// Copyright 2015 The Chromium Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
import 'package:flutter/gestures.dart';
import 'package:vector_math/vector_math_64.dart';
import 'box.dart';
import 'debug.dart';
import 'object.dart';
import 'semantics.dart';
export 'package:flutter/gestures.dart' show
PointerEvent,
PointerDownEvent,
PointerMoveEvent,
PointerUpEvent,
PointerCancelEvent;
/// A base class for render objects that resemble their children.
///
/// A proxy box has a single child and simply mimics all the properties of that
/// child by calling through to the child for each function in the render box
/// protocol. For example, a proxy box determines its size by askings its child
/// to layout with the same constraints and then matching the size.
///
/// A proxy box isn't useful on its own because you might as well just replace
/// the proxy box with its child. However, RenderProxyBox is a useful base class
/// for render objects that wish to mimic most, but not all, of the properties
/// of their child.
class RenderProxyBox extends RenderBox with RenderObjectWithChildMixin<RenderBox> {
RenderProxyBox([RenderBox child = null]) {
this.child = child;
}
double getMinIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMinIntrinsicWidth(constraints);
return super.getMinIntrinsicWidth(constraints);
}
double getMaxIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMaxIntrinsicWidth(constraints);
return super.getMaxIntrinsicWidth(constraints);
}
double getMinIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMinIntrinsicHeight(constraints);
return super.getMinIntrinsicHeight(constraints);
}
double getMaxIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMaxIntrinsicHeight(constraints);
return super.getMaxIntrinsicHeight(constraints);
}
double computeDistanceToActualBaseline(TextBaseline baseline) {
if (child != null)
return child.getDistanceToActualBaseline(baseline);
return super.computeDistanceToActualBaseline(baseline);
}
void performLayout() {
if (child != null) {
child.layout(constraints, parentUsesSize: true);
size = child.size;
} else {
performResize();
}
}
bool hitTestChildren(HitTestResult result, { Point position }) {
return child?.hitTest(result, position: position) ?? false;
}
void paint(PaintingContext context, Offset offset) {
if (child != null)
context.paintChild(child, offset);
}
}
/// How to behave during hit tests.
enum HitTestBehavior {
/// Targets that defer to their children receive events within their bounds
/// only if one of their children is hit by the hit test.
deferToChild,
/// Opaque targets can be hit by hit tests, causing them to both receive
/// events within their bounds and prevent targets visually behind them from
/// also receiving events.
opaque,
/// Translucent targets both receive events within their bounds and permit
/// targets visually behind them to also receive events.
translucent,
}
/// A RenderProxyBox subclass that allows you to customize the
/// hit-testing behavior.
abstract class RenderProxyBoxWithHitTestBehavior extends RenderProxyBox {
RenderProxyBoxWithHitTestBehavior({
this.behavior: HitTestBehavior.deferToChild,
RenderBox child
}) : super(child);
HitTestBehavior behavior;
bool hitTest(HitTestResult result, { Point position }) {
bool hitTarget = false;
if (position.x >= 0.0 && position.x < size.width &&
position.y >= 0.0 && position.y < size.height) {
hitTarget = hitTestChildren(result, position: position) || hitTestSelf(position);
if (hitTarget || behavior == HitTestBehavior.translucent)
result.add(new BoxHitTestEntry(this, position));
}
return hitTarget;
}
bool hitTestSelf(Point position) => behavior == HitTestBehavior.opaque;
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
switch (behavior) {
case HitTestBehavior.translucent:
description.add('behavior: translucent');
break;
case HitTestBehavior.opaque:
description.add('behavior: opaque');
break;
case HitTestBehavior.deferToChild:
description.add('behavior: defer-to-child');
break;
}
}
}
/// Imposes additional constraints on its child.
///
/// A render constrained box proxies most functions in the render box protocol
/// to its child, except that when laying out its child, it tightens the
/// constraints provided by its parent by enforcing the [additionalConstraints]
/// as well.
///
/// For example, if you wanted [child] to have a minimum height of 50.0 logical
/// pixels, you could use `const BoxConstraints(minHeight: 50.0)`` as the
/// [additionalConstraints].
class RenderConstrainedBox extends RenderProxyBox {
RenderConstrainedBox({
RenderBox child,
BoxConstraints additionalConstraints
}) : _additionalConstraints = additionalConstraints, super(child) {
assert(additionalConstraints != null);
assert(additionalConstraints.debugAssertIsNormalized);
}
/// Additional constraints to apply to [child] during layout
BoxConstraints get additionalConstraints => _additionalConstraints;
BoxConstraints _additionalConstraints;
void set additionalConstraints (BoxConstraints newConstraints) {
assert(newConstraints != null);
assert(newConstraints.debugAssertIsNormalized);
if (_additionalConstraints == newConstraints)
return;
_additionalConstraints = newConstraints;
markNeedsLayout();
}
double getMinIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMinIntrinsicWidth(_additionalConstraints.enforce(constraints));
return _additionalConstraints.enforce(constraints).constrainWidth(0.0);
}
double getMaxIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMaxIntrinsicWidth(_additionalConstraints.enforce(constraints));
return _additionalConstraints.enforce(constraints).constrainWidth(0.0);
}
double getMinIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMinIntrinsicHeight(_additionalConstraints.enforce(constraints));
return _additionalConstraints.enforce(constraints).constrainHeight(0.0);
}
double getMaxIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMaxIntrinsicHeight(_additionalConstraints.enforce(constraints));
return _additionalConstraints.enforce(constraints).constrainHeight(0.0);
}
void performLayout() {
if (child != null) {
child.layout(_additionalConstraints.enforce(constraints), parentUsesSize: true);
size = child.size;
} else {
size = _additionalConstraints.enforce(constraints).constrain(Size.zero);
}
}
void debugPaintSize(PaintingContext context, Offset offset) {
super.debugPaintSize(context, offset);
assert(() {
Paint paint;
if (child == null || child.size.isEmpty) {
paint = new Paint()
..color = debugPaintSpacingColor;
context.canvas.drawRect(offset & size, paint);
}
return true;
});
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('additionalConstraints: $additionalConstraints');
}
}
/// Sizes itself to a fraction of the total available space.
///
/// For both its width and width height, this render object imposes a tight
/// constraint on its child that is a multiple (typically less than 1.0) of the
/// maximum constraint it received from its parent on that axis. If the factor
/// for a given axis is null, then the constraints from the parent are just
/// passed through instead.
///
/// It then tries to size itself t the size of its child.
class RenderFractionallySizedBox extends RenderProxyBox {
RenderFractionallySizedBox({
RenderBox child,
double widthFactor,
double heightFactor
}) : _widthFactor = widthFactor, _heightFactor = heightFactor, super(child) {
assert(_widthFactor == null || _widthFactor >= 0.0);
assert(_heightFactor == null || _heightFactor >= 0.0);
}
/// If non-null, the factor of the incoming width to use.
///
/// If non-null, the child is given a tight width constraint that is the max
/// incoming width constraint multipled by this factor. If null, the child is
/// given the incoming width constraings.
double get widthFactor => _widthFactor;
double _widthFactor;
void set widthFactor (double value) {
assert(value == null || value >= 0.0);
if (_widthFactor == value)
return;
_widthFactor = value;
markNeedsLayout();
}
/// If non-null, the factor of the incoming height to use.
///
/// If non-null, the child is given a tight height constraint that is the max
/// incoming width constraint multipled by this factor. If null, the child is
/// given the incoming width constraings.
double get heightFactor => _heightFactor;
double _heightFactor;
void set heightFactor (double value) {
assert(value == null || value >= 0.0);
if (_heightFactor == value)
return;
_heightFactor = value;
markNeedsLayout();
}
BoxConstraints _getInnerConstraints(BoxConstraints constraints) {
double minWidth = constraints.minWidth;
double maxWidth = constraints.maxWidth;
if (_widthFactor != null) {
double width = maxWidth * _widthFactor;
minWidth = width;
maxWidth = width;
}
double minHeight = constraints.minHeight;
double maxHeight = constraints.maxHeight;
if (_heightFactor != null) {
double height = maxHeight * _heightFactor;
minHeight = height;
maxHeight = height;
}
return new BoxConstraints(
minWidth: minWidth,
maxWidth: maxWidth,
minHeight: minHeight,
maxHeight: maxHeight
);
}
double getMinIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMinIntrinsicWidth(_getInnerConstraints(constraints));
return _getInnerConstraints(constraints).constrainWidth(0.0);
}
double getMaxIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMaxIntrinsicWidth(_getInnerConstraints(constraints));
return _getInnerConstraints(constraints).constrainWidth(0.0);
}
double getMinIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMinIntrinsicHeight(_getInnerConstraints(constraints));
return _getInnerConstraints(constraints).constrainHeight(0.0);
}
double getMaxIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child != null)
return child.getMaxIntrinsicHeight(_getInnerConstraints(constraints));
return _getInnerConstraints(constraints).constrainHeight(0.0);
}
void performLayout() {
if (child != null) {
child.layout(_getInnerConstraints(constraints), parentUsesSize: true);
size = child.size;
} else {
size = _getInnerConstraints(constraints).constrain(Size.zero);
}
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('widthFactor: ${_widthFactor ?? "pass-through"}');
description.add('heightFactor: ${_heightFactor ?? "pass-through"}');
}
}
/// Attempts to size the child to a specific aspect ratio.
///
/// The render object first tries the largest width permited by the layout
/// constraints. The height of the render object is determined by applying the
/// given aspect ratio to the width, expressed as a ratio of width to height.
///
/// For example, a 16:9 width:height aspect ratio would have a value of
/// 16.0/9.0. If the maximum width is infinite, the initial width is determined
/// by applying the aspect ratio to the maximum height.
///
/// Now consider a second example, this time with an aspect ratio of 2.0 and
/// layout constraints that require the width to be between 0.0 and 100.0 and
/// the height to be between 0.0 and 100.0. We'll select a width of 100.0 (the
/// biggest allowed) and a height of 50.0 (to match the aspect ratio).
///
/// In that same situation, if the aspect ratio is 0.5, we'll also select a
/// width of 100.0 (still the biggest allowed) and we'll attempt to use a height
/// of 200.0. Unfortunately, that violates the constraints because the child can
/// be at most 100.0 pixels tall. The render object will then take that value
/// and apply the aspect ratio again to obtain a width of 50.0. That width is
/// permitted by the constraints and the child receives a width of 50.0 and a
/// height of 100.0. If the width were not permitted, the render object would
/// continue iterating through the constraints. If the render object does not
/// find a feasible size after consulting each constraint, the render object
/// will eventually select a size for the child that meets the layout
/// constraints but fails to meet the aspect ratio constraints.
class RenderAspectRatio extends RenderProxyBox {
RenderAspectRatio({
RenderBox child,
double aspectRatio
}) : _aspectRatio = aspectRatio, super(child) {
assert(_aspectRatio != null);
}
/// The aspect ratio to attempt to use.
///
/// The aspect ratio is expressed as a ratio of width to height. For example,
/// a 16:9 width:height aspect ratio would have a value of 16.0/9.0.
double get aspectRatio => _aspectRatio;
double _aspectRatio;
void set aspectRatio (double newAspectRatio) {
assert(newAspectRatio != null);
if (_aspectRatio == newAspectRatio)
return;
_aspectRatio = newAspectRatio;
markNeedsLayout();
}
double getMinIntrinsicWidth(BoxConstraints constraints) {
return constraints.minWidth;
}
double getMaxIntrinsicWidth(BoxConstraints constraints) {
return constraints.maxWidth;
}
double getMinIntrinsicHeight(BoxConstraints constraints) {
return constraints.minHeight;
}
double getMaxIntrinsicHeight(BoxConstraints constraints) {
return constraints.maxHeight;
}
Size _applyAspectRatio(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
assert(() {
if (!constraints.hasBoundedWidth && !constraints.hasBoundedHeight) {
throw new RenderingError(
'$runtimeType has unbounded constraints.\n'
'This $runtimeType was given an aspect ratio of $aspectRatio but was given '
'both unbounded width and unbounded height constraints. Because both '
'constraints were unbounded, this render object doesn\'t know how much '
'size to consume.'
);
}
return true;
});
if (constraints.isTight)
return constraints.smallest;
double width = constraints.maxWidth;
double height;
// We default to picking the height based on the width, but if the width
// would be infinite, that's not sensible so we try to infer the height
// from the width.
if (width.isFinite) {
height = width / _aspectRatio;
} else {
height = constraints.maxHeight;
width = height * _aspectRatio;
}
// Similar to RenderImage, we iteratively attempt to fit within the given
// constraings while maintaining the given aspect ratio. The order of
// applying the constraints is also biased towards inferring the height
// from the width.
if (width > constraints.maxWidth) {
width = constraints.maxWidth;
height = width / _aspectRatio;
}
if (height > constraints.maxHeight) {
height = constraints.maxHeight;
width = height * _aspectRatio;
}
if (width < constraints.minWidth) {
width = constraints.minWidth;
height = width / _aspectRatio;
}
if (height < constraints.minHeight) {
height = constraints.minHeight;
width = height * _aspectRatio;
}
return constraints.constrain(new Size(width, height));
}
void performLayout() {
size = _applyAspectRatio(constraints);
if (child != null)
child.layout(new BoxConstraints.tight(size));
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('aspectRatio: $aspectRatio');
}
}
/// Sizes its child to the child's intrinsic width.
///
/// Sizes its child's width to the child's maximum intrinsic width. If
/// [stepWidth] is non-null, the child's width will be snapped to a multiple of
/// the [stepWidth]. Similarly, if [stepHeight] is non-null, the child's height
/// will be snapped to a multiple of the [stepHeight].
///
/// This class is useful, for example, when unlimited width is available and
/// you would like a child that would otherwise attempt to expand infinitely to
/// instead size itself to a more reasonable width.
///
/// This class is relatively expensive. Avoid using it where possible.
class RenderIntrinsicWidth extends RenderProxyBox {
RenderIntrinsicWidth({
double stepWidth,
double stepHeight,
RenderBox child
}) : _stepWidth = stepWidth, _stepHeight = stepHeight, super(child);
/// If non-null, force the child's width to be a multiple of this value.
double get stepWidth => _stepWidth;
double _stepWidth;
void set stepWidth(double newStepWidth) {
if (newStepWidth == _stepWidth)
return;
_stepWidth = newStepWidth;
markNeedsLayout();
}
/// If non-null, force the child's height to be a multiple of this value.
double get stepHeight => _stepHeight;
double _stepHeight;
void set stepHeight(double newStepHeight) {
if (newStepHeight == _stepHeight)
return;
_stepHeight = newStepHeight;
markNeedsLayout();
}
static double _applyStep(double input, double step) {
if (step == null)
return input;
return (input / step).ceil() * step;
}
BoxConstraints _getInnerConstraints(BoxConstraints constraints) {
assert(child != null);
if (constraints.hasTightWidth)
return constraints;
double width = child.getMaxIntrinsicWidth(constraints);
assert(width == constraints.constrainWidth(width));
return constraints.tighten(width: _applyStep(width, _stepWidth));
}
double getMinIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
return getMaxIntrinsicWidth(constraints);
}
double getMaxIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child == null)
return constraints.constrainWidth(0.0);
double childResult = child.getMaxIntrinsicWidth(constraints);
return constraints.constrainWidth(_applyStep(childResult, _stepWidth));
}
double getMinIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child == null)
return constraints.constrainHeight(0.0);
double childResult = child.getMinIntrinsicHeight(_getInnerConstraints(constraints));
return constraints.constrainHeight(_applyStep(childResult, _stepHeight));
}
double getMaxIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child == null)
return constraints.constrainHeight(0.0);
double childResult = child.getMaxIntrinsicHeight(_getInnerConstraints(constraints));
return constraints.constrainHeight(_applyStep(childResult, _stepHeight));
}
void performLayout() {
if (child != null) {
BoxConstraints childConstraints = _getInnerConstraints(constraints);
if (_stepHeight != null)
childConstraints.tighten(height: getMaxIntrinsicHeight(childConstraints));
child.layout(childConstraints, parentUsesSize: true);
size = child.size;
} else {
performResize();
}
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('stepWidth: $stepWidth');
description.add('stepHeight: $stepHeight');
}
}
/// Sizes its child to the child's intrinsic height.
///
/// This class is useful, for example, when unlimited height is available and
/// you would like a child that would otherwise attempt to expand infinitely to
/// instead size itself to a more reasonable height.
///
/// This class is relatively expensive. Avoid using it where possible.
class RenderIntrinsicHeight extends RenderProxyBox {
RenderIntrinsicHeight({
RenderBox child
}) : super(child);
BoxConstraints _getInnerConstraints(BoxConstraints constraints) {
assert(child != null);
if (constraints.hasTightHeight)
return constraints;
double height = child.getMaxIntrinsicHeight(constraints);
assert(height == constraints.constrainHeight(height));
return constraints.tighten(height: height);
}
double getMinIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child == null)
return constraints.constrainWidth(0.0);
return child.getMinIntrinsicWidth(_getInnerConstraints(constraints));
}
double getMaxIntrinsicWidth(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child == null)
return constraints.constrainWidth(0.0);
return child.getMaxIntrinsicWidth(_getInnerConstraints(constraints));
}
double getMinIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
return getMaxIntrinsicHeight(constraints);
}
double getMaxIntrinsicHeight(BoxConstraints constraints) {
assert(constraints.debugAssertIsNormalized);
if (child == null)
return constraints.constrainHeight(0.0);
return child.getMaxIntrinsicHeight(constraints);
}
void performLayout() {
if (child != null) {
child.layout(_getInnerConstraints(constraints), parentUsesSize: true);
size = child.size;
} else {
performResize();
}
}
}
int _getAlphaFromOpacity(double opacity) => (opacity * 255).round();
/// Makes its child partially transparent.
///
/// This class paints its child into an intermediate buffer and then blends the
/// child back into the scene partially transparent.
///
/// This class is relatively expensive because it requires painting the child
/// into an intermediate buffer.
class RenderOpacity extends RenderProxyBox {
RenderOpacity({ RenderBox child, double opacity: 1.0 })
: _opacity = opacity, _alpha = _getAlphaFromOpacity(opacity), super(child) {
assert(opacity >= 0.0 && opacity <= 1.0);
}
bool get alwaysNeedsCompositing => child != null && (_alpha != 0 && _alpha != 255);
/// The fraction to scale the child's alpha value.
///
/// An opacity of 1.0 is fully opaque. An opacity of 0.0 is fully transparent
/// (i.e., invisible).
double get opacity => _opacity;
double _opacity;
void set opacity (double newOpacity) {
assert(newOpacity != null);
assert(newOpacity >= 0.0 && newOpacity <= 1.0);
if (_opacity == newOpacity)
return;
_opacity = newOpacity;
_alpha = _getAlphaFromOpacity(_opacity);
markNeedsCompositingBitsUpdate();
markNeedsPaint();
markNeedsSemanticsUpdate();
}
int _alpha;
void paint(PaintingContext context, Offset offset) {
if (child != null) {
if (_alpha == 0)
return;
if (_alpha == 255) {
context.paintChild(child, offset);
return;
}
assert(needsCompositing);
context.pushOpacity(offset, _alpha, super.paint);
}
}
void visitChildrenForSemantics(RenderObjectVisitor visitor) {
if (child != null && _alpha != 0)
visitor(child);
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('opacity: ${opacity.toStringAsFixed(1)}');
}
}
typedef Shader ShaderCallback(Rect bounds);
class RenderShaderMask extends RenderProxyBox {
RenderShaderMask({ RenderBox child, ShaderCallback shaderCallback, TransferMode transferMode })
: _shaderCallback = shaderCallback, _transferMode = transferMode, super(child);
ShaderCallback get shaderCallback => _shaderCallback;
ShaderCallback _shaderCallback;
void set shaderCallback (ShaderCallback newShaderCallback) {
assert(newShaderCallback != null);
if (_shaderCallback == newShaderCallback)
return;
_shaderCallback = newShaderCallback;
markNeedsPaint();
}
TransferMode get transferMode => _transferMode;
TransferMode _transferMode;
void set transferMode (TransferMode newTransferMode) {
assert(newTransferMode != null);
if (_transferMode == newTransferMode)
return;
_transferMode = newTransferMode;
markNeedsPaint();
}
bool get alwaysNeedsCompositing => child != null;
void paint(PaintingContext context, Offset offset) {
if (child != null) {
assert(needsCompositing);
Rect rect = Point.origin & size;
context.pushShaderMask(offset, _shaderCallback(rect), rect, _transferMode, super.paint);
}
}
}
/// A class that provides custom clips.
abstract class CustomClipper<T> {
/// Returns a description of the clip given that the render object being
/// clipped is of the given size.
T getClip(Size size);
/// Returns an approximation of the clip returned by [getClip], as
/// an axis-aligned Rect. This is used by the semantics layer to
/// determine whether widgets should be excluded.
///
/// By default, this returns a rectangle that is the same size as
/// the RenderObject. If getClip returns a shape that is roughly the
/// same size as the RenderObject (e.g. it's a rounded rectangle
/// with very small arcs in the corners), then this may be adequate.
Rect getApproximateClipRect(Size size) => Point.origin & size;
/// Returns true if the new instance will result in a different clip
/// than the oldClipper instance.
bool shouldRepaint(CustomClipper<T> oldClipper);
}
abstract class _RenderCustomClip<T> extends RenderProxyBox {
_RenderCustomClip({
RenderBox child,
CustomClipper<T> clipper
}) : _clipper = clipper, super(child);
/// If non-null, determines which clip to use on the child.
CustomClipper<T> get clipper => _clipper;
CustomClipper<T> _clipper;
void set clipper (CustomClipper<T> newClipper) {
if (_clipper == newClipper)
return;
CustomClipper<T> oldClipper = _clipper;
_clipper = newClipper;
if (newClipper == null) {
assert(oldClipper != null);
markNeedsPaint();
markNeedsSemanticsUpdate(onlyChanges: true);
} else if (oldClipper == null ||
oldClipper.runtimeType != oldClipper.runtimeType ||
newClipper.shouldRepaint(oldClipper)) {
markNeedsPaint();
markNeedsSemanticsUpdate(onlyChanges: true);
}
}
T get _defaultClip;
T get _clip => _clipper?.getClip(size) ?? _defaultClip;
Rect describeApproximatePaintClip(RenderObject child) => _clipper?.getApproximateClipRect(size) ?? Point.origin & size;
}
/// Clips its child using a rectangle.
///
/// Prevents its child from painting outside its bounds.
class RenderClipRect extends _RenderCustomClip<Rect> {
RenderClipRect({
RenderBox child,
CustomClipper<Rect> clipper
}) : super(child: child, clipper: clipper);
Rect get _defaultClip => Point.origin & size;
bool hitTest(HitTestResult result, { Point position }) {
if (_clipper != null) {
Rect clipRect = _clip;
if (!clipRect.contains(position))
return false;
}
return super.hitTest(result, position: position);
}
void paint(PaintingContext context, Offset offset) {
if (child != null)
context.pushClipRect(needsCompositing, offset, _clip, super.paint);
}
}
/// Clips its child using a rounded rectangle.
///
/// Creates a rounded rectangle from its layout dimensions and the given x and
/// y radius values and prevents its child from painting outside that rounded
/// rectangle.
class RenderClipRRect extends RenderProxyBox {
RenderClipRRect({
RenderBox child,
double xRadius,
double yRadius
}) : _xRadius = xRadius, _yRadius = yRadius, super(child) {
assert(_xRadius != null);
assert(_yRadius != null);
}
/// The radius of the rounded corners in the horizontal direction in logical pixels.
///
/// Values are clamped to be between zero and half the width of the render
/// object.
double get xRadius => _xRadius;
double _xRadius;
void set xRadius (double newXRadius) {
assert(newXRadius != null);
if (_xRadius == newXRadius)
return;
_xRadius = newXRadius;
markNeedsPaint();
}
/// The radius of the rounded corners in the vertical direction in logical pixels.
///
/// Values are clamped to be between zero and half the height of the render
/// object.
double get yRadius => _yRadius;
double _yRadius;
void set yRadius (double newYRadius) {
assert(newYRadius != null);
if (_yRadius == newYRadius)
return;
_yRadius = newYRadius;
markNeedsPaint();
}
// TODO(ianh): either convert this to the CustomClipper world, or
// TODO(ianh): implement describeApproximatePaintClip for this class
void paint(PaintingContext context, Offset offset) {
if (child != null) {
Rect rect = Point.origin & size;
RRect rrect = new RRect.fromRectXY(rect, xRadius, yRadius);
context.pushClipRRect(needsCompositing, offset, rect, rrect, super.paint);
}
}
}
/// Clips its child using an oval.
///
/// Inscribes an oval into its layout dimensions and prevents its child from
/// painting outside that oval.
class RenderClipOval extends _RenderCustomClip<Rect> {
RenderClipOval({
RenderBox child,
CustomClipper<Rect> clipper
}) : super(child: child, clipper: clipper);
Rect _cachedRect;
Path _cachedPath;
Path _getClipPath(Rect rect) {
if (rect != _cachedRect) {
_cachedRect = rect;
_cachedPath = new Path()..addOval(_cachedRect);
}
return _cachedPath;
}
Rect get _defaultClip => Point.origin & size;
bool hitTest(HitTestResult result, { Point position }) {
Rect clipBounds = _clip;
Point center = clipBounds.center;
// convert the position to an offset from the center of the unit circle
Offset offset = new Offset((position.x - center.x) / clipBounds.width,
(position.y - center.y) / clipBounds.height);
// check if the point is outside the unit circle
if (offset.distanceSquared > 0.25) // x^2 + y^2 > r^2
return false;
return super.hitTest(result, position: position);
}
void paint(PaintingContext context, Offset offset) {
if (child != null) {
Rect clipBounds = _clip;
context.pushClipPath(needsCompositing, offset, clipBounds, _getClipPath(clipBounds), super.paint);
}
}
}
/// Where to paint a box decoration.
enum DecorationPosition {
/// Paint the box decoration behind the children.
background,
/// Paint the box decoration in front of the children.
foreground,
}
/// Paints a [Decoration] either before or after its child paints.
class RenderDecoratedBox extends RenderProxyBox {
RenderDecoratedBox({
Decoration decoration,
DecorationPosition position: DecorationPosition.background,
RenderBox child
}) : _decoration = decoration,
_position = position,
super(child) {
assert(decoration != null);
assert(position != null);
}
BoxPainter _painter;
/// What decoration to paint.
Decoration get decoration => _decoration;
Decoration _decoration;
void set decoration (Decoration newDecoration) {
assert(newDecoration != null);
if (newDecoration == _decoration)
return;
_removeListenerIfNeeded();
_painter = null;
_decoration = newDecoration;
_addListenerIfNeeded();
markNeedsPaint();
}
/// Where to paint the box decoration.
DecorationPosition get position => _position;
DecorationPosition _position;
void set position (DecorationPosition newPosition) {
assert(newPosition != null);
if (newPosition == _position)
return;
_position = newPosition;
markNeedsPaint();
}
bool get _needsListeners {
return attached && _decoration.needsListeners;
}
void _addListenerIfNeeded() {
if (_needsListeners)
_decoration.addChangeListener(markNeedsPaint);
}
void _removeListenerIfNeeded() {
if (_needsListeners)
_decoration.removeChangeListener(markNeedsPaint);
}
void attach() {
super.attach();
_addListenerIfNeeded();
}
void detach() {
_removeListenerIfNeeded();
super.detach();
}
bool hitTestSelf(Point position) {
return _decoration.hitTest(size, position);
}
void paint(PaintingContext context, Offset offset) {
assert(size.width != null);
assert(size.height != null);
_painter ??= _decoration.createBoxPainter();
if (position == DecorationPosition.background)
_painter.paint(context.canvas, offset & size);
super.paint(context, offset);
if (position == DecorationPosition.foreground)
_painter.paint(context.canvas, offset & size);
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('decoration:');
description.addAll(_decoration.toString(" ").split('\n'));
}
}
/// Applies a transformation before painting its child.
class RenderTransform extends RenderProxyBox {
RenderTransform({
Matrix4 transform,
Offset origin,
FractionalOffset alignment,
this.transformHitTests: true,
RenderBox child
}) : super(child) {
assert(transform != null);
assert(alignment == null || (alignment.dx != null && alignment.dy != null));
this.transform = transform;
this.alignment = alignment;
this.origin = origin;
}
/// The origin of the coordinate system (relative to the upper left corder of
/// this render object) in which to apply the matrix.
///
/// Setting an origin is equivalent to conjugating the transform matrix by a
/// translation. This property is provided just for convenience.
Offset get origin => _origin;
Offset _origin;
void set origin (Offset newOrigin) {
if (_origin == newOrigin)
return;
_origin = newOrigin;
markNeedsPaint();
}
/// The alignment of the origin, relative to the size of the box.
///
/// This is equivalent to setting an origin based on the size of the box.
/// If it is specificed at the same time as an offset, both are applied.
FractionalOffset get alignment => _alignment;
FractionalOffset _alignment;
void set alignment (FractionalOffset newAlignment) {
assert(newAlignment == null || (newAlignment.dx != null && newAlignment.dy != null));
if (_alignment == newAlignment)
return;
_alignment = newAlignment;
markNeedsPaint();
}
/// When set to true, hit tests are performed based on the position of the
/// child as it is painted. When set to false, hit tests are performed
/// ignoring the transformation.
///
/// applyPaintTransform(), and therefore localToGlobal() and globalToLocal(),
/// always honor the transformation, regardless of the value of this property.
bool transformHitTests;
// Note the lack of a getter for transform because Matrix4 is not immutable
Matrix4 _transform;
/// The matrix to transform the child by during painting.
void set transform(Matrix4 newTransform) {
assert(newTransform != null);
if (_transform == newTransform)
return;
_transform = new Matrix4.copy(newTransform);
markNeedsPaint();
}
/// Sets the transform to the identity matrix.
void setIdentity() {
_transform.setIdentity();
markNeedsPaint();
}
/// Concatenates a rotation about the x axis into the transform.
void rotateX(double radians) {
_transform.rotateX(radians);
markNeedsPaint();
}
/// Concatenates a rotation about the y axis into the transform.
void rotateY(double radians) {
_transform.rotateY(radians);
markNeedsPaint();
}
/// Concatenates a rotation about the z axis into the transform.
void rotateZ(double radians) {
_transform.rotateZ(radians);
markNeedsPaint();
}
/// Concatenates a translation by (x, y, z) into the transform.
void translate(double x, [double y = 0.0, double z = 0.0]) {
_transform.translate(x, y, z);
markNeedsPaint();
}
/// Concatenates a scale into the transform.
void scale(double x, [double y, double z]) {
_transform.scale(x, y, z);
markNeedsPaint();
}
Matrix4 get _effectiveTransform {
if (_origin == null && _alignment == null)
return _transform;
Matrix4 result = new Matrix4.identity();
if (_origin != null)
result.translate(_origin.dx, _origin.dy);
Offset translation;
if (_alignment != null) {
translation = _alignment.alongSize(size);
result.translate(translation.dx, translation.dy);
}
result.multiply(_transform);
if (_alignment != null)
result.translate(-translation.dx, -translation.dy);
if (_origin != null)
result.translate(-_origin.dx, -_origin.dy);
return result;
}
bool hitTest(HitTestResult result, { Point position }) {
if (transformHitTests) {
Matrix4 inverse;
try {
inverse = new Matrix4.inverted(_effectiveTransform);
} catch (e) {
// We cannot invert the effective transform. That means the child
// doesn't appear on screen and cannot be hit.
return false;
}
Vector3 position3 = new Vector3(position.x, position.y, 0.0);
Vector3 transformed3 = inverse.transform3(position3);
position = new Point(transformed3.x, transformed3.y);
}
return super.hitTest(result, position: position);
}
void paint(PaintingContext context, Offset offset) {
if (child != null) {
Matrix4 transform = _effectiveTransform;
Offset childOffset = MatrixUtils.getAsTranslation(transform);
if (childOffset == null)
context.pushTransform(needsCompositing, offset, transform, super.paint);
else
super.paint(context, offset + childOffset);
}
}
void applyPaintTransform(RenderBox child, Matrix4 transform) {
transform.multiply(_effectiveTransform);
super.applyPaintTransform(child, transform);
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('transform matrix:');
description.addAll(debugDescribeTransform(_transform));
description.add('origin: $origin');
description.add('alignment: $alignment');
description.add('transformHitTests: $transformHitTests');
}
}
/// Applies a translation transformation before painting its child. The
/// translation is expressed as a [FractionalOffset] relative to the
/// RenderFractionalTranslation box's size. Hit tests will only be detected
/// inside the bounds of the RenderFractionalTranslation, even if the contents
/// are offset such that they overflow.
class RenderFractionalTranslation extends RenderProxyBox {
RenderFractionalTranslation({
FractionalOffset translation,
this.transformHitTests: true,
RenderBox child
}) : _translation = translation, super(child) {
assert(translation == null || (translation.dx != null && translation.dy != null));
}
/// The translation to apply to the child, as a multiple of the size.
FractionalOffset get translation => _translation;
FractionalOffset _translation;
void set translation (FractionalOffset newTranslation) {
assert(newTranslation == null || (newTranslation.dx != null && newTranslation.dy != null));
if (_translation == newTranslation)
return;
_translation = newTranslation;
markNeedsPaint();
}
/// When set to true, hit tests are performed based on the position of the
/// child as it is painted. When set to false, hit tests are performed
/// ignoring the transformation.
///
/// applyPaintTransform(), and therefore localToGlobal() and globalToLocal(),
/// always honor the transformation, regardless of the value of this property.
bool transformHitTests;
bool hitTest(HitTestResult result, { Point position }) {
assert(!needsLayout);
if (transformHitTests)
position = new Point(position.x - translation.dx * size.width, position.y - translation.dy * size.height);
return super.hitTest(result, position: position);
}
void paint(PaintingContext context, Offset offset) {
assert(!needsLayout);
if (child != null)
super.paint(context, offset + translation.alongSize(size));
}
void applyPaintTransform(RenderBox child, Matrix4 transform) {
transform.translate(translation.dx * size.width, translation.dy * size.height);
super.applyPaintTransform(child, transform);
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('translation: $translation');
description.add('transformHitTests: $transformHitTests');
}
}
abstract class CustomPainter {
const CustomPainter();
void paint(Canvas canvas, Size size);
bool shouldRepaint(CustomPainter oldDelegate);
bool hitTest(Point position) => null;
}
/// Delegates its painting
///
/// When asked to paint, custom paint first asks painter to paint with the
/// current canvas and then paints its children. After painting its children,
/// custom paint asks foregroundPainter to paint. The coodinate system of the
/// canvas matches the coordinate system of the custom paint object. The
/// painters are expected to paint within a rectangle starting at the origin
/// and encompassing a region of the given size. If the painters paints outside
/// those bounds, there might be insufficient memory allocated to rasterize the
/// painting commands and the resulting behavior is undefined.
///
/// Because custom paint calls its painters during paint, you cannot dirty
/// layout or paint information during the callback.
class RenderCustomPaint extends RenderProxyBox {
RenderCustomPaint({
CustomPainter painter,
CustomPainter foregroundPainter,
RenderBox child
}) : _painter = painter, _foregroundPainter = foregroundPainter, super(child);
CustomPainter get painter => _painter;
CustomPainter _painter;
void set painter (CustomPainter newPainter) {
if (_painter == newPainter)
return;
CustomPainter oldPainter = _painter;
_painter = newPainter;
_checkForRepaint(_painter, oldPainter);
}
CustomPainter get foregroundPainter => _foregroundPainter;
CustomPainter _foregroundPainter;
void set foregroundPainter (CustomPainter newPainter) {
if (_foregroundPainter == newPainter)
return;
CustomPainter oldPainter = _foregroundPainter;
_foregroundPainter = newPainter;
_checkForRepaint(_foregroundPainter, oldPainter);
}
void _checkForRepaint(CustomPainter newPainter, CustomPainter oldPainter) {
if (newPainter == null) {
assert(oldPainter != null); // We should be called only for changes.
markNeedsPaint();
} else if (oldPainter == null ||
newPainter.runtimeType != oldPainter.runtimeType ||
newPainter.shouldRepaint(oldPainter)) {
markNeedsPaint();
}
}
bool hitTestChildren(HitTestResult result, { Point position }) {
if (_foregroundPainter != null && (_foregroundPainter.hitTest(position) ?? false))
return true;
return super.hitTestChildren(result, position: position);
}
bool hitTestSelf(Point position) {
return _painter != null && (_painter.hitTest(position) ?? true);
}
void _paintWithPainter(Canvas canvas, Offset offset, CustomPainter painter) {
int debugPreviousCanvasSaveCount;
canvas.save();
assert(() { debugPreviousCanvasSaveCount = canvas.getSaveCount(); return true; });
canvas.translate(offset.dx, offset.dy);
painter.paint(canvas, size);
assert(() {
// This isn't perfect. For example, we can't catch the case of
// someone first restoring, then setting a transform or whatnot,
// then saving.
// If this becomes a real problem, we could add logic to the
// Canvas class to lock the canvas at a particular save count
// such that restore() fails if it would take the lock count
// below that number.
int debugNewCanvasSaveCount = canvas.getSaveCount();
if (debugNewCanvasSaveCount > debugPreviousCanvasSaveCount) {
throw new RenderingError(
'The $painter custom painter called canvas.save() or canvas.saveLayer() at least '
'${debugNewCanvasSaveCount - debugPreviousCanvasSaveCount} more '
'time${debugNewCanvasSaveCount - debugPreviousCanvasSaveCount == 1 ? '' : 's' } '
'than it called canvas.restore().\n'
'This leaves the canvas in an inconsistent state and will probably result in a broken display.\n'
'You must pair each call to save()/saveLayer() with a later matching call to restore().'
);
}
if (debugNewCanvasSaveCount < debugPreviousCanvasSaveCount) {
throw new RenderingError(
'The $painter custom painter called canvas.restore() '
'${debugPreviousCanvasSaveCount - debugNewCanvasSaveCount} more '
'time${debugPreviousCanvasSaveCount - debugNewCanvasSaveCount == 1 ? '' : 's' } '
'than it called canvas.save() or canvas.saveLayer().\n'
'This leaves the canvas in an inconsistent state and will result in a broken display.\n'
'You should only call restore() if you first called save() or saveLayer().'
);
}
return debugNewCanvasSaveCount == debugPreviousCanvasSaveCount;
});
canvas.restore();
}
void paint(PaintingContext context, Offset offset) {
if (_painter != null)
_paintWithPainter(context.canvas, offset, _painter);
super.paint(context, offset);
if (_foregroundPainter != null)
_paintWithPainter(context.canvas, offset, _foregroundPainter);
}
}
typedef void PointerDownEventListener(PointerDownEvent event);
typedef void PointerMoveEventListener(PointerMoveEvent event);
typedef void PointerUpEventListener(PointerUpEvent event);
typedef void PointerCancelEventListener(PointerCancelEvent event);
/// Invokes the callbacks in response to pointer events.
class RenderPointerListener extends RenderProxyBoxWithHitTestBehavior {
RenderPointerListener({
this.onPointerDown,
this.onPointerMove,
this.onPointerUp,
this.onPointerCancel,
HitTestBehavior behavior: HitTestBehavior.deferToChild,
RenderBox child
}) : super(behavior: behavior, child: child);
PointerDownEventListener onPointerDown;
PointerMoveEventListener onPointerMove;
PointerUpEventListener onPointerUp;
PointerCancelEventListener onPointerCancel;
void handleEvent(PointerEvent event, HitTestEntry entry) {
if (onPointerDown != null && event is PointerDownEvent)
return onPointerDown(event);
if (onPointerMove != null && event is PointerMoveEvent)
return onPointerMove(event);
if (onPointerUp != null && event is PointerUpEvent)
return onPointerUp(event);
if (onPointerCancel != null && event is PointerCancelEvent)
return onPointerCancel(event);
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
List<String> listeners = <String>[];
if (onPointerDown != null)
listeners.add('down');
if (onPointerMove != null)
listeners.add('move');
if (onPointerUp != null)
listeners.add('up');
if (onPointerCancel != null)
listeners.add('cancel');
if (listeners.isEmpty)
listeners.add('<none>');
description.add('listeners: ${listeners.join(", ")}');
}
}
/// Creates a separate display list for its child.
///
/// This render object creates a separate display list for its child, which
/// can improve performance if the subtree repaints at different times than
/// the surrounding parts of the tree. Specifically, when the child does not
/// repaint but its parent does, we can re-use the display list we recorded
/// previously. Similarly, when the child repaints but the surround tree does
/// not, we can re-record its display list without re-recording the display list
/// for the surround tree.
class RenderRepaintBoundary extends RenderProxyBox {
RenderRepaintBoundary({ RenderBox child }) : super(child);
bool get isRepaintBoundary => true;
}
/// Is invisible during hit testing.
///
/// When [ignoring] is true, this render object (and its subtree) is invisible
/// to hit testing. It still consumes space during layout and paints its child
/// as usual. It just cannot be the target of located events because it returns
/// false from [hitTest].
///
/// When [ignoringSemantics] is true, the subtree will be invisible to
/// the semantics layer (and thus e.g. accessibility tools). If
/// [ignoringSemantics] is null, it uses the value of [ignoring].
class RenderIgnorePointer extends RenderProxyBox {
RenderIgnorePointer({
RenderBox child,
bool ignoring: true,
bool ignoringSemantics
}) : _ignoring = ignoring, _ignoringSemantics = ignoringSemantics, super(child) {
assert(_ignoring != null);
}
bool get ignoring => _ignoring;
bool _ignoring;
void set ignoring(bool value) {
assert(value != null);
if (value == _ignoring)
return;
_ignoring = value;
if (ignoringSemantics == null)
markNeedsSemanticsUpdate();
}
bool get ignoringSemantics => _ignoringSemantics;
bool _ignoringSemantics;
void set ignoringSemantics(bool value) {
if (value == _ignoringSemantics)
return;
bool oldEffectiveValue = _effectiveIgnoringSemantics;
_ignoringSemantics = value;
if (oldEffectiveValue != _effectiveIgnoringSemantics)
markNeedsSemanticsUpdate();
}
bool get _effectiveIgnoringSemantics => ignoringSemantics == null ? ignoring : ignoringSemantics;
bool hitTest(HitTestResult result, { Point position }) {
return ignoring ? false : super.hitTest(result, position: position);
}
// TODO(ianh): figure out a way to still include labels and flags in
// descendants, just make them non-interactive, even when
// _effectiveIgnoringSemantics is true
void visitChildrenForSemantics(RenderObjectVisitor visitor) {
if (child != null && !_effectiveIgnoringSemantics)
visitor(child);
}
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('ignoring: $ignoring');
description.add('ignoringSemantics: ${ ignoringSemantics == null ? "implicitly " : "" }$_effectiveIgnoringSemantics');
}
}
/// Holds opaque meta data in the render tree.
class RenderMetaData extends RenderProxyBoxWithHitTestBehavior {
RenderMetaData({
this.metaData,
HitTestBehavior behavior: HitTestBehavior.deferToChild,
RenderBox child
}) : super(behavior: behavior, child: child);
/// Opaque meta data ignored by the render tree
dynamic metaData;
void debugFillDescription(List<String> description) {
super.debugFillDescription(description);
description.add('metaData: $metaData');
}
}
/// Listens for the specified gestures from the semantics server (e.g.
/// an accessibility tool).
class RenderSemanticsGestureHandler extends RenderProxyBox implements SemanticActionHandler {
RenderSemanticsGestureHandler({
RenderBox child,
GestureTapCallback onTap,
GestureLongPressCallback onLongPress,
GestureDragUpdateCallback onHorizontalDragUpdate,
GestureDragUpdateCallback onVerticalDragUpdate,
this.scrollFactor: 0.8
}) : _onTap = onTap,
_onLongPress = onLongPress,
_onHorizontalDragUpdate = onHorizontalDragUpdate,
_onVerticalDragUpdate = onVerticalDragUpdate,
super(child);
GestureTapCallback get onTap => _onTap;
GestureTapCallback _onTap;
void set onTap(GestureTapCallback value) {
if (_onTap == value)
return;
bool didHaveSemantics = hasSemantics;
bool hadHandler = _onTap != null;
_onTap = value;
if ((value != null) != hadHandler)
markNeedsSemanticsUpdate(onlyChanges: hasSemantics == didHaveSemantics);
}
GestureLongPressCallback get onLongPress => _onLongPress;
GestureLongPressCallback _onLongPress;
void set onLongPress(GestureLongPressCallback value) {
if (_onLongPress == value)
return;
bool didHaveSemantics = hasSemantics;
bool hadHandler = _onLongPress != null;
_onLongPress = value;
if ((value != null) != hadHandler)
markNeedsSemanticsUpdate(onlyChanges: hasSemantics == didHaveSemantics);
}
GestureDragUpdateCallback get onHorizontalDragUpdate => _onHorizontalDragUpdate;
GestureDragUpdateCallback _onHorizontalDragUpdate;
void set onHorizontalDragUpdate(GestureDragUpdateCallback value) {
if (_onHorizontalDragUpdate == value)
return;
bool didHaveSemantics = hasSemantics;
bool hadHandler = _onHorizontalDragUpdate != null;
_onHorizontalDragUpdate = value;
if ((value != null) != hadHandler)
markNeedsSemanticsUpdate(onlyChanges: hasSemantics == didHaveSemantics);
}
GestureDragUpdateCallback get onVerticalDragUpdate => _onVerticalDragUpdate;
GestureDragUpdateCallback _onVerticalDragUpdate;
void set onVerticalDragUpdate(GestureDragUpdateCallback value) {
if (_onVerticalDragUpdate == value)
return;
bool didHaveSemantics = hasSemantics;
bool hadHandler = _onVerticalDragUpdate != null;
_onVerticalDragUpdate = value;
if ((value != null) != hadHandler)
markNeedsSemanticsUpdate(onlyChanges: hasSemantics == didHaveSemantics);
}
/// The fraction of the dimension of this render box to use when
/// scrolling. For example, if this is 0.8 and the box is 200 pixels
/// wide, then when a left-scroll action is received from the
/// accessibility system, it will translate into a 160 pixel
/// leftwards drag.
double scrollFactor;
bool get hasSemantics {
return onTap != null
|| onLongPress != null
|| onHorizontalDragUpdate != null
|| onVerticalDragUpdate != null;
}
Iterable<SemanticAnnotator> getSemanticAnnotators() sync* {
if (hasSemantics) {
yield (SemanticsNode semantics) {
semantics.canBeTapped = onTap != null;
semantics.canBeLongPressed = onLongPress != null;
semantics.canBeScrolledHorizontally = onHorizontalDragUpdate != null;
semantics.canBeScrolledVertically = onVerticalDragUpdate != null;
};
}
}
void handleSemanticTap() {
if (onTap != null)
onTap();
}
void handleSemanticLongPress() {
if (onLongPress != null)
onLongPress();
}
void handleSemanticScrollLeft() {
if (onHorizontalDragUpdate != null)
onHorizontalDragUpdate(size.width * -scrollFactor);
}
void handleSemanticScrollRight() {
if (onHorizontalDragUpdate != null)
onHorizontalDragUpdate(size.width * scrollFactor);
}
void handleSemanticScrollUp() {
if (onVerticalDragUpdate != null)
onVerticalDragUpdate(size.height * -scrollFactor);
}
void handleSemanticScrollDown() {
if (onVerticalDragUpdate != null)
onVerticalDragUpdate(size.height * scrollFactor);
}
}
/// Add annotations to the SemanticsNode for this subtree.
class RenderSemanticAnnotations extends RenderProxyBox {
RenderSemanticAnnotations({
RenderBox child,
bool container: false,
bool checked,
String label
}) : _container = container,
_checked = checked,
_label = label,
super(child) {
assert(container != null);
}
/// If 'container' is true, this RenderObject will introduce a new
/// node in the semantics tree. Otherwise, the semantics will be
/// merged with the semantics of any ancestors.
///
/// The 'container' flag is implicitly set to true on the immediate
/// semantics-providing descendants of a node where multiple
/// children have semantics or have descendants providing semantics.
/// In other words, the semantics of siblings are not merged. To
/// merge the semantics of an entire subtree, including siblings,
/// you can use a [RenderMergeSemantics].
bool get container => _container;
bool _container;
void set container(bool value) {
assert(value != null);
if (container == value)
return;
_container = value;
markNeedsSemanticsUpdate();
}
/// If non-null, sets the "hasCheckedState" semantic to true and the
/// "isChecked" semantic to the given value.
bool get checked => _checked;
bool _checked;
void set checked(bool value) {
if (checked == value)
return;
bool hadValue = checked != null;
_checked = value;
markNeedsSemanticsUpdate(onlyChanges: (value != null) == hadValue);
}
/// If non-null, sets the "label" semantic to the given value.
String get label => _label;
String _label;
void set label(String value) {
if (label == value)
return;
bool hadValue = label != null;
_label = value;
markNeedsSemanticsUpdate(onlyChanges: (value != null) == hadValue);
}
bool get hasSemantics => container;
Iterable<SemanticAnnotator> getSemanticAnnotators() sync* {
if (checked != null) {
yield (SemanticsNode semantics) {
semantics.hasCheckedState = true;
semantics.isChecked = checked;
};
}
if (label != null) {
yield (SemanticsNode semantics) {
semantics.label = label;
};
}
}
}
/// Causes the semantics of all descendants to be merged into this
/// node such that the entire subtree becomes a single leaf in the
/// semantics tree.
///
/// Useful for combining the semantics of multiple render objects that
/// form part of a single conceptual widget, e.g. a checkbox, a label,
/// and the gesture detector that goes with them.
class RenderMergeSemantics extends RenderProxyBox {
RenderMergeSemantics({ RenderBox child }) : super(child);
Iterable<SemanticAnnotator> getSemanticAnnotators() sync* {
yield (SemanticsNode node) { node.mergeAllDescendantsIntoThisNode = true; };
}
}
/// Excludes this subtree from the semantic tree.
///
/// Useful e.g. for hiding text that is redundant with other text next
/// to it (e.g. text included only for the visual effect).
class RenderExcludeSemantics extends RenderProxyBox {
RenderExcludeSemantics({ RenderBox child }) : super(child);
void visitChildrenForSemantics(RenderObjectVisitor visitor) { }
}