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In the C++ Primer book, Chapter (3), there is the following for-loop that resets the elements in the vector to zero.

for (vector<int>::size_type ix = 0; ix ! = ivec.size(); ++ix)
ivec[ix] = 0;

Why is it using vector<int>::size_type ix = 0? Cannot we say int ix = 0? What is the benefit of using the first form on the the second?


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up vote 9 down vote accepted

The C++ Standard says,

 size_type  |  unsigned integral type  |  a type that can represent the size of the largest object in the
allocation model

Then it adds,

Implementations of containers described in this International Standard are permitted to assume that their Allocator template parameter meets the following two additional requirements beyond those in Table 32.

  • The typedef members pointer, const_pointer, size_type, and difference_type are required to be T*,T const*, size_t, and ptrdiff_t, respectively

So most likely, size_type is a typedef of size_t.

And the Standard really defines it as,

template <class T> 
class allocator 
       typedef size_t size_type;

So the most important points to be noted are :

  • size_type is unsigned integral, while int is not necessarily unsigned. :-)
  • it can represent the largest index, because it's unsigned.
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vector<int>::size_type is a type that is guaranteed to hold the size of the biggest vector you may have, and thus it's guaranteed to let you index all the elements of the vector (since indexes go from 0 to size-1); it is the type used for indexes and sizes in all the vector methods.

If you have very big arrays this may be actually relevant, since other integer types may overflow (and if they are signed types things can get quite strange); even if you won't ever get to arrays so big that this may matter, it's fundamentally a code cleanliness thing; moreover, your ix has the same type of ivec.size(), so you don't get warnings for comparing signed and unsigned integers.

Background: vector<T>::size_type is usually a typedef for size_t (I read somewhere that actually the standard implicitly imposes it to be size_t - EDIT: it's not implicit at all, see @Nawaz's answer), which, in turn, is the return type of the sizeof operator. This implicitly says that it can hold the size for the biggest object usable in a C++ application, so it is surely (just) big enough to index arrays of any type.

Actually, I use size_t (defined in <cstddef>) as index also for C-style arrays, and I think it's good practice for exactly the same reasons.

By the way, you may also forget of the type used for indexes altogether and just go with iterators:

for (vector<int>::iterator it = ivec.begin(); it != ivec.end(); ++it)
    *it = 0;

or with iterators+<algorithm>:

std::fill(ivec.begin(), ivec.end(), 0);

These two options work whatever container ivec is, so you don't have to change anything in the code if you decide to change container type.

With vector you can also use the assign method (as suggested in some other answer):

ivec.assign(ivec.size(), 0);
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Do you use size_t or std::size_t? ;-) – fredoverflow Jan 31 '11 at 10:26
std::size_t, there's an implicit using namespace std; at the top of this answer (but not in my code) :P – Matteo Italia Jan 31 '11 at 10:28
When you say vector<int>::size_type is a type that is guaranteed to specify the size of the biggest vector you may have, can you explain it further a bit? Thanks – Simplicity Jan 31 '11 at 10:32
@user588855: sorry it was poor wording, replace "specify" with "hold"; however, I meant that it's guaranteed that the type size_type can store the size (=number of items) of the biggest array you can actually allocate, so, whatever the size of your array is, you're sure that, iterating over it using size_type as index, you won't get any integer overflow problem. – Matteo Italia Jan 31 '11 at 10:36

Yes you can use int, but only the type vector<int>::size_type guarantees that its type can be used to index all vector elements.

It may or may not be the same size as int. Eg, when compiling for 64-bit Windows, int is 32-bit wide, whereas vector<int>::size_type will be 64-bit wide.

Instead of using the rather verbose vector<int>::size_type, you could use std::size_t, as the former is a typedef for the latter. However, if you ever happen to change the container type, then its size_type maybe a different type, and you may have to modify your code if it uses std::size_t.

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more than that, size_type will probably never be int. It will generally be size_t (unsigned int). – rursw1 Jan 31 '11 at 10:20
Yes, I meant that it could be the same size as an int. – Daniel Gehriger Jan 31 '11 at 10:23
Can the size be of types other than int or unsigned int? – Simplicity Jan 31 '11 at 10:26
@Daniel Gehriger. When you say when compiling for 64-bit Windows, int is 32-bit wide, whereas vector<int>::size_type will be 64-bit wide.', but aren't they at the end of type int`. Where is the problem here? Thanks – Simplicity Jan 31 '11 at 10:27
The size of int is implementation dependent. For VisualC++, for instance, see here: As you can see, int is 32-bit, but pointers are 64-bit. See also – Daniel Gehriger Jan 31 '11 at 10:29

You should not use intbecause vector<int>::size_type is an unsigned type, that is, vector indexes its elements with an unsigned type. int however is a signed type and mixing signed and unsigned types can lead to weird problems. (Although it would not be a problem for small n in your example.)

Note that I think it's clearer to just use size_t (as opposed to T::size_type) - less typing and should work on all implementations.

Note also that the for loop you posted:

for(size_t ix=0; ix != ivec.size(); ++ix) ...

would be better written as:

for(size_t i=0, e=ivec.size(); i!=e; ++ix) ...

-- no need to call size() every iteration.

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Actually, I would be very surprised if the assembly code for the first version of your for loop was any more compact than the 2nd. The call to vector<T>::size() will be inlined. – Daniel Gehriger Jan 31 '11 at 10:33
@Fred: I'd agree in the general case. But for the templated std::vector, all code affecting the vector size is clearly visible to the compiler, as it has to specialize it for the element type. I quickly ran a test and, indeed, there isn't a difference. – Daniel Gehriger Jan 31 '11 at 10:43
@Fred: Oh yes, in that case it isn't the same of course. But I believe that @Martin's point was about optimization and my opinion is that this kind of optimization only makes code more difficult to read without actually affecting performance. If the algorithm demands it, then that's another issue. – Daniel Gehriger Jan 31 '11 at 10:51
@Daniel: I won't enter a discussion about the optimizer here. Suffice to say that the second form I posted is my recommended idiomatic use of a C++ for loop. I find it clear what's going on, and it also makes the intention clear that size certainly won't change during the for-loop. – Martin Ba Jan 31 '11 at 11:29
@Martin: Great! I see the point. I do it myself. Like using pre-incrementing ++i when possible even for simple datatypes. – Daniel Gehriger Jan 31 '11 at 13:31

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