635 lines
17 KiB
C
635 lines
17 KiB
C
/*++
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Copyright (c) 1989 Microsoft Corporation
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Copyright (c) 1992 Digital Equipment Corporation
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Module Name:
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physsect.c
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Abstract:
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This module contains the routine for mapping physical sections for
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ALPHA machines.
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Author:
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Lou Perazzoli (loup) 22-May-1989
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Joe Notarangelo 21-Sep-1992
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Revision History:
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--*/
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#include "mi.h"
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//#define FIRSTDBG 1
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//#define AGGREGATE_DBG FIRSTDBG
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static
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ULONG
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MaximumAlignment(
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ULONG Offset
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);
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static
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ULONG
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AggregatePages(
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PMMPTE,
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PFN_NUMBER,
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ULONG,
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PULONG
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);
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NTSTATUS
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MiMapViewOfPhysicalSection (
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IN PCONTROL_AREA ControlArea,
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IN PEPROCESS Process,
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IN PVOID *CapturedBase,
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IN PLARGE_INTEGER SectionOffset,
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IN PSIZE_T CapturedViewSize,
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IN ULONG ProtectionMask,
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IN ULONG_PTR ZeroBits,
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IN ULONG AllocationType,
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IN BOOLEAN WriteCombined,
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OUT PBOOLEAN ReleasedWsMutex
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)
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/*++
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Routine Description:
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This routine maps the specified physical section into the
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specified process's address space.
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Arguments:
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see MmMapViewOfSection above...
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ControlArea - Supplies the control area for the section.
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Process - Supplies the process pointer which is receiving the section.
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ProtectionMask - Supplies the initial page protection-mask.
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ReleasedWsMutex - Supplies FALSE, receives TRUE if the working set
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mutex is released.
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Return Value:
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Status of the map view operation.
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Environment:
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Kernel Mode, working set mutex and address creation mutex held.
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--*/
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{
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PMMVAD Vad;
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PVOID StartingAddress;
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PVOID EndingAddress;
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KIRQL OldIrql;
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PMMPTE PointerPpe;
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PMMPTE PointerPde;
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PMMPTE PointerPte;
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PMMPTE LastPte;
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MMPTE TempPte;
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PMMPFN Pfn2;
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SIZE_T PhysicalViewSize;
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ULONG Alignment;
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ULONG PagesToMap;
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PFN_NUMBER NextPfn;
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PVOID UsedPageTableHandle;
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PVOID UsedPageDirectoryHandle;
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PMI_PHYSICAL_VIEW PhysicalView;
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//
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// Physical memory section.
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//
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#ifdef FIRSTDBG
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DbgPrint( "MM: Physsect CaptureBase = %x SectionOffset = %x\n",
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CapturedBase, SectionOffset->LowPart );
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DbgPrint( "MM: Physsect Allocation Type = %x, MEM_LARGE_PAGES = %x\n",
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AllocationType, MEM_LARGE_PAGES );
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#endif //FIRSTDBG
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//
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// Compute the alignment we require for the virtual mapping.
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// The default is 64K to match protection boundaries.
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// Larger page sizes are used if MEM_LARGE_PAGES is requested.
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// The Alpha AXP architecture supports granularity hints so that
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// larger pages can be defined in the following multiples of
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// PAGE_SIZE:
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// 8**(GH) * PAGE_SIZE, where GH element of {0,1,2,3}
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//
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Alignment = X64K;
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if( AllocationType & MEM_LARGE_PAGES ){
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//
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// MaxAlignment is the maximum boundary alignment of the
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// SectionOffset (where the maximum boundary is one of the possible
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// granularity hints boundaries)
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//
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ULONG MaxAlignment = MaximumAlignment( SectionOffset->LowPart );
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Alignment = (MaxAlignment > Alignment) ? MaxAlignment : Alignment;
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#ifdef FIRSTDBG
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DbgPrint( "MM: Alignment = %x, SectionOffset = %x\n",
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Alignment, SectionOffset->LowPart );
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#endif //FIRSTDBG
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}
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LOCK_WS (Process);
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if (*CapturedBase == NULL) {
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//
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// Attempt to locate address space. This could raise an
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// exception.
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//
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try {
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//
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// Find a starting address on an alignment boundary.
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//
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PhysicalViewSize = (SectionOffset->LowPart + *CapturedViewSize) -
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(ULONG_PTR)MI_64K_ALIGN(SectionOffset->LowPart);
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StartingAddress = MiFindEmptyAddressRange (PhysicalViewSize,
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Alignment,
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(ULONG)ZeroBits);
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} except (EXCEPTION_EXECUTE_HANDLER) {
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return GetExceptionCode();
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}
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EndingAddress = (PVOID)(((ULONG_PTR)StartingAddress +
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PhysicalViewSize - 1L) | (PAGE_SIZE - 1L));
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StartingAddress = (PVOID)((ULONG_PTR)StartingAddress +
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(SectionOffset->LowPart & (X64K - 1)));
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if (ZeroBits > 0) {
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if (EndingAddress > (PVOID)((LONG_PTR)0xFFFFFFFF >> ZeroBits)) {
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return STATUS_NO_MEMORY;
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}
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}
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} else {
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//
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// Check to make sure the specified base address to ending address
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// is currently unused.
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//
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PhysicalViewSize = (SectionOffset->LowPart + *CapturedViewSize) -
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(ULONG_PTR)MI_64K_ALIGN(SectionOffset->LowPart);
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StartingAddress = (PVOID)((ULONG_PTR)MI_64K_ALIGN(*CapturedBase) +
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(SectionOffset->LowPart & (X64K - 1)));
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EndingAddress = (PVOID)(((ULONG_PTR)StartingAddress +
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*CapturedViewSize - 1L) | (PAGE_SIZE - 1L));
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Vad = MiCheckForConflictingVad (StartingAddress, EndingAddress);
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if (Vad != (PMMVAD)NULL) {
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#if 0
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MiDumpConflictingVad (StartingAddress, EndingAddress, Vad);
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#endif
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return STATUS_CONFLICTING_ADDRESSES;
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}
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}
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//
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// An unoccuppied address range has been found, build the virtual
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// address descriptor to describe this range.
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//
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//
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// Establish an exception handler and attempt to allocate
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// the pool and charge quota. Note that the InsertVad routine
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// will also charge quota which could raise an exception.
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//
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try {
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PhysicalView = (PMI_PHYSICAL_VIEW)ExAllocatePoolWithTag (NonPagedPool,
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sizeof(MI_PHYSICAL_VIEW),
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MI_PHYSICAL_VIEW_KEY);
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if (PhysicalView == NULL) {
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ExRaiseStatus (STATUS_INSUFFICIENT_RESOURCES);
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}
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Vad = (PMMVAD)ExAllocatePoolWithTag (NonPagedPool, sizeof(MMVAD), ' daV');
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if (Vad == NULL) {
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ExRaiseStatus (STATUS_INSUFFICIENT_RESOURCES);
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}
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PhysicalView->Vad = Vad;
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PhysicalView->StartVa = StartingAddress;
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PhysicalView->EndVa = EndingAddress;
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Vad->StartingVpn = MI_VA_TO_VPN (StartingAddress);
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Vad->EndingVpn = MI_VA_TO_VPN (EndingAddress);
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Vad->ControlArea = ControlArea;
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Vad->u.LongFlags = 0;
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Vad->u2.VadFlags2.Inherit = ViewUnmap;
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Vad->u.VadFlags.PhysicalMapping = 1;
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Vad->u4.Banked = NULL;
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// Vad->u.VadFlags.ImageMap = 0;
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Vad->u.VadFlags.Protection = ProtectionMask;
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Vad->u2.VadFlags2.CopyOnWrite = 0;
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// Vad->u.VadFlags.LargePages = 0;
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Vad->FirstPrototypePte =
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(PMMPTE)(MI_CONVERT_PHYSICAL_BUS_TO_PFN(*SectionOffset));
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//
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// Set the first prototype PTE field in the Vad.
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//
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Vad->LastContiguousPte =
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(PMMPTE)(MI_CONVERT_PHYSICAL_BUS_TO_PFN(*SectionOffset));
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//
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// Insert the VAD. This could get an exception.
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//
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MiInsertVad (Vad);
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} except (EXCEPTION_EXECUTE_HANDLER) {
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if (PhysicalView != NULL) {
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ExFreePool (PhysicalView);
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}
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if (Vad != (PMMVAD)NULL) {
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//
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// The pool allocation suceeded, but the quota charge
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// in InsertVad failed, deallocate the pool and return
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// and error.
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//
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ExFreePool (Vad);
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return GetExceptionCode();
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}
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return STATUS_INSUFFICIENT_RESOURCES;
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}
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// Increment the count of the number of views for the
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// section object. This requires the PFN mutex to be held.
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//
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LOCK_AWE (Process, OldIrql);
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LOCK_PFN_AT_DPC ();
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if (PhysicalView->Vad->u.VadFlags.PhysicalMapping == 1) {
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Process->HasPhysicalVad = 1;
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}
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InsertHeadList (&Process->PhysicalVadList, &PhysicalView->ListEntry);
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ControlArea->NumberOfMappedViews += 1;
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ControlArea->NumberOfUserReferences += 1;
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ASSERT (ControlArea->NumberOfSectionReferences != 0);
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UNLOCK_PFN_FROM_DPC ();
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UNLOCK_AWE (Process, OldIrql);
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//
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// Build the PTEs in the address space.
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//
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PointerPpe = MiGetPpeAddress (StartingAddress);
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PointerPde = MiGetPdeAddress (StartingAddress);
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PointerPte = MiGetPteAddress (StartingAddress);
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LastPte = MiGetPteAddress (EndingAddress);
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#if defined (_WIN64)
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MiMakePpeExistAndMakeValid (PointerPpe, Process, FALSE);
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if (PointerPde->u.Long == 0) {
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UsedPageDirectoryHandle = MI_GET_USED_PTES_HANDLE (PointerPte);
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ASSERT (MI_GET_USED_PTES_FROM_HANDLE (UsedPageDirectoryHandle) == 0);
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MI_INCREMENT_USED_PTES_BY_HANDLE (UsedPageDirectoryHandle);
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}
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#endif
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MiMakePdeExistAndMakeValid(PointerPde, Process, FALSE);
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Pfn2 = MI_PFN_ELEMENT(PointerPde->u.Hard.PageFrameNumber);
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PagesToMap = (ULONG)((((ULONG_PTR)EndingAddress - (ULONG_PTR)StartingAddress))
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+ (PAGE_SIZE-1) ) >> PAGE_SHIFT;
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NextPfn = MI_CONVERT_PHYSICAL_BUS_TO_PFN(*SectionOffset);
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#ifdef FIRSTDBG
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DbgPrint( "MM: Physsect, PagesToMap = %x NextPfn = %x\n",
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PagesToMap, NextPfn );
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#endif //FIRSTDBG
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MI_MAKE_VALID_PTE (TempPte,
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NextPfn,
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ProtectionMask,
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PointerPte);
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if (WriteCombined == TRUE) {
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MI_SET_PTE_WRITE_COMBINE (TempPte);
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}
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if (TempPte.u.Hard.Write) {
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TempPte.u.Hard.FaultOnWrite = 1;
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}
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while (PointerPte <= LastPte) {
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ULONG PagesTogether;
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ULONG GranularityHint;
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//
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// Compute the number of pages that can be mapped together
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//
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if( AllocationType & MEM_LARGE_PAGES ){
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PagesTogether = AggregatePages( PointerPte,
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NextPfn,
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PagesToMap,
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&GranularityHint );
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} else {
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PagesTogether = 1;
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GranularityHint = 0;
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}
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#ifdef FIRSTDBG
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DbgPrint( "MM: Physsect PointerPte = %x, NextPfn = %x\n",
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PointerPte, NextPfn );
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DbgPrint( "MM: Va = %x TempPte.Pfn = %x\n",
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MiGetVirtualAddressMappedByPte( PointerPte ),
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TempPte.u.Hard.PageFrameNumber );
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DbgPrint( "MM: PagesToMap = %x\n", PagesToMap );
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DbgPrint( "MM: PagesTogether = %x, GH = %x\n",
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PagesTogether, GranularityHint );
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#endif //FIRSTDBG
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TempPte.u.Hard.GranularityHint = GranularityHint;
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NextPfn += PagesTogether;
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PagesToMap -= PagesTogether;
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UsedPageTableHandle = MI_GET_USED_PTES_HANDLE (MiGetVirtualAddressMappedByPte (PointerPte));
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while( PagesTogether-- ){
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if (MiIsPteOnPdeBoundary (PointerPte)) {
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PointerPde = MiGetPteAddress (PointerPte);
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if (MiIsPteOnPpeBoundary (PointerPte)) {
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PointerPpe = MiGetPteAddress (PointerPde);
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MiMakePpeExistAndMakeValid (PointerPpe, Process, FALSE);
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if (PointerPde->u.Long == 0) {
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UsedPageDirectoryHandle = MI_GET_USED_PTES_HANDLE (PointerPte);
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ASSERT (MI_GET_USED_PTES_FROM_HANDLE (UsedPageDirectoryHandle) == 0);
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MI_INCREMENT_USED_PTES_BY_HANDLE (UsedPageDirectoryHandle);
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}
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}
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MiMakePdeExistAndMakeValid (PointerPde, Process, FALSE);
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Pfn2 = MI_PFN_ELEMENT (PointerPde->u.Hard.PageFrameNumber);
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UsedPageTableHandle = MI_GET_USED_PTES_HANDLE (MiGetVirtualAddressMappedByPte (PointerPte));
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}
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ASSERT( PointerPte->u.Long == 0 );
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*PointerPte = TempPte;
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#if PFN_CONSISTENCY
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LOCK_PFN (OldIrql);
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#endif
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Pfn2->u2.ShareCount += 1;
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#if PFN_CONSISTENCY
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UNLOCK_PFN (OldIrql);
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#endif
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//
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// Increment the count of non-zero page table entries for this
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// page table and the number of private pages for the process.
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//
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MI_INCREMENT_USED_PTES_BY_HANDLE (UsedPageTableHandle);
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PointerPte += 1;
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TempPte.u.Hard.PageFrameNumber += 1;
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} // while (PagesTogether-- )
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} // while (PointerPte <= LastPte)
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UNLOCK_WS (Process);
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*ReleasedWsMutex = TRUE;
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//
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// Update the current virtual size in the process header.
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//
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*CapturedViewSize = (ULONG)((ULONG_PTR)EndingAddress - (ULONG_PTR)StartingAddress + 1L);
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Process->VirtualSize += *CapturedViewSize;
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if (Process->VirtualSize > Process->PeakVirtualSize) {
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Process->PeakVirtualSize = Process->VirtualSize;
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}
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//
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// Translate the virtual address to a quasi-virtual address for
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// use by drivers that touch mapped devices. Note: the routine
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// HalCreateQva will not translate the StartingAddress if the
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// StartingAddress is within system memory address space.
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//
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// N.B. - It will not work to attempt map addresses that begin in
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// system memory and extend through i/o space.
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//
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*CapturedBase = HalCreateQva( *SectionOffset, StartingAddress );
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return STATUS_SUCCESS;
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}
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ULONG
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MaximumAlignment(
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IN ULONG Offset
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)
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/*++
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Routine Description:
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This routine returns the maximum granularity hint alignment boundary
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to which Offset is naturally aligned.
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Arguments:
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Offset - Supplies the address offset to check for alignment.
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Return Value:
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The number which represents the largest natural alignment of Offset.
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Environment:
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--*/
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{
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if( (Offset & (GH3_PAGE_SIZE - 1)) == 0 ){
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return GH3_PAGE_SIZE;
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}
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if( (Offset & (GH2_PAGE_SIZE - 1)) == 0 ){
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return GH2_PAGE_SIZE;
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}
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if( (Offset & (GH1_PAGE_SIZE - 1)) == 0 ){
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return GH1_PAGE_SIZE;
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}
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if( (Offset & (PAGE_SIZE - 1)) == 0 ){
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return PAGE_SIZE;
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}
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return 0;
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}
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ULONG
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AggregatePages(
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IN PMMPTE PointerPte,
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IN PFN_NUMBER Pfn,
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IN ULONG Pages,
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OUT PULONG GranularityHint
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)
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/*++
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Routine Description:
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This routine computes the number of standard size pages that can be
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aggregated into a single large page and returns the granularity hint
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for that size large page.
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Arguments:
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PointerPte - Supplies the PTE pointer for the starting virtual address
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of the mapping.
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Pfn - Supplies the starting page frame number of the memory to be
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mapped.
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Pages - Supplies the number of pages to map.
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GranularityHint - Receives the granularity hint for the large page used
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to aggregate the standard pages.
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Return Value:
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The number of pages that can be aggregated together.
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Environment:
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--*/
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{
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ULONG MaxVirtualAlignment;
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ULONG MaxPhysicalAlignment;
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ULONG MaxPageAlignment;
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ULONG MaxAlignment;
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//
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// Determine the largest page that will map a maximum of Pages.
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// The largest page must be both virtually and physically aligned
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// to the large page size boundary.
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// Determine the largest common alignment for the virtual and
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// physical addresses, factor in Pages, and then match to the
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// largest page size possible via the granularity hints.
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//
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MaxVirtualAlignment =
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MaximumAlignment((ULONG)((ULONG_PTR)MiGetVirtualAddressMappedByPte(PointerPte)));
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MaxPhysicalAlignment = MaximumAlignment( (ULONG)(Pfn << PAGE_SHIFT) );
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MaxPageAlignment = (ULONG)(Pages << PAGE_SHIFT);
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#ifdef AGGREGATE_DBG
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DbgPrint( "MM: Aggregate MaxVirtualAlign = %x\n", MaxVirtualAlignment );
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DbgPrint( "MM: Aggregate MaxPhysicalAlign = %x\n", MaxPhysicalAlignment );
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||
DbgPrint( "MM: Aggregate MaxPageAlign = %x\n", MaxPageAlignment );
|
||
|
||
#endif //AGGREGATE_DBG
|
||
//
|
||
// Maximum alignment is the minimum of the virtual and physical alignments.
|
||
//
|
||
|
||
MaxAlignment = (MaxVirtualAlignment > MaxPhysicalAlignment) ?
|
||
MaxPhysicalAlignment : MaxVirtualAlignment;
|
||
MaxAlignment = (MaxAlignment > MaxPageAlignment) ?
|
||
MaxPageAlignment : MaxAlignment;
|
||
|
||
//
|
||
// Convert MaxAlignment to granularity hint value
|
||
//
|
||
|
||
if( (MaxAlignment & (GH3_PAGE_SIZE - 1)) == 0 ){
|
||
|
||
*GranularityHint = GH3;
|
||
|
||
} else if( (MaxAlignment & (GH2_PAGE_SIZE - 1)) == 0 ){
|
||
|
||
*GranularityHint = GH2;
|
||
|
||
} else if( (MaxAlignment & (GH1_PAGE_SIZE - 1)) == 0 ){
|
||
|
||
*GranularityHint = GH1;
|
||
|
||
} else if( (MaxAlignment & (PAGE_SIZE - 1)) == 0 ){
|
||
|
||
*GranularityHint = GH0;
|
||
|
||
} else {
|
||
|
||
*GranularityHint = GH0;
|
||
|
||
#if DBG
|
||
|
||
DbgPrint( "MM: Aggregate Physical pages - not page aligned\n" );
|
||
|
||
#endif //DBG
|
||
|
||
} // end, if then elseif
|
||
|
||
//
|
||
// Return number of pages aggregated.
|
||
//
|
||
|
||
return( MaxAlignment >> PAGE_SHIFT );
|
||
|
||
}
|