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/*
  Copyright (C) 2016  Tristan Gingold <tgingold@free.fr>

  This program is free software: you can redistribute it and/or modify
  it under the terms of the GNU General Public License as published by
  the Free Software Foundation, either version 3 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, see <https://www.gnu.org/licenses/>.

*/

#include "kernel/yosys.h"
#include "kernel/sigtools.h"
#include "kernel/log.h"
#include <stdlib.h>
#include <stdio.h>
#include <string.h>

USING_YOSYS_NAMESPACE

#ifdef YOSYS_ENABLE_GHDL

#include "ghdlsynth.h"

using namespace GhdlSynth;

//  Convert an Sname to a string.
static std::string to_str(Sname name)
{
	std::string res;
	bool is_sys = false;

	log_assert(is_valid(name));

	for (Sname pfx = name; is_valid(pfx); pfx = get_sname_prefix(pfx)) {
		switch (get_sname_kind(pfx)) {
		case Sname_Artificial:
			is_sys = true;
			// fallthrough
		case Sname_User:
			res = '.' + string(get_cstr(get_sname_suffix(pfx))) + res;
			break;
		case Sname_Version:
			res = '%' + stringf("%u", get_sname_version(pfx)) + res;
			break;
		}
	}
	res[0] = is_sys ? '$' : '\\';
	return res;
}

//  Get the corresponding wire for net N (or null if not found).
static Wire *get_wire(std::vector<RTLIL::Wire *> &net_map, Net n)
{
	log_assert(n.id != 0);

	//  Search if N is the output of a cell.
	Wire *res = n.id < net_map.size() ? net_map.at(n.id) : nullptr;
	return res;
}

//  Convert bit I of V to State.
static RTLIL::State logic32_to_state(struct logic_32 v, unsigned int i)
{
	i &= 31;

	switch((((v.va >> i)) & 1) + ((v.zx >> i) & 1)*2)
	{
	case 0:
		return RTLIL::State::S0;
	case 1:
		return RTLIL::State::S1;
	case 2:
		return RTLIL::State::Sz;
	case 3:
	default:
		return RTLIL::State::Sx;
	}
}

//  Convert V to a Const.
static RTLIL::Const pval_to_const(Pval v)
{
	const unsigned wd = get_pval_length(v);
	std::vector<RTLIL::State> bits(wd);
	struct logic_32 val;

	for (unsigned i = 0; i < wd; i++) {
		if (i % 32 == 0)
			val = read_pval(v, i / 32);
		bits[i] = logic32_to_state(val, i);
	}
	return RTLIL::Const(bits);
}

static RTLIL::SigSpec get_src(std::vector<RTLIL::Wire *> &net_map, Net n);
static RTLIL::SigSpec get_src_extract(std::vector<RTLIL::Wire *> &net_map, Net n, unsigned off, unsigned wd);

//  Concatenate the NBR_IN inputs of INST (ie handle Id_ConcatX).
static RTLIL::SigSpec get_src_concat(std::vector<RTLIL::Wire *> &net_map, Instance inst, unsigned nbr_in)
{
        RTLIL::SigSpec res;
        //  ConcatN means { I0; I1; .. IN}, but append() adds
        //  bits to the MSB side.
        for (unsigned i = nbr_in; i > 0; i--)
                res.append(get_src(net_map, get_input_net(inst, (i - 1))));
        return res;
}

//  Extract WD bits at OFF from concatenation INST.  Do not compute unused bits.
static RTLIL::SigSpec get_src_concat_extract(std::vector<RTLIL::Wire *> &net_map, Instance inst, unsigned nbr_in, unsigned off, unsigned wd)
{
        RTLIL::SigSpec res;

        //  ConcatN means { I0; I1; .. IN}, but append() adds
        //  bits to the MSB side.
        for (unsigned i = nbr_in; i > 0; i--) {
                Net p = get_input_net(inst, (i - 1));
                unsigned pw = get_width(p);
                if (off < pw) {
                        unsigned sub_wd = (off + wd < pw ? wd : pw - off);
                        res.append(get_src_extract(net_map, p, off, sub_wd));
                        //  sub_wd bits have been extracted.
                        wd -= sub_wd;
                        if (wd == 0)
                                break;
                        off = 0;
                }
                else {
                        off -= pw;
                }
        }
        return res;
}

//  Extract WD bits at OFF from N.  Try to avoid computing unused bits as it may result in an infinite recursion if parts of a concatenation are defined by the concatenation.
static RTLIL::SigSpec get_src_extract(std::vector<RTLIL::Wire *> &net_map, Net n, unsigned off, unsigned wd)
{
	Instance inst = get_net_parent(n);
	switch(get_id(inst)) {
        case Id_Signal:
	case Id_Isignal:
	case Id_Port:
        case Id_Output:
                return get_src_extract(net_map, get_input_net(inst, 0), off, wd);
	case Id_Extract:
                log_assert(wd <= get_width(n));
                return get_src_extract(net_map, get_input_net(inst, 0), get_param_uns32(inst, 0) + off, wd);
	case Id_Concat2:
                return get_src_concat_extract(net_map, inst, 2, off, wd);
	case Id_Concat3:
                return get_src_concat_extract(net_map, inst, 3, off, wd);
	case Id_Concat4:
                return get_src_concat_extract(net_map, inst, 4, off, wd);
	case Id_Concatn:
                return get_src_concat_extract(net_map, inst, get_param_uns32(inst, 0), off, wd);
        default:
                RTLIL::SigSpec res = get_src(net_map, n);
                return res.extract(off, wd);
        }
}

static RTLIL::SigSpec get_src(std::vector<RTLIL::Wire *> &net_map, Net n)
{
	log_assert(n.id != 0);

	//  Search if N is the output of a cell.
	Wire *w = get_wire(net_map, n);
	if (w != nullptr)
		return w;

	Instance inst = get_net_parent(n);
	switch(get_id(inst)) {
#define IN(N) get_src(net_map, get_input_net(inst, (N)))
	case Id_Signal:
	case Id_Isignal:
	case Id_Port:
	case Id_Output:
		return IN(0);
	case Id_Uextend:
		{
			RTLIL::SigSpec res = IN(0);
			res.extend_u0(get_width(n), false);
			return res;
		}
	case Id_Sextend:
		{
			RTLIL::SigSpec res = IN(0);
			res.extend_u0(get_width(n), true);
			return res;
		}
	case Id_Utrunc:
	case Id_Strunc:
		{
			RTLIL::SigSpec res = IN(0);
			return res.extract(0, get_width(n));
		}
	case Id_Const_Bit: // arbitrary width binary
		{
			const unsigned wd = get_width(n);
			std::vector<RTLIL::State> bits(wd);
			unsigned int val = 0;
			for (unsigned i = 0; i < wd; i++) {
				if (i % 32 == 0)
					val = get_param_uns32(inst, i / 32);
				bits[i] = (val >> (i%32)) & 1 ? RTLIL::State::S1 : RTLIL::State::S0;
			}
			return RTLIL::SigSpec(RTLIL::Const(bits));
		}
	case Id_Const_UB32: // zero padded binary
		{
			const unsigned wd = get_width(n);
			std::vector<RTLIL::State> bits(wd);
			unsigned int val = get_param_uns32(inst, 0);
			for (unsigned i = 0; i < wd && i < 32; i++) {
				bits[i] = (val >> i) & 1 ? RTLIL::State::S1 : RTLIL::State::S0;
			}
			return RTLIL::SigSpec(RTLIL::Const(bits));
		}
	case Id_Const_SB32: // sign extended binary
		{
			const unsigned wd = get_width(n);
			std::vector<RTLIL::State> bits(wd);
			unsigned int val = get_param_uns32(inst, 0);
			for (unsigned i = 0; i < wd; i++) {
				unsigned idx = i < 32 ? i : 31;
				bits[i] = (val >> idx) & 1 ? RTLIL::State::S1 : RTLIL::State::S0;
			}
			return RTLIL::SigSpec(RTLIL::Const(bits));
		}
	case Id_Const_Z:
		{
			return SigSpec(RTLIL::State::Sz, get_width(n));
		}
	case Id_Const_X:
		{
			return SigSpec(RTLIL::State::Sx, get_width(n));
		}
	case Id_Const_0:
		{
			return SigSpec(RTLIL::State::S0, get_width(n));
		}
	case Id_Const_Log: // arbitrary length 01ZX
		{
			const unsigned wd = get_width(n);
			std::vector<RTLIL::State> bits(wd);
			struct logic_32 v;
			for (unsigned i = 0; i < wd; i++) {
				if (i % 32 == 0) {
					v.va = get_param_uns32(inst, 2*(i / 32));
					v.zx = get_param_uns32(inst, 2*(i / 32) + 1);
				}
				bits[i] = logic32_to_state(v, i);

			}
			return RTLIL::SigSpec(RTLIL::Const(bits));
		}
	case Id_Const_UL32: // zero padded 01ZX
		{
			const unsigned wd = get_width(n);
			std::vector<RTLIL::State> bits(wd);
			unsigned int val01 = get_param_uns32(inst, 0);
			unsigned int valzx = get_param_uns32(inst, 1);
			for (unsigned i = 0; i < wd && i < 32; i++) {
				switch(((val01 >> i)&1)+((valzx >> i)&1)*2)
				{
				case 0:
					bits[i] = RTLIL::State::S0;
					break;
				case 1:
					bits[i] = RTLIL::State::S1;
					break;
				case 2:
					bits[i] = RTLIL::State::Sz;
					break;
				case 3:
					bits[i] = RTLIL::State::Sx;
					break;
				}

			}
			return RTLIL::SigSpec(RTLIL::Const(bits));
		}
	case Id_Extract:
                return get_src_extract(net_map, get_input_net(inst, 0), get_param_uns32(inst, 0), get_width(n));
	case Id_Concat2:
                return get_src_concat(net_map, inst, 2);
	case Id_Concat3:
                return get_src_concat(net_map, inst, 3);
	case Id_Concat4:
                return get_src_concat(net_map, inst, 4);
	case Id_Concatn:
                return get_src_concat(net_map, inst, get_param_uns32(inst, 0));
	default:
		log_cmd_error("wire not found for %s\n", to_str(get_module_name(get_module(inst))).c_str());
		break;
	}
#undef IN
}

static bool is_set(std::vector<RTLIL::Wire *> &net_map, Net n)
{
	//  If not in the map, then certainly not present.
	if (n.id >= net_map.size())
		return false;

	Wire *res = net_map[n.id];
	return (res != nullptr);
}

static void set_src(std::vector<RTLIL::Wire *> &net_map, Net n, Wire *wire)
{
	if (n.id >= net_map.size())
		net_map.resize(n.id + 1, nullptr);
	log_assert(net_map[n.id] == nullptr);
	net_map[n.id] = wire;
}

//  INST is an Id_Memory or an Id_Memory_Init
//  All the inputs have been connected, all the outputs have been pushed.
static void import_memory(RTLIL::Module *module, std::vector<RTLIL::Wire *> &net_map, Instance inst)
{
	Net mem_o = get_output(inst, 0);
	Input first_port = get_first_sink (mem_o);
	std::string mem_str = to_str(get_instance_name(inst));

	//  Memories appear only once.
	log_assert(!is_set(net_map, mem_o));

	//  Create memory.
	RTLIL::Memory *memory = new RTLIL::Memory;
	memory->name = "$mem$" + mem_str;

	//  Add it to module.
	module->memories[memory->name] = memory;

	//  Count number of read and write ports.
	//  Extract width, size, abits.
	unsigned nbr_rd = 0;
	unsigned nbr_wr = 0;
	unsigned width = 0;
	unsigned abits = 0;
	for (Input port = first_port; ;) {
		Instance port_inst = get_input_parent(port);
		Net addr;
		Net dat;
		switch(get_id(port_inst)) {
		case Id_Mem_Rd:
		case Id_Mem_Rd_Sync:
			dat = get_output(port_inst, 1);
			addr = get_input_net(port_inst, 1);
			nbr_rd++;
			break;
		case Id_Mem_Wr_Sync:
			dat = get_input_net(port_inst, 4);
			addr = get_input_net(port_inst, 1);
			nbr_wr++;
			break;
		case Id_Memory:
		case Id_Memory_Init:
			port.id = 0;
			break;
		default:
			log_assert(0);
		}
		if (port.id == 0)
			break;

		if (width == 0) {
			width = get_width(dat);
			abits = get_width(addr);
		} else {
			//  All the ports must have the same width and abits.
			log_assert(width == get_width(dat));
			log_assert(abits == get_width(addr));
		}
		port = get_first_sink(get_output(port_inst,  0));
	}

	unsigned size = get_width(mem_o) / width;
	memory->width = width;
	memory->size = size;
	memory->start_offset = 0;

	//  Create the memory.
	Cell *mem = module->addCell(mem_str, "$mem");
	mem->parameters["\\MEMID"] = Const(mem_str);
	mem->parameters["\\WIDTH"] = Const(width);
	mem->parameters["\\OFFSET"] = Const(0);
	mem->parameters["\\SIZE"] = Const(size);
	mem->parameters["\\ABITS"] = Const(abits);

	Const init_data;
	switch (get_id(inst)) {
	case Id_Memory:
		init_data = Const(State::Sx, size * width);
		break;
	case Id_Memory_Init:
		init_data = get_src(net_map, get_input_net(inst, 1)).as_const();
		break;
	default:
		log_assert(0);
	}
	mem->parameters["\\INIT"] = init_data;
	mem->parameters["\\WR_PORTS"] = Const(nbr_wr);
	mem->parameters["\\RD_PORTS"] = Const(nbr_rd);

	//  Connect.
	SigSpec rd_clk;
	SigSpec rd_addr;
	SigSpec rd_data;
	SigSpec rd_en;
	std::vector<RTLIL::State> rd_clk_en;
	SigSpec wr_clk;
	SigSpec wr_addr;
	SigSpec wr_data;
	SigSpec wr_en;
	for (Input port = first_port; ; ) {
		Instance port_inst = get_input_parent(port);
#define IN(N) get_src(net_map, get_input_net(port_inst, (N)))
#define OUT(N) get_src(net_map, get_output(port_inst, (N)))
		switch(get_id(port_inst)) {
		case Id_Mem_Rd:
			rd_clk_en.push_back(RTLIL::State::S0);
			rd_clk.append(RTLIL::State::Sx);
			rd_addr.append(IN(1));
			rd_data.append(OUT(1));
			rd_en.append(Const(1, 1));
			break;
		case Id_Mem_Rd_Sync:
			rd_clk_en.push_back(RTLIL::State::S1);
			rd_clk.append(IN(2));
			rd_addr.append(IN(1));
			rd_data.append(OUT(1));
			rd_en.append(IN(3));
			break;
		case Id_Mem_Wr_Sync:
			wr_clk.append(IN(2));
			wr_addr.append(IN(1));
			wr_data.append(IN(4));
			wr_en.append(SigSpec(SigBit(IN(3)), width));
			break;
		case Id_Memory:
		case Id_Memory_Init:
			port.id = 0;
			break;
		default:
			log_assert(0);
		}
		if (port.id == 0)
			break;
		port = get_first_sink(get_output(port_inst, 0));
	}
#undef IN
#undef OUT
	mem->parameters["\\RD_CLK_ENABLE"] = nbr_rd ? Const(rd_clk_en) : Const(0, 1);
	mem->parameters["\\RD_CLK_POLARITY"] = Const(RTLIL::State::S1, nbr_rd ? nbr_rd : 1);
	mem->parameters["\\RD_TRANSPARENT"] = Const(RTLIL::State::S0, nbr_rd ? nbr_rd : 1);

	mem->setPort("\\RD_CLK", rd_clk);
	mem->setPort("\\RD_ADDR", rd_addr);
	mem->setPort("\\RD_DATA", rd_data);
	mem->setPort("\\RD_EN", rd_en);

	mem->parameters["\\WR_CLK_ENABLE"] = Const(RTLIL::State::S1, nbr_wr ? nbr_wr : 1);
	mem->parameters["\\WR_CLK_POLARITY"] = Const(RTLIL::State::S1, nbr_wr ? nbr_wr : 1);

	mem->setPort("\\WR_CLK", wr_clk);
	mem->setPort("\\WR_ADDR", wr_addr);
	mem->setPort("\\WR_DATA", wr_data);
	mem->setPort("\\WR_EN", wr_en);
}

static void add_formal_input(RTLIL::Module *module, std::vector<RTLIL::Wire *> &net_map, Instance inst, const char *cellname)
{
	RTLIL::Cell *cell = module->addCell(to_str(get_instance_name(inst)), cellname);
	Net n = get_output(inst, 0);
	cell->setParam("\\WIDTH", get_width(n));
	cell->setPort("\\Y", get_src(net_map, n));
}

static void import_module(RTLIL::Design *design, GhdlSynth::Module m)
{
	Instance self_inst = get_self_instance (m);

	std::string module_name = to_str(get_module_name(m));

	if (design->has(module_name)) {
		log_cmd_error("Re-definition of module `%s'.\n", module_name.c_str());
		return;
	}

	RTLIL::Module *module = new RTLIL::Module;
	module->name = module_name;
	design->add(module);

	log("Importing module %s.\n", RTLIL::id2cstr(module->name));

	//  TODO: support submodules
	if (is_valid(get_first_sub_module(m))) {
		log_cmd_error("Unsupported: submodules in `%s'.\n", module_name.c_str());
		return;
	}

	//  List of all memories.
	std::vector<Instance> memories;

	if (!is_valid(self_inst)) { // blackbox
		module->set_bool_attribute("\\blackbox");

		Port_Idx nbr_inputs = get_nbr_inputs(m);
		for (Port_Idx idx = 0; idx < nbr_inputs; idx++) {
			RTLIL::Wire *wire = module->addWire(
				to_str(get_input_name(m, idx)),
				get_input_width(m, idx));
			wire->port_input = true;
		}
		Port_Idx nbr_outputs = get_nbr_outputs(m);
		for (Port_Idx idx = 0; idx < nbr_outputs; idx++) {
			RTLIL::Wire *wire = module->addWire(
				to_str(get_output_name(m, idx)),
				get_output_width(m, idx));
			if (get_inout_flag(m, idx))
				wire->port_input = true;
			wire->port_output = true;
		}
		Param_Idx nbr_params = get_nbr_params(m);
		for (Param_Idx idx = 0; idx < nbr_params; idx++) {
			module->avail_parameters.insert(to_str(get_param_name(m, idx)));
		}

		module->fixup_ports();
		return;
	}

	//  Create input ports.
	std::vector<RTLIL::Wire *> net_map;
	Port_Idx nbr_inputs = get_nbr_inputs(m);
	for (Port_Idx idx = 0; idx < nbr_inputs; idx++) {
		//  They correspond to ouputs of the self instance.
		Net port = get_output(self_inst, idx);

		RTLIL::Wire *wire = module->addWire(to_str(get_input_name(m, idx)));
		wire->port_id = idx + 1;
		wire->port_input = true;
		wire->width = get_width(port);
		set_src(net_map, port, wire);
	}
	//  Create inout ports, so that they can be read.
	Port_Idx nbr_outputs = get_nbr_outputs(m);
	for (Port_Idx idx = 0; idx < nbr_outputs; idx++) {
		if (!get_inout_flag(m, idx))
			continue;

		//  They correspond to inputs of the self instance.
		Net output_out = get_input_net(self_inst, idx);

		//  Create wire
		RTLIL::Wire *wire = module->addWire(to_str(get_output_name(m, idx)));
		wire->port_id = nbr_inputs + idx + 1;
		wire->port_output = true;
		wire->port_input = true;
		wire->width = get_width(output_out);

		Instance inout_inst = get_net_parent(output_out);
		Net inout_rd = get_output(inout_inst, 0);
		set_src(net_map, inout_rd, wire);
	}

	//  Create wires for outputs of (real) cells.
	for (Instance inst = get_first_instance(m);
	     is_valid(inst);
	     inst = get_next_instance(inst)) {
		GhdlSynth::Module im = get_module(inst);
		Module_Id id = get_id(im);
		switch (id) {
		case Id_And:
		case Id_Or:
		case Id_Xor:
		case Id_Nand:
		case Id_Nor:
		case Id_Xnor:
		case Id_Add:
		case Id_Sub:
		case Id_Neg:
		case Id_Mux2:
		case Id_Mux4:
		case Id_Dff:
		case Id_Idff:
		case Id_Adff:
		case Id_Iadff:
		case Id_Eq:
		case Id_Ne:
		case Id_Ult:
		case Id_Ule:
		case Id_Ugt:
		case Id_Uge:
		case Id_Slt:
		case Id_Sle:
		case Id_Sgt:
		case Id_Sge:
		case Id_Not:
		case Id_Abs:
		case Id_Red_Or:
		case Id_Red_And:
		case Id_Lsr:
		case Id_Lsl:
		case Id_Asr:
		case Id_Smin:
		case Id_Umin:
		case Id_Smax:
		case Id_Umax:
		case Id_Smul:
		case Id_Umul:
		case Id_Sdiv:
		case Id_Udiv:
		case Id_Srem:
		case Id_Smod:
		case Id_Umod:
		case Id_Allconst:
		case Id_Allseq:
		case Id_Anyconst:
		case Id_Anyseq:
		case Id_Mem_Rd:
		case Id_Mem_Rd_Sync:
		case Id_User_None:
		case Id_User_Parameters:
			for (Port_Idx idx = 0; idx < get_nbr_outputs(im); idx++) {
				Net o = get_output(inst, idx);
				//  The wire may have been created for an output
				if (!is_set(net_map, o)) {
					RTLIL::Wire *wire =
						module->addWire(NEW_ID, get_width(o));
					set_src(net_map, o, wire);
				}
			}
			break;
		case Id_Inout:
			//  The wire was created when the port was.
			break;
		case Id_Assert:
		case Id_Assume:
		case Id_Cover:
		case Id_Assert_Cover:
			//  No output
			break;
		case Id_Memory:
		case Id_Memory_Init:
		case Id_Mem_Wr_Sync:
			//  Handled by import_memory.
			break;
		case Id_Signal:
		case Id_Isignal:
		case Id_Output:
		case Id_Port:
		case Id_Const_UB32:
		case Id_Const_SB32:
		case Id_Const_UL32:
		case Id_Const_Bit:
		case Id_Const_Log:
		case Id_Const_Z:
		case Id_Const_X:
		case Id_Const_0:
		case Id_Uextend:
		case Id_Sextend:
		case Id_Utrunc:
		case Id_Strunc:
		case Id_Extract:
		case Id_Concat2:
		case Id_Concat3:
		case Id_Concat4:
		case Id_Concatn:
			//  Skip: these won't create cells.
			break;
		case Id_Edge:
			//  The cell is ignored.
			break;
		default:
			log_cmd_error("Unsupported(1): instance %s of %s.\n",
			              to_str(get_instance_name(inst)).c_str(),
			              to_str(get_module_name(get_module(inst))).c_str());
			return;
		}
	}

	//  Create cells and connect.
	for (Instance inst = get_first_instance(m);
	     is_valid(inst);
	     inst = get_next_instance(inst)) {
		Module_Id id = get_id(inst);
		Sname iname = get_instance_name(inst);
		switch (id) {
#define IN(N) get_src(net_map, get_input_net(inst, (N)))
#define OUT(N) get_src(net_map, get_output(inst, (N)))
		case Id_And:
			module->addAnd(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Or:
			module->addOr(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Xor:
			module->addXor(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Nand:
			{
				SigSpec r = OUT(0);
				RTLIL::Wire *w = module->addWire(NEW_ID, r.size());
				module->addAnd(NEW_ID, IN(0), IN(1), w);
				module->addNot(to_str(iname), w, r);
			}
			break;
		case Id_Nor:
			{
				SigSpec r = OUT(0);
				RTLIL::Wire *w = module->addWire(NEW_ID, r.size());
				module->addOr(NEW_ID, IN(0), IN(1), w);
				module->addNot(to_str(iname), w, r);
			}
			break;
		case Id_Xnor:
			module->addXnor(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Add:
			module->addAdd(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Sub:
			module->addSub(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Neg:
			module->addNeg(to_str(iname), IN(0), OUT(0), true);
			break;
		case Id_Not:
			module->addNot(to_str(iname), IN(0), OUT(0));
			break;
		case Id_Abs:
			{
				SigSpec isNegative = IN(0).extract(IN(0).size() - 1, 1);
				RTLIL::Wire *negated = module->addWire(NEW_ID, IN(0).size());
				module->addNeg(NEW_ID, IN(0), negated);
				module->addMux(NEW_ID, IN(0), negated, isNegative, OUT(0));
			}
			break;
		case Id_Eq:
			module->addEq(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Ne:
			module->addNe(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Ult:
			module->addLt(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Ule:
			module->addLe(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Ugt:
			module->addGt(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Uge:
			module->addGe(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Slt:
			module->addLt(to_str(iname), IN(0), IN(1), OUT(0), true);
			break;
		case Id_Sle:
			module->addLe(to_str(iname), IN(0), IN(1), OUT(0), true);
			break;
		case Id_Sgt:
			module->addGt(to_str(iname), IN(0), IN(1), OUT(0), true);
			break;
		case Id_Sge:
			module->addGe(to_str(iname), IN(0), IN(1), OUT(0), true);
			break;
		case Id_Red_Or:
			module->addReduceOr(to_str(iname), IN(0), OUT(0));
			break;
		case Id_Red_And:
			module->addReduceAnd(to_str(iname), IN(0), OUT(0));
			break;
		case Id_Lsl:
			module->addShl(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Lsr:
			module->addShr(to_str(iname), IN(0), IN(1), OUT(0));
			break;
		case Id_Asr:
			module->addSshr(to_str(iname), IN(0), IN(1), OUT(0), true);
			break;
		case Id_Smin:
		case Id_Umin:
		case Id_Smax:
		case Id_Umax:
			{
				bool is_signed = (id == Id_Smin || id == Id_Smax);

				RTLIL::Wire *select_rhs = module->addWire(NEW_ID);


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