Remove debugging code left in by mistake.
/*
* 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.
*/
#include <string.h>
/* This file cotains two main classes:
* - generate_c_base_c
* - generate_c_base_and_typeid_c
*
* generate_c_base_c
* -----------------
* This class generates C code for all literals and varables. In short, all the basic stuff
* that will probably be needed in all other code generating classes.
* It does not however handle derived datatypes.
*
* generate_c_base_and_typeid_c
* ----------------------------
* This is similar to the generate_c_base_c (from which it inherits), but it also handles
* all the derived datatypes. Note that it does not generate C code for the declaration of
* those datatypes (that is what generate_c_typedecl_c is for), but rather it merely
* generates the name/id of a derived datatype.
* Note too that not all derived datatypes in the IEC 61131-3 have a name (for example,
* VAR a: ARRAY [3..5] of INT END_VAR), in which case an alias for this datatype should
* have been previously generated by either generate_c_typedecl_c or generate_implicit_typedecl_c.
*/
typedef struct
{
symbol_c *param_name;
symbol_c *param_value;
symbol_c *param_type;
function_param_iterator_c::param_direction_t param_direction;
} FUNCTION_PARAM;
#define DECLARE_PARAM_LIST()\
std::list<FUNCTION_PARAM*> param_list;\
std::list<FUNCTION_PARAM*>::iterator pt;\
FUNCTION_PARAM *param;
#define ADD_PARAM_LIST(name, value, type, direction)\
param = new FUNCTION_PARAM;\
param->param_name = name;\
param->param_value = value;\
param->param_type = type;\
param->param_direction = direction;\
param_list.push_back(param);
#define PARAM_LIST_ITERATOR() for(pt = param_list.begin(); pt != param_list.end(); pt++)
#define PARAM_NAME (*pt)->param_name
#define PARAM_VALUE (*pt)->param_value
#define PARAM_TYPE (*pt)->param_type
#define PARAM_DIRECTION (*pt)->param_direction
#define CLEAR_PARAM_LIST()\
PARAM_LIST_ITERATOR()\
delete *pt;\
param_list.clear();
/* generate_c_base_c
* -----------------
* This class generates C code for all literals and varables. In short, all the basic stuff
* that will probably be needed in all other code generating classes.
* It does not however handle derived datatypes.
*/
class generate_c_base_c: public iterator_visitor_c {
protected:
stage4out_c &s4o;
private:
/* Unlike programs that are mapped onto C++ classes, Function Blocks are mapped onto a data structure type
* and a separate function containing the code. This function is passed a pointer to an instance of the data
* structure. This means that the code inside the functions must insert a pointer to the data structure whenever
* it wishes to access a Function Block variable.
* The variable_prefix_ variable will contain the correct string which needs to be prefixed to all variable accesses.
* This string is set with the set_variable_prefix() member function.
*/
const char *variable_prefix_;
public:
generate_c_base_c(stage4out_c *s4o_ptr): s4o(*s4o_ptr) {
variable_prefix_ = NULL;
}
~generate_c_base_c(void) {}
void set_variable_prefix(const char *variable_prefix) {variable_prefix_ = variable_prefix;}
const char *get_variable_prefix(void) {return variable_prefix_;}
bool is_variable_prefix_null(void) {return variable_prefix_ == NULL;}
void print_variable_prefix(void) {
if (variable_prefix_ != NULL)
s4o.print(variable_prefix_);
}
void print_line_directive(symbol_c *symbol) {
if (!generate_line_directives__) return; /* global variable generate_line_directives__ is defined in generate_c.cc */
s4o.print("#line ");
s4o.print(symbol->first_line);
s4o.print(" \"");
s4o.print(symbol->first_file);
s4o.print("\"\n");
}
void *print_token(token_c *token, int offset = 0) {
return s4o.printupper((token->value)+offset);
}
void *print_literal(symbol_c *type, symbol_c *value) {
s4o.print("__");
type->accept(*this);
s4o.print("_LITERAL(");
value->accept(*this);
s4o.print(")");
return NULL;
}
void *print_striped_token(token_c *token, int offset = 0) {
std::string str = "";
bool leading_zero = true;
for (unsigned int i = offset; i < strlen(token->value); i++) {
if (leading_zero
&& ( token->value[i] != '0'
|| i == strlen(token->value) - 1
|| token->value[i + 1] == '.'
)
)
leading_zero = false;
if (!leading_zero && token->value[i] != '_')
str += token->value[i];
}
return s4o.printupper(str);
}
void *print_striped_binary_token(token_c *token, unsigned int offset = 0) {
/* convert the binary value to hexadecimal format... */
unsigned char value, bit_mult;
unsigned int i;
int total_bits;
char str[2] = {'A', '\0'}; /* since the s4o object is not prepared to print out one character at a time... */
s4o.print("0x");
total_bits = 0;
for (i = offset; i < strlen(token->value); i++)
if (token->value[i] != '_')
total_bits++;
value = 0;
bit_mult = (unsigned char)1 << (((total_bits+3)%4)+1);
for (i = offset; i < strlen(token->value); i++) {
if (token->value[i] != '_') {
bit_mult /= 2;
value += bit_mult * ((token->value[i] == '0')? 0:1);
if (bit_mult == 1) {
str[0] = (value <= 9)? (char)'0' + value : (char)'A' + value - 10;
s4o.print(str);
bit_mult = 0x10;
value = 0;
}
}
}
return NULL;
}
void *print_list(list_c *list,
std::string pre_elem_str = "",
std::string inter_elem_str = "",
std::string post_elem_str = "",
visitor_c *visitor = NULL) {
if (visitor == NULL) visitor = this;
if (list->n > 0) {
//std::cout << "generate_c_base_c::print_list(n = " << list->n << ") 000\n";
s4o.print(pre_elem_str);
list->elements[0]->accept(*visitor);
}
for(int i = 1; i < list->n; i++) {
//std::cout << "generate_c_base_c::print_list " << i << "\n";
s4o.print(inter_elem_str);
list->elements[i]->accept(*visitor);
}
if (list->n > 0)
s4o.print(post_elem_str);
return NULL;
}
void *print_binary_expression(symbol_c *l_exp,
symbol_c *r_exp,
const char *operation) {
s4o.print("(");
l_exp->accept(*this);
s4o.print(operation);
r_exp->accept(*this);
s4o.print(")");
return NULL;
}
void *print_unary_expression(symbol_c *exp,
const char *operation) {
s4o.print(operation);
s4o.print("(");
exp->accept(*this);
s4o.print(")");
return NULL;
}
void *print_binary_function(const char *function,
symbol_c *l_exp,
symbol_c *r_exp) {
s4o.print(function);
s4o.print("(");
l_exp->accept(*this);
s4o.print(", ");
r_exp->accept(*this);
s4o.print(")");
return NULL;
}
void *print_compare_function(const char *function,
symbol_c *compare_type,
symbol_c *l_exp,
symbol_c *r_exp) {
s4o.print(function);
compare_type->accept(*this);
s4o.print("(__BOOL_LITERAL(TRUE), NULL, 2, ");
l_exp->accept(*this);
s4o.print(", ");
r_exp->accept(*this);
s4o.print(")");
return NULL;
}
void *print_check_function(symbol_c *type,
symbol_c *value,
symbol_c *fb_name = NULL,
bool temp = false) {
if (!get_datatype_info_c::is_type_valid(type)) ERROR;
bool is_subrange = get_datatype_info_c::is_subrange(type);
if (is_subrange) {
s4o.print("__CHECK_");
type->accept(*this);
s4o.print("(");
}
if (fb_name != NULL) {
s4o.print(GET_VAR);
s4o.print("(");
print_variable_prefix();
fb_name->accept(*this);
s4o.print(".");
value->accept(*this);
s4o.print(")");
}
else {
if (temp)
s4o.print(TEMP_VAR);
value->accept(*this);
}
if (is_subrange)
s4o.print(")");
return NULL;
}
/********************/
/* 2.1.6 - Pragmas */
/********************/
void *visit(enable_code_generation_pragma_c * symbol) {s4o.enable_output(); return NULL;}
void *visit(disable_code_generation_pragma_c * symbol) {s4o.disable_output(); return NULL;}
/* Do not use print_token() as it will change everything into uppercase */
void *visit(pragma_c *symbol) {
s4o.print("#define GetFbVar(var,...) __GET_VAR(data__->var,__VA_ARGS__)\n");
s4o.print(s4o.indent_spaces);
s4o.print("#define SetFbVar(var,val,...) __SET_VAR(data__->,var,__VA_ARGS__,val)\n");
s4o.print(symbol->value);
s4o.print("\n");
s4o.print(s4o.indent_spaces);
s4o.print("#undef GetFbVar\n");
s4o.print(s4o.indent_spaces);
s4o.print("#undef SetFbVar\n");
return NULL;
}
/***************************/
/* B 0 - Programming Model */
/***************************/
/* leave for derived classes... */
/*************************/
/* B.1 - Common elements */
/*************************/
/*******************************************/
/* B 1.1 - Letters, digits and identifiers */
/*******************************************/
void *visit( identifier_c *symbol) {return print_token(symbol);}
void *visit( poutype_identifier_c *symbol) {return print_token(symbol);}
/* If you need the derived_datatype_identifier_c visitor, then you should probably be
* inheriting from generate_c_base_and_typeid_c and not generate_c_base_c !!
*/
void *visit(derived_datatype_identifier_c *symbol) {ERROR; return NULL;}
/*********************/
/* B 1.2 - Constants */
/*********************/
/* originally empty... */
/*********************************/
/* B 1.2.XX - Reference Literals */
/*********************************/
/* defined in IEC 61131-3 v3 - Basically the 'NULL' keyword! */
void *visit(ref_value_null_literal_c *symbol) {s4o.print("NULL"); return NULL;}
/******************************/
/* B 1.2.1 - Numeric Literals */
/******************************/
void *visit(real_c *symbol) {return print_striped_token(symbol);}
void *visit(integer_c *symbol) {return print_striped_token(symbol);}
void *visit(binary_integer_c *symbol) {return print_striped_binary_token(symbol, 2);}
void *visit(octal_integer_c *symbol) {s4o.print("0"); return print_striped_token(symbol, 2);}
void *visit(hex_integer_c *symbol) {s4o.print("0x"); return print_striped_token(symbol, 3);}
void *visit(neg_real_c *symbol) {
s4o.print("-");
symbol->exp->accept(*this);
return NULL;
}
void *visit(neg_integer_c *symbol) {
s4o.print("-");
symbol->exp->accept(*this);
return NULL;
}
void *visit(integer_literal_c *symbol) {return print_literal(symbol->type, symbol->value);}
void *visit(real_literal_c *symbol) {return print_literal(symbol->type, symbol->value);}
void *visit(bit_string_literal_c *symbol) {return print_literal(symbol->type, symbol->value);}
void *visit(boolean_literal_c *symbol) {
if (NULL != symbol->type)
return print_literal(symbol->type, symbol->value);
else {
bool_type_name_c bool_type;
return print_literal(&bool_type, symbol->value);
}
}
/* helper class for boolean_literal_c */
void *visit(boolean_true_c *symbol) {s4o.print("TRUE"); return NULL;}
void *visit(boolean_false_c *symbol) {s4o.print("FALSE"); return NULL;}
void *visit(neg_expression_c *symbol) {
s4o.print("-");
symbol->exp->accept(*this);
return NULL;
}
/*******************************/
/* B.1.2.2 Character Strings */
/*******************************/
void *visit(double_byte_character_string_c *symbol) {
// TO DO ...
ERROR;
return print_token(symbol);
}
void *visit(single_byte_character_string_c *symbol) {
std::string str = "";
unsigned int count = 0;
str += '"';
/* we ignore the first and last bytes, they will be the character ' */
for (unsigned int i = 1; i < strlen(symbol->value) - 1; i++) {
char c = symbol->value[i];
if ((c == '\\') || (c == '"'))
{str += '\\'; str += c; count ++; continue;}
if (c != '$')
{str += c; count++; continue;}
/* this should be safe, since the code has passed the syntax parser!! */
c = symbol->value[++i];
switch (c) {
case '$':
case '\'':
{str += c; count++; continue;}
case 'L':
case 'l':
{str += "\x0A"; /* LF */; count++; continue;}
case 'N':
case 'n':
{str += "\\x0A"; /* NL */; count++; continue;}
case 'P':
case 'p':
{str += "\\f"; /* FF */; count++; continue;}
case 'R':
case 'r':
{str += "\\r"; /* CR */; count++; continue;}
case 'T':
case 't':
{str += "\\t"; /* tab */; count++; continue;}
default: {
if (isxdigit(c)) {
/* this should be safe, since the code has passed the syntax parser!! */
char c2 = symbol->value[++i];
if (isxdigit(c2)) {
str += '\\'; str += 'x'; str += c; str += c2;
count++; continue;
}
}
}
/* otherwise we have an invalid string!! */
/* This should not have got through the syntax parser! */
ERROR;
} /* switch() */
} /* for() */
str += '"';
s4o.print("__STRING_LITERAL(");
s4o.print(count);
s4o.print(",");
s4o.print(str);
s4o.print(")");
return NULL;
}
/***************************/
/* B 1.2.3 - Time Literals */
/***************************/
/************************/
/* B 1.2.3.1 - Duration */
/************************/
/* The following output is actually the parameters to the constructor of the TIME class! */
/* SYM_REF0(neg_time_c) */
void *visit(neg_time_c *symbol) {s4o.print("-1"); /* negative time value */; return NULL;}
/* SYM_REF2(duration_c, neg, interval) */
void *visit(duration_c *symbol) {
TRACE("duration_c");
s4o.print("__time_to_timespec(");
if (NULL == symbol->neg) s4o.print("1"); /* positive time value */
else symbol->neg->accept(*this); /* this will print '-1' :-) */
s4o.print(", ");
symbol->interval->accept(*this);
s4o.print(")");
return NULL;
}
/* SYM_TOKEN(fixed_point_c) */
void *visit(fixed_point_c *symbol) {return print_striped_token(symbol);}
/* SYM_REF5(interval_c, days, hours, minutes, seconds, milliseconds) */
void *visit(interval_c *symbol) {
TRACE("interval_c");
/* s4o.print("0, 0, 0, 0, 0"); // milliseconds, seconds, minutes, hours, days */
if (NULL == symbol->milliseconds) s4o.print("0"); /* milliseconds */
else symbol->milliseconds->accept(*this);
s4o.print(", ");
if (NULL == symbol->seconds) s4o.print("0"); /* seconds */
else symbol->seconds->accept(*this);
s4o.print(", ");
if (NULL == symbol->minutes) s4o.print("0"); /* minutes */
else symbol->minutes->accept(*this);
s4o.print(", ");
if (NULL == symbol->hours) s4o.print("0"); /* hours */
else symbol->hours->accept(*this);
s4o.print(", ");
if (NULL == symbol->days) s4o.print("0"); /* days */
else symbol->days->accept(*this);
return NULL;
}
/************************************/
/* B 1.2.3.2 - Time of day and Date */
/************************************/
/* SYM_REF2(time_of_day_c, daytime, unused) */
void *visit(time_of_day_c *symbol) {
TRACE("time_of_day_c");
s4o.print("__tod_to_timespec(");
symbol->daytime->accept(*this);
s4o.print(")");
return NULL;
}
/* SYM_REF4(daytime_c, day_hour, day_minute, day_second, unused) */
void *visit(daytime_c *symbol) {
TRACE("daytime_c");
symbol->day_second->accept(*this);
s4o.print(", ");
symbol->day_minute->accept(*this);
s4o.print(", ");
symbol->day_hour->accept(*this);
return NULL;
}
/* SYM_REF2(date_c, date_literal, unused) */
void *visit(date_c *symbol) {
TRACE("date_c");
s4o.print("__date_to_timespec(");
symbol->date_literal->accept(*this);
s4o.print(")");
return NULL;
}
/* SYM_REF4(date_literal_c, year, month, day, unused) */
void *visit(date_literal_c *symbol) {
TRACE("date_literal_c");
symbol->day->accept(*this);
s4o.print(", ");
symbol->month->accept(*this);
s4o.print(", ");
symbol->year->accept(*this);
return NULL;
}
/* SYM_REF2(date_and_time_c, date_literal, daytime) */
void *visit(date_and_time_c *symbol) {
TRACE("date_and_time_c");
s4o.print("__dt_to_timespec(");
symbol->daytime->accept(*this);
s4o.print(", ");
symbol->date_literal->accept(*this);
s4o.print(")");
return NULL;
}
/**********************/
/* B.1.3 - Data types */
/**********************/
/***********************************/
/* B 1.3.1 - Elementary Data Types */
/***********************************/
void *visit(time_type_name_c *symbol) {s4o.print("TIME"); return NULL;}
void *visit(bool_type_name_c *symbol) {s4o.print("BOOL"); return NULL;}
void *visit(sint_type_name_c *symbol) {s4o.print("SINT"); return NULL;}
void *visit(int_type_name_c *symbol) {s4o.print("INT"); return NULL;}
void *visit(dint_type_name_c *symbol) {s4o.print("DINT"); return NULL;}
void *visit(lint_type_name_c *symbol) {s4o.print("LINT"); return NULL;}
void *visit(usint_type_name_c *symbol) {s4o.print("USINT"); return NULL;}
void *visit(uint_type_name_c *symbol) {s4o.print("UINT"); return NULL;}
void *visit(udint_type_name_c *symbol) {s4o.print("UDINT"); return NULL;}
void *visit(ulint_type_name_c *symbol) {s4o.print("ULINT"); return NULL;}
void *visit(real_type_name_c *symbol) {s4o.print("REAL"); return NULL;}
void *visit(lreal_type_name_c *symbol) {s4o.print("LREAL"); return NULL;}
void *visit(date_type_name_c *symbol) {s4o.print("DATE"); return NULL;}
void *visit(tod_type_name_c *symbol) {s4o.print("TOD"); return NULL;}
void *visit(dt_type_name_c *symbol) {s4o.print("DT"); return NULL;}
void *visit(byte_type_name_c *symbol) {s4o.print("BYTE"); return NULL;}
void *visit(word_type_name_c *symbol) {s4o.print("WORD"); return NULL;}
void *visit(lword_type_name_c *symbol) {s4o.print("LWORD"); return NULL;}
void *visit(dword_type_name_c *symbol) {s4o.print("DWORD"); return NULL;}
void *visit(string_type_name_c *symbol) {s4o.print("STRING"); return NULL;}
void *visit(wstring_type_name_c *symbol) {s4o.print("WSTRING"); return NULL;}
void *visit(safetime_type_name_c *symbol) {s4o.print("TIME"); return NULL;}
void *visit(safebool_type_name_c *symbol) {s4o.print("BOOL"); return NULL;}
void *visit(safesint_type_name_c *symbol) {s4o.print("SINT"); return NULL;}
void *visit(safeint_type_name_c *symbol) {s4o.print("INT"); return NULL;}
void *visit(safedint_type_name_c *symbol) {s4o.print("DINT"); return NULL;}
void *visit(safelint_type_name_c *symbol) {s4o.print("LINT"); return NULL;}
void *visit(safeusint_type_name_c *symbol) {s4o.print("USINT"); return NULL;}
void *visit(safeuint_type_name_c *symbol) {s4o.print("UINT"); return NULL;}
void *visit(safeudint_type_name_c *symbol) {s4o.print("UDINT"); return NULL;}
void *visit(safeulint_type_name_c *symbol) {s4o.print("ULINT"); return NULL;}
void *visit(safereal_type_name_c *symbol) {s4o.print("REAL"); return NULL;}
void *visit(safelreal_type_name_c *symbol) {s4o.print("LREAL"); return NULL;}
void *visit(safedate_type_name_c *symbol) {s4o.print("DATE"); return NULL;}
void *visit(safetod_type_name_c *symbol) {s4o.print("TOD"); return NULL;}
void *visit(safedt_type_name_c *symbol) {s4o.print("DT"); return NULL;}
void *visit(safebyte_type_name_c *symbol) {s4o.print("BYTE"); return NULL;}
void *visit(safeword_type_name_c *symbol) {s4o.print("WORD"); return NULL;}
void *visit(safelword_type_name_c *symbol) {s4o.print("LWORD"); return NULL;}
void *visit(safedword_type_name_c *symbol) {s4o.print("DWORD"); return NULL;}
void *visit(safestring_type_name_c *symbol) {s4o.print("STRING"); return NULL;}
void *visit(safewstring_type_name_c *symbol) {s4o.print("WSTRING"); return NULL;}
/********************************/
/* B.1.3.2 - Generic data types */
/********************************/
/* Currently only used in REF_TO ANY, which is mapped onto (void *) */
void *visit(generic_type_any_c *symbol) {s4o.print("void"); return NULL;}
/********************************/
/* B 1.3.3 - Derived data types */
/********************************/
/* enumerated_type_name '#' identifier */
void *visit(enumerated_value_c *symbol) {
if (NULL == symbol->datatype) {
debug_c::print(symbol);
ERROR;
}
symbol_c *type_name = get_datatype_info_c::get_id(symbol->datatype);
if (NULL == type_name) {
ERROR_MSG("C code generator does not currently support anonymous enumerated data types.");
}
type_name->accept(*this);
s4o.print("__");
symbol->value->accept(*this);
return NULL;
}
/*********************/
/* B 1.4 - Variables */
/*********************/
void *visit(symbolic_variable_c *symbol) {
TRACE("symbolic_variable_c");
this->print_variable_prefix();
symbol->var_name->accept(*this);
return NULL;
}
/* symbolic_constant_c is used only when a variable is used inside the subrange of an array declaration
* e.g.: ARRAY [1 .. maxval] OF INT
* where maxval is a CONSTANT variable.
* When maxval shows up in the POU body, it will be stored as a standard symbolic_variable_c in the AST.
* When maxval shows up in the ARRAY declaration, it will be stored as a symbolic_constant_c in the AST.
* This will allow us to more easily handle this special case, without affecting the remaining working code.
*/
// a non-standard extension!!
void *visit(symbolic_constant_c *symbol) {
TRACE("symbolic_variable_c");
if (symbol->const_value. _int64.is_valid()) s4o.print(symbol->const_value. _int64.get());
else if (symbol->const_value._uint64.is_valid()) s4o.print(symbol->const_value._uint64.get());
else ERROR;
return NULL;
}
/********************************************/
/* B.1.4.1 Directly Represented Variables */
/********************************************/
void *visit(direct_variable_c *symbol) {
TRACE("direct_variable_c");
/* Do not use print_token() as it will change everything into uppercase */
return s4o.printlocation(symbol->value+1); // '+1' so we do not print the '%' in '%IW3.2'
}
/*************************************/
/* B.1.4.2 Multi-element Variables */
/*************************************/
/* subscripted_variable '[' subscript_list ']' */
//SYM_REF2(array_variable_c, subscripted_variable, subscript_list)
/* record_variable '.' field_selector */
/* WARNING: input and/or output variables of function blocks
* may be accessed as fields of a structured variable!
* Code handling a structured_variable_c must take
* this into account!
*/
// SYM_REF2(structured_variable_c, record_variable, field_selector)
// TODO: It seems to me this code no longer gets to execute, since the function is overloaded in generate_c_st_c and generate_c_il_c
// I will have to check this later, and delete this code if the above is really true!
void *visit(structured_variable_c *symbol) {
TRACE("structured_variable_c");
symbol->record_variable->accept(*this);
s4o.print(".");
symbol->field_selector->accept(*this);
return NULL;
}
/******************************************/
/* B 1.4.3 - Declaration & Initialisation */
/******************************************/
/* leave for derived classes... */
/**************************************/
/* B.1.5 - Program organization units */
/**************************************/
/***********************/
/* B 1.5.1 - Functions */
/***********************/
/* leave for derived classes... */
/*****************************/
/* B 1.5.2 - Function Blocks */
/*****************************/
/* leave for derived classes... */
/**********************/
/* B 1.5.3 - Programs */
/**********************/
/* leave for derived classes... */
/*********************************************/
/* B.1.6 Sequential function chart elements */
/*********************************************/
/********************************/
/* B 1.7 Configuration elements */
/********************************/
/* leave for derived classes... */
/****************************************/
/* B.2 - Language IL (Instruction List) */
/****************************************/
/***********************************/
/* B 2.1 Instructions and Operands */
/***********************************/
/* leave for derived classes... */
/*******************/
/* B 2.2 Operators */
/*******************/
/* leave for derived classes... */
/***************************************/
/* B.3 - Language ST (Structured Text) */
/***************************************/
/***********************/
/* B 3.1 - Expressions */
/***********************/
/* leave for derived classes... */
/********************/
/* B 3.2 Statements */
/********************/
/* leave for derived classes... */
/*********************************/
/* B 3.2.1 Assignment Statements */
/*********************************/
/* leave for derived classes... */
/*****************************************/
/* B 3.2.2 Subprogram Control Statements */
/*****************************************/
/* leave for derived classes... */
/********************************/
/* B 3.2.3 Selection Statements */
/********************************/
/* leave for derived classes... */
/********************************/
/* B 3.2.4 Iteration Statements */
/********************************/
/* leave for derived classes... */
}; /* class generate_c_basic_c */
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/************************************************************************************************/
/* generate_c_base_and_typeid_c
* ----------------------------
* This is similar to the generate_c_base_c (from which it inherits), but it also handles
* all the derived datatypes. Note that it does not generate C code for the declaration of
* those datatypes (that is what generate_c_typedecl_c is for), but rather it merely
* generates the name/id of a derived datatype.
* Note too that not all derived datatypes in the IEC 61131-3 have a name (for example,
* VAR a: ARRAY [3..5] of INT END_VAR), in which case an alias for this datatype should
* have been previously generated by either generate_c_typedecl_c or generate_implicit_typedecl_c.
*/
class generate_c_base_and_typeid_c: public generate_c_base_c {
public:
generate_c_base_and_typeid_c(stage4out_c *s4o_ptr): generate_c_base_c(s4o_ptr) {}
~generate_c_base_and_typeid_c(void) {}
/*************************/
/* B.1 - Common elements */
/*************************/
/*******************************************/
/* B 1.1 - Letters, digits and identifiers */
/*******************************************/
void *visit(derived_datatype_identifier_c *symbol) {
if (get_datatype_info_c::is_array(symbol->datatype)) {
return symbol->datatype->accept(*this);
}
return print_token(symbol);
}
/*********************/
/* B 1.2 - Constants */
/*********************/
/**********************/
/* B.1.3 - Data types */
/**********************/
/***********************************/
/* B 1.3.1 - Elementary Data Types */
/***********************************/
/********************************/
/* B.1.3.2 - Generic data types */
/********************************/
/* Currently only used in REF_TO ANY, which is mapped onto (void *) */
void *visit(generic_type_any_c *symbol) {s4o.print("void"); return NULL;}
/********************************/
/* B 1.3.3 - Derived data types */
/********************************/
/* subrange_type_name ':' subrange_spec_init */
void *visit(subrange_type_declaration_c *symbol) {return symbol->subrange_type_name->accept(*this);}
/* subrange_specification ASSIGN signed_integer */
void *visit(subrange_spec_init_c *symbol) {return symbol->subrange_specification->accept(*this);}
/* integer_type_name '(' subrange')' */
void *visit(subrange_specification_c *symbol) {return symbol->integer_type_name->accept(*this);}
/* enumerated_type_name ':' enumerated_spec_init */
void *visit(enumerated_type_declaration_c *symbol) {return symbol->enumerated_type_name->accept(*this);}
/* enumerated_specification ASSIGN enumerated_value */
void *visit(enumerated_spec_init_c *symbol) {return symbol->enumerated_specification->accept(*this);}
/* enumerated_type_name '#' identifier */
/* Handled by generate_c_base_c class!!
void *visit(enumerated_value_c *symbol) {}
*/
/* identifier ':' array_spec_init */
void *visit(array_type_declaration_c *symbol) {
int implicit_id_count = symbol->anotations_map.count("generate_c_annotaton__implicit_type_id");
if (1 != implicit_id_count) ERROR;
return symbol->anotations_map["generate_c_annotaton__implicit_type_id"]->accept(*this);
}
/* array_specification [ASSIGN array_initialization] */
/* array_initialization may be NULL ! */
void *visit(array_spec_init_c *symbol) {
int implicit_id_count = symbol->anotations_map.count("generate_c_annotaton__implicit_type_id");
if (1 == implicit_id_count) return symbol->anotations_map["generate_c_annotaton__implicit_type_id"]->accept(*this);
if (0 == implicit_id_count) return symbol->datatype->accept(*this);
return NULL;
}
/* ARRAY '[' array_subrange_list ']' OF non_generic_type_name */
void *visit(array_specification_c *symbol) {
int implicit_id_count = symbol->anotations_map.count("generate_c_annotaton__implicit_type_id");
if (1 != implicit_id_count) ERROR;
return symbol->anotations_map["generate_c_annotaton__implicit_type_id"]->accept(*this);
}
/* simple_type_name ':' simple_spec_init */
void *visit(simple_type_declaration_c *symbol) {return symbol->simple_type_name->accept(*this);}
/* simple_specification [ASSIGN constant] */
//SYM_REF2(simple_spec_init_c, simple_specification, constant)
// <constant> may be NULL
void *visit(simple_spec_init_c *symbol) {return symbol->simple_specification->accept(*this);}
/* structure_type_name ':' structure_specification */
//SYM_REF2(structure_type_declaration_c, structure_type_name, structure_specification)
void *visit(structure_type_declaration_c *symbol) {return symbol->structure_type_name->accept(*this);}
/* structure_type_name ASSIGN structure_initialization */
/* structure_initialization may be NULL ! */
//SYM_REF2(initialized_structure_c, structure_type_name, structure_initialization)
void *visit(initialized_structure_c *symbol) {return symbol->structure_type_name->accept(*this);}
/* ref_spec: REF_TO (non_generic_type_name | function_block_type_name) */
// SYM_REF1(ref_spec_c, type_name)
void *visit(ref_spec_c *symbol) {
int implicit_id_count = symbol->anotations_map.count("generate_c_annotaton__implicit_type_id");
if (implicit_id_count > 1) ERROR;
if (implicit_id_count == 1) {
/* this is part of an implicitly declared datatype (i.e. inside a variable decaration), for which an equivalent C datatype
* has already been defined. So, we simly print out the id of that C datatpe...
*/
return symbol->anotations_map["generate_c_annotaton__implicit_type_id"]->accept(*this);
}
/* This is NOT part of an implicitly declared datatype (i.e. we are being called from an visit(ref_type_decl_c *),
* through the visit(ref_spec_init_c*)), so we need to simply print out the name of the datatype we reference to.
*/
//debug_c::print(symbol); ERROR;
symbol->type_name->accept(*this);
s4o.print("*");
return NULL;
}
/* For the moment, we do not support initialising reference data types */
/* ref_spec_init: ref_spec [ ASSIGN ref_initialization ] */
/* NOTE: ref_initialization may be NULL!! */
// SYM_REF2(ref_spec_init_c, ref_spec, ref_initialization)
void *visit(ref_spec_init_c *symbol) {
/* NOTE An ref_type_decl_c will be created in stage4 for each implicitly defined REF_TO datatype,
* and this generate_c_typedecl_c will be called to define that REF_TO datatype in C.
* However, every implictly defined REF_TO datatype with the exact same parameters will be mapped
* to the same identifier (e.g: __REF_TO_INT).
* In order for the C compiler not to find the same datatype being defined two or more times,
* we will keep track of the datatypes that have already been declared, and henceforth
* only declare the datatypes that have not been previously defined.
*/
int implicit_id_count = symbol->anotations_map.count("generate_c_annotaton__implicit_type_id");
if (1 < implicit_id_count) ERROR;
if (1 == implicit_id_count)
return symbol->anotations_map["generate_c_annotaton__implicit_type_id"]->accept(*this);
return symbol->ref_spec->accept(*this); // this is probably pointing to an ***_identifier_c !!
}
/* ref_type_decl: identifier ':' ref_spec_init */
// SYM_REF2(ref_type_decl_c, ref_type_name, ref_spec_init)
void *visit(ref_type_decl_c *symbol) {
TRACE("ref_type_decl_c");
/* NOTE An ref_type_decl_c will be created in stage4 for each implicitly defined REF_TO datatype,
* and this generate_c_typedecl_c will be called to define that REF_TO datatype in C.
* However, every implictly defined REF_TO datatype with the exact same parameters will be mapped
* to the same identifier (e.g: __REF_TO_INT).
* In order for the C compiler not to find the same datatype being defined two or more times,
* we will keep track of the datatypes that have already been declared, and henceforth
* only declare the datatypes that have not been previously defined.
*/
int implicit_id_count = symbol->anotations_map.count("generate_c_annotaton__implicit_type_id");
if (0 != implicit_id_count) ERROR;
//symbol->anotations_map["generate_c_annotaton__implicit_type_id"]->accept(generate_c_base);
return symbol->ref_type_name->accept(*this);
}
}; /* class generate_c_base_and_typeid_c */