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918 lines
23 KiB
918 lines
23 KiB
/*++
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Copyright (c) 1989 Microsoft Corporation
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Module Name:
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vadtree.c
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Abstract:
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This module contains the routine to manipulate the virtual address
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descriptor tree.
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Author:
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Lou Perazzoli (loup) 19-May-1989
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Landy Wang (landyw) 02-June-1997
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Environment:
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Kernel mode only, working set mutex held, APCs disabled.
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Revision History:
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--*/
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#include "mi.h"
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VOID
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VadTreeWalk (
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VOID
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);
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#ifdef ALLOC_PRAGMA
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#pragma alloc_text(PAGE,MiInsertVad)
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#pragma alloc_text(PAGE,MiRemoveVad)
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#pragma alloc_text(PAGE,MiFindEmptyAddressRange)
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#pragma alloc_text(PAGE, MmPerfVadTreeWalk)
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#if DBG
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#pragma alloc_text(PAGE,VadTreeWalk)
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#endif
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#endif
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NTSTATUS
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MiInsertVad (
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IN PMMVAD Vad
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)
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/*++
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Routine Description:
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This function inserts a virtual address descriptor into the tree and
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reorders the splay tree as appropriate.
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Arguments:
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Vad - Supplies a pointer to a virtual address descriptor.
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Return Value:
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NTSTATUS.
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--*/
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{
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ULONG StartBit;
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ULONG EndBit;
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PMMADDRESS_NODE *Root;
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PEPROCESS CurrentProcess;
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SIZE_T RealCharge;
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SIZE_T PageCharge;
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SIZE_T PagesReallyCharged;
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ULONG FirstPage;
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ULONG LastPage;
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SIZE_T PagedPoolCharge;
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LOGICAL ChargedJobCommit;
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NTSTATUS Status;
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RTL_BITMAP VadBitMap;
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#if (_MI_PAGING_LEVELS >= 3)
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ULONG FirstPdPage;
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ULONG LastPdPage;
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#endif
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#if (_MI_PAGING_LEVELS >= 4)
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ULONG FirstPpPage;
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ULONG LastPpPage;
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#endif
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ASSERT (Vad->EndingVpn >= Vad->StartingVpn);
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CurrentProcess = PsGetCurrentProcess();
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//
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// Commit charge of MAX_COMMIT means don't charge quota.
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//
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if (Vad->u.VadFlags.CommitCharge != MM_MAX_COMMIT) {
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PageCharge = 0;
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PagedPoolCharge = 0;
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ChargedJobCommit = FALSE;
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//
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// Charge quota for the nonpaged pool for the VAD. This is
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// done here rather than by using ExAllocatePoolWithQuota
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// so the process object is not referenced by the quota charge.
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//
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Status = PsChargeProcessNonPagedPoolQuota (CurrentProcess, sizeof(MMVAD));
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if (!NT_SUCCESS(Status)) {
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return STATUS_COMMITMENT_LIMIT;
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}
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//
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// Charge quota for the prototype PTEs if this is a mapped view.
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//
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if ((Vad->u.VadFlags.PrivateMemory == 0) &&
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(Vad->ControlArea != NULL)) {
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PagedPoolCharge =
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(Vad->EndingVpn - Vad->StartingVpn + 1) << PTE_SHIFT;
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Status = PsChargeProcessPagedPoolQuota (CurrentProcess,
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PagedPoolCharge);
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if (!NT_SUCCESS(Status)) {
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PagedPoolCharge = 0;
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RealCharge = 0;
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goto Failed;
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}
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}
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//
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// Add in the charge for page table pages.
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//
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FirstPage = MiGetPdeIndex (MI_VPN_TO_VA (Vad->StartingVpn));
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LastPage = MiGetPdeIndex (MI_VPN_TO_VA (Vad->EndingVpn));
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while (FirstPage <= LastPage) {
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if (!MI_CHECK_BIT (MmWorkingSetList->CommittedPageTables,
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FirstPage)) {
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PageCharge += 1;
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}
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FirstPage += 1;
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}
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#if (_MI_PAGING_LEVELS >= 4)
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//
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// Add in the charge for page directory parent pages.
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//
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FirstPpPage = MiGetPxeIndex (MI_VPN_TO_VA (Vad->StartingVpn));
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LastPpPage = MiGetPxeIndex (MI_VPN_TO_VA (Vad->EndingVpn));
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while (FirstPpPage <= LastPpPage) {
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if (!MI_CHECK_BIT (MmWorkingSetList->CommittedPageDirectoryParents,
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FirstPpPage)) {
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PageCharge += 1;
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}
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FirstPpPage += 1;
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}
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#endif
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#if (_MI_PAGING_LEVELS >= 3)
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//
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// Add in the charge for page directory pages.
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//
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FirstPdPage = MiGetPpeIndex (MI_VPN_TO_VA (Vad->StartingVpn));
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LastPdPage = MiGetPpeIndex (MI_VPN_TO_VA (Vad->EndingVpn));
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while (FirstPdPage <= LastPdPage) {
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if (!MI_CHECK_BIT (MmWorkingSetList->CommittedPageDirectories,
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FirstPdPage)) {
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PageCharge += 1;
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}
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FirstPdPage += 1;
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}
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#endif
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RealCharge = Vad->u.VadFlags.CommitCharge + PageCharge;
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if (RealCharge != 0) {
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Status = PsChargeProcessPageFileQuota (CurrentProcess, RealCharge);
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if (!NT_SUCCESS (Status)) {
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RealCharge = 0;
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goto Failed;
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}
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if (CurrentProcess->CommitChargeLimit) {
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if (CurrentProcess->CommitCharge + RealCharge > CurrentProcess->CommitChargeLimit) {
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if (CurrentProcess->Job) {
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PsReportProcessMemoryLimitViolation ();
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}
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goto Failed;
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}
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}
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if (CurrentProcess->JobStatus & PS_JOB_STATUS_REPORT_COMMIT_CHANGES) {
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if (PsChangeJobMemoryUsage(RealCharge) == FALSE) {
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goto Failed;
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}
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ChargedJobCommit = TRUE;
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}
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if (MiChargeCommitment (RealCharge, CurrentProcess) == FALSE) {
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goto Failed;
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}
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CurrentProcess->CommitCharge += RealCharge;
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if (CurrentProcess->CommitCharge > CurrentProcess->CommitChargePeak) {
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CurrentProcess->CommitChargePeak = CurrentProcess->CommitCharge;
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}
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MI_INCREMENT_TOTAL_PROCESS_COMMIT (RealCharge);
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ASSERT (RealCharge == Vad->u.VadFlags.CommitCharge + PageCharge);
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MM_TRACK_COMMIT (MM_DBG_COMMIT_INSERT_VAD, Vad->u.VadFlags.CommitCharge);
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MM_TRACK_COMMIT (MM_DBG_COMMIT_INSERT_VAD_PT, PageCharge);
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}
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if (PageCharge != 0) {
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//
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// Since the commitment was successful, charge the page
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// table pages.
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//
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PagesReallyCharged = 0;
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FirstPage = MiGetPdeIndex (MI_VPN_TO_VA (Vad->StartingVpn));
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while (FirstPage <= LastPage) {
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if (!MI_CHECK_BIT (MmWorkingSetList->CommittedPageTables,
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FirstPage)) {
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MI_SET_BIT (MmWorkingSetList->CommittedPageTables,
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FirstPage);
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MmWorkingSetList->NumberOfCommittedPageTables += 1;
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ASSERT32 (MmWorkingSetList->NumberOfCommittedPageTables <
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PD_PER_SYSTEM * PDE_PER_PAGE);
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PagesReallyCharged += 1;
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}
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FirstPage += 1;
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}
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#if (_MI_PAGING_LEVELS >= 3)
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//
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// Charge the page directory pages.
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//
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FirstPdPage = MiGetPpeIndex (MI_VPN_TO_VA (Vad->StartingVpn));
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while (FirstPdPage <= LastPdPage) {
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if (!MI_CHECK_BIT (MmWorkingSetList->CommittedPageDirectories,
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FirstPdPage)) {
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MI_SET_BIT (MmWorkingSetList->CommittedPageDirectories,
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FirstPdPage);
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MmWorkingSetList->NumberOfCommittedPageDirectories += 1;
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ASSERT (MmWorkingSetList->NumberOfCommittedPageDirectories <
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PDE_PER_PAGE);
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PagesReallyCharged += 1;
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}
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FirstPdPage += 1;
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}
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#endif
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#if (_MI_PAGING_LEVELS >= 4)
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//
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// Charge the page directory parent pages.
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//
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FirstPpPage = MiGetPxeIndex (MI_VPN_TO_VA (Vad->StartingVpn));
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while (FirstPpPage <= LastPpPage) {
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if (!MI_CHECK_BIT (MmWorkingSetList->CommittedPageDirectoryParents,
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FirstPpPage)) {
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MI_SET_BIT (MmWorkingSetList->CommittedPageDirectoryParents,
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FirstPpPage);
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MmWorkingSetList->NumberOfCommittedPageDirectoryParents += 1;
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ASSERT (MmWorkingSetList->NumberOfCommittedPageDirectoryParents <
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PDE_PER_PAGE);
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PagesReallyCharged += 1;
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}
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FirstPpPage += 1;
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}
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#endif
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ASSERT (PageCharge == PagesReallyCharged);
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}
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}
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Root = (PMMADDRESS_NODE *)&CurrentProcess->VadRoot;
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//
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// Set the relevant fields in the Vad bitmap.
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//
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StartBit = (ULONG)(((ULONG_PTR) MI_64K_ALIGN (MI_VPN_TO_VA (Vad->StartingVpn))) / X64K);
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EndBit = (ULONG) (((ULONG_PTR) MI_64K_ALIGN (MI_VPN_TO_VA (Vad->EndingVpn))) / X64K);
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//
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// Initialize the bitmap inline for speed.
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//
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VadBitMap.SizeOfBitMap = MiLastVadBit + 1;
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VadBitMap.Buffer = VAD_BITMAP_SPACE;
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//
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// Note VADs like the PEB & TEB start on page (not 64K) boundaries so
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// for these, the relevant bits may already be set.
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//
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#if defined (_WIN64) || defined (_X86PAE_)
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if (EndBit > MiLastVadBit) {
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EndBit = MiLastVadBit;
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}
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//
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// Only the first (PAGE_SIZE*8*64K) of VA space on NT64 is bitmapped.
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//
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if (StartBit <= MiLastVadBit) {
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RtlSetBits (&VadBitMap, StartBit, EndBit - StartBit + 1);
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}
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#else
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RtlSetBits (&VadBitMap, StartBit, EndBit - StartBit + 1);
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#endif
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if (MmWorkingSetList->VadBitMapHint == StartBit) {
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MmWorkingSetList->VadBitMapHint = EndBit + 1;
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}
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//
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// Set the hint field in the process to this Vad.
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//
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CurrentProcess->VadHint = Vad;
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if (CurrentProcess->VadFreeHint != NULL) {
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if (((ULONG)((PMMVAD)CurrentProcess->VadFreeHint)->EndingVpn +
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MI_VA_TO_VPN (X64K)) >=
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Vad->StartingVpn) {
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CurrentProcess->VadFreeHint = Vad;
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}
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}
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MiInsertNode ((PMMADDRESS_NODE)Vad, Root);
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CurrentProcess->NumberOfVads += 1;
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return STATUS_SUCCESS;
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Failed:
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//
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// Return any quotas charged thus far.
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//
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PsReturnProcessNonPagedPoolQuota (CurrentProcess, sizeof(MMVAD));
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if (PagedPoolCharge != 0) {
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PsReturnProcessPagedPoolQuota (CurrentProcess, PagedPoolCharge);
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}
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if (RealCharge != 0) {
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PsReturnProcessPageFileQuota (CurrentProcess, RealCharge);
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}
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if (ChargedJobCommit == TRUE) {
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PsChangeJobMemoryUsage(-(SSIZE_T)RealCharge);
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}
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return STATUS_COMMITMENT_LIMIT;
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}
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VOID
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MiRemoveVad (
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IN PMMVAD Vad
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)
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/*++
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Routine Description:
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This function removes a virtual address descriptor from the tree and
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reorders the splay tree as appropriate. If any quota or commitment
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was charged by the VAD (as indicated by the CommitCharge field) it
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is released.
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|
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Arguments:
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Vad - Supplies a pointer to a virtual address descriptor.
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Return Value:
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None.
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--*/
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{
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PMMADDRESS_NODE *Root;
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PEPROCESS CurrentProcess;
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SIZE_T RealCharge;
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PLIST_ENTRY Next;
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PMMSECURE_ENTRY Entry;
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CurrentProcess = PsGetCurrentProcess();
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|
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#if defined(_MIALT4K_)
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if (((Vad->u.VadFlags.PrivateMemory) && (Vad->u.VadFlags.NoChange == 0))
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||
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(Vad->u2.VadFlags2.LongVad == 0)) {
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NOTHING;
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}
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else {
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ASSERT ((((PMMVAD_LONG)Vad)->AliasInformation == NULL) || (CurrentProcess->Wow64Process != NULL));
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}
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#endif
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//
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// Commit charge of MAX_COMMIT means don't charge quota.
|
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//
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if (Vad->u.VadFlags.CommitCharge != MM_MAX_COMMIT) {
|
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|
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//
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// Return the quota charge to the process.
|
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//
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PsReturnProcessNonPagedPoolQuota (CurrentProcess, sizeof(MMVAD));
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|
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if ((Vad->u.VadFlags.PrivateMemory == 0) &&
|
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(Vad->ControlArea != NULL)) {
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PsReturnProcessPagedPoolQuota (CurrentProcess,
|
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(Vad->EndingVpn - Vad->StartingVpn + 1) << PTE_SHIFT);
|
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}
|
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|
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RealCharge = Vad->u.VadFlags.CommitCharge;
|
|
|
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if (RealCharge != 0) {
|
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|
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PsReturnProcessPageFileQuota (CurrentProcess, RealCharge);
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|
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if ((Vad->u.VadFlags.PrivateMemory == 0) &&
|
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(Vad->ControlArea != NULL)) {
|
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|
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#if 0 //commented out so page file quota is meaningful.
|
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if (Vad->ControlArea->FilePointer == NULL) {
|
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|
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//
|
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// Don't release commitment for the page file space
|
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// occupied by a page file section. This will be charged
|
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// as the shared memory is committed.
|
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//
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RealCharge -= BYTES_TO_PAGES ((ULONG)Vad->EndingVa -
|
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(ULONG)Vad->StartingVa);
|
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}
|
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#endif
|
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}
|
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|
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MiReturnCommitment (RealCharge);
|
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MM_TRACK_COMMIT (MM_DBG_COMMIT_RETURN_VAD, RealCharge);
|
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if (CurrentProcess->JobStatus & PS_JOB_STATUS_REPORT_COMMIT_CHANGES) {
|
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PsChangeJobMemoryUsage(-(SSIZE_T)RealCharge);
|
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}
|
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CurrentProcess->CommitCharge -= RealCharge;
|
|
|
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MI_INCREMENT_TOTAL_PROCESS_COMMIT (0 - RealCharge);
|
|
}
|
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}
|
|
|
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if (Vad == CurrentProcess->VadFreeHint) {
|
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CurrentProcess->VadFreeHint = MiGetPreviousVad (Vad);
|
|
}
|
|
|
|
Root = (PMMADDRESS_NODE *)&CurrentProcess->VadRoot;
|
|
|
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MiRemoveNode ( (PMMADDRESS_NODE)Vad, Root);
|
|
|
|
ASSERT (CurrentProcess->NumberOfVads >= 1);
|
|
CurrentProcess->NumberOfVads -= 1;
|
|
|
|
if (Vad->u.VadFlags.NoChange) {
|
|
if (Vad->u2.VadFlags2.MultipleSecured) {
|
|
|
|
//
|
|
// Free the oustanding pool allocations.
|
|
//
|
|
|
|
Next = ((PMMVAD_LONG) Vad)->u3.List.Flink;
|
|
do {
|
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Entry = CONTAINING_RECORD( Next,
|
|
MMSECURE_ENTRY,
|
|
List);
|
|
|
|
Next = Entry->List.Flink;
|
|
ExFreePool (Entry);
|
|
} while (Next != &((PMMVAD_LONG)Vad)->u3.List);
|
|
}
|
|
}
|
|
|
|
//
|
|
// If the VadHint was the removed Vad, change the Hint.
|
|
|
|
if (CurrentProcess->VadHint == Vad) {
|
|
CurrentProcess->VadHint = CurrentProcess->VadRoot;
|
|
}
|
|
|
|
return;
|
|
}
|
|
|
|
PMMVAD
|
|
FASTCALL
|
|
MiLocateAddress (
|
|
IN PVOID VirtualAddress
|
|
)
|
|
|
|
/*++
|
|
|
|
Routine Description:
|
|
|
|
The function locates the virtual address descriptor which describes
|
|
a given address.
|
|
|
|
Arguments:
|
|
|
|
VirtualAddress - Supplies the virtual address to locate a descriptor
|
|
for.
|
|
|
|
Return Value:
|
|
|
|
Returns a pointer to the virtual address descriptor which contains
|
|
the supplied virtual address or NULL if none was located.
|
|
|
|
--*/
|
|
|
|
{
|
|
PMMVAD FoundVad;
|
|
PEPROCESS CurrentProcess;
|
|
ULONG_PTR Vpn;
|
|
|
|
CurrentProcess = PsGetCurrentProcess();
|
|
|
|
if (CurrentProcess->VadHint == NULL) {
|
|
return NULL;
|
|
}
|
|
|
|
Vpn = MI_VA_TO_VPN (VirtualAddress);
|
|
if ((Vpn >= ((PMMADDRESS_NODE)CurrentProcess->VadHint)->StartingVpn) &&
|
|
(Vpn <= ((PMMADDRESS_NODE)CurrentProcess->VadHint)->EndingVpn)) {
|
|
|
|
return (PMMVAD)CurrentProcess->VadHint;
|
|
}
|
|
|
|
FoundVad = (PMMVAD)MiLocateAddressInTree ( Vpn,
|
|
(PMMADDRESS_NODE *)&(CurrentProcess->VadRoot));
|
|
|
|
if (FoundVad != NULL) {
|
|
CurrentProcess->VadHint = (PVOID)FoundVad;
|
|
}
|
|
return FoundVad;
|
|
}
|
|
|
|
NTSTATUS
|
|
MiFindEmptyAddressRange (
|
|
IN SIZE_T SizeOfRange,
|
|
IN ULONG_PTR Alignment,
|
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IN ULONG QuickCheck,
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IN PVOID *Base
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)
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/*++
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Routine Description:
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The function examines the virtual address descriptors to locate
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an unused range of the specified size and returns the starting
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address of the range.
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Arguments:
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SizeOfRange - Supplies the size in bytes of the range to locate.
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Alignment - Supplies the alignment for the address. Must be
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a power of 2 and greater than the page_size.
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QuickCheck - Supplies a zero if a quick check for free memory
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after the VadFreeHint exists, non-zero if checking
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should start at the lowest address.
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Base - Receives the starting address of a suitable range on success.
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Return Value:
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NTSTATUS.
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--*/
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{
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ULONG FirstBitValue;
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ULONG StartPosition;
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ULONG BitsNeeded;
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PMMVAD NextVad;
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PMMVAD FreeHint;
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PEPROCESS CurrentProcess;
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PVOID StartingVa;
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PVOID EndingVa;
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NTSTATUS Status;
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RTL_BITMAP VadBitMap;
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CurrentProcess = PsGetCurrentProcess();
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if (QuickCheck == 0) {
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//
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// Initialize the bitmap inline for speed.
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//
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VadBitMap.SizeOfBitMap = MiLastVadBit + 1;
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VadBitMap.Buffer = VAD_BITMAP_SPACE;
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//
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// Skip the first bit here as we don't generally recommend
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// that applications map virtual address zero.
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//
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FirstBitValue = *((PULONG)VAD_BITMAP_SPACE);
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*((PULONG)VAD_BITMAP_SPACE) = (FirstBitValue | 0x1);
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BitsNeeded = (ULONG) ((MI_ROUND_TO_64K (SizeOfRange)) / X64K);
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StartPosition = RtlFindClearBits (&VadBitMap,
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BitsNeeded,
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MmWorkingSetList->VadBitMapHint);
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if (FirstBitValue & 0x1) {
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FirstBitValue = (ULONG)-1;
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}
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else {
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FirstBitValue = (ULONG)~0x1;
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}
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*((PULONG)VAD_BITMAP_SPACE) &= FirstBitValue;
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if (StartPosition != NO_BITS_FOUND) {
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*Base = (PVOID) (((ULONG_PTR)StartPosition) * X64K);
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#if DBG
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if (MiCheckForConflictingVad (CurrentProcess, *Base, (ULONG_PTR)*Base + SizeOfRange - 1) != NULL) {
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DbgPrint ("MiFindEmptyAddressRange: overlapping VAD %p %p\n", *Base, SizeOfRange);
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DbgBreakPoint ();
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}
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#endif
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return STATUS_SUCCESS;
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}
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FreeHint = CurrentProcess->VadFreeHint;
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if (FreeHint != NULL) {
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EndingVa = MI_VPN_TO_VA_ENDING (FreeHint->EndingVpn);
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NextVad = MiGetNextVad (FreeHint);
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if (NextVad == NULL) {
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if (SizeOfRange <
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(((ULONG_PTR)MM_HIGHEST_USER_ADDRESS + 1) -
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MI_ROUND_TO_SIZE((ULONG_PTR)EndingVa, Alignment))) {
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*Base = (PVOID) MI_ROUND_TO_SIZE((ULONG_PTR)EndingVa,
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Alignment);
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return STATUS_SUCCESS;
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}
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}
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else {
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StartingVa = MI_VPN_TO_VA (NextVad->StartingVpn);
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if (SizeOfRange <
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((ULONG_PTR)StartingVa -
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MI_ROUND_TO_SIZE((ULONG_PTR)EndingVa, Alignment))) {
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//
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// Check to ensure that the ending address aligned upwards
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// is not greater than the starting address.
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//
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if ((ULONG_PTR)StartingVa >
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MI_ROUND_TO_SIZE((ULONG_PTR)EndingVa,Alignment)) {
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*Base = (PVOID)MI_ROUND_TO_SIZE((ULONG_PTR)EndingVa,
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Alignment);
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return STATUS_SUCCESS;
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}
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}
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}
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}
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}
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Status = MiFindEmptyAddressRangeInTree (
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SizeOfRange,
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Alignment,
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(PMMADDRESS_NODE)(CurrentProcess->VadRoot),
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(PMMADDRESS_NODE *)&CurrentProcess->VadFreeHint,
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Base);
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return Status;
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}
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#if DBG
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VOID
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VadTreeWalk (
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VOID
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)
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{
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NodeTreeWalk ( (PMMADDRESS_NODE)(PsGetCurrentProcess()->VadRoot));
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return;
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}
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#endif
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LOGICAL
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MiCheckForConflictingVadExistence (
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IN PEPROCESS Process,
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IN PVOID StartingAddress,
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IN PVOID EndingAddress
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)
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/*++
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Routine Description:
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The function determines if any addresses between a given starting and
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ending address is contained within a virtual address descriptor.
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Arguments:
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StartingAddress - Supplies the virtual address to locate a containing
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descriptor.
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EndingAddress - Supplies the virtual address to locate a containing
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descriptor.
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Return Value:
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TRUE if the VAD if found, FALSE if not.
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Environment:
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Kernel mode, process address creation mutex held.
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--*/
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{
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#if 0
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ULONG StartBit;
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ULONG EndBit;
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if (MiLastVadBit != 0) {
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StartBit = (ULONG) (((ULONG_PTR) MI_64K_ALIGN (StartingAddress)) / X64K);
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EndBit = (ULONG) (((ULONG_PTR) MI_64K_ALIGN (EndingAddress)) / X64K);
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ASSERT (StartBit <= EndBit);
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if (EndBit > MiLastVadBit) {
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ASSERT (FALSE);
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EndBit = MiLastVadBit;
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if (StartBit > MiLastVadBit) {
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StartBit = MiLastVadBit;
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}
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}
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while (StartBit <= EndBit) {
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if (MI_CHECK_BIT (((PULONG)VAD_BITMAP_SPACE), StartBit) != 0) {
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return TRUE;
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}
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StartBit += 1;
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}
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ASSERT (MiCheckForConflictingVad (Process, StartingAddress, EndingAddress) == NULL);
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return FALSE;
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}
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#endif
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if (MiCheckForConflictingVad (Process, StartingAddress, EndingAddress) != NULL) {
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return TRUE;
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}
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return FALSE;
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}
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PFILE_OBJECT *
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MmPerfVadTreeWalk (
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IN PEPROCESS Process
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)
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/*++
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Routine Description:
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This routine walks through the VAD tree to find all files mapped
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into the specified process. It returns a pointer to a pool allocation
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containing the referenced file object pointers.
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Arguments:
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Process - Supplies the process to walk.
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Return Value:
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Returns a pointer to a NULL terminated pool allocation containing
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the file object pointers which have been referenced in the process,
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NULL if the memory could not be allocated.
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It is also the responsibility of the caller to dereference each
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file object in the list and then free the returned pool.
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Environment:
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PASSIVE_LEVEL, arbitrary thread context.
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--*/
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{
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PMMVAD Vad;
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PMMVAD NextVad;
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ULONG VadCount;
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PFILE_OBJECT *File;
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PFILE_OBJECT *FileObjects;
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ASSERT (KeGetCurrentIrql () == PASSIVE_LEVEL);
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LOCK_ADDRESS_SPACE(Process);
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Vad = Process->VadRoot;
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if (Vad == NULL) {
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ASSERT (Process->NumberOfVads == 0);
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UNLOCK_ADDRESS_SPACE (Process);
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return NULL;
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}
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ASSERT (Process->NumberOfVads != 0);
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//
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// Allocate one additional entry for the NULL terminator.
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//
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VadCount = Process->NumberOfVads + 1;
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FileObjects = (PFILE_OBJECT *) ExAllocatePoolWithTag (
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PagedPool,
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VadCount * sizeof(PFILE_OBJECT),
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'01pM');
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if (FileObjects == NULL) {
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UNLOCK_ADDRESS_SPACE (Process);
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return NULL;
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}
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File = FileObjects;
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while (Vad->LeftChild != NULL) {
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Vad = Vad->LeftChild;
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}
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if ((!Vad->u.VadFlags.PrivateMemory) &&
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(Vad->ControlArea != NULL) &&
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(Vad->ControlArea->FilePointer != NULL)) {
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*File = Vad->ControlArea->FilePointer;
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ObReferenceObject (*File);
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File += 1;
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}
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for (;;) {
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NextVad = (PMMVAD) MiGetNextNode ((PMMADDRESS_NODE)Vad);
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if (NextVad == NULL) {
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break;
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}
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Vad = (PMMVAD) NextVad;
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|
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if ((!Vad->u.VadFlags.PrivateMemory) &&
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(Vad->ControlArea != NULL) &&
|
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(Vad->ControlArea->FilePointer != NULL)) {
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*File = Vad->ControlArea->FilePointer;
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ObReferenceObject (*File);
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File += 1;
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}
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Vad = NextVad;
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}
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ASSERT (File < FileObjects + VadCount);
|
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|
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UNLOCK_ADDRESS_SPACE(Process);
|
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|
|
*File = NULL;
|
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return FileObjects;
|
|
}
|