void radio_init(uint8_t * rxbuf, uint8_t rxbufsz)
{
trx_regval_t status;
/* init cpu peripherals and global IRQ enable */
radiostatus.rxframe = rxbuf;
radiostatus.rxframesz = rxbufsz;
//trx_set_irq_handler(radio_irq_handler);
/* transceiver initialization */
TRX_RESET_LOW();
TRX_SLPTR_LOW();
DELAY_US(TRX_RESET_TIME_US);
#if defined(CUSTOM_RESET_TIME_MS)
DELAY_MS(CUSTOM_RESET_TIME_MS);
#endif
TRX_RESET_HIGH();
/* disable IRQ and clear any pending IRQs */
trx_reg_write(RG_IRQ_MASK, 0);
trx_reg_read(RG_IRQ_STATUS);
trx_bit_write(SR_TRX_CMD, CMD_TRX_OFF);
DELAY_US(510);
status = trx_bit_read(SR_TRX_STATUS);
if (status != TRX_OFF)
{
radio_error(STATE_SET_FAILED);
}
trx_bit_write(SR_TX_AUTO_CRC_ON, 1);
trx_reg_write(RG_IRQ_MASK, TRX_IRQ_RX_START | TRX_IRQ_RX_END | TRX_IRQ_TX_END);
radiostatus.state = STATE_OFF;
radiostatus.idle_state = STATE_OFF;
}
void radio_set_param(radio_attribute_t attr, radio_param_t parm)
{
switch (attr)
{
case phyCurrentChannel:
if (((int)parm.channel >= TRX_MIN_CHANNEL) &&
((int)parm.channel <= TRX_MAX_CHANNEL))
{
#ifdef CHINABAND
trx_reg_write(RG_CC_CTRL_1, CCBAND);
trx_reg_write(RG_CC_CTRL_0, parm.channel*2+CCNUMBER);
#else
trx_bit_write(SR_CHANNEL, parm.channel);
#endif
radiostatus.channel = parm.channel;
}
else
{
radio_error(SET_PARM_FAILED);
}
break;
case phyTransmitPower:
#if RADIO_TYPE == RADIO_AT86RF212
#ifdef CHINABAND
if (parm.tx_pwr >= -11 && parm.tx_pwr <= 8)
{
/** @todo move this into a radio-specific header file */
static const uint8_t pwrtable[] =
{
0x0A, 0x09, 0x08, /* -11...-9 dBm */
0x07, 0x06, 0x05, /* -8...-6 dBm */
0x04, 0x03, 0x25, /* -5...-3 dBm */
0x46, 0xAC, 0xAB, /* -2...0 dBm */
0xAA, /* 1 dBm */
0xCA, /* 2 dBm */
0xEA, /* 3 dBm */
0xE9, /* 4 dBm */
0xE8, /* 5 dBm */
0xE6, /* 6 dBm */
0xE5, /* 7 dBm */
0xE4, /* 8 dBm */
};
radiostatus.tx_pwr = parm.tx_pwr;
uint8_t idx = parm.tx_pwr + 11;
uint8_t pwrval = pgm_read_byte(pwrtable[idx]);
trx_reg_write(RG_PHY_TX_PWR, pwrval);
}
else
{
radio_error(SET_PARM_FAILED);
}
#endif//chinaband
#else
if (parm.tx_pwr >= -17 && parm.tx_pwr <= 3)
{
/** @todo move this into a radio-specific header file */
static const uint8_t pwrtable[] =
{
0x0F, 0x0F, 0x0F, 0x0F, 0x0F, /* -17...-13 dBm */
0x0E, 0x0E, 0x0E, /* -12...-10 dBm */
0x0D, 0x0D, /* -9...-8 dBm */
0x0C, 0x0C, /* -7...-6 dBm */
0x0B, /* -5 dBm */
0x0A, /* -4 dBm */
0x09, /* -3 dBm */
0x08, /* -2 dBm */
0x07, /* -1 dBm */
0x06, /* 0 dBm */
0x04, /* 1 dBm */
0x02, /* 2 dBm */
0x00 /* 3 dBm */
};
radiostatus.tx_pwr = parm.tx_pwr;
uint8_t idx = parm.tx_pwr + 17;
uint8_t pwrval = pgm_read_byte(pwrtable[idx]);
trx_bit_write(SR_TX_PWR, pwrval);
}
else
{
radio_error(SET_PARM_FAILED);
}
#endif//rf212
break;
case phyCCAMode:
if (parm.cca_mode <= 3)
{
radiostatus.cca_mode = parm.cca_mode;
trx_bit_write(SR_CCA_MODE, radiostatus.cca_mode);
}
else
{
radio_error(SET_PARM_FAILED);
}
break;
case phyIdleState:
radiostatus.idle_state = parm.idle_state;
radio_set_state(parm.idle_state);
break;
case phyChannelsSupported:
break;
case phyPanId:
trx_set_panid(parm.pan_id);
break;
case phyShortAddr:
trx_set_shortaddr(parm.short_addr);
break;
case phyLongAddr:
{
uint8_t regno, *ap;
for (regno = RG_IEEE_ADDR_0, ap = (uint8_t *)parm.long_addr;
regno <= RG_IEEE_ADDR_7;
regno++, ap++)
trx_reg_write(regno, *ap);
break;
}
case phyDataRate:
trx_set_datarate(parm.data_rate);
break;
default:
radio_error(SET_PARM_FAILED);
break;
}
}
void radio_set_state(volatile radio_state_t state)
{
volatile trx_regval_t cmd, expstatus, currstatus;
uint8_t retries;
bool do_sleep = false;
switch(state)
{
case STATE_OFF:
expstatus = TRX_OFF;
cmd = CMD_TRX_OFF;
break;
case STATE_RX:
expstatus = RX_ON;
cmd = CMD_RX_ON;
break;
case STATE_TX:
expstatus = PLL_ON;
cmd = CMD_PLL_ON;
break;
case STATE_RXAUTO:
expstatus = RX_AACK_ON;
cmd = CMD_RX_AACK_ON;
break;
case STATE_TXAUTO:
expstatus = TX_ARET_ON;
cmd = CMD_TX_ARET_ON;
break;
case STATE_SLEEP:
expstatus = TRX_OFF;
cmd = CMD_FORCE_TRX_OFF;
do_sleep = true;
break;
default:
radio_error(GENERAL_ERROR);
expstatus = TRX_OFF;
cmd = CMD_TRX_OFF;
break;
}
if (STATE_SLEEP == radiostatus.state)
{
if (do_sleep)
{
return;
}
TRX_SLPTR_LOW();
/*
* Give the xosc some time to start up. Once it started, the
* SPI interface is operational, and the transceiver state can
* be polled. The state reads as 0b0011111 ("state transition
* in progress") while the transceiver is still in its startup
* phase, which does not match any of the "expstatus" values,
* so polling just continues.
*/
DELAY_US(500);
/*
* The exact wake-up timing is very board-dependent.
* Contributing parameters are the effective series resitance
* of the crystal, and the external bypass capacitor that has
* to be charged by the voltage regulator. Give the crystal
* oscillator some time to start up. 5 ms (100 * 50 us) ought
* to be enough under all circumstances.
*/
retries = 100;
do
{
currstatus = trx_bit_read(SR_TRX_STATUS);
/*
* Sleep could only be entered from TRX_OFF, so that's
* what is expected again.
*/
if (TRX_OFF == currstatus)
{
break;
}
DELAY_US(50);
}
while (--retries);
if (currstatus != TRX_OFF)
{
/* radio didn't wake up */
radio_error(STATE_SET_FAILED);
}
}
trx_bit_write(SR_TRX_CMD, cmd);
retries = 140; /* enough to await an ongoing frame
* reception */
do
{
currstatus = trx_bit_read(SR_TRX_STATUS);
if (expstatus == currstatus)
{
break;
}
/** @todo must wait longer for 790/868/900 MHz radios */
DELAY_US(32);
}
while (--retries);
if (expstatus != currstatus)
{
radio_error(STATE_SET_FAILED);
}
if (do_sleep)
{
TRX_SLPTR_HIGH();
}
radiostatus.state = state;
}
void radio_set_param(radio_attribute_t attr, radio_param_t parm)
{
switch (attr)
{
case phyCurrentChannel:
if (((int)parm.channel >= TRX_MIN_CHANNEL) &&
((int)parm.channel <= TRX_MAX_CHANNEL))
{
trx_bit_write(SR_CHANNEL, parm.channel);
radiostatus.channel = parm.channel;
}
else
{
radio_error(SET_PARM_FAILED);
}
break;
case phyTransmitPower:
if (parm.tx_pwr >= -17 && parm.tx_pwr <= 3)
{
/** @todo move this into a radio-specific header file */
static const uint8_t pwrtable[] =
{
0x0F, 0x0F, 0x0F, 0x0F, 0x0F, /* -17...-13 dBm */
0x0E, 0x0E, 0x0E, /* -12...-10 dBm */
0x0D, 0x0D, /* -9...-8 dBm */
0x0C, 0x0C, /* -7...-6 dBm */
0x0B, /* -5 dBm */
0x0A, /* -4 dBm */
0x09, /* -3 dBm */
0x08, /* -2 dBm */
0x07, /* -1 dBm */
0x06, /* 0 dBm */
0x04, /* 1 dBm */
0x02, /* 2 dBm */
0x00 /* 3 dBm */
};
radiostatus.tx_pwr = parm.tx_pwr;
uint8_t idx = parm.tx_pwr + 17;
uint8_t pwrval = pgm_read_byte(pwrtable[idx]);
trx_bit_write(SR_TX_PWR, pwrval);
}
else
{
radio_error(SET_PARM_FAILED);
}
break;
case phyCCAMode:
if (parm.cca_mode <= 3)
{
radiostatus.cca_mode = parm.cca_mode;
trx_bit_write(SR_CCA_MODE, radiostatus.cca_mode);
}
else
{
radio_error(SET_PARM_FAILED);
}
break;
case phyIdleState:
radiostatus.idle_state = parm.idle_state;
radio_set_state(parm.idle_state);
break;
case phyChannelsSupported:
break;
case phyPanId:
trx_set_panid(parm.pan_id);
break;
case phyShortAddr:
trx_set_shortaddr(parm.short_addr);
break;
case phyLongAddr:
{
uint8_t regno, *ap;
for (regno = RG_IEEE_ADDR_0, ap = (uint8_t *)parm.long_addr;
regno <= RG_IEEE_ADDR_7;
regno++, ap++)
trx_reg_write(regno, *ap);
break;
}
case phyDataRate:
trx_set_datarate(parm.data_rate);
break;
#ifdef TRX_TX_PA_EI
case phyTxPa:
radiostatus.tx_pa = parm.tx_pa;
break;
#endif
#ifdef TRX_RX_LNA_EI
case phyRxLna:
radiostatus.rx_lna = parm.rx_lna;
break;
#endif
default:
radio_error(SET_PARM_FAILED);
break;
}
}
void radio_set_state(radio_state_t state)
{
volatile trx_regval_t cmd, expstatus, currstatus;
uint8_t retries;
bool do_sleep = false;
switch(state)
{
case STATE_OFF:
expstatus = TRX_OFF;
cmd = CMD_TRX_OFF;
break;
case STATE_RX:
expstatus = RX_ON;
cmd = CMD_RX_ON;
break;
case STATE_TX:
expstatus = PLL_ON;
cmd = CMD_PLL_ON;
break;
case STATE_RXAUTO:
expstatus = RX_AACK_ON;
cmd = CMD_RX_AACK_ON;
break;
case STATE_TXAUTO:
expstatus = TX_ARET_ON;
cmd = CMD_TX_ARET_ON;
break;
case STATE_SLEEP:
expstatus = TRX_OFF;
cmd = CMD_FORCE_TRX_OFF;
do_sleep = true;
break;
default:
radio_error(GENERAL_ERROR);
expstatus = TRX_OFF;
cmd = CMD_TRX_OFF;
break;
}
if (STATE_SLEEP == radiostatus.state)
{
if (do_sleep)
{
return;
}
TRX_SLPTR_LOW();
/*
* Give the xosc some time to start up. Once it started, the
* SPI interface is operational, and the transceiver state can
* be polled. The state reads as 0b0011111 ("state transition
* in progress") while the transceiver is still in its startup
* phase, which does not match any of the "expstatus" values,
* so polling just continues.
*/
DELAY_US(500);
}
trx_bit_write(SR_TRX_CMD, cmd);
retries = 140; /* enough to await an ongoing frame
* reception */
do
{
currstatus = trx_bit_read(SR_TRX_STATUS);
if (expstatus == currstatus)
{
break;
}
/** @todo must wait longer for 790/868/900 MHz radios */
DELAY_US(32);
}
while (--retries);
if (expstatus != currstatus)
{
radio_error(STATE_SET_FAILED);
}
if (do_sleep)
{
TRX_SLPTR_HIGH();
}
radiostatus.state = state;
}
