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#include <rcc/rcc.h>
#include <interrupt/interrupt.h>
#include <os/thread.h>
#include <os/time.h>
#include <gpio/pin.h>
#include <usb/usb.h>
#include <usb/descriptor.h>
#include <i2c/i2c.h>
#include <timer/timer.h>
#include "lsm303dlm.h"
#include "l3gd20.h"
#include "ppmsum.h"
static Pin& led_status = PA4;
static Pin& led_error = PC4;
static Pin& usb_vbus = PB13;
static Pin& usb_dm = PB14;
static Pin& usb_dp = PB15;
static Pin& jtag_tdo = PC3;
static Pin& jtag_tms = PC13;
static Pin& jtag_tck = PC14;
static Pin& jtag_tdi = PC15;
static Pin& i2c_scl = PB10;
static Pin& i2c_sda = PB11;
static Pin& cs_pressure = PB4;
static Pin& cs_gyro = PB5;
static Pin& esc_power = PA1;
static Pin pwm_outputs[] = {PC6, PC7, PC8, PC9};
volatile float g_throttle = 0;
class PID {
float i_acc;
float last_error;
const float dt = (1.0 / 400);
public:
float Kp;
float Ki;
float Kd;
PID() : i_acc(0), last_error(0), Kp(0), Ki(0), Kd(0) {}
float update(float error) {
float corr = Kp * error + (i_acc += Ki * error * dt) + Kd * (error - last_error) / dt;
last_error = error;
return corr;
}
void reset() {
i_acc = 0;
last_error = 0;
}
};
PID pid_x;
PID pid_y;
PID pid_z;
volatile uint32_t gyro_calib = 0;
float gyro_calib_x = 0;
float gyro_calib_y = 0;
float gyro_calib_z = 0;
auto dev_desc = device_desc(0x200, 0, 0, 0, 64, 0x1234, 0x5678, 0, 0, 0, 0, 1);
auto conf_desc = configuration_desc(3, 1, 0, 0xc0, 0,
interface_desc(0, 0, 3, 0xff, 0x00, 0x00, 0,
endpoint_desc(0x01, 0x02, 64, 0), // OUT
endpoint_desc(0x81, 0x02, 64, 0), // IN
endpoint_desc(0x82, 0x01, 64, 1) // IN ISO
)
);
desc_t dev_desc_p = {sizeof(dev_desc), (void*)&dev_desc};
desc_t conf_desc_p = {sizeof(conf_desc), (void*)&conf_desc};
USB_otg usb(OTG_HS, dev_desc_p, conf_desc_p);
class USB_I2C : public USB_class_driver {
private:
USB_generic& usb;
I2C_t& i2c;
bool i2c_read(uint16_t wValue, uint16_t wIndex, uint16_t wLength) {
uint8_t buf[wLength];
i2c.read_reg(wValue, wIndex, wLength, buf);
usb.write(0, (uint32_t*)buf, wLength);
return true;
}
public:
USB_I2C(USB_generic& usbd, I2C_t& i2c_bus) : usb(usbd), i2c(i2c_bus) {
usb.register_driver(this);
}
protected:
virtual SetupStatus handle_setup(uint8_t bmRequestType, uint8_t bRequest, uint16_t wValue, uint16_t wIndex, uint16_t wLength) {
if(bmRequestType == 0xc0 && bRequest == 0xf0) {
return i2c_read(wValue, wIndex, wLength) ? SetupStatus::Ok : SetupStatus::Stall;
}
return SetupStatus::Unhandled;
}
};
USB_I2C usb_i2c(usb, I2C2);
class USB_JTAG : public USB_class_driver {
private:
USB_generic& usb;
bool jtag_tick(bool tdi, bool tms) {
bool tdo = jtag_tdo.get();
jtag_tdi.set(tdi);
jtag_tms.set(tms);
jtag_tck.on();
for(uint32_t i = 0; i < 1000; i++) {
asm volatile("nop");
}
jtag_tck.off();
for(uint32_t i = 0; i < 1000; i++) {
asm volatile("nop");
}
return tdo;
}
bool jtag_shift(uint16_t wValue, uint16_t wIndex, uint16_t wLength) {
if(wLength > 16) {
return false;
}
uint32_t tdo = 0;
for(int16_t i = 0; i < wLength; i++) {
tdo |= jtag_tick(wValue & 1, wIndex & 1) ? 1 << i : 0;
wValue >>= 1;
wIndex >>= 1;
}
usb.write(0, &tdo, (wLength + 7) >> 3);
return true;
}
public:
USB_JTAG(USB_generic& usbd) : usb(usbd) {
usb.register_driver(this);
}
protected:
virtual SetupStatus handle_setup(uint8_t bmRequestType, uint8_t bRequest, uint16_t wValue, uint16_t wIndex, uint16_t wLength) {
if(bmRequestType == 0xc0 && bRequest == 0xff) {
return jtag_shift(wValue, wIndex, wLength) ? SetupStatus::Ok : SetupStatus::Stall;
}
return SetupStatus::Unhandled;
}
};
USB_JTAG usb_jtag(usb);
class USB_TM : public USB_class_driver {
private:
USB_generic& usb;
uint32_t buf[16];
public:
USB_TM(USB_generic& usbd) : usb(usbd) {
usb.register_driver(this);
}
protected:
virtual void handle_set_configuration(uint8_t configuration) {
if(configuration) {
usb.hw_conf_ep(0x01, EPType::Bulk, 64);
usb.hw_conf_ep(0x81, EPType::Bulk, 64);
usb.hw_conf_ep(0x82, EPType::Isochronous, 64);
usb.register_out_handler(this, 1);
}
}
virtual void handle_out(uint8_t ep, uint32_t len) {
if(ep == 1 && len) {
usb.read(ep, buf, len);
if(len == 2) {
uint8_t* bufp = (uint8_t*)buf;
switch(bufp[0]) {
case 2:
g_throttle = float(bufp[1]) / 128.0f * 0.7;
break;
case 3:
pid_x.Kp = float(bufp[1]) / 128.0f * 0.4;
pid_y.Kp = float(bufp[1]) / 128.0f * 0.4;
break;
case 4:
pid_x.Ki = float(bufp[1]) / 128.0f * 0.4;
pid_y.Ki = float(bufp[1]) / 128.0f * 0.4;
break;
case 5:
pid_x.Kd = float(bufp[1]) / 128.0f * 0.4;
pid_y.Kd = float(bufp[1]) / 128.0f * 0.4;
break;
case 6:
pid_z.Kp = float(bufp[1]) / 128.0f * 0.4;
break;
case 7:
pid_z.Kp = float(bufp[1]) / 128.0f * 0.4;
break;
case 8:
pid_z.Kp = float(bufp[1]) / 128.0f * 0.4;
break;
case 23:
if(bufp[1]) {
gyro_calib = 256;
gyro_calib_x = 0;
gyro_calib_y = 0;
gyro_calib_z = 0;
}
break;
}
}
}
}
};
USB_TM usb_tm(usb);
template<>
void interrupt<(Interrupt::IRQ)77>() {
usb.process();
}
void usb_main() {
usb_vbus.set_mode(Pin::Input);
usb_dm.set_mode(Pin::AF);
usb_dm.set_pull(Pin::PullNone);
usb_dm.set_af(12);
usb_dp.set_mode(Pin::AF);
usb_dp.set_pull(Pin::PullNone);
usb_dp.set_af(12);
RCC.enable(RCC.OTGHS);
//Interrupt::enable((Interrupt::IRQ)77);
usb.init();
while(1) {
usb.process();
Thread::yield();
}
}
uint32_t usb_stack[1024];
Thread usb_thread(usb_stack, sizeof(usb_stack), usb_main);
L3GD20 gyro(cs_gyro, SPI1);
LSM303DLM_A accel(I2C2);
LSM303DLM_M magn(I2C2);
PPMSum ppmsum;
int main() {
// Initialize system timer.
STK.LOAD = 168000000 / 8 / 1000; // 1000 Hz.
STK.CTRL = 0x03;
RCC.enable(RCC.GPIOA);
RCC.enable(RCC.GPIOB);
RCC.enable(RCC.GPIOC);
RCC.enable(RCC.GPIOD);
led_status.set_mode(Pin::Output);
led_status.off();
led_error.set_mode(Pin::Output);
led_error.off();
jtag_tdi.set_mode(Pin::Output);
jtag_tms.set_mode(Pin::Output);
jtag_tck.set_mode(Pin::Output);
jtag_tdo.set_mode(Pin::Input);
RCC.enable(RCC.I2C2);
I2C2.enable(i2c_scl, i2c_sda);
usb_thread.start();
RCC.enable(RCC.SPI1);
PA5.set_mode(Pin::AF);
PA5.set_af(5);
PA6.set_mode(Pin::AF);
PA6.set_af(5);
PA7.set_mode(Pin::AF);
PA7.set_af(5);
cs_gyro.on();
cs_gyro.set_mode(Pin::Output);
cs_pressure.on();
cs_pressure.set_mode(Pin::Output);
SPI1.reg.CR1 = (1 << 9) | (1 << 8) | (1 << 6) | (3 << 3) | (1 << 2) | (1 << 1) | (1 << 0); // SSM, SSI, SPE, 84/16MHz, MSTR, CPOL, CPHA
Time::sleep(1000);
gyro.init();
accel.init();
magn.init();
PA0.set_mode(Pin::AF);
PA0.set_af(1);
ppmsum.enable();
for(Pin& p : pwm_outputs) {
p.set_af(3);
p.set_mode(Pin::AF);
}
RCC.enable(RCC.TIM8);
TIM8.PSC = 168 - 1;
TIM8.ARR = 2500;
TIM8.CCER = 0x1111;
TIM8.CCMR1 = 0x6868;
TIM8.CCMR2 = 0x6868;
TIM8.BDTR = (1 << 15);
TIM8.CCR1 = 1000;
TIM8.CCR2 = 1000;
TIM8.CCR3 = 1000;
TIM8.CCR4 = 1000;
TIM8.CR1 = 0x05;
float abst = 0;
while(1) {
led_error.toggle();
// Wait for new period.
while(!(TIM8.SR & 1)) {
Thread::yield();
}
TIM8.SR = 0;
float throttle = g_throttle;
gyro.update();
//accel.update();
//magn.update();
if(gyro_calib) {
gyro_calib--;
gyro_calib_x += gyro.x / 256;
gyro_calib_y += gyro.y / 256;
gyro_calib_z += gyro.z / 256;
}
gyro.x -= gyro_calib_x;
gyro.y -= gyro_calib_y;
gyro.z -= gyro_calib_z;
float stab_x = pid_x.update(-gyro.x);
float stab_y = pid_y.update(-gyro.y);
float stab_z = pid_z.update(-gyro.z);
if(throttle < 0.05) {
stab_x = 0;
stab_y = 0;
stab_z = 0;
pid_x.reset();
pid_y.reset();
pid_z.reset();
}
float motors[] = {
throttle - stab_x - stab_y + stab_z,
throttle - stab_x + stab_y - stab_z,
throttle + stab_x + stab_y + stab_z,
throttle + stab_x - stab_y - stab_z
};
TIM8.CCR1 = 1000 + motors[0] * 1000;
TIM8.CCR2 = 1000 + motors[1] * 1000;
TIM8.CCR3 = 1000 + motors[2] * 1000;
TIM8.CCR4 = 1000 + motors[3] * 1000;
float buf[] = {
abst,
gyro.x,
gyro.y,
gyro.z,
stab_x,
stab_y,
stab_z,
throttle,
0,
};
if(usb.ep_ready(2)) {
usb.write(2, (uint32_t*)buf, sizeof(buf));
} else {
usb_rblog.log("Busy.");
}
abst += 1.0 / 400.0;
}
}
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