Single.cs source code in C# .NET

Source code for the .NET framework in C#

                        
Code:

                         / 4.0 / 4.0 / untmp / DEVDIV_TFS / Dev10 / Releases / RTMRel / ndp / clr / src / BCL / System / Single.cs / 1305376 / Single.cs
                        

                        
                            // ==++== 
//
//   Copyright (c) Microsoft Corporation.  All rights reserved.
//
// ==--== 
/*============================================================
** 
** Class:  Single 
**
** 
** Purpose: A wrapper class for the primitive type float.
**
**
===========================================================*/ 
namespace System {
 
    using System.Globalization; 
    using System;
///#if GENERICS_WORK 
///    using System.Numerics;
///#endif
    using System.Runtime.InteropServices;
    using System.Runtime.CompilerServices; 
    using System.Runtime.ConstrainedExecution;
    using System.Diagnostics.Contracts; 
 
[Serializable]
[System.Runtime.InteropServices.StructLayout(LayoutKind.Sequential)] 
[System.Runtime.InteropServices.ComVisible(true)]
#if GENERICS_WORK
    public struct Single : IComparable, IFormattable, IConvertible
        , IComparable, IEquatable 
///     , IArithmetic
#if false // ugly hack to fix syntax for TrimSrc parser, which ignores #if directives 
    { 
    }
#endif 
#else
    public struct Single : IComparable, IFormattable, IConvertible
#endif
    { 
        internal float m_value;
 
        // 
        // Public constants
        // 
        public const float MinValue = (float)-3.40282346638528859e+38;
        public const float Epsilon = (float)1.4e-45;
        public const float MaxValue = (float)3.40282346638528859e+38;
        public const float PositiveInfinity = (float)1.0 / (float)0.0; 
        public const float NegativeInfinity = (float)-1.0 / (float)0.0;
        public const float NaN = (float)0.0 / (float)0.0; 
 
        [Pure]
        [System.Security.SecuritySafeCritical]  // auto-generated 
        public unsafe static bool IsInfinity(float f) {
            return (*(int*)(&f) & 0x7FFFFFFF) == 0x7F800000;
        }
 
        [Pure]
        [System.Security.SecuritySafeCritical]  // auto-generated 
        public unsafe static bool IsPositiveInfinity(float f) { 
            return *(int*)(&f) == 0x7F800000;
        } 

        [Pure]
        [System.Security.SecuritySafeCritical]  // auto-generated
        public unsafe static bool IsNegativeInfinity(float f) { 
            return *(int*)(&f) == unchecked((int)0xFF800000);
        } 
 
        [Pure]
        [ReliabilityContract(Consistency.WillNotCorruptState, Cer.Success)] 
        public static bool IsNaN(float f) {
            //Jit will generate inlineable code with this
// warning CS1718:  Comparison to same variable
#pragma warning disable 1718 
            if (f != f)
            { 
                return true; 
            }
            else 
            {
                return false;
            }
#pragma warning restore 1718 
        }
 
        // 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 Single, this method throws an ArgumentException.
        //
        public int CompareTo(Object value) { 
            if (value == null) {
                return 1; 
            } 
            if (value is Single) {
                float f = (float)value; 
                if (m_value < f) return -1;
                if (m_value > f) return 1;
                if (m_value == f) return 0;
 
                // At least one of the values is NaN.
                if (IsNaN(m_value)) 
                    return (IsNaN(f) ? 0 : -1); 
                else // f is NaN.
                    return 1; 
            }
            throw new ArgumentException (Environment.GetResourceString("Arg_MustBeSingle"));
        }
 

        public int CompareTo(Single value) { 
            if (m_value < value) return -1; 
            if (m_value > value) return 1;
            if (m_value == value) return 0; 

            // At least one of the values is NaN.
            if (IsNaN(m_value))
                return (IsNaN(value) ? 0 : -1); 
            else // f is NaN.
                return 1; 
        } 

        public static bool operator ==(Single left, Single right) { 
            return left == right;
        }

        public static bool operator !=(Single left, Single right) { 
            return left != right;
        } 
 
        public static bool operator <(Single left, Single right) {
            return left < right; 
        }

        public static bool operator >(Single left, Single right) {
            return left > right; 
        }
 
        public static bool operator <=(Single left, Single right) { 
            return left <= right;
        } 

        public static bool operator >=(Single left, Single right) {
            return left >= right;
        } 

        public override bool Equals(Object obj) { 
            if (!(obj is Single)) { 
                return false;
            } 
            float temp = ((Single)obj).m_value;
            if (temp == m_value) {
                return true;
            } 

            return IsNaN(temp) && IsNaN(m_value); 
        } 

        public bool Equals(Single obj) 
        {
            if (obj == m_value) {
                return true;
            } 

            return IsNaN(obj) && IsNaN(m_value); 
        } 

        [System.Security.SecuritySafeCritical]  // auto-generated 
        public unsafe override int GetHashCode() {
            float f = m_value;
            if (f == 0) {
                // Ensure that 0 and -0 have the same hash code 
                return 0;
            } 
            int v = *(int*)(&f); 
            return v;
        } 

        [System.Security.SecuritySafeCritical]  // auto-generated
        public override String ToString() {
            Contract.Ensures(Contract.Result() != null); 
            return Number.FormatSingle(m_value, null, NumberFormatInfo.CurrentInfo);
        } 
 
        [System.Security.SecuritySafeCritical]  // auto-generated
        public String ToString(IFormatProvider provider) { 
            Contract.Ensures(Contract.Result() != null);
            return Number.FormatSingle(m_value, null, NumberFormatInfo.GetInstance(provider));
        }
 
        [System.Security.SecuritySafeCritical]  // auto-generated
        public String ToString(String format) { 
            Contract.Ensures(Contract.Result() != null); 
            return Number.FormatSingle(m_value, format, NumberFormatInfo.CurrentInfo);
        } 

        [System.Security.SecuritySafeCritical]  // auto-generated
        public String ToString(String format, IFormatProvider provider) {
            Contract.Ensures(Contract.Result() != null); 
            return Number.FormatSingle(m_value, format, NumberFormatInfo.GetInstance(provider));
        } 
 
        // Parses a float from a String in the given style.  If
        // a NumberFormatInfo isn't specified, the current culture's 
        // NumberFormatInfo is assumed.
        //
        // This method will not throw an OverflowException, but will return
        // PositiveInfinity or NegativeInfinity for a number that is too 
        // large or too small.
        // 
        public static float Parse(String s) { 
            return Parse(s, NumberStyles.Float | NumberStyles.AllowThousands, NumberFormatInfo.CurrentInfo);
        } 

        public static float Parse(String s, NumberStyles style) {
            NumberFormatInfo.ValidateParseStyleFloatingPoint(style);
            return Parse(s, style, NumberFormatInfo.CurrentInfo); 
        }
 
        public static float Parse(String s, IFormatProvider provider) { 
            return Parse(s, NumberStyles.Float | NumberStyles.AllowThousands, NumberFormatInfo.GetInstance(provider));
        } 

        public static float Parse(String s, NumberStyles style, IFormatProvider provider) {
            NumberFormatInfo.ValidateParseStyleFloatingPoint(style);
            return Parse(s, style, NumberFormatInfo.GetInstance(provider)); 
        }
 
        private static float Parse(String s, NumberStyles style, NumberFormatInfo info) { 
            return Number.ParseSingle(s, style, info);
        } 

        [System.Security.SecuritySafeCritical]  // auto-generated
        public static Boolean TryParse(String s, out Single result) {
            return TryParse(s, NumberStyles.Float | NumberStyles.AllowThousands, NumberFormatInfo.CurrentInfo, out result); 
        }
 
        [System.Security.SecuritySafeCritical]  // auto-generated 
        public static Boolean TryParse(String s, NumberStyles style, IFormatProvider provider, out Single result) {
            NumberFormatInfo.ValidateParseStyleFloatingPoint(style); 
            return TryParse(s, style, NumberFormatInfo.GetInstance(provider), out result);
        }

        private static Boolean TryParse(String s, NumberStyles style, NumberFormatInfo info, out Single result) { 
            if (s == null) {
                result = 0; 
                return false; 
            }
            bool success = Number.TryParseSingle(s, style, info, out result); 
            if (!success) {
                String sTrim = s.Trim();
                if (sTrim.Equals(info.PositiveInfinitySymbol)) {
                    result = PositiveInfinity; 
                } else if (sTrim.Equals(info.NegativeInfinitySymbol)) {
                    result = NegativeInfinity; 
                } else if (sTrim.Equals(info.NaNSymbol)) { 
                    result = NaN;
                } else 
                    return false; // We really failed
            }
            return true;
 
        }
 
        // 
        // IConvertible implementation
        // 

        public TypeCode GetTypeCode() {
            return TypeCode.Single;
        } 

 
        ///  
        bool IConvertible.ToBoolean(IFormatProvider provider) {
            return Convert.ToBoolean(m_value); 
        }

        /// 
        char IConvertible.ToChar(IFormatProvider provider) { 
            throw new InvalidCastException(Environment.GetResourceString("InvalidCast_FromTo", "Single", "Char"));
        } 
 
        /// 
        sbyte IConvertible.ToSByte(IFormatProvider provider) { 
            return Convert.ToSByte(m_value);
        }

        ///  
        byte IConvertible.ToByte(IFormatProvider provider) {
            return Convert.ToByte(m_value); 
        } 

        ///  
        short IConvertible.ToInt16(IFormatProvider provider) {
            return Convert.ToInt16(m_value);
        }
 
        /// 
        ushort IConvertible.ToUInt16(IFormatProvider provider) { 
            return Convert.ToUInt16(m_value); 
        }
 
        /// 
        int IConvertible.ToInt32(IFormatProvider provider) {
            return Convert.ToInt32(m_value);
        } 

        ///  
        uint IConvertible.ToUInt32(IFormatProvider provider) { 
            return Convert.ToUInt32(m_value);
        } 

        /// 
        long IConvertible.ToInt64(IFormatProvider provider) {
            return Convert.ToInt64(m_value); 
        }
 
        ///  
        ulong IConvertible.ToUInt64(IFormatProvider provider) {
            return Convert.ToUInt64(m_value); 
        }

        /// 
        float IConvertible.ToSingle(IFormatProvider provider) { 
            return m_value;
        } 
 
        /// 
        double IConvertible.ToDouble(IFormatProvider provider) { 
            return Convert.ToDouble(m_value);
        }

        ///  
        Decimal IConvertible.ToDecimal(IFormatProvider provider) {
            return Convert.ToDecimal(m_value); 
        } 

        ///  
        DateTime IConvertible.ToDateTime(IFormatProvider provider) {
            throw new InvalidCastException(Environment.GetResourceString("InvalidCast_FromTo", "Single", "DateTime"));
        }
 
        /// 
        Object IConvertible.ToType(Type type, IFormatProvider provider) { 
            return Convert.DefaultToType((IConvertible)this, type, provider); 
        }
///#if GENERICS_WORK 
///        //
///        // IArithmetic implementation
///        //
/// 
///        /// 
///        Single IArithmetic.AbsoluteValue(out bool overflowed) { 
///            Single abs = (m_value < 0 ? -m_value : m_value); 
///            overflowed = IsInfinity(abs) || IsNaN(abs);
///            return abs; 
///        }
///
///        /// 
///        Single IArithmetic.Negate(out bool overflowed) { 
///            Single neg= -m_value;
///            overflowed = IsInfinity(neg) || IsNaN(neg); 
///            return neg; 
///        }
/// 
///        /// 
///        Single IArithmetic.Sign(out bool overflowed) {
///            overflowed = IsNaN(m_value);
///            if (overflowed) { 
///                return m_value;
///            } 
///            return (m_value >= 0 ? (m_value == 0 ? 0 : 1) : -1); 
///        }
/// 
///        /// 
///        Single IArithmetic.Add(Single addend, out bool overflowed) {
///            Single s = m_value + addend;
///            overflowed = IsInfinity(s) || IsNaN(s); 
///            return s;
///        } 
/// 
///        /// 
///        Single IArithmetic.Subtract(Single subtrahend, out bool overflowed) { 
///            Single s = m_value - subtrahend;
///            overflowed = IsInfinity(s) || IsNaN(s);
///            return s;
///        } 
///
///        ///  
///        Single IArithmetic.Multiply(Single multiplier, out bool overflowed) { 
///            Single s = m_value * multiplier;
///            overflowed = IsInfinity(s) || IsNaN(s); 
///            return s;
///        }
///
/// 
///        /// 
///        Single IArithmetic.Divide(Single divisor, out bool overflowed) { 
///            Single s = m_value / divisor; 
///            overflowed = IsInfinity(s) || IsNaN(s);
///            return s; 
///        }
///
///        /// 
///        Single IArithmetic.DivideRemainder(Single divisor, out Single remainder, out bool overflowed) { 
///            remainder = m_value % divisor;
///            Single s = m_value / divisor; 
///            overflowed = IsInfinity(s) || IsInfinity(remainder) || IsNaN(s) || IsNaN(remainder); 
///            return s;
///        } 
///
///        /// 
///        Single IArithmetic.Remainder(Single divisor, out bool overflowed) {
///            Single s = m_value % divisor; 
///            overflowed = IsInfinity(s) || IsNaN(s);
///            return s; 
///        } 
///
///        ///  
///        ArithmeticDescriptor IArithmetic.GetDescriptor() {
///            if (s_descriptor == null) {
///                s_descriptor = new SingleArithmeticDescriptor( ArithmeticCapabilities.One
///                                                             | ArithmeticCapabilities.Zero 
///                                                             | ArithmeticCapabilities.MaxValue
///                                                             | ArithmeticCapabilities.MinValue 
///                                                             | ArithmeticCapabilities.PositiveInfinity 
///                                                             | ArithmeticCapabilities.NegativeInfinity);
///            } 
///            return s_descriptor;
///        }
///
///        private static SingleArithmeticDescriptor s_descriptor; 
///
///        class SingleArithmeticDescriptor : ArithmeticDescriptor { 
///            public SingleArithmeticDescriptor(ArithmeticCapabilities capabilities) : base(capabilities) {} 
///            public override Single One {
///                get { 
///                    return (Single) 1;
///                }
///            }
/// 
///            public override Single Zero {
///                get { 
///                    return (Single) 0; 
///                }
///            } 
///
///            public override Single MinValue {
///                get {
///                    return Single.MinValue; 
///                }
///            } 
/// 
///            public override Single MaxValue {
///                get { 
///                    return Single.MaxValue;
///                }
///            }
/// 
///            public override Single PositiveInfinity {
///                get { 
///                    return Single.PositiveInfinity; 
///                }
///            } 
///
///            public override Single NegativeInfinity {
///                get {
///                    return Single.NegativeInfinity; 
///                }
///            } 
/// 
///        }
///#endif // #if GENERICS_WORK 
    }
}

// File provided for Reference Use Only by Microsoft Corporation (c) 2007.

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