In a C program I was trying the below operations (Just to check the behavior)
x = 5 % (-3);
y = (-5) % (3);
z = (-5) % (-3);
printf("%d ,%d ,%d", x, y, z);
It gave me output as (2, -2 , -2) in gcc. I was expecting a positive result every time. Can a modulus be negative? Can anybody explain this behavior?
C99 requires that when a/b is representable:
(a/b) * b + a%b shall equal a
This makes sense, logically. Right?
Let's see what this leads to:
Example A. 5/(-3) is -1
=> (-1) * (-3) + 5%(-3) = 5
This can only happen if 5%(-3) is 2.
Example B. (-5)/3 is -1
=> (-1) * 3 + (-5)%3 = -5
This can only happen if (-5)%3 is -2
-5/3 is -2 and the mod becomes 1. In short: one module has a sign that follows the dividend sign (truncate), the other module has a sign that follows the divisor sign (Knuth).
a/b in the expression (a/b) * b + a%b above is integer division, so (a/b) * b is not equal to a unless a is divisible by b.
Commented
Dec 17, 2021 at 17:51
The % operator in C is not the modulo operator but the remainder operator.
Modulo and remainder operators differ with respect to negative values.
With a remainder operator, the sign of the result is the same as the sign of the dividend (numerator) while with a modulo operator the sign of the result is the same as the divisor (denominator).
C defines the % operation for a % b as:
a == (a / b * b) + a % b
with / the integer division with truncation towards 0. That's the truncation that is done towards 0 (and not towards negative inifinity) that defines the % as a remainder operator rather than a modulo operator.
remainder and modulo in Scheme, rem and mod in Haskell). These operators specifications differ on these languages on how the division is done: truncation towards 0 or toward negative infinity. By the way the C Standard never calls the % the modulo operator, they just name it the % operator.
remainder function in C, which implements IEEE remainder with round-towards-nearest semantics in the division
-2 as the least absolute remainder of 43 / 5 (since 43 = 9 * 5 - 2). The CS definition is yet again different. But it is worth pointing out that just because we learned something when we were 10 years old, there still might be some subtleties. Try round(2.5) in Python, for instance. It's 2, not 3. And that is mathematically correct, to prevent bias in statistical moments.
Commented
Feb 18, 2021 at 17:25
Based on the C99 Specification: a == (a / b) * b + a % b
We can write a function to calculate (a % b) == a - (a / b) * b!
int remainder(int a, int b)
{
return a - (a / b) * b;
}
For modulo operation, we can have the following function (assuming b > 0)
int mod(int a, int b)
{
int r = a % b;
return r < 0 ? r + b : r;
}
My conclusion is that a % b in C is a remainder operation and NOT a modulo operation.
b is negative (and in fact for r and b both negative it gives results less than -b). To ensure positive results for all inputs you could use r + abs(b) or to match bs sign you could change the condition to r*b < 0 instead.
Commented
Sep 20, 2016 at 11:42
I don't think there isn't any need to check if the number is negative.
A simple function to find the positive modulo would be this -
Edit: Assuming N > 0 and N + N - 1 <= INT_MAX
int modulo(int x,int N){
return (x % N + N) %N;
}
This will work for both positive and negative values of x.
Original P.S: also as pointed out by @chux, If your x and N may reach something like INT_MAX-1 and INT_MAX respectively, just replace int with long long int.
And If they are crossing limits of long long as well (i.e. near LLONG_MAX), then you shall handle positive and negative cases separately as described in other answers here.
N < 0, the result may be negative as in modulo(7, -3) --> -2. Also x % N + N can overflow int math which is undefined behavior. e.g. modulo(INT_MAX - 1,INT_MAX) might result in -3.
long long int, or handle the negative case separately (at the cost of losing simplicity).
Commented
Oct 7, 2018 at 14:08
Can a modulus be negative?
% can be negative as it is the remainder operator, the remainder after division, not after Euclidean_division. Since C99 the result may be 0, negative or positive.
// a % b
7 % 3 --> 1
7 % -3 --> 1
-7 % 3 --> -1
-7 % -3 --> -1
The modulo OP wanted is a classic Euclidean modulo, not %.
I was expecting a positive result every time.
To perform a Euclidean modulo that is well defined whenever a/b is defined, a,b are of any sign and the result is never negative:
int modulo_Euclidean(int a, int b) {
int m = a % b;
if (m < 0) {
// m += (b < 0) ? -b : b; // avoid this form: it is UB when b == INT_MIN
m = (b < 0) ? m - b : m + b;
}
return m;
}
modulo_Euclidean( 7, 3) --> 1
modulo_Euclidean( 7, -3) --> 1
modulo_Euclidean(-7, 3) --> 2
modulo_Euclidean(-7, -3) --> 2
The other answers have explained in C99 or later, division of integers involving negative operands always truncate towards zero.
Note that, in C89, whether the result round upward or downward is implementation-defined. Because (a/b) * b + a%b equals a in all standards, the result of % involving negative operands is also implementation-defined in C89.
According to C99 standard, section 6.5.5 Multiplicative operators, the following is required:
(a / b) * b + a % b = a
The sign of the result of a remainder operation, according to C99, is the same as the dividend's one.
Let's see some examples (dividend / divisor):
(-3 / 2) * 2 + -3 % 2 = -3
(-3 / 2) * 2 = -2
(-3 % 2) must be -1
(3 / -2) * -2 + 3 % -2 = 3
(3 / -2) * -2 = 2
(3 % -2) must be 1
(-3 / -2) * -2 + -3 % -2 = -3
(-3 / -2) * -2 = -2
(-3 % -2) must be -1
6.5.5 Multiplicative operators
Syntax
- multiplicative-expression:
cast-expressionmultiplicative-expression * cast-expressionmultiplicative-expression / cast-expressionmultiplicative-expression % cast-expressionConstraints
- Each of the operands shall have arithmetic type. The operands of the % operator shall have integer type.
Semantics
The usual arithmetic conversions are performed on the operands.
The result of the binary * operator is the product of the operands.
The result of the / operator is the quotient from the division of the first operand by the second; the result of the % operator is the remainder. In both operations, if the value of the second operand is zero, the behavior is undefined.
When integers are divided, the result of the / operator is the algebraic quotient with any fractional part discarded [1]. If the quotient
a/bis representable, the expression(a/b)*b + a%bshall equala.[1]: This is often called "truncation toward zero".
The result of Modulo operation depends on the sign of numerator, and thus you're getting -2 for y and z
Here's the reference
http://www.chemie.fu-berlin.de/chemnet/use/info/libc/libc_14.html
Integer Division
This section describes functions for performing integer division. These functions are redundant in the GNU C library, since in GNU C the '/' operator always rounds towards zero. But in other C implementations, '/' may round differently with negative arguments. div and ldiv are useful because they specify how to round the quotient: towards zero. The remainder has the same sign as the numerator.
In Mathematics, where these conventions stem from, there is no assertion that modulo arithmetic should yield a positive result.
Eg.
1 mod 5 = 1, but it can also equal -4. That is, 1/5 yields a remainder 1 from 0 or -4 from 5. (Both factors of 5)
Similarly, -1 mod 5 = -1, but it can also equal 4. That is, -1/5 yields a remainder -1 from 0 or 4 from -5. (Both factors of 5)
For further reading look into equivalence classes in Mathematics.
a and b, b <> 0. According to the Euclidean division theorem there exists exactly one pair of integers m, r where a = m * b + r and 0 <= r < abs( b ) . The said r is the result of the (mathematical) modulo operation and by definition is non negative. More reading and further links on Wikipedia: en.wikipedia.org/wiki/Euclidean_division
1 mod 5 is always 1. -4 mod 5 might be 1 too, but they are different things.
Modulus operator gives the remainder. Modulus operator in c usually takes the sign of the numerator
Also modulus(remainder) operator can only be used with integer type and cannot be used with floating point.
I believe it's more useful to think of mod as it's defined in abstract arithmetic; not as an operation, but as a whole different class of arithmetic, with different elements, and different operators. That means addition in mod 3 is not the same as the "normal" addition; that is; integer addition.
So when you do:
5 % -3
You are trying to map the integer 5 to an element in the set of mod -3. These are the elements of mod -3:
{ 0, -2, -1 }
So:
0 => 0, 1 => -2, 2 => -1, 3 => 0, 4 => -2, 5 => -1
Say you have to stay up for some reason 30 hours, how many hours will you have left of that day? 30 mod -24.
But what C implements is not mod, it's a remainder. Anyway, the point is that it does make sense to return negatives.
@FelipeC : if you're using the euclidean division approach, then whether you stayed up for 6 hours or 30 hours will still yield -18 (mod -24), which really provides you with no helpful information, since staying up for 6 versus 30 aren't remotely similar to each other.
Commented
Apr 3 at 17:19
30 in integers modulo -24 (ℤ/-24ℤ). The members of this set are themselves a set, so the mathematical object we are talking about is {54, 30, 6, -18, -42}. 6 and 30 are not just equivalent, they are exactly the same mathematical object.
If N is the modulus (ie the divisor), then
(x + N) % N
will simply return the modulo of x.
In other words, as a function:
const modulo = (x, N) => (x + N) % N
Example:
result = modulo(-3, 12) // 9
I was looking for branchless euclidean modulo and this the closest I got:
#include <stdint.h>
int32_t moduloEuclidean(int32_t a, int32_t b)
{
int32_t const int32_width = 32;
int32_t const mod = a % b;
// mod_sign_mask = (mod < 0)? 0b11111111... : 0
int32_t const mod_sign_mask = mod >> (int32_width - 1);
// abs_sign_mask = (b < 0)? 0b11111111... : 0
int32_t const abs_sign_mask = b >> (int32_width - 1);
// abs_value = (b < 0)? (~b - (-1)) : (b - 0)
int32_t const abs_value = (abs_sign_mask ^ b) - abs_sign_mask;
// result = a % b + (a % b < 0? abs(b) : 0)
return mod + (mod_sign_mask & abs_value);
}
Note that this solution relies on 2's complement arithmetic and will work only on those platforms that support it.
I recommend either compiling with -std=c23 or above
or with -fwrapv flag supported by both gcc and clang.
There was a concern that moduloEuclidean(x, 0) has undefined behavior,
however so does euclidean division.
b is INT_MIN and it gets multiply by -1 which also it kinda messes with the result.
abs calculation that's not UB under 2's complement and masked it out when remainder is positive.
int is 32-bit. C spec has a minimum range implying at least 16-bit.
It seems the problem is that / is not floor operation.
int mod(int m, float n)
{
return m - floor(m/n)*n;
}
m converts to float before the division and subtraction and large values incur a precision loss. The division itself readily incurs a precision loss. return fmod(m, n) might be a reasonable alternative, yet using floating point for an integer problem is usually best avoided.
%operator is defined differently in different languages, see en.wikipedia.org/wiki/Modulo#In_programming_languages - there are many definitions, and what C uses is called "Truncated division". (@tcurdt There are more than two, unless you are referring to the existence of two different definitions within C specifically, which is correct, C also supports "Rounded division".)