unleashed-firmware/firmware/targets/f7/furi-hal/furi-hal-power.c
SG 8073992925
[FL-1587] RFID: Clock for emulation timer from antenna (#622)
* RFID: pull antenna down when emulating
* Rfid: fixed HID emulation by adding zero pulse every 4 bits
* Rfid: HID emulation fixed with DSP based FSK oscillator.
* Rfid: receive 125KHz clock for emulation timer from antenna and comparator
* Rfid: commented unused variable
* Firmware: rollback changes in f6.
* Add F7 target based on F6.
* F7/F6: update cube projects, apply changes to the targets, update linker scripts with correct RAM start values.
* FuriHal: RFID init routine.
* Scripts: update OTP tool for v11 board

Co-authored-by: Aleksandr Kutuzov <alleteam@gmail.com>
2021-09-10 05:19:02 +03:00

281 lines
7.7 KiB
C

#include <furi-hal-power.h>
#include <furi-hal-clock.h>
#include <furi-hal-bt.h>
#include <stm32wbxx_ll_rcc.h>
#include <stm32wbxx_ll_pwr.h>
#include <stm32wbxx_ll_hsem.h>
#include <stm32wbxx_ll_cortex.h>
#include <stm32wbxx_ll_gpio.h>
#include <main.h>
#include <hw_conf.h>
#include <bq27220.h>
#include <bq25896.h>
#include <furi.h>
typedef struct {
volatile uint32_t insomnia;
volatile uint32_t deep_insomnia;
} FuriHalPower;
static volatile FuriHalPower furi_hal_power = {
.insomnia = 0,
.deep_insomnia = 1,
};
const ParamCEDV cedv = {
.cedv_conf.gauge_conf = {
.CCT = 1,
.CSYNC = 0,
.EDV_CMP = 0,
.SC = 1,
.FIXED_EDV0 = 1,
.FCC_LIM = 1,
.FC_FOR_VDQ = 1,
.IGNORE_SD = 1,
.SME0 = 0,
},
.full_charge_cap = 2100,
.design_cap = 2100,
.EDV0 = 3300,
.EDV1 = 3321,
.EDV2 = 3355,
.EMF = 3679,
.C0 = 430,
.C1 = 0,
.R1 = 408,
.R0 = 334,
.T0 = 4626,
.TC = 11,
.DOD0 = 4044,
.DOD10 = 3905,
.DOD20 = 3807,
.DOD30 = 3718,
.DOD40 = 3642,
.DOD50 = 3585,
.DOD60 = 3546,
.DOD70 = 3514,
.DOD80 = 3477,
.DOD90 = 3411,
.DOD100 = 3299,
};
void HAL_RCC_CSSCallback(void) {
// TODO: notify user about issue with HSE
furi_hal_power_reset();
}
void furi_hal_power_init() {
LL_PWR_SetRegulVoltageScaling(LL_PWR_REGU_VOLTAGE_SCALE1);
LL_PWR_SMPS_SetMode(LL_PWR_SMPS_STEP_DOWN);
bq27220_init(&cedv);
bq25896_init();
FURI_LOG_I("FuriHalPower", "Init OK");
}
uint16_t furi_hal_power_insomnia_level() {
return furi_hal_power.insomnia;
}
void furi_hal_power_insomnia_enter() {
furi_hal_power.insomnia++;
}
void furi_hal_power_insomnia_exit() {
furi_hal_power.insomnia--;
}
bool furi_hal_power_sleep_available() {
return furi_hal_power.insomnia == 0;
}
bool furi_hal_power_deep_sleep_available() {
return furi_hal_bt_is_alive() && furi_hal_power.deep_insomnia == 0;
}
void furi_hal_power_light_sleep() {
__WFI();
}
void furi_hal_power_deep_sleep() {
while( LL_HSEM_1StepLock(HSEM, CFG_HW_RCC_SEMID));
if (!LL_HSEM_1StepLock(HSEM, CFG_HW_ENTRY_STOP_MODE_SEMID)) {
if(LL_PWR_IsActiveFlag_C2DS()) {
// Release ENTRY_STOP_MODE semaphore
LL_HSEM_ReleaseLock(HSEM, CFG_HW_ENTRY_STOP_MODE_SEMID, 0);
// The switch on HSI before entering Stop Mode is required
furi_hal_clock_switch_to_hsi();
}
} else {
/**
* The switch on HSI before entering Stop Mode is required
*/
furi_hal_clock_switch_to_hsi();
}
/* Release RCC semaphore */
LL_HSEM_ReleaseLock(HSEM, CFG_HW_RCC_SEMID, 0);
// Prepare deep sleep
LL_PWR_SetPowerMode(LL_PWR_MODE_STOP1);
LL_LPM_EnableDeepSleep();
#if defined ( __CC_ARM)
// Force store operations
__force_stores();
#endif
__WFI();
/* Release ENTRY_STOP_MODE semaphore */
LL_HSEM_ReleaseLock(HSEM, CFG_HW_ENTRY_STOP_MODE_SEMID, 0);
while(LL_HSEM_1StepLock(HSEM, CFG_HW_RCC_SEMID));
if(LL_RCC_GetSysClkSource() != LL_RCC_SYS_CLKSOURCE_STATUS_PLL) {
furi_hal_clock_switch_to_pll();
}
LL_HSEM_ReleaseLock(HSEM, CFG_HW_RCC_SEMID, 0);
}
void furi_hal_power_sleep() {
if(furi_hal_power_deep_sleep_available()) {
furi_hal_power_deep_sleep();
} else {
furi_hal_power_light_sleep();
}
}
uint8_t furi_hal_power_get_pct() {
return bq27220_get_state_of_charge();
}
uint8_t furi_hal_power_get_bat_health_pct() {
return bq27220_get_state_of_health();
}
bool furi_hal_power_is_charging() {
return bq25896_is_charging();
}
void furi_hal_power_off() {
bq25896_poweroff();
}
void furi_hal_power_reset() {
NVIC_SystemReset();
}
void furi_hal_power_enable_otg() {
bq25896_enable_otg();
}
void furi_hal_power_disable_otg() {
bq25896_disable_otg();
}
uint32_t furi_hal_power_get_battery_remaining_capacity() {
return bq27220_get_remaining_capacity();
}
uint32_t furi_hal_power_get_battery_full_capacity() {
return bq27220_get_full_charge_capacity();
}
float furi_hal_power_get_battery_voltage(FuriHalPowerIC ic) {
if (ic == FuriHalPowerICCharger) {
return (float)bq25896_get_vbat_voltage() / 1000.0f;
} else if (ic == FuriHalPowerICFuelGauge) {
return (float)bq27220_get_voltage() / 1000.0f;
} else {
return 0.0f;
}
}
float furi_hal_power_get_battery_current(FuriHalPowerIC ic) {
if (ic == FuriHalPowerICCharger) {
return (float)bq25896_get_vbat_current() / 1000.0f;
} else if (ic == FuriHalPowerICFuelGauge) {
return (float)bq27220_get_current() / 1000.0f;
} else {
return 0.0f;
}
}
float furi_hal_power_get_battery_temperature(FuriHalPowerIC ic) {
if (ic == FuriHalPowerICCharger) {
// Linear approximation, +/- 5 C
return (71.0f - (float)bq25896_get_ntc_mpct()/1000) / 0.6f;
} else if (ic == FuriHalPowerICFuelGauge) {
return ((float)bq27220_get_temperature() - 2731.0f) / 10.0f;
} else {
return 0.0f;
}
}
float furi_hal_power_get_usb_voltage(){
return (float)bq25896_get_vbus_voltage() / 1000.0f;
}
void furi_hal_power_dump_state() {
BatteryStatus battery_status;
OperationStatus operation_status;
if (bq27220_get_battery_status(&battery_status) == BQ27220_ERROR
|| bq27220_get_operation_status(&operation_status) == BQ27220_ERROR) {
printf("Failed to get bq27220 status. Communication error.\r\n");
} else {
printf(
"bq27220: CALMD: %d, SEC0: %d, SEC1: %d, EDV2: %d, VDQ: %d, INITCOMP: %d, SMTH: %d, BTPINT: %d, CFGUPDATE: %d\r\n",
operation_status.CALMD, operation_status.SEC0, operation_status.SEC1,
operation_status.EDV2, operation_status.VDQ, operation_status.INITCOMP,
operation_status.SMTH, operation_status.BTPINT, operation_status.CFGUPDATE
);
// Battery status register, part 1
printf(
"bq27220: CHGINH: %d, FC: %d, OTD: %d, OTC: %d, SLEEP: %d, OCVFAIL: %d, OCVCOMP: %d, FD: %d\r\n",
battery_status.CHGINH, battery_status.FC, battery_status.OTD,
battery_status.OTC, battery_status.SLEEP, battery_status.OCVFAIL,
battery_status.OCVCOMP, battery_status.FD
);
// Battery status register, part 2
printf(
"bq27220: DSG: %d, SYSDWN: %d, TDA: %d, BATTPRES: %d, AUTH_GD: %d, OCVGD: %d, TCA: %d, RSVD: %d\r\n",
battery_status.DSG, battery_status.SYSDWN, battery_status.TDA,
battery_status.BATTPRES, battery_status.AUTH_GD, battery_status.OCVGD,
battery_status.TCA, battery_status.RSVD
);
// Voltage and current info
printf(
"bq27220: Full capacity: %dmAh, Design capacity: %dmAh, Remaining capacity: %dmAh, State of Charge: %d%%, State of health: %d%%\r\n",
bq27220_get_full_charge_capacity(), bq27220_get_design_capacity(), bq27220_get_remaining_capacity(),
bq27220_get_state_of_charge(), bq27220_get_state_of_health()
);
printf(
"bq27220: Voltage: %dmV, Current: %dmA, Temperature: %dC\r\n",
bq27220_get_voltage(), bq27220_get_current(), (int)furi_hal_power_get_battery_temperature(FuriHalPowerICFuelGauge)
);
}
printf(
"bq25896: VBUS: %d, VSYS: %d, VBAT: %d, Current: %d, NTC: %ldm%%\r\n",
bq25896_get_vbus_voltage(), bq25896_get_vsys_voltage(),
bq25896_get_vbat_voltage(), bq25896_get_vbat_current(),
bq25896_get_ntc_mpct()
);
}
void furi_hal_power_enable_external_3_3v(){
LL_GPIO_SetOutputPin(PERIPH_POWER_GPIO_Port, PERIPH_POWER_Pin);
}
void furi_hal_power_disable_external_3_3v(){
LL_GPIO_ResetOutputPin(PERIPH_POWER_GPIO_Port, PERIPH_POWER_Pin);
}