Merge branch 'optional_q3map2_type' into 'master'

[xonotic/netradiant.git] / libs / entitylib.h

/*
   Copyright (C) 2001-2006, William Joseph.
   All Rights Reserved.

   This file is part of GtkRadiant.

   GtkRadiant 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.

   GtkRadiant is distributed in the hope that it will be useful,
   but WITHOUT ANY WARRANTY; without even the implied warranty of
   MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE.  See the
   GNU General Public License for more details.

   You should have received a copy of the GNU General Public License
   along with GtkRadiant; if not, write to the Free Software
   Foundation, Inc., 51 Franklin St, Fifth Floor, Boston, MA  02110-1301  USA
 */

#if !defined ( INCLUDED_ENTITYLIB_H )
#define INCLUDED_ENTITYLIB_H

#include "ireference.h"
#include "debugging/debugging.h"

#include "ientity.h"
#include "irender.h"
#include "igl.h"
#include "selectable.h"

#include "generic/callback.h"
#include "math/vector.h"
#include "math/aabb.h"
#include "undolib.h"
#include "string/pooledstring.h"
#include "generic/referencecounted.h"
#include "scenelib.h"
#include "container/container.h"
#include "eclasslib.h"

#include <list>
#include <set>

inline void arrow_draw( const Vector3& origin, const Vector3& direction_forward, const Vector3& direction_left, const Vector3& direction_up ){
        Vector3 endpoint( vector3_added( origin, vector3_scaled( direction_forward, 32.0 ) ) );

        Vector3 tip1( vector3_added( vector3_added( endpoint, vector3_scaled( direction_forward, -8.0 ) ), vector3_scaled( direction_up, -4.0 ) ) );
        Vector3 tip2( vector3_added( tip1, vector3_scaled( direction_up, 8.0 ) ) );
        Vector3 tip3( vector3_added( vector3_added( endpoint, vector3_scaled( direction_forward, -8.0 ) ), vector3_scaled( direction_left, -4.0 ) ) );
        Vector3 tip4( vector3_added( tip3, vector3_scaled( direction_left, 8.0 ) ) );

        glBegin( GL_LINES );

        glVertex3fv( vector3_to_array( origin ) );
        glVertex3fv( vector3_to_array( endpoint ) );

        glVertex3fv( vector3_to_array( endpoint ) );
        glVertex3fv( vector3_to_array( tip1 ) );

        glVertex3fv( vector3_to_array( endpoint ) );
        glVertex3fv( vector3_to_array( tip2 ) );

        glVertex3fv( vector3_to_array( endpoint ) );
        glVertex3fv( vector3_to_array( tip3 ) );

        glVertex3fv( vector3_to_array( endpoint ) );
        glVertex3fv( vector3_to_array( tip4 ) );

        glVertex3fv( vector3_to_array( tip1 ) );
        glVertex3fv( vector3_to_array( tip3 ) );

        glVertex3fv( vector3_to_array( tip3 ) );
        glVertex3fv( vector3_to_array( tip2 ) );

        glVertex3fv( vector3_to_array( tip2 ) );
        glVertex3fv( vector3_to_array( tip4 ) );

        glVertex3fv( vector3_to_array( tip4 ) );
        glVertex3fv( vector3_to_array( tip1 ) );

        glEnd();
}

class SelectionIntersection;

inline void aabb_testselect( const AABB& aabb, SelectionTest& test, SelectionIntersection& best ){
        const IndexPointer::index_type indices[24] = {
                2, 1, 5, 6,
                1, 0, 4, 5,
                0, 1, 2, 3,
                3, 7, 4, 0,
                3, 2, 6, 7,
                7, 6, 5, 4,
        };

        Vector3 points[8];
        aabb_corners( aabb, points );
        test.TestQuads( VertexPointer( reinterpret_cast<VertexPointer::pointer>( points ), sizeof( Vector3 ) ), IndexPointer( indices, 24 ), best );
}

inline void aabb_draw_wire( const Vector3 points[8] ){
        unsigned int indices[26] = {
                0, 1, 1, 2, 2, 3, 3, 0,
                4, 5, 5, 6, 6, 7, 7, 4,
                0, 4, 1, 5, 2, 6, 3, 7,
                // 0, 6, 1, 7, 2, 4, 3, 5 // X cross
                1, 7 // diagonal line (connect mins to maxs corner)
        };
#if 1
        glVertexPointer( 3, GL_FLOAT, 0, points );
        glDrawElements( GL_LINES, sizeof( indices ) / sizeof( indices[0] ), GL_UNSIGNED_INT, indices );
#else
        glBegin( GL_LINES );
        for ( std::size_t i = 0; i < sizeof( indices ) / sizeof( indices[0] ); ++i )
        {
                glVertex3fv( points[indices[i]] );
        }
        glEnd();
#endif
}

inline void aabb_draw_flatshade( const Vector3 points[8] ){
        glBegin( GL_QUADS );

        glNormal3fv( vector3_to_array( aabb_normals[0] ) );
        glVertex3fv( vector3_to_array( points[2] ) );
        glVertex3fv( vector3_to_array( points[1] ) );
        glVertex3fv( vector3_to_array( points[5] ) );
        glVertex3fv( vector3_to_array( points[6] ) );

        glNormal3fv( vector3_to_array( aabb_normals[1] ) );
        glVertex3fv( vector3_to_array( points[1] ) );
        glVertex3fv( vector3_to_array( points[0] ) );
        glVertex3fv( vector3_to_array( points[4] ) );
        glVertex3fv( vector3_to_array( points[5] ) );

        glNormal3fv( vector3_to_array( aabb_normals[2] ) );
        glVertex3fv( vector3_to_array( points[0] ) );
        glVertex3fv( vector3_to_array( points[1] ) );
        glVertex3fv( vector3_to_array( points[2] ) );
        glVertex3fv( vector3_to_array( points[3] ) );

        glNormal3fv( vector3_to_array( aabb_normals[3] ) );
        glVertex3fv( vector3_to_array( points[0] ) );
        glVertex3fv( vector3_to_array( points[3] ) );
        glVertex3fv( vector3_to_array( points[7] ) );
        glVertex3fv( vector3_to_array( points[4] ) );

        glNormal3fv( vector3_to_array( aabb_normals[4] ) );
        glVertex3fv( vector3_to_array( points[3] ) );
        glVertex3fv( vector3_to_array( points[2] ) );
        glVertex3fv( vector3_to_array( points[6] ) );
        glVertex3fv( vector3_to_array( points[7] ) );

        glNormal3fv( vector3_to_array( aabb_normals[5] ) );
        glVertex3fv( vector3_to_array( points[7] ) );
        glVertex3fv( vector3_to_array( points[6] ) );
        glVertex3fv( vector3_to_array( points[5] ) );
        glVertex3fv( vector3_to_array( points[4] ) );

        glEnd();
}

inline void aabb_draw_wire( const AABB& aabb ){
        Vector3 points[8];
        aabb_corners( aabb, points );
        aabb_draw_wire( points );
}

inline void aabb_draw_flatshade( const AABB& aabb ){
        Vector3 points[8];
        aabb_corners( aabb, points );
        aabb_draw_flatshade( points );
}

inline void aabb_draw_textured( const AABB& aabb ){
        Vector3 points[8];
        aabb_corners( aabb, points );

        glBegin( GL_QUADS );

        glNormal3fv( vector3_to_array( aabb_normals[0] ) );
        glTexCoord2fv( aabb_texcoord_topleft );
        glVertex3fv( vector3_to_array( points[2] ) );
        glTexCoord2fv( aabb_texcoord_topright );
        glVertex3fv( vector3_to_array( points[1] ) );
        glTexCoord2fv( aabb_texcoord_botright );
        glVertex3fv( vector3_to_array( points[5] ) );
        glTexCoord2fv( aabb_texcoord_botleft );
        glVertex3fv( vector3_to_array( points[6] ) );

        glNormal3fv( vector3_to_array( aabb_normals[1] ) );
        glTexCoord2fv( aabb_texcoord_topleft );
        glVertex3fv( vector3_to_array( points[1] ) );
        glTexCoord2fv( aabb_texcoord_topright );
        glVertex3fv( vector3_to_array( points[0] ) );
        glTexCoord2fv( aabb_texcoord_botright );
        glVertex3fv( vector3_to_array( points[4] ) );
        glTexCoord2fv( aabb_texcoord_botleft );
        glVertex3fv( vector3_to_array( points[5] ) );

        glNormal3fv( vector3_to_array( aabb_normals[2] ) );
        glTexCoord2fv( aabb_texcoord_topleft );
        glVertex3fv( vector3_to_array( points[0] ) );
        glTexCoord2fv( aabb_texcoord_topright );
        glVertex3fv( vector3_to_array( points[1] ) );
        glTexCoord2fv( aabb_texcoord_botright );
        glVertex3fv( vector3_to_array( points[2] ) );
        glTexCoord2fv( aabb_texcoord_botleft );
        glVertex3fv( vector3_to_array( points[3] ) );

        glNormal3fv( vector3_to_array( aabb_normals[3] ) );
        glTexCoord2fv( aabb_texcoord_topleft );
        glVertex3fv( vector3_to_array( points[0] ) );
        glTexCoord2fv( aabb_texcoord_topright );
        glVertex3fv( vector3_to_array( points[3] ) );
        glTexCoord2fv( aabb_texcoord_botright );
        glVertex3fv( vector3_to_array( points[7] ) );
        glTexCoord2fv( aabb_texcoord_botleft );
        glVertex3fv( vector3_to_array( points[4] ) );

        glNormal3fv( vector3_to_array( aabb_normals[4] ) );
        glTexCoord2fv( aabb_texcoord_topleft );
        glVertex3fv( vector3_to_array( points[3] ) );
        glTexCoord2fv( aabb_texcoord_topright );
        glVertex3fv( vector3_to_array( points[2] ) );
        glTexCoord2fv( aabb_texcoord_botright );
        glVertex3fv( vector3_to_array( points[6] ) );
        glTexCoord2fv( aabb_texcoord_botleft );
        glVertex3fv( vector3_to_array( points[7] ) );

        glNormal3fv( vector3_to_array( aabb_normals[5] ) );
        glTexCoord2fv( aabb_texcoord_topleft );
        glVertex3fv( vector3_to_array( points[7] ) );
        glTexCoord2fv( aabb_texcoord_topright );
        glVertex3fv( vector3_to_array( points[6] ) );
        glTexCoord2fv( aabb_texcoord_botright );
        glVertex3fv( vector3_to_array( points[5] ) );
        glTexCoord2fv( aabb_texcoord_botleft );
        glVertex3fv( vector3_to_array( points[4] ) );

        glEnd();
}

inline void aabb_draw_solid( const AABB& aabb, RenderStateFlags state ){
        if ( state & RENDER_TEXTURE ) {
                aabb_draw_textured( aabb );
        }
        else
        {
                aabb_draw_flatshade( aabb );
        }
}

inline void aabb_draw( const AABB& aabb, RenderStateFlags state ){
        if ( state & RENDER_FILL ) {
                aabb_draw_solid( aabb, state );
        }
        else
        {
                aabb_draw_wire( aabb );
        }
}

class RenderableSolidAABB : public OpenGLRenderable
{
const AABB& m_aabb;
public:
RenderableSolidAABB( const AABB& aabb ) : m_aabb( aabb ){
}
void render( RenderStateFlags state ) const {
        aabb_draw_solid( m_aabb, state );
}
};

class RenderableWireframeAABB : public OpenGLRenderable
{
const AABB& m_aabb;
public:
RenderableWireframeAABB( const AABB& aabb ) : m_aabb( aabb ){
}
void render( RenderStateFlags state ) const {
        aabb_draw_wire( m_aabb );
}
};


/// \brief A key/value pair of strings.
///
/// - Notifies observers when value changes - value changes to "" on destruction.
/// - Provides undo support through the global undo system.
class KeyValue : public EntityKeyValue
{
typedef UnsortedSet<KeyObserver> KeyObservers;

std::size_t m_refcount;
KeyObservers m_observers;
CopiedString m_string;
const char* m_empty;
ObservedUndoableObject<CopiedString> m_undo;
static EntityCreator::KeyValueChangedFunc m_entityKeyValueChanged;
public:

KeyValue( const char* string, const char* empty )
        : m_refcount( 0 ), m_string( string ), m_empty( empty ), m_undo( m_string, UndoImportCaller( *this ) ){
        notify();
}
~KeyValue(){
        ASSERT_MESSAGE( m_observers.empty(), "KeyValue::~KeyValue: observers still attached" );
}

static void setKeyValueChangedFunc( EntityCreator::KeyValueChangedFunc func ){
        m_entityKeyValueChanged = func;
}

void IncRef(){
        ++m_refcount;
}
void DecRef(){
        if ( --m_refcount == 0 ) {
                delete this;
        }
}

void instanceAttach( MapFile* map ){
        m_undo.instanceAttach( map );
}
void instanceDetach( MapFile* map ){
        m_undo.instanceDetach( map );
}

void attach( const KeyObserver& observer ){
        ( *m_observers.insert ( observer ) )( c_str() );
}
void detach( const KeyObserver& observer ){
        observer( m_empty );
        m_observers.erase( observer );
}
const char* c_str() const {
        if ( string_empty( m_string.c_str() ) ) {
                return m_empty;
        }
        return m_string.c_str();
}
void assign( const char* other ){
        if ( !string_equal( m_string.c_str(), other ) ) {
                m_undo.save();
                m_string = other;
                notify();
        }
}

void notify(){
        m_entityKeyValueChanged();
        KeyObservers::reverse_iterator i = m_observers.rbegin();
        while ( i != m_observers.rend() )
        {
                ( *i++ )( c_str() );
        }
}

void importState( const CopiedString& string ){
        m_string = string;

        notify();
}
typedef MemberCaller<KeyValue, void(const CopiedString&), &KeyValue::importState> UndoImportCaller;
};

/// \brief An unsorted list of key/value pairs.
///
/// - Notifies observers when a pair is inserted or removed.
/// - Provides undo support through the global undo system.
/// - New keys are appended to the end of the list.
class EntityKeyValues : public Entity
{
public:
        typedef KeyValue Value;

        static StringPool& getPool(){
                return Static<StringPool, KeyContext>::instance();
        }
private:
        static EntityCreator::KeyValueChangedFunc m_entityKeyValueChanged;
        static Counter* m_counter;

        EntityClass* m_eclass;

        class KeyContext {};
        typedef Static<StringPool, KeyContext> KeyPool;
        typedef PooledString<KeyPool> Key;
        typedef SmartPointer<KeyValue> KeyValuePtr;
        typedef UnsortedMap<Key, KeyValuePtr> KeyValues;
        KeyValues m_keyValues;

        typedef UnsortedSet<Observer*> Observers;
        Observers m_observers;

        ObservedUndoableObject<KeyValues> m_undo;
        bool m_instanced;

        bool m_observerMutex;

        void notifyInsert( const char* key, Value& value ){
                m_observerMutex = true;
                for ( Observers::iterator i = m_observers.begin(); i != m_observers.end(); ++i )
                {
                        ( *i )->insert( key, value );
                }
                m_observerMutex = false;
        }
        void notifyErase( const char* key, Value& value ){
                m_observerMutex = true;
                for ( Observers::iterator i = m_observers.begin(); i != m_observers.end(); ++i )
                {
                        ( *i )->erase( key, value );
                }
                m_observerMutex = false;
        }
        void forEachKeyValue_notifyInsert(){
                for ( KeyValues::const_iterator i = m_keyValues.begin(); i != m_keyValues.end(); ++i )
                {
                        notifyInsert( ( *i ).first.c_str(), *( *i ).second );
                }
        }
        void forEachKeyValue_notifyErase(){
                for ( KeyValues::const_iterator i = m_keyValues.begin(); i != m_keyValues.end(); ++i )
                {
                        notifyErase( ( *i ).first.c_str(), *( *i ).second );
                }
        }

        void insert( const char* key, const KeyValuePtr& keyValue ){
                KeyValues::iterator i = m_keyValues.insert( KeyValues::value_type( key, keyValue ) );
                notifyInsert( key, *( *i ).second );

                if ( m_instanced ) {
                        ( *i ).second->instanceAttach( m_undo.map() );
                }
        }

        void insert( const char* key, const char* value ){
                KeyValues::iterator i = m_keyValues.find( key );
                if ( i != m_keyValues.end() ) {
                        ( *i ).second->assign( value );
                }
                else
                {
                        m_undo.save();
                        insert( key, KeyValuePtr( new KeyValue( value, EntityClass_valueForKey( *m_eclass, key ) ) ) );
                }
        }

        void erase( KeyValues::iterator i ){
                if ( m_instanced ) {
                        ( *i ).second->instanceDetach( m_undo.map() );
                }

                Key key( ( *i ).first );
                KeyValuePtr value( ( *i ).second );
                m_keyValues.erase( i );
                notifyErase( key.c_str(), *value );
        }

        void erase( const char* key ){
                KeyValues::iterator i = m_keyValues.find( key );
                if ( i != m_keyValues.end() ) {
                        m_undo.save();
                        erase( i );
                }
        }

public:
        bool m_isContainer;

        EntityKeyValues( EntityClass* eclass ) :
                m_eclass( eclass ),
                m_undo( m_keyValues, UndoImportCaller( *this ) ),
                m_instanced( false ),
                m_observerMutex( false ),
                m_isContainer( !eclass->fixedsize ){
        }
        EntityKeyValues( const EntityKeyValues& other ) :
                Entity( other ),
                m_eclass( &other.getEntityClass() ),
                m_undo( m_keyValues, UndoImportCaller( *this ) ),
                m_instanced( false ),
                m_observerMutex( false ),
                m_isContainer( other.m_isContainer ){
                for ( KeyValues::const_iterator i = other.m_keyValues.begin(); i != other.m_keyValues.end(); ++i )
                {
                        insert( ( *i ).first.c_str(), ( *i ).second->c_str() );
                }
        }
        ~EntityKeyValues(){
                for ( Observers::iterator i = m_observers.begin(); i != m_observers.end(); )
                {
            // post-increment to allow current element to be removed safely
                        ( *i++ )->clear();
                }
                ASSERT_MESSAGE( m_observers.empty(), "EntityKeyValues::~EntityKeyValues: observers still attached" );
        }

        static void setKeyValueChangedFunc( EntityCreator::KeyValueChangedFunc func ){
                m_entityKeyValueChanged = func;
                KeyValue::setKeyValueChangedFunc( func );
        }
        static void setCounter( Counter* counter ){
                m_counter = counter;
        }

        void importState( const KeyValues& keyValues ){
                for ( KeyValues::iterator i = m_keyValues.begin(); i != m_keyValues.end(); )
                {
                        erase( i++ );
                }

                for ( KeyValues::const_iterator i = keyValues.begin(); i != keyValues.end(); ++i )
                {
                        insert( ( *i ).first.c_str(), ( *i ).second );
                }

                m_entityKeyValueChanged();
        }
        typedef MemberCaller<EntityKeyValues, void(const KeyValues&), &EntityKeyValues::importState> UndoImportCaller;

        void attach( Observer& observer ){
                ASSERT_MESSAGE( !m_observerMutex, "observer cannot be attached during iteration" );
                m_observers.insert( &observer );
                for ( KeyValues::const_iterator i = m_keyValues.begin(); i != m_keyValues.end(); ++i )
                {
                        observer.insert( ( *i ).first.c_str(), *( *i ).second );
                }
        }
        void detach( Observer& observer ){
                ASSERT_MESSAGE( !m_observerMutex, "observer cannot be detached during iteration" );
                m_observers.erase( &observer );
                for ( KeyValues::const_iterator i = m_keyValues.begin(); i != m_keyValues.end(); ++i )
                {
                        observer.erase( ( *i ).first.c_str(), *( *i ).second );
                }
        }

        void forEachKeyValue_instanceAttach( MapFile* map ){
                for ( KeyValues::const_iterator i = m_keyValues.begin(); i != m_keyValues.end(); ++i )
                {
                        ( *i ).second->instanceAttach( map );
                }
        }
        void forEachKeyValue_instanceDetach( MapFile* map ){
                for ( KeyValues::const_iterator i = m_keyValues.begin(); i != m_keyValues.end(); ++i )
                {
                        ( *i ).second->instanceDetach( map );
                }
        }

        void instanceAttach( MapFile* map ){
                if ( m_counter != 0 ) {
                        m_counter->increment();
                }

                m_instanced = true;
                forEachKeyValue_instanceAttach( map );
                m_undo.instanceAttach( map );
        }
        void instanceDetach( MapFile* map ){
                if ( m_counter != 0 ) {
                        m_counter->decrement();
                }

                m_undo.instanceDetach( map );
                forEachKeyValue_instanceDetach( map );
                m_instanced = false;
        }

    // entity
        EntityClass& getEntityClass() const {
                return *m_eclass;
        }
        void forEachKeyValue( Visitor& visitor ) const {
                for ( KeyValues::const_iterator i = m_keyValues.begin(); i != m_keyValues.end(); ++i )
                {
                        visitor.visit( ( *i ).first.c_str(), ( *i ).second->c_str() );
                }
        }
        void setKeyValue( const char* key, const char* value ){
                if ( value[0] == '\0'
             /*|| string_equal(EntityClass_valueForKey(*m_eclass, key), value)*/ ) { // don't delete values equal to default
                        erase( key );
                }
                else
                {
                        insert( key, value );
                }
                m_entityKeyValueChanged();
        }
        const char* getKeyValue( const char* key ) const {
                KeyValues::const_iterator i = m_keyValues.find( key );
                if ( i != m_keyValues.end() ) {
                        return ( *i ).second->c_str();
                }

                return EntityClass_valueForKey( *m_eclass, key );
        }

        bool isContainer() const {
                return m_isContainer;
        }
};

/// \brief A Resource reference with a controlled lifetime.
/// \brief The resource is released when the ResourceReference is destroyed.
class ResourceReference
{
        CopiedString m_name;
        Resource* m_resource;
public:
        ResourceReference( const char* name )
                : m_name( name ){
                capture();
        }
        ResourceReference( const ResourceReference& other )
                : m_name( other.m_name ){
                capture();
        }
        ResourceReference& operator=( const ResourceReference& other ){
                ResourceReference tmp( other );
                tmp.swap( *this );
                return *this;
        }
        ~ResourceReference(){
                release();
        }

        void capture(){
                m_resource = GlobalReferenceCache().capture( m_name.c_str() );
        }
        void release(){
                GlobalReferenceCache().release( m_name.c_str() );
        }

        const char* getName() const {
                return m_name.c_str();
        }
        void setName( const char* name ){
                ResourceReference tmp( name );
                tmp.swap( *this );
        }

        void swap( ResourceReference& other ){
                std::swap( m_resource, other.m_resource );
                std::swap( m_name, other.m_name );
        }

        void attach( ModuleObserver& observer ){
                m_resource->attach( observer );
        }
        void detach( ModuleObserver& observer ){
                m_resource->detach( observer );
        }

        Resource* get(){
                return m_resource;
        }
};

namespace std
{
    /// \brief Swaps the values of \p self and \p other.
    /// Overloads std::swap.
        inline void swap( ResourceReference& self, ResourceReference& other ){
                self.swap( other );
        }
}

#endif