u-boot/arch/arm/cpu/armv7/exynos/clock.c
Masahiro Yamada b41411954d linux/kernel.h: sync min, max, min3, max3 macros with Linux
U-Boot has never cared about the type when we get max/min of two
values, but Linux Kernel does.  This commit gets min, max, min3, max3
macros synced with the kernel introducing type checks.

Many of references of those macros must be fixed to suppress warnings.
We have two options:
 - Use min, max, min3, max3 only when the arguments have the same type
   (or add casts to the arguments)
 - Use min_t/max_t instead with the appropriate type for the first
   argument

Signed-off-by: Masahiro Yamada <yamada.m@jp.panasonic.com>
Acked-by: Pavel Machek <pavel@denx.de>
Acked-by: Lukasz Majewski <l.majewski@samsung.com>
Tested-by: Lukasz Majewski <l.majewski@samsung.com>
[trini: Fixup arch/blackfin/lib/string.c]
Signed-off-by: Tom Rini <trini@ti.com>
2014-11-23 06:48:30 -05:00

1730 lines
36 KiB
C

/*
* Copyright (C) 2010 Samsung Electronics
* Minkyu Kang <mk7.kang@samsung.com>
*
* SPDX-License-Identifier: GPL-2.0+
*/
#include <common.h>
#include <asm/io.h>
#include <asm/arch/clock.h>
#include <asm/arch/clk.h>
#include <asm/arch/periph.h>
#define PLL_DIV_1024 1024
#define PLL_DIV_65535 65535
#define PLL_DIV_65536 65536
/* *
* This structure is to store the src bit, div bit and prediv bit
* positions of the peripheral clocks of the src and div registers
*/
struct clk_bit_info {
int8_t src_bit;
int8_t div_bit;
int8_t prediv_bit;
};
/* src_bit div_bit prediv_bit */
static struct clk_bit_info clk_bit_info[] = {
{0, 0, -1},
{4, 4, -1},
{8, 8, -1},
{12, 12, -1},
{0, 0, 8},
{4, 16, 24},
{8, 0, 8},
{12, 16, 24},
{-1, -1, -1},
{16, 0, 8},
{20, 16, 24},
{24, 0, 8},
{0, 0, 4},
{4, 12, 16},
{-1, -1, -1},
{-1, -1, -1},
{-1, 24, 0},
{-1, 24, 0},
{-1, 24, 0},
{-1, 24, 0},
{-1, 24, 0},
{-1, 24, 0},
{-1, 24, 0},
{-1, 24, 0},
{24, 0, -1},
{24, 0, -1},
{24, 0, -1},
{24, 0, -1},
{24, 0, -1},
};
/* Epll Clock division values to achive different frequency output */
static struct set_epll_con_val exynos5_epll_div[] = {
{ 192000000, 0, 48, 3, 1, 0 },
{ 180000000, 0, 45, 3, 1, 0 },
{ 73728000, 1, 73, 3, 3, 47710 },
{ 67737600, 1, 90, 4, 3, 20762 },
{ 49152000, 0, 49, 3, 3, 9961 },
{ 45158400, 0, 45, 3, 3, 10381 },
{ 180633600, 0, 45, 3, 1, 10381 }
};
/* exynos: return pll clock frequency */
static int exynos_get_pll_clk(int pllreg, unsigned int r, unsigned int k)
{
unsigned long m, p, s = 0, mask, fout;
unsigned int div;
unsigned int freq;
/*
* APLL_CON: MIDV [25:16]
* MPLL_CON: MIDV [25:16]
* EPLL_CON: MIDV [24:16]
* VPLL_CON: MIDV [24:16]
* BPLL_CON: MIDV [25:16]: Exynos5
*/
if (pllreg == APLL || pllreg == MPLL || pllreg == BPLL ||
pllreg == SPLL)
mask = 0x3ff;
else
mask = 0x1ff;
m = (r >> 16) & mask;
/* PDIV [13:8] */
p = (r >> 8) & 0x3f;
/* SDIV [2:0] */
s = r & 0x7;
freq = CONFIG_SYS_CLK_FREQ;
if (pllreg == EPLL || pllreg == RPLL) {
k = k & 0xffff;
/* FOUT = (MDIV + K / 65536) * FIN / (PDIV * 2^SDIV) */
fout = (m + k / PLL_DIV_65536) * (freq / (p * (1 << s)));
} else if (pllreg == VPLL) {
k = k & 0xfff;
/*
* Exynos4210
* FOUT = (MDIV + K / 1024) * FIN / (PDIV * 2^SDIV)
*
* Exynos4412
* FOUT = (MDIV + K / 65535) * FIN / (PDIV * 2^SDIV)
*
* Exynos5250
* FOUT = (MDIV + K / 65536) * FIN / (PDIV * 2^SDIV)
*/
if (proid_is_exynos4210())
div = PLL_DIV_1024;
else if (proid_is_exynos4412())
div = PLL_DIV_65535;
else if (proid_is_exynos5250() || proid_is_exynos5420())
div = PLL_DIV_65536;
else
return 0;
fout = (m + k / div) * (freq / (p * (1 << s)));
} else {
/*
* Exynos4412 / Exynos5250
* FOUT = MDIV * FIN / (PDIV * 2^SDIV)
*
* Exynos4210
* FOUT = MDIV * FIN / (PDIV * 2^(SDIV-1))
*/
if (proid_is_exynos4210())
fout = m * (freq / (p * (1 << (s - 1))));
else
fout = m * (freq / (p * (1 << s)));
}
return fout;
}
/* exynos4: return pll clock frequency */
static unsigned long exynos4_get_pll_clk(int pllreg)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned long r, k = 0;
switch (pllreg) {
case APLL:
r = readl(&clk->apll_con0);
break;
case MPLL:
r = readl(&clk->mpll_con0);
break;
case EPLL:
r = readl(&clk->epll_con0);
k = readl(&clk->epll_con1);
break;
case VPLL:
r = readl(&clk->vpll_con0);
k = readl(&clk->vpll_con1);
break;
default:
printf("Unsupported PLL (%d)\n", pllreg);
return 0;
}
return exynos_get_pll_clk(pllreg, r, k);
}
/* exynos4x12: return pll clock frequency */
static unsigned long exynos4x12_get_pll_clk(int pllreg)
{
struct exynos4x12_clock *clk =
(struct exynos4x12_clock *)samsung_get_base_clock();
unsigned long r, k = 0;
switch (pllreg) {
case APLL:
r = readl(&clk->apll_con0);
break;
case MPLL:
r = readl(&clk->mpll_con0);
break;
case EPLL:
r = readl(&clk->epll_con0);
k = readl(&clk->epll_con1);
break;
case VPLL:
r = readl(&clk->vpll_con0);
k = readl(&clk->vpll_con1);
break;
default:
printf("Unsupported PLL (%d)\n", pllreg);
return 0;
}
return exynos_get_pll_clk(pllreg, r, k);
}
/* exynos5: return pll clock frequency */
static unsigned long exynos5_get_pll_clk(int pllreg)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned long r, k = 0, fout;
unsigned int pll_div2_sel, fout_sel;
switch (pllreg) {
case APLL:
r = readl(&clk->apll_con0);
break;
case MPLL:
r = readl(&clk->mpll_con0);
break;
case EPLL:
r = readl(&clk->epll_con0);
k = readl(&clk->epll_con1);
break;
case VPLL:
r = readl(&clk->vpll_con0);
k = readl(&clk->vpll_con1);
break;
case BPLL:
r = readl(&clk->bpll_con0);
break;
default:
printf("Unsupported PLL (%d)\n", pllreg);
return 0;
}
fout = exynos_get_pll_clk(pllreg, r, k);
/* According to the user manual, in EVT1 MPLL and BPLL always gives
* 1.6GHz clock, so divide by 2 to get 800MHz MPLL clock.*/
if (pllreg == MPLL || pllreg == BPLL) {
pll_div2_sel = readl(&clk->pll_div2_sel);
switch (pllreg) {
case MPLL:
fout_sel = (pll_div2_sel >> MPLL_FOUT_SEL_SHIFT)
& MPLL_FOUT_SEL_MASK;
break;
case BPLL:
fout_sel = (pll_div2_sel >> BPLL_FOUT_SEL_SHIFT)
& BPLL_FOUT_SEL_MASK;
break;
default:
fout_sel = -1;
break;
}
if (fout_sel == 0)
fout /= 2;
}
return fout;
}
static unsigned long exynos5_get_periph_rate(int peripheral)
{
struct clk_bit_info *bit_info = &clk_bit_info[peripheral];
unsigned long sclk, sub_clk;
unsigned int src, div, sub_div;
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
switch (peripheral) {
case PERIPH_ID_UART0:
case PERIPH_ID_UART1:
case PERIPH_ID_UART2:
case PERIPH_ID_UART3:
src = readl(&clk->src_peric0);
div = readl(&clk->div_peric0);
break;
case PERIPH_ID_PWM0:
case PERIPH_ID_PWM1:
case PERIPH_ID_PWM2:
case PERIPH_ID_PWM3:
case PERIPH_ID_PWM4:
src = readl(&clk->src_peric0);
div = readl(&clk->div_peric3);
break;
case PERIPH_ID_I2S0:
src = readl(&clk->src_mau);
div = readl(&clk->div_mau);
case PERIPH_ID_SPI0:
case PERIPH_ID_SPI1:
src = readl(&clk->src_peric1);
div = readl(&clk->div_peric1);
break;
case PERIPH_ID_SPI2:
src = readl(&clk->src_peric1);
div = readl(&clk->div_peric2);
break;
case PERIPH_ID_SPI3:
case PERIPH_ID_SPI4:
src = readl(&clk->sclk_src_isp);
div = readl(&clk->sclk_div_isp);
break;
case PERIPH_ID_SDMMC0:
case PERIPH_ID_SDMMC1:
case PERIPH_ID_SDMMC2:
case PERIPH_ID_SDMMC3:
src = readl(&clk->src_fsys);
div = readl(&clk->div_fsys1);
break;
case PERIPH_ID_I2C0:
case PERIPH_ID_I2C1:
case PERIPH_ID_I2C2:
case PERIPH_ID_I2C3:
case PERIPH_ID_I2C4:
case PERIPH_ID_I2C5:
case PERIPH_ID_I2C6:
case PERIPH_ID_I2C7:
sclk = exynos5_get_pll_clk(MPLL);
sub_div = ((readl(&clk->div_top1) >> bit_info->div_bit)
& 0x7) + 1;
div = ((readl(&clk->div_top0) >> bit_info->prediv_bit)
& 0x7) + 1;
return (sclk / sub_div) / div;
default:
debug("%s: invalid peripheral %d", __func__, peripheral);
return -1;
};
src = (src >> bit_info->src_bit) & 0xf;
switch (src) {
case EXYNOS_SRC_MPLL:
sclk = exynos5_get_pll_clk(MPLL);
break;
case EXYNOS_SRC_EPLL:
sclk = exynos5_get_pll_clk(EPLL);
break;
case EXYNOS_SRC_VPLL:
sclk = exynos5_get_pll_clk(VPLL);
break;
default:
return 0;
}
/* Ratio clock division for this peripheral */
sub_div = (div >> bit_info->div_bit) & 0xf;
sub_clk = sclk / (sub_div + 1);
/* Pre-ratio clock division for SDMMC0 and 2 */
if (peripheral == PERIPH_ID_SDMMC0 || peripheral == PERIPH_ID_SDMMC2) {
div = (div >> bit_info->prediv_bit) & 0xff;
return sub_clk / (div + 1);
}
return sub_clk;
}
unsigned long clock_get_periph_rate(int peripheral)
{
if (cpu_is_exynos5())
return exynos5_get_periph_rate(peripheral);
else
return 0;
}
/* exynos5420: return pll clock frequency */
static unsigned long exynos5420_get_pll_clk(int pllreg)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
unsigned long r, k = 0;
switch (pllreg) {
case APLL:
r = readl(&clk->apll_con0);
break;
case MPLL:
r = readl(&clk->mpll_con0);
break;
case EPLL:
r = readl(&clk->epll_con0);
k = readl(&clk->epll_con1);
break;
case VPLL:
r = readl(&clk->vpll_con0);
k = readl(&clk->vpll_con1);
break;
case BPLL:
r = readl(&clk->bpll_con0);
break;
case RPLL:
r = readl(&clk->rpll_con0);
k = readl(&clk->rpll_con1);
break;
case SPLL:
r = readl(&clk->spll_con0);
break;
default:
printf("Unsupported PLL (%d)\n", pllreg);
return 0;
}
return exynos_get_pll_clk(pllreg, r, k);
}
/* exynos4: return ARM clock frequency */
static unsigned long exynos4_get_arm_clk(void)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned long div;
unsigned long armclk;
unsigned int core_ratio;
unsigned int core2_ratio;
div = readl(&clk->div_cpu0);
/* CORE_RATIO: [2:0], CORE2_RATIO: [30:28] */
core_ratio = (div >> 0) & 0x7;
core2_ratio = (div >> 28) & 0x7;
armclk = get_pll_clk(APLL) / (core_ratio + 1);
armclk /= (core2_ratio + 1);
return armclk;
}
/* exynos4x12: return ARM clock frequency */
static unsigned long exynos4x12_get_arm_clk(void)
{
struct exynos4x12_clock *clk =
(struct exynos4x12_clock *)samsung_get_base_clock();
unsigned long div;
unsigned long armclk;
unsigned int core_ratio;
unsigned int core2_ratio;
div = readl(&clk->div_cpu0);
/* CORE_RATIO: [2:0], CORE2_RATIO: [30:28] */
core_ratio = (div >> 0) & 0x7;
core2_ratio = (div >> 28) & 0x7;
armclk = get_pll_clk(APLL) / (core_ratio + 1);
armclk /= (core2_ratio + 1);
return armclk;
}
/* exynos5: return ARM clock frequency */
static unsigned long exynos5_get_arm_clk(void)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned long div;
unsigned long armclk;
unsigned int arm_ratio;
unsigned int arm2_ratio;
div = readl(&clk->div_cpu0);
/* ARM_RATIO: [2:0], ARM2_RATIO: [30:28] */
arm_ratio = (div >> 0) & 0x7;
arm2_ratio = (div >> 28) & 0x7;
armclk = get_pll_clk(APLL) / (arm_ratio + 1);
armclk /= (arm2_ratio + 1);
return armclk;
}
/* exynos4: return pwm clock frequency */
static unsigned long exynos4_get_pwm_clk(void)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned long pclk, sclk;
unsigned int sel;
unsigned int ratio;
if (s5p_get_cpu_rev() == 0) {
/*
* CLK_SRC_PERIL0
* PWM_SEL [27:24]
*/
sel = readl(&clk->src_peril0);
sel = (sel >> 24) & 0xf;
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
/*
* CLK_DIV_PERIL3
* PWM_RATIO [3:0]
*/
ratio = readl(&clk->div_peril3);
ratio = ratio & 0xf;
} else if (s5p_get_cpu_rev() == 1) {
sclk = get_pll_clk(MPLL);
ratio = 8;
} else
return 0;
pclk = sclk / (ratio + 1);
return pclk;
}
/* exynos4x12: return pwm clock frequency */
static unsigned long exynos4x12_get_pwm_clk(void)
{
unsigned long pclk, sclk;
unsigned int ratio;
sclk = get_pll_clk(MPLL);
ratio = 8;
pclk = sclk / (ratio + 1);
return pclk;
}
/* exynos5420: return pwm clock frequency */
static unsigned long exynos5420_get_pwm_clk(void)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
unsigned long pclk, sclk;
unsigned int ratio;
/*
* CLK_DIV_PERIC0
* PWM_RATIO [31:28]
*/
ratio = readl(&clk->div_peric0);
ratio = (ratio >> 28) & 0xf;
sclk = get_pll_clk(MPLL);
pclk = sclk / (ratio + 1);
return pclk;
}
/* exynos4: return uart clock frequency */
static unsigned long exynos4_get_uart_clk(int dev_index)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned long uclk, sclk;
unsigned int sel;
unsigned int ratio;
/*
* CLK_SRC_PERIL0
* UART0_SEL [3:0]
* UART1_SEL [7:4]
* UART2_SEL [8:11]
* UART3_SEL [12:15]
* UART4_SEL [16:19]
* UART5_SEL [23:20]
*/
sel = readl(&clk->src_peril0);
sel = (sel >> (dev_index << 2)) & 0xf;
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
/*
* CLK_DIV_PERIL0
* UART0_RATIO [3:0]
* UART1_RATIO [7:4]
* UART2_RATIO [8:11]
* UART3_RATIO [12:15]
* UART4_RATIO [16:19]
* UART5_RATIO [23:20]
*/
ratio = readl(&clk->div_peril0);
ratio = (ratio >> (dev_index << 2)) & 0xf;
uclk = sclk / (ratio + 1);
return uclk;
}
/* exynos4x12: return uart clock frequency */
static unsigned long exynos4x12_get_uart_clk(int dev_index)
{
struct exynos4x12_clock *clk =
(struct exynos4x12_clock *)samsung_get_base_clock();
unsigned long uclk, sclk;
unsigned int sel;
unsigned int ratio;
/*
* CLK_SRC_PERIL0
* UART0_SEL [3:0]
* UART1_SEL [7:4]
* UART2_SEL [8:11]
* UART3_SEL [12:15]
* UART4_SEL [16:19]
*/
sel = readl(&clk->src_peril0);
sel = (sel >> (dev_index << 2)) & 0xf;
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
/*
* CLK_DIV_PERIL0
* UART0_RATIO [3:0]
* UART1_RATIO [7:4]
* UART2_RATIO [8:11]
* UART3_RATIO [12:15]
* UART4_RATIO [16:19]
*/
ratio = readl(&clk->div_peril0);
ratio = (ratio >> (dev_index << 2)) & 0xf;
uclk = sclk / (ratio + 1);
return uclk;
}
/* exynos5: return uart clock frequency */
static unsigned long exynos5_get_uart_clk(int dev_index)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned long uclk, sclk;
unsigned int sel;
unsigned int ratio;
/*
* CLK_SRC_PERIC0
* UART0_SEL [3:0]
* UART1_SEL [7:4]
* UART2_SEL [8:11]
* UART3_SEL [12:15]
* UART4_SEL [16:19]
* UART5_SEL [23:20]
*/
sel = readl(&clk->src_peric0);
sel = (sel >> (dev_index << 2)) & 0xf;
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
/*
* CLK_DIV_PERIC0
* UART0_RATIO [3:0]
* UART1_RATIO [7:4]
* UART2_RATIO [8:11]
* UART3_RATIO [12:15]
* UART4_RATIO [16:19]
* UART5_RATIO [23:20]
*/
ratio = readl(&clk->div_peric0);
ratio = (ratio >> (dev_index << 2)) & 0xf;
uclk = sclk / (ratio + 1);
return uclk;
}
/* exynos5420: return uart clock frequency */
static unsigned long exynos5420_get_uart_clk(int dev_index)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
unsigned long uclk, sclk;
unsigned int sel;
unsigned int ratio;
/*
* CLK_SRC_PERIC0
* UART0_SEL [6:4]
* UART1_SEL [10:8]
* UART2_SEL [14:12]
* UART3_SEL [18:16]
* generalised calculation as follows
* sel = (sel >> ((dev_index * 4) + 4)) & mask;
*/
sel = readl(&clk->src_peric0);
sel = (sel >> ((dev_index * 4) + 4)) & 0x7;
if (sel == 0x3)
sclk = get_pll_clk(MPLL);
else if (sel == 0x6)
sclk = get_pll_clk(EPLL);
else if (sel == 0x7)
sclk = get_pll_clk(RPLL);
else
return 0;
/*
* CLK_DIV_PERIC0
* UART0_RATIO [11:8]
* UART1_RATIO [15:12]
* UART2_RATIO [19:16]
* UART3_RATIO [23:20]
* generalised calculation as follows
* ratio = (ratio >> ((dev_index * 4) + 8)) & mask;
*/
ratio = readl(&clk->div_peric0);
ratio = (ratio >> ((dev_index * 4) + 8)) & 0xf;
uclk = sclk / (ratio + 1);
return uclk;
}
static unsigned long exynos4_get_mmc_clk(int dev_index)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned long uclk, sclk;
unsigned int sel, ratio, pre_ratio;
int shift = 0;
sel = readl(&clk->src_fsys);
sel = (sel >> (dev_index << 2)) & 0xf;
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
switch (dev_index) {
case 0:
case 1:
ratio = readl(&clk->div_fsys1);
pre_ratio = readl(&clk->div_fsys1);
break;
case 2:
case 3:
ratio = readl(&clk->div_fsys2);
pre_ratio = readl(&clk->div_fsys2);
break;
case 4:
ratio = readl(&clk->div_fsys3);
pre_ratio = readl(&clk->div_fsys3);
break;
default:
return 0;
}
if (dev_index == 1 || dev_index == 3)
shift = 16;
ratio = (ratio >> shift) & 0xf;
pre_ratio = (pre_ratio >> (shift + 8)) & 0xff;
uclk = (sclk / (ratio + 1)) / (pre_ratio + 1);
return uclk;
}
static unsigned long exynos5_get_mmc_clk(int dev_index)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned long uclk, sclk;
unsigned int sel, ratio, pre_ratio;
int shift = 0;
sel = readl(&clk->src_fsys);
sel = (sel >> (dev_index << 2)) & 0xf;
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
switch (dev_index) {
case 0:
case 1:
ratio = readl(&clk->div_fsys1);
pre_ratio = readl(&clk->div_fsys1);
break;
case 2:
case 3:
ratio = readl(&clk->div_fsys2);
pre_ratio = readl(&clk->div_fsys2);
break;
default:
return 0;
}
if (dev_index == 1 || dev_index == 3)
shift = 16;
ratio = (ratio >> shift) & 0xf;
pre_ratio = (pre_ratio >> (shift + 8)) & 0xff;
uclk = (sclk / (ratio + 1)) / (pre_ratio + 1);
return uclk;
}
static unsigned long exynos5420_get_mmc_clk(int dev_index)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
unsigned long uclk, sclk;
unsigned int sel, ratio;
/*
* CLK_SRC_FSYS
* MMC0_SEL [10:8]
* MMC1_SEL [14:12]
* MMC2_SEL [18:16]
* generalised calculation as follows
* sel = (sel >> ((dev_index * 4) + 8)) & mask
*/
sel = readl(&clk->src_fsys);
sel = (sel >> ((dev_index * 4) + 8)) & 0x7;
if (sel == 0x3)
sclk = get_pll_clk(MPLL);
else if (sel == 0x6)
sclk = get_pll_clk(EPLL);
else
return 0;
/*
* CLK_DIV_FSYS1
* MMC0_RATIO [9:0]
* MMC1_RATIO [19:10]
* MMC2_RATIO [29:20]
* generalised calculation as follows
* ratio = (ratio >> (dev_index * 10)) & mask
*/
ratio = readl(&clk->div_fsys1);
ratio = (ratio >> (dev_index * 10)) & 0x3ff;
uclk = (sclk / (ratio + 1));
return uclk;
}
/* exynos4: set the mmc clock */
static void exynos4_set_mmc_clk(int dev_index, unsigned int div)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned int addr, clear_bit, set_bit;
/*
* CLK_DIV_FSYS1
* MMC0_PRE_RATIO [15:8], MMC1_PRE_RATIO [31:24]
* CLK_DIV_FSYS2
* MMC2_PRE_RATIO [15:8], MMC3_PRE_RATIO [31:24]
* CLK_DIV_FSYS3
* MMC4_RATIO [3:0]
*/
if (dev_index < 2) {
addr = (unsigned int)&clk->div_fsys1;
clear_bit = MASK_PRE_RATIO(dev_index);
set_bit = SET_PRE_RATIO(dev_index, div);
} else if (dev_index == 4) {
addr = (unsigned int)&clk->div_fsys3;
dev_index -= 4;
/* MMC4 is controlled with the MMC4_RATIO value */
clear_bit = MASK_RATIO(dev_index);
set_bit = SET_RATIO(dev_index, div);
} else {
addr = (unsigned int)&clk->div_fsys2;
dev_index -= 2;
clear_bit = MASK_PRE_RATIO(dev_index);
set_bit = SET_PRE_RATIO(dev_index, div);
}
clrsetbits_le32(addr, clear_bit, set_bit);
}
/* exynos5: set the mmc clock */
static void exynos5_set_mmc_clk(int dev_index, unsigned int div)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned int addr;
/*
* CLK_DIV_FSYS1
* MMC0_PRE_RATIO [15:8], MMC1_PRE_RATIO [31:24]
* CLK_DIV_FSYS2
* MMC2_PRE_RATIO [15:8], MMC3_PRE_RATIO [31:24]
*/
if (dev_index < 2) {
addr = (unsigned int)&clk->div_fsys1;
} else {
addr = (unsigned int)&clk->div_fsys2;
dev_index -= 2;
}
clrsetbits_le32(addr, 0xff << ((dev_index << 4) + 8),
(div & 0xff) << ((dev_index << 4) + 8));
}
/* exynos5: set the mmc clock */
static void exynos5420_set_mmc_clk(int dev_index, unsigned int div)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
unsigned int addr;
unsigned int shift;
/*
* CLK_DIV_FSYS1
* MMC0_RATIO [9:0]
* MMC1_RATIO [19:10]
* MMC2_RATIO [29:20]
*/
addr = (unsigned int)&clk->div_fsys1;
shift = dev_index * 10;
clrsetbits_le32(addr, 0x3ff << shift, (div & 0x3ff) << shift);
}
/* get_lcd_clk: return lcd clock frequency */
static unsigned long exynos4_get_lcd_clk(void)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned long pclk, sclk;
unsigned int sel;
unsigned int ratio;
/*
* CLK_SRC_LCD0
* FIMD0_SEL [3:0]
*/
sel = readl(&clk->src_lcd0);
sel = sel & 0xf;
/*
* 0x6: SCLK_MPLL
* 0x7: SCLK_EPLL
* 0x8: SCLK_VPLL
*/
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
/*
* CLK_DIV_LCD0
* FIMD0_RATIO [3:0]
*/
ratio = readl(&clk->div_lcd0);
ratio = ratio & 0xf;
pclk = sclk / (ratio + 1);
return pclk;
}
/* get_lcd_clk: return lcd clock frequency */
static unsigned long exynos5_get_lcd_clk(void)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned long pclk, sclk;
unsigned int sel;
unsigned int ratio;
/*
* CLK_SRC_LCD0
* FIMD0_SEL [3:0]
*/
sel = readl(&clk->src_disp1_0);
sel = sel & 0xf;
/*
* 0x6: SCLK_MPLL
* 0x7: SCLK_EPLL
* 0x8: SCLK_VPLL
*/
if (sel == 0x6)
sclk = get_pll_clk(MPLL);
else if (sel == 0x7)
sclk = get_pll_clk(EPLL);
else if (sel == 0x8)
sclk = get_pll_clk(VPLL);
else
return 0;
/*
* CLK_DIV_LCD0
* FIMD0_RATIO [3:0]
*/
ratio = readl(&clk->div_disp1_0);
ratio = ratio & 0xf;
pclk = sclk / (ratio + 1);
return pclk;
}
static unsigned long exynos5420_get_lcd_clk(void)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
unsigned long pclk, sclk;
unsigned int sel;
unsigned int ratio;
/*
* CLK_SRC_DISP10
* FIMD1_SEL [4]
* 0: SCLK_RPLL
* 1: SCLK_SPLL
*/
sel = readl(&clk->src_disp10);
sel &= (1 << 4);
if (sel)
sclk = get_pll_clk(SPLL);
else
sclk = get_pll_clk(RPLL);
/*
* CLK_DIV_DISP10
* FIMD1_RATIO [3:0]
*/
ratio = readl(&clk->div_disp10);
ratio = ratio & 0xf;
pclk = sclk / (ratio + 1);
return pclk;
}
void exynos4_set_lcd_clk(void)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
/*
* CLK_GATE_BLOCK
* CLK_CAM [0]
* CLK_TV [1]
* CLK_MFC [2]
* CLK_G3D [3]
* CLK_LCD0 [4]
* CLK_LCD1 [5]
* CLK_GPS [7]
*/
setbits_le32(&clk->gate_block, 1 << 4);
/*
* CLK_SRC_LCD0
* FIMD0_SEL [3:0]
* MDNIE0_SEL [7:4]
* MDNIE_PWM0_SEL [8:11]
* MIPI0_SEL [12:15]
* set lcd0 src clock 0x6: SCLK_MPLL
*/
clrsetbits_le32(&clk->src_lcd0, 0xf, 0x6);
/*
* CLK_GATE_IP_LCD0
* CLK_FIMD0 [0]
* CLK_MIE0 [1]
* CLK_MDNIE0 [2]
* CLK_DSIM0 [3]
* CLK_SMMUFIMD0 [4]
* CLK_PPMULCD0 [5]
* Gating all clocks for FIMD0
*/
setbits_le32(&clk->gate_ip_lcd0, 1 << 0);
/*
* CLK_DIV_LCD0
* FIMD0_RATIO [3:0]
* MDNIE0_RATIO [7:4]
* MDNIE_PWM0_RATIO [11:8]
* MDNIE_PWM_PRE_RATIO [15:12]
* MIPI0_RATIO [19:16]
* MIPI0_PRE_RATIO [23:20]
* set fimd ratio
*/
clrsetbits_le32(&clk->div_lcd0, 0xf, 0x1);
}
void exynos5_set_lcd_clk(void)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
/*
* CLK_GATE_BLOCK
* CLK_CAM [0]
* CLK_TV [1]
* CLK_MFC [2]
* CLK_G3D [3]
* CLK_LCD0 [4]
* CLK_LCD1 [5]
* CLK_GPS [7]
*/
setbits_le32(&clk->gate_block, 1 << 4);
/*
* CLK_SRC_LCD0
* FIMD0_SEL [3:0]
* MDNIE0_SEL [7:4]
* MDNIE_PWM0_SEL [8:11]
* MIPI0_SEL [12:15]
* set lcd0 src clock 0x6: SCLK_MPLL
*/
clrsetbits_le32(&clk->src_disp1_0, 0xf, 0x6);
/*
* CLK_GATE_IP_LCD0
* CLK_FIMD0 [0]
* CLK_MIE0 [1]
* CLK_MDNIE0 [2]
* CLK_DSIM0 [3]
* CLK_SMMUFIMD0 [4]
* CLK_PPMULCD0 [5]
* Gating all clocks for FIMD0
*/
setbits_le32(&clk->gate_ip_disp1, 1 << 0);
/*
* CLK_DIV_LCD0
* FIMD0_RATIO [3:0]
* MDNIE0_RATIO [7:4]
* MDNIE_PWM0_RATIO [11:8]
* MDNIE_PWM_PRE_RATIO [15:12]
* MIPI0_RATIO [19:16]
* MIPI0_PRE_RATIO [23:20]
* set fimd ratio
*/
clrsetbits_le32(&clk->div_disp1_0, 0xf, 0x0);
}
void exynos5420_set_lcd_clk(void)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
unsigned int cfg;
/*
* CLK_SRC_DISP10
* FIMD1_SEL [4]
* 0: SCLK_RPLL
* 1: SCLK_SPLL
*/
cfg = readl(&clk->src_disp10);
cfg &= ~(0x1 << 4);
cfg |= (0 << 4);
writel(cfg, &clk->src_disp10);
/*
* CLK_DIV_DISP10
* FIMD1_RATIO [3:0]
*/
cfg = readl(&clk->div_disp10);
cfg &= ~(0xf << 0);
cfg |= (0 << 0);
writel(cfg, &clk->div_disp10);
}
void exynos4_set_mipi_clk(void)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
/*
* CLK_SRC_LCD0
* FIMD0_SEL [3:0]
* MDNIE0_SEL [7:4]
* MDNIE_PWM0_SEL [8:11]
* MIPI0_SEL [12:15]
* set mipi0 src clock 0x6: SCLK_MPLL
*/
clrsetbits_le32(&clk->src_lcd0, 0xf << 12, 0x6 << 12);
/*
* CLK_SRC_MASK_LCD0
* FIMD0_MASK [0]
* MDNIE0_MASK [4]
* MDNIE_PWM0_MASK [8]
* MIPI0_MASK [12]
* set src mask mipi0 0x1: Unmask
*/
setbits_le32(&clk->src_mask_lcd0, 0x1 << 12);
/*
* CLK_GATE_IP_LCD0
* CLK_FIMD0 [0]
* CLK_MIE0 [1]
* CLK_MDNIE0 [2]
* CLK_DSIM0 [3]
* CLK_SMMUFIMD0 [4]
* CLK_PPMULCD0 [5]
* Gating all clocks for MIPI0
*/
setbits_le32(&clk->gate_ip_lcd0, 1 << 3);
/*
* CLK_DIV_LCD0
* FIMD0_RATIO [3:0]
* MDNIE0_RATIO [7:4]
* MDNIE_PWM0_RATIO [11:8]
* MDNIE_PWM_PRE_RATIO [15:12]
* MIPI0_RATIO [19:16]
* MIPI0_PRE_RATIO [23:20]
* set mipi ratio
*/
clrsetbits_le32(&clk->div_lcd0, 0xf << 16, 0x1 << 16);
}
/*
* I2C
*
* exynos5: obtaining the I2C clock
*/
static unsigned long exynos5_get_i2c_clk(void)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned long aclk_66, aclk_66_pre, sclk;
unsigned int ratio;
sclk = get_pll_clk(MPLL);
ratio = (readl(&clk->div_top1)) >> 24;
ratio &= 0x7;
aclk_66_pre = sclk / (ratio + 1);
ratio = readl(&clk->div_top0);
ratio &= 0x7;
aclk_66 = aclk_66_pre / (ratio + 1);
return aclk_66;
}
int exynos5_set_epll_clk(unsigned long rate)
{
unsigned int epll_con, epll_con_k;
unsigned int i;
unsigned int lockcnt;
unsigned int start;
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
epll_con = readl(&clk->epll_con0);
epll_con &= ~((EPLL_CON0_LOCK_DET_EN_MASK <<
EPLL_CON0_LOCK_DET_EN_SHIFT) |
EPLL_CON0_MDIV_MASK << EPLL_CON0_MDIV_SHIFT |
EPLL_CON0_PDIV_MASK << EPLL_CON0_PDIV_SHIFT |
EPLL_CON0_SDIV_MASK << EPLL_CON0_SDIV_SHIFT);
for (i = 0; i < ARRAY_SIZE(exynos5_epll_div); i++) {
if (exynos5_epll_div[i].freq_out == rate)
break;
}
if (i == ARRAY_SIZE(exynos5_epll_div))
return -1;
epll_con_k = exynos5_epll_div[i].k_dsm << 0;
epll_con |= exynos5_epll_div[i].en_lock_det <<
EPLL_CON0_LOCK_DET_EN_SHIFT;
epll_con |= exynos5_epll_div[i].m_div << EPLL_CON0_MDIV_SHIFT;
epll_con |= exynos5_epll_div[i].p_div << EPLL_CON0_PDIV_SHIFT;
epll_con |= exynos5_epll_div[i].s_div << EPLL_CON0_SDIV_SHIFT;
/*
* Required period ( in cycles) to genarate a stable clock output.
* The maximum clock time can be up to 3000 * PDIV cycles of PLLs
* frequency input (as per spec)
*/
lockcnt = 3000 * exynos5_epll_div[i].p_div;
writel(lockcnt, &clk->epll_lock);
writel(epll_con, &clk->epll_con0);
writel(epll_con_k, &clk->epll_con1);
start = get_timer(0);
while (!(readl(&clk->epll_con0) &
(0x1 << EXYNOS5_EPLLCON0_LOCKED_SHIFT))) {
if (get_timer(start) > TIMEOUT_EPLL_LOCK) {
debug("%s: Timeout waiting for EPLL lock\n", __func__);
return -1;
}
}
return 0;
}
int exynos5_set_i2s_clk_source(unsigned int i2s_id)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned int *audio_ass = (unsigned int *)samsung_get_base_audio_ass();
if (i2s_id == 0) {
setbits_le32(&clk->src_top2, CLK_SRC_MOUT_EPLL);
clrsetbits_le32(&clk->src_mau, AUDIO0_SEL_MASK,
(CLK_SRC_SCLK_EPLL));
setbits_le32(audio_ass, AUDIO_CLKMUX_ASS);
} else if (i2s_id == 1) {
clrsetbits_le32(&clk->src_peric1, AUDIO1_SEL_MASK,
(CLK_SRC_SCLK_EPLL));
} else {
return -1;
}
return 0;
}
int exynos5_set_i2s_clk_prescaler(unsigned int src_frq,
unsigned int dst_frq,
unsigned int i2s_id)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
unsigned int div;
if ((dst_frq == 0) || (src_frq == 0)) {
debug("%s: Invalid requency input for prescaler\n", __func__);
debug("src frq = %d des frq = %d ", src_frq, dst_frq);
return -1;
}
div = (src_frq / dst_frq);
if (i2s_id == 0) {
if (div > AUDIO_0_RATIO_MASK) {
debug("%s: Frequency ratio is out of range\n",
__func__);
debug("src frq = %d des frq = %d ", src_frq, dst_frq);
return -1;
}
clrsetbits_le32(&clk->div_mau, AUDIO_0_RATIO_MASK,
(div & AUDIO_0_RATIO_MASK));
} else if(i2s_id == 1) {
if (div > AUDIO_1_RATIO_MASK) {
debug("%s: Frequency ratio is out of range\n",
__func__);
debug("src frq = %d des frq = %d ", src_frq, dst_frq);
return -1;
}
clrsetbits_le32(&clk->div_peric4, AUDIO_1_RATIO_MASK,
(div & AUDIO_1_RATIO_MASK));
} else {
return -1;
}
return 0;
}
/**
* Linearly searches for the most accurate main and fine stage clock scalars
* (divisors) for a specified target frequency and scalar bit sizes by checking
* all multiples of main_scalar_bits values. Will always return scalars up to or
* slower than target.
*
* @param main_scalar_bits Number of main scalar bits, must be > 0 and < 32
* @param fine_scalar_bits Number of fine scalar bits, must be > 0 and < 32
* @param input_freq Clock frequency to be scaled in Hz
* @param target_freq Desired clock frequency in Hz
* @param best_fine_scalar Pointer to store the fine stage divisor
*
* @return best_main_scalar Main scalar for desired frequency or -1 if none
* found
*/
static int clock_calc_best_scalar(unsigned int main_scaler_bits,
unsigned int fine_scalar_bits, unsigned int input_rate,
unsigned int target_rate, unsigned int *best_fine_scalar)
{
int i;
int best_main_scalar = -1;
unsigned int best_error = target_rate;
const unsigned int cap = (1 << fine_scalar_bits) - 1;
const unsigned int loops = 1 << main_scaler_bits;
debug("Input Rate is %u, Target is %u, Cap is %u\n", input_rate,
target_rate, cap);
assert(best_fine_scalar != NULL);
assert(main_scaler_bits <= fine_scalar_bits);
*best_fine_scalar = 1;
if (input_rate == 0 || target_rate == 0)
return -1;
if (target_rate >= input_rate)
return 1;
for (i = 1; i <= loops; i++) {
const unsigned int effective_div =
max(min(input_rate / i / target_rate, cap), 1U);
const unsigned int effective_rate = input_rate / i /
effective_div;
const int error = target_rate - effective_rate;
debug("%d|effdiv:%u, effrate:%u, error:%d\n", i, effective_div,
effective_rate, error);
if (error >= 0 && error <= best_error) {
best_error = error;
best_main_scalar = i;
*best_fine_scalar = effective_div;
}
}
return best_main_scalar;
}
static int exynos5_set_spi_clk(enum periph_id periph_id,
unsigned int rate)
{
struct exynos5_clock *clk =
(struct exynos5_clock *)samsung_get_base_clock();
int main;
unsigned int fine;
unsigned shift, pre_shift;
unsigned mask = 0xff;
u32 *reg;
main = clock_calc_best_scalar(4, 8, 400000000, rate, &fine);
if (main < 0) {
debug("%s: Cannot set clock rate for periph %d",
__func__, periph_id);
return -1;
}
main = main - 1;
fine = fine - 1;
switch (periph_id) {
case PERIPH_ID_SPI0:
reg = &clk->div_peric1;
shift = 0;
pre_shift = 8;
break;
case PERIPH_ID_SPI1:
reg = &clk->div_peric1;
shift = 16;
pre_shift = 24;
break;
case PERIPH_ID_SPI2:
reg = &clk->div_peric2;
shift = 0;
pre_shift = 8;
break;
case PERIPH_ID_SPI3:
reg = &clk->sclk_div_isp;
shift = 0;
pre_shift = 4;
break;
case PERIPH_ID_SPI4:
reg = &clk->sclk_div_isp;
shift = 12;
pre_shift = 16;
break;
default:
debug("%s: Unsupported peripheral ID %d\n", __func__,
periph_id);
return -1;
}
clrsetbits_le32(reg, mask << shift, (main & mask) << shift);
clrsetbits_le32(reg, mask << pre_shift, (fine & mask) << pre_shift);
return 0;
}
static int exynos5420_set_spi_clk(enum periph_id periph_id,
unsigned int rate)
{
struct exynos5420_clock *clk =
(struct exynos5420_clock *)samsung_get_base_clock();
int main;
unsigned int fine;
unsigned shift, pre_shift;
unsigned div_mask = 0xf, pre_div_mask = 0xff;
u32 *reg;
u32 *pre_reg;
main = clock_calc_best_scalar(4, 8, 400000000, rate, &fine);
if (main < 0) {
debug("%s: Cannot set clock rate for periph %d",
__func__, periph_id);
return -1;
}
main = main - 1;
fine = fine - 1;
switch (periph_id) {
case PERIPH_ID_SPI0:
reg = &clk->div_peric1;
shift = 20;
pre_reg = &clk->div_peric4;
pre_shift = 8;
break;
case PERIPH_ID_SPI1:
reg = &clk->div_peric1;
shift = 24;
pre_reg = &clk->div_peric4;
pre_shift = 16;
break;
case PERIPH_ID_SPI2:
reg = &clk->div_peric1;
shift = 28;
pre_reg = &clk->div_peric4;
pre_shift = 24;
break;
case PERIPH_ID_SPI3:
reg = &clk->div_isp1;
shift = 16;
pre_reg = &clk->div_isp1;
pre_shift = 0;
break;
case PERIPH_ID_SPI4:
reg = &clk->div_isp1;
shift = 20;
pre_reg = &clk->div_isp1;
pre_shift = 8;
break;
default:
debug("%s: Unsupported peripheral ID %d\n", __func__,
periph_id);
return -1;
}
clrsetbits_le32(reg, div_mask << shift, (main & div_mask) << shift);
clrsetbits_le32(pre_reg, pre_div_mask << pre_shift,
(fine & pre_div_mask) << pre_shift);
return 0;
}
static unsigned long exynos4_get_i2c_clk(void)
{
struct exynos4_clock *clk =
(struct exynos4_clock *)samsung_get_base_clock();
unsigned long sclk, aclk_100;
unsigned int ratio;
sclk = get_pll_clk(APLL);
ratio = (readl(&clk->div_top)) >> 4;
ratio &= 0xf;
aclk_100 = sclk / (ratio + 1);
return aclk_100;
}
unsigned long get_pll_clk(int pllreg)
{
if (cpu_is_exynos5()) {
if (proid_is_exynos5420())
return exynos5420_get_pll_clk(pllreg);
return exynos5_get_pll_clk(pllreg);
} else {
if (proid_is_exynos4412())
return exynos4x12_get_pll_clk(pllreg);
return exynos4_get_pll_clk(pllreg);
}
}
unsigned long get_arm_clk(void)
{
if (cpu_is_exynos5())
return exynos5_get_arm_clk();
else {
if (proid_is_exynos4412())
return exynos4x12_get_arm_clk();
return exynos4_get_arm_clk();
}
}
unsigned long get_i2c_clk(void)
{
if (cpu_is_exynos5()) {
return exynos5_get_i2c_clk();
} else if (cpu_is_exynos4()) {
return exynos4_get_i2c_clk();
} else {
debug("I2C clock is not set for this CPU\n");
return 0;
}
}
unsigned long get_pwm_clk(void)
{
if (cpu_is_exynos5()) {
if (proid_is_exynos5420())
return exynos5420_get_pwm_clk();
return clock_get_periph_rate(PERIPH_ID_PWM0);
} else {
if (proid_is_exynos4412())
return exynos4x12_get_pwm_clk();
return exynos4_get_pwm_clk();
}
}
unsigned long get_uart_clk(int dev_index)
{
if (cpu_is_exynos5()) {
if (proid_is_exynos5420())
return exynos5420_get_uart_clk(dev_index);
return exynos5_get_uart_clk(dev_index);
} else {
if (proid_is_exynos4412())
return exynos4x12_get_uart_clk(dev_index);
return exynos4_get_uart_clk(dev_index);
}
}
unsigned long get_mmc_clk(int dev_index)
{
if (cpu_is_exynos5()) {
if (proid_is_exynos5420())
return exynos5420_get_mmc_clk(dev_index);
return exynos5_get_mmc_clk(dev_index);
} else {
return exynos4_get_mmc_clk(dev_index);
}
}
void set_mmc_clk(int dev_index, unsigned int div)
{
if (cpu_is_exynos5()) {
if (proid_is_exynos5420())
exynos5420_set_mmc_clk(dev_index, div);
else
exynos5_set_mmc_clk(dev_index, div);
} else {
exynos4_set_mmc_clk(dev_index, div);
}
}
unsigned long get_lcd_clk(void)
{
if (cpu_is_exynos4())
return exynos4_get_lcd_clk();
else {
if (proid_is_exynos5420())
return exynos5420_get_lcd_clk();
else
return exynos5_get_lcd_clk();
}
}
void set_lcd_clk(void)
{
if (cpu_is_exynos4())
exynos4_set_lcd_clk();
else {
if (proid_is_exynos5250())
exynos5_set_lcd_clk();
else if (proid_is_exynos5420())
exynos5420_set_lcd_clk();
}
}
void set_mipi_clk(void)
{
if (cpu_is_exynos4())
exynos4_set_mipi_clk();
}
int set_spi_clk(int periph_id, unsigned int rate)
{
if (cpu_is_exynos5()) {
if (proid_is_exynos5420())
return exynos5420_set_spi_clk(periph_id, rate);
return exynos5_set_spi_clk(periph_id, rate);
} else {
return 0;
}
}
int set_i2s_clk_prescaler(unsigned int src_frq, unsigned int dst_frq,
unsigned int i2s_id)
{
if (cpu_is_exynos5())
return exynos5_set_i2s_clk_prescaler(src_frq, dst_frq, i2s_id);
else
return 0;
}
int set_i2s_clk_source(unsigned int i2s_id)
{
if (cpu_is_exynos5())
return exynos5_set_i2s_clk_source(i2s_id);
else
return 0;
}
int set_epll_clk(unsigned long rate)
{
if (cpu_is_exynos5())
return exynos5_set_epll_clk(rate);
else
return 0;
}