// Licensed to the .NET Foundation under one or more agreements. // The .NET Foundation licenses this file to you under the MIT license. // See the LICENSE file in the project root for more information. /*============================================================ ** ** ** ** Purpose: A wrapper class for the primitive type float. ** ** ===========================================================*/ using System.Globalization; using System.Runtime.CompilerServices; using System.Runtime.InteropServices; using System.Runtime.Versioning; using Internal.Runtime.CompilerServices; namespace System { [Serializable] [StructLayout(LayoutKind.Sequential)] [TypeForwardedFrom("mscorlib, Version=4.0.0.0, Culture=neutral, PublicKeyToken=b77a5c561934e089")] public readonly struct Single : IComparable, IConvertible, IFormattable, IComparable, IEquatable, ISpanFormattable { private readonly float m_value; // Do not rename (binary serialization) // // 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; // We use this explicit definition to avoid the confusion between 0.0 and -0.0. internal const float NegativeZero = (float)-0.0; /// Determines whether the specified value is finite (zero, subnormal, or normal). [NonVersionable] [MethodImpl(MethodImplOptions.AggressiveInlining)] public static bool IsFinite(float f) { var bits = BitConverter.SingleToInt32Bits(f); return (bits & 0x7FFFFFFF) < 0x7F800000; } /// Determines whether the specified value is infinite. [NonVersionable] [MethodImpl(MethodImplOptions.AggressiveInlining)] public static unsafe bool IsInfinity(float f) { var bits = BitConverter.SingleToInt32Bits(f); return (bits & 0x7FFFFFFF) == 0x7F800000; } /// Determines whether the specified value is NaN. [NonVersionable] [MethodImpl(MethodImplOptions.AggressiveInlining)] public static unsafe bool IsNaN(float f) { var bits = BitConverter.SingleToInt32Bits(f); return (bits & 0x7FFFFFFF) > 0x7F800000; } /// Determines whether the specified value is negative. [NonVersionable] [MethodImpl(MethodImplOptions.AggressiveInlining)] public static unsafe bool IsNegative(float f) { return BitConverter.SingleToInt32Bits(f) < 0; } /// Determines whether the specified value is negative infinity. [NonVersionable] [MethodImpl(MethodImplOptions.AggressiveInlining)] public static unsafe bool IsNegativeInfinity(float f) { return (f == float.NegativeInfinity); } /// Determines whether the specified value is normal. [NonVersionable] // This is probably not worth inlining, it has branches and should be rarely called public static unsafe bool IsNormal(float f) { var bits = BitConverter.SingleToInt32Bits(f); bits &= 0x7FFFFFFF; return (bits < 0x7F800000) && (bits != 0) && ((bits & 0x7F800000) != 0); } /// Determines whether the specified value is positive infinity. [NonVersionable] [MethodImpl(MethodImplOptions.AggressiveInlining)] public static unsafe bool IsPositiveInfinity(float f) { return (f == float.PositiveInfinity); } /// Determines whether the specified value is subnormal. [NonVersionable] // This is probably not worth inlining, it has branches and should be rarely called public static unsafe bool IsSubnormal(float f) { var bits = BitConverter.SingleToInt32Bits(f); bits &= 0x7FFFFFFF; return (bits < 0x7F800000) && (bits != 0) && ((bits & 0x7F800000) == 0); } // 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 float) { 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(SR.Arg_MustBeSingle); } public int CompareTo(float 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; } [NonVersionable] public static bool operator ==(float left, float right) { return left == right; } [NonVersionable] public static bool operator !=(float left, float right) { return left != right; } [NonVersionable] public static bool operator <(float left, float right) { return left < right; } [NonVersionable] public static bool operator >(float left, float right) { return left > right; } [NonVersionable] public static bool operator <=(float left, float right) { return left <= right; } [NonVersionable] public static bool operator >=(float left, float right) { return left >= right; } public override bool Equals(object obj) { if (!(obj is float)) { return false; } float temp = ((float)obj).m_value; if (temp == m_value) { return true; } return IsNaN(temp) && IsNaN(m_value); } public bool Equals(float obj) { if (obj == m_value) { return true; } return IsNaN(obj) && IsNaN(m_value); } public override int GetHashCode() { var bits = Unsafe.As(ref Unsafe.AsRef(in m_value)); // Optimized check for IsNan() || IsZero() if (((bits - 1) & 0x7FFFFFFF) >= 0x7F800000) { // Ensure that all NaNs and both zeros have the same hash code bits &= 0x7F800000; } return bits; } public override string ToString() { return Number.FormatSingle(m_value, null, NumberFormatInfo.CurrentInfo); } public string ToString(IFormatProvider provider) { return Number.FormatSingle(m_value, null, NumberFormatInfo.GetInstance(provider)); } public string ToString(string format) { return Number.FormatSingle(m_value, format, NumberFormatInfo.CurrentInfo); } public string ToString(string format, IFormatProvider provider) { return Number.FormatSingle(m_value, format, NumberFormatInfo.GetInstance(provider)); } public bool TryFormat(Span destination, out int charsWritten, ReadOnlySpan format = default, IFormatProvider provider = null) { return Number.TryFormatSingle(m_value, format, NumberFormatInfo.GetInstance(provider), destination, out charsWritten); } // 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) { if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s); return Number.ParseSingle(s, NumberStyles.Float | NumberStyles.AllowThousands, NumberFormatInfo.CurrentInfo); } public static float Parse(string s, NumberStyles style) { NumberFormatInfo.ValidateParseStyleFloatingPoint(style); if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s); return Number.ParseSingle(s, style, NumberFormatInfo.CurrentInfo); } public static float Parse(string s, IFormatProvider provider) { if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s); return Number.ParseSingle(s, NumberStyles.Float | NumberStyles.AllowThousands, NumberFormatInfo.GetInstance(provider)); } public static float Parse(string s, NumberStyles style, IFormatProvider provider) { NumberFormatInfo.ValidateParseStyleFloatingPoint(style); if (s == null) ThrowHelper.ThrowArgumentNullException(ExceptionArgument.s); return Number.ParseSingle(s, style, NumberFormatInfo.GetInstance(provider)); } public static float Parse(ReadOnlySpan s, NumberStyles style = NumberStyles.Float | NumberStyles.AllowThousands, IFormatProvider provider = null) { NumberFormatInfo.ValidateParseStyleFloatingPoint(style); return Number.ParseSingle(s, style, NumberFormatInfo.GetInstance(provider)); } public static bool TryParse(string s, out float result) { if (s == null) { result = 0; return false; } return TryParse((ReadOnlySpan)s, NumberStyles.Float | NumberStyles.AllowThousands, NumberFormatInfo.CurrentInfo, out result); } public static bool TryParse(ReadOnlySpan s, out float result) { return TryParse(s, NumberStyles.Float | NumberStyles.AllowThousands, NumberFormatInfo.CurrentInfo, out result); } public static bool TryParse(string s, NumberStyles style, IFormatProvider provider, out float result) { NumberFormatInfo.ValidateParseStyleFloatingPoint(style); if (s == null) { result = 0; return false; } return TryParse((ReadOnlySpan)s, style, NumberFormatInfo.GetInstance(provider), out result); } public static bool TryParse(ReadOnlySpan s, NumberStyles style, IFormatProvider provider, out float result) { NumberFormatInfo.ValidateParseStyleFloatingPoint(style); return TryParse(s, style, NumberFormatInfo.GetInstance(provider), out result); } private static bool TryParse(ReadOnlySpan s, NumberStyles style, NumberFormatInfo info, out float result) { return Number.TryParseSingle(s, style, info, out result); } // // 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(SR.Format(SR.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(SR.Format(SR.InvalidCast_FromTo, "Single", "DateTime")); } object IConvertible.ToType(Type type, IFormatProvider provider) { return Convert.DefaultToType((IConvertible)this, type, provider); } } }