// ---------------------------------------------------------------------------- // void SceneMovementAnimatorTask::genFanMovement( MovementAnimation& movement, ParticipantArray& participants ) { UINT pan_start = movement.m_pan_start; UINT pan_end = movement.m_pan_end; UINT tilt_start = movement.m_tilt_start; UINT tilt_end = movement.m_tilt_end; if ( pan_start > pan_end ) swap<UINT>( pan_start, pan_end ); UINT pan_increment = pan_end-pan_start; UINT pan_home = pan_start + (pan_increment/2); if ( participants.size() > 2 ) pan_increment = (UINT)(((float)pan_increment)/(participants.size()-1)+0.5); for ( size_t particpant_index=0; particpant_index < participants.size(); ) { AngleList pan; AngleList tilt; ChannelValueArray dimmer; ChannelValueArray speed; // Go home tilt.push_back( tilt_start ); pan.push_back( pan_home ); dimmer.push_back( movement.m_backout_home_return ? 0 : 255 ); speed.push_back( 0 ); // Go to destination for ( UINT i=0; i < movement.m_dest_wait_periods; i++ ) { tilt.push_back( tilt_end ); pan.push_back( pan_start+(pan_increment*particpant_index) ); dimmer.push_back( 255 ); speed.push_back( movement.m_speed ); } // Go back home for ( UINT i=0; i < movement.m_home_wait_periods-1; i++ ) { tilt.push_back( tilt_start ); pan.push_back( pan_home ); dimmer.push_back( movement.m_backout_home_return ? 0 : 255 ); speed.push_back( 0 ); } if ( !movement.m_backout_home_return ) // TEMP fix for dimmer channel contention dimmer.clear(); // Populate the channel arrays for the next group of fixtures populateChannelAnimations( participants, particpant_index, tilt, pan, dimmer, speed, 1, movement.m_run_once ); } }
// ---------------------------------------------------------------------------- // NOTE: Dimmer channel should contain 0 for full off and 255 for full on and // no other values // void SceneMovementAnimatorTask::populateChannelAnimations( ParticipantArray& participants, size_t& particpant_index, AngleList& tilt, AngleList& pan, ChannelValueArray& dimmer, ChannelValueArray& speed, size_t group_size, bool run_once ) { size_t end = particpant_index + group_size; // If run once, add last entry to shut down the lights if ( run_once && dimmer.size() > 0 ) { dimmer.push_back( 0 ); } ChannelAnimationStyle style( run_once ? CAM_LIST_ONCE : CAM_LIST ); for ( ; particpant_index < end && particpant_index < participants.size(); particpant_index++ ) { channel_address pan_channel = participants[ particpant_index ].m_head.m_pan; channel_address tilt_channel = participants[ particpant_index ].m_head.m_tilt; channel_address dimmer_channel = participants[ particpant_index ].m_head.m_dimmer; channel_address speed_channel = participants[ particpant_index ].m_head.m_speed; UID actor_uid = participants[ particpant_index ].m_actor_uid; Fixture* pf = getActorRepresentative( actor_uid ); if ( !pf ) continue; if ( tilt_channel != INVALID_CHANNEL && tilt.size() ) { Channel* cp = pf->getChannel( tilt_channel ); add( actor_uid, tilt_channel, style, anglesToValues( cp, tilt, cp->getMinAngle(), cp->getMaxAngle() ) ); } if ( pan_channel != INVALID_CHANNEL && pan.size() ) { Channel* cp = pf->getChannel( pan_channel ); add( actor_uid, pan_channel, style, anglesToValues( cp, pan, cp->getMinAngle(), cp->getMaxAngle() ) ); } if ( speed_channel != INVALID_CHANNEL && speed.size() ) { add( actor_uid, speed_channel, style, speed ); } if ( dimmer_channel != INVALID_CHANNEL && dimmer.size() ) { Channel* ch = pf->getChannel( dimmer_channel ); STUDIO_ASSERT( ch, "Can't access dimmer channel %d on fixture %s", dimmer_channel, pf->getFullName() ); BYTE low = ch->getDimmerLowestIntensity(); BYTE high = ch->getDimmerHighestIntensity(); // Replace all 255 dimmer high value with the fixture's dimmer value iff the actors value != 0 SceneActor* actor = getActor( actor_uid ); if ( actor && actor->getFinalChannelValue( pf->getUID(), dimmer_channel ) != 0 ) high = actor->getFinalChannelValue( pf->getUID(), dimmer_channel ); if ( low != 0 || high != 255 ) { // Special case odd dimmer values for ( size_t i=0; i < dimmer.size(); i++ ) dimmer[i] = ( dimmer[i] == 255 ) ? high : low; } add( actor_uid, dimmer_channel, style, dimmer ); } } }
// ---------------------------------------------------------------------------- // void SceneMovementAnimatorTask::genCoordinatesMovement( MovementAnimation& movement, ParticipantArray& participants ) { for ( size_t particpant_index=0; particpant_index < participants.size(); ) { AngleList pan; AngleList tilt; ChannelValueArray dimmer; ChannelValueArray speed; // Generate random locations within the tilt and pan bounds for ( UINT index=0; index < movement.m_coordinates.size(); index++ ) { UINT tilt_angle = movement.m_coordinates[index].m_tilt; UINT pan_angle = movement.m_coordinates[index].m_pan; if ( index > 0 && movement.m_backout_home_return ) { pan.push_back( pan_angle ); tilt.push_back( tilt_angle ); speed.push_back( 0 ); dimmer.push_back( 0 ); } for ( UINT wait=0; wait < movement.m_dest_wait_periods; wait++ ) { pan.push_back( pan_angle ); tilt.push_back( tilt_angle ); speed.push_back( movement.m_speed ); dimmer.push_back( 255 ); } } // Populate the channel arrays for the next group of fixtures populateChannelAnimations( participants, particpant_index, tilt, pan, dimmer, speed, movement.m_group_size, movement.m_run_once ); } }
// ---------------------------------------------------------------------------- // void SceneMovementAnimatorTask::genRotateMovement( MovementAnimation& movement, ParticipantArray& participants ) { bool forward = true; // Channel value population direction for alternate for ( size_t particpant_index=0; particpant_index < participants.size(); ) { AngleList pan; AngleList tilt; ChannelValueArray dimmer; ChannelValueArray speed; UINT pan_start = movement.m_pan_start; UINT pan_end = movement.m_pan_end; UINT tilt_start = movement.m_tilt_start; UINT tilt_end = movement.m_tilt_end; if ( !forward ) { swap<UINT>( pan_start, pan_end ); swap<UINT>( tilt_start, tilt_end ); } // Go home tilt.push_back( tilt_start ); pan.push_back( pan_start ); dimmer.push_back( movement.m_backout_home_return ? 0 : 255 ); speed.push_back( 0 ); // Go to destination for ( UINT i=0; i < movement.m_dest_wait_periods; i++ ) { tilt.push_back( tilt_end ); pan.push_back( pan_end ); dimmer.push_back( 255 ); speed.push_back( movement.m_speed ); } // Go back home (this wraps so account for the go home already added) for ( UINT i=0; i < movement.m_home_wait_periods-1; i++ ) { tilt.push_back( tilt_start ); pan.push_back( pan_start ); dimmer.push_back( movement.m_backout_home_return ? 0 : 255 ); speed.push_back( 0 ); } if ( !movement.m_backout_home_return ) // TEMP fix for dimmer channel contention dimmer.clear(); // Populate the channel arrays for the next group of fixtures populateChannelAnimations( participants, particpant_index, tilt, pan, dimmer, speed, movement.m_group_size, movement.m_run_once ); if ( movement.m_alternate_groups ) forward = !forward; } }
// ---------------------------------------------------------------------------- // void ScenePixelAnimator::initAnimation( AnimationTask* task, DWORD time_ms, BYTE* dmx_packet ) { m_animation_task = task; m_channel_animations.clear(); typedef std::vector<Participant> ParticipantArray; ParticipantArray participants; // Determine which channels will be participating for ( UID actor_uid : populateActors() ) { Fixture* pf = m_animation_task->getActorRepresentative( actor_uid ); if ( pf->getNumPixels() > 0 ) { participants.push_back( Participant( actor_uid, pf->getPixels() ) ); } } if ( participants.size() > 0 ) { PixelEngine engine; if ( m_combine_fixtures ) { for ( Participant& p : participants ) engine.loadPixels( p.m_actor_uid, p.m_pixels ); generateEffect( engine ); } else { for ( Participant& p : participants ) { engine.clear(); engine.loadPixels( p.m_actor_uid, p.m_pixels ); generateEffect( engine ); } } } SceneChannelAnimator::initAnimation( task, time_ms, dmx_packet ); }
// ---------------------------------------------------------------------------- // void SceneMovementAnimatorTask::genMoonflowerMovement( MovementAnimation& movement, ParticipantArray& participants ) { STUDIO_ASSERT( movement.m_height > 0, "Height must be a positive integer > 0" ); if ( participants.size() == 0 ) return; double fixture_angle_increment = 360 / participants.size(); double start_angle = 0; for ( size_t particpant_index=0; particpant_index < participants.size(); ) { AngleList pan; AngleList tilt; ChannelValueArray dimmer; ChannelValueArray speed; UINT pan_start; UINT tilt_start; compute_pan_tilt( particpant_index, movement.m_height, movement.m_fixture_spacing, movement.m_home_x, movement.m_home_y, pan_start, tilt_start ); double angle = start_angle; for ( size_t i=0; i < movement.m_positions; i++ ) { // Go home tilt.push_back( tilt_start ); pan.push_back( pan_start ); double target_x = movement.m_home_x + movement.m_radius * cos( angle * 180 / M_PI ); double target_y = movement.m_home_y + movement.m_radius * sin( angle * 180 / M_PI ); //printf( "fixture %d: %f,%f to x,y=%f,%f angle=%f\n", particpant_index, home_x, home_y, target_x, target_y, angle ); UINT pan_target; UINT tilt_target; compute_pan_tilt( particpant_index, movement.m_height, movement.m_fixture_spacing, target_x, target_y, pan_target, tilt_target ); //printf( "%d: pan_start=%d tilt_start=%d pan_end=%d tilt_end=%d\n", particpant_index, pan_start, tilt_start, pan_target, tilt_target); compute_fastest_path( pan_start, tilt_start, pan_target, tilt_target ); //printf( "%d: pan_start=%d tilt_start=%d pan_end=%d tilt_end=%d\n", particpant_index, pan_start, tilt_start, pan_target, tilt_target); // Go to destination for ( UINT i=0; i < movement.m_dest_wait_periods; i++ ) { tilt.push_back( tilt_target ); pan.push_back( pan_target ); } // Go back home for ( UINT i=0; i < movement.m_home_wait_periods-1; i++ ) { tilt.push_back( tilt_start ); pan.push_back( pan_start ); } angle += movement.m_pan_increment; if ( angle > 360 ) angle -= 360; } populateChannelAnimations( participants, particpant_index, tilt, pan, dimmer, speed, 1, movement.m_run_once ); start_angle += fixture_angle_increment; } }
// ---------------------------------------------------------------------------- // void SceneMovementAnimatorTask::genSineMovement( MovementAnimation& movement, ParticipantArray& participants ) { std::vector<double> sinewave; for ( double angle=0.0; angle < 360.0; angle += movement.m_positions ) { double radians = angle * M_PI / 180.0; sinewave.push_back( sin(radians * 2) ); } UINT start_angle = 0; UINT pan_increment = (UINT)(360.0 / sinewave.size() + .5); if ( pan_increment < 1 ) return; for ( size_t particpant_index=0; particpant_index < participants.size(); ) { AngleList pan; AngleList tilt; ChannelValueArray dimmer; ChannelValueArray speed; UINT previous_pan = -1; UINT previous_tilt = -1; UINT range = abs( (long)(movement.m_tilt_end - movement.m_tilt_start) ) / 2; UINT tilt_base = std::min<UINT>( movement.m_tilt_end, movement.m_tilt_start ) + range; for ( UINT pan_angle=start_angle, sine_index=0; sine_index < sinewave.size(); pan_angle += pan_increment, sine_index++ ) { UINT tilt_angle = (UINT)((range * sinewave[sine_index]) + tilt_base); if ( previous_pan != pan_angle || previous_tilt != tilt_angle ) { for ( UINT wait=0; wait < movement.m_dest_wait_periods; wait++ ) { pan.push_back( pan_angle ); tilt.push_back( tilt_angle ); speed.push_back( movement.m_speed ); dimmer.push_back( 255 ); } previous_pan = pan_angle; previous_tilt = tilt_angle; } } // Wave back to home if ( pan.size() > 1 ) { size_t size = pan.size()-2; for ( size_t index=size; index > 0; index-- ) { pan.push_back( pan[index] ); // size-2 through 1 tilt.push_back( tilt[size-index+1] ); // 1 through size-1 speed.push_back( movement.m_speed ); dimmer.push_back( 255 ); } } start_angle += movement.m_pan_increment; if ( !movement.m_backout_home_return ) // TEMP fix for dimmer channel contention dimmer.clear(); // Populate the channel arrays for the next group of fixtures populateChannelAnimations( participants, particpant_index, tilt, pan, dimmer, speed, movement.m_group_size, movement.m_run_once ); } }
void SceneMovementAnimatorTask::genRandomMovement( MovementAnimation& movement, ParticipantArray& participants ) { STUDIO_ASSERT( movement.m_positions > 0 && movement.m_positions < MAX_RANDOM_POSITIONS, "Random postions should be between 1 and %d", MAX_RANDOM_POSITIONS ); for ( size_t particpant_index=0; particpant_index < participants.size(); ) { Fixture* pf = getActorRepresentative( participants[ particpant_index ].m_actor_uid ); if ( !pf ) continue; UINT tilt_start = movement.m_tilt_start, tilt_end = movement.m_tilt_end; UINT pan_start = movement.m_pan_start, pan_end = movement.m_pan_end; AngleList pan; AngleList tilt; ChannelValueArray dimmer; ChannelValueArray speed; channel_address tilt_channel = participants[ particpant_index ].m_head.m_tilt; if ( tilt_channel != INVALID_CHANNEL ) { Channel* cp = pf->getChannel( tilt_channel ); tilt_start = std::max<UINT>( tilt_start, cp->getMinAngle() ); tilt_end = std::min<UINT>( tilt_end, cp->getMaxAngle() ); } channel_address pan_channel = participants[ particpant_index ].m_head.m_pan; if ( pan_channel != INVALID_CHANNEL ) { Channel* cp = pf->getChannel( pan_channel ); pan_start = std::max<UINT>( pan_start, cp->getMinAngle() ); pan_end = std::min<UINT>( pan_end, cp->getMaxAngle() ); } // Generate random locations within the tilt and pan bounds for ( UINT generate=0; generate < movement.m_positions; generate++ ) { UINT tilt_angle = random_angle( tilt_start, tilt_end ); UINT pan_angle = random_angle( pan_start, pan_end ); UINT wait_periods = movement.m_dest_wait_periods; // No light during movement if ( movement.m_backout_home_return && wait_periods > 1 ) { pan.push_back( pan_angle ); tilt.push_back( tilt_angle ); speed.push_back( 0 ); dimmer.push_back( 0 ); wait_periods--; } for ( UINT wait=0; wait < wait_periods; wait++ ) { pan.push_back( pan_angle ); tilt.push_back( tilt_angle ); speed.push_back( movement.m_speed ); dimmer.push_back( 255 ); } } if ( !movement.m_backout_home_return ) // TEMP fix for dimmer channel contention dimmer.clear(); // Populate the channel arrays for the next group of fixtures populateChannelAnimations( participants, particpant_index, tilt, pan, dimmer, speed, movement.m_group_size, movement.m_run_once ); } }
// ---------------------------------------------------------------------------- // void SceneMovementAnimatorTask::genNodMovement( MovementAnimation& movement, ParticipantArray& participants ) { bool forward = true; // Channel value population direction for alternate for ( size_t particpant_index=0; particpant_index < participants.size(); ) { AngleList pan; AngleList tilt; ChannelValueArray dimmer; ChannelValueArray speed; UINT pan_start = movement.m_pan_start; UINT pan_end = movement.m_pan_end; UINT tilt_start = movement.m_tilt_start; UINT tilt_end = movement.m_tilt_end; if ( !forward ) { swap<UINT>( tilt_start, tilt_end ); } // Go home //tilt.push_back( tilt_start ); //pan.push_back( pan_start ); //dimmer.push_back( movement.m_backout_home_return ? 0 : 255 ); //speed.push_back( 0 ); if ( pan_start > pan_end ) swap<UINT>( pan_start, pan_end ); for ( int pan_angle=pan_start; pan_angle <= (int)pan_end; pan_angle += movement.m_pan_increment ) { // Go to destination for ( UINT i=0; i < movement.m_dest_wait_periods; i++ ) { tilt.push_back( tilt_end ); pan.push_back( pan_angle ); dimmer.push_back( 255 ); speed.push_back( movement.m_speed ); } // Go back home for ( UINT i=0; i < movement.m_home_wait_periods; i++ ) { tilt.push_back( tilt_start ); pan.push_back( pan_angle ); dimmer.push_back( movement.m_backout_home_return ? 0 : 255 ); speed.push_back( movement.m_speed ); } if ( movement.m_pan_increment == 0 ) // If not panning, just need one of the above break; } if ( !movement.m_backout_home_return && movement.m_pan_increment > 0 ) { for ( int pan_angle=pan_end-=movement.m_pan_increment; pan_angle >= (int)pan_start; pan_angle-=movement.m_pan_increment ) { // Go to destination for ( UINT i=0; i < movement.m_dest_wait_periods; i++ ) { tilt.push_back( tilt_end ); pan.push_back( pan_angle ); dimmer.push_back( 255 ); speed.push_back( movement.m_speed ); } // Go back home for ( UINT i=0; i < movement.m_home_wait_periods; i++ ) { tilt.push_back( tilt_start ); pan.push_back( pan_angle ); dimmer.push_back( 255 ); speed.push_back( movement.m_speed ); } } } if ( !movement.m_backout_home_return ) // TEMP fix for dimmer channel contention dimmer.clear(); // Populate the channel arrays for the next group of fixtures populateChannelAnimations( participants, particpant_index, tilt, pan, dimmer, speed, movement.m_group_size, movement.m_run_once ); if ( movement.m_alternate_groups ) forward = !forward; } }