reactos/drivers/wdm/audio/hdaudbus/fdo.cpp

690 lines
27 KiB
C++

/*
* COPYRIGHT: See COPYING in the top level directory
* PROJECT: ReactOS Kernel Streaming
* FILE: drivers/wdm/audio/hdaudbus/fdo.cpp
* PURPOSE: HDA Driver Entry
* PROGRAMMER: Johannes Anderwald
*/
#include "hdaudbus.h"
BOOLEAN
NTAPI
HDA_InterruptService(
IN PKINTERRUPT Interrupt,
IN PVOID ServiceContext)
{
PHDA_FDO_DEVICE_EXTENSION DeviceExtension;
ULONG InterruptStatus, Response, ResponseFlags, Cad;
UCHAR RirbStatus, CorbStatus;
USHORT WritePos;
PHDA_CODEC_ENTRY Codec;
/* get device extension */
DeviceExtension = (PHDA_FDO_DEVICE_EXTENSION)ServiceContext;
ASSERT(DeviceExtension->IsFDO == TRUE);
// Check if this interrupt is ours
InterruptStatus = READ_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_INTR_STATUS));
DPRINT1("HDA_InterruptService %lx\n", InterruptStatus);
if ((InterruptStatus & INTR_STATUS_GLOBAL) == 0)
return FALSE;
// Controller or stream related?
if (InterruptStatus & INTR_STATUS_CONTROLLER) {
RirbStatus = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_STATUS);
CorbStatus = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_STATUS);
// Check for incoming responses
if (RirbStatus) {
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_STATUS, RirbStatus);
if (DeviceExtension->RirbLength == 0)
{
/* HACK: spurious interrupt */
return FALSE;
}
if ((RirbStatus & RIRB_STATUS_RESPONSE) != 0) {
WritePos = (READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_RIRB_WRITE_POS)) + 1) % DeviceExtension->RirbLength;
for (; DeviceExtension->RirbReadPos != WritePos; DeviceExtension->RirbReadPos = (DeviceExtension->RirbReadPos + 1) % DeviceExtension->RirbLength)
{
Response = DeviceExtension->RirbBase[DeviceExtension->RirbReadPos].response;
ResponseFlags = DeviceExtension->RirbBase[DeviceExtension->RirbReadPos].flags;
Cad = ResponseFlags & RESPONSE_FLAGS_CODEC_MASK;
DPRINT1("Response %lx ResponseFlags %lx Cad %lx\n", Response, ResponseFlags, Cad);
/* get codec */
Codec = DeviceExtension->Codecs[Cad];
if (Codec == NULL)
{
DPRINT1("hda: response for unknown codec %x Response %x ResponseFlags %x\n", Cad, Response, ResponseFlags);
continue;
}
/* check response count */
if (Codec->ResponseCount >= MAX_CODEC_RESPONSES)
{
DPRINT1("too many responses for codec %x Response %x ResponseFlags %x\n", Cad, Response, ResponseFlags);
continue;
}
// FIXME handle unsolicited responses
ASSERT((ResponseFlags & RESPONSE_FLAGS_UNSOLICITED) == 0);
/* store response */
Codec->Responses[Codec->ResponseCount] = Response;
Codec->ResponseCount++;
}
}
if ((RirbStatus & RIRB_STATUS_OVERRUN) != 0)
DPRINT1("hda: RIRB Overflow\n");
}
// Check for sending errors
if (CorbStatus) {
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_STATUS, CorbStatus);
if ((CorbStatus & CORB_STATUS_MEMORY_ERROR) != 0)
DPRINT1("hda: CORB Memory Error!\n");
}
}
#if 0
if ((intrStatus & INTR_STATUS_STREAM_MASK) != 0) {
for (uint32 index = 0; index < HDA_MAX_STREAMS; index++) {
if ((intrStatus & (1 << index)) != 0) {
if (controller->streams[index]) {
if (stream_handle_interrupt(controller,
controller->streams[index], index)) {
handled = B_INVOKE_SCHEDULER;
}
}
else {
dprintf("hda: Stream interrupt for unconfigured stream "
"%ld!\n", index);
}
}
}
}
#endif
return TRUE;
}
VOID
HDA_SendVerbs(
IN PDEVICE_OBJECT DeviceObject,
IN PHDA_CODEC_ENTRY Codec,
IN PULONG Verbs,
OUT PULONG Responses,
IN ULONG Count)
{
PHDA_FDO_DEVICE_EXTENSION DeviceExtension;
ULONG Sent = 0, ReadPosition, WritePosition, Queued;
/* get device extension */
DeviceExtension = (PHDA_FDO_DEVICE_EXTENSION)DeviceObject->DeviceExtension;
ASSERT(DeviceExtension->IsFDO);
/* reset response count */
Codec->ResponseCount = 0;
while (Sent < Count) {
ReadPosition = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_READ_POS));
Queued = 0;
while (Sent < Count) {
WritePosition = (DeviceExtension->CorbWritePos + 1) % DeviceExtension->CorbLength;
if (WritePosition == ReadPosition) {
// There is no space left in the ring buffer; execute the
// queued commands and wait until
break;
}
DeviceExtension->CorbBase[WritePosition] = Verbs[Sent++];
DeviceExtension->CorbWritePos = WritePosition;
// FIXME HACK
// do proper synchronization
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_WRITE_POS), DeviceExtension->CorbWritePos);
KeStallExecutionProcessor(30);
Queued++;
}
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_WRITE_POS), DeviceExtension->CorbWritePos);
}
if (Responses != NULL) {
memcpy(Responses, Codec->Responses, Codec->ResponseCount * sizeof(ULONG));
}
}
NTSTATUS
HDA_InitCodec(
IN PDEVICE_OBJECT DeviceObject,
IN ULONG codecAddress)
{
PHDA_CODEC_ENTRY Entry;
ULONG verbs[3];
PHDA_FDO_DEVICE_EXTENSION DeviceExtension;
CODEC_RESPONSE Response;
ULONG NodeId, GroupType;
NTSTATUS Status;
PHDA_CODEC_AUDIO_GROUP AudioGroup;
PHDA_PDO_DEVICE_EXTENSION ChildDeviceExtension;
/* lets allocate the entry */
Entry = (PHDA_CODEC_ENTRY)AllocateItem(NonPagedPool, sizeof(HDA_CODEC_ENTRY));
if (!Entry)
{
DPRINT1("hda: failed to allocate memory");
return STATUS_UNSUCCESSFUL;
}
/* init codec */
Entry->Addr = codecAddress;
/* get device extension */
DeviceExtension = (PHDA_FDO_DEVICE_EXTENSION)DeviceObject->DeviceExtension;
/* store codec */
DeviceExtension->Codecs[codecAddress] = Entry;
verbs[0] = MAKE_VERB(codecAddress, 0, VID_GET_PARAMETER, PID_VENDOR_ID);
verbs[1] = MAKE_VERB(codecAddress, 0, VID_GET_PARAMETER, PID_REVISION_ID);
verbs[2] = MAKE_VERB(codecAddress, 0, VID_GET_PARAMETER, PID_SUB_NODE_COUNT);
/* get basic info */
HDA_SendVerbs(DeviceObject, Entry, verbs, (PULONG)&Response, 3);
/* store codec details */
Entry->Major = Response.major;
Entry->Minor = Response.minor;
Entry->ProductId = Response.device;
Entry->Revision = Response.revision;
Entry->Stepping = Response.stepping;
Entry->VendorId = Response.vendor;
DPRINT1("hda Codec %ld Vendor: %04lx Product: %04lx, Revision: %lu.%lu.%lu.%lu NodeStart %u NodeCount %u \n", codecAddress, Response.vendor,
Response.device, Response.major, Response.minor, Response.revision, Response.stepping, Response.start, Response.count);
for (NodeId = Response.start; NodeId < Response.start + Response.count; NodeId++) {
/* get function type */
verbs[0] = MAKE_VERB(codecAddress, NodeId, VID_GET_PARAMETER, PID_FUNCTION_GROUP_TYPE);
HDA_SendVerbs(DeviceObject, Entry, verbs, &GroupType, 1);
DPRINT1("NodeId %u GroupType %x\n", NodeId, GroupType);
if ((GroupType & FUNCTION_GROUP_NODETYPE_MASK) == FUNCTION_GROUP_NODETYPE_AUDIO) {
AudioGroup = (PHDA_CODEC_AUDIO_GROUP)AllocateItem(NonPagedPool, sizeof(HDA_CODEC_AUDIO_GROUP));
if (!AudioGroup)
{
DPRINT1("hda: insufficient memory\n");
return STATUS_INSUFFICIENT_RESOURCES;
}
/* init audio group */
AudioGroup->NodeId = NodeId;
AudioGroup->FunctionGroup = FUNCTION_GROUP_NODETYPE_AUDIO;
// Found an Audio Function Group!
DPRINT1("NodeId %x found an audio function group!\n");
Status = IoCreateDevice(DeviceObject->DriverObject, sizeof(HDA_PDO_DEVICE_EXTENSION), NULL, FILE_DEVICE_SOUND, FILE_AUTOGENERATED_DEVICE_NAME, FALSE, &AudioGroup->ChildPDO);
if (!NT_SUCCESS(Status))
{
FreeItem(AudioGroup);
DPRINT1("hda failed to create device object %x\n", Status);
return Status;
}
/* init child pdo*/
ChildDeviceExtension = (PHDA_PDO_DEVICE_EXTENSION)AudioGroup->ChildPDO->DeviceExtension;
ChildDeviceExtension->IsFDO = FALSE;
ChildDeviceExtension->Codec = Entry;
ChildDeviceExtension->AudioGroup = AudioGroup;
ChildDeviceExtension->FDO = DeviceObject;
/* setup flags */
AudioGroup->ChildPDO->Flags |= DO_POWER_PAGABLE;
AudioGroup->ChildPDO->Flags &= ~DO_DEVICE_INITIALIZING;
/* add audio group*/
Entry->AudioGroups[Entry->AudioGroupCount] = AudioGroup;
Entry->AudioGroupCount++;
}
}
return STATUS_SUCCESS;
}
NTSTATUS
NTAPI
HDA_InitCorbRirbPos(
IN PDEVICE_OBJECT DeviceObject)
{
PHDA_FDO_DEVICE_EXTENSION DeviceExtension;
UCHAR corbSize, value, rirbSize;
PHYSICAL_ADDRESS HighestPhysicalAddress, CorbPhysicalAddress;
ULONG Index;
USHORT corbReadPointer, rirbWritePointer, interruptValue, corbControl, rirbControl;
/* get device extension */
DeviceExtension = (PHDA_FDO_DEVICE_EXTENSION)DeviceObject->DeviceExtension;
// Determine and set size of CORB
corbSize = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_SIZE);
if ((corbSize & CORB_SIZE_CAP_256_ENTRIES) != 0) {
DeviceExtension->CorbLength = 256;
value = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_SIZE) & HDAC_CORB_SIZE_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_SIZE, value | CORB_SIZE_256_ENTRIES);
}
else if (corbSize & CORB_SIZE_CAP_16_ENTRIES) {
DeviceExtension->CorbLength = 16;
value = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_SIZE) & HDAC_CORB_SIZE_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_SIZE, value | CORB_SIZE_16_ENTRIES);
}
else if (corbSize & CORB_SIZE_CAP_2_ENTRIES) {
DeviceExtension->CorbLength = 2;
value = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_SIZE) & HDAC_CORB_SIZE_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_SIZE, value | CORB_SIZE_2_ENTRIES);
}
// Determine and set size of RIRB
rirbSize = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_SIZE);
if (rirbSize & RIRB_SIZE_CAP_256_ENTRIES) {
DeviceExtension->RirbLength = 256;
value = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_SIZE) & HDAC_RIRB_SIZE_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_SIZE, value | RIRB_SIZE_256_ENTRIES);
}
else if (rirbSize & RIRB_SIZE_CAP_16_ENTRIES) {
DeviceExtension->RirbLength = 16;
value = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_SIZE) & HDAC_RIRB_SIZE_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_SIZE, value | RIRB_SIZE_16_ENTRIES);
}
else if (rirbSize & RIRB_SIZE_CAP_2_ENTRIES) {
DeviceExtension->RirbLength = 2;
value = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_SIZE) & HDAC_RIRB_SIZE_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_SIZE, value | RIRB_SIZE_2_ENTRIES);
}
/* init corb */
HighestPhysicalAddress.QuadPart = 0x00000000FFFFFFFF;
DeviceExtension->CorbBase = (PULONG)MmAllocateContiguousMemory(PAGE_SIZE * 3, HighestPhysicalAddress);
ASSERT(DeviceExtension->CorbBase != NULL);
// FIXME align rirb 128bytes
ASSERT(DeviceExtension->CorbLength == 256);
ASSERT(DeviceExtension->RirbLength == 256);
CorbPhysicalAddress = MmGetPhysicalAddress(DeviceExtension->CorbBase);
ASSERT(CorbPhysicalAddress.QuadPart != 0LL);
// Program CORB/RIRB for these locations
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_CORB_BASE_LOWER), CorbPhysicalAddress.LowPart);
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_CORB_BASE_UPPER), CorbPhysicalAddress.HighPart);
DeviceExtension->RirbBase = (PRIRB_RESPONSE)((ULONG_PTR)DeviceExtension->CorbBase + PAGE_SIZE);
CorbPhysicalAddress.QuadPart += PAGE_SIZE;
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_RIRB_BASE_LOWER), CorbPhysicalAddress.LowPart);
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_RIRB_BASE_UPPER), CorbPhysicalAddress.HighPart);
// Program DMA position update
DeviceExtension->StreamPositions = (PVOID)((ULONG_PTR)DeviceExtension->RirbBase + PAGE_SIZE);
CorbPhysicalAddress.QuadPart += PAGE_SIZE;
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_DMA_POSITION_BASE_LOWER), CorbPhysicalAddress.LowPart);
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_DMA_POSITION_BASE_UPPER), CorbPhysicalAddress.HighPart);
value = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_WRITE_POS)) & HDAC_CORB_WRITE_POS_MASK;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_WRITE_POS), value);
// Reset CORB read pointer. Preserve bits marked as RsvdP.
// After setting the reset bit, we must wait for the hardware
// to acknowledge it, then manually unset it and wait for that
// to be acknowledged as well.
corbReadPointer = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_READ_POS));
corbReadPointer |= CORB_READ_POS_RESET;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_READ_POS), corbReadPointer);
for (Index = 0; Index < 100; Index++) {
KeStallExecutionProcessor(10);
corbReadPointer = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_READ_POS));
if ((corbReadPointer & CORB_READ_POS_RESET) != 0)
break;
}
if ((corbReadPointer & CORB_READ_POS_RESET) == 0) {
DPRINT1("hda: CORB read pointer reset not acknowledged\n");
// According to HDA spec v1.0a ch3.3.21, software must read the
// bit as 1 to verify that the reset completed. However, at least
// some nVidia HDA controllers do not update the bit after reset.
// Thus don't fail here on nVidia controllers.
//if (controller->pci_info.vendor_id != PCI_VENDOR_NVIDIA)
// return B_BUSY;
}
corbReadPointer &= ~CORB_READ_POS_RESET;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_READ_POS), corbReadPointer);
for (Index = 0; Index < 10; Index++) {
KeStallExecutionProcessor(10);
corbReadPointer = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_READ_POS));
if ((corbReadPointer & CORB_READ_POS_RESET) == 0)
break;
}
if ((corbReadPointer & CORB_READ_POS_RESET) != 0) {
DPRINT1("hda: CORB read pointer reset failed\n");
return STATUS_UNSUCCESSFUL;
}
// Reset RIRB write pointer
rirbWritePointer = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_RIRB_WRITE_POS)) & RIRB_WRITE_POS_RESET;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_RIRB_WRITE_POS), rirbWritePointer | RIRB_WRITE_POS_RESET);
// Generate interrupt for every response
interruptValue = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_RESPONSE_INTR_COUNT)) & HDAC_RESPONSE_INTR_COUNT_MASK;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_RESPONSE_INTR_COUNT), interruptValue | 1);
// Setup cached read/write indices
DeviceExtension->RirbReadPos = 1;
DeviceExtension->CorbWritePos = 0;
// Gentlemen, start your engines...
corbControl = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_CONTROL)) &HDAC_CORB_CONTROL_MASK;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_CORB_CONTROL), corbControl | CORB_CONTROL_RUN | CORB_CONTROL_MEMORY_ERROR_INTR);
rirbControl = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_RIRB_CONTROL)) & HDAC_RIRB_CONTROL_MASK;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_RIRB_CONTROL), rirbControl | RIRB_CONTROL_DMA_ENABLE | RIRB_CONTROL_OVERRUN_INTR | RIRB_CONTROL_RESPONSE_INTR);
return STATUS_SUCCESS;
}
NTSTATUS
NTAPI
HDA_ResetController(
IN PDEVICE_OBJECT DeviceObject)
{
USHORT ValCapabilities;
ULONG Index;
PHDA_FDO_DEVICE_EXTENSION DeviceExtension;
ULONG InputStreams, OutputStreams, BiDirStreams, Control;
UCHAR corbControl, rirbControl;
/* get device extension */
DeviceExtension = (PHDA_FDO_DEVICE_EXTENSION)DeviceObject->DeviceExtension;
/* read caps */
ValCapabilities = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_GLOBAL_CAP));
InputStreams = GLOBAL_CAP_INPUT_STREAMS(ValCapabilities);
OutputStreams = GLOBAL_CAP_OUTPUT_STREAMS(ValCapabilities);
BiDirStreams = GLOBAL_CAP_BIDIR_STREAMS(ValCapabilities);
DPRINT1("NumInputStreams %u\n", InputStreams);
DPRINT1("NumOutputStreams %u\n", OutputStreams);
DPRINT1("NumBiDirStreams %u\n", BiDirStreams);
/* stop all streams */
for (Index = 0; Index < InputStreams; Index++)
{
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_STREAM_CONTROL0 + HDAC_STREAM_BASE + HDAC_INPUT_STREAM_OFFSET(Index), 0);
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_STREAM_STATUS + HDAC_STREAM_BASE + HDAC_INPUT_STREAM_OFFSET(Index), 0);
}
for (Index = 0; Index < OutputStreams; Index++) {
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_STREAM_CONTROL0 + HDAC_STREAM_BASE + HDAC_OUTPUT_STREAM_OFFSET(InputStreams, Index), 0);
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_STREAM_STATUS + HDAC_STREAM_BASE + HDAC_OUTPUT_STREAM_OFFSET(InputStreams, Index), 0);
}
for (Index = 0; Index < BiDirStreams; Index++) {
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_STREAM_CONTROL0 + HDAC_STREAM_BASE + HDAC_BIDIR_STREAM_OFFSET(InputStreams, OutputStreams, Index), 0);
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_STREAM_STATUS + HDAC_STREAM_BASE + HDAC_BIDIR_STREAM_OFFSET(InputStreams, OutputStreams, Index), 0);
}
// stop DMA
Control = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_CONTROL) & HDAC_CORB_CONTROL_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_CONTROL, Control);
Control = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_CONTROL) & HDAC_RIRB_CONTROL_MASK;
WRITE_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_CONTROL, Control);
for (int timeout = 0; timeout < 10; timeout++) {
KeStallExecutionProcessor(10);
corbControl = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_CORB_CONTROL);
rirbControl = READ_REGISTER_UCHAR(DeviceExtension->RegBase + HDAC_RIRB_CONTROL);
if (corbControl == 0 && rirbControl == 0)
break;
}
if (corbControl != 0 || rirbControl != 0) {
DPRINT1("hda: unable to stop dma\n");
return STATUS_UNSUCCESSFUL;
}
// reset DMA position buffer
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_DMA_POSITION_BASE_LOWER), 0);
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_DMA_POSITION_BASE_UPPER), 0);
// Set reset bit - it must be asserted for at least 100us
Control = READ_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL));
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL), Control & ~GLOBAL_CONTROL_RESET);
for (int timeout = 0; timeout < 10; timeout++) {
KeStallExecutionProcessor(10);
Control = READ_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL));
if ((Control & GLOBAL_CONTROL_RESET) == 0)
break;
}
if ((Control & GLOBAL_CONTROL_RESET) != 0)
{
DPRINT1("hda: unable to reset controller\n");
return STATUS_UNSUCCESSFUL;
}
// Unset reset bit
Control = READ_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL));
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL), Control | GLOBAL_CONTROL_RESET);
for (int timeout = 0; timeout < 10; timeout++) {
KeStallExecutionProcessor(10);
Control = READ_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL));
if ((Control & GLOBAL_CONTROL_RESET) != 0)
break;
}
if ((Control & GLOBAL_CONTROL_RESET) == 0) {
DPRINT1("hda: unable to exit reset\n");
return STATUS_UNSUCCESSFUL;
}
// Wait for codecs to finish their own reset (apparently needs more
// time than documented in the specs)
KeStallExecutionProcessor(100);
// Enable unsolicited responses
Control = READ_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL));
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_GLOBAL_CONTROL), Control | GLOBAL_CONTROL_UNSOLICITED);
return STATUS_SUCCESS;
}
NTSTATUS
NTAPI
HDA_FDOStartDevice(
IN PDEVICE_OBJECT DeviceObject,
IN PIRP Irp)
{
PIO_STACK_LOCATION IoStack;
NTSTATUS Status = STATUS_SUCCESS;
PHDA_FDO_DEVICE_EXTENSION DeviceExtension;
PCM_RESOURCE_LIST Resources;
ULONG Index;
USHORT Value;
/* get device extension */
DeviceExtension = (PHDA_FDO_DEVICE_EXTENSION)DeviceObject->DeviceExtension;
ASSERT(DeviceExtension->IsFDO == TRUE);
/* forward irp to lower device */
Status = HDA_SyncForwardIrp(DeviceExtension->LowerDevice, Irp);
if (!NT_SUCCESS(Status))
{
// failed to start
DPRINT1("HDA_StartDevice Lower device failed to start %x\n", Status);
return Status;
}
/* get current irp stack location */
IoStack = IoGetCurrentIrpStackLocation(Irp);
Resources = IoStack->Parameters.StartDevice.AllocatedResourcesTranslated;
for (Index = 0; Index < Resources->List[0].PartialResourceList.Count; Index++)
{
PCM_PARTIAL_RESOURCE_DESCRIPTOR Descriptor = &Resources->List[0].PartialResourceList.PartialDescriptors[Index];
if (Descriptor->Type == CmResourceTypeMemory)
{
DeviceExtension->RegBase = (PUCHAR)MmMapIoSpace(Descriptor->u.Memory.Start, Descriptor->u.Memory.Length, MmNonCached);
if (DeviceExtension->RegBase == NULL)
{
DPRINT1("[HDAB] Failed to map registers\n");
Status = STATUS_UNSUCCESSFUL;
break;
}
}
else if (Descriptor->Type == CmResourceTypeInterrupt)
{
Status = IoConnectInterrupt(&DeviceExtension->Interrupt,
HDA_InterruptService,
(PVOID)DeviceExtension,
NULL,
Descriptor->u.Interrupt.Vector,
Descriptor->u.Interrupt.Level,
Descriptor->u.Interrupt.Level,
(KINTERRUPT_MODE)(Descriptor->Flags & CM_RESOURCE_INTERRUPT_LATCHED),
(Descriptor->ShareDisposition != CmResourceShareDeviceExclusive),
Descriptor->u.Interrupt.Affinity,
FALSE);
if (!NT_SUCCESS(Status))
{
DPRINT1("[HDAB] Failed to connect interrupt\n");
break;
}
}
}
if (NT_SUCCESS(Status))
{
// Get controller into valid state
Status = HDA_ResetController(DeviceObject);
if (!NT_SUCCESS(Status)) return Status;
// Setup CORB/RIRB/DMA POS
Status = HDA_InitCorbRirbPos(DeviceObject);
if (!NT_SUCCESS(Status)) return Status;
// Don't enable codec state change interrupts. We don't handle
// them, as we want to use the STATE_STATUS register to identify
// available codecs. We'd have to clear that register in the interrupt
// handler to 'ack' the codec change.
Value = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_WAKE_ENABLE)) & ~HDAC_WAKE_ENABLE_MASK;
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_WAKE_ENABLE), Value);
// Enable controller interrupts
WRITE_REGISTER_ULONG((PULONG)(DeviceExtension->RegBase + HDAC_INTR_CONTROL), INTR_CONTROL_GLOBAL_ENABLE | INTR_CONTROL_CONTROLLER_ENABLE);
KeStallExecutionProcessor(100);
Value = READ_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_STATE_STATUS));
if (!Value) {
DPRINT1("hda: bad codec status\n");
return STATUS_UNSUCCESSFUL;
}
WRITE_REGISTER_USHORT((PUSHORT)(DeviceExtension->RegBase + HDAC_STATE_STATUS), Value);
// Create codecs
DPRINT1("Codecs %lx\n", Value);
for (Index = 0; Index < HDA_MAX_CODECS; Index++) {
if ((Value & (1 << Index)) != 0) {
HDA_InitCodec(DeviceObject, Index);
}
}
}
return Status;
}
NTSTATUS
NTAPI
HDA_FDOQueryBusRelations(
IN PDEVICE_OBJECT DeviceObject,
IN PIRP Irp)
{
ULONG DeviceCount, CodecIndex, AFGIndex;
PHDA_FDO_DEVICE_EXTENSION DeviceExtension;
PHDA_CODEC_ENTRY Codec;
PDEVICE_RELATIONS DeviceRelations;
/* get device extension */
DeviceExtension = (PHDA_FDO_DEVICE_EXTENSION)DeviceObject->DeviceExtension;
ASSERT(DeviceExtension->IsFDO == TRUE);
DeviceCount = 0;
for (CodecIndex = 0; CodecIndex < HDA_MAX_CODECS; CodecIndex++)
{
if (DeviceExtension->Codecs[CodecIndex] == NULL)
continue;
Codec = DeviceExtension->Codecs[CodecIndex];
DeviceCount += Codec->AudioGroupCount;
}
if (DeviceCount == 0)
return STATUS_UNSUCCESSFUL;
DeviceRelations = (PDEVICE_RELATIONS)AllocateItem(NonPagedPool, sizeof(DEVICE_RELATIONS) + (DeviceCount > 1 ? sizeof(PDEVICE_OBJECT) * (DeviceCount - 1) : 0));
if (!DeviceRelations)
return STATUS_INSUFFICIENT_RESOURCES;
DeviceRelations->Count = 0;
for (CodecIndex = 0; CodecIndex < HDA_MAX_CODECS; CodecIndex++)
{
if (DeviceExtension->Codecs[CodecIndex] == NULL)
continue;
Codec = DeviceExtension->Codecs[CodecIndex];
for (AFGIndex = 0; AFGIndex < Codec->AudioGroupCount; AFGIndex++)
{
DeviceRelations->Objects[DeviceRelations->Count] = Codec->AudioGroups[AFGIndex]->ChildPDO;
ObReferenceObject(Codec->AudioGroups[AFGIndex]->ChildPDO);
DeviceRelations->Count++;
}
}
/* FIXME handle existing device relations */
ASSERT(Irp->IoStatus.Information == 0);
/* store device relations */
Irp->IoStatus.Information = (ULONG_PTR)DeviceRelations;
/* done */
return STATUS_SUCCESS;
}