sol2/sol/container_traits.hpp

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// The MIT License (MIT)
// Copyright (c) 2013-2017 Rapptz, ThePhD and contributors
// Permission is hereby granted, free of charge, to any person obtaining a copy of
// this software and associated documentation files (the "Software"), to deal in
// the Software without restriction, including without limitation the rights to
// use, copy, modify, merge, publish, distribute, sublicense, and/or sell copies of
// the Software, and to permit persons to whom the Software is furnished to do so,
// subject to the following conditions:
// The above copyright notice and this permission notice shall be included in all
// copies or substantial portions of the Software.
// THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
// IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY, FITNESS
// FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE AUTHORS OR
// COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER LIABILITY, WHETHER
// IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM, OUT OF OR IN
// CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN THE SOFTWARE.
#ifndef SOL_CONTAINER_TRAITS_HPP
#define SOL_CONTAINER_TRAITS_HPP
#include "traits.hpp"
#include "stack.hpp"
#include <unordered_map>
namespace sol {
template <typename T>
struct container_traits;
namespace container_detail {
template <typename T>
struct has_clear_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::clear));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_size_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::size));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_erase_after_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(std::declval<C>().erase_after(std::declval<std::add_rvalue_reference_t<typename C::const_iterator>>()))*);
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T, typename = void>
struct has_find_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(std::declval<C>().find(std::declval<std::add_rvalue_reference_t<typename C::value_type>>()))*);
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_find_test<T, std::enable_if_t<meta::is_lookup<T>::value>> {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(std::declval<C>().find(std::declval<std::add_rvalue_reference_t<typename C::key_type>>()))*);
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_erase_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(std::declval<C>().erase(std::declval<typename C::iterator>()))*);
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_find_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::find));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_insert_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::insert));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_erase_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::erase));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_index_set_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::index_set));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_index_get_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::index_get));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_set_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::set));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_get_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::get));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_pairs_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::pairs));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
struct has_traits_add_test {
private:
typedef std::array<char, 1> one;
typedef std::array<char, 2> two;
template <typename C> static one test(decltype(&C::add));
template <typename C> static two test(...);
public:
static const bool value = sizeof(test<T>(0)) == sizeof(char);
};
template <typename T>
using has_size = meta::boolean<has_size_test<T>::value>;
template <typename T>
using has_clear = meta::boolean<has_clear_test<T>::value>;
template <typename T>
using has_find = meta::boolean<has_find_test<T>::value>;
template <typename T>
using has_erase = meta::boolean<has_erase_test<T>::value>;
template <typename T>
using has_erase_after = meta::boolean<has_erase_after_test<T>::value>;
template <typename T>
using has_traits_get = meta::boolean<has_traits_get_test<T>::value>;
template <typename T>
using has_traits_set = meta::boolean<has_traits_set_test<T>::value>;
template <typename T>
using has_traits_index_get = meta::boolean<has_traits_index_get_test<T>::value>;
template <typename T>
using has_traits_index_set = meta::boolean<has_traits_index_set_test<T>::value>;
template <typename T>
using has_traits_pairs = meta::boolean<has_traits_pairs_test<T>::value>;
template <typename T>
using has_traits_add = meta::boolean<has_traits_add_test<T>::value>;
template <typename T>
using has_traits_size = has_size<T>;
template <typename T>
using has_traits_clear = has_clear<T>;
template <typename T>
using has_traits_find = meta::boolean<has_traits_find_test<T>::value>;
template <typename T>
using has_traits_insert = meta::boolean<has_traits_insert_test<T>::value>;
template <typename T>
using has_traits_insert = meta::boolean<has_traits_insert_test<T>::value>;
template <typename T>
using has_traits_erase = meta::boolean<has_traits_erase_test<T>::value>;
template <typename T>
decltype(auto) get_key(std::false_type, T&& t) {
return std::forward<T>(t);
}
template <typename T>
decltype(auto) get_key(std::true_type, T&& t) {
return t.first;
}
template <typename T>
decltype(auto) get_value(std::false_type, T&& t) {
return std::forward<T>(t);
}
template <typename T>
decltype(auto) get_value(std::true_type, T&& t) {
return t.second;
}
template <typename X, typename = void>
struct container_traits_default {
private:
typedef std::remove_pointer_t<meta::unwrap_unqualified_t<X>> T;
public:
typedef lua_nil_t iterator;
typedef lua_nil_t value_type;
static int get(lua_State* L) {
return luaL_error(L, "sol: cannot call 'get(key)' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int index_get(lua_State* L) {
return luaL_error(L, "sol: cannot call 'container[key]' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int set(lua_State* L) {
return luaL_error(L, "sol: cannot call 'set(key, value)' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int index_set(lua_State* L) {
return luaL_error(L, "sol: cannot call 'container[key] = value' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int add(lua_State* L) {
return luaL_error(L, "sol: cannot call 'add' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int insert(lua_State* L) {
return luaL_error(L, "sol: cannot call 'insert' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int find(lua_State* L) {
return luaL_error(L, "sol: cannot call 'find' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int size(lua_State* L) {
return luaL_error(L, "sol: cannot call 'end' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int clear(lua_State* L) {
return luaL_error(L, "sol: cannot call 'clear' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int erase(lua_State* L) {
return luaL_error(L, "sol: cannot call 'erase' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static int pairs(lua_State* L) {
return luaL_error(L, "sol: cannot call '__pairs' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
}
static iterator begin(lua_State* L, T&) {
luaL_error(L, "sol: cannot call 'being' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
return lua_nil;
}
static iterator end(lua_State* L, T&) {
luaL_error(L, "sol: cannot call 'end' on type '%s': it is not recognized as a container", detail::demangle<T>().c_str());
return lua_nil;
}
};
template <typename X>
struct container_traits_default<X, std::enable_if_t<
meta::all<
is_container<meta::unqualified_t<X>>
, meta::has_value_type<meta::unqualified_t<X>>
, meta::has_iterator<meta::unqualified_t<X>>
>::value
>> {
private:
typedef std::remove_pointer_t<meta::unwrap_unqualified_t<X>> T;
public:
typedef std::true_type is_container;
typedef meta::is_associative<T> is_associative;
private:
typedef meta::is_lookup<T> is_lookup;
typedef typename T::iterator iterator;
typedef typename T::value_type value_type;
typedef std::conditional_t<is_associative::value,
value_type,
std::conditional_t<is_lookup::value, std::pair<value_type, value_type>, std::pair<std::ptrdiff_t, value_type>>
> KV;
typedef typename KV::first_type K;
typedef typename KV::second_type V;
typedef decltype(*std::declval<iterator&>()) iterator_return;
typedef typename meta::iterator_tag<iterator>::type iterator_category;
typedef std::is_same<iterator_category, std::input_iterator_tag> is_input_iterator;
typedef std::conditional_t<is_input_iterator::value,
V,
std::conditional_t<is_associative::value, std::add_lvalue_reference_t<V>, iterator_return>
> push_type;
typedef std::is_copy_assignable<V> is_copyable;
typedef meta::neg<meta::any<
std::is_const<V>
, std::is_const<std::remove_reference_t<iterator_return>>
, meta::neg<is_copyable>
>> is_writable;
typedef meta::unqualified_t<decltype(get_key(is_associative(), std::declval<std::add_lvalue_reference_t<value_type>>()))> key_type;
typedef meta::all<std::is_integral<K>, meta::neg<meta::any<is_associative, is_lookup>>> is_linear_integral;
struct iter {
T& source;
iterator it;
iter(T& source, iterator it) : source(source), it(std::move(it)) {}
};
static auto& get_src(lua_State* L) {
#ifdef SOL_SAFE_USERTYPE
auto p = stack::check_get<T*>(L, 1);
if (!p || p.value() == nullptr) {
luaL_error(L, "sol: 'self' argument is nil or not of type '%s' (pass 'self' as first argument with ':' or call on proper type)", detail::demangle<T>().c_str());
}
return *p.value();
#else
return stack::get<T>(L, 1);
#endif // Safe getting with error
}
static int get_associative(std::true_type, lua_State* L, iterator& it) {
auto& v = *it;
return stack::stack_detail::push_reference<push_type>(L, v.second);
}
static int get_associative(std::false_type, lua_State* L, iterator& it) {
return stack::stack_detail::push_reference<push_type>(L, *it);
}
static int get_category(std::input_iterator_tag, lua_State* L, T& self, K& key) {
if (key < 1) {
return stack::push(L, lua_nil);
}
auto it = begin(L, self);
auto e = end(L, self);
if (it == e) {
return stack::push(L, lua_nil);
}
while (key > 1) {
--key;
++it;
if (it == e) {
return stack::push(L, lua_nil);
}
}
return get_associative(is_associative(), L, it);
}
static int get_category(std::random_access_iterator_tag, lua_State* L, T& self, K& key) {
std::ptrdiff_t len = static_cast<std::ptrdiff_t>(size_start(L, self));
if (key < 1 || key > len) {
return stack::push(L, lua_nil);
}
--key;
auto it = std::next(begin(L, self), key);
return get_associative(is_associative(), L, it);
}
static int get_it(std::true_type, lua_State* L, T& self, K& key) {
return get_category(iterator_category(), L, self, key);
}
static int get_comparative(std::true_type, lua_State* L, T& self, K& key) {
auto fx = [&](const value_type& r) -> bool {
return key == get_key(is_associative(), r);
};
auto e = end(L, self);
auto it = std::find_if(begin(L, self), e, std::ref(fx));
if (it == e) {
return stack::push(L, lua_nil);
}
return get_associative(is_associative(), L, it);
}
static int get_comparative(std::false_type, lua_State* L, T&, K&) {
return luaL_error(L, "cannot get this key on '%s': no suitable way to increment iterator and compare to key value '%s'", detail::demangle<T>().data(), detail::demangle<K>().data());
}
static int get_it(std::false_type, lua_State* L, T& self, K& key) {
return get_comparative(meta::supports_op_equal<K, key_type>(), L, self, key);
}
static void set_associative(std::true_type, iterator& it, stack_object value) {
auto& v = *it;
v.second = value.as<V>();
}
static void set_associative(std::false_type, iterator& it, stack_object value) {
auto& v = *it;
v = value.as<V>();
}
static void set_writable(std::true_type, lua_State*, T&, iterator& it, stack_object value) {
set_associative(is_associative(), it, std::move(value));
}
static void set_writable(std::false_type, lua_State* L, T&, iterator&, stack_object) {
luaL_error(L, "cannot perform a 'set': '%s's iterator reference is not writable (non-copy-assignable or const)", detail::demangle<T>().data());
}
static void set_category(std::input_iterator_tag, lua_State* L, T& self, stack_object okey, stack_object value) {
decltype(auto) key = okey.as<K>();
auto e = end(L, self);
auto it = begin(L, self);
auto backit = it;
for (; key > 1 && it != e; --key, ++it) {
backit = it;
}
if (it == e) {
if (key == 1) {
add_copyable(is_copyable(), L, self, std::move(value), meta::has_insert_after<T>::value ? backit : it);
return;
}
luaL_error(L, "out of bounds (too big) for set on '%s'", detail::demangle<T>().c_str());
return;
}
set_writable(is_writable(), L, self, it, std::move(value));
}
static void set_category(std::random_access_iterator_tag, lua_State* L, T& self, stack_object okey, stack_object value) {
decltype(auto) key = okey.as<K>();
if (key < 1) {
luaL_error(L, "sol: out of bounds (too small) for set on '%s'", detail::demangle<T>().c_str());
return;
}
--key;
std::ptrdiff_t len = static_cast<std::ptrdiff_t>(size_start(L, self));
if (key == len) {
add_copyable(is_copyable(), L, self, std::move(value));
return;
}
else if (key > len) {
luaL_error(L, "sol: out of bounds (too big) for set on '%s'", detail::demangle<T>().c_str());
return;
}
auto it = std::next(begin(L, self), key);
set_writable(is_writable(), L, self, it, std::move(value));
}
static void set_comparative(std::true_type, lua_State* L, T& self, stack_object okey, stack_object value) {
decltype(auto) key = okey.as<K>();
if (!is_writable::value) {
luaL_error(L, "cannot perform a 'set': '%s's iterator reference is not writable (non-copy-assignable or const)", detail::demangle<T>().data());;
return;
}
auto fx = [&](const value_type& r) -> bool {
return key == get_key(is_associative(), r);
};
auto e = end(L, self);
auto it = std::find_if(begin(L, self), e, std::ref(fx));
if (it == e) {
return;
}
set_writable(is_writable(), L, self, it, std::move(value));
}
static void set_comparative(std::false_type, lua_State* L, T&, stack_object, stack_object) {
luaL_error(L, "cannot set this value on '%s': no suitable way to increment iterator or compare to '%s' key", detail::demangle<T>().data(), detail::demangle<K>().data());
}
static void set_associative_insert(std::true_type, lua_State*, T& self, iterator& it, K& key, stack_object value) {
self.insert(it, value_type(key, value.as<V>()));
}
static void set_associative_insert(std::false_type, lua_State*, T& self, iterator& it, K& key, stack_object) {
self.insert(it, key);
}
static void set_associative_find(std::true_type, lua_State* L, T& self, stack_object okey, stack_object value) {
decltype(auto) key = okey.as<K>();
auto it = self.find(key);
if (it == end(L, self)) {
set_associative_insert(is_associative(), L, self, it, key, std::move(value));
return;
}
set_writable(is_writable(), L, self, it, std::move(value));
}
static void set_associative_find(std::false_type, lua_State* L, T& self, stack_object key, stack_object value) {
set_comparative(meta::supports_op_equal<K, key_type>(), L, self, std::move(key), std::move(value));
}
static void set_it(std::true_type, lua_State* L, T& self, stack_object key, stack_object value) {
set_category(iterator_category(), L, self, std::move(key), std::move(value));
}
static void set_it(std::false_type, lua_State* L, T& self, stack_object key, stack_object value) {
set_associative_find(meta::all<has_find<T>, meta::any<is_associative, is_lookup>>(), L, self, std::move(key), std::move(value));
}
static int find_has_associative_lookup(std::true_type, lua_State* L, T& self) {
decltype(auto) key = stack::get<K>(L, 2);
auto it = self.find(key);
if (it == end(L, self)) {
return stack::push(L, lua_nil);
}
return get_associative(is_associative(), L, it);
}
static int find_has_associative_lookup(std::false_type, lua_State* L, T& self) {
decltype(auto) value = stack::get<V>(L, 2);
auto it = self.find(value);
if (it == end(L, self)) {
return stack::push(L, lua_nil);
}
return get_associative(is_associative(), L, it);
}
static int find_has(std::true_type, lua_State* L, T& self) {
return find_has_associative_lookup(meta::any<is_lookup, is_associative>(), L, self);
}
static int find_associative_lookup(std::true_type, lua_State* L, iterator& it, std::size_t) {
return get_associative(is_associative(), L, it);
}
static int find_associative_lookup(std::false_type, lua_State* L, iterator&, std::size_t index) {
return stack::push(L, index);
}
static int find_comparative(std::false_type, lua_State* L, T& ) {
return luaL_error(L, "cannot call 'find' on '%s': there is no 'find' function and the value_type is not equality comparable", detail::demangle<T>().c_str());
}
static int find_comparative(std::true_type, lua_State* L, T& self) {
V value = stack::get<V>(L, 2);
auto it = begin(L, self);
auto e = end(L, self);
std::size_t index = 1;
for (;; ++it, ++index) {
if (it == e) {
return stack::push(L, lua_nil);
}
if (value == get_value(is_associative(), *it)) {
break;
}
}
return find_associative_lookup(meta::any<is_lookup, is_associative>(), L, it, index);
}
static int find_has(std::false_type, lua_State* L, T& self) {
return find_comparative(meta::supports_op_equal<V>(), L, self);
}
static void add_insert_after(std::false_type, lua_State* L, T& self, stack_object value, iterator&) {
add_insert_after(std::false_type(), L, self, value);
}
static void add_insert_after(std::false_type, lua_State* L, T&, stack_object) {
luaL_error(L, "cannot call 'add' on type '%s': no suitable insert/push_back C++ functions", sol::detail::demangle<T>().data());
}
static void add_insert_after(std::true_type, lua_State*, T& self, stack_object value, iterator& at) {
self.insert_after(at, value.as<V>());
}
static void add_insert_after(std::true_type, lua_State* L, T& self, stack_object value) {
auto backit = self.before_begin();
{
auto e = end(L, self);
for (auto it = begin(L, self); it != e; ++backit, ++it) {}
}
return add_insert_after(std::true_type(), L, self, value, backit);
}
static void add_insert(std::true_type, lua_State*, T& self, stack_object value, iterator& at) {
self.insert(at, value.as<V>());
}
static void add_insert(std::true_type, lua_State* L, T& self, stack_object value) {
auto at = end(L, self);
add_insert(std::true_type(), L, self, value, at);
}
static void add_insert(std::false_type, lua_State* L, T& self, stack_object value, iterator& at) {
return add_insert_after(meta::has_insert_after<T>(), L, self, std::move(value), at);
}
static void add_insert(std::false_type, lua_State* L, T& self, stack_object value) {
return add_insert_after(meta::has_insert_after<T>(), L, self, std::move(value));
}
static void add_push_back(std::true_type, lua_State*, T& self, stack_object value, iterator&) {
self.push_back(value.as<V>());
}
static void add_push_back(std::true_type, lua_State*, T& self, stack_object value) {
self.push_back(value.as<V>());
}
static void add_push_back(std::false_type, lua_State* L, T& self, stack_object value, iterator& at) {
add_insert(meta::has_insert<T>(), L, self, value, at);
}
static void add_push_back(std::false_type, lua_State* L, T& self, stack_object value) {
add_insert(meta::has_insert<T>(), L, self, value);
}
static void add_associative(std::true_type, lua_State* L, T& self, stack_object key, iterator& at) {
self.insert(at, value_type(key.as<K>(), stack::get<V>(L, 3)));
}
static void add_associative(std::true_type, lua_State* L, T& self, stack_object key) {
auto at = end(L, self);
add_associative(std::true_type(), L, self, std::move(key), at);
}
static void add_associative(std::false_type, lua_State* L, T& self, stack_object value, iterator& at) {
add_push_back(meta::has_push_back<T>(), L, self, value, at);
}
static void add_associative(std::false_type, lua_State* L, T& self, stack_object value) {
add_push_back(meta::has_push_back<T>(), L, self, value);
}
static void add_copyable(std::true_type, lua_State* L, T& self, stack_object value, iterator& at) {
add_associative(is_associative(), L, self, std::move(value), at);
}
static void add_copyable(std::true_type, lua_State* L, T& self, stack_object value) {
add_associative(is_associative(), L, self, value);
}
static void add_copyable(std::false_type, lua_State* L, T& self, stack_object value, iterator&) {
add_copyable(std::false_type(), L, self, std::move(value));
}
static void add_copyable(std::false_type, lua_State* L, T&, stack_object) {
luaL_error(L, "cannot call 'add' on '%s': value_type is non-copyable", detail::demangle<T>().data());
}
static void insert_lookup(std::true_type, lua_State* L, T& self, stack_object, stack_object value) {
// TODO: should we warn or error about someone calling insert on an ordered / lookup container with no associativity?
add_copyable(std::true_type(), L, self, std::move(value));
}
static void insert_lookup(std::false_type, lua_State* L, T& self, stack_object where, stack_object value) {
auto it = begin(L, self);
auto key = where.as<K>();
--key;
std::advance(it, key);
self.insert(it, value.as<V>());
}
static void insert_after_has(std::true_type, lua_State* L, T& self, stack_object where, stack_object value) {
auto key = where.as<K>();
auto backit = self.before_begin();
{
--key;
auto e = end(L, self);
for (auto it = begin(L, self); key > 0; ++backit, ++it, --key) {
if (backit == e) {
luaL_error(L, "sol: out of bounds (too big) for set on '%s'", detail::demangle<T>().c_str());
return;
}
}
}
self.insert_after(backit, value.as<V>());
}
static void insert_after_has(std::false_type, lua_State* L, T&, stack_object, stack_object) {
luaL_error(L, "cannot call 'insert' on '%s': no suitable or similar functionality detected on this container", detail::demangle<T>().data());
}
static void insert_has(std::true_type, lua_State* L, T& self, stack_object key, stack_object value) {
insert_lookup(meta::all<is_associative, is_lookup>(), L, self, std::move(key), std::move(value));
}
static void insert_has(std::false_type, lua_State* L, T& self, stack_object where, stack_object value) {
insert_after_has(meta::has_insert_after<T>(), L, self, where, value);
}
static void insert_copyable(std::true_type, lua_State* L, T& self, stack_object key, stack_object value) {
insert_has(has_find<T>(), L, self, std::move(key), std::move(value));
}
static void insert_copyable(std::false_type, lua_State* L, T&, stack_object, stack_object) {
luaL_error(L, "cannot call 'insert' on '%s': value_type is non-copyable", detail::demangle<T>().data());
}
static void erase_integral(std::true_type, lua_State* L, T& self, K& key) {
auto it = begin(L, self);
--key;
std::advance(it, key);
self.erase(it);
}
static void erase_integral(std::false_type, lua_State* L, T& self, const K& key) {
auto fx = [&](const value_type& r) -> bool {
return key == r;
};
auto e = end(L, self);
auto it = std::find_if(begin(L, self), e, std::ref(fx));
if (it == e) {
return;
}
self.erase(it);
}
static void erase_associative_lookup(std::true_type, lua_State*, T& self, const K& key) {
self.erase(key);
}
static void erase_associative_lookup(std::false_type, lua_State* L, T& self, K& key) {
erase_integral(std::is_integral<K>(), L, self, key);
}
static void erase_after_has(std::true_type, lua_State* L, T& self, K& key) {
auto backit = self.before_begin();
{
--key;
auto e = end(L, self);
for (auto it = begin(L, self); key > 0; ++backit, ++it, --key) {
if (backit == e) {
luaL_error(L, "sol: out of bounds for erase on '%s'", detail::demangle<T>().c_str());
return;
}
}
}
self.erase_after(backit);
}
static void erase_after_has(std::false_type, lua_State* L, T&, const K&) {
luaL_error(L, "sol: cannot call erase on '%s'", detail::demangle<T>().c_str());
}
static void erase_has(std::true_type, lua_State* L, T& self, K& key) {
erase_associative_lookup(meta::any<is_associative, is_lookup>(), L, self, key);
}
static void erase_has(std::false_type, lua_State* L, T& self, K& key) {
erase_after_has(has_erase_after<T>(), L, self, key);
}
static auto size_has(std::false_type, lua_State* L, T& self) {
return std::distance(container_traits<T>::begin(L, self), container_traits<T>::end(L, self));
}
static auto size_has(std::true_type, lua_State*, T& self) {
return self.size();
}
static void clear_has(std::true_type, lua_State*, T& self) {
self.clear();
}
static void clear_has(std::false_type, lua_State* L, T&) {
luaL_error(L, "sol: cannot call clear on '%s'", detail::demangle<T>().c_str());
}
static int get_start(lua_State* L, T& self, K& key) {
return get_it(is_linear_integral(), L, self, key);
}
static void set_start(lua_State* L, T& self, stack_object key, stack_object value) {
set_it(is_linear_integral(), L, self, std::move(key), std::move(value));
}
static std::size_t size_start(lua_State* L, T& self) {
return size_has(has_size<T>(), L, self);
}
static void clear_start(lua_State* L, T& self) {
clear_has(has_clear<T>(), L, self);
}
static void erase_start(lua_State* L, T& self, K& key) {
erase_has(has_erase<T>(), L, self, key);
}
static int next_associative(std::true_type, lua_State* L) {
iter& i = stack::get<user<iter>>(L, 1);
auto& source = i.source;
auto& it = i.it;
if (it == container_traits<T>::end(L, source)) {
return 0;
}
int p;
p = stack::push_reference(L, it->first);
p += stack::stack_detail::push_reference<push_type>(L, it->second);
std::advance(it, 1);
return p;
}
static int pairs_associative(std::true_type, lua_State* L) {
auto& src = get_src(L);
stack::push(L, next);
stack::push<user<iter>>(L, src, container_traits<T>::begin(L, src));
stack::push(L, 1);
return 3;
}
static int next_associative(std::false_type, lua_State* L) {
iter& i = stack::get<user<iter>>(L, 1);
auto& source = i.source;
auto& it = i.it;
K k = stack::get<K>(L, 2);
if (it == container_traits<T>::end(L, source)) {
return 0;
}
int p;
p = stack::push_reference(L, k + 1);
p += stack::stack_detail::push_reference<push_type>(L, *it);
std::advance(it, 1);
return p;
}
static int pairs_associative(std::false_type, lua_State* L) {
auto& src = get_src(L);
stack::push(L, next);
stack::push<user<iter>>(L, src, container_traits<T>::begin(L, src));
stack::push(L, 0);
return 3;
}
static int next(lua_State* L) {
return next_associative(is_associative(), L);
}
public:
static int get(lua_State* L) {
auto& self = get_src(L);
decltype(auto) key = stack::get<K>(L);
return get_start(L, self, key);
}
static int index_get(lua_State* L) {
return get(L);
}
static int set(lua_State* L) {
stack_object value = stack_object(L, raw_index(3));
if (type_of(L, 3) == type::nil) {
return erase(L);
}
auto& self = get_src(L);
set_start(L, self, stack_object(L, raw_index(2)), std::move(value));
return 0;
}
static int index_set(lua_State* L) {
return set(L);
}
static int add(lua_State* L) {
auto& self = get_src(L);
add_copyable(is_copyable(), L, self, stack_object(L, raw_index(2)));
return 0;
}
static int insert(lua_State* L) {
auto& self = get_src(L);
insert_copyable(meta::any<is_associative, is_lookup>(), L, self, stack_object(L, raw_index(2)), stack_object(L, raw_index(3)));
return 0;
}
static int find(lua_State* L) {
auto& self = get_src(L);
return find_has(has_find<T>(), L, self);
}
static iterator begin(lua_State*, T& self) {
using std::begin;
return begin(self);
}
static iterator end(lua_State*, T& self) {
using std::end;
return end(self);
}
static int size(lua_State* L) {
auto& self = get_src(L);
std::size_t r = size_start(L, self);
return stack::push(L, r);
}
static int clear(lua_State* L) {
auto& self = get_src(L);
clear_start(L, self);
return 0;
}
static int erase(lua_State* L) {
auto& self = get_src(L);
decltype(auto) key = stack::get<K>(L, 2);
erase_start(L, self, key);
return 0;
}
static int pairs(lua_State* L) {
return pairs_associative(is_associative(), L);
}
};
template <typename X>
struct container_traits_default<X, std::enable_if_t<std::is_array<std::remove_pointer_t<meta::unwrap_unqualified_t<X>>>::value>> {
private:
typedef std::remove_pointer_t<meta::unwrap_unqualified_t<X>> T;
public:
typedef std::remove_extent_t<T> value_type;
typedef value_type* iterator;
private:
struct iter {
T& source;
iterator it;
iter(T& source, iterator it) : source(source), it(std::move(it)) {}
};
static auto& get_src(lua_State* L) {
auto p = stack::check_get<T*>(L, 1);
#ifdef SOL_SAFE_USERTYPE
if (!p || p.value() == nullptr) {
luaL_error(L, "sol: 'self' argument is nil or not of type '%s' (pass 'self' as first argument with ':' or call on proper type)", detail::demangle<T>().c_str());
}
#endif // Safe getting with error
return *p.value();
}
static int find(std::true_type, lua_State* L) {
T& self = get_src(L);
decltype(auto) value = stack::get<value_type>(L, 2);
std::size_t N = std::extent<T>::value;
for (std::size_t idx = 0; idx < N; ++idx) {
const auto& v = self[idx];
if (v == value) {
return stack::push(L, idx + 1);
}
}
return stack::push(L, lua_nil);
}
static int find(std::false_type, lua_State* L) {
return luaL_error(L, "sol: cannot call 'find' on '%s': no supported comparison operator for the value type", detail::demangle<T>().c_str());
}
static int next(lua_State* L) {
iter& i = stack::get<user<iter>>(L, 1);
auto& source = i.source;
auto& it = i.it;
std::size_t k = stack::get<std::size_t>(L, 2);
if (it == container_traits<T>::end(L, source)) {
return 0;
}
int p;
p = stack::push_reference(L, k + 1);
p += stack::push_reference(L, *it);
std::advance(it, 1);
return p;
}
public:
static int clear(lua_State* L) {
return luaL_error(L, "sol: cannot call 'clear' on type '%s': cannot remove all items from a fixed array", detail::demangle<T>().c_str());
}
static int erase(lua_State* L) {
return luaL_error(L, "sol: cannot call 'erase' on type '%s': cannot remove an item from fixed arrays", detail::demangle<T>().c_str());
}
static int add(lua_State* L) {
return luaL_error(L, "sol: cannot call 'add' on type '%s': cannot add to fixed arrays", detail::demangle<T>().c_str());
}
static int insert(lua_State* L) {
return luaL_error(L, "sol: cannot call 'insert' on type '%s': cannot insert new entries into fixed arrays", detail::demangle<T>().c_str());
}
static int get(lua_State* L) {
T& self = get_src(L);
std::ptrdiff_t idx = stack::get<std::ptrdiff_t>(L, 2);
if (idx > static_cast<std::ptrdiff_t>(std::extent<T>::value) || idx < 1) {
return stack::push(L, lua_nil);
}
--idx;
return stack::push_reference(L, self[idx]);
}
static int index_get(lua_State* L) {
return get(L);
}
static int set(lua_State* L) {
T& self = get_src(L);
std::ptrdiff_t idx = stack::get<std::ptrdiff_t>(L, 2);
if (idx > static_cast<std::ptrdiff_t>(std::extent<T>::value)) {
return luaL_error(L, "sol: index out of bounds (too big) for set on '%s'", detail::demangle<T>().c_str());
}
if (idx < 1) {
return luaL_error(L, "sol: index out of bounds (too small) for set on '%s'", detail::demangle<T>().c_str());
}
--idx;
self[idx] = stack::get<value_type>(L, 3);
return 0;
}
static int index_set(lua_State* L) {
return set(L);
}
static int find(lua_State* L) {
return find(meta::supports_op_equal<value_type, value_type>(), L);
}
static int size(lua_State* L) {
return stack::push(L, std::extent<T>::value);
}
static int pairs(lua_State* L) {
auto& src = get_src(L);
stack::push(L, next);
stack::push<user<iter>>(L, src, container_traits<T>::begin(L, src));
stack::push(L, 0);
return 3;
}
static iterator begin(lua_State*, T& self) {
return std::addressof(self[0]);
}
static iterator end(lua_State*, T& self) {
return std::addressof(self[std::extent<T>::value]);
}
};
} // container_detail
template <typename T>
struct container_traits : container_detail::container_traits_default<T> {};
} // sol
#endif // SOL_CONTAINER_TRAITS_HPP