RectangleShape¶

Namespace: ThinkGeo.Core

This class represents a rectangle, which is defined as an upper left point and a lower right point.

public class RectangleShape : AreaBaseShape

Inheritance Object → BaseShape → AreaBaseShape → RectangleShape

Remarks:

None

Properties¶

UpperLeftPoint¶

This property returns or sets the PointShape that represents the upper left point of the RectangleShape.

public PointShape UpperLeftPoint { get; set; }

Property Value¶

PointShape

        This property returns a PointShape at represents the upper left point of the
        RectangleShape.

Remarks:

None

UpperRightPoint¶

This property returns the PointShape that represents the upper right point of the RectangleShape.

public PointShape UpperRightPoint { get; }

Property Value¶

PointShape

        This property returns the PointShape that represents the upper right point of the
        RectangleShape.

Remarks:

None

LowerRightPoint¶

This property returns or sets the PointShape that represents the lower right point of the RectangleShape.

public PointShape LowerRightPoint { get; set; }

Property Value¶

PointShape

        This property returns the PointShape that represents the lower right point of the
        RectangleShape.

Remarks:

None

LowerLeftPoint¶

This property returns the PointShape that represents the lower left point of the RectangleShape.

public PointShape LowerLeftPoint { get; }

Property Value¶

PointShape

        This property returns the PointShape that represents the lower left point of the
        RectangleShape.

Remarks:

None

Height¶

This property returns the height of the RectangleShape in the unit of the shape.

public double Height { get; }

Property Value¶

Double

        This property returns the height of the RectangleShape in the unit of the
        shape.

Remarks:

None

Width¶

This property returns the width of the RectangleShape in the unit of the shape.

public double Width { get; }

Property Value¶

Double

        This property returns the width of the RectangleShape in the unit of the
        shape.

Remarks:

None

MinX¶

The MinX of the rectangle, equals to UpperLeftPoint.X

public double MinX { get; }

Property Value¶

Double

MaxY¶

The MaxY of the rectangle, equals to UpperLeftPoint.Y

public double MaxY { get; }

Property Value¶

Double

MaxX¶

The MaxX of the rectangle, equals to LowerRightPoint.X

public double MaxX { get; }

Property Value¶

Double

MinY¶

The MinY of the rectangle, equals to LowerRightPoint.Y

public double MinY { get; }

Property Value¶

Double

Id¶

The id of the shape.

public string Id { get; set; }

Property Value¶

String

Tag¶

The tag of the shape.

public object Tag { get; set; }

Property Value¶

Object

Constructors¶

RectangleShape()¶

This constructor creates a RectangleShape.

public RectangleShape()

Remarks:

None

RectangleShape(PointShape, PointShape)¶

This constructor creates a RectangleShape.

public RectangleShape(PointShape upperLeftPoint, PointShape lowerRightPoint)

Parameters¶

upperLeftPoint PointShape
This parameter specifies the upper left point of the rectangle.

lowerRightPoint PointShape
This parameter specifies the lower right point of the rectangle.

Exceptions¶

ArgumentException
If you pass in a upperLeftPoint that has a X value that is more than the lowerRightPoint's X value, it will throw a ArgumentException.

ArgumentException
If you pass in a upperLeftPoint that has a Y value that is less than the lowerRightPoint's Y value, it will throw a ArgumentException.

Remarks:

None

RectangleShape(Double, Double, Double, Double)¶

This constructor creates a RectangleShape.

public RectangleShape(double minX, double maxY, double maxX, double minY)

Parameters¶

minX Double

        This property specifies the minimum X value. This is also the upper left
        X.

maxY Double

        This property specifies the maximum Y value. This is also the upper left
        Y.

maxX Double

        This property specifies the maximum X value. This is also the lower right
        X.

minY Double

        This property specifies the minimum Y value. This is also the lower right
        Y.

Exceptions¶

ArgumentOutOfRangeException
If you pass in a maxX that is less than the minX, it will throw a ArgumentOutOfRangeException.

ArgumentOutOfRangeException
If you pass in a maxY that is less than the minY, it will throw a ArgumentOutOfRangeException.

Remarks:

None

RectangleShape(String)¶

This constructor creates a RectangleShape.

public RectangleShape(string wellKnownText)

Parameters¶

wellKnownText String
This parameter is the well-known text used to build the shape.

Exceptions¶

ArgumentException
Passing invalid well-known text in the wellKnownText parameter will throw an ArgumentException.

ArgumentNullException
Passing a null as the wellKnownText parameter will throw an ArgumentNullException.

Remarks:

None

RectangleShape(Byte[])¶

This constructor creates a RectangleShape.

public RectangleShape(Byte[] wellKnownBinary)

Parameters¶

wellKnownBinary Byte[]
This parameter is the well-known binary used to build the shape.

Exceptions¶

ArgumentException
Passing invalid well-known binary in the bytes parameter will throw an ArgumentException.

ArgumentNullException
Passing a null as the bytes parameter will throw an ArgumentNullException.

Remarks:

None

Methods¶

IntersectsCore(BaseShape)¶

protected bool IntersectsCore(BaseShape targetShape)

Parameters¶

targetShape BaseShape

Returns¶

Boolean

GetIntersection(RectangleShape)¶

This method returns the intersection of the current RectangleShape and the target shape, defined as the set of all points which lie in both the current shape and the target shape.

public RectangleShape GetIntersection(RectangleShape targetShape)

Parameters¶

targetShape RectangleShape
The shape you are trying to find the intersection with.

Returns¶

RectangleShape

        The return type is a RectangleShape that contains the set of all points which
        lie in both the current shape and the target shape.

Exceptions¶

ArgumentException
If you pass in a targetShape which does not have any points, we will throw an ArgumentException.

ArgumentNullException
If you pass a null as the targetShape, we will throw an ArgumentNullException.

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

Remarks:

None

GetWellKnownTypeCore()¶

This method returns the well-known type for the shape.

protected WellKnownType GetWellKnownTypeCore()

Returns¶

WellKnownType
This method returns the well-known type for the shape.

Remarks:

None

CloneDeepCore()¶

This method returns a complete copy of the shape without any references in common.

protected BaseShape CloneDeepCore()

Returns¶

BaseShape

        This method returns a complete copy of the shape without any references in
        common.

Remarks:

When you override this method, you need to ensure that there are no references in common between the original and copy.

ToPolygon()¶

This method returns the current shape as a PolygonShape.

public PolygonShape ToPolygon()

Returns¶

PolygonShape
This method returns the current shape as a PolygonShape.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

This method is mainly used to convert this GIS non-standard shape to a GIS standard shape.

ExpandToInclude(BaseShape)¶

This method will expand the current RectangleShape to include the targetShape parameter.

public void ExpandToInclude(BaseShape targetShape)

Parameters¶

targetShape BaseShape
This parameter is used to expand the current rectangle.

Exceptions¶

ArgumentException
If you pass in a targetShape which does not have any points, we will throw an ArgumentException.

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

There is also an overload that can expand the RectangleShape using a list of multiple shapes.

ExpandToInclude(Feature)¶

This method will expand the current RectangleShape to include the target feature parameter.

public void ExpandToInclude(Feature targetFeature)

Parameters¶

targetFeature Feature
This parameter is used to expand the current feature.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

There is also an overload that can expand the RectangleShape using a collection of features.

ExpandToInclude(IEnumerable<BaseShape>)¶

This method will expand the current RectangleShape to include the shapes in the targetShapes parameter.

public void ExpandToInclude(IEnumerable<BaseShape> targetShapes)

Parameters¶

targetShapes IEnumerable<BaseShape>
This parameter is used to expand the current rectangle.

Exceptions¶

ArgumentException
If you pass in targetShapes that do not have any points, we will throw an ArgumentException.

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

There is also an overload that can expand the RectangleShape using a single shape.

ExpandToInclude(IEnumerable<Feature>)¶

This method will expand the current RectangleShape to include the features in the targetFeatures parameter.

public void ExpandToInclude(IEnumerable<Feature> targetFeatures)

Parameters¶

targetFeatures IEnumerable<Feature>
This parameter is a group of features used to expand the current rectangle.

Exceptions¶

ArgumentNullException
If you pass in targetFeatures that do not have any points, we will throw an ArgumentException.

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

There also is an overload that can expand the RectangleShape using a single feature.

GetCenterPointCore()¶

This method returns the center point of the current shape's bounding box.

protected PointShape GetCenterPointCore()

Returns¶

PointShape

        A PointShape representing the center point of the current shape's bounding
        box.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

Remarks:

This method returns the center point of the current shape's bounding box. It is important to note that this is the center point of the bounding box. There are numerous ways to calculate the "center" of a geometry such, as its weighted center, etc. You can find other centers by examining the various methods of the shape itself.


Overriding:

Please ensure that you validate the parameters being passed in and raise the exceptions defined above.

ExpandToIncludeCore(BaseShape)¶

This method will expand the current RectangleShape to include the shape in the targetShape parameter.

protected void ExpandToIncludeCore(BaseShape targetShape)

Parameters¶

targetShape BaseShape
This parameter is used to expand the current rectangle.

Exceptions¶

ArgumentException
If you pass in a targetShape which does not have any points, we will throw an ArgumentException.

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

There is also an overload that can expand the RectangleShape using a list of shapes.

GetPerimeterCore(GeographyUnit, DistanceUnit)¶

This method returns the perimeter of the shape (defined as the sum of the lengths of all its sides).

protected double GetPerimeterCore(GeographyUnit shapeUnit, DistanceUnit returningUnit)

Parameters¶

shapeUnit GeographyUnit

        This is the GeographyUnit of the shape you are performing the operation
        on.

returningUnit DistanceUnit

        This is the DistanceUnit you would like to use as the return value. For example, if
        you select miles as your returningUnit, then the distance will be returned in
        miles.

Returns¶

Double

        The return unit is based on the LengthUnit you specify in the returningUnit
        parameter, regardless of the shape's GeographyUnit.

Exceptions¶

ArgumentOutOfRangeException
If you pass in a shapeUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

ArgumentOutOfRangeException
If you pass in a returningUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

Remarks:

You would use this method to find the distance around the area shape.

GetAreaCore(GeographyUnit, AreaUnit)¶

This method returns the area of the shape (defined as the size of the region enclosed by the figure).

protected double GetAreaCore(GeographyUnit shapeUnit, AreaUnit returningUnit)

Parameters¶

shapeUnit GeographyUnit

        This is the GeographyUnit of the shape you are performing the operation
        on.

returningUnit AreaUnit

        This is the AreaUnit you would like to use as the return value. For example, if
        you select square miles as your returningUnit, then the distance will be returned in
        square miles.

Returns¶

Double

        The return unit is based on the AreaUnit you specify in the returningUnit
        parameter, regardless of the shape's GeographyUnit.

Exceptions¶

ArgumentOutOfRangeException
If you pass in a shapeUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

ArgumentOutOfRangeException
If you pass in a returningUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

Remarks:

You would use this method to find the area inside the shape.

ScaleUpCore(Double)¶

This method increases the size of the area shape by the percentage given in the percentage parameter.

protected void ScaleUpCore(double percentage)

Parameters¶

percentage Double
This is the percentage by which to increase the shape's size.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentOutOfRangeException
Passing an invalid percentage which is less than 0 will throw an ArgumentOutOfRangeException.

Remarks:

This method is useful when you would like to increase the size of the shape. Note that a larger percentage will scale the shape up faster, as you are applying the operation multiple times. There is also a ScaleDown method that will shrink the shape.

ScaleDownCore(Double)¶

This method decreases the size of the area shape by the percentage given in the percentage parameter.

protected void ScaleDownCore(double percentage)

Parameters¶

percentage Double
This is the percentage by which to decrease the shape's size.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentOutOfRangeException
Passing an invalid percentage which is less than 0 will throw an ArgumentOutOfRangeException.

Remarks:

None

GetBoundingBoxCore()¶

This method calculates the smallest RectangleShape that encompasses the entire geometry.

protected RectangleShape GetBoundingBoxCore()

Returns¶

RectangleShape

        The RectangleShape returned is the smallest RectangleShape that can encompass the
        entire geometry.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

The GetBoundingBox method calculates the smallest RectangleShape that can encompass the entire geometry by examining each point in the geometry.

Depending on the number of PointShapes and complexity of the geometry, this operation can take longer for larger objects.

If the shape is a PointShape, then the bounding box's upper left and lower right points will be equal. This will create a RectangleShape with no area.

RegisterCore(PointShape, PointShape, DistanceUnit, GeographyUnit)¶

This method returns a MultipointShape which has been registered from its original coordinate system to another based on two anchor PointShapes.

protected BaseShape RegisterCore(PointShape fromPoint, PointShape toPoint, DistanceUnit fromUnit, GeographyUnit toUnit)

Parameters¶

fromPoint PointShape
This parameter is the anchor PointShape in the coordinate of origin.

toPoint PointShape
This parameter is the anchor PointShape in the coordinate of destination.

fromUnit DistanceUnit
This parameter is the GeographyUnit of the coordinate of origin.

toUnit GeographyUnit
This parameter is the GeographyUnit of the coordinate of destination.

Returns¶

BaseShape

        This method returns a MultipointShape which has been registered from its original
        coordinate system to another based on two anchor PointShapes.

Exceptions¶

ArgumentOutOfRangeException
If you pass in a fromUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

ArgumentOutOfRangeException
If you pass in a toUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

The register method is useful, for example, when a group of points represented by a MultipointShape has been generated in a non-geographic coordinate in meters, and you want to plot the points on a map that is in decimal degrees.

TranslateByOffsetCore(Double, Double, GeographyUnit, DistanceUnit)¶

This method moves the base shape from one location to another, based on an X and Y offset distance.

protected void TranslateByOffsetCore(double xOffsetDistance, double yOffsetDistance, GeographyUnit shapeUnit, DistanceUnit distanceUnit)

Parameters¶

xOffsetDistance Double

        This is the number of horizontal units of movement in the DistanceUnit specified as
        the distanceUnit.

yOffsetDistance Double

        This is the number of horizontal units of movement in the DistanceUnit specified as
        the distanceUnit.

shapeUnit GeographyUnit
This is the GeographicUnit of the shape you are performing the operation on.

distanceUnit DistanceUnit
This is the DistanceUnit you would like to use as the measure for the move. For example, if you select miles as your distanceUnit, then the xOffsetDistance and yOffsetDistance will be calculated in miles.

Exceptions¶

ArgumentOutOfRangeException
If you pass in a distanceUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

ArgumentOutOfRangeException
If you pass in a shapeUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

InvalidOperationException
In the event you attempt to call this method from a shape which has no points, it will throw an InvalidOperationException.

Remarks:

This method moves the base shape from one location to another, based on an X and Y offset distance. With this overload, it is important to note that the X and Y offset units are based on the distanceUnit parameter. For example, if your shape is in decimal degrees and you call this method with an X offset of 1 and a Y offset of 1, you're going to move this shape 1 unit of the distanceUnit in the horizontal direction and one unit of the distanceUnit in the vertical direction. In this way, you can easily move a shape in decimal degrees five miles to on the X axis and 3 miles on the Y axis.

TranslateByDegreeCore(Double, Double, GeographyUnit, DistanceUnit)¶

This method moves the shape from one location to another, based on a direction in degrees and distance.

protected void TranslateByDegreeCore(double distance, double angleInDegrees, GeographyUnit shapeUnit, DistanceUnit distanceUnit)

Parameters¶

distance Double

        The distance is the number of units to move the shape in the angle specified. The
        distance unit will be the same as the GeographyUnit for the shape. The distance must be
        greater than or equal to 0.

angleInDegrees Double
A number between 0 and 360 degrees that represents the direction you wish to move the shape, with 0 being up.

shapeUnit GeographyUnit
This is the GeographicUnit of the shape you are performing the operation on.

distanceUnit DistanceUnit
This is the DistanceUnit you would like to use as the measure for the move. For example, if you select miles as your distanceUnit, then the xOffsetDistance and yOffsetDistance will be calculated in miles.

Exceptions¶

ArgumentOutOfRangeException
Passing an invalid angleInDegrees which is not between 0 and 360 will throw an ArgumentOutOfRangeException.

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

ArgumentOutOfRangeException
Passing an invalid distance which is not greater than or equal to 0 will throw an ArgumentOutOfRangeException.

Remarks:

This method moves the base shape from one location to another, based on an angleInDegrees and distance parameter. With this overload, it is important to note that the distance units are the same GeographicUnit as the shape. For example, if your shape is in decimal degrees and you call this method with a distance of 1, you're going to move this shape 1 decimal degree in direction of the angleInDegrees. In many cases it is more useful to specify the DistanceUnit of movement, such as in miles or yards, so for these scenarios there is another overload you may want to use instead.

If you pass a distance of 0, then the operation is ignored.

GetClosestPointToCore(BaseShape, GeographyUnit)¶

This method returns the point of the current shape that is closest to the target shape.

protected PointShape GetClosestPointToCore(BaseShape targetShape, GeographyUnit shapeUnit)

Parameters¶

targetShape BaseShape
The shape you are trying to find the closest point to.

shapeUnit GeographyUnit
This is the GeographicUnit of the shape you are performing the operation on.

Returns¶

PointShape

        A PointShape representing the closest point of the current shape to the
        targetShape.

Exceptions¶

ArgumentException
If you pass in a targetShape which does not have any points, we will throw an ArgumentException.

ArgumentNullException
If you pass a null as the targetShape, we will throw an ArgumentNullException.

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentOutOfRangeException
If you pass in a shapeUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

Remarks:

This method returns the point of the current shape that is closest to the target shape. It is often the case that the point returned is not a point of the object itself. An example would be a line with two points that are far apart from each other. If you set the targetShape to be a point midway between the points but a short distance away from the line, the method would return a point that is on the line but not either of the two points that make up the line.

GetDistanceToCore(BaseShape, GeographyUnit, DistanceUnit)¶

This method computes the distance between the current shape and the targetShape.

protected double GetDistanceToCore(BaseShape targetShape, GeographyUnit shapeUnit, DistanceUnit distanceUnit)

Parameters¶

targetShape BaseShape
The shape you are trying to find the distance to.

shapeUnit GeographyUnit
The GeographyUnit of the targetShape.

distanceUnit DistanceUnit
The DistanceUnit of the returned value.

Returns¶

Double

        The return type is the distance between this shape and the targetShape in the
        GeographyUnit of the shape.
        Overriding:
        Please ensure that you validate the parameters being passed in and raise the exceptions defined
        above.

Exceptions¶

ArgumentException
If you pass in a targetShape which does not have any points, we will throw an ArgumentException.

ArgumentNullException
If you pass a null as the targetShape, we will throw an ArgumentNullException.

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentOutOfRangeException
If you pass in a shapeUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

ArgumentOutOfRangeException
If you pass in a distanceUnit that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

Remarks:

In this method, we compute the closest distance between the two shapes. The returned unit will be in the unit of distance specified.

GetWellKnownTextCore(RingOrder)¶

This method returns the well-known text representation of this shape.

protected string GetWellKnownTextCore(RingOrder outerRingOrder)

Parameters¶

outerRingOrder RingOrder

Returns¶

String
This method returns a string that represents the shape in well-known text.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on this shape which has invalid upper left and lower right points, it will throw an InvalidOperationException.

Remarks:

This method returns a string that represents the shape in well-known text. Well-known text allows you to describe a geometry as a string of text. Well-known text is useful when you want to save a geometry in a format such as a text file, or when you simply want to cut and paste the text between other applications. An alternative to well-known text is well-known binary, which is a binary representation of a geometry object. We have methods that work with well-known binary as well. Below are some samples of what well-known text might look like for various kinds of geometric shapes.

POINT(5 17)

LINESTRING(4 5,10 50,25 80)

POLYGON((2 2,6 2,6 6,2 6,2 2),(3 3,4 3,4 4,3 4,3 3))

MULTIPOINT(3.7 9.7,4.9 11.6)

MULTILINESTRING((4 5,11 51,21 26),(-4 -7,-9 -7,-14 -3))

MULTIPOLYGON(((2 2,6 2,6 6,2 6,2 2),(3 3,4 3,4 4,3 4,3 3)),((4 4,7 3,7 5,4 4)))

GetWellKnownBinaryCore(RingOrder, WkbByteOrder)¶

This method returns a byte array that represents the shape in well-known binary.

protected Byte[] GetWellKnownBinaryCore(RingOrder outerRingOrder, WkbByteOrder byteOrder)

Parameters¶

outerRingOrder RingOrder

byteOrder WkbByteOrder
This parameter specifies whether the byte order is big- or little-endian.

Returns¶

Byte[]

        This method returns a byte array that represents the shape in well-known
        binary.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentOutOfRangeException
If you pass in a ByteOrder that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

Remarks:

This method returns a byte array that represents the shape in well-known binary. Well-known binary allows you to describe a geometry as a binary array. Well-known binary is useful when you want to save a geometry in an efficient format using as little space as possible. An alternative to well-known binary is well-known text, which is a textual representation of a geometry object. We have methods that work with well-known text as well.

LoadFromWellKnownDataCore(String)¶

This method hydrates the current shape with its data from well-known text.

protected void LoadFromWellKnownDataCore(string wellKnownText)

Parameters¶

wellKnownText String
This parameter is the well-known text you will use to hydrate your object.

Exceptions¶

ArgumentException
Passing invalid well-known text in the wellKnownText parameter will throw an ArgumentException.

ArgumentNullException
Passing a null as the wellKnownText parameter will throw an ArgumentNullException.

Remarks:

None

LoadFromWellKnownDataCore(Byte[])¶

This method hydrates the current shape with its data from well-known binary.

protected void LoadFromWellKnownDataCore(Byte[] wellKnownBinary)

Parameters¶

wellKnownBinary Byte[]
This parameter is the well-known binary used to populate the shape.

Exceptions¶

ArgumentException
Passing invalid well-known binary in the bytes parameter will throw an ArgumentException.

ArgumentNullException
Passing a null as the bytes parameter will throw an ArgumentNullException.

Remarks:

This is used when you want to hydrate a shape based on well-known binary. You can create the shape and then load the well-known binary using this method.

IsDisjointedCore(BaseShape)¶

This method returns whether the current shape and the targetShape have no points in common.

protected bool IsDisjointedCore(BaseShape targetShape)

Parameters¶

targetShape BaseShape
The shape you wish to compare the current one to.

Returns¶

Boolean

        This method returns whether the current shape and the targetShape have no points in
        common.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentException
If you pass in a targetShape which is invalid, we will throw an ArgumentException.

ArgumentNullException
If you pass a null as the targetShape, we will throw an ArgumentNullException.

Remarks:

Overriding:

Please ensure that you validate the parameters being passed in and raise the exceptions defined above.

ValidateCore(ShapeValidationMode)¶

This method returns a ShapeValidationResult based on a series of tests.

protected ShapeValidationResult ValidateCore(ShapeValidationMode validationMode)

Parameters¶

validationMode ShapeValidationMode

        This parameter determines whether the test is simple or advanced. In some cases, the
        advanced tests can take some time. The simple test is designed to always be
        fast.

Returns¶

ShapeValidationResult

        This method returns a ShapeValidationResult based on a series of
        tests.

Exceptions¶

ArgumentOutOfRangeException
If you pass in a validationMode that is not defined in the enumeration, it will throw a ArgumentOutOfRangeException.

Remarks:

We use this method, with the simple enumeration, internally before doing any kind of other methods on the shape. In this way, we are able to verify the integrity of the shape itself. If you wish to test things such as whether a polygon self-intersects, we invite you to call this method with the advanced ShapeValidationMode. One thing to consider is that for complex polygon shapes this operation could take some time, which is why we only run the basic, faster test. If you are dealing with polygon shapes that are suspect, we suggest you run the advanced test.

GetCrossingCore(BaseShape)¶

This method returns the crossing points between the current shape and the passed-in target shape.

protected MultipointShape GetCrossingCore(BaseShape targetShape)

Parameters¶

targetShape BaseShape
The target shape you wish to get crossing with.

Returns¶

MultipointShape

        This method returns the crossing points between the current shape and the passed-in target shape.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentNullException
If you pass a null as the targetShape, we will throw an ArgumentNullException.

Remarks:

As this is a concrete public method that wraps a Core method, we reserve the right to add events and other logic to pre- or post-process data returned by the Core version of the method. In this way, we leave our framework open on our end, but also allow you the developer to extend our logic to suit your needs. If you have questions about this, please contact our support team as we would be happy to work with you on extending our framework.

ContainsCore(BaseShape)¶

This method returns if the targetShape lies within the interior of the current shape.

protected bool ContainsCore(BaseShape targetShape)

Parameters¶

targetShape BaseShape
The shape you wish to compare the current one to.

Returns¶

Boolean

        This method returns if the targetShape lies within the interior of the current
        shape.

Exceptions¶

InvalidOperationException
In the event you attempt to call this method on a shape which has no points, it will throw an InvalidOperationException.

ArgumentException
If you pass in a targetShape which is invalid, we will throw an ArgumentException.

ArgumentNullException
If you pass a null as the targetShape, we will throw an ArgumentNullException.

Remarks:

Overriding:

Please ensure that you validate the parameters being passed in and raise the exceptions defined above.

ToString()¶

This method returns a formatted representation of the UpperLeftPoint.X, UpperLeftPoint.Y, LowerRightPoint.X and LowerRightPoint.Y value.

public string ToString()

Returns¶

String

        This method returns a formatted representation of the UpperLeftPoint.X, UpperLeftPoint.Y, LowerRightPoint.X and LowerRightPoint.Y
        value.

Remarks:

The value will be formatted in the standard string format: -180,90,180,-90"