/**************************************************************************** Copyright (c) 1998 Microsoft Corporation Module Name: USBSER.H Abstract: This header file is used for the Legacy USB Modem Driver Environment: Kernel mode & user mode Notes: THIS CODE AND INFORMATION IS PROVIDED "AS IS" WITHOUT WARRANTY OF ANY KIND, EITHER EXPRESSED OR IMPLIED, INCLUDING BUT NOT LIMITED TO THE IMPLIED WARRANTIES OF MERCHANTABILITY AND/OR FITNESS FOR A PARTICULAR PURPOSE. Copyright (c) 1998 Microsoft Corporation. All Rights Reserved. Revision History: 12/23/97 : created Author: Tom Green ****************************************************************************/ #ifndef __USBSER_H__ #define __USBSER_H__ #ifdef DRIVER // Various definitions #define NAME_MAX 80 #define MILLISECONDS_TIMEOUT(x) ((ULONGLONG) ((-x) * 10000)) #define NOTIFICATION_BUFF_SIZE 10 #define MAXIMUM_TRANSFER_SIZE (8 * 1024) #define RX_BUFF_SIZE (16 * 1024) #define USB_RX_BUFF_SIZE (RX_BUFF_SIZE / 4) #define LOW_WATER_MARK (USB_RX_BUFF_SIZE * 3) #define DEVICE_STATE_UNKNOWN 0x0000 #define DEVICE_STATE_STARTED 0x0001 #define DEVICE_STATE_STOPPED 0x0002 #define DEVICE_STATE_REMOVED 0x0003 // device capabilities #define DEVICE_CAP_VERSION 0x0001 #define DEVICE_CAP_UNUSED_PARAM ((ULONG) -1) // these describe bits in the modem status register #define SERIAL_MSR_DCTS 0x0001 #define SERIAL_MSR_DDSR 0x0002 #define SERIAL_MSR_TERI 0x0004 #define SERIAL_MSR_DDCD 0x0008 #define SERIAL_MSR_CTS 0x0010 #define SERIAL_MSR_DSR 0x0020 #define SERIAL_MSR_RI 0x0040 #define SERIAL_MSR_DCD 0x0080 // // These masks define access to the line status register. The line // status register contains information about the status of data // transfer. The first five bits deal with receive data and the // last two bits deal with transmission. An interrupt is generated // whenever bits 1 through 4 in this register are set. // // // This bit is the data ready indicator. It is set to indicate that // a complete character has been received. This bit is cleared whenever // the receive buffer register has been read. // #define SERIAL_LSR_DR 0x01 // // This is the overrun indicator. It is set to indicate that the receive // buffer register was not read befor a new character was transferred // into the buffer. This bit is cleared when this register is read. // #define SERIAL_LSR_OE 0x02 // // This is the parity error indicator. It is set whenever the hardware // detects that the incoming serial data unit does not have the correct // parity as defined by the parity select in the line control register. // This bit is cleared by reading this register. // #define SERIAL_LSR_PE 0x04 // // This is the framing error indicator. It is set whenever the hardware // detects that the incoming serial data unit does not have a valid // stop bit. This bit is cleared by reading this register. // #define SERIAL_LSR_FE 0x08 // // This is the break interrupt indicator. It is set whenever the data // line is held to logic 0 for more than the amount of time it takes // to send one serial data unit. This bit is cleared whenever the // this register is read. // #define SERIAL_LSR_BI 0x10 // // This is the transmit holding register empty indicator. It is set // to indicate that the hardware is ready to accept another character // for transmission. This bit is cleared whenever a character is // written to the transmit holding register. // #define SERIAL_LSR_THRE 0x20 // // This bit is the transmitter empty indicator. It is set whenever the // transmit holding buffer is empty and the transmit shift register // (a non-software accessable register that is used to actually put // the data out on the wire) is empty. Basically this means that all // data has been sent. It is cleared whenever the transmit holding or // the shift registers contain data. // #define SERIAL_LSR_TEMT 0x40 // // This bit indicates that there is at least one error in the fifo. // The bit will not be turned off until there are no more errors // in the fifo. // #define SERIAL_LSR_FIFOERR 0x80 // // Serial naming values // // // Maximum length for symbolic link // #define SYMBOLIC_NAME_LENGTH 128 // // This define gives the default Object directory // that we should use to insert the symbolic links // between the NT device name and namespace used by // that object directory. #define DEFAULT_DIRECTORY L"DosDevices" // // Where in the DeviceMap section of the registry serial port entries // should appear // #define SERIAL_DEVICE_MAP L"SERIALCOMM" // performance info for modem driver typedef struct _PERF_INFO { BOOLEAN PerfModeEnabled; ULONG BytesPerSecond; } PERF_INFO, *PPERF_INFO; #define SANITY_CHECK ((ULONG) 'ENAS') #else #include #endif // IOCTL info, needs to be visible for application #define USBSER_IOCTL_INDEX 0x0800 #define GET_DRIVER_LOG CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 0, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define GET_IRP_HIST CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 1, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define GET_PATH_HIST CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 2, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define GET_ERROR_LOG CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 3, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define GET_ATTACHED_DEVICES CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 4, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define SET_IRP_HIST_SIZE CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 5, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define SET_PATH_HIST_SIZE CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 6, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define SET_ERROR_LOG_SIZE CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 7, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define GET_DRIVER_INFO CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 8, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define ENABLE_PERF_TIMING CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 9, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define DISABLE_PERF_TIMING CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 10, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define GET_PERF_DATA CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 11, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #define SET_DEBUG_TRACE_LEVEL CTL_CODE(FILE_DEVICE_UNKNOWN, \ USBSER_IOCTL_INDEX + 12, \ METHOD_BUFFERED, \ FILE_ANY_ACCESS) #ifdef DRIVER // info about the driver, initialized in DriverEntry routine PCHAR DriverName; PCHAR DriverVersion; ULONG Usbser_Debug_Trace_Level; ULONG UsbSerSerialDebugLevel; KSPIN_LOCK GlobalSpinLock; // // Count of how many times the paged code has been locked // ULONG PAGEUSBSER_Count; // // Handle to the locked paged code // PVOID PAGEUSBSER_Handle; // // Pointer to funcion // PVOID PAGEUSBSER_Function; typedef struct _READ_CONTEXT { PURB Urb; PDEVICE_OBJECT DeviceObject; PIRP Irp; } READ_CONTEXT, *PREAD_CONTEXT; // device extension for driver instance, used to store needed data typedef struct _DEVICE_EXTENSION { PDEVICE_OBJECT PhysDeviceObject; // physical device object PDEVICE_OBJECT StackDeviceObject; // stack device object CHAR LinkName[NAME_MAX]; // string name of symbolic link PUSB_DEVICE_DESCRIPTOR DeviceDescriptor; // device descriptor for device USBD_CONFIGURATION_HANDLE ConfigurationHandle; // configuration of USB device USBD_PIPE_HANDLE DataInPipe; // pipe for reading data USBD_PIPE_HANDLE DataOutPipe; // pipe for writing data USBD_PIPE_HANDLE NotificationPipe; // pipe for getting notifications from the device ULONG IRPCount; // number of IRPs that passed through this device object LARGE_INTEGER ByteCount; // number of bytes of data passed through this device object ULONG Instance; // instance of device BOOLEAN IsDevice; // is this a device or "global" device object BOOLEAN PerfTimerEnabled; // enable perf timing LARGE_INTEGER BytesXfered; // byte count for perf LARGE_INTEGER ElapsedTime; // elapsed time for perf LARGE_INTEGER TimerStart; // timer start for perf DEVICE_CAPABILITIES DeviceCapabilities; ULONG PowerDownLevel; DEVICE_POWER_STATE CurrentDevicePowerState; PIRP PowerIrp; BOOLEAN SelfPowerIrp; KEVENT SelfRequestedPowerIrpEvent; // // Nota Bene: Locking hierarchy is acquire ControlLock *then* // acquire CancelSpinLock. We don't want to stall other // drivers waiting for the cancel spin lock // KSPIN_LOCK ControlLock; // protect extension ULONG CurrentBaud; // current baud rate SERIAL_TIMEOUTS Timeouts; // timeout controls for device ULONG IsrWaitMask; // determine if occurence of events should be noticed SERIAL_LINE_CONTROL LineControl; // current value of line control reg SERIAL_HANDFLOW HandFlow; // Handshake and control flow settings SERIALPERF_STATS PerfStats; // performance stats SERIAL_CHARS SpecialChars; // special characters ULONG DTRRTSState; // keep track of the current state of these lines ULONG SupportedBauds; // "named" baud rates for device UCHAR EscapeChar; // for LsrmstInsert IOCTL USHORT FakeModemStatus; // looks like status register on modem USHORT FakeLineStatus; // looks like line status register USHORT RxMaxPacketSize; // max packet size fo the in data pipe PIRP NotifyIrp; // Irp for notify reads PURB NotifyUrb; // Urb for notify Irp PIRP ReadIrp; // Irp for read requests PURB ReadUrb; // Urb for read requests KEVENT ReadEvent; // used to cancel a read Irp ULONG CharsInReadBuff; // current number of characters buffered ULONG CurrentReadBuffPtr; // pointer into read buffer BOOLEAN AcceptingRequests; // is the device stopped or removed PIRP CurrentMaskIrp; // current set or wait mask Irp ULONG HistoryMask; // store mask events here ULONG OpenCnt; // number of create calls on device PUCHAR NotificationBuff; // buffer for notifications PUCHAR ReadBuff; // circular buffer for read requests PUCHAR USBReadBuff; // buffer to get data from device UCHAR CommInterface; // index of communications interface ULONG RxQueueSize; // fake read buffer size ULONG ReadInterlock; // state machine for starting reads from completion routine BOOLEAN ReadInProgress; ULONG DeviceState; // current state of enumeration // // True if a symbolic link has been created and should be // removed upon deletion. // BOOLEAN CreatedSymbolicLink; // // Symbolic link name -- e.g., \\DosDevices\COMx // UNICODE_STRING SymbolicLinkName; // // Dos Name -- e.g., COMx // UNICODE_STRING DosName; // // Device Name -- e.g., \\Devices\UsbSerx // UNICODE_STRING DeviceName; // // Current Read Irp which is pending // PIRP CurrentReadIrp; // // Current Write Irp which is pending // PIRP CurrentWriteIrp; // // Read queue // LIST_ENTRY ReadQueue; // // This value holds the number of characters desired for a // particular read. It is initially set by read length in the // IRP. It is decremented each time more characters are placed // into the "users" buffer buy the code that reads characters // out of the typeahead buffer into the users buffer. If the // typeahead buffer is exhausted by the read, and the reads buffer // is given to the isr to fill, this value is becomes meaningless. // ULONG NumberNeededForRead; // // Timer for timeout on total read request // KTIMER ReadRequestTotalTimer; // // Timer for timeout on the interval // KTIMER ReadRequestIntervalTimer; // // This is the kernal timer structure used to handle // total time request timing. // KTIMER WriteRequestTotalTimer; // // This value is set by the read code to hold the time value // used for read interval timing. We keep it in the extension // so that the interval timer dpc routine determine if the // interval time has passed for the IO. // LARGE_INTEGER IntervalTime; // // This holds the value that we use to determine if we should use // the long interval delay or the short interval delay. // LARGE_INTEGER CutOverAmount; // // This holds the system time when we last time we had // checked that we had actually read characters. Used // for interval timing. // LARGE_INTEGER LastReadTime; // // This points the the delta time that we should use to // delay for interval timing. // PLARGE_INTEGER IntervalTimeToUse; // // These two values hold the "constant" time that we should use // to delay for the read interval time. // LARGE_INTEGER ShortIntervalAmount; LARGE_INTEGER LongIntervalAmount; // // This dpc is fired off if the timer for the total timeout // for the read expires. It will execute a dpc routine that // will cause the current read to complete. // // KDPC TotalReadTimeoutDpc; // // This dpc is fired off if the timer for the interval timeout // expires. If no more characters have been read then the // dpc routine will cause the read to complete. However, if // more characters have been read then the dpc routine will // resubmit the timer. // KDPC IntervalReadTimeoutDpc; // // This dpc is fired off if the timer for the total timeout // for the write expires. It will execute a dpc routine that // will cause the current write to complete. // // KDPC TotalWriteTimeoutDpc; // // This keeps a total of the number of characters that // are in all of the "write" irps that the driver knows // about. It is only accessed with the cancel spinlock // held. // ULONG TotalCharsQueued; // // This holds a count of the number of characters read // the last time the interval timer dpc fired. It // is a long (rather than a ulong) since the other read // completion routines use negative values to indicate // to the interval timer that it should complete the read // if the interval timer DPC was lurking in some DPC queue when // some other way to complete occurs. // LONG CountOnLastRead; // // This is a count of the number of characters read by the // isr routine. It is *ONLY* written at isr level. We can // read it at dispatch level. // ULONG ReadByIsr; // // If non-NULL, means this write timed out and we should correct the // return value in the completion routine. // PIRP TimedOutWrite; // // If TRUE, that means we need to insert LSRMST // BOOLEAN EscapeSeen; // // Holds data that needs to be pushed such as LSRMST data // LIST_ENTRY ImmediateReadQueue; // // Pending wait-wake irp // PIRP PendingWakeIrp; // // True if WaitWake needs to be sent down before a powerdown // BOOLEAN SendWaitWake; // // SystemWake from devcaps // SYSTEM_POWER_STATE SystemWake; // // DeviceWake from devcaps // DEVICE_POWER_STATE DeviceWake; // // Count of Writes pending in the lower USB levels // ULONG PendingWriteCount; // // Counters and events to drain USB requests // KEVENT PendingDataInEvent; KEVENT PendingDataOutEvent; KEVENT PendingNotifyEvent; KEVENT PendingFlushEvent; ULONG PendingDataInCount; ULONG PendingDataOutCount; ULONG PendingNotifyCount; ULONG SanityCheck; // selective suspend support PIRP PendingIdleIrp; PUSB_IDLE_CALLBACK_INFO IdleCallbackInfo; PIO_WORKITEM IoWorkItem; IO_STATUS_BLOCK StatusBlock; #ifdef SPINLOCK_TRACKING LONG CancelSpinLockCount; LONG SpinLockCount; LONG WaitingOnCancelSpinLock; LONG WaitingOnSpinLock; #endif #ifdef WMI_SUPPORT // // WMI Information // WMILIB_CONTEXT WmiLibInfo; // // Name to use as WMI identifier // UNICODE_STRING WmiIdentifier; #endif } DEVICE_EXTENSION, *PDEVICE_EXTENSION; typedef struct _USBSER_IMMEDIATE_READ_PACKET { // // List of packets // LIST_ENTRY ImmediateReadQueue; // // Length of data // ULONG BufferLen; // // Buffer itself, leave last in struct // UCHAR Buffer; } USBSER_IMMEDIATE_READ_PACKET, *PUSBSER_IMMEDIATE_READ_PACKET; typedef struct _USBSER_WRITE_PACKET { // // Device extension for this write // PDEVICE_EXTENSION DeviceExtension; // // Irp this packet belongs with // PIRP Irp; // // Write timer // KTIMER WriteTimer; // // Timeout value // LARGE_INTEGER WriteTimeout; // // TimerDPC // KDPC TimerDPC; // // Status // NTSTATUS Status; // // Urb for this write N.B.: size is variable, so leave last // URB Urb; } USBSER_WRITE_PACKET, *PUSBSER_WRITE_PACKET; typedef NTSTATUS (*PUSBSER_START_ROUTINE)(IN PDEVICE_EXTENSION); typedef VOID (*PUSBSER_GET_NEXT_ROUTINE) (IN PIRP *CurrentOpIrp, IN PLIST_ENTRY QueueToProcess, OUT PIRP *NewIrp, IN BOOLEAN CompleteCurrent, PDEVICE_EXTENSION Extension); NTSTATUS DriverEntry(IN PDRIVER_OBJECT DriverObject, IN PUNICODE_STRING RegistryPath); NTSTATUS UsbSer_Dispatch(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSer_Create(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSer_Close(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSer_Write(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSer_Read(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); VOID UsbSer_Unload(IN PDRIVER_OBJECT DriverObject); NTSTATUS UsbSer_PnPAddDevice(IN PDRIVER_OBJECT DriverObject, IN PDEVICE_OBJECT PhysicalDeviceObject); NTSTATUS UsbSer_PnP(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSer_Power(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSer_SystemControl(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSer_Cleanup(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSerMajorNotSupported(IN PDEVICE_OBJECT DeviceObject, IN PIRP Irp); NTSTATUS UsbSerStartOrQueue(IN PDEVICE_EXTENSION PDevExt, IN PIRP PIrp, IN PLIST_ENTRY PQueue, IN PIRP *PPCurrentIrp, IN PUSBSER_START_ROUTINE Starter); VOID UsbSerCancelQueued(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp); NTSTATUS UsbSerStartRead(IN PDEVICE_EXTENSION PDevExt); VOID UsbSerCancelCurrentRead(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp); BOOLEAN UsbSerGrabReadFromRx(IN PVOID Context); VOID UsbSerTryToCompleteCurrent(IN PDEVICE_EXTENSION PDevExt, IN KIRQL IrqlForRelease, IN NTSTATUS StatusToUse, IN PIRP *PpCurrentOpIrp, IN PLIST_ENTRY PQueue OPTIONAL, IN PKTIMER PIntervalTimer OPTIONAL, IN PKTIMER PTotalTimer OPTIONAL, IN PUSBSER_START_ROUTINE Starter OPTIONAL, IN PUSBSER_GET_NEXT_ROUTINE PGetNextIrp OPTIONAL, IN LONG RefType, IN BOOLEAN Complete); VOID UsbSerReadTimeout(IN PKDPC PDpc, IN PVOID DeferredContext, IN PVOID SystemContext1, IN PVOID SystemContext2); VOID UsbSerIntervalReadTimeout(IN PKDPC PDpc, IN PVOID DeferredContext, IN PVOID SystemContext1, IN PVOID SystemContext2); VOID UsbSerKillPendingIrps(PDEVICE_OBJECT PDevObj); VOID UsbSerCompletePendingWaitMasks(IN PDEVICE_EXTENSION DeviceExtension); VOID UsbSerKillAllReadsOrWrites(IN PDEVICE_OBJECT PDevObj, IN PLIST_ENTRY PQueueToClean, IN PIRP *PpCurrentOpIrp); VOID UsbSerRestoreModemSettings(PDEVICE_OBJECT PDevObj); VOID UsbSerProcessEmptyTransmit(IN PDEVICE_EXTENSION PDevExt); VOID UsbSerWriteTimeout(IN PKDPC Dpc, IN PVOID DeferredContext, IN PVOID SystemContext1, IN PVOID SystemContext2); NTSTATUS UsbSerGiveWriteToUsb(IN PDEVICE_EXTENSION PDevExt, IN PIRP PIrp, IN LARGE_INTEGER TotalTime); VOID UsbSerCancelWaitOnMask(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp); NTSTATUS UsbSerWriteComplete(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp, IN PUSBSER_WRITE_PACKET PPacket); NTSTATUS UsbSerFlush(IN PDEVICE_OBJECT PDevObj, PIRP PIrp); NTSTATUS UsbSerTossWMIRequest(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp, IN ULONG GuidIndex); NTSTATUS UsbSerSystemControlDispatch(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp); NTSTATUS UsbSerSetWmiDataItem(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp, IN ULONG GuidIndex, IN ULONG InstanceIndex, IN ULONG DataItemId, IN ULONG BufferSize, IN PUCHAR PBuffer); NTSTATUS UsbSerSetWmiDataBlock(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp, IN ULONG GuidIndex, IN ULONG InstanceIndex, IN ULONG BufferSize, IN PUCHAR PBuffer); NTSTATUS UsbSerQueryWmiDataBlock(IN PDEVICE_OBJECT PDevObj, IN PIRP PIrp, IN ULONG GuidIndex, IN ULONG InstanceIndex, IN ULONG InstanceCount, IN OUT PULONG InstanceLengthArray, IN ULONG OutBufferSize, OUT PUCHAR PBuffer); NTSTATUS UsbSerQueryWmiRegInfo(IN PDEVICE_OBJECT PDevObj, OUT PULONG PRegFlags, OUT PUNICODE_STRING PInstanceName, OUT PUNICODE_STRING *PRegistryPath, OUT PUNICODE_STRING MofResourceName, OUT PDEVICE_OBJECT *Pdo); // // The following three macros are used to initialize, set // and clear references in IRPs that are used by // this driver. The reference is stored in the fourth // argument of the irp, which is never used by any operation // accepted by this driver. // #define USBSER_REF_RXBUFFER (0x00000001) #define USBSER_REF_CANCEL (0x00000002) #define USBSER_REF_TOTAL_TIMER (0x00000004) #define USBSER_REF_INT_TIMER (0x00000008) #ifdef SPINLOCK_TRACKING #define ACQUIRE_CANCEL_SPINLOCK(DEVEXT, IRQL) \ { \ ASSERT(DEVEXT->SpinLockCount == 0); \ DEVEXT->WaitingOnCancelSpinLock++; \ IoAcquireCancelSpinLock(IRQL); \ DEVEXT->CancelSpinLockCount++; \ DEVEXT->WaitingOnCancelSpinLock--; \ ASSERT(DEVEXT->CancelSpinLockCount == 1); \ } #define RELEASE_CANCEL_SPINLOCK(DEVEXT, IRQL) \ { \ DEVEXT->CancelSpinLockCount--; \ ASSERT(DEVEXT->CancelSpinLockCount == 0); \ IoReleaseCancelSpinLock(IRQL); \ } #define ACQUIRE_SPINLOCK(DEVEXT, LOCK, IRQL) \ { \ DEVEXT->WaitingOnSpinLock++; \ KeAcquireSpinLock(LOCK, IRQL); \ DEVEXT->SpinLockCount++; \ DEVEXT->WaitingOnSpinLock--; \ ASSERT(DEVEXT->SpinLockCount == 1); \ } #define RELEASE_SPINLOCK(DEVEXT, LOCK, IRQL) \ { \ DEVEXT->SpinLockCount--; \ ASSERT(DEVEXT->SpinLockCount == 0); \ KeReleaseSpinLock(LOCK, IRQL); \ } #else #define ACQUIRE_CANCEL_SPINLOCK(DEVEXT, IRQL) IoAcquireCancelSpinLock(IRQL) #define RELEASE_CANCEL_SPINLOCK(DEVEXT, IRQL) IoReleaseCancelSpinLock(IRQL) #define ACQUIRE_SPINLOCK(DEVEXT, LOCK, IRQL) KeAcquireSpinLock(LOCK, IRQL) #define RELEASE_SPINLOCK(DEVEXT, LOCK, IRQL) KeReleaseSpinLock(LOCK, IRQL) #endif #define USBSER_INIT_REFERENCE(Irp) { \ IoGetCurrentIrpStackLocation((Irp))->Parameters.Others.Argument4 = NULL; \ } #define USBSER_SET_REFERENCE(Irp,RefType) \ do { \ LONG _refType = (RefType); \ PUINT_PTR _arg4 = (PVOID)&IoGetCurrentIrpStackLocation((Irp))->Parameters.Others.Argument4; \ *_arg4 |= _refType; \ } while (0) #define USBSER_CLEAR_REFERENCE(Irp,RefType) \ do { \ LONG _refType = (RefType); \ PUINT_PTR _arg4 = (PVOID)&IoGetCurrentIrpStackLocation((Irp))->Parameters.Others.Argument4; \ *_arg4 &= ~_refType; \ } while (0) #define USBSER_REFERENCE_COUNT(Irp) \ ((UINT_PTR)((IoGetCurrentIrpStackLocation((Irp))->Parameters.Others.Argument4))) // // These values are used by the routines that can be used // to complete a read (other than interval timeout) to indicate // to the interval timeout that it should complete. // #define SERIAL_COMPLETE_READ_CANCEL ((LONG)-1) #define SERIAL_COMPLETE_READ_TOTAL ((LONG)-2) #define SERIAL_COMPLETE_READ_COMPLETE ((LONG)-3) #if DBG #define USBSERDUMPRD ((ULONG)0x00000001) #define USBSERDUMPWR ((ULONG)0x00000002) #define USBSERCOMPEV ((ULONG)0x00000004) #define USBSERTRACETM ((ULONG)0x00100000) #define USBSERTRACECN ((ULONG)0x00200000) #define USBSERTRACEPW ((ULONG)0x00400000) #define USBSERTRACERD ((ULONG)0x01000000) #define USBSERTRACEWR ((ULONG)0x02000000) #define USBSERTRACEIOC ((ULONG)0x04000000) #define USBSERTRACEOTH ((ULONG)0x08000000) #define USBSERBUGCHECK ((ULONG)0x80000000) #define USBSERTRACE ((ULONG)0x0F700000) #define USBSERDBGALL ((ULONG)0xFFFFFFFF) extern ULONG UsbSerSerialDebugLevel; #define UsbSerSerialDump(LEVEL, STRING) \ do { \ ULONG _level = (LEVEL); \ if (UsbSerSerialDebugLevel & _level) { \ DbgPrint("UsbSer: "); \ DbgPrint STRING; \ } \ if (_level == USBSERBUGCHECK) { \ ASSERT(FALSE); \ } \ } while (0) #else #define UsbSerSerialDump(LEVEL,STRING) do {;} while (0) #endif // DBG #define USBSER_VENDOR_COMMAND 0 #define USBSER_CLASS_COMMAND 1 #endif // DRIVER #endif // __USBSER_H__