534 lines
17 KiB
C
534 lines
17 KiB
C
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/****************************************************************************/
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// buffer.c
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//
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// TermDD default OutBuf management.
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//
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// Copyright (C) 1998-2000 Microsoft Corporation
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/****************************************************************************/
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#include <precomp.h>
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#pragma hdrstop
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/*
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* Define default stack size for IRP allocation.
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* (This size will be checked by the TdRawWrite routine.)
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*/
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#define OUTBUF_STACK_SIZE 4
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#define OUTBUF_TIMEOUT 60000 // 1 minute
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#if DBG
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extern PICA_DISPATCH IcaStackDispatchTable[];
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#endif
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/****************************************************************************/
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// IcaBufferGetUsableSpace
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//
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// Used by the protocol stack drivers to determine the number of usable bytes
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// in a TermDD-created OutBuf, given the total size of the OutBuf. This allows
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// a stack driver to target a particular OutBuf size and pack data up to the
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// edges of the internal OutBuf headers. The returned size can be used as an
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// allocation size request that will return an OutBuf of the right size.
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/****************************************************************************/
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unsigned IcaBufferGetUsableSpace(unsigned OutBufTotalSize)
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{
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unsigned IrpSize;
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unsigned MdlSize;
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unsigned MaxOutBufOverhead;
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// Use the same overhead calculations used in IcaBufferAllocInternal()
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// below, plus a 4-byte offset to cover the extra 1-byte difference
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// required in the requesting size to reach a target buffer size.
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IrpSize = IoSizeOfIrp(OUTBUF_STACK_SIZE) + 8;
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if (OutBufTotalSize <= MaxOutBufAlloc)
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MdlSize = MaxOutBufMdlOverhead;
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else
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MdlSize = (unsigned)MmSizeOfMdl((PVOID)(PAGE_SIZE - 1),
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OutBufTotalSize);
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MaxOutBufOverhead = ((sizeof(OUTBUF) + 7) & ~7) + IrpSize + MdlSize;
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return OutBufTotalSize - MaxOutBufOverhead - 4;
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}
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/*******************************************************************************
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* IcaBufferAlloc
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*
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* pContext (input)
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* pointer to SDCONTEXT of caller
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* fWait (input)
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* wait for buffer
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* fControl (input)
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* control buffer flag
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* ByteCount (input)
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* size of buffer to allocate (zero - use default size)
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* pOutBufOrig (input)
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* pointer to original OUTBUF (or null)
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* pOutBuf (output)
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* address to return pointer to OUTBUF structure
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******************************************************************************/
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NTSTATUS IcaBufferAlloc(
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IN PSDCONTEXT pContext,
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IN BOOLEAN fWait,
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IN BOOLEAN fControl,
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IN ULONG ByteCount,
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IN POUTBUF pOutBufOrig,
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OUT POUTBUF *ppOutBuf)
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{
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PSDLINK pSdLink;
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PICA_STACK pStack;
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NTSTATUS Status;
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/*
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* Use SD passed context to get the SDLINK pointer.
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*/
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pSdLink = CONTAINING_RECORD(pContext, SDLINK, SdContext);
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pStack = pSdLink->pStack;
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ASSERT(pSdLink->pStack->Header.Type == IcaType_Stack);
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ASSERT(pSdLink->pStack->Header.pDispatchTable == IcaStackDispatchTable);
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ASSERT(ExIsResourceAcquiredExclusiveLite( &pStack->Resource));
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/*
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* Walk up the SDLINK list looking for a driver which has specified
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* a BufferAlloc callup routine. If we find one, then call the
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* driver BufferAlloc routine to let it handle the call.
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*/
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while ((pSdLink = IcaGetPreviousSdLink(pSdLink)) != NULL) {
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ASSERT( pSdLink->pStack == pStack );
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if (pSdLink->SdContext.pCallup->pSdBufferAlloc) {
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IcaReferenceSdLink(pSdLink);
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Status = (pSdLink->SdContext.pCallup->pSdBufferAlloc)(
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pSdLink->SdContext.pContext,
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fWait,
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fControl,
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ByteCount,
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pOutBufOrig,
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ppOutBuf);
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IcaDereferenceSdLink(pSdLink);
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return Status;
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}
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}
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/*
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* We didn't find a callup routine to handle the request,
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* so we'll process it here.
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*/
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Status = IcaBufferAllocInternal(pContext, fWait, fControl, ByteCount,
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pOutBufOrig, ppOutBuf);
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TRACESTACK((pStack, TC_ICADD, TT_API3,
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"TermDD: IcaBufferAlloc: 0x%08x, Status=0x%x\n", *ppOutBuf,
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Status));
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return Status;
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}
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NTSTATUS IcaBufferAllocInternal(
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IN PSDCONTEXT pContext,
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IN BOOLEAN fWait,
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IN BOOLEAN fControl,
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IN ULONG ByteCount,
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IN POUTBUF pOutBufOrig,
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OUT POUTBUF *ppOutBuf)
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{
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PSDLINK pSdLink;
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PICA_STACK pStack;
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int PoolIndex;
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ULONG irpSize;
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ULONG mdlSize;
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ULONG AllocationSize;
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KIRQL oldIrql;
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PLIST_ENTRY Head;
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POUTBUF pOutBuf;
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NTSTATUS Status;
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unsigned MaxOutBufOverhead;
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/*
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* Use SD passed context to get the SDLINK pointer.
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*/
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pSdLink = CONTAINING_RECORD( pContext, SDLINK, SdContext );
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pStack = pSdLink->pStack;
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ASSERT( pSdLink->pStack->Header.Type == IcaType_Stack );
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ASSERT( pSdLink->pStack->Header.pDispatchTable == IcaStackDispatchTable );
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/*
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* If original buffer is specified use it's flags
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*/
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if (pOutBufOrig) {
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fWait = (BOOLEAN) pOutBufOrig->fWait;
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fControl = (BOOLEAN) pOutBufOrig->fControl;
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}
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/*
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* Check if we already have our maximum number of buffers allocated
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*/
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while (!fControl && (pStack->OutBufAllocCount >= pStack->OutBufCount)) {
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/*
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* increment performance counter
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*/
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pStack->ProtocolStatus.Output.WaitForOutBuf++;
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/*
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* Return if it's not ok to wait
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*/
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if (!fWait)
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return(STATUS_IO_TIMEOUT);
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/*
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* We hit the high watermark
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*/
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pStack->fWaitForOutBuf = TRUE;
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/*
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* Only wait for non-control requests
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*/
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KeClearEvent(&pStack->OutBufEvent);
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Status = IcaWaitForSingleObject(pContext, &pStack->OutBufEvent,
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OUTBUF_TIMEOUT);
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if (NT_SUCCESS(Status)) {
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if (Status != STATUS_WAIT_0)
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return STATUS_IO_TIMEOUT;
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}
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else {
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return Status;
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}
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}
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/*
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* If the caller did not specify a byte count
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* then use the standard outbuf size for this stack.
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*/
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if (ByteCount == 0)
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ByteCount = pStack->OutBufLength;
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// Note MaxOutBufOverhead is the max for the default max allocation.
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// It will be recalculated if the requested alloc size is greater
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// than can be handled by the default.
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irpSize = IoSizeOfIrp(OUTBUF_STACK_SIZE) + 8;
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mdlSize = MaxOutBufMdlOverhead;
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MaxOutBufOverhead = ((sizeof(OUTBUF) + 7) & ~7) + irpSize + mdlSize;
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/*
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* Determine which buffer pool to use, if any,
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* and the OutBuf length to allocate, if necessary.
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* Note that the max requested ByteCount that will hit the buffer pool
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* is (MaxOutBufAlloc - 1 - MaxOutBufOverhead).
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*/
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if ((ByteCount + MaxOutBufOverhead) < MaxOutBufAlloc) {
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ASSERT(((ByteCount + MaxOutBufOverhead) / MinOutBufAlloc) <
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(1 << NumAllocSigBits));
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PoolIndex = OutBufPoolMapping[(ByteCount + MaxOutBufOverhead) /
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MinOutBufAlloc];
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IcaAcquireSpinLock(&IcaSpinLock, &oldIrql);
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if (!IsListEmpty(&IcaFreeOutBufHead[PoolIndex])) {
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Head = RemoveHeadList(&IcaFreeOutBufHead[PoolIndex]);
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IcaReleaseSpinLock(&IcaSpinLock, oldIrql);
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pOutBuf = CONTAINING_RECORD(Head, OUTBUF, Links);
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ASSERT(pOutBuf->PoolIndex == PoolIndex);
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}
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else {
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IcaReleaseSpinLock(&IcaSpinLock, oldIrql);
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AllocationSize = OutBufPoolAllocSizes[PoolIndex];
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pOutBuf = ICA_ALLOCATE_POOL(NonPagedPool, AllocationSize);
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if (pOutBuf == NULL)
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return STATUS_NO_MEMORY;
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// Prevent leaking control OutBufs on OutBuf free.
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if (fControl)
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PoolIndex = FreeThisOutBuf;
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}
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}
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else {
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PoolIndex = FreeThisOutBuf;
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/*
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* Determine the sizes of the various components of an OUTBUF.
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* Note that these are all worst-case calculations --
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* actual size of the MDL may be smaller.
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*/
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mdlSize = (ULONG)MmSizeOfMdl((PVOID)(PAGE_SIZE - 1), ByteCount);
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/*
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* Add up the component sizes of an OUTBUF to determine
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* the total size that is needed to allocate.
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*/
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AllocationSize = ((sizeof(OUTBUF) + 7) & ~7) + irpSize + mdlSize +
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((ByteCount + 3) & ~3);
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pOutBuf = ICA_ALLOCATE_POOL(NonPagedPool, AllocationSize);
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if (pOutBuf == NULL)
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return STATUS_NO_MEMORY;
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}
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/*
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* Initialize the IRP pointer and the IRP itself.
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*/
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pOutBuf->pIrp = (PIRP)((BYTE *)pOutBuf + ((sizeof(OUTBUF) + 7) & ~7));
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IoInitializeIrp(pOutBuf->pIrp, (USHORT)irpSize, OUTBUF_STACK_SIZE);
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/*
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* Set up the MDL pointer but don't build it yet.
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* It will be built by the TD write code if needed.
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*/
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pOutBuf->pMdl = (PMDL)((PCHAR)pOutBuf->pIrp + irpSize);
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/*
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* Set up the address buffer pointer.
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*/
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pOutBuf->pBuffer = (PUCHAR)pOutBuf->pMdl + mdlSize +
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pStack->SdOutBufHeader;
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/*
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* Initialize the rest of output buffer
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*/
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InitializeListHead(&pOutBuf->Links);
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pOutBuf->OutBufLength = ByteCount;
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pOutBuf->PoolIndex = PoolIndex;
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pOutBuf->MaxByteCount = ByteCount - (pStack->SdOutBufHeader +
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pStack->SdOutBufTrailer);
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pOutBuf->ByteCount = 0;
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pOutBuf->fIrpCompleted = FALSE;
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/*
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* Copy inherited fields
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*/
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if (pOutBufOrig == NULL) {
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pOutBuf->fWait = fWait; // wait for outbuf allocation
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pOutBuf->fControl = fControl; // control buffer (ack/nak)
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pOutBuf->fRetransmit = FALSE; // not a retransmit
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pOutBuf->fCompress = TRUE; // compress data
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pOutBuf->StartTime = 0; // time stamp
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pOutBuf->Sequence = 0; // zero sequence number
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pOutBuf->Fragment = 0; // zero fragment number
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}
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else {
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pOutBuf->fWait = pOutBufOrig->fWait;
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pOutBuf->fControl = pOutBufOrig->fControl;
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pOutBuf->fRetransmit = pOutBufOrig->fRetransmit;
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pOutBuf->fCompress = pOutBufOrig->fCompress;
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pOutBuf->StartTime = pOutBufOrig->StartTime;
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pOutBuf->Sequence = pOutBufOrig->Sequence;
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pOutBuf->Fragment = pOutBufOrig->Fragment++;
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}
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/*
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* Increment allocated buffer count
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*/
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pStack->OutBufAllocCount++;
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/*
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* Return buffer to caller
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*/
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*ppOutBuf = pOutBuf;
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/*
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* Return buffer to caller
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*/
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return STATUS_SUCCESS;
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}
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/*******************************************************************************
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* IcaBufferFree
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*
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* pContext (input)
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* pointer to SDCONTEXT of caller
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* pOutBuf (input)
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* pointer to OUTBUF structure
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******************************************************************************/
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void IcaBufferFree(IN PSDCONTEXT pContext, IN POUTBUF pOutBuf)
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{
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PSDLINK pSdLink;
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PICA_STACK pStack;
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NTSTATUS Status;
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/*
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* Use SD passed context to get the SDLINK pointer.
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*/
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pSdLink = CONTAINING_RECORD(pContext, SDLINK, SdContext);
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pStack = pSdLink->pStack;
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ASSERT(pSdLink->pStack->Header.Type == IcaType_Stack);
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ASSERT(pSdLink->pStack->Header.pDispatchTable == IcaStackDispatchTable);
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ASSERT(ExIsResourceAcquiredExclusiveLite( &pStack->Resource));
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/*
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* Walk up the SDLINK list looking for a driver which has specified
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* a BufferFree callup routine. If we find one, then call the
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* driver BufferFree routine to let it handle the call.
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*/
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while ((pSdLink = IcaGetPreviousSdLink(pSdLink)) != NULL) {
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ASSERT(pSdLink->pStack == pStack);
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if (pSdLink->SdContext.pCallup->pSdBufferFree) {
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IcaReferenceSdLink(pSdLink);
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(pSdLink->SdContext.pCallup->pSdBufferFree)(
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pSdLink->SdContext.pContext,
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pOutBuf);
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IcaDereferenceSdLink(pSdLink);
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return;
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}
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}
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IcaBufferFreeInternal(pContext, pOutBuf);
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TRACESTACK((pStack, TC_ICADD, TT_API3,
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"TermDD: IcaBufferFree: 0x%08x\n", pOutBuf));
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}
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/*******************************************************************************
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* IcaBufferError
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*
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* pContext (input)
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* pointer to SDCONTEXT of caller
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* pOutBuf (input)
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* pointer to OUTBUF structure
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******************************************************************************/
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void IcaBufferError(IN PSDCONTEXT pContext, IN POUTBUF pOutBuf)
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{
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PSDLINK pSdLink;
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PICA_STACK pStack;
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NTSTATUS Status;
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/*
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* Use SD passed context to get the SDLINK pointer.
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*/
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pSdLink = CONTAINING_RECORD(pContext, SDLINK, SdContext);
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pStack = pSdLink->pStack;
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ASSERT(pSdLink->pStack->Header.Type == IcaType_Stack);
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ASSERT(pSdLink->pStack->Header.pDispatchTable == IcaStackDispatchTable);
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ASSERT(ExIsResourceAcquiredExclusiveLite( &pStack->Resource));
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/*
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* Walk up the SDLINK list looking for a driver which has specified
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* a BufferError callup routine. If we find one, then call the
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* driver BufferError routine to let it handle the call.
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*/
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while ((pSdLink = IcaGetPreviousSdLink(pSdLink)) != NULL) {
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ASSERT(pSdLink->pStack == pStack);
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if (pSdLink->SdContext.pCallup->pSdBufferError) {
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IcaReferenceSdLink(pSdLink);
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(pSdLink->SdContext.pCallup->pSdBufferError)(
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pSdLink->SdContext.pContext,
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pOutBuf);
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IcaDereferenceSdLink(pSdLink);
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return;
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}
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}
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IcaBufferFreeInternal(pContext, pOutBuf);
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TRACESTACK((pStack, TC_ICADD, TT_API3,
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"TermDD: IcaBufferError: 0x%08x\n", pOutBuf));
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}
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void IcaBufferFreeInternal(IN PSDCONTEXT pContext, IN POUTBUF pOutBuf)
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{
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PSDLINK pSdLink;
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PICA_STACK pStack;
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KIRQL oldIrql;
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/*
|
||
|
* Use SD passed context to get the SDLINK pointer.
|
||
|
*/
|
||
|
pSdLink = CONTAINING_RECORD(pContext, SDLINK, SdContext);
|
||
|
pStack = pSdLink->pStack;
|
||
|
ASSERT(pSdLink->pStack->Header.Type == IcaType_Stack);
|
||
|
ASSERT(pSdLink->pStack->Header.pDispatchTable == IcaStackDispatchTable);
|
||
|
|
||
|
/*
|
||
|
* If the buffer came from a free pool, return it to the pool,
|
||
|
* otherwise free it. Note that pOutBuf->OutBufLength is actually the
|
||
|
* pool index to use.
|
||
|
*/
|
||
|
if (pOutBuf->PoolIndex != FreeThisOutBuf) {
|
||
|
ASSERT(pOutBuf->PoolIndex >= 0 &&
|
||
|
pOutBuf->PoolIndex < NumOutBufPools);
|
||
|
IcaAcquireSpinLock(&IcaSpinLock, &oldIrql);
|
||
|
InsertHeadList(&IcaFreeOutBufHead[pOutBuf->PoolIndex],
|
||
|
&pOutBuf->Links);
|
||
|
IcaReleaseSpinLock(&IcaSpinLock, oldIrql);
|
||
|
}
|
||
|
else {
|
||
|
ICA_FREE_POOL(pOutBuf);
|
||
|
}
|
||
|
|
||
|
/*
|
||
|
* Decrement allocated buffer count
|
||
|
*/
|
||
|
pStack->OutBufAllocCount--;
|
||
|
ASSERT((LONG)pStack->OutBufAllocCount >= 0);
|
||
|
|
||
|
/*
|
||
|
* If we hit the high watermark then we should wait until the low
|
||
|
* watermark is hit before signaling the allocator to continue.
|
||
|
* This should prevent excessive task switching.
|
||
|
*/
|
||
|
if (pStack->fWaitForOutBuf) {
|
||
|
if (pStack->OutBufAllocCount <= pStack->OutBufLowWaterMark) {
|
||
|
pStack->fWaitForOutBuf = FALSE;
|
||
|
|
||
|
/*
|
||
|
* Signal outbuf event (buffer is now available)
|
||
|
*/
|
||
|
(void) KeSetEvent(&pStack->OutBufEvent, EVENT_INCREMENT, FALSE);
|
||
|
}
|
||
|
}
|
||
|
}
|
||
|
|
||
|
|
||
|
/*******************************************************************************
|
||
|
* IcaGetLowWaterMark
|
||
|
*
|
||
|
* Description : Gets the low water mark that the stack specified
|
||
|
*
|
||
|
* pContext (input)
|
||
|
* pointer to SDCONTEXT of caller
|
||
|
******************************************************************************/
|
||
|
ULONG IcaGetLowWaterMark(IN PSDCONTEXT pContext)
|
||
|
{
|
||
|
ULONG ulRet = 0;
|
||
|
PICA_STACK pStack;
|
||
|
PSDLINK pSdLink = CONTAINING_RECORD(pContext, SDLINK, SdContext);
|
||
|
|
||
|
ASSERT(pSdLink);
|
||
|
|
||
|
ASSERT(pSdLink->pStack->Header.Type == IcaType_Stack);
|
||
|
|
||
|
ASSERT(pSdLink->pStack->Header.pDispatchTable == IcaStackDispatchTable);
|
||
|
|
||
|
ASSERT(ExIsResourceAcquiredExclusive( &pSdLink->pStack->Resource));
|
||
|
|
||
|
if (NULL != pSdLink) {
|
||
|
pStack = pSdLink->pStack;
|
||
|
ulRet = pStack->OutBufLowWaterMark;
|
||
|
}
|
||
|
return ulRet;
|
||
|
}
|
||
|
|
||
|
/*******************************************************************************
|
||
|
* IcaGetSizeForNoLowWaterMark
|
||
|
*
|
||
|
* Description : Finds if the stack specified a no low water mark
|
||
|
* If so, returns the size needed to bypass ring
|
||
|
* returns zero if the stack does not specify a PD_NO_LOWWATERMARK
|
||
|
* pContext (input)
|
||
|
* pointer to SDCONTEXT of caller
|
||
|
******************************************************************************/
|
||
|
ULONG IcaGetSizeForNoLowWaterMark(IN PSDCONTEXT pContext)
|
||
|
{
|
||
|
ULONG retVal = 0;
|
||
|
ULONG ulLowWm = IcaGetLowWaterMark(pContext);
|
||
|
|
||
|
if ( MAX_LOW_WATERMARK == ulLowWm ) {
|
||
|
retVal = MaxOutBufAlloc;
|
||
|
}
|
||
|
return retVal;
|
||
|
}
|