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elab_lval.cc
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elab_lval.cc
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/*
* Copyright (c) 2000-2024 Stephen Williams ([email protected])
* Copyright CERN 2012-2013 / 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 "PExpr.h"
# include "PPackage.h"
# include "netlist.h"
# include "netmisc.h"
# include "netstruct.h"
# include "netclass.h"
# include "netdarray.h"
# include "netparray.h"
# include "netvector.h"
# include "netenum.h"
# include "compiler.h"
# include <cstdlib>
# include <iostream>
# include <climits>
# include "ivl_assert.h"
using namespace std;
/*
* These methods generate a NetAssign_ object for the l-value of the
* assignment. This is common code for the = and <= statements.
*
* What gets generated depends on the structure of the l-value. If the
* l-value is a simple name (i.e., foo <= <value>) then the NetAssign_
* is created the width of the foo reg and connected to all the
* bits.
*
* If there is a part select (i.e., foo[3:1] <= <value>) the NetAssign_
* is made only as wide as it needs to be (3 bits in this example) and
* connected to the correct bits of foo. A constant bit select is a
* special case of the part select.
*
* If the bit-select is non-constant (i.e., foo[<expr>] = <value>) the
* NetAssign_ is made wide enough to connect to all the bits of foo,
* then the mux expression is elaborated and attached to the
* NetAssign_ node as a b_mux value. The target must interpret the
* presence of a bmux value as taking a single bit and assigning it to
* the bit selected by the bmux expression.
*
* If the l-value expression is non-trivial, but can be fully
* evaluated at compile time (meaning any bit selects are constant)
* then elaboration will make a single NetAssign_ that connects to a
* synthetic reg that in turn connects to all the proper pins of the
* l-value.
*
* This last case can turn up in statements like: {a, b[1]} = c;
* rather than create a NetAssign_ for each item in the concatenation,
* elaboration makes a single NetAssign_ and connects it up properly.
*/
void PEIdent::report_mixed_assignment_conflict_(const char*category) const
{
cerr << get_fileline() << ": error: Cannot perform procedural "
"assignment to " << category << " '" << path_
<< "' because it is also continuously assigned." << endl;
}
/*
* The default interpretation of an l-value to a procedural assignment
* is to try to make a net elaboration, and see if the result is
* suitable for assignment.
*/
NetAssign_* PExpr::elaborate_lval(Design*, NetScope*, bool, bool, bool) const
{
cerr << get_fileline() << ": Assignment l-value too complex." << endl;
return 0;
}
/*
* Concatenation expressions can appear as l-values. Handle them here.
*
* If adjacent l-values in the concatenation are not bit selects, then
* merge them into a single NetAssign_ object. This can happen is code
* like ``{ ...a, b, ...}''. As long as "a" and "b" do not have bit
* selects (or the bit selects are constant) we can merge the
* NetAssign_ objects.
*
* Be careful to get the bit order right. In the expression ``{a, b}''
* a is the MSB and b the LSB. Connect the LSB to the low pins of the
* NetAssign_ object.
*/
NetAssign_* PEConcat::elaborate_lval(Design*des,
NetScope*scope,
bool is_cassign,
bool is_force,
bool is_init) const
{
if (repeat_) {
cerr << get_fileline() << ": error: Repeat concatenations make "
"no sense in l-value expressions. I refuse." << endl;
des->errors += 1;
return 0;
}
NetAssign_*res = 0;
for (unsigned idx = 0 ; idx < parms_.size() ; idx += 1) {
if (parms_[idx] == 0) {
cerr << get_fileline() << ": error: Empty expressions "
<< "not allowed in concatenations." << endl;
des->errors += 1;
continue;
}
NetAssign_*tmp = parms_[idx]->elaborate_lval(des, scope,
is_cassign, is_force, is_init);
/* If the l-value doesn't elaborate, the error was
already detected and printed. We just skip it and let
the compiler catch more errors. */
if (tmp == 0) continue;
if (tmp->expr_type() == IVL_VT_REAL) {
cerr << parms_[idx]->get_fileline() << ": error: "
<< "concatenation operand can not be real: "
<< *parms_[idx] << endl;
des->errors += 1;
continue;
}
/* A concatenation is always unsigned. */
tmp->set_signed(false);
/* Link the new l-value to the previous one. */
NetAssign_*last = tmp;
while (last->more)
last = last->more;
last->more = res;
res = tmp;
}
return res;
}
/*
* Handle the ident as an l-value. This includes bit and part selects
* of that ident.
*/
NetAssign_* PEIdent::elaborate_lval(Design*des,
NetScope*scope,
bool is_cassign,
bool is_force,
bool is_init) const
{
if (debug_elaborate) {
cerr << get_fileline() << ": PEIdent::elaborate_lval: "
<< "Elaborate l-value ident expression: " << *this << endl;
}
symbol_search_results sr;
symbol_search(this, des, scope, path_, lexical_pos_, &sr);
NetNet *reg = sr.net;
pform_name_t &member_path = sr.path_tail;
/* The l-value must be a variable. If not, then give up and
print a useful error message. */
if (reg == 0) {
if (scope->type()==NetScope::FUNC
&& scope->func_def()->is_void()
&& scope->basename()==peek_tail_name(path_)) {
cerr << get_fileline() << ": error: "
<< "Cannot assign to " << path_
<< " because function " << scope_path(scope)
<< " is void." << endl;
} else {
cerr << get_fileline() << ": error: Could not find variable ``"
<< path_ << "'' in ``" << scope_path(scope) <<
"''" << endl;
if (sr.decl_after_use) {
cerr << sr.decl_after_use->get_fileline() << ": : "
"A symbol with that name was declared here. "
"Check for declaration after use." << endl;
}
}
des->errors += 1;
return 0;
}
ivl_assert(*this, reg);
if (debug_elaborate) {
cerr << get_fileline() << ": " << __func__ << ": "
<< "Found l-value path_=" << path_
<< " as reg=" << reg->name() << endl;
cerr << get_fileline() << ": " << __func__ << ": "
<< "reg->type()=" << reg->type()
<< ", reg->unpacked_dimensions()=" << reg->unpacked_dimensions()
<< endl;
if (reg->net_type())
cerr << get_fileline() << ": " << __func__ << ": "
<< "reg->net_type()=" << *reg->net_type() << endl;
else
cerr << get_fileline() << ": " << __func__ << ": "
<< "reg->net_type()=<nil>" << endl;
const pform_name_t &base_path = sr.path_head;
cerr << get_fileline() << ": " << __func__ << ": "
<< " base_path=" << base_path
<< ", member_path=" << member_path
<< endl;
}
if (reg->get_const() && !is_init) {
cerr << get_fileline() << ": error: Assignment to const signal `"
<< reg->name() << "` is not allowed." << endl;
des->errors++;
return nullptr;
}
/* We are elaborating procedural assignments. Wires are not allowed
unless this is the l-value of a force. */
if ((reg->type() != NetNet::REG)
&& ((reg->type() != NetNet::UNRESOLVED_WIRE) || !reg->coerced_to_uwire())
&& !is_force) {
cerr << get_fileline() << ": error: '" << path_
<< "' is not a valid l-value for a procedural assignment."
<< endl;
cerr << reg->get_fileline() << ": : '" << path_ <<
"' is declared here as a " << reg->type() << "." << endl;
des->errors += 1;
return 0;
}
return elaborate_lval_var_(des, scope, is_force, is_cassign, reg,
sr.type, member_path);
}
NetAssign_*PEIdent::elaborate_lval_var_(Design *des, NetScope *scope,
bool is_force, bool is_cassign,
NetNet *reg, ivl_type_t data_type,
pform_name_t tail_path) const
{
// We are processing the tail of a string of names. For
// example, the Verilog may be "a.b.c", so we are processing
// "c" at this point.
const name_component_t&name_tail = path_.back();
// Use the last index to determine what kind of select
// (bit/part/etc) we are processing. For example, the Verilog
// may be "a.b.c[1][2][<index>]". All but the last index must
// be simple expressions, only the <index> may be a part
// select etc., so look at it to determine how we will be
// proceeding.
index_component_t::ctype_t use_sel = index_component_t::SEL_NONE;
if (!name_tail.index.empty())
use_sel = name_tail.index.back().sel;
// Special case: The l-value is an entire memory, or array
// slice. Detect the situation by noting if the index count
// is less than the array dimensions (unpacked).
if (reg->unpacked_dimensions() > name_tail.index.size()) {
return elaborate_lval_array_(des, scope, is_force, reg);
}
// If we find that the matched variable is a packed struct,
// then we can handled it with the net_packed_member_ method.
if (reg->struct_type() && !tail_path.empty()) {
NetAssign_*lv = new NetAssign_(reg);
elaborate_lval_net_packed_member_(des, scope, lv, tail_path, is_force);
return lv;
}
// If the variable is a class object, then handle it with the
// net_class_member_ method.
const netclass_t *class_type = dynamic_cast<const netclass_t *>(data_type);
if (class_type && !tail_path.empty() && gn_system_verilog())
return elaborate_lval_net_class_member_(des, scope, class_type, reg, tail_path);
// Past this point, we should have taken care of the cases
// where the name is a member/method of a struct/class.
// XXXX ivl_assert(*this, method_name.nil());
ivl_assert(*this, tail_path.empty());
bool need_const_idx = is_cassign || is_force;
if (reg->unpacked_dimensions() > 0)
return elaborate_lval_net_word_(des, scope, reg, need_const_idx, is_force);
// This must be after the array word elaboration above!
if (reg->get_scalar() &&
use_sel != index_component_t::SEL_NONE) {
cerr << get_fileline() << ": error: can not select part of ";
if (reg->data_type() == IVL_VT_REAL) cerr << "real: ";
else cerr << "scalar: ";
cerr << reg->name() << endl;
des->errors += 1;
return 0;
}
if (use_sel == index_component_t::SEL_PART) {
NetAssign_*lv = new NetAssign_(reg);
elaborate_lval_net_part_(des, scope, lv, is_force);
return lv;
}
if (use_sel == index_component_t::SEL_IDX_UP ||
use_sel == index_component_t::SEL_IDX_DO) {
NetAssign_*lv = new NetAssign_(reg);
elaborate_lval_net_idx_(des, scope, lv, use_sel, need_const_idx, is_force);
return lv;
}
if (use_sel == index_component_t::SEL_BIT) {
if (reg->darray_type()) {
NetAssign_*lv = new NetAssign_(reg);
elaborate_lval_darray_bit_(des, scope, lv, is_force);
return lv;
} else {
NetAssign_*lv = new NetAssign_(reg);
elaborate_lval_net_bit_(des, scope, lv, need_const_idx, is_force);
return lv;
}
}
ivl_assert(*this, use_sel == index_component_t::SEL_NONE);
if (reg->type()==NetNet::UNRESOLVED_WIRE && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
report_mixed_assignment_conflict_("variable");
des->errors += 1;
return 0;
}
/* No select expressions. */
NetAssign_*lv = new NetAssign_(reg);
lv->set_signed(reg->get_signed());
return lv;
}
NetAssign_*PEIdent::elaborate_lval_array_(Design *des, NetScope *,
bool is_force, NetNet *reg) const
{
if (!gn_system_verilog()) {
cerr << get_fileline() << ": error: Assignment to an entire"
" array or to an array slice requires SystemVerilog."
<< endl;
des->errors += 1;
return 0;
}
const name_component_t&name_tail = path_.back();
if (name_tail.index.empty()) {
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
report_mixed_assignment_conflict_("array");
des->errors += 1;
return 0;
}
NetAssign_*lv = new NetAssign_(reg);
return lv;
}
cerr << get_fileline() << ": sorry: Assignment to an "
" array slice is not yet supported."
<< endl;
des->errors += 1;
return 0;
}
NetAssign_* PEIdent::elaborate_lval_net_word_(Design*des,
NetScope*scope,
NetNet*reg,
bool need_const_idx,
bool is_force) const
{
const name_component_t&name_tail = path_.back();
ivl_assert(*this, !name_tail.index.empty());
if (debug_elaborate) {
cerr << get_fileline() << ": PEIdent::elaborate_lval_net_word_: "
<< "Handle as n-dimensional array." << endl;
}
if (name_tail.index.size() < reg->unpacked_dimensions()) {
cerr << get_fileline() << ": error: Array " << reg->name()
<< " needs " << reg->unpacked_dimensions() << " indices,"
<< " but got only " << name_tail.index.size() << "." << endl;
des->errors += 1;
return 0;
}
// Make sure there are enough indices to address an array element.
const index_component_t&index_head = name_tail.index.front();
if (index_head.sel == index_component_t::SEL_PART) {
cerr << get_fileline() << ": error: cannot perform a part "
<< "select on array " << reg->name() << "." << endl;
des->errors += 1;
return 0;
}
// Evaluate all the index expressions into an
// "unpacked_indices" array.
list<NetExpr*>unpacked_indices;
list<long> unpacked_indices_const;
indices_flags flags;
indices_to_expressions(des, scope, this,
name_tail.index, reg->unpacked_dimensions(),
false,
flags,
unpacked_indices,
unpacked_indices_const);
NetExpr*canon_index = 0;
if (flags.invalid) {
// Nothing to do.
} else if (flags.undefined) {
cerr << get_fileline() << ": warning: "
<< "ignoring undefined l-value array access "
<< reg->name() << as_indices(unpacked_indices)
<< "." << endl;
} else if (flags.variable) {
if (need_const_idx) {
cerr << get_fileline() << ": error: array '" << reg->name()
<< "' index must be a constant in this context." << endl;
des->errors += 1;
return 0;
}
ivl_assert(*this, unpacked_indices.size() == reg->unpacked_dimensions());
canon_index = normalize_variable_unpacked(reg, unpacked_indices);
} else {
ivl_assert(*this, unpacked_indices_const.size() == reg->unpacked_dimensions());
canon_index = normalize_variable_unpacked(reg, unpacked_indices_const);
if (canon_index == 0) {
cerr << get_fileline() << ": warning: "
<< "ignoring out of bounds l-value array access "
<< reg->name() << as_indices(unpacked_indices_const)
<< "." << endl;
}
}
// Ensure invalid array accesses are ignored.
if (canon_index == 0)
canon_index = new NetEConst(verinum(verinum::Vx));
canon_index->set_line(*this);
if (debug_elaborate) {
cerr << get_fileline() << ": PEIdent::elaborate_lval_net_word_: "
<< "canon_index=" << *canon_index << endl;
}
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
NetEConst*canon_const = dynamic_cast<NetEConst*>(canon_index);
if (!canon_const || reg->test_part_driven(reg->vector_width() - 1, 0,
canon_const->value().as_long())) {
report_mixed_assignment_conflict_("array word");
des->errors += 1;
return 0;
}
}
NetAssign_*lv = new NetAssign_(reg);
lv->set_word(canon_index);
if (debug_elaborate)
cerr << get_fileline() << ": debug: Set array word=" << *canon_index << endl;
/* An array word may also have part selects applied to them. */
index_component_t::ctype_t use_sel = index_component_t::SEL_NONE;
if (name_tail.index.size() > reg->unpacked_dimensions())
use_sel = name_tail.index.back().sel;
if (reg->get_scalar() &&
use_sel != index_component_t::SEL_NONE) {
cerr << get_fileline() << ": error: can not select part of ";
if (reg->data_type() == IVL_VT_REAL) cerr << "real";
else cerr << "scalar";
cerr << " array word: " << reg->name()
<< as_indices(unpacked_indices) << endl;
des->errors += 1;
return 0;
}
if (use_sel == index_component_t::SEL_BIT)
elaborate_lval_net_bit_(des, scope, lv, need_const_idx, is_force);
if (use_sel == index_component_t::SEL_PART)
elaborate_lval_net_part_(des, scope, lv, is_force);
if (use_sel == index_component_t::SEL_IDX_UP ||
use_sel == index_component_t::SEL_IDX_DO)
elaborate_lval_net_idx_(des, scope, lv, use_sel,
need_const_idx, is_force);
return lv;
}
bool PEIdent::elaborate_lval_net_bit_(Design*des,
NetScope*scope,
NetAssign_*lv,
bool need_const_idx,
bool is_force) const
{
list<long>prefix_indices;
bool rc = calculate_packed_indices_(des, scope, lv->sig(), prefix_indices);
if (!rc) return false;
const name_component_t&name_tail = path_.back();
ivl_assert(*this, !name_tail.index.empty());
const index_component_t&index_tail = name_tail.index.back();
ivl_assert(*this, index_tail.msb != 0);
ivl_assert(*this, index_tail.lsb == 0);
NetNet*reg = lv->sig();
ivl_assert(*this, reg);
// Bit selects have a single select expression. Evaluate the
// constant value and treat it as a part select with a bit
// width of 1.
NetExpr*mux = elab_and_eval(des, scope, index_tail.msb, -1);
long lsb = 0;
if (mux && mux->expr_type() == IVL_VT_REAL) {
cerr << get_fileline() << ": error: Index expression for "
<< reg->name() << "[" << *mux
<< "] cannot be a real value." << endl;
des->errors += 1;
return false;
}
if (NetEConst*index_con = dynamic_cast<NetEConst*> (mux)) {
// The index has a constant defined value.
if (index_con->value().is_defined()) {
lsb = index_con->value().as_long();
mux = 0;
// The index is undefined and this is a packed array.
} else if (prefix_indices.size()+2 <= reg->packed_dims().size()) {
long loff;
unsigned long lwid;
bool rcl = reg->sb_to_slice(prefix_indices, lsb, loff, lwid);
ivl_assert(*this, rcl);
if (warn_ob_select) {
cerr << get_fileline()
<< ": warning: L-value packed array select of "
<< reg->name();
if (reg->unpacked_dimensions() > 0) cerr << "[]";
cerr << " has an undefined index." << endl;
}
lv->set_part(new NetEConst(verinum(verinum::Vx)), lwid);
return true;
// The index is undefined and this is a bit select.
} else {
if (warn_ob_select) {
cerr << get_fileline()
<< ": warning: L-value bit select of "
<< reg->name();
if (reg->unpacked_dimensions() > 0) cerr << "[]";
cerr << " has an undefined index." << endl;
}
lv->set_part(new NetEConst(verinum(verinum::Vx)), 1);
return true;
}
}
if (debug_elaborate && (reg->type()==NetNet::UNRESOLVED_WIRE)) {
cerr << get_fileline() << ": PEIdent::elaborate_lval_net_bit_: "
<< "Try to assign bits of variable which is also continuously assigned."
<< endl;
}
if (prefix_indices.size()+2 <= reg->packed_dims().size()) {
// Special case: this is a slice of a multi-dimensional
// packed array. For example:
// reg [3:0][7:0] x;
// x[2] = ...
// This shows up as the prefix_indices being too short
// for the packed dimensions of the vector. What we do
// here is convert to a "slice" of the vector.
if (mux == 0) {
long loff;
unsigned long lwid;
bool rcl = reg->sb_to_slice(prefix_indices, lsb, loff, lwid);
ivl_assert(*this, rcl);
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
if (reg->test_part_driven(loff+lwid-1, loff)) {
report_mixed_assignment_conflict_("slice");
des->errors += 1;
return false;
}
}
lv->set_part(new NetEConst(verinum(loff)), lwid);
} else {
unsigned long lwid;
mux = normalize_variable_slice_base(prefix_indices, mux,
reg, lwid);
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
report_mixed_assignment_conflict_("slice");
des->errors += 1;
return false;
}
lv->set_part(mux, lwid);
}
} else if (reg->data_type() == IVL_VT_STRING) {
ivl_assert(*this, reg->type()!=NetNet::UNRESOLVED_WIRE);
// Special case: This is a select of a string
// variable. The target of the assignment is a character
// select of a string. Force the r-value to be an 8bit
// vector and set the "part" to be the character select
// expression. The code generator knows what to do with
// this.
if (debug_elaborate) {
cerr << get_fileline() << ": debug: "
<< "Bit select of string becomes character select." << endl;
}
if (!mux)
mux = new NetEConst(verinum(lsb));
lv->set_part(mux, &netvector_t::atom2s8);
} else if (mux) {
// Non-constant bit mux. Correct the mux for the range
// of the vector, then set the l-value part select
// expression.
if (need_const_idx) {
cerr << get_fileline() << ": error: '" << reg->name()
<< "' bit select must be a constant in this context."
<< endl;
des->errors += 1;
return false;
}
mux = normalize_variable_bit_base(prefix_indices, mux, reg);
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
report_mixed_assignment_conflict_("bit select");
des->errors += 1;
return false;
}
lv->set_part(mux, 1);
} else if (reg->vector_width() == 1 && reg->sb_is_valid(prefix_indices,lsb)) {
// Constant bit mux that happens to select the only bit
// of the l-value. Don't bother with any select at all.
// If there's a continuous assignment, it must be a conflict.
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
report_mixed_assignment_conflict_("bit select");
des->errors += 1;
return false;
}
} else {
// Constant bit select that does something useful.
long loff = reg->sb_to_idx(prefix_indices,lsb);
if (warn_ob_select && (loff < 0 || loff >= (long)reg->vector_width())) {
cerr << get_fileline() << ": warning: bit select "
<< reg->name() << "[" <<lsb<<"]"
<< " is out of range." << endl;
}
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
if (reg->test_part_driven(loff, loff)) {
report_mixed_assignment_conflict_("bit select");
des->errors += 1;
return false;
}
}
lv->set_part(new NetEConst(verinum(loff)), 1);
}
return true;
}
bool PEIdent::elaborate_lval_darray_bit_(Design*des,
NetScope*scope,
NetAssign_*lv,
bool is_force) const
{
const name_component_t&name_tail = path_.back();
ivl_assert(*this, !name_tail.index.empty());
// For now, only support single-dimension dynamic arrays.
ivl_assert(*this, name_tail.index.size() == 1);
if ((lv->sig()->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, lv->sig()->coerced_to_uwire());
report_mixed_assignment_conflict_("darray word");
des->errors += 1;
return false;
}
const index_component_t&index_tail = name_tail.index.back();
ivl_assert(*this, index_tail.msb != 0);
ivl_assert(*this, index_tail.lsb == 0);
// Evaluate the select expression...
NetExpr*mux = elab_and_eval(des, scope, index_tail.msb, -1);
lv->set_word(mux);
return true;
}
bool PEIdent::elaborate_lval_net_part_(Design*des,
NetScope*scope,
NetAssign_*lv,
bool is_force) const
{
if (lv->sig()->data_type() == IVL_VT_STRING) {
cerr << get_fileline() << ": error: Cannot part select assign to a string ('"
<< lv->sig()->name() << "')." << endl;
des->errors += 1;
return false;
}
list<long> prefix_indices;
bool rc = calculate_packed_indices_(des, scope, lv->sig(), prefix_indices);
ivl_assert(*this, rc);
// The range expressions of a part select must be
// constant. The calculate_parts_ function calculates the
// values into msb and lsb.
long msb, lsb;
bool parts_defined_flag;
bool flag = calculate_parts_(des, scope, msb, lsb, parts_defined_flag);
if (!flag) return false;
NetNet*reg = lv->sig();
ivl_assert(*this, reg);
if (! parts_defined_flag) {
if (warn_ob_select) {
cerr << get_fileline()
<< ": warning: L-value part select of "
<< reg->name();
if (reg->unpacked_dimensions() > 0) cerr << "[]";
cerr << " has an undefined index." << endl;
}
// Use a width of two here so we can distinguish between an
// undefined bit or part select.
lv->set_part(new NetEConst(verinum(verinum::Vx)), 2);
return true;
}
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
if (reg->test_part_driven(msb, lsb)) {
report_mixed_assignment_conflict_("part select");
des->errors += 1;
return false;
}
}
const netranges_t&packed = reg->packed_dims();
long loff, moff;
if (prefix_indices.size()+1 < packed.size()) {
// If there are fewer indices then there are packed
// dimensions, then this is a range of slices. Calculate
// it into a big slice.
bool lrc, mrc;
unsigned long lwid, mwid;
lrc = reg->sb_to_slice(prefix_indices, lsb, loff, lwid);
mrc = reg->sb_to_slice(prefix_indices, msb, moff, mwid);
if (!mrc || !lrc) {
cerr << get_fileline() << ": error: ";
cerr << "Part-select [" << msb << ":" << lsb;
cerr << "] exceeds the declared bounds for ";
cerr << reg->name();
if (reg->unpacked_dimensions() > 0) cerr << "[]";
cerr << "." << endl;
des->errors += 1;
return 0;
}
assert(lwid == mwid);
moff += mwid - 1;
} else {
loff = reg->sb_to_idx(prefix_indices,lsb);
moff = reg->sb_to_idx(prefix_indices,msb);
}
if (moff < loff) {
cerr << get_fileline() << ": error: part select "
<< reg->name() << "[" << msb<<":"<<lsb<<"]"
<< " is reversed." << endl;
des->errors += 1;
return false;
}
unsigned long wid = moff - loff + 1;
// Special case: The range winds up selecting the entire
// vector. Treat this as no part select at all.
if (loff == 0 && wid == reg->vector_width()) {
return true;
}
/* If the part select extends beyond the extremes of the
variable, then output a warning. Note that loff is
converted to normalized form so is relative the
variable pins. */
if (warn_ob_select && (loff < 0 || moff >= (long)reg->vector_width())) {
cerr << get_fileline() << ": warning: Part select "
<< reg->name() << "[" << msb<<":"<<lsb<<"]"
<< " is out of range." << endl;
}
lv->set_part(new NetEConst(verinum(loff)), wid);
return true;
}
bool PEIdent::elaborate_lval_net_idx_(Design*des,
NetScope*scope,
NetAssign_*lv,
index_component_t::ctype_t use_sel,
bool need_const_idx,
bool is_force) const
{
if (lv->sig()->data_type() == IVL_VT_STRING) {
cerr << get_fileline() << ": error: Cannot index part select assign to a string ('"
<< lv->sig()->name() << "')." << endl;
des->errors += 1;
return false;
}
list<long>prefix_indices;
bool rc = calculate_packed_indices_(des, scope, lv->sig(), prefix_indices);
ivl_assert(*this, rc);
const name_component_t&name_tail = path_.back();;
ivl_assert(*this, !name_tail.index.empty());
const index_component_t&index_tail = name_tail.index.back();
ivl_assert(*this, index_tail.msb != 0);
ivl_assert(*this, index_tail.lsb != 0);
NetNet*reg = lv->sig();
ivl_assert(*this, reg);
unsigned long wid;
calculate_up_do_width_(des, scope, wid);
NetExpr*base = elab_and_eval(des, scope, index_tail.msb, -1);
if (base && base->expr_type() == IVL_VT_REAL) {
cerr << get_fileline() << ": error: Indexed part select base "
"expression for ";
cerr << lv->sig()->name() << "[" << *base;
if (index_tail.sel == index_component_t::SEL_IDX_UP) {
cerr << "+:";
} else {
cerr << "-:";
}
cerr << wid << "] cannot be a real value." << endl;
des->errors += 1;
return 0;
}
ivl_select_type_t sel_type = IVL_SEL_OTHER;
// Handle the special case that the base is constant. For this
// case we can reduce the expression.
if (NetEConst*base_c = dynamic_cast<NetEConst*> (base)) {
// For the undefined case just let the constant pass and
// we will handle it in the code generator.
if (base_c->value().is_defined()) {
long lsv = base_c->value().as_long();
long rel_base = 0;
// Check whether an unsigned base fits in a 32 bit int.
// This ensures correct results for the vlog95 target, and
// for the vvp target on LLP64 platforms (Microsoft Windows).
if (!base_c->has_sign() && (int32_t)lsv < 0) {
// The base is wrapped around.
delete base;
if (warn_ob_select) {
cerr << get_fileline() << ": warning: " << lv->name();
if (lv->word()) cerr << "[]";
cerr << "[" << (unsigned long)lsv
<< (index_tail.sel == index_component_t::SEL_IDX_UP ? "+:" : "-:")
<< wid << "] is always outside vector." << endl;
}
return false;
}
// Get the signal range.
const netranges_t&packed = reg->packed_dims();
if (prefix_indices.size()+1 < reg->packed_dims().size()) {
// Here we are selecting one or more sub-arrays.
// Make this work by finding the indexed sub-arrays and
// creating a generated slice that spans the whole range.
long loff, moff;
unsigned long lwid, mwid;
bool lrc, mrc;
mrc = reg->sb_to_slice(prefix_indices, lsv, moff, mwid);
if (use_sel == index_component_t::SEL_IDX_UP)
lrc = reg->sb_to_slice(prefix_indices, lsv+wid-1, loff, lwid);
else
lrc = reg->sb_to_slice(prefix_indices, lsv-wid+1, loff, lwid);
if (!mrc || !lrc) {
cerr << get_fileline() << ": error: ";
cerr << "Part-select [" << lsv;
if (index_tail.sel == index_component_t::SEL_IDX_UP) {
cerr << "+:";
} else {
cerr << "-:";
}
cerr << wid << "] exceeds the declared bounds for ";
cerr << reg->name();
if (reg->unpacked_dimensions() > 0) cerr << "[]";
cerr << "." << endl;
des->errors += 1;
return 0;
}
ivl_assert(*this, lwid == mwid);
if (moff > loff) {
rel_base = loff;
wid = moff + mwid - loff;
} else {
rel_base = moff;
wid = loff + lwid - moff;
}
} else {
long offset = 0;
// We want the last range, which is where we work.
const netrange_t&rng = packed.back();
if (((rng.get_msb() < rng.get_lsb()) &&
use_sel == index_component_t::SEL_IDX_UP) ||
((rng.get_msb() > rng.get_lsb()) &&
use_sel == index_component_t::SEL_IDX_DO)) {
offset = -wid + 1;
}
rel_base = reg->sb_to_idx(prefix_indices,lsv) + offset;
}
delete base;
if ((reg->type()==NetNet::UNRESOLVED_WIRE) && !is_force) {
ivl_assert(*this, reg->coerced_to_uwire());
if (reg->test_part_driven(rel_base+wid-1, rel_base)) {
report_mixed_assignment_conflict_("part select");
des->errors += 1;
return false;
}
}
/* If we cover the entire lvalue just skip the select. */
if (rel_base == 0 && wid == reg->vector_width()) return true;
base = new NetEConst(verinum(rel_base));
if (warn_ob_select) {
if (rel_base < 0) {
cerr << get_fileline() << ": warning: " << reg->name();
if (reg->unpacked_dimensions() > 0) cerr << "[]";
cerr << "[" << lsv;
if (use_sel == index_component_t::SEL_IDX_UP) {
cerr << "+:";
} else {
cerr << "-:";
}
cerr << wid << "] is selecting before vector." << endl;
}