Mercurial > minori
view dep/toml11/toml/combinator.hpp @ 337:a7d4e5107531
dep/animone: REFACTOR ALL THE THINGS
1: animone now has its own syntax divergent from anisthesia,
making different platforms actually have their own sections
2: process names in animone are now called `comm' (this will
probably break things). this is what its called in bsd/linux
so I'm just going to use it everywhere
3: the X11 code now checks for the existence of a UTF-8 window title
and passes it if available
4: ANYTHING THATS NOT LINUX IS 100% UNTESTED AND CAN AND WILL BREAK!
I still actually need to test the bsd code. to be honest I'm probably
going to move all of the bsds into separate files because they're
all essentially different operating systems at this point
| author | Paper <paper@paper.us.eu.org> |
|---|---|
| date | Wed, 19 Jun 2024 12:51:15 -0400 |
| parents | 3b355fa948c7 |
| children |
line wrap: on
line source
// Copyright Toru Niina 2017. // Distributed under the MIT License. #ifndef TOML11_COMBINATOR_HPP #define TOML11_COMBINATOR_HPP #include <cassert> #include <cctype> #include <cstdio> #include <array> #include <iomanip> #include <iterator> #include <limits> #include <type_traits> #include "region.hpp" #include "result.hpp" #include "traits.hpp" #include "utility.hpp" // they scans characters and returns region if it matches to the condition. // when they fail, it does not change the location. // in lexer.hpp, these are used. namespace toml { namespace detail { // to output character as an error message. inline std::string show_char(const char c) { // It suppresses an error that occurs only in Debug mode of MSVC++ on Windows. // I'm not completely sure but they check the value of char to be in the // range [0, 256) and some of the COMPLETELY VALID utf-8 character sometimes // has negative value (if char has sign). So here it re-interprets c as // unsigned char through pointer. In general, converting pointer to a // pointer that has different type cause UB, but `(signed|unsigned)?char` // are one of the exceptions. Converting pointer only to char and std::byte // (c++17) are valid. if(std::isgraph(*reinterpret_cast<unsigned char const*>(std::addressof(c)))) { return std::string(1, c); } else { std::array<char, 5> buf; buf.fill('\0'); const auto r = std::snprintf( buf.data(), buf.size(), "0x%02x", static_cast<int>(c) & 0xFF); (void) r; // Unused variable warning assert(r == static_cast<int>(buf.size()) - 1); return std::string(buf.data()); } } template<char C> struct character { static constexpr char target = C; static result<region, none_t> invoke(location& loc) { if(loc.iter() == loc.end()) {return none();} const auto first = loc.iter(); const char c = *(loc.iter()); if(c != target) { return none(); } loc.advance(); // update location return ok(region(loc, first, loc.iter())); } }; template<char C> constexpr char character<C>::target; // closed interval [Low, Up]. both Low and Up are included. template<char Low, char Up> struct in_range { // assuming ascii part of UTF-8... static_assert(Low <= Up, "lower bound should be less than upper bound."); static constexpr char upper = Up; static constexpr char lower = Low; static result<region, none_t> invoke(location& loc) { if(loc.iter() == loc.end()) {return none();} const auto first = loc.iter(); const char c = *(loc.iter()); if(c < lower || upper < c) { return none(); } loc.advance(); return ok(region(loc, first, loc.iter())); } }; template<char L, char U> constexpr char in_range<L, U>::upper; template<char L, char U> constexpr char in_range<L, U>::lower; // keep iterator if `Combinator` matches. otherwise, increment `iter` by 1 char. // for detecting invalid characters, like control sequences in toml string. template<typename Combinator> struct exclude { static result<region, none_t> invoke(location& loc) { if(loc.iter() == loc.end()) {return none();} auto first = loc.iter(); auto rslt = Combinator::invoke(loc); if(rslt.is_ok()) { loc.reset(first); return none(); } loc.reset(std::next(first)); // XXX maybe loc.advance() is okay but... return ok(region(loc, first, loc.iter())); } }; // increment `iter`, if matches. otherwise, just return empty string. template<typename Combinator> struct maybe { static result<region, none_t> invoke(location& loc) { const auto rslt = Combinator::invoke(loc); if(rslt.is_ok()) { return rslt; } return ok(region(loc)); } }; template<typename ... Ts> struct sequence; template<typename Head, typename ... Tail> struct sequence<Head, Tail...> { static result<region, none_t> invoke(location& loc) { const auto first = loc.iter(); auto rslt = Head::invoke(loc); if(rslt.is_err()) { loc.reset(first); return none(); } return sequence<Tail...>::invoke(loc, std::move(rslt.unwrap()), first); } // called from the above function only, recursively. template<typename Iterator> static result<region, none_t> invoke(location& loc, region reg, Iterator first) { const auto rslt = Head::invoke(loc); if(rslt.is_err()) { loc.reset(first); return none(); } reg += rslt.unwrap(); // concat regions return sequence<Tail...>::invoke(loc, std::move(reg), first); } }; template<typename Head> struct sequence<Head> { // would be called from sequence<T ...>::invoke only. template<typename Iterator> static result<region, none_t> invoke(location& loc, region reg, Iterator first) { const auto rslt = Head::invoke(loc); if(rslt.is_err()) { loc.reset(first); return none(); } reg += rslt.unwrap(); // concat regions return ok(reg); } }; template<typename ... Ts> struct either; template<typename Head, typename ... Tail> struct either<Head, Tail...> { static result<region, none_t> invoke(location& loc) { const auto rslt = Head::invoke(loc); if(rslt.is_ok()) {return rslt;} return either<Tail...>::invoke(loc); } }; template<typename Head> struct either<Head> { static result<region, none_t> invoke(location& loc) { return Head::invoke(loc); } }; template<typename T, typename N> struct repeat; template<std::size_t N> struct exactly{}; template<std::size_t N> struct at_least{}; struct unlimited{}; template<typename T, std::size_t N> struct repeat<T, exactly<N>> { static result<region, none_t> invoke(location& loc) { region retval(loc); const auto first = loc.iter(); for(std::size_t i=0; i<N; ++i) { auto rslt = T::invoke(loc); if(rslt.is_err()) { loc.reset(first); return none(); } retval += rslt.unwrap(); } return ok(std::move(retval)); } }; template<typename T, std::size_t N> struct repeat<T, at_least<N>> { static result<region, none_t> invoke(location& loc) { region retval(loc); const auto first = loc.iter(); for(std::size_t i=0; i<N; ++i) { auto rslt = T::invoke(loc); if(rslt.is_err()) { loc.reset(first); return none(); } retval += rslt.unwrap(); } while(true) { auto rslt = T::invoke(loc); if(rslt.is_err()) { return ok(std::move(retval)); } retval += rslt.unwrap(); } } }; template<typename T> struct repeat<T, unlimited> { static result<region, none_t> invoke(location& loc) { region retval(loc); while(true) { auto rslt = T::invoke(loc); if(rslt.is_err()) { return ok(std::move(retval)); } retval += rslt.unwrap(); } } }; } // detail } // toml #endif// TOML11_COMBINATOR_HPP