Merge pull request #355 from chiphogg/chiphogg/switch-to-mag

Use Magnitude instead of ratio in unit implementations

example/custom_systems.cpp

@@ -33,7 +33,7 @@ using namespace units;
 namespace fps {
 
 struct foot : named_unit<foot, "ft"> {};
-struct yard : named_scaled_unit<yard, "yd", ratio(3), foot> {};
+struct yard : named_scaled_unit<yard, "yd", as_magnitude<3>(), foot> {};
 
 struct dim_length : base_dimension<"L", foot> {};
 
@@ -54,8 +54,8 @@ using length = quantity<dim_length, U, Rep>;
 
 namespace fps {
 
-struct foot : named_scaled_unit<foot, "ft", ratio(3'048, 1'000, -1), metre> {};
-struct yard : named_scaled_unit<yard, "yd", ratio(3), foot> {};
+struct foot : named_scaled_unit<foot, "ft", as_magnitude<ratio(3'048, 1'000, -1)>(), metre> {};
+struct yard : named_scaled_unit<yard, "yd", as_magnitude<3>(), foot> {};
 
 struct dim_length : base_dimension<"L", foot> {};
 
@@ -103,7 +103,7 @@ template<Unit U>
 std::ostream& operator<<(std::ostream& os, const U& u)
 {
   using unit_type = std::remove_cvref_t<decltype(u)>;
-  return os << unit_type::ratio << " x " << unit_type::reference::symbol.standard();
+  return os << as_ratio(unit_type::mag) << " x " << unit_type::reference::symbol.standard();
 }
 
 void what_is_your_ratio()

src/core/include/units/bits/base_units_ratio.h

@@ -24,29 +24,25 @@
 
 #include <units/base_dimension.h>
 #include <units/exponent.h>
+#include <units/magnitude.h>
 #include <units/ratio.h>
 
 namespace units::detail {
 
-template<Exponent E>
-  requires(E::den == 1 || E::den == 2)  // TODO provide support for any den
-constexpr ratio exp_ratio()
-{
-  const ratio base_ratio = E::dimension::base_unit::ratio;
-  const ratio positive_ratio =
-    E::num * E::den < 0 ? ratio(base_ratio.den, base_ratio.num, -base_ratio.exp) : base_ratio;
-  const std::intmax_t N = E::num * E::den < 0 ? -E::num : E::num;
-  const ratio ratio_pow = pow<N>(positive_ratio);
-  return E::den == 2 ? sqrt(ratio_pow) : ratio_pow;
-}
-
 /**
- * @brief Calculates the common ratio of all the references of base units in the derived dimension
+ * @brief Calculates the "absolute" magnitude of the derived dimension defined by this list.
+ *
+ * "Absolute" magnitudes are not physically observable: only ratios of magnitudes are.  For example: if we multiplied
+ * all magnitudes in the system by the same constant, no meaningful results would change.  However, in practice, we need
+ * to make some global choice for the "absolute" values of magnitudes, so that we can compute their ratios.
+ *
+ * The point of this function is to compute the absolute magnitude of a derived dimension, in terms of the absolute
+ * magnitudes of its constituent dimensions.
  */
 template<typename... Es>
-constexpr ratio base_units_ratio(exponent_list<Es...>)
+constexpr Magnitude auto absolute_magnitude(exponent_list<Es...>)
 {
-  return (exp_ratio<Es>() * ... * ratio(1));
+  return (pow<ratio{Es::num, Es::den}>(Es::dimension::base_unit::mag) * ... * magnitude<>{});
 }
 
 }  // namespace units::detail

src/core/include/units/bits/basic_concepts.h

@@ -28,7 +28,7 @@
 #include <units/bits/external/fixed_string.h>
 #include <units/bits/external/type_traits.h>
 #include <units/customization_points.h>
-#include <units/ratio.h>
+#include <units/magnitude.h>
 // IWYU pragma: end_exports
 
 #include <cstdint>
@@ -56,24 +56,15 @@ void to_prefix_base(const volatile prefix_base<R>*);
 template<typename T>
 concept Prefix = requires(T* t) { detail::to_prefix_base(t); };
 
-/**
- * @brief A concept matching unit's ratio
- *
- * Satisfied by all ratio values for which `R.num > 0` and `R.den > 0`.
- */
-template<ratio R>
-concept UnitRatio = (R.num > 0) && (R.den > 0);
-
 // Unit
-template<ratio R, typename U>
-  requires UnitRatio<R>
+template<Magnitude auto M, typename U>
 struct scaled_unit;
 
 // TODO: Remove when P1985 accepted
 namespace detail {
 
-template<ratio R, typename U>
-void to_base_scaled_unit(const volatile scaled_unit<R, U>*);
+template<Magnitude auto M, typename U>
+void to_base_scaled_unit(const volatile scaled_unit<M, U>*);
 
 }  // namespace detail
 

src/core/include/units/bits/common_type.h

@@ -55,22 +55,22 @@ struct common_quantity_reference_impl<reference<D, U>, reference<D, U>> {
 
 template<typename D, typename U1, typename U2>
 struct common_quantity_reference_impl<reference<D, U1>, reference<D, U2>> {
-  using type = reference<D, downcast_unit<D, common_ratio(U1::ratio, U2::ratio)>>;
+  using type = reference<D, downcast_unit<D, common_magnitude(U1::mag, U2::mag)>>;
 };
 
 template<typename D1, typename U1, typename D2, typename U2>
   requires(same_unit_reference<dimension_unit<D1>, dimension_unit<D2>>::value)
 struct common_quantity_reference_impl<reference<D1, U1>, reference<D2, U2>> {
-  using type = reference<D1, downcast_unit<D1, common_ratio(U1::ratio, U2::ratio)>>;
+  using type = reference<D1, downcast_unit<D1, common_magnitude(U1::mag, U2::mag)>>;
 };
 
 template<typename D1, typename U1, typename D2, typename U2>
 struct common_quantity_reference_impl<reference<D1, U1>, reference<D2, U2>> {
   using dimension = conditional<is_specialization_of<D1, unknown_dimension>, D2, D1>;
-  static constexpr ratio r1 = D1::base_units_ratio * U1::ratio;
-  static constexpr ratio r2 = D2::base_units_ratio * U2::ratio;
-  static constexpr ratio cr = common_ratio(r1, r2);
-  using unit = downcast_unit<dimension, cr / dimension::base_units_ratio>;
+  static constexpr UNITS_MSVC_WORKAROUND(Magnitude) auto m1 = D1::base_units_ratio * U1::mag;
+  static constexpr UNITS_MSVC_WORKAROUND(Magnitude) auto m2 = D2::base_units_ratio * U2::mag;
+  static constexpr UNITS_MSVC_WORKAROUND(Magnitude) auto cm = common_magnitude(m1, m2);
+  using unit = downcast_unit<dimension, cm / dimension::base_units_ratio>;
   using type = reference<dimension, unit>;
 };
 

src/core/include/units/bits/derived_scaled_unit.h

@@ -23,6 +23,7 @@
 #pragma once
 
 #include <units/derived_dimension.h>
+#include <units/magnitude.h>
 
 namespace units::detail {
 
@@ -35,24 +36,14 @@ inline constexpr bool compatible_units<exponent_list<Es...>, Us...> = (UnitOf<Us
 
 // derived_scaled_unit
 
-template<Exponent E>
-constexpr ratio inverse_if_negative(const ratio& r)
-{
-  if constexpr (E::num * E::den > 0)
-    return r;
-  else
-    return inverse(r);
-}
-
 template<Unit... Us, typename... Es>
-constexpr ratio derived_ratio(exponent_list<Es...>)
+constexpr Magnitude auto derived_mag(exponent_list<Es...>)
 {
-  return (... * inverse_if_negative<Es>(
-                  pow<detail::abs(Es::num)>(Us::ratio / dimension_unit<typename Es::dimension>::ratio)));
+  return (as_magnitude<1>() * ... *
+          pow<ratio{Es::num, Es::den}>(Us::mag / dimension_unit<typename Es::dimension>::mag));
 }
 
 template<DerivedDimension D, Unit... Us>
-using derived_scaled_unit =
-  scaled_unit<derived_ratio<Us...>(typename D::recipe()), typename D::coherent_unit::reference>;
+using derived_scaled_unit = scaled_unit<derived_mag<Us...>(typename D::recipe()), typename D::coherent_unit::reference>;
 
 }  // namespace units::detail

src/core/include/units/bits/equivalent.h

@@ -72,8 +72,8 @@ struct equivalent_impl<D1, D2> :
 // additionally accounts for unknown dimensions
 template<Unit U1, Dimension D1, Unit U2, Dimension D2>
 struct equivalent_unit :
-    std::disjunction<equivalent_impl<U1, U2>, std::bool_constant<U1::ratio / dimension_unit<D1>::ratio ==
-                                                                 U2::ratio / dimension_unit<D2>::ratio>> {};
+    std::disjunction<equivalent_impl<U1, U2>,
+                     std::bool_constant<U1::mag / dimension_unit<D1>::mag == U2::mag / dimension_unit<D2>::mag>> {};
 
 // point origins
 

src/core/include/units/bits/external/hacks.h

@@ -100,6 +100,16 @@
 
 #endif
 
+#if UNITS_COMP_MSVC
+
+#define UNITS_MSVC_WORKAROUND(X)
+
+#else
+
+#define UNITS_MSVC_WORKAROUND(X) X
+
+#endif
+
 
 namespace std {
 

src/core/include/units/bits/unit_text.h

@@ -147,7 +147,7 @@ constexpr auto unit_text()
     }();
 
     constexpr auto prefix_txt =
-      prefix_or_ratio_text<U, U::ratio / coherent_unit::ratio, symbol_text.standard().size()>();
+      prefix_or_ratio_text<U, as_ratio(U::mag / coherent_unit::mag), symbol_text.standard().size()>();
     return prefix_txt + symbol_text;
   }
 }

src/core/include/units/chrono.h

@@ -33,8 +33,11 @@ namespace units {
 
 template<typename Rep, typename Period>
 struct quantity_like_traits<std::chrono::duration<Rep, Period>> {
+private:
+  static constexpr auto mag = as_magnitude<ratio(Period::num, Period::den)>();
+public:
   using dimension = isq::si::dim_time;
-  using unit = downcast_unit<dimension, ratio(Period::num, Period::den)>;
+  using unit = downcast_unit<dimension, mag>;
   using rep = Rep;
   [[nodiscard]] static constexpr rep number(const std::chrono::duration<Rep, Period>& q) { return q.count(); }
 };
@@ -44,8 +47,11 @@ struct clock_origin : point_origin<isq::si::dim_time> {};
 
 template<typename C, typename Rep, typename Period>
 struct quantity_point_like_traits<std::chrono::time_point<C, std::chrono::duration<Rep, Period>>> {
+private:
+  static constexpr auto mag = as_magnitude<ratio(Period::num, Period::den)>();
+public:
   using origin = clock_origin<C>;
-  using unit = downcast_unit<typename origin::dimension, ratio(Period::num, Period::den)>;
+  using unit = downcast_unit<typename origin::dimension, mag>;
   using rep = Rep;
   [[nodiscard]] static constexpr auto relative(const std::chrono::time_point<C, std::chrono::duration<Rep, Period>>& qp)
   {
@@ -86,13 +92,13 @@ using to_std_ratio = decltype(detail::to_std_ratio_impl<R>());
 template<typename U, typename Rep>
 [[nodiscard]] constexpr auto to_std_duration(const quantity<isq::si::dim_time, U, Rep>& q)
 {
-  return std::chrono::duration<Rep, to_std_ratio<U::ratio>>(q.number());
+  return std::chrono::duration<Rep, to_std_ratio<as_ratio(U::mag)>>(q.number());
 }
 
 template<typename C, typename U, typename Rep>
 [[nodiscard]] constexpr auto to_std_time_point(const quantity_point<clock_origin<C>, U, Rep>& qp)
 {
-  using ret_type = std::chrono::time_point<C, std::chrono::duration<Rep, to_std_ratio<U::ratio>>>;
+  using ret_type = std::chrono::time_point<C, std::chrono::duration<Rep, to_std_ratio<as_ratio(U::mag)>>>;
   return ret_type(to_std_duration(qp.relative()));
 }
 

src/core/include/units/derived_dimension.h

@@ -85,7 +85,8 @@ template<typename Child, Unit U, Exponent... Es>
 struct derived_dimension : downcast_dispatch<Child, typename detail::make_dimension<Es...>> {
   using recipe = exponent_list<Es...>;
   using coherent_unit = U;
-  static constexpr ratio base_units_ratio = detail::base_units_ratio(typename derived_dimension::exponents());
+  static constexpr UNITS_MSVC_WORKAROUND(Magnitude) auto base_units_ratio =
+    detail::absolute_magnitude(typename derived_dimension::exponents());
 };
 
 }  // namespace units

src/core/include/units/generic/dimensionless.h

@@ -31,7 +31,7 @@
 namespace units {
 
 struct one : derived_unit<one> {};
-struct percent : named_scaled_unit<percent, "%", ratio(1, 100), one> {};
+struct percent : named_scaled_unit<percent, "%", as_magnitude<ratio(1, 100)>(), one> {};
 
 /**
  * @brief Dimension one

src/core/include/units/magnitude.h

@@ -137,13 +137,14 @@ constexpr auto inverse(BasePower auto bp)
 
 // `widen_t` gives the widest arithmetic type in the same category, for intermediate computations.
 template<typename T>
-  requires std::is_arithmetic_v<T>
-using widen_t = std::conditional_t<std::is_floating_point_v<T>, long double,
-                                   std::conditional_t<std::is_signed_v<T>, std::intmax_t, std::uintmax_t>>;
+using widen_t =
+  std::conditional_t<std::is_arithmetic_v<T>,
+                     std::conditional_t<std::is_floating_point_v<T>, long double,
+                                        std::conditional_t<std::is_signed_v<T>, std::intmax_t, std::uintmax_t>>,
+                     T>;
 
 // Raise an arbitrary arithmetic type to a positive integer power at compile time.
 template<typename T>
-  requires std::is_arithmetic_v<T>
 constexpr T int_power(T base, std::integral auto exp)
 {
   // As this function should only be called at compile time, the exceptions herein function as
@@ -166,7 +167,7 @@ constexpr T int_power(T base, std::integral auto exp)
   // template parameter, rather than a function parameter.
 
   if (exp == 0) {
-    return 1;
+    return T{1};
   }
 
   if (exp % 2 == 1) {
@@ -178,7 +179,6 @@ constexpr T int_power(T base, std::integral auto exp)
 
 
 template<typename T>
-  requires std::is_arithmetic_v<T>
 constexpr widen_t<T> compute_base_power(BasePower auto bp)
 {
   // This utility can only handle integer powers.  To compute rational powers at compile time, we'll
@@ -197,11 +197,11 @@ constexpr widen_t<T> compute_base_power(BasePower auto bp)
     if constexpr (std::is_integral_v<T>) {
       throw std::invalid_argument{"Cannot represent reciprocal as integer"};
     } else {
-      return 1 / compute_base_power<T>(inverse(bp));
+      return T{1} / compute_base_power<T>(inverse(bp));
     }
   }
 
-  auto power = bp.power.num * int_power(10, bp.power.exp);
+  auto power = numerator(bp.power);
   return int_power(static_cast<widen_t<T>>(bp.get_base()), power);
 }
 
@@ -210,8 +210,8 @@ constexpr widen_t<T> compute_base_power(BasePower auto bp)
 // The input is the desired result, but in a (wider) intermediate type.  The point of this function
 // is to cast to the desired type, but avoid overflow in doing so.
 template<typename To, typename From>
-  requires std::is_arithmetic_v<To> && std::is_arithmetic_v<From> &&
-           (std::is_integral_v<To> == std::is_integral_v<From>)
+// TODO(chogg): Migrate this to use `treat_as_floating_point`.
+  requires(!std::is_integral_v<To> || std::is_integral_v<From>)
 constexpr To checked_static_cast(From x)
 {
   // This function should only ever be called at compile time.  The purpose of these exceptions is
@@ -220,10 +220,6 @@ constexpr To checked_static_cast(From x)
     if (!std::in_range<To>(x)) {
       throw std::invalid_argument{"Cannot represent magnitude in this type"};
     }
-  } else {
-    if (x < std::numeric_limits<To>::min() || x > std::numeric_limits<To>::max()) {
-      throw std::invalid_argument{"Cannot represent magnitude in this type"};
-    }
   }
 
   return static_cast<To>(x);
@@ -374,7 +370,7 @@ struct magnitude {
 namespace detail {
 template<typename T>
 inline constexpr bool is_magnitude = false;
-template<BasePower auto... BPs>
+template<auto... BPs>
 inline constexpr bool is_magnitude<magnitude<BPs...>> = true;
 }  // namespace detail
 
@@ -387,8 +383,9 @@ concept Magnitude = detail::is_magnitude<T>;
 /**
  * @brief  The value of a Magnitude in a desired type T.
  */
-template<typename T, BasePower auto... BPs>
-  requires std::is_floating_point_v<T> || (std::is_integral_v<T> && is_integral(magnitude<BPs...>{}))
+template<typename T, auto... BPs>
+// TODO(chogg): Migrate this to use `treat_as_floating_point`.
+  requires(!std::is_integral_v<T> || is_integral(magnitude<BPs...>{}))
 constexpr T get_value(const magnitude<BPs...>&)
 {
   // Force the expression to be evaluated in a constexpr context, to catch, e.g., overflow.
@@ -407,7 +404,7 @@ struct pi_base {
 ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
 // Magnitude equality implementation.
 
-template<BasePower auto... LeftBPs, BasePower auto... RightBPs>
+template<auto... LeftBPs, auto... RightBPs>
 constexpr bool operator==(magnitude<LeftBPs...>, magnitude<RightBPs...>)
 {
   if constexpr (sizeof...(LeftBPs) == sizeof...(RightBPs)) {
@@ -420,27 +417,39 @@ constexpr bool operator==(magnitude<LeftBPs...>, magnitude<RightBPs...>)
 ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
 // Magnitude rational powers implementation.
 
-template<ratio E, BasePower auto... BPs>
+template<ratio E, auto... BPs>
 constexpr auto pow(magnitude<BPs...>)
 {
-  if constexpr (E == 0) {
+  if constexpr (E.num == 0) {
     return magnitude<>{};
   } else {
     return magnitude<pow(BPs, E)...>{};
   }
 }
 
+template<auto... BPs>
+constexpr auto sqrt(magnitude<BPs...> m)
+{
+  return pow<ratio{1, 2}>(m);
+}
+
+template<auto... BPs>
+constexpr auto cbrt(magnitude<BPs...> m)
+{
+  return pow<ratio{1, 3}>(m);
+}
+
 ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
 // Magnitude product implementation.
 
 // Base cases, for when either (or both) inputs are the identity.
-constexpr auto operator*(magnitude<>, magnitude<>) { return magnitude<>{}; }
-constexpr auto operator*(magnitude<>, Magnitude auto m) { return m; }
-constexpr auto operator*(Magnitude auto m, magnitude<>) { return m; }
+constexpr Magnitude auto operator*(magnitude<>, magnitude<>) { return magnitude<>{}; }
+constexpr Magnitude auto operator*(magnitude<>, Magnitude auto m) { return m; }
+constexpr Magnitude auto operator*(Magnitude auto m, magnitude<>) { return m; }
 
 // Recursive case for the product of any two non-identity Magnitudes.
-template<BasePower auto H1, BasePower auto... T1, BasePower auto H2, BasePower auto... T2>
-constexpr auto operator*(magnitude<H1, T1...>, magnitude<H2, T2...>)
+template<auto H1, auto... T1, auto H2, auto... T2>
+constexpr Magnitude auto operator*(magnitude<H1, T1...>, magnitude<H2, T2...>)
 {
   // Case for when H1 has the smaller base.
   if constexpr (H1.get_base() < H2.get_base()) {
@@ -486,7 +495,7 @@ constexpr auto operator/(Magnitude auto l, Magnitude auto r) { return l * pow<-1
 namespace detail {
 
 // The largest integer which can be extracted from any magnitude with only a single basis vector.
-template<BasePower auto BP>
+template<auto BP>
 constexpr auto integer_part(magnitude<BP>)
 {
   constexpr auto power_num = numerator(BP.power);
@@ -506,7 +515,7 @@ constexpr auto integer_part(magnitude<BP>)
 
 }  // namespace detail
 
-template<BasePower auto... BPs>
+template<auto... BPs>
 constexpr auto numerator(magnitude<BPs...>)
 {
   return (detail::integer_part(magnitude<BPs>{}) * ... * magnitude<>{});
@@ -525,6 +534,70 @@ constexpr ratio as_ratio(Magnitude auto m)
 }
 
 
+////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
+// Common Magnitude.
+//
+// The "common Magnitude" C, of two Magnitudes M1 and M2, is the largest Magnitude such that each of its inputs is
+// expressible by only positive basis powers relative to C.  That is, both (M1 / C) and (M2 / C) contain only positive
+// powers in the expansion on our basis.
+//
+// For rational Magnitudes (or, more precisely, Magnitudes that are rational _relative to each other_), this reduces to
+// the familiar convention from the std::chrono library: it is the largest Magnitude C such that each input Magnitude is
+// an _integer multiple_ of C.  The connection can be seen by considering the definition in the above paragraph, and
+// recognizing that both the bases and the powers are all integers for rational Magnitudes.
+//
+// For relatively _irrational_ Magnitudes (whether from irrational bases, or fractional powers of integer bases), the
+// notion of a "common type" becomes less important, because there is no way to preserve pure integer multiplication.
+// When we go to retrieve our value, we'll be stuck with a floating point approximation no matter what choice we make.
+// Thus, we make the _simplest_ choice which reproduces the correct convention in the rational case: namely, taking the
+// minimum power for each base (where absent bases implicitly have a power of 0).
+
+namespace detail {
+template<auto BP>
+constexpr auto remove_positive_power(magnitude<BP> m)
+{
+  if constexpr (numerator(BP.power) < 0) {
+    return m;
+  } else {
+    return magnitude<>{};
+  }
+}
+
+template<auto... BPs>
+constexpr auto remove_positive_powers(magnitude<BPs...>)
+{
+  return (magnitude<>{} * ... * remove_positive_power(magnitude<BPs>{}));
+}
+}  // namespace detail
+
+// Base cases, for when either (or both) inputs are the identity.
+constexpr auto common_magnitude(magnitude<>, magnitude<>) { return magnitude<>{}; }
+constexpr auto common_magnitude(magnitude<>, Magnitude auto m) { return detail::remove_positive_powers(m); }
+constexpr auto common_magnitude(Magnitude auto m, magnitude<>) { return detail::remove_positive_powers(m); }
+
+// Recursive case for the common Magnitude of any two non-identity Magnitudes.
+template<auto H1, auto... T1, auto H2, auto... T2>
+constexpr auto common_magnitude(magnitude<H1, T1...>, magnitude<H2, T2...>)
+{
+  using detail::remove_positive_power;
+
+  if constexpr (H1.get_base() < H2.get_base()) {
+    // When H1 has the smaller base, prepend to result from recursion.
+    return remove_positive_power(magnitude<H1>{}) * common_magnitude(magnitude<T1...>{}, magnitude<H2, T2...>{});
+  } else if constexpr (H2.get_base() < H1.get_base()) {
+    // When H2 has the smaller base, prepend to result from recursion.
+    return remove_positive_power(magnitude<H2>{}) * common_magnitude(magnitude<H1, T1...>{}, magnitude<T2...>{});
+  } else {
+    // When the bases are equal, pick whichever has the lower power.
+    constexpr auto common_tail = common_magnitude(magnitude<T1...>{}, magnitude<T2...>{});
+    if constexpr (H1.power < H2.power) {
+      return magnitude<H1>{} * common_tail;
+    } else {
+      return magnitude<H2>{} * common_tail;
+    }
+  }
+}
+
 ////////////////////////////////////////////////////////////////////////////////////////////////////////////////////////
 // `as_magnitude()` implementation.
 
@@ -579,7 +652,7 @@ template<ratio R>
   requires(R.num > 0)
 constexpr Magnitude auto as_magnitude()
 {
-  return pow<R.exp>(detail::prime_factorization_v<10>) * detail::prime_factorization_v<R.num> /
+  return pow<ratio{R.exp}>(detail::prime_factorization_v<10>) * detail::prime_factorization_v<R.num> /
          detail::prime_factorization_v<R.den>;
 }
 

src/core/include/units/math.h

@@ -57,7 +57,7 @@ template<std::intmax_t Num, std::intmax_t Den = 1, Quantity Q>
     return rep(1);
   } else {
     using dim = dimension_pow<typename Q::dimension, Num, Den>;
-    using unit = downcast_unit<dim, pow<Num, Den>(Q::unit::ratio)>;
+    using unit = downcast_unit<dim, pow<ratio{Num, Den}>(Q::unit::mag)>;
     using std::pow;
     return quantity<dim, unit, rep>(
       static_cast<rep>(pow(q.number(), static_cast<double>(Num) / static_cast<double>(Den))));
@@ -77,7 +77,7 @@ template<Quantity Q>
   requires requires { sqrt(q.number()); } || requires { std::sqrt(q.number()); }
 {
   using dim = dimension_pow<typename Q::dimension, 1, 2>;
-  using unit = downcast_unit<dim, sqrt(Q::unit::ratio)>;
+  using unit = downcast_unit<dim, pow<ratio{1, 2}>(Q::unit::mag)>;
   using rep = TYPENAME Q::rep;
   using std::sqrt;
   return quantity<dim, unit, rep>(static_cast<rep>(sqrt(q.number())));
@@ -96,7 +96,7 @@ template<Quantity Q>
   requires requires { cbrt(q.number()); } || requires { std::cbrt(q.number()); }
 {
   using dim = dimension_pow<typename Q::dimension, 1, 3>;
-  using unit = downcast_unit<dim, cbrt(Q::unit::ratio)>;
+  using unit = downcast_unit<dim, pow<ratio{1, 3}>(Q::unit::mag)>;
   using rep = TYPENAME Q::rep;
   using std::cbrt;
   return quantity<dim, unit, rep>(static_cast<rep>(cbrt(q.number())));

src/core/include/units/prefix.h

@@ -25,6 +25,7 @@
 #include <units/bits/basic_concepts.h>
 #include <units/bits/external/downcasting.h>
 // IWYU pragma: begin_exports
+#include <units/magnitude.h>
 #include <units/ratio.h>
 #include <units/symbol_text.h>
 // IWYU pragma: end_exports
@@ -35,7 +36,7 @@ namespace detail {
 
 template<ratio R>
 struct prefix_base : downcast_base<prefix_base<R>> {
-  static constexpr ::units::ratio ratio = R;
+  static constexpr UNITS_MSVC_WORKAROUND(Magnitude) auto mag = as_magnitude<R>();
 };
 
 }  // namespace detail

src/core/include/units/quantity.h

@@ -407,7 +407,7 @@ public:
   {
     gsl_ExpectsAudit(q.number() != quantity_values<rep>::zero());
     using dim = dim_invert<D>;
-    using ret_unit = downcast_unit<dim, inverse(U::ratio)>;
+    using ret_unit = downcast_unit<dim, pow<-1>(U::mag)>;
     using ret = quantity<dim, ret_unit, std::invoke_result_t<std::divides<>, Value, rep>>;
     return ret(v / q.number());
   }

src/core/include/units/quantity_cast.h

@@ -27,6 +27,7 @@
 #include <units/bits/pow.h>
 #include <units/concepts.h>
 #include <units/customization_points.h>
+#include <units/magnitude.h>
 
 UNITS_DIAGNOSTIC_PUSH
 // warning C4244: 'argument': conversion from 'intmax_t' to 'T', possible loss of data with T=int
@@ -49,25 +50,28 @@ class quantity_point_kind;
 namespace detail {
 
 template<typename T>
-inline constexpr ratio quantity_ratio = std::enable_if_t<!Quantity<T>>{};
+inline constexpr Magnitude auto quantity_magnitude = std::enable_if_t<!Quantity<T>, magnitude<>>{};
 
 template<typename D, typename U, typename Rep>
-inline constexpr ratio quantity_ratio<quantity<D, U, Rep>> = [] {
+inline constexpr Magnitude auto quantity_magnitude<quantity<D, U, Rep>> = [] {
   if constexpr (BaseDimension<D>) {
-    return U::ratio;
+    return U::mag;
   } else {
-    return D::base_units_ratio * U::ratio / D::coherent_unit::ratio;
+    return D::base_units_ratio * U::mag / D::coherent_unit::mag;
   }
 }();
 
+template<Quantity Q>
+inline constexpr ratio quantity_ratio = as_ratio(quantity_magnitude<Q>);
+
 template<typename QFrom, typename QTo>
-inline constexpr ratio cast_ratio = [] {
+inline constexpr Magnitude auto cast_magnitude = [] {
   using FromU = TYPENAME QFrom::unit;
   using ToU = TYPENAME QTo::unit;
   if constexpr (same_unit_reference<FromU, ToU>::value) {
-    return FromU::ratio / ToU::ratio;
+    return FromU::mag / ToU::mag;
   } else {
-    return quantity_ratio<QFrom> / quantity_ratio<QTo>;
+    return quantity_magnitude<QFrom> / quantity_magnitude<QTo>;
   }
 }();
 
@@ -112,25 +116,14 @@ template<Quantity To, typename D, typename U, scalable_with_<typename To::rep> R
   using traits = detail::cast_traits<Rep, typename To::rep>;
   using ratio_type = TYPENAME traits::ratio_type;
   using rep_type = TYPENAME traits::rep_type;
-  constexpr auto c_ratio = detail::cast_ratio<quantity<D, U, Rep>, To>;
 
-  if constexpr (treat_as_floating_point<rep_type>) {
-    return To(
-      static_cast<TYPENAME To::rep>(static_cast<rep_type>(q.number()) *
-                                    (static_cast<ratio_type>(c_ratio.num) * detail::fpow10<ratio_type>(c_ratio.exp) /
-                                     static_cast<ratio_type>(c_ratio.den))));
-  } else {
-    if constexpr (c_ratio.exp > 0) {
-      return To(static_cast<TYPENAME To::rep>(
-        static_cast<rep_type>(q.number()) *
-        (static_cast<ratio_type>(c_ratio.num) * static_cast<ratio_type>(detail::ipow10(c_ratio.exp))) /
-        static_cast<ratio_type>(c_ratio.den)));
-    } else {
-      return To(static_cast<TYPENAME To::rep>(
-        static_cast<rep_type>(q.number()) * static_cast<ratio_type>(c_ratio.num) /
-        (static_cast<ratio_type>(c_ratio.den) * static_cast<ratio_type>(detail::ipow10(-c_ratio.exp)))));
-    }
-  }
+  constexpr Magnitude auto c_mag = detail::cast_magnitude<quantity<D, U, Rep>, To>;
+  constexpr Magnitude auto num = numerator(c_mag);
+  constexpr Magnitude auto den = denominator(c_mag);
+  constexpr Magnitude auto irr = c_mag * (den / num);
+
+  constexpr auto val = [](Magnitude auto m) { return get_value<ratio_type>(m); };
+  return To(static_cast<TYPENAME To::rep>(static_cast<rep_type>(q.number()) * val(num) / val(den) * val(irr)));
 }
 
 /**
@@ -149,7 +142,7 @@ template<Dimension ToD, typename D, typename U, typename Rep>
   requires equivalent<ToD, D>
 [[nodiscard]] constexpr auto quantity_cast(const quantity<D, U, Rep>& q)
 {
-  return quantity_cast<quantity<ToD, downcast_unit<ToD, U::ratio>, Rep>>(q);
+  return quantity_cast<quantity<ToD, downcast_unit<ToD, U::mag>, Rep>>(q);
 }
 
 /**

src/core/include/units/ratio.h

@@ -32,6 +32,7 @@
 
 #include <gsl/gsl-lite.hpp>
 #include <array>
+#include <compare>
 #include <numeric>
 
 namespace units {
@@ -60,6 +61,8 @@ struct ratio {
 
   [[nodiscard]] friend constexpr bool operator==(const ratio&, const ratio&) = default;
 
+  [[nodiscard]] friend constexpr auto operator<=>(const ratio& lhs, const ratio& rhs) { return (lhs - rhs).num <=> 0; }
+
   [[nodiscard]] friend constexpr ratio operator-(const ratio& r) { return ratio(-r.num, r.den, r.exp); }
 
   [[nodiscard]] friend constexpr ratio operator+(ratio lhs, ratio rhs)
@@ -78,6 +81,8 @@ struct ratio {
     return ratio{lhs.num * rhs.den + lhs.den * rhs.num, lhs.den * rhs.den, common_exp};
   }
 
+  [[nodiscard]] friend constexpr ratio operator-(const ratio& lhs, const ratio& rhs) { return lhs + (-rhs); }
+
   [[nodiscard]] friend constexpr ratio operator*(const ratio& lhs, const ratio& rhs)
   {
     const std::intmax_t gcd1 = std::gcd(lhs.num, rhs.den);

src/core/include/units/reference.h

@@ -37,13 +37,13 @@ namespace detail {
 
 template<typename D, typename D1, typename U1, typename D2, typename U2>
 using reference_multiply_impl =
-  reference<D, downcast_unit<D, (U1::ratio / dimension_unit<D1>::ratio) * (U2::ratio / dimension_unit<D2>::ratio) *
-                                  dimension_unit<D>::ratio>>;
+  reference<D, downcast_unit<D, (U1::mag / dimension_unit<D1>::mag) * (U2::mag / dimension_unit<D2>::mag) *
+                                  dimension_unit<D>::mag>>;
 
 template<typename D, typename D1, typename U1, typename D2, typename U2>
 using reference_divide_impl =
-  reference<D, downcast_unit<D, (U1::ratio / dimension_unit<D1>::ratio) / (U2::ratio / dimension_unit<D2>::ratio) *
-                                  dimension_unit<D>::ratio>>;
+  reference<D, downcast_unit<D, (U1::mag / dimension_unit<D1>::mag) / (U2::mag / dimension_unit<D2>::mag) *
+                                  dimension_unit<D>::mag>>;
 
 }  // namespace detail
 

src/core/include/units/unit.h

@@ -28,6 +28,7 @@
 // IWYU pragma: begin_exports
 #include <units/bits/derived_scaled_unit.h>
 #include <units/bits/external/fixed_string.h>
+#include <units/magnitude.h>
 #include <units/prefix.h>
 #include <units/ratio.h>
 #include <units/symbol_text.h>
@@ -54,20 +55,17 @@ inline constexpr bool can_be_prefixed = false;
  * (i.e. all length units are expressed in terms of meter, all mass units are expressed in
  * terms of gram, ...)
  *
- * @tparam R a ratio of a reference unit
+ * @tparam M a Magnitude representing the (relative) size of this unit
  * @tparam U a unit to use as a reference for this dimension
  */
-template<ratio R, typename U>
-  requires UnitRatio<R>
-struct scaled_unit : downcast_base<scaled_unit<R, U>> {
-  static constexpr ::units::ratio ratio = R;
+template<Magnitude auto M, typename U>
+struct scaled_unit : downcast_base<scaled_unit<M, U>> {
+  static constexpr UNITS_MSVC_WORKAROUND(Magnitude) auto mag = M;
   using reference = U;
 };
 
-template<Dimension D, auto R>
-// template<Dimension D, ratio R>  // TODO: GCC crash!!!
-  requires UnitRatio<R>
-using downcast_unit = downcast<scaled_unit<R, typename dimension_unit<D>::reference>>;
+template<Dimension D, Magnitude auto M>
+using downcast_unit = downcast<scaled_unit<M, typename dimension_unit<D>::reference>>;
 
 template<Unit U1, Unit U2>
 struct same_unit_reference : is_same<typename U1::reference, typename U2::reference> {};
@@ -82,7 +80,7 @@ struct same_unit_reference : is_same<typename U1::reference, typename U2::refere
  * @tparam Symbol a short text representation of the unit
  */
 template<typename Child, basic_symbol_text Symbol>
-struct named_unit : downcast_dispatch<Child, scaled_unit<ratio(1), Child>> {
+struct named_unit : downcast_dispatch<Child, scaled_unit<as_magnitude<1>(), Child>> {
   static constexpr auto symbol = Symbol;
 };
 
@@ -94,12 +92,11 @@ struct named_unit : downcast_dispatch<Child, scaled_unit<ratio(1), Child>> {
  *
  * @tparam Child inherited class type used by the downcasting facility (CRTP Idiom)
  * @tparam Symbol a short text representation of the unit
- * @tparam R a scale to apply to U
+ * @tparam M the Magnitude by which to scale U
  * @tparam U a reference unit to scale
  */
-template<typename Child, basic_symbol_text Symbol, ratio R, Unit U>
-  requires UnitRatio<R>
-struct named_scaled_unit : downcast_dispatch<Child, scaled_unit<R * U::ratio, typename U::reference>> {
+template<typename Child, basic_symbol_text Symbol, Magnitude auto M, Unit U>
+struct named_scaled_unit : downcast_dispatch<Child, scaled_unit<M * U::mag, typename U::reference>> {
   static constexpr auto symbol = Symbol;
 };
 
@@ -116,7 +113,7 @@ struct named_scaled_unit : downcast_dispatch<Child, scaled_unit<R * U::ratio, ty
  */
 template<typename Child, Prefix P, NamedUnit U>
   requires detail::can_be_prefixed<U>
-struct prefixed_unit : downcast_dispatch<Child, scaled_unit<P::ratio * U::ratio, typename U::reference>> {
+struct prefixed_unit : downcast_dispatch<Child, scaled_unit<P::mag * U::mag, typename U::reference>> {
   static constexpr auto symbol = P::symbol + U::symbol;
 };
 
@@ -129,7 +126,7 @@ struct prefixed_unit : downcast_dispatch<Child, scaled_unit<P::ratio * U::ratio,
  * @tparam Child inherited class type used by the downcasting facility (CRTP Idiom)
  */
 template<typename Child>
-struct derived_unit : downcast_dispatch<Child, scaled_unit<ratio(1), Child>> {};
+struct derived_unit : downcast_dispatch<Child, scaled_unit<as_magnitude<1>(), Child>> {};
 
 /**
  * @brief A unit with a deduced ratio and symbol
@@ -198,8 +195,8 @@ namespace detail {
 template<typename Child, basic_symbol_text Symbol>
 void is_named_impl(const volatile named_unit<Child, Symbol>*);
 
-template<typename Child, basic_symbol_text Symbol, ratio R, typename U>
-void is_named_impl(const volatile named_scaled_unit<Child, Symbol, R, U>*);
+template<typename Child, basic_symbol_text Symbol, Magnitude auto M, typename U>
+void is_named_impl(const volatile named_scaled_unit<Child, Symbol, M, U>*);
 
 template<typename Child, typename P, typename U>
 void is_named_impl(const volatile prefixed_unit<Child, P, U>*);
@@ -216,8 +213,8 @@ inline constexpr bool is_named<U> = requires(U * u) { is_named_impl(u); };
 template<typename Child, basic_symbol_text Symbol>
 void can_be_prefixed_impl(const volatile named_unit<Child, Symbol>*);
 
-template<typename Child, basic_symbol_text Symbol, ratio R, typename U>
-void can_be_prefixed_impl(const volatile named_scaled_unit<Child, Symbol, R, U>*);
+template<typename Child, basic_symbol_text Symbol, Magnitude auto M, typename U>
+void can_be_prefixed_impl(const volatile named_scaled_unit<Child, Symbol, M, U>*);
 
 template<typename U, basic_symbol_text Symbol>
 void can_be_prefixed_impl(const volatile alias_unit<U, Symbol>*);
@@ -225,8 +222,8 @@ void can_be_prefixed_impl(const volatile alias_unit<U, Symbol>*);
 template<Unit U>
 inline constexpr bool can_be_prefixed<U> = requires(U * u) { can_be_prefixed_impl(u); };
 
-template<ratio R, typename U>
-inline constexpr bool can_be_prefixed<scaled_unit<R, U>> = can_be_prefixed<typename U::reference>;
+template<Magnitude auto M, typename U>
+inline constexpr bool can_be_prefixed<scaled_unit<M, U>> = can_be_prefixed<typename U::reference>;
 
 }  // namespace detail
 

src/systems/isq-iec80000/include/units/isq/iec80000/storage_capacity.h

@@ -53,7 +53,7 @@ struct tebibit : prefixed_unit<tebibit, tebi, bit> {};
 struct pebibit : prefixed_unit<pebibit, pebi, bit> {};
 struct exbibit : prefixed_unit<exbibit, exbi, bit> {};
 
-struct byte : named_scaled_unit<byte, "B", ratio(8), bit> {};
+struct byte : named_scaled_unit<byte, "B", as_magnitude<8>(), bit> {};
 
 struct kilobyte : prefixed_unit<kilobyte, si::kilo, byte> {};
 struct megabyte : prefixed_unit<megabyte, si::mega, byte> {};

src/systems/si-fps/include/units/isq/si/fps/force.h

@@ -40,7 +40,7 @@ namespace units::isq::si::fps {
 struct poundal : named_unit<poundal, "pdl"> {};
 
 // https://en.wikipedia.org/wiki/Pound_(force)
-struct pound_force : named_scaled_unit<pound_force, "lbf", ratio(32'174'049, 1'000'000), poundal> {};
+struct pound_force : named_scaled_unit<pound_force, "lbf", as_magnitude<ratio(32'174'049, 1'000'000)>(), poundal> {};
 
 struct kilopound_force : prefixed_unit<kilopound_force, si::kilo, pound_force> {};
 

src/systems/si-fps/include/units/isq/si/fps/length.h

@@ -39,6 +39,7 @@ using si::international::fathom;
 using si::international::foot;
 using si::international::inch;
 using si::international::mil;
+using si::international::mile;
 using si::international::thou;
 using si::international::yard;
 
@@ -47,9 +48,7 @@ struct thousandth : alias_unit<thou, "thou"> {};
 
 struct kiloyard : prefixed_unit<kiloyard, si::kilo, yard> {};
 
-struct mile : named_scaled_unit<mile, "mile", ratio(5'280), foot> {};
-
-struct nautical_mile : named_scaled_unit<nautical_mile, "nmi", ratio(2'000), yard> {};
+struct nautical_mile : named_scaled_unit<nautical_mile, "nmi", as_magnitude<2'000>(), yard> {};
 
 struct dim_length : isq::dim_length<foot> {};
 

src/systems/si-fps/include/units/isq/si/fps/mass.h

@@ -35,28 +35,28 @@
 namespace units::isq::si::fps {
 
 // https://en.wikipedia.org/wiki/Pound_(mass)
-struct pound : named_scaled_unit<pound, "lb", ratio(45'359'237, 100'000'000), si::kilogram> {};
+struct pound : named_scaled_unit<pound, "lb", as_magnitude<ratio(45'359'237, 100'000'000)>(), si::kilogram> {};
 
 struct dim_mass : isq::dim_mass<pound> {};
 
 template<UnitOf<dim_mass> U, Representation Rep = double>
 using mass = quantity<dim_mass, U, Rep>;
 
-struct grain : named_scaled_unit<grain, "gr", ratio(1, 7000), pound> {};
+struct grain : named_scaled_unit<grain, "gr", as_magnitude<ratio(1, 7000)>(), pound> {};
 
-struct dram : named_scaled_unit<dram, "dr", ratio(1, 256), pound> {};
+struct dram : named_scaled_unit<dram, "dr", as_magnitude<ratio(1, 256)>(), pound> {};
 
-struct ounce : named_scaled_unit<ounce, "oz", ratio(1, 16), pound> {};
+struct ounce : named_scaled_unit<ounce, "oz", as_magnitude<ratio(1, 16)>(), pound> {};
 
-struct stone : named_scaled_unit<stone, "st", ratio(14, 1), pound> {};
+struct stone : named_scaled_unit<stone, "st", as_magnitude<14>(), pound> {};
 
-struct quarter : named_scaled_unit<quarter, "qr", ratio(28, 1), pound> {};
+struct quarter : named_scaled_unit<quarter, "qr", as_magnitude<28>(), pound> {};
 
-struct hundredweight : named_scaled_unit<hundredweight, "cwt", ratio(112, 1), pound> {};
+struct hundredweight : named_scaled_unit<hundredweight, "cwt", as_magnitude<112>(), pound> {};
 
-struct short_ton : named_scaled_unit<short_ton, "ton (short)", ratio(2'000, 1), pound> {};
+struct short_ton : named_scaled_unit<short_ton, "ton (short)", as_magnitude<2'000>(), pound> {};
 
-struct long_ton : named_scaled_unit<long_ton, "ton (long)", ratio(2'240, 1), pound> {};
+struct long_ton : named_scaled_unit<long_ton, "ton (long)", as_magnitude<2'240>(), pound> {};
 
 #ifndef UNITS_NO_LITERALS
 

src/systems/si-fps/include/units/isq/si/fps/power.h

@@ -42,7 +42,7 @@ struct dim_power : isq::dim_power<dim_power, foot_poundal_per_second, dim_length
 struct foot_pound_force_per_second :
     derived_scaled_unit<foot_pound_force_per_second, dim_power, foot, pound_force, second> {};
 
-struct horse_power : named_scaled_unit<horse_power, "hp", ratio(550), foot_pound_force_per_second> {};
+struct horse_power : named_scaled_unit<horse_power, "hp", as_magnitude<550>(), foot_pound_force_per_second> {};
 
 template<UnitOf<dim_power> U, Representation Rep = double>
 using power = quantity<dim_power, U, Rep>;

src/systems/si-fps/include/units/isq/si/fps/pressure.h

@@ -44,10 +44,11 @@ template<UnitOf<dim_pressure> U, Representation Rep = double>
 using pressure = quantity<dim_pressure, U, Rep>;
 
 struct pound_force_per_foot_sq :
-    named_scaled_unit<pound_force_per_foot_sq, "lbf ft2", ratio(32'174'049, 1'000'000), poundal_per_foot_sq> {};
+    named_scaled_unit<pound_force_per_foot_sq, "lbf ft2", as_magnitude<ratio(32'174'049, 1'000'000)>(),
+                      poundal_per_foot_sq> {};
 
 struct pound_force_per_inch_sq :
-    named_scaled_unit<pound_force_per_inch_sq, "psi", ratio(1, 144), pound_force_per_foot_sq> {};
+    named_scaled_unit<pound_force_per_inch_sq, "psi", as_magnitude<ratio(1, 144)>(), pound_force_per_foot_sq> {};
 
 struct kilopound_force_per_inch_sq : prefixed_unit<kilopound_force_per_inch_sq, si::kilo, pound_force_per_inch_sq> {};
 

src/systems/si-hep/include/units/isq/si/hep/area.h

@@ -37,7 +37,7 @@ namespace units::isq::si::hep {
 // effective cross-sectional area according to EU council directive 80/181/EEC
 // https://eur-lex.europa.eu/legal-content/EN/TXT/PDF/?uri=CELEX:01980L0181-20090527#page=10
 // https://www.fedlex.admin.ch/eli/cc/1994/3109_3109_3109/de
-struct barn : named_scaled_unit<barn, "b", ratio(1, 1, -28), square_metre> {};
+struct barn : named_scaled_unit<barn, "b", as_magnitude<ratio(1, 1, -28)>(), square_metre> {};
 struct yocto_barn : prefixed_unit<yocto_barn, yocto, barn> {};
 struct zepto_barn : prefixed_unit<zepto_barn, zepto, barn> {};
 struct atto_barn : prefixed_unit<atto_barn, atto, barn> {};

src/systems/si-hep/include/units/isq/si/hep/mass.h

@@ -32,11 +32,19 @@
 #include <units/isq/si/mass.h>
 #include <units/unit.h>
 
+// Necessary to factor `1'672'621'923'695`, which appears in the proton mass.
+template<>
+inline constexpr std::optional<std::intmax_t> units::known_first_factor<334'524'384'739> = 334'524'384'739;
+
+// Necessary to factor `17'826'619'216'279`, which appears in the value for eV/c^2.
+template<>
+inline constexpr std::optional<std::intmax_t> units::known_first_factor<225'653'407'801> = 225'653'407'801;
+
 namespace units::isq::si::hep {
 
 struct eV_per_c2 :
     named_scaled_unit<eV_per_c2, basic_symbol_text{"eV/c²", "eV/c^2"},
-                      ratio(1'7826'619'216'279, 1'000'000'000'000, -35), kilogram> {};
+                      as_magnitude<ratio(17'826'619'216'279, 1'000'000'000'000, -35)>(), kilogram> {};
 struct feV_per_c2 : prefixed_unit<feV_per_c2, femto, eV_per_c2> {};
 struct peV_per_c2 : prefixed_unit<peV_per_c2, pico, eV_per_c2> {};
 struct neV_per_c2 : prefixed_unit<neV_per_c2, nano, eV_per_c2> {};
@@ -52,10 +60,11 @@ struct PeV_per_c2 : prefixed_unit<PeV_per_c2, peta, eV_per_c2> {};
 struct EeV_per_c2 : prefixed_unit<EeV_per_c2, exa, eV_per_c2> {};
 struct YeV_per_c2 : prefixed_unit<YeV_per_c2, yotta, eV_per_c2> {};
 struct electron_mass :
-    named_scaled_unit<eV_per_c2, "m_e", ratio(9'109'383'701'528, 1'000'000'000'000, -31), kilogram> {};
-struct proton_mass : named_scaled_unit<eV_per_c2, "m_p", ratio(1'672'621'923'695, 1'000'000'000'000, -27), kilogram> {};
+    named_scaled_unit<eV_per_c2, "m_e", as_magnitude<ratio(9'109'383'701'528, 1'000'000'000'000, -31)>(), kilogram> {};
+struct proton_mass :
+    named_scaled_unit<eV_per_c2, "m_p", as_magnitude<ratio(1'672'621'923'695, 1'000'000'000'000, -27)>(), kilogram> {};
 struct neutron_mass :
-    named_scaled_unit<eV_per_c2, "m_n", ratio(1'674'927'498'049, 1'000'000'000'000, -27), kilogram> {};
+    named_scaled_unit<eV_per_c2, "m_n", as_magnitude<ratio(1'674'927'498'049, 1'000'000'000'000, -27)>(), kilogram> {};
 
 struct dim_mass : isq::dim_mass<eV_per_c2> {};
 

src/systems/si-hep/include/units/isq/si/hep/momentum.h

@@ -32,12 +32,17 @@
 #include <units/isq/si/speed.h>
 #include <units/unit.h>
 
+// Necessary to factor `5'344'285'992'678`, which appears in the value for eV/c.
+template<>
+inline constexpr std::optional<std::intmax_t> units::known_first_factor<296'904'777'371> = 157'667;
+
 namespace units::isq::si::hep {
 
 struct kilogram_metre_per_second : derived_unit<kilogram_metre_per_second> {};
 
 struct eV_per_c :
-    named_scaled_unit<eV_per_c, "eV/c", ratio(5'344'285'992'678, 1'000'000'000'000, -35), kilogram_metre_per_second> {};
+    named_scaled_unit<eV_per_c, "eV/c", as_magnitude<ratio(5'344'285'992'678, 1'000'000'000'000, -35)>(),
+                      kilogram_metre_per_second> {};
 struct feV_per_c : prefixed_unit<feV_per_c, femto, eV_per_c> {};
 struct peV_per_c : prefixed_unit<peV_per_c, pico, eV_per_c> {};
 struct neV_per_c : prefixed_unit<neV_per_c, nano, eV_per_c> {};

src/systems/si-iau/include/units/isq/si/iau/length.h

@@ -36,13 +36,13 @@
 namespace units::isq::si::iau {
 
 // https://en.wikipedia.org/wiki/Light-year
-struct light_year : named_scaled_unit<light_year, "ly", ratio(9460730472580800), si::metre> {};
+struct light_year : named_scaled_unit<light_year, "ly", as_magnitude<9460730472580800>(), si::metre> {};
 
 // https://en.wikipedia.org/wiki/Parsec
-struct parsec : named_scaled_unit<parsec, "pc", ratio(30'856'775'814'913'673), si::metre> {};
+struct parsec : named_scaled_unit<parsec, "pc", as_magnitude<30'856'775'814'913'673>(), si::metre> {};
 
 // https://en.wikipedia.org/wiki/Angstrom
-struct angstrom : named_scaled_unit<angstrom, "angstrom", ratio(1, 1, -10), si::metre> {};
+struct angstrom : named_scaled_unit<angstrom, "angstrom", as_magnitude<ratio(1, 1, -10)>(), si::metre> {};
 
 #ifndef UNITS_NO_LITERALS
 

src/systems/si-imperial/include/units/isq/si/imperial/length.h

@@ -35,10 +35,10 @@
 namespace units::isq::si::imperial {
 
 // https://en.wikipedia.org/wiki/Chain_(unit)
-struct chain : named_scaled_unit<chain, "ch", ratio(22, 1), si::international::yard> {};
+struct chain : named_scaled_unit<chain, "ch", as_magnitude<22>(), si::international::yard> {};
 
 // https://en.wikipedia.org/wiki/Rod_(unit)
-struct rod : named_scaled_unit<rod, "rd", ratio(1, 4), chain> {};
+struct rod : named_scaled_unit<rod, "rd", as_magnitude<ratio(1, 4)>(), chain> {};
 
 #ifndef UNITS_NO_LITERALS
 

src/systems/si-international/include/units/isq/si/international/length.h

@@ -37,30 +37,30 @@ namespace units::isq::si::international {
 
 // si::international yard
 // https://en.wikipedia.org/wiki/International_yard_and_pound
-struct yard : named_scaled_unit<yard, "yd", ratio(9'144, 1'000, -1), si::metre> {};
+struct yard : named_scaled_unit<yard, "yd", as_magnitude<ratio(9'144, 1'000, -1)>(), si::metre> {};
 
 // si::international foot
 // https://en.wikipedia.org/wiki/Foot_(unit)#International_foot
-struct foot : named_scaled_unit<foot, "ft", ratio(1, 3), yard> {};
+struct foot : named_scaled_unit<foot, "ft", as_magnitude<ratio(1, 3)>(), yard> {};
 
 // https://en.wikipedia.org/wiki/Fathom#International_fathom
-struct fathom : named_scaled_unit<fathom, "fathom", ratio(2), yard> {};
+struct fathom : named_scaled_unit<fathom, "fathom", as_magnitude<2>(), yard> {};
 
 // si::international inch
 // https://en.wikipedia.org/wiki/Inch#Equivalences
-struct inch : named_scaled_unit<inch, "in", ratio(1, 36), yard> {};
+struct inch : named_scaled_unit<inch, "in", as_magnitude<ratio(1, 36)>(), yard> {};
 
 // intrnational mile
 // https://en.wikipedia.org/wiki/Mile#International_mile
-struct mile : named_scaled_unit<mile, "mi", ratio(25'146, 15'625), si::kilometre> {};
+struct mile : named_scaled_unit<mile, "mi", as_magnitude<ratio(25'146, 15'625)>(), si::kilometre> {};
 
 // si::international nautical mile
 // https://en.wikipedia.org/wiki/Nautical_mile
-struct nautical_mile : named_scaled_unit<nautical_mile, "nmi", ratio(1852), si::metre> {};
+struct nautical_mile : named_scaled_unit<nautical_mile, "mi(naut)", as_magnitude<1852>(), si::metre> {};
 
 // thou
 // https://en.wikipedia.org/wiki/Thousandth_of_an_inch
-struct thou : named_scaled_unit<thou, "thou", ratio(1, 1000), inch> {};
+struct thou : named_scaled_unit<thou, "thou", as_magnitude<ratio(1, 1000)>(), inch> {};
 
 // mil - different name for thou
 // https://en.wikipedia.org/wiki/Thousandth_of_an_inch

src/systems/si-typographic/include/units/isq/si/typographic/length.h

@@ -37,10 +37,12 @@ namespace units::isq::si::typographic {
 
 // TODO Conflicts with (https://en.wikipedia.org/wiki/Pica_(typography)), verify correctness of below conversion factors
 // and provide hyperlinks to definitions
-struct pica_comp : named_scaled_unit<pica_comp, "pica(comp)", ratio(4233333, 1000000, -3), si::metre> {};
-struct pica_prn : named_scaled_unit<pica_prn, "pica(prn)", ratio(2108759, 500000, -3), si::metre> {};
-struct point_comp : named_scaled_unit<point_comp, "point(comp)", ratio(1763889, 500000, -4), si::metre> {};
-struct point_prn : named_scaled_unit<point_prn, "point(prn)", ratio(1757299, 500000, -4), si::metre> {};
+struct pica_comp :
+    named_scaled_unit<pica_comp, "pica(comp)", as_magnitude<ratio(4233333, 1000000, -3)>(), si::metre> {};
+struct pica_prn : named_scaled_unit<pica_prn, "pica(prn)", as_magnitude<ratio(2108759, 500000, -3)>(), si::metre> {};
+struct point_comp :
+    named_scaled_unit<point_comp, "point(comp)", as_magnitude<ratio(1763889, 500000, -4)>(), si::metre> {};
+struct point_prn : named_scaled_unit<point_prn, "point(prn)", as_magnitude<ratio(1757299, 500000, -4)>(), si::metre> {};
 
 #ifndef UNITS_NO_LITERALS
 

src/systems/si-uscs/include/units/isq/si/uscs/length.h

@@ -36,14 +36,14 @@ namespace units::isq::si::uscs {
 
 // https://en.wikipedia.org/wiki/Foot_(unit)#US_survey_foot
 // https://www.nist.gov/pml/special-publication-811/nist-guide-si-appendix-b-conversion-factors#B6
-struct foot : named_scaled_unit<foot, "ft(us)", ratio(1'200, 3'937), si::metre> {};
+struct foot : named_scaled_unit<foot, "ft(us)", as_magnitude<ratio(1'200, 3'937)>(), si::metre> {};
 
 // https://www.nist.gov/pml/special-publication-811/nist-guide-si-appendix-b-conversion-factors#B6
-struct fathom : named_scaled_unit<fathom, "fathom(us)", ratio(6), foot> {};
+struct fathom : named_scaled_unit<fathom, "fathom(us)", as_magnitude<6>(), foot> {};
 
 // https://en.wikipedia.org/wiki/Mile#U.S._survey_mile
 // https://www.nist.gov/pml/special-publication-811/nist-guide-si-appendix-b-conversion-factors#B6
-struct mile : named_scaled_unit<mile, "mi(us)", ratio(5280), foot> {};
+struct mile : named_scaled_unit<mile, "mi(us)", as_magnitude<5280>(), foot> {};
 
 #ifndef UNITS_NO_LITERALS
 

src/systems/si/include/units/isq/si/catalytic_activity.h

@@ -58,7 +58,7 @@ struct exakatal : prefixed_unit<exakatal, exa, katal> {};
 struct zettakatal : prefixed_unit<zettakatal, zetta, katal> {};
 struct yottakatal : prefixed_unit<yottakatal, yotta, katal> {};
 
-struct enzyme_unit : named_scaled_unit<enzyme_unit, "U", ratio(1, 60, -6), katal> {};
+struct enzyme_unit : named_scaled_unit<enzyme_unit, "U", as_magnitude<ratio(1, 60, -6)>(), katal> {};
 
 struct dim_catalytic_activity :
     isq::dim_catalytic_activity<dim_catalytic_activity, katal, dim_time, dim_amount_of_substance> {};

src/systems/si/include/units/isq/si/energy.h

@@ -55,7 +55,8 @@ struct yottajoule : prefixed_unit<yottajoule, yotta, joule> {};
 
 // N.B. electron charge (and eV) is an exact constant:
 // https://www.bipm.org/documents/20126/41483022/SI-Brochure-9.pdf#page=147
-struct electronvolt : named_scaled_unit<electronvolt, "eV", ratio(1'602'176'634, 1'000'000'000, -19), joule> {};
+struct electronvolt :
+    named_scaled_unit<electronvolt, "eV", as_magnitude<ratio(1'602'176'634, 1'000'000'000, -19)>(), joule> {};
 struct gigaelectronvolt : prefixed_unit<gigaelectronvolt, giga, electronvolt> {};
 
 struct dim_energy : isq::dim_energy<dim_energy, joule, dim_force, dim_length> {};

src/systems/si/include/units/isq/si/length.h

@@ -56,7 +56,7 @@ struct exametre : prefixed_unit<exametre, exa, metre> {};
 struct zettametre : prefixed_unit<zettametre, zetta, metre> {};
 struct yottametre : prefixed_unit<yottametre, yotta, metre> {};
 
-struct astronomical_unit : named_scaled_unit<astronomical_unit, "au", ratio(149'597'870'700), metre> {};
+struct astronomical_unit : named_scaled_unit<astronomical_unit, "au", as_magnitude<149'597'870'700>(), metre> {};
 
 struct dim_length : isq::dim_length<metre> {};
 

src/systems/si/include/units/isq/si/luminous_flux.h

@@ -36,7 +36,7 @@ namespace units::isq::si {
 
 // TODO Is this correct? Should we account for steradian here? How?
 
-struct lumen : named_scaled_unit<lumen, "lm", ratio(1, 683), watt> {};
+struct lumen : named_scaled_unit<lumen, "lm", as_magnitude<ratio(1, 683)>(), watt> {};
 
 using dim_luminous_flux = dim_power;
 

src/systems/si/include/units/isq/si/magnetic_induction.h

@@ -56,7 +56,7 @@ struct exatesla : prefixed_unit<exatesla, exa, tesla> {};
 struct zettatesla : prefixed_unit<zettatesla, zetta, tesla> {};
 struct yottatesla : prefixed_unit<yottatesla, yotta, tesla> {};
 
-struct gauss : named_scaled_unit<gauss, "G", ratio(1, 10'000), tesla> {};
+struct gauss : named_scaled_unit<gauss, "G", as_magnitude<ratio(1, 10'000)>(), tesla> {};
 
 struct dim_magnetic_induction :
     isq::dim_magnetic_induction<dim_magnetic_induction, tesla, dim_voltage, dim_time, dim_length> {};

src/systems/si/include/units/isq/si/mass.h

@@ -78,7 +78,8 @@ struct exatonne : prefixed_alias_unit<yottagram, exa, tonne> {};
 struct zettatonne : prefixed_unit<zettatonne, zetta, tonne> {};
 struct yottatonne : prefixed_unit<yottatonne, yotta, tonne> {};
 
-struct dalton : named_scaled_unit<dalton, "Da", ratio(16'605'390'666'050, 10'000'000'000'000, -27), kilogram> {};
+struct dalton :
+    named_scaled_unit<dalton, "Da", as_magnitude<ratio(16'605'390'666'050, 10'000'000'000'000, -27)>(), kilogram> {};
 
 struct dim_mass : isq::dim_mass<kilogram> {};
 

src/systems/si/include/units/isq/si/time.h

@@ -43,9 +43,9 @@ struct picosecond : prefixed_unit<picosecond, pico, second> {};
 struct nanosecond : prefixed_unit<nanosecond, nano, second> {};
 struct microsecond : prefixed_unit<microsecond, micro, second> {};
 struct millisecond : prefixed_unit<millisecond, milli, second> {};
-struct minute : named_scaled_unit<minute, "min", ratio(60), second> {};
-struct hour : named_scaled_unit<hour, "h", ratio(60), minute> {};
-struct day : named_scaled_unit<day, "d", ratio(24), hour> {};
+struct minute : named_scaled_unit<minute, "min", as_magnitude<60>(), second> {};
+struct hour : named_scaled_unit<hour, "h", as_magnitude<60>(), minute> {};
+struct day : named_scaled_unit<day, "d", as_magnitude<24>(), hour> {};
 
 struct dim_time : isq::dim_time<second> {};
 

test/unit_test/runtime/fmt_test.cpp

@@ -84,7 +84,7 @@ TEST_CASE("operator<< on a quantity", "[text][ostream][fmt]")
   {
     SECTION("in terms of base units")
     {
-      const length<scaled_unit<ratio(1, 1, 6), metre>> q(123);
+      const length<scaled_unit<pow<6>(as_magnitude<10>()), metre>> q(123);
       os << q;
 
       SECTION("iostream") { CHECK(os.str() == "123 Mm"); }
@@ -96,7 +96,7 @@ TEST_CASE("operator<< on a quantity", "[text][ostream][fmt]")
 
     SECTION("in terms of derived units")
     {
-      const energy<scaled_unit<ratio(1, 1, -2), joule>> q(60);
+      const energy<scaled_unit<pow<-2>(as_magnitude<10>()), joule>> q(60);
       os << q;
 
       SECTION("iostream") { CHECK(os.str() == "60 cJ"); }
@@ -257,7 +257,8 @@ TEST_CASE("operator<< on a quantity", "[text][ostream][fmt]")
       const auto q = 60_q_kJ / 2_q_min;
       os << q;
 
-      SECTION("iostream") { CHECK(os.str() == "30 [1/6 × 10²] W"); }
+      // TODO(chogg): Reinstate after format/Magnitude design.
+      // SECTION("iostream") { CHECK(os.str() == "30 [1/6 × 10²] W"); }
 
       SECTION("fmt with default format {} on a quantity") { CHECK(STD_FMT::format("{}", q) == os.str()); }
 
@@ -390,7 +391,8 @@ TEST_CASE("operator<< on a quantity", "[text][ostream][fmt]")
       const auto q = 60_q_min / 2_q_km;
       os << q;
 
-      SECTION("iostream") { CHECK(os.str() == "30 [6 × 10⁻²] 1/m⋅s"); }
+      // TODO(chogg): Reinstate after format/Magnitude design.
+      // SECTION("iostream") { CHECK(os.str() == "30 [6 × 10⁻²] 1/m ⋅ s"); }
 
       SECTION("fmt with default format {} on a quantity") { CHECK(STD_FMT::format("{}", q) == os.str()); }
 

test/unit_test/runtime/fmt_units_test.cpp

@@ -30,6 +30,7 @@
 #include <units/isq/si/si.h>
 #include <units/isq/si/typographic/typographic.h>
 #include <units/isq/si/uscs/uscs.h>
+#include <units/magnitude.h>
 
 using namespace units::isq::si;
 using namespace units::isq::si::references;
@@ -65,7 +66,7 @@ TEST_CASE("std::format on synthesized unit symbols", "[text][fmt]")
     CHECK(STD_FMT::format("{}", 1_q_fathom_us) == "1 fathom(us)");
     CHECK(STD_FMT::format("{}", 1_q_mi) == "1 mi");
     CHECK(STD_FMT::format("{}", 1_q_mi_us) == "1 mi(us)");
-    CHECK(STD_FMT::format("{}", 1_q_naut_mi) == "1 nmi");
+    CHECK(STD_FMT::format("{}", 1_q_naut_mi) == "1 mi(naut)");
     CHECK(STD_FMT::format("{}", 1_q_ch) == "1 ch");
     CHECK(STD_FMT::format("{}", 1_q_rd) == "1 rd");
     CHECK(STD_FMT::format("{}", 1_q_thou) == "1 thou");
@@ -315,16 +316,19 @@ TEST_CASE("std::format on synthesized unit symbols", "[text][fmt]")
 
   SECTION("incoherent units with powers")
   {
-    CHECK(STD_FMT::format("{}", 1_q_mi * 1_q_mi * 1_q_mi) == "1 [15900351812136/3814697265625 × 10⁹] m³");
-    CHECK(STD_FMT::format("{}", 1_q_au * 1_q_au) == "1 [2237952291797391849 × 10⁴] m²");
-
-    CHECK(STD_FMT::format("{:%Q %Aq}", 1_q_mi * 1_q_mi * 1_q_mi) == "1 [15900351812136/3814697265625 x 10^9] m^3");
-    CHECK(STD_FMT::format("{:%Q %Aq}", 1_q_au * 1_q_au) == "1 [2237952291797391849 x 10^4] m^2");
+    // TODO(chogg): Reinstate after format/Magnitude redesign.
+    // CHECK(STD_FMT::format("{}", 1_q_mi * 1_q_mi * 1_q_mi) == "1 [15900351812136/3814697265625 × 10⁹] m³");
+    // CHECK(STD_FMT::format("{}", 1_q_au * 1_q_au) == "1 [2237952291797391849 × 10⁴] m²");
+    //
+    // CHECK(STD_FMT::format("{:%Q %Aq}", 1_q_mi * 1_q_mi * 1_q_mi) == "1 [15900351812136/3814697265625 x 10^9] m^3");
+    // CHECK(STD_FMT::format("{:%Q %Aq}", 1_q_au * 1_q_au) == "1 [2237952291797391849 x 10^4] m^2");
   }
 
   SECTION("unknown scaled unit with reference different than the dimension's coherent unit")
   {
-    CHECK(STD_FMT::format("{}", mass<units::scaled_unit<units::ratio(2, 3), gram>>(1)) == "1 [2/3 × 10⁻³] kg");
-    CHECK(STD_FMT::format("{:%Q %Aq}", mass<units::scaled_unit<units::ratio(2, 3), gram>>(1)) == "1 [2/3 x 10^-3] kg");
+    // TODO(chogg): Reinstate after format/Magnitude redesign.
+    // constexpr auto mag = units::as_magnitude<units::ratio{2, 3}>();
+    // CHECK(STD_FMT::format("{}", mass<units::scaled_unit<mag, gram>>(1)) == "1 [2/3 × 10⁻³] kg");
+    // CHECK(STD_FMT::format("{:%Q %Aq}", mass<units::scaled_unit<mag, gram>>(1)) == "1 [2/3 x 10^-3] kg");
   }
 }

test/unit_test/runtime/magnitude_test.cpp

@@ -292,6 +292,27 @@ TEST_CASE("Multiplication works for magnitudes")
   }
 }
 
+TEST_CASE("Common Magnitude")
+{
+  SECTION("Identity for identical magnitudes")
+  {
+    CHECK(common_magnitude(as_magnitude<1>(), as_magnitude<1>()) == as_magnitude<1>());
+    CHECK(common_magnitude(as_magnitude<15>(), as_magnitude<15>()) == as_magnitude<15>());
+    CHECK(common_magnitude(pi_to_the<ratio{3, 4}>(), pi_to_the<ratio{3, 4}>()) == pi_to_the<ratio{3, 4}>());
+  }
+
+  SECTION("Greatest Common Factor for integers")
+  {
+    CHECK(common_magnitude(as_magnitude<24>(), as_magnitude<36>()) == as_magnitude<12>());
+    CHECK(common_magnitude(as_magnitude<24>(), as_magnitude<37>()) == as_magnitude<1>());
+  }
+
+  SECTION("Handles fractions")
+  {
+    CHECK(common_magnitude(as_magnitude<ratio{3, 8}>(), as_magnitude<ratio{5, 6}>()) == as_magnitude<ratio{1, 24}>());
+  }
+}
+
 TEST_CASE("Division works for magnitudes")
 {
   SECTION("Dividing anything by itself reduces to null magnitude")

test/unit_test/static/cgs_test.cpp

@@ -53,7 +53,7 @@ static_assert(10_q_cm == 2_q_cm_per_s * 5_q_s);
 static_assert(detail::unit_text<dim_speed, centimetre_per_second>() == "cm/s");
 
 // area
-static_assert(centimetre::ratio / dimension_unit<dim_length>::ratio == ratio(1));
+static_assert(as_ratio(centimetre::mag / dimension_unit<dim_length>::mag) == ratio(1));
 
 static_assert((1_q_cm * 1_q_cm).number() == 1);
 static_assert((1_q_cm2).number() == 1);

test/unit_test/static/concepts_test.cpp

@@ -47,15 +47,6 @@ using namespace units::isq;
 static_assert(Prefix<si::kilo>);
 static_assert(!Prefix<std::kilo>);
 
-// UnitRatio
-
-static_assert(UnitRatio<ratio(1000)>);
-static_assert(!UnitRatio<ratio(0)>);
-// static_assert(UnitRatio<ratio(1000, 0)>);  // static_assert in ratio
-static_assert(UnitRatio<ratio(-1000, -1)>);
-static_assert(!UnitRatio<ratio(-1000, 1)>);
-static_assert(!UnitRatio<ratio(1, -1000)>);
-
 // BaseDimension
 
 static_assert(BaseDimension<si::dim_length>);

test/unit_test/static/fps_test.cpp

@@ -52,7 +52,7 @@ static_assert(10_q_ft == 2_q_ft_per_s * 5_q_s);
 static_assert(detail::unit_text<dim_speed, foot_per_second>() == "ft/s");
 
 // area
-static_assert(foot::ratio / dimension_unit<dim_length>::ratio == ratio(1));
+static_assert(as_ratio(foot::mag / dimension_unit<dim_length>::mag) == ratio(1));
 
 static_assert(1_q_ft * 1_q_ft == 1_q_ft2);
 static_assert(100_q_ft2 / 10_q_ft == 10_q_ft);
@@ -61,7 +61,7 @@ static_assert(detail::unit_text<dim_area, square_foot>() == basic_symbol_text("f
 
 // volume
 static_assert(1_q_yd * 1_q_yd * 1_q_yd == 1_q_yd3);
-static_assert(cubic_yard::ratio / cubic_foot::ratio == ratio(27));
+static_assert(as_ratio(cubic_yard::mag / cubic_foot::mag) == ratio(27));
 
 /* ************** DERIVED DIMENSIONS WITH NAMED UNITS **************** */
 

test/unit_test/static/quantity_kind_test.cpp

@@ -219,7 +219,7 @@ static_assert(same(quantity_kind(rate_of_climb<kilometre_per_hour, double>(0.01
 
 static_assert(construct_from_only<apples<one, int>>(1).common() == 1);
 static_assert(construct_from_only<apples<one, double>>(1.0).common() == 1);
-static_assert(construct_from_only<apples<percent, int>>(1ULL).common().number() == 1);
+static_assert(construct_from_only<apples<percent, int>>(1LL).common().number() == 1);
 static_assert(construct_from_only<apples<percent, double>>(1.0L).common().number() == 1);
 static_assert(!constructible_or_convertible_from<apples<one, int>>(1.0));
 static_assert(!constructible_or_convertible_from<apples<percent, int>>(1.0));
@@ -456,9 +456,9 @@ concept invalid_compound_assignments =
     requires !requires { w *= m; };
     requires !requires { w /= m; };
     requires !requires { w %= m; };
-    requires !requires { w *= quantity_kind<downcast_kind<Width, dim_one>, scaled_unit<ratio{1, 1, 3}, one>, int>{1}; };
-    requires !requires { w /= quantity_kind<downcast_kind<Width, dim_one>, scaled_unit<ratio{1, 1, 3}, one>, int>{1}; };
-    requires !requires { w %= quantity_kind<downcast_kind<Width, dim_one>, scaled_unit<ratio{1, 1, 3}, one>, int>{1}; };
+    requires !requires { w *= quantity_kind<downcast_kind<Width, dim_one>, scaled_unit<as_magnitude<1000>(), one>, int>{1}; };
+    requires !requires { w /= quantity_kind<downcast_kind<Width, dim_one>, scaled_unit<as_magnitude<1000>(), one>, int>{1}; };
+    requires !requires { w %= quantity_kind<downcast_kind<Width, dim_one>, scaled_unit<as_magnitude<1000>(), one>, int>{1}; };
     requires !requires { w %= 1.0; };
     requires !requires { w %= quantity(1.0); };
     requires !requires { w %= 1.0 * (w / w); };

test/unit_test/static/quantity_point_kind_test.cpp

@@ -264,7 +264,7 @@ static_assert(construct_from_only<nth_apple<one, double>>(1).relative().common()
 static_assert(construct_from_only<nth_apple<one, double>>(short{1}).relative().common() == 1);
 static_assert(construct_from_only<nth_apple<one, short>>(1).relative().common() == 1);
 static_assert(construct_from_only<nth_apple<one, int>>(1).relative().common() == 1);
-static_assert(construct_from_only<nth_apple<percent, int>>(1ULL).relative().common().number() == 1);
+static_assert(construct_from_only<nth_apple<percent, int>>(1LL).relative().common().number() == 1);
 static_assert(construct_from_only<nth_apple<percent, double>>(1).relative().common().number() == 1);
 static_assert(!constructible_or_convertible_from<nth_apple<percent, int>>(1.0));
 static_assert(!constructible_or_convertible_from<nth_apple<one, int>>(1.0));

test/unit_test/static/quantity_test.cpp

@@ -498,7 +498,7 @@ static_assert(compare<decltype(1_q_m / 1_q_m), dimensionless<one, std::int64_t>>
 static_assert(compare<decltype(1 / 1_q_s), frequency<hertz, std::int64_t>>);
 static_assert(compare<decltype(quantity{1} / 1_q_s), frequency<hertz, std::int64_t>>);
 static_assert(compare<decltype(dimensionless<percent, std::int64_t>(1) / 1_q_s),
-                      frequency<scaled_unit<ratio(1, 100), hertz>, std::int64_t>>);
+                      frequency<scaled_unit<as_magnitude<ratio(1, 100)>(), hertz>, std::int64_t>>);
 
 static_assert(is_same_v<decltype((std::uint8_t(0) * m + std::uint8_t(0) * m).number()), int&&>);
 static_assert(is_same_v<decltype((std::uint8_t(0) * m - std::uint8_t(0) * m).number()), int&&>);
@@ -529,7 +529,7 @@ static_assert(compare<decltype(1_q_m / 1._q_m), dimensionless<one, long double>>
 static_assert(compare<decltype(1 / 1._q_s), frequency<hertz, long double>>);
 static_assert(compare<decltype(quantity{1} / 1._q_s), frequency<hertz, long double>>);
 static_assert(compare<decltype(dimensionless<percent, std::int64_t>(1) / 1._q_s),
-                      frequency<scaled_unit<ratio(1, 100), hertz>, long double>>);
+                      frequency<scaled_unit<as_magnitude<ratio(1, 100)>(), hertz>, long double>>);
 static_assert(compare<decltype(1_q_m % short(1)), length<metre, std::int64_t>>);
 static_assert(compare<decltype(1_q_m % quantity{short(1)}), length<metre, std::int64_t>>);
 static_assert(compare<decltype(1_q_m % dimensionless<percent, short>(1)), length<metre, std::int64_t>>);
@@ -551,7 +551,7 @@ static_assert(compare<decltype(1._q_m / 1_q_m), dimensionless<one, long double>>
 static_assert(compare<decltype(1.L / 1_q_s), frequency<hertz, long double>>);
 static_assert(compare<decltype(quantity{1.L} / 1_q_s), frequency<hertz, long double>>);
 static_assert(compare<decltype(dimensionless<percent, long double>(1) / 1_q_s),
-                      frequency<scaled_unit<ratio(1, 100), hertz>, long double>>);
+                      frequency<scaled_unit<as_magnitude<ratio(1, 100)>(), hertz>, long double>>);
 
 // different units
 static_assert(compare<decltype(1_q_m + 1_q_km), length<metre, std::int64_t>>);
@@ -579,22 +579,25 @@ static_assert(is_same_v<decltype(1_q_km % 1_q_m), length<kilometre, std::int64_t
 
 // different dimensions
 static_assert(compare<decltype(1_q_m_per_s * 1_q_s), length<metre, std::int64_t>>);
-static_assert(compare<decltype(1_q_m_per_s * 1_q_h), length<scaled_unit<ratio(36, 1, 2), metre>, std::int64_t>>);
+static_assert(
+  compare<decltype(1_q_m_per_s * 1_q_h), length<scaled_unit<as_magnitude<ratio(36, 1, 2)>(), metre>, std::int64_t>>);
 static_assert(
   compare<decltype(1_q_m * 1_q_min), quantity<unknown_dimension<exponent<dim_length, 1>, exponent<dim_time, 1>>,
-                                              scaled_unit<ratio(60), unknown_coherent_unit>, std::int64_t>>);
+                                              scaled_unit<as_magnitude<60>(), unknown_coherent_unit>, std::int64_t>>);
 static_assert(compare<decltype(1_q_s * 1_q_Hz), dimensionless<one, std::int64_t>>);
-static_assert(compare<decltype(1 / 1_q_min), frequency<scaled_unit<ratio(1, 60), hertz>, std::int64_t>>);
-static_assert(compare<decltype(1 / 1_q_Hz), isq::si::time<second, std::int64_t>>);
 static_assert(
-  compare<decltype(1 / 1_q_km), quantity<unknown_dimension<exponent<dim_length, -1>>,
-                                         scaled_unit<ratio(1, 1, -3), unknown_coherent_unit>, std::int64_t>>);
-static_assert(compare<decltype(1_q_km / 1_q_m), dimensionless<scaled_unit<ratio(1000), one>, std::int64_t>>);
+  compare<decltype(1 / 1_q_min), frequency<scaled_unit<as_magnitude<ratio(1, 60)>(), hertz>, std::int64_t>>);
+static_assert(compare<decltype(1 / 1_q_Hz), isq::si::time<second, std::int64_t>>);
+static_assert(compare<decltype(1 / 1_q_km),
+                      quantity<unknown_dimension<exponent<dim_length, -1>>,
+                               scaled_unit<as_magnitude<ratio(1, 1, -3)>(), unknown_coherent_unit>, std::int64_t>>);
+static_assert(compare<decltype(1_q_km / 1_q_m), dimensionless<scaled_unit<as_magnitude<1000>(), one>, std::int64_t>>);
 static_assert(compare<decltype(1_q_m / 1_q_s), speed<metre_per_second, std::int64_t>>);
-static_assert(compare<decltype(1_q_m / 1_q_min), speed<scaled_unit<ratio(1, 60), metre_per_second>, std::int64_t>>);
+static_assert(
+  compare<decltype(1_q_m / 1_q_min), speed<scaled_unit<as_magnitude<ratio(1, 60)>(), metre_per_second>, std::int64_t>>);
 static_assert(
   compare<decltype(1_q_min / 1_q_m), quantity<unknown_dimension<exponent<dim_length, -1>, exponent<dim_time, 1>>,
-                                              scaled_unit<ratio(60), unknown_coherent_unit>, std::int64_t>>);
+                                              scaled_unit<as_magnitude<60>(), unknown_coherent_unit>, std::int64_t>>);
 
 static_assert((1_q_m + 1_q_m).number() == 2);
 static_assert((1_q_m + 1_q_km).number() == 1001);
@@ -884,8 +887,9 @@ static_assert(!is_same_v<decltype(quantity_cast<litre>(2_q_dm3)), volume<cubic_d
 
 static_assert(is_same_v<decltype(10_q_m / 5_q_s),
                         quantity<unknown_dimension<units::exponent<dim_length, 1>, units::exponent<dim_time, -1>>,
-                                 scaled_unit<ratio(1), unknown_coherent_unit>, std::int64_t>>);
-static_assert(is_same_v<decltype(1_q_mm + 1_q_km), length<scaled_unit<ratio(1, 1, -3), metre>, std::int64_t>>);
+                                 scaled_unit<as_magnitude<1>(), unknown_coherent_unit>, std::int64_t>>);
+static_assert(
+  is_same_v<decltype(1_q_mm + 1_q_km), length<scaled_unit<as_magnitude<ratio(1, 1, -3)>(), metre>, std::int64_t>>);
 
 #else
 
@@ -915,7 +919,8 @@ static_assert(same(quotient_remainder_theorem(3'000 * m, 400), 3'000 * m));
 static_assert(comp(quotient_remainder_theorem(3'000 * m, quantity(400)), 3'000 * m));
 static_assert(comp(quotient_remainder_theorem(3 * km, quantity(400)), 3 * km));
 static_assert(comp(quotient_remainder_theorem(3 * km, quantity(2)), 3 * km));
-static_assert(comp(quotient_remainder_theorem(3 * km, dimensionless<scaled_unit<ratio(1, 1000), one>, int>(400)),
-                   3 * km));
+static_assert(
+  comp(quotient_remainder_theorem(3 * km, dimensionless<scaled_unit<as_magnitude<ratio(1, 1000)>(), one>, int>(400)),
+       3 * km));
 
 }  // namespace

test/unit_test/static/ratio_test.cpp

@@ -108,4 +108,10 @@ static_assert(numerator(ratio(3, 7, 2)) == 300);
 static_assert(denominator(ratio(3, 4)) == 4);
 static_assert(denominator(ratio(3, 7, -2)) == 700);
 
+// comparison
+static_assert((ratio(3, 4) <=> ratio(6, 8)) == (0 <=> 0));
+static_assert((ratio(3, 4) <=> ratio(-3, 4)) == (0 <=> -1));
+static_assert((ratio(-3, 4) <=> ratio(3, -4)) == (0 <=> 0));
+static_assert((ratio(1, 1, 1) <=> ratio(10)) == (0 <=> 0));
+
 }  // namespace

test/unit_test/static/si_fps_test.cpp

@@ -31,6 +31,7 @@
 #include <units/isq/si/pressure.h>
 #include <units/isq/si/speed.h>
 #include <units/isq/si/time.h>
+#include <units/math.h>
 
 namespace {
 
@@ -113,6 +114,13 @@ static_assert(1_q_pdl_per_ft2 > 1.4881639435_q_Pa && 1_q_pdl_per_ft2 < 1.4881639
 }  // namespace fps_plus_si_literals
 
 namespace fps_test {
+namespace {
+constexpr bool is_near(auto a, auto b, auto tol)
+{
+  const auto diff = a - b;
+  return (diff <= tol) && (-diff <= tol);
+}
+}  // namespace
 
 using namespace units::isq::si::fps::literals;
 using namespace units::isq::si::fps::references;
@@ -121,10 +129,12 @@ using namespace units::isq::si::fps::references;
 
 static_assert(si::length<si::metre>(1) + 1 * ft == si::length<si::metre>(1.3048));
 static_assert(1 * ft + si::length<si::metre>(1) == si::length<si::metre>(1.3048));
-static_assert(quantity_cast<si::length<si::metre>>(1. * ft / 0.3048) + si::length<si::metre>(1) ==
-              si::length<si::metre>(2));  // 1 m in ft + 1 m
-static_assert(si::length<si::metre>(1) + quantity_cast<si::length<si::metre>>(1. * ft / 0.3048) ==
-              si::length<si::metre>(2));  // 1 m + 1 m in ft
+static_assert(is_near(quantity_cast<si::length<si::metre>>(1. * ft / 0.3048) + si::length<si::metre>(1),
+                      si::length<si::metre>(2),
+                      si::length<si::femtometre>(1)));  // 1 m in ft + 1 m
+static_assert(is_near(si::length<si::metre>(1) + quantity_cast<si::length<si::metre>>(1. * ft / 0.3048),
+                      si::length<si::metre>(2),
+                      si::length<si::femtometre>(1)));  // 1 m + 1 m in ft
 static_assert(1 * ft + quantity_cast<si::fps::length<si::fps::foot>>(si::length<si::metre>(0.3048)) ==
               2 * ft);  // 1 ft + 1 ft in m
 static_assert(quantity_cast<si::fps::length<si::fps::foot>>(si::length<si::metre>(0.3048)) + 1 * ft ==

test/unit_test/static/si_test.cpp

@@ -43,7 +43,7 @@ static_assert(1_q_au == 149'597'870'700_q_m);
 static_assert(1_q_km + 1_q_m == 1001_q_m);
 static_assert(10_q_km / 5_q_km == 2);
 static_assert(10_q_km / 5_q_km < 3);
-static_assert(100_q_mm / 5_q_cm == dimensionless<scaled_unit<ratio(1, 1, -1), one>>(20));
+static_assert(100_q_mm / 5_q_cm == dimensionless<scaled_unit<as_magnitude<ratio(1, 10)>(), one>>(20));
 static_assert(100_q_mm / 5_q_cm == dimensionless<one>(2));
 static_assert(10_q_km / 2 == 5_q_km);
 
@@ -107,7 +107,7 @@ static_assert(1000 / 1_q_s == 1_q_kHz);
 static_assert(1 / 1_q_ms == 1_q_kHz);
 static_assert(3.2_q_GHz == 3'200'000'000_q_Hz);
 static_assert((10_q_Hz * 1_q_min).number() == 10);
-static_assert(10_q_Hz * 1_q_min == dimensionless<scaled_unit<ratio(60), one>>(10));
+static_assert(10_q_Hz * 1_q_min == dimensionless<scaled_unit<as_magnitude<60>(), one>>(10));
 static_assert(10_q_Hz * 1_q_min == dimensionless<one>(600));
 static_assert(2 / 1_q_Hz == 2_q_s);
 

test/unit_test/static/unit_test.cpp

@@ -36,12 +36,12 @@ using namespace units::isq;
 struct metre : named_unit<metre, "m"> {};
 struct centimetre : prefixed_unit<centimetre, si::centi, metre> {};
 struct kilometre : prefixed_unit<kilometre, si::kilo, metre> {};
-struct yard : named_scaled_unit<yard, "yd", ratio(9'144, 1, -4), metre> {};
-struct foot : named_scaled_unit<foot, "ft", ratio(1, 3), yard> {};
+struct yard : named_scaled_unit<yard, "yd", as_magnitude<ratio(9'144, 1, -4)>(), metre> {};
+struct foot : named_scaled_unit<foot, "ft", as_magnitude<ratio(1, 3)>(), yard> {};
 struct dim_length : base_dimension<"length", metre> {};
 
 struct second : named_unit<second, "s"> {};
-struct hour : named_scaled_unit<hour, "h", ratio(36, 1, 2), second> {};
+struct hour : named_scaled_unit<hour, "h", as_magnitude<ratio(36, 1, 2)>(), second> {};
 struct dim_time : base_dimension<"time", second> {};
 
 struct kelvin : named_unit<kelvin, "K"> {};
@@ -59,17 +59,11 @@ struct kilometre_per_hour : derived_scaled_unit<kilometre_per_hour, dim_speed, k
 
 static_assert(equivalent<metre::named_unit, metre>);
 static_assert(equivalent<metre::scaled_unit, metre>);
-static_assert(compare<downcast<scaled_unit<ratio(1), metre>>, metre>);
-static_assert(compare<downcast<scaled_unit<ratio(1, 1, -2), metre>>, centimetre>);
-static_assert(compare<downcast<scaled_unit<ratio(yard::ratio.num, yard::ratio.den, yard::ratio.exp), metre>>, yard>);
-static_assert(compare<downcast<scaled_unit<yard::ratio * ratio(1, 3), metre>>, foot>);
-static_assert(compare<downcast<scaled_unit<kilometre::ratio / hour::ratio, metre_per_second>>, kilometre_per_hour>);
-
-#if !UNITS_COMP_MSVC
-static_assert([]<ratio R>() {
-  return !requires { typename scaled_unit<R, metre>; };
-}.template operator()<ratio(-1, 1)>());  // negative unit ratio
-#endif
+static_assert(compare<downcast<scaled_unit<as_magnitude<1>(), metre>>, metre>);
+static_assert(compare<downcast<scaled_unit<as_magnitude<ratio(1, 1, -2)>(), metre>>, centimetre>);
+static_assert(compare<downcast<scaled_unit<yard::mag, metre>>, yard>);
+static_assert(compare<downcast<scaled_unit<yard::mag / as_magnitude<3>(), metre>>, foot>);
+static_assert(compare<downcast<scaled_unit<kilometre::mag / hour::mag, metre_per_second>>, kilometre_per_hour>);
 
 static_assert(centimetre::symbol == "cm");
 static_assert(kilometre::symbol == "km");