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/*
* Copyright (c) 2000-2021 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 <cstring>
# include "t-dll.h"
# include "netlist.h"
# include "netclass.h"
# include <cassert>
# include <cstdlib>
# include "ivl_alloc.h"
# include "ivl_assert.h"
using namespace std;
/*
* This is a little convenience function for converting a NetExpr
* expression type to the expression type used by ivl_expr_t objects.
*/
static ivl_variable_type_t get_expr_type(const NetExpr*net)
{
return net->expr_type();
}
/*
* These methods implement the expression scan that generates the
* ivl_expr_t representing the expression. Each method leaves the
* expr_ member filled with the ivl_expr_t that represents it. Each
* method expects that the expr_ member empty (0) when it starts.
*/
/*
* This function takes an expression in the expr_ member that is
* already built up, and adds a subtraction of the given constant.
*/
void dll_target::sub_off_from_expr_(long off)
{
assert(expr_ != 0);
char*bits;
ivl_expr_t tmpc = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
tmpc->type_ = IVL_EX_NUMBER;
tmpc->value_ = IVL_VT_VECTOR;
tmpc->net_type= 0;
tmpc->width_ = expr_->width_;
tmpc->signed_ = expr_->signed_;
tmpc->sized_ = 1;
tmpc->u_.number_.bits_ = bits = (char*)malloc(tmpc->width_);
for (unsigned idx = 0 ; idx < tmpc->width_ ; idx += 1) {
bits[idx] = (off & 1)? '1' : '0';
off >>= 1;
}
/* Now make the subtracter (x-4 in the above example)
that has as input A the index expression and input B
the constant to subtract. */
ivl_expr_t tmps = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
tmps->type_ = IVL_EX_BINARY;
tmps->value_ = IVL_VT_VECTOR;
tmps->net_type= 0;
tmps->width_ = tmpc->width_;
tmps->signed_ = tmpc->signed_;
tmps->sized_ = 1;
tmps->u_.binary_.op_ = '-';
tmps->u_.binary_.lef_ = expr_;
tmps->u_.binary_.rig_ = tmpc;
/* Replace (x) with (x-off) */
expr_ = tmps;
}
void dll_target::mul_expr_by_const_(long val)
{
assert(expr_ != 0);
char*bits;
ivl_expr_t tmpc = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
tmpc->type_ = IVL_EX_NUMBER;
tmpc->value_ = IVL_VT_VECTOR;
tmpc->net_type= 0;
tmpc->width_ = expr_->width_;
tmpc->signed_ = expr_->signed_;
tmpc->sized_ = 1;
tmpc->u_.number_.bits_ = bits = (char*)malloc(tmpc->width_);
for (unsigned idx = 0 ; idx < tmpc->width_ ; idx += 1) {
bits[idx] = (val & 1)? '1' : '0';
val >>= 1;
}
/* Now make the subtracter (x-4 in the above example)
that has as input A the index expression and input B
the constant to subtract. */
ivl_expr_t tmps = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
tmps->type_ = IVL_EX_BINARY;
tmps->value_ = IVL_VT_VECTOR;
tmpc->net_type= 0;
tmps->width_ = tmpc->width_;
tmps->signed_ = tmpc->signed_;
tmps->sized_ = 1;
tmps->u_.binary_.op_ = '*';
tmps->u_.binary_.lef_ = expr_;
tmps->u_.binary_.rig_ = tmpc;
/* Replace (x) with (x*valf) */
expr_ = tmps;
}
ivl_expr_t dll_target::expr_from_value_(const verinum&val)
{
ivl_expr_t expr = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
unsigned idx;
char*bits;
expr->type_ = IVL_EX_NUMBER;
expr->value_= IVL_VT_VECTOR;
expr->net_type=0;
expr->width_= val.len();
expr->signed_ = val.has_sign()? 1 : 0;
expr->sized_= 1;
expr->u_.number_.bits_ = bits = (char*)malloc(expr->width_ + 1);
for (idx = 0 ; idx < expr->width_ ; idx += 1)
switch (val.get(idx)) {
case verinum::V0:
bits[idx] = '0';
break;
case verinum::V1:
bits[idx] = '1';
break;
case verinum::Vx:
bits[idx] = 'x';
break;
case verinum::Vz:
bits[idx] = 'z';
break;
default:
assert(0);
}
bits[expr->width_] = 0;
return expr;
}
void dll_target::expr_access_func(const NetEAccess*net)
{
assert(expr_ == 0);
// Make a stub Branch Access Function expression node.
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_BACCESS;
expr_->value_ = IVL_VT_REAL;
expr_->net_type=0;
expr_->width_ = 1;
expr_->signed_= 1;
expr_->sized_ = 1;
FILE_NAME(expr_, net);
expr_->u_.branch_.branch = net->get_branch()->target_obj();
expr_->u_.branch_.nature = net->get_nature();
}
void dll_target::expr_array_pattern(const NetEArrayPattern*net)
{
assert(expr_ == 0);
ivl_expr_t expr_tmp = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_tmp->type_ = IVL_EX_ARRAY_PATTERN;
expr_tmp->value_= net->expr_type();
expr_tmp->net_type = net->net_type();
expr_tmp->width_ = 1;
expr_tmp->signed_ = 0;
expr_tmp->sized_ = 0;
FILE_NAME(expr_tmp, net);
expr_tmp->u_.array_pattern_.parms = net->item_size();
expr_tmp->u_.array_pattern_.parm = new ivl_expr_t [net->item_size()];
for (size_t idx = 0 ; idx < net->item_size() ; idx += 1) {
const NetExpr*tmp = net->item(idx);
tmp->expr_scan(this);
expr_tmp->u_.array_pattern_.parm[idx] = expr_;
expr_ = 0;
}
expr_ = expr_tmp;
}
void dll_target::expr_binary(const NetEBinary*net)
{
assert(expr_ == 0);
net->left()->expr_scan(this);
ivl_expr_t left = expr_;
expr_ = 0;
net->right()->expr_scan(this);
ivl_expr_t rght = expr_;
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_BINARY;
expr_->value_= get_expr_type(net);
expr_->net_type=0;
expr_->width_= net->expr_width();
expr_->signed_ = net->has_sign()? 1 : 0;
expr_->sized_= 1;
FILE_NAME(expr_, net);
expr_->u_.binary_.op_ = net->op();
expr_->u_.binary_.lef_ = left;
expr_->u_.binary_.rig_ = rght;
}
void dll_target::expr_concat(const NetEConcat*net)
{
assert(expr_ == 0);
ivl_expr_t cur = new struct ivl_expr_s;
assert(cur);
cur->type_ = IVL_EX_CONCAT;
cur->value_ = net->expr_type();
cur->net_type=0;
cur->width_ = net->expr_width();
cur->signed_ = net->has_sign() ? 1 : 0;
cur->sized_ = 1;
FILE_NAME(cur, net);
cur->u_.concat_.rept = net->repeat();
cur->u_.concat_.parms = net->nparms();
cur->u_.concat_.parm = new ivl_expr_t [net->nparms()];
for (unsigned idx = 0 ; idx < net->nparms() ; idx += 1) {
expr_ = 0;
net->parm(idx)->expr_scan(this);
assert(expr_);
cur->u_.concat_.parm[idx] = expr_;
}
expr_ = cur;
}
void dll_target::expr_const(const NetEConst*net)
{
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->value_= net->expr_type();
expr_->net_type=0;
FILE_NAME(expr_, net);
if (net->value().is_string()) {
expr_->type_ = IVL_EX_STRING;
expr_->width_= net->expr_width();
expr_->u_.string_.value_ =strdup(net->value().as_string().c_str());
} else {
verinum val = net->value();
unsigned idx;
char*bits;
expr_->type_ = IVL_EX_NUMBER;
expr_->width_= net->expr_width();
expr_->signed_ = net->has_sign()? 1 : 0;
expr_->sized_= net->has_width()? 1 : 0;
expr_->u_.number_.bits_ = bits = (char*)malloc(expr_->width_);
for (idx = 0 ; idx < expr_->width_ ; idx += 1)
switch (val.get(idx)) {
case verinum::V0:
bits[idx] = '0';
break;
case verinum::V1:
bits[idx] = '1';
break;
case verinum::Vx:
bits[idx] = 'x';
break;
case verinum::Vz:
bits[idx] = 'z';
break;
default:
assert(0);
}
}
}
void dll_target::expr_param(const NetEConstParam*net)
{
ivl_scope_t scop = find_scope(des_, net->scope());
ivl_parameter_t par = scope_find_param(scop, net->name());
if (par == 0) {
cerr << net->get_fileline() << ": internal error: "
<< "Parameter " << net->name() << " missing from "
<< ivl_scope_name(scop) << endl;
}
assert(par);
expr_const(net);
expr_->u_.string_.parameter = par;
}
void dll_target::expr_rparam(const NetECRealParam*net)
{
ivl_scope_t scop = find_scope(des_, net->scope());
ivl_parameter_t par = scope_find_param(scop, net->name());
if (par == 0) {
cerr << net->get_fileline() << ": internal error: "
<< "Parameter " << net->name() << " missing from "
<< ivl_scope_name(scop) << endl;
}
assert(par);
assert(par->value);
expr_ = par->value;
}
void dll_target::expr_creal(const NetECReal*net)
{
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->width_ = net->expr_width();
expr_->signed_ = 1;
expr_->sized_ = 1;
expr_->type_ = IVL_EX_REALNUM;
FILE_NAME(expr_, net);
expr_->value_= IVL_VT_REAL;
expr_->net_type=0;
expr_->u_.real_.value = net->value().as_double();
}
void dll_target::expr_last(const NetELast*net)
{
assert(expr_ == 0);
ivl_expr_t expr = new struct ivl_expr_s;
expr->type_ = IVL_EX_SFUNC;
expr->value_ = IVL_VT_LOGIC;
expr->width_ = 32;
expr->signed_ = 1;
expr->sized_ = 1;
expr->net_type = 0;
FILE_NAME(expr, net);
expr->u_.sfunc_.name_ = "$high";
ivl_signal_t sig = find_signal(des_, net->sig());
ivl_expr_t esig = new struct ivl_expr_s;
esig->type_ = IVL_EX_SIGNAL;
esig->value_ = IVL_VT_DARRAY;
esig->net_type= sig->net_type;
esig->width_ = 1;
esig->signed_ = sig->net_type->get_signed()? 1 : 0;
FILE_NAME(esig, net);
esig->u_.signal_.word = 0;
esig->u_.signal_.sig = sig;
expr->u_.sfunc_.parms = 1;
expr->u_.sfunc_.parm = new ivl_expr_t[1];
expr->u_.sfunc_.parm[0] = esig;
expr_ = expr;
}
void dll_target::expr_new(const NetENew*net)
{
ivl_expr_t size = 0;
ivl_expr_t init_val = 0;
if (net->size_expr()) {
net->size_expr()->expr_scan(this);
size = expr_;
expr_ = 0;
}
if (net->init_expr()) {
net->init_expr()->expr_scan(this);
init_val = expr_;
expr_ = 0;
}
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->width_ = net->expr_width();
expr_->signed_ = 0;
expr_->sized_ = 1;
expr_->type_ = IVL_EX_NEW;
FILE_NAME(expr_, net);
expr_->value_ = net->expr_type(); // May be IVL_VT_DARRAY or _CLASS
expr_->net_type= net->net_type();
expr_->u_.new_.size = size;
expr_->u_.new_.init_val = init_val;
}
void dll_target::expr_null(const NetENull*net)
{
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->width_ = net->expr_width();
expr_->signed_ = 0;
expr_->sized_ = 1;
expr_->type_ = IVL_EX_NULL;
FILE_NAME(expr_, net);
expr_->value_ = IVL_VT_CLASS;
expr_->net_type= 0;
}
void dll_target::expr_property(const NetEProperty*net)
{
ivl_expr_t index = 0;
if (const NetExpr*index_expr = net->get_index()) {
index_expr->expr_scan(this);
index = expr_;
expr_ = 0;
}
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->width_ = net->expr_width();
expr_->signed_ = net->has_sign();
expr_->sized_ = 1;
expr_->type_ = IVL_EX_PROPERTY;
FILE_NAME(expr_, net);
expr_->value_ = net->expr_type();
expr_->net_type= net->net_type();
expr_->u_.property_.sig = find_signal(des_, net->get_sig());
expr_->u_.property_.prop_idx = net->property_idx();
expr_->u_.property_.index = index;
}
void dll_target::expr_event(const NetEEvent*net)
{
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_EVENT;
FILE_NAME(expr_, net);
expr_->value_= IVL_VT_VOID;
expr_->net_type=0;
/* Locate the event by name. Save the ivl_event_t in the
expression so that the generator can find it easily. */
const NetEvent*ev = net->event();
ivl_scope_t ev_scope = lookup_scope_(ev->scope());
for (unsigned idx = 0 ; idx < ev_scope->nevent_ ; idx += 1) {
const char*ename = ivl_event_basename(ev_scope->event_[idx]);
if (strcmp(ev->name(), ename) == 0) {
expr_->u_.event_.event = ev_scope->event_[idx];
break;
}
}
}
void dll_target::expr_scope(const NetEScope*net)
{
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_SCOPE;
FILE_NAME(expr_, net);
expr_->value_= IVL_VT_VOID;
expr_->net_type=0;
expr_->u_.scope_.scope = lookup_scope_(net->scope());
}
void dll_target::expr_scopy(const NetEShallowCopy*net)
{
assert(expr_ == 0);
net->expr_scan_oper1(this);
ivl_expr_t expr1 = expr_;
expr_ = 0;
net->expr_scan_oper2(this);
ivl_expr_t expr2 = expr_;
expr_ = 0;
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_SHALLOWCOPY;
FILE_NAME(expr_, net);
expr_->value_ = net->expr_type();
expr_->net_type = net->net_type();
expr_->u_.shallow_.dest = expr1;
expr_->u_.shallow_.src = expr2;
}
void dll_target::expr_netenum(const NetENetenum*net)
{
assert(expr_ == 0);
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_ENUMTYPE;
FILE_NAME(expr_, net);
expr_->value_= IVL_VT_VOID;
expr_->net_type=0;
expr_->u_.enumtype_.type = net->netenum();
}
void dll_target::expr_select(const NetESelect*net)
{
assert(expr_ == 0);
net->sub_expr()->expr_scan(this);
ivl_expr_t expr = expr_;
expr_ = 0;
if (net->select())
net->select()->expr_scan(this);
ivl_expr_t base = expr_;
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_SELECT;
expr_->value_= net->expr_type();
expr_->net_type=0;
expr_->width_= net->expr_width();
expr_->signed_ = net->has_sign()? 1 : 0;
expr_->sized_= 1;
FILE_NAME(expr_, net);
expr_->u_.select_.sel_type_ = net->select_type();
expr_->u_.select_.expr_ = expr;
expr_->u_.select_.base_ = base;
}
void dll_target::expr_sfunc(const NetESFunc*net)
{
assert(expr_ == 0);
ivl_expr_t expr = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr->type_ = IVL_EX_SFUNC;
expr->value_= net->expr_type();
expr->net_type=net->net_type();
expr->width_= net->expr_width();
expr->signed_ = net->has_sign()? 1 : 0;
expr->sized_= 1;
FILE_NAME(expr, net);
/* system function names are lex_strings strings. */
expr->u_.sfunc_.name_ = net->name();
unsigned cnt = net->nparms();
expr->u_.sfunc_.parms = cnt;
expr->u_.sfunc_.parm = new ivl_expr_t[cnt];
/* make up the parameter expressions. */
for (unsigned idx = 0 ; idx < cnt ; idx += 1) {
net->parm(idx)->expr_scan(this);
assert(expr_);
expr->u_.sfunc_.parm[idx] = expr_;
expr_ = 0;
}
expr_ = expr;
}
void dll_target::expr_ternary(const NetETernary*net)
{
assert(expr_ == 0);
ivl_expr_t expr = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr->type_ = IVL_EX_TERNARY;
expr->value_= net->expr_type();
expr->net_type=0;
expr->width_ = net->expr_width();
expr->signed_ = net->has_sign()? 1 : 0;
expr->sized_ = 1;
FILE_NAME(expr, net);
net->cond_expr()->expr_scan(this);
assert(expr_);
expr->u_.ternary_.cond = expr_;
expr_ = 0;
net->true_expr()->expr_scan(this);
assert(expr_);
expr->u_.ternary_.true_e = expr_;
expr_ = 0;
net->false_expr()->expr_scan(this);
assert(expr_);
expr->u_.ternary_.false_e = expr_;
expr_ = expr;
}
void dll_target::expr_signal(const NetESignal*net)
{
ivl_signal_t sig = find_signal(des_, net->sig());
assert(expr_ == 0);
/* If there is a word expression, generate it. */
ivl_expr_t word_expr = 0;
if (const NetExpr*word = net->word_index()) {
word->expr_scan(this);
assert(expr_);
word_expr = expr_;
expr_ = 0;
}
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_SIGNAL;
expr_->value_= net->expr_type();
expr_->net_type=0;
expr_->width_= net->expr_width();
expr_->signed_ = net->has_sign()? 1 : 0;
expr_->sized_= 1;
FILE_NAME(expr_, net);
expr_->u_.signal_.word = word_expr;
expr_->u_.signal_.sig = sig;
/* Make account for the special case that this is a reference
to an array as a whole. We detect this case by noting that
this is an array (more than 0 array dimensions) and that
there is no word select expression. For this case, we have
an IVL_EX_ARRAY expression instead of a SIGNAL expression. */
if (sig->array_dimensions_ > 0 && word_expr == 0) {
expr_->type_ = IVL_EX_ARRAY;
expr_->width_ = 0; // Doesn't make much sense for arrays.
}
}
void dll_target::expr_ufunc(const NetEUFunc*net)
{
assert(expr_ == 0);
ivl_expr_t expr = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr->type_ = IVL_EX_UFUNC;
expr->value_= net->expr_type();
expr->net_type=0;
expr->width_= net->expr_width();
expr->signed_ = net->has_sign()? 1 : 0;
expr->sized_= 1;
FILE_NAME(expr, net);
expr->u_.ufunc_.def = lookup_scope_(net->func());
if (expr->u_.ufunc_.def == 0) {
cerr << net->get_fileline() << ": internal error: "
<< "dll_target::expr_ufunc: "
<< "Unable to match scope " << scope_path(net->func()) << endl;
}
ivl_assert(*net, expr->u_.ufunc_.def);
ivl_assert(*net, expr->u_.ufunc_.def->type_ == IVL_SCT_FUNCTION);
unsigned cnt = net->parm_count();
expr->u_.ufunc_.parms = cnt;
expr->u_.ufunc_.parm = new ivl_expr_t[cnt];
/* make up the parameter expressions. */
for (unsigned idx = 0 ; idx < cnt ; idx += 1) {
net->parm(idx)->expr_scan(this);
assert(expr_);
expr->u_.ufunc_.parm[idx] = expr_;
expr_ = 0;
}
expr_ = expr;
}
void dll_target::expr_unary(const NetEUnary*net)
{
assert(expr_ == 0);
net->expr()->expr_scan(this);
assert(expr_);
ivl_expr_t sub = expr_;
expr_ = (ivl_expr_t)calloc(1, sizeof(struct ivl_expr_s));
expr_->type_ = IVL_EX_UNARY;
expr_->value_= net->expr_type();
expr_->net_type=0;
expr_->width_ = net->expr_width();
expr_->signed_ = net->has_sign()? 1 : 0;
expr_->sized_ = 1;
FILE_NAME(expr_, net);
expr_->u_.unary_.op_ = net->op();
expr_->u_.unary_.sub_ = sub;
}
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