#include "calculation.h"
#include "calculation_store.h"
#include "../shared/poincare_helpers.h"
#include <poincare/symbol.h>
#include <string.h>
#include <cmath>
#include <poincare/symbol.h>
#include <poincare/undefined.h>

using namespace Poincare;
using namespace Shared;

namespace Calculation {

Calculation::Calculation() :
  m_inputText(),
  m_exactOutputText(),
  m_approximateOutputText(),
  m_height(-1),
  m_equalSign(EqualSign::Unknown)
{
}

bool Calculation::operator==(const Calculation& c) {
  return strcmp(m_inputText, c.m_inputText) == 0
      && strcmp(m_approximateOutputText, c.m_approximateOutputText) == 0;
}

void Calculation::reset() {
  m_inputText[0] = 0;
  m_exactOutputText[0] = 0;
  m_approximateOutputText[0] = 0;
  tidy();
}

void Calculation::setContent(const char * c, Context * context, Expression ansExpression) {
  reset();
  Expression input = Expression::parse(c).replaceSymbolWithExpression(Symbol::k_ans, ansExpression);
  /* We do not store directly the text enter by the user because we do not want
   * to keep Ans symbol in the calculation store. */
  PoincareHelpers::Serialize(input, m_inputText, sizeof(m_inputText));
  Expression exactOutput = PoincareHelpers::ParseAndSimplify(m_inputText, *context);
  PoincareHelpers::Serialize(exactOutput, m_exactOutputText, sizeof(m_exactOutputText));
  Expression approximateOutput = PoincareHelpers::Approximate<double>(exactOutput, *context);
  PoincareHelpers::Serialize(approximateOutput, m_approximateOutputText, sizeof(m_approximateOutputText));
}

KDCoordinate Calculation::height(Context * context) {
  if (m_height < 0) {
    Layout inputLayout = createInputLayout();
    KDCoordinate inputHeight = inputLayout.layoutSize().height();
    Layout approximateLayout = createApproximateOutputLayout(context);
    KDCoordinate approximateOutputHeight = approximateLayout.layoutSize().height();
    if (shouldOnlyDisplayApproximateOutput(context)) {
      m_height = inputHeight+approximateOutputHeight;
    } else {
      Layout exactLayout = createExactOutputLayout();
      KDCoordinate exactOutputHeight = exactLayout.layoutSize().height();
      KDCoordinate outputHeight = max(exactLayout.baseline(), approximateLayout.baseline()) + max(exactOutputHeight-exactLayout.baseline(), approximateOutputHeight-approximateLayout.baseline());
      m_height = inputHeight + outputHeight;
    }
  }
  return m_height;
}

const char * Calculation::inputText() {
  return m_inputText;
}

const char * Calculation::exactOutputText() {
  return m_exactOutputText;
}

const char * Calculation::approximateOutputText() {
  return m_approximateOutputText;
}

Expression Calculation::input() {
  return Expression::parse(m_inputText);
}

Layout Calculation::createInputLayout() {
  return input().createLayout(Preferences::PrintFloatMode::Decimal, PrintFloat::k_numberOfStoredSignificantDigits);
}

bool Calculation::isEmpty() {
  /* To test if a calculation is empty, we need to test either m_inputText or
   * m_exactOutputText or m_approximateOutputText, the only three fields that
   * are not lazy-loaded. We choose m_exactOutputText to consider that a
   * calculation being added is still empty until the end of the method
   * 'setContent'. Indeed, during 'setContent' method, 'ans' evaluation calls
   * the evaluation of the last calculation only if the calculation being
   * filled is not taken into account.*/
  if (strlen(m_approximateOutputText) == 0) {
    return true;
  }
  return false;
}

void Calculation::tidy() {
  /* Uninitialized all Expression stored to free the Pool */
  m_height = -1;
  m_equalSign = EqualSign::Unknown;
}

Expression Calculation::exactOutput() {
  /* Because the angle unit might have changed, we do not simplify again. We
   * thereby avoid turning cos(Pi/4) into sqrt(2)/2 and displaying
   * 'sqrt(2)/2 = 0.999906' (which is totally wrong) instead of
   * 'cos(pi/4) = 0.999906' (which is true in degree). */
  Expression exactOutput = Expression::parse(m_exactOutputText);
  if (exactOutput.isUninitialized()) {
    return Undefined();
  }
  return exactOutput;
}

Layout Calculation::createExactOutputLayout() {
  return PoincareHelpers::CreateLayout(exactOutput());
}

Expression Calculation::approximateOutput(Context * context) {
  /* To ensure that the expression 'm_output' is a matrix or a complex, we
   * call 'evaluate'. */
  Expression exp = Expression::parse(m_approximateOutputText);
  return PoincareHelpers::Approximate<double>(exp, *context);
}

Layout Calculation::createApproximateOutputLayout(Context * context) {
  return PoincareHelpers::CreateLayout(approximateOutput(context));
}

bool Calculation::shouldOnlyDisplayApproximateOutput(Context * context) {
  if (strcmp(m_exactOutputText, m_approximateOutputText) == 0) {
    return true;
  }
  if (strcmp(m_exactOutputText, "undef") == 0) {
    return true;
  }
  return input().isApproximate(*context) || exactOutput().isApproximate(*context);
}

Calculation::EqualSign Calculation::exactAndApproximateDisplayedOutputsAreEqual(Poincare::Context * context) {
  if (m_equalSign != EqualSign::Unknown) {
    return m_equalSign;
  }
  char buffer[k_printedExpressionSize];
  Preferences * preferences = Preferences::sharedPreferences();
  Expression exactOutputExpression = Expression::ParseAndSimplify(m_exactOutputText, *context, preferences->angleUnit());
  if (exactOutputExpression.isUninitialized()) {
    exactOutputExpression = Undefined();
  }
  m_equalSign = exactOutputExpression.isEqualToItsApproximationLayout(approximateOutput(context), buffer, k_printedExpressionSize, preferences->angleUnit(), preferences->displayMode(), preferences->numberOfSignificantDigits(), *context) ? EqualSign::Equal : EqualSign::Approximation;
  return m_equalSign;
}

}