I actually needed to do this and came here for an answer. Doesn't look like anyone has done this before, so I ended up making something myself. I've not tested every case exhaustively, but it's able to reliably encode and decode numbers correctly, with no error between the input and output numbers.
The functions I wrote work with binary strings, but anyone who needs this should be able to easily adapt it for their own uses.
Here's my code:
--Define some commonly used constants here so we don't have to do this at runtime
--ln(2), used for change of base down the line
local log2 = math.log(2)
--Used to convert the fraction into a (very large) integer
local pow2to52 = math.pow(2,52)
--Used for bit-shifting
local f08 = math.pow(2, 8)
local f16 = math.pow(2,16)
local f24 = math.pow(2,24)
local f32 = math.pow(2,32)
local f40 = math.pow(2,40)
local f48 = math.pow(2,48)
function encodeDouble(number)
--IEEE double-precision floating point number
--Specification: https://en.wikipedia.org/wiki/Double-precision_floating-point_format
--Separate out the sign, exponent and fraction
local sign = number < 0 and 1 or 0
local exponent = math.ceil(math.log(math.abs(number))/log2) - 1
local fraction = math.abs(number)/math.pow(2,exponent) - 1
--Make sure the exponent stays in range - allowed values are -1023 through 1024
if (exponent < -1023) then
--We allow this case for subnormal numbers and just clamp the exponent and re-calculate the fraction
--without the offset of 1
exponent = -1023
fraction = math.abs(number)/math.pow(2,exponent)
elseif (exponent > 1024) then
--If the exponent ever goes above this value, something went horribly wrong and we should probably stop
error("Exponent out of range: " .. exponent)
end
--Handle special cases
if (number == 0) then
--Zero
exponent = -1023
fraction = 0
elseif (math.abs(number) == math.huge) then
--Infinity
exponent = 1024
fraction = 0
elseif (number ~= number) then
--NaN
exponent = 1024
fraction = (pow2to52-1)/pow2to52
end
--Prepare the values for encoding
local expOut = exponent + 1023 --The exponent is an 11 bit offset-binary
local fractionOut = fraction * pow2to52 --The fraction is 52 bit, so multiplying it by 2^52 will give us an integer
--Combine the values into 8 bytes and return the result
return char(
128*sign + math.floor(expOut/16), --Byte 0: Sign and then shift exponent down by 4 bit
(expOut%16)*16 + math.floor(fractionOut/f48), --Byte 1: Shift fraction up by 4 to give most significant bits, and fraction down by 48
math.floor(fractionOut/f40)%256, --Byte 2: Shift fraction down 40 bit
math.floor(fractionOut/f32)%256, --Byte 3: Shift fraction down 32 bit
math.floor(fractionOut/f24)%256, --Byte 4: Shift fraction down 24 bit
math.floor(fractionOut/f16)%256, --Byte 5: Shift fraction down 16 bit
math.floor(fractionOut/f08)%256, --Byte 6: Shift fraction down 8 bit
math.floor(fractionOut % 256) --Byte 7: Last 8 bits of the fraction
)
end
function decodeDouble(str)
--Get bytes from the string
local byte0 = byte(substr(str,1,1))
local byte1 = byte(substr(str,2,2))
local byte2 = byte(substr(str,3,3))
local byte3 = byte(substr(str,4,4))
local byte4 = byte(substr(str,5,5))
local byte5 = byte(substr(str,6,6))
local byte6 = byte(substr(str,7,7))
local byte7 = byte(substr(str,8,8))
--Separate out the values
local sign = byte0 >= 128 and 1 or 0
local exponent = (byte0%128)*16 + math.floor(byte1/16)
local fraction = (byte1%16)*f48
+ byte2*f40 + byte3*f32 + byte4*f24
+ byte5*f16 + byte6*f08 + byte7
--Handle special cases
if (exponent == 2047) then
--Infinities
if (fraction == 0) then return math.pow(-1,sign) * math.huge end
--NaN
if (fraction == pow2to52-1) then return 0/0 end
end
--Combine the values and return the result
if (exponent == 0) then
--Handle subnormal numbers
return math.pow(-1,sign) * math.pow(2,exponent-1023) * (fraction/pow2to52)
else
--Handle normal numbers
return math.pow(-1,sign) * math.pow(2,exponent-1023) * (fraction/pow2to52 + 1)
end
end