//===-- GDBRemoteCommunicationClient.cpp ------------------------*- C++ -*-===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
#include "GDBRemoteCommunicationClient.h"
// C Includes
#include <sys/stat.h>
// C++ Includes
#include <sstream>
// Other libraries and framework includes
#include "llvm/ADT/Triple.h"
#include "lldb/Interpreter/Args.h"
#include "lldb/Core/ConnectionFileDescriptor.h"
#include "lldb/Core/Log.h"
#include "lldb/Core/State.h"
#include "lldb/Core/StreamGDBRemote.h"
#include "lldb/Core/StreamString.h"
#include "lldb/Host/Endian.h"
#include "lldb/Host/Host.h"
#include "lldb/Host/TimeValue.h"
// Project includes
#include "Utility/StringExtractorGDBRemote.h"
#include "ProcessGDBRemote.h"
#include "ProcessGDBRemoteLog.h"
#include "lldb/Host/Config.h"
using namespace lldb;
using namespace lldb_private;
#ifdef LLDB_DISABLE_POSIX
#define SIGSTOP 17
#endif
//----------------------------------------------------------------------
// GDBRemoteCommunicationClient constructor
//----------------------------------------------------------------------
GDBRemoteCommunicationClient::GDBRemoteCommunicationClient(bool is_platform) :
GDBRemoteCommunication("gdb-remote.client", "gdb-remote.client.rx_packet", is_platform),
m_supports_not_sending_acks (eLazyBoolCalculate),
m_supports_thread_suffix (eLazyBoolCalculate),
m_supports_threads_in_stop_reply (eLazyBoolCalculate),
m_supports_vCont_all (eLazyBoolCalculate),
m_supports_vCont_any (eLazyBoolCalculate),
m_supports_vCont_c (eLazyBoolCalculate),
m_supports_vCont_C (eLazyBoolCalculate),
m_supports_vCont_s (eLazyBoolCalculate),
m_supports_vCont_S (eLazyBoolCalculate),
m_qHostInfo_is_valid (eLazyBoolCalculate),
m_qProcessInfo_is_valid (eLazyBoolCalculate),
m_supports_alloc_dealloc_memory (eLazyBoolCalculate),
m_supports_memory_region_info (eLazyBoolCalculate),
m_supports_watchpoint_support_info (eLazyBoolCalculate),
m_supports_detach_stay_stopped (eLazyBoolCalculate),
m_watchpoints_trigger_after_instruction(eLazyBoolCalculate),
m_attach_or_wait_reply(eLazyBoolCalculate),
m_prepare_for_reg_writing_reply (eLazyBoolCalculate),
m_supports_p (eLazyBoolCalculate),
m_supports_QSaveRegisterState (eLazyBoolCalculate),
m_supports_qXfer_libraries_read (eLazyBoolCalculate),
m_supports_qXfer_libraries_svr4_read (eLazyBoolCalculate),
m_supports_augmented_libraries_svr4_read (eLazyBoolCalculate),
m_supports_qProcessInfoPID (true),
m_supports_qfProcessInfo (true),
m_supports_qUserName (true),
m_supports_qGroupName (true),
m_supports_qThreadStopInfo (true),
m_supports_z0 (true),
m_supports_z1 (true),
m_supports_z2 (true),
m_supports_z3 (true),
m_supports_z4 (true),
m_supports_QEnvironment (true),
m_supports_QEnvironmentHexEncoded (true),
m_curr_tid (LLDB_INVALID_THREAD_ID),
m_curr_tid_run (LLDB_INVALID_THREAD_ID),
m_num_supported_hardware_watchpoints (0),
m_async_mutex (Mutex::eMutexTypeRecursive),
m_async_packet_predicate (false),
m_async_packet (),
m_async_result (PacketResult::Success),
m_async_response (),
m_async_signal (-1),
m_thread_id_to_used_usec_map (),
m_host_arch(),
m_process_arch(),
m_os_version_major (UINT32_MAX),
m_os_version_minor (UINT32_MAX),
m_os_version_update (UINT32_MAX),
m_os_build (),
m_os_kernel (),
m_hostname (),
m_default_packet_timeout (0),
m_max_packet_size (0)
{
}
//----------------------------------------------------------------------
// Destructor
//----------------------------------------------------------------------
GDBRemoteCommunicationClient::~GDBRemoteCommunicationClient()
{
if (IsConnected())
Disconnect();
}
bool
GDBRemoteCommunicationClient::HandshakeWithServer (Error *error_ptr)
{
ResetDiscoverableSettings();
// Start the read thread after we send the handshake ack since if we
// fail to send the handshake ack, there is no reason to continue...
if (SendAck())
{
// Wait for any responses that might have been queued up in the remote
// GDB server and flush them all
StringExtractorGDBRemote response;
PacketResult packet_result = PacketResult::Success;
const uint32_t timeout_usec = 10 * 1000; // Wait for 10 ms for a response
while (packet_result == PacketResult::Success)
packet_result = WaitForPacketWithTimeoutMicroSecondsNoLock (response, timeout_usec);
// The return value from QueryNoAckModeSupported() is true if the packet
// was sent and _any_ response (including UNIMPLEMENTED) was received),
// or false if no response was received. This quickly tells us if we have
// a live connection to a remote GDB server...
if (QueryNoAckModeSupported())
{
#if 0
// Set above line to "#if 1" to test packet speed if remote GDB server
// supports the qSpeedTest packet...
TestPacketSpeed(10000);
#endif
return true;
}
else
{
if (error_ptr)
error_ptr->SetErrorString("failed to get reply to handshake packet");
}
}
else
{
if (error_ptr)
error_ptr->SetErrorString("failed to send the handshake ack");
}
return false;
}
bool
GDBRemoteCommunicationClient::GetAugmentedLibrariesSVR4ReadSupported ()
{
if (m_supports_augmented_libraries_svr4_read == eLazyBoolCalculate)
{
GetRemoteQSupported();
}
return (m_supports_augmented_libraries_svr4_read == eLazyBoolYes);
}
bool
GDBRemoteCommunicationClient::GetQXferLibrariesSVR4ReadSupported ()
{
if (m_supports_qXfer_libraries_svr4_read == eLazyBoolCalculate)
{
GetRemoteQSupported();
}
return (m_supports_qXfer_libraries_svr4_read == eLazyBoolYes);
}
bool
GDBRemoteCommunicationClient::GetQXferLibrariesReadSupported ()
{
if (m_supports_qXfer_libraries_read == eLazyBoolCalculate)
{
GetRemoteQSupported();
}
return (m_supports_qXfer_libraries_read == eLazyBoolYes);
}
uint64_t
GDBRemoteCommunicationClient::GetRemoteMaxPacketSize()
{
if (m_max_packet_size == 0)
{
GetRemoteQSupported();
}
return m_max_packet_size;
}
bool
GDBRemoteCommunicationClient::QueryNoAckModeSupported ()
{
if (m_supports_not_sending_acks == eLazyBoolCalculate)
{
m_send_acks = true;
m_supports_not_sending_acks = eLazyBoolNo;
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("QStartNoAckMode", response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
{
m_send_acks = false;
m_supports_not_sending_acks = eLazyBoolYes;
}
return true;
}
}
return false;
}
void
GDBRemoteCommunicationClient::GetListThreadsInStopReplySupported ()
{
if (m_supports_threads_in_stop_reply == eLazyBoolCalculate)
{
m_supports_threads_in_stop_reply = eLazyBoolNo;
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("QListThreadsInStopReply", response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
m_supports_threads_in_stop_reply = eLazyBoolYes;
}
}
}
bool
GDBRemoteCommunicationClient::GetVAttachOrWaitSupported ()
{
if (m_attach_or_wait_reply == eLazyBoolCalculate)
{
m_attach_or_wait_reply = eLazyBoolNo;
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("qVAttachOrWaitSupported", response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
m_attach_or_wait_reply = eLazyBoolYes;
}
}
if (m_attach_or_wait_reply == eLazyBoolYes)
return true;
else
return false;
}
bool
GDBRemoteCommunicationClient::GetSyncThreadStateSupported ()
{
if (m_prepare_for_reg_writing_reply == eLazyBoolCalculate)
{
m_prepare_for_reg_writing_reply = eLazyBoolNo;
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("qSyncThreadStateSupported", response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
m_prepare_for_reg_writing_reply = eLazyBoolYes;
}
}
if (m_prepare_for_reg_writing_reply == eLazyBoolYes)
return true;
else
return false;
}
void
GDBRemoteCommunicationClient::ResetDiscoverableSettings()
{
m_supports_not_sending_acks = eLazyBoolCalculate;
m_supports_thread_suffix = eLazyBoolCalculate;
m_supports_threads_in_stop_reply = eLazyBoolCalculate;
m_supports_vCont_c = eLazyBoolCalculate;
m_supports_vCont_C = eLazyBoolCalculate;
m_supports_vCont_s = eLazyBoolCalculate;
m_supports_vCont_S = eLazyBoolCalculate;
m_supports_p = eLazyBoolCalculate;
m_supports_QSaveRegisterState = eLazyBoolCalculate;
m_qHostInfo_is_valid = eLazyBoolCalculate;
m_qProcessInfo_is_valid = eLazyBoolCalculate;
m_supports_alloc_dealloc_memory = eLazyBoolCalculate;
m_supports_memory_region_info = eLazyBoolCalculate;
m_prepare_for_reg_writing_reply = eLazyBoolCalculate;
m_attach_or_wait_reply = eLazyBoolCalculate;
m_supports_qXfer_libraries_read = eLazyBoolCalculate;
m_supports_qXfer_libraries_svr4_read = eLazyBoolCalculate;
m_supports_augmented_libraries_svr4_read = eLazyBoolCalculate;
m_supports_qProcessInfoPID = true;
m_supports_qfProcessInfo = true;
m_supports_qUserName = true;
m_supports_qGroupName = true;
m_supports_qThreadStopInfo = true;
m_supports_z0 = true;
m_supports_z1 = true;
m_supports_z2 = true;
m_supports_z3 = true;
m_supports_z4 = true;
m_supports_QEnvironment = true;
m_supports_QEnvironmentHexEncoded = true;
m_host_arch.Clear();
m_process_arch.Clear();
m_max_packet_size = 0;
}
void
GDBRemoteCommunicationClient::GetRemoteQSupported ()
{
// Clear out any capabilities we expect to see in the qSupported response
m_supports_qXfer_libraries_svr4_read = eLazyBoolNo;
m_supports_qXfer_libraries_read = eLazyBoolNo;
m_supports_augmented_libraries_svr4_read = eLazyBoolNo;
m_max_packet_size = UINT64_MAX; // It's supposed to always be there, but if not, we assume no limit
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("qSupported",
response,
/*send_async=*/false) == PacketResult::Success)
{
const char *response_cstr = response.GetStringRef().c_str();
if (::strstr (response_cstr, "qXfer:libraries-svr4:read+"))
m_supports_qXfer_libraries_svr4_read = eLazyBoolYes;
if (::strstr (response_cstr, "augmented-libraries-svr4-read"))
{
m_supports_qXfer_libraries_svr4_read = eLazyBoolYes; // implied
m_supports_augmented_libraries_svr4_read = eLazyBoolYes;
}
if (::strstr (response_cstr, "qXfer:libraries:read+"))
m_supports_qXfer_libraries_read = eLazyBoolYes;
const char *packet_size_str = ::strstr (response_cstr, "PacketSize=");
if (packet_size_str)
{
StringExtractorGDBRemote packet_response(packet_size_str + strlen("PacketSize="));
m_max_packet_size = packet_response.GetHexMaxU64(/*little_endian=*/false, UINT64_MAX);
if (m_max_packet_size == 0)
{
m_max_packet_size = UINT64_MAX; // Must have been a garbled response
Log *log (ProcessGDBRemoteLog::GetLogIfAllCategoriesSet (GDBR_LOG_PROCESS));
if (log)
log->Printf ("Garbled PacketSize spec in qSupported response");
}
}
}
}
bool
GDBRemoteCommunicationClient::GetThreadSuffixSupported ()
{
if (m_supports_thread_suffix == eLazyBoolCalculate)
{
StringExtractorGDBRemote response;
m_supports_thread_suffix = eLazyBoolNo;
if (SendPacketAndWaitForResponse("QThreadSuffixSupported", response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
m_supports_thread_suffix = eLazyBoolYes;
}
}
return m_supports_thread_suffix;
}
bool
GDBRemoteCommunicationClient::GetVContSupported (char flavor)
{
if (m_supports_vCont_c == eLazyBoolCalculate)
{
StringExtractorGDBRemote response;
m_supports_vCont_any = eLazyBoolNo;
m_supports_vCont_all = eLazyBoolNo;
m_supports_vCont_c = eLazyBoolNo;
m_supports_vCont_C = eLazyBoolNo;
m_supports_vCont_s = eLazyBoolNo;
m_supports_vCont_S = eLazyBoolNo;
if (SendPacketAndWaitForResponse("vCont?", response, false) == PacketResult::Success)
{
const char *response_cstr = response.GetStringRef().c_str();
if (::strstr (response_cstr, ";c"))
m_supports_vCont_c = eLazyBoolYes;
if (::strstr (response_cstr, ";C"))
m_supports_vCont_C = eLazyBoolYes;
if (::strstr (response_cstr, ";s"))
m_supports_vCont_s = eLazyBoolYes;
if (::strstr (response_cstr, ";S"))
m_supports_vCont_S = eLazyBoolYes;
if (m_supports_vCont_c == eLazyBoolYes &&
m_supports_vCont_C == eLazyBoolYes &&
m_supports_vCont_s == eLazyBoolYes &&
m_supports_vCont_S == eLazyBoolYes)
{
m_supports_vCont_all = eLazyBoolYes;
}
if (m_supports_vCont_c == eLazyBoolYes ||
m_supports_vCont_C == eLazyBoolYes ||
m_supports_vCont_s == eLazyBoolYes ||
m_supports_vCont_S == eLazyBoolYes)
{
m_supports_vCont_any = eLazyBoolYes;
}
}
}
switch (flavor)
{
case 'a': return m_supports_vCont_any;
case 'A': return m_supports_vCont_all;
case 'c': return m_supports_vCont_c;
case 'C': return m_supports_vCont_C;
case 's': return m_supports_vCont_s;
case 'S': return m_supports_vCont_S;
default: break;
}
return false;
}
// Check if the target supports 'p' packet. It sends out a 'p'
// packet and checks the response. A normal packet will tell us
// that support is available.
//
// Takes a valid thread ID because p needs to apply to a thread.
bool
GDBRemoteCommunicationClient::GetpPacketSupported (lldb::tid_t tid)
{
if (m_supports_p == eLazyBoolCalculate)
{
StringExtractorGDBRemote response;
m_supports_p = eLazyBoolNo;
char packet[256];
if (GetThreadSuffixSupported())
snprintf(packet, sizeof(packet), "p0;thread:%" PRIx64 ";", tid);
else
snprintf(packet, sizeof(packet), "p0");
if (SendPacketAndWaitForResponse(packet, response, false) == PacketResult::Success)
{
if (response.IsNormalResponse())
m_supports_p = eLazyBoolYes;
}
}
return m_supports_p;
}
GDBRemoteCommunicationClient::PacketResult
GDBRemoteCommunicationClient::SendPacketsAndConcatenateResponses
(
const char *payload_prefix,
std::string &response_string
)
{
Mutex::Locker locker;
if (!GetSequenceMutex(locker,
"ProcessGDBRemote::SendPacketsAndConcatenateResponses() failed due to not getting the sequence mutex"))
{
Log *log (ProcessGDBRemoteLog::GetLogIfAnyCategoryIsSet (GDBR_LOG_PROCESS | GDBR_LOG_PACKETS));
if (log)
log->Printf("error: failed to get packet sequence mutex, not sending packets with prefix '%s'",
payload_prefix);
return PacketResult::ErrorNoSequenceLock;
}
response_string = "";
std::string payload_prefix_str(payload_prefix);
unsigned int response_size = 0x1000;
if (response_size > GetRemoteMaxPacketSize()) { // May send qSupported packet
response_size = GetRemoteMaxPacketSize();
}
for (unsigned int offset = 0; true; offset += response_size)
{
StringExtractorGDBRemote this_response;
// Construct payload
char sizeDescriptor[128];
snprintf(sizeDescriptor, sizeof(sizeDescriptor), "%x,%x", offset, response_size);
PacketResult result = SendPacketAndWaitForResponse((payload_prefix_str + sizeDescriptor).c_str(),
this_response,
/*send_async=*/false);
if (result != PacketResult::Success)
return result;
const std::string &this_string = this_response.GetStringRef();
// Check for m or l as first character; l seems to mean this is the last chunk
char first_char = *this_string.c_str();
if (first_char != 'm' && first_char != 'l')
{
return PacketResult::ErrorReplyInvalid;
}
// Skip past m or l
const char *s = this_string.c_str() + 1;
// Concatenate the result so far
response_string += s;
if (first_char == 'l')
// We're done
return PacketResult::Success;
}
}
GDBRemoteCommunicationClient::PacketResult
GDBRemoteCommunicationClient::SendPacketAndWaitForResponse
(
const char *payload,
StringExtractorGDBRemote &response,
bool send_async
)
{
return SendPacketAndWaitForResponse (payload,
::strlen (payload),
response,
send_async);
}
GDBRemoteCommunicationClient::PacketResult
GDBRemoteCommunicationClient::SendPacketAndWaitForResponseNoLock (const char *payload,
size_t payload_length,
StringExtractorGDBRemote &response)
{
PacketResult packet_result = SendPacketNoLock (payload, payload_length);
if (packet_result == PacketResult::Success)
packet_result = WaitForPacketWithTimeoutMicroSecondsNoLock (response, GetPacketTimeoutInMicroSeconds ());
return packet_result;
}
GDBRemoteCommunicationClient::PacketResult
GDBRemoteCommunicationClient::SendPacketAndWaitForResponse
(
const char *payload,
size_t payload_length,
StringExtractorGDBRemote &response,
bool send_async
)
{
PacketResult packet_result = PacketResult::ErrorSendFailed;
Mutex::Locker locker;
Log *log (ProcessGDBRemoteLog::GetLogIfAllCategoriesSet (GDBR_LOG_PROCESS));
size_t response_len = 0;
if (GetSequenceMutex (locker))
{
packet_result = SendPacketAndWaitForResponseNoLock (payload, payload_length, response);
}
else
{
if (send_async)
{
if (IsRunning())
{
Mutex::Locker async_locker (m_async_mutex);
m_async_packet.assign(payload, payload_length);
m_async_packet_predicate.SetValue (true, eBroadcastNever);
if (log)
log->Printf ("async: async packet = %s", m_async_packet.c_str());
bool timed_out = false;
if (SendInterrupt(locker, 2, timed_out))
{
if (m_interrupt_sent)
{
m_interrupt_sent = false;
TimeValue timeout_time;
timeout_time = TimeValue::Now();
timeout_time.OffsetWithSeconds (m_packet_timeout);
if (log)
log->Printf ("async: sent interrupt");
if (m_async_packet_predicate.WaitForValueEqualTo (false, &timeout_time, &timed_out))
{
if (log)
log->Printf ("async: got response");
// Swap the response buffer to avoid malloc and string copy
response.GetStringRef().swap (m_async_response.GetStringRef());
response_len = response.GetStringRef().size();
packet_result = m_async_result;
}
else
{
if (log)
log->Printf ("async: timed out waiting for response");
}
// Make sure we wait until the continue packet has been sent again...
if (m_private_is_running.WaitForValueEqualTo (true, &timeout_time, &timed_out))
{
if (log)
{
if (timed_out)
log->Printf ("async: timed out waiting for process to resume, but process was resumed");
else
log->Printf ("async: async packet sent");
}
}
else
{
if (log)
log->Printf ("async: timed out waiting for process to resume");
}
}
else
{
// We had a racy condition where we went to send the interrupt
// yet we were able to get the lock, so the process must have
// just stopped?
if (log)
log->Printf ("async: got lock without sending interrupt");
// Send the packet normally since we got the lock
packet_result = SendPacketAndWaitForResponseNoLock (payload, payload_length, response);
}
}
else
{
if (log)
log->Printf ("async: failed to interrupt");
}
}
else
{
if (log)
log->Printf ("async: not running, async is ignored");
}
}
else
{
if (log)
log->Printf("error: failed to get packet sequence mutex, not sending packet '%*s'", (int) payload_length, payload);
}
}
return packet_result;
}
static const char *end_delimiter = "--end--;";
static const int end_delimiter_len = 8;
std::string
GDBRemoteCommunicationClient::HarmonizeThreadIdsForProfileData
( ProcessGDBRemote *process,
StringExtractorGDBRemote& profileDataExtractor
)
{
std::map<uint64_t, uint32_t> new_thread_id_to_used_usec_map;
std::stringstream final_output;
std::string name, value;
// Going to assuming thread_used_usec comes first, else bail out.
while (profileDataExtractor.GetNameColonValue(name, value))
{
if (name.compare("thread_used_id") == 0)
{
StringExtractor threadIDHexExtractor(value.c_str());
uint64_t thread_id = threadIDHexExtractor.GetHexMaxU64(false, 0);
bool has_used_usec = false;
uint32_t curr_used_usec = 0;
std::string usec_name, usec_value;
uint32_t input_file_pos = profileDataExtractor.GetFilePos();
if (profileDataExtractor.GetNameColonValue(usec_name, usec_value))
{
if (usec_name.compare("thread_used_usec") == 0)
{
has_used_usec = true;
curr_used_usec = strtoull(usec_value.c_str(), NULL, 0);
}
else
{
// We didn't find what we want, it is probably
// an older version. Bail out.
profileDataExtractor.SetFilePos(input_file_pos);
}
}
if (has_used_usec)
{
uint32_t prev_used_usec = 0;
std::map<uint64_t, uint32_t>::iterator iterator = m_thread_id_to_used_usec_map.find(thread_id);
if (iterator != m_thread_id_to_used_usec_map.end())
{
prev_used_usec = m_thread_id_to_used_usec_map[thread_id];
}
uint32_t real_used_usec = curr_used_usec - prev_used_usec;
// A good first time record is one that runs for at least 0.25 sec
bool good_first_time = (prev_used_usec == 0) && (real_used_usec > 250000);
bool good_subsequent_time = (prev_used_usec > 0) &&
((real_used_usec > 0) || (process->HasAssignedIndexIDToThread(thread_id)));
if (good_first_time || good_subsequent_time)
{
// We try to avoid doing too many index id reservation,
// resulting in fast increase of index ids.
final_output << name << ":";
int32_t index_id = process->AssignIndexIDToThread(thread_id);
final_output << index_id << ";";
final_output << usec_name << ":" << usec_value << ";";
}
else
{
// Skip past 'thread_used_name'.
std::string local_name, local_value;
profileDataExtractor.GetNameColonValue(local_name, local_value);
}
// Store current time as previous time so that they can be compared later.
new_thread_id_to_used_usec_map[thread_id] = curr_used_usec;
}
else
{
// Bail out and use old string.
final_output << name << ":" << value << ";";
}
}
else
{
final_output << name << ":" << value << ";";
}
}
final_output << end_delimiter;
m_thread_id_to_used_usec_map = new_thread_id_to_used_usec_map;
return final_output.str();
}
StateType
GDBRemoteCommunicationClient::SendContinuePacketAndWaitForResponse
(
ProcessGDBRemote *process,
const char *payload,
size_t packet_length,
StringExtractorGDBRemote &response
)
{
m_curr_tid = LLDB_INVALID_THREAD_ID;
Log *log (ProcessGDBRemoteLog::GetLogIfAllCategoriesSet (GDBR_LOG_PROCESS));
if (log)
log->Printf ("GDBRemoteCommunicationClient::%s ()", __FUNCTION__);
Mutex::Locker locker(m_sequence_mutex);
StateType state = eStateRunning;
BroadcastEvent(eBroadcastBitRunPacketSent, NULL);
m_public_is_running.SetValue (true, eBroadcastNever);
// Set the starting continue packet into "continue_packet". This packet
// may change if we are interrupted and we continue after an async packet...
std::string continue_packet(payload, packet_length);
bool got_async_packet = false;
while (state == eStateRunning)
{
if (!got_async_packet)
{
if (log)
log->Printf ("GDBRemoteCommunicationClient::%s () sending continue packet: %s", __FUNCTION__, continue_packet.c_str());
if (SendPacketNoLock(continue_packet.c_str(), continue_packet.size()) != PacketResult::Success)
state = eStateInvalid;
m_private_is_running.SetValue (true, eBroadcastAlways);
}
got_async_packet = false;
if (log)
log->Printf ("GDBRemoteCommunicationClient::%s () WaitForPacket(%s)", __FUNCTION__, continue_packet.c_str());
if (WaitForPacketWithTimeoutMicroSecondsNoLock(response, UINT32_MAX) == PacketResult::Success)
{
if (response.Empty())
state = eStateInvalid;
else
{
const char stop_type = response.GetChar();
if (log)
log->Printf ("GDBRemoteCommunicationClient::%s () got packet: %s", __FUNCTION__, response.GetStringRef().c_str());
switch (stop_type)
{
case 'T':
case 'S':
{
if (process->GetStopID() == 0)
{
if (process->GetID() == LLDB_INVALID_PROCESS_ID)
{
lldb::pid_t pid = GetCurrentProcessID ();
if (pid != LLDB_INVALID_PROCESS_ID)
process->SetID (pid);
}
process->BuildDynamicRegisterInfo (true);
}
// Privately notify any internal threads that we have stopped
// in case we wanted to interrupt our process, yet we might
// send a packet and continue without returning control to the
// user.
m_private_is_running.SetValue (false, eBroadcastAlways);
const uint8_t signo = response.GetHexU8 (UINT8_MAX);
bool continue_after_async = m_async_signal != -1 || m_async_packet_predicate.GetValue();
if (continue_after_async || m_interrupt_sent)
{
// We sent an interrupt packet to stop the inferior process
// for an async signal or to send an async packet while running
// but we might have been single stepping and received the
// stop packet for the step instead of for the interrupt packet.
// Typically when an interrupt is sent a SIGINT or SIGSTOP
// is used, so if we get anything else, we need to try and
// get another stop reply packet that may have been sent
// due to sending the interrupt when the target is stopped
// which will just re-send a copy of the last stop reply
// packet. If we don't do this, then the reply for our
// async packet will be the repeat stop reply packet and cause
// a lot of trouble for us!
if (signo != SIGINT && signo != SIGSTOP)
{
continue_after_async = false;
// We didn't get a a SIGINT or SIGSTOP, so try for a
// very brief time (1 ms) to get another stop reply
// packet to make sure it doesn't get in the way
StringExtractorGDBRemote extra_stop_reply_packet;
uint32_t timeout_usec = 1000;
if (WaitForPacketWithTimeoutMicroSecondsNoLock (extra_stop_reply_packet, timeout_usec) == PacketResult::Success)
{
switch (extra_stop_reply_packet.GetChar())
{
case 'T':
case 'S':
// We did get an extra stop reply, which means
// our interrupt didn't stop the target so we
// shouldn't continue after the async signal
// or packet is sent...
continue_after_async = false;
break;
}
}
}
}
if (m_async_signal != -1)
{
if (log)
log->Printf ("async: send signo = %s", Host::GetSignalAsCString (m_async_signal));
// Save off the async signal we are supposed to send
const int async_signal = m_async_signal;
// Clear the async signal member so we don't end up
// sending the signal multiple times...
m_async_signal = -1;
// Check which signal we stopped with
if (signo == async_signal)
{
if (log)
log->Printf ("async: stopped with signal %s, we are done running", Host::GetSignalAsCString (signo));
// We already stopped with a signal that we wanted
// to stop with, so we are done
}
else
{
// We stopped with a different signal that the one
// we wanted to stop with, so now we must resume
// with the signal we want
char signal_packet[32];
int signal_packet_len = 0;
signal_packet_len = ::snprintf (signal_packet,
sizeof (signal_packet),
"C%2.2x",
async_signal);
if (log)
log->Printf ("async: stopped with signal %s, resume with %s",
Host::GetSignalAsCString (signo),
Host::GetSignalAsCString (async_signal));
// Set the continue packet to resume even if the
// interrupt didn't cause our stop (ignore continue_after_async)
continue_packet.assign(signal_packet, signal_packet_len);
continue;
}
}
else if (m_async_packet_predicate.GetValue())
{
Log * packet_log (ProcessGDBRemoteLog::GetLogIfAllCategoriesSet (GDBR_LOG_PACKETS));
// We are supposed to send an asynchronous packet while
// we are running.
m_async_response.Clear();
if (m_async_packet.empty())
{
m_async_result = PacketResult::ErrorSendFailed;
if (packet_log)
packet_log->Printf ("async: error: empty async packet");
}
else
{
if (packet_log)
packet_log->Printf ("async: sending packet");
m_async_result = SendPacketAndWaitForResponse (&m_async_packet[0],
m_async_packet.size(),
m_async_response,
false);
}
// Let the other thread that was trying to send the async
// packet know that the packet has been sent and response is
// ready...
m_async_packet_predicate.SetValue(false, eBroadcastAlways);
if (packet_log)
packet_log->Printf ("async: sent packet, continue_after_async = %i", continue_after_async);
// Set the continue packet to resume if our interrupt
// for the async packet did cause the stop
if (continue_after_async)
{
// Reverting this for now as it is causing deadlocks
// in programs (<rdar://problem/11529853>). 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.
continue_packet.assign (1, 'c');
continue;
}
}
// Stop with signal and thread info
state = eStateStopped;
}
break;
case 'W':
case 'X':
// process exited
state = eStateExited;
break;
case 'O':
// STDOUT
{
got_async_packet = true;
std::string inferior_stdout;
inferior_stdout.reserve(response.GetBytesLeft () / 2);
char ch;
while ((ch = response.GetHexU8()) != '\0')
inferior_stdout.append(1, ch);
process->AppendSTDOUT (inferior_stdout.c_str(), inferior_stdout.size());
}
break;
case 'A':
// Async miscellaneous reply. Right now, only profile data is coming through this channel.
{
got_async_packet = true;
std::string input = response.GetStringRef().substr(1); // '1' to move beyond 'A'
if (m_partial_profile_data.length() > 0)
{
m_partial_profile_data.append(input);
input = m_partial_profile_data;
m_partial_profile_data.clear();
}
size_t found, pos = 0, len = input.length();
while ((found = input.find(end_delimiter, pos)) != std::string::npos)
{
StringExtractorGDBRemote profileDataExtractor(input.substr(pos, found).c_str());
std::string profile_data = HarmonizeThreadIdsForProfileData(process, profileDataExtractor);
process->BroadcastAsyncProfileData (profile_data);
pos = found + end_delimiter_len;
}
if (pos < len)
{
// Last incomplete chunk.
m_partial_profile_data = input.substr(pos);
}
}
break;
case 'E':
// ERROR
state = eStateInvalid;
break;
default:
if (log)
log->Printf ("GDBRemoteCommunicationClient::%s () unrecognized async packet", __FUNCTION__);
state = eStateInvalid;
break;
}
}
}
else
{
if (log)
log->Printf ("GDBRemoteCommunicationClient::%s () WaitForPacket(...) => false", __FUNCTION__);
state = eStateInvalid;
}
}
if (log)
log->Printf ("GDBRemoteCommunicationClient::%s () => %s", __FUNCTION__, StateAsCString(state));
response.SetFilePos(0);
m_private_is_running.SetValue (false, eBroadcastAlways);
m_public_is_running.SetValue (false, eBroadcastAlways);
return state;
}
bool
GDBRemoteCommunicationClient::SendAsyncSignal (int signo)
{
Mutex::Locker async_locker (m_async_mutex);
m_async_signal = signo;
bool timed_out = false;
Mutex::Locker locker;
if (SendInterrupt (locker, 1, timed_out))
return true;
m_async_signal = -1;
return false;
}
// This function takes a mutex locker as a parameter in case the GetSequenceMutex
// actually succeeds. If it doesn't succeed in acquiring the sequence mutex
// (the expected result), then it will send the halt packet. If it does succeed
// then the caller that requested the interrupt will want to keep the sequence
// locked down so that no one else can send packets while the caller has control.
// This function usually gets called when we are running and need to stop the
// target. It can also be used when we are running and and we need to do something
// else (like read/write memory), so we need to interrupt the running process
// (gdb remote protocol requires this), and do what we need to do, then resume.
bool
GDBRemoteCommunicationClient::SendInterrupt
(
Mutex::Locker& locker,
uint32_t seconds_to_wait_for_stop,
bool &timed_out
)
{
timed_out = false;
Log *log (ProcessGDBRemoteLog::GetLogIfAnyCategoryIsSet (GDBR_LOG_PROCESS | GDBR_LOG_PACKETS));
if (IsRunning())
{
// Only send an interrupt if our debugserver is running...
if (GetSequenceMutex (locker))
{
if (log)
log->Printf ("SendInterrupt () - got sequence mutex without having to interrupt");
}
else
{
// Someone has the mutex locked waiting for a response or for the
// inferior to stop, so send the interrupt on the down low...
char ctrl_c = '\x03';
ConnectionStatus status = eConnectionStatusSuccess;
size_t bytes_written = Write (&ctrl_c, 1, status, NULL);
if (log)
log->PutCString("send packet: \\x03");
if (bytes_written > 0)
{
m_interrupt_sent = true;
if (seconds_to_wait_for_stop)
{
TimeValue timeout;
if (seconds_to_wait_for_stop)
{
timeout = TimeValue::Now();
timeout.OffsetWithSeconds (seconds_to_wait_for_stop);
}
if (m_private_is_running.WaitForValueEqualTo (false, &timeout, &timed_out))
{
if (log)
log->PutCString ("SendInterrupt () - sent interrupt, private state stopped");
return true;
}
else
{
if (log)
log->Printf ("SendInterrupt () - sent interrupt, timed out wating for async thread resume");
}
}
else
{
if (log)
log->Printf ("SendInterrupt () - sent interrupt, not waiting for stop...");
return true;
}
}
else
{
if (log)
log->Printf ("SendInterrupt () - failed to write interrupt");
}
return false;
}
}
else
{
if (log)
log->Printf ("SendInterrupt () - not running");
}
return true;
}
lldb::pid_t
GDBRemoteCommunicationClient::GetCurrentProcessID ()
{
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("qC", strlen("qC"), response, false) == PacketResult::Success)
{
if (response.GetChar() == 'Q')
if (response.GetChar() == 'C')
return response.GetHexMaxU32 (false, LLDB_INVALID_PROCESS_ID);
}
return LLDB_INVALID_PROCESS_ID;
}
bool
GDBRemoteCommunicationClient::GetLaunchSuccess (std::string &error_str)
{
error_str.clear();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("qLaunchSuccess", strlen("qLaunchSuccess"), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return true;
if (response.GetChar() == 'E')
{
// A string the describes what failed when launching...
error_str = response.GetStringRef().substr(1);
}
else
{
error_str.assign ("unknown error occurred launching process");
}
}
else
{
error_str.assign ("timed out waiting for app to launch");
}
return false;
}
int
GDBRemoteCommunicationClient::SendArgumentsPacket (const ProcessLaunchInfo &launch_info)
{
// Since we don't get the send argv0 separate from the executable path, we need to
// make sure to use the actual exectuable path found in the launch_info...
std::vector<const char *> argv;
FileSpec exe_file = launch_info.GetExecutableFile();
std::string exe_path;
const char *arg = NULL;
const Args &launch_args = launch_info.GetArguments();
if (exe_file)
exe_path = exe_file.GetPath();
else
{
arg = launch_args.GetArgumentAtIndex(0);
if (arg)
exe_path = arg;
}
if (!exe_path.empty())
{
argv.push_back(exe_path.c_str());
for (uint32_t i=1; (arg = launch_args.GetArgumentAtIndex(i)) != NULL; ++i)
{
if (arg)
argv.push_back(arg);
}
}
if (!argv.empty())
{
StreamString packet;
packet.PutChar('A');
for (size_t i = 0, n = argv.size(); i < n; ++i)
{
arg = argv[i];
const int arg_len = strlen(arg);
if (i > 0)
packet.PutChar(',');
packet.Printf("%i,%i,", arg_len * 2, (int)i);
packet.PutBytesAsRawHex8 (arg, arg_len);
}
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
}
}
return -1;
}
int
GDBRemoteCommunicationClient::SendEnvironmentPacket (char const *name_equal_value)
{
if (name_equal_value && name_equal_value[0])
{
StreamString packet;
bool send_hex_encoding = false;
for (const char *p = name_equal_value; *p != '\0' && send_hex_encoding == false; ++p)
{
if (isprint(*p))
{
switch (*p)
{
case '$':
case '#':
send_hex_encoding = true;
break;
default:
break;
}
}
else
{
// We have non printable characters, lets hex encode this...
send_hex_encoding = true;
}
}
StringExtractorGDBRemote response;
if (send_hex_encoding)
{
if (m_supports_QEnvironmentHexEncoded)
{
packet.PutCString("QEnvironmentHexEncoded:");
packet.PutBytesAsRawHex8 (name_equal_value, strlen(name_equal_value));
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
if (response.IsUnsupportedResponse())
m_supports_QEnvironmentHexEncoded = false;
}
}
}
else if (m_supports_QEnvironment)
{
packet.Printf("QEnvironment:%s", name_equal_value);
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
if (response.IsUnsupportedResponse())
m_supports_QEnvironment = false;
}
}
}
return -1;
}
int
GDBRemoteCommunicationClient::SendLaunchArchPacket (char const *arch)
{
if (arch && arch[0])
{
StreamString packet;
packet.Printf("QLaunchArch:%s", arch);
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
}
}
return -1;
}
bool
GDBRemoteCommunicationClient::GetOSVersion (uint32_t &major,
uint32_t &minor,
uint32_t &update)
{
if (GetHostInfo ())
{
if (m_os_version_major != UINT32_MAX)
{
major = m_os_version_major;
minor = m_os_version_minor;
update = m_os_version_update;
return true;
}
}
return false;
}
bool
GDBRemoteCommunicationClient::GetOSBuildString (std::string &s)
{
if (GetHostInfo ())
{
if (!m_os_build.empty())
{
s = m_os_build;
return true;
}
}
s.clear();
return false;
}
bool
GDBRemoteCommunicationClient::GetOSKernelDescription (std::string &s)
{
if (GetHostInfo ())
{
if (!m_os_kernel.empty())
{
s = m_os_kernel;
return true;
}
}
s.clear();
return false;
}
bool
GDBRemoteCommunicationClient::GetHostname (std::string &s)
{
if (GetHostInfo ())
{
if (!m_hostname.empty())
{
s = m_hostname;
return true;
}
}
s.clear();
return false;
}
ArchSpec
GDBRemoteCommunicationClient::GetSystemArchitecture ()
{
if (GetHostInfo ())
return m_host_arch;
return ArchSpec();
}
const lldb_private::ArchSpec &
GDBRemoteCommunicationClient::GetProcessArchitecture ()
{
if (m_qProcessInfo_is_valid == eLazyBoolCalculate)
GetCurrentProcessInfo ();
return m_process_arch;
}
bool
GDBRemoteCommunicationClient::GetHostInfo (bool force)
{
if (force || m_qHostInfo_is_valid == eLazyBoolCalculate)
{
m_qHostInfo_is_valid = eLazyBoolNo;
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse ("qHostInfo", response, false) == PacketResult::Success)
{
if (response.IsNormalResponse())
{
std::string name;
std::string value;
uint32_t cpu = LLDB_INVALID_CPUTYPE;
uint32_t sub = 0;
std::string arch_name;
std::string os_name;
std::string vendor_name;
std::string triple;
std::string distribution_id;
uint32_t pointer_byte_size = 0;
StringExtractor extractor;
ByteOrder byte_order = eByteOrderInvalid;
uint32_t num_keys_decoded = 0;
while (response.GetNameColonValue(name, value))
{
if (name.compare("cputype") == 0)
{
// exception type in big endian hex
cpu = Args::StringToUInt32 (value.c_str(), LLDB_INVALID_CPUTYPE, 0);
if (cpu != LLDB_INVALID_CPUTYPE)
++num_keys_decoded;
}
else if (name.compare("cpusubtype") == 0)
{
// exception count in big endian hex
sub = Args::StringToUInt32 (value.c_str(), 0, 0);
if (sub != 0)
++num_keys_decoded;
}
else if (name.compare("arch") == 0)
{
arch_name.swap (value);
++num_keys_decoded;
}
else if (name.compare("triple") == 0)
{
// The triple comes as ASCII hex bytes since it contains '-' chars
extractor.GetStringRef().swap(value);
extractor.SetFilePos(0);
extractor.GetHexByteString (triple);
++num_keys_decoded;
}
else if (name.compare ("distribution_id") == 0)
{
extractor.GetStringRef ().swap (value);
extractor.SetFilePos (0);
extractor.GetHexByteString (distribution_id);
++num_keys_decoded;
}
else if (name.compare("os_build") == 0)
{
extractor.GetStringRef().swap(value);
extractor.SetFilePos(0);
extractor.GetHexByteString (m_os_build);
++num_keys_decoded;
}
else if (name.compare("hostname") == 0)
{
extractor.GetStringRef().swap(value);
extractor.SetFilePos(0);
extractor.GetHexByteString (m_hostname);
++num_keys_decoded;
}
else if (name.compare("os_kernel") == 0)
{
extractor.GetStringRef().swap(value);
extractor.SetFilePos(0);
extractor.GetHexByteString (m_os_kernel);
++num_keys_decoded;
}
else if (name.compare("ostype") == 0)
{
os_name.swap (value);
++num_keys_decoded;
}
else if (name.compare("vendor") == 0)
{
vendor_name.swap(value);
++num_keys_decoded;
}
else if (name.compare("endian") == 0)
{
++num_keys_decoded;
if (value.compare("little") == 0)
byte_order = eByteOrderLittle;
else if (value.compare("big") == 0)
byte_order = eByteOrderBig;
else if (value.compare("pdp") == 0)
byte_order = eByteOrderPDP;
else
--num_keys_decoded;
}
else if (name.compare("ptrsize") == 0)
{
pointer_byte_size = Args::StringToUInt32 (value.c_str(), 0, 0);
if (pointer_byte_size != 0)
++num_keys_decoded;
}
else if (name.compare("os_version") == 0)
{
Args::StringToVersion (value.c_str(),
m_os_version_major,
m_os_version_minor,
m_os_version_update);
if (m_os_version_major != UINT32_MAX)
++num_keys_decoded;
}
else if (name.compare("watchpoint_exceptions_received") == 0)
{
++num_keys_decoded;
if (strcmp(value.c_str(),"before") == 0)
m_watchpoints_trigger_after_instruction = eLazyBoolNo;
else if (strcmp(value.c_str(),"after") == 0)
m_watchpoints_trigger_after_instruction = eLazyBoolYes;
else
--num_keys_decoded;
}
else if (name.compare("default_packet_timeout") == 0)
{
m_default_packet_timeout = Args::StringToUInt32(value.c_str(), 0);
if (m_default_packet_timeout > 0)
{
SetPacketTimeout(m_default_packet_timeout);
++num_keys_decoded;
}
}
}
if (num_keys_decoded > 0)
m_qHostInfo_is_valid = eLazyBoolYes;
if (triple.empty())
{
if (arch_name.empty())
{
if (cpu != LLDB_INVALID_CPUTYPE)
{
m_host_arch.SetArchitecture (eArchTypeMachO, cpu, sub);
if (pointer_byte_size)
{
assert (pointer_byte_size == m_host_arch.GetAddressByteSize());
}
if (byte_order != eByteOrderInvalid)
{
assert (byte_order == m_host_arch.GetByteOrder());
}
if (!os_name.empty() && vendor_name.compare("apple") == 0 && os_name.find("darwin") == 0)
{
switch (m_host_arch.GetMachine())
{
case llvm::Triple::arm:
case llvm::Triple::thumb:
os_name = "ios";
break;
default:
os_name = "macosx";
break;
}
}
if (!vendor_name.empty())
m_host_arch.GetTriple().setVendorName (llvm::StringRef (vendor_name));
if (!os_name.empty())
m_host_arch.GetTriple().setOSName (llvm::StringRef (os_name));
}
}
else
{
std::string triple;
triple += arch_name;
if (!vendor_name.empty() || !os_name.empty())
{
triple += '-';
if (vendor_name.empty())
triple += "unknown";
else
triple += vendor_name;
triple += '-';
if (os_name.empty())
triple += "unknown";
else
triple += os_name;
}
m_host_arch.SetTriple (triple.c_str());
llvm::Triple &host_triple = m_host_arch.GetTriple();
if (host_triple.getVendor() == llvm::Triple::Apple && host_triple.getOS() == llvm::Triple::Darwin)
{
switch (m_host_arch.GetMachine())
{
case llvm::Triple::arm:
case llvm::Triple::thumb:
host_triple.setOS(llvm::Triple::IOS);
break;
default:
host_triple.setOS(llvm::Triple::MacOSX);
break;
}
}
if (pointer_byte_size)
{
assert (pointer_byte_size == m_host_arch.GetAddressByteSize());
}
if (byte_order != eByteOrderInvalid)
{
assert (byte_order == m_host_arch.GetByteOrder());
}
}
}
else
{
m_host_arch.SetTriple (triple.c_str());
if (pointer_byte_size)
{
assert (pointer_byte_size == m_host_arch.GetAddressByteSize());
}
if (byte_order != eByteOrderInvalid)
{
assert (byte_order == m_host_arch.GetByteOrder());
}
}
if (!distribution_id.empty ())
m_host_arch.SetDistributionId (distribution_id.c_str ());
}
}
}
return m_qHostInfo_is_valid == eLazyBoolYes;
}
int
GDBRemoteCommunicationClient::SendAttach
(
lldb::pid_t pid,
StringExtractorGDBRemote& response
)
{
if (pid != LLDB_INVALID_PROCESS_ID)
{
char packet[64];
const int packet_len = ::snprintf (packet, sizeof(packet), "vAttach;%" PRIx64, pid);
assert (packet_len < (int)sizeof(packet));
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsErrorResponse())
return response.GetError();
return 0;
}
}
return -1;
}
const lldb_private::ArchSpec &
GDBRemoteCommunicationClient::GetHostArchitecture ()
{
if (m_qHostInfo_is_valid == eLazyBoolCalculate)
GetHostInfo ();
return m_host_arch;
}
uint32_t
GDBRemoteCommunicationClient::GetHostDefaultPacketTimeout ()
{
if (m_qHostInfo_is_valid == eLazyBoolCalculate)
GetHostInfo ();
return m_default_packet_timeout;
}
addr_t
GDBRemoteCommunicationClient::AllocateMemory (size_t size, uint32_t permissions)
{
if (m_supports_alloc_dealloc_memory != eLazyBoolNo)
{
m_supports_alloc_dealloc_memory = eLazyBoolYes;
char packet[64];
const int packet_len = ::snprintf (packet, sizeof(packet), "_M%" PRIx64 ",%s%s%s",
(uint64_t)size,
permissions & lldb::ePermissionsReadable ? "r" : "",
permissions & lldb::ePermissionsWritable ? "w" : "",
permissions & lldb::ePermissionsExecutable ? "x" : "");
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
if (!response.IsErrorResponse())
return response.GetHexMaxU64(false, LLDB_INVALID_ADDRESS);
}
else
{
m_supports_alloc_dealloc_memory = eLazyBoolNo;
}
}
return LLDB_INVALID_ADDRESS;
}
bool
GDBRemoteCommunicationClient::DeallocateMemory (addr_t addr)
{
if (m_supports_alloc_dealloc_memory != eLazyBoolNo)
{
m_supports_alloc_dealloc_memory = eLazyBoolYes;
char packet[64];
const int packet_len = ::snprintf(packet, sizeof(packet), "_m%" PRIx64, (uint64_t)addr);
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return true;
}
else
{
m_supports_alloc_dealloc_memory = eLazyBoolNo;
}
}
return false;
}
Error
GDBRemoteCommunicationClient::Detach (bool keep_stopped)
{
Error error;
if (keep_stopped)
{
if (m_supports_detach_stay_stopped == eLazyBoolCalculate)
{
char packet[64];
const int packet_len = ::snprintf(packet, sizeof(packet), "qSupportsDetachAndStayStopped:");
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
m_supports_detach_stay_stopped = eLazyBoolYes;
}
else
{
m_supports_detach_stay_stopped = eLazyBoolNo;
}
}
if (m_supports_detach_stay_stopped == eLazyBoolNo)
{
error.SetErrorString("Stays stopped not supported by this target.");
return error;
}
else
{
PacketResult packet_result = SendPacket ("D1", 2);
if (packet_result != PacketResult::Success)
error.SetErrorString ("Sending extended disconnect packet failed.");
}
}
else
{
PacketResult packet_result = SendPacket ("D", 1);
if (packet_result != PacketResult::Success)
error.SetErrorString ("Sending disconnect packet failed.");
}
return error;
}
Error
GDBRemoteCommunicationClient::GetMemoryRegionInfo (lldb::addr_t addr,
lldb_private::MemoryRegionInfo ®ion_info)
{
Error error;
region_info.Clear();
if (m_supports_memory_region_info != eLazyBoolNo)
{
m_supports_memory_region_info = eLazyBoolYes;
char packet[64];
const int packet_len = ::snprintf(packet, sizeof(packet), "qMemoryRegionInfo:%" PRIx64, (uint64_t)addr);
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
std::string name;
std::string value;
addr_t addr_value;
bool success = true;
bool saw_permissions = false;
while (success && response.GetNameColonValue(name, value))
{
if (name.compare ("start") == 0)
{
addr_value = Args::StringToUInt64(value.c_str(), LLDB_INVALID_ADDRESS, 16, &success);
if (success)
region_info.GetRange().SetRangeBase(addr_value);
}
else if (name.compare ("size") == 0)
{
addr_value = Args::StringToUInt64(value.c_str(), 0, 16, &success);
if (success)
region_info.GetRange().SetByteSize (addr_value);
}
else if (name.compare ("permissions") == 0 && region_info.GetRange().IsValid())
{
saw_permissions = true;
if (region_info.GetRange().Contains (addr))
{
if (value.find('r') != std::string::npos)
region_info.SetReadable (MemoryRegionInfo::eYes);
else
region_info.SetReadable (MemoryRegionInfo::eNo);
if (value.find('w') != std::string::npos)
region_info.SetWritable (MemoryRegionInfo::eYes);
else
region_info.SetWritable (MemoryRegionInfo::eNo);
if (value.find('x') != std::string::npos)
region_info.SetExecutable (MemoryRegionInfo::eYes);
else
region_info.SetExecutable (MemoryRegionInfo::eNo);
}
else
{
// The reported region does not contain this address -- we're looking at an unmapped page
region_info.SetReadable (MemoryRegionInfo::eNo);
region_info.SetWritable (MemoryRegionInfo::eNo);
region_info.SetExecutable (MemoryRegionInfo::eNo);
}
}
else if (name.compare ("error") == 0)
{
StringExtractorGDBRemote name_extractor;
// Swap "value" over into "name_extractor"
name_extractor.GetStringRef().swap(value);
// Now convert the HEX bytes into a string value
name_extractor.GetHexByteString (value);
error.SetErrorString(value.c_str());
}
}
// We got a valid address range back but no permissions -- which means this is an unmapped page
if (region_info.GetRange().IsValid() && saw_permissions == false)
{
region_info.SetReadable (MemoryRegionInfo::eNo);
region_info.SetWritable (MemoryRegionInfo::eNo);
region_info.SetExecutable (MemoryRegionInfo::eNo);
}
}
else
{
m_supports_memory_region_info = eLazyBoolNo;
}
}
if (m_supports_memory_region_info == eLazyBoolNo)
{
error.SetErrorString("qMemoryRegionInfo is not supported");
}
if (error.Fail())
region_info.Clear();
return error;
}
Error
GDBRemoteCommunicationClient::GetWatchpointSupportInfo (uint32_t &num)
{
Error error;
if (m_supports_watchpoint_support_info == eLazyBoolYes)
{
num = m_num_supported_hardware_watchpoints;
return error;
}
// Set num to 0 first.
num = 0;
if (m_supports_watchpoint_support_info != eLazyBoolNo)
{
char packet[64];
const int packet_len = ::snprintf(packet, sizeof(packet), "qWatchpointSupportInfo:");
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
m_supports_watchpoint_support_info = eLazyBoolYes;
std::string name;
std::string value;
while (response.GetNameColonValue(name, value))
{
if (name.compare ("num") == 0)
{
num = Args::StringToUInt32(value.c_str(), 0, 0);
m_num_supported_hardware_watchpoints = num;
}
}
}
else
{
m_supports_watchpoint_support_info = eLazyBoolNo;
}
}
if (m_supports_watchpoint_support_info == eLazyBoolNo)
{
error.SetErrorString("qWatchpointSupportInfo is not supported");
}
return error;
}
lldb_private::Error
GDBRemoteCommunicationClient::GetWatchpointSupportInfo (uint32_t &num, bool& after)
{
Error error(GetWatchpointSupportInfo(num));
if (error.Success())
error = GetWatchpointsTriggerAfterInstruction(after);
return error;
}
lldb_private::Error
GDBRemoteCommunicationClient::GetWatchpointsTriggerAfterInstruction (bool &after)
{
Error error;
// we assume watchpoints will happen after running the relevant opcode
// and we only want to override this behavior if we have explicitly
// received a qHostInfo telling us otherwise
if (m_qHostInfo_is_valid != eLazyBoolYes)
after = true;
else
after = (m_watchpoints_trigger_after_instruction != eLazyBoolNo);
return error;
}
int
GDBRemoteCommunicationClient::SetSTDIN (char const *path)
{
if (path && path[0])
{
StreamString packet;
packet.PutCString("QSetSTDIN:");
packet.PutBytesAsRawHex8(path, strlen(path));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
}
}
return -1;
}
int
GDBRemoteCommunicationClient::SetSTDOUT (char const *path)
{
if (path && path[0])
{
StreamString packet;
packet.PutCString("QSetSTDOUT:");
packet.PutBytesAsRawHex8(path, strlen(path));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
}
}
return -1;
}
int
GDBRemoteCommunicationClient::SetSTDERR (char const *path)
{
if (path && path[0])
{
StreamString packet;
packet.PutCString("QSetSTDERR:");
packet.PutBytesAsRawHex8(path, strlen(path));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
}
}
return -1;
}
bool
GDBRemoteCommunicationClient::GetWorkingDir (std::string &cwd)
{
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse ("qGetWorkingDir", response, false) == PacketResult::Success)
{
if (response.IsUnsupportedResponse())
return false;
if (response.IsErrorResponse())
return false;
response.GetHexByteString (cwd);
return !cwd.empty();
}
return false;
}
int
GDBRemoteCommunicationClient::SetWorkingDir (char const *path)
{
if (path && path[0])
{
StreamString packet;
packet.PutCString("QSetWorkingDir:");
packet.PutBytesAsRawHex8(path, strlen(path));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
}
}
return -1;
}
int
GDBRemoteCommunicationClient::SetDisableASLR (bool enable)
{
char packet[32];
const int packet_len = ::snprintf (packet, sizeof (packet), "QSetDisableASLR:%i", enable ? 1 : 0);
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return 0;
uint8_t error = response.GetError();
if (error)
return error;
}
return -1;
}
bool
GDBRemoteCommunicationClient::DecodeProcessInfoResponse (StringExtractorGDBRemote &response, ProcessInstanceInfo &process_info)
{
if (response.IsNormalResponse())
{
std::string name;
std::string value;
StringExtractor extractor;
uint32_t cpu = LLDB_INVALID_CPUTYPE;
uint32_t sub = 0;
std::string vendor;
std::string os_type;
while (response.GetNameColonValue(name, value))
{
if (name.compare("pid") == 0)
{
process_info.SetProcessID (Args::StringToUInt32 (value.c_str(), LLDB_INVALID_PROCESS_ID, 0));
}
else if (name.compare("ppid") == 0)
{
process_info.SetParentProcessID (Args::StringToUInt32 (value.c_str(), LLDB_INVALID_PROCESS_ID, 0));
}
else if (name.compare("uid") == 0)
{
process_info.SetUserID (Args::StringToUInt32 (value.c_str(), UINT32_MAX, 0));
}
else if (name.compare("euid") == 0)
{
process_info.SetEffectiveUserID (Args::StringToUInt32 (value.c_str(), UINT32_MAX, 0));
}
else if (name.compare("gid") == 0)
{
process_info.SetGroupID (Args::StringToUInt32 (value.c_str(), UINT32_MAX, 0));
}
else if (name.compare("egid") == 0)
{
process_info.SetEffectiveGroupID (Args::StringToUInt32 (value.c_str(), UINT32_MAX, 0));
}
else if (name.compare("triple") == 0)
{
// The triple comes as ASCII hex bytes since it contains '-' chars
extractor.GetStringRef().swap(value);
extractor.SetFilePos(0);
extractor.GetHexByteString (value);
process_info.GetArchitecture ().SetTriple (value.c_str());
}
else if (name.compare("name") == 0)
{
StringExtractor extractor;
// The process name from ASCII hex bytes since we can't
// control the characters in a process name
extractor.GetStringRef().swap(value);
extractor.SetFilePos(0);
extractor.GetHexByteString (value);
process_info.GetExecutableFile().SetFile (value.c_str(), false);
}
else if (name.compare("cputype") == 0)
{
cpu = Args::StringToUInt32 (value.c_str(), LLDB_INVALID_CPUTYPE, 16);
}
else if (name.compare("cpusubtype") == 0)
{
sub = Args::StringToUInt32 (value.c_str(), 0, 16);
}
else if (name.compare("vendor") == 0)
{
vendor = value;
}
else if (name.compare("ostype") == 0)
{
os_type = value;
}
}
if (cpu != LLDB_INVALID_CPUTYPE && !vendor.empty() && !os_type.empty())
{
if (vendor == "apple")
{
process_info.GetArchitecture().SetArchitecture (eArchTypeMachO, cpu, sub);
process_info.GetArchitecture().GetTriple().setVendorName (llvm::StringRef (vendor));
process_info.GetArchitecture().GetTriple().setOSName (llvm::StringRef (os_type));
}
}
if (process_info.GetProcessID() != LLDB_INVALID_PROCESS_ID)
return true;
}
return false;
}
bool
GDBRemoteCommunicationClient::GetProcessInfo (lldb::pid_t pid, ProcessInstanceInfo &process_info)
{
process_info.Clear();
if (m_supports_qProcessInfoPID)
{
char packet[32];
const int packet_len = ::snprintf (packet, sizeof (packet), "qProcessInfoPID:%" PRIu64, pid);
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
return DecodeProcessInfoResponse (response, process_info);
}
else
{
m_supports_qProcessInfoPID = false;
return false;
}
}
return false;
}
bool
GDBRemoteCommunicationClient::GetCurrentProcessInfo ()
{
if (m_qProcessInfo_is_valid == eLazyBoolYes)
return true;
if (m_qProcessInfo_is_valid == eLazyBoolNo)
return false;
GetHostInfo ();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse ("qProcessInfo", response, false) == PacketResult::Success)
{
if (response.IsNormalResponse())
{
std::string name;
std::string value;
uint32_t cpu = LLDB_INVALID_CPUTYPE;
uint32_t sub = 0;
std::string arch_name;
std::string os_name;
std::string vendor_name;
std::string triple;
uint32_t pointer_byte_size = 0;
StringExtractor extractor;
ByteOrder byte_order = eByteOrderInvalid;
uint32_t num_keys_decoded = 0;
while (response.GetNameColonValue(name, value))
{
if (name.compare("cputype") == 0)
{
cpu = Args::StringToUInt32 (value.c_str(), LLDB_INVALID_CPUTYPE, 16);
if (cpu != LLDB_INVALID_CPUTYPE)
++num_keys_decoded;
}
else if (name.compare("cpusubtype") == 0)
{
sub = Args::StringToUInt32 (value.c_str(), 0, 16);
if (sub != 0)
++num_keys_decoded;
}
else if (name.compare("ostype") == 0)
{
os_name.swap (value);
++num_keys_decoded;
}
else if (name.compare("vendor") == 0)
{
vendor_name.swap(value);
++num_keys_decoded;
}
else if (name.compare("endian") == 0)
{
++num_keys_decoded;
if (value.compare("little") == 0)
byte_order = eByteOrderLittle;
else if (value.compare("big") == 0)
byte_order = eByteOrderBig;
else if (value.compare("pdp") == 0)
byte_order = eByteOrderPDP;
else
--num_keys_decoded;
}
else if (name.compare("ptrsize") == 0)
{
pointer_byte_size = Args::StringToUInt32 (value.c_str(), 0, 16);
if (pointer_byte_size != 0)
++num_keys_decoded;
}
}
if (num_keys_decoded > 0)
m_qProcessInfo_is_valid = eLazyBoolYes;
if (cpu != LLDB_INVALID_CPUTYPE && !os_name.empty() && !vendor_name.empty())
{
m_process_arch.SetArchitecture (eArchTypeMachO, cpu, sub);
if (pointer_byte_size)
{
assert (pointer_byte_size == m_process_arch.GetAddressByteSize());
}
m_host_arch.GetTriple().setVendorName (llvm::StringRef (vendor_name));
m_host_arch.GetTriple().setOSName (llvm::StringRef (os_name));
return true;
}
}
}
else
{
m_qProcessInfo_is_valid = eLazyBoolNo;
}
return false;
}
uint32_t
GDBRemoteCommunicationClient::FindProcesses (const ProcessInstanceInfoMatch &match_info,
ProcessInstanceInfoList &process_infos)
{
process_infos.Clear();
if (m_supports_qfProcessInfo)
{
StreamString packet;
packet.PutCString ("qfProcessInfo");
if (!match_info.MatchAllProcesses())
{
packet.PutChar (':');
const char *name = match_info.GetProcessInfo().GetName();
bool has_name_match = false;
if (name && name[0])
{
has_name_match = true;
NameMatchType name_match_type = match_info.GetNameMatchType();
switch (name_match_type)
{
case eNameMatchIgnore:
has_name_match = false;
break;
case eNameMatchEquals:
packet.PutCString ("name_match:equals;");
break;
case eNameMatchContains:
packet.PutCString ("name_match:contains;");
break;
case eNameMatchStartsWith:
packet.PutCString ("name_match:starts_with;");
break;
case eNameMatchEndsWith:
packet.PutCString ("name_match:ends_with;");
break;
case eNameMatchRegularExpression:
packet.PutCString ("name_match:regex;");
break;
}
if (has_name_match)
{
packet.PutCString ("name:");
packet.PutBytesAsRawHex8(name, ::strlen(name));
packet.PutChar (';');
}
}
if (match_info.GetProcessInfo().ProcessIDIsValid())
packet.Printf("pid:%" PRIu64 ";",match_info.GetProcessInfo().GetProcessID());
if (match_info.GetProcessInfo().ParentProcessIDIsValid())
packet.Printf("parent_pid:%" PRIu64 ";",match_info.GetProcessInfo().GetParentProcessID());
if (match_info.GetProcessInfo().UserIDIsValid())
packet.Printf("uid:%u;",match_info.GetProcessInfo().GetUserID());
if (match_info.GetProcessInfo().GroupIDIsValid())
packet.Printf("gid:%u;",match_info.GetProcessInfo().GetGroupID());
if (match_info.GetProcessInfo().EffectiveUserIDIsValid())
packet.Printf("euid:%u;",match_info.GetProcessInfo().GetEffectiveUserID());
if (match_info.GetProcessInfo().EffectiveGroupIDIsValid())
packet.Printf("egid:%u;",match_info.GetProcessInfo().GetEffectiveGroupID());
if (match_info.GetProcessInfo().EffectiveGroupIDIsValid())
packet.Printf("all_users:%u;",match_info.GetMatchAllUsers() ? 1 : 0);
if (match_info.GetProcessInfo().GetArchitecture().IsValid())
{
const ArchSpec &match_arch = match_info.GetProcessInfo().GetArchitecture();
const llvm::Triple &triple = match_arch.GetTriple();
packet.PutCString("triple:");
packet.PutCStringAsRawHex8(triple.getTriple().c_str());
packet.PutChar (';');
}
}
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success)
{
do
{
ProcessInstanceInfo process_info;
if (!DecodeProcessInfoResponse (response, process_info))
break;
process_infos.Append(process_info);
response.GetStringRef().clear();
response.SetFilePos(0);
} while (SendPacketAndWaitForResponse ("qsProcessInfo", strlen ("qsProcessInfo"), response, false) == PacketResult::Success);
}
else
{
m_supports_qfProcessInfo = false;
return 0;
}
}
return process_infos.GetSize();
}
bool
GDBRemoteCommunicationClient::GetUserName (uint32_t uid, std::string &name)
{
if (m_supports_qUserName)
{
char packet[32];
const int packet_len = ::snprintf (packet, sizeof (packet), "qUserName:%i", uid);
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsNormalResponse())
{
// Make sure we parsed the right number of characters. The response is
// the hex encoded user name and should make up the entire packet.
// If there are any non-hex ASCII bytes, the length won't match below..
if (response.GetHexByteString (name) * 2 == response.GetStringRef().size())
return true;
}
}
else
{
m_supports_qUserName = false;
return false;
}
}
return false;
}
bool
GDBRemoteCommunicationClient::GetGroupName (uint32_t gid, std::string &name)
{
if (m_supports_qGroupName)
{
char packet[32];
const int packet_len = ::snprintf (packet, sizeof (packet), "qGroupName:%i", gid);
assert (packet_len < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse (packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsNormalResponse())
{
// Make sure we parsed the right number of characters. The response is
// the hex encoded group name and should make up the entire packet.
// If there are any non-hex ASCII bytes, the length won't match below..
if (response.GetHexByteString (name) * 2 == response.GetStringRef().size())
return true;
}
}
else
{
m_supports_qGroupName = false;
return false;
}
}
return false;
}
void
GDBRemoteCommunicationClient::TestPacketSpeed (const uint32_t num_packets)
{
uint32_t i;
TimeValue start_time, end_time;
uint64_t total_time_nsec;
if (SendSpeedTestPacket (0, 0))
{
static uint32_t g_send_sizes[] = { 0, 64, 128, 512, 1024 };
static uint32_t g_recv_sizes[] = { 0, 64, 128, 512, 1024 }; //, 4*1024, 8*1024, 16*1024, 32*1024, 48*1024, 64*1024, 96*1024, 128*1024 };
const size_t k_num_send_sizes = sizeof(g_send_sizes)/sizeof(uint32_t);
const size_t k_num_recv_sizes = sizeof(g_recv_sizes)/sizeof(uint32_t);
const uint64_t k_recv_amount = 4*1024*1024; // Receive 4MB
for (uint32_t send_idx = 0; send_idx < k_num_send_sizes; ++send_idx)
{
const uint32_t send_size = g_send_sizes[send_idx];
for (uint32_t recv_idx = 0; recv_idx < k_num_recv_sizes; ++recv_idx)
{
const uint32_t recv_size = g_recv_sizes[recv_idx];
StreamString packet;
packet.Printf ("qSpeedTest:response_size:%i;data:", recv_size);
uint32_t bytes_left = send_size;
while (bytes_left > 0)
{
if (bytes_left >= 26)
{
packet.PutCString("abcdefghijklmnopqrstuvwxyz");
bytes_left -= 26;
}
else
{
packet.Printf ("%*.*s;", bytes_left, bytes_left, "abcdefghijklmnopqrstuvwxyz");
bytes_left = 0;
}
}
start_time = TimeValue::Now();
if (recv_size == 0)
{
for (i=0; i<num_packets; ++i)
{
StringExtractorGDBRemote response;
SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false);
}
}
else
{
uint32_t bytes_read = 0;
while (bytes_read < k_recv_amount)
{
StringExtractorGDBRemote response;
SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false);
bytes_read += recv_size;
}
}
end_time = TimeValue::Now();
total_time_nsec = end_time.GetAsNanoSecondsSinceJan1_1970() - start_time.GetAsNanoSecondsSinceJan1_1970();
if (recv_size == 0)
{
float packets_per_second = (((float)num_packets)/(float)total_time_nsec) * (float)TimeValue::NanoSecPerSec;
printf ("%u qSpeedTest(send=%-7u, recv=%-7u) in %" PRIu64 ".%9.9" PRIu64 " sec for %f packets/sec.\n",
num_packets,
send_size,
recv_size,
total_time_nsec / TimeValue::NanoSecPerSec,
total_time_nsec % TimeValue::NanoSecPerSec,
packets_per_second);
}
else
{
float mb_second = ((((float)k_recv_amount)/(float)total_time_nsec) * (float)TimeValue::NanoSecPerSec) / (1024.0*1024.0);
printf ("%u qSpeedTest(send=%-7u, recv=%-7u) sent 4MB in %" PRIu64 ".%9.9" PRIu64 " sec for %f MB/sec.\n",
num_packets,
send_size,
recv_size,
total_time_nsec / TimeValue::NanoSecPerSec,
total_time_nsec % TimeValue::NanoSecPerSec,
mb_second);
}
}
}
}
}
bool
GDBRemoteCommunicationClient::SendSpeedTestPacket (uint32_t send_size, uint32_t recv_size)
{
StreamString packet;
packet.Printf ("qSpeedTest:response_size:%i;data:", recv_size);
uint32_t bytes_left = send_size;
while (bytes_left > 0)
{
if (bytes_left >= 26)
{
packet.PutCString("abcdefghijklmnopqrstuvwxyz");
bytes_left -= 26;
}
else
{
packet.Printf ("%*.*s;", bytes_left, bytes_left, "abcdefghijklmnopqrstuvwxyz");
bytes_left = 0;
}
}
StringExtractorGDBRemote response;
return SendPacketAndWaitForResponse (packet.GetData(), packet.GetSize(), response, false) == PacketResult::Success;
}
uint16_t
GDBRemoteCommunicationClient::LaunchGDBserverAndGetPort (lldb::pid_t &pid, const char *remote_accept_hostname)
{
pid = LLDB_INVALID_PROCESS_ID;
StringExtractorGDBRemote response;
StreamString stream;
stream.PutCString("qLaunchGDBServer;");
std::string hostname;
if (remote_accept_hostname && remote_accept_hostname[0])
hostname = remote_accept_hostname;
else
{
if (Host::GetHostname (hostname))
{
// Make the GDB server we launch only accept connections from this host
stream.Printf("host:%s;", hostname.c_str());
}
else
{
// Make the GDB server we launch accept connections from any host since we can't figure out the hostname
stream.Printf("host:*;");
}
}
const char *packet = stream.GetData();
int packet_len = stream.GetSize();
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
std::string name;
std::string value;
uint16_t port = 0;
while (response.GetNameColonValue(name, value))
{
if (name.compare("port") == 0)
port = Args::StringToUInt32(value.c_str(), 0, 0);
else if (name.compare("pid") == 0)
pid = Args::StringToUInt64(value.c_str(), LLDB_INVALID_PROCESS_ID, 0);
}
return port;
}
return 0;
}
bool
GDBRemoteCommunicationClient::KillSpawnedProcess (lldb::pid_t pid)
{
StreamString stream;
stream.Printf ("qKillSpawnedProcess:%" PRId64 , pid);
const char *packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
return true;
}
return false;
}
bool
GDBRemoteCommunicationClient::SetCurrentThread (uint64_t tid)
{
if (m_curr_tid == tid)
return true;
char packet[32];
int packet_len;
if (tid == UINT64_MAX)
packet_len = ::snprintf (packet, sizeof(packet), "Hg-1");
else
packet_len = ::snprintf (packet, sizeof(packet), "Hg%" PRIx64, tid);
assert (packet_len + 1 < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
{
m_curr_tid = tid;
return true;
}
}
return false;
}
bool
GDBRemoteCommunicationClient::SetCurrentThreadForRun (uint64_t tid)
{
if (m_curr_tid_run == tid)
return true;
char packet[32];
int packet_len;
if (tid == UINT64_MAX)
packet_len = ::snprintf (packet, sizeof(packet), "Hc-1");
else
packet_len = ::snprintf (packet, sizeof(packet), "Hc%" PRIx64, tid);
assert (packet_len + 1 < (int)sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
{
m_curr_tid_run = tid;
return true;
}
}
return false;
}
bool
GDBRemoteCommunicationClient::GetStopReply (StringExtractorGDBRemote &response)
{
if (SendPacketAndWaitForResponse("?", 1, response, false) == PacketResult::Success)
return response.IsNormalResponse();
return false;
}
bool
GDBRemoteCommunicationClient::GetThreadStopInfo (lldb::tid_t tid, StringExtractorGDBRemote &response)
{
if (m_supports_qThreadStopInfo)
{
char packet[256];
int packet_len = ::snprintf(packet, sizeof(packet), "qThreadStopInfo%" PRIx64, tid);
assert (packet_len < (int)sizeof(packet));
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.IsUnsupportedResponse())
m_supports_qThreadStopInfo = false;
else if (response.IsNormalResponse())
return true;
else
return false;
}
else
{
m_supports_qThreadStopInfo = false;
}
}
return false;
}
uint8_t
GDBRemoteCommunicationClient::SendGDBStoppointTypePacket (GDBStoppointType type, bool insert, addr_t addr, uint32_t length)
{
// Check if the stub is known not to support this breakpoint type
if (!SupportsGDBStoppointPacket(type))
return UINT8_MAX;
// Construct the breakpoint packet
char packet[64];
const int packet_len = ::snprintf (packet,
sizeof(packet),
"%c%i,%" PRIx64 ",%x",
insert ? 'Z' : 'z',
type,
addr,
length);
// Check we havent overwritten the end of the packet buffer
assert (packet_len + 1 < (int)sizeof(packet));
StringExtractorGDBRemote response;
// Try to send the breakpoint packet, and check that it was correctly sent
if (SendPacketAndWaitForResponse(packet, packet_len, response, true) == PacketResult::Success)
{
// Receive and OK packet when the breakpoint successfully placed
if (response.IsOKResponse())
return 0;
// Error while setting breakpoint, send back specific error
if (response.IsErrorResponse())
return response.GetError();
// Empty packet informs us that breakpoint is not supported
if (response.IsUnsupportedResponse())
{
// Disable this breakpoint type since it is unsupported
switch (type)
{
case eBreakpointSoftware: m_supports_z0 = false; break;
case eBreakpointHardware: m_supports_z1 = false; break;
case eWatchpointWrite: m_supports_z2 = false; break;
case eWatchpointRead: m_supports_z3 = false; break;
case eWatchpointReadWrite: m_supports_z4 = false; break;
}
}
}
// Signal generic faliure
return UINT8_MAX;
}
size_t
GDBRemoteCommunicationClient::GetCurrentThreadIDs (std::vector<lldb::tid_t> &thread_ids,
bool &sequence_mutex_unavailable)
{
Mutex::Locker locker;
thread_ids.clear();
if (GetSequenceMutex (locker, "ProcessGDBRemote::UpdateThreadList() failed due to not getting the sequence mutex"))
{
sequence_mutex_unavailable = false;
StringExtractorGDBRemote response;
PacketResult packet_result;
for (packet_result = SendPacketAndWaitForResponseNoLock ("qfThreadInfo", strlen("qfThreadInfo"), response);
packet_result == PacketResult::Success && response.IsNormalResponse();
packet_result = SendPacketAndWaitForResponseNoLock ("qsThreadInfo", strlen("qsThreadInfo"), response))
{
char ch = response.GetChar();
if (ch == 'l')
break;
if (ch == 'm')
{
do
{
tid_t tid = response.GetHexMaxU64(false, LLDB_INVALID_THREAD_ID);
if (tid != LLDB_INVALID_THREAD_ID)
{
thread_ids.push_back (tid);
}
ch = response.GetChar(); // Skip the command separator
} while (ch == ','); // Make sure we got a comma separator
}
}
}
else
{
#if defined (LLDB_CONFIGURATION_DEBUG)
// assert(!"ProcessGDBRemote::UpdateThreadList() failed due to not getting the sequence mutex");
#else
Log *log (ProcessGDBRemoteLog::GetLogIfAnyCategoryIsSet (GDBR_LOG_PROCESS | GDBR_LOG_PACKETS));
if (log)
log->Printf("error: failed to get packet sequence mutex, not sending packet 'qfThreadInfo'");
#endif
sequence_mutex_unavailable = true;
}
return thread_ids.size();
}
lldb::addr_t
GDBRemoteCommunicationClient::GetShlibInfoAddr()
{
if (!IsRunning())
{
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse("qShlibInfoAddr", ::strlen ("qShlibInfoAddr"), response, false) == PacketResult::Success)
{
if (response.IsNormalResponse())
return response.GetHexMaxU64(false, LLDB_INVALID_ADDRESS);
}
}
return LLDB_INVALID_ADDRESS;
}
lldb_private::Error
GDBRemoteCommunicationClient::RunShellCommand (const char *command, // Shouldn't be NULL
const char *working_dir, // Pass NULL to use the current working directory
int *status_ptr, // Pass NULL if you don't want the process exit status
int *signo_ptr, // Pass NULL if you don't want the signal that caused the process to exit
std::string *command_output, // Pass NULL if you don't want the command output
uint32_t timeout_sec) // Timeout in seconds to wait for shell program to finish
{
lldb_private::StreamString stream;
stream.PutCString("qPlatform_shell:");
stream.PutBytesAsRawHex8(command, strlen(command));
stream.PutChar(',');
stream.PutHex32(timeout_sec);
if (working_dir && *working_dir)
{
stream.PutChar(',');
stream.PutBytesAsRawHex8(working_dir, strlen(working_dir));
}
const char *packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() != 'F')
return Error("malformed reply");
if (response.GetChar() != ',')
return Error("malformed reply");
uint32_t exitcode = response.GetHexMaxU32(false, UINT32_MAX);
if (exitcode == UINT32_MAX)
return Error("unable to run remote process");
else if (status_ptr)
*status_ptr = exitcode;
if (response.GetChar() != ',')
return Error("malformed reply");
uint32_t signo = response.GetHexMaxU32(false, UINT32_MAX);
if (signo_ptr)
*signo_ptr = signo;
if (response.GetChar() != ',')
return Error("malformed reply");
std::string output;
response.GetEscapedBinaryData(output);
if (command_output)
command_output->assign(output);
return Error();
}
return Error("unable to send packet");
}
Error
GDBRemoteCommunicationClient::MakeDirectory (const char *path,
uint32_t file_permissions)
{
lldb_private::StreamString stream;
stream.PutCString("qPlatform_mkdir:");
stream.PutHex32(file_permissions);
stream.PutChar(',');
stream.PutBytesAsRawHex8(path, strlen(path));
const char *packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
return Error(response.GetHexMaxU32(false, UINT32_MAX), eErrorTypePOSIX);
}
return Error();
}
Error
GDBRemoteCommunicationClient::SetFilePermissions (const char *path,
uint32_t file_permissions)
{
lldb_private::StreamString stream;
stream.PutCString("qPlatform_chmod:");
stream.PutHex32(file_permissions);
stream.PutChar(',');
stream.PutBytesAsRawHex8(path, strlen(path));
const char *packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
return Error(response.GetHexMaxU32(false, UINT32_MAX), eErrorTypePOSIX);
}
return Error();
}
static uint64_t
ParseHostIOPacketResponse (StringExtractorGDBRemote &response,
uint64_t fail_result,
Error &error)
{
response.SetFilePos(0);
if (response.GetChar() != 'F')
return fail_result;
int32_t result = response.GetS32 (-2);
if (result == -2)
return fail_result;
if (response.GetChar() == ',')
{
int result_errno = response.GetS32 (-2);
if (result_errno != -2)
error.SetError(result_errno, eErrorTypePOSIX);
else
error.SetError(-1, eErrorTypeGeneric);
}
else
error.Clear();
return result;
}
lldb::user_id_t
GDBRemoteCommunicationClient::OpenFile (const lldb_private::FileSpec& file_spec,
uint32_t flags,
mode_t mode,
Error &error)
{
lldb_private::StreamString stream;
stream.PutCString("vFile:open:");
std::string path (file_spec.GetPath());
if (path.empty())
return UINT64_MAX;
stream.PutCStringAsRawHex8(path.c_str());
stream.PutChar(',');
const uint32_t posix_open_flags = File::ConvertOpenOptionsForPOSIXOpen(flags);
stream.PutHex32(posix_open_flags);
stream.PutChar(',');
stream.PutHex32(mode);
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
return ParseHostIOPacketResponse (response, UINT64_MAX, error);
}
return UINT64_MAX;
}
bool
GDBRemoteCommunicationClient::CloseFile (lldb::user_id_t fd,
Error &error)
{
lldb_private::StreamString stream;
stream.Printf("vFile:close:%i", (int)fd);
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
return ParseHostIOPacketResponse (response, -1, error) == 0;
}
return false;
}
// Extension of host I/O packets to get the file size.
lldb::user_id_t
GDBRemoteCommunicationClient::GetFileSize (const lldb_private::FileSpec& file_spec)
{
lldb_private::StreamString stream;
stream.PutCString("vFile:size:");
std::string path (file_spec.GetPath());
stream.PutCStringAsRawHex8(path.c_str());
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() != 'F')
return UINT64_MAX;
uint32_t retcode = response.GetHexMaxU64(false, UINT64_MAX);
return retcode;
}
return UINT64_MAX;
}
Error
GDBRemoteCommunicationClient::GetFilePermissions(const char *path, uint32_t &file_permissions)
{
Error error;
lldb_private::StreamString stream;
stream.PutCString("vFile:mode:");
stream.PutCStringAsRawHex8(path);
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() != 'F')
{
error.SetErrorStringWithFormat ("invalid response to '%s' packet", packet);
}
else
{
const uint32_t mode = response.GetS32(-1);
if (mode == -1)
{
if (response.GetChar() == ',')
{
int response_errno = response.GetS32(-1);
if (response_errno > 0)
error.SetError(response_errno, lldb::eErrorTypePOSIX);
else
error.SetErrorToGenericError();
}
else
error.SetErrorToGenericError();
}
else
{
file_permissions = mode & (S_IRWXU|S_IRWXG|S_IRWXO);
}
}
}
else
{
error.SetErrorStringWithFormat ("failed to send '%s' packet", packet);
}
return error;
}
uint64_t
GDBRemoteCommunicationClient::ReadFile (lldb::user_id_t fd,
uint64_t offset,
void *dst,
uint64_t dst_len,
Error &error)
{
lldb_private::StreamString stream;
stream.Printf("vFile:pread:%i,%" PRId64 ",%" PRId64, (int)fd, dst_len, offset);
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() != 'F')
return 0;
uint32_t retcode = response.GetHexMaxU32(false, UINT32_MAX);
if (retcode == UINT32_MAX)
return retcode;
const char next = (response.Peek() ? *response.Peek() : 0);
if (next == ',')
return 0;
if (next == ';')
{
response.GetChar(); // skip the semicolon
std::string buffer;
if (response.GetEscapedBinaryData(buffer))
{
const uint64_t data_to_write = std::min<uint64_t>(dst_len, buffer.size());
if (data_to_write > 0)
memcpy(dst, &buffer[0], data_to_write);
return data_to_write;
}
}
}
return 0;
}
uint64_t
GDBRemoteCommunicationClient::WriteFile (lldb::user_id_t fd,
uint64_t offset,
const void* src,
uint64_t src_len,
Error &error)
{
lldb_private::StreamGDBRemote stream;
stream.Printf("vFile:pwrite:%i,%" PRId64 ",", (int)fd, offset);
stream.PutEscapedBytes(src, src_len);
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() != 'F')
{
error.SetErrorStringWithFormat("write file failed");
return 0;
}
uint64_t bytes_written = response.GetU64(UINT64_MAX);
if (bytes_written == UINT64_MAX)
{
error.SetErrorToGenericError();
if (response.GetChar() == ',')
{
int response_errno = response.GetS32(-1);
if (response_errno > 0)
error.SetError(response_errno, lldb::eErrorTypePOSIX);
}
return 0;
}
return bytes_written;
}
else
{
error.SetErrorString ("failed to send vFile:pwrite packet");
}
return 0;
}
Error
GDBRemoteCommunicationClient::CreateSymlink (const char *src, const char *dst)
{
Error error;
lldb_private::StreamGDBRemote stream;
stream.PutCString("vFile:symlink:");
// the unix symlink() command reverses its parameters where the dst if first,
// so we follow suit here
stream.PutCStringAsRawHex8(dst);
stream.PutChar(',');
stream.PutCStringAsRawHex8(src);
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() == 'F')
{
uint32_t result = response.GetU32(UINT32_MAX);
if (result != 0)
{
error.SetErrorToGenericError();
if (response.GetChar() == ',')
{
int response_errno = response.GetS32(-1);
if (response_errno > 0)
error.SetError(response_errno, lldb::eErrorTypePOSIX);
}
}
}
else
{
// Should have returned with 'F<result>[,<errno>]'
error.SetErrorStringWithFormat("symlink failed");
}
}
else
{
error.SetErrorString ("failed to send vFile:symlink packet");
}
return error;
}
Error
GDBRemoteCommunicationClient::Unlink (const char *path)
{
Error error;
lldb_private::StreamGDBRemote stream;
stream.PutCString("vFile:unlink:");
// the unix symlink() command reverses its parameters where the dst if first,
// so we follow suit here
stream.PutCStringAsRawHex8(path);
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() == 'F')
{
uint32_t result = response.GetU32(UINT32_MAX);
if (result != 0)
{
error.SetErrorToGenericError();
if (response.GetChar() == ',')
{
int response_errno = response.GetS32(-1);
if (response_errno > 0)
error.SetError(response_errno, lldb::eErrorTypePOSIX);
}
}
}
else
{
// Should have returned with 'F<result>[,<errno>]'
error.SetErrorStringWithFormat("unlink failed");
}
}
else
{
error.SetErrorString ("failed to send vFile:unlink packet");
}
return error;
}
// Extension of host I/O packets to get whether a file exists.
bool
GDBRemoteCommunicationClient::GetFileExists (const lldb_private::FileSpec& file_spec)
{
lldb_private::StreamString stream;
stream.PutCString("vFile:exists:");
std::string path (file_spec.GetPath());
stream.PutCStringAsRawHex8(path.c_str());
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() != 'F')
return false;
if (response.GetChar() != ',')
return false;
bool retcode = (response.GetChar() != '0');
return retcode;
}
return false;
}
bool
GDBRemoteCommunicationClient::CalculateMD5 (const lldb_private::FileSpec& file_spec,
uint64_t &high,
uint64_t &low)
{
lldb_private::StreamString stream;
stream.PutCString("vFile:MD5:");
std::string path (file_spec.GetPath());
stream.PutCStringAsRawHex8(path.c_str());
const char* packet = stream.GetData();
int packet_len = stream.GetSize();
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, packet_len, response, false) == PacketResult::Success)
{
if (response.GetChar() != 'F')
return false;
if (response.GetChar() != ',')
return false;
if (response.Peek() && *response.Peek() == 'x')
return false;
low = response.GetHexMaxU64(false, UINT64_MAX);
high = response.GetHexMaxU64(false, UINT64_MAX);
return true;
}
return false;
}
bool
GDBRemoteCommunicationClient::ReadRegister(lldb::tid_t tid, uint32_t reg, StringExtractorGDBRemote &response)
{
Mutex::Locker locker;
if (GetSequenceMutex (locker, "Didn't get sequence mutex for p packet."))
{
const bool thread_suffix_supported = GetThreadSuffixSupported();
if (thread_suffix_supported || SetCurrentThread(tid))
{
char packet[64];
int packet_len = 0;
if (thread_suffix_supported)
packet_len = ::snprintf (packet, sizeof(packet), "p%x;thread:%4.4" PRIx64 ";", reg, tid);
else
packet_len = ::snprintf (packet, sizeof(packet), "p%x", reg);
assert (packet_len < ((int)sizeof(packet) - 1));
return SendPacketAndWaitForResponse(packet, response, false) == PacketResult::Success;
}
}
return false;
}
bool
GDBRemoteCommunicationClient::ReadAllRegisters (lldb::tid_t tid, StringExtractorGDBRemote &response)
{
Mutex::Locker locker;
if (GetSequenceMutex (locker, "Didn't get sequence mutex for g packet."))
{
const bool thread_suffix_supported = GetThreadSuffixSupported();
if (thread_suffix_supported || SetCurrentThread(tid))
{
char packet[64];
int packet_len = 0;
// Get all registers in one packet
if (thread_suffix_supported)
packet_len = ::snprintf (packet, sizeof(packet), "g;thread:%4.4" PRIx64 ";", tid);
else
packet_len = ::snprintf (packet, sizeof(packet), "g");
assert (packet_len < ((int)sizeof(packet) - 1));
return SendPacketAndWaitForResponse(packet, response, false) == PacketResult::Success;
}
}
return false;
}
bool
GDBRemoteCommunicationClient::SaveRegisterState (lldb::tid_t tid, uint32_t &save_id)
{
save_id = 0; // Set to invalid save ID
if (m_supports_QSaveRegisterState == eLazyBoolNo)
return false;
m_supports_QSaveRegisterState = eLazyBoolYes;
Mutex::Locker locker;
if (GetSequenceMutex (locker, "Didn't get sequence mutex for QSaveRegisterState."))
{
const bool thread_suffix_supported = GetThreadSuffixSupported();
if (thread_suffix_supported || SetCurrentThread(tid))
{
char packet[256];
if (thread_suffix_supported)
::snprintf (packet, sizeof(packet), "QSaveRegisterState;thread:%4.4" PRIx64 ";", tid);
else
::strncpy (packet, "QSaveRegisterState", sizeof(packet));
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, response, false) == PacketResult::Success)
{
if (response.IsUnsupportedResponse())
{
// This packet isn't supported, don't try calling it again
m_supports_QSaveRegisterState = eLazyBoolNo;
}
const uint32_t response_save_id = response.GetU32(0);
if (response_save_id != 0)
{
save_id = response_save_id;
return true;
}
}
}
}
return false;
}
bool
GDBRemoteCommunicationClient::RestoreRegisterState (lldb::tid_t tid, uint32_t save_id)
{
// We use the "m_supports_QSaveRegisterState" variable here becuase the
// QSaveRegisterState and QRestoreRegisterState packets must both be supported in
// order to be useful
if (m_supports_QSaveRegisterState == eLazyBoolNo)
return false;
Mutex::Locker locker;
if (GetSequenceMutex (locker, "Didn't get sequence mutex for QRestoreRegisterState."))
{
const bool thread_suffix_supported = GetThreadSuffixSupported();
if (thread_suffix_supported || SetCurrentThread(tid))
{
char packet[256];
if (thread_suffix_supported)
::snprintf (packet, sizeof(packet), "QRestoreRegisterState:%u;thread:%4.4" PRIx64 ";", save_id, tid);
else
::snprintf (packet, sizeof(packet), "QRestoreRegisterState:%u" PRIx64 ";", save_id);
StringExtractorGDBRemote response;
if (SendPacketAndWaitForResponse(packet, response, false) == PacketResult::Success)
{
if (response.IsOKResponse())
{
return true;
}
else if (response.IsUnsupportedResponse())
{
// This packet isn't supported, don't try calling this packet or
// QSaveRegisterState again...
m_supports_QSaveRegisterState = eLazyBoolNo;
}
}
}
}
return false;
}