dev/pmic/pm8x41/pm8x41.c - kernel/lk - Gitiles

 /* Copyright (c) 2012-2015, 2017-2018, The Linux Foundation. All rights reserved.

  * Redistribution and use in source and binary forms, with or without
  * modification, are permitted provided that the following conditions are
  * met:
  *   * Redistributions of source code must retain the above copyright
  *     notice, this list of conditions and the following disclaimer.
  *   * Redistributions in binary form must reproduce the above
  *     copyright notice, this list of conditions and the following
  *     disclaimer in the documentation and/or other materials provided
  *     with the distribution.
  *   * Neither the name of The Linux Foundation, nor the names of its
  *     contributors may be used to endorse or promote products derived
  *     from this software without specific prior written permission.
  *
  * THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
  * WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
  * MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
  * ARE DISCLAIMED.  IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
  * BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
  * CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
  * SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
  * BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
  * WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
  * OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
  * IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
  */

 #include <bits.h>
 #include <debug.h>
 #include <reg.h>
 #include <spmi.h>
 #include <string.h>
 #include <pm8x41_hw.h>
 #include <pm8x41.h>
 #include <rpm-ipc.h>
 #include <regulator.h>
 #include <platform/timer.h>
 #include <pm_vib.h>

 #define QPNP_VIB_EN    BIT(7)

 /* Enable LN BB CLK */
 static uint32_t ln_bb_clk[][8] = {
 	{
 		RPM_CLK_BUFFER_A_REQ, LNBB_CLK_ID,
 		KEY_SOFTWARE_ENABLE, 4, GENERIC_DISABLE,
 		RPM_KEY_PIN_CTRL_CLK_BUFFER_ENABLE_KEY, 4, RPM_CLK_BUFFER_PIN_CONTROL_ENABLE_NONE,
 	},
 	{
 		RPM_CLK_BUFFER_A_REQ, LNBB_CLK_ID,
 		KEY_SOFTWARE_ENABLE, 4, GENERIC_ENABLE,
 		RPM_KEY_PIN_CTRL_CLK_BUFFER_ENABLE_KEY, 4, RPM_CLK_BUFFER_PIN_CONTROL_ENABLE_NONE,
 	},
 };

 static uint8_t mpp_slave_id;

 void pmi8994_config_mpp_slave_id(uint8_t slave_id)
 {
 	mpp_slave_id = slave_id;
 }
 /* SPMI helper functions */
 uint8_t pm8x41_reg_read(uint32_t addr)
 {
 	uint8_t val = 0;
 	struct pmic_arb_cmd cmd;
 	struct pmic_arb_param param;

 	cmd.address  = PERIPH_ID(addr);
 	cmd.offset   = REG_OFFSET(addr);
 	cmd.slave_id = SLAVE_ID(addr);
 	cmd.priority = 0;

 	param.buffer = &val;
 	param.size   = 1;

 	pmic_arb_read_cmd(&cmd, &param);

 	return val;
 }

 uint32_t spmi_reg_read(uint32_t slave_id, uint16_t addr, uint8_t *data, uint8_t priority)
 {
 	struct pmic_arb_cmd cmd;
 	struct pmic_arb_param param;

 	cmd.address = PERIPH_ID(addr);
 	cmd.offset = REG_OFFSET(addr);
 	cmd.slave_id = slave_id;

 	cmd.priority = priority;

 	param.buffer = data;
 	param.size   = 1;

 	return pmic_arb_read_cmd(&cmd, &param);
 }

 uint32_t spmi_reg_write(uint32_t slave_id, uint16_t addr, uint8_t *data, uint8_t priority)
 {
 	struct pmic_arb_cmd cmd;
 	struct pmic_arb_param param;

 	cmd.address = PERIPH_ID(addr);
 	cmd.offset = REG_OFFSET(addr);
 	cmd.slave_id = slave_id;

 	cmd.priority = priority;

 	param.buffer = data;
 	param.size   = 1;

 	return pmic_arb_write_cmd(&cmd, &param);
 }

 /* SPMI helper function which takes slave id as the i/p */
 void pm8xxx_reg_write(uint8_t slave_id, uint32_t addr, uint8_t val)
 {
 	struct pmic_arb_cmd cmd;
 	struct pmic_arb_param param;

 	cmd.address = PERIPH_ID(addr);
 	cmd.offset = REG_OFFSET(addr);
 	cmd.slave_id = slave_id;

 	cmd.priority = 0;

 	param.buffer = &val;
 	param.size   = 1;

 	pmic_arb_write_cmd(&cmd, &param);
 }

 void pm8x41_reg_write(uint32_t addr, uint8_t val)
 {
 	struct pmic_arb_cmd cmd;
 	struct pmic_arb_param param;

 	cmd.address  = PERIPH_ID(addr);
 	cmd.offset   = REG_OFFSET(addr);
 	cmd.slave_id = SLAVE_ID(addr);
 	cmd.priority = 0;

 	param.buffer = &val;
 	param.size   = 1;

 	pmic_arb_write_cmd(&cmd, &param);
 }

 /* Exported functions */

 /* Set the boot done flag */
 void pm8x41_set_boot_done()
 {
 	uint8_t val;

 	val  = REG_READ(SMBB_MISC_BOOT_DONE);
 	val |= BIT(BOOT_DONE_BIT);
 	REG_WRITE(SMBB_MISC_BOOT_DONE, val);
 }

 /* Configure GPIO */
 int pm8x41_gpio_config(uint8_t gpio, struct pm8x41_gpio *config)
 {
 	uint8_t  val;
 	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

 	/* Disable the GPIO */
 	val  = REG_READ(gpio_base + GPIO_EN_CTL);
 	val &= ~BIT(PERPH_EN_BIT);
 	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

 	/* Select the mode */
 	val = config->function | (config->direction << 4);
 	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

 	/* Set the right pull */
 	val = config->pull;
 	REG_WRITE(gpio_base + GPIO_DIG_PULL_CTL, val);

 	/* Select the VIN */
 	val = config->vin_sel;
 	REG_WRITE(gpio_base + GPIO_DIG_VIN_CTL, val);

 	if (config->direction == PM_GPIO_DIR_OUT) {
 		/* Set the right dig out control */
 		val = config->out_strength | (config->output_buffer << 4);
 		REG_WRITE(gpio_base + GPIO_DIG_OUT_CTL, val);
 	}

 	/* Output source sel and output invert */
 	val = config->inv_int_pol << 7;
 	REG_WRITE(gpio_base + GPIO_DIG_OUT_SRC_CTL, val);

 	/* Enable the GPIO */
 	val  = REG_READ(gpio_base + GPIO_EN_CTL);
 	val |= BIT(PERPH_EN_BIT);
 	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

 	return 0;
 }

 /* Reads the status of requested gpio */
 int pm8x41_gpio_get(uint8_t gpio, uint8_t *status)
 {
 	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

 	*status = REG_READ(gpio_base + GPIO_STATUS);

 	/* Return the value of the GPIO pin */
 	*status &= BIT(GPIO_STATUS_VAL_BIT);

 	dprintf(SPEW, "GPIO %d status is %d\n", gpio, *status);

 	return 0;
 }

 /* Write the output value of the requested gpio */
 int pm8x41_gpio_set(uint8_t gpio, uint8_t value)
 {
 	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);
 	uint8_t val;

 	/* Set the output value of the gpio */
 	val = REG_READ(gpio_base + GPIO_MODE_CTL);
 	val = (val & ~PM_GPIO_OUTPUT_MASK) | value;
 	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

 	return 0;
 }

 /* Configure PM and PMI GPIO with slave id */
 int pm8x41_gpio_config_sid(uint8_t sid, uint8_t gpio, struct pm8x41_gpio *config)
 {
 	uint8_t  val;
 	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

 	gpio_base &= 0x0ffff;	/* clear sid */
 	gpio_base |= (sid << 16);	/* add sid */

 	dprintf(SPEW, "%s: gpio=%d base=%x\n", __func__, gpio, gpio_base);

 	/* Disable the GPIO */
 	val  = REG_READ(gpio_base + GPIO_EN_CTL);
 	val &= ~BIT(PERPH_EN_BIT);
 	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

 	/* Select the mode */
 	val = config->function | (config->direction << 4);
 	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

 	/* Set the right pull */
 	val = config->pull;
 	REG_WRITE(gpio_base + GPIO_DIG_PULL_CTL, val);

 	/* Select the VIN */
 	val = config->vin_sel;
 	REG_WRITE(gpio_base + GPIO_DIG_VIN_CTL, val);

 	if (config->direction == PM_GPIO_DIR_OUT) {
 		/* Set the right dig out control */
 		val = config->out_strength | (config->output_buffer << 4);
 		REG_WRITE(gpio_base + GPIO_DIG_OUT_CTL, val);
 	}

 	/* Enable the GPIO */
 	val  = REG_READ(gpio_base + GPIO_EN_CTL);
 	val |= BIT(PERPH_EN_BIT);
 	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

 	return 0;
 }

 /* Reads the status of requested gpio */
 int pm8x41_gpio_get_sid(uint8_t sid, uint8_t gpio, uint8_t *status)
 {
 	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

 	gpio_base &= 0x0ffff;	/* clear sid */
 	gpio_base |= (sid << 16);	/* add sid */

 	*status = REG_READ(gpio_base + GPIO_STATUS);

 	/* Return the value of the GPIO pin */
 	*status &= BIT(GPIO_STATUS_VAL_BIT);

 	dprintf(SPEW, "GPIO %d status is %d\n", gpio, *status);

 	return 0;
 }

 /* Write the output value of the requested gpio */
 int pm8x41_gpio_set_sid(uint8_t sid, uint8_t gpio, uint8_t value)
 {
 	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);
 	uint8_t val;

 	gpio_base &= 0x0ffff;	/* clear sid */
 	gpio_base |= (sid << 16);	/* add sid */

 	dprintf(SPEW, "%s: gpio=%d base=%x\n", __func__, gpio, gpio_base);

 	/* Set the output value of the gpio */
 	val = REG_READ(gpio_base + GPIO_MODE_CTL);
 	val = (val & ~PM_GPIO_OUTPUT_MASK) | value;
 	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

 	return 0;
 }

 /* Prepare PON RESIN S2 reset (bite) */
 void pm8x41_resin_s2_reset_enable()
 {
 	uint8_t val;

 	/* disable s2 reset */
 	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, 0x0);

 	/* Delay needed for disable to kick in. */
 	udelay(300);

 	/* configure s1 timer to 0 */
 	REG_WRITE(PON_RESIN_N_RESET_S1_TIMER, 0x0);

 	/* configure s2 timer to 2s */
 	REG_WRITE(PON_RESIN_N_RESET_S2_TIMER, PON_RESIN_N_RESET_S2_TIMER_MAX_VALUE);

 	/* configure reset type */
 	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, S2_RESET_TYPE_WARM);

 	val = REG_READ(PON_RESIN_N_RESET_S2_CTL);

 	/* enable s2 reset */
 	val |= BIT(S2_RESET_EN_BIT);
 	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, val);
 }

 /* Disable PON RESIN S2 reset. (bite)*/
 void pm8x41_resin_s2_reset_disable()
 {
 	/* disable s2 reset */
 	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, 0x0);

 	/* Delay needed for disable to kick in. */
 	udelay(300);
 }

 /* Resin irq status for faulty pmic*/
 uint32_t pm8x41_v2_resin_status()
 {
 	uint8_t rt_sts = 0;

 	/* Enable S2 reset so we can detect the volume down key press */
 	pm8x41_resin_s2_reset_enable();

 	/* Delay before interrupt triggering.
 	 * See PON_DEBOUNCE_CTL reg.
 	 */
 	mdelay(100);

 	rt_sts = REG_READ(PON_INT_RT_STS);

 	/* Must disable S2 reset otherwise PMIC will reset if key
 	 * is held longer than S2 timer.
 	 */
 	pm8x41_resin_s2_reset_disable();

 	return (rt_sts & BIT(RESIN_BARK_INT_BIT));
 }

 /* Resin pin status */
 uint32_t pm8x41_resin_status()
 {
 	uint8_t rt_sts = 0;

 	rt_sts = REG_READ(PON_INT_RT_STS);

 	return (rt_sts & BIT(RESIN_ON_INT_BIT));
 }

 /* Return 1 if power key is pressed */
 uint32_t pm8x41_get_pwrkey_is_pressed()
 {
 	uint8_t pwr_sts = 0;

 	pwr_sts = REG_READ(PON_INT_RT_STS);

 	if (pwr_sts & BIT(KPDPWR_ON_INT_BIT))
 		return 1;
 	else
 		return 0;
 }

 void pmi632_reset_configure(uint8_t reset_type)
 {
 	/* Slave ID of pm8953 and pmi632 */
 	uint8_t slave_id[] = {0, 2};
 	uint8_t i;

 	/* Reset sequence
 	1. Disable the ps hold for pm8953 and pmi632
 	2. set reset type for both pm8953 & pmi632
 	3. Enable ps hold for pm8953 to trigger the reset
 	*/
 	/* disable PS_HOLD_RESET */
 	pm8xxx_reg_write(slave_id[0], PON_PS_HOLD_RESET_CTL2, 0x0);
 	pm8xxx_reg_write(slave_id[1], PON_PS_HOLD_RESET_CTL2, 0x0);

 	/* Delay needed for disable to kick in. */
 	udelay(300);

 	/* configure reset type */
 	for (i = 0; i < ARRAY_SIZE(slave_id); i++)
 		pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL, reset_type);

 	if (reset_type == PON_PSHOLD_WARM_RESET)
 	{
 		/* enable PS_HOLD_RESET */
 		for (i = 0; i < ARRAY_SIZE(slave_id); i++)
 			pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
 	}
 	else
 	{
 			pm8xxx_reg_write(slave_id[0], PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
 	}
 }

 void pm8994_reset_configure(uint8_t reset_type)
 {
 	/* Slave ID of pm8994 and pmi8994 */
 	uint8_t slave_id[] = {0, 2};
 	uint8_t i;

 	/* Reset sequence
 	1. Disable the ps hold for pm8994
 	2. set reset type for both pm8994 & pmi8994
 	3. Enable ps hold for pm8994 to trigger the reset
 	*/
 	/* disable PS_HOLD_RESET */
 	pm8xxx_reg_write(slave_id[0], PON_PS_HOLD_RESET_CTL2, 0x0);
 	pm8xxx_reg_write(slave_id[1], PON_PS_HOLD_RESET_CTL2, 0x0);

 	/* Delay needed for disable to kick in. */
 	udelay(300);

 	/* configure reset type */
 	for (i = 0; i < ARRAY_SIZE(slave_id); i++)
 		pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL, reset_type);

 	/* enable PS_HOLD_RESET */
 	for (i = 0; i < ARRAY_SIZE(slave_id); i++)
 		pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
 }

 void pm8996_reset_configure(uint8_t slave_id, uint8_t reset_type)
 {
 	/* Reset sequence
 	1. Disable the ps hold
 	2. set reset type
 	3. Enable ps hold to trigger the reset
 	*/
 	/* disable PS_HOLD_RESET */
 	pm8xxx_reg_write(slave_id, PON_PS_HOLD_RESET_CTL2, 0x0);

 	/* Delay needed for disable to kick in. */
 	udelay(300);

 	/* configure reset type */
 	pm8xxx_reg_write(slave_id, PON_PS_HOLD_RESET_CTL, reset_type);
 	/* enable PS_HOLD_RESET */
 	pm8xxx_reg_write(slave_id, PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
 }

 void pm8x41_v2_reset_configure(uint8_t reset_type)
 {
 	uint8_t val;

 	/* disable PS_HOLD_RESET */
 	REG_WRITE(PON_PS_HOLD_RESET_CTL, 0x0);

 	/* Delay needed for disable to kick in. */
 	udelay(300);

 	/* configure reset type */
 	REG_WRITE(PON_PS_HOLD_RESET_CTL, reset_type);

 	val = REG_READ(PON_PS_HOLD_RESET_CTL);

 	/* enable PS_HOLD_RESET */
 	val |= BIT(S2_RESET_EN_BIT);
 	REG_WRITE(PON_PS_HOLD_RESET_CTL, val);
 }

 void pm8x41_reset_configure(uint8_t reset_type)
 {
 	/* disable PS_HOLD_RESET */
 	REG_WRITE(PON_PS_HOLD_RESET_CTL2, 0x0);

 	/* Delay needed for disable to kick in. */
 	udelay(300);

 	/* configure reset type */
 	REG_WRITE(PON_PS_HOLD_RESET_CTL, reset_type);

 	/* enable PS_HOLD_RESET */
 	REG_WRITE(PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
 }

 /*
  * LDO set voltage, takes ldo name & voltage in UV as input
  */
 int pm8x41_ldo_set_voltage(struct pm8x41_ldo *ldo, uint32_t voltage)
 {
 	uint32_t range = 0;
 	uint32_t step = 0;
 	uint32_t mult = 0;
 	uint32_t val = 0;
 	uint32_t vmin = 0;

 	if (!ldo)
 	{
 		dprintf(CRITICAL, "LDO pointer is invalid: %p\n", ldo);
 		return 1;
 	}

 	/* Program Normal power mode */
 	val = 0x0;
 	val = (1 << LDO_NORMAL_PWR_BIT);
 	REG_WRITE((ldo->base + LDO_POWER_MODE), val);

 	/*
 	 * Select range, step & vmin based on input voltage & type of LDO
 	 * LDO can operate in low, mid, high power mode
 	 */
 	if (ldo->type == PLDO_TYPE)
 	{
 		if (voltage < PLDO_UV_MIN)
 		{
 			range = 2;
 			step = PLDO_UV_STEP_LOW;
 			vmin = PLDO_UV_VMIN_LOW;
 		}
 		else if (voltage < PDLO_UV_MID)
 		{
 			range = 3;
 			step = PLDO_UV_STEP_MID;
 			vmin = PLDO_UV_VMIN_MID;
 		}
 		else
 		{
 			range = 4;
 			step = PLDO_UV_STEP_HIGH;
 			vmin = PLDO_UV_VMIN_HIGH;
 		}
 	}
 	else
 	{
 		range = 2;
 		step = NLDO_UV_STEP;
 		vmin = NLDO_UV_VMIN_LOW;
 	}

 	mult = (voltage - vmin) / step;

 	/* Set Range in voltage ctrl register */
 	val = 0x0;
 	val = range << LDO_RANGE_SEL_BIT;
 	REG_WRITE((ldo->base + LDO_RANGE_CTRL), val);

 	/* Set multiplier in voltage ctrl register */
 	val = 0x0;
 	val = mult << LDO_VSET_SEL_BIT;
 	REG_WRITE((ldo->base + LDO_STEP_CTRL), val);

 	return 0;
 }

 /*
  * Enable or Disable LDO
  */
 int pm8x41_ldo_control(struct pm8x41_ldo *ldo, uint8_t enable)
 {
 	uint32_t val = 0;

 	if (!ldo)
 	{
 		dprintf(CRITICAL, "LDO pointer is invalid: %p\n", ldo);
 		return 1;
 	}

 	/* Enable LDO */
 	if (enable)
 		val = (1 << LDO_VREG_ENABLE_BIT);
 	else
 		val = (0 << LDO_VREG_ENABLE_BIT);

 	REG_WRITE((ldo->base + LDO_EN_CTL_REG), val);

 	return 0;
 }

 /*
  * lpg channel register write:
  */
 void pm8x41_lpg_write(uint8_t chan, uint8_t off, uint8_t val)
 {
 	uint32_t lpg_base = LPG_N_PERIPHERAL_BASE(chan);

 	REG_WRITE(lpg_base + off, val);
 }

 /*
  * pmi lpg channel register write with slave_id:
  */
 void pm8x41_lpg_write_sid(uint8_t sid, uint8_t chan, uint8_t off, uint8_t val)
 {
 	uint32_t lpg_base = LPG_N_PERIPHERAL_BASE(chan);

 	lpg_base &= 0x0ffff;	/* clear sid */
 	lpg_base |= (sid << 16);	/* add sid */

 	dprintf(SPEW, "%s: lpg=%d base=%x\n", __func__, chan, lpg_base);

 	REG_WRITE(lpg_base + off, val);
 }

 uint8_t pmi8950_get_pmi_subtype()
 {
 	uint8_t subtype;
 	spmi_reg_read((PMI8950_SLAVE_ID >> 16), REVID_REV_ID_SPARE_0, &subtype, 0);
 	return subtype;
 }

 uint8_t pm8x41_get_pmic_rev()
 {
 	return REG_READ(REVID_REVISION4);
 }

 uint8_t pm660_get_pon_reason()
 {
 	return REG_READ(PM660_PON_REASON1);
 }

 uint8_t pm8x41_get_pon_reason()
 {
 	return REG_READ(PON_PON_REASON1);
 }

 uint8_t pm8950_get_pon_reason()
 {
 	uint8_t pon_reason = 0;

 	pon_reason = REG_READ(SMBCHGL_USB_ICL_STS_2|PMI8950_SLAVE_ID);
 	/* check usbin/dcin status on pmi and set the corresponding bits for pon */
 	pon_reason = (pon_reason & (USBIN_ACTIVE_PWR_SRC|DCIN_ACTIVE_PWR_SRC)) << 3 ;
 	pon_reason |= REG_READ(PON_PON_REASON1);

 	return pon_reason;
 }

 uint8_t pmi632_get_pon_reason()
 {
 	uint8_t pon_reason = 0;

 	pon_reason = REG_READ(SCHG_USB_INT_RT_STS|PMI8950_SLAVE_ID);
 	/* Check USBIN status on PMI and set the corresponding bits for pon */
 	pon_reason = (pon_reason & USBIN_PLUGIN_RT_STS);
 	pon_reason |= REG_READ(PON_PON_REASON1);

 	return pon_reason;
 }

 uint8_t pm8x41_get_pon_poff_reason1()
 {
 	return REG_READ(PON_POFF_REASON1);
 }

 uint8_t pm8x41_get_pon_poff_reason2()
 {
 	return REG_READ(PON_POFF_REASON2);
 }

 void pm8x41_enable_mvs(struct pm8x41_mvs *mvs, enum mvs_en_ctl enable)
 {
 	ASSERT(mvs);

 	REG_WRITE(mvs->base + MVS_EN_CTL, enable << MVS_EN_CTL_ENABLE_SHIFT);
 }

 void pm8x41_enable_mpp(struct pm8x41_mpp *mpp, enum mpp_en_ctl enable)
 {
 	ASSERT(mpp);

 	REG_WRITE(((mpp->base + MPP_EN_CTL) + (mpp_slave_id << 16)), enable << MPP_EN_CTL_ENABLE_SHIFT);
 }

 void pm8x41_config_output_mpp(struct pm8x41_mpp *mpp)
 {
 	ASSERT(mpp);

 	REG_WRITE(((mpp->base + MPP_DIG_VIN_CTL) + (mpp_slave_id << 16)), mpp->vin);

 	REG_WRITE(((mpp->base + MPP_MODE_CTL) + (mpp_slave_id << 16)), mpp->mode | (MPP_DIGITAL_OUTPUT << MPP_MODE_CTL_MODE_SHIFT));
 }

 uint8_t pm660_get_is_cold_boot()
 {
 	if (REG_READ(PM660_PON_WARMBOOT_STATUS1)) {
 		dprintf(INFO,"%s: Warm boot\n", __func__);
 		return 0;
 	}
 	return 1;
 }

 uint8_t pm8x41_get_is_cold_boot()
 {
 	if (REG_READ(PON_WARMBOOT_STATUS1) || REG_READ(PON_WARMBOOT_STATUS2)) {
 		dprintf(INFO,"%s: Warm boot\n", __func__);
 		return 0;
 	}
 	dprintf(INFO,"%s: cold boot\n", __func__);
 	return 1;
 }

 /* api to control lnbb clock */
 void pm8x41_lnbb_clock_ctrl(uint8_t enable)
 {
 	if (enable)
 	{
 		rpm_clk_enable(&ln_bb_clk[GENERIC_ENABLE][0], 24);
 	}
 	else
 	{
 		rpm_clk_enable(&ln_bb_clk[GENERIC_DISABLE][0], 24);
 	}
 }

 /* api to control diff clock */
 void pm8x41_diff_clock_ctrl(uint8_t enable)
 {
 	uint8_t reg;

 	reg = REG_READ(DIFF_CLK1_EN_CTL);

 	if (enable)
 	{
 		reg |= BIT(DIFF_CLK1_EN_BIT);
 	}
 	else
 	{
 		reg &= ~BIT(DIFF_CLK1_EN_BIT);
 	}

 	REG_WRITE(DIFF_CLK1_EN_CTL, reg);
 }

 void pm8x41_clear_pmic_watchdog(void)
 {
 	pm8x41_reg_write(PMIC_WD_RESET_S2_CTL2, 0x0);
 }

 /* API to check for borken battery */
 int pm8xxx_is_battery_broken()
 {
 	uint8_t trkl_default = 0;
 	uint8_t vbat_det_default = 0;
 	int batt_is_broken = 0;

 	/* Store original trickle charging current setting */
 	trkl_default = pm8x41_reg_read(PM8XXX_IBAT_ATC_A);
 	/* Store original VBAT_DET_LO setting */
 	vbat_det_default = pm8x41_reg_read(PM8XXX_VBAT_DET);

 	/*Set trickle charge current to 50mA (IBAT_ATC_A = 0x00) */
 	pm8x41_reg_write(PM8XXX_IBAT_ATC_A, 0x00);
 	/* Set VBAT_DET_LO to 4.3V so that VBAT_DET_HI = 4.52V (VBAT_DET_LO = 0x35) */
 	pm8x41_reg_write(PM8XXX_VBAT_DET, VBAT_DET_LO_4_30V);
 	/* Unlock SMBBP Secured Register */
 	pm8x41_reg_write(PM8XXX_SEC_ACCESS, SEC_ACCESS);
 	/* Disable VTRKL_FAULT comp (SMBBP_CHGR_COMP_OVR0 = 0x08) */
 	pm8x41_reg_write(PM8XXX_COMP_OVR0, OVR0_DIS_VTRKL_FAULT);
 	/* Disable VCP (SMBB_BAT_IF_VCP = 0x00) */
 	pm8x41_reg_write(PM8XXX_VCP, 0x00);
 	/* Unlock SMBBP Secured Register */
 	pm8x41_reg_write(PM8XXX_SEC_ACCESS, SEC_ACCESS);
 	/* Force trickle charging (SMBB_CHGR_TRKL_CHG_TEST = 0x01) */
 	pm8x41_reg_write(PM8XXX_TRKL_CHG_TEST, CHG_TRICKLE_FORCED_ON);
 	/* Wait for vbat to rise */
 	mdelay(12);

 	/* Check Above VBAT_DET_HIGH status */
 	if (pm8x41_reg_read(PM8XXX_VBAT_IN_TSTS) & VBAT_DET_HI_RT_STS)
 		batt_is_broken = 1;
 	else
 		batt_is_broken = 0;

 	/* Unlock SMBBP Secured Register */
 	pm8x41_reg_write(PM8XXX_SEC_ACCESS, SEC_ACCESS);

 	/* Disable force trickle charging */
 	pm8x41_reg_write(PM8XXX_TRKL_CHG_TEST, 0x00);
 	/* re-enable VCP */
 	pm8x41_reg_write(PM8XXX_VCP, VCP_ENABLE);
 	/* restore trickle charging default current */
 	pm8x41_reg_write(PM8XXX_IBAT_ATC_A, trkl_default);
 	/* restore VBAT_DET_LO setting to original value */
 	pm8x41_reg_write(PM8XXX_VBAT_DET, vbat_det_default);

 	return batt_is_broken;
 }

 /* Detect broken battery for pmi 8994*/
 bool pmi8994_is_battery_broken()
 {
 	bool batt_is_broken;
 	uint8_t fast_charge = 0;

 	/* Disable the input missing ppoller */
 	REG_WRITE(PMI8994_CHGR_TRIM_OPTIONS_7_0, REG_READ(PMI8994_CHGR_TRIM_OPTIONS_7_0) & ~INPUT_MISSING_POLLER_EN);
 	/* Disable current termination */
 	REG_WRITE(PMI8994_CHGR_CFG2, REG_READ(PMI8994_CHGR_CFG2) & ~CURRENT_TERM_EN);
 	/* Fast-charge current to 300 mA */
 	fast_charge = REG_READ(PMI8994_FCC_CFG);
 	REG_WRITE(PMI8994_FCC_CFG, 0x0);
 	/* Change the float voltage to 4.50V */
 	REG_WRITE(PMI8994_FV_CFG, 0x3F);

 	mdelay(5);

 	if (REG_READ(PMI8994_INT_RT_STS) & BAT_TAPER_MODE_CHARGING_RT_STS)
 		batt_is_broken = true;
 	else
 		batt_is_broken = false;

 	/* Set float voltage back to 4.35V */
 	REG_WRITE(PMI8994_FV_CFG, 0x2B);
 	/* Enable current termination */
 	REG_WRITE(PMI8994_CHGR_CFG2, REG_READ(PMI8994_CHGR_CFG2) | CURRENT_TERM_EN);
 	/* Fast-charge current back to default mA */
 	REG_WRITE(PMI8994_FCC_CFG, fast_charge);
 	/* Re-enable the input missing poller */
 	REG_WRITE(PMI8994_CHGR_TRIM_OPTIONS_7_0, REG_READ(PMI8994_CHGR_TRIM_OPTIONS_7_0) | INPUT_MISSING_POLLER_EN);

 	return batt_is_broken;
 }

 void pm8x41_vib_turn_on(void)
 {
 	uint8_t val;

 	val = pm8x41_reg_read(QPNP_VIB_VTG_CTL);
 	val &= ~QPNP_VIB_VTG_SET_MASK;
 	val |= (QPNP_VIB_DEFAULT_VTG_LVL & QPNP_VIB_VTG_SET_MASK);
 	pm8x41_reg_write(QPNP_VIB_VTG_CTL, val);

 	val = pm8x41_reg_read(QPNP_VIB_EN_CTL);
 	val |= QPNP_VIB_EN;
 	pm8x41_reg_write(QPNP_VIB_EN_CTL, val);
 }

 /* Turn off vibrator */
 void pm8x41_vib_turn_off(void)
 {
 	uint8_t val;

 	val = pm8x41_reg_read(QPNP_VIB_EN_CTL);
 	val &= ~QPNP_VIB_EN;
 	pm8x41_reg_write(QPNP_VIB_EN_CTL, val);
 }
	/* Copyright (c) 2012-2015, 2017-2018, The Linux Foundation. All rights reserved.

	* Redistribution and use in source and binary forms, with or without
	* modification, are permitted provided that the following conditions are
	* met:
	* * Redistributions of source code must retain the above copyright
	* notice, this list of conditions and the following disclaimer.
	* * Redistributions in binary form must reproduce the above
	* copyright notice, this list of conditions and the following
	* disclaimer in the documentation and/or other materials provided
	* with the distribution.
	* * Neither the name of The Linux Foundation, nor the names of its
	* contributors may be used to endorse or promote products derived
	* from this software without specific prior written permission.
	*
	* THIS SOFTWARE IS PROVIDED "AS IS" AND ANY EXPRESS OR IMPLIED
	* WARRANTIES, INCLUDING, BUT NOT LIMITED TO, THE IMPLIED WARRANTIES OF
	* MERCHANTABILITY, FITNESS FOR A PARTICULAR PURPOSE AND NON-INFRINGEMENT
	* ARE DISCLAIMED. IN NO EVENT SHALL THE COPYRIGHT OWNER OR CONTRIBUTORS
	* BE LIABLE FOR ANY DIRECT, INDIRECT, INCIDENTAL, SPECIAL, EXEMPLARY, OR
	* CONSEQUENTIAL DAMAGES (INCLUDING, BUT NOT LIMITED TO, PROCUREMENT OF
	* SUBSTITUTE GOODS OR SERVICES; LOSS OF USE, DATA, OR PROFITS; OR
	* BUSINESS INTERRUPTION) HOWEVER CAUSED AND ON ANY THEORY OF LIABILITY,
	* WHETHER IN CONTRACT, STRICT LIABILITY, OR TORT (INCLUDING NEGLIGENCE
	* OR OTHERWISE) ARISING IN ANY WAY OUT OF THE USE OF THIS SOFTWARE, EVEN
	* IF ADVISED OF THE POSSIBILITY OF SUCH DAMAGE.
	*/

	#include <bits.h>
	#include <debug.h>
	#include <reg.h>
	#include <spmi.h>
	#include <string.h>
	#include <pm8x41_hw.h>
	#include <pm8x41.h>
	#include <rpm-ipc.h>
	#include <regulator.h>
	#include <platform/timer.h>
	#include <pm_vib.h>

	#define QPNP_VIB_EN BIT(7)

	/* Enable LN BB CLK */
	static uint32_t ln_bb_clk[][8] = {
	{
	RPM_CLK_BUFFER_A_REQ, LNBB_CLK_ID,
	KEY_SOFTWARE_ENABLE, 4, GENERIC_DISABLE,
	RPM_KEY_PIN_CTRL_CLK_BUFFER_ENABLE_KEY, 4, RPM_CLK_BUFFER_PIN_CONTROL_ENABLE_NONE,
	},
	{
	RPM_CLK_BUFFER_A_REQ, LNBB_CLK_ID,
	KEY_SOFTWARE_ENABLE, 4, GENERIC_ENABLE,
	RPM_KEY_PIN_CTRL_CLK_BUFFER_ENABLE_KEY, 4, RPM_CLK_BUFFER_PIN_CONTROL_ENABLE_NONE,
	},
	};

	static uint8_t mpp_slave_id;

	void pmi8994_config_mpp_slave_id(uint8_t slave_id)
	{
	mpp_slave_id = slave_id;
	}
	/* SPMI helper functions */
	uint8_t pm8x41_reg_read(uint32_t addr)
	{
	uint8_t val = 0;
	struct pmic_arb_cmd cmd;
	struct pmic_arb_param param;

	cmd.address = PERIPH_ID(addr);
	cmd.offset = REG_OFFSET(addr);
	cmd.slave_id = SLAVE_ID(addr);
	cmd.priority = 0;

	param.buffer = &val;
	param.size = 1;

	pmic_arb_read_cmd(&cmd, &param);

	return val;
	}

	uint32_t spmi_reg_read(uint32_t slave_id, uint16_t addr, uint8_t *data, uint8_t priority)
	{
	struct pmic_arb_cmd cmd;
	struct pmic_arb_param param;

	cmd.address = PERIPH_ID(addr);
	cmd.offset = REG_OFFSET(addr);
	cmd.slave_id = slave_id;

	cmd.priority = priority;

	param.buffer = data;
	param.size = 1;

	return pmic_arb_read_cmd(&cmd, &param);
	}

	uint32_t spmi_reg_write(uint32_t slave_id, uint16_t addr, uint8_t *data, uint8_t priority)
	{
	struct pmic_arb_cmd cmd;
	struct pmic_arb_param param;

	cmd.address = PERIPH_ID(addr);
	cmd.offset = REG_OFFSET(addr);
	cmd.slave_id = slave_id;

	cmd.priority = priority;

	param.buffer = data;
	param.size = 1;

	return pmic_arb_write_cmd(&cmd, &param);
	}

	/* SPMI helper function which takes slave id as the i/p */
	void pm8xxx_reg_write(uint8_t slave_id, uint32_t addr, uint8_t val)
	{
	struct pmic_arb_cmd cmd;
	struct pmic_arb_param param;

	cmd.address = PERIPH_ID(addr);
	cmd.offset = REG_OFFSET(addr);
	cmd.slave_id = slave_id;

	cmd.priority = 0;

	param.buffer = &val;
	param.size = 1;

	pmic_arb_write_cmd(&cmd, &param);
	}

	void pm8x41_reg_write(uint32_t addr, uint8_t val)
	{
	struct pmic_arb_cmd cmd;
	struct pmic_arb_param param;

	cmd.address = PERIPH_ID(addr);
	cmd.offset = REG_OFFSET(addr);
	cmd.slave_id = SLAVE_ID(addr);
	cmd.priority = 0;

	param.buffer = &val;
	param.size = 1;

	pmic_arb_write_cmd(&cmd, &param);
	}

	/* Exported functions */

	/* Set the boot done flag */
	void pm8x41_set_boot_done()
	{
	uint8_t val;

	val = REG_READ(SMBB_MISC_BOOT_DONE);
	val \|= BIT(BOOT_DONE_BIT);
	REG_WRITE(SMBB_MISC_BOOT_DONE, val);
	}

	/* Configure GPIO */
	int pm8x41_gpio_config(uint8_t gpio, struct pm8x41_gpio *config)
	{
	uint8_t val;
	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

	/* Disable the GPIO */
	val = REG_READ(gpio_base + GPIO_EN_CTL);
	val &= ~BIT(PERPH_EN_BIT);
	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

	/* Select the mode */
	val = config->function \| (config->direction << 4);
	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

	/* Set the right pull */
	val = config->pull;
	REG_WRITE(gpio_base + GPIO_DIG_PULL_CTL, val);

	/* Select the VIN */
	val = config->vin_sel;
	REG_WRITE(gpio_base + GPIO_DIG_VIN_CTL, val);

	if (config->direction == PM_GPIO_DIR_OUT) {
	/* Set the right dig out control */
	val = config->out_strength \| (config->output_buffer << 4);
	REG_WRITE(gpio_base + GPIO_DIG_OUT_CTL, val);
	}

	/* Output source sel and output invert */
	val = config->inv_int_pol << 7;
	REG_WRITE(gpio_base + GPIO_DIG_OUT_SRC_CTL, val);

	/* Enable the GPIO */
	val = REG_READ(gpio_base + GPIO_EN_CTL);
	val \|= BIT(PERPH_EN_BIT);
	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

	return 0;
	}

	/* Reads the status of requested gpio */
	int pm8x41_gpio_get(uint8_t gpio, uint8_t *status)
	{
	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

	*status = REG_READ(gpio_base + GPIO_STATUS);

	/* Return the value of the GPIO pin */
	*status &= BIT(GPIO_STATUS_VAL_BIT);

	dprintf(SPEW, "GPIO %d status is %d\n", gpio, *status);

	return 0;
	}

	/* Write the output value of the requested gpio */
	int pm8x41_gpio_set(uint8_t gpio, uint8_t value)
	{
	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);
	uint8_t val;

	/* Set the output value of the gpio */
	val = REG_READ(gpio_base + GPIO_MODE_CTL);
	val = (val & ~PM_GPIO_OUTPUT_MASK) \| value;
	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

	return 0;
	}

	/* Configure PM and PMI GPIO with slave id */
	int pm8x41_gpio_config_sid(uint8_t sid, uint8_t gpio, struct pm8x41_gpio *config)
	{
	uint8_t val;
	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

	gpio_base &= 0x0ffff; /* clear sid */
	gpio_base \|= (sid << 16); /* add sid */

	dprintf(SPEW, "%s: gpio=%d base=%x\n", __func__, gpio, gpio_base);

	/* Disable the GPIO */
	val = REG_READ(gpio_base + GPIO_EN_CTL);
	val &= ~BIT(PERPH_EN_BIT);
	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

	/* Select the mode */
	val = config->function \| (config->direction << 4);
	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

	/* Set the right pull */
	val = config->pull;
	REG_WRITE(gpio_base + GPIO_DIG_PULL_CTL, val);

	/* Select the VIN */
	val = config->vin_sel;
	REG_WRITE(gpio_base + GPIO_DIG_VIN_CTL, val);

	if (config->direction == PM_GPIO_DIR_OUT) {
	/* Set the right dig out control */
	val = config->out_strength \| (config->output_buffer << 4);
	REG_WRITE(gpio_base + GPIO_DIG_OUT_CTL, val);
	}

	/* Enable the GPIO */
	val = REG_READ(gpio_base + GPIO_EN_CTL);
	val \|= BIT(PERPH_EN_BIT);
	REG_WRITE(gpio_base + GPIO_EN_CTL, val);

	return 0;
	}

	/* Reads the status of requested gpio */
	int pm8x41_gpio_get_sid(uint8_t sid, uint8_t gpio, uint8_t *status)
	{
	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);

	gpio_base &= 0x0ffff; /* clear sid */
	gpio_base \|= (sid << 16); /* add sid */

	*status = REG_READ(gpio_base + GPIO_STATUS);

	/* Return the value of the GPIO pin */
	*status &= BIT(GPIO_STATUS_VAL_BIT);

	dprintf(SPEW, "GPIO %d status is %d\n", gpio, *status);

	return 0;
	}

	/* Write the output value of the requested gpio */
	int pm8x41_gpio_set_sid(uint8_t sid, uint8_t gpio, uint8_t value)
	{
	uint32_t gpio_base = GPIO_N_PERIPHERAL_BASE(gpio);
	uint8_t val;

	gpio_base &= 0x0ffff; /* clear sid */
	gpio_base \|= (sid << 16); /* add sid */

	dprintf(SPEW, "%s: gpio=%d base=%x\n", __func__, gpio, gpio_base);

	/* Set the output value of the gpio */
	val = REG_READ(gpio_base + GPIO_MODE_CTL);
	val = (val & ~PM_GPIO_OUTPUT_MASK) \| value;
	REG_WRITE(gpio_base + GPIO_MODE_CTL, val);

	return 0;
	}

	/* Prepare PON RESIN S2 reset (bite) */
	void pm8x41_resin_s2_reset_enable()
	{
	uint8_t val;

	/* disable s2 reset */
	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, 0x0);

	/* Delay needed for disable to kick in. */
	udelay(300);

	/* configure s1 timer to 0 */
	REG_WRITE(PON_RESIN_N_RESET_S1_TIMER, 0x0);

	/* configure s2 timer to 2s */
	REG_WRITE(PON_RESIN_N_RESET_S2_TIMER, PON_RESIN_N_RESET_S2_TIMER_MAX_VALUE);

	/* configure reset type */
	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, S2_RESET_TYPE_WARM);

	val = REG_READ(PON_RESIN_N_RESET_S2_CTL);

	/* enable s2 reset */
	val \|= BIT(S2_RESET_EN_BIT);
	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, val);
	}

	/* Disable PON RESIN S2 reset. (bite)*/
	void pm8x41_resin_s2_reset_disable()
	{
	/* disable s2 reset */
	REG_WRITE(PON_RESIN_N_RESET_S2_CTL, 0x0);

	/* Delay needed for disable to kick in. */
	udelay(300);
	}

	/* Resin irq status for faulty pmic*/
	uint32_t pm8x41_v2_resin_status()
	{
	uint8_t rt_sts = 0;

	/* Enable S2 reset so we can detect the volume down key press */
	pm8x41_resin_s2_reset_enable();

	/* Delay before interrupt triggering.
	* See PON_DEBOUNCE_CTL reg.
	*/
	mdelay(100);

	rt_sts = REG_READ(PON_INT_RT_STS);

	/* Must disable S2 reset otherwise PMIC will reset if key
	* is held longer than S2 timer.
	*/
	pm8x41_resin_s2_reset_disable();

	return (rt_sts & BIT(RESIN_BARK_INT_BIT));
	}

	/* Resin pin status */
	uint32_t pm8x41_resin_status()
	{
	uint8_t rt_sts = 0;

	rt_sts = REG_READ(PON_INT_RT_STS);

	return (rt_sts & BIT(RESIN_ON_INT_BIT));
	}

	/* Return 1 if power key is pressed */
	uint32_t pm8x41_get_pwrkey_is_pressed()
	{
	uint8_t pwr_sts = 0;

	pwr_sts = REG_READ(PON_INT_RT_STS);

	if (pwr_sts & BIT(KPDPWR_ON_INT_BIT))
	return 1;
	else
	return 0;
	}

	void pmi632_reset_configure(uint8_t reset_type)
	{
	/* Slave ID of pm8953 and pmi632 */
	uint8_t slave_id[] = {0, 2};
	uint8_t i;

	/* Reset sequence
	1. Disable the ps hold for pm8953 and pmi632
	2. set reset type for both pm8953 & pmi632
	3. Enable ps hold for pm8953 to trigger the reset
	*/
	/* disable PS_HOLD_RESET */
	pm8xxx_reg_write(slave_id[0], PON_PS_HOLD_RESET_CTL2, 0x0);
	pm8xxx_reg_write(slave_id[1], PON_PS_HOLD_RESET_CTL2, 0x0);

	/* Delay needed for disable to kick in. */
	udelay(300);

	/* configure reset type */
	for (i = 0; i < ARRAY_SIZE(slave_id); i++)
	pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL, reset_type);

	if (reset_type == PON_PSHOLD_WARM_RESET)
	{
	/* enable PS_HOLD_RESET */
	for (i = 0; i < ARRAY_SIZE(slave_id); i++)
	pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
	}
	else
	{
	pm8xxx_reg_write(slave_id[0], PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
	}
	}

	void pm8994_reset_configure(uint8_t reset_type)
	{
	/* Slave ID of pm8994 and pmi8994 */
	uint8_t slave_id[] = {0, 2};
	uint8_t i;

	/* Reset sequence
	1. Disable the ps hold for pm8994
	2. set reset type for both pm8994 & pmi8994
	3. Enable ps hold for pm8994 to trigger the reset
	*/
	/* disable PS_HOLD_RESET */
	pm8xxx_reg_write(slave_id[0], PON_PS_HOLD_RESET_CTL2, 0x0);
	pm8xxx_reg_write(slave_id[1], PON_PS_HOLD_RESET_CTL2, 0x0);

	/* Delay needed for disable to kick in. */
	udelay(300);

	/* configure reset type */
	for (i = 0; i < ARRAY_SIZE(slave_id); i++)
	pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL, reset_type);

	/* enable PS_HOLD_RESET */
	for (i = 0; i < ARRAY_SIZE(slave_id); i++)
	pm8xxx_reg_write(slave_id[i], PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
	}

	void pm8996_reset_configure(uint8_t slave_id, uint8_t reset_type)
	{
	/* Reset sequence
	1. Disable the ps hold
	2. set reset type
	3. Enable ps hold to trigger the reset
	*/
	/* disable PS_HOLD_RESET */
	pm8xxx_reg_write(slave_id, PON_PS_HOLD_RESET_CTL2, 0x0);

	/* Delay needed for disable to kick in. */
	udelay(300);

	/* configure reset type */
	pm8xxx_reg_write(slave_id, PON_PS_HOLD_RESET_CTL, reset_type);
	/* enable PS_HOLD_RESET */
	pm8xxx_reg_write(slave_id, PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
	}

	void pm8x41_v2_reset_configure(uint8_t reset_type)
	{
	uint8_t val;

	/* disable PS_HOLD_RESET */
	REG_WRITE(PON_PS_HOLD_RESET_CTL, 0x0);

	/* Delay needed for disable to kick in. */
	udelay(300);

	/* configure reset type */
	REG_WRITE(PON_PS_HOLD_RESET_CTL, reset_type);

	val = REG_READ(PON_PS_HOLD_RESET_CTL);

	/* enable PS_HOLD_RESET */
	val \|= BIT(S2_RESET_EN_BIT);
	REG_WRITE(PON_PS_HOLD_RESET_CTL, val);
	}

	void pm8x41_reset_configure(uint8_t reset_type)
	{
	/* disable PS_HOLD_RESET */
	REG_WRITE(PON_PS_HOLD_RESET_CTL2, 0x0);

	/* Delay needed for disable to kick in. */
	udelay(300);

	/* configure reset type */
	REG_WRITE(PON_PS_HOLD_RESET_CTL, reset_type);

	/* enable PS_HOLD_RESET */
	REG_WRITE(PON_PS_HOLD_RESET_CTL2, BIT(S2_RESET_EN_BIT));
	}

	/*
	* LDO set voltage, takes ldo name & voltage in UV as input
	*/
	int pm8x41_ldo_set_voltage(struct pm8x41_ldo *ldo, uint32_t voltage)
	{
	uint32_t range = 0;
	uint32_t step = 0;
	uint32_t mult = 0;
	uint32_t val = 0;
	uint32_t vmin = 0;

	if (!ldo)
	{
	dprintf(CRITICAL, "LDO pointer is invalid: %p\n", ldo);
	return 1;
	}

	/* Program Normal power mode */
	val = 0x0;
	val = (1 << LDO_NORMAL_PWR_BIT);
	REG_WRITE((ldo->base + LDO_POWER_MODE), val);

	/*
	* Select range, step & vmin based on input voltage & type of LDO
	* LDO can operate in low, mid, high power mode
	*/
	if (ldo->type == PLDO_TYPE)
	{
	if (voltage < PLDO_UV_MIN)
	{
	range = 2;
	step = PLDO_UV_STEP_LOW;
	vmin = PLDO_UV_VMIN_LOW;
	}
	else if (voltage < PDLO_UV_MID)
	{
	range = 3;
	step = PLDO_UV_STEP_MID;
	vmin = PLDO_UV_VMIN_MID;
	}
	else
	{
	range = 4;
	step = PLDO_UV_STEP_HIGH;
	vmin = PLDO_UV_VMIN_HIGH;
	}
	}
	else
	{
	range = 2;
	step = NLDO_UV_STEP;
	vmin = NLDO_UV_VMIN_LOW;
	}

	mult = (voltage - vmin) / step;

	/* Set Range in voltage ctrl register */
	val = 0x0;
	val = range << LDO_RANGE_SEL_BIT;
	REG_WRITE((ldo->base + LDO_RANGE_CTRL), val);

	/* Set multiplier in voltage ctrl register */
	val = 0x0;
	val = mult << LDO_VSET_SEL_BIT;
	REG_WRITE((ldo->base + LDO_STEP_CTRL), val);

	return 0;
	}

	/*
	* Enable or Disable LDO
	*/
	int pm8x41_ldo_control(struct pm8x41_ldo *ldo, uint8_t enable)
	{
	uint32_t val = 0;

	if (!ldo)
	{
	dprintf(CRITICAL, "LDO pointer is invalid: %p\n", ldo);
	return 1;
	}

	/* Enable LDO */
	if (enable)
	val = (1 << LDO_VREG_ENABLE_BIT);
	else
	val = (0 << LDO_VREG_ENABLE_BIT);

	REG_WRITE((ldo->base + LDO_EN_CTL_REG), val);

	return 0;
	}

	/*
	* lpg channel register write:
	*/
	void pm8x41_lpg_write(uint8_t chan, uint8_t off, uint8_t val)
	{
	uint32_t lpg_base = LPG_N_PERIPHERAL_BASE(chan);

	REG_WRITE(lpg_base + off, val);
	}

	/*
	* pmi lpg channel register write with slave_id:
	*/
	void pm8x41_lpg_write_sid(uint8_t sid, uint8_t chan, uint8_t off, uint8_t val)
	{
	uint32_t lpg_base = LPG_N_PERIPHERAL_BASE(chan);

	lpg_base &= 0x0ffff; /* clear sid */
	lpg_base \|= (sid << 16); /* add sid */

	dprintf(SPEW, "%s: lpg=%d base=%x\n", __func__, chan, lpg_base);

	REG_WRITE(lpg_base + off, val);
	}

	uint8_t pmi8950_get_pmi_subtype()
	{
	uint8_t subtype;
	spmi_reg_read((PMI8950_SLAVE_ID >> 16), REVID_REV_ID_SPARE_0, &subtype, 0);
	return subtype;
	}

	uint8_t pm8x41_get_pmic_rev()
	{
	return REG_READ(REVID_REVISION4);
	}

	uint8_t pm660_get_pon_reason()
	{
	return REG_READ(PM660_PON_REASON1);
	}

	uint8_t pm8x41_get_pon_reason()
	{
	return REG_READ(PON_PON_REASON1);
	}

	uint8_t pm8950_get_pon_reason()
	{
	uint8_t pon_reason = 0;

	pon_reason = REG_READ(SMBCHGL_USB_ICL_STS_2\|PMI8950_SLAVE_ID);
	/* check usbin/dcin status on pmi and set the corresponding bits for pon */
	pon_reason = (pon_reason & (USBIN_ACTIVE_PWR_SRC\|DCIN_ACTIVE_PWR_SRC)) << 3 ;
	pon_reason \|= REG_READ(PON_PON_REASON1);

	return pon_reason;
	}

	uint8_t pmi632_get_pon_reason()
	{
	uint8_t pon_reason = 0;

	pon_reason = REG_READ(SCHG_USB_INT_RT_STS\|PMI8950_SLAVE_ID);
	/* Check USBIN status on PMI and set the corresponding bits for pon */
	pon_reason = (pon_reason & USBIN_PLUGIN_RT_STS);
	pon_reason \|= REG_READ(PON_PON_REASON1);

	return pon_reason;
	}

	uint8_t pm8x41_get_pon_poff_reason1()
	{
	return REG_READ(PON_POFF_REASON1);
	}

	uint8_t pm8x41_get_pon_poff_reason2()
	{
	return REG_READ(PON_POFF_REASON2);
	}

	void pm8x41_enable_mvs(struct pm8x41_mvs *mvs, enum mvs_en_ctl enable)
	{
	ASSERT(mvs);

	REG_WRITE(mvs->base + MVS_EN_CTL, enable << MVS_EN_CTL_ENABLE_SHIFT);
	}

	void pm8x41_enable_mpp(struct pm8x41_mpp *mpp, enum mpp_en_ctl enable)
	{
	ASSERT(mpp);

	REG_WRITE(((mpp->base + MPP_EN_CTL) + (mpp_slave_id << 16)), enable << MPP_EN_CTL_ENABLE_SHIFT);
	}

	void pm8x41_config_output_mpp(struct pm8x41_mpp *mpp)
	{
	ASSERT(mpp);

	REG_WRITE(((mpp->base + MPP_DIG_VIN_CTL) + (mpp_slave_id << 16)), mpp->vin);

	REG_WRITE(((mpp->base + MPP_MODE_CTL) + (mpp_slave_id << 16)), mpp->mode \| (MPP_DIGITAL_OUTPUT << MPP_MODE_CTL_MODE_SHIFT));
	}

	uint8_t pm660_get_is_cold_boot()
	{
	if (REG_READ(PM660_PON_WARMBOOT_STATUS1)) {
	dprintf(INFO,"%s: Warm boot\n", __func__);
	return 0;
	}
	return 1;
	}

	uint8_t pm8x41_get_is_cold_boot()
	{
	if (REG_READ(PON_WARMBOOT_STATUS1) \|\| REG_READ(PON_WARMBOOT_STATUS2)) {
	dprintf(INFO,"%s: Warm boot\n", __func__);
	return 0;
	}
	dprintf(INFO,"%s: cold boot\n", __func__);
	return 1;
	}

	/* api to control lnbb clock */
	void pm8x41_lnbb_clock_ctrl(uint8_t enable)
	{
	if (enable)
	{
	rpm_clk_enable(&ln_bb_clk[GENERIC_ENABLE][0], 24);
	}
	else
	{
	rpm_clk_enable(&ln_bb_clk[GENERIC_DISABLE][0], 24);
	}
	}

	/* api to control diff clock */
	void pm8x41_diff_clock_ctrl(uint8_t enable)
	{
	uint8_t reg;

	reg = REG_READ(DIFF_CLK1_EN_CTL);

	if (enable)
	{
	reg \|= BIT(DIFF_CLK1_EN_BIT);
	}
	else
	{
	reg &= ~BIT(DIFF_CLK1_EN_BIT);
	}

	REG_WRITE(DIFF_CLK1_EN_CTL, reg);
	}

	void pm8x41_clear_pmic_watchdog(void)
	{
	pm8x41_reg_write(PMIC_WD_RESET_S2_CTL2, 0x0);
	}

	/* API to check for borken battery */
	int pm8xxx_is_battery_broken()
	{
	uint8_t trkl_default = 0;
	uint8_t vbat_det_default = 0;
	int batt_is_broken = 0;

	/* Store original trickle charging current setting */
	trkl_default = pm8x41_reg_read(PM8XXX_IBAT_ATC_A);
	/* Store original VBAT_DET_LO setting */
	vbat_det_default = pm8x41_reg_read(PM8XXX_VBAT_DET);

	/Set trickle charge current to 50mA (IBAT_ATC_A = 0x00) /
	pm8x41_reg_write(PM8XXX_IBAT_ATC_A, 0x00);
	/* Set VBAT_DET_LO to 4.3V so that VBAT_DET_HI = 4.52V (VBAT_DET_LO = 0x35) */
	pm8x41_reg_write(PM8XXX_VBAT_DET, VBAT_DET_LO_4_30V);
	/* Unlock SMBBP Secured Register */
	pm8x41_reg_write(PM8XXX_SEC_ACCESS, SEC_ACCESS);
	/* Disable VTRKL_FAULT comp (SMBBP_CHGR_COMP_OVR0 = 0x08) */
	pm8x41_reg_write(PM8XXX_COMP_OVR0, OVR0_DIS_VTRKL_FAULT);
	/* Disable VCP (SMBB_BAT_IF_VCP = 0x00) */
	pm8x41_reg_write(PM8XXX_VCP, 0x00);
	/* Unlock SMBBP Secured Register */
	pm8x41_reg_write(PM8XXX_SEC_ACCESS, SEC_ACCESS);
	/* Force trickle charging (SMBB_CHGR_TRKL_CHG_TEST = 0x01) */
	pm8x41_reg_write(PM8XXX_TRKL_CHG_TEST, CHG_TRICKLE_FORCED_ON);
	/* Wait for vbat to rise */
	mdelay(12);

	/* Check Above VBAT_DET_HIGH status */
	if (pm8x41_reg_read(PM8XXX_VBAT_IN_TSTS) & VBAT_DET_HI_RT_STS)
	batt_is_broken = 1;
	else
	batt_is_broken = 0;

	/* Unlock SMBBP Secured Register */
	pm8x41_reg_write(PM8XXX_SEC_ACCESS, SEC_ACCESS);

	/* Disable force trickle charging */
	pm8x41_reg_write(PM8XXX_TRKL_CHG_TEST, 0x00);
	/* re-enable VCP */
	pm8x41_reg_write(PM8XXX_VCP, VCP_ENABLE);
	/* restore trickle charging default current */
	pm8x41_reg_write(PM8XXX_IBAT_ATC_A, trkl_default);
	/* restore VBAT_DET_LO setting to original value */
	pm8x41_reg_write(PM8XXX_VBAT_DET, vbat_det_default);

	return batt_is_broken;
	}

	/* Detect broken battery for pmi 8994*/
	bool pmi8994_is_battery_broken()
	{
	bool batt_is_broken;
	uint8_t fast_charge = 0;

	/* Disable the input missing ppoller */
	REG_WRITE(PMI8994_CHGR_TRIM_OPTIONS_7_0, REG_READ(PMI8994_CHGR_TRIM_OPTIONS_7_0) & ~INPUT_MISSING_POLLER_EN);
	/* Disable current termination */
	REG_WRITE(PMI8994_CHGR_CFG2, REG_READ(PMI8994_CHGR_CFG2) & ~CURRENT_TERM_EN);
	/* Fast-charge current to 300 mA */
	fast_charge = REG_READ(PMI8994_FCC_CFG);
	REG_WRITE(PMI8994_FCC_CFG, 0x0);
	/* Change the float voltage to 4.50V */
	REG_WRITE(PMI8994_FV_CFG, 0x3F);

	mdelay(5);

	if (REG_READ(PMI8994_INT_RT_STS) & BAT_TAPER_MODE_CHARGING_RT_STS)
	batt_is_broken = true;
	else
	batt_is_broken = false;

	/* Set float voltage back to 4.35V */
	REG_WRITE(PMI8994_FV_CFG, 0x2B);
	/* Enable current termination */
	REG_WRITE(PMI8994_CHGR_CFG2, REG_READ(PMI8994_CHGR_CFG2) \| CURRENT_TERM_EN);
	/* Fast-charge current back to default mA */
	REG_WRITE(PMI8994_FCC_CFG, fast_charge);
	/* Re-enable the input missing poller */
	REG_WRITE(PMI8994_CHGR_TRIM_OPTIONS_7_0, REG_READ(PMI8994_CHGR_TRIM_OPTIONS_7_0) \| INPUT_MISSING_POLLER_EN);

	return batt_is_broken;
	}

	void pm8x41_vib_turn_on(void)
	{
	uint8_t val;

	val = pm8x41_reg_read(QPNP_VIB_VTG_CTL);
	val &= ~QPNP_VIB_VTG_SET_MASK;
	val \|= (QPNP_VIB_DEFAULT_VTG_LVL & QPNP_VIB_VTG_SET_MASK);
	pm8x41_reg_write(QPNP_VIB_VTG_CTL, val);

	val = pm8x41_reg_read(QPNP_VIB_EN_CTL);
	val \|= QPNP_VIB_EN;
	pm8x41_reg_write(QPNP_VIB_EN_CTL, val);
	}

	/* Turn off vibrator */
	void pm8x41_vib_turn_off(void)
	{
	uint8_t val;

	val = pm8x41_reg_read(QPNP_VIB_EN_CTL);
	val &= ~QPNP_VIB_EN;
	pm8x41_reg_write(QPNP_VIB_EN_CTL, val);
	}