8

I have discovered an inconsistency for uint64 when using vectors in Matlab. It seems as an array of uint64 is not exact for all 64 bits. This did not give the output I expected,

p=uint64([0;0]);
p(1)=13286492335502040542
p =
 13286492335502041088
                    0

However

q = uint64(13286492335502040542)
q =
 13286492335502040542

does. It is also working with

p(1)=uint64(13286492335502040542)
p =
 13286492335502040542
                    0

Working with unsigned integers one expect a special behaviour and usually also perfect precision. This seems weird and even a bit uncanny. I do not see this problem with smaller numbers. Maybe anyone knows more? I do not expect this to be an unknown problem, so I guess there must be some explanation to it. I would be good to know why this happen and when, to be able to avoid it. As usual this kind of issues is mentioned nowhere in the documentation.

Matlab 2014a, windows 7.

EDIT

It is worth mentioning that I can see the same behaviour when defining arrays directly.

p=uint64([13286492335502040542;13286492335502040543])
p =
 13286492335502041088
 13286492335502041088

This is the root to why I ask this question. I have hard to see workaround for this case.

10

While it might be surprising, this is a floating point precision issue. :-)

The thing is, all numeric literals are by default of type double in MATLAB; that's why:

13286492335502040542 == 13286492335502041088

will return true; the floating point representation in double precision of 13286492335502040542 is 13286492335502041088. Since p has the class uint64, all assignments done to it will cast the right-hand-side to its class.

On another hand, the uint64(13286492335502040542) "call" will be optimized by the MATLAB interpreter to avoid the overhead of calling the uint64 function for the double argument, and will convert the literal directly to its unsigned integer representation (which is exact).

On a third hand [sic], the function call optimization doesn't apply to

p = uint64([13286492335502040542;13286492335502040543])

because the argument of uint64 is not a literal, but the result of an expression, i.e. the result of the vertcat operator applied to two double operands. In this case the MATLAB interpreter is not smart enough to figure out that the two function calls should "commute" (concatenation of uint should be the same as uint of concatenation), so it evaluates the concatenation (which gives an array of equal double because FP precision), then converts the two similar double values to uint64.

TLDR: the difference between

p = uint64(13286492335502040542);

and

u = 13286492335502040542; p = uint64(u);

is a side effect of function call optimization.

7

Matlab, unless told otherwise reads numbers as double, then casts to the relevant datatype. The Matlab double datatype allows for 51 bits for the floating point fraction, giving the possibility to store 52 bit integers without loss of prepossession (mantissa). Notice that 13286492335502041088 is just 13286492335502040543 with the last 12 bits set to zero.

the solution as you said, is to convert the literals directly uint64(13286492335502040543).

p=uint64([13286492335502040542;13286492335502040543]) does not work because it creates a double array and then converts it to uint64

This issue is mentioned in the uint64 documentation, under 'More About', although it doesn't mention that laterals are read as doubles unless otherwise specified.

  • I understand, for some reason I thought matlabs JIT compiler was smarter than this (like understanding that I want an array of uint64). I guess that matlab does not really handle uint64 then. The options of downcasting from double (which IMO is ugly), or adding values one-by-one is definitely not sufficient :(. Do you know any workaround for this problem? – patrik Jan 4 '16 at 13:52
  • 2
    Matlab supports uint64 just fine, you generally don't add data hard coded as literals in your code, if you read from a file, there are ways to read directly into uint64. – pseudoDust Jan 4 '16 at 14:02
0

I agree this seems weird and I don't have an explanation. I do have a workaround:

p=[uint64(13286492335502040542);uint64(13286492335502040543)]

i.e., cast the separate values to uint64s.

  • Well, that is true, but this is typically something which must be done by hand. Thus it cannot be seen as a proper workaround in my eyes. Thanks anyway. – patrik Jan 4 '16 at 13:45
  • 1
    If you are typing in the numbers by hand, it doesn't seem a stretch to add the uint64(...), for any other method of data input there are other ways... – pseudoDust Jan 4 '16 at 13:51

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