Files
clang-p2996/compiler-rt/lib/tsan/rtl/tsan_platform_linux.cc
Adhemerval Zanella d7984710ae [tsan] Enable tsan for aarch64
This patch enabled TSAN for aarch64 with 39-bit VMA layout.  As defined by
tsan_platform.h the layout used is:

0000 4000 00 - 0200 0000 00: main binary
2000 0000 00 - 4000 0000 00: shadow memory
4000 0000 00 - 5000 0000 00: metainfo
5000 0000 00 - 6000 0000 00: -
6000 0000 00 - 6200 0000 00: traces
6200 0000 00 - 7d00 0000 00: -
7d00 0000 00 - 7e00 0000 00: heap
7e00 0000 00 - 7fff ffff ff: modules and main thread stack

Which gives it about 8GB for main binary, 4GB for heap and 8GB for
modules and main thread stack.

Most of tests are passing, with the exception of:

 * ignore_lib0, ignore_lib1, ignore_lib3 due a kernel limitation for
   no support to make mmap page non-executable.

 * longjmp tests due missing specialized assembly routines.

These tests are xfail for now.

The only tsan issue still showing is:

  rtl/TsanRtlTest/Posix.ThreadLocalAccesses

Which still required further investigation.  The test is disable for
aarch64 for now.

llvm-svn: 244055
2015-08-05 15:17:59 +00:00

424 lines
14 KiB
C++

//===-- tsan_platform_linux.cc --------------------------------------------===//
//
// The LLVM Compiler Infrastructure
//
// This file is distributed under the University of Illinois Open Source
// License. See LICENSE.TXT for details.
//
//===----------------------------------------------------------------------===//
//
// This file is a part of ThreadSanitizer (TSan), a race detector.
//
// Linux- and FreeBSD-specific code.
//===----------------------------------------------------------------------===//
#include "sanitizer_common/sanitizer_platform.h"
#if SANITIZER_LINUX || SANITIZER_FREEBSD
#include "sanitizer_common/sanitizer_common.h"
#include "sanitizer_common/sanitizer_libc.h"
#include "sanitizer_common/sanitizer_posix.h"
#include "sanitizer_common/sanitizer_procmaps.h"
#include "sanitizer_common/sanitizer_stoptheworld.h"
#include "sanitizer_common/sanitizer_stackdepot.h"
#include "tsan_platform.h"
#include "tsan_rtl.h"
#include "tsan_flags.h"
#include <fcntl.h>
#include <pthread.h>
#include <signal.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <stdarg.h>
#include <sys/mman.h>
#include <sys/syscall.h>
#include <sys/socket.h>
#include <sys/time.h>
#include <sys/types.h>
#include <sys/resource.h>
#include <sys/stat.h>
#include <unistd.h>
#include <errno.h>
#include <sched.h>
#include <dlfcn.h>
#if SANITIZER_LINUX
#define __need_res_state
#include <resolv.h>
#endif
#ifdef sa_handler
# undef sa_handler
#endif
#ifdef sa_sigaction
# undef sa_sigaction
#endif
#if SANITIZER_FREEBSD
extern "C" void *__libc_stack_end;
void *__libc_stack_end = 0;
#endif
namespace __tsan {
static uptr g_data_start;
static uptr g_data_end;
enum {
MemTotal = 0,
MemShadow = 1,
MemMeta = 2,
MemFile = 3,
MemMmap = 4,
MemTrace = 5,
MemHeap = 6,
MemOther = 7,
MemCount = 8,
};
void FillProfileCallback(uptr p, uptr rss, bool file,
uptr *mem, uptr stats_size) {
mem[MemTotal] += rss;
if (p >= kShadowBeg && p < kShadowEnd)
mem[MemShadow] += rss;
else if (p >= kMetaShadowBeg && p < kMetaShadowEnd)
mem[MemMeta] += rss;
#ifndef SANITIZER_GO
else if (p >= kHeapMemBeg && p < kHeapMemEnd)
mem[MemHeap] += rss;
else if (p >= kLoAppMemBeg && p < kLoAppMemEnd)
mem[file ? MemFile : MemMmap] += rss;
else if (p >= kHiAppMemBeg && p < kHiAppMemEnd)
mem[file ? MemFile : MemMmap] += rss;
#else
else if (p >= kAppMemBeg && p < kAppMemEnd)
mem[file ? MemFile : MemMmap] += rss;
#endif
else if (p >= kTraceMemBeg && p < kTraceMemEnd)
mem[MemTrace] += rss;
else
mem[MemOther] += rss;
}
void WriteMemoryProfile(char *buf, uptr buf_size, uptr nthread, uptr nlive) {
uptr mem[MemCount] = {};
__sanitizer::GetMemoryProfile(FillProfileCallback, mem, 7);
StackDepotStats *stacks = StackDepotGetStats();
internal_snprintf(buf, buf_size,
"RSS %zd MB: shadow:%zd meta:%zd file:%zd mmap:%zd"
" trace:%zd heap:%zd other:%zd stacks=%zd[%zd] nthr=%zd/%zd\n",
mem[MemTotal] >> 20, mem[MemShadow] >> 20, mem[MemMeta] >> 20,
mem[MemFile] >> 20, mem[MemMmap] >> 20, mem[MemTrace] >> 20,
mem[MemHeap] >> 20, mem[MemOther] >> 20,
stacks->allocated >> 20, stacks->n_uniq_ids,
nlive, nthread);
}
#if SANITIZER_LINUX
void FlushShadowMemoryCallback(
const SuspendedThreadsList &suspended_threads_list,
void *argument) {
FlushUnneededShadowMemory(kShadowBeg, kShadowEnd - kShadowBeg);
}
#endif
void FlushShadowMemory() {
#if SANITIZER_LINUX
StopTheWorld(FlushShadowMemoryCallback, 0);
#endif
}
#ifndef SANITIZER_GO
static void ProtectRange(uptr beg, uptr end) {
CHECK_LE(beg, end);
if (beg == end)
return;
if (beg != (uptr)MmapNoAccess(beg, end - beg)) {
Printf("FATAL: ThreadSanitizer can not protect [%zx,%zx]\n", beg, end);
Printf("FATAL: Make sure you are not using unlimited stack\n");
Die();
}
}
// Mark shadow for .rodata sections with the special kShadowRodata marker.
// Accesses to .rodata can't race, so this saves time, memory and trace space.
static void MapRodata() {
// First create temp file.
const char *tmpdir = GetEnv("TMPDIR");
if (tmpdir == 0)
tmpdir = GetEnv("TEST_TMPDIR");
#ifdef P_tmpdir
if (tmpdir == 0)
tmpdir = P_tmpdir;
#endif
if (tmpdir == 0)
return;
char name[256];
internal_snprintf(name, sizeof(name), "%s/tsan.rodata.%d",
tmpdir, (int)internal_getpid());
uptr openrv = internal_open(name, O_RDWR | O_CREAT | O_EXCL, 0600);
if (internal_iserror(openrv))
return;
internal_unlink(name); // Unlink it now, so that we can reuse the buffer.
fd_t fd = openrv;
// Fill the file with kShadowRodata.
const uptr kMarkerSize = 512 * 1024 / sizeof(u64);
InternalScopedBuffer<u64> marker(kMarkerSize);
// volatile to prevent insertion of memset
for (volatile u64 *p = marker.data(); p < marker.data() + kMarkerSize; p++)
*p = kShadowRodata;
internal_write(fd, marker.data(), marker.size());
// Map the file into memory.
uptr page = internal_mmap(0, GetPageSizeCached(), PROT_READ | PROT_WRITE,
MAP_PRIVATE | MAP_ANONYMOUS, fd, 0);
if (internal_iserror(page)) {
internal_close(fd);
return;
}
// Map the file into shadow of .rodata sections.
MemoryMappingLayout proc_maps(/*cache_enabled*/true);
uptr start, end, offset, prot;
// Reusing the buffer 'name'.
while (proc_maps.Next(&start, &end, &offset, name, ARRAY_SIZE(name), &prot)) {
if (name[0] != 0 && name[0] != '['
&& (prot & MemoryMappingLayout::kProtectionRead)
&& (prot & MemoryMappingLayout::kProtectionExecute)
&& !(prot & MemoryMappingLayout::kProtectionWrite)
&& IsAppMem(start)) {
// Assume it's .rodata
char *shadow_start = (char*)MemToShadow(start);
char *shadow_end = (char*)MemToShadow(end);
for (char *p = shadow_start; p < shadow_end; p += marker.size()) {
internal_mmap(p, Min<uptr>(marker.size(), shadow_end - p),
PROT_READ, MAP_PRIVATE | MAP_FIXED, fd, 0);
}
}
}
internal_close(fd);
}
void InitializeShadowMemory() {
// Map memory shadow.
uptr shadow =
(uptr)MmapFixedNoReserve(kShadowBeg, kShadowEnd - kShadowBeg, "shadow");
if (shadow != kShadowBeg) {
Printf("FATAL: ThreadSanitizer can not mmap the shadow memory\n");
Printf("FATAL: Make sure to compile with -fPIE and "
"to link with -pie (%p, %p).\n", shadow, kShadowBeg);
Die();
}
// This memory range is used for thread stacks and large user mmaps.
// Frequently a thread uses only a small part of stack and similarly
// a program uses a small part of large mmap. On some programs
// we see 20% memory usage reduction without huge pages for this range.
// FIXME: don't use constants here.
#if defined(__x86_64__)
const uptr kMadviseRangeBeg = 0x7f0000000000ull;
const uptr kMadviseRangeSize = 0x010000000000ull;
#elif defined(__mips64)
const uptr kMadviseRangeBeg = 0xff00000000ull;
const uptr kMadviseRangeSize = 0x0100000000ull;
#elif defined(__aarch64__)
const uptr kMadviseRangeBeg = 0x7e00000000ull;
const uptr kMadviseRangeSize = 0x0100000000ull;
#endif
NoHugePagesInRegion(MemToShadow(kMadviseRangeBeg),
kMadviseRangeSize * kShadowMultiplier);
// Meta shadow is compressing and we don't flush it,
// so it makes sense to mark it as NOHUGEPAGE to not over-allocate memory.
// On one program it reduces memory consumption from 5GB to 2.5GB.
NoHugePagesInRegion(kMetaShadowBeg, kMetaShadowEnd - kMetaShadowBeg);
if (common_flags()->use_madv_dontdump)
DontDumpShadowMemory(kShadowBeg, kShadowEnd - kShadowBeg);
DPrintf("memory shadow: %zx-%zx (%zuGB)\n",
kShadowBeg, kShadowEnd,
(kShadowEnd - kShadowBeg) >> 30);
// Map meta shadow.
uptr meta_size = kMetaShadowEnd - kMetaShadowBeg;
uptr meta =
(uptr)MmapFixedNoReserve(kMetaShadowBeg, meta_size, "meta shadow");
if (meta != kMetaShadowBeg) {
Printf("FATAL: ThreadSanitizer can not mmap the shadow memory\n");
Printf("FATAL: Make sure to compile with -fPIE and "
"to link with -pie (%p, %p).\n", meta, kMetaShadowBeg);
Die();
}
if (common_flags()->use_madv_dontdump)
DontDumpShadowMemory(meta, meta_size);
DPrintf("meta shadow: %zx-%zx (%zuGB)\n",
meta, meta + meta_size, meta_size >> 30);
MapRodata();
}
static void InitDataSeg() {
MemoryMappingLayout proc_maps(true);
uptr start, end, offset;
char name[128];
#if SANITIZER_FREEBSD
// On FreeBSD BSS is usually the last block allocated within the
// low range and heap is the last block allocated within the range
// 0x800000000-0x8ffffffff.
while (proc_maps.Next(&start, &end, &offset, name, ARRAY_SIZE(name),
/*protection*/ 0)) {
DPrintf("%p-%p %p %s\n", start, end, offset, name);
if ((start & 0xffff00000000ULL) == 0 && (end & 0xffff00000000ULL) == 0 &&
name[0] == '\0') {
g_data_start = start;
g_data_end = end;
}
}
#else
bool prev_is_data = false;
while (proc_maps.Next(&start, &end, &offset, name, ARRAY_SIZE(name),
/*protection*/ 0)) {
DPrintf("%p-%p %p %s\n", start, end, offset, name);
bool is_data = offset != 0 && name[0] != 0;
// BSS may get merged with [heap] in /proc/self/maps. This is not very
// reliable.
bool is_bss = offset == 0 &&
(name[0] == 0 || internal_strcmp(name, "[heap]") == 0) && prev_is_data;
if (g_data_start == 0 && is_data)
g_data_start = start;
if (is_bss)
g_data_end = end;
prev_is_data = is_data;
}
#endif
DPrintf("guessed data_start=%p data_end=%p\n", g_data_start, g_data_end);
CHECK_LT(g_data_start, g_data_end);
CHECK_GE((uptr)&g_data_start, g_data_start);
CHECK_LT((uptr)&g_data_start, g_data_end);
}
static void CheckAndProtect() {
// Ensure that the binary is indeed compiled with -pie.
MemoryMappingLayout proc_maps(true);
uptr p, end;
while (proc_maps.Next(&p, &end, 0, 0, 0, 0)) {
if (IsAppMem(p))
continue;
if (p >= kHeapMemEnd &&
p < HeapEnd())
continue;
if (p >= kVdsoBeg) // vdso
break;
Printf("FATAL: ThreadSanitizer: unexpected memory mapping %p-%p\n", p, end);
Die();
}
ProtectRange(kLoAppMemEnd, kShadowBeg);
ProtectRange(kShadowEnd, kMetaShadowBeg);
ProtectRange(kMetaShadowEnd, kTraceMemBeg);
// Memory for traces is mapped lazily in MapThreadTrace.
// Protect the whole range for now, so that user does not map something here.
ProtectRange(kTraceMemBeg, kTraceMemEnd);
ProtectRange(kTraceMemEnd, kHeapMemBeg);
ProtectRange(HeapEnd(), kHiAppMemBeg);
}
#endif // #ifndef SANITIZER_GO
void InitializePlatform() {
DisableCoreDumperIfNecessary();
// Go maps shadow memory lazily and works fine with limited address space.
// Unlimited stack is not a problem as well, because the executable
// is not compiled with -pie.
if (kCppMode) {
bool reexec = false;
// TSan doesn't play well with unlimited stack size (as stack
// overlaps with shadow memory). If we detect unlimited stack size,
// we re-exec the program with limited stack size as a best effort.
if (StackSizeIsUnlimited()) {
const uptr kMaxStackSize = 32 * 1024 * 1024;
VReport(1, "Program is run with unlimited stack size, which wouldn't "
"work with ThreadSanitizer.\n"
"Re-execing with stack size limited to %zd bytes.\n",
kMaxStackSize);
SetStackSizeLimitInBytes(kMaxStackSize);
reexec = true;
}
if (!AddressSpaceIsUnlimited()) {
Report("WARNING: Program is run with limited virtual address space,"
" which wouldn't work with ThreadSanitizer.\n");
Report("Re-execing with unlimited virtual address space.\n");
SetAddressSpaceUnlimited();
reexec = true;
}
if (reexec)
ReExec();
}
#ifndef SANITIZER_GO
CheckAndProtect();
InitTlsSize();
InitDataSeg();
#endif
}
bool IsGlobalVar(uptr addr) {
return g_data_start && addr >= g_data_start && addr < g_data_end;
}
#ifndef SANITIZER_GO
// Extract file descriptors passed to glibc internal __res_iclose function.
// This is required to properly "close" the fds, because we do not see internal
// closes within glibc. The code is a pure hack.
int ExtractResolvFDs(void *state, int *fds, int nfd) {
#if SANITIZER_LINUX
int cnt = 0;
__res_state *statp = (__res_state*)state;
for (int i = 0; i < MAXNS && cnt < nfd; i++) {
if (statp->_u._ext.nsaddrs[i] && statp->_u._ext.nssocks[i] != -1)
fds[cnt++] = statp->_u._ext.nssocks[i];
}
return cnt;
#else
return 0;
#endif
}
// Extract file descriptors passed via UNIX domain sockets.
// This is requried to properly handle "open" of these fds.
// see 'man recvmsg' and 'man 3 cmsg'.
int ExtractRecvmsgFDs(void *msgp, int *fds, int nfd) {
int res = 0;
msghdr *msg = (msghdr*)msgp;
struct cmsghdr *cmsg = CMSG_FIRSTHDR(msg);
for (; cmsg; cmsg = CMSG_NXTHDR(msg, cmsg)) {
if (cmsg->cmsg_level != SOL_SOCKET || cmsg->cmsg_type != SCM_RIGHTS)
continue;
int n = (cmsg->cmsg_len - CMSG_LEN(0)) / sizeof(fds[0]);
for (int i = 0; i < n; i++) {
fds[res++] = ((int*)CMSG_DATA(cmsg))[i];
if (res == nfd)
return res;
}
}
return res;
}
// Note: this function runs with async signals enabled,
// so it must not touch any tsan state.
int call_pthread_cancel_with_cleanup(int(*fn)(void *c, void *m,
void *abstime), void *c, void *m, void *abstime,
void(*cleanup)(void *arg), void *arg) {
// pthread_cleanup_push/pop are hardcore macros mess.
// We can't intercept nor call them w/o including pthread.h.
int res;
pthread_cleanup_push(cleanup, arg);
res = fn(c, m, abstime);
pthread_cleanup_pop(0);
return res;
}
#endif
} // namespace __tsan
#endif // SANITIZER_LINUX || SANITIZER_FREEBSD