/*========================================================================== * * Copyright (C) 1999 Microsoft Corporation. All Rights Reserved. * * File: Receive.cpp * Content: This file contains code which receives indications of incoming data * from a ServiceProvider, cracks the data, and handles it appropriately. * History: * Date By Reason * ==== == ====== * 11/06/98 ejs Created * 07/01/2000 masonb Assumed Ownership * ****************************************************************************/ #include "dnproti.h" #include #include // local protos BOOL CancelFrame(PEPD, BYTE, DWORD tNow); VOID CompleteSends(PEPD); VOID DropReceive(PEPD, PRCD); HRESULT IndicateReceive(PSPD, PSPIE_DATA); HRESULT IndicateConnect(PSPD, PSPIE_CONNECT); HRESULT ProcessEnumQuery( PSPD, PSPIE_QUERY ); HRESULT ProcessQueryResponse( PSPD, PSPIE_QUERYRESPONSE ); VOID ProcessConnectedResponse(PSPD, PEPD, PCFRAME, DWORD); VOID ProcessConnectRequest(PSPD, PEPD, PCFRAME); VOID ProcessEndOfStream(PEPD); VOID ProcessListenStatus(PSPD, PSPIE_LISTENSTATUS); VOID ProcessConnectAddressInfo(PSPD, PSPIE_CONNECTADDRESSINFO); VOID ProcessEnumAddressInfo(PSPD, PSPIE_ENUMADDRESSINFO); VOID ProcessListenAddressInfo(PSPD, PSPIE_LISTENADDRESSINFO); VOID ProcessSendMask(PEPD, BYTE, ULONG, ULONG, DWORD tNow); VOID ProcessSPDisconnect(PSPD, PSPIE_DISCONNECT); VOID ReceiveInOrderFrame(PEPD, PRCD); VOID ReceiveOutOfOrderFrame(PEPD, PRCD, ULONG); HRESULT CrackCommand(PSPD, PEPD, PSPRECEIVEDBUFFER, DWORD); HRESULT CrackDataFrame(PSPD, PEPD, PSPRECEIVEDBUFFER, DWORD); /* ** Indicate Receive ** ** Service Provider calls this entry when data arrives on the network. ** We will quickly validate the frame and then figure what to do with it... ** ** Poll/Response activity should be handled before data is indicated to ** clients. We want to measure the network latency up to delivery, not including ** delivery. */ #undef DPF_MODNAME #define DPF_MODNAME "DNSP_IndicateEvent" HRESULT WINAPI DNSP_IndicateEvent(IDP8SPCallback *pIDNSP, SP_EVENT_TYPE Opcode, PVOID DataBlock) { PSPD pSPD = (PSPD) pIDNSP; ASSERT_SPD(pSPD); switch(Opcode) { case SPEV_DATA: return IndicateReceive(pSPD, (PSPIE_DATA) DataBlock); case SPEV_CONNECT: return IndicateConnect(pSPD, (PSPIE_CONNECT) DataBlock); case SPEV_ENUMQUERY: return ProcessEnumQuery( pSPD, (PSPIE_QUERY) DataBlock ); case SPEV_QUERYRESPONSE: return ProcessQueryResponse( pSPD, (PSPIE_QUERYRESPONSE) DataBlock ); case SPEV_DISCONNECT: ProcessSPDisconnect(pSPD, (PSPIE_DISCONNECT) DataBlock); break; case SPEV_LISTENSTATUS: ProcessListenStatus(pSPD, (PSPIE_LISTENSTATUS) DataBlock); break; case SPEV_LISTENADDRESSINFO: ProcessListenAddressInfo(pSPD, (PSPIE_LISTENADDRESSINFO) DataBlock); break; case SPEV_CONNECTADDRESSINFO: ProcessConnectAddressInfo(pSPD, (PSPIE_CONNECTADDRESSINFO) DataBlock); break; case SPEV_ENUMADDRESSINFO: ProcessEnumAddressInfo(pSPD, (PSPIE_ENUMADDRESSINFO) DataBlock); break; // // SP passed something unexpected // default: DPFX(DPFPREP,0, "Unknown Event indicated by SP"); ASSERT(0); break; } return DPN_OK; } /* ** Indicate Connect ** ** This event is indicated for both calling and listening sides. The ** calling side will do most of its work when the SP Connect call completes ** and the listening side will do most of its work when the CONNECT frame ** gets delivered. All we do here is allocate the EPD and attach it to the ** MSD (for calling case) ** ** Since we have a connect protocol, there will always be a CONNECT ** frame following closely on the heels of this indication. Therefore, ** there is not a whole lot of stuff that we need to do here. We will ** allocate the EndPoint and leave it dormant. ** ** Synchronization Issue: We have decided that if an SP Listen command is cancelled, ** the cancel call will not complete until all ConnectIndications have returned from the ** protocol. This means that we are GUARANTEED that the Listen command in the context ** will be valid throughout this call. This is important because now we can add a reference ** to the Listen's MSD here and now and we will know that it wont disappear on us before we ** do it. Truth, however, is that there will be a race until SP fixes itself to follow ** this behavior. */ #undef DPF_MODNAME #define DPF_MODNAME "IndicateConnect" HRESULT IndicateConnect(PSPD pSPD, PSPIE_CONNECT pConnData) { PEPD pEPD; PMSD pMSD; pMSD = (PMSD) pConnData->pCommandContext; ASSERT_MSD(pMSD); ASSERT(pMSD->pSPD == pSPD); DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pConnData[%p] - pMSD[%p]", pSPD, pConnData, pMSD); Lock(&pMSD->CommandLock); LOCK_MSD(pMSD, "EPD Ref"); // Place a reference on the command object. This prevents it from // going away during the Connect Protocol, an assumption which simplifies // life extraordinarily. We will want to ASSERT this fact, however, to make // sure that SP is playing by our rules. if ((pMSD->CommandID != COMMAND_ID_CONNECT) && (pMSD->CommandID != COMMAND_ID_LISTEN)) { DPFX(DPFPREP,1, "Connect Rejected - CommandID is not Connect or Listen, returning DPNERR_ABORTED, pMSD[%p]", pMSD); RELEASE_MSD(pMSD, "EPD Ref"); // Releases CommandLock return DPNERR_ABORTED; } if ((pMSD->CommandID == COMMAND_ID_CONNECT) && (pMSD->pEPD != NULL)) { DPFX(DPFPREP,1, "Connect Rejected - Connect command already has an endpoint, returning DPNERR_ABORTED, pMSD[%p], pEPD[%p]", pMSD, pMSD->pEPD); RELEASE_MSD(pMSD, "EPD Ref"); // Releases CommandLock return DPNERR_ABORTED; } if(pMSD->ulMsgFlags1 & MFLAGS_ONE_CANCELLED) { DPFX(DPFPREP,1, "Connect Rejected - Command is cancelled, returning DPNERR_ABORTED, pMSD[%p]", pMSD); RELEASE_MSD(pMSD, "EPD Ref"); // Releases CommandLock return DPNERR_ABORTED; } if((pEPD = NewEndPoint(pSPD, pConnData->hEndpoint)) == NULL) { DPFX(DPFPREP,0, "Failed to allocate new EPD, returning DPNERR_ABORTED, pMSD[%p]", pMSD); RELEASE_MSD(pMSD, "EPD Ref"); // Releases CommandLock return DPNERR_ABORTED; // This error will implicitly DISCONNECT from Endpoint } // Associate either the Connect or Listen with this Endpoint, this will be removed when the connection is complete. // The EPD Ref placed above will be carried around until this is NULL'd. pEPD->pCommand = pMSD; if(pMSD->CommandID == COMMAND_ID_CONNECT) { DPFX(DPFPREP,5, "INDICATE CONNECT (CALLING) -- EPD = %p, pMSD[%p]", pEPD, pMSD); pMSD->pEPD = pEPD; } else { DPFX(DPFPREP,5, "INDICATE CONNECT (LISTENING) -- EPD = %p, pMSD[%p]", pEPD, pMSD); ASSERT(pMSD->CommandID == COMMAND_ID_LISTEN); ASSERT((pEPD->ulEPFlags & EPFLAGS_LINKED_TO_LISTEN)==0); // For a Listen command, connecting endpoints are held on the blFrameList pEPD->blSPLinkage.InsertBefore( &pMSD->blFrameList); pEPD->ulEPFlags |= EPFLAGS_LINKED_TO_LISTEN; } pConnData->pEndpointContext = pEPD; Unlock(&pMSD->CommandLock); return DPN_OK; } /* ** Indicate Receive ** ** A frame has been delivered by the service provider. We are Guaranteed to ** have an active Endpoint in our hash table (or else something is wrong). I have not ** decided whether I will respond to POLL bits at this high level or else let ** each handler repond in its own particular... eh... idiom. ** ** Our return value controls whether SP will recycle the receive buffer, or whether ** we can keep the buffer around until we are ready to indicate it to higher levels ** later on. If we return DPN_OK then we are done with the buffer and it will be recycled. ** If we return DPNERR_PENDING then we may hold on to the buffer until we release them later. */ #undef DPF_MODNAME #define DPF_MODNAME "IndicateReceive" #define MINDATAFRAMESIZE (sizeof(DFRAME)) #define MINCMDFRAMESIZE (MIN(sizeof(CFRAME), sizeof(SACKFRAME8))) HRESULT IndicateReceive(PSPD pSPD, PSPIE_DATA pDataBlock) { PEPD pEPD = static_cast( pDataBlock->pEndpointContext ); HRESULT hr; PPacketHeader pFrame = (PPacketHeader) pDataBlock->pReceivedData->BufferDesc.pBufferData; DWORD tNow = GETTIMESTAMP(); DWORD dwDataLength = pDataBlock->pReceivedData->BufferDesc.dwBufferSize; DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pDataBlock[%p] - pEPD[%p]", pSPD, pDataBlock, pEPD); if(pSPD->ulSPFlags & SPFLAGS_TERMINATING) { DPFX(DPFPREP,1, "(%p) SP is terminating, returning DPN_OK, pSPD[%p]", pEPD, pSPD); return DPN_OK; } ASSERT_EPD(pEPD); ASSERT(pEPD->pSPD == pSPD); if(LOCK_EPD(pEPD, "LOCK (IND RECEIVE)") == 0) { ASSERT(0); DPFX(DPFPREP,1, "(%p) Rejecting receive on unreferenced EPD, returning DPN_OK", pEPD); return DPN_OK; } pEPD->tLastPacket = tNow; // Track last time each guy writes to us #ifdef DEBUG // copy this frame to buffer in EPD so we can look after a break. DWORD dwLen = MIN(32, pDataBlock->pReceivedData->BufferDesc.dwBufferSize); memcpy(pEPD->LastPacket, pDataBlock->pReceivedData->BufferDesc.pBufferData, dwLen); #endif // A valid data packet is one that meets the length requirements and has the Data flag set. // All other flags are allowed on a data frame (NOTE: even PACKET_COMMAND_CFRAME is allowed // as it shares its value with PACKET_COMMAND_USER_2). if( (dwDataLength >= MINDATAFRAMESIZE) && // Validate the length first (pFrame->bCommand & PACKET_COMMAND_DATA)) // Data goes this way { hr = CrackDataFrame(pSPD, pEPD, pDataBlock->pReceivedData, tNow); } else if ((dwDataLength >= MINCMDFRAMESIZE) && // Validate the length first ((pFrame->bCommand == PACKET_COMMAND_CFRAME) || // Only the CFRAME and POLL flags are allowed on a CFrame (pFrame->bCommand == (PACKET_COMMAND_CFRAME|PACKET_COMMAND_POLL)))) { hr = CrackCommand(pSPD, pEPD, pDataBlock->pReceivedData, tNow); } else { DPFX(DPFPREP,1, "(%p) Received frame that is neither Command nor Data, rejecting", pEPD); DNASSERTX(FALSE, 2); RejectInvalidPacket(pEPD, FALSE); // Lock not already held hr = DPN_OK; } Lock(&pEPD->EPLock); RELEASE_EPD(pEPD, "UNLOCK (IND RCV DONE)"); // Releases EPLock // This is either DPN_OK or DPNSUCCESS_PENDING. If it is pending we have to return the buffer later. return hr; } /* ** Process Enum Query ** ** A frame has been delivered by the service provider representing an enumereation ** query. */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessEnumQuery" HRESULT ProcessEnumQuery( PSPD pSPD, PSPIE_QUERY pQueryBlock ) { MSD *pMSD; PROTOCOL_ENUM_DATA EnumData; pMSD = static_cast( pQueryBlock->pUserContext ); ASSERT_MSD(pMSD); ASSERT(pMSD->pSPD == pSPD); DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pQueryBlock[%p] - pMSD[%p]", pSPD, pQueryBlock, pMSD); EnumData.pSenderAddress = pQueryBlock->pAddressSender; EnumData.pDeviceAddress = pQueryBlock->pAddressDevice; EnumData.ReceivedData.pBufferData = pQueryBlock->pReceivedData->BufferDesc.pBufferData; EnumData.ReceivedData.dwBufferSize = pQueryBlock->pReceivedData->BufferDesc.dwBufferSize; EnumData.hEnumQuery = pQueryBlock; DBG_CASSERT( sizeof( &EnumData ) == sizeof( PBYTE ) ); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->IndicateEnumQuery, Core Context[%p]", pMSD, pMSD->Context); pSPD->pPData->pfVtbl->IndicateEnumQuery( pSPD->pPData->Parent, pMSD->Context, pMSD, reinterpret_cast( &EnumData ), sizeof( EnumData )); return DPN_OK; } /* ** Process Query Response ** ** A frame has been delivered by the service provider representing a response to an enum. */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessQueryResponse" HRESULT ProcessQueryResponse( PSPD pSPD, PSPIE_QUERYRESPONSE pQueryResponseBlock) { MSD *pMSD; PROTOCOL_ENUM_RESPONSE_DATA EnumResponseData; pMSD = static_cast( pQueryResponseBlock->pUserContext ); ASSERT_MSD(pMSD); ASSERT(pMSD->pSPD == pSPD); DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pQueryResponseBlock[%p] - pMSD[%p]", pSPD, pQueryResponseBlock, pMSD); EnumResponseData.pSenderAddress = pQueryResponseBlock->pAddressSender; EnumResponseData.pDeviceAddress = pQueryResponseBlock->pAddressDevice; EnumResponseData.ReceivedData.pBufferData = pQueryResponseBlock->pReceivedData->BufferDesc.pBufferData; EnumResponseData.ReceivedData.dwBufferSize = pQueryResponseBlock->pReceivedData->BufferDesc.dwBufferSize; EnumResponseData.dwRoundTripTime = pQueryResponseBlock->dwRoundTripTime; DBG_CASSERT( sizeof( &EnumResponseData ) == sizeof( PBYTE ) ); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->IndicateEnumResponse, Core Context[%p]", pMSD, pMSD->Context); pSPD->pPData->pfVtbl->IndicateEnumResponse( pSPD->pPData->Parent, pMSD, pMSD->Context, reinterpret_cast( &EnumResponseData ), sizeof( EnumResponseData )); return DPN_OK; } // *** Called with lock held or not depending on parameter, Returns with EPLock released #undef DPF_MODNAME #define DPF_MODNAME "RejectInvalidPacket" VOID RejectInvalidPacket(PEPD pEPD, BOOL fLockHeld) { PMSD pMSD; if (!fLockHeld) { Lock(&pEPD->EPLock); } else { AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); } if(pEPD->ulEPFlags & EPFLAGS_STATE_DORMANT) { // Unlink MSD from EPD, there should always be one if we are in the DORMANT state pMSD = pEPD->pCommand; ASSERT_MSD(pMSD); if (pMSD->CommandID == COMMAND_ID_LISTEN) { pEPD->pCommand = NULL; LOCK_EPD(pEPD, "Temp Ref"); DPFX(DPFPREP,1, "(%p) Received invalid frame on a dormant, listening endpoint, dropping link", pEPD); DropLink(pEPD); // This will release the EPLock // The order here is important. We call DropLink first without ever leaving the EPLock because // we need to ensure no new packets try to come in. After calling DropLink we know we stay in the // TERMINATING state until returning to the pool, so state is not an issue after that call. Lock(&pMSD->CommandLock); Lock(&pEPD->EPLock); // If a cancel on a listen comes in at the same time as this happens, it is possible that the cancel came // through and already unlinked this EPD from the Listen while we were outside the lock. If so, removing // it from the pMSD->blFrameList twice is harmless. pEPD->ulEPFlags &= ~(EPFLAGS_LINKED_TO_LISTEN); pEPD->blSPLinkage.RemoveFromList(); // Unlink EPD from Listen Queue RELEASE_EPD(pEPD, "Temp Ref"); // Releases EPLock RELEASE_MSD(pMSD, "EPD Ref"); // Releases CommandLock } else { DPFX(DPFPREP,1, "(%p) Received invalid frame on a dormant, connecting endpoint, ignoring", pEPD); Unlock(&pEPD->EPLock); } } else { DPFX(DPFPREP,1, "(%p) Received invalid frame on a non-dormant endpoint, ignoring", pEPD); Unlock(&pEPD->EPLock); } } /* ** Crack Command ** ** This frame is a maintainance frame containing no user data ** */ #undef DPF_MODNAME #define DPF_MODNAME "CrackCommand" HRESULT CrackCommand(PSPD pSPD, PEPD pEPD, PSPRECEIVEDBUFFER pRcvBuffer, DWORD tNow) { DWORD dwDataLength = pRcvBuffer->BufferDesc.dwBufferSize; UNALIGNED ULONG *array_ptr; ULONG mask1, mask2; union { PCFRAME pCFrame; PSFBIG8 pSack; } pData; pData.pCFrame = (PCFRAME) pRcvBuffer->BufferDesc.pBufferData; switch(pData.pCFrame->bExtOpcode) { case FRAME_EXOPCODE_SACK: DPFX(DPFPREP,7, "(%p) SACK Frame Received", pEPD); Lock(&pEPD->EPLock); // Check state if(!(pEPD->ulEPFlags & EPFLAGS_STATE_CONNECTED)) { DPFX(DPFPREP,1, "(%p) Received SACK on non-connected endpoint, rejecting...", pEPD); DNASSERTX(FALSE, 4); RejectInvalidPacket(pEPD, TRUE); // TRUE means lock held, returns with lock released break; } // Drop short frames (should not happen) DWORD dwRequiredLength; dwRequiredLength = sizeof(SACKFRAME8); array_ptr = pData.pSack->rgMask; if (pData.pSack->bFlags & SACK_FLAGS_SACK_MASK1) { dwRequiredLength += sizeof(DWORD); } if (pData.pSack->bFlags & SACK_FLAGS_SACK_MASK2) { dwRequiredLength += sizeof(DWORD); } if (pData.pSack->bFlags & SACK_FLAGS_SEND_MASK1) { dwRequiredLength += sizeof(DWORD); } if (pData.pSack->bFlags & SACK_FLAGS_SEND_MASK2) { dwRequiredLength += sizeof(DWORD); } if (dwDataLength < dwRequiredLength) { DPFX(DPFPREP,1, "(%p) Dropping short frame on connected link", pEPD); DNASSERTX(FALSE, 2); Unlock(&pEPD->EPLock); return DPN_OK; } if( pData.pSack->bFlags & SACK_FLAGS_RESPONSE ) { DPFX(DPFPREP,7, "(%p) ACK RESP RCVD: Retry=%d, N(R)=0x%02x", pEPD, pData.pSack->bRetry, pData.pSack->bNRcv); } mask1 = pData.pSack->bFlags & SACK_FLAGS_SACK_MASK1 ? *array_ptr++ : 0; mask2 = pData.pSack->bFlags & SACK_FLAGS_SACK_MASK2 ? *array_ptr++ : 0; DPFX(DPFPREP,7, "(%p) UpdateXmitState - N(R) 0x%02x Mask 0x%08x 0x%08x", pEPD, (DWORD)pData.pSack->bNRcv, mask2, mask1); UpdateXmitState(pEPD, pData.pSack->bNRcv, mask1, mask2, tNow); mask1 = pData.pSack->bFlags & SACK_FLAGS_SEND_MASK1 ? *array_ptr++ : 0; mask2 = pData.pSack->bFlags & SACK_FLAGS_SEND_MASK2 ? *array_ptr++ : 0; if(mask1 | mask2) { DPFX(DPFPREP,7, "(%p) Processing Send Mask N(S) 0x%02x Mask 0x%08x 0x%08x", pEPD, (DWORD) pData.pSack->bNSeq, mask2, mask1); ProcessSendMask(pEPD, pData.pSack->bNSeq, mask1, mask2, tNow); } if( (!pEPD->blCompleteList.IsEmpty()) && ((pEPD->ulEPFlags & EPFLAGS_IN_RECEIVE_COMPLETE) == FALSE)) { DPFX(DPFPREP,8, "(%p) Completing Receives...", pEPD); pEPD->ulEPFlags |= EPFLAGS_IN_RECEIVE_COMPLETE; // ReceiveComplete will clear this flag when done ReceiveComplete(pEPD); // Deliver the goods, returns with EPLock released } else { Unlock(&pEPD->EPLock); } DPFX(DPFPREP,8, "(%p) Completing Sends...", pEPD); CompleteSends(pEPD); break; case FRAME_EXOPCODE_CONNECT: DPFX(DPFPREP,7, "(%p) CONNECT Frame Received", pEPD); if (dwDataLength < sizeof(CFRAME)) { DPFX(DPFPREP,1, "(%p) Received short CONNECT frame, rejecting...", pEPD); DNASSERTX(FALSE, 2); RejectInvalidPacket(pEPD, FALSE); // FALSE means lock not held return DPN_OK; } ProcessConnectRequest(pSPD, pEPD, pData.pCFrame); break; case FRAME_EXOPCODE_CONNECTED: DPFX(DPFPREP,7, "(%p) CONNECTED Frame Received", pEPD); if (dwDataLength < sizeof(CFRAME)) { DPFX(DPFPREP,1, "(%p) Received short CONNECTED frame, rejecting...", pEPD); DNASSERTX(FALSE, 2); RejectInvalidPacket(pEPD, FALSE); // FALSE means lock not held return DPN_OK; } ProcessConnectedResponse(pSPD, pEPD, pData.pCFrame, tNow); break; default: DPFX(DPFPREP,1, "(%p) Received invalid CFrame, rejecting...", pEPD); DNASSERTX(FALSE, 2); RejectInvalidPacket(pEPD, FALSE); // FALSE means lock not held break; } return DPN_OK; } /* ** Crack Data Frame ** ** In addition to delivering data contained in the frame, we also must ** use the included state info to drive the transmission process. We will update ** our link state according to this info and see if we need to put this session ** back into the sending pipeline. ** ** Of course, data will only be delivered if we have completed an entire message. ** ** CRITICAL SECTION NOTE -- It might seem rather lavish the way we hold the EPD->StateLock ** thru this entire routine, but anything less would require an obscene level of complexity ** to keep ironed out. This is why I defer all ReceiveIndications and buffer mappings until ** the end of the routine when the Lock can be released. ** */ #undef DPF_MODNAME #define DPF_MODNAME "CrackDataFrame" HRESULT CrackDataFrame(PSPD pSPD, PEPD pEPD, PSPRECEIVEDBUFFER pRcvBuffer, DWORD tNow) { DWORD dwDataLength = pRcvBuffer->BufferDesc.dwBufferSize; PDFBIG pFrame = (PDFBIG) (pRcvBuffer->BufferDesc.pBufferData); PRCD pRCD; ULONG bit; UINT count; UNALIGNED ULONG *array_ptr; ULONG MaskArray[4]; UINT header_size; ULONG mask; Lock(&pEPD->EPLock); // Data on an unconnected link // // There are two possibilities (as I see it today). Either we have dropped our link because partner // went silent, but now he has started sending again. OR We have disconnected and are now reconnecting // but there are some old data frames bouncing around (less likely). // // If we have dropped and partner is just figuring it out, we must kill the endpoint or else it will hang // around forever after partner stops bothering us. We can help out partner by sending him a DISC frame // so he knows that we arent playing anymore, buts its not technically necessary. // // In the second case, we do not want to close the EP because that will crush the session startup that // is supposedly in progress. Therefore, if we are not in a DORMANT state, then we know a session // startup is in progress, and we will let the EP remain open. if(!(pEPD->ulEPFlags & EPFLAGS_STATE_CONNECTED)) { DPFX(DPFPREP,1, "(%p) Received data on non-connected endpoint, rejecting...", pEPD); DNASSERTX(FALSE, 4); RejectInvalidPacket(pEPD, TRUE); // TRUE means lock held, returns with lock released return DPN_OK; // do not accept data before we have connected } BYTE bSeq = pFrame->bSeq; DPFX(DPFPREP,7, "(%p) Data Frame Arrives Seq=%x; N(R)=%x", pEPD, bSeq, pEPD->bNextReceive); // Make sure that new frame is within our receive window if((BYTE)(bSeq - pEPD->bNextReceive) >= (BYTE) MAX_FRAME_OFFSET) { DPFX(DPFPREP,1, "(%p) Rejecting frame that is out of receive window SeqN=%x, N(R)=%x", pEPD, bSeq, pEPD->bNextReceive); pEPD->ulEPFlags |= EPFLAGS_DELAY_ACKNOWLEDGE; if(pFrame->bCommand & PACKET_COMMAND_POLL) { // Is he asking for an immediate response DPFX(DPFPREP,7, "(%p) Sending Ack Frame", pEPD); SendAckFrame(pEPD, 1); // This unlocks the EPLock since param 2 is 1 } else if(pEPD->DelayedAckTimer == 0) { // If timer is not running better start it now LOCK_EPD(pEPD, "LOCK (DelayedAckTimer)"); // Bump RefCnt for new timer DPFX(DPFPREP,7, "(%p) Setting Delayed Ack Timer", pEPD); SetMyTimer(SHORT_DELAYED_ACK_TIMEOUT, 0, DelayedAckTimeout, (PVOID) pEPD, &pEPD->DelayedAckTimer, &pEPD->DelayedAckTimerUnique); Unlock(&pEPD->EPLock); } else { Unlock(&pEPD->EPLock); } return DPN_OK; } DWORD dwRequiredLength = sizeof(DFRAME); if (pFrame->bControl & PACKET_CONTROL_SACK_MASK1) { dwRequiredLength += sizeof(DWORD); } if (pFrame->bControl & PACKET_CONTROL_SACK_MASK2) { dwRequiredLength += sizeof(DWORD); } if (pFrame->bControl & PACKET_CONTROL_SEND_MASK1) { dwRequiredLength += sizeof(DWORD); } if (pFrame->bControl & PACKET_CONTROL_SEND_MASK2) { dwRequiredLength += sizeof(DWORD); } if (dwDataLength < dwRequiredLength) { DPFX(DPFPREP,1, "(%p) Dropping short frame on connected link", pEPD); DNASSERTX(FALSE, 2); Unlock(&pEPD->EPLock); return DPN_OK; } // Determine how large the variable length header is mask = (pFrame->bControl & PACKET_CONTROL_VARIABLE_MASKS) / PACKET_CONTROL_SACK_MASK1; if(mask) { array_ptr = pFrame->rgMask; for(count = 0; count < 4; count++, mask >>= 1) { MaskArray[count] = (mask & 1) ? *array_ptr++ : 0; } header_size = (UINT) ((UINT_PTR) array_ptr - (UINT_PTR) pFrame); // See if this frame Acknowledges any of our outstanding data DPFX(DPFPREP,7, "(%p) UpdateXmitState - N(R) 0x%02x Mask 0x%08x 0x%08x", pEPD, (DWORD)pFrame->bNRcv, MaskArray[1], MaskArray[0]); UpdateXmitState(pEPD, pFrame->bNRcv, MaskArray[0], MaskArray[1], tNow); // Do this before taking StateLock // Determine if there is a SendMask in this frame which identifies dropped frames as unreliable if(pFrame->bControl & (PACKET_CONTROL_SEND_MASK1 | PACKET_CONTROL_SEND_MASK2)) { DPFX(DPFPREP,7, "(%p) Processing Send Mask N(S) 0x%02x Mask 0x%08x 0x%08x", pEPD, (DWORD)pFrame->bSeq, MaskArray[3], MaskArray[2]); ProcessSendMask(pEPD, pFrame->bSeq, MaskArray[2], MaskArray[3], tNow); // NOTE: ProcessSendMask may have advanced N(R) // Re-verify that the new frame is within our receive window if((BYTE)(bSeq - pEPD->bNextReceive) >= (BYTE) MAX_FRAME_OFFSET) { DPFX(DPFPREP,1, "(%p) ProcessSendMask advanced N(R) such that the current frame is out of window, rejecting receive, N(R)=0x%02x, Seq=0x%02x", pEPD, (DWORD)pEPD->bNextReceive, (DWORD)pFrame->bSeq); Unlock(&pEPD->EPLock); return DPN_OK; } } } else { header_size = sizeof(DFRAME); DPFX(DPFPREP,7, "(%p) UpdateXmitState - N(R) 0x%02x No Mask", pEPD, (DWORD)pFrame->bNRcv); UpdateXmitState(pEPD, pFrame->bNRcv, 0, 0, tNow); // Do this before taking StateLock } // We can receive this frame. Copy relevant info into Receive descriptor if((pRCD = static_cast( RCDPool->Get(RCDPool) )) == NULL) { DPFX(DPFPREP,0, "(%p) Failed to allocate new RCD", pEPD); Unlock(&pEPD->EPLock); return DPN_OK; } pEPD->ulEPFlags |= EPFLAGS_DELAY_ACKNOWLEDGE; // State has changed. Make sure it gets sent. pRCD->bSeq = bSeq; pRCD->bFrameFlags = pFrame->bCommand; pRCD->bFrameControl = pFrame->bControl; pRCD->pbData = (PBYTE) (((PBYTE) pFrame) + header_size); pRCD->uiDataSize = dwDataLength - header_size; pRCD->tTimestamp = tNow; pRCD->pRcvBuff = pRcvBuffer; // Update our receiving state info. // // RCDs go onto one of two queues. If it is the next numbered (expected) frame then it is // placed on the ReceiveList (in EPD). If this frame completes a message it can now be // indicated. If this frame fills a hole left by previous frames then a condensation with // the second list must occur. // If it is not the next numbered frame then it is placed, in order, on the MisOrdered frame // list, and the bitmask is updated. // // Condensation of lists is performed by testing the LSB of the ReceiveMask. Each time LSB is set, // the first frame on the list can be moved to the ReceiveList, and the mask is shifted right. // As each frame is moved to the ReceiveList, the EOM flag must be checked for and if set, then // everything on the ReceiveList should be moved to the CompleteList for indication to the user. BOOL fPoll = pFrame->bCommand & PACKET_COMMAND_POLL; BOOL fCorrelate = pFrame->bControl & PACKET_CONTROL_CORRELATE; if(bSeq == pEPD->bNextReceive) { // Frame is the next expected # in sequence DPFX(DPFPREP,8, "(%p) Receiving In-Order Frame, pRCD[%p]", pEPD, pRCD); ReceiveInOrderFrame(pEPD, pRCD); // Build frame into message AND move adjacent frames off OddFrameList // NOTE: ReceiveInOrderFrame may have caused the frame to be freed via DropReceive // so we absolutely must not use pFrame past this point! // See if we need to respond right away... // // Because there are lots of way to generate POLL bits (full window, empty queue, poll count) we sometimes find ourselves // generating too much dedicated ack-traffic. Therefore, we will treat the POLL not as Respond-Immediately but instead as // Respond-Soon. We will not wait the full Delayed_Ack_Timeout interval but we will wait long enough to allow a quick piggyback // response (say 5ms) (we may want this longer on a slow connection...) // Is he asking for an instant response? if(fCorrelate) { DPFX(DPFPREP,7, "(%p) Sending Ack Frame", pEPD); SendAckFrame(pEPD, 0); // Send Ack w/timing info } // Is he asking for a response soon? else if(fPoll) { if(pEPD->ulEPFlags & EPFLAGS_USE_POLL_DELAY) { if(pEPD->DelayedAckTimer != NULL) { DPFX(DPFPREP,7, "(%p) Cancelling Delayed Ack Timer", pEPD); if(CancelMyTimer(pEPD->DelayedAckTimer, pEPD->DelayedAckTimerUnique)!= DPN_OK) { DPFX(DPFPREP,7, "(%p) Cancelling Delayed Ack Timer Failed", pEPD); LOCK_EPD(pEPD, "LOCK (re-start delayed ack timer)"); } } else { LOCK_EPD(pEPD, "LOCK (start short delayed ack timer)"); } DPFX(DPFPREP,7, "Delaying POLL RESP"); pEPD->ulEPFlags |= EPFLAGS_DELAY_ACKNOWLEDGE; DPFX(DPFPREP,7, "(%p) Setting Delayed Ack Timer", pEPD); SetMyTimer(4, 4, DelayedAckTimeout, (PVOID) pEPD, &pEPD->DelayedAckTimer, &pEPD->DelayedAckTimerUnique); } else { DPFX(DPFPREP,7, "(%p) Sending Ack Frame", pEPD); SendAckFrame(pEPD, 0); // Send Ack w/timing info } } else if(pEPD->DelayedAckTimer == 0) { // If timer is not running better start it now LOCK_EPD(pEPD, "LOCK (DelayedAckTimer)"); // Bump RefCnt for timer SetMyTimer(DELAYED_ACK_TIMEOUT, 0, DelayedAckTimeout, (PVOID) pEPD, &pEPD->DelayedAckTimer, &pEPD->DelayedAckTimerUnique); } } // IF frame is in order else { // Frame arrives out of order // bit location in mask for this frame bit = (BYTE) ((bSeq - pEPD->bNextReceive) - 1); // Make sure this is not a duplicate frame if( ((bit < 32) && (pEPD->ulReceiveMask & (1 << bit))) || ((bit > 31) && (pEPD->ulReceiveMask2 & (1 << (bit - 32)))) ) { DPFX(DPFPREP,7, "(%p) REJECT DUPLICATE OUT-OF-ORDER Frame Seq=%x", pEPD, bSeq); Unlock(&pEPD->EPLock); pRCD->pRcvBuff = NULL; RELEASE_RCD(pRCD); return DPN_OK; } DPFX(DPFPREP,8, "(%p) Receiving Out-of-Order Frame, pRCD[%p]", pEPD, pRCD); ReceiveOutOfOrderFrame(pEPD, pRCD, bit); // NOTE: ReceiveOutOfOrderFrame may have caused the frame to be freed via DropReceive // so we absolutely must not use pFrame past this point! if(fPoll) { if(pEPD->DelayedAckTimer != NULL) { DPFX(DPFPREP,7, "(%p) Cancelling Delayed Ack Timer", pEPD); if(CancelMyTimer(pEPD->DelayedAckTimer, pEPD->DelayedAckTimerUnique)!= DPN_OK) { DPFX(DPFPREP,7, "(%p) Cancelling Delayed Ack Timer Failed", pEPD); LOCK_EPD(pEPD, "LOCK (re-start delayed ack timer)"); } // Start an abreviated delayed ack timer in case NACK gets cancelled } else { LOCK_EPD(pEPD, "LOCK (start short delayed ack timer)"); } DPFX(DPFPREP,7, "Delaying POLL RESP"); pEPD->ulEPFlags |= EPFLAGS_DELAY_ACKNOWLEDGE; DPFX(DPFPREP,7, "(%p) Setting Delayed Ack Timer", pEPD); SetMyTimer(5, 5, DelayedAckTimeout, (PVOID) pEPD, &pEPD->DelayedAckTimer, &pEPD->DelayedAckTimerUnique); } } // EPD->StateLock is still HELD // // We use a FLAG for exclusive access to ReceiveComplete routine. This is safe because the flag is only // tested and modified while holding the EPD->StateLock. Lets be sure to keep it that way... if( (!pEPD->blCompleteList.IsEmpty()) && ((pEPD->ulEPFlags & EPFLAGS_IN_RECEIVE_COMPLETE) == FALSE)) { DPFX(DPFPREP,8, "(%p) Completing Receives...", pEPD); pEPD->ulEPFlags |= EPFLAGS_IN_RECEIVE_COMPLETE; // ReceiveComplete will clear this flag when done ReceiveComplete(pEPD); // Deliver the goods, returns with EPLock released } else { DPFX(DPFPREP,7, "(%p) Already in ReceiveComplete, letting other thread handle receives", pEPD); Unlock(&pEPD->EPLock); } DPFX(DPFPREP,8, "(%p) Completing Sends...", pEPD); CompleteSends(pEPD); return DPNERR_PENDING; } /* ** Receive In Order Frame ** ** The interesting part of this function is moving frames off of the OddFrameList that ** the new frame adjoins. This may also be called with a NULL frame which will happen when ** a cancelled frame is the next-in-order receive. ** ** One result of having cancelled frames running around is that we may miss the SOM or EOM ** flags which delimit messages. Therefore, we must watch as we assemble messages that we do not ** see unexpected flags, ie a new message w/o an SOM on first frame which means that part of the ** message must have been lost, and the whole thing must be trashed... ** ** ** EPLOCK is HELD through this entire function ** */ #undef DPF_MODNAME #define DPF_MODNAME "ReceiveInOrderFrame" VOID ReceiveInOrderFrame(PEPD pEPD, PRCD pRCD) { CBilink *pLink; UINT flag; AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); // Condensing Loop WHILE (Next In-Order Frame has been received) do { ASSERT(pRCD->bSeq == pEPD->bNextReceive); pEPD->tLastDataFrame = pRCD->tTimestamp; // Always keep the receive time of (N(R) - 1) pEPD->bLastDataRetry = (pRCD->bFrameControl & PACKET_CONTROL_RETRY); #ifdef DEBUG pEPD->bLastDataSeq = pRCD->bSeq; #endif pRCD->pMsgLink = NULL; if(pEPD->pNewMessage == NULL) { // Add this frame to the in-order rcv list // pNewMessage implies we have no current message, head or tail ASSERT(pEPD->pNewTail == NULL); if(!(pRCD->bFrameFlags & PACKET_COMMAND_NEW_MSG)) { // There is no NEW_MESSAGE flag on the first frame we see. We must // have lost the first frame or this is an invalid packet. We can throw // this frame away... DPFX(DPFPREP,1, "(%p) NEW_MESSAGE flag not set on first frame of message, scrapping frame (%x)", pEPD, pRCD->bSeq); pRCD->ulRFlags |= RFLAGS_FRAME_LOST; pRCD->bFrameFlags |= PACKET_COMMAND_END_MSG; // Turn this on so we will release buffer right away } // Even if we get rid of it, we will need these below pEPD->pNewMessage = pRCD; pEPD->pNewTail = pRCD; pRCD->uiFrameCount = 1; pRCD->uiMsgSize = pRCD->uiDataSize; DPFX(DPFPREP,8, "(%p) Queuing Frame (NEW MESSAGE) (%x)", pEPD, pRCD->bSeq); } else { if (pRCD->bFrameFlags & PACKET_COMMAND_NEW_MSG) { // We are getting the start of a new message in the start of an existing message, drop it all DPFX(DPFPREP,1, "(%p) NEW_MESSAGE flag set in the middle of existing message, scrapping message (%x, %x)", pEPD, pEPD->pNewMessage->bSeq, pRCD->bSeq); pRCD->ulRFlags |= RFLAGS_FRAME_LOST; pRCD->bFrameFlags |= PACKET_COMMAND_END_MSG; // Turn this on so we will release buffer right away } ASSERT((pEPD->pNewTail->bSeq) == (BYTE)(pRCD->bSeq - 1)); // Make sure they stay sequential pEPD->pNewTail->pMsgLink = pRCD; pEPD->pNewMessage->uiFrameCount++; pEPD->pNewMessage->uiMsgSize += pRCD->uiDataSize; pEPD->pNewMessage->ulRFlags |= (pRCD->ulRFlags & RFLAGS_FRAME_LOST);// UNION FRAME_LOST flag from all frames of a message pEPD->pNewTail = pRCD; DPFX(DPFPREP,8, "(%p) Queuing Frame (ON TAIL) (%x)", pEPD, pRCD->bSeq); } if(pRCD->bFrameFlags & PACKET_COMMAND_END_MSG) { // Either this frame completes a message or we decided to drop this one above // All frames on the ReceiveList should now be removed and delivered // Get either the message we are dropping above, or the beginning of the sequence of messages we are completing pRCD = pEPD->pNewMessage; pEPD->pNewMessage = NULL; if(pRCD->ulRFlags & RFLAGS_FRAME_LOST) { // We need to throw this away DPFX(DPFPREP,7, "(%p) Throwing away message with missing frames (%x, %x)", pEPD, pRCD->bSeq, pEPD->pNewTail->bSeq); pEPD->pNewTail = NULL; DropReceive(pEPD, pRCD); } else { // We need to complete this sequence pRCD->blCompleteLinkage.InsertBefore( &pEPD->blCompleteList); // place on end of Completion list DPFX(DPFPREP,7, "(%p) Adding msg to complete list FirstSeq=%x, LastSeq=%x QueueSize=%d", pEPD, pRCD->bSeq, pEPD->pNewTail->bSeq, pEPD->uiCompleteMsgCount); pEPD->pNewTail = NULL; pEPD->uiCompleteMsgCount++; } } // Since we are allowing out of order indication of receives it is possible that frames later than // the new one have already been indicated. This means that there may be bits set in the ReceiveMask // whose correlating frames do not need to be indicated. The most straightforward way to implement this // is to leave the early-indicated frames in the list, but mark them as INDICATED_NONSEQ. So inside this // master DO loop there will be an inner DO loop which passes over INDICATED frames and just takes them off // the list. // // Now its possible that a NonSeq indicated frame is still sitting on the CompleteList awaiting indication, // so I am using a ref count. An extra ref is added when a frame is completed non-seq. When a completed frame // is removed below we will release one reference, and the indication code will release one reference when it // finishes on that end. Happily, we can release the actual buffers while the RCD turd is still sitting on the // OddFrameList. BOOL fIndicatedNonSeq = FALSE; do { flag = pEPD->ulReceiveMask & 1; // set flag if next frame in stream is present pEPD->bNextReceive += 1; // Update receive window RIGHT_SHIFT_64(pEPD->ulReceiveMask2, pEPD->ulReceiveMask);// shift mask because base has changed DPFX(DPFPREP,7, "(%p) N(R) incremented to %x, Mask %x %x", pEPD, pEPD->bNextReceive, pEPD->ulReceiveMask2, pEPD->ulReceiveMask); if(flag) { // The next frame in the sequence has arrived already since low bit of ulReceiveMask was set // Several things can happen here: // 1) We are in the middle of a message, in which case, its next piece is on the out of order list // 2) We have just finished a message, which leaves two subcases: // a) We are beginning a new message. In this case our first piece is on the out of order list // b) Out-of-order non-sequential messages have completed while we were completing our in-order message // In this case there are some already indicated RCDs on the out of order list, and a new partial // message may or may not follow. pLink = pEPD->blOddFrameList.GetNext(); ASSERT(pLink != &pEPD->blOddFrameList); // Make sure we didn't run out of RCDs on the list pRCD = CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage); ASSERT_RCD(pRCD); pLink->RemoveFromList(); // take next frame out of OddFrameList // Make sure everything previous got removed from the odd frame list, and it is sorted correctly ASSERT(pRCD->bSeq == pEPD->bNextReceive); if (pRCD->ulRFlags & RFLAGS_FRAME_INDICATED_NONSEQ) { if (pEPD->pNewMessage) { // We need to throw this away PRCD pRCDTemp = pEPD->pNewMessage; pEPD->pNewMessage = NULL; DPFX(DPFPREP,1, "(%p) Throwing away non-ended message (%x, %x)", pEPD, pRCDTemp->bSeq, pEPD->pNewTail->bSeq); pEPD->pNewTail = NULL; DropReceive(pEPD, pRCDTemp); } fIndicatedNonSeq = TRUE; DPFX(DPFPREP,7, "(%p) Pulling Indicated-NonSequential message off of Out-of-Order List Seq=%x", pEPD, pRCD->bSeq); pEPD->tLastDataFrame = pRCD->tTimestamp; // Always keep the receive time of (N(R) - 1) pEPD->bLastDataRetry = (pRCD->bFrameControl & PACKET_CONTROL_RETRY); DEBUG_ONLY(pEPD->bLastDataSeq = pRCD->bSeq); RELEASE_RCD(pRCD); } else { // In the case of cancelling one of the messages in the middle of a large message, // we will drop all previous, drop that one, and then we will get to a situation where we aren't // currently working on a new message (pNewMessage was NULL'ed in the cancelling) and the current // message does not have the NEW_MSG flag, in which case we scrap it above. ASSERT(!fIndicatedNonSeq || (pRCD->bFrameFlags & PACKET_COMMAND_NEW_MSG) || (!pEPD->pNewMessage && !(pRCD->bFrameFlags & PACKET_COMMAND_NEW_MSG))); // go ahead and move this to the receive list DPFX(DPFPREP,7, "(%p) Moving OutOfOrder frame to received list Seq=%x", pEPD, pRCD->bSeq); ASSERT(pRCD->bSeq == pEPD->bNextReceive); break; // Back to the top } } } while (flag); // DO WHILE (There are still in order frames that have already arrived with no incomplete messages) } while (flag); // DO WHILE (There are still in order frames that have already arrived with an incomplete message) if((pEPD->ulReceiveMask | pEPD->ulReceiveMask2)==0) { pEPD->ulEPFlags &= ~(EPFLAGS_DELAYED_NACK); if(((pEPD->ulEPFlags & EPFLAGS_DELAYED_SENDMASK)==0)&&(pEPD->DelayedMaskTimer != NULL)) { DPFX(DPFPREP,7, "(%p) Cancelling Delayed Mask Timer", pEPD); if(CancelMyTimer(pEPD->DelayedMaskTimer, pEPD->DelayedMaskTimerUnique) == DPN_OK) { DECREMENT_EPD(pEPD, "UNLOCK (cancel DelayedMask)"); // SPLock not already held pEPD->DelayedMaskTimer = 0; } else { DPFX(DPFPREP,7, "(%p) Cancelling Delayed Mask Timer Failed", pEPD); } } } } /* ** Receive Out Of Order Frame ** ** Its like the title says. We must set the appropriate bit in the 64-bit ReceiveMask ** and then place it into the OddFrameList in its proper sorted place. After that, we must ** scan to see if a complete message has been formed and see if we are able to indicate it ** early. ** ** ** EPLOCK is HELD through this entire function ** */ #undef DPF_MODNAME #define DPF_MODNAME "ReceiveOutOfOrderFrame" VOID ReceiveOutOfOrderFrame(PEPD pEPD, PRCD pRCD, ULONG bit) { PRCD pRCD1; PRCD pRCD2; CBilink *pLink; BYTE NextSeq; ULONG highbit; ULONG Mask; ULONG WorkMaskHigh; ULONG WorkMaskLow; ULONG MaskHigh; ULONG MaskLow; BOOL nack = FALSE; UINT count; BOOL lost = FALSE; UINT frame_count = 0; UINT msg_length = 0; DPFX(DPFPREP,8,"(%p) Received out of order frame, Seq=%x, bit=%x", pEPD, pRCD->bSeq, bit); // Bit shouldn't be more than 64 (MAX_RECEIVE_RANGE) ASSERT(bit <= MAX_RECEIVE_RANGE); AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); // RECEIVE OUT OF ORDER FRAME // // DO WE SEND IMMEDIATE ACK FOR THIS OUT OF ORDER FRAME? // // When we receive an OutOfOrder frame it is almost certainly because the missing frame has been lost. // So we can accelerate the re-transmission process greatly by telling partner right away that frames // are missing. HOWEVER, with a large send window we will get many mis-ordered frames for each drop, // but we only want to send a Negative Ack once. SO, we will only initiate a NACK here if we have // created a NEW HOLE in our receive mask! // // First, we will not have created a new hole unless we added to the END of the OddFrameList. // Second, we will not have created a new hole unless the FIRST BIT TO THE RIGHT of the new bit // is CLEAR. // // So we will only generate an immediate NACK frame if both of the above cases are true! // NOTE - if this is the only OoO frame, then we should always send a NACK // // ANOTHER NOTE. SP implementation has been changed so that it frequently misorders receives in close // proximity. One effect of this is that we must not immediately send a NACK for an out of order frame, but // instead should wait a short period (say ~5ms) and see if the missing frame hasn't shown up. // Make sure this RCD is within the receive window // NOTE: Presume SACK arrives with bNSeq of 84, N(R) is 20, and all bits are set except the one representing 20. // In that case, pRCD->bSeq - pEPD->bNextReceive will be equal to 63 (ie MAX_FRAME_OFFSET). ASSERT((BYTE)(pRCD->bSeq - pEPD->bNextReceive) <= (BYTE)MAX_FRAME_OFFSET); // We will insert frame in OddFrameList maintaining sort by Seq number // // We can optimize for most likely case, which is new frames are added to END of list. We can // check for this first case by investigating whether the new bit is the left-most bit in the mask. // If it is LMB, then it trivially gets added to the END of the list. // // Please note that both this and the following algorithms assume that we have already verified // that the new frame is NOT already in the list MaskLow = pEPD->ulReceiveMask; // Get scratch copy of Mask MaskHigh = pEPD->ulReceiveMask2; if(bit < 32) { // Frame is within 32 of N(Rcv) WorkMaskLow = 1 << bit; // Find bit in mask for new frame WorkMaskHigh = 0; pEPD->ulReceiveMask |= WorkMaskLow; // Set appropriate bit in mask // check immediately preceeding bit for NACK determination if( (MaskLow & (WorkMaskLow >> 1)) == 0) { nack = TRUE; // preceeding bit is not set } } else { highbit = bit - 32; WorkMaskHigh = 1 << highbit; WorkMaskLow = 0; pEPD->ulReceiveMask2 |= WorkMaskHigh; // Set appropriate bit in mask if(highbit) { // check preceeding bit for NACK determination if( (MaskHigh & (WorkMaskHigh >> 1)) == 0) { nack = TRUE; // preceeding bit is not set } } else { if( (MaskLow & 0x80000000) == 0) { nack = TRUE; } } } // Insert frame in sorted OddFrameList. // // First test for trivial insert at tail condition. True if new bit is LEFTMOST set bit in // both masks. if( (WorkMaskHigh > MaskHigh) || ( (MaskHigh == 0) && (WorkMaskLow > MaskLow) ) ) { // TAIL INSERTION DPFX(DPFPREP,7, "(%p) Received %x OUT OF ORDER - INSERT AT TAIL NRcv=%x MaskL=%x MaskH=%x", pEPD, pRCD->bSeq, pEPD->bNextReceive, pEPD->ulReceiveMask, pEPD->ulReceiveMask2); pLink = &pEPD->blOddFrameList; // Make sure this is either the only RCD in the list, or it is farther in the window than the last one ASSERT(pLink->IsEmpty() || ((BYTE)(CONTAINING_RECORD(pLink->GetPrev(), RCD, blOddFrameLinkage))->bSeq - pEPD->bNextReceive) < (BYTE)(pRCD->bSeq - pEPD->bNextReceive)); pRCD->blOddFrameLinkage.InsertBefore( pLink); // Check to see if we should NACK (negative acknowledge) any frames. We only want to NACK a given // frame once so we will NACK if this is the first frame added to the OOF list, or if the immediately // preceeding frame is missing. First condition is trivial to test. if( ((MaskLow | MaskHigh) == 0) || (nack == 1) ) { pEPD->ulEPFlags |= EPFLAGS_DELAYED_NACK; if(pEPD->DelayedMaskTimer == 0) { DPFX(DPFPREP,7, "(%p) Setting Delayed Mask Timer", pEPD); LOCK_EPD(pEPD, "LOCK (DelayedMaskTimer)"); // Bump RefCnt for timer SetMyTimer(SHORT_DELAYED_ACK_TIMEOUT, 5, DelayedAckTimeout, (PVOID) pEPD, &pEPD->DelayedMaskTimer, &pEPD->DelayedMaskTimerUnique); pEPD->tReceiveMaskDelta = GETTIMESTAMP(); } else { DPFX(DPFPREP,7, "(%p) *** DELAYED NACK *** Timer already running", pEPD); } } } else { // NOT TAIL INSERTION // This is the non-trivial case, ie new frame goes at beginning or in middle of OddFrameList. // So we need to count the ONE bits that are to the RIGHT of the new bit in the ReceiveMask. // We will mask off bits higher then the New Bit and then do a quick bit-count... DPFX(DPFPREP,7, "(%p) Receive OUT OF ORDER - Walking Frame List (Seq=%x, NRcv=%x) MaskL=%x MaskH=%x", pEPD, pRCD->bSeq, pEPD->bNextReceive, pEPD->ulReceiveMask, pEPD->ulReceiveMask2); // If we are inserting into high mask, we must count all one-bits in low mask // // We will test for the special case of all-bits-set at the outset... pLink = pEPD->blOddFrameList.GetNext(); // pLink = First frame in list; we will walk list as we count if(WorkMaskHigh) { // new frame in high mask. only count bits to right of new bit WorkMaskHigh -= 1; // Convert to mask preserving all bits to right of new bit WorkMaskHigh &= MaskHigh; // WMH now represents all bits to right of new bit while(WorkMaskHigh) { // Make sure this is farther in the window than the one we are skipping ASSERT(((BYTE)(CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage))->bSeq - pEPD->bNextReceive) < (BYTE)(pRCD->bSeq - pEPD->bNextReceive)); // Count bits in WMH Mask = WorkMaskHigh - 1; WorkMaskHigh &= Mask; pLink = pLink->GetNext(); } if(MaskLow == 0xFFFFFFFF) { // special case if low mask is full for(count = 0; count < 32; count++) { // Make sure this is farther in the window than the one we are skipping ASSERT(((BYTE)(CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage))->bSeq - pEPD->bNextReceive) < (BYTE)(pRCD->bSeq - pEPD->bNextReceive)); pLink = pLink->GetNext(); } } else { // else count all bits in lower mask while(MaskLow) { // Make sure this is farther in the window than the one we are skipping ASSERT(((BYTE)(CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage))->bSeq - pEPD->bNextReceive) < (BYTE)(pRCD->bSeq - pEPD->bNextReceive)); Mask = MaskLow - 1; MaskLow &= Mask; // Mask off low 1-bit pLink = pLink->GetNext(); } } } else { WorkMaskLow -= 1; WorkMaskLow &= MaskLow; // WML == bits to the right of new bit while(WorkMaskLow) { // Make sure this is farther in the window than the one we are skipping ASSERT(((BYTE)(CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage))->bSeq - pEPD->bNextReceive) < (BYTE)(pRCD->bSeq - pEPD->bNextReceive)); Mask = WorkMaskLow - 1; WorkMaskLow &= Mask; // Mask off low 1-bit pLink = pLink->GetNext(); } } // Make sure this is farther in the window than the last one ASSERT(((BYTE)(CONTAINING_RECORD(pLink->GetPrev(), RCD, blOddFrameLinkage))->bSeq - pEPD->bNextReceive) < (BYTE)(pRCD->bSeq - pEPD->bNextReceive)); pRCD->blOddFrameLinkage.InsertBefore( pLink); // Insert new frame in sorted list } // Receive not at tail #ifdef DEBUG // Dump the contents of the Out of Order Frame List for verification. There are at most 64 frames. { BYTE bCurSeq = pEPD->bNextReceive + 1; ULONG64 ulMask = ((ULONG64)pEPD->ulReceiveMask2 << 32) | ((ULONG64)pEPD->ulReceiveMask); CBilink* pTemp; TCHAR szOOFL[256]; szOOFL[0] = 0; pTemp = pEPD->blOddFrameList.GetNext(); while (pTemp != &pEPD->blOddFrameList) { while (ulMask != 0 && !(ulMask & 1)) { ulMask >>= 1; bCurSeq++; } ASSERT(ulMask != 0); PRCD pRCDTemp = CONTAINING_RECORD(pTemp, RCD, blOddFrameLinkage); ASSERT_RCD(pRCDTemp); ASSERT(bCurSeq == pRCDTemp->bSeq); _stprintf(szOOFL, _T("%s %02x"), szOOFL, pRCDTemp->bSeq); ulMask >>= 1; bCurSeq++; pTemp = pTemp->GetNext(); } DPFX(DPFPREP, 7, "OOFL contents: %s", szOOFL); } #endif // DEBUG // ** Non-Sequential Indication // // This is the Non-Trivial implementation of non-sequential receive indication. // We will work from the assumption that we only need to complete messages that are touched by the new frame. // So we must back up in the OddFrame list until we see either a gap or a Start of Message marker. Then we must work // forward looking for an End of Message... // // One more complication is the fact that dropped packets might in the list via place-holding dummies. Since we // do not know what SOM/EOM flags would have been present on a dropped frame, we can consider them to have BOTH flags. // Then we also need to be aware that frames bordering on dropped frames without a delimiter (SOM or EOM) are fragments // and therefore count as dropped data too. I think to keep this from getting too complex, we wont probe further for // neighbors of lost data frames. We will discover them when we are building a message later. // // pLink = Item after new element in Out of Order list // pRCD = new Item // IF this frame is not marked as SEQUENTIAL if((pRCD->bFrameFlags & PACKET_COMMAND_SEQUENTIAL)==0) { DPFX(DPFPREP,7, "(%p) Received Non-Seq %x out of order; flags=%x", pEPD, pRCD->bSeq, pRCD->bFrameFlags); NextSeq = pRCD->bSeq; // NOTE: The first pLink will be the passed in RCD so we will have included that in the frame_count and msg_length after leaving this while while ( (pLink = pLink->GetPrev()) != &pEPD->blOddFrameList ) { pRCD1 = CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage); ASSERT_RCD(pRCD1); frame_count++; msg_length += pRCD1->uiDataSize; if((pRCD1->bFrameFlags & PACKET_COMMAND_NEW_MSG) || (pRCD1->bSeq != NextSeq)) { break; // Stop probing when we find a NEW_MSG flag OR a gap in the frame sequence numbers } --NextSeq; } // We have either found a NEW_MSG or a sequence gap. If its a NEW_MSG, then we probe forward for an END_MSG if((pRCD1->bFrameFlags & PACKET_COMMAND_NEW_MSG) && (pRCD1->bSeq == NextSeq)) { // So far so good. We have a sequential message start frame // // pRCD = frame just arrived // pRCD1 = Start of message frame // pLink = Start of message linkage pLink = &pRCD->blOddFrameLinkage; NextSeq = pRCD->bSeq; // Look for the message end or a sequence gap while ( ( (pRCD->bFrameFlags & PACKET_COMMAND_END_MSG)==0 ) && (pRCD->bSeq == NextSeq)) { // Stop if we hit the end of the OddFrameList if((pLink = pLink->GetNext()) == &pEPD->blOddFrameList) { break; } // NOTE: the first pLink here will be the one after the passed in RCD. If there is a gap that won't // matter because we are out of here after the next if. If it is the next message we will continue until // we hit the END_MSG and have a proper frame_count and msg_length. pRCD = CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage); ASSERT_RCD(pRCD); frame_count++; msg_length += pRCD->uiDataSize; NextSeq++; } // pLink should not be used after this point due to the way the above while could have left it either valid // or at &pEPD->blOddFrameList. pLink = NULL; if((pRCD->bFrameFlags & PACKET_COMMAND_END_MSG) && (pRCD->bSeq == NextSeq)) { // We have completed a message // // pRCD1 = First frame in message // pRCD = Last frame in message DPFX(DPFPREP,7, "(%p) Completed Non-Seq Msg: First=%x, Last=%x", pEPD, pRCD1->bSeq, pRCD->bSeq); lost = FALSE; pRCD->ulRFlags |= RFLAGS_FRAME_INDICATED_NONSEQ; pRCD->pMsgLink = NULL; lost |= pRCD->ulRFlags & RFLAGS_FRAME_LOST; // Get the pointer to the next to last message so we can remove the last pLink = pRCD->blOddFrameLinkage.GetPrev(); LOCK_RCD(pRCD); // ReceiveInOrderFrame must remove this // Walk from the last message to the first message accumulating lost flags, linking messages, // setting indicated flag, and pulling off of the odd frame list while (pRCD != pRCD1) { ASSERT(pLink != &pEPD->blOddFrameList); // Make sure we didn't run out of RCDs on the list pRCD2 = CONTAINING_RECORD(pLink, RCD, blOddFrameLinkage); ASSERT_RCD(pRCD2); pRCD2->pMsgLink = pRCD; LOCK_RCD(pRCD2); // ReceiveInOrderFrame must remove this pRCD2->ulRFlags |= RFLAGS_FRAME_INDICATED_NONSEQ; lost |= pRCD2->ulRFlags & RFLAGS_FRAME_LOST; pLink = pRCD2->blOddFrameLinkage.GetPrev(); pRCD = pRCD2; } // Both RCD and RCD1 point to the first message now // If any were lost, drop the receive, otherwise complete it if(!lost) { pRCD->uiFrameCount = frame_count; pRCD->uiMsgSize = msg_length; DPFX(DPFPREP,7, "(%p) Adding msg to complete list FirstSeq=%x QueueSize=%d", pEPD, pRCD->bSeq, pEPD->uiCompleteMsgCount); pRCD->blCompleteLinkage.InsertBefore( &pEPD->blCompleteList); pEPD->uiCompleteMsgCount++; } else { DPFX(DPFPREP,7, "(%p) Complete Non-Seq MSG is dropped due to missing frames", pEPD); DropReceive(pEPD, pRCD); } } } // else there is nothing to complete at this time... } // IF NON SEQUENTIAL } /* ** Drop Receive ** ** One or more frames composing a message have been dropped, so the entire message can be scrapped. ** If this was determined during an out of order receive then the RCDs will remain on the OddFrameList ** as usual. */ #undef DPF_MODNAME #define DPF_MODNAME "DropReceive" VOID DropReceive(PEPD pEPD, PRCD pRCD) { PRCD pNext; PSPRECEIVEDBUFFER pRcvBuff = NULL; while(pRCD != NULL) { ASSERT_RCD(pRCD); if (pRCD->bFrameFlags & PACKET_COMMAND_RELIABLE) { DPFX(DPFPREP,1, "(%p) Dropping G receive frame %x!!!", pEPD, pRCD->bSeq); } else { DPFX(DPFPREP,7, "(%p) Dropping NG receive frame %x", pEPD, pRCD->bSeq); } RELEASE_SP_BUFFER(pRCD->pRcvBuff); pNext = pRCD->pMsgLink; RELEASE_RCD(pRCD); pRCD = pNext; } if(pRcvBuff != NULL) { DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling SP->ReturnReceiveBuffers, pSPD[%p]", pEPD, pEPD->pSPD); IDP8ServiceProvider_ReturnReceiveBuffers(pEPD->pSPD->IISPIntf, pRcvBuff); } } /* ** Receive Complete ** ** We have received an entire reliable message, potentially spanning ** multiple messages. We are still on the receive thread right now so depending ** upon our desired indication behavior we will either indicate it directly or ** else queue it to be indicated on a background thread of some sort. ** ** Messages spanning multiple frames (for now) will be copied into a contiguous ** buffer for delivery. CODEWORK -- Server implementations should be able to receive ** large messages as buffer chains (or arrays of BufDescs). ** ** This is also where we must notice that an End Of Stream flag is set in a message, ** indicating that the connection is being closed. ** ** *** CALLED WITH EPD->STATELOCK HELD *** RETURNS WITH STATELOCK RELEASED *** */ #undef DPF_MODNAME #define DPF_MODNAME "ReceiveComplete" VOID ReceiveComplete(PEPD pEPD) { CBilink *pLink; PRCD pRCD; PRCD pNext; PSPRECEIVEDBUFFER pRcvBuff = NULL; PBIGBUF pBuf; PBYTE write; UINT length; UINT frames; DWORD flag; UINT MsgSize; HRESULT hr; AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); while((pLink = pEPD->blCompleteList.GetNext()) != &pEPD->blCompleteList) { pLink->RemoveFromList(); ASSERT(pEPD->uiCompleteMsgCount > 0); pEPD->uiCompleteMsgCount--; Unlock(&pEPD->EPLock); pRCD = CONTAINING_RECORD(pLink, RCD, blCompleteLinkage); ASSERT_RCD(pRCD); // Handle easy case first if(pRCD->uiFrameCount == 1) // message is only 1 frame { if(pRCD->uiDataSize > 0) { pEPD->uiMessagesReceived++; if(pRCD->bFrameFlags & PACKET_COMMAND_RELIABLE) { pEPD->uiGuaranteedFramesReceived++; pEPD->uiGuaranteedBytesReceived += pRCD->uiDataSize; } else { pEPD->uiDatagramFramesReceived++; pEPD->uiDatagramBytesReceived += pRCD->uiDataSize; } pRCD->pRcvBuff->dwProtocolData = RBT_SERVICE_PROVIDER_BUFFER; pRCD->pRcvBuff->pServiceProviderDescriptor = pEPD->pSPD; flag = (((DWORD) pRCD->bFrameFlags) & (PACKET_COMMAND_USER_1 | PACKET_COMMAND_USER_2)) * (DN_SENDFLAGS_SET_USER_FLAG / PACKET_COMMAND_USER_1); DEBUG_ONLY(InterlockedIncrement(&pEPD->pSPD->pPData->ThreadsInReceive)); DEBUG_ONLY(InterlockedIncrement(&pEPD->pSPD->pPData->BuffersInReceive)); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->IndicateReceive, pRCD[%p], Core Context[%p]", pEPD, pRCD, pEPD->Context); hr = pEPD->pSPD->pPData->pfVtbl->IndicateReceive(pEPD->pSPD->pPData->Parent, pEPD->Context, pRCD->pbData, pRCD->uiDataSize, pRCD->pRcvBuff, flag); if(hr == DPN_OK) { RELEASE_SP_BUFFER(pRCD->pRcvBuff); // Really only queues it to be released DEBUG_ONLY(InterlockedDecrement(&pEPD->pSPD->pPData->BuffersInReceive)); } else { ASSERT(hr == DPNERR_PENDING); // The Core owns it now and is responsible for calling DNPReleaseReceiveBuffer to free it pRCD->pRcvBuff = NULL; } DEBUG_ONLY(InterlockedDecrement(&pEPD->pSPD->pPData->ThreadsInReceive)); } else { // If DataSize == 0 & EOS is not set, then this was a keep alive message and is ignored if(pRCD->bFrameControl & PACKET_CONTROL_END_STREAM) { // END OF STREAM indicated DPFX(DPFPREP,7, "(%p) Processing EndOfStream, pRCD[%p]", pEPD, pRCD); ProcessEndOfStream(pEPD); } RELEASE_SP_BUFFER(pRCD->pRcvBuff); // Really only queues it to be released } RELEASE_RCD(pRCD); // Release reference for Complete Processing } else // Message spans multiple frames { // Multiple buffers. Need to copy data into contiguous buffer. if((MsgSize = pRCD->uiMsgSize) <= SMALL_BUFFER_SIZE) { pBuf = static_cast( BufPool->Get(BufPool) ); } else if (MsgSize <= MEDIUM_BUFFER_SIZE) { pBuf = static_cast( MedBufPool->Get(MedBufPool) ); } else if (MsgSize <= LARGE_BUFFER_SIZE) { pBuf = static_cast( BigBufPool->Get(BigBufPool) ); } else { DPFX(DPFPREP,7, "(%p) RECEIVE HUGE MESSAGE", pEPD); // Receive is larger then our biggest static receive buffer. This means we have to allocate a dynamic buffer. pBuf = (PBIGBUF) DNMalloc(MsgSize + sizeof(DYNBUF)); if(pBuf) { pBuf->Type = RBT_DYNAMIC_BUFFER; } } if(pBuf == NULL) { DPFX(DPFPREP,0, "MEMORY ALLOC FAILED. Cannot deliver data"); while(pRCD != NULL) { ASSERT_RCD(pRCD); pNext = pRCD->pMsgLink; RELEASE_SP_BUFFER(pRCD->pRcvBuff); RELEASE_RCD(pRCD); pRCD = pNext; } Lock(&pEPD->EPLock); continue; // blow it off! } write = pBuf->data; // initialize write pointer length = 0; frames = 0; while(pRCD != NULL) { ASSERT_RCD(pRCD); memcpy(write, pRCD->pbData, pRCD->uiDataSize); write += pRCD->uiDataSize; length += pRCD->uiDataSize; frames++; pNext = pRCD->pMsgLink; flag = (DWORD) pRCD->bFrameFlags; RELEASE_SP_BUFFER(pRCD->pRcvBuff); RELEASE_RCD(pRCD); pRCD = pNext; } pEPD->uiMessagesReceived++; if(flag & PACKET_COMMAND_RELIABLE) { pEPD->uiGuaranteedFramesReceived += frames; pEPD->uiGuaranteedBytesReceived += length; } else { pEPD->uiDatagramFramesReceived += frames; pEPD->uiDatagramBytesReceived += length; } flag = (flag & (PACKET_COMMAND_USER_1 | PACKET_COMMAND_USER_2)) * (DN_SENDFLAGS_SET_USER_FLAG / PACKET_COMMAND_USER_1); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->IndicateReceive, Core Context[%p]", pEPD, pEPD->Context); hr = pEPD->pSPD->pPData->pfVtbl->IndicateReceive(pEPD->pSPD->pPData->Parent, pEPD->Context, pBuf->data, length, pBuf, flag); if(hr == DPN_OK) { if(pBuf->Type == RBT_PROTOCOL_BUFFER) { pBuf->Owner->Release(pBuf->Owner, pBuf); } else { DNFree(pBuf); } } else { ASSERT(hr == DPNERR_PENDING); } } Lock(&pEPD->EPLock); } ASSERT(pEPD->blCompleteList.IsEmpty()); pEPD->ulEPFlags &= ~(EPFLAGS_IN_RECEIVE_COMPLETE); // Clear this before releasing Lock final time Unlock(&pEPD->EPLock); if(pRcvBuff != NULL) { DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling SP->ReturnReceiveBuffers, pSPD[%p]", pEPD, pEPD->pSPD); IDP8ServiceProvider_ReturnReceiveBuffers(pEPD->pSPD->IISPIntf, pRcvBuff); } } /* ** Process Send Mask ** ** The send mask is what our partner uses to tell us to stop waiting for particular frames. ** This will happen after an Unreliable frame is dropped. Instead of retransmitting the unreliable ** frame, the sender will forward the appropriate bit in a send mask. In this routine, we attempt ** to update our receive state pursuant to the newly received mask. ** ** THIS IS CALLED WITH STATELOCK HELD AND RETURNS WITH STATELOCK HELD ** ** suffice it to say that we should not release statelock anywhere in the following */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessSendMask" VOID ProcessSendMask(PEPD pEPD, BYTE bSeq, ULONG MaskLow, ULONG MaskHigh, DWORD tNow) { INT deltaS; ULONG workmaskS; BYTE bThisFrame; UINT skip; ASSERT(MaskLow | MaskHigh); DPFX(DPFPREP,7, "(%p) PROCESS SEND MASK N(R)=%x, bSeq=%x, MaskL=%x, MaskH=%x", pEPD, pEPD->bNextReceive, bSeq, MaskLow, MaskHigh); // The mask can only refer to frames earlier than the Seq number in this frame. So if this frame // is the next In-Order then the mask can have nothing interesting in it. // // The SendMask is coded with decending frame numbers starting at the Seq in this frame - 1. // The ReceiveMask is coded with ascending frame numbers start at N(Rcv) + 1. // // We will walk forward through the rcvmask and backward through the sendmask looking for the magic combo // of a bit clear in the rcvmask and the corresponding bit set in the sendmask. For each of these matches, // a dummy cancel frame can be 'received' for that sequence number. // // This would be fairly straightforward if it wasn't for the fact that both masks are 64 bits so the code has // to track which DWORD of each mask we are dealing with at any given time. // // NOTE: It is perfectly legitimate for a SACK to come in with a bNSeq at MAX_FRAME_OFFSET from pEPD->bNextReceive. Consider // the case where pEPD->bNextReceive is 0 and the sender has sent and timed out 0-63. A SACK would arrive with a bNSeq of 64 // and both masks fully set. top: if (bSeq != pEPD->bNextReceive) { deltaS = (INT) (((BYTE)(bSeq - pEPD->bNextReceive)) - 1); // count of frames between first missing frame and sequence base of mask bThisFrame = pEPD->bNextReceive; if ( deltaS <= MAX_FRAME_OFFSET ) { // If the difference is greater then 32 frames then we need to look at the high mask first and // then fall through to the low mask. Otherwise, we can ignore the highmask and start with the low. while((deltaS > 31) && (MaskHigh)) // Any work to do in the upper bits? { workmaskS = 1 << (deltaS - 32); // walks bit positions backward in send mask // See if the next frame we are interested in is covered by this mask if(workmaskS & MaskHigh) { CancelFrame(pEPD, bThisFrame, tNow); MaskHigh &= ~workmaskS; // N(R) may have been bumped up multiple times by CancelFrame, reset to make sure we work with // up to date information. goto top; } else { bThisFrame++; deltaS--; } } if(deltaS > 31) { skip = deltaS - 31; // how many bit positions did we skip bThisFrame += (BYTE) skip; deltaS -= skip; } while((deltaS >= 0) && (MaskLow)) // Any work to do in the lower bits? { workmaskS = 1 << deltaS; if(workmaskS & MaskLow) { CancelFrame(pEPD, bThisFrame, tNow); MaskLow &= ~workmaskS; // N(R) may have been bumped up multiple times by CancelFrame, reset to make sure we work with // up to date information. goto top; } else { bThisFrame++; deltaS--; } } } } // We need to ACK every time a send mask. Consider the case of one way Non-Guaranteed traffic. If data or an ACK gets lost, // this will be the only way we get back in sync with the other side. // If timer is not running better start it now if(pEPD->DelayedAckTimer == 0) { LOCK_EPD(pEPD, "LOCK (DelayedAckTimer)"); // Bump RefCnt for timer pEPD->ulEPFlags |= EPFLAGS_DELAY_ACKNOWLEDGE; DPFX(DPFPREP,7, "(%p) Setting Delayed Ack Timer", pEPD); SetMyTimer(DELAYED_ACK_TIMEOUT, 0, DelayedAckTimeout, (PVOID) pEPD, &pEPD->DelayedAckTimer, &pEPD->DelayedAckTimerUnique); } } #undef DPF_MODNAME #define DPF_MODNAME "BuildCancelledRCD" PRCD BuildCancelledRCD(PEPD pEPD, BYTE bSeq, DWORD tNow) { PRCD pRCD; if((pRCD = static_cast (RCDPool->Get(RCDPool))) == NULL) { DPFX(DPFPREP,0, "Failed to allocate RCD"); return NULL; } pRCD->bSeq = bSeq; pRCD->bFrameFlags = PACKET_COMMAND_NEW_MSG | PACKET_COMMAND_END_MSG; pRCD->bFrameControl = 0; pRCD->pbData = NULL; pRCD->uiDataSize = 0; pRCD->tTimestamp = tNow; pRCD->pRcvBuff = NULL; pRCD->ulRFlags = RFLAGS_FRAME_LOST; return pRCD; } /* Cancel Frame ** ** An unreliable frame has been reported as lost by sender. This means we should consider it acknowledged ** and remove it from our receive window. This may require us to place a dummy receive descriptor in the OddFrameList ** to hold its place until the window moves past it. */ #undef DPF_MODNAME #define DPF_MODNAME "CancelFrame" BOOL CancelFrame(PEPD pEPD, BYTE bSeq, DWORD tNow) { PRCD pRCD; ULONG bit; DPFX(DPFPREP,7, "(%p) CANCEL FRAME: Seq=%x", pEPD, bSeq); AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); // Trivial case is when the cancelled frame is at the front of the window. In this case we can complete not only // this frame but any contiguous frames following it in the OddFrameList if(pEPD->bNextReceive == bSeq) { if((pRCD = BuildCancelledRCD(pEPD, bSeq, tNow)) == NULL) { return FALSE; } ReceiveInOrderFrame(pEPD, pRCD); } // Here we have to place a dummy node on the OddFrameList to represent this frame. else { // bit location in mask for this frame bit = (BYTE) ((bSeq - pEPD->bNextReceive) - 1); // Make sure this is not a duplicate frame if( ((bit < 32) && (pEPD->ulReceiveMask & (1 << bit))) || ((bit > 31) && (pEPD->ulReceiveMask2 & (1 << (bit - 32)))) ) { DPFX(DPFPREP,7, "(%p) Received CancelMask for frame that's already received Seq=%x", pEPD, bSeq); return FALSE; } if((pRCD = BuildCancelledRCD(pEPD, bSeq, tNow)) == NULL) { return FALSE; } ReceiveOutOfOrderFrame(pEPD, pRCD, bit); } return TRUE; } /* ** Release Receive Buffer ** ** The core calls this function to return buffers previously handed ** over in an IndicateUserData call. This call may be made before the ** actual indication returns. */ #undef DPF_MODNAME #define DPF_MODNAME "DNPReleaseReceiveBuffer" HRESULT DNPReleaseReceiveBuffer(HANDLE hBuffer) { union { PBIGBUF pBuf; PSPRECEIVEDBUFFER pRcvBuff; } pBuffer; PSPD pSPD; DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: hBuffer[%p]", hBuffer); pBuffer.pBuf = (PBIGBUF) hBuffer; switch(pBuffer.pBuf->Type) { case RBT_SERVICE_PROVIDER_BUFFER: pSPD = (PSPD) pBuffer.pRcvBuff->pServiceProviderDescriptor; ASSERT_SPD(pSPD); DEBUG_ONLY(InterlockedDecrement(&pSPD->pPData->BuffersInReceive)); pBuffer.pRcvBuff->pNext = NULL; DPFX(DPFPREP,DPF_CALLOUT_LVL, "Calling SP->ReturnReceiveBuffers, pRcvBuff[%p], pSPD[%p]", pBuffer.pRcvBuff, pSPD); IDP8ServiceProvider_ReturnReceiveBuffers(pSPD->IISPIntf, pBuffer.pRcvBuff); break; case RBT_PROTOCOL_BUFFER: pBuffer.pBuf->Owner->Release(pBuffer.pBuf->Owner, pBuffer.pBuf); break; case RBT_DYNAMIC_BUFFER: DNFree(hBuffer); break; default: DPFX(DPFPREP,0, "RELEASE RECEIVE BUFFER CALLED WITH BAD PARAMETER"); return DPNERR_INVALIDPARAM; } return DPN_OK; } /* ** Complete Sends ** ** Reliable sends are completed upon acknowlegement. Acknowlegements are discovered inside ** the UpdateXmitState routine while walking through the pending window. Since the actual completion ** event requires the user to be called, state can change. So the easiest thing to do is defer these ** completion callbacks until we are finished walking and can release any state locks. Also, this way ** we can defer the callbacks until after we have indicated any data which the acks were piggybacking on, ** something which ought to have priority anyway. ** ** So we will place all completed reliable sends onto a complete list and after all other processing ** we will come here and callback everything on the list. */ #undef DPF_MODNAME #define DPF_MODNAME "CompleteSends" VOID CompleteSends(PEPD pEPD) { PMSD pMSD; CBilink *pLink; Lock(&pEPD->EPLock); pLink = pEPD->blCompleteSendList.GetNext(); while((pEPD->ulEPFlags & EPFLAGS_COMPLETE_SENDS) && (pLink != &pEPD->blCompleteSendList)) { pMSD = CONTAINING_RECORD(pLink, MSD, blQLinkage); ASSERT_MSD(pMSD); if(pMSD->CommandID != COMMAND_ID_SEND_DATAGRAM) { // Reliables, Keepalives, and Disconnects will come down this path if(pMSD->ulMsgFlags2 & (MFLAGS_TWO_SEND_COMPLETE|MFLAGS_TWO_ABORT)) { if (pMSD->uiFrameCount == 0) { DPFX(DPFPREP, DPF_FRAMECNT_LVL, "Completing, pMSD[%p], framecount[%u]", pMSD, pMSD->uiFrameCount); pLink->RemoveFromList(); Unlock(&pEPD->EPLock); Lock(&pMSD->CommandLock); CompleteReliableSend(pEPD->pSPD, pMSD, DPN_OK); // This releases the CommandLock Lock(&pEPD->EPLock); pLink = pEPD->blCompleteSendList.GetNext(); } else { DPFX(DPFPREP, DPF_FRAMECNT_LVL, "Frames still out, pMSD[%p], framecount[%u]", pMSD, pMSD->uiFrameCount); pLink = pLink->GetNext(); } } else { DPFX(DPFPREP, DPF_FRAMECNT_LVL, "Message not yet complete, pMSD[%p], framecount[%u]", pMSD, pMSD->uiFrameCount); break; // These will complete in order, so stop checking when we see one that's not Complete. } } else { // Datagrams will come down this path DPFX(DPFPREP, DPF_FRAMECNT_LVL, "Skipping datagram frame on complete list, pMSD[%p], framecount[%u]", pMSD, pMSD->uiFrameCount); pLink = pLink->GetNext(); } } #ifdef DEBUG // In DEBUG we want to assert that no one one the list could have been completed if we are leaving here pLink = pEPD->blCompleteSendList.GetNext(); while(pLink != &pEPD->blCompleteSendList) { pMSD = CONTAINING_RECORD(pLink, MSD, blQLinkage); ASSERT_MSD(pMSD); ASSERT(!(pMSD->ulMsgFlags2 & (MFLAGS_TWO_SEND_COMPLETE|MFLAGS_TWO_ABORT)) || pMSD->uiFrameCount != 0); pLink = pLink->GetNext(); } #endif pEPD->ulEPFlags &= ~(EPFLAGS_COMPLETE_SENDS); Unlock(&pEPD->EPLock); } /* ** Lookup CheckPoint ** ** Walk the EndPoint's list of active CPs looking for one with the provided ** response correlator. ** We keep the CKPT queue sorted by age so the matches should be at the front ** of the queue. So as we pass by entries at the head we will check the age of each ** and timeout the ones that are 4(RTT) or greater. ** Since DG drops are reported by the partner, we dont need to do any booking about ** the orphaned checkpoints. ** ** *!* This link's StateLock must be held on entry */ #ifdef DEBUG #undef DPF_MODNAME #define DPF_MODNAME "DumpChkPtList" VOID DumpChkPtList(PEPD pEPD) { CBilink *pLink; PCHKPT pCP; AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); DPFX(DPFPREP,1, "==== DUMPING CHECKPOINT LIST ==== (pEPD = %p)", pEPD); pLink = pEPD->blChkPtQueue.GetNext(); while(pLink != &pEPD->blChkPtQueue) { pCP = CONTAINING_RECORD(pLink, CHKPT, blLinkage); DPFX(DPFPREP,1, "(%p) MsgID=%x; Timestamp=%x", pEPD, pCP->bMsgID, pCP->tTimestamp); pLink = pLink->GetNext(); } } #endif #undef DPF_MODNAME #define DPF_MODNAME "LookupCheckPoint" PCHKPT LookupCheckPoint(PEPD pEPD, BYTE bRspID) { CBilink *pLink; PCHKPT pCP; AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); pCP = CONTAINING_RECORD((pLink = pEPD->blChkPtQueue.GetNext()), CHKPT, blLinkage); while(pLink != &pEPD->blChkPtQueue) { // Look for checkpoint that matches correlator if(pCP->bMsgID == bRspID) { pLink->RemoveFromList(); return pCP; } // We have passed the spot for this correlator! else if ((bRspID - pCP->bMsgID) & 0x80) { DPFX(DPFPREP,1, "(%p) CHECKPOINT NOT FOUND - Later Chkpt found in list (%x)", pEPD, bRspID); return NULL; } else { pLink = pLink->GetNext(); // Remove ChkPts prior to the one received pCP->blLinkage.RemoveFromList(); // ..target and remove the stale ones. ChkPtPool->Release(ChkPtPool, pCP); // we expect them to complete in order of queue pCP = CONTAINING_RECORD(pLink, CHKPT, blLinkage); } } DPFX(DPFPREP,1, "(%p) CHECKPOINT NOT FOUND - EXHAUSTED LIST W/O MATCH (%x)", pEPD, bRspID); #ifdef DEBUG DumpChkPtList(pEPD); #endif return NULL; } #undef DPF_MODNAME #define DPF_MODNAME "FlushCheckPoints" VOID FlushCheckPoints(PEPD pEPD) { PCHKPT pCP; AssertCriticalSectionIsTakenByThisThread(&pEPD->EPLock, TRUE); while(!pEPD->blChkPtQueue.IsEmpty()) { pCP = CONTAINING_RECORD(pEPD->blChkPtQueue.GetNext(), CHKPT, blLinkage); pCP->blLinkage.RemoveFromList(); ChkPtPool->Release(ChkPtPool, pCP); } } /* ** Process End Of Stream ** ** Our partner has initiated an orderly link termination. He will not be ** sending us any more data. We are allowed to finish sending any data in our ** pipeline, but should not allow any new sends to be accepted. When our send ** pipeline is emptied, we should send an EOS frame and take down our ** link. Easiest way to do this is enqueue the EOS at the end of send queue now. */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessEndOfStream" VOID ProcessEndOfStream(PEPD pEPD) { PMSD pMSD; Lock(&pEPD->EPLock); // Since an EOS comes in as a data packet, and we must be Connected to receive data, we know // we can now be in either the Connected or Terminating state. If we are in the Terminating // state, someone is already attempting to destroy the link and we will ignore this EOS, and // let that termination finish. Otherwise, we expect to be in the Connected state, and this // is a normal disconnect. if (pEPD->ulEPFlags & EPFLAGS_STATE_TERMINATING) { DPFX(DPFPREP,7, "(%p) Received EndOfStream on an already terminating link, ignoring", pEPD); Unlock(&pEPD->EPLock); return; } ASSERT(pEPD->ulEPFlags & EPFLAGS_STATE_CONNECTED); DPFX(DPFPREP,7, "(%p) Process EndOfStream", pEPD); // Have we started closing on this side? if(!(pEPD->ulEPFlags & EPFLAGS_RECEIVED_DISCONNECT)) { // Our side has not started closing yet, so our partner must have initiated a Disconnect. // We are allowed to finish sending all data in our pipeline, but we should not accept // any new data. We must deliver an indication to the application telling him that // Disconnection is now underway. // // Please note that we do not set the TERMINATING flag until the Disconnecting indication // returns. This allows the application to send any final messages (last words) before // the gate is slammed shut. DPFX(DPFPREP,7, "(%p) Partner Disconnect received (refcnt=%d)", pEPD, pEPD->lRefCnt); // Don't let anyone else in here again. pEPD->ulEPFlags |= EPFLAGS_RECEIVED_DISCONNECT; // Force 3 disconnect ACKs now since we are going away. // Setting fFinalAck to TRUE on last ACK so CommandComplete will drop if appropriate DPFX(DPFPREP,7, "(%p) ACK'ing Partner's Disconnect", pEPD); SendAckFrame(pEPD, 0); SendAckFrame(pEPD, 0); SendAckFrame(pEPD, 0, TRUE); // There is the possibility that this side initiated a disconnect, and is now receiving a // disconnect from the other side simultaneously. In this case, we do not want to tell the // Core on our side about the disconnect, because the Core on our side is already disconnecting // anyway. We also do not need to send an EOS, because we have sent one already, and can // just wait for that one to be ACK'd. if(!(pEPD->ulEPFlags & EPFLAGS_SENT_DISCONNECT)) { // We know we won't get in here twice because of EPFLAGS_RECEIVED_DISCONNECT above. Unlock(&pEPD->EPLock); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->IndicateDisconnect, Core Context[%p]", pEPD, pEPD->Context); pEPD->pSPD->pPData->pfVtbl->IndicateDisconnect(pEPD->pSPD->pPData->Parent, pEPD->Context); Lock(&pEPD->EPLock); // This will prevent any new sends, so don't set it until after calling IndicateDisconnect. pEPD->ulEPFlags |= EPFLAGS_SENT_DISCONNECT; if((pMSD = BuildDisconnectFrame(pEPD)) == NULL) { DropLink(pEPD); // DROPLINK will release EPLock for us return; } pMSD->CommandID = COMMAND_ID_DISC_RESPONSE; // Mark MSD so we know its not a user command LOCK_EPD(pEPD, "LOCK (DISC RESP)"); // Add reference for this frame pEPD->pCommand = pMSD; // Store the DisconnectResp on the Endpoint until it is complete DPFX(DPFPREP,7, "(%p) Responding to Disconnect. pMSD=0x%p", pEPD, pMSD); EnqueueMessage(pMSD, pEPD); // Enqueue the DISC frame at end of sendQ } } Unlock(&pEPD->EPLock); } /* ** Process SP Disconnect ** ** Service Provider has told us that an endpoint has gone away. This is probably ** because we have Disconnected it ourselves, in which case the IN_USE flag will be ** clear. Otherwise, we need to clean this thing up ourselves... */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessSPDisconnect" VOID ProcessSPDisconnect(PSPD pSPD, PSPIE_DISCONNECT pDataBlock) { PEPD pEPD = static_cast( pDataBlock->pEndpointContext ); ASSERT_EPD(pEPD); ASSERT(pEPD->pSPD == pSPD); PMSD pMSD = NULL; DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pDataBlock[%p] - pEPD[%p]", pSPD, pDataBlock, pEPD); Lock(&pEPD->EPLock); // Make sure ReleaseEPD knows that this occurred pEPD->ulEPFlags |= EPFLAGS_SP_DISCONNECTED; if (!(pEPD->ulEPFlags & EPFLAGS_STATE_TERMINATING)) { DECREMENT_EPD(pEPD, "SP reference"); // Remove the SP reference // If there is an outstanding connection, clean it up if (pEPD->ulEPFlags & (EPFLAGS_STATE_CONNECTING|EPFLAGS_STATE_DORMANT)) { // Even if this is COMMAND_ID_CONNECT this is safe to do pEPD->ulEPFlags &= ~(EPFLAGS_LINKED_TO_LISTEN); pEPD->blSPLinkage.RemoveFromList(); // Unlink EPD from Listen Queue // We know this will only happen once because the person who does it will transition us out // of the CONNECTING state, and we can't get here unless we are in that state. pMSD = pEPD->pCommand; pEPD->pCommand = NULL; } DropLink(pEPD); // This will release the EPLock if (pMSD) { Lock(&pMSD->CommandLock); RELEASE_MSD(pMSD, "EPD Ref"); } } else { RELEASE_EPD(pEPD, "SP reference"); // releases EPLock } } /* ** Process Listen Status ** ** This call tells us that a submitted Listen command has become active. Truth is, we ** dont care. We are just interested in seeing the Connect indications as they arrive. What we ** do care about, however, is the Endpoint handle associated with this listen in case we are ** later asked about the address associated with the listen. So we will pull it out of the ** data block and save it in our MSD. */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessListenStatus" VOID ProcessListenStatus(PSPD pSPD, PSPIE_LISTENSTATUS pDataBlock) { PMSD pMSD; DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pDataBlock[%p] - hr=%x", pSPD, pDataBlock, pDataBlock->hResult); pMSD = (PMSD) pDataBlock->pUserContext; ASSERT_MSD(pMSD); ASSERT(pMSD->pSPD == pSPD); ASSERT(pMSD->CommandID == COMMAND_ID_LISTEN); pMSD->hListenEndpoint = pDataBlock->hEndpoint; DPFX(DPFPREP,DPF_CALLOUT_LVL, "Calling Core->CompleteListen, pMSD[%p], Core Context[%p], hr[%x]", pMSD, pMSD->Context, pDataBlock->hResult); pSPD->pPData->pfVtbl->CompleteListen(pSPD->pPData->Parent, &pMSD->Context, pDataBlock->hResult, pDataBlock->hEndpoint); if(pDataBlock->hResult != DPN_OK) { // Release the final reference on the MSD AFTER indicating to the Core Lock(&pMSD->CommandLock); RELEASE_MSD(pMSD, "Release On Complete"); } return; } /* ** Process Connect Address Info ** ** This call tells us what addressing information has been used to start a connect. */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessConnectAddressInfo" VOID ProcessConnectAddressInfo(PSPD pSPD, PSPIE_CONNECTADDRESSINFO pDataBlock) { PMSD pMSD; pMSD = (PMSD) pDataBlock->pCommandContext; DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pDataBlock[%p] - pMSD[%p]", pSPD, pDataBlock, pMSD); ASSERT_MSD(pMSD); ASSERT(pMSD->pSPD == pSPD); ASSERT(pMSD->CommandID == COMMAND_ID_CONNECT); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->AddressInfoConnect, Core Context[%p]", pMSD, pMSD->Context); pSPD->pPData->pfVtbl->AddressInfoConnect( pSPD->pPData->Parent, pMSD->Context, pDataBlock->hCommandStatus, pDataBlock->pHostAddress, pDataBlock->pDeviceAddress ); return; } /* ** Process Enum Address Info ** ** This call tells us what addressing information has been used to start an enum. */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessEnumAddressInfo" VOID ProcessEnumAddressInfo(PSPD pSPD, PSPIE_ENUMADDRESSINFO pDataBlock) { PMSD pMSD; pMSD = (PMSD) pDataBlock->pCommandContext; DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pDataBlock[%p] - pMSD[%p]", pSPD, pDataBlock, pMSD); ASSERT_MSD(pMSD); ASSERT(pMSD->pSPD == pSPD); ASSERT(pMSD->CommandID == COMMAND_ID_ENUM ); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->AddressInfoEnum, Core Context[%p]", pMSD, pMSD->Context); pSPD->pPData->pfVtbl->AddressInfoEnum( pSPD->pPData->Parent, pMSD->Context, pDataBlock->hCommandStatus, pDataBlock->pHostAddress, pDataBlock->pDeviceAddress ); return; } /* ** Process Listen Address Info ** ** This call tells us what addressing information has been used to start a listen. */ #undef DPF_MODNAME #define DPF_MODNAME "ProcessListenAddressInfo" VOID ProcessListenAddressInfo(PSPD pSPD, PSPIE_LISTENADDRESSINFO pDataBlock) { PMSD pMSD; pMSD = (PMSD) pDataBlock->pCommandContext; DPFX(DPFPREP,DPF_CALLIN_LVL, "Parameters: pSPD[%p], pDataBlock[%p] - pMSD[%p]", pSPD, pDataBlock, pMSD); ASSERT_MSD(pMSD); ASSERT(pMSD->pSPD == pSPD); ASSERT(pMSD->CommandID == COMMAND_ID_LISTEN ); DPFX(DPFPREP,DPF_CALLOUT_LVL, "(%p) Calling Core->AddressInfoListen, Core Context[%p]", pMSD, pMSD->Context); pSPD->pPData->pfVtbl->AddressInfoListen( pSPD->pPData->Parent, pMSD->Context, pDataBlock->hCommandStatus, pDataBlock->pDeviceAddress ); return; } /************************************* ** ** RECEIVE BUFFER MANAGEMENT ** ** When multiple frame messages arrive we *may* have to copy them in to a single contiguous ** buffer. We are supporting an OPTIONAL scatter-receive option which would allow sophisticated ** clients to receive a BUFFER_DESCRIPTOR array instead of a single cont-buffer, and avoiding ** a large datacopy. ** ** For clients which dont support scatter-receive, we need a pooling strategy for large receive ** buffers. We will only need buffers LARGER then our frame limit because smaller receives are delivered ** in the SPs buffer. ** ** Try placing receives into generally sized buffers. If frame size is usu 1.4K bytes, 2K is a small ** buffer, 4K, 16K, 32K, 64K. If frame size is <1K we can have 1K buffers too. ** ** *************************************/ /*********************** ========SPACER========== ************************/ /* ** RCD Pool support routines ** ** These are the functions called by Fixed Pool Manager as it handles RCDs. */ #define pELEMENT ((PRCD) pElement) #undef DPF_MODNAME #define DPF_MODNAME "RCD_Allocate" BOOL RCD_Allocate(PVOID pElement) { DPFX(DPFPREP,7, "(%p) Allocating new RCD", pELEMENT); pELEMENT->blOddFrameLinkage.Initialize(); pELEMENT->blCompleteLinkage.Initialize(); pELEMENT->Sign = RCD_SIGN; return TRUE; } // Get is called each time an MSD is used #undef DPF_MODNAME #define DPF_MODNAME "RCD_Get" VOID RCD_Get(PVOID pElement) { DPFX(DPFPREP,DPF_REFCNT_FINAL_LVL, "CREATING RCD %p", pELEMENT); // NOTE: First sizeof(PVOID) bytes will have been overwritten by the pool code, // we must set them to acceptable values. pELEMENT->pRcvBuff = NULL; pELEMENT->lRefCnt = 1; pELEMENT->ulRFlags = 0; ASSERT_RCD(pELEMENT); } // RCD Release -- This release call will release an entire chain of RCDs // that are linked together... or then again maybe not. #undef DPF_MODNAME #define DPF_MODNAME "RCD_Release" VOID RCD_Release(PVOID pElement) { ASSERT_RCD(pELEMENT); ASSERT(pELEMENT->lRefCnt == 0); ASSERT(pELEMENT->pRcvBuff == NULL); DPFX(DPFPREP,DPF_REFCNT_FINAL_LVL, "RELEASING RCD %p", pELEMENT); } #undef DPF_MODNAME #define DPF_MODNAME "RCD_Free" VOID RCD_Free(PVOID pElement) { } #undef pELEMENT /* ** Buffer pool support ** ** */ #define pELEMENT ((PBUF) pElement) #undef DPF_MODNAME #define DPF_MODNAME "Buf_Allocate" BOOL Buf_Allocate(PVOID pElement) { DPFX(DPFPREP,7, "(%p) Allocating new Buf", pElement); return TRUE; } #undef DPF_MODNAME #define DPF_MODNAME "Buf_Get" VOID Buf_Get(PVOID pElement) { // NOTE: First sizeof(PVOID) bytes will have been overwritten by the pool code, // we must set them to acceptable values. pELEMENT->Type = RBT_PROTOCOL_BUFFER; pELEMENT->Owner = BufPool; } #undef DPF_MODNAME #define DPF_MODNAME "Buf_GetMed" VOID Buf_GetMed(PVOID pElement) { // NOTE: First sizeof(PVOID) bytes will have been overwritten by the pool code, // we must set them to acceptable values. pELEMENT->Type = RBT_PROTOCOL_BUFFER; pELEMENT->Owner = MedBufPool; } #undef DPF_MODNAME #define DPF_MODNAME "Buf_GetBig" VOID Buf_GetBig(PVOID pElement) { // NOTE: First sizeof(PVOID) bytes will have been overwritten by the pool code, // we must set them to acceptable values. pELEMENT->Type = RBT_PROTOCOL_BUFFER; pELEMENT->Owner = BigBufPool; } #undef pELEMENT