linux-stable/drivers/net/ieee802154/mrf24j40.c

// SPDX-License-Identifier: GPL-2.0-or-later
/*
 * Driver for Microchip MRF24J40 802.15.4 Wireless-PAN Networking controller
 *
 * Copyright (C) 2012 Alan Ott <alan@signal11.us>
 *                    Signal 11 Software
 */

#include <linux/spi/spi.h>
#include <linux/interrupt.h>
#include <linux/mod_devicetable.h>
#include <linux/module.h>
#include <linux/regmap.h>
#include <linux/ieee802154.h>
#include <linux/irq.h>
#include <net/cfg802154.h>
#include <net/mac802154.h>

/* MRF24J40 Short Address Registers */
#define REG_RXMCR	0x00  /* Receive MAC control */
#define BIT_PROMI	BIT(0)
#define BIT_ERRPKT	BIT(1)
#define BIT_NOACKRSP	BIT(5)
#define BIT_PANCOORD	BIT(3)

#define REG_PANIDL	0x01  /* PAN ID (low) */
#define REG_PANIDH	0x02  /* PAN ID (high) */
#define REG_SADRL	0x03  /* Short address (low) */
#define REG_SADRH	0x04  /* Short address (high) */
#define REG_EADR0	0x05  /* Long address (low) (high is EADR7) */
#define REG_EADR1	0x06
#define REG_EADR2	0x07
#define REG_EADR3	0x08
#define REG_EADR4	0x09
#define REG_EADR5	0x0A
#define REG_EADR6	0x0B
#define REG_EADR7	0x0C
#define REG_RXFLUSH	0x0D
#define REG_ORDER	0x10
#define REG_TXMCR	0x11  /* Transmit MAC control */
#define TXMCR_MIN_BE_SHIFT		3
#define TXMCR_MIN_BE_MASK		0x18
#define TXMCR_CSMA_RETRIES_SHIFT	0
#define TXMCR_CSMA_RETRIES_MASK		0x07

#define REG_ACKTMOUT	0x12
#define REG_ESLOTG1	0x13
#define REG_SYMTICKL	0x14
#define REG_SYMTICKH	0x15
#define REG_PACON0	0x16  /* Power Amplifier Control */
#define REG_PACON1	0x17  /* Power Amplifier Control */
#define REG_PACON2	0x18  /* Power Amplifier Control */
#define REG_TXBCON0	0x1A
#define REG_TXNCON	0x1B  /* Transmit Normal FIFO Control */
#define BIT_TXNTRIG	BIT(0)
#define BIT_TXNSECEN	BIT(1)
#define BIT_TXNACKREQ	BIT(2)

#define REG_TXG1CON	0x1C
#define REG_TXG2CON	0x1D
#define REG_ESLOTG23	0x1E
#define REG_ESLOTG45	0x1F
#define REG_ESLOTG67	0x20
#define REG_TXPEND	0x21
#define REG_WAKECON	0x22
#define REG_FROMOFFSET	0x23
#define REG_TXSTAT	0x24  /* TX MAC Status Register */
#define REG_TXBCON1	0x25
#define REG_GATECLK	0x26
#define REG_TXTIME	0x27
#define REG_HSYMTMRL	0x28
#define REG_HSYMTMRH	0x29
#define REG_SOFTRST	0x2A  /* Soft Reset */
#define REG_SECCON0	0x2C
#define REG_SECCON1	0x2D
#define REG_TXSTBL	0x2E  /* TX Stabilization */
#define REG_RXSR	0x30
#define REG_INTSTAT	0x31  /* Interrupt Status */
#define BIT_TXNIF	BIT(0)
#define BIT_RXIF	BIT(3)
#define BIT_SECIF	BIT(4)
#define BIT_SECIGNORE	BIT(7)

#define REG_INTCON	0x32  /* Interrupt Control */
#define BIT_TXNIE	BIT(0)
#define BIT_RXIE	BIT(3)
#define BIT_SECIE	BIT(4)

#define REG_GPIO	0x33  /* GPIO */
#define REG_TRISGPIO	0x34  /* GPIO direction */
#define REG_SLPACK	0x35
#define REG_RFCTL	0x36  /* RF Control Mode Register */
#define BIT_RFRST	BIT(2)

#define REG_SECCR2	0x37
#define REG_BBREG0	0x38
#define REG_BBREG1	0x39  /* Baseband Registers */
#define BIT_RXDECINV	BIT(2)

#define REG_BBREG2	0x3A  /* */
#define BBREG2_CCA_MODE_SHIFT	6
#define BBREG2_CCA_MODE_MASK	0xc0

#define REG_BBREG3	0x3B
#define REG_BBREG4	0x3C
#define REG_BBREG6	0x3E  /* */
#define REG_CCAEDTH	0x3F  /* Energy Detection Threshold */

/* MRF24J40 Long Address Registers */
#define REG_RFCON0	0x200  /* RF Control Registers */
#define RFCON0_CH_SHIFT	4
#define RFCON0_CH_MASK	0xf0
#define RFOPT_RECOMMEND	3

#define REG_RFCON1	0x201
#define REG_RFCON2	0x202
#define REG_RFCON3	0x203

#define TXPWRL_MASK	0xc0
#define TXPWRL_SHIFT	6
#define TXPWRL_30	0x3
#define TXPWRL_20	0x2
#define TXPWRL_10	0x1
#define TXPWRL_0	0x0

#define TXPWRS_MASK	0x38
#define TXPWRS_SHIFT	3
#define TXPWRS_6_3	0x7
#define TXPWRS_4_9	0x6
#define TXPWRS_3_7	0x5
#define TXPWRS_2_8	0x4
#define TXPWRS_1_9	0x3
#define TXPWRS_1_2	0x2
#define TXPWRS_0_5	0x1
#define TXPWRS_0	0x0

#define REG_RFCON5	0x205
#define REG_RFCON6	0x206
#define REG_RFCON7	0x207
#define REG_RFCON8	0x208
#define REG_SLPCAL0	0x209
#define REG_SLPCAL1	0x20A
#define REG_SLPCAL2	0x20B
#define REG_RFSTATE	0x20F
#define REG_RSSI	0x210
#define REG_SLPCON0	0x211  /* Sleep Clock Control Registers */
#define BIT_INTEDGE	BIT(1)

#define REG_SLPCON1	0x220
#define REG_WAKETIMEL	0x222  /* Wake-up Time Match Value Low */
#define REG_WAKETIMEH	0x223  /* Wake-up Time Match Value High */
#define REG_REMCNTL	0x224
#define REG_REMCNTH	0x225
#define REG_MAINCNT0	0x226
#define REG_MAINCNT1	0x227
#define REG_MAINCNT2	0x228
#define REG_MAINCNT3	0x229
#define REG_TESTMODE	0x22F  /* Test mode */
#define REG_ASSOEAR0	0x230
#define REG_ASSOEAR1	0x231
#define REG_ASSOEAR2	0x232
#define REG_ASSOEAR3	0x233
#define REG_ASSOEAR4	0x234
#define REG_ASSOEAR5	0x235
#define REG_ASSOEAR6	0x236
#define REG_ASSOEAR7	0x237
#define REG_ASSOSAR0	0x238
#define REG_ASSOSAR1	0x239
#define REG_UNONCE0	0x240
#define REG_UNONCE1	0x241
#define REG_UNONCE2	0x242
#define REG_UNONCE3	0x243
#define REG_UNONCE4	0x244
#define REG_UNONCE5	0x245
#define REG_UNONCE6	0x246
#define REG_UNONCE7	0x247
#define REG_UNONCE8	0x248
#define REG_UNONCE9	0x249
#define REG_UNONCE10	0x24A
#define REG_UNONCE11	0x24B
#define REG_UNONCE12	0x24C
#define REG_RX_FIFO	0x300  /* Receive FIFO */

/* Device configuration: Only channels 11-26 on page 0 are supported. */
#define MRF24J40_CHAN_MIN 11
#define MRF24J40_CHAN_MAX 26
#define CHANNEL_MASK (((u32)1 << (MRF24J40_CHAN_MAX + 1)) \
		      - ((u32)1 << MRF24J40_CHAN_MIN))

#define TX_FIFO_SIZE 128 /* From datasheet */
#define RX_FIFO_SIZE 144 /* From datasheet */
#define SET_CHANNEL_DELAY_US 192 /* From datasheet */

enum mrf24j40_modules { MRF24J40, MRF24J40MA, MRF24J40MC };

/* Device Private Data */
struct mrf24j40 {
	struct spi_device *spi;
	struct ieee802154_hw *hw;

	struct regmap *regmap_short;
	struct regmap *regmap_long;

	/* for writing txfifo */
	struct spi_message tx_msg;
	u8 tx_hdr_buf[2];
	struct spi_transfer tx_hdr_trx;
	u8 tx_len_buf[2];
	struct spi_transfer tx_len_trx;
	struct spi_transfer tx_buf_trx;
	struct sk_buff *tx_skb;

	/* post transmit message to send frame out  */
	struct spi_message tx_post_msg;
	u8 tx_post_buf[2];
	struct spi_transfer tx_post_trx;

	/* for protect/unprotect/read length rxfifo */
	struct spi_message rx_msg;
	u8 rx_buf[3];
	struct spi_transfer rx_trx;

	/* receive handling */
	struct spi_message rx_buf_msg;
	u8 rx_addr_buf[2];
	struct spi_transfer rx_addr_trx;
	u8 rx_lqi_buf[2];
	struct spi_transfer rx_lqi_trx;
	u8 rx_fifo_buf[RX_FIFO_SIZE];
	struct spi_transfer rx_fifo_buf_trx;

	/* isr handling for reading intstat */
	struct spi_message irq_msg;
	u8 irq_buf[2];
	struct spi_transfer irq_trx;
};

/* regmap information for short address register access */
#define MRF24J40_SHORT_WRITE	0x01
#define MRF24J40_SHORT_READ	0x00
#define MRF24J40_SHORT_NUMREGS	0x3F

/* regmap information for long address register access */
#define MRF24J40_LONG_ACCESS	0x80
#define MRF24J40_LONG_NUMREGS	0x38F

/* Read/Write SPI Commands for Short and Long Address registers. */
#define MRF24J40_READSHORT(reg) ((reg) << 1)
#define MRF24J40_WRITESHORT(reg) ((reg) << 1 | 1)
#define MRF24J40_READLONG(reg) (1 << 15 | (reg) << 5)
#define MRF24J40_WRITELONG(reg) (1 << 15 | (reg) << 5 | 1 << 4)

/* The datasheet indicates the theoretical maximum for SCK to be 10MHz */
#define MAX_SPI_SPEED_HZ 10000000

#define printdev(X) (&X->spi->dev)

static bool
mrf24j40_short_reg_writeable(struct device *dev, unsigned int reg)
{
	switch (reg) {
	case REG_RXMCR:
	case REG_PANIDL:
	case REG_PANIDH:
	case REG_SADRL:
	case REG_SADRH:
	case REG_EADR0:
	case REG_EADR1:
	case REG_EADR2:
	case REG_EADR3:
	case REG_EADR4:
	case REG_EADR5:
	case REG_EADR6:
	case REG_EADR7:
	case REG_RXFLUSH:
	case REG_ORDER:
	case REG_TXMCR:
	case REG_ACKTMOUT:
	case REG_ESLOTG1:
	case REG_SYMTICKL:
	case REG_SYMTICKH:
	case REG_PACON0:
	case REG_PACON1:
	case REG_PACON2:
	case REG_TXBCON0:
	case REG_TXNCON:
	case REG_TXG1CON:
	case REG_TXG2CON:
	case REG_ESLOTG23:
	case REG_ESLOTG45:
	case REG_ESLOTG67:
	case REG_TXPEND:
	case REG_WAKECON:
	case REG_FROMOFFSET:
	case REG_TXBCON1:
	case REG_GATECLK:
	case REG_TXTIME:
	case REG_HSYMTMRL:
	case REG_HSYMTMRH:
	case REG_SOFTRST:
	case REG_SECCON0:
	case REG_SECCON1:
	case REG_TXSTBL:
	case REG_RXSR:
	case REG_INTCON:
	case REG_TRISGPIO:
	case REG_GPIO:
	case REG_RFCTL:
	case REG_SECCR2:
	case REG_SLPACK:
	case REG_BBREG0:
	case REG_BBREG1:
	case REG_BBREG2:
	case REG_BBREG3:
	case REG_BBREG4:
	case REG_BBREG6:
	case REG_CCAEDTH:
		return true;
	default:
		return false;
	}
}

static bool
mrf24j40_short_reg_readable(struct device *dev, unsigned int reg)
{
	bool rc;

	/* all writeable are also readable */
	rc = mrf24j40_short_reg_writeable(dev, reg);
	if (rc)
		return rc;

	/* readonly regs */
	switch (reg) {
	case REG_TXSTAT:
	case REG_INTSTAT:
		return true;
	default:
		return false;
	}
}

static bool
mrf24j40_short_reg_volatile(struct device *dev, unsigned int reg)
{
	/* can be changed during runtime */
	switch (reg) {
	case REG_TXSTAT:
	case REG_INTSTAT:
	case REG_RXFLUSH:
	case REG_TXNCON:
	case REG_SOFTRST:
	case REG_RFCTL:
	case REG_TXBCON0:
	case REG_TXG1CON:
	case REG_TXG2CON:
	case REG_TXBCON1:
	case REG_SECCON0:
	case REG_RXSR:
	case REG_SLPACK:
	case REG_SECCR2:
	case REG_BBREG6:
	/* use them in spi_async and regmap so it's volatile */
	case REG_BBREG1:
		return true;
	default:
		return false;
	}
}

static bool
mrf24j40_short_reg_precious(struct device *dev, unsigned int reg)
{
	/* don't clear irq line on read */
	switch (reg) {
	case REG_INTSTAT:
		return true;
	default:
		return false;
	}
}

static const struct regmap_config mrf24j40_short_regmap = {
	.name = "mrf24j40_short",
	.reg_bits = 7,
	.val_bits = 8,
	.pad_bits = 1,
	.write_flag_mask = MRF24J40_SHORT_WRITE,
	.read_flag_mask = MRF24J40_SHORT_READ,
	.cache_type = REGCACHE_MAPLE,
	.max_register = MRF24J40_SHORT_NUMREGS,
	.writeable_reg = mrf24j40_short_reg_writeable,
	.readable_reg = mrf24j40_short_reg_readable,
	.volatile_reg = mrf24j40_short_reg_volatile,
	.precious_reg = mrf24j40_short_reg_precious,
};

static bool
mrf24j40_long_reg_writeable(struct device *dev, unsigned int reg)
{
	switch (reg) {
	case REG_RFCON0:
	case REG_RFCON1:
	case REG_RFCON2:
	case REG_RFCON3:
	case REG_RFCON5:
	case REG_RFCON6:
	case REG_RFCON7:
	case REG_RFCON8:
	case REG_SLPCAL2:
	case REG_SLPCON0:
	case REG_SLPCON1:
	case REG_WAKETIMEL:
	case REG_WAKETIMEH:
	case REG_REMCNTL:
	case REG_REMCNTH:
	case REG_MAINCNT0:
	case REG_MAINCNT1:
	case REG_MAINCNT2:
	case REG_MAINCNT3:
	case REG_TESTMODE:
	case REG_ASSOEAR0:
	case REG_ASSOEAR1:
	case REG_ASSOEAR2:
	case REG_ASSOEAR3:
	case REG_ASSOEAR4:
	case REG_ASSOEAR5:
	case REG_ASSOEAR6:
	case REG_ASSOEAR7:
	case REG_ASSOSAR0:
	case REG_ASSOSAR1:
	case REG_UNONCE0:
	case REG_UNONCE1:
	case REG_UNONCE2:
	case REG_UNONCE3:
	case REG_UNONCE4:
	case REG_UNONCE5:
	case REG_UNONCE6:
	case REG_UNONCE7:
	case REG_UNONCE8:
	case REG_UNONCE9:
	case REG_UNONCE10:
	case REG_UNONCE11:
	case REG_UNONCE12:
		return true;
	default:
		return false;
	}
}

static bool
mrf24j40_long_reg_readable(struct device *dev, unsigned int reg)
{
	bool rc;

	/* all writeable are also readable */
	rc = mrf24j40_long_reg_writeable(dev, reg);
	if (rc)
		return rc;

	/* readonly regs */
	switch (reg) {
	case REG_SLPCAL0:
	case REG_SLPCAL1:
	case REG_RFSTATE:
	case REG_RSSI:
		return true;
	default:
		return false;
	}
}

static bool
mrf24j40_long_reg_volatile(struct device *dev, unsigned int reg)
{
	/* can be changed during runtime */
	switch (reg) {
	case REG_SLPCAL0:
	case REG_SLPCAL1:
	case REG_SLPCAL2:
	case REG_RFSTATE:
	case REG_RSSI:
	case REG_MAINCNT3:
		return true;
	default:
		return false;
	}
}

static const struct regmap_config mrf24j40_long_regmap = {
	.name = "mrf24j40_long",
	.reg_bits = 11,
	.val_bits = 8,
	.pad_bits = 5,
	.write_flag_mask = MRF24J40_LONG_ACCESS,
	.read_flag_mask = MRF24J40_LONG_ACCESS,
	.cache_type = REGCACHE_MAPLE,
	.max_register = MRF24J40_LONG_NUMREGS,
	.writeable_reg = mrf24j40_long_reg_writeable,
	.readable_reg = mrf24j40_long_reg_readable,
	.volatile_reg = mrf24j40_long_reg_volatile,
};

static int mrf24j40_long_regmap_write(void *context, const void *data,
				      size_t count)
{
	struct spi_device *spi = context;
	u8 buf[3];

	if (count > 3)
		return -EINVAL;

	/* regmap supports read/write mask only in frist byte
	 * long write access need to set the 12th bit, so we
	 * make special handling for write.
	 */
	memcpy(buf, data, count);
	buf[1] |= (1 << 4);

	return spi_write(spi, buf, count);
}

static int
mrf24j40_long_regmap_read(void *context, const void *reg, size_t reg_size,
			  void *val, size_t val_size)
{
	struct spi_device *spi = context;

	return spi_write_then_read(spi, reg, reg_size, val, val_size);
}

static const struct regmap_bus mrf24j40_long_regmap_bus = {
	.write = mrf24j40_long_regmap_write,
	.read = mrf24j40_long_regmap_read,
	.reg_format_endian_default = REGMAP_ENDIAN_BIG,
	.val_format_endian_default = REGMAP_ENDIAN_BIG,
};

static void write_tx_buf_complete(void *context)
{
	struct mrf24j40 *devrec = context;
	__le16 fc = ieee802154_get_fc_from_skb(devrec->tx_skb);
	u8 val = BIT_TXNTRIG;
	int ret;

	if (ieee802154_is_secen(fc))
		val |= BIT_TXNSECEN;

	if (ieee802154_is_ackreq(fc))
		val |= BIT_TXNACKREQ;

	devrec->tx_post_msg.complete = NULL;
	devrec->tx_post_buf[0] = MRF24J40_WRITESHORT(REG_TXNCON);
	devrec->tx_post_buf[1] = val;

	ret = spi_async(devrec->spi, &devrec->tx_post_msg);
	if (ret)
		dev_err(printdev(devrec), "SPI write Failed for transmit buf\n");
}

/* This function relies on an undocumented write method. Once a write command
   and address is set, as many bytes of data as desired can be clocked into
   the device. The datasheet only shows setting one byte at a time. */
static int write_tx_buf(struct mrf24j40 *devrec, u16 reg,
			const u8 *data, size_t length)
{
	u16 cmd;
	int ret;

	/* Range check the length. 2 bytes are used for the length fields.*/
	if (length > TX_FIFO_SIZE-2) {
		dev_err(printdev(devrec), "write_tx_buf() was passed too large a buffer. Performing short write.\n");
		length = TX_FIFO_SIZE-2;
	}

	cmd = MRF24J40_WRITELONG(reg);
	devrec->tx_hdr_buf[0] = cmd >> 8 & 0xff;
	devrec->tx_hdr_buf[1] = cmd & 0xff;
	devrec->tx_len_buf[0] = 0x0; /* Header Length. Set to 0 for now. TODO */
	devrec->tx_len_buf[1] = length; /* Total length */
	devrec->tx_buf_trx.tx_buf = data;
	devrec->tx_buf_trx.len = length;

	ret = spi_async(devrec->spi, &devrec->tx_msg);
	if (ret)
		dev_err(printdev(devrec), "SPI write Failed for TX buf\n");

	return ret;
}

static int mrf24j40_tx(struct ieee802154_hw *hw, struct sk_buff *skb)
{
	struct mrf24j40 *devrec = hw->priv;

	dev_dbg(printdev(devrec), "tx packet of %d bytes\n", skb->len);
	devrec->tx_skb = skb;

	return write_tx_buf(devrec, 0x000, skb->data, skb->len);
}

static int mrf24j40_ed(struct ieee802154_hw *hw, u8 *level)
{
	/* TODO: */
	pr_warn("mrf24j40: ed not implemented\n");
	*level = 0;
	return 0;
}

static int mrf24j40_start(struct ieee802154_hw *hw)
{
	struct mrf24j40 *devrec = hw->priv;

	dev_dbg(printdev(devrec), "start\n");

	/* Clear TXNIE and RXIE. Enable interrupts */
	return regmap_update_bits(devrec->regmap_short, REG_INTCON,
				  BIT_TXNIE | BIT_RXIE | BIT_SECIE, 0);
}

static void mrf24j40_stop(struct ieee802154_hw *hw)
{
	struct mrf24j40 *devrec = hw->priv;

	dev_dbg(printdev(devrec), "stop\n");

	/* Set TXNIE and RXIE. Disable Interrupts */
	regmap_update_bits(devrec->regmap_short, REG_INTCON,
			   BIT_TXNIE | BIT_RXIE, BIT_TXNIE | BIT_RXIE);
}

static int mrf24j40_set_channel(struct ieee802154_hw *hw, u8 page, u8 channel)
{
	struct mrf24j40 *devrec = hw->priv;
	u8 val;
	int ret;

	dev_dbg(printdev(devrec), "Set Channel %d\n", channel);

	WARN_ON(page != 0);
	WARN_ON(channel < MRF24J40_CHAN_MIN);
	WARN_ON(channel > MRF24J40_CHAN_MAX);

	/* Set Channel TODO */
	val = (channel - 11) << RFCON0_CH_SHIFT | RFOPT_RECOMMEND;
	ret = regmap_update_bits(devrec->regmap_long, REG_RFCON0,
				 RFCON0_CH_MASK, val);
	if (ret)
		return ret;

	/* RF Reset */
	ret = regmap_update_bits(devrec->regmap_short, REG_RFCTL, BIT_RFRST,
				 BIT_RFRST);
	if (ret)
		return ret;

	ret = regmap_update_bits(devrec->regmap_short, REG_RFCTL, BIT_RFRST, 0);
	if (!ret)
		udelay(SET_CHANNEL_DELAY_US); /* per datasheet */

	return ret;
}

static int mrf24j40_filter(struct ieee802154_hw *hw,
			   struct ieee802154_hw_addr_filt *filt,
			   unsigned long changed)
{
	struct mrf24j40 *devrec = hw->priv;

	dev_dbg(printdev(devrec), "filter\n");

	if (changed & IEEE802154_AFILT_SADDR_CHANGED) {
		/* Short Addr */
		u8 addrh, addrl;

		addrh = le16_to_cpu(filt->short_addr) >> 8 & 0xff;
		addrl = le16_to_cpu(filt->short_addr) & 0xff;

		regmap_write(devrec->regmap_short, REG_SADRH, addrh);
		regmap_write(devrec->regmap_short, REG_SADRL, addrl);
		dev_dbg(printdev(devrec),
			"Set short addr to %04hx\n", filt->short_addr);
	}

	if (changed & IEEE802154_AFILT_IEEEADDR_CHANGED) {
		/* Device Address */
		u8 i, addr[8];

		memcpy(addr, &filt->ieee_addr, 8);
		for (i = 0; i < 8; i++)
			regmap_write(devrec->regmap_short, REG_EADR0 + i,
				     addr[i]);

#ifdef DEBUG
		pr_debug("Set long addr to: ");
		for (i = 0; i < 8; i++)
			pr_debug("%02hhx ", addr[7 - i]);
		pr_debug("\n");
#endif
	}

	if (changed & IEEE802154_AFILT_PANID_CHANGED) {
		/* PAN ID */
		u8 panidl, panidh;

		panidh = le16_to_cpu(filt->pan_id) >> 8 & 0xff;
		panidl = le16_to_cpu(filt->pan_id) & 0xff;
		regmap_write(devrec->regmap_short, REG_PANIDH, panidh);
		regmap_write(devrec->regmap_short, REG_PANIDL, panidl);

		dev_dbg(printdev(devrec), "Set PANID to %04hx\n", filt->pan_id);
	}

	if (changed & IEEE802154_AFILT_PANC_CHANGED) {
		/* Pan Coordinator */
		u8 val;
		int ret;

		if (filt->pan_coord)
			val = BIT_PANCOORD;
		else
			val = 0;
		ret = regmap_update_bits(devrec->regmap_short, REG_RXMCR,
					 BIT_PANCOORD, val);
		if (ret)
			return ret;

		/* REG_SLOTTED is maintained as default (unslotted/CSMA-CA).
		 * REG_ORDER is maintained as default (no beacon/superframe).
		 */

		dev_dbg(printdev(devrec), "Set Pan Coord to %s\n",
			filt->pan_coord ? "on" : "off");
	}

	return 0;
}

static void mrf24j40_handle_rx_read_buf_unlock(struct mrf24j40 *devrec)
{
	int ret;

	/* Turn back on reception of packets off the air. */
	devrec->rx_msg.complete = NULL;
	devrec->rx_buf[0] = MRF24J40_WRITESHORT(REG_BBREG1);
	devrec->rx_buf[1] = 0x00; /* CLR RXDECINV */
	ret = spi_async(devrec->spi, &devrec->rx_msg);
	if (ret)
		dev_err(printdev(devrec), "failed to unlock rx buffer\n");
}

static void mrf24j40_handle_rx_read_buf_complete(void *context)
{
	struct mrf24j40 *devrec = context;
	u8 len = devrec->rx_buf[2];
	u8 rx_local_buf[RX_FIFO_SIZE];
	struct sk_buff *skb;

	memcpy(rx_local_buf, devrec->rx_fifo_buf, len);
	mrf24j40_handle_rx_read_buf_unlock(devrec);

	skb = dev_alloc_skb(IEEE802154_MTU);
	if (!skb) {
		dev_err(printdev(devrec), "failed to allocate skb\n");
		return;
	}

	skb_put_data(skb, rx_local_buf, len);
	ieee802154_rx_irqsafe(devrec->hw, skb, 0);

#ifdef DEBUG
	 print_hex_dump(KERN_DEBUG, "mrf24j40 rx: ", DUMP_PREFIX_OFFSET, 16, 1,
			rx_local_buf, len, 0);
	 pr_debug("mrf24j40 rx: lqi: %02hhx rssi: %02hhx\n",
		  devrec->rx_lqi_buf[0], devrec->rx_lqi_buf[1]);
#endif
}

static void mrf24j40_handle_rx_read_buf(void *context)
{
	struct mrf24j40 *devrec = context;
	u16 cmd;
	int ret;

	/* if length is invalid read the full MTU */
	if (!ieee802154_is_valid_psdu_len(devrec->rx_buf[2]))
		devrec->rx_buf[2] = IEEE802154_MTU;

	cmd = MRF24J40_READLONG(REG_RX_FIFO + 1);
	devrec->rx_addr_buf[0] = cmd >> 8 & 0xff;
	devrec->rx_addr_buf[1] = cmd & 0xff;
	devrec->rx_fifo_buf_trx.len = devrec->rx_buf[2];
	ret = spi_async(devrec->spi, &devrec->rx_buf_msg);
	if (ret) {
		dev_err(printdev(devrec), "failed to read rx buffer\n");
		mrf24j40_handle_rx_read_buf_unlock(devrec);
	}
}

static void mrf24j40_handle_rx_read_len(void *context)
{
	struct mrf24j40 *devrec = context;
	u16 cmd;
	int ret;

	/* read the length of received frame */
	devrec->rx_msg.complete = mrf24j40_handle_rx_read_buf;
	devrec->rx_trx.len = 3;
	cmd = MRF24J40_READLONG(REG_RX_FIFO);
	devrec->rx_buf[0] = cmd >> 8 & 0xff;
	devrec->rx_buf[1] = cmd & 0xff;

	ret = spi_async(devrec->spi, &devrec->rx_msg);
	if (ret) {
		dev_err(printdev(devrec), "failed to read rx buffer length\n");
		mrf24j40_handle_rx_read_buf_unlock(devrec);
	}
}

static int mrf24j40_handle_rx(struct mrf24j40 *devrec)
{
	/* Turn off reception of packets off the air. This prevents the
	 * device from overwriting the buffer while we're reading it.
	 */
	devrec->rx_msg.complete = mrf24j40_handle_rx_read_len;
	devrec->rx_trx.len = 2;
	devrec->rx_buf[0] = MRF24J40_WRITESHORT(REG_BBREG1);
	devrec->rx_buf[1] = BIT_RXDECINV; /* SET RXDECINV */

	return spi_async(devrec->spi, &devrec->rx_msg);
}

static int
mrf24j40_csma_params(struct ieee802154_hw *hw, u8 min_be, u8 max_be,
		     u8 retries)
{
	struct mrf24j40 *devrec = hw->priv;
	u8 val;

	/* min_be */
	val = min_be << TXMCR_MIN_BE_SHIFT;
	/* csma backoffs */
	val |= retries << TXMCR_CSMA_RETRIES_SHIFT;

	return regmap_update_bits(devrec->regmap_short, REG_TXMCR,
				  TXMCR_MIN_BE_MASK | TXMCR_CSMA_RETRIES_MASK,
				  val);
}

static int mrf24j40_set_cca_mode(struct ieee802154_hw *hw,
				 const struct wpan_phy_cca *cca)
{
	struct mrf24j40 *devrec = hw->priv;
	u8 val;

	/* mapping 802.15.4 to driver spec */
	switch (cca->mode) {
	case NL802154_CCA_ENERGY:
		val = 2;
		break;
	case NL802154_CCA_CARRIER:
		val = 1;
		break;
	case NL802154_CCA_ENERGY_CARRIER:
		switch (cca->opt) {
		case NL802154_CCA_OPT_ENERGY_CARRIER_AND:
			val = 3;
			break;
		default:
			return -EINVAL;
		}
		break;
	default:
		return -EINVAL;
	}

	return regmap_update_bits(devrec->regmap_short, REG_BBREG2,
				  BBREG2_CCA_MODE_MASK,
				  val << BBREG2_CCA_MODE_SHIFT);
}

/* array for representing ed levels */
static const s32 mrf24j40_ed_levels[] = {
	-9000, -8900, -8800, -8700, -8600, -8500, -8400, -8300, -8200, -8100,
	-8000, -7900, -7800, -7700, -7600, -7500, -7400, -7300, -7200, -7100,
	-7000, -6900, -6800, -6700, -6600, -6500, -6400, -6300, -6200, -6100,
	-6000, -5900, -5800, -5700, -5600, -5500, -5400, -5300, -5200, -5100,
	-5000, -4900, -4800, -4700, -4600, -4500, -4400, -4300, -4200, -4100,
	-4000, -3900, -3800, -3700, -3600, -3500
};

/* map ed levels to register value */
static const s32 mrf24j40_ed_levels_map[][2] = {
	{ -9000, 0 }, { -8900, 1 }, { -8800, 2 }, { -8700, 5 }, { -8600, 9 },
	{ -8500, 13 }, { -8400, 18 }, { -8300, 23 }, { -8200, 27 },
	{ -8100, 32 }, { -8000, 37 }, { -7900, 43 }, { -7800, 48 },
	{ -7700, 53 }, { -7600, 58 }, { -7500, 63 }, { -7400, 68 },
	{ -7300, 73 }, { -7200, 78 }, { -7100, 83 }, { -7000, 89 },
	{ -6900, 95 }, { -6800, 100 }, { -6700, 107 }, { -6600, 111 },
	{ -6500, 117 }, { -6400, 121 }, { -6300, 125 }, { -6200, 129 },
	{ -6100, 133 },	{ -6000, 138 }, { -5900, 143 }, { -5800, 148 },
	{ -5700, 153 }, { -5600, 159 },	{ -5500, 165 }, { -5400, 170 },
	{ -5300, 176 }, { -5200, 183 }, { -5100, 188 }, { -5000, 193 },
	{ -4900, 198 }, { -4800, 203 }, { -4700, 207 }, { -4600, 212 },
	{ -4500, 216 }, { -4400, 221 }, { -4300, 225 }, { -4200, 228 },
	{ -4100, 233 }, { -4000, 239 }, { -3900, 245 }, { -3800, 250 },
	{ -3700, 253 }, { -3600, 254 }, { -3500, 255 },
};

static int mrf24j40_set_cca_ed_level(struct ieee802154_hw *hw, s32 mbm)
{
	struct mrf24j40 *devrec = hw->priv;
	int i;

	for (i = 0; i < ARRAY_SIZE(mrf24j40_ed_levels_map); i++) {
		if (mrf24j40_ed_levels_map[i][0] == mbm)
			return regmap_write(devrec->regmap_short, REG_CCAEDTH,
					    mrf24j40_ed_levels_map[i][1]);
	}

	return -EINVAL;
}

static const s32 mrf24j40ma_powers[] = {
	0, -50, -120, -190, -280, -370, -490, -630, -1000, -1050, -1120, -1190,
	-1280, -1370, -1490, -1630, -2000, -2050, -2120, -2190, -2280, -2370,
	-2490, -2630, -3000, -3050, -3120, -3190, -3280, -3370, -3490, -3630,
};

static int mrf24j40_set_txpower(struct ieee802154_hw *hw, s32 mbm)
{
	struct mrf24j40 *devrec = hw->priv;
	s32 small_scale;
	u8 val;

	if (0 >= mbm && mbm > -1000) {
		val = TXPWRL_0 << TXPWRL_SHIFT;
		small_scale = mbm;
	} else if (-1000 >= mbm && mbm > -2000) {
		val = TXPWRL_10 << TXPWRL_SHIFT;
		small_scale = mbm + 1000;
	} else if (-2000 >= mbm && mbm > -3000) {
		val = TXPWRL_20 << TXPWRL_SHIFT;
		small_scale = mbm + 2000;
	} else if (-3000 >= mbm && mbm > -4000) {
		val = TXPWRL_30 << TXPWRL_SHIFT;
		small_scale = mbm + 3000;
	} else {
		return -EINVAL;
	}

	switch (small_scale) {
	case 0:
		val |= (TXPWRS_0 << TXPWRS_SHIFT);
		break;
	case -50:
		val |= (TXPWRS_0_5 << TXPWRS_SHIFT);
		break;
	case -120:
		val |= (TXPWRS_1_2 << TXPWRS_SHIFT);
		break;
	case -190:
		val |= (TXPWRS_1_9 << TXPWRS_SHIFT);
		break;
	case -280:
		val |= (TXPWRS_2_8 << TXPWRS_SHIFT);
		break;
	case -370:
		val |= (TXPWRS_3_7 << TXPWRS_SHIFT);
		break;
	case -490:
		val |= (TXPWRS_4_9 << TXPWRS_SHIFT);
		break;
	case -630:
		val |= (TXPWRS_6_3 << TXPWRS_SHIFT);
		break;
	default:
		return -EINVAL;
	}

	return regmap_update_bits(devrec->regmap_long, REG_RFCON3,
				  TXPWRL_MASK | TXPWRS_MASK, val);
}

static int mrf24j40_set_promiscuous_mode(struct ieee802154_hw *hw, bool on)
{
	struct mrf24j40 *devrec = hw->priv;
	int ret;

	if (on) {
		/* set PROMI, ERRPKT and NOACKRSP */
		ret = regmap_update_bits(devrec->regmap_short, REG_RXMCR,
					 BIT_PROMI | BIT_ERRPKT | BIT_NOACKRSP,
					 BIT_PROMI | BIT_ERRPKT | BIT_NOACKRSP);
	} else {
		/* clear PROMI, ERRPKT and NOACKRSP */
		ret = regmap_update_bits(devrec->regmap_short, REG_RXMCR,
					 BIT_PROMI | BIT_ERRPKT | BIT_NOACKRSP,
					 0);
	}

	return ret;
}

static const struct ieee802154_ops mrf24j40_ops = {
	.owner = THIS_MODULE,
	.xmit_async = mrf24j40_tx,
	.ed = mrf24j40_ed,
	.start = mrf24j40_start,
	.stop = mrf24j40_stop,
	.set_channel = mrf24j40_set_channel,
	.set_hw_addr_filt = mrf24j40_filter,
	.set_csma_params = mrf24j40_csma_params,
	.set_cca_mode = mrf24j40_set_cca_mode,
	.set_cca_ed_level = mrf24j40_set_cca_ed_level,
	.set_txpower = mrf24j40_set_txpower,
	.set_promiscuous_mode = mrf24j40_set_promiscuous_mode,
};

static void mrf24j40_intstat_complete(void *context)
{
	struct mrf24j40 *devrec = context;
	u8 intstat = devrec->irq_buf[1];

	enable_irq(devrec->spi->irq);

	/* Ignore Rx security decryption */
	if (intstat & BIT_SECIF)
		regmap_write_async(devrec->regmap_short, REG_SECCON0,
				   BIT_SECIGNORE);

	/* Check for TX complete */
	if (intstat & BIT_TXNIF)
		ieee802154_xmit_complete(devrec->hw, devrec->tx_skb, false);

	/* Check for Rx */
	if (intstat & BIT_RXIF)
		mrf24j40_handle_rx(devrec);
}

static irqreturn_t mrf24j40_isr(int irq, void *data)
{
	struct mrf24j40 *devrec = data;
	int ret;

	disable_irq_nosync(irq);

	devrec->irq_buf[0] = MRF24J40_READSHORT(REG_INTSTAT);
	devrec->irq_buf[1] = 0;

	/* Read the interrupt status */
	ret = spi_async(devrec->spi, &devrec->irq_msg);
	if (ret) {
		enable_irq(irq);
		return IRQ_NONE;
	}

	return IRQ_HANDLED;
}

static int mrf24j40_hw_init(struct mrf24j40 *devrec)
{
	u32 irq_type;
	int ret;

	/* Initialize the device.
		From datasheet section 3.2: Initialization. */
	ret = regmap_write(devrec->regmap_short, REG_SOFTRST, 0x07);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_short, REG_PACON2, 0x98);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_short, REG_TXSTBL, 0x95);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_long, REG_RFCON0, 0x03);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_long, REG_RFCON1, 0x01);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_long, REG_RFCON2, 0x80);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_long, REG_RFCON6, 0x90);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_long, REG_RFCON7, 0x80);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_long, REG_RFCON8, 0x10);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_long, REG_SLPCON1, 0x21);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_short, REG_BBREG2, 0x80);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_short, REG_CCAEDTH, 0x60);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_short, REG_BBREG6, 0x40);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_short, REG_RFCTL, 0x04);
	if (ret)
		goto err_ret;

	ret = regmap_write(devrec->regmap_short, REG_RFCTL, 0x0);
	if (ret)
		goto err_ret;

	udelay(192);

	/* Set RX Mode. RXMCR<1:0>: 0x0 normal, 0x1 promisc, 0x2 error */
	ret = regmap_update_bits(devrec->regmap_short, REG_RXMCR, 0x03, 0x00);
	if (ret)
		goto err_ret;

	if (spi_get_device_id(devrec->spi)->driver_data == MRF24J40MC) {
		/* Enable external amplifier.
		 * From MRF24J40MC datasheet section 1.3: Operation.
		 */
		regmap_update_bits(devrec->regmap_long, REG_TESTMODE, 0x07,
				   0x07);

		/* Set GPIO3 as output. */
		regmap_update_bits(devrec->regmap_short, REG_TRISGPIO, 0x08,
				   0x08);

		/* Set GPIO3 HIGH to enable U5 voltage regulator */
		regmap_update_bits(devrec->regmap_short, REG_GPIO, 0x08, 0x08);

		/* Reduce TX pwr to meet FCC requirements.
		 * From MRF24J40MC datasheet section 3.1.1
		 */
		regmap_write(devrec->regmap_long, REG_RFCON3, 0x28);
	}

	irq_type = irq_get_trigger_type(devrec->spi->irq);
	if (irq_type == IRQ_TYPE_EDGE_RISING ||
	    irq_type == IRQ_TYPE_EDGE_FALLING)
		dev_warn(&devrec->spi->dev,
			 "Using edge triggered irq's are not recommended, because it can cause races and result in a non-functional driver!\n");
	switch (irq_type) {
	case IRQ_TYPE_EDGE_RISING:
	case IRQ_TYPE_LEVEL_HIGH:
		/* set interrupt polarity to rising */
		ret = regmap_update_bits(devrec->regmap_long, REG_SLPCON0,
					 BIT_INTEDGE, BIT_INTEDGE);
		if (ret)
			goto err_ret;
		break;
	default:
		/* default is falling edge */
		break;
	}

	return 0;

err_ret:
	return ret;
}

static void
mrf24j40_setup_tx_spi_messages(struct mrf24j40 *devrec)
{
	spi_message_init(&devrec->tx_msg);
	devrec->tx_msg.context = devrec;
	devrec->tx_msg.complete = write_tx_buf_complete;
	devrec->tx_hdr_trx.len = 2;
	devrec->tx_hdr_trx.tx_buf = devrec->tx_hdr_buf;
	spi_message_add_tail(&devrec->tx_hdr_trx, &devrec->tx_msg);
	devrec->tx_len_trx.len = 2;
	devrec->tx_len_trx.tx_buf = devrec->tx_len_buf;
	spi_message_add_tail(&devrec->tx_len_trx, &devrec->tx_msg);
	spi_message_add_tail(&devrec->tx_buf_trx, &devrec->tx_msg);

	spi_message_init(&devrec->tx_post_msg);
	devrec->tx_post_msg.context = devrec;
	devrec->tx_post_trx.len = 2;
	devrec->tx_post_trx.tx_buf = devrec->tx_post_buf;
	spi_message_add_tail(&devrec->tx_post_trx, &devrec->tx_post_msg);
}

static void
mrf24j40_setup_rx_spi_messages(struct mrf24j40 *devrec)
{
	spi_message_init(&devrec->rx_msg);
	devrec->rx_msg.context = devrec;
	devrec->rx_trx.len = 2;
	devrec->rx_trx.tx_buf = devrec->rx_buf;
	devrec->rx_trx.rx_buf = devrec->rx_buf;
	spi_message_add_tail(&devrec->rx_trx, &devrec->rx_msg);

	spi_message_init(&devrec->rx_buf_msg);
	devrec->rx_buf_msg.context = devrec;
	devrec->rx_buf_msg.complete = mrf24j40_handle_rx_read_buf_complete;
	devrec->rx_addr_trx.len = 2;
	devrec->rx_addr_trx.tx_buf = devrec->rx_addr_buf;
	spi_message_add_tail(&devrec->rx_addr_trx, &devrec->rx_buf_msg);
	devrec->rx_fifo_buf_trx.rx_buf = devrec->rx_fifo_buf;
	spi_message_add_tail(&devrec->rx_fifo_buf_trx, &devrec->rx_buf_msg);
	devrec->rx_lqi_trx.len = 2;
	devrec->rx_lqi_trx.rx_buf = devrec->rx_lqi_buf;
	spi_message_add_tail(&devrec->rx_lqi_trx, &devrec->rx_buf_msg);
}

static void
mrf24j40_setup_irq_spi_messages(struct mrf24j40 *devrec)
{
	spi_message_init(&devrec->irq_msg);
	devrec->irq_msg.context = devrec;
	devrec->irq_msg.complete = mrf24j40_intstat_complete;
	devrec->irq_trx.len = 2;
	devrec->irq_trx.tx_buf = devrec->irq_buf;
	devrec->irq_trx.rx_buf = devrec->irq_buf;
	spi_message_add_tail(&devrec->irq_trx, &devrec->irq_msg);
}

static void  mrf24j40_phy_setup(struct mrf24j40 *devrec)
{
	ieee802154_random_extended_addr(&devrec->hw->phy->perm_extended_addr);
	devrec->hw->phy->current_channel = 11;

	/* mrf24j40 supports max_minbe 0 - 3 */
	devrec->hw->phy->supported.max_minbe = 3;
	/* datasheet doesn't say anything about max_be, but we have min_be
	 * So we assume the max_be default.
	 */
	devrec->hw->phy->supported.min_maxbe = 5;
	devrec->hw->phy->supported.max_maxbe = 5;

	devrec->hw->phy->cca.mode = NL802154_CCA_CARRIER;
	devrec->hw->phy->supported.cca_modes = BIT(NL802154_CCA_ENERGY) |
					       BIT(NL802154_CCA_CARRIER) |
					       BIT(NL802154_CCA_ENERGY_CARRIER);
	devrec->hw->phy->supported.cca_opts = BIT(NL802154_CCA_OPT_ENERGY_CARRIER_AND);

	devrec->hw->phy->cca_ed_level = -6900;
	devrec->hw->phy->supported.cca_ed_levels = mrf24j40_ed_levels;
	devrec->hw->phy->supported.cca_ed_levels_size = ARRAY_SIZE(mrf24j40_ed_levels);

	switch (spi_get_device_id(devrec->spi)->driver_data) {
	case MRF24J40:
	case MRF24J40MA:
		devrec->hw->phy->supported.tx_powers = mrf24j40ma_powers;
		devrec->hw->phy->supported.tx_powers_size = ARRAY_SIZE(mrf24j40ma_powers);
		devrec->hw->phy->flags |= WPAN_PHY_FLAG_TXPOWER;
		break;
	default:
		break;
	}
}

static int mrf24j40_probe(struct spi_device *spi)
{
	int ret = -ENOMEM, irq_type;
	struct ieee802154_hw *hw;
	struct mrf24j40 *devrec;

	dev_info(&spi->dev, "probe(). IRQ: %d\n", spi->irq);

	/* Register with the 802154 subsystem */

	hw = ieee802154_alloc_hw(sizeof(*devrec), &mrf24j40_ops);
	if (!hw)
		goto err_ret;

	devrec = hw->priv;
	devrec->spi = spi;
	spi_set_drvdata(spi, devrec);
	devrec->hw = hw;
	devrec->hw->parent = &spi->dev;
	devrec->hw->phy->supported.channels[0] = CHANNEL_MASK;
	devrec->hw->flags = IEEE802154_HW_TX_OMIT_CKSUM | IEEE802154_HW_AFILT |
			    IEEE802154_HW_CSMA_PARAMS |
			    IEEE802154_HW_PROMISCUOUS;

	devrec->hw->phy->flags = WPAN_PHY_FLAG_CCA_MODE |
				 WPAN_PHY_FLAG_CCA_ED_LEVEL;

	mrf24j40_setup_tx_spi_messages(devrec);
	mrf24j40_setup_rx_spi_messages(devrec);
	mrf24j40_setup_irq_spi_messages(devrec);

	devrec->regmap_short = devm_regmap_init_spi(spi,
						    &mrf24j40_short_regmap);
	if (IS_ERR(devrec->regmap_short)) {
		ret = PTR_ERR(devrec->regmap_short);
		dev_err(&spi->dev, "Failed to allocate short register map: %d\n",
			ret);
		goto err_register_device;
	}

	devrec->regmap_long = devm_regmap_init(&spi->dev,
					       &mrf24j40_long_regmap_bus,
					       spi, &mrf24j40_long_regmap);
	if (IS_ERR(devrec->regmap_long)) {
		ret = PTR_ERR(devrec->regmap_long);
		dev_err(&spi->dev, "Failed to allocate long register map: %d\n",
			ret);
		goto err_register_device;
	}

	if (spi->max_speed_hz > MAX_SPI_SPEED_HZ) {
		dev_warn(&spi->dev, "spi clock above possible maximum: %d",
			 MAX_SPI_SPEED_HZ);
		ret = -EINVAL;
		goto err_register_device;
	}

	ret = mrf24j40_hw_init(devrec);
	if (ret)
		goto err_register_device;

	mrf24j40_phy_setup(devrec);

	/* request IRQF_TRIGGER_LOW as fallback default */
	irq_type = irq_get_trigger_type(spi->irq);
	if (!irq_type)
		irq_type = IRQF_TRIGGER_LOW;

	ret = devm_request_irq(&spi->dev, spi->irq, mrf24j40_isr,
			       irq_type, dev_name(&spi->dev), devrec);
	if (ret) {
		dev_err(printdev(devrec), "Unable to get IRQ");
		goto err_register_device;
	}

	dev_dbg(printdev(devrec), "registered mrf24j40\n");
	ret = ieee802154_register_hw(devrec->hw);
	if (ret)
		goto err_register_device;

	return 0;

err_register_device:
	ieee802154_free_hw(devrec->hw);
err_ret:
	return ret;
}

static void mrf24j40_remove(struct spi_device *spi)
{
	struct mrf24j40 *devrec = spi_get_drvdata(spi);

	dev_dbg(printdev(devrec), "remove\n");

	ieee802154_unregister_hw(devrec->hw);
	ieee802154_free_hw(devrec->hw);
	/* TODO: Will ieee802154_free_device() wait until ->xmit() is
	 * complete? */
}

static const struct of_device_id mrf24j40_of_match[] = {
	{ .compatible = "microchip,mrf24j40", .data = (void *)MRF24J40 },
	{ .compatible = "microchip,mrf24j40ma", .data = (void *)MRF24J40MA },
	{ .compatible = "microchip,mrf24j40mc", .data = (void *)MRF24J40MC },
	{ },
};
MODULE_DEVICE_TABLE(of, mrf24j40_of_match);

static const struct spi_device_id mrf24j40_ids[] = {
	{ "mrf24j40", MRF24J40 },
	{ "mrf24j40ma", MRF24J40MA },
	{ "mrf24j40mc", MRF24J40MC },
	{ },
};
MODULE_DEVICE_TABLE(spi, mrf24j40_ids);

static struct spi_driver mrf24j40_driver = {
	.driver = {
		.of_match_table = mrf24j40_of_match,
		.name = "mrf24j40",
	},
	.id_table = mrf24j40_ids,
	.probe = mrf24j40_probe,
	.remove = mrf24j40_remove,
};

module_spi_driver(mrf24j40_driver);

MODULE_LICENSE("GPL");
MODULE_AUTHOR("Alan Ott");
MODULE_DESCRIPTION("MRF24J40 SPI 802.15.4 Controller Driver");