boost/hana/fwd/concept/sequence.hpp
/*! @file Forward declares `boost::hana::Sequence`. @copyright Louis Dionne 2013-2017 Distributed under the Boost Software License, Version 1.0. (See accompanying file LICENSE.md or copy at http://boost.org/LICENSE_1_0.txt) */ #ifndef BOOST_HANA_FWD_CONCEPT_SEQUENCE_HPP #define BOOST_HANA_FWD_CONCEPT_SEQUENCE_HPP #include <boost/hana/config.hpp> #include <boost/hana/core/when.hpp> BOOST_HANA_NAMESPACE_BEGIN //! @ingroup group-concepts //! @defgroup group-Sequence Sequence //! The `Sequence` concept represents generic index-based sequences. //! //! Compared to other abstract concepts, the Sequence concept is very //! specific. It represents generic index-based sequences. The reason //! why such a specific concept is provided is because there are a lot //! of models that behave exactly the same while being implemented in //! wildly different ways. It is useful to regroup all those data types //! under the same umbrella for the purpose of generic programming. //! //! In fact, models of this concept are not only _similar_. They are //! actually _isomorphic_, in a sense that we define below, which is //! a fancy way of rigorously saying that they behave exactly the same //! to an external observer. //! //! //! Minimal complete definition //! --------------------------- //! `Iterable`, `Foldable`, and `make` //! //! The `Sequence` concept does not provide basic methods that could be //! used as a minimal complete definition; instead, it borrows methods //! from other concepts and add laws to them. For this reason, it is //! necessary to specialize the `Sequence` metafunction in Hana's //! namespace to tell Hana that a type is indeed a `Sequence`. Explicitly //! specializing the `Sequence` metafunction can be seen like a seal //! saying "this data type satisfies the additional laws of a `Sequence`", //! since those can't be checked by Hana automatically. //! //! //! Laws //! ---- //! The laws for being a `Sequence` are simple, and their goal is to //! restrict the semantics that can be associated to the functions //! provided by other concepts. First, a `Sequence` must be a finite //! `Iterable` (thus a `Foldable` too). Secondly, for a `Sequence` tag //! `S`, `make<S>(x1, ..., xn)` must be an object of tag `S` and whose //! linearization is `[x1, ..., xn]`. This basically ensures that objects //! of tag `S` are equivalent to their linearization, and that they can //! be created from such a linearization (with `make`). //! //! While it would be possible in theory to handle infinite sequences, //! doing so complicates the implementation of many algorithms. For //! simplicity, the current version of the library only handles finite //! sequences. However, note that this does not affect in any way the //! potential for having infinite `Searchable`s and `Iterable`s. //! //! //! Refined concepts //! ---------------- //! 1. `Comparable` (definition provided automatically)\n //! Two `Sequence`s are equal if and only if they contain the same number //! of elements and their elements at any given index are equal. //! @include example/sequence/comparable.cpp //! //! 2. `Orderable` (definition provided automatically)\n //! `Sequence`s are ordered using the traditional lexicographical ordering. //! @include example/sequence/orderable.cpp //! //! 3. `Functor` (definition provided automatically)\n //! `Sequence`s implement `transform` as the mapping of a function over //! each element of the sequence. This is somewhat equivalent to what //! `std::transform` does to ranges of iterators. Also note that mapping //! a function over an empty sequence returns an empty sequence and never //! applies the function, as would be expected. //! @include example/sequence/functor.cpp //! //! 4. `Applicative` (definition provided automatically)\n //! First, `lift`ing a value into a `Sequence` is the same as creating a //! singleton sequence containing that value. Second, applying a sequence //! of functions to a sequence of values will apply each function to //! all the values in the sequence, and then return a list of all the //! results. In other words, //! @code //! ap([f1, ..., fN], [x1, ..., xM]) == [ //! f1(x1), ..., f1(xM), //! ... //! fN(x1), ..., fN(xM) //! ] //! @endcode //! Example: //! @include example/sequence/applicative.cpp //! //! 5. `Monad` (definition provided automatically)\n //! First, `flaten`ning a `Sequence` takes a sequence of sequences and //! concatenates them to get a larger sequence. In other words, //! @code //! flatten([[a1, ..., aN], ..., [z1, ..., zM]]) == [ //! a1, ..., aN, ..., z1, ..., zM //! ] //! @endcode //! This acts like a `std::tuple_cat` function, except it receives a //! sequence of sequences instead of a variadic pack of sequences to //! flatten.\n //! __Example__: //! @include example/sequence/monad.ints.cpp //! Also note that the model of `Monad` for `Sequence`s can be seen as //! modeling nondeterminism. A nondeterministic computation can be //! modeled as a function which returns a sequence of possible results. //! In this line of thought, `chain`ing a sequence of values into such //! a function will return a sequence of all the possible output values, //! i.e. a sequence of all the values applied to all the functions in //! the sequences.\n //! __Example__: //! @include example/sequence/monad.types.cpp //! //! 6. `MonadPlus` (definition provided automatically)\n //! `Sequence`s are models of the `MonadPlus` concept by considering the //! empty sequence as the unit of `concat`, and sequence concatenation //! as `concat`. //! @include example/sequence/monad_plus.cpp //! //! 7. `Foldable`\n //! The model of `Foldable` for `Sequence`s is uniquely determined by the //! model of `Iterable`. //! @include example/sequence/foldable.cpp //! //! 8. `Iterable`\n //! The model of `Iterable` for `Sequence`s corresponds to iteration over //! each element of the sequence, in order. This model is not provided //! automatically, and it is in fact part of the minimal complete //! definition for the `Sequence` concept. //! @include example/sequence/iterable.cpp //! //! 9. `Searchable` (definition provided automatically)\n //! Searching through a `Sequence` is equivalent to just searching through //! a list of the values it contains. The keys and the values on which //! the search is performed are both the elements of the sequence. //! @include example/sequence/searchable.cpp //! //! //! Concrete models //! --------------- //! `hana::tuple` //! //! //! [1]: http://en.wikipedia.org/wiki/Isomorphism#Isomorphism_vs._bijective_morphism #ifdef BOOST_HANA_DOXYGEN_INVOKED template <typename S> struct Sequence; #else template <typename S, typename = void> struct Sequence : Sequence<S, when<true>> { }; #endif BOOST_HANA_NAMESPACE_END #endif // !BOOST_HANA_FWD_CONCEPT_SEQUENCE_HPP