# How scanf() handles floating point precision formats?

Below is an excerpt from a program -

``````float val=214.20;
double val1=214.20;

printf("\n\n\nfloat :: %f,  %4.6f, %4.2f \n ",val,val,val);
printf("double:: %f,  %4.6f, %4.2f \n ",val1,val1,val1);
``````

And the output is -

``````float :: 214.199997,  214.199997, 214.20<--- is the correct value as we wanted
double:: 214.200000,  214.200000, 214.20
``````

I understand that 214.20 has infinite binary representation. The first two elements of first line has approximation of the intended value, but the last value has absolutely same data. This caused a question in my mind -

How the scanf/fscanf/sprintf functions treat the precision formats ??

With no precision provided it printed an approximate value, but with `%4.2f` it gave correct result. Can some friend may explain me the algorithm used by scanf when handling precisions.

Thanks, Ripunjay

-

The thing is, 214.20 cannot be expressed exactly with binary representation. Few decimal numbers can. So an approximation is stored. Now when you use printf, the binary representation is turned into a decimal representation, but it again cannot be expressed exactly and is only approximated.

As you noticed, you can give a precision to printf to tell it how to round the decimal approximation. And if you don't give it a precision then a precision of 6 is assumed (see the man page for details).

If you use `%.40f` for the float and `%.40lf` for the double in your example above, you will get these results:

``````214.1999969482421875000000000000000000000000
214.1999999999999886313162278383970260620117
``````

They are different because with double, there are more bits to better approximate 214.20. But as you can see, they are still very odd when represented in decimal.

I recommend to read the Wikipedia article on floating point numbers for more insights about how floating point numbers work. An excellent read is also What Every Computer Scientist Should Know About Floating-Point Arithmetic

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Thanks for answering, though my question still is at same place. In the first place itself the float could NOT contain the exact value of 214.20, then how could it regain it ONLY with %4.2f precision, and NOT with %4.6f. What did it do to regain the value. I understand that approximation is done, but WHAT WAS THE BIT PATTERN USED THAT CAUSED INTERNALLY STORED 214.199997 TO BECOME 214.20 AND HOW DID WE ARRIVED AT THAT? –  RIPUNJAY TRIPATHI Sep 24 '10 at 19:33
Not sure I get you, but that's just the rounding. It's pure chance that `%4.2f` gives you exactly the value that you wanted. It's still "wrong" since the binary representation is not equivalent to 214.20 but to 214.1999969482421875. Now, if you round "214.1999969482421875" to 6 digits, you get "214.199997" because the 7th digit is a 9, turning the 6 into a 7. But when you only round to 2 digits, you get "214.20" because the 3rd digit is a nine, so you need to increase the 9 on the 2nd digit. That "overflows" to 10, turning the ".19" into ".20". –  DarkDust Sep 24 '10 at 19:41
Oh!! I believe you are trying to say that this operation is done in decimal representation, and that's how 214.199997 was formed as a round effect of double precision. Because had it been in binary representation we already confirmed that 214.20 is NOT representable in binary, with all rounding skills used. –  RIPUNJAY TRIPATHI Sep 24 '10 at 19:50
Yes, that's what I wanted to say :-) –  DarkDust Sep 24 '10 at 20:04

Since you asked about `scanf`, one thing you should note is that POSIX requires `printf` and a subsequent `scanf` (or `strtod`) to reconstruct the original value exactly as long as sufficiently significant digits (at least `DECIMAL_DIG`, I believe) were printed. Plain C of course makes no such requirement; the C standard pretty much allows floating point operations to give whatever result the implementor likes as long as they document it. However, if your intent is to store floating point numbers in text files to be read back later, you might be better off using the C99 `%a` specifier to print them in hex. This way they'll be exact and there's no confusion about whether the serialize/deserialize process loses precision.

Keep in mind thatr when I said "reconstruct the original value", I mean the actual value which was held in the variable/expression passed to `printf`, not the original decimal you wrote in the source file which got rounded to the best binary representation by the compiler.

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`scanf` will round the input value to the nearest exactly representable floating point value. As DarkDust's answer illustrates, in single precision the closest exactly representable value is below the exact value, and in double precision the closest exactly representable value is above the exact value.