//===== Copyright © 1996-2005, Valve Corporation, All rights reserved. ======// // // Purpose: // // $NoKeywords: $ //===========================================================================// #include "cbase.h" #include "c_sprite.h" #include "model_types.h" #include "iviewrender.h" #include "view.h" #include "enginesprite.h" #include "engine/ivmodelinfo.h" #include "util_shared.h" #include "tier0/vprof.h" #include "materialsystem/imaterial.h" #include "materialsystem/IMaterialVar.h" #include "view_shared.h" #include "viewrender.h" #include "tier1/KeyValues.h" #include "toolframework/itoolframework.h" #include "toolframework_client.h" // memdbgon must be the last include file in a .cpp file!!! #include "tier0/memdbgon.h" ConVar r_drawsprites( "r_drawsprites", "1", FCVAR_CHEAT ); //----------------------------------------------------------------------------- // Purpose: Generic sprite model renderer // Input : *baseentity - // *psprite - // fscale - // frame - // rendermode - // r - // g - // b - // a - // forward - // right - // up - //----------------------------------------------------------------------------- static unsigned int s_nHDRColorScaleCache = 0; void DrawSpriteModel( IClientEntity *baseentity, CEngineSprite *psprite, const Vector &origin, float fscale, float frame, int rendermode, int r, int g, int b, int a, const Vector& forward, const Vector& right, const Vector& up, float flHDRColorScale ) { float scale; IMaterial *material; // don't even bother culling, because it's just a single // polygon without a surface cache if ( fscale > 0 ) scale = fscale; else scale = 1.0f; if ( rendermode == kRenderNormal ) { render->SetBlend( 1.0f ); } material = psprite->GetMaterial( (RenderMode_t)rendermode, frame ); if ( !material ) return; CMatRenderContextPtr pRenderContext( materials ); if ( ShouldDrawInWireFrameMode() || r_drawsprites.GetInt() == 2 ) { IMaterial *pMaterial = materials->FindMaterial( "debug/debugspritewireframe", TEXTURE_GROUP_OTHER ); pRenderContext->Bind( pMaterial, NULL ); } else { pRenderContext->Bind( material, (IClientRenderable*)baseentity ); } unsigned char color[4]; color[0] = r; color[1] = g; color[2] = b; color[3] = a; IMaterialVar *pHDRColorScaleVar = material->FindVarFast( "$HDRCOLORSCALE", &s_nHDRColorScaleCache ); if( pHDRColorScaleVar ) { pHDRColorScaleVar->SetVecValue( flHDRColorScale, flHDRColorScale, flHDRColorScale ); } Vector point; IMesh* pMesh = pRenderContext->GetDynamicMesh(); CMeshBuilder meshBuilder; meshBuilder.Begin( pMesh, MATERIAL_QUADS, 1 ); Vector vec_a; Vector vec_b; Vector vec_c; Vector vec_d; // isolate common terms VectorMA( origin, psprite->GetDown() * scale, up, vec_a ); VectorScale( right, psprite->GetLeft() * scale, vec_b ); VectorMA( origin, psprite->GetUp() * scale, up, vec_c ); VectorScale( right, psprite->GetRight() * scale, vec_d ); float flMinU, flMinV, flMaxU, flMaxV; psprite->GetTexCoordRange( &flMinU, &flMinV, &flMaxU, &flMaxV ); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, flMinU, flMaxV ); VectorAdd( vec_a, vec_b, point ); meshBuilder.Position3fv( point.Base() ); meshBuilder.AdvanceVertex(); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, flMinU, flMinV ); VectorAdd( vec_c, vec_b, point ); meshBuilder.Position3fv( point.Base() ); meshBuilder.AdvanceVertex(); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, flMaxU, flMinV ); VectorAdd( vec_c, vec_d, point ); meshBuilder.Position3fv( point.Base() ); meshBuilder.AdvanceVertex(); meshBuilder.Color4ubv( color ); meshBuilder.TexCoord2f( 0, flMaxU, flMaxV ); VectorAdd( vec_a, vec_d, point ); meshBuilder.Position3fv( point.Base() ); meshBuilder.AdvanceVertex(); meshBuilder.End(); pMesh->Draw(); } //----------------------------------------------------------------------------- // Purpose: Determine glow brightness/scale based on distance to render origin and trace results // Input : entorigin - // rendermode - // renderfx - // alpha - // pscale - Pointer to the value for scale, will be changed based on distance and rendermode. //----------------------------------------------------------------------------- float StandardGlowBlend( const pixelvis_queryparams_t ¶ms, pixelvis_handle_t *queryHandle, int rendermode, int renderfx, int alpha, float *pscale ) { float dist; float brightness; brightness = PixelVisibility_FractionVisible( params, queryHandle ); if ( brightness <= 0.0f ) { return 0.0f; } dist = GlowSightDistance( params.position, false ); if ( dist <= 0.0f ) { return 0.0f; } if ( renderfx == kRenderFxNoDissipation ) { return (float)alpha * (1.0f/255.0f) * brightness; } // UNDONE: Tweak these magic numbers (1200 - distance at full brightness) float fadeOut = (1200.0f*1200.0f) / (dist*dist); fadeOut = clamp( fadeOut, 0.0f, 1.0f ); if (rendermode != kRenderWorldGlow) { // Make the glow fixed size in screen space, taking into consideration the scale setting. if ( *pscale == 0.0f ) { *pscale = 1.0f; } *pscale *= dist * (1.0f/200.0f); } return fadeOut * brightness; } static float SpriteAspect( CEngineSprite *pSprite ) { if ( pSprite ) { float x = fabsf(pSprite->GetRight() - pSprite->GetLeft()); float y = fabsf(pSprite->GetDown() - pSprite->GetUp()); if ( y != 0 && x != 0 ) { return x / y; } } return 1.0f; } float C_SpriteRenderer::GlowBlend( CEngineSprite *psprite, const Vector& entorigin, int rendermode, int renderfx, int alpha, float *pscale ) { pixelvis_queryparams_t params; float aspect = SpriteAspect(psprite); params.Init( entorigin, PIXELVIS_DEFAULT_PROXY_SIZE, aspect ); return StandardGlowBlend( params, &m_queryHandle, rendermode, renderfx, alpha, pscale ); } // since sprites can network down a glow proxy size, handle that here float CSprite::GlowBlend( CEngineSprite *psprite, const Vector& entorigin, int rendermode, int renderfx, int alpha, float *pscale ) { pixelvis_queryparams_t params; float aspect = SpriteAspect(psprite); params.Init( entorigin, m_flGlowProxySize, aspect ); return StandardGlowBlend( params, &m_queryHandle, rendermode, renderfx, alpha, pscale ); } //----------------------------------------------------------------------------- // Purpose: Determine sprite orientation axes // Input : type - // forward - // right - // up - //----------------------------------------------------------------------------- void C_SpriteRenderer::GetSpriteAxes( SPRITETYPE type, const Vector& origin, const QAngle& angles, Vector& forward, Vector& right, Vector& up ) { int i; float dot, angle, sr, cr; Vector tvec; // Automatically roll parallel sprites if requested if ( angles[2] != 0 && type == SPR_VP_PARALLEL ) { type = SPR_VP_PARALLEL_ORIENTED; } switch( type ) { case SPR_FACING_UPRIGHT: { // generate the sprite's axes, with vup straight up in worldspace, and // r_spritedesc.vright perpendicular to modelorg. // This will not work if the view direction is very close to straight up or // down, because the cross product will be between two nearly parallel // vectors and starts to approach an undefined state, so we don't draw if // the two vectors are less than 1 degree apart tvec[0] = -origin[0]; tvec[1] = -origin[1]; tvec[2] = -origin[2]; VectorNormalize (tvec); dot = tvec[2]; // same as DotProduct (tvec, r_spritedesc.vup) because // r_spritedesc.vup is 0, 0, 1 if ((dot > 0.999848f) || (dot < -0.999848f)) // cos(1 degree) = 0.999848 return; up[0] = 0; up[1] = 0; up[2] = 1; right[0] = tvec[1]; // CrossProduct(r_spritedesc.vup, -modelorg, right[1] = -tvec[0]; // r_spritedesc.vright) right[2] = 0; VectorNormalize (right); forward[0] = -right[1]; forward[1] = right[0]; forward[2] = 0; // CrossProduct (r_spritedesc.vright, r_spritedesc.vup, // r_spritedesc.vpn) } break; case SPR_VP_PARALLEL: { // generate the sprite's axes, completely parallel to the viewplane. There // are no problem situations, because the sprite is always in the same // position relative to the viewer for (i=0 ; i<3 ; i++) { up[i] = CurrentViewUp()[i]; right[i] = CurrentViewRight()[i]; forward[i] = CurrentViewForward()[i]; } } break; case SPR_VP_PARALLEL_UPRIGHT: { // generate the sprite's axes, with g_vecVUp straight up in worldspace, and // r_spritedesc.vright parallel to the viewplane. // This will not work if the view direction is very close to straight up or // down, because the cross product will be between two nearly parallel // vectors and starts to approach an undefined state, so we don't draw if // the two vectors are less than 1 degree apart dot = CurrentViewForward()[2]; // same as DotProduct (vpn, r_spritedesc.g_vecVUp) because // r_spritedesc.vup is 0, 0, 1 if ((dot > 0.999848f) || (dot < -0.999848f)) // cos(1 degree) = 0.999848 return; up[0] = 0; up[1] = 0; up[2] = 1; right[0] = CurrentViewForward()[1]; // CrossProduct (r_spritedesc.vup, vpn, right[1] = -CurrentViewForward()[0]; // r_spritedesc.vright) right[2] = 0; VectorNormalize (right); forward[0] = -right[1]; forward[1] = right[0]; forward[2] = 0; // CrossProduct (r_spritedesc.vright, r_spritedesc.vup, // r_spritedesc.vpn) } break; case SPR_ORIENTED: { // generate the sprite's axes, according to the sprite's world orientation AngleVectors( angles, &forward, &right, &up ); } break; case SPR_VP_PARALLEL_ORIENTED: { // generate the sprite's axes, parallel to the viewplane, but rotated in // that plane around the center according to the sprite entity's roll // angle. So vpn stays the same, but vright and vup rotate angle = angles[ROLL] * (M_PI*2.0f/360.0f); SinCos( angle, &sr, &cr ); for (i=0 ; i<3 ; i++) { forward[i] = CurrentViewForward()[i]; right[i] = CurrentViewRight()[i] * cr + CurrentViewUp()[i] * sr; up[i] = CurrentViewRight()[i] * -sr + CurrentViewUp()[i] * cr; } } break; default: Warning( "GetSpriteAxes: Bad sprite type %d\n", type ); break; } } //----------------------------------------------------------------------------- // Purpose: // Output : int //----------------------------------------------------------------------------- int C_SpriteRenderer::DrawSprite( IClientEntity *entity, const model_t *model, const Vector& origin, const QAngle& angles, float frame, IClientEntity *attachedto, int attachmentindex, int rendermode, int renderfx, int alpha, int r, int g, int b, float scale, float flHDRColorScale ) { VPROF_BUDGET( "C_SpriteRenderer::DrawSprite", VPROF_BUDGETGROUP_PARTICLE_RENDERING ); if ( !r_drawsprites.GetBool() || !model || modelinfo->GetModelType( model ) != mod_sprite ) { return 0; } // Get extra data CEngineSprite *psprite = (CEngineSprite *)modelinfo->GetModelExtraData( model ); if ( !psprite ) { return 0; } Vector effect_origin; VectorCopy( origin, effect_origin ); // Use attachment point if ( attachedto ) { C_BaseEntity *ent = attachedto->GetBaseEntity(); if ( ent ) { // don't draw viewmodel effects in reflections if ( CurrentViewID() == VIEW_REFLECTION ) { if ( g_pClientLeafSystem->IsRenderingWithViewModels( ent->RenderHandle() ) ) return 0; } QAngle temp; ent->GetAttachment( attachmentindex, effect_origin, temp ); } } if ( rendermode != kRenderNormal ) { float blend = render->GetBlend(); // kRenderGlow and kRenderWorldGlow have a special blending function if (( rendermode == kRenderGlow ) || ( rendermode == kRenderWorldGlow )) { blend *= GlowBlend( psprite, effect_origin, rendermode, renderfx, alpha, &scale ); // Fade out the sprite depending on distance from the view origin. r *= blend; g *= blend; b *= blend; } render->SetBlend( blend ); if ( blend <= 0.0f ) { return 0; } } // Get orthonormal basis Vector forward, right, up; GetSpriteAxes( (SPRITETYPE)psprite->GetOrientation(), origin, angles, forward, right, up ); // Draw DrawSpriteModel( entity, psprite, effect_origin, scale, frame, rendermode, r, g, b, alpha, forward, right, up, flHDRColorScale ); return 1; } //----------------------------------------------------------------------------- // Purpose: //----------------------------------------------------------------------------- void CSprite::GetToolRecordingState( KeyValues *msg ) { if ( !ToolsEnabled() ) return; VPROF_BUDGET( "CSprite::GetToolRecordingState", VPROF_BUDGETGROUP_TOOLS ); BaseClass::GetToolRecordingState( msg ); // Use attachment point if ( m_hAttachedToEntity ) { C_BaseEntity *ent = m_hAttachedToEntity->GetBaseEntity(); if ( ent ) { BaseEntityRecordingState_t *pState = (BaseEntityRecordingState_t*)msg->GetPtr( "baseentity" ); // override position if we're driven by an attachment QAngle temp; pState->m_vecRenderOrigin = GetAbsOrigin(); ent->GetAttachment( m_nAttachment, pState->m_vecRenderOrigin, temp ); // override viewmodel if we're driven by an attachment bool bViewModel = ToBaseViewModel( ent ) != NULL; msg->SetInt( "viewmodel", bViewModel ); } } float renderscale = GetRenderScale(); if ( m_bWorldSpaceScale ) { CEngineSprite *psprite = ( CEngineSprite * )modelinfo->GetModelExtraData( GetModel() ); float flMinSize = MIN( psprite->GetWidth(), psprite->GetHeight() ); renderscale /= flMinSize; } color24 c = GetRenderColor(); // sprite params static SpriteRecordingState_t state; state.m_flRenderScale = renderscale; state.m_flFrame = m_flFrame; state.m_flProxyRadius = m_flGlowProxySize; state.m_nRenderMode = GetRenderMode(); state.m_nRenderFX = GetRenderFX() ? true : false; state.m_Color.SetColor( c.r, c.g, c.b, GetRenderBrightness() ); msg->SetPtr( "sprite", &state ); }