297 lines
11 KiB
C
297 lines
11 KiB
C
#include <stdio.h>
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#include <stdlib.h>
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#include <string.h>
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#include <math.h>
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#include "./unity/unity.h"
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#include "neuralNetwork.h"
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// TODO
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// Das Neuronale Netz
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// Inhalte: Strukturen, Dateien schreiben
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// Ein neuronales besteht aus verschiedenen Schichten und ihren Parametern.
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// Die Struktur NeuralNetwork und die Implementierung in der entsprechenden Quelltextdatei bildet dies ab.
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// Für die passenden Unittests fehlt jedoch noch eine Methode, die eine gültige Testdatei erzeugt,
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// mit der die Funktionalität getestet werden kann.
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// Die Datei beginnt mit dem Identifikationstag __info2_neural_network_file_format__,
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// gefolgt von den einzelnen Schichten.
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//
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// Aufgaben:
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// 1) Implementieren Sie die Funktion prepareNeuralNetworkFile() in neuralNetworkTests.c.
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// 2) Stellen Sie sicher, dass alle Unittests erfolgreich durchlaufen.
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// make neuralNetworkTests && ./runNeuralNetworkTests
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static void prepareNeuralNetworkFile(const char *path, const NeuralNetwork nn)
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{
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FILE *file = fopen(path, "wb");
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if (file == NULL) {
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return;
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}
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// 1. Header schreiben
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const char *fileHeader = "__info2_neural_network_file_format__";
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fwrite(fileHeader, sizeof(char), strlen(fileHeader), file);
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// Prüfen ob Layer existieren
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if (nn.numberOfLayers > 0)
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{
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// 2. Die Input-Dimension der ALLERERSTEN Schicht schreiben
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// (Das sind die Spalten der Gewichtsmatrix der ersten Schicht)
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int inputDim = nn.layers[0].weights.cols;
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fwrite(&inputDim, sizeof(int), 1, file);
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// 3. Durch alle Schichten iterieren
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for(int i = 0; i < nn.numberOfLayers; i++)
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{
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// Die Output-Dimension dieser Schicht schreiben (Zeilen der Gewichtsmatrix)
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int outputDim = nn.layers[i].weights.rows;
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fwrite(&outputDim, sizeof(int), 1, file);
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// 4. Gewichte (Weights) schreiben (nur den Buffer, keine Dimensionen mehr!)
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// loadModel weiß durch inputDim und outputDim schon, wie groß die Matrix ist.
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int weightsCount = nn.layers[i].weights.rows * nn.layers[i].weights.cols;
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fwrite(nn.layers[i].weights.buffer, sizeof(MatrixType), weightsCount, file);
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// 5. Biases schreiben (nur den Buffer)
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int biasCount = nn.layers[i].biases.rows * nn.layers[i].biases.cols;
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fwrite(nn.layers[i].biases.buffer, sizeof(MatrixType), biasCount, file);
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}
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}
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// 6. Eine 0 schreiben, um das Ende der Dimensionen zu signalisieren
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// (loadModel bricht die while-Schleife ab, wenn readDimension 0 liefert)
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int stopMark = 0;
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fwrite(&stopMark, sizeof(int), 1, file);
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fclose(file);
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}
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void test_loadModelReturnsCorrectNumberOfLayers(void)
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{
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const char *path = "some__nn_test_file.info2";
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MatrixType buffer1[] = {1, 2, 3, 4, 5, 6};
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MatrixType buffer2[] = {1, 2, 3, 4, 5, 6};
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Matrix weights1 = {.buffer=buffer1, .rows=3, .cols=2};
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Matrix weights2 = {.buffer=buffer2, .rows=2, .cols=3};
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MatrixType buffer3[] = {1, 2, 3};
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MatrixType buffer4[] = {1, 2};
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Matrix biases1 = {.buffer=buffer3, .rows=3, .cols=1};
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Matrix biases2 = {.buffer=buffer4, .rows=2, .cols=1};
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Layer layers[] = {{.weights=weights1, .biases=biases1}, {.weights=weights2, .biases=biases2}};
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NeuralNetwork expectedNet = {.layers=layers, .numberOfLayers=2};
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NeuralNetwork netUnderTest;
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prepareNeuralNetworkFile(path, expectedNet);
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netUnderTest = loadModel(path);
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remove(path);
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TEST_ASSERT_EQUAL_INT(expectedNet.numberOfLayers, netUnderTest.numberOfLayers);
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clearModel(&netUnderTest);
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}
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void test_loadModelReturnsCorrectWeightDimensions(void)
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{
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const char *path = "some__nn_test_file.info2";
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MatrixType weightBuffer[] = {1, 2, 3, 4, 5, 6};
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Matrix weights = {.buffer=weightBuffer, .rows=3, .cols=2};
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MatrixType biasBuffer[] = {7, 8, 9};
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Matrix biases = {.buffer=biasBuffer, .rows=3, .cols=1};
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Layer layers[] = {{.weights=weights, .biases=biases}};
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NeuralNetwork expectedNet = {.layers=layers, .numberOfLayers=1};
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NeuralNetwork netUnderTest;
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prepareNeuralNetworkFile(path, expectedNet);
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netUnderTest = loadModel(path);
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remove(path);
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TEST_ASSERT_TRUE(netUnderTest.numberOfLayers > 0);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].weights.rows, netUnderTest.layers[0].weights.rows);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].weights.cols, netUnderTest.layers[0].weights.cols);
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clearModel(&netUnderTest);
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}
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void test_loadModelReturnsCorrectBiasDimensions(void)
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{
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const char *path = "some__nn_test_file.info2";
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MatrixType weightBuffer[] = {1, 2, 3, 4, 5, 6};
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Matrix weights = {.buffer=weightBuffer, .rows=3, .cols=2};
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MatrixType biasBuffer[] = {7, 8, 9};
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Matrix biases = {.buffer=biasBuffer, .rows=3, .cols=1};
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Layer layers[] = {{.weights=weights, .biases=biases}};
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NeuralNetwork expectedNet = {.layers=layers, .numberOfLayers=1};
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NeuralNetwork netUnderTest;
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prepareNeuralNetworkFile(path, expectedNet);
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netUnderTest = loadModel(path);
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remove(path);
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TEST_ASSERT_TRUE(netUnderTest.numberOfLayers > 0);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].biases.rows, netUnderTest.layers[0].biases.rows);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].biases.cols, netUnderTest.layers[0].biases.cols);
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clearModel(&netUnderTest);
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}
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void test_loadModelReturnsCorrectWeights(void)
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{
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const char *path = "some__nn_test_file.info2";
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MatrixType weightBuffer[] = {1, 2, 3, 4, 5, 6};
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Matrix weights = {.buffer=weightBuffer, .rows=3, .cols=2};
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MatrixType biasBuffer[] = {7, 8, 9};
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Matrix biases = {.buffer=biasBuffer, .rows=3, .cols=1};
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Layer layers[] = {{.weights=weights, .biases=biases}};
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NeuralNetwork expectedNet = {.layers=layers, .numberOfLayers=1};
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NeuralNetwork netUnderTest;
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prepareNeuralNetworkFile(path, expectedNet);
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netUnderTest = loadModel(path);
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remove(path);
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TEST_ASSERT_TRUE(netUnderTest.numberOfLayers > 0);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].weights.rows, netUnderTest.layers[0].weights.rows);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].weights.cols, netUnderTest.layers[0].weights.cols);
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int n = netUnderTest.layers[0].weights.rows * netUnderTest.layers[0].weights.cols;
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TEST_ASSERT_EQUAL_INT_ARRAY(expectedNet.layers[0].weights.buffer, netUnderTest.layers[0].weights.buffer, n);
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clearModel(&netUnderTest);
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}
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void test_loadModelReturnsCorrectBiases(void)
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{
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const char *path = "some__nn_test_file.info2";
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MatrixType weightBuffer[] = {1, 2, 3, 4, 5, 6};
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Matrix weights = {.buffer=weightBuffer, .rows=3, .cols=2};
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MatrixType biasBuffer[] = {7, 8, 9};
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Matrix biases = {.buffer=biasBuffer, .rows=3, .cols=1};
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Layer layers[] = {{.weights=weights, .biases=biases}};
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NeuralNetwork expectedNet = {.layers=layers, .numberOfLayers=1};
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NeuralNetwork netUnderTest;
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prepareNeuralNetworkFile(path, expectedNet);
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netUnderTest = loadModel(path);
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remove(path);
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TEST_ASSERT_TRUE(netUnderTest.numberOfLayers > 0);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].weights.rows, netUnderTest.layers[0].weights.rows);
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TEST_ASSERT_EQUAL_INT(expectedNet.layers[0].weights.cols, netUnderTest.layers[0].weights.cols);
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int n = netUnderTest.layers[0].biases.rows * netUnderTest.layers[0].biases.cols;
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TEST_ASSERT_EQUAL_INT_ARRAY(expectedNet.layers[0].biases.buffer, netUnderTest.layers[0].biases.buffer, n);
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clearModel(&netUnderTest);
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}
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void test_loadModelFailsOnWrongFileTag(void)
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{
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const char *path = "some_nn_test_file.info2";
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NeuralNetwork netUnderTest;
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FILE *file = fopen(path, "wb");
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if(file != NULL)
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{
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const char *fileTag = "info2_neural_network_file_format";
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fwrite(fileTag, sizeof(char), strlen(fileTag), file);
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fclose(file);
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}
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netUnderTest = loadModel(path);
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remove(path);
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TEST_ASSERT_NULL(netUnderTest.layers);
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TEST_ASSERT_EQUAL_INT(0, netUnderTest.numberOfLayers);
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}
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void test_clearModelSetsMembersToNull(void)
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{
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const char *path = "some__nn_test_file.info2";
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MatrixType weightBuffer[] = {1, 2, 3, 4, 5, 6};
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Matrix weights = {.buffer=weightBuffer, .rows=3, .cols=2};
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MatrixType biasBuffer[] = {7, 8, 9};
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Matrix biases = {.buffer=biasBuffer, .rows=3, .cols=1};
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Layer layers[] = {{.weights=weights, .biases=biases}};
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NeuralNetwork expectedNet = {.layers=layers, .numberOfLayers=1};
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NeuralNetwork netUnderTest;
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prepareNeuralNetworkFile(path, expectedNet);
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netUnderTest = loadModel(path);
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remove(path);
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TEST_ASSERT_NOT_NULL(netUnderTest.layers);
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TEST_ASSERT_TRUE(netUnderTest.numberOfLayers > 0);
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clearModel(&netUnderTest);
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TEST_ASSERT_NULL(netUnderTest.layers);
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TEST_ASSERT_EQUAL_INT(0, netUnderTest.numberOfLayers);
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}
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static void someActivation(Matrix *matrix)
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{
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for(int i = 0; i < matrix->rows * matrix->cols; i++)
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{
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matrix->buffer[i] = fabs(matrix->buffer[i]);
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}
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}
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void test_predictReturnsCorrectLabels(void)
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{
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const unsigned char expectedLabels[] = {4, 2};
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GrayScalePixelType imageBuffer1[] = {10, 30, 25, 17};
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GrayScalePixelType imageBuffer2[] = {20, 40, 10, 128};
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GrayScaleImage inputImages[] = {{.buffer=imageBuffer1, .width=2, .height=2}, {.buffer=imageBuffer2, .width=2, .height=2}};
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MatrixType weightsBuffer1[] = {1, -2, 3, -4, 5, -6, 7, -8};
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MatrixType weightsBuffer2[] = {-9, 10, 11, 12, 13, 14};
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MatrixType weightsBuffer3[] = {-15, 16, 17, 18, -19, 20, 21, 22, 23, -24, 25, 26, 27, -28, -29};
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Matrix weights1 = {.buffer=weightsBuffer1, .rows=2, .cols=4};
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Matrix weights2 = {.buffer=weightsBuffer2, .rows=3, .cols=2};
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Matrix weights3 = {.buffer=weightsBuffer3, .rows=5, .cols=3};
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MatrixType biasBuffer1[] = {200, 0};
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MatrixType biasBuffer2[] = {0, -100, 0};
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MatrixType biasBuffer3[] = {0, -1000, 0, 2000, 0};
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Matrix biases1 = {.buffer=biasBuffer1, .rows=2, .cols=1};
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Matrix biases2 = {.buffer=biasBuffer2, .rows=3, .cols=1};
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Matrix biases3 = {.buffer=biasBuffer3, .rows=5, .cols=1};
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Layer layers[] = {{.weights=weights1, .biases=biases1, .activation=someActivation}, \
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{.weights=weights2, .biases=biases2, .activation=someActivation}, \
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{.weights=weights3, .biases=biases3, .activation=someActivation}};
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NeuralNetwork netUnderTest = {.layers=layers, .numberOfLayers=3};
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unsigned char *predictedLabels = predict(netUnderTest, inputImages, 2);
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TEST_ASSERT_NOT_NULL(predictedLabels);
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int n = (int)(sizeof(expectedLabels) / sizeof(expectedLabels[0]));
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TEST_ASSERT_EQUAL_UINT8_ARRAY(expectedLabels, predictedLabels, n);
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free(predictedLabels);
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}
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void setUp(void) {
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// Falls notwendig, kann hier Vorbereitungsarbeit gemacht werden
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}
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void tearDown(void) {
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// Hier kann Bereinigungsarbeit nach jedem Test durchgeführt werden
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}
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int main()
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{
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UNITY_BEGIN();
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printf("\n============================\nNeural network tests\n============================\n");
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RUN_TEST(test_loadModelReturnsCorrectNumberOfLayers);
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RUN_TEST(test_loadModelReturnsCorrectWeightDimensions);
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RUN_TEST(test_loadModelReturnsCorrectBiasDimensions);
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RUN_TEST(test_loadModelReturnsCorrectWeights);
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RUN_TEST(test_loadModelReturnsCorrectBiases);
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RUN_TEST(test_loadModelFailsOnWrongFileTag);
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RUN_TEST(test_clearModelSetsMembersToNull);
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RUN_TEST(test_predictReturnsCorrectLabels);
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return UNITY_END();
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} |