//===-- GDBRemoteClientBase.cpp -------------------------------------------===// // // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions. // See https://llvm.org/LICENSE.txt for license information. // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception // //===----------------------------------------------------------------------===// #include "GDBRemoteClientBase.h" #include "llvm/ADT/StringExtras.h" #include "lldb/Target/UnixSignals.h" #include "lldb/Utility/LLDBAssert.h" #include "ProcessGDBRemoteLog.h" using namespace lldb; using namespace lldb_private; using namespace lldb_private::process_gdb_remote; using namespace std::chrono; // When we've sent a continue packet and are waiting for the target to stop, // we wake up the wait with this interval to make sure the stub hasn't gone // away while we were waiting. static const seconds kWakeupInterval(5); ///////////////////////// // GDBRemoteClientBase // ///////////////////////// GDBRemoteClientBase::ContinueDelegate::~ContinueDelegate() = default; GDBRemoteClientBase::GDBRemoteClientBase(const char *comm_name) : GDBRemoteCommunication(), Broadcaster(nullptr, comm_name), m_async_count(0), m_is_running(false), m_should_stop(false) {} StateType GDBRemoteClientBase::SendContinuePacketAndWaitForResponse( ContinueDelegate &delegate, const UnixSignals &signals, llvm::StringRef payload, std::chrono::seconds interrupt_timeout, StringExtractorGDBRemote &response) { Log *log = GetLog(GDBRLog::Process); response.Clear(); { std::lock_guard lock(m_mutex); m_continue_packet = std::string(payload); m_should_stop = false; } ContinueLock cont_lock(*this); if (!cont_lock) return eStateInvalid; OnRunPacketSent(true); // The main ReadPacket loop wakes up at computed_timeout intervals, just to // check that the connection hasn't dropped. When we wake up we also check // whether there is an interrupt request that has reached its endpoint. // If we want a shorter interrupt timeout that kWakeupInterval, we need to // choose the shorter interval for the wake up as well. std::chrono::seconds computed_timeout = std::min(interrupt_timeout, kWakeupInterval); for (;;) { PacketResult read_result = ReadPacket(response, computed_timeout, false); // Reset the computed_timeout to the default value in case we are going // round again. computed_timeout = std::min(interrupt_timeout, kWakeupInterval); switch (read_result) { case PacketResult::ErrorReplyTimeout: { std::lock_guard lock(m_mutex); if (m_async_count == 0) { continue; } auto cur_time = steady_clock::now(); if (cur_time >= m_interrupt_endpoint) return eStateInvalid; else { // We woke up and found an interrupt is in flight, but we haven't // exceeded the interrupt wait time. So reset the wait time to the // time left till the interrupt timeout. But don't wait longer // than our wakeup timeout. auto new_wait = m_interrupt_endpoint - cur_time; computed_timeout = std::min(kWakeupInterval, std::chrono::duration_cast(new_wait)); continue; } break; } case PacketResult::Success: break; default: LLDB_LOGF(log, "GDBRemoteClientBase::%s () ReadPacket(...) => false", __FUNCTION__); return eStateInvalid; } if (response.Empty()) return eStateInvalid; const char stop_type = response.GetChar(); LLDB_LOGF(log, "GDBRemoteClientBase::%s () got packet: %s", __FUNCTION__, response.GetStringRef().data()); switch (stop_type) { case 'W': case 'X': return eStateExited; case 'E': // ERROR return eStateInvalid; default: LLDB_LOGF(log, "GDBRemoteClientBase::%s () unrecognized async packet", __FUNCTION__); return eStateInvalid; case 'O': { std::string inferior_stdout; response.GetHexByteString(inferior_stdout); delegate.HandleAsyncStdout(inferior_stdout); break; } case 'A': delegate.HandleAsyncMisc( llvm::StringRef(response.GetStringRef()).substr(1)); break; case 'J': delegate.HandleAsyncStructuredDataPacket(response.GetStringRef()); break; case 'T': case 'S': // Do this with the continue lock held. const bool should_stop = ShouldStop(signals, response); response.SetFilePos(0); // The packet we should resume with. In the future we should check our // thread list and "do the right thing" for new threads that show up // while we stop and run async packets. Setting the packet to 'c' to // continue all threads is the right thing to do 99.99% of the time // because if a thread was single stepping, and we sent an interrupt, we // will notice above that we didn't stop due to an interrupt but stopped // due to stepping and we would _not_ continue. This packet may get // modified by the async actions (e.g. to send a signal). m_continue_packet = 'c'; cont_lock.unlock(); delegate.HandleStopReply(); if (should_stop) return eStateStopped; switch (cont_lock.lock()) { case ContinueLock::LockResult::Success: break; case ContinueLock::LockResult::Failed: return eStateInvalid; case ContinueLock::LockResult::Cancelled: return eStateStopped; } OnRunPacketSent(false); break; } } } bool GDBRemoteClientBase::SendAsyncSignal( int signo, std::chrono::seconds interrupt_timeout) { Lock lock(*this, interrupt_timeout); if (!lock || !lock.DidInterrupt()) return false; m_continue_packet = 'C'; m_continue_packet += llvm::hexdigit((signo / 16) % 16); m_continue_packet += llvm::hexdigit(signo % 16); return true; } bool GDBRemoteClientBase::Interrupt(std::chrono::seconds interrupt_timeout) { Lock lock(*this, interrupt_timeout); if (!lock.DidInterrupt()) return false; m_should_stop = true; return true; } GDBRemoteCommunication::PacketResult GDBRemoteClientBase::SendPacketAndWaitForResponse( llvm::StringRef payload, StringExtractorGDBRemote &response, std::chrono::seconds interrupt_timeout) { Lock lock(*this, interrupt_timeout); if (!lock) { if (Log *log = GetLog(GDBRLog::Process)) LLDB_LOGF(log, "GDBRemoteClientBase::%s failed to get mutex, not sending " "packet '%.*s'", __FUNCTION__, int(payload.size()), payload.data()); return PacketResult::ErrorSendFailed; } return SendPacketAndWaitForResponseNoLock(payload, response); } GDBRemoteCommunication::PacketResult GDBRemoteClientBase::ReadPacketWithOutputSupport( StringExtractorGDBRemote &response, Timeout timeout, bool sync_on_timeout, llvm::function_ref output_callback) { auto result = ReadPacket(response, timeout, sync_on_timeout); while (result == PacketResult::Success && response.IsNormalResponse() && response.PeekChar() == 'O') { response.GetChar(); std::string output; if (response.GetHexByteString(output)) output_callback(output); result = ReadPacket(response, timeout, sync_on_timeout); } return result; } GDBRemoteCommunication::PacketResult GDBRemoteClientBase::SendPacketAndReceiveResponseWithOutputSupport( llvm::StringRef payload, StringExtractorGDBRemote &response, std::chrono::seconds interrupt_timeout, llvm::function_ref output_callback) { Lock lock(*this, interrupt_timeout); if (!lock) { if (Log *log = GetLog(GDBRLog::Process)) LLDB_LOGF(log, "GDBRemoteClientBase::%s failed to get mutex, not sending " "packet '%.*s'", __FUNCTION__, int(payload.size()), payload.data()); return PacketResult::ErrorSendFailed; } PacketResult packet_result = SendPacketNoLock(payload); if (packet_result != PacketResult::Success) return packet_result; return ReadPacketWithOutputSupport(response, GetPacketTimeout(), true, output_callback); } GDBRemoteCommunication::PacketResult GDBRemoteClientBase::SendPacketAndWaitForResponseNoLock( llvm::StringRef payload, StringExtractorGDBRemote &response) { PacketResult packet_result = SendPacketNoLock(payload); if (packet_result != PacketResult::Success) return packet_result; const size_t max_response_retries = 3; for (size_t i = 0; i < max_response_retries; ++i) { packet_result = ReadPacket(response, GetPacketTimeout(), true); // Make sure we received a response if (packet_result != PacketResult::Success) return packet_result; // Make sure our response is valid for the payload that was sent if (response.ValidateResponse()) return packet_result; // Response says it wasn't valid Log *log = GetLog(GDBRLog::Packets); LLDB_LOGF( log, "error: packet with payload \"%.*s\" got invalid response \"%s\": %s", int(payload.size()), payload.data(), response.GetStringRef().data(), (i == (max_response_retries - 1)) ? "using invalid response and giving up" : "ignoring response and waiting for another"); } return packet_result; } bool GDBRemoteClientBase::ShouldStop(const UnixSignals &signals, StringExtractorGDBRemote &response) { std::lock_guard lock(m_mutex); if (m_async_count == 0) return true; // We were not interrupted. The process stopped on its own. // Older debugserver stubs (before April 2016) can return two stop-reply // packets in response to a ^C packet. Additionally, all debugservers still // return two stop replies if the inferior stops due to some other reason // before the remote stub manages to interrupt it. We need to wait for this // additional packet to make sure the packet sequence does not get skewed. StringExtractorGDBRemote extra_stop_reply_packet; ReadPacket(extra_stop_reply_packet, milliseconds(100), false); // Interrupting is typically done using SIGSTOP or SIGINT, so if the process // stops with some other signal, we definitely want to stop. const uint8_t signo = response.GetHexU8(UINT8_MAX); if (signo != signals.GetSignalNumberFromName("SIGSTOP") && signo != signals.GetSignalNumberFromName("SIGINT")) return true; // We probably only stopped to perform some async processing, so continue // after that is done. // TODO: This is not 100% correct, as the process may have been stopped with // SIGINT or SIGSTOP that was not caused by us (e.g. raise(SIGINT)). This will // normally cause a stop, but if it's done concurrently with a async // interrupt, that stop will get eaten (llvm.org/pr20231). return false; } void GDBRemoteClientBase::OnRunPacketSent(bool first) { if (first) BroadcastEvent(eBroadcastBitRunPacketSent, nullptr); } /////////////////////////////////////// // GDBRemoteClientBase::ContinueLock // /////////////////////////////////////// GDBRemoteClientBase::ContinueLock::ContinueLock(GDBRemoteClientBase &comm) : m_comm(comm), m_acquired(false) { lock(); } GDBRemoteClientBase::ContinueLock::~ContinueLock() { if (m_acquired) unlock(); } void GDBRemoteClientBase::ContinueLock::unlock() { lldbassert(m_acquired); { std::unique_lock lock(m_comm.m_mutex); m_comm.m_is_running = false; } m_comm.m_cv.notify_all(); m_acquired = false; } GDBRemoteClientBase::ContinueLock::LockResult GDBRemoteClientBase::ContinueLock::lock() { Log *log = GetLog(GDBRLog::Process); LLDB_LOGF(log, "GDBRemoteClientBase::ContinueLock::%s() resuming with %s", __FUNCTION__, m_comm.m_continue_packet.c_str()); lldbassert(!m_acquired); std::unique_lock lock(m_comm.m_mutex); m_comm.m_cv.wait(lock, [this] { return m_comm.m_async_count == 0; }); if (m_comm.m_should_stop) { m_comm.m_should_stop = false; LLDB_LOGF(log, "GDBRemoteClientBase::ContinueLock::%s() cancelled", __FUNCTION__); return LockResult::Cancelled; } if (m_comm.SendPacketNoLock(m_comm.m_continue_packet) != PacketResult::Success) return LockResult::Failed; lldbassert(!m_comm.m_is_running); m_comm.m_is_running = true; m_acquired = true; return LockResult::Success; } /////////////////////////////// // GDBRemoteClientBase::Lock // /////////////////////////////// GDBRemoteClientBase::Lock::Lock(GDBRemoteClientBase &comm, std::chrono::seconds interrupt_timeout) : m_async_lock(comm.m_async_mutex, std::defer_lock), m_comm(comm), m_interrupt_timeout(interrupt_timeout), m_acquired(false), m_did_interrupt(false) { SyncWithContinueThread(); if (m_acquired) m_async_lock.lock(); } void GDBRemoteClientBase::Lock::SyncWithContinueThread() { Log *log = GetLog(GDBRLog::Process|GDBRLog::Packets); std::unique_lock lock(m_comm.m_mutex); if (m_comm.m_is_running && m_interrupt_timeout == std::chrono::seconds(0)) return; // We were asked to avoid interrupting the sender. Lock is not // acquired. ++m_comm.m_async_count; if (m_comm.m_is_running) { if (m_comm.m_async_count == 1) { // The sender has sent the continue packet and we are the first async // packet. Let's interrupt it. const char ctrl_c = '\x03'; ConnectionStatus status = eConnectionStatusSuccess; size_t bytes_written = m_comm.Write(&ctrl_c, 1, status, nullptr); if (bytes_written == 0) { --m_comm.m_async_count; LLDB_LOGF(log, "GDBRemoteClientBase::Lock::Lock failed to send " "interrupt packet"); return; } m_comm.m_interrupt_endpoint = steady_clock::now() + m_interrupt_timeout; if (log) log->PutCString("GDBRemoteClientBase::Lock::Lock sent packet: \\x03"); } m_comm.m_cv.wait(lock, [this] { return !m_comm.m_is_running; }); m_did_interrupt = true; } m_acquired = true; } GDBRemoteClientBase::Lock::~Lock() { if (!m_acquired) return; { std::unique_lock lock(m_comm.m_mutex); --m_comm.m_async_count; } m_comm.m_cv.notify_one(); }