revert commits improved performance of some extensible Standard Functions (ADD, MUL, AND, OR, XOR)
Following commits are reverted:
mjsousa 0b275a2 improve performance of some extensible Standard Functions (ADD, MUL, AND, OR, XOR) -- increase hardcoded limit to 499
mjsousa 2228799 improve performance of some extensible Standard Functions (ADD, MUL, AND, OR, XOR) -- Add comments!!
mjsousa ce81fa6 improve performance of some extensible Standard Functions (ADD, MUL, AND, OR, XOR)"
The reason is that they cause regression in some cases (if function is
used as argument for function block, for example) and this is not
fixed for a long time.
/*
* matiec - a compiler for the programming languages defined in IEC 61131-3
* Copyright (C) 2003-2011 Mario de Sousa (msousa@fe.up.pt)
* Copyright (C) 2007-2011 Laurent Bessard and Edouard Tisserant
*
* 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 3 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, see <http://www.gnu.org/licenses/>.
*
*
* This code is made available on the understanding that it will not be
* used in safety-critical situations without a full and competent review.
*/
/*
* An IEC 61131-3 compiler.
*
* Based on the
* FINAL DRAFT - IEC 61131-3, 2nd Ed. (2001-12-10)
*
*/
/*
* VISITOR.HH
*
*
* The asbract syntax tree is scaned several times
* during the whole compilation process. For e.g., stage 3 verifies
* semantics, and stage 4 produces output.
*
* Since the number of functions that need to scan through
* the abtract syntax tree may increase in time, (e.g. new
* output formats, new semantic checks, etc...) while the
* abstract syntax tree class structure is pretty stable
* (i.e. the ST and IL languages will not be changing much...),
* we use the 'visitor' design patern.
*
* It is not strictly necessary to use this pattern, but it does
* have the advantage of bringing together the functions
* that implement the same algorithm, each on a different
* class of object in the abstract syntax tree.
*
*
* This file contains the interface that each visitor class
* must implement in order to be able to visit the abstract
* syntax tree (class visitor_c)
*
* Three implementations of this interface are also provided,
* that may be later extended to execute a particular algorithm.
*
* The null (class null_visitor_c) does nothing.
*
* The iterator (class iterator_visitor_c) iterates through
* every object in the syntax tree.
*
* The search class (class search_visitor_c) iterates through
* every object, until one returns a value != NULL.
*/
#ifndef _VISITOR_HH
#define _VISITOR_HH
#include "absyntax.hh"
#define SYM_LIST(class_name_c, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_TOKEN(class_name_c, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_REF0(class_name_c, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_REF1(class_name_c, ref1, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_REF2(class_name_c, ref1, ref2, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_REF3(class_name_c, ref1, ref2, ref3, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_REF4(class_name_c, ref1, ref2, ref3, ref4, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_REF5(class_name_c, ref1, ref2, ref3, ref4, ref5, ...) virtual void *visit(class_name_c *symbol) = 0;
#define SYM_REF6(class_name_c, ref1, ref2, ref3, ref4, ref5, ref6, ...) virtual void *visit(class_name_c *symbol) = 0;
class visitor_c {
public:
#include "absyntax.def"
virtual ~visitor_c(void);
};
#undef SYM_LIST
#undef SYM_TOKEN
#undef SYM_REF0
#undef SYM_REF1
#undef SYM_REF2
#undef SYM_REF3
#undef SYM_REF4
#undef SYM_REF5
#undef SYM_REF6
#define SYM_LIST(class_name_c, ...) virtual void *visit(class_name_c *symbol);
#define SYM_TOKEN(class_name_c, ...) virtual void *visit(class_name_c *symbol);
#define SYM_REF0(class_name_c, ...) virtual void *visit(class_name_c *symbol);
#define SYM_REF1(class_name_c, ref1, ...) virtual void *visit(class_name_c *symbol);
#define SYM_REF2(class_name_c, ref1, ref2, ...) virtual void *visit(class_name_c *symbol);
#define SYM_REF3(class_name_c, ref1, ref2, ref3, ...) virtual void *visit(class_name_c *symbol);
#define SYM_REF4(class_name_c, ref1, ref2, ref3, ref4, ...) virtual void *visit(class_name_c *symbol);
#define SYM_REF5(class_name_c, ref1, ref2, ref3, ref4, ref5, ...) virtual void *visit(class_name_c *symbol);
#define SYM_REF6(class_name_c, ref1, ref2, ref3, ref4, ref5, ref6, ...) virtual void *visit(class_name_c *symbol);
class null_visitor_c: public visitor_c {
public:
#include "absyntax.def"
virtual ~null_visitor_c(void);
};
class fcall_visitor_c: public visitor_c {
public:
virtual void fcall(symbol_c *symbol) = 0;
public:
#include "absyntax.def"
// virtual ~fcall_visitor_c(void);
};
class iterator_visitor_c: public visitor_c {
protected:
void *visit_list(list_c *list);
public:
#include "absyntax.def"
virtual ~iterator_visitor_c(void);
};
class fcall_iterator_visitor_c: public iterator_visitor_c {
public:
virtual void prefix_fcall(symbol_c *symbol);
virtual void suffix_fcall(symbol_c *symbol);
public:
#include "absyntax.def"
virtual ~fcall_iterator_visitor_c(void);
};
class search_visitor_c: public visitor_c {
protected:
void *visit_list(list_c *list);
public:
#include "absyntax.def"
virtual ~search_visitor_c(void);
};
#undef SYM_LIST
#undef SYM_TOKEN
#undef SYM_REF0
#undef SYM_REF1
#undef SYM_REF2
#undef SYM_REF3
#undef SYM_REF4
#undef SYM_REF5
#undef SYM_REF6
#endif /* _VISITOR_HH */