存储管理动态分区分配及回收算法
作者:互联网
一、目的和要求
分区管理是应用较广泛的一种存储管理技术。本实验要求用一种结构化高级语言构造分区描述器,编制动态分区分配算法和回收算法模拟程序,并讨论不同分配算法的特点。
二、实验内容
1、编写:First Fit Algorithm
2、编写:Best Fit Algorithm
3、编写:空闲区回收算法
三、提示和说明
(一)主程序
1、定义分区描述器node,包括 3个元素:
(1)adr——分区首地址
(2)size——分区大小
(3)next——指向下一个分区的指针
2、定义 3个指向node结构的指针变量:
(1)head1——空闲区队列首指针
(2)back1——指向释放区node结构的指针
(3)assign——指向申请的内存分区node结构的指针
3、定义 1个整形变量:
free——用户申请存储区的大小(由用户键入)
(二)过程
1、定义check过程,用于检查指定的释放块(由用户键入)的合法性
2、定义assignment1过程,实现First Fit Algorithm
3、定义assignment2过程,实现Best Fit Algorithm
4、定义acceptment1过程,实现First Fit Algorithm的回收算法
5、定义acceptment2过程,实现Best Fit Algorithm的回收算法
6、定义print过程,打印空闲区队列
(三)执行
程序首先申请一整块空闲区,其首址为0,大小为32767;然后,提示用户使用哪种分配算法,再提示是分配还是回收;分配时要求输入申请区的大小,回收时要求输入释放区的首址和大小。
(四)输出
要求每执行一次,输出一次空闲区队列情况,内容包括:
编号 首址 终址 大小
注:输出空闲区队列的排序,应符合所用分配算法的要求。
实验报告
一、实验目的
分区管理是应用较广泛的一种存储管理技术。本实验要求用一种结构化高级语言构造分区描述器,编制动态分区分配算法和回收算法模拟程序,并讨论不同分配算法的特点。。
二、实验内容和要求
- 编写:First Fit Algorithm
编写:Best Fit Algorithm
编写:空闲区回收算法编写两种调度算法程序:
2. 程序首先申请一整块空闲区,其首址为0,大小为32767;然后,提示用户使用哪种分配算法,再提示是分配还是回收;分配时要求输入申请区的大小,回收时要求输入释放区的首址和大小。
3. 将程序源代码和运行截图写入实验报告并提交。
三、实验步骤
- 实验准备
(1) 查阅相关资料;
编写两种地址分配算法的程序参考了比较多的内容,首先参考了教材,将两种地址分配算法又重新复习了一下,增加了一下理论的掌握情况,然后又根据实验报告上的要求进行了主体的搭建,具体细节的实现主要参考了一些网上的文章。主要包括下面三篇文章。
https://www.doc88.com/p-1146521830717.html?s=rel&id=1
https://www.doc88.com/p-9197402934769.html?s=rel&id=4
(2) 初步编写程序;
进程调度算法程序主体框架:
void menu() { //菜单及主要过程 char chose; int ch,num=0, r, add, rd; while (1) { system("cls");//清屏 printf("选择最先适应算法输入F,选择最佳适应算法请输入B,退出程序请输入E\n\n"); printf("请选择你的输入:"); scanf("%c", &chose); if (chose == 'e' || chose == 'E') exit(0); else { system("cls"); while (1) { if (chose == 'f' || chose == 'F') printf("最先适应算法(First-Fit)模拟:\n"); if (chose == 'b' || chose == 'B') printf("最佳适应算法(Best-Fit)模拟:\n"); printf("1.分配内存,2.回收内存,3.查看内存,4.返回\n\n"); printf("请输入你的选择:"); scanf("%d", &ch); fflush(stdin);//清除输入缓冲区中的数据 switch (ch) { case 1: printf("输入申请的分区大小:"); scanf("%d", &r); if (chose == 'f' || chose == 'F') assign = assignment1(num, r); else { assign = assignment2(num, r); } if (assign->adr == -1) { printf("分配内存失败!\n"); } else { printf("分配内存成功!分配的首地址为:%d\n", assign->adr); } break; case 2: printf("输入释放的内存的首地址:"); scanf("%d", &add); printf("输入释放内存的大小:"); scanf("%d", &r); printf("输入释放内存的编号:"); scanf("%d", &rd); if (check(add, r, chose)) { if (chose == 'f' || chose == 'F') acceptment1(add, r, rd); if (chose == 'b' || chose == 'B') acceptment2(add, r, rd); } break; case 3: print(chose); break; case 4: menu(); break; } } } } }
(3) 准备测试数据;
进程调度模拟算法,数据输入格式
首先选择算法类型,然后进行分配内存、回收内存、查看内存、返回,等一系列的选择,如下图所示:
- 上机调试
源代码:
#include<stdio.h> #include<stdlib.h> #include<string.h> #pragma warning(disable:4996) #define MAX_SIZE 32767 typedef struct node { int id; int adr; int size; struct node* next; }Node; Node* head1, * head2, * back1, * back2, * assign; int request; //add释放内存的首地址 siz释放内存大小 c算法类型 int check(int add, int siz, char c) { Node* p, * head; int check = 1; if (add < 0 || siz < 0) check = 0;//地址和大小不能为负 if (c == 'f' || c == 'F') head = head1; else head = head2; p = head->next; while ((p != NULL) && check) //两个判断条件,释放地址小于首址,但释放的末地址大于首址。释放地址大于首址,且小于末地址 if (((add < p->adr) && (add + siz > p->adr)) || ((add >= p->adr) && (add < p->adr + p->size))) check = 0; else p = p->next; if (check == 0) printf("\t 输入释放区地址或大小有错误\n"); return check; } void init() { Node* p; head1 = (Node*)malloc(sizeof(Node)); head2 = (Node*)malloc(sizeof(Node)); p = (Node*)malloc(sizeof(Node)); head1->next = p; head2->next = p; p->size = MAX_SIZE; p->adr = 0; p->next = NULL; p->id = 0; } //首次适应算法分配内存 Node* assignment1(int num, int req) { printf("%d %d", num, req); Node* before, * after, * ass; ass = (Node*)malloc(sizeof(Node)); before = head1; after = head1->next; ass->id = num; ass->size = req; //将after指针指向大小刚好适应需求的空闲地址 while (after->size < req) { before = before->next; after = after->next; } if (after == NULL) { ass->adr = -1; } else { //地址与需求地址相等 if (after->size == req) { before->next = after->next; ass->adr = after->adr; } else { //地址比需求地址大 after->size -= req; ass->adr = after->adr; after->adr += req; } } return ass; } //首先分配算法回收内存 void acceptment1(int address, int siz, int rd) { Node* before, * after; int insert = 0; back1 = (Node*)malloc(sizeof(Node)); before = head1; after = head1->next; back1->adr = address; back1->size = siz; back1->id = rd; back1->next = NULL; printf("%d,%d", head1->adr, head1->size); while (!insert && after) { //将要被收回的分区插入到 空闲区(按首地址从小到大插入) //back1地址的大小位于after和before之间 if ((after == NULL) || ((back1->adr <= after->adr) && (back1->adr >= before->adr))) { before->next = back1; back1->next = after; insert = 1; } else { before = before->next; after = after->next; } } if (insert) { //back1的首地址刚好等于before的末地址 if (after && back1->adr + back1->size == after->adr) { //back1的 //和后边分区合并 back1->size += after->size; back1->next = after->next; back1->id = after->id; free(after); } if (back1->adr == before->adr + before->size) { //和前面分区合并 before->size += back1->size; before->next = back1->next; free(back1); } printf("\t 首先分配算法回收内存成功\n"); } else { printf("\t首先分配算法回收内存失败\n"); } } // 最佳适应算法分配内存 Node* assignment2(int num, int req) { Node* before, * after, * ass, * q; ass = (Node*)malloc(sizeof(Node)); q = (Node*)malloc(sizeof(Node)); before = head2; after = head2->next; ass->id = num; ass->size = req; while (after->size < req) { before = before->next; after = after->next; //printf("while"); } if (after == NULL) { ass->adr = -1; printf("null"); } else { if (after->size == req) { printf("=="); before->next = after->next; ass->adr = after->adr; } else { //after->size > req //q是前去req之后的空白分区 q = after; before->next = after->next; ass->adr = q->adr; q->size -= req; q->adr += req; //将q插入到空白链表的对应位置 before = head2; after = head2->next; if (after == NULL) { before->next = q; q->next = NULL; } else { while (after!=NULL&&(after->size) < (q->size)) { before = before->next; after = after->next; //ass->adr=after->adr; } before->next = q; q->next = after; } } } return (ass); } //最佳适应算法回收内存 void acceptment2(int address, int siz, int rd) { Node* before, * after; int insert = 0; back2 = (Node*)malloc(sizeof(Node)); before = head2; after = head2->next; back2->adr = address; back2->size = siz; back2->id = rd; back2->next = NULL; if (head2->next == NULL) { //空闲队列为空 head2->next = back2; head2->size = back2->size; //printf("null"); } else { //空闲队列不为空 while (after) { if (back2->adr == after->adr + after->size) { //和前面空闲分区合并 before->next = after->next; after->size += back2->size; back2 = after; } else { before = before->next; after = after->next; } } before = head2; after = head2->next; //printf("%d %d\n",before->adr,after->adr); while (after) { if (after->adr == back2->adr + back2->size) { //和后边空闲区合并 before->next = after->next; back2->size += after->size; } else { before = before->next; after = after->next; } } before = head2; after = head2->next; //printf("%d %d\n",before->adr,after->adr); //printf("%d,%d,%d\n",after->size,before->size,back2->size); while (!insert) { //printf("%d,%d,%d\n",after->size,before->size,back2->size); //将被回收的快插入到恰当的位置(按分区大小从小到大) if (after == NULL || ((after->size > back2->size))) { before->next = back2; back2->next = after; insert = 1; break; } else { before = before->next; after = after->next; // printf("%d\n",before->adr); } } } if (insert) printf("\t最佳适应算法回收内存成功\n"); else printf("\t最佳适应算法回收内存失败\n"); } void print(char choice) { //输出空闲区队列信息 Node* p; if (choice == 'f' || choice == 'F') p = head1->next; else p = head2->next; if (p) { printf("\n空闲队列的情况为:\n"); printf("\t编号\t首址\t终址\t大小\n"); while (p) { printf("\t%d\t%d\t%d\t%d\n", p->id, p->adr, p->adr + p->size - 1, p->size); p = p->next; } } } void menu() { //菜单及主要过程 char chose; int ch,num=0, r, add, rd; while (1) { system("cls");//清屏 printf("选择最先适应算法输入F,选择最佳适应算法请输入B,退出程序请输入E\n\n"); printf("请选择你的输入:"); scanf("%c", &chose); if (chose == 'e' || chose == 'E') exit(0); else { system("cls"); while (1) { if (chose == 'f' || chose == 'F') printf("最先适应算法(First-Fit)模拟:\n"); if (chose == 'b' || chose == 'B') printf("最佳适应算法(Best-Fit)模拟:\n"); printf("1.分配内存,2.回收内存,3.查看内存,4.返回\n\n"); printf("请输入你的选择:"); scanf("%d", &ch); fflush(stdin);//清除输入缓冲区中的数据 switch (ch) { case 1: printf("输入申请的分区大小:"); scanf("%d", &r); if (chose == 'f' || chose == 'F') assign = assignment1(num, r); else { assign = assignment2(num, r); } if (assign->adr == -1) { printf("分配内存失败!\n"); } else { printf("分配内存成功!分配的首地址为:%d\n", assign->adr); } break; case 2: printf("输入释放的内存的首地址:"); scanf("%d", &add); printf("输入释放内存的大小:"); scanf("%d", &r); printf("输入释放内存的编号:"); scanf("%d", &rd); if (check(add, r, chose)) { if (chose == 'f' || chose == 'F') acceptment1(add, r, rd); if (chose == 'b' || chose == 'B') acceptment2(add, r, rd); } break; case 3: print(chose); break; case 4: menu(); break; } } } } } int main() { //主函数 init(); menu(); return 0; //}
标签:存储管理,adr,分区,after,next,算法,printf,size,before 来源: https://www.cnblogs.com/wfswf/p/16367057.html