2006-06-12 17:22:12 +02:00
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/*
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* physical memory allocator, intended to be used to allocate
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* memory for user processes. allocates in 4096-byte "pages".
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* free list is sorted and combines adjacent pages into
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* long runs, to make it easier to allocate big segments.
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* one reason the page size is 4k is that the x86 segment size
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* granularity is 4k.
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*/
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#include "param.h"
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#include "types.h"
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#include "defs.h"
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2006-07-12 13:15:38 +02:00
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#include "param.h"
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#include "mmu.h"
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#include "proc.h"
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2006-07-12 03:48:35 +02:00
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#include "spinlock.h"
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struct spinlock kalloc_lock;
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2006-06-12 17:22:12 +02:00
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struct run {
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struct run *next;
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int len; // bytes
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};
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struct run *freelist;
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void ktest();
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/*
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* initialize free list of physical pages. this code
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* cheats by just considering the one megabyte of pages
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* after _end.
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*/
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void
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kinit()
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{
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extern int end;
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unsigned mem;
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char *start;
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start = (char *) &end;
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start = (char *) (((unsigned)start + PAGE) & ~(PAGE-1));
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mem = 256; // XXX
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cprintf("mem = %d\n", mem * PAGE);
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kfree(start, mem * PAGE);
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ktest();
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}
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void
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kfree(char *cp, int len)
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{
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struct run **rr;
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struct run *p = (struct run *) cp;
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struct run *pend = (struct run *) (cp + len);
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2006-07-01 23:26:01 +02:00
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int i;
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2006-06-12 17:22:12 +02:00
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if(len % PAGE)
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panic("kfree");
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2006-07-01 23:26:01 +02:00
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// XXX fill with junk to help debug
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for(i = 0; i < len; i++)
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cp[i] = 1;
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2006-07-12 03:48:35 +02:00
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acquire(&kalloc_lock);
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2006-06-12 17:22:12 +02:00
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rr = &freelist;
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while(*rr){
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struct run *rend = (struct run *) ((char *)(*rr) + (*rr)->len);
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if(p >= *rr && p < rend)
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panic("freeing free page");
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if(pend == *rr){
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p->len = len + (*rr)->len;
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p->next = (*rr)->next;
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*rr = p;
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2006-07-12 03:48:35 +02:00
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goto out;
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2006-06-12 17:22:12 +02:00
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}
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if(pend < *rr){
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p->len = len;
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p->next = *rr;
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*rr = p;
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2006-07-12 03:48:35 +02:00
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goto out;
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2006-06-12 17:22:12 +02:00
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}
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if(p == rend){
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(*rr)->len += len;
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if((*rr)->next && (*rr)->next == pend){
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(*rr)->len += (*rr)->next->len;
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(*rr)->next = (*rr)->next->next;
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}
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2006-07-12 03:48:35 +02:00
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goto out;
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2006-06-12 17:22:12 +02:00
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}
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rr = &((*rr)->next);
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}
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p->len = len;
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p->next = 0;
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*rr = p;
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2006-07-12 03:48:35 +02:00
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out:
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release(&kalloc_lock);
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2006-06-12 17:22:12 +02:00
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}
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/*
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* allocate n bytes of physical memory.
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* returns a kernel-segment pointer.
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* returns 0 if there's no run that's big enough.
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*/
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char *
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kalloc(int n)
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{
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struct run **rr;
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if(n % PAGE)
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panic("kalloc");
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2006-07-12 03:48:35 +02:00
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acquire(&kalloc_lock);
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2006-06-12 17:22:12 +02:00
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rr = &freelist;
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while(*rr){
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struct run *r = *rr;
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if(r->len == n){
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*rr = r->next;
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2006-07-12 03:48:35 +02:00
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release(&kalloc_lock);
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2006-06-12 17:22:12 +02:00
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return (char *) r;
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}
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if(r->len > n){
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char *p = (char *)r + (r->len - n);
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r->len -= n;
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2006-07-12 03:48:35 +02:00
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release(&kalloc_lock);
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2006-06-12 17:22:12 +02:00
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return p;
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}
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rr = &(*rr)->next;
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}
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2006-07-12 03:48:35 +02:00
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release(&kalloc_lock);
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2006-06-12 17:22:12 +02:00
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return 0;
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}
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void
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ktest()
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{
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char *p1, *p2, *p3;
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// test coalescing
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p1 = kalloc(4 * PAGE);
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kfree(p1 + 3*PAGE, PAGE);
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kfree(p1 + 2*PAGE, PAGE);
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kfree(p1, PAGE);
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kfree(p1 + PAGE, PAGE);
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p2 = kalloc(4 * PAGE);
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if(p2 != p1)
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panic("ktest");
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kfree(p2, 4 * PAGE);
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// test finding first run that fits
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p1 = kalloc(1 * PAGE);
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p2 = kalloc(1 * PAGE);
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kfree(p1, PAGE);
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p3 = kalloc(2 * PAGE);
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kfree(p2, PAGE);
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kfree(p3, 2 * PAGE);
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// test running out of memory
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p1 = 0;
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while(1){
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p2 = kalloc(PAGE);
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if(p2 == 0)
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break;
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*(char **)p2 = p1;
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p1 = p2;
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}
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while(p1){
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p2 = *(char **)p1;
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kfree(p1, PAGE);
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p1 = p2;
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}
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p1 = kalloc(PAGE * 20);
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if(p1 == 0)
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panic("ktest2");
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kfree(p1, PAGE * 20);
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}
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