coreboot-libre-fam15h-rdimm/3rdparty/chromeec/common/charge_state_v2.c

/* Copyright 2014 The Chromium OS Authors. All rights reserved.
 * Use of this source code is governed by a BSD-style license that can be
 * found in the LICENSE file.
 *
 * Battery charging task and state machine.
 */

#include "battery.h"
#include "battery_smart.h"
#include "charge_manager.h"
#include "charger_profile_override.h"
#include "charge_state.h"
#include "charger.h"
#include "chipset.h"
#include "common.h"
#include "console.h"
#include "ec_ec_comm_master.h"
#include "ec_ec_comm_slave.h"
#include "extpower.h"
#include "gpio.h"
#include "hooks.h"
#include "host_command.h"
#include "i2c.h"
#include "math_util.h"
#include "printf.h"
#include "system.h"
#include "task.h"
#include "throttle_ap.h"
#include "timer.h"
#include "util.h"

/* Console output macros */
#define CPUTS(outstr) cputs(CC_CHARGER, outstr)
#define CPRINTS(format, args...) cprints(CC_CHARGER, format, ## args)
#define CPRINTF(format, args...) cprintf(CC_CHARGER, format, ## args)

/* Extra debugging prints when allocating power between lid and base. */
#undef CHARGE_ALLOCATE_EXTRA_DEBUG

#define CRITICAL_BATTERY_SHUTDOWN_TIMEOUT_US \
	(CONFIG_BATTERY_CRITICAL_SHUTDOWN_TIMEOUT * SECOND)
#define PRECHARGE_TIMEOUT_US (PRECHARGE_TIMEOUT * SECOND)
#define LFCC_EVENT_THRESH 5 /* Full-capacity change reqd for host event */

#ifdef CONFIG_THROTTLE_AP_ON_BAT_DISCHG_CURRENT
#ifndef CONFIG_HOSTCMD_EVENTS
#error "CONFIG_THROTTLE_AP_ON_BAT_DISCHG_CURRENT needs CONFIG_HOSTCMD_EVENTS"
#endif /* CONFIG_HOSTCMD_EVENTS */
#define BAT_OCP_TIMEOUT_US (60 * SECOND)
/* BAT_OCP_HYSTERESIS_PCT can be optionally overridden in board.h. */
#ifndef BAT_OCP_HYSTERESIS_PCT
#define BAT_OCP_HYSTERESIS_PCT 10
#endif /* BAT_OCP_HYSTERESIS_PCT */
#define BAT_OCP_HYSTERESIS \
	(BAT_MAX_DISCHG_CURRENT * BAT_OCP_HYSTERESIS_PCT / 100) /* mA */
#endif /* CONFIG_THROTTLE_AP_ON_BAT_DISCHG_CURRENT */

#ifdef CONFIG_THROTTLE_AP_ON_BAT_VOLTAGE
#ifndef CONFIG_HOSTCMD_EVENTS
#error "CONFIG_THROTTLE_AP_ON_BAT_VOLTAGE needs CONFIG_HOSTCMD_EVENTS"
#endif /* CONFIG_HOSTCMD_EVENTS */
#define BAT_UVP_TIMEOUT_US (60 * SECOND)
/* BAT_UVP_HYSTERESIS_PCT can be optionally overridden in board.h. */
#ifndef BAT_UVP_HYSTERESIS_PCT
#define BAT_UVP_HYSTERESIS_PCT 3
#endif /* BAT_UVP_HYSTERESIS_PCT */
#define BAT_UVP_HYSTERESIS \
	(BAT_LOW_VOLTAGE_THRESH * BAT_UVP_HYSTERESIS_PCT / 100) /* mV */
static timestamp_t uvp_throttle_start_time;
#endif /* CONFIG_THROTTLE_AP_ON_BAT_OLTAGE */

static int charge_request(int voltage, int current);

static uint8_t battery_level_shutdown;

/*
 * State for charger_task(). Here so we can reset it on a HOOK_INIT, and
 * because stack space is more limited than .bss
 */
static const struct battery_info *batt_info;
static struct charge_state_data curr;
static enum charge_state_v2 prev_state;
static int prev_ac, prev_charge, prev_full, prev_disp_charge;
static enum battery_present prev_bp;
static int is_full; /* battery not accepting current */
static enum ec_charge_control_mode chg_ctl_mode;
static int manual_voltage;  /* Manual voltage override (-1 = no override) */
static int manual_current;  /* Manual current override (-1 = no override) */
static unsigned int user_current_limit = -1U;
test_export_static timestamp_t shutdown_target_time;
static timestamp_t precharge_start_time;

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
static int base_connected;
/* Base has responded to one of our commands already. */
static int base_responsive;
static int charge_base;
static int prev_charge_base;
static int prev_current_base;
static int prev_allow_charge_base;
static int prev_current_lid;

/*
 * In debugging mode, with AC, input current to allocate to base. Negative
 * value disables manual mode.
 */
static int manual_ac_current_base = -1;
/*
 * In debugging mode, when discharging, current to transfer from lid to base
 * (negative to transfer from base to lid). Only valid when enabled is true.
 */
static int manual_noac_enabled;
static int manual_noac_current_base;
#else
static const int base_connected;
#endif

/* Is battery connected but unresponsive after precharge? */
static int battery_seems_to_be_dead;

static int battery_seems_to_be_disconnected;

/*
 * Was battery removed?  Set when we see BP_NO, cleared after the battery is
 * reattached and becomes responsive.  Used to indicate an error state after
 * removal and trigger re-reading the battery static info when battery is
 * reattached and responsive.
 */
static int battery_was_removed;

static int problems_exist;
static int debugging;


/* Track problems in communicating with the battery or charger */
enum problem_type {
	PR_STATIC_UPDATE,
	PR_SET_VOLTAGE,
	PR_SET_CURRENT,
	PR_SET_MODE,
	PR_SET_INPUT_CURR,
	PR_POST_INIT,
	PR_CHG_FLAGS,
	PR_BATT_FLAGS,
	PR_CUSTOM,

	NUM_PROBLEM_TYPES
};
static const char * const prob_text[] = {
	"static update",
	"set voltage",
	"set current",
	"set mode",
	"set input current",
	"post init",
	"chg params",
	"batt params",
	"custom profile",
};
BUILD_ASSERT(ARRAY_SIZE(prob_text) == NUM_PROBLEM_TYPES);

/*
 * TODO(crosbug.com/p/27639): When do we decide a problem is real and not
 * just intermittent? And what do we do about it?
 */
static void problem(enum problem_type p, int v)
{
	static int __bss_slow last_prob_val[NUM_PROBLEM_TYPES];
	static timestamp_t __bss_slow last_prob_time[NUM_PROBLEM_TYPES];
	timestamp_t t_now, t_diff;

	if (last_prob_val[p] != v) {
		t_now = get_time();
		t_diff.val = t_now.val - last_prob_time[p].val;
		CPRINTS("charge problem: %s, 0x%x -> 0x%x after %.6lds",
			 prob_text[p], last_prob_val[p], v, t_diff.val);
		last_prob_val[p] = v;
		last_prob_time[p] = t_now;
	}
	problems_exist = 1;
}

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
/*
 * Parameters for dual-battery policy.
 * TODO(b:71881017): This should be made configurable by AP in the future.
 */
struct dual_battery_policy {
	/*** Policies when AC is not connected. ***/
	/* Voltage to use when using OTG mode between lid and base (mV) */
	uint16_t otg_voltage;
	/* Maximum current to apply from base to lid (mA) */
	uint16_t max_base_to_lid_current;
	/*
	 * Margin to apply between provided OTG output current and input current
	 * limit, to make sure that input charger does not overcurrent output
	 * charger. input_current = (1-margin) * output_current. (/128)
	 */
	uint8_t margin_otg_current;

	/* Only do base to lid OTG when base battery above this value (%) */
	uint8_t min_charge_base_otg;

	/*
	 * When base/lid battery percentage is below this value, do
	 * battery-to-battery charging. (%)
	 */
	uint8_t max_charge_base_batt_to_batt;
	uint8_t max_charge_lid_batt_to_batt;

	/*** Policies when AC is connected. ***/
	/* Minimum power to allocate to base (mW), includes some margin to allow
	 * base to charge when critically low.
	 */
	uint16_t min_base_system_power;

	/* Smoothing factor for lid power (/128) */
	uint8_t lid_system_power_smooth;
	/*
	 * Smoothing factor for base/lid battery power, when the battery power
	 * is decreasing only: we try to estimate the maximum power that the
	 * battery is willing to take and always reset it when it draws more
	 * than the estimate. (/128)
	 */
	uint8_t battery_power_smooth;

	/*
	 * Margin to add to requested base/lid battery power, to figure out how
	 * much current to allocate. allocation = (1+margin) * request. (/128)
	 */
	uint8_t margin_base_battery_power;
	uint8_t margin_lid_battery_power;

	/* Maximum current to apply from lid to base (mA) */
	uint16_t max_lid_to_base_current;
};

static const struct dual_battery_policy db_policy = {
	.otg_voltage = 12000, /* mV */
	.max_base_to_lid_current = 1800, /* mA, about 2000mA with margin. */
	.margin_otg_current = 13, /* /128 = 10.1% */
	.min_charge_base_otg = 5, /* % */
	.max_charge_base_batt_to_batt = 4, /* % */
	.max_charge_lid_batt_to_batt = 10, /* % */
	.min_base_system_power = 1300, /* mW */
	.lid_system_power_smooth = 32, /* 32/128 = 0.25 */
	.battery_power_smooth = 1, /* 1/128 = 0.008 */
	.margin_base_battery_power = 32, /* 32/128 = 0.25 */
	.margin_lid_battery_power = 32, /* 32/128 = 0.25 */
	.max_lid_to_base_current = 2000, /* mA */
};

/* Add at most "value" to power_var, subtracting from total_power budget. */
#define CHG_ALLOCATE(power_var, total_power, value) do {	\
	int val_capped = MIN(value, total_power);		\
	(power_var) += val_capped;				\
	(total_power) -= val_capped;				\
} while (0)

/* Update base battery information */
static void update_base_battery_info(void)
{
	struct ec_response_battery_dynamic_info *const bd =
		&battery_dynamic[BATT_IDX_BASE];

	base_connected = board_is_base_connected();

	if (!base_connected) {
		const int invalid_flags = EC_BATT_FLAG_INVALID_DATA;
		/* Invalidate static/dynamic information */
		if (bd->flags != invalid_flags) {
			bd->flags = invalid_flags;

			host_set_single_event(EC_HOST_EVENT_BATTERY);
			host_set_single_event(EC_HOST_EVENT_BATTERY_STATUS);
		}
		charge_base = -1;
		base_responsive = 0;
		prev_current_base = 0;
		prev_allow_charge_base = 0;
	} else if (base_responsive) {
		int old_flags = bd->flags;
		int flags_changed;
		int old_full_capacity = bd->full_capacity;

		ec_ec_master_base_get_dynamic_info();
		flags_changed = (old_flags != bd->flags);
		/* Fetch static information when flags change. */
		if (flags_changed)
			ec_ec_master_base_get_static_info();

		battery_memmap_refresh(BATT_IDX_BASE);

		/* Newly connected battery, or change in capacity. */
		if (old_flags & EC_BATT_FLAG_INVALID_DATA ||
				((old_flags & EC_BATT_FLAG_BATT_PRESENT) !=
				 (bd->flags & EC_BATT_FLAG_BATT_PRESENT)) ||
				old_full_capacity != bd->full_capacity)
			host_set_single_event(EC_HOST_EVENT_BATTERY);

		if (flags_changed)
			host_set_single_event(EC_HOST_EVENT_BATTERY_STATUS);

		/* Update charge_base */
		if (bd->flags & (BATT_FLAG_BAD_FULL_CAPACITY |
				 BATT_FLAG_BAD_REMAINING_CAPACITY))
			charge_base = -1;
		else if (bd->full_capacity > 0)
			charge_base = 100 * bd->remaining_capacity
						/ bd->full_capacity;
		else
			charge_base = 0;
	}
}

/**
 * Setup current settings for base, and record previous values, if the base
 * is responsive.
 *
 * @param current_base Current to be drawn by base (negative to provide power)
 * @param allow_charge_base Whether base battery should be charged (only makes
 *                          sense with positive current)
 */
static int set_base_current(int current_base, int allow_charge_base)
{
	/* "OTG" voltage from base to lid. */
	const int otg_voltage = db_policy.otg_voltage;
	int ret;

	ret = ec_ec_master_base_charge_control(current_base,
					otg_voltage, allow_charge_base);
	if (ret) {
		/* Ignore errors until the base is responsive. */
		if (base_responsive)
			return ret;
	} else {
		base_responsive = 1;
		prev_current_base = current_base;
		prev_allow_charge_base = allow_charge_base;
	}

	return EC_RES_SUCCESS;
}

/**
 * Setup current settings for lid and base, in a safe way.
 *
 * @param current_base Current to be drawn by base (negative to provide power)
 * @param allow_charge_base Whether base battery should be charged (only makes
 *                          sense with positive current)
 * @param current_lid Current to be drawn by lid (negative to provide power)
 * @param allow_charge_lid Whether lid battery should be charged
 */
static void set_base_lid_current(int current_base, int allow_charge_base,
				 int current_lid, int allow_charge_lid)
{
	/* "OTG" voltage from lid to base. */
	const int otg_voltage = db_policy.otg_voltage;

	int lid_first;
	int ret;

	/* TODO(b:71881017): This is still quite verbose during charging. */
	if (prev_current_base != current_base ||
	    prev_allow_charge_base != allow_charge_base ||
	    prev_current_lid != current_lid) {
		CPRINTS("Base/Lid: %d%s/%d%s mA",
			current_base, allow_charge_base ? "+" : "",
			current_lid, allow_charge_lid ? "+" : "");
	}

	/*
	 * To decide whether to first control the lid or the base, we first
	 * control the side that _reduces_ current that would be drawn, then
	 * setup one that would start providing power, then increase current.
	 */
	if (current_lid >= 0 && current_lid < prev_current_lid)
		lid_first = 1; /* Lid decreases current */
	else if (current_base >= 0 && current_base < prev_current_base)
		lid_first = 0; /* Base decreases current */
	else if (current_lid < 0)
		lid_first = 1; /* Lid provide power */
	else
		lid_first = 0; /* All other cases: control the base first */

	if (!lid_first && base_connected) {
		ret = set_base_current(current_base, allow_charge_base);
		if (ret)
			return;
	}

	if (current_lid >= 0) {
		ret = charge_set_output_current_limit(0, 0);
		if (ret)
			return;
		ret = charger_set_input_current(current_lid);
		if (ret)
			return;
		if (allow_charge_lid)
			ret = charge_request(curr.requested_voltage,
				curr.requested_current);
		else
			ret = charge_request(0, 0);
	} else {
		ret = charge_set_output_current_limit(
						-current_lid, otg_voltage);
	}

	if (ret)
		return;

	prev_current_lid = current_lid;

	if (lid_first && base_connected) {
		ret = set_base_current(current_base, allow_charge_base);
		if (ret)
			return;
	}

	/*
	 * Make sure cross-power is enabled (it might not be enabled right after
	 * plugging the base, or when an adapter just got connected).
	 */
	if (base_connected && current_base != 0)
		board_enable_base_power(1);
}

/**
 * Smooth power value, covering some edge cases.
 * Compute s*curr+(1-s)*prev, where s is in 1/128 unit.
 */
static int smooth_value(int prev, int curr, int s)
{
	if (curr < 0)
		curr = 0;
	if (prev < 0)
		return curr;

	return prev + s * (curr - prev) / 128;
}

/**
 * Add margin m to value. Compute (1+m)*value, where m is in 1/128 unit.
 */
static int add_margin(int value, int m)
{
	return value + m * value / 128;
}

static void charge_allocate_input_current_limit(void)
{
	/*
	 * All the power numbers are in mW.
	 *
	 * Since we work with current and voltage in mA and mV, multiplying them
	 * gives numbers in uW, which are dangerously close to overflowing when
	 * doing intermediate computations (60W * 100 overflows a 32-bit int,
	 * for example). We therefore divide the product by 1000 and re-multiply
	 * the power numbers by 1000 when converting them back to current.
	 */
	int total_power = 0;

	static int prev_base_battery_power = -1;
	int base_battery_power = 0;
	int base_battery_power_max = 0;

	static int prev_lid_system_power = -1;
	int lid_system_power;

	static int prev_lid_battery_power = -1;
	int lid_battery_power = 0;
	int lid_battery_power_max = 0;

	int power_base = 0;
	int power_lid = 0;

	int current_base = 0;
	int current_lid = 0;

	int charge_lid = charge_get_percent();

	const struct ec_response_battery_dynamic_info *const base_bd =
		&battery_dynamic[BATT_IDX_BASE];


	if (!base_connected) {
		set_base_lid_current(0, 0, curr.desired_input_current, 1);
		prev_base_battery_power = -1;
		return;
	}

	/* Charging */
	if (curr.desired_input_current > 0 && curr.input_voltage > 0)
		total_power =
			curr.desired_input_current * curr.input_voltage / 1000;

	/*
	 * TODO(b:71723024): We should be able to replace this test by curr.ac,
	 * but the value is currently wrong, especially during transitions.
	 */
	if (total_power <= 0) {
		int base_critical = charge_base >= 0 &&
			charge_base < db_policy.max_charge_base_batt_to_batt;

		/* Discharging */
		prev_base_battery_power = -1;
		prev_lid_system_power = -1;
		prev_lid_battery_power = -1;

		/* Manual control */
		if (manual_noac_enabled) {
			int lid_current, base_current;

			if (manual_noac_current_base > 0) {
				base_current = -manual_noac_current_base;
				lid_current =
					add_margin(manual_noac_current_base,
						db_policy.margin_otg_current);
			} else {
				lid_current = manual_noac_current_base;
				base_current =
					add_margin(-manual_noac_current_base,
						db_policy.margin_otg_current);
			}

			set_base_lid_current(base_current, 0, lid_current, 0);
			return;
		}

		/*
		 * System is off, cut power to the base. We'll reset the base
		 * when system restarts, or when AC is plugged.
		 */
		if (chipset_in_state(CHIPSET_STATE_ANY_OFF)) {
			set_base_lid_current(0, 0, 0, 0);
			if (base_responsive) {
				/* Base still responsive, put it to sleep. */
				CPRINTF("Hibernating base\n");
				ec_ec_master_hibernate();
				base_responsive = 0;
				board_enable_base_power(0);
			}
			return;
		}

		/*
		 * System is suspended, let the lid and base run on their
		 * own power. However, if the base battery is critically low, we
		 * still want to provide power to the base, to make sure it
		 * stays alive to be able to wake the system on keyboard or
		 * touchpad events.
		 */
		if (chipset_in_state(CHIPSET_STATE_ANY_SUSPEND) &&
					!base_critical) {
			set_base_lid_current(0, 0, 0, 0);
			return;
		}

		if (charge_base > db_policy.min_charge_base_otg) {
			int lid_current = db_policy.max_base_to_lid_current;
			int base_current = add_margin(lid_current,
						db_policy.margin_otg_current);
			/* Draw current from base to lid */
			set_base_lid_current(-base_current, 0, lid_current,
			    charge_lid < db_policy.max_charge_lid_batt_to_batt);
		} else {
			/*
			 * Base battery is too low, apply power to it, and allow
			 * it to charge if it is critically low.
			 *
			 * TODO(b:71881017): When suspended, this will make the
			 * battery charge oscillate between 3 and 4 percent,
			 * which might not be great for battery life. We need
			 * some hysteresis.
			 */
			/*
			 * TODO(b:71881017): Precompute (ideally, at build time)
			 * the base_current, so we do not need to do a division
			 * here.
			 */
			int base_current =
				(db_policy.min_base_system_power * 1000) /
				db_policy.otg_voltage;
			int lid_current = add_margin(base_current,
						db_policy.margin_otg_current);

			set_base_lid_current(base_current, base_critical,
					     -lid_current, 0);
		}

		return;
	}

	/* Manual control */
	if (manual_ac_current_base >= 0) {
		int current_base = manual_ac_current_base;
		int current_lid =
			curr.desired_input_current - manual_ac_current_base;

		if (current_lid < 0) {
			current_base = curr.desired_input_current;
			current_lid = 0;
		}

		set_base_lid_current(current_base, 1, current_lid, 1);
		return;
	}

	/* Estimate system power. */
	lid_system_power = charger_get_system_power() / 1000;

	/* Smooth system power, as it is very spiky */
	lid_system_power = smooth_value(prev_lid_system_power,
			lid_system_power, db_policy.lid_system_power_smooth);
	prev_lid_system_power = lid_system_power;

	/*
	 * TODO(b:71881017): Smoothing the battery power isn't necessarily a
	 * good idea: if the system takes up too much power, we may reduce the
	 * estimate power too quickly, leading to oscillations when the system
	 * power goes down. Instead, we should probably estimate the current
	 * based on remaining capacity.
	 */
	/* Estimate lid battery power. */
	if (!(curr.batt.flags &
			(BATT_FLAG_BAD_VOLTAGE | BATT_FLAG_BAD_CURRENT)))
		lid_battery_power = curr.batt.current *
				    curr.batt.voltage / 1000;
	if (lid_battery_power < prev_lid_battery_power)
		lid_battery_power = smooth_value(prev_lid_battery_power,
			     lid_battery_power, db_policy.battery_power_smooth);
	if (!(curr.batt.flags &
			(BATT_FLAG_BAD_DESIRED_VOLTAGE |
				BATT_FLAG_BAD_DESIRED_CURRENT)))
		lid_battery_power_max = curr.batt.desired_current *
					curr.batt.desired_voltage / 1000;

	lid_battery_power = MIN(lid_battery_power, lid_battery_power_max);

	/* Estimate base battery power. */
	if (!(base_bd->flags & EC_BATT_FLAG_INVALID_DATA)) {
		base_battery_power = base_bd->actual_current *
				     base_bd->actual_voltage / 1000;
		base_battery_power_max = base_bd->desired_current *
					 base_bd->desired_voltage / 1000;
	}
	if (base_battery_power < prev_base_battery_power)
		base_battery_power = smooth_value(prev_base_battery_power,
			    base_battery_power, db_policy.battery_power_smooth);
	base_battery_power = MIN(base_battery_power, base_battery_power_max);

	if (debugging) {
		CPRINTF("%s:\n", __func__);
		CPRINTF("total power: %d\n", total_power);
		CPRINTF("base battery power: %d (%d)\n",
			base_battery_power, base_battery_power_max);
		CPRINTF("lid system power: %d\n", lid_system_power);
		CPRINTF("lid battery power: %d\n", lid_battery_power);
		CPRINTF("percent base/lid: %d%% %d%%\n",
			charge_base, charge_lid);
	}

	prev_lid_battery_power = lid_battery_power;
	prev_base_battery_power = base_battery_power;

	if (total_power > 0) { /* Charging */
		/* Allocate system power */
		CHG_ALLOCATE(power_base, total_power,
			db_policy.min_base_system_power);
		CHG_ALLOCATE(power_lid, total_power, lid_system_power);

		/* Allocate lid, then base battery power */
		lid_battery_power = add_margin(lid_battery_power,
					db_policy.margin_lid_battery_power);
		CHG_ALLOCATE(power_lid, total_power, lid_battery_power);

		base_battery_power = add_margin(base_battery_power,
					db_policy.margin_base_battery_power);
		CHG_ALLOCATE(power_base, total_power, base_battery_power);

		/* Give everything else to the lid. */
		CHG_ALLOCATE(power_lid, total_power, total_power);
		if (debugging)
			CPRINTF("power: base %d mW / lid %d mW\n",
				power_base, power_lid);

		current_base = 1000 * power_base / curr.input_voltage;
		current_lid = 1000 * power_lid / curr.input_voltage;

		if (current_base > db_policy.max_lid_to_base_current) {
			current_lid += (current_base
					- db_policy.max_lid_to_base_current);
			current_base = db_policy.max_lid_to_base_current;
		}

		if (debugging)
			CPRINTF("current: base %d mA / lid %d mA\n",
				current_base, current_lid);

		set_base_lid_current(current_base, 1, current_lid, 1);
	} else { /* Discharging */
	}

	if (debugging)
		CPRINTF("====\n");
}
#endif /* CONFIG_EC_EC_COMM_BATTERY_MASTER */

#ifndef CONFIG_BATTERY_V2
/* Returns zero if every item was updated. */
static int update_static_battery_info(void)
{
	char *batt_str;
	int batt_serial;
	uint8_t batt_flags = 0;
	/*
	 * The return values have type enum ec_error_list, but EC_SUCCESS is
	 * zero. We'll just look for any failures so we can try them all again.
	 */
	int rv;

	/* Smart battery serial number is 16 bits */
	batt_str = (char *)host_get_memmap(EC_MEMMAP_BATT_SERIAL);
	memset(batt_str, 0, EC_MEMMAP_TEXT_MAX);
	rv = battery_serial_number(&batt_serial);
	if (!rv)
		snprintf(batt_str, EC_MEMMAP_TEXT_MAX, "%04X", batt_serial);

	/* Design Capacity of Full */
	rv |= battery_design_capacity(
		(int *)host_get_memmap(EC_MEMMAP_BATT_DCAP));

	/* Design Voltage */
	rv |= battery_design_voltage(
		(int *)host_get_memmap(EC_MEMMAP_BATT_DVLT));

	/* Last Full Charge Capacity (this is only mostly static) */
	rv |= battery_full_charge_capacity(
		(int *)host_get_memmap(EC_MEMMAP_BATT_LFCC));

	/* Cycle Count */
	rv |= battery_cycle_count((int *)host_get_memmap(EC_MEMMAP_BATT_CCNT));

	/* Battery Manufacturer string */
	batt_str = (char *)host_get_memmap(EC_MEMMAP_BATT_MFGR);
	memset(batt_str, 0, EC_MEMMAP_TEXT_MAX);
	rv |= battery_manufacturer_name(batt_str, EC_MEMMAP_TEXT_MAX);

	/* Battery Model string */
	batt_str = (char *)host_get_memmap(EC_MEMMAP_BATT_MODEL);
	memset(batt_str, 0, EC_MEMMAP_TEXT_MAX);
	rv |= battery_device_name(batt_str, EC_MEMMAP_TEXT_MAX);

	/* Battery Type string */
	batt_str = (char *)host_get_memmap(EC_MEMMAP_BATT_TYPE);
	rv |= battery_device_chemistry(batt_str, EC_MEMMAP_TEXT_MAX);

	/* Zero the dynamic entries. They'll come next. */
	*(int *)host_get_memmap(EC_MEMMAP_BATT_VOLT) = 0;
	*(int *)host_get_memmap(EC_MEMMAP_BATT_RATE) = 0;
	*(int *)host_get_memmap(EC_MEMMAP_BATT_CAP) = 0;
	*(int *)host_get_memmap(EC_MEMMAP_BATT_LFCC) = 0;
	if (extpower_is_present())
		batt_flags |= EC_BATT_FLAG_AC_PRESENT;
	*host_get_memmap(EC_MEMMAP_BATT_FLAG) = batt_flags;

	if (rv)
		problem(PR_STATIC_UPDATE, rv);
	else
		/* No errors seen. Battery data is now present */
		*host_get_memmap(EC_MEMMAP_BATTERY_VERSION) = 1;

	return rv;
}

static void update_dynamic_battery_info(void)
{
	/* The memmap address is constant. We should fix these calls somehow. */
	int *memmap_volt = (int *)host_get_memmap(EC_MEMMAP_BATT_VOLT);
	int *memmap_rate = (int *)host_get_memmap(EC_MEMMAP_BATT_RATE);
	int *memmap_cap = (int *)host_get_memmap(EC_MEMMAP_BATT_CAP);
	int *memmap_lfcc = (int *)host_get_memmap(EC_MEMMAP_BATT_LFCC);
	uint8_t *memmap_flags = host_get_memmap(EC_MEMMAP_BATT_FLAG);
	uint8_t tmp;
	int send_batt_status_event = 0;
	int send_batt_info_event = 0;
	static int __bss_slow batt_present;

	tmp = 0;
	if (curr.ac)
		tmp |= EC_BATT_FLAG_AC_PRESENT;

	if (curr.batt.is_present == BP_YES) {
		tmp |= EC_BATT_FLAG_BATT_PRESENT;
		batt_present = 1;
		/* Tell the AP to read battery info if it is newly present. */
		if (!(*memmap_flags & EC_BATT_FLAG_BATT_PRESENT))
			send_batt_info_event++;
	} else {
		/*
		 * Require two consecutive updates with BP_NOT_SURE
		 * before reporting it gone to the host.
		 */
		if (batt_present)
			tmp |= EC_BATT_FLAG_BATT_PRESENT;
		else if (*memmap_flags & EC_BATT_FLAG_BATT_PRESENT)
			send_batt_info_event++;
		batt_present = 0;
	}

	if (curr.batt.flags & EC_BATT_FLAG_INVALID_DATA)
		tmp |= EC_BATT_FLAG_INVALID_DATA;

	if (!(curr.batt.flags & BATT_FLAG_BAD_VOLTAGE))
		*memmap_volt = curr.batt.voltage;

	if (!(curr.batt.flags & BATT_FLAG_BAD_CURRENT))
		*memmap_rate = ABS(curr.batt.current);

	if (!(curr.batt.flags & BATT_FLAG_BAD_REMAINING_CAPACITY)) {
		/*
		 * If we're running off the battery, it must have some charge.
		 * Don't report zero charge, as that has special meaning
		 * to Chrome OS powerd.
		 */
		if (curr.batt.remaining_capacity == 0 && !curr.batt_is_charging)
			*memmap_cap = 1;
		else
			*memmap_cap = curr.batt.remaining_capacity;
	}

	if (!(curr.batt.flags & BATT_FLAG_BAD_FULL_CAPACITY) &&
	    (curr.batt.full_capacity <= (*memmap_lfcc - LFCC_EVENT_THRESH) ||
	     curr.batt.full_capacity >= (*memmap_lfcc + LFCC_EVENT_THRESH))) {
		*memmap_lfcc = curr.batt.full_capacity;
		/* Poke the AP if the full_capacity changes. */
		send_batt_info_event++;
	}

	if (curr.batt.is_present == BP_YES &&
	    !(curr.batt.flags & BATT_FLAG_BAD_STATE_OF_CHARGE) &&
	    curr.batt.state_of_charge <= BATTERY_LEVEL_CRITICAL)
		tmp |= EC_BATT_FLAG_LEVEL_CRITICAL;

	tmp |= curr.batt_is_charging ? EC_BATT_FLAG_CHARGING :
				       EC_BATT_FLAG_DISCHARGING;

	/* Tell the AP to re-read battery status if charge state changes */
	if (*memmap_flags != tmp)
		send_batt_status_event++;

	/* Update flags before sending host events. */
	*memmap_flags = tmp;

	if (send_batt_info_event)
		host_set_single_event(EC_HOST_EVENT_BATTERY);
	if (send_batt_status_event)
		host_set_single_event(EC_HOST_EVENT_BATTERY_STATUS);
}
#else /* CONFIG_BATTERY_V2 */
static int update_static_battery_info(void)
{
	int batt_serial;
	int val;
	/*
	 * The return values have type enum ec_error_list, but EC_SUCCESS is
	 * zero. We'll just look for any failures so we can try them all again.
	 */
	int rv, ret;

	struct ec_response_battery_static_info *const bs =
		&battery_static[BATT_IDX_MAIN];

	/* Clear all static information. */
	memset(bs, 0, sizeof(*bs));

	/* Smart battery serial number is 16 bits */
	rv = battery_serial_number(&batt_serial);
	if (!rv)
		snprintf(bs->serial, sizeof(bs->serial), "%04X", batt_serial);

	/* Design Capacity of Full */
	ret = battery_design_capacity(&val);
	if (!ret)
		bs->design_capacity = val;
	rv |= ret;

	/* Design Voltage */
	ret = battery_design_voltage(&val);
	if (!ret)
		bs->design_voltage = val;
	rv |= ret;

	/* Cycle Count */
	ret = battery_cycle_count(&val);
	if (!ret)
		bs->cycle_count = val;
	rv |= ret;

	/* Battery Manufacturer string */
	rv |= battery_manufacturer_name(bs->manufacturer,
					sizeof(bs->manufacturer));

	/* Battery Model string */
	rv |= battery_device_name(bs->model, sizeof(bs->model));

	/* Battery Type string */
	rv |= battery_device_chemistry(bs->type, sizeof(bs->type));

	/* Zero the dynamic entries. They'll come next. */
	memset(&battery_dynamic[BATT_IDX_MAIN], 0,
	       sizeof(battery_dynamic[BATT_IDX_MAIN]));

	if (rv)
		problem(PR_STATIC_UPDATE, rv);

#ifdef HAS_TASK_HOSTCMD
	battery_memmap_refresh(BATT_IDX_MAIN);
#endif

	return rv;
}

static void update_dynamic_battery_info(void)
{
	static int __bss_slow batt_present;
	uint8_t tmp;
	int send_batt_status_event = 0;
	int send_batt_info_event = 0;

	struct ec_response_battery_dynamic_info *const bd =
		&battery_dynamic[BATT_IDX_MAIN];

	tmp = 0;
	if (curr.ac)
		tmp |= EC_BATT_FLAG_AC_PRESENT;

	if (curr.batt.is_present == BP_YES) {
		tmp |= EC_BATT_FLAG_BATT_PRESENT;
		batt_present = 1;
		/* Tell the AP to read battery info if it is newly present. */
		if (!(bd->flags & EC_BATT_FLAG_BATT_PRESENT))
			send_batt_info_event++;
	} else {
		/*
		 * Require two consecutive updates with BP_NOT_SURE
		 * before reporting it gone to the host.
		 */
		if (batt_present)
			tmp |= EC_BATT_FLAG_BATT_PRESENT;
		else if (bd->flags & EC_BATT_FLAG_BATT_PRESENT)
			send_batt_info_event++;
		batt_present = 0;
	}

	if (curr.batt.flags & EC_BATT_FLAG_INVALID_DATA)
		tmp |= EC_BATT_FLAG_INVALID_DATA;

	if (!(curr.batt.flags & BATT_FLAG_BAD_VOLTAGE))
		bd->actual_voltage = curr.batt.voltage;

	if (!(curr.batt.flags & BATT_FLAG_BAD_CURRENT))
		bd->actual_current = curr.batt.current;

	if (!(curr.batt.flags & BATT_FLAG_BAD_DESIRED_VOLTAGE))
		bd->desired_voltage = curr.batt.desired_voltage;

	if (!(curr.batt.flags & BATT_FLAG_BAD_DESIRED_CURRENT))
		bd->desired_current = curr.batt.desired_current;

	if (!(curr.batt.flags & BATT_FLAG_BAD_REMAINING_CAPACITY)) {
		/*
		 * If we're running off the battery, it must have some charge.
		 * Don't report zero charge, as that has special meaning
		 * to Chrome OS powerd.
		 */
		if (curr.batt.remaining_capacity == 0 && !curr.batt_is_charging)
			bd->remaining_capacity = 1;
		else
			bd->remaining_capacity = curr.batt.remaining_capacity;
	}

	if (!(curr.batt.flags & BATT_FLAG_BAD_FULL_CAPACITY) &&
		(curr.batt.full_capacity <=
			(bd->full_capacity - LFCC_EVENT_THRESH) ||
		 curr.batt.full_capacity >=
			(bd->full_capacity + LFCC_EVENT_THRESH))) {
		bd->full_capacity = curr.batt.full_capacity;
		/* Poke the AP if the full_capacity changes. */
		send_batt_info_event++;
	}

	if (curr.batt.is_present == BP_YES &&
	    !(curr.batt.flags & BATT_FLAG_BAD_STATE_OF_CHARGE) &&
	    curr.batt.state_of_charge <= BATTERY_LEVEL_CRITICAL)
		tmp |= EC_BATT_FLAG_LEVEL_CRITICAL;

	tmp |= curr.batt_is_charging ? EC_BATT_FLAG_CHARGING :
				       EC_BATT_FLAG_DISCHARGING;

	/* Tell the AP to re-read battery status if charge state changes */
	if (bd->flags != tmp)
		send_batt_status_event++;

	bd->flags = tmp;

#ifdef HAS_TASK_HOSTCMD
	battery_memmap_refresh(BATT_IDX_MAIN);
#endif

#ifdef CONFIG_HOSTCMD_EVENTS
	if (send_batt_info_event)
		host_set_single_event(EC_HOST_EVENT_BATTERY);
	if (send_batt_status_event)
		host_set_single_event(EC_HOST_EVENT_BATTERY_STATUS);
#endif
}
#endif /* CONFIG_BATTERY_V2 */

static const char * const state_list[] = {
	"idle", "discharge", "charge", "precharge"
};
BUILD_ASSERT(ARRAY_SIZE(state_list) == NUM_STATES_V2);
static const char * const batt_pres[] = {
	"NO", "YES", "NOT_SURE",
};

static void dump_charge_state(void)
{
#define DUMP(FLD, FMT) ccprintf(#FLD " = " FMT "\n", curr.FLD)
#define DUMP_CHG(FLD, FMT) ccprintf("\t" #FLD " = " FMT "\n", curr.chg. FLD)
#define DUMP_BATT(FLD, FMT) ccprintf("\t" #FLD " = " FMT "\n", curr.batt. FLD)
	ccprintf("state = %s\n", state_list[curr.state]);
	DUMP(ac, "%d");
	DUMP(batt_is_charging, "%d");
	ccprintf("chg.*:\n");
	DUMP_CHG(voltage, "%dmV");
	DUMP_CHG(current, "%dmA");
	DUMP_CHG(input_current, "%dmA");
	DUMP_CHG(status, "0x%x");
	DUMP_CHG(option, "0x%x");
	DUMP_CHG(flags, "0x%x");
	cflush();
	ccprintf("batt.*:\n");
	ccprintf("\ttemperature = %dC\n",
		 DECI_KELVIN_TO_CELSIUS(curr.batt.temperature));
	DUMP_BATT(state_of_charge, "%d%%");
	DUMP_BATT(voltage, "%dmV");
	DUMP_BATT(current, "%dmA");
	DUMP_BATT(desired_voltage, "%dmV");
	DUMP_BATT(desired_current, "%dmA");
	DUMP_BATT(flags, "0x%x");
	DUMP_BATT(remaining_capacity, "%dmAh");
	DUMP_BATT(full_capacity, "%dmAh");
	ccprintf("\tis_present = %s\n", batt_pres[curr.batt.is_present]);
	cflush();
	DUMP(requested_voltage, "%dmV");
	DUMP(requested_current, "%dmA");
#ifdef CONFIG_CHARGER_OTG
	DUMP(output_current, "%dmA");
#endif
#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
	DUMP(input_voltage, "%dmV");
#endif
	ccprintf("chg_ctl_mode = %d\n", chg_ctl_mode);
	ccprintf("manual_voltage = %d\n", manual_voltage);
	ccprintf("manual_current = %d\n", manual_current);
	ccprintf("user_current_limit = %dmA\n", user_current_limit);
	ccprintf("battery_seems_to_be_dead = %d\n", battery_seems_to_be_dead);
	ccprintf("battery_seems_to_be_disconnected = %d\n",
		 battery_seems_to_be_disconnected);
	ccprintf("battery_was_removed = %d\n", battery_was_removed);
	ccprintf("debug output = %s\n", debugging ? "on" : "off");
#undef DUMP
}

static void show_charging_progress(void)
{
	int rv = 0, minutes, to_full;

#ifdef CONFIG_BATTERY_SMART
	/*
	 * Predicted remaining battery capacity based on AverageCurrent().
	 * 65535 = Battery is not being discharged.
	 */
	if (!battery_time_to_empty(&minutes) && minutes != 65535)
		to_full = 0;
	/*
	 * Predicted time-to-full charge based on AverageCurrent().
	 * 65535 = Battery is not being discharged.
	 */
	else if (!battery_time_to_full(&minutes) && minutes != 65535)
		to_full = 1;
	/*
	 * If both time to empty and time to full have invalid data, consider
	 * measured current from the coulomb counter and ac present status to
	 * decide whether battery is about to full or empty.
	 */
	else {
		to_full = curr.batt_is_charging;
		rv = EC_ERROR_UNKNOWN;
	}
#else
	if (!curr.batt_is_charging) {
		rv = battery_time_to_empty(&minutes);
		to_full = 0;
	} else {
		rv = battery_time_to_full(&minutes);
		to_full = 1;
	}
#endif

	if (rv)
		CPRINTS("Battery %d%% (Display %d.%d %%) / ??h:?? %s%s",
			curr.batt.state_of_charge,
			curr.batt.display_charge / 10,
			curr.batt.display_charge % 10,
			to_full ? "to full" : "to empty",
			is_full ? ", not accepting current" : "");
	else
		CPRINTS("Battery %d%% (Display %d.%d %%) / %dh:%d %s%s",
			curr.batt.state_of_charge,
			curr.batt.display_charge / 10,
			curr.batt.display_charge % 10,
			minutes / 60, minutes % 60,
			to_full ? "to full" : "to empty",
			is_full ? ", not accepting current" : "");

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
	CPRINTS("Base battery %d%%", charge_base);
#endif

	if (debugging) {
		ccprintf("battery:\n");
		print_battery_debug();
		ccprintf("charger:\n");
		print_charger_debug();
		ccprintf("chg:\n");
		dump_charge_state();
	}
}

/* Calculate if battery is full based on whether it is accepting charge */
static int calc_is_full(void)
{
	static int __bss_slow ret;

	/* If bad state of charge reading, return last value */
	if (curr.batt.flags & BATT_FLAG_BAD_STATE_OF_CHARGE ||
	    curr.batt.state_of_charge > 100)
		return ret;
	/*
	 * Battery is full when SoC is above 90% and battery desired current
	 * is 0. This is necessary because some batteries stop charging when
	 * the SoC still reports <100%, so we need to check desired current
	 * to know if it is actually full.
	 */
	ret = (curr.batt.state_of_charge >= 90 &&
	       curr.batt.desired_current == 0);
	return ret;
}

/*
 * Ask the charger for some voltage and current. If either value is 0,
 * charging is disabled; otherwise it's enabled. Negative values are ignored.
 */
static int charge_request(int voltage, int current)
{
	int r1 = EC_SUCCESS, r2 = EC_SUCCESS, r3 = EC_SUCCESS;
	static int __bss_slow prev_volt, prev_curr;

	if (!voltage || !current) {
#ifdef CONFIG_CHARGER_NARROW_VDC
		current = 0;
		/*
		 * With NVDC charger, keep VSYS voltage higher than battery,
		 * otherwise the BGATE FET body diode would conduct and
		 * discharge the battery.
		 */
		voltage = charger_closest_voltage(
			curr.batt.voltage + charger_get_info()->voltage_step);
		/* If the battery is full, request the max voltage. */
		if (is_full)
			voltage = battery_get_info()->voltage_max;
		/* And handle dead battery case */
		voltage = MAX(voltage, battery_get_info()->voltage_normal);
#else
		voltage = current = 0;
#endif
	}

	if (curr.ac) {
		if (prev_volt != voltage || prev_curr != current)
			CPRINTS("%s(%dmV, %dmA)", __func__, voltage, current);
	}

	/*
	 * Set current before voltage so that if we are just starting
	 * to charge, we allow some time (i2c delay) for charging circuit to
	 * start at a voltage just above battery voltage before jumping
	 * up. This helps avoid large current spikes when connecting
	 * battery.
	 */
	if (current >= 0)
		r2 = charger_set_current(current);
	if (r2 != EC_SUCCESS)
		problem(PR_SET_CURRENT, r2);

	if (voltage >= 0)
		r1 = charger_set_voltage(voltage);
	if (r1 != EC_SUCCESS)
		problem(PR_SET_VOLTAGE, r1);

	/*
	 * Set the charge inhibit bit when possible as it appears to save
	 * power in some cases (e.g. Nyan with BQ24735).
	 */
	if (voltage > 0 || current > 0)
		r3 = charger_set_mode(0);
	else
		r3 = charger_set_mode(CHARGE_FLAG_INHIBIT_CHARGE);
	if (r3 != EC_SUCCESS)
		problem(PR_SET_MODE, r3);

	/*
	 * Only update if the request worked, so we'll keep trying on failures.
	 */
	if (!r1 && !r2) {
		prev_volt = voltage;
		prev_curr = current;
	}

	return r1 ? r1 : r2;
}

void chgstate_set_manual_current(int curr_ma)
{
	if (curr_ma < 0)
		manual_current = -1;
	else
		manual_current = charger_closest_current(curr_ma);
}

void chgstate_set_manual_voltage(int volt_mv)
{
	manual_voltage = charger_closest_voltage(volt_mv);
}

/* Force charging off before the battery is full. */
static int set_chg_ctrl_mode(enum ec_charge_control_mode mode)
{
	if (mode == CHARGE_CONTROL_NORMAL) {
		chg_ctl_mode = mode;
		manual_current = -1;
		manual_voltage = -1;
	} else {
		/*
		 * Changing mode is only meaningful if external power is
		 * present. If it's not present we can't charge anyway.
		 */
		if (!curr.ac)
			return EC_ERROR_NOT_POWERED;

		chg_ctl_mode = mode;
		manual_current = 0;
		manual_voltage = 0;
	}

	return EC_SUCCESS;
}

/* True if we know the battery temp is too high or too low */
static inline int battery_too_hot(int batt_temp_c)
{
	return (!(curr.batt.flags & BATT_FLAG_BAD_TEMPERATURE) &&
		(batt_temp_c > batt_info->discharging_max_c ||
		 batt_temp_c < batt_info->discharging_min_c));
}

__attribute__((weak)) uint8_t board_set_battery_level_shutdown(void)
{
	return BATTERY_LEVEL_SHUTDOWN;
}

/* True if we know the charge is too low, or we know the voltage is too low. */
static inline int battery_too_low(void)
{
	return ((!(curr.batt.flags & BATT_FLAG_BAD_STATE_OF_CHARGE) &&
		 curr.batt.state_of_charge < battery_level_shutdown) ||
		(!(curr.batt.flags & BATT_FLAG_BAD_VOLTAGE) &&
		 curr.batt.voltage <= batt_info->voltage_min));
}

__attribute__((weak))
enum critical_shutdown board_critical_shutdown_check(
		struct charge_state_data *curr)
{
#ifdef CONFIG_BATTERY_CRITICAL_SHUTDOWN_CUT_OFF
	return CRITICAL_SHUTDOWN_CUTOFF;
#elif defined(CONFIG_HIBERNATE)
	return CRITICAL_SHUTDOWN_HIBERNATE;
#else
	return CRITICAL_SHUTDOWN_IGNORE;
#endif
}

static int is_battery_critical(void)
{
	int batt_temp_c = DECI_KELVIN_TO_CELSIUS(curr.batt.temperature);

	/*
	 * TODO(crosbug.com/p/27642): The thermal loop should watch the battery
	 * temp, so it can turn fans on.
	 */
	if (battery_too_hot(batt_temp_c)) {
		CPRINTS("Batt temp out of range: %dC", batt_temp_c);
		return 1;
	}

	if (battery_too_low() && !curr.batt_is_charging) {
		CPRINTS("Low battery: %d%%, %dmV",
			curr.batt.state_of_charge, curr.batt.voltage);
		return 1;
	}

	return 0;
}

 /*
  * If the battery is at extremely low charge (and discharging) or extremely
  * high temperature, the EC will notify the AP and start a timer. If the
  * critical condition is not corrected before the timeout expires, the EC
  * will shut down the AP (if the AP is not already off) and then optionally
  * hibernate or cut off battery.
  */
static int shutdown_on_critical_battery(void)
{
	if (!is_battery_critical()) {
		/* Reset shutdown warning time */
		shutdown_target_time.val = 0;
		return 0;
	}

	if (!shutdown_target_time.val) {
		/* Start count down timer */
		CPRINTS("Start shutdown due to critical battery");
		shutdown_target_time.val = get_time().val
				+ CRITICAL_BATTERY_SHUTDOWN_TIMEOUT_US;
#ifdef CONFIG_HOSTCMD_EVENTS
		if (!chipset_in_state(CHIPSET_STATE_ANY_OFF))
			host_set_single_event(EC_HOST_EVENT_BATTERY_SHUTDOWN);
#endif
		return 1;
	}

	if (!timestamp_expired(shutdown_target_time, 0))
		return 1;

	/* Timer has expired */
	if (chipset_in_state(CHIPSET_STATE_ANY_OFF)) {
		switch (board_critical_shutdown_check(&curr)) {
		case CRITICAL_SHUTDOWN_HIBERNATE:
			CPRINTS("Hibernate due to critical battery");
			system_hibernate(0, 0);
			break;
		case CRITICAL_SHUTDOWN_CUTOFF:
			CPRINTS("Cutoff due to critical battery");
			/* Ensure logs are flushed. */
			cflush();
			board_cut_off_battery();
			break;
		case CRITICAL_SHUTDOWN_IGNORE:
		default:
			break;
		}
	} else {
		/* Timeout waiting for AP to shut down, so kill it */
		CPRINTS(
		  "charge force shutdown due to critical battery");
		chipset_force_shutdown(CHIPSET_SHUTDOWN_BATTERY_CRIT);
	}

	return 1;
}

/*
 * Send host events as the battery charge drops below certain thresholds.
 * We handle forced shutdown and other actions elsewhere; this is just for the
 * host events. We send these even if the AP is off, since the AP will read and
 * discard any events it doesn't care about the next time it wakes up.
 */
static void notify_host_of_low_battery_charge(void)
{
	/* We can't tell what the current charge is. Assume it's okay. */
	if (curr.batt.flags & BATT_FLAG_BAD_STATE_OF_CHARGE)
		return;

#ifdef CONFIG_HOSTCMD_EVENTS
	if (curr.batt.state_of_charge <= BATTERY_LEVEL_LOW &&
	    prev_charge > BATTERY_LEVEL_LOW)
		host_set_single_event(EC_HOST_EVENT_BATTERY_LOW);

	if (curr.batt.state_of_charge <= BATTERY_LEVEL_CRITICAL &&
	    prev_charge > BATTERY_LEVEL_CRITICAL)
		host_set_single_event(EC_HOST_EVENT_BATTERY_CRITICAL);
#endif
}

static void set_charge_state(enum charge_state_v2 state)
{
	prev_state = curr.state;
	curr.state = state;
}

static void notify_host_of_low_battery_voltage(void)
{
#ifdef CONFIG_THROTTLE_AP_ON_BAT_VOLTAGE
	if ((curr.batt.flags & BATT_FLAG_BAD_VOLTAGE) ||
	    chipset_in_state(CHIPSET_STATE_ANY_OFF))
		return;

	if (!uvp_throttle_start_time.val &&
	    (curr.batt.voltage < BAT_LOW_VOLTAGE_THRESH)) {
		throttle_ap(THROTTLE_ON, THROTTLE_SOFT,
			    THROTTLE_SRC_BAT_VOLTAGE);
		uvp_throttle_start_time = get_time();
	} else if (uvp_throttle_start_time.val &&
		   (curr.batt.voltage < BAT_LOW_VOLTAGE_THRESH +
		    BAT_UVP_HYSTERESIS)) {
		/*
		 * Reset the timer when we are not sure if VBAT can stay
		 * above BAT_LOW_VOLTAGE_THRESH after we stop throttling.
		 */
		uvp_throttle_start_time = get_time();
	} else if (uvp_throttle_start_time.val &&
		   (get_time().val > uvp_throttle_start_time.val +
		     BAT_UVP_TIMEOUT_US)) {
		throttle_ap(THROTTLE_OFF, THROTTLE_SOFT,
			    THROTTLE_SRC_BAT_VOLTAGE);
		uvp_throttle_start_time.val = 0;
	}
#endif
}

static void notify_host_of_over_current(struct batt_params *batt)
{
#ifdef CONFIG_THROTTLE_AP_ON_BAT_DISCHG_CURRENT
	static timestamp_t ocp_throttle_start_time;

	if (batt->flags & BATT_FLAG_BAD_CURRENT)
		return;

	if ((!ocp_throttle_start_time.val &&
	     (batt->current < -BAT_MAX_DISCHG_CURRENT)) ||
	    (ocp_throttle_start_time.val &&
	     (batt->current < -BAT_MAX_DISCHG_CURRENT + BAT_OCP_HYSTERESIS))) {
		ocp_throttle_start_time = get_time();
		throttle_ap(THROTTLE_ON, THROTTLE_SOFT,
			    THROTTLE_SRC_BAT_DISCHG_CURRENT);
	} else if (ocp_throttle_start_time.val &&
		   (get_time().val > ocp_throttle_start_time.val +
		    BAT_OCP_TIMEOUT_US)) {
		/*
		 * Clear the timer and notify AP to stop throttling if
		 * we haven't seen over current for BAT_OCP_TIMEOUT_US.
		 */
		ocp_throttle_start_time.val = 0;
		throttle_ap(THROTTLE_OFF, THROTTLE_SOFT,
			    THROTTLE_SRC_BAT_DISCHG_CURRENT);
	}
#endif
}

const struct batt_params *charger_current_battery_params(void)
{
	return &curr.batt;
}

/*****************************************************************************/
/* Hooks */
void charger_init(void)
{
	/* Initialize current state */
	memset(&curr, 0, sizeof(curr));
	curr.batt.is_present = BP_NOT_SURE;
	/* Manual voltage/current set to off */
	manual_voltage = -1;
	manual_current = -1;
}
DECLARE_HOOK(HOOK_INIT, charger_init, HOOK_PRIO_DEFAULT);

/* Wake up the task when something important happens */
static void charge_wakeup(void)
{
	task_wake(TASK_ID_CHARGER);
}
DECLARE_HOOK(HOOK_CHIPSET_RESUME, charge_wakeup, HOOK_PRIO_DEFAULT);
DECLARE_HOOK(HOOK_AC_CHANGE, charge_wakeup, HOOK_PRIO_DEFAULT);

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
/* Reset the base on S5->S0 transition. */
DECLARE_HOOK(HOOK_CHIPSET_STARTUP, board_base_reset, HOOK_PRIO_DEFAULT);
#endif

#ifdef CONFIG_THROTTLE_AP_ON_BAT_VOLTAGE
static void bat_low_voltage_throttle_reset(void)
{
	uvp_throttle_start_time.val = 0;
}
DECLARE_HOOK(HOOK_CHIPSET_SHUTDOWN,
	     bat_low_voltage_throttle_reset,
	     HOOK_PRIO_DEFAULT);
#endif

static int get_desired_input_current(enum battery_present batt_present,
				     const struct charger_info * const info)
{
	if (batt_present == BP_YES || system_is_locked() || base_connected) {
#ifdef CONFIG_CHARGE_MANAGER
		int ilim = charge_manager_get_charger_current();
		return ilim == CHARGE_CURRENT_UNINITIALIZED ?
			CHARGE_CURRENT_UNINITIALIZED :
			MAX(CONFIG_CHARGER_INPUT_CURRENT, ilim);
#else
		return CONFIG_CHARGER_INPUT_CURRENT;
#endif
	} else {
#ifdef CONFIG_USB_POWER_DELIVERY
		return MIN(PD_MAX_CURRENT_MA, info->input_current_max);
#else
		return info->input_current_max;
#endif
	}
}

/* Main loop */
void charger_task(void *u)
{
	int sleep_usec;
	int battery_critical;
	int need_static = 1;
	const struct charger_info * const info = charger_get_info();

	/* Get the battery-specific values */
	batt_info = battery_get_info();

	prev_ac = prev_charge = prev_disp_charge = -1;
	chg_ctl_mode = CHARGE_CONTROL_NORMAL;
	shutdown_target_time.val = 0UL;
	battery_seems_to_be_dead = 0;
#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
	base_responsive = 0;
	curr.input_voltage = CHARGE_VOLTAGE_UNINITIALIZED;
	battery_dynamic[BATT_IDX_BASE].flags = EC_BATT_FLAG_INVALID_DATA;
	charge_base = -1;
#endif

	/*
	 * If system is not locked and we don't have a battery to live on,
	 * then use max input current limit so that we can pull as much power
	 * as needed.
	 */
	battery_get_params(&curr.batt);
	prev_bp = BP_NOT_INIT;
	curr.desired_input_current = get_desired_input_current(
			curr.batt.is_present, info);

	battery_level_shutdown = board_set_battery_level_shutdown();

	while (1) {

		/* Let's see what's going on... */
		curr.ts = get_time();
		sleep_usec = 0;
		problems_exist = 0;
		battery_critical = 0;
		curr.ac = extpower_is_present();
#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
		/*
		 * When base is powering the system, make sure curr.ac stays 0.
		 * TODO(b:71723024): Fix extpower_is_present() in hardware
		 * instead.
		 */
		if (base_responsive && prev_current_base < 0)
			curr.ac = 0;

		/* System is off: if AC gets connected, reset the base. */
		if (chipset_in_state(CHIPSET_STATE_ANY_OFF) &&
				!prev_ac && curr.ac)
			board_base_reset();
#endif
		if (curr.ac != prev_ac) {
			if (curr.ac) {
				/*
				 * Some chargers are unpowered when the AC is
				 * off, so we'll reinitialize it when AC
				 * comes back and set the input current limit.
				 * Try again if it fails.
				 */
				int rv = charger_post_init();
				if (rv != EC_SUCCESS) {
					problem(PR_POST_INIT, rv);
				} else {
					if (curr.desired_input_current !=
					    CHARGE_CURRENT_UNINITIALIZED)
						rv = charger_set_input_current(
						    curr.desired_input_current);
					if (rv != EC_SUCCESS)
						problem(PR_SET_INPUT_CURR, rv);
					else
						prev_ac = curr.ac;
				}
			} else {
				/* Some things are only meaningful on AC */
				chg_ctl_mode = CHARGE_CONTROL_NORMAL;
				battery_seems_to_be_dead = 0;
				prev_ac = curr.ac;
			}
		}

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
		update_base_battery_info();
#endif

		charger_get_params(&curr.chg);
		battery_get_params(&curr.batt);

		if (prev_bp != curr.batt.is_present) {
			prev_bp = curr.batt.is_present;

			/* Update battery info due to change of battery */
			batt_info = battery_get_info();
			need_static = 1;

			curr.desired_input_current =
				get_desired_input_current(prev_bp, info);
			if (curr.desired_input_current !=
			    CHARGE_CURRENT_UNINITIALIZED)
				charger_set_input_current(
					curr.desired_input_current);
			hook_notify(HOOK_BATTERY_SOC_CHANGE);
		}

		/*
		 * TODO(crosbug.com/p/27527). Sometimes the battery thinks its
		 * temperature is 6280C, which seems a bit high. Let's ignore
		 * anything above the boiling point of tungsten until this bug
		 * is fixed. If the battery is really that warm, we probably
		 * have more urgent problems.
		 */
		if (curr.batt.temperature > CELSIUS_TO_DECI_KELVIN(5660)) {
			CPRINTS("ignoring ridiculous batt.temp of %dC",
				 DECI_KELVIN_TO_CELSIUS(curr.batt.temperature));
			curr.batt.flags |= BATT_FLAG_BAD_TEMPERATURE;
		}

		/* If the battery thinks it's above 100%, don't believe it */
		if (curr.batt.state_of_charge > 100) {
			CPRINTS("ignoring ridiculous batt.soc of %d%%",
				curr.batt.state_of_charge);
			curr.batt.flags |= BATT_FLAG_BAD_STATE_OF_CHARGE;
		}

		notify_host_of_over_current(&curr.batt);

		/*
		 * Now decide what we want to do about it. We'll normally just
		 * pass along whatever the battery wants to the charger. Note
		 * that if battery_get_params() can't get valid values from the
		 * battery it uses (0, 0), which is probably safer than blindly
		 * applying power to a battery we can't talk to.
		 */
		curr.requested_voltage = curr.batt.desired_voltage;
		curr.requested_current = curr.batt.desired_current;

		/* If we *know* there's no battery, wait for one to appear. */
		if (curr.batt.is_present == BP_NO) {
			if (!curr.ac)
				CPRINTS("running with no battery and no AC");
			set_charge_state(ST_IDLE);
			curr.batt_is_charging = 0;
			battery_was_removed = 1;
			goto wait_for_it;
		}

		/*
		 * If we had trouble talking to the battery or the charger, we
		 * should probably do nothing for a bit, and if it doesn't get
		 * better then flag it as an error.
		 */
		if (curr.chg.flags & CHG_FLAG_BAD_ANY)
			problem(PR_CHG_FLAGS, curr.chg.flags);
		if (curr.batt.flags & BATT_FLAG_BAD_ANY)
			problem(PR_BATT_FLAGS, curr.batt.flags);

		/*
		 * If AC is present, check if input current is sufficient to
		 * actually charge battery.
		 */
		curr.batt_is_charging = curr.ac && (curr.batt.current >= 0);

		/* Don't let the battery hurt itself. */
		battery_critical = shutdown_on_critical_battery();

		if (!curr.ac) {
			set_charge_state(ST_DISCHARGE);
			goto wait_for_it;
		}

		/* Okay, we're on AC and we should have a battery. */

		/* Used for factory tests. */
		if (chg_ctl_mode != CHARGE_CONTROL_NORMAL) {
			set_charge_state(ST_IDLE);
			goto wait_for_it;
		}

		/* If the battery is not responsive, try to wake it up. */
		if (!(curr.batt.flags & BATT_FLAG_RESPONSIVE)) {
			if (battery_seems_to_be_dead || battery_is_cut_off()) {
				/* It's dead, do nothing */
				set_charge_state(ST_IDLE);
				curr.requested_voltage = 0;
				curr.requested_current = 0;
			} else if (curr.state == ST_PRECHARGE &&
				   (get_time().val > precharge_start_time.val +
				    PRECHARGE_TIMEOUT_US)) {
				/* We've tried long enough, give up */
				CPRINTS("battery seems to be dead");
				battery_seems_to_be_dead = 1;
				set_charge_state(ST_IDLE);
				curr.requested_voltage = 0;
				curr.requested_current = 0;
			} else {
				/* See if we can wake it up */
				if (curr.state != ST_PRECHARGE) {
					CPRINTS("try to wake battery");
					precharge_start_time = get_time();
					need_static = 1;
				}
				set_charge_state(ST_PRECHARGE);
				curr.requested_voltage =
					batt_info->voltage_max;
				curr.requested_current =
					batt_info->precharge_current;
			}
			goto wait_for_it;
		} else {
			/* The battery is responding. Yay. Try to use it. */
#ifdef CONFIG_BATTERY_REQUESTS_NIL_WHEN_DEAD
			/*
			 * TODO (crosbug.com/p/29467): remove this workaround
			 * for dead battery that requests no voltage/current
			 */
			if (curr.requested_voltage == 0 &&
			    curr.requested_current == 0 &&
			    curr.batt.state_of_charge == 0) {
				/* Battery is dead, give precharge current */
				curr.requested_voltage =
					batt_info->voltage_max;
				curr.requested_current =
					batt_info->precharge_current;
			} else
#endif
#ifdef CONFIG_BATTERY_REVIVE_DISCONNECT
			/*
			 * Always check the disconnect state.  This is because
			 * the battery disconnect state is one of the items used
			 * to decide whether or not to leave safe mode.
			 */
			battery_seems_to_be_disconnected =
				battery_get_disconnect_state() ==
				BATTERY_DISCONNECTED;

			if (curr.requested_voltage == 0 &&
			    curr.requested_current == 0 &&
			    battery_seems_to_be_disconnected) {
				/*
				 * Battery is in disconnect state. Apply a
				 * current to kick it out of this state.
				 */
				CPRINTS("found battery in disconnect state");
				curr.requested_voltage =
					batt_info->voltage_max;
				curr.requested_current =
					batt_info->precharge_current;
			} else
#endif
			if (curr.state == ST_PRECHARGE ||
			    battery_seems_to_be_dead ||
			    battery_was_removed) {
				CPRINTS("battery woke up");

				/* Update the battery-specific values */
				batt_info = battery_get_info();
				need_static = 1;
			    }

			battery_seems_to_be_dead = battery_was_removed = 0;
			set_charge_state(ST_CHARGE);
		}

wait_for_it:
#ifdef CONFIG_CHARGER_PROFILE_OVERRIDE
		if (chg_ctl_mode == CHARGE_CONTROL_NORMAL) {
			sleep_usec = charger_profile_override(&curr);
			if (sleep_usec < 0)
				problem(PR_CUSTOM, sleep_usec);
		}
#endif

#ifdef CONFIG_CHARGE_MANAGER
		if (curr.batt.state_of_charge >=
		    CONFIG_CHARGE_MANAGER_BAT_PCT_SAFE_MODE_EXIT &&
		    !battery_seems_to_be_disconnected) {
			/*
			 * Sometimes the fuel gauge will report that it has
			 * sufficient state of charge and remaining capacity,
			 * but in actuality it doesn't.  When the EC sees that
			 * information, it trusts it and leaves charge manager
			 * safe mode.  Doing so will allow CHARGE_PORT_NONE to
			 * be selected, thereby cutting off the input FETs.
			 * When the battery cannot provide the charge it claims,
			 * the system loses power, shuts down, and the battery
			 * is not charged even though the charger is plugged in.
			 * By waiting 500ms, we can avoid the selection of
			 * CHARGE_PORT_NONE around init time and not cut off the
			 * input FETs.
			 */
			msleep(500);
			charge_manager_leave_safe_mode();
		}
#endif

		/* Keep the AP informed */
		if (need_static)
			need_static = update_static_battery_info();
		/* Wait on the dynamic info until the static info is good. */
		if (!need_static)
			update_dynamic_battery_info();
		notify_host_of_low_battery_charge();
		notify_host_of_low_battery_voltage();

		/* And the EC console */
		is_full = calc_is_full();
		if ((!(curr.batt.flags & BATT_FLAG_BAD_STATE_OF_CHARGE) &&
		    curr.batt.state_of_charge != prev_charge) ||
#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
		    (charge_base != prev_charge_base) ||
#endif
		    (is_full != prev_full) ||
		    (curr.state != prev_state) ||
		    (curr.batt.display_charge != prev_disp_charge)) {
			show_charging_progress();
			prev_charge = curr.batt.state_of_charge;
			prev_disp_charge = curr.batt.display_charge;
#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
			prev_charge_base = charge_base;
#endif
			hook_notify(HOOK_BATTERY_SOC_CHANGE);
		}
		prev_full = is_full;

#ifndef CONFIG_CHARGER_MAINTAIN_VBAT
		/* Turn charger off if it's not needed */
		if (curr.state == ST_IDLE || curr.state == ST_DISCHARGE) {
			curr.requested_voltage = 0;
			curr.requested_current = 0;
		}
#endif

		/* Apply external limits */
		if (curr.requested_current > user_current_limit)
			curr.requested_current = user_current_limit;

		/* Round to valid values */
		curr.requested_voltage =
			charger_closest_voltage(curr.requested_voltage);
		curr.requested_current =
			charger_closest_current(curr.requested_current);

		/* Charger only accpets request when AC is on. */
		if (curr.ac) {
			/*
			 * Some batteries would wake up after cut-off if we keep
			 * charging it. Thus, we only charge when AC is on and
			 * battery is not cut off yet.
			 */
			if (battery_is_cut_off()) {
				curr.requested_voltage = 0;
				curr.requested_current = 0;
			}
			/*
			 * As a safety feature, some chargers will stop
			 * charging if we don't communicate with it frequently
			 * enough. In manual mode, we'll just tell it what it
			 * knows.
			 */
			else {
				if (manual_voltage != -1)
					curr.requested_voltage = manual_voltage;
				if (manual_current != -1)
					curr.requested_current = manual_current;
			}
		} else {
#ifndef CONFIG_CHARGER_MAINTAIN_VBAT
			curr.requested_voltage = charger_closest_voltage(
				curr.batt.voltage + info->voltage_step);
			curr.requested_current = -1;
#endif
#ifdef CONFIG_EC_EC_COMM_BATTERY_SLAVE
			/*
			 * On EC-EC slave, do not charge if curr.ac is 0: there
			 * might still be some external power available but we
			 * do not want to use it for charging.
			 */
			curr.requested_current = 0;
#endif
		}

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
		charge_allocate_input_current_limit();
#else
		charge_request(curr.requested_voltage, curr.requested_current);
#endif

		/* How long to sleep? */
		if (problems_exist)
			/* If there are errors, don't wait very long. */
			sleep_usec = CHARGE_POLL_PERIOD_SHORT;
		else if (sleep_usec <= 0) {
			/* default values depend on the state */
			if (!curr.ac &&
			    (curr.state == ST_IDLE ||
			    curr.state == ST_DISCHARGE)) {
#ifdef CONFIG_CHARGER_OTG
				int output_current = curr.output_current;
#else
				int output_current = 0;
#endif
				/*
				 * If AP is off and we do not provide power, we
				 * can sleep a long time.
				 */
				if (chipset_in_state(CHIPSET_STATE_ANY_OFF |
						     CHIPSET_STATE_ANY_SUSPEND)
						&& output_current == 0)
					sleep_usec =
						CHARGE_POLL_PERIOD_VERY_LONG;
				else
					/* Discharging, not too urgent */
					sleep_usec = CHARGE_POLL_PERIOD_LONG;
			} else {
				/* AC present, so pay closer attention */
				sleep_usec = CHARGE_POLL_PERIOD_CHARGE;
			}
		}

		/* Adjust for time spent in this loop */
		sleep_usec -= (int)(get_time().val - curr.ts.val);
		if (sleep_usec < CHARGE_MIN_SLEEP_USEC)
			sleep_usec = CHARGE_MIN_SLEEP_USEC;
		else if (sleep_usec > CHARGE_MAX_SLEEP_USEC)
			sleep_usec = CHARGE_MAX_SLEEP_USEC;

		/*
		 * If battery is critical, ensure that the sleep time is not
		 * very long since we might want to hibernate or cut-off
		 * battery sooner.
		 */
		if (battery_critical &&
		    (sleep_usec > CRITICAL_BATTERY_SHUTDOWN_TIMEOUT_US))
			sleep_usec = CRITICAL_BATTERY_SHUTDOWN_TIMEOUT_US;

		task_wait_event(sleep_usec);
	}
}


/*****************************************************************************/
/* Exported functions */

int charge_want_shutdown(void)
{
	return (curr.state == ST_DISCHARGE) &&
		!(curr.batt.flags & BATT_FLAG_BAD_STATE_OF_CHARGE) &&
		(curr.batt.state_of_charge < battery_level_shutdown);
}

int charge_prevent_power_on(int power_button_pressed)
{
	int prevent_power_on = 0;
	struct batt_params params;
	struct batt_params *current_batt_params = &curr.batt;
#ifdef CONFIG_CHARGER_MIN_BAT_PCT_FOR_POWER_ON
	static int automatic_power_on = 1;
#endif

	/* If battery params seem uninitialized then retrieve them */
	if (current_batt_params->is_present == BP_NOT_SURE) {
		battery_get_params(&params);
		current_batt_params = &params;
	}

#ifdef CONFIG_CHARGER_MIN_BAT_PCT_FOR_POWER_ON

	/*
	 * Remember that a power button was pressed, and assume subsequent
	 * power-ups are user-requested and non-automatic.
	 */
	if (power_button_pressed)
		automatic_power_on = 0;
	/*
	 * Require a minimum battery level to power on and ensure that the
	 * battery can provide power to the system.
	 */
	if (current_batt_params->is_present != BP_YES ||
#ifdef CONFIG_BATTERY_MEASURE_IMBALANCE
	    (current_batt_params->flags & BATT_FLAG_IMBALANCED_CELL &&
		current_batt_params->state_of_charge <
		CONFIG_CHARGER_MIN_BAT_PCT_IMBALANCED_POWER_ON) ||
#endif
#ifdef CONFIG_BATTERY_REVIVE_DISCONNECT
	    battery_get_disconnect_state() != BATTERY_NOT_DISCONNECTED ||
#endif
	    current_batt_params->state_of_charge <
		CONFIG_CHARGER_MIN_BAT_PCT_FOR_POWER_ON)
		prevent_power_on = 1;

#if defined(CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON) && \
	defined(CONFIG_CHARGE_MANAGER)
	/* However, we can power on if a sufficient charger is present. */
	if (prevent_power_on) {
		if (charge_manager_get_power_limit_uw() >=
		    CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON * 1000)
			prevent_power_on = 0;
#if defined(CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON_WITH_BATT) && \
	defined(CONFIG_CHARGER_MIN_BAT_PCT_FOR_POWER_ON_WITH_AC)
		else if (charge_manager_get_power_limit_uw() >=
		    CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON_WITH_BATT * 1000
#ifdef CONFIG_BATTERY_REVIVE_DISCONNECT
		    && battery_get_disconnect_state() ==
							BATTERY_NOT_DISCONNECTED
#endif
		    && (current_batt_params->state_of_charge >=
			CONFIG_CHARGER_MIN_BAT_PCT_FOR_POWER_ON_WITH_AC))
			prevent_power_on = 0;
#endif
	}
#endif /* CONFIG_CHARGE_MANAGER && CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON */

	/*
	 * Factory override: Always allow power on if WP is disabled,
	 * except when auto-power-on at EC startup and the battery
	 * is physically present.
	 */
	prevent_power_on &= (system_is_locked() || (automatic_power_on
#ifdef CONFIG_BATTERY_HW_PRESENT_CUSTOM
				    && battery_hw_present() == BP_YES
#endif
				     ));
#endif /* CONFIG_CHARGER_MIN_BAT_PCT_FOR_POWER_ON */

#ifdef CONFIG_CHARGE_MANAGER
	/* Always prevent power on until charge current is initialized */
	if (extpower_is_present() &&
	    (charge_manager_get_charger_current() ==
	     CHARGE_CURRENT_UNINITIALIZED))
		prevent_power_on = 1;
#ifdef CONFIG_BATTERY_HW_PRESENT_CUSTOM
	/*
	 * If battery is NOT physically present then prevent power on until
	 * a sufficient charger is present.
	 */
	if (extpower_is_present() && battery_hw_present() == BP_NO
#ifdef CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON
	    && charge_manager_get_power_limit_uw() <
		CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON * 1000
#endif /* CONFIG_CHARGER_MIN_POWER_MW_FOR_POWER_ON */
	    )
		prevent_power_on = 1;
#endif /* CONFIG_BATTERY_HW_PRESENT_CUSTOM */
#endif /* CONFIG_CHARGE_MANAGER */

	/*
	 * Prevent power on if there is no battery nor ac power. This
	 * happens when the servo is powering the EC to flash it. Only include
	 * this logic for boards in initial bring up phase since this won't
	 * happen for released boards.
	 */
#ifdef CONFIG_SYSTEM_UNLOCKED
	if (!current_batt_params->is_present && !curr.ac)
		prevent_power_on = 1;
#endif /* CONFIG_SYSTEM_UNLOCKED */

	return prevent_power_on;
}

static int battery_near_full(void)
{
	if (charge_get_percent() < BATTERY_LEVEL_NEAR_FULL)
		return 0;

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
	if (charge_base > -1 && charge_base < BATTERY_LEVEL_NEAR_FULL)
		return 0;
#endif

	return 1;
}

enum charge_state charge_get_state(void)
{
	switch (curr.state) {
	case ST_IDLE:
		if (battery_seems_to_be_dead || curr.batt.is_present == BP_NO)
			return PWR_STATE_ERROR;
		return PWR_STATE_IDLE;
	case ST_DISCHARGE:
#ifdef CONFIG_PWR_STATE_DISCHARGE_FULL
		if (battery_near_full())
			return PWR_STATE_DISCHARGE_FULL;
		else
#endif
			return PWR_STATE_DISCHARGE;
	case ST_CHARGE:
		/* The only difference here is what the LEDs display. */
		if (battery_near_full())
			return PWR_STATE_CHARGE_NEAR_FULL;
		else
			return PWR_STATE_CHARGE;
	case ST_PRECHARGE:
		/* we're in battery discovery mode */
		return PWR_STATE_IDLE;
	default:
		/* Anything else can be considered an error for LED purposes */
		return PWR_STATE_ERROR;
	}
}

uint32_t charge_get_flags(void)
{
	uint32_t flags = 0;

	if (chg_ctl_mode != CHARGE_CONTROL_NORMAL)
		flags |= CHARGE_FLAG_FORCE_IDLE;
	if (curr.ac)
		flags |= CHARGE_FLAG_EXTERNAL_POWER;
	if (curr.batt.flags & BATT_FLAG_RESPONSIVE)
		flags |= CHARGE_FLAG_BATT_RESPONSIVE;

	return flags;
}

int charge_get_percent(void)
{
	/*
	 * Since there's no way to indicate an error to the caller, we'll just
	 * return the last known value. Even if we've never been able to talk
	 * to the battery, that'll be zero, which is probably as good as
	 * anything.
	 */
	return is_full ? 100 : curr.batt.state_of_charge;
}

int charge_get_display_charge(void)
{
	return curr.batt.display_charge;
}

int charge_get_battery_temp(int idx, int *temp_ptr)
{
	if (curr.batt.flags & BATT_FLAG_BAD_TEMPERATURE)
		return EC_ERROR_UNKNOWN;

	/* Battery temp is 10ths of degrees K, temp wants degrees K */
	*temp_ptr = curr.batt.temperature / 10;
	return EC_SUCCESS;
}

int charge_is_consuming_full_input_current(void)
{
	int chg_pct = charge_get_percent();

	return chg_pct > 2 && chg_pct < 95;
}

#ifdef CONFIG_CHARGER_OTG
int charge_set_output_current_limit(int ma, int mv)
{
	int ret;
	int enable = ma > 0;

	if (enable) {
		ret = charger_set_otg_current_voltage(ma, mv);
		if (ret != EC_SUCCESS)
			return ret;
	}

	ret = charger_enable_otg_power(enable);
	if (ret != EC_SUCCESS)
		return ret;

	/* If we start/stop providing power, wake the charger task. */
	if ((curr.output_current == 0 && enable) ||
	    (curr.output_current > 0 && !enable))
		task_wake(TASK_ID_CHARGER);

	curr.output_current = ma;

	return EC_SUCCESS;
}
#endif

int charge_set_input_current_limit(int ma, int mv)
{
#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
	curr.input_voltage = mv;
#endif
	/*
	 * If battery is not present, we are not locked, and base is not
	 * connected then allow system to pull as much input current as needed.
	 * Yes, we might overcurrent the charger but this is no worse than
	 * browning out due to insufficient input current.
	 */
	if (curr.batt.is_present != BP_YES && !system_is_locked() &&
		!base_connected) {
#ifdef CONFIG_USB_POWER_DELIVERY
#if ((PD_MAX_POWER_MW * 1000) / PD_MAX_VOLTAGE_MV != PD_MAX_CURRENT_MA)
		/*
		 * If battery is not present, input current is set to
		 * PD_MAX_CURRENT_MA. If the input power set is greater than
		 * the maximum allowed system power, system might get damaged.
		 * Hence, limit the input current to meet maximum allowed
		 * input system power.
		 */
		if (mv > 0 && mv * curr.desired_input_current >
			PD_MAX_POWER_MW * 1000)
			ma = (PD_MAX_POWER_MW * 1000) / mv;
		else
			return EC_SUCCESS;
#else
		return EC_SUCCESS;
#endif
#endif /* CONFIG_USB_POWER_DELIVERY */
	}

#ifdef CONFIG_CHARGER_MAX_INPUT_CURRENT
	/* Limit input current limit to max limit for this board */
	ma = MIN(ma, CONFIG_CHARGER_MAX_INPUT_CURRENT);
#endif
	curr.desired_input_current = ma;
#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
	/* Wake up charger task to allocate current between lid and base. */
	charge_wakeup();
	return EC_SUCCESS;
#else
	return charger_set_input_current(ma);
#endif
}

/*****************************************************************************/
/* Host commands */

static enum ec_status
charge_command_charge_control(struct host_cmd_handler_args *args)
{
	const struct ec_params_charge_control *p = args->params;
	int rv;

	rv = set_chg_ctrl_mode(p->mode);
	if (rv != EC_SUCCESS)
		return EC_RES_ERROR;

#ifdef CONFIG_CHARGER_DISCHARGE_ON_AC
#ifdef CONFIG_CHARGER_DISCHARGE_ON_AC_CUSTOM
	rv = board_discharge_on_ac(p->mode == CHARGE_CONTROL_DISCHARGE);
#else
	rv = charger_discharge_on_ac(p->mode == CHARGE_CONTROL_DISCHARGE);
#endif
	if (rv != EC_SUCCESS)
		return EC_RES_ERROR;
#endif

	return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_CHARGE_CONTROL, charge_command_charge_control,
		     EC_VER_MASK(1));

static void reset_current_limit(void)
{
	user_current_limit = -1U;
}
DECLARE_HOOK(HOOK_CHIPSET_SUSPEND, reset_current_limit, HOOK_PRIO_DEFAULT);
DECLARE_HOOK(HOOK_CHIPSET_SHUTDOWN, reset_current_limit, HOOK_PRIO_DEFAULT);

static enum ec_status
charge_command_current_limit(struct host_cmd_handler_args *args)
{
	const struct ec_params_current_limit *p = args->params;

	user_current_limit = p->limit;

	return EC_RES_SUCCESS;
}
DECLARE_HOST_COMMAND(EC_CMD_CHARGE_CURRENT_LIMIT, charge_command_current_limit,
		     EC_VER_MASK(0));

static enum ec_status
charge_command_charge_state(struct host_cmd_handler_args *args)
{
	const struct ec_params_charge_state *in = args->params;
	struct ec_response_charge_state *out = args->response;
	uint32_t val;
	int rv = EC_RES_SUCCESS;

	switch (in->cmd) {

	case CHARGE_STATE_CMD_GET_STATE:
		out->get_state.ac = curr.ac;
		out->get_state.chg_voltage = curr.chg.voltage;
		out->get_state.chg_current = curr.chg.current;
		out->get_state.chg_input_current = curr.chg.input_current;
		out->get_state.batt_state_of_charge = curr.batt.state_of_charge;
		args->response_size = sizeof(out->get_state);
		break;

	case CHARGE_STATE_CMD_GET_PARAM:
		val = 0;
#ifdef CONFIG_CHARGER_PROFILE_OVERRIDE
		/* custom profile params */
		if (in->get_param.param >= CS_PARAM_CUSTOM_PROFILE_MIN &&
		    in->get_param.param <= CS_PARAM_CUSTOM_PROFILE_MAX) {
			rv  = charger_profile_override_get_param(
				in->get_param.param, &val);
		} else
#endif
#ifdef CONFIG_CHARGE_STATE_DEBUG
		/* debug params */
		if (in->get_param.param >= CS_PARAM_DEBUG_MIN &&
		    in->get_param.param <= CS_PARAM_DEBUG_MAX) {
			rv = charge_get_charge_state_debug(
				in->get_param.param, &val);
		} else
#endif
			/* standard params */
			switch (in->get_param.param) {
			case CS_PARAM_CHG_VOLTAGE:
				val = curr.chg.voltage;
				break;
			case CS_PARAM_CHG_CURRENT:
				val = curr.chg.current;
				break;
			case CS_PARAM_CHG_INPUT_CURRENT:
				val = curr.chg.input_current;
				break;
			case CS_PARAM_CHG_STATUS:
				val = curr.chg.status;
				break;
			case CS_PARAM_CHG_OPTION:
				val = curr.chg.option;
				break;
			case CS_PARAM_LIMIT_POWER:
#ifdef CONFIG_CHARGER_LIMIT_POWER_THRESH_CHG_MW
				/*
				 * LIMIT_POWER status is based on battery level
				 * and external charger power.
				 */
				if ((curr.batt.is_present != BP_YES ||
				     curr.batt.state_of_charge <
				     CONFIG_CHARGER_LIMIT_POWER_THRESH_BAT_PCT)
				     && charge_manager_get_power_limit_uw() <
				     CONFIG_CHARGER_LIMIT_POWER_THRESH_CHG_MW
				     * 1000 && system_is_locked())
					val = 1;
				else
#endif
					val = 0;
				break;
			default:
				rv = EC_RES_INVALID_PARAM;
			}

		/* got something */
		out->get_param.value = val;
		args->response_size = sizeof(out->get_param);
		break;

	case CHARGE_STATE_CMD_SET_PARAM:
		if (system_is_locked())
			return EC_RES_ACCESS_DENIED;

		val = in->set_param.value;
#ifdef CONFIG_CHARGER_PROFILE_OVERRIDE
		/* custom profile params */
		if (in->set_param.param >= CS_PARAM_CUSTOM_PROFILE_MIN &&
		    in->set_param.param <= CS_PARAM_CUSTOM_PROFILE_MAX) {
			rv  = charger_profile_override_set_param(
				in->set_param.param, val);
		} else
#endif
			switch (in->set_param.param) {
			case CS_PARAM_CHG_VOLTAGE:
				chgstate_set_manual_voltage(val);
				break;
			case CS_PARAM_CHG_CURRENT:
				chgstate_set_manual_current(val);
				break;
			case CS_PARAM_CHG_INPUT_CURRENT:
				if (charger_set_input_current(val))
					rv = EC_RES_ERROR;
				break;
			case CS_PARAM_CHG_STATUS:
			case CS_PARAM_LIMIT_POWER:
				/* Can't set this */
				rv = EC_RES_ACCESS_DENIED;
				break;
			case CS_PARAM_CHG_OPTION:
				if (charger_set_option(val))
					rv = EC_RES_ERROR;
				break;
			default:
				rv = EC_RES_INVALID_PARAM;

			}
		break;

	default:
		CPRINTS("EC_CMD_CHARGE_STATE: bad cmd 0x%x", in->cmd);
		rv = EC_RES_INVALID_PARAM;
	}

	return rv;
}

DECLARE_HOST_COMMAND(EC_CMD_CHARGE_STATE, charge_command_charge_state,
		     EC_VER_MASK(0));

/*****************************************************************************/
/* Console commands */

#ifdef CONFIG_CMD_PWR_AVG

static int command_pwr_avg(int argc, char **argv)
{
	int avg_mv;
	int avg_ma;
	int avg_mw;

	if (argc != 1)
		return EC_ERROR_PARAM_COUNT;

	avg_mv = battery_get_avg_voltage();
	if (avg_mv < 0)
		return EC_ERROR_UNKNOWN;
	avg_ma = battery_get_avg_current();
	avg_mw = avg_mv * avg_ma / 1000;

	ccprintf("mv = %d\nma = %d\nmw = %d\n",
		avg_mv, avg_ma, avg_mw);
	return EC_SUCCESS;
}

DECLARE_CONSOLE_COMMAND(pwr_avg, command_pwr_avg,
			NULL,
			"Get 1 min power average");

#endif /* CONFIG_CMD_PWR_AVG */

static int command_chgstate(int argc, char **argv)
{
	int rv;
	int val;

	if (argc > 1) {
		if (!strcasecmp(argv[1], "idle")) {
			if (argc <= 2)
				return EC_ERROR_PARAM_COUNT;
			if (!parse_bool(argv[2], &val))
				return EC_ERROR_PARAM2;
			rv = set_chg_ctrl_mode(val ? CHARGE_CONTROL_IDLE :
						CHARGE_CONTROL_NORMAL);
			if (rv)
				return rv;
#ifdef CONFIG_CHARGER_DISCHARGE_ON_AC
		} else if (!strcasecmp(argv[1], "discharge")) {
			if (argc <= 2)
				return EC_ERROR_PARAM_COUNT;
			if (!parse_bool(argv[2], &val))
				return EC_ERROR_PARAM2;
			rv = set_chg_ctrl_mode(val ? CHARGE_CONTROL_DISCHARGE :
						CHARGE_CONTROL_NORMAL);
			if (rv)
				return rv;
#ifdef CONFIG_CHARGER_DISCHARGE_ON_AC_CUSTOM
			rv = board_discharge_on_ac(val);
#else
			rv = charger_discharge_on_ac(val);
#endif /* CONFIG_CHARGER_DISCHARGE_ON_AC_CUSTOM */
			if (rv)
				return rv;
#endif /* CONFIG_CHARGER_DISCHARGE_ON_AC */
		} else if (!strcasecmp(argv[1], "debug")) {
			if (argc <= 2)
				return EC_ERROR_PARAM_COUNT;
			if (!parse_bool(argv[2], &debugging))
				return EC_ERROR_PARAM2;
		} else {
			return EC_ERROR_PARAM1;
		}
	}

	dump_charge_state();
	return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(chgstate, command_chgstate,
			"[idle|discharge|debug on|off]",
			"Get/set charge state machine status");

#ifdef CONFIG_EC_EC_COMM_BATTERY_MASTER
static int command_chgdualdebug(int argc, char **argv)
{
	int val;
	char *e;

	if (argc > 1) {
		if (argv[1][0] == 'c') {
			if (argc <= 2)
				return EC_ERROR_PARAM_COUNT;

			if (!strcasecmp(argv[2], "auto")) {
				val = -1;
			} else {
				val = strtoi(argv[2], &e, 0);
				if (*e || val < 0)
					return EC_ERROR_PARAM2;
			}

			manual_ac_current_base = val;
			charge_wakeup();
		} else if (argv[1][0] == 'd') {
			if (argc <= 2)
				return EC_ERROR_PARAM_COUNT;

			if (!strcasecmp(argv[2], "auto")) {
				manual_noac_enabled = 0;
			} else {
				val = strtoi(argv[2], &e, 0);
				if (*e)
					return EC_ERROR_PARAM2;
				manual_noac_current_base = val;
				manual_noac_enabled = 1;
			}
			charge_wakeup();
		} else {
			return EC_ERROR_PARAM1;
		}
	} else {
		ccprintf("Base/Lid: %d%s/%d mA\n",
			 prev_current_base, prev_allow_charge_base ? "+" : "",
			 prev_current_lid);
	}

	return EC_SUCCESS;
}
DECLARE_CONSOLE_COMMAND(chgdualdebug, command_chgdualdebug,
			"[charge (auto|<current>)|discharge (auto|<current>)]",
			"Manually control dual-battery charging algorithm.");
#endif

#ifdef CONFIG_CHARGE_STATE_DEBUG
int charge_get_charge_state_debug(int param, uint32_t *value)
{
	switch (param) {
	case CS_PARAM_DEBUG_CTL_MODE:
		*value = chg_ctl_mode;
		break;
	case CS_PARAM_DEBUG_MANUAL_CURRENT:
		*value = manual_current;
		break;
	case CS_PARAM_DEBUG_MANUAL_VOLTAGE:
		*value = manual_voltage;
		break;
	case CS_PARAM_DEBUG_SEEMS_DEAD:
		*value = battery_seems_to_be_dead;
		break;
	case CS_PARAM_DEBUG_SEEMS_DISCONNECTED:
		*value = battery_seems_to_be_disconnected;
		break;
	case CS_PARAM_DEBUG_BATT_REMOVED:
		*value = battery_was_removed;
		break;
	default:
		*value = 0;
		return EC_ERROR_INVAL;
	}

	return EC_SUCCESS;
}
#endif