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iBoot/drivers/flash_nand/boot/firmware/nand_firmware.c

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/*
* Copyright (c) 2008-2012 Apple Inc. All rights reserved.
*
* This document is the property of Apple Inc.
* It is considered confidential and proprietary.
*
* This document may not be reproduced or transmitted in any form,
* in whole or in part, without the express written permission of
* Apple Inc.
*/
#if WITH_BLOCKDEV
#include <debug.h>
#include <sys/types.h>
#include <lib/blockdev.h>
#include "nand_part.h"
#include "nand_part_interface.h"
#include "nand_export.h"
#include "nand_firmware.h"
//#undef DEBUG_LEVEL
//#define DEBUG_LEVEL DEBUG_INFO
/* ========================================================================== */
#define kNandFirmwareBDevName "nand_firmware"
#define kNandLLBBDevName "nand_llb"
/* ========================================================================== */
static NandPartInterface * _npi;
static uint32_t _llb_index;
static uint32_t _firmware_index;
static bool _have_cache;
static uint32_t _cached_part;
static uint32_t _cached_block;
static uint32_t _cached_page;
static uint8_t * _page_cache;
/* ========================================================================== */
static bool nand_firmware_cache_page(uint32_t part, uint32_t block, uint32_t page);
static int nand_firmware_read_block_handler(struct blockdev *bdev, void *ptr, block_addr block, uint32_t count);
#if ALLOW_NAND_FIRMWARE_ERASE
static int nand_firmware_erase_block_handler(struct blockdev *bdev, off_t offset, uint64_t len);
#endif
/* ========================================================================== */
bool
nand_firmware_init(NandPartInterface *npi, uint32_t partIndex)
{
const uint32_t page_size = npi_get_bytes_per_page(npi, partIndex);
struct blockdev * _bdev;
bool ok = false;
_npi = npi;
_have_cache = false;
_cached_part = 0;
_cached_block = 0;
_cached_page = 0;
_page_cache = NULL;
_bdev = NULL;
_bdev = malloc(sizeof(struct blockdev));
_page_cache = (uint8_t*)memalign(page_size, CPU_CACHELINE_SIZE);
const uint32_t blockCount = npi_get_block_depth(_npi, partIndex);
const uint32_t pagesPerBlock = npi_get_pages_per_block(_npi, partIndex);
const off_t len = (blockCount * pagesPerBlock * page_size);
const NandPartEntry * entry = npi_get_entry(_npi, partIndex);
switch (entry->content) {
case kNandPartContentFirmware:
_firmware_index = partIndex;
construct_blockdev(_bdev, kNandFirmwareBDevName, len, kNandPartSectorSize);
break;
case kNandPartContentBootBlock:
_llb_index = partIndex;
construct_blockdev(_bdev, kNandLLBBDevName, len, kNandPartSectorSize);
break;
default:
panic("Should never have been here\n");
}
_bdev->read_block_hook = &nand_firmware_read_block_handler;
#if ALLOW_NAND_FIRMWARE_ERASE
_bdev->erase_hook = &nand_firmware_erase_block_handler;
#endif
register_blockdev(_bdev);
ok = true;
return(ok);
}
static bool
nand_firmware_cache_page(uint32_t part, uint32_t block, uint32_t page)
{
bool is_clean;
uint32_t bank;
if (!_have_cache || (_cached_part != part) || (_cached_block != block) || (_cached_page != page)) {
_have_cache = false;
for (bank = 0; bank < npi_get_bank_width(_npi, part); bank++) {
if (npi_is_block_bad(_npi, part, bank, block)) {
dprintf(DEBUG_SPEW,
"WARNING: bad block (%d:%d:%d)\n",
part, bank, block);
continue;
}
if (npi_read_page(_npi, part, bank, block, page, _page_cache, &is_clean)) {
_have_cache = true;
_cached_part = part;
_cached_block = block;
_cached_page = page;
break;
} else {
dprintf(DEBUG_SPEW,
"WARNING: page read (%d:%d:%d:%d) failed\n",
part, bank, block, page);
}
}
}
return(_have_cache);
}
static int
nand_firmware_read_block_handler(struct blockdev *bdev, void *ptr, block_addr sector_addr, uint32_t sector_count)
{
// this is a bit confusing, since a bdev "block" is not the same as a nand "block";
// instead, the bdev "block" concept is mapped to a 512-byte virtual "sector"
const uint32_t sector_base = 0;
uint32_t sector_limit = 0;
uint32_t block_count;
uint32_t bytes_per_page;
uint32_t pages_per_block;
uint32_t bytes_per_block;
uint32_t sectors_per_block;
uint32_t sectors_per_page;
uint32_t first_sector = 0;
uint32_t last_sector = 0;
uint32_t sector_idx;
uint8_t * cursor = (uint8_t *)ptr;
uint32_t sectors_read = 0;
uint32_t part;
if (strcmp(bdev->name, kNandFirmwareBDevName) == 0) {
part = _firmware_index;
} else if (strcmp(bdev->name, kNandLLBBDevName) == 0) {
part = _llb_index;
} else {
/* Something wrong */
dprintf(DEBUG_CRITICAL,
"ERROR: bad bdev: %s\n",
bdev->name);
return(-1);
}
block_count = npi_get_block_depth(_npi, part);
bytes_per_page = npi_get_bytes_per_page(_npi, part);
pages_per_block = npi_get_pages_per_block(_npi, part);
bytes_per_block = (bytes_per_page * pages_per_block);
sectors_per_block = (bytes_per_block / kNandPartSectorSize);
sectors_per_page = (bytes_per_page / kNandPartSectorSize);
sector_limit = (block_count * sectors_per_block);
first_sector = (sector_base + sector_addr);
last_sector = (first_sector + sector_count - 1);
if (last_sector > sector_limit) {
dprintf(DEBUG_CRITICAL,
"ERROR: 0x%08X-0x%08X not within 0x%08X-0x%08X\n",
first_sector, last_sector, sector_base, sector_limit);
return(-1);
}
for (sector_idx = first_sector; sector_idx <= last_sector; sector_idx++) {
const uint32_t block = sector_idx / sectors_per_block;
const uint32_t sector_in_block = sector_idx % sectors_per_block;
const uint32_t page = sector_in_block / sectors_per_page;
const uint32_t offset = sector_in_block % sectors_per_page;
if (!nand_firmware_cache_page(part, block, page)) {
dprintf(DEBUG_SPEW,
"WARNING: unable to read firmware page 0x%X\n",
page);
break;;
}
memcpy(cursor, &_page_cache[offset * kNandPartSectorSize], kNandPartSectorSize);
sectors_read++;
cursor += kNandPartSectorSize;
}
return(sectors_read);
}
#if ALLOW_NAND_FIRMWARE_ERASE
static int
nand_firmware_erase_block_handler(struct blockdev *bdev, off_t offset, uint64_t len)
{
uint32_t block_base = 0;
uint32_t block_num = 0;
bool llb_nuke = false;
uint32_t pages_per_block;
uint32_t bytes_per_page;
uint32_t bytes_per_block;
uint32_t part;
if (strcmp(bdev->name, kNandFirmwareBDevName) == 0) {
part = _firmware_index;
} else if (strcmp(bdev->name, kNandLLBBDevName) == 0) {
part = _llb_index;
llb_nuke = true;
} else {
/* Something wrong */
dprintf(DEBUG_CRITICAL,
"ERROR: bad bdev: %s\n",
bdev->name);
return(-1);
}
pages_per_block = npi_get_pages_per_block(_npi, part);
bytes_per_page = npi_get_bytes_per_page(_npi, part);
bytes_per_block = (pages_per_block * bytes_per_page);
/* Sanity check offset and len before erase, need to be page-size aligned */
ASSERT(offset >= 0);
if ((uint64_t)offset >= bdev->total_len)
return 0;
if ((offset + len) > bdev->total_len)
len = bdev->total_len - offset;
if ((offset % bytes_per_block) || (len % bytes_per_block))
return 0;
block_num = (len / bytes_per_block);
block_base = (offset / bytes_per_block);
for (UInt16 bank = 0; bank < npi_get_bank_width(_npi, part); bank++) {
/* Read the partition table in the case if LLB erase */
if (llb_nuke) {
npi_erase_boot_partition(_npi);
} else {
for (UInt16 block = block_base; block < (block_base + block_num); block++) {
if (!npi_erase_block(_npi, part, bank, block)) {
dprintf(DEBUG_SPEW,
"WARNING: Erase(%d:%d:%d) failed\n", part, bank, block);
}
}
}
}
return(block_num * bytes_per_block);
}
#endif
#endif /* WITH_BLOCKDEV */
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