# What's the C++ suffix for long double literals?

In C++ (and C), a floating point literal without suffix defaults to `double`, while the suffix `f` implies a `float`. But what is the suffix to get a `long double`?

Without knowing, I would define, say,

``````const long double x = 3.14159265358979323846264338328;
``````

But my worry is that the variable `x` contains fewer significant bits of `3.14159265358979323846264338328` than 64, because this is a `double` literal. Is this worry justified?

• Just preprocess this file `#include <float.h> LDBL_MAX` and you see `1.18973149535723176502e+4932L` which answers your question. Feb 4, 2014 at 16:27
• As to the question "is this worry justified" it really depends. Your PI value has a precision of 1e-28. Machine epsilon for double is ~2.22e-16, so it IS smaller than what you are looking for to capture this number precisely. Does it matter? Depends on whether or not you need to be that precise in your calculations... Feb 4, 2014 at 16:35
• @EricPostpischil it obviously shows how to spell out a `long double` constant... (suffix L) Feb 5, 2014 at 12:13

From the C++ Standard

The type of a floating literal is double unless explicitly specified by a suffix. The suffixes f and F specify float, the suffixes l and L specify long double.

It is interesting to compare with corresponding paragraph of the C Standard. In C there is used term `floating constant` instead of `floating literal` in C++:

4 An unsuffixed floating constant has type double. If suffixed by the letter f or F, it has type float. If suffixed by the letter l or L, it has type long double

The C suffix is `L`. I'd strongly suspect that it is the same for C++.

Your worry is justified. Your literal would first be converted to a `double`, and thus truncated, and then converted back to `long double`.

Your concern is valid and you should use a `L` suffix for long double literal.

• Where does the `F` come from? I checked the C standard, and there it only is `L`. Feb 4, 2014 at 16:28

I tried the `l` suffix:

``````#include <iostream>
#include <iomanip>
#include <string>

using namespace std;

int main()
{
float t1 = 1.10000000000000000002l;
double t2 = 1.10000000000000000002l;
long double t3 = 1.10000000000000000002L;
cout << setprecision(25);
cout << t1 << endl;
cout << t2 << endl;
cout << t3 << endl;
}
``````

Still I get this output indicating the lack of desired precision:

``````1.10000002384185791015625
1.100000000000000088817842
1.100000000000000088817842
``````
• With many implementations, the representations (and thus value range, precision etc.) of `double` and `long double` are identical (e.g. 64 bit IEEE float). Just like on many implementations, the representations of `long` and `long long` are identical (e.g. 64 bit 2's complement signed integer). In both cases though, they are still treated as different by the type system. E.g. calling a function template with `1.0` and `1.0L` will deduce different types and call different specializations of the template. Same with `1L` and `1LL`. Dec 19, 2021 at 4:15