/* * This program source code file is part of KiCad, a free EDA CAD application. * * Copyright (C) 2004 Jean-Pierre Charras, jaen-pierre.charras@gipsa-lab.inpg.com * Copyright (C) 2004-2024 KiCad Developers, see AUTHORS.txt for contributors. * * 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. * * This program 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 this program; if not, you may find one here: * http://www.gnu.org/licenses/old-licenses/gpl-2.0.html * or you may search the http://www.gnu.org website for the version 2 license, * or you may write to the Free Software Foundation, Inc., * 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA */ #ifndef SCH_ITEM_H #define SCH_ITEM_H #include #include #include #include #include #include #include #include #include #include #include class CONNECTION_GRAPH; class SCH_CONNECTION; class SCH_SHEET_PATH; class SCHEMATIC; class SYMBOL; class LINE_READER; class SCH_EDIT_FRAME; class SCH_RULE_AREA; struct SCH_PLOT_OPTS; namespace KIFONT { class METRICS; } enum BODY_STYLE : int { BASE = 1, DEMORGAN = 2 }; #define MINIMUM_SELECTION_DISTANCE 2 // Minimum selection distance in mils enum FIELDS_AUTOPLACED { FIELDS_AUTOPLACED_NO = 0, FIELDS_AUTOPLACED_AUTO, FIELDS_AUTOPLACED_MANUAL }; enum DANGLING_END_T { DANGLING_END_UNKNOWN = 0, WIRE_END, BUS_END, JUNCTION_END, PIN_END, LABEL_END, BUS_ENTRY_END, WIRE_ENTRY_END, SHEET_LABEL_END, NO_CONNECT_END, }; /** * Helper class used to store the state of schematic items that can be connected to * other schematic items. */ class DANGLING_END_ITEM { public: DANGLING_END_ITEM( DANGLING_END_T aType, EDA_ITEM* aItem, const VECTOR2I& aPosition ) { m_item = aItem; m_type = aType; m_pos = aPosition; m_parent = aItem; } DANGLING_END_ITEM( DANGLING_END_T aType, EDA_ITEM* aItem, const VECTOR2I& aPosition, const EDA_ITEM* aParent ) { m_item = aItem; m_type = aType; m_pos = aPosition; m_parent = aParent; } bool operator==( const DANGLING_END_ITEM& aB ) const { return GetItem() == aB.GetItem() && GetPosition() == aB.GetPosition() && GetType() == aB.GetType() && GetParent() == aB.GetParent(); } bool operator<( const DANGLING_END_ITEM& rhs ) const { return( m_pos.x < rhs.m_pos.x || ( m_pos.x == rhs.m_pos.x && m_pos.y < rhs.m_pos.y ) || ( m_pos == rhs.m_pos && m_item < rhs.m_item ) ); } VECTOR2I GetPosition() const { return m_pos; } EDA_ITEM* GetItem() const { return m_item; } const EDA_ITEM* GetParent() const { return m_parent; } DANGLING_END_T GetType() const { return m_type; } private: EDA_ITEM* m_item; /// A pointer to the connectable object. VECTOR2I m_pos; /// The position of the connection point. DANGLING_END_T m_type; /// The type of connection of #m_item. const EDA_ITEM* m_parent; /// A pointer to the parent object (in the case of pins) }; class DANGLING_END_ITEM_HELPER { public: static std::vector::iterator get_lower_pos( std::vector& aItemListByPos, const VECTOR2I& aPos ); static std::vector::iterator get_lower_type( std::vector& aItemListByType, const DANGLING_END_T& aType ); /** Both contain the same information */ static void sort_dangling_end_items( std::vector& aItemListByType, std::vector& aItemListByPos ); }; typedef std::vector SCH_ITEM_VEC; /** * Base class for any item which can be embedded within the #SCHEMATIC container class, * and therefore instances of derived classes should only be found in EESCHEMA or other * programs that use class SCHEMATIC and its contents. * * The corresponding class in Pcbnew is #BOARD_ITEM. */ class SCH_ITEM : public EDA_ITEM { public: SCH_ITEM( EDA_ITEM* aParent, KICAD_T aType, int aUnit = 0, int aBodyStyle = 0 ); SCH_ITEM( const SCH_ITEM& aItem ); SCH_ITEM& operator=( const SCH_ITEM& aPin ); virtual ~SCH_ITEM(); wxString GetClass() const override { return wxT( "SCH_ITEM" ); } bool IsType( const std::vector& aScanTypes ) const override { if( EDA_ITEM::IsType( aScanTypes ) ) return true; for( KICAD_T scanType : aScanTypes ) { if( scanType == SCH_ITEM_LOCATE_WIRE_T && m_layer == LAYER_WIRE ) return true; if ( scanType == SCH_ITEM_LOCATE_BUS_T && m_layer == LAYER_BUS ) return true; if ( scanType == SCH_ITEM_LOCATE_GRAPHIC_LINE_T && Type() == SCH_LINE_T && m_layer == LAYER_NOTES ) { return true; } } return false; } /** * Swap the internal data structures \a aItem with the schematic item. * Obviously, aItem must have the same type than me. * @param aItem The item to swap the data structures with. */ virtual void SwapData( SCH_ITEM* aItem ); /** * Swap the non-temp and non-edit flags. */ void SwapFlags( SCH_ITEM* aItem ); /** * Routine to create a new copy of given item. * The new object is not put in draw list (not linked). * * @param doClone (default = false) indicates unique values (such as timestamp and * sheet name) should be duplicated. Use only for undo/redo operations. */ SCH_ITEM* Duplicate( bool doClone = false ) const; static wxString GetUnitDescription( int aUnit ); static wxString GetBodyStyleDescription( int aBodyStyle ); virtual void SetUnit( int aUnit ) { m_unit = aUnit; } int GetUnit() const { return m_unit; } virtual void SetBodyStyle( int aBodyStyle ) { m_bodyStyle = aBodyStyle; } int GetBodyStyle() const { return m_bodyStyle; } void SetPrivate( bool aPrivate ) { m_private = aPrivate; } bool IsPrivate() const { return m_private; } virtual void SetExcludedFromSim( bool aExclude ) { } virtual bool GetExcludedFromSim() const { return false; } /** * @return true for items which are moved with the anchor point at mouse cursor * and false for items moved with no reference to anchor * Usually return true for small items (labels, junctions) and false for * items which can be large (hierarchical sheets, symbols) */ virtual bool IsMovableFromAnchorPoint() const { return true; } VECTOR2I& GetStoredPos() { return m_storedPos; } void SetStoredPos( const VECTOR2I& aPos ) { m_storedPos = aPos; } /** * Searches the item hierarchy to find a SCHEMATIC. * * Every SCH_ITEM that lives on a SCH_SCREEN should be parented to either that screen * or another SCH_ITEM on the same screen (for example, pins to their symbols). * * Every SCH_SCREEN should be parented to the SCHEMATIC. * * @note This hierarchy is not the same as the sheet hierarchy! * * @return the parent schematic this item lives on, or nullptr. */ SCHEMATIC* Schematic() const; const SYMBOL* GetParentSymbol() const; SYMBOL* GetParentSymbol(); virtual bool IsLocked() const { return false; } virtual void SetLocked( bool aLocked ) {} /** * Allow items to support hypertext actions when hovered/clicked. */ virtual bool IsHypertext() const { return false; } virtual void DoHypertextAction( EDA_DRAW_FRAME* aFrame ) const { } /** * Return the layer this item is on. */ SCH_LAYER_ID GetLayer() const { return m_layer; } void SetLayer( SCH_LAYER_ID aLayer ) { m_layer = aLayer; } /** * Return the layers the item is drawn on (which may be more than its "home" layer) */ void ViewGetLayers( int aLayers[], int& aCount ) const override; /** * @return the size of the "pen" that be used to draw or plot this item */ virtual int GetPenWidth() const { return 0; } int GetEffectivePenWidth( const SCH_RENDER_SETTINGS* aSettings ) const; const wxString& GetDefaultFont() const; const KIFONT::METRICS& GetFontMetrics() const; bool RenderAsBitmap( double aWorldScale ) const override; /** * Return a measure of how likely the other object is to represent the same * object. The scale runs from 0.0 (definitely different objects) to 1.0 (same) */ virtual double Similarity( const SCH_ITEM& aItem ) const { wxCHECK_MSG( false, 0.0, wxT( "Similarity not implemented in " ) + GetClass() ); } /** * Calculate the boilerplate similarity for all LIB_ITEMs without * preventing the use above of a pure virtual function that catches at compile * time when a new object has not been fully implemented */ double SimilarityBase( const SCH_ITEM& aItem ) const { double similarity = 1.0; if( m_unit != aItem.m_unit ) similarity *= 0.9; if( m_bodyStyle != aItem.m_bodyStyle ) similarity *= 0.9; if( m_private != aItem.m_private ) similarity *= 0.9; return similarity; } /** * Move the item by \a aMoveVector to a new position. */ virtual void Move( const VECTOR2I& aMoveVector ) { wxCHECK_MSG( false, /*void*/, wxT( "Move not implemented in " ) + GetClass() ); } /** * Mirror item horizontally about \a aCenter. */ virtual void MirrorHorizontally( int aCenter ) { wxCHECK_MSG( false, /*void*/, wxT( "MirrorHorizontally not implemented in " ) + GetClass() ); } /** * Mirror item vertically about \a aCenter. */ virtual void MirrorVertically( int aCenter ) { wxCHECK_MSG( false, /*void*/, wxT( "MirrorVertically not implemented in " ) + GetClass() ); } /** * Rotate the item around \a aCenter 90 degrees in the clockwise direction. */ virtual void Rotate( const VECTOR2I& aCenter, bool aRotateCCW ) { wxCHECK_MSG( false, /*void*/, wxT( "Rotate not implemented in " ) + GetClass() ); } /** * Begin drawing a symbol library draw item at \a aPosition. * * It typically would be called on a left click when a draw tool is selected in * the symbol library editor and one of the graphics tools is selected. * * @param aPosition The position in drawing coordinates where the drawing was started. * May or may not be required depending on the item being drawn. */ virtual void BeginEdit( const VECTOR2I& aPosition ) {} /** * Continue an edit in progress at \a aPosition. * * This is used to perform the next action while drawing an item. This would be * called for each additional left click when the mouse is captured while the item * is being drawn. * * @param aPosition The position of the mouse left click in drawing coordinates. * @return True if additional mouse clicks are required to complete the edit in progress. */ virtual bool ContinueEdit( const VECTOR2I& aPosition ) { return false; } /** * End an object editing action. * * This is used to end or abort an edit action in progress initiated by BeginEdit(). */ virtual void EndEdit( bool aClosed = false ) {} /** * Calculate the attributes of an item at \a aPosition when it is being edited. * * This method gets called by the Draw() method when the item is being edited. This * probably should be a pure virtual method but bezier curves are not yet editable in * the symbol library editor. Therefore, the default method does nothing. * * @param aPosition The current mouse position in drawing coordinates. */ virtual void CalcEdit( const VECTOR2I& aPosition ) {} /** * Add the schematic item end points to \a aItemList if the item has end points. * * The default version doesn't do anything since many of the schematic object cannot * be tested for dangling ends. If you add a new schematic item that can have a * dangling end ( no connect ), override this method to provide the correct end * points. * * @param aItemList is the list of DANGLING_END_ITEMS to add to. */ virtual void GetEndPoints( std::vector< DANGLING_END_ITEM >& aItemList ) {} /** * Test the schematic item to \a aItemList to check if it's dangling state has changed. * * Note that the return value only true when the state of the test has changed. Use * the IsDangling() method to get the current dangling state of the item. Some of * the schematic objects cannot be tested for a dangling state, the default method * always returns false. Only override the method if the item can be tested for a * dangling state. * * If aSheet is passed a non-null pointer to a SCH_SHEET_PATH, the overridden method can * optionally use it to update sheet-local connectivity information * * @param aItemListByType is the list of items to test item against. It's sorted * by item type, keeping WIRE_END pairs together. * @param aItemListByPos is the same list but sorted first by Y then by X. * @param aSheet is the sheet path to update connections for. * @return True if the dangling state has changed from it's current setting. */ virtual bool UpdateDanglingState( std::vector& aItemListByType, std::vector& aItemListByPos, const SCH_SHEET_PATH* aSheet = nullptr ) { return false; } virtual bool IsDangling() const { return false; } virtual bool CanConnect( const SCH_ITEM* aItem ) const { return m_layer == aItem->GetLayer(); } /** * @return true if the schematic item can connect to another schematic item. */ virtual bool IsConnectable() const { return false; } /** * @return true if the given point can start drawing (usually means the anchor is * unused/free/dangling). */ virtual bool IsPointClickableAnchor( const VECTOR2I& aPos ) const { return false; } /** * Add all the connection points for this item to \a aPoints. * * Not all schematic items have connection points so the default method does nothing. * * @param aPoints is the list of connection points to add to. */ virtual std::vector GetConnectionPoints() const { return {}; } /** * Test the item to see if it is connected to \a aPoint. * * @param aPoint is a reference to a VECTOR2I object containing the coordinates to test. * @return True if connection to \a aPoint exists. */ bool IsConnected( const VECTOR2I& aPoint ) const; /** * Retrieve the connection associated with this object in the given sheet. * * @note The returned value can be nullptr. */ SCH_CONNECTION* Connection( const SCH_SHEET_PATH* aSheet = nullptr ) const; /** * Retrieve the set of items connected to this item on the given sheet. */ const SCH_ITEM_VEC& ConnectedItems( const SCH_SHEET_PATH& aPath ); /** * Add a connection link between this item and another. */ void AddConnectionTo( const SCH_SHEET_PATH& aPath, SCH_ITEM* aItem ); /** * Clear all connections to this item. */ void ClearConnectedItems( const SCH_SHEET_PATH& aPath ); /** * Create a new connection object associated with this object. * * @param aPath is the sheet path to initialize. */ SCH_CONNECTION* InitializeConnection( const SCH_SHEET_PATH& aPath, CONNECTION_GRAPH* aGraph ); SCH_CONNECTION* GetOrInitConnection( const SCH_SHEET_PATH& aPath, CONNECTION_GRAPH* aGraph ); /** * Return true if this item should propagate connection info to \a aItem. */ virtual bool ConnectionPropagatesTo( const EDA_ITEM* aItem ) const { return true; } bool IsConnectivityDirty() const { return m_connectivity_dirty; } void SetConnectivityDirty( bool aDirty = true ) { m_connectivity_dirty = aDirty; } /** * Check if \a aItem has connectivity changes against this object. * * This provides granular per object connectivity change testing to prevent the need * to rebuild the #CONNECTION_GRAPH when object properties that have nothing to do with * the schematic connectivity changes i.e. color, thickness, fill type. etc. * * @note Developers should override this method for all objects that are connectable. * * @param aItem is the item to test for connectivity changes. * @param aInstance is the instance to test for connectivity changes. This parameter is * only meaningful for #SCH_SYMBOL objects. * * @return true if there are connectivity changes otherwise false. */ virtual bool HasConnectivityChanges( const SCH_ITEM* aItem, const SCH_SHEET_PATH* aInstance = nullptr ) const { return false; } /// Updates the connection graph for all connections in this item void SetConnectionGraph( CONNECTION_GRAPH* aGraph ); virtual bool HasCachedDriverName() const { return false; } virtual const wxString& GetCachedDriverName() const; virtual void SetLastResolvedState( const SCH_ITEM* aItem ) { } std::shared_ptr GetEffectiveNetClass( const SCH_SHEET_PATH* aSheet = nullptr ) const; /** * Return whether the fields have been automatically placed. */ FIELDS_AUTOPLACED GetFieldsAutoplaced() const { return m_fieldsAutoplaced; } void SetFieldsAutoplaced() { m_fieldsAutoplaced = FIELDS_AUTOPLACED_AUTO; } void ClearFieldsAutoplaced() { m_fieldsAutoplaced = FIELDS_AUTOPLACED_NO; } /** * Autoplace fields only if correct to do so automatically. * * Fields that have been moved by hand are not automatically placed. * * @param aScreen is the SCH_SCREEN associated with the current instance of the symbol. */ void AutoAutoplaceFields( SCH_SCREEN* aScreen ) { if( GetFieldsAutoplaced() ) AutoplaceFields( aScreen, GetFieldsAutoplaced() == FIELDS_AUTOPLACED_MANUAL ); } virtual void AutoplaceFields( SCH_SCREEN* aScreen, bool aManual ) { } virtual void RunOnChildren( const std::function& aFunction ) { } virtual void ClearCaches(); /** * Check if this schematic item has line stoke properties. * * @see #STROKE_PARAMS * * @return true if this schematic item support line stroke properties. Otherwise, false. */ virtual bool HasLineStroke() const { return false; } virtual STROKE_PARAMS GetStroke() const { wxCHECK( false, STROKE_PARAMS() ); } virtual void SetStroke( const STROKE_PARAMS& aStroke ) { wxCHECK( false, /* void */ ); } /** * Print an item. * * @param aUnit - Which unit to print. * @param aBodyStyle - Which body style to print. * @param aOffset - Relative offset. * @param aForceNoFill - Disable printing of fills. * @param aDimmed - Reduce brightness of item. */ virtual void Print( const SCH_RENDER_SETTINGS* aSettings, int aUnit, int aBodyStyle, const VECTOR2I& aOffset, bool aForceNoFill, bool aDimmed ) { wxCHECK_MSG( false, /*void*/, wxT( "Print not implemented in " ) + GetClass() ); } /** * Print just the background fills. */ virtual void PrintBackground( const SCH_RENDER_SETTINGS* aSettings, int aUnit, int aBodyStyle, const VECTOR2I& aOffset, bool aDimmed ) { wxCHECK_MSG( false, /*void*/, wxT( "PrintBackground not implemented in " ) + GetClass() ); } /** * Plot the item to \a aPlotter. * * @param aBackground a poor-man's Z-order. The routine will get called twice, first with * aBackground true and then with aBackground false. * @param aUnit - which unit to print. * @param aBodyStyle - which body style to print. * @param aOffset relative offset. * @param aDimmed reduce brightness of item. */ virtual void Plot( PLOTTER* aPlotter, bool aBackground, const SCH_PLOT_OPTS& aPlotOpts, int aUnit, int aBodyStyle, const VECTOR2I& aOffset, bool aDimmed) { wxCHECK_MSG( false, /*void*/, wxT( "Plot not implemented in " ) + GetClass() ); } /** * Reset the cache of rule areas (called prior to schematic connectivity recomputation) */ void ClearRuleAreasCache() { m_rule_areas_cache.clear(); } /** * Adds a rule area to the item's cache */ void AddRuleAreaToCache( SCH_RULE_AREA* aRuleArea ) { m_rule_areas_cache.insert( aRuleArea ); } /** * Gets the cache of rule areas enclosing this item */ const std::unordered_set& GetRuleAreaCache() const { return m_rule_areas_cache; } /** * The list of flags used by the #compare function. * * UNIT This flag relaxes unit, body-style and pin-number constraints. It is used for * #SCH_ITEM object unit comparisons. * * EQUALITY This flag relaxes ordering constraints so that fields, etc. don't have to * appear in the same order to be considered equal. * * ERC This flag relaxes constraints on data that is settable in the schematic editor. * It compares only symbol-editor-only data. * * SKIP_TST_POS This flag relaxes comparisons on position (mainly for fields) for ERC. */ enum COMPARE_FLAGS : int { UNIT = 0x01, EQUALITY = 0x02, ERC = 0x04, SKIP_TST_POS = 0x08 }; virtual bool operator==( const SCH_ITEM& aOther ) const; virtual bool operator<( const SCH_ITEM& aItem ) const; protected: SCH_RENDER_SETTINGS* getRenderSettings( PLOTTER* aPlotter ) const { return static_cast( aPlotter->RenderSettings() ); } struct cmp_items { bool operator()( const SCH_ITEM* aFirst, const SCH_ITEM* aSecond ) const; }; void getSymbolEditorMsgPanelInfo( EDA_DRAW_FRAME* aFrame, std::vector& aList ); /** * Provide the draw object specific comparison called by the == and < operators. * * The base object sort order which always proceeds the derived object sort order * is as follows: * - Symbol alternate part (DeMorgan) number. * - Symbol part number. * - KICAD_T enum value. * - Result of derived classes comparison. * * @note Make sure you call down to #SCH_ITEM::compare before doing any derived object * comparisons or you will break the sorting using the symbol library file format. * * @param aOther A reference to the other #SCH_ITEM to compare the arc against. * @param aCompareFlags The flags used to perform the comparison. * * @return An integer value less than 0 if the object is less than \a aOther object, * zero if the object is equal to \a aOther object, or greater than 0 if the * object is greater than \a aOther object. */ virtual int compare( const SCH_ITEM& aOther, int aCompareFlags = 0 ) const; private: friend class CONNECTION_GRAPH; /** * Provide the object specific test to see if it is connected to \a aPosition. * * @note Override this function if the derived object can be connect to another * object such as a wire, bus, or junction. Do not override this function * for objects that cannot have connections. The default will always return * false. This functions is call through the public function IsConnected() * which performs tests common to all schematic items before calling the * item specific connection testing. * * @param aPosition is a reference to a VECTOR2I object containing the test position. * @return True if connection to \a aPosition exists. */ virtual bool doIsConnected( const VECTOR2I& aPosition ) const { return false; } protected: SCH_LAYER_ID m_layer; int m_unit; // set to 0 if common to all units int m_bodyStyle; // set to 0 if common to all body styles bool m_private; // only shown in Symbol Editor FIELDS_AUTOPLACED m_fieldsAutoplaced; // indicates status of field autoplacement VECTOR2I m_storedPos; // temp variable used in some move commands to store // an initial position of the item or mouse cursor /// Store pointers to other items that are connected to this one, per sheet. std::map m_connected_items; /// Store connectivity information, per sheet. std::unordered_map m_connection_map; bool m_connectivity_dirty; /// Store pointers to rule areas which this item is contained within std::unordered_set m_rule_areas_cache; private: friend class LIB_SYMBOL; }; #ifndef SWIG DECLARE_ENUM_TO_WXANY( SCH_LAYER_ID ); #endif #endif /* SCH_ITEM_H */