kolibrios-gitea/kernel/branches/kolibri_pe/core/heap.c
Sergey Semyonov (Serge) 072729a7f2 move kernel vars into .bss
git-svn-id: svn://kolibrios.org@928 a494cfbc-eb01-0410-851d-a64ba20cac60
2008-11-22 12:57:25 +00:00

779 lines
18 KiB
C

#include <types.h>
#include <core.h>
#include <spinlock.h>
#include <link.h>
#include <mm.h>
#include <slab.h>
#define MD_FREE 1
#define MD_USED 2
typedef struct {
u32_t av_mapped;
u32_t av_unmapped;
link_t mapped[32];
link_t unmapped[32];
link_t used;
SPINLOCK_DECLARE(lock); /**< this lock protects everything below */
}heap_t;
slab_cache_t *md_slab;
slab_cache_t *phm_slab;
heap_t lheap;
heap_t sheap;
static inline void _set_lavu(count_t idx)
{ asm volatile ("bts %0, _lheap+4"::"r"(idx):"cc"); }
static inline void _reset_lavu(count_t idx)
{ asm volatile ("btr %0, _lheap+4"::"r"(idx):"cc"); }
static inline void _set_savm(count_t idx)
{ asm volatile ("bts %0, _sheap"::"r"(idx):"cc"); }
static inline void _reset_savm(count_t idx)
{ asm volatile ("btr %0, _sheap"::"r"(idx):"cc"); }
static inline void _set_savu(count_t idx)
{ asm volatile ("bts %0, _sheap+4"::"r"(idx):"cc"); }
static inline void _reset_savu(count_t idx)
{ asm volatile ("btr %0, _sheap+4"::"r"(idx):"cc"); }
int __fastcall init_heap(addr_t base, size_t size)
{
md_t *md;
u32_t i;
ASSERT(base != 0);
ASSERT(size != 0)
ASSERT((base & 0x3FFFFF) == 0);
ASSERT((size & 0x3FFFFF) == 0);
for (i = 0; i < 32; i++)
{
list_initialize(&lheap.mapped[i]);
list_initialize(&lheap.unmapped[i]);
list_initialize(&sheap.mapped[i]);
list_initialize(&sheap.unmapped[i]);
};
list_initialize(&lheap.used);
list_initialize(&sheap.used);
md_slab = slab_cache_create(sizeof(md_t), 16,NULL,NULL,SLAB_CACHE_MAGDEFERRED);
md = (md_t*)slab_alloc(md_slab,0);
list_initialize(&md->adj);
md->base = base;
md->size = size;
md->parent = NULL;
md->state = MD_FREE;
list_prepend(&md->link, &lheap.unmapped[31]);
lheap.av_mapped = 0x00000000;
lheap.av_unmapped = 0x80000000;
sheap.av_mapped = 0x00000000;
sheap.av_unmapped = 0x00000000;
return 1;
};
md_t* __fastcall find_large_md(size_t size)
{
md_t *md = NULL;
count_t idx0;
u32_t mask;
ASSERT((size & 0x3FFFFF) == 0);
idx0 = (size>>22) - 1 < 32 ? (size>>22) - 1 : 31;
mask = lheap.av_unmapped & ( -1<<idx0 );
if(mask)
{
if(idx0 == 31)
{
md_t *tmp = (md_t*)lheap.unmapped[31].next;
while(&tmp->link != &lheap.unmapped[31])
{
if(tmp->size >= size)
{
DBG("remove large tmp %x\n", tmp);
md = tmp;
break;
};
};
tmp = (md_t*)tmp->link.next;
}
else
{
idx0 = _bsf(mask);
ASSERT( !list_empty(&lheap.unmapped[idx0]))
md = (md_t*)lheap.unmapped[idx0].next;
};
}
else
return NULL;
ASSERT(md->state == MD_FREE);
list_remove((link_t*)md);
if(list_empty(&lheap.unmapped[idx0]))
_reset_lavu(idx0);
if(md->size > size)
{
count_t idx1;
md_t *new_md = (md_t*)slab_alloc(md_slab,0); /* FIXME check */
link_initialize(&new_md->link);
list_insert(&new_md->adj, &md->adj);
new_md->base = md->base;
new_md->size = size;
new_md->parent = NULL;
new_md->state = MD_USED;
md->base+= size;
md->size-= size;
idx1 = (md->size>>22) - 1 < 32 ? (md->size>>22) - 1 : 31;
list_prepend(&md->link, &lheap.unmapped[idx1]);
_set_lavu(idx1);
return new_md;
};
md->state = MD_USED;
return md;
}
md_t* __fastcall find_unmapped_md(size_t size)
{
eflags_t efl;
md_t *md = NULL;
count_t idx0;
u32_t mask;
ASSERT((size & 0xFFF) == 0);
efl = safe_cli();
idx0 = (size>>12) - 1 < 32 ? (size>>12) - 1 : 31;
mask = sheap.av_unmapped & ( -1<<idx0 );
DBG("smask %x size %x idx0 %x mask %x\n",sheap.av_unmapped, size, idx0, mask);
if(mask)
{
if(idx0 == 31)
{
ASSERT( !list_empty(&sheap.unmapped[31]));
md_t *tmp = (md_t*)sheap.unmapped[31].next;
while( &tmp->link != &sheap.unmapped[31])
{
if(tmp->size >= size)
{
md = tmp;
break;
};
tmp = (md_t*)tmp->link.next;
};
}
else
{
idx0 = _bsf(mask);
ASSERT( !list_empty(&sheap.unmapped[idx0]));
md = (md_t*)sheap.unmapped[idx0].next;
}
};
if(md)
{
DBG("remove md %x\n", md);
ASSERT(md->state==MD_FREE);
ASSERT(md->parent != NULL);
list_remove((link_t*)md);
if(list_empty(&sheap.unmapped[idx0]))
_reset_savu(idx0);
}
else
{
md_t *lmd;
lmd = find_large_md((size+0x3FFFFF)&~0x3FFFFF);
DBG("get large md %x\n", lmd);
if( !lmd)
{
safe_sti(efl);
return NULL;
};
ASSERT(lmd->size != 0);
ASSERT(lmd->base != 0);
ASSERT((lmd->base & 0x3FFFFF) == 0);
ASSERT(lmd->parent == NULL);
md = (md_t*)slab_alloc(md_slab,0); /* FIXME check */
link_initialize(&md->link);
list_initialize(&md->adj);
md->base = lmd->base;
md->size = lmd->size;
md->parent = lmd;
md->state = MD_USED;
};
if(md->size > size)
{
count_t idx1;
md_t *new_md = (md_t*)slab_alloc(md_slab,0); /* FIXME check */
link_initialize(&new_md->link);
list_insert(&new_md->adj, &md->adj);
new_md->base = md->base;
new_md->size = size;
new_md->parent = md->parent;
new_md->state = MD_USED;
md->base+= size;
md->size-= size;
md->state = MD_FREE;
idx1 = (md->size>>12) - 1 < 32 ? (md->size>>12) - 1 : 31;
DBG("insert md %x, base %x size %x idx %x\n", md,md->base, md->size,idx1);
if( idx1 < 31)
list_prepend(&md->link, &sheap.unmapped[idx1]);
else
{
if( list_empty(&sheap.unmapped[31]))
list_prepend(&md->link, &sheap.unmapped[31]);
else
{
md_t *tmp = (md_t*)sheap.unmapped[31].next;
while( &tmp->link != &sheap.unmapped[31])
{
if(md->base < tmp->base)
break;
tmp = (md_t*)tmp->link.next;
}
list_insert(&md->link, &tmp->link);
};
};
_set_savu(idx1);
safe_sti(efl);
return new_md;
};
md->state = MD_USED;
safe_sti(efl);
return md;
}
md_t* __fastcall find_mapped_md(size_t size)
{
eflags_t efl;
md_t *md = NULL;
count_t idx0;
u32_t mask;
ASSERT((size & 0xFFF) == 0);
efl = safe_cli();
idx0 = (size>>12) - 1 < 32 ? (size>>12) - 1 : 31;
mask = sheap.av_mapped & ( -1<<idx0 );
DBG("small av_mapped %x size %x idx0 %x mask %x\n",sheap.av_mapped, size,
idx0, mask);
if(mask)
{
if(idx0 == 31)
{
ASSERT( !list_empty(&sheap.mapped[31]));
md_t *tmp = (md_t*)sheap.mapped[31].next;
while( &tmp->link != &sheap.mapped[31])
{
if(tmp->size >= size)
{
md = tmp;
break;
};
tmp = (md_t*)tmp->link.next;
};
}
else
{
idx0 = _bsf(mask);
ASSERT( !list_empty(&sheap.mapped[idx0]));
md = (md_t*)sheap.mapped[idx0].next;
}
};
if(md)
{
DBG("remove md %x\n", md);
ASSERT(md->state==MD_FREE);
list_remove((link_t*)md);
if(list_empty(&sheap.mapped[idx0]))
_reset_savm(idx0);
}
else
{
md_t *lmd;
addr_t frame;
addr_t *pte;
int i;
lmd = find_large_md((size+0x3FFFFF)&~0x3FFFFF);
DBG("get large md %x\n", lmd);
if( !lmd)
{
safe_sti(efl);
return NULL;
};
ASSERT(lmd->size != 0);
ASSERT(lmd->base != 0);
ASSERT((lmd->base & 0x3FFFFF) == 0);
ASSERT(lmd->parent == NULL);
frame = core_alloc(10); /* FIXME check */
lmd->parent = (void*)frame;
pte = &((addr_t*)page_tabs)[lmd->base>>12]; /* FIXME remove */
for(i = 0; i<1024; i++)
{
*pte++ = frame;
frame+= 4096;
}
md = (md_t*)slab_alloc(md_slab,0); /* FIXME check */
link_initialize(&md->link);
list_initialize(&md->adj);
md->base = lmd->base;
md->size = lmd->size;
md->parent = lmd;
md->state = MD_USED;
};
if(md->size > size)
{
count_t idx1;
md_t *new_md = (md_t*)slab_alloc(md_slab,0); /* FIXME check */
link_initialize(&new_md->link);
list_insert(&new_md->adj, &md->adj);
new_md->base = md->base;
new_md->size = size;
new_md->parent = md->parent;
md->base+= size;
md->size-= size;
md->state = MD_FREE;
idx1 = (md->size>>12) - 1 < 32 ? (md->size>>12) - 1 : 31;
DBG("insert md %x, base %x size %x idx %x\n", md,md->base, md->size,idx1);
if( idx1 < 31)
list_prepend(&md->link, &sheap.mapped[idx1]);
else
{
if( list_empty(&sheap.mapped[31]))
list_prepend(&md->link, &sheap.mapped[31]);
else
{
md_t *tmp = (md_t*)sheap.mapped[31].next;
while( &tmp->link != &sheap.mapped[31])
{
if(md->base < tmp->base)
break;
tmp = (md_t*)tmp->link.next;
}
list_insert(&md->link, &tmp->link);
};
};
_set_savm(idx1);
md = new_md;
};
md->state = MD_USED;
safe_sti(efl);
return md;
}
void __fastcall free_unmapped_md(md_t *md)
{
eflags_t efl ;
md_t *fd;
md_t *bk;
count_t idx;
ASSERT(md->parent != NULL);
efl = safe_cli();
spinlock_lock(&sheap.lock);
if( !list_empty(&md->adj))
{
bk = (md_t*)md->adj.prev;
fd = (md_t*)md->adj.next;
if(fd->state == MD_FREE)
{
idx = (fd->size>>12) - 1 < 32 ? (fd->size>>12) - 1 : 31;
list_remove((link_t*)fd);
if(list_empty(&sheap.unmapped[idx]))
_reset_savu(idx);
md->size+= fd->size;
md->adj.next = fd->adj.next;
md->adj.next->prev = (link_t*)md;
slab_free(md_slab, fd);
};
if(bk->state == MD_FREE)
{
idx = (bk->size>>12) - 1 < 32 ? (bk->size>>12) - 1 : 31;
list_remove((link_t*)bk);
if(list_empty(&sheap.unmapped[idx]))
_reset_savu(idx);
bk->size+= md->size;
bk->adj.next = md->adj.next;
bk->adj.next->prev = (link_t*)bk;
slab_free(md_slab, md);
md = fd;
};
};
md->state = MD_FREE;
idx = (md->size>>12) - 1 < 32 ? (md->size>>12) - 1 : 31;
_set_savu(idx);
if( idx < 31)
list_prepend(&md->link, &sheap.unmapped[idx]);
else
{
if( list_empty(&sheap.unmapped[31]))
list_prepend(&md->link, &sheap.unmapped[31]);
else
{
md_t *tmp = (md_t*)sheap.unmapped[31].next;
while( &tmp->link != &sheap.unmapped[31])
{
if(md->base < tmp->base)
break;
tmp = (md_t*)tmp->link.next;
}
list_insert(&md->link, &tmp->link);
};
};
spinlock_unlock(&sheap.lock);
safe_sti(efl);
};
void __fastcall free_mapped_md(md_t *md)
{
eflags_t efl ;
md_t *fd;
md_t *bk;
count_t idx;
ASSERT(md->parent != NULL);
ASSERT( ((md_t*)(md->parent))->parent != NULL);
efl = safe_cli();
spinlock_lock(&sheap.lock);
if( !list_empty(&md->adj))
{
bk = (md_t*)md->adj.prev;
fd = (md_t*)md->adj.next;
if(fd->state == MD_FREE)
{
idx = (fd->size>>12) - 1 < 32 ? (fd->size>>12) - 1 : 31;
list_remove((link_t*)fd);
if(list_empty(&sheap.mapped[idx]))
_reset_savm(idx);
md->size+= fd->size;
md->adj.next = fd->adj.next;
md->adj.next->prev = (link_t*)md;
slab_free(md_slab, fd);
};
if(bk->state == MD_FREE)
{
idx = (bk->size>>12) - 1 < 32 ? (bk->size>>12) - 1 : 31;
list_remove((link_t*)bk);
if(list_empty(&sheap.mapped[idx]))
_reset_savm(idx);
bk->size+= md->size;
bk->adj.next = md->adj.next;
bk->adj.next->prev = (link_t*)bk;
slab_free(md_slab, md);
md = fd;
};
};
md->state = MD_FREE;
idx = (md->size>>12) - 1 < 32 ? (md->size>>12) - 1 : 31;
_set_savm(idx);
if( idx < 31)
list_prepend(&md->link, &sheap.mapped[idx]);
else
{
if( list_empty(&sheap.mapped[31]))
list_prepend(&md->link, &sheap.mapped[31]);
else
{
md_t *tmp = (md_t*)sheap.mapped[31].next;
while( &tmp->link != &sheap.mapped[31])
{
if(md->base < tmp->base)
break;
tmp = (md_t*)tmp->link.next;
}
list_insert(&md->link, &tmp->link);
};
};
spinlock_unlock(&sheap.lock);
safe_sti(efl);
};
md_t* __fastcall md_alloc(size_t size, u32_t flags)
{
eflags_t efl;
md_t *md;
size = (size+4095)&~4095;
if( flags & PG_MAP )
{
md = find_mapped_md(size);
if( !md )
return NULL;
ASSERT(md->state == MD_USED);
ASSERT(md->parent != NULL);
md_t *lmd = (md_t*)md->parent;
ASSERT( lmd != NULL);
ASSERT( lmd->parent != NULL);
addr_t frame = (md->base - lmd->base + (addr_t)lmd->parent)|
(flags & 0xFFF);
DBG("frame %x\n", frame);
ASSERT(frame != 0);
count_t tmp = size >> 12;
addr_t *pte = &((addr_t*)page_tabs)[md->base>>12];
while(tmp--)
{
*pte++ = frame;
frame+= 4096;
};
}
else
{
md = find_unmapped_md(size);
if( !md )
return NULL;
ASSERT(md->parent != NULL);
ASSERT(md->state == MD_USED);
}
return md;
};
void __fastcall md_free(md_t *md)
{
if( md )
{
md_t *lmd;
DBG("free md: %x base: %x size: %x\n",md, md->base, md->size);
ASSERT(md->state == MD_USED);
list_remove((link_t*)md);
lmd = (md_t*)md->parent;
ASSERT(lmd != 0);
if(lmd->parent != 0)
{
addr_t mem = md->base;
addr_t *pte = &((addr_t*)page_tabs)[md->base>>12];
count_t tmp = md->size >> 12;
while(tmp--)
{
*pte++ = 0;
asm volatile ( "invlpg (%0)" ::"r" (mem) );
mem+= 4096;
};
free_mapped_md( md );
}
else
free_unmapped_md( md );
}
return;
};
void * __fastcall mem_alloc(size_t size, u32_t flags)
{
eflags_t efl;
md_t *md;
DBG("\nmem_alloc: %x bytes\n", size);
ASSERT(size != 0);
md = md_alloc(size, flags);
if( !md )
return NULL;
efl = safe_cli();
spinlock_lock(&sheap.lock);
if( list_empty(&sheap.used) )
list_prepend(&md->link, &sheap.used);
else
{
md_t *tmp = (md_t*)sheap.used.next;
while( &tmp->link != &sheap.used)
{
if(md->base < tmp->base)
break;
tmp = (md_t*)tmp->link.next;
}
list_insert(&md->link, &tmp->link);
};
spinlock_unlock(&sheap.lock);
safe_sti(efl);
DBG("allocate: %x size %x\n\n",md->base, size);
return (void*)md->base;
};
void __fastcall mem_free(void *mem)
{
eflags_t efl;
md_t *tmp;
md_t *md = NULL;
DBG("mem_free: %x\n",mem);
ASSERT( mem != 0 );
ASSERT( ((addr_t)mem & 0xFFF) == 0 );
ASSERT( ! list_empty(&sheap.used));
efl = safe_cli();
tmp = (md_t*)sheap.used.next;
while( &tmp->link != &sheap.used)
{
if( tmp->base == (addr_t)mem )
{
md = tmp;
break;
};
tmp = (md_t*)tmp->link.next;
}
if( md )
{
md_free( md );
}
else
DBG("\tERROR: invalid base address: %x\n", mem);
safe_sti(efl);
};