You can also use the then
function proposed by Herb Sutter. Here is a slightly modified version of the function. More information about how it was modified and a link to the original talk can be found in this SO question. Your code would boil down to:
return then(std::move(component), [](Component c) { return Item(c); });
The original idea is to have the function then
as a member function of std::future<T>
and there is some ongoing work of putting it into the standard. The second version of the function is for void
futures (essentially just chaining functions asynchronously). As Herb pointed out, you might pay for using this approach by potentially needing an extra thread.
Your code would look like this:
#include <future>
#include <thread>
#include <iostream>
template <typename T, typename Work>
auto then(std::future<T> f, Work w) -> std::future<decltype(w(f.get()))>
{
return std::async([](std::future<T> f, Work w)
{ return w(f.get()); }, std::move(f), std::move(w));
}
template <typename Work>
auto then(std::future<void> f, Work w) -> std::future<decltype(w())>
{
return std::async([](std::future<void> f, Work w) -> decltype(w())
{ f.wait(); return w(); }, std::move(f), std::move(w));
}
struct Component { };
struct Item {
Item(Component component) : comp(component) {}
Component comp;
};
struct Factory {
static std::future<Item> get_item() {
std::future<Component> component = get_component();
return then(std::move(component), [](Component c) { return Item(c); });
}
static std::future<Component> get_component()
{
return std::async([](){ return Component(); });
}
};
int main(int argc, char** argv)
{
auto f = Factory::get_item();
return 0;
}
The above code compiles fine with clang and libc++ (tested on Mac OS X 10.8).