public void UnequalsF()
{
float f1 = 1.0999f;
float f2 = 1.1f;
int r = Numeric.Compare(f1, f2);
Assert.AreEqual(-1, r);
r = Numeric.Compare(f2, f1);
Assert.AreEqual(1, r);
r = Numeric.Compare(f1, f2, 0.00001f);
Assert.AreEqual(-1, r);
r = Numeric.Compare(f2, f1, 0.00001f);
Assert.AreEqual(1, r);
bool b = Numeric.AreEqual(f1, f2);
Assert.IsFalse(b);
b = Numeric.AreEqual(f1, f2, 0.00001f);
Assert.IsFalse(b);
}
public void ComparisionsWithZeroF()
{
// Test case for bug fix
Assert.IsTrue(Numeric.AreEqual(0.0f, 0.0f));
Assert.AreEqual(0, Numeric.Compare(0.0f, 0.0f));
// Values near zero are treated as zero
Assert.IsTrue(Numeric.AreEqual(0.0f, 1e-10f));
Assert.IsTrue(Numeric.AreEqual(0.0f, -1e-10f));
Assert.IsTrue(Numeric.AreEqual(-1e-10f, 0.0f));
Assert.IsTrue(Numeric.AreEqual(1e-10f, 0.0f));
Assert.IsFalse(Numeric.AreEqual(0.0f, 1e-4f));
Assert.IsFalse(Numeric.AreEqual(0.0f, -1e-4f));
Assert.IsFalse(Numeric.AreEqual(-1e-4f, 0.0f));
Assert.IsFalse(Numeric.AreEqual(1e-4f, 0.0f));
// Values near zero are treated as zero
Assert.AreEqual(0, Numeric.Compare(0.0f, 1e-10f));
Assert.AreEqual(0, Numeric.Compare(0.0f, -1e-10f));
Assert.AreEqual(0, Numeric.Compare(-1e-10f, 0.0f));
Assert.AreEqual(0, Numeric.Compare(1e-10f, 0.0f));
Assert.AreEqual(-1, Numeric.Compare(0.0f, 1e-4f));
Assert.AreEqual(+1, Numeric.Compare(0.0f, -1e-4f));
Assert.AreEqual(-1, Numeric.Compare(-1e-4f, 0.0f));
Assert.AreEqual(+1, Numeric.Compare(1e-4f, 0.0f));
}
public void UnequalsD()
{
double d1 = 1.0999;
double d2 = 1.1;
int r = Numeric.Compare(d1, d2);
Assert.AreEqual(-1, r);
r = Numeric.Compare(d2, d1);
Assert.AreEqual(1, r);
r = Numeric.Compare(d1, d2, 0.00001);
Assert.AreEqual(-1, r);
r = Numeric.Compare(d2, d1, 0.00001);
Assert.AreEqual(1, r);
bool b = Numeric.AreEqual(d1, d2);
Assert.IsFalse(b);
b = Numeric.AreEqual(d1, d2, 0.00001);
Assert.IsFalse(b);
}
public void NegativeValuesF()
{
// Test case for bug fix
Assert.IsTrue(Numeric.AreEqual(-1000.0f, -1000.0f));
Assert.IsFalse(Numeric.AreEqual(-1000.0f, 1000.0f));
Assert.IsFalse(Numeric.AreEqual(1000.0f, -1000.0f));
Assert.AreEqual(0, Numeric.Compare(-1000.0f, -1000.0f));
Assert.AreEqual(-1, Numeric.Compare(-1000.0f, 1000.0f));
Assert.AreEqual(1, Numeric.Compare(1000.0f, -1000.0f));
}
public void SmallNumbersF()
{
Assert.AreEqual(-1, Numeric.Compare(1e-10f, 1.002e-10f, 0.001e-10f));
Assert.AreEqual(0, Numeric.Compare(1e-10f, 1.0001e-10f, 0.001e-10f));
Assert.AreEqual(1, Numeric.Compare(1.002e-10f, 1e-10f, 0.001e-10f));
// Values near zero are treated as zero
Assert.IsTrue(Numeric.AreEqual(1e-10f, 1.0000001e-10f));
Assert.IsTrue(Numeric.AreEqual(1e-10f, 1.000002e-10f));
// Values near zero can only be compared by specifying an epsilon value.
Assert.IsTrue(Numeric.AreEqual(1e-10f, 1.0001e-10f, 0.001e-10f));
Assert.IsFalse(Numeric.AreEqual(1e-10f, 1.0002e-10f, 0.0001e-10f));
}
public void EqualsF()
{
float f1 = 1.1f;
float f2 = 1.0999999f;
int r = Numeric.Compare(f1, f2);
Assert.AreEqual(0, r);
r = Numeric.Compare(f1, f2, 0.000001f);
Assert.AreEqual(0, r);
bool b = Numeric.AreEqual(f1, f2);
Assert.IsTrue(b);
b = Numeric.AreEqual(f1, f2, 0.0001f);
Assert.IsTrue(b);
}
public void EqualsD()
{
double d1 = 1.1;
double d2 = 1.099999999999999999;
int r = Numeric.Compare(d1, d2);
Assert.AreEqual(0, r);
r = Numeric.Compare(d1, d2, 0.00000001);
Assert.AreEqual(0, r);
bool b = Numeric.AreEqual(d1, d2);
Assert.IsTrue(b);
b = Numeric.AreEqual(d1, d2, 0.0001);
Assert.IsTrue(b);
}
public void BigNumbersF()
{
float originalEpsilon = Numeric.EpsilonF;
Numeric.EpsilonF = 1e-8f;
Assert.AreEqual(-1, Numeric.Compare(1e10f, 1.0000002e10f));
Assert.AreEqual(0, Numeric.Compare(1e10f, 1.00000001e10f));
Assert.AreEqual(1, Numeric.Compare(1.0000002e10f, 1e10f));
Assert.AreEqual(-1, Numeric.Compare(1e10f, 1.002e10f, 0.001e10f));
Assert.AreEqual(0, Numeric.Compare(1e10f, 1.0001e10f, 0.001e10f));
Assert.AreEqual(1, Numeric.Compare(1.002e10f, 1e10f, 0.001e10f));
Assert.IsTrue(Numeric.AreEqual(1e10f, 1.00000001e10f));
Assert.IsFalse(Numeric.AreEqual(1e10f, 1.0000002e10f));
Assert.IsTrue(Numeric.AreEqual(1e10f, 1.0001e10f, 0.001e10f));
Numeric.EpsilonF = originalEpsilon;
}
public void BigNumbersD()
{
double originalEpsilon = Numeric.EpsilonD;
Numeric.EpsilonD = 1e-8;
Assert.AreEqual(-1, Numeric.Compare(1e20, 1.0000002e20));
Assert.AreEqual(0, Numeric.Compare(1e20, 1.00000001e20));
Assert.AreEqual(1, Numeric.Compare(1.0000002e20, 1e20));
Assert.AreEqual(-1, Numeric.Compare(1e20, 1.002e20, 0.001e20));
Assert.AreEqual(0, Numeric.Compare(1e20, 1.0001e20, 0.001e20));
Assert.AreEqual(1, Numeric.Compare(1.002e20, 1e20, 0.001e20));
Assert.IsTrue(Numeric.AreEqual(1e20, 1.00000001e20));
Assert.IsFalse(Numeric.AreEqual(1e20, 1.0000002e20));
Assert.IsTrue(Numeric.AreEqual(1e20, 1.0001e20, 0.001e20));
Numeric.EpsilonD = originalEpsilon;
}
public void InfinityEqualityD()
{
Assert.IsTrue(Numeric.AreEqual(double.PositiveInfinity, double.PositiveInfinity));
Assert.IsTrue(Numeric.AreEqual(double.PositiveInfinity, double.PositiveInfinity, 0.1d));
Assert.IsTrue(Numeric.AreEqual(double.NegativeInfinity, double.NegativeInfinity));
Assert.IsTrue(Numeric.AreEqual(double.NegativeInfinity, double.NegativeInfinity, 0.1d));
Assert.IsFalse(Numeric.AreEqual(double.PositiveInfinity, double.NegativeInfinity));
Assert.IsFalse(Numeric.AreEqual(double.NegativeInfinity, double.PositiveInfinity, 0.1d));
Assert.IsFalse(Numeric.AreEqual(0d, double.PositiveInfinity));
Assert.IsFalse(Numeric.AreEqual(double.NegativeInfinity, 0d));
Assert.IsTrue(Numeric.Compare(double.PositiveInfinity, double.PositiveInfinity) == 0);
Assert.IsTrue(Numeric.Compare(double.NegativeInfinity, double.NegativeInfinity) == 0);
Assert.IsTrue(Numeric.Compare(double.NegativeInfinity, double.PositiveInfinity) < 0);
Assert.IsTrue(Numeric.Compare(double.PositiveInfinity, double.NegativeInfinity) > 0);
Assert.IsTrue(Numeric.Compare(0d, double.NegativeInfinity) > 0);
Assert.IsTrue(Numeric.Compare(0d, double.PositiveInfinity) < 0);
Assert.IsTrue(Numeric.Compare(0d, double.NegativeInfinity) > 0);
}
public void InfinityEqualityF()
{
Assert.IsTrue(Numeric.AreEqual(float.PositiveInfinity, float.PositiveInfinity));
Assert.IsTrue(Numeric.AreEqual(float.PositiveInfinity, float.PositiveInfinity, 0.1f));
Assert.IsTrue(Numeric.AreEqual(float.NegativeInfinity, float.NegativeInfinity));
Assert.IsTrue(Numeric.AreEqual(float.NegativeInfinity, float.NegativeInfinity, 0.1f));
Assert.IsFalse(Numeric.AreEqual(float.PositiveInfinity, float.NegativeInfinity));
Assert.IsFalse(Numeric.AreEqual(float.NegativeInfinity, float.PositiveInfinity, 0.1f));
Assert.IsFalse(Numeric.AreEqual(0f, float.PositiveInfinity));
Assert.IsFalse(Numeric.AreEqual(float.NegativeInfinity, 0f));
Assert.IsTrue(Numeric.Compare(float.PositiveInfinity, float.PositiveInfinity) == 0);
Assert.IsTrue(Numeric.Compare(float.NegativeInfinity, float.NegativeInfinity) == 0);
Assert.IsTrue(Numeric.Compare(float.NegativeInfinity, float.PositiveInfinity) < 0);
Assert.IsTrue(Numeric.Compare(float.PositiveInfinity, float.NegativeInfinity) > 0);
Assert.IsTrue(Numeric.Compare(0f, float.NegativeInfinity) > 0);
Assert.IsTrue(Numeric.Compare(0f, float.PositiveInfinity) < 0);
Assert.IsTrue(Numeric.Compare(0f, float.NegativeInfinity) > 0);
}
public void CompareFException()
{
Numeric.Compare(0.0f, 0.0f, -0.1f);
}
public void CompareDException()
{
Numeric.Compare(0.0, 0.0, -0.1);
}
private PaletteEntry GetPaletteEntry(double value)
{
if (Count == 0)
{
throw new PaletteException("The palette is empty.");
}
// Try direct index access. This is faster for palettes where the index of a
// PaletteEntry is equal to the value of the entry.
if (value >= 0 && (int)value < Count)
{
PaletteEntry entry = this[(int)value];
if (Numeric.AreEqual(entry.Value, value))
{
return(entry);
}
}
BuildInternalSortedList();
PaletteEntry?lessEntry = null; // Entry whose data value is less than value.
PaletteEntry?greaterEntry = null; // Entry whose data value is greater than value.
PaletteEntry?equalEntry = null; // Entry whose data value exactly matches value.
for (int i = 0; i < _sortedPaletteEntries.Count; i++)
{
#if SILVERLIGHT || WINDOWS_PHONE
PaletteEntry entry = _sortedPaletteEntries[i];
#else
PaletteEntry entry = _sortedPaletteEntries.Values[i];
#endif
int comparisonResult = Numeric.Compare(entry.Value, value);
if (comparisonResult < 0)
{
lessEntry = entry;
}
else if (comparisonResult == 0)
{
equalEntry = entry;
}
else
{
Debug.Assert(comparisonResult > 0, "Sanity check.");
greaterEntry = entry;
break;
}
}
if (equalEntry != null)
{
// Exact match!
return(equalEntry.Value);
}
if (lessEntry != null && greaterEntry != null)
{
// value lies between two colors.
switch (Mode)
{
case PaletteMode.LessOrEqual:
return(lessEntry.Value);
case PaletteMode.GreaterOrEqual:
return(greaterEntry.Value);
case PaletteMode.Closest:
return((value - lessEntry.Value.Value < greaterEntry.Value.Value - value) ? lessEntry.Value : greaterEntry.Value);
case PaletteMode.Interpolate:
Color interpolatedColor = GetInterpolatedColor(value, lessEntry.Value, greaterEntry.Value);
PaletteEntry interpolatedEntry = new PaletteEntry(value, interpolatedColor);
return(interpolatedEntry);
}
}
if (lessEntry != null && greaterEntry == null)
{
// value is greater than the colors in the palette.
switch (Mode)
{
case PaletteMode.LessOrEqual:
case PaletteMode.Closest:
case PaletteMode.Interpolate:
return(lessEntry.Value);
case PaletteMode.GreaterOrEqual:
throw new PaletteException("No suitable color found. Specified value is greater than all color entries in the palette.");
}
}
if (lessEntry == null && greaterEntry != null)
{
// value is less than the colors in the palette.
switch (Mode)
{
case PaletteMode.GreaterOrEqual:
case PaletteMode.Closest:
case PaletteMode.Interpolate:
return(greaterEntry.Value);
case PaletteMode.LessOrEqual:
throw new PaletteException("No suitable color found. Specified value is less than all color entries in the palette.");
}
}
throw new PaletteException("No suitable color found.");
}
protected override Size ArrangeOverride(Size finalSize)
{
// Ensure that all axes are up to date.
foreach (Axis axis in _monitoredAxes)
{
axis.Update();
}
UIElementCollection children = Children;
for (int i = 0; i < children.Count; ++i)
{
UIElement child = children[i];
if (child == null)
{
continue;
}
// Get the child or one of its descendants that needs to be positioned.
DependencyObject elementThatRequiresArrange = GetElementThatRequiresArrange(child);
if (elementThatRequiresArrange == null)
{
// This child ignores the attached properties (X1, Y1, X2, Y2).
Rect childBounds = new Rect(new Point(), finalSize);
// Arrange element,
child.Arrange(childBounds);
// Clip to chart area.
if (GetClipToChartArea(child))
{
ClipElementToChartArea(child, childBounds);
}
}
else
{
// Determine alignment.
HorizontalAlignment horizontalAlignment = HorizontalAlignment.Left;
VerticalAlignment verticalAlignment = VerticalAlignment.Top;
if (elementThatRequiresArrange is FrameworkElement)
{
FrameworkElement frameworkElement = (FrameworkElement)elementThatRequiresArrange;
horizontalAlignment = frameworkElement.HorizontalAlignment;
verticalAlignment = frameworkElement.VerticalAlignment;
}
// Get associated axes.
Axis xAxis = GetXAxis(elementThatRequiresArrange);
Axis yAxis = GetYAxis(elementThatRequiresArrange);
// Check whether we have to position the element relative to a point (X1, Y1)
// or inside a region (X1, Y1) - (X2, Y2).
// Convert positions given in data values to pixel positions.
double x1 = xAxis.GetPosition(GetX1(elementThatRequiresArrange));
double y1 = yAxis.GetPosition(GetY1(elementThatRequiresArrange));
double x2 = xAxis.GetPosition(GetX2(elementThatRequiresArrange));
double y2 = yAxis.GetPosition(GetY2(elementThatRequiresArrange));
bool isX1Valid = Numeric.IsFinite(x1);
bool isY1Valid = Numeric.IsFinite(y1);
bool isX2Valid = Numeric.IsFinite(x2);
bool isY2Valid = Numeric.IsFinite(y2);
double availableWidth = Double.PositiveInfinity;
double availableHeight = Double.PositiveInfinity;
if (!isX1Valid && !isX2Valid)
{
// No coordinates set. Use 0 and 'left' alignment.
x1 = 0;
x2 = Double.NaN;
horizontalAlignment = HorizontalAlignment.Left;
}
else if (!isX1Valid)
{
// Only X2 set. Use X2 as position.
x1 = x2;
x2 = Double.NaN;
}
else if (isX2Valid)
{
// X1 and X2 are set.
int result = Numeric.Compare(x1, x2);
if (result < 0)
{
// X1 < X2: Horizontal region.
availableWidth = x2 - x1;
}
else if (result == 0)
{
// X1 == X2: Use only X1.
x2 = Double.NaN;
}
else
{
// X2 > X1: Horizontal region, but swapped.
ChartHelper.Swap(ref x1, ref x2);
availableWidth = x2 - x1;
}
}
if (!isY1Valid && !isY2Valid)
{
// No coordinates set. Use 0 and 'top' alignment.
y1 = 0;
y2 = Double.NaN;
verticalAlignment = VerticalAlignment.Top;
}
else if (!isY1Valid)
{
// Only Y2 set. Use Y2 as position.
y1 = y2;
y2 = Double.NaN;
}
else if (isY2Valid)
{
// Y1 and Y2 are set.
int result = Numeric.Compare(y1, y2);
if (result < 0)
{
// Y1 < Y2: Horizontal region.
availableHeight = y2 - y1;
}
else if (result == 0)
{
// Y1 == Y2: Use only Y1.
y2 = Double.NaN;
}
else
{
// Y2 > Y1: Horizontal region, but swapped.
ChartHelper.Swap(ref y1, ref y2);
availableHeight = y2 - y1;
}
}
// Get size of child.
double elementWidth = child.DesiredSize.Width;
double elementHeight = child.DesiredSize.Height;
if (elementWidth == 0.0 && elementHeight == 0.0 && child is FrameworkElement)
{
// Fix for Silverlight.
FrameworkElement frameworkElement = (FrameworkElement)child;
elementWidth = frameworkElement.ActualWidth;
elementHeight = frameworkElement.ActualHeight;
}
// Compute bounds of the child element.
Rect childBounds = new Rect();
// Position child horizontally.
if (Numeric.IsNaN(x2))
{
// Position child relative to point.
switch (horizontalAlignment)
{
case HorizontalAlignment.Left:
case HorizontalAlignment.Stretch:
childBounds.X = x1;
childBounds.Width = elementWidth;
break;
case HorizontalAlignment.Center:
childBounds.X = x1 - elementWidth / 2.0;
childBounds.Width = elementWidth;
break;
case HorizontalAlignment.Right:
childBounds.X = x1 - elementWidth;
childBounds.Width = elementWidth;
break;
}
}
else
{
// Position child inside horizontal region.
switch (horizontalAlignment)
{
case HorizontalAlignment.Left:
childBounds.X = x1;
childBounds.Width = elementWidth;
break;
case HorizontalAlignment.Center:
childBounds.X = x1 + availableWidth / 2.0 - elementWidth / 2.0;
childBounds.Width = elementWidth;
break;
case HorizontalAlignment.Right:
childBounds.X = x2 - elementWidth;
childBounds.Width = elementWidth;
break;
case HorizontalAlignment.Stretch:
childBounds.X = x1;
childBounds.Width = availableWidth;
break;
}
}
// Position child vertically.
if (Numeric.IsNaN(y2))
{
// Position child relative to point.
switch (verticalAlignment)
{
case VerticalAlignment.Top:
case VerticalAlignment.Stretch:
childBounds.Y = y1;
childBounds.Height = elementHeight;
break;
case VerticalAlignment.Center:
childBounds.Y = y1 - elementHeight / 2.0;
childBounds.Height = elementHeight;
break;
case VerticalAlignment.Bottom:
childBounds.Y = y1 - elementHeight;
childBounds.Height = elementHeight;
break;
}
}
else
{
// Position child inside vertical region.
switch (verticalAlignment)
{
case VerticalAlignment.Top:
childBounds.Y = y1;
childBounds.Height = elementHeight;
break;
case VerticalAlignment.Center:
childBounds.Y = y1 + availableHeight / 2.0 - elementHeight / 2.0;
childBounds.Height = elementHeight;
break;
case VerticalAlignment.Bottom:
childBounds.Y = y2 - elementHeight;
childBounds.Height = elementHeight;
break;
case VerticalAlignment.Stretch:
childBounds.Y = y1;
childBounds.Height = availableHeight;
break;
}
}
// Arrange element.
child.Arrange(childBounds);
// Clip to chart area.
if (elementThatRequiresArrange is UIElement && GetClipToChartArea(elementThatRequiresArrange))
{
UIElement element = (UIElement)elementThatRequiresArrange;
ClipElementToChartArea(element, childBounds);
}
}
}
return(finalSize);
}