Example #1
0
void ShimmerEffect::Render(Effect *effect, const SettingsMap &SettingsMap, RenderBuffer &buffer) {
    float oset = buffer.GetEffectTimeIntervalPosition();
    int Duty_Factor = GetValueCurveInt("Shimmer_Duty_Factor", 50, SettingsMap, oset);
    bool Use_All_Colors = SettingsMap.GetBool("CHECKBOX_Shimmer_Use_All_Colors", false);
    float cycles = GetValueCurveDouble("Shimmer_Cycles", 1.0, SettingsMap, oset);
    int colorcnt=buffer.GetColorCount();
    
    double position = buffer.GetEffectTimeIntervalPosition(cycles);
    
    double ColorIdx = round(position * 0.999 * (double)colorcnt);
    
    double pos2 = position * colorcnt;
    while (pos2 > 1.0) {
        pos2 -= 1.0;
    }
    if (pos2 * 100 > Duty_Factor) {
        return;
    }
    
    xlColor color;
    buffer.palette.GetColor(ColorIdx, color);
    for (int y=0; y<buffer.BufferHt; y++) {
        for (int x=0; x<buffer.BufferWi; x++) {
            if(Use_All_Colors) { // Should we randomly assign colors from palette or cycle thru sequentially?
                ColorIdx=rand() % colorcnt; // Select random numbers from 0 up to number of colors the user has checked. 0-5 if 6 boxes checked
                buffer.palette.GetColor(ColorIdx, color); // Now go and get the hsv value for this ColorIdx
            }
            
            buffer.SetPixel(x,y,color); // Turn pixel
        }
    }
}
Example #2
0
void MorphEffect::Render(Effect *effect, const SettingsMap &SettingsMap, RenderBuffer &buffer) {

    int start_x1 = SettingsMap.GetInt("SLIDER_Morph_Start_X1", 0);
    int start_y1 = SettingsMap.GetInt("SLIDER_Morph_Start_Y1", 0);
    int start_x2 = SettingsMap.GetInt("SLIDER_Morph_Start_X2", 0);
    int start_y2 = SettingsMap.GetInt("SLIDER_Morph_Start_Y2", 0);
    int end_x1 = SettingsMap.GetInt("SLIDER_Morph_End_X1", 0);
    int end_y1 = SettingsMap.GetInt("SLIDER_Morph_End_Y1", 0);
    int end_x2 = SettingsMap.GetInt("SLIDER_Morph_End_X2", 0);
    int end_y2 = SettingsMap.GetInt("SLIDER_Morph_End_Y2", 0);
    int start_length = SettingsMap.GetInt("SLIDER_MorphStartLength", 0);
    int end_length = SettingsMap.GetInt("SLIDER_MorphEndLength", 0);
    bool start_linked = SettingsMap.GetBool("CHECKBOX_Morph_Start_Link");
    bool end_linked = SettingsMap.GetBool("CHECKBOX_Morph_End_Link");
    int duration = SettingsMap.GetInt("SLIDER_MorphDuration", 0);
    int acceleration = SettingsMap.GetInt("SLIDER_MorphAccel", 0);
    bool showEntireHeadAtStart = SettingsMap.GetBool("CHECKBOX_ShowHeadAtStart");
    int repeat_count = SettingsMap.GetInt("SLIDER_Morph_Repeat_Count", 0);
    int repeat_skip = SettingsMap.GetInt("SLIDER_Morph_Repeat_Skip", 0);
    int stagger = SettingsMap.GetInt("SLIDER_Morph_Stagger", 0);

    double eff_pos = buffer.GetEffectTimeIntervalPosition();
    double step_size = 0.1;

    int hcols = 0, hcole = 1;
    int tcols = 2, tcole = 3;
    int num_tail_colors = 2;
    switch (buffer.palette.Size()) {
        case 1:  //one color selected, use it for all
            hcols = hcole = tcols = tcole = 0;
            break;
        case 2: //two colors, head/tail
            hcols = hcole = 0;
            tcols = tcole = 1;
            break;
        case 3: //three colors, head /tail start/end
            hcols = hcole = 0;
            tcols = 1;
            tcole = 2;
            break;
        case 4:
            break;
        case 5:
            num_tail_colors = 3;
            break;
        case 6:
            num_tail_colors = 4;
            break;
    }

    int x1a = calcPosition(start_x1, buffer.BufferWi);
    int y1a = calcPosition(start_y1, buffer.BufferHt);
    int x2a = calcPosition(end_x1, buffer.BufferWi);
    int y2a = calcPosition(end_y1, buffer.BufferHt);

    int x1b, x2b, y1b, y2b;

    if( start_linked )
    {
        x1b = x1a;
        y1b = y1a;
    }
    else
    {
        x1b = calcPosition(start_x2, buffer.BufferWi);
        y1b = calcPosition(start_y2, buffer.BufferHt);
    }

    if( end_linked )
    {
        x2b = x2a;
        y2b = y2a;
    }
    else
    {
        x2b = calcPosition(end_x2, buffer.BufferWi);
        y2b = calcPosition(end_y2, buffer.BufferHt);
    }

    xlColor head_color, tail_color, test_color;

    // compute direction
    int delta_xa = x2a - x1a;
    int delta_xb = x2b - x1b;
    int delta_ya = y2a - y1a;
    int delta_yb = y2b - y1b;
    int direction = delta_xa + delta_xb + delta_ya + delta_yb;
    int repeat_x = 0;
    int repeat_y = 0;
    double effect_pct = 1.0;
    double stagger_pct = 0.0;
    if( repeat_count > 0 )
    {
        if( (std::abs((float)delta_xa) + std::abs((float)delta_xb)) < (std::abs((float)delta_ya) + std::abs((float)delta_yb)) )
        {
            repeat_x = repeat_skip;
        }
        else
        {
            repeat_y = repeat_skip;
        }
        double stagger_val = (double)(std::abs((double)stagger))/200.0;
        effect_pct = 1.0 / (1 + stagger_val * repeat_count);
        stagger_pct = effect_pct * stagger_val;
    }

    std::vector<int> v_ax;
    std::vector<int> v_ay;
    std::vector<int> v_bx;
    std::vector<int> v_by;

    StoreLine(x1a, y1a, x2a, y2a, &v_ax, &v_ay);  // store side a
    StoreLine(x1b, y1b, x2b, y2b, &v_bx, &v_by);  // store side b

    int size_a = v_ax.size();
    int size_b = v_bx.size();

    std::vector<int> *v_lngx;  // pointer to longest vector x
    std::vector<int> *v_lngy;  // pointer to longest vector y
    std::vector<int> *v_shtx;  // pointer to shorter vector x
    std::vector<int> *v_shty;  // pointer to shorter vector y

    if( size_a > size_b )
    {
        v_lngx = &v_ax;
        v_lngy = &v_ay;
        v_shtx = &v_bx;
        v_shty = &v_by;
    }
    else
    {
        v_lngx = &v_bx;
        v_lngy = &v_by;
        v_shtx = &v_ax;
        v_shty = &v_ay;
    }

    double pos_a, pos_b;
    double total_tail_length, alpha_pct;
    double total_length = v_lngx->size();     // total length of longest vector
    double head_duration = duration/100.0;    // time the head is in the frame
    double head_end_of_head_pos = total_length + 1;
    double tail_end_of_head_pos = total_length + 1;
    double head_end_of_tail_pos = -1;
    double tail_end_of_tail_pos = -1;

    for( int repeat = 0; repeat <= repeat_count; repeat++ )
    {
        double eff_pos_adj = buffer.calcAccel(eff_pos, acceleration);
        double eff_start_pct = (stagger >= 0) ? stagger_pct*repeat : stagger_pct*(repeat_count-repeat);
        double eff_end_pct = eff_start_pct + effect_pct;
        eff_pos_adj = (eff_pos_adj - eff_start_pct) / (eff_end_pct - eff_start_pct);
        if( eff_pos_adj < 0.0 )
        {
            head_end_of_head_pos = -1;
            tail_end_of_head_pos = -1;
            head_end_of_tail_pos = -1;
            tail_end_of_tail_pos = -1;
            total_tail_length = 1.0;
            if( showEntireHeadAtStart )
            {
                head_end_of_head_pos = start_length;
            }
        }
        else
        {
            if( head_duration > 0.0 )
            {
                double head_loc_pct = eff_pos_adj / head_duration;
                head_end_of_head_pos = total_length * head_loc_pct;
                double current_total_head_length = end_length * head_loc_pct + start_length * (1.0 - head_loc_pct);  // adjusted head length excluding clipping
                head_end_of_head_pos += current_total_head_length * head_loc_pct * head_duration;
                total_tail_length = total_length * ( 1 / head_duration - 1.0);
                if( showEntireHeadAtStart )
                {
                    head_end_of_head_pos += current_total_head_length * (1.0 - eff_pos_adj);
                }
                tail_end_of_head_pos = head_end_of_head_pos - current_total_head_length;
                head_end_of_tail_pos = tail_end_of_head_pos - step_size;
                tail_end_of_tail_pos = head_end_of_tail_pos - total_tail_length;
                buffer.Get2ColorBlend(hcols, hcole, std::min( head_loc_pct, 1.0), head_color);
            }
            else
            {
                total_tail_length = total_length;
                head_end_of_tail_pos = total_length * 2 * eff_pos_adj;
                tail_end_of_tail_pos = head_end_of_tail_pos - total_tail_length;
            }
        }

        // draw the tail
        for( double i = std::min(head_end_of_tail_pos, total_length-1); i >= tail_end_of_tail_pos && i >= 0.0; i -= step_size )
        {
            double pct = ((total_length == 0) ? 0.0 : i / total_length);
            pos_a = i;
            pos_b = v_shtx->size() * pct;
            double tail_color_pct = (i-tail_end_of_tail_pos) / total_tail_length;
            if( num_tail_colors > 2 )
            {
                double color_index = ((double)num_tail_colors - 1.0) * (1.0 - tail_color_pct);
                tail_color_pct = color_index - (double)((int)color_index);
                tcols = (int)color_index + 2;
                tcole = tcols + 1;
                if( tcole == num_tail_colors+1 )
                {
                    alpha_pct = (1.0 - tail_color_pct);
                }
                else
                {
                    alpha_pct = 1.0;
                }
                buffer.Get2ColorBlend(tcols, tcole, tail_color_pct, tail_color);
            }
            else
            {
                if( tail_color_pct > 0.5 )
                {
                    alpha_pct = 1.0;
                }
                else
                {
                    alpha_pct = tail_color_pct / 0.5;
                }
                buffer.Get2ColorBlend(tcole, tcols, tail_color_pct, tail_color);
            }
            if( buffer.allowAlpha ) {
                tail_color.alpha = 255 * alpha_pct;
            }
            buffer.DrawThickLine( (*v_lngx)[pos_a]+(repeat_x*repeat), (*v_lngy)[pos_a]+(repeat_y*repeat), (*v_shtx)[pos_b]+(repeat_x*repeat), (*v_shty)[pos_b]+(repeat_y*repeat), tail_color, direction >= 0);
        }

        // draw the head
        for( double i = std::max(tail_end_of_head_pos, 0.0); i <= head_end_of_head_pos && i < total_length; i += step_size )
        {
            double pct = ((total_length == 0) ? 0.0 : i / total_length);
            pos_a = i;
            pos_b = v_shtx->size() * pct;
            buffer.DrawThickLine( (*v_lngx)[pos_a]+(repeat_x*repeat), (*v_lngy)[pos_a]+(repeat_y*repeat), (*v_shtx)[pos_b]+(repeat_x*repeat), (*v_shty)[pos_b]+(repeat_y*repeat), head_color, direction >= 0);
        }
    }
}
Example #3
0
void GalaxyEffect::Render(Effect *effect, const SettingsMap &SettingsMap, RenderBuffer &buffer) {
    int center_x = SettingsMap.GetInt("SLIDER_Galaxy_CenterX");
    int center_y = SettingsMap.GetInt("SLIDER_Galaxy_CenterY");
    int start_radius = SettingsMap.GetInt("SLIDER_Galaxy_Start_Radius");
    int end_radius = SettingsMap.GetInt("SLIDER_Galaxy_End_Radius");
    int start_angle = SettingsMap.GetInt("SLIDER_Galaxy_Start_Angle");
    int revolutions = SettingsMap.GetInt("SLIDER_Galaxy_Revolutions");
    int start_width = SettingsMap.GetInt("SLIDER_Galaxy_Start_Width");
    int end_width = SettingsMap.GetInt("SLIDER_Galaxy_End_Width");
    int duration = SettingsMap.GetInt("SLIDER_Galaxy_Duration");
    int acceleration = SettingsMap.GetInt("SLIDER_Galaxy_Accel");
    bool reverse_dir = SettingsMap.GetBool("CHECKBOX_Galaxy_Reverse");
    bool blend_edges = SettingsMap.GetBool("CHECKBOX_Galaxy_Blend_Edges");
    bool inward = SettingsMap.GetBool("CHECKBOX_Galaxy_Inward");

    if( revolutions == 0 ) return;
    std::vector< std::vector<double> > temp_colors_pct(buffer.BufferWi, std::vector<double>(buffer.BufferHt));
    std::vector< std::vector<double> > pixel_age(buffer.BufferWi, std::vector<double>(buffer.BufferHt));

    double eff_pos = buffer.GetEffectTimeIntervalPosition();
    int num_colors = buffer.palette.Size();
    xlColor color, c_old, c_new;
    HSVValue hsv1;
    double eff_pos_adj = buffer.calcAccel(eff_pos, acceleration);
    double revs = (double)revolutions;

    double pos_x = buffer.BufferWi * center_x/100.0;
    double pos_y = buffer.BufferHt * center_y/100.0;

    double head_duration = duration/100.0;    // time the head is in the frame
    double tail_length = revs * (1.0 - head_duration);
    double color_length = tail_length / num_colors;
    if(color_length < 1.0) color_length = 1.0;


    double tail_end_of_tail = ((revs + tail_length) * eff_pos_adj) - tail_length;
    double head_end_of_tail = tail_end_of_tail + tail_length;

    double radius1 = start_radius;
    double radius2 = end_radius;
    double width1 = start_width;
    double width2 = end_width;

    double step = buffer.GetStepAngle(radius1, radius2);

    for( int x = 0; x < buffer.BufferWi; x++ )
    {
        for( int y = 0; y < buffer.BufferHt; y++ )
        {
            temp_colors_pct[x][y] = 0.0;
            pixel_age[x][y] = 0.0;
        }
    }
    buffer.ClearTempBuf();

    double last_check = (inward ? std::min(head_end_of_tail,revs) : std::max(0.0, tail_end_of_tail) ) + (double)start_angle;

    for( double i = (inward ? std::min(head_end_of_tail,revs) : std::max(0.0, tail_end_of_tail));
        (inward ? i >= std::max(0.0, tail_end_of_tail) : i <= std::min(head_end_of_tail,revs));
        (inward ? i -= step : i += step) )
    {
        double adj_angle = i + (double)start_angle;
        if( reverse_dir )
        {
            adj_angle *= -1.0;
        }
        double color_val = (head_end_of_tail-i) / color_length;
        int color_int = (int)color_val;
        double color_pct = color_val - (double)color_int;
        int color2 = std::min(color_int+1, num_colors-1);
        if( color_int < color2 )
        {
            buffer.Get2ColorBlend(color_int, color2, std::min( color_pct, 1.0), color);
        }
        else
        {
            buffer.palette.GetColor(color2, color);
        }
        HSVValue hsv(color);
        double full_brightness = hsv.value;
        double pct = i/revs;
        double current_radius = radius2 * pct + radius1 * (1.0 - pct);
        double current_width = width2 * pct + width1 * (1.0 - pct);
        double half_width = current_width / 2.0;
        double inside_radius = current_radius - half_width;
        for( double r = inside_radius; ; r += 0.5 )
        {
            if( r > current_radius ) r = current_radius;
            double x1 = buffer.sin(ToRadians(adj_angle)) * r + (double)pos_x;
            double y1 = buffer.cos(ToRadians(adj_angle)) * r + (double)pos_y;
            double outside_radius = current_radius + (current_radius - r);
            double x2 = buffer.sin(ToRadians(adj_angle)) * outside_radius + (double)pos_x;
            double y2 = buffer.cos(ToRadians(adj_angle)) * outside_radius + (double)pos_y;
            double color_pct2 = (r-inside_radius)/(current_radius-inside_radius);
            if( blend_edges )
            {
                if( hsv.value > 0.0 )
                {
                    if ((int)x1 >= 0 && (int)x1 < buffer.BufferWi && (int)y1 >= 0 && (int)y1 < buffer.BufferHt)
                    {
                        buffer.SetTempPixel((int)x1,(int)y1,color);
                        temp_colors_pct[(int)x1][(int)y1] = color_pct2;
                        pixel_age[(int)x1][(int)y1] = adj_angle;
                    }
                    if ((int)x2 >= 0 && (int)x2 < buffer.BufferWi && (int)y2 >= 0 && (int)y2 < buffer.BufferHt)
                    {
                        buffer.SetTempPixel((int)x2,(int)y2,color);
                        temp_colors_pct[(int)x2][(int)y2] = color_pct2;
                        pixel_age[(int)x2][(int)y2] = adj_angle;
                    }
                }
            }
            else
            {
                hsv.value = full_brightness * color_pct2;
                if( hsv.value > 0.0 )
                {
                    buffer.SetPixel(x1,y1,hsv);
                    buffer.SetPixel(x2,y2,hsv);
                }
            }
            if( r >= current_radius ) break;
        }
        // blend old data down into final buffer
        if( blend_edges && ( (inward ? (last_check-adj_angle) : (adj_angle-last_check)) >= 90.0) )
        {
            for( int x = 0; x < buffer.BufferWi; x++ )
            {
                for( int y = 0; y < buffer.BufferHt; y++ )
                {
                    if( temp_colors_pct[x][y] > 0.0 && ((inward ? (pixel_age[x][y]-adj_angle) : (adj_angle-pixel_age[x][y])) >= 180.0) )
                    {
                        buffer.GetTempPixel(x,y,c_new);
                        buffer.GetPixel(x,y,c_old);
                        buffer.Get2ColorAlphaBlend(c_old, c_new, temp_colors_pct[x][y], color);
                        buffer.SetPixel(x,y,color);
                        temp_colors_pct[x][y] = 0.0;
                        pixel_age[x][y] = 0.0;
                    }
                }
            }
            last_check = adj_angle;
        }
    }

    // blend remaining data down into final buffer
    if( blend_edges )
    {
        for( int x = 0; x < buffer.BufferWi; x++ )
        {
            for( int y = 0; y < buffer.BufferHt; y++ )
            {
                if( temp_colors_pct[x][y] > 0.0 )
                {
                    buffer.GetTempPixel(x,y,c_new);
                    buffer.GetPixel(x,y,c_old);
                    buffer.Get2ColorAlphaBlend(c_old, c_new, temp_colors_pct[x][y], color);
                    buffer.SetPixel(x,y,color);
                }
            }
        }
    }

}
Example #4
0
void GarlandsEffect::Render(Effect *effect, const SettingsMap &SettingsMap, RenderBuffer &buffer) {
    int GarlandType = SettingsMap.GetInt("SLIDER_Garlands_Type", 0);
    int Spacing = SettingsMap.GetInt("SLIDER_Garlands_Spacing", 0);
    float cycles = SettingsMap.GetDouble("TEXTCTRL_Garlands_Cycles", 1.0);

    if (Spacing < 1) {
        Spacing = 1;
    }
    int x,y,yadj,ylimit,ring;
    double ratio;
    xlColor color;
    int dir = GetDirection(SettingsMap.Get("CHOICE_Garlands_Direction", "Up"));
    double position = buffer.GetEffectTimeIntervalPosition(cycles);
    if (dir > 3) {
        dir -= 4;
        if (position > 0.5) {
            position = (1.0 - position) * 2.0;
        } else {
            position *= 2.0;
        }
    }
    int buffMax = buffer.BufferHt;
    int garlandWid = buffer.BufferWi;
    if (dir > 1) {
        buffMax = buffer.BufferWi;
        garlandWid = buffer.BufferHt;
    }
    double PixelSpacing=Spacing*buffMax/100.0;
    if (PixelSpacing < 2.0) PixelSpacing=2.0;


    double total = buffMax * PixelSpacing - buffMax + 1;
    double positionOffset = total * position;

    for (ring = 0; ring < buffMax; ring++)
    {
        ratio=double(buffMax-ring-1)/double(buffMax);
        buffer.GetMultiColorBlend(ratio, false, color);

        y = 1.0 + ring*PixelSpacing - positionOffset;


        ylimit=ring;
        for (x=0; x<garlandWid; x++)
        {
            yadj=y;
            switch (GarlandType)
            {
            case 1:
                switch (x%5)
                {
                case 2:
                    yadj-=2;
                    break;
                case 1:
                case 3:
                    yadj-=1;
                    break;
                }
                break;
            case 2:
                switch (x%5)
                {
                case 2:
                    yadj-=4;
                    break;
                case 1:
                case 3:
                    yadj-=2;
                    break;
                }
                break;
            case 3:
                switch (x%6)
                {
                case 3:
                    yadj-=6;
                    break;
                case 2:
                case 4:
                    yadj-=4;
                    break;
                case 1:
                case 5:
                    yadj-=2;
                    break;
                }
                break;
            case 4:
                switch (x%5)
                {
                case 1:
                case 3:
                    yadj-=2;
                    break;
                }
                break;
            }
            if (yadj < ylimit) yadj=ylimit;
            if (yadj < buffMax) {
                if (dir == 1 || dir == 2) {
                    yadj = buffMax - yadj - 1;
                }
                if (dir > 1) {
                    buffer.SetPixel(yadj,x,color);
                } else {
                    buffer.SetPixel(x,yadj,color);
                }
            }
        }
    }
}
Example #5
0
void StateEffect::RenderState(RenderBuffer &buffer,
                             SequenceElements *elements, const std::string &faceDefinition,
                             const std::string& Phoneme, const std::string &trackName, const std::string& mode, const std::string& colourmode)
{
    if (buffer.needToInit) {
        buffer.needToInit = false;
        elements->AddRenderDependency(trackName, buffer.cur_model);
    
        if (buffer.isTransformed)
        {
            log4cpp::Category &logger_base = log4cpp::Category::getInstance(std::string("log_base"));
            logger_base.warn("State effect starting at %dms until %dms on model %s has a transformed buffer. This may not work as expected.", buffer.curEffStartPer * buffer.frameTimeInMs, buffer.curEffEndPer * buffer.frameTimeInMs, (const char *)buffer.cur_model.c_str());
        }
    }

    Element *track = elements->GetElement(trackName);
    std::recursive_mutex tmpLock;
    std::recursive_mutex *lock = &tmpLock;
    if (track != nullptr) {
        lock = &track->GetChangeLock();
    }
    std::unique_lock<std::recursive_mutex> locker(*lock);

    if (buffer.cur_model == "") {
        return;
    }

    Model* model_info = buffer.frame->AllModels[buffer.cur_model];
    if (model_info == nullptr) {
        return;
    }

    std::string definition = faceDefinition;
    bool found = true;
    std::map<std::string, std::map<std::string, std::string> >::iterator it = model_info->stateInfo.find(definition);
    if (it == model_info->stateInfo.end()) {
        //not found
        found = false;
    }
    if (!found) {
        if ("Coro" == definition && model_info->stateInfo.find("SingleNode") != model_info->stateInfo.end()) {
            definition = "SingleNode";
            found = true;
        } else if ("SingleNode" == definition && model_info->stateInfo.find("Coro") != model_info->stateInfo.end()) {
            definition = "Coro";
            found = true;
        }
    }

    if (definition == "")
    {
        return;
    }

    std::string modelType = found ? model_info->stateInfo[definition]["Type"] : definition;
    if (modelType == "") {
        modelType = definition;
    }

    int type = 1;

    if ("SingleNode" == modelType) {
        type = 0;
    } else if ("NodeRange" == modelType) {
        type = 1;
    }

    std::string tstates = Phoneme;
    int intervalnumber = 0;
    //GET label from timing track
    int startms = -1;
    int endms = -1;
    int posms = -1;
    if (tstates == "") {

        // if we dont have a track then exit
        if (track == NULL)
        {
            return;
        }

        EffectLayer *layer = track->GetEffectLayer(0);
        std::unique_lock<std::recursive_mutex> locker(layer->GetLock());
        int time = buffer.curPeriod * buffer.frameTimeInMs + 1;
        posms = buffer.curPeriod * buffer.frameTimeInMs;
        Effect *ef = layer->GetEffectByTime(time);
        if (ef == nullptr) {
            tstates = "";
        }
        else {
            startms = ef->GetStartTimeMS();
            endms = ef->GetEndTimeMS();
            tstates = ef->GetEffectName();
        }

        ef = layer->GetEffectByTime(buffer.curEffStartPer * buffer.frameTimeInMs + 1);
        while (ef != NULL && ef->GetStartTimeMS() <= time)
        {
            intervalnumber++;
            int endtime = ef->GetEndTimeMS();
            ef = layer->GetEffectByTime(endtime + 1);
            if (ef == NULL)
            {
                ef = layer->GetEffectAfterTime(endtime + 1);
            }
        }
    }

    std::vector<std::string> sstates;

    if (mode == "Default" || startms == -1)
    {
        wxString ss = wxString(tstates);
        wxStringTokenizer tkz(ss, wxT(" ,;:"));
        while (tkz.HasMoreTokens())
        {
            wxString token = tkz.GetNextToken();
            sstates.push_back(token.Lower().ToStdString());
        }
    }
    else if (mode == "Countdown")
    {
        // tstates should contain the starting number
        int val = wxAtoi(tstates);

        val = val * 1000;
        int subtracttime = (posms - startms);
        val = val - subtracttime;
        val = val / 1000;

        int v = val;
        bool force = false;
        if ((v / 1000) * 1000 > 0)
        {
            sstates.push_back(wxString::Format("%d", (v / 1000) * 1000).ToStdString());
            force = true;
        }
        v = v - (v / 1000) * 1000;
        if ((v / 100) * 100 > 0)
        {
            sstates.push_back(wxString::Format("%d", (v / 100) * 100).ToStdString());
            force = true;
        }
        else
        {
            if (force)
            {
                sstates.push_back("000");
            }
        }
        v = v - (v / 100) * 100;
        if ((v / 10) * 10 > 0)
        {
            sstates.push_back(wxString::Format("%d", (v / 10) * 10).ToStdString());
        }
        else
        {
            if (force)
            {
                sstates.push_back("00");
            }
        }
        v = v - (v / 10) * 10;
        sstates.push_back(wxString::Format("%d", v).ToStdString());
    }
    else if (mode == "Time Countdown")
    {
        wxDateTime dt;
        dt.ParseFormat(tstates.c_str(), "%H:%M:%S");

        if (!dt.IsValid())
        {
            dt.ParseFormat(tstates.c_str(), "%M:%S");
        }

        if (dt.IsValid())
        {
            dt.Subtract(wxTimeSpan(0, 0, 0, (buffer.curPeriod - buffer.curEffStartPer) * buffer.frameTimeInMs));
            int m = dt.GetMinute();
            if ((m / 10) * 1000 > 0)
            {
                sstates.push_back(wxString::Format("%d", (m / 10) * 1000).ToStdString());
            }
            else
            {
                sstates.push_back("0000");
            }
            m = m - (m / 10) * 10;
            if (m * 100 > 0)
            {
                sstates.push_back(wxString::Format("%d", m * 100).ToStdString());
            }
            else
            {
                sstates.push_back("000");
            }
            int s = dt.GetSecond();
            if ((s / 10) * 10 > 0)
            {
                sstates.push_back(wxString::Format("%d", (s / 10) * 10).ToStdString());
            }
            else
            {
                sstates.push_back("00");
            }
            s = s - (s / 10) * 10;
            sstates.push_back(wxString::Format("%d", s).ToStdString());
        }
        sstates.push_back("colon");
    }
    else if (mode == "Number") // used for FM frequencies
    {
        double f = wxAtof(tstates);
        sstates.push_back("dot");
        double f2 = f - int(f);
        f2 = (int)(f2 * 10 + 0.5);
        sstates.push_back(wxString::Format("%d", (int)f2).ToStdString());

        int v = f;
        bool force = false;
        if ((v / 100) * 1000 > 0)
        {
            sstates.push_back(wxString::Format("%d", (v / 100) * 1000).ToStdString());
            force = true;
        }
        v = v - (v / 100) * 100;
        if ((v / 10) * 100 > 0)
        {
            sstates.push_back(wxString::Format("%d", (v / 10) * 100).ToStdString());
        }
        else
        {
            if (force)
            {
                sstates.push_back("000");
            }
        }
        v = v - (v / 10) * 10;
        if (v * 10 > 0)
        {
            sstates.push_back(wxString::Format("%d", v * 10).ToStdString());
        }
        else
        {
            sstates.push_back("00");
        }
    }
    else if (mode == "Iterate")
    {
        float progressthroughtimeinterval = ((float)posms - (float)startms) / ((float)endms - (float)startms);

        std::vector<std::string> tmpstates;
        wxString ss = wxString(tstates);
        wxStringTokenizer tkz(ss, wxT(" ,;:"));
        while (tkz.HasMoreTokens())
        {
            wxString token = tkz.GetNextToken();
            tmpstates.push_back(token.Lower().ToStdString());
        }

        int which = tmpstates.size() * progressthroughtimeinterval;

        if (which < sstates.size())
        {
            sstates.push_back(tmpstates[which]);
        }
    }

    bool customColor = found ? model_info->stateInfo[definition]["CustomColors"] == "1" : false;

    // process each token
    for (size_t i = 0; i < sstates.size(); i++)
    {
        // get the channels
        std::string statename = FindState(model_info->stateInfo[definition], sstates[i]);
        std::string channels = model_info->stateInfo[definition][statename];

        if (statename != "" && channels != "")
        {
            xlColor color;
            if (colourmode == "Graduate")
            {
                buffer.GetMultiColorBlend(buffer.GetEffectTimeIntervalPosition(), false, color);
            }
            else if (colourmode == "Cycle")
            {
                buffer.palette.GetColor((intervalnumber - 1) % buffer.GetColorCount(), color);
            }
            else
            {
                // allocate
                int statenum = wxAtoi(statename.substr(1));
                buffer.palette.GetColor((statenum - 1) % buffer.GetColorCount(), color);
            }
            if (customColor) {
                std::string cname = model_info->stateInfo[definition][statename + "-Color"];
                if (cname == "") {
                    color = xlWHITE;
                }
                else {
                    color = xlColor(cname);
                }
            }

            wxStringTokenizer wtkz(channels, ",");
            while (wtkz.HasMoreTokens())
            {
                wxString valstr = wtkz.GetNextToken();

                if (type == 0) {
                    for (size_t n = 0; n < model_info->GetNodeCount(); n++) {
                        wxString nn = model_info->GetNodeName(n, true);
                        if (nn == valstr) {
                            for (auto a = buffer.Nodes[n]->Coords.begin() ; a != buffer.Nodes[n]->Coords.end(); a++) {
                                buffer.SetPixel(a->bufX, a->bufY, color);
                            }
                        }
                    }
                }
                else if (type == 1) {
                    int start, end;
                    if (valstr.Contains("-")) {
                        int idx = valstr.Index('-');
                        start = wxAtoi(valstr.Left(idx));
                        end = wxAtoi(valstr.Right(valstr.size() - idx - 1));
                    }
                    else {
                        start = end = wxAtoi(valstr);
                    }
                    if (start > end) {
                        start = end;
                    }
                    start--;
                    end--;
                    for (int n = start; n <= end; n++) {
                        if (n < buffer.Nodes.size()) {
                            for (auto a = buffer.Nodes[n]->Coords.begin() ; a != buffer.Nodes[n]->Coords.end(); a++) {
                                buffer.SetPixel(a->bufX, a->bufY, color);
                            }
                        }
                    }
                }
            }
        }
    }
}
Example #6
0
void ColorWashEffect::Render(Effect *effect, const SettingsMap &SettingsMap, RenderBuffer &buffer) {
    bool HorizFade = SettingsMap.GetBool(CHECKBOX_ColorWash_HFade);
    bool VertFade = SettingsMap.GetBool(CHECKBOX_ColorWash_VFade);
    float cycles = SettingsMap.GetDouble(TEXTCTRL_ColorWash_Cycles, 1.0);
    bool EntireModel = SettingsMap.GetInt(CHECKBOX_ColorWash_EntireModel, 1);
    int x1 = SettingsMap.GetInt(SLIDER_ColorWash_X1, -50);
    int y1 = SettingsMap.GetInt(SLIDER_ColorWash_Y1, -50);
    int x2 = SettingsMap.GetInt(SLIDER_ColorWash_X2, 50);
    int y2 = SettingsMap.GetInt(SLIDER_ColorWash_Y2, 50);
    bool shimmer = SettingsMap.GetInt(CHECKBOX_ColorWash_Shimmer, 0);
    bool circularPalette = SettingsMap.GetInt(CHECKBOX_ColorWash_CircularPalette, 0);
    
    
    int x,y;
    xlColor color, orig;
    
    double position = buffer.GetEffectTimeIntervalPosition(cycles);
    buffer.GetMultiColorBlend(position, circularPalette, color);
    
    int startX = 0;
    int startY = 0;
    int endX = buffer.BufferWi - 1;
    int endY = buffer.BufferHt - 1;
    
    if (!EntireModel) {
        startX = std::min(x1, x2);
        endX = std::max(x1, x2);
        startY = std::min(y1, y2);
        endY = std::max(y1, y2);
        startX = std::round(double(buffer.BufferWi - 0.5) * (double)startX / 100.0);
        endX = std::round(double(buffer.BufferWi - 0.5) * (double)endX / 100.0);
        startY = std::round(double(buffer.BufferHt - 0.5) * (double)startY / 100.0);
        endY = std::round(double(buffer.BufferHt - 0.5) * (double)endY / 100.0);
        startX = std::max(startX, 0);
        endX = std::min(endX, buffer.BufferWi - 1);
        startY = std::max(startY, 0);
        endY = std::min(endY, buffer.BufferHt - 1);
    }
    int tot = buffer.curPeriod - buffer.curEffStartPer;
    if (!shimmer || (tot % 2) == 0) {
        double HalfHt=double(endY - startY)/2.0;
        double HalfWi=double(endX - startX)/2.0;
        
        orig = color;
        HSVValue hsvOrig = color.asHSV();
        xlColor color2 = color;
        for (x=startX; x <= endX; x++)
        {
            HSVValue hsv = hsvOrig;
            if (HorizFade) {
                if (buffer.allowAlpha) {
                    color.alpha = (double)orig.alpha*(1.0-std::abs(HalfWi-x-startX)/HalfWi);
                } else {
                    hsv.value*=1.0-std::abs(HalfWi-x-startX)/HalfWi;
                    color = hsv;
                }
            }
            color2.alpha = color.alpha;
            for (y=startY; y<=endY; y++) {
                if (VertFade) {
                    if (buffer.allowAlpha) {
                        color.alpha = (double)color2.alpha*(1.0-std::abs(HalfHt-(y-startY))/HalfHt);
                    } else {
                        HSVValue hsv2 = hsv;
                        hsv2.value*=1.0-std::abs(HalfHt-(y-startY))/HalfHt;
                        color = hsv2;
                    }
                }
                buffer.SetPixel(x, y, color);
            }
        }
    } else {
        orig = xlBLACK;
    }
    wxMutexLocker lock(effect->GetBackgroundDisplayList().lock);
    if (VertFade || HorizFade) {
        effect->GetBackgroundDisplayList().resize((buffer.curEffEndPer - buffer.curEffStartPer + 1) * 4 * 2);
        int total = buffer.curEffEndPer - buffer.curEffStartPer + 1;
        double x1 = double(buffer.curPeriod - buffer.curEffStartPer) / double(total);
        double x2 = (buffer.curPeriod - buffer.curEffStartPer + 1.0) / double(total);
        int idx = (buffer.curPeriod - buffer.curEffStartPer) * 8;
        buffer.SetDisplayListVRect(effect, idx, x1, 0.0, x2, 0.5,
                                   xlBLACK, orig);
        buffer.SetDisplayListVRect(effect, idx + 4, x1, 0.5, x2, 1.0,
                                   orig, xlBLACK);
    } else {
        effect->GetBackgroundDisplayList().resize((buffer.curEffEndPer - buffer.curEffStartPer + 1) * 4);
        int midX = (startX + endX) / 2;
        int midY = (startY + endY) / 2;
        buffer.CopyPixelsToDisplayListX(effect, midY, midX, midX);
    }

}
Example #7
0
void ShockwaveEffect::Render(Effect *effect, const SettingsMap &SettingsMap, RenderBuffer &buffer) {
    int center_x = SettingsMap.GetInt("SLIDER_Shockwave_CenterX", 0);
    int center_y = SettingsMap.GetInt("SLIDER_Shockwave_CenterY", 0);
    int start_radius = SettingsMap.GetInt("SLIDER_Shockwave_Start_Radius", 0);
    int end_radius = SettingsMap.GetInt("SLIDER_Shockwave_End_Radius", 0);
    int start_width = SettingsMap.GetInt("SLIDER_Shockwave_Start_Width", 0);
    int end_width = SettingsMap.GetInt("SLIDER_Shockwave_End_Width", 0);
    int acceleration = SettingsMap.GetInt("SLIDER_Shockwave_Accel", 0);
    bool blend_edges = SettingsMap.GetBool("CHECKBOX_Shockwave_Blend_Edges");

    std::vector< std::vector<double> > temp_colors_pct(buffer.BufferWi, std::vector<double>(buffer.BufferHt));
    double eff_pos = buffer.GetEffectTimeIntervalPosition();
    int num_colors = buffer.palette.Size();
    if( num_colors == 0 )
        num_colors = 1;
    xlColor color, c_old, c_new;
    double eff_pos_adj = buffer.calcAccel(eff_pos, acceleration);

    double blend_pct = 1.0 / (num_colors-1);
    double color_pct1 = eff_pos_adj / blend_pct;
    int color_index = (int)color_pct1;
    blend_pct = color_pct1 - (double)color_index;
    buffer.Get2ColorBlend(color_index, std::min(color_index+1,num_colors-1), std::min( blend_pct, 1.0), color);

    double pos_x = buffer.BufferWi * center_x/100.0;
    double pos_y = buffer.BufferHt * center_y/100.0;

    double radius1 = start_radius;
    double radius2 = end_radius;
    double radius_center = radius1 + (radius2 - radius1) * eff_pos_adj;
    double half_width = (start_width + (end_width - start_width) * eff_pos_adj) / 2.0;
    radius1 = radius_center - half_width;
    radius2 = radius_center + half_width;

    double step = buffer.GetStepAngle(radius1, radius2);

    for( int x = 0; x < buffer.BufferWi; x++ )
    {
        for( int y = 0; y < buffer.BufferHt; y++ )
        {
            temp_colors_pct[x][y] = 0.0;
        }
    }
    buffer.ClearTempBuf();

    for( double current_angle = 0.0; current_angle <= 360.0; current_angle += step )
    {
        for( double r = std::max(0.0, radius1); r <= radius2; r += 0.5 )
        {
            double x1 = buffer.sin(ToRadians(current_angle)) * r + (double)pos_x;
            double y1 = buffer.cos(ToRadians(current_angle)) * r + (double)pos_y;

            if( blend_edges )
            {
                double color_pct = 1.0 - std::abs(r-radius_center)/half_width;
                if( color_pct > 0.0 )
                {
                    if (x1 >= 0 && x1 < buffer.BufferWi && y1 >= 0 && y1 < buffer.BufferHt)
                    {
                        if (buffer.allowAlpha) {
                            color.alpha = 255.0 * color_pct;
                            buffer.SetPixel((int)x1,(int)y1,color);
                        } else {
                            temp_colors_pct[(int)x1][(int)y1] = color_pct;
                            buffer.SetTempPixel((int)x1,(int)y1,color);
                        }
                    }
                }
            }
            else
            {
                buffer.SetPixel((int)x1,(int)y1,color);
            }
        }
    }

    // blend element data into final buffer
    if( blend_edges && !buffer.allowAlpha )
    {
        for( int x = 0; x < buffer.BufferWi; x++ )
        {
            for( int y = 0; y < buffer.BufferHt; y++ )
            {
                if( temp_colors_pct[x][y] > 0.0 )
                {
                    buffer.GetTempPixel(x,y,c_new);
                    buffer.GetPixel(x,y,c_old);
                    buffer.Get2ColorAlphaBlend(c_old, c_new, temp_colors_pct[x][y], color);
                    buffer.SetPixel(x,y,color);
                    temp_colors_pct[x][y] = 0.0;
                }
            }
        }
    }
}
Example #8
0
void PinwheelEffect::Render(Effect *effect, const SettingsMap &SettingsMap, RenderBuffer &buffer) {

    float oset = buffer.GetEffectTimeIntervalPosition();

    int pinwheel_arms = SettingsMap.GetInt("SLIDER_Pinwheel_Arms", 3);
    int pinwheel_twist = GetValueCurveInt("Pinwheel_Twist", 0, SettingsMap, oset);
    int pinwheel_thickness = GetValueCurveInt("Pinwheel_Thickness", 0, SettingsMap, oset);
    bool pinwheel_rotation = SettingsMap.GetBool("CHECKBOX_Pinwheel_Rotation");
    const std::string &pinwheel_3d = SettingsMap["CHOICE_Pinwheel_3D"];
    int xc_adj = GetValueCurveInt("PinwheelXC", 0, SettingsMap, oset);
    int yc_adj = GetValueCurveInt("PinwheelYC", 0, SettingsMap, oset);
    int pinwheel_armsize = GetValueCurveInt("Pinwheel_ArmSize", 100, SettingsMap, oset);
    int pspeed = GetValueCurveInt("Pinwheel_Speed", 10, SettingsMap, oset);
    const std::string &pinwheel_style = SettingsMap["CHOICE_Pinwheel_Style"];

    int xc;
    float tmax;
    HSVValue hsv, hsv1;
    double pos = (buffer.curPeriod - buffer.curEffStartPer) * pspeed * buffer.frameTimeInMs / 50;
    int degrees_per_arm = 1;
    if (pinwheel_arms > 0) degrees_per_arm = 360 / pinwheel_arms;
    float armsize = (pinwheel_armsize / 100.0);

    if (pinwheel_style == "New Render Method")
    {
        std::vector<size_t> colorarray;
        colorarray.resize(pinwheel_arms);
        for (int i = 0; i < pinwheel_arms; i++) { colorarray[i] = i%buffer.GetColorCount(); }

        xc = (int)(ceil(std::hypot(buffer.BufferWi, buffer.BufferHt) / 2));
        xc_adj = xc_adj*buffer.BufferWi / 200;
        yc_adj = yc_adj*buffer.BufferHt / 200;


        int max_radius = xc * armsize;
        if (pinwheel_thickness == 0) pinwheel_thickness = 1;
        tmax = (pinwheel_thickness / 100.0)*degrees_per_arm;

        // Force single visible line in case width is narrower than visible
        float pi_180 = M_PI/180;
        for(int a=0; a<pinwheel_arms; a++)
        {
            int ColorIdx = a%pinwheel_arms;
            xlColor color;
            buffer.palette.GetHSV(colorarray[ColorIdx], hsv);
            color = xlColor(hsv);

            int angle = (a*degrees_per_arm);
            if (pinwheel_rotation == 1) // do we have CW rotation
            {
                angle = (270 - angle) + pos;
            } else {
                angle = angle - 90 - pos;
            }
            int x,y, degrees_twist;
            for (float r=0; r<=max_radius; r+=0.5)
            {
                degrees_twist = (r/max_radius) * pinwheel_twist;
                int t2 = (int)angle%degrees_per_arm;
                double round = (float)t2 / (float)tmax;
                x = floor((int)(r * buffer.cos((angle + degrees_twist) * pi_180)) + xc_adj + buffer.BufferWi / 2);
                y = floor((int)(r * buffer.sin((angle + degrees_twist) * pi_180)) + yc_adj + buffer.BufferHt / 2);
                if (buffer.palette.IsSpatial(colorarray[ColorIdx]))
                {
                    buffer.palette.GetSpatialColor(colorarray[ColorIdx], xc_adj + buffer.BufferWi / 2, yc_adj + buffer.BufferHt / 2, x, y, round, max_radius, color);
                }
                buffer.SetPixel(x,y,color);
            }
        }

        // Draw actual pinwheel arms
        for (int x = 0; x < buffer.BufferWi; x++)
        {
            int x1 = x - xc_adj - (buffer.BufferWi / 2);
            for (int y = 0; y < buffer.BufferHt; y++)
            {
                int y1 = y - yc_adj - (buffer.BufferHt / 2);
                double r = std::hypot(x1, y1);
                if (r <= max_radius) {
                    double degrees_twist = (r / max_radius)*pinwheel_twist;
                    double theta = (std::atan2(x1, y1) * 180 / 3.14159) + degrees_twist;
                    if (pinwheel_rotation == 1) // do we have CW rotation
                    {
                        theta = pos + theta + (tmax/2);
                    } else {
                        theta = pos - theta + (tmax/2);
                    }
                    theta = theta + 540.0;
                    int t2 = (int)theta%degrees_per_arm;
                    if (t2 <= tmax) {
                        double round = (float)t2 / (float)tmax;
                        t2 = std::abs(t2 - (tmax/2)) * 2;
                        xlColor color;
                        int ColorIdx2 = ((int)((theta/degrees_per_arm)))%pinwheel_arms;
                        if (buffer.palette.IsSpatial(colorarray[ColorIdx2]))
                        {
                            buffer.palette.GetSpatialColor(colorarray[ColorIdx2], xc_adj + buffer.BufferWi / 2, yc_adj + buffer.BufferHt / 2, x, y, round, max_radius, color);
                            hsv = color.asHSV();
                        } else {
                            buffer.palette.GetHSV(colorarray[ColorIdx2], hsv);
                        }
                        hsv1=hsv;
                        color = xlColor(hsv1);
                        if(pinwheel_3d=="3D")
                        {
                            if (buffer.allowAlpha) {
                                color.alpha = 255.0 * ((tmax - t2) / tmax);
                            }
                            else {
                                hsv1.value = hsv.value * ((tmax - t2) / tmax);
                                color = hsv1;
                            }
                        }
                        else if (pinwheel_3d == "3D Inverted")
                        {
                            if (buffer.allowAlpha) {
                                color.alpha = 255.0 * ((t2) / tmax);
                            }
                            else {
                                hsv1.value = hsv.value * ((t2) / tmax);
                                color = hsv1;
                            }
                        }
                        buffer.SetPixel(x, y, color);
                    }
                }
            }
        }
    } else { // Old Render Method
        int a,xc,ColorIdx,base_degrees;
        float t,tmax;
        float radius;
        HSVValue hsv,hsv0,hsv1;
        size_t colorcnt=buffer.GetColorCount();

        xc= (int)(std::max(buffer.BufferWi, buffer.BufferHt)/2);
        radius = xc/100.0;

        for(a=1; a<=pinwheel_arms; a++)
        {
            ColorIdx=a%colorcnt;
            buffer.palette.GetHSV(ColorIdx, hsv); // Now go and get the hsv value for this ColorIdx
            if(pinwheel_rotation==1) // do we have CW rotation
            {
                base_degrees = (a-1)*degrees_per_arm + pos; // yes
            }
            else
            {
                base_degrees = (a-1)*degrees_per_arm - pos; // no, we are CCW
            }
            Draw_arm(buffer, base_degrees, xc*armsize, pinwheel_twist,hsv,xc_adj,yc_adj);
            if(pinwheel_thickness>0)
            {
                tmax= (pinwheel_thickness/100.0)*degrees_per_arm/2.0;
                hsv1=hsv;
                xlColor color(hsv1);
                for (t=1; t<=tmax; t++)
                {
                    if(pinwheel_3d=="3D")
                    {
                        if (buffer.allowAlpha) {
                            color.alpha = 255.0 * ((tmax-t)/tmax);
                        } else {
                            hsv1.value = hsv.value * ((tmax-t)/tmax);
                            color = hsv1;
                        }
                    }
                    else if(pinwheel_3d=="3D Inverted")
                    {
                        if (buffer.allowAlpha) {
                            color.alpha = 255.0 * ((t)/tmax);
                        } else {
                            hsv1.value = hsv.value * ((t)/tmax);
                            color = hsv1;
                        }
                    }
                    Draw_arm(buffer, base_degrees-t, xc*armsize, pinwheel_twist,color,xc_adj,yc_adj);
                    Draw_arm(buffer, base_degrees+t, xc*armsize, pinwheel_twist,color,xc_adj,yc_adj);
                }
            }
        }
    }
}
Example #9
0
void OnEffect::Render(Effect *eff, const SettingsMap &SettingsMap, RenderBuffer &buffer) {
    int start = SettingsMap.GetInt(TEXTCTRL_Eff_On_Start, 100);
    int end = SettingsMap.GetInt(TEXTCTRL_Eff_On_End, 100);
    bool shimmer = SettingsMap.GetInt(CHECKBOX_On_Shimmer, 0) > 0;
    float cycles = SettingsMap.GetDouble(TEXTCTRL_On_Cycles, 1.0);
    int x,y;
    int cidx = 0;
    if (shimmer) {
        int tot = buffer.curPeriod - buffer.curEffStartPer;
        if (tot % 2) {
            if (buffer.palette.Size() <= 1) {
                return;
            }
            cidx = 1;
        }
    }

    bool spatialcolour = buffer.palette.IsSpatial(cidx);

    double adjust = buffer.GetEffectTimeIntervalPosition(cycles);

    xlColor color;
    if (start == 100 && end == 100) {
        buffer.palette.GetColor(cidx, color);
    } else {
        HSVValue hsv;
        buffer.palette.GetHSV(cidx,hsv);
        double d = adjust;
        d = start + (end - start) * d;
        d = d / 100.0;
        hsv.value = hsv.value * d;
        color = hsv;
    }
    
    int transparency = GetValueCurveInt("On_Transparency", 0, SettingsMap, adjust);
    if (transparency) {
        transparency *= 255;
        transparency /= 100;
        color.alpha = 255 - transparency;
    }

    ///////////////////////// DMX Support ////////////////////////
    // if the model is a DMX model this will write the color into
    // the proper red, green, and blue channels.
    //////////////////////////////////////////////////////////////
    if (buffer.cur_model != "") {
        Model* model_info = buffer.frame->AllModels[buffer.cur_model];
        if (model_info != nullptr) {
            if( model_info->GetDisplayAs() == "DMX" ) {
                xlColor c;
                DmxModel* dmx = (DmxModel*)model_info;
                int red_channel = dmx->GetRedChannel();
                int grn_channel = dmx->GetGreenChannel();
                int blu_channel = dmx->GetBlueChannel();
                if( red_channel != 0 ) {
                    c.red = color.red;
                    c.green = color.red;
                    c.blue = color.red;
                    buffer.SetPixel(red_channel-1, 0, c);
                }
                if( grn_channel != 0 ) {
                    c.red = color.green;
                    c.green = color.green;
                    c.blue = color.green;
                    buffer.SetPixel(grn_channel-1, 0, c);
                }
                if( blu_channel != 0 ) {
                    c.red = color.blue;
                    c.green = color.blue;
                    c.blue = color.blue;
                    buffer.SetPixel(blu_channel-1, 0, c);
                }
                return;
            }
        }
    }
    //////////////////////////////////////////////////////////////
    ///////////////////// End DMX Support ////////////////////////
    //////////////////////////////////////////////////////////////

    //Every Node set to selected color
    for (x=0; x<buffer.BufferWi; x++)
    {
        for (y=0; y<buffer.BufferHt; y++)
        {
            if (spatialcolour)
            {
                buffer.palette.GetSpatialColor(cidx, (float)x / (float)buffer.BufferWi, (float)y / (float)buffer.BufferHt, color);
                if (start == 100 && end == 100) {
                }
                else {
                    HSVValue hsv = color.asHSV();
                    double d = adjust;
                    d = start + (end - start) * d;
                    d = d / 100.0;
                    hsv.value = hsv.value * d;
                    color = hsv;
                }
                if (transparency) {
                    color.alpha = 255 - transparency;
                }
            }

            buffer.SetPixel(x,y,color);
        }
    }

    if (shimmer || cycles != 1.0) {
        std::lock_guard<std::recursive_mutex> lock(eff->GetBackgroundDisplayList().lock);
        eff->GetBackgroundDisplayList().resize((buffer.curEffEndPer - buffer.curEffStartPer + 1) * 6);
        buffer.CopyPixelsToDisplayListX(eff, 0, 0, 0);
    } else if (buffer.needToInit) {
        std::lock_guard<std::recursive_mutex> lock(eff->GetBackgroundDisplayList().lock);
        eff->GetBackgroundDisplayList().resize(6);
        if (start == 100 && end == 100) {
            buffer.palette.GetColor(0, color);
            buffer.SetDisplayListHRect(eff, 0, 0.0, 0.0, 1.0, 1.0, color, color);
        } else {
            HSVValue hsv;
            buffer.palette.GetHSV(cidx,hsv);
            hsv.value = hsv.value * start / 100.0;
            color = hsv;

            buffer.palette.GetHSV(cidx,hsv);
            hsv.value = hsv.value * end / 100.0;
            buffer.SetDisplayListHRect(eff, 0, 0.0, 0.0, 1.0, 1.0, color, xlColor(hsv));
        }
        buffer.needToInit = false;
    }
}