# How do I print a double value with full precision using cout?

So I've gotten the answer to my last question (I don't know why I didn't think of that). I was printing a `double` using `cout` that got rounded when I wasn't expecting it. How can I make `cout` print a `double` using full precision?

You can set the precision directly on `std::cout` and use the `std::fixed` format specifier.

``````double d = 3.14159265358979;
cout.precision(17);
cout << "Pi: " << fixed << d << endl;
``````

You can `#include <limits>` to get the maximum precision of a float or double.

``````#include <limits>

typedef std::numeric_limits< double > dbl;

double d = 3.14159265358979;
cout.precision(dbl::max_digits10);
cout << "Pi: " << d << endl;
``````
• Why do you explicitly advise to use `fixed`? With `double h = 6.62606957e-34;`, `fixed` gives me `0.000000000000000` and `scientific` outputs `6.626069570000000e-34`. – Arthur Jan 9 '12 at 17:58
• The precision needs to be 17 (or std::numeric_limits<double>::digits10 + 2) because 2 extra digits are needed when converting from decimal back to the binary representation to ensure the value is rounded to the same original value. Here is a paper with some details: docs.oracle.com/cd/E19957-01/806-3568/ncg_goldberg.html – Mike Fisher Oct 28 '13 at 9:16
• Is the really the right answer? When I manually use a high number, I can print out as many as 51 digits of approximated e, but with `cout.precision(numeric_limits<double>::digits10 + 2);` I only get 16.... – Assimilater Sep 4 '14 at 22:07
• For those looking where it mentions 17 digits in the paper @MikeFisher cited, it's under Theorem 15. – Emile Cormier Jan 11 '15 at 21:23
• @MikeFisher You're right, C++11 introduces `max_digits10` to denote the same. Fixed the answer to reflect this. – legends2k Aug 24 '15 at 7:47
``````std::cout << std::setprecision (15) << 3.14159265358979 << std::endl;
``````
• Is there some kind of MAX_PRECISION macro or enum or something I can pass to std::setPrecision? – Jason Punyon Feb 16 '09 at 18:23
• std::setprecision(15) for a double (ok or 16), log_10(2**53) ~= 15.9 – user7116 Feb 16 '09 at 18:24
• std::setprecision(std::numeric_limits<double>::digits10) – Éric Malenfant Feb 16 '09 at 18:42
• Should be `std::setprecision (17)` for double, see comments on @Bill The Lizard's answer. – Alec Jacobson Dec 17 '15 at 14:45
• for std::setprecision to work, #include <iomanip> should be included. – user2262504 Jul 16 '16 at 8:34

Here is what I would use:

``````std::cout << std::setprecision (std::numeric_limits<double>::digits10 + 1)
<< 3.14159265358979
<< std::endl;
``````

Basically the limits package has traits for all the build in types.
One of the traits for floating point numbers (float/double/long double) is the digits10 attribute. This defines the accuracy (I forget the exact terminology) of a floating point number in base 10.

See: http://www.cplusplus.com/reference/std/limits/numeric_limits.html

• This header is needed to use `std::setprecision()`: `#include <iomanip>` – Martin Berger Aug 19 '11 at 15:26
• it should be `std::numeric_limits<double>` instead of `numberic_limits<double>` – niklasfi Apr 15 '14 at 14:00
• Why do you add `1` to `std::numeric_limits<double>::digits10`? – Alessandro Jacopson Oct 3 '14 at 11:40
• @LokiAstari You can use C+11's `max_digits10` instead. See this. – legends2k Aug 25 '15 at 9:04
• @AlecJacobson It should rather be `max_digits10`, not some arbitrary `digits10+2`. Otherwise, in the case of `float`, `long double`, `boost::multiprecision::float128` this will fail, since there you'd need `+3` instead of `+2`. – Ruslan May 27 at 17:41

The iostreams way is kind of clunky. I prefer using `boost::lexical_cast` because it calculates the right precision for me. And it's fast, too.

``````#include <string>
#include <boost/lexical_cast.hpp>

using boost::lexical_cast;
using std::string;

double d = 3.14159265358979;
cout << "Pi: " << lexical_cast<string>(d) << endl;
``````

Output:

Pi: 3.14159265358979

By full precision, I assume mean enough precision to show the best approximation to the intended value, but it should be pointed out that `double` is stored using base 2 representation and base 2 can't represent something as trivial as `1.1` exactly. The only way to get the full-full precision of the actual double (with NO ROUND OFF ERROR) is to print out the binary bits (or hex nybbles). One way of doing that is writing the `double` to a `union` and then printing out the integer value of the bits.

``````union {
double d;
uint64_t u64;
} x;
x.d = 1.1;
std::cout << std::hex << x.u64;
``````

This will give you the 100% accurate precision of the double... and be utterly unreadable because humans can't read IEEE double format ! Wikipedia has a good write up on how to interpret the binary bits.

In newer C++, you can do

``````std::cout << std::hexfloat << 1.1;
``````

Here is how to display a double with full precision:

``````double d = 100.0000000000005;
int precision = std::numeric_limits<double>::max_digits10;
std::cout << std::setprecision(precision) << d << std::endl;
``````

This displays:

100.0000000000005

max_digits10 is the number of digits that are necessary to uniquely represent all distinct double values. max_digits10 represents the number of digits before and after the decimal point.

Don't use set_precision(max_digits10) with std::fixed.
On fixed notation, set_precision() sets the number of digits only after the decimal point. This is incorrect as max_digits10 represents the number of digits before and after the decimal point.

``````double d = 100.0000000000005;
int precision = std::numeric_limits<double>::max_digits10;
std::cout << std::fixed << std::setprecision(precision) << d << std::endl;
``````

This displays incorrect result:

100.00000000000049738

``````#include <iomanip>
#include <limits>
``````
• This happens because `100.0000000000005` isn't being represented exactly as a `double`. (It might seem like it should, but it doesn't, because it gets normalised, i.e. its binary representation). To see this, try: `100.0000000000005 - 100`. We get `4.973799150320701e-13`. – Evgeni Sergeev Sep 8 '17 at 12:12

How do I print a `double` value with full precision using cout?

Use `hexfloat` or
use `scientific` and set the precision

``````std::cout.precision(std::numeric_limits<double>::max_digits10 - 1);
std::cout << std::scientific <<  1.0/7.0 << '\n';

// C++11 Typical output
1.4285714285714285e-01
``````

Too many answers address only one of 1) base 2) fixed/scientific layout or 3) precision. Too many answers with precision do not provide the proper value needed. Hence this answer to a old question.

1. What base?

A `double` is certainly encoded using base 2. A direct approach with C++11 is to print using `std::hexfloat`.
If a non-decimal output is acceptable, we are done.

``````std::cout << "hexfloat: " << std::hexfloat << exp (-100) << '\n';
std::cout << "hexfloat: " << std::hexfloat << exp (+100) << '\n';
// output
hexfloat: 0x1.a8c1f14e2af5dp-145
hexfloat: 0x1.3494a9b171bf5p+144
``````

1. Otherwise: `fixed` or `scientific`?

A `double` is a floating point type, not fixed point.

Do not use `std::fixed` as that fails to print small `double` as anything but `0.000...000`. For large `double`, it prints many digits, perhaps hundreds of questionable informativeness.

``````std::cout << "std::fixed: " << std::fixed << exp (-100) << '\n';
std::cout << "std::fixed: " << std::fixed << exp (+100) << '\n';
// output
std::fixed: 0.000000
std::fixed: 26881171418161356094253400435962903554686976.000000
``````

To print with full precision, first use `std::scientific` which will "write floating-point values in scientific notation". Notice the default of 6 digits after the decimal point, an insufficient amount, is handled in the next point.

``````std::cout << "std::scientific: " << std::scientific << exp (-100) << '\n';
std::cout << "std::scientific: " << std::scientific << exp (+100) << '\n';
// output
std::scientific: 3.720076e-44
std::scientific: 2.688117e+43
``````

1. How much precision (how many total digits)?

A `double` encoded using the binary base 2 encodes the same precision between various powers of 2. This is often 53 bits.

[1.0...2.0) there are 253 different `double`,
[2.0...4.0) there are 253 different `double`,
[4.0...8.0) there are 253 different `double`,
[8.0...10.0) there are 2/8 * 253 different `double`.

Yet if code prints in decimal with `N` significant digits, the number of combinations [1.0...10.0) is 9/10 * 10N.

Whatever `N` (precision) is chosen, there will not be a one-to-one mapping between `double` and decimal text. If a fixed `N` is chosen, sometimes it will be slightly more or less than truly needed for certain `double` values. We could error on too few (`a)` below) or too many (`b)` below).

3 candidate `N`:

a) Use an `N` so when converting from text-`double`-text we arrive at the same text for all `double`.

``````std::cout << dbl::digits10 << '\n';
// Typical output
15
``````

b) Use an `N` so when converting from `double`-text-`double` we arrive at the same `double` for all `double`.

``````// C++11
std::cout << dbl::max_digits10 << '\n';
// Typical output
17
``````

When `max_digits10` is not available, note that due to base 2 and base 10 attributes, `digits10 + 2 <= max_digits10 <= digits10 + 3`, we can use `digits10 + 3` to insure enough decimal digits are printed.

c) Use an `N` that varies with the value.

This can be useful when code wants to display minimal text (`N == 1`) or the exact value of a `double` (`N == 1000-ish` in the case of `denorm_min`). Yet since this is "work" and not likely OP's goal, it will be set aside.

It is usually b) that is used to "print a `double` value with full precision". Some applications may prefer a) to error on not providing too much information.

With `.scientific`, `.precision()` sets the number of digits to print after the decimal point, so `1 + .precision()` digits are printed. Code needs `max_digits10` total digits so `.precision()` is called with a `max_digits10 - 1`.

``````typedef std::numeric_limits< double > dbl;
std::cout.precision(dbl::max_digits10 - 1);
std::cout << std::scientific <<  exp (-100) << '\n';
std::cout << std::scientific <<  exp (+100) << '\n';
// Typical output
3.7200759760208361e-44
2.6881171418161356e+43
//1234567890123456  17 total digits
``````

Similar C question

``````printf("%.12f", M_PI);
``````

%.12f means floating point, with precision of 12 digits.

• This is not "using cout". – Johnsyweb Jan 26 '11 at 23:45
• But solved my lazy go-to-google question @Johnsyweb jajaja – BlastDV May 26 '14 at 20:07
• 12 digits is not "full precision" – Roland Illig Jan 14 '18 at 9:06

Most portably...

``````#include <limits>

using std::numeric_limits;

...
cout.precision(numeric_limits<double>::digits10 + 1);
cout << d;
``````

With ostream::precision(int)

``````cout.precision( numeric_limits<double>::digits10 + 1);
cout << M_PI << ", " << M_E << endl;
``````

will yield

``````3.141592653589793, 2.718281828459045
``````

Why you have to say "+1" I have no clue, but the extra digit you get out of it is correct.

• numeric_limits<unsigned char>::digits10 equals to 2. Because it can contain any decimal number of two digits 0..99. It can also contain 255.. but not 256, 257... 300 etc. this is why digits10 is not 3! I think "+1" is added to overcome something like this. – Dmitriy Yurchenko Apr 24 '13 at 23:42