/*************************************************************************** * Copyright (C) 2003-2005 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. * ***************************************************************************/ #ifndef CIRCUIT_H #define CIRCUIT_H #include #include "tqstringlist.h" #include "tqvaluelist.h" #include "elementset.h" class CircuitDocument; class Wire; class Pin; class Element; class LogicOut; typedef TQValueList > PinList; typedef TQValueList ElementList; class LogicCacheNode { public: LogicCacheNode(); ~LogicCacheNode(); LogicCacheNode * high; LogicCacheNode * low; Vector * data; }; /** Usage of this class (usually invoked from CircuitDocument): (1) Add Wires, Pins and Elements to the class as appropriate (2) Call init to initialize the simulation (3) Control the simulation with step() This class can be considered a bridge between the gui-tainted CircuitDocument - specific to this implementation, and the pure untainted ElementSet. Please keep it that way. @short Simulates a collection of components @author David Saxton */ class Circuit { public: Circuit(); ~Circuit(); void addPin( Pin *node ); void addElement( Element *element ); bool tqcontains( Pin *node ); bool containsNonLinear() const { return m_elementSet->containsNonLinear(); } void init(); /** * Called after everything else has been setup - before doNonLogic or * doLogic are called for the first time. Preps the circuit. */ void initCache(); /** * Marks all cached results as invalidated and removes them. */ void setCacheInvalidated(); /** * Solves for non-logic elements */ void doNonLogic(); /** * Solves for logic elements (i.e just does fbSub) */ void doLogic() { m_elementSet->doLinear(false); } void displayEquations(); void updateCurrents(); void createMatrixMap(); /** * This will identify the ground node and non-ground nodes in the given set. * Ground will be given the eqId -1, non-ground of 0. * @param highest The highest ground type of the groundnodes found. If no ground nodes were found, this will be (gt_never-1). * @returns the number of ground nodes. If all nodes are at or below the * gt_never threshold, then this will be zero. */ static int identifyGround( PinList nodeList, int *highest = 0l ); void setNextChanged( Circuit * circuit, unsigned char chain ) { m_pNextChanged[chain] = circuit; } Circuit * nextChanged( unsigned char chain ) const { return m_pNextChanged[chain]; } void setCanAddChanged( bool canAdd ) { m_bCanAddChanged = canAdd; } bool canAddChanged() const { return m_bCanAddChanged; } protected: void cacheAndUpdate(); /** * Update the nodal voltages from those calculated in ElementSet */ void updateNodalVoltages(); /** * Step the reactive elements. */ void stepReactive(); /** * Returns true if any of the nodes are ground */ static bool recursivePinAdd( Pin *node, PinList *unassignedNodes, PinList *associated, PinList *nodes ); int m_cnodeCount; int m_branchCount; int m_prepNLCount; // Count until next m_elementSet->prepareNonLinear() is called PinList m_pinList; ElementList m_elementList; ElementSet *m_elementSet; //Stuff for caching bool m_bCanCache; LogicCacheNode * m_pLogicCacheBase; unsigned m_logicOutCount; LogicOut ** m_pLogicOut; bool m_bCanAddChanged; Circuit * m_pNextChanged[2]; }; #endif