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EV-COG-AD3029LZ
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stm-spirit1-rf-driver
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SimpleSpirit1.cpp
- Committer:
- Wolfgang Betz
- Date:
- 2016-11-15
- Revision:
- 27:e68ffb6ac223
- Parent:
- 26:45dae8d48029
- Child:
- 28:6a71e15d5272
File content as of revision 27:e68ffb6ac223:
/*** Mbed Includes ***/
#include "SimpleSpirit1.h"
#include "radio_spi.h"
#define SPIRIT_GPIO_IRQ (SPIRIT_GPIO_3)
static uint16_t last_state;
#define SPIRIT1_STATUS() (last_state = (((uint16_t)refresh_state()) & SPIRIT1_STATE_STATEBITS))
#define BUSYWAIT_UNTIL(cond, millisecs) \
do { \
uint32_t start = us_ticker_read(); \
while (!(cond) && ((us_ticker_read() - start) < ((uint32_t)millisecs)*1000U)); \
} while(0)
extern volatile SpiritStatus g_xStatus;
#define st_lib_g_x_status (g_xStatus)
#define st_lib_spirit_irqs SpiritIrqs
#define STATE_TIMEOUT (1000)
/*** Class Implementation ***/
/** Static Class Variables **/
SimpleSpirit1 *SimpleSpirit1::_singleton = NULL;
/** Constructor **/
SimpleSpirit1::SimpleSpirit1(PinName mosi, PinName miso, PinName sclk,
PinName irq, PinName cs, PinName sdn,
PinName led) :
_spi(mosi, miso, sclk),
_irq(irq),
_chip_select(cs),
_shut_down(sdn),
_led(led),
_current_irq_callback(),
_rx_receiving_timeout()
{
}
/** Init Function **/
void SimpleSpirit1::init() {
/* reset irq disable counter and irq callback & disable irq */
_nr_of_irq_disables = 0;
disable_spirit_irq();
/* unselect chip */
chip_unselect();
/* configure spi */
_spi.format(8, 0); /* 8-bit, mode = 0, [order = SPI_MSB] only available in mbed3 */
_spi.frequency(1000000); // 1MHz // betzw - NOTE: higher frequencies lead to instability of Spirit1
/* install irq handler */
_irq.mode(PullUp);
_irq.fall(Callback<void()>(this, &SimpleSpirit1::IrqHandler));
/* init cube vars */
spirit_on = OFF;
last_rssi = 0 ; //MGR
last_lqi = 0 ; //MGR
/* set frequencies */
radio_set_xtal_freq(XTAL_FREQUENCY);
mgmt_set_freq_base((uint32_t)BASE_FREQUENCY);
/* restart board */
enter_shutdown();
exit_shutdown();
/* soft core reset */
cmd_strobe(SPIRIT1_STROBE_SRES);
/* Configures the SPIRIT1 radio part */
SRadioInit x_radio_init = {
XTAL_OFFSET_PPM,
(uint32_t)BASE_FREQUENCY,
(uint32_t)CHANNEL_SPACE,
CHANNEL_NUMBER,
MODULATION_SELECT,
DATARATE,
(uint32_t)FREQ_DEVIATION,
(uint32_t)BANDWIDTH
};
radio_init(&x_radio_init);
radio_set_pa_level_dbm(0,POWER_DBM);
radio_set_pa_level_max_index(0);
/* Configures the SPIRIT1 packet handler part*/
PktBasicInit x_basic_init = {
PREAMBLE_LENGTH,
SYNC_LENGTH,
SYNC_WORD,
LENGTH_TYPE,
LENGTH_WIDTH,
CRC_MODE,
CONTROL_LENGTH,
EN_ADDRESS,
EN_FEC,
EN_WHITENING
};
pkt_basic_init(&x_basic_init);
/* Enable the following interrupt sources, routed to GPIO */
irq_de_init(NULL);
irq_clear_status();
irq_set_status(TX_DATA_SENT, S_ENABLE);
irq_set_status(RX_DATA_READY,S_ENABLE);
irq_set_status(RX_DATA_DISC, S_ENABLE);
irq_set_status(TX_FIFO_ERROR, S_ENABLE);
irq_set_status(RX_FIFO_ERROR, S_ENABLE);
irq_set_status(RX_FIFO_ALMOST_FULL, S_ENABLE);
irq_set_status(VALID_SYNC, S_ENABLE);
irq_set_status(MAX_BO_CCA_REACH, S_ENABLE);
/* Configure Spirit1 */
radio_persisten_rx(S_ENABLE);
qi_set_sqi_threshold(SQI_TH_0);
qi_sqi_check(S_ENABLE);
qi_set_rssi_threshold_dbm(CCA_THRESHOLD);
timer_set_rx_timeout_stop_condition(SQI_ABOVE_THRESHOLD);
timer_set_infinite_rx_timeout();
radio_afc_freeze_on_sync(S_ENABLE);
calibration_rco(S_ENABLE);
spirit_on = OFF;
CLEAR_TXBUF();
CLEAR_RXBUF();
_spirit_tx_started = false;
_spirit_rx_err = false;
_is_receiving = false;
/* Configure the radio to route the IRQ signal to its GPIO 3 */
SGpioInit x_gpio_init = {
SPIRIT_GPIO_IRQ,
SPIRIT_GPIO_MODE_DIGITAL_OUTPUT_LP,
SPIRIT_GPIO_DIG_OUT_IRQ
};
spirit_gpio_init(&x_gpio_init);
/* Setup CSMA/CA */
CsmaInit x_csma_init = {
S_DISABLE, // no persistent mode
TBIT_TIME_64, // Tcca time
TCCA_TIME_3, // Lcca length
3, // max nr of backoffs (<8)
1, // BU counter seed
8 // BU prescaler
};
csma_ca_init(&x_csma_init);
#ifdef RX_FIFO_THR_WA
linear_fifo_set_almost_full_thr_rx(SPIRIT_MAX_FIFO_LEN-(MAX_PACKET_LEN+1));
#endif
/* Puts the SPIRIT1 in STANDBY mode (125us -> rx/tx) */
cmd_strobe(SPIRIT1_STROBE_STANDBY);
}
int SimpleSpirit1::send(const void *payload, unsigned int payload_len) {
/* Checks if the payload length is supported */
if(payload_len > MAX_PACKET_LEN) {
return RADIO_TX_ERR;
}
#ifndef NDEBUG
if(SPIRIT1_STATUS() != SPIRIT1_STATE_RX) {
debug("\n\rAssert failed in: %s (%d): state=%x\n\r", __func__, __LINE__, last_state>>1);
}
#endif
disable_spirit_irq();
/* Reset State to Ready */
set_ready_state();
cmd_strobe(SPIRIT1_STROBE_FTX); // flush TX FIFO buffer
#ifndef NDEBUG
debug_if(!(linear_fifo_read_num_elements_tx_fifo() == 0), "\n\rAssert failed in: %s (%d)\n\r", __func__, __LINE__);
#endif
pkt_basic_set_payload_length(payload_len); // set desired payload len
#ifdef RX_FIFO_THR_WA
// betzw - TODO: seems to be incompatible with TX FIFO usage (to be investigated)
csma_ca_state(S_ENABLE); // enable CSMA/CA
#endif
cmd_strobe(SPIRIT1_STROBE_TX);
int i = 0;
int remaining = payload_len;
const uint8_t *buffer = (const uint8_t*)payload;
do {
uint8_t fifo_available = SPIRIT_MAX_FIFO_LEN - linear_fifo_read_num_elements_tx_fifo();
uint8_t to_send = (remaining > fifo_available) ? fifo_available : remaining;
/* Fill FIFO Buffer */
if(to_send > 0) {
spi_write_linear_fifo(to_send, (uint8_t*)&buffer[i]);
}
i += to_send;
remaining -= to_send;
} while(remaining != 0);
_spirit_tx_started = true;
enable_spirit_irq();
BUSYWAIT_UNTIL(SPIRIT1_STATUS() == SPIRIT1_STATE_RX, STATE_TIMEOUT);
#ifndef NDEBUG
if(last_state != SPIRIT1_STATE_RX) {
debug("\n\rAssert failed in: %s (%d): state=%x\n\r", __func__, __LINE__, last_state>>1);
}
#endif
return RADIO_TX_OK;
}
/** Set Ready State **/
void SimpleSpirit1::set_ready_state(void) {
uint16_t state;
disable_spirit_irq();
_is_receiving = false;
stop_rx_timeout();
state = SPIRIT1_STATUS();
if(state == SPIRIT1_STATE_STANDBY) {
cmd_strobe(SPIRIT1_STROBE_READY);
} else if(state == SPIRIT1_STATE_RX) {
cmd_strobe(SPIRIT1_STROBE_SABORT);
} else if(state != SPIRIT1_STATE_READY) {
#ifndef NDEBUG
debug("\n\rAssert failed in: %s (%d): state=%x\n\r", __func__, __LINE__, state>>1);
#endif
}
BUSYWAIT_UNTIL(SPIRIT1_STATUS() == SPIRIT1_STATE_READY, STATE_TIMEOUT);
if(last_state != SPIRIT1_STATE_READY) {
error("\n\rSpirit1: failed to become ready (%x) => pls. reset!\n\r", last_state>>1);
enable_spirit_irq();
return;
}
irq_clear_status();
enable_spirit_irq();
}
int SimpleSpirit1::off(void) {
if(spirit_on == ON) {
/* Disables the mcu to get IRQ from the SPIRIT1 */
disable_spirit_irq();
/* first stop rx/tx */
set_ready_state();
/* Puts the SPIRIT1 in STANDBY */
cmd_strobe(SPIRIT1_STROBE_STANDBY);
BUSYWAIT_UNTIL(SPIRIT1_STATUS() == SPIRIT1_STATE_STANDBY, STATE_TIMEOUT);
if(last_state != SPIRIT1_STATE_STANDBY) {
error("\n\rSpirit1: failed to enter standby (%x)\n\r", last_state>>1);
return 1;
}
spirit_on = OFF;
_nr_of_irq_disables = 1;
_spirit_tx_started = false;
_is_receiving = false;
stop_rx_timeout();
CLEAR_TXBUF();
CLEAR_RXBUF();
}
return 0;
}
int SimpleSpirit1::on(void) {
if(spirit_on == OFF) {
set_ready_state();
/* now we go to Rx */
cmd_strobe(SPIRIT1_STROBE_RX);
BUSYWAIT_UNTIL(SPIRIT1_STATUS() == SPIRIT1_STATE_RX, STATE_TIMEOUT);
if(last_state != SPIRIT1_STATE_RX) {
error("\n\rSpirit1: failed to enter rx (%x) => retry\n\r", last_state>>1);
}
cmd_strobe(SPIRIT1_STROBE_FRX);
CLEAR_RXBUF();
_spirit_rx_err = false;
_is_receiving = false;
stop_rx_timeout();
/* Enables the mcu to get IRQ from the SPIRIT1 */
spirit_on = ON;
#ifndef NDEBUG
debug_if(!(_nr_of_irq_disables == 1), "\n\rAssert failed in: %s (%d)\n\r", __func__, __LINE__);
#endif
enable_spirit_irq();
}
#ifndef NDEBUG
if(SPIRIT1_STATUS() != SPIRIT1_STATE_RX) {
debug("\n\rAssert failed in: %s (%d): state=%x\n\r", __func__, __LINE__, last_state>>1);
}
#endif
return 0;
}
uint8_t SimpleSpirit1::refresh_state(void) {
uint8_t mcstate;
SpiritSpiReadRegisters(MC_STATE0_BASE, 1, &mcstate);
return mcstate;
}
int SimpleSpirit1::read(void *buf, unsigned int bufsize)
{
disable_spirit_irq();
/* Checks if the RX buffer is empty */
if(IS_RXBUF_EMPTY()) {
CLEAR_RXBUF();
set_ready_state();
cmd_strobe(SPIRIT1_STROBE_FRX);
cmd_strobe(SPIRIT1_STROBE_RX);
BUSYWAIT_UNTIL(SPIRIT1_STATUS() == SPIRIT1_STATE_RX, STATE_TIMEOUT);
_spirit_rx_err = false;
_is_receiving = false;
stop_rx_timeout();
enable_spirit_irq();
return 0;
}
if(bufsize < spirit_rx_len) {
enable_spirit_irq();
/* If buf has the correct size */
#ifndef NDEBUG
debug("\n\rTOO SMALL BUF\n\r");
#endif
return 0;
} else {
/* Copies the packet received */
memcpy(buf, spirit_rx_buf, spirit_rx_len);
bufsize = spirit_rx_len;
_is_receiving = false;
stop_rx_timeout();
CLEAR_RXBUF();
enable_spirit_irq();
return bufsize;
}
}
int SimpleSpirit1::channel_clear(void)
{
float rssi_value;
/* Local variable used to memorize the SPIRIT1 state */
uint8_t spirit_state = ON;
if(spirit_on == OFF) {
/* Wakes up the SPIRIT1 */
on();
spirit_state = OFF;
}
#ifndef NDEBUG
if(SPIRIT1_STATUS() != SPIRIT1_STATE_RX) {
debug("\n\rAssert failed in: %s (%d): state=%x\n\r", __func__, __LINE__, last_state>>1);
}
#endif
disable_spirit_irq();
/* Reset State to Ready */
set_ready_state();
/* Stores the RSSI value */
rssi_value = qi_get_rssi_dbm();
enable_spirit_irq();
/* Puts the SPIRIT1 in its previous state */
if(spirit_state==OFF) {
off();
#ifndef NDEBUG
if(SPIRIT1_STATUS() != SPIRIT1_STATE_STANDBY) {
debug("\n\rAssert failed in: %s (%d): state=%x\n\r", __func__, __LINE__, last_state>>1);
}
#endif
} else {
disable_spirit_irq();
set_ready_state();
cmd_strobe(SPIRIT1_STROBE_RX);
BUSYWAIT_UNTIL(SPIRIT1_STATUS() == SPIRIT1_STATE_RX, STATE_TIMEOUT);
if(last_state != SPIRIT1_STATE_RX) {
error("\n\rSpirit1: (#2) failed to enter rx (%x) => retry\n\r", last_state>>1);
}
CLEAR_RXBUF();
_spirit_rx_err = false;
_is_receiving = false;
stop_rx_timeout();
enable_spirit_irq();
#ifndef NDEBUG
if(SPIRIT1_STATUS() != SPIRIT1_STATE_RX) {
debug("\n\rAssert failed in: %s (%d): state=%x\n\r", __func__, __LINE__, last_state>>1);
}
#endif
}
/* Checks the RSSI value with the threshold */
if(rssi_value<CCA_THRESHOLD) {
return 0;
} else {
return 1;
}
}
int SimpleSpirit1::get_pending_packet(void)
{
return !IS_RXBUF_EMPTY();
}
/** Spirit Irq Callback **/
void SimpleSpirit1::IrqHandler() {
st_lib_spirit_irqs x_irq_status;
/* get interrupt source from radio */
irq_get_status(&x_irq_status);
/* Reception errors */
if((x_irq_status.IRQ_RX_FIFO_ERROR) || (x_irq_status.IRQ_RX_DATA_DISC)) {
#ifndef NDEBUG
debug("\n\r%s (%d)", __func__, __LINE__);
#endif
_spirit_rx_err = true;
_is_receiving = false;
CLEAR_RXBUF();
cmd_strobe(SPIRIT1_STROBE_FRX);
stop_rx_timeout();
if(_spirit_tx_started) {
_spirit_tx_started = false;
CLEAR_TXBUF();
/* call user callback */
if(_current_irq_callback) {
_current_irq_callback(TX_ERR);
}
}
}
/* Transmission error */
if(x_irq_status.IRQ_TX_FIFO_ERROR) {
#ifndef NDEBUG
debug("\n\r%s (%d)", __func__, __LINE__);
#endif
csma_ca_state(S_DISABLE); // disable CSMA/CA
cmd_strobe(SPIRIT1_STROBE_FTX);
cmd_strobe(SPIRIT1_STROBE_RX);
if(_spirit_tx_started) {
_spirit_tx_started = false;
CLEAR_TXBUF();
/* call user callback */
if(_current_irq_callback) {
_current_irq_callback(TX_ERR);
}
}
}
/* The IRQ_VALID_SYNC is used to notify a new packet is coming */
if(x_irq_status.IRQ_VALID_SYNC) {
_is_receiving = true;
_spirit_rx_err = false;
CLEAR_RXBUF();
#ifndef NDEBUG
debug_if(_spirit_tx_started, "\n\rAssert failed in: %s (%d)\n\r", __func__, __LINE__);
#endif
start_rx_timeout();
}
/* The IRQ_TX_DATA_SENT notifies the packet received. Puts the SPIRIT1 in RX */
if(x_irq_status.IRQ_TX_DATA_SENT) {
#ifndef NDEBUG
debug_if(!_spirit_tx_started, "\n\rAssert failed in: %s (%d)\n\r", __func__, __LINE__);
#endif
csma_ca_state(S_DISABLE); // disable CSMA/CA
cmd_strobe(SPIRIT1_STROBE_FRX);
cmd_strobe(SPIRIT1_STROBE_RX);
CLEAR_TXBUF();
CLEAR_RXBUF();
_spirit_rx_err = false;
_spirit_tx_started = false;
/* call user callback */
if(_current_irq_callback) {
_current_irq_callback(TX_DONE);
}
}
/* RX FIFO almost full */
if(x_irq_status.IRQ_RX_FIFO_ALMOST_FULL) {
if(_spirit_rx_err) {
_is_receiving = false;
cmd_strobe(SPIRIT1_STROBE_FRX);
CLEAR_RXBUF();
stop_rx_timeout();
} else {
uint8_t fifo_available = linear_fifo_read_num_elements_rx_fifo();
unsigned int remaining = MAX_PACKET_LEN - _spirit_rx_pos;
if(fifo_available > remaining) {
_spirit_rx_err = true;
_is_receiving = false;
CLEAR_RXBUF();
cmd_strobe(SPIRIT1_STROBE_FRX);
stop_rx_timeout();
} else {
spi_read_linear_fifo(fifo_available, &spirit_rx_buf[_spirit_rx_pos]);
_spirit_rx_pos += fifo_available;
if(!_is_receiving) {
_is_receiving = true;
start_rx_timeout();
}
}
}
}
/* The IRQ_RX_DATA_READY notifies a new packet arrived */
if(x_irq_status.IRQ_RX_DATA_READY) {
_is_receiving = false; // Finished receiving
stop_rx_timeout();
if(_spirit_rx_err) {
_spirit_rx_err = false;
CLEAR_RXBUF();
cmd_strobe(SPIRIT1_STROBE_FRX);
} else {
spirit_rx_len = pkt_basic_get_received_pkt_length();
#ifndef NDEBUG
debug_if(!(spirit_rx_len <= MAX_PACKET_LEN), "\n\rAssert failed in: %s (%d)\n\r", __func__, __LINE__);
#endif
for(; _spirit_rx_pos < spirit_rx_len;) {
uint8_t to_receive = spirit_rx_len - _spirit_rx_pos;
if(to_receive > 0) {
spi_read_linear_fifo(to_receive, &spirit_rx_buf[_spirit_rx_pos]);
_spirit_rx_pos += to_receive;
}
}
cmd_strobe(SPIRIT1_STROBE_FRX);
last_rssi = qi_get_rssi(); //MGR
last_lqi = qi_get_lqi(); //MGR
/* call user callback */
if(_current_irq_callback) {
_current_irq_callback(RX_DONE);
}
}
}
/* Max number of back-off during CCA */
if(x_irq_status.IRQ_MAX_BO_CCA_REACH) {
#ifndef NDEBUG
debug("\n\r%s (%d)", __func__, __LINE__);
#endif
csma_ca_state(S_DISABLE); // disable CSMA/CA
cmd_strobe(SPIRIT1_STROBE_FRX);
cmd_strobe(SPIRIT1_STROBE_RX);
CLEAR_TXBUF();
CLEAR_RXBUF();
_spirit_rx_err = false;
_spirit_tx_started = false;
/* call user callback */
if(_current_irq_callback) {
_current_irq_callback(TX_ERR);
}
}
}