QMK/lib/chibios-contrib/os/various/devices_lib/rf/nrf52_radio.h

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2020-03-23 10:48:11 +01:00
/* Copyright (c) 2014 Nordic Semiconductor. All Rights Reserved.
*
* The information contained herein is property of Nordic Semiconductor ASA.
* Terms and conditions of usage are described in detail in NORDIC
* SEMICONDUCTOR STANDARD SOFTWARE LICENSE AGREEMENT.
*
* Licensees are granted free, non-transferable use of the information. NO
* WARRANTY of ANY KIND is provided. This heading must NOT be removed from
* the file.
*
* @brief Enhanced ShockBurst (ESB) is a basic protocol supporting two-way data
* packet communication including packet buffering, packet acknowledgment
* and automatic retransmission of lost packets.
*
* ported on: 25/10/2018, by andru
*
*/
#ifndef NRF52_RADIO_H_
#define NRF52_RADIO_H_
// Hard coded parameters - change if necessary
#ifndef NRF52_MAX_PAYLOAD_LENGTH
#define NRF52_MAX_PAYLOAD_LENGTH 32 /**< The max size of the payload. Valid values are 1 to 252 */
#endif
#define NRF52_CRC_RESET_VALUE 0xFFFF /**< CRC reset value*/
#define NRF52_TX_FIFO_SIZE 8 /**< The size of the transmission first in first out buffer. */
#define NRF52_RX_FIFO_SIZE 8 /**< The size of the reception first in first out buffer. */
#define NRF52_RADIO_USE_TIMER0 FALSE /**< TIMER0 will be used by the module. */
#define NRF52_RADIO_USE_TIMER1 TRUE /**< TIMER1 will be used by the module. */
#define NRF52_RADIO_USE_TIMER2 FALSE /**< TIMER2 will be used by the module. */
#define NRF52_RADIO_USE_TIMER3 FALSE /**< TIMER3 will be used by the module. */
#define NRF52_RADIO_USE_TIMER4 FALSE /**< TIMER4 will be used by the module. */
#define NRF52_RADIO_IRQ_PRIORITY 3 /**< RADIO interrupt priority. */
#define NRF52_RADIO_INTTHD_PRIORITY (NORMALPRIO+2) /**< Interrupts handle thread priority. */
#define NRF52_RADIO_EVTTHD_PRIORITY (NORMALPRIO+1) /**< Events handle thread priority */
#define NRF52_RADIO_PPI_TIMER_START 10 /**< The PPI channel used for timer start. */
#define NRF52_RADIO_PPI_TIMER_STOP 11 /**< The PPI channel used for timer stop. */
#define NRF52_RADIO_PPI_RX_TIMEOUT 12 /**< The PPI channel used for RX timeout. */
#define NRF52_RADIO_PPI_TX_START 13 /**< The PPI channel used for starting TX. */
typedef enum {
NRF52_SUCCESS, /* Call was successful. */
NRF52_INVALID_STATE, /* Module is not initialized. */
NRF52_ERROR_BUSY, /* Module was not in idle state. */
NRF52_ERROR_NULL, /* Required parameter was NULL. */
NRF52_ERROR_INVALID_PARAM, /* Required parameter is invalid */
NRF52_ERROR_NOT_SUPPORTED, /* p_payload->noack was false while selective ack was not enabled. */
NRF52_ERROR_INVALID_LENGTH, /* Payload length was invalid (zero or larger than max allowed). */
} nrf52_error_t;
// Internal radio module state.
typedef enum {
NRF52_STATE_UNINIT, /**< Module not initialized. */
NRF52_STATE_IDLE, /**< Module idle. */
NRF52_STATE_PTX_TX, /**< Module transmitting without ack. */
NRF52_STATE_PTX_TX_ACK, /**< Module transmitting with ack. */
NRF52_STATE_PTX_RX_ACK, /**< Module transmitting with ack and reception of payload with the ack response. */
NRF52_STATE_PRX, /**< Module receiving packets without ack. */
NRF52_STATE_PRX_SEND_ACK, /**< Module transmitting ack in RX mode. */
} nrf52_state_t;
/**@brief Events to indicate the last transmission/receiving status. */
typedef enum {
NRF52_EVENT_TX_SUCCESS = 0x01, /**< Event triggered on TX success. */
NRF52_EVENT_TX_FAILED = 0x02, /**< Event triggered on TX failed. */
NRF52_EVENT_RX_RECEIVED = 0x04, /**< Event triggered on RX Received. */
} nrf52_event_t;
// Interrupt flags
typedef enum {
NRF52_INT_TX_SUCCESS_MSK = 0x01, /**< The flag used to indicate a success since last event. */
NRF52_INT_TX_FAILED_MSK = 0x02, /**< The flag used to indicate a failiure since last event. */
NRF52_INT_RX_DR_MSK = 0x04, /**< The flag used to indicate a received packet since last event. */
} nrf52_int_flags_t;
/**Macro to create initializer for a TX data packet.
*
* @details This macro generates an initializer. It is more efficient
* than setting the individual parameters dynamically.
*
* @param[in] _pipe The pipe to use for the data packet.
* @param[in] ... Comma separated list of character data to put in the TX buffer.
* Supported values are from 1 to 63 characters.
*
* @return Initializer that sets up pipe, length and the byte array for content of the TX data.
*/
#define NRF52_CREATE_PAYLOAD(_pipe, ...) \
{.pipe = _pipe, .length = NUM_VA_ARGS(__VA_ARGS__), .data = {__VA_ARGS__}}; \
STATIC_ASSERT(NUM_VA_ARGS(__VA_ARGS__) > 0 && NUM_VA_ARGS(__VA_ARGS__) <= 63)
/**@brief Enhanced ShockBurst protocol. */
typedef enum {
NRF52_PROTOCOL_ESB, /*< Enhanced ShockBurst with fixed payload length. */
NRF52_PROTOCOL_ESB_DPL /*< Enhanced ShockBurst with dynamic payload length. */
} nrf52_protocol_t;
/**@brief Enhanced ShockBurst mode. */
typedef enum {
NRF52_MODE_PTX, /*< Primary transmitter mode. */
NRF52_MODE_PRX /*< Primary receiver mode. */
} nrf52_mode_t;
/**@brief Enhanced ShockBurst bitrate mode. */
typedef enum {
NRF52_BITRATE_2MBPS = RADIO_MODE_MODE_Nrf_2Mbit, /**< 2Mbit radio mode. */
NRF52_BITRATE_1MBPS = RADIO_MODE_MODE_Nrf_1Mbit, /**< 1Mbit radio mode. */
} nrf52_bitrate_t;
/**@brief Enhanced ShockBurst CRC modes. */
typedef enum {
NRF52_CRC_16BIT = RADIO_CRCCNF_LEN_Two, /**< Use two byte CRC. */
NRF52_CRC_8BIT = RADIO_CRCCNF_LEN_One, /**< Use one byte CRC. */
NRF52_CRC_OFF = RADIO_CRCCNF_LEN_Disabled /**< Disable CRC. */
} nrf52_crc_t;
/**@brief Enhanced ShockBurst radio transmission power modes. */
typedef enum {
NRF52_TX_POWER_4DBM = RADIO_TXPOWER_TXPOWER_Pos4dBm, /**< 4 dBm radio transmit power. */
NRF52_TX_POWER_0DBM = RADIO_TXPOWER_TXPOWER_0dBm, /**< 0 dBm radio transmit power. */
NRF52_TX_POWER_NEG4DBM = RADIO_TXPOWER_TXPOWER_Neg4dBm, /**< -4 dBm radio transmit power. */
NRF52_TX_POWER_NEG8DBM = RADIO_TXPOWER_TXPOWER_Neg8dBm, /**< -8 dBm radio transmit power. */
NRF52_TX_POWER_NEG12DBM = RADIO_TXPOWER_TXPOWER_Neg12dBm, /**< -12 dBm radio transmit power. */
NRF52_TX_POWER_NEG16DBM = RADIO_TXPOWER_TXPOWER_Neg16dBm, /**< -16 dBm radio transmit power. */
NRF52_TX_POWER_NEG20DBM = RADIO_TXPOWER_TXPOWER_Neg20dBm, /**< -20 dBm radio transmit power. */
NRF52_TX_POWER_NEG30DBM = RADIO_TXPOWER_TXPOWER_Neg30dBm /**< -30 dBm radio transmit power. */
} nrf52_tx_power_t;
/**@brief Enhanced ShockBurst transmission modes. */
typedef enum {
NRF52_TXMODE_AUTO, /*< Automatic TX mode - When the TX fifo is non-empty and the radio is idle packets will be sent automatically. */
NRF52_TXMODE_MANUAL, /*< Manual TX mode - Packets will not be sent until radio_start_tx() is called. Can be used to ensure consistent packet timing. */
NRF52_TXMODE_MANUAL_START /*< Manual start TX mode - Packets will not be sent until radio_start_tx() is called, but transmission will continue automatically until the TX fifo is empty. */
} nrf52_tx_mode_t;
/**@brief Enhanced ShockBurst addresses.
*
* @details The module is able to transmit packets with the TX address stored in tx_address.
The module can also receive packets from peers with up to eight different tx_addresses
stored in esb_addr_p0 - esb_addr_p7. esb_addr_p0 can have 5 arbitrary bytes
independent of the other addresses. esb_addr_p1 - esb_addr_p7 will share the
same four byte base address found in the last four bytes of esb_addr_p1.
They have an independent prefix byte found in esb_addr_p1[0] and esb_addr_p2 -
esb_addr_p7.
*/
typedef struct {
uint8_t base_addr_p0[4]; /**< Base address for pipe 0 encoded in big endian. */
uint8_t base_addr_p1[4]; /**< Base address for pipe 1-7 encoded in big endian. */
uint8_t pipe_prefixes[8]; /**< Address prefix for pipe P0 to P7. */
uint8_t num_pipes; /**< Number of pipes available. */
uint8_t addr_length; /**< Length of address including prefix */
uint8_t rx_pipes; /**< Bitfield for enabled RX pipes. */
uint8_t rf_channel; /**< Which channel is to be used. Must be in range 0 and 125 to be valid. */
} nrf52_address_t;
/**@brief Enhanced ShockBurst payload.
*
* @note The payload is used both for transmission and receive with ack and payload.
*/
typedef struct
{
uint8_t length; /**< Length of the packet. Should be equal or less than NRF_ESB_MAX_PAYLOAD_LENGTH. */
uint8_t pipe; /**< Pipe used for this payload. */
int8_t rssi; /**< RSSI for received packet. */
uint8_t noack; /**< Flag indicating that this packet will not be acknowledged. */
uint8_t pid; /**< PID assigned during communication. */
uint8_t data[NRF52_MAX_PAYLOAD_LENGTH]; /**< The payload data. */
} nrf52_payload_t;
/**@brief Retransmit attempts delay and counter. */
typedef struct {
uint16_t delay; /**< The delay between each retransmission of unacked packets. */
uint16_t count; /**< The number of retransmissions attempts before transmission fail. */
} nrf52_retransmit_t;
/**@brief Main nrf_esb configuration struct. */
typedef struct {
nrf52_protocol_t protocol; /**< Enhanced ShockBurst protocol. */
nrf52_mode_t mode; /**< Enhanced ShockBurst default RX or TX mode. */
// General RF parameters
nrf52_bitrate_t bitrate; /**< Enhanced ShockBurst bitrate mode. */
nrf52_crc_t crc; /**< Enhanced ShockBurst CRC mode. */
nrf52_tx_power_t tx_power; /**< Enhanced ShockBurst radio transmission power mode.*/
// Control settings
nrf52_tx_mode_t tx_mode; /**< Enhanced ShockBurst transmit mode. */
bool selective_auto_ack; /**< Enable or disable selective auto acknowledgement. */
nrf52_retransmit_t retransmit; /**< Packet retransmit parameters */
uint8_t payload_length; /**< Enhanced ShockBurst static payload length */
nrf52_address_t address; /**< Address parameters structure */
} nrf52_config_t;
typedef struct {
/**
* @brief NRF52 radio peripheral.
*/
NRF_RADIO_Type *radio;
/**
* @brief NRF52 timer peripheral.
*/
NRF_TIMER_Type *timer;
/**
* @brief Driver state.
*/
nrf52_state_t state;
/**
* @brief RF parameters.
*/
nrf52_config_t config;
/**
* @brief Interrupts flag.
*/
nrf52_int_flags_t flags;
/**
* @brief TX attempt number.
*/
uint16_t tx_attempt;
/**
* @brief TX retransmits remaining.
*/
uint16_t tx_remaining;
/**
* @brief Radio events source.
*/
event_source_t eventsrc;
} RFDriver;
extern RFDriver RFD1;
nrf52_error_t radio_init(nrf52_config_t const *config);
nrf52_error_t radio_disable(void);
nrf52_error_t radio_write_payload(nrf52_payload_t const * p_payload);
nrf52_error_t radio_read_rx_payload(nrf52_payload_t * p_payload);
nrf52_error_t radio_start_tx(void);
nrf52_error_t radio_start_rx(void);
nrf52_error_t radio_stop_rx(void);
nrf52_error_t radio_flush_tx(void);
nrf52_error_t radio_flush_rx(void);
nrf52_error_t radio_pop_tx(void);
nrf52_error_t radio_set_base_address_0(uint8_t const * p_addr);
nrf52_error_t radio_set_base_address_1(uint8_t const * p_addr);
nrf52_error_t radio_set_prefixes(uint8_t const * p_prefixes, uint8_t num_pipes);
nrf52_error_t radio_set_prefix(uint8_t pipe, uint8_t prefix);
#endif /* NRF52_RADIO_H_ */