Philippe Spino
project de marde si tu touch le no-homo s'applique pas
Fork of
XBeeLib
by 
Digi International Inc.
XBee/XBee.h
- Committer:
- hbujanda
- Date:
- 2015-05-14
- Revision:
- 2:2ee1b6d51df2
- Parent:
- 1:794d1d3e4a08
- Child:
- 3:8662ebe83570
File content as of revision 2:2ee1b6d51df2:
/**
* Copyright (c) 2015 Digi International Inc.,
* All rights not expressly granted are reserved.
*
* This Source Code Form is subject to the terms of the Mozilla Public
* License, v. 2.0. If a copy of the MPL was not distributed with this file,
* You can obtain one at http://mozilla.org/MPL/2.0/.
*
* Digi International Inc. 11001 Bren Road East, Minnetonka, MN 55343
* =======================================================================
*/
#if !defined(__DIGI_RADIO_H_)
#define __DIGI_RADIO_H_
#include <stdint.h>
#include "config.h"
#include "Utils/Debug.h"
#include "Frames/AtCmdFrame.h"
#include "FrameHandlers/FrameHandler.h"
#include "FrameHandlers/FH_ModemStatus.h"
#include "FrameBuffer/FrameBuffer.h"
#include "Addresses.h"
#include "RemoteXBee/RemoteXBee.h"
#include "IO/IO.h"
#define MAX_FRAME_HANDLERS 4
#define RESET_TIMEOUT_MS 5000
#define DR_API_FRAME_OVERHEAD 4 /* Start of frame + frame len + checksum */
#define DR_MIN_API_FRAME_LEN 4
#define DR_START_OF_FRAME 0x7E
#define DR_ESCAPE_BYTE 0x7D
#define DR_XON_BYTE 0x11
#define DR_XOFF_BYTE 0x13
#define DR_ESCAPE_XOR_BYTE 0x20
/* TODO, verify these flags work in all modules */
#define DISABLE_RETRIES_AND_ROUTE_REPAIR 0x01
#define ENABLE_APS_ENCRYPTION 0x20
#define USE_EXTENDED_TX_TIMEOUT 0x40
namespace XBeeLib {
/**
* @defgroup RadioStatus
* @{
*/
/**
* RadioStatus
*/
enum RadioStatus {
Success = 0, /**< Success */
Failure = -1, /**< Failure */
OpNotSupported = -2, /**< Option Not Supported */
};
/**
* @}
*/
/**
* @defgroup RadioType
* @{
*/
/**
* RadioType
*/
enum RadioType {
Unknown = 0, /**< Not detected yet */
XB24_A_S1 = 0x17, /**< S1 */
XBP24_A_S1 = 0x18, /**< S1 */
XB24_B_S2 = 0x19, /**< S2 */
XBP24_B_S2 = 0x1A, /**< S2 */
XBP09_D = 0x1B, /**< S4 */
XBP09_XC = 0x1C, /**< S3 */
XBP08_D = 0x1D, /**< 868MHz S5 */
XBP24_B_S2B = 0x1E, /**< S2B */
XB24_WF = 0x1F, /**< S6 */
XBP24_C_SMT = 0x21, /**< XBee PRO SMT S2C */
XB24_C_SMT = 0x22, /**< XBee SMT S2C */
XBP09_XC_B = 0x23, /**< S3B */
XBP09_B = 0x23, /**< S3B */
XB8 = 0x24, /**< S8 */
XB2B_WF_TH = 0x27, /**< S6B TH */
XB2B_WF_SMT = 0x28, /**< S6B SMT */
XBP24_C_TH = 0x2D, /**< S2C TH */
XB24_C_TH = 0x2E, /**< S2C TH */
};
/**
* @}
*/
/**
* @defgroup TxStatus
* @{
*/
/**
* TxStatus
*/
enum TxStatus {
TxStatusSuccess = 0, /**< Success */
TxStatusAckFail = 1, /**< MAC ACK Failure */
TxStatusCCAFail = 2, /**< CCA Failure */
TxStatusInvDestEP = 0x15, /**< Invalid destination endpoint */
TxStatusNwAckFail = 0x21, /**< Network ACK Failure */
TxStatusNotJoinNw = 0x22, /**< Not Joined to Network */
TxStatusSelfAddr = 0x23, /**< Self-addressed */
TxStatusAddrNotFound = 0x24, /**< Address Not Found */
TxStatusRouteNotFound = 0x25, /**< Route Not Found */
TxStatusBroadSrcFail2Heard = 0x26, /**< Broadcast source failed to hear a neighbor relay the message */
TxStatusInvBindTableIdx = 0x2B, /**< Invalid binding table index */
TxStatusResourceError = 0x2C, /**< Resource error lack of free buffers, timers, etc. */
TxStatusAttBroadcWithAPS = 0x2D, /**< Attempted broadcast with APS transmission */
TxStatusAttUnicWithAPSEE0 = 0x2E, /**< Attempted unicast with APS transmission, but EE=0 */
TxStatusResourceError2 = 0x31, /**< TxStatusResourceError2 */
TxStatusInternalError = 0x32, /**< Resource error lack of free buffers, timers, etc. */
TxStatusPayloadTooLarge = 0x74, /**< Data payload too large */
TxStatusIndirectMsgUnReq = 0x75, /**< Indirect message unrequested */
TxStatusInvalidAddr = 0xfe, /**< Invalid Address (Error generated by the library) */
TxStatusTimeout = 0xff, /**< Timeout (Error generated by the library) */
};
/**
* @}
*/
/**
* @defgroup PmMode
* @{
*/
/**
* PmMode
*/
enum PmMode {
SleepDisabled = 0, /**< SleepDisabled */
PinSleep = 1, /**< PinSleep */
PinDoze = 2, /**< PinDoze */
CyclicSeleep = 4, /**< CyclicSeleep */
CyclicSeleepPinW = 5, /**< CyclicSeleepPinW */
};
/**
* @}
*/
/**
* @defgroup NetworkRole
* @{
*/
/**
* NetworkRole
*/
enum NetworkRole {
UnknownRole, /**< Unknown Role */
Coordinator, /**< Coordinator */
Router, /**< Router */
EndDevice, /**< EndDevice */
};
/**
* @}
*/
/**
* @defgroup RadioLocation
* @{
*/
/**
* RadioLocation
*/
enum RadioLocation {
RadioLocal = 0, /**< Local Radio */
RadioRemote = 1, /**< Remote Radio */
};
/**
* @}
*/
/** Parent Class for XBee modules, not to be directly used */
class XBee
{
private:
/** wait_for_module_to_reset - waits until a Modem Status packet with a reset status
* is received, or the timeout expires.
*
* @returns
* Success if a Modem Status was received,
* Failure otherwise
*/
RadioStatus wait_for_module_to_reset(volatile uint16_t *rst_cnt_p, uint16_t init_rst_cnt);
protected:
/** timer used by local and remote objects */
static Timer _timer;
/** buffer to store the received frames */
static FrameBuffer _framebuf;
public:
/**
* RadioMode
*/
enum RadioMode {
ModeUnknown = 0, /**< Unknown */
ModeAPI1 = 1, /**< API1 */
ModeAPI2 = 2, /**< API2 */
ModeTransparent = 3, /**< Transparent */
ModeBootloader = 4, /**< Bootloader */
};
/** Class constructor
* @param tx the TX pin of the UART that will interface the XBee module
* @param rx the RX pin of the UART that will interface the XBee module
* @param reset the pin to which the XBee's reset line is attached to, use NC if not available
* @param rts the RTS pin for the UART that will interface the XBee module, use NC if not available
* @param cts the CTS pin for the UART that will interface the XBee module, use NC if not available
* @param baud the baudrate for the UART that will interface the XBee module. Note that the module has to be already configured
* to this baud rate (ATBD parameter). By default it is configured to 9600 bps
* */
XBee(PinName tx, PinName rx, PinName reset = NC, PinName rts = NC, PinName cts = NC, int baud = 9600);
XBee(const XBee& other); /* Intentionally not implemented */
/** Class destructor */
virtual ~XBee();
/** init- initializes object
* This function must be called just after creating the object so it initializes internal data.
* @returns
* Success if the module has been properly initialized and is ready to process data.
* Failure otherwise.
*/
RadioStatus init();
/** get_addr64 - returns the 64bit address of the local device
*
* @returns the 64bit address of the local device
*/
uint64_t get_addr64() const;
/** get_addr16 - returns the 16bit address of the local device
*
* @returns the 16-bit address of the local device.
*/
uint16_t get_addr16() const;
/** get_network_address - gets the 16bit network address of the device
*
* @param addr pointer where the device 16bit network address will be stored
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus get_network_address(uint16_t * const addr);
/** hardware_reset - performs a hardware reset. The reset GPIO must have
* been provided to the constructor
*
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus hardware_reset();
/** software_reset - performs a firmware reset
*
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus software_reset();
/** device_reset - performs a hardware reset if there is a GPIO connected to the
* reset line of the device. Otherwise, performs a firmware reset.
*
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
#if defined(UNIT_TEST)
virtual
#endif
RadioStatus device_reset();
/** get_radio_type - returns the type of radio, in most cases the hardware version
*
* @returns the radio type
*/
RadioType get_radio_type() const;
/** set_tx_options - sets the transmit options byte, used with the transmit frames.
* Valid flags are:
* - DISABLE_RETRIES_AND_ROUTE_REPAIR
* - ENABLE_APS_ENCRYPTION
* - USE_EXTENDED_TX_TIMEOUT
*
* @param options variable with the option flags
*/
void set_tx_options(uint8_t options);
/** set_broadcast_radius - sets the max number of hops for a broadcast msg.
* When set to 0 uses the maximum possible.
*
* @param bc_radius variable with the broadcast radious
*/
void set_broadcast_radius(uint8_t bc_radius);
/** get_tx_options - returns the tx options byte configured in the library.
*
* @returns the tx options byte configured in the library.
*/
uint8_t get_tx_options() const;
/** get_bc_radius - returns the broadcast radius configured in the library.
*
* @returns the broadcast radius configured in the library.
*/
uint8_t get_bc_radius() const;
/************************ Configuration member methods *************************/
/** write_config - write settings to non volatile memory
*
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus write_config();
/** config_io_sample_destination - configures to which node a remote module will send its IO Samples to.
* @Note: this will modify 'remote' DH and DL parameters, if the remote node is configured in transparent mode this could lead to unwanted behavior.
* Consult the module's reference manual for more information.
*
* @param remote remote device that will be sending the IO Samples
* @param destination remote device that will be receiving the IO Samples sent by 'remote'
* @returns the result of the data transfer
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus config_io_sample_destination(const RemoteXBee& remote, const RemoteXBee& destination);
/** set_io_sample_rate - configures how often the IO Samples should be sent to the destination (see @ref send_io_sample_to).
*
* @param remote remote device that will be sending the IO Samples
* @param seconds the IO Sample sending rate in seconds (granularity is of 1 millisecond). Maximum is 65.535 seconds.
* @returns the result of the data transfer
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus set_io_sample_rate(const RemoteXBee& remote, float seconds);
/** set_power_level - sets the power level at which the radio will transmit
*
* @param level power level at which the radio will transmit
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus set_power_level(uint8_t level);
/** get_power_level - reads the power level configured in the radio
*
* @param level pointer where the read power level will be stored
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus get_power_level(uint8_t * const level);
/** get_hw_version - gets the hardware version of the radio
*
* @returns the hardware version of the radio
*/
uint16_t get_hw_version() const;
/** get_fw_version - gets the firmware version of the radio
*
* @returns the firmware version of the radio
*/
uint16_t get_fw_version() const;
/** set_node_identifier - configures the Node Identifier string
*
* @param node_id NULL-terminated string with the Node Identifier that will be set on the module. Up to 20 characters length (21 with NULL-terminator).
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus set_node_identifier(const char * const node_id);
/** get_node_identifier - reads the configured Node Identifier string
*
* @param node_id Pointer to where to store the read Node Identifier, it must point to a buffer with at least 21-bytes length.
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus get_node_identifier(char * const node_id);
/** start_node_discovery - starts a node discovery operation. The responses
* have to be processes on the callback function that have to be registered
* for that purpose
*
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus start_node_discovery();
#define XBEEZB_ND_OPTION_APPEND_DD (1 << 0)
#define XBEEZB_ND_OPTION_SELF_RESPONSE (1 << 1)
#define XBEE802_ND_OPTION_SELF_RESPONSE (1 << 0)
/** config_node_discovery - configures the node discovery operation
*
* @param timeout_ms max allowed time for devices in the network to answer
* to the Node Discovery request
* @param options node discovery options (flags)
* XBEE802_ND_OPTION_SELF_RESPONSE - to allow the module self responding (802.15.4 only)
* XBEEZB_ND_OPTION_SELF_RESPONSE - to allow the module self responding (ZigBee only)
* XBEEZB_ND_OPTION_APPEND_DD - to append the DD value to the response (ZigBee only)
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus config_node_discovery(uint16_t timeout_ms, uint8_t options = 0);
/** get_config_node_discovery - reads the configuration of the node discovery
* settings
*
* @param timeout_ms pointer where the node discovery time out value will be stored
* @param options pointer whre the node discovery options (flags) will be saved
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus get_config_node_discovery(uint16_t * const timeout_ms, uint8_t * const options);
/** set_timeout - sets the timeout in ms, used by sync methods
*
* @param timeout_ms new timeout in ms
*/
void set_timeout(uint16_t timeout_ms);
/** get_timeout - gets the timeout in ms configured in the library. This value
* is used in sync commands
*
* @returns the configured timeout value in ms
*/
uint16_t get_timeout() const;
/* ... */
/*********************** send_data member methods ************************/
/** send_data - sends data to a remote device waiting for the packet
* answer with the result of the operation
*
* @param remote remote device
* @param data pointer to the data that will be sent
* @param len number of bytes that will be transmitted
* @returns the result of the data transfer
* TxStatusSuccess if the operation was successful,
* the error code otherwise
*/
virtual TxStatus send_data(const RemoteXBee& remote, const uint8_t *const data, uint16_t len) = 0;
/** send_data_broadcast - sends data to all devices in the network, using the
* broadcast address. The method waits for the packet
* answer with the result of the operation
*
* @param data pointer to the data that will be sent
* @param len number of bytes that will be transmitted
* @returns the result of the data transfer
* TxStatusSuccess if the operation was successful,
* the error code otherwise
*/
TxStatus send_data_broadcast(const uint8_t *const data, uint16_t len);
/** set_param - sets a parameter in the local radio by sending an AT command and waiting for the response.
*
* @param param parameter to be set.
* @param data the parameter value (4 bytes) to be set.
* @returns the command response status.
*/
AtCmdFrame::AtCmdResp set_param(const char * const param, uint32_t data);
/** set_param - sets a parameter in the local radio by sending an AT command and waiting for the response.
*
* @param param parameter to be set.
* @param data the parameter value byte array (len bytes) to be set.
* @param len number of bytes of the parameter value.
* @returns the command response status.
*/
AtCmdFrame::AtCmdResp set_param(const char * const param, const uint8_t * data = NULL, uint16_t len = 0);
/** get_param - gets a parameter from the local radio by sending an AT command and waiting for the response.
*
* @param param parameter to be get.
* @param data pointer where the param value (4 bytes) will be stored.
* @returns the command response status.
*/
AtCmdFrame::AtCmdResp get_param(const char * const param, uint32_t * const data);
/** get_param - gets a parameter from the local radio by sending an AT command and waiting for the response.
*
* @param param parameter to be get.
* @param data pointer where the param value (n bytes) will be stored.
* @param len pointer where the number of bytes of the param value will be stored.
* @returns the command response status.
*/
AtCmdFrame::AtCmdResp get_param(const char * const param, uint8_t * const data, uint16_t * const len);
/** set_param - sets a parameter in a remote radio by sending an AT command and waiting for the response.
*
* @param remote remote device
* @param param parameter to be set.
* @param data the parameter value (4 bytes) to be set.
* @returns the command response status.
*/
virtual AtCmdFrame::AtCmdResp set_param(const RemoteXBee& remote, const char * const param, uint32_t data) = 0;
/** set_param - sets a parameter in a remote radio by sending an AT command and waiting for the response.
*
* @param remote remote device
* @param param parameter to be set.
* @param data the parameter value byte array (len bytes) to be set.
* @param len number of bytes of the parameter value.
* @returns the command response status.
*/
virtual AtCmdFrame::AtCmdResp set_param(const RemoteXBee& remote, const char * const param, const uint8_t * data = NULL, uint16_t len = 0) = 0;
/** get_param - gets a parameter from a remote radio by sending an AT command and waiting for the response.
*
* @param remote remote device
* @param param parameter to be get.
* @param data pointer where the param value (4 bytes) will be stored.
* @returns the command response status.
*/
virtual AtCmdFrame::AtCmdResp get_param(const RemoteXBee& remote, const char * const param, uint32_t * const data) = 0;
/** get_param - gets a parameter from a remote radio by sending an AT command and waiting for the response.
*
* @param remote remote device
* @param param parameter to be get.
* @param data pointer where the param value (n bytes) will be stored.
* @param len pointer where the number of bytes of the param value will be stored.
* @returns the command response status.
*/
virtual AtCmdFrame::AtCmdResp get_param(const RemoteXBee& remote, const char * const param, uint8_t * const data, uint16_t * const len) = 0;
#if defined(ENABLE_PM_SUPPORT)
/** set_pm_control - sets the operational mode of the Power Management on
* the radio and registers the GPIOs used to handle the
* Power Management
*
* @param mode operational mode of the power management
* @param on_sleep pin used to detect the on/sleep status of the module
* @param sleep_rq pin used to request the module to go to sleep (when pin
* sleep mode is used
* @returns the result of the configuration operation
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus set_pm_control(PmMode mode, PinName on_sleep = NC, PinName sleep_rq = NC);
/** get_pm_mode - gets the power management mode programmed in the radio.
*
* @param mode pointer where the read mode will be stored.
* @returns the result of the configuration operation
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus get_pm_mode(PmMode *mode);
/** config_pm_timing - configures the power management timing parameters.
*
* @param before_sleep_ms number of miliseconds of inactivity before the radio will
* automatically go to sleep again (when using cyclic sleep).
* @param total_sleep_period_ms time interval in ms the radio will be sleeping. Once
* this time passes, the radio will wakeup, will check for
* packets and will wait before_sleep_ms of inactivity
* before entering again in sleep mode.
* @returns the result of the configuration operation
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus config_pm_timing(uint32_t before_sleep_ms, uint32_t total_sleep_period_ms);
/** enter_sleep_mode - sets the radio into low power mode. If the pm working mode
* is pin-sleep, then it will use the GPIO, otherwise, it will
* use the serial interface.
*
* @note the method does not wait until the radio enters in sleep mode, it returns
* without making any verification.
* @returns the result of the operation
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus enter_sleep_mode();
/** exit_sleep_mode - for the pm mode called pin-sleep, sets the radio into active power
* using the corresponding GPIO.
*
*/
void exit_sleep_mode();
/** is_sleeping - checks if the radio is sleeping or if its active.
*
* @returns true if the radio is sleeping, false otherwisw
*/
bool is_sleeping();
/** register_wakeup_cb - registers the callback function that will be called
* when the radio wakes up from sleep mode.
*
* @param f function pointer with the callback function
*/
void register_wakeup_cb(void (*f)(void));
/** unregister_wakeup_cb - removes the wakeup callback */
void unregister_wakeup_cb();
#endif /* defined(ENABLE_PM_SUPPORT) */
/** process_rx_frames - method that process the frames queued in the reception
* buffer. Calls the process_frame_data method of the frame
* handlers registered
*
* @returns Number of dropped frames since latest call to this method.
*/
uint32_t process_rx_frames();
/** register_modem_status_cb - registers the callback function that will be called
* when a Modem Status packet is received
*
* @param function function pointer with the callback function
*/
void register_modem_status_cb(modem_status_cb_t function);
/** unregister_modem_status_cb - removes the Modem Status reception callback */
void unregister_modem_status_cb();
protected:
enum RadioProtocol {
None,
ZigBee,
Raw_802_15_4,
#ifdef EXTRA_XBEE_PROTOCOLS
XBeeWiFi,
DigiMesh,
SmartEnergy,
DigiPoint,
ZNet,
#endif
};
/** send_byte_escaping_if - sends a byte, through the serial interface, to
* the radio, escaping the byte if the working mode of the radio is API2.
*
* @param line PWM line being set
* @param data the byte that will be send to radio
*/
void send_byte_escaping_if(uint8_t data);
/** uart_read_cb - serial interface callback, called when data is received on
* the serial port. The function parses the incoming data and, when a good
* frame is detected, saves it in the frame list
*/
void uart_read_cb();
/** get_this_api_frame - searches in the FrameBuffer for an incoming frame
* with frameid equal to id and frame type equal to type
* or type2. If after timeout the frame hast not been found,
* returns.
*
* @param id id of the frame we are looking for.
* @param type tye type we expect the frame to be.
* @param type2 alternative valid type, if provided.
* @returns a pointer to the frame found in the FrameBuffer or a null pointer if
* the frame has not been found and the timeout expired.
*/
ApiFrame * get_this_api_frame(uint8_t id, ApiFrame::ApiFrameType type,
ApiFrame::ApiFrameType type2 = ApiFrame::Invalid);
/** send_api_frame - method to send, over the serial port, an API frame
*
* @param frame pointer to the frame that will be sent.
*/
#if defined(UNIT_TEST)
virtual
#endif
void send_api_frame(ApiFrame *frame);
/** update_radio_status - method called when a modem status frame is received
* to update the internal status variables of the library.
* @note This is not a pure virtual function because it can be called while
* the object is being constructed and we need the implementation of the
* base class.
*
* @param status byte with the status received in the modem status frame
*/
virtual void radio_status_update(AtCmdFrame::ModemStatus modem_status);
/** Method used internaly by the derived classes to transmit data to
* remote nodes, waiting for the answer from the device
*
* @param frame frame that will be sent to the radio (have to be a
* proper transmit frame
* @returns the result of the data transfer
* TxStatusSuccess if the operation was successful,
* the error code otherwise
*/
TxStatus send_data(ApiFrame *frame);
/** send_at_cmd - sends an AT command to the radio and waits for the response.
*
* @param frame api frame with the command and command params.
* @param buf pointer where the param response (n bytes) will be stored.
* @param len pointer where the number of bytes of the param response will be stored.
* @param radio_location radio location, either RadioLocal or RadioRemote.
* @param reverse reverse the byte ordering of the response saved in buf.
* @returns the command response status.
*/
AtCmdFrame::AtCmdResp send_at_cmd(AtCmdFrame *frame,
uint8_t *const buf, uint16_t *const len, RadioLocation radio_location = RadioLocal, bool reverse = true);
/* send_at_cmd - methods used internally by other methods */
AtCmdFrame::AtCmdResp send_at_cmd(AtCmdFrame *frame);
AtCmdFrame::AtCmdResp send_at_cmd(AtCmdFrame *frame, uint8_t *data);
AtCmdFrame::AtCmdResp send_at_cmd(AtCmdFrame *frame, uint16_t *data);
AtCmdFrame::AtCmdResp send_at_cmd(AtCmdFrame *frame, uint32_t *data);
#if defined(ENABLE_PM_SUPPORT)
/** Sets the radio into low power mode. This method is used by enter_sleep_mode() */
RadioStatus sleep_now();
#endif /* defined(ENABLE_PM_SUPPORT) */
/** register_frame_handler - registers an object to handle incoming frames from
* the radio.
* @note For any type of frame more than one handler can be registered and all
* of them are called, sequentially, when a frame of that type arrives.
*
* @param handler pointer to the frame handler object
* @returns the result of the registration
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus register_frame_handler(FrameHandler *const handler);
/** unregister_frame_handler - removes a previously registered frame handler
*
* @param handler pointer to the frame handler object
* @returns the result of the unregister operation
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus unregister_frame_handler(FrameHandler *const handler);
/** get_radio_protocol - returns the RF protocol that the connected module uses
* based on its firmware and hardware versions
*
* @returns a RadioProtocol enum.
*/
RadioProtocol get_radio_protocol(void) const;
/** get_iosample - forces an io_sample read (reads all digital and analog inputs)
*
* @param remote remote device
* @param io_sample buffer where the io_sample response is copied
* @param len pointer where the length of the io_sample response is stored
* @returns
* Success if the operation was successful,
* Failure otherwise
*/
RadioStatus get_iosample(const RemoteXBee& remote, uint8_t * const io_sample, uint16_t * const len);
void _get_remote_node_by_id(const char * const node_id, uint64_t * addr64, uint16_t * addr16);
/** check_radio_flow_control - checks that the radio has the CTS "D7" and RTS "D6" pins configured
* according to the serial hardware flow control selected by the user
*
* @returns true if check success.
*/
bool check_radio_flow_control();
/** serial hardware flow control selected by the user (RTSCTS, RTS,CTS) */
SerialBase::Flow _serial_flow_type;
/** Operating mode of the module (API1, API2,...) */
RadioMode _mode;
/** Type of radio, mainly the hardware version, but may differ in some cases */
RadioType _type;
/** Hardware version value of the radio */
uint16_t _hw_version;
/** Firmware version value of the radio */
uint16_t _fw_version;
/** Timeout in ms for sync operations (when we wait for a response) */
uint16_t _timeout_ms;
/** Device 64 bit address (SH, SL) */
uint64_t _dev_addr64;
/** Device 16 bit address (MY) */
uint16_t _dev_addr16;
/** Serial Interface, use RawSerial as we dont use the streams */
RawSerial *_uart;
/** IO connected to the radio reset line */
DigitalOut *_reset;
/** Transmit options byte */
uint8_t _tx_options;
/** Broadcast radius, number of hops a broadcast transmission can occur.
* When set to 0 it will use the maximum */
uint8_t _bc_radius;
/** Array of frame handler pointers. We use an array instead of a vector or other
* data structure to save memory and avoid dynamic memory allocation, to avoid
* memory fragmentation */
FrameHandler *_fhandlers[MAX_FRAME_HANDLERS];
/** Hardware reset counter, automatically updated by the library */
volatile uint16_t _hw_reset_cnt;
/** Watchdog reset counter, automatically updated by the library */
volatile uint16_t _wd_reset_cnt;
uint16_t _reset_timeout;
/** Frame handler used for the Modem Status packets. Automatically registered when a callback
* function is registered */
FH_ModemStatus *_modem_status_handler;
/** Latest modem status received */
AtCmdFrame::ModemStatus _modem_status;
/** Library is initializing */
bool _initializing;
#if defined(ENABLE_PM_SUPPORT)
/* Power Management mode used by the radio */
PmMode _pm_mode;
/** IO connected to the radio on_sleep line */
InterruptIn *_on_sleep;
/** IO connected to the radio sleep_req line */
DigitalOut *_sleep_req;
#endif
};
} /* namespace XBeeLib */
#endif /* defined(__DIGI_RADIO_H_) */