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#include <poincare/arc_tangent.h>
#include <poincare/trigonometry.h>
#include <poincare/simplification_engine.h>
extern "C" {
#include <assert.h>
}
#include <cmath>
namespace Poincare {
Expression::Type ArcTangent::type() const {
return Type::ArcTangent;
}
Expression * ArcTangent::clone() const {
ArcTangent * a = new ArcTangent(m_operands, true);
return a;
}
Expression * ArcTangent::shallowReduce(Context& context, AngleUnit angleUnit) {
Expression * e = Expression::shallowReduce(context, angleUnit);
if (e != this) {
return e;
}
#if MATRIX_EXACT_REDUCING
if (operand(0)->type() == Type::Matrix) {
return SimplificationEngine::map(this, context, angleUnit);
}
#endif
return Trigonometry::shallowReduceInverseFunction(this, context, angleUnit);
}
template<typename T>
std::complex<T> ArcTangent::computeOnComplex(const std::complex<T> c, AngleUnit angleUnit) {
std::complex<T> result = std::atan(c);
/* atan has a branch cut on ]-inf*i, -i[U]i, +inf*i[: it is then multivalued
* on this cut. We followed the convention chosen by the lib c++ of llvm on
* ]-i+0, -i*inf+0[ (warning: atan takes the other side of the cut values on
* ]-i+0, -i*inf+0[) and choose the values on ]-inf*i, -i[ to comply with
* atan(-x) = -atan(x) and sin(arctan(x)) = x/sqrt(1+x^2). */
if (c.real() == 0 && c.imag() < -1) {
result.real(-result.real()); // other side of the cut
}
result = Trigonometry::RoundToMeaningfulDigits(result);
return Trigonometry::ConvertRadianToAngleUnit(result, angleUnit);
}
}
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