Commit ef509b90 authored by Vitaly Andrianov's avatar Vitaly Andrianov Committed by Tom Rini

k2hk: add support for k2hk SOC and EVM

k2hk EVM is based on Texas Instruments Keystone2 Hawking/Kepler
SoC. Keystone2 SoC has ARM v7 Cortex-A15 MPCore processor. Please
refer the ti/k2hk_evm/README for details on the board, build and other
information.

This patch add support for keystone architecture and k2hk evm.
Signed-off-by: default avatarVitaly Andrianov <vitalya@ti.com>
Signed-off-by: default avatarMurali Karicheri <m-karicheri2@ti.com>
Signed-off-by: default avatarWingMan Kwok <w-kwok2@ti.com>
Signed-off-by: default avatarSandeep Nair <sandeep_n@ti.com>
parent e8459dcc
......@@ -870,6 +870,16 @@ OBJCOPYFLAGS_u-boot.spr = -I binary -O binary --pad-to=$(CONFIG_SPL_PAD_TO) \
u-boot.spr: spl/u-boot-spl.img u-boot.img FORCE
$(call if_changed,pad_cat)
MKIMAGEFLAGS_u-boot-spl.gph = -A $(ARCH) -T gpimage -C none \
-a $(CONFIG_SPL_TEXT_BASE) -e $(CONFIG_SPL_TEXT_BASE) -n SPL
spl/u-boot-spl.gph: spl/u-boot-spl.bin FORCE
$(call if_changed,mkimage)
OBJCOPYFLAGS_u-boot-spi.gph = -I binary -O binary --pad-to=$(CONFIG_SPL_PAD_TO) \
--gap-fill=0
u-boot-spi.gph: spl/u-boot-spl.gph u-boot.img FORCE
$(call if_changed,pad_cat)
ifneq ($(CONFIG_TEGRA),)
OBJCOPYFLAGS_u-boot-nodtb-tegra.bin = -O binary --pad-to=$(CONFIG_SYS_TEXT_BASE)
u-boot-nodtb-tegra.bin: spl/u-boot-spl u-boot.bin FORCE
......
#
# (C) Copyright 2012-2014
# Texas Instruments Incorporated, <www.ti.com>
#
# SPDX-License-Identifier: GPL-2.0+
#
obj-y += aemif.o
obj-y += init.o
obj-y += psc.o
obj-y += clock.o
obj-y += cmd_clock.o
obj-y += cmd_mon.o
obj-y += msmc.o
obj-$(CONFIG_SPL_BUILD) += spl.o
obj-y += ddr3.o
/*
* Keystone2: Asynchronous EMIF Configuration
*
* (C) Copyright 2012-2014
* Texas Instruments Incorporated, <www.ti.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <asm/io.h>
#include <asm/arch/clock.h>
#include <asm/arch/emif_defs.h>
#define AEMIF_CFG_SELECT_STROBE(v) ((v) ? 1 << 31 : 0)
#define AEMIF_CFG_EXTEND_WAIT(v) ((v) ? 1 << 30 : 0)
#define AEMIF_CFG_WR_SETUP(v) (((v) & 0x0f) << 26)
#define AEMIF_CFG_WR_STROBE(v) (((v) & 0x3f) << 20)
#define AEMIF_CFG_WR_HOLD(v) (((v) & 0x07) << 17)
#define AEMIF_CFG_RD_SETUP(v) (((v) & 0x0f) << 13)
#define AEMIF_CFG_RD_STROBE(v) (((v) & 0x3f) << 7)
#define AEMIF_CFG_RD_HOLD(v) (((v) & 0x07) << 4)
#define AEMIF_CFG_TURN_AROUND(v) (((v) & 0x03) << 2)
#define AEMIF_CFG_WIDTH(v) (((v) & 0x03) << 0)
#define set_config_field(reg, field, val) \
do { \
if (val != -1) { \
reg &= ~AEMIF_CFG_##field(0xffffffff); \
reg |= AEMIF_CFG_##field(val); \
} \
} while (0)
void configure_async_emif(int cs, struct async_emif_config *cfg)
{
unsigned long tmp;
if (cfg->mode == ASYNC_EMIF_MODE_NAND) {
tmp = __raw_readl(&davinci_emif_regs->nandfcr);
tmp |= (1 << cs);
__raw_writel(tmp, &davinci_emif_regs->nandfcr);
} else if (cfg->mode == ASYNC_EMIF_MODE_ONENAND) {
tmp = __raw_readl(&davinci_emif_regs->one_nand_cr);
tmp |= (1 << cs);
__raw_writel(tmp, &davinci_emif_regs->one_nand_cr);
}
tmp = __raw_readl(&davinci_emif_regs->abncr[cs]);
set_config_field(tmp, SELECT_STROBE, cfg->select_strobe);
set_config_field(tmp, EXTEND_WAIT, cfg->extend_wait);
set_config_field(tmp, WR_SETUP, cfg->wr_setup);
set_config_field(tmp, WR_STROBE, cfg->wr_strobe);
set_config_field(tmp, WR_HOLD, cfg->wr_hold);
set_config_field(tmp, RD_SETUP, cfg->rd_setup);
set_config_field(tmp, RD_STROBE, cfg->rd_strobe);
set_config_field(tmp, RD_HOLD, cfg->rd_hold);
set_config_field(tmp, TURN_AROUND, cfg->turn_around);
set_config_field(tmp, WIDTH, cfg->width);
__raw_writel(tmp, &davinci_emif_regs->abncr[cs]);
}
void init_async_emif(int num_cs, struct async_emif_config *config)
{
int cs;
for (cs = 0; cs < num_cs; cs++)
configure_async_emif(cs, config + cs);
}
/*
* Keystone2: pll initialization
*
* (C) Copyright 2012-2014
* Texas Instruments Incorporated, <www.ti.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <asm-generic/errno.h>
#include <asm/io.h>
#include <asm/processor.h>
#include <asm/arch/clock.h>
#include <asm/arch/clock_defs.h>
static void wait_for_completion(const struct pll_init_data *data)
{
int i;
for (i = 0; i < 100; i++) {
sdelay(450);
if ((pllctl_reg_read(data->pll, stat) & PLLSTAT_GO) == 0)
break;
}
}
struct pll_regs {
u32 reg0, reg1;
};
static const struct pll_regs pll_regs[] = {
[CORE_PLL] = { K2HK_MAINPLLCTL0, K2HK_MAINPLLCTL1},
[PASS_PLL] = { K2HK_PASSPLLCTL0, K2HK_PASSPLLCTL1},
[TETRIS_PLL] = { K2HK_ARMPLLCTL0, K2HK_ARMPLLCTL1},
[DDR3A_PLL] = { K2HK_DDR3APLLCTL0, K2HK_DDR3APLLCTL1},
[DDR3B_PLL] = { K2HK_DDR3BPLLCTL0, K2HK_DDR3BPLLCTL1},
};
/* Fout = Fref * NF(mult) / NR(prediv) / OD */
static unsigned long pll_freq_get(int pll)
{
unsigned long mult = 1, prediv = 1, output_div = 2;
unsigned long ret;
u32 tmp, reg;
if (pll == CORE_PLL) {
ret = external_clk[sys_clk];
if (pllctl_reg_read(pll, ctl) & PLLCTL_PLLEN) {
/* PLL mode */
tmp = __raw_readl(K2HK_MAINPLLCTL0);
prediv = (tmp & PLL_DIV_MASK) + 1;
mult = (((tmp & PLLM_MULT_HI_SMASK) >> 6) |
(pllctl_reg_read(pll, mult) &
PLLM_MULT_LO_MASK)) + 1;
output_div = ((pllctl_reg_read(pll, secctl) >>
PLL_CLKOD_SHIFT) & PLL_CLKOD_MASK) + 1;
ret = ret / prediv / output_div * mult;
}
} else {
switch (pll) {
case PASS_PLL:
ret = external_clk[pa_clk];
reg = K2HK_PASSPLLCTL0;
break;
case TETRIS_PLL:
ret = external_clk[tetris_clk];
reg = K2HK_ARMPLLCTL0;
break;
case DDR3A_PLL:
ret = external_clk[ddr3a_clk];
reg = K2HK_DDR3APLLCTL0;
break;
case DDR3B_PLL:
ret = external_clk[ddr3b_clk];
reg = K2HK_DDR3BPLLCTL0;
break;
default:
return 0;
}
tmp = __raw_readl(reg);
if (!(tmp & PLLCTL_BYPASS)) {
/* Bypass disabled */
prediv = (tmp & PLL_DIV_MASK) + 1;
mult = ((tmp >> PLL_MULT_SHIFT) & PLL_MULT_MASK) + 1;
output_div = ((tmp >> PLL_CLKOD_SHIFT) &
PLL_CLKOD_MASK) + 1;
ret = ((ret / prediv) * mult) / output_div;
}
}
return ret;
}
unsigned long clk_get_rate(unsigned int clk)
{
switch (clk) {
case core_pll_clk: return pll_freq_get(CORE_PLL);
case pass_pll_clk: return pll_freq_get(PASS_PLL);
case tetris_pll_clk: return pll_freq_get(TETRIS_PLL);
case ddr3a_pll_clk: return pll_freq_get(DDR3A_PLL);
case ddr3b_pll_clk: return pll_freq_get(DDR3B_PLL);
case sys_clk0_1_clk:
case sys_clk0_clk: return pll_freq_get(CORE_PLL) / pll0div_read(1);
case sys_clk1_clk: return pll_freq_get(CORE_PLL) / pll0div_read(2);
case sys_clk2_clk: return pll_freq_get(CORE_PLL) / pll0div_read(3);
case sys_clk3_clk: return pll_freq_get(CORE_PLL) / pll0div_read(4);
case sys_clk0_2_clk: return clk_get_rate(sys_clk0_clk) / 2;
case sys_clk0_3_clk: return clk_get_rate(sys_clk0_clk) / 3;
case sys_clk0_4_clk: return clk_get_rate(sys_clk0_clk) / 4;
case sys_clk0_6_clk: return clk_get_rate(sys_clk0_clk) / 6;
case sys_clk0_8_clk: return clk_get_rate(sys_clk0_clk) / 8;
case sys_clk0_12_clk: return clk_get_rate(sys_clk0_clk) / 12;
case sys_clk0_24_clk: return clk_get_rate(sys_clk0_clk) / 24;
case sys_clk1_3_clk: return clk_get_rate(sys_clk1_clk) / 3;
case sys_clk1_4_clk: return clk_get_rate(sys_clk1_clk) / 4;
case sys_clk1_6_clk: return clk_get_rate(sys_clk1_clk) / 6;
case sys_clk1_12_clk: return clk_get_rate(sys_clk1_clk) / 12;
default:
break;
}
return 0;
}
void init_pll(const struct pll_init_data *data)
{
u32 tmp, tmp_ctl, pllm, plld, pllod, bwadj;
pllm = data->pll_m - 1;
plld = (data->pll_d - 1) & PLL_DIV_MASK;
pllod = (data->pll_od - 1) & PLL_CLKOD_MASK;
if (data->pll == MAIN_PLL) {
/* The requered delay before main PLL configuration */
sdelay(210000);
tmp = pllctl_reg_read(data->pll, secctl);
if (tmp & (PLLCTL_BYPASS)) {
setbits_le32(pll_regs[data->pll].reg1,
BIT(MAIN_ENSAT_OFFSET));
pllctl_reg_clrbits(data->pll, ctl, PLLCTL_PLLEN |
PLLCTL_PLLENSRC);
sdelay(340);
pllctl_reg_setbits(data->pll, secctl, PLLCTL_BYPASS);
pllctl_reg_setbits(data->pll, ctl, PLLCTL_PLLPWRDN);
sdelay(21000);
pllctl_reg_clrbits(data->pll, ctl, PLLCTL_PLLPWRDN);
} else {
pllctl_reg_clrbits(data->pll, ctl, PLLCTL_PLLEN |
PLLCTL_PLLENSRC);
sdelay(340);
}
pllctl_reg_write(data->pll, mult, pllm & PLLM_MULT_LO_MASK);
clrsetbits_le32(pll_regs[data->pll].reg0, PLLM_MULT_HI_SMASK,
(pllm << 6));
/* Set the BWADJ (12 bit field) */
tmp_ctl = pllm >> 1; /* Divide the pllm by 2 */
clrsetbits_le32(pll_regs[data->pll].reg0, PLL_BWADJ_LO_SMASK,
(tmp_ctl << PLL_BWADJ_LO_SHIFT));
clrsetbits_le32(pll_regs[data->pll].reg1, PLL_BWADJ_HI_MASK,
(tmp_ctl >> 8));
/*
* Set the pll divider (6 bit field) *
* PLLD[5:0] is located in MAINPLLCTL0
*/
clrsetbits_le32(pll_regs[data->pll].reg0, PLL_DIV_MASK, plld);
/* Set the OUTPUT DIVIDE (4 bit field) in SECCTL */
pllctl_reg_rmw(data->pll, secctl, PLL_CLKOD_SMASK,
(pllod << PLL_CLKOD_SHIFT));
wait_for_completion(data);
pllctl_reg_write(data->pll, div1, PLLM_RATIO_DIV1);
pllctl_reg_write(data->pll, div2, PLLM_RATIO_DIV2);
pllctl_reg_write(data->pll, div3, PLLM_RATIO_DIV3);
pllctl_reg_write(data->pll, div4, PLLM_RATIO_DIV4);
pllctl_reg_write(data->pll, div5, PLLM_RATIO_DIV5);
pllctl_reg_setbits(data->pll, alnctl, 0x1f);
/*
* Set GOSET bit in PLLCMD to initiate the GO operation
* to change the divide
*/
pllctl_reg_setbits(data->pll, cmd, PLLSTAT_GO);
sdelay(1500); /* wait for the phase adj */
wait_for_completion(data);
/* Reset PLL */
pllctl_reg_setbits(data->pll, ctl, PLLCTL_PLLRST);
sdelay(21000); /* Wait for a minimum of 7 us*/
pllctl_reg_clrbits(data->pll, ctl, PLLCTL_PLLRST);
sdelay(105000); /* Wait for PLL Lock time (min 50 us) */
pllctl_reg_clrbits(data->pll, secctl, PLLCTL_BYPASS);
tmp = pllctl_reg_setbits(data->pll, ctl, PLLCTL_PLLEN);
} else if (data->pll == TETRIS_PLL) {
bwadj = pllm >> 1;
/* 1.5 Set PLLCTL0[BYPASS] =1 (enable bypass), */
setbits_le32(pll_regs[data->pll].reg0, PLLCTL_BYPASS);
/*
* Set CHIPMISCCTL1[13] = 0 (enable glitchfree bypass)
* only applicable for Kepler
*/
clrbits_le32(K2HK_MISC_CTRL, ARM_PLL_EN);
/* 2 In PLLCTL1, write PLLRST = 1 (PLL is reset) */
setbits_le32(pll_regs[data->pll].reg1 ,
PLL_PLLRST | PLLCTL_ENSAT);
/*
* 3 Program PLLM and PLLD in PLLCTL0 register
* 4 Program BWADJ[7:0] in PLLCTL0 and BWADJ[11:8] in
* PLLCTL1 register. BWADJ value must be set
* to ((PLLM + 1) >> 1) – 1)
*/
tmp = ((bwadj & PLL_BWADJ_LO_MASK) << PLL_BWADJ_LO_SHIFT) |
(pllm << 6) |
(plld & PLL_DIV_MASK) |
(pllod << PLL_CLKOD_SHIFT) | PLLCTL_BYPASS;
__raw_writel(tmp, pll_regs[data->pll].reg0);
/* Set BWADJ[11:8] bits */
tmp = __raw_readl(pll_regs[data->pll].reg1);
tmp &= ~(PLL_BWADJ_HI_MASK);
tmp |= ((bwadj>>8) & PLL_BWADJ_HI_MASK);
__raw_writel(tmp, pll_regs[data->pll].reg1);
/*
* 5 Wait for at least 5 us based on the reference
* clock (PLL reset time)
*/
sdelay(21000); /* Wait for a minimum of 7 us*/
/* 6 In PLLCTL1, write PLLRST = 0 (PLL reset is released) */
clrbits_le32(pll_regs[data->pll].reg1, PLL_PLLRST);
/*
* 7 Wait for at least 500 * REFCLK cycles * (PLLD + 1)
* (PLL lock time)
*/
sdelay(105000);
/* 8 disable bypass */
clrbits_le32(pll_regs[data->pll].reg0, PLLCTL_BYPASS);
/*
* 9 Set CHIPMISCCTL1[13] = 1 (disable glitchfree bypass)
* only applicable for Kepler
*/
setbits_le32(K2HK_MISC_CTRL, ARM_PLL_EN);
} else {
setbits_le32(pll_regs[data->pll].reg1, PLLCTL_ENSAT);
/*
* process keeps state of Bypass bit while programming
* all other DDR PLL settings
*/
tmp = __raw_readl(pll_regs[data->pll].reg0);
tmp &= PLLCTL_BYPASS; /* clear everything except Bypass */
/*
* Set the BWADJ[7:0], PLLD[5:0] and PLLM to PLLCTL0,
* bypass disabled
*/
bwadj = pllm >> 1;
tmp |= ((bwadj & PLL_BWADJ_LO_SHIFT) << PLL_BWADJ_LO_SHIFT) |
(pllm << PLL_MULT_SHIFT) |
(plld & PLL_DIV_MASK) |
(pllod << PLL_CLKOD_SHIFT);
__raw_writel(tmp, pll_regs[data->pll].reg0);
/* Set BWADJ[11:8] bits */
tmp = __raw_readl(pll_regs[data->pll].reg1);
tmp &= ~(PLL_BWADJ_HI_MASK);
tmp |= ((bwadj >> 8) & PLL_BWADJ_HI_MASK);
/* set PLL Select (bit 13) for PASS PLL */
if (data->pll == PASS_PLL)
tmp |= PLLCTL_PAPLL;
__raw_writel(tmp, pll_regs[data->pll].reg1);
/* Reset bit: bit 14 for both DDR3 & PASS PLL */
tmp = PLL_PLLRST;
/* Set RESET bit = 1 */
setbits_le32(pll_regs[data->pll].reg1, tmp);
/* Wait for a minimum of 7 us*/
sdelay(21000);
/* Clear RESET bit */
clrbits_le32(pll_regs[data->pll].reg1, tmp);
sdelay(105000);
/* clear BYPASS (Enable PLL Mode) */
clrbits_le32(pll_regs[data->pll].reg0, PLLCTL_BYPASS);
sdelay(21000); /* Wait for a minimum of 7 us*/
}
/*
* This is required to provide a delay between multiple
* consequent PPL configurations
*/
sdelay(210000);
}
void init_plls(int num_pll, struct pll_init_data *config)
{
int i;
for (i = 0; i < num_pll; i++)
init_pll(&config[i]);
}
/*
* keystone2: commands for clocks
*
* (C) Copyright 2012-2014
* Texas Instruments Incorporated, <www.ti.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <command.h>
#include <asm/arch/hardware.h>
#include <asm/arch/clock.h>
#include <asm/arch/psc_defs.h>
struct pll_init_data cmd_pll_data = {
.pll = MAIN_PLL,
.pll_m = 16,
.pll_d = 1,
.pll_od = 2,
};
int do_pll_cmd(cmd_tbl_t *cmdtp, int flag, int argc, char * const argv[])
{
if (argc != 5)
goto pll_cmd_usage;
if (strncmp(argv[1], "pa", 2) == 0)
cmd_pll_data.pll = PASS_PLL;
else if (strncmp(argv[1], "arm", 3) == 0)
cmd_pll_data.pll = TETRIS_PLL;
else if (strncmp(argv[1], "ddr3a", 5) == 0)
cmd_pll_data.pll = DDR3A_PLL;
else if (strncmp(argv[1], "ddr3b", 5) == 0)
cmd_pll_data.pll = DDR3B_PLL;
else
goto pll_cmd_usage;
cmd_pll_data.pll_m = simple_strtoul(argv[2], NULL, 10);
cmd_pll_data.pll_d = simple_strtoul(argv[3], NULL, 10);
cmd_pll_data.pll_od = simple_strtoul(argv[4], NULL, 10);
printf("Trying to set pll %d; mult %d; div %d; OD %d\n",
cmd_pll_data.pll, cmd_pll_data.pll_m,
cmd_pll_data.pll_d, cmd_pll_data.pll_od);
init_pll(&cmd_pll_data);
return 0;
pll_cmd_usage:
return cmd_usage(cmdtp);
}
U_BOOT_CMD(
pllset, 5, 0, do_pll_cmd,
"set pll multiplier and pre divider",
"<pa|arm|ddr3a|ddr3b> <mult> <div> <OD>\n"
);
int do_getclk_cmd(cmd_tbl_t *cmdtp, int flag, int argc, char * const argv[])
{
unsigned int clk;
unsigned int freq;
if (argc != 2)
goto getclk_cmd_usage;
clk = simple_strtoul(argv[1], NULL, 10);
freq = clk_get_rate(clk);
printf("clock index [%d] - frequency %u\n", clk, freq);
return 0;
getclk_cmd_usage:
return cmd_usage(cmdtp);
}
U_BOOT_CMD(
getclk, 2, 0, do_getclk_cmd,
"get clock rate",
"<clk index>\n"
"See the 'enum clk_e' in the k2hk clock.h for clk indexes\n"
);
int do_psc_cmd(cmd_tbl_t *cmdtp, int flag, int argc, char * const argv[])
{
int psc_module;
int res;
if (argc != 3)
goto psc_cmd_usage;
psc_module = simple_strtoul(argv[1], NULL, 10);
if (strcmp(argv[2], "en") == 0) {
res = psc_enable_module(psc_module);
printf("psc_enable_module(%d) - %s\n", psc_module,
(res) ? "ERROR" : "OK");
return 0;
}
if (strcmp(argv[2], "di") == 0) {
res = psc_disable_module(psc_module);
printf("psc_disable_module(%d) - %s\n", psc_module,
(res) ? "ERROR" : "OK");
return 0;
}
if (strcmp(argv[2], "domain") == 0) {
res = psc_disable_domain(psc_module);
printf("psc_disable_domain(%d) - %s\n", psc_module,
(res) ? "ERROR" : "OK");
return 0;
}
psc_cmd_usage:
return cmd_usage(cmdtp);
}
U_BOOT_CMD(
psc, 3, 0, do_psc_cmd,
"<enable/disable psc module os disable domain>",
"<mod/domain index> <en|di|domain>\n"
"See the hardware.h for Power and Sleep Controller (PSC) Domains\n"
);
/*
* K2HK: secure kernel command file
*
* (C) Copyright 2012-2014
* Texas Instruments Incorporated, <www.ti.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <command.h>
asm(".arch_extension sec\n\t");
static int mon_install(u32 addr, u32 dpsc, u32 freq)
{
int result;
__asm__ __volatile__ (
"stmfd r13!, {lr}\n"
"mov r0, %1\n"
"mov r1, %2\n"
"mov r2, %3\n"
"blx r0\n"
"ldmfd r13!, {lr}\n"
: "=&r" (result)
: "r" (addr), "r" (dpsc), "r" (freq)
: "cc", "r0", "r1", "r2", "memory");
return result;
}
static int do_mon_install(cmd_tbl_t *cmdtp, int flag, int argc,
char * const argv[])
{
u32 addr, dpsc_base = 0x1E80000, freq;
int rcode = 0;
if (argc < 2)
return CMD_RET_USAGE;
freq = clk_get_rate(sys_clk0_6_clk);
addr = simple_strtoul(argv[1], NULL, 16);
rcode = mon_install(addr, dpsc_base, freq);
printf("## installed monitor, freq [%d], status %d\n",
freq, rcode);
return 0;
}
U_BOOT_CMD(mon_install, 2, 0, do_mon_install,
"Install boot kernel at 'addr'",
""
);
static void core_spin(void)
{
while (1)
; /* forever */;
}
int mon_power_on(int core_id, void *ep)
{
int result;
asm volatile (
"stmfd r13!, {lr}\n"
"mov r1, %1\n"
"mov r2, %2\n"
"mov r0, #0\n"
"smc #0\n"
"ldmfd r13!, {lr}\n"
: "=&r" (result)
: "r" (core_id), "r" (ep)
: "cc", "r0", "r1", "r2", "memory");
return result;
}
int mon_power_off(int core_id)
{
int result;
asm volatile (
"stmfd r13!, {lr}\n"
"mov r1, %1\n"
"mov r0, #1\n"
"smc #1\n"
"ldmfd r13!, {lr}\n"
: "=&r" (result)
: "r" (core_id)
: "cc", "r0", "r1", "memory");
return result;
}
int do_mon_power(cmd_tbl_t *cmdtp, int flag, int argc,
char * const argv[])
{
int rcode = 0, core_id, on;
void (*fn)(void);
fn = core_spin;
if (argc < 3)
return CMD_RET_USAGE;
core_id = simple_strtoul(argv[1], NULL, 16);
on = simple_strtoul(argv[2], NULL, 16);
if (on)
rcode = mon_power_on(core_id, fn);
else
rcode = mon_power_off(core_id);
if (on) {
if (!rcode)
printf("core %d powered on successfully\n", core_id);
else
printf("core %d power on failure\n", core_id);
} else {
printf("core %d powered off successfully\n", core_id);
}
return 0;
}
U_BOOT_CMD(mon_power, 3, 0, do_mon_power,
"Power On/Off secondary core",
"mon_power <coreid> <oper>\n"
"- coreid (1-3) and oper (1 - ON, 0 - OFF)\n"
""
);
/*
* Keystone2: DDR3 initialization
*
* (C) Copyright 2012-2014
* Texas Instruments Incorporated, <www.ti.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <asm/arch/hardware.h>
#include <asm/io.h>
void init_ddrphy(u32 base, struct ddr3_phy_config *phy_cfg)
{
unsigned int tmp;
while ((__raw_readl(base + KS2_DDRPHY_PGSR0_OFFSET)
& 0x00000001) != 0x00000001)
;
__raw_writel(phy_cfg->pllcr, base + KS2_DDRPHY_PLLCR_OFFSET);
tmp = __raw_readl(base + KS2_DDRPHY_PGCR1_OFFSET);
tmp &= ~(phy_cfg->pgcr1_mask);
tmp |= phy_cfg->pgcr1_val;
__raw_writel(tmp, base + KS2_DDRPHY_PGCR1_OFFSET);
__raw_writel(phy_cfg->ptr0, base + KS2_DDRPHY_PTR0_OFFSET);
__raw_writel(phy_cfg->ptr1, base + KS2_DDRPHY_PTR1_OFFSET);
__raw_writel(phy_cfg->ptr3, base + KS2_DDRPHY_PTR3_OFFSET);
__raw_writel(phy_cfg->ptr4, base + KS2_DDRPHY_PTR4_OFFSET);