10

I have the following Python snippet that I would like to reproduce using C++:

from itertools import count, imap

source = count(1)
pipe1 = imap(lambda x: 2 * x, source)
pipe2 = imap(lambda x: x + 1, pipe1)
sink = imap(lambda x: 3 * x, pipe2)
for i in sink:
    print i

I've heard of Boost Phoenix, but I couldn't find an example of a lazy transform behaving in the same way as Python's imap.

Edit: to clarify my question, the idea is not only to apply functions in sequence using a for, but rather to be able to use algorithms like std::transform on infinite generators. The way the functions are composed (in a more functional language like dialect) is also important, as the next step is function composition.

Update: thanks bradgonesurfing, David Brown, and Xeo for the amazing answers! I chose Xeo's because it's the most concise and it gets me right where I wanted to be, but David's was very important into getting the concepts through. Also, bradgonesurfing's tipped Boost::Range :).

  • 3
    I got this far and realised it wasn't going to happen easily: Python... reproduce in C++... itertools. – Phil H Oct 30 '12 at 17:16
  • Nice; this can certainly be done in C++, though it won't be quite as short. – Kerrek SB Oct 30 '12 at 17:19
  • Small comment on your original code - it would be easier read, in my opinion, with generator expressions rather than imap, since you're only taking values from one iterator at a time. pipe1 = (2*x for x in source). – Benjamin Hodgson Oct 30 '12 at 17:20
  • Moreover, your code would be better (simpler, faster, etc) as a single expression, rather than lots of nested iterators. sink = (3 * (2*x + 1) for x in count(1)) – Benjamin Hodgson Oct 30 '12 at 17:22
  • Yes, generator expressions would be simpler to read, @poorsod (and more 'Pythonic'). This is just a simple example to illustrate what I want to accomplish in C++. Please note that the resulting 'pipeline' would be (way) more complex :). – bruno nery Oct 30 '12 at 17:24
12

Employing Boost.Range:

int main(){
  auto map = boost::adaptors::transformed; // shorten the name
  auto sink = generate(1) | map([](int x){ return 2*x; })
                          | map([](int x){ return x+1; })
                          | map([](int x){ return 3*x; });
  for(auto i : sink)
    std::cout << i << "\n";
}

Live example including the generate function.

  • That's beautiful, Xeo! And short! What are you using to compile the example, though? I'm getting errors with gcc 4.6.1 and boost 1.51 (using -std=c++0x). – bruno nery Oct 30 '12 at 19:02
  • I replaced using generate_range = boost::iterator_range<generate_iterator>; with typedef boost::iterator_range<generate_iterator>; and it works :). What kind of dialect is the first one, Xeo? – bruno nery Oct 30 '12 at 19:05
  • @bruno: C++11 dialect. ;) GCC 4.6 didn't implement using aliases, it seems. And I used GCC 4.7.2, as can be seen in the example link. – Xeo Oct 30 '12 at 19:12
  • This is very cool with one small failing. Its pretty hard to figure out the type of sink. Thus if you want to return it from a function you need to declare the type. I came across a polymorphic range/iterator library once that erases the complex type. There was a small performance hit. – bradgonesurfing Oct 30 '12 at 20:58
  • 1
    @brad: If you're using normal functors, the trailing-return-type works wonders here. Sadly, lambdas aren't allowed inside of decltype, so it's not applicable here. What you can use, though, is boost::any_range. – Xeo Oct 30 '12 at 21:11
4

I think the most idiomatic way to do this in C++ is with iterators. Here is a basic iterator class that takes an iterator and applies a function to its result:

template<class Iterator, class Function>
class LazyIterMap
{
private:
    Iterator i;
    Function f;
public:
    LazyIterMap(Iterator i, Function f) : i(i), f(f) {}
    decltype(f(*i)) operator* () { return f(*i); }
    void operator++ () { ++i; }
};

template<class Iterator, class Function>
LazyIterMap<Iterator, Function> makeLazyIterMap(Iterator i, Function f)
{
    return LazyIterMap<Iterator, Function>(i, f);
}

This is just a basic example and is still incomplete as it has no way to check if you've reached the end of the iterable sequence.

Here's a recreation of your example python code (also defining a simple infinite counter class).

#include <iostream>

class Counter
{
public:
    Counter (int start) : value(start) {}
    int operator* () { return value; }
    void operator++ () { ++value; }
private:
    int value;
};

int main(int argc, char const *argv[])
{
    Counter source(0);
    auto pipe1 = makeLazyIterMap(source, [](int n) { return 2 * n; });
    auto pipe2 = makeLazyIterMap(pipe1, [](int n) { return n + 1; });
    auto sink = makeLazyIterMap(pipe2, [](int n) { return 3 * n; });
    for (int i = 0; i < 10; ++i, ++sink)
    {
        std::cout << *sink << std::endl;
    }
}

Apart from the class definitions (which are just reproducing what the python library functions do), the code is about as long as the python version.

  • Apart from your exapmle typo, this looks very interesting (and simple). I wonder if a (possibly Boost) library exists that allow me to do this (and possibly much more :)). I'm looking into Boost::Rangex right nowm, as bradgonesurfing suggested. – bruno nery Oct 30 '12 at 18:07
  • @brunonery boost's transform iterator is probably worth looking into. – David Brown Oct 30 '12 at 18:15
  • I looked into transform iterators and they are very promising. However, the fact that you have to specify the input iterator type confuses me. How would you specify a transform_iterator that works on another transform_iterator? Like rewriting this example using transform_iterator :) – bruno nery Oct 30 '12 at 18:27
  • @brunonery look at the example on the boost page, it very similar to this. In my code you can almost just replace makeLazyIterMap with boost::make_transform_iterator. However my counter class isn't compatable with boosts standard iterators it seems. If you replace it with one of boosts ranges it should work. – David Brown Oct 30 '12 at 18:41
2

I think the boost::rangex library is what you are looking for. It should work nicely with the new c++lambda syntax.

2
int pipe1(int val) {
    return 2*val;
}

int pipe2(int val) {
    return val+1;
}

int sink(int val) {
    return val*3;
}

for(int i=0; i < SOME_MAX; ++i)
{
    cout << sink(pipe2(pipe1(i))) << endl;
}

I know, it's not quite what you were expecting, but it certainly evaluates at the time you want it to, although not with an iterator iterface. A very related article is this:

Component programming in D

Edit 6/Nov/12:

An alternative, still sticking to bare C++, is to use function pointers and construct your own piping for the above functions (vector of function pointers from SO q: How can I store function pointer in vector?):

typedef std::vector<int (*)(int)> funcVec;
int runPipe(funcVec funcs, int sinkVal) {
    int running = sinkVal;
    for(funcVec::iterator it = funcs.begin(); it != funcs.end(); ++it) {
        running = (*(*it))(running); // not sure of the braces and asterisks here
    }
    return running;
}

This is intended to run through all the functions in a vector of such and return the resulting value. Then you can:

funcVec funcs;
funcs.pushback(&pipe1);
funcs.pushback(&pipe2);
funcs.pushback(&sink);

for(int i=0; i < SOME_MAX; ++i)
{
    cout << runPipe(funcs, i) << endl;
}

Of course you could also construct a wrapper for that via a struct (I would use a closure if C++ did them...):

struct pipeWork {
     funcVec funcs;
     int run(int i);
};

int pipeWork::run(int i) {
    //... guts as runPipe, or keep it separate and call:
    return runPipe(funcs, i);
}

// later...
pipeWork kitchen;
kitchen.funcs = someFuncs;
int (*foo) = &kitchen.run();

cout << foo(5) << endl;

Or something like that. Caveat: No idea what this will do if the pointers are passed between threads.

Extra caveat: If you want to do this with varying function interfaces, you will end up having to have a load of void *(void *)(void *) functions so that they can take whatever and emit whatever, or lots of templating to fix the kind of pipe you have. I suppose ideally you'd construct different kinds of pipe for different interfaces between functions, so that a | b | c works even when they are passing different types between them. But I'm going to guess that that's largely what the Boost stuff is doing.

  • Well, your code is not lazy. – Vlad Oct 30 '12 at 17:20
  • Specially because I cannot use an infinite generator there. – bruno nery Oct 30 '12 at 17:22
  • @Vlad: it is lazy in the sense that you call the functions when you are about to push the value out, rather than generating lists of intermediate values; the memory requirement is just one value at a time. However, it is not lazy in the sense that evaluation can be separated from the declaration. – Phil H Oct 30 '12 at 17:38
  • That's interesting, PhilH - but D is not an option, unfortunately. Is there something as components for C++? – bruno nery Oct 30 '12 at 17:50
  • @brunonery: that's what I've been hoping for for some time. – Phil H Oct 30 '12 at 19:44
-3

Depending on the simplicity of the functions :

#define pipe1(x) 2*x
#define pipe2(x) pipe1(x)+1

#define sink(x) pipe2(x)*3

int j = 1
while( ++j > 0 )
{
    std::cout << sink(j) << std::endl;
}
  • This looks very close to PhilH answer above, but 1. you don't even call the pipeline anywhere and 2. ++j, when j=1, will always be >0. – bruno nery Oct 30 '12 at 17:31
  • 1. OK typo error, you shoud read cout << sink(j) << end; 2. I know it is an infinite loop, it was just to recreate the count(1) which don't end neither. The solution is close to PhilH's one, but I think preprocessor directives closer to Python lambda expression than function IMHO – lucasg Oct 30 '12 at 17:38

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