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reactos/ntoskrnl/ke/freeldr.c
Amine Khaldi 475719f162 [CMAKE] 
- Sync with trunk r51165.

svn path=/branches/cmake-bringup/; revision=51166
2011-03-26 23:14:25 +00:00

1417 lines
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/*
* PROJECT: ReactOS Kernel
* LICENSE: GPL - See COPYING in the top level directory
* FILE: ntoskrnl/ke/freeldr.c
* PURPOSE: FreeLDR Bootstrap Support
* PROGRAMMERS: Alex Ionescu (alex.ionescu@reactos.org)
*/
/* INCLUDES *****************************************************************/
#if !defined(_X86_)
#include <ntoskrnl.h>
#define NDEBUG
#include <debug.h>
#if defined(_PPC_)
#include <ppcmmu/mmu.h>
#define KERNEL_RVA(x) RVA(x,0x80800000)
#define KERNEL_DESCRIPTOR_PAGE(x) (((ULONG_PTR)x + KernelBase) >> PAGE_SHIFT)
#else
#define KERNEL_RVA(x) RVA(x,KSEG0_BASE)
#define KERNEL_DESCRIPTOR_PAGE(x) (((ULONG_PTR)x &~ KSEG0_BASE) >> PAGE_SHIFT)
#endif
typedef struct _BIOS_MEMORY_DESCRIPTOR
{
ULONG BlockBase;
ULONG BlockSize;
} BIOS_MEMORY_DESCRIPTOR, *PBIOS_MEMORY_DESCRIPTOR;
/* GLOBALS *******************************************************************/
/* FreeLDR Loader Data */
PROS_LOADER_PARAMETER_BLOCK KeRosLoaderBlock;
ADDRESS_RANGE KeMemoryMap[64];
ULONG KeMemoryMapRangeCount;
/* NT Loader Module/Descriptor Count */
ULONG BldrCurrentMd;
ULONG BldrCurrentMod;
/* NT Loader Data. Eats up about 100KB! */
LOADER_PARAMETER_BLOCK BldrLoaderBlock; // 0x0000
LOADER_PARAMETER_EXTENSION BldrExtensionBlock; // 0x0060
CHAR BldrCommandLine[256]; // 0x00DC
CHAR BldrArcBootPath[64]; // 0x01DC
CHAR BldrArcHalPath[64]; // 0x021C
CHAR BldrNtHalPath[64]; // 0x025C
CHAR BldrNtBootPath[64]; // 0x029C
LDR_DATA_TABLE_ENTRY BldrModules[64]; // 0x02DC
MEMORY_ALLOCATION_DESCRIPTOR BldrMemoryDescriptors[60]; // 0x14DC
WCHAR BldrModuleStrings[64][260]; // 0x19DC
WCHAR BldrModuleStringsFull[64][260]; // 0x9BDC
NLS_DATA_BLOCK BldrNlsDataBlock; // 0x11DDC
SETUP_LOADER_BLOCK BldrSetupBlock; // 0x11DE8
ARC_DISK_INFORMATION BldrArcDiskInfo; // 0x12134
CHAR BldrArcNames[32][256]; // 0x1213C
ARC_DISK_SIGNATURE BldrDiskInfo[32]; // 0x1413C
CHAR BldrArcHwBuffer[16 * 1024]; // 0x1843C
/* BIOS Memory Map */
BIOS_MEMORY_DESCRIPTOR BiosMemoryDescriptors[16] = { { 0, 0 }, };
PBIOS_MEMORY_DESCRIPTOR BiosMemoryDescriptorList = BiosMemoryDescriptors;
/* ARC Memory Map */
ULONG NumberDescriptors = 0;
MEMORY_DESCRIPTOR MDArray[60] = { { 0, 0, 0 }, };
#if defined(_X86_)
/* The Boot TSS */
KTSS KiBootTss;
/* Old boot style IDT */
KIDTENTRY KiBootIdt[256];
/* The Boot GDT */
KGDTENTRY KiBootGdt[256] =
{
{0x0000, 0x0000, {{0x00, 0x00, 0x00, 0x00}}}, /* KGDT_NULL */
{0xffff, 0x0000, {{0x00, 0x9b, 0xcf, 0x00}}}, /* KGDT_R0_CODE */
{0xffff, 0x0000, {{0x00, 0x93, 0xcf, 0x00}}}, /* KGDT_R0_DATA */
{0xffff, 0x0000, {{0x00, 0xfb, 0xcf, 0x00}}}, /* KGDT_R3_CODE */
{0xffff, 0x0000, {{0x00, 0xf3, 0xcf, 0x00}}}, /* KGDT_R3_DATA*/
{0x0000, 0x0000, {{0x00, 0x00, 0x00, 0x00}}}, /* KGDT_TSS */
{0x0001, 0xf000, {{0xdf, 0x93, 0xc0, 0xff}}}, /* KGDT_R0_PCR */
{0x0fff, 0x0000, {{0x00, 0xf3, 0x40, 0x00}}}, /* KGDT_R3_TEB */
{0x0000, 0x0000, {{0x00, 0x00, 0x00, 0x00}}}, /* KGDT_UNUSED */
{0x0000, 0x0000, {{0x00, 0x00, 0x00, 0x00}}}, /* KGDT_LDT */
{0x0000, 0x0000, {{0x00, 0x00, 0x00, 0x00}}}, /* KGDT_DF_TSS */
{0x0000, 0x0000, {{0x00, 0x00, 0x00, 0x00}}} /* KGDT_NMI_TSS */
};
/* GDT Descriptor */
KDESCRIPTOR KiGdtDescriptor = {0, sizeof(KiBootGdt) - 1, (ULONG)KiBootGdt};
#endif
/* FUNCTIONS *****************************************************************/
PMEMORY_ALLOCATION_DESCRIPTOR
NTAPI
KiRosGetMdFromArray(VOID)
{
/* Return the next MD from the list, but make sure we don't overflow */
if (BldrCurrentMd > 60) ASSERT(FALSE);
return &BldrMemoryDescriptors[BldrCurrentMd++];
}
VOID
NTAPI
KiRosAddBiosBlock(ULONG Address,
ULONG Size)
{
PBIOS_MEMORY_DESCRIPTOR BiosBlock = BiosMemoryDescriptorList;
/* Loop our BIOS Memory Descriptor List */
while (BiosBlock->BlockSize > 0)
{
/* Check if we've found a matching head block */
if (Address + Size == BiosBlock->BlockBase)
{
/* Simply enlarge and rebase it */
BiosBlock->BlockBase = Address;
BiosBlock->BlockSize += Size;
break;
}
/* Check if we've found a matching tail block */
if (Address == (BiosBlock->BlockBase + BiosBlock->BlockSize))
{
/* Simply enlarge it */
BiosBlock->BlockSize += Size;
break;
}
/* Nothing suitable found, try the next block */
BiosBlock++;
}
/* No usable blocks found, found a free block instead */
if (!BiosBlock->BlockSize)
{
/* Write our data */
BiosBlock->BlockBase = Address;
BiosBlock->BlockSize = Size;
/* Create a new block and mark it as the end of the array */
BiosBlock++;
BiosBlock->BlockBase = BiosBlock->BlockSize = 0L;
}
}
VOID
NTAPI
KiRosBuildBiosMemoryMap(VOID)
{
ULONG BlockBegin, BlockEnd;
ULONG j;
/* Loop the BIOS Memory Map */
for (j = 0; j < KeMemoryMapRangeCount; j++)
{
/* Get the start and end addresses */
BlockBegin = KeMemoryMap[j].BaseAddrLow;
BlockEnd = KeMemoryMap[j].BaseAddrLow + KeMemoryMap[j].LengthLow - 1;
/* Make sure this isn't a > 4GB descriptor */
if (!KeMemoryMap[j].BaseAddrHigh)
{
/* Make sure we don't overflow */
if (BlockEnd < BlockBegin) BlockEnd = 0xFFFFFFFF;
/* Check if this is free memory */
if (KeMemoryMap[j].Type == 1)
{
/* Add it to our BIOS descriptors */
KiRosAddBiosBlock(BlockBegin, BlockEnd - BlockBegin + 1);
}
}
}
}
NTSTATUS
NTAPI
KiRosAllocateArcDescriptor(IN ULONG PageBegin,
IN ULONG PageEnd,
IN MEMORY_TYPE MemoryType)
{
ULONG i;
/* Loop all our descriptors */
for (i = 0; i < NumberDescriptors; i++)
{
/* Attempt to fing a free block that describes our region */
if ((MDArray[i].MemoryType == MemoryFree) &&
(MDArray[i].BasePage <= PageBegin) &&
(MDArray[i].BasePage + MDArray[i].PageCount > PageBegin) &&
(MDArray[i].BasePage + MDArray[i].PageCount >= PageEnd))
{
/* Found one! */
break;
}
}
/* Check if we found no free blocks, and fail if so */
if (i == NumberDescriptors) return ENOMEM;
/* Check if the block has our base address */
if (MDArray[i].BasePage == PageBegin)
{
/* Check if it also has our ending address */
if ((MDArray[i].BasePage + MDArray[i].PageCount) == PageEnd)
{
/* Then convert this region into our new memory type */
MDArray[i].MemoryType = MemoryType;
}
else
{
/* Otherwise, make sure we have enough descriptors */
if (NumberDescriptors == 60) return ENOMEM;
/* Cut this descriptor short */
MDArray[i].BasePage = PageEnd;
MDArray[i].PageCount -= (PageEnd - PageBegin);
/* And allocate a new descriptor for our memory range */
MDArray[NumberDescriptors].BasePage = PageBegin;
MDArray[NumberDescriptors].PageCount = PageEnd - PageBegin;
MDArray[NumberDescriptors].MemoryType = MemoryType;
NumberDescriptors++;
}
}
else if ((MDArray[i].BasePage + MDArray[i].PageCount) == PageEnd)
{
/* This block has our end address, make sure we have a free block */
if (NumberDescriptors == 60) return ENOMEM;
/* Rebase this descriptor */
MDArray[i].PageCount = PageBegin - MDArray[i].BasePage;
/* And allocate a new descriptor for our memory range */
MDArray[NumberDescriptors].BasePage = PageBegin;
MDArray[NumberDescriptors].PageCount = PageEnd - PageBegin;
MDArray[NumberDescriptors].MemoryType = MemoryType;
NumberDescriptors++;
}
else
{
/* We'll need two descriptors, make sure they're available */
if ((NumberDescriptors + 1) >= 60) return ENOMEM;
/* Allocate a free memory descriptor for what follows us */
MDArray[NumberDescriptors].BasePage = PageEnd;
MDArray[NumberDescriptors].PageCount = MDArray[i].PageCount -
(PageEnd - MDArray[i].BasePage);
MDArray[NumberDescriptors].MemoryType = MemoryFree;
NumberDescriptors++;
/* Cut down the current free descriptor */
MDArray[i].PageCount = PageBegin - MDArray[i].BasePage;
/* Allocate a new memory descriptor for our memory range */
MDArray[NumberDescriptors].BasePage = PageBegin;
MDArray[NumberDescriptors].PageCount = PageEnd - PageBegin;
MDArray[NumberDescriptors].MemoryType = MemoryType;
NumberDescriptors++;
}
/* Everything went well */
return STATUS_SUCCESS;
}
NTSTATUS
NTAPI
KiRosConfigureArcDescriptor(IN ULONG PageBegin,
IN ULONG PageEnd,
IN TYPE_OF_MEMORY MemoryType)
{
ULONG i;
ULONG BlockBegin, BlockEnd;
MEMORY_TYPE BlockType;
BOOLEAN Combined = FALSE;
/* If this descriptor seems bogus, just return */
if (PageEnd <= PageBegin) return STATUS_SUCCESS;
/* Loop every ARC descriptor, trying to find one we can modify */
for (i = 0; i < NumberDescriptors; i++)
{
/* Get its settings */
BlockBegin = MDArray[i].BasePage;
BlockEnd = MDArray[i].BasePage + MDArray[i].PageCount;
BlockType = MDArray[i].MemoryType;
/* Check if we can fit inside this block */
if (BlockBegin < PageBegin)
{
/* Check if we are larger then it */
if ((BlockEnd > PageBegin) && (BlockEnd <= PageEnd))
{
/* Make it end where we start */
BlockEnd = PageBegin;
}
/* Check if it ends after we do */
if (BlockEnd > PageEnd)
{
/* Make sure we can allocate a descriptor */
if (NumberDescriptors == 60) return ENOMEM;
/* Create a descriptor for whatever memory we're not part of */
MDArray[NumberDescriptors].MemoryType = BlockType;
MDArray[NumberDescriptors].BasePage = PageEnd;
MDArray[NumberDescriptors].PageCount = BlockEnd - PageEnd;
NumberDescriptors++;
/* The next block ending is now where we begin */
BlockEnd = PageBegin;
}
}
else
{
/* Check if the blog begins inside our range */
if (BlockBegin < PageEnd)
{
/* Check if it ends before we do */
if (BlockEnd < PageEnd)
{
/* Then make it disappear */
BlockEnd = BlockBegin;
}
else
{
/* Otherwise make it start where we end */
BlockBegin = PageEnd;
}
}
}
/* Check if the block matches us, and we haven't tried combining yet */
if (((TYPE_OF_MEMORY)BlockType == MemoryType) && !(Combined))
{
/* Check if it starts where we end */
if (BlockBegin == PageEnd)
{
/* Make it start with us, and combine us */
BlockBegin = PageBegin;
Combined = TRUE;
}
else if (BlockEnd == PageBegin)
{
/* Otherwise, it ends where we begin, combine its ending */
BlockEnd = PageEnd;
Combined = TRUE;
}
}
/* Check the original block data matches with what we came up with */
if ((MDArray[i].BasePage == BlockBegin) &&
(MDArray[i].PageCount == BlockEnd - BlockBegin))
{
/* Then skip it */
continue;
}
/* Otherwise, set our new settings for this block */
MDArray[i].BasePage = BlockBegin;
MDArray[i].PageCount = BlockEnd - BlockBegin;
/* Check if we are killing the block */
if (BlockBegin == BlockEnd)
{
/* Delete this block and restart the loop properly */
NumberDescriptors--;
if (i < NumberDescriptors) MDArray[i] = MDArray[NumberDescriptors];
i--;
}
}
/* If we got here without combining, we need to allocate a new block */
if (!(Combined) && (MemoryType < LoaderMaximum))
{
/* Make sure there's enough descriptors */
if (NumberDescriptors == 60) return ENOMEM;
/* Allocate a new block with our data */
MDArray[NumberDescriptors].MemoryType = MemoryType;
MDArray[NumberDescriptors].BasePage = PageBegin;
MDArray[NumberDescriptors].PageCount = PageEnd - PageBegin;
NumberDescriptors++;
}
/* Changes complete, return success */
return STATUS_SUCCESS;
}
NTSTATUS
NTAPI
KiRosBuildOsMemoryMap(VOID)
{
PBIOS_MEMORY_DESCRIPTOR MdBlock;
ULONG BlockStart, BlockEnd, BiasedStart, BiasedEnd, PageStart, PageEnd;
NTSTATUS Status = STATUS_SUCCESS;
ULONG BiosPage = 0xA0;
/* Loop the BIOS Memory Descriptor List */
MdBlock = BiosMemoryDescriptorList;
while (MdBlock->BlockSize)
{
/* Get the statrt and end addresses */
BlockStart = MdBlock->BlockBase;
BlockEnd = BlockStart + MdBlock->BlockSize - 1;
/* Align them to page boundaries */
BiasedStart = BlockStart & (PAGE_SIZE - 1);
if (BiasedStart) BlockStart = BlockStart + PAGE_SIZE - BiasedStart;
BiasedEnd = (BlockEnd + 1) & (ULONG)(PAGE_SIZE - 1);
if (BiasedEnd) BlockEnd -= BiasedEnd;
/* Get the actual page numbers */
PageStart = BlockStart >> PAGE_SHIFT;
PageEnd = (BlockEnd + 1) >> PAGE_SHIFT;
/* If we're starting at page 0, then put the BIOS page at the end */
if (!PageStart) BiosPage = PageEnd;
/* Check if we did any alignment */
if (BiasedStart)
{
/* Mark that region as reserved */
Status = KiRosConfigureArcDescriptor(PageStart - 1,
PageStart,
MemorySpecialMemory);
if (Status != STATUS_SUCCESS) break;
}
/* Check if we did any alignment */
if (BiasedEnd)
{
/* Mark that region as reserved */
Status = KiRosConfigureArcDescriptor(PageEnd - 1,
PageEnd,
MemorySpecialMemory);
if (Status != STATUS_SUCCESS) break;
/* If the bios page was the last page, use the next one instead */
if (BiosPage == PageEnd) BiosPage += 1;
}
/* Check if the page is below the 16MB Memory hole */
if (PageEnd <= 0xFC0)
{
/* It is, mark the memory a free */
Status = KiRosConfigureArcDescriptor(PageStart,
PageEnd,
LoaderFree);
}
else if (PageStart >= 0x1000)
{
/* It's over 16MB, so that memory gets marked as reserve */
Status = KiRosConfigureArcDescriptor(PageStart,
PageEnd,
LoaderFree);
}
else
{
/* Check if it starts below the memory hole */
if (PageStart < 0xFC0)
{
/* Mark that part as free */
Status = KiRosConfigureArcDescriptor(PageStart,
0xFC0,
MemoryFree);
if (Status != STATUS_SUCCESS) break;
/* And update the page start for the code below */
PageStart = 0xFC0;
}
/* Any code in the memory hole region ends up as reserve */
Status = KiRosConfigureArcDescriptor(PageStart,
PageEnd,
LoaderFree);
}
/* If we failed, break out, otherwise, go to the next BIOS block */
if (Status != STATUS_SUCCESS) break;
MdBlock++;
}
/* If anything failed until now, return error code */
if (Status != STATUS_SUCCESS) return Status;
#if defined(_X86_)
/* Set the top 16MB region as reserved */
Status = KiRosConfigureArcDescriptor(0xFC0, 0x1000, MemorySpecialMemory);
if (Status != STATUS_SUCCESS) return Status;
/* Setup the BIOS region as reserved */
KiRosConfigureArcDescriptor(0xA0, 0x100, LoaderMaximum);
KiRosConfigureArcDescriptor(BiosPage, 0x100, MemoryFirmwarePermanent);
/* Build an entry for the IVT */
Status = KiRosAllocateArcDescriptor(0, 1, MemoryFirmwarePermanent);
if (Status != STATUS_SUCCESS) return Status;
#endif
/* Build an entry for the KPCR and KUSER_SHARED_DATA */
Status = KiRosAllocateArcDescriptor(1, 3, LoaderStartupPcrPage);
if (Status != STATUS_SUCCESS) return Status;
/* Build an entry for the PDE and return the status */
Status = KiRosAllocateArcDescriptor(KeRosLoaderBlock->
PageDirectoryStart >> PAGE_SHIFT,
KeRosLoaderBlock->
PageDirectoryEnd >> PAGE_SHIFT,
LoaderMemoryData);
return Status;
}
#if defined(_X86_)
VOID
NTAPI
KiRosBuildReservedMemoryMap(VOID)
{
ULONG j;
ULONG BlockBegin, BlockEnd, BiasedPage;
/* Loop the BIOS Memory Map */
for (j = 0; j < KeMemoryMapRangeCount; j++)
{
/* Get the start and end addresses */
BlockBegin = KeMemoryMap[j].BaseAddrLow;
BlockEnd = BlockBegin + KeMemoryMap[j].LengthLow - 1;
/* Make sure it wasn't a > 4GB descriptor */
if (!KeMemoryMap[j].BaseAddrHigh)
{
/* Make sure it doesn't overflow */
if (BlockEnd < BlockBegin) BlockEnd = 0xFFFFFFFF;
/* Check if this was free memory */
if (KeMemoryMap[j].Type == 1)
{
/* Get the page-aligned addresses */
BiasedPage = BlockBegin & (PAGE_SIZE - 1);
BlockBegin >>= PAGE_SHIFT;
if (BiasedPage) BlockBegin++;
BlockEnd = (BlockEnd >> PAGE_SHIFT) + 1;
/* Check if the block is within the 16MB memory hole */
if ((BlockBegin < 0xFC0) && (BlockEnd >= 0xFC0))
{
/* Don't allow it to cross this boundary */
BlockBegin = 0xFC0;
}
/* Check if the boundary is across 16MB */
if ((BlockEnd > 0xFFF) && (BlockBegin <= 0xFFF))
{
/* Don't let it cross */
BlockEnd = 0xFFF;
}
/* Check if the block describes the memory hole */
if ((BlockBegin >= 0xFC0) && (BlockEnd <= 0xFFF))
{
/* Set this region as temporary */
KiRosConfigureArcDescriptor(BlockBegin,
BlockEnd,
MemoryFirmwareTemporary);
}
}
else
{
/* Get the page-aligned addresses */
BlockBegin >>= PAGE_SHIFT;
BiasedPage = (BlockEnd + 1) & (PAGE_SIZE - 1);
BlockEnd >>= PAGE_SHIFT;
if (BiasedPage) BlockEnd++;
/* Set this memory as reserved */
KiRosConfigureArcDescriptor(BlockBegin,
BlockEnd + 1,
MemorySpecialMemory);
}
}
}
}
#endif
VOID
NTAPI
KiRosInsertNtDescriptor(IN PMEMORY_ALLOCATION_DESCRIPTOR NewDescriptor)
{
PLIST_ENTRY ListHead, PreviousEntry, NextEntry;
PMEMORY_ALLOCATION_DESCRIPTOR Descriptor = NULL, NextDescriptor = NULL;
/* Loop the memory descriptor list */
ListHead = &KeLoaderBlock->MemoryDescriptorListHead;
PreviousEntry = ListHead;
NextEntry = ListHead->Flink;
while (NextEntry != ListHead)
{
/* Get the current descriptor and check if it's below ours */
NextDescriptor = CONTAINING_RECORD(NextEntry,
MEMORY_ALLOCATION_DESCRIPTOR,
ListEntry);
if (NewDescriptor->BasePage < NextDescriptor->BasePage) break;
/* It isn't, save the previous entry and descriptor, and try again */
PreviousEntry = NextEntry;
Descriptor = NextDescriptor;
NextEntry = NextEntry->Flink;
}
/* So we found the right spot to insert. Is this free memory? */
if (NewDescriptor->MemoryType != LoaderFree)
{
/* It isn't, so insert us before the last descriptor */
InsertHeadList(PreviousEntry, &NewDescriptor->ListEntry);
}
else
{
/* We're free memory. Check if the entry we found is also free memory */
if ((PreviousEntry != ListHead) &&
((Descriptor->MemoryType == LoaderFree) ||
(Descriptor->MemoryType == LoaderReserve)) &&
((Descriptor->BasePage + Descriptor->PageCount) ==
NewDescriptor->BasePage))
{
/* It's free memory, and we're right after it. Enlarge that block */
Descriptor->PageCount += NewDescriptor->PageCount;
NewDescriptor = Descriptor;
}
else
{
/* Our range scan't be combined, so just insert us separately */
InsertHeadList(PreviousEntry, &NewDescriptor->ListEntry);
}
/* Check if we merged with an existing free memory block */
if ((NextEntry != ListHead) &&
((NextDescriptor->MemoryType == LoaderFree) ||
(NextDescriptor->MemoryType == LoaderReserve)) &&
((NewDescriptor->BasePage + NewDescriptor->PageCount) ==
NextDescriptor->BasePage))
{
/* Update our own block */
NewDescriptor->PageCount += NextDescriptor->PageCount;
/* Remove the next block */
RemoveEntryList(&NextDescriptor->ListEntry);
}
}
}
NTSTATUS
NTAPI
KiRosBuildNtDescriptor(IN PMEMORY_ALLOCATION_DESCRIPTOR MemoryDescriptor,
IN MEMORY_TYPE MemoryType,
IN ULONG BasePage,
IN ULONG PageCount)
{
PMEMORY_ALLOCATION_DESCRIPTOR Descriptor, NextDescriptor = NULL;
LONG Delta;
TYPE_OF_MEMORY CurrentType;
BOOLEAN UseNext;
/* Check how many pages we'll be consuming */
Delta = BasePage - MemoryDescriptor->BasePage;
if (!(Delta) && (PageCount == MemoryDescriptor->PageCount))
{
/* We can simply convert the current descriptor into our new type */
MemoryDescriptor->MemoryType = MemoryType;
}
else
{
/* Get the current memory type of the descriptor, and reserve it */
CurrentType = MemoryDescriptor->MemoryType;
MemoryDescriptor->MemoryType = LoaderSpecialMemory;
/* Check if we'll need another descriptor for what's left of memory */
UseNext = ((BasePage != MemoryDescriptor->BasePage) &&
(Delta + PageCount != MemoryDescriptor->PageCount));
/* Get a descriptor */
Descriptor = KiRosGetMdFromArray();
if (!Descriptor) return STATUS_INSUFFICIENT_RESOURCES;
/* Check if we are using another descriptor */
if (UseNext)
{
/* Allocate that one too */
NextDescriptor = KiRosGetMdFromArray();
if (!NextDescriptor) return STATUS_INSUFFICIENT_RESOURCES;
}
/* Build the descriptor we got */
Descriptor->MemoryType = MemoryType;
Descriptor->BasePage = BasePage;
Descriptor->PageCount = PageCount;
/* Check if we're starting at the same place as the old one */
if (BasePage == MemoryDescriptor->BasePage)
{
/* Simply decrease the old descriptor and rebase it */
MemoryDescriptor->BasePage += PageCount;
MemoryDescriptor->PageCount -= PageCount;
MemoryDescriptor->MemoryType = CurrentType;
}
else if (Delta + PageCount == MemoryDescriptor->PageCount)
{
/* We finish where the old one did, shorten it */
MemoryDescriptor->PageCount -= PageCount;
MemoryDescriptor->MemoryType = CurrentType;
}
else
{
/* We're inside the current block, mark our free region */
NextDescriptor->MemoryType = LoaderFree;
NextDescriptor->BasePage = BasePage + PageCount;
NextDescriptor->PageCount = MemoryDescriptor->PageCount -
(PageCount + Delta);
/* And cut down the current descriptor */
MemoryDescriptor->PageCount = Delta;
MemoryDescriptor->MemoryType = CurrentType;
/* Finally, insert our new free descriptor into the list */
KiRosInsertNtDescriptor(NextDescriptor);
}
/* Insert the descriptor we allocated */
KiRosInsertNtDescriptor(Descriptor);
}
/* Return success */
return STATUS_SUCCESS;
}
PMEMORY_ALLOCATION_DESCRIPTOR
NTAPI
KiRosFindNtDescriptor(IN ULONG BasePage)
{
PMEMORY_ALLOCATION_DESCRIPTOR MdBlock = NULL;
PLIST_ENTRY NextEntry, ListHead;
/* Scan the memory descriptor list */
ListHead = &KeLoaderBlock->MemoryDescriptorListHead;
NextEntry = ListHead->Flink;
while (NextEntry != ListHead)
{
/* Get the current descriptor */
MdBlock = CONTAINING_RECORD(NextEntry,
MEMORY_ALLOCATION_DESCRIPTOR,
ListEntry);
/* Check if it can contain our memory range */
if ((MdBlock->BasePage <= BasePage) &&
(MdBlock->BasePage + MdBlock->PageCount > BasePage))
{
/* It can, break out */
break;
}
/* Go to the next descriptor */
NextEntry = NextEntry->Flink;
}
/* Return the descriptor we found, if any */
return MdBlock;
}
NTSTATUS
NTAPI
KiRosAllocateNtDescriptor(IN TYPE_OF_MEMORY MemoryType,
IN ULONG BasePage,
IN ULONG PageCount,
IN ULONG Alignment,
OUT PULONG ReturnedBase)
{
PMEMORY_ALLOCATION_DESCRIPTOR MdBlock;
ULONG AlignedBase, AlignedLimit;
PMEMORY_ALLOCATION_DESCRIPTOR ActiveMdBlock;
ULONG ActiveAlignedBase = 0;
PLIST_ENTRY NextEntry, ListHead;
/* If no information was given, make some assumptions */
if (!Alignment) Alignment = 1;
if (!PageCount) PageCount = 1;
/* Start looking for a matching descvriptor */
do
{
/* Calculate the limit of the range */
AlignedLimit = PageCount + BasePage;
/* Find a descriptor that already contains our base address */
MdBlock = KiRosFindNtDescriptor(BasePage);
if (MdBlock)
{
/* If it contains our limit as well, break out early */
if ((MdBlock->PageCount + MdBlock->BasePage) >= AlignedLimit) break;
}
/* Loop the memory list */
ActiveMdBlock = NULL;
ListHead = &KeLoaderBlock->MemoryDescriptorListHead;
NextEntry = ListHead->Flink;
while (NextEntry != ListHead)
{
/* Get the current descriptors */
MdBlock = CONTAINING_RECORD(NextEntry,
MEMORY_ALLOCATION_DESCRIPTOR,
ListEntry);
/* Align the base address and our limit */
AlignedBase = (MdBlock->BasePage + (Alignment - 1)) &~ Alignment;
AlignedLimit = MdBlock->PageCount -
AlignedBase +
MdBlock->BasePage;
/* Check if this is a free block that can satisfy us */
if ((MdBlock->MemoryType == LoaderFree) &&
(AlignedLimit <= MdBlock->PageCount) &&
(PageCount <= AlignedLimit))
{
/* It is, stop searching */
ActiveMdBlock = MdBlock;
ActiveAlignedBase = AlignedBase;
break;
}
/* Try the next block */
NextEntry = NextEntry->Flink;
}
/* See if we came up with an adequate block */
if (ActiveMdBlock)
{
/* Generate a descriptor in it */
*ReturnedBase = AlignedBase;
return KiRosBuildNtDescriptor(ActiveMdBlock,
MemoryType,
ActiveAlignedBase,
PageCount);
}
} while (TRUE);
/* We found a matching block, generate a descriptor with it */
*ReturnedBase = BasePage;
return KiRosBuildNtDescriptor(MdBlock, MemoryType, BasePage, PageCount);
}
NTSTATUS
NTAPI
KiRosBuildArcMemoryList(VOID)
{
PMEMORY_ALLOCATION_DESCRIPTOR Descriptor;
MEMORY_DESCRIPTOR *Memory;
ULONG i;
/* Loop all BIOS Memory Descriptors */
for (i = 0; i < NumberDescriptors; i++)
{
/* Get the current descriptor */
Memory = &MDArray[i];
/* Allocate an NT Memory Descriptor */
Descriptor = KiRosGetMdFromArray();
if (!Descriptor) return ENOMEM;
/* Copy the memory type */
Descriptor->MemoryType = Memory->MemoryType;
if (Memory->MemoryType == MemoryFreeContiguous)
{
/* Convert this to free */
Descriptor->MemoryType = LoaderFree;
}
else if (Memory->MemoryType == MemorySpecialMemory)
{
/* Convert this to special memory */
Descriptor->MemoryType = LoaderSpecialMemory;
}
/* Copy the range data */
Descriptor->BasePage = Memory->BasePage;
Descriptor->PageCount = Memory->PageCount;
/* Insert the descriptor */
if (Descriptor->PageCount) KiRosInsertNtDescriptor(Descriptor);
}
/* All went well */
return STATUS_SUCCESS;
}
VOID
NTAPI
KiRosFixupComponentTree(IN PCONFIGURATION_COMPONENT_DATA p,
IN ULONG i)
{
PCONFIGURATION_COMPONENT pp;
/* Loop each entry */
while (p)
{
/* Grab the component entry */
pp = &p->ComponentEntry;
/* Fixup the pointers */
if (pp->Identifier) pp->Identifier = (PVOID)((ULONG_PTR)pp->Identifier + i);
if (p->ConfigurationData) p->ConfigurationData = (PVOID)((ULONG_PTR)p->ConfigurationData + i);
if (p->Parent) p->Parent = (PVOID)((ULONG_PTR)p->Parent + i);
if (p->Sibling) p->Sibling = (PVOID)((ULONG_PTR)p->Sibling + i);
if (p->Child) p->Child = (PVOID)((ULONG_PTR)p->Child + i);
/* Check if we have a child */
if (p->Child) KiRosFixupComponentTree(p->Child, i);
/* Get to the next entry */
p = p->Sibling;
}
}
VOID
NTAPI
KiRosFrldrLpbToNtLpb(IN PROS_LOADER_PARAMETER_BLOCK RosLoaderBlock,
IN PLOADER_PARAMETER_BLOCK *NtLoaderBlock)
{
PLOADER_PARAMETER_BLOCK LoaderBlock;
PLDR_DATA_TABLE_ENTRY LdrEntry;
PLOADER_MODULE RosEntry = NULL;
ULONG i, j, ModSize;
PVOID ModStart;
PCHAR DriverName;
PCHAR BootPath, HalPath;
CHAR CommandLine[256];
PARC_DISK_SIGNATURE RosDiskInfo, ArcDiskInfo;
PIMAGE_NT_HEADERS NtHeader;
WCHAR PathToDrivers[] = L"\\SystemRoot\\System32\\drivers\\";
WCHAR PathToSystem32[] = L"\\SystemRoot\\System32\\";
WCHAR PathSetup[] = L"\\SystemRoot\\";
CHAR DriverNameLow[256];
ULONG Base;
size_t Remaining;
WCHAR *StringEnd;
#if defined(_PPC_)
ULONG KernelBase = RosLoaderBlock->ModsAddr[0].ModStart;
#endif
/* Set the NT Loader block and initialize it */
*NtLoaderBlock = KeLoaderBlock = LoaderBlock = &BldrLoaderBlock;
RtlZeroMemory(LoaderBlock, sizeof(LOADER_PARAMETER_BLOCK));
/* Set the NLS Data block */
LoaderBlock->NlsData = &BldrNlsDataBlock;
/* Set the ARC Data block */
LoaderBlock->ArcDiskInformation = &BldrArcDiskInfo;
/* Assume this is from FreeLDR's SetupLdr */
LoaderBlock->SetupLdrBlock = &BldrSetupBlock;
/* Setup the list heads */
InitializeListHead(&LoaderBlock->LoadOrderListHead);
InitializeListHead(&LoaderBlock->MemoryDescriptorListHead);
InitializeListHead(&LoaderBlock->BootDriverListHead);
InitializeListHead(&LoaderBlock->ArcDiskInformation->DiskSignatureListHead);
/* Build the free memory map, which uses BIOS Descriptors */
KiRosBuildBiosMemoryMap();
/* Build entries for ReactOS memory ranges, which uses ARC Descriptors */
KiRosBuildOsMemoryMap();
#if defined(_X86_)
/* Build entries for the reserved map, which uses ARC Descriptors */
KiRosBuildReservedMemoryMap();
#endif
/* Now convert the BIOS and ARC Descriptors into NT Memory Descirptors */
KiRosBuildArcMemoryList();
/* Loop boot driver list */
for (i = 0; i < RosLoaderBlock->ModsCount; i++)
{
/* Get the ROS loader entry */
RosEntry = &RosLoaderBlock->ModsAddr[i];
DriverName = (PCHAR)RosEntry->String;
ModStart = (PVOID)RosEntry->ModStart;
ModSize = RosEntry->ModEnd - (ULONG_PTR)ModStart;
#if defined(_PPC_)
ModStart -= KernelBase;
#endif
/* Check if this is any of the NLS files */
if (!_stricmp(DriverName, "ansi.nls"))
{
/* ANSI Code page */
LoaderBlock->NlsData->AnsiCodePageData = KERNEL_RVA(ModStart);
/* Create an MD for it */
KiRosAllocateNtDescriptor(LoaderNlsData,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
continue;
}
else if (!_stricmp(DriverName, "oem.nls"))
{
/* OEM Code page */
LoaderBlock->NlsData->OemCodePageData = KERNEL_RVA(ModStart);
/* Create an MD for it */
KiRosAllocateNtDescriptor(LoaderNlsData,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
continue;
}
else if (!_stricmp(DriverName, "casemap.nls"))
{
/* Unicode Code page */
LoaderBlock->NlsData->UnicodeCodePageData = KERNEL_RVA(ModStart);
/* Create an MD for it */
KiRosAllocateNtDescriptor(LoaderNlsData,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
continue;
}
/* Check if this is the SYSTEM hive */
if (!(_stricmp(DriverName, "system")) ||
!(_stricmp(DriverName, "system.hiv")))
{
/* Save registry data */
LoaderBlock->RegistryBase = KERNEL_RVA(ModStart);
LoaderBlock->RegistryLength = ModSize;
/* Disable setup mode */
LoaderBlock->SetupLdrBlock = NULL;
/* Create an MD for it */
KiRosAllocateNtDescriptor(LoaderRegistryData,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
continue;
}
/* Check if this is the HARDWARE hive */
if (!(_stricmp(DriverName, "hardware")) ||
!(_stricmp(DriverName, "hardware.hiv")))
{
/* Create an MD for it */
KiRosAllocateNtDescriptor(LoaderRegistryData,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
continue;
}
/* Check if this is the kernel */
if (!(_stricmp(DriverName, "ntoskrnl.exe")))
{
/* Create an MD for it */
KiRosAllocateNtDescriptor(LoaderSystemCode,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
}
else if (!(_stricmp(DriverName, "hal.dll")))
{
/* Create an MD for the HAL */
KiRosAllocateNtDescriptor(LoaderHalCode,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
}
else
{
/* Create an MD for any driver */
KiRosAllocateNtDescriptor(LoaderBootDriver,
KERNEL_DESCRIPTOR_PAGE(ModStart),
(ModSize + PAGE_SIZE - 1)>> PAGE_SHIFT,
0,
&Base);
}
#if defined(_PPC_)
ModStart += 0x80800000;
#endif
/* Lowercase the drivername so we can check its extension later */
strcpy(DriverNameLow, DriverName);
_strlwr(DriverNameLow);
/* Setup the loader entry */
LdrEntry = &BldrModules[i];
RtlZeroMemory(LdrEntry, sizeof(LDR_DATA_TABLE_ENTRY));
/* Convert driver name from ANSI to Unicode */
for (j = 0; j < strlen(DriverName); j++)
{
BldrModuleStrings[i][j] = DriverName[j];
}
/* Setup driver name */
RtlInitUnicodeString(&LdrEntry->BaseDllName, BldrModuleStrings[i]);
/* Construct a correct full name */
BldrModuleStringsFull[i][0] = 0;
LdrEntry->FullDllName.MaximumLength = sizeof(BldrModuleStringsFull[i]);
LdrEntry->FullDllName.Length = 0;
LdrEntry->FullDllName.Buffer = BldrModuleStringsFull[i];
/* Guess the path */
if (LoaderBlock->SetupLdrBlock)
{
UNICODE_STRING TempString;
RtlInitUnicodeString(&TempString, PathSetup);
RtlAppendUnicodeStringToString(&LdrEntry->FullDllName, &TempString);
}
else if (strstr(DriverNameLow, ".dll") || strstr(DriverNameLow, ".exe"))
{
UNICODE_STRING TempString;
RtlInitUnicodeString(&TempString, PathToSystem32);
RtlAppendUnicodeStringToString(&LdrEntry->FullDllName, &TempString);
}
else /* .sys */
{
UNICODE_STRING TempString;
RtlInitUnicodeString(&TempString, PathToDrivers);
RtlAppendUnicodeStringToString(&LdrEntry->FullDllName, &TempString);
}
/* Append base name of the driver */
RtlAppendUnicodeStringToString(&LdrEntry->FullDllName, &LdrEntry->BaseDllName);
/* Copy data from Freeldr Module Entry */
LdrEntry->DllBase = ModStart;
LdrEntry->SizeOfImage = ModSize;
/* Copy additional data */
NtHeader = RtlImageNtHeader(ModStart);
LdrEntry->EntryPoint = RVA(ModStart,
NtHeader->
OptionalHeader.AddressOfEntryPoint);
/* Initialize other data */
LdrEntry->LoadCount = 1;
LdrEntry->Flags = LDRP_IMAGE_DLL |
LDRP_ENTRY_PROCESSED;
if (RosEntry->Reserved) LdrEntry->Flags |= LDRP_ENTRY_INSERTED;
/* Check if this is HAL */
if (!(_stricmp(DriverName, "hal.dll")))
{
/* Check if there is a second entry already */
if (LoaderBlock->LoadOrderListHead.Flink->Flink !=
&LoaderBlock->LoadOrderListHead)
{
PLIST_ENTRY OldSecondEntry;
/* Get the second entry */
OldSecondEntry =
LoaderBlock->LoadOrderListHead.Flink->Flink;
/* Set up our entry correctly */
LdrEntry->InLoadOrderLinks.Flink = OldSecondEntry;
LdrEntry->InLoadOrderLinks.Blink = OldSecondEntry->Blink;
/* Make the first entry (always the kernel) point to us */
LoaderBlock->LoadOrderListHead.Flink->Flink =
&LdrEntry->InLoadOrderLinks;
/* Make the old entry point back to us and continue looping */
OldSecondEntry->Blink = &LdrEntry->InLoadOrderLinks;
continue;
}
}
/* Insert it into the loader block */
InsertTailList(&LoaderBlock->LoadOrderListHead,
&LdrEntry->InLoadOrderLinks);
}
/* Now mark the remainder of the FreeLDR 6MB area as "in use" */
KiRosAllocateNtDescriptor(LoaderMemoryData,
KERNEL_DESCRIPTOR_PAGE(RosEntry->ModEnd),
KERNEL_DESCRIPTOR_PAGE((0x80800000 + 0x600000)) -
KERNEL_DESCRIPTOR_PAGE(RosEntry->ModEnd),
0,
&Base);
/* Check if we have a ramdisk */
if ((RosLoaderBlock->RdAddr) && (RosLoaderBlock->RdLength))
{
/* Build a descriptor for it */
KiRosAllocateNtDescriptor(LoaderXIPRom,
KERNEL_DESCRIPTOR_PAGE(RosLoaderBlock->RdAddr),
(RosLoaderBlock->RdLength + PAGE_SIZE - 1) >> PAGE_SHIFT,
0,
&Base);
}
/* Setup command line */
LoaderBlock->LoadOptions = BldrCommandLine;
strcpy(BldrCommandLine, RosLoaderBlock->CommandLine);
/* Setup the extension block */
LoaderBlock->Extension = &BldrExtensionBlock;
LoaderBlock->Extension->Size = sizeof(LOADER_PARAMETER_EXTENSION);
LoaderBlock->Extension->MajorVersion = 5;
LoaderBlock->Extension->MinorVersion = 2;
/* FreeLDR hackllocates 1536 static pages for the initial boot images */
LoaderBlock->Extension->LoaderPagesSpanned = 1536 * PAGE_SIZE;
/* ReactOS always boots the kernel at 0x80800000 (just like NT 5.2) */
LoaderBlock->Extension->LoaderPagesSpanned += 0x80800000 - KSEG0_BASE;
/* Now convert to pages */
LoaderBlock->Extension->LoaderPagesSpanned /= PAGE_SIZE;
/* Check if FreeLdr detected a ACPI table */
if (RosLoaderBlock->Flags & MB_FLAGS_ACPI_TABLE)
{
/* Set the pointer to something for compatibility */
LoaderBlock->Extension->AcpiTable = (PVOID)1;
}
/* Now setup the setup block if we have one */
if (LoaderBlock->SetupLdrBlock)
{
/* All we'll setup right now is the flag for text-mode setup */
LoaderBlock->SetupLdrBlock->Flags = SETUPLDR_TEXT_MODE;
}
/* Make a copy of the command line */
strcpy(CommandLine, LoaderBlock->LoadOptions);
/* Find the first \, separating the ARC path from NT path */
BootPath = strchr(CommandLine, '\\');
*BootPath = ANSI_NULL;
RtlStringCbCopyA(BldrArcBootPath, sizeof(BldrArcBootPath), CommandLine);
LoaderBlock->ArcBootDeviceName = BldrArcBootPath;
/* The rest of the string is the NT path */
HalPath = strchr(BootPath + 1, ' ');
*HalPath = ANSI_NULL;
Remaining = sizeof(BldrNtBootPath);
RtlStringCbCopyExA(BldrNtBootPath, Remaining, "\\", &StringEnd, &Remaining, 0);
RtlStringCbCopyExA(StringEnd, Remaining, BootPath + 1, &StringEnd, &Remaining, 0);
RtlStringCbCopyA(StringEnd, Remaining, "\\");
LoaderBlock->NtBootPathName = BldrNtBootPath;
/* Set the HAL paths */
RtlStringCbCopyA(BldrArcHalPath, sizeof(BldrArcHalPath), BldrArcBootPath);
LoaderBlock->ArcHalDeviceName = BldrArcHalPath;
strcpy(BldrNtHalPath, "\\");
LoaderBlock->NtHalPathName = BldrNtHalPath;
/* Use this new command line */
RtlStringCbCopyA(LoaderBlock->LoadOptions, 255, HalPath + 2);
/* Parse it and change every slash to a space */
BootPath = LoaderBlock->LoadOptions;
do {if (*BootPath == '/') *BootPath = ' ';} while (*BootPath++);
/* Now let's loop ARC disk information */
for (i = 0; i < RosLoaderBlock->DrivesCount; i++)
{
/* Get the ROS loader entry */
RosDiskInfo = &RosLoaderBlock->DrivesAddr[i];
/* Get the ARC structure */
ArcDiskInfo = &BldrDiskInfo[i];
/* Copy the data over */
ArcDiskInfo->Signature = RosDiskInfo->Signature;
ArcDiskInfo->CheckSum = RosDiskInfo->CheckSum;
/* Copy the ARC Name */
strcpy(BldrArcNames[i], RosDiskInfo->ArcName);
ArcDiskInfo->ArcName = BldrArcNames[i];
/* Insert into the list */
InsertTailList(&LoaderBlock->ArcDiskInformation->DiskSignatureListHead,
&ArcDiskInfo->ListEntry);
}
/* Copy the ARC Hardware Tree */
RtlCopyMemory(BldrArcHwBuffer, (PVOID)RosLoaderBlock->ArchExtra, 16 * 1024);
LoaderBlock->ConfigurationRoot = (PVOID)BldrArcHwBuffer;
/* Apply fixups */
KiRosFixupComponentTree(LoaderBlock->ConfigurationRoot,
(ULONG_PTR)BldrArcHwBuffer -
RosLoaderBlock->ArchExtra);
}
VOID
NTAPI
KiSetupSyscallHandler();
VOID
NTAPI
KiRosPrepareForSystemStartup(IN PROS_LOADER_PARAMETER_BLOCK LoaderBlock)
{
PLOADER_PARAMETER_BLOCK NtLoaderBlock;
ULONG size, i = 0, *ent;
#if defined(_X86_)
PKTSS Tss;
PKGDTENTRY TssEntry;
KDESCRIPTOR IdtDescriptor;
__sidt(&IdtDescriptor.Limit);
RtlCopyMemory(KiBootIdt, (PVOID)IdtDescriptor.Base, IdtDescriptor.Limit + 1);
IdtDescriptor.Base = (ULONG)&KiBootIdt;
IdtDescriptor.Limit = sizeof(KiBootIdt) - 1;
/* Load the GDT and IDT */
Ke386SetGlobalDescriptorTable(&KiGdtDescriptor.Limit);
__lidt(&IdtDescriptor.Limit);
/* Initialize the boot TSS */
Tss = &KiBootTss;
TssEntry = &KiBootGdt[KGDT_TSS / sizeof(KGDTENTRY)];
TssEntry->HighWord.Bits.Type = I386_TSS;
TssEntry->HighWord.Bits.Pres = 1;
TssEntry->HighWord.Bits.Dpl = 0;
TssEntry->BaseLow = (USHORT)((ULONG_PTR)Tss & 0xFFFF);
TssEntry->HighWord.Bytes.BaseMid = (UCHAR)((ULONG_PTR)Tss >> 16);
TssEntry->HighWord.Bytes.BaseHi = (UCHAR)((ULONG_PTR)Tss >> 24);
/* Set the TSS selector */
Ke386SetTr(KGDT_TSS);
#endif
#if defined(_M_PPC)
// Zero bats. We might have residual bats set that will interfere with
// our mapping of ofwldr.
for (i = 0; i < 4; i++)
{
SetBat(i, 0, 0, 0); SetBat(i, 1, 0, 0);
}
KiSetupSyscallHandler();
DbgPrint("Kernel Power (%08x)\n", LoaderBlock);
DbgPrint("ArchExtra (%08x)!\n", LoaderBlock->ArchExtra);
#endif
/* Save pointer to ROS Block */
KeRosLoaderBlock = LoaderBlock;
/* Save memory manager data */
KeMemoryMapRangeCount = 0;
if (LoaderBlock->Flags & MB_FLAGS_MMAP_INFO)
{
/* We have a memory map from the nice BIOS */
ent = ((PULONG)(LoaderBlock->MmapAddr - sizeof(ULONG)));
size = *ent;
i = 0;
/* Map it until we run out of size */
while (i < LoaderBlock->MmapLength)
{
/* Copy into the Kernel Memory Map */
memcpy (&KeMemoryMap[KeMemoryMapRangeCount],
(PVOID)(LoaderBlock->MmapAddr + i),
sizeof(ADDRESS_RANGE));
/* Increase Memory Map Count */
KeMemoryMapRangeCount++;
/* Increase Size */
i += size;
}
/* Save data */
LoaderBlock->MmapLength = KeMemoryMapRangeCount * sizeof(ADDRESS_RANGE);
LoaderBlock->MmapAddr = (ULONG)KeMemoryMap;
}
else
{
/* Nothing from BIOS */
LoaderBlock->MmapLength = 0;
LoaderBlock->MmapAddr = (ULONG)KeMemoryMap;
}
/* Convert the loader block */
KiRosFrldrLpbToNtLpb(KeRosLoaderBlock, &NtLoaderBlock);
#if defined(_M_PPC)
DbgPrint("Finished KiRosFrldrLpbToNtLpb\n");
#endif
/* Do general System Startup */
KiSystemStartup(NtLoaderBlock);
}
#endif
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