libsanitizer/tsan/tsan_clock.cpp - gcc - Git at Google

 //===-- tsan_clock.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_clock.h"
 #include "tsan_rtl.h"
 #include "sanitizer_common/sanitizer_placement_new.h"

 // SyncClock and ThreadClock implement vector clocks for sync variables
 // (mutexes, atomic variables, file descriptors, etc) and threads, respectively.
 // ThreadClock contains fixed-size vector clock for maximum number of threads.
 // SyncClock contains growable vector clock for currently necessary number of
 // threads.
 // Together they implement very simple model of operations, namely:
 //
 //   void ThreadClock::acquire(const SyncClock *src) {
 //     for (int i = 0; i < kMaxThreads; i++)
 //       clock[i] = max(clock[i], src->clock[i]);
 //   }
 //
 //   void ThreadClock::release(SyncClock *dst) const {
 //     for (int i = 0; i < kMaxThreads; i++)
 //       dst->clock[i] = max(dst->clock[i], clock[i]);
 //   }
 //
 //   void ThreadClock::releaseStoreAcquire(SyncClock *sc) const {
 //     for (int i = 0; i < kMaxThreads; i++) {
 //       tmp = clock[i];
 //       clock[i] = max(clock[i], sc->clock[i]);
 //       sc->clock[i] = tmp;
 //     }
 //   }
 //
 //   void ThreadClock::ReleaseStore(SyncClock *dst) const {
 //     for (int i = 0; i < kMaxThreads; i++)
 //       dst->clock[i] = clock[i];
 //   }
 //
 //   void ThreadClock::acq_rel(SyncClock *dst) {
 //     acquire(dst);
 //     release(dst);
 //   }
 //
 // Conformance to this model is extensively verified in tsan_clock_test.cpp.
 // However, the implementation is significantly more complex. The complexity
 // allows to implement important classes of use cases in O(1) instead of O(N).
 //
 // The use cases are:
 // 1. Singleton/once atomic that has a single release-store operation followed
 //    by zillions of acquire-loads (the acquire-load is O(1)).
 // 2. Thread-local mutex (both lock and unlock can be O(1)).
 // 3. Leaf mutex (unlock is O(1)).
 // 4. A mutex shared by 2 threads (both lock and unlock can be O(1)).
 // 5. An atomic with a single writer (writes can be O(1)).
 // The implementation dynamically adopts to workload. So if an atomic is in
 // read-only phase, these reads will be O(1); if it later switches to read/write
 // phase, the implementation will correctly handle that by switching to O(N).
 //
 // Thread-safety note: all const operations on SyncClock's are conducted under
 // a shared lock; all non-const operations on SyncClock's are conducted under
 // an exclusive lock; ThreadClock's are private to respective threads and so
 // do not need any protection.
 //
 // Description of SyncClock state:
 // clk_ - variable size vector clock, low kClkBits hold timestamp,
 //   the remaining bits hold "acquired" flag (the actual value is thread's
 //   reused counter);
 //   if acquired == thr->reused_, then the respective thread has already
 //   acquired this clock (except possibly for dirty elements).
 // dirty_ - holds up to two indices in the vector clock that other threads
 //   need to acquire regardless of "acquired" flag value;
 // release_store_tid_ - denotes that the clock state is a result of
 //   release-store operation by the thread with release_store_tid_ index.
 // release_store_reused_ - reuse count of release_store_tid_.

 namespace __tsan {

 static atomic_uint32_t *ref_ptr(ClockBlock *cb) {
   return reinterpret_cast<atomic_uint32_t *>(&cb->table[ClockBlock::kRefIdx]);
 }

 // Drop reference to the first level block idx.
 static void UnrefClockBlock(ClockCache *c, u32 idx, uptr blocks) {
   ClockBlock *cb = ctx->clock_alloc.Map(idx);
   atomic_uint32_t *ref = ref_ptr(cb);
   u32 v = atomic_load(ref, memory_order_acquire);
   for (;;) {
     CHECK_GT(v, 0);
     if (v == 1)
       break;
     if (atomic_compare_exchange_strong(ref, &v, v - 1, memory_order_acq_rel))
       return;
   }
   // First level block owns second level blocks, so them as well.
   for (uptr i = 0; i < blocks; i++)
     ctx->clock_alloc.Free(c, cb->table[ClockBlock::kBlockIdx - i]);
   ctx->clock_alloc.Free(c, idx);
 }

 ThreadClock::ThreadClock(unsigned tid, unsigned reused)
     : tid_(tid)
     , reused_(reused + 1)  // 0 has special meaning
     , last_acquire_()
     , global_acquire_()
     , cached_idx_()
     , cached_size_()
     , cached_blocks_() {
   CHECK_LT(tid, kMaxTidInClock);
   CHECK_EQ(reused_, ((u64)reused_ << kClkBits) >> kClkBits);
   nclk_ = tid_ + 1;
   internal_memset(clk_, 0, sizeof(clk_));
 }

 void ThreadClock::ResetCached(ClockCache *c) {
   if (cached_idx_) {
     UnrefClockBlock(c, cached_idx_, cached_blocks_);
     cached_idx_ = 0;
     cached_size_ = 0;
     cached_blocks_ = 0;
   }
 }

 void ThreadClock::acquire(ClockCache *c, SyncClock *src) {
   DCHECK_LE(nclk_, kMaxTid);
   DCHECK_LE(src->size_, kMaxTid);

   // Check if it's empty -> no need to do anything.
   const uptr nclk = src->size_;
   if (nclk == 0)
     return;

   bool acquired = false;
   for (unsigned i = 0; i < kDirtyTids; i++) {
     SyncClock::Dirty dirty = src->dirty_[i];
     unsigned tid = dirty.tid();
     if (tid != kInvalidTid) {
       if (clk_[tid] < dirty.epoch) {
         clk_[tid] = dirty.epoch;
         acquired = true;
       }
     }
   }

   // Check if we've already acquired src after the last release operation on src
   if (tid_ >= nclk || src->elem(tid_).reused != reused_) {
     // O(N) acquire.
     nclk_ = max(nclk_, nclk);
     u64 *dst_pos = &clk_[0];
     for (ClockElem &src_elem : *src) {
       u64 epoch = src_elem.epoch;
       if (*dst_pos < epoch) {
         *dst_pos = epoch;
         acquired = true;
       }
       dst_pos++;
     }

     // Remember that this thread has acquired this clock.
     if (nclk > tid_)
       src->elem(tid_).reused = reused_;
   }

   if (acquired) {
     last_acquire_ = clk_[tid_];
     ResetCached(c);
   }
 }

 void ThreadClock::releaseStoreAcquire(ClockCache *c, SyncClock *sc) {
   DCHECK_LE(nclk_, kMaxTid);
   DCHECK_LE(sc->size_, kMaxTid);

   if (sc->size_ == 0) {
     // ReleaseStore will correctly set release_store_tid_,
     // which can be important for future operations.
     ReleaseStore(c, sc);
     return;
   }

   nclk_ = max(nclk_, (uptr) sc->size_);

   // Check if we need to resize sc.
   if (sc->size_ < nclk_)
     sc->Resize(c, nclk_);

   bool acquired = false;

   sc->Unshare(c);
   // Update sc->clk_.
   sc->FlushDirty();
   uptr i = 0;
   for (ClockElem &ce : *sc) {
     u64 tmp = clk_[i];
     if (clk_[i] < ce.epoch) {
       clk_[i] = ce.epoch;
       acquired = true;
     }
     ce.epoch = tmp;
     ce.reused = 0;
     i++;
   }
   sc->release_store_tid_ = kInvalidTid;
   sc->release_store_reused_ = 0;

   if (acquired) {
     last_acquire_ = clk_[tid_];
     ResetCached(c);
   }
 }

 void ThreadClock::release(ClockCache *c, SyncClock *dst) {
   DCHECK_LE(nclk_, kMaxTid);
   DCHECK_LE(dst->size_, kMaxTid);

   if (dst->size_ == 0) {
     // ReleaseStore will correctly set release_store_tid_,
     // which can be important for future operations.
     ReleaseStore(c, dst);
     return;
   }

   // Check if we need to resize dst.
   if (dst->size_ < nclk_)
     dst->Resize(c, nclk_);

   // Check if we had not acquired anything from other threads
   // since the last release on dst. If so, we need to update
   // only dst->elem(tid_).
   if (!HasAcquiredAfterRelease(dst)) {
     UpdateCurrentThread(c, dst);
     if (dst->release_store_tid_ != tid_ ||
         dst->release_store_reused_ != reused_)
       dst->release_store_tid_ = kInvalidTid;
     return;
   }

   // O(N) release.
   dst->Unshare(c);
   // First, remember whether we've acquired dst.
   bool acquired = IsAlreadyAcquired(dst);
   // Update dst->clk_.
   dst->FlushDirty();
   uptr i = 0;
   for (ClockElem &ce : *dst) {
     ce.epoch = max(ce.epoch, clk_[i]);
     ce.reused = 0;
     i++;
   }
   // Clear 'acquired' flag in the remaining elements.
   dst->release_store_tid_ = kInvalidTid;
   dst->release_store_reused_ = 0;
   // If we've acquired dst, remember this fact,
   // so that we don't need to acquire it on next acquire.
   if (acquired)
     dst->elem(tid_).reused = reused_;
 }

 void ThreadClock::ReleaseStore(ClockCache *c, SyncClock *dst) {
   DCHECK_LE(nclk_, kMaxTid);
   DCHECK_LE(dst->size_, kMaxTid);

   if (dst->size_ == 0 && cached_idx_ != 0) {
     // Reuse the cached clock.
     // Note: we could reuse/cache the cached clock in more cases:
     // we could update the existing clock and cache it, or replace it with the
     // currently cached clock and release the old one. And for a shared
     // existing clock, we could replace it with the currently cached;
     // or unshare, update and cache. But, for simplicity, we currently reuse
     // cached clock only when the target clock is empty.
     dst->tab_ = ctx->clock_alloc.Map(cached_idx_);
     dst->tab_idx_ = cached_idx_;
     dst->size_ = cached_size_;
     dst->blocks_ = cached_blocks_;
     CHECK_EQ(dst->dirty_[0].tid(), kInvalidTid);
     // The cached clock is shared (immutable),
     // so this is where we store the current clock.
     dst->dirty_[0].set_tid(tid_);
     dst->dirty_[0].epoch = clk_[tid_];
     dst->release_store_tid_ = tid_;
     dst->release_store_reused_ = reused_;
     // Remember that we don't need to acquire it in future.
     dst->elem(tid_).reused = reused_;
     // Grab a reference.
     atomic_fetch_add(ref_ptr(dst->tab_), 1, memory_order_relaxed);
     return;
   }

   // Check if we need to resize dst.
   if (dst->size_ < nclk_)
     dst->Resize(c, nclk_);

   if (dst->release_store_tid_ == tid_ &&
       dst->release_store_reused_ == reused_ &&
       !HasAcquiredAfterRelease(dst)) {
     UpdateCurrentThread(c, dst);
     return;
   }

   // O(N) release-store.
   dst->Unshare(c);
   // Note: dst can be larger than this ThreadClock.
   // This is fine since clk_ beyond size is all zeros.
   uptr i = 0;
   for (ClockElem &ce : *dst) {
     ce.epoch = clk_[i];
     ce.reused = 0;
     i++;
   }
   for (uptr i = 0; i < kDirtyTids; i++) dst->dirty_[i].set_tid(kInvalidTid);
   dst->release_store_tid_ = tid_;
   dst->release_store_reused_ = reused_;
   // Remember that we don't need to acquire it in future.
   dst->elem(tid_).reused = reused_;

   // If the resulting clock is cachable, cache it for future release operations.
   // The clock is always cachable if we released to an empty sync object.
   if (cached_idx_ == 0 && dst->Cachable()) {
     // Grab a reference to the ClockBlock.
     atomic_uint32_t *ref = ref_ptr(dst->tab_);
     if (atomic_load(ref, memory_order_acquire) == 1)
       atomic_store_relaxed(ref, 2);
     else
       atomic_fetch_add(ref_ptr(dst->tab_), 1, memory_order_relaxed);
     cached_idx_ = dst->tab_idx_;
     cached_size_ = dst->size_;
     cached_blocks_ = dst->blocks_;
   }
 }

 void ThreadClock::acq_rel(ClockCache *c, SyncClock *dst) {
   acquire(c, dst);
   ReleaseStore(c, dst);
 }

 // Updates only single element related to the current thread in dst->clk_.
 void ThreadClock::UpdateCurrentThread(ClockCache *c, SyncClock *dst) const {
   // Update the threads time, but preserve 'acquired' flag.
   for (unsigned i = 0; i < kDirtyTids; i++) {
     SyncClock::Dirty *dirty = &dst->dirty_[i];
     const unsigned tid = dirty->tid();
     if (tid == tid_ || tid == kInvalidTid) {
       dirty->set_tid(tid_);
       dirty->epoch = clk_[tid_];
       return;
     }
   }
   // Reset all 'acquired' flags, O(N).
   // We are going to touch dst elements, so we need to unshare it.
   dst->Unshare(c);
   dst->elem(tid_).epoch = clk_[tid_];
   for (uptr i = 0; i < dst->size_; i++)
     dst->elem(i).reused = 0;
   dst->FlushDirty();
 }

 // Checks whether the current thread has already acquired src.
 bool ThreadClock::IsAlreadyAcquired(const SyncClock *src) const {
   if (src->elem(tid_).reused != reused_)
     return false;
   for (unsigned i = 0; i < kDirtyTids; i++) {
     SyncClock::Dirty dirty = src->dirty_[i];
     if (dirty.tid() != kInvalidTid) {
       if (clk_[dirty.tid()] < dirty.epoch)
         return false;
     }
   }
   return true;
 }

 // Checks whether the current thread has acquired anything
 // from other clocks after releasing to dst (directly or indirectly).
 bool ThreadClock::HasAcquiredAfterRelease(const SyncClock *dst) const {
   const u64 my_epoch = dst->elem(tid_).epoch;
   return my_epoch <= last_acquire_ ||
       my_epoch <= atomic_load_relaxed(&global_acquire_);
 }

 // Sets a single element in the vector clock.
 // This function is called only from weird places like AcquireGlobal.
 void ThreadClock::set(ClockCache *c, unsigned tid, u64 v) {
   DCHECK_LT(tid, kMaxTid);
   DCHECK_GE(v, clk_[tid]);
   clk_[tid] = v;
   if (nclk_ <= tid)
     nclk_ = tid + 1;
   last_acquire_ = clk_[tid_];
   ResetCached(c);
 }

 void ThreadClock::DebugDump(int(*printf)(const char *s, ...)) {
   printf("clock=[");
   for (uptr i = 0; i < nclk_; i++)
     printf("%s%llu", i == 0 ? "" : ",", clk_[i]);
   printf("] tid=%u/%u last_acq=%llu", tid_, reused_, last_acquire_);
 }

 SyncClock::SyncClock() {
   ResetImpl();
 }

 SyncClock::~SyncClock() {
   // Reset must be called before dtor.
   CHECK_EQ(size_, 0);
   CHECK_EQ(blocks_, 0);
   CHECK_EQ(tab_, 0);
   CHECK_EQ(tab_idx_, 0);
 }

 void SyncClock::Reset(ClockCache *c) {
   if (size_)
     UnrefClockBlock(c, tab_idx_, blocks_);
   ResetImpl();
 }

 void SyncClock::ResetImpl() {
   tab_ = 0;
   tab_idx_ = 0;
   size_ = 0;
   blocks_ = 0;
   release_store_tid_ = kInvalidTid;
   release_store_reused_ = 0;
   for (uptr i = 0; i < kDirtyTids; i++) dirty_[i].set_tid(kInvalidTid);
 }

 void SyncClock::Resize(ClockCache *c, uptr nclk) {
   Unshare(c);
   if (nclk <= capacity()) {
     // Memory is already allocated, just increase the size.
     size_ = nclk;
     return;
   }
   if (size_ == 0) {
     // Grow from 0 to one-level table.
     CHECK_EQ(size_, 0);
     CHECK_EQ(blocks_, 0);
     CHECK_EQ(tab_, 0);
     CHECK_EQ(tab_idx_, 0);
     tab_idx_ = ctx->clock_alloc.Alloc(c);
     tab_ = ctx->clock_alloc.Map(tab_idx_);
     internal_memset(tab_, 0, sizeof(*tab_));
     atomic_store_relaxed(ref_ptr(tab_), 1);
     size_ = 1;
   } else if (size_ > blocks_ * ClockBlock::kClockCount) {
     u32 idx = ctx->clock_alloc.Alloc(c);
     ClockBlock *new_cb = ctx->clock_alloc.Map(idx);
     uptr top = size_ - blocks_ * ClockBlock::kClockCount;
     CHECK_LT(top, ClockBlock::kClockCount);
     const uptr move = top * sizeof(tab_->clock[0]);
     internal_memcpy(&new_cb->clock[0], tab_->clock, move);
     internal_memset(&new_cb->clock[top], 0, sizeof(*new_cb) - move);
     internal_memset(tab_->clock, 0, move);
     append_block(idx);
   }
   // At this point we have first level table allocated and all clock elements
   // are evacuated from it to a second level block.
   // Add second level tables as necessary.
   while (nclk > capacity()) {
     u32 idx = ctx->clock_alloc.Alloc(c);
     ClockBlock *cb = ctx->clock_alloc.Map(idx);
     internal_memset(cb, 0, sizeof(*cb));
     append_block(idx);
   }
   size_ = nclk;
 }

 // Flushes all dirty elements into the main clock array.
 void SyncClock::FlushDirty() {
   for (unsigned i = 0; i < kDirtyTids; i++) {
     Dirty *dirty = &dirty_[i];
     if (dirty->tid() != kInvalidTid) {
       CHECK_LT(dirty->tid(), size_);
       elem(dirty->tid()).epoch = dirty->epoch;
       dirty->set_tid(kInvalidTid);
     }
   }
 }

 bool SyncClock::IsShared() const {
   if (size_ == 0)
     return false;
   atomic_uint32_t *ref = ref_ptr(tab_);
   u32 v = atomic_load(ref, memory_order_acquire);
   CHECK_GT(v, 0);
   return v > 1;
 }

 // Unshares the current clock if it's shared.
 // Shared clocks are immutable, so they need to be unshared before any updates.
 // Note: this does not apply to dirty entries as they are not shared.
 void SyncClock::Unshare(ClockCache *c) {
   if (!IsShared())
     return;
   // First, copy current state into old.
   SyncClock old;
   old.tab_ = tab_;
   old.tab_idx_ = tab_idx_;
   old.size_ = size_;
   old.blocks_ = blocks_;
   old.release_store_tid_ = release_store_tid_;
   old.release_store_reused_ = release_store_reused_;
   for (unsigned i = 0; i < kDirtyTids; i++)
     old.dirty_[i] = dirty_[i];
   // Then, clear current object.
   ResetImpl();
   // Allocate brand new clock in the current object.
   Resize(c, old.size_);
   // Now copy state back into this object.
   Iter old_iter(&old);
   for (ClockElem &ce : *this) {
     ce = *old_iter;
     ++old_iter;
   }
   release_store_tid_ = old.release_store_tid_;
   release_store_reused_ = old.release_store_reused_;
   for (unsigned i = 0; i < kDirtyTids; i++)
     dirty_[i] = old.dirty_[i];
   // Drop reference to old and delete if necessary.
   old.Reset(c);
 }

 // Can we cache this clock for future release operations?
 ALWAYS_INLINE bool SyncClock::Cachable() const {
   if (size_ == 0)
     return false;
   for (unsigned i = 0; i < kDirtyTids; i++) {
     if (dirty_[i].tid() != kInvalidTid)
       return false;
   }
   return atomic_load_relaxed(ref_ptr(tab_)) == 1;
 }

 // elem linearizes the two-level structure into linear array.
 // Note: this is used only for one time accesses, vector operations use
 // the iterator as it is much faster.
 ALWAYS_INLINE ClockElem &SyncClock::elem(unsigned tid) const {
   DCHECK_LT(tid, size_);
   const uptr block = tid / ClockBlock::kClockCount;
   DCHECK_LE(block, blocks_);
   tid %= ClockBlock::kClockCount;
   if (block == blocks_)
     return tab_->clock[tid];
   u32 idx = get_block(block);
   ClockBlock *cb = ctx->clock_alloc.Map(idx);
   return cb->clock[tid];
 }

 ALWAYS_INLINE uptr SyncClock::capacity() const {
   if (size_ == 0)
     return 0;
   uptr ratio = sizeof(ClockBlock::clock[0]) / sizeof(ClockBlock::table[0]);
   // How many clock elements we can fit into the first level block.
   // +1 for ref counter.
   uptr top = ClockBlock::kClockCount - RoundUpTo(blocks_ + 1, ratio) / ratio;
   return blocks_ * ClockBlock::kClockCount + top;
 }

 ALWAYS_INLINE u32 SyncClock::get_block(uptr bi) const {
   DCHECK(size_);
   DCHECK_LT(bi, blocks_);
   return tab_->table[ClockBlock::kBlockIdx - bi];
 }

 ALWAYS_INLINE void SyncClock::append_block(u32 idx) {
   uptr bi = blocks_++;
   CHECK_EQ(get_block(bi), 0);
   tab_->table[ClockBlock::kBlockIdx - bi] = idx;
 }

 // Used only by tests.
 u64 SyncClock::get(unsigned tid) const {
   for (unsigned i = 0; i < kDirtyTids; i++) {
     Dirty dirty = dirty_[i];
     if (dirty.tid() == tid)
       return dirty.epoch;
   }
   return elem(tid).epoch;
 }

 // Used only by Iter test.
 u64 SyncClock::get_clean(unsigned tid) const {
   return elem(tid).epoch;
 }

 void SyncClock::DebugDump(int(*printf)(const char *s, ...)) {
   printf("clock=[");
   for (uptr i = 0; i < size_; i++)
     printf("%s%llu", i == 0 ? "" : ",", elem(i).epoch);
   printf("] reused=[");
   for (uptr i = 0; i < size_; i++)
     printf("%s%llu", i == 0 ? "" : ",", elem(i).reused);
   printf("] release_store_tid=%d/%d dirty_tids=%d[%llu]/%d[%llu]",
          release_store_tid_, release_store_reused_, dirty_[0].tid(),
          dirty_[0].epoch, dirty_[1].tid(), dirty_[1].epoch);
 }

 void SyncClock::Iter::Next() {
   // Finished with the current block, move on to the next one.
   block_++;
   if (block_ < parent_->blocks_) {
     // Iterate over the next second level block.
     u32 idx = parent_->get_block(block_);
     ClockBlock *cb = ctx->clock_alloc.Map(idx);
     pos_ = &cb->clock[0];
     end_ = pos_ + min(parent_->size_ - block_ * ClockBlock::kClockCount,
         ClockBlock::kClockCount);
     return;
   }
   if (block_ == parent_->blocks_ &&
       parent_->size_ > parent_->blocks_ * ClockBlock::kClockCount) {
     // Iterate over elements in the first level block.
     pos_ = &parent_->tab_->clock[0];
     end_ = pos_ + min(parent_->size_ - block_ * ClockBlock::kClockCount,
         ClockBlock::kClockCount);
     return;
   }
   parent_ = nullptr;  // denotes end
 }
 }  // namespace __tsan
	//===-- tsan_clock.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_clock.h"
	#include "tsan_rtl.h"
	#include "sanitizer_common/sanitizer_placement_new.h"

	// SyncClock and ThreadClock implement vector clocks for sync variables
	// (mutexes, atomic variables, file descriptors, etc) and threads, respectively.
	// ThreadClock contains fixed-size vector clock for maximum number of threads.
	// SyncClock contains growable vector clock for currently necessary number of
	// threads.
	// Together they implement very simple model of operations, namely:
	//
	// void ThreadClock::acquire(const SyncClock *src) {
	// for (int i = 0; i < kMaxThreads; i++)
	// clock[i] = max(clock[i], src->clock[i]);
	// }
	//
	// void ThreadClock::release(SyncClock *dst) const {
	// for (int i = 0; i < kMaxThreads; i++)
	// dst->clock[i] = max(dst->clock[i], clock[i]);
	// }
	//
	// void ThreadClock::releaseStoreAcquire(SyncClock *sc) const {
	// for (int i = 0; i < kMaxThreads; i++) {
	// tmp = clock[i];
	// clock[i] = max(clock[i], sc->clock[i]);
	// sc->clock[i] = tmp;
	// }
	// }
	//
	// void ThreadClock::ReleaseStore(SyncClock *dst) const {
	// for (int i = 0; i < kMaxThreads; i++)
	// dst->clock[i] = clock[i];
	// }
	//
	// void ThreadClock::acq_rel(SyncClock *dst) {
	// acquire(dst);
	// release(dst);
	// }
	//
	// Conformance to this model is extensively verified in tsan_clock_test.cpp.
	// However, the implementation is significantly more complex. The complexity
	// allows to implement important classes of use cases in O(1) instead of O(N).
	//
	// The use cases are:
	// 1. Singleton/once atomic that has a single release-store operation followed
	// by zillions of acquire-loads (the acquire-load is O(1)).
	// 2. Thread-local mutex (both lock and unlock can be O(1)).
	// 3. Leaf mutex (unlock is O(1)).
	// 4. A mutex shared by 2 threads (both lock and unlock can be O(1)).
	// 5. An atomic with a single writer (writes can be O(1)).
	// The implementation dynamically adopts to workload. So if an atomic is in
	// read-only phase, these reads will be O(1); if it later switches to read/write
	// phase, the implementation will correctly handle that by switching to O(N).
	//
	// Thread-safety note: all const operations on SyncClock's are conducted under
	// a shared lock; all non-const operations on SyncClock's are conducted under
	// an exclusive lock; ThreadClock's are private to respective threads and so
	// do not need any protection.
	//
	// Description of SyncClock state:
	// clk_ - variable size vector clock, low kClkBits hold timestamp,
	// the remaining bits hold "acquired" flag (the actual value is thread's
	// reused counter);
	// if acquired == thr->reused_, then the respective thread has already
	// acquired this clock (except possibly for dirty elements).
	// dirty_ - holds up to two indices in the vector clock that other threads
	// need to acquire regardless of "acquired" flag value;
	// release_store_tid_ - denotes that the clock state is a result of
	// release-store operation by the thread with release_store_tid_ index.
	// release_store_reused_ - reuse count of release_store_tid_.

	namespace __tsan {

	static atomic_uint32_t ref_ptr(ClockBlock cb) {
	return reinterpret_cast<atomic_uint32_t *>(&cb->table[ClockBlock::kRefIdx]);
	}

	// Drop reference to the first level block idx.
	static void UnrefClockBlock(ClockCache *c, u32 idx, uptr blocks) {
	ClockBlock *cb = ctx->clock_alloc.Map(idx);
	atomic_uint32_t *ref = ref_ptr(cb);
	u32 v = atomic_load(ref, memory_order_acquire);
	for (;;) {
	CHECK_GT(v, 0);
	if (v == 1)
	break;
	if (atomic_compare_exchange_strong(ref, &v, v - 1, memory_order_acq_rel))
	return;
	}
	// First level block owns second level blocks, so them as well.
	for (uptr i = 0; i < blocks; i++)
	ctx->clock_alloc.Free(c, cb->table[ClockBlock::kBlockIdx - i]);
	ctx->clock_alloc.Free(c, idx);
	}

	ThreadClock::ThreadClock(unsigned tid, unsigned reused)
	: tid_(tid)
	, reused_(reused + 1) // 0 has special meaning
	, last_acquire_()
	, global_acquire_()
	, cached_idx_()
	, cached_size_()
	, cached_blocks_() {
	CHECK_LT(tid, kMaxTidInClock);
	CHECK_EQ(reused_, ((u64)reused_ << kClkBits) >> kClkBits);
	nclk_ = tid_ + 1;
	internal_memset(clk_, 0, sizeof(clk_));
	}

	void ThreadClock::ResetCached(ClockCache *c) {
	if (cached_idx_) {
	UnrefClockBlock(c, cached_idx_, cached_blocks_);
	cached_idx_ = 0;
	cached_size_ = 0;
	cached_blocks_ = 0;
	}
	}

	void ThreadClock::acquire(ClockCache c, SyncClock src) {
	DCHECK_LE(nclk_, kMaxTid);
	DCHECK_LE(src->size_, kMaxTid);

	// Check if it's empty -> no need to do anything.
	const uptr nclk = src->size_;
	if (nclk == 0)
	return;

	bool acquired = false;
	for (unsigned i = 0; i < kDirtyTids; i++) {
	SyncClock::Dirty dirty = src->dirty_[i];
	unsigned tid = dirty.tid();
	if (tid != kInvalidTid) {
	if (clk_[tid] < dirty.epoch) {
	clk_[tid] = dirty.epoch;
	acquired = true;
	}
	}
	}

	// Check if we've already acquired src after the last release operation on src
	if (tid_ >= nclk \|\| src->elem(tid_).reused != reused_) {
	// O(N) acquire.
	nclk_ = max(nclk_, nclk);
	u64 *dst_pos = &clk_[0];
	for (ClockElem &src_elem : *src) {
	u64 epoch = src_elem.epoch;
	if (*dst_pos < epoch) {
	*dst_pos = epoch;
	acquired = true;
	}
	dst_pos++;
	}

	// Remember that this thread has acquired this clock.
	if (nclk > tid_)
	src->elem(tid_).reused = reused_;
	}

	if (acquired) {
	last_acquire_ = clk_[tid_];
	ResetCached(c);
	}
	}

	void ThreadClock::releaseStoreAcquire(ClockCache c, SyncClock sc) {
	DCHECK_LE(nclk_, kMaxTid);
	DCHECK_LE(sc->size_, kMaxTid);

	if (sc->size_ == 0) {
	// ReleaseStore will correctly set release_store_tid_,
	// which can be important for future operations.
	ReleaseStore(c, sc);
	return;
	}

	nclk_ = max(nclk_, (uptr) sc->size_);

	// Check if we need to resize sc.
	if (sc->size_ < nclk_)
	sc->Resize(c, nclk_);

	bool acquired = false;

	sc->Unshare(c);
	// Update sc->clk_.
	sc->FlushDirty();
	uptr i = 0;
	for (ClockElem &ce : *sc) {
	u64 tmp = clk_[i];
	if (clk_[i] < ce.epoch) {
	clk_[i] = ce.epoch;
	acquired = true;
	}
	ce.epoch = tmp;
	ce.reused = 0;
	i++;
	}
	sc->release_store_tid_ = kInvalidTid;
	sc->release_store_reused_ = 0;

	if (acquired) {
	last_acquire_ = clk_[tid_];
	ResetCached(c);
	}
	}

	void ThreadClock::release(ClockCache c, SyncClock dst) {
	DCHECK_LE(nclk_, kMaxTid);
	DCHECK_LE(dst->size_, kMaxTid);

	if (dst->size_ == 0) {
	// ReleaseStore will correctly set release_store_tid_,
	// which can be important for future operations.
	ReleaseStore(c, dst);
	return;
	}

	// Check if we need to resize dst.
	if (dst->size_ < nclk_)
	dst->Resize(c, nclk_);

	// Check if we had not acquired anything from other threads
	// since the last release on dst. If so, we need to update
	// only dst->elem(tid_).
	if (!HasAcquiredAfterRelease(dst)) {
	UpdateCurrentThread(c, dst);
	if (dst->release_store_tid_ != tid_ \|\|
	dst->release_store_reused_ != reused_)
	dst->release_store_tid_ = kInvalidTid;
	return;
	}

	// O(N) release.
	dst->Unshare(c);
	// First, remember whether we've acquired dst.
	bool acquired = IsAlreadyAcquired(dst);
	// Update dst->clk_.
	dst->FlushDirty();
	uptr i = 0;
	for (ClockElem &ce : *dst) {
	ce.epoch = max(ce.epoch, clk_[i]);
	ce.reused = 0;
	i++;
	}
	// Clear 'acquired' flag in the remaining elements.
	dst->release_store_tid_ = kInvalidTid;
	dst->release_store_reused_ = 0;
	// If we've acquired dst, remember this fact,
	// so that we don't need to acquire it on next acquire.
	if (acquired)
	dst->elem(tid_).reused = reused_;
	}

	void ThreadClock::ReleaseStore(ClockCache c, SyncClock dst) {
	DCHECK_LE(nclk_, kMaxTid);
	DCHECK_LE(dst->size_, kMaxTid);

	if (dst->size_ == 0 && cached_idx_ != 0) {
	// Reuse the cached clock.
	// Note: we could reuse/cache the cached clock in more cases:
	// we could update the existing clock and cache it, or replace it with the
	// currently cached clock and release the old one. And for a shared
	// existing clock, we could replace it with the currently cached;
	// or unshare, update and cache. But, for simplicity, we currently reuse
	// cached clock only when the target clock is empty.
	dst->tab_ = ctx->clock_alloc.Map(cached_idx_);
	dst->tab_idx_ = cached_idx_;
	dst->size_ = cached_size_;
	dst->blocks_ = cached_blocks_;
	CHECK_EQ(dst->dirty_[0].tid(), kInvalidTid);
	// The cached clock is shared (immutable),
	// so this is where we store the current clock.
	dst->dirty_[0].set_tid(tid_);
	dst->dirty_[0].epoch = clk_[tid_];
	dst->release_store_tid_ = tid_;
	dst->release_store_reused_ = reused_;
	// Remember that we don't need to acquire it in future.
	dst->elem(tid_).reused = reused_;
	// Grab a reference.
	atomic_fetch_add(ref_ptr(dst->tab_), 1, memory_order_relaxed);
	return;
	}

	// Check if we need to resize dst.
	if (dst->size_ < nclk_)
	dst->Resize(c, nclk_);

	if (dst->release_store_tid_ == tid_ &&
	dst->release_store_reused_ == reused_ &&
	!HasAcquiredAfterRelease(dst)) {
	UpdateCurrentThread(c, dst);
	return;
	}

	// O(N) release-store.
	dst->Unshare(c);
	// Note: dst can be larger than this ThreadClock.
	// This is fine since clk_ beyond size is all zeros.
	uptr i = 0;
	for (ClockElem &ce : *dst) {
	ce.epoch = clk_[i];
	ce.reused = 0;
	i++;
	}
	for (uptr i = 0; i < kDirtyTids; i++) dst->dirty_[i].set_tid(kInvalidTid);
	dst->release_store_tid_ = tid_;
	dst->release_store_reused_ = reused_;
	// Remember that we don't need to acquire it in future.
	dst->elem(tid_).reused = reused_;

	// If the resulting clock is cachable, cache it for future release operations.
	// The clock is always cachable if we released to an empty sync object.
	if (cached_idx_ == 0 && dst->Cachable()) {
	// Grab a reference to the ClockBlock.
	atomic_uint32_t *ref = ref_ptr(dst->tab_);
	if (atomic_load(ref, memory_order_acquire) == 1)
	atomic_store_relaxed(ref, 2);
	else
	atomic_fetch_add(ref_ptr(dst->tab_), 1, memory_order_relaxed);
	cached_idx_ = dst->tab_idx_;
	cached_size_ = dst->size_;
	cached_blocks_ = dst->blocks_;
	}
	}

	void ThreadClock::acq_rel(ClockCache c, SyncClock dst) {
	acquire(c, dst);
	ReleaseStore(c, dst);
	}

	// Updates only single element related to the current thread in dst->clk_.
	void ThreadClock::UpdateCurrentThread(ClockCache c, SyncClock dst) const {
	// Update the threads time, but preserve 'acquired' flag.
	for (unsigned i = 0; i < kDirtyTids; i++) {
	SyncClock::Dirty *dirty = &dst->dirty_[i];
	const unsigned tid = dirty->tid();
	if (tid == tid_ \|\| tid == kInvalidTid) {
	dirty->set_tid(tid_);
	dirty->epoch = clk_[tid_];
	return;
	}
	}
	// Reset all 'acquired' flags, O(N).
	// We are going to touch dst elements, so we need to unshare it.
	dst->Unshare(c);
	dst->elem(tid_).epoch = clk_[tid_];
	for (uptr i = 0; i < dst->size_; i++)
	dst->elem(i).reused = 0;
	dst->FlushDirty();
	}

	// Checks whether the current thread has already acquired src.
	bool ThreadClock::IsAlreadyAcquired(const SyncClock *src) const {
	if (src->elem(tid_).reused != reused_)
	return false;
	for (unsigned i = 0; i < kDirtyTids; i++) {
	SyncClock::Dirty dirty = src->dirty_[i];
	if (dirty.tid() != kInvalidTid) {
	if (clk_[dirty.tid()] < dirty.epoch)
	return false;
	}
	}
	return true;
	}

	// Checks whether the current thread has acquired anything
	// from other clocks after releasing to dst (directly or indirectly).
	bool ThreadClock::HasAcquiredAfterRelease(const SyncClock *dst) const {
	const u64 my_epoch = dst->elem(tid_).epoch;
	return my_epoch <= last_acquire_ \|\|
	my_epoch <= atomic_load_relaxed(&global_acquire_);
	}

	// Sets a single element in the vector clock.
	// This function is called only from weird places like AcquireGlobal.
	void ThreadClock::set(ClockCache *c, unsigned tid, u64 v) {
	DCHECK_LT(tid, kMaxTid);
	DCHECK_GE(v, clk_[tid]);
	clk_[tid] = v;
	if (nclk_ <= tid)
	nclk_ = tid + 1;
	last_acquire_ = clk_[tid_];
	ResetCached(c);
	}

	void ThreadClock::DebugDump(int(printf)(const char s, ...)) {
	printf("clock=[");
	for (uptr i = 0; i < nclk_; i++)
	printf("%s%llu", i == 0 ? "" : ",", clk_[i]);
	printf("] tid=%u/%u last_acq=%llu", tid_, reused_, last_acquire_);
	}

	SyncClock::SyncClock() {
	ResetImpl();
	}

	SyncClock::~SyncClock() {
	// Reset must be called before dtor.
	CHECK_EQ(size_, 0);
	CHECK_EQ(blocks_, 0);
	CHECK_EQ(tab_, 0);
	CHECK_EQ(tab_idx_, 0);
	}

	void SyncClock::Reset(ClockCache *c) {
	if (size_)
	UnrefClockBlock(c, tab_idx_, blocks_);
	ResetImpl();
	}

	void SyncClock::ResetImpl() {
	tab_ = 0;
	tab_idx_ = 0;
	size_ = 0;
	blocks_ = 0;
	release_store_tid_ = kInvalidTid;
	release_store_reused_ = 0;
	for (uptr i = 0; i < kDirtyTids; i++) dirty_[i].set_tid(kInvalidTid);
	}

	void SyncClock::Resize(ClockCache *c, uptr nclk) {
	Unshare(c);
	if (nclk <= capacity()) {
	// Memory is already allocated, just increase the size.
	size_ = nclk;
	return;
	}
	if (size_ == 0) {
	// Grow from 0 to one-level table.
	CHECK_EQ(size_, 0);
	CHECK_EQ(blocks_, 0);
	CHECK_EQ(tab_, 0);
	CHECK_EQ(tab_idx_, 0);
	tab_idx_ = ctx->clock_alloc.Alloc(c);
	tab_ = ctx->clock_alloc.Map(tab_idx_);
	internal_memset(tab_, 0, sizeof(*tab_));
	atomic_store_relaxed(ref_ptr(tab_), 1);
	size_ = 1;
	} else if (size_ > blocks_ * ClockBlock::kClockCount) {
	u32 idx = ctx->clock_alloc.Alloc(c);
	ClockBlock *new_cb = ctx->clock_alloc.Map(idx);
	uptr top = size_ - blocks_ * ClockBlock::kClockCount;
	CHECK_LT(top, ClockBlock::kClockCount);
	const uptr move = top * sizeof(tab_->clock[0]);
	internal_memcpy(&new_cb->clock[0], tab_->clock, move);
	internal_memset(&new_cb->clock[top], 0, sizeof(*new_cb) - move);
	internal_memset(tab_->clock, 0, move);
	append_block(idx);
	}
	// At this point we have first level table allocated and all clock elements
	// are evacuated from it to a second level block.
	// Add second level tables as necessary.
	while (nclk > capacity()) {
	u32 idx = ctx->clock_alloc.Alloc(c);
	ClockBlock *cb = ctx->clock_alloc.Map(idx);
	internal_memset(cb, 0, sizeof(*cb));
	append_block(idx);
	}
	size_ = nclk;
	}

	// Flushes all dirty elements into the main clock array.
	void SyncClock::FlushDirty() {
	for (unsigned i = 0; i < kDirtyTids; i++) {
	Dirty *dirty = &dirty_[i];
	if (dirty->tid() != kInvalidTid) {
	CHECK_LT(dirty->tid(), size_);
	elem(dirty->tid()).epoch = dirty->epoch;
	dirty->set_tid(kInvalidTid);
	}
	}
	}

	bool SyncClock::IsShared() const {
	if (size_ == 0)
	return false;
	atomic_uint32_t *ref = ref_ptr(tab_);
	u32 v = atomic_load(ref, memory_order_acquire);
	CHECK_GT(v, 0);
	return v > 1;
	}

	// Unshares the current clock if it's shared.
	// Shared clocks are immutable, so they need to be unshared before any updates.
	// Note: this does not apply to dirty entries as they are not shared.
	void SyncClock::Unshare(ClockCache *c) {
	if (!IsShared())
	return;
	// First, copy current state into old.
	SyncClock old;
	old.tab_ = tab_;
	old.tab_idx_ = tab_idx_;
	old.size_ = size_;
	old.blocks_ = blocks_;
	old.release_store_tid_ = release_store_tid_;
	old.release_store_reused_ = release_store_reused_;
	for (unsigned i = 0; i < kDirtyTids; i++)
	old.dirty_[i] = dirty_[i];
	// Then, clear current object.
	ResetImpl();
	// Allocate brand new clock in the current object.
	Resize(c, old.size_);
	// Now copy state back into this object.
	Iter old_iter(&old);
	for (ClockElem &ce : *this) {
	ce = *old_iter;
	++old_iter;
	}
	release_store_tid_ = old.release_store_tid_;
	release_store_reused_ = old.release_store_reused_;
	for (unsigned i = 0; i < kDirtyTids; i++)
	dirty_[i] = old.dirty_[i];
	// Drop reference to old and delete if necessary.
	old.Reset(c);
	}

	// Can we cache this clock for future release operations?
	ALWAYS_INLINE bool SyncClock::Cachable() const {
	if (size_ == 0)
	return false;
	for (unsigned i = 0; i < kDirtyTids; i++) {
	if (dirty_[i].tid() != kInvalidTid)
	return false;
	}
	return atomic_load_relaxed(ref_ptr(tab_)) == 1;
	}

	// elem linearizes the two-level structure into linear array.
	// Note: this is used only for one time accesses, vector operations use
	// the iterator as it is much faster.
	ALWAYS_INLINE ClockElem &SyncClock::elem(unsigned tid) const {
	DCHECK_LT(tid, size_);
	const uptr block = tid / ClockBlock::kClockCount;
	DCHECK_LE(block, blocks_);
	tid %= ClockBlock::kClockCount;
	if (block == blocks_)
	return tab_->clock[tid];
	u32 idx = get_block(block);
	ClockBlock *cb = ctx->clock_alloc.Map(idx);
	return cb->clock[tid];
	}

	ALWAYS_INLINE uptr SyncClock::capacity() const {
	if (size_ == 0)
	return 0;
	uptr ratio = sizeof(ClockBlock::clock[0]) / sizeof(ClockBlock::table[0]);
	// How many clock elements we can fit into the first level block.
	// +1 for ref counter.
	uptr top = ClockBlock::kClockCount - RoundUpTo(blocks_ + 1, ratio) / ratio;
	return blocks_ * ClockBlock::kClockCount + top;
	}

	ALWAYS_INLINE u32 SyncClock::get_block(uptr bi) const {
	DCHECK(size_);
	DCHECK_LT(bi, blocks_);
	return tab_->table[ClockBlock::kBlockIdx - bi];
	}

	ALWAYS_INLINE void SyncClock::append_block(u32 idx) {
	uptr bi = blocks_++;
	CHECK_EQ(get_block(bi), 0);
	tab_->table[ClockBlock::kBlockIdx - bi] = idx;
	}

	// Used only by tests.
	u64 SyncClock::get(unsigned tid) const {
	for (unsigned i = 0; i < kDirtyTids; i++) {
	Dirty dirty = dirty_[i];
	if (dirty.tid() == tid)
	return dirty.epoch;
	}
	return elem(tid).epoch;
	}

	// Used only by Iter test.
	u64 SyncClock::get_clean(unsigned tid) const {
	return elem(tid).epoch;
	}

	void SyncClock::DebugDump(int(printf)(const char s, ...)) {
	printf("clock=[");
	for (uptr i = 0; i < size_; i++)
	printf("%s%llu", i == 0 ? "" : ",", elem(i).epoch);
	printf("] reused=[");
	for (uptr i = 0; i < size_; i++)
	printf("%s%llu", i == 0 ? "" : ",", elem(i).reused);
	printf("] release_store_tid=%d/%d dirty_tids=%d[%llu]/%d[%llu]",
	release_store_tid_, release_store_reused_, dirty_[0].tid(),
	dirty_[0].epoch, dirty_[1].tid(), dirty_[1].epoch);
	}

	void SyncClock::Iter::Next() {
	// Finished with the current block, move on to the next one.
	block_++;
	if (block_ < parent_->blocks_) {
	// Iterate over the next second level block.
	u32 idx = parent_->get_block(block_);
	ClockBlock *cb = ctx->clock_alloc.Map(idx);
	pos_ = &cb->clock[0];
	end_ = pos_ + min(parent_->size_ - block_ * ClockBlock::kClockCount,
	ClockBlock::kClockCount);
	return;
	}
	if (block_ == parent_->blocks_ &&
	parent_->size_ > parent_->blocks_ * ClockBlock::kClockCount) {
	// Iterate over elements in the first level block.
	pos_ = &parent_->tab_->clock[0];
	end_ = pos_ + min(parent_->size_ - block_ * ClockBlock::kClockCount,
	ClockBlock::kClockCount);
	return;
	}
	parent_ = nullptr; // denotes end
	}
	} // namespace __tsan