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RH_NRF24.h
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// RH_NRF24.h
// Author: Mike McCauley
// Copyright (C) 2012 Mike McCauley
// $Id: RH_NRF24.h,v 1.21 2020/06/15 23:39:39 mikem Exp $
//
#ifndef RH_NRF24_h
#define RH_NRF24_h
#include <RHGenericSPI.h>
#include <RHNRFSPIDriver.h>
// This is the maximum number of bytes that can be carried by the nRF24.
// We use some for headers, keeping fewer for RadioHead messages
#define RH_NRF24_MAX_PAYLOAD_LEN 32
// The length of the headers we add.
// The headers are inside the nRF24 payload
#define RH_NRF24_HEADER_LEN 4
// This is the maximum RadioHead user message length that can be supported by this library. Limited by
// the supported message lengths in the nRF24
#define RH_NRF24_MAX_MESSAGE_LEN (RH_NRF24_MAX_PAYLOAD_LEN-RH_NRF24_HEADER_LEN)
// SPI Command names
#define RH_NRF24_COMMAND_R_REGISTER 0x00
#define RH_NRF24_COMMAND_W_REGISTER 0x20
#define RH_NRF24_COMMAND_ACTIVATE 0x50 // only on RFM73 ?
#define RH_NRF24_COMMAND_R_RX_PAYLOAD 0x61
#define RH_NRF24_COMMAND_W_TX_PAYLOAD 0xa0
#define RH_NRF24_COMMAND_FLUSH_TX 0xe1
#define RH_NRF24_COMMAND_FLUSH_RX 0xe2
#define RH_NRF24_COMMAND_REUSE_TX_PL 0xe3
#define RH_NRF24_COMMAND_R_RX_PL_WID 0x60
#define RH_NRF24_COMMAND_W_ACK_PAYLOAD(pipe) (0xa8|(pipe&0x7))
#define RH_NRF24_COMMAND_W_TX_PAYLOAD_NOACK 0xb0
#define RH_NRF24_COMMAND_NOP 0xff
// Register names
#define RH_NRF24_REGISTER_MASK 0x1f
#define RH_NRF24_REG_00_CONFIG 0x00
#define RH_NRF24_REG_01_EN_AA 0x01
#define RH_NRF24_REG_02_EN_RXADDR 0x02
#define RH_NRF24_REG_03_SETUP_AW 0x03
#define RH_NRF24_REG_04_SETUP_RETR 0x04
#define RH_NRF24_REG_05_RF_CH 0x05
#define RH_NRF24_REG_06_RF_SETUP 0x06
#define RH_NRF24_REG_07_STATUS 0x07
#define RH_NRF24_REG_08_OBSERVE_TX 0x08
#define RH_NRF24_REG_09_RPD 0x09
#define RH_NRF24_REG_0A_RX_ADDR_P0 0x0a
#define RH_NRF24_REG_0B_RX_ADDR_P1 0x0b
#define RH_NRF24_REG_0C_RX_ADDR_P2 0x0c
#define RH_NRF24_REG_0D_RX_ADDR_P3 0x0d
#define RH_NRF24_REG_0E_RX_ADDR_P4 0x0e
#define RH_NRF24_REG_0F_RX_ADDR_P5 0x0f
#define RH_NRF24_REG_10_TX_ADDR 0x10
#define RH_NRF24_REG_11_RX_PW_P0 0x11
#define RH_NRF24_REG_12_RX_PW_P1 0x12
#define RH_NRF24_REG_13_RX_PW_P2 0x13
#define RH_NRF24_REG_14_RX_PW_P3 0x14
#define RH_NRF24_REG_15_RX_PW_P4 0x15
#define RH_NRF24_REG_16_RX_PW_P5 0x16
#define RH_NRF24_REG_17_FIFO_STATUS 0x17
#define RH_NRF24_REG_1C_DYNPD 0x1c
#define RH_NRF24_REG_1D_FEATURE 0x1d
// These register masks etc are named wherever possible
// corresponding to the bit and field names in the nRF24L01 Product Specification
// #define RH_NRF24_REG_00_CONFIG 0x00
#define RH_NRF24_MASK_RX_DR 0x40
#define RH_NRF24_MASK_TX_DS 0x20
#define RH_NRF24_MASK_MAX_RT 0x10
#define RH_NRF24_EN_CRC 0x08
#define RH_NRF24_CRCO 0x04
#define RH_NRF24_PWR_UP 0x02
#define RH_NRF24_PRIM_RX 0x01
// #define RH_NRF24_REG_01_EN_AA 0x01
#define RH_NRF24_ENAA_P5 0x20
#define RH_NRF24_ENAA_P4 0x10
#define RH_NRF24_ENAA_P3 0x08
#define RH_NRF24_ENAA_P2 0x04
#define RH_NRF24_ENAA_P1 0x02
#define RH_NRF24_ENAA_P0 0x01
// #define RH_NRF24_REG_02_EN_RXADDR 0x02
#define RH_NRF24_ERX_P5 0x20
#define RH_NRF24_ERX_P4 0x10
#define RH_NRF24_ERX_P3 0x08
#define RH_NRF24_ERX_P2 0x04
#define RH_NRF24_ERX_P1 0x02
#define RH_NRF24_ERX_P0 0x01
// #define RH_NRF24_REG_03_SETUP_AW 0x03
#define RH_NRF24_AW_3_BYTES 0x01
#define RH_NRF24_AW_4_BYTES 0x02
#define RH_NRF24_AW_5_BYTES 0x03
// #define RH_NRF24_REG_04_SETUP_RETR 0x04
#define RH_NRF24_ARD 0xf0
#define RH_NRF24_ARC 0x0f
// #define RH_NRF24_REG_05_RF_CH 0x05
#define RH_NRF24_RF_CH 0x7f
// #define RH_NRF24_REG_06_RF_SETUP 0x06
#define RH_NRF24_CONT_WAVE 0x80
#define RH_NRF24_RF_DR_LOW 0x20
#define RH_NRF24_PLL_LOCK 0x10
#define RH_NRF24_RF_DR_HIGH 0x08
#define RH_NRF24_PWR 0x06
#define RH_NRF24_PWR_m18dBm 0x00
#define RH_NRF24_PWR_m12dBm 0x02
#define RH_NRF24_PWR_m6dBm 0x04
#define RH_NRF24_PWR_0dBm 0x06
#define RH_NRF24_LNA_HCURR 0x01
// #define RH_NRF24_REG_07_STATUS 0x07
#define RH_NRF24_RX_DR 0x40
#define RH_NRF24_TX_DS 0x20
#define RH_NRF24_MAX_RT 0x10
#define RH_NRF24_RX_P_NO 0x0e
#define RH_NRF24_STATUS_TX_FULL 0x01
// #define RH_NRF24_REG_08_OBSERVE_TX 0x08
#define RH_NRF24_PLOS_CNT 0xf0
#define RH_NRF24_ARC_CNT 0x0f
// #define RH_NRF24_REG_09_RPD 0x09
#define RH_NRF24_RPD 0x01
// #define RH_NRF24_REG_17_FIFO_STATUS 0x17
#define RH_NRF24_TX_REUSE 0x40
#define RH_NRF24_TX_FULL 0x20
#define RH_NRF24_TX_EMPTY 0x10
#define RH_NRF24_RX_FULL 0x02
#define RH_NRF24_RX_EMPTY 0x01
// #define RH_NRF24_REG_1C_DYNPD 0x1c
#define RH_NRF24_DPL_ALL 0x3f
#define RH_NRF24_DPL_P5 0x20
#define RH_NRF24_DPL_P4 0x10
#define RH_NRF24_DPL_P3 0x08
#define RH_NRF24_DPL_P2 0x04
#define RH_NRF24_DPL_P1 0x02
#define RH_NRF24_DPL_P0 0x01
// #define RH_NRF24_REG_1D_FEATURE 0x1d
#define RH_NRF24_EN_DPL 0x04
#define RH_NRF24_EN_ACK_PAY 0x02
#define RH_NRF24_EN_DYN_ACK 0x01
/////////////////////////////////////////////////////////////////////
/// \class RH_NRF24 RH_NRF24.h <RH_NRF24.h>
/// \brief Send and receive unaddressed, unreliable datagrams by nRF24L01 and compatible transceivers.
///
/// Supported transceivers include:
/// - Nordic nRF24 based 2.4GHz radio modules, such as nRF24L01 http://www.nordicsemi.com/eng/Products/2.4GHz-RF/nRF24L01
/// and other compatible transceivers.
/// - nRF24L01p with PA and LNA modules that produce a higher power output similar to this one:
/// http://www.elecfreaks.com/wiki/index.php?title=2.4G_Wireless_nRF24L01p_with_PA_and_LNA
/// - Sparkfun WRL-00691 module with nRF24L01 https://www.sparkfun.com/products/691
/// or WRL-00705 https://www.sparkfun.com/products/705 etc.
/// - Hope-RF RFM73 http://www.hoperf.com/rf/2.4g_module/RFM73.htm and
/// http://www.anarduino.com/details.jsp?pid=121
/// and compatible devices (such as BK2423). nRF24L01 and RFM73 can interoperate
/// with each other.
///
/// This base class provides basic functions for sending and receiving unaddressed, unreliable datagrams
/// of arbitrary length to 28 octets per packet. Use one of the Manager classes to get addressing and
/// acknowledgement reliability, routing, meshes etc.
///
/// The nRF24L01 (http://www.sparkfun.com/datasheets/Wireless/Nordic/nRF24L01P_Product_Specification_1_0.pdf)
/// is a low-cost 2.4GHz ISM transceiver module. It supports a number of channel frequencies in the 2.4GHz band
/// and a range of data rates.
///
/// This library provides functions for sending and receiving messages of up to 28 octets on any
/// frequency supported by the nRF24L01, at a selected data rate.
///
/// Several nRF24L01 modules can be connected to an Arduino, permitting the construction of translators
/// and frequency changers, etc.
///
/// The nRF24 transceiver is configured to use Enhanced Shockburst with no acknowledgement and no retransmits.
/// TX_ADDR and RX_ADDR_P0 are set to the network address. If you need the low level auto-acknowledgement
/// feature supported by this chip, you can use our original NRF24 library
/// at http://www.airspayce.com/mikem/arduino/NRF24
///
/// Naturally, for any 2 radios to communicate that must be configured to use the same frequency and
/// data rate, and with identical network addresses.
///
/// Example Arduino programs are included to show the main modes of use.
///
/// \par Packet Format
///
/// All messages sent and received by this class conform to this packet format, as specified by
/// the nRF24L01 product specification:
///
/// - 1 octets PREAMBLE
/// - 3 to 5 octets NETWORK ADDRESS
/// - 9 bits packet control field
/// - 0 to 32 octets PAYLOAD, consisting of:
/// - 1 octet TO header
/// - 1 octet FROM header
/// - 1 octet ID header
/// - 1 octet FLAGS header
/// - 0 to 28 octets of user message
/// - 2 octets CRC
///
/// \par Connecting nRF24L01 to Arduino
///
/// The electrical connection between the nRF24L01 and the Arduino require 3.3V, the 3 x SPI pins (SCK, SDI, SDO),
/// a Chip Enable pin and a Slave Select pin.
/// If you are using the Sparkfun WRL-00691 module, it has a voltage regulator on board and
/// can be should with 5V VCC if possible.
/// The examples below assume the Sparkfun WRL-00691 module
///
/// Connect the nRF24L01 to most Arduino's like this (Caution, Arduino Mega has different pins for SPI,
/// see below). Use these same connections for Teensy 3.1 (use 3.3V not 5V Vcc).
/// \code
/// Arduino Sparkfun WRL-00691
/// 5V-----------VCC (3.3V to 7V in)
/// pin D8-----------CE (chip enable in)
/// SS pin D10----------CSN (chip select in)
/// SCK pin D13----------SCK (SPI clock in)
/// MOSI pin D11----------SDI (SPI Data in)
/// MISO pin D12----------SDO (SPI data out)
/// IRQ (Interrupt output, not connected)
/// GND----------GND (ground in)
/// \endcode
///
/// For an Arduino Leonardo (the SPI pins do not come out on the Digital pins as for normal Arduino, but only
/// appear on the ICSP header)
/// \code
/// Leonardo Sparkfun WRL-00691
/// 5V-----------VCC (3.3V to 7V in)
/// pin D8-----------CE (chip enable in)
/// SS pin D10----------CSN (chip select in)
/// SCK ICSP pin 3----------SCK (SPI clock in)
/// MOSI ICSP pin 4----------SDI (SPI Data in)
/// MISO ICSP pin 1----------SDO (SPI data out)
/// IRQ (Interrupt output, not connected)
/// GND----------GND (ground in)
/// \endcode
/// and initialise the NRF24 object like this to explicitly set the SS pin
/// NRF24 nrf24(8, 10);
///
/// For an Arduino Due (the SPI pins do not come out on the Digital pins as for normal Arduino, but only
/// appear on the SPI header). Use the same connections for Yun with 5V or 3.3V.
/// \code
/// Due Sparkfun WRL-00691
/// 3.3V-----------VCC (3.3V to 7V in)
/// pin D8-----------CE (chip enable in)
/// SS pin D10----------CSN (chip select in)
/// SCK SPI pin 3----------SCK (SPI clock in)
/// MOSI SPI pin 4----------SDI (SPI Data in)
/// MISO SPI pin 1----------SDO (SPI data out)
/// IRQ (Interrupt output, not connected)
/// GND----------GND (ground in)
/// \endcode
/// and initialise the NRF24 object with the default constructor
/// NRF24 nrf24;
///
/// For an Arduino Mega:
/// \code
/// Mega Sparkfun WRL-00691
/// 5V-----------VCC (3.3V to 7V in)
/// pin D8-----------CE (chip enable in)
/// SS pin D53----------CSN (chip select in)
/// SCK pin D52----------SCK (SPI clock in)
/// MOSI pin D51----------SDI (SPI Data in)
/// MISO pin D50----------SDO (SPI data out)
/// IRQ (Interrupt output, not connected)
/// GND----------GND (ground in)
/// \endcode
/// and you can then use the constructor RH_NRF24(8, 53).
///
/// For an Itead Studio IBoard Pro http://imall.iteadstudio.com/iboard-pro.html, connected by hardware SPI to the
/// ITDB02 Parallel LCD Module Interface pins:
/// \code
/// IBoard Signal=ITDB02 pin Sparkfun WRL-00691
/// 3.3V 37-----------VCC (3.3V to 7V in)
/// D2 28-----------CE (chip enable in)
/// D29 27----------CSN (chip select in)
/// SCK D52 32----------SCK (SPI clock in)
/// MOSI D51 34----------SDI (SPI Data in)
/// MISO D50 30----------SDO (SPI data out)
/// IRQ (Interrupt output, not connected)
/// GND 39----------GND (ground in)
/// \endcode
/// And initialise like this:
/// \code
/// RH_NRF24 nrf24(2, 29);
/// \endcode
///
/// For an Itead Studio IBoard Pro http://imall.iteadstudio.com/iboard-pro.html, connected by software SPI to the
/// nRF24L01+ Module Interface pins. CAUTION: performance of software SPI is very slow and is not
/// compatible with other modules running hardware SPI.
/// \code
/// IBoard Signal=Module pin Sparkfun WRL-00691
/// 3.3V 2----------VCC (3.3V to 7V in)
/// D12 3-----------CE (chip enable in)
/// D29 4----------CSN (chip select in)
/// D9 5----------SCK (SPI clock in)
/// D8 6----------SDI (SPI Data in)
/// D7 7----------SDO (SPI data out)
/// IRQ (Interrupt output, not connected)
/// GND 1----------GND (ground in)
/// \endcode
/// And initialise like this:
/// \code
/// #include <SPI.h>
/// #include <RH_NRF24.h>
/// #include <RHSoftwareSPI.h>
/// Singleton instance of the radio driver
/// RHSoftwareSPI spi;
/// RH_NRF24 nrf24(12, 11, spi);
/// void setup() {
/// spi.setPins(7, 8, 9);
/// ....
/// \endcode
///
///
/// For Raspberry Pi with Sparkfun WRL-00691
/// \code
/// Raspberry Pi P1 pin Sparkfun WRL-00691
/// 5V 2-----------VCC (3.3V to 7V in)
/// GPIO25 22-----------CE (chip enable in)
/// GPIO8 24----------CSN (chip select in)
/// GPIO11 23----------SCK (SPI clock in)
/// GPIO10 19----------SDI (SPI Data in)
/// GPIO9 21----------SDO (SPI data out)
/// IRQ (Interrupt output, not connected)
/// GND 6----------GND (ground in)
/// \endcode
/// and initialise like this:
/// \code
/// RH_NRF24 nrf24(RPI_V2_GPIO_P1_22, RPI_V2_GPIO_P1_24);
/// \endcode
/// See the example program and Makefile in examples/raspi. Requires bcm2835 library to be previously installed.
/// \code
/// cd examples/raspi
/// make
/// sudo ./RasPiRH
/// \endcode
/// \code
///
/// You can override the default settings for the CSN and CE pins
/// in the NRF24() constructor if you wish to connect the slave select CSN to other than the normal one for your
///
/// Caution: on the Raspberry Pi Zero, the hardware SPI, is only connected to the
/// ICSP-header. So in order to use the RF, one must either connect it to the SPI-pins
/// of the ICSP-header or use the software SPI provided by RHSoftwareSPI.
/// the mapping of the SPI-Pins for each board here:
/// https://www.arduino.cc/en/Reference/SPI
/// Arduino (D10 for Diecimila, Uno etc and D53 for Mega)
///
/// Caution: on some Arduinos such as the Mega 2560, if you set the slave select pin to be other than the usual SS
/// pin (D53 on Mega 2560), you may need to set the usual SS pin to be an output to force the Arduino into SPI
/// master mode.
///
/// Caution: this module has not been proved to work with Leonardo, at least without level
/// shifters between the nRF24 and the Leonardo. Tests seem to indicate that such level shifters would be required
/// with Leonardo to make it work.
///
/// It is possible to have 2 radios conected to one arduino, provided each radio has its own
/// CSN and CE line (SCK, SDI and SDO are common to both radios)
///
/// \par SPI Interface
///
/// You can interface to nRF24L01 with with hardware or software SPI. Use of software SPI with the RHSoftwareSPI
/// class depends on a fast enough processor and digitalOut() functions to achieve a high enough SPI bus frequency.
/// If you observe reliable behaviour with the default hardware SPI RHHardwareSPI, but unreliable behaviour
/// with Software SPI RHSoftwareSPI, it may be due to slow CPU performance.
///
/// Initialisation example with hardware SPI
/// \code
/// #include <RH_NRF24.h>
/// RH_NRF24 driver;
/// RHReliableDatagram manager(driver, CLIENT_ADDRESS);
/// \endcode
///
/// Initialisation example with software SPI
/// \code
/// #include <RH_NRF24.h>
/// #include <RHSoftwareSPI.h>
/// RHSoftwareSPI spi;
/// RH_NRF24 driver(8, 10, spi);
/// RHReliableDatagram manager(driver, CLIENT_ADDRESS);
/// \endcode
///
/// \par Example programs
///
/// Several example programs are provided.
///
/// \par Radio Performance
///
/// Frequency accuracy may be debatable. For nominal frequency of 2401.000 MHz (ie channel 1),
/// my Yaesu VR-5000 receiver indicated the center frequency for my test radios
/// was 2401.121 MHz. Its not clear to me if the Yaesu
/// is the source of the error, but I tend to believe it, which would make the nRF24l01 frequency out by 121kHz.
///
/// The measured power output for a nRF24L01p with PA and LNA set to 0dBm output is about 18dBm.
///
/// \par Radio operating strategy and defaults
///
/// The radio is enabled all the time, and switched between TX and RX modes depending on
/// whether there is any data to send. Sending data sets the radio to TX mode.
/// After data is sent, the radio automatically returns to Standby II mode. Calling waitAvailable() or
/// waitAvailableTimeout() starts the radio in RX mode.
///
/// The radio is configured by default to Channel 2, 2Mbps, 0dBm power, 5 bytes address, payload width 1, CRC enabled
/// 2 byte CRC, No Auto-Ack mode. Enhanced shockburst is used.
/// TX and P0 are set to the Network address. Node addresses and decoding are handled with the RH_NRF24 module.
///
/// \par Memory
///
/// Memory usage of this class is minimal. The compiled client and server sketches are about 6000 bytes on Arduino.
/// The reliable client and server sketches compile to about 8500 bytes on Arduino.
/// RAM requirements are minimal.
///
class RH_NRF24 : public RHNRFSPIDriver
{
public:
/// \brief Defines convenient values for setting data rates in setRF()
typedef enum
{
DataRate1Mbps = 0, ///< 1 Mbps
DataRate2Mbps, ///< 2 Mbps
DataRate250kbps ///< 250 kbps
} DataRate;
/// \brief Convenient values for setting transmitter power in setRF()
/// These are designed to agree with the values for RF_PWR in RH_NRF24_REG_06_RF_SETUP
/// To be passed to setRF();
typedef enum
{
// Add 20dBm for nRF24L01p with PA and LNA modules
TransmitPowerm18dBm = 0, ///< On nRF24, -18 dBm
TransmitPowerm12dBm, ///< On nRF24, -12 dBm
TransmitPowerm6dBm, ///< On nRF24, -6 dBm
TransmitPower0dBm, ///< On nRF24, 0 dBm
// Sigh, different power levels for the same bit patterns on RFM73:
// On RFM73P-S, there is a Tx power amp, so expect higher power levels, up to 20dBm. Alas
// there is no clear documentation on the power for different settings :-(
RFM73TransmitPowerm10dBm = 0, ///< On RFM73, -10 dBm
RFM73TransmitPowerm5dBm, ///< On RFM73, -5 dBm
RFM73TransmitPowerm0dBm, ///< On RFM73, 0 dBm
RFM73TransmitPower5dBm ///< On RFM73, 5 dBm. 20dBm on RFM73P-S2 ?
} TransmitPower;
/// Constructor. You can have multiple instances, but each instance must have its own
/// chip enable and slave select pin.
/// After constructing, you must call init() to initialise the interface
/// and the radio module
/// \param[in] chipEnablePin the Arduino pin to use to enable the chip for transmit/receive
/// \param[in] slaveSelectPin the Arduino pin number of the output to use to select the NRF24 before
/// accessing it. Defaults to the normal SS pin for your Arduino (D10 for Diecimila, Uno etc, D53 for Mega,
/// D10 for Maple)
/// \param[in] spi Pointer to the SPI interface object to use.
/// Defaults to the standard Arduino hardware SPI interface
RH_NRF24(uint8_t chipEnablePin = 8, uint8_t slaveSelectPin = SS, RHGenericSPI& spi = hardware_spi);
/// Initialises this instance and the radio module connected to it.
/// The following steps are taken:g
/// - Set the chip enable and chip select pins to output LOW, HIGH respectively.
/// - Initialise the SPI output pins
/// - Initialise the SPI interface library to 8MHz (Hint, if you want to lower
/// the SPI frequency (perhaps where you have other SPI shields, low voltages etc),
/// call SPI.setClockDivider() after init()).
/// -Flush the receiver and transmitter buffers
/// - Set the radio to receive with powerUpRx();
/// \return true if everything was successful
bool init();
/// Reads a single register from the NRF24
/// \param[in] reg Register number, one of RH_NRF24_REG_*
/// \return The value of the register
uint8_t spiReadRegister(uint8_t reg);
/// Writes a single byte to the NRF24, and at the same time reads the current STATUS register
/// \param[in] reg Register number, one of RH_NRF24_REG_*
/// \param[in] val The value to write
/// \return the current STATUS (read while the command is sent)
uint8_t spiWriteRegister(uint8_t reg, uint8_t val);
/// Reads a number of consecutive registers from the NRF24 using burst read mode
/// \param[in] reg Register number of the first register, one of RH_NRF24_REG_*
/// \param[in] dest Array to write the register values to. Must be at least len bytes
/// \param[in] len Number of bytes to read
/// \return the current STATUS (read while the command is sent)
uint8_t spiBurstReadRegister(uint8_t reg, uint8_t* dest, uint8_t len);
/// Write a number of consecutive registers using burst write mode
/// \param[in] reg Register number of the first register, one of RH_NRF24_REG_*
/// \param[in] src Array of new register values to write. Must be at least len bytes
/// \param[in] len Number of bytes to write
/// \return the current STATUS (read while the command is sent)
uint8_t spiBurstWriteRegister(uint8_t reg, uint8_t* src, uint8_t len);
/// Reads and returns the device status register NRF24_REG_02_DEVICE_STATUS
/// \return The value of the device status register
uint8_t statusRead();
/// Sets the transmit and receive channel number.
/// The frequency used is (2400 + channel) MHz
/// \return true on success
bool setChannel(uint8_t channel);
/// Sets the chip configuration that will be used to set
/// the NRF24 NRF24_REG_00_CONFIG register when in Idle mode. This allows you to change some
/// chip configuration for compatibility with libraries other than this one.
/// You should not normally need to call this.
/// Defaults to NRF24_EN_CRC| RH_NRF24_CRCO, which is the standard configuration for this library
/// (2 byte CRC enabled).
/// \param[in] mode The chip configuration to be used whe in Idle mode.
/// \return true on success
bool setOpMode(uint8_t mode);
/// Sets the Network address.
/// Only nodes with the same network address can communicate with each other. You
/// can set different network addresses in different sets of nodes to isolate them from each other.
/// Internally, this sets the nRF24 TX_ADDR and RX_ADDR_P0 to be the given network address.
/// The default network address is 0xE7E7E7E7E7
/// \param[in] address The new network address. Must match the network address of any receiving node(s).
/// \param[in] len Number of bytes of address to set (3 to 5).
/// \return true on success, false if len is not in the range 3-5 inclusive.
bool setNetworkAddress(uint8_t* address, uint8_t len);
/// Sets the data rate and transmitter power to use. Note that the nRF24 and the RFM73 have different
/// available power levels, and for convenience, 2 different sets of values are available in the
/// RH_NRF24::TransmitPower enum. The ones with the RFM73 only have meaning on the RFM73 and compatible
/// devces. The others are for the nRF24.
/// \param [in] data_rate The data rate to use for all packets transmitted and received. One of RH_NRF24::DataRate.
/// \param [in] power Transmitter power. One of RH_NRF24::TransmitPower.
/// \return true on success
bool setRF(DataRate data_rate, TransmitPower power);
/// Sets the radio in power down mode, with the configuration set to the
/// last value from setOpMode().
/// Sets chip enable to LOW.
void setModeIdle();
/// Sets the radio in RX mode.
/// Sets chip enable to HIGH to enable the chip in RX mode.
void setModeRx();
/// Sets the radio in TX mode.
/// Pulses the chip enable LOW then HIGH to enable the chip in TX mode.
void setModeTx();
/// Sends data to the address set by setTransmitAddress()
/// Sets the radio to TX mode
/// \param [in] data Data bytes to send.
/// \param [in] len Number of data bytes to send
/// \return true on success (which does not necessarily mean the receiver got the message, only that the message was
/// successfully transmitted).
bool send(const uint8_t* data, uint8_t len);
/// Blocks until the current message (if any)
/// has been transmitted
/// \return true on success, false if the chip is not in transmit mode or other transmit failure
virtual bool waitPacketSent();
/// Indicates if the chip is in transmit mode and
/// there is a packet currently being transmitted
/// \return true if the chip is in transmit mode and there is a transmission in progress
bool isSending();
/// Prints the value of all chip registers
/// to the Serial device if RH_HAVE_SERIAL is defined for the current platform
/// For debugging purposes only.
/// \return true on success
bool printRegisters();
/// Checks whether a received message is available.
/// This can be called multiple times in a timeout loop
/// \return true if a complete, valid message has been received and is able to be retrieved by
/// recv()
bool available();
/// Turns the receiver on if it not already on.
/// If there is a valid message available, copy it to buf and return true
/// else return false.
/// If a message is copied, *len is set to the length (Caution, 0 length messages are permitted).
/// You should be sure to call this function frequently enough to not miss any messages
/// It is recommended that you call it in your main loop.
/// \param[in] buf Location to copy the received message
/// \param[in,out] len Pointer to the number of octets available in buf. The number be reset to the actual number of octets copied.
/// \return true if a valid message was copied to buf
bool recv(uint8_t* buf, uint8_t* len);
/// The maximum message length supported by this driver
/// \return The maximum message length supported by this driver
uint8_t maxMessageLength();
/// Sets the radio into Power Down mode.
/// If successful, the radio will stay in Power Down mode until woken by
/// changing mode it idle, transmit or receive (eg by calling send(), recv(), available() etc)
/// Caution: there is a time penalty as the radio takes a finite time to wake from sleep mode.
/// \return true if sleep mode was successfully entered.
virtual bool sleep();
protected:
/// Flush the TX FIFOs
/// \return the value of the device status register
uint8_t flushTx();
/// Flush the RX FIFOs
/// \return the value of the device status register
uint8_t flushRx();
/// Examine the receive buffer to determine whether the message is for this node
void validateRxBuf();
/// Clear our local receive buffer
void clearRxBuf();
private:
/// This idle mode chip configuration
uint8_t _configuration;
/// the number of the chip enable pin
uint8_t _chipEnablePin;
/// Number of octets in the buffer
uint8_t _bufLen;
/// The receiver/transmitter buffer
uint8_t _buf[RH_NRF24_MAX_PAYLOAD_LEN];
/// True when there is a valid message in the buffer
bool _rxBufValid;
};
/// @example nrf24_client.pde
/// @example nrf24_server.pde
/// @example nrf24_encrypted_client.pde
/// @example nrf24_encrypted_server.pde
/// @example nrf24_reliable_datagram_client.pde
/// @example nrf24_reliable_datagram_server.pde
/// @example RasPiRH.cpp
#endif