/*==LICENSE==* CyanWorlds.com Engine - MMOG client, server and tools Copyright (C) 2011 Cyan Worlds, Inc. This program is free software: you can redistribute it and/or modify it under the terms of the GNU General Public License as published by the Free Software Foundation, either version 3 of the License, or (at your option) any later version. This program is distributed in the hope that it will be useful, but WITHOUT ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License for more details. You should have received a copy of the GNU General Public License along with this program. If not, see . Additional permissions under GNU GPL version 3 section 7 If you modify this Program, or any covered work, by linking or combining it with any of RAD Game Tools Bink SDK, Autodesk 3ds Max SDK, NVIDIA PhysX SDK, Microsoft DirectX SDK, OpenSSL library, Independent JPEG Group JPEG library, Microsoft Windows Media SDK, or Apple QuickTime SDK (or a modified version of those libraries), containing parts covered by the terms of the Bink SDK EULA, 3ds Max EULA, PhysX SDK EULA, DirectX SDK EULA, OpenSSL and SSLeay licenses, IJG JPEG Library README, Windows Media SDK EULA, or QuickTime SDK EULA, the licensors of this Program grant you additional permission to convey the resulting work. Corresponding Source for a non-source form of such a combination shall include the source code for the parts of OpenSSL and IJG JPEG Library used as well as that of the covered work. You can contact Cyan Worlds, Inc. by email legal@cyan.com or by snail mail at: Cyan Worlds, Inc. 14617 N Newport Hwy Mead, WA 99021 *==LICENSE==*/ //#define DYNAHEADER_CREATE_STORAGE #include "HeadSpin.h" #include "hsWindows.h" #include #include "hsG3DDeviceSelector.h" #include "hsStream.h" #include "plPipeline.h" #ifdef HS_OPEN_GL #if HS_BUILD_FOR_WIN32 #include #include #include #endif #endif /////////////////////////////////////////////////// /////////////////////////////////////////////////// /////////////////////////////////////////////////// hsG3DDeviceMode::hsG3DDeviceMode() : fWidth(0), fHeight(0), fDepth(0), fFlags(kNone) { } hsG3DDeviceMode::~hsG3DDeviceMode() { Clear(); } bool hsG3DDeviceMode::operator< (const hsG3DDeviceMode &mode) const { // Color depth overrides everything else if (fDepth < mode.GetColorDepth()) return true; // Only compare width and height if the color depth is the same else if (fDepth == mode.GetColorDepth() ) { if( fWidth < mode.GetWidth() ) return true; else if( fWidth == mode.GetWidth() && fHeight < mode.GetHeight() ) return true; } return false; } void hsG3DDeviceMode::Clear() { fFlags = kNone; fWidth = 0; fHeight = 0; fDepth = 0; fZStencilDepths.Reset(); fFSAATypes.Reset(); } void hsG3DDeviceMode::Read( hsStream* s ) { Clear(); fFlags = s->ReadLE32(); fWidth = s->ReadLE32(); fHeight = s->ReadLE32(); fDepth = s->ReadLE32(); fZStencilDepths.Reset(); uint8_t count= s->ReadByte(); while( count-- ) fZStencilDepths.Append( s->ReadLE16() ); /// Version 9 fFSAATypes.Reset(); count = s->ReadByte(); while( count-- ) fFSAATypes.Append( s->ReadByte() ); fCanRenderToCubics = s->ReadBool(); } void hsG3DDeviceMode::Write( hsStream* s ) const { s->WriteLE32(fFlags); s->WriteLE32(fWidth); s->WriteLE32(fHeight); s->WriteLE32(fDepth); uint8_t i, count = (uint8_t)fZStencilDepths.GetCount(); s->WriteByte( count ); for( i = 0; i < count; i++ ) s->WriteLE16( fZStencilDepths[ i ] ); /// Version 9 count = (uint8_t)fFSAATypes.GetCount(); s->WriteByte( count ); for( i = 0; i < count; i++ ) s->WriteByte( fFSAATypes[ i ] ); s->WriteBool( fCanRenderToCubics ); } /////////////////////////////////////////////////// /////////////////////////////////////////////////// /////////////////////////////////////////////////// hsG3DDeviceRecord::hsG3DDeviceRecord() : fFlags(kNone), fG3DDeviceType(hsG3DDeviceSelector::kDevTypeUnknown), fG3DDriverDesc(nil), fG3DDriverName(nil), fG3DDriverVersion(nil), fG3DDeviceDesc(nil), fLayersAtOnce(0), fMemoryBytes(0), fG3DHALorHEL(hsG3DDeviceSelector::kHHTypeUnknown), fZBiasRating( 0 ), fRecordVersion( kCurrRecordVersion ), fLODBiasRating( 0 ), fFogExpApproxStart( 0.0 ), fFogExp2ApproxStart( 0.0 ), fFogEndBias( 0.0 ), fMaxAnisotropicSamples( 1 ) { SetFogKneeParams( kFogExp, 0, 0 ); SetFogKneeParams( kFogExp2, 0, 0 ); } hsG3DDeviceRecord::~hsG3DDeviceRecord() { Clear(); } hsG3DDeviceRecord::hsG3DDeviceRecord(const hsG3DDeviceRecord& src) : fFlags(kNone), fG3DDeviceType(hsG3DDeviceSelector::kDevTypeUnknown), fG3DDriverDesc(nil), fG3DDriverName(nil), fG3DDriverVersion(nil), fG3DDeviceDesc(nil), fG3DHALorHEL(hsG3DDeviceSelector::kHHTypeUnknown), fZBiasRating( src.fZBiasRating ), fRecordVersion( kCurrRecordVersion ), fLODBiasRating( 0 ), fFogExpApproxStart( src.fFogExpApproxStart ), fFogExp2ApproxStart( src.fFogExp2ApproxStart ), fFogEndBias( src.fFogEndBias ), fMaxAnisotropicSamples( src.fMaxAnisotropicSamples ) { *this = src; } hsG3DDeviceRecord& hsG3DDeviceRecord::operator=(const hsG3DDeviceRecord& src) { fFlags = src.fFlags; SetG3DDeviceType(src.GetG3DDeviceType()); SetG3DHALorHEL(src.GetG3DHALorHEL()); SetDriverDesc(src.GetDriverDesc()); SetDriverName(src.GetDriverName()); SetDriverVersion(src.GetDriverVersion()); SetDeviceDesc(src.GetDeviceDesc()); fCaps = src.fCaps; fLayersAtOnce = src.fLayersAtOnce; fMemoryBytes = src.fMemoryBytes; fZBiasRating = src.fZBiasRating; fLODBiasRating = src.fLODBiasRating; fFogExpApproxStart = src.fFogExpApproxStart; fFogExp2ApproxStart = src.fFogExp2ApproxStart; fFogEndBias = src.fFogEndBias; fModes.SetCount(src.fModes.GetCount()); int i; for( i = 0; i < fModes.GetCount(); i++ ) fModes[i] = src.fModes[i]; fFogKnees[ 0 ] = src.fFogKnees[ 0 ]; fFogKnees[ 1 ] = src.fFogKnees[ 1 ]; fFogKneeVals[ 0 ] = src.fFogKneeVals[ 0 ]; fFogKneeVals[ 1 ] = src.fFogKneeVals[ 1 ]; fAASetting = src.fAASetting; fMaxAnisotropicSamples = src.fMaxAnisotropicSamples; return *this; } void hsG3DDeviceRecord::SetDriverDesc( const char *s ) { delete [] fG3DDriverDesc; fG3DDriverDesc = s ? hsStrcpy(s) : nil; } void hsG3DDeviceRecord::SetDriverName( const char *s ) { delete [] fG3DDriverName; fG3DDriverName = s ? hsStrcpy(s) : nil; } void hsG3DDeviceRecord::SetDriverVersion( const char *s ) { delete [] fG3DDriverVersion; fG3DDriverVersion = s ? hsStrcpy(s) : nil; } void hsG3DDeviceRecord::SetDeviceDesc( const char *s ) { delete [] fG3DDeviceDesc; fG3DDeviceDesc = s ? hsStrcpy(s) : nil; } const char* hsG3DDeviceRecord::GetG3DDeviceTypeName() const { static const char* deviceNames[hsG3DDeviceSelector::kNumDevTypes] = { "Unknown", "Glide", "Direct3D", "OpenGL" }; uint32_t devType = GetG3DDeviceType(); if( devType > hsG3DDeviceSelector::kNumDevTypes ) devType = hsG3DDeviceSelector::kDevTypeUnknown; return deviceNames[devType]; } void hsG3DDeviceRecord::RemoveDiscarded() { int i; for( i = 0; i < fModes.GetCount(); ) { if( fModes[i].GetDiscarded() ) { fModes[i].Clear(); fModes.Remove(i); } else i++; } if( !fModes.GetCount() ) SetDiscarded(true); } void hsG3DDeviceRecord::ClearModes() { int i; for( i = 0; i < fModes.GetCount(); i++ ) fModes[i].Clear(); fModes.Reset(); } void hsG3DDeviceRecord::Clear() { fFlags = kNone; delete [] fG3DDriverDesc; fG3DDriverDesc = nil; delete [] fG3DDriverName; fG3DDriverName = nil; delete [] fG3DDriverVersion; fG3DDriverVersion = nil; delete [] fG3DDeviceDesc; fG3DDeviceDesc = nil; fCaps.Clear(); fLayersAtOnce = 0; int i; for( i = 0; i < fModes.GetCount(); i++ ) fModes[i].Clear(); fModes.Reset(); fZBiasRating = 0; fLODBiasRating = 0; fFogExpApproxStart = 0; fFogExp2ApproxStart = 0; fFogEndBias = 0; SetFogKneeParams( kFogExp, 0, 0 ); SetFogKneeParams( kFogExp2, 0, 0 ); fAASetting = 0; fMaxAnisotropicSamples = 1; } //// Read ///////////////////////////////////////////////////////////////////// // 9.6.2000 mcn - Updated to reflect version 2 format // 9.8.2000 mcn - (temporary?) set to invalid on old (<2) versions void hsG3DDeviceRecord::Read(hsStream* s) { Clear(); /// Read version fRecordVersion = s->ReadLE32(); hsAssert( fRecordVersion <= kCurrRecordVersion, "Invalid version number in hsG3DDeviceRecord::Read()" ); if( fRecordVersion == kCurrRecordVersion ) { fFlags = s->ReadLE32(); } else { SetInvalid(); return; // fFlags = fRecordVersion; // fRecordVersion = 1; // hsStatusMessage( "WARNING: Old version of hsG3DDeviceRecord found. Attempting to read." ); } /// Now read everything else in as normal fG3DDeviceType = s->ReadLE32(); int len; len = s->ReadLE32(); fG3DDriverDesc = new char[len + 1]; s->Read(len, fG3DDriverDesc); fG3DDriverDesc[len] = 0; len = s->ReadLE32(); fG3DDriverName = new char[len + 1]; s->Read(len, fG3DDriverName); fG3DDriverName[len] = 0; len = s->ReadLE32(); fG3DDriverVersion = new char[len + 1]; s->Read(len, fG3DDriverVersion); fG3DDriverVersion[len] = 0; len = s->ReadLE32(); fG3DDeviceDesc = new char[len + 1]; s->Read(len, fG3DDeviceDesc); fG3DDeviceDesc[len] = 0; fCaps.Read(s); fLayersAtOnce = s->ReadLE32(); fMemoryBytes = s->ReadLE32(); len = s->ReadLE32(); fModes.SetCount(len); int i; for( i = 0; i < len; i++ ) fModes[i].Read( s ); /// Version 3 stuff fZBiasRating = s->ReadLEFloat(); fLODBiasRating = s->ReadLEFloat(); fFogExpApproxStart = s->ReadLEFloat(); fFogExp2ApproxStart = s->ReadLEFloat(); fFogEndBias = s->ReadLEFloat(); /// Version 7 stuff float knee, kneeVal; knee = s->ReadLEFloat(); kneeVal = s->ReadLEFloat(); SetFogKneeParams( kFogExp, knee, kneeVal ); knee = s->ReadLEFloat(); kneeVal = s->ReadLEFloat(); SetFogKneeParams( kFogExp2, knee, kneeVal ); /// Version 9 stuff fAASetting = s->ReadByte(); /// Version A stuff fMaxAnisotropicSamples = s->ReadByte(); /// Reset record version now fRecordVersion = kCurrRecordVersion; } void hsG3DDeviceRecord::Write(hsStream* s) const { s->WriteLE32( fRecordVersion ); s->WriteLE32(fFlags); s->WriteLE32(fG3DDeviceType); int len; len = strlen(fG3DDriverDesc); s->WriteLE32(len); s->Write(len, fG3DDriverDesc); len = strlen(fG3DDriverName); s->WriteLE32(len); s->Write(len, fG3DDriverName); len = strlen(fG3DDriverVersion); s->WriteLE32(len); s->Write(len, fG3DDriverVersion); len = strlen(fG3DDeviceDesc); s->WriteLE32(len); s->Write(len, fG3DDeviceDesc); fCaps.Write(s); s->WriteLE32(fLayersAtOnce); s->WriteLE32(fMemoryBytes); s->WriteLE32(fModes.GetCount()); int i; for( i = 0; i < fModes.GetCount(); i++ ) fModes[i].Write( s ); /// Version 3 data s->WriteLEFloat( fZBiasRating ); s->WriteLEFloat( fLODBiasRating ); s->WriteLEFloat( fFogExpApproxStart ); s->WriteLEFloat( fFogExp2ApproxStart ); s->WriteLEFloat( fFogEndBias ); /// Version 7 data s->WriteLEFloat( fFogKnees[ kFogExp ] ); s->WriteLEFloat( fFogKneeVals[ kFogExp ] ); s->WriteLEFloat( fFogKnees[ kFogExp2 ] ); s->WriteLEFloat( fFogKneeVals[ kFogExp2 ] ); /// Version 9 data s->WriteByte( fAASetting ); /// Version A stuff s->WriteByte( fMaxAnisotropicSamples ); } /////////////////////////////////////////////////// /////////////////////////////////////////////////// /////////////////////////////////////////////////// hsG3DDeviceModeRecord::hsG3DDeviceModeRecord(const hsG3DDeviceRecord& devRec, const hsG3DDeviceMode& devMode) : fDevice(devRec), fMode(devMode) { } hsG3DDeviceModeRecord::hsG3DDeviceModeRecord() { } hsG3DDeviceModeRecord::~hsG3DDeviceModeRecord() { } hsG3DDeviceModeRecord::hsG3DDeviceModeRecord(const hsG3DDeviceModeRecord& src) { *this = src; } hsG3DDeviceModeRecord& hsG3DDeviceModeRecord::operator=(const hsG3DDeviceModeRecord& src) { fDevice = src.fDevice; fMode = src.fMode; return *this; } /////////////////////////////////////////////////// /////////////////////////////////////////////////// /////////////////////////////////////////////////// hsG3DDeviceSelector::hsG3DDeviceSelector() { } hsG3DDeviceSelector::~hsG3DDeviceSelector() { Clear(); } void hsG3DDeviceSelector::RemoveDiscarded() { int i; for( i = 0; i < fRecords.GetCount(); ) { fRecords[i].RemoveDiscarded(); if( fRecords[i].GetDiscarded() ) { fRecords[i].Clear(); fRecords.Remove(i); } else i++; } } void hsG3DDeviceSelector::Clear() { int i; for( i = 0; i < fRecords.GetCount(); i++ ) fRecords[i].Clear(); fRecords.Reset(); } void hsG3DDeviceSelector::RemoveUnusableDevModes(bool bTough) { plDemoDebugFile::Write( "Removing unusable devices and modes..." ); for (int i = 0; i < fRecords.GetCount(); i++) { // // Remove modes // hsTArray& modes = fRecords[i].GetModes(); for (int j = 0; j < modes.GetCount(); j++) { // Remove windowed modes if ((modes[j].GetWidth() == 0) && (modes[j].GetHeight() == 0) && (modes[j].GetColorDepth() == 0)) { plDemoDebugFile::Write( " Removing windowed mode on ", (char *)fRecords[ i ].GetDriverDesc() ); modes[j].SetDiscarded(true); } // If tough, remove modes less than 640x480 else if (bTough && ((modes[j].GetWidth() < 640) || (modes[j].GetHeight() < 480))) { plDemoDebugFile::Write( " Removing mode < 640x480 on ", (char *)fRecords[ i ].GetDriverDesc() ); modes[j].SetDiscarded(true); } else { plString log = plString::Format(" Keeping mode (%dx%d) on device %s", modes[j].GetWidth(), modes[j].GetHeight(), fRecords[ i ].GetDriverDesc()); plDemoDebugFile::Write( log.c_str() ); } } // // Remove devices // if (fRecords[i].GetG3DDeviceType() == hsG3DDeviceSelector::kDevTypeUnknown) { plDemoDebugFile::Write( " Removing unknown device. Description", (char *)fRecords[ i ].GetDriverDesc() ); fRecords[i].SetDiscarded(true); } else if( fRecords[i].GetG3DDeviceType() == hsG3DDeviceSelector::kDevTypeDirect3D || fRecords[i].GetG3DDeviceType() == hsG3DDeviceSelector::kDevTypeDirect3DTnL ) { uint32_t totalMem; char devDesc[ 256 ]; // For our 3dfx test later strncpy( devDesc, fRecords[i].GetDriverDesc(), sizeof( devDesc ) - 1 ); hsStrLower( devDesc ); // Remove software Direct3D devices if ((fRecords[i].GetG3DHALorHEL() != hsG3DDeviceSelector::kHHD3DHALDev) && (fRecords[i].GetG3DHALorHEL() != hsG3DDeviceSelector::kHHD3DTnLHalDev) && (fRecords[i].GetG3DHALorHEL() != hsG3DDeviceSelector::kHHD3D3dfxDev) && (fRecords[i].GetG3DHALorHEL() != hsG3DDeviceSelector::kHHD3D3dfxVoodoo5Dev) #ifdef HS_ALLOW_D3D_REF_DRIVER && (fRecords[i].GetG3DHALorHEL() != hsG3DDeviceSelector::kHHD3DRefDev) #endif ) { plDemoDebugFile::Write( " Removing software Direct3D device. Description", (char *)fRecords[ i ].GetDriverDesc() ); fRecords[i].SetDiscarded(true); } // Remove 3Dfx Direct3D devices, take 2 // 10.13.2000 mcn - Now we do it even when we're wimpy // 10.25.2000 mcn - Think again. // 11.3.2000 mcn - Shesh, is this EVER going to be stable?? else if( bTough && fRecords[i].GetG3DHALorHEL() == hsG3DDeviceSelector::kHHD3D3dfxDev ) // else if( bTough && ( strstr( devDesc, "3dfx" ) || strstr( devDesc, "voodoo" ) ) ) { plDemoDebugFile::Write( " Removing 3Dfx non-Voodoo5 Direct3D device (We only support Glide on 3Dfx). Description", (char *)fRecords[ i ].GetDriverDesc() ); fRecords[i].SetDiscarded(true); } // Remove Direct3D devices with less than 11 megs of RAM else if (bTough && ( totalMem = IAdjustDirectXMemory( fRecords[i].GetMemoryBytes() ) ) < 11*1024*1024 ) { plString log = plString::Format(" Removing Direct3D device with < 11MB RAM. Device RAM (in kB): %d (Description: %s)", totalMem / 1024, fRecords[ i ].GetDriverDesc() ); plDemoDebugFile::Write( log.c_str() ); fRecords[i].SetDiscarded(true); } else { if( fRecords[i].GetG3DDeviceType() == hsG3DDeviceSelector::kDevTypeDirect3DTnL ) plDemoDebugFile::Write( " Keeping DX8 Direct3D device", (char *)fRecords[ i ].GetDriverDesc() ); else plDemoDebugFile::Write( " Keeping Direct3D device", (char *)fRecords[ i ].GetDriverDesc() ); } } else plDemoDebugFile::Write( " Keeping device", (char *)fRecords[ i ].GetDriverDesc() ); } RemoveDiscarded(); } //// IAdjustDirectXMemory ///////////////////////////////////////////////////// // Adjusts the number coming off of the DirectX caps for "total video memory" // to be more reflective of what is really on the board. According to // Microsoft, the best way to do this is to add in the memory necessary for // the entire desktop. Okay, whatever... uint32_t hsG3DDeviceSelector::IAdjustDirectXMemory( uint32_t cardMem ) { #if HS_BUILD_FOR_WIN32 HDC deskDC; int width, height, bpp, total; deskDC = GetDC( nil ); width = GetDeviceCaps( deskDC, HORZRES ); height = GetDeviceCaps( deskDC, VERTRES ); bpp = GetDeviceCaps( deskDC, BITSPIXEL ); total = width * height; if( bpp > 8 ) total *= ( bpp >> 3 ); return cardMem + total; #else return cardMem; #endif } bool hsG3DDeviceSelector::Init( void ) { // See if we're all capable of initing if( !IInitDirect3D() ) { return false; } return true; } void hsG3DDeviceSelector::Enumerate(hsWinRef winRef) { Clear(); #ifdef HS_BUILD_FOR_WIN32 /// 9.6.2000 - Create the class to use as our temporary window class WNDCLASS tempClass; strcpy( fTempWinClass, "DSTestClass" ); memset( &tempClass, 0, sizeof( tempClass ) ); tempClass.lpfnWndProc = DefWindowProc; tempClass.hInstance = GetModuleHandle( nil ); tempClass.hbrBackground = (HBRUSH)GetStockObject( BLACK_BRUSH ); tempClass.lpszClassName = fTempWinClass; uint16_t ret = RegisterClass(&tempClass); hsAssert(ret, "Cannot create temporary window class to test for device modes" ); #endif /// Now try our devices #ifdef HS_SELECT_DX7 ITryDirect3D(winRef); #endif // HS_SELECT_DX7 ITryDirect3DTnL(winRef); // ITryOpenGL(winRef); #ifdef HS_BUILD_FOR_WIN32 /// Get rid of the class UnregisterClass( fTempWinClass, GetModuleHandle( nil ) ); #endif } bool hsG3DDeviceSelector::GetDefault (hsG3DDeviceModeRecord *dmr) { int32_t iTnL, iD3D, iOpenGL, device, mode, i; device = iTnL = iD3D = iOpenGL = mode = -1; if (device == -1) { // Get an index for any 3D devices for (i = 0; i < fRecords.GetCount(); i++) { switch (fRecords[i].GetG3DDeviceType()) { case kDevTypeDirect3D: case kDevTypeDirect3DTnL: if (fRecords[i].GetG3DHALorHEL() == kHHD3DTnLHalDev) { if (iTnL == -1 #ifndef PLASMA_EXTERNAL_RELEASE || plPipeline::fInitialPipeParams.ForceSecondMonitor #endif // PLASMA_EXTERNAL_RELEASE ) { iTnL = i; } } else if (fRecords[i].GetG3DHALorHEL() == kHHD3DHALDev || fRecords[i].GetG3DHALorHEL() == kHHD3D3dfxVoodoo5Dev ) { if (iD3D == -1 #ifndef PLASMA_EXTERNAL_RELEASE || plPipeline::fInitialPipeParams.ForceSecondMonitor #endif // PLASMA_EXTERNAL_RELEASE ) { iD3D = i; } } break; case kDevTypeOpenGL: if (iOpenGL == -1 #ifndef PLASMA_EXTERNAL_RELEASE || plPipeline::fInitialPipeParams.ForceSecondMonitor #endif // PLASMA_EXTERNAL_RELEASE ) { iOpenGL = i; } break; } } // Pick a default device (Priority D3D T&L, D3D HAL, OpenGL) if (iTnL != -1) device = iTnL; else if (iD3D != -1) device = iD3D; else if (iOpenGL != -1) device = iOpenGL; else return false; } // // Try and find the default mode // hsTArray& modes = fRecords[device].GetModes(); // If there are no modes (for some insane reason), fail if (modes.GetCount() == 0) return false; for (i = 0; i < modes.GetCount(); i++) { if ((modes[i].GetWidth() == kDefaultWidth) && (modes[i].GetHeight() == kDefaultHeight) && (modes[i].GetNumZStencilDepths() > 0)) { // Don't be too picky about the depth, use what's available if the // default isn't found. if (mode == -1 || modes[mode].GetColorDepth() != kDefaultDepth) mode = i; } } // Default mode not found, what kind of card is this?! // Regardless, just use the first mode since this isn't a fatal error. if (mode == -1) mode = 0; *dmr = hsG3DDeviceModeRecord(fRecords[device], modes[mode]); return true; } //// ITryOpenGL /////////////////////////////////////////////////////////////// // Updated 8.24.2000 mcn to (hopefully) detect OpenGL drivers. void hsG3DDeviceSelector::ITryOpenGL(hsWinRef winRef) { #ifdef HS_OPEN_GL #if HS_BUILD_FOR_WIN32 int i, numDrivers; int modeRes[ 6 ][ 3 ] = { { 640, 480, 16 }, { 800, 600, 16 }, { 1024, 768, 16 }, { 1152, 864, 16 }, { 1280, 1024, 16 }, { 1600, 1200, 16 } }; gls_driver_info driverInfo; hsG3DDeviceRecord devRec; hsG3DDeviceMode devMode; char str[ 128 ]; HDC hDC; HGLRC tempContext; HWND testWindow = nil, testWindow2 = nil; WINDOWPLACEMENT oldWindowPlace; /// Save old window position oldWindowPlace.length = sizeof( oldWindowPlace ); GetWindowPlacement( (HWND)winRef, &oldWindowPlace ); /// Use the GLS API to get us a list of all OpenGL drivers available on /// this system and their capabilities numDrivers = glsGetNumberOfDrivers(); for( i = 0; i < numDrivers; i++ ) { /// Get main driver info glsGetDriverInfo( i, &driverInfo ); devRec.SetG3DDeviceType( kDevTypeOpenGL ); devRec.SetDriverDesc( driverInfo.aDriverDescription ); devRec.SetDriverName( driverInfo.GLDriver.aDriverFilePath ); sprintf( str, "%d.%d", driverInfo.GLDriver.DriverFileVersionHigh, driverInfo.GLDriver.DriverFileVersionLow ); devRec.SetDriverVersion( str ); devRec.SetCap( kCapsMipmap ); devRec.SetCap( kCapsMipmap ); devRec.SetCap( kCapsPerspective ); if( driverInfo.DriverFlags & GLS_FLAGS_FULLSCREEN_ONLY ) devRec.SetCap( kCapsNoWindow ); if( !( driverInfo.DriverFlags & GLS_FLAGS_SOFTWARE_ONLY ) ) devRec.SetCap( kCapsHardware ); devRec.SetCap( kCapsDoesSmallTextures ); /// We have a problem here--OpenGL has no way of detecting the rest of /// the information we want, so we'll have to guess/kludge on most of it. glsLoadDriver( i ); sprintf( str, "ITryOpenGL(): FOUND OpenGL Driver: %s (%s)\n", driverInfo.aDriverDescription, driverInfo.GLDriver.aDriverFilePath ); hsStatusMessage( str ); /// (and of COURSE we have to open a bloody rendering context for /// glGetString to work...whose bright idea was THAT?) testWindow = CreateWindowEx( WS_EX_APPWINDOW, fTempWinClass, "OpenGL Screen Test Window", WS_POPUP | WS_CLIPSIBLINGS | WS_CLIPCHILDREN | WS_VISIBLE, 0, 0, 640, 480, nil, nil, GetModuleHandle( nil ), 0 ); hDC = GetDC( testWindow ); tempContext = (HGLRC)ICreateTempOpenGLContext( hDC, driverInfo.DriverFlags & GLS_FLAGS_FULLSCREEN_ONLY ); if( tempContext != nil ) { wglMakeCurrent( hDC, tempContext ); IGetExtOpenGLInfo( devRec ); /// Reset everything back now wglMakeCurrent( nil, nil ); wglDeleteContext( tempContext ); ReleaseDC( testWindow, hDC ); } /// Resize window to hide what we're about to do SetWindowPos( testWindow, nil, 0, 0, 1600, 1200, SWP_NOZORDER | SWP_NOMOVE ); /// Check for windowed screen mode (which SOMEBODY decided to test for /// bitdepth of 0 instead of the caps flag we're setting....hmmmm wasn't me....) if( !( driverInfo.DriverFlags & GLS_FLAGS_FULLSCREEN_ONLY ) ) { devMode.Clear(); devMode.SetWidth( 0 ); devMode.SetHeight( 0 ); devMode.SetColorDepth( 0 ); devRec.GetModes().Append( devMode ); } /// Go get the screen modes IGetOpenGLModes( devRec, driverInfo.aDriverDescription ); /// Get rid of the window now DestroyWindow( testWindow ); /// Unload this driver now glsUnloadDriver(); } /// Restore old window position SetWindowPlacement( (HWND)winRef, &oldWindowPlace ); #endif #endif } //// IGetOpenGLModes ////////////////////////////////////////////////////////// // Scans through all the possible imaginable combinations of screen modes, // pixel formats whatnot and adds the final, culled-down list of graphics // modes to the given device record. void hsG3DDeviceSelector::IGetOpenGLModes( hsG3DDeviceRecord &devRec, char *driverName ) { #ifdef HS_OPEN_GL #if HS_BUILD_FOR_WIN32 int j; int maxMode, mode; int modeRes[ 6 ][ 3 ] = { { 640, 480, 16 }, { 800, 600, 16 }, { 1024, 768, 16 }, { 1152, 864, 16 }, { 1280, 1024, 16 }, { 1600, 1200, 16 } }; int bitDepths[ 3 ] = { 32, 24, 16 }, bitDepth; hsG3DDeviceMode devMode; DEVMODE modeInfo; HWND testWindow = nil, testWindow2 = nil; char str[ 128 ]; /// Find the maximum resolution that we can support on this monitor--then /// we'll start there and work down until we find a mode supported by OpenGL modeInfo.dmSize = sizeof( modeInfo ); maxMode = -1; for( j = 0; EnumDisplaySettings( nil, j, &modeInfo ) != 0; j++ ) { for( mode = 0; mode < sizeof( modeRes ) / sizeof( modeRes[ 0 ] ); mode++ ) { if( modeRes[ mode ][ 0 ] == modeInfo.dmPelsWidth && modeRes[ mode ][ 1 ] == modeInfo.dmPelsHeight ) { if( modeInfo.dmBitsPerPel > modeRes[ mode ][ 2 ] ) modeRes[ mode ][ 2 ] = modeInfo.dmBitsPerPel; if( mode > maxMode ) { maxMode = mode; break; } } } } if( maxMode != -1 ) { /// Outer loop: loop through color depths for( bitDepth = 0; bitDepth < 3; bitDepth++ ) { /// Loop through each of the display settings, starting at /// the maxMode and going down, happily get pixel formats for each modeInfo.dmSize = sizeof( modeInfo ); modeInfo.dmFields = DM_PELSWIDTH | DM_PELSHEIGHT | DM_BITSPERPEL; for( mode = maxMode; mode >= 0; mode-- ) { /// Does this resolution work at this bit depth? if( modeRes[ mode ][ 2 ] < bitDepths[ bitDepth ] ) continue; /// Attempt to set this screen mode modeInfo.dmPelsWidth = modeRes[ mode ][ 0 ]; modeInfo.dmPelsHeight = modeRes[ mode ][ 1 ]; modeInfo.dmBitsPerPel = bitDepths[ bitDepth ]; if( ChangeDisplaySettings( &modeInfo, CDS_FULLSCREEN ) == DISP_CHANGE_SUCCESSFUL ) { if( ITestOpenGLRes( modeRes[ mode ][ 0 ], modeRes[ mode ][ 1 ], bitDepths[ bitDepth ], devRec, driverName ) ) { /// Go and add the rest of 'em (we just assume that we can get /// lower resolutions if we got this one) for( mode--; mode >= 0; mode-- ) { devMode.SetWidth( modeRes[ mode ][ 0 ] ); devMode.SetHeight( modeRes[ mode ][ 1 ] ); devMode.SetColorDepth( bitDepths[ bitDepth ] ); devRec.GetModes().Append( devMode ); sprintf( str, "ITryOpenGL(): Assuming mode: %dx%dx%dbpp, %s\n", modeRes[ mode ][ 0 ], modeRes[ mode ][ 1 ], bitDepths[ bitDepth ], driverName ); hsStatusMessage( str ); } } } } } /// Note: this will also reset the screen after any mode changes from /// creating our context ChangeDisplaySettings( nil, 0 ); if( devRec.GetModes().GetCount() ) fRecords.Append( devRec ); } #endif #endif } //// ITestOpenGLRes /////////////////////////////////////////////////////////// // Tests all the possible OpenGL settings once the screen has been set // to a given test resolution. bool hsG3DDeviceSelector::ITestOpenGLRes( int width, int height, int bitDepth, hsG3DDeviceRecord &devRec, char *driverName ) { bool retValue = false; #ifdef HS_OPEN_GL #if HS_BUILD_FOR_WIN32 int j, bitDepthFlags, myBitDepth; hsG3DDeviceMode devMode; char str[ 128 ]; HDC hDC, hDC2; HGLRC tempContext; HWND testWindow = nil, testWindow2 = nil; PIXELFORMATDESCRIPTOR pfd; /// Create test window #1 testWindow = CreateWindowEx( WS_EX_APPWINDOW, fTempWinClass, "OpenGL Screen Test Window", WS_POPUP | WS_CLIPSIBLINGS | WS_CLIPCHILDREN | WS_VISIBLE, 0, 0, width, height, nil, nil, GetModuleHandle( nil ), 0 ); hDC = GetDC( testWindow ); /// Loop through using DescribePixelFormat in an attempt to find all the /// pixel formats we actually do support using this OpenGL driver devMode.Clear(); pfd.nSize = sizeof( pfd ); bitDepthFlags = 0; for( j = 1; retValue == false && DescribePixelFormat( hDC, j, sizeof( pfd ), &pfd ) != 0; j++ ) { /// Can we use this one? if( pfd.cColorBits != bitDepth ) continue; myBitDepth = ( pfd.cColorBits == 32 ) ? 0x04 : ( pfd.cColorBits == 24 ) ? 0x02 : 0x01; if( ( pfd.dwFlags & PFD_SUPPORT_OPENGL ) && ( pfd.dwFlags & PFD_DRAW_TO_WINDOW ) && ( pfd.dwFlags & PFD_DOUBLEBUFFER ) && ( pfd.iPixelType == PFD_TYPE_RGBA ) && ( pfd.iLayerType == PFD_MAIN_PLANE ) && ( ( bitDepthFlags & myBitDepth ) == 0 ) ) { /// Looks like it! But is it REALLY? testWindow2 = CreateWindowEx( WS_EX_APPWINDOW, fTempWinClass, "OpenGL Screen Test Window #2", WS_POPUP | WS_CLIPSIBLINGS | WS_CLIPCHILDREN | WS_VISIBLE, 0, 0, width, height, nil, nil, GetModuleHandle( nil ), 0 ); hDC2 = GetDC( testWindow2 ); if( SetPixelFormat( hDC2, j, &pfd ) ) { tempContext = wglCreateContext( hDC2 ); if( tempContext != nil ) { if( wglMakeCurrent( hDC2, tempContext ) ) { /// Guess it really does work... devMode.SetWidth( width ); devMode.SetHeight( height ); devMode.SetColorDepth( pfd.cColorBits ); devRec.GetModes().Append( devMode ); bitDepthFlags |= myBitDepth; sprintf( str, "ITryOpenGL(): Adding mode: %dx%dx%dbpp, %s\n", width, height, pfd.cColorBits, driverName ); hsStatusMessage( str ); wglMakeCurrent( nil, nil ); retValue = true; /// Break us out } wglDeleteContext( tempContext ); } } ReleaseDC( testWindow2, hDC2 ); DestroyWindow( testWindow2 ); } } ReleaseDC( testWindow, hDC ); DestroyWindow( testWindow ); #endif #endif return retValue; } //// IGetExtOpenGLInfo //////////////////////////////////////////////////////// // Gets extended info--i.e. info requiring an OpenGL context. Assumes the // said context is already created and active. void hsG3DDeviceSelector::IGetExtOpenGLInfo( hsG3DDeviceRecord &devRec ) { #ifdef HS_OPEN_GL #if HS_BUILD_FOR_WIN32 GLint numTMUs; char *extString, *c, *c2; char str[ 128 ]; int j; if( ( extString = (char *)glGetString( GL_RENDERER ) ) != nil ) { devRec.SetDeviceDesc( extString ); /// Can we guess at the amount of texture memory? c = strstr( extString, "MB" ); if( c != nil && c != extString && ( isdigit( *( c - 1 ) ) || isspace( *( c - 1 ) ) ) ) { /// Looks like we found a "xxMB" texture memory specification--use it /// as our guess c2 = c; do { c2--; } while( c2 >= extString && ( isdigit( *c2 ) || isspace( *c2 ) ) ); c2++; strncpy( str, c2, (uint32_t)c - (uint32_t)c2 ); j = atoi( str ); sprintf( str, "ITryOpenGL(): Device has %d MB texture memory\n", j ); hsStatusMessage( str ); j *= 1024 * 1024; /// Translate to bytes devRec.SetMemoryBytes( j ); } else { devRec.SetMemoryBytes( 4 * 1024 * 1024 ); hsStatusMessage( "ITryOpenGL(): WARNING: Cannot determine texture memory for this card, assuming 4MB\n" ); } } else { devRec.SetDeviceDesc( "" ); devRec.SetMemoryBytes( 4 * 1024 * 1024 ); hsStatusMessage( "ITryOpenGL(): WARNING: Cannot determine texture memory for this card, assuming 4MB\n" ); } if( ( extString = (char *)glGetString( GL_EXTENSIONS ) ) != nil ) { /// For the number of TMUs, we'll detect for the availability of the /// multitexture extension--if it's there, we'll assume we have two TMUs /// (if we don't, OpenGL will probably handle it for us--or rather, it BETTER). if( strstr( extString, "ARB_multitexture" ) ) devRec.SetLayersAtOnce( 2 ); else devRec.SetLayersAtOnce( 1 ); /// Can we use compressed textures? if( strstr( extString, "ARB_texture_compression" ) ) devRec.SetCap( kCapsCompressTextures ); } /// Get TMU count glGetIntegerv( GL_MAX_TEXTURE_UNITS_ARB, &numTMUs ); if( numTMUs <= 0 ) numTMUs = 0; devRec.SetLayersAtOnce( numTMUs ); #endif #endif } //// ICreateTempOpenGLContext ///////////////////////////////////////////////// // Creates a temporary context for testing OpenGL stuff with. #ifdef HS_OPEN_GL #if HS_BUILD_FOR_WIN32 uint32_t hsG3DDeviceSelector::ICreateTempOpenGLContext( HDC hDC, bool32 makeItFull ) { DEVMODE modeInfo; int pixFmt; if( makeItFull ) { /// Attempt resolution change to 640x480x32bpp memset( &modeInfo, 0, sizeof( modeInfo ) ); modeInfo.dmSize = sizeof( modeInfo ); modeInfo.dmBitsPerPel = 16; modeInfo.dmPelsWidth = 640; modeInfo.dmPelsHeight = 480; if( ChangeDisplaySettings( &modeInfo, CDS_FULLSCREEN ) != DISP_CHANGE_SUCCESSFUL ) { return nil; /// We want fullscreen, can't get it, oops. } } /// Now try to set a pixel format PIXELFORMATDESCRIPTOR pfd = { sizeof(PIXELFORMATDESCRIPTOR), // size of this pfd 1, // version number PFD_DRAW_TO_WINDOW | // support window PFD_SUPPORT_OPENGL | // support OpenGL PFD_DOUBLEBUFFER, // double buffered PFD_TYPE_RGBA, // RGBA type 16, // 24-bit color depth 0, 0, 0, 0, 0, 0, // color bits ignored 0, // no alpha buffer 0, // shift bit ignored 0, // no accumulation buffer 0, 0, 0, 0, // accum bits ignored 0, // 32-bit z-buffer 0, // no stencil buffer 0, // no auxiliary buffer PFD_MAIN_PLANE, // main layer 0, // reserved 0, 0, 0 // layer masks ignored }; pixFmt = ChoosePixelFormat( hDC, &pfd ); if( pixFmt > 0 && SetPixelFormat( hDC, pixFmt, &pfd ) ) return (uint32_t)wglCreateContext( hDC ); return 0; } #endif #endif /////////////////////////////////////////////////////////////////////////////// //// Fudging Routines ///////////////////////////////////////////////////////// /////////////////////////////////////////////////////////////////////////////// namespace { /// Here's our CFT--Chipset Fudgefactor Table /// The table consists of entries for each of our supported chipsets in the table, /// plus, flags to be forced set and flags to be forced cleared. Also included /// is a Z-buffer suckiness rating, which represents how badly we need to bias /// the z and w values to avoid z-buffer artifacts, stored as an float (i.e /// a float). A rating of 0 means very good/default (read: Nvidia), while, say, /// a 9.0 (i.e. shift the scale 9 times above normal) means s****y, like, say, /// a Savage4. Also also included is a forced value for max # of layers (0 means /// to use default). Also also also included is an LOD rating indicating how much /// (and in which direction) to alter the base LOD bias value for this device. General /// interpretation of this value is to add (-lodRating) to the LOD bias value. /// This is because the LOD bias starts out negative and typically goes in 0.25 /// increments. /// Also also ALSO included are three new values for fog tweaking. The first two-- /// fFogExp/Exp2ApproxStart, are the start of the linear approximation of exponential /// fog. Tweak these to adjust the linear approximation on any cards that don't support /// exponential and exponential-squared fog natively. The third value is the fFogEndBias-- /// this is a value (stored as a percentage of the max possible fog value) to add on to /// to the linear fog-end parameter AFTER ALL CALCULATIONS. This is so we can, for /// example, tweak the end of the fog on the ATI Rage cards to not fog out as quickly. /// 9.14.2000 - fog end bias now has a new meaning. What it *really* represents is the /// quantization of fog on a particular card, where the end bias = ( 2^bitdepth - 2 ) / ( 2^bitdepth - 1 ) /// So, for 8 bit fog, we end up with 254 / 255, etc. So far, everything is set to 8 /// bit fog, but we have it here just in case we need to change it in the future. enum { kDefaultChipset = 0x00, kSavage4Chipset, kATIRageFuryChipset, kATIRageProChipset, kNVidiaTNTChipset, kNVidiaGeForceChipset, kMatroxG400Chipset, kIntelI810Chipset, kSavage2000Chipset, kS3GenericChipset, kATIGenericChipset, kMatroxGenericChipset, kKYROChipset, k3dfxV5Chipset, kSavage3DChipset, kATIRadeonChipset, kATIR7X00Chipset, kATIR7500Chipset, kATIR8X00Chipset, kMatroxParhelia, kNVidiaGeForce2Chipset, kNVidiaGeForce3Chipset, kNVidiaGeForce4MXChipset, kNVidiaGeForce4Chipset, kNVidiaGeForceFXChipset }; typedef struct { float fFogExpApproxStart; float fFogExp2ApproxStart; float fFogEndBias; float fFogExpKnee; // Fog knees float fFogExpKneeVal; float fFogExp2Knee; float fFogExp2KneeVal; } FogTweakTable; FogTweakTable dsDefaultFogVals = { 0, 0, 254.0 / 255.0, 0.5f, 0.15f, 0.5f, 0.15f }; FogTweakTable dsATIFogVals = { 0.1f, 0.1f, 254.0 / 255.0, 0.85f, 0.15f, 0.5f, 0.15f }; FogTweakTable dsS3DFogVals = { 0, 0, 254.0 / 255.0, 1.0f, 1.0f, 1.0f, 1.0f }; FogTweakTable dsi810FogVals = { 0, 0, 254.0 / 255.0, 0.6f, 0.15f, 0.4f, 0.15f }; FogTweakTable dsRadeonFogVals = { 0, 0, 254.0 / 255.0, 0.7f, 0.15f, 0.5f, 0.2f }; typedef struct { uint8_t fType; // Our chipset ID uint32_t *fFlagsToSet; uint32_t *fFlagsToClear; float fZSuckiness; // See above uint32_t fForceMaxLayers; // The max # of layers we REALLY want (0 to not force) float fLODRating; FogTweakTable *fFogTweaks; } CFTable; uint32_t dsSavageCapsClr[] = { 4, // First integer is always the length hsG3DDeviceSelector::kCapsCompressTextures, hsG3DDeviceSelector::kCapsFogExp, hsG3DDeviceSelector::kCapsFogExp2, hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsSavageCapsSet[] = { 1, // First integer is always the length hsG3DDeviceSelector::kCapsBadYonStuff }; uint32_t dsSavage2kCapsClr[] = { 5, // First integer is always the length hsG3DDeviceSelector::kCapsCompressTextures, hsG3DDeviceSelector::kCapsPixelFog, hsG3DDeviceSelector::kCapsFogExp, hsG3DDeviceSelector::kCapsFogExp2, hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsS3GenerCapsClr[] = { 4, // First integer is always the length hsG3DDeviceSelector::kCapsCompressTextures, hsG3DDeviceSelector::kCapsFogExp, hsG3DDeviceSelector::kCapsFogExp2, hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsATIFuryCapsClr[] = { 3, // First integer is always the length hsG3DDeviceSelector::kCapsFogExp, hsG3DDeviceSelector::kCapsFogExp2, hsG3DDeviceSelector::kCapsPixelFog }; uint32_t dsATIRageCapsClr[] = { 4, // First integer is always the length hsG3DDeviceSelector::kCapsFogExp, hsG3DDeviceSelector::kCapsFogExp2, hsG3DDeviceSelector::kCapsDoesSmallTextures, hsG3DDeviceSelector::kCapsPixelFog }; uint32_t dsATIGenerCapsClr[] = { 4, // First integer is always the length hsG3DDeviceSelector::kCapsPixelFog, hsG3DDeviceSelector::kCapsFogExp, hsG3DDeviceSelector::kCapsFogExp2, hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsATIRadeonCapsSet[] = { 2, // First integer is always the length hsG3DDeviceSelector::kCapsBadManaged, hsG3DDeviceSelector::kCapsShareDepth }; uint32_t dsATIRadeonCapsClr[] = { 2, // First integer is always the length hsG3DDeviceSelector::kCapsWBuffer, hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsATIR7X00CapsSet[] = { 4, // First integer is always the length hsG3DDeviceSelector::kCapsCantShadow, hsG3DDeviceSelector::kCapsBadManaged, hsG3DDeviceSelector::kCapsShareDepth, hsG3DDeviceSelector::kCapsNoAniso }; uint32_t dsATIR7500CapsSet[] = { 5, // First integer is always the length hsG3DDeviceSelector::kCapsMaxUVWSrc2, hsG3DDeviceSelector::kCapsCantShadow, hsG3DDeviceSelector::kCapsBadManaged, hsG3DDeviceSelector::kCapsShareDepth, hsG3DDeviceSelector::kCapsNoAniso }; uint32_t dsATIR7X00CapsClr[] = { 2, // First integer is always the length hsG3DDeviceSelector::kCapsWBuffer, hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsATIR8X00CapsSet[] = { 2, // First integer is always the length hsG3DDeviceSelector::kCapsBadManaged, hsG3DDeviceSelector::kCapsShareDepth }; uint32_t dsATIR8X00CapsClr[] = { 2, // First integer is always the length hsG3DDeviceSelector::kCapsWBuffer, hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsTNTCapsClr[] = { 1, // First integer is always the length hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsDefaultCapsClr[] = { 1, // First integer is always the length hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsMG400CapsClr[] = { 1, // First integer is always the length hsG3DDeviceSelector::kCapsDoesSmallTextures }; uint32_t dsKYROCapsClr[] = { 2, // First integer is always the length hsG3DDeviceSelector::kCapsDoesSmallTextures, hsG3DDeviceSelector::kCapsPixelFog }; uint32_t dsKYROCapsSet[] = { 1, // First integer is always the length hsG3DDeviceSelector::kCapsNoKindaSmallTexs }; uint32_t ds3dfxV5CapsClr[] = { 2, // First integer is always the length hsG3DDeviceSelector::kCapsFogExp, hsG3DDeviceSelector::kCapsFogExp2 }; uint32_t dsMatroxParheliaSet[] = { 1, hsG3DDeviceSelector::kCapsNoAA }; uint32_t dsGeForceSet[] = { 2, hsG3DDeviceSelector::kCapsCantProj, hsG3DDeviceSelector::kCapsDoubleFlush }; uint32_t dsGeForce2Set[] = { 1, hsG3DDeviceSelector::kCapsDoubleFlush }; uint32_t dsGeForce3Set[] = { 1, hsG3DDeviceSelector::kCapsSingleFlush }; uint32_t dsGeForce4MXSet[] = { 1, hsG3DDeviceSelector::kCapsSingleFlush }; uint32_t dsGeForce4Set[] = { 1, hsG3DDeviceSelector::kCapsSingleFlush }; CFTable dsCFTable[] = { // Chipset ID // F2Set // F2Clear // ZSuck // MaxLayers // LODBias // Fog Value Tables { kDefaultChipset, nil, dsDefaultCapsClr, 0, 0, 0, &dsDefaultFogVals }, { kATIRageFuryChipset, nil, dsATIFuryCapsClr, 4.25f, 1, 0, &dsATIFogVals }, { kATIRageProChipset, nil, dsATIRageCapsClr, 4.25f, 1, 0, &dsATIFogVals }, { kATIGenericChipset, nil, dsATIGenerCapsClr, 4.25f, 1, 0, &dsATIFogVals }, { kNVidiaTNTChipset, nil, dsTNTCapsClr, 0, 0, 0, &dsDefaultFogVals }, { kNVidiaGeForce2Chipset,dsGeForce2Set, nil, 0, 0, 0, &dsDefaultFogVals }, { kNVidiaGeForce3Chipset,dsGeForce3Set, nil, 0, 0, 0, &dsDefaultFogVals }, { kNVidiaGeForce4MXChipset,dsGeForce4MXSet, nil, 0, 0, 0, &dsDefaultFogVals }, { kNVidiaGeForce4Chipset,dsGeForce4Set, nil, 0, 0, 0, &dsDefaultFogVals }, { kNVidiaGeForceChipset,dsGeForceSet, nil, 0, 0, 0, &dsDefaultFogVals }, { kNVidiaGeForceFXChipset,nil, nil, 0, 0, 0, &dsDefaultFogVals }, { kMatroxG400Chipset, nil, dsMG400CapsClr, 3.25f, 0, 0, &dsDefaultFogVals }, { kMatroxParhelia, dsMatroxParheliaSet,nil, 0, 0, 0, &dsDefaultFogVals }, { kMatroxGenericChipset,nil, dsMG400CapsClr, 3.25f, 0, 0, &dsDefaultFogVals }, { kIntelI810Chipset, nil, dsDefaultCapsClr, 4.5f, 1, -0.5f, &dsi810FogVals }, { kSavage4Chipset, dsSavageCapsSet, dsSavageCapsClr, 4.0f, 1, 0, &dsDefaultFogVals }, // LOD bias should be -0.5 here { kSavage2000Chipset, dsSavageCapsSet, dsSavage2kCapsClr, 4.0f, 1, 0, &dsDefaultFogVals }, { kS3GenericChipset, dsSavageCapsSet, dsS3GenerCapsClr, 4.0f, 1, 0, &dsDefaultFogVals }, { kKYROChipset, dsKYROCapsSet, dsKYROCapsClr, -151.0f, 1, 0, &dsDefaultFogVals }, { k3dfxV5Chipset, nil, ds3dfxV5CapsClr, 3.5f, 0, 0, &dsDefaultFogVals }, { kSavage3DChipset, nil, dsDefaultCapsClr, 0, 0, 0, &dsS3DFogVals }, { kATIRadeonChipset, dsATIRadeonCapsSet, dsATIRadeonCapsClr, 0, 0, 0, &dsRadeonFogVals }, { kATIR7X00Chipset, dsATIR7X00CapsSet, dsATIR7X00CapsClr, 3.f, 2, 0, &dsRadeonFogVals }, { kATIR7500Chipset, dsATIR7500CapsSet, dsATIR7X00CapsClr, 3.f, 2, 0, &dsRadeonFogVals }, { kATIR8X00Chipset, dsATIR8X00CapsSet, dsATIR8X00CapsClr, 0, 0, 0, &dsRadeonFogVals }, }; }; //// IFudgeDirectXDevice ////////////////////////////////////////////////////// // Checks this DirectX device against all our known types and fudges our caps // flags and bias values, etc, accordingly #ifdef HS_SELECT_DIRECT3D void hsG3DDeviceSelector::IFudgeDirectXDevice( hsG3DDeviceRecord &record, D3DEnum_DriverInfo *driverInfo, D3DEnum_DeviceInfo *deviceInfo ) { char desc[ 512 ]; // Can't rely on D3D constant, since that's in another file now uint32_t vendorID, deviceID; char *szDriver, *szDesc; /// Send it off to each D3D device, respectively if( record.GetG3DDeviceType() == kDevTypeDirect3DTnL ) { if( !IGetD3DCardInfo( record, driverInfo, deviceInfo, &vendorID, &deviceID, &szDriver, &szDesc ) ) { // {} to make VC6 happy in release build hsAssert( false, "Trying to fudge D3D device but D3D support isn't in this EXE!" ); } } #ifdef HS_SELECT_DX7 else if( record.GetG3DDeviceType() == kDevTypeDirect3D ) { if( !IGetD3D7CardInfo( record, driverInfo, deviceInfo, &vendorID, &deviceID, &szDriver, &szDesc ) ) { // {} to make VC6 happy in release build hsAssert( false, "Trying to fudge D3D7 device but D3D7 support isn't in this EXE!" ); } } #endif // HS_SELECT_DX7 else { hsAssert( false, "IFudgeDirectXDevice got a device type that support wasn't compiled for!" ); } /// So capitalization won't matter in our tests hsAssert( strlen( szDesc ) < sizeof( desc ), "D3D device description longer than expected!" ); hsStrcpy( desc, szDesc ); hsStrLower( desc ); //// S3-based Cards /////////////////////////////////////////////////////// /// Detect Savage 4 chipset if( deviceID == 0x00008a22 || stricmp( szDriver, "s3savg4.dll" ) == 0 || ( strstr( desc, "diamond" ) != nil && strstr( desc, "stealth iii" ) != nil ) || strstr( desc, "savage4 " ) != nil ) { /// Yup, Savage 4. hsStatusMessage( "== Using fudge factors for a Savage 4 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a Savage 4 chipset" ); ISetFudgeFactors( kSavage4Chipset, record ); } /// Detect Savage 2000 chipset else if( deviceID == 0x00009102 || stricmp( szDriver, "s3sav2k.dll" ) == 0 || ( strstr( desc, "diamond" ) != nil && strstr( desc, "viperii" ) != nil ) || strstr( desc, "savage2000 " ) != nil ) { /// Yup, Savage 2000. hsStatusMessage( "== Using fudge factors for a Savage 2000 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a Savage 2000 chipset" ); ISetFudgeFactors( kSavage2000Chipset, record ); } /// Detect Savage3D chipset else if( deviceID == 0x00008a20 || stricmp( szDriver, "s3_6.dll" ) == 0 || strstr( desc, "savage3d" ) != nil ) { /// Yup, Savage3D. hsStatusMessage( "== Using fudge factors for a Savage3D chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a Savage3D chipset" ); ISetFudgeFactors( kSavage3DChipset, record ); } /// Detect Generic S3 chipset else if( ( strncmp( szDriver, "s3", 2 ) == 0 ) || ( strstr( desc, "savage" ) != nil ) ) { /// Yup, Generic S3. hsStatusMessage( "== Using fudge factors for a generic S3 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a generic S3 chipset" ); ISetFudgeFactors( kS3GenericChipset, record ); } //// ATI-based Cards ////////////////////////////////////////////////////// /// Detect ATI Radeon HD else if (strstr( desc, "radeon hd" ) != nullptr) { hsStatusMessage( "== Using fudge factors for an ATI Radeon HD chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an ATI Radeon HD chipset" ); ISetFudgeFactors( kDefaultChipset, record ); } /// Detect ATI Rage 128 Pro chipset else if( ( deviceID == 0x00005046 && // Normal ATI Rage 128 Pro detection ( stricmp( szDriver, "ati2dvaa.dll" ) == 0 || strstr( desc, "rage 128 pro" ) != nil ) ) || ( deviceID == 0x00005246 && // ATI All-in-wonder--same chipset, diff values ( stricmp( szDriver, "ati3draa.dll" ) == 0 || strstr( desc, "all-in-wonder 128" ) != nil ) ) ) { hsStatusMessage( "== Using fudge factors for an ATI Rage 128 Pro chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an ATI Rage 128 Pro chipset" ); ISetFudgeFactors( kATIRageProChipset, record ); } /// Detect(detest?) ATI Rage FURY MAXX chipset else if( deviceID == 0x00005046 && ( stricmp( szDriver, "ati3drau.dll" ) == 0 || strstr( desc, "rage fury" ) != nil ) ) { hsStatusMessage( "== Using fudge factors for an ATI Rage Fury MAXX chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an ATI Rage Fury MAXX chipset" ); ISetFudgeFactors( kATIRageFuryChipset, record ); } /// Detect ATI Radeon chipset // We will probably need to differentiate between different Radeons at some point in // the future, but not now. else if( // deviceID == 0x00005144 && ( stricmp( szDriver, "ati2dvag.dll" ) == 0 || strstr( desc, "radeon" ) != nil ) ) { int series = 0; const char* str = strstr(desc, "radeon"); if( str ) str += strlen("radeon"); else { str = strstr(desc, "all-in-wonder"); if( str ) str += strlen("all-in-wonder"); } if( str ) { if( 1 == sscanf(str, "%d", &series) ) { if( (series == 7500) || (series == 7200) ) { hsStatusMessage( "== Using fudge factors for ATI Radeon 7200/7500 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for ATI Radeon 7200/7500 chipset" ); ISetFudgeFactors( kATIR7500Chipset, record ); } else if( (series >= 7000) && (series < 8000) ) { hsStatusMessage( "== Using fudge factors for ATI Radeon 7X00 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for ATI Radeon 7X00 chipset" ); ISetFudgeFactors( kATIR7X00Chipset, record ); } else if( (series >= 8000) && (series < 9000) ) { hsStatusMessage( "== Using fudge factors for ATI Radeon 8X00 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for ATI Radeon 8X00 chipset" ); ISetFudgeFactors( kATIR8X00Chipset, record ); } else { series = 0; } } else { series = 0; // Skip white space while( *str && (*str <= 0x32) ) str++; // I've still never seen either of these, so I'm just going by ATI's site. // Don't have the option of using device-id's. if( (str[0] == 'v') && (str[1] == 'e') ) { // Got an alias here. If it's an All-in-Wonder VE, it's really a 7500. // If it's a Radeon VE, it's really a 7000. if( strstr(desc, "radeon") ) series = 7000; else if( strstr(desc, "all-in-wonder") ) series = 7500; } } } if( !series ) { hsStatusMessage( "== Using fudge factors for ATI Radeon chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for ATI Radeon chipset" ); ISetFudgeFactors( kATIRadeonChipset, record ); } } /// Detect generic ATI chipset else if( ( strncmp( szDriver, "ati", 3 ) == 0 ) || ( strstr( desc, "ati " ) != nil ) ) { hsStatusMessage( "== Using fudge factors for a generic ATI chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a generic ATI chipset" ); ISetFudgeFactors( kATIGenericChipset, record ); } //// Matrox-based Cards /////////////////////////////////////////////////// else if( (deviceID == 0x527) || strstr(desc, "parhelia") ) { hsStatusMessage( "== Using fudge factors for a Matrox Parhelia chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a Matrox Millenium G400 chipset" ); ISetFudgeFactors( kMatroxParhelia, record ); } /// Detect Matrox G400 chipset else if( deviceID == 0x00000525 && ( stricmp( szDriver, "g400d.dll" ) == 0 || ( strstr( desc, "matrox" ) != nil && strstr( desc, "g400" ) != nil ) ) ) { hsStatusMessage( "== Using fudge factors for a Matrox Millenium G400 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a Matrox Millenium G400 chipset" ); ISetFudgeFactors( kMatroxG400Chipset, record ); } /// Detect generic Matrox chipset else if( strstr( desc, "matrox" ) != nil ) { hsStatusMessage( "== Using fudge factors for a generic Matrox chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a generic Matrox chipset" ); ISetFudgeFactors( kMatroxGenericChipset, record ); } //// Other Cards ////////////////////////////////////////////////////////// /// Detect NVidia RIVA TNT chipset else if( deviceID == 0x00000020 && ( stricmp( szDriver, "nvdd32.dll" ) == 0 || strstr( desc, "nvidia riva tnt" ) != nil ) ) { hsStatusMessage( "== Using fudge factors for an NVidia RIVA TNT chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an NVidia RIVA TNT chipset" ); ISetFudgeFactors( kNVidiaTNTChipset, record ); if( record.GetMemoryBytes() < 16 * 1024 * 1024 ) { hsStatusMessage( "== (also fudging memory up to 16MB) ==\n" ); plDemoDebugFile::Write( " (also fudging memory up to 16MB)" ); record.SetMemoryBytes( 16 * 1024 * 1024 ); } } /// Detect Intel i810 chipset else if( deviceID == 0x00007125 && ( stricmp( szDriver, "i81xdd.dll" ) == 0 || ( strstr( desc, "intel" ) != nil && strstr( desc, "810" ) != nil ) ) ) { hsStatusMessage( "== Using fudge factors for an Intel i810 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an Intel i810 chipset" ); ISetFudgeFactors( kIntelI810Chipset, record ); } /// Detect STMicroelectronics KYRO chipset else if( deviceID == 0x00000010 && ( strstr( desc, "kyro" ) != nil ) ) { hsStatusMessage( "== Using fudge factors for a KYRO chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a KYRO chipset" ); ISetFudgeFactors( kKYROChipset, record ); } /// Detect for a 3dfx Voodoo5 else if( vendorID == 0x121a && deviceID == 0x00000009 && stricmp( szDriver, "3dfxvs.dll" ) == 0 ) { hsStatusMessage( "== Using fudge factors for a 3dfx Voodoo5 chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for a 3dfx Voodoo5 chipset" ); ISetFudgeFactors( k3dfxV5Chipset, record ); } /// Detect for a GeForce-class card. We can be loose here because we want /// to get ALL GeForce/2/256 cards else if( strstr( desc, "nvidia" ) != nil && strstr( desc, "geforce2" ) != nil ) { hsStatusMessage( "== Using fudge factors for an NVidia GeForce2-based chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an NVidia GeForce2-based chipset" ); ISetFudgeFactors( kNVidiaGeForce2Chipset, record ); } else if( strstr( desc, "nvidia" ) != nil && strstr( desc, "geforce3" ) != nil ) { hsStatusMessage( "== Using fudge factors for an NVidia GeForce3-based chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an NVidia GeForce3-based chipset" ); ISetFudgeFactors( kNVidiaGeForce3Chipset, record ); } else if( strstr( desc, "nvidia" ) != nil && strstr( desc, "geforce4 mx" ) != nil ) { hsStatusMessage( "== Using fudge factors for an NVidia GeForce4MX-based chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an NVidia GeForce4MX-based chipset" ); ISetFudgeFactors( kNVidiaGeForce4MXChipset, record ); } else if( strstr( desc, "nvidia" ) != nil && strstr( desc, "geforce4" ) != nil ) { hsStatusMessage( "== Using fudge factors for an NVidia GeForce4-based chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an NVidia GeForce4-based chipset" ); ISetFudgeFactors( kNVidiaGeForce4Chipset, record ); } else if( strstr( desc, "nvidia" ) && strstr( desc, "geforce" ) && ( (deviceID == 0x101) ||(deviceID == 0x100) ||strstr(desc, "256") ) ) { hsStatusMessage( "== Using fudge factors for an NVidia GeForce-based chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an NVidia GeForce-based chipset" ); ISetFudgeFactors( kNVidiaGeForceChipset, record ); } else if( strstr( desc, "nvidia" ) != nil && strstr( desc, "geforce" ) != nil ) { hsStatusMessage( "== Using fudge factors for an NVidia GeForceFX-based chipset ==\n" ); plDemoDebugFile::Write( " Using fudge factors for an NVidia GeForceFX-based chipset" ); ISetFudgeFactors( kNVidiaGeForceFXChipset, record ); } /// Detect for a TNT-based card and force it to >= 16MB memory, so we always use it else if( strstr( desc, "tnt" ) != nil && record.GetMemoryBytes() < 16 * 1024 * 1024 ) { hsStatusMessage( "== NVidia TNT-based card detected. Fudging memory reading to 16MB ==\n" ); plDemoDebugFile::Write( " NVidia TNT-based card detected. Fudging memory reading to 16MB" ); record.SetMemoryBytes( 16 * 1024 * 1024 ); } /// Default fudge values else { hsStatusMessage( "== Using default fudge factors ==\n" ); plDemoDebugFile::Write( " Using default fudge factors" ); ISetFudgeFactors( kDefaultChipset, record ); } } #endif //// ISetFudgeFactors ///////////////////////////////////////////////////////// // Given a chipset ID, looks the values up in the CFT and sets the appropriate // values. void hsG3DDeviceSelector::ISetFudgeFactors( uint8_t chipsetID, hsG3DDeviceRecord &record ) { int i, maxIDs, j; maxIDs = sizeof( dsCFTable ) / sizeof( dsCFTable[ 0 ] ); /// Search for our chipset for( i = 0; i < maxIDs; i++ ) { if( dsCFTable[ i ].fType == chipsetID ) { /// Found it! // Flags to force set if( dsCFTable[ i ].fFlagsToSet != nil ) { for( j = 0; j < dsCFTable[ i ].fFlagsToSet[ 0 ]; j++ ) record.SetCap( dsCFTable[ i ].fFlagsToSet[ j + 1 ] ); } // Flags to force clear if( dsCFTable[ i ].fFlagsToClear != nil ) { for( j = 0; j < dsCFTable[ i ].fFlagsToClear[ 0 ]; j++ ) record.SetCap( dsCFTable[ i ].fFlagsToClear[ j + 1 ], false ); } // Suckiness record.SetZBiasRating( dsCFTable[ i ].fZSuckiness ); // Max # of layers if( dsCFTable[ i ].fForceMaxLayers > 0 ) record.SetLayersAtOnce( dsCFTable[ i ].fForceMaxLayers ); // LOD bias rating record.SetLODBiasRating( dsCFTable[ i ].fLODRating ); // Fog tweaks FogTweakTable *fogTweaks = dsCFTable[ i ].fFogTweaks; record.SetFogApproxStarts( fogTweaks->fFogExpApproxStart, fogTweaks->fFogExp2ApproxStart ); record.SetFogEndBias( fogTweaks->fFogEndBias ); record.SetFogKneeParams( hsG3DDeviceRecord::kFogExp, fogTweaks->fFogExpKnee, fogTweaks->fFogExpKneeVal ); record.SetFogKneeParams( hsG3DDeviceRecord::kFogExp2, fogTweaks->fFogExp2Knee, fogTweaks->fFogExp2KneeVal ); if( record.GetCap(kCapsNoAA) ) { int j; for( j = 0; j < record.GetModes().GetCount(); j++ ) record.GetModes()[j].ClearFSAATypes(); } return; } } } /////////////////////////////////////////////////////////////////////////////// // // Demo Debug File functions // Created 10.10.2000 by Mathew Burrack @ Cyan, Inc. // Modified 10.11 mcn to conform (more) to coding standards. // /////////////////////////////////////////////////////////////////////////////// //// Local Globals //////////////////////////////////////////////////////////// #if M3DDEMOINFO // Demo Debug Build static plDemoDebugFile sMyDDFWriter; bool plDemoDebugFile::fIsOpen = false; FILE *plDemoDebugFile::fDemoDebugFP = nil; bool plDemoDebugFile::fEnabled = false; #endif //// IDDFOpen ///////////////////////////////////////////////////////////////// // Internal function--opens the demo debug file for writing. Returns true // if successful, false otherwise. bool plDemoDebugFile::IDDFOpen( void ) { #if M3DDEMOINFO // Demo Debug Build char fileName[] = "log/debug_info.dat"; time_t currTime; struct tm *localTime; char timeString[ 27 ]; // see definition of asctime() char *c; /// Don't open if we're not enabled if( !fEnabled ) return false; /// Open the file if( fDemoDebugFP == nil ) fDemoDebugFP = fopen( fileName, "wt" ); if( fDemoDebugFP == nil ) return( fIsOpen = false ); /// Write out a header line time( &currTime ); localTime = localtime( &currTime ); // Note: asctime includes a carriage return. Gotta strip... strcpy( timeString, asctime( localTime ) ); c = strchr( timeString, '\n' ); if( c != nil ) *c = 0; fprintf( fDemoDebugFP, "\n--- Demo Debug Info File (Created %s) ---\n", timeString ); /// All done! return( fIsOpen = true ); #else return false; #endif } //// IDDFClose //////////////////////////////////////////////////////////////// // "Whatcha gonna do when the lightning strikes and hits you...." // -- "Lightning Strikes", Yes, 1999 void plDemoDebugFile::IDDFClose( void ) { #if M3DDEMOINFO // Demo Debug Build if( fDemoDebugFP != nil ) { // Write an exit line (fun fun) fputs( "--- End of Demo Debug Info File ---\n\n", fDemoDebugFP ); // Close fclose( fDemoDebugFP ); } fIsOpen = false; #endif } //// Write //////////////////////////////////////////////////////////////////// // Writes a string to the DDF. If the DDF isn't open, opens it. void plDemoDebugFile::Write( const char *string ) { #if M3DDEMOINFO // Demo Debug Build if( !fIsOpen ) IDDFOpen(); if( fIsOpen ) fprintf( fDemoDebugFP, "%s\n", string ); #endif } void plDemoDebugFile::Write( const char *string1, const char *string2 ) { #if M3DDEMOINFO // Demo Debug Build if( !fIsOpen ) IDDFOpen(); if( fIsOpen ) fprintf( fDemoDebugFP, "%s: %s\n", string1, string2 ); #endif } void plDemoDebugFile::Write( const char *string1, int32_t value ) { #if M3DDEMOINFO // Demo Debug Build if( !fIsOpen ) IDDFOpen(); if( fIsOpen ) fprintf( fDemoDebugFP, "%s: %d (0x%x)\n", string1, value, value ); #endif }