clang-format on new examples

example/box_example.cpp

@@ -1,101 +1,99 @@
-
-
 #include <units/physical/si/acceleration.h>
-#include <units/physical/si/length.h>
-#include <units/physical/si/volume.h>
-#include <units/physical/si/time.h>
-#include <units/physical/si/force.h>
-#include <units/physical/si/mass.h>
 #include <units/physical/si/density.h>
+#include <units/physical/si/force.h>
+#include <units/physical/si/length.h>
+#include <units/physical/si/mass.h>
+#include <units/physical/si/time.h>
+#include <units/physical/si/volume.h>
 #include <cassert>
 
-namespace{
+namespace {
 
-   namespace length{
+namespace length {
 
-      template <typename Rep = double>
-      using m = units::si::length<units::si::metre,Rep>;
+template<typename Rep = double>
+using m = units::si::length<units::si::metre, Rep>;
 
-      template <typename Rep = double>
-      using mm = units::si::length<units::si::millimetre,Rep>;
-   }
-   
-   namespace acceleration{
+template<typename Rep = double>
+using mm = units::si::length<units::si::millimetre, Rep>;
 
-      template <typename Rep = double>
-      using mps2 = units::si::acceleration<units::si::metre_per_second_sq,Rep>;
+}  // namespace length
 
-      template <typename Rep = double>
-      constexpr mps2<> g{static_cast<Rep>(9.80665)};
-   }
+namespace acceleration {
 
-   namespace force{
+template<typename Rep = double>
+using mps2 = units::si::acceleration<units::si::metre_per_second_sq, Rep>;
 
-      template <typename Rep = double>
-      using N = units::si::force<units::si::newton,Rep>;
-   }
+template<typename Rep = double>
+constexpr mps2<> g{static_cast<Rep>(9.80665)};
 
-   namespace mass {
+}  // namespace acceleration
 
-      template <typename Rep = double>
-      using kg = units::si::mass<units::si::kilogram,Rep>;
-   }
+namespace force {
 
-   namespace density {
+template<typename Rep = double>
+using N = units::si::force<units::si::newton, Rep>;
 
-      template <typename Rep = double>
-      using kgpm3 = units::si::density<units::si::kilogram_per_metre_cub,Rep>;
-   }
-
-   namespace volume {
-
-      template <typename Rep = double>
-      using m3 = units::si::volume<units::si::cubic_metre,Rep>;
-   }
 }
 
-struct Box{
+namespace mass {
 
-    Box(const length::m<> & l,
-        const length::m<> & w,
-        const length::m<> & h
-    ): length{l},width{w},height{h}{}
+template<typename Rep = double>
+using kg = units::si::mass<units::si::kilogram, Rep>;
 
-    force::N<> filled_weight()const
-    {
-        const volume::m3<>  volume
-           = length * width * height;
-        const mass::kg<>  mass = contents.density * volume;
-        return mass * acceleration::g<>;
-    }
+}
 
-    length::m<> fill_level(const mass::kg<> & measured_mass)const
-    {
-       return height
-          * (measured_mass * acceleration::g<>) / filled_weight();
-    }
+namespace density {
 
-    volume::m3<> spare_capacity(const  mass::kg<> & measured_mass)const
-    {
-       return (height - fill_level(measured_mass)) * width * length;
-    }
+template<typename Rep = double>
+using kgpm3 = units::si::density<units::si::kilogram_per_metre_cub, Rep>;
 
-    struct contents{
-        contents():density{air_density}{}
-        density::kgpm3<> density;
-    }contents;
+}
 
-    void set_contents_density(const density::kgpm3<>  & density_in)
-    {
-        assert( density_in > air_density );
-        contents.density = density_in;
-    }
+namespace volume {
 
-    static constexpr density::kgpm3<> air_density{1.225};
+template<typename Rep = double>
+using m3 = units::si::volume<units::si::cubic_metre, Rep>;
+
+}
+}  // namespace
+
+struct Box {
+  static constexpr density::kgpm3<> air_density{1.225};
+
+  length::m<> length;
+  length::m<> width;
+  length::m<> height;
+
+  struct contents {
+    density::kgpm3<> density = air_density;
+  } contents;
+
+  Box(const length::m<>& l, const length::m<>& w, const length::m<>& h) : length{l}, width{w}, height{h} {}
+
+  force::N<> filled_weight() const
+  {
+    const volume::m3<> volume = length * width * height;
+    const mass::kg<> mass = contents.density * volume;
+    return mass * acceleration::g<>;
+  }
+
+  length::m<> fill_level(const mass::kg<>& measured_mass) const
+  {
+    return height * (measured_mass * acceleration::g<>) / filled_weight();
+  }
+
+  volume::m3<> spare_capacity(const mass::kg<>& measured_mass) const
+  {
+    return (height - fill_level(measured_mass)) * width * length;
+  }
+
+  void set_contents_density(const density::kgpm3<>& density_in)
+  {
+    assert(density_in > air_density);
+    contents.density = density_in;
+  }
 
-    length::m<> length;
-    length::m<> width;
-    length::m<> height;
 };
 
 #include <iostream>
@@ -103,23 +101,18 @@ struct Box{
 using namespace units::si::literals;
 int main()
 {
-   auto box = Box{1000.0mm, 500.0mm, 200.0mm};
-   box.set_contents_density(1000.0kgpm3);
+  auto box = Box{1000.0mm, 500.0mm, 200.0mm};
+  box.set_contents_density(1000.0kgpm3);
 
-   auto fill_time = 200.0s;      // time since starting fill
-   auto measured_mass = 20.0kg;  // measured mass at fill_time
-
-   std::cout << "mpusz/units box example...\n";
-   std::cout << "fill height at " << fill_time << " = "
-   << box.fill_level(measured_mass) << "( " << (box.fill_level(measured_mass)/ box.height)*100 << "% full)\n";
-   std::cout << "spare_capacity at " << fill_time << " = "
-   << box.spare_capacity(measured_mass) <<'\n';
-   std::cout << "input flow rate after " << fill_time
-   << " = " << measured_mass / fill_time <<'\n';
-   std::cout << "float rise rate = "
-   << box.fill_level(measured_mass) / fill_time <<'\n';
-   auto fill_time_left
-   = (box.height / box.fill_level(measured_mass) - 1) * fill_time ;
-   std::cout << "box full E.T.A. at current flow rate = " << fill_time_left <<'\n';
+  auto fill_time = 200.0s;      // time since starting fill
+  auto measured_mass = 20.0kg;  // measured mass at fill_time
 
+  std::cout << "mpusz/units box example...\n";
+  std::cout << "fill height at " << fill_time << " = " << box.fill_level(measured_mass) << " ("
+            << (box.fill_level(measured_mass) / box.height) * 100 << "% full)\n";
+  std::cout << "spare_capacity at " << fill_time << " = " << box.spare_capacity(measured_mass) << '\n';
+  std::cout << "input flow rate after " << fill_time << " = " << measured_mass / fill_time << '\n';
+  std::cout << "float rise rate = " << box.fill_level(measured_mass) / fill_time << '\n';
+  auto fill_time_left = (box.height / box.fill_level(measured_mass) - 1) * fill_time;
+  std::cout << "box full E.T.A. at current flow rate = " << fill_time_left << '\n';
 }