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13 KiB
13 KiB
介绍
排序(Sorting) 是计算机程序设计中的一种重要操作,它的功能是将一个数据元素(或记录)的任意序列,重新排列成一个关键字有序的序列。排序就是把集合中的元素按照一定的次序排序在一起,一般来说有升序排列和降序排列2种排序。
排序算法的逻辑是固定的,所要排序的数据集结构和数据项结构会不同,当针对每种数据集结构或者数据项结构都写一套排序算法函数,那无疑会增加冗余的代码。
varch提供sort模块就为了解决这个问题,把算法模型所需的数据集和数据项类型的不同进行抽象化,只要针对不同数据以及排序规则提供对应的操作函数,就可以统一调用排序算法进行排序操作。
接口
int sort_bubble(void *array, int begin, int end, SOPS* ops);
int sort_select(void *array, int begin, int end, SOPS* ops);
int sort_insert(void *array, int begin, int end, SOPS* ops);
int sort_shell(void *array, int begin, int end, SOPS* ops);
int sort_quick(void *array, int begin, int end, SOPS* ops);
int sort_heap(void *array, int begin, int end, SOPS* ops);
这里给出了6种常用的排序法,分别是冒泡排序、选择排序、插入排序、希尔排序、快速排序、堆排序,这几个排序法在使用上一致。
array传入数组或者其他任意的数据容器,begin和end指定需要排序的区间,ops则是指定排序所需的一些函数操作集。
/* Sorting algorithm operation function set structure definition */
typedef struct
{
/**
* \brief ordering rules, e.g front < back ascending and front > back descending
* \param[in] front: address of front data
* \param[in] back: address of back data
* \return positive: following sorting rules
* negative: violating sorting rules
* 0: does't affect sorting rules
*/
int (*order)(void *front, void *back);
/**
* \brief get the address of the space where the element is located
* \param[in] array: data handle
* \param[in] index: item data index
* \return address of item data
*/
void* (*addr)(void *array, int index);
/**
* \brief Swap data between two spaces
* \param[in] array: data handle
* \param[in] index0: item data index0
* \param[in] index1: item data index1
* \return none
*/
void (*swap)(void *array, int index0, int index1);
} SOPS;
首先需要在ops中order指定排序的规则(升序还是降序),front的项大于back的项,那就是降序的规则,反之亦然。
因为array支持任意类型的数据结构,所以要在ops中addr成员指定获取特定数据结构项的指定成员地址,比如char数组和int数组返回相应地址不一样。
排序就涉及数据的位置交换,ops的swap成员就指定交换数据的方法(因为并不是所有数据结构的交换数据都是直接交换亮着数据的内容,比如链表就是交换数据指向就可以了)。
常用的数据结构排序的ops已经封装好了,根据类型选择实际ops即可。
extern SOPS sops_char_ascend;
extern SOPS sops_char_descend;
extern SOPS sops_uchar_ascend;
extern SOPS sops_uchar_descend;
extern SOPS sops_short_ascend;
extern SOPS sops_short_descend;
extern SOPS sops_ushort_ascend;
extern SOPS sops_ushort_descend;
extern SOPS sops_int_ascend;
extern SOPS sops_int_descend;
extern SOPS sops_uint_ascend;
extern SOPS sops_uint_descend;
extern SOPS sops_float_ascend;
extern SOPS sops_float_descend;
extern SOPS sops_double_ascend;
extern SOPS sops_double_descend;
实测例子
基本升降序用法
针对基本数据类型的升降序排序,以以冒泡排序算法举例。
static void test_basic_usage(void)
{
/* 针对int型数组,进行升序
*/
int array_int[] = {1, 3, 6, 5, 0, 2, 9, 8, 7, -4}; // 定义时候任意乱序
// 传入数组基地址,排序的区间,指定int型的升序ops
sort_bubble(array_int, 0, sizeof(array_int)/sizeof(array_int[0]) - 1, &sops_int_ascend);
// 输出排序后的数组
for (int i = 0; i < sizeof(array_int)/sizeof(array_int[0]); i++)
{
printf("%d, ", array_int[i]);
}
printf("\r\n");
/* ---------------------------------------- 代码分割线 ---------------------------------------- */
/* 针对float型数组,进行降序
*/
float array_float[] = {-1.1, 2.1, 6.6, 5.0, 0.1, 2.8, 9.9, 9.8, 7.0, -4.5}; // 定义时候任意乱序
// 传入数组基地址,排序的区间,指定float型的降序ops
sort_bubble(array_float, 0, sizeof(array_float)/sizeof(array_float[0]) - 1, &sops_float_descend);
// 输出排序后的数组
for (int i = 0; i < sizeof(array_float)/sizeof(array_float[0]); i++)
{
printf("%.2f, ", array_float[i]);
}
printf("\r\n");
}
测试结果:
-4, 0, 1, 2, 3, 5, 6, 7, 8, 9,
9.90, 9.80, 7.00, 6.60, 5.00, 2.80, 2.10, 0.10, -1.10, -4.50,
针对指定区间进行排序
除了一般常用的全区间进行排序,还可以指定某段区间内进行。
static void test_interval(void)
{
int array_int[] = {0, 1, 2, 3, 4, 5, 6, 7, 8, 9}; // 先定义升序的数组
// 传入数组基地址,指定在[3, 7]区间内进行排序,指定int型的降序ops
sort_bubble(array_int, 3, 7, &sops_int_descend);
// 输出排序后的数组
for (int i = 0; i < sizeof(array_int)/sizeof(array_int[0]); i++)
{
printf("%d, ", array_int[i]);
}
printf("\r\n");
}
测试结果:
0, 1, 2, 7, 6, 5, 4, 3, 8, 9,
针对不是数组的其他容器排序
下面以list容器为例子,测试int型list升序排序。
这个测试代码依赖list容器。
// 获取list数据项地址
static void* list_int_addr(void *array, int index)
{
return list_data((list_t)array, index);
}
// 交换list两个成员数据
static void list_int_swap(void *array, int index0, int index1)
{
int temp = list_at((list_t)array, int, index0);
list_at((list_t)array, int, index0) = list_at((list_t)array, int, index1);
list_at((list_t)array, int, index1) = temp;
}
// 显示list存储的数据
static void list_int_show(list_t list)
{
for (int i = 0; i < list_size(list); i++)
{
printf("%d, ", list_at(list, int, i));
}
printf("\r\n");
}
static void test_list_sort(void)
{
list_t list = list(int); // 定义一个int型的list
SOPS ops; // 定义一个新的ops
int array[] = {1, 3, 6, 5, 0, 2, 9, 8, 7, -4}; // 定义要给list装载的数据
// 将数据装载到list
for (int i = 0; i < sizeof(array)/sizeof(array[0]); i++)
{
list_push_back(list, &array[i]);
}
ops.order = sops_int_ascend.order; // 复用int升序规则
ops.addr = list_int_addr; // 使用list获取元素的地址
ops.swap = list_int_swap; // list交换数据
// 输出排序前的list
list_int_show(list);
// 进行排序
sort_bubble(list, 0, list_size(list) - 1, &ops);
// 输出排序后的list
list_int_show(list);
// 释放list
_list(list);
}
测试结果:
1, 3, 6, 5, 0, 2, 9, 8, 7, -4,
-4, 0, 1, 2, 3, 5, 6, 7, 8, 9,
针对自定义数据结构进行排序
前面提供的例子都是基础数据类型的,接下来的例子是针对自定义数据类型的,比如结构体,根据结构体的某些成员项进行排序。
typedef struct
{
char *name;
int age;
char gender; /* 1 表示男,0 表示女 */
float weight;
} STUDENT;
static void student_print(STUDENT *s, int size)
{
for (int i = 0; i < size; i++)
{
printf("name: %s, \t\t age = %d, \t\t gender = %d, \t\t weight = %.2f\r\n", s[i].name, s[i].age, s[i].gender, s[i].weight);
}
}
static void* student_addr(void *array, int index)
{
return ((STUDENT *)array) + index;
}
static void student_swap(void *array, int index0, int index1)
{
STUDENT temp = ((STUDENT *)array)[index0];
((STUDENT *)array)[index0] = ((STUDENT *)array)[index1];
((STUDENT *)array)[index1] = temp;
}
static int student_name_ascend(void *front, void *back)
{
return -strcmp(((STUDENT *)front)->name, ((STUDENT *)back)->name);
}
static int student_gender_descend(void *front, void *back)
{
if (((STUDENT *)front)->gender > ((STUDENT *)back)->gender) return 1;
else if (((STUDENT *)front)->gender < ((STUDENT *)back)->gender) return -1;
else return 0;
}
static int student_age_descend(void *front, void *back)
{
if (((STUDENT *)front)->age > ((STUDENT *)back)->age) return 1;
else if (((STUDENT *)front)->age < ((STUDENT *)back)->age) return -1;
else return 0;
}
static int student_weight_ascend(void *front, void *back)
{
if (((STUDENT *)front)->weight < ((STUDENT *)back)->weight) return 1;
else if (((STUDENT *)front)->weight > ((STUDENT *)back)->weight) return -1;
else return 0;
}
static void test_struct(void)
{
SOPS ops;
STUDENT table[] = {
{"ZhanSan", 18, 1, 56.3},
{"LiSi", 17, 1, 62.2},
{"WangWu", 21, 0, 58.9},
{"ZhaoLiu", 22, 1, 65.5},
{"SunQi", 18, 1, 71.7},
{"ZhouBa", 30, 0, 48.8},
{"WuJiu", 16, 1, 56.3},
{"ZhenShi", 19, 0, 52.1},
};
ops.addr = student_addr;
ops.swap = student_swap;
// 指定为按照名字升序排序
ops.order = student_name_ascend;
sort_bubble(table, 0, sizeof(table)/sizeof(table[0])-1, &ops);
printf("sorting by name in ascending order\r\n");
student_print(table, sizeof(table)/sizeof(table[0]));
printf("---------------------------------\r\n");
// 指定为按照年龄降序排序
ops.order = student_age_descend;
sort_bubble(table, 0, sizeof(table)/sizeof(table[0])-1, &ops);
printf("sorting by age in descending order\r\n");
student_print(table, sizeof(table)/sizeof(table[0]));
printf("---------------------------------\r\n");
// 指定为按照性别降序排序
ops.order = student_gender_descend;
sort_bubble(table, 0, sizeof(table)/sizeof(table[0])-1, &ops);
printf("sorting by gender in descending order\r\n");
student_print(table, sizeof(table)/sizeof(table[0]));
printf("---------------------------------\r\n");
// 指定为按照体重升序排序
ops.order = student_weight_ascend;
sort_bubble(table, 0, sizeof(table)/sizeof(table[0])-1, &ops);
printf("sorting by weight in ascending order\r\n");
student_print(table, sizeof(table)/sizeof(table[0]));
printf("---------------------------------\r\n");
}
测试结果:
sorting by name in ascending order
name: LiSi, age = 17, gender = 1, weight = 62.20
name: SunQi, age = 18, gender = 1, weight = 71.70
name: WangWu, age = 21, gender = 0, weight = 58.90
name: WuJiu, age = 16, gender = 1, weight = 56.30
name: ZhanSan, age = 18, gender = 1, weight = 56.30
name: ZhaoLiu, age = 22, gender = 1, weight = 65.50
name: ZhenShi, age = 19, gender = 0, weight = 52.10
name: ZhouBa, age = 30, gender = 0, weight = 48.80
---------------------------------
sorting by age in descending order
name: ZhouBa, age = 30, gender = 0, weight = 48.80
name: ZhaoLiu, age = 22, gender = 1, weight = 65.50
name: WangWu, age = 21, gender = 0, weight = 58.90
name: ZhenShi, age = 19, gender = 0, weight = 52.10
name: ZhanSan, age = 18, gender = 1, weight = 56.30
name: SunQi, age = 18, gender = 1, weight = 71.70
name: LiSi, age = 17, gender = 1, weight = 62.20
name: WuJiu, age = 16, gender = 1, weight = 56.30
---------------------------------
sorting by gender in descending order
name: ZhaoLiu, age = 22, gender = 1, weight = 65.50
name: ZhanSan, age = 18, gender = 1, weight = 56.30
name: SunQi, age = 18, gender = 1, weight = 71.70
name: LiSi, age = 17, gender = 1, weight = 62.20
name: WuJiu, age = 16, gender = 1, weight = 56.30
name: WangWu, age = 21, gender = 0, weight = 58.90
name: ZhenShi, age = 19, gender = 0, weight = 52.10
name: ZhouBa, age = 30, gender = 0, weight = 48.80
---------------------------------
sorting by weight in ascending order
name: ZhouBa, age = 30, gender = 0, weight = 48.80
name: ZhenShi, age = 19, gender = 0, weight = 52.10
name: ZhanSan, age = 18, gender = 1, weight = 56.30
name: WuJiu, age = 16, gender = 1, weight = 56.30
name: WangWu, age = 21, gender = 0, weight = 58.90
name: LiSi, age = 17, gender = 1, weight = 62.20
name: ZhaoLiu, age = 22, gender = 1, weight = 65.50
name: SunQi, age = 18, gender = 1, weight = 71.70
---------------------------------