Integral numeric types (C# reference)
The integral numeric types represent integer numbers. All integral numeric types are value types. They're also simple types and can be initialized with literals. All integral numeric types support arithmetic, bitwise logical, comparison, and equality operators.
Characteristics of the integral types
C# supports the following predefined integral types:
C# type/keyword | Range | Size | .NET type |
---|---|---|---|
sbyte |
-128 to 127 | Signed 8-bit integer | System.SByte |
byte |
0 to 255 | Unsigned 8-bit integer | System.Byte |
short |
-32,768 to 32,767 | Signed 16-bit integer | System.Int16 |
ushort |
0 to 65,535 | Unsigned 16-bit integer | System.UInt16 |
int |
-2,147,483,648 to 2,147,483,647 | Signed 32-bit integer | System.Int32 |
uint |
0 to 4,294,967,295 | Unsigned 32-bit integer | System.UInt32 |
long |
-9,223,372,036,854,775,808 to 9,223,372,036,854,775,807 | Signed 64-bit integer | System.Int64 |
ulong |
0 to 18,446,744,073,709,551,615 | Unsigned 64-bit integer | System.UInt64 |
nint |
Depends on platform (computed at runtime) | Signed 32-bit or 64-bit integer | System.IntPtr |
nuint |
Depends on platform (computed at runtime) | Unsigned 32-bit or 64-bit integer | System.UIntPtr |
In all of the table rows except the last two, each C# type keyword from the leftmost column is an alias for the corresponding .NET type. The keyword and .NET type name are interchangeable. For example, the following declarations declare variables of the same type:
int a = 123;
System.Int32 b = 123;
The nint
and nuint
types in the last two rows of the table are native-sized integers. You can use the nint
and nuint
contextual keywords to define native-sized integers. These are 32-bit integers when running in a 32-bit process, or 64-bit integers when running in a 64-bit process. They can be used for interop scenarios, low-level libraries, and to optimize performance in scenarios where integer math is used extensively.
The native-sized integer types are represented internally as the .NET types System.IntPtr and System.UIntPtr. Starting in C# 11, the nint
and nuint
types are aliases for the underlying types.
The default value of each integral type is zero, 0
.
Each of the integral types has MinValue
and MaxValue
properties that provide the minimum and maximum value of that type. These properties are compile-time constants except for the case of the native-sized types (nint
and nuint
). The MinValue
and MaxValue
properties are calculated at runtime for native-sized types. The sizes of those types depend on the process settings.
Use the System.Numerics.BigInteger structure to represent a signed integer with no upper or lower bounds.
Integer literals
Integer literals can be
- decimal: without any prefix
- hexadecimal: with the
0x
or0X
prefix - binary: with the
0b
or0B
prefix
The following code demonstrates an example of each:
var decimalLiteral = 42;
var hexLiteral = 0x2A;
var binaryLiteral = 0b_0010_1010;
The preceding example also shows the use of _
as a digit separator. You can use the digit separator with all kinds of numeric literals.
The type of an integer literal is determined by its suffix as follows:
If the literal has no suffix, its type is the first of the following types in which its value can be represented:
int
,uint
,long
,ulong
.Note
Literals are interpreted as positive values. For example, the literal
0xFF_FF_FF_FF
represents the number4294967295
of theuint
type, though it has the same bit representation as the number-1
of theint
type. If you need a value of a certain type, cast a literal to that type. Use theunchecked
operator, if a literal value cannot be represented in the target type. For example,unchecked((int)0xFF_FF_FF_FF)
produces-1
.If the literal is suffixed by
U
oru
, its type is the first of the following types in which its value can be represented:uint
,ulong
.If the literal is suffixed by
L
orl
, its type is the first of the following types in which its value can be represented:long
,ulong
.Note
You can use the lowercase letter
l
as a suffix. However, this generates a compiler warning because the letterl
can be confused with the digit1
. UseL
for clarity.If the literal is suffixed by
UL
,Ul
,uL
,ul
,LU
,Lu
,lU
, orlu
, its type isulong
.
If the value represented by an integer literal exceeds UInt64.MaxValue, a compiler error CS1021 occurs.
If the determined type of an integer literal is int
and the value represented by the literal is within the range of the destination type, the value can be implicitly converted to sbyte
, byte
, short
, ushort
, uint
, ulong
, nint
or nuint
:
byte a = 17;
byte b = 300; // CS0031: Constant value '300' cannot be converted to a 'byte'
As the preceding example shows, if the literal's value isn't within the range of the destination type, a compiler error CS0031 occurs.
You can also use a cast to convert the value represented by an integer literal to the type other than the determined type of the literal:
var signedByte = (sbyte)42;
var longVariable = (long)42;
Conversions
You can convert any integral numeric type to any other integral numeric type. If the destination type can store all values of the source type, the conversion is implicit. Otherwise, you need to use a cast expression to perform an explicit conversion. For more information, see Built-in numeric conversions.
Native sized integers
Native sized integer types have special behavior because the storage is determined by the natural integer size on the target machine.
To get the size of a native-sized integer at run time, you can use
sizeof()
. However, the code must be compiled in an unsafe context. For example:Console.WriteLine($"size of nint = {sizeof(nint)}"); Console.WriteLine($"size of nuint = {sizeof(nuint)}"); // output when run in a 64-bit process //size of nint = 8 //size of nuint = 8 // output when run in a 32-bit process //size of nint = 4 //size of nuint = 4
You can also get the equivalent value from the static IntPtr.Size and UIntPtr.Size properties.
To get the minimum and maximum values of native-sized integers at run time, use
MinValue
andMaxValue
as static properties with thenint
andnuint
keywords, as in the following example:Console.WriteLine($"nint.MinValue = {nint.MinValue}"); Console.WriteLine($"nint.MaxValue = {nint.MaxValue}"); Console.WriteLine($"nuint.MinValue = {nuint.MinValue}"); Console.WriteLine($"nuint.MaxValue = {nuint.MaxValue}"); // output when run in a 64-bit process //nint.MinValue = -9223372036854775808 //nint.MaxValue = 9223372036854775807 //nuint.MinValue = 0 //nuint.MaxValue = 18446744073709551615 // output when run in a 32-bit process //nint.MinValue = -2147483648 //nint.MaxValue = 2147483647 //nuint.MinValue = 0 //nuint.MaxValue = 4294967295
You can use constant values in the following ranges:
- For
nint
: Int32.MinValue to Int32.MaxValue. - For
nuint
: UInt32.MinValue to UInt32.MaxValue.
- For
The compiler provides implicit and explicit conversions to other numeric types. For more information, see Built-in numeric conversions.
There's no direct syntax for native-sized integer literals. There's no suffix to indicate that a literal is a native-sized integer, such as
L
to indicate along
. You can use implicit or explicit casts of other integer values instead. For example:nint a = 42 nint a = (nint)42;
C# language specification
For more information, see the following sections of the C# language specification:
See also
Feedback
https://aka.ms/ContentUserFeedback.
Coming soon: Throughout 2024 we will be phasing out GitHub Issues as the feedback mechanism for content and replacing it with a new feedback system. For more information see:Submit and view feedback for