#ifndef __RSTL_HPP__ #define __RSTL_HPP__ #include #include #include #include "optional.hpp" namespace rstl { template using optional_object = std::experimental::optional; /** * @brief Vector reserved on construction */ template class reserved_vector : public std::vector { public: reserved_vector() { this->reserve(N); } reserved_vector(size_t n, const T& val) : std::vector(n, val) {} }; template class prereserved_vector { size_t x0_size = 1; T x4_data[N]; public: void set_size(size_t n) { if (n <= N) x0_size = n; } void set_data(const T* data) { memmove(x4_data, data, sizeof(T) * x0_size); } size_t size() const { return x0_size; } T& back() const { return x4_data[(x0_size == 0) ? 0 : x0_size - 1]; } T& front() const { return x4_data[0]; } T& operator[](size_t idx) { return x4_data[idx]; } const T& operator[](size_t idx) const { return x4_data[idx]; } }; template ForwardIt binary_find(ForwardIt first, ForwardIt last, const T& value) { first = std::lower_bound(first, last, value); return (!(first == last) && !(value < *first)) ? first : last; } template ForwardIt binary_find(ForwardIt first, ForwardIt last, const T& value, GetKey getkey) { auto comp = [&](const auto& left, const T& right) { return getkey(left) < right; }; first = std::lower_bound(first, last, value, comp); return (!(first == last) && !(value < getkey(*first))) ? first : last; } #if 0 template class basic_string { struct COWData { uint32_t x0_capacity; uint32_t x4_refCount; _CharTp x8_data[]; }; const _CharTp* x0_ptr; COWData* x4_cow; uint32_t x8_size; void internal_allocate(int size) { x4_cow = reinterpret_cast(new uint8_t[size * sizeof(_CharTp) + 8]); x0_ptr = x4_cow->x8_data; x4_cow->x0_capacity = uint32_t(size); x4_cow->x4_refCount = 1; } static const _CharTp _EmptyString; public: struct literal_t {}; basic_string(literal_t, const _CharTp* data) { x0_ptr = data; x4_cow = nullptr; const _CharTp* it = data; while (*it) ++it; x8_size = uint32_t((it - data) / sizeof(_CharTp)); } basic_string(const basic_string& str) { x0_ptr = str.x0_ptr; x4_cow = str.x4_cow; x8_size = str.x8_size; if (x4_cow) ++x4_cow->x4_refCount; } basic_string(const _CharTp* data, int size) { if (size <= 0 && !data) { x0_ptr = &_EmptyString; x4_cow = nullptr; x8_size = 0; return; } const _CharTp* it = data; uint32_t len = 0; while (*it) { if (size != -1 && len >= size) break; ++it; ++len; } internal_allocate(len + 1); x8_size = len; for (int i = 0; i < len; ++i) x4_cow->x8_data[i] = data[i]; x4_cow->x8_data[len] = 0; } ~basic_string() { if (x4_cow && --x4_cow->x4_refCount == 0) delete[] x4_cow; } }; template <> const char basic_string::_EmptyString = 0; template <> const wchar_t basic_string::_EmptyString = 0; typedef basic_string wstring; typedef basic_string string; wstring wstring_l(const wchar_t* data) { return wstring(wstring::literal_t(), data); } string string_l(const char* data) { return string(string::literal_t(), data); } #endif } #endif // __RSTL_HPP__