#include <poincare/sine.h>
  #include <poincare/trigonometry.h>
  #include <poincare/hyperbolic_sine.h>
  #include <poincare/complex.h>
  #include <poincare/multiplication.h>
  #include <poincare/symbol.h>
  #include <poincare/simplification_engine.h>
  #include <ion.h>
  extern "C" {
  #include <assert.h>
  }
  #include <cmath>
  
  namespace Poincare {
  
  Expression::Type Sine::type() const {
    return Expression::Type::Sine;
  }
  
  Expression * Sine::clone() const {
    Sine * a = new Sine(m_operands, true);
    return a;
  }
  
  Expression * Sine::shallowReduce(Context& context, AngleUnit angleUnit) {
    Expression * e = Expression::shallowReduce(context, angleUnit);
    if (e != this) {
      return e;
    }
  #if MATRIX_EXACT_REDUCING
    Expression * op = editableOperand(0);
    if (op->type() == Type::Matrix) {
      return SimplificationEngine::map(this, context, angleUnit);
    }
  #endif
    return Trigonometry::shallowReduceDirectFunction(this, context, angleUnit);
  }
  
  template<typename T>
  Complex<T> Sine::computeOnComplex(const Complex<T> c, AngleUnit angleUnit) {
    if (c.b() == 0) {
      T input = c.a();
      if (angleUnit == AngleUnit::Degree) {
        input *= M_PI/180;
      }
      T result = std::sin(input);
      /* Cheat: see comment in cosine.cpp
       * We cheat to avoid returning sin(Pi) = epsilon */
      if (input !=  0 && std::fabs(result/input) <= epsilon<T>()) {
        return Complex<T>::Float(0);
      }
      return Complex<T>::Float(result);
    }
    Complex<T> arg = Complex<T>::Cartesian(-c.b(), c.a());
    Complex<T> sinh = HyperbolicSine::computeOnComplex(arg, angleUnit);
    return Multiplication::compute(Complex<T>::Cartesian(0, -1), sinh);
  }
  
  }