#pragma once #include #include #include #include #include #include #include #include namespace DB { namespace ErrorCodes { extern const int CANNOT_PARSE_INPUT_ASSERTION_FAILED; extern const int CANNOT_PARSE_DATE; extern const int CANNOT_FORMAT_DATETIME; extern const int LOGICAL_ERROR; } /** Proleptic Gregorian calendar date. YearT is an integral type * which should be at least 32 bits wide, and should preferably * be signed. */ template class GregorianDate { public: /** Construct from date in text form 'YYYY-MM-DD' by reading from * ReadBuffer. */ explicit GregorianDate(ReadBuffer & in); /** Construct from Modified Julian Day. The type T is an * integral type which should be at least 32 bits wide, and * should preferably signed. */ explicit GregorianDate(is_integer auto modified_julian_day); /** Convert to Modified Julian Day. The type T is an integral type * which should be at least 32 bits wide, and should preferably * signed. */ template T toModifiedJulianDay() const; /** Write the date in text form 'YYYY-MM-DD' to a buffer. */ void write(WriteBuffer & buf) const; /** Convert to a string in text form 'YYYY-MM-DD'. */ std::string toString() const; YearT year() const noexcept { return year_; } uint8_t month() const noexcept { return month_; } uint8_t day_of_month() const noexcept /// NOLINT { return day_of_month_; } private: YearT year_; /// NOLINT uint8_t month_; /// NOLINT uint8_t day_of_month_; /// NOLINT }; /** ISO 8601 Ordinal Date. YearT is an integral type which should * be at least 32 bits wide, and should preferably signed. */ template class OrdinalDate { public: OrdinalDate(YearT year, uint16_t day_of_year); /** Construct from Modified Julian Day. The type T is an * integral type which should be at least 32 bits wide, and * should preferably signed. */ template explicit OrdinalDate(DayT modified_julian_day); /** Convert to Modified Julian Day. The type T is an integral * type which should be at least 32 bits wide, and should * preferably be signed. */ template T toModifiedJulianDay() const noexcept; YearT year() const noexcept { return year_; } uint16_t dayOfYear() const noexcept { return day_of_year_; } private: YearT year_; /// NOLINT uint16_t day_of_year_; /// NOLINT }; class MonthDay { public: /** Construct from month and day. */ MonthDay(uint8_t month, uint8_t day_of_month); /** Construct from day of year in Gregorian or Julian * calendars to month and day. */ MonthDay(bool is_leap_year, uint16_t day_of_year); /** Convert month and day in Gregorian or Julian calendars to * day of year. */ uint16_t dayOfYear(bool is_leap_year) const; uint8_t month() const noexcept { return month_; } uint8_t day_of_month() const noexcept /// NOLINT { return day_of_month_; } private: uint8_t month_; /// NOLINT uint8_t day_of_month_; /// NOLINT }; } /* Implementation */ namespace gd { using namespace DB; template static inline constexpr bool is_leap_year(YearT year) { return (year % 4 == 0) && ((year % 400 == 0) || (year % 100 != 0)); } static inline constexpr uint8_t monthLength(bool is_leap_year, uint8_t month) { switch (month) { case 1: return 31; case 2: return is_leap_year ? 29 : 28; case 3: return 31; case 4: return 30; case 5: return 31; case 6: return 30; case 7: return 31; case 8: return 31; case 9: return 30; case 10: return 31; case 11: return 30; case 12: return 31; default: std::terminate(); } } /** Integer division truncated toward negative infinity. */ template static inline constexpr I div(I x, J y) { const auto y_cast = static_cast(y); if (x > 0 && y_cast < 0) return ((x - 1) / y_cast) - 1; else if (x < 0 && y_cast > 0) return ((x + 1) / y_cast) - 1; else return x / y_cast; } /** Integer modulus, satisfying div(x, y)*y + mod(x, y) == x. */ template static inline constexpr I mod(I x, J y) { const auto y_cast = static_cast(y); const auto r = x % y_cast; if ((x > 0 && y_cast < 0) || (x < 0 && y_cast > 0)) return r == 0 ? static_cast(0) : r + y_cast; else return r; } /** Like std::min(), but the type of operands may differ. */ template static inline constexpr I min(I x, J y) { const auto y_cast = static_cast(y); return x < y_cast ? x : y_cast; } static inline char readDigit(ReadBuffer & in) { char c; if (!in.read(c)) throw Exception( "Cannot parse input: expected a digit at the end of stream", ErrorCodes::CANNOT_PARSE_INPUT_ASSERTION_FAILED); else if (c < '0' || c > '9') throw Exception( "Cannot read input: expected a digit but got something else", ErrorCodes::CANNOT_PARSE_INPUT_ASSERTION_FAILED); else return c - '0'; } } namespace DB { template GregorianDate::GregorianDate(ReadBuffer & in) { year_ = gd::readDigit(in) * 1000 + gd::readDigit(in) * 100 + gd::readDigit(in) * 10 + gd::readDigit(in); assertChar('-', in); month_ = gd::readDigit(in) * 10 + gd::readDigit(in); assertChar('-', in); day_of_month_ = gd::readDigit(in) * 10 + gd::readDigit(in); assertEOF(in); if (month_ < 1 || month_ > 12 || day_of_month_ < 1 || day_of_month_ > gd::monthLength(gd::is_leap_year(year_), month_)) throw Exception("Invalid date: " + toString(), ErrorCodes::CANNOT_PARSE_DATE); } template GregorianDate::GregorianDate(is_integer auto modified_julian_day) { const OrdinalDate ord(modified_julian_day); const MonthDay md(gd::is_leap_year(ord.year()), ord.dayOfYear()); year_ = ord.year(); month_ = md.month(); day_of_month_ = md.day_of_month(); } template template T GregorianDate::toModifiedJulianDay() const { const MonthDay md(month_, day_of_month_); const auto day_of_year = md.dayOfYear(gd::is_leap_year(year_)); const OrdinalDate ord(year_, day_of_year); return ord.template toModifiedJulianDay(); } template void GregorianDate::write(WriteBuffer & buf) const { if (year_ < 0 || year_ > 9999) { throw Exception( "Impossible to stringify: year too big or small: " + DB::toString(year_), ErrorCodes::CANNOT_FORMAT_DATETIME); } else { auto y = year_; writeChar('0' + y / 1000, buf); y %= 1000; writeChar('0' + y / 100, buf); y %= 100; writeChar('0' + y / 10, buf); y %= 10; writeChar('0' + y , buf); writeChar('-', buf); auto m = month_; writeChar('0' + m / 10, buf); m %= 10; writeChar('0' + m , buf); writeChar('-', buf); auto d = day_of_month_; writeChar('0' + d / 10, buf); d %= 10; writeChar('0' + d , buf); } } template std::string GregorianDate::toString() const { WriteBufferFromOwnString buf; write(buf); return buf.str(); } template OrdinalDate::OrdinalDate(YearT year, uint16_t day_of_year) : year_(year) , day_of_year_(day_of_year) { if (day_of_year < 1 || day_of_year > (gd::is_leap_year(year) ? 366 : 365)) { throw Exception( "Invalid ordinal date: " + toString(year) + "-" + toString(day_of_year), ErrorCodes::LOGICAL_ERROR); } } template template OrdinalDate::OrdinalDate(DayT modified_julian_day) { /// This function supports day number from -678941 to 2973119 (which represent 0000-01-01 and 9999-12-31 respectively). if constexpr (is_signed_v && std::numeric_limits::lowest() < -678941) if (modified_julian_day < -678941) throw Exception( ErrorCodes::CANNOT_FORMAT_DATETIME, "Value cannot be represented as date because it's out of range"); if constexpr (std::numeric_limits::max() > 2973119) if (modified_julian_day > 2973119) throw Exception( ErrorCodes::CANNOT_FORMAT_DATETIME, "Value cannot be represented as date because it's out of range"); const auto a = modified_julian_day + 678575; const auto quad_cent = gd::div(a, 146097); const auto b = gd::mod(a, 146097); const auto cent = gd::min(gd::div(b, 36524), 3); const auto c = b - cent * 36524; const auto quad = gd::div(c, 1461); const auto d = gd::mod(c, 1461); const auto y = gd::min(gd::div(d, 365), 3); day_of_year_ = d - y * 365 + 1; year_ = static_cast(quad_cent * 400 + cent * 100 + quad * 4 + y + 1); } template template T OrdinalDate::toModifiedJulianDay() const noexcept { const auto y = year_ - 1; return day_of_year_ + 365 * y + gd::div(y, 4) - gd::div(y, 100) + gd::div(y, 400) - 678576; } inline MonthDay::MonthDay(uint8_t month, uint8_t day_of_month) : month_(month) , day_of_month_(day_of_month) { if (month < 1 || month > 12) throw Exception( "Invalid month: " + DB::toString(month), ErrorCodes::LOGICAL_ERROR); /* We can't validate day_of_month here, because we don't know if * it's a leap year. */ } inline MonthDay::MonthDay(bool is_leap_year, uint16_t day_of_year) { if (day_of_year < 1 || day_of_year > (is_leap_year ? 366 : 365)) throw Exception( std::string("Invalid day of year: ") + (is_leap_year ? "leap, " : "non-leap, ") + DB::toString(day_of_year), ErrorCodes::LOGICAL_ERROR); month_ = 1; uint16_t d = day_of_year; while (true) { const auto len = gd::monthLength(is_leap_year, month_); if (d <= len) break; month_++; d -= len; } day_of_month_ = d; } inline uint16_t MonthDay::dayOfYear(bool is_leap_year) const { if (day_of_month_ < 1 || day_of_month_ > gd::monthLength(is_leap_year, month_)) { throw Exception( std::string("Invalid day of month: ") + (is_leap_year ? "leap, " : "non-leap, ") + DB::toString(month_) + "-" + DB::toString(day_of_month_), ErrorCodes::LOGICAL_ERROR); } const auto k = month_ <= 2 ? 0 : is_leap_year ? -1 :-2; return (367 * month_ - 362) / 12 + k + day_of_month_; } }