What is double evaluation and why should it be avoided?

I was reading that in C++ using macros like

#define max(a,b) (a > b ? a : b)

can result in a 'double evaluation'. Can someone give me an example of when a double evaluation occurs and why it's bad?

P.S.: Surprisingly I couldn't find any detailed explanation when googling for it except for an example in Clojure (which I can't understand).

• I would have interpreted that otherwise: if a and b are complex or function calls they would be evaluated more than once. Not good for performance and may even generate bugs. – Jean-François Fabre Sep 11 '16 at 18:18
• What if a or b were a function call with side effects? What if a or b were x++ or ++x? – James McLaughlin Sep 11 '16 at 18:19
• Also related to side effects in macro arguments: stackoverflow.com/a/18885626/103167 – Ben Voigt Sep 11 '16 at 18:27
• @BenVoigt OK, I see now what they mean: If a is ((throw 0), 0), then surely a is only evaluated once and b is evaluated once or zero times. You are right, there is a possibility that neither is evaluated twice. – Johannes Schaub - litb Sep 11 '16 at 18:28
• Consider: pips = max (rand(), 5) + 1; // rolling a die. Is this guaranteed to return an integer in [1,6]? Not if max() is a macro that involves double evaluation. – njuffa Sep 11 '16 at 19:09

Imagine you wrote this:

#define Max(a,b) (a < b ? b : a)

int x(){ turnLeft();   return 0; }
int y(){ turnRight();  return 1; }

then called it like this:

auto var = Max(x(), y());

Do you know that turnRight() will be executed twice? That macro, Max will expand to:

auto var = (x() < y() ? y() : x());

After evaluating the condition x() < y(), the program then takes the required branch between y() : x(): in our case true, which calls y() for the second time. See it Live On Coliru.

Simply put, passing an expression as an argument to your function-like macro, Max will potentially evaluate that expression twice, because the expression will be repeated where ever the macro parameter it takes on, is used in the macro's definition. Remember, macros are handled by the preprocessor.

So, bottom line is, do not use macros to define a function (actually an expression in this case) simply because you want it to be generic, while it can be effectively done using a function templates

PS: C++ has a std::max template function.

• What is the resolution for the example? Is there a max thingy in the C++ standard library? Depending on the C++ standard version (e.g. C++14)? – Peter Mortensen Sep 12 '16 at 1:08
• @PeterMortensen There has always been a std::max template function in C++, though it's been modified to reflect changes in recent C++ version – WhiZTiM Sep 12 '16 at 1:22
• @PatrickM'Bongo: Both points appear to be rather meaningless. std::max<double>(12.f, 13.) is the normal way to disambiguate this. And no function can extend the lifetime of its arguments, that's not how C++ works. Not that it really matters: the reference doesn't dangle until the end of the full expression anyway. It only matters if you use it to initialize another reference, and at that point you obviously are responsible for your reference. – MSalters Sep 12 '16 at 8:59
• @MSalters No, in the sane case you return as common_type_t<Ts...>, because that's free with ?:. – Griwes Sep 12 '16 at 9:11
• Note in C gcc and clang support an extension called statement expressions which can be used to avoid the double evaluation issue. In C++ we have other techniques available. – Shafik Yaghmour Sep 12 '16 at 15:31

a and b occur two times in the macro definition. So if you use it with arguments that have side-effects, the side-effects are executed two times.

max(++i, 4);

will return 6 if i = 4 before the call. As it is not the expected behavior, you should prefer inline functions to replace such macros like max.

• Also, this is not an undefuned behaviour ((++i) < (4) ? (++i) (4)), because there is a sequence point after evaluating first ++i. However, using several increments on the same variable on the same line is probably not a good idea in general. – Daerdemandt Sep 12 '16 at 18:14

Consider the following expression:

x = max(Foo(), Bar());

Where Foo and Bar are like this:

int Foo()
{
// do some complicated code that takes a long time
return result;
}

int Bar()
{
global_var++;
return global_var;
}

Then in the original max expression is expanded like:

Foo() > Bar() ? Foo() : Bar();

In either case, Foo or Bar is going to executed twice. Thereby taking longer than necessary or changing the program state more than the expected number of times. In my simple Bar example, it doesn't return the same value consistently.

The macro language in C and C++ is processed by a dedicated parser at the 'pre-processing' stage; the tokens are translated and the output is then fed into the input stream of the parser proper. #define and #include tokens are not recognized by the C or C++ parsers themselves.

This is important because it means that when a macro is said to be "expanded" it means literally that. Given

#define MAX(A, B) (A > B ? A : B)

int i = 1, j = 2;
MAX(i, j);

what the C++ parser sees is

(i > j ? i : j);

However if we use the macro with something more complex, the same expansion happens:

MAX(i++, ++j);

is expanded to

(i++ > ++j ? i++ : ++j);

If we pass something that makes a function call:

MAX(f(), g());

this will expand to

(f() > g() ? f() : g());

If the compiler/optimizer can demonstrate that f() has no side-effects, then it will treat this as

auto fret = f();
auto gret = g();
(fret > gret) ? fret : gret;

If it can't, then it will have to call f() and g() twice, for example:

#include <iostream>

int f() { std::cout << "f()\n"; return 1; }
int g() { std::cout << "g()\n"; return 2; }

#define MAX(A, B) (A > B ? A : B)

int main() {
MAX(f(), g());
}

Live demo: http://ideone.com/3JBAmF

Similarly if we were calling an extern function, the optimizer may not be able to avoid calling the function twice.