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#include <poincare/sequence.h>
#include <poincare/symbol.h>
#include <poincare/complex.h>
#include <poincare/variable_context.h>
#include <poincare/undefined.h>
#include "layout/string_layout.h"
#include "layout/horizontal_layout.h"
extern "C" {
#include <assert.h>
#include <stdlib.h>
}
#include <cmath>
namespace Poincare {
ExpressionLayout * Sequence::privateCreateLayout(FloatDisplayMode floatDisplayMode, ComplexFormat complexFormat) const {
assert(floatDisplayMode != FloatDisplayMode::Default);
assert(complexFormat != ComplexFormat::Default);
ExpressionLayout * childrenLayouts[2];
childrenLayouts[0] = new StringLayout("n=", 2);
childrenLayouts[1] = operand(1)->createLayout(floatDisplayMode, complexFormat);
return createSequenceLayoutWithArgumentLayouts(new HorizontalLayout(childrenLayouts, 2), operand(2)->createLayout(floatDisplayMode, complexFormat), operand(0)->createLayout(floatDisplayMode, complexFormat));
}
template<typename T>
Expression * Sequence::templatedApproximate(Context& context, AngleUnit angleUnit) const {
Expression * aInput = operand(1)->approximate<T>(context, angleUnit);
Expression * bInput = operand(2)->approximate<T>(context, angleUnit);
T start = aInput->type() == Type::Complex ? static_cast<Complex<T> *>(aInput)->toScalar() : NAN;
T end = bInput->type() == Type::Complex ? static_cast<Complex<T> *>(bInput)->toScalar() : NAN;
delete aInput;
delete bInput;
if (std::isnan(start) || std::isnan(end) || start != (int)start || end != (int)end || end - start > k_maxNumberOfSteps) {
return new Complex<T>(Complex<T>::Float(NAN));
}
VariableContext<T> nContext = VariableContext<T>('n', &context);
Symbol nSymbol('n');
Expression * result = new Complex<T>(Complex<T>::Float(emptySequenceValue()));
for (int i = (int)start; i <= (int)end; i++) {
if (shouldStopProcessing()) {
delete result;
return new Complex<T>(Complex<T>::Float(NAN));
}
Complex<T> iExpression = Complex<T>::Float(i);
nContext.setExpressionForSymbolName(&iExpression, &nSymbol, nContext);
Expression * expression = operand(0)->approximate<T>(nContext, angleUnit);
Expression * newResult = evaluateWithNextTerm(T(), result, expression);
delete result;
delete expression;
result = newResult;
}
return result;
}
}
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