Double.Equals 方法
定义
重要
一些信息与预发行产品相关,相应产品在发行之前可能会进行重大修改。 对于此处提供的信息,Microsoft 不作任何明示或暗示的担保。
返回一个值,该值指示两个 Double 表示相同值的实例。
重载
| 名称 | 说明 |
|---|---|
| Equals(Double) |
返回一个值,该值指示此实例和指定的 Double 对象是否表示相同的值。 |
| Equals(Object) |
返回一个值,该值指示此实例是否等于指定的对象。 |
Equals(Double)
- Source:
- Double.cs
- Source:
- Double.cs
- Source:
- Double.cs
- Source:
- Double.cs
- Source:
- Double.cs
返回一个值,该值指示此实例和指定的 Double 对象是否表示相同的值。
public:
virtual bool Equals(double obj);public bool Equals(double obj);override this.Equals : double -> boolPublic Function Equals (obj As Double) As Boolean参数
返回
true 如果 obj 等于此实例,则为 ;否则为 false。
实现
注解
该方法 Double.Equals(Double) 实现 System.IEquatable<T> 接口,并且性能略好于 Double.Equals(Object) 因为它不必将 obj 参数转换为对象。
扩大转换
根据编程语言的不同,可能编码一个Equals方法,其中参数类型的比特数少于实例类型(即较窄)。 这是可能的,因为一些编程语言执行隐式扩大转换,该转换将参数表示为一个类型,其位数与实例数相同。
例如,假设实例类型为 Double ,参数类型为 Int32. Microsoft C# 编译器生成将参数值表示为 Double 对象的指令,然后生成一个 Double.Equals(Double) 方法,该方法比较实例的值和参数的扩大表示形式。
请参阅编程语言的文档,以确定其编译器是否执行数字类型的隐式扩展转换。 有关详细信息,请参阅 类型转换表 主题。
比较中的精度
Equals应谨慎使用该方法,因为两个明显等效的值可能由于两个值的精度不同而不相等。 以下示例表明Double值.333333与Double通过1除以3返回的值不相等。
// Initialize two doubles with apparently identical values
double double1 = .33333;
double double2 = (double) 1/3;
// Compare them for equality
Console.WriteLine(double1.Equals(double2)); // displays false
// Initialize two doubles with apparently identical values
let double1 = 0.33333
let double2 = double (1 / 3)
// Compare them for equality
printfn $"{double1.Equals double2}" // displays false
' Initialize two doubles with apparently identical values
Dim double1 As Double = .33333
Dim double2 As Double = 1/3
' Compare them for equality
Console.WriteLine(double1.Equals(double2)) ' displays False
另一种技术不是简单比较是否相等,而是定义两个值之间的可接受相对误差范围(例如,其中一个值的 0.001%)。 如果两个值的绝对值小于或等于该边距,则差异可能是由于精度差异,因此,这些值可能相等。 下面的示例使用此方法比较 .33333 和 1/3,前一个代码示例发现两 Double 个值不相等。 在这种情况下,这些值相等。
// Initialize two doubles with apparently identical values
double double1 = .333333;
double double2 = (double) 1/3;
// Define the tolerance for variation in their values
double difference = Math.Abs(double1 * .00001);
// Compare the values
// The output to the console indicates that the two values are equal
if (Math.Abs(double1 - double2) <= difference)
Console.WriteLine("double1 and double2 are equal.");
else
Console.WriteLine("double1 and double2 are unequal.");
// Initialize two doubles with apparently identical values
let double1 = 0.333333
let double2 = double (1 / 3)
// Define the tolerance for variation in their values
let difference = abs (double1 * 0.00001)
// Compare the values
// The output to the console indicates that the two values are equal
if abs (double1 - double2) <= difference then
printfn "double1 and double2 are equal."
else
printfn "double1 and double2 are unequal."
' Initialize two doubles with apparently identical values
Dim double1 As Double = .33333
Dim double2 As Double = 1/3
' Define the tolerance for variation in their values
Dim difference As Double = Math.Abs(double1 * .00001)
' Compare the values
' The output to the console indicates that the two values are equal
If Math.Abs(double1 - double2) <= difference Then
Console.WriteLine("double1 and double2 are equal.")
Else
Console.WriteLine("double1 and double2 are unequal.")
End If
注释
由于 Epsilon 定义其范围接近零的正值的最小表达式,因此两个相似值之间的差差必须大于 Epsilon。 通常,它比 Epsilon 大很多倍。 因此,建议在比较的值是否相等时,Epsilon使用Double。
第二种方法涉及比较两个浮点数与一些绝对值之间的差异。 如果差值小于或等于该绝对值,则数字相等。 如果它更大,则数字不相等。 一种替代方法是任意选择绝对值。 但是,这是有问题的,因为可接受的差异边距取决于值的大小 Double 。 另一种替代方法利用浮点格式的设计功能:两个浮点值的整数表示形式之间的差异表示可能分隔它们的浮点值数。 例如,0.0 和 Epsilon 之间的差异是 1,因为 Epsilon 是在处理 Double 值为零时可表示的最小值。 下面的示例使用此技术比较 .33333 和 1/3,这两个值是上一个 Double 代码示例发现不相等的 Equals(Double) 值。 该示例使用 BitConverter.DoubleToInt64Bits 该方法将双精度浮点值转换为其整数表示形式。 如果整数表示形式之间没有可能的浮点值,该示例将值声明为相等。
public static void Main()
{
// Initialize the values.
double value1 = .1 * 10;
double value2 = 0;
for (int ctr = 0; ctr < 10; ctr++)
value2 += .1;
Console.WriteLine($"{value1:R} = {value2:R}: " +
$"{HasMinimalDifference(value1, value2, 1)}");
}
public static bool HasMinimalDifference(
double value1,
double value2,
int allowableDifference
)
{
// Convert the double values to long values.
long lValue1 = BitConverter.DoubleToInt64Bits(value1);
long lValue2 = BitConverter.DoubleToInt64Bits(value2);
// If the signs are different, return false except for +0 and -0.
if ((lValue1 >> 63) != (lValue2 >> 63))
{
if (value1 == value2)
return true;
return false;
}
// Calculate the number of possible
// floating-point values in the difference.
long diff = Math.Abs(lValue1 - lValue2);
if (diff <= allowableDifference)
return true;
return false;
}
// The example displays the following output:
//
// 1 = 0.99999999999999989: True
open System
let hasMinimalDifference (value1: double) (value2: double) (units: int) =
let lValue1 = BitConverter.DoubleToInt64Bits value1
let lValue2 = BitConverter.DoubleToInt64Bits value2
// If the signs are different, return false except for +0 and -0.
if (lValue1 >>> 63) <> (lValue2 >>> 63) then
value1 = value2
else
let diff = abs (lValue1 - lValue2)
diff <= int64 units
let value1 = 0.1 * 10.
let mutable value2 = 0.
for _ = 0 to 9 do
value2 <- value2 + 0.1
printfn $"{value1:R} = {value2:R}: {hasMinimalDifference value1 value2 1}"
// The example displays the following output:
// 1 = 0.99999999999999989: True
Module Example1
Public Sub Main()
Dim value1 As Double = .1 * 10
Dim value2 As Double = 0
For ctr As Integer = 0 To 9
value2 += .1
Next
Console.WriteLine("{0:R} = {1:R}: {2}", value1, value2,
HasMinimalDifference(value1, value2, 1))
End Sub
Public Function HasMinimalDifference(value1 As Double, value2 As Double, units As Integer) As Boolean
Dim lValue1 As long = BitConverter.DoubleToInt64Bits(value1)
Dim lValue2 As long = BitConverter.DoubleToInt64Bits(value2)
' If the signs are different, Return False except for +0 and -0.
If ((lValue1 >> 63) <> (lValue2 >> 63)) Then
If value1 = value2 Then
Return True
End If
Return False
End If
Dim diff As Long = Math.Abs(lValue1 - lValue2)
If diff <= units Then
Return True
End If
Return False
End Function
End Module
' The example displays the following output:
' 1 = 0.99999999999999989: True
注释
对于某些值,即使整数表示形式之间存在可能的浮点值,也可以将其视为相等。 例如,考虑双精度浮点值 0.39 和 1.69 - 1.3 (其计算结果为 0.3899999999999999)。 在小端计算机上,这些值的整数表示形式分别为 4600697235336603894 和 4600697235336603892。 整数值之间的差异是2,这意味着在和0.39之间可能存在一个浮点值。
版本差异
超出文档记录精度的浮点数的精度依赖于 .NET 的实现和版本。 因此,两个特定数字的比较可能会在 .NET 的版本之间发生更改,因为数字的内部表示形式的精度可能会更改。
NAN
如果通过调用Double.NaN该方法测试两Equals个值是否相等,该方法将true返回。 但是,如果通过相等运算符来测试两个Double.NaN值是否相等,那么该运算符将返回。 如果要确定 a Double 的值是否不是数字(NaN),另一种方法是调用 IsNaN 该方法。
调用方说明
编译器重载解析可能会导致两 Equals(Object) 个方法重载的行为明显差异。 如果定义自变量和 a obj 之间的Double隐式转换,并且参数未键入为类型Object,编译器可能会执行隐式转换并调用Equals(Double)该方法。 否则,它们将调用Equals(Object)该方法,如果该方法的参数不是false值,则始终返回obj该方法Double。 下面的示例说明了两个方法重载的行为差异。 对于除 C# 以外的 Decimal 所有基元数值类型,第一个比较返回是因为 true 编译器会自动执行扩大转换并调用 Equals(Double) 该方法,而第二个比较返回 false 是因为编译器调用 Equals(Object) 该方法。
using System;
public class OverExample
{
static double value = 112;
public static void Main()
{
byte byte1= 112;
Console.WriteLine("value = byte1: {0,16}", value.Equals(byte1));
TestObjectForEquality(byte1);
short short1 = 112;
Console.WriteLine("value = short1: {0,16}", value.Equals(short1));
TestObjectForEquality(short1);
int int1 = 112;
Console.WriteLine("value = int1: {0,18}", value.Equals(int1));
TestObjectForEquality(int1);
long long1 = 112;
Console.WriteLine("value = long1: {0,17}", value.Equals(long1));
TestObjectForEquality(long1);
sbyte sbyte1 = 112;
Console.WriteLine("value = sbyte1: {0,16}", value.Equals(sbyte1));
TestObjectForEquality(sbyte1);
ushort ushort1 = 112;
Console.WriteLine("value = ushort1: {0,16}", value.Equals(ushort1));
TestObjectForEquality(ushort1);
uint uint1 = 112;
Console.WriteLine("value = uint1: {0,18}", value.Equals(uint1));
TestObjectForEquality(uint1);
ulong ulong1 = 112;
Console.WriteLine("value = ulong1: {0,17}", value.Equals(ulong1));
TestObjectForEquality(ulong1);
decimal dec1 = 112m;
Console.WriteLine("value = dec1: {0,21}", value.Equals(dec1));
TestObjectForEquality(dec1);
float sng1 = 112;
Console.WriteLine("value = sng1: {0,19}", value.Equals(sng1));
TestObjectForEquality(sng1);
}
private static void TestObjectForEquality(Object obj)
{
Console.WriteLine("{0} ({1}) = {2} ({3}): {4}\n",
value, value.GetType().Name,
obj, obj.GetType().Name,
value.Equals(obj));
}
}
// The example displays the following output:
// value = byte1: True
// 112 (Double) = 112 (Byte): False
//
// value = short1: True
// 112 (Double) = 112 (Int16): False
//
// value = int1: True
// 112 (Double) = 112 (Int32): False
//
// value = long1: True
// 112 (Double) = 112 (Int64): False
//
// value = sbyte1: True
// 112 (Double) = 112 (SByte): False
//
// value = ushort1: True
// 112 (Double) = 112 (UInt16): False
//
// value = uint1: True
// 112 (Double) = 112 (UInt32): False
//
// value = ulong1: True
// 112 (Double) = 112 (UInt64): False
//
// value = dec1: False
// 112 (Double) = 112 (Decimal): False
//
// value = sng1: True
// 112 (Double) = 112 (Single): False
let value = 112
let testObjectForEquality (obj: obj) =
printfn $"{value} ({value.GetType().Name}) = {obj} ({obj.GetType().Name}): {value.Equals obj}\n"
let byte1 = 112uy
printfn $"value = byte1: {value.Equals byte1,16}"
testObjectForEquality byte1
let short1 = 112s
printfn $"value = short1: {value.Equals short1,16}"
testObjectForEquality short1
let int1 = 112
printfn $"value = int1: {value.Equals int1,18}"
testObjectForEquality int1
let long1 = 112L
printfn $"value = long1: {value.Equals long1,17}"
testObjectForEquality long1
let sbyte1 = 112y
printfn $"value = sbyte1: {value.Equals sbyte1,16}"
testObjectForEquality sbyte1
let ushort1 = 112us
printfn $"value = ushort1: {value.Equals ushort1,16}"
testObjectForEquality ushort1
let uint1 = 112u
printfn $"value = uint1: {value.Equals uint1,18}"
testObjectForEquality uint1
let ulong1 = 112uL
printfn $"value = ulong1: {value.Equals ulong1,17}"
testObjectForEquality ulong1
let dec1 = 112m
printfn $"value = dec1: {value.Equals dec1,21}"
testObjectForEquality dec1
let sng1 = 112f
printfn $"value = sng1: {value.Equals sng1,19}"
testObjectForEquality sng1
// The example displays the following output:
// value = byte1: True
// 112 (Double) = 112 (Byte): False
//
// value = short1: True
// 112 (Double) = 112 (Int16): False
//
// value = int1: True
// 112 (Double) = 112 (Int32): False
//
// value = long1: True
// 112 (Double) = 112 (Int64): False
//
// value = sbyte1: True
// 112 (Double) = 112 (SByte): False
//
// value = ushort1: True
// 112 (Double) = 112 (UInt16): False
//
// value = uint1: True
// 112 (Double) = 112 (UInt32): False
//
// value = ulong1: True
// 112 (Double) = 112 (UInt64): False
//
// value = dec1: False
// 112 (Double) = 112 (Decimal): False
//
// value = sng1: True
// 112 (Double) = 112 (Single): False
Module Example2
Dim value As Double = 112
Public Sub Main()
Dim byte1 As Byte = 112
Console.WriteLine("value = byte1: {0,16}", value.Equals(byte1))
TestObjectForEquality(byte1)
Dim short1 As Short = 112
Console.WriteLine("value = short1: {0,16}", value.Equals(short1))
TestObjectForEquality(short1)
Dim int1 As Integer = 112
Console.WriteLine("value = int1: {0,18}", value.Equals(int1))
TestObjectForEquality(int1)
Dim long1 As Long = 112
Console.WriteLine("value = long1: {0,17}", value.Equals(long1))
TestObjectForEquality(long1)
Dim sbyte1 As SByte = 112
Console.WriteLine("value = sbyte1: {0,16}", value.Equals(sbyte1))
TestObjectForEquality(sbyte1)
Dim ushort1 As UShort = 112
Console.WriteLine("value = ushort1: {0,16}", value.Equals(ushort1))
TestObjectForEquality(ushort1)
Dim uint1 As UInteger = 112
Console.WriteLine("value = uint1: {0,18}", value.Equals(uint1))
TestObjectForEquality(uint1)
Dim ulong1 As ULong = 112
Console.WriteLine("value = ulong1: {0,17}", value.Equals(ulong1))
TestObjectForEquality(ulong1)
Dim dec1 As Decimal = 112d
Console.WriteLine("value = dec1: {0,20}", value.Equals(dec1))
TestObjectForEquality(dec1)
Dim sng1 As Single = 112
Console.WriteLine("value = sng1: {0,19}", value.Equals(sng1))
TestObjectForEquality(sng1)
End Sub
Private Sub TestObjectForEquality(obj As Object)
Console.WriteLine("{0} ({1}) = {2} ({3}): {4}",
value, value.GetType().Name,
obj, obj.GetType().Name,
value.Equals(obj))
Console.WriteLine()
End Sub
End Module
' The example displays the following output:
' value = byte1: True
' 112 (Double) = 112 (Byte): False
'
' value = short1: True
' 112 (Double) = 112 (Int16): False
'
' value = int1: True
' 112 (Double) = 112 (Int32): False
'
' value = long1: True
' 112 (Double) = 112 (Int64): False
'
' value = sbyte1: True
' 112 (Double) = 112 (SByte): False
'
' value = ushort1: True
' 112 (Double) = 112 (UInt16): False
'
' value = uint1: True
' 112 (Double) = 112 (UInt32): False
'
' value = ulong1: True
' 112 (Double) = 112 (UInt64): False
'
' value = dec1: True
' 112 (Double) = 112 (Decimal): False
'
' value = sng1: True
' 112 (Double) = 112 (Single): False
另请参阅
适用于
Equals(Object)
- Source:
- Double.cs
- Source:
- Double.cs
- Source:
- Double.cs
- Source:
- Double.cs
- Source:
- Double.cs
返回一个值,该值指示此实例是否等于指定的对象。
public:
override bool Equals(System::Object ^ obj);public override bool Equals(object obj);public override bool Equals(object? obj);override this.Equals : obj -> boolPublic Overrides Function Equals (obj As Object) As Boolean参数
- obj
- Object
要与此实例进行比较的对象。
返回
true 如果 obj 为此实例的 Double 实例且等于此实例的值,则为 ;否则为 false。
注解
Equals应谨慎使用该方法,因为两个明显等效的值可能由于两个值的精度不同而不相等。 下面的示例报告 Double 值 .3333 和 Double 除以 1 除以 3 返回的值不相等。
// Initialize two doubles with apparently identical values
double double1 = .33333;
object double2 = (double) 1/3;
// Compare them for equality
Console.WriteLine(double1.Equals(double2)); // displays false
// Initialize two doubles with apparently identical values
let double1 = 0.33333
let double2 = double (1 / 3) |> box
// Compare them for equality
printfn $"{double1.Equals double2}" // displays false
' Initialize two doubles with apparently identical values
Dim double1 As Double = .33333
Dim double2 As Object = 1/3
' Compare them for equality
Console.WriteLine(double1.Equals(double2)) ' displays False
有关调用该方法的 Equals 替代方法,请参阅重载的文档 Equals(Double) 。
超出记录精度的浮点数的精度特定于.NET框架的实现和版本。 因此,两个特定数字的比较可能会在.NET框架的版本之间发生更改,因为数字的内部表示形式的精度可能会改变。
如果通过调用Double.NaN该方法测试两Equals个值是否相等,该方法将true返回。 但是,如果使用相等运算符测试两 NaN 个值是否相等,运算符将 false返回。 如果要确定 a Double 的值是否不是数字(NaN),另一种方法是调用 IsNaN 该方法。
调用方说明
编译器重载解析可能会导致两 Equals(Object) 个方法重载的行为明显差异。 如果定义自变量和 a obj 之间的Double隐式转换,并且参数未键入为类型Object,编译器可能会执行隐式转换并调用Equals(Double)该方法。 否则,它们将调用Equals(Object)该方法,如果该方法的参数不是false值,则始终返回obj该方法Double。 下面的示例说明了两个方法重载的行为差异。 对于除 C# 以外的 Decimal 所有基元数值类型,第一个比较返回是因为 true 编译器会自动执行扩大转换并调用 Equals(Double) 该方法,而第二个比较返回 false 是因为编译器调用 Equals(Object) 该方法。
using System;
public class OverExample
{
static double value = 112;
public static void Main()
{
byte byte1= 112;
Console.WriteLine("value = byte1: {0,16}", value.Equals(byte1));
TestObjectForEquality(byte1);
short short1 = 112;
Console.WriteLine("value = short1: {0,16}", value.Equals(short1));
TestObjectForEquality(short1);
int int1 = 112;
Console.WriteLine("value = int1: {0,18}", value.Equals(int1));
TestObjectForEquality(int1);
long long1 = 112;
Console.WriteLine("value = long1: {0,17}", value.Equals(long1));
TestObjectForEquality(long1);
sbyte sbyte1 = 112;
Console.WriteLine("value = sbyte1: {0,16}", value.Equals(sbyte1));
TestObjectForEquality(sbyte1);
ushort ushort1 = 112;
Console.WriteLine("value = ushort1: {0,16}", value.Equals(ushort1));
TestObjectForEquality(ushort1);
uint uint1 = 112;
Console.WriteLine("value = uint1: {0,18}", value.Equals(uint1));
TestObjectForEquality(uint1);
ulong ulong1 = 112;
Console.WriteLine("value = ulong1: {0,17}", value.Equals(ulong1));
TestObjectForEquality(ulong1);
decimal dec1 = 112m;
Console.WriteLine("value = dec1: {0,21}", value.Equals(dec1));
TestObjectForEquality(dec1);
float sng1 = 112;
Console.WriteLine("value = sng1: {0,19}", value.Equals(sng1));
TestObjectForEquality(sng1);
}
private static void TestObjectForEquality(Object obj)
{
Console.WriteLine("{0} ({1}) = {2} ({3}): {4}\n",
value, value.GetType().Name,
obj, obj.GetType().Name,
value.Equals(obj));
}
}
// The example displays the following output:
// value = byte1: True
// 112 (Double) = 112 (Byte): False
//
// value = short1: True
// 112 (Double) = 112 (Int16): False
//
// value = int1: True
// 112 (Double) = 112 (Int32): False
//
// value = long1: True
// 112 (Double) = 112 (Int64): False
//
// value = sbyte1: True
// 112 (Double) = 112 (SByte): False
//
// value = ushort1: True
// 112 (Double) = 112 (UInt16): False
//
// value = uint1: True
// 112 (Double) = 112 (UInt32): False
//
// value = ulong1: True
// 112 (Double) = 112 (UInt64): False
//
// value = dec1: False
// 112 (Double) = 112 (Decimal): False
//
// value = sng1: True
// 112 (Double) = 112 (Single): False
let value = 112
let testObjectForEquality (obj: obj) =
printfn $"{value} ({value.GetType().Name}) = {obj} ({obj.GetType().Name}): {value.Equals obj}\n"
let byte1 = 112uy
printfn $"value = byte1: {value.Equals byte1,16}"
testObjectForEquality byte1
let short1 = 112s
printfn $"value = short1: {value.Equals short1,16}"
testObjectForEquality short1
let int1 = 112
printfn $"value = int1: {value.Equals int1,18}"
testObjectForEquality int1
let long1 = 112L
printfn $"value = long1: {value.Equals long1,17}"
testObjectForEquality long1
let sbyte1 = 112y
printfn $"value = sbyte1: {value.Equals sbyte1,16}"
testObjectForEquality sbyte1
let ushort1 = 112us
printfn $"value = ushort1: {value.Equals ushort1,16}"
testObjectForEquality ushort1
let uint1 = 112u
printfn $"value = uint1: {value.Equals uint1,18}"
testObjectForEquality uint1
let ulong1 = 112uL
printfn $"value = ulong1: {value.Equals ulong1,17}"
testObjectForEquality ulong1
let dec1 = 112m
printfn $"value = dec1: {value.Equals dec1,21}"
testObjectForEquality dec1
let sng1 = 112f
printfn $"value = sng1: {value.Equals sng1,19}"
testObjectForEquality sng1
// The example displays the following output:
// value = byte1: True
// 112 (Double) = 112 (Byte): False
//
// value = short1: True
// 112 (Double) = 112 (Int16): False
//
// value = int1: True
// 112 (Double) = 112 (Int32): False
//
// value = long1: True
// 112 (Double) = 112 (Int64): False
//
// value = sbyte1: True
// 112 (Double) = 112 (SByte): False
//
// value = ushort1: True
// 112 (Double) = 112 (UInt16): False
//
// value = uint1: True
// 112 (Double) = 112 (UInt32): False
//
// value = ulong1: True
// 112 (Double) = 112 (UInt64): False
//
// value = dec1: False
// 112 (Double) = 112 (Decimal): False
//
// value = sng1: True
// 112 (Double) = 112 (Single): False
Module Example2
Dim value As Double = 112
Public Sub Main()
Dim byte1 As Byte = 112
Console.WriteLine("value = byte1: {0,16}", value.Equals(byte1))
TestObjectForEquality(byte1)
Dim short1 As Short = 112
Console.WriteLine("value = short1: {0,16}", value.Equals(short1))
TestObjectForEquality(short1)
Dim int1 As Integer = 112
Console.WriteLine("value = int1: {0,18}", value.Equals(int1))
TestObjectForEquality(int1)
Dim long1 As Long = 112
Console.WriteLine("value = long1: {0,17}", value.Equals(long1))
TestObjectForEquality(long1)
Dim sbyte1 As SByte = 112
Console.WriteLine("value = sbyte1: {0,16}", value.Equals(sbyte1))
TestObjectForEquality(sbyte1)
Dim ushort1 As UShort = 112
Console.WriteLine("value = ushort1: {0,16}", value.Equals(ushort1))
TestObjectForEquality(ushort1)
Dim uint1 As UInteger = 112
Console.WriteLine("value = uint1: {0,18}", value.Equals(uint1))
TestObjectForEquality(uint1)
Dim ulong1 As ULong = 112
Console.WriteLine("value = ulong1: {0,17}", value.Equals(ulong1))
TestObjectForEquality(ulong1)
Dim dec1 As Decimal = 112d
Console.WriteLine("value = dec1: {0,20}", value.Equals(dec1))
TestObjectForEquality(dec1)
Dim sng1 As Single = 112
Console.WriteLine("value = sng1: {0,19}", value.Equals(sng1))
TestObjectForEquality(sng1)
End Sub
Private Sub TestObjectForEquality(obj As Object)
Console.WriteLine("{0} ({1}) = {2} ({3}): {4}",
value, value.GetType().Name,
obj, obj.GetType().Name,
value.Equals(obj))
Console.WriteLine()
End Sub
End Module
' The example displays the following output:
' value = byte1: True
' 112 (Double) = 112 (Byte): False
'
' value = short1: True
' 112 (Double) = 112 (Int16): False
'
' value = int1: True
' 112 (Double) = 112 (Int32): False
'
' value = long1: True
' 112 (Double) = 112 (Int64): False
'
' value = sbyte1: True
' 112 (Double) = 112 (SByte): False
'
' value = ushort1: True
' 112 (Double) = 112 (UInt16): False
'
' value = uint1: True
' 112 (Double) = 112 (UInt32): False
'
' value = ulong1: True
' 112 (Double) = 112 (UInt64): False
'
' value = dec1: True
' 112 (Double) = 112 (Decimal): False
'
' value = sng1: True
' 112 (Double) = 112 (Single): False
