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/*
* Copyright (C) 2012 Juergen Beisert
*
* 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.
*/
#include <config.h>
#include <common.h>
#include <init.h>
#include <clock.h>
#include <io.h>
#include <asm-generic/div64.h>
#include <mach/s3c-iomap.h>
#include <mach/s3c-generic.h>
#include <mach/s3c-clocks.h>
/*
* The main clock tree:
*
* ref_in
* |
* v
* o-----------\
* | MUX -o------------\
* | / ^ | MUX --- DIV_APLL ------- ARMCLK -> CPU core
* o--- APLL -- | | / |
* | | o--/2 ------- |
* | APLL_SEL | |<-MISC_CON_SYN667
* | \ |
* o-----------\ MUX-o-------\ |
* | MUX--/ ^ | MUX --- DIV -o--------- HCLKx2 -> SDRAM (max. 266 MHz)
* | / ^ | | / |
* o---- MPLL-- | | o--/5 -- o-- DIV -- HCLK -> AXI / AHB (max. 133 MHz)
* | | | |
* | MPLL_SEL OTHERS_CLK_SELECT o-- DIV -- PCLK -> APB (max. 66 MHz)
* |
* o-----------\
* | MUX---- to various hardware
* | / ^
* o---- EPLL-- EPLL_SEL
*
*/
static unsigned s3c_get_apllclk(void)
{
uint32_t m, p, s, reg_val;
if (!(readl(S3C_CLK_SRC) & S3C_CLK_SRC_FOUTAPLL))
return S3C64XX_CLOCK_REFERENCE;
reg_val = readl(S3C_APLLCON);
if (!(reg_val & S3C_APLLCON_ENABLE))
return 0;
m = S3C_APLLCON_GET_MDIV(reg_val);
p = S3C_APLLCON_GET_PDIV(reg_val);
s = S3C_APLLCON_GET_SDIV(reg_val);
return (S3C64XX_CLOCK_REFERENCE * m) / (p << s);
}
uint32_t s3c_get_mpllclk(void)
{
uint32_t m, p, s, reg_val;
if (!(readl(S3C_CLK_SRC) & S3C_CLK_SRC_FOUTMPLL))
return S3C64XX_CLOCK_REFERENCE;
reg_val = readl(S3C_MPLLCON);
if (!(reg_val & S3C_MPLLCON_ENABLE))
return 0;
m = S3C_MPLLCON_GET_MDIV(reg_val);
p = S3C_MPLLCON_GET_PDIV(reg_val);
s = S3C_MPLLCON_GET_SDIV(reg_val);
return (S3C64XX_CLOCK_REFERENCE * m) / (p << s);
}
unsigned s3c_get_epllclk(void)
{
u32 m, p, s, k, reg0_val, reg1_val;
u64 tmp;
if (!(readl(S3C_CLK_SRC) & S3C_CLK_SRC_FOUTEPLL))
return S3C64XX_CLOCK_REFERENCE;
reg0_val = readl(S3C_EPLLCON0);
if (!(reg0_val & S3C_EPLLCON0_ENABLE))
return 0; /* PLL is disabled */
reg1_val = readl(S3C_EPLLCON1);
m = S3C_EPLLCON0_GET_MDIV(reg0_val);
p = S3C_EPLLCON0_GET_PDIV(reg0_val);
s = S3C_EPLLCON0_GET_SDIV(reg0_val);
k = S3C_EPLLCON1_GET_KDIV(reg1_val);
tmp = S3C64XX_CLOCK_REFERENCE;
tmp *= (m << 16) + k;
do_div(tmp, (p << s));
return (unsigned)(tmp >> 16);
}
unsigned s3c_set_epllclk(unsigned m, unsigned p, unsigned s, unsigned k)
{
u32 con0, con1, src = readl(S3C_CLK_SRC) & ~S3C_CLK_SRC_FOUTEPLL;
/* do not use the EPLL clock when it is in transit to the new frequency */
writel(src, S3C_CLK_SRC);
con0 = S3C_EPLLCON0_SET_MDIV(m) | S3C_EPLLCON0_SET_PDIV(p) |
S3C_EPLLCON0_SET_SDIV(s) | S3C_EPLLCON0_ENABLE;
con1 = S3C_EPLLCON1_SET_KDIV(k);
/*
* After changing the multiplication value 'm' the PLL output will
* be masked for the time set in the EPLL_LOCK register until it
* settles to the new frequency. EPLL_LOCK contains a value for a
* simple counter which counts the external reference clock.
*/
writel(con0, S3C_EPLLCON0);
writel(con1, S3C_EPLLCON1);
udelay((1000000000 / S3C64XX_CLOCK_REFERENCE)
* (S3C_EPLL_LOCK_PLL_LOCKTIME(readl(S3C_EPLL_LOCK)) + 1) / 1000);
/* enable the EPLL's clock output to the system */
writel(src | S3C_CLK_SRC_FOUTEPLL, S3C_CLK_SRC);
return s3c_get_epllclk();
}
uint32_t s3c_get_fclk(void)
{
unsigned clk;
clk = s3c_get_apllclk();
if (readl(S3C_MISC_CON) & S3C_MISC_CON_SYN667)
clk /= 2;
return clk / (S3C_CLK_DIV0_GET_ADIV(readl(S3C_CLK_DIV0)) + 1);
}
static unsigned s3c_get_hclk_in(void)
{
unsigned clk;
if (readl(S3C_OTHERS) & S3C_OTHERS_CLK_SELECT)
clk = s3c_get_apllclk();
else
clk = s3c_get_mpllclk();
if (readl(S3C_MISC_CON) & S3C_MISC_CON_SYN667)
clk /= 5;
return clk;
}
static unsigned s3c_get_hclkx2(void)
{
return s3c_get_hclk_in() /
(S3C_CLK_DIV0_GET_HCLK2(readl(S3C_CLK_DIV0)) + 1);
}
uint32_t s3c_get_hclk(void)
{
return s3c_get_hclkx2() /
(S3C_CLK_DIV0_GET_HCLK(readl(S3C_CLK_DIV0)) + 1);
}
uint32_t s3c_get_pclk(void)
{
return s3c_get_hclkx2() /
(S3C_CLK_DIV0_GET_PCLK(readl(S3C_CLK_DIV0)) + 1);
}
static void s3c_init_mpll_dout(void)
{
unsigned reg;
/* keep it at the same frequency as HCLKx2 */
reg = readl(S3C_CLK_DIV0) | S3C_CLK_DIV0_SET_MPLL_DIV(1); /* e.g. / 2 */
writel(reg, S3C_CLK_DIV0);
}
/* configure and enable UCLK1 */
static int s3c_init_uart_clock(void)
{
unsigned reg;
s3c_init_mpll_dout(); /* to have a reliable clock source */
/* source the UART clock from the MPLL, currently *not* from EPLL */
reg = readl(S3C_CLK_SRC) | S3C_CLK_SRC_UARTMPLL;
writel(reg, S3C_CLK_SRC);
/* keep UART clock at the same frequency than the PCLK */
reg = readl(S3C_CLK_DIV2) & ~S3C_CLK_DIV2_UART_MASK;
reg |= S3C_CLK_DIV2_SET_UART(0x3); /* / 4 */
writel(reg, S3C_CLK_DIV2);
/* ensure this very special clock is running */
reg = readl(S3C_SCLK_GATE) | S3C_SCLK_GATE_UART;
writel(reg, S3C_SCLK_GATE);
return 0;
}
core_initcall(s3c_init_uart_clock);
/* UART source selection
* The UART related clock path: |
* v
* PCLK --------------------------------------o-----0-\
* ???? -------------------------------UCLK0--|-----1--\MUX----- UART
* MPLL -----DIV0------\ +-----2--/
* MUX---DIV2------UCLK1--------3-/
* EPLL ---------------/
* ^SRC_UARTMPLL
*/
unsigned s3c_get_uart_clk(unsigned source)
{
u32 reg;
unsigned clk, pdiv, uartpdiv;
switch (source) {
default: /* PCLK */
clk = s3c_get_pclk();
pdiv = uartpdiv = 1;
break;
case 1: /* UCLK0 */
clk = 0;
pdiv = uartpdiv = 1; /* TODO */
break;
case 3: /* UCLK1 */
reg = readl(S3C_CLK_SRC);
if (reg & S3C_CLK_SRC_UARTMPLL) {
clk = s3c_get_mpllclk();
pdiv = S3C_CLK_DIV0_GET_MPLL_DIV(readl(S3C_CLK_DIV0)) + 1;
} else {
clk = s3c_get_epllclk();
pdiv = 1;
}
uartpdiv = S3C_CLK_DIV2_GET_UART(readl(S3C_CLK_DIV2)) + 1;
break;
}
return clk / pdiv / uartpdiv;
}
/*
* The MMC related clock path:
*
* MMCx_SEL
* |
* v
* EPLLout --------0-\
* MPLLout --DIV0--1--\-------SCLK_MMCx----DIV_MMCx------>HSMMCx
* EPLLin --------2--/ on/off / 1..16
* 27 MHz --------3-/
*
* The datasheet is not very precise here, so the schematic shown above was
* made by checking various bits in the SYSCON.
*/
unsigned s3c_get_hsmmc_clk(int id)
{
u32 sel, div, sclk = readl(S3C_SCLK_GATE);
unsigned bclk;
if (!(sclk & S3C_SCLK_GATE_MMC(id)))
return 0; /* disabled */
sel = S3C_CLK_SRC_GET_MMC_SEL(id, readl(S3C_CLK_SRC));
switch (sel) {
case 0:
bclk = s3c_get_epllclk();
break;
case 1:
bclk = s3c_get_mpllclk();
bclk >>= S3C_CLK_DIV0_GET_MPLL_DIV(readl(S3C_CLK_DIV0));
break;
case 2:
bclk = S3C64XX_CLOCK_REFERENCE;
break;
case 3:
bclk = 27000000;
break;
}
div = S3C_CLK_DIV0_GET_MMC(id, readl(S3C_CLK_DIV0)) + 1;
return bclk / div;
}
void s3c_set_hsmmc_clk(int id, int src, unsigned div)
{
u32 reg;
if (!div)
div = 1;
writel(readl(S3C_SCLK_GATE) & ~S3C_SCLK_GATE_MMC(id), S3C_SCLK_GATE);
/* select the new clock source */
reg = readl(S3C_CLK_SRC) & ~S3C_CLK_SRC_SET_MMC_SEL(id, ~0);
reg |= S3C_CLK_SRC_SET_MMC_SEL(id, src);
writel(reg, S3C_CLK_SRC);
/* select the new pre-divider */
reg = readl(S3C_CLK_DIV0) & ~ S3C_CLK_DIV0_SET_MMC(id, ~0);
reg |= S3C_CLK_DIV0_SET_MMC(id, div - 1);
writel(reg, S3C_CLK_DIV0);
/* calling this function implies enabling of the clock */
writel(readl(S3C_SCLK_GATE) | S3C_SCLK_GATE_MMC(id), S3C_SCLK_GATE);
}
static int s3c64xx_dump_clocks(void)
{
printf("refclk: %7d kHz\n", S3C64XX_CLOCK_REFERENCE / 1000);
printf("apll: %7d kHz\n", s3c_get_apllclk() / 1000);
printf("mpll: %7d kHz\n", s3c_get_mpllclk() / 1000);
printf("epll: %7d kHz\n", s3c_get_epllclk() / 1000);
printf("CPU: %7d kHz\n", s3c_get_fclk() / 1000);
printf("hclkx2: %7d kHz\n", s3c_get_hclkx2() / 1000);
printf("hclk: %7d kHz\n", s3c_get_hclk() / 1000);
printf("pclk: %7d kHz\n", s3c_get_pclk() / 1000);
return 0;
}
late_initcall(s3c64xx_dump_clocks);
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