Creating User-Defined Types - Coding

Applies to: SQL Server

When coding your user-defined type (UDT) definition, you must implement various features, depending on whether you are implementing the UDT as a class or a structure, as well as on the format and serialization options you have chosen.

The example in this section illustrates implementing a Point UDT as a struct (or Structure in Visual Basic). The Point UDT consists of X and Y coordinates implemented as property procedures.

The following namespaces are required when defining a UDT:

Imports System  
Imports System.Data.SqlTypes  
Imports Microsoft.SqlServer.Server  
using System;  
using System.Data.SqlTypes;  
using Microsoft.SqlServer.Server;  

The Microsoft.SqlServer.Server namespace contains the objects required for various attributes of your UDT, and the System.Data.SqlTypes namespace contains the classes that represent SQL Server native data types available to the assembly. There may of course be additional namespaces that your assembly requires in order to function correctly. The Point UDT also uses the System.Text namespace for working with strings.

Note

Visual C++ database objects, such as UDTs, compiled with /clr:pure are not supported for execution.

Specifying Attributes

Attributes determine how serialization is used to construct the storage representation of UDTs and to transmit UDTs by value to the client.

The Microsoft.SqlServer.Server.SqlUserDefinedTypeAttribute is required. The Serializable attribute is optional. You can also specify the Microsoft.SqlServer.Server.SqlFacetAttribute to provide information about the return type of a UDT. For more information, see Custom Attributes for CLR Routines.

Point UDT Attributes

The Microsoft.SqlServer.Server.SqlUserDefinedTypeAttribute sets the storage format for the Point UDT to Native. IsByteOrdered is set to true, which guarantees that the results of comparisons are the same in SQL Server as if the same comparison had taken place in managed code. The UDT implements the System.Data.SqlTypes.INullable interface to make the UDT null aware.

The following code fragment shows the attributes for the Point UDT.

<Serializable(), SqlUserDefinedTypeAttribute(Format.Native, _  
  IsByteOrdered:=True)> _  
  Public Structure Point  
    Implements INullable  
[Serializable]  
[Microsoft.SqlServer.Server.SqlUserDefinedType(Format.Native,  
  IsByteOrdered=true)]  
public struct Point : INullable  
{  

Implementing Nullability

In addition to specifying the attributes for your assemblies correctly, your UDT must also support nullability. UDTs loaded into SQL Server are null-aware, but in order for the UDT to recognize a null value, the UDT must implement the System.Data.SqlTypes.INullable interface.

You must create a property named IsNull, which is needed to determine whether a value is null from within CLR code. When SQL Server finds a null instance of a UDT, the UDT is persisted using normal null-handling methods. The server does not waste time serializing or deserializing the UDT if it does not have to, and it does not waste space to store a null UDT. This check for nulls is performed every time a UDT is brought over from the CLR, which means that using the Transact-SQL IS NULL construct to check for null UDTs should always work. The IsNull property is also used by the server to test whether an instance is null. Once the server determines that the UDT is null, it can use its native null handling.

The get() method of IsNull is not special-cased in any way. If a Point variable @p is Null, then @p.IsNull will, by default, evaluate to "NULL", not "1". This is because the SqlMethod(OnNullCall) attribute of the IsNull get() method defaults to false. Because the object is Null, when the property is requested the object is not deserialized, the method is not called, and a default value of "NULL" is returned.

Example

In the following example, the is_Null variable is private and holds the state of null for the instance of the UDT. Your code must maintain an appropriate value for is_Null. The UDT must also have a static property named Null that returns a null value instance of the UDT. This allows the UDT to return a null value if the instance is indeed null in the database.

Private is_Null As Boolean  
  
Public ReadOnly Property IsNull() As Boolean _  
   Implements INullable.IsNull  
    Get  
        Return (is_Null)  
    End Get  
End Property  
  
Public Shared ReadOnly Property Null() As Point  
    Get  
        Dim pt As New Point  
        pt.is_Null = True  
        Return (pt)  
    End Get  
End Property  
private bool is_Null;  
  
public bool IsNull  
{  
    get  
    {  
        return (is_Null);  
    }  
}  
  
public static Point Null  
{  
    get  
    {  
        Point pt = new Point();  
        pt.is_Null = true;  
        return pt;  
    }  
}  

IS NULL vs. IsNull

Consider a table that contains the schema Points(id int, location Point), where Point is a CLR UDT, and the following queries:

--Query 1  
SELECT ID  
FROM Points  
WHERE NOT (location IS NULL) -- Or, WHERE location IS NOT NULL;  
--Query 2:  
SELECT ID  
FROM Points  
WHERE location.IsNull = 0;  

Both queries return the IDs of points with non-Null locations. In Query 1, normal null-handling is used, and there no deserialization of UDTs is required. Query 2, on the other hand, has to deserialize each non-Null object and call into the CLR to obtain the value of the IsNull property. Clearly, using IS NULL will exhibit better performance and there should never be a reason to read the IsNull property of a UDT from Transact-SQL code.

So, what is the use of the IsNull property? First, it is needed to determine whether a value is Null from within CLR code. Second, the server needs a way to test whether an instance is Null, so this property is used by the server. After it determines it is Null, then it can use its native null handling to handle it.

Implementing the Parse Method

The Parse and ToString methods allow for conversions to and from string representations of the UDT. The Parse method allows a string to be converted into a UDT. It must be declared as static (or Shared in Visual Basic), and take a parameter of type System.Data.SqlTypes.SqlString.

The following code implements the Parse method for the Point UDT, which separates out the X and Y coordinates. The Parse method has a single argument of type System.Data.SqlTypes.SqlString, and assumes that X and Y values are supplied as a comma-delimited string. Setting the Microsoft.SqlServer.Server.SqlMethodAttribute.OnNullCall attribute to false prevents the Parse method from being called from a null instance of Point.

<SqlMethod(OnNullCall:=False)> _  
Public Shared Function Parse(ByVal s As SqlString) As Point  
    If s.IsNull Then  
        Return Null  
    End If  
  
    ' Parse input string here to separate out points.  
    Dim pt As New Point()  
    Dim xy() As String = s.Value.Split(",".ToCharArray())  
    pt.X = Int32.Parse(xy(0))  
    pt.Y = Int32.Parse(xy(1))  
    Return pt  
End Function  
[SqlMethod(OnNullCall = false)]  
public static Point Parse(SqlString s)  
{  
    if (s.IsNull)  
        return Null;  
  
    // Parse input string to separate out points.  
    Point pt = new Point();  
    string[] xy = s.Value.Split(",".ToCharArray());  
    pt.X = Int32.Parse(xy[0]);  
    pt.Y = Int32.Parse(xy[1]);  
    return pt;  
}  

Implementing the ToString Method

The ToString method converts the Point UDT to a string value. In this case, the string "NULL" is returned for a Null instance of the Point type. The ToString method reverses the Parse method by using a System.Text.StringBuilder to return a comma-delimited System.String consisting of the X and Y coordinate values. Because InvokeIfReceiverIsNull defaults to false, the check for a null instance of Point is unnecessary.

Private _x As Int32  
Private _y As Int32  
  
Public Overrides Function ToString() As String  
    If Me.IsNull Then  
        Return "NULL"  
    Else  
        Dim builder As StringBuilder = New StringBuilder  
        builder.Append(_x)  
        builder.Append(",")  
        builder.Append(_y)  
        Return builder.ToString  
    End If  
End Function  
private Int32 _x;  
private Int32 _y;  
  
public override string ToString()  
{  
    if (this.IsNull)  
        return "NULL";  
    else  
    {  
        StringBuilder builder = new StringBuilder();  
        builder.Append(_x);  
        builder.Append(",");  
        builder.Append(_y);  
        return builder.ToString();  
    }  
}  

Exposing UDT Properties

The Point UDT exposes X and Y coordinates that are implemented as public read-write properties of type System.Int32.

Public Property X() As Int32  
    Get  
        Return (Me._x)  
    End Get  
  
    Set(ByVal Value As Int32)  
        _x = Value  
    End Set  
End Property  
  
Public Property Y() As Int32  
    Get  
        Return (Me._y)  
    End Get  
  
    Set(ByVal Value As Int32)  
        _y = Value  
    End Set  
End Property  
public Int32 X  
{  
    get  
    {  
        return this._x;  
    }  
    set   
    {  
        _x = value;  
    }  
}  
  
public Int32 Y  
{  
    get  
    {  
        return this._y;  
    }  
    set  
    {  
        _y = value;  
    }  
}  

Validating UDT Values

When working with UDT data, SQL Server Database Engine automatically converts binary values to UDT values. This conversion process involves checking that values are appropriate for the serialization format of the type and ensuring that the value can be deserialized correctly. This ensures that the value can be converted back to binary form. In the case of byte-ordered UDTs, this also ensures that the resulting binary value matches the original binary value. This prevents invalid values from being persisted in the database. In some cases, this level of checking may be inadequate. Additional validation may be required when UDT values are required to be in an expected domain or range. For example, a UDT that implements a date might require the day value to be a positive number that falls within a certain range of valid values.

The Microsoft.SqlServer.Server.SqlUserDefinedTypeAttribute.ValidationMethodName property of the Microsoft.SqlServer.Server.SqlUserDefinedTypeAttribute allows you to supply the name of a validation method that the server runs when data is assigned to a UDT or converted to a UDT. ValidationMethodName is also called during the running of the bcp utility, BULK INSERT, DBCC CHECKDB, DBCC CHECKFILEGROUP, DBCC CHECKTABLE, distributed query, and tabular data stream (TDS) remote procedure call (RPC) operations. The default value for ValidationMethodName is null, indicating that there is no validation method.

Example

The following code fragment shows the declaration for the Point class, which specifies a ValidationMethodName of ValidatePoint.

<Serializable(), SqlUserDefinedTypeAttribute(Format.Native, _  
  IsByteOrdered:=True, _  
  ValidationMethodName:="ValidatePoint")> _  
  Public Structure Point  
[Serializable]  
[Microsoft.SqlServer.Server.SqlUserDefinedType(Format.Native,  
  IsByteOrdered=true,   
  ValidationMethodName = "ValidatePoint")]  
public struct Point : INullable  
{  

If a validation method is specified, it must have a signature that looks like the following code fragment.

Private Function ValidationFunction() As Boolean  
    If (validation logic here) Then  
        Return True  
    Else  
        Return False  
    End If  
End Function  
private bool ValidationFunction()  
{  
    if (validation logic here)  
    {  
        return true;  
    }  
    else  
    {  
        return false;  
    }  
}  

The validation method can have any scope and should return true if the value is valid, and false otherwise. If the method returns false or throws an exception, the value is treated as not valid and an error is raised.

In the example below, the code allows only values of zero or greater the X and Y coordinates.

Private Function ValidatePoint() As Boolean  
    If (_x >= 0) And (_y >= 0) Then  
        Return True  
    Else  
        Return False  
    End If  
End Function  
private bool ValidatePoint()  
{  
    if ((_x >= 0) && (_y >= 0))  
    {  
        return true;  
    }  
    else  
    {  
        return false;  
    }  
}  

Validation Method Limitations

The server calls the validation method when the server is performing conversions, not when data is inserted by setting individual properties or when data is inserted using a Transact-SQL INSERT statement.

You must explicitly call the validation method from property setters and the Parse method if you want the validation method to execute in all situations. This is not a requirement, and in some cases may not even be desirable.

Parse Validation Example

To ensure that the ValidatePoint method is invoked in the Point class, you must call it from the Parse method and from the property procedures that set the X and Y coordinate values. The following code fragment shows how to call the ValidatePoint validation method from the Parse function.

<SqlMethod(OnNullCall:=False)> _  
Public Shared Function Parse(ByVal s As SqlString) As Point  
    If s.IsNull Then  
        Return Null  
    End If  
  
    ' Parse input string here to separate out points.  
    Dim pt As New Point()  
    Dim xy() As String = s.Value.Split(",".ToCharArray())  
    pt.X = Int32.Parse(xy(0))  
    pt.Y = Int32.Parse(xy(1))  
  
    ' Call ValidatePoint to enforce validation  
    ' for string conversions.  
    If Not pt.ValidatePoint() Then  
        Throw New ArgumentException("Invalid XY coordinate values.")  
    End If  
    Return pt  
End Function  
[SqlMethod(OnNullCall = false)]  
public static Point Parse(SqlString s)  
{  
    if (s.IsNull)  
        return Null;  
  
    // Parse input string to separate out points.  
    Point pt = new Point();  
    string[] xy = s.Value.Split(",".ToCharArray());  
    pt.X = Int32.Parse(xy[0]);  
    pt.Y = Int32.Parse(xy[1]);  
  
    // Call ValidatePoint to enforce validation  
    // for string conversions.  
    if (!pt.ValidatePoint())   
        throw new ArgumentException("Invalid XY coordinate values.");  
    return pt;  
}  

Property Validation Example

The following code fragment shows how to call the ValidatePoint validation method from the property procedures that set the X and Y coordinates.

Public Property X() As Int32  
    Get  
        Return (Me._x)  
    End Get  
  
    Set(ByVal Value As Int32)  
        Dim temp As Int32 = _x  
        _x = Value  
        If Not ValidatePoint() Then  
            _x = temp  
            Throw New ArgumentException("Invalid X coordinate value.")  
        End If  
    End Set  
End Property  
  
Public Property Y() As Int32  
    Get  
        Return (Me._y)  
    End Get  
  
    Set(ByVal Value As Int32)  
        Dim temp As Int32 = _y  
        _y = Value  
        If Not ValidatePoint() Then  
            _y = temp  
            Throw New ArgumentException("Invalid Y coordinate value.")  
        End If  
    End Set  
End Property  
    public Int32 X  
{  
    get  
    {  
        return this._x;  
    }  
    // Call ValidatePoint to ensure valid range of Point values.  
    set   
    {  
        Int32 temp = _x;  
        _x = value;  
        if (!ValidatePoint())  
        {  
            _x = temp;  
            throw new ArgumentException("Invalid X coordinate value.");  
        }  
    }  
}  
  
public Int32 Y  
{  
    get  
    {  
        return this._y;  
    }  
    set  
    {  
        Int32 temp = _y;  
        _y = value;  
        if (!ValidatePoint())  
        {  
            _y = temp;  
            throw new ArgumentException("Invalid Y coordinate value.");  
        }  
    }  
}  

Coding UDT Methods

When coding UDT methods, consider whether the algorithm used could possibly change over time. If so, you may want to consider creating a separate class for the methods your UDT uses. If the algorithm changes, you can recompile the class with the new code and load the assembly into SQL Server without affecting the UDT. In many cases UDTs can be reloaded using the Transact-SQL ALTER ASSEMBLY statement, but that could potentially cause problems with existing data. For example, the Currency UDT included with the AdventureWorks sample database uses a ConvertCurrency function to convert currency values, which is implemented in a separate class. It is possible that conversion algorithms may change in unpredictable ways in the future, or that new functionality may be required. Separating the ConvertCurrency function from the Currency UDT implementation provides greater flexibility when planning for future changes.

Example

The Point class contains three simple methods for calculating distance: Distance, DistanceFrom and DistanceFromXY. Each returns a double calculating the distance from Point to zero, the distance from a specified point to Point, and the distance from specified X and Y coordinates to Point. Distance and DistanceFrom each call DistanceFromXY, and demonstrate how to use different arguments for each method.

' Distance from 0 to Point.  
<SqlMethod(OnNullCall:=False)> _  
Public Function Distance() As Double  
    Return DistanceFromXY(0, 0)  
End Function  
  
' Distance from Point to the specified point.  
<SqlMethod(OnNullCall:=False)> _  
Public Function DistanceFrom(ByVal pFrom As Point) As Double  
    Return DistanceFromXY(pFrom.X, pFrom.Y)  
End Function  
  
' Distance from Point to the specified x and y values.  
<SqlMethod(OnNullCall:=False)> _  
Public Function DistanceFromXY(ByVal ix As Int32, ByVal iy As Int32) _  
    As Double  
    Return Math.Sqrt(Math.Pow(ix - _x, 2.0) + Math.Pow(iy - _y, 2.0))  
End Function  
// Distance from 0 to Point.  
[SqlMethod(OnNullCall = false)]  
public Double Distance()  
{  
    return DistanceFromXY(0, 0);  
}  
  
// Distance from Point to the specified point.  
[SqlMethod(OnNullCall = false)]  
public Double DistanceFrom(Point pFrom)  
{  
    return DistanceFromXY(pFrom.X, pFrom.Y);  
}  
  
// Distance from Point to the specified x and y values.  
[SqlMethod(OnNullCall = false)]  
public Double DistanceFromXY(Int32 iX, Int32 iY)  
{  
    return Math.Sqrt(Math.Pow(iX - _x, 2.0) + Math.Pow(iY - _y, 2.0));  
}  

Using SqlMethod Attributes

The Microsoft.SqlServer.Server.SqlMethodAttribute class provides custom attributes that can be used to mark method definitions in order to specify determinism, on null call behavior, and to specify whether a method is a mutator. Default values for these properties are assumed, and the custom attribute is only used when a non-default value is needed.

Note

The SqlMethodAttribute class inherits from the SqlFunctionAttribute class, so SqlMethodAttribute inherits the FillRowMethodName and TableDefinition fields from SqlFunctionAttribute. This implies that it is possible to write a table-valued method, which is not the case. The method compiles and the assembly deploys, but an error about the IEnumerable return type is raised at runtime with the following message: "Method, property, or field '<name>' in class '<class>' in assembly '<assembly>' has invalid return type."

The following table describes some of the relevant Microsoft.SqlServer.Server.SqlMethodAttribute properties that can be used in UDT methods, and lists their default values.

DataAccess
Indicates whether the function involves access to user data stored in the local instance of SQL Server. Default is DataAccessKind.None.

IsDeterministic
Indicates whether the function produces the same output values given the same input values and the same database state. Default is false.

IsMutator
Indicates whether the method causes a state change in the UDT instance. Default is false.

IsPrecise
Indicates whether the function involves imprecise computations, such as floating point operations. Default is false.

OnNullCall
Indicates whether the method is called when null reference input arguments are specified. Default is true.

Example

The Microsoft.SqlServer.Server.SqlMethodAttribute.IsMutator property allows you to mark a method that allows a change in the state of an instance of a UDT. Transact-SQL does not allow you to set two UDT properties in the SET clause of one UPDATE statement. However, you can have a method marked as a mutator that changes the two members.

Note

Mutator methods are not allowed in queries. They can be called only in assignment statements or data modification statements. If a method marked as mutator does not return void (or is not a Sub in Visual Basic), CREATE TYPE fails with an error.

The following statement assumes the existence of a Triangles UDT that has a Rotate method. The following Transact-SQL update statement invokes the Rotate method:

UPDATE Triangles SET t.RotateY(0.6) WHERE id=5  

The Rotate method is decorated with the SqlMethod attribute setting IsMutator to true so that SQL Server can mark the method as a mutator method. The code also sets OnNullCall to false, which indicates to the server that the method returns a null reference (Nothing in Visual Basic) if any of the input parameters are null references.

<SqlMethod(IsMutator:=True, OnNullCall:=False)> _  
Public Sub Rotate(ByVal anglex as Double, _  
  ByVal angley as Double, ByVal anglez As Double)   
   RotateX(anglex)  
   RotateY(angley)  
   RotateZ(anglez)  
End Sub  
[SqlMethod(IsMutator = true, OnNullCall = false)]  
public void Rotate(double anglex, double angley, double anglez)   
{  
   RotateX(anglex);  
   RotateY(angley);  
   RotateZ(anglez);  
}  

Implementing a UDT with a User-Defined Format

When implementing a UDT with a user-defined format, you must implement Read and Write methods that implement the Microsoft.SqlServer.Server.IBinarySerialize interface to handle serializing and deserializing UDT data. You must also specify the MaxByteSize property of the Microsoft.SqlServer.Server.SqlUserDefinedTypeAttribute.

The Currency UDT

The Currency UDT is included with the CLR samples that can be installed with SQL Server, beginning with SQL Server 2005 (9.x).

The Currency UDT supports handling amounts of money in the monetary system of a particular culture. You must define two fields: a string for CultureInfo, which specifies who issued the currency (en-us, for example) and a decimal for CurrencyValue, the amount of money.

Although it is not used by the server for performing comparisons, the Currency UDT implements the System.IComparable interface, which exposes a single method, System.IComparable.CompareTo. This is used on the client side in situations where it is desirable to accurately compare or order currency values within cultures.

Code running in the CLR compares the culture separately from the currency value. For Transact-SQL code, the following actions determine the comparison:

  1. Set the IsByteOrdered attribute to true, which tells SQL Server to use the persisted binary representation on disk for comparisons.

  2. Use the Write method for the Currency UDT to determine how the UDT is persisted on disk and therefore how UDT values are compared and ordered for Transact-SQL operations.

  3. Save the Currency UDT using the following binary format:

    1. Save the culture as a UTF-16 encoded string for bytes 0-19 with padding to the right with null characters.

    2. Use bytes 20 and above to contain the decimal value of the currency.

The purpose of the padding is to ensure that the culture is completely separated from the currency value, so that when one UDT is compared against another in Transact-SQL code, culture bytes are compared against culture bytes, and currency byte values are compared against currency byte values.

Currency Attributes

The Currency UDT is defined with the following attributes.

<Serializable(), Microsoft.SqlServer.Server.SqlUserDefinedType( _  
    Microsoft.SqlServer.Server.Format.UserDefined, _  
    IsByteOrdered:=True, MaxByteSize:=32), _  
    CLSCompliant(False)> _  
Public Structure Currency  
Implements INullable, IComparable, _  
Microsoft.SqlServer.Server.IBinarySerialize  
[Serializable]  
[SqlUserDefinedType(Format.UserDefined,   
    IsByteOrdered = true, MaxByteSize = 32)]  
    [CLSCompliant(false)]  
    public struct Currency : INullable, IComparable, IBinarySerialize  
    {  

Creating Read and Write Methods with IBinarySerialize

When you choose UserDefined serialization format, you also must implement the IBinarySerialize interface and create your own Read and Write methods. The following procedures from the Currency UDT use the System.IO.BinaryReader and System.IO.BinaryWriter to read from and write to the UDT.

' IBinarySerialize methods  
' The binary layout is as follow:  
'    Bytes 0 - 19: Culture name, padded to the right with null  
'    characters, UTF-16 encoded  
'    Bytes 20+: Decimal value of money  
' If the culture name is empty, the currency is null.  
Public Sub Write(ByVal w As System.IO.BinaryWriter) _  
  Implements Microsoft.SqlServer.Server.IBinarySerialize.Write  
    If Me.IsNull Then  
        w.Write(nullMarker)  
        w.Write(System.Convert.ToDecimal(0))  
        Return  
    End If  
  
    If cultureName.Length > cultureNameMaxSize Then  
        Throw New ApplicationException(String.Format(CultureInfo.CurrentUICulture, _  
           "{0} is an invalid culture name for currency as it is too long.", cultureNameMaxSize))  
    End If  
  
    Dim paddedName As String = cultureName.PadRight(cultureNameMaxSize, CChar(vbNullChar))  
  
    For i As Integer = 0 To cultureNameMaxSize - 1  
        w.Write(paddedName(i))  
    Next i  
  
    ' Normalize decimal value to two places  
    currencyVal = Decimal.Floor(currencyVal * 100) / 100  
    w.Write(currencyVal)  
End Sub  
  
Public Sub Read(ByVal r As System.IO.BinaryReader) _  
  Implements Microsoft.SqlServer.Server.IBinarySerialize.Read  
    Dim name As Char() = r.ReadChars(cultureNameMaxSize)  
    Dim stringEnd As Integer = Array.IndexOf(name, CChar(vbNullChar))  
  
    If stringEnd = 0 Then  
        cultureName = Nothing  
        Return  
    End If  
  
    cultureName = New String(name, 0, stringEnd)  
    currencyVal = r.ReadDecimal()  
End Sub  
  
// IBinarySerialize methods  
// The binary layout is as follow:  
//    Bytes 0 - 19:Culture name, padded to the right   
//    with null characters, UTF-16 encoded  
//    Bytes 20+:Decimal value of money  
// If the culture name is empty, the currency is null.  
public void Write(System.IO.BinaryWriter w)  
{  
    if (this.IsNull)  
    {  
        w.Write(nullMarker);  
        w.Write((decimal)0);  
        return;  
    }  
  
    if (cultureName.Length > cultureNameMaxSize)  
    {  
        throw new ApplicationException(string.Format(  
            CultureInfo.InvariantCulture,   
            "{0} is an invalid culture name for currency as it is too long.",   
            cultureNameMaxSize));  
    }  
  
    String paddedName = cultureName.PadRight(cultureNameMaxSize, '\0');  
    for (int i = 0; i < cultureNameMaxSize; i++)  
    {  
        w.Write(paddedName[i]);  
    }  
  
    // Normalize decimal value to two places  
    currencyValue = Decimal.Floor(currencyValue * 100) / 100;  
    w.Write(currencyValue);  
}  
public void Read(System.IO.BinaryReader r)  
{  
    char[] name = r.ReadChars(cultureNameMaxSize);  
    int stringEnd = Array.IndexOf(name, '\0');  
  
    if (stringEnd == 0)  
    {  
        cultureName = null;  
        return;  
    }  
  
    cultureName = new String(name, 0, stringEnd);  
    currencyValue = r.ReadDecimal();  
}  

See Also

Creating a User-Defined Type