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/*
 * Copyright (c) 1997, 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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package com.sun.javafx.geom;

import java.util.NoSuchElementException;

/**
 * The FlatteningPathIterator class returns a flattened view of
 * another {@link PathIterator} object.  Other {@link java.awt.Shape Shape} 
 * classes can use this class to provide flattening behavior for their paths
 * without having to perform the interpolation calculations themselves.
 *
 * @version 1.6 06/29/98
 */
public class FlatteningPathIterator implements PathIterator {
    static final int GROW_SIZE = 24;    // Multiple of cubic & quad curve size

    PathIterator src;           // The source iterator

    float squareflat;           // Square of the flatness parameter
                    // for testing against squared lengths

    int limit;              // Maximum number of recursion levels

    // hold field must be volatile to work around a Mac runtime bug (see RT-12386)
    volatile float hold[] = new float[14];   // The cache of interpolated coords
                    // Note that this must be long enough
                    // to store a full cubic segment and
                    // a relative cubic segment to avoid
                    // aliasing when copying the coords
                    // of a curve to the end of the array.
                    // This is also serendipitously equal
                    // to the size of a full quad segment
                    // and 2 relative quad segments.

    float curx, cury;           // The ending x,y of the last segment

    float movx, movy;           // The x,y of the last move segment

    int holdType;           // The type of the curve being held
                    // for interpolation

    int holdEnd;            // The index of the last curve segment
                    // being held for interpolation

    int holdIndex;          // The index of the curve segment
                    // that was last interpolated.  This
                    // is the curve segment ready to be
                    // returned in the next call to
                    // currentSegment().

    int levels[];           // The recursion level at which
                    // each curve being held in storage
                    // was generated.

    int levelIndex;         // The index of the entry in the
                    // levels array of the curve segment
                    // at the holdIndex

    boolean done;           // True when iteration is done

    /**
     * Constructs a new FlatteningPathIterator object that 
     * flattens a path as it iterates over it.  The iterator does not 
     * subdivide any curve read from the source iterator to more than 
     * 10 levels of subdivision which yields a maximum of 1024 line 
     * segments per curve.
     * @param src the original unflattened path being iterated over
     * @param flatness the maximum allowable distance between the
     * control points and the flattened curve
     */
    public FlatteningPathIterator(PathIterator src, float flatness) {
        this(src, flatness, 10);
    }

    /**
     * Constructs a new FlatteningPathIterator object 
     * that flattens a path as it iterates over it.
     * The limit parameter allows you to control the
     * maximum number of recursive subdivisions that the iterator
     * can make before it assumes that the curve is flat enough
     * without measuring against the flatness parameter.
     * The flattened iteration therefore never generates more than
     * a maximum of (2^limit) line segments per curve.
     * @param src the original unflattened path being iterated over
     * @param flatness the maximum allowable distance between the
     * control points and the flattened curve
     * @param limit the maximum number of recursive subdivisions
     * allowed for any curved segment
     * @exception IllegalArgumentException if 
     *      flatness or limit
     *      is less than zero
     */
    public FlatteningPathIterator(PathIterator src, float flatness,
                  int limit) {
        if (flatness < 0f) {
            throw new IllegalArgumentException("flatness must be >= 0");
        }
        if (limit < 0) {
            throw new IllegalArgumentException("limit must be >= 0");
        }
        this.src = src;
        this.squareflat = flatness * flatness;
        this.limit = limit;
        this.levels = new int[limit + 1];
        // prime the first path segment
        next(false);
    }

    /**
     * Returns the flatness of this iterator.
     * @return the flatness of this FlatteningPathIterator.
     */
    public float getFlatness() {
        return (float) Math.sqrt(squareflat);
    }

    /**
     * Returns the recursion limit of this iterator.
     * @return the recursion limit of this 
     * FlatteningPathIterator.
     */
    public int getRecursionLimit() {
        return limit;
    }

    /**
     * Returns the winding rule for determining the interior of the
     * path.
     * @return the winding rule of the original unflattened path being
     * iterated over.
     * @see PathIterator#WIND_EVEN_ODD
     * @see PathIterator#WIND_NON_ZERO
     */
    public int getWindingRule() {
        return src.getWindingRule();
    }

    /**
     * Tests if the iteration is complete.
     * @return true if all the segments have
     * been read; false otherwise.
     */
    public boolean isDone() {
    return done;
    }

    /*
     * Ensures that the hold array can hold up to (want) more values.
     * It is currently holding (hold.length - holdIndex) values.
     */
    void ensureHoldCapacity(int want) {
    if (holdIndex - want < 0) {
        int have = hold.length - holdIndex;
        int newsize = hold.length + GROW_SIZE;
        float newhold[] = new float[newsize];
        System.arraycopy(hold, holdIndex,
                 newhold, holdIndex + GROW_SIZE,
                 have);
        hold = newhold;
        holdIndex += GROW_SIZE;
        holdEnd += GROW_SIZE;
    }
    }

    /**
     * Moves the iterator to the next segment of the path forwards
     * along the primary direction of traversal as long as there are
     * more points in that direction.
     */
    public void next() {
        next(true);
    }

    private void next(boolean doNext) {
        int level;
    
        if (holdIndex >= holdEnd) {
            if (doNext) {
            src.next();
            }
            if (src.isDone()) {
            done = true;
            return;
            }
            holdType = src.currentSegment(hold);
            levelIndex = 0;
            levels[0] = 0;
        }
    
        switch (holdType) {
        case SEG_MOVETO:
        case SEG_LINETO:
            curx = hold[0];
            cury = hold[1];
            if (holdType == SEG_MOVETO) {
            movx = curx;
            movy = cury;
            }
            holdIndex = 0;
            holdEnd = 0;
            break;
        case SEG_CLOSE:
            curx = movx;
            cury = movy;
            holdIndex = 0;
            holdEnd = 0;
            break;
        case SEG_QUADTO:
            if (holdIndex >= holdEnd) {
            // Move the coordinates to the end of the array.
            holdIndex = hold.length - 6;
            holdEnd = hold.length - 2;
            hold[holdIndex + 0] = curx;
            hold[holdIndex + 1] = cury;
            hold[holdIndex + 2] = hold[0];
            hold[holdIndex + 3] = hold[1];
            hold[holdIndex + 4] = curx = hold[2];
            hold[holdIndex + 5] = cury = hold[3];
            }
    
            level = levels[levelIndex];
            while (level < limit) {
            if (QuadCurve2D.getFlatnessSq(hold, holdIndex) < squareflat) {
                break;
            }
    
            ensureHoldCapacity(4);
            QuadCurve2D.subdivide(hold, holdIndex,
                          hold, holdIndex - 4,
                          hold, holdIndex);
            holdIndex -= 4;
    
            // Now that we have subdivided, we have constructed
            // two curves of one depth lower than the original
            // curve.  One of those curves is in the place of
            // the former curve and one of them is in the next
            // set of held coordinate slots.  We now set both
            // curves level values to the next higher level.
            level++;
            levels[levelIndex] = level;
            levelIndex++;
            levels[levelIndex] = level;
            }
    
            // This curve segment is flat enough, or it is too deep
            // in recursion levels to try to flatten any more.  The
            // two coordinates at holdIndex+4 and holdIndex+5 now
            // contain the endpoint of the curve which can be the
            // endpoint of an approximating line segment.
            holdIndex += 4;
            levelIndex--;
            break;
        case SEG_CUBICTO:
            if (holdIndex >= holdEnd) {
            // Move the coordinates to the end of the array.
            holdIndex = hold.length - 8;
            holdEnd = hold.length - 2;
            hold[holdIndex + 0] = curx;
            hold[holdIndex + 1] = cury;
            hold[holdIndex + 2] = hold[0];
            hold[holdIndex + 3] = hold[1];
            hold[holdIndex + 4] = hold[2];
            hold[holdIndex + 5] = hold[3];
            hold[holdIndex + 6] = curx = hold[4];
            hold[holdIndex + 7] = cury = hold[5];
            }
    
            level = levels[levelIndex];
            while (level < limit) {
            if (CubicCurve2D.getFlatnessSq(hold, holdIndex) < squareflat) {
                break;
            }
    
            ensureHoldCapacity(6);
            CubicCurve2D.subdivide(hold, holdIndex,
                           hold, holdIndex - 6,
                           hold, holdIndex);
            holdIndex -= 6;
    
            // Now that we have subdivided, we have constructed
            // two curves of one depth lower than the original
            // curve.  One of those curves is in the place of
            // the former curve and one of them is in the next
            // set of held coordinate slots.  We now set both
            // curves level values to the next higher level.
            level++;
            levels[levelIndex] = level;
            levelIndex++;
            levels[levelIndex] = level;
            }
    
            // This curve segment is flat enough, or it is too deep
            // in recursion levels to try to flatten any more.  The
            // two coordinates at holdIndex+6 and holdIndex+7 now
            // contain the endpoint of the curve which can be the
            // endpoint of an approximating line segment.
            holdIndex += 6;
            levelIndex--;
            break;
        }
    }

    /**
     * Returns the coordinates and type of the current path segment in
     * the iteration.
     * The return value is the path segment type:
     * SEG_MOVETO, SEG_LINETO, or SEG_CLOSE.
     * A float array of length 6 must be passed in and can be used to
     * store the coordinates of the point(s).
     * Each point is stored as a pair of float x,y coordinates.
     * SEG_MOVETO and SEG_LINETO types return one point,
     * and SEG_CLOSE does not return any points.
     * @param coords an array that holds the data returned from
     * this method
     * @return the path segment type of the current path segment.
     * @exception NoSuchElementException if there
     *      are no more elements in the flattening path to be
     *      returned.
     * @see PathIterator#SEG_MOVETO
     * @see PathIterator#SEG_LINETO
     * @see PathIterator#SEG_CLOSE
     */
    public int currentSegment(float[] coords) {
        if (isDone()) {
            throw new NoSuchElementException("flattening iterator out of bounds");
        }
        int type = holdType;
        if (type != SEG_CLOSE) {
            coords[0] = (float) hold[holdIndex + 0];
            coords[1] = (float) hold[holdIndex + 1];
            if (type != SEG_MOVETO) {
            type = SEG_LINETO;
            }
        }
        return type;
    }
}




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