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zephyr/drivers/ieee802154/ieee802154_mcr20a.c
Jordan Yates e7a5505e74 ieee802154: mcr20a: Add chip select flags 
Adds the chip select devicetree flags to the spi_cs_control instance.

Signed-off-by: Jordan Yates <jordan.yates@data61.csiro.au>
2020-07-01 16:40:03 -05:00

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/* ieee802154_mcr20a.c - NXP MCR20A driver */
#define DT_DRV_COMPAT nxp_mcr20a
/*
* Copyright (c) 2017 PHYTEC Messtechnik GmbH
*
* SPDX-License-Identifier: Apache-2.0
*/
#define LOG_MODULE_NAME ieee802154_mcr20a
#define LOG_LEVEL CONFIG_IEEE802154_DRIVER_LOG_LEVEL
#include <logging/log.h>
LOG_MODULE_REGISTER(LOG_MODULE_NAME);
#include <errno.h>
#include <kernel.h>
#include <arch/cpu.h>
#include <debug/stack.h>
#include <device.h>
#include <init.h>
#include <net/net_if.h>
#include <net/net_pkt.h>
#include <sys/byteorder.h>
#include <string.h>
#include <random/rand32.h>
#include <debug/stack.h>
#include <drivers/gpio.h>
#include <net/ieee802154_radio.h>
#include "ieee802154_mcr20a.h"
#include "MCR20Overwrites.h"
/*
* max. TX duraton = (PR + SFD + FLI + PDU + FCS)
* + RX_warmup + cca + TX_warmup
* TODO: Calculate the value from frame length.
* Invalid for the SLOTTED mode.
*/
#define _MAX_PKT_TX_DURATION (133 + 9 + 8 + 9)
#if LOG_LEVEL == LOG_LEVEL_DBG
/* Prevent timer overflow during LOG_* output */
#define _MACACKWAITDURATION (864 / 16 + 11625)
#define MCR20A_SEQ_SYNC_TIMEOUT (200)
#else
#define MCR20A_SEQ_SYNC_TIMEOUT (20)
#define _MACACKWAITDURATION (864 / 16) /* 864us * 62500Hz */
#endif
#define MCR20A_FCS_LENGTH (2)
#define MCR20A_PSDU_LENGTH (125)
#define MCR20A_GET_SEQ_STATE_RETRIES (3)
/* Values for the clock output (CLK_OUT) configuration */
#ifdef CONFIG_MCR20A_CLK_OUT_DISABLED
#define MCR20A_CLK_OUT_CONFIG (MCR20A_CLK_OUT_HIZ)
#elif CONFIG_MCR20A_CLK_OUT_32MHZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(0) | MCR20A_CLK_OUT_DS |\
MCR20A_CLK_OUT_EN)
#elif CONFIG_MCR20A_CLK_OUT_16MHZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(1) | MCR20A_CLK_OUT_DS |\
MCR20A_CLK_OUT_EN)
#elif CONFIG_MCR20A_CLK_OUT_8MHZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(2) | MCR20A_CLK_OUT_EN)
#elif CONFIG_MCR20A_CLK_OUT_4MHZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(3) | MCR20A_CLK_OUT_EN)
#elif CONFIG_MCR20A_CLK_OUT_1MHZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(4) | MCR20A_CLK_OUT_EN)
#elif CONFIG_MCR20A_CLK_OUT_250KHZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(5) | MCR20A_CLK_OUT_EN)
#elif CONFIG_MCR20A_CLK_OUT_62500HZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(6) | MCR20A_CLK_OUT_EN)
#elif CONFIG_MCR20A_CLK_OUT_32768HZ
#define MCR20A_CLK_OUT_CONFIG (set_bits_clk_out_div(7) | MCR20A_CLK_OUT_EN)
#endif
#ifdef CONFIG_MCR20A_IS_PART_OF_KW2XD_SIP
#define PART_OF_KW2XD_SIP 1
#else
#define PART_OF_KW2XD_SIP 0
#endif
/* Values for the power mode (PM) configuration */
#define MCR20A_PM_HIBERNATE 0
#define MCR20A_PM_DOZE MCR20A_PWR_MODES_XTALEN
#define MCR20A_PM_IDLE (MCR20A_PWR_MODES_XTALEN |\
MCR20A_PWR_MODES_PMC_MODE)
#define MCR20A_PM_AUTODOZE (MCR20A_PWR_MODES_XTALEN |\
MCR20A_PWR_MODES_AUTODOZE)
/* Default settings for the device initialization */
#define MCR20A_DEFAULT_TX_POWER (0)
#define MCR20A_DEFAULT_CHANNEL (26)
/* RF TX power max/min values (dBm) */
#define MCR20A_OUTPUT_POWER_MAX (8)
#define MCR20A_OUTPUT_POWER_MIN (-35)
/* Lookup table for the Power Control register */
static const uint8_t pow_lt[44] = {
3, 4, 5, 6,
6, 7, 7, 8,
8, 9, 9, 10,
11, 11, 12, 13,
13, 14, 14, 15,
16, 16, 17, 18,
18, 19, 20, 20,
21, 21, 22, 23,
23, 24, 25, 25,
26, 27, 27, 28,
28, 29, 30, 31
};
/* PLL integer and fractional lookup tables
*
* Fc = 2405 + 5(k - 11) , k = 11,12,...,26
*
* Equation for PLL frequency, MKW2xD Reference Manual, p.255 :
* F = ((PLL_INT0 + 64) + (PLL_FRAC0/65536))32MHz
*
*/
static const uint8_t pll_int_lt[16] = {
11, 11, 11, 11,
11, 11, 12, 12,
12, 12, 12, 12,
13, 13, 13, 13
};
static const uint16_t pll_frac_lt[16] = {
10240, 20480, 30720, 40960,
51200, 61440, 6144, 16384,
26624, 36864, 47104, 57344,
2048, 12288, 22528, 32768
};
#define z_usleep(usec) k_busy_wait(usec)
/* Read direct (dreg is true) or indirect register (dreg is false) */
uint8_t z_mcr20a_read_reg(struct mcr20a_context *dev, bool dreg, uint8_t addr)
{
uint8_t cmd_buf[3] = {
dreg ? (MCR20A_REG_READ | addr) :
(MCR20A_IAR_INDEX | MCR20A_REG_WRITE),
dreg ? 0 : (addr | MCR20A_REG_READ),
0
};
uint8_t len = dreg ? 2 : 3;
const struct spi_buf buf = {
.buf = cmd_buf,
.len = len
};
const struct spi_buf_set tx = {
.buffers = &buf,
.count = 1
};
const struct spi_buf_set rx = {
.buffers = &buf,
.count = 1
};
if (spi_transceive(dev->spi, &dev->spi_cfg, &tx, &rx) == 0) {
return cmd_buf[len - 1];
}
LOG_ERR("Failed");
return 0;
}
/* Write direct (dreg is true) or indirect register (dreg is false) */
bool z_mcr20a_write_reg(struct mcr20a_context *dev, bool dreg, uint8_t addr,
uint8_t value)
{
uint8_t cmd_buf[3] = {
dreg ? (MCR20A_REG_WRITE | addr) :
(MCR20A_IAR_INDEX | MCR20A_REG_WRITE),
dreg ? value : (addr | MCR20A_REG_WRITE),
dreg ? 0 : value
};
const struct spi_buf buf = {
.buf = cmd_buf,
.len = dreg ? 2 : 3
};
const struct spi_buf_set tx = {
.buffers = &buf,
.count = 1
};
return (spi_write(dev->spi, &dev->spi_cfg, &tx) == 0);
}
/* Write multiple bytes to direct or indirect register */
bool z_mcr20a_write_burst(struct mcr20a_context *dev, bool dreg, uint16_t addr,
uint8_t *data_buf, uint8_t len)
{
uint8_t cmd_buf[2] = {
dreg ? MCR20A_REG_WRITE | addr :
MCR20A_IAR_INDEX | MCR20A_REG_WRITE,
dreg ? 0 : addr | MCR20A_REG_WRITE
};
struct spi_buf bufs[2] = {
{
.buf = cmd_buf,
.len = dreg ? 1 : 2
},
{
.buf = data_buf,
.len = len
}
};
const struct spi_buf_set tx = {
.buffers = bufs,
.count = 2
};
return (spi_write(dev->spi, &dev->spi_cfg, &tx) == 0);
}
/* Read multiple bytes from direct or indirect register */
bool z_mcr20a_read_burst(struct mcr20a_context *dev, bool dreg, uint16_t addr,
uint8_t *data_buf, uint8_t len)
{
uint8_t cmd_buf[2] = {
dreg ? MCR20A_REG_READ | addr :
MCR20A_IAR_INDEX | MCR20A_REG_WRITE,
dreg ? 0 : addr | MCR20A_REG_READ
};
struct spi_buf bufs[2] = {
{
.buf = cmd_buf,
.len = dreg ? 1 : 2
},
{
.buf = data_buf,
.len = len
}
};
const struct spi_buf_set tx = {
.buffers = bufs,
.count = 1
};
const struct spi_buf_set rx = {
.buffers = bufs,
.count = 2
};
return (spi_transceive(dev->spi, &dev->spi_cfg, &tx, &rx) == 0);
}
/* Mask (msk is true) or unmask all interrupts from asserting IRQ_B */
static bool mcr20a_mask_irqb(struct mcr20a_context *dev, bool msk)
{
uint8_t ctrl4 = read_reg_phy_ctrl4(dev);
if (msk) {
ctrl4 |= MCR20A_PHY_CTRL4_TRCV_MSK;
} else {
ctrl4 &= ~MCR20A_PHY_CTRL4_TRCV_MSK;
}
return write_reg_phy_ctrl4(dev, ctrl4);
}
/** Set an timeout value for the given compare register */
static int mcr20a_timer_set(struct mcr20a_context *mcr20a,
uint8_t cmp_reg,
uint32_t timeout)
{
uint32_t now = 0U;
uint32_t next;
bool retval;
if (!read_burst_event_timer(mcr20a, (uint8_t *)&now)) {
goto error;
}
now = sys_le32_to_cpu(now);
next = now + timeout;
LOG_DBG("now: 0x%x set 0x%x", now, next);
next = sys_cpu_to_le32(next);
switch (cmp_reg) {
case 1:
retval = write_burst_t1cmp(mcr20a, (uint8_t *)&next);
break;
case 2:
retval = write_burst_t2cmp(mcr20a, (uint8_t *)&next);
break;
case 3:
retval = write_burst_t3cmp(mcr20a, (uint8_t *)&next);
break;
case 4:
retval = write_burst_t4cmp(mcr20a, (uint8_t *)&next);
break;
default:
goto error;
}
if (!retval) {
goto error;
}
return 0;
error:
LOG_ERR("Failed");
return -EIO;
}
static int mcr20a_timer_init(struct device *dev, uint8_t tb)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t buf[3] = {0, 0, 0};
uint8_t ctrl4;
if (!write_reg_tmr_prescale(mcr20a,
set_bits_tmr_prescale(tb))) {
goto error;
}
if (!write_burst_t1cmp(mcr20a, buf)) {
goto error;
}
ctrl4 = read_reg_phy_ctrl4(mcr20a);
ctrl4 |= MCR20A_PHY_CTRL4_TMRLOAD;
if (!write_reg_phy_ctrl4(mcr20a, ctrl4)) {
goto error;
}
LOG_DBG("done, timebase %d", tb);
return 0;
error:
LOG_ERR("Failed");
return -EIO;
}
/* Set Timer Comparator 4 */
static int mcr20a_t4cmp_set(struct mcr20a_context *mcr20a,
uint32_t timeout)
{
uint8_t irqsts3;
uint8_t ctrl3;
if (mcr20a_timer_set(mcr20a, 4, timeout)) {
goto error;
}
/* enable and clear irq for the timer 4 */
irqsts3 = read_reg_irqsts3(mcr20a);
irqsts3 &= ~MCR20A_IRQSTS3_TMR4MSK;
irqsts3 |= MCR20A_IRQSTS3_TMR4IRQ;
if (!write_reg_irqsts3(mcr20a, irqsts3)) {
goto error;
}
ctrl3 = read_reg_phy_ctrl3(mcr20a);
ctrl3 |= MCR20A_PHY_CTRL3_TMR4CMP_EN;
if (!write_reg_phy_ctrl3(mcr20a, ctrl3)) {
goto error;
}
return 0;
error:
LOG_DBG("Failed");
return -EIO;
}
/* Clear Timer Comparator 4 */
static int mcr20a_t4cmp_clear(struct mcr20a_context *mcr20a)
{
uint8_t irqsts3;
uint8_t ctrl3;
ctrl3 = read_reg_phy_ctrl3(mcr20a);
ctrl3 &= ~MCR20A_PHY_CTRL3_TMR4CMP_EN;
if (!write_reg_phy_ctrl3(mcr20a, ctrl3)) {
goto error;
}
irqsts3 = read_reg_irqsts3(mcr20a);
irqsts3 |= MCR20A_IRQSTS3_TMR4IRQ;
if (!write_reg_irqsts3(mcr20a, irqsts3)) {
goto error;
}
return 0;
error:
LOG_DBG("Failed");
return -EIO;
}
static inline void xcvseq_wait_until_idle(struct mcr20a_context *mcr20a)
{
uint8_t state;
uint8_t retries = MCR20A_GET_SEQ_STATE_RETRIES;
do {
state = read_reg_seq_state(mcr20a);
retries--;
} while ((state & MCR20A_SEQ_STATE_MASK) && retries);
if (state & MCR20A_SEQ_STATE_MASK) {
LOG_ERR("Timeout");
}
}
static inline int mcr20a_abort_sequence(struct mcr20a_context *mcr20a,
bool force)
{
uint8_t ctrl1;
ctrl1 = read_reg_phy_ctrl1(mcr20a);
LOG_DBG("CTRL1 0x%02x", ctrl1);
if (((ctrl1 & MCR20A_PHY_CTRL1_XCVSEQ_MASK) == MCR20A_XCVSEQ_TX) ||
((ctrl1 & MCR20A_PHY_CTRL1_XCVSEQ_MASK) == MCR20A_XCVSEQ_TX_RX)) {
if (!force) {
return -1;
}
}
/* Abort ongoing sequence */
ctrl1 &= ~MCR20A_PHY_CTRL1_XCVSEQ_MASK;
if (!write_reg_phy_ctrl1(mcr20a, ctrl1)) {
return -1;
}
xcvseq_wait_until_idle(mcr20a);
/* Clear relevant interrupt flags */
if (!write_reg_irqsts1(mcr20a, MCR20A_IRQSTS1_IRQ_MASK)) {
return -1;
}
return 0;
}
/* Initiate a (new) Transceiver Sequence */
static inline int mcr20a_set_sequence(struct mcr20a_context *mcr20a,
uint8_t seq)
{
uint8_t ctrl1 = 0U;
seq = set_bits_phy_ctrl1_xcvseq(seq);
ctrl1 = read_reg_phy_ctrl1(mcr20a);
ctrl1 &= ~MCR20A_PHY_CTRL1_XCVSEQ_MASK;
if ((seq == MCR20A_XCVSEQ_TX_RX) &&
(ctrl1 & MCR20A_PHY_CTRL1_RXACKRQD)) {
/* RXACKRQD enabled, timer should be set. */
mcr20a_t4cmp_set(mcr20a, _MACACKWAITDURATION +
_MAX_PKT_TX_DURATION);
}
ctrl1 |= seq;
if (!write_reg_phy_ctrl1(mcr20a, ctrl1)) {
return -EIO;
}
return 0;
}
static inline uint32_t mcr20a_get_rssi(uint32_t lqi)
{
/* Get rssi (Received Signal Strength Indicator, unit is dBm)
* from lqi (Link Quality Indicator) value.
* There are two different equations for RSSI:
* RF = (LQI 286.6) / 2.69333 (MKW2xD Reference Manual)
* RF = (LQI 295.4) / 2.84 (MCR20A Reference Manual)
* The last appears more to match the graphic (Figure 3-10).
* Since RSSI value is always positive and we want to
* avoid the floating point computation:
* -RF * 65536 = (LQI / 2.84 - 295.4 / 2.84) * 65536
* RF * 65536 = (295.4 * 65536 / 2.84) - (LQI * 65536 / 2.84)
*/
uint32_t a = (uint32_t)(295.4 * 65536 / 2.84);
uint32_t b = (uint32_t)(65536 / 2.84);
return (a - (b * lqi)) >> 16;
}
static inline uint8_t *get_mac(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint32_t *ptr = (uint32_t *)(mcr20a->mac_addr);
UNALIGNED_PUT(sys_rand32_get(), ptr);
ptr = (uint32_t *)(mcr20a->mac_addr + 4);
UNALIGNED_PUT(sys_rand32_get(), ptr);
mcr20a->mac_addr[0] = (mcr20a->mac_addr[0] & ~0x01) | 0x02;
return mcr20a->mac_addr;
}
static inline bool read_rxfifo_content(struct mcr20a_context *dev,
struct net_buf *buf, uint8_t len)
{
uint8_t cmd = MCR20A_BUF_READ;
struct spi_buf bufs[2] = {
{
.buf = &cmd,
.len = 1
},
{
.buf = buf->data,
.len = len
}
};
const struct spi_buf_set tx = {
.buffers = bufs,
.count = 1
};
const struct spi_buf_set rx = {
.buffers = bufs,
.count = 2
};
if (spi_transceive(dev->spi, &dev->spi_cfg, &tx, &rx) != 0) {
return false;
}
net_buf_add(buf, len);
return true;
}
static inline void mcr20a_rx(struct mcr20a_context *mcr20a, uint8_t len)
{
struct net_pkt *pkt = NULL;
uint8_t pkt_len;
pkt_len = len - MCR20A_FCS_LENGTH;
pkt = net_pkt_alloc_with_buffer(mcr20a->iface, pkt_len,
AF_UNSPEC, 0, K_NO_WAIT);
if (!pkt) {
LOG_ERR("No buf available");
goto out;
}
if (!read_rxfifo_content(mcr20a, pkt->buffer, pkt_len)) {
LOG_ERR("No content read");
goto out;
}
if (ieee802154_radio_handle_ack(mcr20a->iface, pkt) == NET_OK) {
LOG_DBG("ACK packet handled");
goto out;
}
net_pkt_set_ieee802154_lqi(pkt, read_reg_lqi_value(mcr20a));
net_pkt_set_ieee802154_rssi(pkt, mcr20a_get_rssi(
net_pkt_ieee802154_lqi(pkt)));
LOG_DBG("Caught a packet (%u) (LQI: %u, RSSI: %u)",
pkt_len, net_pkt_ieee802154_lqi(pkt),
net_pkt_ieee802154_rssi(pkt));
if (net_recv_data(mcr20a->iface, pkt) < 0) {
LOG_DBG("Packet dropped by NET stack");
goto out;
}
log_stack_usage(&mcr20a->mcr20a_rx_thread);
return;
out:
if (pkt) {
net_pkt_unref(pkt);
}
}
/*
* The function checks how the XCV sequence has been completed
* and sets the variable seq_retval accordingly. It returns true
* if a new sequence is to be set. This function is only to be called
* when a sequence has been completed.
*/
static inline bool irqsts1_event(struct mcr20a_context *mcr20a,
uint8_t *dregs)
{
uint8_t seq = dregs[MCR20A_PHY_CTRL1] & MCR20A_PHY_CTRL1_XCVSEQ_MASK;
uint8_t new_seq = MCR20A_XCVSEQ_RECEIVE;
bool retval = false;
switch (seq) {
case MCR20A_XCVSEQ_RECEIVE:
if ((dregs[MCR20A_IRQSTS1] & MCR20A_IRQSTS1_RXIRQ)) {
if ((dregs[MCR20A_IRQSTS1] & MCR20A_IRQSTS1_TXIRQ)) {
LOG_DBG("Finished RxSeq + TxAck");
} else {
LOG_DBG("Finished RxSeq");
}
mcr20a_rx(mcr20a, dregs[MCR20A_RX_FRM_LEN]);
retval = true;
}
break;
case MCR20A_XCVSEQ_TX:
case MCR20A_XCVSEQ_TX_RX:
if (dregs[MCR20A_IRQSTS1] & MCR20A_IRQSTS1_CCAIRQ) {
if (dregs[MCR20A_IRQSTS2] & MCR20A_IRQSTS2_CCA) {
LOG_DBG("Finished CCA, CH busy");
atomic_set(&mcr20a->seq_retval, -EBUSY);
retval = true;
break;
}
}
if (dregs[MCR20A_IRQSTS1] & MCR20A_IRQSTS1_TXIRQ) {
atomic_set(&mcr20a->seq_retval, 0);
if ((dregs[MCR20A_IRQSTS1] & MCR20A_IRQSTS1_RXIRQ)) {
LOG_DBG("Finished TxSeq + RxAck");
/* Got Ack, timer should be disabled. */
mcr20a_t4cmp_clear(mcr20a);
} else {
LOG_DBG("Finished TxSeq");
}
retval = true;
}
break;
case MCR20A_XCVSEQ_CONTINUOUS_CCA:
case MCR20A_XCVSEQ_CCA:
if ((dregs[MCR20A_IRQSTS1] & MCR20A_IRQSTS1_CCAIRQ)) {
/* If CCCA, then timer should be disabled. */
/* mcr20a_t4cmp_clear(mcr20a); */
if (dregs[MCR20A_IRQSTS2] & MCR20A_IRQSTS2_CCA) {
LOG_DBG("Finished CCA, CH busy");
atomic_set(&mcr20a->seq_retval, -EBUSY);
} else {
/**
* Assume that after the CCA,
* a transmit sequence follows and
* set here the sequence manager to Idle.
*/
LOG_DBG("Finished CCA, CH idle");
new_seq = MCR20A_XCVSEQ_IDLE;
atomic_set(&mcr20a->seq_retval, 0);
}
retval = true;
}
break;
case MCR20A_XCVSEQ_IDLE:
default:
LOG_ERR("SEQ triggered, but XCVSEQ is in the Idle state");
LOG_ERR("IRQSTS: 0x%02x", dregs[MCR20A_IRQSTS1]);
break;
}
dregs[MCR20A_PHY_CTRL1] &= ~MCR20A_PHY_CTRL1_XCVSEQ_MASK;
dregs[MCR20A_PHY_CTRL1] |= new_seq;
return retval;
}
/*
* Check the Timer Comparator IRQ register IRQSTS3.
* Currently we use only T4CMP to cancel the running sequence,
* usually the TR.
*/
static inline bool irqsts3_event(struct mcr20a_context *mcr20a,
uint8_t *dregs)
{
bool retval = false;
if (dregs[MCR20A_IRQSTS3] & MCR20A_IRQSTS3_TMR4IRQ) {
LOG_DBG("Sequence timeout, IRQSTSs 0x%02x 0x%02x 0x%02x",
dregs[MCR20A_IRQSTS1],
dregs[MCR20A_IRQSTS2],
dregs[MCR20A_IRQSTS3]);
atomic_set(&mcr20a->seq_retval, -EBUSY);
mcr20a_t4cmp_clear(mcr20a);
dregs[MCR20A_PHY_CTRL1] &= ~MCR20A_PHY_CTRL1_XCVSEQ_MASK;
dregs[MCR20A_PHY_CTRL1] |= MCR20A_XCVSEQ_RECEIVE;
/* Clear all interrupts */
dregs[MCR20A_IRQSTS1] = MCR20A_IRQSTS1_IRQ_MASK;
retval = true;
} else {
LOG_ERR("IRQSTS3 contains untreated IRQs: 0x%02x",
dregs[MCR20A_IRQSTS3]);
}
return retval;
}
static void mcr20a_thread_main(void *arg)
{
struct device *dev = (struct device *)arg;
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t dregs[MCR20A_PHY_CTRL4 + 1];
bool set_new_seq;
uint8_t ctrl1 = 0U;
while (true) {
k_sem_take(&mcr20a->isr_sem, K_FOREVER);
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
set_new_seq = false;
if (!mcr20a_mask_irqb(mcr20a, true)) {
LOG_ERR("Failed to mask IRQ_B");
goto unmask_irqb;
}
/* Read the register from IRQSTS1 until CTRL4 */
if (!read_burst_irqsts1_ctrl4(mcr20a, dregs)) {
LOG_ERR("Failed to read register");
goto unmask_irqb;
}
/* make backup from PHY_CTRL1 register */
ctrl1 = dregs[MCR20A_PHY_CTRL1];
if (dregs[MCR20A_IRQSTS3] & MCR20A_IRQSTS3_IRQ_MASK) {
set_new_seq = irqsts3_event(mcr20a, dregs);
} else if (dregs[MCR20A_IRQSTS1] & MCR20A_IRQSTS1_SEQIRQ) {
set_new_seq = irqsts1_event(mcr20a, dregs);
}
if (dregs[MCR20A_IRQSTS2] & MCR20A_IRQSTS2_IRQ_MASK) {
LOG_ERR("IRQSTS2 contains untreated IRQs: 0x%02x",
dregs[MCR20A_IRQSTS2]);
}
LOG_DBG("WB: 0x%02x | 0x%02x | 0x%02x",
dregs[MCR20A_IRQSTS1],
dregs[MCR20A_IRQSTS2],
dregs[MCR20A_IRQSTS3]);
/* Write back register, clear IRQs and set new sequence */
if (set_new_seq) {
/* Reset sequence manager */
ctrl1 &= ~MCR20A_PHY_CTRL1_XCVSEQ_MASK;
if (!write_reg_phy_ctrl1(mcr20a, ctrl1)) {
LOG_ERR("Failed to reset SEQ manager");
}
xcvseq_wait_until_idle(mcr20a);
if (!write_burst_irqsts1_ctrl1(mcr20a, dregs)) {
LOG_ERR("Failed to write CTRL1");
}
} else {
if (!write_burst_irqsts1_irqsts3(mcr20a, dregs)) {
LOG_ERR("Failed to write IRQSTS3");
}
}
unmask_irqb:
if (!mcr20a_mask_irqb(mcr20a, false)) {
LOG_ERR("Failed to unmask IRQ_B");
}
k_mutex_unlock(&mcr20a->phy_mutex);
if (set_new_seq) {
k_sem_give(&mcr20a->seq_sync);
}
}
}
static inline void irqb_int_handler(struct device *port,
struct gpio_callback *cb, uint32_t pins)
{
struct mcr20a_context *mcr20a = CONTAINER_OF(cb,
struct mcr20a_context,
irqb_cb);
k_sem_give(&mcr20a->isr_sem);
}
static void enable_irqb_interrupt(struct mcr20a_context *mcr20a,
bool enable)
{
gpio_flags_t flags = enable
? GPIO_INT_EDGE_TO_ACTIVE
: GPIO_INT_DISABLE;
gpio_pin_interrupt_configure(mcr20a->irq_gpio,
DT_INST_GPIO_PIN(0, irqb_gpios),
flags);
}
static inline void setup_gpio_callbacks(struct mcr20a_context *mcr20a)
{
gpio_init_callback(&mcr20a->irqb_cb,
irqb_int_handler,
BIT(DT_INST_GPIO_PIN(0, irqb_gpios)));
gpio_add_callback(mcr20a->irq_gpio, &mcr20a->irqb_cb);
}
static int mcr20a_set_cca_mode(struct device *dev, uint8_t mode)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t ctrl4;
ctrl4 = read_reg_phy_ctrl4(mcr20a);
ctrl4 &= ~MCR20A_PHY_CTRL4_CCATYPE_MASK;
ctrl4 |= set_bits_phy_ctrl4_ccatype(mode);
if (!write_reg_phy_ctrl4(mcr20a, ctrl4)) {
LOG_ERR("Failed");
return -EIO;
}
return 0;
}
static enum ieee802154_hw_caps mcr20a_get_capabilities(struct device *dev)
{
return IEEE802154_HW_FCS |
IEEE802154_HW_2_4_GHZ |
IEEE802154_HW_TX_RX_ACK |
IEEE802154_HW_FILTER;
}
/* Note: CCA before TX is enabled by default */
static int mcr20a_cca(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
int retval;
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
if (!mcr20a_mask_irqb(mcr20a, true)) {
LOG_ERR("Failed to mask IRQ_B");
goto error;
}
k_sem_init(&mcr20a->seq_sync, 0, 1);
if (mcr20a_abort_sequence(mcr20a, false)) {
LOG_ERR("Failed to reset XCV sequence");
goto error;
}
LOG_DBG("start CCA sequence");
if (mcr20a_set_sequence(mcr20a, MCR20A_XCVSEQ_CCA)) {
LOG_ERR("Failed to reset XCV sequence");
goto error;
}
if (!mcr20a_mask_irqb(mcr20a, false)) {
LOG_ERR("Failed to unmask IRQ_B");
goto error;
}
k_mutex_unlock(&mcr20a->phy_mutex);
retval = k_sem_take(&mcr20a->seq_sync,
K_MSEC(MCR20A_SEQ_SYNC_TIMEOUT));
if (retval) {
LOG_ERR("Timeout occurred, %d", retval);
return retval;
}
LOG_DBG("done");
return mcr20a->seq_retval;
error:
k_mutex_unlock(&mcr20a->phy_mutex);
return -EIO;
}
static int mcr20a_set_channel(struct device *dev, uint16_t channel)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t buf[3];
uint8_t ctrl1;
int retval = -EIO;
if (channel < 11 || channel > 26) {
LOG_ERR("Unsupported channel %u", channel);
return -EINVAL;
}
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
if (!mcr20a_mask_irqb(mcr20a, true)) {
LOG_ERR("Failed to mask IRQ_B");
goto out;
}
ctrl1 = read_reg_phy_ctrl1(mcr20a);
if (mcr20a_abort_sequence(mcr20a, true)) {
LOG_ERR("Failed to reset XCV sequence");
goto out;
}
LOG_DBG("%u", channel);
channel -= 11U;
buf[0] = set_bits_pll_int0_val(pll_int_lt[channel]);
buf[1] = (uint8_t)pll_frac_lt[channel];
buf[2] = (uint8_t)(pll_frac_lt[channel] >> 8);
if (!write_burst_pll_int0(mcr20a, buf)) {
LOG_ERR("Failed to set PLL");
goto out;
}
if (mcr20a_set_sequence(mcr20a, ctrl1)) {
LOG_ERR("Failed to restore XCV sequence");
goto out;
}
retval = 0;
out:
if (!mcr20a_mask_irqb(mcr20a, false)) {
LOG_ERR("Failed to unmask IRQ_B");
retval = -EIO;
}
k_mutex_unlock(&mcr20a->phy_mutex);
return retval;
}
static int mcr20a_set_pan_id(struct device *dev, uint16_t pan_id)
{
struct mcr20a_context *mcr20a = dev->driver_data;
pan_id = sys_le16_to_cpu(pan_id);
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
if (!write_burst_pan_id(mcr20a, (uint8_t *) &pan_id)) {
LOG_ERR("Failed");
k_mutex_unlock(&mcr20a->phy_mutex);
return -EIO;
}
k_mutex_unlock(&mcr20a->phy_mutex);
LOG_DBG("0x%x", pan_id);
return 0;
}
static int mcr20a_set_short_addr(struct device *dev, uint16_t short_addr)
{
struct mcr20a_context *mcr20a = dev->driver_data;
short_addr = sys_le16_to_cpu(short_addr);
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
if (!write_burst_short_addr(mcr20a, (uint8_t *) &short_addr)) {
LOG_ERR("Failed");
k_mutex_unlock(&mcr20a->phy_mutex);
return -EIO;
}
k_mutex_unlock(&mcr20a->phy_mutex);
LOG_DBG("0x%x", short_addr);
return 0;
}
static int mcr20a_set_ieee_addr(struct device *dev, const uint8_t *ieee_addr)
{
struct mcr20a_context *mcr20a = dev->driver_data;
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
if (!write_burst_ext_addr(mcr20a, (void *)ieee_addr)) {
LOG_ERR("Failed");
k_mutex_unlock(&mcr20a->phy_mutex);
return -EIO;
}
k_mutex_unlock(&mcr20a->phy_mutex);
LOG_DBG("IEEE address %02x:%02x:%02x:%02x:%02x:%02x:%02x:%02x",
ieee_addr[7], ieee_addr[6], ieee_addr[5], ieee_addr[4],
ieee_addr[3], ieee_addr[2], ieee_addr[1], ieee_addr[0]);
return 0;
}
static int mcr20a_filter(struct device *dev,
bool set,
enum ieee802154_filter_type type,
const struct ieee802154_filter *filter)
{
LOG_DBG("Applying filter %u", type);
if (!set) {
return -ENOTSUP;
}
if (type == IEEE802154_FILTER_TYPE_IEEE_ADDR) {
return mcr20a_set_ieee_addr(dev, filter->ieee_addr);
} else if (type == IEEE802154_FILTER_TYPE_SHORT_ADDR) {
return mcr20a_set_short_addr(dev, filter->short_addr);
} else if (type == IEEE802154_FILTER_TYPE_PAN_ID) {
return mcr20a_set_pan_id(dev, filter->pan_id);
}
return -ENOTSUP;
}
static int mcr20a_set_txpower(struct device *dev, int16_t dbm)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t pwr;
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
LOG_DBG("%d", dbm);
if ((dbm > MCR20A_OUTPUT_POWER_MAX) ||
(dbm < MCR20A_OUTPUT_POWER_MIN)) {
goto error;
}
pwr = pow_lt[dbm - MCR20A_OUTPUT_POWER_MIN];
if (!write_reg_pa_pwr(mcr20a, set_bits_pa_pwr_val(pwr))) {
goto error;
}
k_mutex_unlock(&mcr20a->phy_mutex);
return 0;
error:
k_mutex_unlock(&mcr20a->phy_mutex);
LOG_DBG("Failed");
return -EIO;
}
static inline bool write_txfifo_content(struct mcr20a_context *dev,
struct net_pkt *pkt,
struct net_buf *frag)
{
size_t payload_len = frag->len;
uint8_t cmd_buf[2] = {
MCR20A_BUF_WRITE,
payload_len + MCR20A_FCS_LENGTH
};
const struct spi_buf bufs[2] = {
{
.buf = cmd_buf,
.len = 2
},
{
.buf = frag->data,
.len = payload_len
}
};
const struct spi_buf_set tx = {
.buffers = bufs,
.count = 2
};
if (payload_len > MCR20A_PSDU_LENGTH) {
LOG_ERR("Payload too long");
return 0;
}
return (spi_write(dev->spi, &dev->spi_cfg, &tx) == 0);
}
static int mcr20a_tx(struct device *dev,
enum ieee802154_tx_mode mode,
struct net_pkt *pkt,
struct net_buf *frag)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t seq = ieee802154_is_ar_flag_set(frag) ? MCR20A_XCVSEQ_TX_RX :
MCR20A_XCVSEQ_TX;
int retval;
if (mode != IEEE802154_TX_MODE_DIRECT) {
NET_ERR("TX mode %d not supported", mode);
return -ENOTSUP;
}
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
LOG_DBG("%p (%u)", frag, frag->len);
if (!mcr20a_mask_irqb(mcr20a, true)) {
LOG_ERR("Failed to mask IRQ_B");
goto error;
}
if (mcr20a_abort_sequence(mcr20a, false)) {
LOG_ERR("Failed to reset XCV sequence");
goto error;
}
if (!write_txfifo_content(mcr20a, pkt, frag)) {
LOG_ERR("Did not write properly into TX FIFO");
goto error;
}
k_sem_init(&mcr20a->seq_sync, 0, 1);
if (mcr20a_set_sequence(mcr20a, seq)) {
LOG_ERR("Cannot start transmission");
goto error;
}
if (!mcr20a_mask_irqb(mcr20a, false)) {
LOG_ERR("Failed to unmask IRQ_B");
goto error;
}
k_mutex_unlock(&mcr20a->phy_mutex);
retval = k_sem_take(&mcr20a->seq_sync,
K_MSEC(MCR20A_SEQ_SYNC_TIMEOUT));
if (retval) {
LOG_ERR("Timeout occurred, %d", retval);
return retval;
}
LOG_DBG("done");
return mcr20a->seq_retval;
error:
k_mutex_unlock(&mcr20a->phy_mutex);
return -EIO;
}
static int mcr20a_start(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t timeout = 6U;
uint8_t status;
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
enable_irqb_interrupt(mcr20a, false);
if (!write_reg_pwr_modes(mcr20a, MCR20A_PM_AUTODOZE)) {
LOG_ERR("Error starting MCR20A");
goto error;
}
do {
z_usleep(50);
timeout--;
status = read_reg_pwr_modes(mcr20a);
} while (!(status & MCR20A_PWR_MODES_XTAL_READY) && timeout);
if (!(status & MCR20A_PWR_MODES_XTAL_READY)) {
LOG_ERR("Timeout, failed to wake up");
goto error;
}
/* Clear all interrupt flags */
write_reg_irqsts1(mcr20a, MCR20A_IRQSTS1_IRQ_MASK);
write_reg_irqsts2(mcr20a, MCR20A_IRQSTS2_IRQ_MASK);
write_reg_irqsts3(mcr20a, MCR20A_IRQSTS3_IRQ_MASK |
MCR20A_IRQSTS3_TMR_MASK);
if (mcr20a_abort_sequence(mcr20a, true)) {
LOG_ERR("Failed to reset XCV sequence");
goto error;
}
if (mcr20a_set_sequence(mcr20a, MCR20A_XCVSEQ_RECEIVE)) {
LOG_ERR("Failed to set XCV sequence");
goto error;
}
enable_irqb_interrupt(mcr20a, true);
if (!mcr20a_mask_irqb(mcr20a, false)) {
LOG_ERR("Failed to unmask IRQ_B");
goto error;
}
k_mutex_unlock(&mcr20a->phy_mutex);
LOG_DBG("started");
return 0;
error:
k_mutex_unlock(&mcr20a->phy_mutex);
return -EIO;
}
static int mcr20a_stop(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t power_mode;
k_mutex_lock(&mcr20a->phy_mutex, K_FOREVER);
if (!mcr20a_mask_irqb(mcr20a, true)) {
LOG_ERR("Failed to mask IRQ_B");
goto error;
}
if (mcr20a_abort_sequence(mcr20a, true)) {
LOG_ERR("Failed to reset XCV sequence");
goto error;
}
enable_irqb_interrupt(mcr20a, false);
if (PART_OF_KW2XD_SIP) {
power_mode = MCR20A_PM_DOZE;
} else {
power_mode = MCR20A_PM_HIBERNATE;
}
if (!write_reg_pwr_modes(mcr20a, power_mode)) {
goto error;
}
LOG_DBG("stopped");
k_mutex_unlock(&mcr20a->phy_mutex);
return 0;
error:
k_mutex_unlock(&mcr20a->phy_mutex);
LOG_ERR("Error stopping MCR20A");
return -EIO;
}
static int mcr20a_update_overwrites(struct mcr20a_context *dev)
{
if (!write_reg_overwrite_ver(dev, overwrites_direct[0].data)) {
goto error;
}
for (uint8_t i = 0;
i < sizeof(overwrites_indirect) / sizeof(overwrites_t);
i++) {
if (!z_mcr20a_write_reg(dev, false,
overwrites_indirect[i].address,
overwrites_indirect[i].data)) {
goto error;
}
}
return 0;
error:
LOG_ERR("Error update overwrites");
return -EIO;
}
static int power_on_and_setup(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t timeout = 6U;
int pin;
uint8_t tmp = 0U;
if (!PART_OF_KW2XD_SIP) {
gpio_pin_set(mcr20a->reset_gpio,
DT_INST_GPIO_PIN(0, reset_gpios), 1);
z_usleep(150);
gpio_pin_set(mcr20a->reset_gpio,
DT_INST_GPIO_PIN(0, reset_gpios), 0);
do {
z_usleep(50);
timeout--;
pin = gpio_pin_get(mcr20a->irq_gpio,
DT_INST_GPIO_PIN(0, irqb_gpios));
} while (pin > 0 && timeout);
if (pin) {
LOG_ERR("Timeout, failed to get WAKE IRQ");
return -EIO;
}
}
tmp = MCR20A_CLK_OUT_CONFIG | MCR20A_CLK_OUT_EXTEND;
write_reg_clk_out_ctrl(mcr20a, tmp);
if (read_reg_clk_out_ctrl(mcr20a) != tmp) {
LOG_ERR("Failed to get device up");
return -EIO;
}
/* Clear all interrupt flags */
write_reg_irqsts1(mcr20a, MCR20A_IRQSTS1_IRQ_MASK);
write_reg_irqsts2(mcr20a, MCR20A_IRQSTS2_IRQ_MASK);
write_reg_irqsts3(mcr20a, MCR20A_IRQSTS3_IRQ_MASK |
MCR20A_IRQSTS3_TMR_MASK);
mcr20a_update_overwrites(mcr20a);
mcr20a_timer_init(dev, MCR20A_TIMEBASE_62500HZ);
mcr20a_set_txpower(dev, MCR20A_DEFAULT_TX_POWER);
mcr20a_set_channel(dev, MCR20A_DEFAULT_CHANNEL);
mcr20a_set_cca_mode(dev, 1);
write_reg_rx_wtr_mark(mcr20a, 8);
/* Configure PHY behaviour */
tmp = MCR20A_PHY_CTRL1_CCABFRTX |
MCR20A_PHY_CTRL1_AUTOACK |
MCR20A_PHY_CTRL1_RXACKRQD;
write_reg_phy_ctrl1(mcr20a, tmp);
/* Enable Sequence-end interrupt */
tmp = MCR20A_PHY_CTRL2_SEQMSK;
write_reg_phy_ctrl2(mcr20a, ~tmp);
setup_gpio_callbacks(mcr20a);
return 0;
}
static inline int configure_gpios(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
/* setup gpio for the modem interrupt */
mcr20a->irq_gpio =
device_get_binding(DT_INST_GPIO_LABEL(0, irqb_gpios));
if (mcr20a->irq_gpio == NULL) {
LOG_ERR("Failed to get pointer to %s device",
DT_INST_GPIO_LABEL(0, irqb_gpios));
return -EINVAL;
}
gpio_pin_configure(mcr20a->irq_gpio,
DT_INST_GPIO_PIN(0, irqb_gpios),
GPIO_INPUT | DT_INST_GPIO_FLAGS(0, irqb_gpios));
if (!PART_OF_KW2XD_SIP) {
/* setup gpio for the modems reset */
mcr20a->reset_gpio =
device_get_binding(
DT_INST_GPIO_LABEL(0, reset_gpios));
if (mcr20a->reset_gpio == NULL) {
LOG_ERR("Failed to get pointer to %s device",
DT_INST_GPIO_LABEL(0, reset_gpios));
return -EINVAL;
}
gpio_pin_configure(mcr20a->reset_gpio,
DT_INST_GPIO_PIN(0, reset_gpios),
GPIO_OUTPUT_ACTIVE |
DT_INST_GPIO_FLAGS(0, reset_gpios));
}
return 0;
}
static inline int configure_spi(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
mcr20a->spi = device_get_binding(DT_INST_BUS_LABEL(0));
if (!mcr20a->spi) {
LOG_ERR("Unable to get SPI device");
return -ENODEV;
}
#if DT_INST_SPI_DEV_HAS_CS_GPIOS(0)
mcr20a->cs_ctrl.gpio_dev = device_get_binding(
DT_INST_SPI_DEV_CS_GPIOS_LABEL(0));
if (!mcr20a->cs_ctrl.gpio_dev) {
LOG_ERR("Unable to get GPIO SPI CS device");
return -ENODEV;
}
mcr20a->cs_ctrl.gpio_pin = DT_INST_SPI_DEV_CS_GPIOS_PIN(0);
mcr20a->cs_ctrl.gpio_flags = DT_INST_SPI_DEV_CS_GPIOS_FLAGS(0);
mcr20a->cs_ctrl.delay = 0U;
mcr20a->spi_cfg.cs = &mcr20a->cs_ctrl;
LOG_DBG("SPI GPIO CS configured on %s:%u",
DT_INST_SPI_DEV_CS_GPIOS_LABEL(0),
DT_INST_SPI_DEV_CS_GPIOS_PIN(0));
#endif /* DT_INST_SPI_DEV_HAS_CS_GPIOS(0) */
mcr20a->spi_cfg.frequency = DT_INST_PROP(0, spi_max_frequency);
mcr20a->spi_cfg.operation = SPI_WORD_SET(8);
mcr20a->spi_cfg.slave = DT_INST_REG_ADDR(0);
LOG_DBG("SPI configured %s, %d",
DT_INST_BUS_LABEL(0),
DT_INST_REG_ADDR(0));
return 0;
}
static int mcr20a_init(struct device *dev)
{
struct mcr20a_context *mcr20a = dev->driver_data;
k_mutex_init(&mcr20a->phy_mutex);
k_sem_init(&mcr20a->isr_sem, 0, 1);
LOG_DBG("\nInitialize MCR20A Transceiver\n");
if (configure_gpios(dev) != 0) {
LOG_ERR("Configuring GPIOS failed");
return -EIO;
}
if (configure_spi(dev) != 0) {
LOG_ERR("Configuring SPI failed");
return -EIO;
}
LOG_DBG("GPIO and SPI configured");
if (power_on_and_setup(dev) != 0) {
LOG_ERR("Configuring MCR20A failed");
return -EIO;
}
k_thread_create(&mcr20a->mcr20a_rx_thread, mcr20a->mcr20a_rx_stack,
CONFIG_IEEE802154_MCR20A_RX_STACK_SIZE,
(k_thread_entry_t)mcr20a_thread_main,
dev, NULL, NULL, K_PRIO_COOP(2), 0, K_NO_WAIT);
k_thread_name_set(&mcr20a->mcr20a_rx_thread, "mcr20a_rx");
return 0;
}
static void mcr20a_iface_init(struct net_if *iface)
{
struct device *dev = net_if_get_device(iface);
struct mcr20a_context *mcr20a = dev->driver_data;
uint8_t *mac = get_mac(dev);
net_if_set_link_addr(iface, mac, 8, NET_LINK_IEEE802154);
mcr20a->iface = iface;
ieee802154_init(iface);
LOG_DBG("done");
}
static struct mcr20a_context mcr20a_context_data;
static struct ieee802154_radio_api mcr20a_radio_api = {
.iface_api.init = mcr20a_iface_init,
.get_capabilities = mcr20a_get_capabilities,
.cca = mcr20a_cca,
.set_channel = mcr20a_set_channel,
.filter = mcr20a_filter,
.set_txpower = mcr20a_set_txpower,
.start = mcr20a_start,
.stop = mcr20a_stop,
.tx = mcr20a_tx,
};
#if defined(CONFIG_IEEE802154_RAW_MODE)
DEVICE_AND_API_INIT(mcr20a, CONFIG_IEEE802154_MCR20A_DRV_NAME,
mcr20a_init, &mcr20a_context_data, NULL,
POST_KERNEL, CONFIG_IEEE802154_MCR20A_INIT_PRIO,
&mcr20a_radio_api);
#else
NET_DEVICE_INIT(mcr20a, CONFIG_IEEE802154_MCR20A_DRV_NAME,
mcr20a_init, device_pm_control_nop, &mcr20a_context_data, NULL,
CONFIG_IEEE802154_MCR20A_INIT_PRIO,
&mcr20a_radio_api, IEEE802154_L2,
NET_L2_GET_CTX_TYPE(IEEE802154_L2),
MCR20A_PSDU_LENGTH);
#endif
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