/*
* <ofmem_common.c>
*
* OF Memory manager
*
* Copyright (C) 1999-2004 Samuel Rydh (samuel@ibrium.se)
* Copyright (C) 2004 Stefan Reinauer
*
* This program is free software; you can redistribute it and/or
* modify it under the terms of the GNU General Public License
* as published by the Free Software Foundation
*
*/
#include "config.h"
#include "libopenbios/bindings.h"
#include "libopenbios/ofmem.h"
/* Default size of memory allocated for each of the MMU properties (in bytes) */
#define OFMEM_DEFAULT_PROP_SIZE 2048
/*
* define OFMEM_FILL_RANGE to claim any unclaimed virtual and
* physical memory in the range for ofmem_map
*
* TODO: remove this macro and wrapped code if not needed by implementations
*/
//#define OFMEM_FILL_RANGE
static inline size_t align_size(size_t x, size_t a)
{
return (x + a - 1) & ~(a - 1);
}
static inline phys_addr_t align_ptr(uintptr_t x, size_t a)
{
return (x + a - 1) & ~(a - 1);
}
static ucell get_ram_size( void )
{
ofmem_t *ofmem = ofmem_arch_get_private();
return ofmem->ramsize;
}
/************************************************************************/
/* debug */
/************************************************************************/
#if 0
static void
print_range( range_t *r, const char *str )
{
printk("--- Range %s ---\n", str );
for( ; r; r=r->next )
printk("%p : " FMT_plx " - " FMT_plx "\n", r, r->start, r->start + r->size - 1);
printk("\n");
}
static void
print_phys_range(void)
{
ofmem_t *ofmem = ofmem_arch_get_private();
print_range( ofmem->phys_range, "phys" );
}
static void
print_virt_range(void)
{
ofmem_t *ofmem = ofmem_arch_get_private();
print_range( ofmem->virt_range, "virt" );
}
static void
print_trans( void )
{
ofmem_t *ofmem = ofmem_arch_get_private();
translation_t *t = ofmem->trans;
printk("--- Translations ---\n");
for( ; t; t=t->next )
printk("%p : " FMT_ucellx " -> " FMT_plx " [size " FMT_ucellx "]\n", t, t->virt, t->phys, t->size);
printk("\n");
}
#endif
/************************************************************************/
/* OF private allocations */
/************************************************************************/
int ofmem_posix_memalign( void **memptr, size_t alignment, size_t size )
{
ofmem_t *ofmem = ofmem_arch_get_private();
alloc_desc_t *d, **pp;
void *ret;
ucell top;
phys_addr_t pa;
if( !size )
return ENOMEM;
if( !ofmem->next_malloc )
ofmem->next_malloc = (char*)ofmem_arch_get_malloc_base();
size = align_size(size + sizeof(alloc_desc_t), alignment);
/* look in the freelist */
for( pp=&ofmem->mfree; *pp && (**pp).size < size; pp = &(**pp).next ) {
}
/* waste at most 4K by taking an entry from the freelist */
if( *pp && (**pp).size > size + 0x1000 ) {
/* Alignment should be on physical not virtual address */
pa = va2pa((uintptr_t)*pp + sizeof(alloc_desc_t));
pa = align_ptr(pa, alignment);
ret = (void *)pa2va(pa);
memset( ret, 0, (**pp).size - sizeof(alloc_desc_t) );
*pp = (**pp).next;
*memptr = ret;
return 0;
}
top = ofmem_arch_get_heap_top();
/* Alignment should be on physical not virtual address */
pa = va2pa((uintptr_t)ofmem->next_malloc + sizeof(alloc_desc_t));
pa = align_ptr(pa, alignment);
ret = (void *)pa2va(pa);
if( pointer2cell(ret) + size > top ) {
printk("out of malloc memory (%x)!\n", size );
return ENOMEM;
}
d = (alloc_desc_t*)((uintptr_t)ret - sizeof(alloc_desc_t));
ofmem->next_malloc += size;
d->next = NULL;
d->size = size;
memset( ret, 0, size - sizeof(alloc_desc_t) );
*memptr = ret;
return 0;
}
void* ofmem_malloc( size_t size )
{
void *memptr;
int res;
res = ofmem_posix_memalign( &memptr, CONFIG_OFMEM_MALLOC_ALIGN, size );
if (!res) {
/* Success */
return memptr;
} else {
/* Failure */
return NULL;
}
}
void ofmem_free( void *ptr )
{
ofmem_t *ofmem = ofmem_arch_get_private();
alloc_desc_t **pp, *d;
/* it is legal to free NULL pointers (size zero allocations) */
if( !ptr )
return;
d = (alloc_desc_t*)((char *)ptr - sizeof(alloc_desc_t));
d->next = ofmem->mfree;
/* insert in the (sorted) freelist */
for( pp=&ofmem->mfree; *pp && (**pp).size < d->size ; pp = &(**pp).next ) {
}
d->next = *pp;
*pp = d;
}
void* ofmem_realloc( void *ptr, size_t size )
{
alloc_desc_t *d = (alloc_desc_t*)((char *)ptr - sizeof(alloc_desc_t));
char *p;
if( !ptr )
return malloc( size );
if( !size ) {
free( ptr );
return NULL;
}
p = malloc( size );
memcpy( p, ptr, MIN(d->size - sizeof(alloc_desc_t),size) );
free( ptr );
return p;
}
/************************************************************************/
/* "translations" and "available" property tracking */
/************************************************************************/
static int trans_prop_size = 0, phys_range_prop_size = 0, virt_range_prop_size = 0;
static int trans_prop_used = 0, phys_range_prop_used = 0, virt_range_prop_used = 0;
static ucell *trans_prop, *phys_range_prop, *virt_range_prop;
static void
ofmem_set_property( phandle_t ph, const char *name, const char *buf, int len )
{
/* This is very similar to set_property() in libopenbios/bindings.c but allows
us to set the property pointer directly, rather than having to copy it
into the Forth dictonary every time we update the memory properties */
if( !ph ) {
printk("ofmem_set_property: NULL phandle\n");
return;
}
PUSH(pointer2cell(buf));
PUSH(len);
push_str(name);
PUSH_ph(ph);
fword("encode-property");
}
phandle_t s_phandle_memory = 0;
phandle_t s_phandle_mmu = 0;
static void ofmem_update_mmu_translations( void )
{
ofmem_t *ofmem = ofmem_arch_get_private();
translation_t *t;
int ncells, prop_used, prop_size;
if (s_phandle_mmu == 0)
return;
for( t = ofmem->trans, ncells = 0; t ; t=t->next, ncells++ ) {
}
/* Get the current number of bytes required for the MMU translation property */
prop_used = ncells * sizeof(ucell) * ofmem_arch_get_translation_entry_size();
if (prop_used > trans_prop_size) {
/* The property doesn't fit within the existing space, so keep doubling it
until it does */
prop_size = trans_prop_size;
while (prop_size < prop_used) {
prop_size *= 2;
}
/* Allocate the new memory and copy all of the existing information across */
trans_prop = realloc(trans_prop, prop_size);
trans_prop_size = prop_size;
trans_prop_used = prop_used;
}
if (trans_prop == NULL) {
/* out of memory! */
printk("Unable to allocate memory for translations property!\n");
return;
}
/* Call architecture-specific routines to generate translation entries */
for( t = ofmem->trans, ncells = 0 ; t ; t=t->next ) {
ofmem_arch_create_translation_entry(&trans_prop[ncells], t);
ncells += ofmem_arch_get_translation_entry_size();
}
ofmem_set_property(s_phandle_mmu, "translations",
(char*)trans_prop, ncells * sizeof(trans_prop[0]));
}
static void ofmem_update_memory_available( phandle_t ph, range_t *range,
ucell **mem_prop, int *mem_prop_size, int *mem_prop_used, u64 top_address )
{
range_t *r;
int ncells, prop_used, prop_size;
phys_addr_t start;
ucell size, *prop;
if (s_phandle_memory == 0)
return;
/* count phys_range list entries */
for( r = range, ncells = 0; r ; r=r->next, ncells++ ) {
}
/* inverse of phys_range list could take 2 or more additional cells for the tail
For /memory, physical addresses may be wider than one ucell. */
prop_used = (ncells + 1) * sizeof(ucell) * ofmem_arch_get_available_entry_size(ph) + 1;
if (prop_used > *mem_prop_size) {
/* The property doesn't fit within the existing space, so keep doubling it
until it does */
prop_size = *mem_prop_size;
while (prop_size < prop_used) {
prop_size *= 2;
}
/* Allocate the new memory and copy all of the existing information across */
*mem_prop = realloc(*mem_prop, prop_size);
*mem_prop_size = prop_size;
*mem_prop_used = prop_used;
}
if (*mem_prop == NULL) {
/* out of memory! */
printk("Unable to allocate memory for memory range property!\n");
return;
}
start = 0;
ncells = 0;
prop = *mem_prop;
for (r = range; r; r=r->next) {
if (r->start >= top_address) {
break;
}
size = r->start - start;
if (size) {
ofmem_arch_create_available_entry(ph, &prop[ncells], start, size);
ncells += ofmem_arch_get_available_entry_size(ph);
}
start = r->start + r->size;
}
/* tail */
if ((start - 1) < top_address) {
ofmem_arch_create_available_entry(ph, &prop[ncells], start, top_address - start + 1);
ncells += ofmem_arch_get_available_entry_size(ph);
}
ofmem_set_property(ph, "available",
(char*)prop, ncells * sizeof(prop[0]));
}
static void ofmem_update_translations( void )
{
ofmem_t *ofmem = ofmem_arch_get_private();
ofmem_update_memory_available(s_phandle_memory, ofmem->phys_range,
&phys_range_prop, &phys_range_prop_size, &phys_range_prop_used, get_ram_size() - 1);
ofmem_update_memory_available(s_phandle_mmu, ofmem->virt_range,
&virt_range_prop, &virt_range_prop_size, &virt_range_prop_used, (ucell)-1);
ofmem_update_mmu_translations();
}
/************************************************************************/
/* client interface */
/************************************************************************/
static int is_free( phys_addr_t ea, ucell size, range_t *r )
{
if( size == 0 )
return 1;
for( ; r ; r=r->next ) {
if( r->start + r->size - 1 >= ea && r->start <= ea )
return 0;
if( r->start >= ea && r->start <= ea + size - 1 )
return 0;
}
return 1;
}
static void add_entry_( phys_addr_t ea, ucell size, range_t **r )
{
range_t *nr;
for( ; *r && (**r).start < ea; r=&(**r).next ) {
}
nr = (range_t*)malloc( sizeof(range_t) );
nr->next = *r;
nr->start = ea;
nr->size = size;
*r = nr;
}
static int add_entry( phys_addr_t ea, ucell size, range_t **r )
{
if( !is_free( ea, size, *r ) ) {
OFMEM_TRACE("add_entry: range not free!\n");
return -1;
}
add_entry_( ea, size, r );
return 0;
}
#if defined(OFMEM_FILL_RANGE)
static void join_ranges( range_t **rr )
{
range_t *n, *r = *rr;
while( r ) {
if( !(n=r->next) )
break;
if( r->start + r->size - 1 >= n->start -1 ) {
int s = n->size + (n->start - r->start - r->size);
if( s > 0 )
r->size += s;
r->next = n->next;
free( n );
continue;
}
r=r->next;
}
}
static void fill_range( phys_addr_t ea, ucell size, range_t **rr )
{
add_entry_( ea, size, rr );
join_ranges( rr );
}
#endif
static ucell find_area( ucell align, ucell size, range_t *r,
phys_addr_t min, phys_addr_t max, int reverse )
{
phys_addr_t base = min;
range_t *r2;
ucell old_align = align;
int i;
if( (align < PAGE_SIZE) ) {
/* Minimum alignment is page size */
align = PAGE_SIZE;
OFMEM_TRACE("warning: bad alignment " FMT_ucellx " rounded up to " FMT_ucellx "\n", old_align, align);
}
if( (align & (align-1)) ) {
/* As per IEEE1275 specification, round up to the nearest power of 2 */
align--;
for (i = 1; i < sizeof(ucell) * 8; i<<=1) {
align |= align >> i;
}
align++;
OFMEM_TRACE("warning: bad alignment " FMT_ucellx " rounded up to " FMT_ucellx "\n", old_align, align);
}
base = reverse ? max - size : min;
r2 = reverse ? NULL : r;
for( ;; ) {
if( !reverse ) {
base = (base + align - 1) & ~(align-1);
if( base < min )
base = min;
if( base + size - 1 >= max -1 )
break;
} else {
if( base > max - size )
base = max - size;
base -= base & (align-1);
}
if( is_free( base, size, r ) )
return base;
if( !reverse ) {
if( !r2 )
break;
base = r2->start + r2->size;
r2 = r2->next;
} else {
range_t *rp;
for( rp=r; rp && rp->next != r2 ; rp=rp->next ) {
}
r2 = rp;
if( !r2 )
break;
base = r2->start - size;
}
}
return -1;
}
static phys_addr_t ofmem_claim_phys_( phys_addr_t phys, ucell size, ucell align,
phys_addr_t min, phys_addr_t max, int reverse )
{
ofmem_t *ofmem = ofmem_arch_get_private();
if( !align ) {
if( !is_free( phys, size, ofmem->phys_range ) ) {
OFMEM_TRACE("Non-free physical memory claimed!\n");
return -1;
}
add_entry( phys, size, &ofmem->phys_range );
ofmem_update_translations();
return phys;
}
phys = find_area( align, size, ofmem->phys_range, min, max, reverse );
if( phys == -1 ) {
printk("ofmem_claim_phys - out of space (failed request for " FMT_ucellx " bytes)\n", size);
return -1;
}
add_entry( phys, size, &ofmem->phys_range );
ofmem_update_translations();
return phys;
}
/* if align != 0, phys is ignored. Returns -1 on error */
phys_addr_t ofmem_claim_phys( phys_addr_t phys, ucell size, ucell align )
{
OFMEM_TRACE("ofmem_claim_phys phys=" FMT_plx " size=" FMT_ucellx
" align=" FMT_ucellx "\n",
phys, size, align);
return ofmem_claim_phys_( phys, size, align, 0, get_ram_size(), 1 );
}
static ucell ofmem_claim_virt_( ucell virt, ucell size, ucell align,
ucell min, ucell max, int reverse )
{
ofmem_t *ofmem = ofmem_arch_get_private();
if( !align ) {
if( !is_free( virt, size, ofmem->virt_range ) ) {
OFMEM_TRACE("Non-free virtual memory claimed!\n");
return -1;
}
add_entry( virt, size, &ofmem->virt_range );
ofmem_update_translations();
return virt;
}
virt = find_area( align, size, ofmem->virt_range, min, max, reverse );
if( virt == -1 ) {
printk("ofmem_claim_virt - out of space (failed request for " FMT_ucellx " bytes)\n", size);
return -1;
}
add_entry( virt, size, &ofmem->virt_range );
ofmem_update_translations();
return virt;
}
ucell ofmem_claim_virt( ucell virt, ucell size, ucell align )
{
OFMEM_TRACE("ofmem_claim_virt virt=" FMT_ucellx " size=" FMT_ucellx
" align=" FMT_ucellx "\n",
virt, size, align);
/* printk("+ ofmem_claim virt %08lx %lx %ld\n", virt, size, align ); */
return ofmem_claim_virt_( virt, size, align,
get_ram_size(), ofmem_arch_get_virt_top(), 1 );
}
static ucell ofmem_claim_io_( ucell virt, ucell size, ucell align,
ucell min, ucell max, int reverse )
{
ofmem_t *ofmem = ofmem_arch_get_private();
if( !align ) {
if( !is_free( virt, size, ofmem->io_range ) ) {
OFMEM_TRACE("Non-free I/O memory claimed!\n");
return -1;
}
add_entry( virt, size, &ofmem->io_range );
return virt;
}
virt = find_area( align, size, ofmem->io_range, min, max, reverse );
if( virt == -1 ) {
printk("ofmem_claim_io - out of space (failed request for " FMT_ucellx " bytes)\n", size);
return -1;
}
add_entry( virt, size, &ofmem->io_range );
return virt;
}
ucell ofmem_claim_io( ucell virt, ucell size, ucell align )
{
/* Claim a section of memory from the I/O range */
return ofmem_claim_io_( virt, size, align,
ofmem_arch_get_iomem_base(), ofmem_arch_get_iomem_top(), 0 );
}
/* if align != 0, phys is ignored. Returns -1 on error */
phys_addr_t ofmem_retain( phys_addr_t phys, ucell size, ucell align )
{
retain_t *retained = ofmem_arch_get_retained();
phys_addr_t retain_phys;
OFMEM_TRACE("ofmem_retain phys=" FMT_plx " size=" FMT_ucellx
" align=" FMT_ucellx "\n",
phys, size, align);
retain_phys = ofmem_claim_phys_( phys, size, align, 0, get_ram_size(), 1 /* reverse */ );
/* Add to the retain_phys_range list */
retained->retain_phys_range[retained->numentries].next = NULL;
retained->retain_phys_range[retained->numentries].start = retain_phys;
retained->retain_phys_range[retained->numentries].size = size;
retained->numentries++;
return retain_phys;
}
/* allocate both physical and virtual space and add a translation */
ucell ofmem_claim( ucell addr, ucell size, ucell align )
{
ofmem_t *ofmem = ofmem_arch_get_private();
ucell virt;
phys_addr_t phys;
ucell offs = addr & (PAGE_SIZE - 1);
OFMEM_TRACE("ofmem_claim " FMT_ucellx " " FMT_ucellx " " FMT_ucellx "\n", addr, size, align );
virt = phys = 0;
if( !align ) {
if( is_free(addr, size, ofmem->virt_range) &&
is_free(addr, size, ofmem->phys_range) ) {
ofmem_claim_phys_( addr, size, 0, 0, 0, 0 );
ofmem_claim_virt_( addr, size, 0, 0, 0, 0 );
virt = phys = addr;
} else {
OFMEM_TRACE("**** ofmem_claim failure ***!\n");
return -1;
}
} else {
if( align < PAGE_SIZE )
align = PAGE_SIZE;
phys = ofmem_claim_phys_( -1, size, align, 0, get_ram_size(), 1 /* reverse */ );
virt = ofmem_claim_virt_( phys, size, 0, 0, 0, 0 );
if( phys == -1 || virt == -1 ) {
OFMEM_TRACE("ofmem_claim failed\n");
return -1;
}
/* printk("...phys = %08lX, virt = %08lX, size = %08lX\n", phys, virt, size ); */
}
/* align */
if( phys & (PAGE_SIZE - 1) ) {
size += (phys & (PAGE_SIZE - 1));
virt -= (phys & (PAGE_SIZE - 1));
phys &= PAGE_MASK;
}
if( size & (PAGE_SIZE - 1) )
size = (size + (PAGE_SIZE - 1)) & PAGE_MASK;
/* printk("...free memory found... phys: %08lX, virt: %08lX, size %lX\n", phys, virt, size ); */
ofmem_map( phys, virt, size, -1 );
return virt + offs;
}
/************************************************************************/
/* keep track of ea -> phys translations */
/************************************************************************/
static void split_trans( ucell virt )
{
ofmem_t *ofmem = ofmem_arch_get_private();
translation_t *t, *t2;
for( t=ofmem->trans; t; t=t->next ) {
if( virt > t->virt && virt < t->virt + t->size-1 ) {
t2 = (translation_t*)malloc( sizeof(translation_t) );
t2->virt = virt;
t2->size = t->size - (virt - t->virt);
t->size = virt - t->virt;
t2->phys = t->phys + t->size;
t2->mode = t->mode;
t2->next = t->next;
t->next = t2;
}
}
}
int ofmem_map_page_range( phys_addr_t phys, ucell virt, ucell size, ucell mode )
{
ofmem_t *ofmem = ofmem_arch_get_private();
translation_t *t, **tt;
OFMEM_TRACE("ofmem_map_page_range " FMT_ucellx
" -> " FMT_plx " " FMT_ucellx " mode " FMT_ucellx "\n",
virt, phys, size, mode );
split_trans( virt );
split_trans( virt + size );
/* detect remappings */
for( t=ofmem->trans; t; ) {
if( virt == t->virt || (virt < t->virt && virt + size > t->virt )) {
if( t->phys + virt - t->virt != phys ) {
OFMEM_TRACE("mapping altered virt=" FMT_ucellx ")\n", t->virt );
} else if( t->mode != mode ){
OFMEM_TRACE("mapping mode altered virt=" FMT_ucellx
" old mode=" FMT_ucellx " new mode=" FMT_ucellx "\n",
t->virt, t->mode, mode);
}
for( tt=&ofmem->trans; *tt != t ; tt=&(**tt).next ) {
}
*tt = t->next;
/* really unmap these pages */
ofmem_arch_unmap_pages(t->virt, t->size);
free((char*)t);
t=ofmem->trans;
continue;
}
t=t->next;
}
/* add mapping */
for( tt=&ofmem->trans; *tt && (**tt).virt < virt ; tt=&(**tt).next ) {
}
t = (translation_t*)malloc( sizeof(translation_t) );
t->virt = virt;
t->phys = phys;
t->size = size;
t->mode = mode;
t->next = *tt;
*tt = t;
ofmem_update_translations();
return 0;
}
static int unmap_page_range( ucell virt, ucell size )
{
ofmem_t *ofmem = ofmem_arch_get_private();
translation_t **plink;
/* make sure there is exactly one matching translation entry */
split_trans( virt );
split_trans( virt + size );
/* find and unlink entries in range */
plink = &ofmem->trans;
while (*plink && (*plink)->virt < virt+size) {
translation_t **plinkentry = plink;
translation_t *t = *plink;
/* move ahead */
plink = &t->next;
if (t->virt >= virt && t->virt + t->size <= virt+size) {
/* unlink entry */
*plinkentry = t->next;
OFMEM_TRACE("unmap_page_range found "
FMT_ucellx " -> " FMT_plx " " FMT_ucellx
" mode " FMT_ucellx "\n",
t->virt, t->phys, t->size, t->mode );
// really map these pages
ofmem_arch_unmap_pages(t->virt, t->size);
free((char*)t);
}
}
ofmem_update_translations();
return 0;
}
int ofmem_map( phys_addr_t phys, ucell virt, ucell size, ucell mode )
{
/* printk("+ofmem_map: %08lX --> %08lX (size %08lX, mode 0x%02X)\n",
virt, phys, size, mode ); */
if( (phys & (PAGE_SIZE - 1)) || (virt & (PAGE_SIZE - 1)) || (size & (PAGE_SIZE - 1)) ) {
OFMEM_TRACE("ofmem_map: Bad parameters ("
FMT_plx " " FMT_ucellx " " FMT_ucellx ")\n",
phys, virt, size );
phys &= PAGE_MASK;
virt &= PAGE_MASK;
size = (size + (PAGE_SIZE - 1)) & PAGE_MASK;
}
#if defined(OFMEM_FILL_RANGE)
{
ofmem_t *ofmem = ofmem_arch_get_private();
/* claim any unclaimed virtual memory in the range */
fill_range( virt, size, &ofmem->virt_range );
/* hmm... we better claim the physical range too */
fill_range( phys, size, &ofmem->phys_range );
}
#endif
if (mode==-1) {
mode = ofmem_arch_default_translation_mode(phys);
}
/* install translations */
ofmem_map_page_range(phys, virt, size, mode);
/* allow arch to map the pages */
ofmem_arch_map_pages(phys, virt, size, mode);
return 0;
}
int ofmem_unmap( ucell virt, ucell size )
{
OFMEM_TRACE("ofmem_unmap " FMT_ucellx " " FMT_ucellx "\n",
virt, size );
if( (virt & (PAGE_SIZE - 1)) || (size & (PAGE_SIZE - 1)) ) {
/* printk("ofmem_unmap: Bad parameters (%08lX %08lX)\n",
virt, size ); */
virt &= PAGE_MASK;
size = (size + (PAGE_SIZE - 1)) & PAGE_MASK;
}
/* remove translations and unmap pages */
unmap_page_range(virt, size);
return 0;
}
ucell ofmem_map_io( phys_addr_t phys, ucell size )
{
/* Claim virtual memory from the I/O range and map the page-aligned
physical address phys to it, returning the newly allocated
virtual address */
ucell virt, mode;
phys_addr_t off;
int npages;
off = phys & (PAGE_SIZE - 1);
npages = (off + size - 1) / PAGE_SIZE + 1;
phys &= ~(PAGE_SIZE - 1);
virt = ofmem_claim_io(-1, npages * PAGE_SIZE, PAGE_SIZE);
mode = ofmem_arch_io_translation_mode(off);
ofmem_map_page_range(phys, virt, npages * PAGE_SIZE, mode);
ofmem_arch_map_pages(phys, virt, npages * PAGE_SIZE, mode);
return (virt + off);
}
/* virtual -> physical. */
phys_addr_t ofmem_translate( ucell virt, ucell *mode )
{
ofmem_t *ofmem = ofmem_arch_get_private();
translation_t *t;
for( t=ofmem->trans; t && t->virt <= virt ; t=t->next ) {
ucell offs;
if( t->virt + t->size - 1 < virt )
continue;
offs = virt - t->virt;
*mode = t->mode;
return t->phys + offs;
}
/*printk("ofmem_translate: no translation defined (%08lx)\n", virt);*/
/*print_trans();*/
return -1;
}
static void remove_range_( phys_addr_t ea, ucell size, range_t **r )
{
range_t **t, *u;
/* If not an exact match then split the range */
for (t = r; *t; t = &(**t).next) {
if (ea > (**t).start && ea < (**t).start + (**t).size - 1) {
u = (range_t*)malloc(sizeof(range_t));
u->start = ea;
u->size = size;
u->next = (**t).next;
OFMEM_TRACE("remove_range_ splitting range with addr=" FMT_plx
" size=" FMT_ucellx " -> addr=" FMT_plx " size=" FMT_ucellx ", "
"addr=" FMT_plx " size=" FMT_ucellx "\n",
(**t).start, (**t).size, (**t).start, (**t).size - size,
u->start, u->size);
(**t).size = (**t).size - size;
(**t).next = u;
}
}
for (t = r; *t; t = &(**t).next) {
if (ea >= (**t).start && ea + size <= (**t).start + (**t).size) {
OFMEM_TRACE("remove_range_ freeing range with addr=" FMT_plx
" size=" FMT_ucellx "\n", (**t).start, (**t).size);
u = *t;
*t = (**t).next;
free(u);
break;
}
}
}
static int remove_range( phys_addr_t ea, ucell size, range_t **r )
{
if( is_free( ea, size, *r ) ) {
OFMEM_TRACE("remove_range: range isn't occupied\n");
return -1;
}
remove_range_( ea, size, r );
return 0;
}
/* release memory allocated by ofmem_claim_phys */
void ofmem_release_phys( phys_addr_t phys, ucell size )
{
OFMEM_TRACE("ofmem_release_phys addr=" FMT_plx " size=" FMT_ucellx "\n",
phys, size);
ofmem_t *ofmem = ofmem_arch_get_private();
remove_range(phys, size, &ofmem->phys_range);
}
/* release memory allocated by ofmem_claim_virt */
void ofmem_release_virt( ucell virt, ucell size )
{
OFMEM_TRACE("ofmem_release_virt addr=" FMT_ucellx " size=" FMT_ucellx "\n",
virt, size);
ofmem_t *ofmem = ofmem_arch_get_private();
remove_range(virt, size, &ofmem->virt_range);
}
/* release memory allocated by ofmem_claim_io */
void ofmem_release_io( ucell virt, ucell size )
{
OFMEM_TRACE("ofmem_release_io addr=" FMT_ucellx " size=" FMT_ucellx "\n",
virt, size);
ofmem_t *ofmem = ofmem_arch_get_private();
remove_range(virt, size, &ofmem->io_range);
}
/* release memory allocated by ofmem_claim - 6.3.2.4 */
void ofmem_release( ucell virt, ucell size )
{
OFMEM_TRACE("%s addr=" FMT_ucellx " size=" FMT_ucellx "\n",
__func__, virt, size);
ucell mode;
phys_addr_t phys = ofmem_translate(virt, &mode);
if (phys == (phys_addr_t)-1) {
OFMEM_TRACE("%s: no mapping\n", __func__);
return;
}
ofmem_unmap(virt, size);
ofmem_release_virt(virt, size);
ofmem_release_phys(phys, size);
}
/************************************************************************/
/* init / cleanup */
/************************************************************************/
void ofmem_register( phandle_t ph_memory, phandle_t ph_mmu )
{
s_phandle_memory = ph_memory;
s_phandle_mmu = ph_mmu;
/* Initialise some default property sizes */
trans_prop_size = phys_range_prop_size = virt_range_prop_size = OFMEM_DEFAULT_PROP_SIZE;
trans_prop = malloc(trans_prop_size);
phys_range_prop = malloc(phys_range_prop_size);
virt_range_prop = malloc(virt_range_prop_size);
ofmem_update_translations();
}