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#include <tools/assistant.h>

#include <tgl.h>
#include <tproperty.h>

#include <limits>
#include <cassert>

#ifdef MACOSX
const double line_width_scale = 1.5;
#else
const double line_width_scale = 1.0;
#endif

//************************************************************************
//    TGuideline implementation
//************************************************************************

void
TGuideline::drawSegment(
  const TPointD &p0,
  const TPointD &p1,
  double pixelSize,
  bool active,
  bool enabled ) const
{
  double colorBlack[4] = { 0.0, 0.0, 0.0, 0.25 };
  double colorWhite[4] = { 1.0, 1.0, 1.0, 0.25 };

  if (!this->enabled || !enabled)
    colorBlack[3] = (colorWhite[3] = 0.125);
  else if (active)
    colorBlack[3] = (colorWhite[3] = 0.5);

  glPushAttrib(GL_ALL_ATTRIB_BITS);
  tglEnableBlending();
  tglEnableLineSmooth(true, 1.0 * line_width_scale);
  TPointD d = p1 - p0;
  double k = norm2(d);
  if (k > TConsts::epsilon*TConsts::epsilon) {
    k = 0.5*pixelSize*line_width_scale/sqrt(k);
    d = TPointD(-k*d.y, k*d.x);
    glColor4dv(colorWhite);
    tglDrawSegment(p0 - d, p1 - d);
    glColor4dv(colorBlack);
    tglDrawSegment(p0 + d, p1 + d);
  }
  glPopAttrib();
}

//---------------------------------------------------------------------------------------------------

double
TGuideline::calcTrackWeight(const TTrack &track, const TAffine &toScreen, bool &outLongEnough) const {
  outLongEnough = false;
  if (!enabled || track.size() < 2)
    return std::numeric_limits<double>::infinity();

  const double snapLenght = 20.0;
  const double snapScale = 1.0;
  const double maxLength = 2.0*snapLenght*snapScale;

  double sumWeight = 0.0;
  double sumLength = 0.0;
  double sumDeviation = 0.0;

  TPointD prev = toScreen*track[0].position;
  for(int i = 1; i < track.size(); ++i) {
    const TTrackPoint &tp = track[i];
    TTrackPoint mid = TTrack::interpolationLinear(track[i-1], track[i], 0.5);
    TPointD p = toScreen*tp.position;
    double length = tdistance(p, prev);
    sumLength += length;

    double midStepLength = sumLength - 0.5*length;
    if (midStepLength > TConsts::epsilon) {
      double weight = length*logNormalDistribuitionUnscaled(midStepLength, snapLenght, snapScale);
      sumWeight += weight;

      TTrackPoint ntp = transformPoint(mid);
      double deviation = tdistance(toScreen*ntp.position, p);
      sumDeviation += weight*deviation;
    }
    prev = p;

    if (sumLength >= maxLength)
      { outLongEnough = true; break; }
  }
  return sumWeight > TConsts::epsilon
       ? sumDeviation/sumWeight
       : std::numeric_limits<double>::infinity();
}

//---------------------------------------------------------------------------------------------------

TGuidelineP
TGuideline::findBest(const TGuidelineList &guidelines, const TTrack &track, const TAffine &toScreen, bool &outLongEnough) {
  outLongEnough = true;
  double bestWeight = 0.0;
  TGuidelineP best;
  for(TGuidelineList::const_iterator i = guidelines.begin(); i != guidelines.end(); ++i) {
    double weight = (*i)->calcTrackWeight(track, toScreen, outLongEnough);
    if (!best || weight < bestWeight)
      { bestWeight = weight; best = *i; }
  }
  return best;
}


//************************************************************************
//    TAssistantPoint implementation
//************************************************************************

TAssistantPoint::TAssistantPoint(const TStringId &name, const TPointD &defPosition):
  name(name),
  defPosition(defPosition),
  type(Circle),
  position(defPosition),
  radius(10.0),
  visible(true),
  selected() { }


//************************************************************************
//    TAssistantType implementation
//************************************************************************

TMetaObjectHandler*
TAssistantType::createHandler(TMetaObject &obj) const
  { return createAssistant(obj); }


//************************************************************************
//    TAssistant implementation
//************************************************************************

TAssistant::TAssistant(TMetaObject &object):
  TMetaObjectHandler(object),
  m_idEnabled("enabled"),
  m_idPoints("points"),
  m_idX("x"),
  m_idY("y"),
  m_idMagnetism("magnetism"),
  m_basePoint()
{
  addProperty( new TBoolProperty(m_idEnabled.str(), getEnabled()) );
  addProperty( new TDoubleProperty(m_idMagnetism.str(), 0.0, 1.0, getMagnetism()) );
}

//---------------------------------------------------------------------------------------------------

TAssistantPoint&
TAssistant::addPoint(
  const TStringId &name,
  TAssistantPoint::Type type,
  const TPointD &defPosition,
  bool visible,
  double radius )
{
  assert(!m_points.count(name));
  TAssistantPoint &p = m_points.insert(
    TAssistantPointMap::value_type(name, TAssistantPoint(name, defPosition)) ).first->second;
  m_pointsOrder.push_back(&p);
  p.type     = type;
  p.radius   = radius;
  p.visible  = visible;
  if (!m_basePoint) m_basePoint = &p;
  return p;
}

//---------------------------------------------------------------------------------------------------

TAssistantPoint&
TAssistant::addPoint(
  const TStringId &name,
  TAssistantPoint::Type type,
  const TPointD &defPosition,
  bool visible )
    { return addPoint(name, type, defPosition, visible, 10.0); }

//---------------------------------------------------------------------------------------------------

const TAssistantPoint&
TAssistant::getBasePoint() const
  { assert(m_basePoint); return *m_basePoint; }

//---------------------------------------------------------------------------------------------------

void
TAssistant::addProperty(TProperty *p)
  { m_properties.add(p); }

//---------------------------------------------------------------------------------------------------

void
TAssistant::setTranslation(const TStringId &name, const QString &localName) const
  { m_properties.getProperty(name)->setQStringName( localName ); }

//---------------------------------------------------------------------------------------------------

void
TAssistant::updateTranslation() const {
  setTranslation(m_idEnabled, tr("Enabled"));
  setTranslation(m_idMagnetism, tr("Magnetism"));
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::onSetDefaults() {
  setEnabled(true);
  setMagnetism(1.0);
  for(TAssistantPointMap::iterator i = m_points.begin(); i != m_points.end(); ++i)
    i->second.position = i->second.defPosition;
  fixPoints();
  fixData();
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::fixPoints()
  { onFixPoints(); }

//---------------------------------------------------------------------------------------------------

bool
TAssistant::move(const TPointD &position) {
  TPointD d = position - getBasePoint().position;
  if (d != TPointD()) {
    for(TAssistantPointMap::iterator i = m_points.begin(); i != m_points.end(); ++i)
      i->second.position += d;
    fixPoints();
    return true;
  }
  return false;
}

//---------------------------------------------------------------------------------------------------

bool
TAssistant::movePoint(const TStringId &name, const TPointD &position) {
  TAssistantPointMap::iterator i = m_points.find(name);
  if (i != m_points.end() && i->second.position != position) {
    onMovePoint(i->second, position);
    return true;
  }
  return false;
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::setPointSelection(const TStringId &name, bool selected)  const {
  if (const TAssistantPoint *p = findPoint(name))
    p->selected = selected;
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::setAllPointsSelection(bool selected) const {
  for(TAssistantPointMap::const_iterator i = points().begin(); i != points().end(); ++i)
    i->second.selected = selected;
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::onDataChanged(const TVariant &value) {
  const TVariant& pointsData = data()[m_idPoints];
  TVariantPathEntry entry;

  if (&value == &data() || &value == &pointsData)
    onAllDataChanged();
  else
  if (pointsData.getChildPathEntry(value, entry) && entry.isField()) {
    const TVariant& pointData = pointsData[entry];
    TPointD position = TPointD(
      pointData[m_idX].getDouble(),
      pointData[m_idY].getDouble() );
    movePoint(entry.field(), position);
  } else
  if (data().getChildPathEntry(value, entry) && entry.isField()) {
    onDataFieldChanged(entry.field(), data()[entry.field()]);
  }
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::onDataFieldChanged(const TStringId &name, const TVariant &value) {
  updateProperty(name, value);
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::onAllDataChanged() {
  const TVariant& pointsData = data()[m_idPoints];
  for(TAssistantPointMap::iterator i = m_points.begin(); i != m_points.end(); ++i) {
    const TVariant& pointData = pointsData[i->first];
    i->second.position = TPointD(
      pointData[m_idX].getDouble(),
      pointData[m_idY].getDouble() );
  }
  fixPoints();
  updateProperties();
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::onFixPoints()
  { }

//---------------------------------------------------------------------------------------------------

void
TAssistant::onMovePoint(TAssistantPoint &point, const TPointD &position)
  { point.position = position; }

//---------------------------------------------------------------------------------------------------

void
TAssistant::onFixData() {
  TVariant& pointsData = data()[m_idPoints];
  for(TAssistantPointMap::const_iterator i = points().begin(); i != points().end(); ++i) {
    TVariant& pointData = pointsData[i->first];
    pointData[m_idX].setDouble( i->second.position.x );
    pointData[m_idY].setDouble( i->second.position.y );
  }
  setMagnetism( std::max(0.0, std::min(1.0, getMagnetism())) );
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::updateProperties() {
  const TVariantMap &map = data().getMap();
  for(TVariantMap::const_iterator i = map.begin(); i != map.end(); ++i)
    if (i->first != m_idPoints)
      updateProperty(i->first, i->second);
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::updateProperty(const TStringId &name, const TVariant &value) {
  TProperty *property = m_properties.getProperty(name);
  if (!property)
    return;

  if (TBoolProperty *boolProperty = dynamic_cast<TBoolProperty*>(property)) {
    boolProperty->setValue( value.getBool() );
  } else
  if (TDoubleProperty *doubleProperty = dynamic_cast<TDoubleProperty*>(property)) {
    doubleProperty->setValue( value.getDouble() );
  } else
  if (TStringProperty *stringProperty = dynamic_cast<TStringProperty*>(property)) {
    stringProperty->setValue( to_wstring(value.getString()) );
  } else
  if (TEnumProperty *enumProperty = dynamic_cast<TEnumProperty*>(property)) {
    enumProperty->setValue( to_wstring(value.getString()) );
  }
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::onPropertyChanged(const TStringId &name) {
  TProperty *property = m_properties.getProperty(name);
  if (!property)
    return;

  if (name == m_idPoints)
    return;

  if (TBoolProperty *boolProperty = dynamic_cast<TBoolProperty*>(property)) {
    data()[name].setBool( boolProperty->getValue() );
  } else
  if (TDoubleProperty *doubleProperty = dynamic_cast<TDoubleProperty*>(property)) {
    data()[name].setDouble( doubleProperty->getValue() );
  } else
  if (TStringProperty *stringProperty = dynamic_cast<TStringProperty*>(property)) {
    data()[name].setString( to_string(stringProperty->getValue()) );
  } else
  if (TEnumProperty *enumProperty = dynamic_cast<TEnumProperty*>(property)) {
    data()[name].setString( to_string(enumProperty->getValue()) );
  }
}

//---------------------------------------------------------------------------------------------------

double
TAssistant::getDrawingAlpha(bool enabled) const
  { return enabled && this->getEnabled() ? 0.5 : 0.25; }

//---------------------------------------------------------------------------------------------------

double
TAssistant::getDrawingGridAlpha() const
  { return 0.2; }

//---------------------------------------------------------------------------------------------------

void
TAssistant::drawSegment(const TPointD &p0, const TPointD &p1, double pixelSize, double alpha) const {
  double colorBlack[4] = { 0.0, 0.0, 0.0, alpha };
  double colorWhite[4] = { 1.0, 1.0, 1.0, alpha };

  glPushAttrib(GL_ALL_ATTRIB_BITS);
  tglEnableBlending();
  tglEnableLineSmooth(true, 1.0 * line_width_scale);
  TPointD d = p1 - p0;
  double k = norm2(d);
  if (k > TConsts::epsilon*TConsts::epsilon) {
    k = 0.5*pixelSize*line_width_scale/sqrt(k);
    d = TPointD(-k*d.y, k*d.x);
    glColor4dv(colorWhite);
    tglDrawSegment(p0 - d, p1 - d);
    glColor4dv(colorBlack);
    tglDrawSegment(p0 + d, p1 + d);
  }
  glPopAttrib();
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::drawDot(const TPointD &p, double alpha) const {
  double colorBlack[4] = { 0.0, 0.0, 0.0, alpha };
  double colorWhite[4] = { 1.0, 1.0, 1.0, alpha };

  glPushAttrib(GL_ALL_ATTRIB_BITS);
  tglEnableBlending();

  glColor4dv(colorWhite);
  tglEnablePointSmooth(6.0);
  glBegin(GL_POINTS);
  glVertex2d(p.x, p.y);
  glEnd();

  glColor4dv(colorBlack);
  tglEnablePointSmooth(3.0);
  glBegin(GL_POINTS);
  glVertex2d(p.x, p.y);
  glEnd();

  glPopAttrib();
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::drawPoint(const TAssistantPoint &point, double pixelSize) const {
  if (!point.visible) return;

  double radius = point.radius;
  double crossSize = 1.2*radius;

  double alpha = 0.5;
  double colorBlack[4] = { 0.0, 0.0, 0.0, alpha };
  double colorGray[4]  = { 0.5, 0.5, 0.5, alpha };
  double colorWhite[4] = { 1.0, 1.0, 1.0, alpha };
  double width = 1.5;

  if (point.selected) {
    colorBlack[2] = 1.0;
    colorGray[2] = 1.0;
    width = 2.0;
  }

  glPushAttrib(GL_ALL_ATTRIB_BITS);

  // fill
  tglEnableBlending();
  if (point.type == TAssistantPoint::CircleFill) {
    glColor4dv(colorGray);
    tglDrawDisk(point.position, radius*pixelSize);
  }

  TPointD crossDx(pixelSize*crossSize, 0.0);
  TPointD crossDy(0.0, pixelSize*crossSize);
  TPointD gridDx(pixelSize*radius, 0.0);
  TPointD gridDy(0.0, pixelSize*radius);

  // back line
  tglEnableLineSmooth(true, 2.0*width*line_width_scale);
  glColor4dv(colorWhite);
  if (point.type == TAssistantPoint::CircleCross) {
    tglDrawSegment(point.position - crossDx, point.position + crossDx);
    tglDrawSegment(point.position - crossDy, point.position + crossDy);
  }
  tglDrawCircle(point.position, radius*pixelSize);

  // front line
  glLineWidth(width * line_width_scale);
  glColor4dv(colorBlack);
  if (point.type == TAssistantPoint::CircleCross) {
    tglDrawSegment(point.position - crossDx, point.position + crossDx);
    tglDrawSegment(point.position - crossDy, point.position + crossDy);
  }
  tglDrawCircle(point.position, radius*pixelSize);

  // dots
  switch(point.type) {
  case TAssistantPoint::CircleDoubleDots:
    drawDot(point.position - gridDx*0.5, alpha);
    drawDot(point.position + gridDx*0.5, alpha);
    drawDot(point.position - gridDy*0.5, alpha);
    drawDot(point.position + gridDy*0.5, alpha);
    //no break
  case TAssistantPoint::CircleDots:
    drawDot(point.position - gridDx, alpha);
    drawDot(point.position + gridDx, alpha);
    drawDot(point.position - gridDy, alpha);
    drawDot(point.position + gridDy, alpha);
    //no break
  case TAssistantPoint::Circle:
    drawDot(point.position, alpha);
    break;
  default:
    break;
  }

  glPopAttrib();
}

//---------------------------------------------------------------------------------------------------

void
TAssistant::getGuidelines(const TPointD &position, const TAffine &toTool, TGuidelineList &outGuidelines) const
  { }

//---------------------------------------------------------------------------------------------------

void
TAssistant::draw(TToolViewer *viewer, bool enabled) const
  { }

//---------------------------------------------------------------------------------------------------

void
TAssistant::drawEdit(TToolViewer *viewer) const {
  // paint all points
  draw(viewer);
  double pixelSize = sqrt(tglGetPixelSize2());
  for(TAssistantPointMap::const_iterator i = points().begin(); i != points().end(); ++i)
    drawPoint(i->second, pixelSize);
}

//---------------------------------------------------------------------------------------------------

bool
TAssistant::calcPerspectiveStep(
  double minStep,
  double minX,
  double maxX,
  double x0,
  double x1,
  double x2,
  double &outK,
  double &outMin,
  double &outMax )
{
  outK = outMin = outMax = 0.0;

  double dx1 = x1 - x0;
  double dx2 = x2 - x0;
  if (fabs(dx1) <= TConsts::epsilon) return false;
  if (fabs(dx2) <= TConsts::epsilon) return false;
  if ((dx1 < 0.0) != (dx2 < 0.0)) dx2 = -dx2;
  if (fabs(dx2 - dx1) <= minStep) return false;
  if (fabs(dx2) < fabs(dx1)) std::swap(dx1, dx2);

  if (x0 <= minX + TConsts::epsilon && dx1 < 0.0) return false;
  if (x0 >= maxX - TConsts::epsilon && dx1 > 0.0) return false;

  outK = dx2/dx1;
  double minI = log(minStep/fabs(dx1*(1.0 - 1.0/outK)))/log(outK);
  outMin = dx1*pow(outK, floor(minI - TConsts::epsilon));
  if (fabs(outMin) < TConsts::epsilon) return false;
  outMax = (dx1 > 0.0 ? maxX : minX) - x0;
  return true;
}