实验名称:动态分区分配方式模拟
实验目的
进一步加深对动态分区分配管理方式的理解;掌握动态分区分配方式使用的数据结构、分配算法和回收算法
实验内容
编写C语言程序,模拟实现首次/最佳/最坏适应算法的内存块分配和回收,要求每次分配和回收后显示出空闲分区和已分配分区的情况。假设初始状态下,可用的内存空间为640K。
数据结构设计
- 空闲分区表:Unallocated Table
index | address | end | size |
---|---|---|---|
0 | 0 | 639 | 640 |
- 已分配分区表:Allocated Table
index | address | end | size |
---|---|---|---|
0 | 630 | 639 | 10 |
分配算法设计
- 首次适应算法
- 最佳适应算法
- 最差适应算法
根据选择的分配算法决定空闲分区表的排序方式
回收算法设计
文章来源:https://www.toymoban.com/news/detail-768257.html
- 上下都无空分区
- 有上空分区无下空分区
- 无上空分区有下空分区
- 上下分区都为空分区
代码:文章来源地址https://www.toymoban.com/news/detail-768257.html
#include<stdio.h>
#include<stdlib.h>
#include<string.h>
#include<ctype.h>
#define MAX 640
struct node //定义分区
{
int address, size;
struct node *next;
};
typedef struct node RECT;
/*-----函数定义-------*/
void firstfit(RECT *head,int application); //针对首次适应分配算法分配分区
void bestfit(RECT *head,int application); //针对最佳适应分配算法分配分区
void worstfit(RECT *head,int application); //针对最坏适应分配算法分配分区
int backcheck(RECT *head,RECT *back1); //合法性检查
void recycle(RECT *head,RECT *heada,RECT *back1); //回收分区
void print(RECT *head); //输出已分配分区表或空闲分区
/*-----变量定义-------*/
RECT *head,*heada,*back,*assign1,*p;
int application1,maxblocknum;
char way; //用于定义分配方式:首先适应(f)、最佳适应(b)、最差适应(w)
int main()
{
char choose;
int check;
RECT *allocated; //
head=malloc(sizeof(RECT)); //建立空闲分区表的初始状态
p=malloc(sizeof(RECT));
head->size=MAX;
head->address=0;
head->next=p;
maxblocknum=1; //初始只有一块空闲区
p->size=MAX;
p->address=0;
p->next=NULL;
print(head); //输出空闲分区表的初始状态
printf("Enter the way (first, best or worst (f/b/w))\n");
scanf("%c",&way);
heada=malloc(sizeof(RECT)); //建立已分配分区表的初始状态
heada->size=0;
heada->address=0;
heada->next=NULL;
//print(heada); //输出空闲分区表的初始状态
//way='f';
do
{
printf("Enter the allocate or reclaim (a/r),or press other key to exit.\n");
scanf(" %c",&choose); //选择分配或回收
if(tolower(choose)=='a') //a为分配
{
printf("Input application:\n");
scanf("%d",&application1); //输入申请空间大小
if(tolower(way)=='f')
firstfit(head,application1); //首先适应算法分配
else if(tolower(way)=='b')
bestfit(head,application1); //调用最佳适应分配算法函数分配内存
else
worstfit(head,application1); //最坏适应算法分配
if (assign1->address==-1) //分配不成功
printf("Too large application! Allocation fails! \n\n");
else{//分配成功
printf("Allocation Success! ADDRESS=%5d\n",assign1->address);
printf("\n*********Unallocated Table**********\n");
print(head); //输出
printf("\n*********Allocated Table************\n");
print(heada);
}
}
else if (tolower(choose)=='r') //回收内存
{
back=malloc(sizeof(RECT));
printf("Input address and Size:\n");
scanf("%d%d",&back->address,&back->size);//输入回收地址和大小
check=backcheck(head,back);
if (check==1)
{
recycle(head,heada,back);
printf("\n*********Unallocated Table**********\n");
print(head); //输出
printf("\n*********Allocated Table************\n");
print(heada);
}
}
}while(tolower(choose)=='a'||tolower(choose)=='r');
exit(0);
} //main() end.
/*-------内存回收函数,back1为回收节点到地址-------*/
void recycle(RECT *head,RECT *heada,RECT *back1)
{
RECT *before, *after, *back2;
int insert = 0, del;
back2 = malloc(sizeof(RECT));
back2->address = back1->address;
back2->size = back1->size;
back2->next = back1->next;
before = head;
after = head->next;
if (head->next == NULL) // 没有空闲区,直接回收
{
head->size = back1->size;
head->next = back1;
maxblocknum++;
back1->next = NULL;
}
else
{
while (!insert&&after!=NULL) // 遍历空闲区
{
if (back1->address == after->size + after->address) /*要回收的内存在当前空闲区之后,与上一块合并*/
{//第一种情况,回收区与相邻低地址合并
after->size+=back1->size;
insert=1;
// before->next = after->next;
// back->size = after->size + back1->size;
// free(after);
// after = NULL;
}else if(back1->address+back1->size==after->address)
{ //第二种情况,回收区与相邻高地址合并
after->size+=back1->size;
after->address=back1->address;
insert=1;
}else if(before->address<back1->address&&after->address>back1->address)
{ //第三种情况,回收区与相邻的高地址、低地址合并,被夹在中间
before->size+=back1->size+after->size;
insert=1;
}
after = after->next;
before = before->next;
}
//第四种情况,回收区独自一块,需要在空闲表中新增一项
before = head; /*将回收节点插入到合适到位置*/
after = head->next;
do
{
if (after == NULL)
{
before->next = back1;
back1->next = after;
insert = 1;
}
else
{
before = before->next;
after = after->next;
}
} while (!insert);
if (head->size < back1->size) /*修改最大块值和最大块数*/
{
head->size = back1->size;
maxblocknum++;
}
else
{
if (head->size == back1->size)
maxblocknum++;
}
}
// 修改已分配分区表,删除相应节点
before = heada;
after = heada->next;
del = 0;
while (!del &&after != NULL) // 1,循环在已删除或者遍历结束时退出,将回收区从已分配分区表中删除
{
if ((after->address == back2->address) && (after->size == back2->size))
{
before->next = after->next;
free(after);
del = 1;
}
else
{
before = before->next;
after = after->next;
}
}
heada->size--;
}
/*------------------首次适应分配算法------------*/
void firstfit(RECT *head,int application)
{
RECT *after, *before, *assign;
assign = malloc(sizeof(RECT)); // 申请分配空间
assign->size = application;
assign->next = NULL;
if (application > head->size || application < 0)
assign->address = -1; // 申请无效
else
{
before = head;
after = head->next;
while (after->size < application) // 遍历链表,查找合适到节点
{
before = before->next;
after = after->next;
}
if (after->size == application) // 若节点大小等于申请大小则完全分配
{
if (after->size == head->size)
maxblocknum--;
before->next = after->next; // 指向后面的空闲区
assign->address = after->address; // 将这个同样大小的地址直接赋给分配的对象
free(after);
}
else
{
if (after->size == head->size) // 这个可分配空间等于剩余总的空闲空间
maxblocknum--;
after->size = after->size - application; // 大于申请空间则截取相应大小分配
assign->address = after->address + after->size; // 分配靠后的地址
}
if (maxblocknum == 0) // 修改最大数和头节点
{
before = head;
head->size = 0;
maxblocknum = 1;
while (before != NULL) // 遍历空闲区
{
if (before->size > head->size)
{
head->size = before->size;
maxblocknum = 1;
}
else if (before->size == head->size)
maxblocknum++;
before = before->next;
}
}
}
assign1 = assign;
// 修改已分配分区表,添加节点
after = heada;
while (after->next != NULL)
after = after->next;
after->next = assign;
heada->size++;
}
/*-----------------最佳适应分配算法--------------*/
void bestfit(RECT *head,int application)
{
RECT *after, *before, *assign;
assign = malloc(sizeof(RECT)); // 申请分配空间
assign->size = application;
assign->next = NULL;
if (application > head->size || application < 0)
assign->address = -1; // 申请无效
else
{
before = head;
RECT* ptr = head->next;
int tmp=0;
//找到第一块最合适的空闲分区,即空间大于application的最小分区
while (ptr!=NULL) // 遍历链表,查找合适到节点
{
if(ptr->size>=application){
if(!tmp||ptr->size<tmp){
after=ptr;
tmp=ptr->size;
}
}
ptr=ptr->next;
}
if (after->size == application) // 若节点大小等于申请大小则完全分配
{
if (after->size == head->size)
maxblocknum--;
before->next = after->next; // 指向后面的空闲区
assign->address = after->address; // 将这个同样大小的地址直接赋给分配的对象
free(after);
}
else
{
if (after->size == head->size) // 这个可分配空间等于剩余总的空闲空间
maxblocknum--;
after->size = after->size - application; // 大于申请空间则截取相应大小分配
assign->address = after->address + after->size; // 分配靠后的地址
}
if (maxblocknum == 0) // 修改最大数和头节点
{
before = head;
head->size = 0;
maxblocknum = 1;
while (before != NULL) // 遍历空闲区
{
if (before->size > head->size)
{
head->size = before->size;
maxblocknum = 1;
}
else if (before->size == head->size)
maxblocknum++;
before = before->next;
}
}
}
assign1 = assign;
// 修改已分配分区表,添加节点
after = heada;
while (after->next != NULL)
after = after->next;
after->next = assign;
heada->size++;
}
/*-----------------最坏适应分配算法--------------*/
void worstfit(RECT *head,int application)
{
RECT *after, *before, *assign;
assign = malloc(sizeof(RECT)); // 申请分配空间
assign->size = application;
assign->next = NULL;
if (application > head->size || application < 0)
assign->address = -1; // 申请无效
else
{
before = head;
RECT* ptr = head->next;
int tmp=0;
//找到最大的空闲分区进行分配
while (ptr!=NULL) // 遍历链表,查找合适到节点
{
if(ptr->size>=application){
if(ptr->size>tmp){
after=ptr;
tmp=ptr->size;
}
}
ptr=ptr->next;
}
if (after->size == application) // 若节点大小等于申请大小则完全分配
{
if (after->size == head->size)
maxblocknum--;
before->next = after->next; // 指向后面的空闲区
assign->address = after->address; // 将这个同样大小的地址直接赋给分配的对象
free(after);
}
else
{
if (after->size == head->size) // 这个可分配空间等于剩余总的空闲空间
maxblocknum--;
after->size = after->size - application; // 大于申请空间则截取相应大小分配
assign->address = after->address + after->size; // 分配靠后的地址
}
if (maxblocknum == 0) // 修改最大数和头节点
{
before = head;
head->size = 0;
maxblocknum = 1;
while (before != NULL) // 遍历空闲区
{
if (before->size > head->size)
{
head->size = before->size;
maxblocknum = 1;
}
else if (before->size == head->size)
maxblocknum++;
before = before->next;
}
}
}
assign1 = assign;
// 修改已分配分区表,添加节点
after = heada;
while (after->next != NULL)
after = after->next;
after->next = assign;
heada->size++;
}
/*-----------------打印输出链表--------------*/
void print(RECT *output)
{
RECT *before;
int index;
before=output->next;
index=0;
if(output->next==NULL)
printf("NO part for print!\n");
else
{
printf("index****address****end*****size**** \n");
while(before!=NULL)
{
printf("------------------------------------\n");
printf(" %-9d%- 9d%- 9d%- 9d\n",index,before->address,before->address+before->size-1,before->size);
printf("------------------------------------\n");
index++;
before=before->next;
}
}
}
/*检查回收块到合法性,back1为要回收到节点地址*/
int backcheck(RECT *head,RECT *back1)
{
RECT *before;
int check=1;
if(back1->address<0 || back1->size<0) check=0; //地址和大小不能为负数
before=head->next;
while((before!=NULL)&&check) //地址不能和空闲区表中节点出现重叠
if(((back1->address<before->address)&&(back1->address+back1->size>before->address))||((back1->address>=before->address)&&(back1->address<before->address+before->size)))
check=0;
else
before=before->next;
if(check==0) printf("Error input!\n");
return check;
}
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