// ==++== // // Copyright (c) Microsoft Corporation. All rights reserved. // // ==--== namespace System { using System; using System.Diagnostics; using System.Globalization; using System.Runtime.InteropServices; using System.Runtime.CompilerServices; // Implements the Decimal data type. The Decimal data type can // represent values ranging from -79,228,162,514,264,337,593,543,950,335 to // 79,228,162,514,264,337,593,543,950,335 with 28 significant digits. The // Decimal data type is ideally suited to financial calculations that // require a large number of significant digits and no round-off errors. // // The finite set of values of type Decimal are of the form m // / 10e, where m is an integer such that // -296 < m < 296, and e is an integer // between 0 and 28 inclusive. // // Contrary to the float and double data types, decimal // fractional numbers such as 0.1 can be represented exactly in the // Decimal representation. In the float and double // representations, such numbers are often infinite fractions, making those // representations more prone to round-off errors. // // The Decimal class implements widening conversions from the // ubyte, char, short, int, and long types // to Decimal. These widening conversions never loose any information // and never throw exceptions. The Decimal class also implements // narrowing conversions from Decimal to ubyte, char, // short, int, and long. These narrowing conversions round // the Decimal value towards zero to the nearest integer, and then // converts that integer to the destination type. An OverflowException // is thrown if the result is not within the range of the destination type. // // The Decimal class provides narrowing conversions to and from the // float and double types. A conversion from Decimal to // float or double may loose precision, but will not loose // information about the overall magnitude of the numeric value, and will never // throw an exception. A conversion from float or double to // Decimal throws an OverflowException if the value is not within // the range of the Decimal type. //| [StructLayout(LayoutKind.Sequential)] public struct Decimal : IFormattable, IComparable { // Sign mask for the flags field. A value of zero in this bit indicates a // positive Decimal value, and a value of one in this bit indicates a // negative Decimal value. // // Look at OleAut's DECIMAL_NEG constant to check for negative values // in native code. //| private const int SignMask = unchecked((int)0x80000000); // Scale mask for the flags field. This byte in the flags field contains // the power of 10 to divide the Decimal value by. The scale byte must // contain a value between 0 and 28 inclusive. //| private const int ScaleMask = 0x00FF0000; // Number of bits scale is shifted by. private const int ScaleShift = 16; // Constant representing the Decimal value 0. //| public const Decimal Zero = 0m; // Constant representing the Decimal value 1. //| public const Decimal One = 1m; // Constant representing the Decimal value -1. //| public const Decimal MinusOne = -1m; // Constant representing the largest possible Decimal value. The value of // this constant is 79,228,162,514,264,337,593,543,950,335. //| public const Decimal MaxValue = 79228162514264337593543950335m; // Constant representing the smallest possible Decimal value. The value of // this constant is -79,228,162,514,264,337,593,543,950,335. //| public const Decimal MinValue = -79228162514264337593543950335m; // The lo, mid, hi, and flags fields contain the representation of the // Decimal value. The lo, mid, and hi fields contain the 96-bit integer // part of the Decimal. Bits 0-15 (the lower word) of the flags field are // unused and must be zero; bits 16-23 contain must contain a value between // 0 and 28, indicating the power of 10 to divide the 96-bit integer part // by to produce the Decimal value; bits 24-30 are unused and must be zero; // and finally bit 31 indicates the sign of the Decimal value, 0 meaning // positive and 1 meaning negative. // // NOTE: Do not change the order in which these fields are declared. The // native methods in this class rely on this particular order. private int flags; private int hi; private int lo; private int mid; internal short reserved { get { return unchecked((short) (this.flags & 0xFFFF)); } set { this.flags = ((this.flags & ~0xFFFF) | (value & 0xFFFF)); } } internal byte scale { get { return unchecked((byte) (this.flags >> 16)); } set { this.flags = ((this.flags & ~0xFF0000) | (value << 16)); } } internal bool negative { get { return (this.flags < 0); } set { this.flags = (value ? (this.flags & 0x00FFFFFF) : (this.flags | ~0x7FFFFFFF)); } } internal uint hi32 { get { return unchecked((uint) this.hi); } set { this.hi = unchecked((int) value); } } internal uint mid32 { get { return unchecked((uint) this.mid); } set { this.mid = unchecked((int) value); } } internal uint lo32 { get { return unchecked((uint) this.lo); } set { this.lo = unchecked((int) value); } } // Constructs a zero Decimal. //public Decimal() { // lo = 0; // mid = 0; // hi = 0; // flags = 0; //} // Constructs a Decimal from an integer value. // //| public Decimal(int value) { if (value >= 0) { flags = 0; } else { flags = SignMask; value = -value; } lo = value; mid = 0; hi = 0; } // Constructs a Decimal from an unsigned integer value. // //| [CLSCompliant(false)] public Decimal(uint value) { flags = 0; lo = (int) value; mid = 0; hi = 0; } // Constructs a Decimal from a long value. // //| public Decimal(long value) { if (value >= 0) { flags = 0; } else { flags = SignMask; value = -value; } lo = (int)value; mid = (int)(value >> 32); hi = 0; } // Constructs a Decimal from an unsigned long value. // //| [CLSCompliant(false)] public Decimal(ulong value) { flags = 0; lo = (int)value; mid = (int)(value >> 32); hi = 0; } // Constructs a Decimal from a float value. // //| public Decimal(float value) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::InitSingle if (DecimalFromFloat(value, out this) < 0) { throw new OverflowException("Overflow_Decimal"); } this.reserved = 0; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] [GCAnnotation(GCOption.NONE)] private static extern int DecimalFromFloat(float f, out Decimal result); // Constructs a Decimal from a double value. // //| public Decimal(double value) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::InitDouble if (DecimalFromDouble(value, out this) < 0) { throw new OverflowException("Overflow_Decimal"); } this.reserved = 0; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalFromDouble(double d, out Decimal result); // Constructs a Decimal from an integer array containing a binary // representation. The bits argument must be a non-null integer // array with four elements. bits[0], bits[1], and // bits[2] contain the low, middle, and high 32 bits of the 96-bit // integer part of the Decimal. bits[3] contains the scale factor // and sign of the Decimal: bits 0-15 (the lower word) are unused and must // be zero; bits 16-23 must contain a value between 0 and 28, indicating // the power of 10 to divide the 96-bit integer part by to produce the // Decimal value; bits 24-30 are unused and must be zero; and finally bit // 31 indicates the sign of the Decimal value, 0 meaning positive and 1 // meaning negative. // // Note that there are several possible binary representations for the // same numeric value. For example, the value 1 can be represented as {1, // 0, 0, 0} (integer value 1 with a scale factor of 0) and equally well as // {1000, 0, 0, 0x30000} (integer value 1000 with a scale factor of 3). // The possible binary representations of a particular value are all // equally valid, and all are numerically equivalent. // //| public Decimal(int[] bits) { if (bits==null) throw new ArgumentNullException("bits"); if (bits.Length == 4) { int f = bits[3]; if ((f & ~(SignMask | ScaleMask)) == 0 && (f & ScaleMask) <= (28 << 16)) { lo = bits[0]; mid = bits[1]; hi = bits[2]; flags = f; return; } } throw new ArgumentException("Arg_DecBitCtor"); } // Constructs a Decimal from its constituent parts. // //| public Decimal(int lo, int mid, int hi, bool isNegative, byte scale) { if (scale > 28) throw new ArgumentOutOfRangeException("ArgumentOutOfRange_DecimalScale"); this.lo = lo; this.mid = mid; this.hi = hi; this.flags = ((int)scale) << 16; if (isNegative) this.flags |= SignMask; } // Constructs a Decimal from its constituent parts. private Decimal(int lo, int mid, int hi, int flags) { this.lo = lo; this.mid = mid; this.hi = hi; this.flags = flags; } // Returns the absolute value of the given Decimal. If d is // positive, the result is d. If d is negative, the result // is -d. // //| internal static Decimal Abs(Decimal d) { return new Decimal(d.lo, d.mid, d.hi, d.flags & ~SignMask); } // Adds two Decimal values. // //| public static Decimal Add(Decimal d1, Decimal d2) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Add Decimal result; if (DecimalAdd(ref d2, ref d1, out result) < 0) { throw new OverflowException("Decimal.Add"); } result.reserved = 0; return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalAdd(ref Decimal d1, ref Decimal d2, out Decimal result); // Compares two Decimal values, returning an integer that indicates their // relationship. // //| public static int Compare(Decimal d1, Decimal d2) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Compare return (DecimalCompare(ref d2, ref d1) - 1); } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalCompare(ref Decimal d1, ref Decimal d2); // 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 Decimal, this method throws an ArgumentException. // //| public int CompareTo(Object value) { if (value == null) return 1; if (!(value is Decimal)) throw new ArgumentException("Arg_MustBeDecimal"); return Decimal.Compare(this, (Decimal)value); } // Divides two Decimal values. // //| public static Decimal Divide(Decimal d1, Decimal d2) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Divide Decimal result; if (DecimalDivide(ref d2, ref d1, out result) < 0) { throw new OverflowException("Decimal.Divide"); } result.reserved = 0; return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalDivide(ref Decimal d1, ref Decimal d2, out Decimal result); // Checks if this Decimal is equal to a given object. Returns true // if the given object is a boxed Decimal and its value is equal to the // value of this Decimal. Returns false otherwise. // //| public override bool Equals(Object value) { if (value is Decimal) { return Compare(this, (Decimal)value) == 0; } return false; } // Returns the hash code for this Decimal. // //| public override int GetHashCode() { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::GetHashCode double dbl; if (DoubleFromDecimal(ref this, out dbl) != 0) { throw new Exception("Decimal.GetHashCode failure"); } return dbl.GetHashCode(); } // Compares two Decimal values for equality. Returns true if the two // Decimal values are equal, or false if they are not equal. // //| public static bool Equals(Decimal d1, Decimal d2) { return Compare(d1, d2) == 0; } // Rounds a Decimal to an integer value. The Decimal argument is rounded // towards negative infinity. // //| public static Decimal Floor(Decimal d) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Floor Decimal result; DecimalFloor(ref d, out result); return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalFloor(ref Decimal d, out Decimal result); // Converts this Decimal to a string. The resulting string consists of an // optional minus sign ("-") followed to a sequence of digits ("0" - "9"), // optionally followed by a decimal point (".") and another sequence of // digits. // //| public override String ToString() { return ToString(null); } //| public String ToString(String format) { return Number.FormatDecimal(this, format); } // Converts a string to a Decimal. The string must consist of an optional // minus sign ("-") followed by a sequence of digits ("0" - "9"). The // sequence of digits may optionally contain a single decimal point (".") // character. Leading and trailing whitespace characters are allowed. // Parse also a trailing negative sign, and parentheses in the number. // //| public static Decimal Parse(String s) { return Parse(s, NumberStyles.Number); } //| public static Decimal Parse(String s, NumberStyles style) { return Number.ParseDecimal(s, style); } /* Returns a binary representation of a Decimal. The return value is an * integer array with four elements. Elements 0, 1, and 2 contain the low, * middle, and high 32 bits of the 96-bit integer part of the Decimal. * Element 3 contains the scale factor and sign of the Decimal: bits 0-15 * (the lower word) are unused; bits 16-23 contain a value between 0 and * 28, indicating the power of 10 to divide the 96-bit integer part by to * produce the Decimal value; bits 24-30 are unused; and finally bit 31 * indicates the sign of the Decimal value, 0 meaning positive and 1 * meaning negative. * * @param d A Decimal value. * @return An integer array with four elements containing the binary * representation of the argument. * @see Decimal(int[]) */ //| public static int[] GetBits(Decimal d) { return new int[] {d.lo, d.mid, d.hi, d.flags}; } public static void GetBytes(Decimal d, byte [] buffer) { if (buffer == null || buffer.Length < 16) { throw new ArgumentException("Arg_MustBe16Bytes"); } buffer[0] = (byte) d.lo; buffer[1] = (byte) (d.lo >> 8); buffer[2] = (byte) (d.lo >> 16); buffer[3] = (byte) (d.lo >> 24); buffer[4] = (byte) d.mid; buffer[5] = (byte) (d.mid >> 8); buffer[6] = (byte) (d.mid >> 16); buffer[7] = (byte) (d.mid >> 24); buffer[8] = (byte) d.hi; buffer[9] = (byte) (d.hi >> 8); buffer[10] = (byte) (d.hi >> 16); buffer[11] = (byte) (d.hi >> 24); buffer[12] = (byte) d.flags; buffer[13] = (byte) (d.flags >> 8); buffer[14] = (byte) (d.flags >> 16); buffer[15] = (byte) (d.flags >> 24); } public static decimal ToDecimal(byte [] buffer) { if (buffer == null || buffer.Length < 16) { throw new ArgumentException("Arg_MustBe16Bytes"); } int lo = ((int)buffer[0]) | ((int)buffer[1] << 8) | ((int)buffer[2] << 16) | ((int)buffer[3] << 24); int mid = ((int)buffer[4]) | ((int)buffer[5] << 8) | ((int)buffer[6] << 16) | ((int)buffer[7] << 24); int hi = ((int)buffer[8]) | ((int)buffer[9] << 8) | ((int)buffer[10] << 16) | ((int)buffer[11] << 24); int flags = ((int)buffer[12]) | ((int)buffer[13] << 8) | ((int)buffer[14] << 16) | ((int)buffer[15] << 24); return new Decimal(lo,mid,hi,flags); } // Returns the larger of two Decimal values. // //| internal static Decimal Max(Decimal d1, Decimal d2) { return Compare(d1, d2) >= 0? d1: d2; } // Returns the smaller of two Decimal values. // //| internal static Decimal Min(Decimal d1, Decimal d2) { return Compare(d1, d2) < 0? d1: d2; } //| public static Decimal Remainder(Decimal d1, Decimal d2) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Remainder Decimal tmp = Truncate(Divide(d1, d2)); return Subtract(d1, Multiply(d2, tmp)); } // Multiplies two Decimal values. // //| public static Decimal Multiply(Decimal d1, Decimal d2) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Multiply Decimal result; if (DecimalMultiply(ref d1, ref d2, out result) < 0) { throw new OverflowException("Decimal.Multiply"); } result.reserved = 0; return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalMultiply(ref Decimal d1, ref Decimal d2, out Decimal result); // Returns the negated value of the given Decimal. If d is non-zero, // the result is -d. If d is zero, the result is zero. // //| public static Decimal Negate(Decimal d) { return new Decimal(d.lo, d.mid, d.hi, d.flags ^ SignMask); } // Rounds a Decimal value to a given number of decimal places. The value // given by d is rounded to the number of decimal places given by // decimals. The decimals argument must be an integer between // 0 and 28 inclusive. // // The operation Decimal.Round(d, dec) conceptually // corresponds to evaluating Decimal.Truncate(d * // 10^dec + delta) / 10^dec, where // delta is 0.5 for positive values of d and -0.5 for // negative values of d. // //| public static Decimal Round(Decimal d1, int decimals) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Round Decimal result; if (decimals < 0 || decimals > 28) { throw new ArgumentOutOfRangeException("decimals"); } if (DecimalRound(ref d1, decimals, out result) < 0) { throw new OverflowException("Decimal.Round"); } result.reserved = 0; return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalRound(ref Decimal d, int decimals, out Decimal result); // Subtracts two Decimal values. // //| public static Decimal Subtract(Decimal d1, Decimal d2) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp::Subtract Decimal result; if (DecimalSubtract(ref d1, ref d2, out result) < 0) { throw new OverflowException("Decimal.Subtract"); } result.reserved = 0; return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalSubtract(ref Decimal d1, ref Decimal d2, out Decimal result); // Converts a Decimal to an unsigned byte. The Decimal value is rounded // towards zero to the nearest integer value, and the result of this // operation is returned as a byte. // //| public static byte ToByte(Decimal value) { uint temp = ToUInt32(value); if (temp < Byte.MinValue || temp > Byte.MaxValue) throw new OverflowException("Overflow_Byte"); return (byte)temp; } // Converts a Decimal to a signed byte. The Decimal value is rounded // towards zero to the nearest integer value, and the result of this // operation is returned as a byte. // //| [CLSCompliant(false)] public static sbyte ToSByte(Decimal value) { int temp = ToInt32(value); if (temp < SByte.MinValue || temp > SByte.MaxValue) throw new OverflowException("Overflow_SByte"); return (sbyte)temp; } // Converts a Decimal to a short. The Decimal value is // rounded towards zero to the nearest integer value, and the result of // this operation is returned as a short. // //| public static short ToInt16(Decimal value) { int temp = ToInt32(value); if (temp < Int16.MinValue || temp > Int16.MaxValue) throw new OverflowException("Overflow_Int16"); return (short)temp; } // Converts a Decimal to a double. Since a double has fewer significant // digits than a Decimal, this operation may produce round-off errors. // //| public static double ToDouble(Decimal d) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp double result; DoubleFromDecimal(ref d, out result); return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DoubleFromDecimal(ref Decimal d, out double result); // Converts a Decimal to an integer. The Decimal value is rounded towards // zero to the nearest integer value, and the result of this operation is // returned as an integer. // //| public static int ToInt32(Decimal d) { if ((d.flags & ScaleMask) != 0) d = Truncate(d); if (d.hi == 0 && d.mid == 0) { int i = d.lo; if (d.flags >= 0) { if (i >= 0) return i; } else { i = -i; if (i <= 0) return i; } } throw new OverflowException("Overflow_Int32"); } // Converts a Decimal to a long. The Decimal value is rounded towards zero // to the nearest integer value, and the result of this operation is // returned as a long. // //| public static long ToInt64(Decimal d) { if ((d.flags & ScaleMask) != 0) d = Truncate(d); if (d.hi == 0) { long l = d.lo & 0xFFFFFFFFL | (long)d.mid << 32; if (d.flags >= 0) { if (l >= 0) return l; } else { l = -l; if (l <= 0) return l; } } throw new OverflowException("Overflow_Int64"); } // Converts a Decimal to an ushort. The Decimal // value is rounded towards zero to the nearest integer value, and the // result of this operation is returned as an ushort. // //| [CLSCompliant(false)] public static ushort ToUInt16(Decimal value) { uint temp = ToUInt32(value); if (temp < UInt16.MinValue || temp > UInt16.MaxValue) throw new OverflowException("Overflow_UInt16"); return (ushort)temp; } // Converts a Decimal to an unsigned integer. The Decimal // value is rounded towards zero to the nearest integer value, and the // result of this operation is returned as an unsigned integer. // //| [CLSCompliant(false)] public static uint ToUInt32(Decimal d) { if ((d.flags & ScaleMask) != 0) d = Truncate(d); if (d.hi == 0 && d.mid == 0) { uint i = (uint) d.lo; if (d.flags >= 0 || i == 0) return i; } throw new OverflowException("Overflow_UInt32"); } // Converts a Decimal to an unsigned long. The Decimal // value is rounded towards zero to the nearest integer value, and the // result of this operation is returned as a long. // //| [CLSCompliant(false)] public static ulong ToUInt64(Decimal d) { if ((d.flags & ScaleMask) != 0) d = Truncate(d); if (d.hi == 0) { ulong l = ((ulong)(uint)d.lo) | ((ulong)(uint)d.mid << 32); if (d.flags >= 0 || l == 0) return l; } throw new OverflowException("Overflow_UInt64"); } // Converts a Decimal to a float. Since a float has fewer significant // digits than a Decimal, this operation may produce round-off errors. // //| public static float ToSingle(Decimal d) { // rusa: see also Lightning\Src\VM\COMDecimal.cpp float result; FloatFromDecimal(ref d, out result); return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int FloatFromDecimal(ref Decimal d, out float result); // Truncates a Decimal to an integer value. The Decimal argument is rounded // towards zero to the nearest integer value, corresponding to removing all // digits after the decimal point. // //| public static Decimal Truncate(Decimal d) { Decimal result; DecimalTruncate(ref d, out result); return result; } [AccessedByRuntime("Output to header:defined in Decimal.cpp")] [MethodImpl(MethodImplOptions.InternalCall)] [StackBound(1024)] private static extern int DecimalTruncate(ref Decimal d, out Decimal result); //| public static implicit operator Decimal(byte value) { return new Decimal(value); } //| [CLSCompliant(false)] public static implicit operator Decimal(sbyte value) { return new Decimal(value); } //| public static implicit operator Decimal(short value) { return new Decimal(value); } //| [CLSCompliant(false)] public static implicit operator Decimal(ushort value) { return new Decimal(value); } //| public static implicit operator Decimal(char value) { return new Decimal(value); } //| public static implicit operator Decimal(int value) { return new Decimal(value); } //| [CLSCompliant(false)] public static implicit operator Decimal(uint value) { return new Decimal(value); } //| public static implicit operator Decimal(long value) { return new Decimal(value); } //| [CLSCompliant(false)] public static implicit operator Decimal(ulong value) { return new Decimal(value); } //| public static explicit operator Decimal(float value) { return new Decimal(value); } //| public static explicit operator Decimal(double value) { return new Decimal(value); } //| public static explicit operator byte(Decimal value) { return ToByte(value); } //| [CLSCompliant(false)] public static explicit operator sbyte(Decimal value) { return ToSByte(value); } //| public static explicit operator char(Decimal value) { return (char)ToUInt16(value); } //| public static explicit operator short(Decimal value) { return ToInt16(value); } //| [CLSCompliant(false)] public static explicit operator ushort(Decimal value) { return ToUInt16(value); } //| public static explicit operator int(Decimal value) { return ToInt32(value); } //| [CLSCompliant(false)] public static explicit operator uint(Decimal value) { return ToUInt32(value); } //| public static explicit operator long(Decimal value) { return ToInt64(value); } //| [CLSCompliant(false)] public static explicit operator ulong(Decimal value) { return ToUInt64(value); } //| public static explicit operator float(Decimal value) { return ToSingle(value); } //| public static explicit operator double(Decimal value) { return ToDouble(value); } //| public static Decimal operator +(Decimal d) { return d; } //| public static Decimal operator -(Decimal d) { return Negate(d); } //| public static Decimal operator ++(Decimal d) { return Add(d, One); } //| public static Decimal operator --(Decimal d) { return Subtract(d, One); } //| public static Decimal operator +(Decimal d1, Decimal d2) { return Add(d1, d2); } //| public static Decimal operator -(Decimal d1, Decimal d2) { return Subtract(d1, d2); } //| public static Decimal operator *(Decimal d1, Decimal d2) { return Multiply(d1, d2); } //| public static Decimal operator /(Decimal d1, Decimal d2) { return Divide(d1, d2); } //| public static Decimal operator %(Decimal d1, Decimal d2) { return Remainder(d1, d2); } /*private static bool operator equals(Decimal d1, Decimal d2) { return Compare(d1, d2) == 0; } private static int operator compare(Decimal d1, Decimal d2) { int c = Compare(d1, d2); if (c < 0) return -1; if (c > 0) return 1; return 0; }*/ //| public static bool operator ==(Decimal d1, Decimal d2) { return Compare(d1, d2) == 0; } //| public static bool operator !=(Decimal d1, Decimal d2) { return Compare(d1, d2) != 0; } //| public static bool operator <(Decimal d1, Decimal d2) { return Compare(d1, d2) < 0; } //| public static bool operator <=(Decimal d1, Decimal d2) { return Compare(d1, d2) <= 0; } //| public static bool operator >(Decimal d1, Decimal d2) { return Compare(d1, d2) > 0; } //| public static bool operator >=(Decimal d1, Decimal d2) { return Compare(d1, d2) >= 0; } // // IValue implementation // //| [NoHeapAllocation] public override TypeCode GetTypeCode() { return TypeCode.Decimal; } } }