Слияние кода завершено, страница обновится автоматически
/*
* Copyright (c) 2000-2022 Stephen Williams (steve@icarus.com)
*
* 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 <iostream>
# include <set>
# include <cstdlib>
/*
* This source file contains all the implementations of the Design
* class declared in netlist.h.
*/
# include "netlist.h"
# include "netscalar.h"
# include "netvector.h"
# include "util.h"
# include "compiler.h"
# include "netmisc.h"
# include "PExpr.h"
# include "PTask.h"
# include <sstream>
# include "ivl_assert.h"
using namespace std;
Design:: Design()
: errors(0), nodes_(0), procs_(0), aprocs_(0)
{
branches_ = 0;
procs_idx_ = 0;
des_precision_ = 0;
nodes_functor_cur_ = 0;
nodes_functor_nxt_ = 0;
des_delay_sel_ = Design::TYP;
}
Design::~Design()
{
}
void Design::set_precision(int val)
{
if (val < des_precision_)
des_precision_ = val;
}
int Design::get_precision() const
{
return des_precision_;
}
void Design::set_delay_sel(delay_sel_t sel)
{
des_delay_sel_ = sel;
}
const char* Design::get_delay_sel() const
{
switch (des_delay_sel_) {
case Design::MIN:
return "MINIMUM";
break;
case Design::TYP:
return "TYPICAL";
break;
case Design::MAX:
return "MAXIMUM";
break;
default:
assert(0);
return "TYPICAL";
}
}
uint64_t Design::scale_to_precision(uint64_t val,
const NetScope*scope) const
{
int units = scope->time_unit();
assert( units >= des_precision_ );
while (units > des_precision_) {
units -= 1;
val *= 10;
}
return val;
}
NetScope* Design::make_root_scope(perm_string root, NetScope*unit_scope,
bool program_block, bool is_interface)
{
NetScope *root_scope_;
root_scope_ = new NetScope(0, hname_t(root), NetScope::MODULE, unit_scope,
false, program_block, is_interface);
/* This relies on the fact that the basename return value is
permallocated. */
root_scope_->set_module_name(root_scope_->basename());
root_scopes_.push_back(root_scope_);
return root_scope_;
}
NetScope* Design::find_root_scope()
{
assert(root_scopes_.front());
return root_scopes_.front();
}
list<NetScope*> Design::find_root_scopes() const
{
return root_scopes_;
}
NetScope* Design::make_package_scope(perm_string name, NetScope*unit_scope,
bool is_unit)
{
NetScope*scope;
scope = new NetScope(0, hname_t(name), NetScope::PACKAGE, unit_scope,
false, false, false, is_unit);
scope->set_module_name(scope->basename());
packages_[name] = scope;
return scope;
}
NetScope* Design::find_package(perm_string name) const
{
map<perm_string,NetScope*>::const_iterator cur = packages_.find(name);
if (cur == packages_.end())
return 0;
return cur->second;
}
list<NetScope*> Design::find_package_scopes() const
{
list<NetScope*>res;
for (map<perm_string,NetScope*>::const_iterator cur = packages_.begin()
; cur != packages_.end() ; ++cur) {
res.push_back (cur->second);
}
return res;
}
/*
* This method locates a scope in the design, given its rooted
* hierarchical name. Each component of the key is used to scan one
* more step down the tree until the name runs out or the search
* fails.
*/
NetScope* Design::find_scope(const std::list<hname_t>&path) const
{
if (path.empty())
return 0;
for (list<NetScope*>::const_iterator scope = root_scopes_.begin()
; scope != root_scopes_.end(); ++ scope ) {
NetScope*cur = *scope;
if (path.front() != cur->fullname())
continue;
std::list<hname_t> tmp = path;
tmp.pop_front();
while (cur) {
if (tmp.empty()) return cur;
cur = cur->child( tmp.front() );
tmp.pop_front();
}
}
return 0;
}
/*
* This method locates a scope in the design, given its rooted
* hierarchical name. Each component of the key is used to scan one
* more step down the tree until the name runs out or the search
* fails.
*/
NetScope* Design::find_scope(const hname_t&path) const
{
for (list<NetScope*>::const_iterator scope = root_scopes_.begin()
; scope != root_scopes_.end(); ++ scope ) {
NetScope*cur = *scope;
if (path.peek_name() == cur->basename())
return cur;
}
return 0;
}
static bool is_design_unit(NetScope*scope)
{
return (scope->type() == NetScope::MODULE && !scope->nested_module())
|| (scope->type() == NetScope::PACKAGE);
}
static bool is_subroutine(NetScope::TYPE type)
{
return type == NetScope::TASK || type == NetScope::FUNC;
}
/*
* This method locates a scope within another scope, given its relative
* hierarchical name. Each component of the key is used to scan one
* more step down the tree until the name runs out or the search
* fails.
*/
NetScope* Design::find_scope_(NetScope*scope, const std::list<hname_t>&path,
NetScope::TYPE type) const
{
std::list<hname_t> tmp = path;
do {
hname_t key = tmp.front();
/* If we are looking for a module or we are not
* looking at the last path component check for
* a name match (second line). */
if (scope->type() == NetScope::MODULE
&& (type == NetScope::MODULE || tmp.size() > 1)
&& scope->module_name()==key.peek_name()) {
/* Up references may match module name */
} else {
NetScope*found_scope = scope->child(key);
if (found_scope == 0) {
found_scope = scope->find_import(this, key.peek_name());
if (found_scope)
found_scope = found_scope->child(key);
}
scope = found_scope;
if (scope == 0) break;
}
tmp.pop_front();
} while (! tmp.empty());
return scope;
}
/*
* This is a relative lookup of a scope by name. The starting point is
* the scope parameter within which I start looking for the scope. If
* I do not find the scope within the passed scope, start looking in
* parent scopes until I find it, or I run out of parent scopes.
*/
NetScope* Design::find_scope(NetScope*scope, const std::list<hname_t>&path,
NetScope::TYPE type) const
{
assert(scope);
if (path.empty())
return scope;
// Record the compilation unit scope for use later.
NetScope*unit_scope = scope->unit();
// First search upwards through the hierarchy.
while (scope) {
NetScope*found_scope = find_scope_(scope, path, type);
if (found_scope)
return found_scope;
// Avoid searching the unit scope twice.
if (scope == unit_scope)
unit_scope = 0;
// Special case - see IEEE 1800-2012 section 23.8.1.
if (unit_scope && is_design_unit(scope) && is_subroutine(type)) {
found_scope = find_scope_(unit_scope, path, type);
if (found_scope)
return found_scope;
unit_scope = 0;
}
scope = scope->parent();
}
// If we haven't already done so, search the compilation unit scope.
if (unit_scope) {
NetScope*found_scope = find_scope_(unit_scope, path, type);
if (found_scope)
return found_scope;
}
// Last chance. Look for the name starting at the root.
return find_scope(path);
}
/*
* This method locates a scope within another scope, given its relative
* hierarchical name. Each component of the key is used to scan one
* more step down the tree until the name runs out or the search
* fails.
*/
NetScope* Design::find_scope_(NetScope*scope, const hname_t&path,
NetScope::TYPE type) const
{
/* If we are looking for a module or we are not
* looking at the last path component check for
* a name match (second line). */
if ((scope->type() == NetScope::MODULE) && (type == NetScope::MODULE)
&& (scope->module_name() == path.peek_name())) {
/* Up references may match module name */
return scope;
}
NetScope*found_scope = scope->child(path);
if (found_scope == 0) {
found_scope = scope->find_import(this, path.peek_name());
if (found_scope)
found_scope = found_scope->child(path);
}
return found_scope;
}
/*
* This is a relative lookup of a scope by name. The starting point is
* the scope parameter within which I start looking for the scope. If
* I do not find the scope within the passed scope, start looking in
* parent scopes until I find it, or I run out of parent scopes.
*/
NetScope* Design::find_scope(NetScope*scope, const hname_t&path,
NetScope::TYPE type) const
{
assert(scope);
// Record the compilation unit scope for use later.
NetScope*unit_scope = scope->unit();
// First search upwards through the hierarchy.
while (scope) {
NetScope*found_scope = find_scope_(scope, path, type);
if (found_scope)
return found_scope;
// Avoid searching the unit scope twice.
if (scope == unit_scope)
unit_scope = 0;
// Special case - see IEEE 1800-2012 section 23.8.1.
if (unit_scope && is_design_unit(scope) && is_subroutine(type)) {
found_scope = find_scope_(unit_scope, path, type);
if (found_scope)
return found_scope;
unit_scope = 0;
}
scope = scope->parent();
}
// If we haven't already done so, search the compilation unit scope.
if (unit_scope) {
NetScope*found_scope = find_scope_(unit_scope, path, type);
if (found_scope)
return found_scope;
}
// Last chance. Look for the name starting at the root.
list<hname_t>path_list;
path_list.push_back(path);
return find_scope(path_list);
}
/*
* This method runs through the scope, noticing the defparam
* statements that were collected during the elaborate_scope pass and
* applying them to the target parameters. The implementation actually
* works by using a specialized method from the NetScope class that
* does all the work for me.
*/
void Design::run_defparams()
{
for (list<NetScope*>::const_iterator scope = root_scopes_.begin();
scope != root_scopes_.end(); ++ scope )
(*scope)->run_defparams(this);
}
void NetScope::run_defparams(Design*des)
{
for (map<hname_t,NetScope*>::const_iterator cur = children_.begin()
; cur != children_.end() ; ++ cur )
cur->second->run_defparams(des);
while (! defparams.empty()) {
pair<pform_name_t,PExpr*> pp = defparams.front();
defparams.pop_front();
pform_name_t path = pp.first;
PExpr*val = pp.second;
perm_string perm_name = peek_tail_name(path);
path.pop_back();
list<hname_t> eval_path = eval_scope_path(des, this, path);
/* If there is no path on the name, then the targ_scope
is the current scope. */
NetScope*targ_scope = des->find_scope(this, eval_path);
if (targ_scope == 0) {
// Push the defparam onto a list for retry
// later. It is possible for the scope lookup to
// fail if the scope being defparam'd into is
// generated by an index array for generate.
eval_path.push_back(hname_t(perm_name));
defparams_later.push_back(make_pair(eval_path,val));
continue;
}
targ_scope->replace_parameter(des, perm_name, val, this, true);
}
// If some of the defparams didn't find a scope in the name,
// then try again later. It may be that the target scope is
// created later by generate scheme or instance array.
if (! defparams_later.empty())
des->defparams_later.insert(this);
}
void NetScope::run_defparams_later(Design*des)
{
set<NetScope*> target_scopes;
list<pair<list<hname_t>,PExpr*> > defparams_even_later;
while (! defparams_later.empty()) {
pair<list<hname_t>,PExpr*> cur = defparams_later.front();
defparams_later.pop_front();
list<hname_t>eval_path = cur.first;
perm_string name = eval_path.back().peek_name();
eval_path.pop_back();
PExpr*val = cur.second;
NetScope*targ_scope = des->find_scope(this, eval_path);
if (targ_scope == 0) {
// If a scope in the target path is not found,
// then push this defparam for handling even
// later. Maybe a later generate scheme or
// instance array will create the scope.
defparams_even_later.push_back(cur);
continue;
}
targ_scope->replace_parameter(des, name, val, this, true);
// We'll need to re-evaluate parameters in this scope
target_scopes.insert(targ_scope);
}
// The scopes that this defparam set touched will be
// re-evaluated later it a top_defparams work item. So do not
// do the evaluation now.
// If there are some scopes that still have missing scopes,
// then save them back into the defparams_later list for a
// later pass.
defparams_later = defparams_even_later;
if (! defparams_later.empty())
des->defparams_later.insert(this);
}
void Design::evaluate_parameters()
{
for (map<perm_string,NetScope*>::const_iterator cur = packages_.begin()
; cur != packages_.end() ; ++ cur) {
cur->second->evaluate_parameters(this);
}
for (list<NetScope*>::const_iterator scope = root_scopes_.begin()
; scope != root_scopes_.end() ; ++ scope ) {
(*scope)->evaluate_parameters(this);
}
}
void NetScope::evaluate_parameter_logic_(Design*des, param_ref_t cur)
{
/* Evaluate the parameter expression. */
PExpr*val_expr = (*cur).second.val_expr;
NetScope*val_scope = (*cur).second.val_scope;
// The param_type may be nil if the parameter has no declared type. In
// this case, we'll try to take our type from the r-value.
ivl_type_t param_type = cur->second.ivl_type;
// Most parameter declarations are packed vectors, of the form:
// parameter [H:L] foo == bar;
// so get the netvector_t. Note that this may also be the special
// case of a netvector_t with no dimensions, that exists only to carry
// signed-ness, e.g.:
// parameter signed foo = bar;
// These will be marked as scalar, but also have the implict flag set.
const netvector_t* param_vect = dynamic_cast<const netvector_t*> (param_type);
if (debug_elaborate) {
cerr << val_expr->get_fileline() << ": " << __func__ << ": "
<< "parameter=" << cur->first << endl;
if (param_type)
cerr << val_expr->get_fileline() << ": " << __func__ << ": "
<< "param_type=" << *param_type << endl;
else
cerr << val_expr->get_fileline() << ": " << __func__ << ": "
<< "param_type=(nil)" << endl;
cerr << val_expr->get_fileline() << ": " << __func__ << ": "
<< "val_expr=" << *val_expr << endl;
}
ivl_variable_type_t use_type;
int lv_width = -2;
if (param_type) {
use_type = param_type->base_type();
// Is this an implicit netvector_t with no dimenions?
if (param_vect && param_vect->get_implicit() &&
param_vect->get_scalar())
lv_width = -2;
else if (param_type->packed())
lv_width = param_type->packed_width();
} else {
use_type = val_expr->expr_type();
}
if (debug_elaborate) {
cerr << val_expr->get_fileline() << ": " << __func__ << ": "
<< "use_type = " << use_type << endl;
}
NetExpr *expr;
// Handle assignment patterns as a special case as they need the type to
// be evaluated correctly.
if (param_type && dynamic_cast<PEAssignPattern*>(val_expr)) {
expr = elab_and_eval(des, val_scope, val_expr, param_type, true);
} else {
expr = elab_and_eval(des, val_scope, val_expr, lv_width, true,
cur->second.is_annotatable, use_type);
}
if (! expr)
return;
// Make sure to carry the signed-ness from a vector type.
if (param_vect)
expr->cast_signed(param_vect->get_signed());
if (debug_elaborate) {
cerr << val_expr->get_fileline() << ": " << __func__ << ": "
<< "expr = " << *expr << endl;
cerr << val_expr->get_fileline() << ": " << __func__ << ": "
<< "expr type = " << expr->expr_type() << endl;
}
switch (expr->expr_type()) {
case IVL_VT_REAL:
if (! dynamic_cast<const NetECReal*>(expr)) {
cerr << expr->get_fileline()
<< ": error: Unable to evaluate real parameter "
<< (*cur).first << " value: " << *expr << endl;
des->errors += 1;
return;
}
// If the parameter has no type, then infer its type from the
// r-value expression.
if (param_type==0) {
param_type = &netreal_t::type_real;
cur->second.ivl_type = param_type;
}
break;
case IVL_VT_LOGIC:
case IVL_VT_BOOL:
if (! dynamic_cast<const NetEConst*>(expr)) {
cerr << expr->get_fileline()
<< ": error: Unable to evaluate parameter "
<< (*cur).first << " value: " << *expr << endl;
des->errors += 1;
return;
}
// If the parameter has no type, then infer its type from the
// r-value expression.
if (param_type==0) {
param_type = new netvector_t(expr->expr_type(), expr->expr_width()-1,
0, expr->has_sign());
cur->second.ivl_type = param_type;
}
if (param_type->base_type() != IVL_VT_NO_TYPE)
expr->cast_signed(param_type->get_signed());
if (!expr->has_width()) {
expr = pad_to_width(expr, integer_width, *expr);
} else if (param_type->slice_dimensions().size()==0 && !expr->has_width()) {
expr = pad_to_width(expr, integer_width, *expr);
}
break;
default:
cerr << expr->get_fileline()
<< ": internal error: "
<< "Unhandled expression type "
<< expr->expr_type() << "?" << endl;
cerr << expr->get_fileline()
<< ": : "
<< "param_type: " << *param_type << endl;
des->errors += 1;
return;
}
// By the time we're done with the above, we should certainly know the
// type of the parameter.
ivl_assert(*expr, cur->second.ivl_type);
cur->second.val = expr;
// If there are no value ranges to test the value against,
// then we are done.
if ((*cur).second.range == 0)
return;
NetEConst*val = dynamic_cast<NetEConst*>((*cur).second.val);
ivl_assert(*expr, val);
verinum value = val->value();
bool from_flag = (*cur).second.range == 0? true : false;
for (range_t*value_range = (*cur).second.range
; value_range ; value_range = value_range->next) {
// If we already know that the value is
// within a "from" range, then do not test
// any more of the from ranges.
if (from_flag && value_range->exclude_flag==false)
continue;
if (value_range->low_expr) {
NetEConst*tmp = dynamic_cast<NetEConst*>(value_range->low_expr);
ivl_assert(*value_range->low_expr, tmp);
if (value_range->low_open_flag && value <= tmp->value())
continue;
else if (value < tmp->value())
continue;
}
if (value_range->high_expr) {
NetEConst*tmp = dynamic_cast<NetEConst*>(value_range->high_expr);
ivl_assert(*value_range->high_expr, tmp);
if (value_range->high_open_flag && value >= tmp->value())
continue;
else if (value > tmp->value())
continue;
}
// Within the range. If this is a "from"
// range, then set the from_flag and continue.
if (value_range->exclude_flag == false) {
from_flag = true;
continue;
}
// OH NO! In an excluded range. signal an error.
from_flag = false;
break;
}
// If we found no from range that contains the
// value, then report an error.
if (! from_flag) {
cerr << val->get_fileline() << ": error: "
<< "Parameter value " << value
<< " is out of range for parameter " << (*cur).first
<< "." << endl;
des->errors += 1;
}
}
void NetScope::evaluate_parameter_real_(Design*des, param_ref_t cur)
{
PExpr*val_expr = (*cur).second.val_expr;
NetScope*val_scope = (*cur).second.val_scope;
ivl_type_t param_type = cur->second.ivl_type;
ivl_assert(*val_expr, param_type);
NetExpr*expr = elab_and_eval(des, val_scope, val_expr, -1, true,
cur->second.is_annotatable,
param_type->base_type());
if (! expr)
return;
NetECReal*res = 0;
switch (expr->expr_type()) {
case IVL_VT_REAL:
if (NetECReal*tmp = dynamic_cast<NetECReal*>(expr)) {
res = tmp;
} else {
cerr << expr->get_fileline()
<< ": error: "
<< "Unable to evaluate real parameter "
<< (*cur).first << " value: " << *expr << endl;
des->errors += 1;
return;
}
break;
default:
cerr << expr->get_fileline()
<< ": internal error: "
<< "Failed to cast expression?" << endl;
des->errors += 1;
return;
break;
}
(*cur).second.val = res;
double value = res->value().as_double();
bool from_flag = (*cur).second.range == 0? true : false;
for (range_t*value_range = (*cur).second.range
; value_range ; value_range = value_range->next) {
if (from_flag && value_range->exclude_flag==false)
continue;
if (value_range->low_expr) {
double tmp;
bool flag = eval_as_double(tmp, value_range->low_expr);
ivl_assert(*value_range->low_expr, flag);
if (value_range->low_open_flag && value <= tmp)
continue;
else if (value < tmp)
continue;
}
if (value_range->high_expr) {
double tmp;
bool flag = eval_as_double(tmp, value_range->high_expr);
ivl_assert(*value_range->high_expr, flag);
if (value_range->high_open_flag && value >= tmp)
continue;
else if (value > tmp)
continue;
}
if (value_range->exclude_flag == false) {
from_flag = true;
continue;
}
// All the above tests failed, so we must have tripped
// an exclude rule.
from_flag = false;
break;
}
if (! from_flag) {
cerr << res->get_fileline() << ": error: "
<< "Parameter value " << value
<< " is out of range for real parameter " << (*cur).first
<< "." << endl;
des->errors += 1;
}
}
/*
* Evaluate a parameter that is forced to type string. This comes to pass when
* the input is something like this:
*
* parameter string foo = <expr>;
*
* The param_type should be netstring_t, the val_expr is the pform of the
* input <expr>, and we try to elaborate/evaluate down to a IVL_VT_STRING
* expression.
*/
void NetScope::evaluate_parameter_string_(Design*des, param_ref_t cur)
{
PExpr*val_expr = (*cur).second.val_expr;
NetScope*val_scope = (*cur).second.val_scope;
ivl_type_t param_type = cur->second.ivl_type;
ivl_assert(cur->second, val_expr);
ivl_assert(cur->second, param_type);
NetExpr*expr = elab_and_eval(des, val_scope, val_expr, param_type, true);
if (! expr)
return;
cur->second.val = expr;
if (debug_elaborate) {
cerr << cur->second.get_fileline() << ": " << __func__ << ": "
<< "Parameter type: " << *param_type << endl;
cerr << cur->second.get_fileline() << ": " << __func__ << ": "
<< "Parameter value: " << *val_expr << endl;
cerr << cur->second.get_fileline() << ": " << __func__ << ": "
<< "Elaborated value: " << *expr << endl;
}
}
void NetScope::evaluate_type_parameter_(Design *des, param_ref_t cur)
{
const PETypename *type_expr = dynamic_cast<const PETypename*>(cur->second.val_expr);
if (!type_expr) {
cerr << this->get_fileline() << ": error: "
<< "Type parameter `" << cur->first << "` value `"
<< *cur->second.val_expr << "` is not a type."
<< endl;
des->errors++;
// Recover
cur->second.ivl_type = netvector_t::integer_type();
return;
}
data_type_t *ptype = type_expr->get_type();
NetScope *type_scope = cur->second.val_scope;
cur->second.ivl_type = ptype->elaborate_type(des, type_scope);
}
void NetScope::evaluate_parameter_(Design*des, param_ref_t cur)
{
// If the parameter has already been evaluated, quietly return.
if (cur->second.val || cur->second.ivl_type)
return;
if (cur->second.val_expr == 0) {
cerr << this->get_fileline() << ": error: "
<< "Missing value for parameter `"
<< cur->first << "`." << endl;
des->errors += 1;
cur->second.val = new NetEConst(verinum(verinum::Vx));
return;
}
if (cur->second.type_flag) {
evaluate_type_parameter_(des, cur);
return;
}
ivl_type_t param_type = cur->second.ivl_type;
// If the parameter type is present, then elaborate it now. Elaborate
// the type in the current scope, and not the scope of the expression.
if (cur->second.val_type) {
param_type = cur->second.val_type->elaborate_type(des, this);
cur->second.ivl_type = param_type;
cur->second.val_type = 0;
}
// Guess the varaiable type of the parameter. If the parameter has no
// given type, then guess the type from the expression and use that to
// evaluate (this is currently handled in evaluate_parameter_logic_()).
ivl_variable_type_t use_type;
if (param_type)
use_type = param_type->base_type();
else
use_type = IVL_VT_NO_TYPE;
if (cur->second.solving) {
cerr << cur->second.get_fileline() << ": error: "
<< "Recursive parameter reference found involving "
<< cur->first << "." << endl;
des->errors += 1;
} else {
cur->second.solving = true;
switch (use_type) {
case IVL_VT_NO_TYPE:
case IVL_VT_BOOL:
case IVL_VT_LOGIC:
evaluate_parameter_logic_(des, cur);
break;
case IVL_VT_REAL:
evaluate_parameter_real_(des, cur);
break;
case IVL_VT_STRING:
evaluate_parameter_string_(des, cur);
break;
default:
cerr << cur->second.get_fileline() << ": internal error: "
<< "Unexpected parameter type " << use_type
<< "." << endl;
cerr << cur->second.get_fileline() << ": : "
<< "Parameter name: " << cur->first << endl;
if (param_type)
cerr << cur->second.get_fileline() << ": : "
<< "Parameter ivl_type: " << *param_type << endl;
cerr << cur->second.get_fileline() << ": : "
<< "Expression is: " << *cur->second.val_expr << endl;
ivl_assert(cur->second, 0);
break;
}
cur->second.solving = false;
}
// If we have failed to evaluate the expression, create a dummy
// value. This prevents spurious error messages being output.
if (cur->second.val == 0) {
verinum val(verinum::Vx);
cur->second.val = new NetEConst(val);
}
// Flag that the expression has been evaluated.
cur->second.val_expr = 0;
}
void NetScope::evaluate_parameters(Design*des)
{
for (map<hname_t,NetScope*>::const_iterator cur = children_.begin()
; cur != children_.end() ; ++ cur )
cur->second->evaluate_parameters(des);
if (debug_scopes)
cerr << "debug: "
<< "Evaluating parameters in " << scope_path(this) << endl;
for (param_ref_t cur = parameters.begin()
; cur != parameters.end() ; ++ cur) {
evaluate_parameter_(des, cur);
}
}
void Design::residual_defparams()
{
for (list<NetScope*>::const_iterator scope = root_scopes_.begin();
scope != root_scopes_.end(); ++ scope )
(*scope)->residual_defparams(this);
}
void NetScope::residual_defparams(Design*des)
{
// Clean out the list of defparams that never managed to match
// a scope. Print a warning for each.
while (! defparams_later.empty()) {
pair<list<hname_t>,PExpr*> cur = defparams_later.front();
defparams_later.pop_front();
cerr << cur.second->get_fileline() << ": warning: "
<< "Scope of " << cur.first << " not found." << endl;
}
for (map<hname_t,NetScope*>::const_iterator cur = children_.begin()
; cur != children_.end() ; ++ cur )
cur->second->residual_defparams(des);
}
const char* Design::get_flag(const string&key) const
{
map<string,const char*>::const_iterator tmp = flags_.find(key);
if (tmp == flags_.end())
return "";
else
return (*tmp).second;
}
/*
* This method looks for a signal (reg, wire, whatever) starting at
* the specified scope. If the name is hierarchical, it is split into
* scope and name and the scope used to find the proper starting point
* for the real search.
*
* It is the job of this function to properly implement Verilog scope
* rules as signals are concerned.
*/
NetNet* Design::find_signal(NetScope*scope, pform_name_t path)
{
assert(scope);
perm_string key = peek_tail_name(path);
path.pop_back();
if (! path.empty()) {
list<hname_t> eval_path = eval_scope_path(this, scope, path);
scope = find_scope(scope, eval_path);
}
while (scope) {
if (NetNet*net = scope->find_signal(key))
return net;
if (NetScope*import_scope = scope->find_import(this, key)) {
scope = import_scope;
continue;
}
if (scope->type() == NetScope::MODULE)
break;
scope = scope->parent();
}
return 0;
}
NetFuncDef* Design::find_function(NetScope*scope, const pform_name_t&name)
{
assert(scope);
std::list<hname_t> eval_path = eval_scope_path(this, scope, name);
NetScope*func = find_scope(scope, eval_path, NetScope::FUNC);
if (func && (func->type() == NetScope::FUNC)) {
// If a function is used in a parameter definition or in
// a signal declaration, it is possible to get here before
// the function's signals have been elaborated. If this is
// the case, elaborate them now.
if (func->elab_stage() < 2) {
func->need_const_func(true);
const PFunction*pfunc = func->func_pform();
assert(pfunc);
pfunc->elaborate_sig(this, func);
}
return func->func_def();
}
return 0;
}
NetScope* Design::find_task(NetScope*scope, const pform_name_t&name)
{
std::list<hname_t> eval_path = eval_scope_path(this, scope, name);
NetScope*task = find_scope(scope, eval_path, NetScope::TASK);
if (task && (task->type() == NetScope::TASK))
return task;
return 0;
}
void Design::add_node(NetNode*net)
{
assert(net->design_ == 0);
if (nodes_ == 0) {
net->node_next_ = net;
net->node_prev_ = net;
} else {
net->node_next_ = nodes_->node_next_;
net->node_prev_ = nodes_;
net->node_next_->node_prev_ = net;
net->node_prev_->node_next_ = net;
}
nodes_ = net;
net->design_ = this;
}
void Design::del_node(NetNode*net)
{
assert(net != 0);
assert(net->design_ == this);
/* Interact with the Design::functor method by manipulating the
cur and nxt pointers that it is using. */
if (net == nodes_functor_nxt_)
nodes_functor_nxt_ = nodes_functor_nxt_->node_next_;
if (net == nodes_functor_nxt_)
nodes_functor_nxt_ = 0;
if (net == nodes_functor_cur_)
nodes_functor_cur_ = 0;
/* Now perform the actual delete. */
if (nodes_ == net)
nodes_ = net->node_prev_;
if (nodes_ == net) {
nodes_ = 0;
} else {
net->node_next_->node_prev_ = net->node_prev_;
net->node_prev_->node_next_ = net->node_next_;
}
net->design_ = 0;
}
void Design::add_branch(NetBranch*bra)
{
bra->next_ = branches_;
branches_ = bra;
}
void Design::add_process(NetProcTop*pro)
{
pro->next_ = procs_;
procs_ = pro;
}
void Design::add_process(NetAnalogTop*pro)
{
pro->next_ = aprocs_;
aprocs_ = pro;
}
void Design::delete_process(NetProcTop*top)
{
assert(top);
if (procs_ == top) {
procs_ = top->next_;
} else {
NetProcTop*cur = procs_;
while (cur->next_ != top) {
assert(cur->next_);
cur = cur->next_;
}
cur->next_ = top->next_;
}
if (procs_idx_ == top)
procs_idx_ = top->next_;
delete top;
}
void Design::join_islands(void)
{
if (nodes_ == 0)
return;
NetNode*cur = nodes_->node_next_;
do {
join_island(cur);
cur = cur->node_next_;
} while (cur != nodes_->node_next_);
}
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