The right way to do memoization in C++ is to mix the Y-combinator in.
Your base function needs a modification. Instead of calling itself directly, it takes a templateized reference to itself as its first argument (or, a std::function<Same_Signature>
recursion as its first argument).
We start with a Y-combinator. Then we add in a cache on the operator()
and rename it to memoizer
, and give it a fixed signature (for the table).
The only thing left is to write a tuple_hash<template<class...>class Hash>
that does a hash on a tuple.
The type of the function that can be memoized is (((Args...)->R), Args...) -> R
, which makes the memoizer of type ( (((Args...) -> R), Args...) -> R ) -> ((Args...) -> R)
. Having a Y-combinator around to produce a 'traditional' recursive implementation can also be useful.
Note that if the function memoized modifies its args during a call, the memoizer will cache the results in the wrong spot.
struct wrap {};
template<class Sig, class F, template<class...>class Hash=std::hash>
struct memoizer;
template<class R, class...Args, class F, template<class...>class Hash>
struct memoizer<R(Args...), F, Hash> {
using base_type = F;
private:
F base;
mutable std::unordered_map< std::tuple<std::decay_t<Args>...>, R, tuple_hash<Hash> > cache;
public:
template<class... Ts>
R operator()(Ts&&... ts) const
{
auto args = std::make_tuple(ts...);
auto it = cache.find( args );
if (it != cache.end())
return it->second;
auto&& retval = base(*this, std::forward<Ts>(ts)...);
cache.emplace( std::move(args), retval );
return decltype(retval)(retval);
}
template<class... Ts>
R operator()(Ts&&... ts)
{
auto args = std::tie(ts...);
auto it = cache.find( args );
if (it != cache.end())
return it->second;
auto&& retval = base(*this, std::forward<Ts>(ts)...);
cache.emplace( std::move(args), retval );
return decltype(retval)(retval);
}
memoizer(memoizer const&)=default;
memoizer(memoizer&&)=default;
memoizer& operator=(memoizer const&)=default;
memoizer& operator=(memoizer&&)=default;
memoizer() = delete;
template<typename L>
memoizer( wrap, L&& f ):
base( std::forward<L>(f) )
{}
};
template<class Sig, class F>
memoizer<Sig, std::decay_t<F>> memoize( F&& f ) { return {wrap{}, std::forward<F>(f)}; }
live example with a hard-coded hash function based off this SO post.
auto fib = memoize<size_t(size_t)>(
[](auto&& fib, size_t i)->size_t{
if (i<=1) return 1;
return fib(i-1)+fib(i-2);
}
);