/* Copyright 2019 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. */ /* Zork family-specific configuration */ #include "adc.h" #include "adc_chip.h" #include "button.h" #include "charge_manager.h" #include "charge_state.h" #include "charge_state_v2.h" #include "common.h" #include "compile_time_macros.h" #include "console.h" #include "cros_board_info.h" #include "driver/accel_kionix.h" #include "driver/accel_kx022.h" #include "driver/accelgyro_bmi160.h" #include "driver/bc12/pi3usb9201.h" #include "driver/ppc/nx20p348x.h" #include "driver/ppc/sn5s330.h" #include "driver/tcpm/ps8xxx.h" #include "driver/tcpm/nct38xx.h" #include "driver/temp_sensor/sb_tsi.h" #include "ec_commands.h" #include "extpower.h" #include "fan.h" #include "fan_chip.h" #include "gpio.h" #include "hooks.h" #include "ioexpander.h" #include "ioexpander_nct38xx.h" #include "i2c.h" #include "keyboard_scan.h" #include "lid_switch.h" #include "motion_sense.h" #include "power.h" #include "power_button.h" #include "pwm.h" #include "pwm_chip.h" #include "registers.h" #include "switch.h" #include "system.h" #include "task.h" #include "tcpci.h" #include "temp_sensor.h" #include "thermistor.h" #include "usb_mux.h" #include "usb_pd.h" #include "usb_pd_tcpm.h" #include "usbc_ppc.h" #include "util.h" #define CPRINTSUSB(format, args...) cprints(CC_USBCHARGE, format, ## args) #define CPRINTFUSB(format, args...) cprintf(CC_USBCHARGE, format, ## args) const enum gpio_signal hibernate_wake_pins[] = { GPIO_LID_OPEN, GPIO_AC_PRESENT, GPIO_POWER_BUTTON_L, GPIO_EC_RST_ODL, }; const int hibernate_wake_pins_used = ARRAY_SIZE(hibernate_wake_pins); const struct adc_t adc_channels[] = { [ADC_TEMP_SENSOR_CHARGER] = { .name = "CHARGER", .input_ch = NPCX_ADC_CH2, .factor_mul = ADC_MAX_VOLT, .factor_div = ADC_READ_MAX + 1, .shift = 0, }, [ADC_TEMP_SENSOR_SOC] = { .name = "SOC", .input_ch = NPCX_ADC_CH3, .factor_mul = ADC_MAX_VOLT, .factor_div = ADC_READ_MAX + 1, .shift = 0, }, }; BUILD_ASSERT(ARRAY_SIZE(adc_channels) == ADC_CH_COUNT); const struct power_signal_info power_signal_list[] = { [X86_SLP_S3_N] = { .gpio = GPIO_PCH_SLP_S3_L, .flags = POWER_SIGNAL_ACTIVE_HIGH, .name = "SLP_S3_DEASSERTED", }, [X86_SLP_S5_N] = { .gpio = GPIO_PCH_SLP_S5_L, .flags = POWER_SIGNAL_ACTIVE_HIGH, .name = "SLP_S5_DEASSERTED", }, [X86_S0_PGOOD] = { .gpio = GPIO_S0_PGOOD, .flags = POWER_SIGNAL_ACTIVE_HIGH, .name = "S0_PGOOD", }, [X86_S5_PGOOD] = { .gpio = GPIO_S5_PGOOD, .flags = POWER_SIGNAL_ACTIVE_HIGH, .name = "S5_PGOOD", }, }; BUILD_ASSERT(ARRAY_SIZE(power_signal_list) == POWER_SIGNAL_COUNT); const struct i2c_port_t i2c_ports[] = { { .name = "tcpc0", .port = I2C_PORT_TCPC0, .kbps = 400, .scl = GPIO_EC_I2C_USB_A0_C0_SCL, .sda = GPIO_EC_I2C_USB_A0_C0_SDA, }, { .name = "tcpc1", .port = I2C_PORT_TCPC1, .kbps = 400, .scl = GPIO_EC_I2C_USB_A1_C1_SCL, .sda = GPIO_EC_I2C_USB_A1_C1_SDA, }, { .name = "power", .port = I2C_PORT_BATTERY, .kbps = 100, .scl = GPIO_EC_I2C_POWER_CBI_SCL, .sda = GPIO_EC_I2C_POWER_CBI_SDA, }, { .name = "mux", .port = I2C_PORT_MUX, .kbps = 400, .scl = GPIO_EC_I2C_USBC_AP_MUX_SCL, .sda = GPIO_EC_I2C_USBC_AP_MUX_SDA, }, { .name = "thermal", .port = I2C_PORT_THERMAL, .kbps = 400, .scl = GPIO_FCH_SIC, .sda = GPIO_FCH_SID, }, { .name = "sensor", .port = I2C_PORT_SENSOR, .kbps = 400, .scl = GPIO_EC_I2C_SENSOR_SCL, .sda = GPIO_EC_I2C_SENSOR_SDA, }, { .name = "ap_audio", .port = I2C_PORT_AP_AUDIO, .kbps = 400, .scl = GPIO_FCH_I2C_AUDIO_SCL, .sda = GPIO_FCH_I2C_AUDIO_SDA, }, { .name = "ap_hdmi", .port = I2C_PORT_AP_HDMI, .kbps = 400, .scl = GPIO_FCH_I2C_HDMI_HUB_3V3_SCL, .sda = GPIO_FCH_I2C_HDMI_HUB_3V3_SDA, }, }; const unsigned int i2c_ports_used = ARRAY_SIZE(i2c_ports); const struct pwm_t pwm_channels[] = { [PWM_CH_KBLIGHT] = { .channel = 3, .flags = PWM_CONFIG_DSLEEP, .freq = 100, }, [PWM_CH_FAN] = { .channel = 2, .flags = PWM_CONFIG_OPEN_DRAIN, .freq = 25000, }, }; BUILD_ASSERT(ARRAY_SIZE(pwm_channels) == PWM_CH_COUNT); /* Physical fans. These are logically separate from pwm_channels. */ const struct fan_conf fan_conf_0 = { .flags = FAN_USE_RPM_MODE, .ch = MFT_CH_0, /* Use MFT id to control fan */ .pgood_gpio = -1, .enable_gpio = -1, }; const struct fan_rpm fan_rpm_0 = { .rpm_min = 3100, .rpm_start = 3100, .rpm_max = 6900, }; struct fan_t fans[] = { [FAN_CH_0] = { .conf = &fan_conf_0, .rpm = &fan_rpm_0, }, }; BUILD_ASSERT(ARRAY_SIZE(fans) == FAN_CH_COUNT); /* MFT channels. These are logically separate from pwm_channels. */ const struct mft_t mft_channels[] = { [MFT_CH_0] = { .module = NPCX_MFT_MODULE_1, .clk_src = TCKC_LFCLK, .pwm_id = PWM_CH_FAN, }, }; BUILD_ASSERT(ARRAY_SIZE(mft_channels) == MFT_CH_COUNT); struct ppc_config_t ppc_chips[] = { [USBC_PORT_C0] = { .i2c_port = I2C_PORT_TCPC0, .i2c_addr_flags = SN5S330_ADDR0_FLAGS, .drv = &sn5s330_drv }, [USBC_PORT_C1] = { .i2c_port = I2C_PORT_TCPC1, .i2c_addr_flags = NX20P3483_ADDR1_FLAGS, .drv = &nx20p348x_drv }, }; BUILD_ASSERT(ARRAY_SIZE(ppc_chips) == USBC_PORT_COUNT); unsigned int ppc_cnt = ARRAY_SIZE(ppc_chips); void ppc_interrupt(enum gpio_signal signal) { switch (signal) { case GPIO_USB_C0_PPC_INT_ODL: sn5s330_interrupt(USBC_PORT_C0); break; case GPIO_USB_C1_PPC_INT_ODL: nx20p348x_interrupt(USBC_PORT_C1); break; default: break; } } int ppc_get_alert_status(int port) { switch (port) { case USBC_PORT_C0: return gpio_get_level(GPIO_USB_C0_PPC_INT_ODL) == 0; case USBC_PORT_C1: return gpio_get_level(GPIO_USB_C1_PPC_INT_ODL) == 0; default: return 0; } } int board_set_active_charge_port(int port) { int is_valid_port = (port >= 0 && port < CONFIG_USB_PD_PORT_COUNT); int i; if (port == CHARGE_PORT_NONE) { CPRINTSUSB("Disabling all charger ports"); /* Disable all ports. */ for (i = 0; i < ppc_cnt; i++) { /* * Do not return early if one fails otherwise we can * get into a boot loop assertion failure. */ if (ppc_vbus_sink_enable(i, 0)) CPRINTSUSB("Disabling C%d as sink failed.", i); } return EC_SUCCESS; } else if (!is_valid_port) { return EC_ERROR_INVAL; } /* Check if the port is sourcing VBUS. */ if (ppc_is_sourcing_vbus(port)) { CPRINTFUSB("Skip enable C%d", port); return EC_ERROR_INVAL; } CPRINTSUSB("New charge port: C%d", port); /* * Turn off the other ports' sink path FETs, before enabling the * requested charge port. */ for (i = 0; i < ppc_cnt; i++) { if (i == port) continue; if (ppc_vbus_sink_enable(i, 0)) CPRINTSUSB("C%d: sink path disable failed.", i); } /* Enable requested charge port. */ if (ppc_vbus_sink_enable(port, 1)) { CPRINTSUSB("C%d: sink path enable failed.", port); return EC_ERROR_UNKNOWN; } return EC_SUCCESS; } const struct tcpc_config_t tcpc_config[] = { [USBC_PORT_C0] = { .bus_type = EC_BUS_TYPE_I2C, .i2c_info = { .port = I2C_PORT_TCPC0, .addr_flags = NCT38XX_I2C_ADDR1_1_FLAGS, }, .drv = &nct38xx_tcpm_drv, }, [USBC_PORT_C1] = { .bus_type = EC_BUS_TYPE_I2C, .i2c_info = { .port = I2C_PORT_TCPC1, .addr_flags = NCT38XX_I2C_ADDR1_1_FLAGS, }, .drv = &nct38xx_tcpm_drv, }, }; BUILD_ASSERT(ARRAY_SIZE(tcpc_config) == USBC_PORT_COUNT); BUILD_ASSERT(CONFIG_USB_PD_PORT_COUNT == USBC_PORT_COUNT); const struct pi3usb9201_config_t pi3usb9201_bc12_chips[] = { [USBC_PORT_C0] = { .i2c_port = I2C_PORT_TCPC0, .i2c_addr_flags = PI3USB9201_I2C_ADDR_3_FLAGS, }, [USBC_PORT_C1] = { .i2c_port = I2C_PORT_TCPC1, .i2c_addr_flags = PI3USB9201_I2C_ADDR_3_FLAGS, }, }; BUILD_ASSERT(ARRAY_SIZE(pi3usb9201_bc12_chips) == USBC_PORT_COUNT); void baseboard_tcpc_init(void) { /* Enable PPC interrupts. */ gpio_enable_interrupt(GPIO_USB_C0_PPC_INT_ODL); gpio_enable_interrupt(GPIO_USB_C1_PPC_INT_ODL); /* Enable TCPC interrupts. */ gpio_enable_interrupt(GPIO_USB_C0_TCPC_INT_ODL); gpio_enable_interrupt(GPIO_USB_C1_TCPC_INT_ODL); /* Enable BC 1.2 interrupts */ gpio_enable_interrupt(GPIO_USB_C0_BC12_INT_ODL); gpio_enable_interrupt(GPIO_USB_C1_BC12_INT_ODL); } DECLARE_HOOK(HOOK_INIT, baseboard_tcpc_init, HOOK_PRIO_INIT_I2C + 1); static void reset_pd_port(int port, enum gpio_signal reset_gpio_l, int hold_delay, int finish_delay) { gpio_set_level(reset_gpio_l, 0); msleep(hold_delay); gpio_set_level(reset_gpio_l, 1); if (finish_delay) msleep(finish_delay); } void board_reset_pd_mcu(void) { /* Reset TCPC0 */ reset_pd_port(USBC_PORT_C0, GPIO_USB_C0_TCPC_RST_L, NCT38XX_RESET_HOLD_DELAY_MS, NCT38XX_RESET_POST_DELAY_MS); /* Reset TCPC1 */ reset_pd_port(USBC_PORT_C1, GPIO_USB_C1_TCPC_RST_L, NCT38XX_RESET_HOLD_DELAY_MS, NCT38XX_RESET_POST_DELAY_MS); } uint16_t tcpc_get_alert_status(void) { uint16_t status = 0; /* * Check which port has the ALERT line set and ignore if that TCPC has * its reset line active. */ if (!gpio_get_level(GPIO_USB_C0_TCPC_INT_ODL)) { if (gpio_get_level(GPIO_USB_C0_TCPC_RST_L) != 0) status |= PD_STATUS_TCPC_ALERT_0; } if (!gpio_get_level(GPIO_USB_C1_TCPC_INT_ODL)) { if (gpio_get_level(GPIO_USB_C1_TCPC_RST_L) != 0) status |= PD_STATUS_TCPC_ALERT_1; } return status; } void tcpc_alert_event(enum gpio_signal signal) { int port = -1; switch (signal) { case GPIO_USB_C0_TCPC_INT_ODL: port = 0; break; case GPIO_USB_C1_TCPC_INT_ODL: port = 1; break; default: return; } schedule_deferred_pd_interrupt(port); } void bc12_interrupt(enum gpio_signal signal) { switch (signal) { case GPIO_USB_C0_BC12_INT_ODL: task_set_event(TASK_ID_USB_CHG_P0, USB_CHG_EVENT_BC12, 0); break; case GPIO_USB_C1_BC12_INT_ODL: task_set_event(TASK_ID_USB_CHG_P1, USB_CHG_EVENT_BC12, 0); break; default: break; } } struct usb_mux usb_muxes[] = { [USBC_PORT_C0] = { .driver = &tcpci_tcpm_usb_mux_driver, .hpd_update = &ps8xxx_tcpc_update_hpd_status, }, [USBC_PORT_C1] = { .driver = &tcpci_tcpm_usb_mux_driver, .hpd_update = &ps8xxx_tcpc_update_hpd_status, }, }; BUILD_ASSERT(ARRAY_SIZE(usb_muxes) == USBC_PORT_COUNT); struct ioexpander_config_t ioex_config[] = { [USBC_PORT_C0] = { .i2c_host_port = I2C_PORT_TCPC0, .i2c_slave_addr = NCT38XX_I2C_ADDR1_1_FLAGS, .drv = &nct38xx_ioexpander_drv, }, [USBC_PORT_C1] = { .i2c_host_port = I2C_PORT_TCPC1, .i2c_slave_addr = NCT38XX_I2C_ADDR1_1_FLAGS, .drv = &nct38xx_ioexpander_drv, }, }; BUILD_ASSERT(ARRAY_SIZE(ioex_config) == USBC_PORT_COUNT); BUILD_ASSERT(CONFIG_IO_EXPANDER_PORT_COUNT == USBC_PORT_COUNT); static void baseboard_chipset_suspend(void) { /* Disable display and keyboard backlights. */ gpio_set_level(GPIO_ENABLE_BACKLIGHT_L, 1); ioex_set_level(IOEX_KB_BL_EN, 0); } DECLARE_HOOK(HOOK_CHIPSET_SUSPEND, baseboard_chipset_suspend, HOOK_PRIO_DEFAULT); static void baseboard_chipset_resume(void) { /* Enable display and keyboard backlights. */ gpio_set_level(GPIO_ENABLE_BACKLIGHT_L, 0); ioex_set_level(IOEX_KB_BL_EN, 1); } DECLARE_HOOK(HOOK_CHIPSET_RESUME, baseboard_chipset_resume, HOOK_PRIO_DEFAULT); void board_set_charge_limit(int port, int supplier, int charge_ma, int max_ma, int charge_mv) { charge_set_input_current_limit(MAX(charge_ma, CONFIG_CHARGER_INPUT_CURRENT), charge_mv); } /* Keyboard scan setting */ struct keyboard_scan_config keyscan_config = { /* Extra delay when KSO2 is tied to Cr50. */ .output_settle_us = 60, .debounce_down_us = 6 * MSEC, .debounce_up_us = 30 * MSEC, .scan_period_us = 1500, .min_post_scan_delay_us = 1000, .poll_timeout_us = SECOND, .actual_key_mask = { 0x3c, 0xff, 0xff, 0xff, 0xff, 0xf5, 0xff, 0xa4, 0xff, 0xfe, 0x55, 0xfa, 0xca /* full set */ }, }; /* * We use 11 as the scaling factor so that the maximum mV value below (2761) * can be compressed to fit in a uint8_t. */ #define THERMISTOR_SCALING_FACTOR 11 /* * Values are calculated from the "Resistance VS. Temperature" table on the * Murata page for part NCP15WB473F03RC. Vdd=3.3V, R=30.9Kohm. */ static const struct thermistor_data_pair thermistor_data[] = { { 2761 / THERMISTOR_SCALING_FACTOR, 0}, { 2492 / THERMISTOR_SCALING_FACTOR, 10}, { 2167 / THERMISTOR_SCALING_FACTOR, 20}, { 1812 / THERMISTOR_SCALING_FACTOR, 30}, { 1462 / THERMISTOR_SCALING_FACTOR, 40}, { 1146 / THERMISTOR_SCALING_FACTOR, 50}, { 878 / THERMISTOR_SCALING_FACTOR, 60}, { 665 / THERMISTOR_SCALING_FACTOR, 70}, { 500 / THERMISTOR_SCALING_FACTOR, 80}, { 434 / THERMISTOR_SCALING_FACTOR, 85}, { 376 / THERMISTOR_SCALING_FACTOR, 90}, { 326 / THERMISTOR_SCALING_FACTOR, 95}, { 283 / THERMISTOR_SCALING_FACTOR, 100} }; static const struct thermistor_info thermistor_info = { .scaling_factor = THERMISTOR_SCALING_FACTOR, .num_pairs = ARRAY_SIZE(thermistor_data), .data = thermistor_data, }; static int board_get_temp(int idx, int *temp_k) { /* idx is the sensor index set below in temp_sensors[] */ int mv = adc_read_channel( idx ? ADC_TEMP_SENSOR_SOC : ADC_TEMP_SENSOR_CHARGER); int temp_c; if (mv < 0) return -1; temp_c = thermistor_linear_interpolate(mv, &thermistor_info); *temp_k = C_TO_K(temp_c); return 0; } const struct temp_sensor_t temp_sensors[] = { [TEMP_SENSOR_CHARGER] = { .name = "Charger", .type = TEMP_SENSOR_TYPE_BOARD, .read = board_get_temp, .idx = 0, .action_delay_sec = 1, }, [TEMP_SENSOR_SOC] = { .name = "SOC", .type = TEMP_SENSOR_TYPE_BOARD, .read = board_get_temp, .idx = 1, .action_delay_sec = 5, }, [TEMP_SENSOR_CPU] = { .name = "CPU", .type = TEMP_SENSOR_TYPE_CPU, .read = sb_tsi_get_val, .idx = 0, .action_delay_sec = 4, }, }; BUILD_ASSERT(ARRAY_SIZE(temp_sensors) == TEMP_SENSOR_COUNT); const static struct ec_thermal_config thermal_a = { .temp_host = { [EC_TEMP_THRESH_HIGH] = C_TO_K(75), [EC_TEMP_THRESH_HALT] = C_TO_K(80), }, .temp_host_release = { [EC_TEMP_THRESH_HIGH] = C_TO_K(65), }, .temp_fan_off = C_TO_K(25), .temp_fan_max = C_TO_K(50), }; struct ec_thermal_config thermal_params[TEMP_SENSOR_COUNT]; static void setup_fans(void) { thermal_params[TEMP_SENSOR_CHARGER] = thermal_a; thermal_params[TEMP_SENSOR_SOC] = thermal_a; thermal_params[TEMP_SENSOR_CPU] = thermal_a; } #ifdef HAS_TASK_MOTIONSENSE /* Motion sensors */ static struct mutex g_lid_mutex; static struct mutex g_base_mutex; mat33_fp_t zork_base_standard_ref = { { FLOAT_TO_FP(1), 0, 0}, { 0, FLOAT_TO_FP(1), 0}, { 0, 0, FLOAT_TO_FP(1)} }; mat33_fp_t lid_standard_ref = { { FLOAT_TO_FP(1), 0, 0}, { 0, FLOAT_TO_FP(1), 0}, { 0, 0, FLOAT_TO_FP(1)} }; /* sensor private data */ static struct kionix_accel_data g_kx022_data; static struct bmi160_drv_data_t g_bmi160_data; /* TODO(gcc >= 5.0) Remove the casts to const pointer at rot_standard_ref */ struct motion_sensor_t motion_sensors[] = { [LID_ACCEL] = { .name = "Lid Accel", .active_mask = SENSOR_ACTIVE_S0_S3, .chip = MOTIONSENSE_CHIP_KX022, .type = MOTIONSENSE_TYPE_ACCEL, .location = MOTIONSENSE_LOC_LID, .drv = &kionix_accel_drv, .mutex = &g_lid_mutex, .drv_data = &g_kx022_data, .port = I2C_PORT_SENSOR, .i2c_spi_addr_flags = KX022_ADDR1_FLAGS, .rot_standard_ref = (const mat33_fp_t *)&lid_standard_ref, .default_range = 2, /* g, enough for laptop. */ .min_frequency = KX022_ACCEL_MIN_FREQ, .max_frequency = KX022_ACCEL_MAX_FREQ, .config = { /* EC use accel for angle detection */ [SENSOR_CONFIG_EC_S0] = { .odr = 10000 | ROUND_UP_FLAG, .ec_rate = 100, }, /* EC use accel for angle detection */ [SENSOR_CONFIG_EC_S3] = { .odr = 10000 | ROUND_UP_FLAG, }, }, }, [BASE_ACCEL] = { .name = "Base Accel", .active_mask = SENSOR_ACTIVE_S0_S3, .chip = MOTIONSENSE_CHIP_BMI160, .type = MOTIONSENSE_TYPE_ACCEL, .location = MOTIONSENSE_LOC_BASE, .drv = &bmi160_drv, .mutex = &g_base_mutex, .drv_data = &g_bmi160_data, .port = I2C_PORT_SENSOR, .i2c_spi_addr_flags = BMI160_ADDR0_FLAGS, .default_range = 2, /* g, enough for laptop */ .rot_standard_ref = (const mat33_fp_t *)&zork_base_standard_ref, .min_frequency = BMI160_ACCEL_MIN_FREQ, .max_frequency = BMI160_ACCEL_MAX_FREQ, .config = { /* EC use accel for angle detection */ [SENSOR_CONFIG_EC_S0] = { .odr = 10000 | ROUND_UP_FLAG, .ec_rate = 100, }, /* EC use accel for angle detection */ [SENSOR_CONFIG_EC_S3] = { .odr = 10000 | ROUND_UP_FLAG, }, }, }, [BASE_GYRO] = { .name = "Base Gyro", .active_mask = SENSOR_ACTIVE_S0_S3, .chip = MOTIONSENSE_CHIP_BMI160, .type = MOTIONSENSE_TYPE_GYRO, .location = MOTIONSENSE_LOC_BASE, .drv = &bmi160_drv, .mutex = &g_base_mutex, .drv_data = &g_bmi160_data, .port = I2C_PORT_SENSOR, .i2c_spi_addr_flags = BMI160_ADDR0_FLAGS, .default_range = 1000, /* dps */ .rot_standard_ref = (const mat33_fp_t *)&zork_base_standard_ref, .min_frequency = BMI160_GYRO_MIN_FREQ, .max_frequency = BMI160_GYRO_MAX_FREQ, }, }; unsigned int motion_sensor_count = ARRAY_SIZE(motion_sensors); #endif /* HAS_TASK_MOTIONSENSE */ #ifndef TEST_BUILD void lid_angle_peripheral_enable(int enable) { if (board_is_convertible()) keyboard_scan_enable(enable, KB_SCAN_DISABLE_LID_ANGLE); } #endif static uint32_t sku_id; static void cbi_init(void) { uint32_t board_version = 0; uint32_t val; if (cbi_get_board_version(&val) == EC_SUCCESS) board_version = val; ccprints("Board Version: %d (0x%x)", board_version, board_version); if (cbi_get_sku_id(&val) == EC_SUCCESS) sku_id = val; ccprints("SKU: %d (0x%x)", sku_id, sku_id); #ifdef HAS_TASK_MOTIONSENSE board_update_sensor_config_from_sku(); #endif } DECLARE_HOOK(HOOK_INIT, cbi_init, HOOK_PRIO_INIT_I2C + 1); uint32_t system_get_sku_id(void) { return sku_id; } /* * Returns 1 for boards that are convertible into tablet mode, and zero for * clamshells. */ int board_is_convertible(void) { /* TODO: Add convertible SKU values */ return 0; } int board_is_lid_angle_tablet_mode(void) { return board_is_convertible(); } uint32_t board_override_feature_flags0(uint32_t flags0) { return flags0; } uint32_t board_override_feature_flags1(uint32_t flags1) { return flags1; } void board_overcurrent_event(int port, int is_overcurrented) { switch (port) { case USBC_PORT_C0: ioex_set_level(IOEX_USB_C0_FAULT_ODL, !is_overcurrented); break; case USBC_PORT_C1: ioex_set_level(IOEX_USB_C1_FAULT_ODL, !is_overcurrented); break; default: break; } } static void baseboard_init(void) { /* Initialize Fans */ setup_fans(); } DECLARE_HOOK(HOOK_INIT, baseboard_init, HOOK_PRIO_DEFAULT);