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elab_scope.cc
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elab_scope.cc
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/*
* Copyright (c) 2000-2024 Stephen Williams ([email protected])
* Copyright CERN 2013 / Stephen Williams ([email protected])
*
* This source code is free software; you can redistribute it
* and/or modify it in source code form under the terms of the GNU
* General Public License as published by the Free Software
* Foundation; either version 2 of the License, or (at your option)
* any later version.
*
* This program is distributed in the hope that it will be useful,
* but WITHOUT ANY WARRANTY; without even the implied warranty of
* MERCHANTABILITY or FITNESS FOR A PARTICULAR PURPOSE. See the
* GNU General Public License for more details.
*
* You should have received a copy of the GNU General Public License
* along with this program; if not, write to the Free Software
* Foundation, Inc., 51 Franklin Street, Fifth Floor, Boston, MA 02110-1301, USA.
*/
# include "config.h"
# include "compiler.h"
# include "netmisc.h"
# include "netvector.h"
# include "netparray.h"
# include <cstring>
# include <iostream>
# include <cstdlib>
# include <cstdio>
/*
* Elaboration happens in two passes, generally. The first scans the
* pform to generate the NetScope tree and attach it to the Design
* object. The methods in this source file implement the elaboration
* of the scopes.
*/
# include "Module.h"
# include "PClass.h"
# include "PExpr.h"
# include "PEvent.h"
# include "PClass.h"
# include "PGate.h"
# include "PGenerate.h"
# include "PPackage.h"
# include "PTask.h"
# include "PWire.h"
# include "Statement.h"
# include "AStatement.h"
# include "netlist.h"
# include "netclass.h"
# include "netenum.h"
# include "netqueue.h"
# include "parse_api.h"
# include "util.h"
# include <typeinfo>
# include "ivl_assert.h"
using namespace std;
void set_scope_timescale(Design*des, NetScope*scope, PScope*pscope)
{
scope->time_unit(pscope->time_unit);
scope->time_precision(pscope->time_precision);
scope->time_from_timescale(pscope->has_explicit_timescale());
des->set_precision(pscope->time_precision);
}
typedef map<perm_string,LexicalScope::param_expr_t*>::const_iterator mparm_it_t;
static void collect_parm_item(Design*des, NetScope*scope, perm_string name,
const LexicalScope::param_expr_t&cur,
bool is_annotatable)
{
if (debug_scopes) {
cerr << cur.get_fileline() << ": " << __func__ << ": "
<< "parameter " << name << " ";
if (cur.data_type)
cerr << *cur.data_type;
else
cerr << "(nil type)";
ivl_assert(cur, cur.expr);
cerr << " = " << *cur.expr << "; ";
if (cur.range)
cerr << "with ranges ";
else
cerr << "without ranges ";
cerr << "; in scope " << scope_path(scope) << endl;
}
NetScope::range_t*range_list = 0;
for (LexicalScope::range_t*range = cur.range ; range ; range = range->next) {
NetScope::range_t*tmp = new NetScope::range_t;
tmp->exclude_flag = range->exclude_flag;
tmp->low_open_flag = range->low_open_flag;
tmp->high_open_flag = range->high_open_flag;
if (range->low_expr) {
tmp->low_expr = elab_and_eval(des, scope, range->low_expr, -1);
ivl_assert(*range->low_expr, tmp->low_expr);
} else {
tmp->low_expr = 0;
}
if (range->high_expr && range->high_expr==range->low_expr) {
// Detect the special case of a "point"
// range. These are called out by setting the high
// and low expression ranges to the same
// expression. The exclude_flags should be false
// in this case
ivl_assert(*range->high_expr, tmp->low_open_flag==false && tmp->high_open_flag==false);
tmp->high_expr = tmp->low_expr;
} else if (range->high_expr) {
tmp->high_expr = elab_and_eval(des, scope, range->high_expr, -1);
ivl_assert(*range->high_expr, tmp->high_expr);
} else {
tmp->high_expr = 0;
}
tmp->next = range_list;
range_list = tmp;
}
// The type of the parameter, if unspecified in the source, will come
// from the type of the value assigned to it. Therefore, if the type is
// not yet known, don't try to guess here, put the type guess off. Also
// don't try to elaborate it here, because there may be references to
// other parameters still being located during scope elaboration.
scope->set_parameter(name, is_annotatable, cur, range_list);
}
static void collect_scope_parameters(Design*des, NetScope*scope,
const map<perm_string,LexicalScope::param_expr_t*>¶meters)
{
if (debug_scopes) {
cerr << scope->get_fileline() << ": " << __func__ << ": "
<< "collect parameters for " << scope_path(scope) << "." << endl;
}
for (mparm_it_t cur = parameters.begin()
; cur != parameters.end() ; ++ cur ) {
collect_parm_item(des, scope, cur->first, *(cur->second), false);
}
}
static void collect_scope_specparams(Design*des, NetScope*scope,
const map<perm_string,LexicalScope::param_expr_t*>&specparams)
{
if (debug_scopes) {
cerr << scope->get_fileline() << ": " << __func__ << ": "
<< "collect specparams for " << scope_path(scope) << "." << endl;
}
for (mparm_it_t cur = specparams.begin()
; cur != specparams.end() ; ++ cur ) {
collect_parm_item(des, scope, cur->first, *(cur->second), true);
}
}
static void collect_scope_signals(NetScope*scope,
const map<perm_string,PWire*>&wires)
{
for (map<perm_string,PWire*>::const_iterator cur = wires.begin()
; cur != wires.end() ; ++ cur ) {
PWire*wire = (*cur).second;
if (debug_scopes) {
cerr << wire->get_fileline() << ": " << __func__ << ": "
<< "adding placeholder for signal '" << wire->basename()
<< "' in scope '" << scope_path(scope) << "'." << endl;
}
scope->add_signal_placeholder(wire);
}
}
/*
* Elaborate the enumeration into the given scope.
*/
static void elaborate_scope_enumeration(Design*des, NetScope*scope,
enum_type_t*enum_type)
{
bool rc_flag;
enum_type->elaborate_type(des, scope);
netenum_t *use_enum = scope->enumeration_for_key(enum_type);
size_t name_idx = 0;
// Find the enumeration width.
long raw_width = use_enum->packed_width();
ivl_assert(*use_enum, raw_width > 0);
unsigned enum_width = (unsigned)raw_width;
bool is_signed = use_enum->get_signed();
// Define the default start value and the increment value to be the
// correct type for this enumeration.
verinum cur_value ((uint64_t)0, enum_width);
cur_value.has_sign(is_signed);
verinum one_value ((uint64_t)1, enum_width);
one_value.has_sign(is_signed);
// Find the maximum allowed enumeration value.
verinum max_value (0);
if (is_signed) {
max_value = pow(verinum(2), verinum(enum_width-1)) - one_value;
} else {
max_value = pow(verinum(2), verinum(enum_width)) - one_value;
}
max_value.has_sign(is_signed);
// Variable to indicate when a defined value wraps.
bool implicit_wrapped = false;
// Process the enumeration definition.
for (list<named_pexpr_t>::const_iterator cur = enum_type->names->begin()
; cur != enum_type->names->end() ; ++ cur, name_idx += 1) {
// Check to see if the enumeration name has a value given.
if (cur->parm) {
// There is an explicit value. elaborate/evaluate
// the value and assign it to the enumeration name.
NetExpr*val = elab_and_eval(des, scope, cur->parm, -1);
NetEConst*val_const = dynamic_cast<NetEConst*> (val);
if (val_const == 0) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration expression for "
<< cur->name <<" is not an integer constant."
<< endl;
des->errors += 1;
continue;
}
cur_value = val_const->value();
// Clear the implicit wrapped flag if a parameter is given.
implicit_wrapped = false;
// A 2-state value can not have a constant with X/Z bits.
if (use_enum->base_type() == IVL_VT_BOOL &&
! cur_value.is_defined()) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name " << cur->name
<< " can not have an undefined value." << endl;
des->errors += 1;
}
// If this is a literal constant and it has a defined
// width then the width must match the enumeration width.
if (PENumber *tmp = dynamic_cast<PENumber*>(cur->parm)) {
if (tmp->value().has_len() &&
(tmp->value().len() != enum_width)) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name " << cur->name
<< " has an incorrectly sized constant."
<< endl;
des->errors += 1;
}
}
// If we are padding/truncating a negative value for an
// unsigned enumeration that is an error or if the new
// value does not have a defined width.
if (((cur_value.len() != enum_width) ||
! cur_value.has_len()) &&
! is_signed && cur_value.is_negative()) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name " << cur->name
<< " has a negative value." << endl;
des->errors += 1;
}
// Narrower values need to be padded to the width of the
// enumeration and defined to have the specified width.
if (cur_value.len() < enum_width) {
cur_value = pad_to_width(cur_value, enum_width);
}
// Some wider values can be truncated.
if (cur_value.len() > enum_width) {
unsigned check_width = enum_width - 1;
// Check that the upper bits match the MSB
for (unsigned idx = enum_width;
idx < cur_value.len();
idx += 1) {
if (cur_value[idx] != cur_value[check_width]) {
// If this is an unsigned enumeration
// then zero padding is okay.
if (!is_signed &&
(idx == enum_width) &&
(cur_value[idx] == verinum::V0)) {
check_width += 1;
continue;
}
if (cur_value.is_defined()) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name "
<< cur->name
<< " has a value that is too "
<< ((cur_value > max_value) ?
"large" : "small")
<< " " << cur_value << "."
<< endl;
} else {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name "
<< cur->name
<< " has trimmed bits that do "
<< "not match the enumeration "
<< "MSB: " << cur_value << "."
<< endl;
}
des->errors += 1;
break;
}
}
// If this is an unsigned value then make sure
// The upper bits are not 1.
if (! cur_value.has_sign() &&
(cur_value[enum_width] == verinum::V1)) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name "
<< cur->name
<< " has a value that is too large: "
<< cur_value << "." << endl;
des->errors += 1;
break;
}
cur_value = verinum(cur_value, enum_width);
}
// At this point the value has the correct size and needs
// to have the correct sign attribute set.
cur_value.has_len(true);
cur_value.has_sign(is_signed);
} else if (! cur_value.is_defined()) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name " << cur->name
<< " has an undefined inferred value." << endl;
des->errors += 1;
continue;
}
// Check to see if an implicitly wrapped value is used.
if (implicit_wrapped) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name " << cur->name
<< " has an inferred value that overflowed." << endl;
des->errors += 1;
}
// The enumeration value must be unique.
perm_string dup_name = use_enum->find_value(cur_value);
if (dup_name) {
cerr << use_enum->get_fileline()
<< ": error: Enumeration name "
<< cur->name << " and " << dup_name
<< " have the same value: " << cur_value << endl;
des->errors += 1;
}
rc_flag = use_enum->insert_name(name_idx, cur->name, cur_value);
rc_flag &= scope->add_enumeration_name(use_enum, cur->name);
if (! rc_flag) {
cerr << use_enum->get_fileline()
<< ": error: Duplicate enumeration name "
<< cur->name << endl;
des->errors += 1;
}
// In case the next name has an implicit value,
// increment the current value by one.
if (cur_value.is_defined()) {
if (cur_value == max_value) implicit_wrapped = true;
cur_value = cur_value + one_value;
}
}
use_enum->insert_name_close();
}
static void elaborate_scope_enumerations(Design*des, NetScope*scope,
const vector<enum_type_t*>&enum_types)
{
if (debug_scopes) {
cerr << scope->get_fileline() << ": " << __func__ << ": "
<< "Elaborate " << enum_types.size() << " enumerations"
<< " in scope " << scope_path(scope) << "."
<< endl;
}
for (vector<enum_type_t*>::const_iterator cur = enum_types.begin()
; cur != enum_types.end() ; ++ cur) {
enum_type_t*curp = *cur;
elaborate_scope_enumeration(des, scope, curp);
}
}
/*
* If the pclass includes an implicit and explicit constructor, then
* merge the implicit constructor into the explicit constructor as
* statements in the beginning.
*
* This is not necessary for proper functionality, it is an
* optimization, so we can easily give up if it doesn't seem like it
* will obviously work.
*/
static void blend_class_constructors(PClass*pclass)
{
perm_string new1 = perm_string::literal("new");
perm_string new2 = perm_string::literal("new@");
PFunction*use_new;
PFunction*use_new2;
// Locate the explicit constructor.
map<perm_string,PFunction*>::iterator iter_new = pclass->funcs.find(new1);
if (iter_new == pclass->funcs.end())
use_new = 0;
else
use_new = iter_new->second;
// Locate the implicit constructor.
map<perm_string,PFunction*>::iterator iter_new2 = pclass->funcs.find(new2);
if (iter_new2 == pclass->funcs.end())
use_new2 = 0;
else
use_new2 = iter_new2->second;
// If there are no constructors, then we are done.
if (use_new==0 && use_new2==0)
return;
// While we're here, look for a super.new() call. If we find
// it, strip it out of the constructor and set it aside for
// when we actually call the chained constructor.
PChainConstructor*chain_new = use_new? use_new->extract_chain_constructor() : NULL;
// If we do not have an explicit constructor chain, but there
// is a parent class, then create an implicit chain.
if (chain_new==0 && pclass->type->base_type) {
chain_new = new PChainConstructor(pclass->type->base_args);
chain_new->set_line(*pclass);
}
// If there are both an implicit and explicit constructor,
// then blend the implicit constructor into the explicit
// constructor. This eases the task for the elaborator later.
if (use_new && use_new2) {
// These constructors must be methods of the same class.
ivl_assert(*use_new, use_new->method_of() == use_new2->method_of());
Statement*def_new = use_new->get_statement();
Statement*def_new2 = use_new2->get_statement();
// It is possible, i.e. recovering from a parse error,
// for the statement from the constructor to be
// missing. In that case, create an empty one.
if (def_new==0) {
def_new = new PBlock(PBlock::BL_SEQ);
use_new->set_statement(def_new);
}
if (def_new2) use_new->push_statement_front(def_new2);
// Now the implicit initializations are all built into
// the constructor. Delete the "new@" constructor.
pclass->funcs.erase(iter_new2);
delete use_new2;
use_new2 = 0;
}
if (chain_new) {
if (use_new2) {
use_new2->push_statement_front(chain_new);
} else {
use_new->push_statement_front(chain_new);
}
}
}
static void elaborate_scope_class(Design*des, NetScope*scope, PClass*pclass)
{
class_type_t*use_type = pclass->type;
if (debug_scopes) {
cerr << pclass->get_fileline() <<": elaborate_scope_class: "
<< "Elaborate scope class " << pclass->pscope_name()
<< " within scope " << scope_path(scope)
<< endl;
}
const netclass_t*use_base_class = 0;
if (use_type->base_type) {
ivl_type_t base_type = use_type->base_type->elaborate_type(des, scope);
use_base_class = dynamic_cast<const netclass_t *>(base_type);
if (!use_base_class) {
cerr << pclass->get_fileline() << ": error: "
<< "Base type of " << use_type->name
<< " is not a class." << endl;
des->errors += 1;
}
}
netclass_t*use_class = new netclass_t(use_type->name, use_base_class);
NetScope*class_scope = new NetScope(scope, hname_t(pclass->pscope_name()),
NetScope::CLASS, scope->unit());
class_scope->set_line(pclass);
class_scope->set_class_def(use_class);
use_class->set_class_scope(class_scope);
use_class->set_definition_scope(scope);
use_class->set_virtual(use_type->virtual_class);
set_scope_timescale(des, class_scope, pclass);
class_scope->add_typedefs(&pclass->typedefs);
collect_scope_parameters(des, class_scope, pclass->parameters);
collect_scope_signals(class_scope, pclass->wires);
// Elaborate enum types declared in the class. We need these
// now because enumeration constants can be used during scope
// elaboration.
if (debug_scopes) {
cerr << pclass->get_fileline() << ": elaborate_scope_class: "
<< "Elaborate " << pclass->enum_sets.size() << " enumerations"
<< " in class " << scope_path(class_scope)
<< ", scope=" << scope_path(scope) << "."
<< endl;
}
elaborate_scope_enumerations(des, class_scope, pclass->enum_sets);
for (map<perm_string,PTask*>::iterator cur = pclass->tasks.begin()
; cur != pclass->tasks.end() ; ++cur) {
hname_t use_name (cur->first);
NetScope*method_scope = new NetScope(class_scope, use_name, NetScope::TASK);
// Task methods are always automatic...
if (!cur->second->is_auto()) {
cerr << "error: Lifetime of method `"
<< scope_path(method_scope)
<< "` must not be static" << endl;
des->errors += 1;
}
method_scope->is_auto(true);
method_scope->set_line(cur->second);
method_scope->add_imports(&cur->second->explicit_imports);
if (debug_scopes) {
cerr << cur->second->get_fileline() << ": elaborate_scope_class: "
<< "Elaborate method (task) scope "
<< scope_path(method_scope) << endl;
}
cur->second->elaborate_scope(des, method_scope);
}
for (map<perm_string,PFunction*>::iterator cur = pclass->funcs.begin()
; cur != pclass->funcs.end() ; ++cur) {
hname_t use_name (cur->first);
NetScope*method_scope = new NetScope(class_scope, use_name, NetScope::FUNC);
// Function methods are always automatic...
if (!cur->second->is_auto()) {
cerr << "error: Lifetime of method `"
<< scope_path(method_scope)
<< "` must not be static" << endl;
des->errors += 1;
}
method_scope->is_auto(true);
method_scope->set_line(cur->second);
method_scope->add_imports(&cur->second->explicit_imports);
if (debug_scopes) {
cerr << cur->second->get_fileline() << ": elaborate_scope_class: "
<< "Elaborate method (function) scope "
<< scope_path(method_scope) << endl;
}
cur->second->elaborate_scope(des, method_scope);
}
scope->add_class(use_class);
}
static void elaborate_scope_classes(Design*des, NetScope*scope,
const vector<PClass*>&classes)
{
if (debug_scopes) {
cerr << scope->get_fileline() << ": " << __func__ << ": "
<< "Elaborate " << classes.size() << " classes"
<< " in scope " << scope_path(scope) << "."
<< endl;
}
for (size_t idx = 0 ; idx < classes.size() ; idx += 1) {
blend_class_constructors(classes[idx]);
elaborate_scope_class(des, scope, classes[idx]);
}
}
static void replace_scope_parameters(Design *des, NetScope*scope, const LineInfo&loc,
const Module::replace_t&replacements)
{
if (debug_scopes) {
cerr << scope->get_fileline() << ": " << __func__ << ": "
<< "Replace scope parameters for " << scope_path(scope) << "." << endl;
}
for (Module::replace_t::const_iterator cur = replacements.begin()
; cur != replacements.end() ; ++ cur ) {
PExpr*val = (*cur).second;
if (val == 0) {
cerr << loc.get_fileline() << ": internal error: "
<< "Missing expression in parameter replacement for "
<< (*cur).first << endl;;
}
ivl_assert(loc, val);
if (debug_scopes) {
cerr << loc.get_fileline() << ": debug: "
<< "Replace " << (*cur).first
<< " with expression " << *val
<< " from " << val->get_fileline() << "." << endl;
cerr << loc.get_fileline() << ": : "
<< "Type=" << val->expr_type() << endl;
}
scope->replace_parameter(des, (*cur).first, val, scope->parent());
}
}
static void elaborate_scope_events_(Design*des, NetScope*scope,
const map<perm_string,PEvent*>&events)
{
for (map<perm_string,PEvent*>::const_iterator et = events.begin()
; et != events.end() ; ++ et ) {
(*et).second->elaborate_scope(des, scope);
}
}
static void elaborate_scope_task(Design*des, NetScope*scope, PTask*task)
{
hname_t use_name( task->pscope_name() );
NetScope*task_scope = new NetScope(scope, use_name, NetScope::TASK);
task_scope->is_auto(task->is_auto());
task_scope->set_line(task);
task_scope->add_imports(&task->explicit_imports);
if (debug_scopes) {
cerr << task->get_fileline() << ": elaborate_scope_task: "
<< "Elaborate task scope " << scope_path(task_scope) << endl;
}
task->elaborate_scope(des, task_scope);
}
static void elaborate_scope_tasks(Design*des, NetScope*scope,
const map<perm_string,PTask*>&tasks)
{
typedef map<perm_string,PTask*>::const_iterator tasks_it_t;
for (tasks_it_t cur = tasks.begin()
; cur != tasks.end() ; ++ cur ) {
elaborate_scope_task(des, scope, cur->second);
}
}
static void elaborate_scope_func(Design*des, NetScope*scope, PFunction*task)
{
hname_t use_name( task->pscope_name() );
NetScope*task_scope = new NetScope(scope, use_name, NetScope::FUNC);
task_scope->is_auto(task->is_auto());
task_scope->set_line(task);
task_scope->add_imports(&task->explicit_imports);
if (debug_scopes) {
cerr << task->get_fileline() << ": elaborate_scope_func: "
<< "Elaborate function scope " << scope_path(task_scope)
<< endl;
}
task->elaborate_scope(des, task_scope);
}
static void elaborate_scope_funcs(Design*des, NetScope*scope,
const map<perm_string,PFunction*>&funcs)
{
typedef map<perm_string,PFunction*>::const_iterator funcs_it_t;
for (funcs_it_t cur = funcs.begin()
; cur != funcs.end() ; ++ cur ) {
elaborate_scope_func(des, scope, cur->second);
}
}
class generate_schemes_work_item_t : public elaborator_work_item_t {
public:
generate_schemes_work_item_t(Design*des__, NetScope*scope, Module*mod)
: elaborator_work_item_t(des__), scope_(scope), mod_(mod)
{ }
void elaborate_runrun()
{
if (debug_scopes)
cerr << mod_->get_fileline() << ": debug: "
<< "Processing generate schemes for "
<< scope_path(scope_) << endl;
// Generate schemes can create new scopes in the form of
// generated code. Scan the generate schemes, and *generate*
// new scopes, which is slightly different from simple
// elaboration.
typedef list<PGenerate*>::const_iterator generate_it_t;
for (generate_it_t cur = mod_->generate_schemes.begin()
; cur != mod_->generate_schemes.end() ; ++ cur ) {
(*cur) -> generate_scope(des, scope_);
}
}
private:
// The scope_ is the scope that contains the generate scheme
// we are to work on. the mod_ is the Module definition for
// that scope, and contains the parsed generate schemes.
NetScope*scope_;
Module*mod_;
};
bool PPackage::elaborate_scope(Design*des, NetScope*scope)
{
if (debug_scopes) {
cerr << get_fileline() << ": PPackage::elaborate_scope: "
<< "Elaborate package " << scope_path(scope) << "." << endl;
}
scope->add_typedefs(&typedefs);
collect_scope_parameters(des, scope, parameters);
collect_scope_signals(scope, wires);
if (debug_scopes) {
cerr << get_fileline() << ": PPackage::elaborate_scope: "
<< "Elaborate " << enum_sets.size() << " enumerations"
<< " in package scope " << scope_path(scope) << "."
<< endl;
}
elaborate_scope_enumerations(des, scope, enum_sets);
elaborate_scope_classes(des, scope, classes_lexical);
elaborate_scope_funcs(des, scope, funcs);
elaborate_scope_tasks(des, scope, tasks);
elaborate_scope_events_(des, scope, events);
return true;
}
bool Module::elaborate_scope(Design*des, NetScope*scope,
const replace_t&replacements)
{
if (debug_scopes) {
cerr << get_fileline() << ": Module::elaborate_scope: "
<< "Elaborate " << scope_path(scope) << "." << endl;
}
scope->add_typedefs(&typedefs);
// Add the genvars to the scope.
typedef map<perm_string,LineInfo*>::const_iterator genvar_it_t;
for (genvar_it_t cur = genvars.begin(); cur != genvars.end(); ++ cur ) {
scope->add_genvar((*cur).first, (*cur).second);
}
// Scan the parameters in the module, and store the information
// needed to evaluate the parameter expressions. The expressions
// will be evaluated later, once all parameter overrides for this
// module have been done.
collect_scope_parameters(des, scope, parameters);
collect_scope_specparams(des, scope, specparams);
collect_scope_signals(scope, wires);
// Run parameter replacements that were collected from the
// containing scope and meant for me.
replace_scope_parameters(des, scope, *this, replacements);
elaborate_scope_enumerations(des, scope, enum_sets);
ivl_assert(*this, classes.size() == classes_lexical.size());
elaborate_scope_classes(des, scope, classes_lexical);
// Run through the defparams for this module and save the result
// in a table for later final override.
typedef list<Module::named_expr_t>::const_iterator defparms_iter_t;
for (defparms_iter_t cur = defparms.begin()
; cur != defparms.end() ; ++ cur ) {
scope->defparams.push_back(make_pair(cur->first, cur->second));
}
// Evaluate the attributes. Evaluate them in the scope of the
// module that the attribute is attached to. Is this correct?
unsigned nattr;
attrib_list_t*attr = evaluate_attributes(attributes, nattr, des, scope);
for (unsigned idx = 0 ; idx < nattr ; idx += 1)
scope->attribute(attr[idx].key, attr[idx].val);
delete[]attr;
// Generate schemes need to have their scopes elaborated, but
// we can not do that until defparams are run, so push it off
// into an elaborate work item.
if (debug_scopes)
cerr << get_fileline() << ": " << __func__ << ": "
<< "Schedule generates within " << scope_path(scope)
<< " for elaboration after defparams." << endl;
des->elaboration_work_list.push_back(new generate_schemes_work_item_t(des, scope, this));
// Tasks introduce new scopes, so scan the tasks in this
// module. Create a scope for the task and pass that to the
// elaborate_scope method of the PTask for detailed
// processing.
elaborate_scope_tasks(des, scope, tasks);
// Functions are very similar to tasks, at least from the
// perspective of scopes. So handle them exactly the same
// way.
elaborate_scope_funcs(des, scope, funcs);
// Look for implicit modules and implicit gates for them.
for (map<perm_string,Module*>::iterator cur = nested_modules.begin()
; cur != nested_modules.end() ; ++cur) {
// Skip modules that must be explicitly instantiated.
if (cur->second->port_count() > 0)
continue;
PGModule*nested_gate = new PGModule(cur->second, cur->second->mod_name());
nested_gate->set_line(*cur->second);
gates_.push_back(nested_gate);
}
// Gates include modules, which might introduce new scopes, so
// scan all of them to create those scopes.
typedef list<PGate*>::const_iterator gates_it_t;
for (gates_it_t cur = gates_.begin()
; cur != gates_.end() ; ++ cur ) {
(*cur) -> elaborate_scope(des, scope);
}
// initial and always blocks may contain begin-end and
// fork-join blocks that can introduce scopes. Therefore, I
// get to scan processes here.
typedef list<PProcess*>::const_iterator proc_it_t;
for (proc_it_t cur = behaviors.begin()
; cur != behaviors.end() ; ++ cur ) {
(*cur) -> statement() -> elaborate_scope(des, scope);
}
// Scan through all the named events in this scope. We do not
// need anything more than the current scope to do this
// elaboration, so do it now. This allows for normal
// elaboration to reference these events.
elaborate_scope_events_(des, scope, events);
scope->is_cell(is_cell);
return des->errors == 0;
}
bool PGenerate::generate_scope(Design*des, NetScope*container)
{
switch (scheme_type) {
case GS_LOOP:
return generate_scope_loop_(des, container);
case GS_CONDIT:
return generate_scope_condit_(des, container, false);
case GS_ELSE:
return generate_scope_condit_(des, container, true);
case GS_CASE:
return generate_scope_case_(des, container);
case GS_NBLOCK:
return generate_scope_nblock_(des, container);
case GS_CASE_ITEM:
cerr << get_fileline() << ": internal error: "
<< "Case item outside of a case generate scheme?" << endl;
return false;
default:
cerr << get_fileline() << ": sorry: Generate of this sort"
<< " is not supported yet!" << endl;
return false;
}
}
void PGenerate::check_for_valid_genvar_value_(long value)
{
if (generation_flag < GN_VER2005 && value < 0) {
cerr << get_fileline() << ": warning: A negative value (" << value
<< ") has been assigned to genvar '" << loop_index << "'."
<< endl;
cerr << get_fileline() << ": : This is illegal in "
"Verilog-2001. Use at least -g2005 to remove this warning."
<< endl;
}
}
/*
* This is the elaborate scope method for a generate loop.
*/
bool PGenerate::generate_scope_loop_(Design*des, NetScope*container)
{
if (!local_index) {
// Check that the loop_index variable was declared in a
// genvar statement.
NetScope*cscope = container;
while (cscope && !cscope->find_genvar(loop_index)) {
if (cscope->symbol_exists(loop_index)) {
cerr << get_fileline() << ": error: "
<< "generate loop variable '" << loop_index
<< "' is not a genvar in this scope." << endl;
des->errors += 1;
return false;
}
cscope = cscope->parent();
}
if (!cscope) {
cerr << get_fileline() << ": error: genvar is missing for "
"generate \"loop\" variable '" << loop_index << "'."
<< endl;
des->errors += 1;
return false;
}
}
// We're going to need a genvar...
long genvar;
// The initial value for the genvar does not need (nor can it
// use) the genvar itself, so we can evaluate this expression
// the same way any other parameter value is evaluated.
NetExpr*init_ex = elab_and_eval(des, container, loop_init, -1, true);
NetEConst*init = dynamic_cast<NetEConst*> (init_ex);
if (init == 0) {
cerr << get_fileline() << ": error: Cannot evaluate genvar"
<< " init expression: " << *loop_init << endl;
des->errors += 1;
return false;
}
genvar = init->value().as_long();
check_for_valid_genvar_value_(genvar);
delete init_ex;
if (debug_scopes)
cerr << get_fileline() << ": debug: genvar init = " << genvar << endl;
container->genvar_tmp = loop_index;
container->genvar_tmp_val = genvar;
NetExpr*test_ex = elab_and_eval(des, container, loop_test, -1, true);
NetEConst*test = dynamic_cast<NetEConst*>(test_ex);
if (test == 0) {
cerr << get_fileline() << ": error: Cannot evaluate genvar"
<< " conditional expression: " << *loop_test << endl;
des->errors += 1;
return false;
}
while (test->value().as_long()) {
// The actual name of the scope includes the genvar so
// that each instance has a unique name in the
// container. The format of using [] is part of the
// Verilog standard.
hname_t use_name (scope_name, genvar);
if (debug_scopes)