public XmlRenderer(System.Windows.Size size)
{
Size = size;
m_stream = new MemoryStream();
m_writer = new XmlTextWriter(m_stream, Encoding.UTF8);
m_writer.Formatting = Formatting.Indented;
}
public static Uri Create(string filename, string text, SolidColorBrush backgroundColor, double textSize, Size size)
{
var background = new Rectangle();
background.Width = size.Width;
background.Height = size.Height;
background.Fill = backgroundColor;
var textBlock = new TextBlock();
textBlock.Width = 500;
textBlock.Height = 500;
textBlock.TextWrapping = TextWrapping.Wrap;
textBlock.Text = text;
textBlock.FontSize = textSize;
textBlock.Foreground = new SolidColorBrush(Colors.White);
textBlock.FontFamily = new FontFamily("Segoe WP");
var tileImage = "/Shared/ShellContent/" + filename;
using (IsolatedStorageFile store = IsolatedStorageFile.GetUserStoreForApplication())
{
var bitmap = new WriteableBitmap((int)size.Width, (int)size.Height);
bitmap.Render(background, new TranslateTransform());
bitmap.Render(textBlock, new TranslateTransform() { X = 39, Y = 88 });
var stream = store.CreateFile(tileImage);
bitmap.Invalidate();
bitmap.SaveJpeg(stream, (int)size.Width, (int)size.Height, 0, 99);
stream.Close();
}
return new Uri("ms-appdata:///local" + tileImage, UriKind.Absolute);
}
protected override void OnRender(DrawingContext dc)
{
Size size = new Size(base.ActualWidth, base.ActualHeight);
int tickCount = (int)((this.Maximum - this.Minimum) / this.TickFrequency) + 1;
if ((this.Maximum - this.Minimum) % this.TickFrequency == 0)
tickCount -= 1;
Double tickFrequencySize;
// Calculate tick's setting
tickFrequencySize = (size.Width * this.TickFrequency / (this.Maximum - this.Minimum));
string text = "";
FormattedText formattedText = null;
double num = this.Maximum - this.Minimum;
int i = 0;
// Draw each tick text
for (i = 0; i <= tickCount; i++)
{
text = Convert.ToString(Convert.ToInt32(this.Minimum + this.TickFrequency * i), 10);
//g.DrawString(text, font, brush, drawRect.Left + tickFrequencySize * i, drawRect.Top + drawRect.Height/2, stringFormat);
formattedText = new FormattedText(text, CultureInfo.GetCultureInfo("ru-Ru"), FlowDirection.LeftToRight, new Typeface("Arial"), 8, Brushes.Black);
dc.DrawText(formattedText, new Point((tickFrequencySize * i), 30));
}
}
/// <summary>
/// Prints this instance.
/// </summary>
public bool Print()
{
try
{
PrintDialog printDlg = new System.Windows.Controls.PrintDialog();
bool? results = printDlg.ShowDialog();
if (results == null || results == false) return false;
//get selected printer capabilities
System.Printing.PrintCapabilities capabilities = printDlg.PrintQueue.GetPrintCapabilities(printDlg.PrintTicket);
//get the size of the printer page
System.Windows.Size printSize = new System.Windows.Size(
capabilities.PageImageableArea.ExtentHeight, capabilities.PageImageableArea.ExtentWidth);
// Build print view
this.Height = printSize.Height;
this.Width = printSize.Width;
Measure(printSize);
Arrange(new System.Windows.Rect(printSize));
XpsDocumentWriter xpsdw = PrintQueue.CreateXpsDocumentWriter(printDlg.PrintQueue);
printDlg.PrintTicket.PageOrientation = PageOrientation.Landscape;
xpsdw.WriteAsync(this);
}
catch (Exception ex)
{
MessageBox.Show(ex.GetBaseException().Message, "Printing Error", MessageBoxButton.OK, MessageBoxImage.Error);
return false;
}
return true;
}
protected override Size ArrangeOverride(Size finalSize)
{
if (Children.Count == 0)
return finalSize;
var children = Children.OfType<UIElement>().ToArray();
var actualTop = 0d;
var currentNumOfChildrenInRow = 0;
foreach (var child in children)
{
child.Arrange(new Rect(
_elementWidth * currentNumOfChildrenInRow,
actualTop,
_elementWidth,
_elementHeight));
currentNumOfChildrenInRow++;
if (currentNumOfChildrenInRow != _maxElementPerRow)
continue;
actualTop += _elementHeight;
currentNumOfChildrenInRow = 0;
}
var size = new Size(
_elementWidth * _maxElementPerRow,
actualTop + _elementHeight);
size.Width = Math.Max(size.Width, finalSize.Width);
size.Height = Math.Max(size.Height, finalSize.Height);
return size;
}
protected override Size MeasureOverride(Size availableSize)
{
onPreApplyTemplate();
Size theChildSize = getItemSize();
foreach (UIElement child in Children)
{
child.Measure(theChildSize);
}
int childrenPerRow;
// Figure out how many children fit on each row
if (availableSize.Width == Double.PositiveInfinity)
{
childrenPerRow = this.Children.Count;
}
else
{
childrenPerRow = Math.Max(1, (int)Math.Floor(availableSize.Width / this.ItemWidth));
}
// Calculate the width and height this results in
double width = childrenPerRow * this.ItemWidth;
var fudge = (width - childrenPerRow * ItemWidth) / childrenPerRow;
double height = (this.ItemHeight +fudge )* (Math.Floor((double)(this.Children.Count +childrenPerRow - 1) / childrenPerRow) );
height = (height.IsValid()) ? height : 0;
return new Size(width, height);
}
protected override Size MeasureOverride(Size availableSize)
{
if (Children.Count == 0)
return new Size();
var children = Children.OfType<UIElement>().ToArray();
// Damit die Children eine DesiredSize haben, muss erstmal Measure gemacht werden
children.ForEachElement(it => it.Measure(availableSize));
// Was ist das breiteste / höchste Element?
var widestWidth = children.Max(it => it.DesiredSize.Width);
_elementHeight = children.Max(it => it.DesiredSize.Height);
// Wieviele Elemente bekommt man in eine Zeile?
_maxElementPerRow = (int)(availableSize.Width / widestWidth);
if (_maxElementPerRow == 0)
_maxElementPerRow = 1;
_elementWidth = availableSize.Width / _maxElementPerRow;
var resultingHeight = ((children.Count() - 1) / _maxElementPerRow + 1) * _elementHeight;
var desiredSize = new Size(availableSize.Width, resultingHeight);
return desiredSize;
}
protected override Size ArrangeOverride(Size finalSize)
{
if (GetValues(this) != null)
{
double total = 0.0;
for (int i = 0; i < InternalChildren.Count; i++)
{
total += (double)(GetValues(this)[i]);
}
double offsetAngle = 0.0;
double radius = finalSize.Width < finalSize.Height ? finalSize.Width / 2 : finalSize.Height / 2;
//radius -= 2;
Point beginFigure = new Point(finalSize.Width / 2, finalSize.Height / 2);
Point lineToBeforeTransform = new Point(beginFigure.X + radius, beginFigure.Y);
for (int i = 0; i < InternalChildren.Count; i++)
{
ContentControl container = InternalChildren[i] as ContentControl;
double wedgeAngle = (double)(GetValues(this)[i]) * 360 / total;
RotateTransform rt = new RotateTransform(offsetAngle, beginFigure.X, beginFigure.Y);
container.SetValue(PiePanel.BeginFigurePointProperty, beginFigure);
container.SetValue(PiePanel.LineToPointProperty, rt.Transform(lineToBeforeTransform));
container.SetValue(PiePanel.WedgeAngleProperty, wedgeAngle);
offsetAngle += wedgeAngle;
Rect r = new Rect(finalSize);
container.Arrange(r);
}
}
return finalSize;
}
private FixedPage CreateFifthPageContent()
{
//PageContent pageContent = new PageContent();
FixedPage fixedPage = new FixedPage();
UIElement visual = BuildDrawing(); // CreateThirdVisual(false);
FixedPage.SetLeft(visual, 0);
FixedPage.SetTop(visual, 0);
double pageWidth = 96 * 8.5;
double pageHeight = 96 * 11;
fixedPage.Width = pageWidth;
fixedPage.Height = pageHeight;
fixedPage.Children.Add((UIElement)visual);
Size sz = new Size(8.5 * 96, 11 * 96);
fixedPage.Measure(sz);
fixedPage.Arrange(new Rect(new Point(), sz));
fixedPage.UpdateLayout();
//((IAddChild)pageContent).AddChild(fixedPage);
return fixedPage;
}
/// <summary>
/// Overrides MeasureOverride
/// </summary>
/// <param name="availableSize"></param>
/// <returns></returns>
protected override Size MeasureOverride(Size availableSize)
{
if (Symbol is ESRI.ArcGIS.Client.Symbols.FillSymbol || Symbol is ESRI.ArcGIS.Client.Symbols.LineSymbol)
{
SetPath(availableSize);
return base.MeasureOverride(availableSize);
}
else if (Symbol is ESRI.ArcGIS.Client.Symbols.MarkerSymbol)
{
// Set the margin to null else the desiredsize would be impacted by this margin
// For example with a negative margin, the desired size is going towards 0 which can't be the right size of the swatch
UIElement child = GetChild();
if (child is FrameworkElement)
((FrameworkElement)child).Margin = new Thickness(0.0);
// Now measure without the margin
child.Measure(new Size(double.PositiveInfinity, double.PositiveInfinity));
Size size = child.DesiredSize;
// Take care of the child transform to define the size of the swatch
// For example with a scale of 2, the swatch size must be twice the desired size
// with a rotation, the swatch size must take care of this rotation
Transform childTransform = child == null ? null : child.RenderTransform;
if (childTransform != null)
{
Rect rect = childTransform.TransformBounds(new Rect(new Point(0, 0), size));
size.Height = rect.Height;
size.Width = rect.Width;
}
return size;
}
else return base.MeasureOverride(availableSize);
}
/// <summary>
/// Provides the behavior for the Arrange pass of Silverlight layout. Classes can override this method to define their own Arrange pass behavior.
/// </summary>
/// <param name="finalSize">The final area within the parent that this object should use to arrange itself and its children.</param>
/// <returns>
/// The actual size that is used after the element is arranged in layout.
/// </returns>
protected override Size ArrangeOverride(Size finalSize)
{
if (Symbol is ESRI.ArcGIS.Client.Symbols.MarkerSymbol)
{
UIElement child = GetChild();
Transform childTransform = child == null ? null : child.RenderTransform;
if (childTransform != null)
{
// Arrange the symbol following it's desired size, the final size which is taking care of the transform is not the good one
Size size = child.DesiredSize.Height == 0 && child.DesiredSize.Width == 0 ? finalSize : child.DesiredSize;
child.Arrange(new Rect(new Point(0, 0), size));
// Now we need to translate the symbol in order that the visual part of the symbol be in the snapshot
Rect rect = childTransform.TransformBounds(new Rect(new Point(0, 0), child.DesiredSize)); // visual position of the symbol after transformation
child.RenderTransformOrigin = new Point(0, 0); // for the swatch, the transform origin must be (0,0) whatever the transform origin used in the map
if (rect.X != 0 || rect.Y != 0)
RenderTransform = new TranslateTransform { X = -rect.X, Y = -rect.Y }; // Center the symbol
return finalSize;
}
}
return base.ArrangeOverride(finalSize);
}
/// <inheritdoc/>
protected override Size MeasureOverride(Size availableSize)
{
foreach (FoldingMarginMarker m in markers) {
m.Measure(availableSize);
}
return new Size(SizeFactor * (double)GetValue(TextBlock.FontSizeProperty), 0);
}
private void OnDragInitialize(object sender, DragInitializeEventArgs args)
{
args.AllowedEffects = DragDropEffects.All;
if (args.OriginalSource.GetType() == typeof(Telerik.Windows.Controls.RadListBoxItem))
{
var draggedShape = (args.OriginalSource as Telerik.Windows.Controls.RadListBoxItem).ChildrenOfType<RadDiagramShapeBase>().FirstOrDefault();
if (draggedShape != null)
{
var shapeSize = new Size(draggedShape.ActualWidth, draggedShape.ActualHeight);
if (shapeSize.Width > 0 && shapeSize.Height > 0)
{
var dropInfo = new DiagramDropInfo(shapeSize, SerializationService.Default.SerializeItems(new List<IDiagramItem> {draggedShape}));
args.Data = dropInfo;
args.DragVisualOffset = new Point(args.RelativeStartPoint.X - (shapeSize.Width / 2), args.RelativeStartPoint.Y - (shapeSize.Height / 2));
var draggingImage = new System.Windows.Controls.Image
{
Source = new Telerik.Windows.Media.Imaging.RadBitmap(draggedShape).Bitmap,
Width = shapeSize.Width,
Height = shapeSize.Height
};
args.DragVisual = draggingImage;
}
}
}
}
/// <summary>
/// Calculate the actual size because it is unknown otherwise, since we
/// are using a canvas.
/// </summary>
protected override Size MeasureOverride(Size constraint)
{
Size size = new Size();
foreach (UIElement element in this.InternalChildren)
{
double left = Canvas.GetLeft(element);
double top = Canvas.GetTop(element);
left = double.IsNaN(left) ? 0 : left;
top = double.IsNaN(top) ? 0 : top;
//measure desired size for each child
element.Measure(constraint);
Size desiredSize = element.DesiredSize;
if (!double.IsNaN(desiredSize.Width) && !double.IsNaN(desiredSize.Height))
{
size.Width = Math.Max(size.Width, left + desiredSize.Width);
size.Height = Math.Max(size.Height, top + desiredSize.Height);
}
}
// add margin
size.Width += 10;
size.Height += 10;
return size;
}
protected override Size MeasureOverride(Size availableSize)
{
dynamicOrder.Clear();
foreach (UIElement e in Children)
e.Measure(infiniteSize);
if (RowsToRender == 2)
{
Size size = FitsInDynamicRows(availableSize, 2, Children);
if (!size.IsEmpty)
return size;
}
else
{
List<UIElement> ordered = (from UIElement e in Children orderby e.DesiredSize.Width descending select e).ToList();
bool swap = false;
IEnumerable<UIElement> elements;
while ((elements = Get3Elements(ordered, swap)) != null)
{
swap ^= true;
foreach (UIElement e in elements)
dynamicOrder.Add(e);
}
Size size = FitsInDynamicRows(availableSize, 3, dynamicOrder);
if (!size.IsEmpty)
return size;
}
return new Size(48, 3*MaxSmallHeight);
}
/// <inheritdoc/>
protected override void OnSourceInitialized(EventArgs e) {
base.OnSourceInitialized(e);
var hwndSource = PresentationSource.FromVisual(this) as HwndSource;
Debug.Assert(hwndSource != null);
if (hwndSource != null) {
hwndSource.AddHook(WndProc);
wpfDpi = new Size(96.0 * hwndSource.CompositionTarget.TransformToDevice.M11, 96.0 * hwndSource.CompositionTarget.TransformToDevice.M22);
var w = Width;
var h = Height;
WindowDpi = GetDpi(hwndSource.Handle) ?? wpfDpi;
// For some reason, we can't initialize the non-fit-to-size property, so always force
// manual mode. When we're here, we should already have a valid Width and Height
Debug.Assert(h > 0 && !double.IsNaN(h));
Debug.Assert(w > 0 && !double.IsNaN(w));
SizeToContent = SizeToContent.Manual;
if (!wpfSupportsPerMonitorDpi) {
double scale = DisableDpiScalingAtStartup ? 1 : WpfPixelScaleFactor;
Width = w * scale;
Height = h * scale;
if (WindowStartupLocation == WindowStartupLocation.CenterOwner || WindowStartupLocation == WindowStartupLocation.CenterScreen) {
Left -= (w * scale - w) / 2;
Top -= (h * scale - h) / 2;
}
}
}
WindowUtils.UpdateWin32Style(this);
}
public ZoomableInlineAdornment(UIElement content, ITextView parent, Size desiredSize) {
_parent = parent;
Debug.Assert(parent is IInputElement);
_originalSize = _desiredSize = new Size(
Math.Max(double.IsNaN(desiredSize.Width) ? 100 : desiredSize.Width, 10),
Math.Max(double.IsNaN(desiredSize.Height) ? 100 : desiredSize.Height, 10)
);
// First time through, we want to reduce the image to fit within the
// viewport.
if (_desiredSize.Width > parent.ViewportWidth) {
_desiredSize.Width = parent.ViewportWidth;
_desiredSize.Height = _originalSize.Height / _originalSize.Width * _desiredSize.Width;
}
if (_desiredSize.Height > parent.ViewportHeight) {
_desiredSize.Height = parent.ViewportHeight;
_desiredSize.Width = _originalSize.Width / _originalSize.Height * _desiredSize.Height;
}
ContextMenu = MakeContextMenu();
Focusable = true;
MinWidth = MinHeight = 50;
Children.Add(content);
GotFocus += OnGotFocus;
LostFocus += OnLostFocus;
}
protected override Size MeasureOverride(Size availableSize)
{
m_itemHeight = ItemRender.ItemHeight;
ScrollMax = Math.Max(0, m_itemHeight* (m_list == null? 0 : m_list.Count) - m_clipSize.Height + 2 * m_itemHeight);
ViewportSize = m_clipSize.Height;
return new Size(Width, ScrollMax );
}
public IClipboardObject AddAsHtml(FrameworkElement fe, Size imageSize, Size imageElementSize)
{
if (fe == null)
throw new NullReferenceException(nameof(fe));
var bmp = fe.RenderToBitmap(imageSize);
var img_src = string.Empty;
var use_inline_image = false;
if (use_inline_image)
{
// Inline images are not actually supported by Office applications, so don't use it.
// maybe in future...
var img_data = bmp.ToBitmap().ToArray();
var base64_img_data = Convert.ToBase64String(img_data);
img_src = $"data:image/png;charset=utf-8;base64, {base64_img_data}";
}
else
{
// create a temp file with image and use it as a source
var tmp = Path.GetTempFileName();
bmp.Save(tmp);
img_src = new Uri(tmp, UriKind.Absolute).ToString();
}
var html_data = CF_HTML.PrepareHtmlFragment($"<img height=\"{imageElementSize.Height}\" width=\"{imageElementSize.Width}\" src=\"{img_src}\" />");
Data.SetData(DataFormats.Html, html_data);
return this;
}
protected override Size MeasureOverride(Size availableSize)
{
_perimeter = 0;
_maxChildHeight = 0;
// Find the tallest child and determine the perimeter
// based on the width of all of the children after
// measuring all of the them and letting them size
// to content by passing Double.PositiveInfinity as
// the available size.
foreach (UIElement uie in Children)
{
uie.Measure(new Size(Double.PositiveInfinity, Double.PositiveInfinity));
_perimeter += uie.DesiredSize.Width;
_maxChildHeight = Math.Max(_maxChildHeight, uie.DesiredSize.Height);
}
// If the marginal angle is not 0, 90 or 180
// then the adjustFactor is needed.
if (Children.Count > 2 && Children.Count != 4)
_adjustFactor = 10;
// Determine the radius of the circle layout and determine
// the RadialPanel's DesiredSize.
_radius = _perimeter / (2 * Math.PI) + _adjustFactor;
double _squareSize = 2 * (_radius + _maxChildHeight);
return new Size(_squareSize, _squareSize);
}
protected override Size MeasureOverride(Size availableSize)
{
Size infiniteSize = new Size(double.PositiveInfinity, double.PositiveInfinity);
double curX = 0, curY = 0, curLineHeight = 0;
foreach (UIElement child in Children)
{
child.Measure(infiniteSize);
if (curX + child.DesiredSize.Width > availableSize.Width)
{ //Wrap to next line
curY += curLineHeight;
curX = 0;
curLineHeight = 0;
}
curX += child.DesiredSize.Width;
if (child.DesiredSize.Height > curLineHeight)
curLineHeight = child.DesiredSize.Height;
}
curY += curLineHeight;
Size resultSize = new Size();
resultSize.Width = double.IsPositiveInfinity(availableSize.Width)
? curX : availableSize.Width;
resultSize.Height = double.IsPositiveInfinity(availableSize.Height)
? curY : availableSize.Height;
return resultSize;
}
protected override Size ArrangeOverride (Size finalSize)
{
Tester.WriteLine ("ArrangeOverride input = " + finalSize.ToString ());
Size output = base.MeasureOverride (finalSize);
Tester.WriteLine ("ArrangeOverride output = " + output.ToString ());
return output;
}
public PageCompositor(BookModel book, int fontSize, Size pageSize, IList<BookImage> images)
{
_book = book;
_fontSize = fontSize;
_pageSize = pageSize;
_images = images;
}
protected override Size ArrangeOverride(Size finalSize)
{
if(ParentRow == null)
return base.ArrangeOverride(finalSize);
double totalWidth = 0d;
Children.OfType<TimespanHeaderCell>().ToList().ForEach(cell =>
{
double width = cell.DesiredSize.Width;
double x = totalWidth + ParentRow.CellBorderThickness.Left + ParentRow.CellBorderThickness.Right;
if (x + width > finalSize.Width)
{
width -= (x + width) - finalSize.Width;
}
if (width < 0)
width = 0;
cell.Arrange(new Rect(x, 0, width, finalSize.Height));
totalWidth += width;
}
);
return finalSize;
}
//-------------------------------------------------------------------
//
// Protected Methods
//
//-------------------------------------------------------------------
#region Protected Methods
/// <summary>
/// Content measurement.
/// </summary>
/// <param name="constraint">Constraint size.</param>
/// <returns>Computed desired size.</returns>
protected sealed override Size MeasureOverride(Size constraint)
{
Size desiredSize = new Size();
if (_suspendLayout)
{
desiredSize = this.DesiredSize;
}
else if (Document != null)
{
// Create bottomless formatter, if necessary.
EnsureFormatter();
// Format bottomless content.
_formatter.Format(constraint);
// DesiredSize is set to the calculated size of the page.
// If hosted by ScrollViewer, desired size is limited to constraint.
if (_scrollData != null)
{
desiredSize.Width = Math.Min(constraint.Width, _formatter.DocumentPage.Size.Width);
desiredSize.Height = Math.Min(constraint.Height, _formatter.DocumentPage.Size.Height);
}
else
{
desiredSize = _formatter.DocumentPage.Size;
}
}
return desiredSize;
}
protected override Size ArrangeOverride( Size finalSize ) {
foreach ( UIElement child in this.InternalChildren ) {
child.Arrange( new Rect( new Point( 0, 0 ), child.DesiredSize ) );
}
return finalSize;
}
protected override Size MeasureOverride (Size availableSize)
{
Tester.WriteLine ("MeasureOverride input = " + availableSize.ToString ());
Size output = base.MeasureOverride (availableSize);
Tester.WriteLine ("MeasureOverride output = " + output.ToString ());
return output;
}
/// <summary>
/// Measures the size required for all the child elements in this panel.
/// </summary>
/// <param name="constraint">The size constraint given by our parent.</param>
/// <returns>The requested size for this panel including all children</returns>
protected override Size MeasureOverride(Size constraint)
{
double col1Width = 0;
double col2Width = 0;
RowHeights.Clear();
// First, measure all the left column children
for (int i = 0; i < VisualChildrenCount; i += 2)
{
var child = Children[i];
child.Measure(constraint);
col1Width = Math.Max(child.DesiredSize.Width, col1Width);
RowHeights.Add(child.DesiredSize.Height);
}
// Then, measure all the right column children, they get whatever remains in width
var newWidth = Math.Max(0, constraint.Width - col1Width - ColumnSpacing);
Size newConstraint = new Size(newWidth, constraint.Height);
for (int i = 1; i < VisualChildrenCount; i += 2)
{
var child = Children[i];
child.Measure(newConstraint);
col2Width = Math.Max(child.DesiredSize.Width, col2Width);
RowHeights[i / 2] = Math.Max(RowHeights[i / 2], child.DesiredSize.Height);
}
Column1Width = col1Width;
return new Size(
col1Width + ColumnSpacing + col2Width,
RowHeights.Sum() + ((RowHeights.Count - 1) * RowSpacing));
}
protected override sw.Size MeasureOverride(sw.Size constraint)
{
var size = base.MeasureOverride(constraint);
// WPF has problems with multiple rows or columns with GridUnitType.Star
// 1) it doesn't autosize correctly to the largest row/column
// 2) it doesn't position elements correctly until next layout pass
if (RowDefinitions.Count > 1 && (double.IsInfinity(constraint.Height) || !IsLoaded))
{
double maxHeight = 0;
double totalHeight = 0;
int totalRows = 0;
for (int i = 0; i < RowDefinitions.Count; i++)
{
var rd = RowDefinitions[i];
if (rd.Height.IsStar)
{
double rowHeight = 0;
for (int childIndex = 0; childIndex < Children.Count; childIndex++)
{
var child = Children[childIndex];
var row = GetRow(child);
if (row != i)
{
continue;
}
//child.Measure(constraint);
var desired = child.DesiredSize.Height;
if (!double.IsInfinity(desired))
{
rowHeight = Math.Max(rowHeight, desired);
}
}
maxHeight = Math.Max(rowHeight, maxHeight);
totalHeight += rowHeight;
totalRows++;
}
}
if (totalRows > 1)
{
size.Height = Math.Max(0, size.Height - totalHeight + maxHeight * totalRows);
}
}
if (ColumnDefinitions.Count > 1 && (double.IsInfinity(constraint.Width) || !IsLoaded))
{
double maxWidth = 0;
double totalWidth = 0;
int totalColumns = 0;
for (int i = 0; i < ColumnDefinitions.Count; i++)
{
var cd = ColumnDefinitions[i];
if (cd.Width.IsStar)
{
double columnWidth = 0;
for (int childIndex = 0; childIndex < Children.Count; childIndex++)
{
var child = Children[childIndex];
var row = GetColumn(child);
if (row != i)
{
continue;
}
//child.Measure(constraint);
var desired = child.DesiredSize.Width;
if (!double.IsInfinity(desired))
{
columnWidth = Math.Max(columnWidth, desired);
}
}
maxWidth = Math.Max(columnWidth, maxWidth);
totalWidth += columnWidth;
totalColumns++;
}
}
if (totalColumns > 1)
{
size.Width = Math.Max(0, size.Width - totalWidth + maxWidth * totalColumns);
}
}
return(size);
}
public static Bitmap ToBitmap(this UIElement element, Size size, PixelFormat pixelFormat)
{
return(element.ToRenderTargetBitmap(size, pixelFormat)
.ToBitmap());
}
/// <summary>
/// Method that starts or pauses the recording
/// </summary>
private async void RecordPause()
{
Extras.CreateTemp(_pathTemp);
switch (Stage)
{
case Stage.Stopped:
#region To Record
_capture = new Timer {
Interval = 1000 / FpsIntegerUpDown.Value
};
_snapDelay = null;
ListFrames = new List <FrameInfo>();
FrameCount = 0;
await Task.Factory.StartNew(UpdateScreenDpi);
#region Sizing
if (UserSettings.All.FullScreenMode)
{
_size = new Size((int)_sizeScreen.X, (int)_sizeScreen.Y);
}
else
{
_size = new Size((int)Math.Round((Width - Constants.HorizontalOffset) * _scale), (int)Math.Round((Height - Constants.VerticalOffset) * _scale));
}
#endregion
HeightIntegerBox.IsEnabled = false;
WidthIntegerBox.IsEnabled = false;
FpsIntegerUpDown.IsEnabled = false;
IsRecording = true;
Topmost = true;
FrameRate.Start(_capture.Interval);
UnregisterEvents();
#region Start
if (UserSettings.All.UsePreStart)
{
Title = $"Screen To Gif ({FindResource("Recorder.PreStart")} 2s)";
RecordPauseButton.IsEnabled = false;
Stage = Stage.PreStarting;
_preStartCount = 1; //Reset timer to 2 seconds, 1 second to trigger the timer so 1 + 1 = 2
_preStartTimer.Start();
}
else
{
if (UserSettings.All.ShowCursor)
{
#region If Show Cursor
if (!UserSettings.All.FullScreenMode)
{
if (UserSettings.All.AsyncRecording)
{
_capture.Tick += CursorAsync_Elapsed;
}
else
{
_capture.Tick += Cursor_Elapsed;
}
_capture.Start();
}
else
{
_capture.Tick += FullCursor_Elapsed;
_capture.Start();
}
Stage = Stage.Recording;
AutoFitButtons();
#endregion
}
else
{
#region If Not
if (!UserSettings.All.FullScreenMode)
{
if (UserSettings.All.AsyncRecording)
{
_capture.Tick += NormalAsync_Elapsed;
}
else
{
_capture.Tick += Normal_Elapsed;
}
_capture.Start();
}
else
{
_capture.Tick += Full_Elapsed;
_capture.Start();
}
Stage = Stage.Recording;
AutoFitButtons();
#endregion
}
}
break;
#endregion
#endregion
case Stage.Recording:
#region To Pause
Stage = Stage.Paused;
Title = FindResource("Recorder.Paused").ToString();
DiscardButton.BeginStoryboard(FindResource("ShowDiscardStoryboard") as Storyboard, HandoffBehavior.Compose);
AutoFitButtons();
_capture.Stop();
FrameRate.Stop();
break;
#endregion
case Stage.Paused:
#region To Record Again
Stage = Stage.Recording;
Title = "Screen To Gif";
DiscardButton.BeginStoryboard(FindResource("HideDiscardStoryboard") as Storyboard, HandoffBehavior.Compose);
AutoFitButtons();
FrameRate.Start(_capture.Interval);
_capture.Start();
break;
#endregion
}
}
public static SizeF ToEto(this sw.Size value)
{
return(new SizeF((float)value.Width, (float)value.Height));
}
protected override System.Windows.Size MeasureOverride(System.Windows.Size constraint)
{
// Ask for no space
Child.Measure(new System.Windows.Size(0, 0));
return(new System.Windows.Size(0, 0));
}
protected override System.Windows.Size MeasureOverride(System.Windows.Size constraint)
{
var s = base.MeasureOverride(constraint);
return(Backend.MeasureOverride(constraint, s));
}
/// <summary>
/// Arrange the children in the panel using the calculations from measure pass.
/// </summary>
/// <param name="finalSize">Total area available to arrange the controls</param>
/// <returns>Total used area</returns>
protected override System.Windows.Size ArrangeOverride(System.Windows.Size finalSize)
{
double closedExpandersTotalHeight = 0; // Total minimum height required by closed expanders and expanders with user defined height.
double openExpandersTotalHeight = 0; // Total size asked by all open expanders
foreach (UIElement child in this.Children)
{
Expander childExpander = child as Expander;
if (childExpander != null)
{
// Get a height if user has resized
double?userHeight = (double?)childExpander.GetValue(UserDefinedSizeProperty);
if (userHeight != null)
{
closedExpandersTotalHeight += (double)userHeight;
}
else if (childExpander.IsExpanded)
{
openExpandersTotalHeight += childExpander.DesiredSize.Height;
}
else
{
closedExpandersTotalHeight += childExpander.DesiredSize.Height;
}
}
else if (child as VerticalDragThumb != null)
{
closedExpandersTotalHeight += child.DesiredSize.Height;
}
}
// Start arranging
double usedHeight = 0;
double usedWidth = 0;
double openSpace = finalSize.Height - closedExpandersTotalHeight;
double openHeightDistributionFactor = openSpace / openExpandersTotalHeight; // Multiplication factor for distributing available free space
double currentChildHeight = 0;
foreach (UIElement child in this.Children)
{
Expander childExpander = child as Expander;
if (childExpander != null)
{
double?userHeight = (double?)childExpander.GetValue(UserDefinedSizeProperty);
// Find height to allocate
if (userHeight != null)
{
currentChildHeight = (double)userHeight;
}
else if (childExpander.IsExpanded)
{
currentChildHeight = child.DesiredSize.Height * openHeightDistributionFactor;
}
else
{
currentChildHeight = childExpander.DesiredSize.Height;
}
// Set height property so that its contents wont draw beyond this height
childExpander.Height = currentChildHeight - (childExpander.Margin.Top + childExpander.Margin.Bottom + childExpander.Padding.Top + childExpander.Padding.Bottom);
childExpander.Arrange(
new Rect(0,
usedHeight,
finalSize.Width,
currentChildHeight
));
childExpander.SetValue(AllocatedSizeProperty, currentChildHeight);
}
else if (child as VerticalDragThumb != null)
{
currentChildHeight = child.DesiredSize.Height;
child.Arrange(new Rect(0, usedHeight, finalSize.Width, child.DesiredSize.Height));
}
usedHeight += currentChildHeight;
usedWidth = child.DesiredSize.Width > usedWidth ? child.DesiredSize.Width : usedWidth;
}
return(new Size(finalSize.Width, usedHeight));
}
private PathFigureCollection GetFigures()
{
List <PathFigure> figures = new List <PathFigure>();
// 원 중심 (Xc, Yc)이고 반지름 r을 가지는
// 원의 방정식 : (x - Xc)^2 + (y - Yc)^2 = r^2
// y = Yc ± Math.Sqrt(Math.Pow(r,2) - Math.Pow(x - Xc, 2));
// x = Xc ± Math.Sqrt(Math.Pow(r,2) - Math.Pow(y - Yc, 2));
double centerX = Circle.Center.X;
double centerY = Circle.Center.Y;
double r = Circle.Radius;
double w = m_InputImage.Width;
double h = m_InputImage.Height;
double distX = Math.Abs(centerY);
double distY = Math.Abs(centerX);
double distW = Math.Abs(centerX - w);
double distH = Math.Abs(centerY - h);
var size = new System.Windows.Size(r, r);
int location = (distX < r ? 1 : 0) + (distY < r ? 2 : 0) + (distH < r ? 4 : 0) + (distW < r ? 8 : 0);
double tmpXVal = Math.Pow(r, 2) >= Math.Pow(centerY, 2) ? Math.Sqrt(Math.Pow(r, 2) - Math.Pow(centerY, 2)) : 0;
double tmpYVal = Math.Pow(r, 2) >= Math.Pow(centerX, 2) ? Math.Sqrt(Math.Pow(r, 2) - Math.Pow(centerX, 2)) : 0;
double tmpWVal = Math.Pow(r, 2) >= Math.Pow(centerX - w, 2) ? Math.Sqrt(Math.Pow(r, 2) - Math.Pow(w - centerX, 2)) : 0;
double tmpHVal = Math.Pow(r, 2) >= Math.Pow(centerY - h, 2) ? Math.Sqrt(Math.Pow(r, 2) - Math.Pow(h - centerY, 2)) : 0;
switch (location)
{
// 원이 이미지 안에 온전히 있거나 완전히 벗어난 경우,
case 0:
break;
// 원이 y = 0 인 직선에만 두 점에 걸린 경우,
case 1:
//원이 이미지 밖을 벗어난 경우,
if (centerX < -r || centerX > w + r)
{
break;
}
var loc1_p0 = new Point(centerX - tmpXVal, 0);
var loc1_p1 = new Point(centerX + tmpXVal, 0);
bool loc1_isLargeArc = centerY > 0 ? true : false;
figures.Add(new PathFigure(loc1_p1, new ArcSegment[] { new ArcSegment(loc1_p0, size, 0, loc1_isLargeArc, SweepDirection.Clockwise, true) }, false));
break;
// 원이 x = 0 인 직선에만 두 점에 걸린 경우,
case 2:
//원이 이미지 밖을 벗어난 경우,
if (centerY < -r || centerY > h + r)
{
break;
}
var loc2_p0 = new Point(0, centerY - tmpYVal);
var loc2_p1 = new Point(0, centerY + tmpYVal);
var loc2_isLargeArc = centerX > 0 ? true : false;
figures.Add(new PathFigure(loc2_p0, new ArcSegment[] { new ArcSegment(loc2_p1, size, 0, loc2_isLargeArc, SweepDirection.Clockwise, true) }, false));
break;
// 원이 y = h 인 직선에만 두 점에 걸린 경우,
case 4:
//원이 이미지 밖을 벗어난 경우,
if (centerX < -r || centerX > w + r)
{
break;
}
var loc4_p0 = new Point(centerX - tmpHVal, h);
var loc4_p1 = new Point(centerX + tmpHVal, h);
bool loc4_isLargeArc = centerY < h ? true : false;
figures.Add(new PathFigure(loc4_p0, new ArcSegment[] { new ArcSegment(loc4_p1, size, 0, loc4_isLargeArc, SweepDirection.Clockwise, true) }, false));
break;
// 원이 x = w 인 직선에만 두 점에 걸린 경우,
case 8:
//원이 이미지 밖을 벗어난 경우,
if (centerY < -r || centerY > h + r)
{
break;
}
var loc8_p0 = new Point(w, centerY - tmpWVal);
var loc8_p1 = new Point(w, centerY + tmpWVal);
bool loc8_isLargeArc = centerX < w ? true : false;
figures.Add(new PathFigure(loc8_p1, new ArcSegment[] { new ArcSegment(loc8_p0, size, 0, loc8_isLargeArc, SweepDirection.Clockwise, true) }, false));
break;
// 원이 y = 0 인 직선과 x = 0 인 직선에 각각 두 점에 걸린 경우,
case 3:
//원이 이미지 밖을 벗어난 경우,
if (centerX < 0 && centerY < 0 && Math.Sqrt(Math.Pow(centerX, 2) + Math.Pow(centerY, 2)) > r)
{
break;
}
var loc3_p0 = new Point(centerX - tmpXVal, 0);
var loc3_p1 = new Point(centerX + tmpXVal, 0);
var loc3_p2 = new Point(0, centerY - tmpYVal);
var loc3_p3 = new Point(0, centerY + tmpYVal);
if (loc3_p0.X > 0 && loc3_p2.Y > 0)
{
figures.Add(new PathFigure(loc3_p2, new ArcSegment[] { new ArcSegment(loc3_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
figures.Add(new PathFigure(loc3_p1, new ArcSegment[] { new ArcSegment(loc3_p3, size, 0, true, SweepDirection.Clockwise, true) }, false));
}
else if (loc3_p0.X > 0)
{
figures.Add(new PathFigure(loc3_p1, new ArcSegment[] { new ArcSegment(loc3_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else if (loc3_p2.Y > 0)
{
figures.Add(new PathFigure(loc3_p2, new ArcSegment[] { new ArcSegment(loc3_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc3_p1, new ArcSegment[] { new ArcSegment(loc3_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 y = 0 인 직선과 y = h 인 직선에 각각 두 점에 걸린 경우,
case 5:
//원이 이미지 밖을 벗어난 경우,
if (centerX < -r || centerX > w + r)
{
break;
}
var loc5_p0 = new Point(centerX - tmpXVal, 0);
var loc5_p1 = new Point(centerX + tmpXVal, 0);
var loc5_p2 = new Point(centerX - tmpHVal, h);
var loc5_p3 = new Point(centerX + tmpHVal, h);
figures.Add(new PathFigure(loc5_p1, new ArcSegment[] { new ArcSegment(loc5_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
figures.Add(new PathFigure(loc5_p2, new ArcSegment[] { new ArcSegment(loc5_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
break;
// 원이 y = 0 인 직선과 x = w 인 직선에 각각 두 점에 걸린 경우,
case 9:
//원이 이미지 밖을 벗어난 경우,
if (centerX > w && centerY < 0 && Math.Sqrt(Math.Pow(centerX - w, 2) + Math.Pow(centerY, 2)) > r)
{
break;
}
var loc9_p0 = new Point(centerX - tmpXVal, 0);
var loc9_p1 = new Point(centerX + tmpXVal, 0);
var loc9_p2 = new Point(w, centerY - tmpWVal);
var loc9_p3 = new Point(w, centerY + tmpWVal);
if (loc9_p1.X < w && loc9_p2.Y > 0)
{
figures.Add(new PathFigure(loc9_p1, new ArcSegment[] { new ArcSegment(loc9_p2, size, 0, false, SweepDirection.Clockwise, true) }, false));
figures.Add(new PathFigure(loc9_p3, new ArcSegment[] { new ArcSegment(loc9_p0, size, 0, true, SweepDirection.Clockwise, true) }, false));
}
else if (loc9_p1.X < w)
{
figures.Add(new PathFigure(loc9_p1, new ArcSegment[] { new ArcSegment(loc9_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else if (loc9_p2.Y > 0)
{
figures.Add(new PathFigure(loc9_p3, new ArcSegment[] { new ArcSegment(loc9_p2, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc9_p3, new ArcSegment[] { new ArcSegment(loc9_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 x = 0 인 직선과 y = h 인 직선에 각각 두 점에 걸린 경우,
case 6:
//원이 이미지 밖을 벗어난 경우,
if (centerX < 0 && centerY > h && Math.Sqrt(Math.Pow(centerX, 2) + Math.Pow(centerY - h, 2)) > r)
{
break;
}
var loc6_p0 = new Point(0, centerY - tmpYVal);
var loc6_p1 = new Point(0, centerY + tmpYVal);
var loc6_p2 = new Point(centerX - tmpHVal, h);
var loc6_p3 = new Point(centerX + tmpHVal, h);
if (loc6_p0.X > 0 && loc6_p3.Y < h)
{
figures.Add(new PathFigure(loc6_p2, new ArcSegment[] { new ArcSegment(loc6_p1, size, 0, false, SweepDirection.Clockwise, true) }, false));
figures.Add(new PathFigure(loc6_p0, new ArcSegment[] { new ArcSegment(loc6_p3, size, 0, true, SweepDirection.Clockwise, true) }, false));
}
else if (loc6_p0.X > 0)
{
figures.Add(new PathFigure(loc6_p1, new ArcSegment[] { new ArcSegment(loc6_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else if (loc6_p3.Y < h)
{
figures.Add(new PathFigure(loc6_p2, new ArcSegment[] { new ArcSegment(loc6_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc6_p0, new ArcSegment[] { new ArcSegment(loc6_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 x = 0 인 직선과 x = w 인 직선에 각각 두 점에 걸린 경우,
case 10:
//원이 이미지 밖을 벗어난 경우,
if (centerY < -r || centerY > h + r)
{
break;
}
var loc10_p0 = new Point(0, centerY - tmpYVal);
var loc10_p1 = new Point(0, centerY + tmpYVal);
var loc10_p2 = new Point(w, centerY - tmpWVal);
var loc10_p3 = new Point(w, centerY + tmpWVal);
figures.Add(new PathFigure(loc10_p0, new ArcSegment[] { new ArcSegment(loc10_p2, size, 0, false, SweepDirection.Clockwise, true) }, false));
figures.Add(new PathFigure(loc10_p3, new ArcSegment[] { new ArcSegment(loc10_p1, size, 0, false, SweepDirection.Clockwise, true) }, false));
break;
// 원이 y = h 인 직선과 x = w 인 직선에 각각 두 점에 걸린 경우,
case 12:
//원이 이미지 밖을 벗어난 경우,
if (centerX > w && centerY > h && Math.Sqrt(Math.Pow(centerX - w, 2) + Math.Pow(centerY - h, 2)) > r)
{
break;
}
var loc12_p0 = new Point(centerX - tmpHVal, h);
var loc12_p1 = new Point(centerX + tmpHVal, h);
var loc12_p2 = new Point(w, centerY - tmpWVal);
var loc12_p3 = new Point(w, centerY + tmpWVal);
if (loc12_p1.X < w && loc12_p3.Y < h)
{
figures.Add(new PathFigure(loc12_p3, new ArcSegment[] { new ArcSegment(loc12_p1, size, 0, false, SweepDirection.Clockwise, true) }, false));
figures.Add(new PathFigure(loc12_p0, new ArcSegment[] { new ArcSegment(loc12_p2, size, 0, true, SweepDirection.Clockwise, true) }, false));
}
else if (loc12_p1.X < w)
{
figures.Add(new PathFigure(loc12_p0, new ArcSegment[] { new ArcSegment(loc12_p1, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else if (loc12_p3.Y < h)
{
figures.Add(new PathFigure(loc12_p3, new ArcSegment[] { new ArcSegment(loc12_p2, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc12_p0, new ArcSegment[] { new ArcSegment(loc12_p2, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 y = 0 인 직선과 x = 0 인 직선, y = h 인 직선에 각각 두 점에 걸린 경우,
case 7:
var loc7_p0 = new Point(centerX - tmpXVal, 0);
var loc7_p1 = new Point(centerX + tmpXVal, 0);
var loc7_p2 = new Point(0, centerY - tmpYVal);
var loc7_p3 = new Point(0, centerY + tmpYVal);
var loc7_p4 = new Point(centerX - tmpHVal, h);
var loc7_p5 = new Point(centerX + tmpHVal, h);
if (loc7_p1.X > 0)
{
if (loc7_p5.X < 0)
{
figures.Add(new PathFigure(loc7_p1, new ArcSegment[] { new ArcSegment(loc7_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc7_p1, new ArcSegment[] { new ArcSegment(loc7_p5, size, 0, false, SweepDirection.Clockwise, true) }, false));
if (loc7_p0.X > 0)
{
figures.Add(new PathFigure(loc7_p2, new ArcSegment[] { new ArcSegment(loc7_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
if (loc7_p4.X > 0)
{
figures.Add(new PathFigure(loc7_p4, new ArcSegment[] { new ArcSegment(loc7_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
}
}
else if (loc7_p5.X > 0)
{
figures.Add(new PathFigure(loc7_p2, new ArcSegment[] { new ArcSegment(loc7_p5, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc7_p2, new ArcSegment[] { new ArcSegment(loc7_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 y = 0 인 직선과 x = 0 인 직선, x = w 인 직선에 각각 두 점에 걸린 경우,
case 11:
var loc11_p0 = new Point(centerX - tmpXVal, 0);
var loc11_p1 = new Point(centerX + tmpXVal, 0);
var loc11_p2 = new Point(0, centerY - tmpYVal);
var loc11_p3 = new Point(0, centerY + tmpYVal);
var loc11_p4 = new Point(w, centerY - tmpWVal);
var loc11_p5 = new Point(w, centerY + tmpWVal);
if (loc11_p5.Y > 0)
{
if (loc11_p3.Y < 0)
{
figures.Add(new PathFigure(loc11_p5, new ArcSegment[] { new ArcSegment(loc11_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc11_p5, new ArcSegment[] { new ArcSegment(loc11_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
if (loc11_p2.Y > 0)
{
figures.Add(new PathFigure(loc11_p2, new ArcSegment[] { new ArcSegment(loc11_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
if (loc11_p4.Y > 0)
{
figures.Add(new PathFigure(loc11_p1, new ArcSegment[] { new ArcSegment(loc11_p4, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
}
}
else if (loc11_p3.Y > 0)
{
figures.Add(new PathFigure(loc11_p1, new ArcSegment[] { new ArcSegment(loc11_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc11_p1, new ArcSegment[] { new ArcSegment(loc11_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 y = 0 인 직선과 y = h 인 직선, x = w 인 직선에 각각 두 점에 걸린 경우,
case 13:
var loc13_p0 = new Point(centerX - tmpXVal, 0);
var loc13_p1 = new Point(centerX + tmpXVal, 0);
var loc13_p2 = new Point(centerX - tmpHVal, h);
var loc13_p3 = new Point(centerX + tmpHVal, h);
var loc13_p4 = new Point(w, centerY - tmpWVal);
var loc13_p5 = new Point(w, centerY + tmpWVal);
if (loc13_p0.X < w)
{
if (loc13_p2.X > w)
{
figures.Add(new PathFigure(loc13_p5, new ArcSegment[] { new ArcSegment(loc13_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc13_p2, new ArcSegment[] { new ArcSegment(loc13_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
if (loc13_p3.X < w)
{
figures.Add(new PathFigure(loc13_p5, new ArcSegment[] { new ArcSegment(loc13_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
if (loc13_p1.X < w)
{
figures.Add(new PathFigure(loc13_p1, new ArcSegment[] { new ArcSegment(loc13_p4, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
}
}
else if (loc13_p2.X < w)
{
figures.Add(new PathFigure(loc13_p2, new ArcSegment[] { new ArcSegment(loc13_p4, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc13_p5, new ArcSegment[] { new ArcSegment(loc13_p4, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 x = 0 인 직선과 y = h 인 직선, x = w 인 직선에 각각 두 점에 걸린 경우,
case 14:
var loc14_p0 = new Point(0, centerY - tmpYVal);
var loc14_p1 = new Point(0, centerY + tmpYVal);
var loc14_p2 = new Point(centerX - tmpHVal, h);
var loc14_p3 = new Point(centerX + tmpHVal, h);
var loc14_p4 = new Point(w, centerY - tmpWVal);
var loc14_p5 = new Point(w, centerY + tmpWVal);
if (loc14_p0.Y < h)
{
if (loc14_p4.Y > h)
{
figures.Add(new PathFigure(loc14_p0, new ArcSegment[] { new ArcSegment(loc14_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc14_p0, new ArcSegment[] { new ArcSegment(loc14_p4, size, 0, false, SweepDirection.Clockwise, true) }, false));
if (loc14_p5.Y < h)
{
figures.Add(new PathFigure(loc14_p5, new ArcSegment[] { new ArcSegment(loc14_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
if (loc14_p1.Y < h)
{
figures.Add(new PathFigure(loc14_p2, new ArcSegment[] { new ArcSegment(loc14_p1, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
}
}
else if (loc14_p4.Y < h)
{
figures.Add(new PathFigure(loc14_p2, new ArcSegment[] { new ArcSegment(loc14_p4, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
else
{
figures.Add(new PathFigure(loc14_p2, new ArcSegment[] { new ArcSegment(loc14_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
// 원이 모든 직선에 각각 두 점에 걸린 경우,
case 15:
var loc15_p0 = new Point(centerX - tmpXVal, 0);
var loc15_p1 = new Point(centerX + tmpXVal, 0);
var loc15_p2 = new Point(0, centerY - tmpYVal);
var loc15_p3 = new Point(0, centerY + tmpYVal);
var loc15_p4 = new Point(centerX - tmpHVal, h);
var loc15_p5 = new Point(centerX + tmpHVal, h);
var loc15_p6 = new Point(w, centerY - tmpWVal);
var loc15_p7 = new Point(w, centerY + tmpWVal);
if (loc15_p0.X >= 0 && loc15_p0.X <= w && loc15_p2.Y >= 0 && loc15_p2.Y <= h)
{
figures.Add(new PathFigure(loc15_p2, new ArcSegment[] { new ArcSegment(loc15_p0, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
if (loc15_p1.X >= 0 && loc15_p1.X <= w && loc15_p6.Y >= 0 && loc15_p6.Y <= h)
{
figures.Add(new PathFigure(loc15_p1, new ArcSegment[] { new ArcSegment(loc15_p6, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
if (loc15_p5.X >= 0 && loc15_p5.X <= w && loc15_p7.Y >= 0 && loc15_p7.Y <= h)
{
figures.Add(new PathFigure(loc15_p7, new ArcSegment[] { new ArcSegment(loc15_p5, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
if (loc15_p4.X >= 0 && loc15_p4.X <= w && loc15_p3.Y >= 0 && loc15_p3.Y <= h)
{
figures.Add(new PathFigure(loc15_p4, new ArcSegment[] { new ArcSegment(loc15_p3, size, 0, false, SweepDirection.Clockwise, true) }, false));
}
break;
default:
throw new Exception("Invalid location number.");
}
return(new PathFigureCollection(figures));
}
protected override Size MeasureOverride(Size availableSize)
{
return(new Size(24, 24));
}
public override sw.Size GetPreferredSize(sw.Size constraint)
{
return(base.GetPreferredSize(Conversions.ZeroSize));
}
public static sw.Size Subtract(this sw.Size size1, sw.Size size2)
{
return(new sw.Size(Math.Max(0, size1.Width - size2.Width), Math.Max(0, size1.Height - size2.Height)));
}
private void Snap()
{
if (ListFrames.Count == 0)
{
#region If Fullscreen
if (UserSettings.All.FullScreenMode)
{
_size = new Size((int)_sizeScreen.X, (int)_sizeScreen.Y);
}
else
{
_size = new Size((int)Math.Round((Width - Constants.HorizontalOffset) * _scale), (int)Math.Round((Height - Constants.VerticalOffset) * _scale));
}
#endregion
DiscardButton.BeginStoryboard(FindResource("ShowDiscardStoryboard") as Storyboard, HandoffBehavior.Compose);
IsRecording = true;
}
_snapDelay = UserSettings.All.SnapshotDefaultDelay;
#region Take Screenshot (All possibles types)
if (UserSettings.All.ShowCursor)
{
if (UserSettings.All.FullScreenMode)
{
FullCursor_Elapsed(null, null);
}
else
{
if (UserSettings.All.AsyncRecording)
{
CursorAsync_Elapsed(null, null);
}
else
{
Cursor_Elapsed(null, null);
}
}
}
else
{
if (UserSettings.All.FullScreenMode)
{
Full_Elapsed(null, null);
}
else
{
if (UserSettings.All.AsyncRecording)
{
NormalAsync_Elapsed(null, null);
}
else
{
Normal_Elapsed(null, null);
}
}
}
#endregion
}
protected override System.Windows.Size MeasureOverride(System.Windows.Size availableSize)
{
ControlRoot.Measure(availableSize.ToAvaloniaSize());
return(ControlRoot.DesiredSize.ToWpfSize());
}
// Whenever a control gets a change affecting its size/appearance,
// it keep literaly *waiting* for a call to Arrange(), sometimes even if not truly needed.
// In this cases ArrangeOverride is called, and we 'refresh' the controls that require it
// (this is done by all the containers inheriting from Panel).
protected override SW.Size ArrangeOverride(SW.Size finalSize)
{
ArrangeChildren(false);
return(base.ArrangeOverride(finalSize));
}
/// <summary>
/// When overridden in a derived class, measures the size in layout required for child elements and determines a size for the <see cref="T:System.Windows.FrameworkElement"/>-derived class.
/// </summary>
/// <returns>
/// The size that this element determines it needs during layout, based on its calculations of child element sizes.
/// </returns>
/// <param name="availableSize">The available size that this element can give to child elements. Infinity can be specified as a value to indicate that the element will size to whatever content is available.</param>
protected override System.Windows.Size MeasureOverride(System.Windows.Size availableSize)
{
// Sort children
leftChildren.Clear();
rightChildren.Clear();
otherChildren.Clear();
for (int i = 0; i < InternalChildren.Count; i++)
{
FrameworkElement child = InternalChildren[i] as FrameworkElement;
if (child != null)
{
if (child.HorizontalAlignment == HorizontalAlignment.Left)
{
leftChildren.Add(child);
}
else if (child.HorizontalAlignment == HorizontalAlignment.Right)
{
rightChildren.Add(child);
}
else
{
otherChildren.Add(child);
}
}
}
lastRightIndex = rightChildren.Count;
lastLeftIndex = leftChildren.Count;
// Measure children
Size infinity = new Size(double.PositiveInfinity, double.PositiveInfinity);
Size zero = new Size(0, 0);
double width = 0;
double height = 0;
bool canAdd = true;
// Right children
for (int i = 0; i < rightChildren.Count; i++)
{
if (canAdd)
{
rightChildren[i].Measure(infinity);
height = Math.Max(rightChildren[i].DesiredSize.Height, height);
if (width + rightChildren[i].DesiredSize.Width <= availableSize.Width)
{
width += rightChildren[i].DesiredSize.Width;
}
else
{
canAdd = false;
rightChildren[i].Measure(zero);
lastRightIndex = i;
lastLeftIndex = 0;
}
}
else
{
rightChildren[i].Measure(zero);
}
}
// Left children
for (int i = 0; i < leftChildren.Count; i++)
{
if (canAdd)
{
leftChildren[i].Measure(infinity);
height = Math.Max(leftChildren[i].DesiredSize.Height, height);
if (width + leftChildren[i].DesiredSize.Width <= availableSize.Width)
{
width += leftChildren[i].DesiredSize.Width;
}
else
{
canAdd = false;
leftChildren[i].Measure(zero);
lastLeftIndex = i;
}
}
else
{
leftChildren[i].Measure(zero);
}
}
// Collapse other children
for (int i = 0; i < otherChildren.Count; i++)
{
otherChildren[i].Measure(zero);
}
return(new Size(width, height));
}
public static sw.Size Add(this sw.Size size1, sw.Size size2)
{
return(new sw.Size(size1.Width + size2.Width, size1.Height + size2.Height));
}
private void MakeBitmap()
{
while (true)
{
_newText.WaitOne();
GlyphTypeface glyphTypeface = null;
if (_glyphTypeface != null)
{
lock (_glyphTypeface)
{
glyphTypeface = _glyphTypeface;
}
}
if (glyphTypeface != null)
{
if (_lines == null || _lines.Length == 0)
{
_img = null;
}
else
{
if (_lines[0].VobSubMergedPack != null)
{
var bitmaps = _lines.Select(l => l.GetImage()).ToArray();
int bw = bitmaps.Max(b => b.Width);
int bh = bitmaps.Sum(b => b.Height);
BitmapSource bimage = CreateBitmap((int)bw, (int)bh, 96,
dc =>
{
double ypos = 0;
for (int lb = 0; lb < bitmaps.Count(); lb++)
{
var bs = bitmaps[lb].ToBitmapSource();
Point bLoc = new Point((bw - bs.Width) / 2, ypos);
Size bSize = new Size(bs.Width, bs.Height);
ypos += bs.Height;
dc.DrawImage(bs, new Rect(bLoc, bSize));
}
});
bimage.Freeze();
_img = bimage;
}
else
{
var lines = new List <string>(_lines.Select(l => l.Text).SelectMany(t => t.Split(new string[] { Environment.NewLine }, 10000, StringSplitOptions.None))).ToArray();
{
ushort[][] glyphIndexes = new ushort[lines.Length][];
double[][] advanceWidths = new double[lines.Length][];
double[] totalWidth = new double[lines.Length];
int l = 0;
foreach (var text in lines)
{
glyphIndexes[l] = new ushort[text.Length];
advanceWidths[l] = new double[text.Length];
for (int n = 0; n < text.Length; n++)
{
if (glyphTypeface.CharacterToGlyphMap.ContainsKey(text[n]))
{
ushort glyphIndex = glyphTypeface.CharacterToGlyphMap[text[n]];
glyphIndexes[l][n] = glyphIndex;
double width = glyphTypeface.AdvanceWidths[glyphIndex] * _fontSize;
advanceWidths[l][n] = width;
totalWidth[l] += width;
}
}
l++;
}
double w = totalWidth.Max(lw => lw) + _marginLeft + _marginRight;
double h = (lines.Length * _fontSize) + _fontSize / 4 + _marginBottom;
BitmapSource image = CreateBitmap((int)w, (int)h, 96,
dc =>
{
int line = 1;
if (_back != Brushes.Transparent)
{
dc.DrawRectangle(_back, null, new Rect(0d, 0d, w, h));
}
foreach (var text in lines)
{
if (string.IsNullOrEmpty(text))
{
line++;
continue;
}
var origin = new Point((w - totalWidth[line - 1]) / 2, line * _fontSize);
var orig = ((SolidColorBrush)_stroke.Clone()).Color;
var strokeBrush = new SolidColorBrush
{
Color =
new Color()
{
B = orig.B,
R = orig.R,
G = orig.G,
A = _strokeGlow ? (byte)35 : orig.A
}
};
var glyphRun = new GlyphRun(glyphTypeface, 0, false, _fontSize,
glyphIndexes[line - 1], origin,
advanceWidths[line - 1], null, null,
null, null,
null, null);
if (_underline)
{
double y = origin.Y;
y -= (glyphTypeface.Baseline + _typeface.UnderlinePosition * _fontSize);
for (double i = _strokeThickness; i > 0; i--)
{
dc.DrawLine(
new Pen(strokeBrush, (_typeface.UnderlineThickness * _fontSize) + i),
new Point(origin.X - _strokeThickness / 2, y),
new Point(origin.X + totalWidth[line - 1] + _strokeThickness / 2, y));
if (!_strokeGlow)
{
break;
}
}
}
var geo = glyphRun.BuildGeometry();
for (double i = _strokeThickness; i > 0; i--)
{
dc.DrawGeometry(null, new Pen(strokeBrush, i), geo);
if (!_strokeGlow)
{
break;
}
}
dc.DrawGlyphRun(_fill, glyphRun);
if (_underline)
{
double y = origin.Y;
y -= (glyphTypeface.Baseline + _typeface.UnderlinePosition * _fontSize);
dc.DrawLine(new Pen(_fill, _typeface.UnderlineThickness * _fontSize),
new Point(origin.X, y),
new Point(origin.X + totalWidth[line - 1], y));
}
line++;
}
});
image.Freeze();
_img = image;
}
}
}
}
try
{
_newText.Release();
}
catch
{
}
Dispatcher.Invoke(((Action)(() =>
{
_newText.WaitOne(); InvalidateVisual();
})), DispatcherPriority.Render, new object[] { });
}
}
public OxFigure()
{
Color = SelectionLayer.GetInstance.CurrentColor;
size = new Size(0, 0);
}
public override sw.Size GetPreferredSize(sw.Size constraint)
{
return(base.GetPreferredSize(sw.Size.Empty));
}
/// <summary>
/// Method that starts or pauses the recording
/// </summary>
internal async void RecordPause()
{
switch (Stage)
{
case Stage.Stopped:
#region To Record
_capture = new Timer {
Interval = 1000 / FpsIntegerUpDown.Value
};
_snapDelay = null;
Project = new ProjectInfo().CreateProjectFolder(ProjectByType.ScreenRecorder);
_keyList.Clear();
FrameCount = 0;
await Task.Factory.StartNew(UpdateScreenDpi);
//Sizing.
_size = new Size((int)Math.Round((Width - Constants.HorizontalOffset) * _scale), (int)Math.Round((Height - Constants.VerticalOffset) * _scale));
HeightIntegerBox.IsEnabled = false;
WidthIntegerBox.IsEnabled = false;
FpsIntegerUpDown.IsEnabled = false;
IsRecording = true;
Topmost = true;
FrameRate.Start(_capture.Interval);
UnregisterEvents();
#region Start
if (UserSettings.All.UsePreStart)
{
Title = $"Screen To Gif ({FindResource("Recorder.PreStart")} {UserSettings.All.PreStartValue}s)";
RecordPauseButton.IsEnabled = false;
Stage = Stage.PreStarting;
_preStartCount = UserSettings.All.PreStartValue - 1;
_preStartTimer.Start();
}
else
{
if (UserSettings.All.ShowCursor)
{
#region If Show Cursor
if (UserSettings.All.AsyncRecording)
{
_capture.Tick += CursorAsync_Elapsed;
}
else
{
_capture.Tick += Cursor_Elapsed;
}
_capture.Start();
Stage = Stage.Recording;
AutoFitButtons();
#endregion
}
else
{
#region If Not
if (UserSettings.All.AsyncRecording)
{
_capture.Tick += NormalAsync_Elapsed;
}
else
{
_capture.Tick += Normal_Elapsed;
}
_capture.Start();
Stage = Stage.Recording;
AutoFitButtons();
#endregion
}
}
break;
#endregion
#endregion
case Stage.Recording:
#region To Pause
Stage = Stage.Paused;
Title = FindResource("Recorder.Paused").ToString();
DiscardButton.BeginStoryboard(FindResource("ShowDiscardStoryboard") as Storyboard, HandoffBehavior.Compose);
AutoFitButtons();
_capture.Stop();
FrameRate.Stop();
break;
#endregion
case Stage.Paused:
#region To Record Again
Stage = Stage.Recording;
Title = "Screen To Gif";
DiscardButton.BeginStoryboard(FindResource("HideDiscardStoryboard") as Storyboard, HandoffBehavior.Compose);
AutoFitButtons();
FrameRate.Start(_capture.Interval);
_capture.Start();
break;
#endregion
}
}
private static CustomPopupPlacement[] CustomPopupPlacementCallback(Size popupSize, Size targetSize, Point offset)
{
var p = new Point
{
Y = targetSize.Height - offset.Y,
X = -offset.X
};
return(new[]
{
new CustomPopupPlacement(p, PopupPrimaryAxis.Horizontal)
});
}
public void UpdateWindowSize(System.Windows.Size CurrentWindowSize)
{
_CurrentDXWindowSize = DxContainer.ClientSize;
needsReset = true;
}
public void PerformOperation(object sender, RoutedEventArgs e)
{
RadioButton li = sender as RadioButton;
// Strings used to display results
String syntaxString, resultType, operationString;
///The local variables point1, point2, vector2, etc are defined in each
///case block for readability reasons. Each variable is contained within
///the scope of each case statement.
switch (li.Name)
{ //begin switch
case "rb1":
{
// Translates a Point by a Vector using the overloaded + operator.
System.Windows.Point point1 = new System.Windows.Point(10, 5);
Vector vector1 = new Vector(20, 30);
System.Windows.Point pointResult = new System.Windows.Point();
pointResult = point1 + vector1;
// pointResult is equal to (-10,-25)
// Displaying Results
syntaxString = "pointResult = point1 + vector1;";
resultType = "Point";
operationString = "Translating a Point by a Vector";
ShowResults(pointResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb2":
{
//<Snippet10>
// Adds a Vector to a Vector using the overloaded + operator.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Vector vectorResult = new Vector();
// vectorResult is equal to (65,100)
vectorResult = vector1 + vector2;
//</Snippet10>
// Displaying Results
syntaxString = "vectorResult = vector1 + vector2;";
resultType = "Vector";
operationString = "Adding a Vector to a Vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb3":
{
// Adds a Vector to a Vector using the static Add method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Vector vectorResult = new Vector();
vectorResult = Vector.Add(vector1, vector2);
// vectorResult is equal to (65,100)
// Displaying Results
syntaxString = "vectorResult = Vector.Add(vector1, vector2);";
resultType = "Vector";
operationString = "Adding a Vector to a Vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb4":
{
// Translates a Point by a Vector using the static Add method.
Vector vector1 = new Vector(20, 30);
System.Windows.Point point1 = new System.Windows.Point(10, 5);
System.Windows.Point pointResult = new System.Windows.Point();
pointResult = Vector.Add(vector1, point1);
// vectorResult is equal to (30,35)
// Displaying Results
syntaxString = "pointResult = Vector.Add(vector1, point1);";
resultType = "Point";
operationString = "Translating a Point by a Vector";
ShowResults(pointResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb5":
{
// Subtracts a Vector from a Vector using the overloaded - operator.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Vector vectorResult = new Vector();
vectorResult = vector1 - vector2;
// vector Result is equal to (-25, -40)
// Displaying Results
syntaxString = "vectorResult = vector1 - vector2;";
resultType = "Vector";
operationString = "Subtracting a Vector from a Vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb6":
{
// Subtracts a Vector from a Vector using the static Subtract method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Vector vectorResult = new Vector();
vectorResult = Vector.Subtract(vector1, vector2);
// vector Result is equal to (-25, -40)
// Displaying Results
syntaxString = "Vector.Subtract(vector1, vector2);";
resultType = "Vector";
operationString = "Subtracting a Vector from a Vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb7":
{
// Multiplies a Vector by a Scalar using the overloaded * operator.
Vector vector1 = new Vector(20, 30);
Double scalar1 = 75;
Vector vectorResult = new Vector();
vectorResult = vector1 * scalar1;
// vectorResult is equal to (1500,2250)
// Displaying Results
syntaxString = "vectorResult = vector1 * scalar1;";
resultType = "Vector";
operationString = "Multiplies a Vector by a Scalar";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb8":
{
// Multiplies a Scalar by a Vector using the overloaded * operator.
Vector vector1 = new Vector(20, 30);
Double scalar1 = 75;
Vector vectorResult = new Vector();
vectorResult = scalar1 * vector1;
// vectorResult is equal to (1500,2250)
// Displaying Results
syntaxString = "vectorResult = scalar1 * vector1;";
resultType = "Vector";
operationString = "Multiplies a Scalar by a Vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb9":
{
// Multiplies a Vector by a Vector using the overloaded * operator.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Double doubleResult;
doubleResult = vector1 * vector2;
// doubleResult is equal to 3000
// Displaying Results
syntaxString = "doubleResult = vector1 * vector2;";
resultType = "Double";
operationString = "Multiplies a Vector by a Vector";
ShowResults(doubleResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb10":
{
// Multiplies a Vector by a Matrix using the overloaded * operator.
Vector vector1 = new Vector(20, 30);
Matrix matrix1 = new Matrix(40, 50, 60, 70, 80, 90);
Vector vectorResult = new Vector();
vectorResult = vector1 * matrix1;
// vector Result is equal to (2600,3100)
// Displaying Results
syntaxString = "vectorResult = vector1 * matrix1;";
resultType = "Vector";
operationString = "Multiplies a Vector by a Matrix";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb11":
{
// Multiplies a Vector by a Scalar using the static Multiply method.
Vector vector1 = new Vector(20, 30);
Double scalar1 = 75;
Vector vectorResult = new Vector();
vectorResult = Vector.Multiply(vector1, scalar1);
// vectorResult is equal to (1500,2250)
// Displaying Results
syntaxString = "vectorResult = Vector.Multiply(vector1, scalar1);";
resultType = "Vector";
operationString = "Multiplies a Vector by a Scalar";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb12":
{
// Multiplies a Scalar by a Vector using the static Multiply method.
Vector vector1 = new Vector(20, 30);
Double scalar1 = 75;
Vector vectorResult = new Vector();
vectorResult = Vector.Multiply(scalar1, vector1);
// vectorResult is equal to (1500,2250)
// Displaying Results
syntaxString = "vectorResult = Vector.Multiply(scalar1, vector1);";
resultType = "Vector";
operationString = "Multiplies a Scalar by a Vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb13":
{
// Multiplies a Vector by a Vector using the static Multiply method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Double doubleResult;
doubleResult = Vector.Multiply(vector1, vector2);
// doubleResult is equal to 3000
// Displaying Results
syntaxString = "DoubleResult = Vector.Multiply(vector1,vector2);";
resultType = "Double";
operationString = "Multiplies a Vector by a Vector";
ShowResults(doubleResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb14":
{
// Multiplies a Vector by a Matrix using the static Multiply method.
Vector vector1 = new Vector(20, 30);
Matrix matrix1 = new Matrix(40, 50, 60, 70, 80, 90);
Vector vectorResult = new Vector();
vectorResult = Vector.Multiply(vector1, matrix1);
// vector Result is equal to (2600,3100)
// Displaying Results
syntaxString = "vectorResult = Vector.Multiply(vector1,matrix1);";
resultType = "Vector";
operationString = "Multiplies a Vector by a Matrix";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb15":
{
// Divides a Vector by a Scalar using the overloaded / operator.
Vector vector1 = new Vector(20, 30);
Vector vectorResult = new Vector();
Double scalar1 = 75;
vectorResult = vector1 / scalar1;
// vectorResult is approximately equal to (0.26667,0.4)
// Displaying Results
syntaxString = "vectorResult = vector1 / scalar1;";
resultType = "Vector";
operationString = "Dividing a Vector by a Scalar";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb16":
{
// Divides a Vector by a Double using the static Divide method.
Vector vector1 = new Vector(20, 30);
Vector vectorResult = new Vector();
Double scalar1 = 75;
vectorResult = Vector.Divide(vector1, scalar1);
// vectorResult is approximately equal to (0.26667,0.4)
// Displaying Results
syntaxString = "vectorResult = Vector.Divide(vector1, scalar1);";
resultType = "Vector";
operationString = "Dividing a Vector by a Scalar";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb17":
{
// Gets the hashcode of a Vector structure
Vector vector1 = new Vector(20, 30);
int vectorHashCode;
vectorHashCode = vector1.GetHashCode();
// Displaying Results
syntaxString = "vectorHashCode = vector1.GetHashCode();";
resultType = "int";
operationString = "Getting the hashcode of a Vector";
ShowResults(vectorHashCode.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb18":
{
// Gets the length of a Vector.
Vector vector1 = new Vector(20, 30);
Double length;
length = vector1.Length;
// length is approximately equal to 36.0555
// Displaying Results
syntaxString = "length = vector1.Length();";
resultType = "Double";
operationString = "Getting the length of a Vector";
ShowResults(length.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb19":
{
// Gets the square of the length of a Vector.
Vector vector1 = new Vector(20, 30);
Double lengthSq;
lengthSq = vector1.LengthSquared;
// lengthSq is equal to 1300
// Displaying Results
syntaxString = "lengthSq = vector1.LengthSquared;";
resultType = "Double";
operationString = "Getting the length square of a Vector";
ShowResults(lengthSq.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb20":
{
// Normalizes a Vector using the Normalize method.
Vector vector1 = new Vector(20, 30);
vector1.Normalize();
// vector1 is approximately equal to (0.5547,0.8321)
// Displaying Results
syntaxString = "vector1.Normalize();";
resultType = "Vector";
operationString = "Normalizing a Vector";
ShowResults(vector1.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb21":
{
// Calculates the angle between two Vectors using the static AngleBetween method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Double angleBetween;
angleBetween = Vector.AngleBetween(vector1, vector2);
// angleBetween is approximately equal to 0.9548
// Displaying Results
syntaxString = "angleBetween = Vector.AngleBetween(vector1, vector2);";
resultType = "Double";
operationString = "Calculating the angle between two Vectors";
ShowResults(angleBetween.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb22":
{
// Calculates the cross product of two Vectors using the static CrossProduct method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Double crossProduct;
crossProduct = Vector.CrossProduct(vector1, vector2);
// crossProduct is equal to 50
// Displaying Results
syntaxString = "crossProduct = Vector.CrossProduct(vector1,vector2);";
resultType = "Double";
operationString = "Calculating the crossproduct of two Vectors";
ShowResults(crossProduct.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb23":
{
// Calculates the determinant of two Vectors using the static Determinant method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Double determinant;
determinant = Vector.Determinant(vector1, vector2);
// determinant is equal to 50
// Displaying Results
syntaxString = "determinant = Vector.Determinant(vector1, vector2);";
resultType = "Double";
operationString = "Calculating the determinant of two Vectors";
ShowResults(determinant.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb24":
{
// Checks if two Vectors are equal using the overloaded equality operator.
// Declaring vecto1 and initializing x,y values
Vector vector1 = new Vector(20, 30);
// Declaring vector2 without initializing x,y values
Vector vector2 = new Vector();
// Boolean to hold the result of the comparison
Boolean areEqual;
// assigning values to vector2
vector2.X = 45;
vector2.Y = 70;
// Comparing Vectors for equality
areEqual = (vector1 == vector2);
// areEqual is False
// Displaying Results
syntaxString = "areEqual = (vector1 == vector2);";
resultType = "Boolean";
operationString = "Checking if two vectors are equal";
ShowResults(areEqual.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb25":
{
// Checks if two Vectors are equal using the static Equals method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Boolean areEqual;
areEqual = Vector.Equals(vector1, vector2);
// areEqual is False
// Displaying Results
syntaxString = "areEqual = Vector.Equals(vector1, vector2);";
resultType = "Boolean";
operationString = "Checking if two vectors are equal";
ShowResults(areEqual.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb26":
{
// Compares an Object and a Vector for equality using the non-static Equals method.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Boolean areEqual;
areEqual = vector1.Equals(vector2);
// areEqual is False
// Displaying Results
syntaxString = "areEqual = vector1.Equals(vector2);";
resultType = "Boolean";
operationString = "Checking if two vectors are equal";
ShowResults(areEqual.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb27":
{
// Converts a string representation of a vector into a Vector structure
Vector vectorResult = new Vector();
vectorResult = Vector.Parse("1,3");
// vectorResult is equal to (1,3)
// Displaying Results
syntaxString = "vectorResult = Vector.Parse(\"1,3\");";
resultType = "Vector";
operationString = "Converting a string into a Vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb28":
{
// Checks if two Vectors are not equal using the overloaded inequality operator.
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
Boolean areNotEqual;
areNotEqual = (vector1 != vector2);
// areNotEqual is True
// Displaying Results
syntaxString = "areNotEqual = (vector1 != vector2);";
resultType = "Boolean";
operationString = "Checking if two points are not equal";
ShowResults(areNotEqual.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb29":
{
// Negates a Vector using the Negate method.
Vector vector1 = new Vector(20, 30);
Vector vectorResult = new Vector();
vector1.Negate();
// vector1 is equal to (-20, -30)
// Displaying Results
syntaxString = "vector1.Negate();";
resultType = "void";
operationString = "Negating a vector";
ShowResults(vector1.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb30":
{
// Negates a Vector using the overloaded unary negation operator.
Vector vector1 = new Vector(20, 30);
Vector vectorResult = new Vector();
vectorResult = -vector1;
// vectorResult is equal to (-20, -30)
// Displaying Results
syntaxString = "vectorResult = -vector1;";
resultType = "Vector";
operationString = "Negating a vector";
ShowResults(vectorResult.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb31":
{
// Gets a String representation of a Vector structure
Vector vector1 = new Vector(20, 30);
String vectorString;
vectorString = vector1.ToString();
// vectorString is equal to 10,5
// Displaying Results
syntaxString = "vectorString = vector1.ToString();";
resultType = "String";
operationString = "Getting the string representation of a Vector";
ShowResults(vectorString.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb32":
{
// Explicitly converts a Vector structure into a Size structure
// Returns a Size.
Vector vector1 = new Vector(20, 30);
System.Windows.Size size1 = new System.Windows.Size();
size1 = (System.Windows.Size)vector1;
// size1 has a width of 20 and a height of 30
// Displaying Results
syntaxString = "size1 = (Size)vector1;";
resultType = "Size";
operationString = "Expliciting casting a Vector into a Size";
ShowResults(size1.ToString(), syntaxString, resultType, operationString);
break;
}
case "rb33":
{
// Explicitly converts a Vector structure into a Point structure
// Returns a Point.
Vector vector1 = new Vector(20, 30);
System.Windows.Point point1 = new System.Windows.Point();
point1 = (System.Windows.Point)vector1;
// point1 is equal to (20, 30)
// Displaying Results
syntaxString = "point1 = (Point)vector1;";
resultType = "Point";
operationString = "Expliciting casting a Vector into a Point";
ShowResults(point1.ToString(), syntaxString, resultType, operationString);
break;
}
// task example. this case statement is not referenced from the list of radio buttons
case "rb40":
{
// adds two vectors using Add and +
Vector vector1 = new Vector(20, 30);
Vector vector2 = new Vector(45, 70);
vector1 = vector1 + vector2;
// vector1 is now equal to (65, 100)
vector1 = Vector.Add(vector1, vector2);
// vector1 is now equal to (110, 170)
// Displaying Results
syntaxString = "vectorResult = Vector.Negate(vector1);";
resultType = "Vector";
operationString = "Negating a vector";
ShowResults(vector1.ToString(), syntaxString, resultType, operationString);
break;
}
default:
break;
} // end switch
}
protected override System.Windows.Size ArrangeOverride(System.Windows.Size finalSize)
{
base.ArrangeOverride(finalSize);
UpdateSize();
return(finalSize);
}
public static RenderTargetBitmap ToRenderTargetBitmap(this UIElement element, Size size, PixelFormat pixelFormat)
{
var result = new RenderTargetBitmap((int)size.Width, (int)size.Height, 96, 96, pixelFormat);
element.Measure(size);
element.Arrange(new Rect(size));
result.Render(element);
return(result);
}
public static void SaveImage(this UIElement element, Size size, string fileName)
{
SaveImage(element, size, GetPixelFormat(fileName), fileName);
}
/// <summary>
/// Parametre olarak aldıgı Size degerine göre gelen Image i yeni boyutunu ayarlar
/// </summary>
/// <param name="imgToResize"></param>
/// <param name="size"></param>
/// <returns></returns>
public static System.Windows.Controls.Image ResizeImage(this System.Windows.Controls.Image imgToResize, System.Windows.Size size)
{
imgToResize.Width = size.Width;
imgToResize.Height = size.Height;
return(imgToResize);
}
public static RenderTargetBitmap ToRenderTargetBitmap(this UIElement element, Size size)
{
return(element.ToRenderTargetBitmap(size, PixelFormats.Pbgra32));
}
/// <summary>
/// Arranges the content of a System.Windows.Controls.Canvas element.
/// </summary>
/// <param name="arrangeSize"></param>
/// <returns></returns>
protected override System.Windows.Size ArrangeOverride(System.Windows.Size arrangeSize)
{
var offset = new Vector(arrangeSize.Width / 2, arrangeSize.Height / 2);
if (_slices != null)
{
double radius = Math.Min(arrangeSize.Width / 2, arrangeSize.Height / 2);
double startAngle = 0;
var fullCircle = new Circle {
Radius = radius
};
double minimumArcAngle = MinimumArcLength / fullCircle.Circumference * 2 * Math.PI;
foreach (IPieSlice slice in _slices)
{
PieChartSliceItem item = _sliceItems[slice];
double relativeValue = item.Slice.Value / SumOfSlices;
double openAngle = Math.Max(relativeValue * 2 * Math.PI, minimumArcAngle);
item.Center = (Point)offset;
item.StartAngle = startAngle;
item.OpenAngle = openAngle;
item.Radius = radius;
item.Arrange(new Rect(0, 0, arrangeSize.Width, arrangeSize.Height));
startAngle += openAngle;
}
}
foreach (var pair in _valueItems)
{
IPieSlice slice = pair.Key;
PieChartValueItem item = pair.Value;
PieChartSliceItem sliceItem = _sliceItems[slice];
System.Windows.Size desiredSize = item.DesiredSize;
Rect rect = FindValuePosition(sliceItem.Shape, desiredSize);
if (sliceItem.Shape.Contains(rect))
{
item.Visibility = Visibility.Visible;
item.Arrange(rect);
}
else
{
item.Visibility = Visibility.Collapsed;
}
}
foreach (var pair in _titleItems)
{
IPieSlice slice = pair.Key;
PieChartLabelItem item = pair.Value;
PieChartSliceItem sliceItem = _sliceItems[slice];
System.Windows.Size desiredSize = item.DesiredSize;
Vector specificOffset;
switch (sliceItem.Direction)
{
case SliceDirection.TopRight:
specificOffset = new Vector(0, -desiredSize.Height);
break;
case SliceDirection.BottomRight:
specificOffset = new Vector(0, 0);
break;
case SliceDirection.BottomLeft:
specificOffset = new Vector(-desiredSize.Width, 0);
break;
default:
specificOffset = new Vector(-desiredSize.Width, -desiredSize.Height);
break;
}
Circle circle = sliceItem.Shape.Circle;
circle.Radius += LabelMargin;
Point position = circle.GetPoint(sliceItem.Angle) + specificOffset;
var rect = new Rect(position, desiredSize);
item.Arrange(rect);
}
return(arrangeSize);
}
/// <summary>
/// A default implementation of MeasureOverride to be used by all WPF widgets
/// </summary>
/// <param name="constraint">Size constraints</param>
/// <param name="wpfMeasure">Size returned by the base MeasureOverride</param>
/// <returns></returns>
public System.Windows.Size MeasureOverride(System.Windows.Size constraint, System.Windows.Size wpfMeasure)
{
var defNaturalSize = eventSink.GetDefaultNaturalSize();
if (!double.IsPositiveInfinity(constraint.Width))
{
defNaturalSize.Width = Math.Min(defNaturalSize.Width, constraint.Width);
}
if (!double.IsPositiveInfinity(constraint.Height))
{
defNaturalSize.Height = Math.Min(defNaturalSize.Height, constraint.Height);
}
// -2 means use the WPF default, -1 use the XWT default, any other other value is used as custom natural size
var nw = DefaultNaturalWidth;
if (nw == -1)
{
nw = defNaturalSize.Width;
if (nw == 0)
{
nw = wpfMeasure.Width;
}
wpfMeasure.Width = nw;
}
else if (nw != -2)
{
wpfMeasure.Width = nw;
}
var nh = DefaultNaturalHeight;
if (nh == -1)
{
nh = defNaturalSize.Height;
if (nh == 0)
{
nh = wpfMeasure.Height;
}
wpfMeasure.Height = nh;
}
else if (nh != -2)
{
wpfMeasure.Height = nh;
}
// If we are calculating the default preferred size of the widget we end here.
// See note above about when GetPreferred* methods are called.
if (calculatingPreferredSize)
{
return(wpfMeasure);
}
if ((enabledEvents & WidgetEvent.PreferredSizeCheck) != 0)
{
Context.InvokeUserCode(delegate
{
// Calculate the preferred width through the frontend if there is an overriden OnGetPreferredWidth, but only do it
// if we are not given a constraint. If there is a width constraint, we'll use that constraint value for calculating the height
var cw = double.IsPositiveInfinity(constraint.Width) ? SizeConstraint.Unconstrained : constraint.Width;
var ch = double.IsPositiveInfinity(constraint.Height) ? SizeConstraint.Unconstrained : constraint.Height;
var ws = eventSink.GetPreferredSize(cw, ch);
wpfMeasure = new System.Windows.Size(ws.Width, ws.Height);
});
}
return(wpfMeasure);
}
public static void AskToPrint( FrameworkElement ctrl
, string printJobDesc = "Scaled Visual")
{
PrintDialog print = new PrintDialog();
if (print.ShowDialog() != true) return;
PrintCapabilities capabilities = print.PrintQueue.GetPrintCapabilities(print.PrintTicket);
double scale = Math.Min(capabilities.PageImageableArea.ExtentWidth / ctrl.ActualWidth,
capabilities.PageImageableArea.ExtentHeight / ctrl.ActualHeight);
//Transform oldTransform = ctrl.LayoutTransform;
ctrl.LayoutTransform = new ScaleTransform(scale, scale);
//Size oldSize = new Size(ctrl.ActualWidth, ctrl.ActualHeight);
Size sz = new Size(capabilities.PageImageableArea.ExtentWidth, capabilities.PageImageableArea.ExtentHeight);
ctrl.Measure(sz);
((UIElement)ctrl).Arrange(new Rect(new Point(capabilities.PageImageableArea.OriginWidth, capabilities.PageImageableArea.OriginHeight),
sz));
ctrl.Focus();
print.PrintVisual(ctrl, printJobDesc);
//ctrl.LayoutTransform = oldTransform;
//ctrl.Measure(oldSize);
//((UIElement)ctrl).Arrange(new Rect(new Point(0, 0),
// oldSize));
}
public void PreparePrinting(PrintTicket printTicket, Size pageSize)
{
printTicket.PageOrientation = pageSize.Height >= pageSize.Width ? PageOrientation.Portrait : PageOrientation.Landscape;
var printExtension = _reportProvider as IReportPrintExtension;
if (printExtension != null)
printExtension.PreparePrinting(printTicket, pageSize);
}
