3

I know that this question has already been discussed several times but I am not entirely satisfied with the answer. Please don't respond "Doubles are inaccurate, you can't represent 0.1! You have to use BigDecimal"...

Basically I am doing a financial software and we needed to store a lot of prices in memory. BigDecimal was too big to fit in the cache so we have decided to switch to double. So far we are not experiencing any bug for the good reason and we need an accuracy of 12 digits. The 12 digits estimations is based on the fact that even when we talk in million, we are still able to deal with cents.

A double gives a 15 significant decimal digit precision. If you round your doubles when you have to display/compare them, what can goes wrong??

I guess on problem is the accumulation of the inaccuracy, but how bad is it? How many operations will it take before it affect the 12th digit?

Do you see any other problems with doubles?

EDIT: About long, that's definitely something that we have thinked about. We are doing a lot of division multiplication and long won't deal well with that (losing the decimal and overflow), or at least you have to be very very careful with what you do. My question is more about the theory of doubles, basically how bad is it and is the inaccuracy acceptable?

EDIT2: Don't try to solve my software, I am fine with inaccuracy :). I re-word the question : How likely an inaccuracy will happen if you need only 12digits and that you round doubles when displaying/comparing?

25
  • 2
    cannot you just store the whole amount of cents?
    – Vlad
    Nov 14, 2013 at 13:04
  • 1
    @tibo That's what I've said - "there is something wrong with memory complexity of your approach". Even if you save these 24 bytes, it will still explode when you'll have 40 million prices not 10...
    – BartoszKP
    Nov 14, 2013 at 13:18
  • 5
    With regards to doubles being "bad", see my answer; basically doubles are no worse than our own decimal system (try to represent 1/3 in decimal). The two systems simply have different numbers that they "like". It is within this context that you should consider doubles. The financial system just has a particular love of 1/100 which happens to be exactly representable in decimal but not binary Nov 14, 2013 at 14:00
  • 4
    This is somewhat of a hack, but if you must must must use doubles then rounding to 2 significant figures every operation would supress the build up of error Nov 14, 2013 at 14:23
  • 4
    The question “How many operations will it take before it affect the 12th digit?” cannot be answered without additional information, notably which operations are to be performed and with what values, particularly since the question mentions division and multiplication, not just adding and subtracting amounts of money. Nov 14, 2013 at 15:03

8 Answers 8

14

If you absolutely can't use BigDecimal and would prefer not to use doubles, use longs 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 doubles, 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 nth 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 longs as I suggested above.

Disclaimer, again: The accumulation of floating-point error makes the use of doubles 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.

4
  • See may edit, that's a very good point but that's not what I am looking for ;)
    – tibo
    Nov 14, 2013 at 13:09
  • 1
    considering percental interest rates this is still a problem (1 * 1.05 is 1.05, qhich is 1.05 cents and nothing less)
    – LionC
    Nov 14, 2013 at 13:13
  • Expanded to try to better answer the original question.
    – pobrelkey
    Nov 14, 2013 at 15:03
  • Really like your code example, good start for estimating roughly how bad is the accumulation of inaccuracy. NB, you can do the same kind of reasoning with BigDecimal (and divide them by 3 or 7 or 9 or....). About long I think that it is the worst solution, divide it by 3 and you result is truncated, Multiply 2 long together and you end up with a long overflow...
    – tibo
    Nov 15, 2013 at 2:55
7

Martin Fowler wrote something on that topic. He suggests a Money class with internal long representation, and a decimal factor. http://martinfowler.com/eaaCatalog/money.html

5
  • 1
    Wrapper Class <==> Object Pointer overhead <==> my cache size is multiplied by at least 2
    – tibo
    Nov 14, 2013 at 13:11
  • Yep, but you get more reliable code, validation and other things.
    – Stroboskop
    Nov 20, 2013 at 17:48
  • On the other hand performance and memory usage are getting worse. Depends on the way you want to use it. For a server processing millions of amounts it's not a good idea - in a GUI its built in validation can help a lot, e.g. preventing users from putting mixed currencies in one bag or using decimals on a Yen...
    – Stroboskop
    Nov 20, 2013 at 17:54
  • The Money class sounds unnecessary, it is similar to the implementation of BigDecimal. A BigInteger (unlimited precision non-fractional integer, accomplished with a char[]) and a decimal position value.
    – Ron
    Nov 23, 2013 at 5:38
  • If you just want to store amounts, it doesn't add anything. But if you are using different currencies, you can implement sanity checks or use the exact number of fraction digits allowed. E.g. Japanese Yen has no "cents". If you don't do it you might end up with half a Yen.
    – Stroboskop
    Nov 26, 2013 at 13:29
7

Without using fixed point (integer) arithmetic you can NOT be sure that your calculations are ALWAYS correct. This is because of the way IEEE 754 floating point representation works, some decimal numbers cannot be represented as finite-length binary fractions. However, ALL fixed point numbers can be expressed as a finite length integer; therefore, they can be stored as exact binary values.

Consider the following:

public static void main(String[] args) {
    double d = 0.1;
    for (int i = 0; i < 1000; i++) {
        d += 0.1;
    }
    System.out.println(d);
}

This prints 100.09999999999859. ANY money implementation using doubles WILL fail.

For a more visual explanation, click the decimal to binary converter and try to convert 0.1 to binary. You end up with 0.00011001100110011001100110011001 (0011 repeating), converting it back to decimal you get 0.0999999998603016138.

Therefore 0.1 == 0.0999999998603016138


As a sidenote, BigDecimal is simply a BigInteger with an int decimal location. BigInteger relys on an underlying int[] to hold its digits, therefore offering fixed point precision.

public static void main(String[] args) {
    double d = 0;
    BigDecimal b = new BigDecimal(0);
    for (long i = 0; i < 100000000; i++) {
        d += 0.1;
        b = b.add(new BigDecimal("0.1"));
    }
    System.out.println(d);
    System.out.println(b);
}

Output:
9999999.98112945 (A whole cent is lost after 10^8 additions)
10000000.0

30
  • 5
    My point is that the precision doesn't matter. Even with 150 significant digit precision you will go wrong after 10000 additions. There is no way any floating-point type can be used successfully in this situation.
    – Ron
    Nov 14, 2013 at 13:26
  • 1
    @tibo Wait until your software has been in operation for years and pennies start appearing/missing.
    – Ron
    Nov 14, 2013 at 13:46
  • 1
    @tibo Okay I think I understand what you're getting at. Consider BartoszKP's comment though: If increasing your space complexity by less than a factor of 4 exceeds your limit, perhaps you are looking at the wrong type of solution.
    – Ron
    Nov 14, 2013 at 13:55
  • 1
    @RonE about your sidenote, you initialise your BigDecimal with a float so you have the inaccuracy. Initialize it with the string "0.1" and I am prety sure that the problem will go away ;)
    – tibo
    Nov 14, 2013 at 14:08
  • 3
    The first statement, that “Without using fixed point (integer) arithmetic, you can NEVER be sure that your calculations are correct”, is false. IEEE-754 is well specified and is susceptible to mathematical proof. Calculations can be designed that produce correct results, and provably so, for particular circumstances. The fact that .01 is not exactly represented does not mean it is impossible to design calculations that temporarily contain inaccuracies but whose results are designed well enough that exact values can be produced in the end. Nov 14, 2013 at 15:00
2

Historically, it was often reasonable to use floating-point types for precise calculations on whole numbers which could get bigger than 2^32, but not bigger than 2^52 [or, on machines with a proper "long double" type, 2^64]. Dividing a 52-bit number by a 32-bit number to yield a 20-bit quotient would require a rather lengthy drawn-out process on the 8088, but the 8087 processor can do it comparatively quickly and easily. Using decimals for financial calculations would have been perfectly reasonable, if all values that needed to be precise were always represented by whole numbers.

Nowadays, computers are much more able to handle larger integer values efficiently, and as a consequence it generally makes more sense to use integers to handle quantities which are going to be represented by whole numbers. Floating-point may seem convenient for things like fractional division, but correct code will have to deal with the effects of rounding things to whole numbers no matter what it does. If three people need to pay for something that costs $100.00, one can't achieve penny-accurate accounting by having everyone pay $33.333333333333; the only way to make things balance will be to have the people pay unequal amounts.

1

If the size of BigDecimal is too large for your cache, than you should convert amounts to long values when they are written to the cache and convert them back to BigDecimal when they are read. This will give you a smaller memory footprint for your cache and will have accurate calculations in your application.

Even if you are able to represent your inputs to calculations correctly with doubles, that doesn't mean that you will always get accurate results. You can still suffer from cancellation and other things.

If you refuse to use BigDecimal for your application logic, than you will rewrite lots of functionality that BigDecimal already provides.

4
  • How do you loose no precision when converting BigDecimals to long and vice versa?
    – LionC
    Nov 14, 2013 at 13:17
  • @LionC you are able to represent LONG.MIN_VALUE cents to Long.MAX_VALUE cents amounts with a single long. If all amounts the application will ever store in the cache are in that interval than this works. Nov 14, 2013 at 13:20
  • But youre not able to store half a cent and so on which considering interest rate tax and so on is an issue in financial software
    – LionC
    Nov 14, 2013 at 13:25
  • Actually @SpaceTrucker that's an excellent point and I think I should have done that ( a long in the implementation and a getter that return a BigDecimal).
    – tibo
    Nov 14, 2013 at 13:28
0

I am going to answer at question by addressing a different part of the problem. Please accept that I am trying to address the root problem not the state question to the letter. Have you looked at all of the options for reducing memory?

  1. For example, how are you caching?
  2. Are you using a Fly Weight pattern to reduce storage of duplicate numbers?
  3. Have you considered representing common numbers in a certain way?
    Example zero is a constant, ZERO.
  4. How about some sort of digit range compression, or hierarchy of digits, for example a hash map by major digits? Store a 32 bit within flag or multiple of some kind
  5. Hints at a cool difference approach, http://citeseerx.ist.psu.edu/viewdoc/summary?doi=10.1.1.65.2643
  6. Is your run of the mill cache doing something less efficient?
  7. Pointers are not free, thought about array groups? depending on your problem.
  8. Are you storing objects in the cache as well, they are not small, you can serialize them to structs etc, as well.

Look at the storage problem and stop looking to avoid a potential math issue. Typically there is a lot of excess in Java before you have to worry about digits. Even some you can work around them with the ideas above.

2
  • Thanks for your answer Ted. Wasn't expecting that but that's very clever. Actually yes on our cache we have different kind of optimization, including compression and using a pool of shared value. We are storing very few object and for example we use Trove for having collection of primitive. To be honest, now we are not looking at it anymore since we now have reached what we needed.
    – tibo
    Nov 14, 2013 at 13:57
  • Thanks for taking it in the spirit in which it was offered. Cheers. Nov 15, 2013 at 7:24
-1

You cannot trust doubles in financial software. They may work great in simple cases, but due to rounding, inaccuracy in presenting certain values etc. you will run into problems.

You have no choice but to use BigDecimal. Otherwise you're saying "I'm writing financial code which almost works. You'll barely notice any discrepancies." and that's not something that'll make you look trustworthy.

Fixed point works in certain cases, but can you be sure that 1 cent accuracy is enough now and in the future?

5
  • In my case inaccuracy is acceptable but that's not the point. I am trying to find out the limit of double and at what point in time this inaccuracy becomes visible
    – tibo
    Nov 14, 2013 at 13:12
  • 3
    @tibo The answer is: it depends. You can't rely on double being accurate to a certain point. If you're doing a lot of multiplication and division, eventually you'll come up with wrong numbers. Then you'll have to hope your customers don't notice it.
    – Kayaman
    Nov 14, 2013 at 13:19
  • 1
    I think you missed my point. I know that you have to deal with inaccuracy. That the same for BigDecimal, e.g. you can't represent 1/3 and you will also come up with wrong number as you said. Everything is about handling inaccuracy. BigDecimal have MathContext while doubles have a default mechanism. I am really annoyed to see everyone thinking that BigDecimal is the silver bullet without going deeper. BigDecimal are great but there are different solution for different problem
    – tibo
    Nov 15, 2013 at 2:46
  • @tibo So far you haven't presented any different solutions. You've said "I don't want to use BigDecimal, but I want the features it offers". The difference between inaccuracy in BigDecimal and double, is that in BigDecimal you decide when to realize the inaccuracy (i.e. when the computations are complete), whereas in double you never know if the accuracy has already gone to hell and you're just making it worse.
    – Kayaman
    Nov 15, 2013 at 6:49
  • Besides, we know nothing of your solution. You could have a completely idiotic implementation in there, and instead of addressing the root cause, you're blaming BigDecimal. If you're making professional financial software, I can't believe you'd be running out of memory because of BigDecimals!
    – Kayaman
    Nov 15, 2013 at 6:52
-1

I hope you have read Joshua Bloch Java Puzzlers Traps Pitfalls. This is what he has said in the puzzle 2: Time for a change.

Binary floating-point is particularly ill-suited to monetary calculations, as it is impossible to represent 0.1— or any other negative power of 10— exactly as a finite-length binary fraction [EJ Item 31].

2
  • I like this explanation. It shows how it's not just about how many digits to represent but also that some rational decimal numbers are not expressible as any finite-length binary fraction
    – Ron
    Nov 14, 2013 at 13:10
  • I know that and I have read this answer a lot of times... I am trying to go beyond that
    – tibo
    Nov 14, 2013 at 13:26

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