u-boot/board/samsung/smdk5250/clock_init.c - nest-learning-thermostat/5.0.1/u-boot - Git at Google

 /*
  * Clock setup for SMDK5250 board based on EXYNOS5
  *
  * Copyright (C) 2012 Samsung Electronics
  *
  * 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 <config.h>
 #include <asm/io.h>
 #include <asm/arch/clk.h>
 #include <asm/arch/clock.h>
 #include <asm/arch/spl.h>

 #include "clock_init.h"
 #include "setup.h"

 DECLARE_GLOBAL_DATA_PTR;

 struct arm_clk_ratios arm_clk_ratios[] = {
 	{
 		.arm_freq_mhz = 600,

 		.apll_mdiv = 0xc8,
 		.apll_pdiv = 0x4,
 		.apll_sdiv = 0x1,

 		.arm2_ratio = 0x0,
 		.apll_ratio = 0x1,
 		.pclk_dbg_ratio = 0x1,
 		.atb_ratio = 0x2,
 		.periph_ratio = 0x7,
 		.acp_ratio = 0x7,
 		.cpud_ratio = 0x1,
 		.arm_ratio = 0x0,
 	}, {
 		.arm_freq_mhz = 800,

 		.apll_mdiv = 0x64,
 		.apll_pdiv = 0x3,
 		.apll_sdiv = 0x0,

 		.arm2_ratio = 0x0,
 		.apll_ratio = 0x1,
 		.pclk_dbg_ratio = 0x1,
 		.atb_ratio = 0x3,
 		.periph_ratio = 0x7,
 		.acp_ratio = 0x7,
 		.cpud_ratio = 0x2,
 		.arm_ratio = 0x0,
 	}, {
 		.arm_freq_mhz = 1000,

 		.apll_mdiv = 0x7d,
 		.apll_pdiv = 0x3,
 		.apll_sdiv = 0x0,

 		.arm2_ratio = 0x0,
 		.apll_ratio = 0x1,
 		.pclk_dbg_ratio = 0x1,
 		.atb_ratio = 0x4,
 		.periph_ratio = 0x7,
 		.acp_ratio = 0x7,
 		.cpud_ratio = 0x2,
 		.arm_ratio = 0x0,
 	}, {
 		.arm_freq_mhz = 1200,

 		.apll_mdiv = 0x96,
 		.apll_pdiv = 0x3,
 		.apll_sdiv = 0x0,

 		.arm2_ratio = 0x0,
 		.apll_ratio = 0x3,
 		.pclk_dbg_ratio = 0x1,
 		.atb_ratio = 0x5,
 		.periph_ratio = 0x7,
 		.acp_ratio = 0x7,
 		.cpud_ratio = 0x3,
 		.arm_ratio = 0x0,
 	}, {
 		.arm_freq_mhz = 1400,

 		.apll_mdiv = 0xaf,
 		.apll_pdiv = 0x3,
 		.apll_sdiv = 0x0,

 		.arm2_ratio = 0x0,
 		.apll_ratio = 0x3,
 		.pclk_dbg_ratio = 0x1,
 		.atb_ratio = 0x6,
 		.periph_ratio = 0x7,
 		.acp_ratio = 0x7,
 		.cpud_ratio = 0x3,
 		.arm_ratio = 0x0,
 	}, {
 		.arm_freq_mhz = 1700,

 		.apll_mdiv = 0x1a9,
 		.apll_pdiv = 0x6,
 		.apll_sdiv = 0x0,

 		.arm2_ratio = 0x0,
 		.apll_ratio = 0x3,
 		.pclk_dbg_ratio = 0x1,
 		.atb_ratio = 0x6,
 		.periph_ratio = 0x7,
 		.acp_ratio = 0x7,
 		.cpud_ratio = 0x3,
 		.arm_ratio = 0x0,
 	}
 };
 struct mem_timings mem_timings[] = {
 	{
 		.mem_manuf = MEM_MANUF_ELPIDA,
 		.mem_type = DDR_MODE_DDR3,
 		.frequency_mhz = 800,
 		.mpll_mdiv = 0xc8,
 		.mpll_pdiv = 0x3,
 		.mpll_sdiv = 0x0,
 		.cpll_mdiv = 0xde,
 		.cpll_pdiv = 0x4,
 		.cpll_sdiv = 0x2,
 		.gpll_mdiv = 0x215,
 		.gpll_pdiv = 0xc,
 		.gpll_sdiv = 0x1,
 		.epll_mdiv = 0x60,
 		.epll_pdiv = 0x3,
 		.epll_sdiv = 0x3,
 		.vpll_mdiv = 0x96,
 		.vpll_pdiv = 0x3,
 		.vpll_sdiv = 0x2,

 		.bpll_mdiv = 0x64,
 		.bpll_pdiv = 0x3,
 		.bpll_sdiv = 0x0,
 		.pclk_cdrex_ratio = 0x5,
 		.direct_cmd_msr = {
 			0x00020018, 0x00030000, 0x00010042, 0x00000d70
 		},
 		.timing_ref = 0x000000bb,
 		.timing_row = 0x8c36650e,
 		.timing_data = 0x3630580b,
 		.timing_power = 0x41000a44,
 		.phy0_dqs = 0x08080808,
 		.phy1_dqs = 0x08080808,
 		.phy0_dq = 0x08080808,
 		.phy1_dq = 0x08080808,
 		.phy0_tFS = 0x4,
 		.phy1_tFS = 0x4,
 		.phy0_pulld_dqs = 0xf,
 		.phy1_pulld_dqs = 0xf,

 		.lpddr3_ctrl_phy_reset = 0x1,
 		.ctrl_start_point = 0x10,
 		.ctrl_inc = 0x10,
 		.ctrl_start = 0x1,
 		.ctrl_dll_on = 0x1,
 		.ctrl_ref = 0x8,

 		.ctrl_force = 0x1a,
 		.ctrl_rdlat = 0x0b,
 		.ctrl_bstlen = 0x08,

 		.fp_resync = 0x8,
 		.iv_size = 0x7,
 		.dfi_init_start = 1,
 		.aref_en = 1,

 		.rd_fetch = 0x3,

 		.zq_mode_dds = 0x7,
 		.zq_mode_term = 0x1,
 		.zq_mode_noterm = 0,

 		/*
 		* Dynamic Clock: Always Running
 		* Memory Burst length: 8
 		* Number of chips: 1
 		* Memory Bus width: 32 bit
 		* Memory Type: DDR3
 		* Additional Latancy for PLL: 0 Cycle
 		*/
 		.memcontrol = DMC_MEMCONTROL_CLK_STOP_DISABLE |
 			DMC_MEMCONTROL_DPWRDN_DISABLE |
 			DMC_MEMCONTROL_DPWRDN_ACTIVE_PRECHARGE |
 			DMC_MEMCONTROL_TP_DISABLE |
 			DMC_MEMCONTROL_DSREF_ENABLE |
 			DMC_MEMCONTROL_ADD_LAT_PALL_CYCLE(0) |
 			DMC_MEMCONTROL_MEM_TYPE_DDR3 |
 			DMC_MEMCONTROL_MEM_WIDTH_32BIT |
 			DMC_MEMCONTROL_NUM_CHIP_1 |
 			DMC_MEMCONTROL_BL_8 |
 			DMC_MEMCONTROL_PZQ_DISABLE |
 			DMC_MEMCONTROL_MRR_BYTE_7_0,
 		.memconfig = DMC_MEMCONFIGx_CHIP_MAP_INTERLEAVED |
 			DMC_MEMCONFIGx_CHIP_COL_10 |
 			DMC_MEMCONFIGx_CHIP_ROW_15 |
 			DMC_MEMCONFIGx_CHIP_BANK_8,
 		.membaseconfig0 = DMC_MEMBASECONFIG_VAL(0x40),
 		.membaseconfig1 = DMC_MEMBASECONFIG_VAL(0x80),
 		.prechconfig_tp_cnt = 0xff,
 		.dpwrdn_cyc = 0xff,
 		.dsref_cyc = 0xffff,
 		.concontrol = DMC_CONCONTROL_DFI_INIT_START_DISABLE |
 			DMC_CONCONTROL_TIMEOUT_LEVEL0 |
 			DMC_CONCONTROL_RD_FETCH_DISABLE |
 			DMC_CONCONTROL_EMPTY_DISABLE |
 			DMC_CONCONTROL_AREF_EN_DISABLE |
 			DMC_CONCONTROL_IO_PD_CON_DISABLE,
 		.dmc_channels = 2,
 		.chips_per_channel = 2,
 		.chips_to_configure = 1,
 		.send_zq_init = 1,
 		.impedance = IMP_OUTPUT_DRV_30_OHM,
 		.gate_leveling_enable = 0,
 	}, {
 		.mem_manuf = MEM_MANUF_SAMSUNG,
 		.mem_type = DDR_MODE_DDR3,
 		.frequency_mhz = 800,
 		.mpll_mdiv = 0xc8,
 		.mpll_pdiv = 0x3,
 		.mpll_sdiv = 0x0,
 		.cpll_mdiv = 0xde,
 		.cpll_pdiv = 0x4,
 		.cpll_sdiv = 0x2,
 		.gpll_mdiv = 0x215,
 		.gpll_pdiv = 0xc,
 		.gpll_sdiv = 0x1,
 		.epll_mdiv = 0x60,
 		.epll_pdiv = 0x3,
 		.epll_sdiv = 0x3,
 		.vpll_mdiv = 0x96,
 		.vpll_pdiv = 0x3,
 		.vpll_sdiv = 0x2,

 		.bpll_mdiv = 0x64,
 		.bpll_pdiv = 0x3,
 		.bpll_sdiv = 0x0,
 		.pclk_cdrex_ratio = 0x5,
 		.direct_cmd_msr = {
 			0x00020018, 0x00030000, 0x00010000, 0x00000d70
 		},
 		.timing_ref = 0x000000bb,
 		.timing_row = 0x8c36650e,
 		.timing_data = 0x3630580b,
 		.timing_power = 0x41000a44,
 		.phy0_dqs = 0x08080808,
 		.phy1_dqs = 0x08080808,
 		.phy0_dq = 0x08080808,
 		.phy1_dq = 0x08080808,
 		.phy0_tFS = 0x8,
 		.phy1_tFS = 0x8,
 		.phy0_pulld_dqs = 0xf,
 		.phy1_pulld_dqs = 0xf,

 		.lpddr3_ctrl_phy_reset = 0x1,
 		.ctrl_start_point = 0x10,
 		.ctrl_inc = 0x10,
 		.ctrl_start = 0x1,
 		.ctrl_dll_on = 0x1,
 		.ctrl_ref = 0x8,

 		.ctrl_force = 0x1a,
 		.ctrl_rdlat = 0x0b,
 		.ctrl_bstlen = 0x08,

 		.fp_resync = 0x8,
 		.iv_size = 0x7,
 		.dfi_init_start = 1,
 		.aref_en = 1,

 		.rd_fetch = 0x3,

 		.zq_mode_dds = 0x5,
 		.zq_mode_term = 0x1,
 		.zq_mode_noterm = 1,

 		/*
 		* Dynamic Clock: Always Running
 		* Memory Burst length: 8
 		* Number of chips: 1
 		* Memory Bus width: 32 bit
 		* Memory Type: DDR3
 		* Additional Latancy for PLL: 0 Cycle
 		*/
 		.memcontrol = DMC_MEMCONTROL_CLK_STOP_DISABLE |
 			DMC_MEMCONTROL_DPWRDN_DISABLE |
 			DMC_MEMCONTROL_DPWRDN_ACTIVE_PRECHARGE |
 			DMC_MEMCONTROL_TP_DISABLE |
 			DMC_MEMCONTROL_DSREF_ENABLE |
 			DMC_MEMCONTROL_ADD_LAT_PALL_CYCLE(0) |
 			DMC_MEMCONTROL_MEM_TYPE_DDR3 |
 			DMC_MEMCONTROL_MEM_WIDTH_32BIT |
 			DMC_MEMCONTROL_NUM_CHIP_1 |
 			DMC_MEMCONTROL_BL_8 |
 			DMC_MEMCONTROL_PZQ_DISABLE |
 			DMC_MEMCONTROL_MRR_BYTE_7_0,
 		.memconfig = DMC_MEMCONFIGx_CHIP_MAP_INTERLEAVED |
 			DMC_MEMCONFIGx_CHIP_COL_10 |
 			DMC_MEMCONFIGx_CHIP_ROW_15 |
 			DMC_MEMCONFIGx_CHIP_BANK_8,
 		.membaseconfig0 = DMC_MEMBASECONFIG_VAL(0x40),
 		.membaseconfig1 = DMC_MEMBASECONFIG_VAL(0x80),
 		.prechconfig_tp_cnt = 0xff,
 		.dpwrdn_cyc = 0xff,
 		.dsref_cyc = 0xffff,
 		.concontrol = DMC_CONCONTROL_DFI_INIT_START_DISABLE |
 			DMC_CONCONTROL_TIMEOUT_LEVEL0 |
 			DMC_CONCONTROL_RD_FETCH_DISABLE |
 			DMC_CONCONTROL_EMPTY_DISABLE |
 			DMC_CONCONTROL_AREF_EN_DISABLE |
 			DMC_CONCONTROL_IO_PD_CON_DISABLE,
 		.dmc_channels = 2,
 		.chips_per_channel = 2,
 		.chips_to_configure = 1,
 		.send_zq_init = 1,
 		.impedance = IMP_OUTPUT_DRV_40_OHM,
 		.gate_leveling_enable = 1,
 	}
 };

 /**
  * Get the required memory type and speed (SPL version).
  *
  * In SPL we have no device tree, so we use the machine parameters
  *
  * @param mem_type	Returns memory type
  * @param frequency_mhz	Returns memory speed in MHz
  * @param arm_freq	Returns ARM clock speed in MHz
  * @param mem_manuf	Return Memory Manufacturer name
  * @return 0 if all ok
  */
 static int clock_get_mem_selection(enum ddr_mode *mem_type,
 		unsigned *frequency_mhz, unsigned *arm_freq,
 		enum mem_manuf *mem_manuf)
 {
 	struct spl_machine_param *params;

 	params = spl_get_machine_params();
 	*mem_type = params->mem_type;
 	*frequency_mhz = params->frequency_mhz;
 	*arm_freq = params->arm_freq_mhz;
 	*mem_manuf = params->mem_manuf;

 	return 0;
 }

 /* Get the ratios for setting ARM clock */
 struct arm_clk_ratios *get_arm_ratios(void)
 {
 	struct arm_clk_ratios *arm_ratio;
 	enum ddr_mode mem_type;
 	enum mem_manuf mem_manuf;
 	unsigned frequency_mhz, arm_freq;
 	int i;

 	if (clock_get_mem_selection(&mem_type, &frequency_mhz,
 					&arm_freq, &mem_manuf))
 		;
 	for (i = 0, arm_ratio = arm_clk_ratios; i < ARRAY_SIZE(arm_clk_ratios);
 		i++, arm_ratio++) {
 		if (arm_ratio->arm_freq_mhz == arm_freq)
 			return arm_ratio;
 	}

 	/* will hang if failed to find clock ratio */
 	while (1)
 		;

 	return NULL;
 }

 struct mem_timings *clock_get_mem_timings(void)
 {
 	struct mem_timings *mem;
 	enum ddr_mode mem_type;
 	enum mem_manuf mem_manuf;
 	unsigned frequency_mhz, arm_freq;
 	int i;

 	if (!clock_get_mem_selection(&mem_type, &frequency_mhz,
 						&arm_freq, &mem_manuf)) {
 		for (i = 0, mem = mem_timings; i < ARRAY_SIZE(mem_timings);
 				i++, mem++) {
 			if (mem->mem_type == mem_type &&
 					mem->frequency_mhz == frequency_mhz &&
 					mem->mem_manuf == mem_manuf)
 				return mem;
 		}
 	}

 	/* will hang if failed to find memory timings */
 	while (1)
 		;

 	return NULL;
 }

 void system_clock_init()
 {
 	struct exynos5_clock *clk = (struct exynos5_clock *)EXYNOS5_CLOCK_BASE;
 	struct mem_timings *mem;
 	struct arm_clk_ratios *arm_clk_ratio;
 	u32 val, tmp;

 	mem = clock_get_mem_timings();
 	arm_clk_ratio = get_arm_ratios();

 	clrbits_le32(&clk->src_cpu, MUX_APLL_SEL_MASK);
 	do {
 		val = readl(&clk->mux_stat_cpu);
 	} while ((val | MUX_APLL_SEL_MASK) != val);

 	clrbits_le32(&clk->src_core1, MUX_MPLL_SEL_MASK);
 	do {
 		val = readl(&clk->mux_stat_core1);
 	} while ((val | MUX_MPLL_SEL_MASK) != val);

 	clrbits_le32(&clk->src_core1, MUX_CPLL_SEL_MASK);
 	clrbits_le32(&clk->src_core1, MUX_EPLL_SEL_MASK);
 	clrbits_le32(&clk->src_core1, MUX_VPLL_SEL_MASK);
 	clrbits_le32(&clk->src_core1, MUX_GPLL_SEL_MASK);
 	tmp = MUX_CPLL_SEL_MASK | MUX_EPLL_SEL_MASK | MUX_VPLL_SEL_MASK
 		| MUX_GPLL_SEL_MASK;
 	do {
 		val = readl(&clk->mux_stat_top2);
 	} while ((val | tmp) != val);

 	clrbits_le32(&clk->src_cdrex, MUX_BPLL_SEL_MASK);
 	do {
 		val = readl(&clk->mux_stat_cdrex);
 	} while ((val | MUX_BPLL_SEL_MASK) != val);

 	/* PLL locktime */
 	writel(APLL_LOCK_VAL, &clk->apll_lock);

 	writel(MPLL_LOCK_VAL, &clk->mpll_lock);

 	writel(BPLL_LOCK_VAL, &clk->bpll_lock);

 	writel(CPLL_LOCK_VAL, &clk->cpll_lock);

 	writel(GPLL_LOCK_VAL, &clk->gpll_lock);

 	writel(EPLL_LOCK_VAL, &clk->epll_lock);

 	writel(VPLL_LOCK_VAL, &clk->vpll_lock);

 	writel(CLK_REG_DISABLE, &clk->pll_div2_sel);

 	writel(MUX_HPM_SEL_MASK, &clk->src_cpu);
 	do {
 		val = readl(&clk->mux_stat_cpu);
 	} while ((val | HPM_SEL_SCLK_MPLL) != val);

 	val = arm_clk_ratio->arm2_ratio << 28
 		| arm_clk_ratio->apll_ratio << 24
 		| arm_clk_ratio->pclk_dbg_ratio << 20
 		| arm_clk_ratio->atb_ratio << 16
 		| arm_clk_ratio->periph_ratio << 12
 		| arm_clk_ratio->acp_ratio << 8
 		| arm_clk_ratio->cpud_ratio << 4
 		| arm_clk_ratio->arm_ratio;
 	writel(val, &clk->div_cpu0);
 	do {
 		val = readl(&clk->div_stat_cpu0);
 	} while (0 != val);

 	writel(CLK_DIV_CPU1_VAL, &clk->div_cpu1);
 	do {
 		val = readl(&clk->div_stat_cpu1);
 	} while (0 != val);

 	/* Set APLL */
 	writel(APLL_CON1_VAL, &clk->apll_con1);
 	val = set_pll(arm_clk_ratio->apll_mdiv, arm_clk_ratio->apll_pdiv,
 			arm_clk_ratio->apll_sdiv);
 	writel(val, &clk->apll_con0);
 	while (readl(&clk->apll_con0) & APLL_CON0_LOCKED)
 		;

 	/* Set MPLL */
 	writel(MPLL_CON1_VAL, &clk->mpll_con1);
 	val = set_pll(mem->mpll_mdiv, mem->mpll_pdiv, mem->mpll_sdiv);
 	writel(val, &clk->mpll_con0);
 	while (readl(&clk->mpll_con0) & MPLL_CON0_LOCKED)
 		;

 	/* Set BPLL */
 	writel(BPLL_CON1_VAL, &clk->bpll_con1);
 	val = set_pll(mem->bpll_mdiv, mem->bpll_pdiv, mem->bpll_sdiv);
 	writel(val, &clk->bpll_con0);
 	while (readl(&clk->bpll_con0) & BPLL_CON0_LOCKED)
 		;

 	/* Set CPLL */
 	writel(CPLL_CON1_VAL, &clk->cpll_con1);
 	val = set_pll(mem->cpll_mdiv, mem->cpll_pdiv, mem->cpll_sdiv);
 	writel(val, &clk->cpll_con0);
 	while (readl(&clk->cpll_con0) & CPLL_CON0_LOCKED)
 		;

 	/* Set GPLL */
 	writel(GPLL_CON1_VAL, &clk->gpll_con1);
 	val = set_pll(mem->gpll_mdiv, mem->gpll_pdiv, mem->gpll_sdiv);
 	writel(val, &clk->gpll_con0);
 	while (readl(&clk->gpll_con0) & GPLL_CON0_LOCKED)
 		;

 	/* Set EPLL */
 	writel(EPLL_CON2_VAL, &clk->epll_con2);
 	writel(EPLL_CON1_VAL, &clk->epll_con1);
 	val = set_pll(mem->epll_mdiv, mem->epll_pdiv, mem->epll_sdiv);
 	writel(val, &clk->epll_con0);
 	while (readl(&clk->epll_con0) & EPLL_CON0_LOCKED)
 		;

 	/* Set VPLL */
 	writel(VPLL_CON2_VAL, &clk->vpll_con2);
 	writel(VPLL_CON1_VAL, &clk->vpll_con1);
 	val = set_pll(mem->vpll_mdiv, mem->vpll_pdiv, mem->vpll_sdiv);
 	writel(val, &clk->vpll_con0);
 	while (readl(&clk->vpll_con0) & VPLL_CON0_LOCKED)
 		;

 	writel(CLK_SRC_CORE0_VAL, &clk->src_core0);
 	writel(CLK_DIV_CORE0_VAL, &clk->div_core0);
 	while (readl(&clk->div_stat_core0) != 0)
 		;

 	writel(CLK_DIV_CORE1_VAL, &clk->div_core1);
 	while (readl(&clk->div_stat_core1) != 0)
 		;

 	writel(CLK_DIV_SYSRGT_VAL, &clk->div_sysrgt);
 	while (readl(&clk->div_stat_sysrgt) != 0)
 		;

 	writel(CLK_DIV_ACP_VAL, &clk->div_acp);
 	while (readl(&clk->div_stat_acp) != 0)
 		;

 	writel(CLK_DIV_SYSLFT_VAL, &clk->div_syslft);
 	while (readl(&clk->div_stat_syslft) != 0)
 		;

 	writel(CLK_SRC_TOP0_VAL, &clk->src_top0);
 	writel(CLK_SRC_TOP1_VAL, &clk->src_top1);
 	writel(TOP2_VAL, &clk->src_top2);
 	writel(CLK_SRC_TOP3_VAL, &clk->src_top3);

 	writel(CLK_DIV_TOP0_VAL, &clk->div_top0);
 	while (readl(&clk->div_stat_top0))
 		;

 	writel(CLK_DIV_TOP1_VAL, &clk->div_top1);
 	while (readl(&clk->div_stat_top1))
 		;

 	writel(CLK_SRC_LEX_VAL, &clk->src_lex);
 	while (1) {
 		val = readl(&clk->mux_stat_lex);
 		if (val == (val | 1))
 			break;
 	}

 	writel(CLK_DIV_LEX_VAL, &clk->div_lex);
 	while (readl(&clk->div_stat_lex))
 		;

 	writel(CLK_DIV_R0X_VAL, &clk->div_r0x);
 	while (readl(&clk->div_stat_r0x))
 		;

 	writel(CLK_DIV_R0X_VAL, &clk->div_r0x);
 	while (readl(&clk->div_stat_r0x))
 		;

 	writel(CLK_DIV_R1X_VAL, &clk->div_r1x);
 	while (readl(&clk->div_stat_r1x))
 		;

 	writel(CLK_REG_DISABLE, &clk->src_cdrex);

 	writel(CLK_DIV_CDREX_VAL, &clk->div_cdrex);
 	while (readl(&clk->div_stat_cdrex))
 		;

 	val = readl(&clk->src_cpu);
 	val |= CLK_SRC_CPU_VAL;
 	writel(val, &clk->src_cpu);

 	val = readl(&clk->src_top2);
 	val |= CLK_SRC_TOP2_VAL;
 	writel(val, &clk->src_top2);

 	val = readl(&clk->src_core1);
 	val |= CLK_SRC_CORE1_VAL;
 	writel(val, &clk->src_core1);

 	writel(CLK_SRC_FSYS0_VAL, &clk->src_fsys);
 	writel(CLK_DIV_FSYS0_VAL, &clk->div_fsys0);
 	while (readl(&clk->div_stat_fsys0))
 		;

 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_cpu);
 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_core);
 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_acp);
 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_top);
 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_lex);
 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_r0x);
 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_r1x);
 	writel(CLK_REG_DISABLE, &clk->clkout_cmu_cdrex);

 	writel(CLK_SRC_PERIC0_VAL, &clk->src_peric0);
 	writel(CLK_DIV_PERIC0_VAL, &clk->div_peric0);

 	writel(CLK_SRC_PERIC1_VAL, &clk->src_peric1);
 	writel(CLK_DIV_PERIC1_VAL, &clk->div_peric1);
 	writel(CLK_DIV_PERIC2_VAL, &clk->div_peric2);
 	writel(CLK_DIV_PERIC3_VAL, &clk->div_peric3);

 	writel(SCLK_SRC_ISP_VAL, &clk->sclk_src_isp);
 	writel(SCLK_DIV_ISP_VAL, &clk->sclk_div_isp);
 	writel(CLK_DIV_ISP0_VAL, &clk->div_isp0);
 	writel(CLK_DIV_ISP1_VAL, &clk->div_isp1);
 	writel(CLK_DIV_ISP2_VAL, &clk->div_isp2);

 	/* FIMD1 SRC CLK SELECTION */
 	writel(CLK_SRC_DISP1_0_VAL, &clk->src_disp1_0);

 	val = MMC2_PRE_RATIO_VAL << MMC2_PRE_RATIO_OFFSET
 		| MMC2_RATIO_VAL << MMC2_RATIO_OFFSET
 		| MMC3_PRE_RATIO_VAL << MMC3_PRE_RATIO_OFFSET
 		| MMC3_RATIO_VAL << MMC3_RATIO_OFFSET;
 	writel(val, &clk->div_fsys2);
 }

 void clock_init_dp_clock(void)
 {
 	struct exynos5_clock *clk = (struct exynos5_clock *)EXYNOS5_CLOCK_BASE;

 	/* DP clock enable */
 	setbits_le32(&clk->gate_ip_disp1, CLK_GATE_DP1_ALLOW);

 	/* We run DP at 267 Mhz */
 	setbits_le32(&clk->div_disp1_0, CLK_DIV_DISP1_0_FIMD1);
 }
	/*
	* Clock setup for SMDK5250 board based on EXYNOS5
	*
	* Copyright (C) 2012 Samsung Electronics
	*
	* 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 <config.h>
	#include <asm/io.h>
	#include <asm/arch/clk.h>
	#include <asm/arch/clock.h>
	#include <asm/arch/spl.h>

	#include "clock_init.h"
	#include "setup.h"

	DECLARE_GLOBAL_DATA_PTR;

	struct arm_clk_ratios arm_clk_ratios[] = {
	{
	.arm_freq_mhz = 600,

	.apll_mdiv = 0xc8,
	.apll_pdiv = 0x4,
	.apll_sdiv = 0x1,

	.arm2_ratio = 0x0,
	.apll_ratio = 0x1,
	.pclk_dbg_ratio = 0x1,
	.atb_ratio = 0x2,
	.periph_ratio = 0x7,
	.acp_ratio = 0x7,
	.cpud_ratio = 0x1,
	.arm_ratio = 0x0,
	}, {
	.arm_freq_mhz = 800,

	.apll_mdiv = 0x64,
	.apll_pdiv = 0x3,
	.apll_sdiv = 0x0,

	.arm2_ratio = 0x0,
	.apll_ratio = 0x1,
	.pclk_dbg_ratio = 0x1,
	.atb_ratio = 0x3,
	.periph_ratio = 0x7,
	.acp_ratio = 0x7,
	.cpud_ratio = 0x2,
	.arm_ratio = 0x0,
	}, {
	.arm_freq_mhz = 1000,

	.apll_mdiv = 0x7d,
	.apll_pdiv = 0x3,
	.apll_sdiv = 0x0,

	.arm2_ratio = 0x0,
	.apll_ratio = 0x1,
	.pclk_dbg_ratio = 0x1,
	.atb_ratio = 0x4,
	.periph_ratio = 0x7,
	.acp_ratio = 0x7,
	.cpud_ratio = 0x2,
	.arm_ratio = 0x0,
	}, {
	.arm_freq_mhz = 1200,

	.apll_mdiv = 0x96,
	.apll_pdiv = 0x3,
	.apll_sdiv = 0x0,

	.arm2_ratio = 0x0,
	.apll_ratio = 0x3,
	.pclk_dbg_ratio = 0x1,
	.atb_ratio = 0x5,
	.periph_ratio = 0x7,
	.acp_ratio = 0x7,
	.cpud_ratio = 0x3,
	.arm_ratio = 0x0,
	}, {
	.arm_freq_mhz = 1400,

	.apll_mdiv = 0xaf,
	.apll_pdiv = 0x3,
	.apll_sdiv = 0x0,

	.arm2_ratio = 0x0,
	.apll_ratio = 0x3,
	.pclk_dbg_ratio = 0x1,
	.atb_ratio = 0x6,
	.periph_ratio = 0x7,
	.acp_ratio = 0x7,
	.cpud_ratio = 0x3,
	.arm_ratio = 0x0,
	}, {
	.arm_freq_mhz = 1700,

	.apll_mdiv = 0x1a9,
	.apll_pdiv = 0x6,
	.apll_sdiv = 0x0,

	.arm2_ratio = 0x0,
	.apll_ratio = 0x3,
	.pclk_dbg_ratio = 0x1,
	.atb_ratio = 0x6,
	.periph_ratio = 0x7,
	.acp_ratio = 0x7,
	.cpud_ratio = 0x3,
	.arm_ratio = 0x0,
	}
	};
	struct mem_timings mem_timings[] = {
	{
	.mem_manuf = MEM_MANUF_ELPIDA,
	.mem_type = DDR_MODE_DDR3,
	.frequency_mhz = 800,
	.mpll_mdiv = 0xc8,
	.mpll_pdiv = 0x3,
	.mpll_sdiv = 0x0,
	.cpll_mdiv = 0xde,
	.cpll_pdiv = 0x4,
	.cpll_sdiv = 0x2,
	.gpll_mdiv = 0x215,
	.gpll_pdiv = 0xc,
	.gpll_sdiv = 0x1,
	.epll_mdiv = 0x60,
	.epll_pdiv = 0x3,
	.epll_sdiv = 0x3,
	.vpll_mdiv = 0x96,
	.vpll_pdiv = 0x3,
	.vpll_sdiv = 0x2,

	.bpll_mdiv = 0x64,
	.bpll_pdiv = 0x3,
	.bpll_sdiv = 0x0,
	.pclk_cdrex_ratio = 0x5,
	.direct_cmd_msr = {
	0x00020018, 0x00030000, 0x00010042, 0x00000d70
	},
	.timing_ref = 0x000000bb,
	.timing_row = 0x8c36650e,
	.timing_data = 0x3630580b,
	.timing_power = 0x41000a44,
	.phy0_dqs = 0x08080808,
	.phy1_dqs = 0x08080808,
	.phy0_dq = 0x08080808,
	.phy1_dq = 0x08080808,
	.phy0_tFS = 0x4,
	.phy1_tFS = 0x4,
	.phy0_pulld_dqs = 0xf,
	.phy1_pulld_dqs = 0xf,

	.lpddr3_ctrl_phy_reset = 0x1,
	.ctrl_start_point = 0x10,
	.ctrl_inc = 0x10,
	.ctrl_start = 0x1,
	.ctrl_dll_on = 0x1,
	.ctrl_ref = 0x8,

	.ctrl_force = 0x1a,
	.ctrl_rdlat = 0x0b,
	.ctrl_bstlen = 0x08,

	.fp_resync = 0x8,
	.iv_size = 0x7,
	.dfi_init_start = 1,
	.aref_en = 1,

	.rd_fetch = 0x3,

	.zq_mode_dds = 0x7,
	.zq_mode_term = 0x1,
	.zq_mode_noterm = 0,

	/*
	* Dynamic Clock: Always Running
	* Memory Burst length: 8
	* Number of chips: 1
	* Memory Bus width: 32 bit
	* Memory Type: DDR3
	* Additional Latancy for PLL: 0 Cycle
	*/
	.memcontrol = DMC_MEMCONTROL_CLK_STOP_DISABLE \|
	DMC_MEMCONTROL_DPWRDN_DISABLE \|
	DMC_MEMCONTROL_DPWRDN_ACTIVE_PRECHARGE \|
	DMC_MEMCONTROL_TP_DISABLE \|
	DMC_MEMCONTROL_DSREF_ENABLE \|
	DMC_MEMCONTROL_ADD_LAT_PALL_CYCLE(0) \|
	DMC_MEMCONTROL_MEM_TYPE_DDR3 \|
	DMC_MEMCONTROL_MEM_WIDTH_32BIT \|
	DMC_MEMCONTROL_NUM_CHIP_1 \|
	DMC_MEMCONTROL_BL_8 \|
	DMC_MEMCONTROL_PZQ_DISABLE \|
	DMC_MEMCONTROL_MRR_BYTE_7_0,
	.memconfig = DMC_MEMCONFIGx_CHIP_MAP_INTERLEAVED \|
	DMC_MEMCONFIGx_CHIP_COL_10 \|
	DMC_MEMCONFIGx_CHIP_ROW_15 \|
	DMC_MEMCONFIGx_CHIP_BANK_8,
	.membaseconfig0 = DMC_MEMBASECONFIG_VAL(0x40),
	.membaseconfig1 = DMC_MEMBASECONFIG_VAL(0x80),
	.prechconfig_tp_cnt = 0xff,
	.dpwrdn_cyc = 0xff,
	.dsref_cyc = 0xffff,
	.concontrol = DMC_CONCONTROL_DFI_INIT_START_DISABLE \|
	DMC_CONCONTROL_TIMEOUT_LEVEL0 \|
	DMC_CONCONTROL_RD_FETCH_DISABLE \|
	DMC_CONCONTROL_EMPTY_DISABLE \|
	DMC_CONCONTROL_AREF_EN_DISABLE \|
	DMC_CONCONTROL_IO_PD_CON_DISABLE,
	.dmc_channels = 2,
	.chips_per_channel = 2,
	.chips_to_configure = 1,
	.send_zq_init = 1,
	.impedance = IMP_OUTPUT_DRV_30_OHM,
	.gate_leveling_enable = 0,
	}, {
	.mem_manuf = MEM_MANUF_SAMSUNG,
	.mem_type = DDR_MODE_DDR3,
	.frequency_mhz = 800,
	.mpll_mdiv = 0xc8,
	.mpll_pdiv = 0x3,
	.mpll_sdiv = 0x0,
	.cpll_mdiv = 0xde,
	.cpll_pdiv = 0x4,
	.cpll_sdiv = 0x2,
	.gpll_mdiv = 0x215,
	.gpll_pdiv = 0xc,
	.gpll_sdiv = 0x1,
	.epll_mdiv = 0x60,
	.epll_pdiv = 0x3,
	.epll_sdiv = 0x3,
	.vpll_mdiv = 0x96,
	.vpll_pdiv = 0x3,
	.vpll_sdiv = 0x2,

	.bpll_mdiv = 0x64,
	.bpll_pdiv = 0x3,
	.bpll_sdiv = 0x0,
	.pclk_cdrex_ratio = 0x5,
	.direct_cmd_msr = {
	0x00020018, 0x00030000, 0x00010000, 0x00000d70
	},
	.timing_ref = 0x000000bb,
	.timing_row = 0x8c36650e,
	.timing_data = 0x3630580b,
	.timing_power = 0x41000a44,
	.phy0_dqs = 0x08080808,
	.phy1_dqs = 0x08080808,
	.phy0_dq = 0x08080808,
	.phy1_dq = 0x08080808,
	.phy0_tFS = 0x8,
	.phy1_tFS = 0x8,
	.phy0_pulld_dqs = 0xf,
	.phy1_pulld_dqs = 0xf,

	.lpddr3_ctrl_phy_reset = 0x1,
	.ctrl_start_point = 0x10,
	.ctrl_inc = 0x10,
	.ctrl_start = 0x1,
	.ctrl_dll_on = 0x1,
	.ctrl_ref = 0x8,

	.ctrl_force = 0x1a,
	.ctrl_rdlat = 0x0b,
	.ctrl_bstlen = 0x08,

	.fp_resync = 0x8,
	.iv_size = 0x7,
	.dfi_init_start = 1,
	.aref_en = 1,

	.rd_fetch = 0x3,

	.zq_mode_dds = 0x5,
	.zq_mode_term = 0x1,
	.zq_mode_noterm = 1,

	/*
	* Dynamic Clock: Always Running
	* Memory Burst length: 8
	* Number of chips: 1
	* Memory Bus width: 32 bit
	* Memory Type: DDR3
	* Additional Latancy for PLL: 0 Cycle
	*/
	.memcontrol = DMC_MEMCONTROL_CLK_STOP_DISABLE \|
	DMC_MEMCONTROL_DPWRDN_DISABLE \|
	DMC_MEMCONTROL_DPWRDN_ACTIVE_PRECHARGE \|
	DMC_MEMCONTROL_TP_DISABLE \|
	DMC_MEMCONTROL_DSREF_ENABLE \|
	DMC_MEMCONTROL_ADD_LAT_PALL_CYCLE(0) \|
	DMC_MEMCONTROL_MEM_TYPE_DDR3 \|
	DMC_MEMCONTROL_MEM_WIDTH_32BIT \|
	DMC_MEMCONTROL_NUM_CHIP_1 \|
	DMC_MEMCONTROL_BL_8 \|
	DMC_MEMCONTROL_PZQ_DISABLE \|
	DMC_MEMCONTROL_MRR_BYTE_7_0,
	.memconfig = DMC_MEMCONFIGx_CHIP_MAP_INTERLEAVED \|
	DMC_MEMCONFIGx_CHIP_COL_10 \|
	DMC_MEMCONFIGx_CHIP_ROW_15 \|
	DMC_MEMCONFIGx_CHIP_BANK_8,
	.membaseconfig0 = DMC_MEMBASECONFIG_VAL(0x40),
	.membaseconfig1 = DMC_MEMBASECONFIG_VAL(0x80),
	.prechconfig_tp_cnt = 0xff,
	.dpwrdn_cyc = 0xff,
	.dsref_cyc = 0xffff,
	.concontrol = DMC_CONCONTROL_DFI_INIT_START_DISABLE \|
	DMC_CONCONTROL_TIMEOUT_LEVEL0 \|
	DMC_CONCONTROL_RD_FETCH_DISABLE \|
	DMC_CONCONTROL_EMPTY_DISABLE \|
	DMC_CONCONTROL_AREF_EN_DISABLE \|
	DMC_CONCONTROL_IO_PD_CON_DISABLE,
	.dmc_channels = 2,
	.chips_per_channel = 2,
	.chips_to_configure = 1,
	.send_zq_init = 1,
	.impedance = IMP_OUTPUT_DRV_40_OHM,
	.gate_leveling_enable = 1,
	}
	};

	/**
	* Get the required memory type and speed (SPL version).
	*
	* In SPL we have no device tree, so we use the machine parameters
	*
	* @param mem_type Returns memory type
	* @param frequency_mhz Returns memory speed in MHz
	* @param arm_freq Returns ARM clock speed in MHz
	* @param mem_manuf Return Memory Manufacturer name
	* @return 0 if all ok
	*/
	static int clock_get_mem_selection(enum ddr_mode *mem_type,
	unsigned frequency_mhz, unsigned arm_freq,
	enum mem_manuf *mem_manuf)
	{
	struct spl_machine_param *params;

	params = spl_get_machine_params();
	*mem_type = params->mem_type;
	*frequency_mhz = params->frequency_mhz;
	*arm_freq = params->arm_freq_mhz;
	*mem_manuf = params->mem_manuf;

	return 0;
	}

	/* Get the ratios for setting ARM clock */
	struct arm_clk_ratios *get_arm_ratios(void)
	{
	struct arm_clk_ratios *arm_ratio;
	enum ddr_mode mem_type;
	enum mem_manuf mem_manuf;
	unsigned frequency_mhz, arm_freq;
	int i;

	if (clock_get_mem_selection(&mem_type, &frequency_mhz,
	&arm_freq, &mem_manuf))
	;
	for (i = 0, arm_ratio = arm_clk_ratios; i < ARRAY_SIZE(arm_clk_ratios);
	i++, arm_ratio++) {
	if (arm_ratio->arm_freq_mhz == arm_freq)
	return arm_ratio;
	}

	/* will hang if failed to find clock ratio */
	while (1)
	;

	return NULL;
	}

	struct mem_timings *clock_get_mem_timings(void)
	{
	struct mem_timings *mem;
	enum ddr_mode mem_type;
	enum mem_manuf mem_manuf;
	unsigned frequency_mhz, arm_freq;
	int i;

	if (!clock_get_mem_selection(&mem_type, &frequency_mhz,
	&arm_freq, &mem_manuf)) {
	for (i = 0, mem = mem_timings; i < ARRAY_SIZE(mem_timings);
	i++, mem++) {
	if (mem->mem_type == mem_type &&
	mem->frequency_mhz == frequency_mhz &&
	mem->mem_manuf == mem_manuf)
	return mem;
	}
	}

	/* will hang if failed to find memory timings */
	while (1)
	;

	return NULL;
	}

	void system_clock_init()
	{
	struct exynos5_clock clk = (struct exynos5_clock )EXYNOS5_CLOCK_BASE;
	struct mem_timings *mem;
	struct arm_clk_ratios *arm_clk_ratio;
	u32 val, tmp;

	mem = clock_get_mem_timings();
	arm_clk_ratio = get_arm_ratios();

	clrbits_le32(&clk->src_cpu, MUX_APLL_SEL_MASK);
	do {
	val = readl(&clk->mux_stat_cpu);
	} while ((val \| MUX_APLL_SEL_MASK) != val);

	clrbits_le32(&clk->src_core1, MUX_MPLL_SEL_MASK);
	do {
	val = readl(&clk->mux_stat_core1);
	} while ((val \| MUX_MPLL_SEL_MASK) != val);

	clrbits_le32(&clk->src_core1, MUX_CPLL_SEL_MASK);
	clrbits_le32(&clk->src_core1, MUX_EPLL_SEL_MASK);
	clrbits_le32(&clk->src_core1, MUX_VPLL_SEL_MASK);
	clrbits_le32(&clk->src_core1, MUX_GPLL_SEL_MASK);
	tmp = MUX_CPLL_SEL_MASK \| MUX_EPLL_SEL_MASK \| MUX_VPLL_SEL_MASK
	\| MUX_GPLL_SEL_MASK;
	do {
	val = readl(&clk->mux_stat_top2);
	} while ((val \| tmp) != val);

	clrbits_le32(&clk->src_cdrex, MUX_BPLL_SEL_MASK);
	do {
	val = readl(&clk->mux_stat_cdrex);
	} while ((val \| MUX_BPLL_SEL_MASK) != val);

	/* PLL locktime */
	writel(APLL_LOCK_VAL, &clk->apll_lock);

	writel(MPLL_LOCK_VAL, &clk->mpll_lock);

	writel(BPLL_LOCK_VAL, &clk->bpll_lock);

	writel(CPLL_LOCK_VAL, &clk->cpll_lock);

	writel(GPLL_LOCK_VAL, &clk->gpll_lock);

	writel(EPLL_LOCK_VAL, &clk->epll_lock);

	writel(VPLL_LOCK_VAL, &clk->vpll_lock);

	writel(CLK_REG_DISABLE, &clk->pll_div2_sel);

	writel(MUX_HPM_SEL_MASK, &clk->src_cpu);
	do {
	val = readl(&clk->mux_stat_cpu);
	} while ((val \| HPM_SEL_SCLK_MPLL) != val);

	val = arm_clk_ratio->arm2_ratio << 28
	\| arm_clk_ratio->apll_ratio << 24
	\| arm_clk_ratio->pclk_dbg_ratio << 20
	\| arm_clk_ratio->atb_ratio << 16
	\| arm_clk_ratio->periph_ratio << 12
	\| arm_clk_ratio->acp_ratio << 8
	\| arm_clk_ratio->cpud_ratio << 4
	\| arm_clk_ratio->arm_ratio;
	writel(val, &clk->div_cpu0);
	do {
	val = readl(&clk->div_stat_cpu0);
	} while (0 != val);

	writel(CLK_DIV_CPU1_VAL, &clk->div_cpu1);
	do {
	val = readl(&clk->div_stat_cpu1);
	} while (0 != val);

	/* Set APLL */
	writel(APLL_CON1_VAL, &clk->apll_con1);
	val = set_pll(arm_clk_ratio->apll_mdiv, arm_clk_ratio->apll_pdiv,
	arm_clk_ratio->apll_sdiv);
	writel(val, &clk->apll_con0);
	while (readl(&clk->apll_con0) & APLL_CON0_LOCKED)
	;

	/* Set MPLL */
	writel(MPLL_CON1_VAL, &clk->mpll_con1);
	val = set_pll(mem->mpll_mdiv, mem->mpll_pdiv, mem->mpll_sdiv);
	writel(val, &clk->mpll_con0);
	while (readl(&clk->mpll_con0) & MPLL_CON0_LOCKED)
	;

	/* Set BPLL */
	writel(BPLL_CON1_VAL, &clk->bpll_con1);
	val = set_pll(mem->bpll_mdiv, mem->bpll_pdiv, mem->bpll_sdiv);
	writel(val, &clk->bpll_con0);
	while (readl(&clk->bpll_con0) & BPLL_CON0_LOCKED)
	;

	/* Set CPLL */
	writel(CPLL_CON1_VAL, &clk->cpll_con1);
	val = set_pll(mem->cpll_mdiv, mem->cpll_pdiv, mem->cpll_sdiv);
	writel(val, &clk->cpll_con0);
	while (readl(&clk->cpll_con0) & CPLL_CON0_LOCKED)
	;

	/* Set GPLL */
	writel(GPLL_CON1_VAL, &clk->gpll_con1);
	val = set_pll(mem->gpll_mdiv, mem->gpll_pdiv, mem->gpll_sdiv);
	writel(val, &clk->gpll_con0);
	while (readl(&clk->gpll_con0) & GPLL_CON0_LOCKED)
	;

	/* Set EPLL */
	writel(EPLL_CON2_VAL, &clk->epll_con2);
	writel(EPLL_CON1_VAL, &clk->epll_con1);
	val = set_pll(mem->epll_mdiv, mem->epll_pdiv, mem->epll_sdiv);
	writel(val, &clk->epll_con0);
	while (readl(&clk->epll_con0) & EPLL_CON0_LOCKED)
	;

	/* Set VPLL */
	writel(VPLL_CON2_VAL, &clk->vpll_con2);
	writel(VPLL_CON1_VAL, &clk->vpll_con1);
	val = set_pll(mem->vpll_mdiv, mem->vpll_pdiv, mem->vpll_sdiv);
	writel(val, &clk->vpll_con0);
	while (readl(&clk->vpll_con0) & VPLL_CON0_LOCKED)
	;

	writel(CLK_SRC_CORE0_VAL, &clk->src_core0);
	writel(CLK_DIV_CORE0_VAL, &clk->div_core0);
	while (readl(&clk->div_stat_core0) != 0)
	;

	writel(CLK_DIV_CORE1_VAL, &clk->div_core1);
	while (readl(&clk->div_stat_core1) != 0)
	;

	writel(CLK_DIV_SYSRGT_VAL, &clk->div_sysrgt);
	while (readl(&clk->div_stat_sysrgt) != 0)
	;

	writel(CLK_DIV_ACP_VAL, &clk->div_acp);
	while (readl(&clk->div_stat_acp) != 0)
	;

	writel(CLK_DIV_SYSLFT_VAL, &clk->div_syslft);
	while (readl(&clk->div_stat_syslft) != 0)
	;

	writel(CLK_SRC_TOP0_VAL, &clk->src_top0);
	writel(CLK_SRC_TOP1_VAL, &clk->src_top1);
	writel(TOP2_VAL, &clk->src_top2);
	writel(CLK_SRC_TOP3_VAL, &clk->src_top3);

	writel(CLK_DIV_TOP0_VAL, &clk->div_top0);
	while (readl(&clk->div_stat_top0))
	;

	writel(CLK_DIV_TOP1_VAL, &clk->div_top1);
	while (readl(&clk->div_stat_top1))
	;

	writel(CLK_SRC_LEX_VAL, &clk->src_lex);
	while (1) {
	val = readl(&clk->mux_stat_lex);
	if (val == (val \| 1))
	break;
	}

	writel(CLK_DIV_LEX_VAL, &clk->div_lex);
	while (readl(&clk->div_stat_lex))
	;

	writel(CLK_DIV_R0X_VAL, &clk->div_r0x);
	while (readl(&clk->div_stat_r0x))
	;

	writel(CLK_DIV_R0X_VAL, &clk->div_r0x);
	while (readl(&clk->div_stat_r0x))
	;

	writel(CLK_DIV_R1X_VAL, &clk->div_r1x);
	while (readl(&clk->div_stat_r1x))
	;

	writel(CLK_REG_DISABLE, &clk->src_cdrex);

	writel(CLK_DIV_CDREX_VAL, &clk->div_cdrex);
	while (readl(&clk->div_stat_cdrex))
	;

	val = readl(&clk->src_cpu);
	val \|= CLK_SRC_CPU_VAL;
	writel(val, &clk->src_cpu);

	val = readl(&clk->src_top2);
	val \|= CLK_SRC_TOP2_VAL;
	writel(val, &clk->src_top2);

	val = readl(&clk->src_core1);
	val \|= CLK_SRC_CORE1_VAL;
	writel(val, &clk->src_core1);

	writel(CLK_SRC_FSYS0_VAL, &clk->src_fsys);
	writel(CLK_DIV_FSYS0_VAL, &clk->div_fsys0);
	while (readl(&clk->div_stat_fsys0))
	;

	writel(CLK_REG_DISABLE, &clk->clkout_cmu_cpu);
	writel(CLK_REG_DISABLE, &clk->clkout_cmu_core);
	writel(CLK_REG_DISABLE, &clk->clkout_cmu_acp);
	writel(CLK_REG_DISABLE, &clk->clkout_cmu_top);
	writel(CLK_REG_DISABLE, &clk->clkout_cmu_lex);
	writel(CLK_REG_DISABLE, &clk->clkout_cmu_r0x);
	writel(CLK_REG_DISABLE, &clk->clkout_cmu_r1x);
	writel(CLK_REG_DISABLE, &clk->clkout_cmu_cdrex);

	writel(CLK_SRC_PERIC0_VAL, &clk->src_peric0);
	writel(CLK_DIV_PERIC0_VAL, &clk->div_peric0);

	writel(CLK_SRC_PERIC1_VAL, &clk->src_peric1);
	writel(CLK_DIV_PERIC1_VAL, &clk->div_peric1);
	writel(CLK_DIV_PERIC2_VAL, &clk->div_peric2);
	writel(CLK_DIV_PERIC3_VAL, &clk->div_peric3);

	writel(SCLK_SRC_ISP_VAL, &clk->sclk_src_isp);
	writel(SCLK_DIV_ISP_VAL, &clk->sclk_div_isp);
	writel(CLK_DIV_ISP0_VAL, &clk->div_isp0);
	writel(CLK_DIV_ISP1_VAL, &clk->div_isp1);
	writel(CLK_DIV_ISP2_VAL, &clk->div_isp2);

	/* FIMD1 SRC CLK SELECTION */
	writel(CLK_SRC_DISP1_0_VAL, &clk->src_disp1_0);

	val = MMC2_PRE_RATIO_VAL << MMC2_PRE_RATIO_OFFSET
	\| MMC2_RATIO_VAL << MMC2_RATIO_OFFSET
	\| MMC3_PRE_RATIO_VAL << MMC3_PRE_RATIO_OFFSET
	\| MMC3_RATIO_VAL << MMC3_RATIO_OFFSET;
	writel(val, &clk->div_fsys2);
	}

	void clock_init_dp_clock(void)
	{
	struct exynos5_clock clk = (struct exynos5_clock )EXYNOS5_CLOCK_BASE;

	/* DP clock enable */
	setbits_le32(&clk->gate_ip_disp1, CLK_GATE_DP1_ALLOW);

	/* We run DP at 267 Mhz */
	setbits_le32(&clk->div_disp1_0, CLK_DIV_DISP1_0_FIMD1);
	}