mirror of
https://github.com/facebook/rocksdb.git
synced 2024-12-04 20:02:50 +00:00
1cfdece85d
Summary: When internal cpp modernizer attempts to format rocksdb code, it will replace macro `ROCKSDB_NAMESPACE` with its default definition `rocksdb` when collapsing nested namespace. We filed a feedback for the tool T180254030 and the team filed a bug for this: https://github.com/llvm/llvm-project/issues/83452. At the same time, they suggested us to run the modernizer tool ourselves so future auto codemod attempts will be smaller. This diff contains: Running `xplat/scripts/codemod_service/cpp_modernizer.sh` in fbcode/internal_repo_rocksdb/repo (excluding some directories in utilities/transactions/lock/range/range_tree/lib that has a non meta copyright comment) without swapping out the namespace macro `ROCKSDB_NAMESPACE` Followed by RocksDB's own `make format` Pull Request resolved: https://github.com/facebook/rocksdb/pull/12398 Test Plan: Auto tests Reviewed By: hx235 Differential Revision: D54382532 Pulled By: jowlyzhang fbshipit-source-id: e7d5b40f9b113b60e5a503558c181f080b9d02fa
522 lines
18 KiB
C++
522 lines
18 KiB
C++
// Copyright (c) 2011-present, Facebook, Inc. All rights reserved.
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// This source code is licensed under both the GPLv2 (found in the
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// COPYING file in the root directory) and Apache 2.0 License
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// (found in the LICENSE.Apache file in the root directory).
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//
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// Copyright (c) 2011 The LevelDB Authors. All rights reserved.
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// Use of this source code is governed by a BSD-style license that can be
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// found in the LICENSE file. See the AUTHORS file for names of contributors.
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#include "util/thread_local.h"
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#include <cstdlib>
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#include "port/likely.h"
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#include "util/mutexlock.h"
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namespace ROCKSDB_NAMESPACE {
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struct Entry {
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Entry() : ptr(nullptr) {}
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Entry(const Entry& e) : ptr(e.ptr.load(std::memory_order_relaxed)) {}
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std::atomic<void*> ptr;
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};
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class StaticMeta;
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// This is the structure that is declared as "thread_local" storage.
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// The vector keep list of atomic pointer for all instances for "current"
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// thread. The vector is indexed by an Id that is unique in process and
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// associated with one ThreadLocalPtr instance. The Id is assigned by a
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// global StaticMeta singleton. So if we instantiated 3 ThreadLocalPtr
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// instances, each thread will have a ThreadData with a vector of size 3:
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// ---------------------------------------------------
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// | | instance 1 | instance 2 | instance 3 |
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// ---------------------------------------------------
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// | thread 1 | void* | void* | void* | <- ThreadData
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// ---------------------------------------------------
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// | thread 2 | void* | void* | void* | <- ThreadData
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// ---------------------------------------------------
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// | thread 3 | void* | void* | void* | <- ThreadData
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// ---------------------------------------------------
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struct ThreadData {
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explicit ThreadData(ThreadLocalPtr::StaticMeta* _inst)
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: entries(), next(nullptr), prev(nullptr), inst(_inst) {}
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std::vector<Entry> entries;
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ThreadData* next;
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ThreadData* prev;
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ThreadLocalPtr::StaticMeta* inst;
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};
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class ThreadLocalPtr::StaticMeta {
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public:
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StaticMeta();
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// Return the next available Id
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uint32_t GetId();
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// Return the next available Id without claiming it
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uint32_t PeekId() const;
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// Return the given Id back to the free pool. This also triggers
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// UnrefHandler for associated pointer value (if not NULL) for all threads.
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void ReclaimId(uint32_t id);
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// Return the pointer value for the given id for the current thread.
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void* Get(uint32_t id) const;
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// Reset the pointer value for the given id for the current thread.
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void Reset(uint32_t id, void* ptr);
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// Atomically swap the supplied ptr and return the previous value
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void* Swap(uint32_t id, void* ptr);
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// Atomically compare and swap the provided value only if it equals
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// to expected value.
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bool CompareAndSwap(uint32_t id, void* ptr, void*& expected);
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// Reset all thread local data to replacement, and return non-nullptr
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// data for all existing threads
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void Scrape(uint32_t id, autovector<void*>* ptrs, void* const replacement);
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// Update res by applying func on each thread-local value. Holds a lock that
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// prevents unref handler from running during this call, but clients must
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// still provide external synchronization since the owning thread can
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// access the values without internal locking, e.g., via Get() and Reset().
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void Fold(uint32_t id, FoldFunc func, void* res);
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// Register the UnrefHandler for id
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void SetHandler(uint32_t id, UnrefHandler handler);
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// protect inst, next_instance_id_, free_instance_ids_, head_,
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// ThreadData.entries
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//
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// Note that here we prefer function static variable instead of the usual
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// global static variable. The reason is that c++ destruction order of
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// static variables in the reverse order of their construction order.
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// However, C++ does not guarantee any construction order when global
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// static variables are defined in different files, while the function
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// static variables are initialized when their function are first called.
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// As a result, the construction order of the function static variables
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// can be controlled by properly invoke their first function calls in
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// the right order.
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//
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// For instance, the following function contains a function static
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// variable. We place a dummy function call of this inside
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// Env::Default() to ensure the construction order of the construction
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// order.
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static port::Mutex* Mutex();
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// Returns the member mutex of the current StaticMeta. In general,
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// Mutex() should be used instead of this one. However, in case where
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// the static variable inside Instance() goes out of scope, MemberMutex()
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// should be used. One example is OnThreadExit() function.
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port::Mutex* MemberMutex() { return &mutex_; }
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private:
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// Get UnrefHandler for id with acquiring mutex
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// REQUIRES: mutex locked
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UnrefHandler GetHandler(uint32_t id);
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// Triggered before a thread terminates
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static void OnThreadExit(void* ptr);
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// Add current thread's ThreadData to the global chain
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// REQUIRES: mutex locked
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void AddThreadData(ThreadData* d);
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// Remove current thread's ThreadData from the global chain
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// REQUIRES: mutex locked
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void RemoveThreadData(ThreadData* d);
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static ThreadData* GetThreadLocal();
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uint32_t next_instance_id_;
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// Used to recycle Ids in case ThreadLocalPtr is instantiated and destroyed
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// frequently. This also prevents it from blowing up the vector space.
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autovector<uint32_t> free_instance_ids_;
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// Chain all thread local structure together. This is necessary since
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// when one ThreadLocalPtr gets destroyed, we need to loop over each
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// thread's version of pointer corresponding to that instance and
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// call UnrefHandler for it.
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ThreadData head_;
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std::unordered_map<uint32_t, UnrefHandler> handler_map_;
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// The private mutex. Developers should always use Mutex() instead of
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// using this variable directly.
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port::Mutex mutex_;
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// Thread local storage
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static thread_local ThreadData* tls_;
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// Used to make thread exit trigger possible if !defined(OS_MACOSX).
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// Otherwise, used to retrieve thread data.
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pthread_key_t pthread_key_;
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};
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thread_local ThreadData* ThreadLocalPtr::StaticMeta::tls_ = nullptr;
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// Windows doesn't support a per-thread destructor with its
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// TLS primitives. So, we build it manually by inserting a
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// function to be called on each thread's exit.
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// See http://www.codeproject.com/Articles/8113/Thread-Local-Storage-The-C-Way
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// and http://www.nynaeve.net/?p=183
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//
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// really we do this to have clear conscience since using TLS with thread-pools
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// is iffy
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// although OK within a request. But otherwise, threads have no identity in its
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// modern use.
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// This runs on windows only called from the System Loader
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#ifdef OS_WIN
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// Windows cleanup routine is invoked from a System Loader with a different
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// signature so we can not directly hookup the original OnThreadExit which is
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// private member
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// so we make StaticMeta class share with the us the address of the function so
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// we can invoke it.
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namespace wintlscleanup {
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// This is set to OnThreadExit in StaticMeta singleton constructor
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UnrefHandler thread_local_inclass_routine = nullptr;
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pthread_key_t thread_local_key = pthread_key_t(-1);
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// Static callback function to call with each thread termination.
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void NTAPI WinOnThreadExit(PVOID module, DWORD reason, PVOID reserved) {
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// We decided to punt on PROCESS_EXIT
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if (DLL_THREAD_DETACH == reason) {
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if (thread_local_key != pthread_key_t(-1) &&
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thread_local_inclass_routine != nullptr) {
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void* tls = TlsGetValue(thread_local_key);
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if (tls != nullptr) {
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thread_local_inclass_routine(tls);
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}
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}
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}
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}
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} // namespace wintlscleanup
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// extern "C" suppresses C++ name mangling so we know the symbol name for the
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// linker /INCLUDE:symbol pragma above.
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extern "C" {
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#ifdef _MSC_VER
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// The linker must not discard thread_callback_on_exit. (We force a reference
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// to this variable with a linker /include:symbol pragma to ensure that.) If
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// this variable is discarded, the OnThreadExit function will never be called.
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#ifndef _X86_
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// .CRT section is merged with .rdata on x64 so it must be constant data.
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#pragma const_seg(".CRT$XLB")
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// When defining a const variable, it must have external linkage to be sure the
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// linker doesn't discard it.
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extern const PIMAGE_TLS_CALLBACK p_thread_callback_on_exit;
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const PIMAGE_TLS_CALLBACK p_thread_callback_on_exit =
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wintlscleanup::WinOnThreadExit;
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// Reset the default section.
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#pragma const_seg()
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#pragma comment(linker, "/include:_tls_used")
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#pragma comment(linker, "/include:p_thread_callback_on_exit")
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#else // _X86_
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#pragma data_seg(".CRT$XLB")
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PIMAGE_TLS_CALLBACK p_thread_callback_on_exit = wintlscleanup::WinOnThreadExit;
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// Reset the default section.
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#pragma data_seg()
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#pragma comment(linker, "/INCLUDE:__tls_used")
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#pragma comment(linker, "/INCLUDE:_p_thread_callback_on_exit")
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#endif // _X86_
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#else
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// https://github.com/couchbase/gperftools/blob/master/src/windows/port.cc
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BOOL WINAPI DllMain(HINSTANCE h, DWORD dwReason, PVOID pv) {
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if (dwReason == DLL_THREAD_DETACH)
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wintlscleanup::WinOnThreadExit(h, dwReason, pv);
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return TRUE;
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}
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#endif
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} // extern "C"
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#endif // OS_WIN
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void ThreadLocalPtr::InitSingletons() { ThreadLocalPtr::Instance(); }
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ThreadLocalPtr::StaticMeta* ThreadLocalPtr::Instance() {
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// Here we prefer function static variable instead of global
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// static variable as function static variable is initialized
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// when the function is first call. As a result, we can properly
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// control their construction order by properly preparing their
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// first function call.
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//
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// Note that here we decide to make "inst" a static pointer w/o deleting
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// it at the end instead of a static variable. This is to avoid the following
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// destruction order disaster happens when a child thread using ThreadLocalPtr
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// dies AFTER the main thread dies: When a child thread happens to use
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// ThreadLocalPtr, it will try to delete its thread-local data on its
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// OnThreadExit when the child thread dies. However, OnThreadExit depends
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// on the following variable. As a result, if the main thread dies before any
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// child thread happen to use ThreadLocalPtr dies, then the destruction of
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// the following variable will go first, then OnThreadExit, therefore causing
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// invalid access.
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//
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// The above problem can be solved by using thread_local to store tls_.
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// thread_local supports dynamic construction and destruction of
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// non-primitive typed variables. As a result, we can guarantee the
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// destruction order even when the main thread dies before any child threads.
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static ThreadLocalPtr::StaticMeta* inst = new ThreadLocalPtr::StaticMeta();
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return inst;
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}
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port::Mutex* ThreadLocalPtr::StaticMeta::Mutex() { return &Instance()->mutex_; }
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void ThreadLocalPtr::StaticMeta::OnThreadExit(void* ptr) {
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auto* tls = static_cast<ThreadData*>(ptr);
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assert(tls != nullptr);
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// Use the cached StaticMeta::Instance() instead of directly calling
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// the variable inside StaticMeta::Instance() might already go out of
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// scope here in case this OnThreadExit is called after the main thread
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// dies.
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auto* inst = tls->inst;
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pthread_setspecific(inst->pthread_key_, nullptr);
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MutexLock l(inst->MemberMutex());
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inst->RemoveThreadData(tls);
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// Unref stored pointers of current thread from all instances
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uint32_t id = 0;
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for (auto& e : tls->entries) {
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void* raw = e.ptr.load();
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if (raw != nullptr) {
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auto unref = inst->GetHandler(id);
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if (unref != nullptr) {
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unref(raw);
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}
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}
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++id;
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}
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// Delete thread local structure no matter if it is Mac platform
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delete tls;
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}
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ThreadLocalPtr::StaticMeta::StaticMeta()
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: next_instance_id_(0), head_(this), pthread_key_(0) {
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if (pthread_key_create(&pthread_key_, &OnThreadExit) != 0) {
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abort();
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}
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// OnThreadExit is not getting called on the main thread.
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// Call through the static destructor mechanism to avoid memory leak.
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//
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// Caveats: ~A() will be invoked _after_ ~StaticMeta for the global
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// singleton (destructors are invoked in reverse order of constructor
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// _completion_); the latter must not mutate internal members. This
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// cleanup mechanism inherently relies on use-after-release of the
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// StaticMeta, and is brittle with respect to compiler-specific handling
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// of memory backing destructed statically-scoped objects. Perhaps
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// registering with atexit(3) would be more robust.
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//
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// This is not required on Windows.
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#if !defined(OS_WIN)
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static struct A {
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~A() {
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if (tls_) {
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OnThreadExit(tls_);
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}
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}
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} a;
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#endif // !defined(OS_WIN)
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head_.next = &head_;
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head_.prev = &head_;
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#ifdef OS_WIN
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// Share with Windows its cleanup routine and the key
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wintlscleanup::thread_local_inclass_routine = OnThreadExit;
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wintlscleanup::thread_local_key = pthread_key_;
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#endif
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}
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void ThreadLocalPtr::StaticMeta::AddThreadData(ThreadData* d) {
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Mutex()->AssertHeld();
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d->next = &head_;
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d->prev = head_.prev;
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head_.prev->next = d;
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head_.prev = d;
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}
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void ThreadLocalPtr::StaticMeta::RemoveThreadData(ThreadData* d) {
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Mutex()->AssertHeld();
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d->next->prev = d->prev;
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d->prev->next = d->next;
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d->next = d->prev = d;
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}
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ThreadData* ThreadLocalPtr::StaticMeta::GetThreadLocal() {
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if (UNLIKELY(tls_ == nullptr)) {
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auto* inst = Instance();
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tls_ = new ThreadData(inst);
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{
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// Register it in the global chain, needs to be done before thread exit
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// handler registration
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MutexLock l(Mutex());
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inst->AddThreadData(tls_);
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}
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// Even it is not OS_MACOSX, need to register value for pthread_key_ so that
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// its exit handler will be triggered.
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if (pthread_setspecific(inst->pthread_key_, tls_) != 0) {
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{
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MutexLock l(Mutex());
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inst->RemoveThreadData(tls_);
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}
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delete tls_;
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abort();
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}
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}
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return tls_;
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}
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void* ThreadLocalPtr::StaticMeta::Get(uint32_t id) const {
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auto* tls = GetThreadLocal();
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if (UNLIKELY(id >= tls->entries.size())) {
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return nullptr;
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}
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return tls->entries[id].ptr.load(std::memory_order_acquire);
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}
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void ThreadLocalPtr::StaticMeta::Reset(uint32_t id, void* ptr) {
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auto* tls = GetThreadLocal();
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if (UNLIKELY(id >= tls->entries.size())) {
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// Need mutex to protect entries access within ReclaimId
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MutexLock l(Mutex());
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tls->entries.resize(id + 1);
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}
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tls->entries[id].ptr.store(ptr, std::memory_order_release);
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}
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void* ThreadLocalPtr::StaticMeta::Swap(uint32_t id, void* ptr) {
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auto* tls = GetThreadLocal();
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if (UNLIKELY(id >= tls->entries.size())) {
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// Need mutex to protect entries access within ReclaimId
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MutexLock l(Mutex());
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tls->entries.resize(id + 1);
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}
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return tls->entries[id].ptr.exchange(ptr, std::memory_order_acquire);
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}
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bool ThreadLocalPtr::StaticMeta::CompareAndSwap(uint32_t id, void* ptr,
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void*& expected) {
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auto* tls = GetThreadLocal();
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if (UNLIKELY(id >= tls->entries.size())) {
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// Need mutex to protect entries access within ReclaimId
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MutexLock l(Mutex());
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tls->entries.resize(id + 1);
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}
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return tls->entries[id].ptr.compare_exchange_strong(
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expected, ptr, std::memory_order_release, std::memory_order_relaxed);
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}
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void ThreadLocalPtr::StaticMeta::Scrape(uint32_t id, autovector<void*>* ptrs,
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void* const replacement) {
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MutexLock l(Mutex());
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for (ThreadData* t = head_.next; t != &head_; t = t->next) {
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if (id < t->entries.size()) {
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void* ptr =
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t->entries[id].ptr.exchange(replacement, std::memory_order_acquire);
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if (ptr != nullptr) {
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ptrs->push_back(ptr);
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}
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}
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}
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}
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void ThreadLocalPtr::StaticMeta::Fold(uint32_t id, FoldFunc func, void* res) {
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MutexLock l(Mutex());
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for (ThreadData* t = head_.next; t != &head_; t = t->next) {
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if (id < t->entries.size()) {
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void* ptr = t->entries[id].ptr.load();
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if (ptr != nullptr) {
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func(ptr, res);
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}
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}
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}
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}
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uint32_t ThreadLocalPtr::TEST_PeekId() { return Instance()->PeekId(); }
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void ThreadLocalPtr::StaticMeta::SetHandler(uint32_t id, UnrefHandler handler) {
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MutexLock l(Mutex());
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handler_map_[id] = handler;
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}
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UnrefHandler ThreadLocalPtr::StaticMeta::GetHandler(uint32_t id) {
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Mutex()->AssertHeld();
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auto iter = handler_map_.find(id);
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if (iter == handler_map_.end()) {
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return nullptr;
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}
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return iter->second;
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}
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uint32_t ThreadLocalPtr::StaticMeta::GetId() {
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MutexLock l(Mutex());
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if (free_instance_ids_.empty()) {
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return next_instance_id_++;
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}
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uint32_t id = free_instance_ids_.back();
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free_instance_ids_.pop_back();
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return id;
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}
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uint32_t ThreadLocalPtr::StaticMeta::PeekId() const {
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MutexLock l(Mutex());
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if (!free_instance_ids_.empty()) {
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return free_instance_ids_.back();
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}
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return next_instance_id_;
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}
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void ThreadLocalPtr::StaticMeta::ReclaimId(uint32_t id) {
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// This id is not used, go through all thread local data and release
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// corresponding value
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MutexLock l(Mutex());
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auto unref = GetHandler(id);
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for (ThreadData* t = head_.next; t != &head_; t = t->next) {
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if (id < t->entries.size()) {
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void* ptr = t->entries[id].ptr.exchange(nullptr);
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if (ptr != nullptr && unref != nullptr) {
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|
unref(ptr);
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}
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}
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}
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handler_map_[id] = nullptr;
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free_instance_ids_.push_back(id);
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}
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ThreadLocalPtr::ThreadLocalPtr(UnrefHandler handler)
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: id_(Instance()->GetId()) {
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if (handler != nullptr) {
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Instance()->SetHandler(id_, handler);
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|
}
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|
}
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|
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ThreadLocalPtr::~ThreadLocalPtr() { Instance()->ReclaimId(id_); }
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|
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void* ThreadLocalPtr::Get() const { return Instance()->Get(id_); }
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|
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void ThreadLocalPtr::Reset(void* ptr) { Instance()->Reset(id_, ptr); }
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|
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void* ThreadLocalPtr::Swap(void* ptr) { return Instance()->Swap(id_, ptr); }
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bool ThreadLocalPtr::CompareAndSwap(void* ptr, void*& expected) {
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|
return Instance()->CompareAndSwap(id_, ptr, expected);
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|
}
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|
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void ThreadLocalPtr::Scrape(autovector<void*>* ptrs, void* const replacement) {
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Instance()->Scrape(id_, ptrs, replacement);
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}
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|
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void ThreadLocalPtr::Fold(FoldFunc func, void* res) {
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Instance()->Fold(id_, func, res);
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|
}
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} // namespace ROCKSDB_NAMESPACE
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