reactos/ntoskrnl/mm/ARM3/syspte.c
Timo Kreuzer 71fefa32db
[NDK][NTOS] Add global definition of INIT_FUNCTION/INIT_SECTION (#779)
* Add an NDK header to define INIT_FUNCTION/INIT_SECTION globally
* Use _declspec(allocate(x)) and _declspec(code_seg(x)) on MSVC versions that support it
* Use INIT_FUNCTION on functions only and INIT_SECTION on data only (required by MSVC)
* Place INIT_FUNCTION before the return type (required by MSVC)
* Make sure declarations and implementations share the same modifiers (required by MSVC)
* Add a global linker option to suppress warnings about defined but unused INIT section
* Merge INIT section into .text in freeldr
2018-12-30 12:19:11 +01:00

454 lines
12 KiB
C

/*
* PROJECT: ReactOS Kernel
* LICENSE: BSD - See COPYING.ARM in the top level directory
* FILE: ntoskrnl/mm/ARM3/syspte.c
* PURPOSE: ARM Memory Manager System PTE Allocator
* PROGRAMMERS: ReactOS Portable Systems Group
* Roel Messiant (roel.messiant@reactos.org)
*/
/* INCLUDES *******************************************************************/
#include <ntoskrnl.h>
#define NDEBUG
#include <debug.h>
#define MODULE_INVOLVED_IN_ARM3
#include <mm/ARM3/miarm.h>
/* GLOBALS ********************************************************************/
PMMPTE MmSystemPteBase;
PMMPTE MmSystemPtesStart[MaximumPtePoolTypes];
PMMPTE MmSystemPtesEnd[MaximumPtePoolTypes];
MMPTE MmFirstFreeSystemPte[MaximumPtePoolTypes];
ULONG MmTotalFreeSystemPtes[MaximumPtePoolTypes];
ULONG MmTotalSystemPtes;
ULONG MiNumberOfExtraSystemPdes;
const ULONG MmSysPteIndex[5] = { 1, 2, 4, 8, 16 };
const UCHAR MmSysPteTables[] = { 0, // 1
0, // 1
1, // 2
2, 2, // 4
3, 3, 3, 3, // 8
4, 4, 4, 4, 4, 4, 4, 4 // 16
};
LONG MmSysPteListBySizeCount[5];
/* PRIVATE FUNCTIONS **********************************************************/
//
// The free System Page Table Entries are stored in a bunch of clusters,
// each consisting of one or more PTEs. These PTE clusters are connected
// in a singly linked list, ordered by increasing cluster size.
//
// A cluster consisting of a single PTE is marked by having the OneEntry flag
// of its PTE set. The forward link is contained in the NextEntry field.
//
// Clusters containing multiple PTEs have the OneEntry flag of their first PTE
// reset. The NextEntry field of the first PTE contains the forward link, and
// the size of the cluster is stored in the NextEntry field of its second PTE.
//
// Reserving PTEs currently happens by walking the linked list until a cluster
// is found that contains the requested amount of PTEs or more. This cluster
// is removed from the list, and the requested amount of PTEs is taken from the
// tail of this cluster. If any PTEs remain in the cluster, the linked list is
// walked again until a second cluster is found that contains the same amount
// of PTEs or more. The first cluster is then inserted in front of the second
// one.
//
// Releasing PTEs currently happens by walking the whole linked list, recording
// the first cluster that contains the amount of PTEs to release or more. When
// a cluster is found that is adjacent to the PTEs being released, this cluster
// is removed from the list and subsequently added to the PTEs being released.
// This ensures no two clusters are adjacent, which maximizes their size.
// After the walk is complete, a new cluster is created that contains the PTEs
// being released, which is then inserted in front of the recorded cluster.
//
FORCEINLINE
ULONG
MI_GET_CLUSTER_SIZE(IN PMMPTE Pte)
{
//
// First check for a single PTE
//
if (Pte->u.List.OneEntry)
return 1;
//
// Then read the size from the trailing PTE
//
Pte++;
return (ULONG)Pte->u.List.NextEntry;
}
PMMPTE
NTAPI
MiReserveAlignedSystemPtes(IN ULONG NumberOfPtes,
IN MMSYSTEM_PTE_POOL_TYPE SystemPtePoolType,
IN ULONG Alignment)
{
KIRQL OldIrql;
PMMPTE PreviousPte, NextPte, ReturnPte;
ULONG ClusterSize;
//
// Sanity check
//
ASSERT(Alignment <= PAGE_SIZE);
//
// Acquire the System PTE lock
//
OldIrql = KeAcquireQueuedSpinLock(LockQueueSystemSpaceLock);
//
// Find the last cluster in the list that doesn't contain enough PTEs
//
PreviousPte = &MmFirstFreeSystemPte[SystemPtePoolType];
while (PreviousPte->u.List.NextEntry != MM_EMPTY_PTE_LIST)
{
//
// Get the next cluster and its size
//
NextPte = MmSystemPteBase + PreviousPte->u.List.NextEntry;
ClusterSize = MI_GET_CLUSTER_SIZE(NextPte);
//
// Check if this cluster contains enough PTEs
//
if (NumberOfPtes <= ClusterSize)
break;
//
// On to the next cluster
//
PreviousPte = NextPte;
}
//
// Make sure we didn't reach the end of the cluster list
//
if (PreviousPte->u.List.NextEntry == MM_EMPTY_PTE_LIST)
{
//
// Release the System PTE lock and return failure
//
KeReleaseQueuedSpinLock(LockQueueSystemSpaceLock, OldIrql);
return NULL;
}
//
// Unlink the cluster
//
PreviousPte->u.List.NextEntry = NextPte->u.List.NextEntry;
//
// Check if the reservation spans the whole cluster
//
if (ClusterSize == NumberOfPtes)
{
//
// Return the first PTE of this cluster
//
ReturnPte = NextPte;
//
// Zero the cluster
//
if (NextPte->u.List.OneEntry == 0)
{
NextPte->u.Long = 0;
NextPte++;
}
NextPte->u.Long = 0;
}
else
{
//
// Divide the cluster into two parts
//
ClusterSize -= NumberOfPtes;
ReturnPte = NextPte + ClusterSize;
//
// Set the size of the first cluster, zero the second if needed
//
if (ClusterSize == 1)
{
NextPte->u.List.OneEntry = 1;
ReturnPte->u.Long = 0;
}
else
{
NextPte++;
NextPte->u.List.NextEntry = ClusterSize;
}
//
// Step through the cluster list to find out where to insert the first
//
PreviousPte = &MmFirstFreeSystemPte[SystemPtePoolType];
while (PreviousPte->u.List.NextEntry != MM_EMPTY_PTE_LIST)
{
//
// Get the next cluster
//
NextPte = MmSystemPteBase + PreviousPte->u.List.NextEntry;
//
// Check if the cluster to insert is smaller or of equal size
//
if (ClusterSize <= MI_GET_CLUSTER_SIZE(NextPte))
break;
//
// On to the next cluster
//
PreviousPte = NextPte;
}
//
// Retrieve the first cluster and link it back into the cluster list
//
NextPte = ReturnPte - ClusterSize;
NextPte->u.List.NextEntry = PreviousPte->u.List.NextEntry;
PreviousPte->u.List.NextEntry = NextPte - MmSystemPteBase;
}
//
// Decrease availability
//
MmTotalFreeSystemPtes[SystemPtePoolType] -= NumberOfPtes;
//
// Release the System PTE lock
//
KeReleaseQueuedSpinLock(LockQueueSystemSpaceLock, OldIrql);
//
// Flush the TLB
//
KeFlushProcessTb();
//
// Return the reserved PTEs
//
return ReturnPte;
}
PMMPTE
NTAPI
MiReserveSystemPtes(IN ULONG NumberOfPtes,
IN MMSYSTEM_PTE_POOL_TYPE SystemPtePoolType)
{
PMMPTE PointerPte;
//
// Use the extended function
//
PointerPte = MiReserveAlignedSystemPtes(NumberOfPtes, SystemPtePoolType, 0);
//
// Check if allocation failed
//
if (!PointerPte)
{
//
// Warn that we are out of memory
//
DPRINT1("MiReserveSystemPtes: Failed to reserve %lu PTE(s)!\n", NumberOfPtes);
}
//
// Return the PTE Pointer
//
return PointerPte;
}
VOID
NTAPI
MiReleaseSystemPtes(IN PMMPTE StartingPte,
IN ULONG NumberOfPtes,
IN MMSYSTEM_PTE_POOL_TYPE SystemPtePoolType)
{
KIRQL OldIrql;
ULONG ClusterSize;
PMMPTE PreviousPte, NextPte, InsertPte;
//
// Check to make sure the PTE address is within bounds
//
ASSERT(NumberOfPtes != 0);
ASSERT(StartingPte >= MmSystemPtesStart[SystemPtePoolType]);
ASSERT(StartingPte + NumberOfPtes - 1 <= MmSystemPtesEnd[SystemPtePoolType]);
//
// Zero PTEs
//
RtlZeroMemory(StartingPte, NumberOfPtes * sizeof(MMPTE));
//
// Acquire the System PTE lock
//
OldIrql = KeAcquireQueuedSpinLock(LockQueueSystemSpaceLock);
//
// Increase availability
//
MmTotalFreeSystemPtes[SystemPtePoolType] += NumberOfPtes;
//
// Step through the cluster list to find where to insert the PTEs
//
PreviousPte = &MmFirstFreeSystemPte[SystemPtePoolType];
InsertPte = NULL;
while (PreviousPte->u.List.NextEntry != MM_EMPTY_PTE_LIST)
{
//
// Get the next cluster and its size
//
NextPte = MmSystemPteBase + PreviousPte->u.List.NextEntry;
ClusterSize = MI_GET_CLUSTER_SIZE(NextPte);
//
// Check if this cluster is adjacent to the PTEs being released
//
if ((NextPte + ClusterSize == StartingPte) ||
(StartingPte + NumberOfPtes == NextPte))
{
//
// Add the PTEs in the cluster to the PTEs being released
//
NumberOfPtes += ClusterSize;
if (NextPte < StartingPte)
StartingPte = NextPte;
//
// Unlink this cluster and zero it
//
PreviousPte->u.List.NextEntry = NextPte->u.List.NextEntry;
if (NextPte->u.List.OneEntry == 0)
{
NextPte->u.Long = 0;
NextPte++;
}
NextPte->u.Long = 0;
//
// Invalidate the previously found insertion location, if any
//
InsertPte = NULL;
}
else
{
//
// Check if the insertion location is right before this cluster
//
if ((InsertPte == NULL) && (NumberOfPtes <= ClusterSize))
InsertPte = PreviousPte;
//
// On to the next cluster
//
PreviousPte = NextPte;
}
}
//
// If no insertion location was found, use the tail of the list
//
if (InsertPte == NULL)
InsertPte = PreviousPte;
//
// Create a new cluster using the PTEs being released
//
if (NumberOfPtes != 1)
{
StartingPte->u.List.OneEntry = 0;
NextPte = StartingPte + 1;
NextPte->u.List.NextEntry = NumberOfPtes;
}
else
StartingPte->u.List.OneEntry = 1;
//
// Link the new cluster into the cluster list at the insertion location
//
StartingPte->u.List.NextEntry = InsertPte->u.List.NextEntry;
InsertPte->u.List.NextEntry = StartingPte - MmSystemPteBase;
//
// Release the System PTE lock
//
KeReleaseQueuedSpinLock(LockQueueSystemSpaceLock, OldIrql);
}
INIT_FUNCTION
VOID
NTAPI
MiInitializeSystemPtes(IN PMMPTE StartingPte,
IN ULONG NumberOfPtes,
IN MMSYSTEM_PTE_POOL_TYPE PoolType)
{
//
// Sanity checks
//
ASSERT(NumberOfPtes >= 1);
//
// Set the starting and ending PTE addresses for this space
//
MmSystemPteBase = MI_SYSTEM_PTE_BASE;
MmSystemPtesStart[PoolType] = StartingPte;
MmSystemPtesEnd[PoolType] = StartingPte + NumberOfPtes - 1;
DPRINT("System PTE space for %d starting at: %p and ending at: %p\n",
PoolType, MmSystemPtesStart[PoolType], MmSystemPtesEnd[PoolType]);
//
// Clear all the PTEs to start with
//
RtlZeroMemory(StartingPte, NumberOfPtes * sizeof(MMPTE));
//
// Make the first entry free and link it
//
StartingPte->u.List.NextEntry = MM_EMPTY_PTE_LIST;
MmFirstFreeSystemPte[PoolType].u.Long = 0;
MmFirstFreeSystemPte[PoolType].u.List.NextEntry = StartingPte -
MmSystemPteBase;
//
// The second entry stores the size of this PTE space
//
StartingPte++;
StartingPte->u.Long = 0;
StartingPte->u.List.NextEntry = NumberOfPtes;
//
// We also keep a global for it
//
MmTotalFreeSystemPtes[PoolType] = NumberOfPtes;
//
// Check if this is the system PTE space
//
if (PoolType == SystemPteSpace)
{
//
// Remember how many PTEs we have
//
MmTotalSystemPtes = NumberOfPtes;
}
}
/* EOF */