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gfiber / uboot / prism / refs/heads/master / . / board / gth2 / gth2.c
blob: 59873d5ef6a80d7b0e108d20069bb729bd94726f [file] [log] [blame]
/*
* (C) Copyright 2005
* Thomas.Lange@corelatus.se
*
* See file CREDITS for list of people who contributed to this
* project.
*
* 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 (at your option) 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., 59 Temple Place, Suite 330, Boston,
* MA 02111-1307 USA
*/
#include <common.h>
#include <command.h>
#include <asm/au1x00.h>
#include <asm/addrspace.h>
#include <asm/mipsregs.h>
#include <asm/io.h>
#include <watchdog.h>
#include "ee_access.h"
static int wdi_status = 0;
#define SDRAM_SIZE ((64*1024*1024)-(12*4096))
#define SERIAL_LOG_BUFFER CKSEG1ADDR(SDRAM_SIZE + (8*4096))
void inline log_serial_char(char c){
char *serial_log_buffer = (char*)SERIAL_LOG_BUFFER;
int serial_log_offset;
u32 *serial_log_offsetp = (u32*)SERIAL_LOG_BUFFER;
serial_log_offset = *serial_log_offsetp;
*(serial_log_buffer + serial_log_offset) = c;
serial_log_offset++;
if(serial_log_offset >= 4096){
serial_log_offset = 4;
}
*serial_log_offsetp = serial_log_offset;
}
void init_log_serial(void){
char *serial_log_buffer = (char*)SERIAL_LOG_BUFFER;
u32 *serial_log_offsetp = (u32*)SERIAL_LOG_BUFFER;
/* Copy buffer from last run */
memcpy(serial_log_buffer + 4096,
serial_log_buffer,
4096);
memset(serial_log_buffer, 0, 4096);
*serial_log_offsetp = 4;
}
void hw_watchdog_reset(void){
volatile u32 *sys_outputset = (volatile u32*)SYS_OUTPUTSET;
volatile u32 *sys_outputclear = (volatile u32*)SYS_OUTPUTCLR;
if(wdi_status){
*sys_outputset = GPIO_CPU_LED|GPIO_WDI;
wdi_status = 0;
}
else{
*sys_outputclear = GPIO_CPU_LED|GPIO_WDI;
wdi_status = 1;
}
}
phys_size_t initdram(int board_type)
{
/* Sdram is setup by assembler code */
/* If memory could be changed, we should return the true value here */
WATCHDOG_RESET();
return (SDRAM_SIZE);
}
/* In cpu/mips/cpu.c */
void write_one_tlb( int index, u32 pagemask, u32 hi, u32 low0, u32 low1 );
void set_ledcard(u32 value){
/* Clock 24 bits to led card */
int i;
volatile u32 *sys_outputset = (volatile u32*)SYS_OUTPUTSET;
volatile u32 *sys_outputclr = (volatile u32*)SYS_OUTPUTCLR;
/* Start with known values */
*sys_outputclr = GPIO_LEDCLK|GPIO_LEDD;
for(i=0;i<24;i++){
if(value&0x00800000){
*sys_outputset = GPIO_LEDD;
}
else{
*sys_outputclr = GPIO_LEDD;
}
udelay(1);
*sys_outputset = GPIO_LEDCLK;
udelay(1);
*sys_outputclr = GPIO_LEDCLK;
udelay(1);
value<<=1;
}
/* Data is enable output */
*sys_outputset = GPIO_LEDD;
}
int checkboard (void)
{
volatile u32 *sys_counter = (volatile u32*)SYS_COUNTER_CNTRL;
volatile u32 *sys_outputset = (volatile u32*)SYS_OUTPUTSET;
volatile u32 *sys_outputclr = (volatile u32*)SYS_OUTPUTCLR;
u32 proc_id;
WATCHDOG_RESET();
*sys_counter = 0x100; /* Enable 32 kHz oscillator for RTC/TOY */
proc_id = read_c0_prid();
switch (proc_id >> 24) {
case 0:
puts ("Board: GTH2\n");
printf ("CPU: Au1000 500 MHz, id: 0x%02x, rev: 0x%02x\n",
(proc_id >> 8) & 0xFF, proc_id & 0xFF);
break;
default:
printf ("Unsupported cpu %d, proc_id=0x%x\n", proc_id >> 24, proc_id);
}
set_io_port_base(0);
#ifdef CONFIG_IDE_PCMCIA
/* PCMCIA is on a 36 bit physical address.
We need to map it into a 32 bit addresses */
write_one_tlb(20, /* index */
0x01ffe000, /* Pagemask, 16 MB pages */
CONFIG_SYS_PCMCIA_IO_BASE, /* Hi */
0x3C000017, /* Lo0 */
0x3C200017); /* Lo1 */
write_one_tlb(21, /* index */
0x01ffe000, /* Pagemask, 16 MB pages */
CONFIG_SYS_PCMCIA_ATTR_BASE, /* Hi */
0x3D000017, /* Lo0 */
0x3D200017); /* Lo1 */
write_one_tlb(22, /* index */
0x01ffe000, /* Pagemask, 16 MB pages */
CONFIG_SYS_PCMCIA_MEM_ADDR, /* Hi */
0x3E000017, /* Lo0 */
0x3E200017); /* Lo1 */
#endif /* CONFIG_IDE_PCMCIA */
/* Wait for GPIO ports to become stable */
udelay(5000); /* FIXME */
/* Release reset of ethernet PHY chips */
/* Always do this, because linux does not know about it */
*sys_outputset = GPIO_ERESET;
/* Kill FPGA:s */
*sys_outputclr = GPIO_CACONFIG|GPIO_DPACONFIG;
udelay(2);
*sys_outputset = GPIO_CACONFIG|GPIO_DPACONFIG;
/* Turn front led yellow */
set_ledcard(0x00100000);
return 0;
}
#define POWER_OFFSET 0xF0000
#define SW_WATCHDOG_REASON 13
#define BOOTDATA_OFFSET 0xF8000
#define MAX_ATTEMPTS 5
#define FAILSAFE_BOOT 1
#define SYSTEM_BOOT 2
#define SYSTEM2_BOOT 3
#define WRITE_FLASH16(a, d) \
do \
{ \
*((volatile u16 *) (a)) = (d);\
} while(0)
static void write_bootdata (volatile u16 * addr, u8 System, u8 Count)
{
u16 data;
volatile u16 *flash = (u16 *) (CONFIG_SYS_FLASH_BASE);
switch(System){
case FAILSAFE_BOOT:
printf ("Setting failsafe boot in flash\n");
break;
case SYSTEM_BOOT:
printf ("Setting system boot in flash\n");
break;
case SYSTEM2_BOOT:
printf ("Setting system2 boot in flash\n");
break;
default:
printf ("Invalid system data %u, setting failsafe\n", System);
System = FAILSAFE_BOOT;
}
if ((Count < 1) | (Count > MAX_ATTEMPTS)) {
printf ("Invalid boot count %u, setting 1\n", Count);
Count = 1;
}
printf ("Boot attempt %d\n", Count);
data = (System << 8) | Count;
/* AMD 16 bit */
WRITE_FLASH16 (&flash[0x555], 0xAAAA);
WRITE_FLASH16 (&flash[0x2AA], 0x5555);
WRITE_FLASH16 (&flash[0x555], 0xA0A0);
WRITE_FLASH16 (addr, data);
}
static int random_system(void){
/* EEPROM read failed. Just try to choose one
system release and hope it works */
/* FIXME */
return(SYSTEM_BOOT);
}
static int switch_system(int old_system){
u8 Rx[10];
u8 Tx[5];
int valid_release;
if(old_system==FAILSAFE_BOOT){
/* Find out which system release to use */
/* Copy from nvram to scratchpad */
Tx[0] = RECALL_MEMORY;
Tx[1] = 7; /* Page */
if (ee_do_cpu_command (Tx, 2, NULL, 0, 1)) {
printf ("EE user page 7 recall failed\n");
return (random_system());
}
Tx[0] = READ_SCRATCHPAD;
if (ee_do_cpu_command (Tx, 2, Rx, 9, 1)) {
printf ("EE user page 7 read failed\n");
return (random_system());
}
/* Crc in 9:th byte */
if (!ee_crc_ok (Rx, 8, *(Rx + 8))) {
printf ("EE read failed, page 7. CRC error\n");
return (random_system());
}
valid_release = Rx[7];
if((valid_release==0xFF)|
((valid_release&1) == 0)){
return(SYSTEM_BOOT);
}
else{
return(SYSTEM2_BOOT);
}
}
else{
return(FAILSAFE_BOOT);
}
}
static void check_boot_tries (void)
{
/* Count the number of boot attemps
switch system if too many */
int i;
volatile u16 *addr;
volatile u16 data;
u8 system = FAILSAFE_BOOT;
u8 count;
addr = (u16 *) (CONFIG_SYS_FLASH_BASE + BOOTDATA_OFFSET);
if (*addr == 0xFFFF) {
printf ("*** No bootdata exists. ***\n");
write_bootdata (addr, FAILSAFE_BOOT, 1);
} else {
/* Search for latest written bootdata */
i = 0;
while ((*(addr + 1) != 0xFFFF) & (i < 8000)) {
addr++;
i++;
}
if (i >= 8000) {
/* Whoa, dont write any more */
printf ("*** No bootdata found. Not updating flash***\n");
} else {
/* See how many times we have tried to boot real system */
data = *addr;
system = data >> 8;
count = data & 0xFF;
if ((system != SYSTEM_BOOT) &
(system != SYSTEM2_BOOT) &
(system != FAILSAFE_BOOT)) {
printf ("*** Wrong system %d\n", system);
system = FAILSAFE_BOOT;
count = 1;
} else {
switch (count) {
case 0:
case 1:
case 2:
case 3:
case 4:
/* Try same system again if needed */
count++;
break;
case 5:
/* Switch system and reset tries */
count = 1;
system = switch_system(system);
printf ("***Too many boot attempts, switching system***\n");
break;
default:
/* Switch system, start over and hope it works */
printf ("***Unexpected data on addr 0x%x, %u***\n",
(u32) addr, data);
count = 1;
system = switch_system(system);
}
}
write_bootdata (addr + 1, system, count);
}
}
switch(system){
case FAILSAFE_BOOT:
printf ("Booting failsafe system\n");
setenv ("bootargs", "panic=1 root=/dev/hda7");
setenv ("bootcmd", "ide reset;disk 0x81000000 0:5;run addmisc;bootm");
break;
case SYSTEM_BOOT:
printf ("Using normal system\n");
setenv ("bootargs", "panic=1 root=/dev/hda4");
setenv ("bootcmd", "ide reset;disk 0x81000000 0:2;run addmisc;bootm");
break;
case SYSTEM2_BOOT:
printf ("Using normal system2\n");
setenv ("bootargs", "panic=1 root=/dev/hda9");
setenv ("bootcmd", "ide reset;disk 0x81000000 0:8;run addmisc;bootm");
break;
default:
printf ("Invalid system %d\n", system);
printf ("Hanging\n");
while(1);
}
}
int misc_init_r(void){
u8 Rx[80];
u8 Tx[5];
int page;
int read = 0;
WATCHDOG_RESET();
if (ee_init_cpu_data ()) {
printf ("EEPROM init failed\n");
return (0);
}
/* Check which release to boot */
check_boot_tries ();
/* Read the pages where ethernet address is stored */
for (page = EE_USER_PAGE_0; page <= EE_USER_PAGE_0 + 2; page++) {
/* Copy from nvram to scratchpad */
Tx[0] = RECALL_MEMORY;
Tx[1] = page;
if (ee_do_cpu_command (Tx, 2, NULL, 0, 1)) {
printf ("EE user page %d recall failed\n", page);
return (0);
}
Tx[0] = READ_SCRATCHPAD;
if (ee_do_cpu_command (Tx, 2, Rx + read, 9, 1)) {
printf ("EE user page %d read failed\n", page);
return (0);
}
/* Crc in 9:th byte */
if (!ee_crc_ok (Rx + read, 8, *(Rx + read + 8))) {
printf ("EE read failed, page %d. CRC error\n", page);
return (0);
}
read += 8;
}
/* Add eos after eth addr */
Rx[17] = 0;
printf ("Ethernet addr read from eeprom: %s\n\n", Rx);
if ((Rx[2] != ':') |
(Rx[5] != ':') |
(Rx[8] != ':') | (Rx[11] != ':') | (Rx[14] != ':')) {
printf ("*** ethernet addr invalid, using default ***\n");
} else {
setenv ("ethaddr", (char *)Rx);
}
return (0);
}