path: root/src/java/org/apache/fop/render/afp/AFPImageHandlerRenderedImage.java

/*
 * Licensed to the Apache Software Foundation (ASF) under one or more
 * contributor license agreements.  See the NOTICE file distributed with
 * this work for additional information regarding copyright ownership.
 * The ASF licenses this file to You under the Apache License, Version 2.0
 * (the "License"); you may not use this file except in compliance with
 * the License.  You may obtain a copy of the License at
 *
 *      http://www.apache.org/licenses/LICENSE-2.0
 *
 * Unless required by applicable law or agreed to in writing, software
 * distributed under the License is distributed on an "AS IS" BASIS,
 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
 * See the License for the specific language governing permissions and
 * limitations under the License.
 */

/* $Id$ */

package org.apache.fop.render.afp;

import java.awt.Dimension;
import java.awt.Rectangle;
import java.awt.image.ColorModel;
import java.awt.image.DataBuffer;
import java.awt.image.DataBufferByte;
import java.awt.image.MultiPixelPackedSampleModel;
import java.awt.image.Raster;
import java.awt.image.RenderedImage;
import java.awt.image.SampleModel;
import java.io.IOException;
import java.io.OutputStream;

import org.apache.commons.io.output.ByteArrayOutputStream;
import org.apache.commons.logging.Log;
import org.apache.commons.logging.LogFactory;

import org.apache.xmlgraphics.image.loader.Image;
import org.apache.xmlgraphics.image.loader.ImageFlavor;
import org.apache.xmlgraphics.image.loader.ImageInfo;
import org.apache.xmlgraphics.image.loader.ImageSize;
import org.apache.xmlgraphics.image.loader.impl.ImageRendered;
import org.apache.xmlgraphics.ps.ImageEncodingHelper;
import org.apache.xmlgraphics.util.MimeConstants;
import org.apache.xmlgraphics.util.UnitConv;

import org.apache.fop.afp.AFPDataObjectInfo;
import org.apache.fop.afp.AFPImageObjectInfo;
import org.apache.fop.afp.AFPObjectAreaInfo;
import org.apache.fop.afp.AFPPaintingState;
import org.apache.fop.afp.AFPResourceInfo;
import org.apache.fop.afp.AFPResourceManager;
import org.apache.fop.afp.modca.ResourceObject;
import org.apache.fop.render.ImageHandler;
import org.apache.fop.render.RenderingContext;
import org.apache.fop.util.bitmap.BitmapImageUtil;

/**
 * PDFImageHandler implementation which handles RenderedImage instances.
 */
public class AFPImageHandlerRenderedImage extends AFPImageHandler implements ImageHandler {

    /** logging instance */
    private static Log log = LogFactory.getLog(AFPImageHandlerRenderedImage.class);

    private static final ImageFlavor[] FLAVORS = new ImageFlavor[] {
        ImageFlavor.BUFFERED_IMAGE,
        ImageFlavor.RENDERED_IMAGE
    };

    private void setDefaultResourceLevel(AFPImageObjectInfo imageObjectInfo,
            AFPResourceManager resourceManager) {
        AFPResourceInfo resourceInfo = imageObjectInfo.getResourceInfo();
        if (!resourceInfo.levelChanged()) {
            resourceInfo.setLevel(resourceManager.getResourceLevelDefaults()
                    .getDefaultResourceLevel(ResourceObject.TYPE_IMAGE));
        }
    }

    /** {@inheritDoc} */
    @Override
    protected AFPDataObjectInfo createDataObjectInfo() {
        return new AFPImageObjectInfo();
    }

    /** {@inheritDoc} */
    public int getPriority() {
        return 300;
    }

    /** {@inheritDoc} */
    public Class getSupportedImageClass() {
        return ImageRendered.class;
    }

    /** {@inheritDoc} */
    public ImageFlavor[] getSupportedImageFlavors() {
        return FLAVORS;
    }

    /** {@inheritDoc} */
    public void handleImage(RenderingContext context, Image image, Rectangle pos)
            throws IOException {
        AFPRenderingContext afpContext = (AFPRenderingContext)context;

        AFPImageObjectInfo imageObjectInfo = (AFPImageObjectInfo)createDataObjectInfo();
        AFPPaintingState paintingState = afpContext.getPaintingState();

        // set resource information
        setResourceInformation(imageObjectInfo,
                image.getInfo().getOriginalURI(),
                afpContext.getForeignAttributes());
        setDefaultResourceLevel(imageObjectInfo, afpContext.getResourceManager());

        // Positioning
        imageObjectInfo.setObjectAreaInfo(createObjectAreaInfo(paintingState, pos));
        Dimension targetSize = pos.getSize();


        // Image content
        ImageRendered imageRend = (ImageRendered)image;
        RenderedImageEncoder encoder = new RenderedImageEncoder(imageRend, targetSize);
        encoder.prepareEncoding(imageObjectInfo, paintingState);

        boolean included = afpContext.getResourceManager().tryIncludeObject(imageObjectInfo);
        if (!included) {
            long start = System.currentTimeMillis();
            //encode only if the same image has not been encoded, yet
            encoder.encodeImage(imageObjectInfo, paintingState);
            if (log.isDebugEnabled()) {
                long duration = System.currentTimeMillis() - start;
                log.debug("Image encoding took " + duration + "ms.");
            }

            // Create image
            afpContext.getResourceManager().createObject(imageObjectInfo);
        }
    }

    /** {@inheritDoc} */
    public boolean isCompatible(RenderingContext targetContext, Image image) {
        return (image == null || image instanceof ImageRendered)
            && targetContext instanceof AFPRenderingContext;
    }

    private static final class RenderedImageEncoder {

        private ImageRendered imageRendered;
        private Dimension targetSize;

        private boolean useFS10;
        private int maxPixelSize;
        private boolean usePageSegments;
        private boolean resample;
        private Dimension resampledDim;
        private ImageSize intrinsicSize;
        private ImageSize effIntrinsicSize;

        private RenderedImageEncoder(ImageRendered imageRendered, Dimension targetSize) {
            this.imageRendered = imageRendered;
            this.targetSize = targetSize;

        }

        private void prepareEncoding(AFPImageObjectInfo imageObjectInfo,
                AFPPaintingState paintingState) {
            maxPixelSize = paintingState.getBitsPerPixel();
            if (paintingState.isColorImages()) {
                if (paintingState.isCMYKImagesSupported()) {
                    maxPixelSize *= 4; //CMYK is maximum
                } else {
                    maxPixelSize *= 3; //RGB is maximum
                }
            }
            RenderedImage renderedImage = imageRendered.getRenderedImage();
            useFS10 = (maxPixelSize == 1) || BitmapImageUtil.isMonochromeImage(renderedImage);

            ImageInfo imageInfo = imageRendered.getInfo();
            this.intrinsicSize = imageInfo.getSize();
            this.effIntrinsicSize = intrinsicSize;

            AFPResourceInfo resourceInfo = imageObjectInfo.getResourceInfo();
            this.usePageSegments = useFS10 && !resourceInfo.getLevel().isInline();
            if (usePageSegments) {
                //The image may need to be resized/resampled for use as a page segment
                int resolution = paintingState.getResolution();
                this.resampledDim = new Dimension(
                        (int)Math.ceil(UnitConv.mpt2px(targetSize.getWidth(), resolution)),
                        (int)Math.ceil(UnitConv.mpt2px(targetSize.getHeight(), resolution)));
                resourceInfo.setImageDimension(resampledDim);
                //Only resample/downsample if image is smaller than its intrinsic size
                //to make print file smaller
                this.resample = resampledDim.width < renderedImage.getWidth()
                        && resampledDim.height < renderedImage.getHeight();
                if (resample) {
                    effIntrinsicSize = new ImageSize(
                            resampledDim.width, resampledDim.height, resolution);
                }
            }

            //Update image object info
            imageObjectInfo.setDataHeightRes((int)Math.round(
                    effIntrinsicSize.getDpiHorizontal() * 10));
            imageObjectInfo.setDataWidthRes((int)Math.round(
                    effIntrinsicSize.getDpiVertical() * 10));
            imageObjectInfo.setDataHeight(effIntrinsicSize.getHeightPx());
            imageObjectInfo.setDataWidth(effIntrinsicSize.getWidthPx());

            // set object area info
            int resolution = paintingState.getResolution();
            AFPObjectAreaInfo objectAreaInfo = imageObjectInfo.getObjectAreaInfo();
            objectAreaInfo.setWidthRes(resolution);
            objectAreaInfo.setHeightRes(resolution);
        }

        private AFPDataObjectInfo encodeImage
            (AFPImageObjectInfo imageObjectInfo,
             AFPPaintingState paintingState)
                throws IOException {

            RenderedImage renderedImage = imageRendered.getRenderedImage();
            int functionSet = useFS10 ? 10 : 11;

            if (usePageSegments) {
                assert resampledDim != null;
                //Resize, optionally resample and convert image

                imageObjectInfo.setCreatePageSegment(true);

                float ditheringQuality = paintingState.getDitheringQuality();
                if (this.resample) {
                    if (log.isDebugEnabled()) {
                        log.debug("Resample from " + intrinsicSize.getDimensionPx()
                                + " to " + resampledDim);
                    }
                    renderedImage = BitmapImageUtil.convertToMonochrome(renderedImage,
                            resampledDim, ditheringQuality);
                } else if (ditheringQuality >= 0.5f) {
                    renderedImage = BitmapImageUtil.convertToMonochrome(renderedImage,
                            intrinsicSize.getDimensionPx(), ditheringQuality);
                }
            }

            //TODO To reduce AFP file size, investigate using a compression scheme.
            //Currently, all image data is uncompressed.
            ColorModel cm = renderedImage.getColorModel();
            if (log.isTraceEnabled()) {
                log.trace("ColorModel: " + cm);
            }
            int pixelSize = cm.getPixelSize();
            if (cm.hasAlpha()) {
                pixelSize -= 8;
            }

            byte[] imageData = null;
            ByteArrayOutputStream baos = new ByteArrayOutputStream();
            boolean allowDirectEncoding = true;
            if (allowDirectEncoding && (pixelSize <= maxPixelSize)) {
                //Attempt to encode without resampling the image
                ImageEncodingHelper helper = new ImageEncodingHelper(renderedImage,
                        pixelSize == 32);
                ColorModel encodedColorModel = helper.getEncodedColorModel();
                boolean directEncode = true;
                if (helper.getEncodedColorModel().getPixelSize() > maxPixelSize) {
                    directEncode = false; //pixel size needs to be reduced
                }
                if (BitmapImageUtil.getColorIndexSize(renderedImage) > 2) {
                    directEncode = false; //Lookup tables are not implemented, yet
                }
                if (useFS10
                        && BitmapImageUtil.isMonochromeImage(renderedImage)
                        && BitmapImageUtil.isZeroBlack(renderedImage)) {
                    directEncode = false;
                    //need a special method to invert the bit-stream since setting the
                    //subtractive mode in AFP alone doesn't seem to do the trick.
                    if (encodeInvertedBilevel(helper, imageObjectInfo, baos)) {
                        imageData = baos.toByteArray();
                    }
                }
                if (directEncode) {
                    log.debug("Encoding image directly...");
                    imageObjectInfo.setBitsPerPixel(encodedColorModel.getPixelSize());
                    if (pixelSize == 32) {
                        functionSet = 45; //IOCA FS45 required for CMYK
                    }

                    helper.encode(baos);
                    imageData = baos.toByteArray();
                }
            }
            if (imageData == null) {
                log.debug("Encoding image via RGB...");
                imageData = encodeViaRGB(renderedImage, imageObjectInfo, paintingState, baos);
            }

            switch (functionSet) {
            case 10:
                imageObjectInfo.setMimeType(MimeConstants.MIME_AFP_IOCA_FS10);
                break;
            case 11:
                imageObjectInfo.setMimeType(MimeConstants.MIME_AFP_IOCA_FS11);
                break;
            case 45:
                imageObjectInfo.setMimeType(MimeConstants.MIME_AFP_IOCA_FS45);
                break;
            default:
                throw new IllegalStateException("Invalid IOCA function set: " + functionSet);
            }

            imageObjectInfo.setData(imageData);

            return imageObjectInfo;
        }

        private byte[] encodeViaRGB(RenderedImage renderedImage,
                AFPImageObjectInfo imageObjectInfo, AFPPaintingState paintingState,
                ByteArrayOutputStream baos) throws IOException {
            byte[] imageData;
            //Convert image to 24bit RGB
            ImageEncodingHelper.encodeRenderedImageAsRGB(renderedImage, baos);
            imageData = baos.toByteArray();
            imageObjectInfo.setBitsPerPixel(24);

            boolean colorImages = paintingState.isColorImages();
            imageObjectInfo.setColor(colorImages);

            // convert to grayscale
            if (!colorImages) {
                log.debug("Converting RGB image to grayscale...");
                baos.reset();
                int bitsPerPixel = paintingState.getBitsPerPixel();
                imageObjectInfo.setBitsPerPixel(bitsPerPixel);
                //TODO this should be done off the RenderedImage to avoid buffering the
                //intermediate 24bit image
                ImageEncodingHelper.encodeRGBAsGrayScale(
                      imageData, renderedImage.getWidth(), renderedImage.getHeight(),
                      bitsPerPixel, baos);
                imageData = baos.toByteArray();
                if (bitsPerPixel == 1) {
                    imageObjectInfo.setSubtractive(true);
                }
            }
            return imageData;
        }

        /**
         * Efficiently encodes a bi-level image in inverted form as a plain bit-stream.
         * @param helper the image encoding helper used to analyze the image
         * @param imageObjectInfo the AFP image object
         * @param out the output stream
         * @return true if the image was encoded, false if there was something prohibiting that
         * @throws IOException if an I/O error occurs
         */
        private boolean encodeInvertedBilevel(ImageEncodingHelper helper,
                AFPImageObjectInfo imageObjectInfo, OutputStream out) throws IOException {
            RenderedImage renderedImage = helper.getImage();
            if (!BitmapImageUtil.isMonochromeImage(renderedImage)) {
                throw new IllegalStateException("This method only supports binary images!");
            }
            int tiles = renderedImage.getNumXTiles() * renderedImage.getNumYTiles();
            if (tiles > 1) {
                return false;
            }
            SampleModel sampleModel = renderedImage.getSampleModel();
            SampleModel expectedSampleModel = new MultiPixelPackedSampleModel(DataBuffer.TYPE_BYTE,
                    renderedImage.getWidth(), renderedImage.getHeight(), 1);
            if (!expectedSampleModel.equals(sampleModel)) {
                return false; //Pixels are not packed
            }

            imageObjectInfo.setBitsPerPixel(1);

            Raster raster = renderedImage.getTile(0, 0);
            DataBuffer buffer = raster.getDataBuffer();
            if (buffer instanceof DataBufferByte) {
                DataBufferByte byteBuffer = (DataBufferByte)buffer;
                log.debug("Encoding image as inverted bi-level...");
                byte[] rawData = byteBuffer.getData();
                int remaining = rawData.length;
                int pos = 0;
                byte[] data = new byte[4096];
                while (remaining > 0) {
                    int size = Math.min(remaining, data.length);
                    for (int i = 0; i < size; i++) {
                        data[i] = (byte)~rawData[pos]; //invert bits
                        pos++;
                    }
                    out.write(data, 0, size);
                    remaining -= size;
                }
                return true;
            }
            return false;
        }

    }

}