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epsilon-master/poincare/src/division_remainder.cpp 2.2 KB
6663b6c9   adorian   projet complet av...
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  #include <poincare/division_remainder.h>
  #include <poincare/rational.h>
  #include <poincare/undefined.h>
  
  extern "C" {
  #include <assert.h>
  }
  #include <cmath>
  
  namespace Poincare {
  
  Expression::Type DivisionRemainder::type() const {
    return Type::DivisionRemainder;
  }
  
  Expression * DivisionRemainder::clone() const {
    DivisionRemainder * a = new DivisionRemainder(m_operands, true);
    return a;
  }
  
  Expression * DivisionRemainder::shallowReduce(Context& context, AngleUnit angleUnit) {
    Expression * e = Expression::shallowReduce(context, angleUnit);
    if (e != this) {
      return e;
    }
    Expression * op0 = editableOperand(0);
    Expression * op1 = editableOperand(1);
  #if MATRIX_EXACT_REDUCING
    if (op0->type() == Type::Matrix || op1->type() == Type::Matrix) {
      return replaceWith(new Undefined(), true);
    }
  #endif
    if (op0->type() == Type::Rational) {
      Rational * r0 = static_cast<Rational *>(op0);
      if (!r0->denominator().isOne()) {
        return replaceWith(new Undefined(), true);
      }
    }
    if (op1->type() == Type::Rational) {
      Rational * r1 = static_cast<Rational *>(op1);
      if (!r1->denominator().isOne()) {
        return replaceWith(new Undefined(), true);
      }
    }
    if (op0->type() != Type::Rational || op1->type() != Type::Rational) {
      return this;
    }
    Rational * r0 = static_cast<Rational *>(op0);
    Rational * r1 = static_cast<Rational *>(op1);
  
    Integer a = r0->numerator();
    Integer b = r1->numerator();
    if (b.isZero()) {
      return replaceWith(new Undefined(), true); // TODO: new Infinite(a.isNegative())
    }
    Integer result = Integer::Division(a, b).remainder;
    return replaceWith(new Rational(result), true);
  }
  
  template<typename T>
  Complex<T> * DivisionRemainder::templatedApproximate(Context& context, AngleUnit angleUnit) const {
    Evaluation<T> * f1Input = operand(0)->privateApproximate(T(), context, angleUnit);
    Evaluation<T> * f2Input = operand(1)->privateApproximate(T(), context, angleUnit);
    T f1 = f1Input->toScalar();
    T f2 = f2Input->toScalar();
    delete f1Input;
    delete f2Input;
    if (std::isnan(f1) || std::isnan(f2) || f1 != (int)f1 || f2 != (int)f2) {
      return new Complex<T>(Complex<T>::Undefined());
    }
    return new Complex<T>(std::round(f1-f2*std::floor(f1/f2)));
  }
  
  }