/* *02-线性结构1 一元多项式的乘法与加法运算 *本人采用的是不带头结点的单向链表表示多项式 */ # include <stdio.h> # include <stdlib.h> typedef struct Node * List; struct Node{ int xishu; int zhishu; List next; }; typedef struct Node Node; //求表长 int getLength(List list){ if(list == NULL) return 0; int length = 0; List p = list; while(p){ //到达尾结点 length ++; p = p->next; } return length; } //遍历一个链表 void print(List list){ if(NULL == list) printf("0 0"); List p = list; int flag = 0; while(p){ if(flag) printf(" "); else flag = 1; printf("%d %d",p->xishu,p->zhishu); p = p->next; } } //在最后添加一个结点 List insert(List list, List target){ if(list == NULL){ list = target; return list; }else{ List p = list; while(p->next != NULL){ p = p->next; //p指向当前链表的最后一个结点 } p->next = target; return list; //返回插入后的新链表 } } //两个链表相加 List add(List a_list, List b_list){ List sum = NULL, i = a_list, j = b_list, val; while(i && j){ if(i->zhishu > j->zhishu){ val = (List)malloc(sizeof(Node)); val->xishu = i->xishu; val->zhishu = i->zhishu; val->next = NULL; sum = insert(sum,val); i = i->next; }else if(i->zhishu < j->zhishu){ val = (List)malloc(sizeof(Node)); val->xishu = j->xishu; val->zhishu = j->zhishu; val->next = NULL; sum = insert(sum,val); j = j->next; }else{ //指数相等的时候 List newNode = (List)malloc(sizeof(Node)); newNode->xishu = i->xishu + j->xishu; newNode->zhishu = i->zhishu; newNode->next = NULL; sum = insert(sum, newNode); i = i->next; j = j->next; } } while(i){ sum = insert(sum, i); i = i->next; } while(j){ sum = insert(sum, j); j = j->next; } return sum; } //两个链表相乘 List mul(List a_list, List b_list){ List product = NULL; //存放最终结果 List temp = NULL; //存放内层循环结果 List i = a_list, j = b_list; List newNode; while(i){ j=b_list; //这一步千万不要忘记了 temp = NULL; while(j){ newNode = (List)malloc(sizeof(Node)); newNode->xishu = i->xishu * j->xishu; newNode->zhishu = i->zhishu + j->zhishu; newNode->next = NULL; j = j->next; product = insert(product,newNode); //temp = insert(temp,newNode); } //product = add(product, temp); //每个内层循环完之后,与最终结果归并一次 i = i->next; } return product; } //test int main (void){ int a_length, b_length; List a_list = NULL,b_list = NULL; List sum, product; //存放结果 //输入a链表 scanf("%d", &a_length); for(int i=0; i<a_length; i++){ List newNode = (List)malloc(sizeof(Node)); scanf("%d%d", &newNode->xishu, &newNode->zhishu); newNode->next = NULL; a_list = insert(a_list, newNode); } //输入b链表 scanf("%d", &b_length); for(int j=0; j<b_length; j++){ List newNode = (List)malloc(sizeof(Node)); scanf("%d%d", &newNode->xishu, &newNode->zhishu); newNode->next = NULL; b_list = insert(b_list, newNode); } //print(a_list); //print(b_list); sum = add(a_list,b_list); product = mul(a_list,b_list); print(product); printf("\n"); print(sum); return 0; }
解决方案
5
仅供参考:
//链表实现一元多项式的加法减法乘法 #include <stdio.h> #include <stdlib.h> typedef struct node { float coef; //系数 int expn; //指数 struct node *next; } PolyNode; //多项式节点 polynomial node typedef PolyNode* Polynomial; Polynomial createPolynomial() { //创建多项式 PolyNode *p, *q, *head = (PolyNode *)malloc(sizeof(PolyNode)); //头节点 head->next = NULL; float coef; int expn; printf("输入该多项式每一项的系数和指数,每项一行,输入0 0结束!\n"); while (scanf("%f %d", &coef, &expn) && coef) { // 默认,按指数递减排列 if (head->next) { p = head; while (p->next && expn < p->next->expn) p = p->next; if (p->next) { if (expn == p->next->expn) { //有相同指数的直接把系数加到原多项式 p->next->coef += coef; if (p->next->coef > -0.000001 && p->next->coef < 0.000001) { //若是相加后系数为0,则舍弃该节点 q = p->next; p->next = q->next; free(q); } } else { q = (PolyNode*)malloc(sizeof(PolyNode)); q->coef = coef; q->expn = expn; q->next = p->next; p->next = q; } } else { p->next = (PolyNode*)malloc(sizeof(PolyNode)); p = p->next; p->coef = coef; p->expn = expn; p->next = NULL; } } else { head->next = (PolyNode*)malloc(sizeof(PolyNode)); head->next->coef = coef; head->next->expn = expn; head->next->next = NULL; } } return head; } Polynomial multiply(Polynomial poly, float coef, int expn) { //多项式与指定单项式相乘,该单项式为 coefx^expn PolyNode *p, *q, *Poly = (PolyNode*)malloc(sizeof(PolyNode)); p = Poly; q = poly->next; while (q) { p->next = (PolyNode*)malloc(sizeof(PolyNode)); p = p->next; p->coef = (q->coef*coef); p->expn = (q->expn + expn); q = q->next; } p->next = NULL; return Poly; } void add(Polynomial poly1, Polynomial poly2) { //把 poly2 加到 poly1 上 PolyNode *p, *q, *r; r = poly1; p = poly1->next; //指向第一个节点 q = poly2->next; poly2->next = NULL; while (p && q) { if (p->expn > q->expn) { r->next = p; p = p->next; r = r->next; } else if (p->expn < q->expn) { r->next = q; q = q->next; r = r->next; } else { PolyNode *t; p->coef += q->coef; if (!(p->coef > -0.000001 && p->coef < 0.000001)) //系数不为0 { r->next = p; r = r->next; p = p->next; } else { t = p; p = p->next; free(t); } t = q; q = q->next; free(t); } } if (p) r->next = p; if (q) r->next = q; } Polynomial polySubtract(Polynomial poly1, Polynomial poly2) { //多项式减法 poly1-poly2形成一个新的多项式 //把poly2的系数取相反数,形成一个新的多项式 Polynomial poly = (PolyNode*)malloc(sizeof(PolyNode)); //构造头节点 PolyNode *p, *q; p = poly; q = poly2->next; while (q) { p->next = (PolyNode*)malloc(sizeof(PolyNode)); p = p->next; p->coef = -(q->coef); //系数取反 p->expn = q->expn; q = q->next; } p->next = NULL; add(poly, poly1); //利用加法 return poly; } Polynomial polyAdd(Polynomial poly1, Polynomial poly2) { //多项式相加 poly1+poly2形成一个新的多项式 Polynomial poly = (PolyNode*)malloc(sizeof(PolyNode)); //和多项式的头节点 poly->next = NULL; PolyNode *p, *q, *r; r = poly; p = poly1->next; q = poly2->next; while (p&&q) { if (p->expn > q->expn) { r->next = (PolyNode*)malloc(sizeof(PolyNode)); r = r->next; r->coef = p->coef; r->expn = p->expn; p = p->next; } else if (p->expn < q->expn) { r->next = (PolyNode*)malloc(sizeof(PolyNode)); r = r->next; r->coef = q->coef; r->expn = q->expn; q = q->next; } else { float m = p->coef + q->coef; if (!(m > -0.000001 && m < 0.000001)) { r->next = (PolyNode*)malloc(sizeof(PolyNode)); r = r->next; r->coef = m; r->expn = p->expn; } q = q->next; p = p->next; } } while (p) { r->next = (PolyNode*)malloc(sizeof(PolyNode)); r = r->next; r->coef = p->coef; r->expn = p->expn; p = p->next; } while (q) { r->next = (PolyNode*)malloc(sizeof(PolyNode)); r = r->next; r->coef = q->coef; r->expn = q->expn; q = q->next; } r->next = NULL; return poly; } Polynomial polyMultiply(Polynomial poly1, Polynomial poly2) { //多项式相乘 Polynomial poly = (PolyNode*)malloc(sizeof(PolyNode)); //创建多项式和的头节点 poly->next = NULL; PolyNode *p; p = poly2->next; while (p) { add(poly, multiply(poly1, p->coef, p->expn)); p = p->next; } return poly; } void printPoly(Polynomial poly) { //打印多项式 if (poly && poly->next) { PolyNode *p = poly->next; //p指向第一个节点 while (p->next) { printf("%gx^%d", p->coef, p->expn); p = p->next; if (p && (p->coef > 0)) printf("+"); } if (p->expn == 0) printf("%g", p->coef); //打印常数项 else printf("%gx^%d", p->coef, p->expn); printf("\n"); } } void freePoly(Polynomial poly) { //释放内存 if (poly && poly->next) { PolyNode *p, *q; p = poly; while (p) { q = p->next; free(p); p = q; } } poly = NULL; } int main() { printf("用链表实现多项式的加减法\n"); Polynomial poly1, poly2, poly3; printf("创建多项式一\n"); poly1 = createPolynomial(); printf("多项式一:\n"); printPoly(poly1); printf("创建多项式二\n"); poly2 = createPolynomial(); printf("多项式二:\n"); printPoly(poly2); printf("两多项式相加,和为:\n"); poly3 = polyAdd(poly1, poly2); printPoly(poly3); freePoly(poly3); printf("两个多项式相乘,积为:\n"); poly3 = polyMultiply(poly1, poly2); printPoly(poly3); freePoly(poly3); printf("两多项式相减,差为:\n"); poly3 = polySubtract(poly1, poly2); printPoly(poly3); freePoly(poly1); freePoly(poly2); freePoly(poly3); system("pause"); return 0; }
窃代码不叫偷!
5
不带有节点的缺点,你没避开吧
之所以单链表通常会有头结点
是原因是,不带空头结点的单链表
头结点数据的插入,删除等等。
需要特殊处理
添加一个空的(非数据)头结点。
全部数据节点的处理方式就一致了,避免了特殊处理的麻烦。
之所以单链表通常会有头结点
是原因是,不带空头结点的单链表
头结点数据的插入,删除等等。
需要特殊处理
添加一个空的(非数据)头结点。
全部数据节点的处理方式就一致了,避免了特殊处理的麻烦。
20
//两个链表相加
List add(List a_list, List b_list)
的逻辑是混乱的
混合了,创新式产插入和直接插入两种方式
结果是
三个链表中,可能有个链表是互相纠缠的,二者尾部是相同的
形成如下结构
List add(List a_list, List b_list)
的逻辑是混乱的
混合了,创新式产插入和直接插入两种方式
结果是
三个链表中,可能有个链表是互相纠缠的,二者尾部是相同的
形成如下结构
sum-> –> P — >NULL
^
|
i 或 j –>–>
至于乘法倒是没有这个问题,只是忽略了需要降幂(或升幂)排列的事实
同时也没有进行合并同类项的操作。
这里,忽略了多项式乘法的数学意义。
暂时就发现这么多
5
三个链表中,可能有两个链表是互相纠缠的,二者尾部是相同的
一个为和链表
一个为加数链表
其实,乘法采用插入排序的方式插入乘积,就可以做到合并同类项和 升幂,或降幂排列的目的了
实际上,鉴于多项式是升幂或降幂排列的
插入数据的时候,应该进行插入排序,
这样才能保证多项式是有序的
这比靠记忆,或有序输入做到,容易得多
一个为和链表
一个为加数链表
其实,乘法采用插入排序的方式插入乘积,就可以做到合并同类项和 升幂,或降幂排列的目的了
实际上,鉴于多项式是升幂或降幂排列的
插入数据的时候,应该进行插入排序,
这样才能保证多项式是有序的
这比靠记忆,或有序输入做到,容易得多
5
仅供参考:
//不带表头结点的单向链表
#include <stdio.h>
#include <stdlib.h>
#include <malloc.h>
#include <time.h>
#include <locale.h>
struct NODE {
int data;
struct NODE *next;
} *head,*p,*q,*s,*p1,*p2,*q1,**ta;
int i,k,n,t,m,v,N=10;
int main() {
setlocale(LC_ALL,"chs");
srand(time(NULL));
head=NULL;
printf("创建%d个节点的单链表:",N);//创建N个节点的单链表
p=head;
for (i=0;i<N;i++) {
q=(struct NODE *)malloc(sizeof(struct NODE));
if (NULL==q) exit(1);
q->data=rand()%100;//填写0..99的随机值
q->next=NULL;
if (NULL==p) {
head=q;
p=head;
} else {
p->next=q;
p=q;
}
}
//输出整个单链表
s=head;
while (1) {
if (NULL==s) {
printf("\n");
break;
}
printf("%02d->",s->data);
s=s->next;
}
k=3;
v=5;
printf("将值为%d的结点插入到单链表的第%d个结点前:",v,k);//将值为v的结点插入到单链表的第k个结点前
n=0;
p=head;
while (1) {
if (NULL==p) {
break;
}
n++;
if (k==1) {
q=(struct NODE *)malloc(sizeof(struct NODE));
if (NULL==q) exit(1);
q->data=v;
q->next=head;
head=q;
break;
} else {
if (k-1==n) {
q=(struct NODE *)malloc(sizeof(struct NODE));
if (NULL==q) exit(1);
q->data=v;
q->next=p->next;
p->next=q;
break;
}
}
p=p->next;
}
//输出整个单链表
s=head;
while (1) {
if (NULL==s) {
printf("\n");
break;
}
printf("%02d->",s->data);
s=s->next;
}
k=5;
printf("删除第%d个节点:",k);//删除第k个节点
n=0;
p=head;
while (1) {
if (NULL==p) {
break;
}
n++;
if (k==1) {
q=head;
head=head->next;
free(q);
break;
} else {
if (k-1==n) {
q=p->next;
if (q) {
p->next=q->next;
free(q);
}
break;
}
}
p=p->next;
}
//输出整个单链表
s=head;
while (1) {
if (NULL==s) {
printf("\n");
break;
}
printf("%02d->",s->data);
s=s->next;
}
printf("从小到大排序:");//从小到大排序
for (p=head,p1=NULL;p!=NULL;p1=p,p=p->next) {
for (q=p->next,q1=p;q!=NULL;q1=q,q=q->next) {
if (p->data > q->data) {
//交换data
// printf("swap %02d %02d\n",p->data,q->data);
// t=p->data;p->data=q->data;q->data=t;
//或
//交换next
// printf("swap %02d %02d\n",p->data,q->data);
if (p==head) {//p是头
if (p->next==q) {//pq挨着
head=q;
p->next=q->next;
q->next=p;
q=p;
p=head;
} else {//pq不挨着
head=q;
p2=p->next;
p->next=q->next;
q->next=p2;
q1->next=p;
q=p;
p=head;
}
} else {//p不是头
if (p->next==q) {//pq挨着
p1->next=q;
p->next=q->next;
q->next=p;
q=p;
p=p1->next;
} else {//pq不挨着
p1->next=q;
p2=p->next;
p->next=q->next;
q->next=p2;
q1->next=p;
q=p;
p=p1->next;
}
}
//输出整个单链表
// s=head;
// while (1) {
// if (NULL==s) {
// printf("\n");
// break;
// }
// printf("%02d->",s->data);
// s=s->next;
// }
// getchar();
}
}
}
//输出整个单链表并计算链表长度n
n=0;
s=head;
while (1) {
if (NULL==s) {
printf("\n");
break;
}
printf("%02d->",s->data);
n++;
s=s->next;
}
printf("将整个链表逆序:");//将整个链表逆序
if (n>=2) {
p=head;
q=p->next;
p->next=NULL;
while (1) {
q1=q->next;
q->next=p;
p=q;
q=q1;
if (NULL==q) break;
}
head=p;
}
//输出整个单链表
s=head;
while (1) {
if (NULL==s) {
printf("\n");
break;
}
printf("%02d->",s->data);
s=s->next;
}
m=4;
n=6;
printf("将单链表中前%d个结点和后%d个结点进行互换:",m,n);//将单链表中前m个结点和后n个结点进行互换,m+n为链表总长
k=0;
p=head;
while (1) {
if (NULL==p) {
break;
}
k++;
if (m==k) {
q=p;
}
s=p;
p=p->next;
}
q1=head;
head=q->next;
s->next=q1;
q->next=NULL;
//输出整个单链表
s=head;
while (1) {
if (NULL==s) {
printf("\n");
break;
}
printf("%02d->",s->data);
s=s->next;
}
//释放全部节点
p=head;
while (1) {
if (NULL==p) {
break;
}
q=p->next;
free(p);
p=q;
}
return 0;
}
//创建10个节点的单链表:08->74->07->23->03->99->31->56->88->16->
//将值为5的结点插入到单链表的第3个结点前:08->74->05->07->23->03->99->31->56->88->16->
//删除第5个节点:08->74->05->07->03->99->31->56->88->16->
//从小到大排序:03->05->07->08->16->31->56->74->88->99->
//将整个链表逆序:99->88->74->56->31->16->08->07->05->03->
//将单链表中前4个结点和后6个结点进行互换:31->16->08->07->05->03->99->88->74->56->
//
CodeBye 版权所有丨如未注明 , 均为原创丨本网站采用BY-NC-SA协议进行授权 , 转载请注明链表一元多项式乘法, 乘法运行错误,想不通哪里的问题,求帮助!