C语言实现 冒泡排序 选择排序 希尔排序

时间:2023-03-09 01:14:13
C语言实现 冒泡排序 选择排序 希尔排序 
// 冒泡排序

// 选择排序

// 希尔排序

// 快速排序

// 递归排序

// 堆排序

#define _CRT_SECURE_NO_WARNINGS

#include <stdio.h>

#include <stdlib.h>

#include <string.h>

#include <time.h>

#include <sys/timeb.h>

#define MAX 40000

long getSystemTime()

{

    struct timeb tb;

    ftime(&tb);

    return tb.time *  + tb.millitm;

}

void Swap(int *a, int *b)

{

    int temp = *a;

    *a = *b;

    *b = temp;

}

void MySwap(int arr[], int a, int b)

{

    int temp = arr[a];

    arr[a] = arr[b];

    arr[b] = temp;

}

//创建数组

int* CreateArray()

{

    srand((unsigned int)time(NULL));

    int* arr = (int*)malloc(sizeof(int)*MAX);

    for (int i = ; i < MAX; i++)

    {

        arr[i] = rand() % MAX;

    }

    return arr;

}

void PrintArray(int arr[], int length)

{

    for (size_t i = ; i < length; i++)

    {

        printf("%d ", arr[i]);

    }

    printf("\n");

}

// 冒泡排序

void BubbleSort(int arr[], int length)

{

    for (size_t i = ; i < length; i++)

    {

        for (size_t j = i + ; j < length; j++)

        {

            if (arr[i] < arr[j])

            {

                Swap(&arr[i], &arr[j]);

            }

        }

    }

}

// 选择排序

void SelectSort(int arr[], int length)

{

    int min = ;

    for (int i = ; i < length; i++)

    {

        for (size_t j = i + ; j < length; j++)

        {

            if (arr[j] < arr[min])

            {

                min = j;

            }

        }

        if (min != i)

        {

            Swap(&arr[min], &arr[i]);

        }

    }

}

// 希尔排序

void ShellSort(int arr[], int length)

{

    int increasement = length;

    int i, j, k;

    do {

        //确定分组的增量

        increasement = increasement /  + ;

        for (i = ; i < increasement; i++)

        {

            for (j = i + increasement; j < length; j += increasement)

            {

                if (arr[j] < arr[j - increasement])

                {

                    int temp = arr[j];

                    for (k = j - increasement; k >=  && temp < arr[k]; k -= increasement)

                    {

                        arr[k + increasement] = arr[k];

                    }

                    arr[k + increasement] = temp;

                }

            }

        }

    } while (increasement > );

}

int partition(int arr[], int low, int high) {

    int key;

    key = arr[low];

    while (low<high) {

        while (low <high && arr[high] >= key)

            high--;

        if (low<high)

            arr[low++] = arr[high];

        while (low<high && arr[low] <= key)

            low++;

        if (low<high)

            arr[high--] = arr[low];

    }

    arr[low] = key;

    return low;

}

void quick_sort(int arr[], int start, int end) {

    int pos;

    if (start<end) {

        pos = partition(arr, start, end);

        quick_sort(arr, start, pos - );

        quick_sort(arr, pos + , end);

    }

    return;

}

// 快速排序

void QuickSort(int arr[], int start, int end)

{

    int i = start;

    int j = end;

    //基准数

    int temp = arr[start];

    if (i < j)

    {

        while (i < j)

        {

            while (i < j && arr[j] >= temp)

            {

                j--;

            }

            if (i < j)

            {

                arr[i] = arr[j];

                i++;

            }

            while (i < j && arr[i] < arr[temp])

            {

                i++;

            }

            if (i < j)

            {

                arr[j] = arr[i];

                j--;

            }

        }

        arr[i] = temp;

        QuickSort(arr, start, i - );

        QuickSort(arr, i + , end);

    }

}

// 合并算法

void Merge(int arr[], int start, int  end, int mid, int* temp)

{

    int i_start = start;

    int i_end = mid;

    int j_start = mid + ;

    int j_end = end;

    // 表示辅助空间有多少个元素

    int length = ;

    // 合并两个有序序列

    while (i_start <= i_end && j_start <= j_end)

    {

        if (arr[i_start] < arr[j_start])

        {

            temp[length] = arr[i_start];

            length++;

            i_start++;

        }

        else

        {

            temp[length] = arr[j_start];

            length++;

            j_start++;

        }

    }

    // i这个序列

    while (i_start <= i_end)

    {

        temp[length] = arr[i_start];

        length++;

        i_start++;

    }

    while (j_start <= j_end)

    {

        temp[length] = arr[j_start];

        length++;

        j_start++;

    }

    // 辅助空间数据覆盖到原空间

    for (int i = ; i < length; i++)

    {

        arr[start + i] = temp[i];

    }

}

//归并排序

void MergeSort(int arr[], int start, int end, int* temp)

{

    if (start >= end)

    {

        return;

    }

    int mid = (start + end) / ;

    MergeSort(arr, start, mid, temp);

    MergeSort(arr, mid + , end, temp);

    Merge(arr, start, end, mid, temp);

}

/*

@param arr 待调整的数组

#param index 待调整的节点的下标

@param len 数组长度

*/

void HeapAdjust(int arr[], int index, int length)

{

    // 保存当前节点下标

    int max = index;

    // 保存子节点的数组下标

    int lchild = index *  + ;

    int rchild = index *  + ;

    if (lchild < length && arr[lchild] > arr[max])

    {

        max = lchild;

    }

    if (rchild<length&& arr[rchild]>arr[max])

    {

        max = rchild;

    }

    if (max != index)

    {

        MySwap(arr, max, index);

        HeapAdjust(arr, max, length);

    }

}

void HeapSort(int arr[], int length)

{

    // 初始化堆

    for (int i = length /  - ; i >= ; i--)

    {

        HeapAdjust(arr, i, length);

    }

    // 交换堆顶元素和最后一个元素

    for (int i = length - ; i >= ; i--)

    {

        MySwap(arr, , i);

        HeapAdjust(arr, , i);

    }

}

int main(void)

{

    int* arr_bubble = CreateArray();

    int* arr_select = CreateArray();

    int* arr_shell = CreateArray();

    int* arr_quick = CreateArray();

    int* arr_merge = CreateArray();

    int* arr_heap = CreateArray();

    long tbubble_start = ;

    long tbubble_end = ;

    // 冒泡排序

    //PrintArray(arr_bubble, MAX);

    tbubble_start = getSystemTime();

    BubbleSort(arr_bubble, MAX);

    tbubble_end = getSystemTime();

    //PrintArray(arr_bubble, MAX);

    printf("冒泡排序%d个数,所需时间:%d\n", MAX, tbubble_end - tbubble_start);

    printf("---------------------------------------\n");

    // 选择排序

    //PrintArray(arr_select, MAX);

    tbubble_start = getSystemTime();

    SelectSort(arr_select, MAX);

    tbubble_end = getSystemTime();

    //PrintArray(arr_select, MAX);

    printf("选择排序%d个数,所需时间:%d\n", MAX, tbubble_end - tbubble_start);

    printf("---------------------------------------\n");

    // 希尔排序

    //PrintArray(arr_shell, MAX);

    tbubble_start = getSystemTime();

    ShellSort(arr_shell, MAX);

    tbubble_end = getSystemTime();

    //PrintArray(arr_shell, MAX);

    printf("希尔排序%d个数,所需时间:%d\n", MAX, tbubble_end - tbubble_start);

    printf("---------------------------------------\n");

    // 快速排序

    int start = ;

    int end = MAX-;

    //PrintArray(arr_quick, MAX);

    tbubble_start = getSystemTime();

    quick_sort(arr_quick, start, end);

    tbubble_end = getSystemTime();

    //PrintArray(arr_quick, MAX);

    printf("快速排序%d个数,所需时间:%d\n", MAX, tbubble_end - tbubble_start);

    printf("---------------------------------------\n");

    // 递归排序

    //PrintArray(arr_merge, MAX);

    tbubble_start = getSystemTime();

    int* arr_temp = (int*)malloc(sizeof(int)*MAX);

    MergeSort(arr_merge, , MAX - , arr_temp);

    tbubble_end = getSystemTime();

    //PrintArray(arr_merge, MAX);

    printf("递归排序%d个数,所需时间:%d\n", MAX, tbubble_end - tbubble_start);

    printf("---------------------------------------\n");

    // 堆排序

    //PrintArray(arr_heap, MAX);

    tbubble_start = getSystemTime();

    HeapSort(arr_heap, MAX);

    tbubble_end = getSystemTime();

    //PrintArray(arr_heap, MAX);

    printf("堆排序%d个数,所需时间:%d\n", MAX, tbubble_end - tbubble_start);

    free(arr_temp);

    free(arr_bubble);

    free(arr_select);

    free(arr_shell);

    free(arr_quick);

    free(arr_merge);

    return ;

}

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