| /* |
| * Copyright (c) 2007, 2017, 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 |
| * or visit www.oracle.com if you need additional information or have any |
| * questions. |
| */ |
| |
| package sun.java2d.marlin; |
| |
| import java.awt.BasicStroke; |
| import java.awt.Shape; |
| import java.awt.geom.AffineTransform; |
| import java.awt.geom.Path2D; |
| import java.awt.geom.PathIterator; |
| import java.security.AccessController; |
| import static sun.java2d.marlin.MarlinUtils.logInfo; |
| import sun.java2d.ReentrantContextProvider; |
| import sun.java2d.ReentrantContextProviderCLQ; |
| import sun.java2d.ReentrantContextProviderTL; |
| import sun.java2d.pipe.AATileGenerator; |
| import sun.java2d.pipe.Region; |
| import sun.java2d.pipe.RenderingEngine; |
| import sun.security.action.GetPropertyAction; |
| |
| /** |
| * Marlin RendererEngine implementation (derived from Pisces) |
| */ |
| public final class DMarlinRenderingEngine extends RenderingEngine |
| implements MarlinConst |
| { |
| private static enum NormMode { |
| ON_WITH_AA { |
| @Override |
| PathIterator getNormalizingPathIterator(final DRendererContext rdrCtx, |
| final PathIterator src) |
| { |
| // NormalizingPathIterator NearestPixelCenter: |
| return rdrCtx.nPCPathIterator.init(src); |
| } |
| }, |
| ON_NO_AA{ |
| @Override |
| PathIterator getNormalizingPathIterator(final DRendererContext rdrCtx, |
| final PathIterator src) |
| { |
| // NearestPixel NormalizingPathIterator: |
| return rdrCtx.nPQPathIterator.init(src); |
| } |
| }, |
| OFF{ |
| @Override |
| PathIterator getNormalizingPathIterator(final DRendererContext rdrCtx, |
| final PathIterator src) |
| { |
| // return original path iterator if normalization is disabled: |
| return src; |
| } |
| }; |
| |
| abstract PathIterator getNormalizingPathIterator(DRendererContext rdrCtx, |
| PathIterator src); |
| } |
| |
| private static final float MIN_PEN_SIZE = 1.0f / NORM_SUBPIXELS; |
| |
| static final double UPPER_BND = Float.MAX_VALUE / 2.0d; |
| static final double LOWER_BND = -UPPER_BND; |
| |
| /** |
| * Public constructor |
| */ |
| public DMarlinRenderingEngine() { |
| super(); |
| logSettings(DMarlinRenderingEngine.class.getName()); |
| } |
| |
| /** |
| * Create a widened path as specified by the parameters. |
| * <p> |
| * The specified {@code src} {@link Shape} is widened according |
| * to the specified attribute parameters as per the |
| * {@link BasicStroke} specification. |
| * |
| * @param src the source path to be widened |
| * @param width the width of the widened path as per {@code BasicStroke} |
| * @param caps the end cap decorations as per {@code BasicStroke} |
| * @param join the segment join decorations as per {@code BasicStroke} |
| * @param miterlimit the miter limit as per {@code BasicStroke} |
| * @param dashes the dash length array as per {@code BasicStroke} |
| * @param dashphase the initial dash phase as per {@code BasicStroke} |
| * @return the widened path stored in a new {@code Shape} object |
| * @since 1.7 |
| */ |
| @Override |
| public Shape createStrokedShape(Shape src, |
| float width, |
| int caps, |
| int join, |
| float miterlimit, |
| float[] dashes, |
| float dashphase) |
| { |
| final DRendererContext rdrCtx = getRendererContext(); |
| try { |
| // initialize a large copyable Path2D to avoid a lot of array growing: |
| final Path2D.Double p2d = rdrCtx.getPath2D(); |
| |
| strokeTo(rdrCtx, |
| src, |
| null, |
| width, |
| NormMode.OFF, |
| caps, |
| join, |
| miterlimit, |
| dashes, |
| dashphase, |
| rdrCtx.transformerPC2D.wrapPath2d(p2d) |
| ); |
| |
| // Use Path2D copy constructor (trim) |
| return new Path2D.Double(p2d); |
| |
| } finally { |
| // recycle the DRendererContext instance |
| returnRendererContext(rdrCtx); |
| } |
| } |
| |
| /** |
| * Sends the geometry for a widened path as specified by the parameters |
| * to the specified consumer. |
| * <p> |
| * The specified {@code src} {@link Shape} is widened according |
| * to the parameters specified by the {@link BasicStroke} object. |
| * Adjustments are made to the path as appropriate for the |
| * {@link java.awt.RenderingHints#VALUE_STROKE_NORMALIZE} hint if the |
| * {@code normalize} boolean parameter is true. |
| * Adjustments are made to the path as appropriate for the |
| * {@link java.awt.RenderingHints#VALUE_ANTIALIAS_ON} hint if the |
| * {@code antialias} boolean parameter is true. |
| * <p> |
| * The geometry of the widened path is forwarded to the indicated |
| * {@link DPathConsumer2D} object as it is calculated. |
| * |
| * @param src the source path to be widened |
| * @param bs the {@code BasicSroke} object specifying the |
| * decorations to be applied to the widened path |
| * @param normalize indicates whether stroke normalization should |
| * be applied |
| * @param antialias indicates whether or not adjustments appropriate |
| * to antialiased rendering should be applied |
| * @param consumer the {@code DPathConsumer2D} instance to forward |
| * the widened geometry to |
| * @since 1.7 |
| */ |
| @Override |
| public void strokeTo(Shape src, |
| AffineTransform at, |
| BasicStroke bs, |
| boolean thin, |
| boolean normalize, |
| boolean antialias, |
| final sun.awt.geom.PathConsumer2D consumer) |
| { |
| final NormMode norm = (normalize) ? |
| ((antialias) ? NormMode.ON_WITH_AA : NormMode.ON_NO_AA) |
| : NormMode.OFF; |
| |
| final DRendererContext rdrCtx = getRendererContext(); |
| try { |
| strokeTo(rdrCtx, src, at, bs, thin, norm, antialias, |
| rdrCtx.p2dAdapter.init(consumer)); |
| } finally { |
| // recycle the DRendererContext instance |
| returnRendererContext(rdrCtx); |
| } |
| } |
| |
| final void strokeTo(final DRendererContext rdrCtx, |
| Shape src, |
| AffineTransform at, |
| BasicStroke bs, |
| boolean thin, |
| NormMode normalize, |
| boolean antialias, |
| DPathConsumer2D pc2d) |
| { |
| double lw; |
| if (thin) { |
| if (antialias) { |
| lw = userSpaceLineWidth(at, MIN_PEN_SIZE); |
| } else { |
| lw = userSpaceLineWidth(at, 1.0d); |
| } |
| } else { |
| lw = bs.getLineWidth(); |
| } |
| strokeTo(rdrCtx, |
| src, |
| at, |
| lw, |
| normalize, |
| bs.getEndCap(), |
| bs.getLineJoin(), |
| bs.getMiterLimit(), |
| bs.getDashArray(), |
| bs.getDashPhase(), |
| pc2d); |
| } |
| |
| private final double userSpaceLineWidth(AffineTransform at, double lw) { |
| |
| double widthScale; |
| |
| if (at == null) { |
| widthScale = 1.0d; |
| } else if ((at.getType() & (AffineTransform.TYPE_GENERAL_TRANSFORM | |
| AffineTransform.TYPE_GENERAL_SCALE)) != 0) { |
| widthScale = Math.sqrt(at.getDeterminant()); |
| } else { |
| // First calculate the "maximum scale" of this transform. |
| double A = at.getScaleX(); // m00 |
| double C = at.getShearX(); // m01 |
| double B = at.getShearY(); // m10 |
| double D = at.getScaleY(); // m11 |
| |
| /* |
| * Given a 2 x 2 affine matrix [ A B ] such that |
| * [ C D ] |
| * v' = [x' y'] = [Ax + Cy, Bx + Dy], we want to |
| * find the maximum magnitude (norm) of the vector v' |
| * with the constraint (x^2 + y^2 = 1). |
| * The equation to maximize is |
| * |v'| = sqrt((Ax+Cy)^2+(Bx+Dy)^2) |
| * or |v'| = sqrt((AA+BB)x^2 + 2(AC+BD)xy + (CC+DD)y^2). |
| * Since sqrt is monotonic we can maximize |v'|^2 |
| * instead and plug in the substitution y = sqrt(1 - x^2). |
| * Trigonometric equalities can then be used to get |
| * rid of most of the sqrt terms. |
| */ |
| |
| double EA = A*A + B*B; // x^2 coefficient |
| double EB = 2.0d * (A*C + B*D); // xy coefficient |
| double EC = C*C + D*D; // y^2 coefficient |
| |
| /* |
| * There is a lot of calculus omitted here. |
| * |
| * Conceptually, in the interests of understanding the |
| * terms that the calculus produced we can consider |
| * that EA and EC end up providing the lengths along |
| * the major axes and the hypot term ends up being an |
| * adjustment for the additional length along the off-axis |
| * angle of rotated or sheared ellipses as well as an |
| * adjustment for the fact that the equation below |
| * averages the two major axis lengths. (Notice that |
| * the hypot term contains a part which resolves to the |
| * difference of these two axis lengths in the absence |
| * of rotation.) |
| * |
| * In the calculus, the ratio of the EB and (EA-EC) terms |
| * ends up being the tangent of 2*theta where theta is |
| * the angle that the long axis of the ellipse makes |
| * with the horizontal axis. Thus, this equation is |
| * calculating the length of the hypotenuse of a triangle |
| * along that axis. |
| */ |
| |
| double hypot = Math.sqrt(EB*EB + (EA-EC)*(EA-EC)); |
| // sqrt omitted, compare to squared limits below. |
| double widthsquared = ((EA + EC + hypot) / 2.0d); |
| |
| widthScale = Math.sqrt(widthsquared); |
| } |
| |
| return (lw / widthScale); |
| } |
| |
| final void strokeTo(final DRendererContext rdrCtx, |
| Shape src, |
| AffineTransform at, |
| double width, |
| NormMode norm, |
| int caps, |
| int join, |
| float miterlimit, |
| float[] dashes, |
| float dashphase, |
| DPathConsumer2D pc2d) |
| { |
| // We use strokerat so that in Stroker and Dasher we can work only |
| // with the pre-transformation coordinates. This will repeat a lot of |
| // computations done in the path iterator, but the alternative is to |
| // work with transformed paths and compute untransformed coordinates |
| // as needed. This would be faster but I do not think the complexity |
| // of working with both untransformed and transformed coordinates in |
| // the same code is worth it. |
| // However, if a path's width is constant after a transformation, |
| // we can skip all this untransforming. |
| |
| // As pathTo() will check transformed coordinates for invalid values |
| // (NaN / Infinity) to ignore such points, it is necessary to apply the |
| // transformation before the path processing. |
| AffineTransform strokerat = null; |
| |
| int dashLen = -1; |
| boolean recycleDashes = false; |
| double[] dashesD = null; |
| |
| // Ensure converting dashes to double precision: |
| if (dashes != null) { |
| recycleDashes = true; |
| dashLen = dashes.length; |
| dashesD = rdrCtx.dasher.copyDashArray(dashes); |
| } |
| |
| if (at != null && !at.isIdentity()) { |
| final double a = at.getScaleX(); |
| final double b = at.getShearX(); |
| final double c = at.getShearY(); |
| final double d = at.getScaleY(); |
| final double det = a * d - c * b; |
| |
| if (Math.abs(det) <= (2.0d * Double.MIN_VALUE)) { |
| // this rendering engine takes one dimensional curves and turns |
| // them into 2D shapes by giving them width. |
| // However, if everything is to be passed through a singular |
| // transformation, these 2D shapes will be squashed down to 1D |
| // again so, nothing can be drawn. |
| |
| // Every path needs an initial moveTo and a pathDone. If these |
| // are not there this causes a SIGSEGV in libawt.so (at the time |
| // of writing of this comment (September 16, 2010)). Actually, |
| // I am not sure if the moveTo is necessary to avoid the SIGSEGV |
| // but the pathDone is definitely needed. |
| pc2d.moveTo(0.0d, 0.0d); |
| pc2d.pathDone(); |
| return; |
| } |
| |
| // If the transform is a constant multiple of an orthogonal transformation |
| // then every length is just multiplied by a constant, so we just |
| // need to transform input paths to stroker and tell stroker |
| // the scaled width. This condition is satisfied if |
| // a*b == -c*d && a*a+c*c == b*b+d*d. In the actual check below, we |
| // leave a bit of room for error. |
| if (nearZero(a*b + c*d) && nearZero(a*a + c*c - (b*b + d*d))) { |
| final double scale = Math.sqrt(a*a + c*c); |
| |
| if (dashesD != null) { |
| for (int i = 0; i < dashLen; i++) { |
| dashesD[i] *= scale; |
| } |
| dashphase *= scale; |
| } |
| width *= scale; |
| |
| // by now strokerat == null. Input paths to |
| // stroker (and maybe dasher) will have the full transform at |
| // applied to them and nothing will happen to the output paths. |
| } else { |
| strokerat = at; |
| |
| // by now strokerat == at. Input paths to |
| // stroker (and maybe dasher) will have the full transform at |
| // applied to them, then they will be normalized, and then |
| // the inverse of *only the non translation part of at* will |
| // be applied to the normalized paths. This won't cause problems |
| // in stroker, because, suppose at = T*A, where T is just the |
| // translation part of at, and A is the rest. T*A has already |
| // been applied to Stroker/Dasher's input. Then Ainv will be |
| // applied. Ainv*T*A is not equal to T, but it is a translation, |
| // which means that none of stroker's assumptions about its |
| // input will be violated. After all this, A will be applied |
| // to stroker's output. |
| } |
| } else { |
| // either at is null or it's the identity. In either case |
| // we don't transform the path. |
| at = null; |
| } |
| |
| if (USE_SIMPLIFIER) { |
| // Use simplifier after stroker before Renderer |
| // to remove collinear segments (notably due to cap square) |
| pc2d = rdrCtx.simplifier.init(pc2d); |
| } |
| |
| final DTransformingPathConsumer2D transformerPC2D = rdrCtx.transformerPC2D; |
| pc2d = transformerPC2D.deltaTransformConsumer(pc2d, strokerat); |
| |
| pc2d = rdrCtx.stroker.init(pc2d, width, caps, join, miterlimit); |
| |
| if (dashesD != null) { |
| pc2d = rdrCtx.dasher.init(pc2d, dashesD, dashLen, dashphase, |
| recycleDashes); |
| } |
| pc2d = transformerPC2D.inverseDeltaTransformConsumer(pc2d, strokerat); |
| |
| final PathIterator pi = norm.getNormalizingPathIterator(rdrCtx, |
| src.getPathIterator(at)); |
| |
| pathTo(rdrCtx, pi, pc2d); |
| |
| /* |
| * Pipeline seems to be: |
| * shape.getPathIterator(at) |
| * -> (NormalizingPathIterator) |
| * -> (inverseDeltaTransformConsumer) |
| * -> (Dasher) |
| * -> Stroker |
| * -> (deltaTransformConsumer) |
| * |
| * -> (CollinearSimplifier) to remove redundant segments |
| * |
| * -> pc2d = Renderer (bounding box) |
| */ |
| } |
| |
| private static boolean nearZero(final double num) { |
| return Math.abs(num) < 2.0d * Math.ulp(num); |
| } |
| |
| abstract static class NormalizingPathIterator implements PathIterator { |
| |
| private PathIterator src; |
| |
| // the adjustment applied to the current position. |
| private double curx_adjust, cury_adjust; |
| // the adjustment applied to the last moveTo position. |
| private double movx_adjust, movy_adjust; |
| |
| private final double[] tmp; |
| |
| NormalizingPathIterator(final double[] tmp) { |
| this.tmp = tmp; |
| } |
| |
| final NormalizingPathIterator init(final PathIterator src) { |
| this.src = src; |
| return this; // fluent API |
| } |
| |
| /** |
| * Disposes this path iterator: |
| * clean up before reusing this instance |
| */ |
| final void dispose() { |
| // free source PathIterator: |
| this.src = null; |
| } |
| |
| @Override |
| public final int currentSegment(final double[] coords) { |
| int lastCoord; |
| final int type = src.currentSegment(coords); |
| |
| switch(type) { |
| case PathIterator.SEG_MOVETO: |
| case PathIterator.SEG_LINETO: |
| lastCoord = 0; |
| break; |
| case PathIterator.SEG_QUADTO: |
| lastCoord = 2; |
| break; |
| case PathIterator.SEG_CUBICTO: |
| lastCoord = 4; |
| break; |
| case PathIterator.SEG_CLOSE: |
| // we don't want to deal with this case later. We just exit now |
| curx_adjust = movx_adjust; |
| cury_adjust = movy_adjust; |
| return type; |
| default: |
| throw new InternalError("Unrecognized curve type"); |
| } |
| |
| // normalize endpoint |
| double coord, x_adjust, y_adjust; |
| |
| coord = coords[lastCoord]; |
| x_adjust = normCoord(coord); // new coord |
| coords[lastCoord] = x_adjust; |
| x_adjust -= coord; |
| |
| coord = coords[lastCoord + 1]; |
| y_adjust = normCoord(coord); // new coord |
| coords[lastCoord + 1] = y_adjust; |
| y_adjust -= coord; |
| |
| // now that the end points are done, normalize the control points |
| switch(type) { |
| case PathIterator.SEG_MOVETO: |
| movx_adjust = x_adjust; |
| movy_adjust = y_adjust; |
| break; |
| case PathIterator.SEG_LINETO: |
| break; |
| case PathIterator.SEG_QUADTO: |
| coords[0] += (curx_adjust + x_adjust) / 2.0d; |
| coords[1] += (cury_adjust + y_adjust) / 2.0d; |
| break; |
| case PathIterator.SEG_CUBICTO: |
| coords[0] += curx_adjust; |
| coords[1] += cury_adjust; |
| coords[2] += x_adjust; |
| coords[3] += y_adjust; |
| break; |
| case PathIterator.SEG_CLOSE: |
| // handled earlier |
| default: |
| } |
| curx_adjust = x_adjust; |
| cury_adjust = y_adjust; |
| return type; |
| } |
| |
| abstract double normCoord(final double coord); |
| |
| @Override |
| public final int currentSegment(final float[] coords) { |
| final double[] _tmp = tmp; // dirty |
| int type = this.currentSegment(_tmp); |
| for (int i = 0; i < 6; i++) { |
| coords[i] = (float)_tmp[i]; |
| } |
| return type; |
| } |
| |
| @Override |
| public final int getWindingRule() { |
| return src.getWindingRule(); |
| } |
| |
| @Override |
| public final boolean isDone() { |
| if (src.isDone()) { |
| // Dispose this instance: |
| dispose(); |
| return true; |
| } |
| return false; |
| } |
| |
| @Override |
| public final void next() { |
| src.next(); |
| } |
| |
| static final class NearestPixelCenter |
| extends NormalizingPathIterator |
| { |
| NearestPixelCenter(final double[] tmp) { |
| super(tmp); |
| } |
| |
| @Override |
| double normCoord(final double coord) { |
| // round to nearest pixel center |
| return Math.floor(coord) + 0.5d; |
| } |
| } |
| |
| static final class NearestPixelQuarter |
| extends NormalizingPathIterator |
| { |
| NearestPixelQuarter(final double[] tmp) { |
| super(tmp); |
| } |
| |
| @Override |
| double normCoord(final double coord) { |
| // round to nearest (0.25, 0.25) pixel quarter |
| return Math.floor(coord + 0.25d) + 0.25d; |
| } |
| } |
| } |
| |
| private static void pathTo(final DRendererContext rdrCtx, final PathIterator pi, |
| final DPathConsumer2D pc2d) |
| { |
| // mark context as DIRTY: |
| rdrCtx.dirty = true; |
| |
| final double[] coords = rdrCtx.double6; |
| |
| pathToLoop(coords, pi, pc2d); |
| |
| // mark context as CLEAN: |
| rdrCtx.dirty = false; |
| } |
| |
| private static void pathToLoop(final double[] coords, final PathIterator pi, |
| final DPathConsumer2D pc2d) |
| { |
| // ported from DuctusRenderingEngine.feedConsumer() but simplified: |
| // - removed skip flag = !subpathStarted |
| // - removed pathClosed (ie subpathStarted not set to false) |
| boolean subpathStarted = false; |
| |
| for (; !pi.isDone(); pi.next()) { |
| switch (pi.currentSegment(coords)) { |
| case PathIterator.SEG_MOVETO: |
| /* Checking SEG_MOVETO coordinates if they are out of the |
| * [LOWER_BND, UPPER_BND] range. This check also handles NaN |
| * and Infinity values. Skipping next path segment in case of |
| * invalid data. |
| */ |
| if (coords[0] < UPPER_BND && coords[0] > LOWER_BND && |
| coords[1] < UPPER_BND && coords[1] > LOWER_BND) |
| { |
| pc2d.moveTo(coords[0], coords[1]); |
| subpathStarted = true; |
| } |
| break; |
| case PathIterator.SEG_LINETO: |
| /* Checking SEG_LINETO coordinates if they are out of the |
| * [LOWER_BND, UPPER_BND] range. This check also handles NaN |
| * and Infinity values. Ignoring current path segment in case |
| * of invalid data. If segment is skipped its endpoint |
| * (if valid) is used to begin new subpath. |
| */ |
| if (coords[0] < UPPER_BND && coords[0] > LOWER_BND && |
| coords[1] < UPPER_BND && coords[1] > LOWER_BND) |
| { |
| if (subpathStarted) { |
| pc2d.lineTo(coords[0], coords[1]); |
| } else { |
| pc2d.moveTo(coords[0], coords[1]); |
| subpathStarted = true; |
| } |
| } |
| break; |
| case PathIterator.SEG_QUADTO: |
| // Quadratic curves take two points |
| /* Checking SEG_QUADTO coordinates if they are out of the |
| * [LOWER_BND, UPPER_BND] range. This check also handles NaN |
| * and Infinity values. Ignoring current path segment in case |
| * of invalid endpoints's data. Equivalent to the SEG_LINETO |
| * if endpoint coordinates are valid but there are invalid data |
| * among other coordinates |
| */ |
| if (coords[2] < UPPER_BND && coords[2] > LOWER_BND && |
| coords[3] < UPPER_BND && coords[3] > LOWER_BND) |
| { |
| if (subpathStarted) { |
| if (coords[0] < UPPER_BND && coords[0] > LOWER_BND && |
| coords[1] < UPPER_BND && coords[1] > LOWER_BND) |
| { |
| pc2d.quadTo(coords[0], coords[1], |
| coords[2], coords[3]); |
| } else { |
| pc2d.lineTo(coords[2], coords[3]); |
| } |
| } else { |
| pc2d.moveTo(coords[2], coords[3]); |
| subpathStarted = true; |
| } |
| } |
| break; |
| case PathIterator.SEG_CUBICTO: |
| // Cubic curves take three points |
| /* Checking SEG_CUBICTO coordinates if they are out of the |
| * [LOWER_BND, UPPER_BND] range. This check also handles NaN |
| * and Infinity values. Ignoring current path segment in case |
| * of invalid endpoints's data. Equivalent to the SEG_LINETO |
| * if endpoint coordinates are valid but there are invalid data |
| * among other coordinates |
| */ |
| if (coords[4] < UPPER_BND && coords[4] > LOWER_BND && |
| coords[5] < UPPER_BND && coords[5] > LOWER_BND) |
| { |
| if (subpathStarted) { |
| if (coords[0] < UPPER_BND && coords[0] > LOWER_BND && |
| coords[1] < UPPER_BND && coords[1] > LOWER_BND && |
| coords[2] < UPPER_BND && coords[2] > LOWER_BND && |
| coords[3] < UPPER_BND && coords[3] > LOWER_BND) |
| { |
| pc2d.curveTo(coords[0], coords[1], |
| coords[2], coords[3], |
| coords[4], coords[5]); |
| } else { |
| pc2d.lineTo(coords[4], coords[5]); |
| } |
| } else { |
| pc2d.moveTo(coords[4], coords[5]); |
| subpathStarted = true; |
| } |
| } |
| break; |
| case PathIterator.SEG_CLOSE: |
| if (subpathStarted) { |
| pc2d.closePath(); |
| // do not set subpathStarted to false |
| // in case of missing moveTo() after close() |
| } |
| break; |
| default: |
| } |
| } |
| pc2d.pathDone(); |
| } |
| |
| /** |
| * Construct an antialiased tile generator for the given shape with |
| * the given rendering attributes and store the bounds of the tile |
| * iteration in the bbox parameter. |
| * The {@code at} parameter specifies a transform that should affect |
| * both the shape and the {@code BasicStroke} attributes. |
| * The {@code clip} parameter specifies the current clip in effect |
| * in device coordinates and can be used to prune the data for the |
| * operation, but the renderer is not required to perform any |
| * clipping. |
| * If the {@code BasicStroke} parameter is null then the shape |
| * should be filled as is, otherwise the attributes of the |
| * {@code BasicStroke} should be used to specify a draw operation. |
| * The {@code thin} parameter indicates whether or not the |
| * transformed {@code BasicStroke} represents coordinates smaller |
| * than the minimum resolution of the antialiasing rasterizer as |
| * specified by the {@code getMinimumAAPenWidth()} method. |
| * <p> |
| * Upon returning, this method will fill the {@code bbox} parameter |
| * with 4 values indicating the bounds of the iteration of the |
| * tile generator. |
| * The iteration order of the tiles will be as specified by the |
| * pseudo-code: |
| * <pre> |
| * for (y = bbox[1]; y < bbox[3]; y += tileheight) { |
| * for (x = bbox[0]; x < bbox[2]; x += tilewidth) { |
| * } |
| * } |
| * </pre> |
| * If there is no output to be rendered, this method may return |
| * null. |
| * |
| * @param s the shape to be rendered (fill or draw) |
| * @param at the transform to be applied to the shape and the |
| * stroke attributes |
| * @param clip the current clip in effect in device coordinates |
| * @param bs if non-null, a {@code BasicStroke} whose attributes |
| * should be applied to this operation |
| * @param thin true if the transformed stroke attributes are smaller |
| * than the minimum dropout pen width |
| * @param normalize true if the {@code VALUE_STROKE_NORMALIZE} |
| * {@code RenderingHint} is in effect |
| * @param bbox returns the bounds of the iteration |
| * @return the {@code AATileGenerator} instance to be consulted |
| * for tile coverages, or null if there is no output to render |
| * @since 1.7 |
| */ |
| @Override |
| public AATileGenerator getAATileGenerator(Shape s, |
| AffineTransform at, |
| Region clip, |
| BasicStroke bs, |
| boolean thin, |
| boolean normalize, |
| int[] bbox) |
| { |
| MarlinTileGenerator ptg = null; |
| DRenderer r = null; |
| |
| final DRendererContext rdrCtx = getRendererContext(); |
| try { |
| // Test if at is identity: |
| final AffineTransform _at = (at != null && !at.isIdentity()) ? at |
| : null; |
| |
| final NormMode norm = (normalize) ? NormMode.ON_WITH_AA : NormMode.OFF; |
| |
| if (bs == null) { |
| // fill shape: |
| final PathIterator pi = norm.getNormalizingPathIterator(rdrCtx, |
| s.getPathIterator(_at)); |
| |
| // note: Winding rule may be EvenOdd ONLY for fill operations ! |
| r = rdrCtx.renderer.init(clip.getLoX(), clip.getLoY(), |
| clip.getWidth(), clip.getHeight(), |
| pi.getWindingRule()); |
| |
| // TODO: subdivide quad/cubic curves into monotonic curves ? |
| pathTo(rdrCtx, pi, r); |
| } else { |
| // draw shape with given stroke: |
| r = rdrCtx.renderer.init(clip.getLoX(), clip.getLoY(), |
| clip.getWidth(), clip.getHeight(), |
| PathIterator.WIND_NON_ZERO); |
| |
| strokeTo(rdrCtx, s, _at, bs, thin, norm, true, r); |
| } |
| if (r.endRendering()) { |
| ptg = rdrCtx.ptg.init(); |
| ptg.getBbox(bbox); |
| // note: do not returnRendererContext(rdrCtx) |
| // as it will be called later by MarlinTileGenerator.dispose() |
| r = null; |
| } |
| } finally { |
| if (r != null) { |
| // dispose renderer and recycle the RendererContext instance: |
| r.dispose(); |
| } |
| } |
| |
| // Return null to cancel AA tile generation (nothing to render) |
| return ptg; |
| } |
| |
| @Override |
| public final AATileGenerator getAATileGenerator(double x, double y, |
| double dx1, double dy1, |
| double dx2, double dy2, |
| double lw1, double lw2, |
| Region clip, |
| int[] bbox) |
| { |
| // REMIND: Deal with large coordinates! |
| double ldx1, ldy1, ldx2, ldy2; |
| boolean innerpgram = (lw1 > 0.0d && lw2 > 0.0d); |
| |
| if (innerpgram) { |
| ldx1 = dx1 * lw1; |
| ldy1 = dy1 * lw1; |
| ldx2 = dx2 * lw2; |
| ldy2 = dy2 * lw2; |
| x -= (ldx1 + ldx2) / 2.0d; |
| y -= (ldy1 + ldy2) / 2.0d; |
| dx1 += ldx1; |
| dy1 += ldy1; |
| dx2 += ldx2; |
| dy2 += ldy2; |
| if (lw1 > 1.0d && lw2 > 1.0d) { |
| // Inner parallelogram was entirely consumed by stroke... |
| innerpgram = false; |
| } |
| } else { |
| ldx1 = ldy1 = ldx2 = ldy2 = 0.0d; |
| } |
| |
| MarlinTileGenerator ptg = null; |
| DRenderer r = null; |
| |
| final DRendererContext rdrCtx = getRendererContext(); |
| try { |
| r = rdrCtx.renderer.init(clip.getLoX(), clip.getLoY(), |
| clip.getWidth(), clip.getHeight(), |
| DRenderer.WIND_EVEN_ODD); |
| |
| r.moveTo( x, y); |
| r.lineTo( (x+dx1), (y+dy1)); |
| r.lineTo( (x+dx1+dx2), (y+dy1+dy2)); |
| r.lineTo( (x+dx2), (y+dy2)); |
| r.closePath(); |
| |
| if (innerpgram) { |
| x += ldx1 + ldx2; |
| y += ldy1 + ldy2; |
| dx1 -= 2.0d * ldx1; |
| dy1 -= 2.0d * ldy1; |
| dx2 -= 2.0d * ldx2; |
| dy2 -= 2.0d * ldy2; |
| r.moveTo( x, y); |
| r.lineTo( (x+dx1), (y+dy1)); |
| r.lineTo( (x+dx1+dx2), (y+dy1+dy2)); |
| r.lineTo( (x+dx2), (y+dy2)); |
| r.closePath(); |
| } |
| r.pathDone(); |
| |
| if (r.endRendering()) { |
| ptg = rdrCtx.ptg.init(); |
| ptg.getBbox(bbox); |
| // note: do not returnRendererContext(rdrCtx) |
| // as it will be called later by MarlinTileGenerator.dispose() |
| r = null; |
| } |
| } finally { |
| if (r != null) { |
| // dispose renderer and recycle the RendererContext instance: |
| r.dispose(); |
| } |
| } |
| |
| // Return null to cancel AA tile generation (nothing to render) |
| return ptg; |
| } |
| |
| /** |
| * Returns the minimum pen width that the antialiasing rasterizer |
| * can represent without dropouts occuring. |
| * @since 1.7 |
| */ |
| @Override |
| public float getMinimumAAPenSize() { |
| return MIN_PEN_SIZE; |
| } |
| |
| static { |
| if (PathIterator.WIND_NON_ZERO != DRenderer.WIND_NON_ZERO || |
| PathIterator.WIND_EVEN_ODD != DRenderer.WIND_EVEN_ODD || |
| BasicStroke.JOIN_MITER != DStroker.JOIN_MITER || |
| BasicStroke.JOIN_ROUND != DStroker.JOIN_ROUND || |
| BasicStroke.JOIN_BEVEL != DStroker.JOIN_BEVEL || |
| BasicStroke.CAP_BUTT != DStroker.CAP_BUTT || |
| BasicStroke.CAP_ROUND != DStroker.CAP_ROUND || |
| BasicStroke.CAP_SQUARE != DStroker.CAP_SQUARE) |
| { |
| throw new InternalError("mismatched renderer constants"); |
| } |
| } |
| |
| // --- DRendererContext handling --- |
| // use ThreadLocal or ConcurrentLinkedQueue to get one DRendererContext |
| private static final boolean USE_THREAD_LOCAL; |
| |
| // reference type stored in either TL or CLQ |
| static final int REF_TYPE; |
| |
| // Per-thread DRendererContext |
| private static final ReentrantContextProvider<DRendererContext> RDR_CTX_PROVIDER; |
| |
| // Static initializer to use TL or CLQ mode |
| static { |
| USE_THREAD_LOCAL = MarlinProperties.isUseThreadLocal(); |
| |
| // Soft reference by default: |
| final String refType = AccessController.doPrivileged( |
| new GetPropertyAction("sun.java2d.renderer.useRef", |
| "soft")); |
| |
| // Java 1.6 does not support strings in switch: |
| if ("hard".equalsIgnoreCase(refType)) { |
| REF_TYPE = ReentrantContextProvider.REF_HARD; |
| } else if ("weak".equalsIgnoreCase(refType)) { |
| REF_TYPE = ReentrantContextProvider.REF_WEAK; |
| } else { |
| REF_TYPE = ReentrantContextProvider.REF_SOFT; |
| } |
| |
| if (USE_THREAD_LOCAL) { |
| RDR_CTX_PROVIDER = new ReentrantContextProviderTL<DRendererContext>(REF_TYPE) |
| { |
| @Override |
| protected DRendererContext newContext() { |
| return DRendererContext.createContext(); |
| } |
| }; |
| } else { |
| RDR_CTX_PROVIDER = new ReentrantContextProviderCLQ<DRendererContext>(REF_TYPE) |
| { |
| @Override |
| protected DRendererContext newContext() { |
| return DRendererContext.createContext(); |
| } |
| }; |
| } |
| } |
| |
| private static boolean SETTINGS_LOGGED = !ENABLE_LOGS; |
| |
| private static void logSettings(final String reClass) { |
| // log information at startup |
| if (SETTINGS_LOGGED) { |
| return; |
| } |
| SETTINGS_LOGGED = true; |
| |
| String refType; |
| switch (REF_TYPE) { |
| default: |
| case ReentrantContextProvider.REF_HARD: |
| refType = "hard"; |
| break; |
| case ReentrantContextProvider.REF_SOFT: |
| refType = "soft"; |
| break; |
| case ReentrantContextProvider.REF_WEAK: |
| refType = "weak"; |
| break; |
| } |
| |
| logInfo("==========================================================" |
| + "====================="); |
| |
| logInfo("Marlin software rasterizer = ENABLED"); |
| logInfo("Version = [" |
| + Version.getVersion() + "]"); |
| logInfo("sun.java2d.renderer = " |
| + reClass); |
| logInfo("sun.java2d.renderer.useThreadLocal = " |
| + USE_THREAD_LOCAL); |
| logInfo("sun.java2d.renderer.useRef = " |
| + refType); |
| |
| logInfo("sun.java2d.renderer.edges = " |
| + MarlinConst.INITIAL_EDGES_COUNT); |
| logInfo("sun.java2d.renderer.pixelsize = " |
| + MarlinConst.INITIAL_PIXEL_DIM); |
| |
| logInfo("sun.java2d.renderer.subPixel_log2_X = " |
| + MarlinConst.SUBPIXEL_LG_POSITIONS_X); |
| logInfo("sun.java2d.renderer.subPixel_log2_Y = " |
| + MarlinConst.SUBPIXEL_LG_POSITIONS_Y); |
| |
| logInfo("sun.java2d.renderer.tileSize_log2 = " |
| + MarlinConst.TILE_H_LG); |
| logInfo("sun.java2d.renderer.tileWidth_log2 = " |
| + MarlinConst.TILE_W_LG); |
| logInfo("sun.java2d.renderer.blockSize_log2 = " |
| + MarlinConst.BLOCK_SIZE_LG); |
| |
| // RLE / blockFlags settings |
| |
| logInfo("sun.java2d.renderer.forceRLE = " |
| + MarlinProperties.isForceRLE()); |
| logInfo("sun.java2d.renderer.forceNoRLE = " |
| + MarlinProperties.isForceNoRLE()); |
| logInfo("sun.java2d.renderer.useTileFlags = " |
| + MarlinProperties.isUseTileFlags()); |
| logInfo("sun.java2d.renderer.useTileFlags.useHeuristics = " |
| + MarlinProperties.isUseTileFlagsWithHeuristics()); |
| logInfo("sun.java2d.renderer.rleMinWidth = " |
| + MarlinCache.RLE_MIN_WIDTH); |
| |
| // optimisation parameters |
| logInfo("sun.java2d.renderer.useSimplifier = " |
| + MarlinConst.USE_SIMPLIFIER); |
| |
| // debugging parameters |
| logInfo("sun.java2d.renderer.doStats = " |
| + MarlinConst.DO_STATS); |
| logInfo("sun.java2d.renderer.doMonitors = " |
| + MarlinConst.DO_MONITORS); |
| logInfo("sun.java2d.renderer.doChecks = " |
| + MarlinConst.DO_CHECKS); |
| |
| // logging parameters |
| logInfo("sun.java2d.renderer.useLogger = " |
| + MarlinConst.USE_LOGGER); |
| logInfo("sun.java2d.renderer.logCreateContext = " |
| + MarlinConst.LOG_CREATE_CONTEXT); |
| logInfo("sun.java2d.renderer.logUnsafeMalloc = " |
| + MarlinConst.LOG_UNSAFE_MALLOC); |
| |
| // quality settings |
| logInfo("sun.java2d.renderer.cubic_dec_d2 = " |
| + MarlinProperties.getCubicDecD2()); |
| logInfo("sun.java2d.renderer.cubic_inc_d1 = " |
| + MarlinProperties.getCubicIncD1()); |
| logInfo("sun.java2d.renderer.quad_dec_d2 = " |
| + MarlinProperties.getQuadDecD2()); |
| |
| logInfo("Renderer settings:"); |
| logInfo("CUB_DEC_BND = " + DRenderer.CUB_DEC_BND); |
| logInfo("CUB_INC_BND = " + DRenderer.CUB_INC_BND); |
| logInfo("QUAD_DEC_BND = " + DRenderer.QUAD_DEC_BND); |
| |
| logInfo("INITIAL_EDGES_CAPACITY = " |
| + MarlinConst.INITIAL_EDGES_CAPACITY); |
| logInfo("INITIAL_CROSSING_COUNT = " |
| + DRenderer.INITIAL_CROSSING_COUNT); |
| |
| logInfo("==========================================================" |
| + "====================="); |
| } |
| |
| /** |
| * Get the DRendererContext instance dedicated to the current thread |
| * @return DRendererContext instance |
| */ |
| @SuppressWarnings({"unchecked"}) |
| static DRendererContext getRendererContext() { |
| final DRendererContext rdrCtx = RDR_CTX_PROVIDER.acquire(); |
| if (DO_MONITORS) { |
| rdrCtx.stats.mon_pre_getAATileGenerator.start(); |
| } |
| return rdrCtx; |
| } |
| |
| /** |
| * Reset and return the given DRendererContext instance for reuse |
| * @param rdrCtx DRendererContext instance |
| */ |
| static void returnRendererContext(final DRendererContext rdrCtx) { |
| rdrCtx.dispose(); |
| |
| if (DO_MONITORS) { |
| rdrCtx.stats.mon_pre_getAATileGenerator.stop(); |
| } |
| RDR_CTX_PROVIDER.release(rdrCtx); |
| } |
| } |