import collections import os import os.path import random import re import shlex import subprocess import sys import tempfile import time import traceback import pipes import pexpect print_log_names = False real_stdout = sys.stdout # Note that gdb comes with its own testsuite. I was unable to figure out how to # run that testsuite against the spike simulator. def find_file(path): for directory in (os.getcwd(), os.path.dirname(__file__)): fullpath = os.path.join(directory, path) relpath = os.path.relpath(fullpath) if len(relpath) >= len(fullpath): relpath = fullpath if os.path.exists(relpath): return relpath return None def compile(args): # pylint: disable=redefined-builtin cmd = ["riscv64-unknown-elf-gcc", "-g"] for arg in args: found = find_file(arg) if found: cmd.append(found) else: cmd.append(arg) header("Compile") print("+", " ".join(cmd)) process = subprocess.Popen(cmd, stdout=subprocess.PIPE, stderr=subprocess.PIPE) stdout, stderr = process.communicate() if process.returncode: print(stdout, end=" ") print(stderr, end=" ") header("") raise Exception("Compile failed!") class Spike: # pylint: disable=too-many-instance-attributes # pylint: disable=too-many-locals def __init__(self, target, halted=False, timeout=None, with_jtag_gdb=True, isa=None, progbufsize=None, dmi_rti=None, abstract_rti=None, support_hasel=True, support_abstract_csr=True, support_haltgroups=True): """Launch spike. Return tuple of its process and the port it's running on.""" self.process = None self.isa = isa self.progbufsize = progbufsize self.dmi_rti = dmi_rti self.abstract_rti = abstract_rti self.support_abstract_csr = support_abstract_csr self.support_hasel = support_hasel self.support_haltgroups = support_haltgroups if target.harts: harts = target.harts else: harts = [target] cmd = self.command(target, harts, halted, timeout, with_jtag_gdb) self.infinite_loop = target.compile(harts[0], "programs/checksum.c", "programs/tiny-malloc.c", "programs/infinite_loop.S", "-DDEFINE_MALLOC", "-DDEFINE_FREE") cmd.append(self.infinite_loop) self.logfile = tempfile.NamedTemporaryFile(prefix="spike-", suffix=".log") self.logname = self.logfile.name if print_log_names: real_stdout.write("Temporary spike log: %s\n" % self.logname) self.logfile.write(("+ %s\n" % " ".join(cmd)).encode()) self.logfile.flush() self.process = subprocess.Popen(cmd, stdin=subprocess.PIPE, stdout=self.logfile, stderr=self.logfile) if with_jtag_gdb: self.port = None for _ in range(30): m = re.search(r"Listening for remote bitbang connection on " r"port (\d+).", open(self.logname).read()) if m: self.port = int(m.group(1)) os.environ['REMOTE_BITBANG_PORT'] = m.group(1) break time.sleep(0.11) if not self.port: print_log(self.logname) raise Exception("Didn't get spike message about bitbang " "connection") # pylint: disable=too-many-branches def command(self, target, harts, halted, timeout, with_jtag_gdb): # pylint: disable=no-self-use if target.sim_cmd: cmd = shlex.split(target.sim_cmd) else: cmd = ["spike"] cmd += ["-p%d" % len(harts)] assert len(set(t.xlen for t in harts)) == 1, \ "All spike harts must have the same XLEN" if self.isa: isa = self.isa else: isa = "RV%dG" % harts[0].xlen cmd += ["--isa", isa] cmd += ["--dm-auth"] if not self.progbufsize is None: cmd += ["--dm-progsize", str(self.progbufsize)] cmd += ["--dm-sba", "32"] if not self.dmi_rti is None: cmd += ["--dmi-rti", str(self.dmi_rti)] if not self.abstract_rti is None: cmd += ["--dm-abstract-rti", str(self.abstract_rti)] if not self.support_abstract_csr: cmd.append("--dm-no-abstract-csr") if not self.support_hasel: cmd.append("--dm-no-hasel") if not self.support_haltgroups: cmd.append("--dm-no-halt-groups") assert len(set(t.ram for t in harts)) == 1, \ "All spike harts must have the same RAM layout" assert len(set(t.ram_size for t in harts)) == 1, \ "All spike harts must have the same RAM layout" os.environ['WORK_AREA'] = '0x%x' % harts[0].ram cmd += ["-m0x%x:0x%x" % (harts[0].ram, harts[0].ram_size)] if timeout: cmd = ["timeout", str(timeout)] + cmd if halted: cmd.append('-H') if with_jtag_gdb: cmd += ['--rbb-port', '0'] os.environ['REMOTE_BITBANG_HOST'] = 'localhost' return cmd def __del__(self): if self.process: try: self.process.kill() self.process.wait() except OSError: pass def wait(self, *args, **kwargs): return self.process.wait(*args, **kwargs) class VcsSim: logfile = tempfile.NamedTemporaryFile(prefix='simv', suffix='.log') logname = logfile.name def __init__(self, sim_cmd=None, debug=False, timeout=300): if sim_cmd: cmd = shlex.split(sim_cmd) else: cmd = ["simv"] cmd += ["+jtag_vpi_enable"] if debug: cmd[0] = cmd[0] + "-debug" cmd += ["+vcdplusfile=output/gdbserver.vpd"] logfile = open(self.logname, "w") if print_log_names: real_stdout.write("Temporary VCS log: %s\n" % self.logname) logfile.write("+ %s\n" % " ".join(cmd)) logfile.flush() listenfile = open(self.logname, "r") listenfile.seek(0, 2) self.process = subprocess.Popen(cmd, stdin=subprocess.PIPE, stdout=logfile, stderr=logfile) done = False start = time.time() while not done: # Fail if VCS exits early exit_code = self.process.poll() if exit_code is not None: raise RuntimeError('VCS simulator exited early with status %d' % exit_code) line = listenfile.readline() if not line: time.sleep(1) match = re.match(r"^Listening on port (\d+)$", line) if match: done = True self.port = int(match.group(1)) os.environ['JTAG_VPI_PORT'] = str(self.port) if (time.time() - start) > timeout: raise Exception("Timed out waiting for VCS to listen for JTAG " "vpi") def __del__(self): try: self.process.kill() self.process.wait() except OSError: pass class Openocd: logfile = tempfile.NamedTemporaryFile(prefix='openocd', suffix='.log') logname = logfile.name def __init__(self, server_cmd=None, config=None, debug=False, timeout=60): self.timeout = timeout if server_cmd: cmd = shlex.split(server_cmd) else: cmd = ["openocd"] if debug: cmd.append("-d") # This command needs to come before any config scripts on the command # line, since they are executed in order. cmd += [ # Tell OpenOCD to bind gdb to an unused, ephemeral port. "--command", "gdb_port 0", # Disable tcl and telnet servers, since they are unused and because # the port numbers will conflict if multiple OpenOCD processes are # running on the same server. "--command", "tcl_port disabled", "--command", "telnet_port disabled", ] if config: self.config_file = find_file(config) if self.config_file is None: print("Unable to read file", config) exit(1) cmd += ["-f", self.config_file] if debug: cmd.append("-d") logfile = open(Openocd.logname, "w") if print_log_names: real_stdout.write("Temporary OpenOCD log: %s\n" % Openocd.logname) env_entries = ("REMOTE_BITBANG_HOST", "REMOTE_BITBANG_PORT", "WORK_AREA") env_entries = [key for key in env_entries if key in os.environ] logfile.write("+ %s%s\n" % ( "".join("%s=%s " % (key, os.environ[key]) for key in env_entries), " ".join(map(pipes.quote, cmd)))) logfile.flush() self.gdb_ports = [] self.process = self.start(cmd, logfile) def start(self, cmd, logfile): process = subprocess.Popen(cmd, stdin=subprocess.PIPE, stdout=logfile, stderr=logfile) try: # Wait for OpenOCD to have made it through riscv_examine(). When # using OpenOCD to communicate with a simulator this may take a # long time, and gdb will time out when trying to connect if we # attempt too early. start = time.time() messaged = False fd = open(Openocd.logname, "r") while True: line = fd.readline() if not line: if not process.poll() is None: raise Exception("OpenOCD exited early.") time.sleep(0.1) continue m = re.search(r"Listening on port (\d+) for gdb connections", line) if m: self.gdb_ports.append(int(m.group(1))) if "telnet server disabled" in line: return process if not messaged and time.time() - start > 1: messaged = True print("Waiting for OpenOCD to start...") if (time.time() - start) > self.timeout: raise Exception("Timed out waiting for OpenOCD to " "listen for gdb") except Exception: print_log(Openocd.logname) raise def __del__(self): try: self.process.terminate() start = time.time() while time.time() < start + 10: if self.process.poll(): break else: self.process.kill() except (OSError, AttributeError): pass def smp(self): """Return true iff OpenOCD internally sees the harts as part of an SMP group.""" for line in open(self.config_file, "r"): if "target smp" in line: return True return False class OpenocdCli: def __init__(self, port=4444): self.child = pexpect.spawn( "sh -c 'telnet localhost %d | tee openocd-cli.log'" % port) self.child.expect("> ") def command(self, cmd): self.child.sendline(cmd) self.child.expect(cmd) self.child.expect("\n") self.child.expect("> ") return self.child.before.strip("\t\r\n \0").decode("utf-8") def reg(self, reg=''): output = self.command("reg %s" % reg) matches = re.findall(r"(\w+) \(/\d+\): (0x[0-9A-F]+)", output) values = {r: int(v, 0) for r, v in matches} if reg: return values[reg] return values def load_image(self, image): output = self.command("load_image %s" % image) if 'invalid ELF file, only 32bits files are supported' in output: raise TestNotApplicable(output) class CannotAccess(Exception): def __init__(self, address): Exception.__init__(self) self.address = address class CouldNotFetch(Exception): def __init__(self, regname, explanation): Exception.__init__(self) self.regname = regname self.explanation = explanation Thread = collections.namedtuple('Thread', ('id', 'description', 'target_id', 'name', 'frame')) def parse_rhs(text): text = text.strip() if text.startswith("{") and text.endswith("}"): inner = text[1:-1] parsed = [parse_rhs(t) for t in inner.split(", ")] if all([isinstance(p, dict) for p in parsed]): dictionary = {} for p in parsed: for k, v in p.items(): dictionary[k] = v parsed = dictionary return parsed elif text.startswith('"') and text.endswith('"'): return text[1:-1] elif ' = ' in text: lhs, rhs = text.split(' = ', 1) return {lhs: parse_rhs(rhs)} elif re.match(r"-?(\d+\.\d+(e-?\d+)?|inf)", text): return float(text) elif re.match(r"-?nan\(0x[a-f0-9]+\)", text): return float("nan") else: return int(text, 0) class Gdb: """A single gdb class which can interact with one or more gdb instances.""" # pylint: disable=too-many-public-methods # pylint: disable=too-many-instance-attributes def __init__(self, ports, cmd="riscv64-unknown-elf-gdb", timeout=60, binary=None): assert ports self.ports = ports self.cmd = cmd self.timeout = timeout self.binary = binary self.stack = [] self.harts = {} self.logfiles = [] self.children = [] for port in ports: logfile = tempfile.NamedTemporaryFile(prefix="gdb@%d-" % port, suffix=".log") self.logfiles.append(logfile) if print_log_names: real_stdout.write("Temporary gdb log: %s\n" % logfile.name) child = pexpect.spawn(cmd) child.logfile = logfile child.logfile.write(("+ %s\n" % cmd).encode()) self.children.append(child) self.active_child = self.children[0] def connect(self): for port, child in zip(self.ports, self.children): self.select_child(child) self.wait() self.command("set style enabled off") self.command("set confirm off") self.command("set width 0") self.command("set height 0") # Force consistency. self.command("set print entry-values no") self.command("set remotetimeout %d" % self.timeout) self.command("target extended-remote localhost:%d" % port, ops=10) if self.binary: self.command("file %s" % self.binary) threads = self.threads() for t in threads: hartid = None if t.name: m = re.search(r"Hart (\d+)", t.name) if m: hartid = int(m.group(1)) if hartid is None: if self.harts: hartid = max(self.harts) + 1 else: hartid = 0 # solo: True iff this is the only thread on this child self.harts[hartid] = {'child': child, 'thread': t, 'solo': len(threads) == 1} def __del__(self): for child in self.children: del child def one_hart_per_gdb(self): return all(h['solo'] for h in self.harts.values()) def lognames(self): return [logfile.name for logfile in self.logfiles] def select_child(self, child): self.active_child = child def select_hart(self, hart): h = self.harts[hart.id] self.select_child(h['child']) if not h['solo']: output = self.command("thread %s" % h['thread'].id, ops=5) assert "Unknown" not in output def push_state(self): self.stack.append({ 'active_child': self.active_child }) def pop_state(self): state = self.stack.pop() self.active_child = state['active_child'] def wait(self): """Wait for prompt.""" self.active_child.expect(r"\(gdb\)") def command(self, command, ops=1): """ops is the estimated number of operations gdb will have to perform to perform this command. It is used to compute a timeout based on self.timeout.""" timeout = ops * self.timeout self.active_child.sendline(command) self.active_child.expect("\n", timeout=timeout) self.active_child.expect(r"\(gdb\)", timeout=timeout) return self.active_child.before.strip().decode("utf-8") def global_command(self, command): """Execute this command on every gdb that we control.""" with PrivateState(self): for child in self.children: self.select_child(child) self.command(command) def c(self, wait=True, sync=True, checkOutput=True, ops=20): """ Dumb c command. In RTOS mode, gdb will resume all harts. In multi-gdb mode, this command will just go to the current gdb, so will only resume one hart. """ if sync: sync = "" else: sync = "&" if wait: output = self.command("c%s" % sync, ops=ops) if checkOutput: assert "Continuing" in output assert "Could not insert hardware" not in output return output else: self.active_child.sendline("c%s" % sync) self.active_child.expect("Continuing", timeout=ops * self.timeout) return "" def c_all(self, wait=True): """ Resume every hart. This function works fine when using multiple gdb sessions, but the caller must be careful when using it nonetheless. gdb's behavior is to not set breakpoints until just before the hart is resumed, and then clears them as soon as the hart halts. That means that you can't set one software breakpoint, and expect multiple harts to hit it. It's possible that the first hart completes set/run/halt/clear before the second hart even gets to resume, so it will never hit the breakpoint. """ with PrivateState(self): for child in self.children: child.sendline("c") child.expect("Continuing") if wait: for child in self.children: child.expect(r"\(gdb\)") def interrupt(self, ops=1): self.active_child.send("\003") self.active_child.expect(r"\(gdb\)", timeout=self.timeout * ops) return self.active_child.before.strip().decode() def interrupt_all(self): for child in self.children: self.select_child(child) self.interrupt() def x(self, address, size='w'): output = self.command("x/%s %s" % (size, address)) value = int(output.split(':')[1].strip(), 0) return value def p_raw(self, obj): output = self.command("p %s" % obj) m = re.search("Cannot access memory at address (0x[0-9a-f]+)", output) if m: raise CannotAccess(int(m.group(1), 0)) return output.split('=', 1)[-1].strip() def p(self, obj, fmt="/x", ops=1): output = self.command("p%s %s" % (fmt, obj), ops=ops).splitlines()[-1] m = re.search("Cannot access memory at address (0x[0-9a-f]+)", output) if m: raise CannotAccess(int(m.group(1), 0)) m = re.search(r"Could not fetch register \"(\w+)\"; (.*)$", output) if m: raise CouldNotFetch(m.group(1), m.group(2)) rhs = output.split('=', 1)[-1] return parse_rhs(rhs) def p_fpr(self, obj, ops=1): result = self.p(obj, fmt="", ops=ops) if isinstance(result, dict): return result['double'] return result def p_string(self, obj): output = self.command("p %s" % obj) value = shlex.split(output.split('=')[-1].strip())[1] return value def info_registers(self, group): output = self.command("info registers %s" % group, ops=5) result = {} for line in output.splitlines(): m = re.match(r"(\w+)\s+({.*})\s+(\(.*\))", line) if m: parts = m.groups() else: parts = line.split() name = parts[0] if "Could not fetch" in line: result[name] = " ".join(parts[1:]) else: result[name] = parse_rhs(parts[1]) return result def stepi(self): output = self.command("stepi", ops=10) return output def load(self): output = self.command("load", ops=1000) assert "failed" not in output assert "Transfer rate" in output output = self.command("compare-sections", ops=1000) assert "matched" in output assert "MIS" not in output def b(self, location): output = self.command("b %s" % location, ops=5) assert "not defined" not in output assert "Breakpoint" in output m = re.search(r"Breakpoint (\d+),? ", output) assert m, output return int(m.group(1)) def hbreak(self, location): output = self.command("hbreak %s" % location, ops=5) assert "not defined" not in output assert "Hardware assisted breakpoint" in output return output def watch(self, expr): output = self.command("watch %s" % expr, ops=5) assert "not defined" not in output assert "atchpoint" in output return output def swatch(self, expr): self.command("show can-use-hw-watchpoints") self.command("set can-use-hw-watchpoints 0") output = self.command("watch %s" % expr, ops=5) assert "not defined" not in output assert "atchpoint" in output self.command("set can-use-hw-watchpoints 1") return output def threads(self): output = self.command("info threads", ops=100) threads = [] for line in output.splitlines(): m = re.match( r"[\s\*]*(\d+)\s*" r"(Remote target|Thread (\d+)\s*\(Name: ([^\)]+))" r"\s*(.*)", line) if m: threads.append(Thread(*m.groups())) assert threads #>>>if not threads: #>>> threads.append(Thread('1', '1', 'Default', '???')) return threads def thread(self, thread): return self.command("thread %s" % thread.id) def where(self): return self.command("where 1") class PrivateState: def __init__(self, gdb): self.gdb = gdb def __enter__(self): self.gdb.push_state() def __exit__(self, _type, _value, _traceback): self.gdb.pop_state() def run_all_tests(module, target, parsed): todo = [] for name in dir(module): definition = getattr(module, name) if isinstance(definition, type) and hasattr(definition, 'test') and \ (not parsed.test or any(test in name for test in parsed.test)): todo.append((name, definition, None)) if parsed.list_tests: for name, definition, hart in todo: print(name) return 0 try: os.makedirs(parsed.logs) except OSError: # There's a race where multiple instances of the test program might # decide to create the logs directory at the same time. pass overall_start = time.time() global gdb_cmd # pylint: disable=global-statement gdb_cmd = parsed.gdb examine_added = False for hart in target.harts: if parsed.misaval: hart.misa = int(parsed.misaval, 16) print("Using $misa from command line: 0x%x" % hart.misa) elif hart.misa: print("Using $misa from hart definition: 0x%x" % hart.misa) elif not examine_added: todo.insert(0, ("ExamineTarget", ExamineTarget, None)) examine_added = True results, count = run_tests(parsed, target, todo) header("ran %d tests in %.0fs" % (count, time.time() - overall_start), dash=':') return print_results(results) good_results = set(('pass', 'not_applicable')) def run_tests(parsed, target, todo): results = {} count = 0 for name, definition, hart in todo: log_name = os.path.join(parsed.logs, "%s-%s-%s.log" % (time.strftime("%Y%m%d-%H%M%S"), type(target).__name__, name)) log_fd = open(log_name, 'w') print("[%s] Starting > %s" % (name, log_name)) instance = definition(target, hart) sys.stdout.flush() log_fd.write("Test: %s\n" % name) log_fd.write("Target: %s\n" % type(target).__name__) start = time.time() global real_stdout # pylint: disable=global-statement real_stdout = sys.stdout sys.stdout = log_fd try: result = instance.run() log_fd.write("Result: %s\n" % result) log_fd.write("Logfile: %s\n" % log_name) log_fd.write("Reproduce: %s %s %s\n" % (sys.argv[0], parsed.target, name)) finally: sys.stdout = real_stdout log_fd.write("Time elapsed: %.2fs\n" % (time.time() - start)) log_fd.flush() print("[%s] %s in %.2fs" % (name, result, time.time() - start)) if result not in good_results and parsed.print_failures: sys.stdout.write(open(log_name).read()) sys.stdout.flush() results.setdefault(result, []).append((name, log_name)) count += 1 if result not in good_results and parsed.fail_fast: break return results, count def print_results(results): result = 0 for key, value in results.items(): print("%d tests returned %s" % (len(value), key)) if key not in good_results: result = 1 for name, log_name in value: print(" %s > %s" % (name, log_name)) return result def add_test_run_options(parser): parser.add_argument("--logs", default="logs", help="Store logs in the specified directory.") parser.add_argument("--fail-fast", "-f", action="store_true", help="Exit as soon as any test fails.") parser.add_argument("--print-failures", action="store_true", help="When a test fails, print the log file to stdout.") parser.add_argument("--print-log-names", "--pln", action="store_true", help="Print names of temporary log files as soon as they are " "created.") parser.add_argument("--list-tests", action="store_true", help="Print out a list of tests, and exit immediately.") parser.add_argument("test", nargs='*', help="Run only tests that are named here.") parser.add_argument("--gdb", help="The command to use to start gdb.") parser.add_argument("--misaval", help="Don't run ExamineTarget, just assume the misa value which is " "specified.") def header(title, dash='-', length=78): if title: dashes = dash * (length - 4 - len(title)) before = dashes[:len(dashes)//2] after = dashes[len(dashes)//2:] print("%s[ %s ]%s" % (before, title, after)) else: print(dash * length) def print_log_handle(name, handle): header(name) for l in handle: sys.stdout.write(l) print() def print_log(path): print_log_handle(path, open(path, "r")) class BaseTest: compiled = {} def __init__(self, target, hart=None): self.target = target if hart: self.hart = hart else: self.hart = random.choice(target.harts) self.server = None self.target_process = None self.binary = None self.start = 0 self.logs = [] def early_applicable(self): """Return a false value if the test has determined it cannot run without ever needing to talk to the target or server.""" # pylint: disable=no-self-use return True def setup(self): pass def compile(self): compile_args = getattr(self, 'compile_args', None) if compile_args: if compile_args not in BaseTest.compiled: BaseTest.compiled[compile_args] = \ self.target.compile(self.hart, *compile_args) self.binary = BaseTest.compiled.get(compile_args) def classSetup(self): self.compile() self.target_process = self.target.create() if self.target_process: self.logs.append(self.target_process.logname) try: self.server = self.target.server() self.logs.append(self.server.logname) except Exception: for log in self.logs: print_log(log) raise def classTeardown(self): del self.server del self.target_process def postMortem(self): pass def run(self): """ If compile_args is set, compile a program and set self.binary. Call setup(). Then call test() and return the result, displaying relevant information if an exception is raised. """ sys.stdout.flush() if not self.early_applicable(): return "not_applicable" self.start = time.time() try: self.classSetup() self.setup() result = self.test() # pylint: disable=no-member except TestNotApplicable: result = "not_applicable" except Exception as e: # pylint: disable=broad-except if isinstance(e, TestFailed): result = "fail" else: result = "exception" if isinstance(e, TestFailed): # pylint: disable=no-member header("Message") print(e.message) header("Traceback") traceback.print_exc(file=sys.stdout) try: self.postMortem() except Exception as e: # pylint: disable=broad-except header("postMortem Exception") print(e) traceback.print_exc(file=sys.stdout) return result finally: # Get handles to logs before the files are deleted. logs = [] for log in self.logs: logs.append((log, open(log, "r"))) self.classTeardown() for name, handle in logs: print_log_handle(name, handle) header("End of logs") if not result: result = 'pass' return result gdb_cmd = None class GdbTest(BaseTest): def __init__(self, target, hart=None): BaseTest.__init__(self, target, hart=hart) self.gdb = None def classSetup(self): BaseTest.classSetup(self) if gdb_cmd: self.gdb = Gdb(self.server.gdb_ports, gdb_cmd, timeout=self.target.timeout_sec, binary=self.binary) else: self.gdb = Gdb(self.server.gdb_ports, timeout=self.target.timeout_sec, binary=self.binary) self.logs += self.gdb.lognames() self.gdb.connect() self.gdb.global_command("set remotetimeout %d" % self.target.timeout_sec) for cmd in self.target.gdb_setup: self.gdb.command(cmd) self.gdb.select_hart(self.hart) # FIXME: OpenOCD doesn't handle PRIV now #self.gdb.p("$priv=3") def postMortem(self): if not self.gdb: return self.gdb.interrupt() self.gdb.command("info breakpoints") self.gdb.command("disassemble", ops=20) self.gdb.command("info registers all", ops=20) self.gdb.command("flush regs") self.gdb.command("info threads", ops=20) def classTeardown(self): del self.gdb BaseTest.classTeardown(self) def parkOtherHarts(self): """Park harts besides the currently selected one in loop_forever().""" for hart in self.target.harts: # Park all harts that we're not using in a safe place. if hart != self.hart: self.gdb.select_hart(hart) self.gdb.p("$pc=loop_forever") self.gdb.select_hart(self.hart) class GdbSingleHartTest(GdbTest): def classSetup(self): GdbTest.classSetup(self) self.parkOtherHarts() class ExamineTarget(GdbTest): def test(self): for hart in self.target.harts: self.gdb.select_hart(hart) hart.misa = self.gdb.p("$misa") txt = "RV" misa_xlen = 0 if ((hart.misa & 0xFFFFFFFF) >> 30) == 1: misa_xlen = 32 elif ((hart.misa & 0xFFFFFFFFFFFFFFFF) >> 62) == 2: misa_xlen = 64 elif ((hart.misa & 0xFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFFF) >> 126) == 3: misa_xlen = 128 else: raise TestFailed("Couldn't determine XLEN from $misa (0x%x)" % self.hart.misa) if misa_xlen != hart.xlen: raise TestFailed("MISA reported XLEN of %d but we were "\ "expecting XLEN of %d\n" % (misa_xlen, hart.xlen)) txt += ("%d" % misa_xlen) for i in range(26): if hart.misa & (1< b: raise TestFailed("%r not greater than %r" % (a, b)) def assertLess(a, b, comment=None): if not a < b: raise TestFailed("%r not less than %r" % (a, b), comment) def assertTrue(a): if not a: raise TestFailed("%r is not True" % a) def assertRegex(text, regexp): if not re.search(regexp, text): raise TestFailed("can't find %r in %r" % (regexp, text))