path: root/src/drivers/ao_cc1120.c

/*
 * Copyright © 2012 Keith Packard <keithp@keithp.com>
 *
 * This program is free software; you can redistribute it and/or modify
 * it under the terms of the GNU General Public License as published by
 * the Free Software Foundation; version 2 of the License.
 *
 * This program is distributed in the hope that it will be useful, but
 * WITHOUT ANY WARRANTY; without even the implied warranty of
 * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the GNU
 * General Public License for more details.
 *
 * You should have received a copy of the GNU General Public License along
 * with this program; if not, write to the Free Software Foundation, Inc.,
 * 59 Temple Place, Suite 330, Boston, MA 02111-1307 USA.
 */

#include <ao.h>
#include <ao_cc1120.h>
#include <ao_exti.h>
#include <ao_fec.h>
#include <ao_packet.h>

#define AO_RADIO_MAX_RECV	sizeof(struct ao_packet)
#define AO_RADIO_MAX_SEND	sizeof(struct ao_packet)

uint8_t ao_radio_wake;
uint8_t ao_radio_mutex;
uint8_t ao_radio_abort;
uint8_t ao_radio_in_recv;

#define CC1120_DEBUG	AO_FEC_DEBUG
#define CC1120_TRACE	0

extern const uint32_t	ao_radio_cal;

#define FOSC	32000000

#define ao_radio_select()	ao_spi_get_mask(AO_CC1120_SPI_CS_PORT,(1 << AO_CC1120_SPI_CS_PIN),AO_CC1120_SPI_BUS,AO_SPI_SPEED_1MHz)
#define ao_radio_deselect()	ao_spi_put_mask(AO_CC1120_SPI_CS_PORT,(1 << AO_CC1120_SPI_CS_PIN),AO_CC1120_SPI_BUS)
#define ao_radio_spi_send(d,l)	ao_spi_send((d), (l), AO_CC1120_SPI_BUS)
#define ao_radio_spi_send_fixed(d,l) ao_spi_send_fixed((d), (l), AO_CC1120_SPI_BUS)
#define ao_radio_spi_recv(d,l)	ao_spi_recv((d), (l), AO_CC1120_SPI_BUS)
#define ao_radio_duplex(o,i,l)	ao_spi_duplex((o), (i), (l), AO_CC1120_SPI_BUS)

static uint8_t
ao_radio_reg_read(uint16_t addr)
{
	uint8_t	data[2];
	uint8_t	d;

#if CC1120_TRACE
	printf("\t\tao_radio_reg_read (%04x): ", addr); flush();
#endif
	if (CC1120_IS_EXTENDED(addr)) {
		data[0] = ((1 << CC1120_READ)  |
			   (0 << CC1120_BURST) |
			   CC1120_EXTENDED);
		data[1] = addr;
		d = 2;
	} else {
		data[0] = ((1 << CC1120_READ)  |
			   (0 << CC1120_BURST) |
			   addr);
		d = 1;
	}
	ao_radio_select();
	ao_radio_spi_send(data, d);
	ao_radio_spi_recv(data, 1);
	ao_radio_deselect();
#if CC1120_TRACE
	printf (" %02x\n", data[0]);
#endif
	return data[0];
}

static void
ao_radio_reg_write(uint16_t addr, uint8_t value)
{
	uint8_t	data[3];
	uint8_t	d;

#if CC1120_TRACE
	printf("\t\tao_radio_reg_write (%04x): %02x\n", addr, value);
#endif
	if (CC1120_IS_EXTENDED(addr)) {
		data[0] = ((0 << CC1120_READ)  |
			   (0 << CC1120_BURST) |
			   CC1120_EXTENDED);
		data[1] = addr;
		d = 2;
	} else {
		data[0] = ((0 << CC1120_READ)  |
			   (0 << CC1120_BURST) |
			   addr);
		d = 1;
	}
	data[d] = value;
	ao_radio_select();
	ao_radio_spi_send(data, d+1);
	ao_radio_deselect();
}

static void
ao_radio_burst_read_start (uint16_t addr)
{
	uint8_t data[2];
	uint8_t d;

	if (CC1120_IS_EXTENDED(addr)) {
		data[0] = ((1 << CC1120_READ)  |
			   (1 << CC1120_BURST) |
			   CC1120_EXTENDED);
		data[1] = addr;
		d = 2;
	} else {
		data[0] = ((1 << CC1120_READ)  |
			   (1 << CC1120_BURST) |
			   addr);
		d = 1;
	}
	ao_radio_select();
	ao_radio_spi_send(data, d);
}

static void
ao_radio_burst_read_stop (void)
{
	ao_radio_deselect();
}


static uint8_t
ao_radio_strobe(uint8_t addr)
{
	uint8_t	in;

#if CC1120_TRACE
	printf("\t\tao_radio_strobe (%02x): ", addr); flush();
#endif
	ao_radio_select();
	ao_radio_duplex(&addr, &in, 1);
	ao_radio_deselect();
#if CC1120_TRACE
	printf("%02x\n", in); flush();
#endif
	return in;
}

static uint8_t
ao_radio_fifo_read(uint8_t *data, uint8_t len)
{
	uint8_t	addr = ((1 << CC1120_READ)  |
			(1 << CC1120_BURST) |
			CC1120_FIFO);
	uint8_t status;

	ao_radio_select();
	ao_radio_duplex(&addr, &status, 1);
	ao_radio_spi_recv(data, len);
	ao_radio_deselect();
	return status;
}

static uint8_t
ao_radio_fifo_write_start(void)
{
	uint8_t	addr = ((0 << CC1120_READ)  |
			(1 << CC1120_BURST) |
			CC1120_FIFO);
	uint8_t status;

	ao_radio_select();
	ao_radio_duplex(&addr, &status, 1);
	return status;
}

static inline uint8_t ao_radio_fifo_write_stop(uint8_t status) {
	ao_radio_deselect();
	return status;
}

static uint8_t
ao_radio_fifo_write(uint8_t *data, uint8_t len)
{
	uint8_t	status = ao_radio_fifo_write_start();
	ao_radio_spi_send(data, len);
	return ao_radio_fifo_write_stop(status);
}

static uint8_t
ao_radio_fifo_write_fixed(uint8_t data, uint8_t len)
{
	uint8_t status = ao_radio_fifo_write_start();
	ao_radio_spi_send_fixed(data, len);
	return ao_radio_fifo_write_stop(status);
}

static uint8_t
ao_radio_tx_fifo_space(void)
{
	return CC1120_FIFO_SIZE - ao_radio_reg_read(CC1120_NUM_TXBYTES);
}

static uint8_t
ao_radio_status(void)
{
	return ao_radio_strobe (CC1120_SNOP);
}

void
ao_radio_recv_abort(void)
{
	ao_radio_abort = 1;
	ao_wakeup(&ao_radio_wake);
}

#define ao_radio_rdf_value 0x55

static uint8_t
ao_radio_marc_status(void)
{
	return ao_radio_reg_read(CC1120_MARC_STATUS1);
}

static void
ao_radio_tx_isr(void)
{
	ao_exti_disable(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN);
	ao_radio_wake = 1;
	ao_wakeup(&ao_radio_wake);
}

static void
ao_radio_start_tx(void)
{
	ao_exti_set_callback(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN, ao_radio_tx_isr);
	ao_exti_enable(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN);
	ao_radio_strobe(CC1120_STX);
}

static void
ao_radio_idle(void)
{
	for (;;) {
		uint8_t	state = ao_radio_strobe(CC1120_SIDLE);
		if ((state >> CC1120_STATUS_STATE) == CC1120_STATUS_STATE_IDLE)
			break;
	}
}

/*
 * Packet deviation is 20.5kHz
 *
 *	fdev = fosc >> 24 * (256 + dev_m) << dev_e
 *
 *     	32e6Hz / (2 ** 24) * (256 + 80) * (2 ** 5) = 20508Hz
 */

#define PACKET_DEV_E	5
#define PACKET_DEV_M	80

/*
 * For our packet data, set the symbol rate to 38360 Baud
 *
 *              (2**20 + DATARATE_M) * 2 ** DATARATE_E
 *	Rdata = -------------------------------------- * fosc
 *		             2 ** 39
 *
 *
 *	DATARATE_M = 239914
 *	DATARATE_E = 9
 */
#define PACKET_DRATE_E	9
#define PACKET_DRATE_M	239914

static const uint16_t packet_setup[] = {
	CC1120_DEVIATION_M,	PACKET_DEV_M,
	CC1120_MODCFG_DEV_E,	((CC1120_MODCFG_DEV_E_MODEM_MODE_NORMAL << CC1120_MODCFG_DEV_E_MODEM_MODE) |
				 (CC1120_MODCFG_DEV_E_MOD_FORMAT_2_GFSK << CC1120_MODCFG_DEV_E_MOD_FORMAT) |
				 (PACKET_DEV_E << CC1120_MODCFG_DEV_E_DEV_E)),
	CC1120_DRATE2,		((PACKET_DRATE_E << CC1120_DRATE2_DATARATE_E) |
				 (((PACKET_DRATE_M >> 16) & CC1120_DRATE2_DATARATE_M_19_16_MASK) << CC1120_DRATE2_DATARATE_M_19_16)),
	CC1120_DRATE1,		((PACKET_DRATE_M >> 8) & 0xff),
	CC1120_DRATE0,		((PACKET_DRATE_M >> 0) & 0xff),
	CC1120_PKT_CFG2,	((CC1120_PKT_CFG2_CCA_MODE_ALWAYS_CLEAR << CC1120_PKT_CFG2_CCA_MODE) |
				 (CC1120_PKT_CFG2_PKT_FORMAT_NORMAL << CC1120_PKT_CFG2_PKT_FORMAT)),
	CC1120_PKT_CFG1,	((0 << CC1120_PKT_CFG1_WHITE_DATA) |
				 (CC1120_PKT_CFG1_ADDR_CHECK_CFG_NONE << CC1120_PKT_CFG1_ADDR_CHECK_CFG) |
				 (CC1120_PKT_CFG1_CRC_CFG_DISABLED << CC1120_PKT_CFG1_CRC_CFG) |
				 (0 << CC1120_PKT_CFG1_APPEND_STATUS)),
	CC1120_PKT_CFG0,	((0 << CC1120_PKT_CFG0_RESERVED7) |
				 (CC1120_PKT_CFG0_LENGTH_CONFIG_FIXED << CC1120_PKT_CFG0_LENGTH_CONFIG) |
				 (0 << CC1120_PKT_CFG0_PKG_BIT_LEN) |
				 (0 << CC1120_PKT_CFG0_UART_MODE_EN) |
				 (0 << CC1120_PKT_CFG0_UART_SWAP_EN)),
};

static const uint16_t packet_tx_setup[] = {
	CC1120_PKT_CFG2,	((CC1120_PKT_CFG2_CCA_MODE_ALWAYS_CLEAR << CC1120_PKT_CFG2_CCA_MODE) |
				 (CC1120_PKT_CFG2_PKT_FORMAT_NORMAL << CC1120_PKT_CFG2_PKT_FORMAT)),
	CC1120_IOCFG2, 		CC1120_IOCFG_GPIO_CFG_RX0TX1_CFG,
};

static const uint16_t packet_rx_setup[] = {
	CC1120_PKT_CFG2,	((CC1120_PKT_CFG2_CCA_MODE_ALWAYS_CLEAR << CC1120_PKT_CFG2_CCA_MODE) |
				 (CC1120_PKT_CFG2_PKT_FORMAT_SYNCHRONOUS_SERIAL << CC1120_PKT_CFG2_PKT_FORMAT)),
	CC1120_IOCFG2, 		CC1120_IOCFG_GPIO_CFG_CLKEN_SOFT,
};

/*
 * RDF deviation is 5kHz
 *
 *	fdev = fosc >> 24 * (256 + dev_m) << dev_e
 *
 *     	32e6Hz / (2 ** 24) * (256 + 71) * (2 ** 3) = 4989
 */

#define RDF_DEV_E	3
#define RDF_DEV_M	71
#define RDF_PACKET_LEN	50

/*
 * For our RDF beacon, set the symbol rate to 2kBaud (for a 1kHz tone)
 *
 *              (2**20 + DATARATE_M) * 2 ** DATARATE_E
 *	Rdata = -------------------------------------- * fosc
 *		             2 ** 39
 *
 *	DATARATE_M = 25166
 *	DATARATE_E = 5
 *
 * To make the tone last for 200ms, we need 2000 * .2 = 400 bits or 50 bytes
 */
#define RDF_DRATE_E	5
#define RDF_DRATE_M	25166
#define RDF_PACKET_LEN	50

static const uint16_t rdf_setup[] = {
	CC1120_DEVIATION_M,	RDF_DEV_M,
	CC1120_MODCFG_DEV_E,	((CC1120_MODCFG_DEV_E_MODEM_MODE_NORMAL << CC1120_MODCFG_DEV_E_MODEM_MODE) |
				 (CC1120_MODCFG_DEV_E_MOD_FORMAT_2_GFSK << CC1120_MODCFG_DEV_E_MOD_FORMAT) |
				 (RDF_DEV_E << CC1120_MODCFG_DEV_E_DEV_E)),
	CC1120_DRATE2,		((RDF_DRATE_E << CC1120_DRATE2_DATARATE_E) |
				 (((RDF_DRATE_M >> 16) & CC1120_DRATE2_DATARATE_M_19_16_MASK) << CC1120_DRATE2_DATARATE_M_19_16)),
	CC1120_DRATE1,		((RDF_DRATE_M >> 8) & 0xff),
	CC1120_DRATE0,		((RDF_DRATE_M >> 0) & 0xff),
	CC1120_PKT_CFG2,	((CC1120_PKT_CFG2_CCA_MODE_ALWAYS_CLEAR << CC1120_PKT_CFG2_CCA_MODE) |
				 (CC1120_PKT_CFG2_PKT_FORMAT_NORMAL << CC1120_PKT_CFG2_PKT_FORMAT)),
	CC1120_PKT_CFG1,	((0 << CC1120_PKT_CFG1_WHITE_DATA) |
				 (CC1120_PKT_CFG1_ADDR_CHECK_CFG_NONE << CC1120_PKT_CFG1_ADDR_CHECK_CFG) |
				 (CC1120_PKT_CFG1_CRC_CFG_DISABLED << CC1120_PKT_CFG1_CRC_CFG) |
				 (0 << CC1120_PKT_CFG1_APPEND_STATUS)),
	CC1120_PKT_CFG0,	((0 << CC1120_PKT_CFG0_RESERVED7) |
				 (CC1120_PKT_CFG0_LENGTH_CONFIG_FIXED << CC1120_PKT_CFG0_LENGTH_CONFIG) |
				 (0 << CC1120_PKT_CFG0_PKG_BIT_LEN) |
				 (0 << CC1120_PKT_CFG0_UART_MODE_EN) |
				 (0 << CC1120_PKT_CFG0_UART_SWAP_EN)),
};

/*
 * APRS deviation is 5kHz
 *
 *	fdev = fosc >> 24 * (256 + dev_m) << dev_e
 *
 *     	32e6Hz / (2 ** 24) * (256 + 71) * (2 ** 3) = 4989
 */

#define APRS_DEV_E	3
#define APRS_DEV_M	71
#define APRS_PACKET_LEN	50

/*
 * For our APRS beacon, set the symbol rate to 9.6kBaud (8x oversampling for 1200 baud data rate)
 *
 *              (2**20 + DATARATE_M) * 2 ** DATARATE_E
 *	Rdata = -------------------------------------- * fosc
 *		             2 ** 39
 *
 *	DATARATE_M = 239914
 *	DATARATE_E = 7
 *
 *	Rdata = 9599.998593330383301
 *
 */
#define APRS_DRATE_E	5
#define APRS_DRATE_M	25166

static const uint16_t aprs_setup[] = {
	CC1120_DEVIATION_M,	APRS_DEV_M,
	CC1120_MODCFG_DEV_E,	((CC1120_MODCFG_DEV_E_MODEM_MODE_NORMAL << CC1120_MODCFG_DEV_E_MODEM_MODE) |
				 (CC1120_MODCFG_DEV_E_MOD_FORMAT_2_GFSK << CC1120_MODCFG_DEV_E_MOD_FORMAT) |
				 (APRS_DEV_E << CC1120_MODCFG_DEV_E_DEV_E)),
	CC1120_DRATE2,		((APRS_DRATE_E << CC1120_DRATE2_DATARATE_E) |
				 (((APRS_DRATE_M >> 16) & CC1120_DRATE2_DATARATE_M_19_16_MASK) << CC1120_DRATE2_DATARATE_M_19_16)),
	CC1120_DRATE1,		((APRS_DRATE_M >> 8) & 0xff),
	CC1120_DRATE0,		((APRS_DRATE_M >> 0) & 0xff),
	CC1120_PKT_CFG2,	((CC1120_PKT_CFG2_CCA_MODE_ALWAYS_CLEAR << CC1120_PKT_CFG2_CCA_MODE) |
				 (CC1120_PKT_CFG2_PKT_FORMAT_NORMAL << CC1120_PKT_CFG2_PKT_FORMAT)),
	CC1120_PKT_CFG1,	((0 << CC1120_PKT_CFG1_WHITE_DATA) |
				 (CC1120_PKT_CFG1_ADDR_CHECK_CFG_NONE << CC1120_PKT_CFG1_ADDR_CHECK_CFG) |
				 (CC1120_PKT_CFG1_CRC_CFG_DISABLED << CC1120_PKT_CFG1_CRC_CFG) |
				 (0 << CC1120_PKT_CFG1_APPEND_STATUS)),
};

#define AO_PKT_CFG0_INFINITE ((0 << CC1120_PKT_CFG0_RESERVED7) |	\
			      (CC1120_PKT_CFG0_LENGTH_CONFIG_INFINITE << CC1120_PKT_CFG0_LENGTH_CONFIG) | \
			      (0 << CC1120_PKT_CFG0_PKG_BIT_LEN) |	\
			      (0 << CC1120_PKT_CFG0_UART_MODE_EN) |	\
			      (0 << CC1120_PKT_CFG0_UART_SWAP_EN))

#define AO_PKT_CFG0_FIXED ((0 << CC1120_PKT_CFG0_RESERVED7) |		\
			   (CC1120_PKT_CFG0_LENGTH_CONFIG_FIXED << CC1120_PKT_CFG0_LENGTH_CONFIG) | \
			   (0 << CC1120_PKT_CFG0_PKG_BIT_LEN) |		\
			   (0 << CC1120_PKT_CFG0_UART_MODE_EN) |	\
			   (0 << CC1120_PKT_CFG0_UART_SWAP_EN))

static uint16_t ao_radio_mode;

#define AO_RADIO_MODE_BITS_PACKET	1
#define AO_RADIO_MODE_BITS_PACKET_TX	2
#define AO_RADIO_MODE_BITS_TX_BUF	4
#define AO_RADIO_MODE_BITS_TX_FINISH	8
#define AO_RADIO_MODE_BITS_PACKET_RX	16
#define AO_RADIO_MODE_BITS_RDF		32
#define AO_RADIO_MODE_BITS_APRS		64
#define AO_RADIO_MODE_BITS_INFINITE	128
#define AO_RADIO_MODE_BITS_FIXED	256

#define AO_RADIO_MODE_NONE		0
#define AO_RADIO_MODE_PACKET_TX_BUF	(AO_RADIO_MODE_BITS_PACKET | AO_RADIO_MODE_BITS_PACKET_TX | AO_RADIO_MODE_BITS_TX_BUF)
#define AO_RADIO_MODE_PACKET_TX_FINISH	(AO_RADIO_MODE_BITS_PACKET | AO_RADIO_MODE_BITS_PACKET_TX | AO_RADIO_MODE_BITS_TX_FINISH)
#define AO_RADIO_MODE_PACKET_RX		(AO_RADIO_MODE_BITS_PACKET | AO_RADIO_MODE_BITS_PACKET_RX)
#define AO_RADIO_MODE_RDF		(AO_RADIO_MODE_BITS_RDF | AO_RADIO_MODE_BITS_TX_FINISH)
#define AO_RADIO_MODE_APRS_BUF		(AO_RADIO_MODE_BITS_APRS | AO_RADIO_MODE_BITS_INFINITE)
#define AO_RADIO_MODE_APRS_FINISH	(AO_RADIO_MODE_BITS_APRS | AO_RADIO_MODE_BITS_FIXED)

static void
ao_radio_set_mode(uint16_t new_mode)
{
	uint16_t changes;
	int i;

	if (new_mode == ao_radio_mode)
		return;

	changes = new_mode & (~ao_radio_mode);
	if (changes & AO_RADIO_MODE_BITS_PACKET)
		for (i = 0; i < sizeof (packet_setup) / sizeof (packet_setup[0]); i += 2)
			ao_radio_reg_write(packet_setup[i], packet_setup[i+1]);

	if (changes & AO_RADIO_MODE_BITS_PACKET_TX)
		for (i = 0; i < sizeof (packet_tx_setup) / sizeof (packet_tx_setup[0]); i += 2)
			ao_radio_reg_write(packet_tx_setup[i], packet_tx_setup[i+1]);
		
	if (changes & AO_RADIO_MODE_BITS_TX_BUF)
		ao_radio_reg_write(CC1120_IOCFG2, CC1120_IOCFG_GPIO_CFG_TXFIFO_THR);

	if (changes & AO_RADIO_MODE_BITS_TX_FINISH)
		ao_radio_reg_write(CC1120_IOCFG2, CC1120_IOCFG_GPIO_CFG_RX0TX1_CFG);

	if (changes & AO_RADIO_MODE_BITS_PACKET_RX)
		for (i = 0; i < sizeof (packet_rx_setup) / sizeof (packet_rx_setup[0]); i += 2)
			ao_radio_reg_write(packet_rx_setup[i], packet_rx_setup[i+1]);
		
	if (changes & AO_RADIO_MODE_BITS_RDF)
		for (i = 0; i < sizeof (rdf_setup) / sizeof (rdf_setup[0]); i += 2)
			ao_radio_reg_write(rdf_setup[i], rdf_setup[i+1]);

	if (changes & AO_RADIO_MODE_BITS_APRS)
		for (i = 0; i < sizeof (aprs_setup) / sizeof (aprs_setup[0]); i += 2)
			ao_radio_reg_write(aprs_setup[i], aprs_setup[i+1]);

	if (changes & AO_RADIO_MODE_BITS_INFINITE)
		ao_radio_reg_write(CC1120_PKT_CFG0, AO_PKT_CFG0_INFINITE);

	if (changes & AO_RADIO_MODE_BITS_FIXED)
		ao_radio_reg_write(CC1120_PKT_CFG0, AO_PKT_CFG0_FIXED);

	ao_radio_mode = new_mode;
}

static const uint16_t radio_setup[] = {
#include "ao_cc1120_CC1120.h"
};

static uint8_t	ao_radio_configured = 0;

static void
ao_radio_setup(void)
{
	int	i;

	ao_radio_strobe(CC1120_SRES);

	for (i = 0; i < sizeof (radio_setup) / sizeof (radio_setup[0]); i += 2)
		ao_radio_reg_write(radio_setup[i], radio_setup[i+1]);

	ao_radio_mode = 0;

	ao_config_get();

	ao_radio_configured = 1;
}

static void
ao_radio_set_len(uint8_t len)
{
	static uint8_t	last_len;

	if (len != last_len) {
		ao_radio_reg_write(CC1120_PKT_LEN, len);
		last_len = len;
	}
}

static void
ao_radio_get(uint8_t len)
{
	static uint32_t	last_radio_setting;

	ao_mutex_get(&ao_radio_mutex);
	if (!ao_radio_configured)
		ao_radio_setup();
	if (ao_config.radio_setting != last_radio_setting) {
		ao_radio_reg_write(CC1120_FREQ2, ao_config.radio_setting >> 16);
		ao_radio_reg_write(CC1120_FREQ1, ao_config.radio_setting >> 8);
		ao_radio_reg_write(CC1120_FREQ0, ao_config.radio_setting);
		last_radio_setting = ao_config.radio_setting;
	}
	ao_radio_set_len(len);
}

#define ao_radio_put()	ao_mutex_put(&ao_radio_mutex)

static void
ao_rdf_start(uint8_t len)
{
	ao_radio_abort = 0;
	ao_radio_get(len);

	ao_radio_set_mode(AO_RADIO_MODE_RDF);
	ao_radio_wake = 0;

}

static void
ao_rdf_run(void)
{
	ao_radio_start_tx();

	ao_arch_block_interrupts();
	while (!ao_radio_wake && !ao_radio_abort)
		ao_sleep(&ao_radio_wake);
	ao_arch_release_interrupts();
	if (!ao_radio_wake)
		ao_radio_idle();
	ao_radio_put();
}

void
ao_radio_rdf(void)
{
	ao_rdf_start(AO_RADIO_RDF_LEN);

	ao_radio_fifo_write_fixed(ao_radio_rdf_value, AO_RADIO_RDF_LEN);

	ao_rdf_run();
}

void
ao_radio_continuity(uint8_t c)
{
	uint8_t	i;
	uint8_t status;

	ao_rdf_start(AO_RADIO_CONT_TOTAL_LEN);

	status = ao_radio_fifo_write_start();
	for (i = 0; i < 3; i++) {
		ao_radio_spi_send_fixed(0x00, AO_RADIO_CONT_PAUSE_LEN);
		if (i < c)
			ao_radio_spi_send_fixed(ao_radio_rdf_value, AO_RADIO_CONT_TONE_LEN);
		else
			ao_radio_spi_send_fixed(0x00, AO_RADIO_CONT_TONE_LEN);
	}
	ao_radio_spi_send_fixed(0x00, AO_RADIO_CONT_PAUSE_LEN);
	status = ao_radio_fifo_write_stop(status);
	(void) status;
	ao_rdf_run();
}

void
ao_radio_rdf_abort(void)
{
	ao_radio_abort = 1;
	ao_wakeup(&ao_radio_wake);
}

static void
ao_radio_test_cmd(void)
{
	uint8_t	mode = 2;
	static uint8_t radio_on;
	ao_cmd_white();
	if (ao_cmd_lex_c != '\n') {
		ao_cmd_decimal();
		mode = (uint8_t) ao_cmd_lex_u32;
	}
	mode++;
	if ((mode & 2) && !radio_on) {
#if HAS_MONITOR
		ao_monitor_disable();
#endif
#if PACKET_HAS_SLAVE
		ao_packet_slave_stop();
#endif
		ao_radio_get(0xff);
		ao_radio_strobe(CC1120_STX);
#if CC1120_TRACE
		{ int t; 
			for (t = 0; t < 10; t++) {
				printf ("status: %02x\n", ao_radio_status());
				ao_delay(AO_MS_TO_TICKS(100));
			}
		}
#endif
		radio_on = 1;
	}
	if (mode == 3) {
		printf ("Hit a character to stop..."); flush();
		getchar();
		putchar('\n');
	}
	if ((mode & 1) && radio_on) {
		ao_radio_idle();
		ao_radio_put();
		radio_on = 0;
#if HAS_MONITOR
		ao_monitor_enable();
#endif
	}
}

static uint8_t
ao_radio_wait_tx(uint8_t wait_fifo)
{
	uint8_t	fifo_space = 0;

	do {
		ao_radio_wake = 0;
		ao_arch_block_interrupts();
		while (!ao_radio_wake)
			ao_sleep(&ao_radio_wake);
		ao_arch_release_interrupts();
		if (!wait_fifo)
			return 0;
		fifo_space = ao_radio_tx_fifo_space();
	} while (!fifo_space);
	return fifo_space;
}

static uint8_t	tx_data[(AO_RADIO_MAX_SEND + 4) * 2];

void
ao_radio_send(const void *d, uint8_t size)
{
	uint8_t		marc_status;
	uint8_t		*e = tx_data;
	uint8_t		encode_len;
	uint8_t		this_len;
	uint8_t		started = 0;
	uint8_t		fifo_space;

	encode_len = ao_fec_encode(d, size, tx_data);

	ao_radio_get(encode_len);

	started = 0;
	fifo_space = CC1120_FIFO_SIZE;
	while (encode_len) {
		this_len = encode_len;

		if (this_len > fifo_space) {
			this_len = fifo_space;
			ao_radio_set_mode(AO_RADIO_MODE_PACKET_TX_BUF);
		} else {
			ao_radio_set_mode(AO_RADIO_MODE_PACKET_TX_FINISH);
		}

		ao_radio_fifo_write(e, this_len);
		e += this_len;
		encode_len -= this_len;

		if (!started) {
			ao_radio_start_tx();
			started = 1;
		} else {
			ao_exti_enable(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN);
		}
			
		fifo_space = ao_radio_wait_tx(encode_len != 0);
	}
	ao_radio_put();
}

#define AO_RADIO_LOTS	64

void
ao_radio_send_lots(ao_radio_fill_func fill)
{
	uint8_t	buf[AO_RADIO_LOTS], *b;
	int	cnt;
	int	total = 0;
	uint8_t	done = 0;
	uint8_t	started = 0;
	uint8_t	fifo_space;

	ao_radio_get(0xff);
	fifo_space = CC1120_FIFO_SIZE;
	while (!done) {
		cnt = (*fill)(buf, sizeof(buf));
		if (cnt < 0) {
			done = 1;
			cnt = -cnt;
		}
		total += cnt;
		if (done) {
			ao_radio_set_len(total & 0xff);
			ao_radio_set_mode(AO_RADIO_MODE_APRS_FINISH);
		} else
			ao_radio_set_mode(AO_RADIO_MODE_APRS_BUF);
		b = buf;
		while (cnt) {
			uint8_t	this_len = cnt;
			if (this_len > fifo_space)
				this_len = fifo_space;
			ao_radio_fifo_write(b, this_len);
			b += this_len;
			cnt -= this_len;
			if (!started) {
				ao_radio_start_tx();
				started = 1;
			}
			fifo_space = ao_radio_wait_tx(!done || cnt);
		}
	}
	ao_radio_put();
}

static uint8_t	rx_data[(AO_RADIO_MAX_RECV + 4) * 2 * 8];
static uint16_t	rx_data_count;
static uint16_t	rx_data_consumed;
static uint16_t rx_data_cur;
static uint8_t	rx_ignore;
static uint8_t	rx_waiting;

#if AO_PROFILE
static uint32_t	rx_start_tick, rx_packet_tick, rx_done_tick, rx_last_done_tick;

uint32_t	ao_rx_start_tick, ao_rx_packet_tick, ao_rx_done_tick, ao_rx_last_done_tick;

#include <ao_profile.h>
#endif

static void
ao_radio_rx_isr(void)
{
	uint8_t	d;

	d = stm_spi2.dr;
	stm_spi2.dr = 0;
	if (rx_ignore == 0) {
		if (rx_data_cur >= rx_data_count)
			ao_exti_disable(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN);
		else
			rx_data[rx_data_cur++] = d;
		if (rx_waiting && rx_data_cur - rx_data_consumed >= AO_FEC_DECODE_BLOCK) {
#if AO_PROFILE
			if (!rx_packet_tick)
				rx_packet_tick = ao_profile_tick();
			if (rx_data_cur < rx_data_count)
				return;
#endif
			rx_waiting = 0;
			ao_wakeup(&ao_radio_wake);
		}
	} else {
		--rx_ignore;
	}
}

static uint16_t
ao_radio_rx_wait(void)
{
	ao_arch_block_interrupts();
	rx_waiting = 1;
	while (rx_data_cur - rx_data_consumed < AO_FEC_DECODE_BLOCK &&
	       !ao_radio_abort) {
		ao_sleep(&ao_radio_wake);
	}
	rx_waiting = 0;
	ao_arch_release_interrupts();
	if (ao_radio_abort)
		return 0;
	rx_data_consumed += AO_FEC_DECODE_BLOCK;
#if AO_PROFILE
	return rx_data_cur - rx_data_consumed;
#endif
	return AO_FEC_DECODE_BLOCK;
}

uint8_t
ao_radio_recv(__xdata void *d, uint8_t size)
{
	uint8_t		len;
	uint16_t	i;
	uint8_t		rssi;
	uint8_t		ret;
	static int been_here = 0;

	size -= 2;			/* status bytes */
	if (size > AO_RADIO_MAX_RECV) {
		ao_delay(AO_SEC_TO_TICKS(1));
		return 0;
	}
#if AO_PROFILE
	rx_start_tick = ao_profile_tick();
	rx_packet_tick = 0;
#endif
	len = size + 2;			/* CRC bytes */
	len += 1 + ~(len & 1);		/* 1 or two pad bytes */
	len *= 2;			/* 1/2 rate convolution */
	rx_data_count = len * 8;	/* bytes to bits */
	rx_data_cur = 0;
	rx_data_consumed = 0;
	rx_ignore = 2;

	ao_radio_abort = 0;
	ao_radio_in_recv = 1;
	/* configure interrupt pin */
	ao_radio_get(len);
	ao_radio_set_mode(AO_RADIO_MODE_PACKET_RX);

	ao_radio_wake = 0;

	stm_spi2.cr2 = 0;

	/* clear any RXNE */
	(void) stm_spi2.dr;

	ao_exti_set_callback(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN, ao_radio_rx_isr);
	ao_exti_enable(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN);

	ao_radio_strobe(CC1120_SRX);

	ao_radio_burst_read_start(CC1120_SOFT_RX_DATA_OUT);

	ret = ao_fec_decode(rx_data, rx_data_count, d, size + 2, ao_radio_rx_wait);

	ao_radio_burst_read_stop();

	ao_radio_strobe(CC1120_SIDLE);

	/* Convert from 'real' rssi to cc1111-style values */

	rssi = AO_RADIO_FROM_RSSI(ao_radio_reg_read(CC1120_RSSI1));

	ao_radio_put();

	/* Store the received RSSI value; the crc-OK byte is already done */

	((uint8_t *) d)[size] = (uint8_t) rssi;

	ao_radio_in_recv = 0;

	if (ao_radio_abort)
		ao_delay(1);

#if AO_PROFILE
	rx_last_done_tick = rx_done_tick;
	rx_done_tick = ao_profile_tick();

	ao_rx_start_tick = rx_start_tick;
	ao_rx_packet_tick = rx_packet_tick;
	ao_rx_done_tick = rx_done_tick;
	ao_rx_last_done_tick = rx_last_done_tick;
#endif

	return ret;
}


#if CC1120_DEBUG
static char *cc1120_state_name[] = {
	[CC1120_STATUS_STATE_IDLE] = "IDLE",
	[CC1120_STATUS_STATE_RX] = "RX",
	[CC1120_STATUS_STATE_TX] = "TX",
	[CC1120_STATUS_STATE_FSTXON] = "FSTXON",
	[CC1120_STATUS_STATE_CALIBRATE] = "CALIBRATE",
	[CC1120_STATUS_STATE_SETTLING] = "SETTLING",
	[CC1120_STATUS_STATE_RX_FIFO_ERROR] = "RX_FIFO_ERROR",
	[CC1120_STATUS_STATE_TX_FIFO_ERROR] = "TX_FIFO_ERROR",
};

struct ao_cc1120_reg {
	uint16_t	addr;
	char		*name;
};

const static struct ao_cc1120_reg ao_cc1120_reg[] = {
	{ .addr = CC1120_IOCFG3,	.name = "IOCFG3" },
	{ .addr = CC1120_IOCFG2,	.name = "IOCFG2" },
	{ .addr = CC1120_IOCFG1,	.name = "IOCFG1" },
	{ .addr = CC1120_IOCFG0,	.name = "IOCFG0" },
	{ .addr = CC1120_SYNC3,	.name = "SYNC3" },
	{ .addr = CC1120_SYNC2,	.name = "SYNC2" },
	{ .addr = CC1120_SYNC1,	.name = "SYNC1" },
	{ .addr = CC1120_SYNC0,	.name = "SYNC0" },
	{ .addr = CC1120_SYNC_CFG1,	.name = "SYNC_CFG1" },
	{ .addr = CC1120_SYNC_CFG0,	.name = "SYNC_CFG0" },
	{ .addr = CC1120_DEVIATION_M,	.name = "DEVIATION_M" },
	{ .addr = CC1120_MODCFG_DEV_E,	.name = "MODCFG_DEV_E" },
	{ .addr = CC1120_DCFILT_CFG,	.name = "DCFILT_CFG" },
	{ .addr = CC1120_PREAMBLE_CFG1,	.name = "PREAMBLE_CFG1" },
	{ .addr = CC1120_PREAMBLE_CFG0,	.name = "PREAMBLE_CFG0" },
	{ .addr = CC1120_FREQ_IF_CFG,	.name = "FREQ_IF_CFG" },
	{ .addr = CC1120_IQIC,	.name = "IQIC" },
	{ .addr = CC1120_CHAN_BW,	.name = "CHAN_BW" },
	{ .addr = CC1120_MDMCFG1,	.name = "MDMCFG1" },
	{ .addr = CC1120_MDMCFG0,	.name = "MDMCFG0" },
	{ .addr = CC1120_DRATE2,	.name = "DRATE2" },
	{ .addr = CC1120_DRATE1,	.name = "DRATE1" },
	{ .addr = CC1120_DRATE0,	.name = "DRATE0" },
	{ .addr = CC1120_AGC_REF,	.name = "AGC_REF" },
	{ .addr = CC1120_AGC_CS_THR,	.name = "AGC_CS_THR" },
	{ .addr = CC1120_AGC_GAIN_ADJUST,	.name = "AGC_GAIN_ADJUST" },
	{ .addr = CC1120_AGC_CFG3,	.name = "AGC_CFG3" },
	{ .addr = CC1120_AGC_CFG2,	.name = "AGC_CFG2" },
	{ .addr = CC1120_AGC_CFG1,	.name = "AGC_CFG1" },
	{ .addr = CC1120_AGC_CFG0,	.name = "AGC_CFG0" },
	{ .addr = CC1120_FIFO_CFG,	.name = "FIFO_CFG" },
	{ .addr = CC1120_DEV_ADDR,	.name = "DEV_ADDR" },
	{ .addr = CC1120_SETTLING_CFG,	.name = "SETTLING_CFG" },
	{ .addr = CC1120_FS_CFG,	.name = "FS_CFG" },
	{ .addr = CC1120_WOR_CFG1,	.name = "WOR_CFG1" },
	{ .addr = CC1120_WOR_CFG0,	.name = "WOR_CFG0" },
	{ .addr = CC1120_WOR_EVENT0_MSB,	.name = "WOR_EVENT0_MSB" },
	{ .addr = CC1120_WOR_EVENT0_LSB,	.name = "WOR_EVENT0_LSB" },
	{ .addr = CC1120_PKT_CFG2,	.name = "PKT_CFG2" },
	{ .addr = CC1120_PKT_CFG1,	.name = "PKT_CFG1" },
	{ .addr = CC1120_PKT_CFG0,	.name = "PKT_CFG0" },
	{ .addr = CC1120_RFEND_CFG1,	.name = "RFEND_CFG1" },
	{ .addr = CC1120_RFEND_CFG0,	.name = "RFEND_CFG0" },
	{ .addr = CC1120_PA_CFG2,	.name = "PA_CFG2" },
	{ .addr = CC1120_PA_CFG1,	.name = "PA_CFG1" },
	{ .addr = CC1120_PA_CFG0,	.name = "PA_CFG0" },
	{ .addr = CC1120_PKT_LEN,	.name = "PKT_LEN" },
	{ .addr = CC1120_IF_MIX_CFG,	.name = "IF_MIX_CFG" },
	{ .addr = CC1120_FREQOFF_CFG,	.name = "FREQOFF_CFG" },
	{ .addr = CC1120_TOC_CFG,	.name = "TOC_CFG" },
	{ .addr = CC1120_MARC_SPARE,	.name = "MARC_SPARE" },
	{ .addr = CC1120_ECG_CFG,	.name = "ECG_CFG" },
	{ .addr = CC1120_SOFT_TX_DATA_CFG,	.name = "SOFT_TX_DATA_CFG" },
	{ .addr = CC1120_EXT_CTRL,	.name = "EXT_CTRL" },
	{ .addr = CC1120_RCCAL_FINE,	.name = "RCCAL_FINE" },
	{ .addr = CC1120_RCCAL_COARSE,	.name = "RCCAL_COARSE" },
	{ .addr = CC1120_RCCAL_OFFSET,	.name = "RCCAL_OFFSET" },
	{ .addr = CC1120_FREQOFF1,	.name = "FREQOFF1" },
	{ .addr = CC1120_FREQOFF0,	.name = "FREQOFF0" },
	{ .addr = CC1120_FREQ2,	.name = "FREQ2" },
	{ .addr = CC1120_FREQ1,	.name = "FREQ1" },
	{ .addr = CC1120_FREQ0,	.name = "FREQ0" },
	{ .addr = CC1120_IF_ADC2,	.name = "IF_ADC2" },
	{ .addr = CC1120_IF_ADC1,	.name = "IF_ADC1" },
	{ .addr = CC1120_IF_ADC0,	.name = "IF_ADC0" },
	{ .addr = CC1120_FS_DIG1,	.name = "FS_DIG1" },
	{ .addr = CC1120_FS_DIG0,	.name = "FS_DIG0" },
	{ .addr = CC1120_FS_CAL3,	.name = "FS_CAL3" },
	{ .addr = CC1120_FS_CAL2,	.name = "FS_CAL2" },
	{ .addr = CC1120_FS_CAL1,	.name = "FS_CAL1" },
	{ .addr = CC1120_FS_CAL0,	.name = "FS_CAL0" },
	{ .addr = CC1120_FS_CHP,	.name = "FS_CHP" },
	{ .addr = CC1120_FS_DIVTWO,	.name = "FS_DIVTWO" },
	{ .addr = CC1120_FS_DSM1,	.name = "FS_DSM1" },
	{ .addr = CC1120_FS_DSM0,	.name = "FS_DSM0" },
	{ .addr = CC1120_FS_DVC1,	.name = "FS_DVC1" },
	{ .addr = CC1120_FS_DVC0,	.name = "FS_DVC0" },
	{ .addr = CC1120_FS_LBI,	.name = "FS_LBI" },
	{ .addr = CC1120_FS_PFD,	.name = "FS_PFD" },
	{ .addr = CC1120_FS_PRE,	.name = "FS_PRE" },
	{ .addr = CC1120_FS_REG_DIV_CML,	.name = "FS_REG_DIV_CML" },
	{ .addr = CC1120_FS_SPARE,	.name = "FS_SPARE" },
	{ .addr = CC1120_FS_VCO4,	.name = "FS_VCO4" },
	{ .addr = CC1120_FS_VCO3,	.name = "FS_VCO3" },
	{ .addr = CC1120_FS_VCO2,	.name = "FS_VCO2" },
	{ .addr = CC1120_FS_VCO1,	.name = "FS_VCO1" },
	{ .addr = CC1120_FS_VCO0,	.name = "FS_VCO0" },
	{ .addr = CC1120_GBIAS6,	.name = "GBIAS6" },
	{ .addr = CC1120_GBIAS5,	.name = "GBIAS5" },
	{ .addr = CC1120_GBIAS4,	.name = "GBIAS4" },
	{ .addr = CC1120_GBIAS3,	.name = "GBIAS3" },
	{ .addr = CC1120_GBIAS2,	.name = "GBIAS2" },
	{ .addr = CC1120_GBIAS1,	.name = "GBIAS1" },
	{ .addr = CC1120_GBIAS0,	.name = "GBIAS0" },
	{ .addr = CC1120_IFAMP,	.name = "IFAMP" },
	{ .addr = CC1120_LNA,	.name = "LNA" },
	{ .addr = CC1120_RXMIX,	.name = "RXMIX" },
	{ .addr = CC1120_XOSC5,	.name = "XOSC5" },
	{ .addr = CC1120_XOSC4,	.name = "XOSC4" },
	{ .addr = CC1120_XOSC3,	.name = "XOSC3" },
	{ .addr = CC1120_XOSC2,	.name = "XOSC2" },
	{ .addr = CC1120_XOSC1,	.name = "XOSC1" },
	{ .addr = CC1120_XOSC0,	.name = "XOSC0" },
	{ .addr = CC1120_ANALOG_SPARE,	.name = "ANALOG_SPARE" },
	{ .addr = CC1120_PA_CFG3,	.name = "PA_CFG3" },
	{ .addr = CC1120_WOR_TIME1,	.name = "WOR_TIME1" },
	{ .addr = CC1120_WOR_TIME0,	.name = "WOR_TIME0" },
	{ .addr = CC1120_WOR_CAPTURE1,	.name = "WOR_CAPTURE1" },
	{ .addr = CC1120_WOR_CAPTURE0,	.name = "WOR_CAPTURE0" },
	{ .addr = CC1120_BIST,	.name = "BIST" },
	{ .addr = CC1120_DCFILTOFFSET_I1,	.name = "DCFILTOFFSET_I1" },
	{ .addr = CC1120_DCFILTOFFSET_I0,	.name = "DCFILTOFFSET_I0" },
	{ .addr = CC1120_DCFILTOFFSET_Q1,	.name = "DCFILTOFFSET_Q1" },
	{ .addr = CC1120_DCFILTOFFSET_Q0,	.name = "DCFILTOFFSET_Q0" },
	{ .addr = CC1120_IQIE_I1,	.name = "IQIE_I1" },
	{ .addr = CC1120_IQIE_I0,	.name = "IQIE_I0" },
	{ .addr = CC1120_IQIE_Q1,	.name = "IQIE_Q1" },
	{ .addr = CC1120_IQIE_Q0,	.name = "IQIE_Q0" },
	{ .addr = CC1120_RSSI1,	.name = "RSSI1" },
	{ .addr = CC1120_RSSI0,	.name = "RSSI0" },
	{ .addr = CC1120_MARCSTATE,	.name = "MARCSTATE" },
	{ .addr = CC1120_LQI_VAL,	.name = "LQI_VAL" },
	{ .addr = CC1120_PQT_SYNC_ERR,	.name = "PQT_SYNC_ERR" },
	{ .addr = CC1120_DEM_STATUS,	.name = "DEM_STATUS" },
	{ .addr = CC1120_FREQOFF_EST1,	.name = "FREQOFF_EST1" },
	{ .addr = CC1120_FREQOFF_EST0,	.name = "FREQOFF_EST0" },
	{ .addr = CC1120_AGC_GAIN3,	.name = "AGC_GAIN3" },
	{ .addr = CC1120_AGC_GAIN2,	.name = "AGC_GAIN2" },
	{ .addr = CC1120_AGC_GAIN1,	.name = "AGC_GAIN1" },
	{ .addr = CC1120_AGC_GAIN0,	.name = "AGC_GAIN0" },
	{ .addr = CC1120_SOFT_RX_DATA_OUT,	.name = "SOFT_RX_DATA_OUT" },
	{ .addr = CC1120_SOFT_TX_DATA_IN,	.name = "SOFT_TX_DATA_IN" },
	{ .addr = CC1120_ASK_SOFT_RX_DATA,	.name = "ASK_SOFT_RX_DATA" },
	{ .addr = CC1120_RNDGEN,	.name = "RNDGEN" },
	{ .addr = CC1120_MAGN2,	.name = "MAGN2" },
	{ .addr = CC1120_MAGN1,	.name = "MAGN1" },
	{ .addr = CC1120_MAGN0,	.name = "MAGN0" },
	{ .addr = CC1120_ANG1,	.name = "ANG1" },
	{ .addr = CC1120_ANG0,	.name = "ANG0" },
	{ .addr = CC1120_CHFILT_I2,	.name = "CHFILT_I2" },
	{ .addr = CC1120_CHFILT_I1,	.name = "CHFILT_I1" },
	{ .addr = CC1120_CHFILT_I0,	.name = "CHFILT_I0" },
	{ .addr = CC1120_CHFILT_Q2,	.name = "CHFILT_Q2" },
	{ .addr = CC1120_CHFILT_Q1,	.name = "CHFILT_Q1" },
	{ .addr = CC1120_CHFILT_Q0,	.name = "CHFILT_Q0" },
	{ .addr = CC1120_GPIO_STATUS,	.name = "GPIO_STATUS" },
	{ .addr = CC1120_FSCAL_CTRL,	.name = "FSCAL_CTRL" },
	{ .addr = CC1120_PHASE_ADJUST,	.name = "PHASE_ADJUST" },
	{ .addr = CC1120_PARTNUMBER,	.name = "PARTNUMBER" },
	{ .addr = CC1120_PARTVERSION,	.name = "PARTVERSION" },
	{ .addr = CC1120_SERIAL_STATUS,	.name = "SERIAL_STATUS" },
	{ .addr = CC1120_RX_STATUS,	.name = "RX_STATUS" },
	{ .addr = CC1120_TX_STATUS,	.name = "TX_STATUS" },
	{ .addr = CC1120_MARC_STATUS1,	.name = "MARC_STATUS1" },
	{ .addr = CC1120_MARC_STATUS0,	.name = "MARC_STATUS0" },
	{ .addr = CC1120_PA_IFAMP_TEST,	.name = "PA_IFAMP_TEST" },
	{ .addr = CC1120_FSRF_TEST,	.name = "FSRF_TEST" },
	{ .addr = CC1120_PRE_TEST,	.name = "PRE_TEST" },
	{ .addr = CC1120_PRE_OVR,	.name = "PRE_OVR" },
	{ .addr = CC1120_ADC_TEST,	.name = "ADC_TEST" },
	{ .addr = CC1120_DVC_TEST,	.name = "DVC_TEST" },
	{ .addr = CC1120_ATEST,	.name = "ATEST" },
	{ .addr = CC1120_ATEST_LVDS,	.name = "ATEST_LVDS" },
	{ .addr = CC1120_ATEST_MODE,	.name = "ATEST_MODE" },
	{ .addr = CC1120_XOSC_TEST1,	.name = "XOSC_TEST1" },
	{ .addr = CC1120_XOSC_TEST0,	.name = "XOSC_TEST0" },
	{ .addr = CC1120_RXFIRST,	.name = "RXFIRST" },
	{ .addr = CC1120_TXFIRST,	.name = "TXFIRST" },
	{ .addr = CC1120_RXLAST,	.name = "RXLAST" },
	{ .addr = CC1120_TXLAST,	.name = "TXLAST" },
	{ .addr = CC1120_NUM_TXBYTES,	.name = "NUM_TXBYTES" },
	{ .addr = CC1120_NUM_RXBYTES,	.name = "NUM_RXBYTES" },
	{ .addr = CC1120_FIFO_NUM_TXBYTES,	.name = "FIFO_NUM_TXBYTES" },
	{ .addr = CC1120_FIFO_NUM_RXBYTES,	.name = "FIFO_NUM_RXBYTES" },
};

#define AO_NUM_CC1120_REG	(sizeof ao_cc1120_reg / sizeof ao_cc1120_reg[0])

static void ao_radio_show(void) {
	uint8_t	status = ao_radio_status();
	int	i;

	ao_radio_get(0xff);
	status = ao_radio_status();
	printf ("Status:   %02x\n", status);
	printf ("CHIP_RDY: %d\n", (status >> CC1120_STATUS_CHIP_RDY) & 1);
	printf ("STATE:    %s\n", cc1120_state_name[(status >> CC1120_STATUS_STATE) & CC1120_STATUS_STATE_MASK]);
	printf ("MARC:     %02x\n", ao_radio_marc_status());

	for (i = 0; i < AO_NUM_CC1120_REG; i++)
		printf ("\t%02x %-20.20s\n", ao_radio_reg_read(ao_cc1120_reg[i].addr), ao_cc1120_reg[i].name);
	ao_radio_put();
}

static void ao_radio_beep(void) {
	ao_radio_rdf(RDF_PACKET_LEN);
}

static void ao_radio_packet(void) {
	static const uint8_t packet[] = {
#if 1
		0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
		0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
		0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
		0x00, 0x01, 0x02, 0x03, 0x04, 0x05, 0x06, 0x07,
#else
		3, 1, 2, 3
#endif
	};

	ao_radio_send(packet, sizeof (packet));
}

void
ao_radio_test_recv()
{
	uint8_t	bytes[34];
	uint8_t	b;

	if (ao_radio_recv(bytes, 34)) {
		if (bytes[33] & 0x80)
			printf ("CRC OK");
		else
			printf ("CRC BAD");
		printf (" RSSI %d", AO_RSSI_FROM_RADIO(bytes[32]));
		for (b = 0; b < 32; b++)
			printf (" %02x", bytes[b]);
		printf ("\n");
	}
}

#endif

static const struct ao_cmds ao_radio_cmds[] = {
	{ ao_radio_test_cmd,	"C <1 start, 0 stop, none both>\0Radio carrier test" },
#if CC1120_DEBUG
	{ ao_radio_show,	"R\0Show CC1120 status" },
	{ ao_radio_beep,	"b\0Emit an RDF beacon" },
	{ ao_radio_packet,	"p\0Send a test packet" },
	{ ao_radio_test_recv,	"q\0Recv a test packet" },
#endif
	{ 0, NULL }
};

void
ao_radio_init(void)
{
	int	i;

	ao_radio_configured = 0;
	ao_spi_init_cs (AO_CC1120_SPI_CS_PORT, (1 << AO_CC1120_SPI_CS_PIN));

#if 0
	AO_CC1120_SPI_CS_PORT->bsrr = ((uint32_t) (1 << AO_CC1120_SPI_CS_PIN));
	for (i = 0; i < 10000; i++) {
		if ((SPI_2_PORT->idr & (1 << SPI_2_MISO_PIN)) == 0)
			break;
	}
	AO_CC1120_SPI_CS_PORT->bsrr = (1 << AO_CC1120_SPI_CS_PIN);
	if (i == 10000)
		ao_panic(AO_PANIC_SELF_TEST_CC1120);
#endif

	/* Enable the EXTI interrupt for the appropriate pin */
	ao_enable_port(AO_CC1120_INT_PORT);
	ao_exti_setup(AO_CC1120_INT_PORT, AO_CC1120_INT_PIN,
		      AO_EXTI_MODE_FALLING|AO_EXTI_PRIORITY_HIGH,
		      ao_radio_tx_isr);

	ao_cmd_register(&ao_radio_cmds[0]);
}