static int _set_state(at86rf2xx_t *dev, netopt_state_t state)
{
switch (state) {
case NETOPT_STATE_SLEEP:
at86rf2xx_set_state(dev, AT86RF2XX_STATE_SLEEP);
break;
case NETOPT_STATE_IDLE:
at86rf2xx_set_state(dev, AT86RF2XX_STATE_RX_AACK_ON);
break;
case NETOPT_STATE_TX:
if (dev->netdev.flags & AT86RF2XX_OPT_PRELOADING) {
at86rf2xx_tx_exec(dev);
}
break;
case NETOPT_STATE_RESET:
at86rf2xx_reset(dev);
break;
default:
return -ENOTSUP;
}
return sizeof(netopt_state_t);
}
void at86rf2xx_tx_prepare(at86rf2xx_t *dev)
{
uint8_t state;
/* make sure ongoing transmissions are finished */
do {
state = at86rf2xx_get_status(dev);
} while (state == AT86RF2XX_STATE_BUSY_RX_AACK ||
state == AT86RF2XX_STATE_BUSY_TX_ARET);
if (state != AT86RF2XX_STATE_TX_ARET_ON) {
dev->idle_state = state;
}
at86rf2xx_set_state(dev, AT86RF2XX_STATE_TX_ARET_ON);
dev->tx_frame_len = IEEE802154_FCS_LEN;
}
static void _isr(netdev2_t *netdev)
{
at86rf2xx_t *dev = (at86rf2xx_t *) netdev;
uint8_t irq_mask;
uint8_t state;
uint8_t trac_status;
/* If transceiver is sleeping register access is impossible and frames are
* lost anyway, so return immediately.
*/
state = at86rf2xx_get_status(dev);
if (state == AT86RF2XX_STATE_SLEEP) {
return;
}
/* read (consume) device status */
irq_mask = at86rf2xx_reg_read(dev, AT86RF2XX_REG__IRQ_STATUS);
trac_status = at86rf2xx_reg_read(dev, AT86RF2XX_REG__TRX_STATE) &
AT86RF2XX_TRX_STATE_MASK__TRAC;
if (irq_mask & AT86RF2XX_IRQ_STATUS_MASK__RX_START) {
netdev->event_callback(netdev, NETDEV2_EVENT_RX_STARTED, NULL);
DEBUG("[at86rf2xx] EVT - RX_START\n");
}
if (irq_mask & AT86RF2XX_IRQ_STATUS_MASK__TRX_END) {
if (state == AT86RF2XX_STATE_RX_AACK_ON ||
state == AT86RF2XX_STATE_BUSY_RX_AACK) {
DEBUG("[at86rf2xx] EVT - RX_END\n");
if (!(dev->netdev.flags & AT86RF2XX_OPT_TELL_RX_END)) {
return;
}
netdev->event_callback(netdev, NETDEV2_EVENT_RX_COMPLETE, NULL);
}
else if (state == AT86RF2XX_STATE_TX_ARET_ON ||
state == AT86RF2XX_STATE_BUSY_TX_ARET) {
/* check for more pending TX calls and return to idle state if
* there are none */
assert(dev->pending_tx != 0);
if ((--dev->pending_tx) == 0) {
at86rf2xx_set_state(dev, dev->idle_state);
DEBUG("[at86rf2xx] return to state 0x%x\n", dev->idle_state);
}
DEBUG("[at86rf2xx] EVT - TX_END\n");
if (netdev->event_callback && (dev->netdev.flags & AT86RF2XX_OPT_TELL_TX_END)) {
switch (trac_status) {
case AT86RF2XX_TRX_STATE__TRAC_SUCCESS:
case AT86RF2XX_TRX_STATE__TRAC_SUCCESS_DATA_PENDING:
netdev->event_callback(netdev, NETDEV2_EVENT_TX_COMPLETE, NULL);
DEBUG("[at86rf2xx] TX SUCCESS\n");
break;
case AT86RF2XX_TRX_STATE__TRAC_NO_ACK:
netdev->event_callback(netdev, NETDEV2_EVENT_TX_NOACK, NULL);
DEBUG("[at86rf2xx] TX NO_ACK\n");
break;
case AT86RF2XX_TRX_STATE__TRAC_CHANNEL_ACCESS_FAILURE:
netdev->event_callback(netdev, NETDEV2_EVENT_TX_MEDIUM_BUSY, NULL);
DEBUG("[at86rf2xx] TX_CHANNEL_ACCESS_FAILURE\n");
break;
default:
DEBUG("[at86rf2xx] Unhandled TRAC_STATUS: %d\n",
trac_status >> 5);
}
}
}
}
static int _set(netdev2_t *netdev, netopt_t opt, void *val, size_t len)
{
at86rf2xx_t *dev = (at86rf2xx_t *) netdev;
uint8_t old_state = at86rf2xx_get_status(dev);
int res = -ENOTSUP;
if (dev == NULL) {
return -ENODEV;
}
/* temporarily wake up if sleeping */
if (old_state == AT86RF2XX_STATE_SLEEP) {
at86rf2xx_assert_awake(dev);
}
switch (opt) {
case NETOPT_ADDRESS:
if (len > sizeof(uint16_t)) {
res = -EOVERFLOW;
}
else {
at86rf2xx_set_addr_short(dev, *((uint16_t *)val));
/* don't set res to set netdev2_ieee802154_t::short_addr */
}
break;
case NETOPT_ADDRESS_LONG:
if (len > sizeof(uint64_t)) {
res = -EOVERFLOW;
}
else {
at86rf2xx_set_addr_long(dev, *((uint64_t *)val));
/* don't set res to set netdev2_ieee802154_t::long_addr */
}
break;
case NETOPT_NID:
if (len > sizeof(uint16_t)) {
res = -EOVERFLOW;
}
else {
at86rf2xx_set_pan(dev, *((uint16_t *)val));
/* don't set res to set netdev2_ieee802154_t::pan */
}
break;
case NETOPT_CHANNEL:
if (len != sizeof(uint16_t)) {
res = -EINVAL;
}
else {
uint8_t chan = ((uint8_t *)val)[0];
if (chan < AT86RF2XX_MIN_CHANNEL ||
chan > AT86RF2XX_MAX_CHANNEL) {
res = -EINVAL;
break;
}
at86rf2xx_set_chan(dev, chan);
/* don't set res to set netdev2_ieee802154_t::chan */
}
break;
case NETOPT_CHANNEL_PAGE:
if (len != sizeof(uint16_t)) {
res = -EINVAL;
}
else {
uint8_t page = ((uint8_t *)val)[0];
#ifdef MODULE_AT86RF212B
if ((page != 0) && (page != 2)) {
res = -EINVAL;
}
else {
at86rf2xx_set_page(dev, page);
res = sizeof(uint16_t);
}
#else
/* rf23x only supports page 0, no need to configure anything in the driver. */
if (page != 0) {
res = -EINVAL;
}
else {
res = sizeof(uint16_t);
}
#endif
}
break;
case NETOPT_TX_POWER:
if (len > sizeof(int16_t)) {
res = -EOVERFLOW;
}
else {
at86rf2xx_set_txpower(dev, *((int16_t *)val));
res = sizeof(uint16_t);
}
break;
case NETOPT_STATE:
if (len > sizeof(netopt_state_t)) {
res = -EOVERFLOW;
}
else {
res = _set_state(dev, *((netopt_state_t *)val));
}
break;
case NETOPT_AUTOACK:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_AUTOACK,
((bool *)val)[0]);
/* don't set res to set netdev2_ieee802154_t::flags */
break;
case NETOPT_RETRANS:
if (len > sizeof(uint8_t)) {
res = -EOVERFLOW;
}
else {
at86rf2xx_set_max_retries(dev, *((uint8_t *)val));
res = sizeof(uint8_t);
}
break;
case NETOPT_PRELOADING:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_PRELOADING,
((bool *)val)[0]);
res = sizeof(netopt_enable_t);
break;
case NETOPT_PROMISCUOUSMODE:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_PROMISCUOUS,
((bool *)val)[0]);
res = sizeof(netopt_enable_t);
break;
case NETOPT_RX_START_IRQ:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_RX_START,
((bool *)val)[0]);
res = sizeof(netopt_enable_t);
break;
case NETOPT_RX_END_IRQ:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_RX_END,
((bool *)val)[0]);
res = sizeof(netopt_enable_t);
break;
case NETOPT_TX_START_IRQ:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_TX_START,
((bool *)val)[0]);
res = sizeof(netopt_enable_t);
break;
case NETOPT_TX_END_IRQ:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_TX_END,
((bool *)val)[0]);
res = sizeof(netopt_enable_t);
break;
case NETOPT_CSMA:
at86rf2xx_set_option(dev, AT86RF2XX_OPT_CSMA,
((bool *)val)[0]);
res = sizeof(netopt_enable_t);
break;
case NETOPT_CSMA_RETRIES:
if ((len > sizeof(uint8_t)) ||
(*((uint8_t *)val) > 5)) {
res = -EOVERFLOW;
}
else if (dev->netdev.flags & AT86RF2XX_OPT_CSMA) {
/* only set if CSMA is enabled */
at86rf2xx_set_csma_max_retries(dev, *((uint8_t *)val));
res = sizeof(uint8_t);
}
break;
case NETOPT_CCA_THRESHOLD:
if (len > sizeof(int8_t)) {
res = -EOVERFLOW;
}
else {
at86rf2xx_set_cca_threshold(dev, *((int8_t *)val));
res = sizeof(int8_t);
}
break;
default:
break;
}
/* go back to sleep if were sleeping and state hasn't been changed */
if ((old_state == AT86RF2XX_STATE_SLEEP) &&
(opt != NETOPT_STATE)) {
at86rf2xx_set_state(dev, AT86RF2XX_STATE_SLEEP);
}
if (res == -ENOTSUP) {
res = netdev2_ieee802154_set((netdev2_ieee802154_t *)netdev, opt,
val, len);
}
return res;
}
static int _get(netdev2_t *netdev, netopt_t opt, void *val, size_t max_len)
{
at86rf2xx_t *dev = (at86rf2xx_t *) netdev;
if (netdev == NULL) {
return -ENODEV;
}
/* getting these options doesn't require the transceiver to be responsive */
switch (opt) {
case NETOPT_CHANNEL_PAGE:
if (max_len < sizeof(uint16_t)) {
return -EOVERFLOW;
}
((uint8_t *)val)[1] = 0;
((uint8_t *)val)[0] = at86rf2xx_get_page(dev);
return sizeof(uint16_t);
case NETOPT_MAX_PACKET_SIZE:
if (max_len < sizeof(int16_t)) {
return -EOVERFLOW;
}
*((uint16_t *)val) = AT86RF2XX_MAX_PKT_LENGTH - _MAX_MHR_OVERHEAD;
return sizeof(uint16_t);
case NETOPT_STATE:
if (max_len < sizeof(netopt_state_t)) {
return -EOVERFLOW;
}
*((netopt_state_t *)val) = _get_state(dev);
return sizeof(netopt_state_t);
case NETOPT_PRELOADING:
if (dev->netdev.flags & AT86RF2XX_OPT_PRELOADING) {
*((netopt_enable_t *)val) = NETOPT_ENABLE;
}
else {
*((netopt_enable_t *)val) = NETOPT_DISABLE;
}
return sizeof(netopt_enable_t);
case NETOPT_PROMISCUOUSMODE:
if (dev->netdev.flags & AT86RF2XX_OPT_PROMISCUOUS) {
*((netopt_enable_t *)val) = NETOPT_ENABLE;
}
else {
*((netopt_enable_t *)val) = NETOPT_DISABLE;
}
return sizeof(netopt_enable_t);
case NETOPT_RX_START_IRQ:
*((netopt_enable_t *)val) =
!!(dev->netdev.flags & AT86RF2XX_OPT_TELL_RX_START);
return sizeof(netopt_enable_t);
case NETOPT_RX_END_IRQ:
*((netopt_enable_t *)val) =
!!(dev->netdev.flags & AT86RF2XX_OPT_TELL_RX_END);
return sizeof(netopt_enable_t);
case NETOPT_TX_START_IRQ:
*((netopt_enable_t *)val) =
!!(dev->netdev.flags & AT86RF2XX_OPT_TELL_TX_START);
return sizeof(netopt_enable_t);
case NETOPT_TX_END_IRQ:
*((netopt_enable_t *)val) =
!!(dev->netdev.flags & AT86RF2XX_OPT_TELL_TX_END);
return sizeof(netopt_enable_t);
case NETOPT_CSMA:
*((netopt_enable_t *)val) =
!!(dev->netdev.flags & AT86RF2XX_OPT_CSMA);
return sizeof(netopt_enable_t);
default:
/* Can still be handled in second switch */
break;
}
int res;
if (((res = netdev2_ieee802154_get((netdev2_ieee802154_t *)netdev, opt, val,
max_len)) >= 0) || (res != -ENOTSUP)) {
return res;
}
uint8_t old_state = at86rf2xx_get_status(dev);
res = 0;
/* temporarily wake up if sleeping */
if (old_state == AT86RF2XX_STATE_SLEEP) {
at86rf2xx_assert_awake(dev);
}
/* these options require the transceiver to be not sleeping*/
switch (opt) {
case NETOPT_TX_POWER:
if (max_len < sizeof(int16_t)) {
res = -EOVERFLOW;
}
else {
*((uint16_t *)val) = at86rf2xx_get_txpower(dev);
res = sizeof(uint16_t);
}
break;
case NETOPT_RETRANS:
if (max_len < sizeof(uint8_t)) {
res = -EOVERFLOW;
}
else {
*((uint8_t *)val) = at86rf2xx_get_max_retries(dev);
res = sizeof(uint8_t);
}
break;
case NETOPT_IS_CHANNEL_CLR:
if (at86rf2xx_cca(dev)) {
*((netopt_enable_t *)val) = NETOPT_ENABLE;
}
else {
*((netopt_enable_t *)val) = NETOPT_DISABLE;
}
res = sizeof(netopt_enable_t);
break;
case NETOPT_CSMA_RETRIES:
if (max_len < sizeof(uint8_t)) {
res = -EOVERFLOW;
}
else {
*((uint8_t *)val) = at86rf2xx_get_csma_max_retries(dev);
res = sizeof(uint8_t);
}
break;
case NETOPT_CCA_THRESHOLD:
if (max_len < sizeof(int8_t)) {
res = -EOVERFLOW;
}
else {
*((int8_t *)val) = at86rf2xx_get_cca_threshold(dev);
res = sizeof(int8_t);
}
break;
default:
res = -ENOTSUP;
}
/* go back to sleep if were sleeping */
if (old_state == AT86RF2XX_STATE_SLEEP) {
at86rf2xx_set_state(dev, AT86RF2XX_STATE_SLEEP);
}
return res;
}
void at86rf2xx_reset(at86rf2xx_t *dev)
{
eui64_t addr_long;
at86rf2xx_hardware_reset(dev);
/* Reset state machine to ensure a known state */
at86rf2xx_reset_state_machine(dev);
/* reset options and sequence number */
dev->netdev.seq = 0;
dev->netdev.flags = 0;
/* get an 8-byte unique ID to use as hardware address */
luid_get(addr_long.uint8, IEEE802154_LONG_ADDRESS_LEN);
/* make sure we mark the address as non-multicast and not globally unique */
addr_long.uint8[0] &= ~(0x01);
addr_long.uint8[0] |= (0x02);
/* set short and long address */
at86rf2xx_set_addr_long(dev, NTOHLL(addr_long.uint64.u64));
at86rf2xx_set_addr_short(dev, NTOHS(addr_long.uint16[0].u16));
/* set default PAN id */
at86rf2xx_set_pan(dev, AT86RF2XX_DEFAULT_PANID);
/* set default channel */
at86rf2xx_set_chan(dev, AT86RF2XX_DEFAULT_CHANNEL);
/* set default TX power */
at86rf2xx_set_txpower(dev, AT86RF2XX_DEFAULT_TXPOWER);
/* set default options */
at86rf2xx_set_option(dev, AT86RF2XX_OPT_AUTOACK, true);
at86rf2xx_set_option(dev, AT86RF2XX_OPT_CSMA, true);
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_RX_START, false);
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_RX_END, true);
#ifdef MODULE_NETSTATS_L2
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_TX_END, true);
#endif
/* set default protocol */
#ifdef MODULE_GNRC_SIXLOWPAN
dev->netdev.proto = GNRC_NETTYPE_SIXLOWPAN;
#elif MODULE_GNRC
dev->netdev.proto = GNRC_NETTYPE_UNDEF;
#endif
/* enable safe mode (protect RX FIFO until reading data starts) */
at86rf2xx_reg_write(dev, AT86RF2XX_REG__TRX_CTRL_2,
AT86RF2XX_TRX_CTRL_2_MASK__RX_SAFE_MODE);
#ifdef MODULE_AT86RF212B
at86rf2xx_set_page(dev, 0);
#endif
/* don't populate masked interrupt flags to IRQ_STATUS register */
uint8_t tmp = at86rf2xx_reg_read(dev, AT86RF2XX_REG__TRX_CTRL_1);
tmp &= ~(AT86RF2XX_TRX_CTRL_1_MASK__IRQ_MASK_MODE);
at86rf2xx_reg_write(dev, AT86RF2XX_REG__TRX_CTRL_1, tmp);
/* disable clock output to save power */
tmp = at86rf2xx_reg_read(dev, AT86RF2XX_REG__TRX_CTRL_0);
tmp &= ~(AT86RF2XX_TRX_CTRL_0_MASK__CLKM_CTRL);
tmp &= ~(AT86RF2XX_TRX_CTRL_0_MASK__CLKM_SHA_SEL);
tmp |= (AT86RF2XX_TRX_CTRL_0_CLKM_CTRL__OFF);
at86rf2xx_reg_write(dev, AT86RF2XX_REG__TRX_CTRL_0, tmp);
/* enable interrupts */
at86rf2xx_reg_write(dev, AT86RF2XX_REG__IRQ_MASK,
AT86RF2XX_IRQ_STATUS_MASK__TRX_END);
/* clear interrupt flags */
at86rf2xx_reg_read(dev, AT86RF2XX_REG__IRQ_STATUS);
/* go into RX state */
at86rf2xx_set_state(dev, AT86RF2XX_STATE_RX_AACK_ON);
DEBUG("at86rf2xx_reset(): reset complete.\n");
}
void at86rf2xx_reset(at86rf2xx_t *dev)
{
#if CPUID_LEN
uint8_t cpuid[CPUID_LEN];
eui64_t addr_long;
#endif
at86rf2xx_hardware_reset(dev);
/* Reset state machine to ensure a known state */
at86rf2xx_reset_state_machine(dev);
/* reset options and sequence number */
dev->seq_nr = 0;
dev->options = 0;
/* set short and long address */
#if CPUID_LEN
cpuid_get(cpuid);
#if CPUID_LEN < 8
/* in case CPUID_LEN < 8, fill missing bytes with zeros */
for (int i = CPUID_LEN; i < 8; i++) {
cpuid[i] = 0;
}
#else
for (int i = 8; i < CPUID_LEN; i++) {
cpuid[i & 0x07] ^= cpuid[i];
}
#endif
/* make sure we mark the address as non-multicast and not globally unique */
cpuid[0] &= ~(0x01);
cpuid[0] |= 0x02;
/* copy and set long address */
memcpy(&addr_long, cpuid, 8);
at86rf2xx_set_addr_long(dev, NTOHLL(addr_long.uint64.u64));
at86rf2xx_set_addr_short(dev, NTOHS(addr_long.uint16[0].u16));
#else
at86rf2xx_set_addr_long(dev, AT86RF2XX_DEFAULT_ADDR_LONG);
at86rf2xx_set_addr_short(dev, AT86RF2XX_DEFAULT_ADDR_SHORT);
#endif
/* set default PAN id */
at86rf2xx_set_pan(dev, AT86RF2XX_DEFAULT_PANID);
/* set default channel */
at86rf2xx_set_chan(dev, AT86RF2XX_DEFAULT_CHANNEL);
/* set default TX power */
at86rf2xx_set_txpower(dev, AT86RF2XX_DEFAULT_TXPOWER);
/* set default options */
at86rf2xx_set_option(dev, AT86RF2XX_OPT_AUTOACK, true);
at86rf2xx_set_option(dev, AT86RF2XX_OPT_CSMA, true);
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_RX_START, false);
at86rf2xx_set_option(dev, AT86RF2XX_OPT_TELL_RX_END, true);
/* set default protocol */
#ifdef MODULE_GNRC_SIXLOWPAN
dev->proto = GNRC_NETTYPE_SIXLOWPAN;
#else
dev->proto = GNRC_NETTYPE_UNDEF;
#endif
/* enable safe mode (protect RX FIFO until reading data starts) */
at86rf2xx_reg_write(dev, AT86RF2XX_REG__TRX_CTRL_2,
AT86RF2XX_TRX_CTRL_2_MASK__RX_SAFE_MODE);
#ifdef MODULE_AT86RF212B
at86rf2xx_set_page(dev, 0);
#endif
/* don't populate masked interrupt flags to IRQ_STATUS register */
uint8_t tmp = at86rf2xx_reg_read(dev, AT86RF2XX_REG__TRX_CTRL_1);
tmp &= ~(AT86RF2XX_TRX_CTRL_1_MASK__IRQ_MASK_MODE);
at86rf2xx_reg_write(dev, AT86RF2XX_REG__TRX_CTRL_1, tmp);
/* disable clock output to save power */
tmp = at86rf2xx_reg_read(dev, AT86RF2XX_REG__TRX_CTRL_0);
tmp &= ~(AT86RF2XX_TRX_CTRL_0_MASK__CLKM_CTRL);
tmp &= ~(AT86RF2XX_TRX_CTRL_0_MASK__CLKM_SHA_SEL);
tmp |= (AT86RF2XX_TRX_CTRL_0_CLKM_CTRL__OFF);
at86rf2xx_reg_write(dev, AT86RF2XX_REG__TRX_CTRL_0, tmp);
/* enable interrupts */
at86rf2xx_reg_write(dev, AT86RF2XX_REG__IRQ_MASK,
AT86RF2XX_IRQ_STATUS_MASK__TRX_END);
/* clear interrupt flags */
at86rf2xx_reg_read(dev, AT86RF2XX_REG__IRQ_STATUS);
/* go into RX state */
at86rf2xx_set_state(dev, AT86RF2XX_STATE_RX_AACK_ON);
DEBUG("at86rf2xx_reset(): reset complete.\n");
}
void at86rf2xx_configure_phy(at86rf2xx_t *dev)
{
/* make sure device is not sleeping */
at86rf2xx_assert_awake(dev);
uint8_t state;
/* make sure ongoing transmissions are finished */
do {
state = at86rf2xx_get_status(dev);
}
while ((state == AT86RF2XX_STATE_BUSY_TX_ARET) || (state == AT86RF2XX_STATE_BUSY_RX_AACK));
/* we must be in TRX_OFF before changing the PHY configuration */
at86rf2xx_force_trx_off(dev);
#ifdef MODULE_AT86RF212B
/* The TX power register must be updated after changing the channel if
* moving between bands. */
int16_t txpower = at86rf2xx_get_txpower(dev);
uint8_t trx_ctrl2 = at86rf2xx_reg_read(dev, AT86RF2XX_REG__TRX_CTRL_2);
uint8_t rf_ctrl0 = at86rf2xx_reg_read(dev, AT86RF2XX_REG__RF_CTRL_0);
/* Clear previous configuration for PHY mode */
trx_ctrl2 &= ~(AT86RF2XX_TRX_CTRL_2_MASK__FREQ_MODE);
/* Clear previous configuration for GC_TX_OFFS */
rf_ctrl0 &= ~AT86RF2XX_RF_CTRL_0_MASK__GC_TX_OFFS;
if (dev->netdev.chan != 0) {
/* Set sub mode bit on 915 MHz as recommended by the data sheet */
trx_ctrl2 |= AT86RF2XX_TRX_CTRL_2_MASK__SUB_MODE;
}
if (dev->page == 0) {
/* BPSK coding */
/* Data sheet recommends using a +2 dB setting for BPSK */
rf_ctrl0 |= AT86RF2XX_RF_CTRL_0_GC_TX_OFFS__2DB;
}
else if (dev->page == 2) {
/* O-QPSK coding */
trx_ctrl2 |= AT86RF2XX_TRX_CTRL_2_MASK__BPSK_OQPSK;
/* Data sheet recommends using a +1 dB setting for O-QPSK */
rf_ctrl0 |= AT86RF2XX_RF_CTRL_0_GC_TX_OFFS__1DB;
}
at86rf2xx_reg_write(dev, AT86RF2XX_REG__TRX_CTRL_2, trx_ctrl2);
at86rf2xx_reg_write(dev, AT86RF2XX_REG__RF_CTRL_0, rf_ctrl0);
#endif
uint8_t phy_cc_cca = at86rf2xx_reg_read(dev, AT86RF2XX_REG__PHY_CC_CCA);
/* Clear previous configuration for channel number */
phy_cc_cca &= ~(AT86RF2XX_PHY_CC_CCA_MASK__CHANNEL);
/* Update the channel register */
phy_cc_cca |= (dev->netdev.chan & AT86RF2XX_PHY_CC_CCA_MASK__CHANNEL);
at86rf2xx_reg_write(dev, AT86RF2XX_REG__PHY_CC_CCA, phy_cc_cca);
#ifdef MODULE_AT86RF212B
/* Update the TX power register to achieve the same power (in dBm) */
at86rf2xx_set_txpower(dev, txpower);
#endif
/* Return to the state we had before reconfiguring */
at86rf2xx_set_state(dev, state);
}
