Is using increment (operator++) on floats bad style?

Question

Is it considered "bad style" to use the increment operator (++) on floats? It compiles just fine but I find it smelly and counter-intuitive.

The question: In what cases is using ++ on float variable justified and better than += 1.0f? If there are no use cases, is there a respectable C++ style guide that explicitly says that ++ on float is evil?

For float ++ does not increment by the smallest possble value, but by 1.0. 1.0f has no special meaning (unlike integer 1). It may confuse the reader causing him to think that the variable is int.

For float it is not guaranteed that operator++ changes the argument. For example the following loop is not infinite:

float i, j;
for (i=0.0, j=1.0; i!=j;i=j++);

Consequently doing ++ immediately after -- does not guarantee that the value is unchanged.

Answer 1

In general ++/-- is not defined for floats, since it's not clear with which value the float should be incremented. So, you may have luck on one system where ++ leads to f += 1.0f but there may be situations where this is not valid. Therefore, for floats, you'll have to provide a specific value.

++/-- is defined as "increment/decrement by 1". Therefore this is applicable to floating point values. However, personally i think, that this can be confusing to someone who isn't aware of this definition (or only applies it to integers), so i would recommend using f += 1.0f.

Answer 2

When you add a lots of 1.0 to a float, because of floating point arithmetic you might be a little off in the end

The best way is to do

for ( int i = 0; i < 100; i++ )
{
     float f = 2.433f + i * 1.0f;

instead of

for ( float f = 2.433f; f < 102.433f; f += 1.0f )

In the second case the floating point arithmetic error adds up and in the first case it doesn't. As certain users have pointed out in comments below adding integrals floats might not accumulate errors but in general it is a good idea to avoid it.

Answer 3

There is nothing wrong with using ++ and -- on float or double operands. It simply adds or subtracts 1. That's what it's for!

Answer 4

It's bad style. ++ and -- are intended to set an lvalue to its next or previous value, like the next or previous integer, the next or previous element in an array (for pointers), the next or previous element in a container (iterators), etc.

Next and previous values are not well-defined for floats. Do f += 1. explicitly.

Answer 5

I realise this is an old question, but I'd like to point out something that none of the other answers have brought up (though some comments have aluded to it).

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For those who can't be bothered to read the full explanation of why the behaviour of ++ and -- may be confusing for some people, I'll cut straight to the main point:

Whether or not a behaviour is well understood by the people working on the code is more important than whether the behaviour is well defined.

In the words of Donald Knuth:

The best programs are written so that computing machines can perform them quickly and so that human beings can understand them clearly.

(Emphasis mine.)

If everyone on your team understands the behaviour then there is a reasonable case to use the operators.

If some of your team struggle with the ++ and -- operators when used in conjunction with floating points and claim that they find += 1 and -= 1 to be more readable then there is a good case to avoid ++ and -- in favour of improving readability for your other team members.

Whilst this is a decision that ought to be made on a per-team basis, personally I would argue that += 1 and -= 1 in the case of floating point types is certainly never less clear than ++ and --, whilst the fact we have answers disagreeing about the clarity of ++ and -- is evidence enough that the meaning is not 'obvious' to everyone.

If there were another compelling reason to prefer ++ and -- (e.g. in the case of iterators only random access iterators support += and -=, hence ++ and -- are more idiomatic) then it would be worth greater debate or consideration, but given that ++ and -- are equivalent to += 1 and -= 1 for floating points, readability should be the sole consideration.

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Why the behaviour may be confusing is a bit of an intricate topic...

While ++ and -- do generally mean += 1 and -= 1 in the context of most arithmetic types, when used with other types that definition doesn't entirely hold and frankly seems a bit of a naive definition.

In the case of iterators ++ and -- mean 'advance iterator' and 'retreat iterator'. One could argue that's a similar behaviour to adding and subtracting 1, but in this situation the '1' is not a concrete entity which can lead to confusion.

Thus for the case of iterators a more appropriate analogy is the idea that ++ means 'next value' and -- means 'previous value' (other languages have a similar idea in the form of succ and pred functions).

For the case of iterators the analogy of 'successor' and 'predecesor' functions holds much better, which is precisely where the confusion comes from - some people take ++ and -- to mean 'successor' and 'predecessor' and in the context of floating point values that would imply adding the 'epsilon' value.

In the case of pointers, whilst technically ++ does means += 1 and -- does mean -= 1, the 1 in this case doesn't actually mean the numerical value of 1, numerically it actually means 1 * sizeof(*pointer) (i.e. advance the pointer by the size of the object it is pointing to).

In the case of non-pointer iterators, there may well be no use of +=. Consider a linked list, where the behaviour of the iterator would be something along the lines of this->pointer = this->pointer->next.

Once again, the idea of the 'successor' and 'predecessor' functions is a better fit than the idea of 'adding one'.

This is where the problem arises with the floating point types (float, double, long double). For those who understand ++ and -- to be the 'successor' and 'predecessor' functions (or 'advance' and 'retreat' if you prefer), the behaviour is not obvious because by that analogy += std::numeric_limits<T>::epsilon and -= std::numeric_limits<T>::epsilon would also be valid implementations.

Another way of looking at this is that 1 is the smallest possible value by which an integer can increase, but 1 is not the smallest possible value by which a floating point value can be increased.

Thus to anyone who understands these alternative analogies the behaviour of ++ and -- on floating point types may be non-obvious, which is precisely why they should be avoided.