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com.sun.scenario.effect.impl.sw.java.JSWLinearConvolvePeer Maven / Gradle / Ivy

/*
 * Copyright (c) 2009, 2013, Oracle and/or its affiliates. All rights reserved.
 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
 *
 * This code is free software; you can redistribute it and/or modify it
 * under the terms of the GNU General Public License version 2 only, as
 * published by the Free Software Foundation.  Oracle designates this
 * particular file as subject to the "Classpath" exception as provided
 * by Oracle in the LICENSE file that accompanied this code.
 *
 * This code 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.  See the GNU General Public License
 * version 2 for more details (a copy is included in the LICENSE file that
 * accompanied this code).
 *
 * You should have received a copy of the GNU General Public License version
 * 2 along with this work; if not, write to the Free Software Foundation,
 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
 *
 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
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 * questions.
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/*
 * This file was originally generated by JSLC
 * and then hand edited for performance.
 */

package com.sun.scenario.effect.impl.sw.java;

import java.nio.FloatBuffer;
import com.sun.scenario.effect.FilterContext;
import com.sun.scenario.effect.ImageData;
import com.sun.scenario.effect.Effect;
import com.sun.scenario.effect.impl.HeapImage;
import com.sun.scenario.effect.impl.Renderer;
import com.sun.javafx.geom.Rectangle;
import com.sun.javafx.geom.transform.BaseTransform;
import com.sun.scenario.effect.impl.state.AccessHelper;
import com.sun.scenario.effect.impl.state.LinearConvolveKernel;
import com.sun.scenario.effect.impl.state.LinearConvolveKernel.PassType;
import com.sun.scenario.effect.impl.state.LinearConvolvePeer;

public class JSWLinearConvolvePeer extends JSWEffectPeer implements LinearConvolvePeer {

    public JSWLinearConvolvePeer(FilterContext fctx, Renderer r, String uniqueName) {
        super(fctx, r, uniqueName);
    }

    @Override
    protected final Effect getEffect() {
        return (Effect)super.getEffect();
    }

    protected LinearConvolveKernel getKernel() {
        return (LinearConvolveKernel) AccessHelper.getState(getEffect());
    }

    public int getPow2ScaleX(LinearConvolveKernel kernel) {
        return kernel.getPow2ScaleX();
    }

    public int getPow2ScaleY(LinearConvolveKernel kernel) {
        return kernel.getPow2ScaleY();
    }

    @Override
    public Rectangle getResultBounds(BaseTransform transform,
                                     Rectangle outputClip,
                                     ImageData... inputDatas)
    {
        Rectangle r = inputDatas[0].getTransformedBounds(null);
        r = getKernel().getScaledResultBounds(r, getPass());
        r.intersectWith(outputClip);
        return r;
    }

    private int getCount() {
        return getKernel().getScaledKernelSize(getPass());
    }

    private float[] getOffset() {
        return getKernel().getVector(getInputNativeBounds(0),
                                     getInputTransform(0),
                                     getPass());
    }

    private FloatBuffer getWeights() {
        return getKernel().getWeights(getPass());
    }

    @Override
    public ImageData filter(Effect effect,
                            BaseTransform transform,
                            Rectangle outputClip,
                            ImageData... inputs)
    {
        setEffect(effect);
        Rectangle dstRawBounds = getResultBounds(transform, null, inputs);
        Rectangle dstBounds = new Rectangle(dstRawBounds);
        dstBounds.intersectWith(outputClip);
        setDestBounds(dstBounds);
        int dstw = dstBounds.width;
        int dsth = dstBounds.height;

        // NOTE: for now, all input images must be TYPE_INT_ARGB_PRE
        HeapImage src = (HeapImage)inputs[0].getUntransformedImage();
        int srcw = src.getPhysicalWidth();
        int srch = src.getPhysicalHeight();
        int srcscan = src.getScanlineStride();
        int[] srcPixels = src.getPixelArray();

        Rectangle src0Bounds = inputs[0].getUntransformedBounds();
        BaseTransform src0Transform = inputs[0].getTransform();
        Rectangle src0NativeBounds = new Rectangle(0, 0, srcw, srch);
        // Assert: ((FilterEffect) effect).operatesInUserSpace()...
        setInputBounds(0, src0Bounds);
        setInputTransform(0, src0Transform);
        setInputNativeBounds(0, src0NativeBounds);

        HeapImage dst = (HeapImage)getRenderer().getCompatibleImage(dstw, dsth);
        setDestNativeBounds(dst.getPhysicalWidth(), dst.getPhysicalHeight());
        int dstscan = dst.getScanlineStride();
        int[] dstPixels = dst.getPixelArray();

        int count = getCount();
        FloatBuffer weights_buf = getWeights();

        PassType type = getKernel().getPassType(getPass());
        if (!src0Transform.isIdentity() ||
            !dstBounds.contains(dstRawBounds.x, dstRawBounds.y))
        {
            // RT-27387
            // TODO: Fix the optimized loops to deal with non-zero srcxy0
            // and transforms...
            type = PassType.GENERAL_VECTOR;
        }
        type = PassType.GENERAL_VECTOR;
        if (type == PassType.HORIZONTAL_CENTERED) {
            float[] weights_arr = new float[count * 2];
            weights_buf.get(weights_arr, 0, count);
            weights_buf.rewind();
            weights_buf.get(weights_arr, count, count);
            filterHV(dstPixels, dstw, dsth, 1, dstscan,
                     srcPixels, srcw, srch, 1, srcscan,
                     weights_arr);
        } else if (type == PassType.VERTICAL_CENTERED) {
            float[] weights_arr = new float[count * 2];
            weights_buf.get(weights_arr, 0, count);
            weights_buf.rewind();
            weights_buf.get(weights_arr, count, count);
            filterHV(dstPixels, dsth, dstw, dstscan, 1,
                     srcPixels, srch, srcw, srcscan, 1,
                     weights_arr);
        } else {
            float[] weights_arr = new float[count];
            weights_buf.get(weights_arr, 0, count);

            float[] srcRect = new float[8];
            int nCoords = getTextureCoordinates(0, srcRect,
                                                src0Bounds.x, src0Bounds.y,
                                                src0NativeBounds.width,
                                                src0NativeBounds.height,
                                                dstBounds, src0Transform);
            float srcx0 = srcRect[0] * srcw;
            float srcy0 = srcRect[1] * srch;
            float dxcol, dycol, dxrow, dyrow;
            if (nCoords < 8) {
                dxcol = (srcRect[2] - srcRect[0]) * srcw / dstBounds.width;
                dycol = 0f;
                dxrow = 0f;
                dyrow = (srcRect[3] - srcRect[1]) * srch / dstBounds.height;
            } else {
                dxcol = (srcRect[4] - srcRect[0]) * srcw / dstBounds.width;
                dycol = (srcRect[5] - srcRect[1]) * srch / dstBounds.height;
                dxrow = (srcRect[6] - srcRect[0]) * srcw / dstBounds.width;
                dyrow = (srcRect[7] - srcRect[1]) * srch / dstBounds.height;
            }

            float[] offset_arr = getOffset();
            float deltax = offset_arr[0] * srcw;
            float deltay = offset_arr[1] * srch;
            float offsetx = offset_arr[2] * srcw;
            float offsety = offset_arr[3] * srch;

            filterVector(dstPixels, dstw, dsth, dstscan,
                         srcPixels, srcw, srch, srcscan,
                         weights_arr, count,
                         srcx0, srcy0,
                         offsetx, offsety,
                         deltax, deltay,
                         dxcol, dycol, dxrow, dyrow);
        }

        return new ImageData(getFilterContext(), dst, dstBounds);
    }

    private static final float cmin = 1f;
    private static final float cmax = 254f + 15f/16f;

    protected void filterVector(int dstPixels[], int dstw, int dsth, int dstscan,
                                int srcPixels[], int srcw, int srch, int srcscan,
                                float weights[], int count,
                                float srcx0, float srcy0,
                                float offsetx, float offsety,
                                float deltax, float deltay,
                                float dxcol, float dycol, float dxrow, float dyrow)
    {
        int dstrow = 0;
        float fvals[] = new float[4];
        // srcxy0 point at UL corner, shift them to center of 1st dest pixel:
        srcx0 += (dxrow + dxcol) * 0.5f;
        srcy0 += (dyrow + dycol) * 0.5f;
        for (int dy = 0; dy < dsth; dy++) {
            float srcx = srcx0;
            float srcy = srcy0;
            for (int dx = 0; dx < dstw; dx++) {
                fvals[0] = fvals[1] = fvals[2] = fvals[3] = 0.0f;
                float sampx = srcx + offsetx;
                float sampy = srcy + offsety;
                for (int i = 0; i < count; ++i) {
                    laccumsample(srcPixels, sampx, sampy,
                                 srcw, srch, srcscan,
                                 weights[i], fvals);
                    sampx += deltax;
                    sampy += deltay;
                }
                dstPixels[dstrow + dx] =
                    (((fvals[FVALS_A] < cmin) ? 0 : ((fvals[FVALS_A] > cmax) ? 255 : ((int) fvals[FVALS_A]))) << 24) +
                    (((fvals[FVALS_R] < cmin) ? 0 : ((fvals[FVALS_R] > cmax) ? 255 : ((int) fvals[FVALS_R]))) << 16) +
                    (((fvals[FVALS_G] < cmin) ? 0 : ((fvals[FVALS_G] > cmax) ? 255 : ((int) fvals[FVALS_G]))) <<  8) +
                    (((fvals[FVALS_B] < cmin) ? 0 : ((fvals[FVALS_B] > cmax) ? 255 : ((int) fvals[FVALS_B])))      );
                srcx += dxcol;
                srcy += dycol;
            }
            srcx0 += dxrow;
            srcy0 += dyrow;
            dstrow += dstscan;
        }
    }

    /**
     * In the nomenclature of the argument list for this method, "row" refers
     * to the coordinate which increments once for each new stream of single
     * axis data that we are blurring in a single pass.  And "col" refers to
     * the other coordinate that increments along the row.
     * Rows are horizontal in the first pass and vertical in the second pass.
     * Cols are vice versa.
     */
    protected void filterHV(int dstPixels[], int dstcols, int dstrows, int dcolinc, int drowinc,
                            int srcPixels[], int srccols, int srcrows, int scolinc, int srowinc,
                            float weights[])
    {
        // cvals stores the component values from the surrounding K pixels
        // from x-r to x+r
        int kernelSize = weights.length / 2;
        float cvals[] = new float[kernelSize * 4];
        int dstrow = 0;
        int srcrow = 0;
        for (int r = 0; r < dstrows; r++) {
            int dstoff = dstrow;
            int srcoff = srcrow;
            // Must clear out the array at the start of every line
            // Might be able to rely on the fact that the previous line must
            // have run out of data towards the end of the scan line, though.
            for (int i = 0; i < cvals.length; i++) {
                cvals[i] = 0f;
            }
            int koff = kernelSize;
            for (int c = 0; c < dstcols; c++) {
                // Load the data for this x location into the array.
                int i = (kernelSize - koff) * 4;
                int rgb = (c < srccols) ? srcPixels[srcoff] : 0;
                cvals[i+0] = (rgb >>> 24);
                cvals[i+1] = (rgb >>  16) & 0xff;
                cvals[i+2] = (rgb >>   8) & 0xff;
                cvals[i+3] = (rgb       ) & 0xff;
                // Bump the koff to the next spot to align the coefficients.
                if (--koff <= 0) {
                    koff += kernelSize;
                }
                float suma = 0;
                float sumr = 0;
                float sumg = 0;
                float sumb = 0;
                for (i = 0; i < cvals.length; i += 4) {
                    float factor = weights[koff + (i>>2)];
                    suma += cvals[i+0] * factor;
                    sumr += cvals[i+1] * factor;
                    sumg += cvals[i+2] * factor;
                    sumb += cvals[i+3] * factor;
                }
                dstPixels[dstoff] =
                    (((suma < cmin) ? 0 : ((suma > cmax) ? 255 : ((int) suma))) << 24) +
                    (((sumr < cmin) ? 0 : ((sumr > cmax) ? 255 : ((int) sumr))) << 16) +
                    (((sumg < cmin) ? 0 : ((sumg > cmax) ? 255 : ((int) sumg))) <<  8) +
                    (((sumb < cmin) ? 0 : ((sumb > cmax) ? 255 : ((int) sumb)))      );
                dstoff += dcolinc;
                srcoff += scolinc;
            }
            dstrow += drowinc;
            srcrow += srowinc;
        }
    }
}




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