/***************************************************************************
 *   Copyright (C) 2004-2005 by David Saxton                               *
 *   david@bluehaze.org                                                    *
 *                                                                         *
 *   This program is free software; you can redistribute it and/or modify  *
 *   it under the terms of the GNU General Public License as published by  *
 *   the Free Software Foundation; either version 2 of the License, or     *
 *   (at your option) any later version.                                   *
 ***************************************************************************/

#include "itemdocumentdata.h"
#include "mechanicsitem.h"
#include "mechanicsdocument.h"

#include <kdebug.h>
#include <tdelocale.h>
#include <tqbitarray.h>
#include <tqpainter.h>
#include <tqwmatrix.h>
#include <cmath>

/**
@returns an angle between 0 and 2 pi
*/
double normalizeAngle( double angle )
{
	if ( angle < 0 )
		angle += 6.2832*(std::ceil(-angle));
	
	return angle - 6.2832*std::floor(angle/6.2832);
}

MechanicsItem::MechanicsItem( MechanicsDocument *mechanicsDocument, bool newItem, const TQString &id )
	: Item( mechanicsDocument, newItem, id )
{
	p_mechanicsDocument = mechanicsDocument;
	m_selectionMode = MechanicsItem::sm_move;
	
	createProperty( "mass", Variant::Type::Double );
	property("mass")->setCaption( i18n("Mass") );
	property("mass")->setUnit("g");
	property("mass")->setValue(10.0);
	property("mass")->setMinValue(1e-3);
	property("mass")->setMaxValue(1e12);
	property("mass")->setAdvanced(true);
	
	createProperty( "moi", Variant::Type::Double );
	property("moi")->setCaption( i18n("Moment of Inertia") );
	property("moi")->setUnit("gm");
	property("moi")->setValue(0.01);
	property("moi")->setMinValue(1e-3);
	property("moi")->setMaxValue(1e12);
	property("moi")->setAdvanced(true);
	
	setZ(ItemDocument::Z::Item);
	setAnimated(true);
	p_mechanicsDocument->registerItem(this);
}


MechanicsItem::~MechanicsItem()
{
}


int MechanicsItem::rtti() const
{
	return ItemDocument::RTTI::MechanicsItem;
}


void MechanicsItem::setSelectionMode( SelectionMode sm )
{
	if ( sm == m_selectionMode )
		return;
	
	m_selectionMode = sm;
}


void MechanicsItem::setSelected( bool yes )
{
	if ( yes == isSelected() )
		return;
	
	if (!yes)
		// Reset the selection mode
		m_selectionMode = MechanicsItem::sm_resize;
	
	Item::setSelected(yes);
}


void MechanicsItem::dataChanged()
{
	Item::dataChanged();
	m_mechanicsInfo.mass = dataDouble("mass");
	m_mechanicsInfo.momentOfInertia = dataDouble("moi");
	updateMechanicsInfoCombined();
}


PositionInfo MechanicsItem::absolutePosition() const
{
	MechanicsItem *parentMechItem = dynamic_cast<MechanicsItem*>((Item*)(p_parentItem));
	if (parentMechItem)
		return parentMechItem->absolutePosition() + m_relativePosition;
	
	return m_relativePosition;
}


void MechanicsItem::reparented( Item *oldItem, Item *newItem )
{
	MechanicsItem *oldMechItem = dynamic_cast<MechanicsItem*>(oldItem);
	MechanicsItem *newMechItem = dynamic_cast<MechanicsItem*>(newItem);
	
	if (oldMechItem)
	{
		m_relativePosition = oldMechItem->absolutePosition() + m_relativePosition;
		disconnect( oldMechItem, TQT_SIGNAL(moved()), this, TQT_SLOT(parentMoved()) );
	}
	
	if (newMechItem)
	{
		m_relativePosition = m_relativePosition - newMechItem->absolutePosition();
		connect( newMechItem, TQT_SIGNAL(moved()), this, TQT_SLOT(parentMoved()) );
	}
	
	updateCanvasPoints();
}


void MechanicsItem::childAdded( Item *child )
{
	MechanicsItem *mechItem = dynamic_cast<MechanicsItem*>(child);
	if (!mechItem)
		return;
	
	connect( mechItem, TQT_SIGNAL(updateMechanicsInfoCombined()), this, TQT_SLOT(childMoved()) );
	updateMechanicsInfoCombined();
}


void MechanicsItem::childRemoved( Item *child )
{
	MechanicsItem *mechItem = dynamic_cast<MechanicsItem*>(child);
	if (!mechItem)
		return;
	
	disconnect( mechItem, TQT_SIGNAL(updateMechanicsInfoCombined()), this, TQT_SLOT(childMoved()) );
	updateMechanicsInfoCombined();
}


void MechanicsItem::parentMoved()
{
	PositionInfo absPos = absolutePosition();
	Item::moveBy( absPos.x() - x(), absPos.y() - y() );
	updateCanvasPoints();
	emit moved();
}


void MechanicsItem::updateCanvasPoints()
{
	const TQRect ipbr = m_itemPoints.boundingRect();
	
	double scalex = double(m_sizeRect.width()) / double(ipbr.width());
	double scaley = double(m_sizeRect.height()) / double(ipbr.height());
	
	PositionInfo abs = absolutePosition();
	
	TQWMatrix m;
	m.rotate(abs.angle()*57.29577951308232);
	m.translate( m_sizeRect.left(), m_sizeRect.top() );
	m.scale( scalex, scaley );
	m.translate( -int(ipbr.left()), -int(ipbr.top()) );
	setPoints( m.map(m_itemPoints) );
	
	TQRect tempt = m.mapRect(ipbr);
}


void MechanicsItem::rotateBy( double dtheta )
{
	m_relativePosition.rotate(dtheta);
	updateCanvasPoints();
	updateMechanicsInfoCombined();
	emit moved();
}


void MechanicsItem::moveBy( double dx, double dy )
{
	m_relativePosition.translate( dx, dy );
	Item::moveBy( m_relativePosition.x() - x(), m_relativePosition.y() - y() );
	emit moved();
}


void MechanicsItem::updateMechanicsInfoCombined()
{
	m_mechanicsInfoCombined = m_mechanicsInfo;
	
	double mass_x = 0.;
	double mass_y = 0.;
	
	const ItemList::const_iterator end = m_children.end();
	for ( ItemList::const_iterator it = m_children.begin(); it != end; ++it )
	{
		MechanicsItem *child = dynamic_cast<MechanicsItem*>((Item*)*it);
		if (child)
		{
			CombinedMechanicsInfo *childInfo = child->mechanicsInfoCombined();
			const PositionInfo relativeChildPosition = child->relativePosition();
			
			double mass = childInfo->mass;
// 			double angle = relativeChildPosition.angle();
			double dx = relativeChildPosition.x() /*+ cos(angle)*childInfo->m_x - sin(angle)*childInfo->m_y*/;
			double dy = relativeChildPosition.y() /*+ sin(angle)*childInfo->m_x + cos(angle)*childInfo->m_y*/;
			
			m_mechanicsInfoCombined.mass += mass;
			mass_x += mass * dx;
			mass_y += mass * dy;
			
			double length_squared = dx*dx + dy*dy;
			m_mechanicsInfoCombined.momentOfInertia += length_squared * childInfo->momentOfInertia;
		}
	}
	
	m_mechanicsInfoCombined.x = mass_x / m_mechanicsInfoCombined.mass;
	m_mechanicsInfoCombined.y = mass_y / m_mechanicsInfoCombined.mass;
}


ItemData MechanicsItem::itemData() const
{
	ItemData itemData = Item::itemData();
	itemData.angleDegrees = m_relativePosition.angle()*57.29577951308232;
	return itemData;
}


bool MechanicsItem::mousePressEvent( const EventInfo &eventInfo )
{
	Q_UNUSED(eventInfo);
	return false;
}


bool MechanicsItem::mouseReleaseEvent( const EventInfo &eventInfo )
{
	Q_UNUSED(eventInfo);
	return false;
}


bool MechanicsItem::mouseDoubleClickEvent( const EventInfo &eventInfo )
{
	Q_UNUSED(eventInfo);
	return false;
}


bool MechanicsItem::mouseMoveEvent( const EventInfo &eventInfo )
{
	Q_UNUSED(eventInfo);
	return false;
}


bool MechanicsItem::wheelEvent( const EventInfo &eventInfo )
{
	Q_UNUSED(eventInfo);
	return false;
}


void MechanicsItem::enterEvent()
{
}


void MechanicsItem::leaveEvent()
{
}


TQRect MechanicsItem::maxInnerRectangle( const TQRect &outerRect ) const
{
	TQRect normalizedOuterRect = outerRect.normalize();
	const double LEFT = normalizedOuterRect.left();
	const double TOP = normalizedOuterRect.top();
	const double X = normalizedOuterRect.width();
	const double Y = normalizedOuterRect.height();
	const double a = normalizeAngle(absolutePosition().angle());
	
	double left;
	double top;
	double width;
	double height;
	
// 	if ( can change width/height ratio )
	{
		double x1 = X*std::cos(a) - Y*std::sin(a);
		double y1 = X*std::sin(a) + Y*std::cos(a);
		double x2 = X*std::cos(a);
		double y2 = X*std::sin(a);
		double x3 = -Y*std::sin(a);
		double y3 = Y*std::cos(a);
		
		double xbig;/* = std::max( std::abs(x2-x3), std::abs(x1) );*/
		double ybig;/* = std::max( std::abs(y2-y3), std::abs(y1) );*/
		if ( (a - floor(a/6.2832)*6.2832) < 3.1416 )
		{
			xbig = std::abs(x3-x2);
			ybig = std::abs(y1);
		}
		else
		{
			xbig = std::abs(x1);
			ybig = std::abs(y3-y2);
		}
		
		width = X*(X/xbig);
		height = Y*(Y/ybig);
		
		top = -std::sin(a) * (LEFT + width*std::sin(a)) + std::cos(a)*TOP;
		left = std::cos(a) * (LEFT + width*std::sin(a)) + std::sin(a)*TOP;
	}
	
	return TQRect( int(left), int(top), int(width), int(height) );
}


void MechanicsItem::initPainter( TQPainter &p )
{
       PositionInfo absPos = absolutePosition();
       p.translate( absPos.x(), absPos.y() );
       // 57.29577951308232 is the number of degrees per radian.
       p.rotate( absPos.angle()*57.29577951308232 );
       p.translate( -absPos.x(), -absPos.y() );
}


void MechanicsItem::deinitPainter( TQPainter &p )
{
       PositionInfo absPos = absolutePosition();
       p.translate( absPos.x(), absPos.y() );
       // 57.29577951308232 is the number of degrees per radian.
       p.rotate( -absPos.angle()*57.29577951308232 );
       p.translate( -absPos.x(), -absPos.y() );
}





PositionInfo::PositionInfo()
{
	reset();
}


const PositionInfo PositionInfo::operator+( const PositionInfo &info )
{
	// Copy the child to a new position
	PositionInfo newInfo = info;
	
	// Translate the newInfo by our translation amount
	newInfo.translate( x(), y() );
	
	// Rotate the child about us
	newInfo.rotateAboutPoint( x(), y(), angle() );
	
	return newInfo;
}


const PositionInfo PositionInfo::operator-( const PositionInfo &info )
{

	PositionInfo newInfo = *this;
	
	newInfo.translate( -info.x(), -info.y() );
	newInfo.rotate( -info.angle() );
	
	return newInfo;
}


void PositionInfo::rotateAboutPoint( double x, double y, double angle )
{
	m_angle += angle;
	
	double newx = x + (m_x-x)*std::cos(angle) - (m_y-y)*std::sin(angle);
	double newy = y + (m_x-x)*std::sin(angle) + (m_y-y)*std::cos(angle);
	
	m_x = newx;
	m_y = newy;
}


void PositionInfo::reset()
{
	m_x = 0.;
	m_y = 0.;
	m_angle = 0.;
}



MechanicsInfo::MechanicsInfo()
{
	mass = 0.;
	momentOfInertia = 0.;
}
CombinedMechanicsInfo::CombinedMechanicsInfo()
	: MechanicsInfo()
{
	x = 0.;
	y = 0.;
}
CombinedMechanicsInfo::CombinedMechanicsInfo( const MechanicsInfo &info )
	: MechanicsInfo(info)
{
	x = 0.;
	y = 0.;
}


#include "mechanicsitem.moc"