upstream u-boot with additional patches for our devices/boards: https://lists.denx.de/pipermail/u-boot/2017-March/282789.html (AXP crashes) ; Gbit ethernet patch for some LIME2 revisions ; with SPI flash support
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u-boot/board/mpl/pati/pati.c

618 lines
17 KiB

/*
* (C) Copyright 2003
* Martin Winistoerfer, martinwinistoerfer@gmx.ch.
* Atapted for PATI
* Denis Peter, d.peter@mpl.ch
* 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
*/
/***********************************************************************************
* Bits for the SDRAM controller
* -----------------------------
*
* CAL: CAS Latency. If cleared to 0 (default) the SDRAM controller asserts TA# on
* the 2nd Clock after ACTIVE command (CAS Latency = 2). If set to 1 the SDRAM
* controller asserts TA# on the 3rd Clock after ACTIVE command (CAS Latency = 3).
* RCD: RCD ACTIVE to READ or WRITE Delay (Ras to Cas Delay). If cleared 0 (default)
* tRCD of the SDRAM must equal or less 25ns. If set to 1 tRCD must be equal or less 50ns.
* WREC:Write Recovery. If cleared 0 (default) tWR of the SDRAM must equal or less 25ns.
* If set to 1 tWR must be equal or less 50ns.
* RP: Precharge Command Time. If cleared 0 (default) tRP of the SDRAM must equal or less
* 25ns. If set to 1 tRP must be equal or less 50ns.
* RC: Auto Refresh to Active Time. If cleared 0 (default) tRC of the SDRAM must equal
* or less 75ns. If set to 1 tRC must be equal or less 100ns.
* LMR: Bit to set the Mode Register of the SDRAM. If set, the next access to the SDRAM
* is the Load Mode Register Command.
* IIP: Init in progress. Set to 1 for starting the init sequence
* (Precharge All). As long this bit is set, the Precharge All is still in progress.
* After command has completed, wait at least for 8 refresh (200usec) before proceed.
**********************************************************************************/
#include <common.h>
#include <mpc5xx.h>
#include <devices.h>
#include <pci_ids.h>
#define PLX9056_LOC
#include "plx9056.h"
#include "pati.h"
#if defined(__APPLE__)
/* Leading underscore on symbols */
# define SYM_CHAR "_"
#else /* No leading character on symbols */
# define SYM_CHAR
#endif
#undef SDRAM_DEBUG
/*
* Macros to generate global absolutes.
*/
#define GEN_SYMNAME(str) SYM_CHAR #str
#define GEN_VALUE(str) #str
#define GEN_ABS(name, value) \
asm (".globl " GEN_SYMNAME(name)); \
asm (GEN_SYMNAME(name) " = " GEN_VALUE(value))
/************************************************************************
* Early debug routines
*/
void write_hex (unsigned char i)
{
char cc;
cc = i >> 4;
cc &= 0xf;
if (cc > 9)
serial_putc (cc + 55);
else
serial_putc (cc + 48);
cc = i & 0xf;
if (cc > 9)
serial_putc (cc + 55);
else
serial_putc (cc + 48);
}
#if defined(SDRAM_DEBUG)
void write_4hex (unsigned long val)
{
write_hex ((unsigned char) (val >> 24));
write_hex ((unsigned char) (val >> 16));
write_hex ((unsigned char) (val >> 8));
write_hex ((unsigned char) val);
}
#endif
unsigned long in32(unsigned long addr)
{
unsigned long *p=(unsigned long *)addr;
return *p;
}
void out32(unsigned long addr,unsigned long data)
{
unsigned long *p=(unsigned long *)addr;
*p=data;
}
typedef struct {
unsigned short boardtype; /* Board revision and Population Options */
unsigned char cal; /* cas Latency 0:CAL=2 1:CAL=3 */
unsigned char rcd; /* ras to cas delay 0:<25ns 1:<50ns*/
unsigned char wrec; /* write recovery 0:<25ns 1:<50ns */
unsigned char pr; /* Precharge Command Time 0:<25ns 1:<50ns */
unsigned char rc; /* Auto Refresh to Active Time 0:<75ns 1:<100ns */
unsigned char sz; /* log binary => Size = (4MByte<<sz) 5 = 128, 4 = 64, 3 = 32, 2 = 16, 1=8 */
} sdram_t;
const sdram_t sdram_table[] = {
{ 0x0000, /* PATI Rev A, 16MByte -1 Board */
1, /* Case Latenty = 3 */
0, /* ras to cas delay 0 (20ns) */
0, /* write recovery 0:<25ns 1:<50ns*/
0, /* Precharge Command Time 0 (20ns) */
0, /* Auto Refresh to Active Time 0 (68) */
2 /* log binary => Size 2 = 16MByte, 1=8 */
},
{ 0xffff, /* terminator */
0xff,
0xff,
0xff,
0xff,
0xff,
0xff }
};
extern int mem_test (unsigned long start, unsigned long ramsize, int quiet);
extern void mem_test_reloc(void);
/*
* Get RAM size.
*/
long int initdram(int board_type)
{
unsigned char board_rev;
unsigned long reg;
unsigned long lmr;
int i,timeout;
#if defined(SDRAM_DEBUG)
reg=in32(PLD_CONFIG_BASE+PLD_PART_ID);
puts("\n\nSYSTEM part 0x"); write_4hex(SYSCNTR_PART(reg));
puts(" Vers 0x"); write_4hex(SYSCNTR_ID(reg));
puts("\nSDRAM part 0x"); write_4hex(SDRAM_PART(reg));
puts(" Vers 0x"); write_4hex(SDRAM_ID(reg));
reg=in32(PLD_CONFIG_BASE+PLD_BOARD_TIMING);
puts("\nBoard rev. 0x"); write_4hex(SYSCNTR_BREV(reg));
putc('\n');
#endif
reg=in32(PLD_CONFIG_BASE+PLD_BOARD_TIMING);
board_rev=(unsigned char)(SYSCNTR_BREV(reg));
i=0;
while(1) {
if(sdram_table[i].boardtype==0xffff) {
puts("ERROR, found no table for Board 0x");
write_hex(board_rev);
while(1);
}
if(sdram_table[i].boardtype==(unsigned char)board_rev)
break;
i++;
}
/* Set CAL, RCD, WREQ, PR and RC Bits */
#if defined(SDRAM_DEBUG)
puts("Set CAL, RCD, WREQ, PR and RC Bits\n");
#endif
/* mask bits */
reg &= ~(SET_REG_BIT(1,SDRAM_CAL) | SET_REG_BIT(1,SDRAM_RCD) | SET_REG_BIT(1,SDRAM_WREQ) |
SET_REG_BIT(1,SDRAM_PR) | SET_REG_BIT(1,SDRAM_RC) | SET_REG_BIT(1,SDRAM_LMR) |
SET_REG_BIT(1,SDRAM_IIP) | SET_REG_BIT(1,SDRAM_RES0));
/* set bits */
reg |= (SET_REG_BIT(sdram_table[i].cal,SDRAM_CAL) |
SET_REG_BIT(sdram_table[i].rcd,SDRAM_RCD) |
SET_REG_BIT(sdram_table[i].wrec,SDRAM_WREQ) |
SET_REG_BIT(sdram_table[i].pr,SDRAM_PR) |
SET_REG_BIT(sdram_table[i].rc,SDRAM_RC));
out32(PLD_CONFIG_BASE+PLD_BOARD_TIMING,reg);
/* step 2 set IIP */
#if defined(SDRAM_DEBUG)
puts("step 2 set IIP\n");
#endif
/* step 2 set IIP */
reg |= SET_REG_BIT(1,SDRAM_IIP);
timeout=0;
while (timeout!=0xffff) {
__asm__ volatile("eieio");
reg=in32(PLD_CONFIG_BASE+PLD_BOARD_TIMING);
if((reg & SET_REG_BIT(1,SDRAM_IIP))==0)
break;
timeout++;
udelay(1);
}
/* wait for at least 8 refresh */
udelay(1000);
/* set LMR */
reg |= SET_REG_BIT(1,SDRAM_LMR);
out32(PLD_CONFIG_BASE+PLD_BOARD_TIMING,reg);
__asm__ volatile("eieio");
lmr=0x00000002; /* sequential burst 4 data */
if(sdram_table[i].cal==1)
lmr|=0x00000030; /* cal = 3 */
else
lmr|=0000000020; /* cal = 2 */
/* rest standard operation programmed write burst length */
/* we have a x32 bit bus to the SDRAM, so shift the addr with 2 */
lmr<<=2;
in32(CFG_SDRAM_BASE + lmr);
/* ok, we're done, return SDRAM size */
return ((0x400000 << sdram_table[i].sz)); /* log2 value of 4MByte */
}
void set_flash_vpp(int ext_vpp, int ext_wp, int int_vpp)
{
unsigned long reg;
reg=in32(PLD_CONF_REG2+PLD_CONFIG_BASE);
reg &= ~(SET_REG_BIT(1,SYSCNTR_CPU_VPP) |
SET_REG_BIT(1,SYSCNTR_FL_VPP) |
SET_REG_BIT(1,SYSCNTR_FL_WP));
reg |= (SET_REG_BIT(int_vpp,SYSCNTR_CPU_VPP) |
SET_REG_BIT(ext_vpp,SYSCNTR_FL_VPP) |
SET_REG_BIT(ext_wp,SYSCNTR_FL_WP));
out32(PLD_CONF_REG2+PLD_CONFIG_BASE,reg);
udelay(100);
}
void show_pld_regs(void)
{
unsigned long reg,reg1;
reg=in32(PLD_CONFIG_BASE+PLD_PART_ID);
printf("\nSYSTEM part %ld, Vers %ld\n",SYSCNTR_PART(reg),SYSCNTR_ID(reg));
printf("SDRAM part %ld, Vers %ld\n",SDRAM_PART(reg),SDRAM_ID(reg));
reg=in32(PLD_CONFIG_BASE+PLD_BOARD_TIMING);
printf("Board rev. %c\n",(char) (SYSCNTR_BREV(reg)+'A'));
printf("Waitstates %ld\n",GET_SYSCNTR_FLWAIT(reg));
printf("SDRAM: CAL=%ld RCD=%ld WREQ=%ld PR=%ld\n RC=%ld LMR=%ld IIP=%ld\n",
GET_REG_BIT(reg,SDRAM_CAL),GET_REG_BIT(reg,SDRAM_RCD),
GET_REG_BIT(reg,SDRAM_WREQ),GET_REG_BIT(reg,SDRAM_PR),
GET_REG_BIT(reg,SDRAM_RC),GET_REG_BIT(reg,SDRAM_LMR),
GET_REG_BIT(reg,SDRAM_IIP));
reg=in32(PLD_CONFIG_BASE+PLD_CONF_REG1);
reg1=in32(PLD_CONFIG_BASE+PLD_CONF_REG2);
printf("HW Config: FLAG=%ld IP=%ld index=%ld PRPM=%ld\n ICW=%ld ISB=%ld BDIS=%ld PCIM=%ld\n",
GET_REG_BIT(reg,SYSCNTR_FLAG),GET_REG_BIT(reg,SYSCNTR_IP),
GET_SYSCNTR_BOOTIND(reg),GET_REG_BIT(reg,SYSCNTR_PRM),
GET_REG_BIT(reg,SYSCNTR_ICW),GET_SYSCNTR_ISB(reg),
GET_REG_BIT(reg1,SYSCNTR_BDIS),GET_REG_BIT(reg1,SYSCNTR_PCIM));
printf("Switches: MUX=%ld PCI_DIS=%ld Boot_EN=%ld Config=%ld\n",GET_SDRAM_MUX(reg),
GET_REG_BIT(reg,SDRAM_PDIS),GET_REG_BIT(reg1,SYSCNTR_BOOTEN),
GET_SYSCNTR_CFG(reg1));
printf("Misc: RIP=%ld CPU_VPP=%ld FLSH_VPP=%ld FLSH_WP=%ld\n\n",
GET_REG_BIT(reg,SDRAM_RIP),GET_REG_BIT(reg1,SYSCNTR_CPU_VPP),
GET_REG_BIT(reg1,SYSCNTR_FL_VPP),GET_REG_BIT(reg1,SYSCNTR_FL_WP));
}
/****************************************************************
* Setting IOs
* -----------
* GPIO6 is User LED1
* GPIO7 is Interrupt PLX (Output)
* GPIO5 is User LED0
* GPIO2 is PLX USERi (Output)
* GPIO1 is PLX Interrupt (Input)
****************************************************************/
void init_ios(void)
{
volatile immap_t * immr = (immap_t *) CFG_IMMR;
volatile sysconf5xx_t *sysconf = &immr->im_siu_conf;
unsigned long reg;
reg=sysconf->sc_sgpiocr; /* Data direction register */
reg &= ~0x67000000;
reg |= 0x27000000; /* set outpupts */
sysconf->sc_sgpiocr=reg; /* Data direction register */
reg=sysconf->sc_sgpiodt2; /* Data register */
/* set output to 0 */
reg &= ~0x27000000;
/* set IRQ and USERi to 1 */
reg |= 0x28000000;
sysconf->sc_sgpiodt2=reg; /* Data register */
}
void user_led0(int led_on)
{
volatile immap_t * immr = (immap_t *) CFG_IMMR;
volatile sysconf5xx_t *sysconf = &immr->im_siu_conf;
unsigned long reg;
reg=sysconf->sc_sgpiodt2; /* Data register */
if(led_on) /* set output to 1 */
reg |= 0x04000000;
else
reg &= ~0x04000000;
sysconf->sc_sgpiodt2=reg; /* Data register */
}
void user_led1(int led_on)
{
volatile immap_t * immr = (immap_t *) CFG_IMMR;
volatile sysconf5xx_t *sysconf = &immr->im_siu_conf;
unsigned long reg;
reg=sysconf->sc_sgpiodt2; /* Data register */
if(led_on) /* set output to 1 */
reg |= 0x02000000;
else
reg &= ~0x02000000;
sysconf->sc_sgpiodt2=reg; /* Data register */
}
/****************************************************************
* Last Stage Init
****************************************************************/
int last_stage_init (void)
{
mem_test_reloc();
init_ios();
return 0;
}
/****************************************************************
* Check the board
****************************************************************/
#define BOARD_NAME "PATI"
int checkboard (void)
{
unsigned char s[50];
unsigned long reg;
char rev;
int i;
puts ("\nBoard: ");
reg=in32(PLD_CONFIG_BASE+PLD_BOARD_TIMING);
rev=(char)(SYSCNTR_BREV(reg)+'A');
i = getenv_r ("serial#", s, 32);
if ((i == -1)) {
puts ("### No HW ID - assuming " BOARD_NAME);
printf(" Rev. %c\n",rev);
}
else {
s[sizeof(BOARD_NAME)-1] = 0;
printf ("%s-1 Rev %c SN: %s\n", s,rev,
&s[sizeof(BOARD_NAME)]);
}
set_flash_vpp(1,0,0); /* set Flash VPP */
return 0;
}
#ifdef CFG_PCI_CON_DEVICE
/************************************************************************
* PCI Communication
*
* Alive (Pinging):
* ----------------
* PCI Host sends message ALIVE, Local acknowledges with ALIVE
*
* PCI_CON console over PCI:
* -------------------------
* Local side:
* - uses PCI9056_LOC_TO_PCI_DBELL register to signal that
* data is avaible (PCIMSG_CONN)
* - uses PCI9056_MAILBOX1 to send data
* - uses PCI9056_MAILBOX0 to receive data
* PCI side:
* - uses PCI9056_PCI_TO_LOC_DBELL register to signal that
* data is avaible (PCIMSG_CONN)
* - uses PCI9056_MAILBOX0 to send data
* - uses PCI9056_MAILBOX1 to receive data
*
* How it works:
* Send:
* - check if PCICON_TRANSMIT_REG is empty
* - write data or'ed with 0x80000000 into the PCICON_TRANSMIT_REG
* - write PCIMSG_CONN into the PCICON_DBELL_REG to signal a data
* is waiting
* Receive:
* - get an interrupt via the PCICON_ACK_REG register message
* PCIMSG_CONN
* - write the data from the PCICON_RECEIVE_REG into the receive
* buffer and if the receive buffer is not full, clear the
* PCICON_RECEIVE_REG (this allows the counterpart to write more data)
* - Clear the interrupt by writing 0xFFFFFFFF to the PCICON_ACK_REG
*
* The PCICON_RECEIVE_REG must be cleared by the routine which reads
* the receive buffer if the buffer is not full any more
*
*/
#undef PCI_CON_DEBUG
#ifdef PCI_CON_DEBUG
#define PCI_CON_PRINTF(fmt,args...) serial_printf (fmt ,##args)
#else
#define PCI_CON_PRINTF(fmt,args...)
#endif
/*********************************************************
* we work only with a receive buffer on eiter side.
* Transmit buffer is free, if mailbox is cleared.
* Transmit character is or'ed with 0x80000000
* PATI receive register MAILBOX0
* PATI transmit register MAILBOX1
*********************************************************/
#define PCICON_RECEIVE_REG PCI9056_MAILBOX0
#define PCICON_TRANSMIT_REG PCI9056_MAILBOX1
#define PCICON_DBELL_REG PCI9056_LOC_TO_PCI_DBELL
#define PCICON_ACK_REG PCI9056_PCI_TO_LOC_DBELL
#define PCIMSG_ALIVE 0x1
#define PCIMSG_CONN 0x2
#define PCIMSG_DISC 0x3
#define PCIMSG_CON_DATA 0x5
#define PCICON_GET_REG(x) (in32(x + PCI_CONFIG_BASE))
#define PCICON_SET_REG(x,y) (out32(x + PCI_CONFIG_BASE,y))
#define PCICON_TX_FLAG 0x80000000
#define REC_BUFFER_SIZE 0x100
int recbuf[REC_BUFFER_SIZE];
static int r_ptr = 0;
int w_ptr;
device_t pci_con_dev;
int conn=0;
int buff_full=0;
void pci_con_put_it(const char c)
{
/* Test for completition */
unsigned long reg;
do {
reg=PCICON_GET_REG(PCICON_TRANSMIT_REG);
}while(reg);
reg=PCICON_TX_FLAG + c;
PCICON_SET_REG(PCICON_TRANSMIT_REG,reg);
PCICON_SET_REG(PCICON_DBELL_REG,PCIMSG_CON_DATA);
}
void pci_con_putc(const char c)
{
pci_con_put_it(c);
if(c == '\n')
pci_con_put_it('\r');
}
int pci_con_getc(void)
{
int res;
int diff;
while(r_ptr==(volatile int)w_ptr);
res=recbuf[r_ptr++];
if(r_ptr==REC_BUFFER_SIZE)
r_ptr=0;
if(w_ptr<r_ptr)
diff=r_ptr+REC_BUFFER_SIZE-w_ptr;
else
diff=r_ptr-w_ptr;
if((diff<(REC_BUFFER_SIZE-4)) && buff_full) {
/* clear Mail box */
buff_full=0;
PCICON_SET_REG(PCICON_RECEIVE_REG,0L);
}
return res;
}
int pci_con_tstc(void)
{
if(r_ptr==(volatile int)w_ptr)
return 0;
return 1;
}
void pci_con_puts (const char *s)
{
while (*s) {
pci_con_putc(*s);
++s;
}
}
void pci_con_init (void)
{
w_ptr = 0;
r_ptr = 0;
PCICON_SET_REG(PCICON_RECEIVE_REG,0L);
conn=1;
}
/*******************************************
* IRQ routine
******************************************/
int pci_dorbell_irq(void)
{
unsigned long reg,data;
int diff;
reg=PCICON_GET_REG(PCI9056_INT_CTRL_STAT);
PCI_CON_PRINTF(" PCI9056_INT_CTRL_STAT = %08lX\n",reg);
if(reg & (1<<20) ) {
/* read doorbell */
reg=PCICON_GET_REG(PCICON_ACK_REG);
switch(reg) {
case PCIMSG_ALIVE:
PCI_CON_PRINTF(" Alive\n");
PCICON_SET_REG(PCICON_DBELL_REG,PCIMSG_ALIVE);
break;
case PCIMSG_CONN:
PCI_CON_PRINTF(" Conn %d",conn);
w_ptr = 0;
r_ptr = 0;
buff_full=0;
PCICON_SET_REG(PCICON_RECEIVE_REG,0L);
conn=1;
PCI_CON_PRINTF(" ... %d\n",conn);
break;
case PCIMSG_CON_DATA:
data=PCICON_GET_REG(PCICON_RECEIVE_REG);
recbuf[w_ptr++]=(int)(data&0xff);
PCI_CON_PRINTF(" Data Console %lX, %X %d %d %X\n",data,((int)(data&0xFF)),
r_ptr,w_ptr,recbuf[w_ptr-1]);
if(w_ptr==REC_BUFFER_SIZE)
w_ptr=0;
if(w_ptr<r_ptr)
diff=r_ptr+REC_BUFFER_SIZE-w_ptr;
else
diff=r_ptr-w_ptr;
if(diff>(REC_BUFFER_SIZE-4))
buff_full=1;
else
/* clear Mail box */
PCICON_SET_REG(PCICON_RECEIVE_REG,0L);
break;
default:
serial_printf(" PCI9056_PCI_TO_LOC_DBELL = %08lX\n",reg);
}
/* clear IRQ */
PCICON_SET_REG(PCICON_ACK_REG,~0L);
}
return 0;
}
void pci_con_connect(void)
{
unsigned long reg;
conn=0;
reg=PCICON_GET_REG(PCI9056_INT_CTRL_STAT);
/* default 0x0f010180 */
reg &= 0xff000000;
reg |= 0x00030000; /* enable local dorbell */
reg |= 0x00000300; /* enable PCI dorbell */
PCICON_SET_REG(PCI9056_INT_CTRL_STAT , reg);
irq_install_handler (0x2, (interrupt_handler_t *) pci_dorbell_irq,NULL);
memset (&pci_con_dev, 0, sizeof (pci_con_dev));
strcpy (pci_con_dev.name, "pci_con");
pci_con_dev.flags = DEV_FLAGS_OUTPUT | DEV_FLAGS_INPUT | DEV_FLAGS_SYSTEM;
pci_con_dev.putc = pci_con_putc;
pci_con_dev.puts = pci_con_puts;
pci_con_dev.getc = pci_con_getc;
pci_con_dev.tstc = pci_con_tstc;
device_register (&pci_con_dev);
printf("PATI ready for PCI connection, type ctrl-c for exit\n");
do {
udelay(10);
if((volatile int)conn)
break;
if(ctrlc()) {
irq_free_handler(0x2);
return;
}
}while(1);
console_assign(stdin,"pci_con");
console_assign(stderr,"pci_con");
console_assign(stdout,"pci_con");
}
void pci_con_disc(void)
{
console_assign(stdin,"serial");
console_assign(stderr,"serial");
console_assign(stdout,"serial");
PCICON_SET_REG(PCICON_DBELL_REG,PCIMSG_DISC);
/* reconnection */
irq_free_handler(0x02);
pci_con_connect();
}
#endif /* #ifdef CFG_PCI_CON_DEVICE */
/*
* Absolute environment address for linker file.
*/
GEN_ABS(env_start, CFG_ENV_OFFSET + CFG_FLASH_BASE);