def signal_two_signals(self):
threads = self.start_threads(1)
# try sending two different signals to two threads
self.test_sequence.add_log_lines([
"read packet: $vCont;C{0:x}:{1:x};C{2:x}:{3:x}#00".format(
lldbutil.get_signal_number('SIGUSR1'), threads[0],
lldbutil.get_signal_number('SIGUSR2'), threads[1]),
{"direction": "send", "regex": r"^\$E1e#db$"},
], True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
def test_signal_process_without_tid(self):
self.build()
self.set_inferior_startup_launch()
threads = self.start_threads(1)
self.send_and_check_signal(
"C{0:x}".format(lldbutil.get_signal_number('SIGUSR1')), threads)
def test_signal_minus_one(self):
self.build()
self.set_inferior_startup_launch()
threads = self.start_threads(1)
self.send_and_check_signal(
"C{0:x}:-1".format(lldbutil.get_signal_number('SIGUSR1')), threads)
def test_inferior_seg_fault_received(self):
self.build()
if self.platformIsDarwin():
self.inferior_seg_fault_received(
self.GDB_REMOTE_STOP_CODE_BAD_ACCESS)
else:
self.inferior_seg_fault_received(
lldbutil.get_signal_number('SIGSEGV'))
def test_signal_one_thread(self):
self.build()
self.set_inferior_startup_launch()
threads = self.start_threads(1)
# try sending a signal to one of the two threads
self.send_and_check_signal(
"C{0:x}:{1:x};c".format(lldbutil.get_signal_number('SIGUSR1')),
threads[:1])
def test_signal_all_threads(self):
self.build()
self.set_inferior_startup_launch()
threads = self.start_threads(1)
# try sending a signal to two threads (= the process)
self.send_and_check_signal(
"C{0:x}:{1:x};C{0:x}:{2:x}".format(
lldbutil.get_signal_number('SIGUSR1'), *threads), threads)
def test_default_signals_behavior(self):
self.build()
self.set_inferior_startup_launch()
procs = self.prep_debug_monitor_and_inferior()
expected_signals = ["SIGSEGV", "SIGUSR1", "SIGUSR2",
"SIGALRM", "SIGFPE", "SIGBUS", "SIGINT", "SIGHUP"]
for signal_name in expected_signals:
signo = lldbutil.get_signal_number(signal_name)
self.expect_signal(signo)
self.expect_exit_code(0)
def test_Hc_then_Csignal_signals_correct_thread_launch(self):
self.build()
self.set_inferior_startup_launch()
if self.platformIsDarwin():
# Darwin debugserver translates some signals like SIGSEGV into some gdb
# expectations about fixed signal numbers.
self.Hc_then_Csignal_signals_correct_thread(self.TARGET_EXC_BAD_ACCESS)
else:
self.Hc_then_Csignal_signals_correct_thread(
lldbutil.get_signal_number('SIGSEGV'))
def signal_one_thread(self):
threads = self.start_threads(1)
# try sending a signal to one of the two threads
self.test_sequence.add_log_lines([
"read packet: $vCont;C{0:x}:{1:x};c#00".format(
lldbutil.get_signal_number('SIGUSR1'), threads[0]),
{"direction": "send", "regex": r"^\$W00#b7$"},
], True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
def test_default_signals_behavior(self):
self.init_llgs_test()
self.build()
self.set_inferior_startup_launch()
procs = self.prep_debug_monitor_and_inferior()
expected_signals = ["SIGSEGV", "SIGUSR1", "SIGUSR2",
"SIGALRM", "SIGFPE", "SIGBUS", "SIGINT", "SIGHUP"]
for signal_name in expected_signals:
signo = lldbutil.get_signal_number(signal_name)
self.expect_signal(signo)
self.expect_exit_code(0)
def test_q_pass_signals(self):
self.build()
self.set_inferior_startup_launch()
procs = self.prep_debug_monitor_and_inferior()
expected_signals = ["SIGSEGV",
"SIGALRM", "SIGFPE", "SIGBUS", "SIGINT", "SIGHUP"]
signals_to_ignore = ["SIGUSR1", "SIGUSR2"]
self.ignore_signals(signals_to_ignore)
for signal_name in expected_signals:
signo = lldbutil.get_signal_number(signal_name)
self.expect_signal(signo)
self.expect_exit_code(len(signals_to_ignore))
def signal_two_of_three_threads(self):
threads = self.start_threads(2)
# try sending a signal to 2 out of 3 threads
self.test_sequence.add_log_lines([
"read packet: $vCont;C{0:x}:{1:x};C{0:x}:{2:x};c#00".format(
lldbutil.get_signal_number('SIGUSR1'),
threads[1], threads[2]),
{"direction": "send", "regex": r"^\$E1e#db$"},
], True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
def test_signal_all_threads(self):
self.build()
self.set_inferior_startup_launch()
threads = self.start_threads(1)
# try sending a signal to two threads (= the process)
self.test_sequence.add_log_lines([
"read packet: $vCont;C{0:x}:{1:x};C{0:x}:{2:x}#00".format(
lldbutil.get_signal_number('SIGUSR1'),
threads[0], threads[1]),
{"direction": "send", "regex": r"^\$W00#b7$"},
], True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
def test_change_signals_at_runtime(self):
self.init_llgs_test()
self.build()
self.set_inferior_startup_launch()
procs = self.prep_debug_monitor_and_inferior()
expected_signals = ["SIGSEGV", "SIGUSR1", "SIGUSR2",
"SIGALRM", "SIGHUP"]
signals_to_ignore = ["SIGFPE", "SIGBUS", "SIGINT"]
for signal_name in expected_signals:
signo = lldbutil.get_signal_number(signal_name)
self.expect_signal(signo)
if signal_name == "SIGALRM":
self.ignore_signals(signals_to_ignore)
self.expect_exit_code(len(signals_to_ignore))
def inferior_abort_received(self):
procs = self.prep_debug_monitor_and_inferior(inferior_args=["abort"])
self.assertIsNotNone(procs)
self.test_sequence.add_log_lines([
"read packet: $vCont;c#a8",
{"direction":"send", "regex":r"^\$T([0-9a-fA-F]{2}).*#[0-9a-fA-F]{2}$", "capture":{ 1:"hex_exit_code"} },
], True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
hex_exit_code = context.get("hex_exit_code")
self.assertIsNotNone(hex_exit_code)
self.assertEqual(int(hex_exit_code, 16),
lldbutil.get_signal_number('SIGABRT'))
def run_and_check_name(self, expected_name):
self.test_sequence.add_log_lines(["read packet: $vCont;c#a8",
{"direction": "send",
"regex":
r"^\$T([0-9a-fA-F]{2})([^#]+)#[0-9a-fA-F]{2}$",
"capture": {
1: "signal",
2: "key_vals_text"}},
],
True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
sigint = lldbutil.get_signal_number("SIGINT")
self.assertEqual(sigint, int(context.get("signal"), 16))
kv_dict = self.parse_key_val_dict(context.get("key_vals_text"))
self.assertEqual(expected_name, kv_dict.get("name"))
def run_and_check_name(self, expected_name):
self.test_sequence.add_log_lines(["read packet: $vCont;c#a8",
{"direction": "send",
"regex":
r"^\$T([0-9a-fA-F]{2})([^#]+)#[0-9a-fA-F]{2}$",
"capture": {
1: "signal",
2: "key_vals_text"}},
],
True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
sigint = lldbutil.get_signal_number("SIGINT")
self.assertEqual(sigint, int(context.get("signal"), 16))
kv_dict = self.parse_key_val_dict(context.get("key_vals_text"))
self.assertEqual(expected_name, kv_dict.get("name"))
def inferior_abort_received(self):
procs = self.prep_debug_monitor_and_inferior(inferior_args=["abort"])
self.assertIsNotNone(procs)
self.test_sequence.add_log_lines(["read packet: $vCont;c#a8",
{"direction": "send",
"regex": r"^\$T([0-9a-fA-F]{2}).*#[0-9a-fA-F]{2}$",
"capture": {1: "hex_exit_code"}},
],
True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
hex_exit_code = context.get("hex_exit_code")
self.assertIsNotNone(hex_exit_code)
self.assertEqual(int(hex_exit_code, 16),
lldbutil.get_signal_number('SIGABRT'))
def signal_name_to_hex(signame):
return format(lldbutil.get_signal_number(signame), 'x')
def test_inferior_seg_fault_received_llgs(self):
self.build()
self.inferior_seg_fault_received(lldbutil.get_signal_number('SIGSEGV'))
def test_with_run_command(self):
"""Test that lldb command 'process signal SIGUSR1' sends a signal to the inferior process."""
self.build()
exe = self.getBuildArtifact("a.out")
# Create a target by the debugger.
target = self.dbg.CreateTarget(exe)
self.assertTrue(target, VALID_TARGET)
# Now create a breakpoint on main.c by name 'c'.
breakpoint = target.BreakpointCreateByLocation('main.c', self.line)
self.assertTrue(breakpoint and
breakpoint.GetNumLocations() == 1,
VALID_BREAKPOINT)
# Get the breakpoint location from breakpoint after we verified that,
# indeed, it has one location.
location = breakpoint.GetLocationAtIndex(0)
self.assertTrue(location and
location.IsEnabled(),
VALID_BREAKPOINT_LOCATION)
# Now launch the process, no arguments & do not stop at entry point.
launch_info = target.GetLaunchInfo()
launch_info.SetWorkingDirectory(self.get_process_working_directory())
process_listener = lldb.SBListener("signal_test_listener")
launch_info.SetListener(process_listener)
error = lldb.SBError()
process = target.Launch(launch_info, error)
self.assertTrue(process, PROCESS_IS_VALID)
self.runCmd("process handle -n False -p True -s True SIGUSR1")
thread = lldbutil.get_stopped_thread(
process, lldb.eStopReasonBreakpoint)
self.assertTrue(thread.IsValid(), "We hit the first breakpoint.")
# After resuming the process, send it a SIGUSR1 signal.
self.setAsync(True)
self.assertTrue(
process_listener.IsValid(),
"Got a good process listener")
# Disable our breakpoint, we don't want to hit it anymore...
breakpoint.SetEnabled(False)
# Now continue:
process.Continue()
# If running remote test, there should be a connected event
if lldb.remote_platform:
self.match_state(process_listener, lldb.eStateConnected)
self.match_state(process_listener, lldb.eStateRunning)
# Now signal the process, and make sure it stops:
process.Signal(lldbutil.get_signal_number('SIGUSR1'))
self.match_state(process_listener, lldb.eStateStopped)
# Now make sure the thread was stopped with a SIGUSR1:
threads = lldbutil.get_stopped_threads(process, lldb.eStopReasonSignal)
self.assertEquals(len(threads), 1, "One thread stopped for a signal.")
thread = threads[0]
self.assertTrue(
thread.GetStopReasonDataCount() >= 1,
"There was data in the event.")
self.assertTrue(
thread.GetStopReasonDataAtIndex(0) == lldbutil.get_signal_number('SIGUSR1'),
"The stop signal was SIGUSR1")
def test_inferior_seg_fault_received_llgs(self):
self.init_llgs_test()
self.build()
self.inferior_seg_fault_received(lldbutil.get_signal_number('SIGSEGV'))
def breakpoint_set_and_remove_work(self, want_hardware):
# Start up the inferior.
procs = self.prep_debug_monitor_and_inferior(inferior_args=[
"get-code-address-hex:hello", "sleep:1", "call-function:hello"
])
# Run the process
self.add_register_info_collection_packets()
self.add_process_info_collection_packets()
self.test_sequence.add_log_lines(
[ # Start running after initial stop.
"read packet: $c#63",
# Match output line that prints the memory address of the function call entry point.
# Note we require launch-only testing so we can get inferior otuput.
{
"type":
"output_match",
"regex":
self.maybe_strict_output_regex(
r"code address: 0x([0-9a-fA-F]+)\r\n"),
"capture": {
1: "function_address"
}
},
# Now stop the inferior.
"read packet: {}".format(chr(3)),
# And wait for the stop notification.
{
"direction": "send",
"regex": r"^\$T([0-9a-fA-F]{2})thread:([0-9a-fA-F]+);",
"capture": {
1: "stop_signo",
2: "stop_thread_id"
}
}
],
True)
# Run the packet stream.
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
# Gather process info - we need endian of target to handle register
# value conversions.
process_info = self.parse_process_info_response(context)
endian = process_info.get("endian")
self.assertIsNotNone(endian)
# Gather register info entries.
reg_infos = self.parse_register_info_packets(context)
(pc_lldb_reg_index, pc_reg_info) = self.find_pc_reg_info(reg_infos)
self.assertIsNotNone(pc_lldb_reg_index)
self.assertIsNotNone(pc_reg_info)
# Grab the function address.
self.assertIsNotNone(context.get("function_address"))
function_address = int(context.get("function_address"), 16)
# Get current target architecture
target_arch = self.getArchitecture()
# Set the breakpoint.
if (target_arch == "arm") or (target_arch == "aarch64"):
# TODO: Handle case when setting breakpoint in thumb code
BREAKPOINT_KIND = 4
else:
BREAKPOINT_KIND = 1
# Set default packet type to Z0 (software breakpoint)
z_packet_type = 0
# If hardware breakpoint is requested set packet type to Z1
if want_hardware == True:
z_packet_type = 1
self.reset_test_sequence()
self.add_set_breakpoint_packets(function_address,
z_packet_type,
do_continue=True,
breakpoint_kind=BREAKPOINT_KIND)
# Run the packet stream.
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
# Verify the stop signal reported was the breakpoint signal number.
stop_signo = context.get("stop_signo")
self.assertIsNotNone(stop_signo)
self.assertEqual(int(stop_signo, 16),
lldbutil.get_signal_number('SIGTRAP'))
# Ensure we did not receive any output. If the breakpoint was not set, we would
# see output (from a launched process with captured stdio) printing a hello, world message.
# That would indicate the breakpoint didn't take.
self.assertEqual(len(context["O_content"]), 0)
# Verify that the PC for the main thread is where we expect it - right at the breakpoint address.
# This acts as a another validation on the register reading code.
self.reset_test_sequence()
self.test_sequence.add_log_lines(
[
# Print the PC. This should match the breakpoint address.
"read packet: $p{0:x}#00".format(pc_lldb_reg_index),
# Capture $p results.
{
"direction": "send",
"regex": r"^\$([0-9a-fA-F]+)#",
"capture": {
1: "p_response"
}
},
],
True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
# Verify the PC is where we expect. Note response is in endianness of
# the inferior.
p_response = context.get("p_response")
self.assertIsNotNone(p_response)
# Convert from target endian to int.
returned_pc = lldbgdbserverutils.unpack_register_hex_unsigned(
endian, p_response)
self.assertEqual(returned_pc, function_address)
# Verify that a breakpoint remove and continue gets us the expected
# output.
self.reset_test_sequence()
# Add breakpoint remove packets
self.add_remove_breakpoint_packets(function_address,
z_packet_type,
breakpoint_kind=BREAKPOINT_KIND)
self.test_sequence.add_log_lines(
[
# Continue running.
"read packet: $c#63",
# We should now receive the output from the call.
{
"type": "output_match",
"regex": r"^hello, world\r\n$"
},
# And wait for program completion.
{
"direction": "send",
"regex": r"^\$W00(.*)#[0-9a-fA-F]{2}$"
},
],
True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
def signal_name_to_hex(signame):
return format(lldbutil.get_signal_number(signame), 'x')
def test_with_run_command(self):
"""Test that lldb command 'process signal SIGUSR1' sends a signal to the inferior process."""
self.build()
exe = os.path.join(os.getcwd(), "a.out")
# Create a target by the debugger.
target = self.dbg.CreateTarget(exe)
self.assertTrue(target, VALID_TARGET)
# Now create a breakpoint on main.c by name 'c'.
breakpoint = target.BreakpointCreateByLocation('main.c', self.line)
self.assertTrue(breakpoint and
breakpoint.GetNumLocations() == 1,
VALID_BREAKPOINT)
# Get the breakpoint location from breakpoint after we verified that,
# indeed, it has one location.
location = breakpoint.GetLocationAtIndex(0)
self.assertTrue(location and
location.IsEnabled(),
VALID_BREAKPOINT_LOCATION)
# Now launch the process, no arguments & do not stop at entry point.
launch_info = lldb.SBLaunchInfo([exe])
launch_info.SetWorkingDirectory(self.get_process_working_directory())
process_listener = lldb.SBListener("signal_test_listener")
launch_info.SetListener(process_listener)
error = lldb.SBError()
process = target.Launch(launch_info, error)
self.assertTrue(process, PROCESS_IS_VALID)
self.runCmd("process handle -n False -p True -s True SIGUSR1")
thread = lldbutil.get_stopped_thread(process, lldb.eStopReasonBreakpoint)
self.assertTrue(thread.IsValid(), "We hit the first breakpoint.")
# After resuming the process, send it a SIGUSR1 signal.
self.setAsync(True)
self.assertTrue(process_listener.IsValid(), "Got a good process listener")
# Disable our breakpoint, we don't want to hit it anymore...
breakpoint.SetEnabled(False)
# Now continue:
process.Continue()
# If running remote test, there should be a connected event
if lldb.remote_platform:
self.match_state(process_listener, lldb.eStateConnected)
self.match_state(process_listener, lldb.eStateRunning)
# Now signal the process, and make sure it stops:
process.Signal(lldbutil.get_signal_number('SIGUSR1'))
self.match_state(process_listener, lldb.eStateStopped)
# Now make sure the thread was stopped with a SIGUSR1:
threads = lldbutil.get_stopped_threads(process, lldb.eStopReasonSignal)
self.assertTrue(len(threads) == 1, "One thread stopped for a signal.")
thread = threads[0]
self.assertTrue(thread.GetStopReasonDataCount() >= 1, "There was data in the event.")
self.assertTrue(thread.GetStopReasonDataAtIndex(0) == lldbutil.get_signal_number('SIGUSR1'),
"The stop signal was SIGUSR1")
def Hc_then_Csignal_signals_correct_thread(self, segfault_signo):
# NOTE only run this one in inferior-launched mode: we can't grab inferior stdout when running attached,
# and the test requires getting stdout from the exe.
NUM_THREADS = 3
# Startup the inferior with three threads (main + NUM_THREADS-1 worker threads).
# inferior_args=["thread:print-ids"]
inferior_args = ["thread:segfault"]
for i in range(NUM_THREADS - 1):
# if i > 0:
# Give time between thread creation/segfaulting for the handler to work.
# inferior_args.append("sleep:1")
inferior_args.append("thread:new")
inferior_args.append("sleep:10")
# Launch/attach. (In our case, this should only ever be launched since
# we need inferior stdout/stderr).
procs = self.prep_debug_monitor_and_inferior(
inferior_args=inferior_args)
self.test_sequence.add_log_lines(["read packet: $c#63"], True)
context = self.expect_gdbremote_sequence()
# Let the inferior process have a few moments to start up the thread when launched.
# context = self.run_process_then_stop(run_seconds=1)
# Wait at most x seconds for all threads to be present.
# threads = self.wait_for_thread_count(NUM_THREADS)
# self.assertEquals(len(threads), NUM_THREADS)
signaled_tids = {}
print_thread_ids = {}
# Switch to each thread, deliver a signal, and verify signal delivery
for i in range(NUM_THREADS - 1):
# Run until SIGSEGV comes in.
self.reset_test_sequence()
self.test_sequence.add_log_lines([{
"direction": "send",
"regex": r"^\$T([0-9a-fA-F]{2})thread:([0-9a-fA-F]+);",
"capture": {
1: "signo",
2: "thread_id"
}
}], True)
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
signo = context.get("signo")
self.assertEqual(int(signo, 16), segfault_signo)
# Ensure we haven't seen this tid yet.
thread_id = int(context.get("thread_id"), 16)
self.assertFalse(thread_id in signaled_tids)
signaled_tids[thread_id] = 1
# Send SIGUSR1 to the thread that signaled the SIGSEGV.
self.reset_test_sequence()
self.test_sequence.add_log_lines(
[
# Set the continue thread.
# Set current thread.
"read packet: $Hc{0:x}#00".format(thread_id),
"send packet: $OK#00",
# Continue sending the signal number to the continue thread.
# The commented out packet is a way to do this same operation without using
# a $Hc (but this test is testing $Hc, so we'll stick with the former).
"read packet: $C{0:x}#00".format(
lldbutil.get_signal_number('SIGUSR1')),
# "read packet: $vCont;C{0:x}:{1:x};c#00".format(lldbutil.get_signal_number('SIGUSR1'), thread_id),
# FIXME: Linux does not report the thread stop on the delivered signal (SIGUSR1 here). MacOSX debugserver does.
# But MacOSX debugserver isn't guaranteeing the thread the signal handler runs on, so currently its an XFAIL.
# Need to rectify behavior here. The linux behavior is more intuitive to me since we're essentially swapping out
# an about-to-be-delivered signal (for which we already sent a stop packet) to a different signal.
# {"direction":"send", "regex":r"^\$T([0-9a-fA-F]{2})thread:([0-9a-fA-F]+);", "capture":{1:"stop_signo", 2:"stop_thread_id"} },
# "read packet: $c#63",
{
"type": "output_match",
"regex":
r"^received SIGUSR1 on thread id: ([0-9a-fA-F]+)\r\nthread ([0-9a-fA-F]+): past SIGSEGV\r\n",
"capture": {
1: "print_thread_id",
2: "post_handle_thread_id"
}
},
],
True)
# Run the sequence.
context = self.expect_gdbremote_sequence()
self.assertIsNotNone(context)
# Ensure the stop signal is the signal we delivered.
# stop_signo = context.get("stop_signo")
# self.assertIsNotNone(stop_signo)
# self.assertEquals(int(stop_signo,16), lldbutil.get_signal_number('SIGUSR1'))
# Ensure the stop thread is the thread to which we delivered the signal.
# stop_thread_id = context.get("stop_thread_id")
# self.assertIsNotNone(stop_thread_id)
# self.assertEquals(int(stop_thread_id,16), thread_id)
# Ensure we haven't seen this thread id yet. The inferior's
# self-obtained thread ids are not guaranteed to match the stub
# tids (at least on MacOSX).
print_thread_id = context.get("print_thread_id")
self.assertIsNotNone(print_thread_id)
print_thread_id = int(print_thread_id, 16)
self.assertFalse(print_thread_id in print_thread_ids)
# Now remember this print (i.e. inferior-reflected) thread id and
# ensure we don't hit it again.
print_thread_ids[print_thread_id] = 1
# Ensure post signal-handle thread id matches the thread that
# initially raised the SIGSEGV.
post_handle_thread_id = context.get("post_handle_thread_id")
self.assertIsNotNone(post_handle_thread_id)
post_handle_thread_id = int(post_handle_thread_id, 16)
self.assertEqual(post_handle_thread_id, print_thread_id)
