If you absolutely can't use BigDecimal
and would prefer not to use double
s, use long
s to do fixed-point arithmetic (so each long
value would represent the number of cents, for example). This will let you represent 18 significant digits.
I'd say use joda-money, but this uses BigDecimal
under the covers.
Edit (as the above doesn't really answer the question):
Disclaimer: Please, if accuracy matters to you at all, don't use double
to represent money. But it seems the poster doesn't need exact accuracy (this seems to be about a financial pricing model which probably has more than 10**-12 built-in uncertainty), and cares more about performance. Assuming this is the case, using a double
is excusable.
In general, a double
cannot exactly represent a decimal fraction. So, how inexact is a double
? There's no short answer for this.
A double
may be able to represent a number well enough that you can read the number into a double
, then write it back out again, preserving fifteen decimal digits of precision. But as it's a binary rather than a decimal fraction, it can't be exact - it's the value we wish to represent, plus or minus some error. When many arithmetic operations are performed involving inexact double
s, the amount of this error can build up over time, such that the end product has fewer than fifteen decimal digits of accuracy. How many fewer? That depends.
Consider the following function that takes the n
th root of 1000, then multiplies it by itself n
times:
private static double errorDemo(int n) {
double r = Math.pow(1000.0, 1.0/n);
double result = 1.0;
for (int i = 0; i < n; i++) {
result *= r;
}
return 1000.0 - result;
}
Results are as follows:
errorDemo( 10) = -7.958078640513122E-13
errorDemo( 31) = 9.094947017729282E-13
errorDemo( 100) = 3.410605131648481E-13
errorDemo( 310) = -1.4210854715202004E-11
errorDemo( 1000) = -1.6370904631912708E-11
errorDemo( 3100) = 1.1107204045401886E-10
errorDemo( 10000) = -1.2255441106390208E-10
errorDemo( 31000) = 1.3799308362649754E-9
errorDemo( 100000) = 4.00075350626139E-9
errorDemo( 310000) = -3.100740286754444E-8
errorDemo(1000000) = -9.706695891509298E-9
Note that the size of the accumulated inaccuracy doesn't increase exactly in proportion to the number of intermediate steps (indeed, it's not monotonically increasing). Given a known series of intermediate operations we can determine the probability distribtion of the inaccuracy; while this will have a wider range the more operations there are, the exact amount will depend on the numbers fed into the calculation. The uncertainty is itself uncertain!
Depending on what kind of calculation you're performing, you may be able to control this error by rounding to whole units/whole cents after intermediate steps. (Consider the case of a bank account holding $100 at 6% annual interest compounded monthly, so 0.5% interest per month. After the third month of interest is credited, do you want the balance to be $101.50 or $101.51?) Having your double
stand for the number of fractional units (i.e. cents) rather than the number of whole units would make this easier - but if you're doing that, you may as well just use long
s as I suggested above.
Disclaimer, again: The accumulation of floating-point error makes the use of double
s for amounts of money potentially quite messy. Speaking as a Java dev who's had the evils of using double
for a decimal representation of anything drummed into him for years, I'd use decimal rather than floating-point arithmetic for any important calculations involving money.