插入新元素导致链表c编程错误

不清楚您的函数create()是什么

void create(struct node * head, int num) {
struct node * tmp = head;
struct node * prev = NULL;
struct node* new = malloc(sizeof(struct node));
new->key = num;
prev = tmp;
tmp = tmp->next;
while (tmp != NULL && tmp->key < num) {
prev = tmp;
tmp = tmp->next;
}
new->next = tmp;
prev->next = new;
if (tmp == NULL)
head = tmp;
}

应该这样做。你有效地向它传递了一个NULL指针并返回void，所以它所做的一切对外界来说都没有意义。

^tm每个无bs链表实现的起点：

#include <stdbool.h>
#include <stdlib.h>
#include <stdio.h>
typedef struct node_tag {
int value;
struct node_tag *next;
} node_t;
// write functions to encapsulate the data and provide a stable interface:
node_t* node_create_value(int value)
{
node_t *new_node = calloc(1, sizeof *new_node);
if(new_node) new_node->value = value;
return new_node;
}
node_t* node_advance(node_t const *node) { return node->next; }

typedef struct list_tag {  // a list usually consists of
node_t *head;          // a pointer to the first and
node_t *tail;          // a pointer to the last element
// size_t size;        // one might want to add that.
} list_t;
list_t list_create(void)
{
list_t list = { NULL, NULL };
return list;
}
// make code based on these functions "speak" for itself:
node_t* list_begin(list_t const *list) { return list->head; }
node_t* list_end  (list_t const *list) { return list->tail; }
bool list_is_empty(list_t const *list) { return !list_begin(list); }
// common operations for lists:
node_t* list_push_front(list_t *list, int value)
{
node_t *new_node = node_create_value(value);
if (!new_node)
return NULL;
new_node->next = list->head;
return list->head = new_node;
}
node_t* list_push_back(list_t *list, int value)
{
// push_back on an empty list is push_front:
if (list_is_empty(list))
return list->tail = list_push_front(list, value);
node_t *new_node = node_create_value(value);
if (!new_node)
return NULL;
list->tail->next = new_node;
return list->tail = new_node;
}
node_t* list_insert_after(list_t *list, node_t *node, int value)
{
if (list_end(list) == node)
return list_push_back(list, value);
node_t *new_node = node_create_value(value);
if (!new_node)
return NULL;
new_node->next = node->next;
return node->next = new_node;
}
node_t* list_insert_sorted(list_t *list, int value)
{
// first handle the special cases that don't require iterating the whole list:
if (list_is_empty(list) || value < list_begin(list)->value)
return list_push_front(list, value);
if (value > list_end(list)->value)
return list_push_back(list, value);
// the general (worst) case:
for (node_t *current_node = list_begin(list); node_advance(current_node); current_node = node_advance(current_node))
if (value < node_advance(current_node)->value)
return list_insert_after(list, current_node, value);
return NULL; // should never happen
}
void list_print(list_t const *list)
{
for (node_t *current_node = list_begin(list); current_node; current_node = node_advance(current_node))
printf("%dn", current_node->value);
}
void list_free(list_t *list)
{
for(node_t *current_node = list_begin(list), *next_node; current_node; current_node = next_node) {
next_node = current_node->next;
free(current_node);
}
}
// user code should not be required to know anything about the inner workings
// of our list:
int main(void)
{
list_t list = list_create();
for (int i = 1; i < 10; i += 2) {
if (!list_push_back(&list, i)) {
list_free(&list);
fputs("Not enough memory :(nn", stderr);
return EXIT_FAILURE;
}
}
list_print(&list);
putchar('n');
for (int i = 0; i < 11; i += 2) {
if (!list_insert_sorted(&list, i)) {
list_free(&list);
fputs("Not enough memory :(nn", stderr);
return EXIT_FAILURE;
}
}
list_print(&list);
list_free(&list);
}

输出：

1
3
5
7
9
0
1
2
3
4
5
6
7
8
9
10