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Postponing PnP IRP Processing Until Lower Drivers Finish

Some PnP and power IRPs must be processed first by the parent bus driver for a device and then by each next-higher driver in the device stack. For example, the parent bus driver must be the first driver to perform its start operations for a device (IRP_MN_START_DEVICE), followed by each next-higher driver. For such an IRP, function and filter drivers must set an I/O completion routine, pass the IRP to the next-lower driver, and postpone any activities to process the IRP until the lower drivers have finished with the IRP.

An IoCompletion routine can be called at IRQL DISPATCH_LEVEL, but a function or filter driver might need to process the IRP at IRQL = PASSIVE_LEVEL. To return to PASSIVE_LEVEL from an IoCompletion routine, a driver can use a kernel event. The driver registers an IoCompletion routine that sets a kernel-mode event and then the driver waits on the event in its DispatchPnP routine. When the event is set, lower drivers have completed the IRP and the driver is allowed to process the IRP.

Note that a driver must not use this technique to wait for lower drivers to finish a power IRP (IRP_MJ_POWER). Waiting on an event in the DispatchPower routine that is set in the IoCompletion routine can cause a deadlock. See Passing Power IRPs for more information.

The following two figures show an example of how a driver waits for lower drivers to complete a PnP IRP. The example shows what the function and bus drivers must do, plus how they interact with the PnP manager and the I/O manager.

diagram illustrating postponing plug and play irp handling, part 1.

The following notes correspond to the circled numbers in the previous figure:

  1. The PnP manager calls the I/O manager to send an IRP to the top driver in the device stack.

  2. The I/O manager calls the DispatchPnP routine of the top driver. In this example, there are only two drivers in the device stack (the function driver and the parent bus driver) and the function driver is the top driver.

  3. The function driver declares and initializes a kernel-mode event, sets up the stack location for the next-lower driver, and sets an IoCompletion routine for this IRP.

    The function driver can use IoCopyCurrentIrpStackLocationToNext to set up the stack location.

    In the call to IoSetCompletionRoutine, the function driver sets InvokeOnSuccess, InvokeOnError, and InvokeOnCancel to TRUE and passes the kernel-mode event as part of the context parameter.

  4. The function driver passes the IRP down the device stack with IoCallDriver before performing any operations to handle the IRP.

  5. The I/O manager sends the IRP to the next-lower driver in the device stack by calling that driver's DispatchPnP routine.

  6. The next-lower driver in this example is the lowest driver in the device stack, the parent bus driver. The bus driver performs its operations to start the device. The bus driver sets Irp->IoStatus.Status, sets Irp->IoStatus.Information if relevant to this IRP, and completes the IRP by calling IoCompleteRequest.

    If the bus driver calls other driver routines or sends I/O to the device in order to start it, the bus driver does not complete the PnP IRP in its DispatchPnP routine. Instead, it must mark the IRP pending with IoMarkIrpPending and return STATUS_PENDING from its DispatchPnP routine. The driver later calls IoCompleteRequest from another driver routine, possibly a DPC routine.

The following figure shows the second part of the example, where the higher drivers in the device stack resume their postponed IRP processing.

diagram illustrating postponing plug and play irp handling, part 2.

The following notes correspond to the circled numbers in the previous figure:

  1. When the bus driver calls IoCompleteRequest, the I/O manager examines the stack locations of the higher drivers and calls any IoCompletion routines it finds. In this example, the I/O manager locates and calls the IoCompletion routine for the next-higher driver, the function driver.

  2. The function driver's IoCompletion routine sets the kernel-mode event supplied in the context parameter and returns STATUS_MORE_PROCESSING_REQUIRED.

    The IoCompletion routine must return STATUS_MORE_PROCESSING_REQUIRED to prevent the I/O manager from calling IoCompletion routines set by higher drivers at this time. The IoCompletion routine uses this status to forestall completion so its driver's DispatchPnP routine can regain control. The I/O manager will resume calling higher drivers' IoCompletion routines for this IRP when this driver's DispatchPnP routine completes the IRP.

  3. The I/O manager stops completing the IRP and returns control to the routine that called IoCompleteRequest, which in this example is the bus driver's DispatchPnP routine.

  4. The bus driver returns from its DispatchPnP routine with status indicating the result of its IRP processing: either STATUS_SUCCESS or an error status.

  5. IoCallDriver returns control to its caller, which in this example is the function driver's DispatchPnP routine.

  6. The function driver's DispatchPnP routine resumes processing the IRP.

    If IoCallDriver returns STATUS_PENDING, the DispatchPnP routine has resumed execution before its IoCompletion routine has been called. The DispatchPnP routine, therefore, must wait for the kernel event to be signaled by its IoCompletion routine. This ensures that the DispatchPnP routine will not continue processing the IRP until all lower drivers have completed it.

    If Irp->IoStatus.Status is set to an error, a lower driver has failed the IRP and the function driver must not continue handling the IRP (except for any necessary cleanup).

  7. Once lower drivers have successfully completed the IRP, the function driver processes the IRP.

    For IRPs being handled first by the parent bus driver, the bus driver typically sets a successful status in Irp->IoStatus.Status and optionally sets a value in Irp->IoStatus.Information. Function and filter drivers leave the values in IoStatus as is unless they fail the IRP.

    The function driver's DispatchPnP routine calls IoCompleteRequest to complete the IRP. The I/O manager resumes I/O completion processing. In this example, there are no filter drivers above the function driver, and thus no more IoCompletion routines to call. When IoCompleteRequest returns control to the function driver DispatchPnP routine, the DispatchPnP routine returns status.

For some IRPs, if a function or filter driver fails the IRP on its way back up the device stack, the PnP manager informs the lower drivers. For example, if a function or filter driver fails an IRP_MN_START_DEVICE, the PnP manager sends an IRP_MN_REMOVE_DEVICE to the device stack.