libs/flyweight/example/composite.cpp
/* Boost.Flyweight example of a composite design. * * Copyright 2006-2014 Joaquin M Lopez Munoz. * Distributed under the Boost Software License, Version 1.0. * (See accompanying file LICENSE_1_0.txt or copy at * http://www.boost.org/LICENSE_1_0.txt) * * See http://www.boost.org/libs/flyweight for library home page. */ #include <boost/flyweight.hpp> #include <boost/functional/hash.hpp> #include <boost/tokenizer.hpp> #include <boost/variant.hpp> #include <boost/variant/apply_visitor.hpp> #include <boost/variant/recursive_wrapper.hpp> #include <iostream> #include <stdexcept> #include <string> #include <vector> using namespace boost::flyweights; /* A node of a lisp-like list can be modeled as a boost::variant of * 1. A string (primitive node) * 2. A vector of nodes (embedded list) * To save space, 2 is stored as a vector of flyweights. * As is usual with recursive data structures, a node can be thought * of also as a list. To close the flyweight circle, the final * type list is a flyweight wrapper, so that the final structure can * be described as follows in BNF-like style: * * list ::= flyweight<list_impl> * list_impl ::= std::string | std::vector<list> */ struct list_elems; typedef boost::variant< std::string, boost::recursive_wrapper<list_elems> > list_impl; struct list_elems:std::vector<flyweight<list_impl> >{}; typedef flyweight<list_impl> list; /* list_impl must be hashable to be used by flyweight: If a * node is a std::string, its hash resolves to that of the string; * if it is a vector of flyweight nodes, we combine their corresponding * hash values. As hashing a flyweight does not involve actually hashing * its pointed-to value, the resulting computation does not recursively * descend down the entire data structure. */ struct list_hasher:boost::static_visitor<std::size_t> { std::size_t operator()(const std::string& str)const { boost::hash<std::string> h; return h(str); } std::size_t operator()(const list_elems& elms)const { std::size_t res=0; for(list_elems::const_iterator it=elms.begin(),it_end=elms.end(); it!=it_end;++it){ boost::hash_combine(res,*it); } return res; } }; #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP) namespace boost{ #endif std::size_t hash_value(const list_impl& limpl) { return boost::apply_visitor(list_hasher(),limpl); } #if defined(BOOST_NO_ARGUMENT_DEPENDENT_LOOKUP) } /* namespace boost */ #endif /* basic pretty printer with indentation according to the nesting level */ struct list_pretty_printer:boost::static_visitor<> { list_pretty_printer():nest(0){} void operator()(const std::string& str) { indent(); std::cout<<str<<"\n"; } void operator()(const boost::recursive_wrapper<list_elems>& elmsw) { indent(); std::cout<<"(\n"; ++nest; const list_elems& elms=elmsw.get(); for(list_elems::const_iterator it=elms.begin(),it_end=elms.end(); it!=it_end;++it){ boost::apply_visitor(*this,it->get()); } --nest; indent(); std::cout<<")\n"; } private: void indent()const { for(int i=nest;i--;)std::cout<<" "; } int nest; }; void pretty_print(const list& l) { list_pretty_printer pp; boost::apply_visitor(pp,l.get()); } /* list parser */ template<typename InputIterator> list parse_list(InputIterator& first,InputIterator last,int nest) { list_elems elms; while(first!=last){ std::string str=*first++; if(str=="("){ elms.push_back(parse_list(first,last,nest+1)); } else if(str==")"){ if(nest==0)throw std::runtime_error("unmatched )"); return list(elms); } else{ elms.push_back(list(str)); } } if(nest!=0)throw std::runtime_error("unmatched ("); return list(elms); } list parse_list(const std::string str) { typedef boost::tokenizer<boost::char_separator<char> > tokenizer; tokenizer tok(str,boost::char_separator<char>(" ","()")); tokenizer::iterator begin=tok.begin(); return parse_list(begin,tok.end(),0); } int main() { std::cout<<"enter list: "; std::string str; std::getline(std::cin,str); try{ pretty_print(parse_list(str)); } catch(const std::exception& e){ std::cout<<"error: "<<e.what()<<"\n"; } return 0; }