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u-boot-brain/cpu/ppc4xx/44x_spd_ddr2.c
Felix Radensky 48e2b535a0 4xx: Fix compilation warnings and MQ registers dump in SPD DDR2 code 
This patch fixes printf format string compilation warnings in several
debug statements. It also fixes the dump of DDR controller MQ registers
found on some 44x and 46x platforms. The current register dump code
uses incorrect DCRs to access these registers.

Signed-off-by: Felix Radensky <felix@embedded-sol.com>
Signed-off-by: Stefan Roese <sr@denx.de>
2009-07-08 10:59:07 +02:00

3285 lines
102 KiB
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/*
* cpu/ppc4xx/44x_spd_ddr2.c
* This SPD SDRAM detection code supports AMCC PPC44x cpu's with a
* DDR2 controller (non Denali Core). Those currently are:
*
* 405: 405EX(r)
* 440/460: 440SP/440SPe/460EX/460GT
*
* Copyright (c) 2008 Nuovation System Designs, LLC
* Grant Erickson <gerickson@nuovations.com>
* (C) Copyright 2007-2008
* Stefan Roese, DENX Software Engineering, sr@denx.de.
*
* COPYRIGHT AMCC CORPORATION 2004
*
* 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
*
*/
/* define DEBUG for debugging output (obviously ;-)) */
#if 0
#define DEBUG
#endif
#include <common.h>
#include <command.h>
#include <ppc4xx.h>
#include <i2c.h>
#include <asm/io.h>
#include <asm/processor.h>
#include <asm/mmu.h>
#include <asm/cache.h>
#include "ecc.h"
#if defined(CONFIG_SDRAM_PPC4xx_IBM_DDR2)
#define PPC4xx_IBM_DDR2_DUMP_REGISTER(mnemonic) \
do { \
u32 data; \
mfsdram(SDRAM_##mnemonic, data); \
printf("%20s[%02x] = 0x%08X\n", \
"SDRAM_" #mnemonic, SDRAM_##mnemonic, data); \
} while (0)
#define PPC4xx_IBM_DDR2_DUMP_MQ_REGISTER(mnemonic) \
do { \
u32 data; \
data = mfdcr(SDRAM_##mnemonic); \
printf("%20s[%02x] = 0x%08X\n", \
"SDRAM_" #mnemonic, SDRAM_##mnemonic, data); \
} while (0)
#if defined(CONFIG_440)
/*
* This DDR2 setup code can dynamically setup the TLB entries for the DDR2
* memory region. Right now the cache should still be disabled in U-Boot
* because of the EMAC driver, that need its buffer descriptor to be located
* in non cached memory.
*
* If at some time this restriction doesn't apply anymore, just define
* CONFIG_4xx_DCACHE in the board config file and this code should setup
* everything correctly.
*/
#ifdef CONFIG_4xx_DCACHE
/* enable caching on SDRAM */
#define MY_TLB_WORD2_I_ENABLE 0
#else
/* disable caching on SDRAM */
#define MY_TLB_WORD2_I_ENABLE TLB_WORD2_I_ENABLE
#endif /* CONFIG_4xx_DCACHE */
#endif /* CONFIG_440 */
#if defined(CONFIG_SPD_EEPROM)
/*-----------------------------------------------------------------------------+
* Defines
*-----------------------------------------------------------------------------*/
#ifndef TRUE
#define TRUE 1
#endif
#ifndef FALSE
#define FALSE 0
#endif
#define SDRAM_DDR1 1
#define SDRAM_DDR2 2
#define SDRAM_NONE 0
#define MAXDIMMS 2
#define MAXRANKS 4
#define MAXBXCF 4
#define MAX_SPD_BYTES 256 /* Max number of bytes on the DIMM's SPD EEPROM */
#define ONE_BILLION 1000000000
#define MULDIV64(m1, m2, d) (u32)(((u64)(m1) * (u64)(m2)) / (u64)(d))
#define CMD_NOP (7 << 19)
#define CMD_PRECHARGE (2 << 19)
#define CMD_REFRESH (1 << 19)
#define CMD_EMR (0 << 19)
#define CMD_READ (5 << 19)
#define CMD_WRITE (4 << 19)
#define SELECT_MR (0 << 16)
#define SELECT_EMR (1 << 16)
#define SELECT_EMR2 (2 << 16)
#define SELECT_EMR3 (3 << 16)
/* MR */
#define DLL_RESET 0x00000100
#define WRITE_RECOV_2 (1 << 9)
#define WRITE_RECOV_3 (2 << 9)
#define WRITE_RECOV_4 (3 << 9)
#define WRITE_RECOV_5 (4 << 9)
#define WRITE_RECOV_6 (5 << 9)
#define BURST_LEN_4 0x00000002
/* EMR */
#define ODT_0_OHM 0x00000000
#define ODT_50_OHM 0x00000044
#define ODT_75_OHM 0x00000004
#define ODT_150_OHM 0x00000040
#define ODS_FULL 0x00000000
#define ODS_REDUCED 0x00000002
#define OCD_CALIB_DEF 0x00000380
/* defines for ODT (On Die Termination) of the 440SP(e) DDR2 controller */
#define ODT_EB0R (0x80000000 >> 8)
#define ODT_EB0W (0x80000000 >> 7)
#define CALC_ODT_R(n) (ODT_EB0R << (n << 1))
#define CALC_ODT_W(n) (ODT_EB0W << (n << 1))
#define CALC_ODT_RW(n) (CALC_ODT_R(n) | CALC_ODT_W(n))
/* Defines for the Read Cycle Delay test */
#define NUMMEMTESTS 8
#define NUMMEMWORDS 8
#define NUMLOOPS 64 /* memory test loops */
/*
* Newer PPC's like 440SPe, 460EX/GT can be equipped with more than 2GB of SDRAM.
* To support such configurations, we "only" map the first 2GB via the TLB's. We
* need some free virtual address space for the remaining peripherals like, SoC
* devices, FLASH etc.
*
* Note that ECC is currently not supported on configurations with more than 2GB
* SDRAM. This is because we only map the first 2GB on such systems, and therefore
* the ECC parity byte of the remaining area can't be written.
*/
/*
* Board-specific Platform code can reimplement spd_ddr_init_hang () if needed
*/
void __spd_ddr_init_hang (void)
{
hang ();
}
void spd_ddr_init_hang (void) __attribute__((weak, alias("__spd_ddr_init_hang")));
/*
* To provide an interface for board specific config values in this common
* DDR setup code, we implement he "weak" default functions here. They return
* the default value back to the caller.
*
* Please see include/configs/yucca.h for an example fora board specific
* implementation.
*/
u32 __ddr_wrdtr(u32 default_val)
{
return default_val;
}
u32 ddr_wrdtr(u32) __attribute__((weak, alias("__ddr_wrdtr")));
u32 __ddr_clktr(u32 default_val)
{
return default_val;
}
u32 ddr_clktr(u32) __attribute__((weak, alias("__ddr_clktr")));
/* Private Structure Definitions */
/* enum only to ease code for cas latency setting */
typedef enum ddr_cas_id {
DDR_CAS_2 = 20,
DDR_CAS_2_5 = 25,
DDR_CAS_3 = 30,
DDR_CAS_4 = 40,
DDR_CAS_5 = 50
} ddr_cas_id_t;
/*-----------------------------------------------------------------------------+
* Prototypes
*-----------------------------------------------------------------------------*/
static phys_size_t sdram_memsize(void);
static void get_spd_info(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void check_mem_type(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void check_frequency(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void check_rank_number(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void check_voltage_type(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void program_memory_queue(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void program_codt(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void program_mode(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks,
ddr_cas_id_t *selected_cas,
int *write_recovery);
static void program_tr(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void program_rtr(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void program_bxcf(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void program_copt1(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
static void program_initplr(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks,
ddr_cas_id_t selected_cas,
int write_recovery);
static unsigned long is_ecc_enabled(void);
#ifdef CONFIG_DDR_ECC
static void program_ecc(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks,
unsigned long tlb_word2_i_value);
static void program_ecc_addr(unsigned long start_address,
unsigned long num_bytes,
unsigned long tlb_word2_i_value);
#endif
#if !defined(CONFIG_PPC4xx_DDR_AUTOCALIBRATION)
static void program_DQS_calibration(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks);
#ifdef HARD_CODED_DQS /* calibration test with hardvalues */
static void test(void);
#else
static void DQS_calibration_process(void);
#endif
#endif
int do_reset (cmd_tbl_t *cmdtp, int flag, int argc, char *argv[]);
void dcbz_area(u32 start_address, u32 num_bytes);
static unsigned char spd_read(uchar chip, uint addr)
{
unsigned char data[2];
if (i2c_probe(chip) == 0)
if (i2c_read(chip, addr, 1, data, 1) == 0)
return data[0];
return 0;
}
/*-----------------------------------------------------------------------------+
* sdram_memsize
*-----------------------------------------------------------------------------*/
static phys_size_t sdram_memsize(void)
{
phys_size_t mem_size;
unsigned long mcopt2;
unsigned long mcstat;
unsigned long mb0cf;
unsigned long sdsz;
unsigned long i;
mem_size = 0;
mfsdram(SDRAM_MCOPT2, mcopt2);
mfsdram(SDRAM_MCSTAT, mcstat);
/* DDR controller must be enabled and not in self-refresh. */
/* Otherwise memsize is zero. */
if (((mcopt2 & SDRAM_MCOPT2_DCEN_MASK) == SDRAM_MCOPT2_DCEN_ENABLE)
&& ((mcopt2 & SDRAM_MCOPT2_SREN_MASK) == SDRAM_MCOPT2_SREN_EXIT)
&& ((mcstat & (SDRAM_MCSTAT_MIC_MASK | SDRAM_MCSTAT_SRMS_MASK))
== (SDRAM_MCSTAT_MIC_COMP | SDRAM_MCSTAT_SRMS_NOT_SF))) {
for (i = 0; i < MAXBXCF; i++) {
mfsdram(SDRAM_MB0CF + (i << 2), mb0cf);
/* Banks enabled */
if ((mb0cf & SDRAM_BXCF_M_BE_MASK) == SDRAM_BXCF_M_BE_ENABLE) {
sdsz = mfdcr_any(SDRAM_R0BAS + i) & SDRAM_RXBAS_SDSZ_MASK;
switch(sdsz) {
case SDRAM_RXBAS_SDSZ_8:
mem_size+=8;
break;
case SDRAM_RXBAS_SDSZ_16:
mem_size+=16;
break;
case SDRAM_RXBAS_SDSZ_32:
mem_size+=32;
break;
case SDRAM_RXBAS_SDSZ_64:
mem_size+=64;
break;
case SDRAM_RXBAS_SDSZ_128:
mem_size+=128;
break;
case SDRAM_RXBAS_SDSZ_256:
mem_size+=256;
break;
case SDRAM_RXBAS_SDSZ_512:
mem_size+=512;
break;
case SDRAM_RXBAS_SDSZ_1024:
mem_size+=1024;
break;
case SDRAM_RXBAS_SDSZ_2048:
mem_size+=2048;
break;
case SDRAM_RXBAS_SDSZ_4096:
mem_size+=4096;
break;
default:
printf("WARNING: Unsupported bank size (SDSZ=0x%lx)!\n"
, sdsz);
mem_size=0;
break;
}
}
}
}
return mem_size << 20;
}
/*-----------------------------------------------------------------------------+
* initdram. Initializes the 440SP Memory Queue and DDR SDRAM controller.
* Note: This routine runs from flash with a stack set up in the chip's
* sram space. It is important that the routine does not require .sbss, .bss or
* .data sections. It also cannot call routines that require these sections.
*-----------------------------------------------------------------------------*/
/*-----------------------------------------------------------------------------
* Function: initdram
* Description: Configures SDRAM memory banks for DDR operation.
* Auto Memory Configuration option reads the DDR SDRAM EEPROMs
* via the IIC bus and then configures the DDR SDRAM memory
* banks appropriately. If Auto Memory Configuration is
* not used, it is assumed that no DIMM is plugged
*-----------------------------------------------------------------------------*/
phys_size_t initdram(int board_type)
{
unsigned char iic0_dimm_addr[] = SPD_EEPROM_ADDRESS;
unsigned char spd0[MAX_SPD_BYTES];
unsigned char spd1[MAX_SPD_BYTES];
unsigned char *dimm_spd[MAXDIMMS];
unsigned long dimm_populated[MAXDIMMS];
unsigned long num_dimm_banks; /* on board dimm banks */
unsigned long val;
ddr_cas_id_t selected_cas = DDR_CAS_5; /* preset to silence compiler */
int write_recovery;
phys_size_t dram_size = 0;
num_dimm_banks = sizeof(iic0_dimm_addr);
/*------------------------------------------------------------------
* Set up an array of SPD matrixes.
*-----------------------------------------------------------------*/
dimm_spd[0] = spd0;
dimm_spd[1] = spd1;
/*------------------------------------------------------------------
* Reset the DDR-SDRAM controller.
*-----------------------------------------------------------------*/
mtsdr(SDR0_SRST, (0x80000000 >> 10));
mtsdr(SDR0_SRST, 0x00000000);
/*
* Make sure I2C controller is initialized
* before continuing.
*/
/* switch to correct I2C bus */
I2C_SET_BUS(CONFIG_SYS_SPD_BUS_NUM);
i2c_init(CONFIG_SYS_I2C_SPEED, CONFIG_SYS_I2C_SLAVE);
/*------------------------------------------------------------------
* Clear out the serial presence detect buffers.
* Perform IIC reads from the dimm. Fill in the spds.
* Check to see if the dimm slots are populated
*-----------------------------------------------------------------*/
get_spd_info(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Check the memory type for the dimms plugged.
*-----------------------------------------------------------------*/
check_mem_type(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Check the frequency supported for the dimms plugged.
*-----------------------------------------------------------------*/
check_frequency(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Check the total rank number.
*-----------------------------------------------------------------*/
check_rank_number(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Check the voltage type for the dimms plugged.
*-----------------------------------------------------------------*/
check_voltage_type(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Program SDRAM controller options 2 register
* Except Enabling of the memory controller.
*-----------------------------------------------------------------*/
mfsdram(SDRAM_MCOPT2, val);
mtsdram(SDRAM_MCOPT2,
(val &
~(SDRAM_MCOPT2_SREN_MASK | SDRAM_MCOPT2_PMEN_MASK |
SDRAM_MCOPT2_IPTR_MASK | SDRAM_MCOPT2_XSRP_MASK |
SDRAM_MCOPT2_ISIE_MASK))
| (SDRAM_MCOPT2_SREN_ENTER | SDRAM_MCOPT2_PMEN_DISABLE |
SDRAM_MCOPT2_IPTR_IDLE | SDRAM_MCOPT2_XSRP_ALLOW |
SDRAM_MCOPT2_ISIE_ENABLE));
/*------------------------------------------------------------------
* Program SDRAM controller options 1 register
* Note: Does not enable the memory controller.
*-----------------------------------------------------------------*/
program_copt1(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Set the SDRAM Controller On Die Termination Register
*-----------------------------------------------------------------*/
program_codt(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Program SDRAM refresh register.
*-----------------------------------------------------------------*/
program_rtr(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Program SDRAM mode register.
*-----------------------------------------------------------------*/
program_mode(dimm_populated, iic0_dimm_addr, num_dimm_banks,
&selected_cas, &write_recovery);
/*------------------------------------------------------------------
* Set the SDRAM Write Data/DM/DQS Clock Timing Reg
*-----------------------------------------------------------------*/
mfsdram(SDRAM_WRDTR, val);
mtsdram(SDRAM_WRDTR, (val & ~(SDRAM_WRDTR_LLWP_MASK | SDRAM_WRDTR_WTR_MASK)) |
ddr_wrdtr(SDRAM_WRDTR_LLWP_1_CYC | SDRAM_WRDTR_WTR_90_DEG_ADV));
/*------------------------------------------------------------------
* Set the SDRAM Clock Timing Register
*-----------------------------------------------------------------*/
mfsdram(SDRAM_CLKTR, val);
mtsdram(SDRAM_CLKTR, (val & ~SDRAM_CLKTR_CLKP_MASK) |
ddr_clktr(SDRAM_CLKTR_CLKP_0_DEG));
/*------------------------------------------------------------------
* Program the BxCF registers.
*-----------------------------------------------------------------*/
program_bxcf(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Program SDRAM timing registers.
*-----------------------------------------------------------------*/
program_tr(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Set the Extended Mode register
*-----------------------------------------------------------------*/
mfsdram(SDRAM_MEMODE, val);
mtsdram(SDRAM_MEMODE,
(val & ~(SDRAM_MEMODE_DIC_MASK | SDRAM_MEMODE_DLL_MASK |
SDRAM_MEMODE_RTT_MASK | SDRAM_MEMODE_DQS_MASK)) |
(SDRAM_MEMODE_DIC_NORMAL | SDRAM_MEMODE_DLL_ENABLE
| SDRAM_MEMODE_RTT_150OHM | SDRAM_MEMODE_DQS_ENABLE));
/*------------------------------------------------------------------
* Program Initialization preload registers.
*-----------------------------------------------------------------*/
program_initplr(dimm_populated, iic0_dimm_addr, num_dimm_banks,
selected_cas, write_recovery);
/*------------------------------------------------------------------
* Delay to ensure 200usec have elapsed since reset.
*-----------------------------------------------------------------*/
udelay(400);
/*------------------------------------------------------------------
* Set the memory queue core base addr.
*-----------------------------------------------------------------*/
program_memory_queue(dimm_populated, iic0_dimm_addr, num_dimm_banks);
/*------------------------------------------------------------------
* Program SDRAM controller options 2 register
* Enable the memory controller.
*-----------------------------------------------------------------*/
mfsdram(SDRAM_MCOPT2, val);
mtsdram(SDRAM_MCOPT2,
(val & ~(SDRAM_MCOPT2_SREN_MASK | SDRAM_MCOPT2_DCEN_MASK |
SDRAM_MCOPT2_IPTR_MASK | SDRAM_MCOPT2_ISIE_MASK)) |
SDRAM_MCOPT2_IPTR_EXECUTE);
/*------------------------------------------------------------------
* Wait for IPTR_EXECUTE init sequence to complete.
*-----------------------------------------------------------------*/
do {
mfsdram(SDRAM_MCSTAT, val);
} while ((val & SDRAM_MCSTAT_MIC_MASK) == SDRAM_MCSTAT_MIC_NOTCOMP);
/* enable the controller only after init sequence completes */
mfsdram(SDRAM_MCOPT2, val);
mtsdram(SDRAM_MCOPT2, (val | SDRAM_MCOPT2_DCEN_ENABLE));
/* Make sure delay-line calibration is done before proceeding */
do {
mfsdram(SDRAM_DLCR, val);
} while (!(val & SDRAM_DLCR_DLCS_COMPLETE));
/* get installed memory size */
dram_size = sdram_memsize();
/*
* Limit size to 2GB
*/
if (dram_size > CONFIG_MAX_MEM_MAPPED)
dram_size = CONFIG_MAX_MEM_MAPPED;
/* and program tlb entries for this size (dynamic) */
/*
* Program TLB entries with caches enabled, for best performace
* while auto-calibrating and ECC generation
*/
program_tlb(0, 0, dram_size, 0);
/*------------------------------------------------------------------
* DQS calibration.
*-----------------------------------------------------------------*/
#if defined(CONFIG_PPC4xx_DDR_AUTOCALIBRATION)
DQS_autocalibration();
#else
program_DQS_calibration(dimm_populated, iic0_dimm_addr, num_dimm_banks);
#endif
#ifdef CONFIG_DDR_ECC
/*------------------------------------------------------------------
* If ecc is enabled, initialize the parity bits.
*-----------------------------------------------------------------*/
program_ecc(dimm_populated, iic0_dimm_addr, num_dimm_banks, 0);
#endif
/*
* Now after initialization (auto-calibration and ECC generation)
* remove the TLB entries with caches enabled and program again with
* desired cache functionality
*/
remove_tlb(0, dram_size);
program_tlb(0, 0, dram_size, MY_TLB_WORD2_I_ENABLE);
ppc4xx_ibm_ddr2_register_dump();
/*
* Clear potential errors resulting from auto-calibration.
* If not done, then we could get an interrupt later on when
* exceptions are enabled.
*/
set_mcsr(get_mcsr());
return sdram_memsize();
}
static void get_spd_info(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long dimm_found;
unsigned char num_of_bytes;
unsigned char total_size;
dimm_found = FALSE;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
num_of_bytes = 0;
total_size = 0;
num_of_bytes = spd_read(iic0_dimm_addr[dimm_num], 0);
debug("\nspd_read(0x%x) returned %d\n",
iic0_dimm_addr[dimm_num], num_of_bytes);
total_size = spd_read(iic0_dimm_addr[dimm_num], 1);
debug("spd_read(0x%x) returned %d\n",
iic0_dimm_addr[dimm_num], total_size);
if ((num_of_bytes != 0) && (total_size != 0)) {
dimm_populated[dimm_num] = TRUE;
dimm_found = TRUE;
debug("DIMM slot %lu: populated\n", dimm_num);
} else {
dimm_populated[dimm_num] = FALSE;
debug("DIMM slot %lu: Not populated\n", dimm_num);
}
}
if (dimm_found == FALSE) {
printf("ERROR - No memory installed. Install a DDR-SDRAM DIMM.\n\n");
spd_ddr_init_hang ();
}
}
void board_add_ram_info(int use_default)
{
PPC4xx_SYS_INFO board_cfg;
u32 val;
if (is_ecc_enabled())
puts(" (ECC");
else
puts(" (ECC not");
get_sys_info(&board_cfg);
mfsdr(SDR0_DDR0, val);
val = MULDIV64((board_cfg.freqPLB), SDR0_DDR0_DDRM_DECODE(val), 1);
printf(" enabled, %d MHz", (val * 2) / 1000000);
mfsdram(SDRAM_MMODE, val);
val = (val & SDRAM_MMODE_DCL_MASK) >> 4;
printf(", CL%d)", val);
}
/*------------------------------------------------------------------
* For the memory DIMMs installed, this routine verifies that they
* really are DDR specific DIMMs.
*-----------------------------------------------------------------*/
static void check_mem_type(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long dimm_type;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] == TRUE) {
dimm_type = spd_read(iic0_dimm_addr[dimm_num], 2);
switch (dimm_type) {
case 1:
printf("ERROR: Standard Fast Page Mode DRAM DIMM detected in "
"slot %d.\n", (unsigned int)dimm_num);
printf("Only DDR and DDR2 SDRAM DIMMs are supported.\n");
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
case 2:
printf("ERROR: EDO DIMM detected in slot %d.\n",
(unsigned int)dimm_num);
printf("Only DDR and DDR2 SDRAM DIMMs are supported.\n");
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
case 3:
printf("ERROR: Pipelined Nibble DIMM detected in slot %d.\n",
(unsigned int)dimm_num);
printf("Only DDR and DDR2 SDRAM DIMMs are supported.\n");
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
case 4:
printf("ERROR: SDRAM DIMM detected in slot %d.\n",
(unsigned int)dimm_num);
printf("Only DDR and DDR2 SDRAM DIMMs are supported.\n");
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
case 5:
printf("ERROR: Multiplexed ROM DIMM detected in slot %d.\n",
(unsigned int)dimm_num);
printf("Only DDR and DDR2 SDRAM DIMMs are supported.\n");
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
case 6:
printf("ERROR: SGRAM DIMM detected in slot %d.\n",
(unsigned int)dimm_num);
printf("Only DDR and DDR2 SDRAM DIMMs are supported.\n");
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
case 7:
debug("DIMM slot %lu: DDR1 SDRAM detected\n", dimm_num);
dimm_populated[dimm_num] = SDRAM_DDR1;
break;
case 8:
debug("DIMM slot %lu: DDR2 SDRAM detected\n", dimm_num);
dimm_populated[dimm_num] = SDRAM_DDR2;
break;
default:
printf("ERROR: Unknown DIMM detected in slot %d.\n",
(unsigned int)dimm_num);
printf("Only DDR1 and DDR2 SDRAM DIMMs are supported.\n");
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
}
}
}
for (dimm_num = 1; dimm_num < num_dimm_banks; dimm_num++) {
if ((dimm_populated[dimm_num-1] != SDRAM_NONE)
&& (dimm_populated[dimm_num] != SDRAM_NONE)
&& (dimm_populated[dimm_num-1] != dimm_populated[dimm_num])) {
printf("ERROR: DIMM's DDR1 and DDR2 type can not be mixed.\n");
spd_ddr_init_hang ();
}
}
}
/*------------------------------------------------------------------
* For the memory DIMMs installed, this routine verifies that
* frequency previously calculated is supported.
*-----------------------------------------------------------------*/
static void check_frequency(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long tcyc_reg;
unsigned long cycle_time;
unsigned long calc_cycle_time;
unsigned long sdram_freq;
unsigned long sdr_ddrpll;
PPC4xx_SYS_INFO board_cfg;
/*------------------------------------------------------------------
* Get the board configuration info.
*-----------------------------------------------------------------*/
get_sys_info(&board_cfg);
mfsdr(SDR0_DDR0, sdr_ddrpll);
sdram_freq = ((board_cfg.freqPLB) * SDR0_DDR0_DDRM_DECODE(sdr_ddrpll));
/*
* calc_cycle_time is calculated from DDR frequency set by board/chip
* and is expressed in multiple of 10 picoseconds
* to match the way DIMM cycle time is calculated below.
*/
calc_cycle_time = MULDIV64(ONE_BILLION, 100, sdram_freq);
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
tcyc_reg = spd_read(iic0_dimm_addr[dimm_num], 9);
/*
* Byte 9, Cycle time for CAS Latency=X, is split into two nibbles:
* the higher order nibble (bits 4-7) designates the cycle time
* to a granularity of 1ns;
* the value presented by the lower order nibble (bits 0-3)
* has a granularity of .1ns and is added to the value designated
* by the higher nibble. In addition, four lines of the lower order
* nibble are assigned to support +.25,+.33, +.66 and +.75.
*/
/* Convert from hex to decimal */
if ((tcyc_reg & 0x0F) == 0x0D)
cycle_time = (((tcyc_reg & 0xF0) >> 4) * 100) + 75;
else if ((tcyc_reg & 0x0F) == 0x0C)
cycle_time = (((tcyc_reg & 0xF0) >> 4) * 100) + 66;
else if ((tcyc_reg & 0x0F) == 0x0B)
cycle_time = (((tcyc_reg & 0xF0) >> 4) * 100) + 33;
else if ((tcyc_reg & 0x0F) == 0x0A)
cycle_time = (((tcyc_reg & 0xF0) >> 4) * 100) + 25;
else
cycle_time = (((tcyc_reg & 0xF0) >> 4) * 100) +
((tcyc_reg & 0x0F)*10);
debug("cycle_time=%lu [10 picoseconds]\n", cycle_time);
if (cycle_time > (calc_cycle_time + 10)) {
/*
* the provided sdram cycle_time is too small
* for the available DIMM cycle_time.
* The additionnal 100ps is here to accept a small incertainty.
*/
printf("ERROR: DRAM DIMM detected with cycle_time %d ps in "
"slot %d \n while calculated cycle time is %d ps.\n",
(unsigned int)(cycle_time*10),
(unsigned int)dimm_num,
(unsigned int)(calc_cycle_time*10));
printf("Replace the DIMM, or change DDR frequency via "
"strapping bits.\n\n");
spd_ddr_init_hang ();
}
}
}
}
/*------------------------------------------------------------------
* For the memory DIMMs installed, this routine verifies two
* ranks/banks maximum are availables.
*-----------------------------------------------------------------*/
static void check_rank_number(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long dimm_rank;
unsigned long total_rank = 0;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
dimm_rank = spd_read(iic0_dimm_addr[dimm_num], 5);
if (((unsigned long)spd_read(iic0_dimm_addr[dimm_num], 2)) == 0x08)
dimm_rank = (dimm_rank & 0x0F) +1;
else
dimm_rank = dimm_rank & 0x0F;
if (dimm_rank > MAXRANKS) {
printf("ERROR: DRAM DIMM detected with %lu ranks in "
"slot %lu is not supported.\n", dimm_rank, dimm_num);
printf("Only %d ranks are supported for all DIMM.\n", MAXRANKS);
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
} else
total_rank += dimm_rank;
}
if (total_rank > MAXRANKS) {
printf("ERROR: DRAM DIMM detected with a total of %d ranks "
"for all slots.\n", (unsigned int)total_rank);
printf("Only %d ranks are supported for all DIMM.\n", MAXRANKS);
printf("Remove one of the DIMM modules.\n\n");
spd_ddr_init_hang ();
}
}
}
/*------------------------------------------------------------------
* only support 2.5V modules.
* This routine verifies this.
*-----------------------------------------------------------------*/
static void check_voltage_type(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long voltage_type;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
voltage_type = spd_read(iic0_dimm_addr[dimm_num], 8);
switch (voltage_type) {
case 0x00:
printf("ERROR: Only DIMMs DDR 2.5V or DDR2 1.8V are supported.\n");
printf("This DIMM is 5.0 Volt/TTL.\n");
printf("Replace the DIMM module in slot %d with a supported DIMM.\n\n",
(unsigned int)dimm_num);
spd_ddr_init_hang ();
break;
case 0x01:
printf("ERROR: Only DIMMs DDR 2.5V or DDR2 1.8V are supported.\n");
printf("This DIMM is LVTTL.\n");
printf("Replace the DIMM module in slot %d with a supported DIMM.\n\n",
(unsigned int)dimm_num);
spd_ddr_init_hang ();
break;
case 0x02:
printf("ERROR: Only DIMMs DDR 2.5V or DDR2 1.8V are supported.\n");
printf("This DIMM is 1.5 Volt.\n");
printf("Replace the DIMM module in slot %d with a supported DIMM.\n\n",
(unsigned int)dimm_num);
spd_ddr_init_hang ();
break;
case 0x03:
printf("ERROR: Only DIMMs DDR 2.5V or DDR2 1.8V are supported.\n");
printf("This DIMM is 3.3 Volt/TTL.\n");
printf("Replace the DIMM module in slot %d with a supported DIMM.\n\n",
(unsigned int)dimm_num);
spd_ddr_init_hang ();
break;
case 0x04:
/* 2.5 Voltage only for DDR1 */
break;
case 0x05:
/* 1.8 Voltage only for DDR2 */
break;
default:
printf("ERROR: Only DIMMs DDR 2.5V or DDR2 1.8V are supported.\n");
printf("Replace the DIMM module in slot %d with a supported DIMM.\n\n",
(unsigned int)dimm_num);
spd_ddr_init_hang ();
break;
}
}
}
}
/*-----------------------------------------------------------------------------+
* program_copt1.
*-----------------------------------------------------------------------------*/
static void program_copt1(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long mcopt1;
unsigned long ecc_enabled;
unsigned long ecc = 0;
unsigned long data_width = 0;
unsigned long dimm_32bit;
unsigned long dimm_64bit;
unsigned long registered = 0;
unsigned long attribute = 0;
unsigned long buf0, buf1; /* TODO: code to be changed for IOP1.6 to support 4 DIMMs */
unsigned long bankcount;
unsigned long ddrtype;
unsigned long val;
#ifdef CONFIG_DDR_ECC
ecc_enabled = TRUE;
#else
ecc_enabled = FALSE;
#endif
dimm_32bit = FALSE;
dimm_64bit = FALSE;
buf0 = FALSE;
buf1 = FALSE;
/*------------------------------------------------------------------
* Set memory controller options reg 1, SDRAM_MCOPT1.
*-----------------------------------------------------------------*/
mfsdram(SDRAM_MCOPT1, val);
mcopt1 = val & ~(SDRAM_MCOPT1_MCHK_MASK | SDRAM_MCOPT1_RDEN_MASK |
SDRAM_MCOPT1_PMU_MASK | SDRAM_MCOPT1_DMWD_MASK |
SDRAM_MCOPT1_UIOS_MASK | SDRAM_MCOPT1_BCNT_MASK |
SDRAM_MCOPT1_DDR_TYPE_MASK | SDRAM_MCOPT1_RWOO_MASK |
SDRAM_MCOPT1_WOOO_MASK | SDRAM_MCOPT1_DCOO_MASK |
SDRAM_MCOPT1_DREF_MASK);
mcopt1 |= SDRAM_MCOPT1_QDEP;
mcopt1 |= SDRAM_MCOPT1_PMU_OPEN;
mcopt1 |= SDRAM_MCOPT1_RWOO_DISABLED;
mcopt1 |= SDRAM_MCOPT1_WOOO_DISABLED;
mcopt1 |= SDRAM_MCOPT1_DCOO_DISABLED;
mcopt1 |= SDRAM_MCOPT1_DREF_NORMAL;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
/* test ecc support */
ecc = (unsigned long)spd_read(iic0_dimm_addr[dimm_num], 11);
if (ecc != 0x02) /* ecc not supported */
ecc_enabled = FALSE;
/* test bank count */
bankcount = (unsigned long)spd_read(iic0_dimm_addr[dimm_num], 17);
if (bankcount == 0x04) /* bank count = 4 */
mcopt1 |= SDRAM_MCOPT1_4_BANKS;
else /* bank count = 8 */
mcopt1 |= SDRAM_MCOPT1_8_BANKS;
/* test DDR type */
ddrtype = (unsigned long)spd_read(iic0_dimm_addr[dimm_num], 2);
/* test for buffered/unbuffered, registered, differential clocks */
registered = (unsigned long)spd_read(iic0_dimm_addr[dimm_num], 20);
attribute = (unsigned long)spd_read(iic0_dimm_addr[dimm_num], 21);
/* TODO: code to be changed for IOP1.6 to support 4 DIMMs */
if (dimm_num == 0) {
if (dimm_populated[dimm_num] == SDRAM_DDR1) /* DDR1 type */
mcopt1 |= SDRAM_MCOPT1_DDR1_TYPE;
if (dimm_populated[dimm_num] == SDRAM_DDR2) /* DDR2 type */
mcopt1 |= SDRAM_MCOPT1_DDR2_TYPE;
if (registered == 1) { /* DDR2 always buffered */
/* TODO: what about above comments ? */
mcopt1 |= SDRAM_MCOPT1_RDEN;
buf0 = TRUE;
} else {
/* TODO: the mask 0x02 doesn't match Samsung def for byte 21. */
if ((attribute & 0x02) == 0x00) {
/* buffered not supported */
buf0 = FALSE;
} else {
mcopt1 |= SDRAM_MCOPT1_RDEN;
buf0 = TRUE;
}
}
}
else if (dimm_num == 1) {
if (dimm_populated[dimm_num] == SDRAM_DDR1) /* DDR1 type */
mcopt1 |= SDRAM_MCOPT1_DDR1_TYPE;
if (dimm_populated[dimm_num] == SDRAM_DDR2) /* DDR2 type */
mcopt1 |= SDRAM_MCOPT1_DDR2_TYPE;
if (registered == 1) {
/* DDR2 always buffered */
mcopt1 |= SDRAM_MCOPT1_RDEN;
buf1 = TRUE;
} else {
if ((attribute & 0x02) == 0x00) {
/* buffered not supported */
buf1 = FALSE;
} else {
mcopt1 |= SDRAM_MCOPT1_RDEN;
buf1 = TRUE;
}
}
}
/* Note that for DDR2 the byte 7 is reserved, but OK to keep code as is. */
data_width = (unsigned long)spd_read(iic0_dimm_addr[dimm_num], 6) +
(((unsigned long)spd_read(iic0_dimm_addr[dimm_num], 7)) << 8);
switch (data_width) {
case 72:
case 64:
dimm_64bit = TRUE;
break;
case 40:
case 32:
dimm_32bit = TRUE;
break;
default:
printf("WARNING: Detected a DIMM with a data width of %lu bits.\n",
data_width);
printf("Only DIMMs with 32 or 64 bit DDR-SDRAM widths are supported.\n");
break;
}
}
}
/* verify matching properties */
if ((dimm_populated[0] != SDRAM_NONE) && (dimm_populated[1] != SDRAM_NONE)) {
if (buf0 != buf1) {
printf("ERROR: DIMM's buffered/unbuffered, registered, clocking don't match.\n");
spd_ddr_init_hang ();
}
}
if ((dimm_64bit == TRUE) && (dimm_32bit == TRUE)) {
printf("ERROR: Cannot mix 32 bit and 64 bit DDR-SDRAM DIMMs together.\n");
spd_ddr_init_hang ();
}
else if ((dimm_64bit == TRUE) && (dimm_32bit == FALSE)) {
mcopt1 |= SDRAM_MCOPT1_DMWD_64;
} else if ((dimm_64bit == FALSE) && (dimm_32bit == TRUE)) {
mcopt1 |= SDRAM_MCOPT1_DMWD_32;
} else {
printf("ERROR: Please install only 32 or 64 bit DDR-SDRAM DIMMs.\n\n");
spd_ddr_init_hang ();
}
if (ecc_enabled == TRUE)
mcopt1 |= SDRAM_MCOPT1_MCHK_GEN;
else
mcopt1 |= SDRAM_MCOPT1_MCHK_NON;
mtsdram(SDRAM_MCOPT1, mcopt1);
}
/*-----------------------------------------------------------------------------+
* program_codt.
*-----------------------------------------------------------------------------*/
static void program_codt(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long codt;
unsigned long modt0 = 0;
unsigned long modt1 = 0;
unsigned long modt2 = 0;
unsigned long modt3 = 0;
unsigned char dimm_num;
unsigned char dimm_rank;
unsigned char total_rank = 0;
unsigned char total_dimm = 0;
unsigned char dimm_type = 0;
unsigned char firstSlot = 0;
/*------------------------------------------------------------------
* Set the SDRAM Controller On Die Termination Register
*-----------------------------------------------------------------*/
mfsdram(SDRAM_CODT, codt);
codt &= ~(SDRAM_CODT_DQS_SINGLE_END | SDRAM_CODT_CKSE_SINGLE_END);
codt |= SDRAM_CODT_IO_NMODE;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
dimm_rank = (unsigned long)spd_read(iic0_dimm_addr[dimm_num], 5);
if (((unsigned long)spd_read(iic0_dimm_addr[dimm_num], 2)) == 0x08) {
dimm_rank = (dimm_rank & 0x0F) + 1;
dimm_type = SDRAM_DDR2;
} else {
dimm_rank = dimm_rank & 0x0F;
dimm_type = SDRAM_DDR1;
}
total_rank += dimm_rank;
total_dimm++;
if ((dimm_num == 0) && (total_dimm == 1))
firstSlot = TRUE;
else
firstSlot = FALSE;
}
}
if (dimm_type == SDRAM_DDR2) {
codt |= SDRAM_CODT_DQS_1_8_V_DDR2;
if ((total_dimm == 1) && (firstSlot == TRUE)) {
if (total_rank == 1) { /* PUUU */
codt |= CALC_ODT_R(0);
modt0 = CALC_ODT_W(0);
modt1 = 0x00000000;
modt2 = 0x00000000;
modt3 = 0x00000000;
}
if (total_rank == 2) { /* PPUU */
codt |= CALC_ODT_R(0) | CALC_ODT_R(1);
modt0 = CALC_ODT_W(0) | CALC_ODT_W(1);
modt1 = 0x00000000;
modt2 = 0x00000000;
modt3 = 0x00000000;
}
} else if ((total_dimm == 1) && (firstSlot != TRUE)) {
if (total_rank == 1) { /* UUPU */
codt |= CALC_ODT_R(2);
modt0 = 0x00000000;
modt1 = 0x00000000;
modt2 = CALC_ODT_W(2);
modt3 = 0x00000000;
}
if (total_rank == 2) { /* UUPP */
codt |= CALC_ODT_R(2) | CALC_ODT_R(3);
modt0 = 0x00000000;
modt1 = 0x00000000;
modt2 = CALC_ODT_W(2) | CALC_ODT_W(3);
modt3 = 0x00000000;
}
}
if (total_dimm == 2) {
if (total_rank == 2) { /* PUPU */
codt |= CALC_ODT_R(0) | CALC_ODT_R(2);
modt0 = CALC_ODT_RW(2);
modt1 = 0x00000000;
modt2 = CALC_ODT_RW(0);
modt3 = 0x00000000;
}
if (total_rank == 4) { /* PPPP */
codt |= CALC_ODT_R(0) | CALC_ODT_R(1) |
CALC_ODT_R(2) | CALC_ODT_R(3);
modt0 = CALC_ODT_RW(2) | CALC_ODT_RW(3);
modt1 = 0x00000000;
modt2 = CALC_ODT_RW(0) | CALC_ODT_RW(1);
modt3 = 0x00000000;
}
}
} else {
codt |= SDRAM_CODT_DQS_2_5_V_DDR1;
modt0 = 0x00000000;
modt1 = 0x00000000;
modt2 = 0x00000000;
modt3 = 0x00000000;
if (total_dimm == 1) {
if (total_rank == 1)
codt |= 0x00800000;
if (total_rank == 2)
codt |= 0x02800000;
}
if (total_dimm == 2) {
if (total_rank == 2)
codt |= 0x08800000;
if (total_rank == 4)
codt |= 0x2a800000;
}
}
debug("nb of dimm %d\n", total_dimm);
debug("nb of rank %d\n", total_rank);
if (total_dimm == 1)
debug("dimm in slot %d\n", firstSlot);
mtsdram(SDRAM_CODT, codt);
mtsdram(SDRAM_MODT0, modt0);
mtsdram(SDRAM_MODT1, modt1);
mtsdram(SDRAM_MODT2, modt2);
mtsdram(SDRAM_MODT3, modt3);
}
/*-----------------------------------------------------------------------------+
* program_initplr.
*-----------------------------------------------------------------------------*/
static void program_initplr(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks,
ddr_cas_id_t selected_cas,
int write_recovery)
{
u32 cas = 0;
u32 odt = 0;
u32 ods = 0;
u32 mr;
u32 wr;
u32 emr;
u32 emr2;
u32 emr3;
int dimm_num;
int total_dimm = 0;
/******************************************************
** Assumption: if more than one DIMM, all DIMMs are the same
** as already checked in check_memory_type
******************************************************/
if ((dimm_populated[0] == SDRAM_DDR1) || (dimm_populated[1] == SDRAM_DDR1)) {
mtsdram(SDRAM_INITPLR0, 0x81B80000);
mtsdram(SDRAM_INITPLR1, 0x81900400);
mtsdram(SDRAM_INITPLR2, 0x81810000);
mtsdram(SDRAM_INITPLR3, 0xff800162);
mtsdram(SDRAM_INITPLR4, 0x81900400);
mtsdram(SDRAM_INITPLR5, 0x86080000);
mtsdram(SDRAM_INITPLR6, 0x86080000);
mtsdram(SDRAM_INITPLR7, 0x81000062);
} else if ((dimm_populated[0] == SDRAM_DDR2) || (dimm_populated[1] == SDRAM_DDR2)) {
switch (selected_cas) {
case DDR_CAS_3:
cas = 3 << 4;
break;
case DDR_CAS_4:
cas = 4 << 4;
break;
case DDR_CAS_5:
cas = 5 << 4;
break;
default:
printf("ERROR: ucode error on selected_cas value %d", selected_cas);
spd_ddr_init_hang ();
break;
}
#if 0
/*
* ToDo - Still a problem with the write recovery:
* On the Corsair CM2X512-5400C4 module, setting write recovery
* in the INITPLR reg to the value calculated in program_mode()
* results in not correctly working DDR2 memory (crash after
* relocation).
*
* So for now, set the write recovery to 3. This seems to work
* on the Corair module too.
*
* 2007-03-01, sr
*/
switch (write_recovery) {
case 3:
wr = WRITE_RECOV_3;
break;
case 4:
wr = WRITE_RECOV_4;
break;
case 5:
wr = WRITE_RECOV_5;
break;
case 6:
wr = WRITE_RECOV_6;
break;
default:
printf("ERROR: write recovery not support (%d)", write_recovery);
spd_ddr_init_hang ();
break;
}
#else
wr = WRITE_RECOV_3; /* test-only, see description above */
#endif
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++)
if (dimm_populated[dimm_num] != SDRAM_NONE)
total_dimm++;
if (total_dimm == 1) {
odt = ODT_150_OHM;
ods = ODS_FULL;
} else if (total_dimm == 2) {
odt = ODT_75_OHM;
ods = ODS_REDUCED;
} else {
printf("ERROR: Unsupported number of DIMM's (%d)", total_dimm);
spd_ddr_init_hang ();
}
mr = CMD_EMR | SELECT_MR | BURST_LEN_4 | wr | cas;
emr = CMD_EMR | SELECT_EMR | odt | ods;
emr2 = CMD_EMR | SELECT_EMR2;
emr3 = CMD_EMR | SELECT_EMR3;
/* NOP - Wait 106 MemClk cycles */
mtsdram(SDRAM_INITPLR0, SDRAM_INITPLR_ENABLE | CMD_NOP |
SDRAM_INITPLR_IMWT_ENCODE(106));
udelay(1000);
/* precharge 4 MemClk cycles */
mtsdram(SDRAM_INITPLR1, SDRAM_INITPLR_ENABLE | CMD_PRECHARGE |
SDRAM_INITPLR_IMWT_ENCODE(4));
/* EMR2 - Wait tMRD (2 MemClk cycles) */
mtsdram(SDRAM_INITPLR2, SDRAM_INITPLR_ENABLE | emr2 |
SDRAM_INITPLR_IMWT_ENCODE(2));
/* EMR3 - Wait tMRD (2 MemClk cycles) */
mtsdram(SDRAM_INITPLR3, SDRAM_INITPLR_ENABLE | emr3 |
SDRAM_INITPLR_IMWT_ENCODE(2));
/* EMR DLL ENABLE - Wait tMRD (2 MemClk cycles) */
mtsdram(SDRAM_INITPLR4, SDRAM_INITPLR_ENABLE | emr |
SDRAM_INITPLR_IMWT_ENCODE(2));
/* MR w/ DLL reset - 200 cycle wait for DLL reset */
mtsdram(SDRAM_INITPLR5, SDRAM_INITPLR_ENABLE | mr | DLL_RESET |
SDRAM_INITPLR_IMWT_ENCODE(200));
udelay(1000);
/* precharge 4 MemClk cycles */
mtsdram(SDRAM_INITPLR6, SDRAM_INITPLR_ENABLE | CMD_PRECHARGE |
SDRAM_INITPLR_IMWT_ENCODE(4));
/* Refresh 25 MemClk cycles */
mtsdram(SDRAM_INITPLR7, SDRAM_INITPLR_ENABLE | CMD_REFRESH |
SDRAM_INITPLR_IMWT_ENCODE(25));
/* Refresh 25 MemClk cycles */
mtsdram(SDRAM_INITPLR8, SDRAM_INITPLR_ENABLE | CMD_REFRESH |
SDRAM_INITPLR_IMWT_ENCODE(25));
/* Refresh 25 MemClk cycles */
mtsdram(SDRAM_INITPLR9, SDRAM_INITPLR_ENABLE | CMD_REFRESH |
SDRAM_INITPLR_IMWT_ENCODE(25));
/* Refresh 25 MemClk cycles */
mtsdram(SDRAM_INITPLR10, SDRAM_INITPLR_ENABLE | CMD_REFRESH |
SDRAM_INITPLR_IMWT_ENCODE(25));
/* MR w/o DLL reset - Wait tMRD (2 MemClk cycles) */
mtsdram(SDRAM_INITPLR11, SDRAM_INITPLR_ENABLE | mr |
SDRAM_INITPLR_IMWT_ENCODE(2));
/* EMR OCD Default - Wait tMRD (2 MemClk cycles) */
mtsdram(SDRAM_INITPLR12, SDRAM_INITPLR_ENABLE | OCD_CALIB_DEF |
SDRAM_INITPLR_IMWT_ENCODE(2) | emr);
/* EMR OCD Exit */
mtsdram(SDRAM_INITPLR13, SDRAM_INITPLR_ENABLE | emr |
SDRAM_INITPLR_IMWT_ENCODE(2));
} else {
printf("ERROR: ucode error as unknown DDR type in program_initplr");
spd_ddr_init_hang ();
}
}
/*------------------------------------------------------------------
* This routine programs the SDRAM_MMODE register.
* the selected_cas is an output parameter, that will be passed
* by caller to call the above program_initplr( )
*-----------------------------------------------------------------*/
static void program_mode(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks,
ddr_cas_id_t *selected_cas,
int *write_recovery)
{
unsigned long dimm_num;
unsigned long sdram_ddr1;
unsigned long t_wr_ns;
unsigned long t_wr_clk;
unsigned long cas_bit;
unsigned long cas_index;
unsigned long sdram_freq;
unsigned long ddr_check;
unsigned long mmode;
unsigned long tcyc_reg;
unsigned long cycle_2_0_clk;
unsigned long cycle_2_5_clk;
unsigned long cycle_3_0_clk;
unsigned long cycle_4_0_clk;
unsigned long cycle_5_0_clk;
unsigned long max_2_0_tcyc_ns_x_100;
unsigned long max_2_5_tcyc_ns_x_100;
unsigned long max_3_0_tcyc_ns_x_100;
unsigned long max_4_0_tcyc_ns_x_100;
unsigned long max_5_0_tcyc_ns_x_100;
unsigned long cycle_time_ns_x_100[3];
PPC4xx_SYS_INFO board_cfg;
unsigned char cas_2_0_available;
unsigned char cas_2_5_available;
unsigned char cas_3_0_available;
unsigned char cas_4_0_available;
unsigned char cas_5_0_available;
unsigned long sdr_ddrpll;
/*------------------------------------------------------------------
* Get the board configuration info.
*-----------------------------------------------------------------*/
get_sys_info(&board_cfg);
mfsdr(SDR0_DDR0, sdr_ddrpll);
sdram_freq = MULDIV64((board_cfg.freqPLB), SDR0_DDR0_DDRM_DECODE(sdr_ddrpll), 1);
debug("sdram_freq=%lu\n", sdram_freq);
/*------------------------------------------------------------------
* Handle the timing. We need to find the worst case timing of all
* the dimm modules installed.
*-----------------------------------------------------------------*/
t_wr_ns = 0;
cas_2_0_available = TRUE;
cas_2_5_available = TRUE;
cas_3_0_available = TRUE;
cas_4_0_available = TRUE;
cas_5_0_available = TRUE;
max_2_0_tcyc_ns_x_100 = 10;
max_2_5_tcyc_ns_x_100 = 10;
max_3_0_tcyc_ns_x_100 = 10;
max_4_0_tcyc_ns_x_100 = 10;
max_5_0_tcyc_ns_x_100 = 10;
sdram_ddr1 = TRUE;
/* loop through all the DIMM slots on the board */
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
/* If a dimm is installed in a particular slot ... */
if (dimm_populated[dimm_num] != SDRAM_NONE) {
if (dimm_populated[dimm_num] == SDRAM_DDR1)
sdram_ddr1 = TRUE;
else
sdram_ddr1 = FALSE;
/* t_wr_ns = max(t_wr_ns, (unsigned long)dimm_spd[dimm_num][36] >> 2); */ /* not used in this loop. */
cas_bit = spd_read(iic0_dimm_addr[dimm_num], 18);
debug("cas_bit[SPD byte 18]=%02lx\n", cas_bit);
/* For a particular DIMM, grab the three CAS values it supports */
for (cas_index = 0; cas_index < 3; cas_index++) {
switch (cas_index) {
case 0:
tcyc_reg = spd_read(iic0_dimm_addr[dimm_num], 9);
break;
case 1:
tcyc_reg = spd_read(iic0_dimm_addr[dimm_num], 23);
break;
default:
tcyc_reg = spd_read(iic0_dimm_addr[dimm_num], 25);
break;
}
if ((tcyc_reg & 0x0F) >= 10) {
if ((tcyc_reg & 0x0F) == 0x0D) {
/* Convert from hex to decimal */
cycle_time_ns_x_100[cas_index] =
(((tcyc_reg & 0xF0) >> 4) * 100) + 75;
} else {
printf("ERROR: SPD reported Tcyc is incorrect for DIMM "
"in slot %d\n", (unsigned int)dimm_num);
spd_ddr_init_hang ();
}
} else {
/* Convert from hex to decimal */
cycle_time_ns_x_100[cas_index] =
(((tcyc_reg & 0xF0) >> 4) * 100) +
((tcyc_reg & 0x0F)*10);
}
debug("cas_index=%lu: cycle_time_ns_x_100=%lu\n", cas_index,
cycle_time_ns_x_100[cas_index]);
}
/* The rest of this routine determines if CAS 2.0, 2.5, 3.0, 4.0 and 5.0 are */
/* supported for a particular DIMM. */
cas_index = 0;
if (sdram_ddr1) {
/*
* DDR devices use the following bitmask for CAS latency:
* Bit 7 6 5 4 3 2 1 0
* TBD 4.0 3.5 3.0 2.5 2.0 1.5 1.0
*/
if (((cas_bit & 0x40) == 0x40) && (cas_index < 3) &&
(cycle_time_ns_x_100[cas_index] != 0)) {
max_4_0_tcyc_ns_x_100 = max(max_4_0_tcyc_ns_x_100,
cycle_time_ns_x_100[cas_index]);
cas_index++;
} else {
if (cas_index != 0)
cas_index++;
cas_4_0_available = FALSE;
}
if (((cas_bit & 0x10) == 0x10) && (cas_index < 3) &&
(cycle_time_ns_x_100[cas_index] != 0)) {
max_3_0_tcyc_ns_x_100 = max(max_3_0_tcyc_ns_x_100,
cycle_time_ns_x_100[cas_index]);
cas_index++;
} else {
if (cas_index != 0)
cas_index++;
cas_3_0_available = FALSE;
}
if (((cas_bit & 0x08) == 0x08) && (cas_index < 3) &&
(cycle_time_ns_x_100[cas_index] != 0)) {
max_2_5_tcyc_ns_x_100 = max(max_2_5_tcyc_ns_x_100,
cycle_time_ns_x_100[cas_index]);
cas_index++;
} else {
if (cas_index != 0)
cas_index++;
cas_2_5_available = FALSE;
}
if (((cas_bit & 0x04) == 0x04) && (cas_index < 3) &&
(cycle_time_ns_x_100[cas_index] != 0)) {
max_2_0_tcyc_ns_x_100 = max(max_2_0_tcyc_ns_x_100,
cycle_time_ns_x_100[cas_index]);
cas_index++;
} else {
if (cas_index != 0)
cas_index++;
cas_2_0_available = FALSE;
}
} else {
/*
* DDR2 devices use the following bitmask for CAS latency:
* Bit 7 6 5 4 3 2 1 0
* TBD 6.0 5.0 4.0 3.0 2.0 TBD TBD
*/
if (((cas_bit & 0x20) == 0x20) && (cas_index < 3) &&
(cycle_time_ns_x_100[cas_index] != 0)) {
max_5_0_tcyc_ns_x_100 = max(max_5_0_tcyc_ns_x_100,
cycle_time_ns_x_100[cas_index]);
cas_index++;
} else {
if (cas_index != 0)
cas_index++;
cas_5_0_available = FALSE;
}
if (((cas_bit & 0x10) == 0x10) && (cas_index < 3) &&
(cycle_time_ns_x_100[cas_index] != 0)) {
max_4_0_tcyc_ns_x_100 = max(max_4_0_tcyc_ns_x_100,
cycle_time_ns_x_100[cas_index]);
cas_index++;
} else {
if (cas_index != 0)
cas_index++;
cas_4_0_available = FALSE;
}
if (((cas_bit & 0x08) == 0x08) && (cas_index < 3) &&
(cycle_time_ns_x_100[cas_index] != 0)) {
max_3_0_tcyc_ns_x_100 = max(max_3_0_tcyc_ns_x_100,
cycle_time_ns_x_100[cas_index]);
cas_index++;
} else {
if (cas_index != 0)
cas_index++;
cas_3_0_available = FALSE;
}
}
}
}
/*------------------------------------------------------------------
* Set the SDRAM mode, SDRAM_MMODE
*-----------------------------------------------------------------*/
mfsdram(SDRAM_MMODE, mmode);
mmode = mmode & ~(SDRAM_MMODE_WR_MASK | SDRAM_MMODE_DCL_MASK);
/* add 10 here because of rounding problems */
cycle_2_0_clk = MULDIV64(ONE_BILLION, 100, max_2_0_tcyc_ns_x_100) + 10;
cycle_2_5_clk = MULDIV64(ONE_BILLION, 100, max_2_5_tcyc_ns_x_100) + 10;
cycle_3_0_clk = MULDIV64(ONE_BILLION, 100, max_3_0_tcyc_ns_x_100) + 10;
cycle_4_0_clk = MULDIV64(ONE_BILLION, 100, max_4_0_tcyc_ns_x_100) + 10;
cycle_5_0_clk = MULDIV64(ONE_BILLION, 100, max_5_0_tcyc_ns_x_100) + 10;
debug("cycle_3_0_clk=%lu\n", cycle_3_0_clk);
debug("cycle_4_0_clk=%lu\n", cycle_4_0_clk);
debug("cycle_5_0_clk=%lu\n", cycle_5_0_clk);
if (sdram_ddr1 == TRUE) { /* DDR1 */
if ((cas_2_0_available == TRUE) && (sdram_freq <= cycle_2_0_clk)) {
mmode |= SDRAM_MMODE_DCL_DDR1_2_0_CLK;
*selected_cas = DDR_CAS_2;
} else if ((cas_2_5_available == TRUE) && (sdram_freq <= cycle_2_5_clk)) {
mmode |= SDRAM_MMODE_DCL_DDR1_2_5_CLK;
*selected_cas = DDR_CAS_2_5;
} else if ((cas_3_0_available == TRUE) && (sdram_freq <= cycle_3_0_clk)) {
mmode |= SDRAM_MMODE_DCL_DDR1_3_0_CLK;
*selected_cas = DDR_CAS_3;
} else {
printf("ERROR: Cannot find a supported CAS latency with the installed DIMMs.\n");
printf("Only DIMMs DDR1 with CAS latencies of 2.0, 2.5, and 3.0 are supported.\n");
printf("Make sure the PLB speed is within the supported range of the DIMMs.\n\n");
spd_ddr_init_hang ();
}
} else { /* DDR2 */
debug("cas_3_0_available=%d\n", cas_3_0_available);
debug("cas_4_0_available=%d\n", cas_4_0_available);
debug("cas_5_0_available=%d\n", cas_5_0_available);
if ((cas_3_0_available == TRUE) && (sdram_freq <= cycle_3_0_clk)) {
mmode |= SDRAM_MMODE_DCL_DDR2_3_0_CLK;
*selected_cas = DDR_CAS_3;
} else if ((cas_4_0_available == TRUE) && (sdram_freq <= cycle_4_0_clk)) {
mmode |= SDRAM_MMODE_DCL_DDR2_4_0_CLK;
*selected_cas = DDR_CAS_4;
} else if ((cas_5_0_available == TRUE) && (sdram_freq <= cycle_5_0_clk)) {
mmode |= SDRAM_MMODE_DCL_DDR2_5_0_CLK;
*selected_cas = DDR_CAS_5;
} else {
printf("ERROR: Cannot find a supported CAS latency with the installed DIMMs.\n");
printf("Only DIMMs DDR2 with CAS latencies of 3.0, 4.0, and 5.0 are supported.\n");
printf("Make sure the PLB speed is within the supported range of the DIMMs.\n");
printf("cas3=%d cas4=%d cas5=%d\n",
cas_3_0_available, cas_4_0_available, cas_5_0_available);
printf("sdram_freq=%lu cycle3=%lu cycle4=%lu cycle5=%lu\n\n",
sdram_freq, cycle_3_0_clk, cycle_4_0_clk, cycle_5_0_clk);
spd_ddr_init_hang ();
}
}
if (sdram_ddr1 == TRUE)
mmode |= SDRAM_MMODE_WR_DDR1;
else {
/* loop through all the DIMM slots on the board */
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
/* If a dimm is installed in a particular slot ... */
if (dimm_populated[dimm_num] != SDRAM_NONE)
t_wr_ns = max(t_wr_ns,
spd_read(iic0_dimm_addr[dimm_num], 36) >> 2);
}
/*
* convert from nanoseconds to ddr clocks
* round up if necessary
*/
t_wr_clk = MULDIV64(sdram_freq, t_wr_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_wr_clk, t_wr_ns);
if (sdram_freq != ddr_check)
t_wr_clk++;
switch (t_wr_clk) {
case 0:
case 1:
case 2:
case 3:
mmode |= SDRAM_MMODE_WR_DDR2_3_CYC;
break;
case 4:
mmode |= SDRAM_MMODE_WR_DDR2_4_CYC;
break;
case 5:
mmode |= SDRAM_MMODE_WR_DDR2_5_CYC;
break;
default:
mmode |= SDRAM_MMODE_WR_DDR2_6_CYC;
break;
}
*write_recovery = t_wr_clk;
}
debug("CAS latency = %d\n", *selected_cas);
debug("Write recovery = %d\n", *write_recovery);
mtsdram(SDRAM_MMODE, mmode);
}
/*-----------------------------------------------------------------------------+
* program_rtr.
*-----------------------------------------------------------------------------*/
static void program_rtr(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
PPC4xx_SYS_INFO board_cfg;
unsigned long max_refresh_rate;
unsigned long dimm_num;
unsigned long refresh_rate_type;
unsigned long refresh_rate;
unsigned long rint;
unsigned long sdram_freq;
unsigned long sdr_ddrpll;
unsigned long val;
/*------------------------------------------------------------------
* Get the board configuration info.
*-----------------------------------------------------------------*/
get_sys_info(&board_cfg);
/*------------------------------------------------------------------
* Set the SDRAM Refresh Timing Register, SDRAM_RTR
*-----------------------------------------------------------------*/
mfsdr(SDR0_DDR0, sdr_ddrpll);
sdram_freq = ((board_cfg.freqPLB) * SDR0_DDR0_DDRM_DECODE(sdr_ddrpll));
max_refresh_rate = 0;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
refresh_rate_type = spd_read(iic0_dimm_addr[dimm_num], 12);
refresh_rate_type &= 0x7F;
switch (refresh_rate_type) {
case 0:
refresh_rate = 15625;
break;
case 1:
refresh_rate = 3906;
break;
case 2:
refresh_rate = 7812;
break;
case 3:
refresh_rate = 31250;
break;
case 4:
refresh_rate = 62500;
break;
case 5:
refresh_rate = 125000;
break;
default:
refresh_rate = 0;
printf("ERROR: DIMM %d unsupported refresh rate/type.\n",
(unsigned int)dimm_num);
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
break;
}
max_refresh_rate = max(max_refresh_rate, refresh_rate);
}
}
rint = MULDIV64(sdram_freq, max_refresh_rate, ONE_BILLION);
mfsdram(SDRAM_RTR, val);
mtsdram(SDRAM_RTR, (val & ~SDRAM_RTR_RINT_MASK) |
(SDRAM_RTR_RINT_ENCODE(rint)));
}
/*------------------------------------------------------------------
* This routine programs the SDRAM_TRx registers.
*-----------------------------------------------------------------*/
static void program_tr(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long sdram_ddr1;
unsigned long t_rp_ns;
unsigned long t_rcd_ns;
unsigned long t_rrd_ns;
unsigned long t_ras_ns;
unsigned long t_rc_ns;
unsigned long t_rfc_ns;
unsigned long t_wpc_ns;
unsigned long t_wtr_ns;
unsigned long t_rpc_ns;
unsigned long t_rp_clk;
unsigned long t_rcd_clk;
unsigned long t_rrd_clk;
unsigned long t_ras_clk;
unsigned long t_rc_clk;
unsigned long t_rfc_clk;
unsigned long t_wpc_clk;
unsigned long t_wtr_clk;
unsigned long t_rpc_clk;
unsigned long sdtr1, sdtr2, sdtr3;
unsigned long ddr_check;
unsigned long sdram_freq;
unsigned long sdr_ddrpll;
PPC4xx_SYS_INFO board_cfg;
/*------------------------------------------------------------------
* Get the board configuration info.
*-----------------------------------------------------------------*/
get_sys_info(&board_cfg);
mfsdr(SDR0_DDR0, sdr_ddrpll);
sdram_freq = ((board_cfg.freqPLB) * SDR0_DDR0_DDRM_DECODE(sdr_ddrpll));
/*------------------------------------------------------------------
* Handle the timing. We need to find the worst case timing of all
* the dimm modules installed.
*-----------------------------------------------------------------*/
t_rp_ns = 0;
t_rrd_ns = 0;
t_rcd_ns = 0;
t_ras_ns = 0;
t_rc_ns = 0;
t_rfc_ns = 0;
t_wpc_ns = 0;
t_wtr_ns = 0;
t_rpc_ns = 0;
sdram_ddr1 = TRUE;
/* loop through all the DIMM slots on the board */
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
/* If a dimm is installed in a particular slot ... */
if (dimm_populated[dimm_num] != SDRAM_NONE) {
if (dimm_populated[dimm_num] == SDRAM_DDR2)
sdram_ddr1 = TRUE;
else
sdram_ddr1 = FALSE;
t_rcd_ns = max(t_rcd_ns, spd_read(iic0_dimm_addr[dimm_num], 29) >> 2);
t_rrd_ns = max(t_rrd_ns, spd_read(iic0_dimm_addr[dimm_num], 28) >> 2);
t_rp_ns = max(t_rp_ns, spd_read(iic0_dimm_addr[dimm_num], 27) >> 2);
t_ras_ns = max(t_ras_ns, spd_read(iic0_dimm_addr[dimm_num], 30));
t_rc_ns = max(t_rc_ns, spd_read(iic0_dimm_addr[dimm_num], 41));
t_rfc_ns = max(t_rfc_ns, spd_read(iic0_dimm_addr[dimm_num], 42));
}
}
/*------------------------------------------------------------------
* Set the SDRAM Timing Reg 1, SDRAM_TR1
*-----------------------------------------------------------------*/
mfsdram(SDRAM_SDTR1, sdtr1);
sdtr1 &= ~(SDRAM_SDTR1_LDOF_MASK | SDRAM_SDTR1_RTW_MASK |
SDRAM_SDTR1_WTWO_MASK | SDRAM_SDTR1_RTRO_MASK);
/* default values */
sdtr1 |= SDRAM_SDTR1_LDOF_2_CLK;
sdtr1 |= SDRAM_SDTR1_RTW_2_CLK;
/* normal operations */
sdtr1 |= SDRAM_SDTR1_WTWO_0_CLK;
sdtr1 |= SDRAM_SDTR1_RTRO_1_CLK;
mtsdram(SDRAM_SDTR1, sdtr1);
/*------------------------------------------------------------------
* Set the SDRAM Timing Reg 2, SDRAM_TR2
*-----------------------------------------------------------------*/
mfsdram(SDRAM_SDTR2, sdtr2);
sdtr2 &= ~(SDRAM_SDTR2_RCD_MASK | SDRAM_SDTR2_WTR_MASK |
SDRAM_SDTR2_XSNR_MASK | SDRAM_SDTR2_WPC_MASK |
SDRAM_SDTR2_RPC_MASK | SDRAM_SDTR2_RP_MASK |
SDRAM_SDTR2_RRD_MASK);
/*
* convert t_rcd from nanoseconds to ddr clocks
* round up if necessary
*/
t_rcd_clk = MULDIV64(sdram_freq, t_rcd_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_rcd_clk, t_rcd_ns);
if (sdram_freq != ddr_check)
t_rcd_clk++;
switch (t_rcd_clk) {
case 0:
case 1:
sdtr2 |= SDRAM_SDTR2_RCD_1_CLK;
break;
case 2:
sdtr2 |= SDRAM_SDTR2_RCD_2_CLK;
break;
case 3:
sdtr2 |= SDRAM_SDTR2_RCD_3_CLK;
break;
case 4:
sdtr2 |= SDRAM_SDTR2_RCD_4_CLK;
break;
default:
sdtr2 |= SDRAM_SDTR2_RCD_5_CLK;
break;
}
if (sdram_ddr1 == TRUE) { /* DDR1 */
if (sdram_freq < 200000000) {
sdtr2 |= SDRAM_SDTR2_WTR_1_CLK;
sdtr2 |= SDRAM_SDTR2_WPC_2_CLK;
sdtr2 |= SDRAM_SDTR2_RPC_2_CLK;
} else {
sdtr2 |= SDRAM_SDTR2_WTR_2_CLK;
sdtr2 |= SDRAM_SDTR2_WPC_3_CLK;
sdtr2 |= SDRAM_SDTR2_RPC_2_CLK;
}
} else { /* DDR2 */
/* loop through all the DIMM slots on the board */
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
/* If a dimm is installed in a particular slot ... */
if (dimm_populated[dimm_num] != SDRAM_NONE) {
t_wpc_ns = max(t_wtr_ns, spd_read(iic0_dimm_addr[dimm_num], 36) >> 2);
t_wtr_ns = max(t_wtr_ns, spd_read(iic0_dimm_addr[dimm_num], 37) >> 2);
t_rpc_ns = max(t_rpc_ns, spd_read(iic0_dimm_addr[dimm_num], 38) >> 2);
}
}
/*
* convert from nanoseconds to ddr clocks
* round up if necessary
*/
t_wpc_clk = MULDIV64(sdram_freq, t_wpc_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_wpc_clk, t_wpc_ns);
if (sdram_freq != ddr_check)
t_wpc_clk++;
switch (t_wpc_clk) {
case 0:
case 1:
case 2:
sdtr2 |= SDRAM_SDTR2_WPC_2_CLK;
break;
case 3:
sdtr2 |= SDRAM_SDTR2_WPC_3_CLK;
break;
case 4:
sdtr2 |= SDRAM_SDTR2_WPC_4_CLK;
break;
case 5:
sdtr2 |= SDRAM_SDTR2_WPC_5_CLK;
break;
default:
sdtr2 |= SDRAM_SDTR2_WPC_6_CLK;
break;
}
/*
* convert from nanoseconds to ddr clocks
* round up if necessary
*/
t_wtr_clk = MULDIV64(sdram_freq, t_wtr_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_wtr_clk, t_wtr_ns);
if (sdram_freq != ddr_check)
t_wtr_clk++;
switch (t_wtr_clk) {
case 0:
case 1:
sdtr2 |= SDRAM_SDTR2_WTR_1_CLK;
break;
case 2:
sdtr2 |= SDRAM_SDTR2_WTR_2_CLK;
break;
case 3:
sdtr2 |= SDRAM_SDTR2_WTR_3_CLK;
break;
default:
sdtr2 |= SDRAM_SDTR2_WTR_4_CLK;
break;
}
/*
* convert from nanoseconds to ddr clocks
* round up if necessary
*/
t_rpc_clk = MULDIV64(sdram_freq, t_rpc_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_rpc_clk, t_rpc_ns);
if (sdram_freq != ddr_check)
t_rpc_clk++;
switch (t_rpc_clk) {
case 0:
case 1:
case 2:
sdtr2 |= SDRAM_SDTR2_RPC_2_CLK;
break;
case 3:
sdtr2 |= SDRAM_SDTR2_RPC_3_CLK;
break;
default:
sdtr2 |= SDRAM_SDTR2_RPC_4_CLK;
break;
}
}
/* default value */
sdtr2 |= SDRAM_SDTR2_XSNR_16_CLK;
/*
* convert t_rrd from nanoseconds to ddr clocks
* round up if necessary
*/
t_rrd_clk = MULDIV64(sdram_freq, t_rrd_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_rrd_clk, t_rrd_ns);
if (sdram_freq != ddr_check)
t_rrd_clk++;
if (t_rrd_clk == 3)
sdtr2 |= SDRAM_SDTR2_RRD_3_CLK;
else
sdtr2 |= SDRAM_SDTR2_RRD_2_CLK;
/*
* convert t_rp from nanoseconds to ddr clocks
* round up if necessary
*/
t_rp_clk = MULDIV64(sdram_freq, t_rp_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_rp_clk, t_rp_ns);
if (sdram_freq != ddr_check)
t_rp_clk++;
switch (t_rp_clk) {
case 0:
case 1:
case 2:
case 3:
sdtr2 |= SDRAM_SDTR2_RP_3_CLK;
break;
case 4:
sdtr2 |= SDRAM_SDTR2_RP_4_CLK;
break;
case 5:
sdtr2 |= SDRAM_SDTR2_RP_5_CLK;
break;
case 6:
sdtr2 |= SDRAM_SDTR2_RP_6_CLK;
break;
default:
sdtr2 |= SDRAM_SDTR2_RP_7_CLK;
break;
}
mtsdram(SDRAM_SDTR2, sdtr2);
/*------------------------------------------------------------------
* Set the SDRAM Timing Reg 3, SDRAM_TR3
*-----------------------------------------------------------------*/
mfsdram(SDRAM_SDTR3, sdtr3);
sdtr3 &= ~(SDRAM_SDTR3_RAS_MASK | SDRAM_SDTR3_RC_MASK |
SDRAM_SDTR3_XCS_MASK | SDRAM_SDTR3_RFC_MASK);
/*
* convert t_ras from nanoseconds to ddr clocks
* round up if necessary
*/
t_ras_clk = MULDIV64(sdram_freq, t_ras_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_ras_clk, t_ras_ns);
if (sdram_freq != ddr_check)
t_ras_clk++;
sdtr3 |= SDRAM_SDTR3_RAS_ENCODE(t_ras_clk);
/*
* convert t_rc from nanoseconds to ddr clocks
* round up if necessary
*/
t_rc_clk = MULDIV64(sdram_freq, t_rc_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_rc_clk, t_rc_ns);
if (sdram_freq != ddr_check)
t_rc_clk++;
sdtr3 |= SDRAM_SDTR3_RC_ENCODE(t_rc_clk);
/* default xcs value */
sdtr3 |= SDRAM_SDTR3_XCS;
/*
* convert t_rfc from nanoseconds to ddr clocks
* round up if necessary
*/
t_rfc_clk = MULDIV64(sdram_freq, t_rfc_ns, ONE_BILLION);
ddr_check = MULDIV64(ONE_BILLION, t_rfc_clk, t_rfc_ns);
if (sdram_freq != ddr_check)
t_rfc_clk++;
sdtr3 |= SDRAM_SDTR3_RFC_ENCODE(t_rfc_clk);
mtsdram(SDRAM_SDTR3, sdtr3);
}
/*-----------------------------------------------------------------------------+
* program_bxcf.
*-----------------------------------------------------------------------------*/
static void program_bxcf(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
unsigned long num_col_addr;
unsigned long num_ranks;
unsigned long num_banks;
unsigned long mode;
unsigned long ind_rank;
unsigned long ind;
unsigned long ind_bank;
unsigned long bank_0_populated;
/*------------------------------------------------------------------
* Set the BxCF regs. First, wipe out the bank config registers.
*-----------------------------------------------------------------*/
mtsdram(SDRAM_MB0CF, 0x00000000);
mtsdram(SDRAM_MB1CF, 0x00000000);
mtsdram(SDRAM_MB2CF, 0x00000000);
mtsdram(SDRAM_MB3CF, 0x00000000);
mode = SDRAM_BXCF_M_BE_ENABLE;
bank_0_populated = 0;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
num_col_addr = spd_read(iic0_dimm_addr[dimm_num], 4);
num_ranks = spd_read(iic0_dimm_addr[dimm_num], 5);
if ((spd_read(iic0_dimm_addr[dimm_num], 2)) == 0x08)
num_ranks = (num_ranks & 0x0F) +1;
else
num_ranks = num_ranks & 0x0F;
num_banks = spd_read(iic0_dimm_addr[dimm_num], 17);
for (ind_bank = 0; ind_bank < 2; ind_bank++) {
if (num_banks == 4)
ind = 0;
else
ind = 5 << 8;
switch (num_col_addr) {
case 0x08:
mode |= (SDRAM_BXCF_M_AM_0 + ind);
break;
case 0x09:
mode |= (SDRAM_BXCF_M_AM_1 + ind);
break;
case 0x0A:
mode |= (SDRAM_BXCF_M_AM_2 + ind);
break;
case 0x0B:
mode |= (SDRAM_BXCF_M_AM_3 + ind);
break;
case 0x0C:
mode |= (SDRAM_BXCF_M_AM_4 + ind);
break;
default:
printf("DDR-SDRAM: DIMM %d BxCF configuration.\n",
(unsigned int)dimm_num);
printf("ERROR: Unsupported value for number of "
"column addresses: %d.\n", (unsigned int)num_col_addr);
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
}
}
if ((dimm_populated[dimm_num] != SDRAM_NONE)&& (dimm_num ==1))
bank_0_populated = 1;
for (ind_rank = 0; ind_rank < num_ranks; ind_rank++) {
mtsdram(SDRAM_MB0CF +
((dimm_num + bank_0_populated + ind_rank) << 2),
mode);
}
}
}
}
/*------------------------------------------------------------------
* program memory queue.
*-----------------------------------------------------------------*/
static void program_memory_queue(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long dimm_num;
phys_size_t rank_base_addr;
unsigned long rank_reg;
phys_size_t rank_size_bytes;
unsigned long rank_size_id;
unsigned long num_ranks;
unsigned long baseadd_size;
unsigned long i;
unsigned long bank_0_populated = 0;
phys_size_t total_size = 0;
/*------------------------------------------------------------------
* Reset the rank_base_address.
*-----------------------------------------------------------------*/
rank_reg = SDRAM_R0BAS;
rank_base_addr = 0x00000000;
for (dimm_num = 0; dimm_num < num_dimm_banks; dimm_num++) {
if (dimm_populated[dimm_num] != SDRAM_NONE) {
num_ranks = spd_read(iic0_dimm_addr[dimm_num], 5);
if ((spd_read(iic0_dimm_addr[dimm_num], 2)) == 0x08)
num_ranks = (num_ranks & 0x0F) + 1;
else
num_ranks = num_ranks & 0x0F;
rank_size_id = spd_read(iic0_dimm_addr[dimm_num], 31);
/*------------------------------------------------------------------
* Set the sizes
*-----------------------------------------------------------------*/
baseadd_size = 0;
switch (rank_size_id) {
case 0x01:
baseadd_size |= SDRAM_RXBAS_SDSZ_1024;
total_size = 1024;
break;
case 0x02:
baseadd_size |= SDRAM_RXBAS_SDSZ_2048;
total_size = 2048;
break;
case 0x04:
baseadd_size |= SDRAM_RXBAS_SDSZ_4096;
total_size = 4096;
break;
case 0x08:
baseadd_size |= SDRAM_RXBAS_SDSZ_32;
total_size = 32;
break;
case 0x10:
baseadd_size |= SDRAM_RXBAS_SDSZ_64;
total_size = 64;
break;
case 0x20:
baseadd_size |= SDRAM_RXBAS_SDSZ_128;
total_size = 128;
break;
case 0x40:
baseadd_size |= SDRAM_RXBAS_SDSZ_256;
total_size = 256;
break;
case 0x80:
baseadd_size |= SDRAM_RXBAS_SDSZ_512;
total_size = 512;
break;
default:
printf("DDR-SDRAM: DIMM %d memory queue configuration.\n",
(unsigned int)dimm_num);
printf("ERROR: Unsupported value for the banksize: %d.\n",
(unsigned int)rank_size_id);
printf("Replace the DIMM module with a supported DIMM.\n\n");
spd_ddr_init_hang ();
}
rank_size_bytes = total_size << 20;
if ((dimm_populated[dimm_num] != SDRAM_NONE) && (dimm_num == 1))
bank_0_populated = 1;
for (i = 0; i < num_ranks; i++) {
mtdcr_any(rank_reg+i+dimm_num+bank_0_populated,
(SDRAM_RXBAS_SDBA_ENCODE(rank_base_addr) |
baseadd_size));
rank_base_addr += rank_size_bytes;
}
}
}
#if defined(CONFIG_440SP) || defined(CONFIG_440SPE) || \
defined(CONFIG_460EX) || defined(CONFIG_460GT) || \
defined(CONFIG_460SX)
/*
* Enable high bandwidth access
* This is currently not used, but with this setup
* it is possible to use it later on in e.g. the Linux
* EMAC driver for performance gain.
*/
mtdcr(SDRAM_PLBADDULL, 0x00000000); /* MQ0_BAUL */
mtdcr(SDRAM_PLBADDUHB, 0x00000008); /* MQ0_BAUH */
/*
* Set optimal value for Memory Queue HB/LL Configuration registers
*/
mtdcr(SDRAM_CONF1HB, (mfdcr(SDRAM_CONF1HB) & ~SDRAM_CONF1HB_MASK) |
SDRAM_CONF1HB_AAFR | SDRAM_CONF1HB_RPEN | SDRAM_CONF1HB_RFTE |
SDRAM_CONF1HB_RPLM | SDRAM_CONF1HB_WRCL);
mtdcr(SDRAM_CONF1LL, (mfdcr(SDRAM_CONF1LL) & ~SDRAM_CONF1LL_MASK) |
SDRAM_CONF1LL_AAFR | SDRAM_CONF1LL_RPEN | SDRAM_CONF1LL_RFTE |
SDRAM_CONF1LL_RPLM);
mtdcr(SDRAM_CONFPATHB, mfdcr(SDRAM_CONFPATHB) | SDRAM_CONFPATHB_TPEN);
#endif
}
/*-----------------------------------------------------------------------------+
* is_ecc_enabled.
*-----------------------------------------------------------------------------*/
static unsigned long is_ecc_enabled(void)
{
unsigned long dimm_num;
unsigned long ecc;
unsigned long val;
ecc = 0;
/* loop through all the DIMM slots on the board */
for (dimm_num = 0; dimm_num < MAXDIMMS; dimm_num++) {
mfsdram(SDRAM_MCOPT1, val);
ecc = max(ecc, SDRAM_MCOPT1_MCHK_CHK_DECODE(val));
}
return ecc;
}
#ifdef CONFIG_DDR_ECC
/*-----------------------------------------------------------------------------+
* program_ecc.
*-----------------------------------------------------------------------------*/
static void program_ecc(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks,
unsigned long tlb_word2_i_value)
{
unsigned long mcopt1;
unsigned long mcopt2;
unsigned long mcstat;
unsigned long dimm_num;
unsigned long ecc;
ecc = 0;
/* loop through all the DIMM slots on the board */
for (dimm_num = 0; dimm_num < MAXDIMMS; dimm_num++) {
/* If a dimm is installed in a particular slot ... */
if (dimm_populated[dimm_num] != SDRAM_NONE)
ecc = max(ecc, spd_read(iic0_dimm_addr[dimm_num], 11));
}
if (ecc == 0)
return;
if (sdram_memsize() > CONFIG_MAX_MEM_MAPPED) {
printf("\nWarning: Can't enable ECC on systems with more than 2GB of SDRAM!\n");
return;
}
mfsdram(SDRAM_MCOPT1, mcopt1);
mfsdram(SDRAM_MCOPT2, mcopt2);
if ((mcopt1 & SDRAM_MCOPT1_MCHK_MASK) != SDRAM_MCOPT1_MCHK_NON) {
/* DDR controller must be enabled and not in self-refresh. */
mfsdram(SDRAM_MCSTAT, mcstat);
if (((mcopt2 & SDRAM_MCOPT2_DCEN_MASK) == SDRAM_MCOPT2_DCEN_ENABLE)
&& ((mcopt2 & SDRAM_MCOPT2_SREN_MASK) == SDRAM_MCOPT2_SREN_EXIT)
&& ((mcstat & (SDRAM_MCSTAT_MIC_MASK | SDRAM_MCSTAT_SRMS_MASK))
== (SDRAM_MCSTAT_MIC_COMP | SDRAM_MCSTAT_SRMS_NOT_SF))) {
program_ecc_addr(0, sdram_memsize(), tlb_word2_i_value);
}
}
return;
}
static void wait_ddr_idle(void)
{
u32 val;
do {
mfsdram(SDRAM_MCSTAT, val);
} while ((val & SDRAM_MCSTAT_IDLE_MASK) == SDRAM_MCSTAT_IDLE_NOT);
}
/*-----------------------------------------------------------------------------+
* program_ecc_addr.
*-----------------------------------------------------------------------------*/
static void program_ecc_addr(unsigned long start_address,
unsigned long num_bytes,
unsigned long tlb_word2_i_value)
{
unsigned long current_address;
unsigned long end_address;
unsigned long address_increment;
unsigned long mcopt1;
char str[] = "ECC generation -";
char slash[] = "\\|/-\\|/-";
int loop = 0;
int loopi = 0;
current_address = start_address;
mfsdram(SDRAM_MCOPT1, mcopt1);
if ((mcopt1 & SDRAM_MCOPT1_MCHK_MASK) != SDRAM_MCOPT1_MCHK_NON) {
mtsdram(SDRAM_MCOPT1,
(mcopt1 & ~SDRAM_MCOPT1_MCHK_MASK) | SDRAM_MCOPT1_MCHK_GEN);
sync();
eieio();
wait_ddr_idle();
puts(str);
if (tlb_word2_i_value == TLB_WORD2_I_ENABLE) {
/* ECC bit set method for non-cached memory */
if ((mcopt1 & SDRAM_MCOPT1_DMWD_MASK) == SDRAM_MCOPT1_DMWD_32)
address_increment = 4;
else
address_increment = 8;
end_address = current_address + num_bytes;
while (current_address < end_address) {
*((unsigned long *)current_address) = 0x00000000;
current_address += address_increment;
if ((loop++ % (2 << 20)) == 0) {
putc('\b');
putc(slash[loopi++ % 8]);
}
}
} else {
/* ECC bit set method for cached memory */
dcbz_area(start_address, num_bytes);
/* Write modified dcache lines back to memory */
clean_dcache_range(start_address, start_address + num_bytes);
}
blank_string(strlen(str));
sync();
eieio();
wait_ddr_idle();
/* clear ECC error repoting registers */
mtsdram(SDRAM_ECCCR, 0xffffffff);
mtdcr(0x4c, 0xffffffff);
mtsdram(SDRAM_MCOPT1,
(mcopt1 & ~SDRAM_MCOPT1_MCHK_MASK) | SDRAM_MCOPT1_MCHK_CHK_REP);
sync();
eieio();
wait_ddr_idle();
}
}
#endif
#if !defined(CONFIG_PPC4xx_DDR_AUTOCALIBRATION)
/*-----------------------------------------------------------------------------+
* program_DQS_calibration.
*-----------------------------------------------------------------------------*/
static void program_DQS_calibration(unsigned long *dimm_populated,
unsigned char *iic0_dimm_addr,
unsigned long num_dimm_banks)
{
unsigned long val;
#ifdef HARD_CODED_DQS /* calibration test with hardvalues */
mtsdram(SDRAM_RQDC, 0x80000037);
mtsdram(SDRAM_RDCC, 0x40000000);
mtsdram(SDRAM_RFDC, 0x000001DF);
test();
#else
/*------------------------------------------------------------------
* Program RDCC register
* Read sample cycle auto-update enable
*-----------------------------------------------------------------*/
mfsdram(SDRAM_RDCC, val);
mtsdram(SDRAM_RDCC,
(val & ~(SDRAM_RDCC_RDSS_MASK | SDRAM_RDCC_RSAE_MASK))
| SDRAM_RDCC_RSAE_ENABLE);
/*------------------------------------------------------------------
* Program RQDC register
* Internal DQS delay mechanism enable
*-----------------------------------------------------------------*/
mtsdram(SDRAM_RQDC, (SDRAM_RQDC_RQDE_ENABLE|SDRAM_RQDC_RQFD_ENCODE(0x38)));
/*------------------------------------------------------------------
* Program RFDC register
* Set Feedback Fractional Oversample
* Auto-detect read sample cycle enable
* Set RFOS to 1/4 of memclk cycle (0x3f)
*-----------------------------------------------------------------*/
mfsdram(SDRAM_RFDC, val);
mtsdram(SDRAM_RFDC,
(val & ~(SDRAM_RFDC_ARSE_MASK | SDRAM_RFDC_RFOS_MASK |
SDRAM_RFDC_RFFD_MASK))
| (SDRAM_RFDC_ARSE_ENABLE | SDRAM_RFDC_RFOS_ENCODE(0x3f) |
SDRAM_RFDC_RFFD_ENCODE(0)));
DQS_calibration_process();
#endif
}
static int short_mem_test(void)
{
u32 *membase;
u32 bxcr_num;
u32 bxcf;
int i;
int j;
phys_size_t base_addr;
u32 test[NUMMEMTESTS][NUMMEMWORDS] = {
{0x00000000, 0x00000000, 0xFFFFFFFF, 0xFFFFFFFF,
0x00000000, 0x00000000, 0xFFFFFFFF, 0xFFFFFFFF},
{0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0x00000000,
0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0x00000000},
{0xAAAAAAAA, 0xAAAAAAAA, 0x55555555, 0x55555555,
0xAAAAAAAA, 0xAAAAAAAA, 0x55555555, 0x55555555},
{0x55555555, 0x55555555, 0xAAAAAAAA, 0xAAAAAAAA,
0x55555555, 0x55555555, 0xAAAAAAAA, 0xAAAAAAAA},
{0xA5A5A5A5, 0xA5A5A5A5, 0x5A5A5A5A, 0x5A5A5A5A,
0xA5A5A5A5, 0xA5A5A5A5, 0x5A5A5A5A, 0x5A5A5A5A},
{0x5A5A5A5A, 0x5A5A5A5A, 0xA5A5A5A5, 0xA5A5A5A5,
0x5A5A5A5A, 0x5A5A5A5A, 0xA5A5A5A5, 0xA5A5A5A5},
{0xAA55AA55, 0xAA55AA55, 0x55AA55AA, 0x55AA55AA,
0xAA55AA55, 0xAA55AA55, 0x55AA55AA, 0x55AA55AA},
{0x55AA55AA, 0x55AA55AA, 0xAA55AA55, 0xAA55AA55,
0x55AA55AA, 0x55AA55AA, 0xAA55AA55, 0xAA55AA55} };
int l;
for (bxcr_num = 0; bxcr_num < MAXBXCF; bxcr_num++) {
mfsdram(SDRAM_MB0CF + (bxcr_num << 2), bxcf);
/* Banks enabled */
if ((bxcf & SDRAM_BXCF_M_BE_MASK) == SDRAM_BXCF_M_BE_ENABLE) {
/* Bank is enabled */
/*
* Only run test on accessable memory (below 2GB)
*/
base_addr = SDRAM_RXBAS_SDBA_DECODE(mfdcr_any(SDRAM_R0BAS+bxcr_num));
if (base_addr >= CONFIG_MAX_MEM_MAPPED)
continue;
/*------------------------------------------------------------------
* Run the short memory test.
*-----------------------------------------------------------------*/
membase = (u32 *)(u32)base_addr;
for (i = 0; i < NUMMEMTESTS; i++) {
for (j = 0; j < NUMMEMWORDS; j++) {
membase[j] = test[i][j];
ppcDcbf((u32)&(membase[j]));
}
sync();
for (l=0; l<NUMLOOPS; l++) {
for (j = 0; j < NUMMEMWORDS; j++) {
if (membase[j] != test[i][j]) {
ppcDcbf((u32)&(membase[j]));
return 0;
}
ppcDcbf((u32)&(membase[j]));
}
sync();
}
}
} /* if bank enabled */
} /* for bxcf_num */
return 1;
}
#ifndef HARD_CODED_DQS
/*-----------------------------------------------------------------------------+
* DQS_calibration_process.
*-----------------------------------------------------------------------------*/
static void DQS_calibration_process(void)
{
unsigned long rfdc_reg;
unsigned long rffd;
unsigned long val;
long rffd_average;
long max_start;
long min_end;
unsigned long begin_rqfd[MAXRANKS];
unsigned long begin_rffd[MAXRANKS];
unsigned long end_rqfd[MAXRANKS];
unsigned long end_rffd[MAXRANKS];
char window_found;
unsigned long dlycal;
unsigned long dly_val;
unsigned long max_pass_length;
unsigned long current_pass_length;
unsigned long current_fail_length;
unsigned long current_start;
long max_end;
unsigned char fail_found;
unsigned char pass_found;
#if !defined(CONFIG_DDR_RQDC_FIXED)
u32 rqdc_reg;
u32 rqfd;
u32 rqfd_start;
u32 rqfd_average;
int loopi = 0;
char str[] = "Auto calibration -";
char slash[] = "\\|/-\\|/-";
/*------------------------------------------------------------------
* Test to determine the best read clock delay tuning bits.
*
* Before the DDR controller can be used, the read clock delay needs to be
* set. This is SDRAM_RQDC[RQFD] and SDRAM_RFDC[RFFD].
* This value cannot be hardcoded into the program because it changes
* depending on the board's setup and environment.
* To do this, all delay values are tested to see if they
* work or not. By doing this, you get groups of fails with groups of
* passing values. The idea is to find the start and end of a passing
* window and take the center of it to use as the read clock delay.
*
* A failure has to be seen first so that when we hit a pass, we know
* that it is truely the start of the window. If we get passing values
* to start off with, we don't know if we are at the start of the window.
*
* The code assumes that a failure will always be found.
* If a failure is not found, there is no easy way to get the middle
* of the passing window. I guess we can pretty much pick any value
* but some values will be better than others. Since the lowest speed
* we can clock the DDR interface at is 200 MHz (2x 100 MHz PLB speed),
* from experimentation it is safe to say you will always have a failure.
*-----------------------------------------------------------------*/
/* first fix RQDC[RQFD] to an average of 80 degre phase shift to find RFDC[RFFD] */
rqfd_start = 64; /* test-only: don't know if this is the _best_ start value */
puts(str);
calibration_loop:
mfsdram(SDRAM_RQDC, rqdc_reg);
mtsdram(SDRAM_RQDC, (rqdc_reg & ~SDRAM_RQDC_RQFD_MASK) |
SDRAM_RQDC_RQFD_ENCODE(rqfd_start));
#else /* CONFIG_DDR_RQDC_FIXED */
/*
* On Katmai the complete auto-calibration somehow doesn't seem to
* produce the best results, meaning optimal values for RQFD/RFFD.
* This was discovered by GDA using a high bandwidth scope,
* analyzing the DDR2 signals. GDA provided a fixed value for RQFD,
* so now on Katmai "only" RFFD is auto-calibrated.
*/
mtsdram(SDRAM_RQDC, CONFIG_DDR_RQDC_FIXED);
#endif /* CONFIG_DDR_RQDC_FIXED */
max_start = 0;
min_end = 0;
begin_rqfd[0] = 0;
begin_rffd[0] = 0;
begin_rqfd[1] = 0;
begin_rffd[1] = 0;
end_rqfd[0] = 0;
end_rffd[0] = 0;
end_rqfd[1] = 0;
end_rffd[1] = 0;
window_found = FALSE;
max_pass_length = 0;
max_start = 0;
max_end = 0;
current_pass_length = 0;
current_fail_length = 0;
current_start = 0;
window_found = FALSE;
fail_found = FALSE;
pass_found = FALSE;
/*
* get the delay line calibration register value
*/
mfsdram(SDRAM_DLCR, dlycal);
dly_val = SDRAM_DLYCAL_DLCV_DECODE(dlycal) << 2;
for (rffd = 0; rffd <= SDRAM_RFDC_RFFD_MAX; rffd++) {
mfsdram(SDRAM_RFDC, rfdc_reg);
rfdc_reg &= ~(SDRAM_RFDC_RFFD_MASK);
/*------------------------------------------------------------------
* Set the timing reg for the test.
*-----------------------------------------------------------------*/
mtsdram(SDRAM_RFDC, rfdc_reg | SDRAM_RFDC_RFFD_ENCODE(rffd));
/*------------------------------------------------------------------
* See if the rffd value passed.
*-----------------------------------------------------------------*/
if (short_mem_test()) {
if (fail_found == TRUE) {
pass_found = TRUE;
if (current_pass_length == 0)
current_start = rffd;
current_fail_length = 0;
current_pass_length++;
if (current_pass_length > max_pass_length) {
max_pass_length = current_pass_length;
max_start = current_start;
max_end = rffd;
}
}
} else {
current_pass_length = 0;
current_fail_length++;
if (current_fail_length >= (dly_val >> 2)) {
if (fail_found == FALSE) {
fail_found = TRUE;
} else if (pass_found == TRUE) {
window_found = TRUE;
break;
}
}
}
} /* for rffd */
/*------------------------------------------------------------------
* Set the average RFFD value
*-----------------------------------------------------------------*/
rffd_average = ((max_start + max_end) >> 1);
if (rffd_average < 0)
rffd_average = 0;
if (rffd_average > SDRAM_RFDC_RFFD_MAX)
rffd_average = SDRAM_RFDC_RFFD_MAX;
/* now fix RFDC[RFFD] found and find RQDC[RQFD] */
mtsdram(SDRAM_RFDC, rfdc_reg | SDRAM_RFDC_RFFD_ENCODE(rffd_average));
#if !defined(CONFIG_DDR_RQDC_FIXED)
max_pass_length = 0;
max_start = 0;
max_end = 0;
current_pass_length = 0;
current_fail_length = 0;
current_start = 0;
window_found = FALSE;
fail_found = FALSE;
pass_found = FALSE;
for (rqfd = 0; rqfd <= SDRAM_RQDC_RQFD_MAX; rqfd++) {
mfsdram(SDRAM_RQDC, rqdc_reg);
rqdc_reg &= ~(SDRAM_RQDC_RQFD_MASK);
/*------------------------------------------------------------------
* Set the timing reg for the test.
*-----------------------------------------------------------------*/
mtsdram(SDRAM_RQDC, rqdc_reg | SDRAM_RQDC_RQFD_ENCODE(rqfd));
/*------------------------------------------------------------------
* See if the rffd value passed.
*-----------------------------------------------------------------*/
if (short_mem_test()) {
if (fail_found == TRUE) {
pass_found = TRUE;
if (current_pass_length == 0)
current_start = rqfd;
current_fail_length = 0;
current_pass_length++;
if (current_pass_length > max_pass_length) {
max_pass_length = current_pass_length;
max_start = current_start;
max_end = rqfd;
}
}
} else {
current_pass_length = 0;
current_fail_length++;
if (fail_found == FALSE) {
fail_found = TRUE;
} else if (pass_found == TRUE) {
window_found = TRUE;
break;
}
}
}
rqfd_average = ((max_start + max_end) >> 1);
/*------------------------------------------------------------------
* Make sure we found the valid read passing window. Halt if not
*-----------------------------------------------------------------*/
if (window_found == FALSE) {
if (rqfd_start < SDRAM_RQDC_RQFD_MAX) {
putc('\b');
putc(slash[loopi++ % 8]);
/* try again from with a different RQFD start value */
rqfd_start++;
goto calibration_loop;
}
printf("\nERROR: Cannot determine a common read delay for the "
"DIMM(s) installed.\n");
debug("%s[%d] ERROR : \n", __FUNCTION__,__LINE__);
ppc4xx_ibm_ddr2_register_dump();
spd_ddr_init_hang ();
}
if (rqfd_average < 0)
rqfd_average = 0;
if (rqfd_average > SDRAM_RQDC_RQFD_MAX)
rqfd_average = SDRAM_RQDC_RQFD_MAX;
mtsdram(SDRAM_RQDC,
(rqdc_reg & ~SDRAM_RQDC_RQFD_MASK) |
SDRAM_RQDC_RQFD_ENCODE(rqfd_average));
blank_string(strlen(str));
#endif /* CONFIG_DDR_RQDC_FIXED */
/*
* Now complete RDSS configuration as mentioned on page 7 of the AMCC
* PowerPC440SP/SPe DDR2 application note:
* "DDR1/DDR2 Initialization Sequence and Dynamic Tuning"
*/
mfsdram(SDRAM_RTSR, val);
if ((val & SDRAM_RTSR_TRK1SM_MASK) == SDRAM_RTSR_TRK1SM_ATPLS1) {
mfsdram(SDRAM_RDCC, val);
if ((val & SDRAM_RDCC_RDSS_MASK) != SDRAM_RDCC_RDSS_T4) {
val += 0x40000000;
mtsdram(SDRAM_RDCC, val);
}
}
mfsdram(SDRAM_DLCR, val);
debug("%s[%d] DLCR: 0x%08lX\n", __FUNCTION__, __LINE__, val);
mfsdram(SDRAM_RQDC, val);
debug("%s[%d] RQDC: 0x%08lX\n", __FUNCTION__, __LINE__, val);
mfsdram(SDRAM_RFDC, val);
debug("%s[%d] RFDC: 0x%08lX\n", __FUNCTION__, __LINE__, val);
mfsdram(SDRAM_RDCC, val);
debug("%s[%d] RDCC: 0x%08lX\n", __FUNCTION__, __LINE__, val);
}
#else /* calibration test with hardvalues */
/*-----------------------------------------------------------------------------+
* DQS_calibration_process.
*-----------------------------------------------------------------------------*/
static void test(void)
{
unsigned long dimm_num;
unsigned long ecc_temp;
unsigned long i, j;
unsigned long *membase;
unsigned long bxcf[MAXRANKS];
unsigned long val;
char window_found;
char begin_found[MAXDIMMS];
char end_found[MAXDIMMS];
char search_end[MAXDIMMS];
unsigned long test[NUMMEMTESTS][NUMMEMWORDS] = {
{0x00000000, 0x00000000, 0xFFFFFFFF, 0xFFFFFFFF,
0x00000000, 0x00000000, 0xFFFFFFFF, 0xFFFFFFFF},
{0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0x00000000,
0xFFFFFFFF, 0xFFFFFFFF, 0x00000000, 0x00000000},
{0xAAAAAAAA, 0xAAAAAAAA, 0x55555555, 0x55555555,
0xAAAAAAAA, 0xAAAAAAAA, 0x55555555, 0x55555555},
{0x55555555, 0x55555555, 0xAAAAAAAA, 0xAAAAAAAA,
0x55555555, 0x55555555, 0xAAAAAAAA, 0xAAAAAAAA},
{0xA5A5A5A5, 0xA5A5A5A5, 0x5A5A5A5A, 0x5A5A5A5A,
0xA5A5A5A5, 0xA5A5A5A5, 0x5A5A5A5A, 0x5A5A5A5A},
{0x5A5A5A5A, 0x5A5A5A5A, 0xA5A5A5A5, 0xA5A5A5A5,
0x5A5A5A5A, 0x5A5A5A5A, 0xA5A5A5A5, 0xA5A5A5A5},
{0xAA55AA55, 0xAA55AA55, 0x55AA55AA, 0x55AA55AA,
0xAA55AA55, 0xAA55AA55, 0x55AA55AA, 0x55AA55AA},
{0x55AA55AA, 0x55AA55AA, 0xAA55AA55, 0xAA55AA55,
0x55AA55AA, 0x55AA55AA, 0xAA55AA55, 0xAA55AA55} };
/*------------------------------------------------------------------
* Test to determine the best read clock delay tuning bits.
*
* Before the DDR controller can be used, the read clock delay needs to be
* set. This is SDRAM_RQDC[RQFD] and SDRAM_RFDC[RFFD].
* This value cannot be hardcoded into the program because it changes
* depending on the board's setup and environment.
* To do this, all delay values are tested to see if they
* work or not. By doing this, you get groups of fails with groups of
* passing values. The idea is to find the start and end of a passing
* window and take the center of it to use as the read clock delay.
*
* A failure has to be seen first so that when we hit a pass, we know
* that it is truely the start of the window. If we get passing values
* to start off with, we don't know if we are at the start of the window.
*
* The code assumes that a failure will always be found.
* If a failure is not found, there is no easy way to get the middle
* of the passing window. I guess we can pretty much pick any value
* but some values will be better than others. Since the lowest speed
* we can clock the DDR interface at is 200 MHz (2x 100 MHz PLB speed),
* from experimentation it is safe to say you will always have a failure.
*-----------------------------------------------------------------*/
mfsdram(SDRAM_MCOPT1, ecc_temp);
ecc_temp &= SDRAM_MCOPT1_MCHK_MASK;
mfsdram(SDRAM_MCOPT1, val);
mtsdram(SDRAM_MCOPT1, (val & ~SDRAM_MCOPT1_MCHK_MASK) |
SDRAM_MCOPT1_MCHK_NON);
window_found = FALSE;
begin_found[0] = FALSE;
end_found[0] = FALSE;
search_end[0] = FALSE;
begin_found[1] = FALSE;
end_found[1] = FALSE;
search_end[1] = FALSE;
for (dimm_num = 0; dimm_num < MAXDIMMS; dimm_num++) {
mfsdram(SDRAM_MB0CF + (bxcr_num << 2), bxcf[bxcr_num]);
/* Banks enabled */
if ((bxcf[dimm_num] & SDRAM_BXCF_M_BE_MASK) == SDRAM_BXCF_M_BE_ENABLE) {
/* Bank is enabled */
membase =
(unsigned long*)(SDRAM_RXBAS_SDBA_DECODE(mfdcr_any(SDRAM_R0BAS+dimm_num)));
/*------------------------------------------------------------------
* Run the short memory test.
*-----------------------------------------------------------------*/
for (i = 0; i < NUMMEMTESTS; i++) {
for (j = 0; j < NUMMEMWORDS; j++) {
membase[j] = test[i][j];
ppcDcbf((u32)&(membase[j]));
}
sync();
for (j = 0; j < NUMMEMWORDS; j++) {
if (membase[j] != test[i][j]) {
ppcDcbf((u32)&(membase[j]));
break;
}
ppcDcbf((u32)&(membase[j]));
}
sync();
if (j < NUMMEMWORDS)
break;
}
/*------------------------------------------------------------------
* See if the rffd value passed.
*-----------------------------------------------------------------*/
if (i < NUMMEMTESTS) {
if ((end_found[dimm_num] == FALSE) &&
(search_end[dimm_num] == TRUE)) {
end_found[dimm_num] = TRUE;
}
if ((end_found[0] == TRUE) &&
(end_found[1] == TRUE))
break;
} else {
if (begin_found[dimm_num] == FALSE) {
begin_found[dimm_num] = TRUE;
search_end[dimm_num] = TRUE;
}
}
} else {
begin_found[dimm_num] = TRUE;
end_found[dimm_num] = TRUE;
}
}
if ((begin_found[0] == TRUE) && (begin_found[1] == TRUE))
window_found = TRUE;
/*------------------------------------------------------------------
* Make sure we found the valid read passing window. Halt if not
*-----------------------------------------------------------------*/
if (window_found == FALSE) {
printf("ERROR: Cannot determine a common read delay for the "
"DIMM(s) installed.\n");
spd_ddr_init_hang ();
}
/*------------------------------------------------------------------
* Restore the ECC variable to what it originally was
*-----------------------------------------------------------------*/
mtsdram(SDRAM_MCOPT1,
(ppcMfdcr_sdram(SDRAM_MCOPT1) & ~SDRAM_MCOPT1_MCHK_MASK)
| ecc_temp);
}
#endif /* !HARD_CODED_DQS */
#endif /* !defined(CONFIG_PPC4xx_DDR_AUTOCALIBRATION) */
#else /* CONFIG_SPD_EEPROM */
/*-----------------------------------------------------------------------------
* Function: initdram
* Description: Configures the PPC4xx IBM DDR1/DDR2 SDRAM memory controller.
* The configuration is performed using static, compile-
* time parameters.
* Configures the PPC405EX(r) and PPC460EX/GT
*---------------------------------------------------------------------------*/
phys_size_t initdram(int board_type)
{
/*
* Only run this SDRAM init code once. For NAND booting
* targets like Kilauea, we call initdram() early from the
* 4k NAND booting image (CONFIG_NAND_SPL) from nand_boot().
* Later on the NAND U-Boot image runs (CONFIG_NAND_U_BOOT)
* which calls initdram() again. This time the controller
* mustn't be reconfigured again since we're already running
* from SDRAM.
*/
#if !defined(CONFIG_NAND_U_BOOT) || defined(CONFIG_NAND_SPL)
unsigned long val;
#if defined(CONFIG_440)
mtdcr(SDRAM_R0BAS, CONFIG_SYS_SDRAM_R0BAS);
mtdcr(SDRAM_R1BAS, CONFIG_SYS_SDRAM_R1BAS);
mtdcr(SDRAM_R2BAS, CONFIG_SYS_SDRAM_R2BAS);
mtdcr(SDRAM_R3BAS, CONFIG_SYS_SDRAM_R3BAS);
mtdcr(SDRAM_PLBADDULL, CONFIG_SYS_SDRAM_PLBADDULL); /* MQ0_BAUL */
mtdcr(SDRAM_PLBADDUHB, CONFIG_SYS_SDRAM_PLBADDUHB); /* MQ0_BAUH */
mtdcr(SDRAM_CONF1LL, CONFIG_SYS_SDRAM_CONF1LL);
mtdcr(SDRAM_CONF1HB, CONFIG_SYS_SDRAM_CONF1HB);
mtdcr(SDRAM_CONFPATHB, CONFIG_SYS_SDRAM_CONFPATHB);
#endif
/* Set Memory Bank Configuration Registers */
mtsdram(SDRAM_MB0CF, CONFIG_SYS_SDRAM0_MB0CF);
mtsdram(SDRAM_MB1CF, CONFIG_SYS_SDRAM0_MB1CF);
mtsdram(SDRAM_MB2CF, CONFIG_SYS_SDRAM0_MB2CF);
mtsdram(SDRAM_MB3CF, CONFIG_SYS_SDRAM0_MB3CF);
/* Set Memory Clock Timing Register */
mtsdram(SDRAM_CLKTR, CONFIG_SYS_SDRAM0_CLKTR);
/* Set Refresh Time Register */
mtsdram(SDRAM_RTR, CONFIG_SYS_SDRAM0_RTR);
/* Set SDRAM Timing Registers */
mtsdram(SDRAM_SDTR1, CONFIG_SYS_SDRAM0_SDTR1);
mtsdram(SDRAM_SDTR2, CONFIG_SYS_SDRAM0_SDTR2);
mtsdram(SDRAM_SDTR3, CONFIG_SYS_SDRAM0_SDTR3);
/* Set Mode and Extended Mode Registers */
mtsdram(SDRAM_MMODE, CONFIG_SYS_SDRAM0_MMODE);
mtsdram(SDRAM_MEMODE, CONFIG_SYS_SDRAM0_MEMODE);
/* Set Memory Controller Options 1 Register */
mtsdram(SDRAM_MCOPT1, CONFIG_SYS_SDRAM0_MCOPT1);
/* Set Manual Initialization Control Registers */
mtsdram(SDRAM_INITPLR0, CONFIG_SYS_SDRAM0_INITPLR0);
mtsdram(SDRAM_INITPLR1, CONFIG_SYS_SDRAM0_INITPLR1);
mtsdram(SDRAM_INITPLR2, CONFIG_SYS_SDRAM0_INITPLR2);
mtsdram(SDRAM_INITPLR3, CONFIG_SYS_SDRAM0_INITPLR3);
mtsdram(SDRAM_INITPLR4, CONFIG_SYS_SDRAM0_INITPLR4);
mtsdram(SDRAM_INITPLR5, CONFIG_SYS_SDRAM0_INITPLR5);
mtsdram(SDRAM_INITPLR6, CONFIG_SYS_SDRAM0_INITPLR6);
mtsdram(SDRAM_INITPLR7, CONFIG_SYS_SDRAM0_INITPLR7);
mtsdram(SDRAM_INITPLR8, CONFIG_SYS_SDRAM0_INITPLR8);
mtsdram(SDRAM_INITPLR9, CONFIG_SYS_SDRAM0_INITPLR9);
mtsdram(SDRAM_INITPLR10, CONFIG_SYS_SDRAM0_INITPLR10);
mtsdram(SDRAM_INITPLR11, CONFIG_SYS_SDRAM0_INITPLR11);
mtsdram(SDRAM_INITPLR12, CONFIG_SYS_SDRAM0_INITPLR12);
mtsdram(SDRAM_INITPLR13, CONFIG_SYS_SDRAM0_INITPLR13);
mtsdram(SDRAM_INITPLR14, CONFIG_SYS_SDRAM0_INITPLR14);
mtsdram(SDRAM_INITPLR15, CONFIG_SYS_SDRAM0_INITPLR15);
/* Set On-Die Termination Registers */
mtsdram(SDRAM_CODT, CONFIG_SYS_SDRAM0_CODT);
mtsdram(SDRAM_MODT0, CONFIG_SYS_SDRAM0_MODT0);
mtsdram(SDRAM_MODT1, CONFIG_SYS_SDRAM0_MODT1);
/* Set Write Timing Register */
mtsdram(SDRAM_WRDTR, CONFIG_SYS_SDRAM0_WRDTR);
/*
* Start Initialization by SDRAM0_MCOPT2[SREN] = 0 and
* SDRAM0_MCOPT2[IPTR] = 1
*/
mtsdram(SDRAM_MCOPT2, (SDRAM_MCOPT2_SREN_EXIT |
SDRAM_MCOPT2_IPTR_EXECUTE));
/*
* Poll SDRAM0_MCSTAT[MIC] for assertion to indicate the
* completion of initialization.
*/
do {
mfsdram(SDRAM_MCSTAT, val);
} while ((val & SDRAM_MCSTAT_MIC_MASK) != SDRAM_MCSTAT_MIC_COMP);
/* Set Delay Control Registers */
mtsdram(SDRAM_DLCR, CONFIG_SYS_SDRAM0_DLCR);
#if !defined(CONFIG_PPC4xx_DDR_AUTOCALIBRATION)
mtsdram(SDRAM_RDCC, CONFIG_SYS_SDRAM0_RDCC);
mtsdram(SDRAM_RQDC, CONFIG_SYS_SDRAM0_RQDC);
mtsdram(SDRAM_RFDC, CONFIG_SYS_SDRAM0_RFDC);
#endif /* !CONFIG_PPC4xx_DDR_AUTOCALIBRATION */
/*
* Enable Controller by SDRAM0_MCOPT2[DCEN] = 1:
*/
mfsdram(SDRAM_MCOPT2, val);
mtsdram(SDRAM_MCOPT2, val | SDRAM_MCOPT2_DCEN_ENABLE);
#if defined(CONFIG_440)
/*
* Program TLB entries with caches enabled, for best performace
* while auto-calibrating and ECC generation
*/
program_tlb(0, 0, (CONFIG_SYS_MBYTES_SDRAM << 20), 0);
#endif
#if defined(CONFIG_PPC4xx_DDR_AUTOCALIBRATION)
#if !defined(CONFIG_NAND_U_BOOT) && !defined(CONFIG_NAND_SPL)
/*------------------------------------------------------------------
| DQS calibration.
+-----------------------------------------------------------------*/
DQS_autocalibration();
#endif /* !defined(CONFIG_NAND_U_BOOT) && !defined(CONFIG_NAND_SPL) */
#endif /* CONFIG_PPC4xx_DDR_AUTOCALIBRATION */
#if defined(CONFIG_DDR_ECC)
ecc_init(CONFIG_SYS_SDRAM_BASE, CONFIG_SYS_MBYTES_SDRAM << 20);
#endif /* defined(CONFIG_DDR_ECC) */
#if defined(CONFIG_440)
/*
* Now after initialization (auto-calibration and ECC generation)
* remove the TLB entries with caches enabled and program again with
* desired cache functionality
*/
remove_tlb(0, (CONFIG_SYS_MBYTES_SDRAM << 20));
program_tlb(0, 0, (CONFIG_SYS_MBYTES_SDRAM << 20), MY_TLB_WORD2_I_ENABLE);
#endif
ppc4xx_ibm_ddr2_register_dump();
#if defined(CONFIG_PPC4xx_DDR_AUTOCALIBRATION)
/*
* Clear potential errors resulting from auto-calibration.
* If not done, then we could get an interrupt later on when
* exceptions are enabled.
*/
set_mcsr(get_mcsr());
#endif /* CONFIG_PPC4xx_DDR_AUTOCALIBRATION */
#endif /* !defined(CONFIG_NAND_U_BOOT) || defined(CONFIG_NAND_SPL) */
return (CONFIG_SYS_MBYTES_SDRAM << 20);
}
#endif /* CONFIG_SPD_EEPROM */
#if !defined(CONFIG_NAND_U_BOOT) && !defined(CONFIG_NAND_SPL)
#if defined(CONFIG_440)
u32 mfdcr_any(u32 dcr)
{
u32 val;
switch (dcr) {
case SDRAM_R0BAS + 0:
val = mfdcr(SDRAM_R0BAS + 0);
break;
case SDRAM_R0BAS + 1:
val = mfdcr(SDRAM_R0BAS + 1);
break;
case SDRAM_R0BAS + 2:
val = mfdcr(SDRAM_R0BAS + 2);
break;
case SDRAM_R0BAS + 3:
val = mfdcr(SDRAM_R0BAS + 3);
break;
default:
printf("DCR %d not defined in case statement!!!\n", dcr);
val = 0; /* just to satisfy the compiler */
}
return val;
}
void mtdcr_any(u32 dcr, u32 val)
{
switch (dcr) {
case SDRAM_R0BAS + 0:
mtdcr(SDRAM_R0BAS + 0, val);
break;
case SDRAM_R0BAS + 1:
mtdcr(SDRAM_R0BAS + 1, val);
break;
case SDRAM_R0BAS + 2:
mtdcr(SDRAM_R0BAS + 2, val);
break;
case SDRAM_R0BAS + 3:
mtdcr(SDRAM_R0BAS + 3, val);
break;
default:
printf("DCR %d not defined in case statement!!!\n", dcr);
}
}
#endif /* defined(CONFIG_440) */
void blank_string(int size)
{
int i;
for (i = 0; i < size; i++)
putc('\b');
for (i = 0; i < size; i++)
putc(' ');
for (i = 0; i < size; i++)
putc('\b');
}
#endif /* !defined(CONFIG_NAND_U_BOOT) && !defined(CONFIG_NAND_SPL) */
inline void ppc4xx_ibm_ddr2_register_dump(void)
{
#if defined(DEBUG)
printf("\nPPC4xx IBM DDR2 Register Dump:\n");
#if (defined(CONFIG_440SP) || defined(CONFIG_440SPE) || \
defined(CONFIG_460EX) || defined(CONFIG_460GT))
PPC4xx_IBM_DDR2_DUMP_MQ_REGISTER(R0BAS);
PPC4xx_IBM_DDR2_DUMP_MQ_REGISTER(R1BAS);
PPC4xx_IBM_DDR2_DUMP_MQ_REGISTER(R2BAS);
PPC4xx_IBM_DDR2_DUMP_MQ_REGISTER(R3BAS);
#endif /* (defined(CONFIG_440SP) || ... */
#if defined(CONFIG_405EX)
PPC4xx_IBM_DDR2_DUMP_REGISTER(BESR);
PPC4xx_IBM_DDR2_DUMP_REGISTER(BEARL);
PPC4xx_IBM_DDR2_DUMP_REGISTER(BEARH);
PPC4xx_IBM_DDR2_DUMP_REGISTER(WMIRQ);
PPC4xx_IBM_DDR2_DUMP_REGISTER(PLBOPT);
PPC4xx_IBM_DDR2_DUMP_REGISTER(PUABA);
#endif /* defined(CONFIG_405EX) */
PPC4xx_IBM_DDR2_DUMP_REGISTER(MB0CF);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MB1CF);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MB2CF);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MB3CF);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MCSTAT);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MCOPT1);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MCOPT2);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MODT0);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MODT1);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MODT2);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MODT3);
PPC4xx_IBM_DDR2_DUMP_REGISTER(CODT);
#if (defined(CONFIG_440SP) || defined(CONFIG_440SPE) || \
defined(CONFIG_460EX) || defined(CONFIG_460GT))
PPC4xx_IBM_DDR2_DUMP_REGISTER(VVPR);
PPC4xx_IBM_DDR2_DUMP_REGISTER(OPARS);
/*
* OPART is only used as a trigger register.
*
* No data is contained in this register, and reading or writing
* to is can cause bad things to happen (hangs). Just skip it and
* report "N/A".
*/
printf("%20s = N/A\n", "SDRAM_OPART");
#endif /* defined(CONFIG_440SP) || ... */
PPC4xx_IBM_DDR2_DUMP_REGISTER(RTR);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR0);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR1);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR2);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR3);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR4);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR5);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR6);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR7);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR8);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR9);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR10);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR11);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR12);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR13);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR14);
PPC4xx_IBM_DDR2_DUMP_REGISTER(INITPLR15);
PPC4xx_IBM_DDR2_DUMP_REGISTER(RQDC);
PPC4xx_IBM_DDR2_DUMP_REGISTER(RFDC);
PPC4xx_IBM_DDR2_DUMP_REGISTER(RDCC);
PPC4xx_IBM_DDR2_DUMP_REGISTER(DLCR);
PPC4xx_IBM_DDR2_DUMP_REGISTER(CLKTR);
PPC4xx_IBM_DDR2_DUMP_REGISTER(WRDTR);
PPC4xx_IBM_DDR2_DUMP_REGISTER(SDTR1);
PPC4xx_IBM_DDR2_DUMP_REGISTER(SDTR2);
PPC4xx_IBM_DDR2_DUMP_REGISTER(SDTR3);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MMODE);
PPC4xx_IBM_DDR2_DUMP_REGISTER(MEMODE);
PPC4xx_IBM_DDR2_DUMP_REGISTER(ECCCR);
#if (defined(CONFIG_440SP) || defined(CONFIG_440SPE) || \
defined(CONFIG_460EX) || defined(CONFIG_460GT))
PPC4xx_IBM_DDR2_DUMP_REGISTER(CID);
#endif /* defined(CONFIG_440SP) || ... */
PPC4xx_IBM_DDR2_DUMP_REGISTER(RID);
PPC4xx_IBM_DDR2_DUMP_REGISTER(FCSR);
PPC4xx_IBM_DDR2_DUMP_REGISTER(RTSR);
#endif /* defined(DEBUG) */
}
#endif /* CONFIG_SDRAM_PPC4xx_IBM_DDR2 */
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