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I am trying to understand roundoff error for basic arithmetic operations in MATLAB and I came across the following curious example.

(0.3)^3 == (0.3)*(0.3)*(0.3)

ans = 0

I'd like to know exactly how the left-hand side is computed. MATLAB documentation suggests that for integer powers an 'exponentiation by squaring' algorithm is used.

"Matrix power. X^p is X to the power p, if p is a scalar. If p is an integer, the power is computed by repeated squaring."

So I assumed (0.3)^3 and (0.3)*(0.3)^2 would return the same value. But this is not the case. How do I explain the difference in roundoff error?

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Please show us where you read that "for integer powers an 'exponentiation by squaring' algorithm is used". I can't find this by a Google search and if it's not the case, then the question is trivial. –  s.bandara Jan 23 '13 at 0:41
In practice you shouldn't compare floating point values with == (this is true whether you're using matlab or anything else), but rather use something more like [abs(#1 - #2) < epsilon]. If you subtract them (at least on my machine), the difference is -3.4694e-18 –  alrikai Jan 23 '13 at 0:41
@StephenCanon on my machine (0.3)^2 == (0.3)*(0.3) returns 1, as does (0.3)^4 == (0.3)*(0.3)*(0.3)*(0.3), while the other combinations don't. –  alrikai Jan 23 '13 at 0:45
@Dougal: You are right, I had them swapped. .3*.3*.3 yields 0.0269999999999999996946886682280819513835012912750244140625 and is closer to the exact result. pow(.3, 3) yields 0.0269999999999999962252417162744677625596523284912109375. Time to get some sleep. –  Eric Postpischil Jan 23 '13 at 3:46
@RudyOldenhuis: The advice not to use == with floating point is naïve and is not applicable to this question. –  Eric Postpischil Jan 23 '13 at 10:24

5 Answers 5

up vote 3 down vote accepted

Thanks to @Dougal I found this:

#include <stdio.h>
int main() {
  double x = 0.3;
  printf("%.40f\n", (x*x*x));

  long double y = 0.3;
  printf("%.40f\n", (double)(y*y*y));

which gives:


The case is strange because the computation with more digits gives a worst result. This is due to the fact that anyway the initial number 0.3 is approximated with few digits and hence we start with a relatively "large" error. In this particular case what happens is that the computation with few digits gives another "large" error but with opposite sign... hence compensating the initial one. Instead the computation with more digits gives a second smaller error but the first one remains.

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I got it! What happens is a strange case where the superposition of two larger errors with opposite sign give (by chance) a smaller error then the superposition of the same first error with a smaller second error but with same sign. –  Emanuele Paolini Jan 23 '13 at 6:26

I don't know anything about MATLAB, but I tried it in Ruby:

irb> 0.3 ** 3
  => 0.026999999999999996
irb> 0.3 * 0.3 * 0.3
  => 0.027

According to the Ruby source code, the exponentiation operator casts the right-hand operand to a float if the left-hand operand is a float, and then calls the standard C function pow(). The float variant of the pow() function must implement a more complex algorithm for handling non-integer exponents, which would use operations that result in roundoff error. Maybe MATLAB works similarly.

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The numbers look identical to those in Matlab and Python (on my 64-bit OS X machine), and I just tracked down that Python also calls pow(). So now we just need to look at the source of pow().... –  Dougal Jan 23 '13 at 0:52
Okay, with a little digging I found this implementation of __ieee754_powf (which is not the one used on any of our systems but might use the same algorithm), and the actual one used in OSX from this directory (filename Source/Intel/powf.s, at least in Libm-315; I don't know which version is used on which OSX). I might look into the actual algorithm later, though it's not especially readable to me.... –  Dougal Jan 23 '13 at 1:14
@Dougal: That is an old version of OSX Libm, and that file is for the single-precision (float) powf. The double-precision (double) pow is in Intel/xmm_power.c. It has since been written in assembly quite nicely by Stephen Canon. And it will not tell us why Matlab is getting the results it is, since it is not the Matlab implementation. –  Eric Postpischil Jan 23 '13 at 1:26
@EricPostpischil It seems pretty likely that matlab is calling the system pow(), since it gets exactly the same results as python and ruby, or at least is using the same algorithm in this case. –  Dougal Jan 23 '13 at 1:27
@Dougal: Showing the same bug would be evidence of a common implementation. Showing the same accurate result is merely evidence of good programming. –  Eric Postpischil Jan 23 '13 at 1:35

Interestingly, scalar ^ seems to be implemented using pow while matrix ^ is implemented using square-and-multiply. To wit:

octave:13> format hex
octave:14> 0.3^3
ans = 3f9ba5e353f7ced8
octave:15> 0.3*0.3*0.3
ans = 3f9ba5e353f7ced9
octave:20> [0.3 0;0 0.3]^3
ans =

  3f9ba5e353f7ced9  0000000000000000
  0000000000000000  3f9ba5e353f7ced9

octave:21> [0.3 0;0 0.3] * [0.3 0;0 0.3] * [0.3 0;0 0.3]
ans =

  3f9ba5e353f7ced9  0000000000000000
  0000000000000000  3f9ba5e353f7ced9

This is confirmed by running octave under gdb and setting a breakpoint in pow.

The same is likely true in matlab, but I can't really verify.

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Same results in matlab. It's not super surprising, though, that matrix ^ uses square-and-multiply; pow doesn't exactly work on matrix multiplication. Note also that .^ on matrices is (of course) the same as ^ on scalars. –  Dougal Jan 23 '13 at 5:28
It has been changed along matlab history, in on an old matlab 6.5.1, (0.3*([1 1;1 1])).^3 - 0.3^3 is not zero... So the of course should be moderated :) –  aka.nice Jan 23 '13 at 14:56

Here's a little test program that follows what the system pow() from Source/Intel/xmm_power.c, in Apple's Libm-2026, does in this case:

#include <stdio.h>
int main() {
    // basically lines 1130-1157 of xmm_power.c, modified a bit to remove
    // irrelevant things

    double x = .3;
    int i = 3;

    //calculate ix = f**i
    long double ix = 1.0, lx = (long double) x;

    //calculate x**i by doing lots of multiplication
    int mask = 1;

    //for each of the bits set in i, multiply ix by x**(2**bit_position)
    while(i != 0)
        if( i & mask )
            ix *= lx;
            i -= mask;
        mask += mask;
        lx *= lx; // In double this might overflow spuriously, but not in long double

    printf("%.40f\n", (double) ix);

This prints out 0.0269999999999999962252417162744677625597, which agrees with the results I get for .3 ^ 3 in Matlab and .3 ** 3 in Python (and we know the latter just calls this code). By contrast, .3 * .3 * .3 for me gets 0.0269999999999999996946886682280819513835, which is the same thing that you get if you just ask to print out 0.027 to that many decimal places and so is presumably the closest double.

So there's the algorithm. We could track out exactly what value is set at each step, but it's not too surprising that it would round to a very slightly smaller number given a different algorithm for doing it.

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I don't understand... if you unroll the loop you see that the operation is simply 0.3 * 0.3 * 0.3 –  Emanuele Paolini Jan 23 '13 at 5:36

Read Goldberg's "What Every Computer Scientist Should Know About Floating-Point Arithmetic" (this is a reprint by Oracle). Do understand it. Floating point numbers are not the real numbers of calculus. Sorry, no TL;DR version available.

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That doesn't answer the question at all. –  s.bandara Jan 23 '13 at 0:37
You didn't read the question. –  Mysticial Jan 23 '13 at 0:37
the paper you suggest does not explain how 0.3**3 could be computed in a different way than 0.3*0.3*0.3 –  Emanuele Paolini Jan 23 '13 at 0:52
(0.3)^3 ~~-> pow(0.3, 3.0) != 0.3 * 0.3 * 0.3 –  vonbrand Jan 23 '13 at 0:57

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