DarkflameServer/thirdparty/raknet/Source/ReplicaManager.h
2021-12-05 18:54:36 +01:00

481 lines
30 KiB
C++

/// \file
/// \brief Contains class ReplicaManager. This system provides management for your game objects and players to make serialization, scoping, and object creation and destruction easier.
///
/// This file is part of RakNet Copyright 2003 Kevin Jenkins.
///
/// Usage of RakNet is subject to the appropriate license agreement.
/// Creative Commons Licensees are subject to the
/// license found at
/// http://creativecommons.org/licenses/by-nc/2.5/
/// Single application licensees are subject to the license found at
/// http://www.jenkinssoftware.com/SingleApplicationLicense.html
/// Custom license users are subject to the terms therein.
/// GPL license users are subject to the GNU General Public
/// License as published by the Free
/// Software Foundation; either version 2 of the License, or (at your
/// option) any later version.
#ifndef __REPLICA_MANAGER_H
#define __REPLICA_MANAGER_H
#include "Export.h"
#include "RakNetTypes.h"
#include "DS_OrderedList.h"
#include "PluginInterface.h"
#include "NetworkIDObject.h"
#include "DS_Queue.h"
#include "ReplicaEnums.h"
/// Forward declarations
namespace RakNet
{
class BitStream;
};
class Replica;
class ReplicaManager;
/// \defgroup REPLICA_MANAGER_GROUP ReplicaManager
/// \ingroup PLUGINS_GROUP
/// An interface for a class that handles the construction callback from the network
/// See ReplicaManager::SetReceiveConstructionCB
/// \ingroup REPLICA_MANAGER_GROUP
class ReceiveConstructionInterface
{
public:
ReceiveConstructionInterface() {}
virtual ~ReceiveConstructionInterface() {}
/// Called when a network object needs to be created by the ReplicaManager class
/// \param[in] inBitStream The bitstream that was written to in Replica::SendConstruction
/// \param[in] timestamp If in Replica::SendConstruction you set sendTimestamp to true, this is the time the packet was sent. Otherwise it is 0.
/// \param[in] networkID If the remote object had an NetworkID set by the time Replica::SendConstruction was called it is here.
/// \param[in] existingNetworkObject If networkID is already in use, existingNetworkObject is the pointer to that object. If existingReplica is non-zero, you usually shouldn't create a new object, unless you are reusing networkIDs, such as having the client and server both on the same computer
/// \param[in] senderId Which SystemAddress sent this packet.
/// \param[in] caller Which instance of ReplicaManager is calling this interface
/// \return See ReplicaReturnResult
virtual ReplicaReturnResult ReceiveConstruction(RakNet::BitStream *inBitStream, RakNetTime timestamp, NetworkID networkID, NetworkIDObject *existingObject, SystemAddress senderId, ReplicaManager *caller)=0;
};
/// An interface for a class that handles the call to send the download complete notification
/// See ReplicaManager::SetDownloadCompleteCB
/// \ingroup REPLICA_MANAGER_GROUP
class SendDownloadCompleteInterface
{
public:
SendDownloadCompleteInterface() {}
virtual ~SendDownloadCompleteInterface() {}
/// \param[out] outBitStream Write whatever you want to this bitstream. It will arrive in the receiveDownloadCompleteCB callback.
/// \param[in] currentTime The current time that would be returned by RakNet::GetTime(). That's a slow call I do already, so you can use the parameter instead of having to call it yourself.
/// \param[in] senderId Who we are sending to
/// \param[in] caller Which instance of ReplicaManager is calling this interface
/// \return See ReplicaReturnResult
virtual ReplicaReturnResult SendDownloadComplete(RakNet::BitStream *outBitStream, RakNetTime currentTime, SystemAddress senderId, ReplicaManager *caller)=0;
};
/// An interface for a class that handles the call to receive the download complete notification
/// See ReplicaManager::SetDownloadCompleteCB
/// \ingroup REPLICA_MANAGER_GROUP
class ReceiveDownloadCompleteInterface
{
public:
ReceiveDownloadCompleteInterface() {}
virtual ~ReceiveDownloadCompleteInterface() {}
/// \param[in] inBitStream The bitstream that was written to in SendDownloadCompleteInterface::SendDownloadComplete
/// \param[in] senderId The SystemAddress of the system that send the datagram
/// \param[in] caller Which instance of ReplicaManager is calling this interface
/// \return See ReplicaReturnResult
virtual ReplicaReturnResult ReceiveDownloadComplete(RakNet::BitStream *inBitStream, SystemAddress senderId, ReplicaManager *caller)=0;
};
/// \deprecated Use RM2_ReplicaManager in ReplicaManager2.h
/// ReplicaManager is a system manager for your game objects that performs the following tasks:
/// 1. Tracks all locally registered game objects and players and only performs operations to and for those objects and players
/// 2. Allows you to automatically turn off unneeded local and remote functions for your game objects, thus providing convenience and security against unauthorized sends.
/// 3. Sends notifications of existing game objects to new connections, including a download complete message.
/// 4. Sends notifications of new game objects to existing players.
/// A. Serialize and scoping calls are not sent to objects that were not notified of that object.
/// B. Notification calls can be canceled on a per-object basis. Object notification sends are tracked on a per-system per-object basis.
/// 5. Configurable per-system per-object scoping.
/// A. Scoping provides a mechanism to hide and unhide remote objects without destroying the whole object, used when when entities should not be destroyed but are currently not visible to systems.
/// B. Serialize calls are not sent to hidden objects.
/// C. Scoping calls can be canceled on a per-object basis. Scope is tracked on a per-system per-object basis.
/// 6. Replicate, SetScope, SignalSerializeNeeded, and the corresponding Replica interfaces are processed in RakPeer::Receive, rather than immediately.
/// A. This allows the ReplicaManager to reorganize function calls in order by dependency. This allows out of order calls, per-object call cancellation (which also cancels dependencies), and per-object call delays (which also delays dependencies)
/// B. For example, although SetScope and SignalSerializeNeeded have a dependency on SetNetworkID(), you can still call them in the constructor and call SetNetworkID() later, as long as it happens before calling RakPeer::Receive()
/// 7. The system is fast, uses little memory, and is intentionally hands off such that it can work with any game architecture and network topology
///
/// What the ReplicaManager system does NOT do for you
/// 1. Actually create or destroy your game objects
/// 2. Associate object destruction events with remote system disconnects.
/// 3. Set networkIDs via SetNetworkID() on newly created objects.
/// 4. Object sub-serialization. Serialize only granular on the level of entire objects. If you want to serialize part of the object, you need to set your own flags and indicate in the BitStream which parts were sent and which not.
/// \brief A management system for your game objects and players to make serialization, scoping, and object creation and destruction easier.
/// \pre You must call RakPeer::SetNetworkIDManager to use this plugin.
/// \ingroup REPLICA_MANAGER_GROUP
class RAK_DLL_EXPORT ReplicaManager : public PluginInterface
{
public:
/// Constructor
ReplicaManager();
/// Destructor
virtual ~ReplicaManager();
/// If you think all objects should have been removed, call this to assert on any that were not.
/// Useful for debugging shutdown or restarts
void AssertReplicatedObjectsClear(void);
/// If you think all participants should have been removed, call this to assert on any that were not.
/// Useful for debugging shutdown or restarts
void AssertParticipantsClear(void);
/// Do or don't automatically call AddParticipant when new systems connect to us.
/// Won't add automatically add connections that already exist before this was called
/// Defaults to false
/// \param[in] autoAdd True or false, to add or not
void SetAutoParticipateNewConnections(bool autoAdd);
/// Adds a participant to the ReplicaManager system. Only these participants get packets and we only accept ReplicaManager packets from these participants.
/// This way you can have connections that have nothing to do with your game - for example remote console logins
/// \param[in] systemAddress Which player you are referring to
/// \return True on success, false on participant already exists
bool AddParticipant(SystemAddress systemAddress);
/// Removes a participant from the data replicator system
/// This is called automatically on ID_DISCONNECTION_NOTIFICATION and ID_CONNECTION_LOST messages, as well as CloseConnection() calls.
/// \param[in] systemAddress Which player you are referring to
/// \return True on success, false on participant does not exist
bool RemoveParticipant(SystemAddress systemAddress);
/// Construct the specified object on the specified system
/// Replica::SendConstruction will be called immediately, this is a change from before, because otherwise if you later send other packets that refer to this object, this object won't exist yet.
/// The other system will get Replica::ReceiveConstruction
/// If your system assigns NetworkIDs, do so before calling Replicate as the NetworkID is automatically included in the packet.
/// Replicate packets that are sent to systems that already have this NetworkID are ignored.
/// \note Objects which are replicated get exactly one call to SendConstruction for every player / object permutation.
/// \note To perform scoping and serialize updates on an object already created by another system, call Construct with \a isCopy true.
/// \note Setting \a isCopy true will consider the object created on that system without actually trying to create it.
/// \note If you don't need to send updates to other systems for this object, it is more efficient to use ReferencePointer instead.
/// \note In a client / server environment, be sure to call Construct() with isCopy true to let the ReplicaManager know that the server has this object. Otherwise you won't be able to send Scope or Serialize changes to the server.
/// \param[in] replica A pointer to your object
/// \param[in] isCopy True means that this is a copy of an object that already exists on the systems specified by \a systemAddress and \a broadcast. If true, we will consider these systems as having the object without sending a datagram to them. SendConstruction will NOT be called for objects which \a isCopy is true.
/// \param[in] systemAddress The participant to send the command to, or the one to exclude if broadcast is true.
/// \param[in] broadcast True to send to all. If systemAddress!=UNASSIGNED_SYSTEM_ADDRESS then this means send to all but that participant
void Construct(Replica *replica, bool isCopy, SystemAddress systemAddress, bool broadcast);
/// Call this with your game objects to have them send Replica::SendDestruction.
/// This will be sent immediately to all participants that have this object. Those participants will get Replica::ReceiveDestruction
/// All pending calls for this object, for this player, are canceled.
/// Nothing is actually deleted - this just signals that the other system called this function. It is up to you to actually delete your object.
/// \pre Call Replicate with this object first.
/// \pre For the other system to get the network message, SetNetworkID on that object must have been called with the same value as GetNetworkID for this object.
/// \note Call Destruct before DereferencePointer if you plan on calling both, since Destruct will fail with no pointer reference.
/// \note Calling ( with systemAddress==UNASSIGNED_SYSTEM_ADDRESS and broadcast true is equivalent to calling DereferencePointer except that Destruct also sends the destruct packet.
/// \note It is important to call this before deleting your object. Otherwise this system will crash the next Update call.
/// \param[in] replica A pointer to your object
/// \param[in] systemAddress The participant to send the command to, or the one to exclude if broadcast is true.
/// \param[in] broadcast True to send to all systems that have the object. If systemAddress!=UNASSIGNED_SYSTEM_ADDRESS then this means send to all but that participant
void Destruct(Replica *replica, SystemAddress systemAddress, bool broadcast);
/// This makes sure the object is tracked, so you can get calls on it.
/// This will automatically happen if you call Construct, SetScope, or SignalSerializeNeeded with \a replica
/// Otherwise you need to call this, or for security the system will ignore calls that reference this object, even if given a valid NetworkID
/// Duplicate calls are safe and are simply ignored.
/// Best place to put this is in the SetReceiveConstructionCB callback so that all your objects are registered.
/// \param[in] replica A pointer to your object
void ReferencePointer(Replica *replica);
/// Call this before you delete \a replica. This locally removes all references to this pointer.
/// No messages are sent.
/// Best place to put this is in the destructor of \a replica
/// \param[in] replica A pointer to your object
void DereferencePointer(Replica *replica);
/// Sets the scope of your object in relation to another participant.
/// Objects that are in-scope for that participant will send out Replica::Serialize calls. Otherwise Serialize calls are not sent.
/// Scoping is useful when you want to disable sends to an object temporarily, without deleting that object.
/// Calling this results in Replica::SendScopeChange being called on the local object and Replica::ReceiveScopeChange on the remote object if that object has been created on that remote system.
/// Your game should ensure that objects not in scope are hidden, but not deallocated, on the remote system.
/// Replica::SendScopeChange with \a inScope as true will automatically perform Replica::Serialize
/// \pre Call Replicate with this object first.
/// \pre For the other system to get the network message, that object must have an NetworkID (set by SetNetworkID()) the same as our object's NetworkID (returned from GetNetworkID()).
/// \note You can set the default scope with SetDefaultScope()
/// \note Individual objects can refuse to perform the SendScopeChange call by not writing to the output bitstream while returning true.
/// \param[in] replica An object previously registered with Replicate
/// \param[in] inScope in scope or not.
/// \param[in] systemAddress The participant to send the command to, or the one to exclude if broadcast is true.
/// \param[in] broadcast True to send to all. If systemAddress!=UNASSIGNED_SYSTEM_ADDRESS then this means send to all but that participant
void SetScope(Replica *replica, bool inScope, SystemAddress systemAddress, bool broadcast);
/// Signal that data has changed and we need to call Serialize() on the \a replica object.
/// This will happen if the object has been registered, Replica::SendConstruction wrote to outBitStream and returned true, and the object is in scope for this player.
/// \pre Call Replicate with this object first.
/// \pre For the other system to get the network message, that object must have an NetworkID (set by SetNetworkID()) the same as our object's NetworkID (returned from GetNetworkID()).
/// \param[in] replica An object previously registered with Replicate
/// \param[in] systemAddress The participant to send the command to, or the one to exclude if broadcast is true.
/// \param[in] broadcast True to send to all. If systemAddress!=UNASSIGNED_SYSTEM_ADDRESS then this means send to all but that participant
void SignalSerializeNeeded(Replica *replica, SystemAddress systemAddress, bool broadcast);
/// Required callback
/// Set your callback to parse requests to create new objects. Specifically, when Replica::SendConstruction is called and the networkID of the object is either unset or can't be found, this callback will get that call.
/// How do you know what object to create? It's up to you, but I suggest in Replica::SendConstruction you encode the class name. The best way to do this is with the StringTable class.
/// \note If you return true from NetworkIDManager::IsNetworkIDAuthority, which you should do for a server or peer, I recommend also encoding the value returned by GetNetworkID() within Replica::SendConstruction into that bitstream and reading it here. Then set that value in a call to SetNetworkID. Dereplicate, SetScope, and SignalSerializeNeeded all rely on being able to call GET_OBJECT_FROM_ID which requires that SetNetworkID be called on that object.
/// \param[in] ReceiveConstructionInterface An instance of a class that implements ReceiveConstructionInterface
void SetReceiveConstructionCB(ReceiveConstructionInterface *receiveConstructionInterface);
/// Set your callbacks to be called when, after connecting to another system, you get all objects that system is going to send to you when it is done with the first iteration through the object list.
/// Optional if you want to send and receive the download complete notification
/// \param[in] sendDownloadComplete A class that implements the SendDownloadCompleteInterface interface.
/// \param[in] receiveDownloadComplete A class that implements the ReceiveDownloadCompleteInterface interface.
/// \sa SendDownloadCompleteInterface , ReceiveDownloadCompleteInterface
void SetDownloadCompleteCB( SendDownloadCompleteInterface *sendDownloadComplete, ReceiveDownloadCompleteInterface *receiveDownloadComplete );
/// This channel will be used for all RakPeer::Send calls
/// \param[in] channel The channel to use for internal RakPeer::Send calls from this system. Defaults to 0.
void SetSendChannel(unsigned char channel);
/// This means automatically construct all known objects to all new participants
/// Has no effect on existing participants
/// Useful if your architecture always has all objects constructed on all systems all the time anyway, or if you want them to normally start constructed
/// Defaults to false.
/// \param[in] autoConstruct true or false, as desired.
void SetAutoConstructToNewParticipants(bool autoConstruct);
/// Set the default scope for new objects to all players. Defaults to false, which means Serialize will not be called for new objects automatically.
/// If you set this to true, then new players will get existing objects, and new objects will be sent to existing players
/// This only applies to players that connect and objects that are replicated after this call. Existing object scopes are not affected.
/// Useful to set to true if you don't use scope, or if all objects normally start in scope
/// \param[in] scope The default scope to use.
void SetDefaultScope(bool scope);
/// When an object goes in scope for a system, you normally want to serialize that object to that system.
/// Setting this flag to true will call Serialize for you automatically when SendScopeChange returns REPLICA_PROCESSING_DONE and the scopeTrue parameter is true
/// Defaults to false
/// \param[in] autoSerialize True or false as needed.
void SetAutoSerializeInScope(bool autoSerialize);
/// Processes all pending commands and does sends as needed.
/// This is called automatically when RakPeerInterface::Receive is called.
/// Depending on where you call RakPeerInterface::Receive you may also wish to call this manually for better responsiveness.
/// For example, if you call RakPeerInterface::Receive at the start of each game tick, this means you would have to wait a render cycle, causing
/// \param[in] peer Pointer to a valid instance of RakPeerInterface used to perform sends
void Update(RakPeerInterface *peer);
/// Lets you enable calling any or all of the interface functions in an instance of Replica
/// This setting is the same for all participants for this object, so if you want per-participant permissions you will need to handle that inside your implementation
/// All functions enabled by default.
/// \param[in] replica The object you are referring to
/// \param[in] interfaceFlags A bitwise-OR of REPLICA_SEND_CONSTRUCTION ... REPLICA_SET_ALL corresponding to the function of the same name
void EnableReplicaInterfaces(Replica *replica, unsigned char interfaceFlags);
/// Lets you disable calling any or all of the interface functions in an instance of Replica
/// This setting is the same for all participants for this object, so if you want per-participant permissions you will need to handle that inside your implementation
/// All functions enabled by default.
/// \note Disabling functions is very useful for security.
/// \note For example, on the server you may wish to disable all receive functions so clients cannot change server objects.
/// \param[in] replica The object you are referring to
/// \param[in] interfaceFlags A bitwise-OR of REPLICA_SEND_CONSTRUCTION ... REPLICA_SET_ALL corresponding to the function of the same name
void DisableReplicaInterfaces(Replica *replica, unsigned char interfaceFlags);
/// Tells us if a particular system got a SendConstruction() message from this object. e.g. does this object exist on this remote system?
/// This is set by the user when calling Replicate and sending (any) data to outBitStream in Replica::SendConstruction
/// \param[in] replica The object we are checking
/// \param[in] systemAddress The system we are checking
bool IsConstructed(Replica *replica, SystemAddress systemAddress);
/// Tells us if a particular object is in scope for a particular system
/// This is set by the user when calling SetScope and sending (any) data to outBitstream in Replica::SendScopeChange
/// \param[in] replica The object we are checking
/// \param[in] systemAddress The system we are checking
bool IsInScope(Replica *replica, SystemAddress systemAddress);
/// Returns how many Replica instances are registered.
/// This number goes up with each non-duplicate call to Replicate and down with each non-duplicate call to Dereplicate
/// Used for GetReplicaAtIndex if you want to perform some object on all registered Replica objects.
/// \return How many replica objects are in the list of replica objects
unsigned GetReplicaCount(void) const;
/// Returns a previously registered Replica *, from index 0 to GetReplicaCount()-1.
/// The order that Replica * objects are returned in is arbitrary (it currently happens to be ordered by pointer address).
/// Calling Dereplicate immediately deletes the Replica * passed to it, so if you call Dereplicate while using this function
/// the array will be shifted over and the current index will now reference the next object in the array, if there was one.
/// \param[in] index An index, from 0 to GetReplicaCount()-1.
/// \return A Replica * previously passed to Construct()
Replica *GetReplicaAtIndex(unsigned index);
/// Returns the number of unique participants added with AddParticipant
/// As these systems disconnect, they are no longer participants, so this accurately returns how many participants are using the system
/// \return The number of unique participants added with AddParticipant
unsigned GetParticipantCount(void) const;
/// Returns a SystemAddress previously added with AddParticipant
/// \param[in] index An index, from 0 to GetParticipantCount()-1.
/// \return A SystemAddress
SystemAddress GetParticipantAtIndex(unsigned index);
/// Returns if a participant has been added
/// \return If this participant has been added
bool HasParticipant(SystemAddress systemAddress);
/// Each participant has a per-remote object bitfield passed to the Replica::Serialize call.
/// This function can set or unset these flags for one or more participants at the same time.
/// Flags are NOT automatically cleared on serialize. You must clear them when you want to do so.
/// \param[in] replica An object previously registered with Replicate
/// \param[in] systemAddress The participant to set the flags for
/// \param[in] broadcast True to apply to all participants. If systemAddress!=UNASSIGNED_SYSTEM_ADDRESS then this means send to all but that participant
/// \param[in] set True set the bits set in \a flags with the per-object per-system serialization flags. False to unset these bits.
/// \param[in] flags Modifier to the Per-object per-system flags sent to Replica::Serialize. See the parameter /a set
void SignalSerializationFlags(Replica *replica, SystemAddress systemAddress, bool broadcast, bool set, unsigned int flags);
/// Each participant has a per-remote object bitfield passed to the Replica::Serialize call.
/// This function is used to read and change these flags directly for a single participant.
/// It gives more control than SignalSerializationFlags but only works for a single participant at a time.
/// \param[in] replica An object previously registered with Replicate
/// \param[in] systemAddress The participant to read/write the flags for
/// \return A pointer to the per-object per-system flags sent to Replica::Serialize. You can read or modify the flags directly with this function. This pointer is only valid until the next call to RakPeer::Receive
unsigned int* AccessSerializationFlags(Replica *replica, SystemAddress systemAddress);
// ---------------------------- ALL INTERNAL AFTER HERE ----------------------------
enum
{
// Treat the object as on the remote system, and send a packet
REPLICA_EXPLICIT_CONSTRUCTION=1<<0,
// Treat the object as on the remote system, but do not send a packet. Overridden by REPLICA_EXPLICIT_CONSTRUCTION.
REPLICA_IMPLICIT_CONSTRUCTION=1<<1,
REPLICA_SCOPE_TRUE=1<<2, // Mutually exclusive REPLICA_SCOPE_FALSE
REPLICA_SCOPE_FALSE=1<<3, // Mutually exclusive REPLICA_SCOPE_TRUE
REPLICA_SERIALIZE=1<<4,
};
/// \internal
/// One pointer and a command to act on that pointer
struct CommandStruct
{
Replica *replica; // Pointer to an external object - not allocated here.
unsigned char command; // This is one of the enums immediately above.
unsigned int userFlags;
};
struct RegisteredReplica
{
Replica *replica; // Pointer to an external object - not allocated here.
RakNetTime lastDeserializeTrue; // For replicatedObjects it's the last time deserialize returned true.
unsigned char allowedInterfaces; // Replica interface flags
unsigned int referenceOrder; // The order in which we started tracking this object. Used so autoconstruction can send objects in-order
};
struct RemoteObject
{
Replica *replica; // Pointer to an external object - not allocated here.
bool inScope; // Is replica in scope or not?
RakNetTime lastSendTime;
unsigned int userFlags;
};
struct ReceivedCommand
{
SystemAddress systemAddress;
NetworkID networkID;
unsigned command; // A packetID
unsigned u1;
RakNet::BitStream *userData;
};
static int RegisteredReplicaComp( Replica* const &key, const ReplicaManager::RegisteredReplica &data );
static int RegisteredReplicaRefOrderComp( const unsigned int &key, const ReplicaManager::RegisteredReplica &data );
static int RemoteObjectComp( Replica* const &key, const ReplicaManager::RemoteObject &data );
static int CommandStructComp( Replica* const &key, const ReplicaManager::CommandStruct &data );
/// \internal
/// One remote system
struct ParticipantStruct
{
~ParticipantStruct();
// The player this participant struct represents.
SystemAddress systemAddress;
// Call sendDownloadCompleteCB when REPLICA_SEND_CONSTRUCTION is done for all objects in commandList
// This variable tracks if we did it yet or not.
bool callDownloadCompleteCB;
// Sorted list of Replica*, sorted by pointer, along with a command to perform on that pointer.
// Ordering is just for fast lookup.
// Nothing is allocated inside this list
// DataStructures::OrderedList<Replica *, CommandStruct, ReplicaManager::CommandStructComp> commandList;
// June 4, 2007 - Don't sort commands in the command list. The game replies on processing the commands in order
DataStructures::List<CommandStruct> commandList;
// Sorted list of Replica*, sorted by pointer, along with if that object is inScope or not for this system
// Only objects that exist on the remote system are in this list, so not all objects are necessarily in this list
DataStructures::OrderedList<Replica *, RemoteObject, ReplicaManager::RemoteObjectComp> remoteObjectList;
// List of pending ReceivedCommand to process
DataStructures::Queue<ReceivedCommand*> pendingCommands;
};
static int ParticipantStructComp( const SystemAddress &key, ReplicaManager::ParticipantStruct * const &data );
protected:
/// Frees all memory
void Clear(void);
// Processes a struct representing a received command
ReplicaReturnResult ProcessReceivedCommand(ParticipantStruct *participantStruct, ReceivedCommand *receivedCommand);
unsigned GetCommandListReplicaIndex(const DataStructures::List<ReplicaManager::CommandStruct> &commandList, Replica *replica, bool *objectExists) const;
// Plugin interface functions
void OnAttach(RakPeerInterface *peer);
PluginReceiveResult OnReceive(RakPeerInterface *peer, Packet *packet);
void OnCloseConnection(RakPeerInterface *peer, SystemAddress systemAddress);
void OnShutdown(RakPeerInterface *peer);
/// List of objects replicated in the Replicate function.
/// Used to make sure queued actions happen on valid pointers, since objects are removed from the list in Dereplicate
/// Sorted by raw pointer address using the default sort
DataStructures::OrderedList<Replica *, RegisteredReplica, ReplicaManager::RegisteredReplicaComp> replicatedObjects;
/// List of participants
/// Each participant has several queues of pending commands
/// Sorted by systemAddress
/// The only complexity is that each participant also needs a list of objects that mirror the variable replicatedObjects so we know per-player if that object is in scope
DataStructures::OrderedList<SystemAddress, ParticipantStruct *, ReplicaManager::ParticipantStructComp> participantList;
// Internal functions
ParticipantStruct* GetParticipantBySystemAddress(const SystemAddress systemAddress) const;
// Callback pointers.
// Required callback to handle construction calls
ReceiveConstructionInterface *_constructionCB;
// Optional callbacks to send and receive download complete.
SendDownloadCompleteInterface *_sendDownloadCompleteCB;
ReceiveDownloadCompleteInterface *_receiveDownloadCompleteCB;
// Channel to do send calls on. All calls are reliable ordered except for Replica::Serialize
unsigned char sendChannel;
// Stores what you pass to SetAutoParticipateNewConnections
bool autoParticipateNewConnections;
bool autoSerializeInScope;
bool defaultScope;
bool autoConstructToNewParticipants;
unsigned int nextReferenceIndex;
RakPeerInterface *rakPeer;
#ifdef _DEBUG
// Check for and assert on recursive calls to update
bool inUpdate;
#endif
};
#endif