20 General utilities library [utilities]

20.16 Compile-time rational arithmetic [ratio]

20.16.1 In general [ratio.general]

Subclause [ratio] describes the ratio library.
It provides a class template ratio which exactly represents any finite rational number with a numerator and denominator representable by compile-time constants of type intmax_­t.
Throughout subclause [ratio], the names of template parameters are used to express type requirements.
If a template parameter is named R1 or R2, and the template argument is not a specialization of the ratio template, the program is ill-formed.

namespace std { // [ratio.ratio], class template ratio template<intmax_t N, intmax_t D = 1> class ratio; // [ratio.arithmetic], ratio arithmetic template<class R1, class R2> using ratio_add = see below; template<class R1, class R2> using ratio_subtract = see below; template<class R1, class R2> using ratio_multiply = see below; template<class R1, class R2> using ratio_divide = see below; // [ratio.comparison], ratio comparison template<class R1, class R2> struct ratio_equal; template<class R1, class R2> struct ratio_not_equal; template<class R1, class R2> struct ratio_less; template<class R1, class R2> struct ratio_less_equal; template<class R1, class R2> struct ratio_greater; template<class R1, class R2> struct ratio_greater_equal; template<class R1, class R2> inline constexpr bool ratio_equal_v = ratio_equal<R1, R2>::value; template<class R1, class R2> inline constexpr bool ratio_not_equal_v = ratio_not_equal<R1, R2>::value; template<class R1, class R2> inline constexpr bool ratio_less_v = ratio_less<R1, R2>::value; template<class R1, class R2> inline constexpr bool ratio_less_equal_v = ratio_less_equal<R1, R2>::value; template<class R1, class R2> inline constexpr bool ratio_greater_v = ratio_greater<R1, R2>::value; template<class R1, class R2> inline constexpr bool ratio_greater_equal_v = ratio_greater_equal<R1, R2>::value; // [ratio.si], convenience SI typedefs using yocto = ratio<1, 1'000'000'000'000'000'000'000'000>; // see below using zepto = ratio<1, 1'000'000'000'000'000'000'000>; // see below using atto = ratio<1, 1'000'000'000'000'000'000>; using femto = ratio<1, 1'000'000'000'000'000>; using pico = ratio<1, 1'000'000'000'000>; using nano = ratio<1, 1'000'000'000>; using micro = ratio<1, 1'000'000>; using milli = ratio<1, 1'000>; using centi = ratio<1, 100>; using deci = ratio<1, 10>; using deca = ratio< 10, 1>; using hecto = ratio< 100, 1>; using kilo = ratio< 1'000, 1>; using mega = ratio< 1'000'000, 1>; using giga = ratio< 1'000'000'000, 1>; using tera = ratio< 1'000'000'000'000, 1>; using peta = ratio< 1'000'000'000'000'000, 1>; using exa = ratio< 1'000'000'000'000'000'000, 1>; using zetta = ratio< 1'000'000'000'000'000'000'000, 1>; // see below using yotta = ratio<1'000'000'000'000'000'000'000'000, 1>; // see below }

20.16.3 Class template ratio[ratio.ratio]

namespace std { template<intmax_t N, intmax_t D = 1> class ratio { public: static constexpr intmax_t num; static constexpr intmax_t den; using type = ratio<num, den>; }; }
If the template argument D is zero or the absolute values of either of the template arguments N and D is not representable by type intmax_­t, the program is ill-formed.
[Note 1:
These rules ensure that infinite ratios are avoided and that for any negative input, there exists a representable value of its absolute value which is positive.
This excludes the most negative value.
— end note]
The static data members num and den shall have the following values, where gcd represents the greatest common divisor of the absolute values of N and D:
• num shall have the value sign(N) * sign(D) * abs(N) / gcd.
• den shall have the value abs(D) / gcd.

20.16.4 Arithmetic on ratios [ratio.arithmetic]

Each of the alias templates ratio_­add, ratio_­subtract, ratio_­multiply, and ratio_­divide denotes the result of an arithmetic computation on two ratios R1 and R2.
With X and Y computed (in the absence of arithmetic overflow) as specified by Table 58, each alias denotes a ratio<U, V> such that U is the same as ratio<X, Y>​::​num and V is the same as ratio<X, Y>​::​den.
If it is not possible to represent U or V with intmax_­t, the program is ill-formed.
Otherwise, an implementation should yield correct values of U and V.
If it is not possible to represent X or Y with intmax_­t, the program is ill-formed unless the implementation yields correct values of U and V.
Table 58: Expressions used to perform ratio arithmetic [tab:ratio.arithmetic]
 🔗 Type Value of X Value of Y 🔗 ratio_­add R1​::​num * R2​::​den + R1​::​den * R2​::​den 🔗 R2​::​num * R1​::​den 🔗 ratio_­subtract R1​::​num * R2​::​den - R1​::​den * R2​::​den 🔗 R2​::​num * R1​::​den 🔗 ratio_­multiply R1​::​num * R2​::​num R1​::​den * R2​::​den 🔗 ratio_­divide R1​::​num * R2​::​den R1​::​den * R2​::​num
[Example 1: static_assert(ratio_add<ratio<1, 3>, ratio<1, 6>>::num == 1, "1/3+1/6 == 1/2"); static_assert(ratio_add<ratio<1, 3>, ratio<1, 6>>::den == 2, "1/3+1/6 == 1/2"); static_assert(ratio_multiply<ratio<1, 3>, ratio<3, 2>>::num == 1, "1/3*3/2 == 1/2"); static_assert(ratio_multiply<ratio<1, 3>, ratio<3, 2>>::den == 2, "1/3*3/2 == 1/2"); // The following cases may cause the program to be ill-formed under some implementations static_assert(ratio_add<ratio<1, INT_MAX>, ratio<1, INT_MAX>>::num == 2, "1/MAX+1/MAX == 2/MAX"); static_assert(ratio_add<ratio<1, INT_MAX>, ratio<1, INT_MAX>>::den == INT_MAX, "1/MAX+1/MAX == 2/MAX"); static_assert(ratio_multiply<ratio<1, INT_MAX>, ratio<INT_MAX, 2>>::num == 1, "1/MAX * MAX/2 == 1/2"); static_assert(ratio_multiply<ratio<1, INT_MAX>, ratio<INT_MAX, 2>>::den == 2, "1/MAX * MAX/2 == 1/2"); — end example]

20.16.5 Comparison of ratios [ratio.comparison]

```template<class R1, class R2> struct ratio_equal : bool_constant<R1::num == R2::num && R1::den == R2::den> { }; ```
```template<class R1, class R2> struct ratio_not_equal : bool_constant<!ratio_equal_v<R1, R2>> { }; ```
```template<class R1, class R2> struct ratio_less : bool_constant<see below> { }; ```
If R1​::​num × R2​::​den is less than R2​::​num × R1​::​den, ratio_­less<R1, R2> shall be derived from bool_­constant<true>; otherwise it shall be derived from bool_­constant<false>.
Implementations may use other algorithms to compute this relationship to avoid overflow.
If overflow occurs, the program is ill-formed.
```template<class R1, class R2> struct ratio_less_equal : bool_constant<!ratio_less_v<R2, R1>> { }; ```
```template<class R1, class R2> struct ratio_greater : bool_constant<ratio_less_v<R2, R1>> { }; ```
```template<class R1, class R2> struct ratio_greater_equal : bool_constant<!ratio_less_v<R1, R2>> { }; ```

20.16.6 SI types for ratio[ratio.si]

For each of the typedef-names yocto, zepto, zetta, and yotta, if both of the constants used in its specification are representable by intmax_­t, the typedef is defined; if either of the constants is not representable by intmax_­t, the typedef is not defined.