compiler-rt/lib/sanitizer_common/sanitizer_mutex.cpp - llvm-project - Git at Google

 //===-- sanitizer_mutex.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 shared between AddressSanitizer and ThreadSanitizer
 // run-time libraries.
 //===----------------------------------------------------------------------===//

 #include "sanitizer_mutex.h"

 #include "sanitizer_common.h"

 namespace __sanitizer {

 void StaticSpinMutex::LockSlow() {
   for (int i = 0;; i++) {
     if (i < 100)
       proc_yield(1);
     else
       internal_sched_yield();
     if (atomic_load(&state_, memory_order_relaxed) == 0 &&
         atomic_exchange(&state_, 1, memory_order_acquire) == 0)
       return;
   }
 }

 void Semaphore::Wait() {
   u32 count = atomic_load(&state_, memory_order_relaxed);
   for (;;) {
     if (count == 0) {
       FutexWait(&state_, 0);
       count = atomic_load(&state_, memory_order_relaxed);
       continue;
     }
     if (atomic_compare_exchange_weak(&state_, &count, count - 1,
                                      memory_order_acquire))
       break;
   }
 }

 void Semaphore::Post(u32 count) {
   CHECK_NE(count, 0);
   atomic_fetch_add(&state_, count, memory_order_release);
   FutexWake(&state_, count);
 }

 #if SANITIZER_CHECK_DEADLOCKS
 // An empty mutex meta table, it effectively disables deadlock detection.
 // Each tool can override the table to define own mutex hierarchy and
 // enable deadlock detection.
 // The table defines a static mutex type hierarchy (what mutex types can be locked
 // under what mutex types). This table is checked to be acyclic and then
 // actual mutex lock/unlock operations are checked to adhere to this hierarchy.
 // The checking happens on mutex types rather than on individual mutex instances
 // because doing it on mutex instances will both significantly complicate
 // the implementation, worsen performance and memory overhead and is mostly
 // unnecessary (we almost never lock multiple mutexes of the same type recursively).
 static constexpr int kMutexTypeMax = 20;
 SANITIZER_WEAK_ATTRIBUTE MutexMeta mutex_meta[kMutexTypeMax] = {};
 SANITIZER_WEAK_ATTRIBUTE void PrintMutexPC(uptr pc) {}
 static StaticSpinMutex mutex_meta_mtx;
 static int mutex_type_count = -1;
 // Adjacency matrix of what mutexes can be locked under what mutexes.
 static bool mutex_can_lock[kMutexTypeMax][kMutexTypeMax];
 // Mutex types with MutexMulti mark.
 static bool mutex_multi[kMutexTypeMax];

 void DebugMutexInit() {
   // Build adjacency matrix.
   bool leaf[kMutexTypeMax];
   internal_memset(&leaf, 0, sizeof(leaf));
   int cnt[kMutexTypeMax];
   internal_memset(&cnt, 0, sizeof(cnt));
   for (int t = 0; t < kMutexTypeMax; t++) {
     mutex_type_count = t;
     if (!mutex_meta[t].name)
       break;
     CHECK_EQ(t, mutex_meta[t].type);
     for (uptr j = 0; j < ARRAY_SIZE(mutex_meta[t].can_lock); j++) {
       MutexType z = mutex_meta[t].can_lock[j];
       if (z == MutexInvalid)
         break;
       if (z == MutexLeaf) {
         CHECK(!leaf[t]);
         leaf[t] = true;
         continue;
       }
       if (z == MutexMulti) {
         mutex_multi[t] = true;
         continue;
       }
       CHECK_LT(z, kMutexTypeMax);
       CHECK(!mutex_can_lock[t][z]);
       mutex_can_lock[t][z] = true;
       cnt[t]++;
     }
   }
   // Indicates the array is not properly terminated.
   CHECK_LT(mutex_type_count, kMutexTypeMax);
   // Add leaf mutexes.
   for (int t = 0; t < mutex_type_count; t++) {
     if (!leaf[t])
       continue;
     CHECK_EQ(cnt[t], 0);
     for (int z = 0; z < mutex_type_count; z++) {
       if (z == MutexInvalid || t == z || leaf[z])
         continue;
       CHECK(!mutex_can_lock[z][t]);
       mutex_can_lock[z][t] = true;
     }
   }
   // Build the transitive closure and check that the graphs is acyclic.
   u32 trans[kMutexTypeMax];
   static_assert(sizeof(trans[0]) * 8 >= kMutexTypeMax,
                 "kMutexTypeMax does not fit into u32, switch to u64");
   internal_memset(&trans, 0, sizeof(trans));
   for (int i = 0; i < mutex_type_count; i++) {
     for (int j = 0; j < mutex_type_count; j++)
       if (mutex_can_lock[i][j])
         trans[i] |= 1 << j;
   }
   for (int k = 0; k < mutex_type_count; k++) {
     for (int i = 0; i < mutex_type_count; i++) {
       if (trans[i] & (1 << k))
         trans[i] |= trans[k];
     }
   }
   for (int i = 0; i < mutex_type_count; i++) {
     if (trans[i] & (1 << i)) {
       Printf("Mutex %s participates in a cycle\n", mutex_meta[i].name);
       Die();
     }
   }
 }

 struct InternalDeadlockDetector {
   struct LockDesc {
     u64 seq;
     uptr pc;
     int recursion;
   };
   int initialized;
   u64 sequence;
   LockDesc locked[kMutexTypeMax];

   void Lock(MutexType type, uptr pc) {
     if (!Initialize(type))
       return;
     CHECK_LT(type, mutex_type_count);
     // Find the last locked mutex type.
     // This is the type we will use for hierarchy checks.
     u64 max_seq = 0;
     MutexType max_idx = MutexInvalid;
     for (int i = 0; i != mutex_type_count; i++) {
       if (locked[i].seq == 0)
         continue;
       CHECK_NE(locked[i].seq, max_seq);
       if (max_seq < locked[i].seq) {
         max_seq = locked[i].seq;
         max_idx = (MutexType)i;
       }
     }
     if (max_idx == type && mutex_multi[type]) {
       // Recursive lock of the same type.
       CHECK_EQ(locked[type].seq, max_seq);
       CHECK(locked[type].pc);
       locked[type].recursion++;
       return;
     }
     if (max_idx != MutexInvalid && !mutex_can_lock[max_idx][type]) {
       Printf("%s: internal deadlock: can't lock %s under %s mutex\n", SanitizerToolName,
              mutex_meta[type].name, mutex_meta[max_idx].name);
       PrintMutexPC(locked[max_idx].pc);
       CHECK(0);
     }
     locked[type].seq = ++sequence;
     locked[type].pc = pc;
     locked[type].recursion = 1;
   }

   void Unlock(MutexType type) {
     if (!Initialize(type))
       return;
     CHECK_LT(type, mutex_type_count);
     CHECK(locked[type].seq);
     CHECK_GT(locked[type].recursion, 0);
     if (--locked[type].recursion)
       return;
     locked[type].seq = 0;
     locked[type].pc = 0;
   }

   void CheckNoLocks() {
     for (int i = 0; i < mutex_type_count; i++) CHECK_EQ(locked[i].recursion, 0);
   }

   bool Initialize(MutexType type) {
     if (type == MutexUnchecked || type == MutexInvalid)
       return false;
     CHECK_GT(type, MutexInvalid);
     if (initialized != 0)
       return initialized > 0;
     initialized = -1;
     SpinMutexLock lock(&mutex_meta_mtx);
     if (mutex_type_count < 0)
       DebugMutexInit();
     initialized = mutex_type_count ? 1 : -1;
     return initialized > 0;
   }
 };

 static THREADLOCAL InternalDeadlockDetector deadlock_detector;

 void CheckedMutex::LockImpl(uptr pc) { deadlock_detector.Lock(type_, pc); }

 void CheckedMutex::UnlockImpl() { deadlock_detector.Unlock(type_); }

 void CheckedMutex::CheckNoLocksImpl() { deadlock_detector.CheckNoLocks(); }
 #endif

 }  // namespace __sanitizer
	//===-- sanitizer_mutex.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 shared between AddressSanitizer and ThreadSanitizer
	// run-time libraries.
	//===----------------------------------------------------------------------===//

	#include "sanitizer_mutex.h"

	#include "sanitizer_common.h"

	namespace __sanitizer {

	void StaticSpinMutex::LockSlow() {
	for (int i = 0;; i++) {
	if (i < 100)
	proc_yield(1);
	else
	internal_sched_yield();
	if (atomic_load(&state_, memory_order_relaxed) == 0 &&
	atomic_exchange(&state_, 1, memory_order_acquire) == 0)
	return;
	}
	}

	void Semaphore::Wait() {
	u32 count = atomic_load(&state_, memory_order_relaxed);
	for (;;) {
	if (count == 0) {
	FutexWait(&state_, 0);
	count = atomic_load(&state_, memory_order_relaxed);
	continue;
	}
	if (atomic_compare_exchange_weak(&state_, &count, count - 1,
	memory_order_acquire))
	break;
	}
	}

	void Semaphore::Post(u32 count) {
	CHECK_NE(count, 0);
	atomic_fetch_add(&state_, count, memory_order_release);
	FutexWake(&state_, count);
	}

	#if SANITIZER_CHECK_DEADLOCKS
	// An empty mutex meta table, it effectively disables deadlock detection.
	// Each tool can override the table to define own mutex hierarchy and
	// enable deadlock detection.
	// The table defines a static mutex type hierarchy (what mutex types can be locked
	// under what mutex types). This table is checked to be acyclic and then
	// actual mutex lock/unlock operations are checked to adhere to this hierarchy.
	// The checking happens on mutex types rather than on individual mutex instances
	// because doing it on mutex instances will both significantly complicate
	// the implementation, worsen performance and memory overhead and is mostly
	// unnecessary (we almost never lock multiple mutexes of the same type recursively).
	static constexpr int kMutexTypeMax = 20;
	SANITIZER_WEAK_ATTRIBUTE MutexMeta mutex_meta[kMutexTypeMax] = {};
	SANITIZER_WEAK_ATTRIBUTE void PrintMutexPC(uptr pc) {}
	static StaticSpinMutex mutex_meta_mtx;
	static int mutex_type_count = -1;
	// Adjacency matrix of what mutexes can be locked under what mutexes.
	static bool mutex_can_lock[kMutexTypeMax][kMutexTypeMax];
	// Mutex types with MutexMulti mark.
	static bool mutex_multi[kMutexTypeMax];

	void DebugMutexInit() {
	// Build adjacency matrix.
	bool leaf[kMutexTypeMax];
	internal_memset(&leaf, 0, sizeof(leaf));
	int cnt[kMutexTypeMax];
	internal_memset(&cnt, 0, sizeof(cnt));
	for (int t = 0; t < kMutexTypeMax; t++) {
	mutex_type_count = t;
	if (!mutex_meta[t].name)
	break;
	CHECK_EQ(t, mutex_meta[t].type);
	for (uptr j = 0; j < ARRAY_SIZE(mutex_meta[t].can_lock); j++) {
	MutexType z = mutex_meta[t].can_lock[j];
	if (z == MutexInvalid)
	break;
	if (z == MutexLeaf) {
	CHECK(!leaf[t]);
	leaf[t] = true;
	continue;
	}
	if (z == MutexMulti) {
	mutex_multi[t] = true;
	continue;
	}
	CHECK_LT(z, kMutexTypeMax);
	CHECK(!mutex_can_lock[t][z]);
	mutex_can_lock[t][z] = true;
	cnt[t]++;
	}
	}
	// Indicates the array is not properly terminated.
	CHECK_LT(mutex_type_count, kMutexTypeMax);
	// Add leaf mutexes.
	for (int t = 0; t < mutex_type_count; t++) {
	if (!leaf[t])
	continue;
	CHECK_EQ(cnt[t], 0);
	for (int z = 0; z < mutex_type_count; z++) {
	if (z == MutexInvalid \|\| t == z \|\| leaf[z])
	continue;
	CHECK(!mutex_can_lock[z][t]);
	mutex_can_lock[z][t] = true;
	}
	}
	// Build the transitive closure and check that the graphs is acyclic.
	u32 trans[kMutexTypeMax];
	static_assert(sizeof(trans[0]) * 8 >= kMutexTypeMax,
	"kMutexTypeMax does not fit into u32, switch to u64");
	internal_memset(&trans, 0, sizeof(trans));
	for (int i = 0; i < mutex_type_count; i++) {
	for (int j = 0; j < mutex_type_count; j++)
	if (mutex_can_lock[i][j])
	trans[i] \|= 1 << j;
	}
	for (int k = 0; k < mutex_type_count; k++) {
	for (int i = 0; i < mutex_type_count; i++) {
	if (trans[i] & (1 << k))
	trans[i] \|= trans[k];
	}
	}
	for (int i = 0; i < mutex_type_count; i++) {
	if (trans[i] & (1 << i)) {
	Printf("Mutex %s participates in a cycle\n", mutex_meta[i].name);
	Die();
	}
	}
	}

	struct InternalDeadlockDetector {
	struct LockDesc {
	u64 seq;
	uptr pc;
	int recursion;
	};
	int initialized;
	u64 sequence;
	LockDesc locked[kMutexTypeMax];

	void Lock(MutexType type, uptr pc) {
	if (!Initialize(type))
	return;
	CHECK_LT(type, mutex_type_count);
	// Find the last locked mutex type.
	// This is the type we will use for hierarchy checks.
	u64 max_seq = 0;
	MutexType max_idx = MutexInvalid;
	for (int i = 0; i != mutex_type_count; i++) {
	if (locked[i].seq == 0)
	continue;
	CHECK_NE(locked[i].seq, max_seq);
	if (max_seq < locked[i].seq) {
	max_seq = locked[i].seq;
	max_idx = (MutexType)i;
	}
	}
	if (max_idx == type && mutex_multi[type]) {
	// Recursive lock of the same type.
	CHECK_EQ(locked[type].seq, max_seq);
	CHECK(locked[type].pc);
	locked[type].recursion++;
	return;
	}
	if (max_idx != MutexInvalid && !mutex_can_lock[max_idx][type]) {
	Printf("%s: internal deadlock: can't lock %s under %s mutex\n", SanitizerToolName,
	mutex_meta[type].name, mutex_meta[max_idx].name);
	PrintMutexPC(locked[max_idx].pc);
	CHECK(0);
	}
	locked[type].seq = ++sequence;
	locked[type].pc = pc;
	locked[type].recursion = 1;
	}

	void Unlock(MutexType type) {
	if (!Initialize(type))
	return;
	CHECK_LT(type, mutex_type_count);
	CHECK(locked[type].seq);
	CHECK_GT(locked[type].recursion, 0);
	if (--locked[type].recursion)
	return;
	locked[type].seq = 0;
	locked[type].pc = 0;
	}

	void CheckNoLocks() {
	for (int i = 0; i < mutex_type_count; i++) CHECK_EQ(locked[i].recursion, 0);
	}

	bool Initialize(MutexType type) {
	if (type == MutexUnchecked \|\| type == MutexInvalid)
	return false;
	CHECK_GT(type, MutexInvalid);
	if (initialized != 0)
	return initialized > 0;
	initialized = -1;
	SpinMutexLock lock(&mutex_meta_mtx);
	if (mutex_type_count < 0)
	DebugMutexInit();
	initialized = mutex_type_count ? 1 : -1;
	return initialized > 0;
	}
	};

	static THREADLOCAL InternalDeadlockDetector deadlock_detector;

	void CheckedMutex::LockImpl(uptr pc) { deadlock_detector.Lock(type_, pc); }

	void CheckedMutex::UnlockImpl() { deadlock_detector.Unlock(type_); }

	void CheckedMutex::CheckNoLocksImpl() { deadlock_detector.CheckNoLocks(); }
	#endif

	} // namespace __sanitizer