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/******************************************************************************
* Copyright (c) 2004, 2008 IBM Corporation
* All rights reserved.
* This program and the accompanying materials
* are made available under the terms of the BSD License
* which accompanies this distribution, and is available at
* http://www.opensource.org/licenses/bsd-license.php
*
* Contributors:
* IBM Corporation - initial implementation
*****************************************************************************/
#include "cache.h"
#include "nvram.h"
#include "../libhvcall/libhvcall.h"
#include <stdio.h>
#include <stdarg.h>
#include <string.h>
#include <southbridge.h>
#include <nvramlog.h>
#include <byteorder.h>
#ifdef RTAS_NVRAM
static uint32_t fetch_token;
static uint32_t store_token;
static uint32_t NVRAM_LENGTH;
static char *nvram_buffer; /* use buffer allocated by SLOF code */
#else
#ifndef NVRAM_LENGTH
#define NVRAM_LENGTH 0x10000
#endif
/*
* This is extremely ugly, but still better than implementing
* another sbrk() around it.
*/
static char nvram_buffer[NVRAM_LENGTH];
#endif
static uint8_t nvram_buffer_locked=0x00;
void nvram_init(uint32_t _fetch_token, uint32_t _store_token,
long _nvram_length, void* nvram_addr)
{
#ifdef RTAS_NVRAM
fetch_token = _fetch_token;
store_token = _store_token;
NVRAM_LENGTH = _nvram_length;
nvram_buffer = nvram_addr;
DEBUG("\nNVRAM: size=%d, fetch=%x, store=%x\n",
NVRAM_LENGTH, fetch_token, store_token);
#endif
}
void asm_cout(long Character,long UART,long NVRAM);
#if defined(DISABLE_NVRAM)
static volatile uint8_t nvram[NVRAM_LENGTH]; /* FAKE */
#define nvram_access(type,size,name) \
type nvram_read_##name(unsigned int offset) \
{ \
type *pos; \
if (offset > (NVRAM_LENGTH - sizeof(type))) \
return 0; \
pos = (type *)(nvram+offset); \
return *pos; \
} \
void nvram_write_##name(unsigned int offset, type data) \
{ \
type *pos; \
if (offset > (NVRAM_LENGTH - sizeof(type))) \
return; \
pos = (type *)(nvram+offset); \
*pos = data; \
}
#elif defined(RTAS_NVRAM)
static inline void nvram_fetch(unsigned int offset, void *buf, unsigned int len)
{
struct hv_rtas_call rtas = {
.token = fetch_token,
.nargs = 3,
.nrets = 2,
.argret = { offset, (uint32_t)(unsigned long)buf, len },
};
h_rtas(&rtas);
}
static inline void nvram_store(unsigned int offset, void *buf, unsigned int len)
{
struct hv_rtas_call rtas = {
.token = store_token,
.nargs = 3,
.nrets = 2,
.argret = { offset, (uint32_t)(unsigned long)buf, len },
};
h_rtas(&rtas);
}
#define nvram_access(type,size,name) \
type nvram_read_##name(unsigned int offset) \
{ \
type val; \
if (offset > (NVRAM_LENGTH - sizeof(type))) \
return 0; \
nvram_fetch(offset, &val, size / 8); \
return val; \
} \
void nvram_write_##name(unsigned int offset, type data) \
{ \
if (offset > (NVRAM_LENGTH - sizeof(type))) \
return; \
nvram_store(offset, &data, size / 8); \
}
#else /* DISABLE_NVRAM */
static volatile uint8_t *nvram = (volatile uint8_t *)SB_NVRAM_adr;
#define nvram_access(type,size,name) \
type nvram_read_##name(unsigned int offset) \
{ \
type *pos; \
if (offset > (NVRAM_LENGTH - sizeof(type))) \
return 0; \
pos = (type *)(nvram+offset); \
return ci_read_##size(pos); \
} \
void nvram_write_##name(unsigned int offset, type data) \
{ \
type *pos; \
if (offset > (NVRAM_LENGTH - sizeof(type))) \
return; \
pos = (type *)(nvram+offset); \
ci_write_##size(pos, data); \
}
#endif
/*
* producer for nvram access functions. Since these functions are
* basically all the same except for the used data types, produce
* them via the nvram_access macro to keep the code from bloating.
*/
nvram_access(uint8_t, 8, byte)
nvram_access(uint16_t, 16, word)
nvram_access(uint32_t, 32, dword)
nvram_access(uint64_t, 64, qword)
/**
* This function is a minimal abstraction for our temporary
* buffer. It should have been malloced, but since there is no
* usable malloc, we go this route.
*
* @return pointer to temporary buffer
*/
char *get_nvram_buffer(unsigned len)
{
if(len>NVRAM_LENGTH)
return NULL;
if(nvram_buffer_locked)
return NULL;
nvram_buffer_locked = 0xff;
return nvram_buffer;
}
/**
* @param buffer pointer to the allocated buffer. This
* is unused, but nice in case we ever get a real malloc
*/
void free_nvram_buffer(char *buffer __attribute__((unused)))
{
nvram_buffer_locked = 0x00;
}
/**
* @param fmt format string, like in printf
* @param ... variable number of arguments
*/
int nvramlog_printf(const char* fmt, ...)
{
char buff[256];
int count, i;
va_list ap;
va_start(ap, fmt);
count = vsprintf(buff, fmt, ap);
va_end(ap);
for (i=0; i<count; i++)
asm_cout(buff[i], 0, 1);
return count;
}
/**
* @param offset start offset of the partition header
*/
static uint8_t get_partition_type(int offset)
{
return nvram_read_byte(offset);
}
/**
* @param offset start offset of the partition header
*/
static uint8_t get_partition_header_checksum(int offset)
{
return nvram_read_byte(offset+1);
}
/**
* @param offset start offset of the partition header
*/
static uint16_t get_partition_len(int offset)
{
return nvram_read_word(offset+2);
}
/**
* @param offset start offset of the partition header
* @return static char array containing the partition name
*
* NOTE: If the partition name needs to be non-temporary, strdup
* and use the copy instead.
*/
static char * get_partition_name(int offset)
{
static char name[12];
int i;
for (i=0; i<12; i++)
name[i]=nvram_read_byte(offset+4+i);
DEBUG("name: \"%s\"\n", name);
return name;
}
static uint8_t calc_partition_header_checksum(int offset)
{
uint16_t plainsum;
uint8_t checksum;
int i;
plainsum = nvram_read_byte(offset);
for (i=2; i<PARTITION_HEADER_SIZE; i++)
plainsum+=nvram_read_byte(offset+i);
checksum=(plainsum>>8)+(plainsum&0xff);
return checksum;
}
static unsigned int calc_used_nvram_space(void)
{
unsigned walk, len;
for (walk=0; walk<NVRAM_LENGTH;) {
if(nvram_read_byte(walk) == 0
|| get_partition_header_checksum(walk) !=
calc_partition_header_checksum(walk)) {
/* If there's no valid entry, bail out */
break;
}
len=get_partition_len(walk);
DEBUG("... part len=%x, %x\n", len, len*16);
if(!len) {
/* If there's a partition type but no len, bail out.
* Don't bail out if type is 0. This can be used to
* find the offset of the first free byte.
*/
break;
}
walk += len * 16;
}
DEBUG("used nvram space: %d\n", walk);
return walk;
}
/**
*
* @param type partition type. Set this to the partition type you are looking
* for. If there are several partitions with the same type, only
* the first partition with that type will be found.
* Set to -1 to ignore. Set to 0 to find free unpartitioned space.
*
* @param name partition name. Set this to the name of the partition you are
* looking for. If there are several partitions with the same name,
* only the first partition with that name will be found.
* Set to NULL to ignore.
*
* To disambiguate the partitions you should have a unique name if you plan to
* have several partitions of the same type.
*
*/
partition_t get_partition(unsigned int type, char *name)
{
partition_t ret={0,-1};
unsigned walk, len;
DEBUG("get_partition(%i, '%s')\n", type, name);
for (walk=0; walk<NVRAM_LENGTH;) {
// DEBUG("get_partition: walk=%x\n", walk);
if(get_partition_header_checksum(walk) !=
calc_partition_header_checksum(walk)) {
/* If there's no valid entry, bail out */
break;
}
len=get_partition_len(walk);
if(type && !len) {
/* If there's a partition type but no len, bail out.
* Don't bail out if type is 0. This can be used to
* find the offset of the first free byte.
*/
break;
}
/* Check if either type or name or both do not match. */
if ( (type!=(unsigned int)-1 && type != get_partition_type(walk)) ||
(name && strncmp(get_partition_name(walk), name, 12)) ) {
/* We hit another partition. Continue
* at the end of this partition
*/
walk += len*16;
continue;
}
ret.addr=walk+PARTITION_HEADER_SIZE;
ret.len=(len*16)-PARTITION_HEADER_SIZE;
break;
}
return ret;
}
/* Get partition specified by a Forth string */
partition_t get_partition_fs(char *name, int namelen)
{
char buf[namelen + 1];
memcpy(buf, name, namelen);
buf[namelen] = 0;
return get_partition(-1, buf);
}
void erase_nvram(int offset, int len)
{
int i;
#ifdef RTAS_NVRAM
char *erase_buf = get_nvram_buffer(len);
if (erase_buf) {
/* Speed up by erasing all memory at once */
memset(erase_buf, 0, len);
nvram_store(offset, erase_buf, len);
free_nvram_buffer(erase_buf);
return;
}
/* If get_nvram_buffer failed, fall through to default code */
#endif
for (i=offset; i<offset+len; i++)
nvram_write_byte(i, 0);
}
void wipe_nvram(void)
{
erase_nvram(0, NVRAM_LENGTH);
}
/**
* @param partition partition structure pointing to the partition to wipe.
* @param header_only if header_only is != 0 only the partition header is
* nulled out, not the whole partition.
*/
int wipe_partition(partition_t partition, int header_only)
{
int pstart, len;
pstart=partition.addr-PARTITION_HEADER_SIZE;
len=PARTITION_HEADER_SIZE;
if(!header_only)
len += partition.len;
erase_nvram(pstart, len);
return 0;
}
static partition_t create_nvram_partition(int type, const char *name, unsigned len)
{
partition_t ret = { 0, 0 };
unsigned i, offset, plen;
plen = ALIGN(len+PARTITION_HEADER_SIZE, 16);
DEBUG("Creating partition type=%x, name=%s, len=%d plen=%d\n",
type, name, len, plen);
offset = calc_used_nvram_space();
if (NVRAM_LENGTH-(calc_used_nvram_space())<plen) {
DEBUG("Not enough free space.\n");
return ret;
}
DEBUG("Writing header.");
nvram_write_byte(offset, type);
nvram_write_word(offset+2, plen/16);
for (i=0; i<strlen(name); i++)
nvram_write_byte(offset+4+i, name[i]);
nvram_write_byte(offset+1, calc_partition_header_checksum(offset));
ret.addr = offset+PARTITION_HEADER_SIZE;
ret.len = len;
DEBUG("partition created: addr=%lx len=%lx\n", ret.addr, ret.len);
return ret;
}
static int create_free_partition(void)
{
int free_space;
partition_t free_part;
free_space = NVRAM_LENGTH - calc_used_nvram_space() - PARTITION_HEADER_SIZE;
free_part = create_nvram_partition(0x7f, "free space", free_space);
return (free_part.addr != 0);
}
partition_t new_nvram_partition(int type, char *name, int len)
{
partition_t free_part, new_part = { 0, 0 };
/* NOTE: Assume all free space is consumed by the "free space"
* partition. This means a partition can not be increased in the middle
* of reset_nvram, which is obviously not a big loss.
*/
free_part=get_partition(0x7f, NULL);
if( free_part.len && free_part.len != -1)
wipe_partition(free_part, 1);
new_part = create_nvram_partition(type, name, len);
if(new_part.len != len) {
new_part.len = 0;
new_part.addr = 0;
}
create_free_partition();
return new_part;
}
partition_t new_nvram_partition_fs(int type, char *name, int namelen, int len)
{
char buf[13];
int i;
for (i = 0; i < 12; i++) {
if (i < namelen)
buf[i] = name[i];
else
buf[i] = 0;
}
buf[12] = 0;
return new_nvram_partition(type, buf, len);
}
/**
* @param partition partition structure pointing to the partition to wipe.
*/
int delete_nvram_partition(partition_t partition)
{
unsigned i;
partition_t free_part;
if(!partition.len || partition.len == -1)
return 0;
for (i=partition.addr+partition.len; i< NVRAM_LENGTH; i++)
nvram_write_byte(i - partition.len - PARTITION_HEADER_SIZE, nvram_read_byte(i));
erase_nvram(NVRAM_LENGTH-partition.len-PARTITION_HEADER_SIZE,
partition.len-PARTITION_HEADER_SIZE);
free_part=get_partition(0x7f, NULL);
wipe_partition(free_part, 0);
create_free_partition();
return 1;
}
int clear_nvram_partition(partition_t part)
{
if(!part.addr)
return 0;
erase_nvram(part.addr, part.len);
return 1;
}
int increase_nvram_partition_size(partition_t partition, int newsize)
{
partition_t free_part;
int free_offset, end_offset, i;
/* We don't support shrinking partitions (yet) */
if (newsize < partition.len) {
return 0;
}
/* NOTE: Assume all free space is consumed by the "free space"
* partition. This means a partition can not be increased in the middle
* of reset_nvram, which is obviously not a big loss.
*/
free_part=get_partition(0x7f, NULL);
// FIXME: It could be 16 byte more. Also handle empty "free" partition.
if (free_part.len == -1 || free_part.len < newsize - partition.len ) {
return 0;
}
free_offset=free_part.addr - PARTITION_HEADER_SIZE; // first unused byte
end_offset=partition.addr + partition.len; // last used byte of partition + 1
if(free_offset > end_offset) {
int j, bufferlen;
char *overlap_buffer;
bufferlen=free_offset - end_offset;
overlap_buffer=get_nvram_buffer(bufferlen);
if(!overlap_buffer) {
return 0;
}
for (i=end_offset, j=0; i<free_offset; i++, j++)
overlap_buffer[j]=nvram_read_byte(i);
/* Only wipe the header. The free space partition is empty per
* definition
*/
wipe_partition(free_part, 1);
for (i=partition.addr+newsize, j=0; i<(int)(partition.addr+newsize+bufferlen); i++, j++)
nvram_write_byte(i, overlap_buffer[j]);
free_nvram_buffer(overlap_buffer);
} else {
/* Only wipe the header. */
wipe_partition(free_part, 1);
}
/* Clear the new partition space */
erase_nvram(partition.addr+partition.len, newsize-partition.len);
nvram_write_word(partition.addr - 16 + 2, newsize);
create_free_partition();
return 1;
}
static void init_cpulog_partition(partition_t cpulog)
{
unsigned int offset=cpulog.addr;
/* see board-xxx/include/nvramlog.h for information */
nvram_write_word(offset+0, 0x40); // offset
nvram_write_word(offset+2, 0x00); // flags
nvram_write_dword(offset+4, 0x01); // pointer
}
void reset_nvram(void)
{
partition_t cpulog0, cpulog1;
struct {
uint32_t prefix;
uint64_t name;
} __attribute__((packed)) header;
DEBUG("Erasing NVRAM\n");
erase_nvram(0, NVRAM_LENGTH);
DEBUG("Creating CPU log partitions\n");
header.prefix = be32_to_cpu(LLFW_LOG_BE0_NAME_PREFIX);
header.name = be64_to_cpu(LLFW_LOG_BE0_NAME);
cpulog0=create_nvram_partition(LLFW_LOG_BE0_SIGNATURE, (char *)&header,
(LLFW_LOG_BE0_LENGTH*16)-PARTITION_HEADER_SIZE);
header.prefix = be32_to_cpu(LLFW_LOG_BE1_NAME_PREFIX);
header.name = be64_to_cpu(LLFW_LOG_BE1_NAME);
cpulog1=create_nvram_partition(LLFW_LOG_BE1_SIGNATURE, (char *)&header,
(LLFW_LOG_BE1_LENGTH*16)-PARTITION_HEADER_SIZE);
DEBUG("Initializing CPU log partitions\n");
init_cpulog_partition(cpulog0);
init_cpulog_partition(cpulog1);
nvramlog_printf("Creating common NVRAM partition\r\n");
create_nvram_partition(0x70, "common", 0x01000-PARTITION_HEADER_SIZE);
create_free_partition();
}
void nvram_debug(void)
{
#ifndef RTAS_NVRAM
printf("\nNVRAM_BASE: %p\n", nvram);
printf("NVRAM_LEN: 0x%x\n", NVRAM_LENGTH);
#endif
}
unsigned int get_nvram_size(void)
{
return NVRAM_LENGTH;
}
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