Mirrors/u-boot
2
0
Fork 0
mirror of https://github.com/AsahiLinux/u-boot synced 2024-11-14 08:57:58 +00:00
Code Issues Projects Releases Packages Wiki Activity
u-boot/arch/arm/cpu/armv7/keystone/clock.c
Vitaly Andrianov ef509b9063 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: Vitaly Andrianov <vitalya@ti.com>
Signed-off-by: Murali Karicheri <m-karicheri2@ti.com>
Signed-off-by: WingMan Kwok <w-kwok2@ti.com>
Signed-off-by: Sandeep Nair <sandeep_n@ti.com>
2014-04-17 17:24:38 -04:00

318 lines
9.1 KiB
C
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

/*
* 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]);
}
Reference in a new issue View git blame Copy permalink