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gerrit.devboardsforandroid.linaro.org / platform / external / u-boot / 607274f7f67e14aca0f0d1cde55569faa48f0183 / . / arch / arm / mach-nexell / clock.c
blob: a0ba2d8e0cf81596d6892be384d1a0983e64b817 [file] [log] [blame]
// SPDX-License-Identifier: GPL-2.0+
/*
* (C) Copyright 2016 Nexell
* Hyunseok, Jung <hsjung@nexell.co.kr>
*/
#include <common.h>
#include <command.h>
#include <linux/err.h>
#include <asm/io.h>
#include <asm/arch/nexell.h>
#include <asm/arch/clk.h>
/*
* clock generator macros
*/
#define I_PLL0_BIT (0)
#define I_PLL1_BIT (1)
#define I_PLL2_BIT (2)
#define I_PLL3_BIT (3)
#define I_EXT1_BIT (4)
#define I_EXT2_BIT (5)
#define I_CLKn_BIT (7)
#define I_EXT1_BIT_FORCE (8)
#define I_EXT2_BIT_FORCE (9)
#define I_CLOCK_NUM 6 /* PLL0, PLL1, PLL2, PLL3, EXT1, EXT2 */
#define I_EXECEPT_CLK (0)
#define I_CLOCK_MASK (((1 << I_CLOCK_NUM) - 1) & ~I_EXECEPT_CLK)
#define I_PLL0 (1 << I_PLL0_BIT)
#define I_PLL1 (1 << I_PLL1_BIT)
#define I_PLL2 (1 << I_PLL2_BIT)
#define I_PLL3 (1 << I_PLL3_BIT)
#define I_EXTCLK1 (1 << I_EXT1_BIT)
#define I_EXTCLK2 (1 << I_EXT2_BIT)
#define I_EXTCLK1_FORCE (1 << I_EXT1_BIT_FORCE)
#define I_EXTCLK2_FORCE (1 << I_EXT2_BIT_FORCE)
#define I_PLL_0_1 (I_PLL0 | I_PLL1)
#define I_PLL_0_2 (I_PLL_0_1 | I_PLL2)
#define I_PLL_0_3 (I_PLL_0_2 | I_PLL3)
#define I_CLKnOUT (0)
#define I_PCLK (1 << 16)
#define I_BCLK (1 << 17)
#define I_GATE_PCLK (1 << 20)
#define I_GATE_BCLK (1 << 21)
#define I_PCLK_MASK (I_GATE_PCLK | I_PCLK)
#define I_BCLK_MASK (I_GATE_BCLK | I_BCLK)
struct clk_dev_peri {
const char *dev_name;
void __iomem *base;
int dev_id;
int periph_id;
int clk_step;
u32 in_mask;
u32 in_mask1;
int div_src_0;
int div_val_0;
int invert_0;
int div_src_1;
int div_val_1;
int invert_1;
int in_extclk_1;
int in_extclk_2;
};
struct clk_dev {
struct clk clk;
struct clk *link;
const char *name;
struct clk_dev_peri *peri;
};
struct clk_dev_map {
unsigned int con_enb;
unsigned int con_gen[4];
};
#define CLK_PERI_1S(name, devid, id, addr, mk)[id] = \
{ .dev_name = name, .dev_id = devid, .periph_id = id, .clk_step = 1, \
.base = (void *)addr, .in_mask = mk, }
#define CLK_PERI_2S(name, devid, id, addr, mk, mk2)[id] = \
{ .dev_name = name, .dev_id = devid, .periph_id = id, .clk_step = 2, \
.base = (void *)addr, .in_mask = mk, .in_mask1 = mk2, }
static const char * const clk_core[] = {
CORECLK_NAME_PLL0, CORECLK_NAME_PLL1, CORECLK_NAME_PLL2,
CORECLK_NAME_PLL3, CORECLK_NAME_FCLK, CORECLK_NAME_MCLK,
CORECLK_NAME_BCLK, CORECLK_NAME_PCLK, CORECLK_NAME_HCLK,
};
/*
* Section ".data" must be used because BSS is not available before relocation,
* in board_init_f(), respectively! I.e. global variables can not be used!
*/
static struct clk_dev_peri clk_periphs[]
__attribute__((section(".data"))) = {
CLK_PERI_1S(DEV_NAME_TIMER, 0, CLK_ID_TIMER_0,
PHY_BASEADDR_CLKGEN14, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_TIMER, 1, CLK_ID_TIMER_1,
PHY_BASEADDR_CLKGEN0, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_TIMER, 2, CLK_ID_TIMER_2,
PHY_BASEADDR_CLKGEN1, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_TIMER, 3, CLK_ID_TIMER_3,
PHY_BASEADDR_CLKGEN2, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_UART, 0, CLK_ID_UART_0,
PHY_BASEADDR_CLKGEN22, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_UART, 1, CLK_ID_UART_1,
PHY_BASEADDR_CLKGEN24, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_UART, 2, CLK_ID_UART_2,
PHY_BASEADDR_CLKGEN23, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_UART, 3, CLK_ID_UART_3,
PHY_BASEADDR_CLKGEN25, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_UART, 4, CLK_ID_UART_4,
PHY_BASEADDR_CLKGEN26, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_UART, 5, CLK_ID_UART_5,
PHY_BASEADDR_CLKGEN27, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_PWM, 0, CLK_ID_PWM_0,
PHY_BASEADDR_CLKGEN13, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_PWM, 1, CLK_ID_PWM_1,
PHY_BASEADDR_CLKGEN3, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_PWM, 2, CLK_ID_PWM_2,
PHY_BASEADDR_CLKGEN4, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_PWM, 3, CLK_ID_PWM_3,
PHY_BASEADDR_CLKGEN5, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_I2C, 0, CLK_ID_I2C_0,
PHY_BASEADDR_CLKGEN6, (I_GATE_PCLK)),
CLK_PERI_1S(DEV_NAME_I2C, 1, CLK_ID_I2C_1,
PHY_BASEADDR_CLKGEN7, (I_GATE_PCLK)),
CLK_PERI_1S(DEV_NAME_I2C, 2, CLK_ID_I2C_2,
PHY_BASEADDR_CLKGEN8, (I_GATE_PCLK)),
CLK_PERI_2S(DEV_NAME_GMAC, 0, CLK_ID_GMAC,
PHY_BASEADDR_CLKGEN10,
(I_PLL_0_3 | I_EXTCLK1 | I_EXTCLK1_FORCE),
(I_CLKnOUT)),
CLK_PERI_2S(DEV_NAME_I2S, 0, CLK_ID_I2S_0,
PHY_BASEADDR_CLKGEN15, (I_PLL_0_3 | I_EXTCLK1),
(I_CLKnOUT)),
CLK_PERI_2S(DEV_NAME_I2S, 1, CLK_ID_I2S_1,
PHY_BASEADDR_CLKGEN16, (I_PLL_0_3 | I_EXTCLK1),
(I_CLKnOUT)),
CLK_PERI_2S(DEV_NAME_I2S, 2, CLK_ID_I2S_2,
PHY_BASEADDR_CLKGEN17, (I_PLL_0_3 | I_EXTCLK1),
(I_CLKnOUT)),
CLK_PERI_1S(DEV_NAME_SDHC, 0, CLK_ID_SDHC_0,
PHY_BASEADDR_CLKGEN18, (I_PLL_0_2 | I_GATE_PCLK)),
CLK_PERI_1S(DEV_NAME_SDHC, 1, CLK_ID_SDHC_1,
PHY_BASEADDR_CLKGEN19, (I_PLL_0_2 | I_GATE_PCLK)),
CLK_PERI_1S(DEV_NAME_SDHC, 2, CLK_ID_SDHC_2,
PHY_BASEADDR_CLKGEN20, (I_PLL_0_2 | I_GATE_PCLK)),
CLK_PERI_1S(DEV_NAME_SPI, 0, CLK_ID_SPI_0,
PHY_BASEADDR_CLKGEN37, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_SPI, 1, CLK_ID_SPI_1,
PHY_BASEADDR_CLKGEN38, (I_PLL_0_2)),
CLK_PERI_1S(DEV_NAME_SPI, 2, CLK_ID_SPI_2,
PHY_BASEADDR_CLKGEN39, (I_PLL_0_2)),
};
#define CLK_PERI_NUM ((int)ARRAY_SIZE(clk_periphs))
#define CLK_CORE_NUM ((int)ARRAY_SIZE(clk_core))
#define CLK_DEVS_NUM (CLK_CORE_NUM + CLK_PERI_NUM)
#define MAX_DIVIDER ((1 << 8) - 1) /* 256, align 2 */
static struct clk_dev st_clk_devs[CLK_DEVS_NUM]
__attribute__((section(".data")));
#define clk_dev_get(n) ((struct clk_dev *)&st_clk_devs[n])
#define clk_container(p) (container_of(p, struct clk_dev, clk))
/*
* Core frequencys
*/
struct _core_hz_ {
unsigned long pll[4]; /* PLL */
unsigned long cpu_fclk, cpu_bclk; /* cpu */
unsigned long mem_fclk, mem_dclk, mem_bclk, mem_pclk; /* ddr */
unsigned long bus_bclk, bus_pclk; /* bus */
#if defined(CONFIG_ARCH_S5P6818)
unsigned long cci4_bclk, cci4_pclk; /* cci */
#endif
/* ip */
unsigned long g3d_bclk;
unsigned long coda_bclk, coda_pclk;
#if defined(CONFIG_ARCH_S5P6818)
unsigned long disp_bclk, disp_pclk;
unsigned long hdmi_pclk;
#endif
};
/*
* Section ".data" must be used because BSS is not available before relocation,
* in board_init_f(), respectively! I.e. global variables can not be used!
*/
/* core clock */
static struct _core_hz_ core_hz __attribute__((section(".data")));
#define CORE_HZ_SIZE (sizeof(core_hz) / 4)
/*
* CLKGEN HW
*/
static inline void clk_dev_bclk(void *base, int on)
{
struct clk_dev_map *reg = base;
unsigned int val = readl(&reg->con_enb) & ~(0x3);
val |= (on ? 3 : 0) & 0x3; /* always BCLK */
writel(val, &reg->con_enb);
}
static inline void clk_dev_pclk(void *base, int on)
{
struct clk_dev_map *reg = base;
unsigned int val = 0;
if (!on)
return;
val = readl(&reg->con_enb) & ~(1 << 3);
val |= (1 << 3);
writel(val, &reg->con_enb);
}
static inline void clk_dev_rate(void *base, int step, int src, int div)
{
struct clk_dev_map *reg = base;
unsigned int val = 0;
val = readl(&reg->con_gen[step << 1]);
val &= ~(0x07 << 2);
val |= (src << 2); /* source */
val &= ~(0xFF << 5);
val |= (div - 1) << 5; /* divider */
writel(val, &reg->con_gen[step << 1]);
}
static inline void clk_dev_inv(void *base, int step, int inv)
{
struct clk_dev_map *reg = base;
unsigned int val = readl(&reg->con_gen[step << 1]) & ~(1 << 1);
val |= (inv << 1);
writel(val, &reg->con_gen[step << 1]);
}
static inline void clk_dev_enb(void *base, int on)
{
struct clk_dev_map *reg = base;
unsigned int val = readl(&reg->con_enb) & ~(1 << 2);
val |= ((on ? 1 : 0) << 2);
writel(val, &reg->con_enb);
}
/*
* CORE FREQUENCY
*
* PLL0 [P,M,S] ------- | | ----- [DIV0] --- CPU-G0
* |M| ----- [DIV1] --- BCLK/PCLK
* PLL1 [P,M,S] ------- | | ----- [DIV2] --- DDR
* |U| ----- [DIV3] --- 3D
* PLL2 [P,M,S,K]-------| | ----- [DIV4] --- CODA
* |X| ----- [DIV5] --- DISPLAY
* PLL3 [P,M,S,K]-------| | ----- [DIV6] --- HDMI
* | | ----- [DIV7] --- CPU-G1
* | | ----- [DIV8] --- CCI-400(FASTBUS)
*
*/
struct nx_clkpwr_registerset {
u32 clkmodereg0; /* 0x000 : Clock Mode Register0 */
u32 __reserved0; /* 0x004 */
u32 pllsetreg[4]; /* 0x008 ~ 0x014 : PLL Setting Register */
u32 __reserved1[2]; /* 0x018 ~ 0x01C */
u32 dvoreg[9]; /* 0x020 ~ 0x040 : Divider Setting Register */
u32 __Reserved2; /* 0x044 */
u32 pllsetreg_sscg[6]; /* 0x048 ~ 0x05C */
u32 __reserved3[8]; /* 0x060 ~ 0x07C */
u8 __reserved4[0x200 - 0x80]; /* padding (0x80 ~ 0x1FF) */
u32 gpiowakeupriseenb; /* 0x200 : GPIO Rising Edge Detect En. Reg. */
u32 gpiowakeupfallenb; /* 0x204 : GPIO Falling Edge Detect En. Reg. */
u32 gpiorstenb; /* 0x208 : GPIO Reset Enable Register */
u32 gpiowakeupenb; /* 0x20C : GPIO Wakeup Source Enable */
u32 gpiointenb; /* 0x210 : Interrupt Enable Register */
u32 gpiointpend; /* 0x214 : Interrupt Pend Register */
u32 resetstatus; /* 0x218 : Reset Status Register */
u32 intenable; /* 0x21C : Interrupt Enable Register */
u32 intpend; /* 0x220 : Interrupt Pend Register */
u32 pwrcont; /* 0x224 : Power Control Register */
u32 pwrmode; /* 0x228 : Power Mode Register */
u32 __reserved5; /* 0x22C : Reserved Region */
u32 scratch[3]; /* 0x230 ~ 0x238 : Scratch Register */
u32 sysrstconfig; /* 0x23C : System Reset Configuration Reg. */
u8 __reserved6[0x2A0 - 0x240]; /* padding (0x240 ~ 0x29F) */
u32 cpupowerdownreq; /* 0x2A0 : CPU Power Down Request Register */
u32 cpupoweronreq; /* 0x2A4 : CPU Power On Request Register */
u32 cpuresetmode; /* 0x2A8 : CPU Reset Mode Register */
u32 cpuwarmresetreq; /* 0x2AC : CPU Warm Reset Request Register */
u32 __reserved7; /* 0x2B0 */
u32 cpustatus; /* 0x2B4 : CPU Status Register */
u8 __reserved8[0x400 - 0x2B8]; /* padding (0x2B8 ~ 0x33F) */
};
static struct nx_clkpwr_registerset * const clkpwr =
(struct nx_clkpwr_registerset *)PHY_BASEADDR_CLKPWR;
#define getquotient(v, d) ((v) / (d))
#define DIV_CPUG0 0
#define DIV_BUS 1
#define DIV_MEM 2
#define DIV_G3D 3
#define DIV_CODA 4
#if defined(CONFIG_ARCH_S5P6818)
#define DIV_DISP 5
#define DIV_HDMI 6
#define DIV_CPUG1 7
#define DIV_CCI4 8
#endif
#define DVO0 3
#define DVO1 9
#define DVO2 15
#define DVO3 21
static unsigned int pll_rate(unsigned int plln, unsigned int xtal)
{
unsigned int val, val1, nP, nM, nS, nK;
unsigned int temp = 0;
val = clkpwr->pllsetreg[plln];
val1 = clkpwr->pllsetreg_sscg[plln];
xtal /= 1000; /* Unit Khz */
nP = (val >> 18) & 0x03F;
nM = (val >> 8) & 0x3FF;
nS = (val >> 0) & 0x0FF;
nK = (val1 >> 16) & 0xFFFF;
if (plln > 1 && nK) {
temp = (unsigned int)(getquotient((getquotient((nK * 1000),
65536) * xtal), nP) >> nS);
}
temp = (unsigned int)((getquotient((nM * xtal), nP) >> nS) * 1000)
+ temp;
return temp;
}
static unsigned int pll_dvo(int dvo)
{
unsigned int val;
val = (clkpwr->dvoreg[dvo] & 0x7);
return val;
}
static unsigned int pll_div(int dvo)
{
unsigned int val = clkpwr->dvoreg[dvo];
return ((((val >> DVO3) & 0x3F) + 1) << 24) |
((((val >> DVO2) & 0x3F) + 1) << 16) |
((((val >> DVO1) & 0x3F) + 1) << 8) |
((((val >> DVO0) & 0x3F) + 1) << 0);
}
#define PLLN_RATE(n) (pll_rate(n, CONFIG_SYS_PLLFIN)) /* 0~ 3 */
#define CPU_FCLK_RATE(n) (pll_rate(pll_dvo(n), CONFIG_SYS_PLLFIN) / \
((pll_div(n) >> 0) & 0x3F))
#define CPU_BCLK_RATE(n) (pll_rate(pll_dvo(n), CONFIG_SYS_PLLFIN) / \
((pll_div(n) >> 0) & 0x3F) / \
((pll_div(n) >> 8) & 0x3F))
#define MEM_FCLK_RATE() (pll_rate(pll_dvo(DIV_MEM), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_MEM) >> 0) & 0x3F) / \
((pll_div(DIV_MEM) >> 8) & 0x3F))
#define MEM_DCLK_RATE() (pll_rate(pll_dvo(DIV_MEM), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_MEM) >> 0) & 0x3F))
#define MEM_BCLK_RATE() (pll_rate(pll_dvo(DIV_MEM), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_MEM) >> 0) & 0x3F) / \
((pll_div(DIV_MEM) >> 8) & 0x3F) / \
((pll_div(DIV_MEM) >> 16) & 0x3F))
#define MEM_PCLK_RATE() (pll_rate(pll_dvo(DIV_MEM), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_MEM) >> 0) & 0x3F) / \
((pll_div(DIV_MEM) >> 8) & 0x3F) / \
((pll_div(DIV_MEM) >> 16) & 0x3F) / \
((pll_div(DIV_MEM) >> 24) & 0x3F))
#define BUS_BCLK_RATE() (pll_rate(pll_dvo(DIV_BUS), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_BUS) >> 0) & 0x3F))
#define BUS_PCLK_RATE() (pll_rate(pll_dvo(DIV_BUS), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_BUS) >> 0) & 0x3F) / \
((pll_div(DIV_BUS) >> 8) & 0x3F))
#define G3D_BCLK_RATE() (pll_rate(pll_dvo(DIV_G3D), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_G3D) >> 0) & 0x3F))
#define MPG_BCLK_RATE() (pll_rate(pll_dvo(DIV_CODA), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_CODA) >> 0) & 0x3F))
#define MPG_PCLK_RATE() (pll_rate(pll_dvo(DIV_CODA), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_CODA) >> 0) & 0x3F) / \
((pll_div(DIV_CODA) >> 8) & 0x3F))
#if defined(CONFIG_ARCH_S5P6818)
#define DISP_BCLK_RATE() (pll_rate(pll_dvo(DIV_DISP), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_DISP) >> 0) & 0x3F))
#define DISP_PCLK_RATE() (pll_rate(pll_dvo(DIV_DISP), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_DISP) >> 0) & 0x3F) / \
((pll_div(DIV_DISP) >> 8) & 0x3F))
#define HDMI_PCLK_RATE() (pll_rate(pll_dvo(DIV_HDMI), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_HDMI) >> 0) & 0x3F))
#define CCI4_BCLK_RATE() (pll_rate(pll_dvo(DIV_CCI4), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_CCI4) >> 0) & 0x3F))
#define CCI4_PCLK_RATE() (pll_rate(pll_dvo(DIV_CCI4), CONFIG_SYS_PLLFIN) / \
((pll_div(DIV_CCI4) >> 0) & 0x3F) / \
((pll_div(DIV_CCI4) >> 8) & 0x3F))
#endif
static void core_update_rate(int type)
{
switch (type) {
case 0:
core_hz.pll[0] = PLLN_RATE(0); break;
case 1:
core_hz.pll[1] = PLLN_RATE(1); break;
case 2:
core_hz.pll[2] = PLLN_RATE(2); break;
case 3:
core_hz.pll[3] = PLLN_RATE(3); break;
case 4:
core_hz.cpu_fclk = CPU_FCLK_RATE(DIV_CPUG0); break;
case 5:
core_hz.mem_fclk = MEM_FCLK_RATE(); break;
case 6:
core_hz.bus_bclk = BUS_BCLK_RATE(); break;
case 7:
core_hz.bus_pclk = BUS_PCLK_RATE(); break;
case 8:
core_hz.cpu_bclk = CPU_BCLK_RATE(DIV_CPUG0); break;
case 9:
core_hz.mem_dclk = MEM_DCLK_RATE(); break;
case 10:
core_hz.mem_bclk = MEM_BCLK_RATE(); break;
case 11:
core_hz.mem_pclk = MEM_PCLK_RATE(); break;
case 12:
core_hz.g3d_bclk = G3D_BCLK_RATE(); break;
case 13:
core_hz.coda_bclk = MPG_BCLK_RATE(); break;
case 14:
core_hz.coda_pclk = MPG_PCLK_RATE(); break;
#if defined(CONFIG_ARCH_S5P6818)
case 15:
core_hz.disp_bclk = DISP_BCLK_RATE(); break;
case 16:
core_hz.disp_pclk = DISP_PCLK_RATE(); break;
case 17:
core_hz.hdmi_pclk = HDMI_PCLK_RATE(); break;
case 18:
core_hz.cci4_bclk = CCI4_BCLK_RATE(); break;
case 19:
core_hz.cci4_pclk = CCI4_PCLK_RATE(); break;
#endif
};
}
static unsigned long core_get_rate(int type)
{
unsigned long rate = 0;
switch (type) {
case 0:
rate = core_hz.pll[0]; break;
case 1:
rate = core_hz.pll[1]; break;
case 2:
rate = core_hz.pll[2]; break;
case 3:
rate = core_hz.pll[3]; break;
case 4:
rate = core_hz.cpu_fclk; break;
case 5:
rate = core_hz.mem_fclk; break;
case 6:
rate = core_hz.bus_bclk; break;
case 7:
rate = core_hz.bus_pclk; break;
case 8:
rate = core_hz.cpu_bclk; break;
case 9:
rate = core_hz.mem_dclk; break;
case 10:
rate = core_hz.mem_bclk; break;
case 11:
rate = core_hz.mem_pclk; break;
case 12:
rate = core_hz.g3d_bclk; break;
case 13:
rate = core_hz.coda_bclk; break;
case 14:
rate = core_hz.coda_pclk; break;
#if defined(CONFIG_ARCH_S5P6818)
case 15:
rate = core_hz.disp_bclk; break;
case 16:
rate = core_hz.disp_pclk; break;
case 17:
rate = core_hz.hdmi_pclk; break;
case 18:
rate = core_hz.cci4_bclk; break;
case 19:
rate = core_hz.cci4_pclk; break;
#endif
default:
printf("unknown core clock type %d ...\n", type);
break;
};
return rate;
}
static long core_set_rate(struct clk *clk, long rate)
{
return clk->rate;
}
static void core_rate_init(void)
{
int i;
for (i = 0; i < CORE_HZ_SIZE; i++)
core_update_rate(i);
}
/*
* Clock Interfaces
*/
static inline long clk_divide(long rate, long request,
int align, int *divide)
{
int div = (rate / request);
int max = MAX_DIVIDER & ~(align - 1);
int adv = (div & ~(align - 1)) + align;
long ret;
if (!div) {
if (divide)
*divide = 1;
return rate;
}
if (div != 1)
div &= ~(align - 1);
if (div != adv && abs(request - rate / div) > abs(request - rate / adv))
div = adv;
div = (div > max ? max : div);
if (divide)
*divide = div;
ret = rate / div;
return ret;
}
void clk_put(struct clk *clk)
{
}
struct clk *clk_get(const char *id)
{
struct clk_dev *cdev = clk_dev_get(0);
struct clk *clk = NULL;
const char *str = NULL, *c = NULL;
int i, devid;
if (id)
str = id;
for (i = 0; i < CLK_DEVS_NUM; i++, cdev++) {
if (!cdev->name)
continue;
if (!strncmp(cdev->name, str, strlen(cdev->name))) {
c = strrchr((const char *)str, (int)'.');
if (!c || !cdev->peri)
break;
devid = simple_strtoul(++c, NULL, 10);
if (cdev->peri->dev_id == devid)
break;
}
}
if (i < CLK_DEVS_NUM)
clk = &cdev->clk;
else
clk = &(clk_dev_get(7))->clk; /* pclk */
return clk ? clk : ERR_PTR(-ENOENT);
}
long clk_round_rate(struct clk *clk, unsigned long rate)
{
struct clk_dev *pll = NULL, *cdev = clk_container(clk);
struct clk_dev_peri *peri = cdev->peri;
unsigned long request = rate, rate_hz = 0;
unsigned int mask;
int step, div[2] = { 0, };
int i, n, clk2 = 0;
int start_src = 0, max_src = I_CLOCK_NUM;
short s1 = 0, s2 = 0, d1 = 0, d2 = 0;
if (!peri)
return core_set_rate(clk, rate);
step = peri->clk_step;
mask = peri->in_mask;
debug("clk: %s.%d request = %ld [input=0x%x]\n", peri->dev_name,
peri->dev_id, rate, mask);
if (!(I_CLOCK_MASK & mask)) {
if (I_PCLK_MASK & mask)
return core_get_rate(CORECLK_ID_PCLK);
else if (I_BCLK_MASK & mask)
return core_get_rate(CORECLK_ID_BCLK);
else
return clk->rate;
}
next:
if (peri->in_mask & I_EXTCLK1_FORCE) {
start_src = 4; max_src = 5;
}
for (n = start_src ; max_src > n; n++) {
if (!(((mask & I_CLOCK_MASK) >> n) & 0x1))
continue;
if (n == I_EXT1_BIT) {
rate = peri->in_extclk_1;
} else if (n == I_EXT2_BIT) {
rate = peri->in_extclk_2;
} else {
pll = clk_dev_get(n);
rate = pll->clk.rate;
}
if (!rate)
continue;
for (i = 0; step > i ; i++)
rate = clk_divide(rate, request, 2, &div[i]);
if (rate_hz && (abs(rate - request) > abs(rate_hz - request)))
continue;
debug("clk: %s.%d, pll.%d[%lu] request[%ld] calc[%ld]\n",
peri->dev_name, peri->dev_id, n, pll->clk.rate,
request, rate);
if (clk2) {
s1 = -1, d1 = -1; /* not use */
s2 = n, d2 = div[0];
} else {
s1 = n, d1 = div[0];
s2 = I_CLKn_BIT, d2 = div[1];
}
rate_hz = rate;
}
/* search 2th clock from input */
if (!clk2 && abs(rate_hz - request) &&
peri->in_mask1 & ((1 << I_CLOCK_NUM) - 1)) {
clk2 = 1;
mask = peri->in_mask1;
step = 1;
goto next;
}
if (peri->in_mask & I_EXTCLK1_FORCE) {
if (s1 == 0) {
s1 = 4; s2 = 7;
d1 = 1; d2 = 1;
}
}
peri->div_src_0 = s1, peri->div_val_0 = d1;
peri->div_src_1 = s2, peri->div_val_1 = d2;
clk->rate = rate_hz;
debug("clk: %s.%d, step[%d] src[%d,%d] %ld", peri->dev_name,
peri->dev_id, peri->clk_step, peri->div_src_0, peri->div_src_1,
rate);
debug("/(div0: %d * div1: %d) = %ld, %ld diff (%ld)\n",
peri->div_val_0, peri->div_val_1, rate_hz, request,
abs(rate_hz - request));
return clk->rate;
}
unsigned long clk_get_rate(struct clk *clk)
{
struct clk_dev *cdev = clk_container(clk);
if (cdev->link)
clk = cdev->link;
return clk->rate;
}
int clk_set_rate(struct clk *clk, unsigned long rate)
{
struct clk_dev *cdev = clk_container(clk);
struct clk_dev_peri *peri = cdev->peri;
int i;
if (!peri)
return core_set_rate(clk, rate);
clk_round_rate(clk, rate);
for (i = 0; peri->clk_step > i ; i++) {
int s = (i == 0 ? peri->div_src_0 : peri->div_src_1);
int d = (i == 0 ? peri->div_val_0 : peri->div_val_1);
if (-1 == s)
continue;
clk_dev_rate(peri->base, i, s, d);
debug("clk: %s.%d (%p) set_rate [%d] src[%d] div[%d]\n",
peri->dev_name, peri->dev_id, peri->base, i, s, d);
}
return clk->rate;
}
int clk_enable(struct clk *clk)
{
struct clk_dev *cdev = clk_container(clk);
struct clk_dev_peri *peri = cdev->peri;
int i = 0, inv = 0;
if (!peri)
return 0;
debug("clk: %s.%d enable (BCLK=%s, PCLK=%s)\n", peri->dev_name,
peri->dev_id, I_GATE_BCLK & peri->in_mask ? "ON" : "PASS",
I_GATE_PCLK & peri->in_mask ? "ON" : "PASS");
if (!(I_CLOCK_MASK & peri->in_mask)) {
/* Gated BCLK/PCLK enable */
if (I_GATE_BCLK & peri->in_mask)
clk_dev_bclk(peri->base, 1);
if (I_GATE_PCLK & peri->in_mask)
clk_dev_pclk(peri->base, 1);
return 0;
}
/* invert */
inv = peri->invert_0;
for (; peri->clk_step > i; i++, inv = peri->invert_1)
clk_dev_inv(peri->base, i, inv);
/* Gated BCLK/PCLK enable */
if (I_GATE_BCLK & peri->in_mask)
clk_dev_bclk(peri->base, 1);
if (I_GATE_PCLK & peri->in_mask)
clk_dev_pclk(peri->base, 1);
/* restore clock rate */
for (i = 0; peri->clk_step > i ; i++) {
int s = (i == 0 ? peri->div_src_0 : peri->div_src_1);
int d = (i == 0 ? peri->div_val_0 : peri->div_val_1);
if (s == -1)
continue;
clk_dev_rate(peri->base, i, s, d);
}
clk_dev_enb(peri->base, 1);
return 0;
}
void clk_disable(struct clk *clk)
{
struct clk_dev *cdev = clk_container(clk);
struct clk_dev_peri *peri = cdev->peri;
if (!peri)
return;
debug("clk: %s.%d disable\n", peri->dev_name, peri->dev_id);
if (!(I_CLOCK_MASK & peri->in_mask)) {
/* Gated BCLK/PCLK disable */
if (I_GATE_BCLK & peri->in_mask)
clk_dev_bclk(peri->base, 0);
if (I_GATE_PCLK & peri->in_mask)
clk_dev_pclk(peri->base, 0);
return;
}
clk_dev_rate(peri->base, 0, 7, 256); /* for power save */
clk_dev_enb(peri->base, 0);
/* Gated BCLK/PCLK disable */
if (I_GATE_BCLK & peri->in_mask)
clk_dev_bclk(peri->base, 0);
if (I_GATE_PCLK & peri->in_mask)
clk_dev_pclk(peri->base, 0);
}
/*
* Core clocks APIs
*/
void __init clk_init(void)
{
struct clk_dev *cdev = st_clk_devs;
struct clk_dev_peri *peri = clk_periphs;
struct clk *clk = NULL;
int i = 0;
memset(cdev, 0, sizeof(st_clk_devs));
core_rate_init();
for (i = 0; (CLK_CORE_NUM + CLK_PERI_NUM) > i; i++, cdev++) {
if (i < CLK_CORE_NUM) {
cdev->name = clk_core[i];
clk = &cdev->clk;
clk->rate = core_get_rate(i);
continue;
}
peri = &clk_periphs[i - CLK_CORE_NUM];
peri->base = (void *)peri->base;
cdev->peri = peri;
cdev->name = peri->dev_name;
if (!(I_CLOCK_MASK & peri->in_mask)) {
if (I_BCLK_MASK & peri->in_mask)
cdev->clk.rate = core_get_rate(CORECLK_ID_BCLK);
if (I_PCLK_MASK & peri->in_mask)
cdev->clk.rate = core_get_rate(CORECLK_ID_PCLK);
}
/* prevent uart clock disable for low step debug message */
#ifndef CONFIG_DEBUG_NX_UART
if (peri->dev_name) {
#ifdef CONFIG_BACKLIGHT_PWM
if (!strcmp(peri->dev_name, DEV_NAME_PWM))
continue;
#endif
}
#endif
}
debug("CPU : Clock Generator= %d EA, ", CLK_DEVS_NUM);
}