# Why dividing a float by a power of 10 is less accurate than typing the number directly?

When I run

``````printf("%.8f\n", 971090899.9008999);
printf("%.8f\n", 9710908999008999.0 / 10000000.0);
``````

I get

``````971090899.90089989
971090899.90089977
``````

I know why neither is exact, but what I don't understand is why doesn't the second match the first?
I thought basic arithmetic operations (+ - * /) were always as accurate as possible...
Isn't the first number a more accurate result of the division than the second?

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Erm. How is this not a dupe of our (many) floating point faq items? (In short: it's not decimal arithmetic. Not even at compiletime) – sehe Feb 1 '14 at 1:46
@hmartinezd completely missing the point of float inexact representations. Also, the constant expression is double, not float. – sehe Feb 1 '14 at 1:49
@Mehrdad: 9710908999008999.0 rounds to 9710908999009000, not 9710908999008998. – Eric Postpischil Feb 1 '14 at 2:55
@Mehrdad: The C implementation you are using is deficient. Obviously, 9710908999008998 and 9710908999009000 are equidistant from 9710908999008999 (and both are representable in `double`). Their significands are 0x1.1400298aa8173 and 0x1.1400298aa8174. The IEEE-754 rules for rounding equidistant values in the common round-to-nearest mode say to round to an even low bit. Thus, 9710908999009000 is correct. – Eric Postpischil Feb 1 '14 at 3:43

Judging from the numbers you're using and based on the standard IEEE 754 floating point standard, it seems the left hand side of the division is too large to be completely encompassed in the mantissa (significand) of a 64-bit double.

You've got 52 bits worth of pure integer representation before you start bleeding precision. `9710908999008999` has ~54 bits in its representation, so it does not fit properly -- thus, the truncation and approximation begins and your end numbers get all finagled.

EDIT: As was pointed out, the first number that has no mathematical operations done on it doesn't fit either. But, since you're doing extra math on the second one, you're introducing extra rounding errors not present with the first number. So you'll have to take that into consideration too!

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If you drop the rambling last paragraph, you'll have my upvote. The compiler is required to simply do the float math in the same domain. Doesn't have to do with runtime (also: that would be horrific if true :)) – sehe Feb 1 '14 at 2:01
@sehe Fine, fine. :c – user3010322 Feb 1 '14 at 2:01
Ooooh I totally missed that the number on the left was rounded to `9710908999008998.0`... that makes sense, thanks! – Mehrdad Feb 1 '14 at 2:02
971090899.9008999 does not fit in a `double` significand either. Both 9710908999008999 and 971090899.9008999 are rounded by conversion to `double`; this answer does not explain why the rounding of one (followed by division by 10000000.0) produces a different result from the rounding of the other. – Eric Postpischil Feb 1 '14 at 2:53
@ThePhD Minor: I'd say 53 bits integer (not counting another 1 for the sign) with IEEE 754. Still 9710908999008999 needs 54 bits – chux Feb 1 '14 at 3:08

Evaluating the expression `971090899.9008999` involves one operation, a conversion from decimal to the floating-point format.

Evaluating the expression `9710908999008999.0 / 10000000.0` involves three operations:

• Converting `9710908999008999.0` from decimal to the floating-point format.
• Converting `10000000.0` from decimal to the floating-point format.
• Dividing the results of the above operations.

The second of those should be exact in any good C implementation, because the result is exactly representable. However, the other two add rounding errors.

C does not require implementations to convert decimal to floating-point as accurately as possible; it allows some slack. However, a good implementation does convert accurately, using extra precision if necessary. Thus, the single operation on `971090899.9008999` produces a more accurate result than the multiple operations.

Additionally, as we learn from a comment, the C implementation used by the OP converts `9710908999008999.0` to 9710908999008998. This is incorrect by the rules of IEEE-754 for the common round-to-nearest mode. The correct result is 9710908999009000. Both of these candidates are representable in IEEE-754 64-bit binary, and both are equidistant from the source value, 9710908999008999. The usual rounding mode is round-to-nearest, ties-to-even, meaning the candidate with the even low bit should be selected, which is 9710908999009000 (with significand 0x1.1400298aa8174), not 9710908999008998 (with significand 0x1.1400298aa8173). (IEEE 754 defines another round-to-nearest mode: ties-to-away, which selects the candidate with the larger magnitude, which is again 9710908999009000.)

The C standard permits some slack in conversions; either of these two candidates conforms to the C standard, but good implementations also conform to IEEE 754.

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