int libx52_set_led_state(libx52_device *x52, libx52_led_id led, libx52_led_state state)
{
if (!x52) {
return -EINVAL;
}
switch (led) {
case LIBX52_LED_FIRE:
case LIBX52_LED_THROTTLE:
if (state == LIBX52_LED_STATE_OFF) {
clr_bit(&x52->led_mask, led);
set_bit(&x52->update_mask, led);
} else if (state == LIBX52_LED_STATE_ON) {
set_bit(&x52->led_mask, led);
set_bit(&x52->update_mask, led);
} else {
/* Colors not supported */
return -ENOTSUP;
}
break;
default:
/* All other LEDs support OFF, RED, AMBER and GREEN states
* However, they are composed of individual RED and GREEN LEDs which
* must be turned on or off individually.
*/
switch (state) {
case LIBX52_LED_STATE_OFF:
clr_bit(&x52->led_mask, led + 0); // Red
clr_bit(&x52->led_mask, led + 1); // Green
break;
case LIBX52_LED_STATE_RED:
set_bit(&x52->led_mask, led + 0); // Red
clr_bit(&x52->led_mask, led + 1); // Green
break;
case LIBX52_LED_STATE_AMBER:
set_bit(&x52->led_mask, led + 0); // Red
set_bit(&x52->led_mask, led + 1); // Green
break;
case LIBX52_LED_STATE_GREEN:
clr_bit(&x52->led_mask, led + 0); // Red
set_bit(&x52->led_mask, led + 1); // Green
break;
default:
/* Cannot set the LED to "ON" */
return -ENOTSUP;
}
/* Set the update mask bits */
set_bit(&x52->update_mask, led + 0); // Red
set_bit(&x52->update_mask, led + 1); // Green
break;
}
return 0;
}
void go_forward(void)
{
int16 obstaculo = 0;
#ifdef sensorir
obstaculo = verificaObstaculo();
if (obstaculo == 0) {
#endif
TIMER0_CLOCK_PRESCALER_64(); //frequencia de oscilacao de 1KHz
TIMER0_COMPARE_A_CONFIGURE(255); //duty cycle 100%
TIMER0_COMPARE_B_CONFIGURE(245); //duty cycle 100%
clr_bit(MOTOR_SHIELD_DDR, MOTOR_INA); //seta a direcao como entrada INA
clr_bit(MOTOR_SHIELD_DDR, MOTOR_INB); //seta a direcao como entrada INB
set_bit(MOTOR_SHIELD_PORT, MOTOR_INA); //set_bit : sentido horario, clr_bit: sentido anti-horario
set_bit(MOTOR_SHIELD_PORT, MOTOR_INB);
#ifdef DEBUG
printf("driving forward...\n");
#endif
#ifdef sensorir
} else if (obstaculo == 1) {
go_idle();
obstaculo = 0;
#ifdef DEBUG
printf("obstacle, going idle to not crash...\n");
#endif
}
#endif
}
int main() {
spi_init_slave();
//Ativa os dois sensores
clr_bit(DDRD, SENSOR1);
clr_bit(DDRD, SENSOR2);
EICRA = (1 << ISC01) |(1 << ISC11); //interrupcoes no INT0 na borda de descida
EIMSK = (1 << INT0); //habilita a interrupcao INT0
TIMSK1 |= 1<<OCIE1A;
TCCR1B |= (1 << WGM12) | (1 << CS12) | (1 << CS10);
/*cada um segundo 7812
* 1000ms 7812
* 1 ms x = 8
*/
OCR1A= 8;
#if DEBUG
uart_init();
uart_sendSTR("Iniciou agente RPM\n");
#endif
sei();
while (1);
}
void BACKWARD()
{
STOP();
set_bit(PORTC, IN1);
clr_bit(PORTC, IN2);
set_bit(PORTC, IN3);
clr_bit(PORTC, IN4);
}
void init_IO() {
clr_bit(DDRC,PC0);
clr_bit(PORTC,PC0);
clr_bit(DDRC,PC1);
clr_bit(PORTC,PC1);
spi_init_slave();
adc_init();
}
void go_back(void)
{
TIMER0_CLOCK_PRESCALER_64(); //frequencia de oscilacao de 1KHz
TIMER0_COMPARE_A_CONFIGURE(255); //duty cycle 100%
TIMER0_COMPARE_B_CONFIGURE(255); //duty cycle 100%
set_bit(MOTOR_SHIELD_DDR, MOTOR_INA);
set_bit(MOTOR_SHIELD_DDR, MOTOR_INB);
clr_bit(MOTOR_SHIELD_PORT, MOTOR_INA); //inversao de sentido nas duas rodas
clr_bit(MOTOR_SHIELD_PORT, MOTOR_INB);
#ifdef DEBUG
printf("driving back...\n");
#endif
}
int main() {
bs_ptr bsptr;
if (!(bsptr = bs_alloc(75))) {
printf("Failed to create bitvector\n");
}
printf("Setting bits 0, 10, 21, 33, 50, 74\n");
set_bit(bsptr, 0);
set_bit(bsptr, 10);
set_bit(bsptr, 21);
set_bit(bsptr, 33);
set_bit(bsptr, 50);
set_bit(bsptr, 74);
printf("Checking Values of bits 0, 10, 21, 33, 50, 74\n");
printf("Value of bit 0: %d\n", get_bit(bsptr, 0));
printf("Value of bit 10: %d\n", get_bit(bsptr, 10));
printf("Value of bit 21: %d\n", get_bit(bsptr, 21));
printf("Value of bit 33: %d\n", get_bit(bsptr, 33));
printf("Value of bit 50: %d\n", get_bit(bsptr, 50));
printf("Value of bit 74: %d\n", get_bit(bsptr, 74));
printf("Checking Values of bits 1, 11, 22, 34, 51, 73\n");
printf("Value of bit 1: %d\n", get_bit(bsptr, 1));
printf("Value of bit 11: %d\n", get_bit(bsptr, 11));
printf("Value of bit 22: %d\n", get_bit(bsptr, 22));
printf("Value of bit 34: %d\n", get_bit(bsptr, 34));
printf("Value of bit 51: %d\n", get_bit(bsptr, 51));
printf("Value of bit 73: %d\n", get_bit(bsptr, 73));
printf("Clearing bits 0, 21, 50\n");
clr_bit(bsptr, 0);
clr_bit(bsptr, 21);
clr_bit(bsptr, 50);
printf("Checking Values of bits 0, 10, 21, 33, 50, 74\n");
printf("Value of bit 0: %d\n", get_bit(bsptr, 0));
printf("Value of bit 10: %d\n", get_bit(bsptr, 10));
printf("Value of bit 21: %d\n", get_bit(bsptr, 21));
printf("Value of bit 33: %d\n", get_bit(bsptr, 33));
printf("Value of bit 50: %d\n", get_bit(bsptr, 50));
printf("Value of bit 74: %d\n", get_bit(bsptr, 74));
}
void turn_right(void)
{
TIMER0_CLOCK_PRESCALER_64(); //frequencia de oscilacao de 1KHz
TIMER0_COMPARE_A_CONFIGURE(255); //duty cycle 100%
TIMER0_COMPARE_B_CONFIGURE(0); //duty cycle 25% //volta mais rapida //era 25% = 64 ou 0 para ficar parado //teste com 255, era 0 21/julho
clr_bit(MOTOR_SHIELD_DDR, MOTOR_INA);
clr_bit(MOTOR_SHIELD_DDR, MOTOR_INB);
set_bit(MOTOR_SHIELD_PORT, MOTOR_INA); //roda de esquerda em sentido horario
clr_bit(MOTOR_SHIELD_PORT, MOTOR_INB); //roda da direita no sentido anti-horario
#ifdef DEBUG
printf("turning right...\n");
#endif
}
void turn_left(void)
{
TIMER0_CLOCK_PRESCALER_64(); //frequencia de oscilacao de 1KHz
TIMER0_COMPARE_A_CONFIGURE(0); //duty cycle 25% //era 25% = 64 ou 0 para parar totalmente o motor //teste com 255, era 0 21/julho
TIMER0_COMPARE_B_CONFIGURE(255); //duty cycle 100%
clr_bit(MOTOR_SHIELD_DDR, MOTOR_INA);
clr_bit(MOTOR_SHIELD_DDR, MOTOR_INB);
clr_bit(MOTOR_SHIELD_PORT, MOTOR_INA); //roda de esquerda em sentido anti-horario
set_bit(MOTOR_SHIELD_PORT, MOTOR_INB); //roda da direita no sentido horario
#ifdef DEBUG
printf("turning left...\n");
#endif
}
PUBLIC uint8_t i2c0_burst_read(uint8_t slaveAddr, uint8_t memAddr, uint16_t byteCount, uint8_t* data)
{
i2c_start();
i2cWriteByte(clr_bit(slaveAddr,0));
}
BOOL CNameHttpCMD::OnExecuted()
{
if (FALSE == m_bError)
{
return FALSE;
}
Json::Value root;
Json::Reader reader;
if( !reader.parse( m_strResult, root ) )
{
SYS_CRITICAL( _SDT( "json parse error, result:%s" ), m_strResult.c_str() );
return FALSE;
}
//检测数据个数,如果为零刚为出错,防止崩溃
if (!root.isObject())
{
SYS_CRITICAL( _SDT( "json size error, result:%s" ), m_strResult.c_str() );
return FALSE;
}
//解析返回的状态码
INT32 nErrCode = 0;
if (!root["errcode"].isInt())
{
SYS_CRITICAL( _SDT( "json size error, result:%s" ), m_strResult.c_str() );
return FALSE;
}
nErrCode = root["errcode"].asInt();
if (0 != nErrCode)
{
SYS_CRITICAL( _SDT( "json size error, result:%s" ), m_strResult.c_str() );
return FALSE;
}
CPlayer *poPlayer = CPlayerMgr::Instance()->FindPlayer(stNameInfo.dwPlayerID);
if(NULL == poPlayer)
{
SYS_CRITICAL(_SDT("[%s: %d]: player[playerid = %u] try to reg dispname[%s] fail!"), MSG_MARK, stNameInfo.dwPlayerID, stNameInfo.strName.c_str());
return FALSE;
}
// 检测玩家是否是因为合区导致的昵称冲突而重新注册的,是的话要记录日志
BOOL bNeedReRegDspName = (get_bit(poPlayer->GetExtData(), em_EDIT_NAME));
if(bNeedReRegDspName)
{
//修改标志位
clr_bit(poPlayer->GetExtData(), em_EDIT_NAME);
CHAR szComment[256] = {0};
SDSnprintf(szComment, sizeof(szComment) - 1, "[%s] - [%s]", stNameInfo.strOldName.c_str(), stNameInfo.strName.c_str());
CRecordMgr::Instance()->RecordInfo(stNameInfo.dwPlayerID, ERM_PLAYER_OPERATE, CRecordMgr::EPO_RE_REG_NICK_NAME, 1, 1,
poPlayer->GetLevel(), poPlayer->GetDT_PLAYER_BASE_DATA().byVipLevel, 0, 0, 0, 0, szComment);
}
return TRUE;
}
static void rt_isr_event_entry(void* parameter)
{
rt_err_t err;
rt_uint32_t e;
printf_syn("rt_isr_event_entry()\n");
say_thread_start();
while (1) {
err = rt_event_recv(&isr_event_set
, EVENT_BIT_NEED_RUN_TIM2_IRQ | EVENT_BIT_NEED_RUN_TIM4_IRQ | EVENT_BIT_NEED_RUN_SI4432_MAC_EXTI_IRQ
, RT_EVENT_FLAG_OR | RT_EVENT_FLAG_CLEAR, RT_WAITING_FOREVER, &e);
if (RT_EOK != err) {
printf_syn("recv isr event error(%d)", err);
} else {
#if RT_USING_SI4432_MAC
if (is_bit_set(isr_event_var_flag, EVENT_BIT_NEED_RUN_SI4432_MAC_EXTI_IRQ)) {
clr_bit(isr_event_var_flag, EVENT_BIT_NEED_RUN_SI4432_MAC_EXTI_IRQ);
si4432_mac_exti_isr();
}
#endif
#if RT_USING_ADE7880
if (is_bit_set(isr_event_var_flag, EVENT_BIT_NEED_RUN_TIM4_IRQ)) {
clr_bit(isr_event_var_flag, EVENT_BIT_NEED_RUN_TIM4_IRQ);
#if 0 == ADE7880_USE_I2C_HSDC
tim4_isr();
#endif
}
#endif
#if RT_USING_SI4432_MAC
if (is_bit_set(isr_event_var_flag, EVENT_BIT_NEED_RUN_SI4432_MAC_EXTI_IRQ)) {
clr_bit(isr_event_var_flag, EVENT_BIT_NEED_RUN_SI4432_MAC_EXTI_IRQ);
si4432_mac_exti_isr();
}
if (is_bit_set(isr_event_var_flag, EVENT_BIT_NEED_RUN_TIM2_IRQ)) {
clr_bit(isr_event_var_flag, EVENT_BIT_NEED_RUN_TIM2_IRQ);
tim2_isr();
}
#endif
}
}
return;
}
void light_func(uint8_t new_light) //latches Federal Signal circuit
{ //toggles based on state
static uint8_t old_light;
if((new_light == 0) && (old_light !=0)){set_bit(PORTD, old_light); old_light = 0;} //turn light off
else{
if(old_light != new_light){set_bit(PORTD, old_light); clr_bit(PORTD, new_light); old_light = new_light;} //record which light is on
}
}
/* ------------------------------------------------------------------------- */
void nrf24_setupPins()
{
set_bit(RF_DDR,CE); // CE output
set_bit(RF_DDR,CSN); // CSN output
set_bit(RF_DDR,SCK); // SCK output
set_bit(RF_DDR,MOSI); // MOSI output
clr_bit(RF_DDR,MISO); // MISO input
}
/* ------------------------------------------------------------------------- */
void nrf24_setupPins()
{
set_bit(DDRC,4); // CE output
set_bit(DDRC,3); // CSN output
set_bit(DDRC,2); // SCK output
set_bit(DDRC,1); // MOSI output
clr_bit(DDRC,0); // MISO input
}
void GPIO_pin_outputBit(regPin *pin, uint8 flag)
{
if(flag)
{
set_bit(*pin->out, pin->pin);
}
else
{
clr_bit(*pin->out, pin->pin);
}
}
void GPIO_outputBit(volatile uint8 *port, uint8 pino, uint8 UI8_flag)
{
if(UI8_flag)
{
set_bit(*port, pino);
}
else
{
clr_bit(*port, pino);
}
}
/* ------------------------------------------------------------------------- */
void nrf24_csn_digitalWrite(uint8_t state)
{
if(state)
{
set_bit(PORTB,0);
}
else
{
clr_bit(PORTB,0);
}
}
/* ------------------------------------------------------------------------- */
void nrf24_ce_digitalWrite(uint8_t state)
{
if(state)
{
set_bit(PORTD,7);
}
else
{
clr_bit(PORTD,7);
}
}
/* ------------------------------------------------------------------------- */
void nrf24_csn_digitalWrite(uint8_t state)
{
if(state)
{
set_bit(RF_PORT,CSN);
}
else
{
clr_bit(RF_PORT,CSN);
}
}
/* ------------------------------------------------------------------------- */
void nrf24_sck_digitalWrite(uint8_t state)
{
if(state)
{
set_bit(RF_PORT, SCK);
}
else
{
clr_bit(RF_PORT,SCK);
}
}
/* ------------------------------------------------------------------------- */
void nrf24_mosi_digitalWrite(uint8_t state)
{
if(state)
{
set_bit(RF_PORT,MOSI);
}
else
{
clr_bit(RF_PORT,MOSI);
}
}
/* ------------------------------------------------------------------------- */
void nrf24_sck_digitalWrite(uint8_t state)
{
if(state)
{
set_bit(PORTC,2);
}
else
{
clr_bit(PORTC,2);
}
}
/* ------------------------------------------------------------------------- */
void nrf24_mosi_digitalWrite(uint8_t state)
{
if(state)
{
set_bit(PORTC,1);
}
else
{
clr_bit(PORTC,1);
}
}
void GPIO_confDir(regGPIO *pin, PIN_DIR IODirection)
{
if(IODirection)
{
//input
set_bit(*pin->tris, pin->numPin);
}
else
{
//output
clr_bit(*pin->tris, pin->numPin);
}
}
int bdealloc(int devId, int bno) {
int i;
char buf[BLKSIZE];
// read block_bitmap block
get_block(devId, getBMap(devId), buf);
clr_bit(buf, bno - 1); //Account for indexing starting at 1
updateFreeBlocks(devId, 1);
put_block(devId, getBMap(devId), buf);
return 0;
}
int idealloc(int devId, int ino) {
int i;
char buf[BLKSIZE];
// read inode_bitmap block
get_block(devId, getIMap(devId), buf);
clr_bit(buf,ino - 1);
updateFreeInodes(devId, 1);
put_block(devId, getIMap(devId), buf);
return 0;
}
int libx52_set_blink(libx52_device *x52, uint8_t state)
{
if (!x52) {
return -EINVAL;
}
if (state) {
set_bit(&x52->led_mask, X52_BIT_POV_BLINK);
} else {
clr_bit(&x52->led_mask, X52_BIT_POV_BLINK);
}
set_bit(&x52->update_mask, X52_BIT_POV_BLINK);
return 0;
}
int libx52_set_shift(libx52_device *x52, uint8_t state)
{
if (!x52) {
return -EINVAL;
}
if (state) {
set_bit(&x52->led_mask, X52_BIT_SHIFT);
} else {
clr_bit(&x52->led_mask, X52_BIT_SHIFT);
}
set_bit(&x52->update_mask, X52_BIT_SHIFT);
return 0;
}
/**
* The UART 3 receive complete interrupt handler.
* For efficiency, implement it in here instead of the default
* generic handlers in uart.c to avoid losing time.
*/
ISR(USART3_RX_vect, ISR_BLOCK) {
/* Display UART status on PORTH.
* PH3: data overrun*/
PORTH |= UCSR3A;
if (rb_free_slots() < CTS_HIGH) {
set_bit(PORTJ, CTS);
}
_rb_put(UDR3);
if (_processing) {
return;
}
_processing = true;
/* Critical section done, reenable other interrupts.
* If more speed is needed think about moving this further up still. */
sei();
uint8_t byte;
uint8_t size;
/* Disable interrupts while accessing ring buffer. */
cli();
while ((size = _rb_data_slots()) != 0) {
_rb_get(&byte);
sei();
/* Putting the CTS code outside the critical section *should*
* be ok since only one "thread" is in this section at a time and
* if the flow control is set to off, we shouldn't be getting any
* new data. If any bugs pop up though, let's keep this in mind. */
if (size == CTS_LOW) {
clr_bit(PORTJ, CTS);
}
_recv_callback(byte);
}
/* Disable interrupts while setting _processing flag.
* Don't call sei() because that happens automatically when
* returning from this. */
cli();
_processing = false;
}
