I have the following question concerning the ranges library in C++20:
Let std::ranges::contiguous_range<T>
for an arbitrary type T.
Can I assume std::ranges::sized_range<T>
?
I have the following question concerning the ranges library in C++20:
Let std::ranges::contiguous_range<T>
for an arbitrary type T.
Can I assume std::ranges::sized_range<T>
?
No, not every contiguous_range
is a sized_range
.
The simplest example is a null-terminated string. It's contiguous, but we don't know its size in O(1)
time. And we can easily represent such a thing using sentinels:
struct ntbs_sentinel {
bool operator==(char const* p) const {
return *p == '\0';
}
};
struct ntbs {
char const* p;
char const* begin() const { return p; }
ntbs_sentinel end() const { return {}; }
};
static_assert(std::ranges::contiguous_range<ntbs>);
static_assert(!std::ranges::sized_range<ntbs>);
noexcept
, add constexpr
, and use cast to bool
instead of comparison to some literal.
– Deduplicator
Oct 20 at 14:24
value_type
) had a conversion to bool
, and that conversion meant that the end of the list had been reached. Considering how rare this is for ranges, it's probably best to be less generic and more explicit about what you're doing.
– Nicol Bolas
Oct 20 at 15:43
value_type
.
– Nicol Bolas
Oct 20 at 16:50
Being a contiguous_range<T>
is insufficient to be considered a sized_range<T>
, due to the presence of a sentinel. However, if you combine contiguous_range<T>
with common_range<T>
(which requires that the sentinel is an iterator), then sized_range<T>
must also be true.
Here's the logic. A contiguous_range<T>
is also a random_access_range<T>
. And a random_access_range<T>
means in part that random_access_iterator<iterator_t<T>>
is true. common_range<T>
means that is_same<iterator_t<T>, sentinel_t<T>>
. Therefore, random_access_iterator<sentinel_t<T>>
must also be true.
Now, random_access_iterator<It>
imposes a requirement that std::sized_sentinel_for<I, I>
is true. Since iterator_t<T>
and sentinel_t<T>
are the same type, this means that std::sized_sentinel_for<sentinel_t<T>, iterator_t<T>>
must also be true.
So, let's look at sized_range<T>
. This requires that std::ranges::size(t)
is valid for a t
of type T
.
ranges::size<T>
is valid if T
models ranges::forward_range<T>
(which it does) and sentinel_t<T>
and iterator_t<T>
models std::sized_sentinel_for<sentinel_t<T>, iterator_t<T>>
.
Which as previously stated, it does.
No.
contiguous_range
is:
template<class T>
concept contiguous_range =
ranges::random_access_range<T> &&
std::contiguous_iterator<ranges::iterator_t<T>> &&
requires(T& t) {
{ ranges::data(t) } ->
std::same_as<std::add_pointer_t<ranges::range_reference_t<T>>>;
};
and, as you can see, it requires
random_access_range
, which is:
template<class T>
concept random_access_range =
ranges::bidirectional_range<T> && std::random_access_iterator<ranges::iterator_t<T>>;
which, on the other hand, requires
bidirectional_range
, which is:
template<class T>
concept bidirectional_range =
ranges::forward_range<T> && std::bidirectional_iterator<ranges::iterator_t<T>>;
which requires
forward_range
, that is:
template<class T>
concept forward_range =
range::input_range<T> && std::forward_iterator<ranges::iterator_t<T>>;
and that requires
input_range
, so it needs:
template<class T>
concept input_range =
ranges::range<T> && std::input_iterator<ranges::iterator_t<T>>;
while range
only requires
that std::ranges::begin()
and std::ranges::end()
are valid for given T
.
You can play a similar game with those std::XXX_iterator
s. Nowhere there is anything for std::ranges::size
(which enables sized_range
).
For example, you may have an infinite stream of data in a form of a range, that is random access (you can skip to any element with O(1)
), but, given that the data is infinite, it cannot be a sized_range
.