# How can 8 bytes hold 302 decimal digits? (Euler challenge 16)

c++ pow(2,1000) is normaly to big for double, but it's working. why?

So I've been learning C++ for couple weeks but the datatypes are still confusing me.

One small minor thing first: the code that 0xbadc0de posted in the other thread is not working for me. First of all `pow(2,1000)` gives me `this more than once instance of overloaded function "pow" matches the argument list.`

I fixed it by changing `pow(2,1000)` -> `pow(2.0,1000)` Seems fine, i run it and get this:

http://i.stack.imgur.com/bbRat.png

``````10715086071862673209484250490600018105614048117055336074437503883703510511249361224931983788156958581275946729175531468251871452856923140435984577574698574803934567774824230985421074605062371141877954182153046474983581941267398767559165543946077062914571196477686542167660429831652624386837205668069376
``````

it is missing a lot of the values, what might be cause that?

But now for the real problem. I'm wondering how can 302 digits long number fit a double (8 bytes)? 0xFFFFFFFFFFFFFFFF = 18446744073709551616 so how can the number be larger than that?

I think it has something to do with the floating point number encoding stuff. Also what is the largest number that can possibly be stored in 8 bytes if it's not 0xFFFFFFFFFFFFFFFF?

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`so how can the number be larger than that?` Have 302 decimal digits of zero. Problem solved. – PreferenceBean Jan 28 '13 at 16:59
A byte is usually 8 bits. Thus one byte is 0xFF. Thus 8 bytes is `0xFFFFFFFFFFFFFFFF` or max of: 18446744073709600000 (though it looks like my calculator rounded that). How you get a 302 digit number in 64 bits is another question (compression)? Some trick. – Loki Astari Jan 28 '13 at 17:06
Its the difference between floating types and integer types. A floating numeric will store a limited representation of an exponential mantissa along with an exponent. The exponent can tell a print function essentially how many zeros to add after the decimal representation of a mantissa. Essentially it will give you for the pow inputs you are giving, a rounded version of the output which is why you see 17 meaningful digits then a whole buncha 0s. – trumpetlicks Jan 28 '13 at 17:08
Here's the wikipedia entry for Floating Point numbers: en.wikipedia.org/wiki/Floating_point In particular interest to you should be the section covering IEEE 754, which is the standard that C++ (and most other programming languages) adhere to where floating point numbers are concerned. – user420442 Jan 28 '13 at 17:12
Hmm.. I think i got the floating point part, but the long number still has 301 digits of precision, not just 0's, so how do you fit 301 digits in the 52bit mantissa? – Ollie Jan 28 '13 at 17:31

Eight bytes contain 64 bits of information, so you can store `2^64 ~ 10^20` unique items using those bits. Those items can easily be interpreted as the integers from `0` to `2^64 - 1`. So you cannot store 302 decimal digits in 8 bytes; most numbers between `0` and `10^303 - 1` cannot be so represented.

Floating point numbers can hold approximations to numbers with 302 decimal digits; this is because they store the mantissa and exponent separately. Numbers in this representation store a certain number of significant digits (15-16 for doubles, if I recall correctly) and an exponent (which can go into the hundreds, of memory serves). However, if a decimal is X bytes long, then it can only distinguish between `2^(8X)` different values... unlikely enough for exactly representing integers with 302 decimal digits.

To represent such numbers, you must use many more bits: about 1000, actually, or 125 bytes.

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Probably would need 1001 bits to represent, as the least sig bit is the 2^0 bit. – trumpetlicks Jan 28 '13 at 17:23

It's called 'floating point' for a reason. The datatype contains a number in the standard sense, and an exponent which says where the decimal point belongs. That's why `pow(2.0, 1000)` works, and it's why you see a lot of zeroes. A floating point (or double, which is just a bigger floating point) number contains a fixed number of digits of precision. All the remaining digits end up being zero. Try `pow(2.0, -1000)` and you'll see the same situation in reverse.

The number of decimal digits of precision in a float (32 bits) is about 7, and for a double (64 bits) it's about 16 decimal digits.

Most systems nowadays use IEEE floating point, and I just linked to a really good description of it. Also, the article on the specific standard IEEE 754-1985 gives a detailed description of the bit layouts of various sizes of floating point number.

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exactly what i wanted to write. about computing the answer: you can use decimal arithmetic of some standard implementation for computing with big numbers, like BigInteger in java – edofic Jan 28 '13 at 17:07

2.0 ^ 1000 mathematically will have a decimal (non-floating) output. IEEE floating point numbers, and in your case doubles (as the pow function takes in doubles and outputs a double) have 52 bits of the 64 bit representation allocated to the mantissa. If you do the math, 2^52 = 4,503,599,627,370,496. Because a floating point number can represent positive and negative numbers, really the integer representation will be ~ 2^51 = 2,251,799,813,685,248. Notice there are 16 digits. there are 16 quality (non-zero) digits in the output you see.

Essentially the pow function is going to perform the exponentiation, but once the exponentiation moves past ~2^51, it is going to begin losing precision. Ultimately it will hold precision for the top ~16 decimal digits, but all other digits right will be un-guaranteed.

Thus it is a floating point precision / rounding problem.

If you were strictly in unsigned integer land, the number would overflow after (2^64 - 1) = 18,446,744,073,709,551,616. What overflowing means, is that you would never actually see the number go ANY HIGHER than the one provided, infact I beleive the answer would be 0 from this operation. Once the answer goes beyond 2^64, the result register would be zero, and any multiply afterwords would be 0 * 2, which would always result in 0. I would have to try it.

The exact answer (as you show) can be obtained using a standard computer using a multi-precision libary. What these do is to emulate a larger bit computer by concatenating multiple of the smaller data types, and use algorithms to convert and print on the fly. Mathematica is one example of a math engine that implements an arbitrary precision math calculation library.

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Floating point types can cover a much larger range than integer types of the same size, but with less precision.

They represent a number as:

• a sign bit `s` to indicate positive or negative;
• a mantissa `m`, a value between 1 and 2, giving a certain number of bits of precision;
• an exponent `e` to indicate the scale of the number.

The value itself is calculated as `m * pow(2,e)`, negated if the sign bit is set.

A standard `double` has a 53-bit mantissa, which gives about 16 decimal digits of precision.

So, if you need to represent an integer with more than (say) 64 bits of precision, then neither a 64-bit integer nor a 64-bit floating-point type will work. You will need either a large integer type, with as many bits as necessary to represent the values you're using, or (depending on the problem you're solving) some other representation such as a prime factorisation. No such type is available in standard C++, so you'll need to make your own.

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If you want to calculate the range of the digits that can be hold by some bytes, it should be (2^(64bits - 1bit)) to (2^(64bits - 1bit) - 1).

Because the left most digit of the variable is for representing sign (+ and -). So the range for negative side of the number should be : (2^(64bits - 1bit)) and the range for positive side of the number should be : (2^(64bits - 1bit) - 1) there is -1 for the positive range because of 0(to avoid reputation of counting 0 for each side).

For example if we are calculating 64bits, the range should be ==> approximately [-9.223372e+18] to [9.223372e+18]

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