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cprop.cc
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cprop.cc
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/*
* Copyright (c) 1998-2024 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 <algorithm>
# include <vector>
# include <cstdlib>
# include "netlist.h"
# include "netmisc.h"
# include "functor.h"
# include "compiler.h"
# include "ivl_assert.h"
using namespace std;
/*
* The cprop function below invokes constant propagation where
* possible. The elaboration generates NetConst objects. I can remove
* these and replace the gates connected to it with simpler ones. I
* may even be able to replace nets with a new constant.
*/
struct cprop_functor : public functor_t {
unsigned count;
virtual void signal(Design*des, NetNet*obj);
virtual void lpm_add_sub(Design*des, NetAddSub*obj);
virtual void lpm_compare(Design*des, const NetCompare*obj);
virtual void lpm_concat(Design*des, NetConcat*obj);
virtual void lpm_ff(Design*des, NetFF*obj);
virtual void lpm_logic(Design*des, NetLogic*obj);
virtual void lpm_mux(Design*des, NetMux*obj);
virtual void lpm_part_select(Design*des, NetPartSelect*obj);
void lpm_compare_eq_(Design*des, const NetCompare*obj);
};
void cprop_functor::signal(Design*, NetNet*)
{
}
void cprop_functor::lpm_add_sub(Design*, NetAddSub*)
{
}
void cprop_functor::lpm_compare(Design*des, const NetCompare*obj)
{
if (obj->pin_AEB().is_linked()) {
assert( ! obj->pin_AGB().is_linked() );
assert( ! obj->pin_AGEB().is_linked() );
assert( ! obj->pin_ALB().is_linked() );
assert( ! obj->pin_ALEB().is_linked() );
assert( ! obj->pin_AGB().is_linked() );
assert( ! obj->pin_ANEB().is_linked() );
lpm_compare_eq_(des, obj);
return;
}
}
void cprop_functor::lpm_compare_eq_(Design*, const NetCompare*)
{
}
void cprop_functor::lpm_concat(Design*des, NetConcat*obj)
{
// Sorry, I don't know how to constant-propagate through
// transparent concatenations.
if (obj->transparent())
return;
verinum result (verinum::Vz, obj->width());
unsigned off = 0;
for (unsigned idx = 1 ; idx < obj->pin_count() ; idx += 1) {
Nexus*nex = obj->pin(idx).nexus();
// If there are non-constant drivers, then give up.
if (! nex->drivers_constant())
return;
verinum tmp = nex->driven_vector();
result.set(off, tmp);
off += tmp.len();
}
if (debug_optimizer)
cerr << obj->get_fileline() << ": cprop_functor::lpm_concat: "
<< "Replace NetConcat with " << result << "." << endl;
NetScope*scope = obj->scope();
// Create a NetConst object to carry the result. Give it the
// same name as the Concat object that we are replacing, and
// link the NetConst to the NetConcat object. Then delete the
// concat that is now replaced.
NetConst*result_obj = new NetConst(scope, obj->name(), result);
result_obj->set_line(*obj);
des->add_node(result_obj);
connect(obj->pin(0), result_obj->pin(0));
// Note that this will leave the const inputs to dangle. They
// will be reaped by other passes of cprop_functor.
delete obj;
count += 1;
}
void cprop_functor::lpm_ff(Design*, NetFF*obj)
{
// Look for and count unlinked FF outputs. Note that if the
// Data and Q pins are connected together, they can be removed
// from the circuit, since it doesn't do anything.
if (connected(obj->pin_Data(), obj->pin_Q())
&& (! obj->pin_Sclr().is_linked())
&& (! obj->pin_Sset().is_linked())
&& (! obj->pin_Aclr().is_linked())
&& (! obj->pin_Aset().is_linked())) {
obj->pin_Data().unlink();
obj->pin_Q().unlink();
delete obj;
}
}
void cprop_functor::lpm_logic(Design*, NetLogic*)
{
}
/*
* This detects the case where the mux selects between a value and
* Vz. In this case, replace the device with a mos with the sel
* input used to enable the output.
*/
void cprop_functor::lpm_mux(Design*des, NetMux*obj)
{
if (obj->size() != 2)
return;
if (obj->sel_width() != 1)
return;
Nexus*sel_nex = obj->pin_Sel().nexus();
/* If the select input is constant, then replace with a BUFZ */
// If the select is not constant, there is nothing we can do.
if (! sel_nex->drivers_constant())
return;
// If the constant select is 'bz or 'bx, then give up.
verinum::V sel_val = sel_nex->driven_value();
if (sel_val == verinum::Vz || sel_val == verinum::Vx)
return;
// The Select input must be a defined constant value, so we
// can replace the device with a BUFZ.
NetBUFZ*tmp = new NetBUFZ(obj->scope(), obj->name(), obj->width(), true);
tmp->set_line(*obj);
if (debug_optimizer)
cerr << obj->get_fileline() << ": debug: "
<< "Replace binary MUX with constant select=" << sel_val
<< " with a BUFZ to the selected input." << endl;
tmp->rise_time(obj->rise_time());
tmp->fall_time(obj->fall_time());
tmp->decay_time(obj->decay_time());
connect(tmp->pin(0), obj->pin_Result());
if (sel_val == verinum::V1)
connect(tmp->pin(1), obj->pin_Data(1));
else
connect(tmp->pin(1), obj->pin_Data(0));
delete obj;
des->add_node(tmp);
count += 1;
}
static bool compare_base(NetPartSelect*a, NetPartSelect*b)
{
return a->base() < b->base();
}
/*
* This optimization searches for Nexa that are driven only by
* NetPartSelect(PV) outputs. These might turn from Verilog input that
* looks like this:
* wire [7:0] foo
* assign foo[7:4] = a;
* assign foo[3:0] = b;
* The idea is to convert the part selects of the above to a single
* concatenation that looks like this:
* assign foo = {a, b};
*/
void cprop_functor::lpm_part_select(Design*des, NetPartSelect*obj)
{
if (obj->dir() != NetPartSelect::PV)
return;
NetScope*scope = obj->scope();
Nexus*nex = obj->pin(1).nexus();
vector<NetPartSelect*> obj_set;
bool output_2_state = false;
for (Link*cur = nex->first_nlink() ; cur ; cur = cur->next_nlink()) {
NetPins*tmp_obj = cur->get_obj();
// Record if we are driving a 2-state net.
NetNet*net_obj = dynamic_cast<NetNet*> (tmp_obj);
if (net_obj && (net_obj->data_type() == IVL_VT_BOOL))
output_2_state = true;
// If this is an input (or passive) then ignore it.
if (cur->get_dir() != Link::OUTPUT)
continue;
// Check to see if this is the output of a
// NetPartSelect::PV. If not, then give up on the blend.
unsigned tmp_pin = cur->get_pin();
NetPartSelect*cur_obj = dynamic_cast<NetPartSelect*> (tmp_obj);
if (cur_obj == 0)
return;
if (cur_obj->dir() != NetPartSelect::PV)
return;
if (tmp_pin != 1)
return;
obj_set.push_back(cur_obj);
}
// When driving a 4-state signal, we only want to create a
// concatenation if we have more than one part select. But
// when driving a 2-state signal, create a concatenation
// even if there's only one part select, which forces the
// undriven bits to zero without needing an explicit cast.
if ((obj_set.size() == 0) || ((obj_set.size() == 1) && !output_2_state))
return;
if (debug_optimizer)
cerr << obj->get_fileline() << ": cprop::lpm_part_select: "
<< "Found " << obj_set.size() << " NetPartSelect(PV) objects."
<< endl;
// Sort by increasing base offset.
sort(obj_set.begin(), obj_set.end(), compare_base);
// Check and make sure there are no overlaps. If there are,
// then give up on this optimization.
for (size_t idx = 1 ; idx < obj_set.size() ; idx += 1) {
unsigned top = obj_set[idx-1]->base() + obj_set[idx-1]->width();
if (top > obj_set[idx]->base()) {
if (debug_optimizer)
cerr << obj->get_fileline() << ": cprop::lpm_part_select: "
<< "Range [" << obj_set[idx-1]->base()
<< " " << top << ") overlaps PV starting at "
<< obj_set[idx]->base() << ". Give up." << endl;
return;
}
}
// Check if the tail runs off the end of the target. If so it
// should be possible to replace it with a bit select to
// shorten the object for the target, but for now just give up.
unsigned sig_width = nex->vector_width();
if (obj_set.back()->base() + obj_set.back()->width() > sig_width) {
if (debug_optimizer)
cerr << obj->get_fileline() << ": cprop::lpm_part_select: "
<< "Range [" << obj_set.back()->base()
<< ":" << (obj_set.back()->base() + obj_set.back()->width() - 1)
<< "] runs off the end of target." << endl;
return;
}
// Figure out how many components we are going to need.
unsigned part_count = 0;
unsigned off = 0;
for (size_t idx = 0 ; idx < obj_set.size() ; idx += 1) {
if (obj_set[idx]->base() > off) {
off = obj_set[idx]->base();
part_count += 1;
}
off += obj_set[idx]->width();
part_count += 1;
}
if (off < sig_width)
part_count += 1;
NetConcat*cncat = new NetConcat(scope, scope->local_symbol(),
sig_width, part_count);
cncat->set_line(*obj);
des->add_node(cncat);
connect(cncat->pin(0), obj->pin(1));
off = 0;
size_t concat_pin = 1;
for (size_t idx = 0 ; idx < obj_set.size() ; idx += 1) {
NetPartSelect*cobj = obj_set[idx];
if (cobj->base() > off) {
NetNet*val = output_2_state
? make_const_0(des, scope, cobj->base()-off)
: make_const_z(des, scope, cobj->base()-off);
connect(cncat->pin(concat_pin), val->pin(0));
concat_pin += 1;
off = cobj->base();
}
connect(cncat->pin(concat_pin), cobj->pin(0));
concat_pin += 1;
off += cobj->width();
}
if (off < sig_width) {
NetNet*val = output_2_state
? make_const_0(des, scope, sig_width-off)
: make_const_z(des, scope, sig_width-off);
connect(cncat->pin(concat_pin), val->pin(0));
concat_pin += 1;
}
ivl_assert(*obj, concat_pin == cncat->pin_count());
for (size_t idx = 0 ; idx < obj_set.size() ; idx += 1) {
delete obj_set[idx];
}
count += 1;
}
/*
* This functor looks to see if the constant is connected to nothing
* but signals. If that is the case, delete the dangling constant and
* the now useless signals. This functor is applied after the regular
* functor to clean up dangling constants that might be left behind.
*/
struct cprop_dc_functor : public functor_t {
virtual void lpm_const(Design*des, NetConst*obj);
};
struct nexus_info_s {
Nexus*nex;
unsigned inp;
unsigned out;
};
void cprop_dc_functor::lpm_const(Design*, NetConst*obj)
{
// 'bz constant values drive high impedance to whatever is
// connected to it. In other words, it is a noop. But that is
// only true if *all* the bits of the vectors.
{ unsigned tmp = 0;
ivl_assert(*obj, obj->pin_count()==1);
for (unsigned idx = 0 ; idx < obj->width() ; idx += 1) {
if (obj->value(idx) == verinum::Vz) {
tmp += 1;
}
}
if (tmp == obj->width()) {
delete obj;
return;
}
}
std::vector<nexus_info_s> nexus_info (obj->pin_count());
for (unsigned idx = 0 ; idx < obj->pin_count() ; idx += 1) {
nexus_info[idx].nex = obj->pin(idx).nexus();
unsigned inputs = 0, outputs = 0;
nexus_info[idx].nex -> count_io(inputs, outputs);
nexus_info[idx].inp = inputs;
nexus_info[idx].out = outputs;
}
// If there are any links that take input, the constant is
// used structurally somewhere.
for (unsigned idx = 0 ; idx < obj->pin_count() ; idx += 1)
if (nexus_info[idx].inp > 0)
return;
// Look for signals that have NetESignal nodes attached to
// them. If I find any, then this constant is used by a
// behavioral expression somewhere.
for (unsigned idx = 0 ; idx < obj->pin_count() ; idx += 1) {
for (Link*clnk = nexus_info[idx].nex->first_nlink()
; clnk ; clnk = clnk->next_nlink()) {
NetPins*cur;
unsigned pin;
clnk->cur_link(cur, pin);
const NetNet*tmp = dynamic_cast<NetNet*>(cur);
if (tmp == 0)
continue;
assert(tmp->scope());
// If the net is a signal name from the source,
// then users will probably want to see it in the
// waveform dump, so unhooking the constant will
// make it look wrong.
if (! tmp->local_flag())
return;
// If the net has an eref, then there is an
// expression somewhere that reads this signal. So
// the constant does get read.
if (tmp->peek_eref() > 0)
return;
// If the net is a port of the root module, then
// the constant may be driving something outside
// the design, so do not eliminate it.
if ((tmp->port_type() != NetNet::NOT_A_PORT)
&& (tmp->scope()->parent() == 0))
return;
}
}
// Done. Found no reason to keep this object, so delete it.
delete obj;
}
void cprop(Design*des)
{
// Continually propagate constants until a scan finds nothing
// to do.
cprop_functor prop;
do {
prop.count = 0;
des->functor(&prop);
if (verbose_flag) {
cout << " ... Iteration detected "
<< prop.count << " optimizations." << endl << flush;
}
} while (prop.count > 0);
if (verbose_flag) {
cout << " ... Look for dangling constants" << endl << flush;
}
cprop_dc_functor dc;
des->functor(&dc);
if (verbose_flag) {
cout << " ... done" << endl << flush;
}
}