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//===-- tsan_report.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
//
//===----------------------------------------------------------------------===//
//
// This file is a part of ThreadSanitizer (TSan), a race detector.
//
//===----------------------------------------------------------------------===//
#include "tsan_report.h"
#include "tsan_platform.h"
#include "tsan_rtl.h"
#include "sanitizer_common/sanitizer_file.h"
#include "sanitizer_common/sanitizer_placement_new.h"
#include "sanitizer_common/sanitizer_report_decorator.h"
#include "sanitizer_common/sanitizer_stacktrace_printer.h"
namespace __tsan {
class Decorator: public __sanitizer::SanitizerCommonDecorator {
public:
Decorator() : SanitizerCommonDecorator() { }
const char *Access() { return Blue(); }
const char *ThreadDescription() { return Cyan(); }
const char *Location() { return Green(); }
const char *Sleep() { return Yellow(); }
const char *Mutex() { return Magenta(); }
};
ReportDesc::ReportDesc()
: tag(kExternalTagNone)
, stacks()
, mops()
, locs()
, mutexes()
, threads()
, unique_tids()
, sleep()
, count() {
}
ReportMop::ReportMop()
: mset() {
}
ReportDesc::~ReportDesc() {
// FIXME(dvyukov): it must be leaking a lot of memory.
}
#if !SANITIZER_GO
const int kThreadBufSize = 32;
const char *thread_name(char *buf, Tid tid) {
if (tid == kMainTid)
return "main thread";
internal_snprintf(buf, kThreadBufSize, "thread T%d", tid);
return buf;
}
static const char *ReportTypeString(ReportType typ, uptr tag) {
switch (typ) {
case ReportTypeRace:
return "data race";
case ReportTypeVptrRace:
return "data race on vptr (ctor/dtor vs virtual call)";
case ReportTypeUseAfterFree:
return "heap-use-after-free";
case ReportTypeVptrUseAfterFree:
return "heap-use-after-free (virtual call vs free)";
case ReportTypeExternalRace: {
const char *str = GetReportHeaderFromTag(tag);
return str ? str : "race on external object";
}
case ReportTypeThreadLeak:
return "thread leak";
case ReportTypeMutexDestroyLocked:
return "destroy of a locked mutex";
case ReportTypeMutexDoubleLock:
return "double lock of a mutex";
case ReportTypeMutexInvalidAccess:
return "use of an invalid mutex (e.g. uninitialized or destroyed)";
case ReportTypeMutexBadUnlock:
return "unlock of an unlocked mutex (or by a wrong thread)";
case ReportTypeMutexBadReadLock:
return "read lock of a write locked mutex";
case ReportTypeMutexBadReadUnlock:
return "read unlock of a write locked mutex";
case ReportTypeSignalUnsafe:
return "signal-unsafe call inside of a signal";
case ReportTypeErrnoInSignal:
return "signal handler spoils errno";
case ReportTypeDeadlock:
return "lock-order-inversion (potential deadlock)";
// No default case so compiler warns us if we miss one
}
UNREACHABLE("missing case");
}
#if SANITIZER_APPLE
static const char *const kInterposedFunctionPrefix = "wrap_";
#else
static const char *const kInterposedFunctionPrefix = "__interceptor_";
#endif
void PrintStack(const ReportStack *ent) {
if (ent == 0 || ent->frames == 0) {
Printf(" [failed to restore the stack]\n\n");
return;
}
SymbolizedStack *frame = ent->frames;
for (int i = 0; frame && frame->info.address; frame = frame->next, i++) {
InternalScopedString res;
RenderFrame(&res, common_flags()->stack_trace_format, i,
frame->info.address, &frame->info,
common_flags()->symbolize_vs_style,
common_flags()->strip_path_prefix, kInterposedFunctionPrefix);
Printf("%s\n", res.data());
}
Printf("\n");
}
static void PrintMutexSet(Vector<ReportMopMutex> const& mset) {
for (uptr i = 0; i < mset.Size(); i++) {
if (i == 0)
Printf(" (mutexes:");
const ReportMopMutex m = mset[i];
Printf(" %s M%u", m.write ? "write" : "read", m.id);
Printf(i == mset.Size() - 1 ? ")" : ",");
}
}
static const char *MopDesc(bool first, bool write, bool atomic) {
return atomic ? (first ? (write ? "Atomic write" : "Atomic read")
: (write ? "Previous atomic write" : "Previous atomic read"))
: (first ? (write ? "Write" : "Read")
: (write ? "Previous write" : "Previous read"));
}
static const char *ExternalMopDesc(bool first, bool write) {
return first ? (write ? "Modifying" : "Read-only")
: (write ? "Previous modifying" : "Previous read-only");
}
static void PrintMop(const ReportMop *mop, bool first) {
Decorator d;
char thrbuf[kThreadBufSize];
Printf("%s", d.Access());
if (mop->external_tag == kExternalTagNone) {
Printf(" %s of size %d at %p by %s",
MopDesc(first, mop->write, mop->atomic), mop->size,
(void *)mop->addr, thread_name(thrbuf, mop->tid));
} else {
const char *object_type = GetObjectTypeFromTag(mop->external_tag);
if (object_type == nullptr)
object_type = "external object";
Printf(" %s access of %s at %p by %s",
ExternalMopDesc(first, mop->write), object_type,
(void *)mop->addr, thread_name(thrbuf, mop->tid));
}
PrintMutexSet(mop->mset);
Printf(":\n");
Printf("%s", d.Default());
PrintStack(mop->stack);
}
static void PrintLocation(const ReportLocation *loc) {
Decorator d;
char thrbuf[kThreadBufSize];
bool print_stack = false;
Printf("%s", d.Location());
if (loc->type == ReportLocationGlobal) {
const DataInfo &global = loc->global;
if (global.size != 0)
Printf(" Location is global '%s' of size %zu at %p (%s+0x%zx)\n\n",
global.name, global.size, reinterpret_cast<void *>(global.start),
StripModuleName(global.module), global.module_offset);
else
Printf(" Location is global '%s' at %p (%s+0x%zx)\n\n", global.name,
reinterpret_cast<void *>(global.start),
StripModuleName(global.module), global.module_offset);
} else if (loc->type == ReportLocationHeap) {
char thrbuf[kThreadBufSize];
const char *object_type = GetObjectTypeFromTag(loc->external_tag);
if (!object_type) {
Printf(" Location is heap block of size %zu at %p allocated by %s:\n",
loc->heap_chunk_size,
reinterpret_cast<void *>(loc->heap_chunk_start),
thread_name(thrbuf, loc->tid));
} else {
Printf(" Location is %s of size %zu at %p allocated by %s:\n",
object_type, loc->heap_chunk_size,
reinterpret_cast<void *>(loc->heap_chunk_start),
thread_name(thrbuf, loc->tid));
}
print_stack = true;
} else if (loc->type == ReportLocationStack) {
Printf(" Location is stack of %s.\n\n", thread_name(thrbuf, loc->tid));
} else if (loc->type == ReportLocationTLS) {
Printf(" Location is TLS of %s.\n\n", thread_name(thrbuf, loc->tid));
} else if (loc->type == ReportLocationFD) {
Printf(" Location is file descriptor %d %s by %s at:\n", loc->fd,
loc->fd_closed ? "destroyed" : "created",
thread_name(thrbuf, loc->tid));
print_stack = true;
}
Printf("%s", d.Default());
if (print_stack)
PrintStack(loc->stack);
}
static void PrintMutexShort(const ReportMutex *rm, const char *after) {
Decorator d;
Printf("%sM%d%s%s", d.Mutex(), rm->id, d.Default(), after);
}
static void PrintMutexShortWithAddress(const ReportMutex *rm,
const char *after) {
Decorator d;
Printf("%sM%d (%p)%s%s", d.Mutex(), rm->id,
reinterpret_cast<void *>(rm->addr), d.Default(), after);
}
static void PrintMutex(const ReportMutex *rm) {
Decorator d;
Printf("%s", d.Mutex());
Printf(" Mutex M%u (%p) created at:\n", rm->id,
reinterpret_cast<void *>(rm->addr));
Printf("%s", d.Default());
PrintStack(rm->stack);
}
static void PrintThread(const ReportThread *rt) {
Decorator d;
if (rt->id == kMainTid) // Little sense in describing the main thread.
return;
Printf("%s", d.ThreadDescription());
Printf(" Thread T%d", rt->id);
if (rt->name && rt->name[0] != '\0')
Printf(" '%s'", rt->name);
char thrbuf[kThreadBufSize];
const char *thread_status = rt->running ? "running" : "finished";
if (rt->thread_type == ThreadType::Worker) {
Printf(" (tid=%llu, %s) is a GCD worker thread\n", rt->os_id,
thread_status);
Printf("\n");
Printf("%s", d.Default());
return;
}
Printf(" (tid=%llu, %s) created by %s", rt->os_id, thread_status,
thread_name(thrbuf, rt->parent_tid));
if (rt->stack)
Printf(" at:");
Printf("\n");
Printf("%s", d.Default());
PrintStack(rt->stack);
}
static void PrintSleep(const ReportStack *s) {
Decorator d;
Printf("%s", d.Sleep());
Printf(" As if synchronized via sleep:\n");
Printf("%s", d.Default());
PrintStack(s);
}
static ReportStack *ChooseSummaryStack(const ReportDesc *rep) {
if (rep->mops.Size())
return rep->mops[0]->stack;
if (rep->stacks.Size())
return rep->stacks[0];
if (rep->mutexes.Size())
return rep->mutexes[0]->stack;
if (rep->threads.Size())
return rep->threads[0]->stack;
return 0;
}
static bool FrameIsInternal(const SymbolizedStack *frame) {
if (frame == 0)
return false;
const char *file = frame->info.file;
const char *module = frame->info.module;
if (file != 0 &&
(internal_strstr(file, "tsan_interceptors_posix.cpp") ||
internal_strstr(file, "sanitizer_common_interceptors.inc") ||
internal_strstr(file, "tsan_interface_")))
return true;
if (module != 0 && (internal_strstr(module, "libclang_rt.tsan_")))
return true;
return false;
}
static SymbolizedStack *SkipTsanInternalFrames(SymbolizedStack *frames) {
while (FrameIsInternal(frames) && frames->next)
frames = frames->next;
return frames;
}
void PrintReport(const ReportDesc *rep) {
Decorator d;
Printf("==================\n");
const char *rep_typ_str = ReportTypeString(rep->typ, rep->tag);
Printf("%s", d.Warning());
Printf("WARNING: ThreadSanitizer: %s (pid=%d)\n", rep_typ_str,
(int)internal_getpid());
Printf("%s", d.Default());
if (rep->typ == ReportTypeErrnoInSignal)
Printf(" Signal %u handler invoked at:\n", rep->signum);
if (rep->typ == ReportTypeDeadlock) {
char thrbuf[kThreadBufSize];
Printf(" Cycle in lock order graph: ");
for (uptr i = 0; i < rep->mutexes.Size(); i++)
PrintMutexShortWithAddress(rep->mutexes[i], " => ");
PrintMutexShort(rep->mutexes[0], "\n\n");
CHECK_GT(rep->mutexes.Size(), 0U);
CHECK_EQ(rep->mutexes.Size() * (flags()->second_deadlock_stack ? 2 : 1),
rep->stacks.Size());
for (uptr i = 0; i < rep->mutexes.Size(); i++) {
Printf(" Mutex ");
PrintMutexShort(rep->mutexes[(i + 1) % rep->mutexes.Size()],
" acquired here while holding mutex ");
PrintMutexShort(rep->mutexes[i], " in ");
Printf("%s", d.ThreadDescription());
Printf("%s:\n", thread_name(thrbuf, rep->unique_tids[i]));
Printf("%s", d.Default());
if (flags()->second_deadlock_stack) {
PrintStack(rep->stacks[2*i]);
Printf(" Mutex ");
PrintMutexShort(rep->mutexes[i],
" previously acquired by the same thread here:\n");
PrintStack(rep->stacks[2*i+1]);
} else {
PrintStack(rep->stacks[i]);
if (i == 0)
Printf(" Hint: use TSAN_OPTIONS=second_deadlock_stack=1 "
"to get more informative warning message\n\n");
}
}
} else {
for (uptr i = 0; i < rep->stacks.Size(); i++) {
if (i)
Printf(" and:\n");
PrintStack(rep->stacks[i]);
}
}
for (uptr i = 0; i < rep->mops.Size(); i++)
PrintMop(rep->mops[i], i == 0);
if (rep->sleep)
PrintSleep(rep->sleep);
for (uptr i = 0; i < rep->locs.Size(); i++)
PrintLocation(rep->locs[i]);
if (rep->typ != ReportTypeDeadlock) {
for (uptr i = 0; i < rep->mutexes.Size(); i++)
PrintMutex(rep->mutexes[i]);
}
for (uptr i = 0; i < rep->threads.Size(); i++)
PrintThread(rep->threads[i]);
if (rep->typ == ReportTypeThreadLeak && rep->count > 1)
Printf(" And %d more similar thread leaks.\n\n", rep->count - 1);
if (ReportStack *stack = ChooseSummaryStack(rep)) {
if (SymbolizedStack *frame = SkipTsanInternalFrames(stack->frames))
ReportErrorSummary(rep_typ_str, frame->info);
}
if (common_flags()->print_module_map == 2)
DumpProcessMap();
Printf("==================\n");
}
#else // #if !SANITIZER_GO
const Tid kMainGoroutineId = 1;
void PrintStack(const ReportStack *ent) {
if (ent == 0 || ent->frames == 0) {
Printf(" [failed to restore the stack]\n");
return;
}
SymbolizedStack *frame = ent->frames;
for (int i = 0; frame; frame = frame->next, i++) {
const AddressInfo &info = frame->info;
Printf(" %s()\n %s:%d +0x%zx\n", info.function,
StripPathPrefix(info.file, common_flags()->strip_path_prefix),
info.line, info.module_offset);
}
}
static void PrintMop(const ReportMop *mop, bool first) {
Printf("\n");
Printf("%s at %p by ",
(first ? (mop->write ? "Write" : "Read")
: (mop->write ? "Previous write" : "Previous read")),
reinterpret_cast<void *>(mop->addr));
if (mop->tid == kMainGoroutineId)
Printf("main goroutine:\n");
else
Printf("goroutine %d:\n", mop->tid);
PrintStack(mop->stack);
}
static void PrintLocation(const ReportLocation *loc) {
switch (loc->type) {
case ReportLocationHeap: {
Printf("\n");
Printf("Heap block of size %zu at %p allocated by ", loc->heap_chunk_size,
reinterpret_cast<void *>(loc->heap_chunk_start));
if (loc->tid == kMainGoroutineId)
Printf("main goroutine:\n");
else
Printf("goroutine %d:\n", loc->tid);
PrintStack(loc->stack);
break;
}
case ReportLocationGlobal: {
Printf("\n");
Printf("Global var %s of size %zu at %p declared at %s:%zu\n",
loc->global.name, loc->global.size,
reinterpret_cast<void *>(loc->global.start), loc->global.file,
loc->global.line);
break;
}
default:
break;
}
}
static void PrintThread(const ReportThread *rt) {
if (rt->id == kMainGoroutineId)
return;
Printf("\n");
Printf("Goroutine %d (%s) created at:\n",
rt->id, rt->running ? "running" : "finished");
PrintStack(rt->stack);
}
void PrintReport(const ReportDesc *rep) {
Printf("==================\n");
if (rep->typ == ReportTypeRace) {
Printf("WARNING: DATA RACE");
for (uptr i = 0; i < rep->mops.Size(); i++)
PrintMop(rep->mops[i], i == 0);
for (uptr i = 0; i < rep->locs.Size(); i++)
PrintLocation(rep->locs[i]);
for (uptr i = 0; i < rep->threads.Size(); i++)
PrintThread(rep->threads[i]);
} else if (rep->typ == ReportTypeDeadlock) {
Printf("WARNING: DEADLOCK\n");
for (uptr i = 0; i < rep->mutexes.Size(); i++) {
Printf("Goroutine %d lock mutex %u while holding mutex %u:\n", 999,
rep->mutexes[i]->id,
rep->mutexes[(i + 1) % rep->mutexes.Size()]->id);
PrintStack(rep->stacks[2*i]);
Printf("\n");
Printf("Mutex %u was previously locked here:\n",
rep->mutexes[(i + 1) % rep->mutexes.Size()]->id);
PrintStack(rep->stacks[2*i + 1]);
Printf("\n");
}
}
Printf("==================\n");
}
#endif
} // namespace __tsan