android_kernel_xiaomi_sm8350/arch/arm/mach-ux500/clock.c
Russell King 3126c7bc41 ARM: AMBA: Add pclk definition for platforms using primecells
Add a dummy clk definition for the APB pclk signal on all platforms
using the AMBA bus infrastructure.  This ensures that these platforms
continue to work when the core amba bus code controls the APB pclk.

Signed-off-by: Russell King <rmk+kernel@arm.linux.org.uk>
2010-07-22 09:55:38 +01:00

622 lines
17 KiB
C

/*
* Copyright (C) 2009 ST-Ericsson
* Copyright (C) 2009 STMicroelectronics
*
* This program is free software; you can redistribute it and/or modify
* it under the terms of the GNU General Public License version 2 as
* published by the Free Software Foundation.
*/
#include <linux/module.h>
#include <linux/kernel.h>
#include <linux/list.h>
#include <linux/errno.h>
#include <linux/err.h>
#include <linux/clk.h>
#include <linux/io.h>
#include <asm/clkdev.h>
#include <plat/mtu.h>
#include <mach/hardware.h>
#include "clock.h"
#define PRCC_PCKEN 0x00
#define PRCC_PCKDIS 0x04
#define PRCC_KCKEN 0x08
#define PRCC_KCKDIS 0x0C
#define PRCM_YYCLKEN0_MGT_SET 0x510
#define PRCM_YYCLKEN1_MGT_SET 0x514
#define PRCM_YYCLKEN0_MGT_CLR 0x518
#define PRCM_YYCLKEN1_MGT_CLR 0x51C
#define PRCM_YYCLKEN0_MGT_VAL 0x520
#define PRCM_YYCLKEN1_MGT_VAL 0x524
#define PRCM_SVAMMDSPCLK_MGT 0x008
#define PRCM_SIAMMDSPCLK_MGT 0x00C
#define PRCM_SGACLK_MGT 0x014
#define PRCM_UARTCLK_MGT 0x018
#define PRCM_MSP02CLK_MGT 0x01C
#define PRCM_MSP1CLK_MGT 0x288
#define PRCM_I2CCLK_MGT 0x020
#define PRCM_SDMMCCLK_MGT 0x024
#define PRCM_SLIMCLK_MGT 0x028
#define PRCM_PER1CLK_MGT 0x02C
#define PRCM_PER2CLK_MGT 0x030
#define PRCM_PER3CLK_MGT 0x034
#define PRCM_PER5CLK_MGT 0x038
#define PRCM_PER6CLK_MGT 0x03C
#define PRCM_PER7CLK_MGT 0x040
#define PRCM_LCDCLK_MGT 0x044
#define PRCM_BMLCLK_MGT 0x04C
#define PRCM_HSITXCLK_MGT 0x050
#define PRCM_HSIRXCLK_MGT 0x054
#define PRCM_HDMICLK_MGT 0x058
#define PRCM_APEATCLK_MGT 0x05C
#define PRCM_APETRACECLK_MGT 0x060
#define PRCM_MCDECLK_MGT 0x064
#define PRCM_IPI2CCLK_MGT 0x068
#define PRCM_DSIALTCLK_MGT 0x06C
#define PRCM_DMACLK_MGT 0x074
#define PRCM_B2R2CLK_MGT 0x078
#define PRCM_TVCLK_MGT 0x07C
#define PRCM_TCR 0x1C8
#define PRCM_TCR_STOPPED (1 << 16)
#define PRCM_TCR_DOZE_MODE (1 << 17)
#define PRCM_UNIPROCLK_MGT 0x278
#define PRCM_SSPCLK_MGT 0x280
#define PRCM_RNGCLK_MGT 0x284
#define PRCM_UICCCLK_MGT 0x27C
#define PRCM_MGT_ENABLE (1 << 8)
static DEFINE_SPINLOCK(clocks_lock);
static void __clk_enable(struct clk *clk)
{
if (clk->enabled++ == 0) {
if (clk->parent_cluster)
__clk_enable(clk->parent_cluster);
if (clk->parent_periph)
__clk_enable(clk->parent_periph);
if (clk->ops && clk->ops->enable)
clk->ops->enable(clk);
}
}
int clk_enable(struct clk *clk)
{
unsigned long flags;
spin_lock_irqsave(&clocks_lock, flags);
__clk_enable(clk);
spin_unlock_irqrestore(&clocks_lock, flags);
return 0;
}
EXPORT_SYMBOL(clk_enable);
static void __clk_disable(struct clk *clk)
{
if (--clk->enabled == 0) {
if (clk->ops && clk->ops->disable)
clk->ops->disable(clk);
if (clk->parent_periph)
__clk_disable(clk->parent_periph);
if (clk->parent_cluster)
__clk_disable(clk->parent_cluster);
}
}
void clk_disable(struct clk *clk)
{
unsigned long flags;
WARN_ON(!clk->enabled);
spin_lock_irqsave(&clocks_lock, flags);
__clk_disable(clk);
spin_unlock_irqrestore(&clocks_lock, flags);
}
EXPORT_SYMBOL(clk_disable);
/*
* The MTU has a separate, rather complex muxing setup
* with alternative parents (peripheral cluster or
* ULP or fixed 32768 Hz) depending on settings
*/
static unsigned long clk_mtu_get_rate(struct clk *clk)
{
void __iomem *addr = __io_address(UX500_PRCMU_BASE)
+ PRCM_TCR;
u32 tcr = readl(addr);
int mtu = (int) clk->data;
/*
* One of these is selected eventually
* TODO: Replace the constant with a reference
* to the ULP source once this is modeled.
*/
unsigned long clk32k = 32768;
unsigned long mturate;
unsigned long retclk;
/* Get the rate from the parent as a default */
if (clk->parent_periph)
mturate = clk_get_rate(clk->parent_periph);
else if (clk->parent_cluster)
mturate = clk_get_rate(clk->parent_cluster);
else
/* We need to be connected SOMEWHERE */
BUG();
/*
* Are we in doze mode?
* In this mode the parent peripheral or the fixed 32768 Hz
* clock is fed into the block.
*/
if (!(tcr & PRCM_TCR_DOZE_MODE)) {
/*
* Here we're using the clock input from the APE ULP
* clock domain. But first: are the timers stopped?
*/
if (tcr & PRCM_TCR_STOPPED) {
clk32k = 0;
mturate = 0;
} else {
/* Else default mode: 0 and 2.4 MHz */
clk32k = 0;
if (cpu_is_u5500())
/* DB5500 divides by 8 */
mturate /= 8;
else if (cpu_is_u8500ed()) {
/*
* This clocking setting must not be used
* in the ED chip, it is simply not
* connected anywhere!
*/
mturate = 0;
BUG();
} else
/*
* In this mode the ulp38m4 clock is divided
* by a factor 16, on the DB8500 typically
* 38400000 / 16 ~ 2.4 MHz.
* TODO: Replace the constant with a reference
* to the ULP source once this is modeled.
*/
mturate = 38400000 / 16;
}
}
/* Return the clock selected for this MTU */
if (tcr & (1 << mtu))
retclk = clk32k;
else
retclk = mturate;
pr_info("MTU%d clock rate: %lu Hz\n", mtu, retclk);
return retclk;
}
unsigned long clk_get_rate(struct clk *clk)
{
unsigned long rate;
/*
* If there is a custom getrate callback for this clock,
* it will take precedence.
*/
if (clk->get_rate)
return clk->get_rate(clk);
if (clk->ops && clk->ops->get_rate)
return clk->ops->get_rate(clk);
rate = clk->rate;
if (!rate) {
if (clk->parent_periph)
rate = clk_get_rate(clk->parent_periph);
else if (clk->parent_cluster)
rate = clk_get_rate(clk->parent_cluster);
}
return rate;
}
EXPORT_SYMBOL(clk_get_rate);
long clk_round_rate(struct clk *clk, unsigned long rate)
{
/*TODO*/
return rate;
}
EXPORT_SYMBOL(clk_round_rate);
int clk_set_rate(struct clk *clk, unsigned long rate)
{
clk->rate = rate;
return 0;
}
EXPORT_SYMBOL(clk_set_rate);
static void clk_prcmu_enable(struct clk *clk)
{
void __iomem *cg_set_reg = __io_address(U8500_PRCMU_BASE)
+ PRCM_YYCLKEN0_MGT_SET + clk->prcmu_cg_off;
writel(1 << clk->prcmu_cg_bit, cg_set_reg);
}
static void clk_prcmu_disable(struct clk *clk)
{
void __iomem *cg_clr_reg = __io_address(U8500_PRCMU_BASE)
+ PRCM_YYCLKEN0_MGT_CLR + clk->prcmu_cg_off;
writel(1 << clk->prcmu_cg_bit, cg_clr_reg);
}
/* ED doesn't have the combined set/clr registers */
static void clk_prcmu_ed_enable(struct clk *clk)
{
void __iomem *addr = __io_address(U8500_PRCMU_BASE)
+ clk->prcmu_cg_mgt;
writel(readl(addr) | PRCM_MGT_ENABLE, addr);
}
static void clk_prcmu_ed_disable(struct clk *clk)
{
void __iomem *addr = __io_address(U8500_PRCMU_BASE)
+ clk->prcmu_cg_mgt;
writel(readl(addr) & ~PRCM_MGT_ENABLE, addr);
}
static struct clkops clk_prcmu_ops = {
.enable = clk_prcmu_enable,
.disable = clk_prcmu_disable,
};
static unsigned int clkrst_base[] = {
[1] = U8500_CLKRST1_BASE,
[2] = U8500_CLKRST2_BASE,
[3] = U8500_CLKRST3_BASE,
[5] = U8500_CLKRST5_BASE,
[6] = U8500_CLKRST6_BASE,
[7] = U8500_CLKRST7_BASE_ED,
};
static void clk_prcc_enable(struct clk *clk)
{
void __iomem *addr = __io_address(clkrst_base[clk->cluster]);
if (clk->prcc_kernel != -1)
writel(1 << clk->prcc_kernel, addr + PRCC_KCKEN);
if (clk->prcc_bus != -1)
writel(1 << clk->prcc_bus, addr + PRCC_PCKEN);
}
static void clk_prcc_disable(struct clk *clk)
{
void __iomem *addr = __io_address(clkrst_base[clk->cluster]);
if (clk->prcc_bus != -1)
writel(1 << clk->prcc_bus, addr + PRCC_PCKDIS);
if (clk->prcc_kernel != -1)
writel(1 << clk->prcc_kernel, addr + PRCC_KCKDIS);
}
static struct clkops clk_prcc_ops = {
.enable = clk_prcc_enable,
.disable = clk_prcc_disable,
};
static struct clk clk_32khz = {
.rate = 32000,
};
/*
* PRCMU level clock gating
*/
/* Bank 0 */
static DEFINE_PRCMU_CLK(svaclk, 0x0, 2, SVAMMDSPCLK);
static DEFINE_PRCMU_CLK(siaclk, 0x0, 3, SIAMMDSPCLK);
static DEFINE_PRCMU_CLK(sgaclk, 0x0, 4, SGACLK);
static DEFINE_PRCMU_CLK_RATE(uartclk, 0x0, 5, UARTCLK, 38400000);
static DEFINE_PRCMU_CLK(msp02clk, 0x0, 6, MSP02CLK);
static DEFINE_PRCMU_CLK(msp1clk, 0x0, 7, MSP1CLK); /* v1 */
static DEFINE_PRCMU_CLK_RATE(i2cclk, 0x0, 8, I2CCLK, 48000000);
static DEFINE_PRCMU_CLK_RATE(sdmmcclk, 0x0, 9, SDMMCCLK, 50000000);
static DEFINE_PRCMU_CLK(slimclk, 0x0, 10, SLIMCLK);
static DEFINE_PRCMU_CLK(per1clk, 0x0, 11, PER1CLK);
static DEFINE_PRCMU_CLK(per2clk, 0x0, 12, PER2CLK);
static DEFINE_PRCMU_CLK(per3clk, 0x0, 13, PER3CLK);
static DEFINE_PRCMU_CLK(per5clk, 0x0, 14, PER5CLK);
static DEFINE_PRCMU_CLK_RATE(per6clk, 0x0, 15, PER6CLK, 133330000);
static DEFINE_PRCMU_CLK_RATE(per7clk, 0x0, 16, PER7CLK, 100000000);
static DEFINE_PRCMU_CLK(lcdclk, 0x0, 17, LCDCLK);
static DEFINE_PRCMU_CLK(bmlclk, 0x0, 18, BMLCLK);
static DEFINE_PRCMU_CLK(hsitxclk, 0x0, 19, HSITXCLK);
static DEFINE_PRCMU_CLK(hsirxclk, 0x0, 20, HSIRXCLK);
static DEFINE_PRCMU_CLK(hdmiclk, 0x0, 21, HDMICLK);
static DEFINE_PRCMU_CLK(apeatclk, 0x0, 22, APEATCLK);
static DEFINE_PRCMU_CLK(apetraceclk, 0x0, 23, APETRACECLK);
static DEFINE_PRCMU_CLK(mcdeclk, 0x0, 24, MCDECLK);
static DEFINE_PRCMU_CLK(ipi2clk, 0x0, 25, IPI2CCLK);
static DEFINE_PRCMU_CLK(dsialtclk, 0x0, 26, DSIALTCLK); /* v1 */
static DEFINE_PRCMU_CLK(dmaclk, 0x0, 27, DMACLK);
static DEFINE_PRCMU_CLK(b2r2clk, 0x0, 28, B2R2CLK);
static DEFINE_PRCMU_CLK(tvclk, 0x0, 29, TVCLK);
static DEFINE_PRCMU_CLK(uniproclk, 0x0, 30, UNIPROCLK); /* v1 */
static DEFINE_PRCMU_CLK_RATE(sspclk, 0x0, 31, SSPCLK, 48000000); /* v1 */
/* Bank 1 */
static DEFINE_PRCMU_CLK(rngclk, 0x4, 0, RNGCLK); /* v1 */
static DEFINE_PRCMU_CLK(uiccclk, 0x4, 1, UICCCLK); /* v1 */
/*
* PRCC level clock gating
* Format: per#, clk, PCKEN bit, KCKEN bit, parent
*/
/* Peripheral Cluster #1 */
static DEFINE_PRCC_CLK(1, i2c4, 10, 9, &clk_i2cclk);
static DEFINE_PRCC_CLK(1, gpio0, 9, -1, NULL);
static DEFINE_PRCC_CLK(1, slimbus0, 8, 8, &clk_slimclk);
static DEFINE_PRCC_CLK(1, spi3_ed, 7, 7, NULL);
static DEFINE_PRCC_CLK(1, spi3_v1, 7, -1, NULL);
static DEFINE_PRCC_CLK(1, i2c2, 6, 6, &clk_i2cclk);
static DEFINE_PRCC_CLK(1, sdi0, 5, 5, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(1, msp1_ed, 4, 4, &clk_msp02clk);
static DEFINE_PRCC_CLK(1, msp1_v1, 4, 4, &clk_msp1clk);
static DEFINE_PRCC_CLK(1, msp0, 3, 3, &clk_msp02clk);
static DEFINE_PRCC_CLK(1, i2c1, 2, 2, &clk_i2cclk);
static DEFINE_PRCC_CLK(1, uart1, 1, 1, &clk_uartclk);
static DEFINE_PRCC_CLK(1, uart0, 0, 0, &clk_uartclk);
/* Peripheral Cluster #2 */
static DEFINE_PRCC_CLK(2, gpio1_ed, 12, -1, NULL);
static DEFINE_PRCC_CLK(2, ssitx_ed, 11, -1, NULL);
static DEFINE_PRCC_CLK(2, ssirx_ed, 10, -1, NULL);
static DEFINE_PRCC_CLK(2, spi0_ed, 9, -1, NULL);
static DEFINE_PRCC_CLK(2, sdi3_ed, 8, 6, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(2, sdi1_ed, 7, 5, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(2, msp2_ed, 6, 4, &clk_msp02clk);
static DEFINE_PRCC_CLK(2, sdi4_ed, 4, 2, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(2, pwl_ed, 3, 1, NULL);
static DEFINE_PRCC_CLK(2, spi1_ed, 2, -1, NULL);
static DEFINE_PRCC_CLK(2, spi2_ed, 1, -1, NULL);
static DEFINE_PRCC_CLK(2, i2c3_ed, 0, 0, &clk_i2cclk);
static DEFINE_PRCC_CLK(2, gpio1_v1, 11, -1, NULL);
static DEFINE_PRCC_CLK(2, ssitx_v1, 10, 7, NULL);
static DEFINE_PRCC_CLK(2, ssirx_v1, 9, 6, NULL);
static DEFINE_PRCC_CLK(2, spi0_v1, 8, -1, NULL);
static DEFINE_PRCC_CLK(2, sdi3_v1, 7, 5, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(2, sdi1_v1, 6, 4, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(2, msp2_v1, 5, 3, &clk_msp02clk);
static DEFINE_PRCC_CLK(2, sdi4_v1, 4, 2, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(2, pwl_v1, 3, 1, NULL);
static DEFINE_PRCC_CLK(2, spi1_v1, 2, -1, NULL);
static DEFINE_PRCC_CLK(2, spi2_v1, 1, -1, NULL);
static DEFINE_PRCC_CLK(2, i2c3_v1, 0, 0, &clk_i2cclk);
/* Peripheral Cluster #3 */
static DEFINE_PRCC_CLK(3, gpio2, 8, -1, NULL);
static DEFINE_PRCC_CLK(3, sdi5, 7, 7, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(3, uart2, 6, 6, &clk_uartclk);
static DEFINE_PRCC_CLK(3, ske, 5, 5, &clk_32khz);
static DEFINE_PRCC_CLK(3, sdi2, 4, 4, &clk_sdmmcclk);
static DEFINE_PRCC_CLK(3, i2c0, 3, 3, &clk_i2cclk);
static DEFINE_PRCC_CLK(3, ssp1_ed, 2, 2, &clk_i2cclk);
static DEFINE_PRCC_CLK(3, ssp0_ed, 1, 1, &clk_i2cclk);
static DEFINE_PRCC_CLK(3, ssp1_v1, 2, 2, &clk_sspclk);
static DEFINE_PRCC_CLK(3, ssp0_v1, 1, 1, &clk_sspclk);
static DEFINE_PRCC_CLK(3, fsmc, 0, -1, NULL);
/* Peripheral Cluster #4 is in the always on domain */
/* Peripheral Cluster #5 */
static DEFINE_PRCC_CLK(5, gpio3, 1, -1, NULL);
static DEFINE_PRCC_CLK(5, usb_ed, 0, 0, &clk_i2cclk);
static DEFINE_PRCC_CLK(5, usb_v1, 0, 0, NULL);
/* Peripheral Cluster #6 */
/* MTU ID in data */
static DEFINE_PRCC_CLK_CUSTOM(6, mtu1_v1, 8, -1, NULL, clk_mtu_get_rate, 1);
static DEFINE_PRCC_CLK_CUSTOM(6, mtu0_v1, 7, -1, NULL, clk_mtu_get_rate, 0);
static DEFINE_PRCC_CLK(6, cfgreg_v1, 6, 6, NULL);
static DEFINE_PRCC_CLK(6, dmc_ed, 6, 6, NULL);
static DEFINE_PRCC_CLK(6, hash1, 5, -1, NULL);
static DEFINE_PRCC_CLK(6, unipro_v1, 4, 1, &clk_uniproclk);
static DEFINE_PRCC_CLK(6, cryp1_ed, 4, -1, NULL);
static DEFINE_PRCC_CLK(6, pka, 3, -1, NULL);
static DEFINE_PRCC_CLK(6, hash0, 2, -1, NULL);
static DEFINE_PRCC_CLK(6, cryp0, 1, -1, NULL);
static DEFINE_PRCC_CLK(6, rng_ed, 0, 0, &clk_i2cclk);
static DEFINE_PRCC_CLK(6, rng_v1, 0, 0, &clk_rngclk);
/* Peripheral Cluster #7 */
static DEFINE_PRCC_CLK(7, tzpc0_ed, 4, -1, NULL);
/* MTU ID in data */
static DEFINE_PRCC_CLK_CUSTOM(7, mtu1_ed, 3, -1, NULL, clk_mtu_get_rate, 1);
static DEFINE_PRCC_CLK_CUSTOM(7, mtu0_ed, 2, -1, NULL, clk_mtu_get_rate, 0);
static DEFINE_PRCC_CLK(7, wdg_ed, 1, -1, NULL);
static DEFINE_PRCC_CLK(7, cfgreg_ed, 0, -1, NULL);
static struct clk clk_dummy_apb_pclk;
static struct clk_lookup u8500_common_clks[] = {
CLK(dummy_apb_pclk, NULL, "apb_pclk"),
/* Peripheral Cluster #1 */
CLK(gpio0, "gpio.0", NULL),
CLK(gpio0, "gpio.1", NULL),
CLK(slimbus0, "slimbus0", NULL),
CLK(i2c2, "nmk-i2c.2", NULL),
CLK(sdi0, "sdi0", NULL),
CLK(msp0, "msp0", NULL),
CLK(i2c1, "nmk-i2c.1", NULL),
CLK(uart1, "uart1", NULL),
CLK(uart0, "uart0", NULL),
/* Peripheral Cluster #3 */
CLK(gpio2, "gpio.2", NULL),
CLK(gpio2, "gpio.3", NULL),
CLK(gpio2, "gpio.4", NULL),
CLK(gpio2, "gpio.5", NULL),
CLK(sdi5, "sdi5", NULL),
CLK(uart2, "uart2", NULL),
CLK(ske, "ske", NULL),
CLK(sdi2, "sdi2", NULL),
CLK(i2c0, "nmk-i2c.0", NULL),
CLK(fsmc, "fsmc", NULL),
/* Peripheral Cluster #5 */
CLK(gpio3, "gpio.8", NULL),
/* Peripheral Cluster #6 */
CLK(hash1, "hash1", NULL),
CLK(pka, "pka", NULL),
CLK(hash0, "hash0", NULL),
CLK(cryp0, "cryp0", NULL),
/* PRCMU level clock gating */
/* Bank 0 */
CLK(svaclk, "sva", NULL),
CLK(siaclk, "sia", NULL),
CLK(sgaclk, "sga", NULL),
CLK(slimclk, "slim", NULL),
CLK(lcdclk, "lcd", NULL),
CLK(bmlclk, "bml", NULL),
CLK(hsitxclk, "stm-hsi.0", NULL),
CLK(hsirxclk, "stm-hsi.1", NULL),
CLK(hdmiclk, "hdmi", NULL),
CLK(apeatclk, "apeat", NULL),
CLK(apetraceclk, "apetrace", NULL),
CLK(mcdeclk, "mcde", NULL),
CLK(ipi2clk, "ipi2", NULL),
CLK(dmaclk, "dma40.0", NULL),
CLK(b2r2clk, "b2r2", NULL),
CLK(tvclk, "tv", NULL),
};
static struct clk_lookup u8500_ed_clks[] = {
/* Peripheral Cluster #1 */
CLK(spi3_ed, "spi3", NULL),
CLK(msp1_ed, "msp1", NULL),
/* Peripheral Cluster #2 */
CLK(gpio1_ed, "gpio.6", NULL),
CLK(gpio1_ed, "gpio.7", NULL),
CLK(ssitx_ed, "ssitx", NULL),
CLK(ssirx_ed, "ssirx", NULL),
CLK(spi0_ed, "spi0", NULL),
CLK(sdi3_ed, "sdi3", NULL),
CLK(sdi1_ed, "sdi1", NULL),
CLK(msp2_ed, "msp2", NULL),
CLK(sdi4_ed, "sdi4", NULL),
CLK(pwl_ed, "pwl", NULL),
CLK(spi1_ed, "spi1", NULL),
CLK(spi2_ed, "spi2", NULL),
CLK(i2c3_ed, "nmk-i2c.3", NULL),
/* Peripheral Cluster #3 */
CLK(ssp1_ed, "ssp1", NULL),
CLK(ssp0_ed, "ssp0", NULL),
/* Peripheral Cluster #5 */
CLK(usb_ed, "musb_hdrc.0", "usb"),
/* Peripheral Cluster #6 */
CLK(dmc_ed, "dmc", NULL),
CLK(cryp1_ed, "cryp1", NULL),
CLK(rng_ed, "rng", NULL),
/* Peripheral Cluster #7 */
CLK(tzpc0_ed, "tzpc0", NULL),
CLK(mtu1_ed, "mtu1", NULL),
CLK(mtu0_ed, "mtu0", NULL),
CLK(wdg_ed, "wdg", NULL),
CLK(cfgreg_ed, "cfgreg", NULL),
};
static struct clk_lookup u8500_v1_clks[] = {
/* Peripheral Cluster #1 */
CLK(i2c4, "nmk-i2c.4", NULL),
CLK(spi3_v1, "spi3", NULL),
CLK(msp1_v1, "msp1", NULL),
/* Peripheral Cluster #2 */
CLK(gpio1_v1, "gpio.6", NULL),
CLK(gpio1_v1, "gpio.7", NULL),
CLK(ssitx_v1, "ssitx", NULL),
CLK(ssirx_v1, "ssirx", NULL),
CLK(spi0_v1, "spi0", NULL),
CLK(sdi3_v1, "sdi3", NULL),
CLK(sdi1_v1, "sdi1", NULL),
CLK(msp2_v1, "msp2", NULL),
CLK(sdi4_v1, "sdi4", NULL),
CLK(pwl_v1, "pwl", NULL),
CLK(spi1_v1, "spi1", NULL),
CLK(spi2_v1, "spi2", NULL),
CLK(i2c3_v1, "nmk-i2c.3", NULL),
/* Peripheral Cluster #3 */
CLK(ssp1_v1, "ssp1", NULL),
CLK(ssp0_v1, "ssp0", NULL),
/* Peripheral Cluster #5 */
CLK(usb_v1, "musb_hdrc.0", "usb"),
/* Peripheral Cluster #6 */
CLK(mtu1_v1, "mtu1", NULL),
CLK(mtu0_v1, "mtu0", NULL),
CLK(cfgreg_v1, "cfgreg", NULL),
CLK(hash1, "hash1", NULL),
CLK(unipro_v1, "unipro", NULL),
CLK(rng_v1, "rng", NULL),
/* PRCMU level clock gating */
/* Bank 0 */
CLK(uniproclk, "uniproclk", NULL),
CLK(dsialtclk, "dsialt", NULL),
/* Bank 1 */
CLK(rngclk, "rng", NULL),
CLK(uiccclk, "uicc", NULL),
};
int __init clk_init(void)
{
if (cpu_is_u8500ed()) {
clk_prcmu_ops.enable = clk_prcmu_ed_enable;
clk_prcmu_ops.disable = clk_prcmu_ed_disable;
clk_per6clk.rate = 100000000;
} else if (cpu_is_u5500()) {
/* Clock tree for U5500 not implemented yet */
clk_prcc_ops.enable = clk_prcc_ops.disable = NULL;
clk_prcmu_ops.enable = clk_prcmu_ops.disable = NULL;
clk_per6clk.rate = 26000000;
}
clkdev_add_table(u8500_common_clks, ARRAY_SIZE(u8500_common_clks));
if (cpu_is_u8500ed())
clkdev_add_table(u8500_ed_clks, ARRAY_SIZE(u8500_ed_clks));
else
clkdev_add_table(u8500_v1_clks, ARRAY_SIZE(u8500_v1_clks));
return 0;
}