Fix a few more bugs related to FB/function calls in IL.
/*
* matiec - a compiler for the programming languages defined in IEC 61131-3
*
* Copyright (C) 2009-2012 Mario de Sousa (msousa@fe.up.pt)
* Copyright (C) 2012 Manuele Conti (manuele.conti@sirius-es.it)
* Copyright (C) 2012 Matteo Facchinetti (matteo.facchinetti@sirius-es.it)
*
* This program is free software: you can redistribute it and/or modify
* it under the terms of the GNU General Public License as published by
* the Free Software Foundation, either version 3 of the License, or
* (at your option) any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program. If not, see <http://www.gnu.org/licenses/>.
*
*
* This code is made available on the understanding that it will not be
* used in safety-critical situations without a full and competent review.
*/
/*
* An IEC 61131-3 compiler.
*
* Based on the
* FINAL DRAFT - IEC 61131-3, 2nd Ed. (2001-12-10)
*
*/
/*
* Narrow class select and store a data type from candidate data types list for all symbols
*/
#include "narrow_candidate_datatypes.hh"
#include "datatype_functions.hh"
#include <typeinfo>
#include <list>
#include <string>
#include <string.h>
#include <strings.h>
/* set to 1 to see debug info during execution */
static int debug = 0;
narrow_candidate_datatypes_c::narrow_candidate_datatypes_c(symbol_c *ignore) {
}
narrow_candidate_datatypes_c::~narrow_candidate_datatypes_c(void) {
}
/* Only set the symbol's desired datatype to 'datatype' if that datatype is in the candidate_datatype list */
static void set_datatype(symbol_c *datatype, symbol_c *symbol) {
symbol->datatype = NULL;
if (search_in_candidate_datatype_list(datatype, symbol->candidate_datatypes) >= 0)
symbol->datatype = datatype;
}
bool narrow_candidate_datatypes_c::is_widening_compatible(symbol_c *left_type, symbol_c *right_type, symbol_c *result_type, const struct widen_entry widen_table[]) {
for (int k = 0; NULL != widen_table[k].left; k++) {
if ((typeid(*left_type) == typeid(*widen_table[k].left))
&& (typeid(*right_type) == typeid(*widen_table[k].right))
&& (typeid(*result_type) == typeid(*widen_table[k].result))) {
return true;
}
}
return false;
}
/*
* All parameters being passed to the called function MUST be in the parameter list to which f_call points to!
* This means that, for non formal function calls in IL, de current (default value) must be artificially added to the
* beginning of the parameter list BEFORE calling handle_function_call().
*/
void narrow_candidate_datatypes_c::narrow_nonformal_call(symbol_c *f_call, symbol_c *f_decl, int *ext_parm_count) {
symbol_c *call_param_value, *param_type;
identifier_c *param_name;
function_param_iterator_c fp_iterator(f_decl);
function_call_param_iterator_c fcp_iterator(f_call);
int extensible_parameter_highest_index = -1;
unsigned int i;
if (NULL != ext_parm_count) *ext_parm_count = -1;
/* Iterating through the non-formal parameters of the function call */
while((call_param_value = fcp_iterator.next_nf()) != NULL) {
/* Obtaining the type of the value being passed in the function call */
/* Iterate to the next parameter of the function being called.
* Get the name of that parameter, and ignore if EN or ENO.
*/
do {
param_name = fp_iterator.next();
/* If there is no other parameter declared, then we are passing too many parameters... */
/* This error should have been caught in fill_candidate_datatypes_c, but may occur here again when we handle FB invocations!
* In this case, we carry on analysing the code in order to be able to provide relevant error messages
* for that code too!
*/
if(param_name == NULL) break;
} while ((strcmp(param_name->value, "EN") == 0) || (strcmp(param_name->value, "ENO") == 0));
/* Set the desired datatype for this parameter, and call it recursively. */
/* Note that if the call has more parameters than those declared in the function/FB declaration,
* we may be setting this to NULL!
*/
symbol_c *desired_datatype = base_type(fp_iterator.param_type());
if ((NULL != param_name) && (NULL == desired_datatype)) ERROR;
if ((NULL == param_name) && (NULL != desired_datatype)) ERROR;
/* NOTE: When we are handling a nonformal function call made from IL, the first parameter is the 'default' or 'current'
* il value. However, a pointer to the prev_il_instruction is pre-pended into the operand list (done in fill_candidate_datatypes_c,
* and later undone in print_datatypes_error_c - this class is run after the first, and before the latter!), so
* the call
* call_param_value->accept(*this);
* may actually be calling an object of the il_instruction_c class.
* If that is the case, that same il_instruction_c object will be called again inside the for() loop
* of void *narrow_candidate_datatypes_c::visit(instruction_list_c *symbol);
* Since this is not safe (the prev_il_instruction variable will be overwritten with a wrong value!),
* we only do the recursive call if this parameter does not point to a il_instruction_c object.
* Actually, it is easier to check whether it is not the same as the prev_il_instruction.
*/
set_datatype(desired_datatype, call_param_value);
if (call_param_value != prev_il_instruction)
call_param_value->accept(*this);
if (NULL != param_name)
if (extensible_parameter_highest_index < fp_iterator.extensible_param_index())
extensible_parameter_highest_index = fp_iterator.extensible_param_index();
}
/* In the case of a call to an extensible function, we store the highest index
* of the extensible parameters this particular call uses, in the symbol_c object
* of the function call itself!
* In calls to non-extensible functions, this value will be set to -1.
* This information is later used in stage4 to correctly generate the
* output code.
*/
if ((NULL != ext_parm_count) && (extensible_parameter_highest_index >=0) /* if call to extensible function */)
*ext_parm_count = 1 + extensible_parameter_highest_index - fp_iterator.first_extensible_param_index();
}
void narrow_candidate_datatypes_c::narrow_formal_call(symbol_c *f_call, symbol_c *f_decl, int *ext_parm_count) {
symbol_c *call_param_value, *call_param_name, *param_type;
symbol_c *verify_duplicate_param;
identifier_c *param_name;
function_param_iterator_c fp_iterator(f_decl);
function_call_param_iterator_c fcp_iterator(f_call);
int extensible_parameter_highest_index = -1;
identifier_c *extensible_parameter_name;
unsigned int i;
if (NULL != ext_parm_count) *ext_parm_count = -1;
/* Iterating through the formal parameters of the function call */
while((call_param_name = fcp_iterator.next_f()) != NULL) {
/* Obtaining the value being passed in the function call */
call_param_value = fcp_iterator.get_current_value();
/* the following should never occur. If it does, then we have a bug in our code... */
if (NULL == call_param_value) ERROR;
/* Find the corresponding parameter in function declaration */
param_name = fp_iterator.search(call_param_name);
/* Set the desired datatype for this parameter, and call it recursively. */
/* NOTE: When handling a FB call, this narrow_formal_call() may be called to analyse
* an invalid FB call (call with parameters that do not exist on the FB declaration).
* For this reason, the param_name may come out as NULL!
*/
symbol_c *desired_datatype = base_type(fp_iterator.param_type());
if ((NULL != param_name) && (NULL == desired_datatype)) ERROR;
if ((NULL == param_name) && (NULL != desired_datatype)) ERROR;
/* set the desired data type for this parameter */
set_datatype(desired_datatype, call_param_value);
/* And recursively call that parameter/expression, so it can propagate that info */
/* However, when handling an implicit IL FB call, the first parameter is fake, and points to the prev_il_instruction.
* In this case, we do not propagate this info down, as that prev_il_instruction will be called later
* (remember, we iterate backwards through the IL instructions) by the for() loop in the instruction_list_c.
*/
if (call_param_value != prev_il_instruction)
call_param_value->accept(*this);
if (NULL != param_name)
if (extensible_parameter_highest_index < fp_iterator.extensible_param_index())
extensible_parameter_highest_index = fp_iterator.extensible_param_index();
}
/* call is compatible! */
/* In the case of a call to an extensible function, we store the highest index
* of the extensible parameters this particular call uses, in the symbol_c object
* of the function call itself!
* In calls to non-extensible functions, this value will be set to -1.
* This information is later used in stage4 to correctly generate the
* output code.
*/
if ((NULL != ext_parm_count) && (extensible_parameter_highest_index >=0) /* if call to extensible function */)
*ext_parm_count = 1 + extensible_parameter_highest_index - fp_iterator.first_extensible_param_index();
}
/*
typedef struct {
symbol_c *function_name,
symbol_c *nonformal_operand_list,
symbol_c * formal_operand_list,
std::vector <symbol_c *> &candidate_functions,
symbol_c &*called_function_declaration,
int &extensible_param_count
} generic_function_call_t;
*/
void narrow_candidate_datatypes_c::narrow_function_invocation(symbol_c *fcall, generic_function_call_t fcall_data) {
/* set the called_function_declaration. */
fcall_data.called_function_declaration = NULL;
/* set the called_function_declaration taking into account the datatype that we need to return */
for(unsigned int i = 0; i < fcall->candidate_datatypes.size(); i++) {
if (is_type_equal(fcall->candidate_datatypes[i], fcall->datatype)) {
fcall_data.called_function_declaration = fcall_data.candidate_functions[i];
break;
}
}
/* NOTE: If we can't figure out the declaration of the function being called, this is not
* necessarily an internal compiler error. It could be because the symbol->datatype is NULL
* (because the ST code being analysed has an error _before_ this function invocation).
* However, we don't just give, up, we carry on recursivly analysing the code, so as to be
* able to print out any error messages related to the parameters being passed in this function
* invocation.
*/
/* if (NULL == symbol->called_function_declaration) ERROR; */
if (fcall->candidate_datatypes.size() == 1) {
/* If only one function declaration, then we use that (even if symbol->datatypes == NULL)
* so we can check for errors in the expressions used to pass parameters in this
* function invocation.
*/
fcall_data.called_function_declaration = fcall_data.candidate_functions[0];
}
/* If an overloaded function is being invoked, and we cannot determine which version to use,
* then we can not meaningfully verify the expressions used inside that function invocation.
* We simply give up!
*/
if (NULL == fcall_data.called_function_declaration)
return;
if (NULL != fcall_data.nonformal_operand_list) narrow_nonformal_call(fcall, fcall_data.called_function_declaration, &(fcall_data.extensible_param_count));
if (NULL != fcall_data. formal_operand_list) narrow_formal_call(fcall, fcall_data.called_function_declaration, &(fcall_data.extensible_param_count));
return;
}
/* narrow implicit FB call in IL.
* e.g. CLK ton_var
* CU counter_var
*
* The algorithm will be to build a fake il_fb_call_c equivalent to the implicit IL FB call, and let
* the visit(il_fb_call_c *) method handle it!
*/
void narrow_candidate_datatypes_c::narrow_implicit_il_fb_call(symbol_c *il_instruction, const char *param_name, symbol_c *&called_fb_declaration) {
if (NULL == called_fb_declaration)
/* The fill_candidate_datatypes_c was not able to determine which FB is being called!
* This may be because the il_operand is not the name of a FB instance, or no operand was given.
* In that case, we just give up!
*/
return;
if (NULL == prev_il_instruction) {
/* This IL implicit FB call (e.g. CLK ton_var) is not preceded by another IL instruction
* (or list of instructions) that will set the IL current/default value.
* We cannot proceed verifying type compatibility of something that does not ecist.
*/
return;
}
identifier_c variable_name(param_name);
// SYM_REF1(il_assign_operator_c, variable_name)
il_assign_operator_c il_assign_operator(&variable_name);
// SYM_REF3(il_param_assignment_c, il_assign_operator, il_operand, simple_instr_list)
il_param_assignment_c il_param_assignment(&il_assign_operator, prev_il_instruction/*il_operand*/, NULL);
il_param_list_c il_param_list;
il_param_list.add_element(&il_param_assignment);
// SYM_REF4(il_fb_call_c, il_call_operator, fb_name, il_operand_list, il_param_list, symbol_c *called_fb_declaration)
il_fb_call_c il_fb_call(NULL, il_operand, NULL, &il_param_list);
/* A FB call does not return any datatype, but the IL instructions that come after this
* FB call may require a specific datatype in the il current/default variable,
* so we must pass this information up to the IL instruction before the FB call, since it will
* be that IL instruction that will be required to produce the desired dtataype.
*
* The above will be done by the visit(il_fb_call_c *) method, so we must make sure to
* correctly set up the il_fb_call.datatype variable!
*/
copy_candidate_datatype_list(il_instruction/*from*/, &il_fb_call/*to*/);
il_fb_call.datatype = il_instruction->datatype;
il_fb_call.accept(*this);
il_instruction->datatype = il_fb_call.datatype;
}
/* a helper function... */
symbol_c *narrow_candidate_datatypes_c::base_type(symbol_c *symbol) {
/* NOTE: symbol == NULL is valid. It will occur when, for e.g., an undefined/undeclared symbolic_variable is used
* in the code.
*/
if (symbol == NULL) return NULL;
return (symbol_c *)symbol->accept(search_base_type);
}
/*********************/
/* B 1.2 - Constants */
/*********************/
/**********************/
/* B 1.3 - Data types */
/**********************/
/********************************/
/* B 1.3.3 - Derived data types */
/********************************/
/* signed_integer DOTDOT signed_integer */
// SYM_REF2(subrange_c, lower_limit, upper_limit)
void *narrow_candidate_datatypes_c::visit(subrange_c *symbol) {
symbol->lower_limit->datatype = symbol->datatype;
symbol->lower_limit->accept(*this);
symbol->upper_limit->datatype = symbol->datatype;
symbol->upper_limit->accept(*this);
return NULL;
}
/* simple_specification ASSIGN constant */
// SYM_REF2(simple_spec_init_c, simple_specification, constant)
void *narrow_candidate_datatypes_c::visit(simple_spec_init_c *symbol) {
symbol_c *datatype = base_type(symbol->simple_specification);
if (NULL != symbol->constant) {
int typeoffset = search_in_candidate_datatype_list(datatype, symbol->constant->candidate_datatypes);
if (typeoffset >= 0)
symbol->constant->datatype = symbol->constant->candidate_datatypes[typeoffset];
}
return NULL;
}
/*********************/
/* B 1.4 - Variables */
/*********************/
/********************************************/
/* B 1.4.1 - Directly Represented Variables */
/********************************************/
/*************************************/
/* B 1.4.2 - Multi-element variables */
/*************************************/
/* subscripted_variable '[' subscript_list ']' */
// SYM_REF2(array_variable_c, subscripted_variable, subscript_list)
void *narrow_candidate_datatypes_c::visit(array_variable_c *symbol) {
/* we need to check the data types of the expressions used for the subscripts... */
symbol->subscript_list->accept(*this);
return NULL;
}
/* subscript_list ',' subscript */
// SYM_LIST(subscript_list_c)
void *narrow_candidate_datatypes_c::visit(subscript_list_c *symbol) {
for (int i = 0; i < symbol->n; i++) {
for (unsigned int k = 0; k < symbol->elements[i]->candidate_datatypes.size(); k++) {
if (is_ANY_INT_type(symbol->elements[i]->candidate_datatypes[k]))
symbol->elements[i]->datatype = symbol->elements[i]->candidate_datatypes[k];
}
symbol->elements[i]->accept(*this);
}
return NULL;
}
/************************************/
/* B 1.5 Program organization units */
/************************************/
/*********************/
/* B 1.5.1 Functions */
/*********************/
void *narrow_candidate_datatypes_c::visit(function_declaration_c *symbol) {
search_varfb_instance_type = new search_varfb_instance_type_c(symbol);
symbol->var_declarations_list->accept(*this);
if (debug) printf("Narrowing candidate data types list in body of function %s\n", ((token_c *)(symbol->derived_function_name))->value);
symbol->function_body->accept(*this);
delete search_varfb_instance_type;
search_varfb_instance_type = NULL;
return NULL;
}
/***************************/
/* B 1.5.2 Function blocks */
/***************************/
void *narrow_candidate_datatypes_c::visit(function_block_declaration_c *symbol) {
search_varfb_instance_type = new search_varfb_instance_type_c(symbol);
symbol->var_declarations->accept(*this);
if (debug) printf("Narrowing candidate data types list in body of FB %s\n", ((token_c *)(symbol->fblock_name))->value);
symbol->fblock_body->accept(*this);
delete search_varfb_instance_type;
search_varfb_instance_type = NULL;
return NULL;
}
/********************/
/* B 1.5.3 Programs */
/********************/
void *narrow_candidate_datatypes_c::visit(program_declaration_c *symbol) {
search_varfb_instance_type = new search_varfb_instance_type_c(symbol);
symbol->var_declarations->accept(*this);
if (debug) printf("Narrowing candidate data types list in body of program %s\n", ((token_c *)(symbol->program_type_name))->value);
symbol->function_block_body->accept(*this);
delete search_varfb_instance_type;
search_varfb_instance_type = NULL;
return NULL;
}
/********************************/
/* B 1.7 Configuration elements */
/********************************/
void *narrow_candidate_datatypes_c::visit(configuration_declaration_c *symbol) {
// TODO !!!
/* for the moment we must return NULL so semantic analysis of remaining code is not interrupted! */
return NULL;
}
/****************************************/
/* B.2 - Language IL (Instruction List) */
/****************************************/
/***********************************/
/* B 2.1 Instructions and Operands */
/***********************************/
/*| instruction_list il_instruction */
// SYM_LIST(instruction_list_c)
void *narrow_candidate_datatypes_c::visit(instruction_list_c *symbol) {
/* In order to execute the narrow algoritm correctly, we need to go through the instructions backwards,
* so we can not use the base class' visitor
*/
for(int i = symbol->n-1; i >= 0; i--) {
symbol->elements[i]->accept(*this);
}
return NULL;
}
/* | label ':' [il_incomplete_instruction] eol_list */
// SYM_REF2(il_instruction_c, label, il_instruction)
// void *visit(instruction_list_c *symbol);
void *narrow_candidate_datatypes_c::visit(il_instruction_c *symbol) {
if (NULL == symbol->il_instruction) {
/* this empty/null il_instruction cannot generate the desired datatype. We pass on the request to the previous il instruction. */
if (NULL != symbol->prev_il_instruction)
symbol->prev_il_instruction->datatype = symbol->datatype;
} else {
/* Tell the il_instruction the datatype that it must generate - this was chosen by the next il_instruction (remember: we are iterating backwards!) */
symbol->il_instruction->datatype = symbol->datatype;
prev_il_instruction = symbol->prev_il_instruction;
symbol->il_instruction->accept(*this);
prev_il_instruction = NULL;
}
return NULL;
}
// void *visit(instruction_list_c *symbol);
void *narrow_candidate_datatypes_c::visit(il_simple_operation_c *symbol) {
/* Tell the il_simple_operator the datatype that it must generate - this was chosen by the next il_instruction (we iterate backwards!) */
symbol->il_simple_operator->datatype = symbol->datatype;
/* recursive call to see whether data types are compatible */
il_operand = symbol->il_operand;
symbol->il_simple_operator->accept(*this);
il_operand = NULL;
return NULL;
}
/* | function_name [il_operand_list] */
/* NOTE: The parameters 'called_function_declaration' and 'extensible_param_count' are used to pass data between the stage 3 and stage 4. */
// SYM_REF2(il_function_call_c, function_name, il_operand_list, symbol_c *called_function_declaration; int extensible_param_count;)
void *narrow_candidate_datatypes_c::visit(il_function_call_c *symbol) {
generic_function_call_t fcall_param = {
/* fcall_param.function_name = */ symbol->function_name,
/* fcall_param.nonformal_operand_list = */ symbol->il_operand_list,
/* fcall_param.formal_operand_list = */ NULL,
/* enum {POU_FB, POU_function} POU_type = */ generic_function_call_t::POU_function,
/* fcall_param.candidate_functions = */ symbol->candidate_functions,
/* fcall_param.called_function_declaration = */ symbol->called_function_declaration,
/* fcall_param.extensible_param_count = */ symbol->extensible_param_count
};
/* The first parameter of a non formal function call in IL will be the 'current value' (i.e. the prev_il_instruction)
* In order to be able to handle this without coding special cases, we simply prepend that symbol
* to the il_operand_list (done in fill_candidate_datatypes_c), and remove it later (in the print_datatypes_error_c).
*
* Since this class is executed after fill_candidate_datatypes_c, and before print_datatypes_error_c,
* the following code is actually correct!
*/
narrow_function_invocation(symbol, fcall_param);
/* The desired datatype of the previous il instruction was already set by narrow_function_invocation() */
return NULL;
}
/* MJS: Manuele, could you please not delete the following 2 lines of comments. They help me understand where this class is used
* and when it is created by bison - syntax parse, and how it can show up in the abstract syntax tree.
*
* Actually, it could be helpful if we could have all the similar comments already present in visit_expression_type_c
* in the 3 new classes fill/narrow/print candidate datatype
*/
/* | il_expr_operator '(' [il_operand] eol_list [simple_instr_list] ')' */
// SYM_REF3(il_expression_c, il_expr_operator, il_operand, simple_instr_list);
void *narrow_candidate_datatypes_c::visit(il_expression_c *symbol) {
/* MJS: TODO... */
return NULL;
}
/* il_call_operator prev_declared_fb_name
* | il_call_operator prev_declared_fb_name '(' ')'
* | il_call_operator prev_declared_fb_name '(' eol_list ')'
* | il_call_operator prev_declared_fb_name '(' il_operand_list ')'
* | il_call_operator prev_declared_fb_name '(' eol_list il_param_list ')'
*/
/* NOTE: The parameter 'called_fb_declaration'is used to pass data between stage 3 and stage4 (although currently it is not used in stage 4 */
// SYM_REF4(il_fb_call_c, il_call_operator, fb_name, il_operand_list, il_param_list, symbol_c *called_fb_declaration)
void *narrow_candidate_datatypes_c::visit(il_fb_call_c *symbol) {
/* set the desired datatype of the previous il instruction */
/* NOTE 1:
* A FB call does not return any datatype, but the IL instructions that come after this
* FB call may require a specific datatype in the il current/default variable,
* so we must pass this information up to the IL instruction before the FB call, since it will
* be that IL instruction that will be required to produce the desired dtataype.
* NOTE 2:
* Copying the required datatype must be done before calling narrow_[non]formal_call().
* Note that this visit(il_fb_call_c *) method will be called from narrow_implicit_il_fb_call().
* This means that we must also be able to handle implicit IL FB calls (e.g. CU counter_var)
* correctly in this visitor class.
* When handling these implicit IL calls, the parameter_value being passed to the FB parameter
* (in the previous example, the 'CU' parameter) is actually the prev_il_instruction.
* In this case, the prev_il_instruction->datatype will be set by the arrow_[non]formal_call(),
* using the prama_value pointer to this same object.
* If we were to have the following line of code after calling arrow_[non]formal_call(),
* we would then be overwriting the datatype with the wrong value!
*/
if (NULL != prev_il_instruction)
prev_il_instruction->datatype = symbol->datatype;
/* Note: We do not use the symbol->called_fb_declaration value (set in fill_candidate_datatypes_c)
* because we try to identify any other datatype errors in the expressions used in the
* parameters to the FB call. e.g.
* fb_var(
* in1 := var1,
* in2 := (
* LD 56
* ADD 43
* )
* )
* even it the call to the FB is invalid.
* This makes sense because it may be errors in those expressions which are
* making this an invalid call, so it makes sense to point them out to the user!
*/
symbol_c *fb_decl = search_varfb_instance_type->get_basetype_decl(symbol->fb_name);
/* Although a call to a non-declared FB is a semantic error, this is currently caught by stage 2! */
if (NULL == fb_decl) ERROR;
if (NULL != symbol->il_operand_list) narrow_nonformal_call(symbol, fb_decl);
if (NULL != symbol-> il_param_list) narrow_formal_call(symbol, fb_decl);
/* NOTE:
* When handling these implicit IL calls, the parameter_value being passed to the FB parameter
* (in the previous example, the 'CU' parameter) is actually the prev_il_instruction.
* In this case, the prev_il_instruction->datatype will be set by the narrow_[non]formal_call(),
* using the param_value pointer to this same object.
*
* We must check that the datatype required by the IL instructions following this FB call
* is the same as that required for the first parameter. If not, then we have a semantic error,
* and we set it to NULL.
*
* However, we only do that if:
* - There really exists an il_prev_instruction
* (if it does not exist, it will be a semantic error. But that will be caught by the print_datatypes_error_c)
* - The IL instruction that comes after this IL FB call actually asked this FB call for a specific
* datatype in the current/default vairable, once this IL FB call returns.
* However, sometimes, (for e.g., this FB call is the last in the IL list) the subsequent FB to not aks this
* FB call for any datatype. In that case, then the datatype required to pass to the first parameter of the
* FB call must be left unchanged!
*/
if ((NULL != prev_il_instruction) && (NULL != symbol->datatype))
if (!is_type_equal(prev_il_instruction->datatype, symbol->datatype)) {
prev_il_instruction->datatype = NULL;
}
return NULL;
}
/* | function_name '(' eol_list [il_param_list] ')' */
/* NOTE: The parameter 'called_function_declaration' is used to pass data between the stage 3 and stage 4. */
// SYM_REF2(il_formal_funct_call_c, function_name, il_param_list, symbol_c *called_function_declaration; int extensible_param_count;)
void *narrow_candidate_datatypes_c::visit(il_formal_funct_call_c *symbol) {
generic_function_call_t fcall_param = {
/* fcall_param.function_name = */ symbol->function_name,
/* fcall_param.nonformal_operand_list = */ NULL,
/* fcall_param.formal_operand_list = */ symbol->il_param_list,
/* enum {POU_FB, POU_function} POU_type = */ generic_function_call_t::POU_function,
/* fcall_param.candidate_functions = */ symbol->candidate_functions,
/* fcall_param.called_function_declaration = */ symbol->called_function_declaration,
/* fcall_param.extensible_param_count = */ symbol->extensible_param_count
};
narrow_function_invocation(symbol, fcall_param);
/* The desired datatype of the previous il instruction was already set by narrow_function_invocation() */
return NULL;
}
/*
void *visit(il_operand_list_c *symbol);
void *visit(simple_instr_list_c *symbol);
void *visit(il_param_list_c *symbol);
void *visit(il_param_assignment_c *symbol);
void *visit(il_param_out_assignment_c *symbol);
*/
/*******************/
/* B 2.2 Operators */
/*******************/
void *narrow_candidate_datatypes_c::handle_il_instruction(symbol_c *symbol) {
if (NULL == symbol->datatype)
/* next IL instructions were unable to determine the datatype this instruction should produce */
return NULL;
/* set the datatype for the operand */
il_operand->datatype = symbol->datatype;
il_operand->accept(*this);
/* set the desired datatype of the previous il instruction */
prev_il_instruction->datatype = symbol->datatype;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(LD_operator_c *symbol) {
if (NULL == symbol->datatype)
/* next IL instructions were unable to determine the datatype this instruction should produce */
return NULL;
/* set the datatype for the operand */
il_operand->datatype = symbol->datatype;
il_operand->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(LDN_operator_c *symbol) {
if (NULL == symbol->datatype)
/* next IL instructions were unable to determine the datatype this instruction should produce */
return NULL;
/* set the datatype for the operand */
il_operand->datatype = symbol->datatype;
il_operand->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(ST_operator_c *symbol) {
if (debug) printf("narrow_candidate_datatypes_c::visit(ST_operator_c *symbol) called.\n");
if (symbol->candidate_datatypes.size() != 1)
return NULL;
symbol->datatype = symbol->candidate_datatypes[0];
/* set the datatype for the operand */
il_operand->datatype = symbol->datatype;
il_operand->accept(*this);
/* set the desired datatype of the previous il instruction */
prev_il_instruction->datatype = symbol->datatype;
if (debug) printf("narrow_candidate_datatypes_c::visit(ST_operator_c *symbol) returning. previous_il_instruction->datatype = %p\n", prev_il_instruction->datatype);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(STN_operator_c *symbol) {
if (symbol->candidate_datatypes.size() != 1)
return NULL;
symbol->datatype = symbol->candidate_datatypes[0];
/* set the datatype for the operand */
il_operand->datatype = symbol->datatype;
il_operand->accept(*this);
/* set the desired datatype of the previous il instruction */
prev_il_instruction->datatype = symbol->datatype;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(NOT_operator_c *symbol) {
prev_il_instruction = symbol;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(S_operator_c *symbol) {
/* TODO: what if this is a FB call? */
return handle_il_instruction(symbol);
}
void *narrow_candidate_datatypes_c::visit(R_operator_c *symbol) {
/* TODO: what if this is a FB call? */
return handle_il_instruction(symbol);
}
void *narrow_candidate_datatypes_c::visit(S1_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "S1", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(R1_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "R1", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(CLK_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "CLK", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(CU_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "CU", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(CD_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "CD", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(PV_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "PV", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(IN_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "IN", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(PT_operator_c *symbol) {
narrow_implicit_il_fb_call(symbol, "PT", symbol->called_fb_declaration);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(AND_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(OR_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(XOR_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(ANDN_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(ORN_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(XORN_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(ADD_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(SUB_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(MUL_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(DIV_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(MOD_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(GT_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(GE_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(EQ_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(LT_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(LE_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(NE_operator_c *symbol) {return handle_il_instruction(symbol);}
void *narrow_candidate_datatypes_c::visit(CAL_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(CALC_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(CALCN_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(RET_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(RETC_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(RETCN_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(JMP_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(JMPC_operator_c *symbol) {
return NULL;
}
void *narrow_candidate_datatypes_c::visit(JMPCN_operator_c *symbol) {
return NULL;
}
/* Symbol class handled together with function call checks */
// void *visit(il_assign_operator_c *symbol, variable_name);
/* Symbol class handled together with function call checks */
// void *visit(il_assign_operator_c *symbol, option, variable_name);
/***************************************/
/* B.3 - Language ST (Structured Text) */
/***************************************/
/***********************/
/* B 3.1 - Expressions */
/***********************/
void *narrow_candidate_datatypes_c::visit(or_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (is_type_equal(symbol->l_exp->candidate_datatypes[i], symbol->r_exp->candidate_datatypes[j])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(xor_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (is_type_equal(symbol->l_exp->candidate_datatypes[i], symbol->r_exp->candidate_datatypes[j])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(and_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (typeid(*symbol->l_exp->candidate_datatypes[i]) == typeid(*symbol->r_exp->candidate_datatypes[j])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(equ_expression_c *symbol) {
/* Here symbol->datatype has already assigned to BOOL
* In conditional symbols like =, <>, =<, <, >, >= we have to set
* l_exp and r_exp expression matched with compatible type.
* Example:
* INT#14 = INT#81
* equ_expression_c symbol->datatype = BOOL from top visit
* symbol->l_exp->datatype => INT
* symbol->r_exp->datatype => INT
*/
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (typeid(*symbol->l_exp->candidate_datatypes[i]) == typeid(*symbol->r_exp->candidate_datatypes[j])) {
/*
* We do not need to check whether the type is an ANY_ELEMENTARY here.
* That was already done in fill_candidate_datatypes_c.
*/
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->r_exp->datatype = selected_type;
}
else
ERROR;
symbol->l_exp->accept(*this);
symbol->r_exp->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(notequ_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (typeid(*symbol->l_exp->candidate_datatypes[i]) == typeid(*symbol->r_exp->candidate_datatypes[j])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(lt_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (typeid(*symbol->l_exp->candidate_datatypes[i]) == typeid(*symbol->r_exp->candidate_datatypes[j])
&& is_ANY_ELEMENTARY_type(symbol->l_exp->candidate_datatypes[i])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(gt_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (typeid(*symbol->l_exp->candidate_datatypes[i]) == typeid(*symbol->r_exp->candidate_datatypes[j])
&& is_ANY_ELEMENTARY_type(symbol->l_exp->candidate_datatypes[i])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(le_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (typeid(*symbol->l_exp->candidate_datatypes[i]) == typeid(*symbol->r_exp->candidate_datatypes[j])
&& is_ANY_ELEMENTARY_type(symbol->l_exp->candidate_datatypes[i])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(ge_expression_c *symbol) {
symbol_c * selected_type = NULL;
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
if (typeid(*symbol->l_exp->candidate_datatypes[i]) == typeid(*symbol->r_exp->candidate_datatypes[j])
&& is_ANY_ELEMENTARY_type(symbol->l_exp->candidate_datatypes[i])) {
selected_type = symbol->l_exp->candidate_datatypes[i];
break;
}
}
}
if (NULL != selected_type) {
symbol->l_exp->datatype = selected_type;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = selected_type;
symbol->r_exp->accept(*this);
}
else
ERROR;
return NULL;
}
void *narrow_candidate_datatypes_c::visit(add_expression_c *symbol) {
int count = 0;
if (is_ANY_NUM_compatible(symbol->datatype)) {
symbol->l_exp->datatype = symbol->datatype;
symbol->r_exp->datatype = symbol->datatype;
count++;
} else {
/* TIME data type */
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
/* test widening compatibility */
if (is_widening_compatible(symbol->l_exp->candidate_datatypes[i],
symbol->r_exp->candidate_datatypes[j],
symbol->datatype, widen_ADD_table)) {
symbol->l_exp->datatype = symbol->l_exp->candidate_datatypes[i];
symbol->r_exp->datatype = symbol->r_exp->candidate_datatypes[j];
count ++;
}
}
}
}
if (count > 1)
ERROR;
symbol->l_exp->accept(*this);
symbol->r_exp->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(sub_expression_c *symbol) {
int count = 0;
if (is_ANY_NUM_compatible(symbol->datatype)) {
symbol->l_exp->datatype = symbol->datatype;
symbol->r_exp->datatype = symbol->datatype;
count++;
} else {
/* TIME data type */
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
/* test widening compatibility */
if (is_widening_compatible(symbol->l_exp->candidate_datatypes[i],
symbol->r_exp->candidate_datatypes[j],
symbol->datatype, widen_SUB_table)) {
symbol->l_exp->datatype = symbol->l_exp->candidate_datatypes[i];
symbol->r_exp->datatype = symbol->r_exp->candidate_datatypes[j];
count ++;
}
}
}
}
if (count > 1)
ERROR;
symbol->l_exp->accept(*this);
symbol->r_exp->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(mul_expression_c *symbol) {
int count = 0;
if (is_ANY_NUM_compatible(symbol->datatype)) {
symbol->l_exp->datatype = symbol->datatype;
symbol->r_exp->datatype = symbol->datatype;
count++;
} else {
/* TIME data type */
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
/* test widening compatibility */
if (is_widening_compatible(symbol->l_exp->candidate_datatypes[i],
symbol->r_exp->candidate_datatypes[j],
symbol->datatype, widen_MUL_table)) {
symbol->l_exp->datatype = symbol->l_exp->candidate_datatypes[i];
symbol->r_exp->datatype = symbol->r_exp->candidate_datatypes[j];
count ++;
}
}
}
}
if (count > 1)
ERROR;
symbol->l_exp->accept(*this);
symbol->r_exp->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(div_expression_c *symbol) {
int count = 0;
if (is_ANY_NUM_compatible(symbol->datatype)) {
symbol->l_exp->datatype = symbol->datatype;
symbol->r_exp->datatype = symbol->datatype;
count++;
} else {
/* TIME data type */
for(unsigned int i = 0; i < symbol->l_exp->candidate_datatypes.size(); i++) {
for(unsigned int j = 0; j < symbol->r_exp->candidate_datatypes.size(); j++) {
/* test widening compatibility */
if (is_widening_compatible(symbol->l_exp->candidate_datatypes[i],
symbol->r_exp->candidate_datatypes[j],
symbol->datatype, widen_DIV_table)) {
symbol->l_exp->datatype = symbol->l_exp->candidate_datatypes[i];
symbol->r_exp->datatype = symbol->r_exp->candidate_datatypes[j];
count ++;
}
}
}
}
if (count > 1)
ERROR;
symbol->l_exp->accept(*this);
symbol->r_exp->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(mod_expression_c *symbol) {
symbol->l_exp->datatype = symbol->datatype;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = symbol->datatype;
symbol->r_exp->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(power_expression_c *symbol) {
symbol->l_exp->datatype = symbol->datatype;
symbol->l_exp->accept(*this);
if (! symbol->r_exp->candidate_datatypes.size()){
symbol->r_exp->datatype = symbol->r_exp->candidate_datatypes[0];
symbol->r_exp->accept(*this);
}
return NULL;
}
void *narrow_candidate_datatypes_c::visit(neg_expression_c *symbol) {
symbol->exp->datatype = symbol->datatype;
symbol->exp->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(not_expression_c *symbol) {
symbol->exp->datatype = symbol->datatype;
symbol->exp->accept(*this);
return NULL;
}
/* NOTE: The parameter 'called_function_declaration', 'extensible_param_count' and 'candidate_functions' are used to pass data between the stage 3 and stage 4. */
/* formal_param_list -> may be NULL ! */
/* nonformal_param_list -> may be NULL ! */
// SYM_REF3(function_invocation_c, function_name, formal_param_list, nonformal_param_list, symbol_c *called_function_declaration; int extensible_param_count; std::vector <symbol_c *> candidate_functions;)
void *narrow_candidate_datatypes_c::visit(function_invocation_c *symbol) {
generic_function_call_t fcall_param = {
/* fcall_param.function_name = */ symbol->function_name,
/* fcall_param.nonformal_operand_list = */ symbol->nonformal_param_list,
/* fcall_param.formal_operand_list = */ symbol->formal_param_list,
/* enum {POU_FB, POU_function} POU_type = */ generic_function_call_t::POU_function,
/* fcall_param.candidate_functions = */ symbol->candidate_functions,
/* fcall_param.called_function_declaration = */ symbol->called_function_declaration,
/* fcall_param.extensible_param_count = */ symbol->extensible_param_count
};
narrow_function_invocation(symbol, fcall_param);
return NULL;
}
/********************/
/* B 3.2 Statements */
/********************/
/*********************************/
/* B 3.2.1 Assignment Statements */
/*********************************/
void *narrow_candidate_datatypes_c::visit(assignment_statement_c *symbol) {
if (symbol->candidate_datatypes.size() != 1)
return NULL;
symbol->datatype = symbol->candidate_datatypes[0];
symbol->l_exp->datatype = symbol->datatype;
symbol->l_exp->accept(*this);
symbol->r_exp->datatype = symbol->datatype;
symbol->r_exp->accept(*this);
return NULL;
}
/*****************************************/
/* B 3.2.2 Subprogram Control Statements */
/*****************************************/
void *narrow_candidate_datatypes_c::visit(fb_invocation_c *symbol) {
/* Note: We do not use the symbol->called_fb_declaration value (set in fill_candidate_datatypes_c)
* because we try to identify any other datatype errors in the expressions used in the
* parameters to the FB call (e.g. fb_var(var1 * 56 + func(var * 43)) )
* even it the call to the FB is invalid.
* This makes sense because it may be errors in those expressions which are
* making this an invalid call, so it makes sense to point them out to the user!
*/
symbol_c *fb_decl = search_varfb_instance_type->get_basetype_decl(symbol->fb_name);
/* Although a call to a non-declared FB is a semantic error, this is currently caught by stage 2! */
if (NULL == fb_decl) ERROR;
if (NULL != symbol->nonformal_param_list) narrow_nonformal_call(symbol, fb_decl);
if (NULL != symbol-> formal_param_list) narrow_formal_call(symbol, fb_decl);
return NULL;
}
/********************************/
/* B 3.2.3 Selection Statements */
/********************************/
void *narrow_candidate_datatypes_c::visit(if_statement_c *symbol) {
for(unsigned int i = 0; i < symbol->expression->candidate_datatypes.size(); i++) {
if (is_type(symbol->expression->candidate_datatypes[i], bool_type_name_c))
symbol->expression->datatype = symbol->expression->candidate_datatypes[i];
}
symbol->expression->accept(*this);
if (NULL != symbol->statement_list)
symbol->statement_list->accept(*this);
if (NULL != symbol->elseif_statement_list)
symbol->elseif_statement_list->accept(*this);
if (NULL != symbol->else_statement_list)
symbol->else_statement_list->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(elseif_statement_c *symbol) {
for (unsigned int i = 0; i < symbol->expression->candidate_datatypes.size(); i++) {
if (is_type(symbol->expression->candidate_datatypes[i], bool_type_name_c))
symbol->expression->datatype = symbol->expression->candidate_datatypes[i];
}
symbol->expression->accept(*this);
if (NULL != symbol->statement_list)
symbol->statement_list->accept(*this);
return NULL;
}
/* CASE expression OF case_element_list ELSE statement_list END_CASE */
// SYM_REF3(case_statement_c, expression, case_element_list, statement_list)
void *narrow_candidate_datatypes_c::visit(case_statement_c *symbol) {
for (unsigned int i = 0; i < symbol->expression->candidate_datatypes.size(); i++) {
if ((is_ANY_INT_type(symbol->expression->candidate_datatypes[i]))
|| (search_base_type.type_is_enumerated(symbol->expression->candidate_datatypes[i])))
symbol->expression->datatype = symbol->expression->candidate_datatypes[i];
}
symbol->expression->accept(*this);
if (NULL != symbol->statement_list)
symbol->statement_list->accept(*this);
if (NULL != symbol->case_element_list) {
symbol->case_element_list->datatype = symbol->expression->datatype;
symbol->case_element_list->accept(*this);
}
return NULL;
}
/* helper symbol for case_statement */
// SYM_LIST(case_element_list_c)
void *narrow_candidate_datatypes_c::visit(case_element_list_c *symbol) {
for (int i = 0; i < symbol->n; i++) {
symbol->elements[i]->datatype = symbol->datatype;
symbol->elements[i]->accept(*this);
}
return NULL;
}
/* case_list ':' statement_list */
// SYM_REF2(case_element_c, case_list, statement_list)
void *narrow_candidate_datatypes_c::visit(case_element_c *symbol) {
symbol->case_list->datatype = symbol->datatype;
symbol->case_list->accept(*this);
symbol->statement_list->accept(*this);
return NULL;
}
// SYM_LIST(case_list_c)
void *narrow_candidate_datatypes_c::visit(case_list_c *symbol) {
for (int i = 0; i < symbol->n; i++) {
for (unsigned int k = 0; k < symbol->elements[i]->candidate_datatypes.size(); k++) {
if (is_type_equal(symbol->datatype, symbol->elements[i]->candidate_datatypes[k]))
symbol->elements[i]->datatype = symbol->elements[i]->candidate_datatypes[k];
}
/* NOTE: this may be an integer, a subrange_c, or a enumerated value! */
symbol->elements[i]->accept(*this);
}
return NULL;
}
/********************************/
/* B 3.2.4 Iteration Statements */
/********************************/
void *narrow_candidate_datatypes_c::visit(for_statement_c *symbol) {
/* Control variable */
for(unsigned int i = 0; i < symbol->control_variable->candidate_datatypes.size(); i++) {
if (is_ANY_INT_type(symbol->control_variable->candidate_datatypes[i])) {
symbol->control_variable->datatype = symbol->control_variable->candidate_datatypes[i];
}
}
symbol->control_variable->accept(*this);
/* BEG expression */
for(unsigned int i = 0; i < symbol->beg_expression->candidate_datatypes.size(); i++) {
if (is_type_equal(symbol->control_variable->datatype,symbol->beg_expression->candidate_datatypes[i]) &&
is_ANY_INT_type(symbol->beg_expression->candidate_datatypes[i])) {
symbol->beg_expression->datatype = symbol->beg_expression->candidate_datatypes[i];
}
}
symbol->beg_expression->accept(*this);
/* END expression */
for(unsigned int i = 0; i < symbol->end_expression->candidate_datatypes.size(); i++) {
if (is_type_equal(symbol->control_variable->datatype,symbol->end_expression->candidate_datatypes[i]) &&
is_ANY_INT_type(symbol->end_expression->candidate_datatypes[i])) {
symbol->end_expression->datatype = symbol->end_expression->candidate_datatypes[i];
}
}
symbol->end_expression->accept(*this);
/* BY expression */
if (NULL != symbol->by_expression) {
for(unsigned int i = 0; i < symbol->by_expression->candidate_datatypes.size(); i++) {
if (is_type_equal(symbol->control_variable->datatype,symbol->by_expression->candidate_datatypes[i]) &&
is_ANY_INT_type(symbol->by_expression->candidate_datatypes[i])) {
symbol->by_expression->datatype = symbol->by_expression->candidate_datatypes[i];
}
}
symbol->by_expression->accept(*this);
}
if (NULL != symbol->statement_list)
symbol->statement_list->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(while_statement_c *symbol) {
for (unsigned int i = 0; i < symbol->expression->candidate_datatypes.size(); i++) {
if(is_BOOL_type(symbol->expression->candidate_datatypes[i]))
symbol->expression->datatype = symbol->expression->candidate_datatypes[i];
}
symbol->expression->accept(*this);
if (NULL != symbol->statement_list)
symbol->statement_list->accept(*this);
return NULL;
}
void *narrow_candidate_datatypes_c::visit(repeat_statement_c *symbol) {
for (unsigned int i = 0; i < symbol->expression->candidate_datatypes.size(); i++) {
if(is_BOOL_type(symbol->expression->candidate_datatypes[i]))
symbol->expression->datatype = symbol->expression->candidate_datatypes[i];
}
symbol->expression->accept(*this);
if (NULL != symbol->statement_list)
symbol->statement_list->accept(*this);
return NULL;
}