In my earlier question 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?
17 Answers
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;

52Why do you explicitly advise to use
fixed
? Withdouble h = 6.62606957e34;
,fixed
gives me0.000000000000000
andscientific
outputs6.626069570000000e34
.– ArthurJan 9, 2012 at 17:58 
38The 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/E1995701/8063568/ncg_goldberg.html Oct 28, 2013 at 9:16

9Is 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.... Sep 4, 2014 at 22:07 
7For those looking where it mentions 17 digits in the paper @MikeFisher cited, it's under Theorem 15. Jan 11, 2015 at 21:23

18@MikeFisher You're right, C++11 introduces
max_digits10
to denote the same. Fixed the answer to reflect this. Aug 24, 2015 at 7:47
Use std::setprecision
:
#include <iomanip>
std::cout << std::setprecision (15) << 3.14159265358979 << std::endl;

2Is there some kind of MAX_PRECISION macro or enum or something I can pass to std::setPrecision? Feb 16, 2009 at 18:23

3std::setprecision(15) for a double (ok or 16), log_10(2**53) ~= 15.9– user7116Feb 16, 2009 at 18:24

17

8Should be
std::setprecision (17)
for double, see comments on @Bill The Lizard's answer. Dec 17, 2015 at 14:45 
15for std::setprecision to work, #include <iomanip> should be included. Jul 16, 2016 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
For details about other attributes.

14This header is needed to use
std::setprecision()
:#include <iomanip>
Aug 19, 2011 at 15:26 
it should be
std::numeric_limits<double>
instead ofnumberic_limits<double>
– niklasfiApr 15, 2014 at 14:00 
2Why do you add
1
tostd::numeric_limits<double>::digits10
? Oct 3, 2014 at 11:40 
6

3@AlecJacobson It should rather be
max_digits10
, not some arbitrarydigits10+2
. Otherwise, in the case offloat
,long double
,boost::multiprecision::float128
this will fail, since there you'd need+3
instead of+2
.– RuslanMay 27, 2019 at 17:41
In C++20 you'll be able to use std::format
to do this:
std::cout << std::format("{}", M_PI);
Output (assuming IEEE754 double
):
3.141592653589793
The default floatingpoint format is the shortest decimal representation with a roundtrip guarantee. The advantage of this method compared to the setprecision
I/O manipulator is that it doesn't print unnecessary digits.
In the meantime you can use the {fmt} library, std::format
is based on. {fmt} also provides the print
function that makes this even easier and more efficient (godbolt):
fmt::print("{}", M_PI);
Disclaimer: I'm the author of {fmt} and C++20 std::format
.
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
1.4285714285714285e01
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.
 What base?
A double
is certainly encoded using base 2. A direct approach with C++11 is to print using std::hexfloat
.
If a nondecimal 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.a8c1f14e2af5dp145
hexfloat: 0x1.3494a9b171bf5p+144
 Otherwise:
fixed
orscientific
?
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 floatingpoint 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: 3.720076e44
std::scientific: 2.688117e+43
 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 2^{53} different double
,
[2.0...4.0) there are 2^{53} different double
,
[4.0...8.0) there are 2^{53} different double
,
[8.0...10.0) there are 2/8 * 2^{53} different double
.
Yet if code prints in decimal with N
significant digits, the number of combinations [1.0...10.0) is 9/10 * 10^{N}.
Whatever N
(precision) is chosen, there will not be a onetoone 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 textdouble
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
textdouble
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 == 1000ish
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
3.7200759760208361e44
2.6881171418161356e+43
//2345678901234567 17 total digits

3Great answer! A few remarks though: You're right that
precision()
sets the number of decimal places for scientific mode. Without specifyingscientific
, it sets the total number of digits, excluding the exponent. You might still end up with scientific output, depending on your number value, but then you might also get less digits than you specified. Example:cout.precision(3); cout << 1.7976931348623158e+308; // "1.8e+308"
Results forprintf
may be different. Confusing stuff one should be aware off. Mar 4, 2020 at 8:46 
1For posterity, here's the required buffer length for guaranteed exact string representation of all double numbers in scientific mode using printf:
char buf[DBL_DECIMAL_DIG + 3 + 5]; sprintf(buf, "%.*g", DBL_DECIMAL_DIG, d);
The extra characters are for: sign, decimal point, trailing zero, e[+], 3 digits for the exponent (DBL_MAX_10_EXP = 308). Hence the total number of required characters is 25. Mar 4, 2020 at 8:56 
Can't edit my first comment, so here we go again: Another issue with scientific mode is that it might decide to not use exponential output, it even might decide to not use floating point output at all. That is, it will output 1.0 as "1", which might be a problem in a serialization/deserialization context. You can force it to output a decimal point by using "%#.*g", but this has the drawback that it adds a number of trailing zeros, which it doesn't without the #... Mar 5, 2020 at 10:13

1@IInspectable True that all finite FP can be converted to decimal text, yet not certainly with
std::cout <<
. Only rare implementations will do so for allstd::cout.precision(n)
. IEEE 754 only requires about at least dbl::max_digits10 + 3. As "onetoone mapping between double and decimal text" refers to both conversion directions, we agree one direction possible maps yet the other does not. Oct 7, 2021 at 12:43 
1Fair enough, "mapping between X and Y" does suggest a bijective relationship, which apparently escaped me back when I left the comment. Oct 7, 2021 at 18:26
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

The boost documentation says "For numerics that have a corresponding specialization of std::numeric_limits, the current version now chooses a precision to match". This seems like the easiest way to get the max precision. (boost.org/doc/libs/1_58_0/doc/html/boost_lexical_cast/…) May 15, 2015 at 21:34

Link with boost::lexical_cast (boost.org/doc/libs/release/libs/conversion/lexical_cast.htm) is dead. Oct 7, 2021 at 18:38

Note that printing a
double
with only 15 digits as with "Pi: 3.14159265358979" might not convert back to the samedouble
. To always do that requires more like max_digits10 significant digits. Oct 7, 2021 at 18:41
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
Note: Header files required
#include <iomanip>
#include <limits>

5This happens because
100.0000000000005
isn't being represented exactly as adouble
. (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 get4.973799150320701e13
. Sep 8, 2017 at 12:12
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 fullfull 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 using a union
to typepun the double
to a integer and then printing the integer, since integers do not suffer from truncation or roundoff issues. (Type punning like this is not supported by the C++ standard, but it is supported in C. However, most C++ compilers will probably print out the correct value anyways. I think g++ supports this.)
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;

variant with union will give you undefined behavior because it attempts to read uninitialized value
x.u64
. Jul 19, 2020 at 9:01
C++20 std::format
This great new C++ library feature has the advantage of not affecting the state of std::cout
as std::setprecision
does:
#include <format>
#include <string>
int main() {
std::cout << std::format("{:.2} {:.3}\n", 3.1415, 3.1415);
}
Expected output:
3.14 3.142
As mentioned at https://stackoverflow.com/a/65329803/895245 if you don't pass the precision explicitly it prints the shortest decimal representation with a roundtrip guarantee. TODO understand in more detail how it compares to: dbl::max_digits10
as shown at https://stackoverflow.com/a/554134/895245 with {:.{}}
:
#include <format>
#include <limits>
#include <string>
int main() {
std::cout << std::format("{:.{}}\n",
3.1415926535897932384626433, dbl::max_digits10);
}
See also:
 Set back default floating point print precision in C++ for how to restore the initial precision in prec++20
 std::string formatting like sprintf
 https://en.cppreference.com/w/cpp/utility/format/formatter#Standard_format_specification
IEEE 754 floating point values are stored using base 2 representation. Any base 2 number can be represented as a decimal (base 10) to full precision. None of the proposed answers, however, do. They all truncate the decimal value.
This seems to be due to a misinterpretation of what std::numeric_limits<T>::max_digits10
represents:
The value of
std::numeric_limits<T>::max_digits10
is the number of base10 digits that are necessary to uniquely represent all distinct values of the typeT
.
In other words: It's the (worstcase) number of digits required to output if you want to roundtrip from binary to decimal to binary, without losing any information. If you output at least max_digits10
decimals and reconstruct a floating point value, you are guaranteed to get the exact same binary representation you started with.
What's important: max_digits10
in general neither yields the shortest decimal, nor is it sufficient to represent the full precision. I'm not aware of a constant in the C++ Standard Library that encodes the maximum number of decimal digits required to contain the full precision of a floating point value. I believe it's something like 767 for double
s^{1}. One way to output a floating point value with full precision would be to use a sufficiently large value for the precision, like so^{2}, and have the library strip any trailing zeros:
#include <iostream>
int main() {
double d = 0.1;
std::cout.precision(767);
std::cout << "d = " << d << std::endl;
}
This produces the following output, that contains the full precision:
d = 0.1000000000000000055511151231257827021181583404541015625
Note that this has significantly more decimals than max_digits10
would suggest.
While that answers the question that was asked, a far more common goal would be to get the shortest decimal representation of any given floating point value, that retains all information. Again, I'm not aware of any way to instruct the Standard I/O library to output that value. Starting with C++17 the possibility to do that conversion has finally arrived in C++ in the form of std::to_chars
. By default, it produces the shortest decimal representation of any given floating point value that retains the entire information.
Its interface is a bit clunky, and you'd probably want to wrap this up into a function template that returns something you can output to std::cout
(like a std::string
), e.g.
#include <charconv>
#include <array>
#include <string>
#include <system_error>
#include <iostream>
#include <cmath>
template<typename T>
std::string to_string(T value)
{
// 24 characters is the longest decimal representation of any double value
std::array<char, 24> buffer {};
auto const res { std::to_chars(buffer.data(), buffer.data() + buffer.size(), value) };
if (res.ec == std::errc {})
{
// Success
return std::string(buffer.data(), res.ptr);
}
// Error
return { "FAILED!" };
}
int main()
{
auto value { 0.1f };
std::cout << to_string(value) << std::endl;
value = std::nextafter(value, INFINITY);
std::cout << to_string(value) << std::endl;
value = std::nextafter(value, INFINITY);
std::cout << to_string(value) << std::endl;
}
This would print out (using Microsoft's C++ Standard Library):
0.1
0.10000001
0.10000002
^{1} From Stephan T. Lavavej's CppCon 2019 talk titled FloatingPoint <charconv>: Making Your Code 10x Faster With C++17's Final Boss. (The entire talk is worth watching.)
^{2} This would also require using a combination of scientific
and fixed
, whichever is shorter. I'm not aware of a way to set this mode using the C++ Standard I/O library.

@chu That assumes that the smallest representable value is also the one with the longest sequence of digits in decimal. That sounds plausible, but plausibility is not quite where floating point values are at home. Have you tried to use nextafter to see, if the lengths increase in the vicinity of
DBL_TRUE_MIN
? Jun 23, 2020 at 21:25 
@chu Ah, true,
DBL_TRUE_MIN
only has its least significant bit set in the mantissa. Hadn't thought of that. Still, I'd need to see a mathematical proof to understand, why that would result in the longest decimal sequence. Jun 23, 2020 at 21:37 
Note: "One way to output a floating point value with full precision would be to use a sufficiently large value for the precision," > A library compliant to IEEE 754 need only print the correctly rounded value to
long double::max_digits10
+ 3 significant digits. We might not get full precision. Jun 23, 2020 at 21:37 
"I'd need to see a mathematical proof to understand" > sounds like a good question on some site  and a bit of work to fulfill  too much for a quick comment. Jun 23, 2020 at 21:39

Yes
DBL_MIN  DBL_TRUE_MIN
took 767 significant digits. Jun 23, 2020 at 23:10
printf("%.12f", M_PI);
%.12f means floating point, with precision of 12 digits.

13

3
Most portably...
#include <limits>
using std::numeric_limits;
...
cout.precision(numeric_limits<double>::digits10 + 1);
cout << d;

18
In this question there is a description on how to convert a double to string losselessly (in Octave, but it can be easily reproduced in C++). De idea is to have a short human readable description of the float and a losseless description in hexa form, for instance: pi > 3.14{54442d18400921fb}.
Here is a function that works for any floatingpoint type, not just double
, and also puts the stream back the way it was found afterwards. Unfortunately it won't interact well with threads, but that's the nature of iostreams. You'll need these includes at the start of your file:
#include <limits>
#include <iostream>
Here's the function, you could it in a header file if you use it a lot:
template <class T>
void printVal(std::ostream& os, T val)
{
auto oldFlags = os.flags();
auto oldPrecision = os.precision();
os.flags(oldFlags & ~std::ios_base::floatfield);
os.precision(std::numeric_limits<T>::digits10);
os << val;
os.flags(oldFlags);
os.precision(oldPrecision);
}
Use it like this:
double d = foo();
float f = bar();
printVal(std::cout, d);
printVal(std::cout, f);
If you want to be able to use the normal insertion <<
operator, you can use this extra wrapper code:
template <class T>
struct PrintValWrapper { T val; };
template <class T>
std::ostream& operator<<(std::ostream& os, PrintValWrapper<T> pvw) {
printVal(os, pvw.val);
return os;
}
template <class T>
PrintValWrapper<T> printIt(T val) {
return PrintValWrapper<T>{val};
}
Now you can use it like this:
double d = foo();
float f = bar();
std::cout << "The values are: " << printIt(d) << ", " << printIt(f) << '\n';
This will show the value up to two decimal places after the dot.
#include <iostream>
#include <iomanip>
double d = 2.0;
int n = 2;
cout << fixed << setprecision(n) << d;
See here: Fixedpoint notation
Use fixed floatingpoint notation Sets the floatfield format flag for the str stream to fixed.
When floatfield is set to fixed, floatingpoint values are written using fixedpoint notation: the value is represented with exactly as many digits in the decimal part as specified by the precision field (precision) and with no exponent part.
Set decimal precision Sets the decimal precision to be used to format floatingpoint values on output operations.
If you're familiar with the IEEE standard for representing the floatingpoints, you would know that it is impossible to show floatingpoints with fullprecision out of the scope of the standard, that is to say, it will always result in a rounding of the real value.
You need to first check whether the value is within the scope, if yes, then use:
cout << defaultfloat << d ;
Use default floatingpoint notation Sets the floatfield format flag for the str stream to defaultfloat.
When floatfield is set to defaultfloat, floatingpoint values are written using the default notation: the representation uses as many meaningful digits as needed up to the stream's decimal precision (precision), counting both the digits before and after the decimal point (if any).
That is also the default behavior of cout
, which means you don't use it explicitly.

It should be setprecision and not setprecison. Note: the edition proposal is blocked because it contains less than 6 characters! Nov 26, 2020 at 9:10
The best option is to use std::setprecision
, and the solution works like this:
# include <iostream>
# include <iomanip>
int main()
{
double a = 34.34322;
std::cout<<std::fixed<<a<<std::setprecision(0)<<std::endl;
return 0;
}
Note: you do not need to use cout.setprecision
to do it and I fill up 0 at std::setprecision
because it must have a argument.
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.

3numeric_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. Apr 24, 2013 at 23:42
cout << *reinterpret_cast<std::uint64_t *>(&my_double);
) This is useful to save your data and reload it later with the exact same value, bit for bit. But in most cases that's not what the user wants.std::hexfloat
is better than casting, but yes