# C++ boost or STL `y += f(x)` type algorithm

I know I can do this `y[i] += f(x[i])` using transform with two input iterators. however it seems somewhat counterintuitive and more complicated than for loop.

Is there a more natural way to do so using existing algorithm in boost or Stl. I could not find clean equivalent.

here is transform (y = y + a*x):

``````using boost::lambda;
transform(y.begin(), y.end(), x.begin(), y.begin(), (_1 + scale*_2);
//  I thought something may exist:
transform2(x.begin(), x.end(), y.begin(), (_2 + scale*_1);
// it does not, so no biggie. I will write wrapper
``````

Thanks

-
What are trying to write? – AraK Apr 30 '10 at 14:29
@Arak I have few daxpy-like loops I would like to C++-ize – Anycorn Apr 30 '10 at 14:31
It would help if you'd show in your question an example of a call to transform() that you find "counterintuitive and more complicated than for loop" – Éric Malenfant Apr 30 '10 at 14:32
The code you presented so far would compile just fine as-is (assuming x, y, i, and f are properly defined. That pretty much leaves everyone mystified as to what you need transform for. – T.E.D. Apr 30 '10 at 14:49
For something this simple, stick with the for loop. It works, and it's easy to read and understand. Trying to do a simple task like this with a transform and a functor would needlessly complicate it, and make it harder for the maintenance programmer to read. – Tim Apr 30 '10 at 15:48

There are several ways to do this.

As you noted you can use `transform` with a number of predicates, some more or less automatically generated:

``````std::vector<X> x = /**/;
std::vector<Y> y = /**/;

assert(x.size() == y.size());

//
// STL-way
//
struct Predicate: std::binary_function<X,Y,Y>
{
Y operator()(X lhs, Y rhs) const { return rhs + f(lhs); }
};

std::transform(x.begin(), x.end(), y.begin(), y.begin(), Predicate());

//
// C++0x way
//
std::transform(x.begin(), x.end(), y.begin(), y.begin(),
[](X lhs, Y rhs) { return rhs += f(lhs); });
``````

Now, if we had a `vector` with the range of indices, we could do it in a more "pythony" way:

``````std::vector<size_t> indices = /**/;

//
// STL-way
//
class Predicate: public std::unary_function<size_t, void>
{
public:
Predicate(const std::vector<X>& x, std::vector<Y>& y): mX(x), mY(y) {}
void operator()(size_t i) const { y.at(i) += f(x.at(i)); }
private:
const std::vector<X>& mX;
std::vector<Y>& mY;
};

std::foreach(indices.begin(), indices.end(), Predicate(x,y));

//
// C++0x way
//
std::foreach(indices.begin(), indices.end(), [&](size_t i) { y.at(i) += f(x.at(i)); });

//
// Boost way
//
BOOST_FOREACH(size_t i, indices) y.at(i) += f(x.at(i));
``````

I don't know if there could be something to do with views, they normally allow some pretty syntax. Of course it's a bit difficult here I think because of the self-modifying `y`.

-
+1 for suggesting newer syntaxes, but still staying correct in the current standard. – Billy ONeal Apr 30 '10 at 15:50
`Predicate` is a function that returns `bool`. Use `UnaryFunction` or `BinaryFunction` names here. – J.F. Sebastian Apr 30 '10 at 18:44
@J.F. Sebastian: I guess I am more lax, I usually use Predicate for any reified action, I usually think of it like in en.wikipedia.org/wiki/Lojban :) – Matthieu M. May 1 '10 at 12:10

Disclaimer: I have no practical experience with valarray, so please don't take this answer as an "advice", but more as a "request for comments". In particular, I have no idea of how efficient this would be. But I'm curious as the notation seems pretty intuitive to me:

With x and y being `valarray<int>` and with a function `int f(int)`, would:

``````y += x.apply(&f);
``````

do what you want?

-
seems the `y` and `x` are mixed up, `y[i] = f(x[i])` – Matthieu M. Apr 30 '10 at 15:44
@Matthieu: Fixed, thanks – Éric Malenfant Apr 30 '10 at 15:51
thanks.unfortunately I have to work with memory already allocated – Anycorn Apr 30 '10 at 18:30

What is wrong with a simple loop?

``````for (size_t i = 0; i < n; ++i)
y[i] += f(x[i]);
``````

In general even in Fortran it would be:

``````forall(i=0:n) y(i) += f(x(i))
``````

Though with restrictions on `f`, `x`, `y` it could be written as:

``````y += f(x)
``````

`transform()` variant is more generic and verbose:

``````std::transform(boost::begin(y), boost::end(y), boost::begin(x),
boost::begin(y), _1 += bind(f, _2));
``````

It might be possible to write `zip()` using `boost::zip_iterator`:

``````foreach (auto v, zip(y, z))
v.get<0>() += f(v.get<1>());
``````

where `foreach` is `BOOST_FOREACH`.

Here's variant similar to @Matthieu M.'s indices:

``````foreach (size_t i, range(n)) // useless compared to simple loop
y[i] += f(x[i]);
``````

### Possible `range()` Implementation

``````template<class T, class T2>
std::pair<boost::counting_iterator<T>,
boost::counting_iterator<T> >
range(T first, T2 last) {
return std::make_pair(boost::counting_iterator<T>(first),
boost::counting_iterator<T>(last));
}

template<class T>
std::pair<boost::counting_iterator<T>,
boost::counting_iterator<T> >
range(T last) {
return range<T>(0, last);
}
``````

### Draft (broken) `zip()` Implementation

``````template<class Range1, class Range2>
struct zip_return_type {
typedef boost::tuple<
typename boost::range_iterator<Range1>::type,
typename boost::range_iterator<Range2>::type> tuple_t;

typedef std::pair<
boost::zip_iterator<tuple_t>,
boost::zip_iterator<tuple_t> > type;
};

template<class Range1, class Range2>
typename zip_return_type<Range1, Range2>::type
zip(Range1 r1, Range2 r2) {
return std::make_pair(
boost::make_zip_iterator(
boost::make_tuple(boost::begin(r1), boost::begin(r2))),
boost::make_zip_iterator(
boost::make_tuple(boost::end(r1), boost::end(r2))));
}
``````
-
hello. overall, I agree with you. there is a number of indices already in function, and trying to reduce visual complexity little bit. to me, transform looks more self-contained. – Anycorn May 1 '10 at 0:55

You have two ways. I suppose `y` is some kind of your own container following the `iterator` idea.

The first way is to write another routine that takes `y`, `x` and some functor as a param. Generally it would do the same `y[i] += f(x[i])` stuff, but if you name it correctly, this would make your code cleaner and easier to understand.

Another way is operator `+=` (or `+`, or better together) overloading so that (let's say `y` has a `container` type) it would look the following way:

``````container& operator+ (functor_type& functor)
``````

Here your functor should be a struct / class declared the following way:

``````class functor {
private:
container c;
public:
functor (container& c) : c(c) { }
container operator() (void) { (...) - your actions on container here }
};
``````

This way you could write `y += f(x)` and it would be ok. However, I wouldn't recommend this way of managing your code, because all these operator overloads on your own datatypes generally make the code harder to understand.

-
Sorry, but -1. It may be confusing for you, but it is the correct way to use the STL. You should prefer algorithm calls to explicit loops. – Billy ONeal Apr 30 '10 at 15:03
@Billy I suspect you have given -1 to the answer when you wanted to give it to the answer – Vicente Botet Escriba Apr 30 '10 at 15:39
@Vicente: What? (Is that a typo?) – Billy ONeal Apr 30 '10 at 15:48