Add clang-tidy. (#368)

src/ftxui/component/animation.cpp

@@ -1,14 +1,18 @@
-#define _USE_MATH_DEFINES
-#include <cmath>  // for sin, pow, sqrt, M_PI_2, M_PI, cos
+#include <cmath>
+#include <ratio>    // for ratio
+#include <utility>  // for move
 
 #include "ftxui/component/animation.hpp"
 
-#include <ratio>  // for ratio
-
-namespace ftxui {
-namespace animation {
+namespace ftxui::animation {
 
 namespace easing {
+
+namespace {
+constexpr float kPi = 3.14159265358979323846F;
+constexpr float kPi2 = kPi / 2.F;
+}  // namespace
+
 // Easing function have been taken out of:
 // https://github.com/warrenm/AHEasing/blob/master/AHEasing/easing.c
 //
@@ -40,7 +44,7 @@ float QuadraticOut(float p) {
 // y = (1/2)((2x)^2)             ; [0, 0.5)
 // y = -(1/2)((2x-1)*(2x-3) - 1) ; [0.5, 1]
 float QuadraticInOut(float p) {
-  if (p < 0.5) {
+  if (p < 0.5F) {  // NOLINT
     return 2 * p * p;
   } else {
     return (-2 * p * p) + (4 * p) - 1;
@@ -62,11 +66,11 @@ float CubicOut(float p) {
 // y = (1/2)((2x)^3)       ; [0, 0.5)
 // y = (1/2)((2x-2)^3 + 2) ; [0.5, 1]
 float CubicInOut(float p) {
-  if (p < 0.5) {
+  if (p < 0.5F) {  // NOLINT
     return 4 * p * p * p;
   } else {
     float f = ((2 * p) - 2);
-    return 0.5 * f * f * f + 1;
+    return 0.5F * f * f * f + 1;  // NOLINT
   }
 }
 
@@ -85,11 +89,11 @@ float QuarticOut(float p) {
 // y = (1/2)((2x)^4)        ; [0, 0.5)
 // y = -(1/2)((2x-2)^4 - 2) ; [0.5, 1]
 float QuarticInOut(float p) {
-  if (p < 0.5) {
-    return 8 * p * p * p * p;
+  if (p < 0.5F) {              // NOLINT
+    return 8 * p * p * p * p;  // NOLINT
   } else {
     float f = (p - 1);
-    return -8 * f * f * f * f + 1;
+    return -8 * f * f * f * f + 1;  // NOLINT
   }
 }
 
@@ -108,119 +112,122 @@ float QuinticOut(float p) {
 // y = (1/2)((2x)^5)       ; [0, 0.5)
 // y = (1/2)((2x-2)^5 + 2) ; [0.5, 1]
 float QuinticInOut(float p) {
-  if (p < 0.5) {
-    return 16 * p * p * p * p * p;
-  } else {
-    float f = ((2 * p) - 2);
-    return 0.5 * f * f * f * f * f + 1;
+  if (p < 0.5F) {                        // NOLINT
+    return 16 * p * p * p * p * p;       // NOLINT
+  } else {                               // NOLINT
+    float f = ((2 * p) - 2);             // NOLINT
+    return 0.5 * f * f * f * f * f + 1;  // NOLINT
   }
 }
 
 // Modeled after quarter-cycle of sine wave
 float SineIn(float p) {
-  return sin((p - 1) * M_PI_2) + 1;
+  return std::sin((p - 1) * kPi2) + 1;
 }
 
 // Modeled after quarter-cycle of sine wave (different phase)
 float SineOut(float p) {
-  return sin(p * M_PI_2);
+  return std::sin(p * kPi2);
 }
 
 // Modeled after half sine wave
 float SineInOut(float p) {
-  return 0.5 * (1 - cos(p * M_PI));
+  return 0.5F * (1 - std::cos(p * kPi));  // NOLINT
 }
 
 // Modeled after shifted quadrant IV of unit circle
 float CircularIn(float p) {
-  return 1 - sqrt(1 - (p * p));
+  return 1 - std::sqrt(1 - (p * p));
 }
 
 // Modeled after shifted quadrant II of unit circle
 float CircularOut(float p) {
-  return sqrt((2 - p) * p);
+  return std::sqrt((2 - p) * p);
 }
 
 // Modeled after the piecewise circular function
 // y = (1/2)(1 - sqrt(1 - 4x^2))           ; [0, 0.5)
 // y = (1/2)(sqrt(-(2x - 3)*(2x - 1)) + 1) ; [0.5, 1]
 float CircularInOut(float p) {
-  if (p < 0.5) {
-    return 0.5 * (1 - sqrt(1 - 4 * (p * p)));
+  if (p < 0.5F) {                                    // NOLINT
+    return 0.5F * (1 - std::sqrt(1 - 4 * (p * p)));  // NOLINT
   } else {
-    return 0.5 * (sqrt(-((2 * p) - 3) * ((2 * p) - 1)) + 1);
+    return 0.5F * (std::sqrt(-((2 * p) - 3) * ((2 * p) - 1)) + 1);  // NOLINT
   }
 }
 
 // Modeled after the exponential function y = 2^(10(x - 1))
 float ExponentialIn(float p) {
-  return (p == 0.0) ? p : pow(2, 10 * (p - 1));
+  return (p == 0.0) ? p : std::pow(2, 10 * (p - 1));  // NOLINT
 }
 
 // Modeled after the exponential function y = -2^(-10x) + 1
 float ExponentialOut(float p) {
-  return (p == 1.0) ? p : 1 - pow(2, -10 * p);
+  return (p == 1.0) ? p : 1 - std::pow(2, -10 * p);  // NOLINT
 }
 
 // Modeled after the piecewise exponential
 // y = (1/2)2^(10(2x - 1))         ; [0,0.5)
 // y = -(1/2)*2^(-10(2x - 1))) + 1 ; [0.5,1]
 float ExponentialInOut(float p) {
-  if (p == 0.0 || p == 1.0)
+  if (p == 0.0 || p == 1.F) {
     return p;
+  }
 
-  if (p < 0.5) {
-    return 0.5 * pow(2, (20 * p) - 10);
-  } else {
-    return -0.5 * pow(2, (-20 * p) + 10) + 1;
+  if (p < 0.5F) {                                   // NOLINT
+    return 0.5 * std::pow(2, (20 * p) - 10);        // NOLINT
+  } else {                                          // NOLINT
+    return -0.5 * std::pow(2, (-20 * p) + 10) + 1;  // NOLINT
   }
 }
 
 // Modeled after the damped sine wave y = sin(13pi/2*x)*pow(2, 10 * (x - 1))
 float ElasticIn(float p) {
-  return sin(13 * M_PI_2 * p) * pow(2, 10 * (p - 1));
+  return std::sin(13.F * kPi2 * p) * std::pow(2.F, 10.F * (p - 1));  // NOLINT
 }
 
 // Modeled after the damped sine wave y = sin(-13pi/2*(x + 1))*pow(2, -10x) +
 // 1
 float ElasticOut(float p) {
-  return sin(-13 * M_PI_2 * (p + 1)) * pow(2, -10 * p) + 1;
+  return std::sin(-13.F * kPi2 * (p + 1)) * std::pow(2.F, -10.F * p) +
+         1;  // NOLINT
 }
 
 // Modeled after the piecewise exponentially-damped sine wave:
 // y = (1/2)*sin(13pi/2*(2*x))*pow(2, 10 * ((2*x) - 1))      ; [0,0.5)
 // y = (1/2)*(sin(-13pi/2*((2x-1)+1))*pow(2,-10(2*x-1)) + 2) ; [0.5, 1]
 float ElasticInOut(float p) {
-  if (p < 0.5) {
-    return 0.5 * sin(13 * M_PI_2 * (2 * p)) * pow(2, 10 * ((2 * p) - 1));
-  } else {
-    return 0.5 *
-           (sin(-13 * M_PI_2 * ((2 * p - 1) + 1)) * pow(2, -10 * (2 * p - 1)) +
-            2);
+  if (p < 0.5F) {                                             // NOLINT
+    return 0.5 * std::sin(13.F * kPi2 * (2 * p)) *              // NOLINT
+           std::pow(2, 10 * ((2 * p) - 1));                   // NOLINT
+  } else {                                                    // NOLINT
+    return 0.5 * (std::sin(-13.F * kPi2 * ((2 * p - 1) + 1)) *  // NOLINT
+                      std::pow(2, -10 * (2 * p - 1)) +        // NOLINT
+                  2);                                         // NOLINT
   }
 }
 
 // Modeled after the overshooting cubic y = x^3-x*sin(x*pi)
 float BackIn(float p) {
-  return p * p * p - p * sin(p * M_PI);
+  return p * p * p - p * std::sin(p * kPi);
 }
 
 // Modeled after overshooting cubic y = 1-((1-x)^3-(1-x)*sin((1-x)*pi))
 float BackOut(float p) {
   float f = (1 - p);
-  return 1 - (f * f * f - f * sin(f * M_PI));
+  return 1 - (f * f * f - f * std::sin(f * kPi));
 }
 
 // Modeled after the piecewise overshooting cubic function:
 // y = (1/2)*((2x)^3-(2x)*sin(2*x*pi))           ; [0, 0.5)
 // y = (1/2)*(1-((1-x)^3-(1-x)*sin((1-x)*pi))+1) ; [0.5, 1]
 float BackInOut(float p) {
-  if (p < 0.5) {
+  if (p < 0.5F) {  // NOLINT
     float f = 2 * p;
-    return 0.5 * (f * f * f - f * sin(f * M_PI));
+    return 0.5F * (f * f * f - f * std::sin(f * kPi));  // NOLINT
   } else {
-    float f = (1 - (2 * p - 1));
-    return 0.5 * (1 - (f * f * f - f * sin(f * M_PI))) + 0.5;
+    float f = (1 - (2 * p - 1));                                    // NOLINT
+    return 0.5F * (1 - (f * f * f - f * std::sin(f * kPi))) + 0.5;  // NOLINT
   }
 }
 
@@ -229,22 +236,23 @@ float BounceIn(float p) {
 }
 
 float BounceOut(float p) {
-  if (p < 4 / 11.0) {
-    return (121 * p * p) / 16.0;
-  } else if (p < 8 / 11.0) {
-    return (363 / 40.0 * p * p) - (99 / 10.0 * p) + 17 / 5.0;
-  } else if (p < 9 / 10.0) {
-    return (4356 / 361.0 * p * p) - (35442 / 1805.0 * p) + 16061 / 1805.0;
-  } else {
-    return (54 / 5.0 * p * p) - (513 / 25.0 * p) + 268 / 25.0;
+  if (p < 4 / 11.0) {                                           // NOLINT
+    return (121 * p * p) / 16.0;                                // NOLINT
+  } else if (p < 8 / 11.0) {                                    // NOLINT
+    return (363 / 40.0 * p * p) - (99 / 10.0 * p) + 17 / 5.0;   // NOLINT
+  } else if (p < 9 / 10.0) {                                    // NOLINT
+    return (4356 / 361.0 * p * p) - (35442 / 1805.0 * p) +      // NOLINT
+           16061 / 1805.0;                                      // NOLINT
+  } else {                                                      // NOLINT
+    return (54 / 5.0 * p * p) - (513 / 25.0 * p) + 268 / 25.0;  // NOLINT
   }
 }
 
-float BounceInOut(float p) {
-  if (p < 0.5) {
-    return 0.5 * BounceIn(p * 2);
-  } else {
-    return 0.5 * BounceOut(p * 2 - 1) + 0.5;
+float BounceInOut(float p) {                    // NOLINT
+  if (p < 0.5F) {                               // NOLINT
+    return 0.5F * BounceIn(p * 2);              // NOLINT
+  } else {                                      // NOLINT
+    return 0.5F * BounceOut(p * 2 - 1) + 0.5F;  // NOLINT
   }
 }
 
@@ -259,7 +267,7 @@ Animator::Animator(float* from,
       from_(*from),
       to_(to),
       duration_(duration),
-      easing_function_(easing_function),
+      easing_function_(std::move(easing_function)),
       current_(-delay) {
   RequestAnimationFrame();
 }
@@ -275,11 +283,11 @@ void Animator::OnAnimation(Params& params) {
   if (current_ <= Duration()) {
     *value_ = from_;
   } else {
-    *value_ = from_ + (to_ - from_) * easing_function_(current_ / duration_);
+    *value_ = from_ +
+              (to_ - from_) * easing_function_(current_ / duration_);  // NOLINT
   }
 
   RequestAnimationFrame();
 }
 
-}  // namespace animation
-}  // namespace ftxui
+}  // namespace ftxui::animation