yosys/frontends/verific/verific.cc

2375 lines
70 KiB
C++

/*
* yosys -- Yosys Open SYnthesis Suite
*
* Copyright (C) 2012 Clifford Wolf <clifford@clifford.at>
*
* Permission to use, copy, modify, and/or distribute this software for any
* purpose with or without fee is hereby granted, provided that the above
* copyright notice and this permission notice appear in all copies.
*
* THE SOFTWARE IS PROVIDED "AS IS" AND THE AUTHOR DISCLAIMS ALL WARRANTIES
* WITH REGARD TO THIS SOFTWARE INCLUDING ALL IMPLIED WARRANTIES OF
* MERCHANTABILITY AND FITNESS. IN NO EVENT SHALL THE AUTHOR BE LIABLE FOR
* ANY SPECIAL, DIRECT, INDIRECT, OR CONSEQUENTIAL DAMAGES OR ANY DAMAGES
* WHATSOEVER RESULTING FROM LOSS OF USE, DATA OR PROFITS, WHETHER IN AN
* ACTION OF CONTRACT, NEGLIGENCE OR OTHER TORTIOUS ACTION, ARISING OUT OF
* OR IN CONNECTION WITH THE USE OR PERFORMANCE OF THIS SOFTWARE.
*
*/
#include "kernel/yosys.h"
#include "kernel/sigtools.h"
#include "kernel/log.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>
#ifndef _WIN32
# include <unistd.h>
# include <dirent.h>
#endif
#include "frontends/verific/verific.h"
USING_YOSYS_NAMESPACE
#ifdef YOSYS_ENABLE_VERIFIC
#ifdef __clang__
#pragma clang diagnostic push
#pragma clang diagnostic ignored "-Woverloaded-virtual"
#endif
#include "veri_file.h"
#include "vhdl_file.h"
#include "hier_tree.h"
#include "VeriModule.h"
#include "VeriWrite.h"
#include "VhdlUnits.h"
#include "Message.h"
#ifdef __clang__
#pragma clang diagnostic pop
#endif
#ifdef VERIFIC_NAMESPACE
using namespace Verific;
#endif
#endif
#ifdef YOSYS_ENABLE_VERIFIC
YOSYS_NAMESPACE_BEGIN
int verific_verbose;
bool verific_import_pending;
string verific_error_msg;
int verific_sva_fsm_limit;
vector<string> verific_incdirs, verific_libdirs;
void msg_func(msg_type_t msg_type, const char *message_id, linefile_type linefile, const char *msg, va_list args)
{
string message_prefix = stringf("VERIFIC-%s [%s] ",
msg_type == VERIFIC_NONE ? "NONE" :
msg_type == VERIFIC_ERROR ? "ERROR" :
msg_type == VERIFIC_WARNING ? "WARNING" :
msg_type == VERIFIC_IGNORE ? "IGNORE" :
msg_type == VERIFIC_INFO ? "INFO" :
msg_type == VERIFIC_COMMENT ? "COMMENT" :
msg_type == VERIFIC_PROGRAM_ERROR ? "PROGRAM_ERROR" : "UNKNOWN", message_id);
string message = linefile ? stringf("%s:%d: ", LineFile::GetFileName(linefile), LineFile::GetLineNo(linefile)) : "";
message += vstringf(msg, args);
if (msg_type == VERIFIC_ERROR || msg_type == VERIFIC_WARNING || msg_type == VERIFIC_PROGRAM_ERROR)
log_warning_noprefix("%s%s\n", message_prefix.c_str(), message.c_str());
else
log("%s%s\n", message_prefix.c_str(), message.c_str());
if (verific_error_msg.empty() && (msg_type == VERIFIC_ERROR || msg_type == VERIFIC_PROGRAM_ERROR))
verific_error_msg = message;
}
string get_full_netlist_name(Netlist *nl)
{
if (nl->NumOfRefs() == 1) {
Instance *inst = (Instance*)nl->GetReferences()->GetLast();
return get_full_netlist_name(inst->Owner()) + "." + inst->Name();
}
return nl->CellBaseName();
}
// ==================================================================
VerificImporter::VerificImporter(bool mode_gates, bool mode_keep, bool mode_nosva, bool mode_names, bool mode_verific, bool mode_autocover) :
mode_gates(mode_gates), mode_keep(mode_keep), mode_nosva(mode_nosva),
mode_names(mode_names), mode_verific(mode_verific), mode_autocover(mode_autocover)
{
}
RTLIL::SigBit VerificImporter::net_map_at(Net *net)
{
if (net->IsExternalTo(netlist))
log_error("Found external reference to '%s.%s' in netlist '%s', please use -flatten or -extnets.\n",
get_full_netlist_name(net->Owner()).c_str(), net->Name(), get_full_netlist_name(netlist).c_str());
return net_map.at(net);
}
void VerificImporter::import_attributes(dict<RTLIL::IdString, RTLIL::Const> &attributes, DesignObj *obj)
{
MapIter mi;
Att *attr;
if (obj->Linefile())
attributes["\\src"] = stringf("%s:%d", LineFile::GetFileName(obj->Linefile()), LineFile::GetLineNo(obj->Linefile()));
// FIXME: Parse numeric attributes
FOREACH_ATTRIBUTE(obj, mi, attr) {
if (attr->Key()[0] == ' ' || attr->Value() == nullptr)
continue;
attributes[RTLIL::escape_id(attr->Key())] = RTLIL::Const(std::string(attr->Value()));
}
}
RTLIL::SigSpec VerificImporter::operatorInput(Instance *inst)
{
RTLIL::SigSpec sig;
for (int i = int(inst->InputSize())-1; i >= 0; i--)
if (inst->GetInputBit(i))
sig.append(net_map_at(inst->GetInputBit(i)));
else
sig.append(RTLIL::State::Sz);
return sig;
}
RTLIL::SigSpec VerificImporter::operatorInput1(Instance *inst)
{
RTLIL::SigSpec sig;
for (int i = int(inst->Input1Size())-1; i >= 0; i--)
if (inst->GetInput1Bit(i))
sig.append(net_map_at(inst->GetInput1Bit(i)));
else
sig.append(RTLIL::State::Sz);
return sig;
}
RTLIL::SigSpec VerificImporter::operatorInput2(Instance *inst)
{
RTLIL::SigSpec sig;
for (int i = int(inst->Input2Size())-1; i >= 0; i--)
if (inst->GetInput2Bit(i))
sig.append(net_map_at(inst->GetInput2Bit(i)));
else
sig.append(RTLIL::State::Sz);
return sig;
}
RTLIL::SigSpec VerificImporter::operatorInport(Instance *inst, const char *portname)
{
PortBus *portbus = inst->View()->GetPortBus(portname);
if (portbus) {
RTLIL::SigSpec sig;
for (unsigned i = 0; i < portbus->Size(); i++) {
Net *net = inst->GetNet(portbus->ElementAtIndex(i));
if (net) {
if (net->IsGnd())
sig.append(RTLIL::State::S0);
else if (net->IsPwr())
sig.append(RTLIL::State::S1);
else
sig.append(net_map_at(net));
} else
sig.append(RTLIL::State::Sz);
}
return sig;
} else {
Port *port = inst->View()->GetPort(portname);
log_assert(port != NULL);
Net *net = inst->GetNet(port);
return net_map_at(net);
}
}
RTLIL::SigSpec VerificImporter::operatorOutput(Instance *inst, const pool<Net*, hash_ptr_ops> *any_all_nets)
{
RTLIL::SigSpec sig;
RTLIL::Wire *dummy_wire = NULL;
for (int i = int(inst->OutputSize())-1; i >= 0; i--)
if (inst->GetOutputBit(i) && (!any_all_nets || !any_all_nets->count(inst->GetOutputBit(i)))) {
sig.append(net_map_at(inst->GetOutputBit(i)));
dummy_wire = NULL;
} else {
if (dummy_wire == NULL)
dummy_wire = module->addWire(NEW_ID);
else
dummy_wire->width++;
sig.append(RTLIL::SigSpec(dummy_wire, dummy_wire->width - 1));
}
return sig;
}
bool VerificImporter::import_netlist_instance_gates(Instance *inst, RTLIL::IdString inst_name)
{
if (inst->Type() == PRIM_AND) {
module->addAndGate(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_NAND) {
RTLIL::SigSpec tmp = module->addWire(NEW_ID);
module->addAndGate(NEW_ID, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), tmp);
module->addNotGate(inst_name, tmp, net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_OR) {
module->addOrGate(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_NOR) {
RTLIL::SigSpec tmp = module->addWire(NEW_ID);
module->addOrGate(NEW_ID, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), tmp);
module->addNotGate(inst_name, tmp, net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_XOR) {
module->addXorGate(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_XNOR) {
module->addXnorGate(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_BUF) {
auto outnet = inst->GetOutput();
if (!any_all_nets.count(outnet))
module->addBufGate(inst_name, net_map_at(inst->GetInput()), net_map_at(outnet));
return true;
}
if (inst->Type() == PRIM_INV) {
module->addNotGate(inst_name, net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_MUX) {
module->addMuxGate(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetControl()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_TRI) {
module->addMuxGate(inst_name, RTLIL::State::Sz, net_map_at(inst->GetInput()), net_map_at(inst->GetControl()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_FADD)
{
RTLIL::SigSpec a = net_map_at(inst->GetInput1()), b = net_map_at(inst->GetInput2()), c = net_map_at(inst->GetCin());
RTLIL::SigSpec x = inst->GetCout() ? net_map_at(inst->GetCout()) : module->addWire(NEW_ID);
RTLIL::SigSpec y = inst->GetOutput() ? net_map_at(inst->GetOutput()) : module->addWire(NEW_ID);
RTLIL::SigSpec tmp1 = module->addWire(NEW_ID);
RTLIL::SigSpec tmp2 = module->addWire(NEW_ID);
RTLIL::SigSpec tmp3 = module->addWire(NEW_ID);
module->addXorGate(NEW_ID, a, b, tmp1);
module->addXorGate(inst_name, tmp1, c, y);
module->addAndGate(NEW_ID, tmp1, c, tmp2);
module->addAndGate(NEW_ID, a, b, tmp3);
module->addOrGate(NEW_ID, tmp2, tmp3, x);
return true;
}
if (inst->Type() == PRIM_DFFRS)
{
VerificClocking clocking(this, inst->GetClock());
log_assert(clocking.disable_sig == State::S0);
log_assert(clocking.body_net == nullptr);
if (inst->GetSet()->IsGnd() && inst->GetReset()->IsGnd())
clocking.addDff(inst_name, net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
else if (inst->GetSet()->IsGnd())
clocking.addAdff(inst_name, net_map_at(inst->GetReset()), net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()), State::S0);
else if (inst->GetReset()->IsGnd())
clocking.addAdff(inst_name, net_map_at(inst->GetSet()), net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()), State::S1);
else
clocking.addDffsr(inst_name, net_map_at(inst->GetSet()), net_map_at(inst->GetReset()),
net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
return true;
}
return false;
}
bool VerificImporter::import_netlist_instance_cells(Instance *inst, RTLIL::IdString inst_name)
{
if (inst->Type() == PRIM_AND) {
module->addAnd(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_NAND) {
RTLIL::SigSpec tmp = module->addWire(NEW_ID);
module->addAnd(NEW_ID, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), tmp);
module->addNot(inst_name, tmp, net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_OR) {
module->addOr(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_NOR) {
RTLIL::SigSpec tmp = module->addWire(NEW_ID);
module->addOr(NEW_ID, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), tmp);
module->addNot(inst_name, tmp, net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_XOR) {
module->addXor(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_XNOR) {
module->addXnor(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_INV) {
module->addNot(inst_name, net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_MUX) {
module->addMux(inst_name, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), net_map_at(inst->GetControl()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_TRI) {
module->addMux(inst_name, RTLIL::State::Sz, net_map_at(inst->GetInput()), net_map_at(inst->GetControl()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_FADD)
{
RTLIL::SigSpec a_plus_b = module->addWire(NEW_ID, 2);
RTLIL::SigSpec y = inst->GetOutput() ? net_map_at(inst->GetOutput()) : module->addWire(NEW_ID);
if (inst->GetCout())
y.append(net_map_at(inst->GetCout()));
module->addAdd(NEW_ID, net_map_at(inst->GetInput1()), net_map_at(inst->GetInput2()), a_plus_b);
module->addAdd(inst_name, a_plus_b, net_map_at(inst->GetCin()), y);
return true;
}
if (inst->Type() == PRIM_DFFRS)
{
VerificClocking clocking(this, inst->GetClock());
log_assert(clocking.disable_sig == State::S0);
log_assert(clocking.body_net == nullptr);
if (inst->GetSet()->IsGnd() && inst->GetReset()->IsGnd())
clocking.addDff(inst_name, net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
else if (inst->GetSet()->IsGnd())
clocking.addAdff(inst_name, net_map_at(inst->GetReset()), net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()), RTLIL::State::S0);
else if (inst->GetReset()->IsGnd())
clocking.addAdff(inst_name, net_map_at(inst->GetSet()), net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()), RTLIL::State::S1);
else
clocking.addDffsr(inst_name, net_map_at(inst->GetSet()), net_map_at(inst->GetReset()),
net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == PRIM_DLATCHRS)
{
if (inst->GetSet()->IsGnd() && inst->GetReset()->IsGnd())
module->addDlatch(inst_name, net_map_at(inst->GetControl()), net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
else
module->addDlatchsr(inst_name, net_map_at(inst->GetControl()), net_map_at(inst->GetSet()), net_map_at(inst->GetReset()),
net_map_at(inst->GetInput()), net_map_at(inst->GetOutput()));
return true;
}
#define IN operatorInput(inst)
#define IN1 operatorInput1(inst)
#define IN2 operatorInput2(inst)
#define OUT operatorOutput(inst)
#define FILTERED_OUT operatorOutput(inst, &any_all_nets)
#define SIGNED inst->View()->IsSigned()
if (inst->Type() == OPER_ADDER) {
RTLIL::SigSpec out = OUT;
if (inst->GetCout() != NULL)
out.append(net_map_at(inst->GetCout()));
if (inst->GetCin()->IsGnd()) {
module->addAdd(inst_name, IN1, IN2, out, SIGNED);
} else {
RTLIL::SigSpec tmp = module->addWire(NEW_ID, GetSize(out));
module->addAdd(NEW_ID, IN1, IN2, tmp, SIGNED);
module->addAdd(inst_name, tmp, net_map_at(inst->GetCin()), out, false);
}
return true;
}
if (inst->Type() == OPER_MULTIPLIER) {
module->addMul(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_DIVIDER) {
module->addDiv(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_MODULO) {
module->addMod(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_REMAINDER) {
module->addMod(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_SHIFT_LEFT) {
module->addShl(inst_name, IN1, IN2, OUT, false);
return true;
}
if (inst->Type() == OPER_ENABLED_DECODER) {
RTLIL::SigSpec vec;
vec.append(net_map_at(inst->GetControl()));
for (unsigned i = 1; i < inst->OutputSize(); i++) {
vec.append(RTLIL::State::S0);
}
module->addShl(inst_name, vec, IN, OUT, false);
return true;
}
if (inst->Type() == OPER_DECODER) {
RTLIL::SigSpec vec;
vec.append(RTLIL::State::S1);
for (unsigned i = 1; i < inst->OutputSize(); i++) {
vec.append(RTLIL::State::S0);
}
module->addShl(inst_name, vec, IN, OUT, false);
return true;
}
if (inst->Type() == OPER_SHIFT_RIGHT) {
Net *net_cin = inst->GetCin();
Net *net_a_msb = inst->GetInput1Bit(0);
if (net_cin->IsGnd())
module->addShr(inst_name, IN1, IN2, OUT, false);
else if (net_cin == net_a_msb)
module->addSshr(inst_name, IN1, IN2, OUT, true);
else
log_error("Can't import Verific OPER_SHIFT_RIGHT instance %s: carry_in is neither 0 nor msb of left input\n", inst->Name());
return true;
}
if (inst->Type() == OPER_REDUCE_AND) {
module->addReduceAnd(inst_name, IN, net_map_at(inst->GetOutput()), SIGNED);
return true;
}
if (inst->Type() == OPER_REDUCE_OR) {
module->addReduceOr(inst_name, IN, net_map_at(inst->GetOutput()), SIGNED);
return true;
}
if (inst->Type() == OPER_REDUCE_XOR) {
module->addReduceXor(inst_name, IN, net_map_at(inst->GetOutput()), SIGNED);
return true;
}
if (inst->Type() == OPER_REDUCE_XNOR) {
module->addReduceXnor(inst_name, IN, net_map_at(inst->GetOutput()), SIGNED);
return true;
}
if (inst->Type() == OPER_REDUCE_NOR) {
SigSpec t = module->ReduceOr(NEW_ID, IN, SIGNED);
module->addNot(inst_name, t, net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == OPER_LESSTHAN) {
Net *net_cin = inst->GetCin();
if (net_cin->IsGnd())
module->addLt(inst_name, IN1, IN2, net_map_at(inst->GetOutput()), SIGNED);
else if (net_cin->IsPwr())
module->addLe(inst_name, IN1, IN2, net_map_at(inst->GetOutput()), SIGNED);
else
log_error("Can't import Verific OPER_LESSTHAN instance %s: carry_in is neither 0 nor 1\n", inst->Name());
return true;
}
if (inst->Type() == OPER_WIDE_AND) {
module->addAnd(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_WIDE_OR) {
module->addOr(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_WIDE_XOR) {
module->addXor(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_WIDE_XNOR) {
module->addXnor(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_WIDE_BUF) {
module->addPos(inst_name, IN, FILTERED_OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_WIDE_INV) {
module->addNot(inst_name, IN, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_MINUS) {
module->addSub(inst_name, IN1, IN2, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_UMINUS) {
module->addNeg(inst_name, IN, OUT, SIGNED);
return true;
}
if (inst->Type() == OPER_EQUAL) {
module->addEq(inst_name, IN1, IN2, net_map_at(inst->GetOutput()), SIGNED);
return true;
}
if (inst->Type() == OPER_NEQUAL) {
module->addNe(inst_name, IN1, IN2, net_map_at(inst->GetOutput()), SIGNED);
return true;
}
if (inst->Type() == OPER_WIDE_MUX) {
module->addMux(inst_name, IN1, IN2, net_map_at(inst->GetControl()), OUT);
return true;
}
if (inst->Type() == OPER_NTO1MUX) {
module->addShr(inst_name, IN2, IN1, net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == OPER_WIDE_NTO1MUX)
{
SigSpec data = IN2, out = OUT;
int wordsize_bits = ceil_log2(GetSize(out));
int wordsize = 1 << wordsize_bits;
SigSpec sel = {IN1, SigSpec(State::S0, wordsize_bits)};
SigSpec padded_data;
for (int i = 0; i < GetSize(data); i += GetSize(out)) {
SigSpec d = data.extract(i, GetSize(out));
d.extend_u0(wordsize);
padded_data.append(d);
}
module->addShr(inst_name, padded_data, sel, out);
return true;
}
if (inst->Type() == OPER_SELECTOR)
{
module->addPmux(inst_name, State::S0, IN2, IN1, net_map_at(inst->GetOutput()));
return true;
}
if (inst->Type() == OPER_WIDE_SELECTOR)
{
SigSpec out = OUT;
module->addPmux(inst_name, SigSpec(State::S0, GetSize(out)), IN2, IN1, out);
return true;
}
if (inst->Type() == OPER_WIDE_TRI) {
module->addMux(inst_name, RTLIL::SigSpec(RTLIL::State::Sz, inst->OutputSize()), IN, net_map_at(inst->GetControl()), OUT);
return true;
}
if (inst->Type() == OPER_WIDE_DFFRS)
{
VerificClocking clocking(this, inst->GetClock());
log_assert(clocking.disable_sig == State::S0);
log_assert(clocking.body_net == nullptr);
RTLIL::SigSpec sig_set = operatorInport(inst, "set");
RTLIL::SigSpec sig_reset = operatorInport(inst, "reset");
if (sig_set.is_fully_const() && !sig_set.as_bool() && sig_reset.is_fully_const() && !sig_reset.as_bool())
clocking.addDff(inst_name, IN, OUT);
else
clocking.addDffsr(inst_name, sig_set, sig_reset, IN, OUT);
return true;
}
#undef IN
#undef IN1
#undef IN2
#undef OUT
#undef SIGNED
return false;
}
void VerificImporter::merge_past_ffs_clock(pool<RTLIL::Cell*> &candidates, SigBit clock, bool clock_pol)
{
bool keep_running = true;
SigMap sigmap;
while (keep_running)
{
keep_running = false;
dict<SigBit, pool<RTLIL::Cell*>> dbits_db;
SigSpec dbits;
for (auto cell : candidates) {
SigBit bit = sigmap(cell->getPort("\\D"));
dbits_db[bit].insert(cell);
dbits.append(bit);
}
dbits.sort_and_unify();
for (auto chunk : dbits.chunks())
{
SigSpec sig_d = chunk;
if (chunk.wire == nullptr || GetSize(sig_d) == 1)
continue;
SigSpec sig_q = module->addWire(NEW_ID, GetSize(sig_d));
RTLIL::Cell *new_ff = module->addDff(NEW_ID, clock, sig_d, sig_q, clock_pol);
if (verific_verbose)
log(" merging single-bit past_ffs into new %d-bit ff %s.\n", GetSize(sig_d), log_id(new_ff));
for (int i = 0; i < GetSize(sig_d); i++)
for (auto old_ff : dbits_db[sig_d[i]])
{
if (verific_verbose)
log(" replacing old ff %s on bit %d.\n", log_id(old_ff), i);
SigBit old_q = old_ff->getPort("\\Q");
SigBit new_q = sig_q[i];
sigmap.add(old_q, new_q);
module->connect(old_q, new_q);
candidates.erase(old_ff);
module->remove(old_ff);
keep_running = true;
}
}
}
}
void VerificImporter::merge_past_ffs(pool<RTLIL::Cell*> &candidates)
{
dict<pair<SigBit, int>, pool<RTLIL::Cell*>> database;
for (auto cell : candidates)
{
SigBit clock = cell->getPort("\\CLK");
bool clock_pol = cell->getParam("\\CLK_POLARITY").as_bool();
database[make_pair(clock, int(clock_pol))].insert(cell);
}
for (auto it : database)
merge_past_ffs_clock(it.second, it.first.first, it.first.second);
}
void VerificImporter::import_netlist(RTLIL::Design *design, Netlist *nl, std::set<Netlist*> &nl_todo)
{
std::string module_name = nl->IsOperator() ? std::string("$verific$") + nl->Owner()->Name() : RTLIL::escape_id(nl->Owner()->Name());
netlist = nl;
if (design->has(module_name)) {
if (!nl->IsOperator())
log_cmd_error("Re-definition of module `%s'.\n", nl->Owner()->Name());
return;
}
module = new RTLIL::Module;
module->name = module_name;
design->add(module);
if (nl->IsBlackBox()) {
log("Importing blackbox module %s.\n", RTLIL::id2cstr(module->name));
module->set_bool_attribute("\\blackbox");
} else {
log("Importing module %s.\n", RTLIL::id2cstr(module->name));
}
SetIter si;
MapIter mi, mi2;
Port *port;
PortBus *portbus;
Net *net;
NetBus *netbus;
Instance *inst;
PortRef *pr;
FOREACH_PORT_OF_NETLIST(nl, mi, port)
{
if (port->Bus())
continue;
if (verific_verbose)
log(" importing port %s.\n", port->Name());
RTLIL::Wire *wire = module->addWire(RTLIL::escape_id(port->Name()));
import_attributes(wire->attributes, port);
wire->port_id = nl->IndexOf(port) + 1;
if (port->GetDir() == DIR_INOUT || port->GetDir() == DIR_IN)
wire->port_input = true;
if (port->GetDir() == DIR_INOUT || port->GetDir() == DIR_OUT)
wire->port_output = true;
if (port->GetNet()) {
net = port->GetNet();
if (net_map.count(net) == 0)
net_map[net] = wire;
else if (wire->port_input)
module->connect(net_map_at(net), wire);
else
module->connect(wire, net_map_at(net));
}
}
FOREACH_PORTBUS_OF_NETLIST(nl, mi, portbus)
{
if (verific_verbose)
log(" importing portbus %s.\n", portbus->Name());
RTLIL::Wire *wire = module->addWire(RTLIL::escape_id(portbus->Name()), portbus->Size());
wire->start_offset = min(portbus->LeftIndex(), portbus->RightIndex());
import_attributes(wire->attributes, portbus);
if (portbus->GetDir() == DIR_INOUT || portbus->GetDir() == DIR_IN)
wire->port_input = true;
if (portbus->GetDir() == DIR_INOUT || portbus->GetDir() == DIR_OUT)
wire->port_output = true;
for (int i = portbus->LeftIndex();; i += portbus->IsUp() ? +1 : -1) {
if (portbus->ElementAtIndex(i) && portbus->ElementAtIndex(i)->GetNet()) {
net = portbus->ElementAtIndex(i)->GetNet();
RTLIL::SigBit bit(wire, i - wire->start_offset);
if (net_map.count(net) == 0)
net_map[net] = bit;
else if (wire->port_input)
module->connect(net_map_at(net), bit);
else
module->connect(bit, net_map_at(net));
}
if (i == portbus->RightIndex())
break;
}
}
module->fixup_ports();
dict<Net*, char, hash_ptr_ops> init_nets;
pool<Net*, hash_ptr_ops> anyconst_nets, anyseq_nets;
pool<Net*, hash_ptr_ops> allconst_nets, allseq_nets;
any_all_nets.clear();
FOREACH_NET_OF_NETLIST(nl, mi, net)
{
if (net->IsRamNet())
{
RTLIL::Memory *memory = new RTLIL::Memory;
memory->name = RTLIL::escape_id(net->Name());
log_assert(module->count_id(memory->name) == 0);
module->memories[memory->name] = memory;
int number_of_bits = net->Size();
int bits_in_word = number_of_bits;
FOREACH_PORTREF_OF_NET(net, si, pr) {
if (pr->GetInst()->Type() == OPER_READ_PORT) {
bits_in_word = min<int>(bits_in_word, pr->GetInst()->OutputSize());
continue;
}
if (pr->GetInst()->Type() == OPER_WRITE_PORT || pr->GetInst()->Type() == OPER_CLOCKED_WRITE_PORT) {
bits_in_word = min<int>(bits_in_word, pr->GetInst()->Input2Size());
continue;
}
log_error("Verific RamNet %s is connected to unsupported instance type %s (%s).\n",
net->Name(), pr->GetInst()->View()->Owner()->Name(), pr->GetInst()->Name());
}
memory->width = bits_in_word;
memory->size = number_of_bits / bits_in_word;
const char *ascii_initdata = net->GetWideInitialValue();
if (ascii_initdata) {
while (*ascii_initdata != 0 && *ascii_initdata != '\'')
ascii_initdata++;
if (*ascii_initdata == '\'')
ascii_initdata++;
if (*ascii_initdata != 0) {
log_assert(*ascii_initdata == 'b');
ascii_initdata++;
}
for (int word_idx = 0; word_idx < memory->size; word_idx++) {
Const initval = Const(State::Sx, memory->width);
bool initval_valid = false;
for (int bit_idx = memory->width-1; bit_idx >= 0; bit_idx--) {
if (*ascii_initdata == 0)
break;
if (*ascii_initdata == '0' || *ascii_initdata == '1') {
initval[bit_idx] = (*ascii_initdata == '0') ? State::S0 : State::S1;
initval_valid = true;
}
ascii_initdata++;
}
if (initval_valid) {
RTLIL::Cell *cell = module->addCell(NEW_ID, "$meminit");
cell->parameters["\\WORDS"] = 1;
if (net->GetOrigTypeRange()->LeftRangeBound() < net->GetOrigTypeRange()->RightRangeBound())
cell->setPort("\\ADDR", word_idx);
else
cell->setPort("\\ADDR", memory->size - word_idx - 1);
cell->setPort("\\DATA", initval);
cell->parameters["\\MEMID"] = RTLIL::Const(memory->name.str());
cell->parameters["\\ABITS"] = 32;
cell->parameters["\\WIDTH"] = memory->width;
cell->parameters["\\PRIORITY"] = RTLIL::Const(autoidx-1);
}
}
}
continue;
}
if (net->GetInitialValue())
init_nets[net] = net->GetInitialValue();
const char *rand_const_attr = net->GetAttValue(" rand_const");
const char *rand_attr = net->GetAttValue(" rand");
const char *anyconst_attr = net->GetAttValue("anyconst");
const char *anyseq_attr = net->GetAttValue("anyseq");
const char *allconst_attr = net->GetAttValue("allconst");
const char *allseq_attr = net->GetAttValue("allseq");
if (rand_const_attr != nullptr && (!strcmp(rand_const_attr, "1") || !strcmp(rand_const_attr, "'1'"))) {
anyconst_nets.insert(net);
any_all_nets.insert(net);
}
else if (rand_attr != nullptr && (!strcmp(rand_attr, "1") || !strcmp(rand_attr, "'1'"))) {
anyseq_nets.insert(net);
any_all_nets.insert(net);
}
else if (anyconst_attr != nullptr && (!strcmp(anyconst_attr, "1") || !strcmp(anyconst_attr, "'1'"))) {
anyconst_nets.insert(net);
any_all_nets.insert(net);
}
else if (anyseq_attr != nullptr && (!strcmp(anyseq_attr, "1") || !strcmp(anyseq_attr, "'1'"))) {
anyseq_nets.insert(net);
any_all_nets.insert(net);
}
else if (allconst_attr != nullptr && (!strcmp(allconst_attr, "1") || !strcmp(allconst_attr, "'1'"))) {
allconst_nets.insert(net);
any_all_nets.insert(net);
}
else if (allseq_attr != nullptr && (!strcmp(allseq_attr, "1") || !strcmp(allseq_attr, "'1'"))) {
allseq_nets.insert(net);
any_all_nets.insert(net);
}
if (net_map.count(net)) {
if (verific_verbose)
log(" skipping net %s.\n", net->Name());
continue;
}
if (net->Bus())
continue;
RTLIL::IdString wire_name = module->uniquify(mode_names || net->IsUserDeclared() ? RTLIL::escape_id(net->Name()) : NEW_ID);
if (verific_verbose)
log(" importing net %s as %s.\n", net->Name(), log_id(wire_name));
RTLIL::Wire *wire = module->addWire(wire_name);
import_attributes(wire->attributes, net);
net_map[net] = wire;
}
FOREACH_NETBUS_OF_NETLIST(nl, mi, netbus)
{
bool found_new_net = false;
for (int i = netbus->LeftIndex();; i += netbus->IsUp() ? +1 : -1) {
net = netbus->ElementAtIndex(i);
if (net_map.count(net) == 0)
found_new_net = true;
if (i == netbus->RightIndex())
break;
}
if (found_new_net)
{
RTLIL::IdString wire_name = module->uniquify(mode_names || netbus->IsUserDeclared() ? RTLIL::escape_id(netbus->Name()) : NEW_ID);
if (verific_verbose)
log(" importing netbus %s as %s.\n", netbus->Name(), log_id(wire_name));
RTLIL::Wire *wire = module->addWire(wire_name, netbus->Size());
wire->start_offset = min(netbus->LeftIndex(), netbus->RightIndex());
import_attributes(wire->attributes, netbus);
RTLIL::Const initval = Const(State::Sx, GetSize(wire));
bool initval_valid = false;
for (int i = netbus->LeftIndex();; i += netbus->IsUp() ? +1 : -1)
{
if (netbus->ElementAtIndex(i))
{
int bitidx = i - wire->start_offset;
net = netbus->ElementAtIndex(i);
RTLIL::SigBit bit(wire, bitidx);
if (init_nets.count(net)) {
if (init_nets.at(net) == '0')
initval.bits.at(bitidx) = State::S0;
if (init_nets.at(net) == '1')
initval.bits.at(bitidx) = State::S1;
initval_valid = true;
init_nets.erase(net);
}
if (net_map.count(net) == 0)
net_map[net] = bit;
else
module->connect(bit, net_map_at(net));
}
if (i == netbus->RightIndex())
break;
}
if (initval_valid)
wire->attributes["\\init"] = initval;
}
else
{
if (verific_verbose)
log(" skipping netbus %s.\n", netbus->Name());
}
SigSpec anyconst_sig;
SigSpec anyseq_sig;
SigSpec allconst_sig;
SigSpec allseq_sig;
for (int i = netbus->RightIndex();; i += netbus->IsUp() ? -1 : +1) {
net = netbus->ElementAtIndex(i);
if (net != nullptr && anyconst_nets.count(net)) {
anyconst_sig.append(net_map_at(net));
anyconst_nets.erase(net);
}
if (net != nullptr && anyseq_nets.count(net)) {
anyseq_sig.append(net_map_at(net));
anyseq_nets.erase(net);
}
if (net != nullptr && allconst_nets.count(net)) {
allconst_sig.append(net_map_at(net));
allconst_nets.erase(net);
}
if (net != nullptr && allseq_nets.count(net)) {
allseq_sig.append(net_map_at(net));
allseq_nets.erase(net);
}
if (i == netbus->LeftIndex())
break;
}
if (GetSize(anyconst_sig))
module->connect(anyconst_sig, module->Anyconst(NEW_ID, GetSize(anyconst_sig)));
if (GetSize(anyseq_sig))
module->connect(anyseq_sig, module->Anyseq(NEW_ID, GetSize(anyseq_sig)));
if (GetSize(allconst_sig))
module->connect(allconst_sig, module->Allconst(NEW_ID, GetSize(allconst_sig)));
if (GetSize(allseq_sig))
module->connect(allseq_sig, module->Allseq(NEW_ID, GetSize(allseq_sig)));
}
for (auto it : init_nets)
{
Const initval;
SigBit bit = net_map_at(it.first);
log_assert(bit.wire);
if (bit.wire->attributes.count("\\init"))
initval = bit.wire->attributes.at("\\init");
while (GetSize(initval) < GetSize(bit.wire))
initval.bits.push_back(State::Sx);
if (it.second == '0')
initval.bits.at(bit.offset) = State::S0;
if (it.second == '1')
initval.bits.at(bit.offset) = State::S1;
bit.wire->attributes["\\init"] = initval;
}
for (auto net : anyconst_nets)
module->connect(net_map_at(net), module->Anyconst(NEW_ID));
for (auto net : anyseq_nets)
module->connect(net_map_at(net), module->Anyseq(NEW_ID));
pool<Instance*, hash_ptr_ops> sva_asserts;
pool<Instance*, hash_ptr_ops> sva_assumes;
pool<Instance*, hash_ptr_ops> sva_covers;
pool<Instance*, hash_ptr_ops> sva_triggers;
pool<RTLIL::Cell*> past_ffs;
FOREACH_INSTANCE_OF_NETLIST(nl, mi, inst)
{
RTLIL::IdString inst_name = module->uniquify(mode_names || inst->IsUserDeclared() ? RTLIL::escape_id(inst->Name()) : NEW_ID);
if (verific_verbose)
log(" importing cell %s (%s) as %s.\n", inst->Name(), inst->View()->Owner()->Name(), log_id(inst_name));
if (mode_verific)
goto import_verific_cells;
if (inst->Type() == PRIM_PWR) {
module->connect(net_map_at(inst->GetOutput()), RTLIL::State::S1);
continue;
}
if (inst->Type() == PRIM_GND) {
module->connect(net_map_at(inst->GetOutput()), RTLIL::State::S0);
continue;
}
if (inst->Type() == PRIM_BUF) {
auto outnet = inst->GetOutput();
if (!any_all_nets.count(outnet))
module->addBufGate(inst_name, net_map_at(inst->GetInput()), net_map_at(outnet));
continue;
}
if (inst->Type() == PRIM_X) {
module->connect(net_map_at(inst->GetOutput()), RTLIL::State::Sx);
continue;
}
if (inst->Type() == PRIM_Z) {
module->connect(net_map_at(inst->GetOutput()), RTLIL::State::Sz);
continue;
}
if (inst->Type() == OPER_READ_PORT)
{
RTLIL::Memory *memory = module->memories.at(RTLIL::escape_id(inst->GetInput()->Name()));
int numchunks = int(inst->OutputSize()) / memory->width;
int chunksbits = ceil_log2(numchunks);
if ((numchunks * memory->width) != int(inst->OutputSize()) || (numchunks & (numchunks - 1)) != 0)
log_error("Import of asymmetric memories of this type is not supported yet: %s %s\n", inst->Name(), inst->GetInput()->Name());
for (int i = 0; i < numchunks; i++)
{
RTLIL::SigSpec addr = {operatorInput1(inst), RTLIL::Const(i, chunksbits)};
RTLIL::SigSpec data = operatorOutput(inst).extract(i * memory->width, memory->width);
RTLIL::Cell *cell = module->addCell(numchunks == 1 ? inst_name :
RTLIL::IdString(stringf("%s_%d", inst_name.c_str(), i)), "$memrd");
cell->parameters["\\MEMID"] = memory->name.str();
cell->parameters["\\CLK_ENABLE"] = false;
cell->parameters["\\CLK_POLARITY"] = true;
cell->parameters["\\TRANSPARENT"] = false;
cell->parameters["\\ABITS"] = GetSize(addr);
cell->parameters["\\WIDTH"] = GetSize(data);
cell->setPort("\\CLK", RTLIL::State::Sx);
cell->setPort("\\EN", RTLIL::State::Sx);
cell->setPort("\\ADDR", addr);
cell->setPort("\\DATA", data);
}
continue;
}
if (inst->Type() == OPER_WRITE_PORT || inst->Type() == OPER_CLOCKED_WRITE_PORT)
{
RTLIL::Memory *memory = module->memories.at(RTLIL::escape_id(inst->GetOutput()->Name()));
if (memory->width != int(inst->Input2Size()))
log_error("Import of asymmetric memories of this type is not supported yet: %s %s\n", inst->Name(), inst->GetInput()->Name());
RTLIL::SigSpec addr = operatorInput1(inst);
RTLIL::SigSpec data = operatorInput2(inst);
RTLIL::Cell *cell = module->addCell(inst_name, "$memwr");
cell->parameters["\\MEMID"] = memory->name.str();
cell->parameters["\\CLK_ENABLE"] = false;
cell->parameters["\\CLK_POLARITY"] = true;
cell->parameters["\\PRIORITY"] = 0;
cell->parameters["\\ABITS"] = GetSize(addr);
cell->parameters["\\WIDTH"] = GetSize(data);
cell->setPort("\\EN", RTLIL::SigSpec(net_map_at(inst->GetControl())).repeat(GetSize(data)));
cell->setPort("\\CLK", RTLIL::State::S0);
cell->setPort("\\ADDR", addr);
cell->setPort("\\DATA", data);
if (inst->Type() == OPER_CLOCKED_WRITE_PORT) {
cell->parameters["\\CLK_ENABLE"] = true;
cell->setPort("\\CLK", net_map_at(inst->GetClock()));
}
continue;
}
if (!mode_gates) {
if (import_netlist_instance_cells(inst, inst_name))
continue;
if (inst->IsOperator() && !verific_sva_prims.count(inst->Type()))
log_warning("Unsupported Verific operator: %s (fallback to gate level implementation provided by verific)\n", inst->View()->Owner()->Name());
} else {
if (import_netlist_instance_gates(inst, inst_name))
continue;
}
if (inst->Type() == PRIM_SVA_ASSERT || inst->Type() == PRIM_SVA_IMMEDIATE_ASSERT)
sva_asserts.insert(inst);
if (inst->Type() == PRIM_SVA_ASSUME || inst->Type() == PRIM_SVA_IMMEDIATE_ASSUME)
sva_assumes.insert(inst);
if (inst->Type() == PRIM_SVA_COVER || inst->Type() == PRIM_SVA_IMMEDIATE_COVER)
sva_covers.insert(inst);
if (inst->Type() == PRIM_SVA_TRIGGERED)
sva_triggers.insert(inst);
if (inst->Type() == OPER_SVA_STABLE)
{
VerificClocking clocking(this, inst->GetInput2Bit(0));
log_assert(clocking.disable_sig == State::S0);
log_assert(clocking.body_net == nullptr);
log_assert(inst->Input1Size() == inst->OutputSize());
SigSpec sig_d, sig_q, sig_o;
sig_q = module->addWire(NEW_ID, inst->Input1Size());
for (int i = int(inst->Input1Size())-1; i >= 0; i--){
sig_d.append(net_map_at(inst->GetInput1Bit(i)));
sig_o.append(net_map_at(inst->GetOutputBit(i)));
}
if (verific_verbose) {
log(" %sedge FF with D=%s, Q=%s, C=%s.\n", clocking.posedge ? "pos" : "neg",
log_signal(sig_d), log_signal(sig_q), log_signal(clocking.clock_sig));
log(" XNOR with A=%s, B=%s, Y=%s.\n",
log_signal(sig_d), log_signal(sig_q), log_signal(sig_o));
}
clocking.addDff(NEW_ID, sig_d, sig_q);
module->addXnor(NEW_ID, sig_d, sig_q, sig_o);
if (!mode_keep)
continue;
}
if (inst->Type() == PRIM_SVA_STABLE)
{
VerificClocking clocking(this, inst->GetInput2());
log_assert(clocking.disable_sig == State::S0);
log_assert(clocking.body_net == nullptr);
SigSpec sig_d = net_map_at(inst->GetInput1());
SigSpec sig_o = net_map_at(inst->GetOutput());
SigSpec sig_q = module->addWire(NEW_ID);
if (verific_verbose) {
log(" %sedge FF with D=%s, Q=%s, C=%s.\n", clocking.posedge ? "pos" : "neg",
log_signal(sig_d), log_signal(sig_q), log_signal(clocking.clock_sig));
log(" XNOR with A=%s, B=%s, Y=%s.\n",
log_signal(sig_d), log_signal(sig_q), log_signal(sig_o));
}
clocking.addDff(NEW_ID, sig_d, sig_q);
module->addXnor(NEW_ID, sig_d, sig_q, sig_o);
if (!mode_keep)
continue;
}
if (inst->Type() == PRIM_SVA_PAST)
{
VerificClocking clocking(this, inst->GetInput2());
log_assert(clocking.disable_sig == State::S0);
log_assert(clocking.body_net == nullptr);
SigBit sig_d = net_map_at(inst->GetInput1());
SigBit sig_q = net_map_at(inst->GetOutput());
if (verific_verbose)
log(" %sedge FF with D=%s, Q=%s, C=%s.\n", clocking.posedge ? "pos" : "neg",
log_signal(sig_d), log_signal(sig_q), log_signal(clocking.clock_sig));
past_ffs.insert(clocking.addDff(NEW_ID, sig_d, sig_q));
if (!mode_keep)
continue;
}
if ((inst->Type() == PRIM_SVA_ROSE || inst->Type() == PRIM_SVA_FELL))
{
VerificClocking clocking(this, inst->GetInput2());
log_assert(clocking.disable_sig == State::S0);
log_assert(clocking.body_net == nullptr);
SigBit sig_d = net_map_at(inst->GetInput1());
SigBit sig_o = net_map_at(inst->GetOutput());
SigBit sig_q = module->addWire(NEW_ID);
if (verific_verbose)
log(" %sedge FF with D=%s, Q=%s, C=%s.\n", clocking.posedge ? "pos" : "neg",
log_signal(sig_d), log_signal(sig_q), log_signal(clocking.clock_sig));
clocking.addDff(NEW_ID, sig_d, sig_q);
module->addEq(NEW_ID, {sig_q, sig_d}, Const(inst->Type() == PRIM_SVA_ROSE ? 1 : 2, 2), sig_o);
if (!mode_keep)
continue;
}
if (!mode_keep && verific_sva_prims.count(inst->Type())) {
if (verific_verbose)
log(" skipping SVA cell in non k-mode\n");
continue;
}
if (inst->Type() == PRIM_HDL_ASSERTION)
{
SigBit cond = net_map_at(inst->GetInput());
if (verific_verbose)
log(" assert condition %s.\n", log_signal(cond));
const char *assume_attr = nullptr; // inst->GetAttValue("assume");
Cell *cell = nullptr;
if (assume_attr != nullptr && !strcmp(assume_attr, "1"))
cell = module->addAssume(NEW_ID, cond, State::S1);
else
cell = module->addAssert(NEW_ID, cond, State::S1);
import_attributes(cell->attributes, inst);
continue;
}
if (inst->IsPrimitive())
{
if (!mode_keep)
log_error("Unsupported Verific primitive %s of type %s\n", inst->Name(), inst->View()->Owner()->Name());
if (!verific_sva_prims.count(inst->Type()))
log_warning("Unsupported Verific primitive %s of type %s\n", inst->Name(), inst->View()->Owner()->Name());
}
import_verific_cells:
nl_todo.insert(inst->View());
RTLIL::Cell *cell = module->addCell(inst_name, inst->IsOperator() ?
std::string("$verific$") + inst->View()->Owner()->Name() : RTLIL::escape_id(inst->View()->Owner()->Name()));
if (inst->IsPrimitive() && mode_keep)
cell->attributes["\\keep"] = 1;
dict<IdString, vector<SigBit>> cell_port_conns;
if (verific_verbose)
log(" ports in verific db:\n");
FOREACH_PORTREF_OF_INST(inst, mi2, pr) {
if (verific_verbose)
log(" .%s(%s)\n", pr->GetPort()->Name(), pr->GetNet()->Name());
const char *port_name = pr->GetPort()->Name();
int port_offset = 0;
if (pr->GetPort()->Bus()) {
port_name = pr->GetPort()->Bus()->Name();
port_offset = pr->GetPort()->Bus()->IndexOf(pr->GetPort()) -
min(pr->GetPort()->Bus()->LeftIndex(), pr->GetPort()->Bus()->RightIndex());
}
IdString port_name_id = RTLIL::escape_id(port_name);
auto &sigvec = cell_port_conns[port_name_id];
if (GetSize(sigvec) <= port_offset) {
SigSpec zwires = module->addWire(NEW_ID, port_offset+1-GetSize(sigvec));
for (auto bit : zwires)
sigvec.push_back(bit);
}
sigvec[port_offset] = net_map_at(pr->GetNet());
}
if (verific_verbose)
log(" ports in yosys db:\n");
for (auto &it : cell_port_conns) {
if (verific_verbose)
log(" .%s(%s)\n", log_id(it.first), log_signal(it.second));
cell->setPort(it.first, it.second);
}
}
if (!mode_nosva)
{
for (auto inst : sva_asserts) {
if (mode_autocover)
verific_import_sva_cover(this, inst);
verific_import_sva_assert(this, inst);
}
for (auto inst : sva_assumes)
verific_import_sva_assume(this, inst);
for (auto inst : sva_covers)
verific_import_sva_cover(this, inst);
for (auto inst : sva_triggers)
verific_import_sva_trigger(this, inst);
merge_past_ffs(past_ffs);
}
}
// ==================================================================
VerificClocking::VerificClocking(VerificImporter *importer, Net *net, bool sva_at_only)
{
module = importer->module;
log_assert(importer != nullptr);
log_assert(net != nullptr);
Instance *inst = net->Driver();
if (inst != nullptr && inst->Type() == PRIM_SVA_AT)
{
net = inst->GetInput1();
body_net = inst->GetInput2();
inst = net->Driver();
Instance *body_inst = body_net->Driver();
if (body_inst != nullptr && body_inst->Type() == PRIM_SVA_DISABLE_IFF) {
disable_net = body_inst->GetInput1();
disable_sig = importer->net_map_at(disable_net);
body_net = body_inst->GetInput2();
}
}
else
{
if (sva_at_only)
return;
}
// Use while() instead of if() to work around VIPER #13453
while (inst != nullptr && inst->Type() == PRIM_SVA_POSEDGE)
{
net = inst->GetInput();
inst = net->Driver();;
}
if (inst != nullptr && inst->Type() == PRIM_INV)
{
net = inst->GetInput();
inst = net->Driver();;
posedge = false;
}
// Detect clock-enable circuit
do {
if (inst == nullptr || inst->Type() != PRIM_AND)
break;
Net *net_dlatch = inst->GetInput1();
Instance *inst_dlatch = net_dlatch->Driver();
if (inst_dlatch == nullptr || inst_dlatch->Type() != PRIM_DLATCHRS)
break;
if (!inst_dlatch->GetSet()->IsGnd() || !inst_dlatch->GetReset()->IsGnd())
break;
Net *net_enable = inst_dlatch->GetInput();
Net *net_not_clock = inst_dlatch->GetControl();
if (net_enable == nullptr || net_not_clock == nullptr)
break;
Instance *inst_not_clock = net_not_clock->Driver();
if (inst_not_clock == nullptr || inst_not_clock->Type() != PRIM_INV)
break;
Net *net_clock1 = inst_not_clock->GetInput();
Net *net_clock2 = inst->GetInput2();
if (net_clock1 == nullptr || net_clock1 != net_clock2)
break;
enable_net = net_enable;
enable_sig = importer->net_map_at(enable_net);
net = net_clock1;
inst = net->Driver();;
} while (0);
// Detect condition expression
do {
if (body_net == nullptr)
break;
Instance *inst_mux = body_net->Driver();
if (inst_mux == nullptr || inst_mux->Type() != PRIM_MUX)
break;
if (!inst_mux->GetInput1()->IsPwr())
break;
Net *sva_net = inst_mux->GetInput2();
if (!verific_is_sva_net(importer, sva_net))
break;
body_net = sva_net;
cond_net = inst_mux->GetControl();
} while (0);
clock_net = net;
clock_sig = importer->net_map_at(clock_net);
const char *gclk_attr = clock_net->GetAttValue("gclk");
if (gclk_attr != nullptr && (!strcmp(gclk_attr, "1") || !strcmp(gclk_attr, "'1'")))
gclk = true;
}
Cell *VerificClocking::addDff(IdString name, SigSpec sig_d, SigSpec sig_q, Const init_value)
{
log_assert(GetSize(sig_d) == GetSize(sig_q));
if (GetSize(init_value) != 0) {
log_assert(GetSize(sig_q) == GetSize(init_value));
if (sig_q.is_wire()) {
sig_q.as_wire()->attributes["\\init"] = init_value;
} else {
Wire *w = module->addWire(NEW_ID, GetSize(sig_q));
w->attributes["\\init"] = init_value;
module->connect(sig_q, w);
sig_q = w;
}
}
if (enable_sig != State::S1)
sig_d = module->Mux(NEW_ID, sig_q, sig_d, enable_sig);
if (disable_sig != State::S0) {
log_assert(gclk == false);
log_assert(GetSize(sig_q) == GetSize(init_value));
return module->addAdff(name, clock_sig, disable_sig, sig_d, sig_q, init_value, posedge);
}
if (gclk)
return module->addFf(name, sig_d, sig_q);
return module->addDff(name, clock_sig, sig_d, sig_q, posedge);
}
Cell *VerificClocking::addAdff(IdString name, RTLIL::SigSpec sig_arst, SigSpec sig_d, SigSpec sig_q, Const arst_value)
{
log_assert(gclk == false);
log_assert(disable_sig == State::S0);
if (enable_sig != State::S1)
sig_d = module->Mux(NEW_ID, sig_q, sig_d, enable_sig);
return module->addAdff(name, clock_sig, sig_arst, sig_d, sig_q, arst_value, posedge);
}
Cell *VerificClocking::addDffsr(IdString name, RTLIL::SigSpec sig_set, RTLIL::SigSpec sig_clr, SigSpec sig_d, SigSpec sig_q)
{
log_assert(gclk == false);
log_assert(disable_sig == State::S0);
if (enable_sig != State::S1)
sig_d = module->Mux(NEW_ID, sig_q, sig_d, enable_sig);
return module->addDffsr(name, clock_sig, sig_set, sig_clr, sig_d, sig_q, posedge);
}
// ==================================================================
struct VerificExtNets
{
int portname_cnt = 0;
// a map from Net to the same Net one level up in the design hierarchy
std::map<Net*, Net*> net_level_up;
Net *get_net_level_up(Net *net)
{
if (net_level_up.count(net) == 0)
{
Netlist *nl = net->Owner();
// Simply return if Netlist is not unique
if (nl->NumOfRefs() != 1)
return net;
Instance *up_inst = (Instance*)nl->GetReferences()->GetLast();
Netlist *up_nl = up_inst->Owner();
// create new Port
string name = stringf("___extnets_%d", portname_cnt++);
Port *new_port = new Port(name.c_str(), DIR_OUT);
nl->Add(new_port);
net->Connect(new_port);
// create new Net in up Netlist
Net *new_net = new Net(name.c_str());
up_nl->Add(new_net);
up_inst->Connect(new_port, new_net);
net_level_up[net] = new_net;
}
return net_level_up.at(net);
}
void run(Netlist *nl)
{
MapIter mi, mi2;
Instance *inst;
PortRef *pr;
vector<tuple<Instance*, Port*, Net*>> todo_connect;
FOREACH_INSTANCE_OF_NETLIST(nl, mi, inst)
run(inst->View());
FOREACH_INSTANCE_OF_NETLIST(nl, mi, inst)
FOREACH_PORTREF_OF_INST(inst, mi2, pr)
{
Port *port = pr->GetPort();
Net *net = pr->GetNet();
if (!net->IsExternalTo(nl))
continue;
if (verific_verbose)
log("Fixing external net reference on port %s.%s.%s:\n", get_full_netlist_name(nl).c_str(), inst->Name(), port->Name());
while (net->IsExternalTo(nl))
{
Net *newnet = get_net_level_up(net);
if (newnet == net) break;
if (verific_verbose)
log(" external net: %s.%s\n", get_full_netlist_name(net->Owner()).c_str(), net->Name());
net = newnet;
}
if (verific_verbose)
log(" final net: %s.%s%s\n", get_full_netlist_name(net->Owner()).c_str(), net->Name(), net->IsExternalTo(nl) ? " (external)" : "");
todo_connect.push_back(tuple<Instance*, Port*, Net*>(inst, port, net));
}
for (auto it : todo_connect) {
get<0>(it)->Disconnect(get<1>(it));
get<0>(it)->Connect(get<1>(it), get<2>(it));
}
}
};
void verific_import(Design *design, std::string top)
{
verific_sva_fsm_limit = 16;
std::set<Netlist*> nl_todo, nl_done;
{
VhdlLibrary *vhdl_lib = vhdl_file::GetLibrary("work", 1);
VeriLibrary *veri_lib = veri_file::GetLibrary("work", 1);
Array veri_libs, vhdl_libs;
if (vhdl_lib) vhdl_libs.InsertLast(vhdl_lib);
if (veri_lib) veri_libs.InsertLast(veri_lib);
Array *netlists = hier_tree::ElaborateAll(&veri_libs, &vhdl_libs);
Netlist *nl;
int i;
FOREACH_ARRAY_ITEM(netlists, i, nl) {
if (top.empty() || nl->Owner()->Name() == top)
nl_todo.insert(nl);
}
delete netlists;
}
if (!verific_error_msg.empty())
log_error("%s\n", verific_error_msg.c_str());
VerificExtNets worker;
for (auto nl : nl_todo)
worker.run(nl);
while (!nl_todo.empty()) {
Netlist *nl = *nl_todo.begin();
if (nl_done.count(nl) == 0) {
VerificImporter importer(false, false, false, false, false, false);
importer.import_netlist(design, nl, nl_todo);
}
nl_todo.erase(nl);
nl_done.insert(nl);
}
veri_file::Reset();
vhdl_file::Reset();
Libset::Reset();
verific_incdirs.clear();
verific_libdirs.clear();
verific_import_pending = false;
if (!verific_error_msg.empty())
log_error("%s\n", verific_error_msg.c_str());
}
YOSYS_NAMESPACE_END
#endif /* YOSYS_ENABLE_VERIFIC */
PRIVATE_NAMESPACE_BEGIN
#ifdef YOSYS_ENABLE_VERIFIC
bool check_noverific_env()
{
const char *e = getenv("YOSYS_NOVERIFIC");
if (e == nullptr)
return false;
if (atoi(e) == 0)
return false;
return true;
}
#endif
struct VerificPass : public Pass {
VerificPass() : Pass("verific", "load Verilog and VHDL designs using Verific") { }
void help() YS_OVERRIDE
{
// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
log("\n");
log(" verific {-vlog95|-vlog2k|-sv2005|-sv2009|-sv2012|-sv} <verilog-file>..\n");
log("\n");
log("Load the specified Verilog/SystemVerilog files into Verific.\n");
log("\n");
log("All files specified in one call to this command are one compilation unit.\n");
log("Files passed to different calls to this command are treated as belonging to\n");
log("different compilation units.\n");
log("\n");
log("Additional -D<macro>[=<value>] options may be added after the option indicating\n");
log("the language version (and before file names) to set additional verilog defines.\n");
log("The macros SYNTHESIS and VERIFIC are defined implicitly.\n");
log("\n");
log("\n");
log(" verific -formal <verilog-file>..\n");
log("\n");
log("Like -sv, but define FORMAL instead of SYNTHESIS.\n");
log("\n");
log("\n");
log(" verific {-vhdl87|-vhdl93|-vhdl2k|-vhdl2008|-vhdl} <vhdl-file>..\n");
log("\n");
log("Load the specified VHDL files into Verific.\n");
log("\n");
log("\n");
log(" verific -work <libname> {-sv|-vhdl|...} <hdl-file>\n");
log("\n");
log("Load the specified Verilog/SystemVerilog/VHDL file into the specified library.\n");
log("(default library when -work is not present: \"work\")\n");
log("\n");
log("\n");
log(" verific -vlog-incdir <directory>..\n");
log("\n");
log("Add Verilog include directories.\n");
log("\n");
log("\n");
log(" verific -vlog-libdir <directory>..\n");
log("\n");
log("Add Verilog library directories. Verific will search in this directories to\n");
log("find undefined modules.\n");
log("\n");
log("\n");
log(" verific -vlog-define <macro>[=<value>]..\n");
log("\n");
log("Add Verilog defines.\n");
log("\n");
log("\n");
log(" verific -vlog-undef <macro>..\n");
log("\n");
log("Remove Verilog defines previously set with -vlog-define.\n");
log("\n");
log("\n");
log(" verific -set-error <msg_id>..\n");
log(" verific -set-warning <msg_id>..\n");
log(" verific -set-info <msg_id>..\n");
log(" verific -set-ignore <msg_id>..\n");
log("\n");
log("Set message severity. <msg_id> is the string in square brackets when a message\n");
log("is printed, such as VERI-1209.\n");
log("\n");
log("\n");
log(" verific -import [options] <top-module>..\n");
log("\n");
log("Elaborate the design for the specified top modules, import to Yosys and\n");
log("reset the internal state of Verific.\n");
log("\n");
log("Import options:\n");
log("\n");
log(" -all\n");
log(" Elaborate all modules, not just the hierarchy below the given top\n");
log(" modules. With this option the list of modules to import is optional.\n");
log("\n");
log(" -gates\n");
log(" Create a gate-level netlist.\n");
log("\n");
log(" -flatten\n");
log(" Flatten the design in Verific before importing.\n");
log("\n");
log(" -extnets\n");
log(" Resolve references to external nets by adding module ports as needed.\n");
log("\n");
log(" -autocover\n");
log(" Generate automatic cover statements for all asserts\n");
log("\n");
log(" -v, -vv\n");
log(" Verbose log messages. (-vv is even more verbose than -v.)\n");
log("\n");
log("The following additional import options are useful for debugging the Verific\n");
log("bindings (for Yosys and/or Verific developers):\n");
log("\n");
log(" -k\n");
log(" Keep going after an unsupported verific primitive is found. The\n");
log(" unsupported primitive is added as blockbox module to the design.\n");
log(" This will also add all SVA related cells to the design parallel to\n");
log(" the checker logic inferred by it.\n");
log("\n");
log(" -V\n");
log(" Import Verific netlist as-is without translating to Yosys cell types. \n");
log("\n");
log(" -nosva\n");
log(" Ignore SVA properties, do not infer checker logic.\n");
log("\n");
log(" -L <int>\n");
log(" Maximum number of ctrl bits for SVA checker FSMs (default=16).\n");
log("\n");
log(" -n\n");
log(" Keep all Verific names on instances and nets. By default only\n");
log(" user-declared names are preserved.\n");
log("\n");
log(" -d <dump_file>\n");
log(" Dump the Verific netlist as a verilog file.\n");
log("\n");
log("Visit http://verific.com/ for more information on Verific.\n");
log("\n");
}
#ifdef YOSYS_ENABLE_VERIFIC
void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
{
static bool set_verific_global_flags = true;
if (check_noverific_env())
log_cmd_error("This version of Yosys is built without Verific support.\n");
log_header(design, "Executing VERIFIC (loading SystemVerilog and VHDL designs using Verific).\n");
if (set_verific_global_flags)
{
Message::SetConsoleOutput(0);
Message::RegisterCallBackMsg(msg_func);
RuntimeFlags::SetVar("db_preserve_user_nets", 1);
RuntimeFlags::SetVar("db_allow_external_nets", 1);
RuntimeFlags::SetVar("vhdl_ignore_assertion_statements", 0);
RuntimeFlags::SetVar("veri_extract_dualport_rams", 0);
RuntimeFlags::SetVar("veri_extract_multiport_rams", 1);
RuntimeFlags::SetVar("db_infer_wide_operators", 1);
// Workaround for VIPER #13851
RuntimeFlags::SetVar("veri_create_name_for_unnamed_gen_block", 1);
// WARNING: instantiating unknown module 'XYZ' (VERI-1063)
Message::SetMessageType("VERI-1063", VERIFIC_ERROR);
set_verific_global_flags = false;
}
verific_verbose = 0;
verific_sva_fsm_limit = 16;
const char *release_str = Message::ReleaseString();
time_t release_time = Message::ReleaseDate();
char *release_tmstr = ctime(&release_time);
if (release_str == nullptr)
release_str = "(no release string)";
for (char *p = release_tmstr; *p; p++)
if (*p == '\n') *p = 0;
log("Built with Verific %s, released at %s.\n", release_str, release_tmstr);
int argidx = 1;
std::string work = "work";
if (GetSize(args) > argidx && (args[argidx] == "-set-error" || args[argidx] == "-set-warning" ||
args[argidx] == "-set-info" || args[argidx] == "-set-ignore"))
{
msg_type_t new_type;
if (args[argidx] == "-set-error")
new_type = VERIFIC_ERROR;
else if (args[argidx] == "-set-warning")
new_type = VERIFIC_WARNING;
else if (args[argidx] == "-set-info")
new_type = VERIFIC_INFO;
else if (args[argidx] == "-set-ignore")
new_type = VERIFIC_IGNORE;
else
log_abort();
for (argidx++; argidx < GetSize(args); argidx++)
Message::SetMessageType(args[argidx].c_str(), new_type);
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-vlog-incdir") {
for (argidx++; argidx < GetSize(args); argidx++)
verific_incdirs.push_back(args[argidx]);
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-vlog-libdir") {
for (argidx++; argidx < GetSize(args); argidx++)
verific_libdirs.push_back(args[argidx]);
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-vlog-define") {
for (argidx++; argidx < GetSize(args); argidx++) {
string name = args[argidx];
size_t equal = name.find('=');
if (equal != std::string::npos) {
string value = name.substr(equal+1);
name = name.substr(0, equal);
veri_file::DefineCmdLineMacro(name.c_str(), value.c_str());
} else {
veri_file::DefineCmdLineMacro(name.c_str());
}
}
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-vlog-undef") {
for (argidx++; argidx < GetSize(args); argidx++) {
string name = args[argidx];
veri_file::UndefineMacro(name.c_str());
}
goto check_error;
}
for (; argidx < GetSize(args); argidx++)
{
if (args[argidx] == "-work" && argidx+1 < GetSize(args)) {
work = args[++argidx];
continue;
}
break;
}
if (GetSize(args) > argidx && (args[argidx] == "-vlog95" || args[argidx] == "-vlog2k" || args[argidx] == "-sv2005" ||
args[argidx] == "-sv2009" || args[argidx] == "-sv2012" || args[argidx] == "-sv" || args[argidx] == "-formal"))
{
Array file_names;
unsigned verilog_mode;
if (args[argidx] == "-vlog95")
verilog_mode = veri_file::VERILOG_95;
else if (args[argidx] == "-vlog2k")
verilog_mode = veri_file::VERILOG_2K;
else if (args[argidx] == "-sv2005")
verilog_mode = veri_file::SYSTEM_VERILOG_2005;
else if (args[argidx] == "-sv2009")
verilog_mode = veri_file::SYSTEM_VERILOG_2009;
else if (args[argidx] == "-sv2012" || args[argidx] == "-sv" || args[argidx] == "-formal")
verilog_mode = veri_file::SYSTEM_VERILOG;
else
log_abort();
veri_file::DefineMacro("VERIFIC");
veri_file::DefineMacro(args[argidx] == "-formal" ? "FORMAL" : "SYNTHESIS");
for (argidx++; argidx < GetSize(args) && GetSize(args[argidx]) >= 2 && args[argidx].substr(0, 2) == "-D"; argidx++) {
std::string name = args[argidx].substr(2);
if (args[argidx] == "-D") {
if (++argidx >= GetSize(args))
break;
name = args[argidx];
}
size_t equal = name.find('=');
if (equal != std::string::npos) {
string value = name.substr(equal+1);
name = name.substr(0, equal);
veri_file::DefineMacro(name.c_str(), value.c_str());
} else {
veri_file::DefineMacro(name.c_str());
}
}
for (auto &dir : verific_incdirs)
veri_file::AddIncludeDir(dir.c_str());
for (auto &dir : verific_libdirs)
veri_file::AddYDir(dir.c_str());
while (argidx < GetSize(args))
file_names.Insert(args[argidx++].c_str());
if (!veri_file::AnalyzeMultipleFiles(&file_names, verilog_mode, work.c_str(), veri_file::MFCU))
log_cmd_error("Reading Verilog/SystemVerilog sources failed.\n");
verific_import_pending = true;
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-vhdl87") {
vhdl_file::SetDefaultLibraryPath((proc_share_dirname() + "verific/vhdl_vdbs_1987").c_str());
for (argidx++; argidx < GetSize(args); argidx++)
if (!vhdl_file::Analyze(args[argidx].c_str(), work.c_str(), vhdl_file::VHDL_87))
log_cmd_error("Reading `%s' in VHDL_87 mode failed.\n", args[argidx].c_str());
verific_import_pending = true;
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-vhdl93") {
vhdl_file::SetDefaultLibraryPath((proc_share_dirname() + "verific/vhdl_vdbs_1993").c_str());
for (argidx++; argidx < GetSize(args); argidx++)
if (!vhdl_file::Analyze(args[argidx].c_str(), work.c_str(), vhdl_file::VHDL_93))
log_cmd_error("Reading `%s' in VHDL_93 mode failed.\n", args[argidx].c_str());
verific_import_pending = true;
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-vhdl2k") {
vhdl_file::SetDefaultLibraryPath((proc_share_dirname() + "verific/vhdl_vdbs_1993").c_str());
for (argidx++; argidx < GetSize(args); argidx++)
if (!vhdl_file::Analyze(args[argidx].c_str(), work.c_str(), vhdl_file::VHDL_2K))
log_cmd_error("Reading `%s' in VHDL_2K mode failed.\n", args[argidx].c_str());
verific_import_pending = true;
goto check_error;
}
if (GetSize(args) > argidx && (args[argidx] == "-vhdl2008" || args[argidx] == "-vhdl")) {
vhdl_file::SetDefaultLibraryPath((proc_share_dirname() + "verific/vhdl_vdbs_2008").c_str());
for (argidx++; argidx < GetSize(args); argidx++)
if (!vhdl_file::Analyze(args[argidx].c_str(), work.c_str(), vhdl_file::VHDL_2008))
log_cmd_error("Reading `%s' in VHDL_2008 mode failed.\n", args[argidx].c_str());
verific_import_pending = true;
goto check_error;
}
if (GetSize(args) > argidx && args[argidx] == "-import")
{
std::set<Netlist*> nl_todo, nl_done;
bool mode_all = false, mode_gates = false, mode_keep = false;
bool mode_nosva = false, mode_names = false, mode_verific = false;
bool mode_autocover = false;
bool flatten = false, extnets = false;
string dumpfile;
for (argidx++; argidx < GetSize(args); argidx++) {
if (args[argidx] == "-all") {
mode_all = true;
continue;
}
if (args[argidx] == "-gates") {
mode_gates = true;
continue;
}
if (args[argidx] == "-flatten") {
flatten = true;
continue;
}
if (args[argidx] == "-extnets") {
extnets = true;
continue;
}
if (args[argidx] == "-k") {
mode_keep = true;
continue;
}
if (args[argidx] == "-nosva") {
mode_nosva = true;
continue;
}
if (args[argidx] == "-L" && argidx+1 < GetSize(args)) {
verific_sva_fsm_limit = atoi(args[++argidx].c_str());
continue;
}
if (args[argidx] == "-n") {
mode_names = true;
continue;
}
if (args[argidx] == "-autocover") {
mode_autocover = true;
continue;
}
if (args[argidx] == "-V") {
mode_verific = true;
continue;
}
if (args[argidx] == "-v") {
verific_verbose = 1;
continue;
}
if (args[argidx] == "-vv") {
verific_verbose = 2;
continue;
}
if (args[argidx] == "-d" && argidx+1 < GetSize(args)) {
dumpfile = args[++argidx];
continue;
}
break;
}
if (argidx > GetSize(args) && args[argidx].substr(0, 1) == "-")
cmd_error(args, argidx, "unknown option");
if (mode_all)
{
#if 0
log("Running veri_file::ElaborateAll().\n");
if (!veri_file::ElaborateAll())
log_cmd_error("Elaboration of Verilog modules failed.\n");
log("Running vhdl_file::ElaborateAll().\n");
if (!vhdl_file::ElaborateAll())
log_cmd_error("Elaboration of VHDL modules failed.\n");
Library *lib = Netlist::PresentDesign()->Owner()->Owner();
if (argidx == GetSize(args))
{
MapIter iter;
char *iter_name;
Verific::Cell *iter_cell;
FOREACH_MAP_ITEM(lib->GetCells(), iter, &iter_name, &iter_cell) {
if (*iter_name != '$')
nl_todo.insert(iter_cell->GetFirstNetlist());
}
}
else
{
for (; argidx < GetSize(args); argidx++)
{
Verific::Cell *cell = lib->GetCell(args[argidx].c_str());
if (cell == nullptr)
log_cmd_error("Module not found: %s\n", args[argidx].c_str());
nl_todo.insert(cell->GetFirstNetlist());
cell->GetFirstNetlist()->SetPresentDesign();
}
}
#else
log("Running hier_tree::ElaborateAll().\n");
VhdlLibrary *vhdl_lib = vhdl_file::GetLibrary(work.c_str(), 1);
VeriLibrary *veri_lib = veri_file::GetLibrary(work.c_str(), 1);
Array veri_libs, vhdl_libs;
if (vhdl_lib) vhdl_libs.InsertLast(vhdl_lib);
if (veri_lib) veri_libs.InsertLast(veri_lib);
Array *netlists = hier_tree::ElaborateAll(&veri_libs, &vhdl_libs);
Netlist *nl;
int i;
FOREACH_ARRAY_ITEM(netlists, i, nl)
nl_todo.insert(nl);
delete netlists;
#endif
}
else
{
if (argidx == GetSize(args))
log_cmd_error("No top module specified.\n");
#if 0
for (; argidx < GetSize(args); argidx++) {
if (veri_file::GetModule(args[argidx].c_str())) {
log("Running veri_file::Elaborate(\"%s\").\n", args[argidx].c_str());
if (!veri_file::Elaborate(args[argidx].c_str()))
log_cmd_error("Elaboration of top module `%s' failed.\n", args[argidx].c_str());
nl_todo.insert(Netlist::PresentDesign());
} else {
log("Running vhdl_file::Elaborate(\"%s\").\n", args[argidx].c_str());
if (!vhdl_file::Elaborate(args[argidx].c_str()))
log_cmd_error("Elaboration of top module `%s' failed.\n", args[argidx].c_str());
nl_todo.insert(Netlist::PresentDesign());
}
}
#else
Array veri_modules, vhdl_units;
for (; argidx < GetSize(args); argidx++)
{
const char *name = args[argidx].c_str();
VeriModule *veri_module = veri_file::GetModule(name);
if (veri_module) {
log("Adding Verilog module '%s' to elaboration queue.\n", name);
veri_modules.InsertLast(veri_module);
continue;
}
VhdlLibrary *vhdl_lib = vhdl_file::GetLibrary(work.c_str(), 1);
VhdlDesignUnit *vhdl_unit = vhdl_lib->GetPrimUnit(name);
if (vhdl_unit) {
log("Adding VHDL unit '%s' to elaboration queue.\n", name);
vhdl_units.InsertLast(vhdl_unit);
continue;
}
log_error("Can't find module/unit '%s'.\n", name);
}
log("Running hier_tree::Elaborate().\n");
Array *netlists = hier_tree::Elaborate(&veri_modules, &vhdl_units);
Netlist *nl;
int i;
FOREACH_ARRAY_ITEM(netlists, i, nl)
nl_todo.insert(nl);
delete netlists;
#endif
}
if (!verific_error_msg.empty())
goto check_error;
if (flatten) {
for (auto nl : nl_todo)
nl->Flatten();
}
if (extnets) {
VerificExtNets worker;
for (auto nl : nl_todo)
worker.run(nl);
}
if (!dumpfile.empty()) {
VeriWrite veri_writer;
veri_writer.WriteFile(dumpfile.c_str(), Netlist::PresentDesign());
}
while (!nl_todo.empty()) {
Netlist *nl = *nl_todo.begin();
if (nl_done.count(nl) == 0) {
VerificImporter importer(mode_gates, mode_keep, mode_nosva,
mode_names, mode_verific, mode_autocover);
importer.import_netlist(design, nl, nl_todo);
}
nl_todo.erase(nl);
nl_done.insert(nl);
}
veri_file::Reset();
vhdl_file::Reset();
Libset::Reset();
verific_incdirs.clear();
verific_libdirs.clear();
verific_import_pending = false;
goto check_error;
}
log_cmd_error("Missing or unsupported mode parameter.\n");
check_error:
if (!verific_error_msg.empty())
log_error("%s\n", verific_error_msg.c_str());
}
#else /* YOSYS_ENABLE_VERIFIC */
void execute(std::vector<std::string>, RTLIL::Design *) YS_OVERRIDE {
log_cmd_error("This version of Yosys is built without Verific support.\n");
}
#endif
} VerificPass;
struct ReadPass : public Pass {
ReadPass() : Pass("read", "load HDL designs") { }
void help() YS_OVERRIDE
{
// |---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|---v---|
log("\n");
log(" read {-vlog95|-vlog2k|-sv2005|-sv2009|-sv2012|-sv|-formal} <verilog-file>..\n");
log("\n");
log("Load the specified Verilog/SystemVerilog files. (Full SystemVerilog support\n");
log("is only available via Verific.)\n");
log("\n");
log("Additional -D<macro>[=<value>] options may be added after the option indicating\n");
log("the language version (and before file names) to set additional verilog defines.\n");
log("\n");
log("\n");
log(" read {-vhdl87|-vhdl93|-vhdl2k|-vhdl2008|-vhdl} <vhdl-file>..\n");
log("\n");
log("Load the specified VHDL files. (Requires Verific.)\n");
log("\n");
log("\n");
log(" read -define <macro>[=<value>]..\n");
log("\n");
log("Set global Verilog/SystemVerilog defines.\n");
log("\n");
log("\n");
log(" read -undef <macro>..\n");
log("\n");
log("Unset global Verilog/SystemVerilog defines.\n");
log("\n");
log("\n");
log(" read -incdir <directory>\n");
log("\n");
log("Add directory to global Verilog/SystemVerilog include directories.\n");
log("\n");
}
void execute(std::vector<std::string> args, RTLIL::Design *design) YS_OVERRIDE
{
if (args.size() < 2)
log_cmd_error("Missing mode parameter.\n");
if (args.size() < 3)
log_cmd_error("Missing file name parameter.\n");
#ifdef YOSYS_ENABLE_VERIFIC
bool use_verific = !check_noverific_env();
#else
bool use_verific = false;
#endif
if (args[1] == "-vlog95" || args[1] == "-vlog2k") {
if (use_verific) {
args[0] = "verific";
} else {
args[0] = "read_verilog";
args.erase(args.begin()+1, args.begin()+2);
}
Pass::call(design, args);
return;
}
if (args[1] == "-sv2005" || args[1] == "-sv2009" || args[1] == "-sv2012" || args[1] == "-sv" || args[1] == "-formal") {
if (use_verific) {
args[0] = "verific";
} else {
args[0] = "read_verilog";
if (args[1] == "-formal")
args.insert(args.begin()+1, std::string());
args[1] = "-sv";
}
Pass::call(design, args);
return;
}
if (args[1] == "-vhdl87" || args[1] == "-vhdl93" || args[1] == "-vhdl2k" || args[1] == "-vhdl2008" || args[1] == "-vhdl") {
if (use_verific) {
args[0] = "verific";
Pass::call(design, args);
} else {
log_cmd_error("This version of Yosys is built without Verific support.\n");
}
return;
}
if (args[1] == "-define") {
if (use_verific) {
args[0] = "verific";
args[1] = "-vlog-define";
Pass::call(design, args);
}
args[0] = "verilog_defines";
args.erase(args.begin()+1, args.begin()+2);
for (int i = 1; i < GetSize(args); i++)
args[i] = "-D" + args[i];
Pass::call(design, args);
return;
}
if (args[1] == "-undef") {
if (use_verific) {
args[0] = "verific";
args[1] = "-vlog-undef";
Pass::call(design, args);
}
args[0] = "verilog_defines";
args.erase(args.begin()+1, args.begin()+2);
for (int i = 1; i < GetSize(args); i++)
args[i] = "-U" + args[i];
Pass::call(design, args);
return;
}
if (args[1] == "-incdir") {
if (use_verific) {
args[0] = "verific";
args[1] = "-vlog-incdir";
Pass::call(design, args);
}
args[0] = "verilog_defaults";
args[1] = "-add";
for (int i = 2; i < GetSize(args); i++)
args[i] = "-I" + args[i];
Pass::call(design, args);
return;
}
log_cmd_error("Missing or unsupported mode parameter.\n");
}
} ReadPass;
PRIVATE_NAMESPACE_END