lib/tsan/rtl/tsan_fd.cc - platform/external/compiler-rt - Git at Google

 //===-- tsan_fd.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.
 //
 //===----------------------------------------------------------------------===//

 #include "tsan_fd.h"
 #include "tsan_rtl.h"
 #include <sanitizer_common/sanitizer_atomic.h>

 namespace __tsan {

 const int kTableSizeL1 = 1024;
 const int kTableSizeL2 = 1024;
 const int kTableSize = kTableSizeL1 * kTableSizeL2;

 struct FdSync {
   atomic_uint64_t rc;
 };

 struct FdDesc {
   FdSync *sync;
   int creation_tid;
   u32 creation_stack;
 };

 struct FdContext {
   atomic_uintptr_t tab[kTableSizeL1];
   // Addresses used for synchronization.
   FdSync globsync;
   FdSync filesync;
   FdSync socksync;
   u64 connectsync;
 };

 static FdContext fdctx;

 static FdSync *allocsync() {
   FdSync *s = (FdSync*)internal_alloc(MBlockFD, sizeof(FdSync));
   atomic_store(&s->rc, 1, memory_order_relaxed);
   return s;
 }

 static FdSync *ref(FdSync *s) {
   if (s && atomic_load(&s->rc, memory_order_relaxed) != (u64)-1)
     atomic_fetch_add(&s->rc, 1, memory_order_relaxed);
   return s;
 }

 static void unref(ThreadState *thr, uptr pc, FdSync *s) {
   if (s && atomic_load(&s->rc, memory_order_relaxed) != (u64)-1) {
     if (atomic_fetch_sub(&s->rc, 1, memory_order_acq_rel) == 1) {
       CHECK_NE(s, &fdctx.globsync);
       CHECK_NE(s, &fdctx.filesync);
       CHECK_NE(s, &fdctx.socksync);
       SyncVar *v = CTX()->synctab.GetAndRemove(thr, pc, (uptr)s);
       if (v)
         DestroyAndFree(v);
       internal_free(s);
     }
   }
 }

 static FdDesc *fddesc(ThreadState *thr, uptr pc, int fd) {
   CHECK_LT(fd, kTableSize);
   atomic_uintptr_t *pl1 = &fdctx.tab[fd / kTableSizeL2];
   uptr l1 = atomic_load(pl1, memory_order_consume);
   if (l1 == 0) {
     uptr size = kTableSizeL2 * sizeof(FdDesc);
     void *p = internal_alloc(MBlockFD, size);
     internal_memset(p, 0, size);
     MemoryResetRange(thr, (uptr)&fddesc, (uptr)p, size);
     if (atomic_compare_exchange_strong(pl1, &l1, (uptr)p, memory_order_acq_rel))
       l1 = (uptr)p;
     else
       internal_free(p);
   }
   return &((FdDesc*)l1)[fd % kTableSizeL2];  // NOLINT
 }

 // pd must be already ref'ed.
 static void init(ThreadState *thr, uptr pc, int fd, FdSync *s) {
   FdDesc *d = fddesc(thr, pc, fd);
   // As a matter of fact, we don't intercept all close calls.
   // See e.g. libc __res_iclose().
   if (d->sync) {
     unref(thr, pc, d->sync);
     d->sync = 0;
   }
   if (flags()->io_sync == 0) {
     unref(thr, pc, s);
   } else if (flags()->io_sync == 1) {
     d->sync = s;
   } else if (flags()->io_sync == 2) {
     unref(thr, pc, s);
     d->sync = &fdctx.globsync;
   }
   d->creation_tid = thr->tid;
   d->creation_stack = CurrentStackId(thr, pc);
   // To catch races between fd usage and open.
   MemoryRangeImitateWrite(thr, pc, (uptr)d, 8);
 }

 void FdInit() {
   atomic_store(&fdctx.globsync.rc, (u64)-1, memory_order_relaxed);
   atomic_store(&fdctx.filesync.rc, (u64)-1, memory_order_relaxed);
   atomic_store(&fdctx.socksync.rc, (u64)-1, memory_order_relaxed);
 }

 void FdOnFork(ThreadState *thr, uptr pc) {
   // On fork() we need to reset all fd's, because the child is going
   // close all them, and that will cause races between previous read/write
   // and the close.
   for (int l1 = 0; l1 < kTableSizeL1; l1++) {
     FdDesc *tab = (FdDesc*)atomic_load(&fdctx.tab[l1], memory_order_relaxed);
     if (tab == 0)
       break;
     for (int l2 = 0; l2 < kTableSizeL2; l2++) {
       FdDesc *d = &tab[l2];
       MemoryResetRange(thr, pc, (uptr)d, 8);
     }
   }
 }

 bool FdLocation(uptr addr, int *fd, int *tid, u32 *stack) {
   for (int l1 = 0; l1 < kTableSizeL1; l1++) {
     FdDesc *tab = (FdDesc*)atomic_load(&fdctx.tab[l1], memory_order_relaxed);
     if (tab == 0)
       break;
     if (addr >= (uptr)tab && addr < (uptr)(tab + kTableSizeL2)) {
       int l2 = (addr - (uptr)tab) / sizeof(FdDesc);
       FdDesc *d = &tab[l2];
       *fd = l1 * kTableSizeL1 + l2;
       *tid = d->creation_tid;
       *stack = d->creation_stack;
       return true;
     }
   }
   return false;
 }

 void FdAcquire(ThreadState *thr, uptr pc, int fd) {
   FdDesc *d = fddesc(thr, pc, fd);
   FdSync *s = d->sync;
   DPrintf("#%d: FdAcquire(%d) -> %p\n", thr->tid, fd, s);
   MemoryRead(thr, pc, (uptr)d, kSizeLog8);
   if (s)
     Acquire(thr, pc, (uptr)s);
 }

 void FdRelease(ThreadState *thr, uptr pc, int fd) {
   FdDesc *d = fddesc(thr, pc, fd);
   FdSync *s = d->sync;
   DPrintf("#%d: FdRelease(%d) -> %p\n", thr->tid, fd, s);
   if (s)
     Release(thr, pc, (uptr)s);
   MemoryRead(thr, pc, (uptr)d, kSizeLog8);
 }

 void FdAccess(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdAccess(%d)\n", thr->tid, fd);
   FdDesc *d = fddesc(thr, pc, fd);
   MemoryRead(thr, pc, (uptr)d, kSizeLog8);
 }

 void FdClose(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdClose(%d)\n", thr->tid, fd);
   FdDesc *d = fddesc(thr, pc, fd);
   // To catch races between fd usage and close.
   MemoryWrite(thr, pc, (uptr)d, kSizeLog8);
   // We need to clear it, because if we do not intercept any call out there
   // that creates fd, we will hit false postives.
   MemoryResetRange(thr, pc, (uptr)d, 8);
   unref(thr, pc, d->sync);
   d->sync = 0;
   d->creation_tid = 0;
   d->creation_stack = 0;
 }

 void FdFileCreate(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdFileCreate(%d)\n", thr->tid, fd);
   init(thr, pc, fd, &fdctx.filesync);
 }

 void FdDup(ThreadState *thr, uptr pc, int oldfd, int newfd) {
   DPrintf("#%d: FdDup(%d, %d)\n", thr->tid, oldfd, newfd);
   // Ignore the case when user dups not yet connected socket.
   FdDesc *od = fddesc(thr, pc, oldfd);
   MemoryRead(thr, pc, (uptr)od, kSizeLog8);
   FdClose(thr, pc, newfd);
   init(thr, pc, newfd, ref(od->sync));
 }

 void FdPipeCreate(ThreadState *thr, uptr pc, int rfd, int wfd) {
   DPrintf("#%d: FdCreatePipe(%d, %d)\n", thr->tid, rfd, wfd);
   FdSync *s = allocsync();
   init(thr, pc, rfd, ref(s));
   init(thr, pc, wfd, ref(s));
   unref(thr, pc, s);
 }

 void FdEventCreate(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdEventCreate(%d)\n", thr->tid, fd);
   init(thr, pc, fd, allocsync());
 }

 void FdSignalCreate(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdSignalCreate(%d)\n", thr->tid, fd);
   init(thr, pc, fd, 0);
 }

 void FdInotifyCreate(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdInotifyCreate(%d)\n", thr->tid, fd);
   init(thr, pc, fd, 0);
 }

 void FdPollCreate(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdPollCreate(%d)\n", thr->tid, fd);
   init(thr, pc, fd, allocsync());
 }

 void FdSocketCreate(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdSocketCreate(%d)\n", thr->tid, fd);
   // It can be a UDP socket.
   init(thr, pc, fd, &fdctx.socksync);
 }

 void FdSocketAccept(ThreadState *thr, uptr pc, int fd, int newfd) {
   DPrintf("#%d: FdSocketAccept(%d, %d)\n", thr->tid, fd, newfd);
   // Synchronize connect->accept.
   Acquire(thr, pc, (uptr)&fdctx.connectsync);
   init(thr, pc, newfd, &fdctx.socksync);
 }

 void FdSocketConnecting(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdSocketConnecting(%d)\n", thr->tid, fd);
   // Synchronize connect->accept.
   Release(thr, pc, (uptr)&fdctx.connectsync);
 }

 void FdSocketConnect(ThreadState *thr, uptr pc, int fd) {
   DPrintf("#%d: FdSocketConnect(%d)\n", thr->tid, fd);
   init(thr, pc, fd, &fdctx.socksync);
 }

 uptr File2addr(char *path) {
   (void)path;
   static u64 addr;
   return (uptr)&addr;
 }

 uptr Dir2addr(char *path) {
   (void)path;
   static u64 addr;
   return (uptr)&addr;
 }

 }  //  namespace __tsan
	//===-- tsan_fd.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.
	//
	//===----------------------------------------------------------------------===//

	#include "tsan_fd.h"
	#include "tsan_rtl.h"
	#include <sanitizer_common/sanitizer_atomic.h>

	namespace __tsan {

	const int kTableSizeL1 = 1024;
	const int kTableSizeL2 = 1024;
	const int kTableSize = kTableSizeL1 * kTableSizeL2;

	struct FdSync {
	atomic_uint64_t rc;
	};

	struct FdDesc {
	FdSync *sync;
	int creation_tid;
	u32 creation_stack;
	};

	struct FdContext {
	atomic_uintptr_t tab[kTableSizeL1];
	// Addresses used for synchronization.
	FdSync globsync;
	FdSync filesync;
	FdSync socksync;
	u64 connectsync;
	};

	static FdContext fdctx;

	static FdSync *allocsync() {
	FdSync s = (FdSync)internal_alloc(MBlockFD, sizeof(FdSync));
	atomic_store(&s->rc, 1, memory_order_relaxed);
	return s;
	}

	static FdSync ref(FdSync s) {
	if (s && atomic_load(&s->rc, memory_order_relaxed) != (u64)-1)
	atomic_fetch_add(&s->rc, 1, memory_order_relaxed);
	return s;
	}

	static void unref(ThreadState thr, uptr pc, FdSync s) {
	if (s && atomic_load(&s->rc, memory_order_relaxed) != (u64)-1) {
	if (atomic_fetch_sub(&s->rc, 1, memory_order_acq_rel) == 1) {
	CHECK_NE(s, &fdctx.globsync);
	CHECK_NE(s, &fdctx.filesync);
	CHECK_NE(s, &fdctx.socksync);
	SyncVar *v = CTX()->synctab.GetAndRemove(thr, pc, (uptr)s);
	if (v)
	DestroyAndFree(v);
	internal_free(s);
	}
	}
	}

	static FdDesc fddesc(ThreadState thr, uptr pc, int fd) {
	CHECK_LT(fd, kTableSize);
	atomic_uintptr_t *pl1 = &fdctx.tab[fd / kTableSizeL2];
	uptr l1 = atomic_load(pl1, memory_order_consume);
	if (l1 == 0) {
	uptr size = kTableSizeL2 * sizeof(FdDesc);
	void *p = internal_alloc(MBlockFD, size);
	internal_memset(p, 0, size);
	MemoryResetRange(thr, (uptr)&fddesc, (uptr)p, size);
	if (atomic_compare_exchange_strong(pl1, &l1, (uptr)p, memory_order_acq_rel))
	l1 = (uptr)p;
	else
	internal_free(p);
	}
	return &((FdDesc*)l1)[fd % kTableSizeL2]; // NOLINT
	}

	// pd must be already ref'ed.
	static void init(ThreadState thr, uptr pc, int fd, FdSync s) {
	FdDesc *d = fddesc(thr, pc, fd);
	// As a matter of fact, we don't intercept all close calls.
	// See e.g. libc __res_iclose().
	if (d->sync) {
	unref(thr, pc, d->sync);
	d->sync = 0;
	}
	if (flags()->io_sync == 0) {
	unref(thr, pc, s);
	} else if (flags()->io_sync == 1) {
	d->sync = s;
	} else if (flags()->io_sync == 2) {
	unref(thr, pc, s);
	d->sync = &fdctx.globsync;
	}
	d->creation_tid = thr->tid;
	d->creation_stack = CurrentStackId(thr, pc);
	// To catch races between fd usage and open.
	MemoryRangeImitateWrite(thr, pc, (uptr)d, 8);
	}

	void FdInit() {
	atomic_store(&fdctx.globsync.rc, (u64)-1, memory_order_relaxed);
	atomic_store(&fdctx.filesync.rc, (u64)-1, memory_order_relaxed);
	atomic_store(&fdctx.socksync.rc, (u64)-1, memory_order_relaxed);
	}

	void FdOnFork(ThreadState *thr, uptr pc) {
	// On fork() we need to reset all fd's, because the child is going
	// close all them, and that will cause races between previous read/write
	// and the close.
	for (int l1 = 0; l1 < kTableSizeL1; l1++) {
	FdDesc tab = (FdDesc)atomic_load(&fdctx.tab[l1], memory_order_relaxed);
	if (tab == 0)
	break;
	for (int l2 = 0; l2 < kTableSizeL2; l2++) {
	FdDesc *d = &tab[l2];
	MemoryResetRange(thr, pc, (uptr)d, 8);
	}
	}
	}

	bool FdLocation(uptr addr, int fd, int tid, u32 *stack) {
	for (int l1 = 0; l1 < kTableSizeL1; l1++) {
	FdDesc tab = (FdDesc)atomic_load(&fdctx.tab[l1], memory_order_relaxed);
	if (tab == 0)
	break;
	if (addr >= (uptr)tab && addr < (uptr)(tab + kTableSizeL2)) {
	int l2 = (addr - (uptr)tab) / sizeof(FdDesc);
	FdDesc *d = &tab[l2];
	fd = l1 kTableSizeL1 + l2;
	*tid = d->creation_tid;
	*stack = d->creation_stack;
	return true;
	}
	}
	return false;
	}

	void FdAcquire(ThreadState *thr, uptr pc, int fd) {
	FdDesc *d = fddesc(thr, pc, fd);
	FdSync *s = d->sync;
	DPrintf("#%d: FdAcquire(%d) -> %p\n", thr->tid, fd, s);
	MemoryRead(thr, pc, (uptr)d, kSizeLog8);
	if (s)
	Acquire(thr, pc, (uptr)s);
	}

	void FdRelease(ThreadState *thr, uptr pc, int fd) {
	FdDesc *d = fddesc(thr, pc, fd);
	FdSync *s = d->sync;
	DPrintf("#%d: FdRelease(%d) -> %p\n", thr->tid, fd, s);
	if (s)
	Release(thr, pc, (uptr)s);
	MemoryRead(thr, pc, (uptr)d, kSizeLog8);
	}

	void FdAccess(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdAccess(%d)\n", thr->tid, fd);
	FdDesc *d = fddesc(thr, pc, fd);
	MemoryRead(thr, pc, (uptr)d, kSizeLog8);
	}

	void FdClose(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdClose(%d)\n", thr->tid, fd);
	FdDesc *d = fddesc(thr, pc, fd);
	// To catch races between fd usage and close.
	MemoryWrite(thr, pc, (uptr)d, kSizeLog8);
	// We need to clear it, because if we do not intercept any call out there
	// that creates fd, we will hit false postives.
	MemoryResetRange(thr, pc, (uptr)d, 8);
	unref(thr, pc, d->sync);
	d->sync = 0;
	d->creation_tid = 0;
	d->creation_stack = 0;
	}

	void FdFileCreate(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdFileCreate(%d)\n", thr->tid, fd);
	init(thr, pc, fd, &fdctx.filesync);
	}

	void FdDup(ThreadState *thr, uptr pc, int oldfd, int newfd) {
	DPrintf("#%d: FdDup(%d, %d)\n", thr->tid, oldfd, newfd);
	// Ignore the case when user dups not yet connected socket.
	FdDesc *od = fddesc(thr, pc, oldfd);
	MemoryRead(thr, pc, (uptr)od, kSizeLog8);
	FdClose(thr, pc, newfd);
	init(thr, pc, newfd, ref(od->sync));
	}

	void FdPipeCreate(ThreadState *thr, uptr pc, int rfd, int wfd) {
	DPrintf("#%d: FdCreatePipe(%d, %d)\n", thr->tid, rfd, wfd);
	FdSync *s = allocsync();
	init(thr, pc, rfd, ref(s));
	init(thr, pc, wfd, ref(s));
	unref(thr, pc, s);
	}

	void FdEventCreate(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdEventCreate(%d)\n", thr->tid, fd);
	init(thr, pc, fd, allocsync());
	}

	void FdSignalCreate(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdSignalCreate(%d)\n", thr->tid, fd);
	init(thr, pc, fd, 0);
	}

	void FdInotifyCreate(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdInotifyCreate(%d)\n", thr->tid, fd);
	init(thr, pc, fd, 0);
	}

	void FdPollCreate(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdPollCreate(%d)\n", thr->tid, fd);
	init(thr, pc, fd, allocsync());
	}

	void FdSocketCreate(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdSocketCreate(%d)\n", thr->tid, fd);
	// It can be a UDP socket.
	init(thr, pc, fd, &fdctx.socksync);
	}

	void FdSocketAccept(ThreadState *thr, uptr pc, int fd, int newfd) {
	DPrintf("#%d: FdSocketAccept(%d, %d)\n", thr->tid, fd, newfd);
	// Synchronize connect->accept.
	Acquire(thr, pc, (uptr)&fdctx.connectsync);
	init(thr, pc, newfd, &fdctx.socksync);
	}

	void FdSocketConnecting(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdSocketConnecting(%d)\n", thr->tid, fd);
	// Synchronize connect->accept.
	Release(thr, pc, (uptr)&fdctx.connectsync);
	}

	void FdSocketConnect(ThreadState *thr, uptr pc, int fd) {
	DPrintf("#%d: FdSocketConnect(%d)\n", thr->tid, fd);
	init(thr, pc, fd, &fdctx.socksync);
	}

	uptr File2addr(char *path) {
	(void)path;
	static u64 addr;
	return (uptr)&addr;
	}

	uptr Dir2addr(char *path) {
	(void)path;
	static u64 addr;
	return (uptr)&addr;
	}

	} // namespace __tsan