reactos/ntoskrnl/ke/powerpc/kiinit.c

357 lines
9.6 KiB
C

/*
* PROJECT: ReactOS Kernel
* LICENSE: GPL - See COPYING in the top level directory
* FILE: ntoskrnl/ke/powerpc/kiinit.c
* PURPOSE: Kernel Initialization for x86 CPUs
* PROGRAMMERS: Alex Ionescu (alex.ionescu@reactos.org)
* Art Yerkes (ayerkes@speakeasy.net)
*/
/* INCLUDES *****************************************************************/
#include <ntoskrnl.h>
//#define NDEBUG
#include <debug.h>
#include "ppcmmu/mmu.h"
/* GLOBALS *******************************************************************/
/* Ku bit should be set, so that we get the best options for page protection */
#define PPC_SEG_Ku 0x40000000
#define PPC_SEG_Ks 0x20000000
extern LOADER_MODULE KeLoaderModules[64];
extern ULONG KeLoaderModuleCount;
extern ULONG_PTR MmFreeLdrLastKernelAddress;
KPRCB PrcbData[MAXIMUM_PROCESSORS];
/* BIOS Memory Map. Not NTLDR-compliant yet */
extern ULONG KeMemoryMapRangeCount;
extern ADDRESS_RANGE KeMemoryMap[64];
/* FUNCTIONS *****************************************************************/
/*
* Trap frame:
* r0 .. r32
* lr, ctr, srr0, srr1, dsisr
*/
extern int syscall_start[], syscall_end, KiDecrementerTrapHandler[],
KiDecrementerTrapHandlerEnd;
VOID
NTAPI
KiSetupSyscallHandler(VOID)
{
paddr_t handler_target;
int *source;
for(source = syscall_start, handler_target = 0xc00;
source < &syscall_end;
source++, handler_target += sizeof(int))
{
SetPhys(handler_target, *source);
}
}
VOID
NTAPI
KiSetupDecrementerTrap(VOID)
{
paddr_t handler_target;
int *source;
/* Turn off EE bit while redefining dec trap */
_disable();
for(source = KiDecrementerTrapHandler, handler_target = 0x900;
source != &KiDecrementerTrapHandlerEnd;
source++, handler_target += sizeof(int))
SetPhys(handler_target, *source);
DPRINT("CurrentThread %08x IdleThread %08x\n",
KeGetCurrentThread(), KeGetCurrentPrcb()->IdleThread);
/* Kick decmrenter! */
__asm__("mtdec %0" : : "r" (0));
/* Enable interrupts! */
_enable();
}
VOID
NTAPI
KiInitializePcr(IN ULONG ProcessorNumber,
IN PKIPCR Pcr,
IN PKTHREAD IdleThread,
IN PVOID DpcStack)
{
Pcr->MajorVersion = PCR_MAJOR_VERSION;
Pcr->MinorVersion = PCR_MINOR_VERSION;
Pcr->CurrentIrql = PASSIVE_LEVEL;
Pcr->PrcbData = &PrcbData[ProcessorNumber];
Pcr->PrcbData->MajorVersion = PRCB_MAJOR_VERSION;
Pcr->PrcbData->MinorVersion = 0;
Pcr->PrcbData->Number = 0; /* UP for now */
Pcr->PrcbData->SetMember = 1;
#if DBG
Pcr->PrcbData->BuildType = PRCB_BUILD_DEBUG;
#else
Pcr->PrcbData->BuildType = 0;
#endif
Pcr->PrcbData->DpcStack = DpcStack;
KeGetPcr()->Prcb = Pcr->PrcbData;
KiProcessorBlock[ProcessorNumber] = Pcr->PrcbData;
}
extern ULONG KiGetFeatureBits();
extern VOID KiSetProcessorType();
extern VOID KiGetCacheInformation();
VOID
NTAPI
KiInitializeKernel(IN PKPROCESS InitProcess,
IN PKTHREAD InitThread,
IN PVOID IdleStack,
IN PKPRCB Prcb,
IN CCHAR Number,
IN PLOADER_PARAMETER_BLOCK LoaderBlock)
{
ULONG FeatureBits;
LARGE_INTEGER PageDirectory;
PVOID DpcStack;
/* Detect and set the CPU Type */
KiSetProcessorType();
/* Initialize the Power Management Support for this PRCB */
PoInitializePrcb(Prcb);
/* Get the processor features for the CPU */
FeatureBits = KiGetFeatureBits();
/* Save feature bits */
Prcb->FeatureBits = FeatureBits;
/* Get cache line information for this CPU */
KiGetCacheInformation();
/* Initialize spinlocks and DPC data */
KiInitSpinLocks(Prcb, Number);
/* Check if this is the Boot CPU */
if (!Number)
{
/* Set Node Data */
KeNodeBlock[0] = &KiNode0;
Prcb->ParentNode = KeNodeBlock[0];
KeNodeBlock[0]->ProcessorMask = Prcb->SetMember;
/* Set boot-level flags */
KeProcessorArchitecture = 0;
KeProcessorLevel = (USHORT)Prcb->CpuType;
KeFeatureBits = FeatureBits;
/* Set the current MP Master KPRCB to the Boot PRCB */
Prcb->MultiThreadSetMaster = Prcb;
/* Lower to APC_LEVEL */
KeLowerIrql(APC_LEVEL);
/* Initialize portable parts of the OS */
KiInitSystem();
/* Initialize the Idle Process and the Process Listhead */
InitializeListHead(&KiProcessListHead);
PageDirectory.QuadPart = 0;
KeInitializeProcess(InitProcess,
0,
0xFFFFFFFF,
&PageDirectory,
TRUE);
InitProcess->QuantumReset = MAXCHAR;
}
else
{
/* FIXME */
DPRINT1("SMP Boot support not yet present\n");
}
/* Setup the Idle Thread */
KeInitializeThread(InitProcess,
InitThread,
NULL,
NULL,
NULL,
NULL,
NULL,
IdleStack);
InitThread->NextProcessor = Number;
InitThread->Priority = HIGH_PRIORITY;
InitThread->State = Running;
InitThread->Affinity = 1 << Number;
InitThread->WaitIrql = DISPATCH_LEVEL;
InitProcess->ActiveProcessors = 1 << Number;
/* HACK for MmUpdatePageDir */
((PETHREAD)InitThread)->ThreadsProcess = (PEPROCESS)InitProcess;
/* Set up the thread-related fields in the PRCB */
Prcb->CurrentThread = InitThread;
Prcb->NextThread = NULL;
Prcb->IdleThread = InitThread;
/* Initialize Kernel Memory Address Space */
MmInit1(MmFreeLdrFirstKrnlPhysAddr,
MmFreeLdrLastKrnlPhysAddr,
MmFreeLdrLastKernelAddress,
KeMemoryMap,
KeMemoryMapRangeCount,
4096);
/* Initialize the Kernel Executive */
ExpInitializeExecutive(0, LoaderBlock);
/* Only do this on the boot CPU */
if (!Number)
{
/* Calculate the time reciprocal */
KiTimeIncrementReciprocal =
KiComputeReciprocal(KeMaximumIncrement,
&KiTimeIncrementShiftCount);
/* Update DPC Values in case they got updated by the executive */
Prcb->MaximumDpcQueueDepth = KiMaximumDpcQueueDepth;
Prcb->MinimumDpcRate = KiMinimumDpcRate;
Prcb->AdjustDpcThreshold = KiAdjustDpcThreshold;
/* Allocate the DPC Stack */
DpcStack = MmCreateKernelStack(FALSE, 0);
if (!DpcStack) KeBugCheckEx(NO_PAGES_AVAILABLE, 1, 0, 0, 0);
Prcb->DpcStack = DpcStack;
}
KfRaiseIrql(DISPATCH_LEVEL);
KeSetPriorityThread(InitThread, 0);
/* Setup decrementer exception */
KiSetupDecrementerTrap();
KfLowerIrql(PASSIVE_LEVEL);
/* Should not return */
while(1)
{
NtYieldExecution();
}
}
extern int KiPageFaultTrap();
KTRAP_FRAME KiInitialTrapFrame;
/* Use this for early boot additions to the page table */
VOID
NTAPI
KiSystemStartupReal(IN PLOADER_PARAMETER_BLOCK LoaderBlock)
{
ULONG Cpu;
ppc_map_info_t info[4];
PKIPCR Pcr = (PKIPCR)KPCR_BASE;
PKPRCB Prcb;
__asm__("mr 13,%0" : : "r" (KPCR_BASE));
/* Set the page fault handler to the kernel */
MmuSetTrapHandler(3,KiPageFaultTrap);
MmuSetTrapHandler(4,KiPageFaultTrap);
// Make 0xf... special
MmuAllocVsid(2, 0x8000);
MmuSetVsid(15,16,2);
/* Get the current CPU */
Cpu = KeNumberProcessors;
if (!Cpu)
{
/* We'll allocate a page from the end of the kernel area for KPCR. This code will probably
* change when we get SMP support.
*/
info[0].phys = 0;
info[0].proc = 2;
info[0].addr = (vaddr_t)Pcr;
info[0].flags = MMU_KRW_UR;
info[1].phys = 0;
info[1].proc = 2;
info[1].addr = ((vaddr_t)Pcr) + (1 << PAGE_SHIFT);
info[1].flags = MMU_KRW_UR;
info[2].phys = 0;
info[2].proc = 2;
info[2].addr = (vaddr_t)KI_USER_SHARED_DATA;
info[2].flags = MMU_KRW_UR;
info[3].phys = 0;
info[3].proc = 2;
info[3].addr = (vaddr_t)KIP0PCRADDRESS;
info[3].flags = MMU_KRW_UR;
MmuMapPage(info, 4);
}
/* Skip initial setup if this isn't the Boot CPU */
if (Cpu) goto AppCpuInit;
/* Initialize the PCR */
RtlZeroMemory(Pcr, PAGE_SIZE);
KiInitializePcr(Cpu,
Pcr,
&KiInitialThread.Tcb,
KiDoubleFaultStack);
/* Set us as the current process */
KiInitialThread.Tcb.ApcState.Process = &KiInitialProcess.Pcb;
KiInitialThread.Tcb.TrapFrame = &KiInitialTrapFrame;
/* Setup CPU-related fields */
AppCpuInit:
Pcr->Number = Cpu;
Pcr->SetMember = 1 << Cpu;
Prcb = KeGetCurrentPrcb();
Prcb->SetMember = 1 << Cpu;
/* Initialize the Processor with HAL */
HalInitializeProcessor(Cpu, LoaderBlock);
/* Set active processors */
KeActiveProcessors |= Pcr->SetMember;
KeNumberProcessors++;
/* Initialize the Debugger for the Boot CPU */
if (!Cpu) KdInitSystem (0, LoaderBlock);
/* Check for break-in */
if (KdPollBreakIn())
{
DbgBreakPointWithStatus(DBG_STATUS_CONTROL_C);
}
/* Raise to HIGH_LEVEL */
KfRaiseIrql(HIGH_LEVEL);
/* Call main kernel intialization */
KiInitializeKernel(&KiInitialProcess.Pcb,
&KiInitialThread.Tcb,
P0BootStack,
Prcb,
Cpu,
(PVOID)LoaderBlock);
}
VOID
NTAPI
KiInitMachineDependent(VOID)
{
}
void abort(VOID)
{
KeBugCheck(KMODE_EXCEPTION_NOT_HANDLED);
while(1);
}