#pragma once #include #include #include #include #include #include #include #include "crow/settings.h" namespace crow { namespace black_magic { #ifndef CROW_MSVC_WORKAROUND struct OutOfRange { OutOfRange(unsigned /*pos*/, unsigned /*length*/) {} }; constexpr unsigned requires_in_range( unsigned i, unsigned len ) { return i >= len ? throw OutOfRange(i, len) : i; } /// A constant string implementation. class const_str { const char * const begin_; unsigned size_; public: template< unsigned N > constexpr const_str( const char(&arr)[N] ) : begin_(arr), size_(N - 1) { static_assert( N >= 1, "not a string literal"); } constexpr char operator[]( unsigned i ) const { return requires_in_range(i, size_), begin_[i]; } constexpr operator const char *() const { return begin_; } constexpr const char* begin() const { return begin_; } constexpr const char* end() const { return begin_ + size_; } constexpr unsigned size() const { return size_; } }; constexpr unsigned find_closing_tag(const_str s, unsigned p) { return s[p] == '>' ? p : find_closing_tag(s, p+1); } constexpr bool is_valid(const_str s, unsigned i = 0, int f = 0) { return i == s.size() ? f == 0 : f < 0 || f >= 2 ? false : s[i] == '<' ? is_valid(s, i+1, f+1) : s[i] == '>' ? is_valid(s, i+1, f-1) : is_valid(s, i+1, f); } constexpr bool is_equ_p(const char* a, const char* b, unsigned n) { return *a == 0 && *b == 0 && n == 0 ? true : (*a == 0 || *b == 0) ? false : n == 0 ? true : *a != *b ? false : is_equ_p(a+1, b+1, n-1); } constexpr bool is_equ_n(const_str a, unsigned ai, const_str b, unsigned bi, unsigned n) { return ai + n > a.size() || bi + n > b.size() ? false : n == 0 ? true : a[ai] != b[bi] ? false : is_equ_n(a,ai+1,b,bi+1,n-1); } constexpr bool is_int(const_str s, unsigned i) { return is_equ_n(s, i, "", 0, 5); } constexpr bool is_uint(const_str s, unsigned i) { return is_equ_n(s, i, "", 0, 6); } constexpr bool is_float(const_str s, unsigned i) { return is_equ_n(s, i, "", 0, 7) || is_equ_n(s, i, "", 0, 8); } constexpr bool is_str(const_str s, unsigned i) { return is_equ_n(s, i, "", 0, 5) || is_equ_n(s, i, "", 0, 8); } constexpr bool is_path(const_str s, unsigned i) { return is_equ_n(s, i, "", 0, 6); } #endif template struct parameter_tag { static const int value = 0; }; #define CROW_INTERNAL_PARAMETER_TAG(t, i) \ template <> \ struct parameter_tag \ { \ static const int value = i; \ } CROW_INTERNAL_PARAMETER_TAG(int, 1); CROW_INTERNAL_PARAMETER_TAG(char, 1); CROW_INTERNAL_PARAMETER_TAG(short, 1); CROW_INTERNAL_PARAMETER_TAG(long, 1); CROW_INTERNAL_PARAMETER_TAG(long long, 1); CROW_INTERNAL_PARAMETER_TAG(unsigned int, 2); CROW_INTERNAL_PARAMETER_TAG(unsigned char, 2); CROW_INTERNAL_PARAMETER_TAG(unsigned short, 2); CROW_INTERNAL_PARAMETER_TAG(unsigned long, 2); CROW_INTERNAL_PARAMETER_TAG(unsigned long long, 2); CROW_INTERNAL_PARAMETER_TAG(double, 3); CROW_INTERNAL_PARAMETER_TAG(std::string, 4); #undef CROW_INTERNAL_PARAMETER_TAG template struct compute_parameter_tag_from_args_list; template <> struct compute_parameter_tag_from_args_list<> { static const int value = 0; }; template struct compute_parameter_tag_from_args_list { static const int sub_value = compute_parameter_tag_from_args_list::value; static const int value = parameter_tag::type>::value ? sub_value* 6 + parameter_tag::type>::value : sub_value; }; static inline bool is_parameter_tag_compatible(uint64_t a, uint64_t b) { if (a == 0) return b == 0; if (b == 0) return a == 0; int sa = a%6; int sb = a%6; if (sa == 5) sa = 4; if (sb == 5) sb = 4; if (sa != sb) return false; return is_parameter_tag_compatible(a/6, b/6); } static inline unsigned find_closing_tag_runtime(const char* s, unsigned p) { return s[p] == 0 ? throw std::runtime_error("unmatched tag <") : s[p] == '>' ? p : find_closing_tag_runtime(s, p + 1); } static inline uint64_t get_parameter_tag_runtime(const char* s, unsigned p = 0) { return s[p] == 0 ? 0 : s[p] == '<' ? ( std::strncmp(s+p, "", 5) == 0 ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 1 : std::strncmp(s+p, "", 6) == 0 ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 2 : (std::strncmp(s+p, "", 7) == 0 || std::strncmp(s+p, "", 8) == 0) ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 3 : (std::strncmp(s+p, "", 5) == 0 || std::strncmp(s+p, "", 8) == 0) ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 4 : std::strncmp(s+p, "", 6) == 0 ? get_parameter_tag_runtime(s, find_closing_tag_runtime(s, p)) * 6 + 5 : throw std::runtime_error("invalid parameter type") ) : get_parameter_tag_runtime(s, p+1); } #ifndef CROW_MSVC_WORKAROUND constexpr uint64_t get_parameter_tag(const_str s, unsigned p = 0) { return p == s.size() ? 0 : s[p] == '<' ? ( is_int(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 1 : is_uint(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 2 : is_float(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 3 : is_str(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 4 : is_path(s, p) ? get_parameter_tag(s, find_closing_tag(s, p)) * 6 + 5 : throw std::runtime_error("invalid parameter type") ) : get_parameter_tag(s, p+1); } #endif template struct S { template using push = S; template using push_back = S; template class U> using rebind = U; }; template struct CallHelper; template struct CallHelper> { template ()(std::declval()...)) > static char __test(int); template static int __test(...); static constexpr bool value = sizeof(__test(0)) == sizeof(char); }; template struct single_tag_to_type { }; template <> struct single_tag_to_type<1> { using type = int64_t; }; template <> struct single_tag_to_type<2> { using type = uint64_t; }; template <> struct single_tag_to_type<3> { using type = double; }; template <> struct single_tag_to_type<4> { using type = std::string; }; template <> struct single_tag_to_type<5> { using type = std::string; }; template struct arguments { using subarguments = typename arguments::type; using type = typename subarguments::template push::type>; }; template <> struct arguments<0> { using type = S<>; }; template struct last_element_type { using type = typename std::tuple_element>::type; }; template <> struct last_element_type<> { }; // from http://stackoverflow.com/questions/13072359/c11-compile-time-array-with-logarithmic-evaluation-depth template using Invoke = typename T::type; template struct seq{ using type = seq; }; template struct concat; template struct concat, seq> : seq{}; template using Concat = Invoke>; template struct gen_seq; template using GenSeq = Invoke>; template struct gen_seq : Concat, GenSeq>{}; template<> struct gen_seq<0> : seq<>{}; template<> struct gen_seq<1> : seq<0>{}; template struct pop_back_helper; template struct pop_back_helper, Tuple> { template