lbessard@70: /*
Edouard@279: * matiec - a compiler for the programming languages defined in IEC 61131-3
lbessard@70: *
Edouard@279: * Copyright (C) 2003-2011 Mario de Sousa (msousa@fe.up.pt)
Edouard@279: * Copyright (C) 2007-2011 Laurent Bessard and Edouard Tisserant
lbessard@70: *
Edouard@279: * This program is free software: you can redistribute it and/or modify
Edouard@279: * it under the terms of the GNU General Public License as published by
Edouard@279: * the Free Software Foundation, either version 3 of the License, or
Edouard@279: * (at your option) any later version.
Edouard@279: *
Edouard@279: * This program is distributed in the hope that it will be useful,
Edouard@279: * but WITHOUT ANY WARRANTY; without even the implied warranty of
Edouard@279: * MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
Edouard@279: * GNU General Public License for more details.
Edouard@279: *
Edouard@279: * You should have received a copy of the GNU General Public License
Edouard@279: * along with this program. If not, see .
Edouard@279: *
lbessard@70: *
lbessard@70: * This code is made available on the understanding that it will not be
lbessard@70: * used in safety-critical situations without a full and competent review.
lbessard@70: */
lbessard@70:
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70:
lbessard@70: /* Returns the data type of an il_operand.
lbessard@70: *
lbessard@70: * Note that the il_operand may be a variable, in which case
lbessard@70: * we return the type of the variable instance.
lbessard@70: * The il_operand may also be a constant, in which case
lbessard@70: * we return the data type of that constant.
lbessard@70: *
lbessard@70: * The variable instance may be a member of a structured variable,
lbessard@70: * or an element in an array, or any combination of the two.
lbessard@70: *
lbessard@70: * The class constructor must be given the search scope
lbessard@70: * (function, function block or program within which
lbessard@70: * the possible il_operand variable instance was declared).
lbessard@70: */
lbessard@70:
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70:
lbessard@70:
msousa@682: /* A new class to ouput the IL implicit variable to c++ code
lbessard@70: * We use this class, inheriting from symbol_c, so it may be used
lbessard@70: * as any other symbol_c object in the intermediate parse tree,
lbessard@70: * more specifically, so it can be used as any other il operand.
lbessard@70: * This makes the rest of the code much easier...
lbessard@70: *
lbessard@70: * Nevertheless, the basic visitor class visitor_c does not know
lbessard@70: * how to visit this new il_default_variable_c class, so we have
lbessard@70: * to extend that too.
lbessard@70: * In reality extending the basic symbols doesn't quite work out
lbessard@70: * as cleanly as desired (we need to use dynamic_cast in the
lbessard@70: * accept method of the il_default_variable_c), but it is cleaner
lbessard@70: * than the alternative...
lbessard@70: */
lbessard@70: class il_default_variable_c;
lbessard@70:
lbessard@70: /* This visitor class is not really required, we could place the
lbessard@70: * visit() method directly in genertae_cc_il_c, but doing it in
lbessard@70: * a seperate class makes the architecture more evident...
lbessard@70: */
lbessard@70: class il_default_variable_visitor_c {
lbessard@70: public:
lbessard@70: virtual void *visit(il_default_variable_c *symbol) = 0;
lbessard@70:
lbessard@70: virtual ~il_default_variable_visitor_c(void) {return;}
lbessard@70: };
lbessard@70:
lbessard@70:
lbessard@70: /* A class to print out to the resulting C++ code
msousa@682: * the IL implicit variable name.
lbessard@70: *
lbessard@70: * It includes a reference to its name,
lbessard@70: * and the data type of the data currently stored
lbessard@70: * in this C++ variable... This is required because the
lbessard@70: * C++ variable is a union, and we must know which member
lbessard@70: * of the union top reference!!
lbessard@70: *
lbessard@70: * Note that we also need to keep track of the data type of
msousa@682: * the value currently being stored in the IL implicit variable.
lbessard@70: * This is required so we can process parenthesis,
lbessard@70: *
lbessard@70: * e.g. :
lbessard@70: * LD var1
lbessard@70: * AND (
lbessard@70: * LD var2
lbessard@70: * OR var3
lbessard@70: * )
lbessard@70: *
lbessard@70: * Note that we only execute the 'AND (' operation when we come across
lbessard@70: * the ')', i.e. once we have evaluated the result of the
lbessard@70: * instructions inside the parenthesis.
lbessard@70: * When we do execute the 'AND (' operation, we need to know the data type
lbessard@70: * of the operand, which in this case is the result of the evaluation of the
lbessard@70: * instruction list inside the parenthesis. We can only know this if we
msousa@682: * keep track of the data type currently stored in the IL implicit variable!
lbessard@70: *
lbessard@70: * We use the current_type inside the generate_c_il::default_variable_name variable
lbessard@70: * to track this!
lbessard@70: */
lbessard@70: class il_default_variable_c: public symbol_c {
lbessard@70: public:
lbessard@70: symbol_c *var_name; /* in principle, this should point to an indentifier_c */
lbessard@70:
lbessard@70: public:
lbessard@70: il_default_variable_c(const char *var_name_str, symbol_c *current_type);
lbessard@70: virtual void *accept(visitor_c &visitor);
lbessard@70: };
lbessard@70:
lbessard@70:
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70: /***********************************************************************/
lbessard@70:
lbessard@70:
lbessard@70:
msousa@669:
msousa@669:
lbessard@70: class generate_c_il_c: public generate_c_typedecl_c, il_default_variable_visitor_c {
lbessard@70:
laurent@217: public:
laurent@217: typedef enum {
laurent@217: expression_vg,
laurent@217: assignment_vg,
berem@228: complextype_base_vg,
laurent@392: complextype_base_assignment_vg,
berem@228: complextype_suffix_vg,
laurent@217: fparam_output_vg
laurent@217: } variablegeneration_t;
laurent@217:
lbessard@70: private:
msousa@682: /* Label to which the current IL jump operation should jump to... */
msousa@682: /* This variable is used to pass data from the
msousa@682: * il_jump_operation_c visitor
msousa@682: * to the il jump operator visitors (i.e. JMP_operator_c,
msousa@682: * JMPC_operator_c, JMPCN_operator_c, ...)
lbessard@70: */
msousa@682: symbol_c *jump_label;
msousa@682:
msousa@682: /* the data type of the IL implicit variable... */
msousa@682: #define IL_DEFVAR_T VAR_LEADER "IL_DEFVAR_T"
msousa@682: /* The name of the IL implicit variable... */
msousa@682: #define IL_DEFVAR VAR_LEADER "IL_DEFVAR"
msousa@682: /* The name of the variable used to pass the result of a
msousa@682: * parenthesised instruction list to the immediately preceding
msousa@682: * scope ...
lbessard@70: */
msousa@682: #define IL_DEFVAR_BACK VAR_LEADER "IL_DEFVAR_BACK"
msousa@682:
msousa@682: il_default_variable_c implicit_variable_current; /* the current implicit variable, with the datatype resulting from the previous IL operation */
msousa@682: il_default_variable_c implicit_variable_result; /* the resulting implicit variable, with the datatype resulting from the current IL operation */
msousa@682: il_default_variable_c implicit_variable_result_back;
msousa@682:
lbessard@70: /* Operand to the IL operation currently being processed... */
lbessard@70: /* These variables are used to pass data from the
lbessard@70: * il_simple_operation_c and il_expression_c visitors
lbessard@70: * to the il operator visitors (i.e. LD_operator_c,
lbessard@70: * LDN_operator_c, ST_operator_c, STN_operator_c, ...)
lbessard@70: */
lbessard@70: symbol_c *current_operand;
lbessard@70:
lbessard@70: /* When calling a function block, we must first find it's type,
lbessard@70: * by searching through the declarations of the variables currently
lbessard@70: * in scope.
lbessard@70: * This class does just that...
lbessard@70: * A new class is instantiated whenever we begin generating the code
lbessard@70: * for a function block type declaration, or a program declaration.
lbessard@70: * This object instance will then later be called while the
lbessard@70: * function block's or the program's body is being handled.
lbessard@70: *
lbessard@70: * Note that functions cannot contain calls to function blocks,
lbessard@70: * so we do not create an object instance when handling
lbessard@70: * a function declaration.
lbessard@70: */
lbessard@70: search_fb_instance_decl_c *search_fb_instance_decl;
lbessard@70:
lbessard@98: search_varfb_instance_type_c *search_varfb_instance_type;
msousa@505: search_var_instance_decl_c *search_var_instance_decl;
lbessard@98:
berem@228: symbol_c* current_array_type;
laurent@235: symbol_c* current_param_type;
berem@228:
laurent@217: int fcall_number;
laurent@217: symbol_c *fbname;
laurent@217:
laurent@217: variablegeneration_t wanted_variablegeneration;
lbessard@146:
lbessard@70: public:
laurent@217: generate_c_il_c(stage4out_c *s4o_ptr, symbol_c *name, symbol_c *scope, const char *variable_prefix = NULL)
lbessard@70: : generate_c_typedecl_c(s4o_ptr),
msousa@682: implicit_variable_current (IL_DEFVAR, NULL),
msousa@682: implicit_variable_result (IL_DEFVAR, NULL),
msousa@682: implicit_variable_result_back(IL_DEFVAR_BACK, NULL)
lbessard@70: {
msousa@669: search_fb_instance_decl = new search_fb_instance_decl_c (scope);
lbessard@98: search_varfb_instance_type = new search_varfb_instance_type_c(scope);
msousa@669: search_var_instance_decl = new search_var_instance_decl_c (scope);
msousa@505:
lbessard@70: current_operand = NULL;
berem@228: current_array_type = NULL;
laurent@235: current_param_type = NULL;
laurent@217: fcall_number = 0;
laurent@217: fbname = name;
laurent@217: wanted_variablegeneration = expression_vg;
lbessard@70: this->set_variable_prefix(variable_prefix);
lbessard@70: }
lbessard@70:
lbessard@70: virtual ~generate_c_il_c(void) {
lbessard@70: delete search_fb_instance_decl;
lbessard@98: delete search_varfb_instance_type;
msousa@505: delete search_var_instance_decl;
lbessard@70: }
lbessard@70:
lbessard@70: void generate(instruction_list_c *il) {
lbessard@70: il->accept(*this);
lbessard@70: }
lbessard@70:
msousa@682: private:
msousa@682: /* Declare an implicit IL variable... */
msousa@682: void declare_implicit_variable(il_default_variable_c *implicit_var) {
lbessard@70: s4o.print(s4o.indent_spaces);
lbessard@70: s4o.print(IL_DEFVAR_T);
lbessard@70: s4o.print(" ");
msousa@682: implicit_var->datatype = NULL;
msousa@682: implicit_var->accept(*this);
lbessard@70: s4o.print(";\n");
lbessard@70: }
lbessard@70:
msousa@682: public:
msousa@682: /* Declare the default variable, that will store the result of the IL operations */
msousa@682: void declare_implicit_variable(void) {
msousa@682: declare_implicit_variable(&this->implicit_variable_result);
msousa@682: }
msousa@682:
msousa@682: /* Declare the backup to the default variable, that will store the result of the IL operations executed inside a parenthesis... */
msousa@682: void declare_implicit_variable_back(void) {
msousa@682: declare_implicit_variable(&this->implicit_variable_result_back);
msousa@682: }
msousa@682:
msousa@682: void print_implicit_variable_back(void) {
msousa@682: this->implicit_variable_result_back.accept(*this);
msousa@682: }
msousa@682:
laurent@392:
lbessard@70: private:
msousa@669: /* a small helper function */
msousa@669: symbol_c *default_literal_type(symbol_c *symbol) {
msousa@669: if (get_datatype_info_c::is_ANY_INT_literal(symbol)) {
msousa@693: return &get_datatype_info_c::lint_type_name;
msousa@669: }
msousa@669: else if (get_datatype_info_c::is_ANY_REAL_literal(symbol)) {
msousa@693: return &get_datatype_info_c::lreal_type_name;
msousa@669: }
msousa@669: return symbol;
msousa@669: }
lbessard@70:
lbessard@70: /* A helper function... */
lbessard@70: void *XXX_operator(symbol_c *lo, const char *op, symbol_c *ro) {
msousa@669: if ((NULL == lo) || (NULL == ro) || (NULL == op)) ERROR;
lbessard@70:
lbessard@70: lo->accept(*this);
lbessard@70: s4o.print(op);
lbessard@70: ro->accept(*this);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: /* A helper function... */
msousa@682: void *XXX_function(symbol_c *res, const char *func, symbol_c *lo, symbol_c *ro) {
msousa@682: if ((NULL == res) || (NULL == lo) || (NULL == ro)) ERROR;
msousa@682: if (NULL == func) ERROR;
msousa@682:
msousa@682: res->accept(*this);
lbessard@70: s4o.print(" = ");
lbessard@70: s4o.print(func);
lbessard@70: s4o.print("(");
lbessard@70: lo->accept(*this);
lbessard@70: s4o.print(", ");
lbessard@70: ro->accept(*this);
lbessard@70: s4o.print(")");
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
msousa@682: /* A helper function... used for implicit FB calls: S1, R1, CLK, CU, CD, PV, IN, and PT */
lbessard@70: void *XXX_CAL_operator(const char *param_name, symbol_c *fb_name) {
laurent@382: if (wanted_variablegeneration != expression_vg) {
laurent@382: s4o.print(param_name);
laurent@382: return NULL;
laurent@382: }
laurent@382:
lbessard@70: if (NULL == fb_name) ERROR;
lbessard@70: symbolic_variable_c *sv = dynamic_cast(fb_name);
lbessard@70: if (NULL == sv) ERROR;
lbessard@70: identifier_c *id = dynamic_cast(sv->var_name);
lbessard@70: if (NULL == id) ERROR;
ccb@202:
lbessard@70: identifier_c param(param_name);
lbessard@70:
lbessard@70: //SYM_REF3(il_param_assignment_c, il_assign_operator, il_operand, simple_instr_list)
ccb@202: il_assign_operator_c il_assign_operator(¶m);
msousa@682: il_param_assignment_c il_param_assignment(&il_assign_operator, &this->implicit_variable_current, NULL);
lbessard@70: // SYM_LIST(il_param_list_c)
ccb@202: il_param_list_c il_param_list;
lbessard@70: il_param_list.add_element(&il_param_assignment);
lbessard@70: CAL_operator_c CAL_operator;
lbessard@70: // SYM_REF4(il_fb_call_c, il_call_operator, fb_name, il_operand_list, il_param_list)
lbessard@70: il_fb_call_c il_fb_call(&CAL_operator, id, NULL, &il_param_list);
lbessard@70:
lbessard@70: il_fb_call.accept(*this);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: /* A helper function... */
msousa@682: void *CMP_operator(symbol_c *operand, const char *operation) {
msousa@682: if (NULL == operand) ERROR;
msousa@682: if (NULL == operand->datatype) ERROR;
msousa@682: if (NULL == this->implicit_variable_current.datatype) ERROR;
msousa@682:
msousa@682: this->implicit_variable_result.accept(*this);
lbessard@70: s4o.print(" = ");
lbessard@70: s4o.print(operation);
msousa@682: operand->datatype->accept(*this);
msousa@682: /* NOTE: we are calling a standard Function:
msousa@682: * 1st parameter: EN (enable)
msousa@682: * 2nd parameter: ENO (enable output)
msousa@682: * 3rd parameter: number of operands we will be passing (required because we are calling an extensible standard function!)
msousa@682: * 4th parameter: the left hand side of the comparison expression (in out case, the IL implicit variable)
msousa@682: * 4th parameter: the right hand side of the comparison expression (in out case, current operand)
msousa@682: */
lbessard@149: s4o.print("(__BOOL_LITERAL(TRUE), NULL, 2, ");
msousa@682: this->implicit_variable_current.accept(*this);
lbessard@70: s4o.print(", ");
msousa@682: operand->accept(*this);
lbessard@70: s4o.print(")");
lbessard@70:
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70: /* A helper function... */
lbessard@70: void C_modifier(void) {
msousa@682: if (!get_datatype_info_c::is_BOOL_compatible(implicit_variable_current.datatype)) ERROR;
msousa@682: s4o.print("if (");
msousa@682: this->implicit_variable_current.accept(*this);
msousa@682: s4o.print(") ");
lbessard@70: }
lbessard@70:
lbessard@70: /* A helper function... */
lbessard@70: void CN_modifier(void) {
msousa@682: if (!get_datatype_info_c::is_BOOL_compatible(implicit_variable_current.datatype)) ERROR;
msousa@682: s4o.print("if (!");
msousa@682: this->implicit_variable_current.accept(*this);
msousa@682: s4o.print(") ");
msousa@682: }
msousa@682:
laurent@210:
berem@228: void *print_getter(symbol_c *symbol) {
msousa@505: unsigned int vartype = search_var_instance_decl->get_vartype(symbol);
laurent@235: if (wanted_variablegeneration == fparam_output_vg) {
Laurent@706: if (vartype == search_var_instance_decl_c::external_vt) {
Laurent@706: if (search_var_instance_decl->type_is_fb(symbol))
Laurent@706: s4o.print(GET_EXTERNAL_FB_BY_REF);
Laurent@706: else
Laurent@706: s4o.print(GET_EXTERNAL_BY_REF);
Laurent@706: }
laurent@235: else if (vartype == search_var_instance_decl_c::located_vt)
laurent@235: s4o.print(GET_LOCATED_BY_REF);
laurent@235: else
laurent@235: s4o.print(GET_VAR_BY_REF);
laurent@235: }
laurent@235: else {
Laurent@706: if (vartype == search_var_instance_decl_c::external_vt) {
Laurent@706: if (search_var_instance_decl->type_is_fb(symbol))
Laurent@706: s4o.print(GET_EXTERNAL_FB);
Laurent@706: else
Laurent@706: s4o.print(GET_EXTERNAL);
Laurent@706: }
Laurent@706: else if (vartype == search_var_instance_decl_c::located_vt)
Laurent@706: s4o.print(GET_LOCATED);
Laurent@706: else
Laurent@706: s4o.print(GET_VAR);
laurent@235: }
berem@228: s4o.print("(");
berem@228:
laurent@235: variablegeneration_t old_wanted_variablegeneration = wanted_variablegeneration;
berem@228: wanted_variablegeneration = complextype_base_vg;
berem@228: symbol->accept(*this);
msousa@531: if (search_var_instance_decl->type_is_complex(symbol))
laurent@235: s4o.print(",");
berem@228: wanted_variablegeneration = complextype_suffix_vg;
berem@228: symbol->accept(*this);
berem@228: s4o.print(")");
laurent@235: wanted_variablegeneration = old_wanted_variablegeneration;
berem@228: return NULL;
berem@228: }
berem@228:
berem@228: void *print_setter(symbol_c* symbol,
Laurent@706: symbol_c* type,
Laurent@706: symbol_c* value,
Laurent@706: symbol_c* fb_symbol = NULL,
Laurent@706: symbol_c* fb_value = NULL,
Laurent@706: bool negative = false) {
Laurent@706:
Laurent@706: bool type_is_complex = search_var_instance_decl->type_is_complex(symbol);
laurent@405: if (fb_symbol == NULL) {
msousa@505: unsigned int vartype = search_var_instance_decl->get_vartype(symbol);
Laurent@706: if (vartype == search_var_instance_decl_c::external_vt) {
Laurent@706: if (search_var_instance_decl->type_is_fb(symbol))
Laurent@706: s4o.print(SET_EXTERNAL_FB);
Laurent@706: else
Laurent@706: s4o.print(SET_EXTERNAL);
Laurent@706: }
laurent@405: else if (vartype == search_var_instance_decl_c::located_vt)
laurent@405: s4o.print(SET_LOCATED);
laurent@405: else
laurent@405: s4o.print(SET_VAR);
laurent@405: }
Laurent@706: else {
Laurent@706: unsigned int vartype = search_var_instance_decl->get_vartype(fb_symbol);
Laurent@706: if (vartype == search_var_instance_decl_c::external_vt)
Laurent@706: s4o.print(SET_EXTERNAL_FB);
Laurent@706: else
Laurent@706: s4o.print(SET_VAR);
Laurent@706: }
laurent@392: s4o.print("(");
berem@228:
berem@228: if (fb_symbol != NULL) {
berem@228: print_variable_prefix();
berem@228: fb_symbol->accept(*this);
laurent@392: s4o.print(".,");
berem@228: }
laurent@382: else if (type_is_complex)
laurent@392: wanted_variablegeneration = complextype_base_assignment_vg;
berem@228: else
laurent@382: wanted_variablegeneration = assignment_vg;
laurent@382:
berem@228: symbol->accept(*this);
berem@228: s4o.print(",");
berem@228: if (negative) {
mjsousa@835: if (get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype))
Laurent@706: s4o.print("!");
Laurent@706: else
Laurent@706: s4o.print("~");
berem@228: }
berem@228: wanted_variablegeneration = expression_vg;
berem@228: print_check_function(type, value, fb_value);
laurent@382: if (type_is_complex) {
berem@228: s4o.print(",");
berem@228: wanted_variablegeneration = complextype_suffix_vg;
berem@228: symbol->accept(*this);
berem@228: }
berem@228: s4o.print(")");
berem@228: wanted_variablegeneration = expression_vg;
berem@228: return NULL;
berem@228: }
lbessard@70:
lbessard@70: public:
lbessard@70: void *visit(il_default_variable_c *symbol) {
lbessard@70: symbol->var_name->accept(*this);
msousa@682: if (NULL != symbol->datatype) {
lbessard@70: s4o.print(".");
msousa@682: symbol->datatype->accept(*this);
lbessard@70: s4o.print("var");
agraeper@563: } return NULL;
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70: private:
lbessard@70:
ccb@202:
lbessard@146:
laurent@377: /********************************/
laurent@377: /* B 1.3.3 - Derived data types */
laurent@377: /********************************/
laurent@377:
laurent@382: /* signed_integer DOTDOT signed_integer */
laurent@382: void *visit(subrange_c *symbol) {
laurent@382: symbol->lower_limit->accept(*this);
laurent@382: return NULL;
laurent@382: }
laurent@382:
laurent@377: /* ARRAY '[' array_subrange_list ']' OF non_generic_type_name */
laurent@377: void *visit(array_specification_c *symbol) {
laurent@377: symbol->non_generic_type_name->accept(*this);
laurent@377: return NULL;
laurent@377: }
laurent@377:
lbessard@146: /*********************/
lbessard@146: /* B 1.4 - Variables */
lbessard@146: /*********************/
laurent@221:
lbessard@146: void *visit(symbolic_variable_c *symbol) {
berem@228: unsigned int vartype;
laurent@382: switch (wanted_variablegeneration) {
laurent@392: case complextype_base_assignment_vg:
laurent@392: case assignment_vg:
laurent@392: this->print_variable_prefix();
laurent@392: s4o.print(",");
laurent@392: symbol->var_name->accept(*this);
laurent@392: break;
laurent@382: case complextype_base_vg:
laurent@221: generate_c_base_c::visit(symbol);
laurent@382: break;
laurent@382: case complextype_suffix_vg:
Laurent@706: break;
laurent@382: default:
laurent@382: if (this->is_variable_prefix_null()) {
Laurent@706: vartype = search_var_instance_decl->get_vartype(symbol);
laurent@382: if (wanted_variablegeneration == fparam_output_vg) {
laurent@382: s4o.print("&(");
laurent@382: generate_c_base_c::visit(symbol);
laurent@382: s4o.print(")");
laurent@382: }
laurent@382: else {
laurent@382: generate_c_base_c::visit(symbol);
laurent@382: }
laurent@382: }
laurent@382: else
laurent@382: print_getter(symbol);
laurent@382: break;
laurent@382: }
lbessard@146: return NULL;
lbessard@146: }
lbessard@146:
lbessard@70: /********************************************/
lbessard@70: /* B.1.4.1 Directly Represented Variables */
lbessard@70: /********************************************/
lbessard@70: // direct_variable: direct_variable_token {$$ = new direct_variable_c($1);};
lbessard@70: void *visit(direct_variable_c *symbol) {
lbessard@70: TRACE("direct_variable_c");
lbessard@70: /* Do not use print_token() as it will change everything into uppercase */
lbessard@70: if (strlen(symbol->value) == 0) ERROR;
laurent@217: if (this->is_variable_prefix_null()) {
laurent@217: if (wanted_variablegeneration != fparam_output_vg)
Laurent@706: s4o.print("*(");
laurent@217: }
laurent@217: else {
laurent@217: switch (wanted_variablegeneration) {
laurent@217: case expression_vg:
Laurent@706: s4o.print(GET_LOCATED);
Laurent@706: s4o.print("(");
Laurent@706: break;
laurent@217: case fparam_output_vg:
laurent@217: s4o.print(GET_LOCATED_BY_REF);
laurent@217: s4o.print("(");
laurent@217: break;
laurent@217: default:
laurent@217: break;
laurent@217: }
lbessard@146: }
lbessard@70: this->print_variable_prefix();
lbessard@70: s4o.printlocation(symbol->value + 1);
laurent@217: if ((this->is_variable_prefix_null() && wanted_variablegeneration != fparam_output_vg) ||
Laurent@706: wanted_variablegeneration != assignment_vg)
lbessard@146: s4o.print(")");
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
berem@228: /*************************************/
berem@228: /* B.1.4.2 Multi-element Variables */
berem@228: /*************************************/
berem@228:
berem@228: // SYM_REF2(structured_variable_c, record_variable, field_selector)
berem@228: void *visit(structured_variable_c *symbol) {
berem@228: TRACE("structured_variable_c");
Laurent@625: bool type_is_complex = search_var_instance_decl->type_is_complex(symbol->record_variable);
berem@228: switch (wanted_variablegeneration) {
berem@228: case complextype_base_vg:
laurent@392: case complextype_base_assignment_vg:
berem@228: symbol->record_variable->accept(*this);
Laurent@410: if (!type_is_complex) {
Laurent@410: s4o.print(".");
Laurent@410: symbol->field_selector->accept(*this);
Laurent@410: }
berem@228: break;
berem@228: case complextype_suffix_vg:
Laurent@706: symbol->record_variable->accept(*this);
Laurent@706: if (type_is_complex) {
Laurent@706: s4o.print(".");
Laurent@706: symbol->field_selector->accept(*this);
Laurent@706: }
Laurent@706: break;
Laurent@706: case assignment_vg:
Laurent@706: symbol->record_variable->accept(*this);
Laurent@706: s4o.print(".");
Laurent@706: symbol->field_selector->accept(*this);
Laurent@706: break;
berem@228: default:
berem@228: if (this->is_variable_prefix_null()) {
Laurent@706: symbol->record_variable->accept(*this);
Laurent@706: s4o.print(".");
Laurent@706: symbol->field_selector->accept(*this);
berem@228: }
berem@228: else
Laurent@706: print_getter(symbol);
berem@228: break;
berem@228: }
berem@228: return NULL;
berem@228: }
berem@228:
berem@228: /* subscripted_variable '[' subscript_list ']' */
berem@228: //SYM_REF2(array_variable_c, subscripted_variable, subscript_list)
berem@228: void *visit(array_variable_c *symbol) {
berem@228: switch (wanted_variablegeneration) {
berem@228: case complextype_base_vg:
laurent@392: case complextype_base_assignment_vg:
berem@228: symbol->subscripted_variable->accept(*this);
berem@228: break;
berem@228: case complextype_suffix_vg:
laurent@238: symbol->subscripted_variable->accept(*this);
laurent@238:
msousa@321: current_array_type = search_varfb_instance_type->get_type_id(symbol->subscripted_variable);
laurent@238: if (current_array_type == NULL) ERROR;
laurent@238:
laurent@238: s4o.print(".table");
laurent@238: symbol->subscript_list->accept(*this);
laurent@238:
laurent@238: current_array_type = NULL;
berem@228: break;
berem@228: default:
berem@228: if (this->is_variable_prefix_null()) {
laurent@238: symbol->subscripted_variable->accept(*this);
laurent@238:
msousa@321: current_array_type = search_varfb_instance_type->get_type_id(symbol->subscripted_variable);
laurent@238: if (current_array_type == NULL) ERROR;
laurent@238:
laurent@238: s4o.print(".table");
laurent@238: symbol->subscript_list->accept(*this);
laurent@238:
laurent@238: current_array_type = NULL;
berem@228: }
berem@228: else
Laurent@706: print_getter(symbol);
berem@228: break;
berem@228: }
berem@228: return NULL;
berem@228: }
berem@228:
berem@228: /* subscript_list ',' subscript */
berem@228: void *visit(subscript_list_c *symbol) {
laurent@377: array_dimension_iterator_c* array_dimension_iterator = new array_dimension_iterator_c(current_array_type);
berem@228: for (int i = 0; i < symbol->n; i++) {
laurent@377: symbol_c* dimension = array_dimension_iterator->next();
Laurent@706: if (dimension == NULL) ERROR;
Laurent@706:
Laurent@706: s4o.print("[(");
berem@228: symbol->elements[i]->accept(*this);
laurent@377: s4o.print(") - (");
laurent@377: dimension->accept(*this);
berem@228: s4o.print(")]");
berem@228: }
laurent@377: delete array_dimension_iterator;
berem@228: return NULL;
berem@228: }
berem@228:
laurent@235: /******************************************/
laurent@235: /* B 1.4.3 - Declaration & Initialisation */
laurent@235: /******************************************/
laurent@237:
laurent@237: /* helper symbol for structure_initialization */
laurent@237: /* structure_element_initialization_list ',' structure_element_initialization */
laurent@235: void *visit(structure_element_initialization_list_c *symbol) {
laurent@235: generate_c_structure_initialization_c *structure_initialization = new generate_c_structure_initialization_c(&s4o);
laurent@235: structure_initialization->init_structure_default(this->current_param_type);
laurent@237: structure_initialization->init_structure_values(symbol);
laurent@235: delete structure_initialization;
laurent@235: return NULL;
laurent@235: }
laurent@235:
laurent@237: /* helper symbol for array_initialization */
laurent@237: /* array_initial_elements_list ',' array_initial_elements */
laurent@237: void *visit(array_initial_elements_list_c *symbol) {
laurent@237: generate_c_array_initialization_c *array_initialization = new generate_c_array_initialization_c(&s4o);
laurent@237: array_initialization->init_array_size(this->current_param_type);
laurent@237: array_initialization->init_array_values(symbol);
laurent@237: delete array_initialization;
laurent@237: return NULL;
laurent@237: }
lbessard@70: /****************************************/
lbessard@70: /* B.2 - Language IL (Instruction List) */
lbessard@70: /****************************************/
lbessard@70:
lbessard@70: /***********************************/
lbessard@70: /* B 2.1 Instructions and Operands */
lbessard@70: /***********************************/
lbessard@70:
lbessard@70: /*| instruction_list il_instruction */
lbessard@70: void *visit(instruction_list_c *symbol) {
lbessard@70:
msousa@682: /* Declare the IL implicit variable, that will store the result of the IL operations... */
msousa@682: declare_implicit_variable();
msousa@682:
msousa@682: /* Declare the backup to the IL implicit variable, that will store the result of the IL operations executed inside a parenthesis... */
msousa@682: declare_implicit_variable_back();
msousa@682: /*
lbessard@70: s4o.print(s4o.indent_spaces);
msousa@682: this->implicit_variable_result_back.accept(*this);
laurent@211: s4o.print(".INTvar = 0;\n\n");
msousa@682: */
lbessard@70: print_list(symbol, s4o.indent_spaces, ";\n" + s4o.indent_spaces, ";\n");
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70: /* | label ':' [il_incomplete_instruction] eol_list */
lbessard@70: // SYM_REF2(il_instruction_c, label, il_instruction)
lbessard@70: void *visit(il_instruction_c *symbol) {
msousa@682: /* all previous IL instructions should have the same datatype (checked in stage3), so we get the datatype from the first previous IL instruction we find */
msousa@682: implicit_variable_current.datatype = (symbol->prev_il_instruction.empty())? NULL : symbol->prev_il_instruction[0]->datatype;
msousa@682: implicit_variable_result .datatype = symbol->datatype;
msousa@682:
lbessard@70: if (NULL != symbol->label) {
lbessard@70: symbol->label->accept(*this);
lbessard@70: s4o.print(":\n");
lbessard@70: s4o.print(s4o.indent_spaces);
lbessard@70: }
msousa@682:
msousa@311: if (NULL != symbol->il_instruction) {
msousa@311: symbol->il_instruction->accept(*this);
msousa@311: }
msousa@682:
msousa@682: implicit_variable_result .datatype = NULL;
msousa@682: implicit_variable_current.datatype = NULL;
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
lbessard@70: /* | il_simple_operator [il_operand] */
lbessard@70: //SYM_REF2(il_simple_operation_c, il_simple_operator, il_operand)
lbessard@70: void *visit(il_simple_operation_c *symbol) {
lbessard@70: this->current_operand = symbol->il_operand;
lbessard@70: symbol->il_simple_operator->accept(*this);
lbessard@70: this->current_operand = NULL;
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70: /* | function_name [il_operand_list] */
lbessard@70: // SYM_REF2(il_function_call_c, function_name, il_operand_list)
lbessard@70: void *visit(il_function_call_c *symbol) {
lbessard@149: symbol_c* function_type_prefix = NULL;
lbessard@149: symbol_c* function_name = NULL;
lbessard@149: symbol_c* function_type_suffix = NULL;
laurent@217: DECLARE_PARAM_LIST()
lbessard@149:
laurent@233: function_call_param_iterator_c function_call_param_iterator(symbol);
laurent@233:
msousa@350: function_declaration_c *f_decl = (function_declaration_c *)symbol->called_function_declaration;
msousa@350: if (f_decl == NULL) ERROR;
msousa@350:
msousa@350: function_name = symbol->function_name;
msousa@350:
msousa@350: /* loop through each function parameter, find the value we should pass
msousa@350: * to it, and then output the c equivalent...
msousa@350: */
msousa@350: function_param_iterator_c fp_iterator(f_decl);
msousa@350: identifier_c *param_name;
msousa@682: /* flag to remember whether we have already used the value stored in the implicit variable to pass to the first parameter */
msousa@350: bool used_defvar = false;
msousa@350: /* flag to cirreclty handle calls to extensible standard functions (i.e. functions with variable number of input parameters) */
msousa@350: bool found_first_extensible_parameter = false;
msousa@350: for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) {
msousa@350: if (fp_iterator.is_extensible_param() && (!found_first_extensible_parameter)) {
msousa@350: /* We are calling an extensible function. Before passing the extensible
msousa@350: * parameters, we must add a dummy paramater value to tell the called
msousa@350: * function how many extensible parameters we will be passing.
msousa@350: *
msousa@350: * Note that stage 3 has already determined the number of extensible
msousa@350: * paramters, and stored that info in the abstract syntax tree. We simply
msousa@350: * re-use that value.
msousa@350: */
msousa@350: /* NOTE: we are not freeing the malloc'd memory. This is not really a bug.
msousa@350: * Since we are writing a compiler, which runs to termination quickly,
msousa@350: * we can consider this as just memory required for the compilation process
msousa@350: * that will be free'd when the program terminates.
msousa@350: */
msousa@350: char *tmp = (char *)malloc(32); /* enough space for a call with 10^31 (larger than 2^64) input parameters! */
msousa@350: if (tmp == NULL) ERROR;
msousa@350: int res = snprintf(tmp, 32, "%d", symbol->extensible_param_count);
msousa@350: if ((res >= 32) || (res < 0)) ERROR;
msousa@350: identifier_c *param_value = new identifier_c(tmp);
msousa@350: uint_type_name_c *param_type = new uint_type_name_c();
msousa@350: identifier_c *param_name = new identifier_c("");
msousa@350: ADD_PARAM_LIST(param_name, param_value, param_type, function_param_iterator_c::direction_in)
msousa@350: found_first_extensible_parameter = true;
msousa@350: }
lbessard@70:
msousa@350: symbol_c *param_type = fp_iterator.param_type();
msousa@350: if (param_type == NULL) ERROR;
lbessard@70:
msousa@350: function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction();
lbessard@149:
msousa@350: symbol_c *param_value = NULL;
msousa@350:
msousa@350: /* Get the value from a foo( = ) style call */
msousa@350: /* NOTE: Since the class il_function_call_c only references a non.formal function call,
msousa@350: * the following line of code is not required in this case. However, it doesn't
msousa@350: * harm to leave it in, as in the case of a non-formal syntax function call,
msousa@350: * it will always return NULL.
msousa@350: * We leave it in in case we later decide to merge this part of the code together
msousa@350: * with the function calling code in generate_c_st_c, which does require
msousa@350: * the following line...
msousa@350: */
msousa@350: if (param_value == NULL)
msousa@350: param_value = function_call_param_iterator.search_f(param_name);
msousa@350:
msousa@350: /* if it is the first parameter in a non-formal function call (which is the
msousa@350: * case being handled!), semantics specifies that we should
msousa@682: * get the value off the IL implicit variable!
msousa@350: *
msousa@350: * However, if the parameter is an implicitly defined EN or ENO parameter, we should not
msousa@682: * use the IL implicit variable as a source of data to pass to those parameters!
msousa@350: */
msousa@350: if ((param_value == NULL) && (!used_defvar) && !fp_iterator.is_en_eno_param_implicit()) {
msousa@683: if (NULL == implicit_variable_current.datatype) ERROR;
msousa@682: param_value = &this->implicit_variable_current;
msousa@350: used_defvar = true;
msousa@350: }
msousa@350:
msousa@350: /* Get the value from a foo() style call */
msousa@350: if ((param_value == NULL) && !fp_iterator.is_en_eno_param_implicit()) {
msousa@350: param_value = function_call_param_iterator.next_nf();
msousa@350: }
lbessard@149:
msousa@350: /* if no more parameter values in function call, and the current parameter
msousa@350: * of the function declaration is an extensible parameter, we
msousa@350: * have reached the end, and should simply jump out of the for loop.
msousa@350: */
msousa@350: if ((param_value == NULL) && (fp_iterator.is_extensible_param())) {
msousa@350: break;
msousa@350: }
lbessard@149:
msousa@350: if ((param_value == NULL) && (param_direction == function_param_iterator_c::direction_in)) {
msousa@350: /* No value given for parameter, so we must use the default... */
msousa@350: /* First check whether default value specified in function declaration...*/
msousa@350: param_value = fp_iterator.default_value();
msousa@350: }
msousa@350:
msousa@350: ADD_PARAM_LIST(param_name, param_value, param_type, fp_iterator.param_direction())
msousa@350: } /* for(...) */
msousa@350:
laurent@233: if (function_call_param_iterator.next_nf() != NULL) ERROR;
laurent@233:
laurent@217: bool has_output_params = false;
laurent@217:
laurent@217: if (!this->is_variable_prefix_null()) {
laurent@217: PARAM_LIST_ITERATOR() {
msousa@350: if ((PARAM_DIRECTION == function_param_iterator_c::direction_out ||
msousa@350: PARAM_DIRECTION == function_param_iterator_c::direction_inout) &&
msousa@350: PARAM_VALUE != NULL) {
msousa@350: has_output_params = true;
msousa@350: }
msousa@350: }
msousa@350: }
msousa@350:
msousa@350: /* Check whether we are calling an overloaded function! */
msousa@721: /* (fdecl_mutiplicity > 1) => calling overloaded function */
msousa@721: int fdecl_mutiplicity = function_symtable.count(symbol->function_name);
msousa@350: if (fdecl_mutiplicity == 0) ERROR;
laurent@217:
msousa@682: this->implicit_variable_result.accept(*this);
lbessard@149: s4o.print(" = ");
lbessard@149:
lbessard@149: if (function_type_prefix != NULL) {
lbessard@149: s4o.print("(");
msousa@669: default_literal_type(function_type_prefix)->accept(*this);
lbessard@149: s4o.print(")");
lbessard@149: }
laurent@336: if (function_type_suffix != NULL) {
msousa@793: function_type_suffix = default_literal_type(function_type_suffix);
laurent@336: }
laurent@217: if (has_output_params) {
msousa@350: fcall_number++;
msousa@350: s4o.print("__");
laurent@217: fbname->accept(*this);
laurent@217: s4o.print("_");
lbessard@149: function_name->accept(*this);
msousa@721: if (fdecl_mutiplicity > 1) {
msousa@350: /* function being called is overloaded! */
msousa@350: s4o.print("__");
laurent@406: print_function_parameter_data_types_c overloaded_func_suf(&s4o);
msousa@350: f_decl->accept(overloaded_func_suf);
msousa@350: }
msousa@594: s4o.print(fcall_number);
laurent@217: }
laurent@217: else {
msousa@350: if (function_name != NULL) {
msousa@350: function_name->accept(*this);
msousa@721: if (fdecl_mutiplicity > 1) {
msousa@350: /* function being called is overloaded! */
msousa@350: s4o.print("__");
laurent@406: print_function_parameter_data_types_c overloaded_func_suf(&s4o);
msousa@350: f_decl->accept(overloaded_func_suf);
msousa@350: }
Laurent@706: }
laurent@217: if (function_type_suffix != NULL)
msousa@350: function_type_suffix->accept(*this);
laurent@217: }
lbessard@149: s4o.print("(");
lbessard@149: s4o.indent_right();
lbessard@149:
laurent@217: int nb_param = 0;
laurent@217: PARAM_LIST_ITERATOR() {
laurent@217: symbol_c *param_value = PARAM_VALUE;
laurent@235: current_param_type = PARAM_TYPE;
lbessard@149:
laurent@217: switch (PARAM_DIRECTION) {
lbessard@149: case function_param_iterator_c::direction_in:
msousa@350: if (nb_param > 0)
msousa@350: s4o.print(",\n"+s4o.indent_spaces);
lbessard@149: if (param_value == NULL) {
lbessard@149: /* If not, get the default value of this variable's type */
msousa@762: param_value = type_initial_value_c::get(current_param_type);
lbessard@149: }
lbessard@149: if (param_value == NULL) ERROR;
laurent@217: s4o.print("(");
msousa@669: if (get_datatype_info_c::is_ANY_INT_literal(current_param_type))
msousa@693: get_datatype_info_c::lint_type_name.accept(*this);
msousa@669: else if (get_datatype_info_c::is_ANY_REAL_literal(current_param_type))
msousa@693: get_datatype_info_c::lreal_type_name.accept(*this);
laurent@220: else
laurent@235: current_param_type->accept(*this);
laurent@217: s4o.print(")");
laurent@235: print_check_function(current_param_type, param_value);
laurent@217: nb_param++;
lbessard@149: break;
lbessard@149: case function_param_iterator_c::direction_out:
lbessard@149: case function_param_iterator_c::direction_inout:
msousa@350: if (!has_output_params) {
laurent@217: if (nb_param > 0)
msousa@350: s4o.print(",\n"+s4o.indent_spaces);
msousa@350: if (param_value == NULL) {
msousa@350: s4o.print("NULL");
msousa@350: } else {
msousa@350: wanted_variablegeneration = fparam_output_vg;
msousa@350: param_value->accept(*this);
msousa@350: wanted_variablegeneration = expression_vg;
msousa@350: }
msousa@350: nb_param++;
msousa@350: }
lbessard@149: break;
lbessard@149: case function_param_iterator_c::direction_extref:
lbessard@149: /* TODO! */
lbessard@149: ERROR;
lbessard@149: break;
lbessard@149: } /* switch */
lbessard@149: }
laurent@217: if (has_output_params) {
laurent@217: if (nb_param > 0)
msousa@350: s4o.print(",\n"+s4o.indent_spaces);
laurent@217: s4o.print(FB_FUNCTION_PARAM);
laurent@217: }
lbessard@149:
lbessard@149: s4o.print(")");
laurent@217:
laurent@217: CLEAR_PARAM_LIST()
laurent@217:
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70: /* | il_expr_operator '(' [il_operand] eol_list [simple_instr_list] ')' */
lbessard@70: //SYM_REF4(il_expression_c, il_expr_operator, il_operand, simple_instr_list, unused)
lbessard@70: void *visit(il_expression_c *symbol) {
msousa@682: LD_operator_c *tmp_LD_operator = NULL;
msousa@682: il_simple_operation_c *tmp_il_simple_operation = NULL;
msousa@682: il_simple_instruction_c *tmp_il_simple_instruction = NULL;
msousa@682:
msousa@682: /* We will be recursevely interpreting an instruction list, so we store a backup of the implicit_variable_result/current.
msousa@682: * Notice that they will be overwriten while processing the parenthsized instruction list.
lbessard@70: */
msousa@682: il_default_variable_c old_implicit_variable_current = this->implicit_variable_current;
msousa@682: il_default_variable_c old_implicit_variable_result = this->implicit_variable_result;
msousa@682:
msousa@690: /* Stage2 will insert an artificial (and equivalent) LD to the simple_instr_list if necessary. We can therefore ignore the 'il_operand' entry! */
msousa@690: //if (NULL != symbol->il_operand) { do nothing!! }
lbessard@70:
lbessard@70: /* Now do the parenthesised instructions... */
msousa@682: /* NOTE: the following code line will overwrite the variables implicit_variable_current and implicit_variable_result */
lbessard@70: symbol->simple_instr_list->accept(*this);
msousa@682:
lbessard@70: /* Now do the operation, using the previous result! */
msousa@682: /* NOTE: The result of the previous instruction list in the parenthesis will be stored
lbessard@70: * in a variable named IL_DEFVAR_BACK. This is done in the visitor
lbessard@70: * to instruction_list_c objects...
lbessard@70: */
msousa@682: this->implicit_variable_result_back.datatype = symbol->simple_instr_list->datatype;
msousa@682: this->current_operand = &(this->implicit_variable_result_back);
msousa@682:
msousa@682: this->implicit_variable_current = old_implicit_variable_current;
msousa@682: this->implicit_variable_result = old_implicit_variable_result;
lbessard@70:
lbessard@70: symbol->il_expr_operator->accept(*this);
lbessard@70:
lbessard@70: this->current_operand = NULL;
msousa@682: this->implicit_variable_result_back.datatype = NULL;
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
lbessard@70: /* il_jump_operator label */
lbessard@70: // SYM_REF2(il_jump_operation_c, il_jump_operator, label)
lbessard@70: void *visit(il_jump_operation_c *symbol) {
msousa@682: /* Pass the symbol->label to the il_jump_operation visitor using the jump_label parameter... */
lbessard@70: this->jump_label = symbol->label;
lbessard@70: symbol->il_jump_operator->accept(*this);
lbessard@70: this->jump_label = NULL;
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
lbessard@70: /* il_call_operator prev_declared_fb_name
lbessard@70: * | il_call_operator prev_declared_fb_name '(' ')'
lbessard@70: * | il_call_operator prev_declared_fb_name '(' eol_list ')'
lbessard@70: * | il_call_operator prev_declared_fb_name '(' il_operand_list ')'
lbessard@70: * | il_call_operator prev_declared_fb_name '(' eol_list il_param_list ')'
lbessard@70: */
lbessard@70: // SYM_REF4(il_fb_call_c, il_call_operator, fb_name, il_operand_list, il_param_list)
lbessard@70: void *visit(il_fb_call_c *symbol) {
lbessard@70: symbol->il_call_operator->accept(*this);
lbessard@70: s4o.print("{\n");
lbessard@70: s4o.indent_right();
lbessard@70: s4o.print(s4o.indent_spaces);
lbessard@70:
lbessard@70: /* first figure out what is the name of the function block type of the function block being called... */
lbessard@70: symbol_c *function_block_type_name = this->search_fb_instance_decl->get_type_name(symbol->fb_name);
lbessard@70: /* should never occur. The function block instance MUST have been declared... */
lbessard@70: if (function_block_type_name == NULL) ERROR;
lbessard@70:
lbessard@70: /* Now find the declaration of the function block type being called... */
lbessard@70: function_block_declaration_c *fb_decl = function_block_type_symtable.find_value(function_block_type_name);
lbessard@70: /* should never occur. The function block type being called MUST be in the symtable... */
lbessard@70: if (fb_decl == function_block_type_symtable.end_value()) ERROR;
lbessard@70:
lbessard@70: /* loop through each function block parameter, find the value we should pass
lbessard@70: * to it, and then output the c equivalent...
lbessard@70: */
lbessard@70: function_param_iterator_c fp_iterator(fb_decl);
lbessard@70: identifier_c *param_name;
lbessard@70: function_call_param_iterator_c function_call_param_iterator(symbol);
lbessard@70: for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) {
lbessard@70: function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction();
lbessard@70:
lbessard@70: /* Get the value from a foo( = ) style call */
ccb@202: symbol_c *param_value = function_call_param_iterator.search_f(param_name);
lbessard@70:
lbessard@70: /* Get the value from a foo() style call */
msousa@350: /* When using the informal invocation style, user can not pass values to EN or ENO parameters if these
msousa@350: * were implicitly defined!
msousa@350: */
msousa@350: if ((param_value == NULL) && !fp_iterator.is_en_eno_param_implicit())
ccb@202: param_value = function_call_param_iterator.next_nf();
lbessard@70:
lbessard@98: symbol_c *param_type = fp_iterator.param_type();
lbessard@98: if (param_type == NULL) ERROR;
lbessard@98:
lbessard@123: /* now output the value assignment */
lbessard@70: if (param_value != NULL)
lbessard@70: if ((param_direction == function_param_iterator_c::direction_in) ||
lbessard@70: (param_direction == function_param_iterator_c::direction_inout)) {
Laurent@706: if (this->is_variable_prefix_null()) {
Laurent@706: symbol->fb_name->accept(*this);
berem@228: s4o.print(".");
berem@228: param_name->accept(*this);
berem@228: s4o.print(" = ");
berem@228: print_check_function(param_type, param_value);
Laurent@706: }
berem@228: else {
berem@228: print_setter(param_name, param_type, param_value, symbol->fb_name);
berem@228: }
lbessard@70: s4o.print(";\n" + s4o.indent_spaces);
lbessard@70: }
lbessard@70: } /* for(...) */
lbessard@70:
lbessard@70: /* now call the function... */
lbessard@70: function_block_type_name->accept(*this);
lbessard@70: s4o.print(FB_FUNCTION_SUFFIX);
Laurent@706: s4o.print("(");
Laurent@706: if (search_var_instance_decl->get_vartype(symbol->fb_name) != search_var_instance_decl_c::external_vt)
Laurent@706: s4o.print("&");
laurent@240: print_variable_prefix();
lbessard@70: symbol->fb_name->accept(*this);
lbessard@70: s4o.print(")");
lbessard@70:
lbessard@70: /* loop through each function parameter, find the variable to which
lbessard@70: * we should atribute the value of all output or inoutput parameters.
lbessard@70: */
lbessard@70: fp_iterator.reset();
lbessard@70: function_call_param_iterator.reset();
lbessard@70: for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) {
lbessard@70: function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction();
lbessard@70:
lbessard@70: /* Get the value from a foo( = ) style call */
ccb@202: symbol_c *param_value = function_call_param_iterator.search_f(param_name);
lbessard@70:
lbessard@70: /* Get the value from a foo() style call */
msousa@350: /* When using the informal invocation style, user can not pass values to EN or ENO parameters if these
msousa@350: * were implicitly defined!
msousa@350: */
msousa@350: if ((param_value == NULL) && !fp_iterator.is_en_eno_param_implicit())
ccb@202: param_value = function_call_param_iterator.next_nf();
lbessard@70:
lbessard@70: /* now output the value assignment */
lbessard@70: if (param_value != NULL)
lbessard@70: if ((param_direction == function_param_iterator_c::direction_out) ||
lbessard@70: (param_direction == function_param_iterator_c::direction_inout)) {
msousa@321: symbol_c *param_type = search_varfb_instance_type->get_type_id(param_value);
laurent@240: s4o.print(";\n" + s4o.indent_spaces);
berem@228: if (this->is_variable_prefix_null()) {
laurent@240: param_value->accept(*this);
Laurent@706: s4o.print(" = ");
Laurent@706: print_check_function(param_type, param_name, symbol->fb_name);
Laurent@706: }
Laurent@706: else {
Laurent@706: print_setter(param_value, param_type, param_name, NULL, symbol->fb_name);
Laurent@706: }
lbessard@70: }
lbessard@70: } /* for(...) */
lbessard@70:
lbessard@70: s4o.print(";\n");
lbessard@70: s4o.indent_left();
lbessard@70: s4o.print(s4o.indent_spaces);
lbessard@70: s4o.print("}");
lbessard@70:
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70: /* | function_name '(' eol_list [il_param_list] ')' */
lbessard@70: // SYM_REF2(il_formal_funct_call_c, function_name, il_param_list)
lbessard@70: void *visit(il_formal_funct_call_c *symbol) {
lbessard@149: symbol_c* function_type_prefix = NULL;
lbessard@149: symbol_c* function_name = NULL;
lbessard@149: symbol_c* function_type_suffix = NULL;
laurent@217: DECLARE_PARAM_LIST()
lbessard@149:
laurent@233: function_call_param_iterator_c function_call_param_iterator(symbol);
laurent@233:
msousa@350: function_declaration_c *f_decl = (function_declaration_c *)symbol->called_function_declaration;
msousa@350: if (f_decl == NULL) ERROR;
msousa@350:
msousa@350: function_name = symbol->function_name;
msousa@350:
msousa@350: /* loop through each function parameter, find the value we should pass
msousa@350: * to it, and then output the c equivalent...
msousa@350: */
msousa@350: function_param_iterator_c fp_iterator(f_decl);
msousa@350: identifier_c *param_name;
msousa@350:
msousa@350: /* flag to cirreclty handle calls to extensible standard functions (i.e. functions with variable number of input parameters) */
msousa@350: bool found_first_extensible_parameter = false;
msousa@350: for(int i = 1; (param_name = fp_iterator.next()) != NULL; i++) {
msousa@350: if (fp_iterator.is_extensible_param() && (!found_first_extensible_parameter)) {
msousa@350: /* We are calling an extensible function. Before passing the extensible
msousa@350: * parameters, we must add a dummy paramater value to tell the called
msousa@350: * function how many extensible parameters we will be passing.
msousa@350: *
msousa@350: * Note that stage 3 has already determined the number of extensible
msousa@350: * paramters, and stored that info in the abstract syntax tree. We simply
msousa@350: * re-use that value.
msousa@350: */
msousa@350: /* NOTE: we are not freeing the malloc'd memory. This is not really a bug.
msousa@350: * Since we are writing a compiler, which runs to termination quickly,
msousa@350: * we can consider this as just memory required for the compilation process
msousa@350: * that will be free'd when the program terminates.
msousa@350: */
msousa@350: char *tmp = (char *)malloc(32); /* enough space for a call with 10^31 (larger than 2^64) input parameters! */
msousa@350: if (tmp == NULL) ERROR;
msousa@350: int res = snprintf(tmp, 32, "%d", symbol->extensible_param_count);
msousa@350: if ((res >= 32) || (res < 0)) ERROR;
msousa@350: identifier_c *param_value = new identifier_c(tmp);
msousa@350: uint_type_name_c *param_type = new uint_type_name_c();
msousa@350: identifier_c *param_name = new identifier_c("");
msousa@350: ADD_PARAM_LIST(param_name, param_value, param_type, function_param_iterator_c::direction_in)
msousa@350: found_first_extensible_parameter = true;
msousa@350: }
lbessard@149:
msousa@350: if (fp_iterator.is_extensible_param()) {
msousa@350: /* since we are handling an extensible parameter, we must add the index to the
msousa@350: * parameter name so we can go looking for the value passed to the correct
msousa@350: * extended parameter (e.g. IN1, IN2, IN3, IN4, ...)
msousa@350: */
msousa@350: char *tmp = (char *)malloc(32); /* enough space for a call with 10^31 (larger than 2^64) input parameters! */
msousa@350: int res = snprintf(tmp, 32, "%d", fp_iterator.extensible_param_index());
msousa@350: if ((res >= 32) || (res < 0)) ERROR;
msousa@350: param_name = new identifier_c(strdup2(param_name->value, tmp));
msousa@350: if (param_name->value == NULL) ERROR;
msousa@350: }
msousa@350:
msousa@350: symbol_c *param_type = fp_iterator.param_type();
msousa@350: if (param_type == NULL) ERROR;
msousa@350:
msousa@350: function_param_iterator_c::param_direction_t param_direction = fp_iterator.param_direction();
msousa@350:
msousa@350: symbol_c *param_value = NULL;
msousa@350:
msousa@350: /* Get the value from a foo( = ) style call */
msousa@350: if (param_value == NULL)
msousa@350: param_value = function_call_param_iterator.search_f(param_name);
msousa@350:
msousa@350: /* Get the value from a foo() style call */
msousa@350: /* NOTE: the following line of code is not required in this case, but it doesn't
msousa@350: * harm to leave it in, as in the case of a formal syntax function call,
msousa@350: * it will always return NULL.
msousa@350: * We leave it in in case we later decide to merge this part of the code together
msousa@350: * with the function calling code in generate_c_st_c, which does require
msousa@350: * the following line...
msousa@350: */
msousa@350: if ((param_value == NULL) && !fp_iterator.is_en_eno_param_implicit()) {
msousa@350: param_value = function_call_param_iterator.next_nf();
msousa@350: }
lbessard@149:
msousa@350: /* if no more parameter values in function call, and the current parameter
msousa@350: * of the function declaration is an extensible parameter, we
msousa@350: * have reached the end, and should simply jump out of the for loop.
msousa@350: */
msousa@350: if ((param_value == NULL) && (fp_iterator.is_extensible_param())) {
msousa@350: break;
msousa@350: }
lbessard@169:
msousa@350: if ((param_value == NULL) && (param_direction == function_param_iterator_c::direction_in)) {
msousa@350: /* No value given for parameter, so we must use the default... */
msousa@350: /* First check whether default value specified in function declaration...*/
msousa@350: param_value = fp_iterator.default_value();
msousa@350: }
lbessard@149:
msousa@350: ADD_PARAM_LIST(param_name, param_value, param_type, fp_iterator.param_direction())
laurent@217: }
laurent@217:
laurent@233: if (function_call_param_iterator.next_nf() != NULL) ERROR;
laurent@233:
laurent@217: bool has_output_params = false;
laurent@217:
laurent@217: if (!this->is_variable_prefix_null()) {
laurent@217: PARAM_LIST_ITERATOR() {
msousa@350: if ((PARAM_DIRECTION == function_param_iterator_c::direction_out ||
msousa@350: PARAM_DIRECTION == function_param_iterator_c::direction_inout) &&
msousa@350: PARAM_VALUE != NULL) {
msousa@350: has_output_params = true;
msousa@350: }
msousa@350: }
msousa@350: }
msousa@350:
msousa@350: /* Check whether we are calling an overloaded function! */
msousa@721: /* (fdecl_mutiplicity > 1) => calling overloaded function */
msousa@721: int fdecl_mutiplicity = function_symtable.count(symbol->function_name);
msousa@350: if (fdecl_mutiplicity == 0) ERROR;
msousa@350: if (fdecl_mutiplicity == 1)
msousa@350: /* function being called is NOT overloaded! */
msousa@350: f_decl = NULL;
laurent@217:
msousa@682: this->implicit_variable_result.accept(*this);
lbessard@149: s4o.print(" = ");
lbessard@149:
lbessard@149: if (function_type_prefix != NULL) {
lbessard@149: s4o.print("(");
msousa@669: default_literal_type(function_type_prefix)->accept(*this);
lbessard@149: s4o.print(")");
lbessard@149: }
laurent@336: if (function_type_suffix != NULL) {
msousa@793: function_type_suffix = default_literal_type(function_type_suffix);
laurent@336: }
laurent@217: if (has_output_params) {
msousa@350: fcall_number++;
msousa@350: s4o.print("__");
laurent@217: fbname->accept(*this);
laurent@217: s4o.print("_");
lbessard@149: function_name->accept(*this);
msousa@721: if (fdecl_mutiplicity > 1) {
msousa@350: /* function being called is overloaded! */
msousa@350: s4o.print("__");
laurent@406: print_function_parameter_data_types_c overloaded_func_suf(&s4o);
msousa@350: f_decl->accept(overloaded_func_suf);
msousa@350: }
msousa@594: s4o.print(fcall_number);
laurent@217: }
laurent@217: else {
msousa@350: if (function_name != NULL) {
laurent@217: function_name->accept(*this);
msousa@721: if (fdecl_mutiplicity > 1) {
msousa@350: /* function being called is overloaded! */
msousa@350: s4o.print("__");
laurent@406: print_function_parameter_data_types_c overloaded_func_suf(&s4o);
msousa@350: f_decl->accept(overloaded_func_suf);
msousa@350: }
msousa@350: }
laurent@217: if (function_type_suffix != NULL)
laurent@217: function_type_suffix->accept(*this);
laurent@217: }
lbessard@70: s4o.print("(");
lbessard@149: s4o.indent_right();
lbessard@149:
laurent@217: int nb_param = 0;
laurent@217: PARAM_LIST_ITERATOR() {
msousa@350: symbol_c *param_value = PARAM_VALUE;
msousa@350: current_param_type = PARAM_TYPE;
laurent@217: switch (PARAM_DIRECTION) {
lbessard@70: case function_param_iterator_c::direction_in:
msousa@350: if (nb_param > 0)
msousa@350: s4o.print(",\n"+s4o.indent_spaces);
msousa@350: if (param_value == NULL) {
lbessard@70: /* If not, get the default value of this variable's type */
msousa@762: param_value = type_initial_value_c::get(current_param_type);
lbessard@70: }
lbessard@70: if (param_value == NULL) ERROR;
laurent@217: s4o.print("(");
msousa@693: if (get_datatype_info_c::is_ANY_INT_literal(current_param_type))
msousa@693: get_datatype_info_c::lint_type_name.accept(*this);
msousa@669: else if (get_datatype_info_c::is_ANY_REAL_literal(current_param_type))
msousa@693: get_datatype_info_c::lreal_type_name.accept(*this);
laurent@220: else
laurent@235: current_param_type->accept(*this);
laurent@217: s4o.print(")");
laurent@235: print_check_function(current_param_type, param_value);
msousa@350: nb_param++;
laurent@217: break;
lbessard@70: case function_param_iterator_c::direction_out:
lbessard@70: case function_param_iterator_c::direction_inout:
msousa@350: if (!has_output_params) {
laurent@217: if (nb_param > 0)
msousa@350: s4o.print(",\n"+s4o.indent_spaces);
msousa@350: if (param_value == NULL) {
msousa@350: s4o.print("NULL");
msousa@350: } else {
msousa@350: wanted_variablegeneration = fparam_output_vg;
msousa@350: param_value->accept(*this);
msousa@350: wanted_variablegeneration = expression_vg;
msousa@350: }
msousa@350: }
msousa@350: break;
lbessard@70: case function_param_iterator_c::direction_extref:
lbessard@70: /* TODO! */
lbessard@70: ERROR;
msousa@350: break;
lbessard@70: } /* switch */
lbessard@70: } /* for(...) */
laurent@217: if (has_output_params) {
laurent@217: if (nb_param > 0)
laurent@217: s4o.print(",\n"+s4o.indent_spaces);
laurent@217: s4o.print(FB_FUNCTION_PARAM);
laurent@217: }
lbessard@70:
lbessard@70: // symbol->parameter_assignment->accept(*this);
lbessard@70: s4o.print(")");
laurent@217:
laurent@217: CLEAR_PARAM_LIST()
laurent@217:
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70: /* | il_operand_list ',' il_operand */
lbessard@70: // SYM_LIST(il_operand_list_c)
lbessard@70: void *visit(il_operand_list_c *symbol) {ERROR; return NULL;} // should never get called!
lbessard@70:
lbessard@70:
lbessard@70: /* | simple_instr_list il_simple_instruction */
lbessard@70: // SYM_LIST(simple_instr_list_c)
lbessard@70: void *visit(simple_instr_list_c *symbol) {
msousa@682: /* A simple_instr_list_c is used to store a list of il operations being done within parenthesis...
lbessard@70: *
lbessard@70: * e.g.:
lbessard@70: * LD var1
lbessard@70: * AND ( var2
lbessard@70: * OR var3
lbessard@70: * OR var4
lbessard@70: * )
lbessard@70: *
msousa@682: * NOTE 1:
lbessard@70: * This will be converted to C++ by defining a new scope
msousa@682: * with a new il implicit variable, and executing the il operands
lbessard@70: * within this new scope.
lbessard@70: * At the end of the scope the result, i.e. the value currently stored
msousa@682: * in the il implicit variable is copied to the variable used to take this
lbessard@70: * value to the outside scope...
lbessard@70: *
lbessard@70: * The above example will result in the following C++ code:
lbessard@70: * {__IL_DEFVAR_T __IL_DEFVAR_BACK;
lbessard@70: * __IL_DEFVAR_T __IL_DEFVAR;
lbessard@70: *
lbessard@70: * __IL_DEFVAR.INTvar = var1;
lbessard@70: * {
lbessard@70: * __IL_DEFVAR_T __IL_DEFVAR;
lbessard@70: *
lbessard@70: * __IL_DEFVAR.INTvar = var2;
lbessard@70: * __IL_DEFVAR.INTvar |= var3;
lbessard@70: * __IL_DEFVAR.INTvar |= var4;
lbessard@70: *
lbessard@70: * __IL_DEFVAR_BACK = __IL_DEFVAR;
lbessard@70: * }
lbessard@70: * __IL_DEFVAR.INTvar &= __IL_DEFVAR_BACK.INTvar;
lbessard@70: *
lbessard@70: * }
lbessard@70: *
msousa@682: * NOTE 2:
msousa@682: * If the intial value of the il implicit variable (in the above
msousa@690: * example 'var2') exists, then stage2 will insert an equivalent
msousa@690: * LD operation into the parenthesized instruction list. This means we do not
msousa@682: * need to do anything here to handle this special situation!
lbessard@70: */
lbessard@70:
msousa@682: /* Declare the IL implicit variable, that will store the result of the IL operations... */
lbessard@70: s4o.print("{\n");
lbessard@70: s4o.indent_right();
msousa@682: declare_implicit_variable();
msousa@682:
lbessard@70: print_list(symbol, s4o.indent_spaces, ";\n" + s4o.indent_spaces, ";\n");
lbessard@70:
msousa@682: /* copy the result in the IL implicit variable to the variable
msousa@682: * used to pass the data out to the scope enclosing the current scope!
lbessard@70: */
msousa@682: this->implicit_variable_result_back.datatype = symbol->datatype;
msousa@682: this->implicit_variable_result .datatype = symbol->datatype;
msousa@682:
lbessard@70: s4o.print("\n");
lbessard@70: s4o.print(s4o.indent_spaces);
msousa@682: this->implicit_variable_result_back.accept(*this);
lbessard@70: s4o.print(" = ");
msousa@682: this->implicit_variable_result.accept(*this);
lbessard@70: s4o.print(";\n");
lbessard@70:
lbessard@70: s4o.indent_left();
lbessard@70: s4o.print(s4o.indent_spaces);
lbessard@70: s4o.print("}\n");
lbessard@70: s4o.print(s4o.indent_spaces);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
msousa@682:
msousa@453: // SYM_REF1(il_simple_instruction_c, il_simple_instruction, symbol_c *prev_il_instruction;)
Laurent@706: void *visit(il_simple_instruction_c *symbol) {
msousa@687: /* all previous IL instructions should have the same datatype (checked in stage3), so we get the datatype from the first previous IL instruction we find */
msousa@687: implicit_variable_current.datatype = (symbol->prev_il_instruction.empty())? NULL : symbol->prev_il_instruction[0]->datatype;
msousa@687: implicit_variable_result .datatype = symbol->datatype;
msousa@687:
msousa@687: symbol->il_simple_instruction->accept(*this);
msousa@687:
msousa@687: implicit_variable_result .datatype = NULL;
msousa@687: implicit_variable_current.datatype = NULL;
msousa@687: return NULL;
msousa@453: }
msousa@453:
msousa@453:
lbessard@70: /* | il_initial_param_list il_param_instruction */
lbessard@70: // SYM_LIST(il_param_list_c)
msousa@682: void *visit(il_param_list_c *symbol) {ERROR; return NULL;} // should never get called!
lbessard@70:
lbessard@70: /* il_assign_operator il_operand
lbessard@70: * | il_assign_operator '(' eol_list simple_instr_list ')'
lbessard@70: */
lbessard@70: // SYM_REF4(il_param_assignment_c, il_assign_operator, il_operand, simple_instr_list, unused)
msousa@682: void *visit(il_param_assignment_c *symbol) {ERROR; return NULL;} // should never get called!
lbessard@70:
lbessard@70: /* il_assign_out_operator variable */
lbessard@70: // SYM_REF2(il_param_out_assignment_c, il_assign_out_operator, variable);
msousa@682: void *visit(il_param_out_assignment_c *symbol) {ERROR; return NULL;} // should never get called!
msousa@682:
lbessard@70:
lbessard@70: /*******************/
lbessard@70: /* B 2.2 Operators */
lbessard@70: /*******************/
lbessard@70:
Laurent@706: void *visit(LD_operator_c *symbol) {
laurent@382: if (wanted_variablegeneration != expression_vg) {
laurent@382: s4o.print("LD");
laurent@382: return NULL;
laurent@382: }
msousa@682: XXX_operator(&(this->implicit_variable_result), " = ", this->current_operand);
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
Laurent@706: void *visit(LDN_operator_c *symbol) {
msousa@682: XXX_operator(&(this->implicit_variable_result), get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype)?" = !":" = ~", this->current_operand);
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
Laurent@706: void *visit(ST_operator_c *symbol) {
berem@228: if (this->is_variable_prefix_null()) {
laurent@217: this->current_operand->accept(*this);
laurent@217: s4o.print(" = ");
msousa@682: print_check_function(this->current_operand->datatype, (symbol_c*)&(this->implicit_variable_current));
berem@228: }
berem@228: else {
msousa@682: print_setter(this->current_operand, this->current_operand->datatype, (symbol_c*)&(this->implicit_variable_current));
msousa@682: }
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
Laurent@706: void *visit(STN_operator_c *symbol) {
berem@228: if (this->is_variable_prefix_null()) {
laurent@217: this->current_operand->accept(*this);
laurent@217: s4o.print(" = ");
msousa@682: if (get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype))
berem@228: s4o.print("!");
berem@228: else
Laurent@706: s4o.print("~");
msousa@682: this->implicit_variable_current.accept(*this);
berem@228: }
berem@228: else {
msousa@682: print_setter(this->current_operand, this->current_operand->datatype, (symbol_c*)&(this->implicit_variable_current), NULL, NULL, true);
msousa@682: }
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
Laurent@706: void *visit(NOT_operator_c *symbol) {
msousa@470: /* NOTE: the standard allows syntax in which the NOT operator is followed by an optional
msousa@470: * NOT []
msousa@470: * However, it does not define the semantic of the NOT operation when the is specified.
msousa@470: * We therefore consider it an error if an il_operand is specified!
msousa@470: * The error is caught in stage 3!
msousa@470: */
msousa@682: if (NULL != this->current_operand) ERROR;
msousa@682: XXX_operator(&(this->implicit_variable_result), get_datatype_info_c::is_BOOL_compatible(symbol->datatype)?" = !":" = ~", &(this->implicit_variable_current));
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
Laurent@706: void *visit(S_operator_c *symbol) {
mjsousa@834: /* This operator must implement one of two possible semantics:
mjsousa@834: * - FB call
mjsousa@834: * - Set all the bits of an ANY_BIT type variable to 1
mjsousa@834: */
mjsousa@834:
mjsousa@834: /* Check whether we must implement the FB call semantics... */
mjsousa@834: if (NULL != symbol->called_fb_declaration)
mjsousa@834: return XXX_CAL_operator( "S", this->current_operand);
mjsousa@834:
mjsousa@834: /* Implement the bit setting semantics... */
laurent@382: if (wanted_variablegeneration != expression_vg) {
laurent@382: s4o.print("LD");
laurent@382: return NULL;
laurent@382: }
laurent@382:
msousa@682: if ((NULL == this->current_operand) || (NULL == this->current_operand->datatype)) ERROR;
lbessard@70:
lbessard@70: C_modifier();
lbessard@70: this->current_operand->accept(*this);
laurent@240: s4o.print(" = __");
msousa@682: if (get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype)) {
laurent@240: s4o.print("BOOL_LITERAL(TRUE)");
msousa@682: } else if (get_datatype_info_c::is_ANY_INT_compatible(this->current_operand->datatype)) {
msousa@682: this->current_operand->datatype->accept(*this);
laurent@240: s4o.print("_LITERAL(1)");
msousa@682: } else
laurent@240: ERROR;
msousa@682: return NULL;
msousa@682: }
msousa@682:
lbessard@70:
Laurent@706: void *visit(R_operator_c *symbol) {
mjsousa@834: /* This operator must implement one of two possible semantics:
mjsousa@834: * - FB call
mjsousa@834: * - Set all the bits of an ANY_BIT type variable to 0
mjsousa@834: */
mjsousa@834:
mjsousa@834: /* Check whether we must implement the FB call semantics... */
mjsousa@834: if (NULL != symbol->called_fb_declaration)
mjsousa@834: return XXX_CAL_operator( "R", this->current_operand);
mjsousa@834:
mjsousa@834: /* Implement the bit setting semantics... */
laurent@382: if (wanted_variablegeneration != expression_vg) {
laurent@382: s4o.print("LD");
laurent@382: return NULL;
laurent@382: }
laurent@382:
msousa@682: if ((NULL == this->current_operand) || (NULL == this->current_operand->datatype)) ERROR;
lbessard@70:
lbessard@70: C_modifier();
lbessard@70: this->current_operand->accept(*this);
laurent@240: s4o.print(" = __");
msousa@682: if (get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype)) {
laurent@240: s4o.print("BOOL_LITERAL(FALSE)");
msousa@682: } else if (get_datatype_info_c::is_ANY_INT_compatible(this->current_operand->datatype)) {
msousa@682: this->current_operand->datatype->accept(*this);
laurent@240: s4o.print("_LITERAL(0)");
msousa@682: } else
laurent@240: ERROR;
lbessard@70: /* the data type resulting from this operation is unchanged! */
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
msousa@682:
msousa@682: void *visit( S1_operator_c *symbol) {return XXX_CAL_operator( "S1", this->current_operand);}
msousa@682: void *visit( R1_operator_c *symbol) {return XXX_CAL_operator( "R1", this->current_operand);}
lbessard@70: void *visit(CLK_operator_c *symbol) {return XXX_CAL_operator("CLK", this->current_operand);}
msousa@682: void *visit( CU_operator_c *symbol) {return XXX_CAL_operator( "CU", this->current_operand);}
msousa@682: void *visit( CD_operator_c *symbol) {return XXX_CAL_operator( "CD", this->current_operand);}
msousa@682: void *visit( PV_operator_c *symbol) {return XXX_CAL_operator( "PV", this->current_operand);}
msousa@682: void *visit( IN_operator_c *symbol) {return XXX_CAL_operator( "IN", this->current_operand);}
msousa@682: void *visit( PT_operator_c *symbol) {return XXX_CAL_operator( "PT", this->current_operand);}
lbessard@70:
Laurent@706: void *visit(AND_operator_c *symbol) {
msousa@682: if (!get_datatype_info_c::is_ANY_BIT_compatible(symbol->datatype)) ERROR;
msousa@682: XXX_operator(&(this->implicit_variable_result), " &= ", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(OR_operator_c *symbol) {
msousa@682: if (!get_datatype_info_c::is_ANY_BIT_compatible(symbol->datatype)) ERROR;
msousa@682: XXX_operator(&(this->implicit_variable_result), " |= ", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(XOR_operator_c *symbol) {
msousa@682: if (!get_datatype_info_c::is_ANY_BIT_compatible(symbol->datatype)) ERROR;
msousa@682: // '^' is a bit by bit exclusive OR !! Also seems to work with boolean types!
msousa@682: XXX_operator(&(this->implicit_variable_result), " ^= ", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(ANDN_operator_c *symbol) {
msousa@682: if (!get_datatype_info_c::is_ANY_BIT_compatible(symbol->datatype)) ERROR;
msousa@682: XXX_operator(&(this->implicit_variable_result), get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype)?" &= !":" &= ~", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(ORN_operator_c *symbol) {
msousa@682: if (!get_datatype_info_c::is_ANY_BIT_compatible(symbol->datatype)) ERROR;
msousa@682: XXX_operator(&(this->implicit_variable_result), get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype)?" |= !":" |= ~", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(XORN_operator_c *symbol) {
msousa@682: if (!get_datatype_info_c::is_ANY_BIT_compatible(symbol->datatype)) ERROR;
msousa@682: // bit by bit exclusive OR !! Also seems to work with boolean types!
msousa@682: XXX_operator(&(this->implicit_variable_result), get_datatype_info_c::is_BOOL_compatible(this->current_operand->datatype)?" ^= !":" ^= ~", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(ADD_operator_c *symbol) {
msousa@682: if (get_datatype_info_c::is_TIME_compatible(symbol->datatype) || get_datatype_info_c::is_ANY_DATE_compatible (symbol->datatype))
msousa@682: XXX_function(&(this->implicit_variable_result), "__time_add", &(this->implicit_variable_current), this->current_operand);
msousa@682: else XXX_operator(&(this->implicit_variable_result), " += ", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(SUB_operator_c *symbol) {
msousa@682: if (get_datatype_info_c::is_TIME_compatible(symbol->datatype) || get_datatype_info_c::is_ANY_DATE_compatible (symbol->datatype))
msousa@682: XXX_function(&(this->implicit_variable_result), "__time_sub", &(this->implicit_variable_current), this->current_operand);
msousa@682: else XXX_operator(&(this->implicit_variable_result), " -= ", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(MUL_operator_c *symbol) {
msousa@682: if (get_datatype_info_c::is_TIME_compatible(symbol->datatype))
msousa@682: XXX_function(&(this->implicit_variable_result), "__time_mul", &(this->implicit_variable_current), this->current_operand);
msousa@682: else XXX_operator(&(this->implicit_variable_result), " *= ", this->current_operand);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
Laurent@706: void *visit(DIV_operator_c *symbol) {
msousa@682: if (get_datatype_info_c::is_TIME_compatible(symbol->datatype))
msousa@682: XXX_function(&(this->implicit_variable_result), "__time_div", &(this->implicit_variable_current), this->current_operand);
msousa@682: else XXX_operator(&(this->implicit_variable_result), " /= ", this->current_operand);
msousa@682: return NULL;
msousa@682: }
msousa@682:
msousa@682: void *visit(MOD_operator_c *symbol) {XXX_operator(&(this->implicit_variable_result), " %= ", this->current_operand); return NULL;}
lbessard@70:
msousa@653: void *visit(GT_operator_c *symbol) {CMP_operator(this->current_operand, "GT_"); return NULL;}
msousa@653: void *visit(GE_operator_c *symbol) {CMP_operator(this->current_operand, "GE_"); return NULL;}
msousa@653: void *visit(EQ_operator_c *symbol) {CMP_operator(this->current_operand, "EQ_"); return NULL;}
msousa@653: void *visit(LT_operator_c *symbol) {CMP_operator(this->current_operand, "LT_"); return NULL;}
msousa@653: void *visit(LE_operator_c *symbol) {CMP_operator(this->current_operand, "LE_"); return NULL;}
msousa@653: void *visit(NE_operator_c *symbol) {CMP_operator(this->current_operand, "NE_"); return NULL;}
lbessard@70:
lbessard@70:
lbessard@70: //SYM_REF0(CAL_operator_c)
lbessard@70: // This method will be called from within the il_fb_call_c visitor method
lbessard@70: void *visit(CAL_operator_c *symbol) {return NULL;}
lbessard@70:
lbessard@70: //SYM_REF0(CALC_operator_c)
lbessard@70: // This method will be called from within the il_fb_call_c visitor method
lbessard@70: void *visit(CALC_operator_c *symbol) {C_modifier(); return NULL;}
lbessard@70:
lbessard@70: //SYM_REF0(CALCN_operator_c)
lbessard@70: // This method will be called from within the il_fb_call_c visitor method
lbessard@70: void *visit(CALCN_operator_c *symbol) {CN_modifier(); return NULL;}
lbessard@70:
lbessard@70: /* NOTE: The semantics of the RET operator requires us to return a value
lbessard@70: * if the IL code is inside a function, but simply return no value if
lbessard@70: * the IL code is inside a function block or program!
lbessard@70: * Nevertheless, it is the generate_c_c class itself that
lbessard@70: * introduces the 'reaturn ' into the c++ code at the end
lbessard@70: * of every function. This class does not know whether the IL code
lbessard@70: * is inside a function or a function block.
lbessard@70: * We work around this by jumping to the end of the code,
lbessard@70: * that will be marked by the END_LABEL label in the
lbessard@70: * instruction_list_c visitor...
lbessard@70: */
lbessard@70: // SYM_REF0(RET_operator_c)
lbessard@70: void *visit(RET_operator_c *symbol) {
lbessard@70: s4o.print("goto ");s4o.print(END_LABEL);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: // SYM_REF0(RETC_operator_c)
lbessard@70: void *visit(RETC_operator_c *symbol) {
lbessard@70: C_modifier();
lbessard@70: s4o.print("goto ");s4o.print(END_LABEL);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: // SYM_REF0(RETCN_operator_c)
lbessard@70: void *visit(RETCN_operator_c *symbol) {
lbessard@70: CN_modifier();
lbessard@70: s4o.print("goto ");s4o.print(END_LABEL);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: //SYM_REF0(JMP_operator_c)
Laurent@706: void *visit(JMP_operator_c *symbol) {
lbessard@70: if (NULL == this->jump_label) ERROR;
lbessard@70: s4o.print("goto ");
lbessard@70: this->jump_label->accept(*this);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: // SYM_REF0(JMPC_operator_c)
Laurent@706: void *visit(JMPC_operator_c *symbol) {
lbessard@70: if (NULL == this->jump_label) ERROR;
lbessard@70: C_modifier();
lbessard@70: s4o.print("goto ");
lbessard@70: this->jump_label->accept(*this);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: // SYM_REF0(JMPCN_operator_c)
Laurent@706: void *visit(JMPCN_operator_c *symbol) {
lbessard@70: if (NULL == this->jump_label) ERROR;
lbessard@70: CN_modifier();
lbessard@70: s4o.print("goto ");
lbessard@70: this->jump_label->accept(*this);
lbessard@70: return NULL;
lbessard@70: }
lbessard@70:
lbessard@70: #if 0
lbessard@70: /*| [NOT] any_identifier SENDTO */
lbessard@70: SYM_REF2(il_assign_out_operator_c, option, variable_name)
lbessard@70: #endif
lbessard@70:
lbessard@70: }; /* generate_c_il_c */
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70: /* The implementation of the single visit() member function
lbessard@70: * of il_default_variable_c.
lbessard@70: * It can only come after the full declaration of
lbessard@70: * generate_c_il_c. Since we define and declare
lbessard@70: * generate_c_il_c simultaneously, it can only come
lbessard@70: * after the definition...
lbessard@70: */
lbessard@70: void *il_default_variable_c::accept(visitor_c &visitor) {
lbessard@70: /* An ugly hack!! */
lbessard@70: /* This is required because we need to over-ride the base
lbessard@70: * accept(visitor_c &) method of the class symbol_c,
lbessard@70: * so this method may be called through a symbol_c *
lbessard@70: * reference!
lbessard@70: *
lbessard@70: * But, the visitor_c does not include a visitor to
lbessard@70: * an il_default_variable_c, which means that we couldn't
lbessard@70: * simply call visitor.visit(this);
lbessard@70: *
lbessard@70: * We therefore need to use the dynamic_cast hack!!
lbessard@70: *
lbessard@70: * Note too that we can't cast a visitor_c to a
lbessard@70: * il_default_variable_visitor_c, since they are not related.
lbessard@70: * Nor may the il_default_variable_visitor_c inherit from
lbessard@70: * visitor_c, because then generate_c_il_c would contain
lbessard@70: * two visitor_c base classes, one each through
lbessard@70: * il_default_variable_visitor_c and generate_c_type_c
lbessard@70: *
lbessard@70: * We could use virtual inheritance of the visitor_c, but it
lbessard@70: * would probably create more problems than it is worth!
lbessard@70: */
lbessard@70: generate_c_il_c *v;
lbessard@70: v = dynamic_cast(&visitor);
lbessard@70: if (v == NULL) ERROR;
lbessard@70:
lbessard@70: return v->visit(this);
lbessard@70: }
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70:
lbessard@70: il_default_variable_c::il_default_variable_c(const char *var_name_str, symbol_c *current_type) {
lbessard@70: if (NULL == var_name_str) ERROR;
lbessard@70: /* Note: current_type may start off with NULL */
lbessard@70:
lbessard@70: this->var_name = new identifier_c(var_name_str);
lbessard@70: if (NULL == this->var_name) ERROR;
lbessard@70:
msousa@682: this->datatype = current_type;
msousa@682: }