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js vgm module and widget fix

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VGM js module by jamisonderek
Js fixes by jamisonderek
This commit is contained in:
MX 2024-04-23 12:24:07 +03:00
parent f88a916ccc
commit 3269f751cd
No known key found for this signature in database
GPG Key ID: 7CCC66B7DBDD1C83
9 changed files with 1114 additions and 2 deletions
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8
applications/system/js_app/application.fam
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@ -117,3 +117,11 @@ App(
requires=["js_app"],
sources=["modules/js_widget.c"],
)
App(
appid="js_vgm",
apptype=FlipperAppType.PLUGIN,
entry_point="js_vgm_ep",
requires=["js_app"],
sources=["modules/js_vgm/*.c", "modules/js_vgm/ICM42688P/*.c"],
)

297
applications/system/js_app/modules/js_vgm/ICM42688P/ICM42688P.c Normal file
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@ -0,0 +1,297 @@
#include "ICM42688P_regs.h"
#include "ICM42688P.h"
#define TAG "ICM42688P"
#define ICM42688P_TIMEOUT 100
struct ICM42688P {
FuriHalSpiBusHandle* spi_bus;
const GpioPin* irq_pin;
float accel_scale;
float gyro_scale;
};
static const struct AccelFullScale {
float value;
uint8_t reg_mask;
} accel_fs_modes[] = {
[AccelFullScale16G] = {16.f, ICM42688_AFS_16G},
[AccelFullScale8G] = {8.f, ICM42688_AFS_8G},
[AccelFullScale4G] = {4.f, ICM42688_AFS_4G},
[AccelFullScale2G] = {2.f, ICM42688_AFS_2G},
};
static const struct GyroFullScale {
float value;
uint8_t reg_mask;
} gyro_fs_modes[] = {
[GyroFullScale2000DPS] = {2000.f, ICM42688_GFS_2000DPS},
[GyroFullScale1000DPS] = {1000.f, ICM42688_GFS_1000DPS},
[GyroFullScale500DPS] = {500.f, ICM42688_GFS_500DPS},
[GyroFullScale250DPS] = {250.f, ICM42688_GFS_250DPS},
[GyroFullScale125DPS] = {125.f, ICM42688_GFS_125DPS},
[GyroFullScale62_5DPS] = {62.5f, ICM42688_GFS_62_5DPS},
[GyroFullScale31_25DPS] = {31.25f, ICM42688_GFS_31_25DPS},
[GyroFullScale15_625DPS] = {15.625f, ICM42688_GFS_15_625DPS},
};
static bool icm42688p_write_reg(FuriHalSpiBusHandle* spi_bus, uint8_t addr, uint8_t value) {
bool res = false;
furi_hal_spi_acquire(spi_bus);
do {
uint8_t cmd_data[2] = {addr & 0x7F, value};
if(!furi_hal_spi_bus_tx(spi_bus, cmd_data, 2, ICM42688P_TIMEOUT)) break;
res = true;
} while(0);
furi_hal_spi_release(spi_bus);
return res;
}
static bool icm42688p_read_reg(FuriHalSpiBusHandle* spi_bus, uint8_t addr, uint8_t* value) {
bool res = false;
furi_hal_spi_acquire(spi_bus);
do {
uint8_t cmd_byte = addr | (1 << 7);
if(!furi_hal_spi_bus_tx(spi_bus, &cmd_byte, 1, ICM42688P_TIMEOUT)) break;
if(!furi_hal_spi_bus_rx(spi_bus, value, 1, ICM42688P_TIMEOUT)) break;
res = true;
} while(0);
furi_hal_spi_release(spi_bus);
return res;
}
static bool
icm42688p_read_mem(FuriHalSpiBusHandle* spi_bus, uint8_t addr, uint8_t* data, uint8_t len) {
bool res = false;
furi_hal_spi_acquire(spi_bus);
do {
uint8_t cmd_byte = addr | (1 << 7);
if(!furi_hal_spi_bus_tx(spi_bus, &cmd_byte, 1, ICM42688P_TIMEOUT)) break;
if(!furi_hal_spi_bus_rx(spi_bus, data, len, ICM42688P_TIMEOUT)) break;
res = true;
} while(0);
furi_hal_spi_release(spi_bus);
return res;
}
bool icm42688p_accel_config(
ICM42688P* icm42688p,
ICM42688PAccelFullScale full_scale,
ICM42688PDataRate rate) {
icm42688p->accel_scale = accel_fs_modes[full_scale].value;
uint8_t reg_value = accel_fs_modes[full_scale].reg_mask | rate;
return icm42688p_write_reg(icm42688p->spi_bus, ICM42688_ACCEL_CONFIG0, reg_value);
}
float icm42688p_accel_get_full_scale(ICM42688P* icm42688p) {
return icm42688p->accel_scale;
}
bool icm42688p_gyro_config(
ICM42688P* icm42688p,
ICM42688PGyroFullScale full_scale,
ICM42688PDataRate rate) {
icm42688p->gyro_scale = gyro_fs_modes[full_scale].value;
uint8_t reg_value = gyro_fs_modes[full_scale].reg_mask | rate;
return icm42688p_write_reg(icm42688p->spi_bus, ICM42688_GYRO_CONFIG0, reg_value);
}
float icm42688p_gyro_get_full_scale(ICM42688P* icm42688p) {
return icm42688p->gyro_scale;
}
bool icm42688p_read_accel_raw(ICM42688P* icm42688p, ICM42688PRawData* data) {
bool ret = icm42688p_read_mem(
icm42688p->spi_bus, ICM42688_ACCEL_DATA_X1, (uint8_t*)data, sizeof(ICM42688PRawData));
return ret;
}
bool icm42688p_read_gyro_raw(ICM42688P* icm42688p, ICM42688PRawData* data) {
bool ret = icm42688p_read_mem(
icm42688p->spi_bus, ICM42688_GYRO_DATA_X1, (uint8_t*)data, sizeof(ICM42688PRawData));
return ret;
}
bool icm42688p_write_gyro_offset(ICM42688P* icm42688p, ICM42688PScaledData* scaled_data) {
if((fabsf(scaled_data->x) > 64.f) || (fabsf(scaled_data->y) > 64.f) ||
(fabsf(scaled_data->z) > 64.f)) {
return false;
}
uint16_t offset_x = (uint16_t)(-(int16_t)(scaled_data->x * 32.f) * 16) >> 4;
uint16_t offset_y = (uint16_t)(-(int16_t)(scaled_data->y * 32.f) * 16) >> 4;
uint16_t offset_z = (uint16_t)(-(int16_t)(scaled_data->z * 32.f) * 16) >> 4;
uint8_t offset_regs[9];
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_REG_BANK_SEL, 4);
icm42688p_read_mem(icm42688p->spi_bus, ICM42688_OFFSET_USER0, offset_regs, 5);
offset_regs[0] = offset_x & 0xFF;
offset_regs[1] = (offset_x & 0xF00) >> 8;
offset_regs[1] |= (offset_y & 0xF00) >> 4;
offset_regs[2] = offset_y & 0xFF;
offset_regs[3] = offset_z & 0xFF;
offset_regs[4] &= 0xF0;
offset_regs[4] |= (offset_z & 0x0F00) >> 8;
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_OFFSET_USER0, offset_regs[0]);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_OFFSET_USER1, offset_regs[1]);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_OFFSET_USER2, offset_regs[2]);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_OFFSET_USER3, offset_regs[3]);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_OFFSET_USER4, offset_regs[4]);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_REG_BANK_SEL, 0);
return true;
}
void icm42688p_apply_scale(ICM42688PRawData* raw_data, float full_scale, ICM42688PScaledData* data) {
data->x = ((float)(raw_data->x)) / 32768.f * full_scale;
data->y = ((float)(raw_data->y)) / 32768.f * full_scale;
data->z = ((float)(raw_data->z)) / 32768.f * full_scale;
}
void icm42688p_apply_scale_fifo(
ICM42688P* icm42688p,
ICM42688PFifoPacket* fifo_data,
ICM42688PScaledData* accel_data,
ICM42688PScaledData* gyro_data) {
float full_scale = icm42688p->accel_scale;
accel_data->x = ((float)(fifo_data->a_x)) / 32768.f * full_scale;
accel_data->y = ((float)(fifo_data->a_y)) / 32768.f * full_scale;
accel_data->z = ((float)(fifo_data->a_z)) / 32768.f * full_scale;
full_scale = icm42688p->gyro_scale;
gyro_data->x = ((float)(fifo_data->g_x)) / 32768.f * full_scale;
gyro_data->y = ((float)(fifo_data->g_y)) / 32768.f * full_scale;
gyro_data->z = ((float)(fifo_data->g_z)) / 32768.f * full_scale;
}
float icm42688p_read_temp(ICM42688P* icm42688p) {
uint8_t reg_val[2];
icm42688p_read_mem(icm42688p->spi_bus, ICM42688_TEMP_DATA1, reg_val, 2);
int16_t temp_int = (reg_val[0] << 8) | reg_val[1];
return ((float)temp_int / 132.48f) + 25.f;
}
void icm42688_fifo_enable(
ICM42688P* icm42688p,
ICM42688PIrqCallback irq_callback,
void* irq_context) {
// FIFO mode: stream
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_FIFO_CONFIG, (1 << 6));
// Little-endian data, FIFO count in records
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INTF_CONFIG0, (1 << 7) | (1 << 6));
// FIFO partial read, FIFO packet: gyro + accel TODO: 20bit
icm42688p_write_reg(
icm42688p->spi_bus, ICM42688_FIFO_CONFIG1, (1 << 6) | (1 << 5) | (1 << 1) | (1 << 0));
// FIFO irq watermark
uint16_t fifo_watermark = 1;
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_FIFO_CONFIG2, fifo_watermark & 0xFF);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_FIFO_CONFIG3, fifo_watermark >> 8);
// IRQ1: push-pull, active high
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_CONFIG, (1 << 1) | (1 << 0));
// Clear IRQ on status read
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_CONFIG0, 0);
// IRQ pulse duration
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_CONFIG1, (1 << 6) | (1 << 5));
uint8_t reg_data = 0;
icm42688p_read_reg(icm42688p->spi_bus, ICM42688_INT_STATUS, &reg_data);
furi_hal_gpio_init(icm42688p->irq_pin, GpioModeInterruptRise, GpioPullDown, GpioSpeedVeryHigh);
furi_hal_gpio_remove_int_callback(icm42688p->irq_pin);
furi_hal_gpio_add_int_callback(icm42688p->irq_pin, irq_callback, irq_context);
// IRQ1 source: FIFO threshold
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE0, (1 << 2));
}
void icm42688_fifo_disable(ICM42688P* icm42688p) {
furi_hal_gpio_remove_int_callback(icm42688p->irq_pin);
furi_hal_gpio_init(icm42688p->irq_pin, GpioModeAnalog, GpioPullNo, GpioSpeedLow);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE0, 0);
// FIFO mode: bypass
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_FIFO_CONFIG, 0);
}
uint16_t icm42688_fifo_get_count(ICM42688P* icm42688p) {
uint16_t reg_val = 0;
icm42688p_read_mem(icm42688p->spi_bus, ICM42688_FIFO_COUNTH, (uint8_t*)&reg_val, 2);
return reg_val;
}
bool icm42688_fifo_read(ICM42688P* icm42688p, ICM42688PFifoPacket* data) {
icm42688p_read_mem(
icm42688p->spi_bus, ICM42688_FIFO_DATA, (uint8_t*)data, sizeof(ICM42688PFifoPacket));
return (data->header) & (1 << 7);
}
ICM42688P* icm42688p_alloc(FuriHalSpiBusHandle* spi_bus, const GpioPin* irq_pin) {
ICM42688P* icm42688p = malloc(sizeof(ICM42688P));
icm42688p->spi_bus = spi_bus;
icm42688p->irq_pin = irq_pin;
return icm42688p;
}
void icm42688p_free(ICM42688P* icm42688p) {
free(icm42688p);
}
bool icm42688p_init(ICM42688P* icm42688p) {
furi_hal_spi_bus_handle_init(icm42688p->spi_bus);
// Software reset
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_REG_BANK_SEL, 0); // Set reg bank to 0
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_DEVICE_CONFIG, 0x01); // SPI Mode 0, SW reset
furi_delay_ms(1);
uint8_t reg_value = 0;
bool read_ok = icm42688p_read_reg(icm42688p->spi_bus, ICM42688_WHO_AM_I, &reg_value);
if(!read_ok) {
FURI_LOG_E(TAG, "Chip ID read failed");
return false;
} else if(reg_value != ICM42688_WHOAMI) {
FURI_LOG_E(
TAG, "Sensor returned wrong ID 0x%02X, expected 0x%02X", reg_value, ICM42688_WHOAMI);
return false;
}
// Disable all interrupts
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE0, 0);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE1, 0);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE3, 0);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE4, 0);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_REG_BANK_SEL, 4);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE6, 0);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INT_SOURCE7, 0);
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_REG_BANK_SEL, 0);
// Data format: little endian
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_INTF_CONFIG0, 0);
// Enable all sensors
icm42688p_write_reg(
icm42688p->spi_bus,
ICM42688_PWR_MGMT0,
ICM42688_PWR_TEMP_ON | ICM42688_PWR_GYRO_MODE_LN | ICM42688_PWR_ACCEL_MODE_LN);
furi_delay_ms(45);
icm42688p_accel_config(icm42688p, AccelFullScale16G, DataRate1kHz);
icm42688p_gyro_config(icm42688p, GyroFullScale2000DPS, DataRate1kHz);
return true;
}
bool icm42688p_deinit(ICM42688P* icm42688p) {
// Software reset
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_REG_BANK_SEL, 0); // Set reg bank to 0
icm42688p_write_reg(icm42688p->spi_bus, ICM42688_DEVICE_CONFIG, 0x01); // SPI Mode 0, SW reset
furi_hal_spi_bus_handle_deinit(icm42688p->spi_bus);
return true;
}

127
applications/system/js_app/modules/js_vgm/ICM42688P/ICM42688P.h Normal file
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#pragma once
#include <furi.h>
#include <furi_hal.h>
#ifdef __cplusplus
extern "C" {
#endif
typedef enum {
DataRate32kHz = 0x01,
DataRate16kHz = 0x02,
DataRate8kHz = 0x03,
DataRate4kHz = 0x04,
DataRate2kHz = 0x05,
DataRate1kHz = 0x06,
DataRate200Hz = 0x07,
DataRate100Hz = 0x08,
DataRate50Hz = 0x09,
DataRate25Hz = 0x0A,
DataRate12_5Hz = 0x0B,
DataRate6_25Hz = 0x0C, // Accelerometer only
DataRate3_125Hz = 0x0D, // Accelerometer only
DataRate1_5625Hz = 0x0E, // Accelerometer only
DataRate500Hz = 0x0F,
} ICM42688PDataRate;
typedef enum {
AccelFullScale16G = 0,
AccelFullScale8G,
AccelFullScale4G,
AccelFullScale2G,
AccelFullScaleTotal,
} ICM42688PAccelFullScale;
typedef enum {
GyroFullScale2000DPS = 0,
GyroFullScale1000DPS,
GyroFullScale500DPS,
GyroFullScale250DPS,
GyroFullScale125DPS,
GyroFullScale62_5DPS,
GyroFullScale31_25DPS,
GyroFullScale15_625DPS,
GyroFullScaleTotal,
} ICM42688PGyroFullScale;
typedef struct {
int16_t x;
int16_t y;
int16_t z;
} __attribute__((packed)) ICM42688PRawData;
typedef struct {
uint8_t header;
int16_t a_x;
int16_t a_y;
int16_t a_z;
int16_t g_x;
int16_t g_y;
int16_t g_z;
uint8_t temp;
uint16_t ts;
} __attribute__((packed)) ICM42688PFifoPacket;
typedef struct {
float x;
float y;
float z;
} ICM42688PScaledData;
typedef struct ICM42688P ICM42688P;
typedef void (*ICM42688PIrqCallback)(void* ctx);
ICM42688P* icm42688p_alloc(FuriHalSpiBusHandle* spi_bus, const GpioPin* irq_pin);
bool icm42688p_init(ICM42688P* icm42688p);
bool icm42688p_deinit(ICM42688P* icm42688p);
void icm42688p_free(ICM42688P* icm42688p);
bool icm42688p_accel_config(
ICM42688P* icm42688p,
ICM42688PAccelFullScale full_scale,
ICM42688PDataRate rate);
float icm42688p_accel_get_full_scale(ICM42688P* icm42688p);
bool icm42688p_gyro_config(
ICM42688P* icm42688p,
ICM42688PGyroFullScale full_scale,
ICM42688PDataRate rate);
float icm42688p_gyro_get_full_scale(ICM42688P* icm42688p);
bool icm42688p_read_accel_raw(ICM42688P* icm42688p, ICM42688PRawData* data);
bool icm42688p_read_gyro_raw(ICM42688P* icm42688p, ICM42688PRawData* data);
bool icm42688p_write_gyro_offset(ICM42688P* icm42688p, ICM42688PScaledData* scaled_data);
void icm42688p_apply_scale(ICM42688PRawData* raw_data, float full_scale, ICM42688PScaledData* data);
void icm42688p_apply_scale_fifo(
ICM42688P* icm42688p,
ICM42688PFifoPacket* fifo_data,
ICM42688PScaledData* accel_data,
ICM42688PScaledData* gyro_data);
float icm42688p_read_temp(ICM42688P* icm42688p);
void icm42688_fifo_enable(
ICM42688P* icm42688p,
ICM42688PIrqCallback irq_callback,
void* irq_context);
void icm42688_fifo_disable(ICM42688P* icm42688p);
uint16_t icm42688_fifo_get_count(ICM42688P* icm42688p);
bool icm42688_fifo_read(ICM42688P* icm42688p, ICM42688PFifoPacket* data);
#ifdef __cplusplus
}
#endif

176
applications/system/js_app/modules/js_vgm/ICM42688P/ICM42688P_regs.h Normal file
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#pragma once
#define ICM42688_WHOAMI 0x47
// Bank 0
#define ICM42688_DEVICE_CONFIG 0x11
#define ICM42688_DRIVE_CONFIG 0x13
#define ICM42688_INT_CONFIG 0x14
#define ICM42688_FIFO_CONFIG 0x16
#define ICM42688_TEMP_DATA1 0x1D
#define ICM42688_TEMP_DATA0 0x1E
#define ICM42688_ACCEL_DATA_X1 0x1F
#define ICM42688_ACCEL_DATA_X0 0x20
#define ICM42688_ACCEL_DATA_Y1 0x21
#define ICM42688_ACCEL_DATA_Y0 0x22
#define ICM42688_ACCEL_DATA_Z1 0x23
#define ICM42688_ACCEL_DATA_Z0 0x24
#define ICM42688_GYRO_DATA_X1 0x25
#define ICM42688_GYRO_DATA_X0 0x26
#define ICM42688_GYRO_DATA_Y1 0x27
#define ICM42688_GYRO_DATA_Y0 0x28
#define ICM42688_GYRO_DATA_Z1 0x29
#define ICM42688_GYRO_DATA_Z0 0x2A
#define ICM42688_TMST_FSYNCH 0x2B
#define ICM42688_TMST_FSYNCL 0x2C
#define ICM42688_INT_STATUS 0x2D
#define ICM42688_FIFO_COUNTH 0x2E
#define ICM42688_FIFO_COUNTL 0x2F
#define ICM42688_FIFO_DATA 0x30
#define ICM42688_APEX_DATA0 0x31
#define ICM42688_APEX_DATA1 0x32
#define ICM42688_APEX_DATA2 0x33
#define ICM42688_APEX_DATA3 0x34
#define ICM42688_APEX_DATA4 0x35
#define ICM42688_APEX_DATA5 0x36
#define ICM42688_INT_STATUS2 0x37
#define ICM42688_INT_STATUS3 0x38
#define ICM42688_SIGNAL_PATH_RESET 0x4B
#define ICM42688_INTF_CONFIG0 0x4C
#define ICM42688_INTF_CONFIG1 0x4D
#define ICM42688_PWR_MGMT0 0x4E
#define ICM42688_GYRO_CONFIG0 0x4F
#define ICM42688_ACCEL_CONFIG0 0x50
#define ICM42688_GYRO_CONFIG1 0x51
#define ICM42688_GYRO_ACCEL_CONFIG0 0x52
#define ICM42688_ACCEL_CONFIG1 0x53
#define ICM42688_TMST_CONFIG 0x54
#define ICM42688_APEX_CONFIG0 0x56
#define ICM42688_SMD_CONFIG 0x57
#define ICM42688_FIFO_CONFIG1 0x5F
#define ICM42688_FIFO_CONFIG2 0x60
#define ICM42688_FIFO_CONFIG3 0x61
#define ICM42688_FSYNC_CONFIG 0x62
#define ICM42688_INT_CONFIG0 0x63
#define ICM42688_INT_CONFIG1 0x64
#define ICM42688_INT_SOURCE0 0x65
#define ICM42688_INT_SOURCE1 0x66
#define ICM42688_INT_SOURCE3 0x68
#define ICM42688_INT_SOURCE4 0x69
#define ICM42688_FIFO_LOST_PKT0 0x6C
#define ICM42688_FIFO_LOST_PKT1 0x6D
#define ICM42688_SELF_TEST_CONFIG 0x70
#define ICM42688_WHO_AM_I 0x75
#define ICM42688_REG_BANK_SEL 0x76
// Bank 1
#define ICM42688_SENSOR_CONFIG0 0x03
#define ICM42688_GYRO_CONFIG_STATIC2 0x0B
#define ICM42688_GYRO_CONFIG_STATIC3 0x0C
#define ICM42688_GYRO_CONFIG_STATIC4 0x0D
#define ICM42688_GYRO_CONFIG_STATIC5 0x0E
#define ICM42688_GYRO_CONFIG_STATIC6 0x0F
#define ICM42688_GYRO_CONFIG_STATIC7 0x10
#define ICM42688_GYRO_CONFIG_STATIC8 0x11
#define ICM42688_GYRO_CONFIG_STATIC9 0x12
#define ICM42688_GYRO_CONFIG_STATIC10 0x13
#define ICM42688_XG_ST_DATA 0x5F
#define ICM42688_YG_ST_DATA 0x60
#define ICM42688_ZG_ST_DATA 0x61
#define ICM42688_TMSTVAL0 0x62
#define ICM42688_TMSTVAL1 0x63
#define ICM42688_TMSTVAL2 0x64
#define ICM42688_INTF_CONFIG4 0x7A
#define ICM42688_INTF_CONFIG5 0x7B
#define ICM42688_INTF_CONFIG6 0x7C
// Bank 2
#define ICM42688_ACCEL_CONFIG_STATIC2 0x03
#define ICM42688_ACCEL_CONFIG_STATIC3 0x04
#define ICM42688_ACCEL_CONFIG_STATIC4 0x05
#define ICM42688_XA_ST_DATA 0x3B
#define ICM42688_YA_ST_DATA 0x3C
#define ICM42688_ZA_ST_DATA 0x3D
// Bank 4
#define ICM42688_APEX_CONFIG1 0x40
#define ICM42688_APEX_CONFIG2 0x41
#define ICM42688_APEX_CONFIG3 0x42
#define ICM42688_APEX_CONFIG4 0x43
#define ICM42688_APEX_CONFIG5 0x44
#define ICM42688_APEX_CONFIG6 0x45
#define ICM42688_APEX_CONFIG7 0x46
#define ICM42688_APEX_CONFIG8 0x47
#define ICM42688_APEX_CONFIG9 0x48
#define ICM42688_ACCEL_WOM_X_THR 0x4A
#define ICM42688_ACCEL_WOM_Y_THR 0x4B
#define ICM42688_ACCEL_WOM_Z_THR 0x4C
#define ICM42688_INT_SOURCE6 0x4D
#define ICM42688_INT_SOURCE7 0x4E
#define ICM42688_INT_SOURCE8 0x4F
#define ICM42688_INT_SOURCE9 0x50
#define ICM42688_INT_SOURCE10 0x51
#define ICM42688_OFFSET_USER0 0x77
#define ICM42688_OFFSET_USER1 0x78
#define ICM42688_OFFSET_USER2 0x79
#define ICM42688_OFFSET_USER3 0x7A
#define ICM42688_OFFSET_USER4 0x7B
#define ICM42688_OFFSET_USER5 0x7C
#define ICM42688_OFFSET_USER6 0x7D
#define ICM42688_OFFSET_USER7 0x7E
#define ICM42688_OFFSET_USER8 0x7F
// PWR_MGMT0
#define ICM42688_PWR_TEMP_ON (0 << 5)
#define ICM42688_PWR_TEMP_OFF (1 << 5)
#define ICM42688_PWR_IDLE (1 << 4)
#define ICM42688_PWR_GYRO_MODE_OFF (0 << 2)
#define ICM42688_PWR_GYRO_MODE_LN (3 << 2)
#define ICM42688_PWR_ACCEL_MODE_OFF (0 << 0)
#define ICM42688_PWR_ACCEL_MODE_LP (2 << 0)
#define ICM42688_PWR_ACCEL_MODE_LN (3 << 0)
// GYRO_CONFIG0
#define ICM42688_GFS_2000DPS (0x00 << 5)
#define ICM42688_GFS_1000DPS (0x01 << 5)
#define ICM42688_GFS_500DPS (0x02 << 5)
#define ICM42688_GFS_250DPS (0x03 << 5)
#define ICM42688_GFS_125DPS (0x04 << 5)
#define ICM42688_GFS_62_5DPS (0x05 << 5)
#define ICM42688_GFS_31_25DPS (0x06 << 5)
#define ICM42688_GFS_15_625DPS (0x07 << 5)
#define ICM42688_GODR_32kHz 0x01
#define ICM42688_GODR_16kHz 0x02
#define ICM42688_GODR_8kHz 0x03
#define ICM42688_GODR_4kHz 0x04
#define ICM42688_GODR_2kHz 0x05
#define ICM42688_GODR_1kHz 0x06
#define ICM42688_GODR_200Hz 0x07
#define ICM42688_GODR_100Hz 0x08
#define ICM42688_GODR_50Hz 0x09
#define ICM42688_GODR_25Hz 0x0A
#define ICM42688_GODR_12_5Hz 0x0B
#define ICM42688_GODR_500Hz 0x0F
// ACCEL_CONFIG0
#define ICM42688_AFS_16G (0x00 << 5)
#define ICM42688_AFS_8G (0x01 << 5)
#define ICM42688_AFS_4G (0x02 << 5)
#define ICM42688_AFS_2G (0x03 << 5)
#define ICM42688_AODR_32kHz 0x01
#define ICM42688_AODR_16kHz 0x02
#define ICM42688_AODR_8kHz 0x03
#define ICM42688_AODR_4kHz 0x04
#define ICM42688_AODR_2kHz 0x05
#define ICM42688_AODR_1kHz 0x06
#define ICM42688_AODR_200Hz 0x07
#define ICM42688_AODR_100Hz 0x08
#define ICM42688_AODR_50Hz 0x09
#define ICM42688_AODR_25Hz 0x0A
#define ICM42688_AODR_12_5Hz 0x0B
#define ICM42688_AODR_6_25Hz 0x0C
#define ICM42688_AODR_3_125Hz 0x0D
#define ICM42688_AODR_1_5625Hz 0x0E
#define ICM42688_AODR_500Hz 0x0F

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The files imu.c, imu.h, and ICM42688P are from https://github.com/flipperdevices/flipperzero-game-engine.git
Please see that file for the license.

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#include <furi.h>
#include "imu.h"
#include "ICM42688P/ICM42688P.h"
#define TAG "IMU"
#define ACCEL_GYRO_RATE DataRate100Hz
#define FILTER_SAMPLE_FREQ 100.f
#define FILTER_BETA 0.08f
#define SAMPLE_RATE_DIV 5
#define SENSITIVITY_K 30.f
#define EXP_RATE 1.1f
#define IMU_CALI_AVG 64
typedef enum {
ImuStop = (1 << 0),
ImuNewData = (1 << 1),
} ImuThreadFlags;
#define FLAGS_ALL (ImuStop | ImuNewData)
typedef struct {
float q0;
float q1;
float q2;
float q3;
float roll;
float pitch;
float yaw;
} ImuProcessedData;
typedef struct {
FuriThread* thread;
ICM42688P* icm42688p;
ImuProcessedData processed_data;
bool lefty;
} ImuThread;
static void imu_madgwick_filter(
ImuProcessedData* out,
ICM42688PScaledData* accel,
ICM42688PScaledData* gyro);
static void imu_irq_callback(void* context) {
furi_assert(context);
ImuThread* imu = context;
furi_thread_flags_set(furi_thread_get_id(imu->thread), ImuNewData);
}
static void imu_process_data(ImuThread* imu, ICM42688PFifoPacket* in_data) {
ICM42688PScaledData accel_data;
ICM42688PScaledData gyro_data;
// Get accel and gyro data in g and degrees/s
icm42688p_apply_scale_fifo(imu->icm42688p, in_data, &accel_data, &gyro_data);
// Gyro: degrees/s to rads/s
gyro_data.x = gyro_data.x / 180.f * M_PI;
gyro_data.y = gyro_data.y / 180.f * M_PI;
gyro_data.z = gyro_data.z / 180.f * M_PI;
// Sensor Fusion algorithm
ImuProcessedData* out = &imu->processed_data;
imu_madgwick_filter(out, &accel_data, &gyro_data);
// Quaternion to euler angles
float roll = atan2f(
out->q0 * out->q1 + out->q2 * out->q3, 0.5f - out->q1 * out->q1 - out->q2 * out->q2);
float pitch = asinf(-2.0f * (out->q1 * out->q3 - out->q0 * out->q2));
float yaw = atan2f(
out->q1 * out->q2 + out->q0 * out->q3, 0.5f - out->q2 * out->q2 - out->q3 * out->q3);
// Euler angles: rads to degrees
out->roll = roll / M_PI * 180.f;
out->pitch = pitch / M_PI * 180.f;
out->yaw = yaw / M_PI * 180.f;
}
static void calibrate_gyro(ImuThread* imu) {
ICM42688PRawData data;
ICM42688PScaledData offset_scaled = {.x = 0.f, .y = 0.f, .z = 0.f};
icm42688p_write_gyro_offset(imu->icm42688p, &offset_scaled);
furi_delay_ms(10);
int32_t avg_x = 0;
int32_t avg_y = 0;
int32_t avg_z = 0;
for(uint8_t i = 0; i < IMU_CALI_AVG; i++) {
icm42688p_read_gyro_raw(imu->icm42688p, &data);
avg_x += data.x;
avg_y += data.y;
avg_z += data.z;
furi_delay_ms(2);
}
data.x = avg_x / IMU_CALI_AVG;
data.y = avg_y / IMU_CALI_AVG;
data.z = avg_z / IMU_CALI_AVG;
icm42688p_apply_scale(&data, icm42688p_gyro_get_full_scale(imu->icm42688p), &offset_scaled);
FURI_LOG_I(
TAG,
"Offsets: x %f, y %f, z %f",
(double)offset_scaled.x,
(double)offset_scaled.y,
(double)offset_scaled.z);
icm42688p_write_gyro_offset(imu->icm42688p, &offset_scaled);
}
// static float imu_angle_diff(float a, float b) {
// float diff = a - b;
// if(diff > 180.f)
// diff -= 360.f;
// else if(diff < -180.f)
// diff += 360.f;
// return diff;
// }
static int32_t imu_thread(void* context) {
furi_assert(context);
ImuThread* imu = context;
// float yaw_last = 0.f;
// float pitch_last = 0.f;
// float diff_x = 0.f;
// float diff_y = 0.f;
calibrate_gyro(imu);
icm42688p_accel_config(imu->icm42688p, AccelFullScale16G, ACCEL_GYRO_RATE);
icm42688p_gyro_config(imu->icm42688p, GyroFullScale2000DPS, ACCEL_GYRO_RATE);
imu->processed_data.q0 = 1.f;
imu->processed_data.q1 = 0.f;
imu->processed_data.q2 = 0.f;
imu->processed_data.q3 = 0.f;
icm42688_fifo_enable(imu->icm42688p, imu_irq_callback, imu);
while(1) {
uint32_t events = furi_thread_flags_wait(FLAGS_ALL, FuriFlagWaitAny, FuriWaitForever);
if(events & ImuStop) {
break;
}
if(events & ImuNewData) {
uint16_t data_pending = icm42688_fifo_get_count(imu->icm42688p);
ICM42688PFifoPacket data;
while(data_pending--) {
icm42688_fifo_read(imu->icm42688p, &data);
imu_process_data(imu, &data);
}
}
}
icm42688_fifo_disable(imu->icm42688p);
return 0;
}
ImuThread* imu_start(ICM42688P* icm42688p) {
ImuThread* imu = malloc(sizeof(ImuThread));
imu->icm42688p = icm42688p;
imu->thread = furi_thread_alloc_ex("ImuThread", 4096, imu_thread, imu);
imu->lefty = furi_hal_rtc_is_flag_set(FuriHalRtcFlagHandOrient);
furi_thread_start(imu->thread);
return imu;
}
void imu_stop(ImuThread* imu) {
furi_assert(imu);
furi_thread_flags_set(furi_thread_get_id(imu->thread), ImuStop);
furi_thread_join(imu->thread);
furi_thread_free(imu->thread);
free(imu);
}
static float imu_inv_sqrt(float number) {
union {
float f;
uint32_t i;
} conv = {.f = number};
conv.i = 0x5F3759Df - (conv.i >> 1);
conv.f *= 1.5f - (number * 0.5f * conv.f * conv.f);
return conv.f;
}
/* Simple madgwik filter, based on: https://github.com/arduino-libraries/MadgwickAHRS/ */
static void imu_madgwick_filter(
ImuProcessedData* out,
ICM42688PScaledData* accel,
ICM42688PScaledData* gyro) {
float recipNorm;
float s0, s1, s2, s3;
float qDot1, qDot2, qDot3, qDot4;
float _2q0, _2q1, _2q2, _2q3, _4q0, _4q1, _4q2, _8q1, _8q2, q0q0, q1q1, q2q2, q3q3;
// Rate of change of quaternion from gyroscope
qDot1 = 0.5f * (-out->q1 * gyro->x - out->q2 * gyro->y - out->q3 * gyro->z);
qDot2 = 0.5f * (out->q0 * gyro->x + out->q2 * gyro->z - out->q3 * gyro->y);
qDot3 = 0.5f * (out->q0 * gyro->y - out->q1 * gyro->z + out->q3 * gyro->x);
qDot4 = 0.5f * (out->q0 * gyro->z + out->q1 * gyro->y - out->q2 * gyro->x);
// Compute feedback only if accelerometer measurement valid (avoids NaN in accelerometer normalisation)
if(!((accel->x == 0.0f) && (accel->y == 0.0f) && (accel->z == 0.0f))) {
// Normalise accelerometer measurement
recipNorm = imu_inv_sqrt(accel->x * accel->x + accel->y * accel->y + accel->z * accel->z);
accel->x *= recipNorm;
accel->y *= recipNorm;
accel->z *= recipNorm;
// Auxiliary variables to avoid repeated arithmetic
_2q0 = 2.0f * out->q0;
_2q1 = 2.0f * out->q1;
_2q2 = 2.0f * out->q2;
_2q3 = 2.0f * out->q3;
_4q0 = 4.0f * out->q0;
_4q1 = 4.0f * out->q1;
_4q2 = 4.0f * out->q2;
_8q1 = 8.0f * out->q1;
_8q2 = 8.0f * out->q2;
q0q0 = out->q0 * out->q0;
q1q1 = out->q1 * out->q1;
q2q2 = out->q2 * out->q2;
q3q3 = out->q3 * out->q3;
// Gradient decent algorithm corrective step
s0 = _4q0 * q2q2 + _2q2 * accel->x + _4q0 * q1q1 - _2q1 * accel->y;
s1 = _4q1 * q3q3 - _2q3 * accel->x + 4.0f * q0q0 * out->q1 - _2q0 * accel->y - _4q1 +
_8q1 * q1q1 + _8q1 * q2q2 + _4q1 * accel->z;
s2 = 4.0f * q0q0 * out->q2 + _2q0 * accel->x + _4q2 * q3q3 - _2q3 * accel->y - _4q2 +
_8q2 * q1q1 + _8q2 * q2q2 + _4q2 * accel->z;
s3 = 4.0f * q1q1 * out->q3 - _2q1 * accel->x + 4.0f * q2q2 * out->q3 - _2q2 * accel->y;
recipNorm =
imu_inv_sqrt(s0 * s0 + s1 * s1 + s2 * s2 + s3 * s3); // normalise step magnitude
s0 *= recipNorm;
s1 *= recipNorm;
s2 *= recipNorm;
s3 *= recipNorm;
// Apply feedback step
qDot1 -= FILTER_BETA * s0;
qDot2 -= FILTER_BETA * s1;
qDot3 -= FILTER_BETA * s2;
qDot4 -= FILTER_BETA * s3;
}
// Integrate rate of change of quaternion to yield quaternion
out->q0 += qDot1 * (1.0f / FILTER_SAMPLE_FREQ);
out->q1 += qDot2 * (1.0f / FILTER_SAMPLE_FREQ);
out->q2 += qDot3 * (1.0f / FILTER_SAMPLE_FREQ);
out->q3 += qDot4 * (1.0f / FILTER_SAMPLE_FREQ);
// Normalise quaternion
recipNorm = imu_inv_sqrt(
out->q0 * out->q0 + out->q1 * out->q1 + out->q2 * out->q2 + out->q3 * out->q3);
out->q0 *= recipNorm;
out->q1 *= recipNorm;
out->q2 *= recipNorm;
out->q3 *= recipNorm;
}
/* IMU API */
struct Imu {
FuriHalSpiBusHandle* icm42688p_device;
ICM42688P* icm42688p;
ImuThread* thread;
bool present;
};
Imu* imu_alloc(void) {
Imu* imu = malloc(sizeof(Imu));
imu->icm42688p_device = malloc(sizeof(FuriHalSpiBusHandle));
memcpy(imu->icm42688p_device, &furi_hal_spi_bus_handle_external, sizeof(FuriHalSpiBusHandle));
imu->icm42688p_device->cs = &gpio_ext_pc3;
imu->icm42688p = icm42688p_alloc(imu->icm42688p_device, &gpio_ext_pb2);
imu->present = icm42688p_init(imu->icm42688p);
if(imu->present) {
imu->thread = imu_start(imu->icm42688p);
}
return imu;
}
void imu_free(Imu* imu) {
if(imu->present) {
imu_stop(imu->thread);
}
icm42688p_deinit(imu->icm42688p);
icm42688p_free(imu->icm42688p);
free(imu->icm42688p_device);
free(imu);
}
bool imu_present(Imu* imu) {
return imu->present;
}
float imu_pitch_get(Imu* imu) {
// we pretend that reading a float is an atomic operation
return imu->thread->lefty ? -imu->thread->processed_data.pitch :
imu->thread->processed_data.pitch;
}
float imu_roll_get(Imu* imu) {
// we pretend that reading a float is an atomic operation
return imu->thread->processed_data.roll;
}
float imu_yaw_get(Imu* imu) {
// we pretend that reading a float is an atomic operation
return imu->thread->lefty ? -imu->thread->processed_data.yaw : imu->thread->processed_data.yaw;
}

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#pragma once
typedef struct Imu Imu;
Imu* imu_alloc(void);
void imu_free(Imu* imu);
bool imu_present(Imu* imu);
float imu_pitch_get(Imu* imu);
float imu_roll_get(Imu* imu);
float imu_yaw_get(Imu* imu);

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#include "../../js_modules.h"
#include <furi.h>
#include <toolbox/path.h>
#include "imu.h"
#define TAG "JsVgm"
typedef struct {
Imu* imu;
bool present;
} JsVgmInst;
static void js_vgm_get_pitch(struct mjs* mjs) {
mjs_val_t obj_inst = mjs_get(mjs, mjs_get_this(mjs), INST_PROP_NAME, ~0);
JsVgmInst* vgm = mjs_get_ptr(mjs, obj_inst);
furi_assert(vgm);
if(vgm->present) {
mjs_return(mjs, mjs_mk_number(mjs, imu_pitch_get(vgm->imu)));
} else {
FURI_LOG_T(TAG, "VGM not present.");
mjs_return(mjs, mjs_mk_undefined());
}
}
static void js_vgm_get_roll(struct mjs* mjs) {
mjs_val_t obj_inst = mjs_get(mjs, mjs_get_this(mjs), INST_PROP_NAME, ~0);
JsVgmInst* vgm = mjs_get_ptr(mjs, obj_inst);
furi_assert(vgm);
if(vgm->present) {
mjs_return(mjs, mjs_mk_number(mjs, imu_roll_get(vgm->imu)));
} else {
FURI_LOG_T(TAG, "VGM not present.");
mjs_return(mjs, mjs_mk_undefined());
}
}
static void js_vgm_get_yaw(struct mjs* mjs) {
mjs_val_t obj_inst = mjs_get(mjs, mjs_get_this(mjs), INST_PROP_NAME, ~0);
JsVgmInst* vgm = mjs_get_ptr(mjs, obj_inst);
furi_assert(vgm);
if(vgm->present) {
mjs_return(mjs, mjs_mk_number(mjs, imu_yaw_get(vgm->imu)));
} else {
FURI_LOG_T(TAG, "VGM not present.");
mjs_return(mjs, mjs_mk_undefined());
}
}
static float distance(float current, float start, float angle) {
// make 0 to 359.999...
current = (current < 0) ? current + 360 : current;
start = (start < 0) ? start + 360 : start;
// get max and min
bool max_is_current = current > start;
float max = (max_is_current) ? current : start;
float min = (max_is_current) ? start : current;
// get diff, check if it's greater than 180, and adjust
float diff = max - min;
bool diff_gt_180 = diff > 180;
if(diff_gt_180) {
diff = 360 - diff;
}
// if diff is less than angle return 0
if(diff < angle) {
FURI_LOG_T(TAG, "diff: %f, angle: %f", (double)diff, (double)angle);
return 0;
}
// return diff with sign
return (max_is_current ^ diff_gt_180) ? -diff : diff;
}
static void js_vgm_delta_yaw(struct mjs* mjs) {
mjs_val_t obj_inst = mjs_get(mjs, mjs_get_this(mjs), INST_PROP_NAME, ~0);
JsVgmInst* vgm = mjs_get_ptr(mjs, obj_inst);
furi_assert(vgm);
size_t num_args = mjs_nargs(mjs);
if(num_args < 1 || num_args > 2) {
mjs_prepend_errorf(
mjs,
MJS_BAD_ARGS_ERROR,
"Invalid args. Pass (angle [, timeout]). Got %d args.",
num_args);
mjs_return(mjs, mjs_mk_undefined());
return;
}
if(!vgm->present) {
FURI_LOG_T(TAG, "VGM not present.");
mjs_return(mjs, MJS_UNDEFINED);
return;
}
double angle = mjs_get_double(mjs, mjs_arg(mjs, 0));
if(isnan(angle)) {
mjs_prepend_errorf(mjs, MJS_TYPE_ERROR, "Invalid arg (angle).");
mjs_return(mjs, mjs_mk_undefined());
return;
}
uint32_t ms = (num_args == 2) ? mjs_get_int(mjs, mjs_arg(mjs, 1)) : 3000;
uint32_t timeout = furi_get_tick() + ms;
float initial_yaw = imu_yaw_get(vgm->imu);
do {
float current_yaw = imu_yaw_get(vgm->imu);
double diff = distance(current_yaw, initial_yaw, angle);
if(diff != 0) {
mjs_return(mjs, mjs_mk_number(mjs, diff));
return;
}
furi_delay_ms(100);
} while(furi_get_tick() < timeout);
mjs_return(mjs, mjs_mk_number(mjs, 0));
}
static void* js_vgm_create(struct mjs* mjs, mjs_val_t* object) {
JsVgmInst* vgm = malloc(sizeof(JsVgmInst));
vgm->imu = imu_alloc();
vgm->present = imu_present(vgm->imu);
if(!vgm->present) FURI_LOG_W(TAG, "VGM not present.");
mjs_val_t vgm_obj = mjs_mk_object(mjs);
mjs_set(mjs, vgm_obj, INST_PROP_NAME, ~0, mjs_mk_foreign(mjs, vgm));
mjs_set(mjs, vgm_obj, "getPitch", ~0, MJS_MK_FN(js_vgm_get_pitch));
mjs_set(mjs, vgm_obj, "getRoll", ~0, MJS_MK_FN(js_vgm_get_roll));
mjs_set(mjs, vgm_obj, "getYaw", ~0, MJS_MK_FN(js_vgm_get_yaw));
mjs_set(mjs, vgm_obj, "deltaYaw", ~0, MJS_MK_FN(js_vgm_delta_yaw));
*object = vgm_obj;
return vgm;
}
static void js_vgm_destroy(void* inst) {
JsVgmInst* vgm = inst;
furi_assert(vgm);
imu_free(vgm->imu);
vgm->imu = NULL;
free(vgm);
}
static const JsModuleDescriptor js_vgm_desc = {
name: "vgm",
create: js_vgm_create,
destroy: js_vgm_destroy,
};
static const FlipperAppPluginDescriptor plugin_descriptor = {
.appid = PLUGIN_APP_ID,
.ep_api_version = PLUGIN_API_VERSION,
.entry_point = &js_vgm_desc,
};
const FlipperAppPluginDescriptor* js_vgm_ep(void) {
return &plugin_descriptor;
}

3
applications/system/js_app/modules/js_widget.c
View File

@ -851,9 +851,8 @@ static void widget_remove_view(void* context) {
ComponentArray_it(it, model->component);
while(!ComponentArray_end_p(it)) {
WidgetComponent* component = *ComponentArray_ref(it);
if(component->free) {
if(component && component->free) {
component->free(component);
component->free = NULL;
}
ComponentArray_next(it);
}