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I want to perform some calculations and I want the result correct up to some decimal places, say 12. So I wrote a sample:

#define PI 3.1415926535897932384626433832795028841971693993751
double d, k, h;
k = 999999/(2*PI);
h = 999999;
d = PI*k*k*h;
printf("%.12f\n", d);

But it gives the output:

79577232813771760.000000000000

I even used setprecision(), but same answer rather in exponential form.

cout<<setprecision(12)<<d<<endl;

prints

7.95772328138e+16

Used long double also, but in vain.

Now is there any way other than storing the integer part and the fractional part separately in long long int types?

If so, what can be done to get the answer precisely?

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4  
@EricLeschinski: An integer multiplied by a double results in a double. –  Benjamin Lindley Apr 10 '13 at 16:37
2  
may I suggest docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html –  rerun Apr 10 '13 at 16:37
2  
You got 16 decimal digits out of your number; you can't expect more out of a double. (Sometimes, you can get 17; after that, you get random values — or zeros.) Read the 'What Every Computer Scientist Should Know About Floating Point Arithmetic' paper — easily found on SO or the Internet. –  Jonathan Leffler Apr 10 '13 at 16:38
1  
A double can store about 16 decimal digits of precision and that appears to be roughly what you are getting? What are you expecting to get as your result? –  jcoder Apr 10 '13 at 16:38
3  
@Sunny: No, it need not. On some systems, long double is the same as double. –  Benjamin Lindley Apr 10 '13 at 16:41

5 Answers 5

A double has only about 16 decimal digits of precision. Everything after the decimal point would be nonsense. (In fact, the last digit or two left of the point may not agree with an infinite-precision calculation.)

Long double is not standardized, AFAIK. It may be that on your system it is the same as double, or no more precise. That would slightly surprise me, but it doesn't violate anything.

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So sir, what other options are left with me to obtain the exact result? –  Sunny Apr 10 '13 at 16:41
    
Just in the interest of being a purist from my old University Physics days, I would add that the "999999" values with no declaration of decimals after it, implies he shouldn't be looking for more than six figures of precision in his answer. But that's splitting hairs. The fact remains, he's asking for more precision than a double can offer him. –  K Scott Piel Apr 10 '13 at 16:41
    
There are several libraries set up for extra-precision arithmetic. Another answer mentions Gnu Multiprecision (GMP) library[http://gmplib.org/]. You should realize few real-world engineering applications will have any meaning to a 17th decimal place. You might share with us what you are trying to do, if it isn’t an arbitrary exercise. –  Andrew Lazarus Apr 10 '13 at 16:47
    
@AndrewLazarus I don't want to use an external library for that. I want my code to be standard. This being a part of a problem in a contest, I cant use a library other than standard anyway. –  Sunny Apr 10 '13 at 16:48
    
@Sunny: Then you'll have to code your own number class that supports higher precision, because the standard does not support it. –  Benjamin Lindley Apr 10 '13 at 16:52

You need to read Double-Precision concepts again; more carefully.

The double has increased precision by using 64 bits.
Stuff before the decimal is more important than that after it.
So, when you have a large integer part, it will truncate the lower precision -- this is being described to you in various answers here as rounding off.


Update:
To increase precision, you'll need to use some library or change your language.
Check this other question: Best coding language for dealing with large numbers (50000+ digits)

Yet, I'll ask you to re-check your intent once more.

  • Do you really need 12 decimal places for numbers that have really high values
    (over 10 digits in the integer part like in your example)?
  • Maybe you won't really have large integer parts
    (in which case such code should work fine).
  • But if you are tracking a value like 10000000000.123456789,
    I am really interested in exactly which application you are working on (astronomy?).
  • If the integer part of your values is some way under 10000, you should be fine here.

Update2:
IF you must demonstrate the ability of a specific formula to work accurately within constrained error limits, the way to go is fixing the processing of your formula such that the least error is introduced.

Example,

  • If you want to do say, (x * y) / z
  • it would be prudent to try something like max(x,y)/z * min(x,y)
  • rather than, the original form which may overflow after (x * y), loosing precision if that did not fit in the 16 decimals of double

If you had just 2 digit precision,

.               2-digit       regular-precision
 `42 * 7        290           297
 (42 * 7)/2     290/2         294/2
 Result ==>     145           147

       But ==>  42/2 = 21
                21 * 7 = 147

This is probably the intent of your contest.

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That explains the behavior of all zeroes, but I am still clueless on the other part of the question, how to still get the result? –  Sunny Apr 10 '13 at 16:47
    
As I commented somewhere, that this being a part of a problem from a contest, my answer A(correct output B) will be considered as correct if and only if |A − B| ≤ 10^-11 * B –  Sunny Apr 10 '13 at 17:20
    
That was a great hint. Let me try more and then I will inform you back . Thanks a lot. –  Sunny Apr 10 '13 at 17:32

The double-precision binary format used by most computers can only hold about 16 digits, after that you'll get rounding. See http://en.wikipedia.org/wiki/Double-precision_floating-point_format

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Floating point values have a limit range of digits. Just because your "PI" value has six times as many digits as a double will support doesn't alter the way the hardware works.

A typical (IEEE754) double will produce approximately 15-16 decimal places. Whether that's 0.12345678901235, 1234567.8901235, 12345678901235 or 12345678901235000000000, or some other variation.

In other words, yes, if you calculate your calculation EXACTLY, you'll get lots of decimal places, because pi never ends. On a computer, you get about 15-16 digits, no matter what input values you use - all that changes is where in that sequence the decimal place sits. To get more, you need "big number support", such as the Gnu Multiprcession (GMP) library.

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You're looking for std::fixed. That tells the ostream not to use exponential form.

cout << setprecision(12) << std::fixed << d << endl;
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I tried, this does not work at all. same output as using printf. –  taocp Apr 10 '13 at 16:39
    
@tacp Ah, you want 12 decimal places past the "ones position" - not 12 decimal places total. See the other answers then. They're good. –  Drew Dormann Apr 10 '13 at 16:41

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