reactos/hal/halx86/generic/memory.c

255 lines
7.8 KiB
C

/*
* PROJECT: ReactOS HAL
* LICENSE: GPL - See COPYING in the top level directory
* FILE: hal/halx86/generic/memory.c
* PURPOSE: HAL memory management
* PROGRAMMERS: ReactOS Portable Systems Group
*/
/* INCLUDES ******************************************************************/
#include <hal.h>
#define NDEBUG
#include <debug.h>
/* Share with Mm headers? */
#define MM_HAL_HEAP_START (PVOID)(MM_HAL_VA_START + (1024 * 1024))
/* GLOBALS *******************************************************************/
ULONG HalpUsedAllocDescriptors;
MEMORY_ALLOCATION_DESCRIPTOR HalpAllocationDescriptorArray[64];
PVOID HalpHeapStart = MM_HAL_HEAP_START;
/* PRIVATE FUNCTIONS *********************************************************/
ULONG64
NTAPI
HalpAllocPhysicalMemory(IN PLOADER_PARAMETER_BLOCK LoaderBlock,
IN ULONG64 MaxAddress,
IN PFN_NUMBER PageCount,
IN BOOLEAN Aligned)
{
ULONG UsedDescriptors;
ULONG64 PhysicalAddress;
PFN_NUMBER MaxPage, BasePage, Alignment;
PLIST_ENTRY NextEntry;
PMEMORY_ALLOCATION_DESCRIPTOR MdBlock, NewBlock, FreeBlock;
/* Highest page we'll go */
MaxPage = MaxAddress >> PAGE_SHIFT;
/* We need at least two blocks */
if ((HalpUsedAllocDescriptors + 2) > 64) return 0;
/* Remember how many we have now */
UsedDescriptors = HalpUsedAllocDescriptors;
/* Loop the loader block memory descriptors */
NextEntry = LoaderBlock->MemoryDescriptorListHead.Flink;
while (NextEntry != &LoaderBlock->MemoryDescriptorListHead)
{
/* Get the block */
MdBlock = CONTAINING_RECORD(NextEntry,
MEMORY_ALLOCATION_DESCRIPTOR,
ListEntry);
/* No alignment by default */
Alignment = 0;
/* Unless requested, in which case we use a 64KB block alignment */
if (Aligned) Alignment = ((MdBlock->BasePage + 0x0F) & ~0x0F) - MdBlock->BasePage;
/* Search for free memory */
if ((MdBlock->MemoryType == LoaderFree) ||
(MdBlock->MemoryType == LoaderFirmwareTemporary))
{
/* Make sure the page is within bounds, including alignment */
BasePage = MdBlock->BasePage;
if ((BasePage) &&
(MdBlock->PageCount >= PageCount + Alignment) &&
(BasePage + PageCount + Alignment < MaxPage))
{
/* We found an address */
PhysicalAddress = ((ULONG64)BasePage + Alignment) << PAGE_SHIFT;
break;
}
}
/* Keep trying */
NextEntry = NextEntry->Flink;
}
/* If we didn't find anything, get out of here */
if (NextEntry == &LoaderBlock->MemoryDescriptorListHead) return 0;
/* Okay, now get a descriptor */
NewBlock = &HalpAllocationDescriptorArray[HalpUsedAllocDescriptors];
NewBlock->PageCount = (ULONG)PageCount;
NewBlock->BasePage = MdBlock->BasePage + Alignment;
NewBlock->MemoryType = LoaderHALCachedMemory;
/* Update count */
UsedDescriptors++;
HalpUsedAllocDescriptors = UsedDescriptors;
/* Check if we had any alignment */
if (Alignment)
{
/* Check if we had leftovers */
if (MdBlock->PageCount > (PageCount + Alignment))
{
/* Get the next descriptor */
FreeBlock = &HalpAllocationDescriptorArray[UsedDescriptors];
FreeBlock->PageCount = MdBlock->PageCount - Alignment - (ULONG)PageCount;
FreeBlock->BasePage = MdBlock->BasePage + Alignment + (ULONG)PageCount;
/* One more */
HalpUsedAllocDescriptors++;
/* Insert it into the list */
InsertHeadList(&MdBlock->ListEntry, &FreeBlock->ListEntry);
}
/* Trim the original block to the alignment only */
MdBlock->PageCount = Alignment;
/* Insert the descriptor after the original one */
InsertHeadList(&MdBlock->ListEntry, &NewBlock->ListEntry);
}
else
{
/* Consume memory from this block */
MdBlock->BasePage += (ULONG)PageCount;
MdBlock->PageCount -= (ULONG)PageCount;
/* Insert the descriptor before the original one */
InsertTailList(&MdBlock->ListEntry, &NewBlock->ListEntry);
/* Remove the entry if the whole block was allocated */
if (MdBlock->PageCount == 0) RemoveEntryList(&MdBlock->ListEntry);
}
/* Return the address */
return PhysicalAddress;
}
PVOID
NTAPI
HalpMapPhysicalMemory64(IN PHYSICAL_ADDRESS PhysicalAddress,
IN PFN_COUNT PageCount)
{
return HalpMapPhysicalMemory64Vista(PhysicalAddress, PageCount, TRUE);
}
VOID
NTAPI
HalpUnmapVirtualAddress(IN PVOID VirtualAddress,
IN PFN_COUNT PageCount)
{
HalpUnmapVirtualAddressVista(VirtualAddress, PageCount, TRUE);
}
PVOID
NTAPI
HalpMapPhysicalMemory64Vista(IN PHYSICAL_ADDRESS PhysicalAddress,
IN PFN_COUNT PageCount,
IN BOOLEAN FlushCurrentTLB)
{
PHARDWARE_PTE PointerPte;
PFN_NUMBER UsedPages = 0;
PVOID VirtualAddress, BaseAddress;
/* Start at the current HAL heap base */
BaseAddress = HalpHeapStart;
VirtualAddress = BaseAddress;
/* Loop until we have all the pages required */
while (UsedPages < PageCount)
{
/* If this overflows past the HAL heap, it means there's no space */
if (VirtualAddress == NULL) return NULL;
/* Get the PTE for this address */
PointerPte = HalAddressToPte(VirtualAddress);
/* Go to the next page */
VirtualAddress = (PVOID)((ULONG_PTR)VirtualAddress + PAGE_SIZE);
/* Check if the page is available */
if (PointerPte->Valid)
{
/* PTE has data, skip it and start with a new base address */
BaseAddress = VirtualAddress;
UsedPages = 0;
continue;
}
/* PTE is available, keep going on this run */
UsedPages++;
}
/* Take the base address of the page plus the actual offset in the address */
VirtualAddress = (PVOID)((ULONG_PTR)BaseAddress +
BYTE_OFFSET(PhysicalAddress.LowPart));
/* If we are starting at the heap, move the heap */
if (BaseAddress == HalpHeapStart)
{
/* Past this allocation */
HalpHeapStart = (PVOID)((ULONG_PTR)BaseAddress + (PageCount * PAGE_SIZE));
}
/* Loop pages that can be mapped */
while (UsedPages--)
{
/* Fill out the PTE */
PointerPte = HalAddressToPte(BaseAddress);
PointerPte->PageFrameNumber = (PFN_NUMBER)(PhysicalAddress.QuadPart >> PAGE_SHIFT);
PointerPte->Valid = 1;
PointerPte->Write = 1;
/* Move to the next address */
PhysicalAddress.QuadPart += PAGE_SIZE;
BaseAddress = (PVOID)((ULONG_PTR)BaseAddress + PAGE_SIZE);
}
/* Flush the TLB and return the address */
if (FlushCurrentTLB)
HalpFlushTLB();
return VirtualAddress;
}
VOID
NTAPI
HalpUnmapVirtualAddressVista(IN PVOID VirtualAddress,
IN PFN_COUNT PageCount,
IN BOOLEAN FlushCurrentTLB)
{
PHARDWARE_PTE PointerPte;
ULONG i;
/* Only accept valid addresses */
if (VirtualAddress < (PVOID)MM_HAL_VA_START) return;
/* Align it down to page size */
VirtualAddress = (PVOID)((ULONG_PTR)VirtualAddress & ~(PAGE_SIZE - 1));
/* Loop PTEs */
PointerPte = HalAddressToPte(VirtualAddress);
for (i = 0; i < PageCount; i++)
{
*(PULONG)PointerPte = 0;
PointerPte++;
}
/* Flush the TLB */
if (FlushCurrentTLB)
HalpFlushTLB();
/* Put the heap back */
if (HalpHeapStart > VirtualAddress) HalpHeapStart = VirtualAddress;
}