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llvm-project/lldb/source/Plugins/Process/Linux/NativeThreadLinux.cpp
Jason Molenda fb36a54ef6
[lldb] Rename formatv verbose log call, misc log cleanups [NFC] (#186951) 
lldb had three preprocessor defines for logging,

LLDB_LOG  - formatv style argument
LLDB_LOGF - printf style argument
LLDB_LOGV - formatv style argument, only when verbose enabled

If you weren't looking at Log.h and the definition of these three, and
wanted to log something with formatv, it was easy to use LLDB_LOGV by
accident. We just had a situation where an important log statement
wasn't logging and it turned out to be this. This is fragile if you
aren't looking at the header directly, so I'd like to make this more
explicit. My proposal:

LLDB_LOG  - formatv style argument
LLDB_LOG_VERBOSE - formatv style argument, only when verbose enabled 
LLDB_LOGF - printf style argument
LLDB_LOGF_VERBOSE - printf style argument, only when verbose enabled

The new fouth one is to remove several places where we do `if (log &&
log->GetVerbose()) LLDB_LOGF (...)` in the sources today, and make both
styles consistent.

This PR implements that change, mechanically changing all LLDB_LOGV's to
LLDB_LOG_VERBOSE.

It also updates many of the `if (log && log->GetVerbose()) LLDB_LOGF`'s.
Some uses of this conditional expression do extra calculations in
addition to logging, and so those were left as-is so we're not doing
throwaway work when running without verbose logging.

There were many instances throughout lldb where callers are still doing
`if (log) LLDB_LOG*(...)`, a remnant of when all calls were to the `Log`
object's `Printf()` method, and you had to check if your local Log*
pointer was non-nullptr before calling the method. I removed those,
again keeping ones where work for logging is done in the block of code.

The code changes are all mechanical and uninteresting, but the question
of whether this naming change is widely agreed on is maybe worth
discussing.
2026-03-18 16:31:33 -07:00

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//===-- NativeThreadLinux.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 "NativeThreadLinux.h"
#include <csignal>
#include <sstream>
#include "NativeProcessLinux.h"
#include "NativeRegisterContextLinux.h"
#include "SingleStepCheck.h"
#include "lldb/Host/HostNativeThread.h"
#include "lldb/Host/linux/Ptrace.h"
#include "lldb/Host/linux/Support.h"
#include "lldb/Utility/LLDBAssert.h"
#include "lldb/Utility/LLDBLog.h"
#include "lldb/Utility/Log.h"
#include "lldb/Utility/State.h"
#include "lldb/lldb-enumerations.h"
#include "llvm/ADT/SmallString.h"
#include "Plugins/Process/POSIX/CrashReason.h"
#include "Plugins/Process/Utility/MemoryTagManagerAArch64MTE.h"
#include <sys/syscall.h>
// Try to define a macro to encapsulate the tgkill syscall
#define tgkill(pid, tid, sig) \
syscall(__NR_tgkill, static_cast<::pid_t>(pid), static_cast<::pid_t>(tid), \
sig)
using namespace lldb;
using namespace lldb_private;
using namespace lldb_private::process_linux;
namespace {
void LogThreadStopInfo(Log &log, const ThreadStopInfo &stop_info,
const char *const header) {
switch (stop_info.reason) {
case eStopReasonNone:
log.Printf("%s: %s no stop reason", __FUNCTION__, header);
return;
case eStopReasonTrace:
log.Printf("%s: %s trace, stopping signal 0x%" PRIx32, __FUNCTION__, header,
stop_info.signo);
return;
case eStopReasonBreakpoint:
log.Printf("%s: %s breakpoint, stopping signal 0x%" PRIx32, __FUNCTION__,
header, stop_info.signo);
return;
case eStopReasonWatchpoint:
log.Printf("%s: %s watchpoint, stopping signal 0x%" PRIx32, __FUNCTION__,
header, stop_info.signo);
return;
case eStopReasonSignal:
log.Printf("%s: %s signal 0x%02" PRIx32, __FUNCTION__, header,
stop_info.signo);
return;
case eStopReasonException:
log.Printf("%s: %s exception type 0x%02" PRIx64, __FUNCTION__, header,
stop_info.details.exception.type);
return;
case eStopReasonExec:
log.Printf("%s: %s exec, stopping signal 0x%" PRIx32, __FUNCTION__, header,
stop_info.signo);
return;
case eStopReasonPlanComplete:
log.Printf("%s: %s plan complete", __FUNCTION__, header);
return;
case eStopReasonThreadExiting:
log.Printf("%s: %s thread exiting", __FUNCTION__, header);
return;
case eStopReasonInstrumentation:
log.Printf("%s: %s instrumentation", __FUNCTION__, header);
return;
case eStopReasonProcessorTrace:
log.Printf("%s: %s processor trace", __FUNCTION__, header);
return;
case eStopReasonHistoryBoundary:
log.Printf("%s: %s history boundary", __FUNCTION__, header);
return;
default:
log.Printf("%s: %s invalid stop reason %" PRIu32, __FUNCTION__, header,
static_cast<uint32_t>(stop_info.reason));
}
}
}
NativeThreadLinux::NativeThreadLinux(NativeProcessLinux &process,
lldb::tid_t tid)
: NativeThreadProtocol(process, tid), m_state(StateType::eStateInvalid),
m_stop_info(),
m_reg_context_up(
NativeRegisterContextLinux::CreateHostNativeRegisterContextLinux(
process.GetArchitecture(), *this)),
m_stop_description() {}
std::string NativeThreadLinux::GetName() {
NativeProcessLinux &process = GetProcess();
auto BufferOrError = getProcFile(process.GetID(), GetID(), "comm");
if (!BufferOrError)
return "";
return std::string(BufferOrError.get()->getBuffer().rtrim('\n'));
}
lldb::StateType NativeThreadLinux::GetState() { return m_state; }
bool NativeThreadLinux::GetStopReason(ThreadStopInfo &stop_info,
std::string &description) {
Log *log = GetLog(LLDBLog::Thread);
description.clear();
switch (m_state) {
case eStateStopped:
case eStateCrashed:
case eStateExited:
case eStateSuspended:
case eStateUnloaded:
if (log)
LogThreadStopInfo(*log, m_stop_info, "m_stop_info in thread:");
stop_info = m_stop_info;
description = m_stop_description;
if (log)
LogThreadStopInfo(*log, stop_info, "returned stop_info:");
return true;
case eStateInvalid:
case eStateConnected:
case eStateAttaching:
case eStateLaunching:
case eStateRunning:
case eStateStepping:
case eStateDetached:
LLDB_LOGF(log,
"NativeThreadLinux::%s tid %" PRIu64
" in state %s cannot answer stop reason",
__FUNCTION__, GetID(), StateAsCString(m_state));
return false;
}
llvm_unreachable("unhandled StateType!");
}
Status NativeThreadLinux::SetWatchpoint(lldb::addr_t addr, size_t size,
uint32_t watch_flags, bool hardware) {
if (!hardware)
return Status::FromErrorString("not implemented");
if (m_state == eStateLaunching)
return Status();
Status error = RemoveWatchpoint(addr);
if (error.Fail())
return error;
uint32_t wp_index =
m_reg_context_up->SetHardwareWatchpoint(addr, size, watch_flags);
if (wp_index == LLDB_INVALID_INDEX32)
return Status::FromErrorString("Setting hardware watchpoint failed.");
m_watchpoint_index_map.insert({addr, wp_index});
return Status();
}
Status NativeThreadLinux::RemoveWatchpoint(lldb::addr_t addr) {
auto wp = m_watchpoint_index_map.find(addr);
if (wp == m_watchpoint_index_map.end())
return Status();
uint32_t wp_index = wp->second;
m_watchpoint_index_map.erase(wp);
if (m_reg_context_up->ClearHardwareWatchpoint(wp_index))
return Status();
return Status::FromErrorString("Clearing hardware watchpoint failed.");
}
Status NativeThreadLinux::SetHardwareBreakpoint(lldb::addr_t addr,
size_t size) {
if (m_state == eStateLaunching)
return Status();
Status error = RemoveHardwareBreakpoint(addr);
if (error.Fail())
return error;
uint32_t bp_index = m_reg_context_up->SetHardwareBreakpoint(addr, size);
if (bp_index == LLDB_INVALID_INDEX32)
return Status::FromErrorString("Setting hardware breakpoint failed.");
m_hw_break_index_map.insert({addr, bp_index});
return Status();
}
Status NativeThreadLinux::RemoveHardwareBreakpoint(lldb::addr_t addr) {
auto bp = m_hw_break_index_map.find(addr);
if (bp == m_hw_break_index_map.end())
return Status();
uint32_t bp_index = bp->second;
if (m_reg_context_up->ClearHardwareBreakpoint(bp_index)) {
m_hw_break_index_map.erase(bp);
return Status();
}
return Status::FromErrorString("Clearing hardware breakpoint failed.");
}
Status NativeThreadLinux::Resume(uint32_t signo) {
const StateType new_state = StateType::eStateRunning;
MaybeLogStateChange(new_state);
m_state = new_state;
m_stop_info.reason = StopReason::eStopReasonNone;
m_stop_description.clear();
// If watchpoints have been set, but none on this thread, then this is a new
// thread. So set all existing watchpoints.
if (m_watchpoint_index_map.empty()) {
NativeProcessLinux &process = GetProcess();
const auto &watchpoint_map = process.GetWatchpointMap();
m_reg_context_up->ClearAllHardwareWatchpoints();
for (const auto &pair : watchpoint_map) {
const auto &wp = pair.second;
SetWatchpoint(wp.m_addr, wp.m_size, wp.m_watch_flags, wp.m_hardware);
}
}
// Set all active hardware breakpoint on all threads.
if (m_hw_break_index_map.empty()) {
NativeProcessLinux &process = GetProcess();
const auto &hw_breakpoint_map = process.GetHardwareBreakpointMap();
m_reg_context_up->ClearAllHardwareBreakpoints();
for (const auto &pair : hw_breakpoint_map) {
const auto &bp = pair.second;
SetHardwareBreakpoint(bp.m_addr, bp.m_size);
}
}
intptr_t data = 0;
if (signo != LLDB_INVALID_SIGNAL_NUMBER)
data = signo;
return NativeProcessLinux::PtraceWrapper(PTRACE_CONT, GetID(), nullptr,
reinterpret_cast<void *>(data));
}
Status NativeThreadLinux::SingleStep(uint32_t signo) {
const StateType new_state = StateType::eStateStepping;
MaybeLogStateChange(new_state);
m_state = new_state;
m_stop_info.reason = StopReason::eStopReasonNone;
if(!m_step_workaround) {
// If we already hava a workaround inplace, don't reset it. Otherwise, the
// destructor of the existing instance will run after the new instance has
// fetched the cpu mask, and the thread will end up with the wrong mask.
m_step_workaround = SingleStepWorkaround::Get(m_tid);
}
intptr_t data = 0;
if (signo != LLDB_INVALID_SIGNAL_NUMBER)
data = signo;
// If hardware single-stepping is not supported, we just do a continue. The
// breakpoint on the next instruction has been setup in
// NativeProcessLinux::Resume.
return NativeProcessLinux::PtraceWrapper(
GetProcess().SupportHardwareSingleStepping() ? PTRACE_SINGLESTEP
: PTRACE_CONT,
m_tid, nullptr, reinterpret_cast<void *>(data));
}
void NativeThreadLinux::SetStoppedBySignal(uint32_t signo,
const siginfo_t *info) {
Log *log = GetLog(LLDBLog::Thread);
LLDB_LOGF(log, "NativeThreadLinux::%s called with signal 0x%02" PRIx32,
__FUNCTION__, signo);
SetStopped();
m_stop_info.reason = StopReason::eStopReasonSignal;
m_stop_info.signo = signo;
m_stop_description.clear();
if (info) {
switch (signo) {
case SIGSEGV:
case SIGBUS:
case SIGFPE:
case SIGILL:
m_stop_description = GetCrashReasonString(*info);
#ifndef SEGV_MTESERR
#define SEGV_MTESERR 9
#endif
if (info->si_signo == SIGSEGV && info->si_code == SEGV_MTESERR)
AnnotateSyncTagCheckFault(
reinterpret_cast<lldb::addr_t>(info->si_addr));
break;
}
}
}
void NativeThreadLinux::AnnotateSyncTagCheckFault(lldb::addr_t fault_addr) {
int32_t allocation_tag_type = 0;
switch (GetProcess().GetArchitecture().GetMachine()) {
// aarch64_32 deliberately not here because there's no 32 bit MTE
case llvm::Triple::aarch64:
case llvm::Triple::aarch64_be:
allocation_tag_type = MemoryTagManagerAArch64MTE::eMTE_allocation;
break;
default:
return;
}
auto details =
GetRegisterContext().GetMemoryTaggingDetails(allocation_tag_type);
if (!details) {
llvm::consumeError(details.takeError());
return;
}
// We assume that the stop description is currently:
// signal SIGSEGV: sync tag check fault (fault address=<addr>)
// Remove the closing )
m_stop_description.pop_back();
std::stringstream ss;
std::unique_ptr<MemoryTagManager> manager(std::move(details->manager));
ss << " logical tag=0x" << std::hex << manager->GetLogicalTag(fault_addr);
std::vector<uint8_t> allocation_tag_data;
// The fault address may not be granule aligned. ReadMemoryTags will granule
// align any range you give it, potentially making it larger.
// To prevent this set len to 1. This always results in a range that is at
// most 1 granule in size and includes fault_addr.
Status status = GetProcess().ReadMemoryTags(allocation_tag_type, fault_addr,
1, allocation_tag_data);
if (status.Success()) {
llvm::Expected<std::vector<lldb::addr_t>> allocation_tag =
manager->UnpackTagsData(allocation_tag_data, 1);
if (allocation_tag) {
ss << " allocation tag=0x" << std::hex << allocation_tag->front() << ")";
} else {
llvm::consumeError(allocation_tag.takeError());
ss << ")";
}
} else
ss << ")";
m_stop_description += ss.str();
}
bool NativeThreadLinux::IsStopped(int *signo) {
if (!StateIsStoppedState(m_state, false))
return false;
// If we are stopped by a signal, return the signo.
if (signo && m_state == StateType::eStateStopped &&
m_stop_info.reason == StopReason::eStopReasonSignal) {
*signo = m_stop_info.signo;
}
// Regardless, we are stopped.
return true;
}
void NativeThreadLinux::SetStopped() {
if (m_state == StateType::eStateStepping)
m_step_workaround.reset();
// On every stop, clear any cached register data structures
GetRegisterContext().InvalidateAllRegisters();
const StateType new_state = StateType::eStateStopped;
MaybeLogStateChange(new_state);
m_state = new_state;
m_stop_description.clear();
}
void NativeThreadLinux::SetStoppedByExec() {
Log *log = GetLog(LLDBLog::Thread);
LLDB_LOGF(log, "NativeThreadLinux::%s()", __FUNCTION__);
SetStopped();
m_stop_info.reason = StopReason::eStopReasonExec;
m_stop_info.signo = SIGSTOP;
}
void NativeThreadLinux::SetStoppedByBreakpoint() {
SetStopped();
m_stop_info.reason = StopReason::eStopReasonBreakpoint;
m_stop_info.signo = SIGTRAP;
m_stop_description.clear();
}
void NativeThreadLinux::SetStoppedByWatchpoint(uint32_t wp_index) {
SetStopped();
lldbassert(wp_index != LLDB_INVALID_INDEX32 && "wp_index cannot be invalid");
std::ostringstream ostr;
ostr << m_reg_context_up->GetWatchpointAddress(wp_index) << " ";
ostr << wp_index;
/*
* MIPS: Last 3bits of the watchpoint address are masked by the kernel. For
* example:
* 'n' is at 0x120010d00 and 'm' is 0x120010d04. When a watchpoint is set at
* 'm', then
* watch exception is generated even when 'n' is read/written. To handle this
* case,
* find the base address of the load/store instruction and append it in the
* stop-info
* packet.
*/
ostr << " " << m_reg_context_up->GetWatchpointHitAddress(wp_index);
m_stop_description = ostr.str();
m_stop_info.reason = StopReason::eStopReasonWatchpoint;
m_stop_info.signo = SIGTRAP;
}
bool NativeThreadLinux::IsStoppedAtBreakpoint() {
return GetState() == StateType::eStateStopped &&
m_stop_info.reason == StopReason::eStopReasonBreakpoint;
}
bool NativeThreadLinux::IsStoppedAtWatchpoint() {
return GetState() == StateType::eStateStopped &&
m_stop_info.reason == StopReason::eStopReasonWatchpoint;
}
void NativeThreadLinux::SetStoppedByTrace() {
SetStopped();
m_stop_info.reason = StopReason::eStopReasonTrace;
m_stop_info.signo = SIGTRAP;
}
void NativeThreadLinux::SetStoppedByFork(bool is_vfork, lldb::pid_t child_pid) {
SetStopped();
m_stop_info.reason =
is_vfork ? StopReason::eStopReasonVFork : StopReason::eStopReasonFork;
m_stop_info.signo = SIGTRAP;
m_stop_info.details.fork.child_pid = child_pid;
m_stop_info.details.fork.child_tid = child_pid;
m_stop_description = std::to_string(child_pid);
m_stop_description += " ";
m_stop_description += std::to_string(child_pid);
}
void NativeThreadLinux::SetStoppedByVForkDone() {
SetStopped();
m_stop_info.reason = StopReason::eStopReasonVForkDone;
m_stop_info.signo = SIGTRAP;
}
void NativeThreadLinux::SetStoppedWithNoReason() {
SetStopped();
m_stop_info.reason = StopReason::eStopReasonNone;
m_stop_info.signo = 0;
}
void NativeThreadLinux::SetStoppedByProcessorTrace(
llvm::StringRef description) {
SetStopped();
m_stop_info.reason = StopReason::eStopReasonProcessorTrace;
m_stop_info.signo = 0;
m_stop_description = description.str();
}
void NativeThreadLinux::SetExited() {
const StateType new_state = StateType::eStateExited;
MaybeLogStateChange(new_state);
m_state = new_state;
m_stop_info.reason = StopReason::eStopReasonThreadExiting;
}
Status NativeThreadLinux::RequestStop() {
Log *log = GetLog(LLDBLog::Thread);
NativeProcessLinux &process = GetProcess();
lldb::pid_t pid = process.GetID();
lldb::tid_t tid = GetID();
LLDB_LOGF(log,
"NativeThreadLinux::%s requesting thread stop(pid: %" PRIu64
", tid: %" PRIu64 ")",
__FUNCTION__, pid, tid);
Status err;
errno = 0;
if (::tgkill(pid, tid, SIGSTOP) != 0) {
err = Status::FromErrno();
LLDB_LOGF(log,
"NativeThreadLinux::%s tgkill(%" PRIu64 ", %" PRIu64
", SIGSTOP) failed: %s",
__FUNCTION__, pid, tid, err.AsCString());
}
return err;
}
void NativeThreadLinux::MaybeLogStateChange(lldb::StateType new_state) {
Log *log = GetLog(LLDBLog::Thread);
// If we're not logging, we're done.
if (!log)
return;
// If this is a state change to the same state, we're done.
lldb::StateType old_state = m_state;
if (new_state == old_state)
return;
LLDB_LOG(log, "pid={0}, tid={1}: changing from state {2} to {3}",
m_process.GetID(), GetID(), old_state, new_state);
}
NativeProcessLinux &NativeThreadLinux::GetProcess() {
return static_cast<NativeProcessLinux &>(m_process);
}
const NativeProcessLinux &NativeThreadLinux::GetProcess() const {
return static_cast<const NativeProcessLinux &>(m_process);
}
llvm::Expected<std::unique_ptr<llvm::MemoryBuffer>>
NativeThreadLinux::GetSiginfo() const {
auto siginfo_buf =
llvm::WritableMemoryBuffer::getNewUninitMemBuffer(sizeof(siginfo_t));
Status error =
GetProcess().GetSignalInfo(GetID(), siginfo_buf->getBufferStart());
if (!error.Success())
return error.ToError();
return std::move(siginfo_buf);
}
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