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hallerni98888:temp
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hallerni98888:nick_branch
hallerni98888:simons_zweig
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freudenreichan:main
hallerni98888:main
hallerni98888:simons_weg
hallerni98888:temp
hallerni98888:simon_wieder_allein
hallerni98888:nick_branch
hallerni98888:simons_zweig

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simons_weg ... main

14 changed files with 89 additions and 797 deletions
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11
.gitignore vendored
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@ -1,11 +0,0 @@
doble_initial.exe
highscores.txt
runStackTest.exe
stack.o
runNumbersTest.exe
numbers.o
.vscode/launch.json
.vscode/settings.json
*.o
*.exe
runBintreeTest

85
bintree.c
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@ -1,48 +1,18 @@
#include <string.h> #include <string.h>
#include <stdio.h>
#include "stack.h" #include "stack.h"
#include "bintree.h" #include "bintree.h"
static StackNode *stack; //TODO: binären Suchbaum implementieren
static TreeNode *tree = NULL;
// TODO: binären Suchbaum implementieren
/* * `addToTree`: fügt ein neues Element in den Baum ein (rekursiv), /* * `addToTree`: fügt ein neues Element in den Baum ein (rekursiv),
* `clearTree`: gibt den gesamten Baum frei (rekursiv), * `clearTree`: gibt den gesamten Baum frei (rekursiv),
* `treeSize`: zählt die Knoten im Baum (rekursiv), * `treeSize`: zählt die Knoten im Baum (rekursiv),
* `nextTreeData`: Traversierung mit Hilfe des zuvor implementierten Stacks. */ * `nextTreeData`: Traversierung mit Hilfe des zuvor implementierten Stacks. */
// Adds a copy of data's pointer destination to the tree using compareFct for ordering. Accepts duplicates // Adds a copy of data's pointer destination to the tree using compareFct for ordering. Accepts duplicates
// if isDuplicate is NULL, otherwise ignores duplicates and sets isDuplicate to 1 (or to 0 if a new entry is added). // if isDuplicate is NULL, otherwise ignores duplicates and sets isDuplicate to 1 (or to 0 if a new entry is added).
TreeNode *addToTree(TreeNode *root, const void *data, size_t dataSize, CompareFctType compareFct, int *isDuplicate) TreeNode *addToTree(TreeNode *root, const void *data, size_t dataSize, CompareFctType compareFct, int *isDuplicate)
{ {
if (root == NULL)
{
TreeNode *newNode = malloc(sizeof(TreeNode));
newNode->data = malloc(dataSize);
memcpy(newNode->data, data, dataSize);
newNode->left = NULL;
newNode->right = NULL;
return newNode;
}
int cmp = compareFct(root->data, data);
if (cmp < 0)
{
root->left = addToTree(root->left, data, dataSize, compareFct, isDuplicate);
}
else if (cmp > 0)
{
root->right = addToTree(root->right, data, dataSize, compareFct, isDuplicate);
}
else
{
if (isDuplicate != NULL)
{
*isDuplicate = 1; // Mark as duplicate if needed.
}
}
return root;
} }
// Iterates over the tree given by root. Follows the usage of strtok. If tree is NULL, the next entry of the last tree given is returned in ordering direction. // Iterates over the tree given by root. Follows the usage of strtok. If tree is NULL, the next entry of the last tree given is returned in ordering direction.
@ -50,62 +20,17 @@ TreeNode *addToTree(TreeNode *root, const void *data, size_t dataSize, CompareFc
// push the top node and push all its left nodes. // push the top node and push all its left nodes.
void *nextTreeData(TreeNode *root) void *nextTreeData(TreeNode *root)
{ {
if (root != NULL)
{
clearStack(stack);
buildStack(root);
}
if(stack != NULL)
{
void* data = top(stack);
stack = pop(stack);
return data;
}
return NULL;
} }
// Releases all memory resources (including data copies). // Releases all memory resources (including data copies).
void clearTree(TreeNode *root) void clearTree(TreeNode *root)
{ {
if (root == NULL)
{
return;
}
if (root->left != NULL)
{
clearTree(root->left);
free(root->left);
root->left = NULL;
}
if (root->right != NULL)
{
clearTree(root->right);
free(root->right);
root->right = NULL;
}
root = NULL;
} }
// Returns the number of entries in the tree given by root. // Returns the number of entries in the tree given by root.
unsigned int treeSize(const TreeNode *root) unsigned int treeSize(const TreeNode *root)
{ {
return root == NULL ? 0 : treeSize(root->left) + treeSize(root->right) + 1;
}
void buildStack(TreeNode *root) }
{
if (root == NULL)
{
return;
}
buildStack(root->left); // biggest first
stack = push(stack, root->data); // push
buildStack(root->right);
}

2
bintree.h
View File

@ -24,6 +24,4 @@ void clearTree(TreeNode *root);
// Returns the number of entries in the tree given by root. // Returns the number of entries in the tree given by root.
unsigned int treeSize(const TreeNode *root); unsigned int treeSize(const TreeNode *root);
void buildStack(TreeNode *root);
#endif #endif

2
highscore.c
View File

@ -79,8 +79,6 @@ int addHighscore(const char *name, double timeInSeconds, unsigned int len)
{ {
HighscoreEntry entry = createHighscoreEntry(name, calculateScore(timeInSeconds, len)); HighscoreEntry entry = createHighscoreEntry(name, calculateScore(timeInSeconds, len));
highscoreTree = addToTree(highscoreTree, &entry, sizeof(entry), compareHighscoreEntries, NULL); highscoreTree = addToTree(highscoreTree, &entry, sizeof(entry), compareHighscoreEntries, NULL);
//HighscoreEntry *temp = highscoreTree->data;
//printf("%s%d\n", temp->name, temp->score);
return entry.score; return entry.score;
} }

6
highscores.txt
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@ -1,5 +1 @@
nick;9963 player1;3999
nick;9946
simon;4965
alex;2996
simon;2996

108
makefile
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@ -1,61 +1,49 @@
CC = gcc CC = gcc
FLAGS = -g -Wall -lm FLAGS = -g -Wall -lm
ifeq ($(OS),Windows_NT) ifeq ($(OS),Windows_NT)
include makefile_windows.variables include makefile_windows.variables
else else
UNAME = $(shell uname) UNAME = $(shell uname)
ifeq ($(UNAME),Linux) ifeq ($(UNAME),Linux)
include makefile_linux.variables include makefile_linux.variables
else else
include makefile_mac.variables include makefile_mac.variables
endif endif
endif endif
raylibfolder = ./raylib raylibfolder = ./raylib
unityfolder = ./unity unityfolder = ./unity
# -------------------------- # --------------------------
# Initiales Programm bauen (zum ausprobieren) # Initiales Programm bauen (zum ausprobieren)
# -------------------------- # --------------------------
doble_initial: doble_initial:
$(CC) -o doble_initial $(BINARIES)/libdoble_complete.a $(CC) -o doble_initial $(BINARIES)/libdoble_complete.a
# -------------------------- # --------------------------
# Selbst implementiertes Programm bauen # Selbst implementiertes Programm bauen
# -------------------------- # --------------------------
program_obj_files = stack.o bintree.o numbers.o timer.o highscore.o program_obj_files = stack.o bintree.o numbers.o timer.o highscore.o
doble : main.o $(program_obj_files) doble : main.o $(program_obj_files)
$(CC) $(FLAGS) $^ -o doble $(CC) $(FLAGS) $^ -o doble
$(program_obj_filesobj_files): %.o: %.c $(program_obj_filesobj_files): %.o: %.c
$(CC) -c $(FLAGS) $^ -o $@ $(CC) -c $(FLAGS) $^ -o $@
# -------------------------- # --------------------------
# Unit Tests # Unit Tests
# -------------------------- # --------------------------
stackTests: stack.o test_stack.c $(unityfolder)/unity.c unitTests:
$(CC) $(FLAGS) -I$(unityfolder) -o runStackTest test_stack.c stack.o $(unityfolder)/unity.c echo "needs to be implemented"
# -------------------------- # --------------------------
# numbers.c Tests # Clean
# -------------------------- # --------------------------
numbersTests: numbers.o test_numbers.c $(unityfolder)/unity.c clean:
$(CC) $(FLAGS) -I$(unityfolder) -o runNumbersTest test_numbers.c numbers.o $(unityfolder)/unity.c ifeq ($(OS),Windows_NT)
del /f *.o doble
# -------------------------- else
# bintree.c Tests rm -f *.o doble
# --------------------------
bintreeTests: bintree.o test_bintree.c $(unityfolder)/unity.c
$(CC) $(FLAGS) -I$(unityfolder) -o runBintreeTest test_bintree.c bintree.o $(unityfolder)/unity.c
# --------------------------
# Clean
# --------------------------
clean:
ifeq ($(OS),Windows_NT)
del /f *.o doble
else
rm -f *.o doble
endif endif

152
numbers.c
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@ -5,166 +5,22 @@
#include "numbers.h" #include "numbers.h"
#include "bintree.h" #include "bintree.h"
// TODO: getDuplicate und createNumbers implementieren //TODO: getDuplicate und createNumbers implementieren
/* * * Erzeugen eines Arrays mit der vom Nutzer eingegebenen Anzahl an Zufallszahlen. /* * * Erzeugen eines Arrays mit der vom Nutzer eingegebenen Anzahl an Zufallszahlen.
* Sicherstellen, dass beim Befüllen keine Duplikate entstehen. * Sicherstellen, dass beim Befüllen keine Duplikate entstehen.
* Duplizieren eines zufälligen Eintrags im Array. * Duplizieren eines zufälligen Eintrags im Array.
* in `getDuplicate()`: Sortieren des Arrays und Erkennen der doppelten Zahl durch Vergleich benachbarter Elemente. */ * in `getDuplicate()`: Sortieren des Arrays und Erkennen der doppelten Zahl durch Vergleich benachbarter Elemente. */
// Returns len random numbers between 1 and 2x len in random order which are all different, except for two entries. // Returns len random numbers between 1 and 2x len in random order which are all different, except for two entries.
// Returns NULL on errors. Use your implementation of the binary search tree to check for possible duplicates while // Returns NULL on errors. Use your implementation of the binary search tree to check for possible duplicates while
// creating random numbers. // creating random numbers.
unsigned int checkArray(unsigned int *array, unsigned int len, unsigned int number)
{
int free = 1;
for (int i = 0; i < len; i++)
{
if (array[i] == number)
{
free = 0;
break;
}
}
return free;
}
unsigned int *createNumbers(unsigned int len) unsigned int *createNumbers(unsigned int len)
{ {
srand(time(NULL));
unsigned int *array = (unsigned int *)malloc(len * sizeof(unsigned int));
int randomNr, randomPos, filler;
if (array == NULL)
{
return NULL; // Fehler
}
for (int i = 0; i < len; i++)
{
array[i] = 0;
}
for (int i = 0; i < len; i++)
{
do
{
array[i] = (rand() % (2 * len))+ 1;
} while (!checkArray(array, i, array[i]));
}
randomPos = rand() % len;
randomNr = array[randomPos];
filler = randomPos;
while(filler == randomPos)
{
filler = rand() % len;
}
array[filler] = randomNr;
return array;
}
void merge(unsigned int arr[], unsigned int left, unsigned int mid, unsigned int right)
{
unsigned int i, j, k;
unsigned int n1 = mid - left + 1;
unsigned int n2 = right - mid;
// Create temporary arrays
unsigned int leftArr[n1], rightArr[n2];
// Copy data to temporary arrays
for (i = 0; i < n1; i++)
leftArr[i] = arr[left + i];
for (j = 0; j < n2; j++)
rightArr[j] = arr[mid + 1 + j];
// Merge the temporary arrays back into arr[left..right]
i = 0;
j = 0;
k = left;
while (i < n1 && j < n2)
{
if (leftArr[i] <= rightArr[j])
{
arr[k] = leftArr[i];
i++;
}
else
{
arr[k] = rightArr[j];
j++;
}
k++;
}
// Copy the remaining elements of leftArr[], if any
while (i < n1)
{
arr[k] = leftArr[i];
i++;
k++;
}
// Copy the remaining elements of rightArr[], if any
while (j < n2)
{
arr[k] = rightArr[j];
j++;
k++;
}
}
void mergeSort(unsigned int arr[], unsigned int left, unsigned int right)
{
if (left < right)
{
// Calculate the midpoint
unsigned int mid = left + (right - left) / 2;
// Sort first and second halves
mergeSort(arr, left, mid);
mergeSort(arr, mid + 1, right);
// Merge the sorted halves
merge(arr, left, mid, right);
}
} }
// Returns only the only number in numbers which is present twice. Returns zero on errors. // Returns only the only number in numbers which is present twice. Returns zero on errors.
unsigned int getDuplicate(const unsigned int numbers[], unsigned int len) unsigned int getDuplicate(const unsigned int numbers[], unsigned int len)
{ {
unsigned int temp[len];
unsigned int duplicate = 0;
/*if(numbers == NULL || (sizeof(numbers) / sizeof(typeof(numbers)) != len))
{
return 0;S
}*/
for (int i = 0; i < len; i++)
{
temp[i] = numbers[i];
}
// Sorting arr using mergesort
mergeSort(temp, 0, len - 1);
for (int i = 0; i < len - 1; i++)
{
duplicate = temp[i];
if (duplicate == temp[i + 1])
{
break;
}
}
return duplicate;
} }

32
stack.c
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@ -1,53 +1,33 @@
#include <stdlib.h> #include <stdlib.h>
#include "stack.h" #include "stack.h"
// TODO: grundlegende Stackfunktionen implementieren: //TODO: grundlegende Stackfunktionen implementieren:
/* * `push`: legt ein Element oben auf den Stack, /* * `push`: legt ein Element oben auf den Stack,
* `pop`: entfernt das oberste Element, * `pop`: entfernt das oberste Element,
* `top`: liefert das oberste Element zurück, * `top`: liefert das oberste Element zurück,
* `clearStack`: gibt den gesamten Speicher frei. */ * `clearStack`: gibt den gesamten Speicher frei. */
// Pushes data as pointer onto the stack. // Pushes data as pointer onto the stack.
StackNode *push(StackNode *stack, void *data) StackNode *push(StackNode *stack, void *data)
{ {
StackNode *newNode = malloc(sizeof(StackNode));
newNode->data = data;
newNode->next = stack; // Set the new node's next pointer to the current top of the stack.
return newNode; // Return the new node as the top of the stack.
} }
// Deletes the top element of the stack (latest added element) and releases its memory. (Pointer to data has to be // Deletes the top element of the stack (latest added element) and releases its memory. (Pointer to data has to be
// freed by caller.) // freed by caller.)
StackNode *pop(StackNode *stack) StackNode *pop(StackNode *stack)
{ {
if (stack == NULL)
{
return NULL; // Nothing to pop if stack is empty.
}
StackNode *tempNode = stack;
stack = stack->next; // Move the stack pointer to the next node.
free(tempNode); // Free the old top node.
return stack;
} }
// Returns the data of the top element. // Returns the data of the top element.
void *top(StackNode *stack) void *top(StackNode *stack)
{ {
if (stack == NULL)
{
return NULL; // Return NULL if stack is empty.
}
return stack->data; // Return the value of the top node.
} }
// Clears stack and releases all memory. // Clears stack and releases all memory.
void clearStack(StackNode *stack) void clearStack(StackNode *stack)
{ {
while (stack != NULL)
{
stack = pop(stack); // Pop each element and free memory.
}
} }

54
stack.h
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@ -1,29 +1,25 @@
#ifndef STACK_H #ifndef STACK_H
#define STACK_H #define STACK_H
/* A stack is a special type of queue which uses the LIFO (last in, first out) principle. /* A stack is a special type of queue which uses the LIFO (last in, first out) principle.
This means that with each new element all other elements are pushed deeper into the stack. This means that with each new element all other elements are pushed deeper into the stack.
The latest element is taken from the stack. */ The latest element is taken from the stack. */
#include <stdlib.h> #include <stdlib.h>
//TODO: passenden Datentyp als struct anlegen //TODO: passenden Datentyp als struct anlegen
typedef struct Node {
void *data; // Pushes data as pointer onto the stack.
struct Node* next; StackNode *push(StackNode *stack, void *data);
} StackNode;
// Deletes the top element of the stack (latest added element) and releases its memory. (Pointer to data has to be
// Pushes data as pointer onto the stack. // freed by caller.)
StackNode *push(StackNode *stack, void *data); StackNode *pop(StackNode *stack);
// Deletes the top element of the stack (latest added element) and releases its memory. (Pointer to data has to be // Returns the data of the top element.
// freed by caller.) void *top(StackNode *stack);
StackNode *pop(StackNode *stack);
// Clears stack and releases all memory.
// Returns the data of the top element. void clearStack(StackNode *stack);
void *top(StackNode *stack);
#endif
// Clears stack and releases all memory.
void clearStack(StackNode *stack);
#endif

100
stackTest.c
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@ -1,100 +0,0 @@
#include "unity.h"
#include "stack.h" // Stack-Header-Datei
#include <stdlib.h>
// Test Setup and Teardown Functions
void setUp(void) {
// Setup code (falls notwendig, wie Initialisierungen)
}
void tearDown(void) {
// Cleanup code (falls notwendig)
}
// Test for push operation
void test_push(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Check if the stack is not empty
TEST_ASSERT_NOT_NULL(stack);
// Check if the top element is correct
int *topData = top(stack);
TEST_ASSERT_EQUAL_INT(20, *topData); // The last pushed element should be on top
}
// Test for pop operation
void test_pop(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Pop the top element
stack = pop(stack);
// Check if the top element is now the first pushed element
int *topData = top(stack);
TEST_ASSERT_EQUAL_INT(10, *topData); // After popping, the first element should be on top
// Pop the last element
stack = pop(stack);
// Check if the stack is empty now
TEST_ASSERT_NULL(stack); // Stack should be NULL now
}
// Test for top operation
void test_top(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Check the top element
int *topData = top(stack);
TEST_ASSERT_EQUAL_INT(20, *topData); // The top element should be 20 (last pushed)
// Pop the top element and check the new top
stack = pop(stack);
topData = top(stack);
TEST_ASSERT_EQUAL_INT(10, *topData); // Now the top element should be 10
}
// Test for clearStack operation
void test_clearStack(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Clear the stack
clearStack(stack);
// The stack should be empty now
TEST_ASSERT_NULL(stack); // Stack should be NULL
}
// Run all tests
int main(void) {
UNITY_BEGIN();
// Run the individual test functions
RUN_TEST(test_push);
RUN_TEST(test_pop);
RUN_TEST(test_top);
RUN_TEST(test_clearStack);
return UNITY_END();
}

80
test_bintree.c
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@ -1,80 +0,0 @@
#include <stdio.h>
#include <stdlib.h>
#include "bintree.h"
#include "unity.h"
void sizeTest()
{
TreeNode *root = (TreeNode *)malloc(sizeof(TreeNode));
TreeNode *node1 = (TreeNode *)malloc(sizeof(TreeNode));
TreeNode *node2 = (TreeNode *)malloc(sizeof(TreeNode));
int dataRoot = 2;
int dataNode1 = 1;
int dataNode2 = 3;
root->data = &dataRoot;
root->left = (TreeNode *)node1;
root->right = (TreeNode *)node2;
node1->data = &dataNode1;
node1->left = NULL;
node1->right = NULL;
node2->data = &dataNode2;
node2->left = NULL;
node2->right = NULL;
TEST_ASSERT_EQUAL_INT(3,treeSize(root));
}
void clearTest()
{
TreeNode *root = (TreeNode *)malloc(sizeof(TreeNode));
TreeNode *node1 = (TreeNode *)malloc(sizeof(TreeNode));
TreeNode *node2 = (TreeNode *)malloc(sizeof(TreeNode));
int dataRoot = 2;
int dataNode1 = 1;
int dataNode2 = 3;
root->data = &dataRoot;
root->left = (TreeNode *)node1;
root->right = (TreeNode *)node2;
node1->data = &dataNode1;
node1->left = NULL;
node1->right = NULL;
node2->data = &dataNode2;
node2->left = NULL;
node2->right = NULL;
TreeNode *ptr = root;
clearTree(ptr);
TEST_ASSERT_EQUAL_INT(0,treeSize(root));
}
void setUp(void)
{
// Falls notwendig, kann hier Vorbereitungsarbeit gemacht werden
}
void tearDown(void)
{
// Hier kann Bereinigungsarbeit nach jedem Test durchgeführt werden
}
int main()
{
UNITY_BEGIN();
printf("============================\nNumbers tests\n============================\n");
RUN_TEST(sizeTest);
RUN_TEST(clearTest);
return UNITY_END();
}

47
test_numbers.c
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@ -1,47 +0,0 @@
#include <stdio.h>
#include <stdlib.h>
#include "numbers.h"
#include "unity.h"
void createNumbersTest()
{
unsigned int *array;
unsigned int len = 6;
array = createNumbers(len);
for (int i = 0; i < len; i++)
{
printf("%u ", array[i]);
}
printf("\n");
TEST_ASSERT_NOT_NULL(array);
}
void duplicateTest()
{
unsigned int array[6] = {1, 4, 5, 2, 3, 1};
unsigned int len = 6;
TEST_ASSERT_EQUAL_INT(1, getDuplicate(array, len));
}
void setUp(void)
{
// Falls notwendig, kann hier Vorbereitungsarbeit gemacht werden
}
void tearDown(void)
{
// Hier kann Bereinigungsarbeit nach jedem Test durchgeführt werden
}
int main()
{
UNITY_BEGIN();
printf("============================\nNumbers tests\n============================\n");
RUN_TEST(createNumbersTest);
RUN_TEST(duplicateTest);
return UNITY_END();
}

197
test_stack.c
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@ -1,197 +0,0 @@
#include <stdio.h>
#include <stdlib.h>
#include "stack.h"
#include "unity.h"
void test_push(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Check if the stack is not empty
TEST_ASSERT_NOT_NULL(stack);
// Check if the top element is correct
int *topData = top(stack);
TEST_ASSERT_EQUAL_INT(20, *topData); // The last pushed element should be on top
}
void test_push1(void)
{
StackNode *testNode = NULL;
int data = 1;
// Test für leeren Stack
testNode = push(testNode, &data);
TEST_ASSERT_NOT_NULL(&testNode);
TEST_ASSERT_NULL(testNode->next);
int *temp = testNode->data;
TEST_ASSERT_EQUAL_INT(1, *temp);
data = 2;
// Test für nicht leeren Stack
testNode = push(testNode, &data);
TEST_ASSERT_NOT_NULL(&testNode);
TEST_ASSERT_NOT_NULL(testNode->next);
TEST_ASSERT_NULL(testNode->next->next);
temp = testNode->data;
TEST_ASSERT_EQUAL_INT(2, *temp);
testNode = testNode->next;
temp = testNode->data;
TEST_ASSERT_EQUAL_INT(1, *temp);
}
StackNode* setup(void *data, StackNode* next) {
StackNode* node = malloc(sizeof(StackNode)); // allocate memory on heap
if (node == NULL) {
perror("malloc failed");
exit(EXIT_FAILURE); // or handle the error differently
}
node->data = data;
node->next = next;
return node;
}
void test_pop(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Pop the top element
stack = pop(stack);
// Check if the top element is now the first pushed element
int *topData = top(stack);
TEST_ASSERT_EQUAL_INT(10, *topData); // After popping, the first element should be on top
// Pop the last element
stack = pop(stack);
// Check if the stack is empty now
TEST_ASSERT_NULL(stack); // Stack should be NULL now
}
void test_pop2(void)
{
int x,y,z;
x = 1;
y = 2;
z = 3;
StackNode* node2 = setup(&z, NULL);
StackNode* node1 = setup(&y, node2);
StackNode* header = setup(&x, node1);
StackNode* temp;
temp = pop(header);
int after = 0;
while(temp)
{
after++;
temp = temp->next;
}
TEST_ASSERT_EQUAL_INT(2, after);
TEST_ASSERT_NULL(node1->next);
}
void test_top(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Check the top element
int *topData = top(stack);
TEST_ASSERT_EQUAL_INT(20, *topData); // The top element should be 20 (last pushed)
// Pop the top element and check the new top
stack = pop(stack);
topData = top(stack);
TEST_ASSERT_EQUAL_INT(10, *topData); // Now the top element should be 10
}
void test_top2(void)
{
int x,y,z;
x = 1;
y = 2;
z = 3;
StackNode* node2 = setup(&z, NULL);
StackNode* node1 = setup(&y, node2);
StackNode* header = setup(&x, node1);
int data = *(int *)top(header);
TEST_ASSERT_EQUAL_INT(node2->data, data);
}
void test_clearStack(void) {
StackNode *stack = NULL;
int data1 = 10, data2 = 20;
// Push elements to the stack
stack = push(stack, &data1);
stack = push(stack, &data2);
// Clear the stack
clearStack(stack);
// The stack should be empty now
TEST_ASSERT_NULL(stack); // Stack should be NULL
}
void test_clear()
{
int x,y,z;
x = 1;
y = 2;
z = 3;
StackNode* node2 = setup(&z, NULL);
StackNode* node1 = setup(&y, node2);
StackNode* header = setup(&x, node1);
StackNode* temp;
clearStack(header);
temp = header;
int after = 0;
while(temp)
{
after++;
temp = temp->next;
}
TEST_ASSERT_NULL(after);
}
void setUp(void)
{
// Falls notwendig, kann hier Vorbereitungsarbeit gemacht werden
}
void tearDown(void)
{
// Hier kann Bereinigungsarbeit nach jedem Test durchgeführt werden
}
int main()
{
UNITY_BEGIN();
printf("============================\nStack tests\n============================\n");
RUN_TEST(test_push);
RUN_TEST(test_pop);
RUN_TEST(test_top);
RUN_TEST(test_clearStack);
return UNITY_END();
}

10
unittest.h
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@ -1,10 +0,0 @@
#ifndef UNITTTESTS_H
#define UNITTTESTS_H
#include <stdio.h>
typedef int (*UnitTestType)(void);
#define RUN_UNIT_TEST(fct) printf("%80s: %d\n", #fct, fct())
#endif