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annotate osx/include/kj/mutex.h @ 140:59a8758c56b1

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Add source for PortAudio stable v190600_20161030
author Chris Cannam <cannam@all-day-breakfast.com>
date Tue, 03 Jan 2017 13:44:07 +0000
parents 41e769c91eca
children 0994c39f1e94
rev   line source
cannam@134 1 // Copyright (c) 2013-2014 Sandstorm Development Group, Inc. and contributors
cannam@134 2 // Licensed under the MIT License:
cannam@134 3 //
cannam@134 4 // Permission is hereby granted, free of charge, to any person obtaining a copy
cannam@134 5 // of this software and associated documentation files (the "Software"), to deal
cannam@134 6 // in the Software without restriction, including without limitation the rights
cannam@134 7 // to use, copy, modify, merge, publish, distribute, sublicense, and/or sell
cannam@134 8 // copies of the Software, and to permit persons to whom the Software is
cannam@134 9 // furnished to do so, subject to the following conditions:
cannam@134 10 //
cannam@134 11 // The above copyright notice and this permission notice shall be included in
cannam@134 12 // all copies or substantial portions of the Software.
cannam@134 13 //
cannam@134 14 // THE SOFTWARE IS PROVIDED "AS IS", WITHOUT WARRANTY OF ANY KIND, EXPRESS OR
cannam@134 15 // IMPLIED, INCLUDING BUT NOT LIMITED TO THE WARRANTIES OF MERCHANTABILITY,
cannam@134 16 // FITNESS FOR A PARTICULAR PURPOSE AND NONINFRINGEMENT. IN NO EVENT SHALL THE
cannam@134 17 // AUTHORS OR COPYRIGHT HOLDERS BE LIABLE FOR ANY CLAIM, DAMAGES OR OTHER
cannam@134 18 // LIABILITY, WHETHER IN AN ACTION OF CONTRACT, TORT OR OTHERWISE, ARISING FROM,
cannam@134 19 // OUT OF OR IN CONNECTION WITH THE SOFTWARE OR THE USE OR OTHER DEALINGS IN
cannam@134 20 // THE SOFTWARE.
cannam@134 21
cannam@134 22 #ifndef KJ_MUTEX_H_
cannam@134 23 #define KJ_MUTEX_H_
cannam@134 24
cannam@134 25 #if defined(__GNUC__) && !KJ_HEADER_WARNINGS
cannam@134 26 #pragma GCC system_header
cannam@134 27 #endif
cannam@134 28
cannam@134 29 #include "memory.h"
cannam@134 30 #include <inttypes.h>
cannam@134 31
cannam@134 32 #if __linux__ && !defined(KJ_USE_FUTEX)
cannam@134 33 #define KJ_USE_FUTEX 1
cannam@134 34 #endif
cannam@134 35
cannam@134 36 #if !KJ_USE_FUTEX && !_WIN32
cannam@134 37 // On Linux we use futex. On other platforms we wrap pthreads.
cannam@134 38 // TODO(someday): Write efficient low-level locking primitives for other platforms.
cannam@134 39 #include <pthread.h>
cannam@134 40 #endif
cannam@134 41
cannam@134 42 namespace kj {
cannam@134 43
cannam@134 44 // =======================================================================================
cannam@134 45 // Private details -- public interfaces follow below.
cannam@134 46
cannam@134 47 namespace _ { // private
cannam@134 48
cannam@134 49 class Mutex {
cannam@134 50 // Internal implementation details. See `MutexGuarded<T>`.
cannam@134 51
cannam@134 52 public:
cannam@134 53 Mutex();
cannam@134 54 ~Mutex();
cannam@134 55 KJ_DISALLOW_COPY(Mutex);
cannam@134 56
cannam@134 57 enum Exclusivity {
cannam@134 58 EXCLUSIVE,
cannam@134 59 SHARED
cannam@134 60 };
cannam@134 61
cannam@134 62 void lock(Exclusivity exclusivity);
cannam@134 63 void unlock(Exclusivity exclusivity);
cannam@134 64
cannam@134 65 void assertLockedByCaller(Exclusivity exclusivity);
cannam@134 66 // In debug mode, assert that the mutex is locked by the calling thread, or if that is
cannam@134 67 // non-trivial, assert that the mutex is locked (which should be good enough to catch problems
cannam@134 68 // in unit tests). In non-debug builds, do nothing.
cannam@134 69
cannam@134 70 private:
cannam@134 71 #if KJ_USE_FUTEX
cannam@134 72 uint futex;
cannam@134 73 // bit 31 (msb) = set if exclusive lock held
cannam@134 74 // bit 30 (msb) = set if threads are waiting for exclusive lock
cannam@134 75 // bits 0-29 = count of readers; If an exclusive lock is held, this is the count of threads
cannam@134 76 // waiting for a read lock, otherwise it is the count of threads that currently hold a read
cannam@134 77 // lock.
cannam@134 78
cannam@134 79 static constexpr uint EXCLUSIVE_HELD = 1u << 31;
cannam@134 80 static constexpr uint EXCLUSIVE_REQUESTED = 1u << 30;
cannam@134 81 static constexpr uint SHARED_COUNT_MASK = EXCLUSIVE_REQUESTED - 1;
cannam@134 82
cannam@134 83 #elif _WIN32
cannam@134 84 uintptr_t srwLock; // Actually an SRWLOCK, but don't want to #include <windows.h> in header.
cannam@134 85
cannam@134 86 #else
cannam@134 87 mutable pthread_rwlock_t mutex;
cannam@134 88 #endif
cannam@134 89 };
cannam@134 90
cannam@134 91 class Once {
cannam@134 92 // Internal implementation details. See `Lazy<T>`.
cannam@134 93
cannam@134 94 public:
cannam@134 95 #if KJ_USE_FUTEX
cannam@134 96 inline Once(bool startInitialized = false)
cannam@134 97 : futex(startInitialized ? INITIALIZED : UNINITIALIZED) {}
cannam@134 98 #else
cannam@134 99 Once(bool startInitialized = false);
cannam@134 100 ~Once();
cannam@134 101 #endif
cannam@134 102 KJ_DISALLOW_COPY(Once);
cannam@134 103
cannam@134 104 class Initializer {
cannam@134 105 public:
cannam@134 106 virtual void run() = 0;
cannam@134 107 };
cannam@134 108
cannam@134 109 void runOnce(Initializer& init);
cannam@134 110
cannam@134 111 #if _WIN32 // TODO(perf): Can we make this inline on win32 somehow?
cannam@134 112 bool isInitialized() noexcept;
cannam@134 113
cannam@134 114 #else
cannam@134 115 inline bool isInitialized() noexcept {
cannam@134 116 // Fast path check to see if runOnce() would simply return immediately.
cannam@134 117 #if KJ_USE_FUTEX
cannam@134 118 return __atomic_load_n(&futex, __ATOMIC_ACQUIRE) == INITIALIZED;
cannam@134 119 #else
cannam@134 120 return __atomic_load_n(&state, __ATOMIC_ACQUIRE) == INITIALIZED;
cannam@134 121 #endif
cannam@134 122 }
cannam@134 123 #endif
cannam@134 124
cannam@134 125 void reset();
cannam@134 126 // Returns the state from initialized to uninitialized. It is an error to call this when
cannam@134 127 // not already initialized, or when runOnce() or isInitialized() might be called concurrently in
cannam@134 128 // another thread.
cannam@134 129
cannam@134 130 private:
cannam@134 131 #if KJ_USE_FUTEX
cannam@134 132 uint futex;
cannam@134 133
cannam@134 134 enum State {
cannam@134 135 UNINITIALIZED,
cannam@134 136 INITIALIZING,
cannam@134 137 INITIALIZING_WITH_WAITERS,
cannam@134 138 INITIALIZED
cannam@134 139 };
cannam@134 140
cannam@134 141 #elif _WIN32
cannam@134 142 uintptr_t initOnce; // Actually an INIT_ONCE, but don't want to #include <windows.h> in header.
cannam@134 143
cannam@134 144 #else
cannam@134 145 enum State {
cannam@134 146 UNINITIALIZED,
cannam@134 147 INITIALIZED
cannam@134 148 };
cannam@134 149 State state;
cannam@134 150 pthread_mutex_t mutex;
cannam@134 151 #endif
cannam@134 152 };
cannam@134 153
cannam@134 154 } // namespace _ (private)
cannam@134 155
cannam@134 156 // =======================================================================================
cannam@134 157 // Public interface
cannam@134 158
cannam@134 159 template <typename T>
cannam@134 160 class Locked {
cannam@134 161 // Return type for `MutexGuarded<T>::lock()`. `Locked<T>` provides access to the guarded object
cannam@134 162 // and unlocks the mutex when it goes out of scope.
cannam@134 163
cannam@134 164 public:
cannam@134 165 KJ_DISALLOW_COPY(Locked);
cannam@134 166 inline Locked(): mutex(nullptr), ptr(nullptr) {}
cannam@134 167 inline Locked(Locked&& other): mutex(other.mutex), ptr(other.ptr) {
cannam@134 168 other.mutex = nullptr;
cannam@134 169 other.ptr = nullptr;
cannam@134 170 }
cannam@134 171 inline ~Locked() {
cannam@134 172 if (mutex != nullptr) mutex->unlock(isConst<T>() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE);
cannam@134 173 }
cannam@134 174
cannam@134 175 inline Locked& operator=(Locked&& other) {
cannam@134 176 if (mutex != nullptr) mutex->unlock(isConst<T>() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE);
cannam@134 177 mutex = other.mutex;
cannam@134 178 ptr = other.ptr;
cannam@134 179 other.mutex = nullptr;
cannam@134 180 other.ptr = nullptr;
cannam@134 181 return *this;
cannam@134 182 }
cannam@134 183
cannam@134 184 inline void release() {
cannam@134 185 if (mutex != nullptr) mutex->unlock(isConst<T>() ? _::Mutex::SHARED : _::Mutex::EXCLUSIVE);
cannam@134 186 mutex = nullptr;
cannam@134 187 ptr = nullptr;
cannam@134 188 }
cannam@134 189
cannam@134 190 inline T* operator->() { return ptr; }
cannam@134 191 inline const T* operator->() const { return ptr; }
cannam@134 192 inline T& operator*() { return *ptr; }
cannam@134 193 inline const T& operator*() const { return *ptr; }
cannam@134 194 inline T* get() { return ptr; }
cannam@134 195 inline const T* get() const { return ptr; }
cannam@134 196 inline operator T*() { return ptr; }
cannam@134 197 inline operator const T*() const { return ptr; }
cannam@134 198
cannam@134 199 private:
cannam@134 200 _::Mutex* mutex;
cannam@134 201 T* ptr;
cannam@134 202
cannam@134 203 inline Locked(_::Mutex& mutex, T& value): mutex(&mutex), ptr(&value) {}
cannam@134 204
cannam@134 205 template <typename U>
cannam@134 206 friend class MutexGuarded;
cannam@134 207 };
cannam@134 208
cannam@134 209 template <typename T>
cannam@134 210 class MutexGuarded {
cannam@134 211 // An object of type T, guarded by a mutex. In order to access the object, you must lock it.
cannam@134 212 //
cannam@134 213 // Write locks are not "recursive" -- trying to lock again in a thread that already holds a lock
cannam@134 214 // will deadlock. Recursive write locks are usually a sign of bad design.
cannam@134 215 //
cannam@134 216 // Unfortunately, **READ LOCKS ARE NOT RECURSIVE** either. Common sense says they should be.
cannam@134 217 // But on many operating systems (BSD, OSX), recursively read-locking a pthread_rwlock is
cannam@134 218 // actually unsafe. The problem is that writers are "prioritized" over readers, so a read lock
cannam@134 219 // request will block if any write lock requests are outstanding. So, if thread A takes a read
cannam@134 220 // lock, thread B requests a write lock (and starts waiting), and then thread A tries to take
cannam@134 221 // another read lock recursively, the result is deadlock.
cannam@134 222
cannam@134 223 public:
cannam@134 224 template <typename... Params>
cannam@134 225 explicit MutexGuarded(Params&&... params);
cannam@134 226 // Initialize the mutex-guarded object by passing the given parameters to its constructor.
cannam@134 227
cannam@134 228 Locked<T> lockExclusive() const;
cannam@134 229 // Exclusively locks the object and returns it. The returned `Locked<T>` can be passed by
cannam@134 230 // move, similar to `Own<T>`.
cannam@134 231 //
cannam@134 232 // This method is declared `const` in accordance with KJ style rules which say that constness
cannam@134 233 // should be used to indicate thread-safety. It is safe to share a const pointer between threads,
cannam@134 234 // but it is not safe to share a mutable pointer. Since the whole point of MutexGuarded is to
cannam@134 235 // be shared between threads, its methods should be const, even though locking it produces a
cannam@134 236 // non-const pointer to the contained object.
cannam@134 237
cannam@134 238 Locked<const T> lockShared() const;
cannam@134 239 // Lock the value for shared access. Multiple shared locks can be taken concurrently, but cannot
cannam@134 240 // be held at the same time as a non-shared lock.
cannam@134 241
cannam@134 242 inline const T& getWithoutLock() const { return value; }
cannam@134 243 inline T& getWithoutLock() { return value; }
cannam@134 244 // Escape hatch for cases where some external factor guarantees that it's safe to get the
cannam@134 245 // value. You should treat these like const_cast -- be highly suspicious of any use.
cannam@134 246
cannam@134 247 inline const T& getAlreadyLockedShared() const;
cannam@134 248 inline T& getAlreadyLockedShared();
cannam@134 249 inline T& getAlreadyLockedExclusive() const;
cannam@134 250 // Like `getWithoutLock()`, but asserts that the lock is already held by the calling thread.
cannam@134 251
cannam@134 252 private:
cannam@134 253 mutable _::Mutex mutex;
cannam@134 254 mutable T value;
cannam@134 255 };
cannam@134 256
cannam@134 257 template <typename T>
cannam@134 258 class MutexGuarded<const T> {
cannam@134 259 // MutexGuarded cannot guard a const type. This would be pointless anyway, and would complicate
cannam@134 260 // the implementation of Locked<T>, which uses constness to decide what kind of lock it holds.
cannam@134 261 static_assert(sizeof(T) < 0, "MutexGuarded's type cannot be const.");
cannam@134 262 };
cannam@134 263
cannam@134 264 template <typename T>
cannam@134 265 class Lazy {
cannam@134 266 // A lazily-initialized value.
cannam@134 267
cannam@134 268 public:
cannam@134 269 template <typename Func>
cannam@134 270 T& get(Func&& init);
cannam@134 271 template <typename Func>
cannam@134 272 const T& get(Func&& init) const;
cannam@134 273 // The first thread to call get() will invoke the given init function to construct the value.
cannam@134 274 // Other threads will block until construction completes, then return the same value.
cannam@134 275 //
cannam@134 276 // `init` is a functor(typically a lambda) which takes `SpaceFor<T>&` as its parameter and returns
cannam@134 277 // `Own<T>`. If `init` throws an exception, the exception is propagated out of that thread's
cannam@134 278 // call to `get()`, and subsequent calls behave as if `get()` hadn't been called at all yet --
cannam@134 279 // in other words, subsequent calls retry initialization until it succeeds.
cannam@134 280
cannam@134 281 private:
cannam@134 282 mutable _::Once once;
cannam@134 283 mutable SpaceFor<T> space;
cannam@134 284 mutable Own<T> value;
cannam@134 285
cannam@134 286 template <typename Func>
cannam@134 287 class InitImpl;
cannam@134 288 };
cannam@134 289
cannam@134 290 // =======================================================================================
cannam@134 291 // Inline implementation details
cannam@134 292
cannam@134 293 template <typename T>
cannam@134 294 template <typename... Params>
cannam@134 295 inline MutexGuarded<T>::MutexGuarded(Params&&... params)
cannam@134 296 : value(kj::fwd<Params>(params)...) {}
cannam@134 297
cannam@134 298 template <typename T>
cannam@134 299 inline Locked<T> MutexGuarded<T>::lockExclusive() const {
cannam@134 300 mutex.lock(_::Mutex::EXCLUSIVE);
cannam@134 301 return Locked<T>(mutex, value);
cannam@134 302 }
cannam@134 303
cannam@134 304 template <typename T>
cannam@134 305 inline Locked<const T> MutexGuarded<T>::lockShared() const {
cannam@134 306 mutex.lock(_::Mutex::SHARED);
cannam@134 307 return Locked<const T>(mutex, value);
cannam@134 308 }
cannam@134 309
cannam@134 310 template <typename T>
cannam@134 311 inline const T& MutexGuarded<T>::getAlreadyLockedShared() const {
cannam@134 312 #ifdef KJ_DEBUG
cannam@134 313 mutex.assertLockedByCaller(_::Mutex::SHARED);
cannam@134 314 #endif
cannam@134 315 return value;
cannam@134 316 }
cannam@134 317 template <typename T>
cannam@134 318 inline T& MutexGuarded<T>::getAlreadyLockedShared() {
cannam@134 319 #ifdef KJ_DEBUG
cannam@134 320 mutex.assertLockedByCaller(_::Mutex::SHARED);
cannam@134 321 #endif
cannam@134 322 return value;
cannam@134 323 }
cannam@134 324 template <typename T>
cannam@134 325 inline T& MutexGuarded<T>::getAlreadyLockedExclusive() const {
cannam@134 326 #ifdef KJ_DEBUG
cannam@134 327 mutex.assertLockedByCaller(_::Mutex::EXCLUSIVE);
cannam@134 328 #endif
cannam@134 329 return const_cast<T&>(value);
cannam@134 330 }
cannam@134 331
cannam@134 332 template <typename T>
cannam@134 333 template <typename Func>
cannam@134 334 class Lazy<T>::InitImpl: public _::Once::Initializer {
cannam@134 335 public:
cannam@134 336 inline InitImpl(const Lazy<T>& lazy, Func&& func): lazy(lazy), func(kj::fwd<Func>(func)) {}
cannam@134 337
cannam@134 338 void run() override {
cannam@134 339 lazy.value = func(lazy.space);
cannam@134 340 }
cannam@134 341
cannam@134 342 private:
cannam@134 343 const Lazy<T>& lazy;
cannam@134 344 Func func;
cannam@134 345 };
cannam@134 346
cannam@134 347 template <typename T>
cannam@134 348 template <typename Func>
cannam@134 349 inline T& Lazy<T>::get(Func&& init) {
cannam@134 350 if (!once.isInitialized()) {
cannam@134 351 InitImpl<Func> initImpl(*this, kj::fwd<Func>(init));
cannam@134 352 once.runOnce(initImpl);
cannam@134 353 }
cannam@134 354 return *value;
cannam@134 355 }
cannam@134 356
cannam@134 357 template <typename T>
cannam@134 358 template <typename Func>
cannam@134 359 inline const T& Lazy<T>::get(Func&& init) const {
cannam@134 360 if (!once.isInitialized()) {
cannam@134 361 InitImpl<Func> initImpl(*this, kj::fwd<Func>(init));
cannam@134 362 once.runOnce(initImpl);
cannam@134 363 }
cannam@134 364 return *value;
cannam@134 365 }
cannam@134 366
cannam@134 367 } // namespace kj
cannam@134 368
cannam@134 369 #endif // KJ_MUTEX_H_