reactos/drivers/filesystems/udfs/env_spec.cpp

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////////////////////////////////////////////////////////////////////
// Copyright (C) Alexander Telyatnikov, Ivan Keliukh, Yegor Anchishkin, SKIF Software, 1999-2013. Kiev, Ukraine
// All rights reserved
// This file was released under the GPLv2 on June 2015.
////////////////////////////////////////////////////////////////////
/*************************************************************************
*
* File: Env_Spec.cpp
*
* Module: UDF File System Driver (Kernel mode execution only)
*
* Description:
* Contains environment-secific code to handle physical
* operations: read, write and device IOCTLS
*
*************************************************************************/
#include "udffs.h"
// define the file specific bug-check id
#define UDF_BUG_CHECK_ID UDF_FILE_ENV_SPEC
#define MEASURE_IO_PERFORMANCE
#ifdef MEASURE_IO_PERFORMANCE
LONGLONG IoReadTime=0;
LONGLONG IoWriteTime=0;
LONGLONG WrittenData=0;
LONGLONG IoRelWriteTime=0;
#endif //MEASURE_IO_PERFORMANCE
#ifdef DBG
ULONG UDF_SIMULATE_WRITES=0;
#endif //DBG
/*
*/
NTSTATUS
NTAPI
UDFAsyncCompletionRoutine(
IN PDEVICE_OBJECT DeviceObject,
IN PIRP Irp,
IN PVOID Contxt
)
{
UDFPrint(("UDFAsyncCompletionRoutine ctx=%x\n", Contxt));
PUDF_PH_CALL_CONTEXT Context = (PUDF_PH_CALL_CONTEXT)Contxt;
PMDL Mdl, NextMdl;
Context->IosbToUse = Irp->IoStatus;
#if 1
// Unlock pages that are described by MDL (if any)...
Mdl = Irp->MdlAddress;
while(Mdl) {
MmPrint((" Unlock MDL=%x\n", Mdl));
MmUnlockPages(Mdl);
Mdl = Mdl->Next;
}
// ... and free MDL
Mdl = Irp->MdlAddress;
while(Mdl) {
MmPrint((" Free MDL=%x\n", Mdl));
NextMdl = Mdl->Next;
IoFreeMdl(Mdl);
Mdl = NextMdl;
}
Irp->MdlAddress = NULL;
IoFreeIrp(Irp);
KeSetEvent( &(Context->event), 0, FALSE );
return STATUS_MORE_PROCESSING_REQUIRED;
#else
KeSetEvent( &(Context->event), 0, FALSE );
return STATUS_SUCCESS;
#endif
} // end UDFAsyncCompletionRoutine()
NTSTATUS
NTAPI
UDFSyncCompletionRoutine(
IN PDEVICE_OBJECT DeviceObject,
IN PIRP Irp,
IN PVOID Contxt
)
{
UDFPrint(("UDFSyncCompletionRoutine ctx=%x\n", Contxt));
PUDF_PH_CALL_CONTEXT Context = (PUDF_PH_CALL_CONTEXT)Contxt;
Context->IosbToUse = Irp->IoStatus;
//KeSetEvent( &(Context->event), 0, FALSE );
return STATUS_SUCCESS;
} // end UDFSyncCompletionRoutine()
/*
NTSTATUS
UDFSyncCompletionRoutine2(
IN PDEVICE_OBJECT DeviceObject,
IN PIRP Irp,
IN PVOID Contxt
)
{
UDFPrint(("UDFSyncCompletionRoutine2\n"));
PKEVENT SyncEvent = (PKEVENT)Contxt;
KeSetEvent( SyncEvent, 0, FALSE );
return STATUS_SUCCESS;
} // end UDFSyncCompletionRoutine2()
*/
/*
Function: UDFPhReadSynchronous()
Description:
UDFFSD will invoke this rotine to read physical device synchronously/asynchronously
Expected Interrupt Level (for execution) :
<= IRQL_DISPATCH_LEVEL
Return Value: STATUS_SUCCESS/Error
*/
NTSTATUS
NTAPI
UDFPhReadSynchronous(
PDEVICE_OBJECT DeviceObject, // the physical device object
PVOID Buffer,
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SIZE_T Length,
LONGLONG Offset,
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PSIZE_T ReadBytes,
ULONG Flags
)
{
NTSTATUS RC = STATUS_SUCCESS;
LARGE_INTEGER ROffset;
PUDF_PH_CALL_CONTEXT Context;
PIRP irp;
KIRQL CurIrql = KeGetCurrentIrql();
PVOID IoBuf = NULL;
// ULONG i;
#ifdef MEASURE_IO_PERFORMANCE
LONGLONG IoEnterTime;
LONGLONG IoExitTime;
ULONG dt;
ULONG dtm;
#endif //MEASURE_IO_PERFORMANCE
#ifdef _BROWSE_UDF_
PVCB Vcb = NULL;
if(Flags & PH_VCB_IN_RETLEN) {
Vcb = (PVCB)(*ReadBytes);
}
#endif //_BROWSE_UDF_
#ifdef MEASURE_IO_PERFORMANCE
KeQuerySystemTime((PLARGE_INTEGER)&IoEnterTime);
#endif //MEASURE_IO_PERFORMANCE
UDFPrint(("UDFPhRead: Length: %x Lba: %lx\n",Length>>0xb,Offset>>0xb));
// UDFPrint(("UDFPhRead: Length: %x Lba: %lx\n",Length>>0x9,Offset>>0x9));
ROffset.QuadPart = Offset;
(*ReadBytes) = 0;
/*
// DEBUG !!!
Flags |= PH_TMP_BUFFER;
*/
if(Flags & PH_TMP_BUFFER) {
IoBuf = Buffer;
} else {
IoBuf = DbgAllocatePoolWithTag(NonPagedPool, Length, 'bNWD');
}
if (!IoBuf) {
UDFPrint((" !IoBuf\n"));
return STATUS_INSUFFICIENT_RESOURCES;
}
Context = (PUDF_PH_CALL_CONTEXT)MyAllocatePool__( NonPagedPool, sizeof(UDF_PH_CALL_CONTEXT) );
if (!Context) {
UDFPrint((" !Context\n"));
try_return(RC = STATUS_INSUFFICIENT_RESOURCES);
}
// Create notification event object to be used to signal the request completion.
KeInitializeEvent(&(Context->event), NotificationEvent, FALSE);
if (CurIrql > PASSIVE_LEVEL) {
irp = IoBuildAsynchronousFsdRequest(IRP_MJ_READ, DeviceObject, IoBuf,
Length, &ROffset, &(Context->IosbToUse) );
if (!irp) {
UDFPrint((" !irp Async\n"));
try_return(RC = STATUS_INSUFFICIENT_RESOURCES);
}
MmPrint((" Alloc async Irp MDL=%x, ctx=%x\n", irp->MdlAddress, Context));
IoSetCompletionRoutine( irp, &UDFAsyncCompletionRoutine,
Context, TRUE, TRUE, TRUE );
} else {
irp = IoBuildSynchronousFsdRequest(IRP_MJ_READ, DeviceObject, IoBuf,
Length, &ROffset, &(Context->event), &(Context->IosbToUse) );
if (!irp) {
UDFPrint((" !irp Sync\n"));
try_return(RC = STATUS_INSUFFICIENT_RESOURCES);
}
MmPrint((" Alloc Irp MDL=%x, ctx=%x\n", irp->MdlAddress, Context));
}
(IoGetNextIrpStackLocation(irp))->Flags |= SL_OVERRIDE_VERIFY_VOLUME;
RC = IoCallDriver(DeviceObject, irp);
if (RC == STATUS_PENDING) {
DbgWaitForSingleObject(&(Context->event), NULL);
if ((RC = Context->IosbToUse.Status) == STATUS_DATA_OVERRUN) {
RC = STATUS_SUCCESS;
}
// *ReadBytes = Context->IosbToUse.Information;
} else {
// *ReadBytes = irp->IoStatus.Information;
}
if(NT_SUCCESS(RC)) {
(*ReadBytes) = Context->IosbToUse.Information;
}
if(!(Flags & PH_TMP_BUFFER)) {
RtlCopyMemory(Buffer, IoBuf, *ReadBytes);
}
if(NT_SUCCESS(RC)) {
/*
for(i=0; i<(*ReadBytes); i+=2048) {
UDFPrint(("IOCRC %8.8x R %x\n", crc32((PUCHAR)Buffer+i, 2048), (ULONG)((Offset+i)/2048) ));
}
*/
#ifdef _BROWSE_UDF_
if(Vcb) {
RC = UDFVRead(Vcb, IoBuf, Length >> Vcb->BlockSizeBits, (ULONG)(Offset >> Vcb->BlockSizeBits), Flags);
}
#endif //_BROWSE_UDF_
}
try_exit: NOTHING;
if(Context) MyFreePool__(Context);
if(IoBuf && !(Flags & PH_TMP_BUFFER)) DbgFreePool(IoBuf);
#ifdef MEASURE_IO_PERFORMANCE
KeQuerySystemTime((PLARGE_INTEGER)&IoExitTime);
IoReadTime += (IoExitTime-IoEnterTime);
dt = (ULONG)((IoExitTime-IoEnterTime)/10/1000);
dtm = (ULONG)(((IoExitTime-IoEnterTime)/10)%1000);
PerfPrint(("\nUDFPhReadSynchronous() exit: %08X, after %d.%4.4d msec.\n", RC, dt, dtm));
#else
UDFPrint(("UDFPhReadSynchronous() exit: %08X\n", RC));
#endif //MEASURE_IO_PERFORMANCE
return(RC);
} // end UDFPhReadSynchronous()
/*
Function: UDFPhWriteSynchronous()
Description:
UDFFSD will invoke this rotine to write physical device synchronously
Expected Interrupt Level (for execution) :
<= IRQL_DISPATCH_LEVEL
Return Value: STATUS_SUCCESS/Error
*/
NTSTATUS
NTAPI
UDFPhWriteSynchronous(
PDEVICE_OBJECT DeviceObject, // the physical device object
PVOID Buffer,
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SIZE_T Length,
LONGLONG Offset,
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PSIZE_T WrittenBytes,
ULONG Flags
)
{
NTSTATUS RC = STATUS_SUCCESS;
LARGE_INTEGER ROffset;
PUDF_PH_CALL_CONTEXT Context;
PIRP irp;
// LARGE_INTEGER timeout;
KIRQL CurIrql = KeGetCurrentIrql();
PVOID IoBuf = NULL;
// ULONG i;
#ifdef MEASURE_IO_PERFORMANCE
LONGLONG IoEnterTime;
LONGLONG IoExitTime;
ULONG dt;
ULONG dtm;
#endif //MEASURE_IO_PERFORMANCE
#ifdef _BROWSE_UDF_
PVCB Vcb = NULL;
if(Flags & PH_VCB_IN_RETLEN) {
Vcb = (PVCB)(*WrittenBytes);
}
#endif //_BROWSE_UDF_
#ifdef MEASURE_IO_PERFORMANCE
KeQuerySystemTime((PLARGE_INTEGER)&IoEnterTime);
#endif //MEASURE_IO_PERFORMANCE
#ifdef USE_PERF_PRINT
ULONG Lba = (ULONG)(Offset>>0xb);
// ASSERT(!(Lba & (32-1)));
PerfPrint(("UDFPhWrite: Length: %x Lba: %lx\n",Length>>0xb,Lba));
// UDFPrint(("UDFPhWrite: Length: %x Lba: %lx\n",Length>>0x9,Offset>>0x9));
#endif //DBG
#ifdef DBG
if(UDF_SIMULATE_WRITES) {
/* FIXME ReactOS
If this function is to force a read from the bufffer to simulate any segfaults, then it makes sense.
Else, this forloop is useless.
UCHAR a;
for(ULONG i=0; i<Length; i++) {
a = ((PUCHAR)Buffer)[i];
}
*/
*WrittenBytes = Length;
return STATUS_SUCCESS;
}
#endif //DBG
ROffset.QuadPart = Offset;
(*WrittenBytes) = 0;
/* IoBuf = ExAllocatePool(NonPagedPool, Length);
if (!IoBuf) return STATUS_INSUFFICIENT_RESOURCES;
RtlCopyMemory(IoBuf, Buffer, Length);*/
IoBuf = Buffer;
/* if(Flags & PH_TMP_BUFFER) {
IoBuf = Buffer;
} else {
IoBuf = DbgAllocatePool(NonPagedPool, Length);
RtlCopyMemory(IoBuf, Buffer, Length);
}*/
Context = (PUDF_PH_CALL_CONTEXT)MyAllocatePool__( NonPagedPool, sizeof(UDF_PH_CALL_CONTEXT) );
if (!Context) try_return (RC = STATUS_INSUFFICIENT_RESOURCES);
// Create notification event object to be used to signal the request completion.
KeInitializeEvent(&(Context->event), NotificationEvent, FALSE);
if (CurIrql > PASSIVE_LEVEL) {
irp = IoBuildAsynchronousFsdRequest(IRP_MJ_WRITE, DeviceObject, IoBuf,
Length, &ROffset, &(Context->IosbToUse) );
if (!irp) try_return(RC = STATUS_INSUFFICIENT_RESOURCES);
MmPrint((" Alloc async Irp MDL=%x, ctx=%x\n", irp->MdlAddress, Context));
IoSetCompletionRoutine( irp, &UDFAsyncCompletionRoutine,
Context, TRUE, TRUE, TRUE );
} else {
irp = IoBuildSynchronousFsdRequest(IRP_MJ_WRITE, DeviceObject, IoBuf,
Length, &ROffset, &(Context->event), &(Context->IosbToUse) );
if (!irp) try_return(RC = STATUS_INSUFFICIENT_RESOURCES);
MmPrint((" Alloc Irp MDL=%x\n, ctx=%x", irp->MdlAddress, Context));
}
(IoGetNextIrpStackLocation(irp))->Flags |= SL_OVERRIDE_VERIFY_VOLUME;
RC = IoCallDriver(DeviceObject, irp);
/*
for(i=0; i<Length; i+=2048) {
UDFPrint(("IOCRC %8.8x W %x\n", crc32((PUCHAR)Buffer+i, 2048), (ULONG)((Offset+i)/2048) ));
}
*/
#ifdef _BROWSE_UDF_
if(Vcb) {
UDFVWrite(Vcb, IoBuf, Length >> Vcb->BlockSizeBits, (ULONG)(Offset >> Vcb->BlockSizeBits), Flags);
}
#endif //_BROWSE_UDF_
if (RC == STATUS_PENDING) {
DbgWaitForSingleObject(&(Context->event), NULL);
if ((RC = Context->IosbToUse.Status) == STATUS_DATA_OVERRUN) {
RC = STATUS_SUCCESS;
}
// *WrittenBytes = Context->IosbToUse.Information;
} else {
// *WrittenBytes = irp->IoStatus.Information;
}
if(NT_SUCCESS(RC)) {
(*WrittenBytes) = Context->IosbToUse.Information;
}
try_exit: NOTHING;
if(Context) MyFreePool__(Context);
// if(IoBuf) ExFreePool(IoBuf);
// if(IoBuf && !(Flags & PH_TMP_BUFFER)) DbgFreePool(IoBuf);
if(!NT_SUCCESS(RC)) {
UDFPrint(("WriteError\n"));
}
#ifdef MEASURE_IO_PERFORMANCE
KeQuerySystemTime((PLARGE_INTEGER)&IoExitTime);
IoWriteTime += (IoExitTime-IoEnterTime);
if (WrittenData > 1024*1024*8) {
PerfPrint(("\nUDFPhWriteSynchronous() Relative size=%I64d, time=%I64d.\n", WrittenData, IoRelWriteTime));
WrittenData = IoRelWriteTime = 0;
}
WrittenData += Length;
IoRelWriteTime += (IoExitTime-IoEnterTime);
dt = (ULONG)((IoExitTime-IoEnterTime)/10/1000);
dtm = (ULONG)(((IoExitTime-IoEnterTime)/10)%1000);
PerfPrint(("\nUDFPhWriteSynchronous() exit: %08X, after %d.%4.4d msec.\n", RC, dt, dtm));
#else
UDFPrint(("nUDFPhWriteSynchronous() exit: %08X\n", RC));
#endif //MEASURE_IO_PERFORMANCE
return(RC);
} // end UDFPhWriteSynchronous()
#if 0
NTSTATUS
UDFPhWriteVerifySynchronous(
PDEVICE_OBJECT DeviceObject, // the physical device object
PVOID Buffer,
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SIZE_T Length,
LONGLONG Offset,
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PSIZE_T WrittenBytes,
ULONG Flags
)
{
NTSTATUS RC;
//PUCHAR v_buff = NULL;
//ULONG ReadBytes;
RC = UDFPhWriteSynchronous(DeviceObject, Buffer, Length, Offset, WrittenBytes, Flags);
/*
if(!Verify)
return RC;
v_buff = (PUCHAR)DbgAllocatePoolWithTag(NonPagedPool, Length, 'bNWD');
if(!v_buff)
return RC;
RC = UDFPhReadSynchronous(DeviceObject, v_buff, Length, Offset, &ReadBytes, Flags);
if(!NT_SUCCESS(RC)) {
BrutePoint();
DbgFreePool(v_buff);
return RC;
}
if(RtlCompareMemory(v_buff, Buffer, ReadBytes) == Length) {
DbgFreePool(v_buff);
return RC;
}
BrutePoint();
DbgFreePool(v_buff);
return STATUS_LOST_WRITEBEHIND_DATA;
*/
return RC;
} // end UDFPhWriteVerifySynchronous()
#endif //0
NTSTATUS
NTAPI
UDFTSendIOCTL(
IN ULONG IoControlCode,
IN PVCB Vcb,
IN PVOID InputBuffer ,
IN ULONG InputBufferLength,
OUT PVOID OutputBuffer ,
IN ULONG OutputBufferLength,
IN BOOLEAN OverrideVerify,
OUT PIO_STATUS_BLOCK Iosb OPTIONAL
)
{
NTSTATUS RC = STATUS_SUCCESS;
BOOLEAN Acquired;
Acquired = UDFAcquireResourceExclusiveWithCheck(&(Vcb->IoResource));
_SEH2_TRY {
RC = UDFPhSendIOCTL(IoControlCode,
Vcb->TargetDeviceObject,
InputBuffer ,
InputBufferLength,
OutputBuffer ,
OutputBufferLength,
OverrideVerify,
Iosb
);
} _SEH2_FINALLY {
if(Acquired)
UDFReleaseResource(&(Vcb->IoResource));
} _SEH2_END;
return RC;
} // end UDFTSendIOCTL()
/*
Function: UDFPhSendIOCTL()
Description:
UDF FSD will invoke this rotine to send IOCTL's to physical
device
Return Value: STATUS_SUCCESS/Error
*/
NTSTATUS
NTAPI
UDFPhSendIOCTL(
IN ULONG IoControlCode,
IN PDEVICE_OBJECT DeviceObject,
IN PVOID InputBuffer ,
IN ULONG InputBufferLength,
OUT PVOID OutputBuffer ,
IN ULONG OutputBufferLength,
IN BOOLEAN OverrideVerify,
OUT PIO_STATUS_BLOCK Iosb OPTIONAL
)
{
NTSTATUS RC = STATUS_SUCCESS;
PIRP irp;
PUDF_PH_CALL_CONTEXT Context;
LARGE_INTEGER timeout;
UDFPrint(("UDFPhDevIOCTL: Code %8x \n",IoControlCode));
Context = (PUDF_PH_CALL_CONTEXT)MyAllocatePool__( NonPagedPool, sizeof(UDF_PH_CALL_CONTEXT) );
if (!Context) return STATUS_INSUFFICIENT_RESOURCES;
// Check if the user gave us an Iosb.
// Create notification event object to be used to signal the request completion.
KeInitializeEvent(&(Context->event), NotificationEvent, FALSE);
irp = IoBuildDeviceIoControlRequest(IoControlCode, DeviceObject, InputBuffer ,
InputBufferLength, OutputBuffer, OutputBufferLength,FALSE,&(Context->event),&(Context->IosbToUse));
if (!irp) try_return (RC = STATUS_INSUFFICIENT_RESOURCES);
MmPrint((" Alloc Irp MDL=%x, ctx=%x\n", irp->MdlAddress, Context));
/*
if (KeGetCurrentIrql() > PASSIVE_LEVEL) {
UDFPrint(("Setting completion routine\n"));
IoSetCompletionRoutine( irp, &UDFSyncCompletionRoutine,
Context, TRUE, TRUE, TRUE );
}
*/
if(OverrideVerify) {
(IoGetNextIrpStackLocation(irp))->Flags |= SL_OVERRIDE_VERIFY_VOLUME;
}
RC = IoCallDriver(DeviceObject, irp);
if (RC == STATUS_PENDING) {
ASSERT(KeGetCurrentIrql() < DISPATCH_LEVEL);
UDFPrint(("Enter wait state on evt %x\n", Context));
if (KeGetCurrentIrql() > PASSIVE_LEVEL) {
timeout.QuadPart = -1000;
UDFPrint(("waiting, TO=%I64d\n", timeout.QuadPart));
RC = DbgWaitForSingleObject(&(Context->event), &timeout);
while(RC == STATUS_TIMEOUT) {
timeout.QuadPart *= 2;
UDFPrint(("waiting, TO=%I64d\n", timeout.QuadPart));
RC = DbgWaitForSingleObject(&(Context->event), &timeout);
}
} else {
DbgWaitForSingleObject(&(Context->event), NULL);
}
if ((RC = Context->IosbToUse.Status) == STATUS_DATA_OVERRUN) {
RC = STATUS_SUCCESS;
}
UDFPrint(("Exit wait state on evt %x, status %8.8x\n", Context, RC));
/* if(Iosb) {
(*Iosb) = Context->IosbToUse;
}*/
} else {
UDFPrint(("No wait completion on evt %x\n", Context));
/* if(Iosb) {
(*Iosb) = irp->IoStatus;
}*/
}
if(Iosb) {
(*Iosb) = Context->IosbToUse;
}
try_exit: NOTHING;
if(Context) MyFreePool__(Context);
return(RC);
} // end UDFPhSendIOCTL()
#ifdef UDF_DBG
VOID
UDFNotifyFullReportChange(
PVCB V,
PUDF_FILE_INFO FI,
ULONG E,
ULONG A
)
{
if((FI)->ParentFile) {
FsRtlNotifyFullReportChange( (V)->NotifyIRPMutex, &((V)->NextNotifyIRP),
(PSTRING)&((FI)->Fcb->FCBName->ObjectName),
((FI)->ParentFile->Fcb->FCBName->ObjectName.Length + sizeof(WCHAR)),
NULL,NULL,
E, A,
NULL);
} else {
FsRtlNotifyFullReportChange( (V)->NotifyIRPMutex, &((V)->NextNotifyIRP),
(PSTRING)&((FI)->Fcb->FCBName->ObjectName),
0,
NULL,NULL,
E, A,
NULL);
}
} // end UDFNotifyFullReportChange()
VOID
UDFNotifyVolumeEvent(
IN PFILE_OBJECT FileObject,
IN ULONG EventCode
)
{
/* ReactOS FIXME This is always true, and we return anyway. */
// if(!FsRtlNotifyVolumeEvent)
return;
//FsRtlNotifyVolumeEvent(FileObject, EventCode);
} // end UDFNotifyVolumeEvent()
#endif // UDF_DBG