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[/] [or1k/] [trunk/] [linux/] [linux-2.4/] [drivers/] [mtd/] [cmdlinepart.c] - Rev 1275
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/* * $Id: cmdlinepart.c,v 1.1.1.1 2004-04-15 01:51:38 phoenix Exp $ * * Read flash partition table from command line * * Copyright 2002 SYSGO Real-Time Solutions GmbH * * The format for the command line is as follows: * * mtdparts=<mtddef>[;<mtddef] * <mtddef> := <mtd-id>:<partdef>[,<partdef>] * <partdef> := <size>[@offset][<name>][ro] * <mtd-id> := unique id used in mapping driver/device * <size> := standard linux memsize OR "-" to denote all remaining space * <name> := '(' NAME ')' * * Examples: * * 1 NOR Flash, with 1 single writable partition: * edb7312-nor:- * * 1 NOR Flash with 2 partitions, 1 NAND with one * edb7312-nor:256k(ARMboot)ro,-(root);edb7312-nand:-(home) */ #include <linux/kernel.h> #include <linux/slab.h> #include <linux/mtd/mtd.h> #include <linux/mtd/partitions.h> #include <asm/setup.h> #include <linux/bootmem.h> /* error message prefix */ #define ERRP "mtd: " /* debug macro */ #if 0 #define dbg(x) do { printk("DEBUG-CMDLINE-PART: "); printk x; } while(0) #else #define dbg(x) #endif /* special size referring to all the remaining space in a partition */ #define SIZE_REMAINING 0xffffffff struct cmdline_mtd_partition { struct cmdline_mtd_partition *next; char *mtd_id; int num_parts; struct mtd_partition *parts; }; /* mtdpart_setup() parses into here */ static struct cmdline_mtd_partition *partitions; /* the command line passed to mtdpart_setupd() */ static char *cmdline; static int cmdline_parsed = 0; /* * Parse one partition definition for an MTD. Since there can be many * comma separated partition definitions, this function calls itself * recursively until no more partition definitions are found. Nice side * effect: the memory to keep the mtd_partition structs and the names * is allocated upon the last definition being found. At that point the * syntax has been verified ok. */ static struct mtd_partition * newpart(char *s, char **retptr, int *num_parts, int this_part, unsigned char **extra_mem_ptr, int extra_mem_size) { struct mtd_partition *parts; unsigned long size; unsigned long offset = 0; char *name; int name_len; unsigned char *extra_mem; char delim; unsigned int mask_flags; /* fetch the partition size */ if (*s == '-') { /* assign all remaining space to this partition */ size = SIZE_REMAINING; s++; } else { size = memparse(s, &s); if (size < PAGE_SIZE) { printk(KERN_ERR ERRP "partition size too small (%lx)\n", size); return 0; } } /* fetch partition name and flags */ mask_flags = 0; /* this is going to be a regular partition */ delim = 0; /* check for offset */ if (*s == '@') { s++; offset = memparse(s, &s); } /* now look for name */ if (*s == '(') { delim = ')'; } if (delim) { char *p; name = ++s; if ((p = strchr(name, delim)) == 0) { printk(KERN_ERR ERRP "no closing %c found in partition name\n", delim); return 0; } name_len = p - name; s = p + 1; } else { name = NULL; name_len = 13; /* Partition_000 */ } /* record name length for memory allocation later */ extra_mem_size += name_len + 1; /* test for options */ if (strncmp(s, "ro", 2) == 0) { mask_flags |= MTD_WRITEABLE; s += 2; } /* test if more partitions are following */ if (*s == ',') { if (size == SIZE_REMAINING) { printk(KERN_ERR ERRP "no partitions allowed after a fill-up partition\n"); return 0; } /* more partitions follow, parse them */ if ((parts = newpart(s + 1, &s, num_parts, this_part + 1, &extra_mem, extra_mem_size)) == 0) return 0; } else { /* this is the last partition: allocate space for all */ int alloc_size; *num_parts = this_part + 1; alloc_size = *num_parts * sizeof(struct mtd_partition) + extra_mem_size; parts = kmalloc(alloc_size, GFP_KERNEL); if (!parts) { printk(KERN_ERR ERRP "out of memory\n"); return 0; } memset(parts, 0, alloc_size); extra_mem = (unsigned char *)(parts + *num_parts); } /* enter this partition (offset will be calculated later if it is zero at this point) */ parts[this_part].size = size; parts[this_part].offset = offset; parts[this_part].mask_flags = mask_flags; if (name) { strncpy(extra_mem, name, name_len); extra_mem[name_len] = 0; } else { sprintf(extra_mem, "Partition_%03d", this_part); } parts[this_part].name = extra_mem; extra_mem += name_len + 1; dbg(("partition %d: name <%s>, offset %x, size %x, mask flags %x\n", this_part, parts[this_part].name, parts[this_part].offset, parts[this_part].size, parts[this_part].mask_flags)); /* return (updated) pointer to extra_mem memory */ if (extra_mem_ptr) *extra_mem_ptr = extra_mem; /* return (updated) pointer command line string */ *retptr = s; /* return partition table */ return parts; } /* * Parse the command line. */ static int mtdpart_setup_real(char *s) { cmdline_parsed = 1; for( ; s != NULL; ) { struct cmdline_mtd_partition *this_mtd; struct mtd_partition *parts; int mtd_id_len; int num_parts; char *p, *mtd_id; mtd_id = s; /* fetch <mtd-id> */ if (!(p = strchr(s, ':'))) { printk(KERN_ERR ERRP "no mtd-id\n"); return 0; } mtd_id_len = p - mtd_id; dbg(("parsing <%s>\n", p+1)); /* * parse one mtd. have it reserve memory for the * struct cmdline_mtd_partition and the mtd-id string. */ parts = newpart(p + 1, /* cmdline */ &s, /* out: updated cmdline ptr */ &num_parts, /* out: number of parts */ 0, /* first partition */ (unsigned char**)&this_mtd, /* out: extra mem */ mtd_id_len + 1 + sizeof(*this_mtd)); if(!parts) { /* * An error occurred. We're either: * a) out of memory, or * b) in the middle of the partition spec * Either way, this mtd is hosed and we're * unlikely to succeed in parsing any more */ return 0; } /* enter results */ this_mtd->parts = parts; this_mtd->num_parts = num_parts; this_mtd->mtd_id = (char*)(this_mtd + 1); strncpy(this_mtd->mtd_id, mtd_id, mtd_id_len); this_mtd->mtd_id[mtd_id_len] = 0; /* link into chain */ this_mtd->next = partitions; partitions = this_mtd; dbg(("mtdid=<%s> num_parts=<%d>\n", this_mtd->mtd_id, this_mtd->num_parts)); /* EOS - we're done */ if (*s == 0) break; /* does another spec follow? */ if (*s != ';') { printk(KERN_ERR ERRP "bad character after partition (%c)\n", *s); return 0; } s++; } return 1; } /* * Main function to be called from the MTD mapping driver/device to * obtain the partitioning information. At this point the command line * arguments will actually be parsed and turned to struct mtd_partition * information. It returns partitions for the requested mtd device, or * the first one in the chain if a NULL mtd_id is passed in. */ int parse_cmdline_partitions(struct mtd_info *master, struct mtd_partition **pparts, const char *mtd_id) { unsigned long offset; int i; struct cmdline_mtd_partition *part; if(!cmdline) return -EINVAL; /* parse command line */ if (!cmdline_parsed) mtdpart_setup_real(cmdline); for(part = partitions; part; part = part->next) { if ((!mtd_id) || (!strcmp(part->mtd_id, mtd_id))) { for(i = 0, offset = 0; i < part->num_parts; i++) { if (!part->parts[i].offset) part->parts[i].offset = offset; else offset = part->parts[i].offset; if (part->parts[i].size == SIZE_REMAINING) part->parts[i].size = master->size - offset; if (offset + part->parts[i].size > master->size) { printk(KERN_WARNING ERRP "%s: partitioning exceeds flash size, truncating\n", part->mtd_id); part->parts[i].size = master->size - offset; part->num_parts = i; } offset += part->parts[i].size; } *pparts = part->parts; return part->num_parts; } } return -EINVAL; } /* * This is the handler for our kernel parameter, called from * main.c::checksetup(). Note that we can not yet kmalloc() anything, * so we only save the commandline for later processing. */ static int __init mtdpart_setup(char *s) { cmdline = s; return 1; } __setup("mtdparts=", mtdpart_setup); EXPORT_SYMBOL(parse_cmdline_partitions); MODULE_LICENSE("GPL"); MODULE_AUTHOR("Marius Groeger <mag@sysgo.de>"); MODULE_DESCRIPTION("Command line configuration of MTD partitions");
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