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RHMesh.h
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RHMesh.h
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// RHMesh.h
//
// Author: Mike McCauley ([email protected])
// Copyright (C) 2011 Mike McCauley
// $Id: RHMesh.h,v 1.15 2015/08/13 02:45:47 mikem Exp $
#ifndef RHMesh_h
#define RHMesh_h
#include <RHRouter.h>
// Types of RHMesh message, used to set msgType in the RHMeshHeader
#define RH_MESH_MESSAGE_TYPE_APPLICATION 0
#define RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST 1
#define RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE 2
#define RH_MESH_MESSAGE_TYPE_ROUTE_FAILURE 3
// Timeout for address resolution in milliecs
#define RH_MESH_ARP_TIMEOUT 4000
/////////////////////////////////////////////////////////////////////
/// \class RHMesh RHMesh.h <RHMesh.h>
/// \brief RHRouter subclass for sending addressed, optionally acknowledged datagrams
/// multi-hop routed across a network, with automatic route discovery
///
/// Manager class that extends RHRouter to add automatic route discovery within a mesh of adjacent nodes,
/// and route signalling.
///
/// Unlike RHRouter, RHMesh can be used in networks where the network topology is fluid, or unknown,
/// or if nodes can mode around or go in or out of service. When a node wants to send a
/// message to another node, it will automatically discover a route to the destination node and use it.
/// If the route becomes unavailable, a new route will be discovered.
///
/// \par Route Discovery
///
/// When a RHMesh mesh node is initialised, it doe not know any routes to any other nodes
/// (see RHRouter for details on route and the routing table).
/// When you attempt to send a message with sendtoWait, will first check to see if there is a route to the
/// destinastion node in the routing tabl;e. If not, it wil initialite 'Route Discovery'.
/// When a node needs to discover a route to another node, it broadcasts MeshRouteDiscoveryMessage
/// with a message type of RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST.
/// Any node that receives such a request checks to see if it is a request for a route to itself
/// (in which case it makes a unicast reply to the originating node with a
/// MeshRouteDiscoveryMessage
/// with a message type of RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE)
/// otherwise it rebroadcasts the request, after adding itself to the list of nodes visited so
/// far by the request.
///
/// If a node receives a RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST that already has itself
/// listed in the visited nodes, it knows it has already seen and rebroadcast this request,
/// and threfore ignores it. This prevents broadcast storms.
/// When a node receives a RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST it can use the list of
/// nodes aready visited to deduce routes back towards the originating (requesting node).
/// This also means that when the destination node of the request is reached, it (and all
/// the previous nodes the request visited) will have a route back to the originating node.
/// This means the unicast RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE
/// reply will be routed successfully back to the original route requester.
///
/// The RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE sent back by the destination node contains
/// the full list of nodes that were visited on the way to the destination.
/// Therefore, intermediate nodes that route the reply back towards the originating node can use the
/// node list in the reply to deduce routes to all the nodes between it and the destination node.
///
/// Therefore, RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST and
/// RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE together ensure the original requester and all
/// the intermediate nodes know how to route to the source and destination nodes and every node along the path.
///
/// Note that there is a race condition here that can effect routing on multipath routes. For example,
/// if the route to the destination can traverse several paths, last reply from the destination
/// will be the one used.
///
/// \par Route Failure
///
/// RHRouter (and therefore RHMesh) use reliable hop-to-hop delivery of messages using
/// hop-to-hop acknowledgements, but not end-to-end acknowledgements. When sendtoWait() returns,
/// you know that the message has been delivered to the next hop, but not if it is (or even if it can be)
/// delivered to the destination node. If during the course of hop-to-hop routing of a message,
/// one of the intermediate RHMesh nodes finds it cannot deliver to the next hop
/// (say due to a lost route or no acknwledgement from the next hop), it replies to the
/// originator with a unicast MeshRouteFailureMessage RH_MESH_MESSAGE_TYPE_ROUTE_FAILURE message.
/// Intermediate nodes (on the way beack to the originator)
/// and the originating node use this message to delete the route to the destination
/// node of the original message. This means that if a route to a destination becomes unusable
/// (either because an intermediate node is off the air, or has moved out of range) a new route
/// will be established the next time a message is to be sent.
///
/// \par Message Format
///
/// RHMesh uses a number of message formats layered on top of RHRouter:
/// - MeshApplicationMessage (message type RH_MESH_MESSAGE_TYPE_APPLICATION).
/// Carries an application layer message for the caller of RHMesh
/// - MeshRouteDiscoveryMessage (message types RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST
/// and RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_RESPONSE). Carries Route Discovery messages
/// (broadcast) and replies (unicast).
/// - MeshRouteFailureMessage (message type RH_MESH_MESSAGE_TYPE_ROUTE_FAILURE) Informs nodes of
/// route failures.
///
/// Part of the Arduino RH library for operating with HopeRF RH compatible transceivers
/// (see http://www.hoperf.com)
///
/// \par Memory
///
/// RHMesh programs require significant amount of SRAM, often approaching 2kbytes,
/// which is beyond or at the limits of some Arduinos and other processors. Programs
/// with additional software besides basic RHMesh programs may well require even more. If you have insufficient
/// SRAM for your program, it may result in failure to run, or wierd crashes and other hard to trace behaviour.
/// In this event you should consider a processor with more SRAM, such as the MotienoMEGA with 16k
/// (https://lowpowerlab.com/shop/moteinomega) or others.
///
/// \par Performance
/// This class (in the interests of simple implemtenation and low memory use) does not have
/// message queueing. This means that only one message at a time can be handled. Message transmission
/// failures can have a severe impact on network performance.
/// If you need high performance mesh networking under all conditions consider XBee or similar.
class RHMesh : public RHRouter
{
public:
/// The maximum length permitted for the application payload data in a RHMesh message
#define RH_MESH_MAX_MESSAGE_LEN (RH_ROUTER_MAX_MESSAGE_LEN - sizeof(RHMesh::MeshMessageHeader))
/// Structure of the basic RHMesh header.
typedef struct
{
uint8_t msgType; ///< Type of RHMesh message, one of RH_MESH_MESSAGE_TYPE_*
} MeshMessageHeader;
/// Signals an application layer message for the caller of RHMesh
typedef struct
{
MeshMessageHeader header; ///< msgType = RH_MESH_MESSAGE_TYPE_APPLICATION
uint8_t data[RH_MESH_MAX_MESSAGE_LEN]; ///< Application layer payload data
} MeshApplicationMessage;
/// Signals a route discovery request or reply (At present only supports physical dest addresses of length 1 octet)
typedef struct
{
MeshMessageHeader header; ///< msgType = RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_*
uint8_t destlen; ///< Reserved. Must be 1.g
uint8_t dest; ///< The address of the destination node whose route is being sought
uint8_t route[RH_MESH_MAX_MESSAGE_LEN - 1]; ///< List of node addresses visited so far. Length is implcit
} MeshRouteDiscoveryMessage;
/// Signals a route failure
typedef struct
{
MeshMessageHeader header; ///< msgType = RH_MESH_MESSAGE_TYPE_ROUTE_FAILURE
uint8_t dest; ///< The address of the destination towards which the route failed
} MeshRouteFailureMessage;
/// Constructor.
/// \param[in] driver The RadioHead driver to use to transport messages.
/// \param[in] thisAddress The address to assign to this node. Defaults to 0
RHMesh(RHGenericDriver& driver, uint8_t thisAddress = 0);
/// Sends a message to the destination node. Initialises the RHRouter message header
/// (the SOURCE address is set to the address of this node, HOPS to 0) and calls
/// route() which looks up in the routing table the next hop to deliver to.
/// If no route is known, initiates route discovery and waits for a reply.
/// Then sends the message to the next hop
/// Then waits for an acknowledgement from the next hop
/// (but not from the destination node (if that is different).
/// \param [in] buf The application message data
/// \param [in] len Number of octets in the application message data. 0 is permitted
/// \param [in] dest The destination node address. If the address is RH_BROADCAST_ADDRESS (255)
/// the message will be broadcast to all the nearby nodes, but not routed or relayed.
/// \param [in] flags Optional flags for use by subclasses or application layer,
/// delivered end-to-end to the dest address. The receiver can recover the flags with recvFromAck().
/// \return The result code:
/// - RH_ROUTER_ERROR_NONE Message was routed and delivered to the next hop
/// (not necessarily to the final dest address)
/// - RH_ROUTER_ERROR_NO_ROUTE There was no route for dest in the local routing table
/// - RH_ROUTER_ERROR_UNABLE_TO_DELIVER Not able to deliver to the next hop
/// (usually because it dod not acknowledge due to being off the air or out of range
uint8_t sendtoWait(uint8_t* buf, uint8_t len, uint8_t dest, uint8_t flags = 0);
/// Starts the receiver if it is not running already, processes and possibly routes any received messages
/// addressed to other nodes
/// and delivers any messages addressed to this node.
/// If there is a valid application layer message available for this node (or RH_BROADCAST_ADDRESS),
/// send an acknowledgement to the last hop
/// address (blocking until this is complete), then copy the application message payload data
/// to buf and return true
/// else return false.
/// If a message is copied, *len is set to the length..
/// If from is not NULL, the originator SOURCE address is placed in *source.
/// If to is not NULL, the DEST address is placed in *dest. This might be this nodes address or
/// RH_BROADCAST_ADDRESS.
/// This is the preferred function for getting messages addressed to this node.
/// If the message is not a broadcast, acknowledge to the sender before returning.
/// \param[in] buf Location to copy the received message
/// \param[in,out] len Available space in buf. Set to the actual number of octets copied.
/// \param[in] source If present and not NULL, the referenced uint8_t will be set to the SOURCE address
/// \param[in] dest If present and not NULL, the referenced uint8_t will be set to the DEST address
/// \param[in] id If present and not NULL, the referenced uint8_t will be set to the ID
/// \param[in] flags If present and not NULL, the referenced uint8_t will be set to the FLAGS
/// (not just those addressed to this node).
/// \return true if a valid message was received for this node and copied to buf
bool recvfromAck(uint8_t* buf, uint8_t* len, uint8_t* source = NULL, uint8_t* dest = NULL, uint8_t* id = NULL, uint8_t* flags = NULL);
/// Starts the receiver if it is not running already.
/// Similar to recvfromAck(), this will block until either a valid application layer
/// message available for this node
/// or the timeout expires.
/// \param[in] buf Location to copy the received message
/// \param[in,out] len Available space in buf. Set to the actual number of octets copied.
/// \param[in] timeout Maximum time to wait in milliseconds
/// \param[in] source If present and not NULL, the referenced uint8_t will be set to the SOURCE address
/// \param[in] dest If present and not NULL, the referenced uint8_t will be set to the DEST address
/// \param[in] id If present and not NULL, the referenced uint8_t will be set to the ID
/// \param[in] flags If present and not NULL, the referenced uint8_t will be set to the FLAGS
/// (not just those addressed to this node).
/// \return true if a valid message was copied to buf
bool recvfromAckTimeout(uint8_t* buf, uint8_t* len, uint16_t timeout, uint8_t* source = NULL, uint8_t* dest = NULL, uint8_t* id = NULL, uint8_t* flags = NULL);
protected:
/// Internal function that inspects messages being received and adjusts the routing table if necessary.
/// Called by recvfromAck() immediately after it gets the message from RHReliableDatagram
/// \param [in] message Pointer to the RHRouter message that was received.
/// \param [in] messageLen Length of message in octets
virtual void peekAtMessage(RoutedMessage* message, uint8_t messageLen);
/// Internal function that inspects messages being received and adjusts the routing table if necessary.
/// This is virtual, which lets subclasses override or intercept the route() function.
/// Called by sendtoWait after the message header has been filled in.
/// \param [in] message Pointer to the RHRouter message to be sent.
/// \param [in] messageLen Length of message in octets
virtual uint8_t route(RoutedMessage* message, uint8_t messageLen);
/// Try to resolve a route for the given address. Blocks while discovering the route
/// which may take up to 4000 msec.
/// Virtual so subclasses can override.
/// \param [in] address The physical address to resolve
/// \return true if the address was resolved and added to the local routing table
virtual bool doArp(uint8_t address);
/// Tests if the given address of length addresslen is indentical to the
/// physical address of this node.
/// RHMesh always implements physical addresses as the 1 octet address of the node
/// given by _thisAddress
/// Called by recvfromAck() to test whether a RH_MESH_MESSAGE_TYPE_ROUTE_DISCOVERY_REQUEST
/// is for this node.
/// Subclasses may want to override to implement more complicated or longer physical addresses
/// \param [in] address Address of the pyysical addres being tested
/// \param [in] addresslen Lengthof the address in bytes
/// \return true if the physical address of this node is identical to address
virtual bool isPhysicalAddress(uint8_t* address, uint8_t addresslen);
private:
/// Temporary message buffer
static uint8_t _tmpMessage[RH_ROUTER_MAX_MESSAGE_LEN];
};
/// @example rf22_mesh_client.pde
/// @example rf22_mesh_server1.pde
/// @example rf22_mesh_server2.pde
/// @example rf22_mesh_server3.pde
#endif