VB6 doesn't appear to make it that easy to store +infinity, -infinity and NaN into double vars. It would help if it could so that I could do comparisons with those values in the context of complex numbers. How?
A few different things. As you can see from Pax's example, you really just need to look up the IEEE 754 standard and then plug your bytes into the right places. The only caution I would give you is that MicroSoft has deprecated RtlMoveMemory due to it's potential for creating security issues of the overflow type. As an alternative you can accomplish this in "pure" VB with a little careful coercion using User Defined Types and LSet. (Also note that there are two types of NaN.)
Option Explicit Public Enum abIEEE754SpecialValues abInfinityPos abInfinityNeg abNaNQuiet abNaNSignalling abDoubleMax abDoubleMin End Enum Private Type TypedDouble value As Double End Type Private Type ByteDouble value(7) As Byte End Type Public Sub Example() MsgBox GetIEEE754SpecialValue(abDoubleMax) End Sub Public Function GetIEEE754SpecialValue(ByVal value As abIEEE754SpecialValues) As Double Dim dblRtnVal As Double Select Case value Case abIEEE754SpecialValues.abInfinityPos dblRtnVal = BuildDouble(byt6:=240, byt7:=127) Case abIEEE754SpecialValues.abInfinityNeg dblRtnVal = BuildDouble(byt6:=240, byt7:=255) Case abIEEE754SpecialValues.abNaNQuiet dblRtnVal = BuildDouble(byt6:=255, byt7:=255) Case abIEEE754SpecialValues.abNaNSignalling dblRtnVal = BuildDouble(byt6:=248, byt7:=255) Case abIEEE754SpecialValues.abDoubleMax dblRtnVal = BuildDouble(255, 255, 255, 255, 255, 255, 239, 127) Case abIEEE754SpecialValues.abDoubleMin dblRtnVal = BuildDouble(255, 255, 255, 255, 255, 255, 239, 255) End Select GetIEEE754SpecialValue = dblRtnVal End Function Public Function BuildDouble( _ Optional byt0 As Byte = 0, _ Optional byt1 As Byte = 0, _ Optional byt2 As Byte = 0, _ Optional byt3 As Byte = 0, _ Optional byt4 As Byte = 0, _ Optional byt5 As Byte = 0, _ Optional byt6 As Byte = 0, _ Optional byt7 As Byte = 0 _ ) As Double Dim bdTmp As ByteDouble, tdRtnVal As TypedDouble bdTmp.value(0) = byt0 bdTmp.value(1) = byt1 bdTmp.value(2) = byt2 bdTmp.value(3) = byt3 bdTmp.value(4) = byt4 bdTmp.value(5) = byt5 bdTmp.value(6) = byt6 bdTmp.value(7) = byt7 LSet tdRtnVal = bdTmp BuildDouble = tdRtnVal.value End Function
One last side note, you can also get NaN this way:
Public Function GetNaN() As Double On Error Resume Next GetNaN = 0 / 0 End Function
Actually, there is a MUCH simpler way to get Infinity, -Infinity and Not a Number:
public lfNaN as Double ' or As Single public lfPosInf as Double public lfNegInf as Double on error resume next ' to ignore Run-time error '6': Overflow and '11': Division by zero lfNaN = 0 / 0 ' -1.#IND lfPosInf = 1 / 0 ' 1.#INF lfNegInf = -1 / 0 ' -1.#INF on error goto 0 ' optional to reset the error handler
This page shows a slightly torturous way to do it. I've trimmed it down to match what your question asked for but haven't tested thoroughly. Let me know if there's any problems. One thing I noticed on that site is that the code they had for a quiet NaN was wrong, it should start the mantissa with a 1-bit - they seemed to have got that confused with a signalling NaN.
Public NegInfinity As Double Public PosInfinity As Double Public QuietNAN As Double Private Declare Sub CopyMemoryWrite Lib "kernel32" Alias "RtlMoveMemory" ( _ ByVal Destination As Long, source As Any, ByVal Length As Long) ' IEEE754 doubles: ' ' seeeeeee eeeemmmm mmmmmmmm mmmmmmmm mmmmmmmm mmmmmmmm mmmmmmmm mmmmmmmm ' ' s = sign ' ' e = exponent ' ' m = mantissa ' ' Quiet NaN: s = x, e = all 1s, m = 1xxx... ' ' +Inf : s = 0, e = all 1s, m = all 0s. ' ' -Inf : s = 1, e = all 1s, m = all 0s. '
Public Sub Init() Dim ptrToDouble As Long Dim byteArray(7) As Byte Dim i As Integer byteArray(7) = &H7F For i = 0 To 6 byteArray(i) = &HFF Next ptrToDouble = VarPtr(QuietNAN) CopyMemoryWrite ptrToDouble, byteArray(0), 8 byteArray(7) = &H7F byteArray(6) = &HF0 For i = 0 To 5 byteArray(i) = 0 Next ptrToDouble = VarPtr(PosInfinity) CopyMemoryWrite ptrToDouble, byteArray(0), 8 byteArray(7) = &HFF byteArray(6) = &HF0 For i = 0 To 5 byteArray(i) = 0 Next ptrToDouble = VarPtr(NegInfinity) CopyMemoryWrite ptrToDouble, byteArray(0), 8 End Sub
It basically uses kernel-level memory copies to transfer the bit patterns from a byte array to the double.
You should keep in mind however that there are multiple bit-values that can represent QNaN, specifically the sign bit can be 0 or 1 and all bits of the mantissa other than the first can also be zero or 1. This may complicate your strategy for comparisons unless you can discover if VB6 only uses one of the bit patterns - it won't affect the initialization of those values however, assuming VB6 properly implements IEE754 doubles.