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|
/*
* Copyright (C) 2010-2011 Freescale Semiconductor, Inc.
*
* 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
*/
#include <common.h>
#include <asm/arch/mx6.h>
#include <asm/arch/regs-anadig.h>
#include <asm/errno.h>
#include <asm/io.h>
#include "crm_regs.h"
#ifdef CONFIG_CMD_CLOCK
#include <asm/clock.h>
#endif
#include <div64.h>
#ifdef CONFIG_ARCH_CPU_INIT
#include <asm/cache-cp15.h>
#endif
#ifdef CONFIG_GET_FEC_MAC_ADDR_FROM_IIM
#include <asm/arch/regs-ocotp.h>
#endif
enum pll_clocks {
CPU_PLL1, /* System PLL */
BUS_PLL2, /* System Bus PLL*/
USBOTG_PLL3, /* OTG USB PLL */
AUD_PLL4, /* Audio PLL */
VID_PLL5, /* Video PLL */
MLB_PLL6, /* MLB PLL */
USBHOST_PLL7, /* Host USB PLL */
ENET_PLL8, /* ENET PLL */
};
#define SZ_DEC_1M 1000000
/* Out-of-reset PFDs and clock source definitions */
#define PLL2_PFD0_FREQ 352000000
#define PLL2_PFD1_FREQ 594000000
#define PLL2_PFD2_FREQ 400000000
#define PLL2_PFD2_DIV_FREQ 200000000
#define PLL3_PFD0_FREQ 720000000
#define PLL3_PFD1_FREQ 540000000
#define PLL3_PFD2_FREQ 508200000
#define PLL3_PFD3_FREQ 454700000
#define PLL3_80M 80000000
#define PLL3_60M 60000000
#define AHB_CLK_ROOT 132000000
#define IPG_CLK_ROOT 66000000
#define ENET_FREQ_0 25000000
#define ENET_FREQ_1 50000000
#define ENET_FREQ_2 100000000
#define ENET_FREQ_3 125000000
#ifdef CONFIG_CMD_CLOCK
#define PLL1_FREQ_MAX 1300000000
#define PLL1_FREQ_MIN 650000000
#define PLL2_FREQ_MAX 528000000
#define PLL2_FREQ_MIN 480000000
#define MAX_DDR_CLK PLL2_FREQ_MAX
#define AHB_CLK_MAX 132000000
#define IPG_CLK_MAX (AHB_CLK_MAX >> 1)
#define NFC_CLK_MAX PLL2_FREQ_MAX
#endif
static u32 __decode_pll(enum pll_clocks pll, u32 infreq)
{
u32 div;
switch (pll) {
case CPU_PLL1:
div = REG_RD(ANATOP_BASE_ADDR, HW_ANADIG_PLL_SYS) &
BM_ANADIG_PLL_SYS_DIV_SELECT;
return infreq * (div >> 1);
case BUS_PLL2:
div = REG_RD(ANATOP_BASE_ADDR, HW_ANADIG_PLL_528) &
BM_ANADIG_PLL_528_DIV_SELECT;
return infreq * (20 + (div << 1));
case USBOTG_PLL3:
div = REG_RD(ANATOP_BASE_ADDR, HW_ANADIG_USB2_PLL_480_CTRL) &
BM_ANADIG_USB2_PLL_480_CTRL_DIV_SELECT;
return infreq * (20 + (div << 1));
case ENET_PLL8:
div = REG_RD(ANATOP_BASE_ADDR, HW_ANADIG_PLL_ENET) &
BM_ANADIG_PLL_ENET_DIV_SELECT;
switch (div) {
default:
case 0:
return ENET_FREQ_0;
case 1:
return ENET_FREQ_1;
case 2:
return ENET_FREQ_2;
case 3:
return ENET_FREQ_3;
}
case AUD_PLL4:
case VID_PLL5:
case MLB_PLL6:
case USBHOST_PLL7:
default:
return 0;
}
}
static u32 __get_mcu_main_clk(void)
{
u32 reg, freq;
reg = (__REG(MXC_CCM_CACRR) & MXC_CCM_CACRR_ARM_PODF_MASK) >>
MXC_CCM_CACRR_ARM_PODF_OFFSET;
freq = __decode_pll(CPU_PLL1, CONFIG_MX6_HCLK_FREQ);
return freq / (reg + 1);
}
static u32 __get_periph_clk(void)
{
u32 reg;
reg = __REG(MXC_CCM_CBCDR);
if (reg & MXC_CCM_CBCDR_PERIPH_CLK_SEL) {
reg = __REG(MXC_CCM_CBCMR);
switch ((reg & MXC_CCM_CBCMR_PERIPH_CLK2_SEL_MASK) >>
MXC_CCM_CBCMR_PERIPH_CLK2_SEL_OFFSET) {
case 0:
return __decode_pll(USBOTG_PLL3, CONFIG_MX6_HCLK_FREQ);
case 1:
case 2:
return CONFIG_MX6_HCLK_FREQ;
default:
return 0;
}
} else {
reg = __REG(MXC_CCM_CBCMR);
switch ((reg & MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_MASK) >>
MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_OFFSET) {
default:
case 0:
return __decode_pll(BUS_PLL2, CONFIG_MX6_HCLK_FREQ);
case 1:
return PLL2_PFD2_FREQ;
case 2:
return PLL2_PFD0_FREQ;
case 3:
return PLL2_PFD2_DIV_FREQ;
}
}
}
static u32 __get_ipg_clk(void)
{
u32 ahb_podf, ipg_podf;
ahb_podf = __REG(MXC_CCM_CBCDR);
ipg_podf = (ahb_podf & MXC_CCM_CBCDR_IPG_PODF_MASK) >>
MXC_CCM_CBCDR_IPG_PODF_OFFSET;
ahb_podf = (ahb_podf & MXC_CCM_CBCDR_AHB_PODF_MASK) >>
MXC_CCM_CBCDR_AHB_PODF_OFFSET;
return __get_periph_clk() / ((ahb_podf + 1) * (ipg_podf + 1));
}
static u32 __get_ipg_per_clk(void)
{
u32 podf;
u32 clk_root = __get_ipg_clk();
podf = __REG(MXC_CCM_CSCMR1) & MXC_CCM_CSCMR1_PERCLK_PODF_MASK;
return clk_root / (podf + 1);
}
static u32 __get_uart_clk(void)
{
u32 freq = PLL3_80M, reg, podf;
reg = __REG(MXC_CCM_CSCDR1);
podf = (reg & MXC_CCM_CSCDR1_UART_CLK_PODF_MASK) >>
MXC_CCM_CSCDR1_UART_CLK_PODF_OFFSET;
freq /= (podf + 1);
return freq;
}
static u32 __get_cspi_clk(void)
{
u32 freq = PLL3_60M, reg, podf;
reg = __REG(MXC_CCM_CSCDR2);
podf = (reg & MXC_CCM_CSCDR2_ECSPI_CLK_PODF_MASK) >>
MXC_CCM_CSCDR2_ECSPI_CLK_PODF_OFFSET;
freq /= (podf + 1);
return freq;
}
static u32 __get_axi_clk(void)
{
u32 clkroot;
u32 cbcdr = __REG(MXC_CCM_CBCDR);
u32 podf = (cbcdr & MXC_CCM_CBCDR_AXI_PODF_MASK) >>
MXC_CCM_CBCDR_AXI_PODF_OFFSET;
if (cbcdr & MXC_CCM_CBCDR_AXI_SEL) {
if (cbcdr & MXC_CCM_CBCDR_AXI_ALT_SEL)
clkroot = PLL2_PFD2_FREQ;
else
clkroot = PLL3_PFD1_FREQ;;
} else
clkroot = __get_periph_clk();
return clkroot / (podf + 1);
}
static u32 __get_ahb_clk(void)
{
u32 cbcdr = __REG(MXC_CCM_CBCDR);
u32 podf = (cbcdr & MXC_CCM_CBCDR_AHB_PODF_MASK) \
>> MXC_CCM_CBCDR_AHB_PODF_OFFSET;
return __get_periph_clk() / (podf + 1);
}
static u32 __get_emi_slow_clk(void)
{
u32 cscmr1 = __REG(MXC_CCM_CSCMR1);
u32 emi_clk_sel = (cscmr1 & MXC_CCM_CSCMR1_ACLK_EMI_SLOW_MASK) >>
MXC_CCM_CSCMR1_ACLK_EMI_SLOW_OFFSET;
u32 podf = (cscmr1 & MXC_CCM_CSCMR1_ACLK_EMI_SLOW_PODF_MASK) >>
MXC_CCM_CSCMR1_ACLK_EMI_PODF_OFFSET;
switch (emi_clk_sel) {
default:
case 0:
return __get_axi_clk() / (podf + 1);
case 1:
return __decode_pll(USBOTG_PLL3, CONFIG_MX6_HCLK_FREQ) /
(podf + 1);
case 2:
return PLL2_PFD2_FREQ / (podf + 1);
case 3:
return PLL2_PFD0_FREQ / (podf + 1);
}
}
static u32 __get_nfc_clk(void)
{
u32 clkroot;
u32 cs2cdr = __REG(MXC_CCM_CS2CDR);
u32 podf = (cs2cdr & MXC_CCM_CS2CDR_ENFC_CLK_PODF_MASK) \
>> MXC_CCM_CS2CDR_ENFC_CLK_PODF_OFFSET;
u32 pred = (cs2cdr & MXC_CCM_CS2CDR_ENFC_CLK_PRED_MASK) \
>> MXC_CCM_CS2CDR_ENFC_CLK_PRED_OFFSET;
switch ((cs2cdr & MXC_CCM_CS2CDR_ENFC_CLK_SEL_MASK) >>
MXC_CCM_CS2CDR_ENFC_CLK_SEL_OFFSET) {
default:
case 0:
clkroot = PLL2_PFD0_FREQ;
break;
case 1:
clkroot = __decode_pll(BUS_PLL2, CONFIG_MX6_HCLK_FREQ);
break;
case 2:
clkroot = __decode_pll(USBOTG_PLL3, CONFIG_MX6_HCLK_FREQ);
break;
case 3:
clkroot = PLL2_PFD2_FREQ;
break;
}
return clkroot / (pred + 1) / (podf + 1);
}
static u32 __get_ddr_clk(void)
{
u32 cbcdr = __REG(MXC_CCM_CBCDR);
u32 podf = (cbcdr & MXC_CCM_CBCDR_MMDC_CH0_PODF_MASK) >>
MXC_CCM_CBCDR_MMDC_CH0_PODF_OFFSET;
return __get_periph_clk() / (podf + 1);
}
static u32 __get_usdhc1_clk(void)
{
u32 clkroot;
u32 cscmr1 = __REG(MXC_CCM_CSCMR1);
u32 cscdr1 = __REG(MXC_CCM_CSCDR1);
u32 podf = (cscdr1 & MXC_CCM_CSCDR1_USDHC1_PODF_MASK) >>
MXC_CCM_CSCDR1_USDHC1_PODF_OFFSET;
if (cscmr1 & MXC_CCM_CSCMR1_USDHC1_CLK_SEL)
clkroot = PLL2_PFD0_FREQ;
else
clkroot = PLL2_PFD2_FREQ;
return clkroot / (podf + 1);
}
static u32 __get_usdhc2_clk(void)
{
u32 clkroot;
u32 cscmr1 = __REG(MXC_CCM_CSCMR1);
u32 cscdr1 = __REG(MXC_CCM_CSCDR1);
u32 podf = (cscdr1 & MXC_CCM_CSCDR1_USDHC2_PODF_MASK) >>
MXC_CCM_CSCDR1_USDHC2_PODF_OFFSET;
if (cscmr1 & MXC_CCM_CSCMR1_USDHC2_CLK_SEL)
clkroot = PLL2_PFD0_FREQ;
else
clkroot = PLL2_PFD2_FREQ;
return clkroot / (podf + 1);
}
static u32 __get_usdhc3_clk(void)
{
u32 clkroot;
u32 cscmr1 = __REG(MXC_CCM_CSCMR1);
u32 cscdr1 = __REG(MXC_CCM_CSCDR1);
u32 podf = (cscdr1 & MXC_CCM_CSCDR1_USDHC3_PODF_MASK) >>
MXC_CCM_CSCDR1_USDHC3_PODF_OFFSET;
if (cscmr1 & MXC_CCM_CSCMR1_USDHC3_CLK_SEL)
clkroot = PLL2_PFD0_FREQ;
else
clkroot = PLL2_PFD2_FREQ;
return clkroot / (podf + 1);
}
static u32 __get_usdhc4_clk(void)
{
u32 clkroot;
u32 cscmr1 = __REG(MXC_CCM_CSCMR1);
u32 cscdr1 = __REG(MXC_CCM_CSCDR1);
u32 podf = (cscdr1 & MXC_CCM_CSCDR1_USDHC4_PODF_MASK) >>
MXC_CCM_CSCDR1_USDHC4_PODF_OFFSET;
if (cscmr1 & MXC_CCM_CSCMR1_USDHC4_CLK_SEL)
clkroot = PLL2_PFD0_FREQ;
else
clkroot = PLL2_PFD2_FREQ;
return clkroot / (podf + 1);
}
unsigned int mxc_get_clock(enum mxc_clock clk)
{
switch (clk) {
case MXC_ARM_CLK:
return __get_mcu_main_clk();
case MXC_PER_CLK:
return __get_periph_clk();
case MXC_AHB_CLK:
return __get_ahb_clk();
case MXC_IPG_CLK:
return __get_ipg_clk();
case MXC_IPG_PERCLK:
return __get_ipg_per_clk();
case MXC_UART_CLK:
return __get_uart_clk();
case MXC_CSPI_CLK:
return __get_cspi_clk();
case MXC_AXI_CLK:
return __get_axi_clk();
case MXC_EMI_SLOW_CLK:
return __get_emi_slow_clk();
case MXC_DDR_CLK:
return __get_ddr_clk();
case MXC_ESDHC_CLK:
return __get_usdhc1_clk();
case MXC_ESDHC2_CLK:
return __get_usdhc2_clk();
case MXC_ESDHC3_CLK:
return __get_usdhc3_clk();
case MXC_ESDHC4_CLK:
return __get_usdhc4_clk();
case MXC_SATA_CLK:
return __get_ahb_clk();
case MXC_NFC_CLK:
case MXC_GPMI_CLK:
case MXC_BCH_CLK:
return __get_nfc_clk();
default:
break;
}
return -1;
}
void mxc_dump_clocks(void)
{
u32 freq;
freq = __decode_pll(CPU_PLL1, CONFIG_MX6_HCLK_FREQ);
printf("mx6q pll1: %dMHz\n", freq / SZ_DEC_1M);
freq = __decode_pll(BUS_PLL2, CONFIG_MX6_HCLK_FREQ);
printf("mx6q pll2: %dMHz\n", freq / SZ_DEC_1M);
freq = __decode_pll(USBOTG_PLL3, CONFIG_MX6_HCLK_FREQ);
printf("mx6q pll3: %dMHz\n", freq / SZ_DEC_1M);
freq = __decode_pll(ENET_PLL8, CONFIG_MX6_HCLK_FREQ);
printf("mx6q pll8: %dMHz\n", freq / SZ_DEC_1M);
printf("ipg clock : %dHz\n", mxc_get_clock(MXC_IPG_CLK));
printf("ipg per clock : %dHz\n", mxc_get_clock(MXC_IPG_PERCLK));
printf("uart clock : %dHz\n", mxc_get_clock(MXC_UART_CLK));
printf("cspi clock : %dHz\n", mxc_get_clock(MXC_CSPI_CLK));
printf("ahb clock : %dHz\n", mxc_get_clock(MXC_AHB_CLK));
printf("axi clock : %dHz\n", mxc_get_clock(MXC_AXI_CLK));
printf("emi_slow clock: %dHz\n", mxc_get_clock(MXC_EMI_SLOW_CLK));
printf("ddr clock : %dHz\n", mxc_get_clock(MXC_DDR_CLK));
printf("usdhc1 clock : %dHz\n", mxc_get_clock(MXC_ESDHC_CLK));
printf("usdhc2 clock : %dHz\n", mxc_get_clock(MXC_ESDHC2_CLK));
printf("usdhc3 clock : %dHz\n", mxc_get_clock(MXC_ESDHC3_CLK));
printf("usdhc4 clock : %dHz\n", mxc_get_clock(MXC_ESDHC4_CLK));
printf("nfc clock : %dHz\n", mxc_get_clock(MXC_NFC_CLK));
}
#ifdef CONFIG_CMD_CLOCK
/*!
* This is to calculate divider based on reference clock and
* targeted clock based on the equation for each PLL.
*
* @param pll pll number
* @param ref reference clock freq in Hz
* @param target targeted clock in Hz
*
* @return divider if successful; -1 otherwise.
*/
static int calc_pll_divider(enum pll_clocks pll, u32 ref, u32 target)
{
int i, div;
switch (pll) {
case CPU_PLL1:
if (target < PLL1_FREQ_MIN || target > PLL1_FREQ_MAX) {
printf("PLL1 frequency should be"
"within [%d - %d] MHz\n", PLL1_FREQ_MIN / SZ_DEC_1M,
PLL1_FREQ_MAX / SZ_DEC_1M);
return -1;
}
for (i = 54, div = i; i < 109; i++) {
if ((ref * (i >> 1)) > target)
break;
div = i;
}
break;
case BUS_PLL2:
if (target < PLL2_FREQ_MIN || target > PLL2_FREQ_MAX) {
printf("PLL2 frequency should be"
"within [%d - %d] MHz\n", PLL2_FREQ_MIN / SZ_DEC_1M,
PLL2_FREQ_MAX / SZ_DEC_1M);
return -1;
}
for (i = 0, div = i; i < 2; i++) {
if (ref * (20 + (i << 1)) > target)
break;
div = i;
}
break;
default:
printf("Changing this PLL not supported\n");
return -1;
break;
}
return div;
}
int clk_info(u32 clk_type)
{
switch (clk_type) {
case CPU_CLK:
printf("CPU Clock: %dHz\n",
mxc_get_clock(MXC_ARM_CLK));
break;
case PERIPH_CLK:
printf("Peripheral Clock: %dHz\n",
mxc_get_clock(MXC_PER_CLK));
break;
case AHB_CLK:
printf("AHB Clock: %dHz\n",
mxc_get_clock(MXC_AHB_CLK));
break;
case IPG_CLK:
printf("IPG Clock: %dHz\n",
mxc_get_clock(MXC_IPG_CLK));
break;
case IPG_PERCLK:
printf("IPG_PER Clock: %dHz\n",
mxc_get_clock(MXC_IPG_PERCLK));
break;
case UART_CLK:
printf("UART Clock: %dHz\n",
mxc_get_clock(MXC_UART_CLK));
break;
case CSPI_CLK:
printf("CSPI Clock: %dHz\n",
mxc_get_clock(MXC_CSPI_CLK));
break;
case DDR_CLK:
printf("DDR Clock: %dHz\n",
mxc_get_clock(MXC_DDR_CLK));
break;
case NFC_CLK:
printf("NFC Clock: %dHz\n",
mxc_get_clock(MXC_NFC_CLK));
break;
case ALL_CLK:
printf("cpu clock: %dMHz\n",
mxc_get_clock(MXC_ARM_CLK) / SZ_DEC_1M);
mxc_dump_clocks();
break;
default:
printf("Unsupported clock type! :(\n");
}
return 0;
}
#define calc_div(target_clk, src_clk, limit) ({ \
u32 tmp = 0; \
if ((src_clk % target_clk) <= 100) \
tmp = src_clk / target_clk; \
else \
tmp = (src_clk / target_clk) + 1; \
if (tmp > limit) \
tmp = limit; \
(tmp - 1); \
})
#define calc_pred_n_podf(target_clk, src_clk, p_pred, p_podf, pred_limit, podf_limit) { \
u32 div = calc_div(target_clk, src_clk, \
pred_limit * podf_limit); \
u32 tmp = 0, tmp_i = 0, tmp_j = 0; \
if ((div + 1) > (pred_limit * podf_limit)) {\
tmp_i = pred_limit; \
tmp_j = podf_limit; \
} \
for (tmp_i = 1; tmp_i <= podf_limit; ++tmp_i) { \
for (tmp_j = 1; tmp_j <= pred_limit; ++tmp_j) { \
if ((div + 1) == (tmp_i * tmp_j)) { \
tmp = 1; \
break; \
} \
} \
if (1 == tmp) \
break; \
} \
*p_pred = tmp_j - 1; \
*p_podf = tmp_i - 1; \
}
static int config_pll_clk(enum pll_clocks pll, u32 divider)
{
u32 ccsr = readl(CCM_BASE_ADDR + CLKCTL_CCSR);
switch (pll) {
case CPU_PLL1:
/* Switch ARM to PLL2 clock */
writel(ccsr | 0x4, CCM_BASE_ADDR + CLKCTL_CCSR);
REG_CLR(ANATOP_BASE_ADDR, HW_ANADIG_PLL_SYS,
BM_ANADIG_PLL_SYS_DIV_SELECT);
REG_SET(ANATOP_BASE_ADDR, HW_ANADIG_PLL_SYS,
BF_ANADIG_PLL_SYS_DIV_SELECT(divider));
/* Enable CPU PLL1 */
REG_SET(ANATOP_BASE_ADDR, HW_ANADIG_PLL_SYS,
BM_ANADIG_PLL_SYS_ENABLE);
/* Wait for PLL lock */
while (REG_RD(ANATOP_BASE_ADDR, HW_ANADIG_PLL_SYS) &
BM_ANADIG_PLL_SYS_LOCK)
udelay(10);
/* Clear bypass bit */
REG_CLR(ANATOP_BASE_ADDR, HW_ANADIG_PLL_SYS,
BM_ANADIG_PLL_SYS_BYPASS);
/* Switch back */
writel(ccsr & ~0x4, CCM_BASE_ADDR + CLKCTL_CCSR);
break;
case BUS_PLL2:
/* Switch to pll2 bypass clock */
writel(ccsr | 0x2, CCM_BASE_ADDR + CLKCTL_CCSR);
REG_CLR(ANATOP_BASE_ADDR, HW_ANADIG_PLL_528,
BM_ANADIG_PLL_528_DIV_SELECT);
REG_SET(ANATOP_BASE_ADDR, HW_ANADIG_PLL_528,
divider);
/* Enable BUS PLL2 */
REG_SET(ANATOP_BASE_ADDR, HW_ANADIG_PLL_528,
BM_ANADIG_PLL_528_ENABLE);
/* Wait for PLL lock */
while (REG_RD(ANATOP_BASE_ADDR, HW_ANADIG_PLL_528) &
BM_ANADIG_PLL_528_LOCK)
udelay(10);
/* Clear bypass bit */
REG_CLR(ANATOP_BASE_ADDR, HW_ANADIG_PLL_528,
BM_ANADIG_PLL_528_BYPASS);
/* Switch back */
writel(ccsr & ~0x2, CCM_BASE_ADDR + CLKCTL_CCSR);
break;
default:
return -1;
}
return 0;
}
static int config_core_clk(u32 ref, u32 freq)
{
int div = calc_pll_divider(CPU_PLL1, ref, freq);
if (div < 0) {
printf("Can't find pll parameters\n");
return div;
}
return config_pll_clk(CPU_PLL1, div);
}
static int config_nfc_clk(u32 nfc_clk)
{
u32 clkroot;
u32 cs2cdr = __REG(MXC_CCM_CS2CDR);
u32 podf = 0, pred = 0;
switch ((cs2cdr & MXC_CCM_CS2CDR_ENFC_CLK_SEL_MASK) >>
MXC_CCM_CS2CDR_ENFC_CLK_SEL_OFFSET) {
default:
case 0:
clkroot = PLL2_PFD0_FREQ;
break;
case 1:
clkroot = __decode_pll(BUS_PLL2, CONFIG_MX6_HCLK_FREQ);
break;
case 2:
clkroot = __decode_pll(USBOTG_PLL3,
CONFIG_MX6_HCLK_FREQ);
break;
case 3:
clkroot = PLL2_PFD2_FREQ;
break;
}
calc_pred_n_podf(nfc_clk, clkroot, &pred, &podf, 8, 64);
cs2cdr &= ~(MXC_CCM_CS2CDR_ENFC_CLK_PRED_MASK |
MXC_CCM_CS2CDR_ENFC_CLK_PODF_MASK);
cs2cdr |= (pred << MXC_CCM_CS2CDR_ENFC_CLK_PRED_OFFSET);
cs2cdr |= (podf << MXC_CCM_CS2CDR_ENFC_CLK_PODF_OFFSET);
writel(cs2cdr, MXC_CCM_CS2CDR);
return 0;
}
static int config_periph_clk(u32 ref, u32 freq)
{
u32 cbcdr = readl(CCM_BASE_ADDR + CLKCTL_CBCDR);
u32 cbcmr = readl(CCM_BASE_ADDR + CLKCTL_CBCMR);
u32 pll2_freq = __decode_pll(BUS_PLL2, CONFIG_MX6_HCLK_FREQ);
u32 pll3_freq = __decode_pll(USBOTG_PLL3, CONFIG_MX6_HCLK_FREQ);
if (freq >= pll2_freq) {
/* PLL2 */
writel(cbcmr & ~MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_MASK,
CCM_BASE_ADDR + CLKCTL_CBCMR);
writel(cbcdr & ~MXC_CCM_CBCDR_PERIPH_CLK_SEL,
CCM_BASE_ADDR + CLKCTL_CBCDR);
} else if (freq < pll2_freq && freq >= pll3_freq) {
/* PLL3 */
writel(cbcmr & ~MXC_CCM_CBCMR_PERIPH_CLK2_SEL_MASK,
CCM_BASE_ADDR + CLKCTL_CBCMR);
writel(cbcdr | MXC_CCM_CBCDR_PERIPH_CLK_SEL,
CCM_BASE_ADDR + CLKCTL_CBCDR);
} else if (freq < pll3_freq && freq >= PLL2_PFD2_FREQ) {
/* 400M PLL2 PFD */
cbcmr = (cbcmr & ~MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_MASK) |
(1 << MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_OFFSET);
writel(cbcmr, CCM_BASE_ADDR + CLKCTL_CBCMR);
writel(cbcdr & ~MXC_CCM_CBCDR_PERIPH_CLK_SEL,
CCM_BASE_ADDR + CLKCTL_CBCDR);
} else if (freq < PLL2_PFD2_FREQ && freq >= PLL2_PFD0_FREQ) {
/* 352M PLL2 PFD */
cbcmr = (cbcmr & ~MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_MASK) |
(2 << MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_OFFSET);
writel(cbcmr, CCM_BASE_ADDR + CLKCTL_CBCMR);
writel(cbcdr & ~MXC_CCM_CBCDR_PERIPH_CLK_SEL,
CCM_BASE_ADDR + CLKCTL_CBCDR);
} else if (freq == PLL2_PFD2_DIV_FREQ) {
/* 200M PLL2 PFD */
cbcmr = (cbcmr & ~MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_MASK) |
(3 << MXC_CCM_CBCMR_PRE_PERIPH_CLK_SEL_OFFSET);
writel(cbcmr, CCM_BASE_ADDR + CLKCTL_CBCMR);
writel(cbcdr & ~MXC_CCM_CBCDR_PERIPH_CLK_SEL,
CCM_BASE_ADDR + CLKCTL_CBCDR);
} else {
printf("Frequency requested not within range [%d-%d] MHz\n",
PLL2_PFD2_DIV_FREQ / SZ_DEC_1M, pll2_freq / SZ_DEC_1M);
return -1;
}
puts("\n");
return 0;
}
static int config_ddr_clk(u32 ddr_clk)
{
u32 clk_src = __get_periph_clk();
u32 i, podf;
u32 cbcdr = readl(CCM_BASE_ADDR + CLKCTL_CBCDR);
if (ddr_clk > MAX_DDR_CLK) {
printf("DDR clock should be less than"
"%d MHz, assuming max value\n",
(MAX_DDR_CLK / SZ_DEC_1M));
ddr_clk = MAX_DDR_CLK;
}
for (i = 1; i < 9; i++)
if ((clk_src / i) <= ddr_clk)
break;
podf = i - 1;
cbcdr &= ~(MXC_CCM_CBCDR_MMDC_CH0_PODF_MASK |
MXC_CCM_CBCDR_MMDC_CH1_PODF_MASK);
cbcdr |= (podf << MXC_CCM_CBCDR_MMDC_CH0_PODF_OFFSET) |
(podf << MXC_CCM_CBCDR_MMDC_CH1_PODF_OFFSET);
writel(cbcdr, CCM_BASE_ADDR + CLKCTL_CBCDR);
while (readl(CCM_BASE_ADDR + CLKCTL_CDHIPR) != 0)
;
writel(0x0, CCM_BASE_ADDR + CLKCTL_CCDR);
return 0;
}
/*!
* This function assumes the expected core clock has to be changed by
* modifying the PLL. This is NOT true always but for most of the times,
* it is. So it assumes the PLL output freq is the same as the expected
* core clock (arm_podf=0) unless the core clock is less than PLL_FREQ_MIN.
*
* @param ref pll input reference clock (24MHz)
* @param freq targeted freq in Hz
* @param clk_type clock type, e.g CPU_CLK, DDR_CLK, etc.
* @return 0 if successful; non-zero otherwise
*/
int clk_config(u32 ref, u32 freq, u32 clk_type)
{
freq *= SZ_DEC_1M;
switch (clk_type) {
case CPU_CLK:
if (config_core_clk(ref, freq))
return -1;
break;
case PERIPH_CLK:
if (config_periph_clk(ref, freq))
return -1;
break;
case DDR_CLK:
if (config_ddr_clk(freq))
return -1;
break;
case NFC_CLK:
if (config_nfc_clk(freq))
return -1;
break;
default:
printf("Unsupported or invalid clock type! :(\n");
return -1;
}
return 0;
}
#endif
#if defined(CONFIG_DISPLAY_CPUINFO)
int print_cpuinfo(void)
{
printf("CPU: Freescale i.MX 6 family %d.%dV at %d MHz\n",
(get_board_rev() & 0xFF) >> 4,
(get_board_rev() & 0xF),
__get_mcu_main_clk() / SZ_DEC_1M);
mxc_dump_clocks();
return 0;
}
#endif
#if defined(CONFIG_MXC_FEC)
extern int mxc_fec_initialize(bd_t *bis);
extern void mxc_fec_set_mac_from_env(char *mac_addr);
void enet_board_init(void);
#ifdef CONFIG_GET_FEC_MAC_ADDR_FROM_IIM
int fec_get_mac_addr(unsigned char *mac)
{
unsigned int value;
value = readl(OCOTP_BASE_ADDR + HW_OCOTP_MACn(0));
mac[5] = value & 0xff;
mac[4] = (value >> 8) & 0xff;
mac[3] = (value >> 16) & 0xff;
mac[2] = (value >> 24) & 0xff;
value = readl(OCOTP_BASE_ADDR + HW_OCOTP_MACn(1));
mac[1] = value & 0xff;
mac[0] = (value >> 8) & 0xff;
return 0;
}
#endif
#endif
int cpu_eth_init(bd_t *bis)
{
int rc = -ENODEV;
#if defined(CONFIG_MXC_FEC)
rc = mxc_fec_initialize(bis);
/* Board level init */
enet_board_init();
#endif
return rc;
}
#if defined(CONFIG_ARCH_CPU_INIT)
int arch_cpu_init(void)
{
int val;
icache_enable();
dcache_enable();
#ifndef CONFIG_L2_OFF
l2_cache_enable();
#endif
/* Increase the VDDSOC to 1.2V */
val = REG_RD(ANATOP_BASE_ADDR, HW_ANADIG_REG_CORE);
val &= ~BM_ANADIG_REG_CORE_REG2_TRG;
val |= BF_ANADIG_REG_CORE_REG2_TRG(0x5);
REG_SET(ANATOP_BASE_ADDR, HW_ANADIG_REG_CORE, val);
return 0;
}
#endif
void ipu_clk_enable(void)
{
}
void ipu_clk_disable(void)
{
}
int otp_clk_enable(void)
{
u32 reg = 0;
reg = readl(CCM_BASE_ADDR + CLKCTL_CCGR2);
if (!(reg & 0x3000))
reg |= 0x3000;
writel(reg, CCM_BASE_ADDR + CLKCTL_CCGR2);
return 0;
}
int otp_clk_disable(void)
{
u32 reg = 0;
reg = readl(CCM_BASE_ADDR + CLKCTL_CCGR2);
if ((reg & 0x3000) == 0x3000)
reg &= ~(0x3000);
writel(reg, CCM_BASE_ADDR + CLKCTL_CCGR2);
return 0;
}
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