# Why does (int)(33.46639 * 1000000) return 33466389?

(int)(33.46639 * 1000000) returns 33466389

Why does this happen?

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What do you expect to happen? –  SLaks Mar 11 '10 at 1:54
You have an extra zero. –  SLaks Mar 11 '10 at 1:57
@Reverend Gonzo: don't you mean "33466390"? –  Pwninstein Mar 11 '10 at 2:01
it would help if you told us what language you were using. you probably are using a language that treats 33.46639 as a floating point type, not as a decimal type. –  Peter Recore Mar 11 '10 at 3:22
@Peter, somebody removed the c# tag, don't know why. –  jfar Mar 11 '10 at 14:47

Floating point math isn't perfect. What every programmer should know about it.

Floating-point arithmetic is considered an esoteric subject by many people. This is rather surprising because floating-point is ubiquitous in computer systems. Almost every language has a floating-point datatype; computers from PCs to supercomputers have floating-point accelerators; most compilers will be called upon to compile floating-point algorithms from time to time; and virtually every operating system must respond to floating-point exceptions such as overflow. This paper presents a tutorial on those aspects of floating-point that have a direct impact on designers of computer systems. It begins with background on floating-point representation and rounding error, continues with a discussion of the IEEE floating-point standard, and concludes with numerous examples of how computer builders can better support floating-point.

...

Squeezing infinitely many real numbers into a finite number of bits requires an approximate representation. Although there are infinitely many integers, in most programs the result of integer computations can be stored in 32 bits. In contrast, given any fixed number of bits, most calculations with real numbers will produce quantities that cannot be exactly represented using that many bits. Therefore the result of a floating-point calculation must often be rounded in order to fit back into its finite representation. This rounding error is the characteristic feature of floating-point computation.

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It's true that floating-point arithmetic is both ubiquitous and complicated, but this doesn't answer the question (unless you count linking to an 80-page paper that has the answer somewhere). –  Henry Jackson Mar 11 '10 at 2:00
@Henry - the point is in the title of the linked article. Every programmer should know about this, and if they don't they should read the article. (OK, maybe not all 80 pages ...) –  Stephen C Mar 11 '10 at 2:16
+1: linking to an 80-page paper that has the answer somewhere is a the standard anwser. This question -- in one form or another -- gets asked way too frequently. This paper is the answer. The questions are all duplicates. We don't need to repeat this information again and again. –  S.Lott Mar 11 '10 at 2:25
+1 I agree @S.Lott, The link to that article is THE answer. –  Pwninstein Mar 11 '10 at 2:37

Double precision is not exact, so internally 33.46639 is actually stored as 33.466389

Edit: As Richard said, it's floating point data, (stored in binary in a finite set of bits) so it's not exactly that) ....

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or 33.4668885 or something else 'close enough' that rounds to it, depending on the hardware. –  DaveE Mar 11 '10 at 1:57
Um, none of the above. It's in base 2. Most such numbers CANNOT be expressed exactly in base 10. (Without resorting using infinitely-repeating digit sequences, anyway. Similar to how 1/3 must be represented as 0.33333[inf] in base 10.) –  Richard Berg Mar 11 '10 at 2:02
@Richard: Wrong. Any base 2 number can be expressed exactly as a non-repeating decimal in base ten. (Because ten is a multiple of two) –  SLaks Mar 11 '10 at 2:06
FWIW, it's exactly 33.46638999999999697365637985058128833770751953125. –  Stephen Canon Mar 11 '10 at 2:21
@Richard Berg: Most real numbers cannot be expressed in floating point. All numbers that can be expressed exactly with N bits to the right of the decimal (binary?) point can be expressed exactly with N digits to the right of the decimal point. –  David Thornley Mar 11 '10 at 15:35

It was New Years' Eve at the end of 1994. Andy Grove, CEO of Intel, was coming off a great year, what with the Pentium processor coming out and being a big hit. So, he walked into a bar and ordered a double shot of Johnnie Walker Green Label.

The bartender served it up and said, "that will be \$20, sir."

Grove put a twenty dollar bill on the counter, looked at it for a moment, and said, "keep the change."

http://en.wikipedia.org/wiki/Pentium_FDIV_bug

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But... that's an integer... –  Rawling Jun 11 at 8:37

The reason is that 33.46639 will be represented as something slightly less than that number.

Multiplying by 1000000 will give you 33466389.99999999.

Type-casting using (int) will then just return the integer part (33466389).

If you want the "right" number, try round() before type casting.

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Whoa! ..... no no no no no. If you want the "right" answer, you can't use floating point arithmetic. –  Reverend Gonzo Mar 11 '10 at 2:08
No. If you want the "right" answer, you can't use binary floating point arithmetic. Use the decimal type which uses decimal floating point arithmetic and it will work as you expect. –  Gabe Mar 11 '10 at 2:13
33.46639 is the "right" answer. The problem is that the questioner isn't asking the right question. –  Stephen Canon Mar 11 '10 at 2:21
@gabe: I was assuming C, not C#. It's not clear from the question. –  Peter K. Mar 11 '10 at 3:14
decimal type also has problems, albeit for other numbers. Any number system with a fixed number of "bits" can only represent a finite set of numbers, and there are infinitely many real numbers between any two numbers. –  Alok Singhal Mar 11 '10 at 3:19

If you're asking why it doesn't become 33466390, it's because doubles do not have infinite precision, and the number cannot be expressed exactly in binary.

If you replace the double with a decimal ((int)(33.46639m * 1000000)), it be equal to 33466390, because decimals are calculated in base 10.

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Problems like these are inherent in floating-point, not just binary floating point. Sure, decimal gets 33.46639*1000000 right, but still has 1/3*3 != 1 and pow(sqrt(2), 2) != 2. –  dan04 Mar 11 '10 at 2:33
Yes, but his specific problem is due to binary. –  SLaks Mar 11 '10 at 2:40

Because 33.46639 can't be expressed exactly in a finite number of binary digits. The actual result of 33.46639 * 1000000 is 33466389.9999999962747097015380859375. The cast truncates it to 33466389.

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Try "can't be expressed exactly in a finite number of fractional binary digits" –  Ben Voigt Mar 11 '10 at 7:15

The reason you got a different result is the fact that you used a 'cast'

(int)(33.46639 * 1000000) returns 33466389
^^^^^


to cast the result to a type of 'int'... which either rounded up or down the integral type when multipled together and then converted to 'int'.... do not rely on floating point to be accurate enough....Skeet posted an excellent introduction on his site here and here...

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There's nothing inherently lossy about a cast. Arbitrary-precision libraries exist. –  Richard Berg Mar 11 '10 at 1:57
I'd imagine he's asking "where did the 8 come from in my result?" Multiplying by 1000000 is like moving the decimal 6 places to the right, which should be "33466390", but that's not what he's getting. Your answer is what I thought initially though, until I read the question again. –  Pwninstein Mar 11 '10 at 1:59
@Richard - coercing a float or double value to an int discards the fractional part, so you do lose information. –  Seth Mar 11 '10 at 2:32
Seth, that's correct. What I'm saying is, truncation is a particular feature of float/double (via the CLI spec). It's not inherent to the C# cast operator, as Tommie seemed to imply. –  Richard Berg Mar 11 '10 at 15:12