Leaked source code of windows server 2003
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/*
************************************************************************
*
* NSC.c
*
*
* Portions Copyright (C) 1996-2001 National Semiconductor Corp.
* All rights reserved.
* Copyright (C) 1996-2001 Microsoft Corporation. All Rights Reserved.
*
*
*
*************************************************************************
*/
#include "nsc.h"
#include "nsc.tmh"
/*
* We keep a linked list of device objects
*/
/* This fuction sets up the device for Recv */
void SetupRecv(IrDevice *thisDev);
//
// Debug Counters
//
DebugCounters RegStats = {0,0,0,0,0,0,0,0,0};
ULONG DebugSpeed=0;
#ifdef RECEIVE_PACKET_LOGGING
typedef struct {
UCHAR Data[12];
} DATA_BITS;
typedef struct {
USHORT Tag;
USHORT Line;
union {
struct {
PNDIS_PACKET Packet;
PVOID DmaBuffer;
ULONG Length;
} Packet;
struct {
PLIST_ENTRY Head;
PLIST_ENTRY Entry;
} List;
struct {
PVOID Start;
ULONG Offset;
ULONG Length;
} Dma;
struct {
ULONG Length;
} Discard;
DATA_BITS Data;
};
} RCV_LOG;
#define CHAIN_PACKET_TAG 'CP'
#define UNCHAIN_PACKET_TAG 'UP'
#define ADD_HEAD_LIST_TAG 'HA'
#define ADD_TAIL_LIST_TAG 'TA'
#define REMOVE_HEAD_LIST_TAG 'HR'
#define REMOVE_ENTRY_TAG 'ER'
#define DMA_TAG 'MD'
#define DATA_TAG 'AD'
#define DATA2_TAG '2D'
#define DISCARD_TAG 'XX'
#define NUM_RCV_LOG 256
ULONG RcvLogIndex = 0;
RCV_LOG RcvLog[NUM_RCV_LOG];
BOOLEAN SyncGetRcvLogEntry(PVOID Context)
{
*(ULONG*)Context = RcvLogIndex++;
RcvLogIndex &= NUM_RCV_LOG-1;
return TRUE;
}
ULONG GetRcvLogEntry(IrDevice *thisDev)
{
ULONG Entry;
NdisAcquireSpinLock(&thisDev->QueueLock);
NdisMSynchronizeWithInterrupt(&thisDev->interruptObj, SyncGetRcvLogEntry, &Entry);
NdisReleaseSpinLock(&thisDev->QueueLock);
return Entry;
}
#define LOG_InsertHeadList(d, h, e) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = ADD_HEAD_LIST_TAG; \
RcvLog[i].Line = __LINE__; \
RcvLog[i].List.Head = (h); \
RcvLog[i].List.Entry = (PLIST_ENTRY)(e); \
}
#define LOG_InsertTailList(d, h, e) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = ADD_TAIL_LIST_TAG; \
RcvLog[i].Line = __LINE__; \
RcvLog[i].List.Head = (h); \
RcvLog[i].List.Entry = (PLIST_ENTRY)(e); \
}
#define LOG_RemoveHeadList(d, h, e) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = REMOVE_HEAD_LIST_TAG; \
RcvLog[i].Line = __LINE__; \
RcvLog[i].List.Head = (h); \
RcvLog[i].List.Entry = (PLIST_ENTRY)(e); \
}
#define LOG_RemoveEntryList(d, e) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = REMOVE_ENTRY_TAG; \
RcvLog[i].Line = __LINE__; \
RcvLog[i].List.Head = NULL; \
RcvLog[i].List.Entry = (PLIST_ENTRY)(e); \
}
#define LOG_PacketChain(d, p) \
{ \
PNDIS_BUFFER NdisBuffer; \
PVOID Address; \
ULONG Len; \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = CHAIN_PACKET_TAG; \
RcvLog[i].Line = __LINE__; \
NdisQueryPacket((p), NULL, NULL, &NdisBuffer, NULL); \
NdisQueryBufferSafe(NdisBuffer, &Address, &Len,NormalPagePriority); \
RcvLog[i].Packet.Packet = (p); \
RcvLog[i].Packet.DmaBuffer = Address; \
RcvLog[i].Packet.Length = Len; \
}
#define LOG_PacketUnchain(d, p) \
{ \
PNDIS_BUFFER NdisBuffer; \
PVOID Address; \
ULONG Len; \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = UNCHAIN_PACKET_TAG; \
RcvLog[i].Line = __LINE__; \
NdisQueryPacket((p), NULL, NULL, &NdisBuffer, NULL); \
NdisQueryBufferSafe(NdisBuffer, &Address, &Len,NormalPagePriority); \
RcvLog[i].Packet.Packet = (p); \
RcvLog[i].Packet.DmaBuffer = Address; \
RcvLog[i].Packet.Length = Len; \
}
#define LOG_Dma(d) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = DMA_TAG; \
RcvLog[i].Line = __LINE__; \
RcvLog[i].Dma.Start = (d)->rcvDmaBuffer; \
RcvLog[i].Dma.Offset = (d)->rcvDmaOffset; \
RcvLog[i].Dma.Length = (d)->rcvDmaSize; \
}
#define LOG_Data(d,s) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = DATA_TAG; \
RcvLog[i].Line = ((USHORT)(s))&0xffff; \
RcvLog[i].Data = *(DATA_BITS*)(s); \
}
#define LOG_Data2(d,s) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = DATA2_TAG; \
RcvLog[i].Line = ((USHORT)(s))&0xffff; \
RcvLog[i].Data = *(DATA_BITS*)(s); \
}
#define LOG_Discard(d,s) \
{ \
ULONG i = GetRcvLogEntry(d); \
RcvLog[i].Tag = DISCARD_TAG; \
RcvLog[i].Line = __LINE__; \
RcvLog[i].Discard.Length = (s); \
}
void DumpNdisPacket(PNDIS_PACKET Packet, UINT Line)
{
UINT PhysBufCnt, BufCnt, TotLen, Len;
PNDIS_BUFFER NdisBuffer;
PVOID Address;
DbgPrint("Badly formed NDIS packet at line %d\n", Line);
NdisQueryPacket(Packet, &PhysBufCnt, &BufCnt, &NdisBuffer, &TotLen);
DbgPrint("Packet:%08X PhysBufCnt:%d BufCnt:%d TotLen:%d\n",
Packet, PhysBufCnt, BufCnt, TotLen);
while (NdisBuffer)
{
NdisQueryBufferSafe(NdisBuffer, &Address, &Len,NormalPagePriority);
DbgPrint(" Buffer:%08X Address:%08X Length:%d\n",
NdisBuffer, Address, Len);
NdisGetNextBuffer(NdisBuffer, &NdisBuffer);
}
ASSERT(0);
}
#define VerifyNdisPacket(p, b) \
{ \
UINT BufCnt; \
\
NdisQueryPacket((p), NULL, &BufCnt, NULL, NULL); \
if (BufCnt>(b)) \
{ \
DumpNdisPacket((p), __LINE__); \
} \
}
#else
#define VerifyNdisPacket(p,b)
#define LOG_InsertHeadList(d, h, e)
#define LOG_InsertTailList(d, h, e)
#define LOG_RemoveHeadList(d, h, e)
#define LOG_RemoveEntryList(d, e)
#define LOG_PacketChain(d, p)
#define LOG_PacketUnchain(d, p)
#define LOG_Dma(d)
#define LOG_Data(d,s)
#define LOG_Data2(d,s)
#define LOG_Discard(d,s)
#endif
BOOLEAN
VerifyHardware(
IrDevice *thisDev
);
/*
*************************************************************************
* MiniportCheckForHang
*************************************************************************
*
* Reports the state of the network interface card.
*
*/
BOOLEAN MiniportCheckForHang(NDIS_HANDLE MiniportAdapterContext)
{
IrDevice *thisDev = CONTEXT_TO_DEV(MiniportAdapterContext);
// LOG("==> MiniportCheckForHang");
DBGOUT(("==> MiniportCheckForHang(0x%x)", MiniportAdapterContext));
// We have seen cases where we hang sending at high speeds. This occurs only
// on very old revisions of the NSC hardware.
// This is an attempt to kick us off again.
NdisDprAcquireSpinLock(&thisDev->QueueLock);
if (thisDev->FirTransmitPending) {
switch (thisDev->HangChk)
{
case 0:
break;
default:
DBGERR(("NSCIRDA: CheckForHang--we appear hung\n"));
LOG_ERROR("CheckForHang--we appear hung\n");
// Issue a soft reset to the transmitter & receiver.
SyncWriteBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 0, 2, 0x06);
//
// turn the timer on and let it gnerate an interrupt
//
thisDev->FirIntMask = 0x90;
SyncWriteBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 4, 2, 0x01);
SyncSetInterruptMask(thisDev, TRUE);
break;
}
thisDev->HangChk++;
}
NdisDprReleaseSpinLock(&thisDev->QueueLock);
// LOG("<== MiniportCheckForHang");
DBGOUT(("<== MiniportCheckForHang(0x%x)", MiniportAdapterContext));
return FALSE;
}
/*
*************************************************************************
* MiniportHalt
*************************************************************************
*
* Halts the network interface card.
*
*/
VOID MiniportHalt(IN NDIS_HANDLE MiniportAdapterContext)
{
IrDevice *thisDev = CONTEXT_TO_DEV(MiniportAdapterContext);
LOG("==> MiniportHalt");
DBGOUT(("==> MiniportHalt(0x%x)", MiniportAdapterContext));
thisDev->hardwareStatus = NdisHardwareStatusClosing;
NdisAcquireSpinLock(&thisDev->QueueLock);
thisDev->Halting=TRUE;
if (thisDev->PacketsSentToProtocol > 0) {
//
// wait for all the packets to come back from the protocol
//
NdisReleaseSpinLock(&thisDev->QueueLock);
NdisWaitEvent(&thisDev->ReceiveStopped, 1*60*1000);
NdisAcquireSpinLock(&thisDev->QueueLock);
}
if (!thisDev->TransmitIsIdle) {
//
// wait for all the packets to be transmitted
//
NdisReleaseSpinLock(&thisDev->QueueLock);
NdisWaitEvent(&thisDev->SendStoppedOnHalt,1*60*1000);
NdisAcquireSpinLock(&thisDev->QueueLock);
}
if (thisDev->FirReceiveDmaActive) {
thisDev->FirReceiveDmaActive=FALSE;
//
// receive dma is running, stop it
//
CompleteDmaTransferFromDevice(
&thisDev->DmaUtil
);
}
//
// which back to SIR mode
//
CloseCOM(thisDev);
SyncSetInterruptMask(thisDev, FALSE);
NdisReleaseSpinLock(&thisDev->QueueLock);
//
// release the interrupt
//
NdisMDeregisterInterrupt(&thisDev->interruptObj);
#if DBG
NdisZeroMemory(&thisDev->interruptObj,sizeof(thisDev->interruptObj));
#endif
//
// release fir related resources including dma channel
//
NSC_Shutdown(thisDev);
//
// release sir related buffers
//
DoClose(thisDev);
if (thisDev->portInfo.ConfigIoBasePhysAddr) {
NdisMDeregisterIoPortRange(thisDev->ndisAdapterHandle,
thisDev->portInfo.ConfigIoBasePhysAddr,
2,
(PVOID)thisDev->portInfo.ConfigIoBaseAddr);
}
NdisMDeregisterIoPortRange(thisDev->ndisAdapterHandle,
thisDev->portInfo.ioBasePhys,
((thisDev->CardType==PUMA108)?16:8),
(PVOID)thisDev->portInfo.ioBase);
//
// free the device block
//
FreeDevice(thisDev);
LOG("<== MiniportHalt");
DBGOUT(("<== MiniportHalt(0x%x)", MiniportAdapterContext));
}
void InterlockedInsertBufferSorted(PLIST_ENTRY Head,
rcvBuffer *rcvBuf,
PNDIS_SPIN_LOCK Lock)
{
PLIST_ENTRY ListEntry;
NdisAcquireSpinLock(Lock);
if (IsListEmpty(Head))
{
InsertHeadList(Head, &rcvBuf->listEntry);
}
else
{
BOOLEAN EntryInserted = FALSE;
for (ListEntry = Head->Flink;
ListEntry != Head;
ListEntry = ListEntry->Flink)
{
rcvBuffer *temp = CONTAINING_RECORD(ListEntry,
rcvBuffer,
listEntry);
if (temp->dataBuf > rcvBuf->dataBuf)
{
// We found one that comes after ours.
// We need to insert before it
InsertTailList(ListEntry, &rcvBuf->listEntry);
EntryInserted = TRUE;
break;
}
}
if (!EntryInserted)
{
// We didn't find an entry on the last who's address was later
// than our buffer. We go at the end.
InsertTailList(Head, &rcvBuf->listEntry);
}
}
NdisReleaseSpinLock(Lock);
}
/*
*************************************************************************
* DeliverFullBuffers
*************************************************************************
*
* Deliver received packets to the protocol.
* Return TRUE if delivered at least one frame.
*
*/
VOID
DeliverFullBuffers(IrDevice *thisDev)
{
PLIST_ENTRY ListEntry;
LOG("==> DeliverFullBuffers");
DBGOUT(("==> DeliverFullBuffers(0x%x)", thisDev));
/*
* Deliver all full rcv buffers
*/
for (
ListEntry = NDISSynchronizedRemoveHeadList(&thisDev->rcvBufFull,
&thisDev->interruptObj);
ListEntry;
ListEntry = NDISSynchronizedRemoveHeadList(&thisDev->rcvBufFull,
&thisDev->interruptObj)
)
{
rcvBuffer *rcvBuf = CONTAINING_RECORD(ListEntry,
rcvBuffer,
listEntry);
NDIS_STATUS stat;
PNDIS_BUFFER packetBuf;
SLOW_IR_FCS_TYPE fcs;
VerifyNdisPacket(rcvBuf->packet, 0);
if (thisDev->currentSpeed <= MAX_SIR_SPEED) {
/*
* The packet we have already has had BOFs,
* EOF, and * escape-sequences removed. It
* contains an FCS code at the end, which we
* need to verify and then remove before
* delivering the frame. We compute the FCS
* on the packet with the packet FCS attached;
* this should produce the constant value
* GOOD_FCS.
*/
fcs = ComputeFCS(rcvBuf->dataBuf,
rcvBuf->dataLen);
if (fcs != GOOD_FCS) {
/*
* FCS Error. Drop this frame.
*/
LOG("Error: Bad FCS in DeliverFullBuffers %x", fcs);
DBGERR(("Bad FCS in DeliverFullBuffers 0x%x!=0x%x.",
(UINT)fcs, (UINT) GOOD_FCS));
rcvBuf->state = STATE_FREE;
DBGSTAT(("Dropped %d/%d pkts; BAD FCS (%xh!=%xh):",
++thisDev->packetsDropped,
thisDev->packetsDropped +
thisDev->packetsRcvd, fcs,
GOOD_FCS));
DBGPRINTBUF(rcvBuf->dataBuf,
rcvBuf->dataLen);
if (!rcvBuf->isDmaBuf)
{
NDISSynchronizedInsertTailList(&thisDev->rcvBufBuf,
RCV_BUF_TO_LIST_ENTRY(rcvBuf->dataBuf),
&thisDev->interruptObj);
}
rcvBuf->dataBuf = NULL;
rcvBuf->isDmaBuf = FALSE;
VerifyNdisPacket(rcvBuf->packet, 0);
NDISSynchronizedInsertHeadList(&thisDev->rcvBufFree,
&rcvBuf->listEntry,
&thisDev->interruptObj);
//break;
continue;
}
/* Remove the FCS from the end of the packet. */
rcvBuf->dataLen -= SLOW_IR_FCS_SIZE;
}
#ifdef DBG_ADD_PKT_ID
if (addPktIdOn) {
/* Remove dbg packet id. */
USHORT uniqueId;
rcvBuf->dataLen -= sizeof(USHORT);
uniqueId = *(USHORT *)(rcvBuf->dataBuf+
rcvBuf->dataLen);
DBGOUT(("ID: RCVing packet %xh **",
(UINT)uniqueId));
LOG("ID: Rcv Pkt id: %xh", uniqueId);
}
#endif
/*
* The packet array is set up with its NDIS_PACKET.
* Now we need to allocate a single NDIS_BUFFER for
* the NDIS_PACKET and set the NDIS_BUFFER to the
* part of dataBuf that we want to deliver.
*/
NdisAllocateBuffer(&stat, &packetBuf,
thisDev->bufferPoolHandle,
(PVOID)rcvBuf->dataBuf, rcvBuf->dataLen);
if (stat != NDIS_STATUS_SUCCESS){
LOG("Error: NdisAllocateBuffer failed");
DBGERR(("NdisAllocateBuffer failed"));
ASSERT(0);
break;
}
VerifyNdisPacket(rcvBuf->packet, 0);
NdisChainBufferAtFront(rcvBuf->packet, packetBuf);
LOG_PacketChain(thisDev, rcvBuf->packet);
VerifyNdisPacket(rcvBuf->packet, 1);
/*
* Fix up some other packet fields.
*/
NDIS_SET_PACKET_HEADER_SIZE(rcvBuf->packet,
IR_ADDR_SIZE+IR_CONTROL_SIZE);
DBGPKT(("Indicating rcv packet 0x%x.", rcvBuf->packet));
/*
* Indicate to the protocol that another packet is
* ready. Set the rcv buffer's state to PENDING first
* to avoid a race condition with NDIS's call to the
* return packet handler.
*/
NdisAcquireSpinLock(&thisDev->QueueLock);
if (thisDev->Halting) {
//
// the adapter is being halted, stop sending packets up
//
NdisReleaseSpinLock(&thisDev->QueueLock);
if (!rcvBuf->isDmaBuf) {
NDISSynchronizedInsertTailList(&thisDev->rcvBufBuf,
RCV_BUF_TO_LIST_ENTRY(rcvBuf->dataBuf),
&thisDev->interruptObj);
}
rcvBuf->dataBuf = NULL;
rcvBuf->isDmaBuf = FALSE;
VerifyNdisPacket(rcvBuf->packet, 0);
NDISSynchronizedInsertHeadList(&thisDev->rcvBufFree,
&rcvBuf->listEntry,
&thisDev->interruptObj);
//
// free the buffer we chained to the packet
//
packetBuf=NULL;
NdisUnchainBufferAtFront(rcvBuf->packet, &packetBuf);
if (packetBuf){
NdisFreeBuffer(packetBuf);
}
continue;
}
//
// increment the count of packets sent to the protocol
//
NdisInterlockedIncrement(&thisDev->PacketsSentToProtocol);
NdisReleaseSpinLock(&thisDev->QueueLock);
rcvBuf->state = STATE_PENDING;
*(rcvBuffer **)rcvBuf->packet->MiniportReserved = rcvBuf;
InterlockedInsertBufferSorted(
&thisDev->rcvBufPend,
rcvBuf,
&thisDev->QueueLock
);
VerifyNdisPacket(rcvBuf->packet, 1);
LOG_Data2(thisDev, rcvBuf->dataBuf);
NDIS_SET_PACKET_STATUS(rcvBuf->packet,STATUS_SUCCESS);
NdisMIndicateReceivePacket(thisDev->ndisAdapterHandle,
&rcvBuf->packet, 1);
/*
* The packet is being delivered asynchronously.
* Leave the rcv buffer's state as PENDING;
* we'll get a callback when the transfer is
*/
LOG("Indicated rcv complete (Async) bytes: %d",
rcvBuf->dataLen);
DBGSTAT(("Rcv Pending. Rcvd %d packets",
++thisDev->packetsRcvd));
}
LOG("<== DeliverFullBuffers");
DBGOUT(("<== DeliverFullBuffers"));
return ;
}
/*
*************************************************************************
* MiniportHandleInterrupt
*************************************************************************
*
*
* This is the deferred interrupt processing routine (DPC) which is
* optionally called following an interrupt serviced by MiniportISR.
*
*/
VOID MiniportHandleInterrupt(NDIS_HANDLE MiniportAdapterContext)
{
IrDevice *thisDev = CONTEXT_TO_DEV( MiniportAdapterContext);
PNDIS_PACKET PacketToComplete=NULL;
NDIS_STATUS PacketStatus=NDIS_STATUS_SUCCESS;
BOOLEAN SpeedChange=FALSE;
LOG("==> MiniportHandleInterrupt");
DBGOUT(("==> MiniportHandleInterrupt(0x%x)", MiniportAdapterContext));
/*
* If we have just started receiving a packet, indicate media-busy
* to the protocol.
*/
if (thisDev->mediaBusy && !thisDev->haveIndicatedMediaBusy) {
if (thisDev->currentSpeed > MAX_SIR_SPEED) {
LOG("Error: MiniportHandleInterrupt is in wrong state %d",
thisDev->currentSpeed);
DBGERR(("MiniportHandleInterrupt is in wrong state: speed is 0x%x",
thisDev->currentSpeed));
ASSERT(0);
}
NdisMIndicateStatus(thisDev->ndisAdapterHandle,
NDIS_STATUS_MEDIA_BUSY, NULL, 0);
NdisMIndicateStatusComplete(thisDev->ndisAdapterHandle);
thisDev->haveIndicatedMediaBusy = TRUE;
}
NdisDprAcquireSpinLock(&thisDev->QueueLock);
if (thisDev->currentSpeed > MAX_SIR_SPEED) {
//
// fir speed
//
//
// disable any other
//
thisDev->FirIntMask = 0x00;
if (thisDev->FirTransmitPending) {
ASSERT(thisDev->CurrentPacket != NULL);
thisDev->FirTransmitPending=FALSE;
//
// we seem to be transmitting now
//
{
ULONG CurrentDMACount;
UCHAR BytesInFifo;
ULONG LoopCount=0;
CurrentDMACount = NdisMReadDmaCounter(thisDev->DmaHandle);
if (CurrentDMACount > 0) {
LOG_ERROR("FIR send: Dma Count was not zero: %d\n\n", CurrentDMACount);
#if DBG
DbgPrint("FIR send: Count was not zero: %d\n\n", CurrentDMACount);
#endif
}
//
// see if the fifo is empty yet
//
BytesInFifo=SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, BANK_2, TXFLV_OFFSET) & 0x3f;
if (BytesInFifo > 0) {
LOG_ERROR("FIR send: Bytes still in fifo: %d", BytesInFifo);
while ((BytesInFifo > 0) && (LoopCount < 64)) {
BytesInFifo=SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, BANK_2, TXFLV_OFFSET) & 0x3f;
LoopCount++;
}
LOG_ERROR("FIR send: Bytes still in fifo after loop: %d, loops=%d", BytesInFifo,LoopCount);
}
}
PacketStatus=CompleteDmaTransferToDevice(
&thisDev->DmaUtil
);
if (PacketStatus != NDIS_STATUS_SUCCESS) {
DBGERR(("NdisMCompleteDmaTransfer failed: %d\n", PacketStatus));
#if DBG
DbgBreakPoint();
#endif
}
/*
* Check for Tx underrun.
*/
if (SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 0, ASCR_OFFSET) & ASCR_TXUR) {
USHORT TransmitCurrentCount;
//
// for debugging purposes, see where we were in the frame when it stopped
//
TransmitCurrentCount = SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, BANK_4, TFRCCL_OFFSET);
TransmitCurrentCount |= ((USHORT)SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, BANK_4, TFRCCH_OFFSET)) << 8;
//
// reset the fifo's
//
SyncWriteBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 0, 2, 0x07);
//
// clear the tx underrun
//
SyncWriteBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 0, ASCR_OFFSET, ASCR_TXUR);
RegStats.TxUnderruns++;
PacketStatus = NDIS_STATUS_FAILURE;
LOG_ERROR("MiniportDpc: Transmit Underrun: tx current count=%d",TransmitCurrentCount);
DEBUGFIR(DBG_TX|DBG_ERR, ("NSC: FIR_MegaSendComplete: Transmit Underrun\n"));
}
PacketToComplete=thisDev->CurrentPacket;
thisDev->CurrentPacket=NULL;
} else {
if (thisDev->FirReceiveDmaActive) {
FIR_DeliverFrames(thisDev);
} else {
DBGERR(("MiniportHandleInterrupt: fir: not sending and not RX state"));
LOG_ERROR("MiniportHandleInterrupt: fir: not sending and not RX state %02x",thisDev->InterruptStatus);
}
}
} else {
//
// in SIR mode
//
if (thisDev->CurrentPacket != NULL) {
//
//
UINT TransmitComplete=InterlockedExchange(&thisDev->portInfo.IsrDoneWithPacket,0);
if (TransmitComplete) {
PacketToComplete=thisDev->CurrentPacket;
thisDev->CurrentPacket=NULL;
}
}
}
thisDev->setSpeedAfterCurrentSendPacket = FALSE;
if (PacketToComplete != NULL) {
if (thisDev->lastPacketAtOldSpeed == PacketToComplete) {
thisDev->lastPacketAtOldSpeed=NULL;
SpeedChange=TRUE;
DBGERR(("defered set speed\n"));
SetSpeed(thisDev);
}
}
NdisDprReleaseSpinLock(&thisDev->QueueLock);
if (PacketToComplete != NULL) {
ProcessSendQueue(thisDev);
NdisMSendComplete(thisDev->ndisAdapterHandle, PacketToComplete, PacketStatus);
}
//
// send any received packets to irda.sys
//
DeliverFullBuffers(thisDev);
SyncSetInterruptMask(thisDev, TRUE);
LOG("<== MiniportHandleInterrupt");
DBGOUT(("<== MiniportHandleInterrupt"));
}
/*
*************************************************************************
* GetPnPResources
*************************************************************************
*
*
*/
BOOLEAN GetPnPResources(IrDevice *thisDev, NDIS_HANDLE WrapperConfigurationContext)
{
NDIS_STATUS stat;
BOOLEAN result = FALSE;
/*
* We should only need 2 adapter resources (2 IO and 1 interrupt),
* but I've seen devices get extra resources.
* So give the NdisMQueryAdapterResources call room for 10 resources.
*/
#define RESOURCE_LIST_BUF_SIZE (sizeof(NDIS_RESOURCE_LIST) + (10*sizeof(CM_PARTIAL_RESOURCE_DESCRIPTOR)))
UCHAR buf[RESOURCE_LIST_BUF_SIZE];
PNDIS_RESOURCE_LIST resList = (PNDIS_RESOURCE_LIST)buf;
UINT bufSize = RESOURCE_LIST_BUF_SIZE;
NdisMQueryAdapterResources(&stat, WrapperConfigurationContext, resList, &bufSize);
if (stat == NDIS_STATUS_SUCCESS){
PCM_PARTIAL_RESOURCE_DESCRIPTOR resDesc;
BOOLEAN haveIRQ = FALSE,
haveIOAddr = FALSE,
haveDma = FALSE;
UINT i;
for (resDesc = resList->PartialDescriptors, i = 0;
i < resList->Count;
resDesc++, i++){
switch (resDesc->Type){
case CmResourceTypePort:
if (thisDev->CardType==PC87108 &&
(resDesc->u.Port.Start.LowPart==0xEA ||
resDesc->u.Port.Start.LowPart==0x398 ||
resDesc->u.Port.Start.LowPart==0x150))
{
// This is an eval board and this is the config io base address
thisDev->portInfo.ConfigIoBasePhysAddr = resDesc->u.Port.Start.LowPart;
}
else if (thisDev->CardType==PC87308 &&
(resDesc->u.Port.Start.LowPart==0x2E ||
resDesc->u.Port.Start.LowPart==0x15C))
{
// This is an eval board and this is the config io base address
thisDev->portInfo.ConfigIoBasePhysAddr = resDesc->u.Port.Start.LowPart;
}
else if (thisDev->CardType==PC87338 &&
(resDesc->u.Port.Start.LowPart==0x2E ||
resDesc->u.Port.Start.LowPart==0x398 ||
resDesc->u.Port.Start.LowPart==0x15C))
{
// This is an eval board and this is the config io base address
thisDev->portInfo.ConfigIoBasePhysAddr = resDesc->u.Port.Start.LowPart;
}
else
{
if (haveIOAddr){
/*
* The *PNP0510 chip on the IBM ThinkPad 760EL
* gets an extra IO range assigned to it.
* So only pick up the first IO port range;
* ignore this subsequent one.
*/
DBGERR(("Ignoring extra PnP IO base %xh because already using %xh.",
(UINT)resDesc->u.Port.Start.LowPart,
(UINT)thisDev->portInfo.ioBasePhys));
}
else {
thisDev->portInfo.ioBasePhys = resDesc->u.Port.Start.LowPart;
haveIOAddr = TRUE;
DBGOUT(("Got UART IO addr: %xh.", thisDev->portInfo.ioBasePhys));
}
}
break;
case CmResourceTypeInterrupt:
if (haveIRQ){
DBGERR(("Ignoring second PnP IRQ %xh because already using %xh.",
(UINT)resDesc->u.Interrupt.Level, thisDev->portInfo.irq));
}
else {
thisDev->portInfo.irq = resDesc->u.Interrupt.Level;
haveIRQ = TRUE;
DBGOUT(("Got PnP IRQ: %d.", thisDev->portInfo.irq));
}
break;
case CmResourceTypeDma:
if (haveDma){
DBGERR(("Ignoring second DMA address %d because already using %d.",
(UINT)resDesc->u.Dma.Channel, (UINT)thisDev->portInfo.DMAChannel));
}
else {
ASSERT(!(resDesc->u.Dma.Channel&0xffffff00));
thisDev->portInfo.DMAChannel = (UCHAR)resDesc->u.Dma.Channel;
haveDma = TRUE;
DBGOUT(("Got DMA channel: %d.", thisDev->portInfo.DMAChannel));
}
break;
}
}
result = (haveIOAddr && haveIRQ && haveDma);
}
return result;
}
/*
*************************************************************************
* Configure
*************************************************************************
*
* Read configurable parameters out of the system registry.
*
*/
BOOLEAN Configure(
IrDevice *thisDev,
NDIS_HANDLE WrapperConfigurationContext
)
{
//
// Status of Ndis calls.
//
NDIS_STATUS Status;
//
// The handle for reading from the registry.
//
NDIS_HANDLE ConfigHandle;
//
// The value read from the registry.
//
PNDIS_CONFIGURATION_PARAMETER ReturnedValue;
//
// String names of all the parameters that will be read.
//
NDIS_STRING CardTypeStr = CARDTYPE;
NDIS_STRING Dongle_A_TypeStr = DONGLE_A_TYPE;
NDIS_STRING Dongle_B_TypeStr = DONGLE_B_TYPE;
NDIS_STRING MaxConnectRateStr = MAXCONNECTRATE;
UINT Valid_DongleTypes[] = VALID_DONGLETYPES;
DBGOUT(("Configure(0x%x)", thisDev));
NdisOpenConfiguration(&Status, &ConfigHandle, WrapperConfigurationContext);
if (Status != NDIS_STATUS_SUCCESS){
DBGERR(("NdisOpenConfiguration failed in Configure()"));
return FALSE;
}
//
// Read Ir108 Configuration I/O base Address
//
//DbgBreakPoint();
NdisReadConfiguration(
&Status,
&ReturnedValue,
ConfigHandle,
&CardTypeStr,
NdisParameterHexInteger
);
if (Status != NDIS_STATUS_SUCCESS){
DBGERR(("NdisReadConfiguration failed in accessing CardType."));
NdisCloseConfiguration(ConfigHandle);
return FALSE;
}
thisDev->CardType = (UCHAR)ReturnedValue->ParameterData.IntegerData;
if (!GetPnPResources(thisDev, WrapperConfigurationContext)){
DBGERR(("GetPnPResources failed\n"));
NdisCloseConfiguration(ConfigHandle);
return FALSE;
}
// Read Dongle type constant Number.
//
NdisReadConfiguration(&Status,
&ReturnedValue,
ConfigHandle,
&Dongle_A_TypeStr,
NdisParameterInteger);
if (Status != NDIS_STATUS_SUCCESS){
DBGERR(("NdisReadConfiguration failed in accessing DongleType (0x%x).",Status));
}
thisDev->DonglesSupported = 1;
thisDev->DongleTypes[0] =
(UCHAR)Valid_DongleTypes[(UCHAR)ReturnedValue->ParameterData.IntegerData];
// Read Dongle type constant Number.
//
NdisReadConfiguration(&Status,
&ReturnedValue,
ConfigHandle,
&Dongle_B_TypeStr,
NdisParameterInteger);
if (Status != NDIS_STATUS_SUCCESS){
DBGERR(("NdisReadConfiguration failed in accessing DongleType (0x%x).",
Status));
}
thisDev->DongleTypes[1] = (UCHAR)Valid_DongleTypes[(UCHAR)ReturnedValue->ParameterData.IntegerData];
thisDev->DonglesSupported++;
// Read MaxConnectRate.
//
NdisReadConfiguration(&Status,
&ReturnedValue,
ConfigHandle,
&MaxConnectRateStr,
NdisParameterInteger);
if (Status != NDIS_STATUS_SUCCESS){
DBGERR(("NdisReadConfiguration failed in accessing MaxConnectRate (0x%x).",Status));
thisDev->AllowedSpeedMask = ALL_IRDA_SPEEDS;
}
else
{
thisDev->AllowedSpeedMask = 0;
switch (ReturnedValue->ParameterData.IntegerData)
{
default:
case 4000000:
thisDev->AllowedSpeedMask |= NDIS_IRDA_SPEED_4M;
case 1152000:
thisDev->AllowedSpeedMask |= NDIS_IRDA_SPEED_1152K;
case 115200:
thisDev->AllowedSpeedMask |= NDIS_IRDA_SPEED_115200;
case 57600:
thisDev->AllowedSpeedMask |= NDIS_IRDA_SPEED_57600;
case 38400:
thisDev->AllowedSpeedMask |= NDIS_IRDA_SPEED_38400;
case 19200:
thisDev->AllowedSpeedMask |= NDIS_IRDA_SPEED_19200;
case 9600:
thisDev->AllowedSpeedMask |= NDIS_IRDA_SPEED_9600 | NDIS_IRDA_SPEED_2400;
break;
}
}
NdisCloseConfiguration(ConfigHandle);
DBGOUT(("Configure done: ConfigIO=0x%x UartIO=0x%x irq=%d DMA=%d",
thisDev->portInfo.ConfigIoBaseAddr,thisDev->portInfo.ioBase,
thisDev->portInfo.irq,thisDev->portInfo.DMAChannel));
return TRUE;
}
/*
*************************************************************************
* MiniportInitialize
*************************************************************************
*
*
* Initializes the network interface card.
*
*
*
*/
NDIS_STATUS MiniportInitialize ( PNDIS_STATUS OpenErrorStatus,
PUINT SelectedMediumIndex,
PNDIS_MEDIUM MediumArray,
UINT MediumArraySize,
NDIS_HANDLE NdisAdapterHandle,
NDIS_HANDLE WrapperConfigurationContext
)
{
UINT mediumIndex;
IrDevice *thisDev = NULL;
NDIS_STATUS retStat, result = NDIS_STATUS_SUCCESS;
DBGOUT(("MiniportInitialize()"));
/*
* Search the passed-in array of supported media for the IrDA medium.
*/
for (mediumIndex = 0; mediumIndex < MediumArraySize; mediumIndex++){
if (MediumArray[mediumIndex] == NdisMediumIrda){
break;
}
}
if (mediumIndex < MediumArraySize){
*SelectedMediumIndex = mediumIndex;
}
else {
/*
* Didn't see the IrDA medium
*/
DBGERR(("Didn't see the IRDA medium in MiniportInitialize"));
result = NDIS_STATUS_UNSUPPORTED_MEDIA;
return result;
}
/*
* Allocate a new device object to represent this connection.
*/
thisDev = NewDevice();
if (!thisDev){
return NDIS_STATUS_NOT_ACCEPTED;
}
thisDev->hardwareStatus = NdisHardwareStatusInitializing;
/*
* Allocate resources for this connection.
*/
if (!OpenDevice(thisDev)){
DBGERR(("OpenDevice failed"));
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
/*
* Record the NDIS wrapper's handle for this adapter, which we use
* when we call up to the wrapper.
* (This miniport's adapter handle is just thisDev, the pointer to the device object.).
*/
DBGOUT(("NDIS handle: %xh <-> IRMINI handle: %xh", NdisAdapterHandle, thisDev));
thisDev->ndisAdapterHandle = NdisAdapterHandle;
/*
* Read the system registry to get parameters like COM port number, etc.
*/
if (!Configure(thisDev, WrapperConfigurationContext)){
DBGERR(("Configure failed"));
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
/*
* This call will associate our adapter handle with the wrapper's
* adapter handle. The wrapper will then always use our handle
* when calling us. We use a pointer to the device object as the context.
*/
NdisMSetAttributesEx(NdisAdapterHandle,
(NDIS_HANDLE)thisDev,
0,
NDIS_ATTRIBUTE_DESERIALIZE,
NdisInterfaceInternal);
/*
* Tell NDIS about the range of IO space that we'll be using.
* Puma uses Chip-select mode, so the ConfigIOBase address actually
* follows the regular io, so get both in one shot.
*/
retStat = NdisMRegisterIoPortRange( (PVOID)&thisDev->portInfo.ioBase,
NdisAdapterHandle,
thisDev->portInfo.ioBasePhys,
((thisDev->CardType==PUMA108)?16:8));
if (retStat != NDIS_STATUS_SUCCESS){
DBGERR(("NdisMRegisterIoPortRange failed"));
thisDev->portInfo.ioBase=NULL;
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
if (thisDev->portInfo.ConfigIoBasePhysAddr)
{
/*
* Eval boards require a second IO range.
*
*/
retStat = NdisMRegisterIoPortRange( (PVOID)&thisDev->portInfo.ConfigIoBaseAddr,
NdisAdapterHandle,
thisDev->portInfo.ConfigIoBasePhysAddr,
2);
if (retStat != NDIS_STATUS_SUCCESS){
DBGERR(("NdisMRegisterIoPortRange config failed"));
thisDev->portInfo.ConfigIoBaseAddr=NULL;
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
}
NdisMSleep(20);
//
// Set to Non-Extended mode
//
NSC_WriteBankReg(thisDev->portInfo.ioBase, 2, 2, 0x02);
//
// set to bank 0
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+LCR_BSR_OFFSET, 03);
//
// mask all ints, before attaching interrupt
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+INT_ENABLE_REG_OFFSET, 0);
/*
* Register an interrupt with NDIS.
*/
retStat = NdisMRegisterInterrupt( (PNDIS_MINIPORT_INTERRUPT)&thisDev->interruptObj,
NdisAdapterHandle,
thisDev->portInfo.irq,
thisDev->portInfo.irq,
TRUE, // want ISR
TRUE, // MUST share interrupts
NdisInterruptLatched
);
if (retStat != NDIS_STATUS_SUCCESS){
DBGERR(("NdisMRegisterInterrupt failed"));
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
thisDev->InterruptRegistered=TRUE;
{
LONG VerifyTries=5;
while (VerifyTries > 0) {
if (VerifyHardware(thisDev)) {
break;
}
#if DBG
DbgPrint("NSCIRDA: VerifiyHardware() failed, trying again, tries left=%d\n",VerifyTries);
#endif
VerifyTries--;
}
if ( VerifyTries == 0) {
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
}
/*
* Open COMM communication channel.
* This will let the dongle driver update its capabilities from their default values.
*/
if (!DoOpen(thisDev)){
DBGERR(("DoOpen failed"));
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
/*
* Do special NSC setup
* (do this after comport resources, like read buf, have been allocated).
*/
if (!NSC_Setup(thisDev)){
DBGERR(("NSC_Setup failed"));
NSC_Shutdown(thisDev);
result = NDIS_STATUS_FAILURE;
goto _initDone;
}
_initDone:
if (result == NDIS_STATUS_SUCCESS){
/*
* Add this device object to the beginning of our global list.
*/
thisDev->hardwareStatus = NdisHardwareStatusReady;
DBGOUT(("MiniportInitialize succeeded"));
return result;
}
//
// init failed, release the resources
//
if (thisDev->InterruptRegistered) {
NdisMDeregisterInterrupt(&thisDev->interruptObj);
thisDev->InterruptRegistered=FALSE;
}
if (thisDev->portInfo.ioBase != NULL) {
NdisMDeregisterIoPortRange(
thisDev->ndisAdapterHandle,
thisDev->portInfo.ioBasePhys,
((thisDev->CardType==PUMA108)?16:8),
(PVOID)thisDev->portInfo.ioBase
);
thisDev->portInfo.ioBase=NULL;
}
if (thisDev->portInfo.ConfigIoBaseAddr != NULL) {
NdisMDeregisterIoPortRange(
thisDev->ndisAdapterHandle,
thisDev->portInfo.ConfigIoBasePhysAddr,
2,
(PVOID)thisDev->portInfo.ConfigIoBaseAddr
);
thisDev->portInfo.ConfigIoBaseAddr=NULL;
}
if (thisDev){
FreeDevice(thisDev);
}
DBGOUT(("MiniportInitialize failed"));
return result;
}
BOOLEAN
VerifyHardware(
IrDevice *thisDev
)
{
UCHAR TempValue;
LONG MilliSecondsToWait=500;
NdisMSleep(20);
//
// set to bank 0
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+LCR_BSR_OFFSET, 03);
//
// mask all ints, before attaching interrupt
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+INT_ENABLE_REG_OFFSET, 0);
NdisRawReadPortUchar(thisDev->portInfo.ioBase+INT_ENABLE_REG_OFFSET,&TempValue);
if (TempValue != 0) {
#if DBG
DbgPrint("NSCIRDA: After masking interrupts IER was not zero %x, base= %x\n",TempValue,thisDev->portInfo.ioBase);
#endif
return FALSE;
}
//
// reset the fifo's and enable the fifos
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+INT_ID_AND_FIFO_CNTRL_REG_OFFSET, 0x7);
//
// read the interrupt ident reg, to see if the fifo's enabled
//
NdisRawReadPortUchar(thisDev->portInfo.ioBase+INT_ID_AND_FIFO_CNTRL_REG_OFFSET,&TempValue);
if ((TempValue & 0xc0) != 0xc0) {
#if DBG
DbgPrint("NSCIRDA: Fifo's not enabled in iir %x, base= %x\n",TempValue,thisDev->portInfo.ioBase);
#endif
return FALSE;
}
//
// bring up DTR and RTS, turn on the out pins
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+MODEM_CONTROL_REG_OFFSET, 0xf);
thisDev->GotTestInterrupt=FALSE;
thisDev->TestingInterrupt=TRUE;
//
// unmask the transmit holding register so an interrupt will be generated
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+INT_ENABLE_REG_OFFSET, 2);
while ((thisDev->GotTestInterrupt == FALSE) && (MilliSecondsToWait > 0)) {
NdisMSleep(1000);
MilliSecondsToWait--;
}
#if DBG
if (!thisDev->GotTestInterrupt) {
NdisRawReadPortUchar(thisDev->portInfo.ioBase+INT_ID_AND_FIFO_CNTRL_REG_OFFSET,&TempValue);
DbgPrint("NSCIRDA: Did not get interrupt while initializing, ier-%x, base= %x\n",TempValue,thisDev->portInfo.ioBase);
}
#endif
//
// mask all ints again;
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+INT_ENABLE_REG_OFFSET, 0);
thisDev->TestingInterrupt=FALSE;
return thisDev->GotTestInterrupt;
}
/*
*************************************************************************
* QueueReceivePacket
*************************************************************************
*
*
*
*
*/
VOID QueueReceivePacket(IrDevice *thisDev, PUCHAR data, UINT dataLen, BOOLEAN IsFIR)
{
rcvBuffer *rcvBuf = NULL;
PLIST_ENTRY ListEntry;
/*
* Note: We cannot use a spinlock to protect the rcv buffer structures
* in an ISR. This is ok, since we used a sync-with-isr function
* the the deferred callback routine to access the rcv buffers.
*/
LOG("==> QueueReceivePacket");
DBGOUT(("==> QueueReceivePacket(0x%x, 0x%lx, 0x%x)",
thisDev, data, dataLen));
LOG("QueueReceivePacket, len: %d ", dataLen);
if (!IsFIR)
{
// This function is called inside the ISR during SIR mode.
if (IsListEmpty(&thisDev->rcvBufFree))
{
ListEntry = NULL;
}
else
{
ListEntry = RemoveHeadList(&thisDev->rcvBufFree);
}
}
else
{
ListEntry = NDISSynchronizedRemoveHeadList(&thisDev->rcvBufFree,
&thisDev->interruptObj);
}
if (ListEntry)
{
rcvBuf = CONTAINING_RECORD(ListEntry,
rcvBuffer,
listEntry);
if (IsFIR)
{
LOG_Data(thisDev, data);
}
}
if (rcvBuf){
rcvBuf->dataBuf = data;
VerifyNdisPacket(rcvBuf->packet, 0);
rcvBuf->state = STATE_FULL;
rcvBuf->dataLen = dataLen;
if (!IsFIR)
{
rcvBuf->isDmaBuf = FALSE;
InsertTailList(&thisDev->rcvBufFull,
ListEntry);
}
else
{
rcvBuf->isDmaBuf = TRUE;
LOG_InsertTailList(thisDev, &thisDev->rcvBufFull, rcvBuf);
NDISSynchronizedInsertTailList(&thisDev->rcvBufFull,
ListEntry,
&thisDev->interruptObj);
}
}
LOG("<== QueueReceivePacket");
DBGOUT(("<== QueueReceivePacket"));
}
/*
*************************************************************************
* MiniportISR
*************************************************************************
*
*
* This is the miniport's interrupt service routine (ISR).
*
*
*/
VOID MiniportISR(PBOOLEAN InterruptRecognized,
PBOOLEAN QueueMiniportHandleInterrupt,
NDIS_HANDLE MiniportAdapterContext)
{
IrDevice *thisDev = CONTEXT_TO_DEV(MiniportAdapterContext);
if (thisDev->TestingInterrupt) {
//
// we are testing to make sure the interrupt works
//
UCHAR TempValue;
//
// Read the interrupt identification register
//
NdisRawReadPortUchar(thisDev->portInfo.ioBase+INT_ID_AND_FIFO_CNTRL_REG_OFFSET,&TempValue);
//
// if the low bit is clear then an interrupt is pending
//
if ((TempValue & 1) == 0) {
//
// inform the test code that we got the interrupt
//
thisDev->GotTestInterrupt=TRUE;
thisDev->TestingInterrupt=FALSE;
//
// mask all ints again
//
NdisRawWritePortUchar(thisDev->portInfo.ioBase+INT_ENABLE_REG_OFFSET, 0);
DBGOUT(("NSCIRDA: Got test interrupt %x\n",TempValue))
*InterruptRecognized=TRUE;
*QueueMiniportHandleInterrupt=FALSE;
return;
}
//
// seems that our uart did not generate this interrupt
//
*InterruptRecognized=FALSE;
*QueueMiniportHandleInterrupt=FALSE;
return;
}
//LOG("==> MiniportISR", ++thisDev->interruptCount);
//DBGOUT(("==> MiniportISR(0x%x), interrupt #%d)", (UINT)thisDev,
// thisDev->interruptCount));
#if DBG
{
UCHAR TempVal;
//
// This code assumes that bank 0 is current, we will make sure of that
//
NdisRawReadPortUchar(thisDev->portInfo.ioBase+LCR_BSR_OFFSET, &TempVal);
ASSERT((TempVal & BKSE) == 0);
}
#endif
/*
* Service the interrupt.
*/
if (thisDev->currentSpeed > MAX_SIR_SPEED){
NSC_FIR_ISR(thisDev, InterruptRecognized,
QueueMiniportHandleInterrupt);
}
else {
COM_ISR(thisDev, InterruptRecognized,
QueueMiniportHandleInterrupt);
}
LOG("<== MiniportISR");
DBGOUT(("<== MiniportISR"));
}
/*
*************************************************************************
* MiniportReset
*************************************************************************
*
*
* MiniportReset issues a hardware reset to the network interface card.
* The miniport driver also resets its software state.
*
*
*/
NDIS_STATUS MiniportReset(PBOOLEAN AddressingReset, NDIS_HANDLE MiniportAdapterContext)
{
IrDevice *thisDev = CONTEXT_TO_DEV(MiniportAdapterContext);
NDIS_STATUS result = NDIS_STATUS_PENDING;
LIST_ENTRY TempList;
BOOLEAN SetSpeedNow=FALSE;
PNDIS_PACKET Packet;
DBGERR(("MiniportReset(0x%x)", MiniportAdapterContext));
InitializeListHead(&TempList);
NdisAcquireSpinLock(&thisDev->QueueLock);
thisDev->hardwareStatus = NdisHardwareStatusReset;
//
// un-queue all the send packets and put them on a temp list
//
while (!IsListEmpty(&thisDev->SendQueue)) {
PLIST_ENTRY ListEntry;
ListEntry=RemoveHeadList(&thisDev->SendQueue);
InsertTailList(&TempList,ListEntry);
}
//
// if there is a current send packet, then request a speed change after it completes
//
if (thisDev->CurrentPacket != NULL) {
//
// the current packet is now the last, chage speed after it is done
//
thisDev->lastPacketAtOldSpeed=thisDev->CurrentPacket;
} else {
//
// no current packet, change speed now
//
SetSpeedNow=TRUE;
}
//
// back to 9600
//
thisDev->linkSpeedInfo = &supportedBaudRateTable[BAUDRATE_9600];
if (SetSpeedNow) {
//
// there are no packets being transmitted now, switch speeds now.
// otherwise the dpc will do it when the current send completes
//
SetSpeed(thisDev);
thisDev->TransmitIsIdle=FALSE;
}
NdisReleaseSpinLock(&thisDev->QueueLock);
if (SetSpeedNow) {
//
// the transmit was idle, but we change this to get the receive going again
//
ProcessSendQueue(thisDev);
}
//
// return all of these back to the protocol
//
while (!IsListEmpty(&TempList)) {
PLIST_ENTRY ListEntry;
ListEntry=RemoveHeadList(&TempList);
Packet= CONTAINING_RECORD(
ListEntry,
NDIS_PACKET,
MiniportReserved
);
NdisMSendComplete(thisDev->ndisAdapterHandle, Packet, NDIS_STATUS_RESET_IN_PROGRESS );
}
thisDev->hardwareStatus = NdisHardwareStatusReady;
NdisMResetComplete(thisDev->ndisAdapterHandle,
NDIS_STATUS_SUCCESS,
TRUE); // Addressing reset
*AddressingReset = TRUE;
DBGOUT(("MiniportReset done."));
return NDIS_STATUS_PENDING;
}
/*
*************************************************************************
* ReturnPacketHandler
*************************************************************************
*
* When NdisMIndicateReceivePacket returns asynchronously,
* the protocol returns ownership of the packet to the miniport via this function.
*
*/
VOID ReturnPacketHandler(NDIS_HANDLE MiniportAdapterContext, PNDIS_PACKET Packet)
{
IrDevice *thisDev = CONTEXT_TO_DEV(MiniportAdapterContext);
rcvBuffer *rcvBuf;
LONG PacketsLeft;
DBGOUT(("ReturnPacketHandler(0x%x)", MiniportAdapterContext));
RegStats.ReturnPacketHandlerCalled++;
//
// MiniportReserved contains the pointer to our rcvBuffer
//
rcvBuf = *(rcvBuffer**) Packet->MiniportReserved;
VerifyNdisPacket(Packet, 1);
if (rcvBuf->state == STATE_PENDING){
PNDIS_BUFFER ndisBuf;
DBGPKT(("Reclaimed rcv packet 0x%x.", Packet));
LOG_RemoveEntryList(thisDev, rcvBuf);
NDISSynchronizedRemoveEntryList(&rcvBuf->listEntry, &thisDev->interruptObj);
LOG_PacketUnchain(thisDev, rcvBuf->packet);
NdisUnchainBufferAtFront(Packet, &ndisBuf);
if (ndisBuf){
NdisFreeBuffer(ndisBuf);
}
if (!rcvBuf->isDmaBuf)
{
NDISSynchronizedInsertTailList(&thisDev->rcvBufBuf,
RCV_BUF_TO_LIST_ENTRY(rcvBuf->dataBuf),
&thisDev->interruptObj);
// ASSERT the pointer is actually outside our FIR DMA buffer
ASSERT(rcvBuf->dataBuf < thisDev->dmaReadBuf ||
rcvBuf->dataBuf >= thisDev->dmaReadBuf+RCV_DMA_SIZE);
}
rcvBuf->dataBuf = NULL;
rcvBuf->state = STATE_FREE;
VerifyNdisPacket(rcvBuf->packet, 0);
NDISSynchronizedInsertHeadList(&thisDev->rcvBufFree,
&rcvBuf->listEntry,
&thisDev->interruptObj);
}
else {
LOG("Error: Packet in ReturnPacketHandler was not PENDING");
DBGERR(("Packet in ReturnPacketHandler was not PENDING."));
}
NdisAcquireSpinLock(&thisDev->QueueLock);
PacketsLeft=NdisInterlockedDecrement(&thisDev->PacketsSentToProtocol);
if (thisDev->Halting && (PacketsLeft == 0)) {
NdisSetEvent(&thisDev->ReceiveStopped);
}
NdisReleaseSpinLock(&thisDev->QueueLock);
VerifyNdisPacket(rcvBuf->packet, 1);
}
VOID
GivePacketToSirISR(
IrDevice *thisDev
)
{
thisDev->portInfo.writeComBufferPos = 0;
thisDev->portInfo.SirWritePending = TRUE;
thisDev->nowReceiving = FALSE;
SetCOMPort(thisDev->portInfo.ioBase, INT_ENABLE_REG_OFFSET, XMIT_MODE_INTS_ENABLE);
}
VOID
SendCurrentPacket(
IrDevice *thisDev
)
{
BOOLEAN Result;
PNDIS_PACKET FailedPacket=NULL;
NdisAcquireSpinLock(&thisDev->QueueLock);
thisDev->TransmitIsIdle=FALSE;
if (thisDev->CurrentPacket == thisDev->lastPacketAtOldSpeed){
thisDev->setSpeedAfterCurrentSendPacket = TRUE;
}
if (thisDev->currentSpeed > MAX_SIR_SPEED) {
//
// send via FIR
//
if (thisDev->FirReceiveDmaActive) {
thisDev->FirReceiveDmaActive=FALSE;
//
// receive dma is running, stop it
//
CompleteDmaTransferFromDevice(
&thisDev->DmaUtil
);
}
thisDev->HangChk=0;
thisDev->FirTransmitPending = TRUE;
//
// Use DMA swap bit to switch to DMA to Transmit.
//
SyncWriteBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 2, 2, 0x0B);
//
// Switch on the DMA interrupt to decide when
// transmission is complete.
//
thisDev->FirIntMask = 0x14;
SyncSetInterruptMask(thisDev, TRUE);
//
// Kick off the first transmit.
//
NdisToFirPacket(
thisDev->CurrentPacket,
(UCHAR *) thisDev->TransmitDmaBuffer,
MAX_IRDA_DATA_SIZE,
&thisDev->TransmitDmaLength
);
LOG_FIR("Sending packet %d",thisDev->TransmitDmaLength);
DEBUGFIR(DBG_PKT, ("NSC: Sending packet\n"));
DBGPRINTBUF(thisDev->TransmitDmaBuffer,thisDev->TransmitDmaLength);
{
UCHAR LsrValue;
//
// make sure the transmitter is empty before starting to send this frame
//
LsrValue=SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 0, LSR_OFFSET);
if ((LsrValue & (LSR_TXRDY | LSR_TXEMP)) != (LSR_TXRDY | LSR_TXEMP)) {
ULONG LoopCount=0;
while (((LsrValue & (LSR_TXRDY | LSR_TXEMP)) != (LSR_TXRDY | LSR_TXEMP)) && (LoopCount < 16)) {
LsrValue=SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 0, LSR_OFFSET);
LoopCount++;
}
LOG_ERROR("SendCurrentPacket: Looped %d times waiting for tx empty",LoopCount);
}
}
/* Setup Transmit DMA. */
StartDmaTransferToDevice(
&thisDev->DmaUtil,
thisDev->xmitDmaBuffer,
0,
thisDev->TransmitDmaLength
);
#if 0
{
ULONG CurrentDMACount;
CurrentDMACount = NdisMReadDmaCounter(thisDev->DmaHandle);
LOG("SendCurrentPacket: dma count after start %d",CurrentDMACount);
}
#endif
SyncSetInterruptMask(thisDev, TRUE);
} else {
//
// SIR mode transfer
//
/*
* See if this was the last packet before we need to change
* speed.
*/
/*
* Send one packet to the COMM port.
*/
DBGPKT(("Sending packet 0x%x (0x%x).", thisDev->packetsSent++, thisDev->CurrentPacket));
/*
* Convert the NDIS packet to an IRDA packet.
*/
Result = NdisToIrPacket(
thisDev->CurrentPacket,
(UCHAR *)thisDev->portInfo.writeComBuffer,
MAX_IRDA_DATA_SIZE,
&thisDev->portInfo.writeComBufferLen
);
if (Result){
LOG_SIR("Sending packet %d",thisDev->portInfo.writeComBufferLen);
NdisMSynchronizeWithInterrupt(
&thisDev->interruptObj,
GivePacketToSirISR,
thisDev
);
} else {
ASSERT(0);
FailedPacket=thisDev->CurrentPacket;
thisDev->CurrentPacket=NULL;
}
}
NdisReleaseSpinLock(&thisDev->QueueLock);
if (FailedPacket != NULL) {
NdisMSendComplete(thisDev->ndisAdapterHandle, FailedPacket, NDIS_STATUS_FAILURE );
ProcessSendQueue(thisDev);
}
return;
}
VOID
DelayedWrite(
IN PVOID SystemSpecific1,
IN PVOID FunctionContext,
IN PVOID SystemSpecific2,
IN PVOID SystemSpecific3
)
{
IrDevice *thisDev = FunctionContext;
#if DBG
ASSERT(thisDev->WaitingForTurnAroundTimer);
thisDev->WaitingForTurnAroundTimer=FALSE;
#endif
LOG("Turn around timer expired");
SendCurrentPacket(thisDev);
}
VOID
ProcessSendQueue(
IrDevice *thisDev
)
{
PNDIS_PACKET Packet=NULL;
PLIST_ENTRY ListEntry;
NdisAcquireSpinLock(&thisDev->QueueLock);
if (thisDev->CurrentPacket == NULL) {
//
// not currently processing a send
//
if (!IsListEmpty(&thisDev->SendQueue)) {
//
// we have some queue packets to process
//
ListEntry=RemoveHeadList(&thisDev->SendQueue);
Packet= CONTAINING_RECORD(
ListEntry,
NDIS_PACKET,
MiniportReserved
);
thisDev->CurrentPacket=Packet;
NdisReleaseSpinLock(&thisDev->QueueLock);
{
PNDIS_IRDA_PACKET_INFO packetInfo;
/*
* Enforce the minimum turnaround time that must transpire
* after the last receive.
*/
packetInfo = GetPacketInfo(Packet);
//
// see if this packet is requesting a turnaround time or not
//
if (packetInfo->MinTurnAroundTime > 0) {
//
// Since we are using the timer to determine when the receive has ended,
// we must have waited atleast the timer timeout period before we indicated
// the packet to the protocol. Therefore, if that timeout was greater than
// the turn around time then we don't need to wait.
//
// this of course assumes that the protocol is not going to start sending
// in the middle of a receive. If it is, then the other station is not going to
// see the data anyway, so it does not matter much
//
// this saves us from waiting the 10ms or so for the time out since the OS timer
// resoltion is around 10ms.
//
// if the transfer ended because the DMA buffer filled up, then we will force a turnaround
//
// we don't do this SIR speeds
//
if ((packetInfo->MinTurnAroundTime > RECEIVE_TIMEOUT)
||
thisDev->ForceTurnAroundTimeout
||
(thisDev->currentSpeed <= MAX_SIR_SPEED) ) {
UINT usecToWait = packetInfo->MinTurnAroundTime;
UINT msecToWait;
msecToWait = (usecToWait<1000) ? 1 : (usecToWait+500)/1000;
#if DBG
thisDev->WaitingForTurnAroundTimer=TRUE;
#endif
NdisSetTimer(&thisDev->TurnaroundTimer, msecToWait);
thisDev->ForceTurnAroundTimeout=FALSE;
return;
}
}
}
SendCurrentPacket(thisDev);
NdisAcquireSpinLock(&thisDev->QueueLock);
}
}
if ((thisDev->CurrentPacket == NULL) && IsListEmpty(&thisDev->SendQueue)) {
//
// not currently processing a send
//
if (!thisDev->TransmitIsIdle) {
//
// We were not idle before
//
thisDev->TransmitIsIdle=TRUE;
if (thisDev->Halting) {
NdisSetEvent(&thisDev->SendStoppedOnHalt);
}
//
// restart receive
//
if (thisDev->currentSpeed > MAX_SIR_SPEED) {
//
// Start receive
//
thisDev->FirIntMask = 0x04;
SetupRecv(thisDev);
SyncSetInterruptMask(thisDev, TRUE);
} else {
//
// For SIR, the ISR switches back to receive for us
//
}
}
}
NdisReleaseSpinLock(&thisDev->QueueLock);
return;
}
/*
*************************************************************************
* SendPacketsHandler
*************************************************************************
*
* Send an array of packets simultaneously.
*
*/
VOID SendPacketsHandler(NDIS_HANDLE MiniportAdapterContext,
PPNDIS_PACKET PacketArray, UINT NumberofPackets)
{
UINT i;
IrDevice *thisDev = CONTEXT_TO_DEV(MiniportAdapterContext);
DEBUGMSG(DBG_TRACE_TX, ("M"));
LOG("==> SendPacketsHandler");
DBGOUT(("==> SendPacketsHandler(0x%x)", MiniportAdapterContext));
LOG("Number of transmit Burst %d ", NumberofPackets);
ASSERT(!thisDev->Halting);
//
// NDIS gives us the PacketArray, but it is not ours to keep, so we have to take
// the packets out and store them elsewhere.
//
NdisAcquireSpinLock(&thisDev->QueueLock);
//
// all packets get queued
//
for (i = 0; i < NumberofPackets; i++) {
if (thisDev->Halting) {
//
// ndis should not send us more packets after calling the halt rountine.
// just make sure here
//
NdisReleaseSpinLock(&thisDev->QueueLock);
NdisMSendComplete(thisDev->ndisAdapterHandle, PacketArray[i], NDIS_STATUS_FAILURE );
NdisAcquireSpinLock(&thisDev->QueueLock);
} else {
InsertTailList(
&thisDev->SendQueue,
(PLIST_ENTRY)PacketArray[i]->MiniportReserved
);
}
}
NdisReleaseSpinLock(&thisDev->QueueLock);
ProcessSendQueue(thisDev);
LOG("<== SendPacketsHandler");
DBGOUT(("<== SendPacketsHandler"));
return ;
}
VOID
NscUloadHandler(
PDRIVER_OBJECT DriverObject
)
{
DBGOUT(("Unloading"));
WPP_CLEANUP(DriverObject);
return;
}
BOOLEAN AbortLoad = FALSE;
/*
*************************************************************************
* DriverEntry
*************************************************************************
*
* Only include if IRMINI is a stand-alone driver.
*
*/
NTSTATUS DriverEntry(PDRIVER_OBJECT DriverObject, PUNICODE_STRING RegistryPath);
#pragma NDIS_INIT_FUNCTION(DriverEntry)
NTSTATUS DriverEntry(PDRIVER_OBJECT DriverObject, PUNICODE_STRING RegistryPath)
{
NTSTATUS result = STATUS_SUCCESS, stat;
NDIS_HANDLE wrapperHandle;
NDIS50_MINIPORT_CHARACTERISTICS info;
WPP_INIT_TRACING(DriverObject,RegistryPath);
LOG("==> DriverEntry");
DBGOUT(("==> DriverEntry"));
//DbgBreakPoint();
if (AbortLoad)
{
return STATUS_CANCELLED;
}
NdisZeroMemory(&info, sizeof(info));
NdisMInitializeWrapper( (PNDIS_HANDLE)&wrapperHandle,
DriverObject,
RegistryPath,
NULL
);
DBGOUT(("Wrapper handle is %xh", wrapperHandle));
info.MajorNdisVersion = (UCHAR)NDIS_MAJOR_VERSION;
info.MinorNdisVersion = (UCHAR)NDIS_MINOR_VERSION;
//info.Flags = 0;
info.CheckForHangHandler = MiniportCheckForHang;
info.HaltHandler = MiniportHalt;
info.InitializeHandler = MiniportInitialize;
info.QueryInformationHandler = MiniportQueryInformation;
info.ReconfigureHandler = NULL;
info.ResetHandler = MiniportReset;
info.SendHandler = NULL; //MiniportSend;
info.SetInformationHandler = MiniportSetInformation;
info.TransferDataHandler = NULL;
info.HandleInterruptHandler = MiniportHandleInterrupt;
info.ISRHandler = MiniportISR;
info.DisableInterruptHandler = NULL;
info.EnableInterruptHandler = NULL; //MiniportEnableInterrupt;
/*
* New NDIS 4.0 fields
*/
info.ReturnPacketHandler = ReturnPacketHandler;
info.SendPacketsHandler = SendPacketsHandler;
info.AllocateCompleteHandler = NULL;
stat = NdisMRegisterMiniport( wrapperHandle,
(PNDIS_MINIPORT_CHARACTERISTICS)&info,
sizeof(info));
if (stat != NDIS_STATUS_SUCCESS){
DBGERR(("NdisMRegisterMiniport failed in DriverEntry"));
result = STATUS_UNSUCCESSFUL;
goto _entryDone;
}
NdisMRegisterUnloadHandler(
wrapperHandle,
NscUloadHandler
);
_entryDone:
DBGOUT(("DriverEntry %s", (PUCHAR)((result == NDIS_STATUS_SUCCESS) ? "succeeded" : "failed")));
LOG("<== DriverEntry");
DBGOUT(("<== DriverEntry"));
return result;
}
PNDIS_IRDA_PACKET_INFO GetPacketInfo(PNDIS_PACKET packet)
{
MEDIA_SPECIFIC_INFORMATION *mediaInfo;
UINT size;
NDIS_GET_PACKET_MEDIA_SPECIFIC_INFO(packet, &mediaInfo, &size);
return (PNDIS_IRDA_PACKET_INFO)mediaInfo->ClassInformation;
}
/* Setup for Recv */
// This function is always called at MIR & FIR speeds
void SetupRecv(IrDevice *thisDev)
{
NDIS_STATUS stat;
UINT FifoClear = 8;
UCHAR FifoStatus;
LOG("SetupRecv - Begin Rcv Setup");
FindLargestSpace(thisDev, &thisDev->rcvDmaOffset, &thisDev->rcvDmaSize);
// Drain the status fifo of any pending packets
//
FifoStatus=SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 5, FRM_ST);
while ((FifoStatus & 0x80) && FifoClear--) {
ULONG Size;
Size = SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 5, RFRL_L);
Size |= SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 5, RFRL_H);
LOG_Discard(thisDev, Size);
LOG_ERROR("SetupRecv: fifo %02x, %d",FifoStatus,Size);
FifoStatus=SyncReadBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 5, FRM_ST);
thisDev->DiscardNextPacketSet = TRUE;
}
thisDev->rcvPktOffset = thisDev->rcvDmaOffset;
//
// Use DMA swap bit to switch to DMA to Receive.
//
SyncWriteBankReg(&thisDev->interruptObj,thisDev->portInfo.ioBase, 2, 2, 0x03);
LOG_Dma(thisDev);
thisDev->FirReceiveDmaActive=TRUE;
if (thisDev->rcvDmaSize < 8192) {
LOG("SetupRecv small dma %d\n",(ULONG)thisDev->rcvDmaSize);
}
thisDev->LastReadDMACount = thisDev->rcvDmaSize;
stat=StartDmaTransferFromDevice(
&thisDev->DmaUtil,
thisDev->rcvDmaBuffer,
(ULONG)thisDev->rcvDmaOffset,
(ULONG)thisDev->rcvDmaSize
);
LOG("SetupRecv - Begin Rcv Setup: offset=%d, size =%d",(ULONG)thisDev->rcvDmaOffset,(ULONG)thisDev->rcvDmaSize);
if (stat != NDIS_STATUS_SUCCESS) {
thisDev->FirReceiveDmaActive=FALSE;
LOG("Error: NdisMSetupDmaTransfer failed in SetupRecv %x", stat);
DBGERR(("NdisMSetupDmaTransfer failed (%xh) in SetupRecv", (UINT)stat));
ASSERT(0);
}
LOG("SetupRecv - End Rcv Setup");
}