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# include <AP_HAL/AP_HAL.h>
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# if HAL_RCINPUT_WITH_AP_RADIO
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# include <AP_Math/AP_Math.h>
# if CONFIG_HAL_BOARD == HAL_BOARD_PX4
# include <board_config.h>
# endif
# include "AP_Radio_cypress.h"
# include <utility>
# include <stdio.h>
# include <StorageManager/StorageManager.h>
# include <AP_HAL/utility/dsm.h>
# include <AP_Math/crc.h>
# include "telem_structure.h"
# include <AP_Notify/AP_Notify.h>
# include <GCS_MAVLink/GCS_MAVLink.h>
/*
driver for CYRF6936 radio
Many thanks to the SuperBitRF project from Paparrazi for their DSM
configuration code and register defines
https : //github.com/esden/superbitrf-firmware
*/
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# if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
static THD_WORKING_AREA ( _irq_handler_wa , 512 ) ;
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# define TIMEOUT_PRIORITY 181
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# define EVT_TIMEOUT EVENT_MASK(0)
# define EVT_IRQ EVENT_MASK(1)
# endif
# ifndef CYRF_SPI_DEVICE
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# define CYRF_SPI_DEVICE "cypress"
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# endif
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# ifndef CYRF_IRQ_INPUT
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# define CYRF_IRQ_INPUT (GPIO_INPUT|GPIO_FLOAT|GPIO_EXTI|GPIO_PORTD|GPIO_PIN15)
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# endif
# ifndef CYRF_RESET_PIN
# define CYRF_RESET_PIN (GPIO_OUTPUT|GPIO_PUSHPULL|GPIO_EXTI|GPIO_PORTB|GPIO_PIN0)
# endif
extern const AP_HAL : : HAL & hal ;
# define Debug(level, fmt, args...) do { if ((level) <= get_debug_level()) { hal.console->printf(fmt, ##args); }} while (0)
# define LP_FIFO_SIZE 16 // Physical data FIFO lengths in Radio
/* The SPI interface defines */
enum {
CYRF_CHANNEL = 0x00 ,
CYRF_TX_LENGTH = 0x01 ,
CYRF_TX_CTRL = 0x02 ,
CYRF_TX_CFG = 0x03 ,
CYRF_TX_IRQ_STATUS = 0x04 ,
CYRF_RX_CTRL = 0x05 ,
CYRF_RX_CFG = 0x06 ,
CYRF_RX_IRQ_STATUS = 0x07 ,
CYRF_RX_STATUS = 0x08 ,
CYRF_RX_COUNT = 0x09 ,
CYRF_RX_LENGTH = 0x0A ,
CYRF_PWR_CTRL = 0x0B ,
CYRF_XTAL_CTRL = 0x0C ,
CYRF_IO_CFG = 0x0D ,
CYRF_GPIO_CTRL = 0x0E ,
CYRF_XACT_CFG = 0x0F ,
CYRF_FRAMING_CFG = 0x10 ,
CYRF_DATA32_THOLD = 0x11 ,
CYRF_DATA64_THOLD = 0x12 ,
CYRF_RSSI = 0x13 ,
CYRF_EOP_CTRL = 0x14 ,
CYRF_CRC_SEED_LSB = 0x15 ,
CYRF_CRC_SEED_MSB = 0x16 ,
CYRF_TX_CRC_LSB = 0x17 ,
CYRF_TX_CRC_MSB = 0x18 ,
CYRF_RX_CRC_LSB = 0x19 ,
CYRF_RX_CRC_MSB = 0x1A ,
CYRF_TX_OFFSET_LSB = 0x1B ,
CYRF_TX_OFFSET_MSB = 0x1C ,
CYRF_MODE_OVERRIDE = 0x1D ,
CYRF_RX_OVERRIDE = 0x1E ,
CYRF_TX_OVERRIDE = 0x1F ,
CYRF_TX_BUFFER = 0x20 ,
CYRF_RX_BUFFER = 0x21 ,
CYRF_SOP_CODE = 0x22 ,
CYRF_DATA_CODE = 0x23 ,
CYRF_PREAMBLE = 0x24 ,
CYRF_MFG_ID = 0x25 ,
CYRF_XTAL_CFG = 0x26 ,
CYRF_CLK_OFFSET = 0x27 ,
CYRF_CLK_EN = 0x28 ,
CYRF_RX_ABORT = 0x29 ,
CYRF_AUTO_CAL_TIME = 0x32 ,
CYRF_AUTO_CAL_OFFSET = 0x35 ,
CYRF_ANALOG_CTRL = 0x39 ,
} ;
# define CYRF_DIR (1<<7) /**< Bit for enabling writing */
// CYRF_MODE_OVERRIDE
# define CYRF_RST (1<<0)
// CYRF_CLK_EN
# define CYRF_RXF (1<<1)
// CYRF_XACT_CFG
enum {
CYRF_MODE_SLEEP = ( 0x0 < < 2 ) ,
CYRF_MODE_IDLE = ( 0x1 < < 2 ) ,
CYRF_MODE_SYNTH_TX = ( 0x2 < < 2 ) ,
CYRF_MODE_SYNTH_RX = ( 0x3 < < 2 ) ,
CYRF_MODE_RX = ( 0x4 < < 2 ) ,
} ;
# define CYRF_FRC_END (1<<5)
# define CYRF_ACK_EN (1<<7)
// CYRF_IO_CFG
# define CYRF_IRQ_GPIO (1<<0)
# define CYRF_SPI_3PIN (1<<1)
# define CYRF_PACTL_GPIO (1<<2)
# define CYRF_PACTL_OD (1<<3)
# define CYRF_XOUT_OD (1<<4)
# define CYRF_MISO_OD (1<<5)
# define CYRF_IRQ_POL (1<<6)
# define CYRF_IRQ_OD (1<<7)
// CYRF_FRAMING_CFG
# define CYRF_LEN_EN (1<<5)
# define CYRF_SOP_LEN (1<<6)
# define CYRF_SOP_EN (1<<7)
// CYRF_RX_STATUS
enum {
CYRF_RX_DATA_MODE_GFSK = 0x00 ,
CYRF_RX_DATA_MODE_8DR = 0x01 ,
CYRF_RX_DATA_MODE_DDR = 0x10 ,
CYRF_RX_DATA_MODE_NV = 0x11 ,
} ;
# define CYRF_RX_CODE (1<<2)
# define CYRF_BAD_CRC (1<<3)
# define CYRF_CRC0 (1<<4)
# define CYRF_EOP_ERR (1<<5)
# define CYRF_PKT_ERR (1<<6)
# define CYRF_RX_ACK (1<<7)
// CYRF_TX_IRQ_STATUS
# define CYRF_TXE_IRQ (1<<0)
# define CYRF_TXC_IRQ (1<<1)
# define CYRF_TXBERR_IRQ (1<<2)
# define CYRF_TXB0_IRQ (1<<3)
# define CYRF_TXB8_IRQ (1<<4)
# define CYRF_TXB15_IRQ (1<<5)
# define CYRF_LV_IRQ (1<<6)
# define CYRF_OS_IRQ (1<<7)
// CYRF_RX_IRQ_STATUS
# define CYRF_RXE_IRQ (1<<0)
# define CYRF_RXC_IRQ (1<<1)
# define CYRF_RXBERR_IRQ (1<<2)
# define CYRF_RXB1_IRQ (1<<3)
# define CYRF_RXB8_IRQ (1<<4)
# define CYRF_RXB16_IRQ (1<<5)
# define CYRF_SOPDET_IRQ (1<<6)
# define CYRF_RXOW_IRQ (1<<7)
// CYRF_TX_CTRL
# define CYRF_TXE_IRQEN (1<<0)
# define CYRF_TXC_IRQEN (1<<1)
# define CYRF_TXBERR_IRQEN (1<<2)
# define CYRF_TXB0_IRQEN (1<<3)
# define CYRF_TXB8_IRQEN (1<<4)
# define CYRF_TXB15_IRQEN (1<<5)
# define CYRF_TX_CLR (1<<6)
# define CYRF_TX_GO (1<<7)
// CYRF_RX_CTRL
# define CYRF_RXE_IRQEN (1<<0)
# define CYRF_RXC_IRQEN (1<<1)
# define CYRF_RXBERR_IRQEN (1<<2)
# define CYRF_RXB1_IRQEN (1<<3)
# define CYRF_RXB8_IRQEN (1<<4)
# define CYRF_RXB16_IRQEN (1<<5)
# define CYRF_RSVD (1<<6)
# define CYRF_RX_GO (1<<7)
// CYRF_RX_OVERRIDE
# define CYRF_ACE (1<<1)
# define CYRF_DIS_RXCRC (1<<2)
# define CYRF_DIS_CRC0 (1<<3)
# define CYRF_FRC_RXDR (1<<4)
# define CYRF_MAN_RXACK (1<<5)
# define CYRF_RXTX_DLY (1<<6)
# define CYRF_ACK_RX (1<<7)
// CYRF_TX_OVERRIDE
# define CYRF_TX_INV (1<<0)
# define CYRF_DIS_TXCRC (1<<2)
# define CYRF_OVRD_ACK (1<<3)
# define CYRF_MAN_TXACK (1<<4)
# define CYRF_FRC_PRE (1<<6)
# define CYRF_ACK_TX (1<<7)
// CYRF_RX_CFG
# define CYRF_VLD_EN (1<<0)
# define CYRF_RXOW_EN (1<<1)
# define CYRF_FAST_TURN_EN (1<<3)
# define CYRF_HILO (1<<4)
# define CYRF_ATT (1<<5)
# define CYRF_LNA (1<<6)
# define CYRF_AGC_EN (1<<7)
// CYRF_TX_CFG
enum {
CYRF_PA_M35 = 0x0 ,
CYRF_PA_M30 = 0x1 ,
CYRF_PA_M24 = 0x2 ,
CYRF_PA_M18 = 0x3 ,
CYRF_PA_M13 = 0x4 ,
CYRF_PA_M5 = 0x5 ,
CYRF_PA_0 = 0x6 ,
CYRF_PA_4 = 0x7 ,
} ;
enum {
CYRF_DATA_MODE_GFSK = ( 0x0 < < 3 ) ,
CYRF_DATA_MODE_8DR = ( 0x1 < < 3 ) ,
CYRF_DATA_MODE_DDR = ( 0x2 < < 3 ) ,
CYRF_DATA_MODE_SDR = ( 0x3 < < 3 ) ,
} ;
# define CYRF_DATA_CODE_LENGTH (1<<5)
# define FLAG_WRITE 0x80
# define FLAG_AUTO_INC 0x40
# define DSM_MAX_CHANNEL 0x4F
# define DSM_SCAN_MIN_CH 8
# define DSM_SCAN_MID_CH 40
# define DSM_SCAN_MAX_CH 70
# define FCC_SUPPORT_CW_MODE 0
# define AUTOBIND_CHANNEL 12
// object instance for trampoline
AP_Radio_cypress * AP_Radio_cypress : : radio_instance ;
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# if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
thread_t * AP_Radio_cypress : : _irq_handler_ctx ;
# endif
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/*
constructor
*/
AP_Radio_cypress : : AP_Radio_cypress ( AP_Radio & _radio ) :
AP_Radio_backend ( _radio )
{
// link to instance for irq_trampoline
radio_instance = this ;
}
/*
initialise radio
*/
bool AP_Radio_cypress : : init ( void )
{
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dev = hal . spi - > get_device ( CYRF_SPI_DEVICE ) ;
# if CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
if ( _irq_handler_ctx ! = nullptr ) {
AP_HAL : : panic ( " AP_Radio_cypress: double instantiation of irq_handler \n " ) ;
}
chVTObjectInit ( & timeout_vt ) ;
_irq_handler_ctx = chThdCreateStatic ( _irq_handler_wa ,
sizeof ( _irq_handler_wa ) ,
TIMEOUT_PRIORITY , /* Initial priority. */
irq_handler_thd , /* Thread function. */
NULL ) ; /* Thread parameter. */
# endif
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load_bind_info ( ) ;
return reset ( ) ;
}
/*
reset radio
*/
bool AP_Radio_cypress : : reset ( void )
{
if ( ! dev - > get_semaphore ( ) - > take ( HAL_SEMAPHORE_BLOCK_FOREVER ) ) {
return false ;
}
/*
to reset radio hold reset high for 0.5 s , then low for 0.5 s
*/
# if CONFIG_HAL_BOARD == HAL_BOARD_PX4
stm32_configgpio ( CYRF_RESET_PIN ) ;
stm32_gpiowrite ( CYRF_RESET_PIN , 1 ) ;
hal . scheduler - > delay ( 500 ) ;
stm32_gpiowrite ( CYRF_RESET_PIN , 0 ) ;
hal . scheduler - > delay ( 500 ) ;
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// use AUX5 as radio IRQ pin
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stm32_configgpio ( CYRF_IRQ_INPUT ) ;
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# elif defined(HAL_GPIO_RADIO_RESET)
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hal . gpio - > write ( HAL_GPIO_RADIO_RESET , 1 ) ;
hal . scheduler - > delay ( 500 ) ;
hal . gpio - > write ( HAL_GPIO_RADIO_RESET , 0 ) ;
hal . scheduler - > delay ( 500 ) ;
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# endif
radio_init ( ) ;
dev - > get_semaphore ( ) - > give ( ) ;
if ( dsm . protocol = = DSM_NONE & &
get_autobind_time ( ) = = 0 ) {
start_recv_bind ( ) ;
}
return true ;
}
/*
return statistics structure from radio
*/
const AP_Radio : : stats & AP_Radio_cypress : : get_stats ( void )
{
return stats ;
}
/*
read one pwm channel from radio
*/
uint16_t AP_Radio_cypress : : read ( uint8_t chan )
{
if ( dsm . need_bind_save ) {
save_bind_info ( ) ;
}
if ( chan > = max_channels ) {
return 0 ;
}
return dsm . pwm_channels [ chan ] ;
}
/*
update status - called from main thread
*/
void AP_Radio_cypress : : update ( void )
{
check_fw_ack ( ) ;
}
/*
print one second debug info
*/
void AP_Radio_cypress : : print_debug_info ( void )
{
Debug ( 2 , " recv:%3u bad:%3u to:%3u re:%u N:%2u TXI:%u TX:%u 1:%4u 2:%4u 3:%4u 4:%4u 5:%4u 6:%4u 7:%4u 8:%4u 14:%u \n " ,
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unsigned ( stats . recv_packets - last_stats . recv_packets ) ,
unsigned ( stats . bad_packets - last_stats . bad_packets ) ,
unsigned ( stats . timeouts - last_stats . timeouts ) ,
unsigned ( stats . recv_errors - last_stats . recv_errors ) ,
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num_channels ( ) ,
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unsigned ( dsm . send_irq_count ) ,
unsigned ( dsm . send_count ) ,
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dsm . pwm_channels [ 0 ] , dsm . pwm_channels [ 1 ] , dsm . pwm_channels [ 2 ] , dsm . pwm_channels [ 3 ] ,
dsm . pwm_channels [ 4 ] , dsm . pwm_channels [ 5 ] , dsm . pwm_channels [ 6 ] , dsm . pwm_channels [ 7 ] ,
dsm . pwm_channels [ 13 ] ) ;
}
/*
return number of active channels
*/
uint8_t AP_Radio_cypress : : num_channels ( void )
{
uint32_t now = AP_HAL : : millis ( ) ;
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uint8_t chan = get_rssi_chan ( ) ;
if ( chan > 0 ) {
dsm . pwm_channels [ chan - 1 ] = dsm . rssi ;
dsm . num_channels = MAX ( dsm . num_channels , chan ) ;
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}
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chan = get_pps_chan ( ) ;
if ( chan > 0 ) {
dsm . pwm_channels [ chan - 1 ] = t_status . pps ;
dsm . num_channels = MAX ( dsm . num_channels , chan ) ;
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}
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chan = get_tx_rssi_chan ( ) ;
if ( chan > 0 ) {
dsm . pwm_channels [ chan - 1 ] = dsm . tx_rssi ;
dsm . num_channels = MAX ( dsm . num_channels , chan ) ;
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}
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chan = get_tx_pps_chan ( ) ;
if ( chan > 0 ) {
dsm . pwm_channels [ chan - 1 ] = dsm . tx_pps ;
dsm . num_channels = MAX ( dsm . num_channels , chan ) ;
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}
if ( now - last_debug_print_ms > 1000 ) {
last_debug_print_ms = now ;
if ( get_debug_level ( ) > 1 ) {
print_debug_info ( ) ;
}
t_status . pps = stats . recv_packets - last_stats . recv_packets ;
t_status . rssi = ( uint8_t ) dsm . rssi ;
last_stats = stats ;
}
return dsm . num_channels ;
}
/*
send a fwupload ack if needed
*/
void AP_Radio_cypress : : check_fw_ack ( void )
{
Debug ( 4 , " check need_ack \n " ) ;
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if ( fwupload . need_ack & & sem . take_nonblocking ( ) ) {
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// ack the send of a DATA96 fw packet to TX
fwupload . need_ack = false ;
uint8_t data16 [ 16 ] { } ;
uint32_t ack_to = fwupload . offset + fwupload . acked ;
memcpy ( & data16 [ 0 ] , & ack_to , 4 ) ;
mavlink_msg_data16_send ( fwupload . chan , 42 , 4 , data16 ) ;
Debug ( 4 , " sent ack DATA16 \n " ) ;
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sem . give ( ) ;
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}
}
/*
return time of last receive in microseconds
*/
uint32_t AP_Radio_cypress : : last_recv_us ( void )
{
// we use the parse time, so it matches when channel values are filled in
return dsm . last_parse_us ;
}
/*
send len bytes as a single packet
*/
bool AP_Radio_cypress : : send ( const uint8_t * pkt , uint16_t len )
{
// disabled for now
return false ;
}
/* The PN codes */
const uint8_t AP_Radio_cypress : : pn_codes [ 5 ] [ 9 ] [ 8 ] = {
{ /* Row 0 */
/* Col 0 */ { 0x03 , 0xBC , 0x6E , 0x8A , 0xEF , 0xBD , 0xFE , 0xF8 } ,
/* Col 1 */ { 0x88 , 0x17 , 0x13 , 0x3B , 0x2D , 0xBF , 0x06 , 0xD6 } ,
/* Col 2 */ { 0xF1 , 0x94 , 0x30 , 0x21 , 0xA1 , 0x1C , 0x88 , 0xA9 } ,
/* Col 3 */ { 0xD0 , 0xD2 , 0x8E , 0xBC , 0x82 , 0x2F , 0xE3 , 0xB4 } ,
/* Col 4 */ { 0x8C , 0xFA , 0x47 , 0x9B , 0x83 , 0xA5 , 0x66 , 0xD0 } ,
/* Col 5 */ { 0x07 , 0xBD , 0x9F , 0x26 , 0xC8 , 0x31 , 0x0F , 0xB8 } ,
/* Col 6 */ { 0xEF , 0x03 , 0x95 , 0x89 , 0xB4 , 0x71 , 0x61 , 0x9D } ,
/* Col 7 */ { 0x40 , 0xBA , 0x97 , 0xD5 , 0x86 , 0x4F , 0xCC , 0xD1 } ,
/* Col 8 */ { 0xD7 , 0xA1 , 0x54 , 0xB1 , 0x5E , 0x89 , 0xAE , 0x86 }
} ,
{ /* Row 1 */
/* Col 0 */ { 0x83 , 0xF7 , 0xA8 , 0x2D , 0x7A , 0x44 , 0x64 , 0xD3 } ,
/* Col 1 */ { 0x3F , 0x2C , 0x4E , 0xAA , 0x71 , 0x48 , 0x7A , 0xC9 } ,
/* Col 2 */ { 0x17 , 0xFF , 0x9E , 0x21 , 0x36 , 0x90 , 0xC7 , 0x82 } ,
/* Col 3 */ { 0xBC , 0x5D , 0x9A , 0x5B , 0xEE , 0x7F , 0x42 , 0xEB } ,
/* Col 4 */ { 0x24 , 0xF5 , 0xDD , 0xF8 , 0x7A , 0x77 , 0x74 , 0xE7 } ,
/* Col 5 */ { 0x3D , 0x70 , 0x7C , 0x94 , 0xDC , 0x84 , 0xAD , 0x95 } ,
/* Col 6 */ { 0x1E , 0x6A , 0xF0 , 0x37 , 0x52 , 0x7B , 0x11 , 0xD4 } ,
/* Col 7 */ { 0x62 , 0xF5 , 0x2B , 0xAA , 0xFC , 0x33 , 0xBF , 0xAF } ,
/* Col 8 */ { 0x40 , 0x56 , 0x32 , 0xD9 , 0x0F , 0xD9 , 0x5D , 0x97 }
} ,
{ /* Row 2 */
/* Col 0 */ { 0x40 , 0x56 , 0x32 , 0xD9 , 0x0F , 0xD9 , 0x5D , 0x97 } ,
/* Col 1 */ { 0x8E , 0x4A , 0xD0 , 0xA9 , 0xA7 , 0xFF , 0x20 , 0xCA } ,
/* Col 2 */ { 0x4C , 0x97 , 0x9D , 0xBF , 0xB8 , 0x3D , 0xB5 , 0xBE } ,
/* Col 3 */ { 0x0C , 0x5D , 0x24 , 0x30 , 0x9F , 0xCA , 0x6D , 0xBD } ,
/* Col 4 */ { 0x50 , 0x14 , 0x33 , 0xDE , 0xF1 , 0x78 , 0x95 , 0xAD } ,
/* Col 5 */ { 0x0C , 0x3C , 0xFA , 0xF9 , 0xF0 , 0xF2 , 0x10 , 0xC9 } ,
/* Col 6 */ { 0xF4 , 0xDA , 0x06 , 0xDB , 0xBF , 0x4E , 0x6F , 0xB3 } ,
/* Col 7 */ { 0x9E , 0x08 , 0xD1 , 0xAE , 0x59 , 0x5E , 0xE8 , 0xF0 } ,
/* Col 8 */ { 0xC0 , 0x90 , 0x8F , 0xBB , 0x7C , 0x8E , 0x2B , 0x8E }
} ,
{ /* Row 3 */
/* Col 0 */ { 0xC0 , 0x90 , 0x8F , 0xBB , 0x7C , 0x8E , 0x2B , 0x8E } ,
/* Col 1 */ { 0x80 , 0x69 , 0x26 , 0x80 , 0x08 , 0xF8 , 0x49 , 0xE7 } ,
/* Col 2 */ { 0x7D , 0x2D , 0x49 , 0x54 , 0xD0 , 0x80 , 0x40 , 0xC1 } ,
/* Col 3 */ { 0xB6 , 0xF2 , 0xE6 , 0x1B , 0x80 , 0x5A , 0x36 , 0xB4 } ,
/* Col 4 */ { 0x42 , 0xAE , 0x9C , 0x1C , 0xDA , 0x67 , 0x05 , 0xF6 } ,
/* Col 5 */ { 0x9B , 0x75 , 0xF7 , 0xE0 , 0x14 , 0x8D , 0xB5 , 0x80 } ,
/* Col 6 */ { 0xBF , 0x54 , 0x98 , 0xB9 , 0xB7 , 0x30 , 0x5A , 0x88 } ,
/* Col 7 */ { 0x35 , 0xD1 , 0xFC , 0x97 , 0x23 , 0xD4 , 0xC9 , 0x88 } ,
/* Col 8 */ { 0x88 , 0xE1 , 0xD6 , 0x31 , 0x26 , 0x5F , 0xBD , 0x40 }
} ,
{ /* Row 4 */
/* Col 0 */ { 0xE1 , 0xD6 , 0x31 , 0x26 , 0x5F , 0xBD , 0x40 , 0x93 } ,
/* Col 1 */ { 0xDC , 0x68 , 0x08 , 0x99 , 0x97 , 0xAE , 0xAF , 0x8C } ,
/* Col 2 */ { 0xC3 , 0x0E , 0x01 , 0x16 , 0x0E , 0x32 , 0x06 , 0xBA } ,
/* Col 3 */ { 0xE0 , 0x83 , 0x01 , 0xFA , 0xAB , 0x3E , 0x8F , 0xAC } ,
/* Col 4 */ { 0x5C , 0xD5 , 0x9C , 0xB8 , 0x46 , 0x9C , 0x7D , 0x84 } ,
/* Col 5 */ { 0xF1 , 0xC6 , 0xFE , 0x5C , 0x9D , 0xA5 , 0x4F , 0xB7 } ,
/* Col 6 */ { 0x58 , 0xB5 , 0xB3 , 0xDD , 0x0E , 0x28 , 0xF1 , 0xB0 } ,
/* Col 7 */ { 0x5F , 0x30 , 0x3B , 0x56 , 0x96 , 0x45 , 0xF4 , 0xA1 } ,
/* Col 8 */ { 0x03 , 0xBC , 0x6E , 0x8A , 0xEF , 0xBD , 0xFE , 0xF8 }
} ,
} ;
const uint8_t AP_Radio_cypress : : pn_bind [ ] = { 0x98 , 0x88 , 0x1B , 0xE4 , 0x30 , 0x79 , 0x03 , 0x84 } ;
/*The CYRF initial config, binding config and transfer config */
const AP_Radio_cypress : : config AP_Radio_cypress : : cyrf_config [ ] = {
{ CYRF_MODE_OVERRIDE , CYRF_RST } , // Reset the device
{ CYRF_CLK_EN , CYRF_RXF } , // Enable the clock
{ CYRF_AUTO_CAL_TIME , 0x3C } , // From manual, needed for initialization
{ CYRF_AUTO_CAL_OFFSET , 0x14 } , // From manual, needed for initialization
{ CYRF_RX_CFG , CYRF_LNA | CYRF_FAST_TURN_EN } , // Enable low noise amplifier and fast turning
{ CYRF_TX_OFFSET_LSB , 0x55 } , // From manual, typical configuration
{ CYRF_TX_OFFSET_MSB , 0x05 } , // From manual, typical configuration
{ CYRF_XACT_CFG , CYRF_MODE_SYNTH_RX | CYRF_FRC_END } , // Force in Synth RX mode
{ CYRF_TX_CFG , CYRF_DATA_CODE_LENGTH | CYRF_DATA_MODE_SDR | CYRF_PA_4 } , // Enable 64 chip codes, SDR mode and amplifier +4dBm
{ CYRF_DATA64_THOLD , 0x0E } , // From manual, typical configuration
{ CYRF_XACT_CFG , CYRF_MODE_SYNTH_RX } , // Set in Synth RX mode (again, really needed?)
{ CYRF_IO_CFG , CYRF_IRQ_POL } , // IRQ active high
} ;
const AP_Radio_cypress : : config AP_Radio_cypress : : cyrf_bind_config [ ] = {
{ CYRF_TX_CFG , CYRF_DATA_CODE_LENGTH | CYRF_DATA_MODE_SDR | CYRF_PA_4 } , // Enable 64 chip codes, SDR mode and amplifier +4dBm
{ CYRF_FRAMING_CFG , CYRF_SOP_LEN | 0xE } , // Set SOP CODE to 64 chips and SOP Correlator Threshold to 0xE
{ CYRF_RX_OVERRIDE , CYRF_FRC_RXDR | CYRF_DIS_RXCRC } , // Force receive data rate and disable receive CRC checker
{ CYRF_EOP_CTRL , 0x02 } , // Only enable EOP symbol count of 2
{ CYRF_TX_OVERRIDE , CYRF_DIS_TXCRC } , // Disable transmit CRC generate
} ;
const AP_Radio_cypress : : config AP_Radio_cypress : : cyrf_transfer_config [ ] = {
{ CYRF_TX_CFG , CYRF_DATA_CODE_LENGTH | CYRF_DATA_MODE_8DR | CYRF_PA_4 } , // Enable 64 chip codes, 8DR mode and amplifier +4dBm
{ CYRF_FRAMING_CFG , CYRF_SOP_EN | CYRF_SOP_LEN | CYRF_LEN_EN | 0xE } , // Set SOP CODE enable, SOP CODE to 64 chips, Packet length enable, and SOP Correlator Threshold to 0xE
{ CYRF_TX_OVERRIDE , 0x00 } , // Reset TX overrides
{ CYRF_RX_OVERRIDE , 0x00 } , // Reset RX overrides
} ;
/*
read radio status , handling the race condition between completion and error
*/
uint8_t AP_Radio_cypress : : read_status_debounced ( uint8_t adr )
{
uint8_t ret ;
dev - > set_chip_select ( true ) ;
ret = read_register ( adr ) ;
// If COMPLETE and ERROR bits mismatch, then re-read register
if ( ( ret & ( CYRF_RXC_IRQ | CYRF_RXE_IRQ ) ) ! = 0
& & ( ret & ( CYRF_RXC_IRQ | CYRF_RXE_IRQ ) ) ! = ( CYRF_RXC_IRQ | CYRF_RXE_IRQ ) ) {
uint8_t v2 ;
dev - > read ( & v2 , 1 ) ;
ret | = v2 ; // re-read and make bits sticky
}
dev - > set_chip_select ( false ) ;
return ret ;
}
/*
force the initial state of the radio
*/
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void AP_Radio_cypress : : force_initial_state ( void )
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{
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while ( true ) {
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write_register ( CYRF_XACT_CFG , CYRF_FRC_END ) ;
uint32_t start_ms = AP_HAL : : millis ( ) ;
do {
if ( ( read_register ( CYRF_XACT_CFG ) & CYRF_FRC_END ) = = 0 ) {
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return ; // FORCE_END done (osc running)
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}
} while ( AP_HAL : : millis ( ) - start_ms < 5 ) ;
// FORCE_END failed to complete, implying going SLEEP to IDLE and
// oscillator failed to start. Recover by returning to SLEEP and
// trying to start oscillator again.
write_register ( CYRF_XACT_CFG , CYRF_MODE_SLEEP ) ;
}
}
/*
set desired channel
*/
void AP_Radio_cypress : : set_channel ( uint8_t channel )
{
if ( dsm . forced_channel ! = - 1 ) {
channel = dsm . forced_channel ;
}
write_register ( CYRF_CHANNEL , channel ) ;
}
void AP_Radio_cypress : : radio_set_config ( const struct config * conf , uint8_t size )
{
// setup required radio config
for ( uint8_t i = 0 ; i < size ; i + + ) {
write_register ( conf [ i ] . reg , conf [ i ] . value ) ;
}
}
/*
initialise the radio
*/
void AP_Radio_cypress : : radio_init ( void )
{
Debug ( 1 , " Cypress: radio_init starting \n " ) ;
// wait for radio to settle
uint16_t i ;
for ( i = 0 ; i < 1000 ; i + + ) {
uint8_t chan = read_register ( CYRF_CHANNEL ) ;
if ( chan = = 1 ) {
break ;
}
write_register ( CYRF_CHANNEL , 1 ) ;
hal . scheduler - > delay ( 10 ) ;
}
if ( i = = 1000 ) {
Debug ( 1 , " Cypress: radio_init failed \n " ) ;
return ;
}
// base config
radio_set_config ( cyrf_config , ARRAY_SIZE ( cyrf_config ) ) ;
// start with receive config
radio_set_config ( cyrf_transfer_config , ARRAY_SIZE ( cyrf_transfer_config ) ) ;
if ( get_disable_crc ( ) ) {
write_register ( CYRF_RX_OVERRIDE , CYRF_DIS_RXCRC ) ;
}
dsm_setup_transfer_dsmx ( ) ;
write_register ( CYRF_XTAL_CTRL , 0x80 ) ; // XOUT=BitSerial
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force_initial_state ( ) ;
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write_register ( CYRF_PWR_CTRL , 0x20 ) ; // Disable PMU
// start in RECV state
state = STATE_RECV ;
Debug ( 1 , " Cypress: radio_init done \n " ) ;
start_receive ( ) ;
// setup handler for rising edge of IRQ pin
# if CONFIG_HAL_BOARD == HAL_BOARD_PX4
stm32_gpiosetevent ( CYRF_IRQ_INPUT , true , false , false , irq_radio_trampoline ) ;
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# elif CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
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hal . gpio - > attach_interrupt ( HAL_GPIO_RADIO_IRQ , trigger_irq_radio_event , AP_HAL : : GPIO : : INTERRUPT_RISING ) ;
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# endif
}
void AP_Radio_cypress : : dump_registers ( uint8_t n )
{
for ( uint8_t i = 0 ; i < n ; i + + ) {
uint8_t v = read_register ( i ) ;
printf ( " %02x:%02x " , i , v ) ;
if ( ( i + 1 ) % 16 = = 0 ) {
printf ( " \n " ) ;
}
}
if ( n % 16 ! = 0 ) {
printf ( " \n " ) ;
}
}
/*
read one register value
*/
uint8_t AP_Radio_cypress : : read_register ( uint8_t reg )
{
uint8_t v = 0 ;
( void ) dev - > read_registers ( reg , & v , 1 ) ;
return v ;
}
/*
write multiple bytes
*/
void AP_Radio_cypress : : write_multiple ( uint8_t reg , uint8_t n , const uint8_t * data )
{
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uint8_t pkt [ n + 1 ] ;
pkt [ 0 ] = reg | FLAG_WRITE ;
memcpy ( & pkt [ 1 ] , data , n ) ;
dev - > transfer ( pkt , n + 1 , nullptr , 0 ) ;
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}
/*
write one register value
*/
void AP_Radio_cypress : : write_register ( uint8_t reg , uint8_t value )
{
dev - > write_register ( reg | FLAG_WRITE , value ) ;
}
/*
support all 4 rc input modes by swapping channels .
*/
void AP_Radio_cypress : : map_stick_mode ( uint16_t * channels )
{
switch ( get_stick_mode ( ) ) {
case 1 : {
// mode1
uint16_t tmp = channels [ 1 ] ;
channels [ 1 ] = 3000 - channels [ 2 ] ;
channels [ 2 ] = 3000 - tmp ;
break ;
}
case 3 : {
// mode3
uint16_t tmp = channels [ 1 ] ;
channels [ 1 ] = 3000 - channels [ 2 ] ;
channels [ 2 ] = 3000 - tmp ;
tmp = channels [ 0 ] ;
channels [ 0 ] = channels [ 3 ] ;
channels [ 3 ] = tmp ;
break ;
}
case 4 : {
// mode4
uint16_t tmp = channels [ 0 ] ;
channels [ 0 ] = channels [ 3 ] ;
channels [ 3 ] = tmp ;
break ;
}
case 2 :
default :
// nothing to do, transmitter is natively mode2
break ;
}
}
/*
check if we are the 2 nd RX bound to this TX
*/
void AP_Radio_cypress : : check_double_bind ( void )
{
if ( dsm . tx_pps < = dsm . telem_send_count | |
get_autobind_time ( ) = = 0 ) {
return ;
}
// the TX has received more telemetry packets in the last second
// than we have ever sent. There must be another RX sending
// telemetry packets. We will reset our mfg_id and go back waiting
// for a new bind packet, hopefully with the right TX
Debug ( 1 , " Double-bind detected \n " ) ;
memset ( dsm . mfg_id , 1 , sizeof ( dsm . mfg_id ) ) ;
dsm . last_recv_us = 0 ;
dsm_setup_transfer_dsmx ( ) ;
}
/*
parse channels from a packet
*/
bool AP_Radio_cypress : : parse_dsm_channels ( const uint8_t * data )
{
uint16_t num_values = 0 ;
uint16_t pwm_channels [ max_channels ] { } ;
// default value for channels above 4 is previous value
memcpy ( & pwm_channels [ 4 ] , & dsm . pwm_channels [ 4 ] , ( max_channels - 4 ) * sizeof ( uint16_t ) ) ;
if ( ! dsm_decode ( AP_HAL : : micros64 ( ) ,
data ,
pwm_channels ,
& num_values ,
ARRAY_SIZE ( pwm_channels ) ) ) {
// invalid packet
Debug ( 2 , " DSM: bad decode \n " ) ;
return false ;
}
if ( num_values < 5 ) {
Debug ( 2 , " DSM: num_values=%u \n " , num_values ) ;
return false ;
}
// cope with mode1/mode2
map_stick_mode ( pwm_channels ) ;
memcpy ( dsm . pwm_channels , pwm_channels , num_values * sizeof ( uint16_t ) ) ;
dsm . last_parse_us = AP_HAL : : micros ( ) ;
// suppress channel 8 ack values
dsm . num_channels = num_values = = 8 ? 7 : num_values ;
if ( num_values = = 8 ) {
// decode telemetry ack value and version
uint16_t d = 0 ;
if ( is_DSM2 ( ) ) {
d = data [ 14 ] < < 8 | data [ 15 ] ;
} else {
// see chan_order[] for DSMX
d = data [ 10 ] < < 8 | data [ 11 ] ;
}
// extra data is sent on channel 8, with 3 bit key and 8 bit data
uint8_t chan = d > > 11 ;
uint8_t key = ( d > > 8 ) & 0x7 ;
uint8_t v = d & 0xFF ;
if ( chan = = 7 & & key = = 0 ) {
// got an ack from key 0
Debug ( 4 , " ack %u seq=%u acked=%u length=%u len=%u \n " ,
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v , fwupload . sequence , unsigned ( fwupload . acked ) , unsigned ( fwupload . length ) , fwupload . len ) ;
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if ( fwupload . sequence = = v & & sem . take_nonblocking ( ) ) {
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fwupload . sequence + + ;
fwupload . acked + = fwupload . len ;
if ( fwupload . acked = = fwupload . length ) {
// trigger send of DATA16 ack to client
fwupload . need_ack = true ;
}
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sem . give ( ) ;
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}
}
if ( chan = = 7 ) {
// extract telemetry extra data
switch ( key ) {
case 1 :
dsm . tx_firmware_year = v ;
break ;
case 2 :
dsm . tx_firmware_month = v ;
break ;
case 3 :
dsm . tx_firmware_day = v ;
break ;
case 4 :
dsm . tx_rssi = v ;
break ;
case 5 :
dsm . tx_pps = v ;
dsm . have_tx_pps = true ;
check_double_bind ( ) ;
break ;
case 6 :
if ( v ! = dsm . tx_bl_version ) {
if ( v = = 2 ) {
// TX with new filter gets a default power of 6
set_tx_max_power_default ( 6 ) ;
}
}
dsm . tx_bl_version = v ;
break ;
}
}
}
return true ;
}
/*
process an incoming bind packet
*/
void AP_Radio_cypress : : process_bind ( const uint8_t * pkt , uint8_t len )
{
if ( len ! = 16 ) {
return ;
}
bool ok = ( len = = 16 & & pkt [ 0 ] = = pkt [ 4 ] & & pkt [ 1 ] = = pkt [ 5 ] & & pkt [ 2 ] = = pkt [ 6 ] & & pkt [ 3 ] = = pkt [ 7 ] ) ;
// Calculate the first sum
uint16_t bind_sum = 384 - 0x10 ;
for ( uint8_t i = 0 ; i < 8 ; i + + ) {
bind_sum + = pkt [ i ] ;
}
// Check the first sum
if ( pkt [ 8 ] ! = bind_sum > > 8 | | pkt [ 9 ] ! = ( bind_sum & 0xFF ) ) {
ok = false ;
}
// Calculate second sum
for ( uint8_t i = 8 ; i < 14 ; i + + ) {
bind_sum + = pkt [ i ] ;
}
// Check the second sum
if ( pkt [ 14 ] ! = bind_sum > > 8 | | pkt [ 15 ] ! = ( bind_sum & 0xFF ) ) {
ok = false ;
}
if ( state = = STATE_AUTOBIND ) {
uint8_t rssi = read_register ( CYRF_RSSI ) & 0x1F ;
Debug ( 3 , " bind RSSI %u \n " , rssi ) ;
if ( rssi < get_autobind_rssi ( ) ) {
ok = false ;
}
}
if ( ok ) {
uint8_t mfg_id [ 4 ] = { uint8_t ( ~ pkt [ 0 ] ) , uint8_t ( ~ pkt [ 1 ] ) , uint8_t ( ~ pkt [ 2 ] ) , uint8_t ( ~ pkt [ 3 ] ) } ;
uint8_t num_chan = pkt [ 11 ] ;
uint8_t protocol = pkt [ 12 ] ;
( void ) num_chan ;
// change to normal receive
memcpy ( dsm . mfg_id , mfg_id , 4 ) ;
state = STATE_RECV ;
radio_set_config ( cyrf_transfer_config , ARRAY_SIZE ( cyrf_transfer_config ) ) ;
if ( get_disable_crc ( ) ) {
write_register ( CYRF_RX_OVERRIDE , CYRF_DIS_RXCRC ) ;
}
dsm . protocol = ( enum dsm_protocol ) protocol ;
dsm_setup_transfer_dsmx ( ) ;
Debug ( 1 , " BIND OK: mfg_id={0x%02x, 0x%02x, 0x%02x, 0x%02x} N=%u P=0x%02x DSM2=%u \n " ,
mfg_id [ 0 ] , mfg_id [ 1 ] , mfg_id [ 2 ] , mfg_id [ 3 ] ,
num_chan ,
protocol ,
is_DSM2 ( ) ) ;
dsm . last_recv_us = AP_HAL : : micros ( ) ;
if ( is_DSM2 ( ) ) {
dsm2_start_sync ( ) ;
}
dsm . need_bind_save = true ;
}
}
/*
start DSM2 sync
*/
void AP_Radio_cypress : : dsm2_start_sync ( void )
{
uint8_t factory_test = get_factory_test ( ) ;
if ( factory_test ! = 0 ) {
dsm . channels [ 0 ] = ( factory_test * 7 ) % DSM_MAX_CHANNEL ;
dsm . channels [ 1 ] = ( dsm . channels [ 0 ] + 5 ) % DSM_MAX_CHANNEL ;
dsm . sync = DSM2_OK ;
} else {
Debug ( 2 , " DSM2 start sync \n " ) ;
dsm . sync = DSM2_SYNC_A ;
}
}
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/*
setup a timeout in timeout_ms milliseconds
*/
void AP_Radio_cypress : : setup_timeout ( uint32_t timeout_ms )
{
# if CONFIG_HAL_BOARD == HAL_BOARD_PX4
hrt_call_after ( & wait_call , timeout_ms * 1000 , ( hrt_callout ) irq_timeout_trampoline , nullptr ) ;
# elif CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
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chVTSet ( & timeout_vt , chTimeMS2I ( timeout_ms ) , trigger_timeout_event , nullptr ) ;
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# endif
}
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/*
process an incoming packet
*/
void AP_Radio_cypress : : process_packet ( const uint8_t * pkt , uint8_t len )
{
if ( len = = 16 ) {
bool ok ;
const uint8_t * id = dsm . mfg_id ;
uint32_t now = AP_HAL : : micros ( ) ;
if ( is_DSM2 ( ) ) {
ok = ( pkt [ 0 ] = = ( ( ~ id [ 2 ] ) & 0xFF ) & & pkt [ 1 ] = = ( ~ id [ 3 ] & 0xFF ) ) ;
} else {
ok = ( pkt [ 0 ] = = id [ 2 ] & & pkt [ 1 ] = = id [ 3 ] ) ;
}
if ( ok & & is_DSM2 ( ) & & dsm . sync < DSM2_OK ) {
if ( dsm . sync = = DSM2_SYNC_A ) {
dsm . channels [ 0 ] = dsm . current_rf_channel ;
dsm . sync = DSM2_SYNC_B ;
Debug ( 2 , " DSM2 SYNCA chan=%u \n " , dsm . channels [ 0 ] ) ;
dsm . last_recv_us = now ;
} else {
if ( dsm . current_rf_channel ! = dsm . channels [ 0 ] ) {
dsm . channels [ 1 ] = dsm . current_rf_channel ;
dsm . sync = DSM2_OK ;
Debug ( 2 , " DSM2 SYNCB chan=%u \n " , dsm . channels [ 1 ] ) ;
dsm . last_recv_us = now ;
}
}
return ;
}
if ( ok & & ( ! is_DSM2 ( ) | | dsm . sync > = DSM2_SYNC_B ) ) {
ok = parse_dsm_channels ( pkt ) ;
}
if ( ok ) {
uint32_t packet_dt_us = now - dsm . last_recv_us ;
dsm . last_recv_chan = dsm . current_channel ;
dsm . last_recv_us = now ;
if ( dsm . crc_errors > 2 ) {
dsm . crc_errors - = 2 ;
}
stats . recv_packets + + ;
// sample the RSSI
uint8_t rssi = read_register ( CYRF_RSSI ) & 0x1F ;
dsm . rssi = 0.95 * dsm . rssi + 0.05 * rssi ;
if ( packet_dt_us < 5000 ) {
dsm . pkt_time1 = packet_dt_us ;
} else if ( packet_dt_us < 8000 ) {
dsm . pkt_time2 = packet_dt_us ;
}
if ( get_telem_enable ( ) ) {
if ( packet_dt_us < 5000 & &
( get_autobind_time ( ) = = 0 | | dsm . have_tx_pps ) ) {
/*
we have just received two packets rapidly , which
means we have about 7 ms before the next
one . That gives time for a telemetry packet . We
send it 1 ms after we receive the incoming packet
If auto - bind is enabled we don ' t send telemetry
till we ' ve received a tx_pps value from the
TX . This allows us to detect double binding ( two
RX bound to the same TX )
*/
state = STATE_SEND_TELEM ;
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setup_timeout ( 1 ) ;
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}
}
} else {
stats . bad_packets + + ;
}
} else {
stats . bad_packets + + ;
}
}
/*
start packet receive
*/
void AP_Radio_cypress : : start_receive ( void )
{
dsm_choose_channel ( ) ;
write_register ( CYRF_RX_IRQ_STATUS , CYRF_RXOW_IRQ ) ;
write_register ( CYRF_RX_CTRL , CYRF_RX_GO | CYRF_RXC_IRQEN | CYRF_RXE_IRQEN ) ;
dsm . receive_start_us = AP_HAL : : micros ( ) ;
if ( state = = STATE_AUTOBIND ) {
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dsm . receive_timeout_msec = 90 ;
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} else if ( state = = STATE_BIND ) {
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dsm . receive_timeout_msec = 15 ;
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} else {
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dsm . receive_timeout_msec = 12 ;
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}
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setup_timeout ( dsm . receive_timeout_msec ) ;
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}
/*
handle a receive IRQ
*/
void AP_Radio_cypress : : irq_handler_recv ( uint8_t rx_status )
{
if ( ( rx_status & ( CYRF_RXC_IRQ | CYRF_RXE_IRQ ) ) = = 0 ) {
// nothing interesting yet
return ;
}
uint8_t pkt [ 16 ] ;
uint8_t rlen = read_register ( CYRF_RX_COUNT ) ;
if ( rlen > 16 ) {
rlen = 16 ;
}
if ( rlen > 0 ) {
dev - > read_registers ( CYRF_RX_BUFFER , pkt , rlen ) ;
}
if ( rx_status & CYRF_RXE_IRQ ) {
uint8_t reason = read_register ( CYRF_RX_STATUS ) ;
if ( reason & CYRF_BAD_CRC ) {
dsm . crc_errors + + ;
if ( dsm . crc_errors > 20 ) {
Debug ( 2 , " Flip CRC \n " ) ;
// flip crc seed, this allows us to resync with transmitter
dsm . crc_seed = ~ dsm . crc_seed ;
dsm . crc_errors = 0 ;
}
}
write_register ( CYRF_XACT_CFG , CYRF_MODE_SYNTH_RX | CYRF_FRC_END ) ;
write_register ( CYRF_RX_ABORT , 0 ) ;
stats . recv_errors + + ;
} else if ( rx_status & CYRF_RXC_IRQ ) {
if ( state = = STATE_RECV ) {
process_packet ( pkt , rlen ) ;
} else {
process_bind ( pkt , rlen ) ;
}
}
if ( state = = STATE_AUTOBIND ) {
state = STATE_RECV ;
}
if ( state ! = STATE_SEND_TELEM ) {
start_receive ( ) ;
}
}
/*
handle a send IRQ
*/
void AP_Radio_cypress : : irq_handler_send ( uint8_t tx_status )
{
if ( ( tx_status & ( CYRF_TXC_IRQ | CYRF_TXE_IRQ ) ) = = 0 ) {
// nothing interesting yet
return ;
}
state = STATE_RECV ;
start_receive ( ) ;
}
/*
IRQ handler
*/
void AP_Radio_cypress : : irq_handler ( void )
{
//hal.console->printf("IRQ\n");
if ( ! dev - > get_semaphore ( ) - > take_nonblocking ( ) ) {
// we have to wait for timeout instead
return ;
}
// always read both rx and tx status. This ensure IRQ is cleared
uint8_t rx_status = read_status_debounced ( CYRF_RX_IRQ_STATUS ) ;
uint8_t tx_status = read_status_debounced ( CYRF_TX_IRQ_STATUS ) ;
switch ( state ) {
case STATE_AUTOBIND :
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FALLTHROUGH ;
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case STATE_RECV :
case STATE_BIND :
irq_handler_recv ( rx_status ) ;
break ;
case STATE_SEND_TELEM :
case STATE_SEND_TELEM_WAIT :
irq_handler_send ( tx_status ) ;
break ;
case STATE_SEND_FCC :
// stop transmit oscillator
write_register ( CYRF_RX_IRQ_STATUS , CYRF_RXOW_IRQ ) ;
write_register ( CYRF_RX_CTRL , CYRF_RX_GO | CYRF_RXC_IRQEN | CYRF_RXE_IRQEN ) ;
break ;
default :
break ;
}
dev - > get_semaphore ( ) - > give ( ) ;
}
/*
called on radio timeout
*/
void AP_Radio_cypress : : irq_timeout ( void )
{
stats . timeouts + + ;
if ( ! dev - > get_semaphore ( ) - > take_nonblocking ( ) ) {
// schedule a new timeout
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setup_timeout ( dsm . receive_timeout_msec ) ;
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return ;
}
if ( get_fcc_test ( ) ! = 0 & & state ! = STATE_SEND_FCC ) {
Debug ( 3 , " Starting FCC test \n " ) ;
state = STATE_SEND_FCC ;
} else if ( get_fcc_test ( ) = = 0 & & state = = STATE_SEND_FCC ) {
Debug ( 3 , " Ending FCC test \n " ) ;
state = STATE_RECV ;
}
switch ( state ) {
case STATE_SEND_TELEM :
send_telem_packet ( ) ;
break ;
case STATE_SEND_FCC :
send_FCC_test_packet ( ) ;
break ;
case STATE_AUTOBIND :
case STATE_SEND_TELEM_WAIT :
state = STATE_RECV ;
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FALLTHROUGH ;
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default :
write_register ( CYRF_XACT_CFG , CYRF_MODE_SYNTH_RX | CYRF_FRC_END ) ;
write_register ( CYRF_RX_ABORT , 0 ) ;
start_receive ( ) ;
break ;
}
dev - > get_semaphore ( ) - > give ( ) ;
}
/*
called on rising edge of radio IRQ pin
*/
# if CONFIG_HAL_BOARD == HAL_BOARD_PX4
int AP_Radio_cypress : : irq_radio_trampoline ( int irq , void * context )
{
radio_instance - > irq_handler ( ) ;
return 0 ;
}
# endif
/*
called on HRT timeout
*/
# if CONFIG_HAL_BOARD == HAL_BOARD_PX4
int AP_Radio_cypress : : irq_timeout_trampoline ( int irq , void * context )
{
radio_instance - > irq_timeout ( ) ;
return 0 ;
}
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# elif CONFIG_HAL_BOARD == HAL_BOARD_CHIBIOS
void AP_Radio_cypress : : irq_handler_thd ( void * arg )
{
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_irq_handler_ctx = chThdGetSelfX ( ) ;
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( void ) arg ;
while ( true ) {
eventmask_t evt = chEvtWaitAny ( ALL_EVENTS ) ;
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if ( evt & EVT_IRQ ) {
radio_instance - > irq_handler ( ) ;
}
if ( evt & EVT_TIMEOUT ) {
radio_instance - > irq_timeout ( ) ;
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}
}
}
void AP_Radio_cypress : : trigger_timeout_event ( void * arg )
{
( void ) arg ;
//we are called from ISR context
chSysLockFromISR ( ) ;
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if ( _irq_handler_ctx ) {
chEvtSignalI ( _irq_handler_ctx , EVT_TIMEOUT ) ;
}
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chSysUnlockFromISR ( ) ;
}
void AP_Radio_cypress : : trigger_irq_radio_event ( )
{
//we are called from ISR context
chSysLockFromISR ( ) ;
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if ( _irq_handler_ctx ) {
chEvtSignalI ( _irq_handler_ctx , EVT_IRQ ) ;
}
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chSysUnlockFromISR ( ) ;
}
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# endif
/*
Set the current DSM channel with SOP , CRC and data code
*/
void AP_Radio_cypress : : dsm_set_channel ( uint8_t channel , bool is_dsm2 , uint8_t sop_col , uint8_t data_col , uint16_t crc_seed )
{
//printf("dsm_set_channel: %u\n", channel);
uint8_t pn_row ;
pn_row = is_dsm2 ? channel % 5 : ( channel - 2 ) % 5 ;
// set CRC seed
write_register ( CYRF_CRC_SEED_LSB , crc_seed & 0xff ) ;
write_register ( CYRF_CRC_SEED_MSB , crc_seed > > 8 ) ;
// set start of packet code
if ( memcmp ( dsm . last_sop_code , pn_codes [ pn_row ] [ sop_col ] , 8 ) ! = 0 ) {
write_multiple ( CYRF_SOP_CODE , 8 , pn_codes [ pn_row ] [ sop_col ] ) ;
memcpy ( dsm . last_sop_code , pn_codes [ pn_row ] [ sop_col ] , 8 ) ;
}
// set data code
if ( memcmp ( dsm . last_data_code , pn_codes [ pn_row ] [ data_col ] , 16 ) ! = 0 ) {
write_multiple ( CYRF_DATA_CODE , 16 , pn_codes [ pn_row ] [ data_col ] ) ;
memcpy ( dsm . last_data_code , pn_codes [ pn_row ] [ data_col ] , 16 ) ;
}
if ( get_disable_crc ( ) ! = dsm . last_discrc ) {
dsm . last_discrc = get_disable_crc ( ) ;
Debug ( 3 , " Cypress: DISCRC=%u \n " , dsm . last_discrc ) ;
write_register ( CYRF_RX_OVERRIDE , dsm . last_discrc ? CYRF_DIS_RXCRC : 0 ) ;
}
if ( get_transmit_power ( ) ! = dsm . last_transmit_power + 1 ) {
dsm . last_transmit_power = get_transmit_power ( ) - 1 ;
Debug ( 3 , " Cypress: TXPOWER=%u \n " , dsm . last_transmit_power ) ;
write_register ( CYRF_TX_CFG , CYRF_DATA_CODE_LENGTH | CYRF_DATA_MODE_8DR | dsm . last_transmit_power ) ;
}
// Change channel
set_channel ( channel ) ;
}
/*
Generate the DSMX channels from the manufacturer ID
*/
void AP_Radio_cypress : : dsm_generate_channels_dsmx ( uint8_t mfg_id [ 4 ] , uint8_t channels [ 23 ] )
{
// Calculate the DSMX channels
int idx = 0 ;
uint32_t id = ~ ( ( mfg_id [ 0 ] < < 24 ) | ( mfg_id [ 1 ] < < 16 ) |
( mfg_id [ 2 ] < < 8 ) | ( mfg_id [ 3 ] < < 0 ) ) ;
uint32_t id_tmp = id ;
// While not all channels are set
while ( idx < 23 ) {
int i ;
int count_3_27 = 0 , count_28_51 = 0 , count_52_76 = 0 ;
id_tmp = id_tmp * 0x0019660D + 0x3C6EF35F ; // Randomization
uint8_t next_ch = ( ( id_tmp > > 8 ) % 0x49 ) + 3 ; // Use least-significant byte and must be larger than 3
if ( ( ( next_ch ^ id ) & 0x01 ) = = 0 ) {
continue ;
}
// Go trough all already set channels
for ( i = 0 ; i < idx ; i + + ) {
// Channel is already used
if ( channels [ i ] = = next_ch ) {
break ;
}
// Count the channel groups
if ( channels [ i ] < = 27 ) {
count_3_27 + + ;
} else if ( channels [ i ] < = 51 ) {
count_28_51 + + ;
} else {
count_52_76 + + ;
}
}
// When channel is already used continue
if ( i ! = idx ) {
continue ;
}
// Set the channel when channel groups aren't full
if ( ( next_ch < 28 & & count_3_27 < 8 ) // Channels 3-27: max 8
| | ( next_ch > = 28 & & next_ch < 52 & & count_28_51 < 7 ) // Channels 28-52: max 7
| | ( next_ch > = 52 & & count_52_76 < 8 ) ) { // Channels 52-76: max 8
channels [ idx + + ] = next_ch ;
}
}
Debug ( 2 , " Generated DSMX channels \n " ) ;
}
/*
setup for DSMX transfers
*/
void AP_Radio_cypress : : dsm_setup_transfer_dsmx ( void )
{
dsm . current_channel = 0 ;
dsm . crc_seed = ~ ( ( dsm . mfg_id [ 0 ] < < 8 ) + dsm . mfg_id [ 1 ] ) ;
dsm . sop_col = ( dsm . mfg_id [ 0 ] + dsm . mfg_id [ 1 ] + dsm . mfg_id [ 2 ] + 2 ) & 0x07 ;
dsm . data_col = 7 - dsm . sop_col ;
dsm_generate_channels_dsmx ( dsm . mfg_id , dsm . channels ) ;
}
/*
choose channel to receive on
*/
void AP_Radio_cypress : : dsm_choose_channel ( void )
{
uint32_t now = AP_HAL : : micros ( ) ;
uint32_t dt = now - dsm . last_recv_us ;
const uint32_t cycle_time = dsm . pkt_time1 + dsm . pkt_time2 ;
uint8_t next_channel ;
if ( state = = STATE_BIND ) {
if ( now - dsm . last_chan_change_us > 15000 ) {
// always use odd channel numbers for bind
dsm . current_rf_channel | = 1 ;
dsm . current_rf_channel = ( dsm . current_rf_channel + 2 ) % DSM_MAX_CHANNEL ;
dsm . last_chan_change_us = now ;
}
set_channel ( dsm . current_rf_channel ) ;
return ;
}
if ( get_autobind_time ( ) ! = 0 & &
dsm . last_recv_us = = 0 & &
now - dsm . last_autobind_send > 300 * 1000UL & &
now > get_autobind_time ( ) * 1000 * 1000UL & &
get_factory_test ( ) = = 0 & &
state = = STATE_RECV ) {
// try to receive an auto-bind packet
dsm_set_channel ( AUTOBIND_CHANNEL , true , 0 , 0 , 0 ) ;
state = STATE_AUTOBIND ;
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Debug ( 3 , " recv autobind %u \n " , unsigned ( now - dsm . last_autobind_send ) ) ;
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dsm . last_autobind_send = now ;
return ;
}
if ( is_DSM2 ( ) & & dsm . sync = = DSM2_SYNC_A ) {
if ( now - dsm . last_chan_change_us > 15000 ) {
// only even channels for DSM2 scan
dsm . current_rf_channel & = ~ 1 ;
dsm . current_rf_channel = ( dsm . current_rf_channel + 2 ) % DSM_MAX_CHANNEL ;
dsm . last_chan_change_us = now ;
}
//hal.console->printf("%u chan=%u\n", AP_HAL::micros(), dsm.current_rf_channel);
dsm_set_channel ( dsm . current_rf_channel , is_DSM2 ( ) ,
dsm . sop_col , dsm . data_col ,
dsm . sync = = DSM2_SYNC_B ? ~ dsm . crc_seed : dsm . crc_seed ) ;
return ;
}
if ( dt < 1000 ) {
// normal channel advance
next_channel = dsm . last_recv_chan + 1 ;
} else if ( dt > 20 * cycle_time ) {
// change channel slowly
next_channel = dsm . last_recv_chan + ( dt / ( cycle_time * 2 ) ) ;
} else {
// predict next channel
next_channel = dsm . last_recv_chan + 1 ;
next_channel + = ( dt / cycle_time ) * 2 ;
if ( dt % cycle_time > ( unsigned ) ( dsm . pkt_time1 + 1000U ) ) {
next_channel + + ;
}
}
uint8_t chan_count = is_DSM2 ( ) ? 2 : 23 ;
dsm . current_channel = next_channel ;
if ( dsm . current_channel > = chan_count ) {
dsm . current_channel % = chan_count ;
if ( ! is_DSM2 ( ) ) {
dsm . crc_seed = ~ dsm . crc_seed ;
}
}
if ( is_DSM2 ( ) & & dsm . sync = = DSM2_SYNC_B & & dsm . current_channel = = 1 ) {
// scan to next channelb
do {
dsm . channels [ 1 ] & = ~ 1 ;
dsm . channels [ 1 ] = ( dsm . channels [ 1 ] + 2 ) % DSM_MAX_CHANNEL ;
} while ( dsm . channels [ 1 ] = = dsm . channels [ 0 ] ) ;
}
dsm . current_rf_channel = dsm . channels [ dsm . current_channel ] ;
uint16_t seed = dsm . crc_seed ;
if ( dsm . current_channel & 1 ) {
seed = ~ seed ;
}
if ( is_DSM2 ( ) ) {
if ( now - dsm . last_recv_us > 5000000 ) {
dsm2_start_sync ( ) ;
}
}
dsm_set_channel ( dsm . current_rf_channel , is_DSM2 ( ) ,
dsm . sop_col , dsm . data_col , seed ) ;
}
/*
setup radio for bind
*/
void AP_Radio_cypress : : start_recv_bind ( void )
{
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if ( ! dev - > get_semaphore ( ) - > take ( 0 ) ) {
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// shouldn't be possible
return ;
}
Debug ( 1 , " Cypress: start_recv_bind \n " ) ;
write_register ( CYRF_XACT_CFG , CYRF_MODE_SYNTH_RX | CYRF_FRC_END ) ;
write_register ( CYRF_RX_ABORT , 0 ) ;
state = STATE_BIND ;
radio_set_config ( cyrf_bind_config , ARRAY_SIZE ( cyrf_bind_config ) ) ;
write_register ( CYRF_CRC_SEED_LSB , 0 ) ;
write_register ( CYRF_CRC_SEED_MSB , 0 ) ;
write_multiple ( CYRF_SOP_CODE , 8 , pn_codes [ 0 ] [ 0 ] ) ;
uint8_t data_code [ 16 ] ;
memcpy ( data_code , pn_codes [ 0 ] [ 8 ] , 8 ) ;
memcpy ( & data_code [ 8 ] , pn_bind , 8 ) ;
write_multiple ( CYRF_DATA_CODE , 16 , data_code ) ;
dsm . current_rf_channel = 1 ;
start_receive ( ) ;
dev - > get_semaphore ( ) - > give ( ) ;
}
/*
save bind info
*/
void AP_Radio_cypress : : save_bind_info ( void )
{
// access to storage for bind information
StorageAccess bind_storage ( StorageManager : : StorageBindInfo ) ;
struct bind_info info ;
info . magic = bind_magic ;
memcpy ( info . mfg_id , dsm . mfg_id , sizeof ( info . mfg_id ) ) ;
info . protocol = dsm . protocol ;
if ( bind_storage . write_block ( 0 , & info , sizeof ( info ) ) ) {
dsm . need_bind_save = false ;
}
}
/*
load bind info
*/
void AP_Radio_cypress : : load_bind_info ( void )
{
// access to storage for bind information
StorageAccess bind_storage ( StorageManager : : StorageBindInfo ) ;
struct bind_info info ;
uint8_t factory_test = get_factory_test ( ) ;
if ( factory_test ! = 0 ) {
Debug ( 1 , " In factory test %u \n " , factory_test ) ;
memset ( dsm . mfg_id , 0 , sizeof ( dsm . mfg_id ) ) ;
dsm . mfg_id [ 0 ] = factory_test ;
dsm . protocol = DSM_DSM2_2 ;
dsm2_start_sync ( ) ;
} else if ( bind_storage . read_block ( & info , 0 , sizeof ( info ) ) & & info . magic = = bind_magic ) {
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Debug ( 1 , " Loaded mfg_id %02x:%02x:%02x:%02x \n " ,
info . mfg_id [ 0 ] , info . mfg_id [ 1 ] , info . mfg_id [ 2 ] , info . mfg_id [ 3 ] ) ;
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memcpy ( dsm . mfg_id , info . mfg_id , sizeof ( info . mfg_id ) ) ;
dsm . protocol = info . protocol ;
}
}
bool AP_Radio_cypress : : is_DSM2 ( void )
{
if ( get_protocol ( ) ! = AP_Radio : : PROTOCOL_AUTO ) {
return get_protocol ( ) = = AP_Radio : : PROTOCOL_DSM2 ;
}
return dsm . protocol = = DSM_DSM2_1 | | dsm . protocol = = DSM_DSM2_2 ;
}
/*
transmit a 16 byte packet
this is a blind send , not waiting for ack or completion
*/
void AP_Radio_cypress : : transmit16 ( const uint8_t data [ 16 ] )
{
write_register ( CYRF_TX_LENGTH , 16 ) ;
write_register ( CYRF_TX_CTRL , CYRF_TX_CLR ) ;
write_multiple ( CYRF_TX_BUFFER , 16 , data ) ;
write_register ( CYRF_TX_CTRL , CYRF_TX_GO | CYRF_TXC_IRQEN ) ;
dsm . send_count + + ;
}
/*
send a telemetry structure packet
*/
void AP_Radio_cypress : : send_telem_packet ( void )
{
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struct telem_packet_cypress pkt ;
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t_status . flags = 0 ;
t_status . flags | = AP_Notify : : flags . gps_status > = 3 ? TELEM_FLAG_GPS_OK : 0 ;
t_status . flags | = AP_Notify : : flags . pre_arm_check ? TELEM_FLAG_ARM_OK : 0 ;
t_status . flags | = AP_Notify : : flags . failsafe_battery ? 0 : TELEM_FLAG_BATT_OK ;
t_status . flags | = hal . util - > get_soft_armed ( ) ? TELEM_FLAG_ARMED : 0 ;
t_status . flags | = AP_Notify : : flags . have_pos_abs ? TELEM_FLAG_POS_OK : 0 ;
t_status . flags | = AP_Notify : : flags . video_recording ? TELEM_FLAG_VIDEO : 0 ;
t_status . flight_mode = AP_Notify : : flags . flight_mode ;
t_status . tx_max = get_tx_max_power ( ) ;
t_status . note_adjust = get_tx_buzzer_adjust ( ) ;
// send fw update packet for 7/8 of packets if any data pending
if ( fwupload . length ! = 0 & &
fwupload . length > fwupload . acked & &
( ( fwupload . counter + + & 0x07 ) ! = 0 ) & &
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sem . take_nonblocking ( ) ) {
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pkt . type = fwupload . fw_type ;
pkt . payload . fw . seq = fwupload . sequence ;
uint32_t len = fwupload . length > fwupload . acked ? fwupload . length - fwupload . acked : 0 ;
pkt . payload . fw . len = len < = 8 ? len : 8 ;
pkt . payload . fw . offset = fwupload . offset + fwupload . acked ;
memcpy ( & pkt . payload . fw . data [ 0 ] , & fwupload . pending_data [ fwupload . acked ] , pkt . payload . fw . len ) ;
fwupload . len = pkt . payload . fw . len ;
Debug ( 4 , " sent fw seq=%u offset=%u len=%u type=%u \n " ,
pkt . payload . fw . seq ,
pkt . payload . fw . offset ,
pkt . payload . fw . len ,
pkt . type ) ;
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sem . give ( ) ;
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pkt . crc = crc_crc8 ( ( const uint8_t * ) & pkt . type , 15 ) ;
} else {
pkt . type = TELEM_STATUS ;
pkt . payload . status = t_status ;
pkt . crc = crc_crc8 ( ( const uint8_t * ) & pkt . type , 15 ) ;
dsm . telem_send_count + + ;
}
write_register ( CYRF_XACT_CFG , CYRF_MODE_SYNTH_TX | CYRF_FRC_END ) ;
write_register ( CYRF_RX_ABORT , 0 ) ;
transmit16 ( ( uint8_t * ) & pkt ) ;
state = STATE_SEND_TELEM_WAIT ;
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setup_timeout ( 2 ) ;
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}
/*
send a FCC test packet
*/
void AP_Radio_cypress : : send_FCC_test_packet ( void )
{
uint8_t pkt [ 16 ] = { 0 , 1 , 2 , 3 , 4 , 5 , 6 , 7 , 8 , 9 , 10 , 11 , 12 , 13 , 14 , 15 } ;
state = STATE_SEND_FCC ;
uint8_t channel = 0 ;
switch ( get_fcc_test ( ) ) {
case 0 :
// switch back to normal operation
dsm . forced_channel = - 1 ;
send_telem_packet ( ) ;
return ;
case 1 :
case 4 :
channel = DSM_SCAN_MIN_CH ;
break ;
case 2 :
case 5 :
channel = DSM_SCAN_MID_CH ;
break ;
case 3 :
case 6 :
default :
channel = DSM_SCAN_MAX_CH ;
break ;
}
Debug ( 5 , " FCC send %u \n " , channel ) ;
if ( channel ! = dsm . forced_channel ) {
Debug ( 1 , " FCC channel %u \n " , channel ) ;
dsm . forced_channel = channel ;
radio_set_config ( cyrf_config , ARRAY_SIZE ( cyrf_config ) ) ;
radio_set_config ( cyrf_transfer_config , ARRAY_SIZE ( cyrf_transfer_config ) ) ;
set_channel ( channel ) ;
}
# if FCC_SUPPORT_CW_MODE
if ( get_fcc_test ( ) > 3 ) {
// continuous preamble transmit is closest approximation to CW
// that is possible with this chip
write_register ( CYRF_PREAMBLE , 0x01 ) ;
write_register ( CYRF_PREAMBLE , 0x00 ) ;
write_register ( CYRF_PREAMBLE , 0x00 ) ;
write_register ( CYRF_TX_OVERRIDE , CYRF_FRC_PRE ) ;
write_register ( CYRF_TX_CTRL , CYRF_TX_GO ) ;
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setup_timeout ( 500 ) ;
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} else {
write_register ( CYRF_XACT_CFG , CYRF_MODE_SYNTH_TX | CYRF_FRC_END ) ;
write_register ( CYRF_RX_ABORT , 0 ) ;
transmit16 ( pkt ) ;
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setup_timeout ( 10 ) ;
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}
# else
write_register ( CYRF_XACT_CFG , CYRF_MODE_SYNTH_TX | CYRF_FRC_END ) ;
write_register ( CYRF_RX_ABORT , 0 ) ;
transmit16 ( pkt ) ;
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setup_timeout ( 10 ) ;
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# endif
}
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// handle a data96 mavlink packet for fw upload
void AP_Radio_cypress : : handle_data_packet ( mavlink_channel_t chan , const mavlink_data96_t & m )
{
uint32_t ofs = 0 ;
memcpy ( & ofs , & m . data [ 0 ] , 4 ) ;
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Debug ( 4 , " got data96 of len %u from chan %u at offset %u \n " , m . len , chan , unsigned ( ofs ) ) ;
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if ( sem . take_nonblocking ( ) ) {
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fwupload . chan = chan ;
fwupload . need_ack = false ;
fwupload . offset = ofs ;
fwupload . length = MIN ( m . len - 4 , 92 ) ;
fwupload . acked = 0 ;
fwupload . sequence + + ;
if ( m . type = = 43 ) {
// sending a tune to play - for development testing
fwupload . fw_type = TELEM_PLAY ;
fwupload . length = MIN ( m . len , 90 ) ;
fwupload . offset = 0 ;
memcpy ( & fwupload . pending_data [ 0 ] , & m . data [ 0 ] , fwupload . length ) ;
} else {
// sending a chunk of firmware OTA upload
fwupload . fw_type = TELEM_FW ;
memcpy ( & fwupload . pending_data [ 0 ] , & m . data [ 4 ] , fwupload . length ) ;
}
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sem . give ( ) ;
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}
}
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# endif // HAL_RCINPUT_WITH_AP_RADIO