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294 lines
9.6 KiB
C++
Vendored
294 lines
9.6 KiB
C++
Vendored
//===-- tsan_clock.h --------------------------------------------*- C++ -*-===//
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//
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// Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
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// See https://llvm.org/LICENSE.txt for license information.
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// SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
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//
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//===----------------------------------------------------------------------===//
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//
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// This file is a part of ThreadSanitizer (TSan), a race detector.
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//
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//===----------------------------------------------------------------------===//
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#ifndef TSAN_CLOCK_H
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#define TSAN_CLOCK_H
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#include "tsan_defs.h"
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#include "tsan_dense_alloc.h"
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namespace __tsan {
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typedef DenseSlabAlloc<ClockBlock, 1 << 22, 1 << 10> ClockAlloc;
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typedef DenseSlabAllocCache ClockCache;
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// The clock that lives in sync variables (mutexes, atomics, etc).
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class SyncClock {
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public:
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SyncClock();
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~SyncClock();
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uptr size() const;
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// These are used only in tests.
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u64 get(unsigned tid) const;
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u64 get_clean(unsigned tid) const;
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void Resize(ClockCache *c, uptr nclk);
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void Reset(ClockCache *c);
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void DebugDump(int(*printf)(const char *s, ...));
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// Clock element iterator.
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// Note: it iterates only over the table without regard to dirty entries.
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class Iter {
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public:
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explicit Iter(SyncClock* parent);
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Iter& operator++();
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bool operator!=(const Iter& other);
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ClockElem &operator*();
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private:
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SyncClock *parent_;
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// [pos_, end_) is the current continuous range of clock elements.
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ClockElem *pos_;
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ClockElem *end_;
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int block_; // Current number of second level block.
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NOINLINE void Next();
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};
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Iter begin();
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Iter end();
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private:
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friend class ThreadClock;
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friend class Iter;
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static const uptr kDirtyTids = 2;
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struct Dirty {
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u32 tid() const { return tid_ == kShortInvalidTid ? kInvalidTid : tid_; }
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void set_tid(u32 tid) {
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tid_ = tid == kInvalidTid ? kShortInvalidTid : tid;
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}
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u64 epoch : kClkBits;
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private:
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// Full kInvalidTid won't fit into Dirty::tid.
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static const u64 kShortInvalidTid = (1ull << (64 - kClkBits)) - 1;
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u64 tid_ : 64 - kClkBits; // kInvalidId if not active
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};
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static_assert(sizeof(Dirty) == 8, "Dirty is not 64bit");
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unsigned release_store_tid_;
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unsigned release_store_reused_;
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Dirty dirty_[kDirtyTids];
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// If size_ is 0, tab_ is nullptr.
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// If size <= 64 (kClockCount), tab_ contains pointer to an array with
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// 64 ClockElem's (ClockBlock::clock).
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// Otherwise, tab_ points to an array with up to 127 u32 elements,
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// each pointing to the second-level 512b block with 64 ClockElem's.
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// Unused space in the first level ClockBlock is used to store additional
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// clock elements.
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// The last u32 element in the first level ClockBlock is always used as
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// reference counter.
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//
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// See the following scheme for details.
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// All memory blocks are 512 bytes (allocated from ClockAlloc).
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// Clock (clk) elements are 64 bits.
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// Idx and ref are 32 bits.
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//
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// tab_
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// |
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// \/
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// +----------------------------------------------------+
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// | clk128 | clk129 | ...unused... | idx1 | idx0 | ref |
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// +----------------------------------------------------+
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// | |
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// | \/
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// | +----------------+
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// | | clk0 ... clk63 |
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// | +----------------+
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// \/
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// +------------------+
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// | clk64 ... clk127 |
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// +------------------+
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//
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// Note: dirty entries, if active, always override what's stored in the clock.
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ClockBlock *tab_;
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u32 tab_idx_;
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u16 size_;
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u16 blocks_; // Number of second level blocks.
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void Unshare(ClockCache *c);
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bool IsShared() const;
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bool Cachable() const;
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void ResetImpl();
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void FlushDirty();
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uptr capacity() const;
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u32 get_block(uptr bi) const;
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void append_block(u32 idx);
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ClockElem &elem(unsigned tid) const;
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};
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// The clock that lives in threads.
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class ThreadClock {
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public:
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typedef DenseSlabAllocCache Cache;
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explicit ThreadClock(unsigned tid, unsigned reused = 0);
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u64 get(unsigned tid) const;
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void set(ClockCache *c, unsigned tid, u64 v);
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void set(u64 v);
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void tick();
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uptr size() const;
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void acquire(ClockCache *c, SyncClock *src);
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void releaseStoreAcquire(ClockCache *c, SyncClock *src);
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void release(ClockCache *c, SyncClock *dst);
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void acq_rel(ClockCache *c, SyncClock *dst);
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void ReleaseStore(ClockCache *c, SyncClock *dst);
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void ResetCached(ClockCache *c);
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void NoteGlobalAcquire(u64 v);
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void DebugReset();
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void DebugDump(int(*printf)(const char *s, ...));
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private:
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static const uptr kDirtyTids = SyncClock::kDirtyTids;
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// Index of the thread associated with he clock ("current thread").
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const unsigned tid_;
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const unsigned reused_; // tid_ reuse count.
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// Current thread time when it acquired something from other threads.
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u64 last_acquire_;
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// Last time another thread has done a global acquire of this thread's clock.
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// It helps to avoid problem described in:
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// https://github.com/golang/go/issues/39186
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// See test/tsan/java_finalizer2.cpp for a regression test.
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// Note the failuire is _extremely_ hard to hit, so if you are trying
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// to reproduce it, you may want to run something like:
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// $ go get golang.org/x/tools/cmd/stress
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// $ stress -p=64 ./a.out
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//
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// The crux of the problem is roughly as follows.
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// A number of O(1) optimizations in the clocks algorithm assume proper
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// transitive cumulative propagation of clock values. The AcquireGlobal
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// operation may produce an inconsistent non-linearazable view of
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// thread clocks. Namely, it may acquire a later value from a thread
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// with a higher ID, but fail to acquire an earlier value from a thread
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// with a lower ID. If a thread that executed AcquireGlobal then releases
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// to a sync clock, it will spoil the sync clock with the inconsistent
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// values. If another thread later releases to the sync clock, the optimized
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// algorithm may break.
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//
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// The exact sequence of events that leads to the failure.
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// - thread 1 executes AcquireGlobal
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// - thread 1 acquires value 1 for thread 2
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// - thread 2 increments clock to 2
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// - thread 2 releases to sync object 1
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// - thread 3 at time 1
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// - thread 3 acquires from sync object 1
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// - thread 3 increments clock to 2
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// - thread 1 acquires value 2 for thread 3
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// - thread 1 releases to sync object 2
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// - sync object 2 clock has 1 for thread 2 and 2 for thread 3
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// - thread 3 releases to sync object 2
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// - thread 3 sees value 2 in the clock for itself
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// and decides that it has already released to the clock
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// and did not acquire anything from other threads after that
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// (the last_acquire_ check in release operation)
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// - thread 3 does not update the value for thread 2 in the clock from 1 to 2
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// - thread 4 acquires from sync object 2
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// - thread 4 detects a false race with thread 2
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// as it should have been synchronized with thread 2 up to time 2,
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// but because of the broken clock it is now synchronized only up to time 1
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//
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// The global_acquire_ value helps to prevent this scenario.
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// Namely, thread 3 will not trust any own clock values up to global_acquire_
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// for the purposes of the last_acquire_ optimization.
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atomic_uint64_t global_acquire_;
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// Cached SyncClock (without dirty entries and release_store_tid_).
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// We reuse it for subsequent store-release operations without intervening
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// acquire operations. Since it is shared (and thus constant), clock value
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// for the current thread is then stored in dirty entries in the SyncClock.
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// We host a refernece to the table while it is cached here.
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u32 cached_idx_;
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u16 cached_size_;
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u16 cached_blocks_;
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// Number of active elements in the clk_ table (the rest is zeros).
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uptr nclk_;
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u64 clk_[kMaxTidInClock]; // Fixed size vector clock.
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bool IsAlreadyAcquired(const SyncClock *src) const;
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bool HasAcquiredAfterRelease(const SyncClock *dst) const;
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void UpdateCurrentThread(ClockCache *c, SyncClock *dst) const;
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};
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ALWAYS_INLINE u64 ThreadClock::get(unsigned tid) const {
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DCHECK_LT(tid, kMaxTidInClock);
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return clk_[tid];
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}
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ALWAYS_INLINE void ThreadClock::set(u64 v) {
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DCHECK_GE(v, clk_[tid_]);
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clk_[tid_] = v;
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}
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ALWAYS_INLINE void ThreadClock::tick() {
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clk_[tid_]++;
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}
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ALWAYS_INLINE uptr ThreadClock::size() const {
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return nclk_;
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}
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ALWAYS_INLINE void ThreadClock::NoteGlobalAcquire(u64 v) {
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// Here we rely on the fact that AcquireGlobal is protected by
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// ThreadRegistryLock, thus only one thread at a time executes it
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// and values passed to this function should not go backwards.
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CHECK_LE(atomic_load_relaxed(&global_acquire_), v);
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atomic_store_relaxed(&global_acquire_, v);
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}
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ALWAYS_INLINE SyncClock::Iter SyncClock::begin() {
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return Iter(this);
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}
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ALWAYS_INLINE SyncClock::Iter SyncClock::end() {
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return Iter(nullptr);
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}
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ALWAYS_INLINE uptr SyncClock::size() const {
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return size_;
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}
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ALWAYS_INLINE SyncClock::Iter::Iter(SyncClock* parent)
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: parent_(parent)
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, pos_(nullptr)
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, end_(nullptr)
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, block_(-1) {
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if (parent)
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Next();
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}
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ALWAYS_INLINE SyncClock::Iter& SyncClock::Iter::operator++() {
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pos_++;
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if (UNLIKELY(pos_ >= end_))
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Next();
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return *this;
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}
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ALWAYS_INLINE bool SyncClock::Iter::operator!=(const SyncClock::Iter& other) {
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return parent_ != other.parent_;
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}
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ALWAYS_INLINE ClockElem &SyncClock::Iter::operator*() {
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return *pos_;
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}
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} // namespace __tsan
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#endif // TSAN_CLOCK_H
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