数据结构与算法_Python_C完整教程目录:https://www.cnblogs.com/nickchen121/p/11407287.html

一、题意理解

设计函数分别求两个一元多项式的乘积与和,例:

\[\text{已知以下两个多项式:} \\
\begin{align}
& 3x^4-5x^2+6x-2 \\
& 5x^{20}-7x^4+3x
\end{align}
\]

\[\text{多项式和为:} \\
\begin{align}
5x^{20}-4x^4-5x^2+9x-2
\end{align}
\]

假设多项式的乘积为\((a+b)(c+d)=ac+ad+bc+bd\),则多项式的乘积如下:

\[\begin{align}
15x^{24}-25x^{22}+30x^{21}-10x^{20}-21x^8+35x^6-33x^5+14x^4-15x^3+18x^2-6x
\end{align}
\]

通过上述题意理解,我们可以设计函数分别求两个一元多项式的乘积与和。

输入样例:

\[\begin{align}
& 3x^4-5x^2+6x-2 \quad –> \quad \text{4个}\,3\,4\,-5\,2\,6\,1\,-2\,0 \\
& 5x^{20}-7x^4+3x \quad –> \quad \text{3个}\,5\,20\,-7\,4\,3\,1 \\
\end{align} \\
\]

输出样例:

\[\begin{align}
& 15x^{24}-25x^{22}+30x^{21}-10x^{20}-21x^8+35x^6-33x^5+14x^4-15x^3+18x^2-6x \\
& 15 \, 24 \, -25 \, 22 \, 30 \, 21 \, -10 \, 20 \, -21 \, 8 \, 35 \, 6 \, -33 \, 5 \, 14 \, 4 \, -15 \, 3 \, 18 \, 2 \, -6 \, 1 \, 5 \, 20 \, -4 \, 4 \, -5 \, 2 \, 9 \, 1 \, -2 \, 0
\end{align}
\]

二、求解思路

  1. 多项式表示
  2. 程序框架
  3. 读多项式
  4. 加法实现
  5. 乘法实现
  6. 多项式输出

三、多项式的表示

仅表示非零项

3.1 数组

优点:编程简单、调试简单

缺点:需要事先确定数组大小

一种比较好的实现方法是:动态数组(动态更改数组的大小)

3.2 链表

优点:动态性强

缺点:编程略为复杂、调试比较困难

数据结构设计:

/* c语言实现 */

typedef struct PolyNode *Polynomial;
struct PolyNode{
  int coef;
  int expon;
  Polynomial link;
}

四、程序框架搭建

/* c语言实现 */

int main()
{
  读入多项式1;
  读入多项式2;
  乘法运算并输出;
  加法运算并输出;
  return 0;
}

int main()
{
  Polynomial P1, P2, PP, PS;
  
  P1 = ReadPoly();
  P2 = ReadPoly();
  PP = Mult(P1, P2);
  PrintPoly(PP);
  PS = Add(P1, P2);
  PrintPoly(PS);
  
  return 0;
}

需要设计的函数:

  • 读一个多项式
  • 两多项式相乘
  • 两多项式相加
  • 多项式输出

五、如何读入多项式

/* c语言实现 */

Polynomial ReadPoly()
{
  ...;
  scanf("%d", &N);
  ...;
  while (N--) {
    scanf("%d %d", &c, &e);
    Attach(c, e, &Rear);
  }
  ...;
  return P;
}

Rear初值是多少?

两种处理方法:

  1. Rear初值为NULL:在Attach函数中根据Rear是否为NULL做不同处理

  1. Rear指向一个空结点

/* c语言实现 */

void Attach(int c, int e, Polynomial *pRear)
{
  Polynomial P;
  
  P = (Polynomial)malloc(sizeof(struct PolyNode));
  p->coef = c; /* 对新结点赋值 */
  p->expon = e;
  p->link = NULL;
  (*pRear)->link = P;
  (*pRear) = P; /* 修改pRear值 */

/* c语言实现 */

Polynomial ReadPoly()
{
  Polynomial P, Rear, t;
  int c, e, N;
  
  scanf("%d", &N);
  P = (Polynomial)malloc(sizeof(struct PolyNode)); // 链表头空结点
  P->link = NULL;
  Rear = P;
  while (N--) {
    scanf("%d %d", &c, &e);
    Attach(c, e, &Rear); // 将当前项插入多项式尾部
  }
  t = P; P = P->link; free(t); // 删除临时生成的头结点
  return P;
}

六、如何将两个多项式相加

/* c语言实现 */

Polynomial Add(Polynomial P1, Polynomial P2)
{
  ...;
  t1 = P1; t2 = P2;
  P = (Polynomial)malloc(sizeof(struct PolyNode));
  P->link = NULL;
  Rear = P;
  while (t1 && t2){
    if (t1->expon == t2->expon){
      ...;
    }
    else if (t1->expon > t2->expon){
      ...;
    }
    else{
      ...;
    }
  }
  while (t1){
    ...;
  }
  while (t2){
    ...;
  }
  ...;
  return P;
}

七、如何将两个多项式相乘

方法:

  1. 将乘法运算转换为加法运算

将P1当前项(ci, ei)乘P2多项式,再加到结果多项式里

/* c语言实现 */

t1 = P1; t2 = P2;
P = (Polynomial)malloc(sizeof(struct PolyNode)); P->link = NULL;
Rear = P;
while (t2){
  Attach(t1->coef * t2->coef, t1->expon + t2->expon, &Rear);
  t2 = t2->link;
}
  1. 逐项插入

将P1当前项(c1_i, e1_i)乘P2当前项(c2_i, e2_i),并插入到结果多项式中。关键是要找到插入位置

初始结果多项式可由P1第一项乘P2获得(如上)

/* c语言实现 */

Polynomial Mult(Polynomial P1, Polynomial P2)
{
  ...;
  t1 = P1; t2 = P2;
  ...;
  while (t2){ // 先用P1的第一项乘以P2,得到P
    ...;
  }
  t1 = t1->link;
  while (t1){
    t2 = P2; Rear = P;
    while (t2){
      e = t1->expon + t2->expon;
      c = t1->coef * t2->coef;
      ...;
      t2 = t2->link;
    }
    t1 = t1->link;
  }
  ...;
}
/* c语言实现 */

Polynomial Mult(Polynomial P1, Polynomial P2)
{
  Polynomial P, Rear, t1, t2, t;
  int c, e;
  
  if (!P1 || !P2) return NULL;
  
  t1 = P1; t2 = P2;
  P = (Polynomial)malloc(sizeof(struct PolyNOde)); P->link = NULL;
  Rear = P;
  while (t2){ // 先用P1的第一项乘以P2,得到P
    Attach(t1->coef * t2->coef, t1->expon + t2->expon, &Rear);
    t2 = t2->link;
  }

  t1 = t1->link;
  while (t1){
    t2 = P2; Rear = P;
    while (t2){
      e = t1->expon + t2->expon;
      c = t1->coef * t2->coef;
      ...;
      t2 = t2->link;
    }
    t1 = t1->link;
  }
  ...;
}

/* c语言实现 */

Polynomial Mult(Polynomial P1, Polynomial P2)
{
  Polynomial P, Rear, t1, t2, t;
  int c, e;
  
  if (!P1 || !P2) return NULL;
  
  t1 = P1; t2 = P2;
  P = (Polynomial)malloc(sizeof(struct PolyNOde)); P->link = NULL;
  Rear = P;
  while (t2){ // 先用P1的第一项乘以P2,得到P
    Attach(t1->coef * t2->coef, t1->expon + t2->expon, &Rear);
    t2 = t2->link;
  }

  t1 = t1->link;
  while (t1) {
    t2 = P2; Rear = P;
    while (t2) {
      e = t1->expon + t2->expon;
      c = t2->coef * t2->coef;
      while (Rear->link && Rear->link->expon > e)
        Rear = Rear->link;
      if (Rear->link && Rear->link->expon == e){
        ...;
      }
      else{
        ...;
      }
      t2 = t2->link;
    }
    t1 = t1->link;
  }
  ...;
}

/* c语言实现 */

Polynomial Mult(Polynomial P1, Polynomial P2)
{
  Polynomial P, Rear, t1, t2, t;
  int c, e;
  
  if (!P1 || !P2) return NULL;
  
  t1 = P1; t2 = P2;
  P = (Polynomial)malloc(sizeof(struct PolyNOde)); P->link = NULL;
  Rear = P;
  while (t2){ // 先用P1的第一项乘以P2,得到P
    Attach(t1->coef * t2->coef, t1->expon + t2->expon, &Rear);
    t2 = t2->link;
  }

  t1 = t1->link;
  while (t1) {
    t2 = P2; Rear = P;
    while (t2) {
      e = t1->expon + t2->expon;
      c = t2->coef * t2->coef;
      while (Rear->link && Rear->link->expon > e)
        Rear = Rear->link;
      if (Rear->link && Rear->link->expon == e){
        if (Rear->link->coef + c)
          Rear->link->coef += c;
        else{
          t = Rear->link;
          Rear->link = t->link;
          free(t);
        }
      }
      else{
        t = (Polynomial)malloc(sizeof(struct PolyNode));
        t->coef = c; t->expon = e;
        t->link = Rear->link;
        Rear->link = t; Rear = Rear->link;
      }
      t2 = t2->link;
    }
    t1 = t1->link;
  }
  ...;
}

/* c语言实现 */

Polynomial Mult(Polynomial P1, Polynomial P2)
{
  Polynomial P, Rear, t1, t2, t;
  int c, e;
  
  if (!P1 || !P2) return NULL;
  
  t1 = P1; t2 = P2;
  P = (Polynomial)malloc(sizeof(struct PolyNOde)); P->link = NULL;
  Rear = P;
  while (t2){ // 先用P1的第一项乘以P2,得到P
    Attach(t1->coef * t2->coef, t1->expon + t2->expon, &Rear);
    t2 = t2->link;
  }

  t1 = t1->link;
  while (t1) {
    t2 = P2; Rear = P;
    while (t2) {
      e = t1->expon + t2->expon;
      c = t2->coef * t2->coef;
      while (Rear->link && Rear->link->expon > e)
        Rear = Rear->link;
      if (Rear->link && Rear->link->expon == e){
        if (Rear->link->coef + c)
          Rear->link->coef += c;
        else{
          t = Rear->link;
          Rear->link = t->link;
          free(t);
        }
      }
      else{
        t = (Polynomial)malloc(sizeof(struct PolyNode));
        t->coef = c; t->expon = e;
        t->link = Rear->link;
        Rear->link = t; Rear = Rear->link;
      }
      t2 = t2->link;
    }
    t1 = t1->link;
  }
  t2 = P; P = P->link; free(t2);
  return P;
}

八、如何将多项式输出

/* c语言实现 */

void PrintPoly(Polynomial P)
{
  // 输出多项式
  int flag = 0;  // 辅助调整输出格式用,判断输出加法还是乘法
  
  if (!P) {printf("0 0\n"); return ;}
  
  while (P) {
    if (!flag)
      flag = 1;
    else
      printf(" ");
    printf("%d %d", P->coef, P->expon);
    P = P->link;
  }
  printf("\n");
}

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本文链接:https://www.cnblogs.com/nickchen121/p/11457287.html