coreboot-libre-fam15h-rdimm/3rdparty/chromeec/board/nami/board.c

1085 lines
28 KiB
C

/* Copyright 2017 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.
*/
/* Poppy board-specific configuration */
#include "adc.h"
#include "adc_chip.h"
#include "anx7447.h"
#include "battery.h"
#include "board_config.h"
#include "button.h"
#include "charge_manager.h"
#include "charge_state.h"
#include "charge_ramp.h"
#include "charger.h"
#include "chipset.h"
#include "console.h"
#include "cros_board_info.h"
#include "driver/pmic_tps650x30.h"
#include "driver/accelgyro_bmi160.h"
#include "driver/accel_bma2x2.h"
#include "driver/accel_kionix.h"
#include "driver/baro_bmp280.h"
#include "driver/led/lm3509.h"
#include "driver/tcpm/ps8xxx.h"
#include "driver/tcpm/tcpci.h"
#include "driver/tcpm/tcpm.h"
#include "driver/temp_sensor/f75303.h"
#include "extpower.h"
#include "gpio.h"
#include "hooks.h"
#include "host_command.h"
#include "i2c.h"
#include "isl923x.h"
#include "keyboard_8042_sharedlib.h"
#include "keyboard_backlight.h"
#include "keyboard_config.h"
#include "keyboard_raw.h"
#include "keyboard_scan.h"
#include "lid_switch.h"
#include "math_util.h"
#include "motion_lid.h"
#include "motion_sense.h"
#include "pi3usb9281.h"
#include "power.h"
#include "power_button.h"
#include "pwm.h"
#include "pwm_chip.h"
#include "spi.h"
#include "switch.h"
#include "system.h"
#include "tablet_mode.h"
#include "task.h"
#include "temp_sensor.h"
#include "timer.h"
#include "uart.h"
#include "usb_charge.h"
#include "usb_mux.h"
#include "usb_pd.h"
#include "usb_pd_tcpm.h"
#include "util.h"
#include "espi.h"
#include "fan.h"
#include "fan_chip.h"
#define CPRINTS(format, args...) cprints(CC_USBCHARGE, format, ## args)
#define CPRINTF(format, args...) cprintf(CC_USBCHARGE, format, ## args)
#define USB_PD_PORT_PS8751 0
#define USB_PD_PORT_ANX7447 1
uint16_t board_version;
uint8_t oem = PROJECT_NAMI;
uint32_t sku;
uint8_t model;
/*
* We have total 30 pins for keyboard connecter {-1, -1} mean
* the N/A pin that don't consider it and reserve index 0 area
* that we don't have pin 0.
*/
const int keyboard_factory_scan_pins[][2] = {
{-1, -1}, {0, 5}, {1, 1}, {1, 0}, {0, 6},
{0, 7}, {-1, -1}, {-1, -1}, {1, 4}, {1, 3},
{-1, -1}, {1, 6}, {1, 7}, {3, 1}, {2, 0},
{1, 5}, {2, 6}, {2, 7}, {2, 1}, {2, 4},
{2, 5}, {1, 2}, {2, 3}, {2, 2}, {3, 0},
{-1, -1}, {-1, -1}, {-1, -1}, {-1, -1}, {-1, -1},
{-1, -1},
};
const int keyboard_factory_scan_pins_used =
ARRAY_SIZE(keyboard_factory_scan_pins);
static void tcpc_alert_event(enum gpio_signal signal)
{
int port = -1;
switch (signal) {
case GPIO_USB_C0_PD_INT_ODL:
port = 0;
break;
case GPIO_USB_C1_PD_INT_ODL:
port = 1;
break;
default:
return;
}
schedule_deferred_pd_interrupt(port);
}
/* Set PD discharge whenever VBUS detection is high (i.e. below threshold). */
static void vbus_discharge_handler(void)
{
pd_set_vbus_discharge(0, gpio_get_level(GPIO_USB_C0_VBUS_WAKE_L));
pd_set_vbus_discharge(1, gpio_get_level(GPIO_USB_C1_VBUS_WAKE_L));
}
DECLARE_DEFERRED(vbus_discharge_handler);
void vbus0_evt(enum gpio_signal signal)
{
/* VBUS present GPIO is inverted */
usb_charger_vbus_change(0, !gpio_get_level(signal));
task_wake(TASK_ID_PD_C0);
hook_call_deferred(&vbus_discharge_handler_data, 0);
}
void vbus1_evt(enum gpio_signal signal)
{
/* VBUS present GPIO is inverted */
usb_charger_vbus_change(1, !gpio_get_level(signal));
task_wake(TASK_ID_PD_C1);
hook_call_deferred(&vbus_discharge_handler_data, 0);
}
void usb0_evt(enum gpio_signal signal)
{
task_set_event(TASK_ID_USB_CHG_P0, USB_CHG_EVENT_BC12, 0);
}
void usb1_evt(enum gpio_signal signal)
{
task_set_event(TASK_ID_USB_CHG_P1, USB_CHG_EVENT_BC12, 0);
}
#include "gpio_list.h"
/* ADC channels */
const struct adc_t adc_channels[] = {
/* Vbus sensing (10x voltage divider). PPVAR_BOOSTIN_SENSE */
[ADC_VBUS] = {"VBUS", NPCX_ADC_CH2, ADC_MAX_VOLT*10, ADC_READ_MAX+1, 0},
/*
* Adapter current output or battery charging/discharging current (uV)
* 18x amplification on charger side.
*/
[ADC_AMON_BMON] = {"AMON_BMON", NPCX_ADC_CH1, ADC_MAX_VOLT*1000/18,
ADC_READ_MAX+1, 0},
};
BUILD_ASSERT(ARRAY_SIZE(adc_channels) == ADC_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,
};
/* Default, Nami, Vayne */
const struct fan_rpm fan_rpm_0 = {
.rpm_min = 3100,
.rpm_start = 3100,
.rpm_max = 6900,
};
/* Sona */
const struct fan_rpm fan_rpm_1 = {
.rpm_min = 2700,
.rpm_start = 2700,
.rpm_max = 6000,
};
/* Pantheon */
const struct fan_rpm fan_rpm_2 = {
.rpm_min = 2100,
.rpm_start = 2300,
.rpm_max = 5100,
};
/* Akali */
const struct fan_rpm fan_rpm_3 = {
.rpm_min = 2700,
.rpm_start = 2700,
.rpm_max = 5500,
};
const struct fan_rpm fan_rpm_4 = {
.rpm_min = 2400,
.rpm_start = 2400,
.rpm_max = 4500,
};
struct fan_t fans[FAN_CH_COUNT] = {
[FAN_CH_0] = { .conf = &fan_conf_0, .rpm = &fan_rpm_0, },
};
/******************************************************************************/
/* MFT channels. These are logically separate from pwm_channels. */
const struct mft_t mft_channels[] = {
[MFT_CH_0] = {NPCX_MFT_MODULE_2, TCKC_LFCLK, PWM_CH_FAN},
};
BUILD_ASSERT(ARRAY_SIZE(mft_channels) == MFT_CH_COUNT);
/* I2C port map */
const struct i2c_port_t i2c_ports[] = {
{"tcpc0", NPCX_I2C_PORT0_0, 400, GPIO_I2C0_0_SCL, GPIO_I2C0_0_SDA},
{"tcpc1", NPCX_I2C_PORT0_1, 400, GPIO_I2C0_1_SCL, GPIO_I2C0_1_SDA},
{"battery", NPCX_I2C_PORT1, 100, GPIO_I2C1_SCL, GPIO_I2C1_SDA},
{"charger", NPCX_I2C_PORT2, 100, GPIO_I2C2_SCL, GPIO_I2C2_SDA},
{"pmic", NPCX_I2C_PORT2, 400, GPIO_I2C2_SCL, GPIO_I2C2_SDA},
{"accelgyro", NPCX_I2C_PORT3, 400, GPIO_I2C3_SCL, GPIO_I2C3_SDA},
};
const unsigned int i2c_ports_used = ARRAY_SIZE(i2c_ports);
/* TCPC mux configuration */
const struct tcpc_config_t tcpc_config[CONFIG_USB_PD_PORT_COUNT] = {
[USB_PD_PORT_PS8751] = {
.bus_type = EC_BUS_TYPE_I2C,
.i2c_info = {
.port = NPCX_I2C_PORT0_0,
.addr_flags = PS8751_I2C_ADDR1_FLAGS,
},
.drv = &ps8xxx_tcpm_drv,
/* Alert is active-low, push-pull */
.flags = 0,
},
[USB_PD_PORT_ANX7447] = {
.bus_type = EC_BUS_TYPE_I2C,
.i2c_info = {
.port = NPCX_I2C_PORT0_1,
.addr_flags = AN7447_TCPC3_I2C_ADDR_FLAGS,
},
.drv = &anx7447_tcpm_drv,
/* Alert is active-low, push-pull */
.flags = 0,
},
};
static int ps8751_tune_mux(int port)
{
/* 0x98 sets lower EQ of DP port (3.6db) */
mux_write(port, PS8XXX_REG_MUX_DP_EQ_CONFIGURATION, 0x98);
return EC_SUCCESS;
}
struct usb_mux usb_muxes[CONFIG_USB_PD_PORT_COUNT] = {
[USB_PD_PORT_PS8751] = {
.driver = &tcpci_tcpm_usb_mux_driver,
.hpd_update = &ps8xxx_tcpc_update_hpd_status,
},
[USB_PD_PORT_ANX7447] = {
.driver = &anx7447_usb_mux_driver,
.hpd_update = &anx7447_tcpc_update_hpd_status,
}
};
struct pi3usb9281_config pi3usb9281_chips[] = {
{
.i2c_port = I2C_PORT_USB_CHARGER_0,
.mux_lock = NULL,
},
{
.i2c_port = I2C_PORT_USB_CHARGER_1,
.mux_lock = NULL,
},
};
BUILD_ASSERT(ARRAY_SIZE(pi3usb9281_chips) ==
CONFIG_BC12_DETECT_PI3USB9281_CHIP_COUNT);
void board_reset_pd_mcu(void)
{
if (oem == PROJECT_AKALI && board_version < 0x0200) {
if (anx7447_flash_erase(USB_PD_PORT_ANX7447))
CPRINTS("Failed to erase OCM flash");
}
/* Assert reset */
gpio_set_level(GPIO_USB_C0_PD_RST_L, 0);
gpio_set_level(GPIO_USB_C1_PD_RST, 1);
msleep(1);
gpio_set_level(GPIO_USB_C0_PD_RST_L, 1);
gpio_set_level(GPIO_USB_C1_PD_RST, 0);
/* After TEST_R release, anx7447/3447 needs 2ms to finish eFuse
* loading. */
msleep(2);
}
void board_tcpc_init(void)
{
int port;
/* Only reset TCPC if not sysjump */
if (!system_jumped_to_this_image())
board_reset_pd_mcu();
/* Enable TCPC interrupts */
gpio_enable_interrupt(GPIO_USB_C0_PD_INT_ODL);
gpio_enable_interrupt(GPIO_USB_C1_PD_INT_ODL);
if (oem == PROJECT_SONA && model != MODEL_SYNDRA)
usb_muxes[USB_PD_PORT_PS8751].board_init = ps8751_tune_mux;
/*
* Initialize HPD to low; after sysjump SOC needs to see
* HPD pulse to enable video path
*/
for (port = 0; port < CONFIG_USB_PD_PORT_COUNT; port++) {
const struct usb_mux *mux = &usb_muxes[port];
mux->hpd_update(port, 0, 0);
}
}
DECLARE_HOOK(HOOK_INIT, board_tcpc_init, HOOK_PRIO_INIT_I2C + 2);
uint16_t tcpc_get_alert_status(void)
{
uint16_t status = 0;
if (!gpio_get_level(GPIO_USB_C0_PD_INT_ODL)) {
if (gpio_get_level(GPIO_USB_C0_PD_RST_L))
status |= PD_STATUS_TCPC_ALERT_0;
}
if (!gpio_get_level(GPIO_USB_C1_PD_INT_ODL)) {
if (!gpio_get_level(GPIO_USB_C1_PD_RST))
status |= PD_STATUS_TCPC_ALERT_1;
}
return status;
}
/*
* F75303_Remote1 is near CPU, and F75303_Remote2 is near 5V power IC.
*/
const struct temp_sensor_t temp_sensors[TEMP_SENSOR_COUNT] = {
{"F75303_Local", TEMP_SENSOR_TYPE_BOARD, f75303_get_val,
F75303_IDX_LOCAL, 4},
{"F75303_Remote1", TEMP_SENSOR_TYPE_CPU, f75303_get_val,
F75303_IDX_REMOTE1, 4},
{"F75303_Remote2", TEMP_SENSOR_TYPE_BOARD, f75303_get_val,
F75303_IDX_REMOTE2, 4},
};
struct ec_thermal_config thermal_params[TEMP_SENSOR_COUNT];
/* Nami/Vayne Remote 1, 2 */
const static struct ec_thermal_config thermal_a = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(75),
[EC_TEMP_THRESH_HALT] = C_TO_K(80),
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(65),
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_fan_off = C_TO_K(39),
.temp_fan_max = C_TO_K(50),
};
/* Sona Remote 1 */
const static struct ec_thermal_config thermal_b1 = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(82),
[EC_TEMP_THRESH_HALT] = C_TO_K(89),
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(72),
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_fan_off = C_TO_K(38),
.temp_fan_max = C_TO_K(58),
};
/* Sona Remote 2 */
const static struct ec_thermal_config thermal_b2 = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(84),
[EC_TEMP_THRESH_HALT] = C_TO_K(91),
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(74),
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_fan_off = C_TO_K(40),
.temp_fan_max = C_TO_K(60),
};
/* Pantheon Remote 1 */
const static struct ec_thermal_config thermal_c1 = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(66),
[EC_TEMP_THRESH_HALT] = C_TO_K(80),
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(56),
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_fan_off = C_TO_K(38),
.temp_fan_max = C_TO_K(61),
};
/* Pantheon Remote 2 */
const static struct ec_thermal_config thermal_c2 = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(74),
[EC_TEMP_THRESH_HALT] = C_TO_K(82),
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = 0,
[EC_TEMP_THRESH_HIGH] = C_TO_K(64),
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_fan_off = C_TO_K(38),
.temp_fan_max = C_TO_K(61),
};
/* Akali Local */
const static struct ec_thermal_config thermal_d0 = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = C_TO_K(79),
[EC_TEMP_THRESH_HIGH] = 0,
[EC_TEMP_THRESH_HALT] = C_TO_K(81),
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = C_TO_K(80),
[EC_TEMP_THRESH_HIGH] = 0,
[EC_TEMP_THRESH_HALT] = C_TO_K(82),
},
.temp_fan_off = C_TO_K(35),
.temp_fan_max = C_TO_K(70),
};
/* Akali Remote 1 */
const static struct ec_thermal_config thermal_d1 = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = C_TO_K(59),
[EC_TEMP_THRESH_HIGH] = 0,
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = C_TO_K(60),
[EC_TEMP_THRESH_HIGH] = 0,
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_fan_off = 0,
.temp_fan_max = 0,
};
/* Akali Remote 2 */
const static struct ec_thermal_config thermal_d2 = {
.temp_host = {
[EC_TEMP_THRESH_WARN] = C_TO_K(59),
[EC_TEMP_THRESH_HIGH] = 0,
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_host_release = {
[EC_TEMP_THRESH_WARN] = C_TO_K(60),
[EC_TEMP_THRESH_HIGH] = 0,
[EC_TEMP_THRESH_HALT] = 0,
},
.temp_fan_off = 0,
.temp_fan_max = 0,
};
#define I2C_PMIC_READ(reg, data) \
i2c_read8(I2C_PORT_PMIC, TPS650X30_I2C_ADDR1_FLAGS,\
(reg), (data))
#define I2C_PMIC_WRITE(reg, data) \
i2c_write8(I2C_PORT_PMIC, TPS650X30_I2C_ADDR1_FLAGS,\
(reg), (data))
static void board_pmic_init(void)
{
int err;
int error_count = 0;
static uint8_t pmic_initialized = 0;
if (pmic_initialized)
return;
/* Read vendor ID */
while (1) {
int data;
err = I2C_PMIC_READ(TPS650X30_REG_VENDORID, &data);
if (!err && data == TPS650X30_VENDOR_ID)
break;
else if (error_count > 5)
goto pmic_error;
error_count++;
}
/*
* VCCIOCNT register setting
* [6] : CSDECAYEN
* otherbits: default
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_VCCIOCNT, 0x4A);
if (err)
goto pmic_error;
/*
* VRMODECTRL:
* [4] : VCCIOLPM clear
* otherbits: default
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_VRMODECTRL, 0x2F);
if (err)
goto pmic_error;
/*
* PGMASK1 : Exclude VCCIO from Power Good Tree
* [7] : MVCCIOPG clear
* otherbits: default
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_PGMASK1, 0x80);
if (err)
goto pmic_error;
/*
* PWFAULT_MASK1 Register settings
* [7] : 1b V4 Power Fault Masked
* [4] : 1b V7 Power Fault Masked
* [2] : 1b V9 Power Fault Masked
* [0] : 1b V13 Power Fault Masked
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_PWFAULT_MASK1, 0x95);
if (err)
goto pmic_error;
/*
* Discharge control 4 register configuration
* [7:6] : 00b Reserved
* [5:4] : 01b V3.3S discharge resistance (V6S), 100 Ohm
* [3:2] : 01b V18S discharge resistance (V8S), 100 Ohm
* [1:0] : 01b V100S discharge resistance (V11S), 100 Ohm
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_DISCHCNT4, 0x15);
if (err)
goto pmic_error;
/*
* Discharge control 3 register configuration
* [7:6] : 01b V1.8U_2.5U discharge resistance (V9), 100 Ohm
* [5:4] : 01b V1.2U discharge resistance (V10), 100 Ohm
* [3:2] : 01b V100A discharge resistance (V11), 100 Ohm
* [1:0] : 01b V085A discharge resistance (V12), 100 Ohm
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_DISCHCNT3, 0x55);
if (err)
goto pmic_error;
/*
* Discharge control 2 register configuration
* [7:6] : 01b V5ADS3 discharge resistance (V5), 100 Ohm
* [5:4] : 01b V33A_DSW discharge resistance (V6), 100 Ohm
* [3:2] : 01b V33PCH discharge resistance (V7), 100 Ohm
* [1:0] : 01b V18A discharge resistance (V8), 100 Ohm
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_DISCHCNT2, 0x55);
if (err)
goto pmic_error;
/*
* Discharge control 1 register configuration
* [7:2] : 00b Reserved
* [1:0] : 01b VCCIO discharge resistance (V4), 100 Ohm
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_DISCHCNT1, 0x01);
if (err)
goto pmic_error;
/*
* Increase Voltage
* [7:0] : 0x2a default
* [5:4] : 10b default
* [5:4] : 01b 5.1V (0x1a)
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_V5ADS3CNT, 0x1a);
if (err)
goto pmic_error;
/*
* PBCONFIG Register configuration
* [7] : 1b Power button debounce, 0ms (no debounce)
* [6] : 0b Power button reset timer logic, no action (default)
* [5:0] : 011111b Force an Emergency reset time, 31s (default)
*/
err = I2C_PMIC_WRITE(TPS650X30_REG_PBCONFIG, 0x9F);
if (err)
goto pmic_error;
CPRINTS("PMIC init done");
pmic_initialized = 1;
return;
pmic_error:
CPRINTS("PMIC init failed: %d", err);
}
void chipset_pre_init_callback(void)
{
board_pmic_init();
}
/**
* Buffer the AC present GPIO to the PCH.
*/
static void board_extpower(void)
{
gpio_set_level(GPIO_PCH_ACPRESENT, extpower_is_present());
}
DECLARE_HOOK(HOOK_AC_CHANGE, board_extpower, HOOK_PRIO_DEFAULT);
/* Set active charge port -- only one port can be active at a time. */
int board_set_active_charge_port(int charge_port)
{
/* charge port is a physical port */
int is_real_port = (charge_port >= 0 &&
charge_port < CONFIG_USB_PD_PORT_COUNT);
/* check if we are sourcing VBUS on the port */
/* dnojiri: revisit */
int is_source = gpio_get_level(charge_port == 0 ?
GPIO_USB_C0_5V_EN : GPIO_USB_C1_5V_EN);
if (is_real_port && is_source) {
CPRINTF("No charging on source port p%d is ", charge_port);
return EC_ERROR_INVAL;
}
CPRINTF("New chg p%d", charge_port);
if (charge_port == CHARGE_PORT_NONE) {
/* Disable both ports */
gpio_set_level(GPIO_USB_C0_CHARGE_L, 1);
gpio_set_level(GPIO_USB_C1_CHARGE_L, 1);
} else {
/* Make sure non-charging port is disabled */
/* dnojiri: revisit. there is always this assumption that
* battery is present. If not, this may cause brownout. */
gpio_set_level(charge_port ? GPIO_USB_C0_CHARGE_L :
GPIO_USB_C1_CHARGE_L, 1);
/* Enable charging port */
gpio_set_level(charge_port ? GPIO_USB_C1_CHARGE_L :
GPIO_USB_C0_CHARGE_L, 0);
}
return EC_SUCCESS;
}
void board_set_charge_limit(int port, int supplier, int charge_ma,
int max_ma, int charge_mv)
{
/*
* Limit the input current to 96% negotiated limit,
* to account for the charger chip margin.
*/
int factor = 96;
if (oem == PROJECT_AKALI &&
(model == MODEL_EKKO || model == MODEL_BARD))
factor = 95;
charge_ma = charge_ma * factor / 100;
charge_set_input_current_limit(
MAX(charge_ma, CONFIG_CHARGER_INPUT_CURRENT),
charge_mv);
}
void board_hibernate(void)
{
CPRINTS("Triggering PMIC shutdown.");
uart_flush_output();
gpio_set_level(GPIO_EC_HIBERNATE, 1);
while (1)
;
}
const struct pwm_t pwm_channels[] = {
[PWM_CH_LED1] = { 3, PWM_CONFIG_DSLEEP, 1200 },
[PWM_CH_LED2] = { 5, PWM_CONFIG_DSLEEP, 1200 },
[PWM_CH_FAN] = {4, PWM_CONFIG_OPEN_DRAIN, 25000},
/*
* 1.2kHz is a multiple of both 50 and 60. So a video recorder
* (generally designed to ignore either 50 or 60 Hz flicker) will not
* alias with refresh rate.
*/
[PWM_CH_KBLIGHT] = { 2, 0, 1200 },
};
BUILD_ASSERT(ARRAY_SIZE(pwm_channels) == PWM_CH_COUNT);
/* Lid Sensor mutex */
static struct mutex g_lid_mutex;
static struct mutex g_base_mutex;
/* Lid accel private data */
static struct bmi160_drv_data_t g_bmi160_data;
static struct kionix_accel_data g_kx022_data;
/* BMA255 private data */
static struct accelgyro_saved_data_t g_bma255_data;
/* Matrix to rotate accelrator into standard reference frame */
const mat33_fp_t base_standard_ref = {
{ 0, FLOAT_TO_FP(-1), 0},
{ FLOAT_TO_FP(1), 0, 0},
{ 0, 0, FLOAT_TO_FP(1)}
};
const mat33_fp_t lid_standard_ref = {
{ FLOAT_TO_FP(1), 0, 0},
{ 0, FLOAT_TO_FP(-1), 0},
{ 0, 0, FLOAT_TO_FP(-1)}
};
const mat33_fp_t rotation_x180_z90 = {
{ 0, FLOAT_TO_FP(-1), 0 },
{ FLOAT_TO_FP(-1), 0, 0 },
{ 0, 0, FLOAT_TO_FP(-1) }
};
const struct motion_sensor_t lid_accel_1 = {
.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_ACCEL,
.i2c_spi_addr_flags = KX022_ADDR1_FLAGS,
.rot_standard_ref = &rotation_x180_z90,
.min_frequency = KX022_ACCEL_MIN_FREQ,
.max_frequency = KX022_ACCEL_MAX_FREQ,
.default_range = 2, /* g, to support tablet mode */
.config = {
/* EC use accel for angle detection */
[SENSOR_CONFIG_EC_S0] = {
.odr = 10000 | ROUND_UP_FLAG,
},
/* Sensor on in S3 */
[SENSOR_CONFIG_EC_S3] = {
.odr = 10000 | ROUND_UP_FLAG,
},
},
};
struct motion_sensor_t motion_sensors[] = {
[LID_ACCEL] = {
.name = "Lid Accel",
.active_mask = SENSOR_ACTIVE_S0_S3,
.chip = MOTIONSENSE_CHIP_BMA255,
.type = MOTIONSENSE_TYPE_ACCEL,
.location = MOTIONSENSE_LOC_LID,
.drv = &bma2x2_accel_drv,
.mutex = &g_lid_mutex,
.drv_data = &g_bma255_data,
.port = I2C_PORT_ACCEL,
.i2c_spi_addr_flags = BMA2x2_I2C_ADDR1_FLAGS,
.rot_standard_ref = &lid_standard_ref,
.min_frequency = BMA255_ACCEL_MIN_FREQ,
.max_frequency = BMA255_ACCEL_MAX_FREQ,
.default_range = 2, /* g, to support tablet mode */
.config = {
/* EC use accel for angle detection */
[SENSOR_CONFIG_EC_S0] = {
.odr = 10000 | ROUND_UP_FLAG,
.ec_rate = 0,
},
/* Sensor on in S3 */
[SENSOR_CONFIG_EC_S3] = {
.odr = 10000 | ROUND_UP_FLAG,
.ec_rate = 0,
},
},
},
[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_ACCEL,
.i2c_spi_addr_flags = BMI160_ADDR0_FLAGS,
.rot_standard_ref = &base_standard_ref,
.min_frequency = BMI160_ACCEL_MIN_FREQ,
.max_frequency = BMI160_ACCEL_MAX_FREQ,
.default_range = 2, /* g, to support tablet mode */
.config = {
/* EC use accel for angle detection */
[SENSOR_CONFIG_EC_S0] = {
.odr = 10000 | ROUND_UP_FLAG,
.ec_rate = 100 * MSEC,
},
/* Sensor on in S3 */
[SENSOR_CONFIG_EC_S3] = {
.odr = 10000 | ROUND_UP_FLAG,
.ec_rate = 0,
},
},
},
[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_ACCEL,
.i2c_spi_addr_flags = BMI160_ADDR0_FLAGS,
.default_range = 1000, /* dps */
.rot_standard_ref = &base_standard_ref,
.min_frequency = BMI160_GYRO_MIN_FREQ,
.max_frequency = BMI160_GYRO_MAX_FREQ,
},
};
unsigned int motion_sensor_count = ARRAY_SIZE(motion_sensors);
/* Enable or disable input devices, based on chipset state and tablet mode */
#ifndef TEST_BUILD
void lid_angle_peripheral_enable(int enable)
{
/* If the lid is in 360 position, ignore the lid angle,
* which might be faulty. Disable keyboard.
*/
if (tablet_get_mode() || chipset_in_state(CHIPSET_STATE_ANY_OFF))
enable = 0;
keyboard_scan_enable(enable, KB_SCAN_DISABLE_LID_ANGLE);
}
#endif
/* Called on AP S3 -> S0 transition */
static void board_chipset_resume(void)
{
gpio_set_level(GPIO_ENABLE_BACKLIGHT_L, 0);
gpio_set_level(GPIO_USB3_POWER_DOWN_L, 1);
}
DECLARE_HOOK(HOOK_CHIPSET_RESUME, board_chipset_resume, HOOK_PRIO_DEFAULT);
/* Called on AP S0 -> S3 transition */
static void board_chipset_suspend(void)
{
gpio_set_level(GPIO_ENABLE_BACKLIGHT_L, 1);
gpio_set_level(GPIO_USB3_POWER_DOWN_L, 0);
}
DECLARE_HOOK(HOOK_CHIPSET_SUSPEND, board_chipset_suspend, HOOK_PRIO_DEFAULT);
static void setup_motion_sensors(void)
{
switch (oem) {
case PROJECT_AKALI:
if (sku & SKU_ID_MASK_CONVERTIBLE) {
/* Rotate axis for Akali 360 */
motion_sensors[LID_ACCEL] = lid_accel_1;
motion_sensors[BASE_ACCEL].rot_standard_ref = NULL;
motion_sensors[BASE_GYRO].rot_standard_ref = NULL;
} else {
/* Clamshell Akali has no accel/gyro */
motion_sensor_count = ARRAY_SIZE(motion_sensors) - 2;
}
break;
default:
break;
}
}
static void setup_fans(void)
{
switch (oem) {
case PROJECT_SONA:
if (model == MODEL_SYNDRA)
fans[FAN_CH_0].rpm = &fan_rpm_4;
else
fans[FAN_CH_0].rpm = &fan_rpm_1;
thermal_params[TEMP_SENSOR_REMOTE1] = thermal_b1;
thermal_params[TEMP_SENSOR_REMOTE2] = thermal_b2;
break;
case PROJECT_PANTHEON:
fans[FAN_CH_0].rpm = &fan_rpm_2;
thermal_params[TEMP_SENSOR_REMOTE1] = thermal_c1;
thermal_params[TEMP_SENSOR_REMOTE2] = thermal_c2;
break;
case PROJECT_AKALI:
fans[FAN_CH_0].rpm = &fan_rpm_3;
thermal_params[TEMP_SENSOR_LOCAL] = thermal_d0;
thermal_params[TEMP_SENSOR_REMOTE1] = thermal_d1;
thermal_params[TEMP_SENSOR_REMOTE2] = thermal_d2;
break;
case PROJECT_NAMI:
case PROJECT_VAYNE:
default:
thermal_params[TEMP_SENSOR_REMOTE1] = thermal_a;
thermal_params[TEMP_SENSOR_REMOTE2] = thermal_a;
}
}
/*
* Read CBI from i2c eeprom and initialize variables for board variants
*/
static void cbi_init(void)
{
uint32_t val;
if (cbi_get_board_version(&val) == EC_SUCCESS && val <= UINT16_MAX)
board_version = val;
CPRINTS("Board Version: 0x%04x", board_version);
if (cbi_get_oem_id(&val) == EC_SUCCESS && val < PROJECT_COUNT)
oem = val;
CPRINTS("OEM: %d", oem);
if (cbi_get_sku_id(&val) == EC_SUCCESS)
sku = val;
CPRINTS("SKU: 0x%08x", sku);
if (cbi_get_model_id(&val) == EC_SUCCESS)
model = val;
CPRINTS("MODEL: 0x%08x", model);
if (board_version < 0x300)
/* Previous boards have GPIO42 connected to TP_INT_CONN */
gpio_set_flags(GPIO_USB2_ID, GPIO_INPUT);
setup_motion_sensors();
setup_fans();
}
DECLARE_HOOK(HOOK_INIT, cbi_init, HOOK_PRIO_INIT_I2C + 1);
/* Keyboard scan setting */
struct keyboard_scan_config keyscan_config = {
/*
* F3 key scan cycle completed but scan input is not
* charging to logic high when EC start scan next
* column for "T" key, so we set .output_settle_us
* to 80us from 50us.
*/
.output_settle_us = 80,
.debounce_down_us = 9 * MSEC,
.debounce_up_us = 30 * MSEC,
.scan_period_us = 3 * MSEC,
.min_post_scan_delay_us = 1000,
.poll_timeout_us = 100 * MSEC,
.actual_key_mask = {
0x14, 0xff, 0xff, 0xff, 0xff, 0xf5, 0xff,
0xa4, 0xff, 0xfe, 0x55, 0xfe, 0xff, 0xff, 0xff, /* full set */
},
};
static void board_init(void)
{
int reg;
/*
* This enables pull-down on F_DIO1 (SPI MISO), and F_DIO0 (SPI MOSI),
* whenever the EC is not doing SPI flash transactions. This avoids
* floating SPI buffer input (MISO), which causes power leakage (see
* b/64797021).
*/
NPCX_PUPD_EN1 |= BIT(NPCX_DEVPU1_F_SPI_PUD_EN);
/* Provide AC status to the PCH */
gpio_set_level(GPIO_PCH_ACPRESENT, extpower_is_present());
/* Reduce Buck-boost mode switching frequency to reduce heat */
if (i2c_read16(I2C_PORT_CHARGER, I2C_ADDR_CHARGER_FLAGS,
ISL9238_REG_CONTROL3, &reg) == EC_SUCCESS) {
reg |= ISL9238_C3_BB_SWITCHING_PERIOD;
if (i2c_write16(I2C_PORT_CHARGER, I2C_ADDR_CHARGER_FLAGS,
ISL9238_REG_CONTROL3, reg))
CPRINTF("Failed to set isl9238\n");
}
/* Enable VBUS interrupt */
gpio_enable_interrupt(GPIO_USB_C0_VBUS_WAKE_L);
gpio_enable_interrupt(GPIO_USB_C1_VBUS_WAKE_L);
/* Enable pericom BC1.2 interrupts */
gpio_enable_interrupt(GPIO_USB_C0_BC12_INT_L);
gpio_enable_interrupt(GPIO_USB_C1_BC12_INT_L);
/* Enable Accel/Gyro interrupt for convertibles. */
if (sku & SKU_ID_MASK_CONVERTIBLE)
gpio_enable_interrupt(GPIO_ACCELGYRO3_INT_L);
#ifndef TEST_BUILD
/* Disable scanning KSO13 & 14 if keypad isn't present. */
if (!(sku & SKU_ID_MASK_KEYPAD)) {
keyboard_raw_set_cols(KEYBOARD_COLS_NO_KEYPAD);
keyscan_config.actual_key_mask[11] = 0xfa;
keyscan_config.actual_key_mask[12] = 0xca;
}
if (oem == PROJECT_AKALI && model == MODEL_BARD) {
/* Search key is moved to col=0,row=3 */
keyscan_config.actual_key_mask[0] = 0x1c;
keyscan_config.actual_key_mask[1] = 0xfe;
/* No need to swap scancode_set2[0][3] and [1][0] because both
* are mapped to search key. */
}
if (sku & SKU_ID_MASK_UK2)
/*
* Observed on Shyvana with UK keyboard,
* \|: 0x0061->0x61->0x56
* r-ctrl: 0xe014->0x14->0x1d
*/
swap(scancode_set2[0][4], scancode_set2[7][2]);
#endif
isl923x_set_ac_prochot(3328 /* mA */);
}
DECLARE_HOOK(HOOK_INIT, board_init, HOOK_PRIO_DEFAULT);
int board_is_lid_angle_tablet_mode(void)
{
/* Boards with no GMR sensor use lid angles to detect tablet mode. */
return oem != PROJECT_AKALI;
}
void board_kblight_init(void)
{
if (!(sku & SKU_ID_MASK_KBLIGHT))
return;
switch (oem) {
default:
case PROJECT_NAMI:
case PROJECT_AKALI:
case PROJECT_VAYNE:
case PROJECT_PANTHEON:
kblight_register(&kblight_lm3509);
break;
case PROJECT_SONA:
kblight_register(&kblight_pwm);
break;
}
}
enum critical_shutdown board_critical_shutdown_check(
struct charge_state_data *curr)
{
if (oem == PROJECT_VAYNE)
return CRITICAL_SHUTDOWN_CUTOFF;
else
return CRITICAL_SHUTDOWN_HIBERNATE;
}
uint8_t board_set_battery_level_shutdown(void)
{
if (oem == PROJECT_VAYNE)
/* We match the shutdown threshold with Powerd's.
* 4 + 1 = 5% because Powerd uses '<=' while EC uses '<'. */
return CONFIG_BATT_HOST_SHUTDOWN_PERCENTAGE + 1;
else
return BATTERY_LEVEL_SHUTDOWN;
}