arch/arm/cpu/armv7/omap-common/clocks-common.c - github/trini/u-boot - Gitiles

 /*
  *
  * Clock initialization for OMAP4
  *
  * (C) Copyright 2010
  * Texas Instruments, <www.ti.com>
  *
  * Aneesh V <aneesh@ti.com>
  *
  * Based on previous work by:
  *	Santosh Shilimkar <santosh.shilimkar@ti.com>
  *	Rajendra Nayak <rnayak@ti.com>
  *
  * 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 <asm/omap_common.h>
 #include <asm/gpio.h>
 #include <asm/arch/clocks.h>
 #include <asm/arch/sys_proto.h>
 #include <asm/utils.h>
 #include <asm/omap_gpio.h>
 #include <asm/emif.h>

 #ifndef CONFIG_SPL_BUILD
 /*
  * printing to console doesn't work unless
  * this code is executed from SPL
  */
 #define printf(fmt, args...)
 #define puts(s)
 #endif

 const u32 sys_clk_array[8] = {
 	12000000,	       /* 12 MHz */
 	13000000,	       /* 13 MHz */
 	16800000,	       /* 16.8 MHz */
 	19200000,	       /* 19.2 MHz */
 	26000000,	       /* 26 MHz */
 	27000000,	       /* 27 MHz */
 	38400000,	       /* 38.4 MHz */
 	20000000,		/* 20 MHz */
 };

 static inline u32 __get_sys_clk_index(void)
 {
 	s8 ind;
 	/*
 	 * For ES1 the ROM code calibration of sys clock is not reliable
 	 * due to hw issue. So, use hard-coded value. If this value is not
 	 * correct for any board over-ride this function in board file
 	 * From ES2.0 onwards you will get this information from
 	 * CM_SYS_CLKSEL
 	 */
 	if (omap_revision() == OMAP4430_ES1_0)
 		ind = OMAP_SYS_CLK_IND_38_4_MHZ;
 	else {
 		/* SYS_CLKSEL - 1 to match the dpll param array indices */
 		ind = (readl((*prcm)->cm_sys_clksel) &
 			CM_SYS_CLKSEL_SYS_CLKSEL_MASK) - 1;
 		/*
 		 * SYS_CLKSEL value for 20MHz is 0. This is introduced newly
 		 * in DRA7XX socs. SYS_CLKSEL -1 will be greater than
 		 * NUM_SYS_CLK. So considering the last 3 bits as the index
 		 * for the dpll param array.
 		 */
 		ind &= CM_SYS_CLKSEL_SYS_CLKSEL_MASK;
 	}
 	return ind;
 }

 u32 get_sys_clk_index(void)
 	__attribute__ ((weak, alias("__get_sys_clk_index")));

 u32 get_sys_clk_freq(void)
 {
 	u8 index = get_sys_clk_index();
 	return sys_clk_array[index];
 }

 void setup_post_dividers(u32 const base, const struct dpll_params *params)
 {
 	struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;

 	/* Setup post-dividers */
 	if (params->m2 >= 0)
 		writel(params->m2, &dpll_regs->cm_div_m2_dpll);
 	if (params->m3 >= 0)
 		writel(params->m3, &dpll_regs->cm_div_m3_dpll);
 	if (params->m4_h11 >= 0)
 		writel(params->m4_h11, &dpll_regs->cm_div_m4_h11_dpll);
 	if (params->m5_h12 >= 0)
 		writel(params->m5_h12, &dpll_regs->cm_div_m5_h12_dpll);
 	if (params->m6_h13 >= 0)
 		writel(params->m6_h13, &dpll_regs->cm_div_m6_h13_dpll);
 	if (params->m7_h14 >= 0)
 		writel(params->m7_h14, &dpll_regs->cm_div_m7_h14_dpll);
 	if (params->h21 >= 0)
 		writel(params->h21, &dpll_regs->cm_div_h21_dpll);
 	if (params->h22 >= 0)
 		writel(params->h22, &dpll_regs->cm_div_h22_dpll);
 	if (params->h23 >= 0)
 		writel(params->h23, &dpll_regs->cm_div_h23_dpll);
 	if (params->h24 >= 0)
 		writel(params->h24, &dpll_regs->cm_div_h24_dpll);
 }

 static inline void do_bypass_dpll(u32 const base)
 {
 	struct dpll_regs *dpll_regs = (struct dpll_regs *)base;

 	clrsetbits_le32(&dpll_regs->cm_clkmode_dpll,
 			CM_CLKMODE_DPLL_DPLL_EN_MASK,
 			DPLL_EN_FAST_RELOCK_BYPASS <<
 			CM_CLKMODE_DPLL_EN_SHIFT);
 }

 static inline void wait_for_bypass(u32 const base)
 {
 	struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;

 	if (!wait_on_value(ST_DPLL_CLK_MASK, 0, &dpll_regs->cm_idlest_dpll,
 				LDELAY)) {
 		printf("Bypassing DPLL failed %x\n", base);
 	}
 }

 static inline void do_lock_dpll(u32 const base)
 {
 	struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;

 	clrsetbits_le32(&dpll_regs->cm_clkmode_dpll,
 		      CM_CLKMODE_DPLL_DPLL_EN_MASK,
 		      DPLL_EN_LOCK << CM_CLKMODE_DPLL_EN_SHIFT);
 }

 static inline void wait_for_lock(u32 const base)
 {
 	struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;

 	if (!wait_on_value(ST_DPLL_CLK_MASK, ST_DPLL_CLK_MASK,
 		&dpll_regs->cm_idlest_dpll, LDELAY)) {
 		printf("DPLL locking failed for %x\n", base);
 		hang();
 	}
 }

 inline u32 check_for_lock(u32 const base)
 {
 	struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;
 	u32 lock = readl(&dpll_regs->cm_idlest_dpll) & ST_DPLL_CLK_MASK;

 	return lock;
 }

 const struct dpll_params *get_mpu_dpll_params(struct dplls const *dpll_data)
 {
 	u32 sysclk_ind = get_sys_clk_index();
 	return &dpll_data->mpu[sysclk_ind];
 }

 const struct dpll_params *get_core_dpll_params(struct dplls const *dpll_data)
 {
 	u32 sysclk_ind = get_sys_clk_index();
 	return &dpll_data->core[sysclk_ind];
 }

 const struct dpll_params *get_per_dpll_params(struct dplls const *dpll_data)
 {
 	u32 sysclk_ind = get_sys_clk_index();
 	return &dpll_data->per[sysclk_ind];
 }

 const struct dpll_params *get_iva_dpll_params(struct dplls const *dpll_data)
 {
 	u32 sysclk_ind = get_sys_clk_index();
 	return &dpll_data->iva[sysclk_ind];
 }

 const struct dpll_params *get_usb_dpll_params(struct dplls const *dpll_data)
 {
 	u32 sysclk_ind = get_sys_clk_index();
 	return &dpll_data->usb[sysclk_ind];
 }

 const struct dpll_params *get_abe_dpll_params(struct dplls const *dpll_data)
 {
 #ifdef CONFIG_SYS_OMAP_ABE_SYSCK
 	u32 sysclk_ind = get_sys_clk_index();
 	return &dpll_data->abe[sysclk_ind];
 #else
 	return dpll_data->abe;
 #endif
 }

 static const struct dpll_params *get_ddr_dpll_params
 			(struct dplls const *dpll_data)
 {
 	u32 sysclk_ind = get_sys_clk_index();

 	if (!dpll_data->ddr)
 		return NULL;
 	return &dpll_data->ddr[sysclk_ind];
 }

 static void do_setup_dpll(u32 const base, const struct dpll_params *params,
 				u8 lock, char *dpll)
 {
 	u32 temp, M, N;
 	struct dpll_regs *const dpll_regs = (struct dpll_regs *)base;

 	if (!params)
 		return;

 	temp = readl(&dpll_regs->cm_clksel_dpll);

 	if (check_for_lock(base)) {
 		/*
 		 * The Dpll has already been locked by rom code using CH.
 		 * Check if M,N are matching with Ideal nominal opp values.
 		 * If matches, skip the rest otherwise relock.
 		 */
 		M = (temp & CM_CLKSEL_DPLL_M_MASK) >> CM_CLKSEL_DPLL_M_SHIFT;
 		N = (temp & CM_CLKSEL_DPLL_N_MASK) >> CM_CLKSEL_DPLL_N_SHIFT;
 		if ((M != (params->m)) || (N != (params->n))) {
 			debug("\n %s Dpll locked, but not for ideal M = %d,"
 				"N = %d values, current values are M = %d,"
 				"N= %d" , dpll, params->m, params->n,
 				M, N);
 		} else {
 			/* Dpll locked with ideal values for nominal opps. */
 			debug("\n %s Dpll already locked with ideal"
 						"nominal opp values", dpll);
 			goto setup_post_dividers;
 		}
 	}

 	bypass_dpll(base);

 	/* Set M & N */
 	temp &= ~CM_CLKSEL_DPLL_M_MASK;
 	temp |= (params->m << CM_CLKSEL_DPLL_M_SHIFT) & CM_CLKSEL_DPLL_M_MASK;

 	temp &= ~CM_CLKSEL_DPLL_N_MASK;
 	temp |= (params->n << CM_CLKSEL_DPLL_N_SHIFT) & CM_CLKSEL_DPLL_N_MASK;

 	writel(temp, &dpll_regs->cm_clksel_dpll);

 	/* Lock */
 	if (lock)
 		do_lock_dpll(base);

 setup_post_dividers:
 	setup_post_dividers(base, params);

 	/* Wait till the DPLL locks */
 	if (lock)
 		wait_for_lock(base);
 }

 u32 omap_ddr_clk(void)
 {
 	u32 ddr_clk, sys_clk_khz, omap_rev, divider;
 	const struct dpll_params *core_dpll_params;

 	omap_rev = omap_revision();
 	sys_clk_khz = get_sys_clk_freq() / 1000;

 	core_dpll_params = get_core_dpll_params(*dplls_data);

 	debug("sys_clk %d\n ", sys_clk_khz * 1000);

 	/* Find Core DPLL locked frequency first */
 	ddr_clk = sys_clk_khz * 2 * core_dpll_params->m /
 			(core_dpll_params->n + 1);

 	if (omap_rev < OMAP5430_ES1_0) {
 		/*
 		 * DDR frequency is PHY_ROOT_CLK/2
 		 * PHY_ROOT_CLK = Fdpll/2/M2
 		 */
 		divider = 4;
 	} else {
 		/*
 		 * DDR frequency is PHY_ROOT_CLK
 		 * PHY_ROOT_CLK = Fdpll/2/M2
 		 */
 		divider = 2;
 	}

 	ddr_clk = ddr_clk / divider / core_dpll_params->m2;
 	ddr_clk *= 1000;	/* convert to Hz */
 	debug("ddr_clk %d\n ", ddr_clk);

 	return ddr_clk;
 }

 /*
  * Lock MPU dpll
  *
  * Resulting MPU frequencies:
  * 4430 ES1.0	: 600 MHz
  * 4430 ES2.x	: 792 MHz (OPP Turbo)
  * 4460		: 920 MHz (OPP Turbo) - DCC disabled
  */
 void configure_mpu_dpll(void)
 {
 	const struct dpll_params *params;
 	struct dpll_regs *mpu_dpll_regs;
 	u32 omap_rev;
 	omap_rev = omap_revision();

 	/*
 	 * DCC and clock divider settings for 4460.
 	 * DCC is required, if more than a certain frequency is required.
 	 * For, 4460 > 1GHZ.
 	 *     5430 > 1.4GHZ.
 	 */
 	if ((omap_rev >= OMAP4460_ES1_0) && (omap_rev < OMAP5430_ES1_0)) {
 		mpu_dpll_regs =
 			(struct dpll_regs *)((*prcm)->cm_clkmode_dpll_mpu);
 		bypass_dpll((*prcm)->cm_clkmode_dpll_mpu);
 		clrbits_le32((*prcm)->cm_mpu_mpu_clkctrl,
 			MPU_CLKCTRL_CLKSEL_EMIF_DIV_MODE_MASK);
 		setbits_le32((*prcm)->cm_mpu_mpu_clkctrl,
 			MPU_CLKCTRL_CLKSEL_ABE_DIV_MODE_MASK);
 		clrbits_le32(&mpu_dpll_regs->cm_clksel_dpll,
 			CM_CLKSEL_DCC_EN_MASK);
 	}

 	params = get_mpu_dpll_params(*dplls_data);

 	do_setup_dpll((*prcm)->cm_clkmode_dpll_mpu, params, DPLL_LOCK, "mpu");
 	debug("MPU DPLL locked\n");
 }

 #ifdef CONFIG_USB_EHCI_OMAP
 static void setup_usb_dpll(void)
 {
 	const struct dpll_params *params;
 	u32 sys_clk_khz, sd_div, num, den;

 	sys_clk_khz = get_sys_clk_freq() / 1000;
 	/*
 	 * USB:
 	 * USB dpll is J-type. Need to set DPLL_SD_DIV for jitter correction
 	 * DPLL_SD_DIV = CEILING ([DPLL_MULT/(DPLL_DIV+1)]* CLKINP / 250)
 	 *      - where CLKINP is sys_clk in MHz
 	 * Use CLKINP in KHz and adjust the denominator accordingly so
 	 * that we have enough accuracy and at the same time no overflow
 	 */
 	params = get_usb_dpll_params(*dplls_data);
 	num = params->m * sys_clk_khz;
 	den = (params->n + 1) * 250 * 1000;
 	num += den - 1;
 	sd_div = num / den;
 	clrsetbits_le32((*prcm)->cm_clksel_dpll_usb,
 			CM_CLKSEL_DPLL_DPLL_SD_DIV_MASK,
 			sd_div << CM_CLKSEL_DPLL_DPLL_SD_DIV_SHIFT);

 	/* Now setup the dpll with the regular function */
 	do_setup_dpll((*prcm)->cm_clkmode_dpll_usb, params, DPLL_LOCK, "usb");
 }
 #endif

 static void setup_dplls(void)
 {
 	u32 temp;
 	const struct dpll_params *params;

 	debug("setup_dplls\n");

 	/* CORE dpll */
 	params = get_core_dpll_params(*dplls_data);	/* default - safest */
 	/*
 	 * Do not lock the core DPLL now. Just set it up.
 	 * Core DPLL will be locked after setting up EMIF
 	 * using the FREQ_UPDATE method(freq_update_core())
 	 */
 	if (emif_sdram_type() == EMIF_SDRAM_TYPE_LPDDR2)
 		do_setup_dpll((*prcm)->cm_clkmode_dpll_core, params,
 							DPLL_NO_LOCK, "core");
 	else
 		do_setup_dpll((*prcm)->cm_clkmode_dpll_core, params,
 							DPLL_LOCK, "core");
 	/* Set the ratios for CORE_CLK, L3_CLK, L4_CLK */
 	temp = (CLKSEL_CORE_X2_DIV_1 << CLKSEL_CORE_SHIFT) |
 	    (CLKSEL_L3_CORE_DIV_2 << CLKSEL_L3_SHIFT) |
 	    (CLKSEL_L4_L3_DIV_2 << CLKSEL_L4_SHIFT);
 	writel(temp, (*prcm)->cm_clksel_core);
 	debug("Core DPLL configured\n");

 	/* lock PER dpll */
 	params = get_per_dpll_params(*dplls_data);
 	do_setup_dpll((*prcm)->cm_clkmode_dpll_per,
 			params, DPLL_LOCK, "per");
 	debug("PER DPLL locked\n");

 	/* MPU dpll */
 	configure_mpu_dpll();

 #ifdef CONFIG_USB_EHCI_OMAP
 	setup_usb_dpll();
 #endif
 	params = get_ddr_dpll_params(*dplls_data);
 	do_setup_dpll((*prcm)->cm_clkmode_dpll_ddrphy,
 		      params, DPLL_LOCK, "ddr");
 }

 #ifdef CONFIG_SYS_CLOCKS_ENABLE_ALL
 static void setup_non_essential_dplls(void)
 {
 	u32 abe_ref_clk;
 	const struct dpll_params *params;

 	/* IVA */
 	clrsetbits_le32((*prcm)->cm_bypclk_dpll_iva,
 		CM_BYPCLK_DPLL_IVA_CLKSEL_MASK, DPLL_IVA_CLKSEL_CORE_X2_DIV_2);

 	params = get_iva_dpll_params(*dplls_data);
 	do_setup_dpll((*prcm)->cm_clkmode_dpll_iva, params, DPLL_LOCK, "iva");

 	/* Configure ABE dpll */
 	params = get_abe_dpll_params(*dplls_data);
 #ifdef CONFIG_SYS_OMAP_ABE_SYSCK
 	abe_ref_clk = CM_ABE_PLL_REF_CLKSEL_CLKSEL_SYSCLK;
 #else
 	abe_ref_clk = CM_ABE_PLL_REF_CLKSEL_CLKSEL_32KCLK;
 	/*
 	 * We need to enable some additional options to achieve
 	 * 196.608MHz from 32768 Hz
 	 */
 	setbits_le32((*prcm)->cm_clkmode_dpll_abe,
 			CM_CLKMODE_DPLL_DRIFTGUARD_EN_MASK|
 			CM_CLKMODE_DPLL_RELOCK_RAMP_EN_MASK|
 			CM_CLKMODE_DPLL_LPMODE_EN_MASK|
 			CM_CLKMODE_DPLL_REGM4XEN_MASK);
 	/* Spend 4 REFCLK cycles at each stage */
 	clrsetbits_le32((*prcm)->cm_clkmode_dpll_abe,
 			CM_CLKMODE_DPLL_RAMP_RATE_MASK,
 			1 << CM_CLKMODE_DPLL_RAMP_RATE_SHIFT);
 #endif

 	/* Select the right reference clk */
 	clrsetbits_le32((*prcm)->cm_abe_pll_ref_clksel,
 			CM_ABE_PLL_REF_CLKSEL_CLKSEL_MASK,
 			abe_ref_clk << CM_ABE_PLL_REF_CLKSEL_CLKSEL_SHIFT);
 	/* Lock the dpll */
 	do_setup_dpll((*prcm)->cm_clkmode_dpll_abe, params, DPLL_LOCK, "abe");
 }
 #endif

 u32 get_offset_code(u32 volt_offset, struct pmic_data *pmic)
 {
 	u32 offset_code;

 	volt_offset -= pmic->base_offset;

 	offset_code = (volt_offset + pmic->step - 1) / pmic->step;

 	/*
 	 * Offset codes 1-6 all give the base voltage in Palmas
 	 * Offset code 0 switches OFF the SMPS
 	 */
 	return offset_code + pmic->start_code;
 }

 void do_scale_vcore(u32 vcore_reg, u32 volt_mv, struct pmic_data *pmic)
 {
 	u32 offset_code;
 	u32 offset = volt_mv;
 	int ret = 0;

 	/* See if we can first get the GPIO if needed */
 	if (pmic->gpio_en)
 		ret = gpio_request(pmic->gpio, "PMIC_GPIO");

 	if (ret < 0) {
 		printf("%s: gpio %d request failed %d\n", __func__,
 							pmic->gpio, ret);
 		return;
 	}

 	/* Pull the GPIO low to select SET0 register, while we program SET1 */
 	if (pmic->gpio_en)
 		gpio_direction_output(pmic->gpio, 0);

 	/* convert to uV for better accuracy in the calculations */
 	offset *= 1000;

 	offset_code = get_offset_code(offset, pmic);

 	debug("do_scale_vcore: volt - %d offset_code - 0x%x\n", volt_mv,
 		offset_code);

 	if (omap_vc_bypass_send_value(SMPS_I2C_SLAVE_ADDR,
 				vcore_reg, offset_code))
 		printf("Scaling voltage failed for 0x%x\n", vcore_reg);

 	if (pmic->gpio_en)
 		gpio_direction_output(pmic->gpio, 1);
 }

 /*
  * Setup the voltages for vdd_mpu, vdd_core, and vdd_iva
  * We set the maximum voltages allowed here because Smart-Reflex is not
  * enabled in bootloader. Voltage initialization in the kernel will set
  * these to the nominal values after enabling Smart-Reflex
  */
 void scale_vcores(struct vcores_data const *vcores)
 {
 	omap_vc_init(PRM_VC_I2C_CHANNEL_FREQ_KHZ);

 	do_scale_vcore(vcores->core.addr, vcores->core.value,
 					  vcores->core.pmic);

 	do_scale_vcore(vcores->mpu.addr, vcores->mpu.value,
 					  vcores->mpu.pmic);

 	do_scale_vcore(vcores->mm.addr, vcores->mm.value,
 					  vcores->mm.pmic);

 	 if (emif_sdram_type() == EMIF_SDRAM_TYPE_DDR3) {
 		/* Configure LDO SRAM "magic" bits */
 		writel(2, (*prcm)->prm_sldo_core_setup);
 		writel(2, (*prcm)->prm_sldo_mpu_setup);
 		writel(2, (*prcm)->prm_sldo_mm_setup);
 	}
 }

 static inline void enable_clock_domain(u32 const clkctrl_reg, u32 enable_mode)
 {
 	clrsetbits_le32(clkctrl_reg, CD_CLKCTRL_CLKTRCTRL_MASK,
 			enable_mode << CD_CLKCTRL_CLKTRCTRL_SHIFT);
 	debug("Enable clock domain - %x\n", clkctrl_reg);
 }

 static inline void wait_for_clk_enable(u32 clkctrl_addr)
 {
 	u32 clkctrl, idlest = MODULE_CLKCTRL_IDLEST_DISABLED;
 	u32 bound = LDELAY;

 	while ((idlest == MODULE_CLKCTRL_IDLEST_DISABLED) ||
 		(idlest == MODULE_CLKCTRL_IDLEST_TRANSITIONING)) {

 		clkctrl = readl(clkctrl_addr);
 		idlest = (clkctrl & MODULE_CLKCTRL_IDLEST_MASK) >>
 			 MODULE_CLKCTRL_IDLEST_SHIFT;
 		if (--bound == 0) {
 			printf("Clock enable failed for 0x%x idlest 0x%x\n",
 				clkctrl_addr, clkctrl);
 			return;
 		}
 	}
 }

 static inline void enable_clock_module(u32 const clkctrl_addr, u32 enable_mode,
 				u32 wait_for_enable)
 {
 	clrsetbits_le32(clkctrl_addr, MODULE_CLKCTRL_MODULEMODE_MASK,
 			enable_mode << MODULE_CLKCTRL_MODULEMODE_SHIFT);
 	debug("Enable clock module - %x\n", clkctrl_addr);
 	if (wait_for_enable)
 		wait_for_clk_enable(clkctrl_addr);
 }

 void freq_update_core(void)
 {
 	u32 freq_config1 = 0;
 	const struct dpll_params *core_dpll_params;
 	u32 omap_rev = omap_revision();

 	core_dpll_params = get_core_dpll_params(*dplls_data);
 	/* Put EMIF clock domain in sw wakeup mode */
 	enable_clock_domain((*prcm)->cm_memif_clkstctrl,
 				CD_CLKCTRL_CLKTRCTRL_SW_WKUP);
 	wait_for_clk_enable((*prcm)->cm_memif_emif_1_clkctrl);
 	wait_for_clk_enable((*prcm)->cm_memif_emif_2_clkctrl);

 	freq_config1 = SHADOW_FREQ_CONFIG1_FREQ_UPDATE_MASK |
 	    SHADOW_FREQ_CONFIG1_DLL_RESET_MASK;

 	freq_config1 |= (DPLL_EN_LOCK << SHADOW_FREQ_CONFIG1_DPLL_EN_SHIFT) &
 				SHADOW_FREQ_CONFIG1_DPLL_EN_MASK;

 	freq_config1 |= (core_dpll_params->m2 <<
 			SHADOW_FREQ_CONFIG1_M2_DIV_SHIFT) &
 			SHADOW_FREQ_CONFIG1_M2_DIV_MASK;

 	writel(freq_config1, (*prcm)->cm_shadow_freq_config1);
 	if (!wait_on_value(SHADOW_FREQ_CONFIG1_FREQ_UPDATE_MASK, 0,
 			(u32 *) (*prcm)->cm_shadow_freq_config1, LDELAY)) {
 		puts("FREQ UPDATE procedure failed!!");
 		hang();
 	}

 	/*
 	 * Putting EMIF in HW_AUTO is seen to be causing issues with
 	 * EMIF clocks and the master DLL. Keep EMIF in SW_WKUP
 	 * in OMAP5430 ES1.0 silicon
 	 */
 	if (omap_rev != OMAP5430_ES1_0) {
 		/* Put EMIF clock domain back in hw auto mode */
 		enable_clock_domain((*prcm)->cm_memif_clkstctrl,
 					CD_CLKCTRL_CLKTRCTRL_HW_AUTO);
 		wait_for_clk_enable((*prcm)->cm_memif_emif_1_clkctrl);
 		wait_for_clk_enable((*prcm)->cm_memif_emif_2_clkctrl);
 	}
 }

 void bypass_dpll(u32 const base)
 {
 	do_bypass_dpll(base);
 	wait_for_bypass(base);
 }

 void lock_dpll(u32 const base)
 {
 	do_lock_dpll(base);
 	wait_for_lock(base);
 }

 void setup_clocks_for_console(void)
 {
 	/* Do not add any spl_debug prints in this function */
 	clrsetbits_le32((*prcm)->cm_l4per_clkstctrl, CD_CLKCTRL_CLKTRCTRL_MASK,
 			CD_CLKCTRL_CLKTRCTRL_SW_WKUP <<
 			CD_CLKCTRL_CLKTRCTRL_SHIFT);

 	/* Enable all UARTs - console will be on one of them */
 	clrsetbits_le32((*prcm)->cm_l4per_uart1_clkctrl,
 			MODULE_CLKCTRL_MODULEMODE_MASK,
 			MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
 			MODULE_CLKCTRL_MODULEMODE_SHIFT);

 	clrsetbits_le32((*prcm)->cm_l4per_uart2_clkctrl,
 			MODULE_CLKCTRL_MODULEMODE_MASK,
 			MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
 			MODULE_CLKCTRL_MODULEMODE_SHIFT);

 	clrsetbits_le32((*prcm)->cm_l4per_uart3_clkctrl,
 			MODULE_CLKCTRL_MODULEMODE_MASK,
 			MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
 			MODULE_CLKCTRL_MODULEMODE_SHIFT);

 	clrsetbits_le32((*prcm)->cm_l4per_uart4_clkctrl,
 			MODULE_CLKCTRL_MODULEMODE_MASK,
 			MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
 			MODULE_CLKCTRL_MODULEMODE_SHIFT);

 	clrsetbits_le32((*prcm)->cm_l4per_clkstctrl, CD_CLKCTRL_CLKTRCTRL_MASK,
 			CD_CLKCTRL_CLKTRCTRL_HW_AUTO <<
 			CD_CLKCTRL_CLKTRCTRL_SHIFT);
 }

 void do_enable_clocks(u32 const *clk_domains,
 			    u32 const *clk_modules_hw_auto,
 			    u32 const *clk_modules_explicit_en,
 			    u8 wait_for_enable)
 {
 	u32 i, max = 100;

 	/* Put the clock domains in SW_WKUP mode */
 	for (i = 0; (i < max) && clk_domains[i]; i++) {
 		enable_clock_domain(clk_domains[i],
 				    CD_CLKCTRL_CLKTRCTRL_SW_WKUP);
 	}

 	/* Clock modules that need to be put in HW_AUTO */
 	for (i = 0; (i < max) && clk_modules_hw_auto[i]; i++) {
 		enable_clock_module(clk_modules_hw_auto[i],
 				    MODULE_CLKCTRL_MODULEMODE_HW_AUTO,
 				    wait_for_enable);
 	};

 	/* Clock modules that need to be put in SW_EXPLICIT_EN mode */
 	for (i = 0; (i < max) && clk_modules_explicit_en[i]; i++) {
 		enable_clock_module(clk_modules_explicit_en[i],
 				    MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN,
 				    wait_for_enable);
 	};

 	/* Put the clock domains in HW_AUTO mode now */
 	for (i = 0; (i < max) && clk_domains[i]; i++) {
 		enable_clock_domain(clk_domains[i],
 				    CD_CLKCTRL_CLKTRCTRL_HW_AUTO);
 	}
 }

 void prcm_init(void)
 {
 	switch (omap_hw_init_context()) {
 	case OMAP_INIT_CONTEXT_SPL:
 	case OMAP_INIT_CONTEXT_UBOOT_FROM_NOR:
 	case OMAP_INIT_CONTEXT_UBOOT_AFTER_CH:
 		enable_basic_clocks();
 		scale_vcores(*omap_vcores);
 		setup_dplls();
 #ifdef CONFIG_SYS_CLOCKS_ENABLE_ALL
 		setup_non_essential_dplls();
 		enable_non_essential_clocks();
 #endif
 		setup_warmreset_time();
 		break;
 	default:
 		break;
 	}

 	if (OMAP_INIT_CONTEXT_SPL != omap_hw_init_context())
 		enable_basic_uboot_clocks();
 }
	/*
	*
	* Clock initialization for OMAP4
	*
	* (C) Copyright 2010
	* Texas Instruments, <www.ti.com>
	*
	* Aneesh V <aneesh@ti.com>
	*
	* Based on previous work by:
	* Santosh Shilimkar <santosh.shilimkar@ti.com>
	* Rajendra Nayak <rnayak@ti.com>
	*
	* 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 <asm/omap_common.h>
	#include <asm/gpio.h>
	#include <asm/arch/clocks.h>
	#include <asm/arch/sys_proto.h>
	#include <asm/utils.h>
	#include <asm/omap_gpio.h>
	#include <asm/emif.h>

	#ifndef CONFIG_SPL_BUILD
	/*
	* printing to console doesn't work unless
	* this code is executed from SPL
	*/
	#define printf(fmt, args...)
	#define puts(s)
	#endif

	const u32 sys_clk_array[8] = {
	12000000, /* 12 MHz */
	13000000, /* 13 MHz */
	16800000, /* 16.8 MHz */
	19200000, /* 19.2 MHz */
	26000000, /* 26 MHz */
	27000000, /* 27 MHz */
	38400000, /* 38.4 MHz */
	20000000, /* 20 MHz */
	};

	static inline u32 __get_sys_clk_index(void)
	{
	s8 ind;
	/*
	* For ES1 the ROM code calibration of sys clock is not reliable
	* due to hw issue. So, use hard-coded value. If this value is not
	* correct for any board over-ride this function in board file
	* From ES2.0 onwards you will get this information from
	* CM_SYS_CLKSEL
	*/
	if (omap_revision() == OMAP4430_ES1_0)
	ind = OMAP_SYS_CLK_IND_38_4_MHZ;
	else {
	/* SYS_CLKSEL - 1 to match the dpll param array indices */
	ind = (readl((*prcm)->cm_sys_clksel) &
	CM_SYS_CLKSEL_SYS_CLKSEL_MASK) - 1;
	/*
	* SYS_CLKSEL value for 20MHz is 0. This is introduced newly
	* in DRA7XX socs. SYS_CLKSEL -1 will be greater than
	* NUM_SYS_CLK. So considering the last 3 bits as the index
	* for the dpll param array.
	*/
	ind &= CM_SYS_CLKSEL_SYS_CLKSEL_MASK;
	}
	return ind;
	}

	u32 get_sys_clk_index(void)
	__attribute__ ((weak, alias("__get_sys_clk_index")));

	u32 get_sys_clk_freq(void)
	{
	u8 index = get_sys_clk_index();
	return sys_clk_array[index];
	}

	void setup_post_dividers(u32 const base, const struct dpll_params *params)
	{
	struct dpll_regs const dpll_regs = (struct dpll_regs )base;

	/* Setup post-dividers */
	if (params->m2 >= 0)
	writel(params->m2, &dpll_regs->cm_div_m2_dpll);
	if (params->m3 >= 0)
	writel(params->m3, &dpll_regs->cm_div_m3_dpll);
	if (params->m4_h11 >= 0)
	writel(params->m4_h11, &dpll_regs->cm_div_m4_h11_dpll);
	if (params->m5_h12 >= 0)
	writel(params->m5_h12, &dpll_regs->cm_div_m5_h12_dpll);
	if (params->m6_h13 >= 0)
	writel(params->m6_h13, &dpll_regs->cm_div_m6_h13_dpll);
	if (params->m7_h14 >= 0)
	writel(params->m7_h14, &dpll_regs->cm_div_m7_h14_dpll);
	if (params->h21 >= 0)
	writel(params->h21, &dpll_regs->cm_div_h21_dpll);
	if (params->h22 >= 0)
	writel(params->h22, &dpll_regs->cm_div_h22_dpll);
	if (params->h23 >= 0)
	writel(params->h23, &dpll_regs->cm_div_h23_dpll);
	if (params->h24 >= 0)
	writel(params->h24, &dpll_regs->cm_div_h24_dpll);
	}

	static inline void do_bypass_dpll(u32 const base)
	{
	struct dpll_regs dpll_regs = (struct dpll_regs )base;

	clrsetbits_le32(&dpll_regs->cm_clkmode_dpll,
	CM_CLKMODE_DPLL_DPLL_EN_MASK,
	DPLL_EN_FAST_RELOCK_BYPASS <<
	CM_CLKMODE_DPLL_EN_SHIFT);
	}

	static inline void wait_for_bypass(u32 const base)
	{
	struct dpll_regs const dpll_regs = (struct dpll_regs )base;

	if (!wait_on_value(ST_DPLL_CLK_MASK, 0, &dpll_regs->cm_idlest_dpll,
	LDELAY)) {
	printf("Bypassing DPLL failed %x\n", base);
	}
	}

	static inline void do_lock_dpll(u32 const base)
	{
	struct dpll_regs const dpll_regs = (struct dpll_regs )base;

	clrsetbits_le32(&dpll_regs->cm_clkmode_dpll,
	CM_CLKMODE_DPLL_DPLL_EN_MASK,
	DPLL_EN_LOCK << CM_CLKMODE_DPLL_EN_SHIFT);
	}

	static inline void wait_for_lock(u32 const base)
	{
	struct dpll_regs const dpll_regs = (struct dpll_regs )base;

	if (!wait_on_value(ST_DPLL_CLK_MASK, ST_DPLL_CLK_MASK,
	&dpll_regs->cm_idlest_dpll, LDELAY)) {
	printf("DPLL locking failed for %x\n", base);
	hang();
	}
	}

	inline u32 check_for_lock(u32 const base)
	{
	struct dpll_regs const dpll_regs = (struct dpll_regs )base;
	u32 lock = readl(&dpll_regs->cm_idlest_dpll) & ST_DPLL_CLK_MASK;

	return lock;
	}

	const struct dpll_params get_mpu_dpll_params(struct dplls const dpll_data)
	{
	u32 sysclk_ind = get_sys_clk_index();
	return &dpll_data->mpu[sysclk_ind];
	}

	const struct dpll_params get_core_dpll_params(struct dplls const dpll_data)
	{
	u32 sysclk_ind = get_sys_clk_index();
	return &dpll_data->core[sysclk_ind];
	}

	const struct dpll_params get_per_dpll_params(struct dplls const dpll_data)
	{
	u32 sysclk_ind = get_sys_clk_index();
	return &dpll_data->per[sysclk_ind];
	}

	const struct dpll_params get_iva_dpll_params(struct dplls const dpll_data)
	{
	u32 sysclk_ind = get_sys_clk_index();
	return &dpll_data->iva[sysclk_ind];
	}

	const struct dpll_params get_usb_dpll_params(struct dplls const dpll_data)
	{
	u32 sysclk_ind = get_sys_clk_index();
	return &dpll_data->usb[sysclk_ind];
	}

	const struct dpll_params get_abe_dpll_params(struct dplls const dpll_data)
	{
	#ifdef CONFIG_SYS_OMAP_ABE_SYSCK
	u32 sysclk_ind = get_sys_clk_index();
	return &dpll_data->abe[sysclk_ind];
	#else
	return dpll_data->abe;
	#endif
	}

	static const struct dpll_params *get_ddr_dpll_params
	(struct dplls const *dpll_data)
	{
	u32 sysclk_ind = get_sys_clk_index();

	if (!dpll_data->ddr)
	return NULL;
	return &dpll_data->ddr[sysclk_ind];
	}

	static void do_setup_dpll(u32 const base, const struct dpll_params *params,
	u8 lock, char *dpll)
	{
	u32 temp, M, N;
	struct dpll_regs const dpll_regs = (struct dpll_regs )base;

	if (!params)
	return;

	temp = readl(&dpll_regs->cm_clksel_dpll);

	if (check_for_lock(base)) {
	/*
	* The Dpll has already been locked by rom code using CH.
	* Check if M,N are matching with Ideal nominal opp values.
	* If matches, skip the rest otherwise relock.
	*/
	M = (temp & CM_CLKSEL_DPLL_M_MASK) >> CM_CLKSEL_DPLL_M_SHIFT;
	N = (temp & CM_CLKSEL_DPLL_N_MASK) >> CM_CLKSEL_DPLL_N_SHIFT;
	if ((M != (params->m)) \|\| (N != (params->n))) {
	debug("\n %s Dpll locked, but not for ideal M = %d,"
	"N = %d values, current values are M = %d,"
	"N= %d" , dpll, params->m, params->n,
	M, N);
	} else {
	/* Dpll locked with ideal values for nominal opps. */
	debug("\n %s Dpll already locked with ideal"
	"nominal opp values", dpll);
	goto setup_post_dividers;
	}
	}

	bypass_dpll(base);

	/* Set M & N */
	temp &= ~CM_CLKSEL_DPLL_M_MASK;
	temp \|= (params->m << CM_CLKSEL_DPLL_M_SHIFT) & CM_CLKSEL_DPLL_M_MASK;

	temp &= ~CM_CLKSEL_DPLL_N_MASK;
	temp \|= (params->n << CM_CLKSEL_DPLL_N_SHIFT) & CM_CLKSEL_DPLL_N_MASK;

	writel(temp, &dpll_regs->cm_clksel_dpll);

	/* Lock */
	if (lock)
	do_lock_dpll(base);

	setup_post_dividers:
	setup_post_dividers(base, params);

	/* Wait till the DPLL locks */
	if (lock)
	wait_for_lock(base);
	}

	u32 omap_ddr_clk(void)
	{
	u32 ddr_clk, sys_clk_khz, omap_rev, divider;
	const struct dpll_params *core_dpll_params;

	omap_rev = omap_revision();
	sys_clk_khz = get_sys_clk_freq() / 1000;

	core_dpll_params = get_core_dpll_params(*dplls_data);

	debug("sys_clk %d\n ", sys_clk_khz * 1000);

	/* Find Core DPLL locked frequency first */
	ddr_clk = sys_clk_khz * 2 * core_dpll_params->m /
	(core_dpll_params->n + 1);

	if (omap_rev < OMAP5430_ES1_0) {
	/*
	* DDR frequency is PHY_ROOT_CLK/2
	* PHY_ROOT_CLK = Fdpll/2/M2
	*/
	divider = 4;
	} else {
	/*
	* DDR frequency is PHY_ROOT_CLK
	* PHY_ROOT_CLK = Fdpll/2/M2
	*/
	divider = 2;
	}

	ddr_clk = ddr_clk / divider / core_dpll_params->m2;
	ddr_clk = 1000; / convert to Hz */
	debug("ddr_clk %d\n ", ddr_clk);

	return ddr_clk;
	}

	/*
	* Lock MPU dpll
	*
	* Resulting MPU frequencies:
	* 4430 ES1.0 : 600 MHz
	* 4430 ES2.x : 792 MHz (OPP Turbo)
	* 4460 : 920 MHz (OPP Turbo) - DCC disabled
	*/
	void configure_mpu_dpll(void)
	{
	const struct dpll_params *params;
	struct dpll_regs *mpu_dpll_regs;
	u32 omap_rev;
	omap_rev = omap_revision();

	/*
	* DCC and clock divider settings for 4460.
	* DCC is required, if more than a certain frequency is required.
	* For, 4460 > 1GHZ.
	* 5430 > 1.4GHZ.
	*/
	if ((omap_rev >= OMAP4460_ES1_0) && (omap_rev < OMAP5430_ES1_0)) {
	mpu_dpll_regs =
	(struct dpll_regs )((prcm)->cm_clkmode_dpll_mpu);
	bypass_dpll((*prcm)->cm_clkmode_dpll_mpu);
	clrbits_le32((*prcm)->cm_mpu_mpu_clkctrl,
	MPU_CLKCTRL_CLKSEL_EMIF_DIV_MODE_MASK);
	setbits_le32((*prcm)->cm_mpu_mpu_clkctrl,
	MPU_CLKCTRL_CLKSEL_ABE_DIV_MODE_MASK);
	clrbits_le32(&mpu_dpll_regs->cm_clksel_dpll,
	CM_CLKSEL_DCC_EN_MASK);
	}

	params = get_mpu_dpll_params(*dplls_data);

	do_setup_dpll((*prcm)->cm_clkmode_dpll_mpu, params, DPLL_LOCK, "mpu");
	debug("MPU DPLL locked\n");
	}

	#ifdef CONFIG_USB_EHCI_OMAP
	static void setup_usb_dpll(void)
	{
	const struct dpll_params *params;
	u32 sys_clk_khz, sd_div, num, den;

	sys_clk_khz = get_sys_clk_freq() / 1000;
	/*
	* USB:
	* USB dpll is J-type. Need to set DPLL_SD_DIV for jitter correction
	* DPLL_SD_DIV = CEILING ([DPLL_MULT/(DPLL_DIV+1)]* CLKINP / 250)
	* - where CLKINP is sys_clk in MHz
	* Use CLKINP in KHz and adjust the denominator accordingly so
	* that we have enough accuracy and at the same time no overflow
	*/
	params = get_usb_dpll_params(*dplls_data);
	num = params->m * sys_clk_khz;
	den = (params->n + 1) * 250 * 1000;
	num += den - 1;
	sd_div = num / den;
	clrsetbits_le32((*prcm)->cm_clksel_dpll_usb,
	CM_CLKSEL_DPLL_DPLL_SD_DIV_MASK,
	sd_div << CM_CLKSEL_DPLL_DPLL_SD_DIV_SHIFT);

	/* Now setup the dpll with the regular function */
	do_setup_dpll((*prcm)->cm_clkmode_dpll_usb, params, DPLL_LOCK, "usb");
	}
	#endif

	static void setup_dplls(void)
	{
	u32 temp;
	const struct dpll_params *params;

	debug("setup_dplls\n");

	/* CORE dpll */
	params = get_core_dpll_params(dplls_data); / default - safest */
	/*
	* Do not lock the core DPLL now. Just set it up.
	* Core DPLL will be locked after setting up EMIF
	* using the FREQ_UPDATE method(freq_update_core())
	*/
	if (emif_sdram_type() == EMIF_SDRAM_TYPE_LPDDR2)
	do_setup_dpll((*prcm)->cm_clkmode_dpll_core, params,
	DPLL_NO_LOCK, "core");
	else
	do_setup_dpll((*prcm)->cm_clkmode_dpll_core, params,
	DPLL_LOCK, "core");
	/* Set the ratios for CORE_CLK, L3_CLK, L4_CLK */
	temp = (CLKSEL_CORE_X2_DIV_1 << CLKSEL_CORE_SHIFT) \|
	(CLKSEL_L3_CORE_DIV_2 << CLKSEL_L3_SHIFT) \|
	(CLKSEL_L4_L3_DIV_2 << CLKSEL_L4_SHIFT);
	writel(temp, (*prcm)->cm_clksel_core);
	debug("Core DPLL configured\n");

	/* lock PER dpll */
	params = get_per_dpll_params(*dplls_data);
	do_setup_dpll((*prcm)->cm_clkmode_dpll_per,
	params, DPLL_LOCK, "per");
	debug("PER DPLL locked\n");

	/* MPU dpll */
	configure_mpu_dpll();

	#ifdef CONFIG_USB_EHCI_OMAP
	setup_usb_dpll();
	#endif
	params = get_ddr_dpll_params(*dplls_data);
	do_setup_dpll((*prcm)->cm_clkmode_dpll_ddrphy,
	params, DPLL_LOCK, "ddr");
	}

	#ifdef CONFIG_SYS_CLOCKS_ENABLE_ALL
	static void setup_non_essential_dplls(void)
	{
	u32 abe_ref_clk;
	const struct dpll_params *params;

	/* IVA */
	clrsetbits_le32((*prcm)->cm_bypclk_dpll_iva,
	CM_BYPCLK_DPLL_IVA_CLKSEL_MASK, DPLL_IVA_CLKSEL_CORE_X2_DIV_2);

	params = get_iva_dpll_params(*dplls_data);
	do_setup_dpll((*prcm)->cm_clkmode_dpll_iva, params, DPLL_LOCK, "iva");

	/* Configure ABE dpll */
	params = get_abe_dpll_params(*dplls_data);
	#ifdef CONFIG_SYS_OMAP_ABE_SYSCK
	abe_ref_clk = CM_ABE_PLL_REF_CLKSEL_CLKSEL_SYSCLK;
	#else
	abe_ref_clk = CM_ABE_PLL_REF_CLKSEL_CLKSEL_32KCLK;
	/*
	* We need to enable some additional options to achieve
	* 196.608MHz from 32768 Hz
	*/
	setbits_le32((*prcm)->cm_clkmode_dpll_abe,
	CM_CLKMODE_DPLL_DRIFTGUARD_EN_MASK\|
	CM_CLKMODE_DPLL_RELOCK_RAMP_EN_MASK\|
	CM_CLKMODE_DPLL_LPMODE_EN_MASK\|
	CM_CLKMODE_DPLL_REGM4XEN_MASK);
	/* Spend 4 REFCLK cycles at each stage */
	clrsetbits_le32((*prcm)->cm_clkmode_dpll_abe,
	CM_CLKMODE_DPLL_RAMP_RATE_MASK,
	1 << CM_CLKMODE_DPLL_RAMP_RATE_SHIFT);
	#endif

	/* Select the right reference clk */
	clrsetbits_le32((*prcm)->cm_abe_pll_ref_clksel,
	CM_ABE_PLL_REF_CLKSEL_CLKSEL_MASK,
	abe_ref_clk << CM_ABE_PLL_REF_CLKSEL_CLKSEL_SHIFT);
	/* Lock the dpll */
	do_setup_dpll((*prcm)->cm_clkmode_dpll_abe, params, DPLL_LOCK, "abe");
	}
	#endif

	u32 get_offset_code(u32 volt_offset, struct pmic_data *pmic)
	{
	u32 offset_code;

	volt_offset -= pmic->base_offset;

	offset_code = (volt_offset + pmic->step - 1) / pmic->step;

	/*
	* Offset codes 1-6 all give the base voltage in Palmas
	* Offset code 0 switches OFF the SMPS
	*/
	return offset_code + pmic->start_code;
	}

	void do_scale_vcore(u32 vcore_reg, u32 volt_mv, struct pmic_data *pmic)
	{
	u32 offset_code;
	u32 offset = volt_mv;
	int ret = 0;

	/* See if we can first get the GPIO if needed */
	if (pmic->gpio_en)
	ret = gpio_request(pmic->gpio, "PMIC_GPIO");

	if (ret < 0) {
	printf("%s: gpio %d request failed %d\n", __func__,
	pmic->gpio, ret);
	return;
	}

	/* Pull the GPIO low to select SET0 register, while we program SET1 */
	if (pmic->gpio_en)
	gpio_direction_output(pmic->gpio, 0);

	/* convert to uV for better accuracy in the calculations */
	offset *= 1000;

	offset_code = get_offset_code(offset, pmic);

	debug("do_scale_vcore: volt - %d offset_code - 0x%x\n", volt_mv,
	offset_code);

	if (omap_vc_bypass_send_value(SMPS_I2C_SLAVE_ADDR,
	vcore_reg, offset_code))
	printf("Scaling voltage failed for 0x%x\n", vcore_reg);

	if (pmic->gpio_en)
	gpio_direction_output(pmic->gpio, 1);
	}

	/*
	* Setup the voltages for vdd_mpu, vdd_core, and vdd_iva
	* We set the maximum voltages allowed here because Smart-Reflex is not
	* enabled in bootloader. Voltage initialization in the kernel will set
	* these to the nominal values after enabling Smart-Reflex
	*/
	void scale_vcores(struct vcores_data const *vcores)
	{
	omap_vc_init(PRM_VC_I2C_CHANNEL_FREQ_KHZ);

	do_scale_vcore(vcores->core.addr, vcores->core.value,
	vcores->core.pmic);

	do_scale_vcore(vcores->mpu.addr, vcores->mpu.value,
	vcores->mpu.pmic);

	do_scale_vcore(vcores->mm.addr, vcores->mm.value,
	vcores->mm.pmic);

	if (emif_sdram_type() == EMIF_SDRAM_TYPE_DDR3) {
	/* Configure LDO SRAM "magic" bits */
	writel(2, (*prcm)->prm_sldo_core_setup);
	writel(2, (*prcm)->prm_sldo_mpu_setup);
	writel(2, (*prcm)->prm_sldo_mm_setup);
	}
	}

	static inline void enable_clock_domain(u32 const clkctrl_reg, u32 enable_mode)
	{
	clrsetbits_le32(clkctrl_reg, CD_CLKCTRL_CLKTRCTRL_MASK,
	enable_mode << CD_CLKCTRL_CLKTRCTRL_SHIFT);
	debug("Enable clock domain - %x\n", clkctrl_reg);
	}

	static inline void wait_for_clk_enable(u32 clkctrl_addr)
	{
	u32 clkctrl, idlest = MODULE_CLKCTRL_IDLEST_DISABLED;
	u32 bound = LDELAY;

	while ((idlest == MODULE_CLKCTRL_IDLEST_DISABLED) \|\|
	(idlest == MODULE_CLKCTRL_IDLEST_TRANSITIONING)) {

	clkctrl = readl(clkctrl_addr);
	idlest = (clkctrl & MODULE_CLKCTRL_IDLEST_MASK) >>
	MODULE_CLKCTRL_IDLEST_SHIFT;
	if (--bound == 0) {
	printf("Clock enable failed for 0x%x idlest 0x%x\n",
	clkctrl_addr, clkctrl);
	return;
	}
	}
	}

	static inline void enable_clock_module(u32 const clkctrl_addr, u32 enable_mode,
	u32 wait_for_enable)
	{
	clrsetbits_le32(clkctrl_addr, MODULE_CLKCTRL_MODULEMODE_MASK,
	enable_mode << MODULE_CLKCTRL_MODULEMODE_SHIFT);
	debug("Enable clock module - %x\n", clkctrl_addr);
	if (wait_for_enable)
	wait_for_clk_enable(clkctrl_addr);
	}

	void freq_update_core(void)
	{
	u32 freq_config1 = 0;
	const struct dpll_params *core_dpll_params;
	u32 omap_rev = omap_revision();

	core_dpll_params = get_core_dpll_params(*dplls_data);
	/* Put EMIF clock domain in sw wakeup mode */
	enable_clock_domain((*prcm)->cm_memif_clkstctrl,
	CD_CLKCTRL_CLKTRCTRL_SW_WKUP);
	wait_for_clk_enable((*prcm)->cm_memif_emif_1_clkctrl);
	wait_for_clk_enable((*prcm)->cm_memif_emif_2_clkctrl);

	freq_config1 = SHADOW_FREQ_CONFIG1_FREQ_UPDATE_MASK \|
	SHADOW_FREQ_CONFIG1_DLL_RESET_MASK;

	freq_config1 \|= (DPLL_EN_LOCK << SHADOW_FREQ_CONFIG1_DPLL_EN_SHIFT) &
	SHADOW_FREQ_CONFIG1_DPLL_EN_MASK;

	freq_config1 \|= (core_dpll_params->m2 <<
	SHADOW_FREQ_CONFIG1_M2_DIV_SHIFT) &
	SHADOW_FREQ_CONFIG1_M2_DIV_MASK;

	writel(freq_config1, (*prcm)->cm_shadow_freq_config1);
	if (!wait_on_value(SHADOW_FREQ_CONFIG1_FREQ_UPDATE_MASK, 0,
	(u32 ) (prcm)->cm_shadow_freq_config1, LDELAY)) {
	puts("FREQ UPDATE procedure failed!!");
	hang();
	}

	/*
	* Putting EMIF in HW_AUTO is seen to be causing issues with
	* EMIF clocks and the master DLL. Keep EMIF in SW_WKUP
	* in OMAP5430 ES1.0 silicon
	*/
	if (omap_rev != OMAP5430_ES1_0) {
	/* Put EMIF clock domain back in hw auto mode */
	enable_clock_domain((*prcm)->cm_memif_clkstctrl,
	CD_CLKCTRL_CLKTRCTRL_HW_AUTO);
	wait_for_clk_enable((*prcm)->cm_memif_emif_1_clkctrl);
	wait_for_clk_enable((*prcm)->cm_memif_emif_2_clkctrl);
	}
	}

	void bypass_dpll(u32 const base)
	{
	do_bypass_dpll(base);
	wait_for_bypass(base);
	}

	void lock_dpll(u32 const base)
	{
	do_lock_dpll(base);
	wait_for_lock(base);
	}

	void setup_clocks_for_console(void)
	{
	/* Do not add any spl_debug prints in this function */
	clrsetbits_le32((*prcm)->cm_l4per_clkstctrl, CD_CLKCTRL_CLKTRCTRL_MASK,
	CD_CLKCTRL_CLKTRCTRL_SW_WKUP <<
	CD_CLKCTRL_CLKTRCTRL_SHIFT);

	/* Enable all UARTs - console will be on one of them */
	clrsetbits_le32((*prcm)->cm_l4per_uart1_clkctrl,
	MODULE_CLKCTRL_MODULEMODE_MASK,
	MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
	MODULE_CLKCTRL_MODULEMODE_SHIFT);

	clrsetbits_le32((*prcm)->cm_l4per_uart2_clkctrl,
	MODULE_CLKCTRL_MODULEMODE_MASK,
	MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
	MODULE_CLKCTRL_MODULEMODE_SHIFT);

	clrsetbits_le32((*prcm)->cm_l4per_uart3_clkctrl,
	MODULE_CLKCTRL_MODULEMODE_MASK,
	MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
	MODULE_CLKCTRL_MODULEMODE_SHIFT);

	clrsetbits_le32((*prcm)->cm_l4per_uart4_clkctrl,
	MODULE_CLKCTRL_MODULEMODE_MASK,
	MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN <<
	MODULE_CLKCTRL_MODULEMODE_SHIFT);

	clrsetbits_le32((*prcm)->cm_l4per_clkstctrl, CD_CLKCTRL_CLKTRCTRL_MASK,
	CD_CLKCTRL_CLKTRCTRL_HW_AUTO <<
	CD_CLKCTRL_CLKTRCTRL_SHIFT);
	}

	void do_enable_clocks(u32 const *clk_domains,
	u32 const *clk_modules_hw_auto,
	u32 const *clk_modules_explicit_en,
	u8 wait_for_enable)
	{
	u32 i, max = 100;

	/* Put the clock domains in SW_WKUP mode */
	for (i = 0; (i < max) && clk_domains[i]; i++) {
	enable_clock_domain(clk_domains[i],
	CD_CLKCTRL_CLKTRCTRL_SW_WKUP);
	}

	/* Clock modules that need to be put in HW_AUTO */
	for (i = 0; (i < max) && clk_modules_hw_auto[i]; i++) {
	enable_clock_module(clk_modules_hw_auto[i],
	MODULE_CLKCTRL_MODULEMODE_HW_AUTO,
	wait_for_enable);
	};

	/* Clock modules that need to be put in SW_EXPLICIT_EN mode */
	for (i = 0; (i < max) && clk_modules_explicit_en[i]; i++) {
	enable_clock_module(clk_modules_explicit_en[i],
	MODULE_CLKCTRL_MODULEMODE_SW_EXPLICIT_EN,
	wait_for_enable);
	};

	/* Put the clock domains in HW_AUTO mode now */
	for (i = 0; (i < max) && clk_domains[i]; i++) {
	enable_clock_domain(clk_domains[i],
	CD_CLKCTRL_CLKTRCTRL_HW_AUTO);
	}
	}

	void prcm_init(void)
	{
	switch (omap_hw_init_context()) {
	case OMAP_INIT_CONTEXT_SPL:
	case OMAP_INIT_CONTEXT_UBOOT_FROM_NOR:
	case OMAP_INIT_CONTEXT_UBOOT_AFTER_CH:
	enable_basic_clocks();
	scale_vcores(*omap_vcores);
	setup_dplls();
	#ifdef CONFIG_SYS_CLOCKS_ENABLE_ALL
	setup_non_essential_dplls();
	enable_non_essential_clocks();
	#endif
	setup_warmreset_time();
	break;
	default:
	break;
	}

	if (OMAP_INIT_CONTEXT_SPL != omap_hw_init_context())
	enable_basic_uboot_clocks();
	}