Type conversion in .NET
Every value has an associated type, which defines attributes such as the amount of space allocated to the value, the range of possible values it can have, and the members that it makes available. Many values can be expressed as more than one type. For example, the value 4 can be expressed as an integer or a floating-point value. Type conversion creates a value in a new type that is equivalent to the value of an old type, but does not necessarily preserve the identity (or exact value) of the original object.
.NET automatically supports the following conversions:
Conversion from a derived class to a base class. This means, for example, that an instance of any class or structure can be converted to an Object instance. This conversion does not require a casting or conversion operator.
Conversion from a base class back to the original derived class. In C#, this conversion requires a casting operator. In Visual Basic, it requires the
CType
operator ifOption Strict
is on.Conversion from a type that implements an interface to an interface object that represents that interface. This conversion does not require a casting or conversion operator.
Conversion from an interface object back to the original type that implements that interface. In C#, this conversion requires a casting operator. In Visual Basic, it requires the
CType
operator ifOption Strict
is on.
In addition to these automatic conversions, .NET provides several features that support custom type conversion. These include the following:
The
Implicit
operator, which defines the available widening conversions between types. For more information, see the Implicit Conversion with the Implicit Operator section.The
Explicit
operator, which defines the available narrowing conversions between types. For more information, see the Explicit Conversion with the Explicit Operator section.The IConvertible interface, which defines conversions to each of the base .NET data types. For more information, see The IConvertible Interface section.
The Convert class, which provides a set of methods that implement the methods in the IConvertible interface. For more information, see The Convert Class section.
The TypeConverter class, which is a base class that can be extended to support the conversion of a specified type to any other type. For more information, see The TypeConverter Class section.
Implicit conversion with the implicit operator
Widening conversions involve the creation of a new value from the value of an existing type that has either a more restrictive range or a more restricted member list than the target type. Widening conversions cannot result in data loss (although they may result in a loss of precision). Because data cannot be lost, compilers can handle the conversion implicitly or transparently, without requiring the use of an explicit conversion method or a casting operator.
Note
Although code that performs an implicit conversion can call a conversion method or use a casting operator, their use is not required by compilers that support implicit conversions.
For example, the Decimal type supports implicit conversions from Byte, Char, Int16, Int32, Int64, SByte, UInt16, UInt32, and UInt64 values. The following example illustrates some of these implicit conversions in assigning values to a Decimal variable.
byte byteValue = 16;
short shortValue = -1024;
int intValue = -1034000;
long longValue = 1152921504606846976;
ulong ulongValue = UInt64.MaxValue;
decimal decimalValue;
decimalValue = byteValue;
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
byteValue.GetType().Name, decimalValue);
decimalValue = shortValue;
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
shortValue.GetType().Name, decimalValue);
decimalValue = intValue;
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
intValue.GetType().Name, decimalValue);
decimalValue = longValue;
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
longValue.GetType().Name, decimalValue);
decimalValue = ulongValue;
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
ulongValue.GetType().Name, decimalValue);
// The example displays the following output:
// After assigning a Byte value, the Decimal value is 16.
// After assigning a Int16 value, the Decimal value is -1024.
// After assigning a Int32 value, the Decimal value is -1034000.
// After assigning a Int64 value, the Decimal value is 1152921504606846976.
// After assigning a UInt64 value, the Decimal value is 18446744073709551615.
Dim byteValue As Byte = 16
Dim shortValue As Short = -1024
Dim intValue As Integer = -1034000
Dim longValue As Long = CLng(1024 ^ 6)
Dim ulongValue As ULong = ULong.MaxValue
Dim decimalValue As Decimal
decimalValue = byteValue
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
byteValue.GetType().Name, decimalValue)
decimalValue = shortValue
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
shortValue.GetType().Name, decimalValue)
decimalValue = intValue
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
intValue.GetType().Name, decimalValue)
decimalValue = longValue
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
longValue.GetType().Name, decimalValue)
decimalValue = ulongValue
Console.WriteLine("After assigning a {0} value, the Decimal value is {1}.",
ulongValue.GetType().Name, decimalValue)
' The example displays the following output:
' After assigning a Byte value, the Decimal value is 16.
' After assigning a Int16 value, the Decimal value is -1024.
' After assigning a Int32 value, the Decimal value is -1034000.
' After assigning a Int64 value, the Decimal value is 1152921504606846976.
' After assigning a UInt64 value, the Decimal value is 18446744073709551615.
If a particular language compiler supports custom operators, you can also define implicit conversions in your own custom types. The following example provides a partial implementation of a signed byte data type named ByteWithSign
that uses sign-and-magnitude representation. It supports implicit conversion of Byte and SByte values to ByteWithSign
values.
public struct ByteWithSign
{
private SByte signValue;
private Byte value;
public static implicit operator ByteWithSign(SByte value)
{
ByteWithSign newValue;
newValue.signValue = (SByte)Math.Sign(value);
newValue.value = (byte)Math.Abs(value);
return newValue;
}
public static implicit operator ByteWithSign(Byte value)
{
ByteWithSign newValue;
newValue.signValue = 1;
newValue.value = value;
return newValue;
}
public override string ToString()
{
return (signValue * value).ToString();
}
}
Public Structure ImplicitByteWithSign
Private signValue As SByte
Private value As Byte
Public Overloads Shared Widening Operator CType(value As SByte) As ImplicitByteWithSign
Dim newValue As ImplicitByteWithSign
newValue.signValue = CSByte(Math.Sign(value))
newValue.value = CByte(Math.Abs(value))
Return newValue
End Operator
Public Overloads Shared Widening Operator CType(value As Byte) As ImplicitByteWithSign
Dim NewValue As ImplicitByteWithSign
newValue.signValue = 1
newValue.value = value
Return newValue
End Operator
Public Overrides Function ToString() As String
Return (signValue * value).ToString()
End Function
End Structure
Client code can then declare a ByteWithSign
variable and assign it Byte and SByte values without performing any explicit conversions or using any casting operators, as the following example shows.
SByte sbyteValue = -120;
ByteWithSign value = sbyteValue;
Console.WriteLine(value);
value = Byte.MaxValue;
Console.WriteLine(value);
// The example displays the following output:
// -120
// 255
Dim sbyteValue As SByte = -120
Dim value As ImplicitByteWithSign = sbyteValue
Console.WriteLine(value.ToString())
value = Byte.MaxValue
Console.WriteLine(value.ToString())
' The example displays the following output:
' -120
' 255
Explicit conversion with the explicit operator
Narrowing conversions involve the creation of a new value from the value of an existing type that has either a greater range or a larger member list than the target type. Because a narrowing conversion can result in a loss of data, compilers often require that the conversion be made explicit through a call to a conversion method or a casting operator. That is, the conversion must be handled explicitly in developer code.
Note
The major purpose of requiring a conversion method or casting operator for narrowing conversions is to make the developer aware of the possibility of data loss or an OverflowException so that it can be handled in code. However, some compilers can relax this requirement. For example, in Visual Basic, if Option Strict
is off (its default setting), the Visual Basic compiler tries to perform narrowing conversions implicitly.
For example, the UInt32, Int64, and UInt64 data types have ranges that exceed that the Int32 data type, as the following table shows.
Type | Comparison with range of Int32 |
---|---|
Int64 | Int64.MaxValue is greater than Int32.MaxValue, and Int64.MinValue is less than (has a greater negative range than) Int32.MinValue. |
UInt32 | UInt32.MaxValue is greater than Int32.MaxValue. |
UInt64 | UInt64.MaxValue is greater than Int32.MaxValue. |
To handle such narrowing conversions, .NET allows types to define an Explicit
operator. Individual language compilers can then implement this operator using their own syntax, or a member of the Convert class can be called to perform the conversion. (For more information about the Convert class, see The Convert Class later in this topic.) The following example illustrates the use of language features to handle the explicit conversion of these potentially out-of-range integer values to Int32 values.
long number1 = int.MaxValue + 20L;
uint number2 = int.MaxValue - 1000;
ulong number3 = int.MaxValue;
int intNumber;
try
{
intNumber = checked((int)number1);
Console.WriteLine("After assigning a {0} value, the Integer value is {1}.",
number1.GetType().Name, intNumber);
}
catch (OverflowException)
{
if (number1 > int.MaxValue)
Console.WriteLine("Conversion failed: {0} exceeds {1}.",
number1, int.MaxValue);
else
Console.WriteLine("Conversion failed: {0} is less than {1}.",
number1, int.MinValue);
}
try
{
intNumber = checked((int)number2);
Console.WriteLine("After assigning a {0} value, the Integer value is {1}.",
number2.GetType().Name, intNumber);
}
catch (OverflowException)
{
Console.WriteLine("Conversion failed: {0} exceeds {1}.",
number2, int.MaxValue);
}
try
{
intNumber = checked((int)number3);
Console.WriteLine("After assigning a {0} value, the Integer value is {1}.",
number3.GetType().Name, intNumber);
}
catch (OverflowException)
{
Console.WriteLine("Conversion failed: {0} exceeds {1}.",
number1, int.MaxValue);
}
// The example displays the following output:
// Conversion failed: 2147483667 exceeds 2147483647.
// After assigning a UInt32 value, the Integer value is 2147482647.
// After assigning a UInt64 value, the Integer value is 2147483647.
Dim number1 As Long = Integer.MaxValue + 20L
Dim number2 As UInteger = Integer.MaxValue - 1000
Dim number3 As ULong = Integer.MaxValue
Dim intNumber As Integer
Try
intNumber = CInt(number1)
Console.WriteLine("After assigning a {0} value, the Integer value is {1}.",
number1.GetType().Name, intNumber)
Catch e As OverflowException
If number1 > Integer.MaxValue Then
Console.WriteLine("Conversion failed: {0} exceeds {1}.",
number1, Integer.MaxValue)
Else
Console.WriteLine("Conversion failed: {0} is less than {1}.\n",
number1, Integer.MinValue)
End If
End Try
Try
intNumber = CInt(number2)
Console.WriteLine("After assigning a {0} value, the Integer value is {1}.",
number2.GetType().Name, intNumber)
Catch e As OverflowException
Console.WriteLine("Conversion failed: {0} exceeds {1}.",
number2, Integer.MaxValue)
End Try
Try
intNumber = CInt(number3)
Console.WriteLine("After assigning a {0} value, the Integer value is {1}.",
number3.GetType().Name, intNumber)
Catch e As OverflowException
Console.WriteLine("Conversion failed: {0} exceeds {1}.",
number1, Integer.MaxValue)
End Try
' The example displays the following output:
' Conversion failed: 2147483667 exceeds 2147483647.
' After assigning a UInt32 value, the Integer value is 2147482647.
' After assigning a UInt64 value, the Integer value is 2147483647.
Explicit conversions can produce different results in different languages, and these results can differ from the value returned by the corresponding Convert method. For example, if the Double value 12.63251 is converted to an Int32, both the Visual Basic CInt
method and the .NET Convert.ToInt32(Double) method round the Double to return a value of 13, but the C# (int)
operator truncates the Double to return a value of 12. Similarly, the C# (int)
operator does not support Boolean-to-integer conversion, but the Visual Basic CInt
method converts a value of true
to -1. On the other hand, the Convert.ToInt32(Boolean) method converts a value of true
to 1.
Most compilers allow explicit conversions to be performed in a checked or unchecked manner. When a checked conversion is performed, an OverflowException is thrown when the value of the type to be converted is outside the range of the target type. When an unchecked conversion is performed under the same conditions, the conversion might not throw an exception, but the exact behavior becomes undefined and an incorrect value might result.
Note
In C#, checked conversions can be performed by using the checked
keyword together with a casting operator, or by specifying the /checked+
compiler option. Conversely, unchecked conversions can be performed by using the unchecked
keyword together with the casting operator, or by specifying the /checked-
compiler option. By default, explicit conversions are unchecked. In Visual Basic, checked conversions can be performed by clearing the Remove integer overflow checks check box in the project's Advanced Compiler Settings dialog box, or by specifying the /removeintchecks-
compiler option. Conversely, unchecked conversions can be performed by selecting the Remove integer overflow checks check box in the project's Advanced Compiler Settings dialog box or by specifying the /removeintchecks+
compiler option. By default, explicit conversions are checked.
The following C# example uses the checked
and unchecked
keywords to illustrate the difference in behavior when a value outside the range of a Byte is converted to a Byte. The checked conversion throws an exception, but the unchecked conversion assigns Byte.MaxValue to the Byte variable.
int largeValue = Int32.MaxValue;
byte newValue;
try
{
newValue = unchecked((byte)largeValue);
Console.WriteLine("Converted the {0} value {1} to the {2} value {3}.",
largeValue.GetType().Name, largeValue,
newValue.GetType().Name, newValue);
}
catch (OverflowException)
{
Console.WriteLine("{0} is outside the range of the Byte data type.",
largeValue);
}
try
{
newValue = checked((byte)largeValue);
Console.WriteLine("Converted the {0} value {1} to the {2} value {3}.",
largeValue.GetType().Name, largeValue,
newValue.GetType().Name, newValue);
}
catch (OverflowException)
{
Console.WriteLine("{0} is outside the range of the Byte data type.",
largeValue);
}
// The example displays the following output:
// Converted the Int32 value 2147483647 to the Byte value 255.
// 2147483647 is outside the range of the Byte data type.
If a particular language compiler supports custom overloaded operators, you can also define explicit conversions in your own custom types. The following example provides a partial implementation of a signed byte data type named ByteWithSign
that uses sign-and-magnitude representation. It supports explicit conversion of Int32 and UInt32 values to ByteWithSign
values.
public struct ByteWithSignE
{
private SByte signValue;
private Byte value;
private const byte MaxValue = byte.MaxValue;
private const int MinValue = -1 * byte.MaxValue;
public static explicit operator ByteWithSignE(int value)
{
// Check for overflow.
if (value > ByteWithSignE.MaxValue || value < ByteWithSignE.MinValue)
throw new OverflowException(String.Format("'{0}' is out of range of the ByteWithSignE data type.",
value));
ByteWithSignE newValue;
newValue.signValue = (SByte)Math.Sign(value);
newValue.value = (byte)Math.Abs(value);
return newValue;
}
public static explicit operator ByteWithSignE(uint value)
{
if (value > ByteWithSignE.MaxValue)
throw new OverflowException(String.Format("'{0}' is out of range of the ByteWithSignE data type.",
value));
ByteWithSignE newValue;
newValue.signValue = 1;
newValue.value = (byte)value;
return newValue;
}
public override string ToString()
{
return (signValue * value).ToString();
}
}
Public Structure ByteWithSign
Private signValue As SByte
Private value As Byte
Private Const MaxValue As Byte = Byte.MaxValue
Private Const MinValue As Integer = -1 * Byte.MaxValue
Public Overloads Shared Narrowing Operator CType(value As Integer) As ByteWithSign
' Check for overflow.
If value > ByteWithSign.MaxValue Or value < ByteWithSign.MinValue Then
Throw New OverflowException(String.Format("'{0}' is out of range of the ByteWithSign data type.", value))
End If
Dim newValue As ByteWithSign
newValue.signValue = CSByte(Math.Sign(value))
newValue.value = CByte(Math.Abs(value))
Return newValue
End Operator
Public Overloads Shared Narrowing Operator CType(value As UInteger) As ByteWithSign
If value > ByteWithSign.MaxValue Then
Throw New OverflowException(String.Format("'{0}' is out of range of the ByteWithSign data type.", value))
End If
Dim NewValue As ByteWithSign
newValue.signValue = 1
newValue.value = CByte(value)
Return newValue
End Operator
Public Overrides Function ToString() As String
Return (signValue * value).ToString()
End Function
End Structure
Client code can then declare a ByteWithSign
variable and assign it Int32 and UInt32 values if the assignments include a casting operator or a conversion method, as the following example shows.
ByteWithSignE value;
try
{
int intValue = -120;
value = (ByteWithSignE)intValue;
Console.WriteLine(value);
}
catch (OverflowException e)
{
Console.WriteLine(e.Message);
}
try
{
uint uintValue = 1024;
value = (ByteWithSignE)uintValue;
Console.WriteLine(value);
}
catch (OverflowException e)
{
Console.WriteLine(e.Message);
}
// The example displays the following output:
// -120
// '1024' is out of range of the ByteWithSignE data type.
Dim value As ByteWithSign
Try
Dim intValue As Integer = -120
value = CType(intValue, ByteWithSign)
Console.WriteLine(value)
Catch e As OverflowException
Console.WriteLine(e.Message)
End Try
Try
Dim uintValue As UInteger = 1024
value = CType(uintValue, ByteWithSign)
Console.WriteLine(value)
Catch e As OverflowException
Console.WriteLine(e.Message)
End Try
' The example displays the following output:
' -120
' '1024' is out of range of the ByteWithSign data type.
The IConvertible interface
To support the conversion of any type to a common language runtime base type, .NET provides the IConvertible interface. The implementing type is required to provide the following:
A method that returns the TypeCode of the implementing type.
Methods to convert the implementing type to each common language runtime base type (Boolean, Byte, DateTime, Decimal, Double, and so on).
A generalized conversion method to convert an instance of the implementing type to another specified type. Conversions that are not supported should throw an InvalidCastException.
Each common language runtime base type (that is, the Boolean, Byte, Char, DateTime, Decimal, Double, Int16, Int32, Int64, SByte, Single, String, UInt16, UInt32, and UInt64), as well as the DBNull and Enum types, implement the IConvertible interface. However, these are explicit interface implementations; the conversion method can be called only through an IConvertible interface variable, as the following example shows. This example converts an Int32 value to its equivalent Char value.
int codePoint = 1067;
IConvertible iConv = codePoint;
char ch = iConv.ToChar(null);
Console.WriteLine("Converted {0} to {1}.", codePoint, ch);
Dim codePoint As Integer = 1067
Dim iConv As IConvertible = codePoint
Dim ch As Char = iConv.ToChar(Nothing)
Console.WriteLine("Converted {0} to {1}.", codePoint, ch)
The requirement to call the conversion method on its interface rather than on the implementing type makes explicit interface implementations relatively expensive. Instead, we recommend that you call the appropriate member of the Convert class to convert between common language runtime base types. For more information, see the next section, The Convert Class.
Note
In addition to the IConvertible interface and the Convert class provided by .NET, individual languages may also provide ways to perform conversions. For example, C# uses casting operators; Visual Basic uses compiler-implemented conversion functions such as CType
, CInt
, and DirectCast
.
For the most part, the IConvertible interface is designed to support conversion between the base types in .NET. However, the interface can also be implemented by a custom type to support conversion of that type to other custom types. For more information, see the section Custom Conversions with the ChangeType Method later in this topic.
The Convert class
Although each base type's IConvertible interface implementation can be called to perform a type conversion, calling the methods of the System.Convert class is the recommended language-neutral way to convert from one base type to another. In addition, the Convert.ChangeType(Object, Type, IFormatProvider) method can be used to convert from a specified custom type to another type.
Conversions between base types
The Convert class provides a language-neutral way to perform conversions between base types and is available to all languages that target the common language runtime. It provides a complete set of methods for both widening and narrowing conversions, and throws an InvalidCastException for conversions that are not supported (such as the conversion of a DateTime value to an integer value). Narrowing conversions are performed in a checked context, and an OverflowException is thrown if the conversion fails.
Important
Because the Convert class includes methods to convert to and from each base type, it eliminates the need to call each base type's IConvertible explicit interface implementation.
The following example illustrates the use of the System.Convert class to perform several widening and narrowing conversions between .NET base types.
// Convert an Int32 value to a Decimal (a widening conversion).
int integralValue = 12534;
decimal decimalValue = Convert.ToDecimal(integralValue);
Console.WriteLine("Converted the {0} value {1} to " +
"the {2} value {3:N2}.",
integralValue.GetType().Name,
integralValue,
decimalValue.GetType().Name,
decimalValue);
// Convert a Byte value to an Int32 value (a widening conversion).
byte byteValue = Byte.MaxValue;
int integralValue2 = Convert.ToInt32(byteValue);
Console.WriteLine("Converted the {0} value {1} to " +
"the {2} value {3:G}.",
byteValue.GetType().Name,
byteValue,
integralValue2.GetType().Name,
integralValue2);
// Convert a Double value to an Int32 value (a narrowing conversion).
double doubleValue = 16.32513e12;
try
{
long longValue = Convert.ToInt64(doubleValue);
Console.WriteLine("Converted the {0} value {1:E} to " +
"the {2} value {3:N0}.",
doubleValue.GetType().Name,
doubleValue,
longValue.GetType().Name,
longValue);
}
catch (OverflowException)
{
Console.WriteLine("Unable to convert the {0:E} value {1}.",
doubleValue.GetType().Name, doubleValue);
}
// Convert a signed byte to a byte (a narrowing conversion).
sbyte sbyteValue = -16;
try
{
byte byteValue2 = Convert.ToByte(sbyteValue);
Console.WriteLine("Converted the {0} value {1} to " +
"the {2} value {3:G}.",
sbyteValue.GetType().Name,
sbyteValue,
byteValue2.GetType().Name,
byteValue2);
}
catch (OverflowException)
{
Console.WriteLine("Unable to convert the {0} value {1}.",
sbyteValue.GetType().Name, sbyteValue);
}
// The example displays the following output:
// Converted the Int32 value 12534 to the Decimal value 12,534.00.
// Converted the Byte value 255 to the Int32 value 255.
// Converted the Double value 1.632513E+013 to the Int64 value 16,325,130,000,000.
// Unable to convert the SByte value -16.
' Convert an Int32 value to a Decimal (a widening conversion).
Dim integralValue As Integer = 12534
Dim decimalValue As Decimal = Convert.ToDecimal(integralValue)
Console.WriteLine("Converted the {0} value {1} to the {2} value {3:N2}.",
integralValue.GetType().Name,
integralValue,
decimalValue.GetType().Name,
decimalValue)
' Convert a Byte value to an Int32 value (a widening conversion).
Dim byteValue As Byte = Byte.MaxValue
Dim integralValue2 As Integer = Convert.ToInt32(byteValue)
Console.WriteLine("Converted the {0} value {1} to " +
"the {2} value {3:G}.",
byteValue.GetType().Name,
byteValue,
integralValue2.GetType().Name,
integralValue2)
' Convert a Double value to an Int32 value (a narrowing conversion).
Dim doubleValue As Double = 16.32513e12
Try
Dim longValue As Long = Convert.ToInt64(doubleValue)
Console.WriteLine("Converted the {0} value {1:E} to " +
"the {2} value {3:N0}.",
doubleValue.GetType().Name,
doubleValue,
longValue.GetType().Name,
longValue)
Catch e As OverflowException
Console.WriteLine("Unable to convert the {0:E} value {1}.",
doubleValue.GetType().Name, doubleValue)
End Try
' Convert a signed byte to a byte (a narrowing conversion).
Dim sbyteValue As SByte = -16
Try
Dim byteValue2 As Byte = Convert.ToByte(sbyteValue)
Console.WriteLine("Converted the {0} value {1} to " +
"the {2} value {3:G}.",
sbyteValue.GetType().Name,
sbyteValue,
byteValue2.GetType().Name,
byteValue2)
Catch e As OverflowException
Console.WriteLine("Unable to convert the {0} value {1}.",
sbyteValue.GetType().Name, sbyteValue)
End Try
' The example displays the following output:
' Converted the Int32 value 12534 to the Decimal value 12,534.00.
' Converted the Byte value 255 to the Int32 value 255.
' Converted the Double value 1.632513E+013 to the Int64 value 16,325,130,000,000.
' Unable to convert the SByte value -16.
In some cases, particularly when converting to and from floating-point values, a conversion may involve a loss of precision, even though it does not throw an OverflowException. The following example illustrates this loss of precision. In the first case, a Decimal value has less precision (fewer significant digits) when it is converted to a Double. In the second case, a Double value is rounded from 42.72 to 43 in order to complete the conversion.
double doubleValue;
// Convert a Double to a Decimal.
decimal decimalValue = 13956810.96702888123451471211m;
doubleValue = Convert.ToDouble(decimalValue);
Console.WriteLine("{0} converted to {1}.", decimalValue, doubleValue);
doubleValue = 42.72;
try
{
int integerValue = Convert.ToInt32(doubleValue);
Console.WriteLine("{0} converted to {1}.",
doubleValue, integerValue);
}
catch (OverflowException)
{
Console.WriteLine("Unable to convert {0} to an integer.",
doubleValue);
}
// The example displays the following output:
// 13956810.96702888123451471211 converted to 13956810.9670289.
// 42.72 converted to 43.
Dim doubleValue As Double
' Convert a Double to a Decimal.
Dim decimalValue As Decimal = 13956810.96702888123451471211d
doubleValue = Convert.ToDouble(decimalValue)
Console.WriteLine("{0} converted to {1}.", decimalValue, doubleValue)
doubleValue = 42.72
Try
Dim integerValue As Integer = Convert.ToInt32(doubleValue)
Console.WriteLine("{0} converted to {1}.",
doubleValue, integerValue)
Catch e As OverflowException
Console.WriteLine("Unable to convert {0} to an integer.",
doubleValue)
End Try
' The example displays the following output:
' 13956810.96702888123451471211 converted to 13956810.9670289.
' 42.72 converted to 43.
For a table that lists both the widening and narrowing conversions supported by the Convert class, see Type Conversion Tables.
Custom conversions with the ChangeType method
In addition to supporting conversions to each of the base types, the Convert class can be used to convert a custom type to one or more predefined types. This conversion is performed by the Convert.ChangeType(Object, Type, IFormatProvider) method, which in turn wraps a call to the IConvertible.ToType method of the value
parameter. This means that the object represented by the value
parameter must provide an implementation of the IConvertible interface.
Note
Because the Convert.ChangeType(Object, Type) and Convert.ChangeType(Object, Type, IFormatProvider) methods use a Type object to specify the target type to which value
is converted, they can be used to perform a dynamic conversion to an object whose type is not known at compile time. However, note that the IConvertible implementation of value
must still support this conversion.
The following example illustrates a possible implementation of the IConvertible interface that allows a TemperatureCelsius
object to be converted to a TemperatureFahrenheit
object and vice versa. The example defines a base class, Temperature
, that implements the IConvertible interface and overrides the Object.ToString method. The derived TemperatureCelsius
and TemperatureFahrenheit
classes each override the ToType
and the ToString
methods of the base class.
using System;
public abstract class Temperature : IConvertible
{
protected decimal temp;
public Temperature(decimal temperature)
{
this.temp = temperature;
}
public decimal Value
{
get { return this.temp; }
set { this.temp = value; }
}
public override string ToString()
{
return temp.ToString(null as IFormatProvider) + "º";
}
// IConvertible implementations.
public TypeCode GetTypeCode()
{
return TypeCode.Object;
}
public bool ToBoolean(IFormatProvider provider)
{
throw new InvalidCastException(String.Format("Temperature-to-Boolean conversion is not supported."));
}
public byte ToByte(IFormatProvider provider)
{
if (temp < Byte.MinValue || temp > Byte.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the Byte data type.", temp));
else
return (byte)temp;
}
public char ToChar(IFormatProvider provider)
{
throw new InvalidCastException("Temperature-to-Char conversion is not supported.");
}
public DateTime ToDateTime(IFormatProvider provider)
{
throw new InvalidCastException("Temperature-to-DateTime conversion is not supported.");
}
public decimal ToDecimal(IFormatProvider provider)
{
return temp;
}
public double ToDouble(IFormatProvider provider)
{
return (double)temp;
}
public short ToInt16(IFormatProvider provider)
{
if (temp < Int16.MinValue || temp > Int16.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the Int16 data type.", temp));
else
return (short)Math.Round(temp);
}
public int ToInt32(IFormatProvider provider)
{
if (temp < Int32.MinValue || temp > Int32.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the Int32 data type.", temp));
else
return (int)Math.Round(temp);
}
public long ToInt64(IFormatProvider provider)
{
if (temp < Int64.MinValue || temp > Int64.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the Int64 data type.", temp));
else
return (long)Math.Round(temp);
}
public sbyte ToSByte(IFormatProvider provider)
{
if (temp < SByte.MinValue || temp > SByte.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the SByte data type.", temp));
else
return (sbyte)temp;
}
public float ToSingle(IFormatProvider provider)
{
return (float)temp;
}
public virtual string ToString(IFormatProvider provider)
{
return temp.ToString(provider) + "°";
}
// If conversionType is implemented by another IConvertible method, call it.
public virtual object ToType(Type conversionType, IFormatProvider provider)
{
switch (Type.GetTypeCode(conversionType))
{
case TypeCode.Boolean:
return this.ToBoolean(provider);
case TypeCode.Byte:
return this.ToByte(provider);
case TypeCode.Char:
return this.ToChar(provider);
case TypeCode.DateTime:
return this.ToDateTime(provider);
case TypeCode.Decimal:
return this.ToDecimal(provider);
case TypeCode.Double:
return this.ToDouble(provider);
case TypeCode.Empty:
throw new NullReferenceException("The target type is null.");
case TypeCode.Int16:
return this.ToInt16(provider);
case TypeCode.Int32:
return this.ToInt32(provider);
case TypeCode.Int64:
return this.ToInt64(provider);
case TypeCode.Object:
// Leave conversion of non-base types to derived classes.
throw new InvalidCastException(String.Format("Cannot convert from Temperature to {0}.",
conversionType.Name));
case TypeCode.SByte:
return this.ToSByte(provider);
case TypeCode.Single:
return this.ToSingle(provider);
case TypeCode.String:
IConvertible iconv = this;
return iconv.ToString(provider);
case TypeCode.UInt16:
return this.ToUInt16(provider);
case TypeCode.UInt32:
return this.ToUInt32(provider);
case TypeCode.UInt64:
return this.ToUInt64(provider);
default:
throw new InvalidCastException("Conversion not supported.");
}
}
public ushort ToUInt16(IFormatProvider provider)
{
if (temp < UInt16.MinValue || temp > UInt16.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the UInt16 data type.", temp));
else
return (ushort)Math.Round(temp);
}
public uint ToUInt32(IFormatProvider provider)
{
if (temp < UInt32.MinValue || temp > UInt32.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the UInt32 data type.", temp));
else
return (uint)Math.Round(temp);
}
public ulong ToUInt64(IFormatProvider provider)
{
if (temp < UInt64.MinValue || temp > UInt64.MaxValue)
throw new OverflowException(String.Format("{0} is out of range of the UInt64 data type.", temp));
else
return (ulong)Math.Round(temp);
}
}
public class TemperatureCelsius : Temperature, IConvertible
{
public TemperatureCelsius(decimal value) : base(value)
{
}
// Override ToString methods.
public override string ToString()
{
return this.ToString(null);
}
public override string ToString(IFormatProvider provider)
{
return temp.ToString(provider) + "°C";
}
// If conversionType is a implemented by another IConvertible method, call it.
public override object ToType(Type conversionType, IFormatProvider provider)
{
// For non-objects, call base method.
if (Type.GetTypeCode(conversionType) != TypeCode.Object)
{
return base.ToType(conversionType, provider);
}
else
{
if (conversionType.Equals(typeof(TemperatureCelsius)))
return this;
else if (conversionType.Equals(typeof(TemperatureFahrenheit)))
return new TemperatureFahrenheit((decimal)this.temp * 9 / 5 + 32);
else
throw new InvalidCastException(String.Format("Cannot convert from Temperature to {0}.",
conversionType.Name));
}
}
}
public class TemperatureFahrenheit : Temperature, IConvertible
{
public TemperatureFahrenheit(decimal value) : base(value)
{
}
// Override ToString methods.
public override string ToString()
{
return this.ToString(null);
}
public override string ToString(IFormatProvider provider)
{
return temp.ToString(provider) + "°F";
}
public override object ToType(Type conversionType, IFormatProvider provider)
{
// For non-objects, call base method.
if (Type.GetTypeCode(conversionType) != TypeCode.Object)
{
return base.ToType(conversionType, provider);
}
else
{
// Handle conversion between derived classes.
if (conversionType.Equals(typeof(TemperatureFahrenheit)))
return this;
else if (conversionType.Equals(typeof(TemperatureCelsius)))
return new TemperatureCelsius((decimal)(this.temp - 32) * 5 / 9);
// Unspecified object type: throw an InvalidCastException.
else
throw new InvalidCastException(String.Format("Cannot convert from Temperature to {0}.",
conversionType.Name));
}
}
}
Public MustInherit Class Temperature
Implements IConvertible
Protected temp As Decimal
Public Sub New(temperature As Decimal)
Me.temp = temperature
End Sub
Public Property Value As Decimal
Get
Return Me.temp
End Get
Set
Me.temp = Value
End Set
End Property
Public Overrides Function ToString() As String
Return temp.ToString() & "º"
End Function
' IConvertible implementations.
Public Function GetTypeCode() As TypeCode Implements IConvertible.GetTypeCode
Return TypeCode.Object
End Function
Public Function ToBoolean(provider As IFormatProvider) As Boolean Implements IConvertible.ToBoolean
Throw New InvalidCastException(String.Format("Temperature-to-Boolean conversion is not supported."))
End Function
Public Function ToByte(provider As IFormatProvider) As Byte Implements IConvertible.ToByte
If temp < Byte.MinValue Or temp > Byte.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the Byte data type.", temp))
Else
Return CByte(temp)
End If
End Function
Public Function ToChar(provider As IFormatProvider) As Char Implements IConvertible.ToChar
Throw New InvalidCastException("Temperature-to-Char conversion is not supported.")
End Function
Public Function ToDateTime(provider As IFormatProvider) As DateTime Implements IConvertible.ToDateTime
Throw New InvalidCastException("Temperature-to-DateTime conversion is not supported.")
End Function
Public Function ToDecimal(provider As IFormatProvider) As Decimal Implements IConvertible.ToDecimal
Return temp
End Function
Public Function ToDouble(provider As IFormatProvider) As Double Implements IConvertible.ToDouble
Return CDbl(temp)
End Function
Public Function ToInt16(provider As IFormatProvider) As Int16 Implements IConvertible.ToInt16
If temp < Int16.MinValue Or temp > Int16.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the Int16 data type.", temp))
End If
Return CShort(Math.Round(temp))
End Function
Public Function ToInt32(provider As IFormatProvider) As Int32 Implements IConvertible.ToInt32
If temp < Int32.MinValue Or temp > Int32.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the Int32 data type.", temp))
End If
Return CInt(Math.Round(temp))
End Function
Public Function ToInt64(provider As IFormatProvider) As Int64 Implements IConvertible.ToInt64
If temp < Int64.MinValue Or temp > Int64.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the Int64 data type.", temp))
End If
Return CLng(Math.Round(temp))
End Function
Public Function ToSByte(provider As IFormatProvider) As SByte Implements IConvertible.ToSByte
If temp < SByte.MinValue Or temp > SByte.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the SByte data type.", temp))
Else
Return CSByte(temp)
End If
End Function
Public Function ToSingle(provider As IFormatProvider) As Single Implements IConvertible.ToSingle
Return CSng(temp)
End Function
Public Overridable Overloads Function ToString(provider As IFormatProvider) As String Implements IConvertible.ToString
Return temp.ToString(provider) & " °C"
End Function
' If conversionType is a implemented by another IConvertible method, call it.
Public Overridable Function ToType(conversionType As Type, provider As IFormatProvider) As Object Implements IConvertible.ToType
Select Case Type.GetTypeCode(conversionType)
Case TypeCode.Boolean
Return Me.ToBoolean(provider)
Case TypeCode.Byte
Return Me.ToByte(provider)
Case TypeCode.Char
Return Me.ToChar(provider)
Case TypeCode.DateTime
Return Me.ToDateTime(provider)
Case TypeCode.Decimal
Return Me.ToDecimal(provider)
Case TypeCode.Double
Return Me.ToDouble(provider)
Case TypeCode.Empty
Throw New NullReferenceException("The target type is null.")
Case TypeCode.Int16
Return Me.ToInt16(provider)
Case TypeCode.Int32
Return Me.ToInt32(provider)
Case TypeCode.Int64
Return Me.ToInt64(provider)
Case TypeCode.Object
' Leave conversion of non-base types to derived classes.
Throw New InvalidCastException(String.Format("Cannot convert from Temperature to {0}.", _
conversionType.Name))
Case TypeCode.SByte
Return Me.ToSByte(provider)
Case TypeCode.Single
Return Me.ToSingle(provider)
Case TypeCode.String
Return Me.ToString(provider)
Case TypeCode.UInt16
Return Me.ToUInt16(provider)
Case TypeCode.UInt32
Return Me.ToUInt32(provider)
Case TypeCode.UInt64
Return Me.ToUInt64(provider)
Case Else
Throw New InvalidCastException("Conversion not supported.")
End Select
End Function
Public Function ToUInt16(provider As IFormatProvider) As UInt16 Implements IConvertible.ToUInt16
If temp < UInt16.MinValue Or temp > UInt16.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the UInt16 data type.", temp))
End If
Return CUShort(Math.Round(temp))
End Function
Public Function ToUInt32(provider As IFormatProvider) As UInt32 Implements IConvertible.ToUInt32
If temp < UInt32.MinValue Or temp > UInt32.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the UInt32 data type.", temp))
End If
Return CUInt(Math.Round(temp))
End Function
Public Function ToUInt64(provider As IFormatProvider) As UInt64 Implements IConvertible.ToUInt64
If temp < UInt64.MinValue Or temp > UInt64.MaxValue Then
Throw New OverflowException(String.Format("{0} is out of range of the UInt64 data type.", temp))
End If
Return CULng(Math.Round(temp))
End Function
End Class
Public Class TemperatureCelsius : Inherits Temperature : Implements IConvertible
Public Sub New(value As Decimal)
MyBase.New(value)
End Sub
' Override ToString methods.
Public Overrides Function ToString() As String
Return Me.ToString(Nothing)
End Function
Public Overrides Function ToString(provider As IFormatProvider) As String
Return temp.ToString(provider) + "°C"
End Function
' If conversionType is a implemented by another IConvertible method, call it.
Public Overrides Function ToType(conversionType As Type, provider As IFormatProvider) As Object
' For non-objects, call base method.
If Type.GetTypeCode(conversionType) <> TypeCode.Object Then
Return MyBase.ToType(conversionType, provider)
Else
If conversionType.Equals(GetType(TemperatureCelsius)) Then
Return Me
ElseIf conversionType.Equals(GetType(TemperatureFahrenheit))
Return New TemperatureFahrenheit(CDec(Me.temp * 9 / 5 + 32))
' Unspecified object type: throw an InvalidCastException.
Else
Throw New InvalidCastException(String.Format("Cannot convert from Temperature to {0}.", _
conversionType.Name))
End If
End If
End Function
End Class
Public Class TemperatureFahrenheit : Inherits Temperature : Implements IConvertible
Public Sub New(value As Decimal)
MyBase.New(value)
End Sub
' Override ToString methods.
Public Overrides Function ToString() As String
Return Me.ToString(Nothing)
End Function
Public Overrides Function ToString(provider As IFormatProvider) As String
Return temp.ToString(provider) + "°F"
End Function
Public Overrides Function ToType(conversionType As Type, provider As IFormatProvider) As Object
' For non-objects, call base method.
If Type.GetTypeCode(conversionType) <> TypeCode.Object Then
Return MyBase.ToType(conversionType, provider)
Else
' Handle conversion between derived classes.
If conversionType.Equals(GetType(TemperatureFahrenheit)) Then
Return Me
ElseIf conversionType.Equals(GetType(TemperatureCelsius))
Return New TemperatureCelsius(CDec((MyBase.temp - 32) * 5 / 9))
' Unspecified object type: throw an InvalidCastException.
Else
Throw New InvalidCastException(String.Format("Cannot convert from Temperature to {0}.", _
conversionType.Name))
End If
End If
End Function
End Class
The following example illustrates several calls to these IConvertible implementations to convert TemperatureCelsius
objects to TemperatureFahrenheit
objects and vice versa.
TemperatureCelsius tempC1 = new TemperatureCelsius(0);
TemperatureFahrenheit tempF1 = (TemperatureFahrenheit)Convert.ChangeType(tempC1, typeof(TemperatureFahrenheit), null);
Console.WriteLine("{0} equals {1}.", tempC1, tempF1);
TemperatureCelsius tempC2 = (TemperatureCelsius)Convert.ChangeType(tempC1, typeof(TemperatureCelsius), null);
Console.WriteLine("{0} equals {1}.", tempC1, tempC2);
TemperatureFahrenheit tempF2 = new TemperatureFahrenheit(212);
TemperatureCelsius tempC3 = (TemperatureCelsius)Convert.ChangeType(tempF2, typeof(TemperatureCelsius), null);
Console.WriteLine("{0} equals {1}.", tempF2, tempC3);
TemperatureFahrenheit tempF3 = (TemperatureFahrenheit)Convert.ChangeType(tempF2, typeof(TemperatureFahrenheit), null);
Console.WriteLine("{0} equals {1}.", tempF2, tempF3);
// The example displays the following output:
// 0°C equals 32°F.
// 0°C equals 0°C.
// 212°F equals 100°C.
// 212°F equals 212°F.
Dim tempC1 As New TemperatureCelsius(0)
Dim tempF1 As TemperatureFahrenheit = CType(Convert.ChangeType(tempC1, GetType(TemperatureFahrenheit), Nothing), TemperatureFahrenheit)
Console.WriteLine("{0} equals {1}.", tempC1, tempF1)
Dim tempC2 As TemperatureCelsius = CType(Convert.ChangeType(tempC1, GetType(TemperatureCelsius), Nothing), TemperatureCelsius)
Console.WriteLine("{0} equals {1}.", tempC1, tempC2)
Dim tempF2 As New TemperatureFahrenheit(212)
Dim tempC3 As TEmperatureCelsius = CType(Convert.ChangeType(tempF2, GEtType(TemperatureCelsius), Nothing), TemperatureCelsius)
Console.WriteLine("{0} equals {1}.", tempF2, tempC3)
Dim tempF3 As TemperatureFahrenheit = CType(Convert.ChangeType(tempF2, GetType(TemperatureFahrenheit), Nothing), TemperatureFahrenheit)
Console.WriteLine("{0} equals {1}.", tempF2, tempF3)
' The example displays the following output:
' 0°C equals 32°F.
' 0°C equals 0°C.
' 212°F equals 100°C.
' 212°F equals 212°F.
The TypeConverter class
.NET also allows you to define a type converter for a custom type by extending the System.ComponentModel.TypeConverter class and associating the type converter with the type through a System.ComponentModel.TypeConverterAttribute attribute. The following table highlights the differences between this approach and implementing the IConvertible interface for a custom type.
Note
Design-time support can be provided for a custom type only if it has a type converter defined for it.
Conversion using TypeConverter | Conversion using IConvertible |
---|---|
Is implemented for a custom type by deriving a separate class from TypeConverter. This derived class is associated with the custom type by applying a TypeConverterAttribute attribute. | Is implemented by a custom type to perform conversion. A user of the type invokes an IConvertible conversion method on the type. |
Can be used both at design time and at run time. | Can be used only at run time. |
Uses reflection; therefore, is slower than conversion enabled by IConvertible. | Does not use reflection. |
Allows two-way type conversions from the custom type to other data types, and from other data types to the custom type. For example, a TypeConverter defined for MyType allows conversions from MyType to String, and from String to MyType . |
Allows conversion from a custom type to other data types, but not from other data types to the custom type. |
For more information about using type converters to perform conversions, see System.ComponentModel.TypeConverter.