EDIT: After some discussion in the comments it came out that because of a luck of knowledge in how floating point numbers are implemented in C, I asked something different from what I meant to ask.
I wanted to use (do operations with) integers larger than those I can have with unsigned long long (that for me is 8 bytes), possibly without recurring to arrays or bigint libraries. Since my long double is 16 bytes, I thought it could've been possible by just switching type. It came out that even though it is possible to represent larger integers, you can't do operations -with these larger long double integers- without losing precision. So it's not possible to achieve what I wanted to do. Actually, as stated in the comments, it is not possible for me. But in general, wether it is possible or not depends on the floating point characteristics of your long double.

// end of EDIT

I am trying to understand what's the largest integer that I can store in a long double.
I know it depends on environment which the program is built in, but I don't know exactly how. I have a sizeof(long double) == 16 for what is worth.

Now in this answer they say that the the maximum value for a 64-bit double should be 2^53, which is around 9 x 10^15, and exactly 9007199254740992.
When I run the following program, it just works:

#include <stdio.h>

int main() {

    long double d = 9007199254740992.0L, i;
    printf("%Lf\n", d);
    for(i = -3.0; i < 4.0; i++) {
        printf("%.Lf) %.1Lf\n", i, d+i);
    return 0;

It works even with 11119007199254740992.0L that is the same number with four 1s added at the start. But when I add one more 1, the first printf works as expected, while all the others show the same number of the first print.
So I tried to get the largest value of my long double with this program

#include <stdio.h>
#include <math.h>

int main() {

    long double d = 11119007199254740992.0L, i;
    for(i = 0.0L; d+i == d+i-1.0; i++) {
        if( !fmodl(i, 10000.0L) ) printf("%Lf\n", i);
    printf("%.Lf\n", i);
    return 0;

But it prints 0.
(Edit: I just realized that I needed the condition != in the for)

Always in the same answer, they say that the largest possible value of a double is DBL_MAX or approximately 1.8 x 10^308.
I have no idea of what does it mean, but if I run

printf("%e\n", LDBL_MAX);

I get every time a different value that is always around 6.9 x 10^(-310).
(Edit: I should have used %Le, getting as output a value around 1.19 x 10^4932)
I took LDBL_MAX from here.

I also tried this one

printf("%d\n", LDBL_MAX_10_EXP);

That gives the value 4932 (which I also found in this C++ question).

Since we have 16 bytes for a long double, even if all of them were for the integer part of the type, we would be able to store numbers till 2^128, that is around 3.4 x 10^38. So I don't get what 308, -310 and 4932 are supposed to mean.

Is someone able to tell me how can I find out what's the largest integer that I can store as long double?

  • 1
    That depends on whether the integer has any 2 factors, which will be taken up by the exponent. The simple answer is the number of specified signifcand bits (plus 1) for loss-less storage of an integer value. The exponent dictates the range of all values that can be approximately represented. Commented Jan 15, 2021 at 16:48
  • 2
    In printf("%e\n", LDBL_MAX); did you mean to use %Le? Commented Jan 15, 2021 at 16:59
  • 1
    There are several ways to interpret the question, all of which yield different results. For instance, all of the largest values that a long double can store are integers, and in particular, LDBL_MAX is an integer. But there is no built-in integer integer data type that can represent that value in most implementations. Commented Jan 15, 2021 at 17:06
  • 1
    The 4932 isn't directly related to the 16 bytes of the floating point type, but 10^4932 comes from the number of bits in the exponent part. Commented Jan 15, 2021 at 17:06
  • 2
    "So it's not possible to achieve what I wanted to do." --> is incorrect. It depends on the floating point characteristics of long double. With LDBL_MANT_DIG == 64, code can effect int65_t like operations. Commented Jan 15, 2021 at 19:01

3 Answers 3


Inasmuch as you express in comments that you want to use long double as a substitute for long long to obtain increased range, I assume that you also require unit precision. Thus, you are asking for the largest number representable by the available number of mantissa digits (LDBL_MANT_DIG) in the radix of the floating-point representation (FLT_RADIX). In the very likely event that FLT_RADIX == 2, you can compute that value like so:

#include <float.h>
#include <math.h>

long double get_max_integer_equivalent() {
    long double max_bit = ldexpl(1, LDBL_MANT_DIG - 1);
    return max_bit + (max_bit - 1);

The ldexp family of functions scale floating-point values by powers of 2, analogous to what the bit-shift operators (<< and >>) do for integers, so the above is similar to

// not reliable for the purpose!
unsigned long long max_bit = 1ULL << (DBL_MANT_DIG - 1);
return max_bit + (max_bit - 1);

Inasmuch as you suppose that your long double provides more mantissa digits than your long long has value bits, however, you must assume that bit shifting would overflow.

There are, of course, much larger values that your long double can express, all of them integers. But they do not have unit precision, and thus the behavior of your long double will diverge from the expected behavior of integers when its values are larger. For example, if long double variable d contains a larger value then at least one of d + 1 == d and d - 1 == d will likely evaluate to true.

  • I run your function and it returns a long number that is 2^64 - 1. I will take my time to understand how the function works, but anyway I get the I can't use long double to manipulate integers larger than those I can manipulate with unsigned long long. Thank you for giving me a piece of code proving this fact.
    – anotherOne
    Commented Jan 15, 2021 at 18:16
  • "But they do not have unit precision" --> Yet get_max_integer_equivalent() +1.0 is representable. Commented Jan 15, 2021 at 18:59
  • Yes indeed, @chux-ReinstateMonica. It is the smallest long double that does not have unit precision. That is, the least in which the least-significant digit has place value greater than 1. The last sentence of this answer applies to it. And if it turns out that adding 1 to that number yields a different number, then the result will not be the next larger integer. Commented Jan 15, 2021 at 19:29
  • As I see it, the long double in question can encode all the integers INT65_MIN...INT65_MAX+1 or up to UINT64_MAX+1. Commented Jan 15, 2021 at 20:15
  • @chux-ReinstateMonica, it is a question, as is often the case, of how you want to use the data. If you only want values that you can rely upon to behave arithmetically the same as integers, as I explicitly take to be the OP's case, then get_max_integer_equivalent() +1.0 is not such a number. This is in fact precisely why I expressed the function is I did, as opposed to using the simpler, but unreliable return ldexpl(1, LDBL_MANT_DIG) - 1;. Commented Jan 15, 2021 at 20:24

You can print the maximum value on your machine using limits.h, the value is ULLONG_MAX

In https://www.geeksforgeeks.org/climits-limits-h-cc/ is a C++ example.

The format specifier for printing unsigned long long with printf() is %llu for printing long double it is %Lf

printf("unsigned long long int: %llu ",(unsigned long long) ULLONG_MAX);

printf("long double: %Lf ",(long double) LDBL_MAX);


Is also in Printing unsigned long long int Value Type Returns Strange Results

  • 1
    And if unsigned long long is 128 bits, ULLONG_MAX simply can't fit into a 128-bit floating point value without loss of data. Commented Jan 15, 2021 at 16:56
  • Printing ULLONG_MAX gives me always a different value around 6.9 x 10^(-310). Like printing LDBL_MAX. However the two values are different between each other.
    – anotherOne
    Commented Jan 15, 2021 at 17:00
  • ULLONG_MAX cannot be 6.9•10^−310 or near it because ULLONG_MAX is an integer and 6.9•10^−310 and values near it are not (except for zero). If you are getting something appearing to be near 6.9•10^−310 when you print ULLONG_MAX, then you are printing it incorrectly. Commented Jan 15, 2021 at 17:12

Assuming you mean "stored without loss of information", LDBL_MANT_DIG gives the number of bits used for the floating-point mantissa, so that's how many bits of an integer value that can be stored without loss of information.*

You'd need 128-bit integers to easily determine the maximum integer value that can be held in a 128-bit float, but this will at least emit the hex value (this assumes unsigned long long is 64 bits - you can use CHAR_BIT and sizeof( unsigned long long ) to get a portable answer):

#include <stdio.h>
#include <float.h>
#include <limits.h>

int main( int argc, char **argv )
    int tooBig = 0;
    unsigned long long shift = LDBL_MANT_DIG;
    if ( shift >= 64 )
        tooBig = 1;
        shift -= 64;

    unsigned long long max = ( 1ULL << shift ) - 1ULL;

    printf( "Max integer value: 0x" );

    // don't emit an extraneous zero if LDBL_MANT_DIG is
    // exactly 64
    if ( max )
        printf( "%llx", max );

    if ( tooBig )
        printf( "%llx", ULLONG_MAX );

    printf( "\n" );

    return( 0 );

* - pedantically, it's the number of digits in FLT_RADIX base, but that base is almost certainly 2.

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