rexylib/include/rexy/string_base.hpp

/**
	This file is a part of rexy's general purpose library
	Copyright (C) 2020 rexy712

	This program is free software: you can redistribute it and/or modify
	it under the terms of the GNU Affero General Public License as published by
	the Free Software Foundation, either version 3 of the License, or
	(at your option) any later version.

	This program is distributed in the hope that it will be useful,
	but WITHOUT ANY WARRANTY; without even the implied warranty of
	MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
	GNU Affero General Public License for more details.

	You should have received a copy of the GNU Affero General Public License
	along with this program.  If not, see <http://www.gnu.org/licenses/>.
*/

#ifndef REXY_STRING_BASE_HPP
#define REXY_STRING_BASE_HPP

#include <type_traits> //is_same, integral_contant, enable_if, etc
#include <utility> //forward
#include <cstdlib> //size_t
#include <cstring> //strlen

#include "steal.hpp"
#include "cx/utility.hpp"
#include "traits.hpp"
#include "expression.hpp"
#include "detail/string_appender.hpp"

namespace rexy{

	//Base of all RAII strings. Its use is allowing passing of rexy strings to functions without knowing the exact type
	class string_base
	{
	protected:
		size_t m_length = 0;
		size_t m_cap = 0;
		char* m_data = nullptr;

	protected:
		constexpr string_base(void)noexcept = default;
		constexpr string_base(size_t len)noexcept:
			m_cap(len){}
		//Initialize without copying
		constexpr string_base(char* data, size_t len)noexcept:
			m_cap(len), m_data(data){}
		constexpr string_base(char* data, size_t len, size_t cap)noexcept:
			m_length(len), m_cap(cap), m_data(data){}
		//Copy ctor (do nothing)
		constexpr string_base(const string_base&)noexcept{}
		~string_base(void)noexcept = default;

	public:
		//Stop managing stored pointer. Does not free.
		constexpr char* release(void)noexcept{return cx::exchange(m_data, nullptr);}

		//Length of string not including null terminator
		constexpr size_t length(void)const noexcept{return m_length;}
		constexpr size_t capacity(void)const noexcept{return m_cap;}
		//direct access to managed pointer
		constexpr char* get(void)noexcept{return m_data;}
		constexpr const char* get(void)const noexcept{return m_data;}
		constexpr operator char*(void)noexcept{return m_data;}
		constexpr operator const char*(void)const noexcept{return m_data;}
		//true if m_data is not null
		constexpr bool valid(void)const noexcept{return m_data;}

		constexpr char& operator[](size_t i)noexcept{return m_data[i];}
		constexpr const char& operator[](size_t i)const noexcept{return m_data[i];}
	};


	//Supplies all functions that string_base can't implement
	template<class Allocator>
	class string_intermediary : public string_base
	{
	public:
		using allocator_type = Allocator;

	private:
		string_intermediary& _copy_string(const char* s, size_t len)
			noexcept(noexcept(Allocator::copy(nullptr,0)) &&
			         noexcept(Allocator::free(nullptr)));

	public:
		constexpr string_intermediary(void)noexcept;
		constexpr string_intermediary(rexy::steal<char*> data, size_t len)noexcept;
		constexpr string_intermediary(rexy::steal<char*> data, size_t len, size_t cap)noexcept;
		constexpr string_intermediary(rexy::steal<char*> data)noexcept;
		string_intermediary(const char* data, size_t len)noexcept(noexcept(Allocator::copy(data,len)));
		string_intermediary(const char* data)noexcept(noexcept(Allocator::copy(data, m_cap)));
		string_intermediary(size_t len)noexcept(noexcept(Allocator::allocate(len)));
		string_intermediary(size_t len, size_t cap)noexcept(noexcept(Allocator::allocate(len)));

		//normal copy and move ctors
		string_intermediary(const string_intermediary& b)noexcept(noexcept(Allocator::copy(b.m_data, b.m_length)));
		constexpr string_intermediary(string_intermediary&& s)noexcept(noexcept(cx::exchange(s.m_data, nullptr)));

		string_intermediary(const string_base& b)noexcept(noexcept(Allocator::copy(b.get(), b.length())));

		//dtor
		~string_intermediary(void)noexcept(noexcept(Allocator::free(m_data)));

		string_intermediary& operator=(const string_intermediary& s)
			noexcept(noexcept(Allocator::copy(nullptr,0)) &&
			         noexcept(Allocator::free(nullptr)));

		constexpr string_intermediary& operator=(string_intermediary&& s)noexcept;
		//Copy from c string
		string_intermediary& operator=(const char* c)
			noexcept(noexcept(Allocator::copy(nullptr,0)) &&
			         noexcept(Allocator::free(nullptr)));
		//Copy from other string_base
		string_intermediary& operator=(const string_base& s)
			noexcept(noexcept(Allocator::copy(nullptr,0)) &&
			         noexcept(Allocator::free(nullptr)));

		//Replace managed pointer. Frees existing value
		void reset(char* val = nullptr)noexcept(noexcept(Allocator::free(m_data)));
		void reset(char* val, size_t len)noexcept(noexcept(Allocator::free(m_data)));
		bool resize(size_t newsize)
			noexcept(noexcept(Allocator::copy(nullptr,0)) &&
			         noexcept(Allocator::free(nullptr)));

		void append(const char* data, size_t len)
			noexcept(noexcept(Allocator::allocate(0)) &&
			         noexcept(Allocator::free(nullptr)));
		void append(const char* data)
			noexcept(noexcept(Allocator::allocate(0)) &&
			         noexcept(Allocator::free(nullptr)));
		void append(const string_base& s)
			noexcept(noexcept(Allocator::allocate(0)) &&
			         noexcept(Allocator::free(nullptr)));

	};

	//Like an expression template but not really
	template<class Left, class Right>
	class string_cat_expr : public rexy::binary_expression<Left,Right>
	{
	public:
		using binary_expression<Left,Right>::binary_expression;

		constexpr string_cat_expr(const string_cat_expr&) = default;
		constexpr string_cat_expr(string_cat_expr&&) = default;

		constexpr size_t length(void)const noexcept;
		template<class Alloc>
		operator string_intermediary<Alloc>(void)
			noexcept(std::is_nothrow_constructible<string_intermediary<Alloc>, size_t>::value &&
			         std::is_nothrow_invocable<detail::string_appender<string_intermediary<Alloc>>,decltype(*this)>::value);
	};
	template<class Left, class Right>
	string_cat_expr(Left&&,Right&&) -> string_cat_expr<Left&&,Right&&>;

	class static_string : public string_base
	{
	public:
		constexpr static_string(void)noexcept = default;
		constexpr static_string(const char* str, size_t len)noexcept;
		constexpr static_string(const char* c)noexcept;
		constexpr static_string(const static_string& s)noexcept;
		constexpr static_string(static_string&& s)noexcept;
		~static_string(void)noexcept = default;

		constexpr static_string& operator=(const char* c)noexcept;
		constexpr static_string& operator=(const static_string& s)noexcept;
		constexpr static_string& operator=(static_string&&)noexcept;
	};


	template<class T>
	struct is_string{
		static constexpr bool value = rexy::is_type<T,string_base>::value || rexy::is_template_type<T,string_cat_expr>::value;
	};
	template<class T>
	struct is_concrete_string{
		static constexpr bool value = rexy::is_type<T,string_base>::value;
	};
	namespace detail{

		template<class... Ts>
		using enable_if_string = std::enable_if_t<(is_string<Ts>::value && ...),int>;
		template<class... Ts>
		using enable_if_concrete_string = std::enable_if_t<(is_concrete_string<Ts>::value && ...),int>;
		template<class... Ts>
		using enable_if_expr_string = std::enable_if_t<(rexy::is_template_type<Ts,string_cat_expr>::value && ...),int>;

	} //namespace detail

	template<class Str1, class Str2, detail::enable_if_concrete_string<Str1,Str2> = 0>
	constexpr bool operator==(Str1&& left, Str2&& right)noexcept{
		return left.valid() && right.valid() && left.length() == right.length() && !cx::strcmp(left.get(), right.get());
	}
	template<class Str1, class Str2, detail::enable_if_concrete_string<Str1,Str2> = 0>
	constexpr bool operator!=(Str1&& left, Str2&& right)noexcept{
		return !(left == right);
	}

	template<class Left, class Right, detail::enable_if_string<Left,Right> = 0>
	constexpr auto operator+(Left&& l, Right&& r)
		//uses deduction guide whereas std::is_nothrow_constructible couldn't
		noexcept(noexcept(::new (nullptr) string_cat_expr(std::forward<Left>(l), std::forward<Right>(r))))
	{
		return string_cat_expr(std::forward<Left>(l), std::forward<Right>(r));
	}
	template<class Right, detail::enable_if_string<Right> = 0>
	constexpr auto operator+(const char* left, Right&& right)
		noexcept(noexcept(::new (nullptr) string_cat_expr(rexy::static_string(left), std::forward<Right>(right))))
	{
		return string_cat_expr(rexy::static_string(left), std::forward<Right>(right));
	}

	template<class Left, detail::enable_if_string<Left> = 0>
	constexpr auto operator+(Left&& left, const char* right)
		noexcept(noexcept(::new (nullptr) string_cat_expr(std::forward<Left>(left), rexy::static_string(right))))
	{
		return rexy::string_cat_expr(std::forward<Left>(left), rexy::static_string(right));
	}

	template<class Left, class Right, detail::enable_if_concrete_string<Left> = 0, detail::enable_if_string<Right> = 0>
	decltype(auto) operator+=(Left& l, Right&& r)
		noexcept(noexcept(l + std::forward<Right>(r)) && std::is_nothrow_assignable<Left, decltype(l + std::forward<Right>(r))>::value)
	{
		return l = (l + std::forward<Right>(r));
	}
	template<class Left, detail::enable_if_concrete_string<Left> = 0>
	decltype(auto) operator+=(Left& l, const char* r)
		noexcept(noexcept(l + r) && std::is_nothrow_assignable<Left, decltype(l + r)>::value)
	{
		return l = (l + r);
	}
}

#include "string_base.tpp"

namespace{
	constexpr inline rexy::static_string operator"" _ss(const char* str, size_t len)noexcept{
		return rexy::static_string(str, len);
	}
}

#ifdef REXY_CX_HASH_HPP
#include "cx/string_hash.hpp"
#endif

#endif