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In this question I see following:

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

I understand that why int is not used here, but why not just use size_t?

Under what circumstances I should use vector<int>::size_type instead of size_t?

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1  
When you're iterating through a vector. (In this case.) –  user529758 Jun 23 '13 at 5:53
1  
and when you want to be pedantic –  David Brown Jun 23 '13 at 5:56
    
It's more explicit. Not everyone knows they're really the same. –  chris Jun 23 '13 at 5:58
    
Don't roll your own loops if you can avoid it. The right thing here would be to write std::fill(ivec.begin(), ivec.end(), 0); –  user515430 Jun 23 '13 at 6:57

4 Answers 4

up vote 6 down vote accepted

The primary time to use size_type is in a template. Although std::vector<T>::size-type is usually size_t, some_other_container<T>::size_type might be some other type instead. One of the few things a user is allowed to add to the std namespace is a specialization of an existing template for some user defined type. Therefore, std::vector<T>::size_type for some oddball T could actually be some type other than size_t, even though the base template defined in the standard library probably always uses size_t.

Therefore, if you want to use the correct type for a specific container inside a template that works with that container, you want to use container::size_type instead of just assuming size_t.

Note, however, that generic code should rarely work directly with a container. Instead, it should typically work with iterators, so instead of container<T>::size_type, it would typically use something like std::iterator_traits<WhateverIterator>::difference_type instead.

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"Today I've Learned." –  Bartek Banachewicz Jun 23 '13 at 11:07

One reason to use it is consistency. While it is true that size_t is sufficient to index/count a std::vector, it conceptually insufficient to index/count a std::list or any other non-array based container. So, when working with containers, you should typically use container_type::size_type.

In generic code, when the actual type of the container is not known, you have no choice but to use container_type::size_type. And even in specific code, when the container is known to be a std::vector, there's no need to make an exception and suddenly switch to size_t.

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"it conceptually insufficient to index/count a std::list or any other non-array based container". Interesting, but I would like to know the why? What is the reason? –  Nawaz Jun 23 '13 at 6:28
1  
@Nawaz: size_t can accomodate the size of the largest possible continous object. This is why it is always sufficient for an array. However, there's no guarantee that size_t is large enough to accomodate the size of the whole available memory. If the contaner is not requred to be continous, it can potentially contain more small elements than size_t can count. A classic example would be old segmented memory platforms, like DOS or Win16. Their size_t in standard memory model was only 16 bits wide, while the available memory space was much greater than 64K. –  AndreyT Jun 23 '13 at 7:29
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On a segmented platform with such memory model you can't have an array larger than 64K, but you can easily have a list with more than 64K elements. Integer type that shold be large enough to count anything is actually uintptr_t, not size_t. –  AndreyT Jun 23 '13 at 7:31
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@Nawaz: That is exactly how I draw that conclusion. The language does not guarantee that you can declare an object that is as large as the entire memory. (Again, in standard DOS memory model one was not allowed to declare an array or struct larger than 64K, while the total amount of memory was much greater than 64K). Any modern 64 bit implementation is free to restrict object size by, say, 4G and use 32 bit size_t. Such implementation can still be conforming. –  AndreyT Jun 23 '13 at 9:21
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Platforms with segmented memory model still exist today. AFAIK, some IBM mainframes use 128 bit memory split into 64 bit segments, with max object size limited at 64 bit boundary. size_t is a 64 bit type, but you can create a list with more than 2^64 elements. –  AndreyT Jun 23 '13 at 9:22

From: C++ - vector<int>::size_type

"size_type is a (static) member type of the type vector<int>. Usually, it is a typedef for std::size_t, which itself is usually a typedef for unsigned int or unsigned long long."

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i think they are same.

typedef typename Allocator::size_type size_type;
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"Your fallacy is anecdotal evidence" –  sehe Jun 23 '13 at 11:51

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