i][j];
        }
    }
    return result_matrix;
 }
 int matrix_argmax(Matrix* matrix) {
    // Expects a Mx1 matrix
    if (matrix->columns != 1){
        printf("ERROR: Matrix is not Mx1 (matrix_argmax)");
        exit(EXIT_FAILURE);
    }
    double max_value = 0;
    int max_index = 0;
    for (int i = 0; i < matrix->rows; i++) {
        if (matrix->numbers[i][0] > max_value) {
            max_value = matrix->numbers[i][0];
            max_index = i;
        }
    }
    return max_index;
 }
 void matrix_randomize(Matrix* matrix, int n) {
    if(!RANDOMIZED){
        srand(time(NULL));
        RANDOMIZED = 1;
    }
    //make a min and max
    double min = -1.0f / sqrt(n);
    double max = 1.0f / sqrt(n);
    //calculate difference
    double difference = max - min;
    //move decimal
    int scaled_difference = (int)(difference * scaling_value);
    for (int i = 0; i < matrix->rows; i++) {
        for (int j = 0; j < matrix->columns; j++) {
            matrix->numbers[i][j] = min + (1.0 * (rand() % scaled_difference) / scaling_value);
        }
    }
 }
 Matrix* matrix_add_bias(Matrix* matrix) {
    if(matrix->columns != 1) {
        printf("ERROR: The size of the matrix does not match an input matrix! (matrix_add_bias)");
        exit(1);
    }
    Matrix* result = matrix_create(matrix->rows + 1, matrix->columns);
    result->numbers[0][0] = 1.0;
    for (int i = 0; i < matrix->rows; ++i) {
        result->numbers[i + 1][0] = matrix->numbers[i][0];
    }
    return result;
 }
--- a/matrix.h
+++ b/matrix.h
@ -0,0 +1,41 @@
 #pragma once
 #include <stdio.h>
 typedef struct {
    int rows, columns;
    double **numbers;
 } Matrix;
 static const int scaling_value = 10000;
 // operational functions
 Matrix* matrix_create(int rows, int columns);
 void matrix_fill(Matrix* matrix, double value);
 void matrix_free(Matrix* matrix);
 void matrix_print(Matrix *matrix);
 Matrix* matrix_copy(Matrix *matrix);
 void matrix_save(Matrix* matrix, char* file_string);
 Matrix* matrix_load(char* file_string);
 Matrix* load_next_matrix(FILE * save_file);
 void matrix_randomize(Matrix* matrix, int n); // don't understand the usage of the n
 int matrix_argmax(Matrix* matrix);
 Matrix* matrix_flatten(Matrix* matrix, int axis);
 Matrix* matrix_add_bias(Matrix* matrix);
 /*
 * These methods won't change or free the input matrix.
 * It creates a new matrix, which is modified and then returned.
 * If we don't need the original matrix, we should consider just changing the original matrix and changing the method signature to void.
 */
 // mathematical functions
 Matrix* multiply(Matrix* matrix1, Matrix* matrix2);
 Matrix* add(Matrix* matrix1, Matrix* matrix2);
 Matrix* subtract(Matrix* matrix1, Matrix* matrix2);
 Matrix* dot(Matrix* matrix1, Matrix* matrix2);
 Matrix* apply(double (*function)(double), Matrix* matrix);
 Matrix* scale(Matrix* matrix, double value);
 Matrix* addScalar(Matrix* matrix, double value);
 Matrix* transpose(Matrix* matrix);
 double matrix_sum(Matrix* matrix);
--- a/networks/89.txt
+++ b/networks/89.txt
--- a/networks/90.txt
+++ b/networks/90.txt
--- a/neuronal_network.c
+++ b/neuronal_network.c
@ -0,0 +1,360 @@
 #include <stdlib.h>
 #include "neuronal_network.h"
 #include <stdio.h>
 #include <math.h>
 double sigmoid(double input);
 Matrix* predict(Neural_Network* network, Matrix* image_data);
 Matrix* sigmoid_derivative(Matrix* matrix);
 Matrix *calculate_weights_delta(Matrix *previous_layer_output, Matrix *delta_matrix, double learning_rate);
 void apply_weights(Neural_Network* network, Matrix* delta_weights_matrix, int index);
 Matrix* calculate_delta_hidden(Matrix* next_layer_delta, Matrix* weights, Matrix* current_layer_output);
 Neural_Network* new_network(int input_size, int hidden_size, int hidden_amount, int output_size, double learning_rate){
    Neural_Network* network = malloc(sizeof(Neural_Network));
    network->input_size = input_size;
    network->hidden_size = hidden_size;
    network->hidden_amount = hidden_amount;
    network->output_size = output_size;
    network->learning_rate = learning_rate;
    Matrix** weights = malloc(sizeof(Matrix*) * (hidden_amount + 1));
    network->weights = weights;
    network->weights[0] = matrix_create(hidden_size, input_size + 1);
    for(int i=1;i<hidden_amount;i++){
        network->weights[i] = matrix_create(hidden_size, hidden_size + 1);
    }
    network->weights[hidden_amount] = matrix_create(output_size, hidden_size + 1);
    return network;
 }
 void randomize_network(Neural_Network* network, int scope){
    for (int i = 0; i < network->hidden_amount + 1; i++) {
        matrix_randomize(network->weights[i], scope);
    }
 }
 void free_network(Neural_Network* network){
    for (int i = 0; i < network->hidden_amount + 1; i++) {
        matrix_free(network->weights[i]);
    }
    free(network->weights);
    free(network);
 }
 void save_network(Neural_Network* network) {
    char* file_name = "../networks/newest_network.txt";
    // create file
    FILE* save_file = fopen(file_name, "w");
    // check if file is successfully opened
    if(save_file == NULL) {
        printf("ERROR: Something went wrong in file creation! (save_network)");
        exit(1);
    }
    // save network size to first line of the file
    fprintf(save_file, "%d\n", network->input_size);
    fprintf(save_file, "%d\n", network->hidden_size);
    fprintf(save_file, "%d\n", network->hidden_amount);
    fprintf(save_file, "%d\n", network->output_size);
    // close the file
    fclose(save_file);
    for (int i = 0; i < network->hidden_amount + 1; ++i) {
        matrix_save(network->weights[i], file_name);
    }
    printf("Network Saved!\n");
 }
 Neural_Network* load_network(char* file) {
    // create file pointer and open file
    FILE* save_file = fopen(file, "r");
    // check if file could be opened
    if(save_file == NULL) {
        printf("ERROR: File could not be opened/found! (load_network)");
        exit(1);
    }
    // read & store the information on the size of the network from the save file
    char buffer[MAX_BYTES];
    fgets(buffer, MAX_BYTES, save_file);
    int input_size = (int) strtol(buffer, NULL, 10);
    fgets(buffer, MAX_BYTES, save_file);
    int hidden_size = (int) strtol(buffer, NULL, 10);
    fgets(buffer, MAX_BYTES, save_file);
    int hidden_amount = (int) strtol(buffer, NULL, 10);
    fgets(buffer, MAX_BYTES, save_file);
    int output_size = (int) strtol(buffer, NULL, 10);
    // create a new network to fill with the saved data
    Neural_Network* saved_network = new_network(input_size, hidden_size, hidden_amount, output_size, 0);
    for (int i = 0; i < saved_network->hidden_amount + 1; ++i) {
        saved_network->weights[i] = load_next_matrix(save_file);
    }
    // return saved network
    fclose(save_file);
    return saved_network;
 }
 void print_network(Neural_Network* network) {
    for (int i = 0; i < network->hidden_amount; ++i) {
        matrix_print(network->weights[i]);
    }
 }
 double measure_network_accuracy(Neural_Network* network, Image** images, int amount) {
    int num_correct = 0;
    for (int i = 0; i < amount; i++) {
        Matrix* prediction = predict_image(network, images[i]);
        int guess = matrix_argmax(prediction);
        int answer = (unsigned char) images[i]->label;
        if (guess == answer) {
            num_correct++;
        }
        matrix_free(prediction);
    }
    return ((double) num_correct) / amount;
 }
 Matrix* predict_image(Neural_Network* network, Image* image){
    Matrix* image_data = matrix_flatten(image->pixel_values, 0);
    Matrix* res = predict(network, image_data);
    matrix_free(image_data);
    return res;
 }
 Matrix* predict(Neural_Network* network, Matrix* image_data) {
    Matrix* input = matrix_add_bias(image_data);
    Matrix* output[network->hidden_amount + 1];
    for (int i = 0; i < network->hidden_amount + 1; ++i) {
        Matrix* neuron_input = dot(network->weights[i], input);
        Matrix* neuron_activation = apply(sigmoid, neuron_input);
        output[i] = neuron_activation;
        matrix_free(neuron_input);
        matrix_free(input);
        input = matrix_add_bias(neuron_activation);
    }
    for (int i = 0; i < network->hidden_amount; ++i) {
        matrix_free(output[i]);
    }
    matrix_free(input);
    return output[network->hidden_amount];
 }
 //void batch_train(Neural_Network* network, Image** images, int amount, int batch_size) {
 //
 //    for (int i = 0; i < amount; ++i) {
 //
 //        if(amount % 1000 == 0) {
 //            printf("1k pics!\n");
 //        }
 //
 //        Matrix* batch_weights[network->hidden_amount + 1];
 //
 //        for (int j = 0; j < batch_size; ++j) {
 //            Matrix** delta_weights = train_network(network, images[i], images[i]->label);
 //
 //            for (int k = 0; k < network->hidden_amount + 1; k++) {
 //                if(j == 0) {
 //                    batch_weights[k] = delta_weights[k];
 //                    continue;
 //                }
 //
 //                Matrix* temp_result = add(batch_weights[k], delta_weights[k]);
 //
 //                matrix_free(batch_weights[k]);
 //                matrix_free(delta_weights[k]);
 //
 //                batch_weights[k] = temp_result;
 //            }
 //
 //            free(delta_weights);
 //        }
 //
 //        for (int j = 0; j < network->hidden_amount + 1; ++j) {
 //            Matrix* average_delta_weight = scale(batch_weights[j], (1.0 / batch_size));
 //            apply_weights(network, average_delta_weight, j);
 //
 //            matrix_free(average_delta_weight);
 //            matrix_free(batch_weights[j]);
 //        }
 //    }
 //}
 void train_network(Neural_Network* network, Image *image, int label) {
    Matrix* image_data = matrix_flatten(image->pixel_values, 0);
    Matrix* input = matrix_add_bias(image_data);
    Matrix* output[network->hidden_amount + 1];
    for (int i = 0; i < network->hidden_amount + 1; ++i) {
        Matrix* neuron_input = dot(network->weights[i], input);
        Matrix* neuron_activation = apply(sigmoid, neuron_input);
        output[i] = neuron_activation;
        matrix_free(neuron_input);
        matrix_free(input);
        input = matrix_add_bias(neuron_activation);
    }
    // back propagation
    //list to store the new weights
    Matrix** delta_weights = malloc(sizeof(Matrix*) * (network->hidden_amount + 1));
    // calculate the derivative of the sigmoid function of the input of the result layer
    Matrix* sigmoid_prime = sigmoid_derivative(output[network->hidden_amount]);
    // create wanted out-put matrix, calculate the difference and delta values (output layer only)
    Matrix* wanted_output = matrix_create(output[network->hidden_amount]->rows, output[network->hidden_amount]->columns);
    matrix_fill(wanted_output, 0);
    wanted_output->numbers[label][0] = 1;
    Matrix* error = subtract(wanted_output, output[network->hidden_amount]);
    Matrix* delta = multiply(sigmoid_prime, error);
    //calculate and apply the delta for all weights in out-put layer
    delta_weights[network->hidden_amount] = calculate_weights_delta(output[network->hidden_amount - 1], delta, network->learning_rate);
    //hidden layers
    Matrix* previous_delta = delta;
    for (int i = network->hidden_amount; i > 1; i--) {
        delta = calculate_delta_hidden(previous_delta, network->weights[i], output[i - 1]);
        delta_weights[i - 1] = calculate_weights_delta(output[i - 2], delta, network->learning_rate);
        matrix_free(previous_delta);
        previous_delta = delta;
    }
    // Input Layer
    delta = calculate_delta_hidden(previous_delta, network->weights[1], output[0]);
    delta_weights[0] = calculate_weights_delta(image_data, delta, network->learning_rate);
    for (int i = 0; i < network->hidden_amount + 1; ++i) {
        apply_weights(network, delta_weights[i], i);
    }
    // De-allocate stuff
    matrix_free(image_data);
    matrix_free(input);
    for (int i = 0; i < network->hidden_amount + 1; ++i) {
        matrix_free(output[i]);
    }
    for (int i = 0; i < network->hidden_amount + 1; ++i) {
        matrix_free(delta_weights[i]);
    }
    matrix_free(sigmoid_prime);
    matrix_free(wanted_output);
    matrix_free(error);
    matrix_free(delta);
    matrix_free(previous_delta);
 //    return delta_weights;
 }
 Matrix* calculate_delta_hidden(Matrix* next_layer_delta, Matrix* weights, Matrix* current_layer_output) {
    // remove bias weights from weights
    Matrix* weights_without_biases = matrix_create(weights->rows, weights->columns - 1);
    for (int i = 0; i < weights->rows; ++i) {
        for (int j = 0; j < weights->columns - 1; ++j) {
            weights_without_biases->numbers[i][j] = weights->numbers[i][j + 1];
        }
    }
    // transpose the new weights and multiply with deltas
    Matrix* transposed_weight_without_biases = transpose(weights_without_biases);
    Matrix* sum_delta_weights = dot(transposed_weight_without_biases, next_layer_delta);
    //multiply with derivative of current layer output
    Matrix* sigmoid_prime = sigmoid_derivative(current_layer_output);
    // multiply to find deltas for current layer
    Matrix* new_deltas = multiply(sigmoid_prime, sum_delta_weights);
    matrix_free(weights_without_biases);
    matrix_free(transposed_weight_without_biases);
    matrix_free(sum_delta_weights);
    matrix_free(sigmoid_prime);
    return new_deltas;
 }
 void apply_weights(Neural_Network* network, Matrix* delta_weights_matrix, int index) {
    if(index > network->hidden_amount || index < 0) {
        printf("ERROR: Index out of range! (apply_weights)");
        exit(1);
    }
    if(delta_weights_matrix->rows != network->weights[index]->rows ||
    delta_weights_matrix->columns != network->weights[index]->columns) {
        printf("ERROR: Size of weight matrices do not match! (apply_weights)");
        exit(1);
    }
    for (int i = 0; i < delta_weights_matrix->rows; i++) {
        for (int j = 0; j < delta_weights_matrix->columns; j++) {
            network->weights[index]->numbers[i][j] += delta_weights_matrix->numbers[i][j]; // multiply delta_weights_matrix with learning rate AND - instead of + because soll-ist
        }
    }
 }
 Matrix *calculate_weights_delta(Matrix *previous_layer_output, Matrix *delta_matrix, double learning_rate) {
    Matrix* previous_out_with_one = matrix_add_bias(previous_layer_output);
    Matrix* transposed_previous_out_with_bias = transpose(previous_out_with_one);
    Matrix* weights_delta_matrix = dot(delta_matrix, transposed_previous_out_with_bias);
    // scale by learning rate
    Matrix* result = scale(weights_delta_matrix, learning_rate);
    matrix_free(previous_out_with_one);
    matrix_free(transposed_previous_out_with_bias);
    matrix_free(weights_delta_matrix);
    return result;
 }
 Matrix* sigmoid_derivative(Matrix* matrix) {
    Matrix* ones = matrix_create(matrix->rows, matrix->columns);
    matrix_fill(ones, 1);
    Matrix* ones_minus_out = subtract(ones, matrix);
    Matrix* sigmoid_derivative = multiply(matrix, ones_minus_out);
    matrix_free(ones);
    matrix_free(ones_minus_out);
    return sigmoid_derivative;
 }
 double sigmoid(double input) {
    return 1.0 / (1 + exp(-1 * input));
 }
--- a/neuronal_network.h
+++ b/neuronal_network.h
@ -0,0 +1,33 @@
 #include "matrix.h"
 #include "image.h"
 typedef struct {
    int input_size;
    int hidden_size;
    int hidden_amount;
    int output_size;
    Matrix** weights;
    double learning_rate;
 } Neural_Network;
 static const int MAX_BYTES = 100;
 Neural_Network* new_network(int input_size, int hidden_size, int hidden_amount, int output_size, double learning_rate);
 void randomize_network(Neural_Network* network, int scope);
 void free_network(Neural_Network* network);
 void save_network(Neural_Network* network);
 Neural_Network* load_network(char* file);
 void print_network(Neural_Network* network);
 void batch_train(Neural_Network* network, Image** images, int amount, int batch_size);
 double measure_network_accuracy(Neural_Network* network, Image** images, int amount);
 Matrix* predict_image(Neural_Network* network, Image* image);
 void train_network(Neural_Network* network, Image *image, int label);
--- a/util.c
+++ b/util.c
@ -0,0 +1,20 @@
 //
 // Created by jakob on 21.09.2023.
 //
 #include "util.h"
 #include <stdio.h>
 void updateBar(int percent_done){
    const int BAR_LENGTH = 30;
    int numChar = percent_done * BAR_LENGTH / 100;
    printf("\r[");
    for(int i = 0; i < numChar; i++){
        printf("#");
    }
    for(int i = 0; i < BAR_LENGTH - numChar; i++){
        printf(".");
    }
    printf("] (%d%%)", percent_done);
    fflush(stdout);
 }
--- a/util.h
+++ b/util.h
@ -0,0 +1,9 @@
 //
 // Created by jakob on 21.09.2023.
 //
 #ifndef C_NET_UTIL_H
 #define C_NET_UTIL_H
 #endif //C_NET_UTIL_H
 void updateBar(int percentDone);
		`@ -0,0 +1,2 @@`
							`<?xml version="1.0" encoding="UTF-8"?>`
							`<module classpath="CMake" type="CPP_MODULE" version="4" />`