forked from OSchip/llvm-project
395 lines
13 KiB
C++
395 lines
13 KiB
C++
//===-- sanitizer_deadlock_detector.h ---------------------------*- C++ -*-===//
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//
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// The LLVM Compiler Infrastructure
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//
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// This file is distributed under the University of Illinois Open Source
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// License. See LICENSE.TXT for details.
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//
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//===----------------------------------------------------------------------===//
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//
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// This file is a part of Sanitizer runtime.
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// The deadlock detector maintains a directed graph of lock acquisitions.
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// When a lock event happens, the detector checks if the locks already held by
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// the current thread are reachable from the newly acquired lock.
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//
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// The detector can handle only a fixed amount of simultaneously live locks
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// (a lock is alive if it has been locked at least once and has not been
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// destroyed). When the maximal number of locks is reached the entire graph
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// is flushed and the new lock epoch is started. The node ids from the old
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// epochs can not be used with any of the detector methods except for
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// nodeBelongsToCurrentEpoch().
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//
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// FIXME: this is work in progress, nothing really works yet.
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//
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//===----------------------------------------------------------------------===//
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#ifndef SANITIZER_DEADLOCK_DETECTOR_H
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#define SANITIZER_DEADLOCK_DETECTOR_H
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#include "sanitizer_common.h"
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#include "sanitizer_bvgraph.h"
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namespace __sanitizer {
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// Thread-local state for DeadlockDetector.
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// It contains the locks currently held by the owning thread.
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template <class BV>
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class DeadlockDetectorTLS {
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public:
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// No CTOR.
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void clear() {
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bv_.clear();
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epoch_ = 0;
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n_recursive_locks = 0;
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n_all_locks_ = 0;
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}
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bool empty() const { return bv_.empty(); }
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void ensureCurrentEpoch(uptr current_epoch) {
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if (epoch_ == current_epoch) return;
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bv_.clear();
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epoch_ = current_epoch;
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}
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uptr getEpoch() const { return epoch_; }
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// Returns true if this is the first (non-recursive) acquisition of this lock.
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bool addLock(uptr lock_id, uptr current_epoch, u32 stk) {
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// Printf("addLock: %zx %zx\n", lock_id, current_epoch);
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CHECK_EQ(epoch_, current_epoch);
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if (!bv_.setBit(lock_id)) {
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// The lock is already held by this thread, it must be recursive.
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CHECK_LT(n_recursive_locks, ARRAY_SIZE(recursive_locks));
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recursive_locks[n_recursive_locks++] = lock_id;
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return false;
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}
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if (stk) {
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CHECK_LT(n_all_locks_, ARRAY_SIZE(all_locks_with_contexts_));
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LockWithContext &l = all_locks_with_contexts_[n_all_locks_++];
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l.lock = static_cast<u32>(lock_id); // lock_id is small index into bv_.
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l.stk = stk;
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}
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return true;
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}
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void removeLock(uptr lock_id) {
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if (n_recursive_locks) {
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for (sptr i = n_recursive_locks - 1; i >= 0; i--) {
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if (recursive_locks[i] == lock_id) {
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n_recursive_locks--;
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Swap(recursive_locks[i], recursive_locks[n_recursive_locks]);
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return;
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}
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}
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}
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// Printf("remLock: %zx %zx\n", lock_id, epoch_);
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CHECK(bv_.clearBit(lock_id));
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if (n_all_locks_) {
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for (sptr i = n_all_locks_ - 1; i >= 0; i--) {
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if (all_locks_with_contexts_[i].lock == static_cast<u32>(lock_id)) {
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Swap(all_locks_with_contexts_[i],
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all_locks_with_contexts_[n_all_locks_ - 1]);
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n_all_locks_--;
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break;
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}
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}
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}
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}
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u32 findLockContext(uptr lock_id) {
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for (uptr i = 0; i < n_all_locks_; i++)
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if (all_locks_with_contexts_[i].lock == static_cast<u32>(lock_id))
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return all_locks_with_contexts_[i].stk;
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return 0;
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}
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const BV &getLocks(uptr current_epoch) const {
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CHECK_EQ(epoch_, current_epoch);
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return bv_;
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}
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private:
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BV bv_;
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uptr epoch_;
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uptr recursive_locks[64];
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uptr n_recursive_locks;
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struct LockWithContext {
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u32 lock;
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u32 stk;
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};
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LockWithContext all_locks_with_contexts_[64];
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uptr n_all_locks_;
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};
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// DeadlockDetector.
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// For deadlock detection to work we need one global DeadlockDetector object
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// and one DeadlockDetectorTLS object per evey thread.
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// This class is not thread safe, all concurrent accesses should be guarded
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// by an external lock.
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// Most of the methods of this class are not thread-safe (i.e. should
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// be protected by an external lock) unless explicitly told otherwise.
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template <class BV>
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class DeadlockDetector {
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public:
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typedef BV BitVector;
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uptr size() const { return g_.size(); }
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// No CTOR.
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void clear() {
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current_epoch_ = 0;
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available_nodes_.clear();
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recycled_nodes_.clear();
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g_.clear();
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n_edges_ = 0;
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}
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// Allocate new deadlock detector node.
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// If we are out of available nodes first try to recycle some.
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// If there is nothing to recycle, flush the graph and increment the epoch.
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// Associate 'data' (opaque user's object) with the new node.
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uptr newNode(uptr data) {
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if (!available_nodes_.empty())
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return getAvailableNode(data);
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if (!recycled_nodes_.empty()) {
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CHECK(available_nodes_.empty());
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// removeEdgesFrom was called in removeNode.
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g_.removeEdgesTo(recycled_nodes_);
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available_nodes_.setUnion(recycled_nodes_);
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recycled_nodes_.clear();
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return getAvailableNode(data);
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}
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// We are out of vacant nodes. Flush and increment the current_epoch_.
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current_epoch_ += size();
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recycled_nodes_.clear();
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available_nodes_.setAll();
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g_.clear();
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return getAvailableNode(data);
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}
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// Get data associated with the node created by newNode().
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uptr getData(uptr node) const { return data_[nodeToIndex(node)]; }
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bool nodeBelongsToCurrentEpoch(uptr node) {
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return node && (node / size() * size()) == current_epoch_;
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}
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void removeNode(uptr node) {
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uptr idx = nodeToIndex(node);
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CHECK(!available_nodes_.getBit(idx));
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CHECK(recycled_nodes_.setBit(idx));
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g_.removeEdgesFrom(idx);
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}
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void ensureCurrentEpoch(DeadlockDetectorTLS<BV> *dtls) {
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dtls->ensureCurrentEpoch(current_epoch_);
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}
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// Returns true if there is a cycle in the graph after this lock event.
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// Ideally should be called before the lock is acquired so that we can
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// report a deadlock before a real deadlock happens.
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bool onLockBefore(DeadlockDetectorTLS<BV> *dtls, uptr cur_node) {
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ensureCurrentEpoch(dtls);
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uptr cur_idx = nodeToIndex(cur_node);
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return g_.isReachable(cur_idx, dtls->getLocks(current_epoch_));
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}
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u32 findLockContext(DeadlockDetectorTLS<BV> *dtls, uptr node) {
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return dtls->findLockContext(nodeToIndex(node));
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}
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// Add cur_node to the set of locks held currently by dtls.
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void onLockAfter(DeadlockDetectorTLS<BV> *dtls, uptr cur_node, u32 stk = 0) {
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ensureCurrentEpoch(dtls);
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uptr cur_idx = nodeToIndex(cur_node);
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dtls->addLock(cur_idx, current_epoch_, stk);
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}
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// Experimental *racy* fast path function.
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// Returns true if all edges from the currently held locks to cur_node exist.
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bool hasAllEdges(DeadlockDetectorTLS<BV> *dtls, uptr cur_node) {
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uptr local_epoch = dtls->getEpoch();
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// Read from current_epoch_ is racy.
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if (cur_node && local_epoch == current_epoch_ &&
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local_epoch == nodeToEpoch(cur_node)) {
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uptr cur_idx = nodeToIndexUnchecked(cur_node);
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return g_.hasAllEdges(dtls->getLocks(local_epoch), cur_idx);
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}
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return false;
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}
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// Adds edges from currently held locks to cur_node,
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// returns the number of added edges, and puts the sources of added edges
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// into added_edges[].
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// Should be called before onLockAfter.
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uptr addEdges(DeadlockDetectorTLS<BV> *dtls, uptr cur_node, u32 stk = 0) {
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ensureCurrentEpoch(dtls);
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uptr cur_idx = nodeToIndex(cur_node);
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uptr added_edges[40];
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uptr n_added_edges = g_.addEdges(dtls->getLocks(current_epoch_), cur_idx,
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added_edges, ARRAY_SIZE(added_edges));
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for (uptr i = 0; i < n_added_edges; i++) {
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if (n_edges_ < ARRAY_SIZE(edges_))
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edges_[n_edges_++] = Edge((u16)added_edges[i], (u16)cur_idx,
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dtls->findLockContext(added_edges[i]), stk);
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// Printf("Edge [%zd]: %u %zd=>%zd\n", i, stk, added_edges[i], cur_idx);
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}
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return n_added_edges;
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}
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bool findEdge(uptr from_node, uptr to_node, u32 *stk_from, u32 *stk_to) {
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uptr from_idx = nodeToIndex(from_node);
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uptr to_idx = nodeToIndex(to_node);
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for (uptr i = 0; i < n_edges_; i++) {
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if (edges_[i].from == from_idx && edges_[i].to == to_idx) {
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*stk_from = edges_[i].stk_from;
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*stk_to = edges_[i].stk_to;
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return true;
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}
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}
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return false;
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}
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// Test-only function. Handles the before/after lock events,
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// returns true if there is a cycle.
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bool onLock(DeadlockDetectorTLS<BV> *dtls, uptr cur_node, u32 stk = 0) {
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ensureCurrentEpoch(dtls);
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bool is_reachable = !isHeld(dtls, cur_node) && onLockBefore(dtls, cur_node);
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addEdges(dtls, cur_node, 0);
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onLockAfter(dtls, cur_node, stk);
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return is_reachable;
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}
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// Handles the try_lock event, returns false.
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// When a try_lock event happens (i.e. a try_lock call succeeds) we need
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// to add this lock to the currently held locks, but we should not try to
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// change the lock graph or to detect a cycle. We may want to investigate
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// whether a more aggressive strategy is possible for try_lock.
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bool onTryLock(DeadlockDetectorTLS<BV> *dtls, uptr cur_node, u32 stk = 0) {
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ensureCurrentEpoch(dtls);
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uptr cur_idx = nodeToIndex(cur_node);
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dtls->addLock(cur_idx, current_epoch_, stk);
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return false;
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}
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// Returns true iff dtls is empty (no locks are currently held) and we can
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// add the node to the currently held locks w/o chanding the global state.
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// This operation is thread-safe as it only touches the dtls.
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bool onFirstLock(DeadlockDetectorTLS<BV> *dtls, uptr node, u32 stk = 0) {
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if (!dtls->empty()) return false;
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if (dtls->getEpoch() && dtls->getEpoch() == nodeToEpoch(node)) {
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dtls->addLock(nodeToIndexUnchecked(node), nodeToEpoch(node), stk);
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return true;
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}
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return false;
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}
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// Finds a path between the lock 'cur_node' (currently not held in dtls)
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// and some currently held lock, returns the length of the path
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// or 0 on failure.
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uptr findPathToLock(DeadlockDetectorTLS<BV> *dtls, uptr cur_node, uptr *path,
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uptr path_size) {
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tmp_bv_.copyFrom(dtls->getLocks(current_epoch_));
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uptr idx = nodeToIndex(cur_node);
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CHECK(!tmp_bv_.getBit(idx));
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uptr res = g_.findShortestPath(idx, tmp_bv_, path, path_size);
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for (uptr i = 0; i < res; i++)
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path[i] = indexToNode(path[i]);
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if (res)
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CHECK_EQ(path[0], cur_node);
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return res;
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}
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// Handle the unlock event.
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// This operation is thread-safe as it only touches the dtls.
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void onUnlock(DeadlockDetectorTLS<BV> *dtls, uptr node) {
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if (dtls->getEpoch() == nodeToEpoch(node))
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dtls->removeLock(nodeToIndexUnchecked(node));
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}
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// Tries to handle the lock event w/o writing to global state.
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// Returns true on success.
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// This operation is thread-safe as it only touches the dtls
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// (modulo racy nature of hasAllEdges).
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bool onLockFast(DeadlockDetectorTLS<BV> *dtls, uptr node, u32 stk = 0) {
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if (hasAllEdges(dtls, node)) {
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dtls->addLock(nodeToIndexUnchecked(node), nodeToEpoch(node), 0);
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return true;
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}
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return false;
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}
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bool isHeld(DeadlockDetectorTLS<BV> *dtls, uptr node) const {
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return dtls->getLocks(current_epoch_).getBit(nodeToIndex(node));
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}
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uptr testOnlyGetEpoch() const { return current_epoch_; }
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bool testOnlyHasEdge(uptr l1, uptr l2) {
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return g_.hasEdge(nodeToIndex(l1), nodeToIndex(l2));
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}
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// idx1 and idx2 are raw indices to g_, not lock IDs.
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bool testOnlyHasEdgeRaw(uptr idx1, uptr idx2) {
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return g_.hasEdge(idx1, idx2);
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}
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void Print() {
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for (uptr from = 0; from < size(); from++)
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for (uptr to = 0; to < size(); to++)
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if (g_.hasEdge(from, to))
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Printf(" %zx => %zx\n", from, to);
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}
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private:
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void check_idx(uptr idx) const { CHECK_LT(idx, size()); }
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void check_node(uptr node) const {
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CHECK_GE(node, size());
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CHECK_EQ(current_epoch_, nodeToEpoch(node));
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}
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uptr indexToNode(uptr idx) const {
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check_idx(idx);
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return idx + current_epoch_;
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}
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uptr nodeToIndexUnchecked(uptr node) const { return node % size(); }
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uptr nodeToIndex(uptr node) const {
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check_node(node);
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return nodeToIndexUnchecked(node);
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}
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uptr nodeToEpoch(uptr node) const { return node / size() * size(); }
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uptr getAvailableNode(uptr data) {
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uptr idx = available_nodes_.getAndClearFirstOne();
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data_[idx] = data;
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return indexToNode(idx);
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}
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struct Edge {
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u16 from;
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u16 to;
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u32 stk_from;
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u32 stk_to;
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// FIXME: replace with initializer list once the tests are built as c++11.
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Edge(u16 f, u16 t, u32 sf, u32 st)
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: from(f), to(t), stk_from(sf), stk_to(st) {}
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Edge() {}
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};
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uptr current_epoch_;
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BV available_nodes_;
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BV recycled_nodes_;
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BV tmp_bv_;
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BVGraph<BV> g_;
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uptr data_[BV::kSize];
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Edge edges_[BV::kSize * 32];
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uptr n_edges_;
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};
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} // namespace __sanitizer
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#endif // SANITIZER_DEADLOCK_DETECTOR_H
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