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linux-packaging-mono/mcs/class/referencesource/mscorlib/system/uint32.cs

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Imported Upstream version 4.6.0.125 Former-commit-id: a2155e9bd80020e49e72e86c44da02a8ac0e57a4
2016-08-03 10:59:49 +00:00
// ==++==
//
// Copyright (c) Microsoft Corporation. All rights reserved.
//
// ==--==
/*============================================================
**
** Class: UInt32
**
**
** Purpose: This class will encapsulate an uint and
** provide an Object representation of it.
**
**
===========================================================*/
namespace System {
using System.Globalization;
using System;
///#if GENERICS_WORK
/// using System.Numerics;
///#endif
using System.Runtime;
using System.Runtime.InteropServices;
using System.Diagnostics.Contracts;
// * Wrapper for unsigned 32 bit integers.
[Serializable]
[CLSCompliant(false), System.Runtime.InteropServices.StructLayout(LayoutKind.Sequential)]
[System.Runtime.InteropServices.ComVisible(true)]
#if GENERICS_WORK
public struct UInt32 : IComparable, IFormattable, IConvertible
, IComparable<UInt32>, IEquatable<UInt32>
/// , IArithmetic<UInt32>
#else
public struct UInt32 : IComparable, IFormattable, IConvertible
#endif
{
private uint m_value;
public const uint MaxValue = (uint)0xffffffff;
public const uint MinValue = 0U;
// Compares this object to another object, returning an integer that
// indicates the relationship.
// Returns a value less than zero if this object
// null is considered to be less than any instance.
// If object is not of type UInt32, this method throws an ArgumentException.
//
public int CompareTo(Object value) {
if (value == null) {
return 1;
}
if (value is UInt32) {
// Need to use compare because subtraction will wrap
// to positive for very large neg numbers, etc.
uint i = (uint)value;
if (m_value < i) return -1;
if (m_value > i) return 1;
return 0;
}
throw new ArgumentException(Environment.GetResourceString("Arg_MustBeUInt32"));
}
public int CompareTo(UInt32 value) {
// Need to use compare because subtraction will wrap
// to positive for very large neg numbers, etc.
if (m_value < value) return -1;
if (m_value > value) return 1;
return 0;
}
public override bool Equals(Object obj) {
if (!(obj is UInt32)) {
return false;
}
return m_value == ((UInt32)obj).m_value;
}
[System.Runtime.Versioning.NonVersionable]
public bool Equals(UInt32 obj)
{
return m_value == obj;
}
// The absolute value of the int contained.
public override int GetHashCode() {
return ((int) m_value);
}
// The base 10 representation of the number with no extra padding.
[System.Security.SecuritySafeCritical] // auto-generated
public override String ToString() {
Contract.Ensures(Contract.Result<String>() != null);
return Number.FormatUInt32(m_value, null, NumberFormatInfo.CurrentInfo);
}
[System.Security.SecuritySafeCritical] // auto-generated
public String ToString(IFormatProvider provider) {
Contract.Ensures(Contract.Result<String>() != null);
return Number.FormatUInt32(m_value, null, NumberFormatInfo.GetInstance(provider));
}
[System.Security.SecuritySafeCritical] // auto-generated
public String ToString(String format) {
Contract.Ensures(Contract.Result<String>() != null);
return Number.FormatUInt32(m_value, format, NumberFormatInfo.CurrentInfo);
}
[System.Security.SecuritySafeCritical] // auto-generated
public String ToString(String format, IFormatProvider provider) {
Contract.Ensures(Contract.Result<String>() != null);
return Number.FormatUInt32(m_value, format, NumberFormatInfo.GetInstance(provider));
}
[CLSCompliant(false)]
public static uint Parse(String s) {
return Number.ParseUInt32(s, NumberStyles.Integer, NumberFormatInfo.CurrentInfo);
}
[CLSCompliant(false)]
public static uint Parse(String s, NumberStyles style) {
NumberFormatInfo.ValidateParseStyleInteger(style);
return Number.ParseUInt32(s, style, NumberFormatInfo.CurrentInfo);
}
[CLSCompliant(false)]
public static uint Parse(String s, IFormatProvider provider) {
return Number.ParseUInt32(s, NumberStyles.Integer, NumberFormatInfo.GetInstance(provider));
}
[CLSCompliant(false)]
public static uint Parse(String s, NumberStyles style, IFormatProvider provider) {
NumberFormatInfo.ValidateParseStyleInteger(style);
return Number.ParseUInt32(s, style, NumberFormatInfo.GetInstance(provider));
}
[CLSCompliant(false)]
public static bool TryParse(String s, out UInt32 result) {
return Number.TryParseUInt32(s, NumberStyles.Integer, NumberFormatInfo.CurrentInfo, out result);
}
[CLSCompliant(false)]
public static bool TryParse(String s, NumberStyles style, IFormatProvider provider, out UInt32 result) {
NumberFormatInfo.ValidateParseStyleInteger(style);
return Number.TryParseUInt32(s, style, NumberFormatInfo.GetInstance(provider), out result);
}
//
// IConvertible implementation
//
public TypeCode GetTypeCode() {
return TypeCode.UInt32;
}
/// <internalonly/>
bool IConvertible.ToBoolean(IFormatProvider provider) {
return Convert.ToBoolean(m_value);
}
/// <internalonly/>
char IConvertible.ToChar(IFormatProvider provider) {
return Convert.ToChar(m_value);
}
/// <internalonly/>
sbyte IConvertible.ToSByte(IFormatProvider provider) {
return Convert.ToSByte(m_value);
}
/// <internalonly/>
byte IConvertible.ToByte(IFormatProvider provider) {
return Convert.ToByte(m_value);
}
/// <internalonly/>
short IConvertible.ToInt16(IFormatProvider provider) {
return Convert.ToInt16(m_value);
}
/// <internalonly/>
ushort IConvertible.ToUInt16(IFormatProvider provider) {
return Convert.ToUInt16(m_value);
}
/// <internalonly/>
int IConvertible.ToInt32(IFormatProvider provider) {
return Convert.ToInt32(m_value);
}
/// <internalonly/>
uint IConvertible.ToUInt32(IFormatProvider provider) {
return m_value;
}
/// <internalonly/>
long IConvertible.ToInt64(IFormatProvider provider) {
return Convert.ToInt64(m_value);
}
/// <internalonly/>
ulong IConvertible.ToUInt64(IFormatProvider provider) {
return Convert.ToUInt64(m_value);
}
/// <internalonly/>
float IConvertible.ToSingle(IFormatProvider provider) {
return Convert.ToSingle(m_value);
}
/// <internalonly/>
double IConvertible.ToDouble(IFormatProvider provider) {
return Convert.ToDouble(m_value);
}
/// <internalonly/>
Decimal IConvertible.ToDecimal(IFormatProvider provider) {
return Convert.ToDecimal(m_value);
}
/// <internalonly/>
DateTime IConvertible.ToDateTime(IFormatProvider provider) {
throw new InvalidCastException(Environment.GetResourceString("InvalidCast_FromTo", "UInt32", "DateTime"));
}
/// <internalonly/>
Object IConvertible.ToType(Type type, IFormatProvider provider) {
return Convert.DefaultToType((IConvertible)this, type, provider);
}
///#if GENERICS_WORK
/// //
/// // IArithmetic<UInt32> implementation
/// //
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.AbsoluteValue(out bool overflowed) {
/// overflowed = false;
/// return m_value;
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.Negate(out bool overflowed) {
/// overflowed = (m_value != 0);
/// return m_value;
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.Sign(out bool overflowed) {
/// overflowed = false;
/// return (UInt32) (m_value == 0 ? 0 : 1);
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.Add(UInt32 addend, out bool overflowed) {
/// ulong ul = ((ulong)m_value) + addend;
/// overflowed = (ul > MaxValue);
/// return (UInt32) ul;
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.Subtract(UInt32 subtrahend, out bool overflowed) {
/// long l = ((long)m_value) - subtrahend;
/// overflowed = (l < MinValue);
/// return (UInt32) l;
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.Multiply(UInt32 multiplier, out bool overflowed) {
/// //
/// // true arithmetic range check => re-written for unsigned int
/// // ------------------------------- -------------------------------
/// // ((m_value * multiplier) > MaxValue) => (multiplier != 0) && (m_value > (MaxValue / multiplier))
/// //
///
/// overflowed = (multiplier != 0) && (m_value > (MaxValue / multiplier));
/// return unchecked(m_value * multiplier);
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.Divide(UInt32 divisor, out bool overflowed) {
/// overflowed = false;
/// return (UInt32) (m_value / divisor); // divide by zero will fail
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.DivideRemainder(UInt32 divisor, out UInt32 remainder, out bool overflowed) {
/// overflowed = false;
/// remainder = (UInt32) (m_value % divisor);
/// return (UInt32) (m_value / divisor); // divide by zero will fail
/// }
///
/// /// <internalonly/>
/// UInt32 IArithmetic<UInt32>.Remainder(UInt32 divisor, out bool overflowed) {
/// overflowed = false;
/// return (UInt32) (m_value % divisor);
/// }
///
/// /// <internalonly/>
/// ArithmeticDescriptor<UInt32> IArithmetic<UInt32>.GetDescriptor() {
/// if (s_descriptor == null) {
/// s_descriptor = new UInt32ArithmeticDescriptor( ArithmeticCapabilities.One
/// | ArithmeticCapabilities.Zero
/// | ArithmeticCapabilities.MaxValue
/// | ArithmeticCapabilities.MinValue
/// | ArithmeticCapabilities.Unsigned);
/// }
/// return s_descriptor;
/// }
///
/// private static UInt32ArithmeticDescriptor s_descriptor;
///
/// class UInt32ArithmeticDescriptor : ArithmeticDescriptor<UInt32> {
/// public UInt32ArithmeticDescriptor(ArithmeticCapabilities capabilities) : base(capabilities) {}
///
/// public override UInt32 One {
/// get {
/// return (UInt32) 1;
/// }
/// }
///
/// public override UInt32 Zero {
/// get {
/// return (UInt32) 0;
/// }
/// }
///
/// public override UInt32 MinValue {
/// get {
/// return UInt32.MinValue;
/// }
/// }
///
/// public override UInt32 MaxValue {
/// get {
/// return UInt32.MaxValue;
/// }
/// }
/// }
///#endif // #if GENERICS_WORK
}
}
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