/*
* Copyright (C) 2006 Michael Brown <mbrown@fensystems.co.uk>.
*
* 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; either version 2 of the
* License, or any later version.
*
* This program is distributed in the hope that it will be useful, but
* WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU
* General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 675 Mass Ave, Cambridge, MA 02139, USA.
*/
FILE_LICENCE ( GPL2_OR_LATER );
#include <stdint.h>
#include <errno.h>
#include <realmode.h>
#include <bios.h>
#include <memsizes.h>
#include <gpxe/memmap.h>
/**
* @file
*
* Memory mapping
*
*/
/** Magic value for INT 15,e820 calls */
#define SMAP ( 0x534d4150 )
/** An INT 15,e820 memory map entry */
struct e820_entry {
/** Start of region */
uint64_t start;
/** Length of region */
uint64_t len;
/** Type of region */
uint32_t type;
/** Extended attributes (optional) */
uint32_t attrs;
} __attribute__ (( packed ));
#define E820_TYPE_RAM 1 /**< Normal memory */
#define E820_TYPE_RESERVED 2 /**< Reserved and unavailable */
#define E820_TYPE_ACPI 3 /**< ACPI reclaim memory */
#define E820_TYPE_NVS 4 /**< ACPI NVS memory */
#define E820_ATTR_ENABLED 0x00000001UL
#define E820_ATTR_NONVOLATILE 0x00000002UL
#define E820_ATTR_UNKNOWN 0xfffffffcUL
#define E820_MIN_SIZE 20
/** Buffer for INT 15,e820 calls */
static struct e820_entry __bss16 ( e820buf );
#define e820buf __use_data16 ( e820buf )
/**
* Get size of extended memory via INT 15,e801
*
* @ret extmem Extended memory size, in kB, or 0
*/
static unsigned int extmemsize_e801 ( void ) {
uint16_t extmem_1m_to_16m_k, extmem_16m_plus_64k;
uint16_t confmem_1m_to_16m_k, confmem_16m_plus_64k;
unsigned int flags;
unsigned int extmem;
__asm__ __volatile__ ( REAL_CODE ( "stc\n\t"
"int $0x15\n\t"
"pushfw\n\t"
"popw %w0\n\t" )
: "=r" ( flags ),
"=a" ( extmem_1m_to_16m_k ),
"=b" ( extmem_16m_plus_64k ),
"=c" ( confmem_1m_to_16m_k ),
"=d" ( confmem_16m_plus_64k )
: "a" ( 0xe801 ) );
if ( flags & CF ) {
DBG ( "INT 15,e801 failed with CF set\n" );
return 0;
}
if ( ! ( extmem_1m_to_16m_k | extmem_16m_plus_64k ) ) {
DBG ( "INT 15,e801 extmem=0, using confmem\n" );
extmem_1m_to_16m_k = confmem_1m_to_16m_k;
extmem_16m_plus_64k = confmem_16m_plus_64k;
}
extmem = ( extmem_1m_to_16m_k + ( extmem_16m_plus_64k * 64 ) );
DBG ( "INT 15,e801 extended memory size %d+64*%d=%d kB "
"[100000,%llx)\n", extmem_1m_to_16m_k, extmem_16m_plus_64k,
extmem, ( 0x100000 + ( ( ( uint64_t ) extmem ) * 1024 ) ) );
/* Sanity check. Some BIOSes report the entire 4GB address
* space as available, which cannot be correct (since that
* would leave no address space available for 32-bit PCI
* BARs).
*/
if ( extmem == ( 0x400000 - 0x400 ) ) {
DBG ( "INT 15,e801 reported whole 4GB; assuming insane\n" );
return 0;
}
return extmem;
}
/**
* Get size of extended memory via INT 15,88
*
* @ret extmem Extended memory size, in kB
*/
static unsigned int extmemsize_88 ( void ) {
uint16_t extmem;
/* Ignore CF; it is not reliable for this call */
__asm__ __volatile__ ( REAL_CODE ( "int $0x15" )
: "=a" ( extmem ) : "a" ( 0x8800 ) );
DBG ( "INT 15,88 extended memory size %d kB [100000, %x)\n",
extmem, ( 0x100000 + ( extmem * 1024 ) ) );
return extmem;
}
/**
* Get size of extended memory
*
* @ret extmem Extended memory size, in kB
*
* Note that this is only an approximation; for an accurate picture,
* use the E820 memory map obtained via get_memmap();
*/
unsigned int extmemsize ( void ) {
unsigned int extmem;
/* Try INT 15,e801 first, then fall back to INT 15,88 */
extmem = extmemsize_e801();
if ( ! extmem )
extmem = extmemsize_88();
return extmem;
}
/**
* Get e820 memory map
*
* @v memmap Memory map to fill in
* @ret rc Return status code
*/
static int meme820 ( struct memory_map *memmap ) {
struct memory_region *region = memmap->regions;
uint32_t next = 0;
uint32_t smap;
size_t size;
unsigned int flags;
unsigned int discard_D;
/* Clear the E820 buffer. Do this once before starting,
* rather than on each call; some BIOSes rely on the contents
* being preserved between calls.
*/
memset ( &e820buf, 0, sizeof ( e820buf ) );
do {
/* Some BIOSes corrupt %esi for fun. Guard against
* this by telling gcc that all non-output registers
* may be corrupted.
*/
__asm__ __volatile__ ( REAL_CODE ( "pushl %%ebp\n\t"
"stc\n\t"
"int $0x15\n\t"
"pushfw\n\t"
"popw %%dx\n\t"
"popl %%ebp\n\t" )
: "=a" ( smap ), "=b" ( next ),
"=c" ( size ), "=d" ( flags ),
"=D" ( discard_D )
: "a" ( 0xe820 ), "b" ( next ),
"D" ( __from_data16 ( &e820buf ) ),
"c" ( sizeof ( e820buf ) ),
"d" ( SMAP )
: "esi", "memory" );
if ( smap != SMAP ) {
DBG ( "INT 15,e820 failed SMAP signature check\n" );
return -ENOTSUP;
}
if ( size < E820_MIN_SIZE ) {
DBG ( "INT 15,e820 returned only %zd bytes\n", size );
return -EINVAL;
}
if ( flags & CF ) {
DBG ( "INT 15,e820 terminated on CF set\n" );
break;
}
/* If first region is not RAM, assume map is invalid */
if ( ( memmap->count == 0 ) &&
( e820buf.type != E820_TYPE_RAM ) ) {
DBG ( "INT 15,e820 failed, first entry not RAM\n" );
return -EINVAL;
}
DBG ( "INT 15,e820 region [%llx,%llx) type %d",
e820buf.start, ( e820buf.start + e820buf.len ),
( int ) e820buf.type );
if ( size > offsetof ( typeof ( e820buf ), attrs ) ) {
DBG ( " (%s", ( ( e820buf.attrs & E820_ATTR_ENABLED )
? "enabled" : "disabled" ) );
if ( e820buf.attrs & E820_ATTR_NONVOLATILE )
DBG ( ", non-volatile" );
if ( e820buf.attrs & E820_ATTR_UNKNOWN )
DBG ( ", other [%08x]", e820buf.attrs );
DBG ( ")" );
}
DBG ( "\n" );
/* Discard non-RAM regions */
if ( e820buf.type != E820_TYPE_RAM )
continue;
/* Check extended attributes, if present */
if ( size > offsetof ( typeof ( e820buf ), attrs ) ) {
if ( ! ( e820buf.attrs & E820_ATTR_ENABLED ) )
continue;
if ( e820buf.attrs & E820_ATTR_NONVOLATILE )
continue;
}
region->start = e820buf.start;
region->end = e820buf.start + e820buf.len;
region++;
memmap->count++;
if ( memmap->count >= ( sizeof ( memmap->regions ) /
sizeof ( memmap->regions[0] ) ) ) {
DBG ( "INT 15,e820 too many regions returned\n" );
/* Not a fatal error; what we've got so far at
* least represents valid regions of memory,
* even if we couldn't get them all.
*/
break;
}
} while ( next != 0 );
/* Sanity checks. Some BIOSes report complete garbage via INT
* 15,e820 (especially at POST time), despite passing the
* signature checks. We currently check for a base memory
* region (starting at 0) and at least one high memory region
* (starting at 0x100000).
*/
if ( memmap->count < 2 ) {
DBG ( "INT 15,e820 returned only %d regions; assuming "
"insane\n", memmap->count );
return -EINVAL;
}
if ( memmap->regions[0].start != 0 ) {
DBG ( "INT 15,e820 region 0 starts at %llx (expected 0); "
"assuming insane\n", memmap->regions[0].start );
return -EINVAL;
}
if ( memmap->regions[1].start != 0x100000 ) {
DBG ( "INT 15,e820 region 1 starts at %llx (expected 100000); "
"assuming insane\n", memmap->regions[0].start );
return -EINVAL;
}
return 0;
}
/**
* Get memory map
*
* @v memmap Memory map to fill in
*/
void get_memmap ( struct memory_map *memmap ) {
unsigned int basemem, extmem;
int rc;
DBG ( "Fetching system memory map\n" );
/* Clear memory map */
memset ( memmap, 0, sizeof ( *memmap ) );
/* Get base and extended memory sizes */
basemem = basememsize();
DBG ( "FBMS base memory size %d kB [0,%x)\n",
basemem, ( basemem * 1024 ) );
extmem = extmemsize();
/* Try INT 15,e820 first */
if ( ( rc = meme820 ( memmap ) ) == 0 ) {
DBG ( "Obtained system memory map via INT 15,e820\n" );
return;
}
/* Fall back to constructing a map from basemem and extmem sizes */
DBG ( "INT 15,e820 failed; constructing map\n" );
memmap->regions[0].end = ( basemem * 1024 );
memmap->regions[1].start = 0x100000;
memmap->regions[1].end = 0x100000 + ( extmem * 1024 );
memmap->count = 2;
}