Conversions in Visual Basic
Conversion is the process of changing a value from one type to another. For example, a value of type Integer
can be converted to a value of type Double
, or a value of type Derived
can be converted to a value of type Base
, assuming that Base
and Derived
are both classes and Derived
inherits from Base
. Conversions may not require the value itself to change (as in the latter example), or they may require significant changes in the value representation (as in the former example).
Conversions may either be widening or narrowing. A widening conversion is a conversion from a type to another type whose value domain is at least as big, if not bigger, than the original type's value domain. Widening conversions should never fail. A narrowing conversion is a conversion from a type to another type whose value domain is either smaller than the original type's value domain or sufficiently unrelated that extra care must be taken when doing the conversion (for example, when converting from Integer
to String
). Narrowing conversions, which may entail loss of information, can fail.
The identity conversion (i.e. a conversion from a type to itself) and default value conversion (i.e. a conversion from Nothing
) are defined for all types.
Implicit and Explicit Conversions
Conversions can be either implicit or explicit. Implicit conversions occur without any special syntax. The following is an example of implicit conversion of an Integer
value to a Long
value:
Module Test
Sub Main()
Dim intValue As Integer = 123
Dim longValue As Long = intValue
Console.WriteLine(intValue & " = " & longValue)
End Sub
End Module
Explicit conversions, on the other hand, require cast operators. Attempting to do an explicit conversion on a value without a cast operator causes a compile-time error. The following example uses an explicit conversion to convert a Long
value to an Integer
value.
Module Test
Sub Main()
Dim longValue As Long = 134
Dim intValue As Integer = CInt(longValue)
Console.WriteLine(longValue & " = " & intValue)
End Sub
End Module
The set of implicit conversions depends on the compilation environment and the Option Strict
statement. If strict semantics are being used, only widening conversions may occur implicitly. If permissive semantics are being used, all widening and narrowing conversions (in other words, all conversions) may occur implicitly.
Boolean Conversions
Although Boolean
is not a numeric type, it does have narrowing conversions to and from the numeric types as if it were an enumerated type. The literal True
converts to the literal 255
for Byte
, 65535
for UShort
, 4294967295
for UInteger
, 18446744073709551615
for ULong
, and to the expression -1
for SByte
, Short
, Integer
, Long
, Decimal
, Single
, and Double
. The literal False
converts to the literal 0
. A zero numeric value converts to the literal False
. All other numeric values convert to the literal True
.
There is a narrowing conversion from Boolean to String, converting to either System.Boolean.TrueString
or System.Boolean.FalseString
. There is also a narrowing conversion from String
to Boolean
: if the string was equal to TrueString
or FalseString
(in the current culture, case-insensitively) then it uses the appropriate value; otherwise it attempts to parse the string as a numeric type (in hex or octal if possible, otherwise as a float) and uses the above rules; otherwise it throws System.InvalidCastException
.
Numeric Conversions
Numeric conversions exist between the types Byte
, SByte
, UShort
, Short
, UInteger
, Integer
, ULong
, Long
, Decimal
, Single
and Double
, and all enumerated types. When being converted, enumerated types are treated as if they were their underlying types. When converting to an enumerated type, the source value is not required to conform to the set of values defined in the enumerated type. For example:
Enum Values
One
Two
Three
End Enum
Module Test
Sub Main()
Dim x As Integer = 5
' OK, even though there is no enumerated value for 5.
Dim y As Values = CType(x, Values)
End Sub
End Module
Numeric conversions are processed at run-time as follows:
For a conversion from a numeric type to a wider numeric type, the value is simply converted to the wider type. Conversions from
UInteger
,Integer
,ULong
,Long
, orDecimal
toSingle
orDouble
are rounded to the nearestSingle
orDouble
value. While this conversion may cause a loss of precision, it will never cause a loss of magnitude.For a conversion from an integral type to another integral type, or from
Single
,Double
, orDecimal
to an integral type, the result depends on whether integer overflow checking is on:If integer overflow is being checked:
If the source is an integral type, the conversion succeeds if the source argument is within the range of the destination type. The conversion throws a
System.OverflowException
exception if the source argument is outside the range of the destination type.If the source is
Single
,Double
, orDecimal
, the source value is rounded up or down to the nearest integral value, and this integral value becomes the result of the conversion. If the source value is equally close to two integral values, the value is rounded to the value that has an even number in the least significant digit position. If the resulting integral value is outside the range of the destination type, aSystem.OverflowException
exception is thrown.
If integer overflow is not being checked:
If the source is an integral type, the conversion always succeeds and simply consists of discarding the most significant bits of the source value.
If the source is
Single
,Double
, orDecimal
, the conversion always succeeds and simply consists of rounding the source value towards the nearest integral value. If the source value is equally close to two integral values, the value is always rounded to the value that has an even number in the least significant digit position.
For a conversion from
Double
toSingle
, theDouble
value is rounded to the nearestSingle
value. If theDouble
value is too small to represent as aSingle
, the result becomes positive zero or negative zero. If theDouble
value is too large to represent as aSingle
, the result becomes positive infinity or negative infinity. If theDouble
value isNaN
, the result is alsoNaN
.For a conversion from
Single
orDouble
toDecimal
, the source value is converted toDecimal
representation and rounded to the nearest number after the 28th decimal place if required. If the source value is too small to represent as aDecimal
, the result becomes zero. If the source value isNaN
, infinity, or too large to represent as aDecimal
, aSystem.OverflowException
exception is thrown.For a conversion from
Double
toSingle
, theDouble
value is rounded to the nearestSingle
value. If theDouble
value is too small to represent as aSingle
, the result becomes positive zero or negative zero. If theDouble
value is too large to represent as aSingle
, the result becomes positive infinity or negative infinity. If theDouble
value isNaN
, the result is alsoNaN
.
Reference Conversions
Reference types may be converted to a base type, and vice versa. Conversions from a base type to a more derived type only succeed at run time if the value being converted is a null value, the derived type itself, or a more derived type.
Class and interface types can be cast to and from any interface type. Conversions between a type and an interface type only succeed at run time if the actual types involved have an inheritance or implementation relationship. Because an interface type will always contain an instance of a type that derives from Object
, an interface type can also always be cast to and from Object
.
Note. It is not an error to convert a NotInheritable
classes to and from interfaces that it does not implement because classes that represent COM classes may have interface implementations that are not known until run time.
If a reference conversion fails at run time, a System.InvalidCastException
exception is thrown.
Reference Variance Conversions
Generic interfaces or delegates may have variant type parameters that allow conversions between compatible variants of the type. Therefore, at runtime a conversion from a class type or an interface type to an interface type that is variant compatible with an interface type it inherits from or implements will succeed. Similarly, delegate types can be cast to and from variant compatible delegate types. For example, the delegate type
Delegate Function F(Of In A, Out R)(a As A) As R
would allow a conversion from F(Of Object, Integer)
to F(Of String, Integer)
. That is, a delegate F
which takes Object
may be safely used as a delegate F
which takes String
. When the delegate is invoked, the target method will be expecting an object, and a string is an object.
A generic delegate or interface type S(Of S1,...,Sn)
is said to be variant compatible with a generic interface or delegate type T(Of T1,...,Tn)
if:
S
andT
are both constructed from the same generic typeU(Of U1,...,Un)
.For each type parameter
Ux
:If the type parameter was declared without variance then
Sx
andTx
must be the same type.If the type parameter was declared
In
then there must be a widening identity, default, reference, array, or type parameter conversion fromSx
toTx
.If the type parameter was declared
Out
then there must be a widening identity, default, reference, array, or type parameter conversion fromTx
toSx
.
When converting from a class to a generic interface with variant type parameters, if the class implements more than one variant compatible interface the conversion is ambiguous if there is not a non-variant conversion. For example:
Class Base
End Class
Class Derived1
Inherits Base
End Class
Class Derived2
Inherits Base
End Class
Class OneAndTwo
Implements IEnumerable(Of Derived1)
Implements IEnumerable(Of Derived2)
End Class
Class BaseAndOneAndTwo
Implements IEnumerable(Of Base)
Implements IEnumerable(Of Derived1)
Implements IEnumerable(Of Derived2)
End Class
Module Test
Sub Main()
' Error: conversion is ambiguous
Dim x As IEnumerable(Of Base) = New OneAndTwo()
' OK, will pick up the direct implementation of IEnumerable(Of Base)
Dim y as IEnumerable(Of Base) = New BaseAndOneAndTwo()
End Sub
End Module
Anonymous Delegate Conversions
When an expression classified as a lambda method is reclassified as a value in a context where there is no target type (for example, Dim x = Function(a As Integer, b As Integer) a + b
), or where the target type is not a delegate type, the type of the resulting expression is an anonymous delegate type equivalent to the signature of the lambda method. This anonymous delegate type has a conversion to any compatible delegate type: a compatible delegate type is any delegate type that can be created using a delegate creation expression with the anonymous delegate type's Invoke
method as a parameter. For example:
' Anonymous delegate type similar to Func(Of Object, Object, Object)
Dim x = Function(x, y) x + y
' OK because delegate type is compatible
Dim y As Func(Of Integer, Integer, Integer) = x
Note that the types System.Delegate
and System.MulticastDelegate
are not themselves considered delegate types (even though all delegate types inherit from them). Also, note that the conversion from anonymous delegate type to a compatible delegate type is not a reference conversion.
Array Conversions
Besides the conversions that are defined on arrays by virtue of the fact that they are reference types, several special conversions exist for arrays.
For any two types A
and B
, if they are both reference types or type parameters not known to be value types, and if A
has a reference, array, or type parameter conversion to B
, a conversion exists from an array of type A
to an array of type B
with the same rank. This relationship is known as array covariance. Array covariance in particular means that an element of an array whose element type is B
may actually be an element of an array whose element type is A
, provided that both A
and B
are reference types and that B
has a reference conversion or array conversion to A
. In the following example, the second invocation of F
causes a System.ArrayTypeMismatchException
exception to be thrown because the actual element type of b
is String
, not Object
:
Module Test
Sub F(ByRef x As Object)
End Sub
Sub Main()
Dim a(10) As Object
Dim b() As Object = New String(10) {}
F(a(0)) ' OK.
F(b(1)) ' Not allowed: System.ArrayTypeMismatchException.
End Sub
End Module
Because of array covariance, assignments to elements of reference type arrays include a run-time check that ensures that the value being assigned to the array element is actually of a permitted type.
Module Test
Sub Fill(array() As Object, index As Integer, count As Integer, _
value As Object)
Dim i As Integer
For i = index To (index + count) - 1
array(i) = value
Next i
End Sub
Sub Main()
Dim strings(100) As String
Fill(strings, 0, 101, "Undefined")
Fill(strings, 0, 10, Nothing)
Fill(strings, 91, 10, 0)
End Sub
End Module
In this example, the assignment to array(i)
in method Fill
implicitly includes a run-time check that ensures that the object referenced by the variable value
is either Nothing
or an instance of a type that is compatible with the actual element type of array array
. In method Main
, the first two invocations of method Fill
succeed, but the third invocation causes a System.ArrayTypeMismatchException
exception to be thrown upon executing the first assignment to array(i)
. The exception occurs because an Integer
cannot be stored in a String
array.
If one of the array element types is a type parameter whose type turns out to be a value type at runtime, a System.InvalidCastException
exception will be thrown. For example:
Module Test
Sub F(Of T As U, U)(x() As T)
Dim y() As U = x
End Sub
Sub Main()
' F will throw an exception because Integer() cannot be
' converted to Object()
F(New Integer() { 1, 2, 3 })
End Sub
End Module
Conversions also exist between an array of an enumerated type and an array of the enumerated type's underlying type or an array of another enumerated type with the same underlying type, provided the arrays have the same rank.
Enum Color As Byte
Red
Green
Blue
End Enum
Module Test
Sub Main()
Dim a(10) As Color
Dim b() As Integer
Dim c() As Byte
b = a ' Error: Integer is not the underlying type of Color
c = a ' OK
a = c ' OK
End Sub
End Module
In this example, an array of Color
is converted to and from an array of Byte
, Color
's underlying type. The conversion to an array of Integer
, however, will be an error because Integer
is not the underlying type of Color
.
A rank-1 array of type A()
also has an array conversion to the collection interface types IList(Of B)
, IReadOnlyList(Of B)
, ICollection(Of B)
, IReadOnlyCollection(Of B)
and IEnumerable(Of B)
found in System.Collections.Generic
, so long as one of the following is true:
A
andB
are both reference types or type parameters not known to be value types; andA
has a widening reference, array or type parameter conversion toB
; orA
andB
are both enumerated types of the same underlying type; or- one of
A
andB
is an enumerated type, and the other is its underlying type.
Any array of type A with any rank also has an array conversion to the non-generic collection interface types IList
, ICollection
and IEnumerable
found in System.Collections
.
It is possible to iterate over the resulting interfaces using For Each
, or through invoking the GetEnumerator
methods directly. In the case of rank-1 arrays converted generic or non-generic forms of IList
or ICollection
, it is also possible to get elements by index. In the case of rank-1 arrays converted to generic or non-generic forms of IList
, it is also possible to set elements by index, subject to the same runtime array covariance checks as described above. The behavior of all other interface methods is undefined by the VB language specification; it is up to the underlying runtime.
Value Type Conversions
A value type value can be converted to one of its base reference types or an interface type that it implements through a process called boxing. When a value type value is boxed, the value is copied from the location where it lives onto the .NET Framework heap. A reference to this location on the heap is then returned and can be stored in a reference type variable. This reference is also referred to as a boxed instance of the value type. The boxed instance has the same semantics as a reference type instead of a value type.
Boxed value types can be converted back to their original value type through a process called unboxing. When a boxed value type is unboxed, the value is copied from the heap into a variable location. From that point on, it behaves as if it was a value type. When unboxing a value type, the value must be a null value or an instance of the value type. Otherwise a System.InvalidCastException
exception is thrown. If the value is an instance of an enumerated type, that value can also be unboxed to the enumerated type's underlying type or another enumerated type that has the same underlying type. A null value is treated as if it were the literal Nothing
.
To support nullable value types well, the value type System.Nullable(Of T)
is treated specially when doing boxing and unboxing. Boxing a value of type Nullable(Of T)
results in a boxed value of type T
if the value's HasValue
property is True
or a value of Nothing
if the value's HasValue
property is False
. Unboxing a value of type T
to Nullable(Of T)
results in an instance of Nullable(Of T)
whose Value
property is the boxed value and whose HasValue
property is True
. The value Nothing
can be unboxed to Nullable(Of T)
for any T
and results in a value whose HasValue
property is False
. Because boxed value types behave like reference types, it is possible to create multiple references to the same value. For the primitive types and enumerated types, this is irrelevant because instances of those types are immutable. That is, it is not possible to modify a boxed instance of those types, so it is not possible to observe the fact that there are multiple references to the same value.
Structures, on the other hand, may be mutable if its instance variables are accessible or if its methods or properties modify its instance variables. If one reference to a boxed structure is used to modify the structure, then all references to the boxed structure will see the change. Because this result may be unexpected, when a value typed as Object
is copied from one location to another boxed value types will automatically be cloned on the heap instead of merely having their references copied. For example:
Class Class1
Public Value As Integer = 0
End Class
Structure Struct1
Public Value As Integer
End Structure
Module Test
Sub Main()
Dim val1 As Object = New Struct1()
Dim val2 As Object = val1
val2.Value = 123
Dim ref1 As Object = New Class1()
Dim ref2 As Object = ref1
ref2.Value = 123
Console.WriteLine("Values: " & val1.Value & ", " & val2.Value)
Console.WriteLine("Refs: " & ref1.Value & ", " & ref2.Value)
End Sub
End Module
The output of the program is:
Values: 0, 123
Refs: 123, 123
The assignment to the field of the local variable val2
does not impact the field of the local variable val1
because when the boxed Struct1
was assigned to val2
, a copy of the value was made. In contrast, the assignment ref2.Value = 123
affects the object that both ref1
and ref2
references.
Note. Structure copying is not done for boxed structures typed as System.ValueType
because it is not possible to late bind off of System.ValueType
.
There is one exception to the rule that boxed value types will be copied on assignment. If a boxed value type reference is stored within another type, the inner reference will not be copied. For example:
Structure Struct1
Public Value As Object
End Structure
Module Test
Sub Main()
Dim val1 As Struct1
Dim val2 As Struct1
val1.Value = New Struct1()
val1.Value.Value = 10
val2 = val1
val2.Value.Value = 123
Console.WriteLine("Values: " & val1.Value.Value & ", " & _
val2.Value.Value)
End Sub
End Module
The output of the program is:
Values: 123, 123
This is because the inner boxed value is not copied when the value is copied. Thus, both val1.Value
and val2.Value
have a reference to the same boxed value type.
Note. The fact that inner boxed value types are not copied is a limitation of the .NET type system -- to ensure that all inner boxed value types were copied whenever a value of type Object
was copied would be prohibitively expensive.
As previously described, boxed value types can only be unboxed to their original type. Boxed primitive types, however, are treated specially when typed as Object
. They can be converted to any other primitive type that they have a conversion to. For example:
Module Test
Sub Main()
Dim o As Object = 5
Dim b As Byte = CByte(o) ' Legal
Console.WriteLine(b) ' Prints 5
End Sub
End Module
Normally, the boxed Integer
value 5
could not be unboxed into a Byte
variable. However, because Integer
and Byte
are primitive types and have a conversion, the conversion is allowed.
It is important to note that converting a value type to an interface is different than a generic argument constrained to an interface. When accessing interface members on a constrained type parameter (or calling methods on Object
), boxing does not occur as it does when a value type is converted to an interface and an interface member is accessed. For example, suppose an interface ICounter
contains a method Increment
which can be used to modify a value. If ICounter
is used as a constraint, the implementation of the Increment
method is called with a reference to the variable that Increment
was called on, not a boxed copy:
Interface ICounter
Sub Increment()
ReadOnly Property Value() As Integer
End Interface
Structure Counter
Implements ICounter
Dim _value As Integer
Property Value() As Integer Implements ICounter.Value
Get
Return _value
End Get
End Property
Sub Increment() Implements ICounter.Increment
value += 1
End Sub
End Structure
Module Test
Sub Test(Of T As ICounter)(x As T)
Console.WriteLine(x.value)
x.Increment() ' Modify x
Console.WriteLine(x.value)
CType(x, ICounter).Increment() ' Modify boxed copy of x
Console.WriteLine(x.value)
End Sub
Sub Main()
Dim x As Counter
Test(x)
End Sub
End Module
The first call to Increment
modifies the value in the variable x
. This is not equivalent to the second call to Increment
, which modifies the value in a boxed copy of x
. Thus, the output of the program is:
0
1
1
Nullable Value Type Conversions
A value type T
can convert to and from the nullable version of the type, T?
. The conversion from T?
to T
throws a System.InvalidOperationException
exception if the value being converted is Nothing
. Also, T?
has a conversion to a type S
if T
has an intrinsic conversion to S
. And if S
is a value type, then the following intrinsic conversions exist between T?
and S?
:
A conversion of the same classification (narrowing or widening) from
T?
toS?
.A conversion of the same classification (narrowing or widening) from
T
toS?
.A narrowing conversion from
S?
toT
.
For example, an intrinsic widening conversion exists from Integer?
to Long?
because an intrinsic widening conversion exists from Integer
to Long
:
Dim i As Integer? = 10
Dim l As Long? = i
When converting from T?
to S?
, if the value of T?
is Nothing
, then the value of S?
will be Nothing
. When converting from S?
to T
or T?
to S
, if the value of T?
or S?
is Nothing
, a System.InvalidCastException
exception will be thrown.
Because of the behavior of the underlying type System.Nullable(Of T)
, when a nullable value type T?
is boxed, the result is a boxed value of type T
, not a boxed value of type T?
. And, conversely, when unboxing to a nullable value type T?
, the value will be wrapped by System.Nullable(Of T)
, and Nothing
will be unboxed to a null value of type T?
. For example:
Dim i1? As Integer = Nothing
Dim o1 As Object = i1
Console.WriteLine(o1 Is Nothing) ' Will print True
o1 = 10
i1 = CType(o1, Integer?)
Console.WriteLine(i1) ' Will print 10
A side effect of this behavior is that a nullable value type T?
appears to implement all of the interfaces of T
, because converting a value type to an interface requires the type to be boxed. As a result, T?
is convertible to all the interfaces that T
is convertible to. It is important to note, however, that a nullable value type T?
does not actually implement the interfaces of T
for the purposes of generic constraint checking or reflection. For example:
Interface I1
End Interface
Structure T1
Implements I1
...
End Structure
Module Test
Sub M1(Of T As I1)(ByVal x As T)
End Sub
Sub Main()
Dim x? As T1 = Nothing
Dim y As I1 = x ' Valid
M1(x) ' Error: x? does not satisfy I1 constraint
End Sub
End Module
String Conversions
Converting Char
into String
results in a string whose first character is the character value. Converting String
into Char
results in a character whose value is the first character of the string. Converting an array of Char
into String
results in a string whose characters are the elements of the array. Converting String
into an array of Char
results in an array of characters whose elements are the characters of the string.
The exact conversions between String
and Boolean
, Byte
, SByte
, UShort
, Short
, UInteger
, Integer
, ULong
, Long
, Decimal
, Single
, Double
, Date
, and vice versa, are beyond the scope of this specification and are implementation dependent with the exception of one detail. String conversions always consider the current culture of the run-time environment. As such, they must be performed at run time.
Widening Conversions
Widening conversions never overflow but may entail a loss of precision. The following conversions are widening conversions:
Identity/Default conversions
From a type to itself.
From an anonymous delegate type generated for a lambda method reclassification to any delegate type with an identical signature.
From the literal
Nothing
to a type.
Numeric conversions
From
Byte
toUShort
,Short
,UInteger
,Integer
,ULong
,Long
,Decimal
,Single
, orDouble
.From
SByte
toShort
,Integer
,Long
,Decimal
,Single
, orDouble
.From
UShort
toUInteger
,Integer
,ULong
,Long
,Decimal
,Single
, orDouble
.From
Short
toInteger
,Long
,Decimal
,Single
orDouble
.From
UInteger
toULong
,Long
,Decimal
,Single
, orDouble
.From
Integer
toLong
,Decimal
,Single
orDouble
.From
ULong
toDecimal
,Single
, orDouble
.From
Long
toDecimal
,Single
orDouble
.From
Decimal
toSingle
orDouble
.From
Single
toDouble
.From the literal
0
to an enumerated type. (Note. The conversion from0
to any enumerated type is widening to simplify testing flags. For example, ifValues
is an enumerated type with a valueOne
, you could test a variablev
of typeValues
by saying(v And Values.One) = 0
.)From an enumerated type to its underlying numeric type, or to a numeric type that its underlying numeric type has a widening conversion to.
From a constant expression of type
ULong
,Long
,UInteger
,Integer
,UShort
,Short
,Byte
, orSByte
to a narrower type, provided the value of the constant expression is within the range of the destination type. (Note. Conversions fromUInteger
orInteger
toSingle
,ULong
orLong
toSingle
orDouble
, orDecimal
toSingle
orDouble
may cause a loss of precision, but will never cause a loss of magnitude. The other widening numeric conversions never lose any information.)
Reference conversions
From a reference type to a base type.
From a reference type to an interface type, provided that the type implements the interface or a variant compatible interface.
From an interface type to
Object
.From an interface type to a variant compatible interface type.
From a delegate type to a variant compatible delegate type. (Note. Many other reference conversions are implied by these rules. For example, anonymous delegates are reference types that inherit from
System.MulticastDelegate
; array types are reference types that inherit fromSystem.Array
; anonymous types are reference types that inherit fromSystem.Object
.)
Anonymous Delegate conversions
- From an anonymous delegate type generated for a lambda method reclassification to any wider delegate type.
Array conversions
From an array type
S
with an element typeSe
to an array typeT
with an element typeTe
, provided all of the following are true:S
andT
differ only in element type.Both
Se
andTe
are reference types or are type parameters known to be a reference type.A widening reference, array, or type parameter conversion exists from
Se
toTe
.
From an array type
S
with an enumerated element typeSe
to an array typeT
with an element typeTe
, provided all of the following are true:S
andT
differ only in element type.Te
is the underlying type ofSe
.
From an array type
S
of rank 1 with an enumerated element typeSe
, toSystem.Collections.Generic.IList(Of Te)
,IReadOnlyList(Of Te)
,ICollection(Of Te)
,IReadOnlyCollection(Of Te)
, andIEnumerable(Of Te)
, provided one of the following is true:Both
Se
andTe
are reference types or are type parameters known to be a reference type, and a widening reference, array, or type parameter conversion exists fromSe
toTe
; orTe
is the underlying type ofSe
; orTe
is identical toSe
Value Type conversions
From a value type to a base type.
From a value type to an interface type that the type implements.
Nullable Value Type conversions
From a type
T
to the typeT?
.From a type
T?
to a typeS?
, where there is a widening conversion from the typeT
to the typeS
.From a type
T
to a typeS?
, where there is a widening conversion from the typeT
to the typeS
.From a type
T?
to an interface type that the typeT
implements.
String conversions
From
Char
toString
.From
Char()
toString
.
Type Parameter conversions
From a type parameter to
Object
.From a type parameter to an interface type constraint or any interface variant compatible with an interface type constraint.
From a type parameter to an interface implemented by a class constraint.
From a type parameter to an interface variant compatible with an interface implemented by a class constraint.
From a type parameter to a class constraint, or a base type of the class constraint.
From a type parameter
T
to a type parameter constraintTx
, or anythingTx
has a widening conversion to.
Narrowing Conversions
Narrowing conversions are conversions that cannot be proved to always succeed, conversions that are known to possibly lose information, and conversions across domains of types sufficiently different to merit narrowing notation. The following conversions are classified as narrowing conversions:
Boolean conversions
From
Boolean
toByte
,SByte
,UShort
,Short
,UInteger
,Integer
,ULong
,Long
,Decimal
,Single
, orDouble
.From
Byte
,SByte
,UShort
,Short
,UInteger
,Integer
,ULong
,Long
,Decimal
,Single
, orDouble
toBoolean
.
Numeric conversions
From
Byte
toSByte
.From
SByte
toByte
,UShort
,UInteger
, orULong
.From
UShort
toByte
,SByte
, orShort
.From
Short
toByte
,SByte
,UShort
,UInteger
, orULong
.From
UInteger
toByte
,SByte
,UShort
,Short
, orInteger
.From
Integer
toByte
,SByte
,UShort
,Short
,UInteger
, orULong
.From
ULong
toByte
,SByte
,UShort
,Short
,UInteger
,Integer
, orLong
.From
Long
toByte
,SByte
,UShort
,Short
,UInteger
,Integer
, orULong
.From
Decimal
toByte
,SByte
,UShort
,Short
,UInteger
,Integer
,ULong
, orLong
.From
Single
toByte
,SByte
,UShort
,Short
,UInteger
,Integer
,ULong
,Long
, orDecimal
.From
Double
toByte
,SByte
,UShort
,Short
,UInteger
,Integer
,ULong
,Long
,Decimal
, orSingle
.From a numeric type to an enumerated type.
From an enumerated type to a numeric type its underlying numeric type has a narrowing conversion to.
From an enumerated type to another enumerated type.
Reference conversions
From a reference type to a more derived type.
From a class type to an interface type, provided the class type does not implement the interface type or an interface type variant compatible with it.
From an interface type to a class type.
From an interface type to another interface type, provided there is no inheritance relationship between the two types and provided they are not variant compatible.
Anonymous Delegate conversions
- From an anonymous delegate type generated for a lambda method reclassification to any narrower delegate type.
Array conversions
From an array type
S
with an element typeSe
, to an array typeT
with an element typeTe
, provided that all of the following are true:S
andT
differ only in element type.- Both
Se
andTe
are reference types or are type parameters not known to be value types. - A narrowing reference, array, or type parameter conversion exists from
Se
toTe
.
From an array type
S
with an element typeSe
to an array typeT
with an enumerated element typeTe
, provided all of the following are true:S
andT
differ only in element type.Se
is the underlying type ofTe
, or they are both different enumerated types that share the same underlying type.
From an array type
S
of rank 1 with an enumerated element typeSe
, toIList(Of Te)
,IReadOnlyList(Of Te)
,ICollection(Of Te)
,IReadOnlyCollection(Of Te)
andIEnumerable(Of Te)
, provided one of the following is true:- Both
Se
andTe
are reference types or are type parameters known to be a reference type, and a narrowing reference, array, or type parameter conversion exists fromSe
toTe
; or Se
is the underlying type ofTe
, or they are both different enumerated types that share the same underlying type.
- Both
Value type conversions
From a reference type to a more derived value type.
From an interface type to a value type, provided the value type implements the interface type.
Nullable Value Type conversions
From a type
T?
to a typeT
.From a type
T?
to a typeS?
, where there is a narrowing conversion from the typeT
to the typeS
.From a type
T
to a typeS?
, where there is a narrowing conversion from the typeT
to the typeS
.From a type
S?
to a typeT
, where there is a conversion from the typeS
to the typeT
.
String conversions
From
String
toChar
.From
String
toChar()
.From
String
toBoolean
and fromBoolean
toString
.Conversions between
String
andByte
,SByte
,UShort
,Short
,UInteger
,Integer
,ULong
,Long
,Decimal
,Single
, orDouble
.From
String
toDate
and fromDate
toString
.
Type Parameter conversions
From
Object
to a type parameter.From a type parameter to an interface type, provided the type parameter is not constrained to that interface or constrained to a class that implements that interface.
From an interface type to a type parameter.
From a type parameter to a derived type of a class constraint.
From a type parameter
T
to anything a type parameter constraintTx
has a narrowing conversion to.
Type Parameter Conversions
Type parameters' conversions are determined by the constraints, if any, put on them. A type parameter T
can always be converted to itself, to and from Object
, and to and from any interface type. Note that if the type T
is a value type at run-time, converting from T
to Object
or an interface type will be a boxing conversion and converting from Object
or an interface type to T
will be an unboxing conversion. A type parameter with a class constraint C
defines additional conversions from the type parameter to C
and its base classes, and vice versa. A type parameter T
with a type parameter constraint Tx
defines a conversion to Tx
and anything Tx
converts to.
An array whose element type is a type parameter with an interface constraint I
has the same covariant array conversions as an array whose element type is I
, provided that the type parameter also has a Class
or class constraint (since only reference array element types can be covariant). An array whose element type is a type parameter with a class constraint C
has the same covariant array conversions as an array whose element type is C
.
The above conversions rules do not permit conversions from unconstrained type parameters to non-interface types, which may be surprising. The reason for this is to prevent confusion about the semantics of such conversions. For example, consider the following declaration:
Class X(Of T)
Public Shared Function F(t As T) As Long
Return CLng(t) ' Error, explicit conversion not permitted
End Function
End Class
If the conversion of T
to Integer
were permitted, one might easily expect that X(Of Integer).F(7)
would return 7L
. However, it would not, because numeric conversions are only considered when the types are known to be numeric at compile time. In order to make the semantics clear, the above example must instead be written:
Class X(Of T)
Public Shared Function F(t As T) As Long
Return CLng(CObj(t)) ' OK, conversions permitted
End Function
End Class
User-Defined Conversions
Intrinsic conversions are conversions defined by the language (i.e. listed in this specification), while user-defined conversions are defined by overloading the CType
operator. When converting between types, if no intrinsic conversions are applicable then user-defined conversions will be considered. If there is a user-defined conversion that is most specific for the source and target types, then the user-defined conversion will be used. Otherwise, a compile-time error results. The most specific conversion is the one whose operand is "closest" to the source type and whose result type is "closest" to the target type. When determining what user-defined conversion to use, the most specific widening conversion will be used; if no widening conversion is most specific, the most specific narrowing conversion will be used. If there is no most specific narrowing conversion, then the conversion is undefined and a compile-time error occurs.
The following sections cover how the most specific conversions are determined. They use the following terms:
If an intrinsic widening conversion exists from a type A
to a type B
, and if neither A
nor B
are interfaces, then A
is encompassed by B
, and B
encompasses A
.
The most encompassing type in a set of types is the one type that encompasses all other types in the set. If no single type encompasses all other types, then the set has no most encompassing type. In intuitive terms, the most encompassing type is the "largest" type in the set -- the one type to which each of the other types can be converted through a widening conversion.
The most encompassed type in a set of types is the one type that is encompassed by all other types in the set. If no single type is encompassed by all other types, then the set has no most encompassed type. In intuitive terms, the most encompassed type is the "smallest" type in the set -- the one type that can be converted to each of the other types through a narrowing conversion.
When collecting the candidate user-defined conversions for a type T?
, the user-defined conversion operators defined by T
are used instead. If the type being converted to is also a nullable value type, then any of T
's user-defined conversions operators that involve only non-nullable value types are lifted. A conversion operator from T
to S
is lifted to be a conversion from T?
to S?
and is evaluated by converting T?
to T
, if necessary, then evaluating the user-defined conversion operator from T
to S
and then converting S
to S?
, if necessary. If the value being converted is Nothing
, however, a lifted conversion operator converts directly into a value of Nothing
typed as S?
. For example:
Structure S
...
End Structure
Structure T
Public Shared Widening Operator CType(ByVal v As T) As S
...
End Operator
End Structure
Module Test
Sub Main()
Dim x As T?
Dim y As S?
y = x ' Legal: y is still null
x = New T()
y = x ' Legal: Converts from T to S
End Sub
End Module
When resolving conversions, user-defined conversions operators are always preferred over lifted conversion operators. For example:
Structure S
...
End Structure
Structure T
Public Shared Widening Operator CType(ByVal v As T) As S
...
End Operator
Public Shared Widening Operator CType(ByVal v As T?) As S?
...
End Operator
End Structure
Module Test
Sub Main()
Dim x As T?
Dim y As S?
y = x ' Calls user-defined conversion, not lifted conversion
End Sub
End Module
At run-time, evaluating a user-defined conversion can involve up to three steps:
First, the value is converted from the source type to the operand type using an intrinsic conversion, if necessary.
Then, the user-defined conversion is invoked.
Finally, the result of the user-defined conversion is converted to the target type using an intrinsic conversion, if necessary.
It is important to note that evaluation of a user-defined conversion will never involve more than one user-defined conversion operator.
Most Specific Widening Conversion
Determining the most specific user-defined widening conversion operator between two types is accomplished using the following steps:
First, all of the candidate conversion operators are collected. The candidate conversion operators are all of the user-defined widening conversion operators in the source type and all of the user-defined widening conversion operators in the target type.
Then, all non-applicable conversion operators are removed from the set. A conversion operator is applicable to a source type and target type if there is an intrinsic widening conversion operator from the source type to the operand type and there is an intrinsic widening conversion operator from the result of the operator to the target type. If there are no applicable conversion operators, then there is no most specific widening conversion.
Then, the most specific source type of the applicable conversion operators is determined:
If any of the conversion operators convert directly from the source type, then the source type is the most specific source type.
Otherwise, the most specific source type is the most encompassed type in the combined set of source types of the conversion operators. If no most encompassed type can be found, then there is no most specific widening conversion.
Then, the most specific target type of the applicable conversion operators is determined:
If any of the conversion operators convert directly to the target type, then the target type is the most specific target type.
Otherwise, the most specific target type is the most encompassing type in the combined set of target types of the conversion operators. If no most encompassing type can be found, then there is no most specific widening conversion.
Then, if exactly one conversion operator converts from the most specific source type to the most specific target type, then this is the most specific conversion operator. If more than one such operator exists, then there is no most specific widening conversion.
Most Specific Narrowing Conversion
Determining the most specific user-defined narrowing conversion operator between two types is accomplished using the following steps:
First, all of the candidate conversion operators are collected. The candidate conversion operators are all of the user-defined conversion operators in the source type and all of the user-defined conversion operators in the target type.
Then, all non-applicable conversion operators are removed from the set. A conversion operator is applicable to a source type and target type if there is an intrinsic conversion operator from the source type to the operand type and there is an intrinsic conversion operator from the result of the operator to the target type. If there are no applicable conversion operators, then there is no most specific narrowing conversion.
Then, the most specific source type of the applicable conversion operators is determined:
If any of the conversion operators convert directly from the source type, then the source type is the most specific source type.
Otherwise, if any of the conversion operators convert from types that encompass the source type, then the most specific source type is the most encompassed type in the combined set of source types of those conversion operators. If no most encompassed type can be found, then there is no most specific narrowing conversion.
Otherwise, the most specific source type is the most encompassing type in the combined set of source types of the conversion operators. If no most encompassing type can be found, then there is no most specific narrowing conversion.
Then, the most specific target type of the applicable conversion operators is determined:
If any of the conversion operators convert directly to the target type, then the target type is the most specific target type.
Otherwise, if any of the conversion operators convert to types that are encompassed by the target type, then the most specific target type is the most encompassing type in the combined set of source types of those conversion operators. If no most encompassing type can be found, then there is no most specific narrowing conversion.
Otherwise, the most specific target type is the most encompassed type in the combined set of target types of the conversion operators. If no most encompassed type can be found, then there is no most specific narrowing conversion.
Then, if exactly one conversion operator converts from the most specific source type to the most specific target type, then this is the most specific conversion operator. If more than one such operator exists, then there is no most specific narrowing conversion.
Native Conversions
Several of the conversions are classified as native conversions because they are supported natively by the .NET Framework. These conversions are ones that can be optimized through the use of the DirectCast
and TryCast
conversion operators, as well as other special behaviors. The conversions classified as native conversions are: identity conversions, default conversions, reference conversions, array conversions, value type conversions, and type parameter conversions.
Dominant Type
Given a set of types, it is often necessary in situations such as type inference to determine the dominant type of the set. The dominant type of a set of types is determined by first removing any types that one or more other types do not have an implicit conversion to. If there are no types left at this point, there is no dominant type. The dominant type is then the most encompassed of the remaining types. If there is more than one type that is most encompassed, then there is no dominant type.
Visual Basic language spec