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nest-open-source / nest-learning-thermostat / 5.8 / x-loader / refs/heads/master / . / x-loader / board / nest / j49-usb-loader / j49.c
blob: 9609bbc6d3e31aaae1b3322136ff9441a4398bf4 [file] [log] [blame]
/*
* Copyright (c) 2010-2011 Nest Labs, Inc.
*
* (C) Copyright 2006
* Texas Instruments, <www.ti.com>
* Jian Zhang <jzhang@ti.com>
* Richard Woodruff <r-woodruff2@ti.com>
*
* 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
*
* Description:
* This file is the board-specific set-up for the Nest Learning
* Thermostat board, based on the TI OMAP3 AM3703ACUS, focusing
* primarily on GPIO, RAM and flash initialization.
*
* This is inherited from the OMAP3 EVM equivalent file.
*
* Initialization function order is roughly:
*
* 1) s_init
* 2) board_init
* 3) misc_init_r
*/
#include <common.h>
#include <command.h>
#include <asm/io.h>
#include <asm/arch/cpu.h>
#include <asm/arch/bits.h>
#include <asm/arch/mux.h>
#include <asm/arch/sys_proto.h>
#include <asm/arch/sys_info.h>
#include <asm/arch/clocks.h>
#include <asm/arch/mem.h>
#include "platform.h"
#define MAX_J49_BOOT_DEVICES (3)
void
udelay(unsigned long usecs) {
delay(usecs);
}
static inline u32
get_cpu_id(void)
{
u32 cpuid = 0;
__asm__ __volatile__("mrc p15, 0, %0, c0, c0, 0":"=r" (cpuid));
return (cpuid);
}
/******************************************
* get_cpu_rev(void) - extract version info
******************************************/
u32
get_cpu_rev(void)
{
const u32 cpuid = get_cpu_id();
/* On ES1.0 the IDCODE register is not exposed on L4
* so using CPU ID to differentiate
* between ES2.0 and ES1.0.
*/
if ((cpuid & 0xf) == 0x0) {
return (CPU_3430_ES1);
} else {
return (CPU_3430_ES2);
}
}
u32
is_cpu_family(void)
{
const u32 cpuid = get_cpu_id();
u32 cpu_family = 0, omap34xx_id = 0;
u16 hawkeye;
if ((cpuid & 0xf) == 0x0) {
cpu_family = CPU_OMAP34XX;
} else {
omap34xx_id = __raw_readl(OMAP34XX_CONTROL_ID);
hawkeye = (omap34xx_id >> HAWKEYE_SHIFT) & 0xffff;
switch (hawkeye) {
case HAWKEYE_AM35XX:
cpu_family = CPU_AM35XX;
break;
case HAWKEYE_OMAP36XX:
cpu_family = CPU_OMAP36XX;
break;
case HAWKEYE_OMAP34XX:
default:
cpu_family = CPU_OMAP34XX;
break;
}
}
return (cpu_family);
}
/******************************************
* cpu_is_3410(void) - returns true for 3410
******************************************/
u32
cpu_is_3410(void)
{
int status;
if(get_cpu_rev() < CPU_3430_ES2) {
return 0;
} else {
/* read scalability status and return 1 for 3410*/
status = __raw_readl(CONTROL_SCALABLE_OMAP_STATUS);
/* Check whether MPU frequency is set to 266 MHz which
* is nominal for 3410. If yes return true else false
*/
if (((status >> 8) & 0x3) == 0x2)
return 1;
else
return 0;
}
}
/*
* void sr32()
*
* Description:
* This routine clears and sets a value in a bit extent for a
* 32-bit value at the specified address.
*
* Input(s):
* addr - The address at which to clear and set the specified
* specified 32-bit value.
* start_bit - The first bit of the 32-bit data to clear and set.
* num_bits - The range of bits of the 32-bit data to clear and set.
* value - The value to set.
*
* Output(s):
* addr - The address with the specified bit extent cleared and
* set to the specified value.
*
* Returns:
* N/A
*
*/
void
sr32(u32 addr, u32 start_bit, u32 num_bits, u32 value)
{
u32 tmp, msk = 0;
msk = (1 << num_bits);
--msk;
tmp = __raw_readl(addr) & ~(msk << start_bit);
tmp |= value << start_bit;
__raw_writel(tmp, addr);
}
/*
* u32 wait_on_value()
*
* Description:
* This routine reads the register at the specified address and
* busy waits until the specified match value is read or until the
* bounded number of loops have been reached.
*
* Input(s):
* read_bit_mask - The bit mask to apply after reading the register.
* match_value - The value to match on after reading and masking.
* read_addr - The register address to read.
* bound - The maximum number of times to read before giving
* up.
*
* Output(s):
* N/A
*
* Returns:
* True (1) if the match_value was reached; otherwise, false (0).
*
*/
u32
wait_on_value(u32 read_bit_mask, u32 match_value, u32 read_addr, u32 bound)
{
u32 i = 0, val;
do {
++i;
val = __raw_readl(read_addr) & read_bit_mask;
if (val == match_value)
return (1);
if (i == bound)
return (0);
} while (1);
}
/*****************************************
* Routine: secure_unlock
* Description: Setup security registers for access
* (GP Device only)
*****************************************/
static void
secure_unlock(void)
{
/* Permission values for registers -Full fledged permissions to all */
#define UNLOCK_1 0xFFFFFFFF
#define UNLOCK_2 0x00000000
#define UNLOCK_3 0x0000FFFF
/* Protection Module Register Target APE (PM_RT)*/
__raw_writel(UNLOCK_1, RT_REQ_INFO_PERMISSION_1);
__raw_writel(UNLOCK_1, RT_READ_PERMISSION_0);
__raw_writel(UNLOCK_1, RT_WRITE_PERMISSION_0);
__raw_writel(UNLOCK_2, RT_ADDR_MATCH_1);
__raw_writel(UNLOCK_3, GPMC_REQ_INFO_PERMISSION_0);
__raw_writel(UNLOCK_3, GPMC_READ_PERMISSION_0);
__raw_writel(UNLOCK_3, GPMC_WRITE_PERMISSION_0);
__raw_writel(UNLOCK_3, OCM_REQ_INFO_PERMISSION_0);
__raw_writel(UNLOCK_3, OCM_READ_PERMISSION_0);
__raw_writel(UNLOCK_3, OCM_WRITE_PERMISSION_0);
__raw_writel(UNLOCK_2, OCM_ADDR_MATCH_2);
/* IVA Changes */
__raw_writel(UNLOCK_3, IVA2_REQ_INFO_PERMISSION_0);
__raw_writel(UNLOCK_3, IVA2_READ_PERMISSION_0);
__raw_writel(UNLOCK_3, IVA2_WRITE_PERMISSION_0);
__raw_writel(UNLOCK_1, SMS_RG_ATT0); /* SDRC region 0 public */
}
/**********************************************************
* Routine: try_unlock_sram()
* Description: If chip is GP type, unlock the SRAM for
* general use.
***********************************************************/
static void
try_unlock_memory(void)
{
const int type = get_device_type();
/*
* If the processor is a GP device, unlock the device SRAM for
* general use.
*/
if (type == CONTROL_STATUS_DEVICETYPE_GP) {
secure_unlock();
}
return;
}
#if defined(CFG_SDRAM_DEBUG)
static void
omap3_sdrc_register_dump(void)
{
printf("\n SDRC Register Dump:\n");
DUMP_REGL(SDRC_REVISION);
DUMP_REGL(SDRC_SYSCONFIG);
DUMP_REGL(SDRC_SYSSTATUS);
DUMP_REGL(SDRC_CS_CFG);
DUMP_REGL(SDRC_SHARING);
DUMP_REGL(SDRC_ERR_ADDR);
DUMP_REGL(SDRC_ERR_TYPE);
DUMP_REGL(SDRC_DLLA_CTRL);
DUMP_REGL(SDRC_DLLA_STATUS);
DUMP_REGL(SDRC_POWER_REG);
DUMP_REGL(SDRC_MCFG_0);
DUMP_REGL(SDRC_MR_0);
DUMP_REGL(SDRC_EMR2_0);
DUMP_REGL(SDRC_ACTIM_CTRLA_0);
DUMP_REGL(SDRC_ACTIM_CTRLB_0);
DUMP_REGL(SDRC_RFR_CTRL_0);
DUMP_REGL(SDRC_MANUAL_0);
DUMP_REGL(SDRC_MCFG_1);
DUMP_REGL(SDRC_MR_1);
DUMP_REGL(SDRC_EMR2_1);
DUMP_REGL(SDRC_ACTIM_CTRLA_1);
DUMP_REGL(SDRC_ACTIM_CTRLB_1);
DUMP_REGL(SDRC_RFR_CTRL_1);
DUMP_REGL(SDRC_MANUAL_1);
}
#else
# define omap3_sdrc_register_dump() do { } while (0)
#endif /* defined(CFG_SDRAM_DEBUG) */
#if defined(CFG_GPMC_DEBUG)
static void
omap3_gpmc_register_dump(void)
{
printf("\n GPMC Register Dump:\n");
DUMP_REGL(GPMC_REVISION);
DUMP_REGL(GPMC_SYSCONFIG);
DUMP_REGL(GPMC_SYSSTATUS);
DUMP_REGL(GPMC_IRQSTATUS);
DUMP_REGL(GPMC_IRQENABLE);
DUMP_REGL(GPMC_TIMEOUT_CONTROL);
DUMP_REGL(GPMC_ERR_ADDRESS);
DUMP_REGL(GPMC_ERR_TYPE );
DUMP_REGL(GPMC_CONFIG );
DUMP_REGL(GPMC_STATUS );
DUMP_REGL(GPMC_CONFIG1_0);
DUMP_REGL(GPMC_CONFIG2_0);
DUMP_REGL(GPMC_CONFIG3_0);
DUMP_REGL(GPMC_CONFIG4_0);
DUMP_REGL(GPMC_CONFIG5_0);
DUMP_REGL(GPMC_CONFIG6_0);
DUMP_REGL(GPMC_CONFIG7_0);
DUMP_REGL(GPMC_CONFIG1_1);
DUMP_REGL(GPMC_CONFIG2_1);
DUMP_REGL(GPMC_CONFIG3_1);
DUMP_REGL(GPMC_CONFIG4_1);
DUMP_REGL(GPMC_CONFIG5_1);
DUMP_REGL(GPMC_CONFIG6_1);
DUMP_REGL(GPMC_CONFIG7_1);
DUMP_REGL(GPMC_CONFIG1_2);
DUMP_REGL(GPMC_CONFIG2_2);
DUMP_REGL(GPMC_CONFIG3_2);
DUMP_REGL(GPMC_CONFIG5_2);
DUMP_REGL(GPMC_CONFIG4_2);
DUMP_REGL(GPMC_CONFIG6_2);
DUMP_REGL(GPMC_CONFIG7_2);
DUMP_REGL(GPMC_CONFIG1_3);
DUMP_REGL(GPMC_CONFIG2_3);
DUMP_REGL(GPMC_CONFIG3_3);
DUMP_REGL(GPMC_CONFIG4_3);
DUMP_REGL(GPMC_CONFIG5_3);
DUMP_REGL(GPMC_CONFIG6_3);
DUMP_REGL(GPMC_CONFIG7_3);
DUMP_REGL(GPMC_CONFIG1_4);
DUMP_REGL(GPMC_CONFIG2_4);
DUMP_REGL(GPMC_CONFIG3_4);
DUMP_REGL(GPMC_CONFIG4_4);
DUMP_REGL(GPMC_CONFIG5_4);
DUMP_REGL(GPMC_CONFIG6_4);
DUMP_REGL(GPMC_CONFIG7_4);
DUMP_REGL(GPMC_CONFIG1_5);
DUMP_REGL(GPMC_CONFIG2_5);
DUMP_REGL(GPMC_CONFIG3_5);
DUMP_REGL(GPMC_CONFIG4_5);
DUMP_REGL(GPMC_CONFIG5_5);
DUMP_REGL(GPMC_CONFIG6_5);
DUMP_REGL(GPMC_CONFIG7_5);
DUMP_REGL(GPMC_CONFIG1_6);
DUMP_REGL(GPMC_CONFIG2_6);
DUMP_REGL(GPMC_CONFIG3_6);
DUMP_REGL(GPMC_CONFIG4_6);
DUMP_REGL(GPMC_CONFIG5_6);
DUMP_REGL(GPMC_CONFIG6_6);
DUMP_REGL(GPMC_CONFIG7_6);
DUMP_REGL(GPMC_CONFIG1_7);
DUMP_REGL(GPMC_CONFIG2_7);
DUMP_REGL(GPMC_CONFIG3_7);
DUMP_REGL(GPMC_CONFIG4_7);
DUMP_REGL(GPMC_CONFIG5_7);
DUMP_REGL(GPMC_CONFIG6_7);
DUMP_REGL(GPMC_CONFIG7_7);
#if 0
DUMP_REGL(GPMC_NAND_COMMAND_0);
DUMP_REGL(GPMC_NAND_COMMAND_1);
DUMP_REGL(GPMC_NAND_COMMAND_2);
DUMP_REGL(GPMC_NAND_COMMAND_3);
DUMP_REGL(GPMC_NAND_COMMAND_4);
DUMP_REGL(GPMC_NAND_COMMAND_5);
DUMP_REGL(GPMC_NAND_COMMAND_6);
DUMP_REGL(GPMC_NAND_COMMAND_7);
DUMP_REGL(GPMC_NAND_ADDRESS_0);
DUMP_REGL(GPMC_NAND_ADDRESS_1);
DUMP_REGL(GPMC_NAND_ADDRESS_2);
DUMP_REGL(GPMC_NAND_ADDRESS_3);
DUMP_REGL(GPMC_NAND_ADDRESS_4);
DUMP_REGL(GPMC_NAND_ADDRESS_5);
DUMP_REGL(GPMC_NAND_ADDRESS_6);
DUMP_REGL(GPMC_NAND_ADDRESS_7);
DUMP_REGL(GPMC_NAND_DATA_0);
DUMP_REGL(GPMC_NAND_DATA_1);
DUMP_REGL(GPMC_NAND_DATA_2);
DUMP_REGL(GPMC_NAND_DATA_3);
DUMP_REGL(GPMC_NAND_DATA_4);
DUMP_REGL(GPMC_NAND_DATA_5);
DUMP_REGL(GPMC_NAND_DATA_6);
DUMP_REGL(GPMC_NAND_DATA_7);
DUMP_REGL(GPMC_PREFETCH_CONFIG1);
DUMP_REGL(GPMC_PREFETCH_CONFIG2);
DUMP_REGL(GPMC_PREFETCH_CONTROL);
DUMP_REGL(GPMC_PREFETCH_STATUS);
DUMP_REGL(GPMC_ECC_CONFIG);
DUMP_REGL(GPMC_ECC_CONTROL);
DUMP_REGL(GPMC_ECC_SIZE_CONFIG);
DUMP_REGL(GPMC_ECC1_RESULT);
DUMP_REGL(GPMC_ECC2_RESULT);
DUMP_REGL(GPMC_ECC3_RESULT);
DUMP_REGL(GPMC_ECC4_RESULT);
DUMP_REGL(GPMC_ECC5_RESULT);
DUMP_REGL(GPMC_ECC6_RESULT);
DUMP_REGL(GPMC_ECC7_RESULT);
DUMP_REGL(GPMC_ECC8_RESULT);
DUMP_REGL(GPMC_ECC9_RESULT);
DUMP_REGL(GPMC_BCH_RESULT0_0);
DUMP_REGL(GPMC_BCH_RESULT0_1);
DUMP_REGL(GPMC_BCH_RESULT0_2);
DUMP_REGL(GPMC_BCH_RESULT0_3);
DUMP_REGL(GPMC_BCH_RESULT0_4);
DUMP_REGL(GPMC_BCH_RESULT0_5);
DUMP_REGL(GPMC_BCH_RESULT0_6);
DUMP_REGL(GPMC_BCH_RESULT0_7);
DUMP_REGL(GPMC_BCH_RESULT1_0);
DUMP_REGL(GPMC_BCH_RESULT1_1);
DUMP_REGL(GPMC_BCH_RESULT1_2);
DUMP_REGL(GPMC_BCH_RESULT1_3);
DUMP_REGL(GPMC_BCH_RESULT1_4);
DUMP_REGL(GPMC_BCH_RESULT1_5);
DUMP_REGL(GPMC_BCH_RESULT1_6);
DUMP_REGL(GPMC_BCH_RESULT1_7);
DUMP_REGL(GPMC_BCH_RESULT2_0);
DUMP_REGL(GPMC_BCH_RESULT2_1);
DUMP_REGL(GPMC_BCH_RESULT2_2);
DUMP_REGL(GPMC_BCH_RESULT2_3);
DUMP_REGL(GPMC_BCH_RESULT2_4);
DUMP_REGL(GPMC_BCH_RESULT2_5);
DUMP_REGL(GPMC_BCH_RESULT2_6);
DUMP_REGL(GPMC_BCH_RESULT2_7);
DUMP_REGL(GPMC_BCH_RESULT3_0);
DUMP_REGL(GPMC_BCH_RESULT3_1);
DUMP_REGL(GPMC_BCH_RESULT3_2);
DUMP_REGL(GPMC_BCH_RESULT3_3);
DUMP_REGL(GPMC_BCH_RESULT3_4);
DUMP_REGL(GPMC_BCH_RESULT3_5);
DUMP_REGL(GPMC_BCH_RESULT3_6);
DUMP_REGL(GPMC_BCH_RESULT3_7);
DUMP_REGL(GPMC_BCH_SWDATA);
#endif
}
#else
# define omap3_gpmc_register_dump() do { } while (0)
#endif /* defined(CFG_NAND_DEBUG) */
#if defined(CFG_PRCM_DEBUG)
static void
omap3_prcm_register_dump(void)
{
printf("\n PRCM Register Dump:\n");
DUMP_REGL(PRCM_PRM_CCR_CLKSEL);
DUMP_REGL(PRCM_PRM_GR_CLKSRC_CTRL);
DUMP_REGL(CM_CLKSEL1_PLL);
DUMP_REGL(CM_CLKSEL2_PLL);
DUMP_REGL(CM_CLKSEL3_PLL);
DUMP_REGL(CM_CLKEN_PLL);
DUMP_REGL(CM_CLKSEL1_PLL_MPU);
DUMP_REGL(CM_CLKSEL2_PLL_MPU);
DUMP_REGL(CM_CLKEN_PLL_MPU);
DUMP_REGL(CM_CLKSEL1_PLL_IVA2);
DUMP_REGL(CM_CLKSEL2_PLL_IVA2);
DUMP_REGL(CM_CLKEN_PLL_IVA2);
DUMP_REGL(CM_CLKSEL_CAM);
DUMP_REGL(CM_CLKSEL_CORE);
DUMP_REGL(CM_CLKSEL_DSS);
DUMP_REGL(CM_CLKSEL1_EMU);
}
#else
#define omap3_prcm_register_dump() do { } while (0)
#endif /* CFG_PRCM_DEBUG */
/*
* void config_diamond_sdram()
*
* Description:
* This routine initializes the processor's SDRAM Controller (SDRC)
* as appropriate for the Samsung K4X51163PI-FCG6 32 Mb x 16 b (64
* MiB) DDR SDRAM on the Nest Learning Thermostat board.
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* N/A
*
*/
void
config_diamond_sdram(void)
{
u32 value, actim_ctrla, actim_ctrlb;
/*
* Step 1: Reset the SDRC controller and then wait for the reset
* event to clear.
*/
__raw_writel(SDRC_SYSCONFIG_SOFTRESET_SET, SDRC_SYSCONFIG);
wait_on_value(SDRC_SYSSTATUS_RESETDONE,
SDRC_SYSSTATUS_RESETDONE,
SDRC_STATUS,
12000000);
__raw_writel(SDRC_SYSCONFIG_SOFTRESET_CLEAR, SDRC_SYSCONFIG);
/*
* Step 2: Setup the position and geometry of the SDRAM device on
* the controller's bus.
*/
value =
(SDRC_SHARING_LOCK_OFF |
SDRC_SHARING_CS1MUXCFG_ENCODE(SDRC_SHARING_CS1MUXCFG_16_BIT_16_0) |
SDRC_SHARING_CS0MUXCFG_ENCODE(SDRC_SHARING_CS0MUXCFG_16_BIT_16_0) |
SDRC_SHARING_SDRCTRISTATE_OFF);
__raw_writel(value, SDRC_SHARING);
/*
* Step 3: Setup the memory configuration, including RAS width,
* CAS width, address multiplexing, size, bank mapping, bus width,
* power mode, DDR type and memory type.
*/
value =
(SDRC_MCFG_LOCKSTATUS_RW |
SDRC_MCFG_RASWIDTH_ENCODE(SDRC_MCFG_RASWIDTH_14_BITS) |
SDRC_MCFG_CASWIDTH_ENCODE(SDRC_MCFG_CASWIDTH_10_BITS) |
SDRC_MCFG_ADDRMUXLEGACY_FLEXIBLE |
SDRC_MCFG_RAMSIZE_ENCODE(CFG_SDRAM_SIZE_MB) |
SDRC_MCFG_BANKALLOCATION_ENCODE(SDRC_MCFG_BANKALLOCATION_R_B_C)|
SDRC_MCFG_B32NOT16_OFF |
SDRC_MCFG_DEEPPD_SUPPORTED |
SDRC_MCFG_DDRTYPE_ENCODE(SDRC_MCFG_DDRTYPE_MOBILE_DDR) |
SDRC_MCFG_RAMTYPE_ENCODE(SDRC_MCFG_RAMTYPE_DDR));
__raw_writel(value, SDRC_MCFG_0);
/*
* Step 4: Establish the AC fine tuning timing characteristics.
*/
actim_ctrla
= (SDRC_ACTIM_CTRLA_TRFC_ENCODE(CFG_SDRC_ACTIM_CTRLA_TRFC) |
SDRC_ACTIM_CTRLA_TRC_ENCODE(CFG_SDRC_ACTIM_CTRLA_TRC) |
SDRC_ACTIM_CTRLA_TRAS_ENCODE(CFG_SDRC_ACTIM_CTRLA_TRAS) |
SDRC_ACTIM_CTRLA_TRP_ENCODE(CFG_SDRC_ACTIM_CTRLA_TRP) |
SDRC_ACTIM_CTRLA_TRCD_ENCODE(CFG_SDRC_ACTIM_CTRLA_TRCD) |
SDRC_ACTIM_CTRLA_TRRD_ENCODE(CFG_SDRC_ACTIM_CTRLA_TRRD) |
SDRC_ACTIM_CTRLA_TDPL_ENCODE(CFG_SDRC_ACTIM_CTRLA_TDPL) |
SDRC_ACTIM_CTRLA_TDAL_ENCODE(CFG_SDRC_ACTIM_CTRLA_TDAL));
actim_ctrlb
= (SDRC_ACTIM_CTRLB_TWTR_ENCODE(CFG_SDRC_ACTIM_CTRLB_TWTR) |
SDRC_ACTIM_CTRLB_TCKE_ENCODE(CFG_SDRC_ACTIM_CTRLB_TCKE) |
SDRC_ACTIM_CTRLB_TXP_ENCODE(CFG_SDRC_ACTIM_CTRLB_TXP) |
SDRC_ACTIM_CTRLB_TXSR_ENCODE(CFG_SDRC_ACTIM_CTRLB_TXSR));
__raw_writel(actim_ctrla, SDRC_ACTIM_CTRLA_0);
__raw_writel(actim_ctrlb, SDRC_ACTIM_CTRLB_0);
/*
* Step 5: Establish the memory autorefresh control
*/
value =
(SDRC_RFR_CTRL_ARCV_ENCODE(1244) |
SDRC_RFR_CTRL_ARE_ENCODE(SDRC_RFR_CTRL_ARE_1_ARCV));
__raw_writel(value, SDRC_RFR_CTRL_0);
value =
(SDRC_POWER_REG_WAKEUP_DELAYED |
SDRC_POWER_REG_AUTOCOUNT_ENCODE(0) |
SDRC_POWER_REG_SRFR_ON_RST_ENABLE |
SDRC_POWER_REG_SRFR_ON_IDLE_DISABLE |
SDRC_POWER_REG_CLKCTRL_ENCODE(SDRC_POWER_REG_CLKCTRL_NONE) |
SDRC_POWER_REG_PAGEPOLICY_HPHB);
__raw_writel(value, SDRC_POWER_REG);
/*
* Step 6: Establish the JEDEC-defined mode and DLL parameters.
*/
__raw_writel(SDRC_MANUAL_CMDCODE_ENCODE(SDRC_MANUAL_CMDCODE_AUTOREFRESH),
SDRC_MANUAL_0);
delay(5000);
__raw_writel(SDRC_MANUAL_CMDCODE_ENCODE(SDRC_MANUAL_CMDCODE_PRECHARGE_ALL),
SDRC_MANUAL_0);
__raw_writel(SDRC_MANUAL_CMDCODE_ENCODE(SDRC_MANUAL_CMDCODE_AUTOREFRESH),
SDRC_MANUAL_0);
__raw_writel(SDRC_MANUAL_CMDCODE_ENCODE(SDRC_MANUAL_CMDCODE_AUTOREFRESH),
SDRC_MANUAL_0);
value =
(SDRC_MR_ZERO_1 |
SDRC_MR_WBST_ENABLE |
SDRC_MR_ZERO_0 |
SDRC_MR_CASL_ENCODE(SDRC_MR_CASL_3) |
SDRC_MR_SIL_SERIAL |
SDRC_MR_BL_ENCODE(SDRC_MR_BL_4));
__raw_writel(value, SDRC_MR_0);
value =
(SDRC_DLLA_CTRL_FIXED_DELAY_ENCODE(0) |
SDRC_DLLA_CTRL_INIT_LAT_ENCODE(0) |
SDRC_DLLA_CTRL_MODE_ON_IDLE_ENCODE(SDRC_DLLA_CTRL_MODE_ON_IDLE_PWD) |
SDRC_DLLA_CTRL_DLL_ENABLE |
SDRC_DLLA_CTRL_LOCK_TRACKINGDELAY);
__raw_writel(value, SDRC_DLLA_CTRL);
/*
* Delay for a "reasonably long" period of time to allow the
* requested changes to take effect.
*/
delay(0x20000);
}
/*
* void s_init()
*
* Description:
* This routine performs very early system initialization of chip
* pin multiplexing and clocks and is called when ONLY an
* SRAM-based stack is available (i.e. no SDRAM).
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* N/A
*
*/
void
s_init(void)
{
watchdog_init();
try_unlock_memory();
set_muxconf_regs();
delay(100);
prcm_init();
per_clocks_enable();
config_diamond_sdram();
}
/*
* int board_init()
*
* Description:
* This routine performs any early, board-specific initialization
* following core CPU initialization but prior to serial and NAND
* initialization.
*
* At present, there is nothing board-specific to do.
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* 0 if OK; otherwise, non-zero on error.
*
*/
int
board_init(void)
{
return (0);
}
/*
* u32 get_device_type()
*
* Description:
* This routine returns the decoded value from the CPU's
* CONTROL_STATUS register DEVICETYPE field, indicating whether the
* device is of TST, EMU, HS or GP type.
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* The decoded CONTROL_STATUS register DEVICETYPE field.
*
*/
u32
get_device_type(void)
{
const int value = __raw_readl(CONTROL_STATUS);
return (CONTROL_STATUS_DEVICETYPE_DECODE(value));
}
/*
* u32 get_sysboot_value()
*
* Description:
* This routine returns the decoded value from the CPU's
* CONTROL_STATUS register SYSBOOT order subfield, indicating the
* order of memory interfaces from which the processor will attempt
* to boot itself.
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* The decoded CONTROL_STATUS register SYSBOOT order subfield.
*
*/
u32
get_sysboot_value(void)
{
#if 0
const u32 value = __raw_readl(CONTROL_STATUS);
const u32 peripheral_type = CONTROL_STATUS_SYSBOOT_TYPE_PERIPHERAL;
/*
* This routine and callers of it are implicitly expecting the
* MEMORY interface (SYSBOOT[5] == 0) not the PERHIPHERAL
* interface (SYSBOOT[5] == 1) boot order, so check that is
* actually the case.
*/
if (CONTROL_STATUS_SYSBOOT_TYPE_DECODE(value) == peripheral_type) {
hang();
}
return (CONTROL_STATUS_SYSBOOT_ORDER_DECODE(value));
#else
return __raw_readl(CONTROL_STATUS) & 0x3f;
#endif
}
/*
* int get_boot_device_list(const u32** device_list)
*
* Description:
* This routine returns a constant list indicating the preferred
* device boot list.
* It gets called from start_armboot in board.c
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* The preferred first processor memory boot interface.
*
*/
int
get_boot_devices_list(const u32** devices_list)
{
static u32 list[MAX_J49_BOOT_DEVICES];
const u32 mem_order = get_sysboot_value();
// set defaults
int number_of_devices = 0;
*devices_list = &list[0];
switch (mem_order) {
case 15:
list[0] = GPMC_NAND;
list[1] = USB_PERIPHERAL;
list[2] = MMC_NAND;
number_of_devices = MAX_J49_BOOT_DEVICES;
break;
case 47:
list[0] = USB_PERIPHERAL;
list[1] = MMC_NAND;
list[2] = GPMC_NAND;
number_of_devices = MAX_J49_BOOT_DEVICES;
break;
default:
break;
}
return number_of_devices;
}
/*
* int misc_init_r()
*
* Description:
* This routine performs any miscellaneous, board-specific
* initialization following CPU, early board, serial and NAND
* initialization but prior to loading the secondary program loader
* to RAM.
*
* At present, there is nothing board-specific to do.
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* 0 if OK; otherwise, non-zero on error.
*
*/
int
misc_init_r(void)
{
return (0);
}
/******************************************************
* Routine: wait_for_command_complete
* Description: Wait for posting to finish on watchdog
******************************************************/
static void
wait_for_command_complete(unsigned int wd_base)
{
int pending = 1;
do {
pending = __raw_readl(wd_base + WWPS);
} while (pending);
}
/****************************************
* Routine: watchdog_init
* Description: Shut down watch dogs
*****************************************/
void
watchdog_init(void)
{
/* There are 3 watch dogs WD1=Secure, WD2=MPU, WD3=IVA. WD1 is
* either taken care of by ROM (HS/EMU) or not accessible (GP).
* We need to take care of WD2-MPU or take a PRCM reset. WD3
* should not be running and does not generate a PRCM reset.
*/
sr32(CM_FCLKEN_WKUP, 5, 1, 1);
sr32(CM_ICLKEN_WKUP, 5, 1, 1);
wait_on_value(BIT5, 0x20, CM_IDLEST_WKUP, 5); /* some issue here */
__raw_writel(WD_UNLOCK1, WD2_BASE + WSPR);
wait_for_command_complete(WD2_BASE);
__raw_writel(WD_UNLOCK2, WD2_BASE + WSPR);
}
/*****************************************************************
* Routine: peripheral_enable
* Description: Enable the clks & power for perifs (GPT2, UART1,...)
******************************************************************/
/*
* void foobar()
*
* Description:
* This routine...
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* N/A
*
*/
void
per_clocks_enable(void)
{
/* Enable GP2 timer. */
sr32(CM_CLKSEL_PER, 0, 1, 0x1); /* GPT2 = sys clk */
sr32(CM_ICLKEN_PER, 3, 1, 0x1); /* ICKen GPT2 */
sr32(CM_FCLKEN_PER, 3, 1, 0x1); /* FCKen GPT2 */
#ifdef CFG_NS16550
/* Enable UART1 clocks */
sr32(CM_FCLKEN1_CORE, 13, 1, 0x1);
sr32(CM_ICLKEN1_CORE, 13, 1, 0x1);
#endif
#ifdef CONFIG_MMC
/* Enable MMC1 clocks */
sr32(CM_FCLKEN1_CORE, 24, 1, 0x1);
sr32(CM_ICLKEN1_CORE, 24, 1, 0x1);
#endif
delay(1000);
}
static int
gpmc_config_0(void)
{
#if defined(CFG_GPMC_CONFIG1_0)
/*
* First, disable the interface and wait.
*/
__raw_writel(GPMC_CONFIG7_CSVALID_DISABLED, GPMC_CONFIG7_0);
delay(1000);
/*
* Next, program the configuration parameters.
*/
__raw_writel(CFG_GPMC_CONFIG1_0, GPMC_CONFIG1_0);
__raw_writel(CFG_GPMC_CONFIG2_0, GPMC_CONFIG2_0);
__raw_writel(CFG_GPMC_CONFIG3_0, GPMC_CONFIG3_0);
__raw_writel(CFG_GPMC_CONFIG4_0, GPMC_CONFIG4_0);
__raw_writel(CFG_GPMC_CONFIG5_0, GPMC_CONFIG5_0);
__raw_writel(CFG_GPMC_CONFIG6_0, GPMC_CONFIG6_0);
/*
* Finally, enable the GPMC mapping and spin for the parameters to
* become active.
*/
__raw_writel((CFG_GPMC_CONFIG7_0 | GPMC_CONFIG7_CSVALID_ENABLED),
GPMC_CONFIG7_0);
delay(2000);
if (nand_chip()){
return (1);
}
#endif /* defined(CFG_GPMC_CONFIG1_0) */
return (0);
}
/*
* int nand_init()
*
* Description:
* This routine initializes the General Purpose Memory Controller
* (GPMC) such that on-board NAND devices may be accessed for
* second-stage boot.
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* 0 if NAND was successfully initialized; otherwise, 1.
*
*/
int
nand_init(void)
{
int status = 1;
/*
* Establish GPMC global settings.
*/
__raw_writel(GPMC_SYSCONFIG_IDLEMODE_SMART, GPMC_SYSCONFIG);
__raw_writel(GPMC_IRQENABLE_ALL_DISABLE, GPMC_IRQENABLE);
__raw_writel(GPMC_TIMEOUTENABLE_OFF, GPMC_TIMEOUT_CONTROL);
if (gpmc_config_0()) {
puts("Unsupported NAND device @ GPMC0!\n");
goto done;
}
status = 0;
done:
/* Dump GPMC and SDRC registers if so configured. */
omap3_sdrc_register_dump();
omap3_gpmc_register_dump();
omap3_prcm_register_dump();
return (status);
}
/*
* void board_hang()
*
* Description:
* This routine performs any board-specific actions when the system
* hangs by executing hang(). At present, there is nothing to do;
* however, we might later drive the piezo or a LED.
*
* Input(s):
* N/A
*
* Output(s):
* N/A
*
* Returns:
* N/A
*
*/
void
board_hang (void)
{
return;
}