isle/LEGO1/mxdirectx/mxdirect3d.cpp
Anonymous Maarten ac8ddca405
Implement mxdirectx stubs (#525)
* Implement MxDeviceEnumerate::SupportsMMX

* Implement MxDeviceEnumerate::EnumerateErrorToString

* fixes

* fixes

* Remove STUB from function

* Fix error messages

* Use return type int

---------

Co-authored-by: Christian Semmler <mail@csemmler.com>
2024-02-04 15:46:15 +01:00

1100 lines
31 KiB
C++

#include "mxdirect3d.h"
#include <stdio.h> // for vsprintf
DECOMP_SIZE_ASSERT(MxAssignedDevice, 0xe4);
DECOMP_SIZE_ASSERT(MxDirect3D, 0x894);
DECOMP_SIZE_ASSERT(MxDevice, 0x1a4);
DECOMP_SIZE_ASSERT(MxDisplayMode, 0x0c);
DECOMP_SIZE_ASSERT(MxDriver, 0x190);
DECOMP_SIZE_ASSERT(MxDeviceEnumerate, 0x14);
// FUNCTION: LEGO1 0x1009b0a0
MxDirect3D::MxDirect3D()
{
this->m_pDirect3d = NULL;
this->m_pDirect3dDevice = NULL;
this->m_unk0x88c = 0;
this->m_assignedDevice = NULL;
}
// FUNCTION: LEGO1 0x1009b140
MxDirect3D::~MxDirect3D()
{
Destroy();
}
// FUNCTION: LEGO1 0x1009b1a0
BOOL MxDirect3D::Create(
HWND hWnd,
BOOL fullscreen_1,
BOOL surface_fullscreen,
BOOL onlySystemMemory,
int width,
int height,
int bpp,
const PALETTEENTRY* pPaletteEntries,
int paletteEntryCount
)
{
BOOL success = FALSE;
BOOL ret = MxDirectDraw::Create(
hWnd,
fullscreen_1,
surface_fullscreen,
onlySystemMemory,
width,
height,
bpp,
pPaletteEntries,
paletteEntryCount
);
if (ret && CreateIDirect3D() && D3DSetMode()) {
success = TRUE;
}
if (!success) {
FUN_1009d920();
}
return success;
}
// FUNCTION: LEGO1 0x1009b210
void MxDirect3D::Destroy()
{
if (this->m_pDirect3dDevice) {
this->m_pDirect3dDevice->Release();
this->m_pDirect3dDevice = NULL;
}
if (this->m_pDirect3d) {
this->m_pDirect3d->Release();
this->m_pDirect3d = NULL;
}
if (this->m_assignedDevice) {
delete m_assignedDevice;
this->m_assignedDevice = NULL;
}
if (m_pCurrentDeviceModesList) {
m_pCurrentDeviceModesList = NULL;
}
MxDirectDraw::Destroy();
}
// FUNCTION: LEGO1 0x1009b290
void MxDirect3D::DestroyButNotDirectDraw()
{
if (this->m_pDirect3dDevice) {
this->m_pDirect3dDevice->Release();
this->m_pDirect3dDevice = NULL;
}
if (this->m_pDirect3d) {
this->m_pDirect3d->Release();
this->m_pDirect3d = NULL;
}
MxDirectDraw::DestroyButNotDirectDraw();
}
// FUNCTION: LEGO1 0x1009b2d0
BOOL MxDirect3D::CreateIDirect3D()
{
HRESULT ret = IDirect3D_QueryInterface(m_pDirectDraw, IID_IDirect3D2, (LPVOID*) &m_pDirect3d);
if (ret) {
Error("Creation of IDirect3D failed", ret);
return FALSE;
}
return TRUE;
}
// FUNCTION: LEGO1 0x1009b310
BOOL MxDirect3D::D3DSetMode()
{
if (m_assignedDevice->m_flags & MxAssignedDevice::c_hardwareMode) {
if (m_bOnlySoftRender) {
Error("Failed to place vital surfaces in video memory for hardware driver", DDERR_GENERIC);
return FALSE;
}
if (m_assignedDevice->m_desc.dpcTriCaps.dwTextureCaps & D3DPTEXTURECAPS_PERSPECTIVE) {
m_unk0x88c = FALSE;
}
else {
m_unk0x88c = TRUE;
}
DWORD bitDepth = GetZBufferBitDepth(m_assignedDevice);
if (!CreateZBuffer(DDSCAPS_VIDEOMEMORY, bitDepth)) {
return FALSE;
}
}
else {
if (m_assignedDevice->m_desc.dpcTriCaps.dwTextureCaps & D3DPTEXTURECAPS_PERSPECTIVE) {
m_unk0x88c = FALSE;
}
else {
m_unk0x88c = TRUE;
}
DWORD bitDepth = GetZBufferBitDepth(m_assignedDevice);
if (!CreateZBuffer(DDSCAPS_SYSTEMMEMORY, bitDepth)) {
return FALSE;
}
}
HRESULT result = m_pDirect3d->CreateDevice(m_assignedDevice->m_guid, m_pBackBuffer, &m_pDirect3dDevice);
if (result != DD_OK) {
Error("Create D3D device failed", result);
return FALSE;
}
MxDirectDraw::Mode mode = m_currentMode;
if (m_bFullScreen && !IsSupportedMode(mode.width, mode.height, mode.bitsPerPixel)) {
Error("This device cannot support the current display mode", DDERR_GENERIC);
return FALSE;
}
LPDIRECTDRAWSURFACE frontBuffer = m_pFrontBuffer;
LPDIRECTDRAWSURFACE backBuffer = m_pBackBuffer;
DDSURFACEDESC desc;
memset(&desc, 0, sizeof(desc));
desc.dwSize = sizeof(desc);
if (backBuffer->Lock(NULL, &desc, DDLOCK_WAIT, NULL) == DD_OK) {
unsigned char* surface = (unsigned char*) desc.lpSurface;
for (int i = mode.height; i > 0; i--) {
memset(surface, 0, mode.width * desc.ddpfPixelFormat.dwRGBBitCount / 8);
surface += desc.lPitch;
}
backBuffer->Unlock(desc.lpSurface);
}
else {
OutputDebugString("MxDirect3D::D3DSetMode() back lock failed\n");
}
if (m_bFullScreen) {
memset(&desc, 0, sizeof(desc));
desc.dwSize = sizeof(desc);
if (frontBuffer->Lock(NULL, &desc, DDLOCK_WAIT, NULL) == DD_OK) {
unsigned char* surface = (unsigned char*) desc.lpSurface;
for (int i = mode.height; i > 0; i--) {
memset(surface, 0, mode.width * desc.ddpfPixelFormat.dwRGBBitCount / 8);
surface += desc.lPitch;
}
frontBuffer->Unlock(desc.lpSurface);
}
else {
OutputDebugString("MxDirect3D::D3DSetMode() front lock failed\n");
}
}
return TRUE;
}
// FUNCTION: LEGO1 0x1009b5a0
DWORD MxDirect3D::GetZBufferBitDepth(MxAssignedDevice* p_assignedDevice)
{
DWORD bitDepth;
if (p_assignedDevice->m_desc.dwFlags & D3DDD_DEVICEZBUFFERBITDEPTH) {
bitDepth = p_assignedDevice->m_desc.dwDeviceZBufferBitDepth;
}
else {
bitDepth = 0;
}
if (bitDepth & DDBD_32) {
return 32;
}
if (bitDepth & DDBD_24) {
return 24;
}
if (bitDepth & DDBD_16) {
return 16;
}
if (bitDepth & DDBD_8) {
return 8;
}
return -1;
}
// FUNCTION: LEGO1 0x1009b5f0
BOOL MxDirect3D::SetDevice(MxDeviceEnumerate& p_deviceEnumerate, MxDriver* p_driver, MxDevice* p_device)
{
if (m_assignedDevice) {
delete m_assignedDevice;
m_assignedDevice = NULL;
m_pCurrentDeviceModesList = NULL;
}
MxAssignedDevice* assignedDevice = new MxAssignedDevice;
int i = 0;
for (list<MxDriver>::iterator it = p_deviceEnumerate.m_list.begin(); it != p_deviceEnumerate.m_list.end(); it++) {
MxDriver& driver = *it;
if (&driver == p_driver) {
assignedDevice->m_deviceInfo = new MxDirectDraw::DeviceModesInfo;
if (driver.m_guid) {
assignedDevice->m_deviceInfo->m_guid = new GUID;
memcpy(assignedDevice->m_deviceInfo->m_guid, driver.m_guid, sizeof(GUID));
}
assignedDevice->m_deviceInfo->m_count = driver.m_displayModes.size();
if (assignedDevice->m_deviceInfo->m_count > 0) {
assignedDevice->m_deviceInfo->m_modeArray =
new MxDirectDraw::Mode[assignedDevice->m_deviceInfo->m_count];
int j = 0;
for (list<MxDisplayMode>::iterator it2 = driver.m_displayModes.begin();
it2 != driver.m_displayModes.end();
it2++) {
assignedDevice->m_deviceInfo->m_modeArray[j].width = (*it2).m_width;
assignedDevice->m_deviceInfo->m_modeArray[j].height = (*it2).m_height;
assignedDevice->m_deviceInfo->m_modeArray[j].bitsPerPixel = (*it2).m_bitsPerPixel;
j++;
}
}
memcpy(
&assignedDevice->m_deviceInfo->m_ddcaps,
&driver.m_ddCaps,
sizeof(assignedDevice->m_deviceInfo->m_ddcaps)
);
if (i == 0) {
assignedDevice->m_flags |= MxAssignedDevice::c_primaryDevice;
}
for (list<MxDevice>::iterator it2 = driver.m_devices.begin(); it2 != driver.m_devices.end(); it2++) {
MxDevice& device = *it2;
if (&device != p_device) {
continue;
}
memcpy(&assignedDevice->m_guid, device.m_guid, sizeof(assignedDevice->m_guid));
D3DDEVICEDESC* desc;
if (device.m_HWDesc.dcmColorModel) {
assignedDevice->m_flags |= MxAssignedDevice::c_hardwareMode;
desc = &device.m_HWDesc;
}
else {
desc = &device.m_HELDesc;
}
memcpy(&assignedDevice->m_desc, desc, sizeof(assignedDevice->m_desc));
m_assignedDevice = assignedDevice;
m_pCurrentDeviceModesList = assignedDevice->m_deviceInfo;
break;
}
}
i++;
}
if (!m_assignedDevice) {
delete assignedDevice;
return FALSE;
}
return TRUE;
}
// FUNCTION: LEGO1 0x1009b8b0
MxAssignedDevice::MxAssignedDevice()
{
memset(this, 0, sizeof(*this));
}
// FUNCTION: LEGO1 0x1009b8d0
MxAssignedDevice::~MxAssignedDevice()
{
if (m_deviceInfo) {
delete m_deviceInfo;
m_deviceInfo = NULL;
}
}
// FUNCTION: LEGO1 0x1009ba80
MxDriver::MxDriver(LPGUID p_guid, LPSTR p_driverDesc, LPSTR p_driverName)
{
m_guid = NULL;
m_driverDesc = NULL;
m_driverName = NULL;
memset(&m_ddCaps, 0, sizeof(m_ddCaps));
Init(p_guid, p_driverDesc, p_driverName);
}
// FUNCTION: LEGO1 0x1009bb80
MxDriver::~MxDriver()
{
if (m_guid) {
delete m_guid;
}
if (m_driverDesc) {
delete[] m_driverDesc;
}
if (m_driverName) {
delete[] m_driverName;
}
}
// FUNCTION: LEGO1 0x1009bc30
void MxDriver::Init(LPGUID p_guid, LPSTR p_driverDesc, LPSTR p_driverName)
{
if (m_driverDesc) {
delete[] m_driverDesc;
m_driverDesc = NULL;
}
if (m_driverName) {
delete[] m_driverName;
m_driverName = NULL;
}
if (p_guid) {
m_guid = new GUID;
memcpy(m_guid, p_guid, sizeof(*m_guid));
}
if (p_driverDesc) {
m_driverDesc = new char[strlen(p_driverDesc) + 1];
strcpy(m_driverDesc, p_driverDesc);
}
if (p_driverName) {
m_driverName = new char[strlen(p_driverName) + 1];
strcpy(m_driverName, p_driverName);
}
}
// FUNCTION: LEGO1 0x1009bd20
MxDevice::MxDevice(
LPGUID p_guid,
LPSTR p_deviceDesc,
LPSTR p_deviceName,
LPD3DDEVICEDESC p_HWDesc,
LPD3DDEVICEDESC p_HELDesc
)
{
memset(this, 0, sizeof(*this));
Init(p_guid, p_deviceDesc, p_deviceName, p_HWDesc, p_HELDesc);
}
// FUNCTION: LEGO1 0x1009bd60
MxDevice::~MxDevice()
{
if (m_guid) {
delete m_guid;
}
if (m_deviceDesc) {
delete[] m_deviceDesc;
}
if (m_deviceName) {
delete[] m_deviceName;
}
}
// FUNCTION: LEGO1 0x1009bda0
void MxDevice::Init(
LPGUID p_guid,
LPSTR p_deviceDesc,
LPSTR p_deviceName,
LPD3DDEVICEDESC p_HWDesc,
LPD3DDEVICEDESC p_HELDesc
)
{
if (m_deviceDesc) {
delete[] m_deviceDesc;
m_deviceDesc = NULL;
}
if (m_deviceName) {
delete[] m_deviceName;
m_deviceName = NULL;
}
if (p_guid) {
m_guid = new GUID;
memcpy(m_guid, p_guid, sizeof(*m_guid));
}
if (p_deviceDesc) {
m_deviceDesc = new char[strlen(p_deviceDesc) + 1];
strcpy(m_deviceDesc, p_deviceDesc);
}
if (p_deviceName) {
m_deviceName = new char[strlen(p_deviceName) + 1];
strcpy(m_deviceName, p_deviceName);
}
if (p_HWDesc) {
memcpy(&m_HWDesc, p_HWDesc, sizeof(m_HWDesc));
}
if (p_HELDesc) {
memcpy(&m_HELDesc, p_HELDesc, sizeof(m_HELDesc));
}
}
// FUNCTION: LEGO1 0x1009bec0
MxDeviceEnumerate::MxDeviceEnumerate()
{
m_initialized = FALSE;
}
// FUNCTION: LEGO1 0x1009c070
BOOL MxDeviceEnumerate::EnumDirectDrawCallback(LPGUID p_guid, LPSTR p_driverDesc, LPSTR p_driverName)
{
MxDriver driver(p_guid, p_driverDesc, p_driverName);
m_list.push_back(driver);
// Must be zeroed because held resources are copied by pointer only
// and should not be freed at the end of this function
driver.m_guid = NULL;
driver.m_driverDesc = NULL;
driver.m_driverName = NULL;
memset(&driver.m_ddCaps, 0, sizeof(driver.m_ddCaps));
LPDIRECT3D2 lpDirect3d2 = NULL;
LPDIRECTDRAW lpDD = NULL;
MxDriver& newDevice = m_list.back();
HRESULT result = DirectDrawCreate(newDevice.m_guid, &lpDD, NULL);
if (result != DD_OK) {
BuildErrorString("DirectDraw Create failed: %s\n", EnumerateErrorToString(result));
}
else {
lpDD->EnumDisplayModes(0, NULL, this, DisplayModesEnumerateCallback);
newDevice.m_ddCaps.dwSize = sizeof(newDevice.m_ddCaps);
result = lpDD->GetCaps(&newDevice.m_ddCaps, NULL);
if (result != DD_OK) {
BuildErrorString("GetCaps failed: %s\n", EnumerateErrorToString(result));
}
else {
result = lpDD->QueryInterface(IID_IDirect3D2, (LPVOID*) &lpDirect3d2);
if (result != DD_OK) {
BuildErrorString("D3D creation failed: %s\n", EnumerateErrorToString(result));
}
else {
result = lpDirect3d2->EnumDevices(DevicesEnumerateCallback, this);
if (result != DD_OK) {
BuildErrorString("D3D enum devices failed: %s\n", EnumerateErrorToString(result));
}
else {
if (newDevice.m_devices.empty()) {
m_list.pop_back();
}
}
}
}
}
if (lpDirect3d2) {
lpDirect3d2->Release();
}
if (lpDD) {
lpDD->Release();
}
return DDENUMRET_OK;
}
// FUNCTION: LEGO1 0x1009c4c0
void MxDeviceEnumerate::BuildErrorString(const char* p_format, ...)
{
va_list args;
char buf[512];
va_start(args, p_format);
vsprintf(buf, p_format, args);
va_end(args);
OutputDebugString(buf);
}
// FUNCTION: LEGO1 0x1009c4f0
HRESULT CALLBACK MxDeviceEnumerate::DisplayModesEnumerateCallback(LPDDSURFACEDESC p_ddsd, LPVOID p_context)
{
MxDeviceEnumerate* deviceEnumerate = (MxDeviceEnumerate*) p_context;
return deviceEnumerate->EnumDisplayModesCallback(p_ddsd);
}
// FUNCTION: LEGO1 0x1009c510
HRESULT CALLBACK MxDeviceEnumerate::DevicesEnumerateCallback(
LPGUID p_guid,
LPSTR p_deviceDesc,
LPSTR p_deviceName,
LPD3DDEVICEDESC p_HWDesc,
LPD3DDEVICEDESC p_HELDesc,
LPVOID p_context
)
{
MxDeviceEnumerate* deviceEnumerate = (MxDeviceEnumerate*) p_context;
return deviceEnumerate->EnumDevicesCallback(p_guid, p_deviceDesc, p_deviceName, p_HWDesc, p_HELDesc);
}
// FUNCTION: LEGO1 0x1009c540
HRESULT MxDeviceEnumerate::EnumDisplayModesCallback(LPDDSURFACEDESC p_ddsd)
{
MxDisplayMode displayMode;
displayMode.m_width = p_ddsd->dwWidth;
displayMode.m_height = p_ddsd->dwHeight;
displayMode.m_bitsPerPixel = p_ddsd->ddpfPixelFormat.dwRGBBitCount;
m_list.back().m_displayModes.push_back(displayMode);
return DDENUMRET_OK;
}
// FUNCTION: LEGO1 0x1009c5d0
HRESULT MxDeviceEnumerate::EnumDevicesCallback(
LPGUID p_guid,
LPSTR p_deviceDesc,
LPSTR p_deviceName,
LPD3DDEVICEDESC p_HWDesc,
LPD3DDEVICEDESC p_HELDesc
)
{
MxDevice device(p_guid, p_deviceDesc, p_deviceName, p_HWDesc, p_HELDesc);
m_list.back().m_devices.push_back(device);
memset(&device, 0, sizeof(device));
return DDENUMRET_OK;
}
// FUNCTION: LEGO1 0x1009c6c0
int MxDeviceEnumerate::DoEnumerate()
{
if (m_initialized) {
return -1;
}
HRESULT ret = DirectDrawEnumerate(DirectDrawEnumerateCallback, this);
if (ret != DD_OK) {
BuildErrorString("DirectDrawEnumerate returned error %s\n", EnumerateErrorToString(ret));
return -1;
}
m_initialized = TRUE;
return 0;
}
// FUNCTION: LEGO1 0x1009c710
BOOL CALLBACK
MxDeviceEnumerate::DirectDrawEnumerateCallback(LPGUID p_guid, LPSTR p_driverDesc, LPSTR p_driverName, LPVOID p_context)
{
MxDeviceEnumerate* deviceEnumerate = (MxDeviceEnumerate*) p_context;
return deviceEnumerate->EnumDirectDrawCallback(p_guid, p_driverDesc, p_driverName);
}
// FUNCTION: LEGO1 0x1009c730
const char* MxDeviceEnumerate::EnumerateErrorToString(HRESULT p_error)
{
switch (p_error) {
case DD_OK:
return "No error.";
case DDERR_GENERIC:
return "Generic failure.";
case DDERR_UNSUPPORTED:
return "Action not supported.";
case DDERR_INVALIDPARAMS:
return "One or more of the parameters passed to the function are incorrect.";
case DDERR_OUTOFMEMORY:
return "DirectDraw does not have enough memory to perform the operation.";
case DDERR_CANNOTATTACHSURFACE:
return "This surface can not be attached to the requested surface.";
case DDERR_ALREADYINITIALIZED:
return "This object is already initialized.";
case DDERR_CURRENTLYNOTAVAIL:
return "Support is currently not available.";
case DDERR_CANNOTDETACHSURFACE:
return "This surface can not be detached from the requested surface.";
case DDERR_HEIGHTALIGN:
return "Height of rectangle provided is not a multiple of reqd alignment.";
case DDERR_EXCEPTION:
return "An exception was encountered while performing the requested operation.";
case DDERR_INVALIDCAPS:
return "One or more of the caps bits passed to the callback are incorrect.";
case DDERR_INCOMPATIBLEPRIMARY:
return "Unable to match primary surface creation request with existing primary surface.";
case DDERR_INVALIDMODE:
return "DirectDraw does not support the requested mode.";
case DDERR_INVALIDCLIPLIST:
return "DirectDraw does not support the provided cliplist.";
case DDERR_INVALIDPIXELFORMAT:
return "The pixel format was invalid as specified.";
case DDERR_INVALIDOBJECT:
return "DirectDraw received a pointer that was an invalid DIRECTDRAW object.";
case DDERR_LOCKEDSURFACES:
return "Operation could not be carried out because one or more surfaces are locked.";
case DDERR_INVALIDRECT:
return "Rectangle provided was invalid.";
case DDERR_NOALPHAHW:
return "Operation could not be carried out because there is no alpha accleration hardware present or "
"available.";
case DDERR_NO3D:
return "There is no 3D present.";
case DDERR_NOCOLORCONVHW:
return "Operation could not be carried out because there is no color conversion hardware present or available.";
case DDERR_NOCLIPLIST:
return "No cliplist available.";
case DDERR_NOCOLORKEY:
return "Surface doesn't currently have a color key";
case DDERR_NOCOOPERATIVELEVELSET:
return "Create function called without DirectDraw object method SetCooperativeLevel being called.";
case DDERR_NOEXCLUSIVEMODE:
return "Operation requires the application to have exclusive mode but the application does not have exclusive "
"mode.";
case DDERR_NOCOLORKEYHW:
return "Operation could not be carried out because there is no hardware support of the destination color key.";
case DDERR_NOGDI:
return "There is no GDI present.";
case DDERR_NOFLIPHW:
return "Flipping visible surfaces is not supported.";
case DDERR_NOTFOUND:
return "Requested item was not found.";
case DDERR_NOMIRRORHW:
return "Operation could not be carried out because there is no hardware present or available.";
case DDERR_NORASTEROPHW:
return "Operation could not be carried out because there is no appropriate raster op hardware present or "
"available.";
case DDERR_NOOVERLAYHW:
return "Operation could not be carried out because there is no overlay hardware present or available.";
case DDERR_NOSTRETCHHW:
return "Operation could not be carried out because there is no hardware support for stretching.";
case DDERR_NOROTATIONHW:
return "Operation could not be carried out because there is no rotation hardware present or available.";
case DDERR_NOTEXTUREHW:
return "Operation could not be carried out because there is no texture mapping hardware present or available.";
case DDERR_NOT4BITCOLOR:
return "DirectDrawSurface is not in 4 bit color palette and the requested operation requires 4 bit color "
"palette.";
case DDERR_NOT4BITCOLORINDEX:
return "DirectDrawSurface is not in 4 bit color index palette and the requested operation requires 4 bit color "
"index palette.";
case DDERR_NOT8BITCOLOR:
return "DirectDrawSurface is not in 8 bit color mode and the requested operation requires 8 bit color.";
case DDERR_NOZBUFFERHW:
return "Operation could not be carried out because there is no hardware support for zbuffer blitting.";
case DDERR_NOVSYNCHW:
return "Operation could not be carried out because there is no hardware support for vertical blank "
"synchronized operations.";
case DDERR_OUTOFCAPS:
return "The hardware needed for the requested operation has already been allocated.";
case DDERR_NOZOVERLAYHW:
return "Overlay surfaces could not be z layered based on their BltOrder because the hardware does not support "
"z layering of overlays.";
case DDERR_COLORKEYNOTSET:
return "No src color key specified for this operation.";
case DDERR_OUTOFVIDEOMEMORY:
return "DirectDraw does not have enough memory to perform the operation.";
case DDERR_OVERLAYCANTCLIP:
return "The hardware does not support clipped overlays.";
case DDERR_OVERLAYCOLORKEYONLYONEACTIVE:
return "Can only have ony color key active at one time for overlays.";
case DDERR_PALETTEBUSY:
return "Access to this palette is being refused because the palette is already locked by another thread.";
case DDERR_SURFACEALREADYDEPENDENT:
return "This surface is already a dependency of the surface it is being made a dependency of.";
case DDERR_SURFACEALREADYATTACHED:
return "This surface is already attached to the surface it is being attached to.";
case DDERR_SURFACEISOBSCURED:
return "Access to surface refused because the surface is obscured.";
case DDERR_SURFACEBUSY:
return "Access to this surface is being refused because the surface is already locked by another thread.";
case DDERR_SURFACENOTATTACHED:
return "The requested surface is not attached.";
case DDERR_SURFACELOST:
return "Access to this surface is being refused because the surface memory is gone. The DirectDrawSurface "
"object representing this surface should have Restore called on it.";
case DDERR_TOOBIGSIZE:
return "Size requested by DirectDraw is too large, but the individual height and width are OK.";
case DDERR_TOOBIGHEIGHT:
return "Height requested by DirectDraw is too large.";
case DDERR_UNSUPPORTEDFORMAT:
return "FOURCC format requested is unsupported by DirectDraw.";
case DDERR_TOOBIGWIDTH:
return "Width requested by DirectDraw is too large.";
case DDERR_VERTICALBLANKINPROGRESS:
return "Vertical blank is in progress.";
case DDERR_UNSUPPORTEDMASK:
return "Bitmask in the pixel format requested is unsupported by DirectDraw.";
case DDERR_XALIGN:
return "Rectangle provided was not horizontally aligned on required boundary.";
case DDERR_WASSTILLDRAWING:
return "Informs DirectDraw that the previous Blt which is transfering information to or from this Surface is "
"incomplete.";
case DDERR_INVALIDDIRECTDRAWGUID:
return "The GUID passed to DirectDrawCreate is not a valid DirectDraw driver identifier.";
case DDERR_DIRECTDRAWALREADYCREATED:
return "A DirectDraw object representing this driver has already been created for this process.";
case DDERR_NODIRECTDRAWHW:
return "A hardware-only DirectDraw object creation was attempted but the driver did not support any hardware.";
case DDERR_PRIMARYSURFACEALREADYEXISTS:
return "This process already has created a primary surface.";
case DDERR_NOEMULATION:
return "Software emulation not available.";
case DDERR_REGIONTOOSMALL:
return "Region passed to Clipper::GetClipList is too small.";
case DDERR_CLIPPERISUSINGHWND:
return "An attempt was made to set a cliplist for a clipper object that is already monitoring an hwnd.";
case DDERR_NOCLIPPERATTACHED:
return "No clipper object attached to surface object.";
case DDERR_NOHWND:
return "Clipper notification requires an HWND or no HWND has previously been set as the CooperativeLevel HWND.";
case DDERR_HWNDSUBCLASSED:
return "HWND used by DirectDraw CooperativeLevel has been subclassed, this prevents DirectDraw from restoring "
"state.";
case DDERR_HWNDALREADYSET:
return "The CooperativeLevel HWND has already been set. It can not be reset while the process has surfaces or "
"palettes created.";
case DDERR_NOPALETTEATTACHED:
return "No palette object attached to this surface.";
case DDERR_NOPALETTEHW:
return "No hardware support for 16 or 256 color palettes.";
case DDERR_BLTFASTCANTCLIP:
return "Return if a clipper object is attached to the source surface passed into a BltFast call.";
case DDERR_NOBLTHW:
return "No blitter hardware present.";
case DDERR_NODDROPSHW:
return "No DirectDraw ROP hardware.";
case DDERR_OVERLAYNOTVISIBLE:
return "Returned when GetOverlayPosition is called on a hidden overlay.";
case DDERR_NOOVERLAYDEST:
return "Returned when GetOverlayPosition is called on an overlay that UpdateOverlay has never been called on "
"to establish a destination.";
case DDERR_INVALIDPOSITION:
return "Returned when the position of the overlay on the destination is no longer legal for that destination.";
case DDERR_NOTAOVERLAYSURFACE:
return "Returned when an overlay member is called for a non-overlay surface.";
case DDERR_EXCLUSIVEMODEALREADYSET:
return "An attempt was made to set the cooperative level when it was already set to exclusive.";
case DDERR_NOTFLIPPABLE:
return "An attempt has been made to flip a surface that is not flippable.";
case DDERR_CANTDUPLICATE:
return "Can't duplicate primary & 3D surfaces, or surfaces that are implicitly created.";
case DDERR_NOTLOCKED:
return "Surface was not locked. An attempt to unlock a surface that was not locked at all, or by this "
"process, has been attempted.";
case DDERR_CANTCREATEDC:
return "Windows can not create any more DCs.";
case DDERR_NODC:
return "No DC was ever created for this surface.";
case DDERR_WRONGMODE:
return "This surface can not be restored because it was created in a different mode.";
case DDERR_IMPLICITLYCREATED:
return "This surface can not be restored because it is an implicitly created surface.";
case DDERR_NOTPALETTIZED:
return "The surface being used is not a palette-based surface.";
default:
return "Unrecognized error value.";
}
}
// FUNCTION: LEGO1 0x1009ce60
int MxDeviceEnumerate::ParseDeviceName(const char* p_deviceId)
{
if (!m_initialized) {
return -1;
}
int num = -1;
int hex[4];
if (sscanf(p_deviceId, "%d 0x%x 0x%x 0x%x 0x%x", &num, &hex[0], &hex[1], &hex[2], &hex[3]) != 5) {
return -1;
}
if (num < 0) {
return -1;
}
GUID guid;
memcpy(&guid, hex, sizeof(guid));
int result = ProcessDeviceBytes(num, guid);
if (result < 0) {
return ProcessDeviceBytes(-1, guid);
}
return result;
}
// FUNCTION: LEGO1 0x1009cf20
int MxDeviceEnumerate::ProcessDeviceBytes(int p_deviceNum, GUID& p_guid)
{
if (!m_initialized) {
return -1;
}
int i = 0;
int j = 0;
struct GUID4 {
int m_data1;
int m_data2;
int m_data3;
int m_data4;
};
static_assert(sizeof(GUID4) == sizeof(GUID), "Equal size");
GUID4 deviceGuid;
memcpy(&deviceGuid, &p_guid, sizeof(GUID4));
for (list<MxDriver>::iterator it = m_list.begin(); it != m_list.end(); it++) {
if (p_deviceNum >= 0 && p_deviceNum < i) {
return -1;
}
GUID4 compareGuid;
MxDriver& driver = *it;
for (list<MxDevice>::iterator it2 = driver.m_devices.begin(); it2 != driver.m_devices.end(); it2++) {
memcpy(&compareGuid, (*it2).m_guid, sizeof(GUID4));
if (compareGuid.m_data1 == deviceGuid.m_data1 && compareGuid.m_data2 == deviceGuid.m_data2 &&
compareGuid.m_data3 == deviceGuid.m_data3 && compareGuid.m_data4 == deviceGuid.m_data4 &&
i == p_deviceNum) {
return j;
}
j++;
}
i++;
}
return -1;
}
// FUNCTION: LEGO1 0x1009d030
int MxDeviceEnumerate::GetDevice(int p_deviceNum, MxDriver*& p_driver, MxDevice*& p_device)
{
if (p_deviceNum >= 0 && m_initialized) {
int i = 0;
for (list<MxDriver>::iterator it = m_list.begin(); it != m_list.end(); it++) {
p_driver = &*it;
for (list<MxDevice>::iterator it2 = p_driver->m_devices.begin(); it2 != p_driver->m_devices.end(); it2++) {
if (i == p_deviceNum) {
p_device = &*it2;
return 0;
}
i++;
}
}
return -1;
}
return -1;
}
// FUNCTION: LEGO1 0x1009d0d0
int MxDeviceEnumerate::FUN_1009d0d0()
{
if (!m_initialized) {
return -1;
}
if (m_list.empty()) {
return -1;
}
int i = 0;
int j = 0;
int k = -1;
int cpu_mmx = SupportsMMX();
for (list<MxDriver>::iterator it = m_list.begin();; it++) {
if (it == m_list.end()) {
return k;
}
for (list<MxDevice>::iterator it2 = (*it).m_devices.begin(); it2 != (*it).m_devices.end(); it2++) {
if ((*it2).m_HWDesc.dcmColorModel) {
return j;
}
if ((cpu_mmx && (*it2).m_HELDesc.dcmColorModel == D3DCOLOR_RGB && i == 0) ||
((*it2).m_HELDesc.dcmColorModel == D3DCOLOR_MONO && i == 0 && k < 0)) {
k = j;
}
j++;
}
i++;
}
return -1;
}
// FUNCTION: LEGO1 0x1009d1a0
int MxDeviceEnumerate::SupportsMMX()
{
int supports_mmx = SupportsCPUID();
if (supports_mmx) {
#ifdef _MSC_VER
__asm {
mov eax, 0x0 ; EAX=0: Highest Function Parameter and Manufacturer ID
#if _MSC_VER > 1100
cpuid ; Run CPUID
#else
__emit 0x0f
__emit 0xa2
#endif
mov eax, 0x1 ; EAX=1: Processor Info and Feature Bits (unused)
#if _MSC_VER > 1100
cpuid ; Run CPUID
#else
__emit 0x0f
__emit 0xa2
#endif
xor eax, eax ; Zero EAX register
bt edx, 0x17 ; Test bit 0x17 (23): MMX instructions (64-bit SIMD) (Store in CF)
adc eax, eax ; Add with carry: EAX = EAX + EAX + CF = CF
mov supports_mmx, eax ; Save eax into C variable
}
#else
__asm__("movl $0x0, %%eax\n\t" // EAX=0: Highest Function Parameter and Manufacturer ID
"cpuid\n\t" // Run CPUID\n"
"mov $0x1, %%eax\n\t" // EAX=1: Processor Info and Feature Bits (unused)
"cpuid\n\t" // Run CPUID
"xorl %%eax, %%eax\n\t" // Zero EAX register
"btl $0x15, %%edx\n\t" // Test bit 0x17 (23): MMX instructions (64-bit SIMD) (Store in CF)
"adc %%eax, %%eax" // Add with carry: EAX = EAX + EAX + CF = CF
: "=a"(supports_mmx) // supports_mmx == EAX
);
#endif
}
return supports_mmx;
}
// FUNCTION: LEGO1 0x1009d1e0
int MxDeviceEnumerate::SupportsCPUID()
{
int has_cpuid;
#ifdef _MSC_VER
__asm {
xor eax, eax ; Zero EAX register
pushfd ; Push EFLAGS register value on the stack
or dword ptr[esp], 0x200000 ; Set bit 0x200000: Able to use CPUID instruction (Pentium+)
popfd ; Write the updated value into the EFLAGS register
pushfd ; Push EFLAGS register value on the stack (again)
btr dword ptr[esp], 0x15 ; Test bit 0x15 (21) and reset (set CF)
adc eax, eax ; Add with carry: EAX = EAX + EAX + CF = CF
popfd ; Push EFLAGS register value on the stack (again, and makes sure the stack remains the same)
mov has_cpuid, eax ; Save eax into C variable
}
#else
__asm__("xorl %%eax, %%eax\n\t" // Zero EAX register
"pushfl\n\t" // Push EFLAGS register value on the stack
"orl $0x200000, (%%esp)\n\t" // Set bit 0x200000: Able to use CPUID instruction (Pentium+)
"popfl\n\t" // Write the updated value into the EFLAGS register
"pushfl\n\t" // Push EFLAGS register value on the stack (again)
"btrl $0x15, (%%esp)\n\t" // Test bit 0x15 (21) and reset (set CF)
"adc %%eax, %%eax\n\t" // Add with carry: EAX = EAX + EAX + CF = CF
"popfl" // Push EFLAGS register value on the stack (again, and makes sure the stack remains the same)
: "=a"(has_cpuid) // has_cpuid == EAX
);
#endif
return has_cpuid;
}
// FUNCTION: LEGO1 0x1009d210
int MxDeviceEnumerate::FUN_1009d210()
{
if (!m_initialized) {
return -1;
}
for (list<MxDriver>::iterator it = m_list.begin(); it != m_list.end();) {
MxDriver& driver = *it;
if (!FUN_1009d370(driver)) {
m_list.erase(it++);
}
else {
for (list<MxDevice>::iterator it2 = driver.m_devices.begin(); it2 != driver.m_devices.end();) {
MxDevice& device = *it2;
if (!FUN_1009d3d0(device)) {
driver.m_devices.erase(it2++);
}
else {
it2++;
}
}
if (driver.m_devices.empty()) {
m_list.erase(it++);
}
else {
it++;
}
}
}
return m_list.empty() ? -1 : 0;
}
// FUNCTION: LEGO1 0x1009d370
unsigned char MxDeviceEnumerate::FUN_1009d370(MxDriver& p_driver)
{
for (list<MxDisplayMode>::iterator it = p_driver.m_displayModes.begin(); it != p_driver.m_displayModes.end();
it++) {
if ((*it).m_width == 640 && (*it).m_height == 480) {
if ((*it).m_bitsPerPixel == 8 || (*it).m_bitsPerPixel == 16) {
return TRUE;
}
}
}
return FALSE;
}
// FUNCTION: LEGO1 0x1009d3d0
unsigned char MxDeviceEnumerate::FUN_1009d3d0(MxDevice& p_device)
{
if (m_list.size() <= 0) {
return FALSE;
}
if (p_device.m_HWDesc.dcmColorModel) {
return p_device.m_HWDesc.dwDeviceZBufferBitDepth & DDBD_16 && p_device.m_HWDesc.dpcTriCaps.dwTextureCaps & 1;
}
for (list<MxDevice>::iterator it = m_list.front().m_devices.begin(); it != m_list.front().m_devices.end(); it++) {
if ((&*it) == &p_device) {
return TRUE;
}
}
return FALSE;
}