# Are all integer values perfectly represented as doubles? [duplicate]

My question is whether all integer values are guaranteed to have a perfect double representation.

Consider the following code sample that prints "Same":

``````// Example program
#include <iostream>
#include <string>

int main()
{
int a = 3;
int b = 4;
double d_a(a);
double d_b(b);

double int_sum = a + b;
double d_sum = d_a + d_b;

if (double(int_sum) == d_sum)
{
std::cout << "Same" << std::endl;
}
}
``````

Is this guaranteed to be true for any architecture, any compiler, any values of `a` and `b`? Will any integer `i` converted to `double`, always be represented as `i.0000000000000` and not, for example, as `i.000000000001`?

I tried it for some other numbers and it always was true, but was unable to find anything about whether this is coincidence or by design.

Note: This is different from this question (aside from the language) since I am adding the two integers.

• You can use a loop to test every possible number. – mch Apr 27 '17 at 10:59
• Short answer is "no" - the range of values an `int` can represent and that a `double` can represent are implementation defined - but a `double` certainly cannot support every integral value in the range it can represent. The practical answer is "it depends". – Peter Apr 27 '17 at 11:00
• @mch: This would prove nothing, it could be true for my architecture but false for others... – Thomas Apr 27 '17 at 11:00
• Is this guaranteed to be true for any architecture, any compiler, any values of a&b? No. AFAIK C++ does not specify any specific binary representation for floating point values. Of course, in practice, you can probably rely on most compilers on most platforms to use IEEE 754 floating point. – sigbjornlo Apr 27 '17 at 11:11
• The smallest positive integral value not representable by a 64bit IEEE double is 9007199254740993. This integral value has 54 significant bits and the double can only represent 53 significant bits. Note that 9007199254740992 takes 54 bits to represent in two's complement. But the double format can represent its mantissa with only 1 bit (well, actually zero because the leading bit is implicit). No need to loop to find this information. Use `numeric_limits<double>::digits`, and `nextafter`. – Howard Hinnant Apr 27 '17 at 14:28

Disclaimer (as suggested by Toby Speight): Although IEEE 754 representations are quite common, an implementation is permitted to use any other representation that satisfies the requirements of the language.

The doubles are represented in the form `mantissa * 2^exponent`, i.e. some of the bits are used for the non-integer part of the double number.

``````             bits        range                       precision
float        32        1.5E-45   .. 3.4E38          7- 8 digits
double       64        5.0E-324  .. 1.7E308        15-16 digits
long double  80        1.9E-4951 .. 1.1E4932       19-20 digits
`````` The part in the fraction can also used to represent an integer by using an exponent which removes all the digits after the dot.

E.g. 2,9979 · 10^4 = 29979.

Since a common `int` is usually 32 bit you can represent all `int`s as double, but for 64 bit integers of course this is no longer true. To be more precise (as LThode noted in a comment): IEEE 754 double-precision can guarantee this for up to 53 bits (52 bits of significand + the implicit leading 1 bit).

Answer: yes for 32 bit ints, no for 64 bit ints.

(This is correct for server/desktop general-purpose CPU environments, but other architectures may behave differently.)

Practical Answer as Malcom McLean puts it: 64 bit doubles are an adequate integer type for almost all integers that are likely to count things in real life.

For the empirically inclined, try this:

``````#include <iostream>
#include <limits>
using namespace std;

int main() {
double test;
volatile int test_int;
for(int i=0; i< std::numeric_limits<int>::max(); i++) {
test = i;
test_int = test;

// compare int with int:
if (test_int != i)
std::cout<<"found integer i="<<i<<", test="<<test<<std::endl;
}
return 0;
}
``````

Success time: 0.85 memory: 15240 signal:0

Subquestion: Regarding the question for fractional differences. Is it possible to have a integer which converts to a double which is just off the correct value by a fraction, but which converts back to the same integer due to rounding?

The answer is no, because any integer which converts back and forth to the same value, actually represents the same integer value in double. For me the simplemost explanation (suggested by ilkkachu) for this is that using the exponent `2^exponent` the step width must always be a power of two. Therefore, beyond the largest 52(+1 sign) bit integer, there are never two double values with a distance smaller than 2, which solves the rounding issue.

• See stackoverflow.com/questions/12629087/… - this is different from my question. Even if double(4) is converted to 4.000000001, your test would still succeed since the integer is also (implicitely) converted to double. – Thomas Apr 27 '17 at 11:27
• The upper part though sounds logical - but so did the other answer from someone else that just got deleted because it was wrong. So I'll wait for a day before accepting it in case someone with more knowledge than me finds an error :) – Thomas Apr 27 '17 at 11:28
• @Beginner This comparison will always return `false`, as the integer `test_int` will be implicitly converted to a `double` in this comparison. So even if the `double` can't represent the `int`, the `int` will be converted to the same imprecise representation, which then compares equal. – Corristo Apr 27 '17 at 11:49
• @Corristo both numbers in the comparison are int, why is anything converted to double? I don't get it, can you explain in more detail? – Beginner Apr 27 '17 at 11:51
• @Beginner essentially yes, but for the sake of completeness, there might be some fringe cases: Say 1 (int) gets converted to 1.0000001. If you add that a million times as integers, you will (correctly) get you a million. If you convert it to double before doing so, you would get 1000001. – Thomas Apr 27 '17 at 13:35

No. Suppose you have a 64-bit integer type and a 64-bit floating-point type (which is typical for a `double`). There are 2^64 possible values for that integer type and there are 2^64 possible values for that floating-point type. But some of those floating-point values (in fact, most of them) do not represent integer values, so the floating-point type can represent fewer integer values than the integer type can.

• What about 32-bit integers? The cardinality-argument is inconclusive for this case. – Beginner Apr 27 '17 at 12:56
• @Beginner - even more extreme, absent perverse floating-point types, every integer value that can be represented as a value of `int8_t` (assuming the type actually exists) can be exactly represented as a double. But the question is broader than that; it asks, without qualification, if all integer values can be represented exactly as doubles, and the answer is "no". And the answer to the implied question is if you need to know which integers can be exactly represented in a double you have to know fairly intimate details of how double is represented on your system. This is not for beginners. – Pete Becker Apr 27 '17 at 14:13
• Perverse or not, any integer value up to 10^6-1 is required to be exactly represented as a float, and any up to 10^10-1 as a double. At least, that's the case in C. Not only int8_t but int16_t and, for double, int32_t (and thus the minimum required ranges of int and long) is well within this range. – Random832 Apr 27 '17 at 23:40

The answer is no. This only works if `int`s are 32 bit, which, while true on most platforms, isn't guaranteed by the standard.

The two integers can share the same double representation.

For example, this

``````#include <iostream>
int main() {
int64_t n = 2397083434877565865;
if (static_cast<double>(n) == static_cast<double>(n - 1)) {
std::cout << "n and (n-1) share the same double representation\n";
}
}
``````

will print

n and (n-1) share the same double representation

I.e. both 2397083434877565865 and 2397083434877565864 will convert to the same `double`.

Note that I used `int64_t` here to guarantee 64-bit integers, which - depending on your platform - might also be what `int` is.

• Thanks for pointing out that floating point precision gets worse the larger the int is. Is there any reason you defined i,j seperately and then added them instead of simply saying k=2397083? – Thomas Apr 27 '17 at 11:19
• @Thomas You could also simply set `k=2397083434877565865`. – Corristo Apr 27 '17 at 11:30
• @Rene Depending on the platform, `int` might be a 64 bit integer. – Corristo Apr 27 '17 at 11:35
• @Rene There could be any number of such platforms. There's no way you can assume a platform doesn't exist just because you don't know about it. This question was tagged "standards" not "happens to work most places". – David Schwartz Apr 27 '17 at 20:20
• @Thomas -- floating-point precision doesn't get worse the larger the into is. It stays exactly the same. Your integer values seem to have more precision because you're writing more non-zero digits, but their precision doesn't change, either. – Pete Becker Apr 28 '17 at 2:10

You have 2 different questions:

Are all integer values perfectly represented as doubles?

That was already answered by other people (TL;DR: it depends on the precision of `int` and `double`).

Consider the following code sample that prints "Same": [...] Is this guaranteed to be true for any architecture, any compiler, any values of a and b?

Your code adds two `int`s and then converts the result to double. The sum of `int`s will overflow for certain values, but the sum of the two separately-converted `double`s will not (typically). For those values the results will differ.

• This is something I didn't have in mind when asking the question, but a good point nonetheless :) – Thomas Jun 16 '17 at 15:43

• the size and representation of `double`
• the range of `int`
For platforms using IEEE-754 doubles, it may be true if `int` is 53-bit or smaller. For platforms where `int` is larger than `double`, it's obviously false.
You may want be able to investigate the properties on your runtime host, using `std::numeric_limits` and `std::nextafter`.