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hallerni98888:main
hallerni98888:simons_weg
hallerni98888:temp
hallerni98888:simon_wieder_allein
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compare: hallerni98888:main
Branches Tags
hallerni98888:simons_weg
hallerni98888:temp
hallerni98888:main
hallerni98888:simon_wieder_allein
hallerni98888:nick_branch
hallerni98888:simons_zweig
freudenreichan:main

1 Commits
simons_weg ... main

Author SHA1 Message Date
Simon May
804294b96e aufräumen 2025-12-02 14:44:04 +01:00
14 changed files with 106 additions and 406 deletions
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3
.gitignore vendored
View File

@ -6,6 +6,3 @@ runNumbersTest.exe
numbers.o
.vscode/launch.json
.vscode/settings.json
*.o
*.exe
runBintreeTest

67
bintree.c
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@ -1,10 +1,7 @@
#include <string.h>
#include <stdio.h>
#include "stack.h"
#include "bintree.h"
static StackNode *stack;
static TreeNode *tree = NULL;
// TODO: binären Suchbaum implementieren
/* * `addToTree`: fügt ein neues Element in den Baum ein (rekursiv),
* `clearTree`: gibt den gesamten Baum frei (rekursiv),
@ -15,34 +12,8 @@ static TreeNode *tree = NULL;
// 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)
{
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.
@ -50,21 +21,6 @@ TreeNode *addToTree(TreeNode *root, const void *data, size_t dataSize, CompareFc
// push the top node and push all its left nodes.
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;
}
@ -80,32 +36,27 @@ void clearTree(TreeNode *root)
{
clearTree(root->left);
free(root->left);
root->left = NULL;
}
if (root->right != NULL)
else if (root->right != NULL)
{
clearTree(root->right);
free(root->right);
root->right = NULL;
}
root = NULL;
root->data = NULL;
}
// Returns the number of entries in the tree given by root.
unsigned int treeSize(const TreeNode *root)
{
return root == NULL ? 0 : treeSize(root->left) + treeSize(root->right) + 1;
}
void buildStack(TreeNode *root)
int counterL, counterR = 0;
if (root->left != NULL)
{
if (root == NULL)
counterL = treeSize(root->left) + 1;
}
else if (root->right != NULL)
{
return;
counterR = treeSize(root->right) + 1;
}
buildStack(root->left); // biggest first
stack = push(stack, root->data); // push
buildStack(root->right);
return counterL + counterR;
}

2
bintree.h
View File

@ -24,6 +24,4 @@ void clearTree(TreeNode *root);
// Returns the number of entries in the tree given by root.
unsigned int treeSize(const TreeNode *root);
void buildStack(TreeNode *root);
#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));
highscoreTree = addToTree(highscoreTree, &entry, sizeof(entry), compareHighscoreEntries, NULL);
//HighscoreEntry *temp = highscoreTree->data;
//printf("%s%d\n", temp->name, temp->score);
return entry.score;
}

6
highscores.txt
View File

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

8
makefile
View File

@ -35,7 +35,7 @@ $(program_obj_filesobj_files): %.o: %.c
# --------------------------
# Unit Tests
# --------------------------
stackTests: stack.o test_stack.c $(unityfolder)/unity.c
unitTests: stack.o test_stack.c $(unityfolder)/unity.c
$(CC) $(FLAGS) -I$(unityfolder) -o runStackTest test_stack.c stack.o $(unityfolder)/unity.c
# --------------------------
@ -44,12 +44,6 @@ stackTests: stack.o test_stack.c $(unityfolder)/unity.c
numbersTests: numbers.o test_numbers.c $(unityfolder)/unity.c
$(CC) $(FLAGS) -I$(unityfolder) -o runNumbersTest test_numbers.c numbers.o $(unityfolder)/unity.c
# --------------------------
# bintree.c Tests
# --------------------------
bintreeTests: bintree.o test_bintree.c $(unityfolder)/unity.c
$(CC) $(FLAGS) -I$(unityfolder) -o runBintreeTest test_bintree.c bintree.o $(unityfolder)/unity.c
# --------------------------
# Clean
# --------------------------

35
numbers.c
View File

@ -23,8 +23,6 @@ unsigned int checkArray(unsigned int *array, unsigned int len, unsigned int numb
if (array[i] == number)
{
free = 0;
break;
}
}
@ -35,37 +33,32 @@ unsigned int *createNumbers(unsigned int len)
{
srand(time(NULL));
unsigned int *array = (unsigned int*)malloc(len * sizeof(unsigned int));
int randomNr, randomPos, filler;
int randomNr, counter;
if(array == NULL)
{
return NULL; // Fehler
}
for (int i = 0; i < len; i++)
{
array[i] = 0;
return NULL;
}
for (int i = 0; i < len; i++)
{
counter = 0;
do
{
array[i] = (rand() % (2 * len))+ 1;
} while (!checkArray(array, i, array[i]));
}
randomPos = rand() % len;
randomNr = array[randomPos];
filler = randomPos;
while(filler == randomPos)
if (counter == 9)
{
filler = rand() % len;
return NULL;
}
array[filler] = randomNr;
randomNr = rand() % (2 * len + 1);
counter++;
} while (!checkArray(array, i, randomNr));
array[i] = randomNr;
printf("%u ", array[i]);
}
printf("\n");
return array;
}

BIN
numbers.o Normal file
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BIN
runNumbersTest.exe Normal file
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62
stack.c
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@ -10,24 +10,46 @@
// Pushes data as pointer onto the stack.
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.
StackNode *tempNode, *newNode;
newNode = malloc(sizeof(StackNode));
newNode->value = *(int *)data;
newNode->next = NULL;
if (stack == NULL)
{
stack = newNode;
return stack;
}
tempNode = stack;
while (tempNode->next != NULL)
{
tempNode = tempNode->next;
}
tempNode->next = newNode;
return stack;
}
// Deletes the top element of the stack (latest added element) and releases its memory. (Pointer to data has to be
// freed by caller.)
StackNode *pop(StackNode *stack)
{
StackNode *tempNode;
if (stack == NULL)
{
return NULL; // Nothing to pop if stack is empty.
return stack;
}
StackNode *tempNode = stack;
stack = stack->next; // Move the stack pointer to the next node.
free(tempNode); // Free the old top node.
tempNode = stack;
while (tempNode->next->next != NULL)
{
tempNode = tempNode->next;
}
free(tempNode->next);
tempNode->next = NULL;
return stack;
}
@ -35,19 +57,35 @@ StackNode *pop(StackNode *stack)
// Returns the data of the top element.
void *top(StackNode *stack)
{
StackNode *tempNode;
if (stack == NULL)
{
return NULL; // Return NULL if stack is empty.
return NULL;
}
return stack->data; // Return the value of the top node.
tempNode = stack;
while (tempNode->next != NULL)
{
tempNode = tempNode->next;
}
return &tempNode->value;
}
// Clears stack and releases all memory.
void clearStack(StackNode *stack)
{
while (stack != NULL)
StackNode *tempNode;
if (stack == NULL)
{
stack = pop(stack); // Pop each element and free memory.
return;
}
tempNode = stack;
while (tempNode != NULL)
{
tempNode = pop(tempNode);
}
}

2
stack.h
View File

@ -9,7 +9,7 @@ The latest element is taken from the stack. */
//TODO: passenden Datentyp als struct anlegen
typedef struct Node {
void *data;
int value;
struct Node* next;
} StackNode;

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
View File

@ -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();
}

127
test_stack.c
View File

@ -3,33 +3,16 @@
#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)
void test_push(void)
{
StackNode *testNode = NULL;
StackNode *testNode;
int data = 1;
// Test für leeren Stack
testNode = push(testNode, &data);
testNode = push(NULL, &data);
TEST_ASSERT_NOT_NULL(&testNode);
TEST_ASSERT_NULL(testNode->next);
int *temp = testNode->data;
TEST_ASSERT_EQUAL_INT(1, *temp);
TEST_ASSERT_EQUAL_INT(1, testNode->value);
data = 2;
@ -38,53 +21,26 @@ void test_push1(void)
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);
TEST_ASSERT_EQUAL_INT(1, testNode->value);
TEST_ASSERT_EQUAL_INT(2, testNode->next->value);
}
StackNode* setup(void *data, StackNode* next) {
StackNode* setup(int value, 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->value = value;
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)
void test_pop(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* node2 = setup(3, NULL);
StackNode* node1 = setup(2, node2);
StackNode* header = setup(1, node1);
StackNode* temp;
temp = pop(header);
@ -100,62 +56,21 @@ void test_pop2(void)
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)
void test_top(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* node2 = setup(3, NULL);
StackNode* node1 = setup(2, node2);
StackNode* header = setup(1, 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
TEST_ASSERT_EQUAL_INT(node2->value, data);
}
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* node2 = setup(3, NULL);
StackNode* node1 = setup(2, node2);
StackNode* header = setup(1, node1);
StackNode* temp;
clearStack(header);
@ -191,7 +106,7 @@ int main()
RUN_TEST(test_push);
RUN_TEST(test_pop);
RUN_TEST(test_top);
RUN_TEST(test_clearStack);
RUN_TEST(test_clear);
return UNITY_END();
}