/************************************************************************************************************************** * IRCOMMON.H SigmaTel STIR4200 common USB/IR definitions ************************************************************************************************************************** * (C) Unpublished Copyright of Sigmatel, Inc. All Rights Reserved. * * * Created: 04/06/2000 * Version 0.9 * Edited: 04/24/2000 * Version 0.91 * Edited: 04/27/2000 * Version 0.92 * Edited: 05/03/2000 * Version 0.93 * Edited: 05/12/2000 * Version 0.94 * Edited: 05/19/2000 * Version 0.95 * Edited: 07/27/2000 * Version 1.01 * Edited: 09/16/2000 * Version 1.03 * Edited: 09/25/2000 * Version 1.10 * Edited: 11/09/2000 * Version 1.12 * Edited: 02/20/2001 * Version 1.15 * **************************************************************************************************************************/ #ifndef _IRCOM_H #define _IRCOM_H #include "stir4200.h" // // This is for use by check-for-hang handler and is just a reasonable guess; // Total # of USBD control errors, read aerrors and write errors; // Used by check-for-hang handler to decide if we need a reset // #define IRUSB_100ns_PER_ms 10000 #define IRUSB_100ns_PER_us 10 #define IRUSB_ms_PER_SEC 1000 #define IRUSB_100ns_PER_SEC ( IRUSB_100ns_PER_ms * IRUSB_ms_PER_SEC ) #define MAX_QUERY_TIME_100ns ( 8 * IRUSB_100ns_PER_SEC ) //8 sec #define MAX_SET_TIME_100ns MAX_QUERY_TIME_100ns #define MAX_SEND_TIME_100ns ( 20 * IRUSB_100ns_PER_SEC ) //20 sec #define MAX_TURNAROUND_usec 10000 #define DEFAULT_TURNAROUND_usec 1000 // // Customer data area size. // Big enough for 2 byte header (7e7e) + one byte count + 255 bytes data. // Header bytes are not sent back to app. // #define STIR4200_CUST_DATA_SIZE (2+256) #define MIN(a,b) (((a) <= (b)) ? (a) : (b)) #define MAX(a,b) (((a) >= (b)) ? (a) : (b)) // // A receive buffer is either FREE (not holding anything) FULL // (holding undelivered data) or PENDING (holding data delivered // asynchronously) // typedef enum { RCV_STATE_FREE, RCV_STATE_FULL, RCV_STATE_PENDING } RCV_BUFFER_STATE, FIFO_BUFFER_STATE; // // Structure to keep track of receive packets and buffers to indicate // receive data to the protocol. // typedef struct { PVOID pPacket; UINT DataLen; PUCHAR pDataBuf; PVOID pThisDev; ULONG fInRcvDpc; RCV_BUFFER_STATE BufferState; #if defined(DIAGS) LIST_ENTRY ListEntry; // This will be used to do the diags queueing #endif #if defined(WORKAROUND_MISSING_C1) BOOLEAN MissingC1Detected; BOOLEAN MissingC1Possible; #endif } RCV_BUFFER, *PRCV_BUFFER; // // Structure to read data from the FIFO // typedef struct { UINT DataLen; PUCHAR pDataBuf; PVOID pThisDev; PVOID pIrp; PURB pUrb; // urb allocated by irp send routine, deallocated UINT UrbLen; // by irp completion handler FIFO_BUFFER_STATE BufferState; } FIFO_BUFFER, *PFIFO_BUFFER; // // All different sizes for data // #define IRDA_ADDRESS_FIELD_SIZE 1 #define IRDA_CONTROL_FIELD_SIZE 1 #define IRDA_A_C_TOTAL_SIZE ( IRDA_ADDRESS_FIELD_SIZE + IRDA_CONTROL_FIELD_SIZE ) #define USB_IRDA_TOTAL_NON_DATA_SIZE ( IRDA_ADDRESS_FIELD_SIZE + IRDA_CONTROL_FIELD_SIZE ) #define IRDA_MAX_DATAONLY_SIZE 2048 #define MAX_TOTAL_SIZE_WITH_ALL_HEADERS ( IRDA_MAX_DATAONLY_SIZE + USB_IRDA_TOTAL_NON_DATA_SIZE ) #define MAX_NUM_EXTRA_BOFS 48 // Fix for MS Security Bug #533267 #define MAX_POSSIBLE_IR_PACKET_SIZE_FOR_DATA(dataLen) ( \ (dataLen) * 2 + (MAX_NUM_EXTRA_BOFS + 1) * \ SLOW_IR_BOF_SIZE + IRDA_ADDRESS_FIELD_SIZE + IRDA_CONTROL_FIELD_SIZE + \ (2 * FAST_IR_FCS_SIZE) + (2 * SLOW_IR_FCS_SIZE) + SLOW_IR_EOF_SIZE) + \ sizeof(STIR4200_FRAME_HEADER) // // Note that the receive size needs to be incremented to account for // the way the decoding can use one more byte // #define MAX_RCV_DATA_SIZE (MAX_TOTAL_SIZE_WITH_ALL_HEADERS + FAST_IR_FCS_SIZE + 1) #define MAX_IRDA_DATA_SIZE MAX_POSSIBLE_IR_PACKET_SIZE_FOR_DATA(IRDA_MAX_DATAONLY_SIZE) // // Possible speeds // typedef enum _BAUD_RATE { // // Slow IR // BAUDRATE_2400 = 0, BAUDRATE_9600, BAUDRATE_19200, BAUDRATE_38400, BAUDRATE_57600, BAUDRATE_115200, // // Medium IR // #if !defined(DWORKAROUND_BROKEN_MIR) BAUDRATE_576000, BAUDRATE_1152000, #endif // // Fast IR // BAUDRATE_4000000, // // must be last // NUM_BAUDRATES } BAUD_RATE; typedef enum _IR_MODE { IR_MODE_SIR = 0, IR_MODE_MIR, IR_MODE_FIR, NUM_IR_MODES } IR_MODE; // // Speeds // #define SPEED_2400 2400 #define SPEED_9600 9600 #define SPEED_19200 19200 #define SPEED_38400 38400 #define SPEED_57600 57600 #define SPEED_115200 115200 #define SPEED_576000 576000 #define SPEED_1152000 1152000 #define SPEED_4000000 4000000 #define DEFAULT_BAUD_RATE SPEED_9600 #define MAX_SIR_SPEED SPEED_115200 #define MAX_MIR_SPEED SPEED_1152000 // // Sizes of IrLAP frame fields: // Beginning Of Frame (BOF) // End Of Frame (EOF) // Address // Control // #define SLOW_IR_BOF_TYPE UCHAR #define SLOW_IR_BOF_SIZE sizeof(SLOW_IR_BOF_TYPE) #define SLOW_IR_EOF_TYPE UCHAR #define SLOW_IR_EOF_SIZE sizeof(SLOW_IR_EOF_TYPE) #define SLOW_IR_FCS_TYPE USHORT #define SLOW_IR_FCS_SIZE sizeof(SLOW_IR_FCS_TYPE) #define SLOW_IR_BOF 0xC0 #define SLOW_IR_EOF 0xC1 #define SLOW_IR_ESC 0x7D #define SLOW_IR_ESC_COMP 0x20 #define SLOW_IR_EXTRA_BOF_TYPE UCHAR #define SLOW_IR_EXTRA_BOF_SIZE sizeof(SLOW_IR_EXTRA_BOF_TYPE) #define SLOW_IR_EXTRA_BOF 0xC0 #define MEDIUM_IR_BOF 0x7E #define MEDIUM_IR_EOF 0x7E #define MEDIUM_IR_FCS_TYPE USHORT #define MEDIUM_IR_FCS_SIZE sizeof(MEDIUM_IR_FCS_TYPE) #define FAST_IR_FCS_TYPE ULONG #define FAST_IR_FCS_SIZE sizeof(FAST_IR_FCS_TYPE) #define FAST_IR_EOF_TYPE ULONG #define FAST_IR_EOF_SIZE sizeof(FAST_IR_EOF_TYPE) // // Definition for speed masks // #define NDIS_IRDA_SPEED_MASK_2400 0x001 // SLOW IR ... #define NDIS_IRDA_SPEED_MASK_9600 0x003 #define NDIS_IRDA_SPEED_MASK_19200 0x007 #define NDIS_IRDA_SPEED_MASK_38400 0x00f #define NDIS_IRDA_SPEED_MASK_57600 0x01f #define NDIS_IRDA_SPEED_MASK_115200 0x03f #define NDIS_IRDA_SPEED_MASK_576K 0x07f // MEDIUM IR ... #define NDIS_IRDA_SPEED_MASK_1152K 0x0ff #define NDIS_IRDA_SPEED_MASK_4M 0x1ff // FAST IR #define GOOD_FCS ((USHORT) ~0xf0b8) #define FIR_GOOD_FCS ((ULONG) ~0xdebb20e3) typedef struct { BAUD_RATE TableIndex; UINT BitsPerSec; IR_MODE IrMode; UINT NdisCode; // bitmask element as used by ndis and in class-specific descriptor UCHAR Stir4200Divisor; } BAUDRATE_INFO; // // Struct to hold the IR USB dongle's USB Class-Specific Descriptor as per // "Universal Serial Bus IrDA Bridge Device Definition" doc, section 7.2 // This is the struct returned by USBD as the result of a request with an urb // of type _URB_CONTROL_VENDOR_OR_CLASS_REQUEST, function URB_FUNCTION_CLASS_DEVICE // // Enable 1-byte alignment in the below struct #pragma pack (push,1) typedef struct _IRUSB_CLASS_SPECIFIC_DESCRIPTOR { BOOLEAN ClassConfigured; UCHAR bmDataSize; // max bytes allowed in any frame as per IrLAP spec, where: #define BM_DATA_SIZE_2048 (1 << 5) #define BM_DATA_SIZE_1024 (1 << 4) #define BM_DATA_SIZE_512 (1 << 3) #define BM_DATA_SIZE_256 (1 << 2) #define BM_DATA_SIZE_128 (1 << 1) #define BM_DATA_SIZE_64 (1 << 0) UCHAR bmWindowSize; // max un-acked frames that can be received // before an ack is sent, where: #define BM_WINDOW_SIZE_7 (1 << 6) #define BM_WINDOW_SIZE_6 (1 << 5) #define BM_WINDOW_SIZE_5 (1 << 4) #define BM_WINDOW_SIZE_4 (1 << 3) #define BM_WINDOW_SIZE_3 (1 << 2) #define BM_WINDOW_SIZE_2 (1 << 1) #define BM_WINDOW_SIZE_1 (1 << 0) UCHAR bmMinTurnaroundTime; // min millisecs required for recovery between // end of last xmission and can receive again, where: #define BM_TURNAROUND_TIME_0ms (1 << 7) // 0 ms #define BM_TURNAROUND_TIME_0p01ms (1 << 6) // 0.01 ms #define BM_TURNAROUND_TIME_0p05ms (1 << 5) // 0.05 ms #define BM_TURNAROUND_TIME_0p1ms (1 << 4) // 0.1 ms #define BM_TURNAROUND_TIME_0p5ms (1 << 3) // 0.5 ms #define BM_TURNAROUND_TIME_1ms (1 << 2) // 1 ms #define BM_TURNAROUND_TIME_5ms (1 << 1) // 5 ms #define BM_TURNAROUND_TIME_10ms (1 << 0) // 10 ms USHORT wBaudRate; // // ir speed masks as used both by NDIS and as formatted in USB class-specfic descriptor // #define NDIS_IRDA_SPEED_2400 (1 << 0) // SLOW IR ... #define NDIS_IRDA_SPEED_9600 (1 << 1) #define NDIS_IRDA_SPEED_19200 (1 << 2) #define NDIS_IRDA_SPEED_38400 (1 << 3) #define NDIS_IRDA_SPEED_57600 (1 << 4) #define NDIS_IRDA_SPEED_115200 (1 << 5) #define NDIS_IRDA_SPEED_576K (1 << 6) // MEDIUM IR ... #define NDIS_IRDA_SPEED_1152K (1 << 7) #define NDIS_IRDA_SPEED_4M (1 << 8) // FAST IR UCHAR bmExtraBofs; // #BOFS required at 115200; 0 if slow speeds <=115200 not supported #define BM_EXTRA_BOFS_0 (1 << 7) #define BM_EXTRA_BOFS_1 (1 << 6) #define BM_EXTRA_BOFS_2 (1 << 5) #define BM_EXTRA_BOFS_3 (1 << 4) #define BM_EXTRA_BOFS_6 (1 << 3) #define BM_EXTRA_BOFS_12 (1 << 2) #define BM_EXTRA_BOFS_24 (1 << 1) #define BM_EXTRA_BOFS_48 (1 << 0) } IRUSB_CLASS_SPECIFIC_DESCRIPTOR, *PIRUSB_CLASS_SPECIFIC_DESCRIPTOR; #pragma pack (pop) //disable 1-byte alignment typedef struct _DONGLE_CAPABILITIES { // // Time (in microseconds) that must transpire between // a transmit and the next receive. // LONG turnAroundTime_usec; // gotten from class-specific descriptor // // Max un-acked frames that can be received // before an ack is sent // UINT windowSize; // gotten from class-specific descriptor // // #BOFS required at 115200; 0 if slow speeds <=115200 are not supported // UINT extraBOFS; // gotten from class-specific descriptor // // max bytes allowed in any frame as per IrLAP spec // UINT dataSize; // gotten from class-specific descriptor } DONGLE_CAPABILITIES, *PDONGLE_CAPABILITIES; // // Enum of context types for SendPacket // typedef enum _CONTEXT_TYPE { CONTEXT_NDIS_PACKET, CONTEXT_SET_SPEED, CONTEXT_READ_WRITE_REGISTER, CONTEXT_DIAGS_ENABLE, CONTEXT_DIAGS_DISABLE, CONTEXT_DIAGS_READ_REGISTERS, CONTEXT_DIAGS_WRITE_REGISTER, CONTEXT_DIAGS_BULK_OUT, CONTEXT_DIAGS_BULK_IN, CONTEXT_DIAGS_SEND } CONTEXT_TYPE; typedef NTSTATUS (*WORK_PROC)(struct _IR_WORK_ITEM *); typedef struct _IR_WORK_ITEM { PVOID pIrDevice; WORK_PROC Callback; PUCHAR pInfoBuf; ULONG InfoBufLen; ULONG fInUse; // declared as ulong for use with interlockedexchange } IR_WORK_ITEM, *PIR_WORK_ITEM; // // Transceiver type definition // typedef enum _TRANSCEIVER_TYPE { TRANSCEIVER_4012 = 0, TRANSCEIVER_4000, TRANSCEIVER_VISHAY, TRANSCEIVER_VISHAY_6102F, TRANSCEIVER_INFINEON, TRANSCEIVER_HP, TRANSCEIVER_CUSTOM } TRANSCEIVER_TYPE; // // Receive mode definition // typedef enum _RXMODE { RXMODE_SLOW = 0, RXMODE_SLOWFAST, RXMODE_FAST } RXMODE; // // Chip revision definition // typedef enum _CHIP_REVISION { CHIP_REVISION_6 = 5, CHIP_REVISION_7, CHIP_REVISION_8 } CHIP_REVISION; typedef struct _IR_DEVICE { // // Keep track of various device objects. // PDEVICE_OBJECT pUsbDevObj; //'Next Device Object' PDEVICE_OBJECT pPhysDevObj; // Physical Device Object // // This is the handle that the NDIS wrapper associates with a connection. // (The handle that the miniport driver associates with the connection // is just an index into the devStates array). // HANDLE hNdisAdapter; // // The dongle interface allows us to check the tranceiver type once // and then set up the interface to allow us to init, set speed, // and deinit the dongle. // // We also want the dongle capabilities. // DONGLE_CAPABILITIES dongleCaps; // // Type of transceiver installed // TRANSCEIVER_TYPE TransceiverType; // // Receive mode // RXMODE ReceiveMode; // // Revision of the installed 4200 // CHIP_REVISION ChipRevision; // // Current speed setting, in bits/sec. // Note: This is updated when we ACTUALLY change the speed, // not when we get the request to change speed via // irusbSetInformation. // // // When speed is changed, we have to clear the send queue before // setting the new speed on the hardware. // These vars let us remember to do it. // UINT currentSpeed; // // Current link speed information. This also will maintain the // chosen speed if the protocol requests a speed change. // BAUDRATE_INFO *linkSpeedInfo; // // Maintain statistical debug info. // ULONG packetsReceived; ULONG packetsReceivedDropped; ULONG packetsReceivedOverflow; ULONG packetsReceivedChecksum; ULONG packetsReceivedRunt; ULONG packetsReceivedNoBuffer; ULONG packetsSent; ULONG packetsSentDropped; ULONG packetsSentRejected; ULONG packetsSentInvalid; #if DBG ULONG packetsHeldByProtocol; ULONG MaxPacketsHeldByProtocol; ULONG TotalBytesReceived; ULONG TotalBytesSent; ULONG NumYesQueryMediaBusyOids; ULONG NumNoQueryMediaBusyOids; ULONG NumSetMediaBusyOids; ULONG NumMediaBusyIndications; ULONG NumPacketsSentRequiringTurnaroundTime; ULONG NumPacketsSentNotRequiringTurnaroundTime; #endif // // used by check hang handler to track Query, Set, and Send times // LARGE_INTEGER LastQueryTime; LARGE_INTEGER LastSetTime; BOOLEAN fSetpending; BOOLEAN fQuerypending; // // Set when device has been started; use for safe cleanup after failed initialization // BOOLEAN fDeviceStarted; // // Indicates that we have received an OID_GEN_CURRENT_PACKET_FILTER // indication from the protocol. We can deliver received packets to the // protocol. // BOOLEAN fGotFilterIndication; // // NDIS calls most of the MiniportXxx function with IRQL DISPATCH_LEVEL. // There are a number of instances where the ir device must send // requests to the device which may be synchronous and // we can't block in DISPATCH_LEVEL. Therefore, we set up a thread to deal // with request which require PASSIVE_LEVEL. An event is used to signal // the thread that work is required. // HANDLE hPassiveThread; BOOLEAN fKillPassiveLevelThread; KEVENT EventPassiveThread; /* According to W2000 ddk doc: The IrDA protocol driver sets this OID to zero to request the miniport to start monitoring for a media busy condition. The IrDA protocol can then query this OID to determine whether the media is busy. If the media is not busy, the miniport returns a zero for this OID when queried. If the media is busy,that is, if the miniport has detected some traffic since the IrDA protocol driver last set OID_IRDA_MEDIA_BUSY to zero the miniport returns a non-zero value for this OID when queried. On detecting the media busy condition. the miniport must also call NdisMIndicateStatus to indicate NDIS_STATUS_MEDIA_BUSY. When the media is busy, the IrDA protocol driver will not send packets to the miniport for transmission. After the miniport has detected a busy state, it does not have to monitor for a media busy condition until the IrDA protocol driver again sets OID_IRDA_MEDIA_BUSY to zero. According to USB IrDA Bridge Device Definition Doc sec 5.4.1.2: The bmStatus field indicators shall be set by the Device as follows: Media_Busy · Media_Busy shall indicate zero (0) if the Device: . has not received a Check Media Busy class-specific request . has detected no traffic on the infrared media since receiving a Check Media Busy . class-specific request . Has returned a header with Media_Busy set to one (1) since receiving a Check Media Busy class-specific request. · Media_Busy shall indicate one (1) if the Device has detected traffic on the infrared media since receiving a Check Media Busy class-specific request. Note that Media_Busy shall indicate one (1) in exactly one header following receipt of each Check Media Busy class-specific request. According to USB IrDA Bridge Device Definition Doc sec 6.2.2: Check Media Busy This class-specific request instructs the Device to look for a media busy condition. If infrared traffic of any kind is detected by this Device, the Device shall set the Media_Busy field in the bmStatus field in the next Data-In packet header sent to the host. In the case where a Check Media Busy command has been received, a media busy condition detected, and no IrLAP frame traffic is ready to transmit to the host, the Device shall set the Media_Busy field and send it in a Data-In packet with no IrLAP frame following the header. bmRequestType bRequest wValue wIndex wLength Data 00100001B 3 Zero Interface Zero [None] */ ULONG fMediaBusy; // declare as ULONGS for use with InterlockedExchange ULONG fIndicatedMediaBusy; // // The variable fProcessing is used to indicate that the ir device // object has an active polling thread, // // Under normal circumstances fReceiving should always be TRUE. // However sometimes the processing has to be stopped // and this variable is used to synchronize // ULONG fProcessing; // // To be set to true when really receiving packets // ULONG fCurrentlyReceiving; // // The variables fPendingHalt and fPendingReset allow the send and receive // completion routines to complete the current pending irp and // then cleanup and stop sending irps to the USB driver. // BOOLEAN fPendingHalt; BOOLEAN fPendingReset; ULONG fPendingReadClearStall; ULONG fPendingWriteClearStall; // // This is required when the part gets into a complete USB hang and a reset is required // ULONG fPendingClearTotalStall; // // We keep an array of receive buffers so that we don't continually // need to allocate buffers to indicate packets to the protocol. // Since the protocol can retain ownership of up to eight packets // and we can be receiving up to WindowSize ( 7 ) packets while the protocol has // ownership of eight packets, we will allocate 16 packets for // receiving. // #define NUM_RCV_BUFS 16 RCV_BUFFER rcvBufs[NUM_RCV_BUFS]; PRCV_BUFFER pCurrentRecBuf; FIFO_BUFFER PreReadBuffer; // // Can have max of NUM_RCV_BUFS packets pending + one set and one query // #define NUM_WORK_ITEMS (NUM_RCV_BUFS+3) IR_WORK_ITEM WorkItems[NUM_WORK_ITEMS]; // // Since we can have multiple write irps pending with the USB driver, // we track the irp contexts for each one so we have all the info we need at each // invokation of the USB write completion routine. See the IRUSB_CONTEXT definition below // There are 128 contexts for sending, one for read/write operations, one for setting the speed // and one for diagnostic operations // #define NUM_SEND_CONTEXTS 131 PVOID pSendContexts; // // Handles to the NDIS packet pool and NDIS buffer pool // for allocating the receive buffers. // HANDLE hPacketPool; HANDLE hBufferPool; BOOLEAN BufferPoolAllocated; KEVENT EventSyncUrb; KEVENT EventAsyncUrb; NTSTATUS StatusControl; NTSTATUS StatusReadWrite; NTSTATUS StatusSendReceive; // // track pending IRPS; this should be zero at halt time // UINT PendingIrpCount; ULONG NumReads; ULONG NumWrites; ULONG NumReadWrites; // // various USB errors // ULONG NumDataErrors; ULONG NumReadWriteErrors; HANDLE BulkInPipeHandle; HANDLE BulkOutPipeHandle; HANDLE hPollingThread; BOOLEAN fKillPollingThread; // // The IR USB dongle's USB Class-Specific Descriptor as per // "Universal Serial Bus IrDA Bridge Device Definition" doc, section 7.2 // This is the struct returned by USBD as the result of a request with an urb // of type _URB_CONTROL_VENDOR_OR_CLASS_REQUEST, function URB_FUNCTION_CLASS_DEVICE. // Note this struct is in-line, not a pointer // IRUSB_CLASS_SPECIFIC_DESCRIPTOR ClassDesc; UINT IdVendor; // USB vendor Id read from dongle // // We don't define it here because we need to isolate USB stuff so we // can build things referencing NDIS with the BINARY_COMPATIBLE flag for win9x // PUCHAR pUsbInfo; // // Optional registry entry for debugging; limit baud rate. // The mask is set up as per the USB Class-Specific descriptor 'wBaudRate' // This is 'and'ed with value from Class descriptor to possibly limit baud rate; // It defaults to 0xffff // UINT BaudRateMask; // // Necessary to read the registry fields // NDIS_HANDLE WrapperConfigurationContext; // // IR Tranceiver Model // STIR4200_TRANCEIVER StIrTranceiver; // // Send buffers (works only if sending is serialied) // PUCHAR pBuffer; UINT BufLen; PUCHAR pStagingBuffer; // // Send FIFO count // ULONG SendFifoCount; // // Receive adaptive delay // ULONG ReceiveAdaptiveDelay; ULONG ReceiveAdaptiveDelayBoost; // MS Security issue - removed pUrb // // Receive buffer and positions // UCHAR pRawBuf[STIR4200_FIFO_SIZE]; ULONG rawCleanupBytesRead; PORT_RCV_STATE rcvState; ULONG readBufPos; BOOLEAN fReadHoldingReg; ULONG PreFifoCount; // // Send lists and lock // LIST_ENTRY SendAvailableQueue; LIST_ENTRY SendBuiltQueue; LIST_ENTRY SendPendingQueue; ULONG SendAvailableCount; ULONG SendBuiltCount; ULONG SendPendingCount; KSPIN_LOCK SendLock; // // Read and write register list, shares the other send queues // LIST_ENTRY ReadWritePendingQueue; ULONG ReadWritePendingCount; // // Diagnostics // #if defined(DIAGS) ULONG DiagsActive; ULONG DiagsPendingActivation; PVOID pIOCTL; NTSTATUS IOCTLStatus; KEVENT EventDiags; LIST_ENTRY DiagsReceiveQueue; KSPIN_LOCK DiagsReceiveLock; #endif NDIS_HANDLE NdisDeviceHandle; // // Logging // #if defined(RECEIVE_LOGGING) HANDLE ReceiveFileHandle; __int64 ReceiveFilePosition; #endif #if defined(RECEIVE_ERROR_LOGGING) HANDLE ReceiveErrorFileHandle; __int64 ReceiveErrorFilePosition; #endif #if defined(SEND_LOGGING) HANDLE SendFileHandle; __int64 SendFilePosition; #endif #if !defined(WORKAROUND_BROKEN_MIR) // // Mir in software // UCHAR pRawUnstuffedBuf[STIR4200_FIFO_SIZE]; UCHAR MirIncompleteByte; ULONG MirIncompleteBitCount; ULONG MirOneBitCount; ULONG MirFlagCount; #endif // // Dummy send fix // BOOLEAN GearedDown; // // Fix for FIR permanent invalid state // BOOLEAN StuckFir; // // Customer data area. // UCHAR pCustomerData[STIR4200_CUST_DATA_SIZE]; BOOLEAN CustomerDataRead; // // Used in Diagnostic version. // #if defined(VARIABLE_SETTINGS) ULONG SirDpll; ULONG FirDpll; ULONG SirSensitivity; ULONG FirSensitivity; #endif } IR_DEVICE, *PIR_DEVICE; // // We use a pointer to the IR_DEVICE structure as the miniport's device context. // #define CONTEXT_TO_DEV(__deviceContext) ((PIR_DEVICE)(__deviceContext)) #define DEV_TO_CONTEXT(__irdev) ((HANDLE)(__irdev)) #define IRUSB_TAG 'RITS' VOID MyNdisMSetInformationComplete( IN PIR_DEVICE pThisDev, IN NDIS_STATUS Status ); VOID MyNdisMQueryInformationComplete( IN PIR_DEVICE pThisDev, IN NDIS_STATUS Status ); USHORT ComputeFCS16( IN PUCHAR pData, UINT DataLen ); ULONG ComputeFCS32( IN PUCHAR pData, ULONG DataLen ); BOOLEAN NdisToFirPacket( IN PIR_DEVICE pIrDev, IN PNDIS_PACKET pPacket, OUT PUCHAR pIrPacketBuf, ULONG IrPacketBufLen, IN PUCHAR pContigPacketBuf, OUT PULONG pIrPacketLen ); BOOLEAN NdisToMirPacket( IN PIR_DEVICE pIrDev, IN PNDIS_PACKET pPacket, OUT PUCHAR pIrPacketBuf, ULONG IrPacketBufLen, IN PUCHAR pContigPacketBuf, OUT PULONG pIrPacketLen ); BOOLEAN NdisToSirPacket( IN PIR_DEVICE pIrDev, IN PNDIS_PACKET pPacket, OUT PUCHAR pIrPacketBuf, ULONG IrPacketBufLen, IN PUCHAR pContigPacketBuf, OUT PULONG pIrPacketLen ); BOOLEAN ReceiveFirStepFSM( IN OUT PIR_DEVICE pIrDev, OUT PULONG pBytesProcessed ); BOOLEAN ReceiveMirStepFSM( IN OUT PIR_DEVICE pIrDev, OUT PULONG pBytesProcessed ); #if !defined(WORKAROUND_BROKEN_MIR) BOOLEAN ReceiveMirUnstuff( IN OUT PIR_DEVICE pIrDev, IN PUCHAR pInputBuffer, ULONG InputBufferSize, OUT PUCHAR pOutputBuffer, OUT PULONG pOutputBufferSize ); #endif BOOLEAN ReceiveSirStepFSM( IN OUT PIR_DEVICE pIrDev, OUT PULONG pBytesProcessed ); VOID ReceiveProcessFifoData( IN OUT PIR_DEVICE pThisDev ); VOID ReceiveResetPointers( IN OUT PIR_DEVICE pThisDev ); NTSTATUS ReceivePreprocessFifo( IN OUT PIR_DEVICE pThisDev, OUT PULONG pFifoCount ); NTSTATUS ReceiveGetFifoData( IN OUT PIR_DEVICE pThisDev, OUT PUCHAR pData, OUT PULONG pBytesRead, ULONG BytesToRead ); VOID ReceiveProcessReturnPacket( OUT PIR_DEVICE pThisDev, OUT PRCV_BUFFER pReceiveBuffer ); NTSTATUS ReceivePacketRead( IN PIR_DEVICE pThisDev, OUT PFIFO_BUFFER pRecBuf ); NTSTATUS ReceiveCompletePacketRead( IN PDEVICE_OBJECT pUsbDevObj, IN PIRP pIrp, IN PVOID Context ); VOID IndicateMediaBusy( IN PIR_DEVICE pThisDev ); VOID IrUsb_IncIoCount( IN OUT PIR_DEVICE pThisDev ); VOID IrUsb_DecIoCount( IN OUT PIR_DEVICE pThisDev ); NTSTATUS IrUsb_GetDongleCaps( IN OUT PIR_DEVICE pThisDev ); VOID IrUsb_SetDongleCaps( IN OUT PIR_DEVICE pThisDev ); VOID MyMemFree( IN PVOID pMem, IN UINT size ); PVOID MyMemAlloc( UINT size ); VOID MyUrbFree( IN PURB pUrb, IN UINT size ); PURB MyUrbAlloc( UINT size ); BOOLEAN AllocUsbInfo( IN OUT PIR_DEVICE pThisDev ); VOID FreeUsbInfo( IN OUT PIR_DEVICE pThisDev ); VOID PollingThread( IN OUT PVOID Context ); extern BAUDRATE_INFO supportedBaudRateTable[NUM_BAUDRATES]; VOID ReceiveDeliverBuffer( IN OUT PIR_DEVICE pThisDev, IN PRCV_BUFFER pRecBuf ); NTSTATUS InitializeProcessing( IN OUT PIR_DEVICE pThisDev, IN BOOLEAN InitPassiveThread ); NTSTATUS IrUsb_ResetPipe ( IN PIR_DEVICE pThisDev, IN HANDLE Pipe ); BOOLEAN IrUsb_InitSendStructures( IN OUT PIR_DEVICE pThisDev ); VOID IrUsb_FreeSendStructures( IN OUT PIR_DEVICE pThisDev ); NDIS_STATUS SendPacketPreprocess( IN OUT PIR_DEVICE pThisDev, IN PVOID pPacketToSend ); NDIS_STATUS SendPreprocessedPacketSend( IN OUT PIR_DEVICE pThisDev, IN PVOID pContext ); NTSTATUS SendWaitCompletion( IN OUT PIR_DEVICE pThisDev ); NTSTATUS SendCheckForOverflow( IN OUT PIR_DEVICE pThisDev ); NTSTATUS SendCompletePacketSend( IN PDEVICE_OBJECT pUsbDevObj, IN PIRP pIrp, IN PVOID Context ); PRCV_BUFFER ReceiveGetBuf( PIR_DEVICE pThisDev, OUT PUINT pIndex, IN RCV_BUFFER_STATE BufferState ); VOID PassiveLevelThread( IN PVOID Context ); BOOLEAN ScheduleWorkItem( IN OUT PIR_DEVICE pThisDev, WORK_PROC Callback, IN PVOID pInfoBuf, ULONG InfoBufLen ); VOID FreeWorkItem( IN OUT PIR_WORK_ITEM pItem ); VOID IrUsb_PrepareSetSpeed( IN OUT PIR_DEVICE pThisDev ); NTSTATUS ResetPipeCallback ( IN PIR_WORK_ITEM pWorkItem ); PVOID AllocXferUrb ( VOID ); VOID FreeXferUrb( IN OUT PVOID pUrb ); #endif // _IRCOM_H