Leaked source code of windows server 2003
You can not select more than 25 topics Topics must start with a letter or number, can include dashes ('-') and can be up to 35 characters long.
 
 
 
 
 
 

812 lines
21 KiB

/*++
Copyright (c) 1989 Microsoft Corporation
Module Name:
ixsysbus.c
Abstract:
Author:
Environment:
Revision History:
--*/
#include "halp.h"
#ifdef WANT_IRQ_ROUTING
#include "ixpciir.h"
#endif
KAFFINITY HalpDefaultInterruptAffinity;
#ifdef ALLOC_PRAGMA
#pragma alloc_text(PAGE,HalpGetSystemInterruptVector)
#pragma alloc_text(PAGE,HalTranslatorReference)
#pragma alloc_text(PAGE,HalTranslatorDereference)
#pragma alloc_text(PAGE,HalIrqTranslateResourcesRoot)
#pragma alloc_text(PAGE,HalIrqTranslateResourceRequirementsRoot)
#pragma alloc_text(PAGE,HalpTransMemIoResource)
#pragma alloc_text(PAGE,HalpTransMemIoResourceRequirement)
#pragma alloc_text(PAGE,HaliGetInterruptTranslator)
#endif
BOOLEAN
HalpFindBusAddressTranslation(
IN PHYSICAL_ADDRESS BusAddress,
IN OUT PULONG AddressSpace,
OUT PPHYSICAL_ADDRESS TranslatedAddress,
IN OUT PULONG_PTR Context,
IN BOOLEAN NextBus
)
/*++
Routine Description:
This routine performs a very similar function to HalTranslateBusAddress
except that InterfaceType and BusNumber are not known by the caller.
This function will walk all busses known by the HAL looking for a
valid translation for the input BusAddress of type AddressSpace.
This function is recallable using the input/output Context parameter.
On the first call to this routine for a given translation the ULONG_PTR
Context should be NULL. Note: Not the address of it but the contents.
If the caller decides the returned translation is not the desired
translation, it calls this routine again passing Context in as it
was returned on the previous call. This allows this routine to
traverse the bus structures until the correct translation is found
and is provided because on multiple bus systems, it is possible for
the same resource to exist in the independent address spaces of
multiple busses.
Arguments:
BusAddress Address to be translated.
AddressSpace 0 = Memory
1 = IO (There are other possibilities).
N.B. This argument is a pointer, the value
will be modified if the translated address
is of a different address space type from
the untranslated bus address.
TranslatedAddress Pointer to where the translated address
should be stored.
Context Pointer to a ULONG_PTR. On the initial call,
for a given BusAddress, it should contain
0. It will be modified by this routine,
on subsequent calls for the same BusAddress
the value should be handed in again,
unmodified by the caller.
NextBus FALSE if we should attempt this translation
on the same bus as indicated by Context,
TRUE if we should be looking for another
bus.
Return Value:
TRUE if translation was successful,
FALSE otherwise.
--*/
{
//
// First, make sure the context parameter was supplied and is
// being used correctly. This also ensures that the caller
// doesn't get stuck in a loop looking for subsequent translations
// for the same thing. We won't succeed the same translation twice
// unless the caller reinits the context.
//
if ((!Context) || (*Context && (NextBus == TRUE))) {
return FALSE;
}
*Context = 1;
//
// PC/AT (halx86) case is simplest, there is no translation.
//
*TranslatedAddress = BusAddress;
return TRUE;
}
BOOLEAN
HalpTranslateSystemBusAddress(
IN PBUS_HANDLER BusHandler,
IN PBUS_HANDLER RootHandler,
IN PHYSICAL_ADDRESS BusAddress,
IN OUT PULONG AddressSpace,
OUT PPHYSICAL_ADDRESS TranslatedAddress
)
/*++
Routine Description:
This function translates a bus-relative address space and address into
a system physical address.
Arguments:
BusAddress - Supplies the bus-relative address
AddressSpace - Supplies the address space number.
Returns the host address space number.
AddressSpace == 0 => memory space
AddressSpace == 1 => I/O space
TranslatedAddress - Supplies a pointer to return the translated address
Return Value:
A return value of TRUE indicates that a system physical address
corresponding to the supplied bus relative address and bus address
number has been returned in TranslatedAddress.
A return value of FALSE occurs if the translation for the address was
not possible
--*/
{
PSUPPORTED_RANGE pRange;
pRange = NULL;
//
// If this fails, it means someone has given us a RESOURCE_TYPE with some decode type flags
// set. We should probably handle this.
//
ASSERT (*AddressSpace == 0 ||
*AddressSpace == 1);
//
// The checking of bus ranges for PCI busses is performed by the PCI driver
// in NT5 (or Windows 2000 or whatever its called) so only check for none
// PCI busses.
//
switch (*AddressSpace) {
case 0:
if (BusHandler->InterfaceType != PCIBus) {
// verify memory address is within buses memory limits
for (pRange = &BusHandler->BusAddresses->PrefetchMemory; pRange; pRange = pRange->Next) {
if (BusAddress.QuadPart >= pRange->Base &&
BusAddress.QuadPart <= pRange->Limit) {
break;
}
}
if (!pRange) {
for (pRange = &BusHandler->BusAddresses->Memory; pRange; pRange = pRange->Next) {
if (BusAddress.QuadPart >= pRange->Base &&
BusAddress.QuadPart <= pRange->Limit) {
break;
}
}
}
} else {
//
// This is a PCI bus and SystemBase is constant for all ranges
//
pRange = &BusHandler->BusAddresses->Memory;
}
break;
case 1:
if (BusHandler->InterfaceType != PCIBus) {
// verify IO address is within buses IO limits
for (pRange = &BusHandler->BusAddresses->IO; pRange; pRange = pRange->Next) {
if (BusAddress.QuadPart >= pRange->Base &&
BusAddress.QuadPart <= pRange->Limit) {
break;
}
}
break;
} else {
//
// This is a PCI bus and SystemBase is constant for all ranges
//
pRange = &BusHandler->BusAddresses->IO;
}
}
if (pRange) {
TranslatedAddress->QuadPart = BusAddress.QuadPart + pRange->SystemBase;
*AddressSpace = pRange->SystemAddressSpace;
return TRUE;
}
return FALSE;
}
ULONG
HalpGetRootInterruptVector(
IN ULONG InterruptLevel,
IN ULONG InterruptVector,
OUT PKIRQL Irql,
OUT PKAFFINITY Affinity
)
{
ULONG SystemVector;
UNREFERENCED_PARAMETER( InterruptLevel );
SystemVector = InterruptLevel + PRIMARY_VECTOR_BASE;
if ((SystemVector < PRIMARY_VECTOR_BASE) ||
(SystemVector > PRIMARY_VECTOR_BASE + HIGHEST_LEVEL_FOR_8259) ) {
//
// This is an illegal BusInterruptVector and cannot be connected.
//
return(0);
}
*Irql = (KIRQL)(HIGHEST_LEVEL_FOR_8259 + PRIMARY_VECTOR_BASE - SystemVector);
*Affinity = HalpDefaultInterruptAffinity;
ASSERT(HalpDefaultInterruptAffinity);
return SystemVector;
}
ULONG
HalpGetSystemInterruptVector(
IN PBUS_HANDLER BusHandler,
IN PBUS_HANDLER RootHandler,
IN ULONG BusInterruptLevel,
IN ULONG BusInterruptVector,
OUT PKIRQL Irql,
OUT PKAFFINITY Affinity
)
/*++
Routine Description:
Arguments:
BusInterruptLevel - Supplies the bus specific interrupt level.
BusInterruptVector - Supplies the bus specific interrupt vector.
Irql - Returns the system request priority.
Affinity - Returns the system wide irq affinity.
Return Value:
Returns the system interrupt vector corresponding to the specified device.
--*/
{
ULONG SystemVector;
UNREFERENCED_PARAMETER( BusHandler );
UNREFERENCED_PARAMETER( RootHandler );
SystemVector = HalpGetRootInterruptVector(BusInterruptLevel,
BusInterruptVector,
Irql,
Affinity);
if (HalpIDTUsageFlags[SystemVector].Flags & IDTOwned ) {
//
// This is an illegal BusInterruptVector and cannot be connected.
//
return(0);
}
return SystemVector;
}
//
// This section implements a "translator," which is the PnP-WDM way
// of doing the same thing that the first part of this file does.
//
VOID
HalTranslatorReference(
PVOID Context
)
{
return;
}
VOID
HalTranslatorDereference(
PVOID Context
)
{
return;
}
NTSTATUS
HalIrqTranslateResourcesRoot(
IN PVOID Context,
IN PCM_PARTIAL_RESOURCE_DESCRIPTOR Source,
IN RESOURCE_TRANSLATION_DIRECTION Direction,
IN ULONG AlternativesCount, OPTIONAL
IN IO_RESOURCE_DESCRIPTOR Alternatives[], OPTIONAL
IN PDEVICE_OBJECT PhysicalDeviceObject,
OUT PCM_PARTIAL_RESOURCE_DESCRIPTOR Target
)
/*++
Routine Description:
This function takes a CM_PARTIAL_RESOURCE_DESCRIPTOR and translates
it to an IO-bus-relative from a Processor-bus-relative form, or the other
way around. In this x86-specific example, an IO-bus-relative form is the
ISA IRQ and the Processor-bus-relative form is the IDT entry and the
associated IRQL.
N.B. This funtion has an associated "Direction." These are not exactly
reciprocals. This has to be the case because the output from
HalIrqTranslateResourceRequirementsRoot will be used as the input
for the ParentToChild case.
ChildToParent:
Level (ISA IRQ) -> IRQL
Vector (ISA IRQ) -> x86 IDT entry
Affinity (not refereced)-> KAFFINITY
ParentToChild:
Level (not referenced) -> (ISA IRQ)
Vector (IDT entry) -> (ISA IRQ)
Affinity -> 0xffffffff
Arguments:
Context - unused
Source - descriptor that we are translating
Direction - direction of translation (parent to child or child to parent)
AlternativesCount - unused
Alternatives - unused
PhysicalDeviceObject- unused
Target - translated descriptor
Return Value:
status
--*/
{
NTSTATUS status = STATUS_UNSUCCESSFUL;
KAFFINITY affinity;
KIRQL irql;
ULONG vector;
UNREFERENCED_PARAMETER(AlternativesCount);
UNREFERENCED_PARAMETER(Alternatives);
UNREFERENCED_PARAMETER(PhysicalDeviceObject);
PAGED_CODE();
ASSERT(Source->Type == CmResourceTypeInterrupt);
//
// Copy everything
//
*Target = *Source;
switch (Direction) {
case TranslateChildToParent:
//
// Translate the IRQ
//
vector = HalpGetRootInterruptVector(Source->u.Interrupt.Level,
Source->u.Interrupt.Vector,
&irql,
&affinity);
if (vector != 0) {
Target->u.Interrupt.Level = irql;
Target->u.Interrupt.Vector = vector;
Target->u.Interrupt.Affinity = affinity;
status = STATUS_TRANSLATION_COMPLETE;
}
break;
case TranslateParentToChild:
//
// There is no inverse to HalpGetSystemInterruptVector, so we
// just do what that function would do.
//
Target->u.Interrupt.Level = Target->u.Interrupt.Vector =
Source->u.Interrupt.Vector - PRIMARY_VECTOR_BASE;
Target->u.Interrupt.Affinity = 0xFFFFFFFF;
status = STATUS_SUCCESS;
break;
default:
status = STATUS_INVALID_PARAMETER;
}
return status;
}
NTSTATUS
HalIrqTranslateResourceRequirementsRoot(
IN PVOID Context,
IN PIO_RESOURCE_DESCRIPTOR Source,
IN PDEVICE_OBJECT PhysicalDeviceObject,
OUT PULONG TargetCount,
OUT PIO_RESOURCE_DESCRIPTOR *Target
)
/*++
Routine Description:
This function takes an IO_RESOURCE_DESCRIPTOR and translates
it from an IO-bus-relative to a Processor-bus-relative form. In this
x86-specific example, an IO-bus-relative form is the ISA IRQ and the
Processor-bus-relative form is the IDT entry and the associated IRQL.
This is essentially a PnP form of HalGetInterruptVector.
Arguments:
Context - unused
Source - descriptor that we are translating
PhysicalDeviceObject- unused
TargetCount - 1
Target - translated descriptor
Return Value:
status
--*/
{
KAFFINITY affinity;
KIRQL irql;
ULONG vector;
PAGED_CODE();
ASSERT(Source->Type == CmResourceTypeInterrupt);
//
// The interrupt requirements were obtained by calling HalAdjustResourceList
// so we don't need to call it again.
//
*Target = ExAllocatePoolWithTag(PagedPool,
sizeof(IO_RESOURCE_DESCRIPTOR),
HAL_POOL_TAG
);
if (!*Target) {
return STATUS_INSUFFICIENT_RESOURCES;
}
*TargetCount = 1;
//
// Copy the requirement unchanged
//
**Target = *Source;
//
// Perform the translation of the minimum & maximum
//
vector = HalpGetRootInterruptVector(Source->u.Interrupt.MinimumVector,
Source->u.Interrupt.MinimumVector,
&irql,
&affinity);
(*Target)->u.Interrupt.MinimumVector = vector;
vector = HalpGetRootInterruptVector(Source->u.Interrupt.MaximumVector,
Source->u.Interrupt.MaximumVector,
&irql,
&affinity);
(*Target)->u.Interrupt.MaximumVector = vector;
return STATUS_TRANSLATION_COMPLETE;
}
NTSTATUS
HalpTransMemIoResourceRequirement(
IN PVOID Context,
IN PIO_RESOURCE_DESCRIPTOR Source,
IN PDEVICE_OBJECT PhysicalDeviceObject,
OUT PULONG TargetCount,
OUT PIO_RESOURCE_DESCRIPTOR *Target
)
/*++
Routine Description:
This routine translates memory and IO resource requirements.
Parameters:
Context - The context from the TRANSLATOR_INTERFACE
Source - The interrupt requirement to translate
PhysicalDeviceObject - The device requesting the resource
TargetCount - Pointer to where to return the number of descriptors this
requirement translates into
Target - Pointer to where a pointer to a callee allocated buffer containing
the translated descriptors should be placed.
Return Value:
STATUS_SUCCESS or an error status
Note:
We do not perform any translation.
--*/
{
ASSERT(Source);
ASSERT(Target);
ASSERT(TargetCount);
ASSERT(Source->Type == CmResourceTypeMemory ||
Source->Type == CmResourceTypePort);
//
// Allocate space for the target
//
*Target = ExAllocatePoolWithTag(PagedPool,
sizeof(IO_RESOURCE_DESCRIPTOR),
HAL_POOL_TAG
);
if (!*Target) {
return STATUS_INSUFFICIENT_RESOURCES;
}
//
// Copy the source to target and update the fields that have changed
//
**Target = *Source;
*TargetCount = 1;
return STATUS_SUCCESS;
}
NTSTATUS
HalpTransMemIoResource(
IN PVOID Context,
IN PCM_PARTIAL_RESOURCE_DESCRIPTOR Source,
IN RESOURCE_TRANSLATION_DIRECTION Direction,
IN ULONG AlternativesCount, OPTIONAL
IN IO_RESOURCE_DESCRIPTOR Alternatives[], OPTIONAL
IN PDEVICE_OBJECT PhysicalDeviceObject,
OUT PCM_PARTIAL_RESOURCE_DESCRIPTOR Target
)
/*++
Routine Description:
This routine translates memory and IO resources. On generic x86
machines, such as those that use this HAL, there isn't actually
any translation.
Parameters:
Context - The context from the TRANSLATOR_INTERFACE
Source - The interrupt resource to translate
Direction - The direction in relation to the Pnp device tree translation
should occur in.
AlternativesCount - The number of alternatives this resource was selected
from.
Alternatives - Array of alternatives this resource was selected from.
PhysicalDeviceObject - The device requesting the resource
Target - Pointer to a caller allocated buffer to hold the translted resource
descriptor.
Return Value:
STATUS_SUCCESS or an error status
--*/
{
NTSTATUS status;
//
// Copy the target to the source
//
*Target = *Source;
switch (Direction) {
case TranslateChildToParent:
//
// Make sure PnP knows it doesn't have to walk up the tree
// translating at each point.
//
status = STATUS_TRANSLATION_COMPLETE;
break;
case TranslateParentToChild:
//
// We do not translate requirements so do nothing...
//
status = STATUS_SUCCESS;
break;
default:
status = STATUS_INVALID_PARAMETER;
}
return status;
}
NTSTATUS
HaliGetInterruptTranslator(
IN INTERFACE_TYPE ParentInterfaceType,
IN ULONG ParentBusNumber,
IN INTERFACE_TYPE BridgeInterfaceType,
IN USHORT Size,
IN USHORT Version,
OUT PTRANSLATOR_INTERFACE Translator,
OUT PULONG BridgeBusNumber
)
/*++
Routine Description:
Arguments:
ParentInterfaceType - The type of the bus the bridge lives on (normally PCI).
ParentBusNumber - The number of the bus the bridge lives on.
ParentSlotNumber - The slot number the bridge lives in (where valid).
BridgeInterfaceType - The bus type the bridge provides (ie ISA for a PCI-ISA bridge).
ResourceType - The resource type we want to translate.
Size - The size of the translator buffer.
Version - The version of the translator interface requested.
Translator - Pointer to the buffer where the translator should be returned
BridgeBusNumber - Pointer to where the bus number of the bridge bus should be returned
Return Value:
Returns the status of this operation.
--*/
{
PAGED_CODE();
UNREFERENCED_PARAMETER(ParentInterfaceType);
UNREFERENCED_PARAMETER(ParentBusNumber);
ASSERT(Version == HAL_IRQ_TRANSLATOR_VERSION);
ASSERT(Size >= sizeof(TRANSLATOR_INTERFACE));
#ifdef WANT_IRQ_ROUTING
//
// Dont provide Irq translator iff Pci Irq Routing
// is enabled.
//
if (IsPciIrqRoutingEnabled()) {
HalPrint(("Not providing Isa Irq Translator since Pci Irq routing is enabled!\n"));
return STATUS_NOT_SUPPORTED;
}
#endif
//
// Fill in the common bits.
//
RtlZeroMemory(Translator, sizeof (TRANSLATOR_INTERFACE));
Translator->Size = sizeof(TRANSLATOR_INTERFACE);
Translator->Version = HAL_IRQ_TRANSLATOR_VERSION;
Translator->Context = (PVOID)BridgeInterfaceType;
Translator->InterfaceReference = HalTranslatorReference;
Translator->InterfaceDereference = HalTranslatorDereference;
switch (BridgeInterfaceType) {
case Eisa:
case Isa:
case InterfaceTypeUndefined: // special "IDE" cookie
//
// Set IRQ translator for (E)ISA interrupts.
//
Translator->TranslateResources = HalIrqTranslateResourcesIsa;
Translator->TranslateResourceRequirements =
HalIrqTranslateResourceRequirementsIsa;
return STATUS_SUCCESS;
case MicroChannel:
case PCIBus:
//
// Set IRQ translator for the MCA interrupts.
//
Translator->TranslateResources = HalIrqTranslateResourcesRoot;
Translator->TranslateResourceRequirements =
HalIrqTranslateResourceRequirementsRoot;
return STATUS_SUCCESS;
}
//
// If we got here, we don't have an interface.
//
return STATUS_NOT_SUPPORTED;
}