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195c491880
Now that the Memory Management is a bit more under control again, and branching releases/0.4.15 is near, do mute some frequent log-spam that got introduced during 0.4.15-dev'ing regarding lazy-flushes and MM balancing. It frequently logged even while being idle. Slightly improve the headers of the two touched files. No rocket-science.
457 lines
12 KiB
C
457 lines
12 KiB
C
/*
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* COPYRIGHT: See COPYING in the top level directory
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* PROJECT: ReactOS kernel
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* PURPOSE: kernel memory management functions
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* PROGRAMMERS: David Welch <welch@cwcom.net>
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* Cameron Gutman <cameron.gutman@reactos.org>
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*/
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/* INCLUDES *****************************************************************/
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#include <ntoskrnl.h>
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#define NDEBUG
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#include <debug.h>
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#include "ARM3/miarm.h"
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/* TYPES ********************************************************************/
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typedef struct _MM_ALLOCATION_REQUEST
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{
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PFN_NUMBER Page;
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LIST_ENTRY ListEntry;
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KEVENT Event;
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}
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MM_ALLOCATION_REQUEST, *PMM_ALLOCATION_REQUEST;
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/* GLOBALS ******************************************************************/
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MM_MEMORY_CONSUMER MiMemoryConsumers[MC_MAXIMUM];
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static ULONG MiMinimumAvailablePages;
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static ULONG MiMinimumPagesPerRun;
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static CLIENT_ID MiBalancerThreadId;
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static HANDLE MiBalancerThreadHandle = NULL;
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static KEVENT MiBalancerEvent;
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static KEVENT MiBalancerDoneEvent;
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static KTIMER MiBalancerTimer;
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static LONG PageOutThreadActive;
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/* FUNCTIONS ****************************************************************/
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CODE_SEG("INIT")
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VOID
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NTAPI
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MmInitializeBalancer(ULONG NrAvailablePages, ULONG NrSystemPages)
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{
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memset(MiMemoryConsumers, 0, sizeof(MiMemoryConsumers));
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/* Set up targets. */
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MiMinimumAvailablePages = 256;
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MiMinimumPagesPerRun = 256;
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MiMemoryConsumers[MC_USER].PagesTarget = NrAvailablePages / 2;
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}
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CODE_SEG("INIT")
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VOID
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NTAPI
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MmInitializeMemoryConsumer(
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ULONG Consumer,
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NTSTATUS (*Trim)(ULONG Target, ULONG Priority, PULONG NrFreed))
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{
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MiMemoryConsumers[Consumer].Trim = Trim;
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}
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VOID
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NTAPI
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MiZeroPhysicalPage(
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IN PFN_NUMBER PageFrameIndex
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);
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NTSTATUS
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NTAPI
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MmReleasePageMemoryConsumer(ULONG Consumer, PFN_NUMBER Page)
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{
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KIRQL OldIrql;
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if (Page == 0)
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{
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DPRINT1("Tried to release page zero.\n");
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KeBugCheck(MEMORY_MANAGEMENT);
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}
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(void)InterlockedDecrementUL(&MiMemoryConsumers[Consumer].PagesUsed);
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UpdateTotalCommittedPages(-1);
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OldIrql = MiAcquirePfnLock();
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MmDereferencePage(Page);
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MiReleasePfnLock(OldIrql);
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return(STATUS_SUCCESS);
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}
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ULONG
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NTAPI
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MiTrimMemoryConsumer(ULONG Consumer, ULONG InitialTarget)
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{
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ULONG Target = InitialTarget;
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ULONG NrFreedPages = 0;
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NTSTATUS Status;
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/* Make sure we can trim this consumer */
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if (!MiMemoryConsumers[Consumer].Trim)
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{
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/* Return the unmodified initial target */
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return InitialTarget;
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}
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if (MmAvailablePages < MiMinimumAvailablePages)
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{
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/* Global page limit exceeded */
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Target = (ULONG)max(Target, MiMinimumAvailablePages - MmAvailablePages);
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}
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else if (MiMemoryConsumers[Consumer].PagesUsed > MiMemoryConsumers[Consumer].PagesTarget)
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{
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/* Consumer page limit exceeded */
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Target = max(Target, MiMemoryConsumers[Consumer].PagesUsed - MiMemoryConsumers[Consumer].PagesTarget);
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}
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if (Target)
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{
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/* Now swap the pages out */
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Status = MiMemoryConsumers[Consumer].Trim(Target, MmAvailablePages < MiMinimumAvailablePages, &NrFreedPages);
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DPRINT("Trimming consumer %lu: Freed %lu pages with a target of %lu pages\n", Consumer, NrFreedPages, Target);
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if (!NT_SUCCESS(Status))
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{
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KeBugCheck(MEMORY_MANAGEMENT);
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}
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}
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/* Return the page count needed to be freed to meet the initial target */
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return (InitialTarget > NrFreedPages) ? (InitialTarget - NrFreedPages) : 0;
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}
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NTSTATUS
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MmTrimUserMemory(ULONG Target, ULONG Priority, PULONG NrFreedPages)
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{
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PFN_NUMBER FirstPage, CurrentPage;
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NTSTATUS Status;
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(*NrFreedPages) = 0;
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DPRINT("MM BALANCER: %s\n", Priority ? "Paging out!" : "Removing access bit!");
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FirstPage = MmGetLRUFirstUserPage();
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CurrentPage = FirstPage;
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while (CurrentPage != 0 && Target > 0)
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{
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if (Priority)
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{
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Status = MmPageOutPhysicalAddress(CurrentPage);
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if (NT_SUCCESS(Status))
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{
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DPRINT("Succeeded\n");
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Target--;
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(*NrFreedPages)++;
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if (CurrentPage == FirstPage)
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{
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FirstPage = 0;
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}
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}
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}
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else
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{
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/* When not paging-out agressively, just reset the accessed bit */
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PEPROCESS Process = NULL;
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PVOID Address = NULL;
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BOOLEAN Accessed = FALSE;
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/*
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* We have a lock-ordering problem here. We cant lock the PFN DB before the Process address space.
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* So we must use circonvoluted loops.
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* Well...
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*/
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while (TRUE)
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{
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KAPC_STATE ApcState;
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KIRQL OldIrql = MiAcquirePfnLock();
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PMM_RMAP_ENTRY Entry = MmGetRmapListHeadPage(CurrentPage);
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while (Entry)
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{
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if (RMAP_IS_SEGMENT(Entry->Address))
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{
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Entry = Entry->Next;
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continue;
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}
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/* Check that we didn't treat this entry before */
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if (Entry->Address < Address)
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{
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Entry = Entry->Next;
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continue;
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}
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if ((Entry->Address == Address) && (Entry->Process <= Process))
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{
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Entry = Entry->Next;
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continue;
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}
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break;
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}
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if (!Entry)
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{
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MiReleasePfnLock(OldIrql);
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break;
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}
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Process = Entry->Process;
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Address = Entry->Address;
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ObReferenceObject(Process);
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if (!ExAcquireRundownProtection(&Process->RundownProtect))
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{
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ObDereferenceObject(Process);
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MiReleasePfnLock(OldIrql);
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continue;
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}
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MiReleasePfnLock(OldIrql);
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KeStackAttachProcess(&Process->Pcb, &ApcState);
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MiLockProcessWorkingSet(Process, PsGetCurrentThread());
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/* Be sure this is still valid. */
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if (MmIsAddressValid(Address))
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{
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PMMPTE Pte = MiAddressToPte(Address);
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Accessed = Accessed || Pte->u.Hard.Accessed;
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Pte->u.Hard.Accessed = 0;
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/* There is no need to invalidate, the balancer thread is never on a user process */
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//KeInvalidateTlbEntry(Address);
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}
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MiUnlockProcessWorkingSet(Process, PsGetCurrentThread());
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KeUnstackDetachProcess(&ApcState);
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ExReleaseRundownProtection(&Process->RundownProtect);
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ObDereferenceObject(Process);
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}
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if (!Accessed)
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{
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/* Nobody accessed this page since the last time we check. Time to clean up */
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Status = MmPageOutPhysicalAddress(CurrentPage);
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if (NT_SUCCESS(Status))
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{
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if (CurrentPage == FirstPage)
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{
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FirstPage = 0;
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}
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}
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// DPRINT1("Paged-out one page: %s\n", NT_SUCCESS(Status) ? "Yes" : "No");
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}
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/* Done for this page. */
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Target--;
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}
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CurrentPage = MmGetLRUNextUserPage(CurrentPage, TRUE);
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if (FirstPage == 0)
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{
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FirstPage = CurrentPage;
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}
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else if (CurrentPage == FirstPage)
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{
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DPRINT1("We are back at the start, abort!\n");
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return STATUS_SUCCESS;
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}
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}
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if (CurrentPage)
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{
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KIRQL OldIrql = MiAcquirePfnLock();
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MmDereferencePage(CurrentPage);
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MiReleasePfnLock(OldIrql);
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}
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return STATUS_SUCCESS;
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}
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VOID
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NTAPI
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MmRebalanceMemoryConsumers(VOID)
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{
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// if (InterlockedCompareExchange(&PageOutThreadActive, 0, 1) == 0)
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{
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KeSetEvent(&MiBalancerEvent, IO_NO_INCREMENT, FALSE);
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}
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}
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VOID
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NTAPI
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MmRebalanceMemoryConsumersAndWait(VOID)
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{
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ASSERT(PsGetCurrentProcess()->AddressCreationLock.Owner != KeGetCurrentThread());
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ASSERT(!MM_ANY_WS_LOCK_HELD(PsGetCurrentThread()));
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ASSERT(KeGetCurrentIrql() < DISPATCH_LEVEL);
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KeResetEvent(&MiBalancerDoneEvent);
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MmRebalanceMemoryConsumers();
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KeWaitForSingleObject(&MiBalancerDoneEvent, Executive, KernelMode, FALSE, NULL);
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}
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NTSTATUS
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NTAPI
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MmRequestPageMemoryConsumer(ULONG Consumer, BOOLEAN CanWait,
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PPFN_NUMBER AllocatedPage)
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{
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PFN_NUMBER Page;
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static INT i = 0;
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static LARGE_INTEGER TinyTime = {{-1L, -1L}};
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/* Delay some requests for the Memory Manager to recover pages */
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if (i++ >= 100)
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{
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KeDelayExecutionThread(KernelMode, FALSE, &TinyTime);
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i = 0;
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}
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/*
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* Actually allocate the page.
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*/
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Page = MmAllocPage(Consumer);
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if (Page == 0)
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{
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*AllocatedPage = 0;
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return STATUS_NO_MEMORY;
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}
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*AllocatedPage = Page;
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/* Update the target */
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InterlockedIncrementUL(&MiMemoryConsumers[Consumer].PagesUsed);
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UpdateTotalCommittedPages(1);
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return(STATUS_SUCCESS);
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}
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VOID
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CcRosTrimCache(
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_In_ ULONG Target,
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_Out_ PULONG NrFreed);
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VOID NTAPI
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MiBalancerThread(PVOID Unused)
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{
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PVOID WaitObjects[2];
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NTSTATUS Status;
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ULONG i;
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WaitObjects[0] = &MiBalancerEvent;
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WaitObjects[1] = &MiBalancerTimer;
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while (1)
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{
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KeSetEvent(&MiBalancerDoneEvent, IO_NO_INCREMENT, FALSE);
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Status = KeWaitForMultipleObjects(2,
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WaitObjects,
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WaitAny,
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Executive,
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KernelMode,
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FALSE,
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NULL,
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NULL);
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if (Status == STATUS_WAIT_0 || Status == STATUS_WAIT_1)
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{
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ULONG InitialTarget = 0;
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ULONG Target;
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ULONG NrFreedPages;
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do
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{
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ULONG OldTarget = InitialTarget;
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/* Trim each consumer */
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for (i = 0; i < MC_MAXIMUM; i++)
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{
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InitialTarget = MiTrimMemoryConsumer(i, InitialTarget);
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}
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/* Trim cache */
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Target = max(InitialTarget, abs(MiMinimumAvailablePages - MmAvailablePages));
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if (Target)
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{
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CcRosTrimCache(Target, &NrFreedPages);
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InitialTarget -= min(NrFreedPages, InitialTarget);
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}
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/* No pages left to swap! */
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if (InitialTarget != 0 &&
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InitialTarget == OldTarget)
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{
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/* Game over */
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KeBugCheck(NO_PAGES_AVAILABLE);
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}
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}
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while (InitialTarget != 0);
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if (Status == STATUS_WAIT_0)
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InterlockedDecrement(&PageOutThreadActive);
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}
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else
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{
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DPRINT1("KeWaitForMultipleObjects failed, status = %x\n", Status);
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KeBugCheck(MEMORY_MANAGEMENT);
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}
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}
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}
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CODE_SEG("INIT")
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VOID
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NTAPI
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MiInitBalancerThread(VOID)
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{
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KPRIORITY Priority;
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NTSTATUS Status;
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LARGE_INTEGER Timeout;
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KeInitializeEvent(&MiBalancerEvent, SynchronizationEvent, FALSE);
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KeInitializeEvent(&MiBalancerDoneEvent, SynchronizationEvent, FALSE);
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KeInitializeTimerEx(&MiBalancerTimer, SynchronizationTimer);
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Timeout.QuadPart = -20000000; /* 2 sec */
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KeSetTimerEx(&MiBalancerTimer,
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Timeout,
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2000, /* 2 sec */
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NULL);
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Status = PsCreateSystemThread(&MiBalancerThreadHandle,
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THREAD_ALL_ACCESS,
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NULL,
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NULL,
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&MiBalancerThreadId,
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MiBalancerThread,
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NULL);
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if (!NT_SUCCESS(Status))
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{
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KeBugCheck(MEMORY_MANAGEMENT);
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}
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Priority = LOW_REALTIME_PRIORITY + 1;
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NtSetInformationThread(MiBalancerThreadHandle,
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ThreadPriority,
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&Priority,
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sizeof(Priority));
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}
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/* EOF */
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