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/* Copyright 2020 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.
*/
/* Wheelie board-specific configuration */
#include "adc_chip.h"
#include "button.h"
#include "charge_manager.h"
#include "charge_state_v2.h"
#include "charger.h"
#include "driver/accel_lis2dh.h"
#include "driver/accelgyro_lsm6dsm.h"
#include "driver/bc12/pi3usb9201.h"
#include "driver/charger/sm5803.h"
#include "driver/sync.h"
#include "driver/retimer/tusb544.h"
#include "driver/temp_sensor/thermistor.h"
#include "driver/tcpm/anx7447.h"
#include "driver/tcpm/it83xx_pd.h"
#include "driver/usb_mux/it5205.h"
#include "gpio.h"
#include "hooks.h"
#include "intc.h"
#include "keyboard_scan.h"
#include "lid_switch.h"
#include "power.h"
#include "power_button.h"
#include "pwm.h"
#include "pwm_chip.h"
#include "switch.h"
#include "tablet_mode.h"
#include "task.h"
#include "tcpci.h"
#include "temp_sensor.h"
#include "uart.h"
#include "usb_charge.h"
#include "usb_mux.h"
#include "usb_pd.h"
#include "usb_pd_tcpm.h"
#define CPRINTUSB(format, args...) cprints(CC_USBCHARGE, format, ## args)
/* C0 interrupt line shared by BC 1.2 and charger */
static void usb_c0_interrupt(enum gpio_signal s)
{
task_set_event(TASK_ID_USB_CHG_P0, USB_CHG_EVENT_BC12);
sm5803_interrupt(0);
}
/* C1 interrupt line shared by BC 1.2, TCPC, and charger */
static void usb_c1_interrupt(enum gpio_signal s)
{
schedule_deferred_pd_interrupt(1);
task_set_event(TASK_ID_USB_CHG_P1, USB_CHG_EVENT_BC12);
sm5803_interrupt(1);
}
static void c0_ccsbu_ovp_interrupt(enum gpio_signal s)
{
cprints(CC_USBPD, "C0: CC OVP, SBU OVP, or thermal event");
pd_handle_cc_overvoltage(0);
}
/* Must come after other header files and interrupt handler declarations */
#include "gpio_list.h"
/* ADC channels */
const struct adc_t adc_channels[] = {
[ADC_VSNS_PP3300_A] = {
.name = "PP3300_A_PGOOD",
.factor_mul = ADC_MAX_MVOLT,
.factor_div = ADC_READ_MAX + 1,
.shift = 0,
.channel = CHIP_ADC_CH0
},
[ADC_TEMP_SENSOR_1] = {
.name = "TEMP_SENSOR1",
.factor_mul = ADC_MAX_MVOLT,
.factor_div = ADC_READ_MAX + 1,
.shift = 0,
.channel = CHIP_ADC_CH2
},
[ADC_TEMP_SENSOR_2] = {
.name = "TEMP_SENSOR2",
.factor_mul = ADC_MAX_MVOLT,
.factor_div = ADC_READ_MAX + 1,
.shift = 0,
.channel = CHIP_ADC_CH3
},
[ADC_SUB_ANALOG] = {
.name = "SUB_ANALOG",
.factor_mul = ADC_MAX_MVOLT,
.factor_div = ADC_READ_MAX + 1,
.shift = 0,
.channel = CHIP_ADC_CH13
},
};
BUILD_ASSERT(ARRAY_SIZE(adc_channels) == ADC_CH_COUNT);
/* BC 1.2 chips */
const struct pi3usb9201_config_t pi3usb9201_bc12_chips[] = {
{
.i2c_port = I2C_PORT_USB_C0,
.i2c_addr_flags = PI3USB9201_I2C_ADDR_3_FLAGS,
},
{
.i2c_port = I2C_PORT_SUB_USB_C1,
.i2c_addr_flags = PI3USB9201_I2C_ADDR_3_FLAGS,
},
};
/* Charger chips */
const struct charger_config_t chg_chips[] = {
[CHARGER_PRIMARY] = {
.i2c_port = I2C_PORT_USB_C0,
.i2c_addr_flags = SM5803_ADDR_CHARGER_FLAGS,
.drv = &sm5803_drv,
},
[CHARGER_SECONDARY] = {
.i2c_port = I2C_PORT_SUB_USB_C1,
.i2c_addr_flags = SM5803_ADDR_CHARGER_FLAGS,
.drv = &sm5803_drv,
},
};
/* TCPCs */
const struct tcpc_config_t tcpc_config[CONFIG_USB_PD_PORT_MAX_COUNT] = {
{
.bus_type = EC_BUS_TYPE_EMBEDDED,
.drv = &it83xx_tcpm_drv,
},
{
.bus_type = EC_BUS_TYPE_I2C,
.i2c_info = {
.port = I2C_PORT_SUB_USB_C1,
.addr_flags = AN7447_TCPC0_I2C_ADDR_FLAGS,
},
.drv = &anx7447_tcpm_drv,
.flags = TCPC_FLAGS_TCPCI_REV2_0,
},
};
/* USB Retimer */
const struct usb_mux usbc1_retimer = {
.usb_port = 1,
.i2c_port = I2C_PORT_SUB_USB_C1,
.i2c_addr_flags = TUSB544_I2C_ADDR_FLAGS0,
.driver = &tusb544_drv,
};
/* USB Muxes */
const struct usb_mux usb_muxes[CONFIG_USB_PD_PORT_MAX_COUNT] = {
{
.usb_port = 0,
.i2c_port = I2C_PORT_USB_C0,
.i2c_addr_flags = IT5205_I2C_ADDR1_FLAGS,
.driver = &it5205_usb_mux_driver,
},
{
.usb_port = 1,
.i2c_port = I2C_PORT_SUB_USB_C1,
.i2c_addr_flags = AN7447_TCPC0_I2C_ADDR_FLAGS,
.driver = &anx7447_usb_mux_driver,
.next_mux = &usbc1_retimer,
},
};
void board_init(void)
{
int on;
gpio_enable_interrupt(GPIO_USB_C0_INT_ODL);
gpio_enable_interrupt(GPIO_USB_C1_INT_ODL);
gpio_enable_interrupt(GPIO_USB_C0_CCSBU_OVP_ODL);
/* Charger on the MB will be outputting PROCHOT_ODL and OD CHG_DET */
sm5803_configure_gpio0(CHARGER_PRIMARY, GPIO0_MODE_PROCHOT, 1);
sm5803_configure_chg_det_od(CHARGER_PRIMARY, 1);
/* Charger on the sub-board will be a push-pull GPIO */
sm5803_configure_gpio0(CHARGER_SECONDARY, GPIO0_MODE_OUTPUT, 0);
/* Turn on 5V if the system is on, otherwise turn it off */
on = chipset_in_state(CHIPSET_STATE_ON | CHIPSET_STATE_ANY_SUSPEND);
board_power_5v_enable(on);
}
DECLARE_HOOK(HOOK_INIT, board_init, HOOK_PRIO_DEFAULT);
void board_reset_pd_mcu(void)
{
/*
* Nothing to do. TCPC C0 is internal, TCPC C1 reset pin is not
* connected to the EC.
*/
}
__override void board_power_5v_enable(int enable)
{
/*
* Motherboard has a GPIO to turn on the 5V regulator, but the sub-board
* sets it through the charger GPIO.
*/
gpio_set_level(GPIO_EN_PP5000, !!enable);
if (sm5803_set_gpio0_level(1, !!enable))
CPRINTUSB("Failed to %sable sub rails!", enable ? "en" : "dis");
}
uint16_t tcpc_get_alert_status(void)
{
/*
* TCPC 0 is embedded in the EC and processes interrupts in the chip
* code (it83xx/intc.c)
*/
uint16_t status = 0;
int regval;
/* Check whether TCPC 1 pulled the shared interrupt line */
if (!gpio_get_level(GPIO_USB_C1_INT_ODL)) {
if (!tcpc_read16(1, TCPC_REG_ALERT, ®val)) {
if (regval)
status = PD_STATUS_TCPC_ALERT_1;
}
}
return status;
}
void board_set_charge_limit(int port, int supplier, int charge_ma, int max_ma,
int charge_mv)
{
int icl = MAX(charge_ma, CONFIG_CHARGER_INPUT_CURRENT);
/*
* TODO(b/151955431): Characterize the input current limit in case a
* scaling needs to be applied here
*/
charge_set_input_current_limit(icl, charge_mv);
}
int board_set_active_charge_port(int port)
{
int is_valid_port = (port >= 0 && port < CONFIG_USB_PD_PORT_MAX_COUNT);
int p0_otg, p1_otg;
if (!is_valid_port && port != CHARGE_PORT_NONE)
return EC_ERROR_INVAL;
/* TODO(b/147440290): charger functions should take chgnum */
p0_otg = chg_chips[0].drv->is_sourcing_otg_power(0, 0);
p1_otg = chg_chips[1].drv->is_sourcing_otg_power(1, 1);
if (port == CHARGE_PORT_NONE) {
CPRINTUSB("Disabling all charge ports");
if (!p0_otg)
chg_chips[0].drv->set_mode(0,
CHARGE_FLAG_INHIBIT_CHARGE);
if (!p1_otg)
chg_chips[1].drv->set_mode(1,
CHARGE_FLAG_INHIBIT_CHARGE);
return EC_SUCCESS;
}
CPRINTUSB("New chg p%d", port);
/*
* Charger task will take care of enabling charging on the new charge
* port. Here, we ensure the other port is not charging by changing
* CHG_EN
*/
if (port == 0) {
if (p0_otg) {
CPRINTUSB("Skip enable p%d", port);
return EC_ERROR_INVAL;
}
if (!p1_otg) {
chg_chips[1].drv->set_mode(1,
CHARGE_FLAG_INHIBIT_CHARGE);
}
} else {
if (p1_otg) {
CPRINTUSB("Skip enable p%d", port);
return EC_ERROR_INVAL;
}
if (!p0_otg) {
chg_chips[0].drv->set_mode(0,
CHARGE_FLAG_INHIBIT_CHARGE);
}
}
return EC_SUCCESS;
}
/* Vconn control for integrated ITE TCPC */
void board_pd_vconn_ctrl(int port, enum usbpd_cc_pin cc_pin, int enabled)
{
/* Vconn control is only for port 0 */
if (port)
return;
if (cc_pin == USBPD_CC_PIN_1)
gpio_set_level(GPIO_EN_USB_C0_CC1_VCONN, !!enabled);
else
gpio_set_level(GPIO_EN_USB_C0_CC2_VCONN, !!enabled);
}
__override void typec_set_source_current_limit(int port, enum tcpc_rp_value rp)
{
int current;
if (port < 0 || port > CONFIG_USB_PD_PORT_MAX_COUNT)
return;
current = (rp == TYPEC_RP_3A0) ? 3000 : 1500;
chg_chips[port].drv->set_otg_current_voltage(port, current, 5000);
}
/* PWM channels. Must be in the exactly same order as in enum pwm_channel. */
const struct pwm_t pwm_channels[] = {
[PWM_CH_KBLIGHT] = {
.channel = 0,
.flags = PWM_CONFIG_DSLEEP,
.freq_hz = 10000,
},
[PWM_CH_LED_RED] = {
.channel = 1,
.flags = PWM_CONFIG_DSLEEP | PWM_CONFIG_ACTIVE_LOW,
.freq_hz = 2400,
},
[PWM_CH_LED_GREEN] = {
.channel = 2,
.flags = PWM_CONFIG_DSLEEP | PWM_CONFIG_ACTIVE_LOW,
.freq_hz = 2400,
},
[PWM_CH_LED_BLUE] = {
.channel = 3,
.flags = PWM_CONFIG_DSLEEP | PWM_CONFIG_ACTIVE_LOW,
.freq_hz = 2400,
}
};
BUILD_ASSERT(ARRAY_SIZE(pwm_channels) == PWM_CH_COUNT);
/* Sensor Mutexes */
static struct mutex g_lid_mutex;
static struct mutex g_base_mutex;
/* Sensor Data */
static struct stprivate_data g_lis2dh_data;
static struct lsm6dsm_data lsm6dsm_data = LSM6DSM_DATA;
/* Drivers */
struct motion_sensor_t motion_sensors[] = {
[LID_ACCEL] = {
.name = "Lid Accel",
.active_mask = SENSOR_ACTIVE_S0_S3,
.chip = MOTIONSENSE_CHIP_LIS2DE,
.type = MOTIONSENSE_TYPE_ACCEL,
.location = MOTIONSENSE_LOC_LID,
.drv = &lis2dh_drv,
.mutex = &g_lid_mutex,
.drv_data = &g_lis2dh_data,
.port = I2C_PORT_SENSOR,
.i2c_spi_addr_flags = LIS2DH_ADDR1_FLAGS,
.rot_standard_ref = NULL,
.default_range = 2, /* g */
/* We only use 2g because its resolution is only 8-bits */
.min_frequency = LIS2DH_ODR_MIN_VAL,
.max_frequency = LIS2DH_ODR_MAX_VAL,
.config = {
[SENSOR_CONFIG_EC_S0] = {
.odr = 10000 | ROUND_UP_FLAG,
},
[SENSOR_CONFIG_EC_S3] = {
.odr = 10000 | ROUND_UP_FLAG,
},
},
},
[BASE_ACCEL] = {
.name = "Base Accel",
.active_mask = SENSOR_ACTIVE_S0_S3,
.chip = MOTIONSENSE_CHIP_LSM6DSM,
.type = MOTIONSENSE_TYPE_ACCEL,
.location = MOTIONSENSE_LOC_BASE,
.drv = &lsm6dsm_drv,
.mutex = &g_base_mutex,
.drv_data = LSM6DSM_ST_DATA(lsm6dsm_data,
MOTIONSENSE_TYPE_ACCEL),
.int_signal = GPIO_BASE_SIXAXIS_INT_L,
.flags = MOTIONSENSE_FLAG_INT_SIGNAL,
.port = I2C_PORT_SENSOR,
.i2c_spi_addr_flags = LSM6DSM_ADDR0_FLAGS,
.rot_standard_ref = NULL,
.default_range = 4, /* g */
.min_frequency = LSM6DSM_ODR_MIN_VAL,
.max_frequency = LSM6DSM_ODR_MAX_VAL,
.config = {
[SENSOR_CONFIG_EC_S0] = {
.odr = 13000 | ROUND_UP_FLAG,
.ec_rate = 100 * MSEC,
},
[SENSOR_CONFIG_EC_S3] = {
.odr = 10000 | ROUND_UP_FLAG,
.ec_rate = 100 * MSEC,
},
},
},
[BASE_GYRO] = {
.name = "Base Gyro",
.active_mask = SENSOR_ACTIVE_S0_S3,
.chip = MOTIONSENSE_CHIP_LSM6DSM,
.type = MOTIONSENSE_TYPE_GYRO,
.location = MOTIONSENSE_LOC_BASE,
.drv = &lsm6dsm_drv,
.mutex = &g_base_mutex,
.drv_data = LSM6DSM_ST_DATA(lsm6dsm_data,
MOTIONSENSE_TYPE_GYRO),
.int_signal = GPIO_BASE_SIXAXIS_INT_L,
.flags = MOTIONSENSE_FLAG_INT_SIGNAL,
.port = I2C_PORT_SENSOR,
.i2c_spi_addr_flags = LSM6DSM_ADDR0_FLAGS,
.default_range = 1000 | ROUND_UP_FLAG, /* dps */
.rot_standard_ref = NULL,
.min_frequency = LSM6DSM_ODR_MIN_VAL,
.max_frequency = LSM6DSM_ODR_MAX_VAL,
},
[VSYNC] = {
.name = "Camera VSYNC",
.active_mask = SENSOR_ACTIVE_S0,
.chip = MOTIONSENSE_CHIP_GPIO,
.type = MOTIONSENSE_TYPE_SYNC,
.location = MOTIONSENSE_LOC_CAMERA,
.drv = &sync_drv,
.default_range = 0,
.min_frequency = 0,
.max_frequency = 1,
},
};
const unsigned int motion_sensor_count = ARRAY_SIZE(motion_sensors);
/* Thermistors */
const struct temp_sensor_t temp_sensors[] = {
[TEMP_SENSOR_1] = {.name = "Memory",
.type = TEMP_SENSOR_TYPE_BOARD,
.read = get_temp_3v3_51k1_47k_4050b,
.idx = ADC_TEMP_SENSOR_1},
[TEMP_SENSOR_2] = {.name = "Ambient",
.type = TEMP_SENSOR_TYPE_BOARD,
.read = get_temp_3v3_51k1_47k_4050b,
.idx = ADC_TEMP_SENSOR_2},
};
BUILD_ASSERT(ARRAY_SIZE(temp_sensors) == TEMP_SENSOR_COUNT);
#ifndef TEST_BUILD
/* This callback disables keyboard when convertibles are fully open */
void lid_angle_peripheral_enable(int enable)
{
int chipset_in_s0 = chipset_in_state(CHIPSET_STATE_ON);
/*
* If the lid is in tablet position via other sensors,
* ignore the lid angle, which might be faulty then
* disable keyboard.
*/
if (tablet_get_mode())
enable = 0;
if (enable) {
keyboard_scan_enable(1, KB_SCAN_DISABLE_LID_ANGLE);
} else {
/*
* Ensure that the chipset is off before disabling the keyboard.
* When the chipset is on, the EC keeps the keyboard enabled and
* the AP decides whether to ignore input devices or not.
*/
if (!chipset_in_s0)
keyboard_scan_enable(0, KB_SCAN_DISABLE_LID_ANGLE);
}
}
#endif
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