/* =========================================================================== Doom 3 GPL Source Code Copyright (C) 1999-2011 id Software LLC, a ZeniMax Media company. This file is part of the Doom 3 GPL Source Code ("Doom 3 Source Code"). Doom 3 Source Code 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. Doom 3 Source Code 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 Doom 3 Source Code. If not, see . In addition, the Doom 3 Source Code is also subject to certain additional terms. You should have received a copy of these additional terms immediately following the terms and conditions of the GNU General Public License which accompanied the Doom 3 Source Code. If not, please request a copy in writing from id Software at the address below. If you have questions concerning this license or the applicable additional terms, you may contact in writing id Software LLC, c/o ZeniMax Media Inc., Suite 120, Rockville, Maryland 20850 USA. =========================================================================== */ #include "sys/platform.h" #include "idlib/LangDict.h" #include "framework/Licensee.h" #include "framework/Console.h" #include "framework/Session.h" #include "renderer/VertexCache.h" #include "renderer/ModelManager.h" #include "renderer/RenderWorld_local.h" #include "renderer/GuiModel.h" #include "sound/sound.h" #include "ui/UserInterface.h" #include "renderer/tr_local.h" // Vista OpenGL wrapper check #ifdef _WIN32 #include "sys/win32/win_local.h" #endif // functions that are not called every frame glconfig_t glConfig; const char *r_rendererArgs[] = { "best", "arb2", NULL }; idCVar r_inhibitFragmentProgram( "r_inhibitFragmentProgram", "0", CVAR_RENDERER | CVAR_BOOL, "ignore the fragment program extension" ); idCVar r_useLightPortalFlow( "r_useLightPortalFlow", "1", CVAR_RENDERER | CVAR_BOOL, "use a more precise area reference determination" ); idCVar r_multiSamples( "r_multiSamples", "0", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_INTEGER, "number of antialiasing samples" ); idCVar r_mode( "r_mode", "3", CVAR_ARCHIVE | CVAR_RENDERER | CVAR_INTEGER, "video mode number" ); idCVar r_displayRefresh( "r_displayRefresh", "0", CVAR_RENDERER | CVAR_INTEGER | CVAR_NOCHEAT, "optional display refresh rate option for vid mode", 0.0f, 200.0f ); idCVar r_fullscreen( "r_fullscreen", "1", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_BOOL, "0 = windowed, 1 = full screen" ); idCVar r_customWidth( "r_customWidth", "720", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_INTEGER, "custom screen width. set r_mode to -1 to activate" ); idCVar r_customHeight( "r_customHeight", "486", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_INTEGER, "custom screen height. set r_mode to -1 to activate" ); idCVar r_singleTriangle( "r_singleTriangle", "0", CVAR_RENDERER | CVAR_BOOL, "only draw a single triangle per primitive" ); idCVar r_checkBounds( "r_checkBounds", "0", CVAR_RENDERER | CVAR_BOOL, "compare all surface bounds with precalculated ones" ); idCVar r_useConstantMaterials( "r_useConstantMaterials", "1", CVAR_RENDERER | CVAR_BOOL, "use pre-calculated material registers if possible" ); idCVar r_useSilRemap( "r_useSilRemap", "1", CVAR_RENDERER | CVAR_BOOL, "consider verts with the same XYZ, but different ST the same for shadows" ); idCVar r_useNodeCommonChildren( "r_useNodeCommonChildren", "1", CVAR_RENDERER | CVAR_BOOL, "stop pushing reference bounds early when possible" ); idCVar r_useShadowProjectedCull( "r_useShadowProjectedCull", "1", CVAR_RENDERER | CVAR_BOOL, "discard triangles outside light volume before shadowing" ); idCVar r_useShadowVertexProgram( "r_useShadowVertexProgram", "1", CVAR_RENDERER | CVAR_BOOL, "do the shadow projection in the vertex program on capable cards" ); idCVar r_useShadowSurfaceScissor( "r_useShadowSurfaceScissor", "1", CVAR_RENDERER | CVAR_BOOL, "scissor shadows by the scissor rect of the interaction surfaces" ); idCVar r_useInteractionTable( "r_useInteractionTable", "1", CVAR_RENDERER | CVAR_BOOL, "create a full entityDefs * lightDefs table to make finding interactions faster" ); idCVar r_useTurboShadow( "r_useTurboShadow", "1", CVAR_RENDERER | CVAR_BOOL, "use the infinite projection with W technique for dynamic shadows" ); idCVar r_useTwoSidedStencil( "r_useTwoSidedStencil", "1", CVAR_RENDERER | CVAR_BOOL, "do stencil shadows in one pass with different ops on each side" ); idCVar r_useDeferredTangents( "r_useDeferredTangents", "1", CVAR_RENDERER | CVAR_BOOL, "defer tangents calculations after deform" ); idCVar r_useCachedDynamicModels( "r_useCachedDynamicModels", "1", CVAR_RENDERER | CVAR_BOOL, "cache snapshots of dynamic models" ); idCVar r_useVertexBuffers( "r_useVertexBuffers", "1", CVAR_RENDERER | CVAR_INTEGER, "use ARB_vertex_buffer_object for vertexes", 0, 1, idCmdSystem::ArgCompletion_Integer<0,1> ); idCVar r_useIndexBuffers( "r_useIndexBuffers", "0", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_INTEGER, "use ARB_vertex_buffer_object for indexes", 0, 1, idCmdSystem::ArgCompletion_Integer<0,1> ); idCVar r_useStateCaching( "r_useStateCaching", "1", CVAR_RENDERER | CVAR_BOOL, "avoid redundant state changes in GL_*() calls" ); idCVar r_useInfiniteFarZ( "r_useInfiniteFarZ", "1", CVAR_RENDERER | CVAR_BOOL, "use the no-far-clip-plane trick" ); idCVar r_znear( "r_znear", "3", CVAR_RENDERER | CVAR_FLOAT, "near Z clip plane distance", 0.001f, 200.0f ); idCVar r_ignoreGLErrors( "r_ignoreGLErrors", "1", CVAR_RENDERER | CVAR_BOOL, "ignore GL errors" ); idCVar r_finish( "r_finish", "0", CVAR_RENDERER | CVAR_BOOL, "force a call to glFinish() every frame" ); idCVar r_swapInterval( "r_swapInterval", "0", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_INTEGER, "changes the GL swap interval" ); idCVar r_gamma( "r_gamma", "1", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_FLOAT, "changes gamma tables", 0.5f, 3.0f ); idCVar r_brightness( "r_brightness", "1", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_FLOAT, "changes gamma tables", 0.5f, 2.0f ); idCVar r_renderer( "r_renderer", "best", CVAR_RENDERER | CVAR_ARCHIVE, "hardware specific renderer path to use", r_rendererArgs, idCmdSystem::ArgCompletion_String ); idCVar r_jitter( "r_jitter", "0", CVAR_RENDERER | CVAR_BOOL, "randomly subpixel jitter the projection matrix" ); idCVar r_skipSuppress( "r_skipSuppress", "0", CVAR_RENDERER | CVAR_BOOL, "ignore the per-view suppressions" ); idCVar r_skipPostProcess( "r_skipPostProcess", "0", CVAR_RENDERER | CVAR_BOOL, "skip all post-process renderings" ); idCVar r_skipLightScale( "r_skipLightScale", "0", CVAR_RENDERER | CVAR_BOOL, "don't do any post-interaction light scaling, makes things dim on low-dynamic range cards" ); idCVar r_skipInteractions( "r_skipInteractions", "0", CVAR_RENDERER | CVAR_BOOL, "skip all light/surface interaction drawing" ); idCVar r_skipDynamicTextures( "r_skipDynamicTextures", "0", CVAR_RENDERER | CVAR_BOOL, "don't dynamically create textures" ); idCVar r_skipCopyTexture( "r_skipCopyTexture", "0", CVAR_RENDERER | CVAR_BOOL, "do all rendering, but don't actually copyTexSubImage2D" ); idCVar r_skipBackEnd( "r_skipBackEnd", "0", CVAR_RENDERER | CVAR_BOOL, "don't draw anything" ); idCVar r_skipRender( "r_skipRender", "0", CVAR_RENDERER | CVAR_BOOL, "skip 3D rendering, but pass 2D" ); idCVar r_skipRenderContext( "r_skipRenderContext", "0", CVAR_RENDERER | CVAR_BOOL, "NULL the rendering context during backend 3D rendering" ); idCVar r_skipTranslucent( "r_skipTranslucent", "0", CVAR_RENDERER | CVAR_BOOL, "skip the translucent interaction rendering" ); idCVar r_skipAmbient( "r_skipAmbient", "0", CVAR_RENDERER | CVAR_BOOL, "bypasses all non-interaction drawing" ); idCVar r_skipNewAmbient( "r_skipNewAmbient", "0", CVAR_RENDERER | CVAR_BOOL | CVAR_ARCHIVE, "bypasses all vertex/fragment program ambient drawing" ); idCVar r_skipBlendLights( "r_skipBlendLights", "0", CVAR_RENDERER | CVAR_BOOL, "skip all blend lights" ); idCVar r_skipFogLights( "r_skipFogLights", "0", CVAR_RENDERER | CVAR_BOOL, "skip all fog lights" ); idCVar r_skipDeforms( "r_skipDeforms", "0", CVAR_RENDERER | CVAR_BOOL, "leave all deform materials in their original state" ); idCVar r_skipFrontEnd( "r_skipFrontEnd", "0", CVAR_RENDERER | CVAR_BOOL, "bypasses all front end work, but 2D gui rendering still draws" ); idCVar r_skipUpdates( "r_skipUpdates", "0", CVAR_RENDERER | CVAR_BOOL, "1 = don't accept any entity or light updates, making everything static" ); idCVar r_skipOverlays( "r_skipOverlays", "0", CVAR_RENDERER | CVAR_BOOL, "skip overlay surfaces" ); idCVar r_skipSpecular( "r_skipSpecular", "0", CVAR_RENDERER | CVAR_BOOL | CVAR_CHEAT | CVAR_ARCHIVE, "use black for specular1" ); idCVar r_skipBump( "r_skipBump", "0", CVAR_RENDERER | CVAR_BOOL | CVAR_ARCHIVE, "uses a flat surface instead of the bump map" ); idCVar r_skipDiffuse( "r_skipDiffuse", "0", CVAR_RENDERER | CVAR_BOOL, "use black for diffuse" ); idCVar r_skipROQ( "r_skipROQ", "0", CVAR_RENDERER | CVAR_BOOL, "skip ROQ decoding" ); idCVar r_ignore( "r_ignore", "0", CVAR_RENDERER, "used for random debugging without defining new vars" ); idCVar r_ignore2( "r_ignore2", "0", CVAR_RENDERER, "used for random debugging without defining new vars" ); idCVar r_usePreciseTriangleInteractions( "r_usePreciseTriangleInteractions", "0", CVAR_RENDERER | CVAR_BOOL, "1 = do winding clipping to determine if each ambiguous tri should be lit" ); idCVar r_useCulling( "r_useCulling", "2", CVAR_RENDERER | CVAR_INTEGER, "0 = none, 1 = sphere, 2 = sphere + box", 0, 2, idCmdSystem::ArgCompletion_Integer<0,2> ); idCVar r_useLightCulling( "r_useLightCulling", "3", CVAR_RENDERER | CVAR_INTEGER, "0 = none, 1 = box, 2 = exact clip of polyhedron faces, 3 = also areas", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_useLightScissors( "r_useLightScissors", "1", CVAR_RENDERER | CVAR_BOOL, "1 = use custom scissor rectangle for each light" ); idCVar r_useClippedLightScissors( "r_useClippedLightScissors", "1", CVAR_RENDERER | CVAR_INTEGER, "0 = full screen when near clipped, 1 = exact when near clipped, 2 = exact always", 0, 2, idCmdSystem::ArgCompletion_Integer<0,2> ); idCVar r_useEntityCulling( "r_useEntityCulling", "1", CVAR_RENDERER | CVAR_BOOL, "0 = none, 1 = box" ); idCVar r_useEntityScissors( "r_useEntityScissors", "0", CVAR_RENDERER | CVAR_BOOL, "1 = use custom scissor rectangle for each entity" ); idCVar r_useInteractionCulling( "r_useInteractionCulling", "1", CVAR_RENDERER | CVAR_BOOL, "1 = cull interactions" ); idCVar r_useInteractionScissors( "r_useInteractionScissors", "2", CVAR_RENDERER | CVAR_INTEGER, "1 = use a custom scissor rectangle for each shadow interaction, 2 = also crop using portal scissors", -2, 2, idCmdSystem::ArgCompletion_Integer<-2,2> ); idCVar r_useShadowCulling( "r_useShadowCulling", "1", CVAR_RENDERER | CVAR_BOOL, "try to cull shadows from partially visible lights" ); idCVar r_useFrustumFarDistance( "r_useFrustumFarDistance", "0", CVAR_RENDERER | CVAR_FLOAT, "if != 0 force the view frustum far distance to this distance" ); idCVar r_clear( "r_clear", "2", CVAR_RENDERER, "force screen clear every frame, 1 = purple, 2 = black, 'r g b' = custom" ); idCVar r_offsetFactor( "r_offsetfactor", "0", CVAR_RENDERER | CVAR_FLOAT, "polygon offset parameter" ); idCVar r_offsetUnits( "r_offsetunits", "-600", CVAR_RENDERER | CVAR_FLOAT, "polygon offset parameter" ); idCVar r_shadowPolygonOffset( "r_shadowPolygonOffset", "-1", CVAR_RENDERER | CVAR_FLOAT, "bias value added to depth test for stencil shadow drawing" ); idCVar r_shadowPolygonFactor( "r_shadowPolygonFactor", "0", CVAR_RENDERER | CVAR_FLOAT, "scale value for stencil shadow drawing" ); idCVar r_frontBuffer( "r_frontBuffer", "0", CVAR_RENDERER | CVAR_BOOL, "draw to front buffer for debugging" ); idCVar r_skipSubviews( "r_skipSubviews", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = don't render any gui elements on surfaces" ); idCVar r_skipGuiShaders( "r_skipGuiShaders", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = skip all gui elements on surfaces, 2 = skip drawing but still handle events, 3 = draw but skip events", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_skipParticles( "r_skipParticles", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = skip all particle systems", 0, 1, idCmdSystem::ArgCompletion_Integer<0,1> ); idCVar r_subviewOnly( "r_subviewOnly", "0", CVAR_RENDERER | CVAR_BOOL, "1 = don't render main view, allowing subviews to be debugged" ); idCVar r_shadows( "r_shadows", "1", CVAR_RENDERER | CVAR_BOOL | CVAR_ARCHIVE, "enable shadows" ); idCVar r_testARBProgram( "r_testARBProgram", "0", CVAR_RENDERER | CVAR_BOOL, "experiment with vertex/fragment programs" ); idCVar r_testGamma( "r_testGamma", "0", CVAR_RENDERER | CVAR_FLOAT, "if > 0 draw a grid pattern to test gamma levels", 0, 195 ); idCVar r_testGammaBias( "r_testGammaBias", "0", CVAR_RENDERER | CVAR_FLOAT, "if > 0 draw a grid pattern to test gamma levels" ); idCVar r_testStepGamma( "r_testStepGamma", "0", CVAR_RENDERER | CVAR_FLOAT, "if > 0 draw a grid pattern to test gamma levels" ); idCVar r_lightScale( "r_lightScale", "2", CVAR_RENDERER | CVAR_FLOAT, "all light intensities are multiplied by this" ); idCVar r_lightSourceRadius( "r_lightSourceRadius", "0", CVAR_RENDERER | CVAR_FLOAT, "for soft-shadow sampling" ); idCVar r_flareSize( "r_flareSize", "1", CVAR_RENDERER | CVAR_FLOAT, "scale the flare deforms from the material def" ); idCVar r_useExternalShadows( "r_useExternalShadows", "1", CVAR_RENDERER | CVAR_INTEGER, "1 = skip drawing caps when outside the light volume, 2 = force to no caps for testing", 0, 2, idCmdSystem::ArgCompletion_Integer<0,2> ); idCVar r_useOptimizedShadows( "r_useOptimizedShadows", "1", CVAR_RENDERER | CVAR_BOOL, "use the dmap generated static shadow volumes" ); idCVar r_useScissor( "r_useScissor", "1", CVAR_RENDERER | CVAR_BOOL, "scissor clip as portals and lights are processed" ); idCVar r_useCombinerDisplayLists( "r_useCombinerDisplayLists", "1", CVAR_RENDERER | CVAR_BOOL | CVAR_NOCHEAT, "put all nvidia register combiner programming in display lists" ); idCVar r_useDepthBoundsTest( "r_useDepthBoundsTest", "1", CVAR_RENDERER | CVAR_BOOL, "use depth bounds test to reduce shadow fill" ); idCVar r_screenFraction( "r_screenFraction", "100", CVAR_RENDERER | CVAR_INTEGER, "for testing fill rate, the resolution of the entire screen can be changed" ); idCVar r_demonstrateBug( "r_demonstrateBug", "0", CVAR_RENDERER | CVAR_BOOL, "used during development to show IHV's their problems" ); idCVar r_usePortals( "r_usePortals", "1", CVAR_RENDERER | CVAR_BOOL, " 1 = use portals to perform area culling, otherwise draw everything" ); idCVar r_singleLight( "r_singleLight", "-1", CVAR_RENDERER | CVAR_INTEGER, "suppress all but one light" ); idCVar r_singleEntity( "r_singleEntity", "-1", CVAR_RENDERER | CVAR_INTEGER, "suppress all but one entity" ); idCVar r_singleSurface( "r_singleSurface", "-1", CVAR_RENDERER | CVAR_INTEGER, "suppress all but one surface on each entity" ); idCVar r_singleArea( "r_singleArea", "0", CVAR_RENDERER | CVAR_BOOL, "only draw the portal area the view is actually in" ); idCVar r_forceLoadImages( "r_forceLoadImages", "0", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_BOOL, "draw all images to screen after registration" ); idCVar r_orderIndexes( "r_orderIndexes", "1", CVAR_RENDERER | CVAR_BOOL, "perform index reorganization to optimize vertex use" ); idCVar r_lightAllBackFaces( "r_lightAllBackFaces", "0", CVAR_RENDERER | CVAR_BOOL, "light all the back faces, even when they would be shadowed" ); // visual debugging info idCVar r_showPortals( "r_showPortals", "0", CVAR_RENDERER | CVAR_BOOL, "draw portal outlines in color based on passed / not passed" ); idCVar r_showUnsmoothedTangents( "r_showUnsmoothedTangents", "0", CVAR_RENDERER | CVAR_BOOL, "if 1, put all nvidia register combiner programming in display lists" ); idCVar r_showSilhouette( "r_showSilhouette", "0", CVAR_RENDERER | CVAR_BOOL, "highlight edges that are casting shadow planes" ); idCVar r_showVertexColor( "r_showVertexColor", "0", CVAR_RENDERER | CVAR_BOOL, "draws all triangles with the solid vertex color" ); idCVar r_showUpdates( "r_showUpdates", "0", CVAR_RENDERER | CVAR_BOOL, "report entity and light updates and ref counts" ); idCVar r_showDemo( "r_showDemo", "0", CVAR_RENDERER | CVAR_BOOL, "report reads and writes to the demo file" ); idCVar r_showDynamic( "r_showDynamic", "0", CVAR_RENDERER | CVAR_BOOL, "report stats on dynamic surface generation" ); idCVar r_showLightScale( "r_showLightScale", "0", CVAR_RENDERER | CVAR_BOOL, "report the scale factor applied to drawing for overbrights" ); idCVar r_showDefs( "r_showDefs", "0", CVAR_RENDERER | CVAR_BOOL, "report the number of modeDefs and lightDefs in view" ); idCVar r_showTrace( "r_showTrace", "0", CVAR_RENDERER | CVAR_INTEGER, "show the intersection of an eye trace with the world", idCmdSystem::ArgCompletion_Integer<0,2> ); idCVar r_showIntensity( "r_showIntensity", "0", CVAR_RENDERER | CVAR_BOOL, "draw the screen colors based on intensity, red = 0, green = 128, blue = 255" ); idCVar r_showImages( "r_showImages", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = show all images instead of rendering, 2 = show in proportional size", 0, 2, idCmdSystem::ArgCompletion_Integer<0,2> ); idCVar r_showSmp( "r_showSmp", "0", CVAR_RENDERER | CVAR_BOOL, "show which end (front or back) is blocking" ); idCVar r_showLights( "r_showLights", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = just print volumes numbers, highlighting ones covering the view, 2 = also draw planes of each volume, 3 = also draw edges of each volume", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_showShadows( "r_showShadows", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = visualize the stencil shadow volumes, 2 = draw filled in", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_showShadowCount( "r_showShadowCount", "0", CVAR_RENDERER | CVAR_INTEGER, "colors screen based on shadow volume depth complexity, >= 2 = print overdraw count based on stencil index values, 3 = only show turboshadows, 4 = only show static shadows", 0, 4, idCmdSystem::ArgCompletion_Integer<0,4> ); idCVar r_showLightScissors( "r_showLightScissors", "0", CVAR_RENDERER | CVAR_BOOL, "show light scissor rectangles" ); idCVar r_showEntityScissors( "r_showEntityScissors", "0", CVAR_RENDERER | CVAR_BOOL, "show entity scissor rectangles" ); idCVar r_showInteractionFrustums( "r_showInteractionFrustums", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = show a frustum for each interaction, 2 = also draw lines to light origin, 3 = also draw entity bbox", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_showInteractionScissors( "r_showInteractionScissors", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = show screen rectangle which contains the interaction frustum, 2 = also draw construction lines", 0, 2, idCmdSystem::ArgCompletion_Integer<0,2> ); idCVar r_showLightCount( "r_showLightCount", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = colors surfaces based on light count, 2 = also count everything through walls, 3 = also print overdraw", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_showViewEntitys( "r_showViewEntitys", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = displays the bounding boxes of all view models, 2 = print index numbers" ); idCVar r_showTris( "r_showTris", "0", CVAR_RENDERER | CVAR_INTEGER, "enables wireframe rendering of the world, 1 = only draw visible ones, 2 = draw all front facing, 3 = draw all", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_showSurfaceInfo( "r_showSurfaceInfo", "0", CVAR_RENDERER | CVAR_BOOL, "show surface material name under crosshair" ); idCVar r_showNormals( "r_showNormals", "0", CVAR_RENDERER | CVAR_FLOAT, "draws wireframe normals" ); idCVar r_showMemory( "r_showMemory", "0", CVAR_RENDERER | CVAR_BOOL, "print frame memory utilization" ); idCVar r_showCull( "r_showCull", "0", CVAR_RENDERER | CVAR_BOOL, "report sphere and box culling stats" ); idCVar r_showInteractions( "r_showInteractions", "0", CVAR_RENDERER | CVAR_BOOL, "report interaction generation activity" ); idCVar r_showDepth( "r_showDepth", "0", CVAR_RENDERER | CVAR_BOOL, "display the contents of the depth buffer and the depth range" ); idCVar r_showSurfaces( "r_showSurfaces", "0", CVAR_RENDERER | CVAR_BOOL, "report surface/light/shadow counts" ); idCVar r_showPrimitives( "r_showPrimitives", "0", CVAR_RENDERER | CVAR_INTEGER, "report drawsurf/index/vertex counts" ); idCVar r_showEdges( "r_showEdges", "0", CVAR_RENDERER | CVAR_BOOL, "draw the sil edges" ); idCVar r_showTexturePolarity( "r_showTexturePolarity", "0", CVAR_RENDERER | CVAR_BOOL, "shade triangles by texture area polarity" ); idCVar r_showTangentSpace( "r_showTangentSpace", "0", CVAR_RENDERER | CVAR_INTEGER, "shade triangles by tangent space, 1 = use 1st tangent vector, 2 = use 2nd tangent vector, 3 = use normal vector", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_showDominantTri( "r_showDominantTri", "0", CVAR_RENDERER | CVAR_BOOL, "draw lines from vertexes to center of dominant triangles" ); idCVar r_showAlloc( "r_showAlloc", "0", CVAR_RENDERER | CVAR_BOOL, "report alloc/free counts" ); idCVar r_showTextureVectors( "r_showTextureVectors", "0", CVAR_RENDERER | CVAR_FLOAT, " if > 0 draw each triangles texture (tangent) vectors" ); idCVar r_showOverDraw( "r_showOverDraw", "0", CVAR_RENDERER | CVAR_INTEGER, "1 = geometry overdraw, 2 = light interaction overdraw, 3 = geometry and light interaction overdraw", 0, 3, idCmdSystem::ArgCompletion_Integer<0,3> ); idCVar r_lockSurfaces( "r_lockSurfaces", "0", CVAR_RENDERER | CVAR_BOOL, "allow moving the view point without changing the composition of the scene, including culling" ); idCVar r_useEntityCallbacks( "r_useEntityCallbacks", "1", CVAR_RENDERER | CVAR_BOOL, "if 0, issue the callback immediately at update time, rather than defering" ); idCVar r_showSkel( "r_showSkel", "0", CVAR_RENDERER | CVAR_INTEGER, "draw the skeleton when model animates, 1 = draw model with skeleton, 2 = draw skeleton only", 0, 2, idCmdSystem::ArgCompletion_Integer<0,2> ); idCVar r_jointNameScale( "r_jointNameScale", "0.02", CVAR_RENDERER | CVAR_FLOAT, "size of joint names when r_showskel is set to 1" ); idCVar r_jointNameOffset( "r_jointNameOffset", "0.5", CVAR_RENDERER | CVAR_FLOAT, "offset of joint names when r_showskel is set to 1" ); idCVar r_debugLineDepthTest( "r_debugLineDepthTest", "0", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_BOOL, "perform depth test on debug lines" ); idCVar r_debugLineWidth( "r_debugLineWidth", "1", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_BOOL, "width of debug lines" ); idCVar r_debugArrowStep( "r_debugArrowStep", "120", CVAR_RENDERER | CVAR_ARCHIVE | CVAR_INTEGER, "step size of arrow cone line rotation in degrees", 0, 120 ); idCVar r_debugPolygonFilled( "r_debugPolygonFilled", "1", CVAR_RENDERER | CVAR_BOOL, "draw a filled polygon" ); idCVar r_materialOverride( "r_materialOverride", "", CVAR_RENDERER, "overrides all materials", idCmdSystem::ArgCompletion_Decl ); idCVar r_debugRenderToTexture( "r_debugRenderToTexture", "0", CVAR_RENDERER | CVAR_INTEGER, "" ); // define qgl functions #define QGLPROC(name, rettype, args) rettype (APIENTRYP q##name) args; #include "renderer/qgl_proc.h" void ( APIENTRY * qglMultiTexCoord2fARB )( GLenum texture, GLfloat s, GLfloat t ); void ( APIENTRY * qglMultiTexCoord2fvARB )( GLenum texture, GLfloat *st ); void ( APIENTRY * qglActiveTextureARB )( GLenum texture ); void ( APIENTRY * qglClientActiveTextureARB )( GLenum texture ); void (APIENTRY *qglTexImage3D)(GLenum, GLint, GLint, GLsizei, GLsizei, GLsizei, GLint, GLenum, GLenum, const GLvoid *); void (APIENTRY * qglColorTableEXT)( int, int, int, int, int, const void * ); // EXT_stencil_two_side PFNGLACTIVESTENCILFACEEXTPROC qglActiveStencilFaceEXT; // ARB_texture_compression PFNGLCOMPRESSEDTEXIMAGE2DARBPROC qglCompressedTexImage2DARB; PFNGLGETCOMPRESSEDTEXIMAGEARBPROC qglGetCompressedTexImageARB; // ARB_vertex_buffer_object PFNGLBINDBUFFERARBPROC qglBindBufferARB; PFNGLDELETEBUFFERSARBPROC qglDeleteBuffersARB; PFNGLGENBUFFERSARBPROC qglGenBuffersARB; PFNGLISBUFFERARBPROC qglIsBufferARB; PFNGLBUFFERDATAARBPROC qglBufferDataARB; PFNGLBUFFERSUBDATAARBPROC qglBufferSubDataARB; PFNGLGETBUFFERSUBDATAARBPROC qglGetBufferSubDataARB; PFNGLMAPBUFFERARBPROC qglMapBufferARB; PFNGLUNMAPBUFFERARBPROC qglUnmapBufferARB; PFNGLGETBUFFERPARAMETERIVARBPROC qglGetBufferParameterivARB; PFNGLGETBUFFERPOINTERVARBPROC qglGetBufferPointervARB; // ARB_vertex_program / ARB_fragment_program PFNGLVERTEXATTRIBPOINTERARBPROC qglVertexAttribPointerARB; PFNGLENABLEVERTEXATTRIBARRAYARBPROC qglEnableVertexAttribArrayARB; PFNGLDISABLEVERTEXATTRIBARRAYARBPROC qglDisableVertexAttribArrayARB; PFNGLPROGRAMSTRINGARBPROC qglProgramStringARB; PFNGLBINDPROGRAMARBPROC qglBindProgramARB; PFNGLGENPROGRAMSARBPROC qglGenProgramsARB; PFNGLPROGRAMENVPARAMETER4FVARBPROC qglProgramEnvParameter4fvARB; PFNGLPROGRAMLOCALPARAMETER4FVARBPROC qglProgramLocalParameter4fvARB; // GL_EXT_depth_bounds_test PFNGLDEPTHBOUNDSEXTPROC qglDepthBoundsEXT; /* ================= R_CheckExtension ================= */ bool R_CheckExtension( const char *name ) { if ( !strstr( glConfig.extensions_string, name ) ) { common->Printf( "X..%s not found\n", name ); return false; } common->Printf( "...using %s\n", name ); return true; } /* ================== R_CheckPortableExtensions ================== */ static void R_CheckPortableExtensions( void ) { glConfig.glVersion = atof( glConfig.version_string ); // GL_ARB_multitexture glConfig.multitextureAvailable = R_CheckExtension( "GL_ARB_multitexture" ); if ( glConfig.multitextureAvailable ) { qglMultiTexCoord2fARB = (void(APIENTRY *)(GLenum, GLfloat, GLfloat))GLimp_ExtensionPointer( "glMultiTexCoord2fARB" ); qglMultiTexCoord2fvARB = (void(APIENTRY *)(GLenum, GLfloat *))GLimp_ExtensionPointer( "glMultiTexCoord2fvARB" ); qglActiveTextureARB = (void(APIENTRY *)(GLenum))GLimp_ExtensionPointer( "glActiveTextureARB" ); qglClientActiveTextureARB = (void(APIENTRY *)(GLenum))GLimp_ExtensionPointer( "glClientActiveTextureARB" ); qglGetIntegerv( GL_MAX_TEXTURE_UNITS_ARB, (GLint *)&glConfig.maxTextureUnits ); if ( glConfig.maxTextureUnits > MAX_MULTITEXTURE_UNITS ) { glConfig.maxTextureUnits = MAX_MULTITEXTURE_UNITS; } if ( glConfig.maxTextureUnits < 2 ) { glConfig.multitextureAvailable = false; // shouldn't ever happen } qglGetIntegerv( GL_MAX_TEXTURE_COORDS_ARB, (GLint *)&glConfig.maxTextureCoords ); qglGetIntegerv( GL_MAX_TEXTURE_IMAGE_UNITS_ARB, (GLint *)&glConfig.maxTextureImageUnits ); } // GL_ARB_texture_env_combine glConfig.textureEnvCombineAvailable = R_CheckExtension( "GL_ARB_texture_env_combine" ); // GL_ARB_texture_cube_map glConfig.cubeMapAvailable = R_CheckExtension( "GL_ARB_texture_cube_map" ); // GL_ARB_texture_env_dot3 glConfig.envDot3Available = R_CheckExtension( "GL_ARB_texture_env_dot3" ); // GL_ARB_texture_env_add glConfig.textureEnvAddAvailable = R_CheckExtension( "GL_ARB_texture_env_add" ); // GL_ARB_texture_non_power_of_two glConfig.textureNonPowerOfTwoAvailable = R_CheckExtension( "GL_ARB_texture_non_power_of_two" ); // GL_ARB_texture_compression + GL_S3_s3tc // DRI drivers may have GL_ARB_texture_compression but no GL_EXT_texture_compression_s3tc if ( R_CheckExtension( "GL_ARB_texture_compression" ) && R_CheckExtension( "GL_EXT_texture_compression_s3tc" ) ) { glConfig.textureCompressionAvailable = true; qglCompressedTexImage2DARB = (PFNGLCOMPRESSEDTEXIMAGE2DARBPROC)GLimp_ExtensionPointer( "glCompressedTexImage2DARB" ); qglGetCompressedTexImageARB = (PFNGLGETCOMPRESSEDTEXIMAGEARBPROC)GLimp_ExtensionPointer( "glGetCompressedTexImageARB" ); } else { glConfig.textureCompressionAvailable = false; } // GL_EXT_texture_filter_anisotropic glConfig.anisotropicAvailable = R_CheckExtension( "GL_EXT_texture_filter_anisotropic" ); if ( glConfig.anisotropicAvailable ) { qglGetFloatv( GL_MAX_TEXTURE_MAX_ANISOTROPY_EXT, &glConfig.maxTextureAnisotropy ); common->Printf( " maxTextureAnisotropy: %f\n", glConfig.maxTextureAnisotropy ); } else { glConfig.maxTextureAnisotropy = 1; } // GL_EXT_texture_lod_bias // The actual extension is broken as specificed, storing the state in the texture unit instead // of the texture object. The behavior in GL 1.4 is the behavior we use. if ( glConfig.glVersion >= 1.4 || R_CheckExtension( "GL_EXT_texture_lod" ) ) { common->Printf( "...using %s\n", "GL_1.4_texture_lod_bias" ); glConfig.textureLODBiasAvailable = true; } else { common->Printf( "X..%s not found\n", "GL_1.4_texture_lod_bias" ); glConfig.textureLODBiasAvailable = false; } // GL_EXT_shared_texture_palette glConfig.sharedTexturePaletteAvailable = R_CheckExtension( "GL_EXT_shared_texture_palette" ); if ( glConfig.sharedTexturePaletteAvailable ) { qglColorTableEXT = ( void ( APIENTRY * ) ( int, int, int, int, int, const void * ) ) GLimp_ExtensionPointer( "glColorTableEXT" ); } // GL_EXT_texture3D (not currently used for anything) glConfig.texture3DAvailable = R_CheckExtension( "GL_EXT_texture3D" ); if ( glConfig.texture3DAvailable ) { qglTexImage3D = (void (APIENTRY *)(GLenum, GLint, GLint, GLsizei, GLsizei, GLsizei, GLint, GLenum, GLenum, const GLvoid *) ) GLimp_ExtensionPointer( "glTexImage3D" ); } // EXT_stencil_wrap // This isn't very important, but some pathological case might cause a clamp error and give a shadow bug. // Nvidia also believes that future hardware may be able to run faster with this enabled to avoid the // serialization of clamping. if ( R_CheckExtension( "GL_EXT_stencil_wrap" ) ) { tr.stencilIncr = GL_INCR_WRAP_EXT; tr.stencilDecr = GL_DECR_WRAP_EXT; } else { tr.stencilIncr = GL_INCR; tr.stencilDecr = GL_DECR; } // GL_EXT_stencil_two_side glConfig.twoSidedStencilAvailable = R_CheckExtension( "GL_EXT_stencil_two_side" ); if ( glConfig.twoSidedStencilAvailable ) qglActiveStencilFaceEXT = (PFNGLACTIVESTENCILFACEEXTPROC)GLimp_ExtensionPointer( "glActiveStencilFaceEXT" ); // ARB_vertex_buffer_object glConfig.ARBVertexBufferObjectAvailable = R_CheckExtension( "GL_ARB_vertex_buffer_object" ); if(glConfig.ARBVertexBufferObjectAvailable) { qglBindBufferARB = (PFNGLBINDBUFFERARBPROC)GLimp_ExtensionPointer( "glBindBufferARB"); qglDeleteBuffersARB = (PFNGLDELETEBUFFERSARBPROC)GLimp_ExtensionPointer( "glDeleteBuffersARB"); qglGenBuffersARB = (PFNGLGENBUFFERSARBPROC)GLimp_ExtensionPointer( "glGenBuffersARB"); qglIsBufferARB = (PFNGLISBUFFERARBPROC)GLimp_ExtensionPointer( "glIsBufferARB"); qglBufferDataARB = (PFNGLBUFFERDATAARBPROC)GLimp_ExtensionPointer( "glBufferDataARB"); qglBufferSubDataARB = (PFNGLBUFFERSUBDATAARBPROC)GLimp_ExtensionPointer( "glBufferSubDataARB"); qglGetBufferSubDataARB = (PFNGLGETBUFFERSUBDATAARBPROC)GLimp_ExtensionPointer( "glGetBufferSubDataARB"); qglMapBufferARB = (PFNGLMAPBUFFERARBPROC)GLimp_ExtensionPointer( "glMapBufferARB"); qglUnmapBufferARB = (PFNGLUNMAPBUFFERARBPROC)GLimp_ExtensionPointer( "glUnmapBufferARB"); qglGetBufferParameterivARB = (PFNGLGETBUFFERPARAMETERIVARBPROC)GLimp_ExtensionPointer( "glGetBufferParameterivARB"); qglGetBufferPointervARB = (PFNGLGETBUFFERPOINTERVARBPROC)GLimp_ExtensionPointer( "glGetBufferPointervARB"); } // ARB_vertex_program glConfig.ARBVertexProgramAvailable = R_CheckExtension( "GL_ARB_vertex_program" ); if (glConfig.ARBVertexProgramAvailable) { qglVertexAttribPointerARB = (PFNGLVERTEXATTRIBPOINTERARBPROC)GLimp_ExtensionPointer( "glVertexAttribPointerARB" ); qglEnableVertexAttribArrayARB = (PFNGLENABLEVERTEXATTRIBARRAYARBPROC)GLimp_ExtensionPointer( "glEnableVertexAttribArrayARB" ); qglDisableVertexAttribArrayARB = (PFNGLDISABLEVERTEXATTRIBARRAYARBPROC)GLimp_ExtensionPointer( "glDisableVertexAttribArrayARB" ); qglProgramStringARB = (PFNGLPROGRAMSTRINGARBPROC)GLimp_ExtensionPointer( "glProgramStringARB" ); qglBindProgramARB = (PFNGLBINDPROGRAMARBPROC)GLimp_ExtensionPointer( "glBindProgramARB" ); qglGenProgramsARB = (PFNGLGENPROGRAMSARBPROC)GLimp_ExtensionPointer( "glGenProgramsARB" ); qglProgramEnvParameter4fvARB = (PFNGLPROGRAMENVPARAMETER4FVARBPROC)GLimp_ExtensionPointer( "glProgramEnvParameter4fvARB" ); qglProgramLocalParameter4fvARB = (PFNGLPROGRAMLOCALPARAMETER4FVARBPROC)GLimp_ExtensionPointer( "glProgramLocalParameter4fvARB" ); } // ARB_fragment_program if ( r_inhibitFragmentProgram.GetBool() ) { glConfig.ARBFragmentProgramAvailable = false; } else { glConfig.ARBFragmentProgramAvailable = R_CheckExtension( "GL_ARB_fragment_program" ); if (glConfig.ARBFragmentProgramAvailable) { // these are the same as ARB_vertex_program qglProgramStringARB = (PFNGLPROGRAMSTRINGARBPROC)GLimp_ExtensionPointer( "glProgramStringARB" ); qglBindProgramARB = (PFNGLBINDPROGRAMARBPROC)GLimp_ExtensionPointer( "glBindProgramARB" ); qglProgramEnvParameter4fvARB = (PFNGLPROGRAMENVPARAMETER4FVARBPROC)GLimp_ExtensionPointer( "glProgramEnvParameter4fvARB" ); qglProgramLocalParameter4fvARB = (PFNGLPROGRAMLOCALPARAMETER4FVARBPROC)GLimp_ExtensionPointer( "glProgramLocalParameter4fvARB" ); } } // check for minimum set if ( !glConfig.multitextureAvailable || !glConfig.textureEnvCombineAvailable || !glConfig.cubeMapAvailable || !glConfig.envDot3Available ) { common->Error( common->GetLanguageDict()->GetString( "#str_06780" ) ); } // GL_EXT_depth_bounds_test glConfig.depthBoundsTestAvailable = R_CheckExtension( "EXT_depth_bounds_test" ); if ( glConfig.depthBoundsTestAvailable ) { qglDepthBoundsEXT = (PFNGLDEPTHBOUNDSEXTPROC)GLimp_ExtensionPointer( "glDepthBoundsEXT" ); } } /* ==================== R_GetModeInfo r_mode is normally a small non-negative integer that looks resolutions up in a table, but if it is set to -1, the values from r_customWidth, amd r_customHeight will be used instead. ==================== */ typedef struct vidmode_s { const char *description; int width, height; } vidmode_t; vidmode_t r_vidModes[] = { { "Mode 0: 320x240", 320, 240 }, { "Mode 1: 400x300", 400, 300 }, { "Mode 2: 512x384", 512, 384 }, { "Mode 3: 640x480", 640, 480 }, { "Mode 4: 800x600", 800, 600 }, { "Mode 5: 1024x768", 1024, 768 }, { "Mode 6: 1152x864", 1152, 864 }, { "Mode 7: 1280x1024", 1280, 1024 }, { "Mode 8: 1600x1200", 1600, 1200 }, }; static int s_numVidModes = ( sizeof( r_vidModes ) / sizeof( r_vidModes[0] ) ); static bool R_GetModeInfo( int *width, int *height, int mode ) { vidmode_t *vm; if ( mode < -1 ) { return false; } if ( mode >= s_numVidModes ) { return false; } if ( mode == -1 ) { *width = r_customWidth.GetInteger(); *height = r_customHeight.GetInteger(); return true; } vm = &r_vidModes[mode]; if ( width ) { *width = vm->width; } if ( height ) { *height = vm->height; } return true; } /* ================== R_InitOpenGL This function is responsible for initializing a valid OpenGL subsystem for rendering. This is done by calling the system specific GLimp_Init, which gives us a working OGL subsystem, then setting all necessary openGL state, including images, vertex programs, and display lists. Changes to the vertex cache size or smp state require a vid_restart. If glConfig.isInitialized is false, no rendering can take place, but all renderSystem functions will still operate properly, notably the material and model information functions. ================== */ void R_InitOpenGL( void ) { GLint temp; glimpParms_t parms; int i; common->Printf( "----- Initializing OpenGL -----\n" ); if ( glConfig.isInitialized ) { common->FatalError( "R_InitOpenGL called while active" ); } // in case we had an error while doing a tiled rendering tr.viewportOffset[0] = 0; tr.viewportOffset[1] = 0; // // initialize OS specific portions of the renderSystem // for ( i = 0 ; i < 2 ; i++ ) { // set the parameters we are trying R_GetModeInfo( &glConfig.vidWidth, &glConfig.vidHeight, r_mode.GetInteger() ); parms.width = glConfig.vidWidth; parms.height = glConfig.vidHeight; parms.fullScreen = r_fullscreen.GetBool(); parms.displayHz = r_displayRefresh.GetInteger(); parms.multiSamples = r_multiSamples.GetInteger(); parms.stereo = false; if ( GLimp_Init( parms ) ) { // it worked break; } if ( i == 1 ) { common->FatalError( "Unable to initialize OpenGL" ); } // if we failed, set everything back to "safe mode" // and try again r_mode.SetInteger( 3 ); r_fullscreen.SetInteger( 1 ); r_displayRefresh.SetInteger( 0 ); r_multiSamples.SetInteger( 0 ); } // load qgl function pointers #define QGLPROC(name, rettype, args) \ q##name = (rettype(APIENTRYP)args)GLimp_ExtensionPointer(#name); \ if (!q##name) \ common->FatalError("Unable to initialize OpenGL (%s)", #name); #include "renderer/qgl_proc.h" // input and sound systems need to be tied to the new window Sys_InitInput(); soundSystem->InitHW(); // get our config strings glConfig.vendor_string = (const char *)qglGetString(GL_VENDOR); glConfig.renderer_string = (const char *)qglGetString(GL_RENDERER); glConfig.version_string = (const char *)qglGetString(GL_VERSION); glConfig.extensions_string = (const char *)qglGetString(GL_EXTENSIONS); // OpenGL driver constants qglGetIntegerv( GL_MAX_TEXTURE_SIZE, &temp ); glConfig.maxTextureSize = temp; // stubbed or broken drivers may have reported 0... if ( glConfig.maxTextureSize <= 0 ) { glConfig.maxTextureSize = 256; } glConfig.isInitialized = true; common->Printf("OpenGL vendor: %s\n", glConfig.vendor_string ); common->Printf("OpenGL renderer: %s\n", glConfig.renderer_string ); common->Printf("OpenGL version: %s\n", glConfig.version_string ); // recheck all the extensions (FIXME: this might be dangerous) R_CheckPortableExtensions(); // parse our vertex and fragment programs, possibly disably support for // one of the paths if there was an error R_ARB2_Init(); cmdSystem->AddCommand( "reloadARBprograms", R_ReloadARBPrograms_f, CMD_FL_RENDERER, "reloads ARB programs" ); R_ReloadARBPrograms_f( idCmdArgs() ); // allocate the vertex array range or vertex objects vertexCache.Init(); // select which renderSystem we are going to use r_renderer.SetModified(); tr.SetBackEndRenderer(); // allocate the frame data, which may be more if smp is enabled R_InitFrameData(); // Reset our gamma R_SetColorMappings(); #ifdef _WIN32 static bool glCheck = false; if ( !glCheck && win32.osversion.dwMajorVersion == 6 ) { glCheck = true; if ( !idStr::Icmp( glConfig.vendor_string, "Microsoft" ) && idStr::FindText( glConfig.renderer_string, "OpenGL-D3D" ) != -1 ) { if ( cvarSystem->GetCVarBool( "r_fullscreen" ) ) { cmdSystem->BufferCommandText( CMD_EXEC_NOW, "vid_restart partial windowed\n" ); Sys_GrabMouseCursor( false ); } int ret = MessageBox( NULL, "Please install OpenGL drivers from your graphics hardware vendor to run " GAME_NAME ".\nYour OpenGL functionality is limited.", "Insufficient OpenGL capabilities", MB_OKCANCEL | MB_ICONWARNING | MB_TASKMODAL ); if ( ret == IDCANCEL ) { cmdSystem->BufferCommandText( CMD_EXEC_APPEND, "quit\n" ); cmdSystem->ExecuteCommandBuffer(); } if ( cvarSystem->GetCVarBool( "r_fullscreen" ) ) { cmdSystem->BufferCommandText( CMD_EXEC_APPEND, "vid_restart\n" ); } } } #endif } /* ================== GL_CheckErrors ================== */ void GL_CheckErrors( void ) { int err; char s[64]; int i; // check for up to 10 errors pending for ( i = 0 ; i < 10 ; i++ ) { err = qglGetError(); if ( err == GL_NO_ERROR ) { return; } switch( err ) { case GL_INVALID_ENUM: strcpy( s, "GL_INVALID_ENUM" ); break; case GL_INVALID_VALUE: strcpy( s, "GL_INVALID_VALUE" ); break; case GL_INVALID_OPERATION: strcpy( s, "GL_INVALID_OPERATION" ); break; case GL_STACK_OVERFLOW: strcpy( s, "GL_STACK_OVERFLOW" ); break; case GL_STACK_UNDERFLOW: strcpy( s, "GL_STACK_UNDERFLOW" ); break; case GL_OUT_OF_MEMORY: strcpy( s, "GL_OUT_OF_MEMORY" ); break; default: idStr::snPrintf( s, sizeof(s), "%i", err); break; } if ( !r_ignoreGLErrors.GetBool() ) { common->Printf( "GL_CheckErrors: %s\n", s ); } } } /* ===================== R_ReloadSurface_f Reload the material displayed by r_showSurfaceInfo ===================== */ static void R_ReloadSurface_f( const idCmdArgs &args ) { modelTrace_t mt; idVec3 start, end; // start far enough away that we don't hit the player model start = tr.primaryView->renderView.vieworg + tr.primaryView->renderView.viewaxis[0] * 16; end = start + tr.primaryView->renderView.viewaxis[0] * 1000.0f; if ( !tr.primaryWorld->Trace( mt, start, end, 0.0f, false ) ) { return; } common->Printf( "Reloading %s\n", mt.material->GetName() ); // reload the decl mt.material->base->Reload(); // reload any images used by the decl mt.material->ReloadImages( false ); } /* ============== R_ListModes_f ============== */ static void R_ListModes_f( const idCmdArgs &args ) { int i; common->Printf( "\n" ); for ( i = 0; i < s_numVidModes; i++ ) { common->Printf( "%s\n", r_vidModes[i].description ); } common->Printf( "\n" ); } /* ============= R_TestImage_f Display the given image centered on the screen. testimage testimage ============= */ void R_TestImage_f( const idCmdArgs &args ) { int imageNum; if ( tr.testVideo ) { delete tr.testVideo; tr.testVideo = NULL; } tr.testImage = NULL; if ( args.Argc() != 2 ) { return; } if ( idStr::IsNumeric( args.Argv(1) ) ) { imageNum = atoi( args.Argv(1) ); if ( imageNum >= 0 && imageNum < globalImages->images.Num() ) { tr.testImage = globalImages->images[imageNum]; } } else { tr.testImage = globalImages->ImageFromFile( args.Argv( 1 ), TF_DEFAULT, false, TR_REPEAT, TD_DEFAULT ); } } /* ============= R_TestVideo_f Plays the cinematic file in a testImage ============= */ void R_TestVideo_f( const idCmdArgs &args ) { if ( tr.testVideo ) { delete tr.testVideo; tr.testVideo = NULL; } tr.testImage = NULL; if ( args.Argc() < 2 ) { return; } tr.testImage = globalImages->ImageFromFile( "_scratch", TF_DEFAULT, false, TR_REPEAT, TD_DEFAULT ); tr.testVideo = idCinematic::Alloc(); tr.testVideo->InitFromFile( args.Argv( 1 ), true ); cinData_t cin; cin = tr.testVideo->ImageForTime( 0 ); if ( !cin.image ) { delete tr.testVideo; tr.testVideo = NULL; tr.testImage = NULL; return; } common->Printf( "%i x %i images\n", cin.imageWidth, cin.imageHeight ); int len = tr.testVideo->AnimationLength(); common->Printf( "%5.1f seconds of video\n", len * 0.001 ); tr.testVideoStartTime = tr.primaryRenderView.time * 0.001; // try to play the matching wav file idStr wavString = args.Argv( ( args.Argc() == 2 ) ? 1 : 2 ); wavString.StripFileExtension(); wavString = wavString + ".wav"; session->sw->PlayShaderDirectly( wavString.c_str() ); } static int R_QsortSurfaceAreas( const void *a, const void *b ) { const idMaterial *ea, *eb; int ac, bc; ea = *(idMaterial **)a; if ( !ea->EverReferenced() ) { ac = 0; } else { ac = ea->GetSurfaceArea(); } eb = *(idMaterial **)b; if ( !eb->EverReferenced() ) { bc = 0; } else { bc = eb->GetSurfaceArea(); } if ( ac < bc ) { return -1; } if ( ac > bc ) { return 1; } return idStr::Icmp( ea->GetName(), eb->GetName() ); } /* =================== R_ReportSurfaceAreas_f Prints a list of the materials sorted by surface area =================== */ void R_ReportSurfaceAreas_f( const idCmdArgs &args ) { int i, count; idMaterial **list; count = declManager->GetNumDecls( DECL_MATERIAL ); list = (idMaterial **)_alloca( count * sizeof( *list ) ); for ( i = 0 ; i < count ; i++ ) { list[i] = (idMaterial *)declManager->DeclByIndex( DECL_MATERIAL, i, false ); } qsort( list, count, sizeof( list[0] ), R_QsortSurfaceAreas ); // skip over ones with 0 area for ( i = 0 ; i < count ; i++ ) { if ( list[i]->GetSurfaceArea() > 0 ) { break; } } for ( ; i < count ; i++ ) { // report size in "editor blocks" int blocks = list[i]->GetSurfaceArea() / 4096.0; common->Printf( "%7i %s\n", blocks, list[i]->GetName() ); } } /* =================== R_ReportImageDuplication_f Checks for images with the same hash value and does a better comparison =================== */ void R_ReportImageDuplication_f( const idCmdArgs &args ) { int i, j; common->Printf( "Images with duplicated contents:\n" ); int count = 0; for ( i = 0 ; i < globalImages->images.Num() ; i++ ) { idImage *image1 = globalImages->images[i]; if ( image1->isPartialImage ) { // ignore background loading stubs continue; } if ( image1->generatorFunction ) { // ignore procedural images continue; } if ( image1->cubeFiles != CF_2D ) { // ignore cube maps continue; } if ( image1->defaulted ) { continue; } byte *data1; int w1, h1; R_LoadImageProgram( image1->imgName, &data1, &w1, &h1, NULL ); for ( j = 0 ; j < i ; j++ ) { idImage *image2 = globalImages->images[j]; if ( image2->isPartialImage ) { continue; } if ( image2->generatorFunction ) { continue; } if ( image2->cubeFiles != CF_2D ) { continue; } if ( image2->defaulted ) { continue; } if ( image1->imageHash != image2->imageHash ) { continue; } if ( image2->uploadWidth != image1->uploadWidth || image2->uploadHeight != image1->uploadHeight ) { continue; } if ( !idStr::Icmp( image1->imgName, image2->imgName ) ) { // ignore same image-with-different-parms continue; } byte *data2; int w2, h2; R_LoadImageProgram( image2->imgName, &data2, &w2, &h2, NULL ); if ( w2 != w1 || h2 != h1 ) { R_StaticFree( data2 ); continue; } if ( memcmp( data1, data2, w1*h1*4 ) ) { R_StaticFree( data2 ); continue; } R_StaticFree( data2 ); common->Printf( "%s == %s\n", image1->imgName.c_str(), image2->imgName.c_str() ); session->UpdateScreen( true ); count++; break; } R_StaticFree( data1 ); } common->Printf( "%i / %i collisions\n", count, globalImages->images.Num() ); } /* ============================================================================== THROUGHPUT BENCHMARKING ============================================================================== */ /* ================ R_RenderingFPS ================ */ static float R_RenderingFPS( const renderView_t *renderView ) { qglFinish(); int start = Sys_Milliseconds(); static const int SAMPLE_MSEC = 1000; int end; int count = 0; while( 1 ) { // render renderSystem->BeginFrame( glConfig.vidWidth, glConfig.vidHeight ); tr.primaryWorld->RenderScene( renderView ); renderSystem->EndFrame( NULL, NULL ); qglFinish(); count++; end = Sys_Milliseconds(); if ( end - start > SAMPLE_MSEC ) { break; } } float fps = count * 1000.0 / ( end - start ); return fps; } /* ================ R_Benchmark_f ================ */ void R_Benchmark_f( const idCmdArgs &args ) { float fps, msec; renderView_t view; if ( !tr.primaryView ) { common->Printf( "No primaryView for benchmarking\n" ); return; } view = tr.primaryRenderView; for ( int size = 100 ; size >= 10 ; size -= 10 ) { r_screenFraction.SetInteger( size ); fps = R_RenderingFPS( &view ); int kpix = glConfig.vidWidth * glConfig.vidHeight * ( size * 0.01 ) * ( size * 0.01 ) * 0.001; msec = 1000.0 / fps; common->Printf( "kpix: %4i msec:%5.1f fps:%5.1f\n", kpix, msec, fps ); } // enable r_singleTriangle 1 while r_screenFraction is still at 10 r_singleTriangle.SetBool( 1 ); fps = R_RenderingFPS( &view ); msec = 1000.0 / fps; common->Printf( "single tri msec:%5.1f fps:%5.1f\n", msec, fps ); r_singleTriangle.SetBool( 0 ); r_screenFraction.SetInteger( 100 ); // enable r_skipRenderContext 1 r_skipRenderContext.SetBool( true ); fps = R_RenderingFPS( &view ); msec = 1000.0 / fps; common->Printf( "no context msec:%5.1f fps:%5.1f\n", msec, fps ); r_skipRenderContext.SetBool( false ); } /* ============================================================================== SCREEN SHOTS ============================================================================== */ /* ==================== R_ReadTiledPixels Allows the rendering of an image larger than the actual window by tiling it into window-sized chunks and rendering each chunk separately If ref isn't specified, the full session UpdateScreen will be done. ==================== */ void R_ReadTiledPixels( int width, int height, byte *buffer, renderView_t *ref = NULL ) { // include extra space for OpenGL padding to word boundaries byte *temp = (byte *)R_StaticAlloc( (glConfig.vidWidth+3) * glConfig.vidHeight * 3 ); int oldWidth = glConfig.vidWidth; int oldHeight = glConfig.vidHeight; tr.tiledViewport[0] = width; tr.tiledViewport[1] = height; // disable scissor, so we don't need to adjust all those rects r_useScissor.SetBool( false ); for ( int xo = 0 ; xo < width ; xo += oldWidth ) { for ( int yo = 0 ; yo < height ; yo += oldHeight ) { tr.viewportOffset[0] = -xo; tr.viewportOffset[1] = -yo; if ( ref ) { tr.BeginFrame( oldWidth, oldHeight ); tr.primaryWorld->RenderScene( ref ); tr.EndFrame( NULL, NULL ); } else { session->UpdateScreen(); } int w = oldWidth; if ( xo + w > width ) { w = width - xo; } int h = oldHeight; if ( yo + h > height ) { h = height - yo; } qglReadBuffer( GL_FRONT ); qglReadPixels( 0, 0, w, h, GL_RGB, GL_UNSIGNED_BYTE, temp ); int row = ( w * 3 + 3 ) & ~3; // OpenGL pads to dword boundaries for ( int y = 0 ; y < h ; y++ ) { memcpy( buffer + ( ( yo + y )* width + xo ) * 3, temp + y * row, w * 3 ); } } } r_useScissor.SetBool( true ); tr.viewportOffset[0] = 0; tr.viewportOffset[1] = 0; tr.tiledViewport[0] = 0; tr.tiledViewport[1] = 0; R_StaticFree( temp ); glConfig.vidWidth = oldWidth; glConfig.vidHeight = oldHeight; } /* ================== TakeScreenshot Move to tr_imagefiles.c... Will automatically tile render large screen shots if necessary Downsample is the number of steps to mipmap the image before saving it If ref == NULL, session->updateScreen will be used ================== */ void idRenderSystemLocal::TakeScreenshot( int width, int height, const char *fileName, int blends, renderView_t *ref ) { byte *buffer; int i, j, c, temp; takingScreenshot = true; int pix = width * height; buffer = (byte *)R_StaticAlloc(pix*3 + 18); memset (buffer, 0, 18); if ( blends <= 1 ) { R_ReadTiledPixels( width, height, buffer + 18, ref ); } else { unsigned short *shortBuffer = (unsigned short *)R_StaticAlloc(pix*2*3); memset (shortBuffer, 0, pix*2*3); // enable anti-aliasing jitter r_jitter.SetBool( true ); for ( i = 0 ; i < blends ; i++ ) { R_ReadTiledPixels( width, height, buffer + 18, ref ); for ( j = 0 ; j < pix*3 ; j++ ) { shortBuffer[j] += buffer[18+j]; } } // divide back to bytes for ( i = 0 ; i < pix*3 ; i++ ) { buffer[18+i] = shortBuffer[i] / blends; } R_StaticFree( shortBuffer ); r_jitter.SetBool( false ); } // fill in the header (this is vertically flipped, which qglReadPixels emits) buffer[2] = 2; // uncompressed type buffer[12] = width & 255; buffer[13] = width >> 8; buffer[14] = height & 255; buffer[15] = height >> 8; buffer[16] = 24; // pixel size // swap rgb to bgr c = 18 + width * height * 3; for (i=18 ; iWriteFile( fileName, buffer, c, "fs_cdpath" ); } else { fileSystem->WriteFile( fileName, buffer, c ); } R_StaticFree( buffer ); takingScreenshot = false; } /* ================== R_ScreenshotFilename Returns a filename with digits appended if we have saved a previous screenshot, don't scan from the beginning, because recording demo avis can involve thousands of shots ================== */ void R_ScreenshotFilename( int &lastNumber, const char *base, idStr &fileName ) { int a,b,c,d, e; bool restrict = cvarSystem->GetCVarBool( "fs_restrict" ); cvarSystem->SetCVarBool( "fs_restrict", false ); lastNumber++; if ( lastNumber > 99999 ) { lastNumber = 99999; } for ( ; lastNumber < 99999 ; lastNumber++ ) { int frac = lastNumber; a = frac / 10000; frac -= a*10000; b = frac / 1000; frac -= b*1000; c = frac / 100; frac -= c*100; d = frac / 10; frac -= d*10; e = frac; sprintf( fileName, "%s%i%i%i%i%i.tga", base, a, b, c, d, e ); if ( lastNumber == 99999 ) { break; } int len = fileSystem->ReadFile( fileName, NULL, NULL ); if ( len <= 0 ) { break; } // check again... } cvarSystem->SetCVarBool( "fs_restrict", restrict ); } /* ================== R_BlendedScreenShot screenshot screenshot [filename] screenshot [width] [height] screenshot [width] [height] [samples] ================== */ #define MAX_BLENDS 256 // to keep the accumulation in shorts void R_ScreenShot_f( const idCmdArgs &args ) { static int lastNumber = 0; idStr checkname; int width = glConfig.vidWidth; int height = glConfig.vidHeight; int blends = 0; switch ( args.Argc() ) { case 1: width = glConfig.vidWidth; height = glConfig.vidHeight; blends = 1; R_ScreenshotFilename( lastNumber, "screenshots/shot", checkname ); break; case 2: width = glConfig.vidWidth; height = glConfig.vidHeight; blends = 1; checkname = args.Argv( 1 ); break; case 3: width = atoi( args.Argv( 1 ) ); height = atoi( args.Argv( 2 ) ); blends = 1; R_ScreenshotFilename( lastNumber, "screenshots/shot", checkname ); break; case 4: width = atoi( args.Argv( 1 ) ); height = atoi( args.Argv( 2 ) ); blends = atoi( args.Argv( 3 ) ); if ( blends < 1 ) { blends = 1; } if ( blends > MAX_BLENDS ) { blends = MAX_BLENDS; } R_ScreenshotFilename( lastNumber, "screenshots/shot", checkname ); break; default: common->Printf( "usage: screenshot\n screenshot \n screenshot \n screenshot \n" ); return; } // put the console away console->Close(); tr.TakeScreenshot( width, height, checkname, blends, NULL ); common->Printf( "Wrote %s\n", checkname.c_str() ); } /* =============== R_StencilShot Save out a screenshot showing the stencil buffer expanded by 16x range =============== */ void R_StencilShot( void ) { byte *buffer; int i, c; int width = tr.GetScreenWidth(); int height = tr.GetScreenHeight(); int pix = width * height; c = pix * 3 + 18; buffer = (byte *)Mem_Alloc(c); memset (buffer, 0, 18); byte *byteBuffer = (byte *)Mem_Alloc(pix); qglReadPixels( 0, 0, width, height, GL_STENCIL_INDEX , GL_UNSIGNED_BYTE, byteBuffer ); for ( i = 0 ; i < pix ; i++ ) { buffer[18+i*3] = buffer[18+i*3+1] = // buffer[18+i*3+2] = ( byteBuffer[i] & 15 ) * 16; buffer[18+i*3+2] = byteBuffer[i]; } // fill in the header (this is vertically flipped, which qglReadPixels emits) buffer[2] = 2; // uncompressed type buffer[12] = width & 255; buffer[13] = width >> 8; buffer[14] = height & 255; buffer[15] = height >> 8; buffer[16] = 24; // pixel size fileSystem->WriteFile( "screenshots/stencilShot.tga", buffer, c, "fs_savepath" ); Mem_Free( buffer ); Mem_Free( byteBuffer ); } /* ================== R_EnvShot_f envshot Saves out env/_ft.tga, etc ================== */ void R_EnvShot_f( const idCmdArgs &args ) { idStr fullname; const char *baseName; int i; idMat3 axis[6]; renderView_t ref; viewDef_t primary; int blends; const char *extensions[6] = { "_px.tga", "_nx.tga", "_py.tga", "_ny.tga", "_pz.tga", "_nz.tga" }; int size; if ( args.Argc() != 2 && args.Argc() != 3 && args.Argc() != 4 ) { common->Printf( "USAGE: envshot [size] [blends]\n" ); return; } baseName = args.Argv( 1 ); blends = 1; if ( args.Argc() == 4 ) { size = atoi( args.Argv( 2 ) ); blends = atoi( args.Argv( 3 ) ); } else if ( args.Argc() == 3 ) { size = atoi( args.Argv( 2 ) ); blends = 1; } else { size = 256; blends = 1; } if ( !tr.primaryView ) { common->Printf( "No primary view.\n" ); return; } primary = *tr.primaryView; memset( &axis, 0, sizeof( axis ) ); axis[0][0][0] = 1; axis[0][1][2] = 1; axis[0][2][1] = 1; axis[1][0][0] = -1; axis[1][1][2] = -1; axis[1][2][1] = 1; axis[2][0][1] = 1; axis[2][1][0] = -1; axis[2][2][2] = -1; axis[3][0][1] = -1; axis[3][1][0] = -1; axis[3][2][2] = 1; axis[4][0][2] = 1; axis[4][1][0] = -1; axis[4][2][1] = 1; axis[5][0][2] = -1; axis[5][1][0] = 1; axis[5][2][1] = 1; for ( i = 0 ; i < 6 ; i++ ) { ref = primary.renderView; ref.x = ref.y = 0; ref.fov_x = ref.fov_y = 90; ref.width = glConfig.vidWidth; ref.height = glConfig.vidHeight; ref.viewaxis = axis[i]; sprintf( fullname, "env/%s%s", baseName, extensions[i] ); tr.TakeScreenshot( size, size, fullname, blends, &ref ); } common->Printf( "Wrote %s, etc\n", fullname.c_str() ); } //============================================================================ static idMat3 cubeAxis[6]; /* ================== R_SampleCubeMap ================== */ void R_SampleCubeMap( const idVec3 &dir, int size, byte *buffers[6], byte result[4] ) { float adir[3]; int axis, x, y; adir[0] = fabs(dir[0]); adir[1] = fabs(dir[1]); adir[2] = fabs(dir[2]); if ( dir[0] >= adir[1] && dir[0] >= adir[2] ) { axis = 0; } else if ( -dir[0] >= adir[1] && -dir[0] >= adir[2] ) { axis = 1; } else if ( dir[1] >= adir[0] && dir[1] >= adir[2] ) { axis = 2; } else if ( -dir[1] >= adir[0] && -dir[1] >= adir[2] ) { axis = 3; } else if ( dir[2] >= adir[1] && dir[2] >= adir[2] ) { axis = 4; } else { axis = 5; } float fx = (dir * cubeAxis[axis][1]) / (dir * cubeAxis[axis][0]); float fy = (dir * cubeAxis[axis][2]) / (dir * cubeAxis[axis][0]); fx = -fx; fy = -fy; x = size * 0.5 * (fx + 1); y = size * 0.5 * (fy + 1); if ( x < 0 ) { x = 0; } else if ( x >= size ) { x = size-1; } if ( y < 0 ) { y = 0; } else if ( y >= size ) { y = size-1; } result[0] = buffers[axis][(y*size+x)*4+0]; result[1] = buffers[axis][(y*size+x)*4+1]; result[2] = buffers[axis][(y*size+x)*4+2]; result[3] = buffers[axis][(y*size+x)*4+3]; } /* ================== R_MakeAmbientMap_f R_MakeAmbientMap_f [size] Saves out env/_amb_ft.tga, etc ================== */ void R_MakeAmbientMap_f( const idCmdArgs &args ) { idStr fullname; const char *baseName; int i; const char *extensions[6] = { "_px.tga", "_nx.tga", "_py.tga", "_ny.tga", "_pz.tga", "_nz.tga" }; int outSize; byte *buffers[6]; int width, height; if ( args.Argc() != 2 && args.Argc() != 3 ) { common->Printf( "USAGE: ambientshot [size]\n" ); return; } baseName = args.Argv( 1 ); if ( args.Argc() == 3 ) { outSize = atoi( args.Argv( 2 ) ); } else { outSize = 32; } memset( &cubeAxis, 0, sizeof( cubeAxis ) ); cubeAxis[0][0][0] = 1; cubeAxis[0][1][2] = 1; cubeAxis[0][2][1] = 1; cubeAxis[1][0][0] = -1; cubeAxis[1][1][2] = -1; cubeAxis[1][2][1] = 1; cubeAxis[2][0][1] = 1; cubeAxis[2][1][0] = -1; cubeAxis[2][2][2] = -1; cubeAxis[3][0][1] = -1; cubeAxis[3][1][0] = -1; cubeAxis[3][2][2] = 1; cubeAxis[4][0][2] = 1; cubeAxis[4][1][0] = -1; cubeAxis[4][2][1] = 1; cubeAxis[5][0][2] = -1; cubeAxis[5][1][0] = 1; cubeAxis[5][2][1] = 1; // read all of the images for ( i = 0 ; i < 6 ; i++ ) { sprintf( fullname, "env/%s%s", baseName, extensions[i] ); common->Printf( "loading %s\n", fullname.c_str() ); session->UpdateScreen(); R_LoadImage( fullname, &buffers[i], &width, &height, NULL, true ); if ( !buffers[i] ) { common->Printf( "failed.\n" ); for ( i-- ; i >= 0 ; i-- ) { Mem_Free( buffers[i] ); } return; } } // resample with hemispherical blending int samples = 1000; byte *outBuffer = (byte *)_alloca( outSize * outSize * 4 ); for ( int map = 0 ; map < 2 ; map++ ) { for ( i = 0 ; i < 6 ; i++ ) { for ( int x = 0 ; x < outSize ; x++ ) { for ( int y = 0 ; y < outSize ; y++ ) { idVec3 dir; float total[3]; dir = cubeAxis[i][0] + -( -1 + 2.0*x/(outSize-1) ) * cubeAxis[i][1] + -( -1 + 2.0*y/(outSize-1) ) * cubeAxis[i][2]; dir.Normalize(); total[0] = total[1] = total[2] = 0; //samples = 1; float limit = map ? 0.95 : 0.25; // small for specular, almost hemisphere for ambient for ( int s = 0 ; s < samples ; s++ ) { // pick a random direction vector that is inside the unit sphere but not behind dir, // which is a robust way to evenly sample a hemisphere idVec3 test; while( 1 ) { for ( int j = 0 ; j < 3 ; j++ ) { test[j] = -1 + 2 * (rand()&0x7fff)/(float)0x7fff; } if ( test.Length() > 1.0 ) { continue; } test.Normalize(); if ( test * dir > limit ) { // don't do a complete hemisphere break; } } byte result[4]; //test = dir; R_SampleCubeMap( test, width, buffers, result ); total[0] += result[0]; total[1] += result[1]; total[2] += result[2]; } outBuffer[(y*outSize+x)*4+0] = total[0] / samples; outBuffer[(y*outSize+x)*4+1] = total[1] / samples; outBuffer[(y*outSize+x)*4+2] = total[2] / samples; outBuffer[(y*outSize+x)*4+3] = 255; } } if ( map == 0 ) { sprintf( fullname, "env/%s_amb%s", baseName, extensions[i] ); } else { sprintf( fullname, "env/%s_spec%s", baseName, extensions[i] ); } common->Printf( "writing %s\n", fullname.c_str() ); session->UpdateScreen(); R_WriteTGA( fullname, outBuffer, outSize, outSize ); } } for ( i = 0 ; i < 6 ; i++ ) { if ( buffers[i] ) { Mem_Free( buffers[i] ); } } } //============================================================================ /* =============== R_SetColorMappings =============== */ void R_SetColorMappings( void ) { int i, j; float g, b; int inf; unsigned short gammaTable[256]; b = r_brightness.GetFloat(); g = r_gamma.GetFloat(); for ( i = 0; i < 256; i++ ) { j = i * b; if (j > 255) { j = 255; } if ( g == 1 ) { inf = (j<<8) | j; } else { inf = 0xffff * pow ( j/255.0f, 1.0f / g ) + 0.5f; } if (inf < 0) { inf = 0; } if (inf > 0xffff) { inf = 0xffff; } gammaTable[i] = inf; } GLimp_SetGamma( gammaTable, gammaTable, gammaTable ); } /* ================ GfxInfo_f ================ */ static void GfxInfo_f( const idCmdArgs &args ) { const char *fsstrings[] = { "windowed", "fullscreen" }; common->Printf( "\nGL_VENDOR: %s\n", glConfig.vendor_string ); common->Printf( "GL_RENDERER: %s\n", glConfig.renderer_string ); common->Printf( "GL_VERSION: %s\n", glConfig.version_string ); common->Printf( "GL_EXTENSIONS: %s\n", glConfig.extensions_string ); common->Printf( "GL_MAX_TEXTURE_SIZE: %d\n", glConfig.maxTextureSize ); common->Printf( "GL_MAX_TEXTURE_UNITS_ARB: %d\n", glConfig.maxTextureUnits ); common->Printf( "GL_MAX_TEXTURE_COORDS_ARB: %d\n", glConfig.maxTextureCoords ); common->Printf( "GL_MAX_TEXTURE_IMAGE_UNITS_ARB: %d\n", glConfig.maxTextureImageUnits ); common->Printf( "\nPIXELFORMAT: color(%d-bits) Z(%d-bit) stencil(%d-bits)\n", glConfig.colorBits, glConfig.depthBits, glConfig.stencilBits ); common->Printf( "MODE: %d, %d x %d %s hz:", r_mode.GetInteger(), glConfig.vidWidth, glConfig.vidHeight, fsstrings[r_fullscreen.GetBool()] ); if ( glConfig.displayFrequency ) { common->Printf( "%d\n", glConfig.displayFrequency ); } else { common->Printf( "N/A\n" ); } const char *active[2] = { "", " (ACTIVE)" }; if ( glConfig.allowARB2Path ) { common->Printf( "ARB2 path ENABLED%s\n", active[tr.backEndRenderer == BE_ARB2] ); } else { common->Printf( "ARB2 path disabled\n" ); } if ( r_finish.GetBool() ) { common->Printf( "Forcing glFinish\n" ); } else { common->Printf( "glFinish not forced\n" ); } bool tss = glConfig.twoSidedStencilAvailable; if ( !r_useTwoSidedStencil.GetBool() && tss ) { common->Printf( "Two sided stencil available but disabled\n" ); } else if ( !tss ) { common->Printf( "Two sided stencil not available\n" ); } else if ( tss ) { common->Printf( "Using two sided stencil\n" ); } if ( vertexCache.IsFast() ) { common->Printf( "Vertex cache is fast\n" ); } else { common->Printf( "Vertex cache is SLOW\n" ); } } /* ================= R_VidRestart_f ================= */ void R_VidRestart_f( const idCmdArgs &args ) { int err; // if OpenGL isn't started, do nothing if ( !glConfig.isInitialized ) { return; } bool full = true; bool forceWindow = false; for ( int i = 1 ; i < args.Argc() ; i++ ) { if ( idStr::Icmp( args.Argv( i ), "partial" ) == 0 ) { full = false; continue; } if ( idStr::Icmp( args.Argv( i ), "windowed" ) == 0 ) { forceWindow = true; continue; } } // this could take a while, so give them the cursor back ASAP Sys_GrabMouseCursor( false ); // dump ambient caches renderModelManager->FreeModelVertexCaches(); // free any current world interaction surfaces and vertex caches R_FreeDerivedData(); // make sure the defered frees are actually freed R_ToggleSmpFrame(); R_ToggleSmpFrame(); // free the vertex caches so they will be regenerated again vertexCache.PurgeAll(); // sound and input are tied to the window we are about to destroy if ( full ) { // free all of our texture numbers soundSystem->ShutdownHW(); Sys_ShutdownInput(); globalImages->PurgeAllImages(); // free the context and close the window GLimp_Shutdown(); glConfig.isInitialized = false; // create the new context and vertex cache bool latch = cvarSystem->GetCVarBool( "r_fullscreen" ); if ( forceWindow ) { cvarSystem->SetCVarBool( "r_fullscreen", false ); } R_InitOpenGL(); cvarSystem->SetCVarBool( "r_fullscreen", latch ); // regenerate all images globalImages->ReloadAllImages(); } else { glimpParms_t parms; parms.width = glConfig.vidWidth; parms.height = glConfig.vidHeight; parms.fullScreen = ( forceWindow ) ? false : r_fullscreen.GetBool(); parms.displayHz = r_displayRefresh.GetInteger(); parms.multiSamples = r_multiSamples.GetInteger(); parms.stereo = false; GLimp_SetScreenParms( parms ); } // make sure the regeneration doesn't use anything no longer valid tr.viewCount++; tr.viewDef = NULL; // regenerate all necessary interactions R_RegenerateWorld_f( idCmdArgs() ); // check for problems err = qglGetError(); if ( err != GL_NO_ERROR ) { common->Printf( "glGetError() = 0x%x\n", err ); } // start sound playing again soundSystem->SetMute( false ); } /* ================= R_InitMaterials ================= */ void R_InitMaterials( void ) { tr.defaultMaterial = declManager->FindMaterial( "_default", false ); if ( !tr.defaultMaterial ) { common->FatalError( "_default material not found" ); } declManager->FindMaterial( "_default", false ); // needed by R_DeriveLightData declManager->FindMaterial( "lights/defaultPointLight" ); declManager->FindMaterial( "lights/defaultProjectedLight" ); } /* ================= R_SizeUp_f Keybinding command ================= */ static void R_SizeUp_f( const idCmdArgs &args ) { if ( r_screenFraction.GetInteger() + 10 > 100 ) { r_screenFraction.SetInteger( 100 ); } else { r_screenFraction.SetInteger( r_screenFraction.GetInteger() + 10 ); } } /* ================= R_SizeDown_f Keybinding command ================= */ static void R_SizeDown_f( const idCmdArgs &args ) { if ( r_screenFraction.GetInteger() - 10 < 10 ) { r_screenFraction.SetInteger( 10 ); } else { r_screenFraction.SetInteger( r_screenFraction.GetInteger() - 10 ); } } /* =============== TouchGui_f this is called from the main thread =============== */ void R_TouchGui_f( const idCmdArgs &args ) { const char *gui = args.Argv( 1 ); if ( !gui[0] ) { common->Printf( "USAGE: touchGui \n" ); return; } common->Printf( "touchGui %s\n", gui ); session->UpdateScreen(); uiManager->Touch( gui ); } /* ================= R_InitCvars ================= */ void R_InitCvars( void ) { // update latched cvars here } /* ================= R_InitCommands ================= */ void R_InitCommands( void ) { cmdSystem->AddCommand( "MakeMegaTexture", idMegaTexture::MakeMegaTexture_f, CMD_FL_RENDERER|CMD_FL_CHEAT, "processes giant images" ); cmdSystem->AddCommand( "sizeUp", R_SizeUp_f, CMD_FL_RENDERER, "makes the rendered view larger" ); cmdSystem->AddCommand( "sizeDown", R_SizeDown_f, CMD_FL_RENDERER, "makes the rendered view smaller" ); cmdSystem->AddCommand( "reloadGuis", R_ReloadGuis_f, CMD_FL_RENDERER, "reloads guis" ); cmdSystem->AddCommand( "listGuis", R_ListGuis_f, CMD_FL_RENDERER, "lists guis" ); cmdSystem->AddCommand( "touchGui", R_TouchGui_f, CMD_FL_RENDERER, "touches a gui" ); cmdSystem->AddCommand( "screenshot", R_ScreenShot_f, CMD_FL_RENDERER, "takes a screenshot" ); cmdSystem->AddCommand( "envshot", R_EnvShot_f, CMD_FL_RENDERER, "takes an environment shot" ); cmdSystem->AddCommand( "makeAmbientMap", R_MakeAmbientMap_f, CMD_FL_RENDERER|CMD_FL_CHEAT, "makes an ambient map" ); cmdSystem->AddCommand( "benchmark", R_Benchmark_f, CMD_FL_RENDERER, "benchmark" ); cmdSystem->AddCommand( "gfxInfo", GfxInfo_f, CMD_FL_RENDERER, "show graphics info" ); cmdSystem->AddCommand( "modulateLights", R_ModulateLights_f, CMD_FL_RENDERER | CMD_FL_CHEAT, "modifies shader parms on all lights" ); cmdSystem->AddCommand( "testImage", R_TestImage_f, CMD_FL_RENDERER | CMD_FL_CHEAT, "displays the given image centered on screen", idCmdSystem::ArgCompletion_ImageName ); cmdSystem->AddCommand( "testVideo", R_TestVideo_f, CMD_FL_RENDERER | CMD_FL_CHEAT, "displays the given cinematic", idCmdSystem::ArgCompletion_VideoName ); cmdSystem->AddCommand( "reportSurfaceAreas", R_ReportSurfaceAreas_f, CMD_FL_RENDERER, "lists all used materials sorted by surface area" ); cmdSystem->AddCommand( "reportImageDuplication", R_ReportImageDuplication_f, CMD_FL_RENDERER, "checks all referenced images for duplications" ); cmdSystem->AddCommand( "regenerateWorld", R_RegenerateWorld_f, CMD_FL_RENDERER, "regenerates all interactions" ); cmdSystem->AddCommand( "showInteractionMemory", R_ShowInteractionMemory_f, CMD_FL_RENDERER, "shows memory used by interactions" ); cmdSystem->AddCommand( "showTriSurfMemory", R_ShowTriSurfMemory_f, CMD_FL_RENDERER, "shows memory used by triangle surfaces" ); cmdSystem->AddCommand( "vid_restart", R_VidRestart_f, CMD_FL_RENDERER, "restarts renderSystem" ); cmdSystem->AddCommand( "listRenderEntityDefs", R_ListRenderEntityDefs_f, CMD_FL_RENDERER, "lists the entity defs" ); cmdSystem->AddCommand( "listRenderLightDefs", R_ListRenderLightDefs_f, CMD_FL_RENDERER, "lists the light defs" ); cmdSystem->AddCommand( "listModes", R_ListModes_f, CMD_FL_RENDERER, "lists all video modes" ); cmdSystem->AddCommand( "reloadSurface", R_ReloadSurface_f, CMD_FL_RENDERER, "reloads the decl and images for selected surface" ); } /* =============== idRenderSystemLocal::Clear =============== */ void idRenderSystemLocal::Clear( void ) { registered = false; frameCount = 0; viewCount = 0; staticAllocCount = 0; frameShaderTime = 0.0f; viewportOffset[0] = 0; viewportOffset[1] = 0; tiledViewport[0] = 0; tiledViewport[1] = 0; backEndRenderer = BE_BAD; backEndRendererHasVertexPrograms = false; backEndRendererMaxLight = 1.0f; ambientLightVector.Zero(); sortOffset = 0; worlds.Clear(); primaryWorld = NULL; memset( &primaryRenderView, 0, sizeof( primaryRenderView ) ); primaryView = NULL; defaultMaterial = NULL; testImage = NULL; ambientCubeImage = NULL; viewDef = NULL; memset( &pc, 0, sizeof( pc ) ); memset( &lockSurfacesCmd, 0, sizeof( lockSurfacesCmd ) ); memset( &identitySpace, 0, sizeof( identitySpace ) ); stencilIncr = 0; stencilDecr = 0; memset( renderCrops, 0, sizeof( renderCrops ) ); currentRenderCrop = 0; guiRecursionLevel = 0; guiModel = NULL; demoGuiModel = NULL; takingScreenshot = false; } /* =============== idRenderSystemLocal::Init =============== */ void idRenderSystemLocal::Init( void ) { // clear all our internal state viewCount = 1; // so cleared structures never match viewCount // we used to memset tr, but now that it is a class, we can't, so // there may be other state we need to reset ambientLightVector[0] = 0.5f; ambientLightVector[1] = 0.5f - 0.385f; ambientLightVector[2] = 0.8925f; ambientLightVector[3] = 1.0f; memset( &backEnd, 0, sizeof( backEnd ) ); R_InitCvars(); R_InitCommands(); guiModel = new idGuiModel; guiModel->Clear(); demoGuiModel = new idGuiModel; demoGuiModel->Clear(); R_InitTriSurfData(); globalImages->Init(); idCinematic::InitCinematic( ); R_InitMaterials(); renderModelManager->Init(); // set the identity space identitySpace.modelMatrix[0*4+0] = 1.0f; identitySpace.modelMatrix[1*4+1] = 1.0f; identitySpace.modelMatrix[2*4+2] = 1.0f; } /* =============== idRenderSystemLocal::Shutdown =============== */ void idRenderSystemLocal::Shutdown( void ) { common->Printf( "idRenderSystem::Shutdown()\n" ); R_DoneFreeType( ); if ( glConfig.isInitialized ) { globalImages->PurgeAllImages(); } renderModelManager->Shutdown(); idCinematic::ShutdownCinematic( ); globalImages->Shutdown(); // free frame memory R_ShutdownFrameData(); // free the vertex cache, which should have nothing allocated now vertexCache.Shutdown(); R_ShutdownTriSurfData(); RB_ShutdownDebugTools(); delete guiModel; delete demoGuiModel; Clear(); ShutdownOpenGL(); } /* ======================== idRenderSystemLocal::BeginLevelLoad ======================== */ void idRenderSystemLocal::BeginLevelLoad( void ) { renderModelManager->BeginLevelLoad(); globalImages->BeginLevelLoad(); } /* ======================== idRenderSystemLocal::EndLevelLoad ======================== */ void idRenderSystemLocal::EndLevelLoad( void ) { renderModelManager->EndLevelLoad(); globalImages->EndLevelLoad(); if ( r_forceLoadImages.GetBool() ) { RB_ShowImages(); } } /* ======================== idRenderSystemLocal::InitOpenGL ======================== */ void idRenderSystemLocal::InitOpenGL( void ) { // if OpenGL isn't started, start it now if ( !glConfig.isInitialized ) { int err; R_InitOpenGL(); globalImages->ReloadAllImages(); err = qglGetError(); if ( err != GL_NO_ERROR ) { common->Printf( "glGetError() = 0x%x\n", err ); } } } /* ======================== idRenderSystemLocal::ShutdownOpenGL ======================== */ void idRenderSystemLocal::ShutdownOpenGL( void ) { // free the context and close the window R_ShutdownFrameData(); GLimp_Shutdown(); glConfig.isInitialized = false; } /* ======================== idRenderSystemLocal::IsOpenGLRunning ======================== */ bool idRenderSystemLocal::IsOpenGLRunning( void ) const { if ( !glConfig.isInitialized ) { return false; } return true; } /* ======================== idRenderSystemLocal::IsFullScreen ======================== */ bool idRenderSystemLocal::IsFullScreen( void ) const { return glConfig.isFullscreen; } /* ======================== idRenderSystemLocal::GetScreenWidth ======================== */ int idRenderSystemLocal::GetScreenWidth( void ) const { return glConfig.vidWidth; } /* ======================== idRenderSystemLocal::GetScreenHeight ======================== */ int idRenderSystemLocal::GetScreenHeight( void ) const { return glConfig.vidHeight; }