#include<iostream>
#include"../../全局定义/预定义常量和类型/预定义常量和类型.cpp"
#include"../../全局定义/Compare函数的定义/Compare函数的定义.cpp"
using namespace std;
template <typename ElemType>
struct LinkNode {
ElemType data;
struct LinkNode<ElemType>* next;
};
#define LinkList LinkNode<ElemType>*
// 初始化链表
template <typename ElemType>
Status InitLinkList(LinkList& linkList) {
// 建立“头结点”,并使得其next指针指向NULL
linkList = (LinkList)malloc(sizeof(LinkNode<ElemType>));
if (!linkList)
exit(OVERFLOW);
linkList->next = NULL;
return OK;
}
// 获取链表的长度
template <typename ElemType>
int LengthOfLinkList(LinkList linkList) {
LinkNode<ElemType>* p = linkList->next;
int length = 0;
while (p != NULL)
{
length++;
p = p->next;
}
return length;
}
// 查找第order个节点的地址
template <typename ElemType>
Status LocationInOrder(LinkList linkList, int order, LinkNode<ElemType>*& p_linkNode) {
// 判断order的合法性: [0, length]
if (0 <= order)
{
int index = 0;
LinkNode<ElemType>* cursor = linkList;
/*
* index < order : 保证终止时index=order,此时p指向第order个位置
* cursor!=NULL : 保证第order个元素不是空【order<=length】
* 总结:①、index<n保证指向第n个节点;②、?!=NULL确定order的最大值为:length-COUNT(next);
*/
while (index < order && cursor)
{
cursor = cursor->next;
index++;
}
if (!cursor) // 表示order>length
return ERROR;
else
{
p_linkNode = cursor;
return OK;
}
}
else
{
return ERROR;
}
}
// 查找相对第order个前驱节点的地址
template <typename ElemType>
Status LocationInRelativeOrder_Prior(LinkList linkList, int relativeOrder, LinkNode<ElemType>* p_linkNode, LinkNode<ElemType>*& p_relative) {
p_relative = NULL;
// relativeOrder的合法性: [0, p_linkNode-1]。
if (relativeOrder < 0)
return ERROR;
// 让游标指向首元结点
LinkNode<ElemType>* cursor = linkList->next;
int order = 1;
// order在这一范围内跳出 → o≤r
// 先让cursor前进relativeOrder个单位,指向relativeOrder+1,这时正好相距relativeOrder-1个单位
while (order < relativeOrder + 1)
{
if (cursor == p_linkNode)
return ERROR;
cursor = cursor->next;
order++;
}
p_relative = linkList->next;
// 然后p_relative与cursor再一起前进直到cursor==p_linkNode,此时
while (cursor != p_linkNode)
{
p_relative = p_relative->next;
cursor = cursor->next;
}
return OK;
}
// 查找相对第order个后继节点的地址
template <typename ElemType>
Status LocationInRelativeOrder_Next(LinkList linkList, int relativeOrder, LinkNode<ElemType>* p_linkNode, LinkNode<ElemType>*& p_relative) {
p_relative = NULL;
if (relativeOrder < 0)
return ERROR;
int order = 0;
p_relative = p_linkNode;
while (order < relativeOrder)
{
p_relative = p_relative->next;
order++;
if (!p_relative)
return ERROR;
}
return OK;
}
// 查找相对第order个节点的地址
template <typename ElemType>
Status LocationInRelativeOrder(LinkList linkList, int relativeOrder, LinkNode<ElemType>* p_linkNode, LinkNode<ElemType>*& p_relative) {
return
relativeOrder <= 0 ?
LocationInRelativeOrder_Prior(linkList, -relativeOrder, p_linkNode, p_relative) :
LocationInRelativeOrder_Next(linkList, relativeOrder, p_linkNode, p_relative);
}
// 查找第1个满足compare关系的data所在的位置以及索引
template <typename ElemType>
int LocationOfLinkNode(LinkList linkList, ElemType data, LinkNode<ElemType>*& p_linkNode, int (*compare)(ElemType, ElemType)) {
LinkNode<ElemType>* cursor = linkList->next;
int index = 1;
while (cursor)
{
if (compare(cursor->data, data))
break;
cursor = cursor->next;
index++;
}
p_linkNode = cursor;
if (!cursor)
index = -1;
return index;
}
// 在链表的头部插入元素(头插法)
template <typename ElemType>
Status InsertLinkList(LinkList& linkList, ElemType data) {
// 创建一个数据为data的新节点
LinkNode<ElemType>* p_dataNode = (LinkNode<ElemType>*)malloc(sizeof(LinkNode<ElemType>));
if (!p_dataNode)
return ERROR;
else
{
p_dataNode->data = data;
// 让新节点的next指向旧节点
p_dataNode->next = linkList->next;
// 让头结点的next指向这个新的节点,使其成为新的第一个节点
linkList->next = p_dataNode;
return OK;
}
}
// 在地址为p_linkNode的后继插入元素
template <typename ElemType>
Status InsertLinkListNext(LinkNode<ElemType>* p_linkNode, ElemType data) {
LinkNode<ElemType>* nextNode = (LinkNode<ElemType>*)malloc(sizeof(LinkNode<ElemType>));
if (!nextNode)
return ERROR;
nextNode->data = data;
nextNode->next = p_linkNode->next;
p_linkNode->next = nextNode;
return OK;
}
// 在指定序号order处插入元素data
template <typename ElemType>
Status InsertLinkList(LinkList& linkList, int order, ElemType data) {
// 找到第order-1个节点
LinkNode<ElemType>* p_preOfOrder = NULL;
// order-1的范围与查找函数规定的范围一致
if (LocationInOrder(linkList, order - 1, p_preOfOrder) == OK)
{
LinkNode<ElemType>* p_dataNode = (LinkNode<ElemType>*)malloc(sizeof(LinkNode<ElemType>));
if (!p_dataNode)
return OVERFLOW;
else
{
p_dataNode->data = data;
p_dataNode->next = p_preOfOrder->next;
p_preOfOrder->next = p_dataNode;
return OK;
}
}
else
{
return ERROR;
}
}
// 在指定序号order处插入新的链表
template <typename ElemType>
Status InsertLinkList(LinkList& linkList_dest, int order, LinkList linkList_source) {
// 判断order的合法性: [1, length+1]
int index = order;
LinkNode<ElemType>* p_source = linkList_source->next;
while (p_source)
{
if (InsertLinkList(linkList_dest, order++, p_source->data) != OK)
return ERROR;
p_source = p_source->next;
}
return OK;
}
// 创建节点,并返回长度
template <typename ElemType>
int InputLinkNodes(LinkList& linkList) {
char finishFlag = '
';
int length = 0;
cout << "请输入一组" << typeid(ElemType).name() << "序列(回车结束输入):";
do {
ElemType data;
cin >> data;
InsertLinkList(linkList, ++length, data);
finishFlag = getchar();
} while (finishFlag != '
');
return length;
}
// 在指定序号order处删除元素
template <typename ElemType>
Status DeleteLinkNode(LinkList& linkList, int order) {
// 找到第order-1个节点
LinkNode<ElemType>* p_preOfOrder = NULL;
// order-1的范围: [0, length-1];查找函数规定的范围: [0, length]
if (LocationInOrder(linkList, order - 1, p_preOfOrder) == OK && p_preOfOrder->next) {
// !p_preOfOrder->next:保证order-1不是第length个节点【order<length+1】
LinkNode<ElemType>* p_del = p_preOfOrder->next;
p_preOfOrder->next = p_del->next;
free(p_del);
return OK;
}
else
{
return ERROR;
}
}
// 删除指定地址的元素
template <typename ElemType>
Status DeleteLinkNode(LinkList& linkList, LinkNode<ElemType>* node_del) {
// 找到直接前驱
LinkNode<ElemType>* p_prior = NULL;
if (LocationInRelativeOrder(linkList, -1, node_del, p_prior) == OK) {
p_prior->next = node_del->next;
free(node_del);
}
else {
return ERROR;
}
}
// 删除指定地址的元素的直接后继
template <typename ElemType>
Status DeleteNextLinkNode(LinkList& linkList, LinkNode<ElemType>* node_del) {
LinkNode<ElemType>* node_del_next = node_del->next;
node_del->next = node_del_next->next;
free(node_del_next);
}
// 将链表逆序
template <typename ElemType>
Status ReverseLinkList(LinkList& linkList) {
// 查找第2个元素,若找不到则说明:linkList中的节点数<2
LinkNode<ElemType>* p_second = NULL;
if (LocationInOrder(linkList, 2, p_second) == OK) {
// 将原有的空间变为两个链表【头结点和头指针】
linkList->next->next = NULL;
LinkNode<ElemType>* preCursor, * cursor;
preCursor = cursor = p_second;
while (preCursor)
{
// cursor保证后继节点有指针指向
cursor = cursor->next;
// 头插法插入_linkList->next指向的节点
preCursor->next = linkList->next;
linkList->next = preCursor;
// _linkList向后移动一位
preCursor = cursor;
}
return OK;
}
else
{
return ERROR;
}
}
// 将两个链表合并
template <typename ElemType>
LinkList MergeLinkList(LinkList& linkList_dest, LinkList& linkList_source) {
LinkNode<ElemType>* p_dest = linkList_dest->next, * p_source = linkList_source->next;
LinkNode<ElemType>* p_tmp = linkList_dest;
while (p_dest && p_source)
{
if (p_dest->data <= p_source->data)
{
p_tmp->next = p_dest;
p_tmp = p_dest;
p_dest = p_dest->next;
}
else
{
p_tmp->next = p_source;
p_tmp = p_source;
p_source = p_source->next;
}
}
p_tmp->next = p_dest ? p_dest : p_source;
free(linkList_source);
return linkList_dest;
}
// 将链表中的所有元素打印出来
template <typename ElemType>
void PrintLinkList(LinkList linkList) {
LinkNode<ElemType>* p = linkList;
cout << "头结点 → ";
while (p->next)
{
p = p->next;
cout << p->data << " → ";
}
cout << "NULL" << endl;
}
int main() {
// 测试用例:12 23 34 45 56 67 78 89 90
#define ElemType int
LinkList linkList;
InitLinkList(linkList);
int length = InputLinkNodes(linkList);
cout << "linkList的长度为:" << length << endl;
cout << "linkList的元素有:";
PrintLinkList(linkList);
int order_del;
order_del = 1;
DeleteLinkNode(linkList, order_del);
cout << "删除第" << order_del << "个节点之后:";
PrintLinkList(linkList);
order_del = 5;
DeleteLinkNode(linkList, order_del);
cout << "删除第" << order_del << "个节点之后:";
PrintLinkList(linkList);
order_del = 3;
DeleteLinkNode(linkList, order_del);
cout << "删除第" << order_del << "个节点之后:";
PrintLinkList(linkList);
cout << "linkList逆序输出: ";
ReverseLinkList(linkList);
PrintLinkList(linkList);
LinkNode<ElemType>* p_linkNode = NULL, * p_relativePrior = NULL, * p_relativeNext = NULL;
int coreOrder = 3;
LocationInOrder(linkList, coreOrder, p_linkNode);
LocationInRelativeOrder(linkList, -2, p_linkNode, p_relativePrior);
LocationInRelativeOrder(linkList, 2, p_linkNode, p_relativeNext);
cout << "相对核心位置" << coreOrder << "为-2:" << p_relativePrior->data << endl;
cout << "相对核心位置" << coreOrder << "为+2:" << p_relativeNext->data << endl;
cout << "删除第" << coreOrder << "个结点(" << p_linkNode->data << ")之后:";
DeleteLinkNode(linkList, p_linkNode);
PrintLinkList(linkList);
#undef ElemType
#define ElemType int
LinkList linkList_source;
InitLinkList(linkList_source);
InsertLinkList(linkList_source, 3);
InsertLinkList(linkList_source, 2);
InsertLinkList(linkList_source, 1);
cout << "linkList : ";
PrintLinkList(linkList);
cout << "linkList_source : ";
PrintLinkList(linkList_source);
cout << "合并后linkList : ";
InsertLinkList(linkList, 2, linkList_source);
PrintLinkList(linkList);
LinkNode<ElemType>* p = NULL, * p_linkNode_2 = NULL;
LocationInOrder(linkList, 2, p);
cout << "第2个位置的元素为:" << p->data << endl;
cout << "第1个" << p->data << "的位置为:" << LocationOfLinkNode(linkList, p->data, p_linkNode_2, Equal) << endl;
#undef ElemType
return 0;
}