#include #include #include #include "layout/nth_root_layout.h" extern "C" { #include } #include #include namespace Poincare { Expression::Type SquareRoot::type() const { return Type::SquareRoot; } Expression * SquareRoot::clone() const { SquareRoot * a = new SquareRoot(m_operands, true); return a; } static_assert('\x91' == Ion::Charset::Root, "Unicode error"); int SquareRoot::writeTextInBuffer(char * buffer, int bufferSize, PrintFloat::Mode floatDisplayMode, int numberOfSignificantDigits) const { return LayoutEngine::writePrefixExpressionTextInBuffer(this, buffer, bufferSize, floatDisplayMode, numberOfSignificantDigits, "\x91"); } template std::complex SquareRoot::computeOnComplex(const std::complex c, AngleUnit angleUnit) { std::complex result = std::sqrt(c); /* Openbsd trigonometric functions are numerical implementation and thus are * approximative. * The error epsilon is ~1E-7 on float and ~1E-15 on double. In order to * avoid weird results as sqrt(-1) = 6E-16+i, we compute the argument of * the result of sqrt(c) and if arg ~ 0 [Pi], we discard the residual imaginary * part and if arg ~ Pi/2 [Pi], we discard the residual real part. */ return ApproximationEngine::truncateRealOrImaginaryPartAccordingToArgument(result); } Expression * SquareRoot::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 Power * p = new Power(operand(0), new Rational(1, 2), false); detachOperands(); replaceWith(p, true); return p->shallowReduce(context, angleUnit); } ExpressionLayout * SquareRoot::createLayout(PrintFloat::Mode floatDisplayMode, int numberOfSignificantDigits) const { return new NthRootLayout(operand(0)->createLayout(floatDisplayMode, numberOfSignificantDigits), false); } }