arch/arm/mach-omap2/omap5/hwinit.c - manifest_repos/u-boot - Git at Google

 // SPDX-License-Identifier: GPL-2.0+
 /*
  *
  * Functions for omap5 based boards.
  *
  * (C) Copyright 2011
  * Texas Instruments, <www.ti.com>
  *
  * Author :
  *	Aneesh V	<aneesh@ti.com>
  *	Steve Sakoman	<steve@sakoman.com>
  *	Sricharan	<r.sricharan@ti.com>
  */
 #include <common.h>
 #include <palmas.h>
 #include <asm/armv7.h>
 #include <asm/arch/cpu.h>
 #include <asm/arch/sys_proto.h>
 #include <asm/arch/clock.h>
 #include <linux/sizes.h>
 #include <asm/utils.h>
 #include <asm/arch/gpio.h>
 #include <asm/emif.h>
 #include <asm/omap_common.h>

 u32 *const omap_si_rev = (u32 *)OMAP_SRAM_SCRATCH_OMAP_REV;

 #ifndef CONFIG_DM_GPIO
 static struct gpio_bank gpio_bank_54xx[8] = {
 	{ (void *)OMAP54XX_GPIO1_BASE },
 	{ (void *)OMAP54XX_GPIO2_BASE },
 	{ (void *)OMAP54XX_GPIO3_BASE },
 	{ (void *)OMAP54XX_GPIO4_BASE },
 	{ (void *)OMAP54XX_GPIO5_BASE },
 	{ (void *)OMAP54XX_GPIO6_BASE },
 	{ (void *)OMAP54XX_GPIO7_BASE },
 	{ (void *)OMAP54XX_GPIO8_BASE },
 };

 const struct gpio_bank *const omap_gpio_bank = gpio_bank_54xx;
 #endif

 void do_set_mux32(u32 base, struct pad_conf_entry const *array, int size)
 {
 	int i;
 	struct pad_conf_entry *pad = (struct pad_conf_entry *)array;

 	for (i = 0; i < size; i++, pad++)
 		writel(pad->val, base + pad->offset);
 }

 #ifdef CONFIG_SPL_BUILD
 /* LPDDR2 specific IO settings */
 static void io_settings_lpddr2(void)
 {
 	const struct ctrl_ioregs *ioregs;

 	get_ioregs(&ioregs);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_0);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_1);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_0);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_1);
 	writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_0);
 	writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_1);
 	writel(ioregs->ctrl_ddrio_0, (*ctrl)->control_ddrio_0);
 	writel(ioregs->ctrl_ddrio_1, (*ctrl)->control_ddrio_1);
 	writel(ioregs->ctrl_ddrio_2, (*ctrl)->control_ddrio_2);
 }

 /* DDR3 specific IO settings */
 static void io_settings_ddr3(void)
 {
 	u32 io_settings = 0;
 	const struct ctrl_ioregs *ioregs;

 	get_ioregs(&ioregs);
 	writel(ioregs->ctrl_ddr3ch, (*ctrl)->control_ddr3ch1_0);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_0);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_1);

 	writel(ioregs->ctrl_ddr3ch, (*ctrl)->control_ddr3ch2_0);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_0);
 	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_1);

 	writel(ioregs->ctrl_ddrio_0, (*ctrl)->control_ddrio_0);
 	writel(ioregs->ctrl_ddrio_1, (*ctrl)->control_ddrio_1);

 	if (!is_dra7xx()) {
 		writel(ioregs->ctrl_ddrio_2, (*ctrl)->control_ddrio_2);
 		writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_1);
 	}

 	/* omap5432 does not use lpddr2 */
 	writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_0);

 	writel(ioregs->ctrl_emif_sdram_config_ext,
 	       (*ctrl)->control_emif1_sdram_config_ext);
 	if (!is_dra72x())
 		writel(ioregs->ctrl_emif_sdram_config_ext,
 		       (*ctrl)->control_emif2_sdram_config_ext);

 	if (is_omap54xx()) {
 		/* Disable DLL select */
 		io_settings = (readl((*ctrl)->control_port_emif1_sdram_config)
 							& 0xFFEFFFFF);
 		writel(io_settings,
 			(*ctrl)->control_port_emif1_sdram_config);

 		io_settings = (readl((*ctrl)->control_port_emif2_sdram_config)
 							& 0xFFEFFFFF);
 		writel(io_settings,
 			(*ctrl)->control_port_emif2_sdram_config);
 	} else {
 		writel(ioregs->ctrl_ddr_ctrl_ext_0,
 				(*ctrl)->control_ddr_control_ext_0);
 	}
 }

 /*
  * Some tuning of IOs for optimal power and performance
  */
 void do_io_settings(void)
 {
 	u32 io_settings = 0, mask = 0;
 	struct emif_reg_struct *emif = (struct emif_reg_struct *)EMIF1_BASE;

 	/* Impedance settings EMMC, C2C 1,2, hsi2 */
 	mask = (ds_mask << 2) | (ds_mask << 8) |
 		(ds_mask << 16) | (ds_mask << 18);
 	io_settings = readl((*ctrl)->control_smart1io_padconf_0) &
 				(~mask);
 	io_settings |= (ds_60_ohm << 8) | (ds_45_ohm << 16) |
 			(ds_45_ohm << 18) | (ds_60_ohm << 2);
 	writel(io_settings, (*ctrl)->control_smart1io_padconf_0);

 	/* Impedance settings Mcspi2 */
 	mask = (ds_mask << 30);
 	io_settings = readl((*ctrl)->control_smart1io_padconf_1) &
 			(~mask);
 	io_settings |= (ds_60_ohm << 30);
 	writel(io_settings, (*ctrl)->control_smart1io_padconf_1);

 	/* Impedance settings C2C 3,4 */
 	mask = (ds_mask << 14) | (ds_mask << 16);
 	io_settings = readl((*ctrl)->control_smart1io_padconf_2) &
 			(~mask);
 	io_settings |= (ds_45_ohm << 14) | (ds_45_ohm << 16);
 	writel(io_settings, (*ctrl)->control_smart1io_padconf_2);

 	/* Slew rate settings EMMC, C2C 1,2 */
 	mask = (sc_mask << 8) | (sc_mask << 16) | (sc_mask << 18);
 	io_settings = readl((*ctrl)->control_smart2io_padconf_0) &
 			(~mask);
 	io_settings |= (sc_fast << 8) | (sc_na << 16) | (sc_na << 18);
 	writel(io_settings, (*ctrl)->control_smart2io_padconf_0);

 	/* Slew rate settings hsi2, Mcspi2 */
 	mask = (sc_mask << 24) | (sc_mask << 28);
 	io_settings = readl((*ctrl)->control_smart2io_padconf_1) &
 			(~mask);
 	io_settings |= (sc_fast << 28) | (sc_fast << 24);
 	writel(io_settings, (*ctrl)->control_smart2io_padconf_1);

 	/* Slew rate settings C2C 3,4 */
 	mask = (sc_mask << 16) | (sc_mask << 18);
 	io_settings = readl((*ctrl)->control_smart2io_padconf_2) &
 			(~mask);
 	io_settings |= (sc_na << 16) | (sc_na << 18);
 	writel(io_settings, (*ctrl)->control_smart2io_padconf_2);

 	/* impedance and slew rate settings for usb */
 	mask = (usb_i_mask << 29) | (usb_i_mask << 26) | (usb_i_mask << 23) |
 		(usb_i_mask << 20) | (usb_i_mask << 17) | (usb_i_mask << 14);
 	io_settings = readl((*ctrl)->control_smart3io_padconf_1) &
 			(~mask);
 	io_settings |= (ds_60_ohm << 29) | (ds_60_ohm << 26) |
 		       (ds_60_ohm << 23) | (sc_fast << 20) |
 		       (sc_fast << 17) | (sc_fast << 14);
 	writel(io_settings, (*ctrl)->control_smart3io_padconf_1);

 	if (emif_sdram_type(emif->emif_sdram_config) == EMIF_SDRAM_TYPE_LPDDR2)
 		io_settings_lpddr2();
 	else
 		io_settings_ddr3();
 }

 static const struct srcomp_params srcomp_parameters[NUM_SYS_CLKS] = {
 	{0x45, 0x1},	/* 12 MHz   */
 	{-1, -1},	/* 13 MHz   */
 	{0x63, 0x2},	/* 16.8 MHz */
 	{0x57, 0x2},	/* 19.2 MHz */
 	{0x20, 0x1},	/* 26 MHz   */
 	{-1, -1},	/* 27 MHz   */
 	{0x41, 0x3}	/* 38.4 MHz */
 };

 void srcomp_enable(void)
 {
 	u32 srcomp_value, mul_factor, div_factor, clk_val, i;
 	u32 sysclk_ind	= get_sys_clk_index();
 	u32 omap_rev	= omap_revision();

 	if (!is_omap54xx())
 		return;

 	mul_factor = srcomp_parameters[sysclk_ind].multiply_factor;
 	div_factor = srcomp_parameters[sysclk_ind].divide_factor;

 	for (i = 0; i < 4; i++) {
 		srcomp_value = readl((*ctrl)->control_srcomp_north_side + i*4);
 		srcomp_value &=
 			~(MULTIPLY_FACTOR_XS_MASK | DIVIDE_FACTOR_XS_MASK);
 		srcomp_value |= (mul_factor << MULTIPLY_FACTOR_XS_SHIFT) |
 			(div_factor << DIVIDE_FACTOR_XS_SHIFT);
 		writel(srcomp_value, (*ctrl)->control_srcomp_north_side + i*4);
 	}

 	if ((omap_rev == OMAP5430_ES1_0) || (omap_rev == OMAP5432_ES1_0)) {
 		clk_val = readl((*prcm)->cm_coreaon_io_srcomp_clkctrl);
 		clk_val |= OPTFCLKEN_SRCOMP_FCLK_MASK;
 		writel(clk_val, (*prcm)->cm_coreaon_io_srcomp_clkctrl);

 		for (i = 0; i < 4; i++) {
 			srcomp_value =
 				readl((*ctrl)->control_srcomp_north_side + i*4);
 			srcomp_value &= ~PWRDWN_XS_MASK;
 			writel(srcomp_value,
 			       (*ctrl)->control_srcomp_north_side + i*4);

 			while (((readl((*ctrl)->control_srcomp_north_side + i*4)
 				& SRCODE_READ_XS_MASK) >>
 				SRCODE_READ_XS_SHIFT) == 0)
 				;

 			srcomp_value =
 				readl((*ctrl)->control_srcomp_north_side + i*4);
 			srcomp_value &= ~OVERRIDE_XS_MASK;
 			writel(srcomp_value,
 			       (*ctrl)->control_srcomp_north_side + i*4);
 		}
 	} else {
 		srcomp_value = readl((*ctrl)->control_srcomp_east_side_wkup);
 		srcomp_value &= ~(MULTIPLY_FACTOR_XS_MASK |
 				  DIVIDE_FACTOR_XS_MASK);
 		srcomp_value |= (mul_factor << MULTIPLY_FACTOR_XS_SHIFT) |
 				(div_factor << DIVIDE_FACTOR_XS_SHIFT);
 		writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);

 		for (i = 0; i < 4; i++) {
 			srcomp_value =
 				readl((*ctrl)->control_srcomp_north_side + i*4);
 			srcomp_value |= SRCODE_OVERRIDE_SEL_XS_MASK;
 			writel(srcomp_value,
 			       (*ctrl)->control_srcomp_north_side + i*4);

 			srcomp_value =
 				readl((*ctrl)->control_srcomp_north_side + i*4);
 			srcomp_value &= ~OVERRIDE_XS_MASK;
 			writel(srcomp_value,
 			       (*ctrl)->control_srcomp_north_side + i*4);
 		}

 		srcomp_value =
 			readl((*ctrl)->control_srcomp_east_side_wkup);
 		srcomp_value |= SRCODE_OVERRIDE_SEL_XS_MASK;
 		writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);

 		srcomp_value =
 			readl((*ctrl)->control_srcomp_east_side_wkup);
 		srcomp_value &= ~OVERRIDE_XS_MASK;
 		writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);

 		clk_val = readl((*prcm)->cm_coreaon_io_srcomp_clkctrl);
 		clk_val |= OPTFCLKEN_SRCOMP_FCLK_MASK;
 		writel(clk_val, (*prcm)->cm_coreaon_io_srcomp_clkctrl);

 		clk_val = readl((*prcm)->cm_wkupaon_io_srcomp_clkctrl);
 		clk_val |= OPTFCLKEN_SRCOMP_FCLK_MASK;
 		writel(clk_val, (*prcm)->cm_wkupaon_io_srcomp_clkctrl);

 		for (i = 0; i < 4; i++) {
 			while (((readl((*ctrl)->control_srcomp_north_side + i*4)
 				& SRCODE_READ_XS_MASK) >>
 				SRCODE_READ_XS_SHIFT) == 0)
 				;

 			srcomp_value =
 				readl((*ctrl)->control_srcomp_north_side + i*4);
 			srcomp_value &= ~SRCODE_OVERRIDE_SEL_XS_MASK;
 			writel(srcomp_value,
 			       (*ctrl)->control_srcomp_north_side + i*4);
 		}

 		while (((readl((*ctrl)->control_srcomp_east_side_wkup) &
 			SRCODE_READ_XS_MASK) >> SRCODE_READ_XS_SHIFT) == 0)
 			;

 		srcomp_value =
 			readl((*ctrl)->control_srcomp_east_side_wkup);
 		srcomp_value &= ~SRCODE_OVERRIDE_SEL_XS_MASK;
 		writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);
 	}
 }
 #endif

 void config_data_eye_leveling_samples(u32 emif_base)
 {
 	const struct ctrl_ioregs *ioregs;

 	get_ioregs(&ioregs);

 	/*EMIF_SDRAM_CONFIG_EXT-Read data eye leveling no of samples =4*/
 	if (emif_base == EMIF1_BASE)
 		writel(ioregs->ctrl_emif_sdram_config_ext_final,
 		       (*ctrl)->control_emif1_sdram_config_ext);
 	else if (emif_base == EMIF2_BASE)
 		writel(ioregs->ctrl_emif_sdram_config_ext_final,
 		       (*ctrl)->control_emif2_sdram_config_ext);
 }

 void init_cpu_configuration(void)
 {
 	u32 l2actlr;

 	asm volatile("mrc p15, 1, %0, c15, c0, 0" : "=r"(l2actlr));
 	/*
 	 * L2ACTLR: Ensure to enable the following:
 	 * 3: Disable clean/evict push to external
 	 * 4: Disable WriteUnique and WriteLineUnique transactions from master
 	 * 8: Disable DVM/CMO message broadcast
 	 */
 	l2actlr |= 0x118;
 	omap_smc1(OMAP5_SERVICE_L2ACTLR_SET, l2actlr);
 }

 void init_omap_revision(void)
 {
 	/*
 	 * For some of the ES2/ES1 boards ID_CODE is not reliable:
 	 * Also, ES1 and ES2 have different ARM revisions
 	 * So use ARM revision for identification
 	 */
 	unsigned int rev = cortex_rev();

 	switch (readl(CONTROL_ID_CODE)) {
 	case OMAP5430_CONTROL_ID_CODE_ES1_0:
 		*omap_si_rev = OMAP5430_ES1_0;
 		if (rev == MIDR_CORTEX_A15_R2P2)
 			*omap_si_rev = OMAP5430_ES2_0;
 		break;
 	case OMAP5432_CONTROL_ID_CODE_ES1_0:
 		*omap_si_rev = OMAP5432_ES1_0;
 		if (rev == MIDR_CORTEX_A15_R2P2)
 			*omap_si_rev = OMAP5432_ES2_0;
 		break;
 	case OMAP5430_CONTROL_ID_CODE_ES2_0:
 		*omap_si_rev = OMAP5430_ES2_0;
 		break;
 	case OMAP5432_CONTROL_ID_CODE_ES2_0:
 		*omap_si_rev = OMAP5432_ES2_0;
 		break;
 	case DRA762_CONTROL_ID_CODE_ES1_0:
 		*omap_si_rev = DRA762_ES1_0;
 		break;
 	case DRA752_CONTROL_ID_CODE_ES1_0:
 		*omap_si_rev = DRA752_ES1_0;
 		break;
 	case DRA752_CONTROL_ID_CODE_ES1_1:
 		*omap_si_rev = DRA752_ES1_1;
 		break;
 	case DRA752_CONTROL_ID_CODE_ES2_0:
 		*omap_si_rev = DRA752_ES2_0;
 		break;
 	case DRA722_CONTROL_ID_CODE_ES1_0:
 		*omap_si_rev = DRA722_ES1_0;
 		break;
 	case DRA722_CONTROL_ID_CODE_ES2_0:
 		*omap_si_rev = DRA722_ES2_0;
 		break;
 	case DRA722_CONTROL_ID_CODE_ES2_1:
 		*omap_si_rev = DRA722_ES2_1;
 		break;
 	default:
 		*omap_si_rev = OMAP5430_SILICON_ID_INVALID;
 	}
 	init_cpu_configuration();
 }

 void init_package_revision(void)
 {
 	unsigned int die_id[4] = { 0 };
 	u8 package;

 	omap_die_id(die_id);
 	package = (die_id[2] >> 16) & 0x3;

 	if (is_dra76x()) {
 		switch (package) {
 		case DRA762_ABZ_PACKAGE:
 			*omap_si_rev = DRA762_ABZ_ES1_0;
 			break;
 		case DRA762_ACD_PACKAGE:
 		default:
 			*omap_si_rev = DRA762_ACD_ES1_0;
 			break;
 		}
 	}
 }

 void omap_die_id(unsigned int *die_id)
 {
 	die_id[0] = readl((*ctrl)->control_std_fuse_die_id_0);
 	die_id[1] = readl((*ctrl)->control_std_fuse_die_id_1);
 	die_id[2] = readl((*ctrl)->control_std_fuse_die_id_2);
 	die_id[3] = readl((*ctrl)->control_std_fuse_die_id_3);
 }

 void reset_cpu(ulong ignored)
 {
 	u32 omap_rev = omap_revision();

 	/*
 	 * WARM reset is not functional in case of OMAP5430 ES1.0 soc.
 	 * So use cold reset in case instead.
 	 */
 	if (omap_rev == OMAP5430_ES1_0)
 		writel(PRM_RSTCTRL_RESET << 0x1, (*prcm)->prm_rstctrl);
 	else
 		writel(PRM_RSTCTRL_RESET, (*prcm)->prm_rstctrl);
 }

 u32 warm_reset(void)
 {
 	return readl((*prcm)->prm_rstst) & PRM_RSTST_WARM_RESET_MASK;
 }

 void setup_warmreset_time(void)
 {
 	u32 rst_time, rst_val;

 	/*
 	 * MAX value for PRM_RSTTIME[9:0]RSTTIME1 stored is 0x3ff.
 	 * 0x3ff is in the no of FUNC_32K_CLK cycles. Converting cycles
 	 * into microsec and passing the value.
 	 */
 	rst_time = usec_to_32k(CONFIG_OMAP_PLATFORM_RESET_TIME_MAX_USEC)
 		<< RSTTIME1_SHIFT;

 	if (rst_time > RSTTIME1_MASK)
 		rst_time = RSTTIME1_MASK;

 	rst_val = readl((*prcm)->prm_rsttime) & ~RSTTIME1_MASK;
 	rst_val |= rst_time;
 	writel(rst_val, (*prcm)->prm_rsttime);
 }

 void v7_arch_cp15_set_l2aux_ctrl(u32 l2auxctrl, u32 cpu_midr,
 				 u32 cpu_rev_comb, u32 cpu_variant,
 				 u32 cpu_rev)
 {
 	omap_smc1(OMAP5_SERVICE_L2ACTLR_SET, l2auxctrl);
 }

 void v7_arch_cp15_set_acr(u32 acr, u32 cpu_midr, u32 cpu_rev_comb,
 			  u32 cpu_variant, u32 cpu_rev)
 {

 #ifdef CONFIG_ARM_ERRATA_801819
 	/*
 	 * DRA72x processors are uniprocessors and DONOT have
 	 * ACP (Accelerator Coherency Port) hooked to ACE (AXI Coherency
 	 * Extensions) Hence the erratum workaround is not applicable for
 	 * DRA72x processors.
 	 */
 	if (is_dra72x())
 		acr &= ~((0x3 << 23) | (0x3 << 25));
 #endif
 	omap_smc1(OMAP5_SERVICE_ACR_SET, acr);
 }

 #if defined(CONFIG_PALMAS_POWER)
 __weak void board_mmc_poweron_ldo(uint voltage)
 {
 	palmas_mmc1_poweron_ldo(LDO1_VOLTAGE, LDO1_CTRL, voltage);
 }

 void vmmc_pbias_config(uint voltage)
 {
 	u32 value = 0;

 	value = readl((*ctrl)->control_pbias);
 	value &= ~SDCARD_PWRDNZ;
 	writel(value, (*ctrl)->control_pbias);
 	udelay(10); /* wait 10 us */
 	value &= ~SDCARD_BIAS_PWRDNZ;
 	writel(value, (*ctrl)->control_pbias);

 	board_mmc_poweron_ldo(voltage);

 	value = readl((*ctrl)->control_pbias);
 	value |= SDCARD_BIAS_PWRDNZ;
 	writel(value, (*ctrl)->control_pbias);
 	udelay(150); /* wait 150 us */
 	value |= SDCARD_PWRDNZ;
 	writel(value, (*ctrl)->control_pbias);
 	udelay(150); /* wait 150 us */
 }
 #endif
	// SPDX-License-Identifier: GPL-2.0+
	/*
	*
	* Functions for omap5 based boards.
	*
	* (C) Copyright 2011
	* Texas Instruments, <www.ti.com>
	*
	* Author :
	* Aneesh V <aneesh@ti.com>
	* Steve Sakoman <steve@sakoman.com>
	* Sricharan <r.sricharan@ti.com>
	*/
	#include <common.h>
	#include <palmas.h>
	#include <asm/armv7.h>
	#include <asm/arch/cpu.h>
	#include <asm/arch/sys_proto.h>
	#include <asm/arch/clock.h>
	#include <linux/sizes.h>
	#include <asm/utils.h>
	#include <asm/arch/gpio.h>
	#include <asm/emif.h>
	#include <asm/omap_common.h>

	u32 const omap_si_rev = (u32 )OMAP_SRAM_SCRATCH_OMAP_REV;

	#ifndef CONFIG_DM_GPIO
	static struct gpio_bank gpio_bank_54xx[8] = {
	{ (void *)OMAP54XX_GPIO1_BASE },
	{ (void *)OMAP54XX_GPIO2_BASE },
	{ (void *)OMAP54XX_GPIO3_BASE },
	{ (void *)OMAP54XX_GPIO4_BASE },
	{ (void *)OMAP54XX_GPIO5_BASE },
	{ (void *)OMAP54XX_GPIO6_BASE },
	{ (void *)OMAP54XX_GPIO7_BASE },
	{ (void *)OMAP54XX_GPIO8_BASE },
	};

	const struct gpio_bank *const omap_gpio_bank = gpio_bank_54xx;
	#endif

	void do_set_mux32(u32 base, struct pad_conf_entry const *array, int size)
	{
	int i;
	struct pad_conf_entry pad = (struct pad_conf_entry )array;

	for (i = 0; i < size; i++, pad++)
	writel(pad->val, base + pad->offset);
	}

	#ifdef CONFIG_SPL_BUILD
	/* LPDDR2 specific IO settings */
	static void io_settings_lpddr2(void)
	{
	const struct ctrl_ioregs *ioregs;

	get_ioregs(&ioregs);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_0);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_1);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_0);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_1);
	writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_0);
	writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_1);
	writel(ioregs->ctrl_ddrio_0, (*ctrl)->control_ddrio_0);
	writel(ioregs->ctrl_ddrio_1, (*ctrl)->control_ddrio_1);
	writel(ioregs->ctrl_ddrio_2, (*ctrl)->control_ddrio_2);
	}

	/* DDR3 specific IO settings */
	static void io_settings_ddr3(void)
	{
	u32 io_settings = 0;
	const struct ctrl_ioregs *ioregs;

	get_ioregs(&ioregs);
	writel(ioregs->ctrl_ddr3ch, (*ctrl)->control_ddr3ch1_0);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_0);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch1_1);

	writel(ioregs->ctrl_ddr3ch, (*ctrl)->control_ddr3ch2_0);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_0);
	writel(ioregs->ctrl_ddrch, (*ctrl)->control_ddrch2_1);

	writel(ioregs->ctrl_ddrio_0, (*ctrl)->control_ddrio_0);
	writel(ioregs->ctrl_ddrio_1, (*ctrl)->control_ddrio_1);

	if (!is_dra7xx()) {
	writel(ioregs->ctrl_ddrio_2, (*ctrl)->control_ddrio_2);
	writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_1);
	}

	/* omap5432 does not use lpddr2 */
	writel(ioregs->ctrl_lpddr2ch, (*ctrl)->control_lpddr2ch1_0);

	writel(ioregs->ctrl_emif_sdram_config_ext,
	(*ctrl)->control_emif1_sdram_config_ext);
	if (!is_dra72x())
	writel(ioregs->ctrl_emif_sdram_config_ext,
	(*ctrl)->control_emif2_sdram_config_ext);

	if (is_omap54xx()) {
	/* Disable DLL select */
	io_settings = (readl((*ctrl)->control_port_emif1_sdram_config)
	& 0xFFEFFFFF);
	writel(io_settings,
	(*ctrl)->control_port_emif1_sdram_config);

	io_settings = (readl((*ctrl)->control_port_emif2_sdram_config)
	& 0xFFEFFFFF);
	writel(io_settings,
	(*ctrl)->control_port_emif2_sdram_config);
	} else {
	writel(ioregs->ctrl_ddr_ctrl_ext_0,
	(*ctrl)->control_ddr_control_ext_0);
	}
	}

	/*
	* Some tuning of IOs for optimal power and performance
	*/
	void do_io_settings(void)
	{
	u32 io_settings = 0, mask = 0;
	struct emif_reg_struct emif = (struct emif_reg_struct )EMIF1_BASE;

	/* Impedance settings EMMC, C2C 1,2, hsi2 */
	mask = (ds_mask << 2) \| (ds_mask << 8) \|
	(ds_mask << 16) \| (ds_mask << 18);
	io_settings = readl((*ctrl)->control_smart1io_padconf_0) &
	(~mask);
	io_settings \|= (ds_60_ohm << 8) \| (ds_45_ohm << 16) \|
	(ds_45_ohm << 18) \| (ds_60_ohm << 2);
	writel(io_settings, (*ctrl)->control_smart1io_padconf_0);

	/* Impedance settings Mcspi2 */
	mask = (ds_mask << 30);
	io_settings = readl((*ctrl)->control_smart1io_padconf_1) &
	(~mask);
	io_settings \|= (ds_60_ohm << 30);
	writel(io_settings, (*ctrl)->control_smart1io_padconf_1);

	/* Impedance settings C2C 3,4 */
	mask = (ds_mask << 14) \| (ds_mask << 16);
	io_settings = readl((*ctrl)->control_smart1io_padconf_2) &
	(~mask);
	io_settings \|= (ds_45_ohm << 14) \| (ds_45_ohm << 16);
	writel(io_settings, (*ctrl)->control_smart1io_padconf_2);

	/* Slew rate settings EMMC, C2C 1,2 */
	mask = (sc_mask << 8) \| (sc_mask << 16) \| (sc_mask << 18);
	io_settings = readl((*ctrl)->control_smart2io_padconf_0) &
	(~mask);
	io_settings \|= (sc_fast << 8) \| (sc_na << 16) \| (sc_na << 18);
	writel(io_settings, (*ctrl)->control_smart2io_padconf_0);

	/* Slew rate settings hsi2, Mcspi2 */
	mask = (sc_mask << 24) \| (sc_mask << 28);
	io_settings = readl((*ctrl)->control_smart2io_padconf_1) &
	(~mask);
	io_settings \|= (sc_fast << 28) \| (sc_fast << 24);
	writel(io_settings, (*ctrl)->control_smart2io_padconf_1);

	/* Slew rate settings C2C 3,4 */
	mask = (sc_mask << 16) \| (sc_mask << 18);
	io_settings = readl((*ctrl)->control_smart2io_padconf_2) &
	(~mask);
	io_settings \|= (sc_na << 16) \| (sc_na << 18);
	writel(io_settings, (*ctrl)->control_smart2io_padconf_2);

	/* impedance and slew rate settings for usb */
	mask = (usb_i_mask << 29) \| (usb_i_mask << 26) \| (usb_i_mask << 23) \|
	(usb_i_mask << 20) \| (usb_i_mask << 17) \| (usb_i_mask << 14);
	io_settings = readl((*ctrl)->control_smart3io_padconf_1) &
	(~mask);
	io_settings \|= (ds_60_ohm << 29) \| (ds_60_ohm << 26) \|
	(ds_60_ohm << 23) \| (sc_fast << 20) \|
	(sc_fast << 17) \| (sc_fast << 14);
	writel(io_settings, (*ctrl)->control_smart3io_padconf_1);

	if (emif_sdram_type(emif->emif_sdram_config) == EMIF_SDRAM_TYPE_LPDDR2)
	io_settings_lpddr2();
	else
	io_settings_ddr3();
	}

	static const struct srcomp_params srcomp_parameters[NUM_SYS_CLKS] = {
	{0x45, 0x1}, /* 12 MHz */
	{-1, -1}, /* 13 MHz */
	{0x63, 0x2}, /* 16.8 MHz */
	{0x57, 0x2}, /* 19.2 MHz */
	{0x20, 0x1}, /* 26 MHz */
	{-1, -1}, /* 27 MHz */
	{0x41, 0x3} /* 38.4 MHz */
	};

	void srcomp_enable(void)
	{
	u32 srcomp_value, mul_factor, div_factor, clk_val, i;
	u32 sysclk_ind = get_sys_clk_index();
	u32 omap_rev = omap_revision();

	if (!is_omap54xx())
	return;

	mul_factor = srcomp_parameters[sysclk_ind].multiply_factor;
	div_factor = srcomp_parameters[sysclk_ind].divide_factor;

	for (i = 0; i < 4; i++) {
	srcomp_value = readl((ctrl)->control_srcomp_north_side + i4);
	srcomp_value &=
	~(MULTIPLY_FACTOR_XS_MASK \| DIVIDE_FACTOR_XS_MASK);
	srcomp_value \|= (mul_factor << MULTIPLY_FACTOR_XS_SHIFT) \|
	(div_factor << DIVIDE_FACTOR_XS_SHIFT);
	writel(srcomp_value, (ctrl)->control_srcomp_north_side + i4);
	}

	if ((omap_rev == OMAP5430_ES1_0) \|\| (omap_rev == OMAP5432_ES1_0)) {
	clk_val = readl((*prcm)->cm_coreaon_io_srcomp_clkctrl);
	clk_val \|= OPTFCLKEN_SRCOMP_FCLK_MASK;
	writel(clk_val, (*prcm)->cm_coreaon_io_srcomp_clkctrl);

	for (i = 0; i < 4; i++) {
	srcomp_value =
	readl((ctrl)->control_srcomp_north_side + i4);
	srcomp_value &= ~PWRDWN_XS_MASK;
	writel(srcomp_value,
	(ctrl)->control_srcomp_north_side + i4);

	while (((readl((ctrl)->control_srcomp_north_side + i4)
	& SRCODE_READ_XS_MASK) >>
	SRCODE_READ_XS_SHIFT) == 0)
	;

	srcomp_value =
	readl((ctrl)->control_srcomp_north_side + i4);
	srcomp_value &= ~OVERRIDE_XS_MASK;
	writel(srcomp_value,
	(ctrl)->control_srcomp_north_side + i4);
	}
	} else {
	srcomp_value = readl((*ctrl)->control_srcomp_east_side_wkup);
	srcomp_value &= ~(MULTIPLY_FACTOR_XS_MASK \|
	DIVIDE_FACTOR_XS_MASK);
	srcomp_value \|= (mul_factor << MULTIPLY_FACTOR_XS_SHIFT) \|
	(div_factor << DIVIDE_FACTOR_XS_SHIFT);
	writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);

	for (i = 0; i < 4; i++) {
	srcomp_value =
	readl((ctrl)->control_srcomp_north_side + i4);
	srcomp_value \|= SRCODE_OVERRIDE_SEL_XS_MASK;
	writel(srcomp_value,
	(ctrl)->control_srcomp_north_side + i4);

	srcomp_value =
	readl((ctrl)->control_srcomp_north_side + i4);
	srcomp_value &= ~OVERRIDE_XS_MASK;
	writel(srcomp_value,
	(ctrl)->control_srcomp_north_side + i4);
	}

	srcomp_value =
	readl((*ctrl)->control_srcomp_east_side_wkup);
	srcomp_value \|= SRCODE_OVERRIDE_SEL_XS_MASK;
	writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);

	srcomp_value =
	readl((*ctrl)->control_srcomp_east_side_wkup);
	srcomp_value &= ~OVERRIDE_XS_MASK;
	writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);

	clk_val = readl((*prcm)->cm_coreaon_io_srcomp_clkctrl);
	clk_val \|= OPTFCLKEN_SRCOMP_FCLK_MASK;
	writel(clk_val, (*prcm)->cm_coreaon_io_srcomp_clkctrl);

	clk_val = readl((*prcm)->cm_wkupaon_io_srcomp_clkctrl);
	clk_val \|= OPTFCLKEN_SRCOMP_FCLK_MASK;
	writel(clk_val, (*prcm)->cm_wkupaon_io_srcomp_clkctrl);

	for (i = 0; i < 4; i++) {
	while (((readl((ctrl)->control_srcomp_north_side + i4)
	& SRCODE_READ_XS_MASK) >>
	SRCODE_READ_XS_SHIFT) == 0)
	;

	srcomp_value =
	readl((ctrl)->control_srcomp_north_side + i4);
	srcomp_value &= ~SRCODE_OVERRIDE_SEL_XS_MASK;
	writel(srcomp_value,
	(ctrl)->control_srcomp_north_side + i4);
	}

	while (((readl((*ctrl)->control_srcomp_east_side_wkup) &
	SRCODE_READ_XS_MASK) >> SRCODE_READ_XS_SHIFT) == 0)
	;

	srcomp_value =
	readl((*ctrl)->control_srcomp_east_side_wkup);
	srcomp_value &= ~SRCODE_OVERRIDE_SEL_XS_MASK;
	writel(srcomp_value, (*ctrl)->control_srcomp_east_side_wkup);
	}
	}
	#endif

	void config_data_eye_leveling_samples(u32 emif_base)
	{
	const struct ctrl_ioregs *ioregs;

	get_ioregs(&ioregs);

	/EMIF_SDRAM_CONFIG_EXT-Read data eye leveling no of samples =4/
	if (emif_base == EMIF1_BASE)
	writel(ioregs->ctrl_emif_sdram_config_ext_final,
	(*ctrl)->control_emif1_sdram_config_ext);
	else if (emif_base == EMIF2_BASE)
	writel(ioregs->ctrl_emif_sdram_config_ext_final,
	(*ctrl)->control_emif2_sdram_config_ext);
	}

	void init_cpu_configuration(void)
	{
	u32 l2actlr;

	asm volatile("mrc p15, 1, %0, c15, c0, 0" : "=r"(l2actlr));
	/*
	* L2ACTLR: Ensure to enable the following:
	* 3: Disable clean/evict push to external
	* 4: Disable WriteUnique and WriteLineUnique transactions from master
	* 8: Disable DVM/CMO message broadcast
	*/
	l2actlr \|= 0x118;
	omap_smc1(OMAP5_SERVICE_L2ACTLR_SET, l2actlr);
	}

	void init_omap_revision(void)
	{
	/*
	* For some of the ES2/ES1 boards ID_CODE is not reliable:
	* Also, ES1 and ES2 have different ARM revisions
	* So use ARM revision for identification
	*/
	unsigned int rev = cortex_rev();

	switch (readl(CONTROL_ID_CODE)) {
	case OMAP5430_CONTROL_ID_CODE_ES1_0:
	*omap_si_rev = OMAP5430_ES1_0;
	if (rev == MIDR_CORTEX_A15_R2P2)
	*omap_si_rev = OMAP5430_ES2_0;
	break;
	case OMAP5432_CONTROL_ID_CODE_ES1_0:
	*omap_si_rev = OMAP5432_ES1_0;
	if (rev == MIDR_CORTEX_A15_R2P2)
	*omap_si_rev = OMAP5432_ES2_0;
	break;
	case OMAP5430_CONTROL_ID_CODE_ES2_0:
	*omap_si_rev = OMAP5430_ES2_0;
	break;
	case OMAP5432_CONTROL_ID_CODE_ES2_0:
	*omap_si_rev = OMAP5432_ES2_0;
	break;
	case DRA762_CONTROL_ID_CODE_ES1_0:
	*omap_si_rev = DRA762_ES1_0;
	break;
	case DRA752_CONTROL_ID_CODE_ES1_0:
	*omap_si_rev = DRA752_ES1_0;
	break;
	case DRA752_CONTROL_ID_CODE_ES1_1:
	*omap_si_rev = DRA752_ES1_1;
	break;
	case DRA752_CONTROL_ID_CODE_ES2_0:
	*omap_si_rev = DRA752_ES2_0;
	break;
	case DRA722_CONTROL_ID_CODE_ES1_0:
	*omap_si_rev = DRA722_ES1_0;
	break;
	case DRA722_CONTROL_ID_CODE_ES2_0:
	*omap_si_rev = DRA722_ES2_0;
	break;
	case DRA722_CONTROL_ID_CODE_ES2_1:
	*omap_si_rev = DRA722_ES2_1;
	break;
	default:
	*omap_si_rev = OMAP5430_SILICON_ID_INVALID;
	}
	init_cpu_configuration();
	}

	void init_package_revision(void)
	{
	unsigned int die_id[4] = { 0 };
	u8 package;

	omap_die_id(die_id);
	package = (die_id[2] >> 16) & 0x3;

	if (is_dra76x()) {
	switch (package) {
	case DRA762_ABZ_PACKAGE:
	*omap_si_rev = DRA762_ABZ_ES1_0;
	break;
	case DRA762_ACD_PACKAGE:
	default:
	*omap_si_rev = DRA762_ACD_ES1_0;
	break;
	}
	}
	}

	void omap_die_id(unsigned int *die_id)
	{
	die_id[0] = readl((*ctrl)->control_std_fuse_die_id_0);
	die_id[1] = readl((*ctrl)->control_std_fuse_die_id_1);
	die_id[2] = readl((*ctrl)->control_std_fuse_die_id_2);
	die_id[3] = readl((*ctrl)->control_std_fuse_die_id_3);
	}

	void reset_cpu(ulong ignored)
	{
	u32 omap_rev = omap_revision();

	/*
	* WARM reset is not functional in case of OMAP5430 ES1.0 soc.
	* So use cold reset in case instead.
	*/
	if (omap_rev == OMAP5430_ES1_0)
	writel(PRM_RSTCTRL_RESET << 0x1, (*prcm)->prm_rstctrl);
	else
	writel(PRM_RSTCTRL_RESET, (*prcm)->prm_rstctrl);
	}

	u32 warm_reset(void)
	{
	return readl((*prcm)->prm_rstst) & PRM_RSTST_WARM_RESET_MASK;
	}

	void setup_warmreset_time(void)
	{
	u32 rst_time, rst_val;

	/*
	* MAX value for PRM_RSTTIME[9:0]RSTTIME1 stored is 0x3ff.
	* 0x3ff is in the no of FUNC_32K_CLK cycles. Converting cycles
	* into microsec and passing the value.
	*/
	rst_time = usec_to_32k(CONFIG_OMAP_PLATFORM_RESET_TIME_MAX_USEC)
	<< RSTTIME1_SHIFT;

	if (rst_time > RSTTIME1_MASK)
	rst_time = RSTTIME1_MASK;

	rst_val = readl((*prcm)->prm_rsttime) & ~RSTTIME1_MASK;
	rst_val \|= rst_time;
	writel(rst_val, (*prcm)->prm_rsttime);
	}

	void v7_arch_cp15_set_l2aux_ctrl(u32 l2auxctrl, u32 cpu_midr,
	u32 cpu_rev_comb, u32 cpu_variant,
	u32 cpu_rev)
	{
	omap_smc1(OMAP5_SERVICE_L2ACTLR_SET, l2auxctrl);
	}

	void v7_arch_cp15_set_acr(u32 acr, u32 cpu_midr, u32 cpu_rev_comb,
	u32 cpu_variant, u32 cpu_rev)
	{

	#ifdef CONFIG_ARM_ERRATA_801819
	/*
	* DRA72x processors are uniprocessors and DONOT have
	* ACP (Accelerator Coherency Port) hooked to ACE (AXI Coherency
	* Extensions) Hence the erratum workaround is not applicable for
	* DRA72x processors.
	*/
	if (is_dra72x())
	acr &= ~((0x3 << 23) \| (0x3 << 25));
	#endif
	omap_smc1(OMAP5_SERVICE_ACR_SET, acr);
	}

	#if defined(CONFIG_PALMAS_POWER)
	__weak void board_mmc_poweron_ldo(uint voltage)
	{
	palmas_mmc1_poweron_ldo(LDO1_VOLTAGE, LDO1_CTRL, voltage);
	}

	void vmmc_pbias_config(uint voltage)
	{
	u32 value = 0;

	value = readl((*ctrl)->control_pbias);
	value &= ~SDCARD_PWRDNZ;
	writel(value, (*ctrl)->control_pbias);
	udelay(10); /* wait 10 us */
	value &= ~SDCARD_BIAS_PWRDNZ;
	writel(value, (*ctrl)->control_pbias);

	board_mmc_poweron_ldo(voltage);

	value = readl((*ctrl)->control_pbias);
	value \|= SDCARD_BIAS_PWRDNZ;
	writel(value, (*ctrl)->control_pbias);
	udelay(150); /* wait 150 us */
	value \|= SDCARD_PWRDNZ;
	writel(value, (*ctrl)->control_pbias);
	udelay(150); /* wait 150 us */
	}
	#endif