#ifndef IVL_functor_H #define IVL_functor_H /* * Copyright (c) 1999-2016 Stephen Williams (steve@icarus.com) * * This source code is free software; you can redistribute it * and/or modify it in source code form 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, write to the Free Software * Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA. */ /* * The functor is an object that can be applied to a design to * transform it. This is different from the target_t, which can only * scan the design but not transform it in any way. * * When a functor it scanning a process, signal or node, the functor * is free to manipulate the list by deleting items, including the * node being scanned. The Design class scanner knows how to handle * the situation. However, if objects are added to the netlist, there * is no guarantee that object will be scanned unless the functor is * rerun. */ class Design; class NetNet; class NetProcTop; struct functor_t { virtual ~functor_t(); /* Events are scanned here. */ virtual void event(class Design*des, class NetEvent*); /* This is called once for each signal in the design. */ virtual void signal(class Design*des, class NetNet*); /* This method is called for each process in the design. */ virtual void process(class Design*des, class NetProcTop*); /* This method is called for each structural abs(). */ virtual void lpm_abs(class Design*des, class NetAbs*); /* This method is called for each structural adder. */ virtual void lpm_add_sub(class Design*des, class NetAddSub*); /* This method is called for each structural comparator. */ virtual void lpm_compare(class Design*des, class NetCompare*); /* This method is called for each structural concatenation. */ virtual void lpm_concat(class Design*des, class NetConcat*); /* This method is called for each structural constant. */ virtual void lpm_const(class Design*des, class NetConst*); /* This method is called for each structural constant. */ virtual void lpm_divide(class Design*des, class NetDivide*); /* Constant literals. */ virtual void lpm_literal(class Design*des, class NetLiteral*); /* This method is called for each structural constant. */ virtual void lpm_modulo(class Design*des, class NetModulo*); /* This method is called for each FF in the design. */ virtual void lpm_ff(class Design*des, class NetFF*); /* This method is called for each LATCH in the design. */ virtual void lpm_latch(class Design*des, class NetLatch*); /* Handle LPM combinational logic devices. */ virtual void lpm_logic(class Design*des, class NetLogic*); /* This method is called for each multiplier. */ virtual void lpm_mult(class Design*des, class NetMult*); /* This method is called for each MUX. */ virtual void lpm_mux(class Design*des, class NetMux*); virtual void lpm_part_select(class Design*des, class NetPartSelect*); /* This method is called for each power. */ virtual void lpm_pow(class Design*des, class NetPow*); /* This method is called for each part substitute. */ virtual void lpm_substitute(class Design*des, class NetSubstitute*); /* This method is called for each unary reduction gate. */ virtual void lpm_ureduce(class Design*des, class NetUReduce*); virtual void sign_extend(class Design*des, class NetSignExtend*); }; struct proc_match_t { virtual ~proc_match_t(); virtual int assign(class NetAssign*); virtual int assign_nb(class NetAssignNB*); virtual int condit(class NetCondit*); virtual int event_wait(class NetEvWait*); virtual int block(class NetBlock*); }; #endif /* IVL_functor_H */