# # yosys -- Yosys Open SYnthesis Suite # # Copyright (C) 2012 Claire Xenia Wolf # # 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. # import sys, re, os, signal import subprocess if os.name == "posix": import resource from copy import copy from select import select from time import time from queue import Queue, Empty from threading import Thread # This is needed so that the recursive SMT2 S-expression parser # does not run out of stack frames when parsing large expressions if os.name == "posix": smtio_reclimit = 64 * 1024 if sys.getrecursionlimit() < smtio_reclimit: sys.setrecursionlimit(smtio_reclimit) current_rlimit_stack = resource.getrlimit(resource.RLIMIT_STACK) if current_rlimit_stack[0] != resource.RLIM_INFINITY: smtio_stacksize = 128 * 1024 * 1024 if os.uname().sysname == "Darwin": # MacOS has rather conservative stack limits smtio_stacksize = 8 * 1024 * 1024 if current_rlimit_stack[1] != resource.RLIM_INFINITY: smtio_stacksize = min(smtio_stacksize, current_rlimit_stack[1]) if current_rlimit_stack[0] < smtio_stacksize: try: resource.setrlimit(resource.RLIMIT_STACK, (smtio_stacksize, current_rlimit_stack[1])) except ValueError: # couldn't get more stack, just run with what we have pass # currently running solvers (so we can kill them) running_solvers = dict() forced_shutdown = False solvers_index = 0 def force_shutdown(signum, frame): global forced_shutdown if not forced_shutdown: forced_shutdown = True if signum is not None: print("<%s>" % signal.Signals(signum).name) for p in running_solvers.values(): # os.killpg(os.getpgid(p.pid), signal.SIGTERM) os.kill(p.pid, signal.SIGTERM) sys.exit(1) if os.name == "posix": signal.signal(signal.SIGHUP, force_shutdown) signal.signal(signal.SIGINT, force_shutdown) signal.signal(signal.SIGTERM, force_shutdown) def except_hook(exctype, value, traceback): if not forced_shutdown: sys.__excepthook__(exctype, value, traceback) force_shutdown(None, None) sys.excepthook = except_hook hex_dict = { "0": "0000", "1": "0001", "2": "0010", "3": "0011", "4": "0100", "5": "0101", "6": "0110", "7": "0111", "8": "1000", "9": "1001", "A": "1010", "B": "1011", "C": "1100", "D": "1101", "E": "1110", "F": "1111", "a": "1010", "b": "1011", "c": "1100", "d": "1101", "e": "1110", "f": "1111" } class SmtModInfo: def __init__(self): self.inputs = set() self.outputs = set() self.registers = set() self.memories = dict() self.wires = set() self.wsize = dict() self.clocks = dict() self.cells = dict() self.asserts = dict() self.covers = dict() self.maximize = set() self.minimize = set() self.anyconsts = dict() self.anyseqs = dict() self.allconsts = dict() self.allseqs = dict() self.asize = dict() class SmtIo: def __init__(self, opts=None): global solvers_index self.logic = None self.logic_qf = True self.logic_ax = True self.logic_uf = True self.logic_bv = True self.logic_dt = False self.forall = False self.timeout = 0 self.produce_models = True self.recheck = False self.smt2cache = [list()] self.smt2_options = dict() self.p = None self.p_index = solvers_index solvers_index += 1 if opts is not None: self.logic = opts.logic self.solver = opts.solver self.solver_opts = opts.solver_opts self.debug_print = opts.debug_print self.debug_file = opts.debug_file self.dummy_file = opts.dummy_file self.timeinfo = opts.timeinfo self.timeout = opts.timeout self.unroll = opts.unroll self.noincr = opts.noincr self.info_stmts = opts.info_stmts self.nocomments = opts.nocomments else: self.solver = "yices" self.solver_opts = list() self.debug_print = False self.debug_file = None self.dummy_file = None self.timeinfo = os.name != "nt" self.timeout = 0 self.unroll = False self.noincr = False self.info_stmts = list() self.nocomments = False self.start_time = time() self.modinfo = dict() self.curmod = None self.topmod = None self.setup_done = False def __del__(self): if self.p is not None and not forced_shutdown: os.killpg(os.getpgid(self.p.pid), signal.SIGTERM) if running_solvers is not None: del running_solvers[self.p_index] def setup(self): assert not self.setup_done if self.forall: self.unroll = False if self.solver == "yices": if self.forall: self.noincr = True if self.noincr: self.popen_vargs = ['yices-smt2'] + self.solver_opts else: self.popen_vargs = ['yices-smt2', '--incremental'] + self.solver_opts if self.timeout != 0: self.popen_vargs.append('-t') self.popen_vargs.append('%d' % self.timeout); if self.solver == "z3": self.popen_vargs = ['z3', '-smt2', '-in'] + self.solver_opts if self.timeout != 0: self.popen_vargs.append('-T:%d' % self.timeout); if self.solver in ["cvc4", "cvc5"]: self.recheck = True if self.noincr: self.popen_vargs = [self.solver, '--lang', 'smt2.6' if self.logic_dt else 'smt2'] + self.solver_opts else: self.popen_vargs = [self.solver, '--incremental', '--lang', 'smt2.6' if self.logic_dt else 'smt2'] + self.solver_opts if self.timeout != 0: self.popen_vargs.append('--tlimit=%d000' % self.timeout); if self.solver == "mathsat": self.popen_vargs = ['mathsat'] + self.solver_opts if self.timeout != 0: print('timeout option is not supported for mathsat.') sys.exit(1) if self.solver in ["boolector", "bitwuzla"]: if self.noincr: self.popen_vargs = [self.solver, '--smt2'] + self.solver_opts else: self.popen_vargs = [self.solver, '--smt2', '-i'] + self.solver_opts self.unroll = True if self.timeout != 0: print('timeout option is not supported for %s.' % self.solver) sys.exit(1) if self.solver == "abc": if len(self.solver_opts) > 0: self.popen_vargs = ['yosys-abc', '-S', '; '.join(self.solver_opts)] else: self.popen_vargs = ['yosys-abc', '-S', '%blast; &sweep -C 5000; &syn4; &cec -s -m -C 2000'] self.logic_ax = False self.unroll = True self.noincr = True if self.timeout != 0: print('timeout option is not supported for abc.') sys.exit(1) if self.solver == "dummy": assert self.dummy_file is not None self.dummy_fd = open(self.dummy_file, "r") else: if self.dummy_file is not None: self.dummy_fd = open(self.dummy_file, "w") if not self.noincr: self.p_open() if self.unroll: assert not self.forall self.logic_uf = False self.unroll_idcnt = 0 self.unroll_buffer = "" self.unroll_sorts = set() self.unroll_objs = set() self.unroll_decls = dict() self.unroll_cache = dict() self.unroll_stack = list() if self.logic is None: self.logic = "" if self.logic_qf: self.logic += "QF_" if self.logic_ax: self.logic += "A" if self.logic_uf: self.logic += "UF" if self.logic_bv: self.logic += "BV" if self.logic_dt: self.logic = "ALL" if self.solver == "yices" and self.forall: self.logic = "BV" self.setup_done = True for stmt in self.info_stmts: self.write(stmt) if self.produce_models: self.write("(set-option :produce-models true)") #See the SMT-LIB Standard, Section 4.1.7 modestart_options = [":global-declarations", ":interactive-mode", ":produce-assertions", ":produce-assignments", ":produce-models", ":produce-proofs", ":produce-unsat-assumptions", ":produce-unsat-cores", ":random-seed"] for key, val in self.smt2_options.items(): if key in modestart_options: self.write("(set-option {} {})".format(key, val)) self.write("(set-logic %s)" % self.logic) if self.forall and self.solver == "yices": self.write("(set-option :yices-ef-max-iters 1000000000)") for key, val in self.smt2_options.items(): if key not in modestart_options: self.write("(set-option {} {})".format(key, val)) def timestamp(self): secs = int(time() - self.start_time) return "## %3d:%02d:%02d " % (secs // (60*60), (secs // 60) % 60, secs % 60) def replace_in_stmt(self, stmt, pat, repl): if stmt == pat: return repl if isinstance(stmt, list): return [self.replace_in_stmt(s, pat, repl) for s in stmt] return stmt def unroll_stmt(self, stmt): if not isinstance(stmt, list): return stmt stmt = [self.unroll_stmt(s) for s in stmt] if len(stmt) >= 2 and not isinstance(stmt[0], list) and stmt[0] in self.unroll_decls: assert stmt[1] in self.unroll_objs key = tuple(stmt) if key not in self.unroll_cache: decl = copy(self.unroll_decls[key[0]]) self.unroll_cache[key] = "|UNROLL#%d|" % self.unroll_idcnt decl[1] = self.unroll_cache[key] self.unroll_idcnt += 1 if decl[0] == "declare-fun": if isinstance(decl[3], list) or decl[3] not in self.unroll_sorts: self.unroll_objs.add(decl[1]) decl[2] = list() else: self.unroll_objs.add(decl[1]) decl = list() elif decl[0] == "define-fun": arg_index = 1 for arg_name, arg_sort in decl[2]: decl[4] = self.replace_in_stmt(decl[4], arg_name, key[arg_index]) arg_index += 1 decl[2] = list() if len(decl) > 0: decl = self.unroll_stmt(decl) self.write(self.unparse(decl), unroll=False) return self.unroll_cache[key] return stmt def p_thread_main(self): while True: data = self.p.stdout.readline().decode("utf-8") if data == "": break self.p_queue.put(data) self.p_queue.put("") self.p_running = False def p_open(self): assert self.p is None try: self.p = subprocess.Popen(self.popen_vargs, stdin=subprocess.PIPE, stdout=subprocess.PIPE, stderr=subprocess.STDOUT) except FileNotFoundError: print("%s SMT Solver '%s' not found in path." % (self.timestamp(), self.popen_vargs[0]), flush=True) sys.exit(1) running_solvers[self.p_index] = self.p self.p_running = True self.p_next = None self.p_queue = Queue() self.p_thread = Thread(target=self.p_thread_main) self.p_thread.start() def p_write(self, data, flush): assert self.p is not None self.p.stdin.write(bytes(data, "utf-8")) if flush: self.p.stdin.flush() def p_read(self): assert self.p is not None if self.p_next is not None: data = self.p_next self.p_next = None return data if not self.p_running: return "" return self.p_queue.get() def p_poll(self, timeout=0.1): assert self.p is not None assert self.p_running if self.p_next is not None: return False try: self.p_next = self.p_queue.get(True, timeout) return False except Empty: return True def p_close(self): assert self.p is not None self.p.stdin.close() self.p_thread.join() assert not self.p_running del running_solvers[self.p_index] self.p = None self.p_next = None self.p_queue = None self.p_thread = None def write(self, stmt, unroll=True): if stmt.startswith(";"): self.info(stmt) if not self.setup_done: self.info_stmts.append(stmt) return elif not self.setup_done: self.setup() stmt = stmt.strip() if self.nocomments or self.unroll: stmt = re.sub(r" *;.*", "", stmt) if stmt == "": return recheck = None if self.solver != "dummy": if self.noincr: # Don't close the solver yet, if we're just unrolling definitions # required for a (get-...) statement if self.p is not None and not stmt.startswith("(get-") and unroll: self.p_close() if unroll and self.unroll: stmt = self.unroll_buffer + stmt self.unroll_buffer = "" s = re.sub(r"\|[^|]*\|", "", stmt) if s.count("(") != s.count(")"): self.unroll_buffer = stmt + " " return s = self.parse(stmt) if self.recheck and s and s[0].startswith("get-"): recheck = self.unroll_idcnt if self.debug_print: print("-> %s" % s) if len(s) == 3 and s[0] == "declare-sort" and s[2] == "0": self.unroll_sorts.add(s[1]) return elif len(s) == 4 and s[0] == "declare-fun" and s[2] == [] and s[3] in self.unroll_sorts: self.unroll_objs.add(s[1]) return elif len(s) >= 4 and s[0] == "declare-fun": for arg_sort in s[2]: if arg_sort in self.unroll_sorts: self.unroll_decls[s[1]] = s return elif len(s) >= 4 and s[0] == "define-fun": for arg_name, arg_sort in s[2]: if arg_sort in self.unroll_sorts: self.unroll_decls[s[1]] = s return stmt = self.unparse(self.unroll_stmt(s)) if recheck is not None and recheck != self.unroll_idcnt: self.check_sat(["sat"]) if stmt == "(push 1)": self.unroll_stack.append(( copy(self.unroll_sorts), copy(self.unroll_objs), copy(self.unroll_decls), copy(self.unroll_cache), )) if stmt == "(pop 1)": self.unroll_sorts, self.unroll_objs, self.unroll_decls, self.unroll_cache = self.unroll_stack.pop() if self.debug_print: print("> %s" % stmt) if self.debug_file: print(stmt, file=self.debug_file) self.debug_file.flush() if self.solver != "dummy": if self.noincr: if stmt == "(push 1)": self.smt2cache.append(list()) elif stmt == "(pop 1)": self.smt2cache.pop() else: if self.p is not None: self.p_write(stmt + "\n", True) self.smt2cache[-1].append(stmt) else: self.p_write(stmt + "\n", True) def info(self, stmt): if not stmt.startswith("; yosys-smt2-"): return fields = stmt.split() if fields[1] == "yosys-smt2-solver-option": self.smt2_options[fields[2]] = fields[3] if fields[1] == "yosys-smt2-nomem": if self.logic is None: self.logic_ax = False if fields[1] == "yosys-smt2-nobv": if self.logic is None: self.logic_bv = False if fields[1] == "yosys-smt2-stdt": if self.logic is None: self.logic_dt = True if fields[1] == "yosys-smt2-forall": if self.logic is None: self.logic_qf = False self.forall = True if fields[1] == "yosys-smt2-module": self.curmod = fields[2] self.modinfo[self.curmod] = SmtModInfo() if fields[1] == "yosys-smt2-cell": self.modinfo[self.curmod].cells[fields[3]] = fields[2] if fields[1] == "yosys-smt2-topmod": self.topmod = fields[2] if fields[1] == "yosys-smt2-input": self.modinfo[self.curmod].inputs.add(fields[2]) self.modinfo[self.curmod].wsize[fields[2]] = int(fields[3]) if fields[1] == "yosys-smt2-output": self.modinfo[self.curmod].outputs.add(fields[2]) self.modinfo[self.curmod].wsize[fields[2]] = int(fields[3]) if fields[1] == "yosys-smt2-register": self.modinfo[self.curmod].registers.add(fields[2]) self.modinfo[self.curmod].wsize[fields[2]] = int(fields[3]) if fields[1] == "yosys-smt2-memory": self.modinfo[self.curmod].memories[fields[2]] = (int(fields[3]), int(fields[4]), int(fields[5]), int(fields[6]), fields[7] == "async") if fields[1] == "yosys-smt2-wire": self.modinfo[self.curmod].wires.add(fields[2]) self.modinfo[self.curmod].wsize[fields[2]] = int(fields[3]) if fields[1] == "yosys-smt2-clock": for edge in fields[3:]: if fields[2] not in self.modinfo[self.curmod].clocks: self.modinfo[self.curmod].clocks[fields[2]] = edge elif self.modinfo[self.curmod].clocks[fields[2]] != edge: self.modinfo[self.curmod].clocks[fields[2]] = "event" if fields[1] == "yosys-smt2-assert": if len(fields) > 4: self.modinfo[self.curmod].asserts["%s_a %s" % (self.curmod, fields[2])] = f'{fields[4]} ({fields[3]})' else: self.modinfo[self.curmod].asserts["%s_a %s" % (self.curmod, fields[2])] = fields[3] if fields[1] == "yosys-smt2-cover": if len(fields) > 4: self.modinfo[self.curmod].covers["%s_c %s" % (self.curmod, fields[2])] = f'{fields[4]} ({fields[3]})' else: self.modinfo[self.curmod].covers["%s_c %s" % (self.curmod, fields[2])] = fields[3] if fields[1] == "yosys-smt2-maximize": self.modinfo[self.curmod].maximize.add(fields[2]) if fields[1] == "yosys-smt2-minimize": self.modinfo[self.curmod].minimize.add(fields[2]) if fields[1] == "yosys-smt2-anyconst": self.modinfo[self.curmod].anyconsts[fields[2]] = (fields[4], None if len(fields) <= 5 else fields[5]) self.modinfo[self.curmod].asize[fields[2]] = int(fields[3]) if fields[1] == "yosys-smt2-anyseq": self.modinfo[self.curmod].anyseqs[fields[2]] = (fields[4], None if len(fields) <= 5 else fields[5]) self.modinfo[self.curmod].asize[fields[2]] = int(fields[3]) if fields[1] == "yosys-smt2-allconst": self.modinfo[self.curmod].allconsts[fields[2]] = (fields[4], None if len(fields) <= 5 else fields[5]) self.modinfo[self.curmod].asize[fields[2]] = int(fields[3]) if fields[1] == "yosys-smt2-allseq": self.modinfo[self.curmod].allseqs[fields[2]] = (fields[4], None if len(fields) <= 5 else fields[5]) self.modinfo[self.curmod].asize[fields[2]] = int(fields[3]) def hiernets(self, top, regs_only=False): def hiernets_worker(nets, mod, cursor): for netname in sorted(self.modinfo[mod].wsize.keys()): if not regs_only or netname in self.modinfo[mod].registers: nets.append(cursor + [netname]) for cellname, celltype in sorted(self.modinfo[mod].cells.items()): hiernets_worker(nets, celltype, cursor + [cellname]) nets = list() hiernets_worker(nets, top, []) return nets def hieranyconsts(self, top): def worker(results, mod, cursor): for name, value in sorted(self.modinfo[mod].anyconsts.items()): width = self.modinfo[mod].asize[name] results.append((cursor, name, value[0], value[1], width)) for cellname, celltype in sorted(self.modinfo[mod].cells.items()): worker(results, celltype, cursor + [cellname]) results = list() worker(results, top, []) return results def hieranyseqs(self, top): def worker(results, mod, cursor): for name, value in sorted(self.modinfo[mod].anyseqs.items()): width = self.modinfo[mod].asize[name] results.append((cursor, name, value[0], value[1], width)) for cellname, celltype in sorted(self.modinfo[mod].cells.items()): worker(results, celltype, cursor + [cellname]) results = list() worker(results, top, []) return results def hierallconsts(self, top): def worker(results, mod, cursor): for name, value in sorted(self.modinfo[mod].allconsts.items()): width = self.modinfo[mod].asize[name] results.append((cursor, name, value[0], value[1], width)) for cellname, celltype in sorted(self.modinfo[mod].cells.items()): worker(results, celltype, cursor + [cellname]) results = list() worker(results, top, []) return results def hierallseqs(self, top): def worker(results, mod, cursor): for name, value in sorted(self.modinfo[mod].allseqs.items()): width = self.modinfo[mod].asize[name] results.append((cursor, name, value[0], value[1], width)) for cellname, celltype in sorted(self.modinfo[mod].cells.items()): worker(results, celltype, cursor + [cellname]) results = list() worker(results, top, []) return results def hiermems(self, top): def hiermems_worker(mems, mod, cursor): for memname in sorted(self.modinfo[mod].memories.keys()): mems.append(cursor + [memname]) for cellname, celltype in sorted(self.modinfo[mod].cells.items()): hiermems_worker(mems, celltype, cursor + [cellname]) mems = list() hiermems_worker(mems, top, []) return mems def read(self): stmt = [] count_brackets = 0 while True: if self.solver == "dummy": line = self.dummy_fd.readline().strip() else: line = self.p_read().strip() if self.dummy_file is not None: self.dummy_fd.write(line + "\n") count_brackets += line.count("(") count_brackets -= line.count(")") stmt.append(line) if self.debug_print: print("< %s" % line) if count_brackets == 0: break if self.solver != "dummy" and self.p.poll(): print("%s Solver terminated unexpectedly: %s" % (self.timestamp(), "".join(stmt)), flush=True) sys.exit(1) stmt = "".join(stmt) if stmt.startswith("(error"): print("%s Solver Error: %s" % (self.timestamp(), stmt), flush=True) if self.solver != "dummy": self.p_close() sys.exit(1) return stmt def check_sat(self, expected=["sat", "unsat", "unknown", "timeout", "interrupted"]): if self.debug_print: print("> (check-sat)") if self.debug_file and not self.nocomments: print("; running check-sat..", file=self.debug_file) self.debug_file.flush() if self.solver != "dummy": if self.noincr: if self.p is not None: self.p_close() self.p_open() for cache_ctx in self.smt2cache: for cache_stmt in cache_ctx: self.p_write(cache_stmt + "\n", False) self.p_write("(check-sat)\n", True) if self.timeinfo: i = 0 s = "/-\|" count = 0 num_bs = 0 while self.p_poll(): count += 1 if count < 25: continue if count % 10 == 0 or count == 25: secs = count // 10 if secs < 60: m = "(%d seconds)" % secs elif secs < 60*60: m = "(%d seconds -- %d:%02d)" % (secs, secs // 60, secs % 60) else: m = "(%d seconds -- %d:%02d:%02d)" % (secs, secs // (60*60), (secs // 60) % 60, secs % 60) print("%s %s %c" % ("\b \b" * num_bs, m, s[i]), end="", file=sys.stderr) num_bs = len(m) + 3 else: print("\b" + s[i], end="", file=sys.stderr) sys.stderr.flush() i = (i + 1) % len(s) if num_bs != 0: print("\b \b" * num_bs, end="", file=sys.stderr) sys.stderr.flush() else: count = 0 while self.p_poll(60): count += 1 msg = None if count == 1: msg = "1 minute" elif count in [5, 10, 15, 30]: msg = "%d minutes" % count elif count == 60: msg = "1 hour" elif count % 60 == 0: msg = "%d hours" % (count // 60) if msg is not None: print("%s waiting for solver (%s)" % (self.timestamp(), msg), flush=True) if self.forall: result = self.read() while result not in ["sat", "unsat", "unknown", "timeout", "interrupted", ""]: print("%s %s: %s" % (self.timestamp(), self.solver, result)) result = self.read() else: result = self.read() if self.debug_file: print("(set-info :status %s)" % result, file=self.debug_file) print("(check-sat)", file=self.debug_file) self.debug_file.flush() if result not in expected: if result == "": print("%s Unexpected EOF response from solver." % (self.timestamp()), flush=True) else: print("%s Unexpected response from solver: %s" % (self.timestamp(), result), flush=True) if self.solver != "dummy": self.p_close() sys.exit(1) return result def parse(self, stmt): def worker(stmt): if stmt[0] == '(': expr = [] cursor = 1 while stmt[cursor] != ')': el, le = worker(stmt[cursor:]) expr.append(el) cursor += le return expr, cursor+1 if stmt[0] == '|': expr = "|" cursor = 1 while stmt[cursor] != '|': expr += stmt[cursor] cursor += 1 expr += "|" return expr, cursor+1 if stmt[0] in [" ", "\t", "\r", "\n"]: el, le = worker(stmt[1:]) return el, le+1 expr = "" cursor = 0 while stmt[cursor] not in ["(", ")", "|", " ", "\t", "\r", "\n"]: expr += stmt[cursor] cursor += 1 return expr, cursor return worker(stmt)[0] def unparse(self, stmt): if isinstance(stmt, list): return "(" + " ".join([self.unparse(s) for s in stmt]) + ")" return stmt def bv2hex(self, v): h = "" v = self.bv2bin(v) while len(v) > 0: d = 0 if len(v) > 0 and v[-1] == "1": d += 1 if len(v) > 1 and v[-2] == "1": d += 2 if len(v) > 2 and v[-3] == "1": d += 4 if len(v) > 3 and v[-4] == "1": d += 8 h = hex(d)[2:] + h if len(v) < 4: break v = v[:-4] return h def bv2bin(self, v): if type(v) is list and len(v) == 3 and v[0] == "_" and v[1].startswith("bv"): x, n = int(v[1][2:]), int(v[2]) return "".join("1" if (x & (1 << i)) else "0" for i in range(n-1, -1, -1)) if v == "true": return "1" if v == "false": return "0" if v.startswith("#b"): return v[2:] if v.startswith("#x"): return "".join(hex_dict.get(x) for x in v[2:]) assert False def bv2int(self, v): return int(self.bv2bin(v), 2) def get(self, expr): self.write("(get-value (%s))" % (expr)) return self.parse(self.read())[0][1] def get_list(self, expr_list): if len(expr_list) == 0: return [] self.write("(get-value (%s))" % " ".join(expr_list)) return [n[1] for n in self.parse(self.read())] def get_path(self, mod, path): assert mod in self.modinfo path = path.replace("\\", "/").split(".") for i in range(len(path)-1): first = ".".join(path[0:i+1]) second = ".".join(path[i+1:]) if first in self.modinfo[mod].cells: nextmod = self.modinfo[mod].cells[first] return [first] + self.get_path(nextmod, second) return [".".join(path)] def net_expr(self, mod, base, path): if len(path) == 0: return base if len(path) == 1: assert mod in self.modinfo if path[0] == "": return base if path[0] in self.modinfo[mod].cells: return "(|%s_h %s| %s)" % (mod, path[0], base) if path[0] in self.modinfo[mod].wsize: return "(|%s_n %s| %s)" % (mod, path[0], base) if path[0] in self.modinfo[mod].memories: return "(|%s_m %s| %s)" % (mod, path[0], base) assert 0 assert mod in self.modinfo assert path[0] in self.modinfo[mod].cells nextmod = self.modinfo[mod].cells[path[0]] nextbase = "(|%s_h %s| %s)" % (mod, path[0], base) return self.net_expr(nextmod, nextbase, path[1:]) def net_width(self, mod, net_path): for i in range(len(net_path)-1): assert mod in self.modinfo assert net_path[i] in self.modinfo[mod].cells mod = self.modinfo[mod].cells[net_path[i]] assert mod in self.modinfo assert net_path[-1] in self.modinfo[mod].wsize return self.modinfo[mod].wsize[net_path[-1]] def net_clock(self, mod, net_path): for i in range(len(net_path)-1): assert mod in self.modinfo assert net_path[i] in self.modinfo[mod].cells mod = self.modinfo[mod].cells[net_path[i]] assert mod in self.modinfo if net_path[-1] not in self.modinfo[mod].clocks: return None return self.modinfo[mod].clocks[net_path[-1]] def net_exists(self, mod, net_path): for i in range(len(net_path)-1): if mod not in self.modinfo: return False if net_path[i] not in self.modinfo[mod].cells: return False mod = self.modinfo[mod].cells[net_path[i]] if mod not in self.modinfo: return False if net_path[-1] not in self.modinfo[mod].wsize: return False return True def mem_exists(self, mod, mem_path): for i in range(len(mem_path)-1): if mod not in self.modinfo: return False if mem_path[i] not in self.modinfo[mod].cells: return False mod = self.modinfo[mod].cells[mem_path[i]] if mod not in self.modinfo: return False if mem_path[-1] not in self.modinfo[mod].memories: return False return True def mem_expr(self, mod, base, path, port=None, infomode=False): if len(path) == 1: assert mod in self.modinfo assert path[0] in self.modinfo[mod].memories if infomode: return self.modinfo[mod].memories[path[0]] return "(|%s_m%s %s| %s)" % (mod, "" if port is None else ":%s" % port, path[0], base) assert mod in self.modinfo assert path[0] in self.modinfo[mod].cells nextmod = self.modinfo[mod].cells[path[0]] nextbase = "(|%s_h %s| %s)" % (mod, path[0], base) return self.mem_expr(nextmod, nextbase, path[1:], port=port, infomode=infomode) def mem_info(self, mod, path): return self.mem_expr(mod, "", path, infomode=True) def get_net(self, mod_name, net_path, state_name): return self.get(self.net_expr(mod_name, state_name, net_path)) def get_net_list(self, mod_name, net_path_list, state_name): return self.get_list([self.net_expr(mod_name, state_name, n) for n in net_path_list]) def get_net_hex(self, mod_name, net_path, state_name): return self.bv2hex(self.get_net(mod_name, net_path, state_name)) def get_net_hex_list(self, mod_name, net_path_list, state_name): return [self.bv2hex(v) for v in self.get_net_list(mod_name, net_path_list, state_name)] def get_net_bin(self, mod_name, net_path, state_name): return self.bv2bin(self.get_net(mod_name, net_path, state_name)) def get_net_bin_list(self, mod_name, net_path_list, state_name): return [self.bv2bin(v) for v in self.get_net_list(mod_name, net_path_list, state_name)] def wait(self): if self.p is not None: self.p.wait() self.p_close() class SmtOpts: def __init__(self): self.shortopts = "s:S:v" self.longopts = ["unroll", "noincr", "noprogress", "timeout=", "dump-smt2=", "logic=", "dummy=", "info=", "nocomments"] self.solver = "yices" self.solver_opts = list() self.debug_print = False self.debug_file = None self.dummy_file = None self.unroll = False self.noincr = False self.timeinfo = os.name != "nt" self.timeout = 0 self.logic = None self.info_stmts = list() self.nocomments = False def handle(self, o, a): if o == "-s": self.solver = a elif o == "-S": self.solver_opts.append(a) elif o == "--timeout": self.timeout = int(a) elif o == "-v": self.debug_print = True elif o == "--unroll": self.unroll = True elif o == "--noincr": self.noincr = True elif o == "--noprogress": self.timeinfo = False elif o == "--dump-smt2": self.debug_file = open(a, "w") elif o == "--logic": self.logic = a elif o == "--dummy": self.dummy_file = a elif o == "--info": self.info_stmts.append(a) elif o == "--nocomments": self.nocomments = True else: return False return True def helpmsg(self): return """ -s set SMT solver: z3, yices, boolector, bitwuzla, cvc4, mathsat, dummy default: yices -S pass as command line argument to the solver --timeout set the solver timeout to the specified value (in seconds). --logic use the specified SMT2 logic (e.g. QF_AUFBV) --dummy if solver is "dummy", read solver output from that file otherwise: write solver output to that file -v enable debug output --unroll unroll uninterpreted functions --noincr don't use incremental solving, instead restart solver for each (check-sat). This also avoids (push) and (pop). --noprogress disable timer display during solving (this option is set implicitly on Windows) --dump-smt2 write smt2 statements to file --info include the specified smt2 info statement in the smt2 output --nocomments strip all comments from the generated smt2 code """ class MkVcd: def __init__(self, f): self.f = f self.t = -1 self.nets = dict() self.clocks = dict() def add_net(self, path, width): path = tuple(path) assert self.t == -1 key = "n%d" % len(self.nets) self.nets[path] = (key, width) def add_clock(self, path, edge): path = tuple(path) assert self.t == -1 key = "n%d" % len(self.nets) self.nets[path] = (key, 1) self.clocks[path] = (key, edge) def set_net(self, path, bits): path = tuple(path) assert self.t >= 0 assert path in self.nets if path not in self.clocks: print("b%s %s" % (bits, self.nets[path][0]), file=self.f) def escape_name(self, name): name = re.sub(r"\[([0-9a-zA-Z_]*[a-zA-Z_][0-9a-zA-Z_]*)\]", r"<\1>", name) if re.match("[\[\]]", name) and name[0] != "\\": name = "\\" + name return name def set_time(self, t): assert t >= self.t if t != self.t: if self.t == -1: print("$version Generated by Yosys-SMTBMC $end", file=self.f) print("$timescale 1ns $end", file=self.f) print("$var integer 32 t smt_step $end", file=self.f) print("$var event 1 ! smt_clock $end", file=self.f) def vcdescape(n): if n.startswith("$") or ":" in n: return "\\" + n return n scope = [] for path in sorted(self.nets): key, width = self.nets[path] uipath = list(path) if "." in uipath[-1] and not uipath[-1].startswith("$"): uipath = uipath[0:-1] + uipath[-1].split(".") for i in range(len(uipath)): uipath[i] = re.sub(r"\[([^\]]*)\]", r"<\1>", uipath[i]) while uipath[:len(scope)] != scope: print("$upscope $end", file=self.f) scope = scope[:-1] while uipath[:-1] != scope: scopename = uipath[len(scope)] print("$scope module %s $end" % vcdescape(scopename), file=self.f) scope.append(uipath[len(scope)]) if path in self.clocks and self.clocks[path][1] == "event": print("$var event 1 %s %s $end" % (key, vcdescape(uipath[-1])), file=self.f) else: print("$var wire %d %s %s $end" % (width, key, vcdescape(uipath[-1])), file=self.f) for i in range(len(scope)): print("$upscope $end", file=self.f) print("$enddefinitions $end", file=self.f) self.t = t assert self.t >= 0 if self.t > 0: print("#%d" % (10 * self.t - 5), file=self.f) for path in sorted(self.clocks.keys()): if self.clocks[path][1] == "posedge": print("b0 %s" % self.nets[path][0], file=self.f) elif self.clocks[path][1] == "negedge": print("b1 %s" % self.nets[path][0], file=self.f) print("#%d" % (10 * self.t), file=self.f) print("1!", file=self.f) print("b%s t" % format(self.t, "032b"), file=self.f) for path in sorted(self.clocks.keys()): if self.clocks[path][1] == "negedge": print("b0 %s" % self.nets[path][0], file=self.f) else: print("b1 %s" % self.nets[path][0], file=self.f)