LookingGlass/idd/LGIdd/CIndirectDeviceContext.cpp

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#include "CIndirectDeviceContext.h"
#include "CIndirectMonitorContext.h"
#include "CPlatformInfo.h"
#include "Debug.h"
#include <sstream>
static const struct LGMPQueueConfig FRAME_QUEUE_CONFIG =
{
LGMP_Q_FRAME, //queueID
LGMP_Q_FRAME_LEN, //numMessages
1000 //subTimeout
};
static const struct LGMPQueueConfig POINTER_QUEUE_CONFIG =
{
LGMP_Q_POINTER, //queueID
LGMP_Q_POINTER_LEN, //numMesages
1000 //subTimeout
};
CIndirectDeviceContext::~CIndirectDeviceContext()
{
if (m_lgmp == nullptr)
return;
if (m_lgmpTimer)
{
WdfTimerStop(m_lgmpTimer, TRUE);
m_lgmpTimer = nullptr;
}
for(int i = 0; i < LGMP_Q_FRAME_LEN; ++i)
lgmpHostMemFree(&m_frameMemory[i]);
for (int i = 0; i < LGMP_Q_POINTER_LEN; ++i)
lgmpHostMemFree(&m_pointerMemory[i]);
for (int i = 0; i < POINTER_SHAPE_BUFFERS; ++i)
lgmpHostMemFree(&m_pointerShapeMemory[i]);
lgmpHostFree(&m_lgmp);
}
void CIndirectDeviceContext::InitAdapter()
{
if (!SetupLGMP())
2023-04-09 19:36:00 +00:00
return;
IDDCX_ADAPTER_CAPS caps = {};
caps.Size = sizeof(caps);
/**
* For some reason if we do not set this flag sometimes windows will
* refuse to enumerate our virtual monitor. Intel also noted in their
* sources that if this is not set dynamic resolution changes from this
* driver will not work. This behaviour is not documented by Microsoft.
*/
caps.Flags = IDDCX_ADAPTER_FLAGS_USE_SMALLEST_MODE;
caps.MaxMonitorsSupported = 1;
caps.EndPointDiagnostics.Size = sizeof(caps.EndPointDiagnostics);
caps.EndPointDiagnostics.GammaSupport = IDDCX_FEATURE_IMPLEMENTATION_NONE;
caps.EndPointDiagnostics.TransmissionType = IDDCX_TRANSMISSION_TYPE_OTHER;
caps.EndPointDiagnostics.pEndPointFriendlyName = L"Looking Glass IDD Device";
caps.EndPointDiagnostics.pEndPointManufacturerName = L"Looking Glass";
caps.EndPointDiagnostics.pEndPointModelName = L"Looking Glass";
IDDCX_ENDPOINT_VERSION ver = {};
ver.Size = sizeof(ver);
ver.MajorVer = 1;
caps.EndPointDiagnostics.pFirmwareVersion = &ver;
caps.EndPointDiagnostics.pHardwareVersion = &ver;
WDF_OBJECT_ATTRIBUTES attr;
WDF_OBJECT_ATTRIBUTES_INIT_CONTEXT_TYPE(&attr, CIndirectDeviceContextWrapper);
IDARG_IN_ADAPTER_INIT init = {};
init.WdfDevice = m_wdfDevice;
init.pCaps = &caps;
init.ObjectAttributes = &attr;
IDARG_OUT_ADAPTER_INIT initOut;
NTSTATUS status = IddCxAdapterInitAsync(&init, &initOut);
if (!NT_SUCCESS(status))
{
DBGPRINT("IddCxAdapterInitAsync Failed");
return;
}
m_adapter = initOut.AdapterObject;
// try to co-exist with the virtual video device by telling IddCx which adapter we prefer to render on
IDXGIFactory * factory = NULL;
IDXGIAdapter * dxgiAdapter;
CreateDXGIFactory(__uuidof(IDXGIFactory), (void **)&factory);
for (UINT i = 0; factory->EnumAdapters(i, &dxgiAdapter) != DXGI_ERROR_NOT_FOUND; ++i)
{
DXGI_ADAPTER_DESC adapterDesc;
dxgiAdapter->GetDesc(&adapterDesc);
dxgiAdapter->Release();
if ((adapterDesc.VendorId == 0x1414 && adapterDesc.DeviceId == 0x008c) || // Microsoft Basic Render Driver
(adapterDesc.VendorId == 0x1b36 && adapterDesc.DeviceId == 0x000d) || // QXL
(adapterDesc.VendorId == 0x1234 && adapterDesc.DeviceId == 0x1111)) // QEMU Standard VGA
continue;
IDARG_IN_ADAPTERSETRENDERADAPTER args = {};
args.PreferredRenderAdapter = adapterDesc.AdapterLuid;
IddCxAdapterSetRenderAdapter(m_adapter, &args);
break;
}
factory->Release();
auto * wrapper = WdfObjectGet_CIndirectDeviceContextWrapper(m_adapter);
wrapper->context = this;
}
static const BYTE EDID[] =
{
0x00,0xFF,0xFF,0xFF,0xFF,0xFF,0xFF,0x00,0x30,0xE8,0x34,0x12,0xC9,0x07,0xCC,0x00,
0x01,0x21,0x01,0x04,0xA5,0x3C,0x22,0x78,0xFB,0x6C,0xE5,0xA5,0x55,0x50,0xA0,0x23,
0x0B,0x50,0x54,0x00,0x02,0x00,0xD1,0xC0,0x01,0x01,0x01,0x01,0x01,0x01,0x01,0x01,
0x01,0x01,0x01,0x01,0x01,0x01,0x58,0xE3,0x00,0xA0,0xA0,0xA0,0x29,0x50,0x30,0x20,
0x35,0x00,0x55,0x50,0x21,0x00,0x00,0x1A,0x00,0x00,0x00,0xFF,0x00,0x4C,0x6F,0x6F,
0x6B,0x69,0x6E,0x67,0x47,0x6C,0x61,0x73,0x73,0x0A,0x00,0x00,0x00,0xFC,0x00,0x4C,
0x6F,0x6F,0x6B,0x69,0x6E,0x67,0x20,0x47,0x6C,0x61,0x73,0x73,0x00,0x00,0x00,0xFD,
0x00,0x28,0x9B,0xFA,0xFA,0x40,0x01,0x0A,0x20,0x20,0x20,0x20,0x20,0x20,0x00,0x4A
};
void CIndirectDeviceContext::FinishInit(UINT connectorIndex)
{
WDF_OBJECT_ATTRIBUTES attr;
WDF_OBJECT_ATTRIBUTES_INIT_CONTEXT_TYPE(&attr, CIndirectMonitorContextWrapper);
IDDCX_MONITOR_INFO info = {};
info.Size = sizeof(info);
info.MonitorType = DISPLAYCONFIG_OUTPUT_TECHNOLOGY_HDMI;
info.ConnectorIndex = connectorIndex;
info.MonitorDescription.Size = sizeof(info.MonitorDescription);
info.MonitorDescription.Type = IDDCX_MONITOR_DESCRIPTION_TYPE_EDID;
if (connectorIndex >= 1)
{
info.MonitorDescription.DataSize = 0;
info.MonitorDescription.pData = nullptr;
}
else
{
info.MonitorDescription.DataSize = sizeof(EDID);
info.MonitorDescription.pData = const_cast<BYTE*>(EDID);
}
CoCreateGuid(&info.MonitorContainerId);
IDARG_IN_MONITORCREATE create = {};
create.ObjectAttributes = &attr;
create.pMonitorInfo = &info;
IDARG_OUT_MONITORCREATE createOut;
NTSTATUS status = IddCxMonitorCreate(m_adapter, &create, &createOut);
if (!NT_SUCCESS(status))
{
DBGPRINT("IddCxMonitorCreate Failed");
return;
}
m_monitor = createOut.MonitorObject;
auto * wrapper = WdfObjectGet_CIndirectMonitorContextWrapper(m_monitor);
wrapper->context = new CIndirectMonitorContext(m_monitor, this);
IDARG_OUT_MONITORARRIVAL out;
status = IddCxMonitorArrival(m_monitor, &out);
}
bool CIndirectDeviceContext::SetupLGMP()
{
if (!m_ivshmem.Init() || !m_ivshmem.Open())
return false;
std::stringstream ss;
{
KVMFR kvmfr = {};
memcpy_s(kvmfr.magic, sizeof(kvmfr.magic), KVMFR_MAGIC, sizeof(KVMFR_MAGIC) - 1);
kvmfr.version = KVMFR_VERSION;
kvmfr.features = KVMFR_FEATURE_SETCURSORPOS;
strncpy_s(kvmfr.hostver, "FIXME-IDD", sizeof(kvmfr.hostver) - 1);
ss.write(reinterpret_cast<const char *>(&kvmfr), sizeof(kvmfr));
}
{
const std::string & model = CPlatformInfo::GetCPUModel();
KVMFRRecord_VMInfo * vmInfo = static_cast<KVMFRRecord_VMInfo *>(calloc(1, sizeof(*vmInfo)));
if (!vmInfo)
{
DBGPRINT("Failed to allocate KVMFRRecord_VMInfo");
return false;
}
vmInfo->cpus = static_cast<uint8_t>(CPlatformInfo::GetProcCount ());
vmInfo->cores = static_cast<uint8_t>(CPlatformInfo::GetCoreCount ());
vmInfo->sockets = static_cast<uint8_t>(CPlatformInfo::GetSocketCount());
const uint8_t * uuid = CPlatformInfo::GetUUID();
memcpy_s (vmInfo->uuid, sizeof(vmInfo->uuid), uuid, 16);
strncpy_s(vmInfo->capture, "Idd Driver", sizeof(vmInfo->capture));
KVMFRRecord * record = static_cast<KVMFRRecord *>(calloc(1, sizeof(*record)));
if (!record)
{
DBGPRINT("Failed to allocate KVMFRRecord");
return false;
}
record->type = KVMFR_RECORD_VMINFO;
record->size = sizeof(*vmInfo) + (uint32_t)model.length() + 1;
ss.write(reinterpret_cast<const char*>(record ), sizeof(*record));
ss.write(reinterpret_cast<const char*>(vmInfo ), sizeof(*vmInfo));
ss.write(reinterpret_cast<const char*>(model.c_str()), model.length() + 1);
}
{
KVMFRRecord_OSInfo * osInfo = static_cast<KVMFRRecord_OSInfo *>(calloc(1, sizeof(*osInfo)));
if (!osInfo)
{
DBGPRINT("Failed to allocate KVMFRRecord_OSInfo");
return false;
}
osInfo->os = KVMFR_OS_WINDOWS;
const std::string & osName = CPlatformInfo::GetProductName();
KVMFRRecord* record = static_cast<KVMFRRecord*>(calloc(1, sizeof(*record)));
if (!record)
{
DBGPRINT("Failed to allocate KVMFRRecord");
return false;
}
record->type = KVMFR_RECORD_OSINFO;
record->size = sizeof(*osInfo) + (uint32_t)osName.length() + 1;
ss.write(reinterpret_cast<const char*>(record), sizeof(*record));
ss.write(reinterpret_cast<const char*>(osInfo), sizeof(*osInfo));
ss.write(reinterpret_cast<const char*>(osName.c_str()), osName.length() + 1);
}
LGMP_STATUS status;
std::string udata = ss.str();
if ((status = lgmpHostInit(m_ivshmem.GetMem(), (uint32_t)m_ivshmem.GetSize(),
&m_lgmp, (uint32_t)udata.size(), (uint8_t*)&udata[0])) != LGMP_OK)
{
DBGPRINT("lgmpHostInit Failed: %s", lgmpStatusString(status));
return false;
}
if ((status = lgmpHostQueueNew(m_lgmp, FRAME_QUEUE_CONFIG, &m_frameQueue)) != LGMP_OK)
{
DBGPRINT("lgmpHostQueueCreate Failed (Frame): %s", lgmpStatusString(status));
return false;
}
if ((status = lgmpHostQueueNew(m_lgmp, POINTER_QUEUE_CONFIG, &m_pointerQueue)) != LGMP_OK)
{
DBGPRINT("lgmpHostQueueCreate Failed (Pointer): %s", lgmpStatusString(status));
return false;
}
for (int i = 0; i < LGMP_Q_POINTER_LEN; ++i)
{
if ((status = lgmpHostMemAlloc(m_lgmp, MAX_POINTER_SIZE, &m_pointerMemory[i])) != LGMP_OK)
{
DBGPRINT("lgmpHostMemAlloc Failed (Pointer): %s", lgmpStatusString(status));
return false;
}
memset(lgmpHostMemPtr(m_pointerMemory[i]), 0, MAX_POINTER_SIZE);
}
for (int i = 0; i < POINTER_SHAPE_BUFFERS; ++i)
{
if ((status = lgmpHostMemAlloc(m_lgmp, MAX_POINTER_SIZE, &m_pointerShapeMemory[i])) != LGMP_OK)
{
DBGPRINT("lgmpHostMemAlloc Failed (Pointer Shapes): %s", lgmpStatusString(status));
return false;
}
memset(lgmpHostMemPtr(m_pointerShapeMemory[i]), 0, MAX_POINTER_SIZE);
}
m_maxFrameSize = lgmpHostMemAvail(m_lgmp);
m_maxFrameSize = (m_maxFrameSize -(CPlatformInfo::GetPageSize() - 1)) & ~(CPlatformInfo::GetPageSize() - 1);
m_maxFrameSize /= LGMP_Q_FRAME_LEN;
DBGPRINT("Max Frame Size: %u MiB\n", (unsigned int)(m_maxFrameSize / 1048576LL));
for (int i = 0; i < LGMP_Q_FRAME_LEN; ++i)
if ((status = lgmpHostMemAllocAligned(m_lgmp, (uint32_t)m_maxFrameSize,
(uint32_t)CPlatformInfo::GetPageSize(), &m_frameMemory[i])) != LGMP_OK)
{
DBGPRINT("lgmpHostMemAllocAligned Failed (Frame): %s", lgmpStatusString(status));
return false;
}
WDF_TIMER_CONFIG config;
WDF_TIMER_CONFIG_INIT_PERIODIC(&config,
[](WDFTIMER timer) -> void
{
WDFOBJECT parent = WdfTimerGetParentObject(timer);
auto wrapper = WdfObjectGet_CIndirectDeviceContextWrapper(parent);
wrapper->context->LGMPTimer();
},
10);
config.AutomaticSerialization = FALSE;
/**
* documentation states that Dispatch is not available under the UDMF, however...
* using Passive returns a not supported error, and Dispatch works.
*/
WDF_OBJECT_ATTRIBUTES attribs;
WDF_OBJECT_ATTRIBUTES_INIT(&attribs);
attribs.ParentObject = m_wdfDevice;
attribs.ExecutionLevel = WdfExecutionLevelDispatch;
NTSTATUS s = WdfTimerCreate(&config, &attribs, &m_lgmpTimer);
if (!NT_SUCCESS(s))
{
DBGPRINT("Timer creation failed: 0x%08x", s);
return false;
}
WdfTimerStart(m_lgmpTimer, WDF_REL_TIMEOUT_IN_MS(10));
return true;
}
void CIndirectDeviceContext::LGMPTimer()
{
LGMP_STATUS status;
if ((status = lgmpHostProcess(m_lgmp)) != LGMP_OK)
{
if (status == LGMP_ERR_CORRUPTED)
{
DBGPRINT("LGMP reported the shared memory has been corrupted, attempting to recover\n");
//TODO: fixme - reinit
return;
}
DBGPRINT("lgmpHostProcess Failed: %s", lgmpStatusString(status));
//TODO: fixme - shutdown
return;
}
uint8_t data[LGMP_MSGS_SIZE];
size_t size;
while ((status = lgmpHostReadData(m_pointerQueue, &data, &size)) == LGMP_OK)
{
KVMFRMessage * msg = (KVMFRMessage *)data;
switch (msg->type)
{
case KVMFR_MESSAGE_SETCURSORPOS:
{
KVMFRSetCursorPos *sp = (KVMFRSetCursorPos *)msg;
SetCursorPos(sp->x, sp->y);
break;
}
}
lgmpHostAckData(m_pointerQueue);
}
if (lgmpHostQueueNewSubs(m_frameQueue) && m_monitor)
{
auto* wrapper = WdfObjectGet_CIndirectMonitorContextWrapper(m_monitor);
if (wrapper)
wrapper->context->ResendLastFrame();
}
if (lgmpHostQueueNewSubs(m_pointerQueue))
ResendCursor();
}
void CIndirectDeviceContext::SendFrame(int width, int height, int pitch, DXGI_FORMAT format, void* data)
{
if (!m_lgmp || !m_frameQueue)
return;
if (m_width != width || m_height != height || m_pitch != pitch || m_format != format)
{
m_width = width;
m_height = height;
m_format = format;
m_pitch = pitch;
++m_formatVer;
}
while (lgmpHostQueuePending(m_frameQueue) == LGMP_Q_FRAME_LEN)
Sleep(0);
if (++m_frameIndex == LGMP_Q_FRAME_LEN)
m_frameIndex = 0;
KVMFRFrame * fi = (KVMFRFrame *)lgmpHostMemPtr(m_frameMemory[m_frameIndex]);
int bpp = 4;
switch (format)
{
case DXGI_FORMAT_B8G8R8A8_UNORM : fi->type = FRAME_TYPE_BGRA ; break;
case DXGI_FORMAT_R8G8B8A8_UNORM : fi->type = FRAME_TYPE_RGBA ; break;
case DXGI_FORMAT_R10G10B10A2_UNORM : fi->type = FRAME_TYPE_RGBA10 ; break;
case DXGI_FORMAT_R16G16B16A16_FLOAT:
fi->type = FRAME_TYPE_RGBA16F;
bpp = 8;
break;
default:
DBGPRINT("Unsuppoted DXGI format");
return;
}
//FIXME: this should not really be done here, this is a hack
#pragma warning(push)
#pragma warning(disable: 4200)
struct FrameBuffer
{
volatile uint32_t wp;
uint8_t data[0];
};
#pragma warning(pop)
fi->formatVer = m_formatVer;
fi->frameSerial = m_frameSerial++;
fi->screenWidth = width;
fi->screenHeight = height;
fi->frameWidth = width;
fi->frameHeight = height;
fi->stride = width * bpp;
fi->pitch = pitch;
fi->offset = (uint32_t)(CPlatformInfo::GetPageSize() - sizeof(FrameBuffer));
fi->flags = 0;
fi->rotation = FRAME_ROT_0;
fi->damageRectsCount = 0;
FrameBuffer * fb = (FrameBuffer *)(((uint8_t*)fi) + fi->offset);
fb->wp = 0;
lgmpHostQueuePost(m_frameQueue, 0, m_frameMemory[m_frameIndex]);
memcpy(fb->data, data, (size_t)height * (size_t)pitch);
fb->wp = height * pitch;
}
void CIndirectDeviceContext::SendCursor(const IDARG_OUT_QUERY_HWCURSOR& info, const BYTE * data)
{
PLGMPMemory mem;
if (info.CursorShapeInfo.CursorType == IDDCX_CURSOR_SHAPE_TYPE_UNINITIALIZED)
{
mem = m_pointerMemory[m_pointerMemoryIndex];
if (++m_pointerMemoryIndex == LGMP_Q_POINTER_LEN)
m_pointerMemoryIndex = 0;
}
else
{
mem = m_pointerShapeMemory[m_pointerShapeIndex];
if (++m_pointerShapeIndex == POINTER_SHAPE_BUFFERS)
m_pointerShapeIndex = 0;
}
KVMFRCursor * cursor = (KVMFRCursor *)lgmpHostMemPtr(mem);
m_cursorVisible = info.IsCursorVisible;
uint32_t flags = 0;
if (info.IsCursorVisible)
{
m_cursorX = info.X;
m_cursorY = info.Y;
cursor->x = (int16_t)info.X;
cursor->y = (int16_t)info.Y;
flags |= CURSOR_FLAG_POSITION | CURSOR_FLAG_VISIBLE;
}
if (info.CursorShapeInfo.CursorType != IDDCX_CURSOR_SHAPE_TYPE_UNINITIALIZED)
{
memcpy(cursor + 1, data,
(size_t)(info.CursorShapeInfo.Height * info.CursorShapeInfo.Pitch));
cursor->hx = (int8_t )info.CursorShapeInfo.XHot;
cursor->hy = (int8_t )info.CursorShapeInfo.YHot;
cursor->width = (uint32_t)info.CursorShapeInfo.Width;
cursor->height = (uint32_t)info.CursorShapeInfo.Height;
cursor->pitch = (uint32_t)info.CursorShapeInfo.Pitch;
switch (info.CursorShapeInfo.CursorType)
{
case IDDCX_CURSOR_SHAPE_TYPE_ALPHA:
cursor->type = CURSOR_TYPE_COLOR;
break;
case IDDCX_CURSOR_SHAPE_TYPE_MASKED_COLOR:
cursor->type = CURSOR_TYPE_MASKED_COLOR;
break;
}
flags |= CURSOR_FLAG_SHAPE;
m_pointerShape = mem;
}
LGMP_STATUS status;
while ((status = lgmpHostQueuePost(m_pointerQueue, flags, mem)) != LGMP_OK)
{
if (status == LGMP_ERR_QUEUE_FULL)
{
Sleep(1);
continue;
}
DBGPRINT("lgmpHostQueuePost Failed (Pointer): %s", lgmpStatusString(status));
break;
}
}
void CIndirectDeviceContext::ResendCursor()
{
PLGMPMemory mem = m_pointerShape;
if (!mem)
return;
KVMFRCursor* cursor = (KVMFRCursor*)lgmpHostMemPtr(mem);
cursor->x = (int16_t)m_cursorX;
cursor->y = (int16_t)m_cursorY;
const uint32_t flags =
CURSOR_FLAG_POSITION | CURSOR_FLAG_SHAPE |
(m_cursorVisible ? CURSOR_FLAG_VISIBLE : 0);
LGMP_STATUS status;
while ((status = lgmpHostQueuePost(m_pointerQueue, flags, mem)) != LGMP_OK)
{
if (status == LGMP_ERR_QUEUE_FULL)
{
Sleep(1);
continue;
}
DBGPRINT("lgmpHostQueuePost Failed (Pointer): %s", lgmpStatusString(status));
break;
}
}