windows-nt/Source/XPSP1/NT/base/hals/halx86/i386/ixpciint.c

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/*++
Copyright (c) 1989 Microsoft Corporation
Module Name:
ixpciint.c
Abstract:
All PCI bus interrupt mapping is in this module, so that a real
system which doesn't have all the limitations which PC PCI
systems have can replaced this code easly.
(bus memory & i/o address mappings can also be fix here)
Author:
Ken Reneris
Environment:
Kernel mode
Revision History:
--*/
#include "halp.h"
#include "pci.h"
#include "pcip.h"
#ifdef WANT_IRQ_ROUTING
#include "ixpciir.h"
#endif
ULONG HalpEisaELCR;
BOOLEAN HalpDoingCrashDump;
BOOLEAN HalpPciLockSettings;
#ifdef ALLOC_PRAGMA
#pragma alloc_text(PAGE,HalpGetPCIIntOnISABus)
#pragma alloc_text(PAGE,HalpAdjustPCIResourceList)
#pragma alloc_text(PAGE,HalpGetISAFixedPCIIrq)
#endif
ULONG
HalpGetPCIIntOnISABus (
IN PBUS_HANDLER BusHandler,
IN PBUS_HANDLER RootHandler,
IN ULONG BusInterruptLevel,
IN ULONG BusInterruptVector,
OUT PKIRQL Irql,
OUT PKAFFINITY Affinity
)
{
if (BusInterruptLevel < 1) {
// bogus bus level
return 0;
}
//
// Current PCI buses just map their IRQs ontop of the ISA space,
// so foreward this to the isa handler for the isa vector
// (the isa vector was saved away at either HalSetBusData or
// IoAssignReosurces time - if someone is trying to connect a
// PCI interrupt without performing one of those operations first,
// they are broken).
//
return HalGetInterruptVector (
#ifndef MCA
Isa, 0,
#else
MicroChannel, 0,
#endif
BusInterruptLevel ^ IRQXOR,
0,
Irql,
Affinity
);
}
VOID
HalpPCIPin2ISALine (
IN PBUS_HANDLER BusHandler,
IN PBUS_HANDLER RootHandler,
IN PCI_SLOT_NUMBER SlotNumber,
IN PPCI_COMMON_CONFIG PciData
)
/*++
This function maps the device's InterruptPin to an InterruptLine
value.
On the current PC implementations, the bios has already filled in
InterruptLine as it's ISA value and there's no portable way to
change it.
On a DBG build we adjust InterruptLine just to ensure driver's
don't connect to it without translating it on the PCI bus.
--*/
{
if (!PciData->u.type0.InterruptPin) {
return ;
}
//
// On a PC there's no Slot/Pin/Line mapping which needs to
// be done.
//
PciData->u.type0.InterruptLine ^= IRQXOR;
}
VOID
HalpPCIISALine2Pin (
IN PBUS_HANDLER BusHandler,
IN PBUS_HANDLER RootHandler,
IN PCI_SLOT_NUMBER SlotNumber,
IN PPCI_COMMON_CONFIG PciNewData,
IN PPCI_COMMON_CONFIG PciOldData
)
/*++
This functions maps the device's InterruptLine to it's
device specific InterruptPin value.
On the current PC implementations, this information is
fixed by the BIOS. Just make sure the value isn't being
editted since PCI doesn't tell us how to dynically
connect the interrupt.
--*/
{
if (!PciNewData->u.type0.InterruptPin) {
return ;
}
PciNewData->u.type0.InterruptLine ^= IRQXOR;
#if DBG
if (PciNewData->u.type0.InterruptLine != PciOldData->u.type0.InterruptLine ||
PciNewData->u.type0.InterruptPin != PciOldData->u.type0.InterruptPin) {
DbgPrint ("HalpPCILine2Pin: System does not support changing the PCI device interrupt routing\n");
DbgBreakPoint ();
}
#endif
}
#if !defined(SUBCLASSPCI)
VOID
HalpPCIAcquireType2Lock (
PKSPIN_LOCK SpinLock,
PKIRQL Irql
)
{
if (!HalpDoingCrashDump) {
*Irql = KfRaiseIrql (HIGH_LEVEL);
KiAcquireSpinLock (SpinLock);
} else {
*Irql = HIGH_LEVEL;
}
}
VOID
HalpPCIReleaseType2Lock (
PKSPIN_LOCK SpinLock,
KIRQL Irql
)
{
if (!HalpDoingCrashDump) {
KiReleaseSpinLock (SpinLock);
KfLowerIrql (Irql);
}
}
#endif
NTSTATUS
HalpAdjustPCIResourceList (
IN PBUS_HANDLER BusHandler,
IN PBUS_HANDLER RootHandler,
IN OUT PIO_RESOURCE_REQUIREMENTS_LIST *pResourceList
)
/*++
Rewrite the callers requested resource list to fit within
the supported ranges of this bus
--*/
{
NTSTATUS Status;
PPCIPBUSDATA BusData;
PCI_SLOT_NUMBER PciSlot;
PSUPPORTED_RANGE Interrupt;
PSUPPORTED_RANGE Range, HoldRange;
PSUPPORTED_RANGES SupportedRanges;
PPCI_COMMON_CONFIG PciData, PciOrigData;
UCHAR buffer[PCI_COMMON_HDR_LENGTH];
UCHAR buffer2[PCI_COMMON_HDR_LENGTH];
BOOLEAN UseBusRanges;
ULONG i, j, RomIndex, length, ebit;
ULONG Base[PCI_TYPE0_ADDRESSES + 1];
PULONG BaseAddress[PCI_TYPE0_ADDRESSES + 1];
BusData = (PPCIPBUSDATA) BusHandler->BusData;
PciSlot = *((PPCI_SLOT_NUMBER) &(*pResourceList)->SlotNumber);
//
// Determine PCI device's interrupt restrictions
//
Status = BusData->GetIrqRange(BusHandler, RootHandler, PciSlot, &Interrupt);
if (!NT_SUCCESS(Status)) {
return Status;
}
SupportedRanges = NULL;
UseBusRanges = TRUE;
Status = STATUS_INSUFFICIENT_RESOURCES;
if (HalpPciLockSettings) {
PciData = (PPCI_COMMON_CONFIG) buffer;
PciOrigData = (PPCI_COMMON_CONFIG) buffer2;
HalpReadPCIConfig (BusHandler, PciSlot, PciData, 0, PCI_COMMON_HDR_LENGTH);
//
// If this is a device, and it current has its decodes enabled,
// then use the currently programmed ranges only
//
if (PCI_CONFIG_TYPE(PciData) == 0 &&
(PciData->Command & (PCI_ENABLE_IO_SPACE | PCI_ENABLE_MEMORY_SPACE))) {
//
// Save current settings
//
RtlMoveMemory (PciOrigData, PciData, PCI_COMMON_HDR_LENGTH);
for (j=0; j < PCI_TYPE0_ADDRESSES; j++) {
BaseAddress[j] = &PciData->u.type0.BaseAddresses[j];
}
BaseAddress[j] = &PciData->u.type0.ROMBaseAddress;
RomIndex = j;
//
// Write all one-bits to determine lengths for each address
//
for (j=0; j < PCI_TYPE0_ADDRESSES + 1; j++) {
Base[j] = *BaseAddress[j];
*BaseAddress[j] = 0xFFFFFFFF;
}
PciData->Command &= ~(PCI_ENABLE_IO_SPACE | PCI_ENABLE_MEMORY_SPACE);
*BaseAddress[RomIndex] &= ~PCI_ROMADDRESS_ENABLED;
HalpWritePCIConfig (BusHandler, PciSlot, PciData, 0, PCI_COMMON_HDR_LENGTH);
HalpReadPCIConfig (BusHandler, PciSlot, PciData, 0, PCI_COMMON_HDR_LENGTH);
//
// restore original settings
//
HalpWritePCIConfig (
BusHandler,
PciSlot,
&PciOrigData->Status,
FIELD_OFFSET (PCI_COMMON_CONFIG, Status),
PCI_COMMON_HDR_LENGTH - FIELD_OFFSET (PCI_COMMON_CONFIG, Status)
);
HalpWritePCIConfig (
BusHandler,
PciSlot,
PciOrigData,
0,
FIELD_OFFSET (PCI_COMMON_CONFIG, Status)
);
//
// Build a memory & io range list of just the ranges already
// programmed into the device
//
UseBusRanges = FALSE;
SupportedRanges = HalpAllocateNewRangeList();
if (!SupportedRanges) {
goto CleanUp;
}
*BaseAddress[RomIndex] &= ~PCI_ADDRESS_IO_SPACE;
for (j=0; j < PCI_TYPE0_ADDRESSES + 1; j++) {
i = *BaseAddress[j];
if (i & PCI_ADDRESS_IO_SPACE) {
length = 1 << 2;
Range = &SupportedRanges->IO;
ebit = PCI_ENABLE_IO_SPACE;
} else {
length = 1 << 4;
Range = &SupportedRanges->Memory;
ebit = PCI_ENABLE_MEMORY_SPACE;
if (i & PCI_ADDRESS_MEMORY_PREFETCHABLE) {
Range = &SupportedRanges->PrefetchMemory;
}
}
Base[j] &= ~(length-1);
while (!(i & length) && length) {
length <<= 1;
}
if (j == RomIndex &&
!(PciOrigData->u.type0.ROMBaseAddress & PCI_ROMADDRESS_ENABLED)) {
// range not enabled, don't use it
length = 0;
}
if (length) {
if (!(PciOrigData->Command & ebit)) {
// range not enabled, don't use preprogrammed values
UseBusRanges = TRUE;
}
if (Range->Limit >= Range->Base) {
HoldRange = Range->Next;
Range->Next = ExAllocatePoolWithTag(
PagedPool,
sizeof(SUPPORTED_RANGE),
HAL_POOL_TAG
);
Range = Range->Next;
if (!Range) {
goto CleanUp;
}
Range->Next = HoldRange;
}
Range->Base = Base[j];
Range->Limit = Base[j] + length - 1;
}
if (Is64BitBaseAddress(i)) {
// skip upper half of 64 bit address since this processor
// only supports 32 bits of address space
j++;
}
}
}
}
//
// Adjust resources
//
Status = HaliAdjustResourceListRange (
UseBusRanges ? BusHandler->BusAddresses : SupportedRanges,
Interrupt,
pResourceList
);
CleanUp:
if (SupportedRanges) {
HalpFreeRangeList (SupportedRanges);
}
ExFreePool (Interrupt);
return Status;
}
NTSTATUS
HalpGetISAFixedPCIIrq (
IN PBUS_HANDLER BusHandler,
IN PBUS_HANDLER RootHandler,
IN PCI_SLOT_NUMBER PciSlot,
OUT PSUPPORTED_RANGE *Interrupt
)
{
UCHAR buffer[PCI_COMMON_HDR_LENGTH];
PPCI_COMMON_CONFIG PciData;
PciData = (PPCI_COMMON_CONFIG) buffer;
HalGetBusData (
PCIConfiguration,
BusHandler->BusNumber,
PciSlot.u.AsULONG,
PciData,
PCI_COMMON_HDR_LENGTH
);
if (PciData->VendorID == PCI_INVALID_VENDORID) {
return STATUS_UNSUCCESSFUL;
}
*Interrupt = ExAllocatePoolWithTag(PagedPool,
sizeof(SUPPORTED_RANGE),
HAL_POOL_TAG);
if (!*Interrupt) {
return STATUS_INSUFFICIENT_RESOURCES;
}
RtlZeroMemory (*Interrupt, sizeof (SUPPORTED_RANGE));
(*Interrupt)->Base = 1; // base = 1, limit = 0
if (!PciData->u.type0.InterruptPin) {
return STATUS_SUCCESS;
}
#ifdef WANT_IRQ_ROUTING
//
// Let the arbiter decide which Irq this device gets.
//
if (IsPciIrqRoutingEnabled()) {
//
// If a video card has been enabled by the BIOS
// and the BIOS did not assign any interrupt to it
// then assume this device does not need an interrupt.
//
if (PciData->Command & (PCI_ENABLE_IO_SPACE | PCI_ENABLE_MEMORY_SPACE)) {
if ( (PciData->BaseClass == PCI_CLASS_PRE_20 && PciData->SubClass == PCI_SUBCLASS_VID_XGA_CTLR) ||
(PciData->BaseClass == PCI_CLASS_DISPLAY_CTLR &&
(PciData->SubClass == PCI_SUBCLASS_VID_VGA_CTLR || PciData->SubClass == PCI_SUBCLASS_VID_XGA_CTLR))) {
if ( PciData->u.type0.InterruptLine == (0 ^ IRQXOR) ||
PciData->u.type0.InterruptLine == (0xFF ^ IRQXOR)) {
#if DBG
DbgPrint ("HalpGetValidPCIFixedIrq: BIOS did not assign an interrupt to the video device %04X%04X\n", PciData->VendorID, PciData->DeviceID);
#endif
//
// We need to let the caller continue, since the caller may
// not care that the interrupt vector is connected or not
//
return STATUS_SUCCESS;
}
}
}
//
// Return all possible interrupts since Pci Irq Routing is enabled.
//
(*Interrupt)->Base = 0;
(*Interrupt)->Limit = 0xFF;
return STATUS_SUCCESS;
}
#endif
if (PciData->u.type0.InterruptLine == (0 ^ IRQXOR) ||
PciData->u.type0.InterruptLine == (0xFF ^ IRQXOR)) {
#if DBG
DbgPrint ("HalpGetValidPCIFixedIrq: BIOS did not assign an interrupt vector for the device\n");
#endif
//
// We need to let the caller continue, since the caller may
// not care that the interrupt vector is connected or not
//
return STATUS_SUCCESS;
}
(*Interrupt)->Base = PciData->u.type0.InterruptLine;
(*Interrupt)->Limit = PciData->u.type0.InterruptLine;
return STATUS_SUCCESS;
}