#pragma once #include #include #include #include #include // for std::monostate #include //#include "../utils/platform.hpp" namespace geode::base { uintptr_t get(); } #if defined(GEODE_IS_MACOS) || defined(GEODE_IS_ANDROID) namespace gd { struct _internal_string { size_t m_len; size_t m_capacity; int m_refcount; }; class GEODE_DLL string { public: string(); string(char const* ok); string(std::string ok) : string(ok.c_str()) {} operator std::string() const { return std::string((char*)m_data, m_data[-1].m_len); } bool operator==(string const& other) const; string(string const& ok); string& operator=(char const* ok); string& operator=(string const& ok); __attribute__((noinline)) ~string(); char const* c_str() const { return (char const*)m_data; } size_t size() const { return m_data[-1].m_len; } protected: _internal_string* m_data; }; struct _rb_tree_base { bool m_isblack; _rb_tree_base* m_parent; _rb_tree_base* m_left; _rb_tree_base* m_right; }; template struct _rb_tree_node : public _rb_tree_base { T m_value; }; static void _rb_tree_rotate_left(_rb_tree_base* const x, _rb_tree_base*& root) { _rb_tree_base* const y = x->m_right; x->m_right = y->m_left; if (y->m_left !=0) y->m_left->m_parent = x; y->m_parent = x->m_parent; if (x == root) root = y; else if (x == x->m_parent->m_left) x->m_parent->m_left = y; else x->m_parent->m_right = y; y->m_left = x; x->m_parent = y; } static void _rb_tree_rotate_right(_rb_tree_base* const x, _rb_tree_base*& root) { _rb_tree_base* const y = x->m_left; x->m_left = y->m_right; if (y->m_right != 0) y->m_right->m_parent = x; y->m_parent = x->m_parent; if (x == root) root = y; else if (x == x->m_parent->m_right) x->m_parent->m_right = y; else x->m_parent->m_left = y; y->m_right = x; x->m_parent = y; } static void _rb_insert_rebalance(const bool insert_left, _rb_tree_base* x, _rb_tree_base* p, _rb_tree_base& header) { _rb_tree_base *& root = header.m_parent; x->m_parent = p; x->m_left = 0; x->m_right = 0; x->m_isblack = false; if (insert_left) { p->m_left = x; if (p == &header) { header.m_parent = x; header.m_right = x; } else if (p == header.m_left){ header.m_left = x; } } else { p->m_right = x; if (p == header.m_right) { header.m_right = x; } } while (x != root && x->m_parent->m_isblack == false) { _rb_tree_base* const xpp = x->m_parent->m_parent; if (x->m_parent == xpp->m_left) { _rb_tree_base* const y = xpp->m_right; if (y && y->m_isblack == false) { x->m_parent->m_isblack = true; y->m_isblack = true; xpp->m_isblack = false; x = xpp; } else { if (x == x->m_parent->m_right) { x = x->m_parent; _rb_tree_rotate_left(x, root); } x->m_parent->m_isblack = true; xpp->m_isblack = false; _rb_tree_rotate_right(xpp, root); } } else { _rb_tree_base* const y = xpp->m_left; if (y && y->m_isblack == false) { x->m_parent->m_isblack = true; y->m_isblack = true; xpp->m_isblack = false; x = xpp; } else { if (x == x->m_parent->m_left) { x = x->m_parent; _rb_tree_rotate_right(x, root); } x->m_parent->m_isblack = true; xpp->m_isblack = false; _rb_tree_rotate_left(xpp, root); } } } root->m_isblack = true; } static _rb_tree_base* _rb_increment(_rb_tree_base* __x) throw () { if (__x->m_right != 0) { __x = __x->m_right; while (__x->m_left != 0) __x = __x->m_left; } else { _rb_tree_base* __y = __x->m_parent; while (__x == __y->m_right) { __x = __y; __y = __y->m_parent; } if (__x->m_right != __y) __x = __y; } return __x; } static _rb_tree_base* _rb_decrement(_rb_tree_base* __x) throw () { if (!__x->m_isblack && __x->m_parent->m_parent == __x) __x = __x->m_right; else if (__x->m_left != 0) { _rb_tree_base* __y = __x->m_left; while (__y->m_right != 0) __y = __y->m_right; __x = __y; } else { _rb_tree_base* __y = __x->m_parent; while (__x == __y->m_left) { __x = __y; __y = __y->m_parent; } __x = __y; } return __x; } template class GEODE_DLL map { protected: std::less compare; _rb_tree_base m_header; size_t m_nodecount; public: typedef _rb_tree_node >* _tree_node; std::map std() { return (std::map)(*this); } operator std::map() { auto iter_node = static_cast<_tree_node>(m_header.m_left); auto end_node = static_cast<_tree_node>(&m_header); std::map out; for (;iter_node != end_node; iter_node = static_cast<_tree_node>(_rb_increment(iter_node))) { out[iter_node->m_value.first] = iter_node->m_value.second; } return out; } operator std::map() const { auto iter_node = static_cast<_tree_node>(m_header.m_left); auto end_node = (_tree_node)(&m_header); std::map out; for (;iter_node != end_node; iter_node = static_cast<_tree_node>(_rb_increment(iter_node))) { out[iter_node->m_value.first] = iter_node->m_value.second; } return out; } void insert(_tree_node x, _tree_node p, const std::pair& val) { bool insert_left = (x != 0 || p == static_cast<_tree_node>(&m_header) || val.first < p->m_value.first); _tree_node z = new _rb_tree_node >(); z->m_value = val; _rb_insert_rebalance(insert_left, z, p, m_header); ++m_nodecount; } void insert_pair(const std::pair& val) { _tree_node x = static_cast<_tree_node>(m_header.m_parent); _tree_node y = static_cast<_tree_node>(&m_header); bool comp = true; while (x != 0) { y = x; comp = val.first < x->m_value.first; x = comp ? static_cast<_tree_node>(x->m_left) : static_cast<_tree_node>(x->m_right); } auto iter = y; if (comp) { if (iter == static_cast<_tree_node>(m_header.m_left)) { insert(x, y, val); } else { iter = static_cast<_tree_node>(_rb_decrement(iter)); } } if (iter->m_value.first < val.first) { insert(x, y, val); } } map(std::map input) { m_header.m_isblack = false; m_header.m_parent = 0; m_header.m_left = &m_header; m_header.m_right = &m_header; for (auto i : input) { insert_pair(i); } } void erase(_tree_node x) { while (x != 0) { erase(static_cast<_tree_node>(x->m_right)); auto y = static_cast<_tree_node>(x->m_left); delete y; x = y; } } map(map const& lol) : map(std::map(lol)) {} map() : map(std::map()) {} ~map() { erase(static_cast<_tree_node>(m_header.m_parent)); } }; template class GEODE_DLL vector { public: using value_type = T; operator std::vector() const { std::vector out; for (auto i = m_start; i != m_finish; ++i) { out.push_back(*i); } return out; } vector(std::vector input) { auto tmp = new T[input.size()]; m_start = tmp; m_finish = m_start + input.size(); m_capacity_end = m_start + input.size(); for (auto i : input) { *tmp = i; tmp++; } } T& front() { return *m_start; } auto begin() { return m_start; } auto end() { return m_finish; } auto begin() const { return static_cast(m_start); } auto end() const { return static_cast(m_finish); } vector(vector const& lol) : vector(std::vector(lol)) {} vector() : vector(std::vector()) {} ~vector() { delete[] m_start; } protected: T* m_start; T* m_finish; T* m_capacity_end; }; struct _bit_reference { uintptr_t* m_bitptr; uintptr_t m_mask; _bit_reference(uintptr_t* x, uintptr_t y) : m_bitptr(x), m_mask(y) {} _bit_reference() : m_bitptr(0), m_mask(0) {} operator bool() const { return !!(*m_bitptr & m_mask); } _bit_reference& operator=(bool x) { if (x) *m_bitptr |= m_mask; else *m_bitptr &= ~m_mask; return *this; } _bit_reference& operator=(const _bit_reference& x) { return *this = bool(x); } bool operator==(const _bit_reference& x) const { return bool(*this) == bool(x); } bool operator<(const _bit_reference& x) const { return !bool(*this) && bool(x); } void flip() { *m_bitptr ^= m_mask; } }; struct _bit_iterator { uintptr_t* m_bitptr; unsigned int m_offset; _bit_iterator(uintptr_t* x) : m_bitptr(x), m_offset(0) {} _bit_iterator(uintptr_t* x, unsigned o) : m_bitptr(x), m_offset(o) {} _bit_reference operator*() const { return _bit_reference(m_bitptr, 1UL << m_offset); } _bit_iterator& operator++() { if (m_offset++ == sizeof(uintptr_t)-1) { m_offset = 0; m_bitptr++; } return *this; } bool operator!=(const _bit_iterator& b) { return !(m_bitptr == b.m_bitptr && m_offset == b.m_offset); } }; template <> class vector { protected: _bit_iterator m_start; _bit_iterator m_end; uintptr_t* m_capacity_end; public: vector(std::vector input) : m_start(0), m_end(0) { auto realsize = input.size()/int(sizeof(uintptr_t)); auto tmp = new uintptr_t[realsize]; m_start = _bit_iterator(tmp); m_end = _bit_iterator(tmp + realsize, input.size()%sizeof(uintptr_t)); m_capacity_end = tmp + realsize; auto itmp = m_start; for (auto i : input) { *itmp = i; ++itmp; } } operator std::vector() { std::vector out; for (auto i = m_start; i != m_end; ++i) { out.push_back(*i); } return out; } operator std::vector() const { std::vector out; for (auto i = m_start; i != m_end; ++i) { out.push_back(*i); } return out; } vector(vector const& lol) : vector(std::vector(lol)) {} vector() : vector(std::vector()) {} ~vector() { delete[] m_start.m_bitptr; } }; }; #elif defined(GEODE_IS_IOS) namespace gd { class GEODE_DLL string { public: string() {} string(char const* ok) : m_internal(ok) {} string(std::string ok) : m_internal(ok) {} operator std::string() { return m_internal; } operator std::string() const { return m_internal; } string(string const& ok) : m_internal(ok) {} string& operator=(char const* ok) {m_internal = ok; return *this;} string& operator=(string const& ok) {m_internal = ok; return *this;} ~string() {} char const* c_str() const {return m_internal.c_str(); } protected: std::string m_internal; }; template class GEODE_DLL vector { public: using value_type = T; operator std::vector() { return m_internal; } operator std::vector() const { return m_internal; } vector(std::vector input) : m_internal(input) {} T& front() { return m_internal.front(); } vector(vector const& lol) : m_internal(lol) {} vector() : m_internal() {} ~vector() {} protected: std::vector m_internal; }; template class GEODE_DLL map { protected: std::map m_internal; public: operator std::map() { return m_internal; } operator std::map() const { return m_internal; } map(std::map input) : m_internal(input) {} map(map const& lol) : m_internal(lol) {} map() {} ~map() {} }; } #else namespace gd = std; #endif