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/*
 * Copyright (c) 2010, 2023, 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 javafx.scene.control.skin;

import com.sun.javafx.scene.ParentHelper;
import com.sun.javafx.scene.control.Logging;
import com.sun.javafx.scene.control.Properties;
import com.sun.javafx.scene.control.VirtualScrollBar;
import com.sun.javafx.scene.control.skin.Utils;
import com.sun.javafx.scene.traversal.Algorithm;
import com.sun.javafx.scene.traversal.Direction;
import com.sun.javafx.scene.traversal.ParentTraversalEngine;
import com.sun.javafx.scene.traversal.TraversalContext;
import javafx.animation.KeyFrame;
import javafx.animation.Timeline;
import javafx.beans.InvalidationListener;
import javafx.beans.Observable;
import javafx.beans.property.BooleanProperty;
import javafx.beans.property.BooleanPropertyBase;
import javafx.beans.property.DoubleProperty;
import javafx.beans.property.IntegerProperty;
import javafx.beans.property.ObjectProperty;
import javafx.beans.property.SimpleBooleanProperty;
import javafx.beans.property.SimpleDoubleProperty;
import javafx.beans.property.SimpleIntegerProperty;
import javafx.beans.property.SimpleObjectProperty;
import javafx.beans.value.ChangeListener;
import javafx.collections.ObservableList;
import javafx.event.EventDispatcher;
import javafx.event.EventHandler;
import javafx.geometry.Orientation;
import javafx.scene.AccessibleRole;
import javafx.scene.Group;
import javafx.scene.Node;
import javafx.scene.Parent;
import javafx.scene.Scene;
import javafx.scene.control.Cell;
import javafx.scene.control.IndexedCell;
import javafx.scene.control.ScrollBar;
import javafx.scene.input.MouseEvent;
import javafx.scene.input.ScrollEvent;
import javafx.scene.layout.Region;
import javafx.scene.layout.StackPane;
import javafx.scene.shape.Rectangle;
import javafx.util.Callback;
import javafx.util.Duration;
import com.sun.javafx.logging.PlatformLogger;

import java.util.AbstractList;
import java.util.ArrayList;
import java.util.BitSet;
import java.util.List;

/**
 * Implementation of a virtualized container using a cell based mechanism. This
 * is used by the skin implementations for UI controls such as
 * {@link javafx.scene.control.ListView}, {@link javafx.scene.control.TreeView},
 * {@link javafx.scene.control.TableView}, and {@link javafx.scene.control.TreeTableView}.
 *
 * @since 9
 */
public class VirtualFlow extends Region {

    /* *************************************************************************
     *                                                                         *
     * Static fields                                                           *
     *                                                                         *
     **************************************************************************/

    /**
     * Scroll events may request to scroll about a number of "lines". We first
     * decide how big one "line" is - for fixed cell size it's clear,
     * for variable cell size we settle on a single number so that the scrolling
     * speed is consistent. Now if the line is so big that
     * MIN_SCROLLING_LINES_PER_PAGE of them don't fit into one page, we make
     * them smaller to prevent the scrolling step to be too big (perhaps
     * even more than one page).
     */
    private static final int MIN_SCROLLING_LINES_PER_PAGE = 8;

    /**
     * Indicates that this is a newly created cell and we need call processCSS for it.
     *
     * See RT-23616 for more details.
     */
    private static final String NEW_CELL = "newcell";

    private static final double GOLDEN_RATIO_MULTIPLIER = 0.618033987;

    /**
     * The default improvement for the estimation of the total size. A value
     * of x means that every time we need to estimate the size, we will add
     * x new cells that are not yet available into the calculations
     */
    private static final int DEFAULT_IMPROVEMENT = 2;



    /* *************************************************************************
     *                                                                         *
     * Private fields                                                          *
     *                                                                         *
     **************************************************************************/

    private boolean touchDetected = false;
    private boolean mouseDown = false;

    /**
     * The width of the VirtualFlow the last time it was laid out. We
     * use this information for several fast paths during the layout pass.
     */
    double lastWidth = -1;

    /**
     * The height of the VirtualFlow the last time it was laid out. We
     * use this information for several fast paths during the layout pass.
     */
    double lastHeight = -1;

    /**
     * The number of "virtual" cells in the flow the last time it was laid out.
     * For example, there may have been 1000 virtual cells, but only 20 actual
     * cells created and in use. In that case, lastCellCount would be 1000.
     */
    int lastCellCount = 0;

    /**
     * We remember the last value for vertical the last time we laid out the
     * flow. If vertical has changed, we will want to change the max & value
     * for the different scroll bars. Since we do all the scroll bar update
     * work in the layoutChildren function, we need to know what the old value for
     * vertical was.
     */
    boolean lastVertical;

    /**
     * The position last time we laid out. If none of the lastXXX vars have
     * changed respective to their values in layoutChildren, then we can just punt
     * out of the method (I hope...)
     */
    double lastPosition;

    /**
     * The breadth of the first visible cell last time we laid out.
     */
    double lastCellBreadth = -1;

    /**
     * The length of the first visible cell last time we laid out.
     */
    double lastCellLength = -1;

    /**
     * The list of cells representing those cells which actually make up the
     * current view. The cells are ordered such that the first cell in this
     * list is the first in the view, and the last cell is the last in the
     * view. When pixel scrolling, the list is simply shifted and items drop
     * off the beginning or the end, depending on the order of scrolling.
     * 

* This is package private ONLY FOR TESTING */ final ArrayLinkedList cells = new ArrayLinkedList<>(); /** * A structure containing cells that can be reused later. These are cells * that at one time were needed to populate the view, but now are no longer * needed. We keep them here until they are needed again. *

* This is package private ONLY FOR TESTING */ final ArrayLinkedList pile = new ArrayLinkedList<>(); /** * A special cell used to accumulate bounds, such that we reduce object * churn. This cell must be recreated whenever the cell factory function * changes. This has package access ONLY for testing. */ T accumCell; /** * This group is used for holding the 'accumCell'. 'accumCell' must * be added to the skin for it to be styled. Otherwise, it doesn't * report the correct width/height leading to issues when scrolling * the flow */ Group accumCellParent; /** * The group which holds the cells. */ final Group sheet; final ObservableList sheetChildren; /** * The scroll bar used for scrolling horizontally. This has package access * ONLY for testing. */ private VirtualScrollBar hbar = new VirtualScrollBar(this); /** * The scroll bar used to scrolling vertically. This has package access * ONLY for testing. */ private VirtualScrollBar vbar = new VirtualScrollBar(this); /** * Control in which the cell's sheet is placed and forms the viewport. The * viewportBreadth and viewportLength are simply the dimensions of the * clipView. This has package access ONLY for testing. */ ClippedContainer clipView; /** * When both the horizontal and vertical scroll bars are visible, * we have to 'fill in' the bottom right corner where the two scroll bars * meet. This is handled by this corner region. This has package access * ONLY for testing. */ StackPane corner; /** * The offset in pixels between the top of the virtualFlow and the content it * shows. When manipulating the position of the content (e.g. by scrolling), * the absoluteOffset must be changed so that it always returns the number of * pixels that, when applied to a translateY (for vertical) or translateX * (for horizontal) operation on each cell, the first cell aligns with the * node. * The following relation should always be true: * 0 <= absoluteOffset <= (estimatedSize - viewportLength) * Based on this relation, the position p is defined as * 0 <= absoluteOffset/(estimatedSize - viewportLength) <= 1 * As a consequence, whenever p, estimatedSize, or viewportLength * changes, the absoluteOffset needs to change as well. * The method adjustAbsoluteOffset() can be used to calculate the * value of absoluteOffset based on the value of the other 3 * variables. * Vice versa, if we change the absoluteOffset, we need to make * sure that the position is changed in a consistent way. This * can be done by calling adjustPosition() */ double absoluteOffset = 0d; /** * An estimation of the total size (height for vertical, width for horizontal). * A value of -1 means that this value is unusable and should not be trusted. * This might happen before any calculations take place, or when a method * invocation is guaranteed to invalidate the current estimation. */ double estimatedSize = -1d; /** * A list containing the cached version of the calculated size (height for * vertical, width for horizontal) for a (fictive or real) cell for * each element of the backing data. * This list is used to calculate the estimatedSize. * The list is not expected to be complete, but it is always up to date. * When the size of the items in the backing list changes, this list is * cleared. */ private ArrayList itemSizeCache = new ArrayList<>(); // used for panning the virtual flow private double lastX; private double lastY; private boolean isPanning = false; private boolean fixedCellSizeEnabled = false; private boolean needsReconfigureCells = false; // when cell contents are the same private boolean needsRecreateCells = false; // when cell factory changed private boolean needsRebuildCells = false; // when cell contents have changed private boolean needsCellsLayout = false; private boolean sizeChanged = false; private final BitSet dirtyCells = new BitSet(); Timeline sbTouchTimeline; KeyFrame sbTouchKF1; KeyFrame sbTouchKF2; private boolean needBreadthBar; private boolean needLengthBar; private boolean tempVisibility = false; private boolean suppressBreadthBar; /* ************************************************************************* * * * Constructors * * * **************************************************************************/ /** * Creates a new VirtualFlow instance. */ public VirtualFlow() { getStyleClass().add("virtual-flow"); setId("virtual-flow"); // initContent // --- sheet sheet = new Group(); sheet.getStyleClass().add("sheet"); sheet.setAutoSizeChildren(false); sheetChildren = sheet.getChildren(); // --- clipView clipView = new ClippedContainer(this); clipView.setNode(sheet); getChildren().add(clipView); // --- accumCellParent accumCellParent = new Group(); accumCellParent.setVisible(false); getChildren().add(accumCellParent); /* ** don't allow the ScrollBar to handle the ScrollEvent, ** In a VirtualFlow a vertical scroll should scroll on the vertical only, ** whereas in a horizontal ScrollBar it can scroll horizontally. */ // block the event from being passed down to children final EventDispatcher blockEventDispatcher = (event, tail) -> event; // block ScrollEvent from being passed down to scrollbar's skin final EventDispatcher oldHsbEventDispatcher = hbar.getEventDispatcher(); hbar.setEventDispatcher((event, tail) -> { if (event.getEventType() == ScrollEvent.SCROLL && !((ScrollEvent)event).isDirect()) { tail = tail.prepend(blockEventDispatcher); tail = tail.prepend(oldHsbEventDispatcher); return tail.dispatchEvent(event); } return oldHsbEventDispatcher.dispatchEvent(event, tail); }); // block ScrollEvent from being passed down to scrollbar's skin final EventDispatcher oldVsbEventDispatcher = vbar.getEventDispatcher(); vbar.setEventDispatcher((event, tail) -> { if (event.getEventType() == ScrollEvent.SCROLL && !((ScrollEvent)event).isDirect()) { tail = tail.prepend(blockEventDispatcher); tail = tail.prepend(oldVsbEventDispatcher); return tail.dispatchEvent(event); } return oldVsbEventDispatcher.dispatchEvent(event, tail); }); /* ** listen for ScrollEvents over the whole of the VirtualFlow ** area, the above dispatcher having removed the ScrollBars ** scroll event handling. */ setOnScroll(new EventHandler() { @Override public void handle(ScrollEvent event) { if (Properties.IS_TOUCH_SUPPORTED) { if (touchDetected == false && mouseDown == false ) { startSBReleasedAnimation(); } } /* ** calculate the delta in the direction of the flow. */ double virtualDelta = 0.0; if (isVertical()) { switch(event.getTextDeltaYUnits()) { case PAGES: virtualDelta = event.getTextDeltaY() * lastHeight; break; case LINES: double lineSize; if (fixedCellSizeEnabled) { lineSize = getFixedCellSize(); } else { // For the scrolling to be reasonably consistent // we set the lineSize to the average size // of all currently loaded lines. T lastCell = cells.getLast(); lineSize = (getCellPosition(lastCell) + getCellLength(lastCell) - getCellPosition(cells.getFirst())) / cells.size(); } if (lastHeight / lineSize < MIN_SCROLLING_LINES_PER_PAGE) { lineSize = lastHeight / MIN_SCROLLING_LINES_PER_PAGE; } virtualDelta = event.getTextDeltaY() * lineSize; break; case NONE: virtualDelta = event.getDeltaY(); } } else { // horizontal switch(event.getTextDeltaXUnits()) { case CHARACTERS: // can we get character size here? // for now, fall through to pixel values case NONE: double dx = event.getDeltaX(); double dy = event.getDeltaY(); virtualDelta = (Math.abs(dx) > Math.abs(dy) ? dx : dy); } } if (virtualDelta != 0.0) { /* ** only consume it if we use it */ double result = scrollPixels(-virtualDelta); if (result != 0.0) { event.consume(); } } ScrollBar nonVirtualBar = isVertical() ? hbar : vbar; if (needBreadthBar) { double nonVirtualDelta = isVertical() ? event.getDeltaX() : event.getDeltaY(); if (nonVirtualDelta != 0.0) { double newValue = nonVirtualBar.getValue() - nonVirtualDelta; if (newValue < nonVirtualBar.getMin()) { nonVirtualBar.setValue(nonVirtualBar.getMin()); } else if (newValue > nonVirtualBar.getMax()) { nonVirtualBar.setValue(nonVirtualBar.getMax()); } else { nonVirtualBar.setValue(newValue); } event.consume(); } } } }); addEventFilter(MouseEvent.MOUSE_PRESSED, new EventHandler() { @Override public void handle(MouseEvent e) { mouseDown = true; if (Properties.IS_TOUCH_SUPPORTED) { scrollBarOn(); } if (isFocusTraversable()) { // We check here to see if the current focus owner is within // this VirtualFlow, and if so we back-off from requesting // focus back to the VirtualFlow itself. This is particularly // relevant given the bug identified in RT-32869. In this // particular case TextInputControl was clearing selection // when the focus on the TextField changed, meaning that the // right-click context menu was not showing the correct // options as there was no selection in the TextField. boolean doFocusRequest = true; Node focusOwner = getScene().getFocusOwner(); if (focusOwner != null) { Parent parent = focusOwner.getParent(); while (parent != null) { if (parent.equals(VirtualFlow.this)) { doFocusRequest = false; break; } parent = parent.getParent(); } } if (doFocusRequest) { requestFocus(); } } lastX = e.getX(); lastY = e.getY(); // determine whether the user has push down on the virtual flow, // or whether it is the scrollbar. This is done to prevent // mouse events being 'doubled up' when dragging the scrollbar // thumb - it has the side-effect of also starting the panning // code, leading to flicker isPanning = ! (vbar.getBoundsInParent().contains(e.getX(), e.getY()) || hbar.getBoundsInParent().contains(e.getX(), e.getY())); } }); addEventFilter(MouseEvent.MOUSE_RELEASED, e -> { mouseDown = false; if (Properties.IS_TOUCH_SUPPORTED) { startSBReleasedAnimation(); } }); addEventFilter(MouseEvent.MOUSE_DRAGGED, e -> { if (Properties.IS_TOUCH_SUPPORTED) { scrollBarOn(); } if (! isPanning || ! isPannable()) return; // With panning enabled, we support panning in both vertical // and horizontal directions, regardless of the fact that // VirtualFlow is virtual in only one direction. double xDelta = lastX - e.getX(); double yDelta = lastY - e.getY(); // figure out the distance that the mouse moved in the virtual // direction, and then perform the movement along that axis // virtualDelta will contain the amount we actually did move double virtualDelta = isVertical() ? yDelta : xDelta; double actual = scrollPixels(virtualDelta); if (actual != 0) { // update last* here, as we know we've just adjusted the // scrollbar. This means we don't get the situation where a // user presses-and-drags a long way past the min or max // values, only to change directions and see the scrollbar // start moving immediately. if (isVertical()) lastY = e.getY(); else lastX = e.getX(); } // similarly, we do the same in the non-virtual direction double nonVirtualDelta = isVertical() ? xDelta : yDelta; ScrollBar nonVirtualBar = isVertical() ? hbar : vbar; if (nonVirtualBar.isVisible()) { double newValue = nonVirtualBar.getValue() + nonVirtualDelta; if (newValue < nonVirtualBar.getMin()) { nonVirtualBar.setValue(nonVirtualBar.getMin()); } else if (newValue > nonVirtualBar.getMax()) { nonVirtualBar.setValue(nonVirtualBar.getMax()); } else { nonVirtualBar.setValue(newValue); // same as the last* comment above if (isVertical()) lastX = e.getX(); else lastY = e.getY(); } } }); /* * We place the scrollbars _above_ the rectangle, such that the drag * operations often used in conjunction with scrollbars aren't * misinterpreted as drag operations on the rectangle as well (which * would be the case if the scrollbars were underneath it as the * rectangle itself doesn't block the mouse. */ // --- vbar vbar.setOrientation(Orientation.VERTICAL); vbar.addEventHandler(MouseEvent.ANY, event -> { event.consume(); }); getChildren().add(vbar); // --- hbar hbar.setOrientation(Orientation.HORIZONTAL); hbar.addEventHandler(MouseEvent.ANY, event -> { event.consume(); }); getChildren().add(hbar); // --- corner corner = new StackPane(); corner.getStyleClass().setAll("corner"); getChildren().add(corner); // initBinds // clipView binds InvalidationListener listenerX = valueModel -> { updateHbar(); }; verticalProperty().addListener(listenerX); hbar.valueProperty().addListener(listenerX); hbar.visibleProperty().addListener(listenerX); visibleProperty().addListener(listenerX); sceneProperty().addListener(listenerX); // ChangeListener listenerY = new ChangeListener() { // @Override public void handle(Bean bean, PropertyReference property) { // clipView.setClipY(isVertical() ? 0 : vbar.getValue()); // } // }; // addChangedListener(VERTICAL, listenerY); // vbar.addChangedListener(ScrollBar.VALUE, listenerY); ChangeListener listenerY = (ov, t, t1) -> { clipView.setClipY(isVertical() ? 0 : vbar.getValue()); }; vbar.valueProperty().addListener(listenerY); super.heightProperty().addListener((observable, oldHeight, newHeight) -> { // Fix for RT-8480, where the VirtualFlow does not show its content // after changing size to 0 and back. if (oldHeight.doubleValue() == 0 && newHeight.doubleValue() > 0) { recreateCells(); } }); /* ** there are certain animations that need to know if the touch is ** happening..... */ setOnTouchPressed(e -> { touchDetected = true; scrollBarOn(); }); setOnTouchReleased(e -> { touchDetected = false; startSBReleasedAnimation(); }); ParentHelper.setTraversalEngine(this, new ParentTraversalEngine(this, new Algorithm() { Node selectNextAfterIndex(int index, TraversalContext context) { T nextCell; while ((nextCell = getVisibleCell(++index)) != null) { if (nextCell.isFocusTraversable()) { return nextCell; } Node n = context.selectFirstInParent(nextCell); if (n != null) { return n; } } return null; } Node selectPreviousBeforeIndex(int index, TraversalContext context) { T prevCell; while ((prevCell = getVisibleCell(--index)) != null) { Node prev = context.selectLastInParent(prevCell); if (prev != null) { return prev; } if (prevCell.isFocusTraversable()) { return prevCell; } } return null; } @Override public Node select(Node owner, Direction dir, TraversalContext context) { T cell; if (cells.isEmpty()) return null; if (cells.contains(owner)) { cell = (T) owner; } else { cell = findOwnerCell(owner); Node next = context.selectInSubtree(cell, owner, dir); if (next != null) { return next; } if (dir == Direction.NEXT) dir = Direction.NEXT_IN_LINE; } int cellIndex = cell.getIndex(); switch(dir) { case PREVIOUS: return selectPreviousBeforeIndex(cellIndex, context); case NEXT: Node n = context.selectFirstInParent(cell); if (n != null) { return n; } // Intentional fall-through case NEXT_IN_LINE: return selectNextAfterIndex(cellIndex, context); } return null; } private T findOwnerCell(Node owner) { Parent p = owner.getParent(); while (!cells.contains(p)) { p = p.getParent(); } return (T)p; } @Override public Node selectFirst(TraversalContext context) { T firstCell = cells.getFirst(); if (firstCell == null) return null; if (firstCell.isFocusTraversable()) return firstCell; Node n = context.selectFirstInParent(firstCell); if (n != null) { return n; } return selectNextAfterIndex(firstCell.getIndex(), context); } @Override public Node selectLast(TraversalContext context) { T lastCell = cells.getLast(); if (lastCell == null) return null; Node p = context.selectLastInParent(lastCell); if (p != null) { return p; } if (lastCell.isFocusTraversable()) return lastCell; return selectPreviousBeforeIndex(lastCell.getIndex(), context); } })); } /* ************************************************************************* * * * Properties * * * **************************************************************************/ /** * There are two main complicating factors in the implementation of the * VirtualFlow, which are made even more complicated due to the performance * sensitive nature of this code. The first factor is the actual * virtualization mechanism, wired together with the PositionMapper. * The second complicating factor is the desire to do minimal layout * and minimal updates to CSS. * * Since the layout mechanism runs at most once per pulse, we want to hook * into this mechanism for minimal recomputation. Whenever a layout pass * is run we record the width/height that the virtual flow was last laid * out to. In subsequent passes, if the width/height has not changed then * we know we only have to rebuild the cells. If the width or height has * changed, then we can make appropriate decisions based on whether the * width / height has been reduced or expanded. * * In various places, if requestLayout is called it is generally just * used to indicate that some form of layout needs to happen (either the * entire thing has to be reconstructed, or just the cells need to be * reconstructed, generally). * * The accumCell is a special cell which is used in some computations * when an actual cell for that item isn't currently available. However, * the accumCell must be cleared whenever the cellFactory function is * changed because we need to use the cells that come from the new factory. * * In addition to storing the lastWidth and lastHeight, we also store the * number of cells that existed last time we performed a layout. In this * way if the number of cells change, we can request a layout and when it * occurs we can tell that the number of cells has changed and react * accordingly. * * Because the VirtualFlow can be laid out horizontally or vertically a * naming problem is present when trying to conceptualize and implement * the flow. In particular, the words "width" and "height" are not * precise when describing the unit of measure along the "virtualized" * axis and the "orthogonal" axis. For example, the height of a cell when * the flow is vertical is the magnitude along the "virtualized axis", * and the width is along the axis orthogonal to it. * * Since "height" and "width" are not reliable terms, we use the words * "length" and "breadth" to describe the magnitude of a cell along * the virtualized axis and orthogonal axis. For example, in a vertical * flow, the height=length and the width=breadth. In a horizontal axis, * the height=breadth and the width=length. * * These terms are somewhat arbitrary, but chosen so that when reading * most of the below code you can think in just one dimension, with * helper functions converting width/height in to length/breadth, while * also being different from width/height so as not to get confused with * the actual width/height of a cell. */ // --- vertical /** * Indicates the primary direction of virtualization. If true, then the * primary direction of virtualization is vertical, meaning that cells will * stack vertically on top of each other. If false, then they will stack * horizontally next to each other. */ private BooleanProperty vertical; public final void setVertical(boolean value) { verticalProperty().set(value); } public final boolean isVertical() { return vertical == null ? true : vertical.get(); } public final BooleanProperty verticalProperty() { if (vertical == null) { vertical = new BooleanPropertyBase(true) { @Override protected void invalidated() { pile.clear(); sheetChildren.clear(); cells.clear(); lastWidth = lastHeight = -1; setMaxPrefBreadth(-1); setViewportBreadth(0); setViewportLength(0); lastPosition = 0; hbar.setValue(0); vbar.setValue(0); setPosition(0.0f); setNeedsLayout(true); requestLayout(); } @Override public Object getBean() { return VirtualFlow.this; } @Override public String getName() { return "vertical"; } }; } return vertical; } // --- pannable /** * Indicates whether the VirtualFlow viewport is capable of being panned * by the user (either via the mouse or touch events). */ private BooleanProperty pannable = new SimpleBooleanProperty(this, "pannable", true); public final boolean isPannable() { return pannable.get(); } public final void setPannable(boolean value) { pannable.set(value); } public final BooleanProperty pannableProperty() { return pannable; } // --- cell count /** * Indicates the number of cells that should be in the flow. The user of * the VirtualFlow must set this appropriately. When the cell count changes * the VirtualFlow responds by updating the visuals. If the items backing * the cells change, but the count has not changed, you must call the * reconfigureCells() function to update the visuals. */ private IntegerProperty cellCount = new SimpleIntegerProperty(this, "cellCount", 0) { private int oldCount = 0; @Override protected void invalidated() { int oldIndex = computeCurrentIndex(oldCount); double oldOffset = computeViewportOffset(getPosition(), oldCount); int cellCount = get(); if (oldIndex > cellCount) { oldIndex = cellCount; } resetSizeEstimates(); getOrCreateCellSize(oldIndex); recalculateAndImproveEstimatedSize(DEFAULT_IMPROVEMENT, oldIndex, oldOffset); boolean countChanged = oldCount != cellCount; double boff = computeBaseOffset(oldIndex); absoluteOffset = boff + oldOffset; oldCount = cellCount; // ensure that the virtual scrollbar adjusts in size based on the current // cell count. if (countChanged) { VirtualScrollBar lengthBar = isVertical() ? vbar : hbar; lengthBar.setMax(cellCount); } // I decided *not* to reset maxPrefBreadth here for the following // situation. Suppose I have 30 cells and then I add 10 more. Just // because I added 10 more doesn't mean the max pref should be // reset. Suppose the first 3 cells were extra long, and I was // scrolled down such that they weren't visible. If I were to reset // maxPrefBreadth when subsequent cells were added or removed, then the // scroll bars would erroneously reset as well. So I do not reset // the maxPrefBreadth here. // Fix for RT-12512, RT-14301 and RT-14864. // Without this, the VirtualFlow length-wise scrollbar would not change // as expected. This would leave items unable to be shown, as they // would exist outside of the visible area, even when the scrollbar // was at its maximum position. // FIXME this should be only executed on the pulse, so this will likely // lead to performance degradation until it is handled properly. if (countChanged) { layoutChildren(); Parent parent = getParent(); if (parent != null) parent.requestLayout(); adjustAbsoluteOffset(); } // TODO suppose I had 100 cells and I added 100 more. Further // suppose I was scrolled to the bottom when that happened. I // actually want to update the position of the mapper such that // the view remains "stable". } }; public final int getCellCount() { return cellCount.get(); } public final void setCellCount(int value) { cellCount.set(value); } public final IntegerProperty cellCountProperty() { return cellCount; } // --- position /** * The position of the VirtualFlow within its list of cells. This is a value * between 0 and 1. */ private DoubleProperty position = new SimpleDoubleProperty(this, "position") { @Override public void setValue(Number v) { super.setValue(com.sun.javafx.util.Utils.clamp(0, get(), 1)); } @Override protected void invalidated() { super.invalidated(); adjustAbsoluteOffset(); requestLayout(); } }; public final double getPosition() { return position.get(); } public final void setPosition(double value) { position.set(value); } public final DoubleProperty positionProperty() { return position; } // --- fixed cell size /** * For optimisation purposes, some use cases can trade dynamic cell length * for speed - if fixedCellSize is greater than zero we'll use that rather * than determine it by querying the cell itself. */ private DoubleProperty fixedCellSize = new SimpleDoubleProperty(this, "fixedCellSize") { @Override protected void invalidated() { fixedCellSizeEnabled = get() > 0; needsCellsLayout = true; layoutChildren(); } }; public final void setFixedCellSize(final double value) { fixedCellSize.set(value); } public final double getFixedCellSize() { return fixedCellSize.get(); } public final DoubleProperty fixedCellSizeProperty() { return fixedCellSize; } // --- Cell Factory private ObjectProperty, T>> cellFactory; /** * Sets a new cell factory to use in the VirtualFlow. This forces all old * cells to be thrown away, and new cells to be created with * the new cell factory. * @param value the new cell factory */ public final void setCellFactory(Callback, T> value) { cellFactoryProperty().set(value); } /** * Returns the current cell factory. * @return the current cell factory */ public final Callback, T> getCellFactory() { return cellFactory == null ? null : cellFactory.get(); } /** *

Setting a custom cell factory has the effect of deferring all cell * creation, allowing for total customization of the cell. Internally, the * VirtualFlow is responsible for reusing cells - all that is necessary * is for the custom cell factory to return from this function a cell * which might be usable for representing any item in the VirtualFlow. * *

Refer to the {@link Cell} class documentation for more detail. * @return the cell factory property */ public final ObjectProperty, T>> cellFactoryProperty() { if (cellFactory == null) { cellFactory = new SimpleObjectProperty<>(this, "cellFactory") { @Override protected void invalidated() { if (get() != null) { setNeedsLayout(true); recreateCells(); if (getParent() != null) getParent().requestLayout(); } if (accumCellParent != null) { accumCellParent.getChildren().clear(); } accumCell = null; } }; } return cellFactory; } /* ************************************************************************* * * * Public API * * * **************************************************************************/ /** * Overridden to implement somewhat more efficient support for layout. The * VirtualFlow can generally be considered as being unmanaged, in that * whenever the position changes, or other such things change, we need * to perform a layout but there is no reason to notify the parent. However * when things change which may impact the preferred size (such as * vertical, createCell, and configCell) then we need to notify the * parent. */ @Override public void requestLayout() { // Note: This block is commented as it was relaying on a bad assumption on how // layout request was handled in parent class that is now fixed. // // // isNeedsLayout() is commented out due to RT-21417. This does not // // appear to impact performance (indeed, it may help), and resolves the // // issue identified in RT-21417. // setNeedsLayout(true); // The fix is to prograte this layout request to its parent class. // A better fix will be required if performance is negatively affected // by this fix. super.requestLayout(); } /** * Keep the position constant and adjust the absoluteOffset to * match the (new) position. */ void adjustAbsoluteOffset() { absoluteOffset = (estimatedSize - viewportLength) * getPosition(); } /** * Keep the absoluteOffset constant and adjust the position to match * the (new) absoluteOffset. */ void adjustPosition() { if (viewportLength >= estimatedSize) { setPosition(0.); } else { setPosition(absoluteOffset / (estimatedSize - viewportLength)); } } /** {@inheritDoc} */ @Override protected void layoutChildren() { // when we enter this method, the absoluteOffset and position are // already determined. In case this method invokes other methods // that may change either absoluteOffset or position, it is the // responsability of those methods to make sure both parameters are // changed in a consistent way. // For example, the recalculateEstimatedSize method also recalculates // the absoluteOffset and position. if (needsRecreateCells) { lastWidth = -1; lastHeight = -1; releaseCell(accumCell); sheet.getChildren().clear(); for (int i = 0, max = cells.size(); i < max; i++) { cells.get(i).updateIndex(-1); } cells.clear(); pile.clear(); releaseAllPrivateCells(); } else if (needsRebuildCells) { lastWidth = -1; lastHeight = -1; releaseCell(accumCell); for (int i = 0, max = cells.size(); i < max; i++) { cells.get(i).updateIndex(-1); } addAllToPile(); releaseAllPrivateCells(); } else if (needsReconfigureCells) { setMaxPrefBreadth(-1); lastWidth = -1; lastHeight = -1; } if (! dirtyCells.isEmpty()) { int index; final int cellsSize = cells.size(); while ((index = dirtyCells.nextSetBit(0)) != -1 && index < cellsSize) { T cell = cells.get(index); // updateIndex(-1) works for TableView, but breaks ListView. // For now, the TableView just does not use the dirtyCells API // cell.updateIndex(-1); if (cell != null) { cell.requestLayout(); } dirtyCells.clear(index); } setMaxPrefBreadth(-1); lastWidth = -1; lastHeight = -1; } final boolean hasSizeChange = sizeChanged; boolean recreatedOrRebuilt = needsRebuildCells || needsRecreateCells || sizeChanged; needsRecreateCells = false; needsReconfigureCells = false; needsRebuildCells = false; sizeChanged = false; if (needsCellsLayout) { for (int i = 0, max = cells.size(); i < max; i++) { T cell = cells.get(i); if (cell != null) { cell.requestLayout(); } } needsCellsLayout = false; // yes, we return here - if needsCellsLayout was set to true, we // only did it to do the above - not rerun the entire layout. return; } final double width = getWidth(); final double height = getHeight(); final boolean isVertical = isVertical(); final double position = getPosition(); // if the width and/or height is 0, then there is no point doing // any of this work. In particular, this can happen during startup if (width <= 0 || height <= 0) { addAllToPile(); lastWidth = width; lastHeight = height; hbar.setVisible(false); vbar.setVisible(false); corner.setVisible(false); return; } // we check if any of the cells in the cells list need layout. This is a // sign that they are perhaps animating their sizes. Without this check, // we may not perform a layout here, meaning that the cell will likely // 'jump' (in height normally) when the user drags the virtual thumb as // that is the first time the layout would occur otherwise. boolean cellNeedsLayout = false; boolean thumbNeedsLayout = false; if (Properties.IS_TOUCH_SUPPORTED) { if ((tempVisibility == true && (hbar.isVisible() == false || vbar.isVisible() == false)) || (tempVisibility == false && (hbar.isVisible() == true || vbar.isVisible() == true))) { thumbNeedsLayout = true; } } if (!cellNeedsLayout) { for (int i = 0; i < cells.size(); i++) { T cell = cells.get(i); cellNeedsLayout = cell.isNeedsLayout(); if (cellNeedsLayout) break; } } final int cellCount = getCellCount(); final T firstCell = getFirstVisibleCell(); // If no cells need layout, we check other criteria to see if this // layout call is even necessary. If it is found that no layout is // needed, we just punt. if (! cellNeedsLayout && !thumbNeedsLayout) { boolean cellSizeChanged = false; if (firstCell != null) { double breadth = getCellBreadth(firstCell); double length = getCellLength(firstCell); cellSizeChanged = (breadth != lastCellBreadth) || (length != lastCellLength); lastCellBreadth = breadth; lastCellLength = length; } if (width == lastWidth && height == lastHeight && cellCount == lastCellCount && isVertical == lastVertical && position == lastPosition && ! cellSizeChanged) { // TODO this happens to work around the problem tested by // testCellLayout_LayoutWithoutChangingThingsUsesCellsInSameOrderAsBefore // but isn't a proper solution. Really what we need to do is, when // laying out cells, we need to make sure that if a cell is pressed // AND we are doing a full rebuild then we need to make sure we // use that cell in the same physical location as before so that // it gets the mouse release event. return; } } /* * This function may get called under a variety of circumstances. * It will determine what has changed from the last time it was laid * out, and will then take one of several execution paths based on * what has changed so as to perform minimal layout work and also to * give the expected behavior. One or more of the following may have * happened: * * 1) width/height has changed * - If the width and/or height has been reduced (but neither of * them has been expanded), then we simply have to reposition and * resize the scroll bars * - If the width (in the vertical case) has expanded, then we * need to resize the existing cells and reposition and resize * the scroll bars * - If the height (in the vertical case) has expanded, then we * need to resize and reposition the scroll bars and add * any trailing cells * * 2) cell count has changed * - If the number of cells is bigger, or it is smaller but not * so small as to move the position then we can just update the * cells in place without performing layout and update the * scroll bars. * - If the number of cells has been reduced and it affects the * position, then move the position and rebuild all the cells * and update the scroll bars * * 3) size of the cell has changed * - If the size changed in the virtual direction (ie: height * in the case of vertical) then layout the cells, adding * trailing cells as necessary and updating the scroll bars * - If the size changed in the non virtual direction (ie: width * in the case of vertical) then simply adjust the widths of * the cells as appropriate and adjust the scroll bars * * 4) vertical changed, cells is empty, maxPrefBreadth == -1, etc * - Full rebuild. * * Each of the conditions really resolves to several of a handful of * possible outcomes: * a) reposition & rebuild scroll bars * b) resize cells in non-virtual direction * c) add trailing cells * d) update cells * e) resize cells in the virtual direction * f) all of the above * * So this function first determines what outcomes need to occur, and * then will execute all the ones that really need to happen. Every code * path ends up touching the "reposition & rebuild scroll bars" outcome, * so that one will be executed every time. */ boolean needTrailingCells = false; boolean rebuild = cellNeedsLayout || isVertical != lastVertical || cells.isEmpty() || getMaxPrefBreadth() == -1 || position != lastPosition || cellCount != lastCellCount || hasSizeChange || (isVertical && height < lastHeight) || (! isVertical && width < lastWidth); if (!rebuild) { // Check if maxPrefBreadth didn't change double maxPrefBreadth = getMaxPrefBreadth(); boolean foundMax = false; for (int i = 0; i < cells.size(); ++i) { double breadth = getCellBreadth(cells.get(i)); if (maxPrefBreadth == breadth) { foundMax = true; } else if (breadth > maxPrefBreadth) { rebuild = true; break; } } if (!foundMax) { // All values were lower rebuild = true; } } if (! rebuild) { if ((isVertical && height > lastHeight) || (! isVertical && width > lastWidth)) { // resized in the virtual direction needTrailingCells = true; } } initViewport(); // Get the index of the "current" cell int currentIndex = computeCurrentIndex(); if (lastCellCount != cellCount) { // The cell count has changed. We want to keep the viewport // stable if possible. If position was 0 or 1, we want to keep // the position in the same place. If the new cell count is >= // the currentIndex, then we will adjust the position to be 1. // Otherwise, our goal is to leave the index of the cell at the // top consistent, with the same translation etc. if (position != 0 && position != 1 && (currentIndex >= cellCount)) { setPosition(1.0f); } // Update the current index currentIndex = computeCurrentIndex(); } if (rebuild) { setMaxPrefBreadth(-1); // Start by dumping all the cells into the pile addAllToPile(); // The distance from the top of the viewport to the top of the // cell for the current index. double offset = -computeViewportOffset(getPosition()); // Add all the leading and trailing cells (the call to add leading // cells will add the current cell as well -- that is, the one that // represents the current position on the mapper). addLeadingCells(currentIndex, offset); // Force filling of space with empty cells if necessary addTrailingCells(true); } else if (needTrailingCells) { addTrailingCells(true); } computeBarVisiblity(); recalculateAndImproveEstimatedSize(0); recreatedOrRebuilt = recreatedOrRebuilt || rebuild; updateScrollBarsAndCells(recreatedOrRebuilt); lastWidth = getWidth(); lastHeight = getHeight(); lastCellCount = getCellCount(); lastVertical = isVertical(); lastPosition = getPosition(); recalculateEstimatedSize(); cleanPile(); } /** {@inheritDoc} */ @Override protected void setWidth(double value) { if (value != lastWidth) { super.setWidth(value); sizeChanged = true; setNeedsLayout(true); requestLayout(); } } /** {@inheritDoc} */ @Override protected void setHeight(double value) { if (value != lastHeight) { super.setHeight(value); sizeChanged = true; setNeedsLayout(true); requestLayout(); } } /** * Get a cell which can be used in the layout. This function will reuse * cells from the pile where possible, and will create new cells when * necessary. * @param prefIndex the preferred index * @return the available cell */ protected T getAvailableCell(int prefIndex) { T cell = null; // Fix for RT-12822. We try to retrieve the cell from the pile rather // than just grab a random cell from the pile (or create another cell). for (int i = 0, max = pile.size(); i < max; i++) { T _cell = pile.get(i); assert _cell != null; if (getCellIndex(_cell) == prefIndex) { cell = _cell; pile.remove(i); break; } } if (cell == null && !pile.isEmpty()) { cell = pile.removeLast(); } if (cell == null) { cell = getCellFactory().call(this); cell.getProperties().put(NEW_CELL, null); } if (cell.getParent() == null) { sheetChildren.add(cell); } return cell; } /** * This method will remove all cells from the VirtualFlow and remove them, * adding them to the 'pile' (that is, a place from where cells can be used * at a later date). This method is protected to allow subclasses to clean up * appropriately. */ protected void addAllToPile() { for (int i = 0, max = cells.size(); i < max; i++) { addToPile(cells.removeFirst()); } } /** * Gets a cell for the given index if the cell has been created and laid out. * "Visible" is a bit of a misnomer, the cell might not be visible in the * viewport (it may be clipped), but does distinguish between cells that * have been created and are in use vs. those that are in the pile or * not created. * @param index the index * @return the visible cell */ public T getVisibleCell(int index) { if (cells.isEmpty()) return null; // check the last index T lastCell = cells.getLast(); int lastIndex = getCellIndex(lastCell); if (index == lastIndex) return lastCell; // check the first index T firstCell = cells.getFirst(); int firstIndex = getCellIndex(firstCell); if (index == firstIndex) return firstCell; // if index is > firstIndex and < lastIndex then we can get the index if (index > firstIndex && index < lastIndex) { T cell = cells.get(index - firstIndex); if (getCellIndex(cell) == index) return cell; } // there is no visible cell for the specified index return null; } /** * Locates and returns the last non-empty IndexedCell that is currently * partially or completely visible. This function may return null if there * are no cells, or if the viewport length is 0. * @return the last visible cell */ public T getLastVisibleCell() { if (cells.isEmpty() || getViewportLength() <= 0) return null; T cell; for (int i = cells.size() - 1; i >= 0; i--) { cell = cells.get(i); if (! cell.isEmpty()) { return cell; } } return null; } /** * Locates and returns the first non-empty IndexedCell that is partially or * completely visible. This really only ever returns null if there are no * cells or the viewport length is 0. * @return the first visible cell */ public T getFirstVisibleCell() { if (cells.isEmpty() || getViewportLength() <= 0) return null; T cell = cells.getFirst(); return cell.isEmpty() ? null : cell; } /** * Adjust the position of cells so that the specified cell * will be positioned at the start of the viewport. The given cell must * already be "live". * @param firstCell the first cell */ public void scrollToTop(T firstCell) { if (firstCell != null) { scrollPixels(getCellPosition(firstCell)); } } /** * Adjust the position of cells so that the specified cell * will be positioned at the end of the viewport. The given cell must * already be "live". * @param lastCell the last cell */ public void scrollToBottom(T lastCell) { if (lastCell != null) { scrollPixels(getCellPosition(lastCell) + getCellLength(lastCell) - getViewportLength()); } } /** * Adjusts the cells such that the selected cell will be fully visible in * the viewport (but only just). * @param cell the cell */ public void scrollTo(T cell) { if (cell != null) { final double start = getCellPosition(cell); final double length = getCellLength(cell); final double end = start + length; final double viewportLength = getViewportLength(); if (start < 0) { scrollPixels(start); } else if (end > viewportLength) { scrollPixels(end - viewportLength); } } } /** * Adjusts the cells such that the cell in the given index will be fully visible in * the viewport. * @param index the index */ public void scrollTo(int index) { T cell = getVisibleCell(index); if (cell != null) { scrollTo(cell); } else { // see JDK-8197536 if (tryScrollOneCell(index, true)) { return; } else if (tryScrollOneCell(index, false)) { return; } adjustPositionToIndex(index); addAllToPile(); requestLayout(); } } // will return true if scroll is successful private boolean tryScrollOneCell(int targetIndex, boolean downOrRight) { // if going down, cell diff is -1, because it will get the target cell index and check if previous // cell is visible to base the position int indexDiff = downOrRight ? -1 : 1; T targetCell = getVisibleCell(targetIndex + indexDiff); if (targetCell != null) { T cell = getAvailableCell(targetIndex); setCellIndex(cell, targetIndex); resizeCell(cell); setMaxPrefBreadth(Math.max(getMaxPrefBreadth(), getCellBreadth(cell))); cell.setVisible(true); if (downOrRight) { cells.addLast(cell); scrollPixels(getCellLength(cell)); } else { // up or left cells.addFirst(cell); scrollPixels(-getCellLength(cell)); } return true; } return false; } /** * Adjusts the cells such that the cell in the given index will be fully visible in * the viewport, and positioned at the very top of the viewport. * @param index the index */ public void scrollToTop(int index) { // make sure we have the real size of cells that are likely to be rendered getCellSizesInExpectedViewport(index); boolean posSet = false; if (index > getCellCount() - 1) { setPosition(1); posSet = true; } else if (index < 0) { setPosition(0); posSet = true; } if (! posSet) { adjustPositionToIndex(index); } requestLayout(); } // //TODO We assume all the cell have the same length. We will need to support // // cells of different lengths. // public void scrollToOffset(int offset) { // scrollPixels(offset * getCellLength(0)); // } /** * Given a delta value representing a number of pixels, this method attempts * to move the VirtualFlow in the given direction (positive is down/right, * negative is up/left) the given number of pixels. It returns the number of * pixels actually moved. * @param delta the delta value * @return the number of pixels actually moved */ public double scrollPixels(final double delta) { int oldIndex = computeCurrentIndex(); // Short cut this method for cases where nothing should be done if (delta == 0) return 0; final boolean isVertical = isVertical(); if (((isVertical && (tempVisibility ? !needLengthBar : !vbar.isVisible())) || (! isVertical && (tempVisibility ? !needLengthBar : !hbar.isVisible())))) return 0; double pos = getPosition(); if (pos == 0.0f && delta < 0) return 0; if (pos == 1.0f && delta > 0) return 0; getCellSizesInExpectedViewport(oldIndex); recalculateEstimatedSize(); double answer = adjustByPixelAmount(delta); if (pos == getPosition()) { // The pos hasn't changed, there's nothing to do. This is likely // to occur when we hit either extremity return 0; } // Now move stuff around. Translating by pixels fundamentally means // moving the cells by the delta. However, after having // done that, we need to go through the cells and see which cells, // after adding in the translation factor, now fall off the viewport. // Also, we need to add cells as appropriate to the end (or beginning, // depending on the direction of travel). // // One simplifying assumption (that had better be true!) is that we // will only make it this far in the function if the virtual scroll // bar is visible. Otherwise, we never will pixel scroll. So as we go, // if we find that the maxPrefBreadth exceeds the viewportBreadth, // then we will be sure to show the breadthBar and update it // accordingly. if (cells.size() > 0) { for (int i = 0; i < cells.size(); i++) { T cell = cells.get(i); assert cell != null; positionCell(cell, getCellPosition(cell) - delta); } // Fix for RT-32908 T firstCell = cells.getFirst(); double layoutY = firstCell == null ? 0 : getCellPosition(firstCell); for (int i = 0; i < cells.size(); i++) { T cell = cells.get(i); assert cell != null; double actualLayoutY = getCellPosition(cell); if (Math.abs(actualLayoutY - layoutY) > 0.001) { // we need to shift the cell to layoutY positionCell(cell, layoutY); } layoutY += getCellLength(cell); } // end of fix for RT-32908 cull(); firstCell = cells.getFirst(); // Add any necessary leading cells if (firstCell != null) { int firstIndex = getCellIndex(firstCell); double prevIndexSize = getCellLength(firstIndex - 1); addLeadingCells(firstIndex - 1, getCellPosition(firstCell) - prevIndexSize); } else { int currentIndex = computeCurrentIndex(); // The distance from the top of the viewport to the top of the // cell for the current index. double offset = -computeViewportOffset(getPosition()); // Add all the leading and trailing cells (the call to add leading // cells will add the current cell as well -- that is, the one that // represents the current position on the mapper). addLeadingCells(currentIndex, offset); } // Starting at the tail of the list, loop adding cells until // all the space on the table is filled up. We want to make // sure that we DO NOT add empty trailing cells (since we are // in the full virtual case and so there are no trailing empty // cells). if (! addTrailingCells(false)) { // Reached the end, but not enough cells to fill up to // the end. So, remove the trailing empty space, and translate // the cells down final T lastCell = getLastVisibleCell(); final double lastCellSize = getCellLength(lastCell); final double cellEnd = getCellPosition(lastCell) + lastCellSize; final double viewportLength = getViewportLength(); if (cellEnd < viewportLength) { // Reposition the nodes double emptySize = viewportLength - cellEnd; for (int i = 0; i < cells.size(); i++) { T cell = cells.get(i); positionCell(cell, getCellPosition(cell) + emptySize); } setPosition(1.0f); // fill the leading empty space firstCell = cells.getFirst(); int firstIndex = getCellIndex(firstCell); double prevIndexSize = getCellLength(firstIndex - 1); addLeadingCells(firstIndex - 1, getCellPosition(firstCell) - prevIndexSize); } } } // Now throw away any cells that don't fit cull(); // Finally, update the scroll bars updateScrollBarsAndCells(false); // notify return answer; } /** {@inheritDoc} */ @Override protected double computePrefWidth(double height) { double w = isVertical() ? getPrefBreadth(height) : getPrefLength(); return w + vbar.prefWidth(-1); } /** {@inheritDoc} */ @Override protected double computePrefHeight(double width) { double h = isVertical() ? getPrefLength() : getPrefBreadth(width); return h + hbar.prefHeight(-1); } /** * Return a cell for the given index. This may be called for any cell, * including beyond the range defined by cellCount, in which case an * empty cell will be returned. The returned value should not be stored for * any reason. * @param index the index * @return the cell */ public T getCell(int index) { // If there are cells, then we will attempt to get an existing cell if (! cells.isEmpty()) { // First check the cells that have already been created and are // in use. If this call returns a value, then we can use it T cell = getVisibleCell(index); if (cell != null) return cell; } // check the pile for (int i = 0; i < pile.size(); i++) { T cell = pile.get(i); if (getCellIndex(cell) == index) { // Note that we don't remove from the pile: if we do it leads // to a severe performance decrease. This seems to be OK, as // getCell() is only used for cell measurement purposes. // pile.remove(i); resizeCell(cell); return cell; } } // We need to use the accumCell and return that if (accumCell == null) { Callback,T> cellFactory = getCellFactory(); if (cellFactory != null) { accumCell = cellFactory.call(this); accumCell.getProperties().put(NEW_CELL, null); accumCellParent.getChildren().setAll(accumCell); // Note the screen reader will attempt to find all // the items inside the view to calculate the item count. // Having items under different parents (sheet and accumCellParent) // leads the screen reader to compute wrong values. // The regular scheme to provide items to the screen reader // uses getPrivateCell(), which places the item in the sheet. // The accumCell, and its children, should be ignored by the // screen reader. accumCell.setAccessibleRole(AccessibleRole.NODE); accumCell.getChildrenUnmodifiable().addListener((Observable c) -> { for (Node n : accumCell.getChildrenUnmodifiable()) { n.setAccessibleRole(AccessibleRole.NODE); } }); } } setCellIndex(accumCell, index); resizeCell(accumCell); return accumCell; } /** * The VirtualFlow uses this method to set a cells index (rather than calling * {@link IndexedCell#updateIndex(int)} directly), so it is a perfect place * for subclasses to override if this if of interest. * * @param cell The cell whose index will be updated. * @param index The new index for the cell. */ protected void setCellIndex(T cell, int index) { assert cell != null; cell.updateIndex(index); // make sure the cell is sized correctly. This is important for both // general layout of cells in a VirtualFlow, but also in cases such as // RT-34333, where the sizes were being reported incorrectly to the // ComboBox popup. if ((cell.isNeedsLayout() && cell.getScene() != null) || cell.getProperties().containsKey(NEW_CELL)) { cell.applyCss(); cell.getProperties().remove(NEW_CELL); } } /** * Return the index for a given cell. This allows subclasses to customise * how cell indices are retrieved. * @param cell the cell * @return the index */ protected int getCellIndex(T cell){ return cell.getIndex(); } /* ************************************************************************* * * * Private implementation * * * **************************************************************************/ /** * Returns the scroll bar used for scrolling horizontally. A developer who needs to be notified when a scroll is * happening could attach a listener to the {@link ScrollBar#valueProperty()}. * * @return the scroll bar used for scrolling horizontally * @since 12 */ protected final ScrollBar getHbar() { return hbar; } /** * Returns the scroll bar used for scrolling vertically. A developer who needs to be notified when a scroll is * happening could attach a listener to the {@link ScrollBar#valueProperty()}. The {@link ScrollBar#getWidth()} is * also useful when adding a component over the {@code TableView} in order to clip it so that it doesn't overlap the * {@code ScrollBar}. * * @return the scroll bar used for scrolling vertically * @since 12 */ protected final ScrollBar getVbar() { return vbar; } /** * The maximum preferred size in the non-virtual direction. For example, * if vertical, then this is the max pref width of all cells encountered. *

* In general, this is the largest preferred size in the non-virtual * direction that we have ever encountered. We don't reduce this size * unless instructed to do so, so as to reduce the amount of scroll bar * jitter. The access on this variable is package ONLY FOR TESTING. */ private double maxPrefBreadth; private final void setMaxPrefBreadth(double value) { this.maxPrefBreadth = value; } final double getMaxPrefBreadth() { return maxPrefBreadth; } /** * The breadth of the viewport portion of the VirtualFlow as computed during * the layout pass. In a vertical flow this would be the same as the clip * view width. In a horizontal flow this is the clip view height. * The access on this variable is package ONLY FOR TESTING. */ private double viewportBreadth; private final void setViewportBreadth(double value) { this.viewportBreadth = value; } private final double getViewportBreadth() { return viewportBreadth; } /** * The length of the viewport portion of the VirtualFlow as computed * during the layout pass. In a vertical flow this would be the same as the * clip view height. In a horizontal flow this is the clip view width. * The access on this variable is package ONLY FOR TESTING. */ private double viewportLength; void setViewportLength(double value) { if (value == this.viewportLength) { return; } this.viewportLength = value; this.absoluteOffset = getPosition() * (estimatedSize - viewportLength); recalculateEstimatedSize(); } double getViewportLength() { return viewportLength; } /** * Compute and return the length of the cell for the given index. This is * called both internally when adjusting by pixels, and also at times * by PositionMapper (see the getItemSize callback). When called by * PositionMapper, it is possible that it will be called for some index * which is not associated with any cell, so we have to do a bit of work * to use a cell as a helper for computing cell size in some cases. */ double getCellLength(int index) { if (fixedCellSizeEnabled) return getFixedCellSize(); T cell = getCell(index); double length = getCellLength(cell); releaseCell(cell); return length; } /** */ double getCellBreadth(int index) { T cell = getCell(index); double b = getCellBreadth(cell); releaseCell(cell); return b; } /** * Gets the length of a specific cell */ double getCellLength(T cell) { if (cell == null) return 0; if (fixedCellSizeEnabled) return getFixedCellSize(); return isVertical() ? cell.getLayoutBounds().getHeight() : cell.getLayoutBounds().getWidth(); } /** * Gets the breadth of a specific cell */ double getCellBreadth(T cell) { return isVertical() ? cell.prefWidth(-1) : cell.prefHeight(-1); } /** * Gets the layout position of the cell along the length axis */ double getCellPosition(T cell) { if (cell == null) return 0; return isVertical() ? cell.getLayoutY() : cell.getLayoutX(); } private void positionCell(T cell, double position) { updateCellSize(cell); if (isVertical()) { cell.setLayoutX(0); cell.setLayoutY(snapSpaceY(position)); } else { cell.setLayoutX(snapSpaceX(position)); cell.setLayoutY(0); } } /** * Resizes the given cell. If {@link #isVertical()} is set to {@code true}, the cell width will be the maximum * between the viewport width and the sum of all the cells' {@code prefWidth}. The cell height will be computed by * the cell itself unless {@code fixedCellSizeEnabled} is set to {@code true}, then {@link #getFixedCellSize()} is * used. If {@link #isVertical()} is set to {@code false}, the width and height calculations are reversed. * * @param cell the cell to resize * @since 12 */ protected void resizeCell(T cell) { if (cell == null) return; double size = Math.max(getMaxPrefBreadth(), getViewportBreadth()); if (isVertical()) { cell.resize(size, fixedCellSizeEnabled ? getFixedCellSize() : Utils.boundedSize(cell.prefHeight(size), cell.minHeight(size), cell.maxHeight(size))); } else { cell.resize(fixedCellSizeEnabled ? getFixedCellSize() : Utils.boundedSize(cell.prefWidth(size), cell.minWidth(size), cell.maxWidth(size)), size); } } /** * Returns the list of cells displayed in the current viewport. *

* The cells are ordered such that the first cell in this list is the first in the view, and the last cell is the * last in the view. When pixel scrolling, the list is simply shifted and items drop off the beginning or the end, * depending on the order of scrolling. * * @return the cells displayed in the current viewport * @since 12 */ protected List getCells() { return cells; } /** * Returns the last visible cell whose bounds are entirely within the viewport. When manually inserting rows, one * may need to know which cell indices are visible in the viewport. * * @return last visible cell whose bounds are entirely within the viewport * @since 12 */ protected T getLastVisibleCellWithinViewport() { if (cells.isEmpty() || getViewportLength() <= 0) return null; T cell; final double max = getViewportLength(); for (int i = cells.size() - 1; i >= 0; i--) { cell = cells.get(i); if (cell.isEmpty()) continue; final double cellStart = getCellPosition(cell); final double cellEnd = cellStart + getCellLength(cell); // we use the magic +2 to allow for a little bit of fuzziness, // this is to help in situations such as RT-34407 if (cellEnd <= (max + 2)) { return cell; } } return null; } /** * Returns the first visible cell whose bounds are entirely within the viewport. When manually inserting rows, one * may need to know which cell indices are visible in the viewport. * * @return first visible cell whose bounds are entirely within the viewport * @since 12 */ protected T getFirstVisibleCellWithinViewport() { if (cells.isEmpty() || getViewportLength() <= 0) return null; T cell; for (int i = 0; i < cells.size(); i++) { cell = cells.get(i); if (cell.isEmpty()) continue; final double cellStart = getCellPosition(cell); if (cellStart >= 0) { return cell; } } return null; } /** * Adds all the cells prior to and including the given currentIndex, until * no more can be added without falling off the flow. The startOffset * indicates the distance from the leading edge (top) of the viewport to * the leading edge (top) of the currentIndex. */ void addLeadingCells(int currentIndex, double startOffset) { // The offset will keep track of the distance from the top of the // viewport to the top of the current index. We will decrement it // as we lay out leading cells. double offset = startOffset; // The index is the absolute index of the cell being laid out int index = currentIndex; // Offset should really be the bottom of the current index boolean first = true; // first time in, we just fudge the offset and let // it be the top of the current index then redefine // it as the bottom of the current index thereafter // while we have not yet laid out so many cells that they would fall // off the flow, we will continue to create and add cells. The // offset is our indication of whether we can lay out additional // cells. If the offset is ever < 0, except in the case of the very // first cell, then we must quit. T cell = null; // special case for the position == 1.0, skip adding last invisible cell if (index == getCellCount() && offset == getViewportLength()) { index--; first = false; } while (index >= 0 && (offset > 0 || first)) { cell = getAvailableCell(index); setCellIndex(cell, index); resizeCell(cell); // resize must be after config cells.addFirst(cell); // A little gross but better than alternatives because it reduces // the number of times we have to update a cell or compute its // size. The first time into this loop "offset" is actually the // top of the current index. On all subsequent visits, it is the // bottom of the current index. if (first) { first = false; } else { offset -= getCellLength(cell); } // Position the cell, and update the maxPrefBreadth variable as we go. positionCell(cell, offset); setMaxPrefBreadth(Math.max(getMaxPrefBreadth(), getCellBreadth(cell))); cell.setVisible(true); --index; } // There are times when after laying out the cells we discover that // the top of the first cell which represents index 0 is below the top // of the viewport. In these cases, we have to adjust the cells up // and reset the mapper position. This might happen when items got // removed at the top or when the viewport size increased. if (cells.size() > 0) { cell = cells.getFirst(); int firstIndex = getCellIndex(cell); double firstCellPos = getCellPosition(cell); if (firstIndex == 0 && firstCellPos > 0) { setPosition(0.0f); offset = 0; for (int i = 0; i < cells.size(); i++) { cell = cells.get(i); positionCell(cell, offset); offset += getCellLength(cell); } } } else { // reset scrollbar to top, so if the flow sees cells again it starts at the top vbar.setValue(0); hbar.setValue(0); } } /** * Adds all the trailing cells that come after the last index in * the cells ObservableList. */ boolean addTrailingCells(boolean fillEmptyCells) { // If cells is empty then addLeadingCells bailed for some reason and // we're hosed, so just punt if (cells.isEmpty()) return false; // While we have not yet laid out so many cells that they would fall // off the flow, so we will continue to create and add cells. When the // offset becomes greater than the width/height of the flow, then we // know we cannot add any more cells. T startCell = cells.getLast(); double offset = getCellPosition(startCell) + getCellLength(startCell); int index = getCellIndex(startCell) + 1; final int cellCount = getCellCount(); boolean filledWithNonEmpty = index <= cellCount; final double viewportLength = getViewportLength(); // Fix for RT-37421, which was a regression caused by RT-36556 if (offset < 0 && !fillEmptyCells) { return false; } // // RT-36507: viewportLength gives the maximum number of // additional cells that should ever be able to fit in the viewport if // every cell had a height of 1. If index ever exceeds this count, // then offset is not incrementing fast enough, or at all, which means // there is something wrong with the cell size calculation. // final double maxCellCount = viewportLength; while (offset < viewportLength) { if (index >= cellCount) { if (offset < viewportLength) filledWithNonEmpty = false; if (! fillEmptyCells) return filledWithNonEmpty; // RT-36507 - return if we've exceeded the maximum if (index > maxCellCount) { final PlatformLogger logger = Logging.getControlsLogger(); if (logger.isLoggable(PlatformLogger.Level.INFO)) { logger.info("index exceeds maxCellCount. Check size calculations for " + startCell.getClass()); } return filledWithNonEmpty; } } T cell = getAvailableCell(index); setCellIndex(cell, index); resizeCell(cell); // resize happens after config! cells.addLast(cell); // Position the cell and update the max pref positionCell(cell, offset); setMaxPrefBreadth(Math.max(getMaxPrefBreadth(), getCellBreadth(cell))); offset += getCellLength(cell); cell.setVisible(true); ++index; } // Discover whether the first cell coincides with index #0. If after // adding all the trailing cells we find that a) the first cell was // not index #0 and b) there are trailing cells, then we have a // problem. We need to shift all the cells down and add leading cells, // one at a time, until either the very last non-empty cells is aligned // with the bottom OR we have laid out cell index #0 at the first // position. T firstCell = cells.getFirst(); index = getCellIndex(firstCell); T lastNonEmptyCell = getLastVisibleCell(); double start = getCellPosition(firstCell); double end = getCellPosition(lastNonEmptyCell) + getCellLength(lastNonEmptyCell); if ((index != 0 || (index == 0 && start < 0)) && fillEmptyCells && lastNonEmptyCell != null && getCellIndex(lastNonEmptyCell) == cellCount - 1 && end < viewportLength) { double prospectiveEnd = end; double distance = viewportLength - end; while (prospectiveEnd < viewportLength && index != 0 && (-start) < distance) { index--; T cell = getAvailableCell(index); setCellIndex(cell, index); resizeCell(cell); // resize must be after config cells.addFirst(cell); double cellLength = getCellLength(cell); start -= cellLength; prospectiveEnd += cellLength; positionCell(cell, start); setMaxPrefBreadth(Math.max(getMaxPrefBreadth(), getCellBreadth(cell))); cell.setVisible(true); } // The amount by which to translate the cells down firstCell = cells.getFirst(); start = getCellPosition(firstCell); double delta = viewportLength - end; if (getCellIndex(firstCell) == 0 && delta > (-start)) { delta = (-start); } // Move things for (int i = 0; i < cells.size(); i++) { T cell = cells.get(i); positionCell(cell, getCellPosition(cell) + delta); } // Check whether the first cell, subsequent to our adjustments, is // now index #0 and aligned with the top. If so, change the position // to be at 0 instead of 1. start = getCellPosition(firstCell); if (getCellIndex(firstCell) == 0 && start == 0) { setPosition(0); } else if (getPosition() != 1) { setPosition(1); } } return filledWithNonEmpty; } /** * Informs the {@code VirtualFlow} that a layout pass should be done, and the cell contents have not changed. For * example, this might be called from a {@code TableView} or {@code ListView} when a layout is needed and no cells * have been added or removed. * * @since 12 */ protected void reconfigureCells() { needsReconfigureCells = true; requestLayout(); } /** * Informs the {@code VirtualFlow} that a layout pass should be done, and that the cell factory has changed. All * cells in the viewport are recreated with the new cell factory. * * @since 12 */ protected void recreateCells() { needsRecreateCells = true; requestLayout(); } /** * Informs the {@code VirtualFlow} that a layout pass should be done, and cell contents have changed. All cells are * removed and then added properly in the viewport. * * @since 12 */ protected void rebuildCells() { needsRebuildCells = true; requestLayout(); } /** * Informs the {@code VirtualFlow} that a layout pass should be done and only the cell layout will be requested. * * @since 12 */ protected void requestCellLayout() { needsCellsLayout = true; requestLayout(); } void setCellDirty(int index) { dirtyCells.set(index); requestLayout(); } /** * Make sure the sizes of the cells that are likely to be visible are known. * When updates to the cell size estimates are occurring, we don't want the current * visible content to be modified. The existing offset and index are respected. * @param index the index of the cell that should be positioned at the top of * the viewport in the next layout cycle. */ void getCellSizesInExpectedViewport(int index) { double oldOffset = computeViewportOffset(getPosition()); int oldIndex = computeCurrentIndex(); double cellLength = getOrCreateCellSize(index); if (index > 0) { getOrCreateCellSize(index - 1); } if (index < getCellCount() - 1) { getOrCreateCellSize(index + 1); } double estlength = cellLength; int i = index; while ((estlength < viewportLength) && (++i < getCellCount())) { estlength = estlength + getOrCreateCellSize(i); } estlength = cellLength; if (estlength < viewportLength) { int j = index; while ((estlength < viewportLength) && (j-- > 0)) { estlength = estlength + getOrCreateCellSize(j); } } recalculateAndImproveEstimatedSize(0, oldIndex, oldOffset); } private void startSBReleasedAnimation() { if (sbTouchTimeline == null) { /* ** timeline to leave the scrollbars visible for a short ** while after a scroll/drag */ sbTouchTimeline = new Timeline(); sbTouchKF1 = new KeyFrame(Duration.millis(0), event -> { tempVisibility = true; requestLayout(); }); sbTouchKF2 = new KeyFrame(Duration.millis(1000), event -> { if (touchDetected == false && mouseDown == false) { tempVisibility = false; requestLayout(); } }); sbTouchTimeline.getKeyFrames().addAll(sbTouchKF1, sbTouchKF2); } sbTouchTimeline.playFromStart(); } private void scrollBarOn() { tempVisibility = true; requestLayout(); } void updateHbar() { if (! isVisible() || getScene() == null) return; // Bring the clipView.clipX back to 0 if control is vertical or // the hbar isn't visible (fix for RT-11666) if (isVertical()) { if (needBreadthBar) { clipView.setClipX(hbar.getValue()); } else { // all cells are now less than the width of the flow, // so we should shift the hbar/clip such that // everything is visible in the viewport. clipView.setClipX(0); hbar.setValue(0); } } } /** * Suppresses the breadth bar from appearing. */ void setSuppressBreadthBar(boolean suppress) { this.suppressBreadthBar = suppress; } /** * @return true if bar visibility changed */ private boolean computeBarVisiblity() { if (cells.isEmpty()) { // In case no cells are set yet, we assume no bars are needed needLengthBar = false; needBreadthBar = false; return true; } final boolean isVertical = isVertical(); boolean barVisibilityChanged = false; VirtualScrollBar breadthBar = isVertical ? hbar : vbar; VirtualScrollBar lengthBar = isVertical ? vbar : hbar; final double viewportBreadth = getViewportBreadth(); final int cellsSize = cells.size(); final int cellCount = getCellCount(); for (int i = 0; i < 2; i++) { final boolean lengthBarVisible = getPosition() > 0 || cellCount > cellsSize || (cellCount == cellsSize && (getCellPosition(cells.getLast()) + getCellLength(cells.getLast())) > getViewportLength()) || (cellCount == cellsSize - 1 && barVisibilityChanged && needBreadthBar); if (lengthBarVisible ^ needLengthBar) { needLengthBar = lengthBarVisible; barVisibilityChanged = true; } final boolean breadthBarVisible = !suppressBreadthBar && (maxPrefBreadth > viewportBreadth); if (breadthBarVisible ^ needBreadthBar) { needBreadthBar = breadthBarVisible; barVisibilityChanged = true; } } // Start by optimistically deciding whether the length bar and // breadth bar are needed and adjust the viewport dimensions // accordingly. If during layout we find that one or the other of the // bars actually is needed, then we will perform a cleanup pass if (!Properties.IS_TOUCH_SUPPORTED) { updateViewportDimensions(); breadthBar.setVisible(needBreadthBar); lengthBar.setVisible(needLengthBar); } else { breadthBar.setVisible(needBreadthBar && tempVisibility); lengthBar.setVisible(needLengthBar && tempVisibility); } return barVisibilityChanged; } private void updateViewportDimensions() { final boolean isVertical = isVertical(); final double breadthBarLength = isVertical ? snapSizeY(hbar.prefHeight(-1)) : snapSizeX(vbar.prefWidth(-1)); final double lengthBarBreadth = isVertical ? snapSizeX(vbar.prefWidth(-1)) : snapSizeY(hbar.prefHeight(-1)); if (!Properties.IS_TOUCH_SUPPORTED) { setViewportBreadth((isVertical ? getWidth() : getHeight()) - (needLengthBar ? lengthBarBreadth : 0)); setViewportLength((isVertical ? getHeight() : getWidth()) - (needBreadthBar ? breadthBarLength : 0)); } else { setViewportBreadth((isVertical ? getWidth() : getHeight())); setViewportLength((isVertical ? getHeight() : getWidth())); } } private void initViewport() { // Initialize the viewportLength and viewportBreadth to match the // width/height of the flow final boolean isVertical = isVertical(); updateViewportDimensions(); VirtualScrollBar breadthBar = isVertical ? hbar : vbar; VirtualScrollBar lengthBar = isVertical ? vbar : hbar; // If there has been a switch between the virtualized bar, then we // will want to do some stuff TODO. breadthBar.setVirtual(false); lengthBar.setVirtual(true); } /** * In case we are not rendering the first cell * AND * there is empty room after the last cell, * the cells need to be shifted down to fill the empty area. */ private void shiftDown() { T lastNonEmptyCell = getLastVisibleCell(); T firstCell = cells.getFirst(); int index = getCellIndex(firstCell); double end = getCellPosition(lastNonEmptyCell) + getCellLength(lastNonEmptyCell); double delta = viewportLength - end; if ((index > 0) && (delta > 0)) { for (int i = 0; i < cells.size(); i++) { T cell = cells.get(i); positionCell(cell, getCellPosition(cell) + delta); } } } private void updateScrollBarsAndCells(boolean recreate) { // Assign the hbar and vbar to the breadthBar and lengthBar so as // to make some subsequent calculations easier. final boolean isVertical = isVertical(); VirtualScrollBar breadthBar = isVertical ? hbar : vbar; VirtualScrollBar lengthBar = isVertical ? vbar : hbar; // We may have adjusted the viewport length and breadth after the // layout due to scroll bars becoming visible. So we need to perform // a follow up pass and resize and shift all the cells to fit the // viewport. Note that the prospective viewport size is always >= the // final viewport size, so we don't have to worry about adding // cells during this cleanup phase. fitCells(); // Update cell positions. // When rebuilding the cells, we add the cells and along the way compute // the maxPrefBreadth. Based on the computed value, we may add // the breadth scrollbar which changes viewport length, so we need // to re-position the cells. if (!cells.isEmpty()) { final double currOffset = -computeViewportOffset(getPosition()); final int currIndex = computeCurrentIndex() - cells.getFirst().getIndex(); final int size = cells.size(); // position leading cells double offset = currOffset; for (int i = currIndex - 1; i >= 0 && i < size; i--) { final T cell = cells.get(i); offset -= getCellLength(cell); positionCell(cell, offset); } // position trailing cells offset = currOffset; for (int i = currIndex; i >= 0 && i < size; i++) { final T cell = cells.get(i); positionCell(cell, offset); offset += getCellLength(cell); } shiftDown(); } // Toggle visibility on the corner corner.setVisible(breadthBar.isVisible() && lengthBar.isVisible()); double sumCellLength = 0; double flowLength = (isVertical ? getHeight() : getWidth()) - (breadthBar.isVisible() ? breadthBar.prefHeight(-1) : 0); final double viewportBreadth = getViewportBreadth(); final double viewportLength = getViewportLength(); // Now position and update the scroll bars if (breadthBar.isVisible()) { /* ** Positioning the ScrollBar */ if (!Properties.IS_TOUCH_SUPPORTED) { if (isVertical) { hbar.resizeRelocate(0, viewportLength, viewportBreadth, hbar.prefHeight(viewportBreadth)); } else { vbar.resizeRelocate(viewportLength, 0, vbar.prefWidth(viewportBreadth), viewportBreadth); } } else { if (isVertical) { double prefHeight = hbar.prefHeight(viewportBreadth); hbar.resizeRelocate(0, viewportLength - prefHeight, viewportBreadth, prefHeight); } else { double prefWidth = vbar.prefWidth(viewportBreadth); vbar.resizeRelocate(viewportLength - prefWidth, 0, prefWidth, viewportBreadth); } } if (getMaxPrefBreadth() != -1) { double newMax = Math.max(1, getMaxPrefBreadth() - viewportBreadth); if (newMax != breadthBar.getMax()) { breadthBar.setMax(newMax); double breadthBarValue = breadthBar.getValue(); boolean maxed = breadthBarValue != 0 && newMax == breadthBarValue; if (maxed || breadthBarValue > newMax) { breadthBar.setValue(newMax); } breadthBar.setVisibleAmount((viewportBreadth / getMaxPrefBreadth()) * newMax); } } } // determine how many cells there are on screen so that the scrollbar // thumb can be appropriately sized if (recreate && (lengthBar.isVisible() || Properties.IS_TOUCH_SUPPORTED)) { final int cellCount = getCellCount(); int numCellsVisibleOnScreen = 0; for (int i = 0, max = cells.size(); i < max; i++) { T cell = cells.get(i); if (cell != null && !cell.isEmpty()) { sumCellLength += (isVertical ? cell.getHeight() : cell.getWidth()); if (sumCellLength > flowLength) { break; } numCellsVisibleOnScreen++; } } lengthBar.setMax(1); if (numCellsVisibleOnScreen == 0 && cellCount == 1) { // special case to help resolve RT-17701 and the case where we have // only a single row and it is bigger than the viewport lengthBar.setVisibleAmount(flowLength / sumCellLength); } else { lengthBar.setVisibleAmount(viewportLength / estimatedSize); } } if (lengthBar.isVisible()) { // Fix for RT-11873. If this isn't here, we can have a situation where // the scrollbar scrolls endlessly. This is possible when the cell // count grows as the user hits the maximal position on the scrollbar // (i.e. the list size dynamically grows as the user needs more). // // This code was commented out to resolve RT-14477 after testing // whether RT-11873 can be recreated. It could not, and therefore // for now this code will remained uncommented until it is deleted // following further testing. // if (lengthBar.getValue() == 1.0 && lastCellCount != cellCount) { // lengthBar.setValue(0.99); // } /* ** Positioning the ScrollBar */ if (!Properties.IS_TOUCH_SUPPORTED) { if (isVertical) { vbar.resizeRelocate(viewportBreadth, 0, vbar.prefWidth(viewportLength), viewportLength); } else { hbar.resizeRelocate(0, viewportBreadth, viewportLength, hbar.prefHeight(-1)); } } else { if (isVertical) { double prefWidth = vbar.prefWidth(viewportLength); vbar.resizeRelocate(viewportBreadth - prefWidth, 0, prefWidth, viewportLength); } else { double prefHeight = hbar.prefHeight(-1); hbar.resizeRelocate(0, viewportBreadth - prefHeight, viewportLength, prefHeight); } } } if (corner.isVisible()) { if (!Properties.IS_TOUCH_SUPPORTED) { corner.resize(vbar.getWidth(), hbar.getHeight()); corner.relocate(hbar.getLayoutX() + hbar.getWidth(), vbar.getLayoutY() + vbar.getHeight()); } else { corner.resize(vbar.getWidth(), hbar.getHeight()); corner.relocate(hbar.getLayoutX() + (hbar.getWidth()-vbar.getWidth()), vbar.getLayoutY() + (vbar.getHeight()-hbar.getHeight())); hbar.resize(hbar.getWidth()-vbar.getWidth(), hbar.getHeight()); vbar.resize(vbar.getWidth(), vbar.getHeight()-hbar.getHeight()); } } clipView.resize(snapSizeX(isVertical ? viewportBreadth : viewportLength), snapSizeY(isVertical ? viewportLength : viewportBreadth)); // If the viewportLength becomes large enough that all cells fit // within the viewport, then we want to update the value to match. if (getPosition() != lengthBar.getValue()) { lengthBar.setValue(getPosition()); } } /** * Adjusts the cells location and size if necessary. The breadths of all * cells will be adjusted to fit the viewportWidth or maxPrefBreadth, and * the layout position will be updated if necessary based on index and * offset. */ private void fitCells() { // Note: Do not optimise this loop by pre-calculating the cells size and // storing that into a int value - this can lead to RT-32828 for (int i = 0; i < cells.size(); i++) { T cell = cells.get(i); resizeCell(cell); } } private void cull() { final double viewportLength = getViewportLength(); for (int i = cells.size() - 1; i >= 0; i--) { T cell = cells.get(i); double cellSize = getCellLength(cell); double cellStart = getCellPosition(cell); double cellEnd = cellStart + cellSize; if (cellStart >= viewportLength || cellEnd < 0) { addToPile(cells.remove(i)); } } } /** * After using the accum cell, it needs to be released! */ private void releaseCell(T cell) { if (accumCell != null && cell == accumCell) { accumCell.setVisible(false); accumCell.updateIndex(-1); } } /** * Creates and returns a new cell for the given index. *

* If the requested index is not already an existing visible cell, it will create a cell for the given index and * insert it into the {@code VirtualFlow} container. If the index exists, simply returns the visible cell. From that * point on, it will be unmanaged, and is up to the caller of this method to manage it. *

* This is useful if a row that should not be visible must be accessed (a row that always stick to the top for * example). It can then be easily created, correctly initialized and inserted in the {@code VirtualFlow} * container. * * @param index the cell index * @return a cell for the given index inserted in the VirtualFlow container * @since 12 */ protected T getPrivateCell(int index) { T cell = null; // If there are cells, then we will attempt to get an existing cell if (! cells.isEmpty()) { // First check the cells that have already been created and are // in use. If this call returns a value, then we can use it cell = getVisibleCell(index); if (cell != null) { // Force the underlying text inside the cell to be updated // so that when the screen reader runs, it will match the // text in the cell (force updateDisplayedText()) cell.layout(); return cell; } } // check the existing sheet children if (cell == null) { for (int i = 0; i < sheetChildren.size(); i++) { T _cell = (T) sheetChildren.get(i); if (getCellIndex(_cell) == index) { return _cell; } } } Callback, T> cellFactory = getCellFactory(); if (cellFactory != null) { cell = cellFactory.call(this); } if (cell != null) { setCellIndex(cell, index); resizeCell(cell); cell.setVisible(false); sheetChildren.add(cell); privateCells.add(cell); } return cell; } private final List privateCells = new ArrayList<>(); private void releaseAllPrivateCells() { sheetChildren.removeAll(privateCells); privateCells.clear(); } /** * Puts the given cell onto the pile. This is called whenever a cell has * fallen off the flow's start. */ private void addToPile(T cell) { assert cell != null; pile.addLast(cell); } private void cleanPile() { boolean wasFocusOwner = false; for (int i = 0, max = pile.size(); i < max; i++) { T cell = pile.get(i); wasFocusOwner = wasFocusOwner || doesCellContainFocus(cell); cell.setVisible(false); } // Fix for RT-35876: Rather than have the cells do weird things with // focus (in particular, have focus jump between cells), we return focus // to the VirtualFlow itself. if (wasFocusOwner) { requestFocus(); } } private boolean doesCellContainFocus(T c) { Scene scene = c.getScene(); final Node focusOwner = scene == null ? null : scene.getFocusOwner(); if (focusOwner != null) { if (c.equals(focusOwner)) { return true; } Parent p = focusOwner.getParent(); while (p != null && ! (p instanceof VirtualFlow)) { if (c.equals(p)) { return true; } p = p.getParent(); } } return false; } private double getPrefBreadth(double oppDimension) { double max = getMaxCellWidth(10); // This primarily exists for the case where we do not want the breadth // to grow to ensure a golden ratio between width and height (for example, // when a ListView is used in a ComboBox - the width should not grow // just because items are being added to the ListView) if (oppDimension > -1) { double prefLength = getPrefLength(); max = Math.max(max, prefLength * GOLDEN_RATIO_MULTIPLIER); } return max; } private double getPrefLength() { double sum = 0.0; int rows = Math.min(10, getCellCount()); for (int i = 0; i < rows; i++) { sum += getCellLength(i); } return sum; } double getMaxCellWidth(int rowsToCount) { double max = 0.0; // we always measure at least one row int rows = Math.max(1, rowsToCount == -1 ? getCellCount() : rowsToCount); for (int i = 0; i < rows; i++) { max = Math.max(max, getCellBreadth(i)); } return max; } // Old PositionMapper /** * Given a position value between 0 and 1, compute and return the viewport * offset from the "current" cell associated with that position value. * That is, if the return value of this function where used as a translation * factor for a sheet that contained all the items, then the current * item would end up positioned correctly. * We calculate the total size until the absoluteoffset is reached. * For this calculation, we use the cached sizes for each item, or an * educated guess in case we don't have a cached size yet. While we could * fill the cache with the size here, we do not do it as it will affect * performance. */ private double computeViewportOffset(double position) { return computeViewportOffset(position, getCellCount()); } private double computeViewportOffset(double position, int localCellCount) { double p = com.sun.javafx.util.Utils.clamp(0, position, 1); double bound = 0d; double estSize = estimatedSize / localCellCount; double maxOff = estimatedSize - getViewportLength(); if ((maxOff > 0) && (absoluteOffset > maxOff)) { return maxOff - absoluteOffset; } for (int i = 0; i < localCellCount; i++) { double h = getCellSize(i); if (h < 0) h = estSize; if (bound + h > absoluteOffset) { return absoluteOffset - bound; } bound += h; } return 0d; } private void adjustPositionToIndex(int index) { if (index > 0) getOrCreateCellSize(index-1); getOrCreateCellSize(index); recalculateEstimatedSize(); int cellCount = getCellCount(); if (cellCount <= 0) { setPosition(0.0f); } else { double targetOffset = 0; double estSize = estimatedSize/cellCount; for (int i = 0; i < index; i++) { double cz = getCellSize(i); if (cz < 0) cz = estSize; targetOffset = targetOffset+ cz; } this.absoluteOffset = (estimatedSize < viewportLength) ? 0 : targetOffset; adjustPosition(); } } /** * Adjust the position based on a delta of pixels. If negative, then the * position will be adjusted negatively. If positive, then the position will * be adjusted positively. If the pixel amount is too great for the range of * the position, then it will be clamped such that position is always * strictly between 0 and 1 * @return the actual number of pixels that have been applied */ private double adjustByPixelAmount(double numPixels) { if (numPixels == 0) return 0; // When we're at the top already, we can't move back further, unless we // want to allow for gravity-alike effects. if ((absoluteOffset <= 0) && (numPixels < 0)) return 0; // start with applying the requested modification double origAbsoluteOffset = this.absoluteOffset; this.absoluteOffset = Math.max(0.d, this.absoluteOffset + numPixels); double newPosition = Math.min(1.0d, absoluteOffset / (estimatedSize - viewportLength)); // estimatedSize changes may result in opposite effect on position // in that case, modify current position 1% in the requested direction if ((numPixels > 0) && (newPosition < getPosition())) { newPosition = getPosition()*1.01; } if ((numPixels < 0) && (newPosition > getPosition())) { newPosition = getPosition()*.99; } // once at 95% of the total estimated size, we want a correct size, not // an estimated size anymore. if (newPosition > .95) { int cci = computeCurrentIndex(); while (cci < getCellCount()) { getOrCreateCellSize(cci); cci++; } recalculateEstimatedSize(); } // if we are at or beyond the edge, correct the absoluteOffset if (newPosition >= 1.d) { absoluteOffset = estimatedSize - viewportLength; } setPosition(newPosition); return absoluteOffset - origAbsoluteOffset; } private double computeBaseOffset(int index) { double baseOffset = 0d; int currentCellCount = getCellCount(); double estSize = estimatedSize / currentCellCount; for (int i = 0; i < index; i++) { double nextSize = getCellSize(i); if (nextSize < 0) nextSize = estSize; baseOffset += nextSize; } return baseOffset; } /** * Compute the index of the first visible cell * This has package access ONLY FOR TESTING. */ int computeCurrentIndex() { return computeCurrentIndex(getCellCount()); } private int computeCurrentIndex(int currentCellCount) { double total = 0; double estSize = estimatedSize / currentCellCount; for (int i = 0; i < currentCellCount; i++) { double nextSize = getCellSize(i); if (nextSize < 0) nextSize = estSize; total = total + nextSize; if (total > absoluteOffset) { return i; } } return currentCellCount == 0 ? 0 : currentCellCount - 1; } /** * Given an item index, this function will compute and return the viewport * offset from the beginning of the specified item. Notice that because each * item has the same percentage of the position dedicated to it, and since * we are measuring from the start of each item, this is a very simple * calculation. */ private double computeOffsetForCell(int itemIndex) { double cellCount = getCellCount(); double p = com.sun.javafx.util.Utils.clamp(0, itemIndex, cellCount) / cellCount; return -(getViewportLength() * p); } double getCellSize(int idx) { return getOrCreateCellSize(idx, false); } /** * Get the size of the considered element. * If the requested element has a size that is not yet in the cache, * it will be computed and cached now. * @return the size of the element; or 1 in case there are no cells yet */ double getOrCreateCellSize(int idx) { return getOrCreateCellSize (idx, true); } private double getOrCreateCellSize (int idx, boolean create) { if (idx < 0) return -1; // is the current cache long enough to contain idx? if (itemSizeCache.size() > idx) { // is there a non-null value stored in the cache? if (itemSizeCache.get(idx) != null) { return itemSizeCache.get(idx); } } if (!create) return -1; boolean doRelease = false; // Make sure we have enough space in the cache to store this index while (idx >= itemSizeCache.size()) { itemSizeCache.add(itemSizeCache.size(), null); } double answer = 1d; if (getFixedCellSize() > 0) { answer = getFixedCellSize(); itemSizeCache.set(idx, answer); } else { // Do we have a visible cell for this index? T cell = getVisibleCell(idx); if (cell == null) { // we might get the accumcell here cell = getCell(idx); doRelease = true; } answer = getCellLength(cell); itemSizeCache.set(idx, answer); if (doRelease) { // we need to release the accumcell releaseCell(cell); } } return answer; } /** * Update the size of a specific cell. * If this cell was already in the cache, its old value is replaced by the * new size. The total size of the flow will be recalculated, respecting the * current index and offset. * If the specific cell is the "current" cell (which is the first cell that is * at least partially visible), the offset used for the viewport needs to be * recalculated in case the new size is different from the cached size. This way, * we keep the end of the current cell (and start of the cell at current + 1) * constant. An exception to this is when the current cell starts at offset 0, * in which case we keep the (0) offset as is. * @param cell the cell which size has to be calculated */ void updateCellSize(T cell) { int cellIndex = cell.getIndex(); if (itemSizeCache.size() > cellIndex) { Double oldSize = itemSizeCache.get(cellIndex); double newSize = getCellLength(cell); itemSizeCache.set(cellIndex, newSize); if ((oldSize != null) && !oldSize.equals(newSize)) { int currentIndex = computeCurrentIndex(); double oldOffset = computeViewportOffset(getPosition()); if ((cellIndex == currentIndex) && (oldOffset != 0)) { oldOffset = oldOffset + newSize - oldSize; } recalculateAndImproveEstimatedSize(0, currentIndex, oldOffset); } } } /** * Recalculate the estimated size for this list based on what we have in the * cache. */ private void recalculateEstimatedSize() { recalculateAndImproveEstimatedSize(DEFAULT_IMPROVEMENT); } private boolean recalculating = false; private void recalculateAndImproveEstimatedSize(int improve) { recalculateAndImproveEstimatedSize(improve, -1, computeViewportOffset(getPosition())); } /** * Recalculate the estimated size. If an oldIndex different from -1 is supplied, that value will * be respected: * at the end of this calculation, we make sure that if the current index is calculated, it will * be the same as the old index. If the oldIndex is -1, there is no guarantee about the new index. */ private void recalculateAndImproveEstimatedSize(int improve, int oldIndex, double oldOffset) { if (recalculating) return; recalculating = true; try { int itemCount = getCellCount(); int cacheCount = itemSizeCache.size(); boolean keepRatio = ((cacheCount > 0) && !Double.isInfinite(this.absoluteOffset)); if (oldIndex < 0) oldIndex = computeCurrentIndex(); int added = 0; while ((itemCount > itemSizeCache.size()) && (added < improve)) { getOrCreateCellSize(itemSizeCache.size()); added++; } cacheCount = itemSizeCache.size(); int cnt = 0; double tot = 0d; for (int i = 0; (i < itemCount && i < cacheCount); i++) { Double il = itemSizeCache.get(i); if (il != null) { tot = tot + il; cnt++; } } this.estimatedSize = cnt == 0 ? 1d : tot * itemCount / cnt; double estSize = estimatedSize / itemCount; if (keepRatio) { double newOffset = 0; for (int i = 0; i < oldIndex; i++) { double h = getCellSize(i); if (h < 0) { h = estSize; } newOffset += h; } this.absoluteOffset = newOffset + oldOffset; adjustPosition(); } } finally { recalculating = false; } } private void resetSizeEstimates() { itemSizeCache.clear(); this.estimatedSize = 1d; } // /** // * Adjust the position based on a chunk of pixels. The position is based // * on the start of the scrollbar position. // */ // private void adjustByPixelChunk(double numPixels) { // setPosition(0); // adjustByPixelAmount(numPixels); // } // end of old PositionMapper code /* ************************************************************************* * * * Support classes * * * **************************************************************************/ /** * A simple extension to Region that ensures that anything wanting to flow * outside of the bounds of the Region is clipped. */ static class ClippedContainer extends Region { /** * The Node which is embedded within this {@code ClipView}. */ private Node node; public Node getNode() { return this.node; } public void setNode(Node n) { this.node = n; getChildren().clear(); getChildren().add(node); } public void setClipX(double clipX) { setLayoutX(-clipX); clipRect.setLayoutX(clipX); } public void setClipY(double clipY) { setLayoutY(-clipY); clipRect.setLayoutY(clipY); } private final Rectangle clipRect; public ClippedContainer(final VirtualFlow flow) { if (flow == null) { throw new IllegalArgumentException("VirtualFlow can not be null"); } getStyleClass().add("clipped-container"); // clipping clipRect = new Rectangle(); clipRect.setSmooth(false); setClip(clipRect); // --- clipping super.widthProperty().addListener(valueModel -> { clipRect.setWidth(getWidth()); }); super.heightProperty().addListener(valueModel -> { clipRect.setHeight(getHeight()); }); } } /** * A List-like implementation that is exceedingly efficient for the purposes * of the VirtualFlow. Typically there is not much variance in the number of * cells -- it is always some reasonably consistent number. Yet for efficiency * in code, we like to use a linked list implementation so as to append to * start or append to end. However, at times when we need to iterate, LinkedList * is expensive computationally as well as requiring the construction of * temporary iterators. *

* This linked list like implementation is done using an array. It begins by * putting the first item in the center of the allocated array, and then grows * outward (either towards the first or last of the array depending on whether * we are inserting at the head or tail). It maintains an index to the start * and end of the array, so that it can efficiently expose iteration. *

* This class is package private solely for the sake of testing. */ static class ArrayLinkedList extends AbstractList { /** * The array list backing this class. We default the size of the array * list to be fairly large so as not to require resizing during normal * use, and since that many ArrayLinkedLists won't be created it isn't * very painful to do so. */ private final ArrayList array; private int firstIndex = -1; private int lastIndex = -1; public ArrayLinkedList() { array = new ArrayList<>(50); for (int i = 0; i < 50; i++) { array.add(null); } } public T getFirst() { return firstIndex == -1 ? null : array.get(firstIndex); } public T getLast() { return lastIndex == -1 ? null : array.get(lastIndex); } public void addFirst(T cell) { // if firstIndex == -1 then that means this is the first item in the // list and we need to initialize firstIndex and lastIndex if (firstIndex == -1) { firstIndex = lastIndex = array.size() / 2; array.set(firstIndex, cell); } else if (firstIndex == 0) { // we're already at the head of the array, so insert at position // 0 and then increment the lastIndex to compensate array.add(0, cell); lastIndex++; } else { // we're not yet at the head of the array, so insert at the // firstIndex - 1 position and decrement first position array.set(--firstIndex, cell); } } public void addLast(T cell) { // if lastIndex == -1 then that means this is the first item in the // list and we need to initialize the firstIndex and lastIndex if (firstIndex == -1) { firstIndex = lastIndex = array.size() / 2; array.set(lastIndex, cell); } else if (lastIndex == array.size() - 1) { // we're at the end of the array so need to "add" so as to force // the array to be expanded in size array.add(++lastIndex, cell); } else { array.set(++lastIndex, cell); } } @Override public int size() { return firstIndex == -1 ? 0 : lastIndex - firstIndex + 1; } @Override public boolean isEmpty() { return firstIndex == -1; } @Override public T get(int index) { if (index > (lastIndex - firstIndex) || index < 0) { // Commented out exception due to RT-29111 // throw new java.lang.ArrayIndexOutOfBoundsException(); return null; } return array.get(firstIndex + index); } @Override public void clear() { for (int i = 0; i < array.size(); i++) { array.set(i, null); } firstIndex = lastIndex = -1; } public T removeFirst() { if (isEmpty()) return null; return remove(0); } public T removeLast() { if (isEmpty()) return null; return remove(lastIndex - firstIndex); } @Override public T remove(int index) { if (index > lastIndex - firstIndex || index < 0) { throw new ArrayIndexOutOfBoundsException(); } // if the index == 0, then we're removing the first // item and can simply set it to null in the array and increment // the firstIndex unless there is only one item, in which case // we have to also set first & last index to -1. if (index == 0) { T cell = array.get(firstIndex); array.set(firstIndex, null); if (firstIndex == lastIndex) { firstIndex = lastIndex = -1; } else { firstIndex++; } return cell; } else if (index == lastIndex - firstIndex) { // if the index == lastIndex - firstIndex, then we're removing the // last item and can simply set it to null in the array and // decrement the lastIndex T cell = array.get(lastIndex); array.set(lastIndex--, null); return cell; } else { // if the index is somewhere in between, then we have to remove the // item and decrement the lastIndex T cell = array.get(firstIndex + index); array.set(firstIndex + index, null); for (int i = (firstIndex + index + 1); i <= lastIndex; i++) { array.set(i - 1, array.get(i)); } array.set(lastIndex--, null); return cell; } } } }





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