//===== Copyright 1996-2005, Valve Corporation, All rights reserved. ======// // // Purpose: Draws grasses and other small objects // // $Revision: $ // $NoKeywords: $ //===========================================================================// #include "cbase.h" #include #include "DetailObjectSystem.h" #include "GameBspFile.h" #include "UtlBuffer.h" #include "tier1/utlmap.h" #include "view.h" #include "ClientMode.h" #include "IViewRender.h" #include "BSPTreeData.h" #include "tier0/vprof.h" #include "engine/ivmodelinfo.h" #include "materialsystem/IMesh.h" #include "model_types.h" #include "env_detail_controller.h" #include "tier0/icommandline.h" #include "tier1/callqueue.h" #include "c_world.h" #ifdef USE_DETAIL_SHAPES #include "engine/ivdebugoverlay.h" #include "playerenumerator.h" #endif #include "materialsystem/imaterialsystemhardwareconfig.h" // memdbgon must be the last include file in a .cpp file!!! #include "tier0/memdbgon.h" #define DETAIL_SPRITE_MATERIAL "detail/detailsprites" //----------------------------------------------------------------------------- // forward declarations //----------------------------------------------------------------------------- struct model_t; #if defined( USE_DETAIL_SHAPES ) ConVar cl_detail_max_sway( "cl_detail_max_sway", "0", FCVAR_ARCHIVE, "Amplitude of the detail prop sway" ); ConVar cl_detail_avoid_radius( "cl_detail_avoid_radius", "0", FCVAR_ARCHIVE, "radius around detail sprite to avoid players" ); ConVar cl_detail_avoid_force( "cl_detail_avoid_force", "0", FCVAR_ARCHIVE, "force with which to avoid players ( in units, percentage of the width of the detail sprite )" ); ConVar cl_detail_avoid_recover_speed( "cl_detail_avoid_recover_speed", "0", FCVAR_ARCHIVE, "how fast to recover position after avoiding players" ); #endif ConVar r_FlashlightDetailProps( "r_FlashlightDetailProps", "1", 0, "Enable a flashlight drawing pass on detail props. 0 = off, 1 = single pass, 2 = multipass (multipass is PC ONLY)" ); ConVar r_ThreadedDetailProps( "r_threadeddetailprops", "1", 0, "enable threading of detail prop drawing" ); enum DetailPropFlashlightMode_t { DPFM_NONE, DPFM_SINGLEPASS, DPFM_MULTIPASS, }; inline DetailPropFlashlightMode_t DetailPropFlashlightMode( void ) { switch( r_FlashlightDetailProps.GetInt() ) { case 1: return DPFM_SINGLEPASS; #ifndef _X360 case 2: return DPFM_MULTIPASS; #endif case 0: default: return DPFM_NONE; } } // Per detail instance information struct DetailModelAdvInfo_t { // precaculated angles for shaped sprites Vector m_vecAnglesForward[3]; Vector m_vecAnglesRight[3]; // better to save this mem and calc per sprite ? Vector m_vecAnglesUp[3]; // direction we're avoiding the player Vector m_vecCurrentAvoid; // yaw to sway on float m_flSwayYaw; // size of the shape float m_flShapeSize; int m_iShapeAngle; float m_flSwayAmount; }; class CDetailObjectSystemPerLeafData { unsigned short m_FirstDetailProp; unsigned short m_DetailPropCount; int m_DetailPropRenderFrame; CDetailObjectSystemPerLeafData( void ) { m_FirstDetailProp = 0; m_DetailPropCount = 0; m_DetailPropRenderFrame = -1; } }; static void DrawMeshCallback( void *pMesh ) { ((IMesh *)pMesh)->Draw(); } //----------------------------------------------------------------------------- // Detail models //----------------------------------------------------------------------------- struct SpriteInfo_t { unsigned short m_nSpriteIndex; float16 m_flScale; }; class CDetailModel : public IClientUnknown, public IClientRenderable { DECLARE_CLASS_NOBASE( CDetailModel ); public: CDetailModel(); ~CDetailModel(); // Initialization bool InitCommon( int index, const Vector& org, const QAngle& angles ); bool Init( int index, const Vector& org, const QAngle& angles, model_t* pModel, ColorRGBExp32 lighting, int lightstyle, unsigned char lightstylecount, int orientation ); bool InitSprite( int index, bool bFlipped, const Vector& org, const QAngle& angles, unsigned short nSpriteIndex, ColorRGBExp32 lighting, int lightstyle, unsigned char lightstylecount, int orientation, float flScale, unsigned char type, unsigned char shapeAngle, unsigned char shapeSize, unsigned char swayAmount ); bool IsTranslucent() const { return m_bIsTranslucent; } // IClientUnknown overrides. public: virtual IClientUnknown* GetIClientUnknown() { return this; } virtual ICollideable* GetCollideable() { return 0; } // Static props DO implement this. virtual IClientNetworkable* GetClientNetworkable() { return 0; } virtual IClientRenderable* GetClientRenderable() { return this; } virtual IClientEntity* GetIClientEntity() { return 0; } virtual C_BaseEntity* GetBaseEntity() { return 0; } virtual IClientThinkable* GetClientThinkable() { return 0; } virtual IClientModelRenderable* GetClientModelRenderable() { return 0; } virtual IClientAlphaProperty* GetClientAlphaProperty() { return 0; } // IClientRenderable overrides. public: virtual int GetBody() { return 0; } virtual const Vector& GetRenderOrigin( ); virtual const QAngle& GetRenderAngles( ); virtual const matrix3x4_t & RenderableToWorldTransform(); virtual bool ShouldDraw(); virtual uint8 OverrideAlphaModulation( uint8 nAlpha ) { return nAlpha; } virtual uint8 OverrideShadowAlphaModulation( uint8 nAlpha ) { return nAlpha; } virtual void OnThreadedDrawSetup() {} virtual const model_t* GetModel( ) const; virtual int DrawModel( int flags, const RenderableInstance_t &instance ); virtual bool SetupBones( matrix3x4a_t *pBoneToWorldOut, int nMaxBones, int boneMask, float currentTime ); virtual void SetupWeights( const matrix3x4_t *pBoneToWorld, int nFlexWeightCount, float *pFlexWeights, float *pFlexDelayedWeights ); virtual bool UsesFlexDelayedWeights() { return false; } virtual void DoAnimationEvents( void ); virtual void GetRenderBounds( Vector& mins, Vector& maxs ); virtual IPVSNotify* GetPVSNotifyInterface(); virtual void GetRenderBoundsWorldspace( Vector& mins, Vector& maxs ); virtual bool ShouldReceiveProjectedTextures( int flags ); virtual bool GetShadowCastDistance( float *pDist, ShadowType_t shadowType ) const { return false; } virtual bool GetShadowCastDirection( Vector *pDirection, ShadowType_t shadowType ) const { return false; } virtual int GetRenderFlags( void ); virtual bool LODTest() { return true; } virtual ClientShadowHandle_t GetShadowHandle() const; virtual ClientRenderHandle_t& RenderHandle(); virtual void GetShadowRenderBounds( Vector &mins, Vector &maxs, ShadowType_t shadowType ); virtual bool IsShadowDirty( ) { return false; } virtual void MarkShadowDirty( bool bDirty ) {} virtual IClientRenderable *GetShadowParent() { return NULL; } virtual IClientRenderable *FirstShadowChild(){ return NULL; } virtual IClientRenderable *NextShadowPeer() { return NULL; } virtual ShadowType_t ShadowCastType() { return SHADOWS_NONE; } virtual void CreateModelInstance() {} virtual ModelInstanceHandle_t GetModelInstance() { return MODEL_INSTANCE_INVALID; } virtual int LookupAttachment( const char *pAttachmentName ) { return -1; } virtual bool GetAttachment( int number, matrix3x4_t &matrix ); virtual bool GetAttachment( int number, Vector &origin, QAngle &angles ); virtual float * GetRenderClipPlane() { return NULL; } virtual int GetSkin() { return 0; } virtual void RecordToolMessage() {} virtual bool ShouldDrawForSplitScreenUser( int nSlot ) { return true; } void GetColorModulation( float* color ); // Computes the render angles for screen alignment void ComputeAngles( void ); // Calls the correct rendering func void DrawSprite( CMeshBuilder &meshBuilder, uint8 nAlpha ); // Returns the number of quads the sprite will draw int QuadsToDraw() const; // Draw functions for the different types of sprite void DrawTypeSprite( CMeshBuilder &meshBuilder, uint8 nAlpha ); #ifdef USE_DETAIL_SHAPES void DrawTypeShapeCross( CMeshBuilder &meshBuilder, uint8 nAlpha ); void DrawTypeShapeTri( CMeshBuilder &meshBuilder, uint8 nAlpha ); // check for players nearby and angle away from them void UpdatePlayerAvoid( void ); void InitShapedSprite( unsigned char shapeAngle, unsigned char shapeSize, unsigned char swayAmount ); void InitShapeTri(); void InitShapeCross(); void DrawSwayingQuad( CMeshBuilder &meshBuilder, Vector vecOrigin, Vector vecSway, Vector2D texul, Vector2D texlr, unsigned char *color, Vector width, Vector height ); #endif int GetType() const { return m_Type; } bool IsDetailModelTranslucent(); // IHandleEntity stubs. public: virtual void SetRefEHandle( const CBaseHandle &handle ) { Assert( false ); } virtual const CBaseHandle& GetRefEHandle() const { Assert( false ); return *((CBaseHandle*)0); } //--------------------------------- struct LightStyleInfo_t { unsigned int m_LightStyle:24; unsigned int m_LightStyleCount:8; }; protected: Vector m_Origin; QAngle m_Angles; ColorRGBExp32 m_Color; unsigned char m_Orientation:2; unsigned char m_Type:2; unsigned char m_bHasLightStyle:1; unsigned char m_bFlipped:1; unsigned char m_bIsTranslucent:1; static CUtlMap gm_LightStylesMap; #pragma warning( disable : 4201 ) //warning C4201: nonstandard extension used : nameless struct/union union { model_t* m_pModel; SpriteInfo_t m_SpriteInfo; }; #pragma warning( default : 4201 ) #ifdef USE_DETAIL_SHAPES // pointer to advanced properties DetailModelAdvInfo_t *m_pAdvInfo; #endif }; static ConVar mat_fullbright( "mat_fullbright", "0", FCVAR_CHEAT ); // hook into engine's cvars.. extern ConVar r_DrawDetailProps; //----------------------------------------------------------------------------- // Dictionary for detail sprites //----------------------------------------------------------------------------- struct DetailPropSpriteDict_t { Vector2D m_UL; // Coordinate of upper left Vector2D m_LR; // Coordinate of lower right Vector2D m_TexUL; // Texcoords of upper left Vector2D m_TexLR; // Texcoords of lower left }; struct FastSpriteX4_t { // mess with this structure without care and you'll be in a world of trouble. layout matters. FourVectors m_Pos; fltx4 m_HalfWidth; fltx4 m_Height; uint8 m_RGBColor[4][4]; DetailPropSpriteDict_t *m_pSpriteDefs[4]; void ReplicateFirstEntryToOthers( void ) { m_HalfWidth = ReplicateX4( SubFloat( m_HalfWidth, 0 ) ); m_Height = ReplicateX4( SubFloat( m_Height, 0 ) ); for( int i = 1; i < 4; i++ ) for( int j = 0; j < 4; j++ ) { m_RGBColor[i][j] = m_RGBColor[0][j]; } m_Pos.x = ReplicateX4( SubFloat( m_Pos.x, 0 ) ); m_Pos.y = ReplicateX4( SubFloat( m_Pos.y, 0 ) ); m_Pos.z = ReplicateX4( SubFloat( m_Pos.z, 0 ) ); } }; struct FastSpriteQuadBuildoutBufferX4_t { // mess with this structure without care and you'll be in a world of trouble. layout matters. FourVectors m_Coords[4]; uint8 m_RGBColor[4][4]; fltx4 m_Alpha; DetailPropSpriteDict_t *m_pSpriteDefs[4]; Vector4D m_Normal; }; struct FastSpriteQuadBuildoutBufferNonSIMDView_t { // mess with this structure without care and you'll be in a world of trouble. layout matters. float m_flX0[4], m_flY0[4], m_flZ0[4]; float m_flX1[4], m_flY1[4], m_flZ1[4]; float m_flX2[4], m_flY2[4], m_flZ2[4]; float m_flX3[4], m_flY3[4], m_flZ3[4]; uint8 m_RGBColor[4][4]; float m_Alpha[4]; DetailPropSpriteDict_t *m_pSpriteDefs[4]; Vector4D m_Normal; }; FourVectors vgarbage; class CFastDetailLeafSpriteList : public CClientLeafSubSystemData { friend class CDetailObjectSystem; int m_nNumSprites; int m_nNumSIMDSprites; // #sprites/4, rounded up // simd pointers into larger array - don't free individually or you will be sad FastSpriteX4_t *m_pSprites; // state for partially drawn sprite lists int m_nNumPendingSprites; int m_nStartSpriteIndex; CFastDetailLeafSpriteList( void ) { m_nNumPendingSprites = 0; m_nStartSpriteIndex = 0; } void TouchData( void ) { vgarbage.x = Four_Zeros; vgarbage.y = Four_Zeros; vgarbage.z = Four_Zeros; for( int i =0; i < m_nNumSIMDSprites; i++ ) { vgarbage += m_pSprites[i].m_Pos; } } }; //----------------------------------------------------------------------------- // Responsible for managing detail objects //----------------------------------------------------------------------------- class CDetailObjectSystem : public IDetailObjectSystem { public: char const *Name() { return "DetailObjectSystem"; } // constructor, destructor CDetailObjectSystem(); ~CDetailObjectSystem(); bool IsPerFrame() { return false; } // Init, shutdown bool Init() { m_flDetailFadeStart = 0.0f; m_flDetailFadeEnd = 0.0f; return true; } void PostInit() {} void Shutdown() {} // Level init, shutdown void LevelInitPreEntity(); void LevelInitPostEntity(); void LevelShutdownPreEntity(); void LevelShutdownPostEntity(); void OnSave() {} void OnRestore() {} void SafeRemoveIfDesired() {} // Gets a particular detail object virtual IClientRenderable* GetDetailModel( int idx ); virtual int GetDetailModelCount() const; virtual void BuildRenderingData( DetailRenderableList_t &list, const SetupRenderInfo_t &info, float flDetailDist, const DistanceFadeInfo_t &fadeInfo ); virtual float ComputeDetailFadeInfo( DistanceFadeInfo_t *pInfo ); // Renders all opaque detail objects in a particular set of leaves void RenderOpaqueDetailObjects( int nLeafCount, LeafIndex_t *pLeafList ); // Renders all translucent detail objects in a particular set of leaves void RenderTranslucentDetailObjects( const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeafCount, LeafIndex_t *pLeafList ); // Renders all translucent detail objects in a particular leaf up to a particular point void RenderTranslucentDetailObjectsInLeaf( const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeaf, const Vector *pVecClosestPoint ); void RenderFastTranslucentDetailObjectsInLeaf( CFastDetailLeafSpriteList *pData, const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeaf, const Vector &vecClosestPoint, bool bFirstLeaf ); // Call this before rendering translucent detail objects void BeginTranslucentDetailRendering( ); DetailPropLightstylesLump_t& DetailLighting( int i ) { return m_DetailLighting[i]; } DetailPropSpriteDict_t& DetailSpriteDict( int i ) { return m_DetailSpriteDict[i]; } void RenderFastSprites( const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeafCount, LeafIndex_t const * pLeafList ); uint8 ComputeDistanceFade( float *pDistSqr, const DistanceFadeInfo_t &info, const Vector &vecViewOrigin, const Vector &vecRenderOrigin ) const; void UpdateDetailFadeValues(); private: struct DetailModelDict_t { model_t* m_pModel; }; struct EnumContext_t { Vector m_vViewOrigin; int m_BuildWorldListNumber; }; struct SortInfo_t { int m_nIndex : 24; int m_nAlpha : 8; float m_flDistance; }; int BuildOutSortedSprites( CFastDetailLeafSpriteList *pData, const DistanceFadeInfo_t &info, Vector const &viewOrigin, Vector const &viewForward, Vector const &viewRight, Vector const &viewUp ); void UnserializeFastSprite( FastSpriteX4_t *pSpritex4, int nSubField, DetailObjectLump_t const &lump, bool bFlipped, Vector const &posOffset ); // Unserialization void ScanForCounts( CUtlBuffer& buf, int *pNumOldStyleObjects, int *pNumFastSpritesToAllocate, int *nMaxOldInLeaf, int *nMaxFastInLeaf ) const; void UnserializeModelDict( CUtlBuffer& buf ); void UnserializeDetailSprites( CUtlBuffer& buf ); void UnserializeModels( CUtlBuffer& buf ); void UnserializeModelLighting( CUtlBuffer& buf ); Vector GetSpriteMiddleBottomPosition( DetailObjectLump_t const &lump ) const; // Count the number of detail sprites in the leaf list int CountSpritesInLeafList( int nLeafCount, LeafIndex_t *pLeafList ) const; // Count the number of detail sprite quads in the leaf list int CountSpriteQuadsInLeafList( int nLeafCount, LeafIndex_t *pLeafList ) const; int CountFastSpritesInLeafList( int nLeafCount, LeafIndex_t const *pLeafList, int *nMaxInLeaf ) const; void FreeSortBuffers( void ); // Sorts sprites in back-to-front order static bool SortLessFunc( const SortInfo_t &left, const SortInfo_t &right ); int SortSpritesBackToFront( int nLeaf, const Vector &viewOrigin, const DistanceFadeInfo_t &fadeInfo, SortInfo_t *pSortInfo ); // For fast detail object insertion IterationRetval_t EnumElement( int userId, int context ); CUtlVector m_DetailObjectDict; CUtlVector m_DetailObjects; CUtlVector m_DetailSpriteDict; CUtlVector m_DetailSpriteDictFlipped; CUtlVector m_DetailLighting; FastSpriteX4_t *m_pFastSpriteData; // Necessary to get sprites to batch correctly CMaterialReference m_DetailSpriteMaterial; CMaterialReference m_DetailWireframeMaterial; // State stored off for rendering detail sprites in a single leaf int m_nSpriteCount; int m_nFirstSprite; int m_nSortedLeaf; int m_nSortedFastLeaf; SortInfo_t *m_pSortInfo; SortInfo_t *m_pFastSortInfo; FastSpriteQuadBuildoutBufferX4_t *m_pBuildoutBuffer; bool m_bFirstLeaf; float m_flDetailFadeStart; float m_flDetailFadeEnd; }; //----------------------------------------------------------------------------- // System for dealing with detail objects //----------------------------------------------------------------------------- static CDetailObjectSystem s_DetailObjectSystem; IDetailObjectSystem *g_pDetailObjectSystem = &s_DetailObjectSystem; static void DetailFadeCallback( IConVar *var, const char *pOldValue, float flOldValue ) { s_DetailObjectSystem.UpdateDetailFadeValues(); } ConVar cl_detaildist( "cl_detaildist", "1200", 0, "Distance at which detail props are no longer visible", DetailFadeCallback ); ConVar cl_detailfade( "cl_detailfade", "400", 0, "Distance across which detail props fade in", DetailFadeCallback ); //----------------------------------------------------------------------------- // Initialization //----------------------------------------------------------------------------- CUtlMap CDetailModel::gm_LightStylesMap( DefLessFunc( CDetailModel * ) ); bool CDetailModel::InitCommon( int index, const Vector& org, const QAngle& angles ) { VectorCopy( org, m_Origin ); VectorCopy( angles, m_Angles ); return true; } //----------------------------------------------------------------------------- // Inline methods //----------------------------------------------------------------------------- // NOTE: If DetailPropType_t enum changes, change CDetailModel::QuadsToDraw static int s_pQuadCount[4] = { 0, //DETAIL_PROP_TYPE_MODEL 1, //DETAIL_PROP_TYPE_SPRITE 4, //DETAIL_PROP_TYPE_SHAPE_CROSS 3, //DETAIL_PROP_TYPE_SHAPE_TRI }; inline int CDetailModel::QuadsToDraw() const { return s_pQuadCount[m_Type]; } //----------------------------------------------------------------------------- // Data accessors //----------------------------------------------------------------------------- const Vector& CDetailModel::GetRenderOrigin( void ) { return m_Origin; } const QAngle& CDetailModel::GetRenderAngles( void ) { return m_Angles; } const matrix3x4_t &CDetailModel::RenderableToWorldTransform() { // Setup our transform. static matrix3x4_t mat; AngleMatrix( GetRenderAngles(), GetRenderOrigin(), mat ); return mat; } bool CDetailModel::GetAttachment( int number, matrix3x4_t &matrix ) { MatrixCopy( RenderableToWorldTransform(), matrix ); return true; } bool CDetailModel::GetAttachment( int number, Vector &origin, QAngle &angles ) { origin = m_Origin; angles = m_Angles; return true; } bool CDetailModel::ShouldDraw() { // Don't draw in commander mode return GetClientMode()->ShouldDrawDetailObjects(); } void CDetailModel::GetRenderBounds( Vector& mins, Vector& maxs ) { if ( m_Type == DETAIL_PROP_TYPE_MODEL ) { int nModelType = modelinfo->GetModelType( m_pModel ); if ( nModelType == mod_studio || nModelType == mod_brush ) { modelinfo->GetModelRenderBounds( GetModel(), mins, maxs ); } else { mins.Init( 0,0,0 ); maxs.Init( 0,0,0 ); } return; } // NOTE: Sway isn't taken into account here DetailPropSpriteDict_t &dict = s_DetailObjectSystem.DetailSpriteDict( m_SpriteInfo.m_nSpriteIndex ); Vector2D ul, lr; float flScale = m_SpriteInfo.m_flScale.GetFloat(); Vector2DMultiply( dict.m_UL, flScale, ul ); Vector2DMultiply( dict.m_LR, flScale, lr ); float flSizeX = MAX( fabs(lr.x), fabs(ul.x) ); float flSizeY = MAX( fabs(lr.y), fabs(ul.y) ); float flRadius = sqrt( flSizeX * flSizeX + flSizeY * flSizeY ); mins.Init( -flRadius, -flRadius, -flRadius ); maxs.Init( flRadius, flRadius, flRadius ); } IPVSNotify* CDetailModel::GetPVSNotifyInterface() { return NULL; } void CDetailModel::GetRenderBoundsWorldspace( Vector& mins, Vector& maxs ) { DefaultRenderBoundsWorldspace( this, mins, maxs ); } bool CDetailModel::ShouldReceiveProjectedTextures( int flags ) { return false; } int CDetailModel::GetRenderFlags( void ) { return 0; } void CDetailModel::GetShadowRenderBounds( Vector &mins, Vector &maxs, ShadowType_t shadowType ) { GetRenderBounds( mins, maxs ); } ClientShadowHandle_t CDetailModel::GetShadowHandle() const { return CLIENTSHADOW_INVALID_HANDLE; } ClientRenderHandle_t& CDetailModel::RenderHandle() { AssertMsg( 0, "CDetailModel has no render handle" ); return *((ClientRenderHandle_t*)NULL); } //----------------------------------------------------------------------------- // Render setup //----------------------------------------------------------------------------- bool CDetailModel::SetupBones( matrix3x4a_t *pBoneToWorldOut, int nMaxBones, int boneMask, float currentTime ) { if (!m_pModel) return false; // Setup our transform. matrix3x4a_t parentTransform; const QAngle &vRenderAngles = GetRenderAngles(); const Vector &vRenderOrigin = GetRenderOrigin(); AngleMatrix( vRenderAngles, parentTransform ); parentTransform[0][3] = vRenderOrigin.x; parentTransform[1][3] = vRenderOrigin.y; parentTransform[2][3] = vRenderOrigin.z; // Just copy it on down baby studiohdr_t *pStudioHdr = modelinfo->GetStudiomodel( m_pModel ); for (int i = 0; i < pStudioHdr->numbones; i++) { MatrixCopy( parentTransform, pBoneToWorldOut[i] ); } return true; } void CDetailModel::SetupWeights( const matrix3x4_t *pBoneToWorld, int nFlexWeightCount, float *pFlexWeights, float *pFlexDelayedWeights ) { } void CDetailModel::DoAnimationEvents( void ) { } //----------------------------------------------------------------------------- // Render baby! //----------------------------------------------------------------------------- const model_t* CDetailModel::GetModel( ) const { return m_pModel; } int CDetailModel::DrawModel( int flags, const RenderableInstance_t &instance ) { if (( instance.m_nAlpha == 0) || (!m_pModel)) return 0; render->SetBlend( instance.m_nAlpha / 255.0f ); int drawn = modelrender->DrawModel( flags, this, MODEL_INSTANCE_INVALID, -1, // no entity index m_pModel, m_Origin, m_Angles, 0, // skin 0, // body 0 // hitboxset ); return drawn; } //----------------------------------------------------------------------------- // Detail models stuff //----------------------------------------------------------------------------- CDetailModel::CDetailModel() { m_Color.r = m_Color.g = m_Color.b = 255; m_Color.exponent = 0; m_bFlipped = 0; m_bHasLightStyle = 0; m_bIsTranslucent = false; #ifdef USE_DETAIL_SHAPES m_pAdvInfo = NULL; #endif } //----------------------------------------------------------------------------- // Destructor //----------------------------------------------------------------------------- CDetailModel::~CDetailModel() { #ifdef USE_DETAIL_SHAPES // delete advanced if ( m_pAdvInfo ) { delete m_pAdvInfo; m_pAdvInfo = NULL; } #endif if ( m_bHasLightStyle ) gm_LightStylesMap.Remove( this ); } //----------------------------------------------------------------------------- // Initialization //----------------------------------------------------------------------------- bool CDetailModel::Init( int index, const Vector& org, const QAngle& angles, model_t* pModel, ColorRGBExp32 lighting, int lightstyle, unsigned char lightstylecount, int orientation) { m_Color = lighting; if ( lightstylecount > 0) { m_bHasLightStyle = 1; int iInfo = gm_LightStylesMap.Insert( this ); if ( lightstyle >= 0x1000000 || lightstylecount >= 100 ) Error( "Light style overflow\n" ); gm_LightStylesMap[iInfo].m_LightStyle = lightstyle; gm_LightStylesMap[iInfo].m_LightStyleCount = lightstylecount; } m_Orientation = orientation; m_Type = DETAIL_PROP_TYPE_MODEL; m_pModel = pModel; m_bIsTranslucent = modelinfo->IsTranslucent( m_pModel ); return InitCommon( index, org, angles ); } bool CDetailModel::InitSprite( int index, bool bFlipped, const Vector& org, const QAngle& angles, unsigned short nSpriteIndex, ColorRGBExp32 lighting, int lightstyle, unsigned char lightstylecount, int orientation, float flScale, unsigned char type, unsigned char shapeAngle, unsigned char shapeSize, unsigned char swayAmount ) { m_Color = lighting; if ( lightstylecount > 0) { m_bHasLightStyle = 1; int iInfo = gm_LightStylesMap.Insert( this ); if ( lightstyle >= 0x1000000 || lightstylecount >= 100 ) Error( "Light style overflow\n" ); gm_LightStylesMap[iInfo].m_LightStyle = lightstyle; gm_LightStylesMap[iInfo].m_LightStyleCount = lightstylecount; } m_Orientation = orientation; m_SpriteInfo.m_nSpriteIndex = nSpriteIndex; m_Type = type; m_SpriteInfo.m_flScale.SetFloat( flScale ); m_bIsTranslucent = true; #ifdef USE_DETAIL_SHAPES m_pAdvInfo = NULL; Assert( type <= 3 ); // precalculate angles for shapes if ( type == DETAIL_PROP_TYPE_SHAPE_TRI || type == DETAIL_PROP_TYPE_SHAPE_CROSS || swayAmount > 0 ) { m_Angles = angles; InitShapedSprite( shapeAngle, shapeSize, swayAmount); } #endif m_bFlipped = bFlipped; return InitCommon( index, org, angles ); } #ifdef USE_DETAIL_SHAPES void CDetailModel::InitShapedSprite( unsigned char shapeAngle, unsigned char shapeSize, unsigned char swayAmount ) { // Set up pointer to advanced shape properties object ( per instance ) Assert( m_pAdvInfo == NULL ); m_pAdvInfo = new DetailModelAdvInfo_t; Assert( m_pAdvInfo ); if ( m_pAdvInfo ) { m_pAdvInfo->m_iShapeAngle = shapeAngle; m_pAdvInfo->m_flSwayAmount = (float)swayAmount / 255.0f; m_pAdvInfo->m_flShapeSize = (float)shapeSize / 255.0f; m_pAdvInfo->m_vecCurrentAvoid = vec3_origin; m_pAdvInfo->m_flSwayYaw = random->RandomFloat( 0, 180 ); } switch ( m_Type ) { case DETAIL_PROP_TYPE_SHAPE_TRI: InitShapeTri(); break; case DETAIL_PROP_TYPE_SHAPE_CROSS: InitShapeCross(); break; default: // sprite will get here break; } } void CDetailModel::InitShapeTri( void ) { // store the three sets of directions matrix3x4_t matrix; // Convert roll/pitch only to matrix AngleMatrix( m_Angles, matrix ); // calculate the vectors for the three sides so they can be used in the sorting test // as well as in drawing for ( int i=0; i<3; i++ ) { // Convert desired rotation to angles QAngle anglesRotated( m_pAdvInfo->m_iShapeAngle, i*120, 0 ); Vector rotForward, rotRight, rotUp; AngleVectors( anglesRotated, &rotForward, &rotRight, &rotUp ); // Rotate direction vectors VectorRotate( rotForward, matrix, m_pAdvInfo->m_vecAnglesForward[i] ); VectorRotate( rotRight, matrix, m_pAdvInfo->m_vecAnglesRight[i] ); VectorRotate( rotUp, matrix, m_pAdvInfo->m_vecAnglesUp[i] ); } } void CDetailModel::InitShapeCross( void ) { AngleVectors( m_Angles, &m_pAdvInfo->m_vecAnglesForward[0], &m_pAdvInfo->m_vecAnglesRight[0], &m_pAdvInfo->m_vecAnglesUp[0] ); } #endif //----------------------------------------------------------------------------- // Color, alpha modulation //----------------------------------------------------------------------------- void CDetailModel::GetColorModulation( float *color ) { if (mat_fullbright.GetInt() == 1) { color[0] = color[1] = color[2] = 1.0f; return; } Vector tmp; Vector normal( 1, 0, 0); engine->ComputeDynamicLighting( m_Origin, &normal, tmp ); float val = engine->LightStyleValue( 0 ); color[0] = tmp[0] + val * TexLightToLinear( m_Color.r, m_Color.exponent ); color[1] = tmp[1] + val * TexLightToLinear( m_Color.g, m_Color.exponent ); color[2] = tmp[2] + val * TexLightToLinear( m_Color.b, m_Color.exponent ); // Add in the lightstyles if ( m_bHasLightStyle ) { int iInfo = gm_LightStylesMap.Find( this ); Assert( iInfo != gm_LightStylesMap.InvalidIndex() ); if ( iInfo != gm_LightStylesMap.InvalidIndex() ) { int nLightStyles = gm_LightStylesMap[iInfo].m_LightStyleCount; int iLightStyle = gm_LightStylesMap[iInfo].m_LightStyle; for (int i = 0; i < nLightStyles; ++i) { DetailPropLightstylesLump_t& lighting = s_DetailObjectSystem.DetailLighting( iLightStyle + i ); val = engine->LightStyleValue( lighting.m_Style ); if (val != 0) { color[0] += val * TexLightToLinear( lighting.m_Lighting.r, lighting.m_Lighting.exponent ); color[1] += val * TexLightToLinear( lighting.m_Lighting.g, lighting.m_Lighting.exponent ); color[2] += val * TexLightToLinear( lighting.m_Lighting.b, lighting.m_Lighting.exponent ); } } } } // Gamma correct.... engine->LinearToGamma( color, color ); } //----------------------------------------------------------------------------- // Is the model itself translucent, regardless of modulation? //----------------------------------------------------------------------------- bool CDetailModel::IsDetailModelTranslucent() { // FIXME: This is only true for my first pass of this feature if (m_Type >= DETAIL_PROP_TYPE_SPRITE) return true; return modelinfo->IsTranslucent(GetModel()); } //----------------------------------------------------------------------------- // Computes the render angles for screen alignment //----------------------------------------------------------------------------- void CDetailModel::ComputeAngles( void ) { switch( m_Orientation ) { case 0: break; case 1: { Vector vecDir; VectorSubtract( CurrentViewOrigin(), m_Origin, vecDir ); VectorAngles( vecDir, m_Angles ); } break; case 2: { Vector vecDir; VectorSubtract( CurrentViewOrigin(), m_Origin, vecDir ); vecDir.z = 0.0f; VectorAngles( vecDir, m_Angles ); } break; } } //----------------------------------------------------------------------------- // Select which rendering func to call //----------------------------------------------------------------------------- void CDetailModel::DrawSprite( CMeshBuilder &meshBuilder, uint8 nAlpha ) { switch( m_Type ) { #ifdef USE_DETAIL_SHAPES case DETAIL_PROP_TYPE_SHAPE_CROSS: DrawTypeShapeCross( meshBuilder, nAlpha ); break; case DETAIL_PROP_TYPE_SHAPE_TRI: DrawTypeShapeTri( meshBuilder, nAlpha ); break; #endif case DETAIL_PROP_TYPE_SPRITE: DrawTypeSprite( meshBuilder, nAlpha ); break; default: Assert(0); break; } } //----------------------------------------------------------------------------- // Draws the single sprite type //----------------------------------------------------------------------------- void CDetailModel::DrawTypeSprite( CMeshBuilder &meshBuilder, uint8 nAlpha ) { Assert( m_Type == DETAIL_PROP_TYPE_SPRITE ); Vector vecColor; GetColorModulation( vecColor.Base() ); unsigned char color[4]; color[0] = (unsigned char)(vecColor[0] * 255.0f); color[1] = (unsigned char)(vecColor[1] * 255.0f); color[2] = (unsigned char)(vecColor[2] * 255.0f); color[3] = nAlpha; DetailPropSpriteDict_t &dict = s_DetailObjectSystem.DetailSpriteDict( m_SpriteInfo.m_nSpriteIndex ); Vector vecOrigin, dx, dy, dz; AngleVectors( m_Angles, &dz, &dx, &dy ); Vector2D ul, lr; float scale = m_SpriteInfo.m_flScale.GetFloat(); Vector2DMultiply( dict.m_UL, scale, ul ); Vector2DMultiply( dict.m_LR, scale, lr ); #ifdef USE_DETAIL_SHAPES UpdatePlayerAvoid(); Vector vecSway = vec3_origin; if ( m_pAdvInfo ) { vecSway = m_pAdvInfo->m_vecCurrentAvoid * m_SpriteInfo.m_flScale.GetFloat(); float flSwayAmplitude = m_pAdvInfo->m_flSwayAmount * cl_detail_max_sway.GetFloat(); if ( flSwayAmplitude > 0 ) { // sway based on time plus a random seed that is constant for this instance of the sprite vecSway += dx * sin(gpGlobals->curtime+m_Origin.x) * flSwayAmplitude; } } #endif VectorMA( m_Origin, ul.x, dx, vecOrigin ); VectorMA( vecOrigin, ul.y, dy, vecOrigin ); dx *= (lr.x - ul.x); dy *= (lr.y - ul.y); Vector2D texul, texlr; texul = dict.m_TexUL; texlr = dict.m_TexLR; if ( !m_bFlipped ) { texul.x = dict.m_TexLR.x; texlr.x = dict.m_TexUL.x; } #ifndef USE_DETAIL_SHAPES meshBuilder.Position3fv( vecOrigin.Base() ); #else meshBuilder.Position3fv( (vecOrigin+vecSway).Base() ); #endif meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2fv( 0, texul.Base() ); meshBuilder.Normal3fv( &dz.x ); meshBuilder.AdvanceVertex(); vecOrigin += dy; meshBuilder.Position3fv( vecOrigin.Base() ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, texul.x, texlr.y ); meshBuilder.Normal3fv( &dz.x ); meshBuilder.AdvanceVertex(); vecOrigin += dx; meshBuilder.Position3fv( vecOrigin.Base() ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2fv( 0, texlr.Base() ); meshBuilder.Normal3fv( &dz.x ); meshBuilder.AdvanceVertex(); vecOrigin -= dy; #ifndef USE_DETAIL_SHAPES meshBuilder.Position3fv( vecOrigin.Base() ); #else meshBuilder.Position3fv( (vecOrigin+vecSway).Base() ); #endif meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, texlr.x, texul.y ); meshBuilder.Normal3fv( &dz.x ); meshBuilder.AdvanceVertex(); } //----------------------------------------------------------------------------- // draws a procedural model, cross shape // two perpendicular sprites //----------------------------------------------------------------------------- #ifdef USE_DETAIL_SHAPES void CDetailModel::DrawTypeShapeCross( CMeshBuilder &meshBuilder, uint8 nAlpha ) { Assert( m_Type == DETAIL_PROP_TYPE_SHAPE_CROSS ); Vector vecColor; GetColorModulation( vecColor.Base() ); unsigned char color[4]; color[0] = (unsigned char)(vecColor[0] * 255.0f); color[1] = (unsigned char)(vecColor[1] * 255.0f); color[2] = (unsigned char)(vecColor[2] * 255.0f); color[3] = nAlpha; DetailPropSpriteDict_t &dict = s_DetailObjectSystem.DetailSpriteDict( m_SpriteInfo.m_nSpriteIndex ); Vector2D texul, texlr; texul = dict.m_TexUL; texlr = dict.m_TexLR; // What a shameless re-use of bits (m_pModel == 0 when it should be flipped horizontally) if ( !m_pModel ) { texul.x = dict.m_TexLR.x; texlr.x = dict.m_TexUL.x; } Vector2D texumid, texlmid; texumid.y = texul.y; texlmid.y = texlr.y; texumid.x = texlmid.x = ( texul.x + texlr.x ) / 2; Vector2D texll; texll.x = texul.x; texll.y = texlr.y; Vector2D ul, lr; float flScale = m_SpriteInfo.m_flScale.GetFloat(); Vector2DMultiply( dict.m_UL, flScale, ul ); Vector2DMultiply( dict.m_LR, flScale, lr ); float flSizeX = ( lr.x - ul.x ) / 2; float flSizeY = ( lr.y - ul.y ); UpdatePlayerAvoid(); // sway based on time plus a random seed that is constant for this instance of the sprite Vector vecSway = ( m_pAdvInfo->m_vecCurrentAvoid * flSizeX * 2 ); float flSwayAmplitude = m_pAdvInfo->m_flSwayAmount * cl_detail_max_sway.GetFloat(); if ( flSwayAmplitude > 0 ) { vecSway += UTIL_YawToVector( m_pAdvInfo->m_flSwayYaw ) * sin(gpGlobals->curtime+m_Origin.x) * flSwayAmplitude; } Vector vecOrigin; VectorMA( m_Origin, ul.y, m_pAdvInfo->m_vecAnglesUp[0], vecOrigin ); Vector forward, right, up; forward = m_pAdvInfo->m_vecAnglesForward[0] * flSizeX; right = m_pAdvInfo->m_vecAnglesRight[0] * flSizeX; up = m_pAdvInfo->m_vecAnglesUp[0] * flSizeY; // figure out drawing order so the branches sort properly // do dot products with the forward and right vectors to determine the quadrant the viewer is in // assume forward points North , right points East /* N | 3 | 0 W---------E 2 | 1 | S */ // eg if they are in quadrant 0, set iBranch to 0, and the draw order will be // 0, 1, 2, 3, or South, west, north, east Vector viewOffset = CurrentViewOrigin() - m_Origin; bool bForward = ( DotProduct( forward, viewOffset ) > 0 ); bool bRight = ( DotProduct( right, viewOffset ) > 0 ); int iBranch = bForward ? ( bRight ? 0 : 3 ) : ( bRight ? 1 : 2 ); //debugoverlay->AddLineOverlay( m_Origin, m_Origin + right * 20, 255, 0, 0, true, 0.01 ); //debugoverlay->AddLineOverlay( m_Origin, m_Origin + forward * 20, 0, 0, 255, true, 0.01 ); int iDrawn = 0; while( iDrawn < 4 ) { switch( iBranch ) { case 0: // south DrawSwayingQuad( meshBuilder, vecOrigin, vecSway, texumid, texlr, color, -forward, up ); break; case 1: // west DrawSwayingQuad( meshBuilder, vecOrigin, vecSway, texumid, texll, color, -right, up ); break; case 2: // north DrawSwayingQuad( meshBuilder, vecOrigin, vecSway, texumid, texll, color, forward, up ); break; case 3: // east DrawSwayingQuad( meshBuilder, vecOrigin, vecSway, texumid, texlr, color, right, up ); break; } iDrawn++; iBranch++; if ( iBranch > 3 ) iBranch = 0; } } #endif //----------------------------------------------------------------------------- // draws a procedural model, tri shape //----------------------------------------------------------------------------- #ifdef USE_DETAIL_SHAPES void CDetailModel::DrawTypeShapeTri( CMeshBuilder &meshBuilder, uint8 nAlpha ) { Assert( m_Type == DETAIL_PROP_TYPE_SHAPE_TRI ); Vector vecColor; GetColorModulation( vecColor.Base() ); unsigned char color[4]; color[0] = (unsigned char)(vecColor[0] * 255.0f); color[1] = (unsigned char)(vecColor[1] * 255.0f); color[2] = (unsigned char)(vecColor[2] * 255.0f); color[3] = nAlpha; DetailPropSpriteDict_t &dict = s_DetailObjectSystem.DetailSpriteDict( m_SpriteInfo.m_nSpriteIndex ); Vector2D texul, texlr; texul = dict.m_TexUL; texlr = dict.m_TexLR; // What a shameless re-use of bits (m_pModel == 0 when it should be flipped horizontally) if ( !m_pModel ) { texul.x = dict.m_TexLR.x; texlr.x = dict.m_TexUL.x; } Vector2D ul, lr; float flScale = m_SpriteInfo.m_flScale.GetFloat(); Vector2DMultiply( dict.m_UL, flScale, ul ); Vector2DMultiply( dict.m_LR, flScale, lr ); // sort the sides relative to the view origin Vector viewOffset = CurrentViewOrigin() - m_Origin; // three sides, A, B, C, counter-clockwise from A is the unrotated side bool bOutsideA = DotProduct( m_pAdvInfo->m_vecAnglesForward[0], viewOffset ) > 0; bool bOutsideB = DotProduct( m_pAdvInfo->m_vecAnglesForward[1], viewOffset ) > 0; bool bOutsideC = DotProduct( m_pAdvInfo->m_vecAnglesForward[2], viewOffset ) > 0; int iBranch = 0; if ( bOutsideA && !bOutsideB ) iBranch = 1; else if ( bOutsideB && !bOutsideC ) iBranch = 2; float flHeight, flWidth; flHeight = (lr.y - ul.y); flWidth = (lr.x - ul.x); Vector vecSway; Vector vecOrigin; Vector vecHeight, vecWidth; UpdatePlayerAvoid(); Vector vecSwayYaw = UTIL_YawToVector( m_pAdvInfo->m_flSwayYaw ); float flSwayAmplitude = m_pAdvInfo->m_flSwayAmount * cl_detail_max_sway.GetFloat(); int iDrawn = 0; while( iDrawn < 3 ) { vecHeight = m_pAdvInfo->m_vecAnglesUp[iBranch] * flHeight; vecWidth = m_pAdvInfo->m_vecAnglesRight[iBranch] * flWidth; VectorMA( m_Origin, ul.x, m_pAdvInfo->m_vecAnglesRight[iBranch], vecOrigin ); VectorMA( vecOrigin, ul.y, m_pAdvInfo->m_vecAnglesUp[iBranch], vecOrigin ); VectorMA( vecOrigin, m_pAdvInfo->m_flShapeSize*flWidth, m_pAdvInfo->m_vecAnglesForward[iBranch], vecOrigin ); // sway is calculated per side so they don't sway exactly the same Vector vecSway = ( m_pAdvInfo->m_vecCurrentAvoid * flWidth ) + vecSwayYaw * sin(gpGlobals->curtime+m_Origin.x+iBranch) * flSwayAmplitude; DrawSwayingQuad( meshBuilder, vecOrigin, vecSway, texul, texlr, color, vecWidth, vecHeight ); iDrawn++; iBranch++; if ( iBranch > 2 ) iBranch = 0; } } #endif //----------------------------------------------------------------------------- // checks for nearby players and pushes the detail to the side //----------------------------------------------------------------------------- #ifdef USE_DETAIL_SHAPES void CDetailModel::UpdatePlayerAvoid( void ) { float flForce = cl_detail_avoid_force.GetFloat(); if ( flForce < 0.1 ) return; if ( m_pAdvInfo == NULL ) return; // get players in a radius float flRadius = cl_detail_avoid_radius.GetFloat(); float flRecoverSpeed = cl_detail_avoid_recover_speed.GetFloat(); Vector vecAvoid; C_BaseEntity *pEnt; float flMaxForce = 0; Vector vecMaxAvoid(0,0,0); CPlayerEnumerator avoid( flRadius, m_Origin ); partition->EnumerateElementsInSphere( PARTITION_CLIENT_SOLID_EDICTS, m_Origin, flRadius, false, &avoid ); // Okay, decide how to avoid if there's anything close by int c = avoid.GetObjectCount(); for ( int i=0; iGetAbsOrigin(); vecAvoid.z = 0; float flDist = vecAvoid.Length2D(); if ( flDist > flRadius ) continue; float flForceScale = RemapValClamped( flDist, 0, flRadius, flForce, 0.0 ); if ( flForceScale > flMaxForce ) { flMaxForce = flForceScale; vecAvoid.NormalizeInPlace(); vecAvoid *= flMaxForce; vecMaxAvoid = vecAvoid; } } // if we are being moved, move fast. Else we recover at a slow rate if ( vecMaxAvoid.Length2D() > m_pAdvInfo->m_vecCurrentAvoid.Length2D() ) flRecoverSpeed = 10; // fast approach m_pAdvInfo->m_vecCurrentAvoid[0] = Approach( vecMaxAvoid[0], m_pAdvInfo->m_vecCurrentAvoid[0], flRecoverSpeed ); m_pAdvInfo->m_vecCurrentAvoid[1] = Approach( vecMaxAvoid[1], m_pAdvInfo->m_vecCurrentAvoid[1], flRecoverSpeed ); m_pAdvInfo->m_vecCurrentAvoid[2] = Approach( vecMaxAvoid[2], m_pAdvInfo->m_vecCurrentAvoid[2], flRecoverSpeed ); } #endif //----------------------------------------------------------------------------- // draws a quad that sways on the top two vertices // pass vecOrigin as the top left vertex position //----------------------------------------------------------------------------- #ifdef USE_DETAIL_SHAPES void CDetailModel::DrawSwayingQuad( CMeshBuilder &meshBuilder, Vector vecOrigin, Vector vecSway, Vector2D texul, Vector2D texlr, unsigned char *color, Vector width, Vector height ) { meshBuilder.Position3fv( (vecOrigin + vecSway).Base() ); meshBuilder.TexCoord2fv( 0, texul.Base() ); meshBuilder.Color4ubv( color ); meshBuilder.AdvanceVertex(); vecOrigin += height; meshBuilder.Position3fv( vecOrigin.Base() ); meshBuilder.TexCoord2f( 0, texul.x, texlr.y ); meshBuilder.Color4ubv( color ); meshBuilder.AdvanceVertex(); vecOrigin += width; meshBuilder.Position3fv( vecOrigin.Base() ); meshBuilder.TexCoord2fv( 0, texlr.Base() ); meshBuilder.Color4ubv( color ); meshBuilder.AdvanceVertex(); vecOrigin -= height; meshBuilder.Position3fv( (vecOrigin + vecSway).Base() ); meshBuilder.TexCoord2f( 0, texlr.x, texul.y ); meshBuilder.Color4ubv( color ); meshBuilder.AdvanceVertex(); } #endif //----------------------------------------------------------------------------- // constructor, destructor //----------------------------------------------------------------------------- CDetailObjectSystem::CDetailObjectSystem() : m_DetailSpriteDict( 0, 32 ), m_DetailObjectDict( 0, 32 ), m_DetailSpriteDictFlipped( 0, 32 ) { m_pFastSpriteData = NULL; m_pSortInfo = NULL; m_pFastSortInfo = NULL; m_pBuildoutBuffer = NULL; } void CDetailObjectSystem::FreeSortBuffers( void ) { if ( m_pSortInfo ) { MemAlloc_FreeAligned( m_pSortInfo ); m_pSortInfo = NULL; } if ( m_pFastSortInfo ) { MemAlloc_FreeAligned( m_pFastSortInfo ); m_pFastSortInfo = NULL; } if ( m_pBuildoutBuffer ) { MemAlloc_FreeAligned( m_pBuildoutBuffer ); m_pBuildoutBuffer = NULL; } } CDetailObjectSystem::~CDetailObjectSystem() { if ( m_pFastSpriteData ) { MemAlloc_FreeAligned( m_pFastSpriteData ); m_pFastSpriteData = NULL; } FreeSortBuffers(); } //----------------------------------------------------------------------------- // Level init, shutdown //----------------------------------------------------------------------------- void CDetailObjectSystem::LevelInitPreEntity() { if ( m_pFastSpriteData ) { MemAlloc_FreeAligned( m_pFastSpriteData ); m_pFastSpriteData = NULL; } FreeSortBuffers(); // Prepare the translucent detail sprite material; we only have 1! const char *pDetailSpriteMaterial = DETAIL_SPRITE_MATERIAL; C_World *pWorld = GetClientWorldEntity(); if ( pWorld && pWorld->GetDetailSpriteMaterial() && *(pWorld->GetDetailSpriteMaterial()) ) { pDetailSpriteMaterial = pWorld->GetDetailSpriteMaterial(); } m_DetailSpriteMaterial.Init( pDetailSpriteMaterial, TEXTURE_GROUP_OTHER ); m_DetailWireframeMaterial.Init( "debug/debugspritewireframe", TEXTURE_GROUP_OTHER ); // Version check if (engine->GameLumpVersion( GAMELUMP_DETAIL_PROPS ) < 4) { Warning("Map uses old detail prop file format.. ignoring detail props\n"); return; } MEM_ALLOC_CREDIT(); // Unserialize int size = engine->GameLumpSize( GAMELUMP_DETAIL_PROPS ); CUtlMemory fileMemory; fileMemory.EnsureCapacity( size ); if (engine->LoadGameLump( GAMELUMP_DETAIL_PROPS, fileMemory.Base(), size )) { CUtlBuffer buf( fileMemory.Base(), size, CUtlBuffer::READ_ONLY ); UnserializeModelDict( buf ); switch (engine->GameLumpVersion( GAMELUMP_DETAIL_PROPS ) ) { case 4: UnserializeDetailSprites( buf ); UnserializeModels( buf ); break; } } if ( m_DetailObjects.Count() || m_DetailSpriteDict.Count() ) { // There are detail objects in the level, so precache the material PrecacheMaterial( DETAIL_SPRITE_MATERIAL ); IMaterial *pMat = m_DetailSpriteMaterial; // adjust for non-square textures (cropped) float flRatio = pMat->GetMappingWidth() / pMat->GetMappingHeight(); if ( flRatio > 1.0 ) { for( int i = 0; iGetHDRType() != HDR_TYPE_NONE ) { detailPropLightingLump = GAMELUMP_DETAIL_PROP_LIGHTING_HDR; } else { detailPropLightingLump = GAMELUMP_DETAIL_PROP_LIGHTING; } size = engine->GameLumpSize( detailPropLightingLump ); fileMemory.EnsureCapacity( size ); if (engine->LoadGameLump( detailPropLightingLump, fileMemory.Base(), size )) { CUtlBuffer buf( fileMemory.Base(), size, CUtlBuffer::READ_ONLY ); UnserializeModelLighting( buf ); } } void CDetailObjectSystem::UpdateDetailFadeValues() { m_flDetailFadeEnd = cl_detaildist.GetInt(); m_flDetailFadeStart = m_flDetailFadeEnd - cl_detailfade.GetInt(); if ( m_flDetailFadeStart < 0 ) { m_flDetailFadeStart = 0; } if ( GetDetailController() ) { m_flDetailFadeStart = MIN( m_flDetailFadeStart, GetDetailController()->m_flFadeStartDist ); m_flDetailFadeEnd = MIN( m_flDetailFadeEnd, GetDetailController()->m_flFadeEndDist ); } } void CDetailObjectSystem::LevelInitPostEntity() { const char *pDetailSpriteMaterial = DETAIL_SPRITE_MATERIAL; C_World *pWorld = GetClientWorldEntity(); if ( pWorld && pWorld->GetDetailSpriteMaterial() && *(pWorld->GetDetailSpriteMaterial()) ) { pDetailSpriteMaterial = pWorld->GetDetailSpriteMaterial(); } m_DetailSpriteMaterial.Init( pDetailSpriteMaterial, TEXTURE_GROUP_OTHER ); UpdateDetailFadeValues(); } void CDetailObjectSystem::LevelShutdownPreEntity() { m_DetailObjects.Purge(); m_DetailObjectDict.Purge(); m_DetailSpriteDict.Purge(); m_DetailSpriteDictFlipped.Purge(); m_DetailLighting.Purge(); m_DetailSpriteMaterial.Shutdown(); } void CDetailObjectSystem::LevelShutdownPostEntity() { m_DetailWireframeMaterial.Shutdown(); } //----------------------------------------------------------------------------- // Computes distance fade //----------------------------------------------------------------------------- inline uint8 CDetailObjectSystem::ComputeDistanceFade( float *pDistSqr, const DistanceFadeInfo_t &info, const Vector &vecViewOrigin, const Vector &vecRenderOrigin ) const { float flDistSq = vecViewOrigin.DistToSqr( vecRenderOrigin ); *pDistSqr = flDistSq; if ( flDistSq >= info.m_flMaxDistSqr ) return 0; uint8 nAlpha = 255; if ( flDistSq > info.m_flMinDistSqr ) { nAlpha = 255.0f * info.m_flFalloffFactor * ( info.m_flMaxDistSqr - flDistSq ); } return nAlpha; } //----------------------------------------------------------------------------- // Before each view, blat out the stored detail sprite state //----------------------------------------------------------------------------- void CDetailObjectSystem::BeginTranslucentDetailRendering( ) { m_nSortedLeaf = -1; m_bFirstLeaf = true; m_nSpriteCount = m_nFirstSprite = 0; } //----------------------------------------------------------------------------- // Gets a particular detail object //----------------------------------------------------------------------------- IClientRenderable* CDetailObjectSystem::GetDetailModel( int idx ) { // FIXME: This is necessary because we have intermixed models + sprites // in a single list (m_DetailObjects) if (m_DetailObjects[idx].GetType() != DETAIL_PROP_TYPE_MODEL) return NULL; return &m_DetailObjects[idx]; } // How many detail models (as opposed to sprites) are there in the level? int CDetailObjectSystem::GetDetailModelCount() const { return m_DetailObjects.Count(); } //----------------------------------------------------------------------------- // Unserialization //----------------------------------------------------------------------------- void CDetailObjectSystem::UnserializeModelDict( CUtlBuffer& buf ) { int count = buf.GetInt(); m_DetailObjectDict.EnsureCapacity( count ); while ( --count >= 0 ) { DetailObjectDictLump_t lump; buf.Get( &lump, sizeof(DetailObjectDictLump_t) ); DetailModelDict_t dict; dict.m_pModel = (model_t *)engine->LoadModel( lump.m_Name, true ); // Don't allow vertex-lit models if (modelinfo->IsModelVertexLit(dict.m_pModel)) { Warning("Detail prop model %s is using vertex-lit materials!\nIt must use unlit materials!\n", lump.m_Name ); dict.m_pModel = (model_t *)engine->LoadModel( "models/error.mdl" ); } m_DetailObjectDict.AddToTail( dict ); } } void CDetailObjectSystem::UnserializeDetailSprites( CUtlBuffer& buf ) { int count = buf.GetInt(); m_DetailSpriteDict.EnsureCapacity( count ); m_DetailSpriteDictFlipped.EnsureCapacity( count ); while ( --count >= 0 ) { int i = m_DetailSpriteDict.AddToTail(); buf.Get( &m_DetailSpriteDict[i], sizeof(DetailSpriteDictLump_t) ); int flipi = m_DetailSpriteDictFlipped.AddToTail(); m_DetailSpriteDictFlipped[flipi] = m_DetailSpriteDict[i]; V_swap( m_DetailSpriteDictFlipped[flipi].m_TexUL.x, m_DetailSpriteDictFlipped[flipi].m_TexLR.x ); } } void CDetailObjectSystem::UnserializeModelLighting( CUtlBuffer& buf ) { int count = buf.GetInt(); m_DetailLighting.EnsureCapacity( count ); while ( --count >= 0 ) { int i = m_DetailLighting.AddToTail(); buf.Get( &m_DetailLighting[i], sizeof(DetailPropLightstylesLump_t) ); } } ConVar cl_detail_multiplier( "cl_detail_multiplier", "1", FCVAR_CHEAT, "extra details to create" ); #define SPRITE_MULTIPLIER ( cl_detail_multiplier.GetInt() ) ConVar cl_fastdetailsprites( "cl_fastdetailsprites", "1", FCVAR_CHEAT, "whether to use new detail sprite system"); static bool DetailObjectIsFastSprite( DetailObjectLump_t const & lump ) { return ( ( cl_fastdetailsprites.GetInt() ) && ( lump.m_Type == DETAIL_PROP_TYPE_SPRITE ) && ( lump.m_LightStyleCount == 0 ) && ( lump.m_Orientation == 2 ) && ( lump.m_ShapeAngle == 0 ) && ( lump.m_ShapeSize == 0 ) && ( lump.m_SwayAmount == 0 ) ); } void CDetailObjectSystem::ScanForCounts( CUtlBuffer& buf, int *pNumOldStyleObjects, int *pNumFastSpritesToAllocate, int *nMaxNumOldSpritesInLeaf, int *nMaxNumFastSpritesInLeaf ) const { int oldpos = buf.TellGet(); // we need to seek back int count = buf.GetInt(); int nOld = 0; int nFast = 0; int detailObjectLeaf = -1; int nNumOldInLeaf = 0; int nNumFastInLeaf = 0; int nMaxOld = 0; int nMaxFast = 0; while ( --count >= 0 ) { DetailObjectLump_t lump; buf.Get( &lump, sizeof(DetailObjectLump_t) ); // We rely on the fact that details objects are sorted by leaf in the // bsp file for this if ( detailObjectLeaf != lump.m_Leaf ) { // need to pad nfast to next sse boundary nFast += ( 0 - nFast ) & 3; nMaxFast = MAX( nMaxFast, nNumFastInLeaf ); nMaxOld = MAX( nMaxOld, nNumOldInLeaf ); nNumOldInLeaf = 0; nNumFastInLeaf = 0; detailObjectLeaf = lump.m_Leaf; } if ( DetailObjectIsFastSprite( lump ) ) { nFast += SPRITE_MULTIPLIER; nNumFastInLeaf += SPRITE_MULTIPLIER; } else { nOld += SPRITE_MULTIPLIER; nNumOldInLeaf += SPRITE_MULTIPLIER; } } // need to pad nfast to next sse boundary nFast += ( 0 - nFast ) & 3; nMaxFast = MAX( nMaxFast, nNumFastInLeaf ); nMaxOld = MAX( nMaxOld, nNumOldInLeaf ); buf.SeekGet( CUtlBuffer::SEEK_HEAD, oldpos ); *pNumFastSpritesToAllocate = nFast; *pNumOldStyleObjects = nOld; nMaxFast = ( 3 + nMaxFast ) & ~3; *nMaxNumOldSpritesInLeaf = nMaxOld; *nMaxNumFastSpritesInLeaf = nMaxFast; } //----------------------------------------------------------------------------- // Unserialize all models //----------------------------------------------------------------------------- void CDetailObjectSystem::UnserializeModels( CUtlBuffer& buf ) { int firstDetailObject = 0; int detailObjectCount = 0; int detailObjectLeaf = -1; int nNumOldStyleObjects; int nNumFastSpritesToAllocate; int nMaxOldInLeaf; int nMaxFastInLeaf; ScanForCounts( buf, &nNumOldStyleObjects, &nNumFastSpritesToAllocate, &nMaxOldInLeaf, &nMaxFastInLeaf ); FreeSortBuffers(); if ( nMaxOldInLeaf ) { m_pSortInfo = reinterpret_cast ( MemAlloc_AllocAligned( (3 + nMaxOldInLeaf ) * sizeof( SortInfo_t ), sizeof( fltx4 ) ) ); Assert( m_pSortInfo ); } if ( nMaxFastInLeaf ) { m_pFastSortInfo = reinterpret_cast ( MemAlloc_AllocAligned( (3 + nMaxFastInLeaf ) * sizeof( SortInfo_t ), sizeof( fltx4 ) ) ); Assert( m_pFastSortInfo ); m_pBuildoutBuffer = reinterpret_cast ( MemAlloc_AllocAligned( ( 1 + nMaxFastInLeaf / 4 ) * sizeof( FastSpriteQuadBuildoutBufferX4_t ), sizeof( fltx4 ) ) ); Assert( m_pBuildoutBuffer ); } if ( nNumFastSpritesToAllocate ) { Assert( ( nNumFastSpritesToAllocate & 3 ) == 0 ); Assert( ! m_pFastSpriteData ); // wtf? didn't free? m_pFastSpriteData = reinterpret_cast ( MemAlloc_AllocAligned( ( nNumFastSpritesToAllocate >> 2 ) * sizeof( FastSpriteX4_t ), sizeof( fltx4 ) ) ); Assert( m_pFastSpriteData ); } if ( nNumOldStyleObjects >= 1 << 24 ) { Assert( 0 ); Warning( "*** CDetailObjectSystem::UnserializeModels: Error! Too many detail objects!\n" ); } m_DetailObjects.EnsureCapacity( nNumOldStyleObjects ); int count = buf.GetInt(); int nCurFastObject = 0; int nNumFastObjectsInCurLeaf = 0; FastSpriteX4_t *pCurFastSpriteOut = m_pFastSpriteData; bool bFlipped = true; while ( --count >= 0 ) { bFlipped = !bFlipped; DetailObjectLump_t lump; buf.Get( &lump, sizeof(DetailObjectLump_t) ); // We rely on the fact that details objects are sorted by leaf in the // bsp file for this if ( detailObjectLeaf != lump.m_Leaf ) { if (detailObjectLeaf != -1) { if ( nNumFastObjectsInCurLeaf ) { CFastDetailLeafSpriteList *pNew = new CFastDetailLeafSpriteList; pNew->m_nNumSprites = nNumFastObjectsInCurLeaf; pNew->m_nNumSIMDSprites = ( 3 + nNumFastObjectsInCurLeaf ) >> 2; pNew->m_pSprites = pCurFastSpriteOut; pCurFastSpriteOut += pNew->m_nNumSIMDSprites; ClientLeafSystem()->SetSubSystemDataInLeaf( detailObjectLeaf, CLSUBSYSTEM_DETAILOBJECTS, pNew ); engine->SetLeafFlag( detailObjectLeaf, LEAF_FLAGS_CONTAINS_DETAILOBJECTS ); // for fast searches // round to see boundary nCurFastObject += ( 0 - nCurFastObject ) & 3; nNumFastObjectsInCurLeaf = 0; } ClientLeafSystem()->SetDetailObjectsInLeaf( detailObjectLeaf, firstDetailObject, detailObjectCount ); } detailObjectLeaf = lump.m_Leaf; firstDetailObject = m_DetailObjects.Count(); detailObjectCount = 0; } if ( DetailObjectIsFastSprite( lump ) ) { for( int i =0 ; i < SPRITE_MULTIPLIER ; i++) { FastSpriteX4_t *pSpritex4 = m_pFastSpriteData + (nCurFastObject >> 2 ); int nSubField = ( nCurFastObject & 3 ); Vector pos(0,0,0); if ( i ) { pos += RandomVector( -50, 50 ); pos.z = 0; } UnserializeFastSprite( pSpritex4, nSubField, lump, bFlipped, pos ); if ( nSubField == 0 ) pSpritex4->ReplicateFirstEntryToOthers(); // keep bad numbers out to prevent denormals, etc nCurFastObject++; nNumFastObjectsInCurLeaf++; } } else { switch( lump.m_Type ) { case DETAIL_PROP_TYPE_MODEL: { int newObj = m_DetailObjects.AddToTail(); m_DetailObjects[newObj].Init( newObj, lump.m_Origin, lump.m_Angles, m_DetailObjectDict[lump.m_DetailModel].m_pModel, lump.m_Lighting, lump.m_LightStyles, lump.m_LightStyleCount, lump.m_Orientation ); ++detailObjectCount; } break; case DETAIL_PROP_TYPE_SPRITE: case DETAIL_PROP_TYPE_SHAPE_CROSS: case DETAIL_PROP_TYPE_SHAPE_TRI: { for( int i=0;im_nNumSprites = nNumFastObjectsInCurLeaf; pNew->m_nNumSIMDSprites = ( 3 + nNumFastObjectsInCurLeaf ) >> 2; pNew->m_pSprites = pCurFastSpriteOut; pCurFastSpriteOut += pNew->m_nNumSIMDSprites; ClientLeafSystem()->SetSubSystemDataInLeaf( detailObjectLeaf, CLSUBSYSTEM_DETAILOBJECTS, pNew ); engine->SetLeafFlag( detailObjectLeaf, LEAF_FLAGS_CONTAINS_DETAILOBJECTS ); // for fast searches } ClientLeafSystem()->SetDetailObjectsInLeaf( detailObjectLeaf, firstDetailObject, detailObjectCount ); } engine->RecalculateBSPLeafFlags(); } Vector CDetailObjectSystem::GetSpriteMiddleBottomPosition( DetailObjectLump_t const &lump ) const { DetailPropSpriteDict_t &dict = s_DetailObjectSystem.DetailSpriteDict( lump.m_DetailModel ); Vector vecDir; QAngle Angles; VectorSubtract( lump.m_Origin + Vector(0,-100,0), lump.m_Origin, vecDir ); vecDir.z = 0.0f; VectorAngles( vecDir, Angles ); Vector vecOrigin, dx, dy; AngleVectors( Angles, NULL, &dx, &dy ); Vector2D ul, lr; float scale = lump.m_flScale; Vector2DMultiply( dict.m_UL, scale, ul ); Vector2DMultiply( dict.m_LR, scale, lr ); VectorMA( lump.m_Origin, ul.x, dx, vecOrigin ); VectorMA( vecOrigin, ul.y, dy, vecOrigin ); dx *= (lr.x - ul.x); dy *= (lr.y - ul.y); Vector2D texul, texlr; texul = dict.m_TexUL; texlr = dict.m_TexLR; return vecOrigin + dy + 0.5 * dx; } void CDetailObjectSystem::UnserializeFastSprite( FastSpriteX4_t *pSpritex4, int nSubField, DetailObjectLump_t const &lump, bool bFlipped, Vector const &posOffset ) { Vector pos = lump.m_Origin + posOffset; pos = GetSpriteMiddleBottomPosition( lump ) + posOffset; pSpritex4->m_Pos.X( nSubField ) = pos.x; pSpritex4->m_Pos.Y( nSubField ) = pos.y; pSpritex4->m_Pos.Z( nSubField ) = pos.z; DetailPropSpriteDict_t *pSDef = &m_DetailSpriteDict[lump.m_DetailModel]; SubFloat( pSpritex4->m_HalfWidth, nSubField ) = 0.5 * lump.m_flScale * ( pSDef->m_LR.x - pSDef->m_UL.x ); SubFloat( pSpritex4->m_Height, nSubField ) = lump.m_flScale * ( pSDef->m_LR.y - pSDef->m_UL.y ); if ( !bFlipped ) { pSDef = &m_DetailSpriteDictFlipped[lump.m_DetailModel]; } // do packed color ColorRGBExp32 rgbcolor = lump.m_Lighting; float color[4]; color[0] = TexLightToLinear( rgbcolor.r, rgbcolor.exponent ); color[1] = TexLightToLinear( rgbcolor.g, rgbcolor.exponent ); color[2] = TexLightToLinear( rgbcolor.b, rgbcolor.exponent ); color[3] = 255; engine->LinearToGamma( color, color ); pSpritex4->m_RGBColor[nSubField][0] = 255.0 * color[0]; pSpritex4->m_RGBColor[nSubField][1] = 255.0 * color[1]; pSpritex4->m_RGBColor[nSubField][2] = 255.0 * color[2]; pSpritex4->m_RGBColor[nSubField][3] = 255; pSpritex4->m_pSpriteDefs[nSubField] = pSDef; } //----------------------------------------------------------------------------- // Count the number of detail sprites in the leaf list //----------------------------------------------------------------------------- int CDetailObjectSystem::CountSpritesInLeafList( int nLeafCount, LeafIndex_t *pLeafList ) const { VPROF_BUDGET( "CDetailObjectSystem::CountSpritesInLeafList", VPROF_BUDGETGROUP_DETAILPROP_RENDERING ); int nPropCount = 0; int nFirstDetailObject, nDetailObjectCount; for ( int i = 0; i < nLeafCount; ++i ) { // FIXME: This actually counts *everything* in the leaf, which is ok for now // given how we're using it ClientLeafSystem()->GetDetailObjectsInLeaf( pLeafList[i], nFirstDetailObject, nDetailObjectCount ); nPropCount += nDetailObjectCount; } return nPropCount; } //----------------------------------------------------------------------------- // Count the number of fast sprites in the leaf list //----------------------------------------------------------------------------- int CDetailObjectSystem::CountFastSpritesInLeafList( int nLeafCount, LeafIndex_t const *pLeafList, int *nMaxFoundInLeaf ) const { VPROF_BUDGET( "CDetailObjectSystem::CountSpritesInLeafList", VPROF_BUDGETGROUP_DETAILPROP_RENDERING ); int nCount = 0; int nMax = 0; for ( int i = 0; i < nLeafCount; ++i ) { CFastDetailLeafSpriteList *pData = reinterpret_cast< CFastDetailLeafSpriteList *> ( ClientLeafSystem()->GetSubSystemDataInLeaf( pLeafList[i], CLSUBSYSTEM_DETAILOBJECTS ) ); if ( pData ) { nCount += pData->m_nNumSprites; nMax = MAX( nMax, pData->m_nNumSprites ); } } *nMaxFoundInLeaf = ( nMax + 3 ) & ~3; // round up return nCount; } //----------------------------------------------------------------------------- // Count the number of detail sprite quads in the leaf list //----------------------------------------------------------------------------- int CDetailObjectSystem::CountSpriteQuadsInLeafList( int nLeafCount, LeafIndex_t *pLeafList ) const { #ifdef USE_DETAIL_SHAPES VPROF_BUDGET( "CDetailObjectSystem::CountSpritesInLeafList", VPROF_BUDGETGROUP_DETAILPROP_RENDERING ); int nQuadCount = 0; int nFirstDetailObject, nDetailObjectCount; for ( int i = 0; i < nLeafCount; ++i ) { // FIXME: This actually counts *everything* in the leaf, which is ok for now // given how we're using it ClientLeafSystem()->GetDetailObjectsInLeaf( pLeafList[i], nFirstDetailObject, nDetailObjectCount ); for ( int j = 0; j < nDetailObjectCount; ++j ) { nQuadCount += m_DetailObjects[j + nFirstDetailObject].QuadsToDraw(); } } return nQuadCount; #else return CountSpritesInLeafList( nLeafCount, pLeafList ); #endif } #define TREATASINT(x) ( *( ( (int32 const *)( &(x) ) ) ) ) //----------------------------------------------------------------------------- // Sorts sprites in back-to-front order //----------------------------------------------------------------------------- inline bool CDetailObjectSystem::SortLessFunc( const CDetailObjectSystem::SortInfo_t &left, const CDetailObjectSystem::SortInfo_t &right ) { return TREATASINT( left.m_flDistance ) > TREATASINT( right.m_flDistance ); } int CDetailObjectSystem::SortSpritesBackToFront( int nLeaf, const Vector &viewOrigin, const DistanceFadeInfo_t &fadeInfo, SortInfo_t *pSortInfo ) { VPROF_BUDGET( "CDetailObjectSystem::SortSpritesBackToFront", VPROF_BUDGETGROUP_DETAILPROP_RENDERING ); int nFirstDetailObject, nDetailObjectCount; ClientLeafSystem()->GetDetailObjectsInLeaf( nLeaf, nFirstDetailObject, nDetailObjectCount ); Vector vecDelta; int nCount = 0; nDetailObjectCount += nFirstDetailObject; for ( int j = nFirstDetailObject; j < nDetailObjectCount; ++j ) { CDetailModel &model = m_DetailObjects[j]; if ( model.GetType() == DETAIL_PROP_TYPE_MODEL ) continue; float flSqDist; uint8 nAlpha = ComputeDistanceFade( &flSqDist, fadeInfo, viewOrigin, model.GetRenderOrigin() ); if ( nAlpha == 0 ) continue; // Perform screen alignment if necessary. model.ComputeAngles(); SortInfo_t *pSortInfoCurrent = &pSortInfo[nCount]; pSortInfoCurrent->m_nIndex = j; pSortInfoCurrent->m_nAlpha = nAlpha; // Compute distance from the camera to each object pSortInfoCurrent->m_flDistance = flSqDist; ++nCount; } if ( nCount ) { VPROF( "CDetailObjectSystem::SortSpritesBackToFront -- Sort" ); std::make_heap( pSortInfo, pSortInfo + nCount, SortLessFunc ); std::sort_heap( pSortInfo, pSortInfo + nCount, SortLessFunc ); } return nCount; } #define MAGIC_NUMBER (1<<23) #ifdef PLAT_BIG_ENDIAN #define MANTISSA_LSB_OFFSET 3 #else #define MANTISSA_LSB_OFFSET 0 #endif static fltx4 Four_MagicNumbers={ MAGIC_NUMBER, MAGIC_NUMBER, MAGIC_NUMBER, MAGIC_NUMBER }; static fltx4 Four_255s={ 255.0, 255.0, 255.0, 255.0 }; static ALIGN16 int32 And255Mask[4] ALIGN16_POST = {0xff,0xff,0xff,0xff}; #define PIXMASK ( * ( reinterpret_cast< fltx4 *>( &And255Mask ) ) ) int CDetailObjectSystem::BuildOutSortedSprites( CFastDetailLeafSpriteList *pData, const DistanceFadeInfo_t &info, Vector const &viewOrigin, Vector const &viewForward, Vector const &viewRight, Vector const &viewUp ) { // part 1 - do all vertex math, fading, etc into a buffer, using as much simd as we can int nSIMDSprites = pData->m_nNumSIMDSprites; FastSpriteX4_t const *pSprites = pData->m_pSprites; SortInfo_t *pOut = m_pFastSortInfo; pOut[0].m_nIndex = 1; FastSpriteQuadBuildoutBufferX4_t *pQuadBufferOut = m_pBuildoutBuffer; pQuadBufferOut->m_Coords[0].x = Four_Zeros; int curidx = 0; int nLastBfMask = 0; Vector4D vNormal( -viewForward.x, -viewForward.y, -viewForward.z, 0.0 ); FourVectors vecViewPos; vecViewPos.DuplicateVector( viewOrigin ); fltx4 maxsqdist = ReplicateX4( info.m_flMaxDistSqr ); fltx4 falloffFactor = ReplicateX4( 1.0/ ( info.m_flMaxDistSqr - info.m_flMinDistSqr ) ); fltx4 startFade = ReplicateX4( info.m_flMinDistSqr ); FourVectors vecUp; vecUp.DuplicateVector(Vector(0,0,1) ); FourVectors vecFwd; vecFwd.DuplicateVector( viewForward ); do { // calculate alpha FourVectors ofs = pSprites->m_Pos; ofs -= vecViewPos; fltx4 ofsDotFwd = ofs * vecFwd; fltx4 distanceSquared = ofs * ofs; nLastBfMask = TestSignSIMD( OrSIMD( ofsDotFwd, CmpGtSIMD( distanceSquared, maxsqdist ) ) ); // cull if ( nLastBfMask != 0xf ) { FourVectors dx1; dx1.x = fnegate( ofs.y ); dx1.y = ( ofs.x ); dx1.z = Four_Zeros; dx1.VectorNormalizeFast(); FourVectors vecDx = dx1; FourVectors vecDy = vecUp; FourVectors vecPos0 = pSprites->m_Pos; vecDx *= pSprites->m_HalfWidth; vecDy *= pSprites->m_Height; fltx4 alpha = MulSIMD( falloffFactor, SubSIMD( distanceSquared, startFade ) ); alpha = SubSIMD( Four_Ones, MinSIMD( MaxSIMD( alpha, Four_Zeros), Four_Ones ) ); pQuadBufferOut->m_Alpha = AddSIMD( Four_MagicNumbers, MulSIMD( Four_255s,alpha ) ); vecPos0 += vecDx; pQuadBufferOut->m_Coords[0] = vecPos0; vecPos0 -= vecDy; pQuadBufferOut->m_Coords[1] = vecPos0; vecPos0 -= vecDx; vecPos0 -= vecDx; pQuadBufferOut->m_Coords[2] = vecPos0; vecPos0 += vecDy; pQuadBufferOut->m_Coords[3] = vecPos0; fltx4 fetch4 = *( ( fltx4 *) ( &pSprites->m_pSpriteDefs[0] ) ); *( (fltx4 *) ( & ( pQuadBufferOut->m_pSpriteDefs[0] ) ) ) = fetch4; fetch4 = *( ( fltx4 *) ( &pSprites->m_RGBColor[0][0] ) ); *( (fltx4 *) ( & ( pQuadBufferOut->m_RGBColor[0][0] ) ) ) = fetch4; //!! bug!! store distance // !! speed!! simd? pOut[0].m_nIndex = curidx; pOut[0].m_flDistance = SubFloat( distanceSquared, 0 ); pOut[1].m_nIndex = curidx+1; pOut[1].m_flDistance = SubFloat( distanceSquared, 1 ); pOut[2].m_nIndex = curidx+2; pOut[2].m_flDistance = SubFloat( distanceSquared, 2 ); pOut[3].m_nIndex = curidx+3; pOut[3].m_flDistance = SubFloat( distanceSquared, 3 ); pQuadBufferOut->m_Normal = vNormal; curidx += 4; pOut += 4; pQuadBufferOut++; } pSprites++; } while( --nSIMDSprites ); // adjust count for tail int nCount = pOut - m_pFastSortInfo; if ( nLastBfMask != 0xf ) // if last not skipped nCount -= ( 0 - pData->m_nNumSprites ) & 3; // part 2 - sort if ( nCount ) { VPROF( "CDetailObjectSystem::SortSpritesBackToFront -- Sort" ); std::make_heap( m_pFastSortInfo, m_pFastSortInfo + nCount, SortLessFunc ); std::sort_heap( m_pFastSortInfo, m_pFastSortInfo + nCount, SortLessFunc ); } return nCount; } static void s_RenderFastSpriteGuts( CDetailObjectSystem *pThis, DistanceFadeInfo_t info, Vector viewOrigin, Vector viewForward, Vector viewRight, Vector viewUp, int nNumLeafs, CUtlEnvelope const &leaflist ) { pThis->RenderFastSprites( info, viewOrigin, viewForward, viewRight, viewUp, nNumLeafs, leaflist ); } void CDetailObjectSystem::RenderFastSprites( const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeafCount, LeafIndex_t const * pLeafList ) { // Here, we must draw all detail objects back-to-front // FIXME: Cache off a sorted list so we don't have to re-sort every frame // Count the total # of detail quads we possibly could render int nMaxInLeaf; int nQuadCount = CountFastSpritesInLeafList( nLeafCount, pLeafList, &nMaxInLeaf ); if ( nQuadCount == 0 ) return; if ( r_DrawDetailProps.GetInt() == 0 ) return; CMatRenderContextPtr pRenderContext( materials ); pRenderContext->MatrixMode( MATERIAL_MODEL ); pRenderContext->PushMatrix(); pRenderContext->LoadIdentity(); IMaterial *pMaterial = m_DetailSpriteMaterial; if ( ShouldDrawInWireFrameMode() || r_DrawDetailProps.GetInt() == 2 ) { pMaterial = m_DetailWireframeMaterial; } CMeshBuilder meshBuilder; DetailPropFlashlightMode_t flashlightMode = DetailPropFlashlightMode(); IMesh *pMesh = pRenderContext->GetDynamicMesh( flashlightMode != DPFM_MULTIPASS, NULL, NULL, pMaterial ); int nMaxVerts, nMaxIndices; pRenderContext->GetMaxToRender( pMesh, false, &nMaxVerts, &nMaxIndices ); int nMaxQuadsToDraw = nMaxIndices / 6; if ( nMaxQuadsToDraw > nMaxVerts / 4 ) { nMaxQuadsToDraw = nMaxVerts / 4; } int nQuadsToDraw = MIN( nQuadCount, nMaxQuadsToDraw ); int nQuadsRemaining = nQuadsToDraw; meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); // Sort detail sprites in each leaf independently; then render them for ( int i = 0; i < nLeafCount; ++i ) { int nLeaf = pLeafList[i]; CFastDetailLeafSpriteList *pData = reinterpret_cast ( ClientLeafSystem()->GetSubSystemDataInLeaf( nLeaf, CLSUBSYSTEM_DETAILOBJECTS ) ); if ( pData ) { Assert( pData->m_nNumSprites ); // ptr with no sprites? int nCount = BuildOutSortedSprites( pData, info, viewOrigin, viewForward, viewRight, viewUp ); // part 3 - stuff the sorted sprites into the vb SortInfo_t const *pDraw = m_pFastSortInfo; FastSpriteQuadBuildoutBufferNonSIMDView_t const *pQuadBuffer = ( FastSpriteQuadBuildoutBufferNonSIMDView_t const *) m_pBuildoutBuffer; COMPILE_TIME_ASSERT( sizeof( FastSpriteQuadBuildoutBufferNonSIMDView_t ) == sizeof( FastSpriteQuadBuildoutBufferX4_t ) ); while( nCount ) { if ( ! nQuadsRemaining ) // no room left? { meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); nQuadsRemaining = nQuadsToDraw; meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); } int nToDraw = MIN( nCount, nQuadsRemaining ); nCount -= nToDraw; nQuadsRemaining -= nToDraw; while( nToDraw-- ) { // draw the sucker int nSIMDIdx = pDraw->m_nIndex >> 2; int nSubIdx = pDraw->m_nIndex & 3; FastSpriteQuadBuildoutBufferNonSIMDView_t const *pquad = pQuadBuffer+nSIMDIdx; const Vector4D &vNormal = pquad->m_Normal; // voodoo - since everything is in 4s, offset structure pointer by a couple of floats to handle sub-index pquad = (FastSpriteQuadBuildoutBufferNonSIMDView_t const *) ( ( (int) ( pquad ) )+ ( nSubIdx << 2 ) ); uint8 const *pColorsCasted = reinterpret_cast ( pquad->m_Alpha ); uint8 color[4]; color[0] = pquad->m_RGBColor[0][0]; color[1] = pquad->m_RGBColor[0][1]; color[2] = pquad->m_RGBColor[0][2]; color[3] = pColorsCasted[MANTISSA_LSB_OFFSET]; DetailPropSpriteDict_t *pDict = pquad->m_pSpriteDefs[0]; meshBuilder.Position3f( pquad->m_flX0[0], pquad->m_flY0[0], pquad->m_flZ0[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexLR.x, pDict->m_TexLR.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); meshBuilder.Position3f( pquad->m_flX1[0], pquad->m_flY1[0], pquad->m_flZ1[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexLR.x, pDict->m_TexUL.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); meshBuilder.Position3f( pquad->m_flX2[0], pquad->m_flY2[0], pquad->m_flZ2[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexUL.x, pDict->m_TexUL.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); meshBuilder.Position3f( pquad->m_flX3[0], pquad->m_flY3[0], pquad->m_flZ3[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexUL.x, pDict->m_TexLR.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); pDraw++; } } } } meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); pRenderContext->PopMatrix(); } static void PushSinglePassFlashLightState( DetailPropFlashlightMode_t nMode ) { //#ifndef _X360 shadowmgr->PushSinglePassFlashlightStateEnabled( nMode == DPFM_SINGLEPASS ); //#endif } static void PopSinglePassFlashLightState( void ) { //#ifndef _X360 shadowmgr->PopSinglePassFlashlightStateEnabled(); //#endif } //----------------------------------------------------------------------------- // Renders all translucent detail objects in a particular set of leaves //----------------------------------------------------------------------------- void CDetailObjectSystem::RenderTranslucentDetailObjects( const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeafCount, LeafIndex_t *pLeafList ) { VPROF_BUDGET( "CDetailObjectSystem::RenderTranslucentDetailObjects", VPROF_BUDGETGROUP_DETAILPROP_RENDERING ); if (nLeafCount == 0) return; // We better not have any partially drawn leaf of detail sprites! Assert( m_nSpriteCount == m_nFirstSprite ); DetailPropFlashlightMode_t flashlightMode = DetailPropFlashlightMode(); PushSinglePassFlashLightState( flashlightMode ); // Here, we must draw all detail objects back-to-front CMatRenderContextPtr pRenderContext( materials ); Assert( m_pFastSortInfo ); ICallQueue *pQueue = pRenderContext->GetCallQueue(); if ( pQueue && r_ThreadedDetailProps.GetInt() ) { pQueue->QueueCall( s_RenderFastSpriteGuts, this, info, viewOrigin, viewForward, viewRight, viewUp, nLeafCount, CUtlEnvelope( pLeafList, nLeafCount ) ); } else RenderFastSprites( info, viewOrigin, viewForward, viewRight, viewUp, nLeafCount, pLeafList ); PopSinglePassFlashLightState(); // FIXME: Cache off a sorted list so we don't have to re-sort every frame // Count the total # of detail quads we possibly could render int nQuadCount = CountSpriteQuadsInLeafList( nLeafCount, pLeafList ); if ( nQuadCount == 0 ) return; PushSinglePassFlashLightState( flashlightMode ); pRenderContext->MatrixMode( MATERIAL_MODEL ); pRenderContext->PushMatrix(); pRenderContext->LoadIdentity(); IMaterial *pMaterial = m_DetailSpriteMaterial; if ( ShouldDrawInWireFrameMode() || r_DrawDetailProps.GetInt() == 2 ) { pMaterial = m_DetailWireframeMaterial; } CMeshBuilder meshBuilder; IMesh *pMesh = pRenderContext->GetDynamicMesh( flashlightMode != DPFM_MULTIPASS, NULL, NULL, pMaterial ); int nMaxVerts, nMaxIndices; pRenderContext->GetMaxToRender( pMesh, false, &nMaxVerts, &nMaxIndices ); int nMaxQuadsToDraw = nMaxIndices / 6; if ( nMaxQuadsToDraw > nMaxVerts / 4 ) { nMaxQuadsToDraw = nMaxVerts / 4; } int nQuadsToDraw = nQuadCount; if ( nQuadsToDraw > nMaxQuadsToDraw ) { nQuadsToDraw = nMaxQuadsToDraw; } meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); int nQuadsDrawn = 0; for ( int i = 0; i < nLeafCount; ++i ) { int nLeaf = pLeafList[i]; int nFirstDetailObject, nDetailObjectCount; ClientLeafSystem()->GetDetailObjectsInLeaf( nLeaf, nFirstDetailObject, nDetailObjectCount ); // Sort detail sprites in each leaf independently; then render them SortInfo_t *pSortInfo = m_pSortInfo; int nCount = SortSpritesBackToFront( nLeaf, viewOrigin, info, pSortInfo ); for ( int j = 0; j < nCount; ++j ) { CDetailModel &model = m_DetailObjects[ pSortInfo[j].m_nIndex ]; int nQuadsInModel = model.QuadsToDraw(); // Prevent the batches from getting too large if ( nQuadsDrawn + nQuadsInModel > nQuadsToDraw ) { meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); nQuadCount -= nQuadsDrawn; nQuadsToDraw = nQuadCount; if (nQuadsToDraw > nMaxQuadsToDraw) { nQuadsToDraw = nMaxQuadsToDraw; } meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); nQuadsDrawn = 0; } model.DrawSprite( meshBuilder, pSortInfo[j].m_nAlpha ); nQuadsDrawn += nQuadsInModel; } } meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); PopSinglePassFlashLightState(); pRenderContext->PopMatrix(); } void CDetailObjectSystem::RenderFastTranslucentDetailObjectsInLeaf( CFastDetailLeafSpriteList *pData, const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeaf, const Vector &vecClosestPoint, bool bFirstCallThisFrame ) { if ( bFirstCallThisFrame || ( m_nSortedFastLeaf != nLeaf ) ) { m_nSortedFastLeaf = nLeaf; pData->m_nNumPendingSprites = BuildOutSortedSprites( pData, info, viewOrigin, viewForward, viewRight, viewUp ); pData->m_nStartSpriteIndex = 0; } if ( pData->m_nNumPendingSprites == 0 ) { return; } Vector vecDelta; VectorSubtract( vecClosestPoint, viewOrigin, vecDelta ); float flMinDistance = vecDelta.LengthSqr(); // we're not supposed to render sprites < flmindistance if ( m_pFastSortInfo[pData->m_nStartSpriteIndex].m_flDistance < flMinDistance ) { return; } int nCount = pData->m_nNumPendingSprites; CMatRenderContextPtr pRenderContext( materials ); pRenderContext->MatrixMode( MATERIAL_MODEL ); pRenderContext->PushMatrix(); pRenderContext->LoadIdentity(); IMaterial *pMaterial = m_DetailSpriteMaterial; if ( ShouldDrawInWireFrameMode() || r_DrawDetailProps.GetInt() == 2 ) { pMaterial = m_DetailWireframeMaterial; } CMeshBuilder meshBuilder; DetailPropFlashlightMode_t flashlightMode = DetailPropFlashlightMode(); IMesh *pMesh = pRenderContext->GetDynamicMesh( false /*flashlightMode != DPFM_MULTIPASS*/, NULL, NULL, pMaterial ); int nMaxVerts, nMaxIndices; pRenderContext->GetMaxToRender( pMesh, false, &nMaxVerts, &nMaxIndices ); int nMaxQuadsToDraw = nMaxIndices / 6; if ( nMaxQuadsToDraw > nMaxVerts / 4 ) { nMaxQuadsToDraw = nMaxVerts / 4; } int nQuadsToDraw = MIN( nCount, nMaxQuadsToDraw ); int nQuadsRemaining = nQuadsToDraw; meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); SortInfo_t const *pDraw = m_pFastSortInfo + pData->m_nStartSpriteIndex; FastSpriteQuadBuildoutBufferNonSIMDView_t const *pQuadBuffer = ( FastSpriteQuadBuildoutBufferNonSIMDView_t const *) m_pBuildoutBuffer; while( nCount && ( pDraw->m_flDistance >= flMinDistance ) ) { if ( ! nQuadsRemaining ) // no room left? { meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); nQuadsRemaining = nQuadsToDraw; meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); } int nToDraw = MIN( nCount, nQuadsRemaining ); nCount -= nToDraw; nQuadsRemaining -= nToDraw; while( nToDraw-- ) { // draw the sucker int nSIMDIdx = pDraw->m_nIndex >> 2; int nSubIdx = pDraw->m_nIndex & 3; FastSpriteQuadBuildoutBufferNonSIMDView_t const *pquad = pQuadBuffer+nSIMDIdx; const Vector4D &vNormal = pquad->m_Normal; // voodoo - since everything is in 4s, offset structure pointer by a couple of floats to handle sub-index pquad = (FastSpriteQuadBuildoutBufferNonSIMDView_t const *) ( ( (int) ( pquad ) )+ ( nSubIdx << 2 ) ); uint8 const *pColorsCasted = reinterpret_cast ( pquad->m_Alpha ); uint8 color[4]; color[0] = pquad->m_RGBColor[0][0]; color[1] = pquad->m_RGBColor[0][1]; color[2] = pquad->m_RGBColor[0][2]; color[3] = pColorsCasted[MANTISSA_LSB_OFFSET]; DetailPropSpriteDict_t *pDict = pquad->m_pSpriteDefs[0]; meshBuilder.Position3f( pquad->m_flX0[0], pquad->m_flY0[0], pquad->m_flZ0[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexLR.x, pDict->m_TexLR.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); meshBuilder.Position3f( pquad->m_flX1[0], pquad->m_flY1[0], pquad->m_flZ1[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexLR.x, pDict->m_TexUL.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); meshBuilder.Position3f( pquad->m_flX2[0], pquad->m_flY2[0], pquad->m_flZ2[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexUL.x, pDict->m_TexUL.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); meshBuilder.Position3f( pquad->m_flX3[0], pquad->m_flY3[0], pquad->m_flZ3[0] ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, pDict->m_TexUL.x, pDict->m_TexLR.y ); meshBuilder.Normal3fv( vNormal.Base() ); meshBuilder.AdvanceVertexF(); pDraw++; } } pData->m_nNumPendingSprites = nCount; pData->m_nStartSpriteIndex = pDraw - m_pFastSortInfo; meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); pRenderContext->PopMatrix(); } //----------------------------------------------------------------------------- // Renders a subset of the detail objects in a particular leaf (for interleaving with other translucent entities) //----------------------------------------------------------------------------- void CDetailObjectSystem::RenderTranslucentDetailObjectsInLeaf( const DistanceFadeInfo_t &info, const Vector &viewOrigin, const Vector &viewForward, const Vector &viewRight, const Vector &viewUp, int nLeaf, const Vector *pVecClosestPoint ) { VPROF_BUDGET( "CDetailObjectSystem::RenderTranslucentDetailObjectsInLeaf", VPROF_BUDGETGROUP_DETAILPROP_RENDERING ); if ( r_DrawDetailProps.GetInt() == 0 ) return; DetailPropFlashlightMode_t flashlightMode = DetailPropFlashlightMode(); CFastDetailLeafSpriteList *pData = reinterpret_cast< CFastDetailLeafSpriteList *> ( ClientLeafSystem()->GetSubSystemDataInLeaf( nLeaf, CLSUBSYSTEM_DETAILOBJECTS ) ); if ( pData ) { shadowmgr->PushSinglePassFlashlightStateEnabled( flashlightMode == DPFM_SINGLEPASS ); CMatRenderContextPtr pRenderContext( materials ); Assert( m_pFastSortInfo ); ICallQueue *pQueue = pRenderContext->GetCallQueue(); Vector cpnt = viewOrigin; if ( pVecClosestPoint ) { cpnt = *pVecClosestPoint; } if ( pQueue && r_ThreadedDetailProps.GetInt() ) { pQueue->QueueCall( this, &CDetailObjectSystem::RenderFastTranslucentDetailObjectsInLeaf, pData, RefToVal( info ), viewOrigin, viewForward, viewRight, viewUp, nLeaf, cpnt, m_bFirstLeaf ); } else { RenderFastTranslucentDetailObjectsInLeaf( pData, info, viewOrigin, viewForward, viewRight, viewUp, nLeaf, cpnt, m_bFirstLeaf ); } m_bFirstLeaf = false; shadowmgr->PopSinglePassFlashlightStateEnabled(); } // We may have already sorted this leaf. If not, sort the leaf. if ( m_nSortedLeaf != nLeaf ) { m_nSortedLeaf = nLeaf; m_nSpriteCount = 0; m_nFirstSprite = 0; // Count the total # of detail sprites we possibly could render LeafIndex_t nLeafIndex = nLeaf; int nSpriteCount = CountSpritesInLeafList( 1, &nLeafIndex ); if (nSpriteCount == 0) return; // Sort detail sprites in each leaf independently; then render them m_nSpriteCount = SortSpritesBackToFront( nLeaf, viewOrigin, info, m_pSortInfo ); Assert( m_nSpriteCount <= nSpriteCount ); } // No more to draw? Bye! if ( m_nSpriteCount == m_nFirstSprite ) return; float flMinDistance = 0.0f; if ( pVecClosestPoint ) { Vector vecDelta; VectorSubtract( *pVecClosestPoint, viewOrigin, vecDelta ); flMinDistance = vecDelta.LengthSqr(); } if ( m_pSortInfo[m_nFirstSprite].m_flDistance < flMinDistance ) return; CMatRenderContextPtr pRenderContext( materials ); pRenderContext->MatrixMode( MATERIAL_MODEL ); pRenderContext->PushMatrix(); pRenderContext->LoadIdentity(); IMaterial *pMaterial = m_DetailSpriteMaterial; if ( ShouldDrawInWireFrameMode() || r_DrawDetailProps.GetInt() == 2 ) { pMaterial = m_DetailWireframeMaterial; } CMeshBuilder meshBuilder; IMesh *pMesh = pRenderContext->GetDynamicMesh( flashlightMode != DPFM_MULTIPASS, NULL, NULL, pMaterial ); shadowmgr->PushSinglePassFlashlightStateEnabled( flashlightMode == DPFM_SINGLEPASS ); int nMaxVerts, nMaxIndices; pRenderContext->GetMaxToRender( pMesh, false, &nMaxVerts, &nMaxIndices ); // needs to be * 4 since there are a max of 4 quads per detail object int nQuadCount = ( m_nSpriteCount - m_nFirstSprite ) * 4; int nMaxQuadsToDraw = nMaxIndices/6; if ( nMaxQuadsToDraw > nMaxVerts / 4 ) { nMaxQuadsToDraw = nMaxVerts / 4; } int nQuadsToDraw = nQuadCount; if ( nQuadsToDraw > nMaxQuadsToDraw ) { nQuadsToDraw = nMaxQuadsToDraw; } meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); int nQuadsDrawn = 0; while ( m_nFirstSprite < m_nSpriteCount && m_pSortInfo[m_nFirstSprite].m_flDistance >= flMinDistance ) { CDetailModel &model = m_DetailObjects[m_pSortInfo[m_nFirstSprite].m_nIndex]; int nQuadsInModel = model.QuadsToDraw(); if ( nQuadsDrawn + nQuadsInModel > nQuadsToDraw ) { meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); nQuadCount = ( m_nSpriteCount - m_nFirstSprite ) * 4; nQuadsToDraw = nQuadCount; if (nQuadsToDraw > nMaxQuadsToDraw) { nQuadsToDraw = nMaxQuadsToDraw; } meshBuilder.Begin( pMesh, MATERIAL_QUADS, nQuadsToDraw ); nQuadsDrawn = 0; } model.DrawSprite( meshBuilder, m_pSortInfo[m_nFirstSprite].m_nAlpha ); ++m_nFirstSprite; nQuadsDrawn += nQuadsInModel; } meshBuilder.End(); pMesh->Draw(); if( flashlightMode == DPFM_MULTIPASS ) shadowmgr->FlashlightDrawCallback( DrawMeshCallback, pMesh ); shadowmgr->PopSinglePassFlashlightStateEnabled(); pRenderContext->PopMatrix(); } //----------------------------------------------------------------------------- // Computes a distance fade factor (returns fade distance) //----------------------------------------------------------------------------- float CDetailObjectSystem::ComputeDetailFadeInfo( DistanceFadeInfo_t *pInfo ) { C_BasePlayer *pLocal = C_BasePlayer::GetLocalPlayer(); float flFactor = pLocal ? pLocal->GetFOVDistanceAdjustFactor() : 1.0f; float flDetailDist = m_flDetailFadeEnd / flFactor; pInfo->m_flMaxDistSqr = flDetailDist * flDetailDist; pInfo->m_flMinDistSqr = m_flDetailFadeStart / flFactor; pInfo->m_flMinDistSqr *= pInfo->m_flMinDistSqr; pInfo->m_flMinDistSqr = MIN( pInfo->m_flMinDistSqr, pInfo->m_flMaxDistSqr - 1 ); pInfo->m_flFalloffFactor = 1.0f / ( pInfo->m_flMaxDistSqr - pInfo->m_flMinDistSqr ); return flDetailDist; } //----------------------------------------------------------------------------- // Builds a list of renderable info for all detail objects to render //----------------------------------------------------------------------------- void CDetailObjectSystem::BuildRenderingData( DetailRenderableList_t &list, const SetupRenderInfo_t &info, float flDetailDist, const DistanceFadeInfo_t &fadeInfo ) { // Don't bother if we turned off detail props if ( !GetClientMode()->ShouldDrawDetailObjects() || ( r_DrawDetailProps.GetInt() == 0 ) ) return; // First, build the list of leaves which are within the appropriate range of detail dist // [box/sphere tests of leaf bounds + sphere] ISpatialQuery* pQuery = engine->GetBSPTreeQuery(); int nLeafCount = info.m_pWorldListInfo->m_LeafCount; const WorldListLeafData_t *pLeafData = info.m_pWorldListInfo->m_pLeafDataList; int *pValidLeafIndex = (int*)stackalloc( nLeafCount * sizeof(int) ); int nValidLeafs = pQuery->ListLeavesInSphereWithFlagSet( pValidLeafIndex, info.m_vecRenderOrigin, flDetailDist, nLeafCount, (const uint16*)pLeafData, sizeof(WorldListLeafData_t), LEAF_FLAGS_CONTAINS_DETAILOBJECTS ); if ( nValidLeafs == 0 ) return; // FIXME: This loop is necessary to deal with marking leaves as needing detail // props. Won't fly in multicore int nFirstDetailObject, nDetailObjectCount; for ( int i = 0; i < nValidLeafs; ++i ) { int nListLeafIndex = pValidLeafIndex[ i ]; int nLeaf = pLeafData[ nListLeafIndex ].leafIndex; // FIXME: Inherently not threadsafe ( use of nBuildWorldListNumber ) g_pClientLeafSystem->DrawDetailObjectsInLeaf( nLeaf, info.m_nDetailBuildFrame, nFirstDetailObject, nDetailObjectCount ); } // No detail objects? No work remaining. if ( m_DetailObjects.Count() == 0 ) return; // Then, for each leaf within range, compute alpha factor float flDistSqr; const Vector &vViewOrigin = info.m_vecRenderOrigin; for ( int i = 0; i < nValidLeafs; ++i ) { int nListLeafIndex = pValidLeafIndex[ i ]; int nLeaf = pLeafData[ nListLeafIndex ].leafIndex; // FIXME: Inherently not threadsafe ( use of nBuildWorldListNumber ) g_pClientLeafSystem->GetDetailObjectsInLeaf( nLeaf, nFirstDetailObject, nDetailObjectCount ); // Compute the translucency. Need to do it now cause we need to // know that when we're rendering (opaque stuff is rendered first) for ( int j = 0; j < nDetailObjectCount; ++j) { // Calculate distance (badly) CDetailModel& model = m_DetailObjects[ nFirstDetailObject + j ]; if ( model.GetType() != DETAIL_PROP_TYPE_MODEL ) continue; uint8 nAlpha = ComputeDistanceFade( &flDistSqr, fadeInfo, vViewOrigin, model.GetRenderOrigin() ); if ( nAlpha == 0 ) continue; // FIXME: Should we return a center + radius so culling can happen? // right now, detail objects are not even frustum culled int d = list.AddToTail(); DetailRenderableInfo_t &info = list[d]; info.m_pRenderable = &model; info.m_InstanceData.m_nAlpha = nAlpha; info.m_nRenderGroup = ( ( nAlpha != 255 ) || model.IsTranslucent() ) ? RENDER_GROUP_TRANSLUCENT : RENDER_GROUP_OPAQUE; info.m_nLeafIndex = nListLeafIndex; // FIXME: Inherently not threadsafe, not to mention not easily SIMDable // move this to happen in DrawModel() // Perform screen alignment if necessary. model.ComputeAngles(); } } }