# Create a vector of int from a vector of points with C++11

I have a simple point structure

``````struct mypoint
{
int x;
int y;
};
``````

and a `vector` of `mypoint`s

``````vector<mypoint> myvector;
``````

If I want to create a vector of `int` containing all the coordinates of my points (i.e. `x1`, `y1`, `x2`, `y2`, `x3`, `y3`, ...), I could easily do it in the following way

``````vector<mypoint>::iterator pt, ptend(myvector.end());
vector<int> newvector;

for(pt=myvector.begin(); pt!=ptend; ++pt)
{
newvector.push_back(pt->x);
newvector.push_back(pt->y);
}
``````

Is there a way to obtain the same result in one (or two) line(s) of code using the C++11?

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"Make it a function" is not applicable? Your code is very readable as it stands. Do you want to sacrifice that? –  Drew Dormann Mar 27 at 15:44
you can make it prettier by using `auto pt = myvector.begin()`. For perfomance you may reserve or resize `newvector` and use `cbegin()` and `cend` in the loop. –  stefan Mar 27 at 15:47
@DrewDormann It was just to explore some new functions of the C++11 unknown to me. I agree that make the code unreadable is not a good idea. –  888 Mar 27 at 16:01
Just as a side note: the data managed by `newvector` will probably end up being binary equal to the data managed by `myvector` (assuming the struct is densely packed). If you're just doing this conversion so you can pass your data to a C function expecting an `int*`, you might just get away with passing `myvector`s data, avoiding the copy completely. –  reima Mar 27 at 16:01
@reima Good remark! –  888 Mar 27 at 16:03

``````std::vector<int> extractIntsFromPoints(const std::vector<mypoint>& pointVector)
{
std::vector<int> retVector;
for (const auto& element : pointVector)
{
retVector.push_back(element.x);
retVector.push_back(element.y);
}
return retVector;
}
``````

Call this function where you need the int vector. I threw in the range-based for loop to make it extra C++11.

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Since you're using C++11, you can use the new for syntax.

``````vector<int> newvector;

for( const auto &pt : myvector)
{
newvector.push_back(pt.x);
newvector.push_back(pt.y);
}
``````
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You beat me to it, so I'm deleting my answer. –  bstamour Mar 27 at 15:48
`pt->x` and `pt->y` should be `pt.x` and `pt.y` respectively. –  reima Mar 27 at 15:52
@reima Thank you! –  Drew Dormann Mar 27 at 15:56

steal from the post: C++ std::transform vector of pairs->first to new vector

``````vector<int> items;
std::transform(pairs.begin(),
pairs.end(),
std::back_inserter(items),
[](const std::pair<int, int>& p) { return p.first; });
``````
-

Here's about 4 lines, using a lambda:

``````vector<mypoint> points;
vector<int> iv;

points.push_back(mypoint(1,2));
points.push_back(mypoint(3,4));
points.push_back(mypoint(5,6));

for_each(points.cbegin(), points.cend(),
[&iv](const mypoint &pt) {
iv.push_back(pt.x);
iv.push_back(pt.y);
});
``````
-

You could use a `std::pair<>` in which you push the coordinates using `std::make_pair` and then push the `std::pair<>` into the vector such as:

``````mypoint a_point;
std::pair<int, int> point = std::make_pair(a_point.x, a_point.y);
vector<std::pair<int, int>> vec.push_back(point).
``````

Perhaps bulky but in two lines it works well and encapsulates a point rather than separating the magnitudes of each point axis and placing them inside a `std::vector`.

-

As reima already noted, if you only want to reference the existing sequence, it is sufficient to cast `myvector.data()` to `int*` (assuming `sizeof(mypoint) == 2 * sizeof(int)` holds). However, if you explicitly want a copy of the flattened sequence, you are probably better off creating a small utility function like this:

``````    template <typename T, typename U>
std::vector<T> flatten(std::vector<U> const& other) {
static_assert(std::is_trivially_copyable<U>::value,
"source type must be trivially copyable!");
static_assert(std::is_trivially_copy_constructible<T>::value,
"destination type must be trivially copy constructible!");
static_assert((sizeof(U) / sizeof(T)) * sizeof(T) == sizeof(U),
"sizeof(U) must be a multiple of sizeof(T)!");

return std::vector<T>(reinterpret_cast<T const*>(other.data()),
reinterpret_cast<T const*>(std::next(other.data(), other.size())));
}

template <typename U>
std::vector<typename U::value_type> flatten(std::vector<U> const& other) {
return flatten<typename U::value_type>(other);
}
``````

``````    auto newvector = flatten<int>(myvector);
``````

or - if you equip your `mypoint` `struct` with a (STL-conforming) `value_type` member type - even to

``````    auto newvector = flatten(myvector);
``````

Note, that this utility function is nothing more than a tweaked constructor using the inherently unsafe `reinterpret_cast` to convert `mypoint` pointers into `int` pointers. To get rid of the safety caveats that go along with the use of `reinterpret_cast`, the `flatten` function uses some `static_assert` parachutes. So, it's better to hide all this in a seprate function. Still, it uses a lot of C++11 features like `auto`, move construction, `static_assert`, type traits, `std::next` and `vector::data()` which pretty much strips down your call site code to a bare minimum.

Also, this is as efficient as it gets because the range constructor of `vector` will only perform the memory allocation and call `uninitialized_copy`, which will probably boil down to a call of `memcpy` for trivially copyable types.

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