// Copyright (C) 1999-2000 Id Software, Inc. // // cg_ents.c -- present snapshot entities, happens every single frame /* * Portions Copyright (C) 2000-2001 Tim Angus * * This program is free software; you can redistribute it and/or modify it * under the terms of the OSML - Open Source Modification License v1.0 as * described in the file COPYING which is distributed with this source * code. * * This program is distributed in the hope that it will be useful, * but WITHOUT ANY WARRANTY; without even the implied warranty of * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. */ #include "cg_local.h" /* ====================== CG_DrawBoxFace Draws a bounding box face ====================== */ static void CG_DrawBoxFace( vec3_t a, vec3_t b, vec3_t c, vec3_t d ) { polyVert_t verts[ 4 ]; vec4_t color = { 255.0f, 0.0f, 0.0f, 128.0f }; VectorCopy( d, verts[ 0 ].xyz ); verts[ 0 ].st[ 0 ] = 1; verts[ 0 ].st[ 1 ] = 1; Vector4Copy( color, verts[ 0 ].modulate ); VectorCopy( c, verts[ 1 ].xyz ); verts[ 1 ].st[ 0 ] = 1; verts[ 1 ].st[ 1 ] = 0; Vector4Copy( color, verts[ 1 ].modulate ); VectorCopy( b, verts[ 2 ].xyz ); verts[ 2 ].st[ 0 ] = 0; verts[ 2 ].st[ 1 ] = 0; Vector4Copy( color, verts[ 2 ].modulate ); VectorCopy( a, verts[ 3 ].xyz ); verts[ 3 ].st[ 0 ] = 0; verts[ 3 ].st[ 1 ] = 1; Vector4Copy( color, verts[ 3 ].modulate ); trap_R_AddPolyToScene( cgs.media.outlineShader, 4, verts ); } /* ====================== CG_DrawBoundingBox Draws a bounding box ====================== */ void CG_DrawBoundingBox( vec3_t origin, vec3_t mins, vec3_t maxs ) { vec3_t ppp, mpp, mmp, pmp; vec3_t mmm, pmm, ppm, mpm; ppp[ 0 ] = origin[ 0 ] + maxs[ 0 ]; ppp[ 1 ] = origin[ 1 ] + maxs[ 1 ]; ppp[ 2 ] = origin[ 2 ] + maxs[ 2 ]; mpp[ 0 ] = origin[ 0 ] + mins[ 0 ]; mpp[ 1 ] = origin[ 1 ] + maxs[ 1 ]; mpp[ 2 ] = origin[ 2 ] + maxs[ 2 ]; mmp[ 0 ] = origin[ 0 ] + mins[ 0 ]; mmp[ 1 ] = origin[ 1 ] + mins[ 1 ]; mmp[ 2 ] = origin[ 2 ] + maxs[ 2 ]; pmp[ 0 ] = origin[ 0 ] + maxs[ 0 ]; pmp[ 1 ] = origin[ 1 ] + mins[ 1 ]; pmp[ 2 ] = origin[ 2 ] + maxs[ 2 ]; ppm[ 0 ] = origin[ 0 ] + maxs[ 0 ]; ppm[ 1 ] = origin[ 1 ] + maxs[ 1 ]; ppm[ 2 ] = origin[ 2 ] + mins[ 2 ]; mpm[ 0 ] = origin[ 0 ] + mins[ 0 ]; mpm[ 1 ] = origin[ 1 ] + maxs[ 1 ]; mpm[ 2 ] = origin[ 2 ] + mins[ 2 ]; mmm[ 0 ] = origin[ 0 ] + mins[ 0 ]; mmm[ 1 ] = origin[ 1 ] + mins[ 1 ]; mmm[ 2 ] = origin[ 2 ] + mins[ 2 ]; pmm[ 0 ] = origin[ 0 ] + maxs[ 0 ]; pmm[ 1 ] = origin[ 1 ] + mins[ 1 ]; pmm[ 2 ] = origin[ 2 ] + mins[ 2 ]; //phew! CG_DrawBoxFace( ppp, mpp, mmp, pmp ); CG_DrawBoxFace( ppp, pmp, pmm, ppm ); CG_DrawBoxFace( mpp, ppp, ppm, mpm ); CG_DrawBoxFace( mmp, mpp, mpm, mmm ); CG_DrawBoxFace( pmp, mmp, mmm, pmm ); CG_DrawBoxFace( mmm, mpm, ppm, pmm ); } /* ====================== CG_PositionEntityOnTag Modifies the entities position and axis by the given tag location ====================== */ void CG_PositionEntityOnTag( refEntity_t *entity, const refEntity_t *parent, qhandle_t parentModel, char *tagName ) { int i; orientation_t lerped; // lerp the tag trap_R_LerpTag( &lerped, parentModel, parent->oldframe, parent->frame, 1.0 - parent->backlerp, tagName ); // FIXME: allow origin offsets along tag? VectorCopy( parent->origin, entity->origin ); for( i = 0; i < 3; i++ ) VectorMA( entity->origin, lerped.origin[ i ], parent->axis[ i ], entity->origin ); // had to cast away the const to avoid compiler problems... MatrixMultiply( lerped.axis, ( (refEntity_t *)parent )->axis, entity->axis ); entity->backlerp = parent->backlerp; } /* ====================== CG_PositionRotatedEntityOnTag Modifies the entities position and axis by the given tag location ====================== */ void CG_PositionRotatedEntityOnTag( refEntity_t *entity, const refEntity_t *parent, qhandle_t parentModel, char *tagName ) { int i; orientation_t lerped; vec3_t tempAxis[ 3 ]; //AxisClear( entity->axis ); // lerp the tag trap_R_LerpTag( &lerped, parentModel, parent->oldframe, parent->frame, 1.0 - parent->backlerp, tagName ); // FIXME: allow origin offsets along tag? VectorCopy( parent->origin, entity->origin ); for( i = 0; i < 3; i++ ) VectorMA( entity->origin, lerped.origin[ i ], parent->axis[ i ], entity->origin ); // had to cast away the const to avoid compiler problems... MatrixMultiply( entity->axis, lerped.axis, tempAxis ); MatrixMultiply( tempAxis, ( (refEntity_t *)parent )->axis, entity->axis ); } /* ========================================================================== FUNCTIONS CALLED EACH FRAME ========================================================================== */ /* ====================== CG_SetEntitySoundPosition Also called by event processing code ====================== */ void CG_SetEntitySoundPosition( centity_t *cent ) { if( cent->currentState.solid == SOLID_BMODEL ) { vec3_t origin; float *v; v = cgs.inlineModelMidpoints[ cent->currentState.modelindex ]; VectorAdd( cent->lerpOrigin, v, origin ); trap_S_UpdateEntityPosition( cent->currentState.number, origin ); } else trap_S_UpdateEntityPosition( cent->currentState.number, cent->lerpOrigin ); } /* ================== CG_EntityEffects Add continuous entity effects, like local entity emission and lighting ================== */ static void CG_EntityEffects( centity_t *cent ) { // update sound origins CG_SetEntitySoundPosition( cent ); // add loop sound if( cent->currentState.loopSound ) { if( cent->currentState.eType != ET_SPEAKER ) { trap_S_AddLoopingSound( cent->currentState.number, cent->lerpOrigin, vec3_origin, cgs.gameSounds[ cent->currentState.loopSound ] ); } else { trap_S_AddRealLoopingSound( cent->currentState.number, cent->lerpOrigin, vec3_origin, cgs.gameSounds[ cent->currentState.loopSound ] ); } } // constant light glow if ( cent->currentState.constantLight ) { int cl; int i, r, g, b; cl = cent->currentState.constantLight; r = cl & 255; g = ( cl >> 8 ) & 255; b = ( cl >> 16 ) & 255; i = ( ( cl >> 24 ) & 255 ) * 4; trap_R_AddLightToScene( cent->lerpOrigin, i, r, g, b ); } } /* ================== CG_General ================== */ static void CG_General( centity_t *cent ) { refEntity_t ent; entityState_t *s1; s1 = ¢->currentState; // if set to invisible, skip if( !s1->modelindex ) return; memset( &ent, 0, sizeof( ent ) ); // set frame ent.frame = s1->frame; ent.oldframe = ent.frame; ent.backlerp = 0; VectorCopy( cent->lerpOrigin, ent.origin); VectorCopy( cent->lerpOrigin, ent.oldorigin); ent.hModel = cgs.gameModels[ s1->modelindex ]; // player model if( s1->number == cg.snap->ps.clientNum ) ent.renderfx |= RF_THIRD_PERSON; // only draw from mirrors // convert angles to axis AnglesToAxis( cent->lerpAngles, ent.axis ); // add to refresh list trap_R_AddRefEntityToScene( &ent ); } /* ================== CG_Speaker Speaker entities can automatically play sounds ================== */ static void CG_Speaker( centity_t *cent ) { if( ! cent->currentState.clientNum ) { // FIXME: use something other than clientNum... return; // not auto triggering } if( cg.time < cent->miscTime ) return; trap_S_StartSound( NULL, cent->currentState.number, CHAN_ITEM, cgs.gameSounds[ cent->currentState.eventParm ] ); // ent->s.frame = ent->wait * 10; // ent->s.clientNum = ent->random * 10; cent->miscTime = cg.time + cent->currentState.frame * 100 + cent->currentState.clientNum * 100 * crandom( ); } //============================================================================ /* =============== CG_Missile =============== */ static void CG_Missile( centity_t *cent ) { refEntity_t ent; entityState_t *s1; const weaponInfo_t *weapon; vec3_t up; float fraction; int index; s1 = ¢->currentState; if( s1->weapon > WP_NUM_WEAPONS ) s1->weapon = 0; weapon = &cg_weapons[ s1->weapon ]; // calculate the axis VectorCopy( s1->angles, cent->lerpAngles ); // add trails if( weapon->missileTrailFunc ) weapon->missileTrailFunc( cent, weapon ); // add dynamic light if( weapon->missileDlight ) { trap_R_AddLightToScene( cent->lerpOrigin, weapon->missileDlight, weapon->missileDlightColor[ 0 ], weapon->missileDlightColor[ 1 ], weapon->missileDlightColor[ 2 ] ); } // add missile sound if( weapon->missileSound ) { vec3_t velocity; BG_EvaluateTrajectoryDelta( ¢->currentState.pos, cg.time, velocity ); trap_S_AddLoopingSound( cent->currentState.number, cent->lerpOrigin, velocity, weapon->missileSound ); } // create the render entity memset( &ent, 0, sizeof( ent ) ); VectorCopy( cent->lerpOrigin, ent.origin ); VectorCopy( cent->lerpOrigin, ent.oldorigin ); switch( cent->currentState.weapon ) { case WP_BLASTER: ent.reType = RT_SPRITE; ent.radius = 4; ent.rotation = 0; ent.customShader = cgs.media.blasterShader; trap_R_AddRefEntityToScene( &ent ); return; break; case WP_PULSE_RIFLE: ent.reType = RT_SPRITE; ent.radius = 4; ent.rotation = 0; ent.customShader = cgs.media.plasmaBallShader; trap_R_AddRefEntityToScene( &ent ); return; break; case WP_LUCIFER_CANNON: ent.skinNum = cg.clientFrame & 1; ent.hModel = weapon->missileModel; ent.renderfx = weapon->missileRenderfx | RF_NOSHADOW; // convert direction of travel into axis if ( VectorNormalize2( s1->pos.trDelta, ent.axis[ 0 ] ) == 0 ) ent.axis[ 0 ][ 2 ] = 1; RotateAroundDirection( ent.axis, cg.time / 4 ); fraction = (float)s1->generic1 / (float)LCANNON_TOTAL_CHARGE; VectorScale( ent.axis[ 0 ], fraction, ent.axis[ 0 ] ); VectorScale( ent.axis[ 1 ], fraction, ent.axis[ 1 ] ); VectorScale( ent.axis[ 2 ], fraction, ent.axis[ 2 ] ); ent.nonNormalizedAxes = qtrue; break; case WP_FLAMER: //TA: don't actually display the missile (use the particle engine) return; break; default: // flicker between two skins ent.skinNum = cg.clientFrame & 1; ent.hModel = weapon->missileModel; ent.renderfx = weapon->missileRenderfx | RF_NOSHADOW; // convert direction of travel into axis if ( VectorNormalize2( s1->pos.trDelta, ent.axis[ 0 ] ) == 0 ) ent.axis[ 0 ][ 2 ] = 1; // spin as it moves if( s1->pos.trType != TR_STATIONARY ) RotateAroundDirection( ent.axis, cg.time / 4 ); else RotateAroundDirection( ent.axis, s1->time ); } // add to refresh list, possibly with quad glow CG_AddRefEntityWithPowerups( &ent, s1->powerups, TEAM_FREE ); } /* =============== CG_Mover =============== */ static void CG_Mover( centity_t *cent ) { refEntity_t ent; entityState_t *s1; s1 = ¢->currentState; // create the render entity memset( &ent, 0, sizeof( ent ) ); VectorCopy( cent->lerpOrigin, ent.origin); VectorCopy( cent->lerpOrigin, ent.oldorigin); AnglesToAxis( cent->lerpAngles, ent.axis ); ent.renderfx = RF_NOSHADOW; // flicker between two skins (FIXME?) ent.skinNum = ( cg.time >> 6 ) & 1; // get the model, either as a bmodel or a modelindex if( s1->solid == SOLID_BMODEL ) ent.hModel = cgs.inlineDrawModel[ s1->modelindex ]; else ent.hModel = cgs.gameModels[ s1->modelindex ]; // add to refresh list trap_R_AddRefEntityToScene( &ent ); // add the secondary model if( s1->modelindex2 ) { ent.skinNum = 0; ent.hModel = cgs.gameModels[ s1->modelindex2 ]; trap_R_AddRefEntityToScene( &ent ); } } /* =============== CG_Beam Also called as an event =============== */ void CG_Beam( centity_t *cent ) { refEntity_t ent; entityState_t *s1; s1 = ¢->currentState; // create the render entity memset( &ent, 0, sizeof( ent ) ); VectorCopy( s1->pos.trBase, ent.origin ); VectorCopy( s1->origin2, ent.oldorigin ); AxisClear( ent.axis ); ent.reType = RT_BEAM; ent.renderfx = RF_NOSHADOW; // add to refresh list trap_R_AddRefEntityToScene( &ent ); } /* =============== CG_Portal =============== */ static void CG_Portal( centity_t *cent ) { refEntity_t ent; entityState_t *s1; s1 = ¢->currentState; // create the render entity memset( &ent, 0, sizeof( ent ) ); VectorCopy( cent->lerpOrigin, ent.origin ); VectorCopy( s1->origin2, ent.oldorigin ); ByteToDir( s1->eventParm, ent.axis[ 0 ] ); PerpendicularVector( ent.axis[ 1 ], ent.axis[ 0 ] ); // negating this tends to get the directions like they want // we really should have a camera roll value VectorSubtract( vec3_origin, ent.axis[ 1 ], ent.axis[ 1 ] ); CrossProduct( ent.axis[ 0 ], ent.axis[ 1 ], ent.axis[ 2 ] ); ent.reType = RT_PORTALSURFACE; ent.oldframe = s1->powerups; ent.frame = s1->frame; // rotation speed ent.skinNum = s1->clientNum / 256.0 * 360; // roll offset // add to refresh list trap_R_AddRefEntityToScene( &ent ); } //============================================================================ #define SETBOUNDS(v1,v2,r) ((v1)[0]=(-r/2),(v1)[1]=(-r/2),(v1)[2]=(-r/2),\ (v2)[0]=(r/2),(v2)[1]=(r/2),(v2)[2]=(r/2)) #define RADIUSSTEP 0.5f #define FLARE_OFF 0 #define FLARE_NOFADE 1 #define FLARE_TIMEFADE 2 #define FLARE_REALFADE 3 /* ========================= CG_LightFlare ========================= */ static void CG_LightFlare( centity_t *cent ) { refEntity_t flare; entityState_t *es; vec3_t forward, delta; float len; trace_t tr; float maxAngle; vec3_t mins, maxs, start, end; float srcRadius, srLocal, ratio = 1.0f; es = ¢->currentState; //don't draw light flares if( cg_lightFlare.integer == FLARE_OFF ) return; //flare is "off" if( es->eFlags & EF_NODRAW ) return; CG_Trace( &tr, cg.refdef.vieworg, NULL, NULL, es->angles2, cg.predictedPlayerState.clientNum, MASK_SHOT ); //if there is no los between the view and the flare source //it definately cannot be seen if( tr.fraction < 1.0f || tr.allsolid ) return; memset( &flare, 0, sizeof( flare ) ); flare.reType = RT_SPRITE; flare.customShader = cgs.gameShaders[ es->modelindex ]; flare.shaderRGBA[ 0 ] = 0xFF; flare.shaderRGBA[ 1 ] = 0xFF; flare.shaderRGBA[ 2 ] = 0xFF; flare.shaderRGBA[ 3 ] = 0xFF; //flares always drawn before the rest of the scene flare.renderfx |= RF_DEPTHHACK; //bunch of geometry AngleVectors( es->angles, forward, NULL, NULL ); VectorCopy( cent->lerpOrigin, flare.origin ); VectorSubtract( flare.origin, cg.refdef.vieworg, delta ); len = VectorLength( delta ); VectorNormalize( delta ); //flare is too close to camera to be drawn if( len < es->generic1 ) return; //don't bother for flares behind the view plane if( DotProduct( delta, cg.refdef.viewaxis[ 0 ] ) < 0.0 ) return; //only recalculate radius and ratio every three frames if( !( cg.clientFrame % 2 ) ) { //can only see the flare when in front of it flare.radius = len / es->origin2[ 0 ]; if( es->origin2[ 2 ] == 0 ) srcRadius = srLocal = flare.radius / 2.0f; else srcRadius = srLocal = len / es->origin2[ 2 ]; maxAngle = es->origin2[ 1 ]; if( maxAngle > 0.0f ) { float radiusMod = 1.0f - ( 180.0f - RAD2DEG( acos( DotProduct( delta, forward ) ) ) ) / maxAngle; if( es->eFlags & EF_NODRAW ) flare.radius *= radiusMod; else if( radiusMod < 0.0f ) flare.radius = 0.0f; } if( flare.radius < 0.0f ) flare.radius = 0.0f; VectorMA( flare.origin, -flare.radius, delta, end ); VectorMA( cg.refdef.vieworg, flare.radius, delta, start ); if( cg_lightFlare.integer == FLARE_REALFADE ) { //draw "correct" albeit inefficient flares srLocal = cent->lastFlareSrcRadius; //flare radius is likely to be the same as last frame so start with it do { srLocal += RADIUSSTEP; SETBOUNDS( mins, maxs, srLocal ); CG_Trace( &tr, start, mins, maxs, end, cg.predictedPlayerState.clientNum, MASK_SHOT ); } while( ( tr.fraction == 1.0f && !tr.startsolid ) && ( srLocal < srcRadius ) ); srLocal -= RADIUSSTEP; //shink the flare until there is a los do { SETBOUNDS( mins, maxs, srLocal ); CG_Trace( &tr, start, mins, maxs, end, cg.predictedPlayerState.clientNum, MASK_SHOT ); srLocal -= RADIUSSTEP; } while( ( tr.fraction < 1.0f || tr.startsolid ) && ( srLocal > 0.0f ) ); ratio = srLocal / srcRadius; cent->lastFlareSrcRadius = srLocal; } else if( cg_lightFlare.integer == FLARE_TIMEFADE ) { //draw timed flares SETBOUNDS( mins, maxs, srcRadius ); CG_Trace( &tr, start, mins, maxs, end, cg.predictedPlayerState.clientNum, MASK_SHOT ); if( ( tr.fraction < 1.0f || tr.startsolid ) && cent->flareStatus ) { cent->flareStatus = qfalse; cent->lastFlareTime = cg.time; } else if( ( tr.fraction == 1.0f && !tr.startsolid ) && !cent->flareStatus ) { cent->flareStatus = qtrue; cent->lastFlareTime = cg.time; } //fade flare up if( cent->flareStatus ) { if( cent->lastFlareTime + es->time > cg.time ) ratio = (float)( cg.time - cent->lastFlareTime ) / es->time; } //fade flare down if( !cent->flareStatus ) { if( cent->lastFlareTime + es->time > cg.time ) { ratio = (float)( cg.time - cent->lastFlareTime ) / es->time; ratio = 1.0f - ratio; } else ratio = 0.0f; } } else if( cg_lightFlare.integer == FLARE_NOFADE ) { //draw nofade flares SETBOUNDS( mins, maxs, srcRadius ); CG_Trace( &tr, start, mins, maxs, end, cg.predictedPlayerState.clientNum, MASK_SHOT ); //flare source occluded if( ( tr.fraction < 1.0f || tr.startsolid ) ) ratio = 0.0f; } } else { ratio = cent->lastFlareRatio; flare.radius = cent->lastFlareRadius; } cent->lastFlareRatio = ratio; cent->lastFlareRadius = flare.radius; if( ratio < 1.0f ) { flare.radius *= ratio; flare.shaderRGBA[ 3 ] = (byte)( (float)flare.shaderRGBA[ 3 ] * ratio ); } if( flare.radius <= 0.0f ) return; trap_R_AddRefEntityToScene( &flare ); } /* ========================= CG_AdjustPositionForMover Also called by client movement prediction code ========================= */ void CG_AdjustPositionForMover( const vec3_t in, int moverNum, int fromTime, int toTime, vec3_t out ) { centity_t *cent; vec3_t oldOrigin, origin, deltaOrigin; vec3_t oldAngles, angles, deltaAngles; if( moverNum <= 0 || moverNum >= ENTITYNUM_MAX_NORMAL ) { VectorCopy( in, out ); return; } cent = &cg_entities[ moverNum ]; if( cent->currentState.eType != ET_MOVER ) { VectorCopy( in, out ); return; } BG_EvaluateTrajectory( ¢->currentState.pos, fromTime, oldOrigin ); BG_EvaluateTrajectory( ¢->currentState.apos, fromTime, oldAngles ); BG_EvaluateTrajectory( ¢->currentState.pos, toTime, origin ); BG_EvaluateTrajectory( ¢->currentState.apos, toTime, angles ); VectorSubtract( origin, oldOrigin, deltaOrigin ); VectorSubtract( angles, oldAngles, deltaAngles ); VectorAdd( in, deltaOrigin, out ); // FIXME: origin change when on a rotating object } /* ============================= CG_InterpolateEntityPosition ============================= */ static void CG_InterpolateEntityPosition( centity_t *cent ) { vec3_t current, next; float f; // it would be an internal error to find an entity that interpolates without // a snapshot ahead of the current one if( cg.nextSnap == NULL ) CG_Error( "CG_InterpoateEntityPosition: cg.nextSnap == NULL" ); f = cg.frameInterpolation; // this will linearize a sine or parabolic curve, but it is important // to not extrapolate player positions if more recent data is available BG_EvaluateTrajectory( ¢->currentState.pos, cg.snap->serverTime, current ); BG_EvaluateTrajectory( ¢->nextState.pos, cg.nextSnap->serverTime, next ); cent->lerpOrigin[ 0 ] = current[ 0 ] + f * ( next[ 0 ] - current[ 0 ] ); cent->lerpOrigin[ 1 ] = current[ 1 ] + f * ( next[ 1 ] - current[ 1 ] ); cent->lerpOrigin[ 2 ] = current[ 2 ] + f * ( next[ 2 ] - current[ 2 ] ); BG_EvaluateTrajectory( ¢->currentState.apos, cg.snap->serverTime, current ); BG_EvaluateTrajectory( ¢->nextState.apos, cg.nextSnap->serverTime, next ); cent->lerpAngles[ 0 ] = LerpAngle( current[ 0 ], next[ 0 ], f ); cent->lerpAngles[ 1 ] = LerpAngle( current[ 1 ], next[ 1 ], f ); cent->lerpAngles[ 2 ] = LerpAngle( current[ 2 ], next[ 2 ], f ); } /* =============== CG_CalcEntityLerpPositions =============== */ static void CG_CalcEntityLerpPositions( centity_t *cent ) { // if this player does not want to see extrapolated players if( !cg_smoothClients.integer ) { // make sure the clients use TR_INTERPOLATE if( cent->currentState.number < MAX_CLIENTS ) { cent->currentState.pos.trType = TR_INTERPOLATE; cent->nextState.pos.trType = TR_INTERPOLATE; } } if( cent->interpolate && cent->currentState.pos.trType == TR_INTERPOLATE ) { CG_InterpolateEntityPosition( cent ); return; } // first see if we can interpolate between two snaps for // linear extrapolated clients if( cent->interpolate && cent->currentState.pos.trType == TR_LINEAR_STOP && cent->currentState.number < MAX_CLIENTS ) { CG_InterpolateEntityPosition( cent ); return; } // just use the current frame and evaluate as best we can BG_EvaluateTrajectory( ¢->currentState.pos, cg.time, cent->lerpOrigin ); BG_EvaluateTrajectory( ¢->currentState.apos, cg.time, cent->lerpAngles ); // adjust for riding a mover if it wasn't rolled into the predicted // player state if( cent != &cg.predictedPlayerEntity ) { CG_AdjustPositionForMover( cent->lerpOrigin, cent->currentState.groundEntityNum, cg.snap->serverTime, cg.time, cent->lerpOrigin ); } } /* =============== CG_AddCEntity =============== */ static void CG_AddCEntity( centity_t *cent ) { // event-only entities will have been dealt with already if( cent->currentState.eType >= ET_EVENTS ) return; // calculate the current origin CG_CalcEntityLerpPositions( cent ); // add automatic effects CG_EntityEffects( cent ); switch( cent->currentState.eType ) { default: CG_Error( "Bad entity type: %i\n", cent->currentState.eType ); break; case ET_INVISIBLE: case ET_PUSH_TRIGGER: case ET_TELEPORT_TRIGGER: break; case ET_GENERAL: CG_General( cent ); break; case ET_CORPSE: CG_Corpse( cent ); break; case ET_PLAYER: CG_Player( cent ); break; case ET_BUILDABLE: CG_Buildable( cent ); break; case ET_MISSILE: CG_Missile( cent ); break; case ET_MOVER: CG_Mover( cent ); break; case ET_BEAM: CG_Beam( cent ); break; case ET_PORTAL: CG_Portal( cent ); break; case ET_SPEAKER: CG_Speaker( cent ); break; case ET_SPRITER: CG_Spriter( cent ); break; case ET_ANIMMAPOBJ: CG_animMapObj( cent ); break; case ET_LIGHTFLARE: CG_LightFlare( cent ); break; } } /* =============== CG_AddPacketEntities =============== */ void CG_AddPacketEntities( void ) { int num; centity_t *cent; playerState_t *ps; // set cg.frameInterpolation if( cg.nextSnap ) { int delta; delta = ( cg.nextSnap->serverTime - cg.snap->serverTime ); if( delta == 0 ) cg.frameInterpolation = 0; else cg.frameInterpolation = (float)( cg.time - cg.snap->serverTime ) / delta; } else { cg.frameInterpolation = 0; // actually, it should never be used, because // no entities should be marked as interpolating } // the auto-rotating items will all have the same axis cg.autoAngles[ 0 ] = 0; cg.autoAngles[ 1 ] = ( cg.time & 2047 ) * 360 / 2048.0; cg.autoAngles[ 2 ] = 0; cg.autoAnglesFast[ 0 ] = 0; cg.autoAnglesFast[ 1 ] = ( cg.time & 1023 ) * 360 / 1024.0f; cg.autoAnglesFast[ 2 ] = 0; AnglesToAxis( cg.autoAngles, cg.autoAxis ); AnglesToAxis( cg.autoAnglesFast, cg.autoAxisFast ); // generate and add the entity from the playerstate ps = &cg.predictedPlayerState; BG_PlayerStateToEntityState( ps, &cg.predictedPlayerEntity.currentState, qfalse ); CG_AddCEntity( &cg.predictedPlayerEntity ); // lerp the non-predicted value for lightning gun origins CG_CalcEntityLerpPositions( &cg_entities[ cg.snap->ps.clientNum ] ); //TA: "empty" item position arrays cg.ep.numAlienBuildables = 0; cg.ep.numHumanBuildables = 0; cg.ep.numAlienClients = 0; cg.ep.numHumanClients = 0; for( num = 0 ; num < cg.snap->numEntities ; num++ ) { cent = &cg_entities[ cg.snap->entities[ num ].number ]; if( cent->currentState.eType == ET_BUILDABLE ) { //TA: add to list of item positions (for creep) if( cent->currentState.modelindex2 == BIT_ALIENS ) { VectorCopy( cent->lerpOrigin, cg.ep.alienBuildablePos[ cg.ep.numAlienBuildables ] ); cg.ep.alienBuildableTimes[ cg.ep.numAlienBuildables ] = cent->miscTime; cg.ep.numAlienBuildables++; } else if( cent->currentState.modelindex2 == BIT_HUMANS ) { VectorCopy( cent->lerpOrigin, cg.ep.humanBuildablePos[ cg.ep.numHumanBuildables ] ); cg.ep.numHumanBuildables++; } } else if( cent->currentState.eType == ET_PLAYER ) { int team = cent->currentState.powerups & 0x00FF; if( team == PTE_ALIENS ) { VectorCopy( cent->lerpOrigin, cg.ep.alienClientPos[ cg.ep.numAlienClients ] ); cg.ep.numAlienClients++; } else if( team == PTE_HUMANS ) { VectorCopy( cent->lerpOrigin, cg.ep.humanClientPos[ cg.ep.numHumanClients ] ); cg.ep.numHumanClients++; } } } //Com_Printf( "%d %d\n", cgIP.numAlienClients, cgIP.numHumanClients ); // add each entity sent over by the server for( num = 0; num < cg.snap->numEntities; num++ ) { cent = &cg_entities[ cg.snap->entities[ num ].number ]; CG_AddCEntity( cent ); } }