593 lines
17 KiB
C
593 lines
17 KiB
C
/*
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* Physical mapping layer for MTD using the Axis partitiontable format
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*
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* Copyright (c) 2001-2007 Axis Communications AB
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*
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* This file is under the GPL.
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*
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* First partition is always sector 0 regardless of if we find a partitiontable
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* or not. In the start of the next sector, there can be a partitiontable that
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* tells us what other partitions to define. If there isn't, we use a default
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* partition split defined below.
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*
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*/
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#include <linux/module.h>
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#include <linux/types.h>
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#include <linux/kernel.h>
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#include <linux/init.h>
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#include <linux/slab.h>
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#include <linux/mtd/concat.h>
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#include <linux/mtd/map.h>
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#include <linux/mtd/mtd.h>
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#include <linux/mtd/mtdram.h>
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#include <linux/mtd/partitions.h>
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#include <asm/axisflashmap.h>
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#include <asm/mmu.h>
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#define MEM_CSE0_SIZE (0x04000000)
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#define MEM_CSE1_SIZE (0x04000000)
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#define FLASH_UNCACHED_ADDR KSEG_E
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#define FLASH_CACHED_ADDR KSEG_F
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#define PAGESIZE (512)
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#if CONFIG_ETRAX_FLASH_BUSWIDTH==1
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#define flash_data __u8
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#elif CONFIG_ETRAX_FLASH_BUSWIDTH==2
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#define flash_data __u16
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#elif CONFIG_ETRAX_FLASH_BUSWIDTH==4
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#define flash_data __u32
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#endif
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/* From head.S */
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extern unsigned long romfs_in_flash; /* 1 when romfs_start, _length in flash */
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extern unsigned long romfs_start, romfs_length;
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extern unsigned long nand_boot; /* 1 when booted from nand flash */
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struct partition_name {
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char name[6];
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};
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/* The master mtd for the entire flash. */
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struct mtd_info* axisflash_mtd = NULL;
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/* Map driver functions. */
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static map_word flash_read(struct map_info *map, unsigned long ofs)
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{
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map_word tmp;
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tmp.x[0] = *(flash_data *)(map->map_priv_1 + ofs);
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return tmp;
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}
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static void flash_copy_from(struct map_info *map, void *to,
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unsigned long from, ssize_t len)
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{
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memcpy(to, (void *)(map->map_priv_1 + from), len);
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}
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static void flash_write(struct map_info *map, map_word d, unsigned long adr)
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{
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*(flash_data *)(map->map_priv_1 + adr) = (flash_data)d.x[0];
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}
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/*
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* The map for chip select e0.
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*
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* We run into tricky coherence situations if we mix cached with uncached
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* accesses to we only use the uncached version here.
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*
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* The size field is the total size where the flash chips may be mapped on the
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* chip select. MTD probes should find all devices there and it does not matter
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* if there are unmapped gaps or aliases (mirrors of flash devices). The MTD
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* probes will ignore them.
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*
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* The start address in map_priv_1 is in virtual memory so we cannot use
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* MEM_CSE0_START but must rely on that FLASH_UNCACHED_ADDR is the start
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* address of cse0.
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*/
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static struct map_info map_cse0 = {
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.name = "cse0",
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.size = MEM_CSE0_SIZE,
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.bankwidth = CONFIG_ETRAX_FLASH_BUSWIDTH,
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.read = flash_read,
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.copy_from = flash_copy_from,
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.write = flash_write,
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.map_priv_1 = FLASH_UNCACHED_ADDR
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};
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/*
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* The map for chip select e1.
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*
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* If there was a gap between cse0 and cse1, map_priv_1 would get the wrong
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* address, but there isn't.
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*/
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static struct map_info map_cse1 = {
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.name = "cse1",
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.size = MEM_CSE1_SIZE,
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.bankwidth = CONFIG_ETRAX_FLASH_BUSWIDTH,
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.read = flash_read,
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.copy_from = flash_copy_from,
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.write = flash_write,
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.map_priv_1 = FLASH_UNCACHED_ADDR + MEM_CSE0_SIZE
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};
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#define MAX_PARTITIONS 7
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#ifdef CONFIG_ETRAX_NANDBOOT
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#define NUM_DEFAULT_PARTITIONS 4
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#define DEFAULT_ROOTFS_PARTITION_NO 2
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#define DEFAULT_MEDIA_SIZE 0x2000000 /* 32 megs */
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#else
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#define NUM_DEFAULT_PARTITIONS 3
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#define DEFAULT_ROOTFS_PARTITION_NO (-1)
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#define DEFAULT_MEDIA_SIZE 0x800000 /* 8 megs */
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#endif
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#if (MAX_PARTITIONS < NUM_DEFAULT_PARTITIONS)
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#error MAX_PARTITIONS must be >= than NUM_DEFAULT_PARTITIONS
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#endif
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/* Initialize the ones normally used. */
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static struct mtd_partition axis_partitions[MAX_PARTITIONS] = {
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{
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.name = "part0",
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.size = CONFIG_ETRAX_PTABLE_SECTOR,
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.offset = 0
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},
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{
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.name = "part1",
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.size = 0,
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.offset = 0
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},
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{
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.name = "part2",
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.size = 0,
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.offset = 0
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},
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{
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.name = "part3",
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.size = 0,
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.offset = 0
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},
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{
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.name = "part4",
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.size = 0,
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.offset = 0
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},
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{
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.name = "part5",
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.size = 0,
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.offset = 0
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},
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{
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.name = "part6",
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.size = 0,
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.offset = 0
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},
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};
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/* If no partition-table was found, we use this default-set.
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* Default flash size is 8MB (NOR). CONFIG_ETRAX_PTABLE_SECTOR is most
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* likely the size of one flash block and "filesystem"-partition needs
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* to be >=5 blocks to be able to use JFFS.
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*/
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static struct mtd_partition axis_default_partitions[NUM_DEFAULT_PARTITIONS] = {
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{
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.name = "boot firmware",
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.size = CONFIG_ETRAX_PTABLE_SECTOR,
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.offset = 0
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},
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{
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.name = "kernel",
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.size = 10 * CONFIG_ETRAX_PTABLE_SECTOR,
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.offset = CONFIG_ETRAX_PTABLE_SECTOR
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},
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#define FILESYSTEM_SECTOR (11 * CONFIG_ETRAX_PTABLE_SECTOR)
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#ifdef CONFIG_ETRAX_NANDBOOT
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{
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.name = "rootfs",
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.size = 10 * CONFIG_ETRAX_PTABLE_SECTOR,
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.offset = FILESYSTEM_SECTOR
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},
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#undef FILESYSTEM_SECTOR
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#define FILESYSTEM_SECTOR (21 * CONFIG_ETRAX_PTABLE_SECTOR)
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#endif
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{
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.name = "rwfs",
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.size = DEFAULT_MEDIA_SIZE - FILESYSTEM_SECTOR,
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.offset = FILESYSTEM_SECTOR
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}
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};
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#ifdef CONFIG_ETRAX_AXISFLASHMAP_MTD0WHOLE
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/* Main flash device */
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static struct mtd_partition main_partition = {
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.name = "main",
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.size = 0,
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.offset = 0
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};
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#endif
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/* Auxiliary partition if we find another flash */
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static struct mtd_partition aux_partition = {
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.name = "aux",
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.size = 0,
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.offset = 0
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};
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/*
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* Probe a chip select for AMD-compatible (JEDEC) or CFI-compatible flash
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* chips in that order (because the amd_flash-driver is faster).
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*/
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static struct mtd_info *probe_cs(struct map_info *map_cs)
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{
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struct mtd_info *mtd_cs = NULL;
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printk(KERN_INFO
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"%s: Probing a 0x%08lx bytes large window at 0x%08lx.\n",
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map_cs->name, map_cs->size, map_cs->map_priv_1);
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#ifdef CONFIG_MTD_CFI
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mtd_cs = do_map_probe("cfi_probe", map_cs);
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#endif
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#ifdef CONFIG_MTD_JEDECPROBE
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if (!mtd_cs)
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mtd_cs = do_map_probe("jedec_probe", map_cs);
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#endif
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return mtd_cs;
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}
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/*
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* Probe each chip select individually for flash chips. If there are chips on
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* both cse0 and cse1, the mtd_info structs will be concatenated to one struct
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* so that MTD partitions can cross chip boundries.
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*
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* The only known restriction to how you can mount your chips is that each
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* chip select must hold similar flash chips. But you need external hardware
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* to do that anyway and you can put totally different chips on cse0 and cse1
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* so it isn't really much of a restriction.
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*/
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extern struct mtd_info* __init crisv32_nand_flash_probe (void);
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static struct mtd_info *flash_probe(void)
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{
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struct mtd_info *mtd_cse0;
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struct mtd_info *mtd_cse1;
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struct mtd_info *mtd_total;
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struct mtd_info *mtds[2];
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int count = 0;
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if ((mtd_cse0 = probe_cs(&map_cse0)) != NULL)
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mtds[count++] = mtd_cse0;
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if ((mtd_cse1 = probe_cs(&map_cse1)) != NULL)
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mtds[count++] = mtd_cse1;
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if (!mtd_cse0 && !mtd_cse1) {
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/* No chip found. */
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return NULL;
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}
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if (count > 1) {
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/* Since the concatenation layer adds a small overhead we
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* could try to figure out if the chips in cse0 and cse1 are
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* identical and reprobe the whole cse0+cse1 window. But since
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* flash chips are slow, the overhead is relatively small.
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* So we use the MTD concatenation layer instead of further
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* complicating the probing procedure.
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*/
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mtd_total = mtd_concat_create(mtds, count, "cse0+cse1");
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if (!mtd_total) {
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printk(KERN_ERR "%s and %s: Concatenation failed!\n",
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map_cse0.name, map_cse1.name);
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/* The best we can do now is to only use what we found
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* at cse0. */
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mtd_total = mtd_cse0;
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map_destroy(mtd_cse1);
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}
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} else
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mtd_total = mtd_cse0 ? mtd_cse0 : mtd_cse1;
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return mtd_total;
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}
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/*
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* Probe the flash chip(s) and, if it succeeds, read the partition-table
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* and register the partitions with MTD.
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*/
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static int __init init_axis_flash(void)
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{
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struct mtd_info *main_mtd;
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struct mtd_info *aux_mtd = NULL;
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int err = 0;
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int pidx = 0;
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struct partitiontable_head *ptable_head = NULL;
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struct partitiontable_entry *ptable;
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int ptable_ok = 0;
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static char page[PAGESIZE];
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size_t len;
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int ram_rootfs_partition = -1; /* -1 => no RAM rootfs partition */
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int part;
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struct mtd_partition *partition;
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/* We need a root fs. If it resides in RAM, we need to use an
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* MTDRAM device, so it must be enabled in the kernel config,
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* but its size must be configured as 0 so as not to conflict
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* with our usage.
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*/
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#if !defined(CONFIG_MTD_MTDRAM) || (CONFIG_MTDRAM_TOTAL_SIZE != 0) || (CONFIG_MTDRAM_ABS_POS != 0)
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if (!romfs_in_flash && !nand_boot) {
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printk(KERN_EMERG "axisflashmap: Cannot create an MTD RAM "
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"device; configure CONFIG_MTD_MTDRAM with size = 0!\n");
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panic("This kernel cannot boot from RAM!\n");
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}
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#endif
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main_mtd = flash_probe();
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if (main_mtd)
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printk(KERN_INFO "%s: 0x%08llx bytes of NOR flash memory.\n",
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main_mtd->name, main_mtd->size);
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#ifdef CONFIG_ETRAX_NANDFLASH
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aux_mtd = crisv32_nand_flash_probe();
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if (aux_mtd)
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printk(KERN_INFO "%s: 0x%08x bytes of NAND flash memory.\n",
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aux_mtd->name, aux_mtd->size);
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#ifdef CONFIG_ETRAX_NANDBOOT
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{
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struct mtd_info *tmp_mtd;
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printk(KERN_INFO "axisflashmap: Set to boot from NAND flash, "
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"making NAND flash primary device.\n");
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tmp_mtd = main_mtd;
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main_mtd = aux_mtd;
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aux_mtd = tmp_mtd;
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}
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#endif /* CONFIG_ETRAX_NANDBOOT */
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#endif /* CONFIG_ETRAX_NANDFLASH */
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if (!main_mtd && !aux_mtd) {
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/* There's no reason to use this module if no flash chip can
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* be identified. Make sure that's understood.
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*/
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printk(KERN_INFO "axisflashmap: Found no flash chip.\n");
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}
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#if 0 /* Dump flash memory so we can see what is going on */
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if (main_mtd) {
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int sectoraddr;
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for (sectoraddr = 0; sectoraddr < 2*65536+4096;
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sectoraddr += PAGESIZE) {
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main_mtd->read(main_mtd, sectoraddr, PAGESIZE, &len,
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page);
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printk(KERN_INFO
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"Sector at %d (length %d):\n",
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sectoraddr, len);
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print_hex_dump(KERN_INFO, "", DUMP_PREFIX_NONE, 16, 1, page, PAGESIZE, false);
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}
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}
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#endif
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if (main_mtd) {
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loff_t ptable_sector = CONFIG_ETRAX_PTABLE_SECTOR;
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main_mtd->owner = THIS_MODULE;
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axisflash_mtd = main_mtd;
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/* First partition (rescue) is always set to the default. */
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pidx++;
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#ifdef CONFIG_ETRAX_NANDBOOT
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/* We know where the partition table should be located,
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* it will be in first good block after that.
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*/
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int blockstat;
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do {
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blockstat = mtd_block_isbad(main_mtd, ptable_sector);
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if (blockstat < 0)
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ptable_sector = 0; /* read error */
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else if (blockstat)
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ptable_sector += main_mtd->erasesize;
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} while (blockstat && ptable_sector);
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#endif
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if (ptable_sector) {
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mtd_read(main_mtd, ptable_sector, PAGESIZE, &len,
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page);
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ptable_head = &((struct partitiontable *) page)->head;
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}
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#if 0 /* Dump partition table so we can see what is going on */
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printk(KERN_INFO
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"axisflashmap: flash read %d bytes at 0x%08x, data: %8ph\n",
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len, CONFIG_ETRAX_PTABLE_SECTOR, page);
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printk(KERN_INFO
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"axisflashmap: partition table offset %d, data: %8ph\n",
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PARTITION_TABLE_OFFSET, page + PARTITION_TABLE_OFFSET);
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#endif
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}
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if (ptable_head && (ptable_head->magic == PARTITION_TABLE_MAGIC)
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&& (ptable_head->size <
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(MAX_PARTITIONS * sizeof(struct partitiontable_entry) +
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PARTITIONTABLE_END_MARKER_SIZE))
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&& (*(unsigned long*)((void*)ptable_head + sizeof(*ptable_head) +
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ptable_head->size -
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PARTITIONTABLE_END_MARKER_SIZE)
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== PARTITIONTABLE_END_MARKER)) {
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/* Looks like a start, sane length and end of a
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* partition table, lets check csum etc.
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*/
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struct partitiontable_entry *max_addr =
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(struct partitiontable_entry *)
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((unsigned long)ptable_head + sizeof(*ptable_head) +
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ptable_head->size);
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unsigned long offset = CONFIG_ETRAX_PTABLE_SECTOR;
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unsigned char *p;
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unsigned long csum = 0;
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ptable = (struct partitiontable_entry *)
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((unsigned long)ptable_head + sizeof(*ptable_head));
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/* Lets be PARANOID, and check the checksum. */
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p = (unsigned char*) ptable;
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while (p <= (unsigned char*)max_addr) {
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csum += *p++;
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csum += *p++;
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csum += *p++;
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csum += *p++;
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}
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ptable_ok = (csum == ptable_head->checksum);
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/* Read the entries and use/show the info. */
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printk(KERN_INFO "axisflashmap: "
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"Found a%s partition table at 0x%p-0x%p.\n",
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(ptable_ok ? " valid" : "n invalid"), ptable_head,
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max_addr);
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/* We have found a working bootblock. Now read the
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* partition table. Scan the table. It ends with 0xffffffff.
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*/
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while (ptable_ok
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&& ptable->offset != PARTITIONTABLE_END_MARKER
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&& ptable < max_addr
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&& pidx < MAX_PARTITIONS - 1) {
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axis_partitions[pidx].offset = offset + ptable->offset;
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#ifdef CONFIG_ETRAX_NANDFLASH
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if (main_mtd->type == MTD_NANDFLASH) {
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axis_partitions[pidx].size =
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(((ptable+1)->offset ==
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PARTITIONTABLE_END_MARKER) ?
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main_mtd->size :
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((ptable+1)->offset + offset)) -
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(ptable->offset + offset);
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} else
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#endif /* CONFIG_ETRAX_NANDFLASH */
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axis_partitions[pidx].size = ptable->size;
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#ifdef CONFIG_ETRAX_NANDBOOT
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/* Save partition number of jffs2 ro partition.
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* Needed if RAM booting or root file system in RAM.
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*/
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if (!nand_boot &&
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ram_rootfs_partition < 0 && /* not already set */
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ptable->type == PARTITION_TYPE_JFFS2 &&
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(ptable->flags & PARTITION_FLAGS_READONLY_MASK) ==
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PARTITION_FLAGS_READONLY)
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ram_rootfs_partition = pidx;
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#endif /* CONFIG_ETRAX_NANDBOOT */
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pidx++;
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ptable++;
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}
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}
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/* Decide whether to use default partition table. */
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/* Only use default table if we actually have a device (main_mtd) */
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partition = &axis_partitions[0];
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if (main_mtd && !ptable_ok) {
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memcpy(axis_partitions, axis_default_partitions,
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sizeof(axis_default_partitions));
|
|
pidx = NUM_DEFAULT_PARTITIONS;
|
|
ram_rootfs_partition = DEFAULT_ROOTFS_PARTITION_NO;
|
|
}
|
|
|
|
/* Add artificial partitions for rootfs if necessary */
|
|
if (romfs_in_flash) {
|
|
/* rootfs is in directly accessible flash memory = NOR flash.
|
|
Add an overlapping device for the rootfs partition. */
|
|
printk(KERN_INFO "axisflashmap: Adding partition for "
|
|
"overlapping root file system image\n");
|
|
axis_partitions[pidx].size = romfs_length;
|
|
axis_partitions[pidx].offset = romfs_start - FLASH_CACHED_ADDR;
|
|
axis_partitions[pidx].name = "romfs";
|
|
axis_partitions[pidx].mask_flags |= MTD_WRITEABLE;
|
|
ram_rootfs_partition = -1;
|
|
pidx++;
|
|
} else if (romfs_length && !nand_boot) {
|
|
/* romfs exists in memory, but not in flash, so must be in RAM.
|
|
* Configure an MTDRAM partition. */
|
|
if (ram_rootfs_partition < 0) {
|
|
/* None set yet, put it at the end */
|
|
ram_rootfs_partition = pidx;
|
|
pidx++;
|
|
}
|
|
printk(KERN_INFO "axisflashmap: Adding partition for "
|
|
"root file system image in RAM\n");
|
|
axis_partitions[ram_rootfs_partition].size = romfs_length;
|
|
axis_partitions[ram_rootfs_partition].offset = romfs_start;
|
|
axis_partitions[ram_rootfs_partition].name = "romfs";
|
|
axis_partitions[ram_rootfs_partition].mask_flags |=
|
|
MTD_WRITEABLE;
|
|
}
|
|
|
|
#ifdef CONFIG_ETRAX_AXISFLASHMAP_MTD0WHOLE
|
|
if (main_mtd) {
|
|
main_partition.size = main_mtd->size;
|
|
err = mtd_device_register(main_mtd, &main_partition, 1);
|
|
if (err)
|
|
panic("axisflashmap: Could not initialize "
|
|
"partition for whole main mtd device!\n");
|
|
}
|
|
#endif
|
|
|
|
/* Now, register all partitions with mtd.
|
|
* We do this one at a time so we can slip in an MTDRAM device
|
|
* in the proper place if required. */
|
|
|
|
for (part = 0; part < pidx; part++) {
|
|
if (part == ram_rootfs_partition) {
|
|
/* add MTDRAM partition here */
|
|
struct mtd_info *mtd_ram;
|
|
|
|
mtd_ram = kmalloc(sizeof(struct mtd_info), GFP_KERNEL);
|
|
if (!mtd_ram)
|
|
panic("axisflashmap: Couldn't allocate memory "
|
|
"for mtd_info!\n");
|
|
printk(KERN_INFO "axisflashmap: Adding RAM partition "
|
|
"for rootfs image.\n");
|
|
err = mtdram_init_device(mtd_ram,
|
|
(void *)(u_int32_t)partition[part].offset,
|
|
partition[part].size,
|
|
partition[part].name);
|
|
if (err)
|
|
panic("axisflashmap: Could not initialize "
|
|
"MTD RAM device!\n");
|
|
/* JFFS2 likes to have an erasesize. Keep potential
|
|
* JFFS2 rootfs happy by providing one. Since image
|
|
* was most likely created for main mtd, use that
|
|
* erasesize, if available. Otherwise, make a guess. */
|
|
mtd_ram->erasesize = (main_mtd ? main_mtd->erasesize :
|
|
CONFIG_ETRAX_PTABLE_SECTOR);
|
|
} else {
|
|
err = mtd_device_register(main_mtd, &partition[part],
|
|
1);
|
|
if (err)
|
|
panic("axisflashmap: Could not add mtd "
|
|
"partition %d\n", part);
|
|
}
|
|
}
|
|
|
|
if (aux_mtd) {
|
|
aux_partition.size = aux_mtd->size;
|
|
err = mtd_device_register(aux_mtd, &aux_partition, 1);
|
|
if (err)
|
|
panic("axisflashmap: Could not initialize "
|
|
"aux mtd device!\n");
|
|
|
|
}
|
|
|
|
return err;
|
|
}
|
|
|
|
/* This adds the above to the kernels init-call chain. */
|
|
module_init(init_axis_flash);
|
|
|
|
EXPORT_SYMBOL(axisflash_mtd);
|