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//---------------------------------------------------------------------------
//
// Copyright (C) Microsoft Corporation. All rights reserved.
//
// File: Viewbox.cs
//
// Description: Contains the Viewbox Decorator class.
// Spec at http://avalon/layout/Specs/Viewbox.xml
//
// History:
// 09/25/2003 : greglett - Added to PDC_DEMO branch.
// 06/09/2004 : t-jaredg - Updated with according to new specs
//
//---------------------------------------------------------------------------
using MS.Internal;
using MS.Utility;
using MS.Internal.Controls;
using MS.Internal.Telemetry.PresentationFramework;
using System.Diagnostics;
using System.Collections;
using System.Windows.Threading;
using System.Windows.Media;
using System.Windows.Documents;
using System;
namespace System.Windows.Controls
{
#region StretchDirection enum type
/// <summary>
/// StretchDirection - Enum which describes when scaling should be used on the content of a Viewbox. This
/// enum restricts the scaling factors along various axes.
/// </summary>
/// <seealso cref="Viewbox" />
public enum StretchDirection
{
/// <summary>
/// Only scales the content upwards when the content is smaller than the Viewbox.
/// If the content is larger, no scaling downwards is done.
/// </summary>
UpOnly,
/// <summary>
/// Only scales the content downwards when the content is larger than the Viewbox.
/// If the content is smaller, no scaling upwards is done.
/// </summary>
DownOnly,
/// <summary>
/// Always stretches to fit the Viewbox according to the stretch mode.
/// </summary>
Both
}
#endregion
/// <summary>
/// </summary>
public class Viewbox : Decorator
{
//-------------------------------------------------------------------
//
// Constructors
//
//-------------------------------------------------------------------
#region Constructors
static Viewbox()
{
ControlsTraceLogger.AddControl(TelemetryControls.ViewBox);
}
/// <summary>
/// Default DependencyObject constructor
/// </summary>
/// <remarks>
/// Automatic determination of current Dispatcher. Use alternative constructor
/// that accepts a Dispatcher for best performance.
/// </remarks>
public Viewbox() : base()
{
}
#endregion
//-------------------------------------------------------------------
//
// Public Fields
//
//-------------------------------------------------------------------
#region Public Fields
/// <summary>
/// This is the DependencyProperty for the Viewbox's Stretch property.
///
/// Default: Stretch.Uniform
/// <seealso cref="Viewbox.Stretch" />
/// </summary>
public static readonly DependencyProperty StretchProperty
= DependencyProperty.Register(
"Stretch", // Property name
typeof(Stretch), // Property type
typeof(Viewbox), // Property owner
new FrameworkPropertyMetadata(Stretch.Uniform, FrameworkPropertyMetadataOptions.AffectsMeasure),
new ValidateValueCallback(ValidateStretchValue));
private static bool ValidateStretchValue(object value)
{
Stretch s = (Stretch)value;
return ( s == Stretch.Uniform
|| s == Stretch.None
|| s == Stretch.Fill
|| s == Stretch.UniformToFill);
}
/// <summary>
/// This is the DependencyProperty for the Viewbox's StretchDirection property.
/// Default: StretchDirection.Both
/// <seealso cref="Viewbox.StretchDirection" />
/// </summary>
public static readonly DependencyProperty StretchDirectionProperty
= DependencyProperty.Register(
"StretchDirection", // Property name
typeof(StretchDirection), // Property type
typeof(Viewbox), // Property owner
new FrameworkPropertyMetadata(StretchDirection.Both, FrameworkPropertyMetadataOptions.AffectsMeasure),
new ValidateValueCallback(ValidateStretchDirectionValue));
private static bool ValidateStretchDirectionValue(object value)
{
StretchDirection sd = (StretchDirection)value;
return ( sd == StretchDirection.Both
|| sd == StretchDirection.DownOnly
|| sd == StretchDirection.UpOnly);
}
#endregion
//-------------------------------------------------------------------
//
// Public Methods
//
//-------------------------------------------------------------------
//-------------------------------------------------------------------
//
// Public Properties
//
//-------------------------------------------------------------------
#region Public Properties
private ContainerVisual InternalVisual
{
get
{
if(_internalVisual == null)
{
_internalVisual = new ContainerVisual();
AddVisualChild(_internalVisual);
}
return _internalVisual;
}
}
private UIElement InternalChild
{
get
{
VisualCollection vc = InternalVisual.Children;
if (vc.Count != 0) return vc[0] as UIElement;
else return null;
}
set
{
VisualCollection vc = InternalVisual.Children;
if (vc.Count != 0) vc.Clear();
vc.Add(value);
}
}
private Transform InternalTransform
{
get
{
return InternalVisual.Transform;
}
set
{
InternalVisual.Transform = value;
}
}
/// <summary>
/// The single child of a <see cref="Viewbox" />
/// </summary>
public override UIElement Child
{
//everything is the same as on Decorator, the only difference is to insert intermediate Visual to
//specify scaling transform
get
{
return InternalChild;
}
set
{
UIElement old = InternalChild;
if(old != value)
{
//need to remove old element from logical tree
RemoveLogicalChild(old);
if(value != null)
{
AddLogicalChild(value);
}
InternalChild = value;
InvalidateMeasure();
}
}
}
/// <summary>
/// Returns the Visual children count.
/// </summary>
protected override int VisualChildrenCount
{
get { return 1; /* Always have internal container visual */ }
}
/// <summary>
/// Returns the child at the specified index.
/// </summary>
protected override Visual GetVisualChild(int index)
{
if (index != 0)
{
throw new ArgumentOutOfRangeException("index", index, SR.Get(SRID.Visual_ArgumentOutOfRange));
}
return InternalVisual;
}
/// <summary>
/// Returns enumerator to logical children.
/// </summary>
protected internal override IEnumerator LogicalChildren
{
get
{
if (InternalChild == null)
{
return EmptyEnumerator.Instance;
}
return new SingleChildEnumerator(InternalChild);
}
}
/// <summary>
/// Gets/Sets the Stretch mode of the Viewbox, which determines how the content will be
/// fit into the Viewbox's space.
///
/// </summary>
/// <seealso cref="Viewbox.StretchProperty" />
/// <seealso cref="Stretch" />
public Stretch Stretch
{
get { return (Stretch)GetValue(StretchProperty); }
set { SetValue(StretchProperty, value); }
}
/// <summary>
/// Gets/Sets the stretch direction of the Viewbox, which determines the restrictions on
/// scaling that are applied to the content inside the Viewbox. For instance, this property
/// can be used to prevent the content from being smaller than its native size or larger than
/// its native size.
/// </summary>
/// <seealso cref="Viewbox.StretchDirectionProperty" />
public StretchDirection StretchDirection
{
get { return (StretchDirection)GetValue(StretchDirectionProperty); }
set { SetValue(StretchDirectionProperty, value); }
}
#endregion Public Properties
//-------------------------------------------------------------------
//
// Protected Methods
//
//-------------------------------------------------------------------
#region Protected Methods
/// <summary>
/// Updates DesiredSize of the Viewbox. Called by parent UIElement. This is the first pass of layout.
/// </summary>
/// <remarks>
/// Viewbox measures it's child at an infinite constraint; it allows the child to be however large it so desires.
/// The child's returned size will be used as it's natural size for scaling to Viewbox's size during Arrange.
/// </remarks>
/// <param name="constraint">Constraint size is an "upper limit" that the return value should not exceed.</param>
/// <returns>The Decorator's desired size.</returns>
protected override Size MeasureOverride(Size constraint)
{
UIElement child = InternalChild;
Size parentSize = new Size();
if (child != null)
{
// Initialize child constraint to infinity. We need to get a "natural" size for the child in absence of constraint.
// Note that an author *can* impose a constraint on a child by using Height/Width, &c... properties
Size infinteConstraint = new Size(Double.PositiveInfinity, Double.PositiveInfinity);
child.Measure(infinteConstraint);
Size childSize = child.DesiredSize;
Size scalefac = ComputeScaleFactor(constraint, childSize, this.Stretch, this.StretchDirection);
parentSize.Width = scalefac.Width * childSize.Width;
parentSize.Height = scalefac.Height * childSize.Height;
}
return parentSize;
}
/// <summary>
/// Viewbox always sets the child to its desired size. It then computes and applies a transformation
/// from that size to the space available: Viewbox's own input size less child margin.
///
/// Viewbox also calls arrange on its child.
/// </summary>
/// <param name="arrangeSize">Size in which Border will draw the borders/background and children.</param>
protected override Size ArrangeOverride(Size arrangeSize)
{
UIElement child = InternalChild;
if (child != null)
{
Size childSize = child.DesiredSize;
// Compute scaling factors from arrange size and the measured child content size
Size scalefac = ComputeScaleFactor(arrangeSize, childSize, this.Stretch, this.StretchDirection);
InternalTransform = new ScaleTransform(scalefac.Width, scalefac.Height);
// Arrange the child to the desired size
child.Arrange(new Rect(new Point(), child.DesiredSize));
//return the size oocupied by scaled child
arrangeSize.Width = scalefac.Width * childSize.Width;
arrangeSize.Height = scalefac.Height * childSize.Height;
}
return arrangeSize;
}
/// <summary>
/// This is a helper function that computes scale factors depending on a target size and a content size
/// </summary>
/// <param name="availableSize">Size into which the content is being fitted.</param>
/// <param name="contentSize">Size of the content, measured natively (unconstrained).</param>
/// <param name="stretch">Value of the Stretch property on the element.</param>
/// <param name="stretchDirection">Value of the StretchDirection property on the element.</param>
internal static Size ComputeScaleFactor(Size availableSize,
Size contentSize,
Stretch stretch,
StretchDirection stretchDirection)
{
// Compute scaling factors to use for axes
double scaleX = 1.0;
double scaleY = 1.0;
bool isConstrainedWidth = !Double.IsPositiveInfinity(availableSize.Width);
bool isConstrainedHeight = !Double.IsPositiveInfinity(availableSize.Height);
if ( (stretch == Stretch.Uniform || stretch == Stretch.UniformToFill || stretch == Stretch.Fill)
&& (isConstrainedWidth || isConstrainedHeight) )
{
// Compute scaling factors for both axes
scaleX = (DoubleUtil.IsZero(contentSize.Width)) ? 0.0 : availableSize.Width / contentSize.Width;
scaleY = (DoubleUtil.IsZero(contentSize.Height)) ? 0.0 : availableSize.Height / contentSize.Height;
if (!isConstrainedWidth) scaleX = scaleY;
else if (!isConstrainedHeight) scaleY = scaleX;
else
{
// If not preserving aspect ratio, then just apply transform to fit
switch (stretch)
{
case Stretch.Uniform: //Find minimum scale that we use for both axes
double minscale = scaleX < scaleY ? scaleX : scaleY;
scaleX = scaleY = minscale;
break;
case Stretch.UniformToFill: //Find maximum scale that we use for both axes
double maxscale = scaleX > scaleY ? scaleX : scaleY;
scaleX = scaleY = maxscale;
break;
case Stretch.Fill: //We already computed the fill scale factors above, so just use them
break;
}
}
//Apply stretch direction by bounding scales.
//In the uniform case, scaleX=scaleY, so this sort of clamping will maintain aspect ratio
//In the uniform fill case, we have the same result too.
//In the fill case, note that we change aspect ratio, but that is okay
switch(stretchDirection)
{
case StretchDirection.UpOnly:
if (scaleX < 1.0) scaleX = 1.0;
if (scaleY < 1.0) scaleY = 1.0;
break;
case StretchDirection.DownOnly:
if (scaleX > 1.0) scaleX = 1.0;
if (scaleY > 1.0) scaleY = 1.0;
break;
case StretchDirection.Both:
break;
default:
break;
}
}
//Return this as a size now
return new Size(scaleX, scaleY);
}
#endregion Protected Methods
//-------------------------------------------------------------------
//
// Private Fields
//
//-------------------------------------------------------------------
#region Private Fields
private ContainerVisual _internalVisual;
#endregion
}
}
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