bfaa1bd26c
Move thrift api from thrift/leveldb.thrift to thrift/if/leveldb.thrift Summary: Test Plan: Reviewers: CC: Task ID: # Blame Rev:
593 lines
19 KiB
C++
593 lines
19 KiB
C++
/*
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* Licensed to the Apache Software Foundation (ASF) under one
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* or more contributor license agreements. See the NOTICE file
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* distributed with this work for additional information
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* regarding copyright ownership. The ASF licenses this file
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* to you under the Apache License, Version 2.0 (the
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* "License"); you may not use this file except in compliance
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* with the License. You may obtain a copy of the License at
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*
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* http://www.apache.org/licenses/LICENSE-2.0
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*
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* Unless required by applicable law or agreed to in writing,
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* software distributed under the License is distributed on an
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* "AS IS" BASIS, WITHOUT WARRANTIES OR CONDITIONS OF ANY
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* KIND, either express or implied. See the License for the
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* specific language governing permissions and limitations
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* under the License.
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*/
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#ifndef THRIFT_ASYNC_TNOTIFICATIONQUEUE_H_
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#define THRIFT_ASYNC_TNOTIFICATIONQUEUE_H_ 1
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#include "thrift/lib/cpp/Thrift.h"
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#include "thrift/lib/cpp/async/TEventBase.h"
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#include "thrift/lib/cpp/async/TEventHandler.h"
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#include "external/google_base/spinlock.h"
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#include "external/glog/logging.h"
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#include <deque>
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#include "folly/eventfd.h"
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namespace apache { namespace thrift { namespace async {
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/**
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* An exception class to be thrown when a TNotificationQueue is full.
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*/
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class TQueueFullException : public TLibraryException {
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public:
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TQueueFullException() :
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TLibraryException("unable to add message to TNotificationQueue: "
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"queue is full") {}
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};
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/**
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* A producer-consumer queue for passing messages between TEventBase threads.
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*
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* Messages can be added to the queue from any thread. Multiple consumers may
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* listen to the queue from multiple TEventBase threads.
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*
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* A TNotificationQueue may not be destroyed while there are still consumers
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* registered to receive events from the queue. It is the user's
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* responsibility to ensure that all consumers are unregistered before the
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* queue is destroyed.
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*
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* MessageT should be MoveConstructible (i.e., must support either a move
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* constructor or a copy constructor, or both). Ideally it's move constructor
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* (or copy constructor if no move constructor is provided) should never throw
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* exceptions. If the constructor may throw, the consumers could end up
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* spinning trying to move a message off the queue and failing, and then
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* retrying.
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*/
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template<typename MessageT>
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class TNotificationQueue {
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public:
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/**
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* A callback interface for consuming messages from the queue as they arrive.
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*/
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class Consumer : private TEventHandler {
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public:
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enum : uint16_t { kDefaultMaxReadAtOnce = 10 };
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Consumer()
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: queue_(NULL),
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destroyedFlagPtr_(NULL),
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maxReadAtOnce_(kDefaultMaxReadAtOnce) {}
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virtual ~Consumer();
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/**
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* messageAvailable() will be invoked whenever a new
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* message is available from the pipe.
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*/
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virtual void messageAvailable(MessageT&& message) = 0;
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/**
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* Begin consuming messages from the specified queue.
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*
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* messageAvailable() will be called whenever a message is available. This
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* consumer will continue to consume messages until stopConsuming() is
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* called.
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*
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* A Consumer may only consume messages from a single TNotificationQueue at
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* a time. startConsuming() should not be called if this consumer is
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* already consuming.
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*/
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void startConsuming(TEventBase* eventBase, TNotificationQueue* queue) {
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init(eventBase, queue);
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registerHandler(READ | PERSIST);
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}
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/**
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* Same as above but registers this event handler as internal so that it
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* doesn't count towards the pending reader count for the IOLoop.
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*/
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void startConsumingInternal(
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TEventBase* eventBase, TNotificationQueue* queue) {
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init(eventBase, queue);
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registerInternalHandler(READ | PERSIST);
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}
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/**
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* Stop consuming messages.
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*
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* startConsuming() may be called again to resume consumption of messages
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* at a later point in time.
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*/
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void stopConsuming();
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/**
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* Get the TNotificationQueue that this consumer is currently consuming
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* messages from. Returns NULL if the consumer is not currently consuming
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* events from any queue.
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*/
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TNotificationQueue* getCurrentQueue() const {
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return queue_;
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}
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/**
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* Set a limit on how many messages this consumer will read each iteration
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* around the event loop.
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*
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* This helps rate-limit how much work the Consumer will do each event loop
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* iteration, to prevent it from starving other event handlers.
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*
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* A limit of 0 means no limit will be enforced. If unset, the limit
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* defaults to kDefaultMaxReadAtOnce (defined to 10 above).
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*/
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void setMaxReadAtOnce(uint32_t maxAtOnce) {
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maxReadAtOnce_ = maxAtOnce;
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}
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uint32_t getMaxReadAtOnce() const {
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return maxReadAtOnce_;
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}
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private:
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void init(TEventBase* eventBase, TNotificationQueue* queue);
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virtual void handlerReady(uint16_t events) THRIFT_NOEXCEPT;
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TNotificationQueue* queue_;
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bool* destroyedFlagPtr_;
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uint32_t maxReadAtOnce_;
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};
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enum class FdType {
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EVENTFD,
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PIPE
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};
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/**
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* Create a new TNotificationQueue.
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*
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* If the maxSize parameter is specified, this sets the maximum queue size
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* that will be enforced by tryPutMessage(). (This size is advisory, and may
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* be exceeded if producers explicitly use putMessage() instead of
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* tryPutMessage().)
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*
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* The fdType parameter determines the type of file descriptor used
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* internally to signal message availability. The default (eventfd) is
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* preferable for performance and because it won't fail when the queue gets
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* too long. It is not available on on older and non-linux kernels, however.
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* In this case the code will fall back to using a pipe, the parameter is
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* mostly for testing purposes.
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*/
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explicit TNotificationQueue(uint32_t maxSize = 0,
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FdType fdType = FdType::EVENTFD)
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: spinlock_(),
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eventfd_(-1),
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pipeFds_{-1, -1},
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advisoryMaxQueueSize_(maxSize),
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queue_() {
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if (fdType == FdType::EVENTFD) {
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eventfd_ = folly::eventfd(0, EFD_CLOEXEC | EFD_NONBLOCK | EFD_SEMAPHORE);
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if (eventfd_ == -1) {
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if (errno == ENOSYS || errno == EINVAL) {
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// eventfd not availalble
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T_ERROR("failed to create eventfd for TNotificationQueue: %d, "
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"falling back to pipe mode", errno);
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fdType = FdType::PIPE;
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} else {
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// some other error
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throw TLibraryException("Failed to create eventfd for "
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"TNotificationQueue", errno);
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}
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}
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}
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if (fdType == FdType::PIPE) {
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if (pipe(pipeFds_)) {
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throw TLibraryException("Failed to create pipe for TNotificationQueue",
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errno);
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}
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try {
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// put both ends of the pipe into non-blocking mode
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if (fcntl(pipeFds_[0], F_SETFL, O_RDONLY | O_NONBLOCK) != 0) {
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throw TLibraryException("failed to put TNotificationQueue pipe read "
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"endpoint into non-blocking mode", errno);
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}
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if (fcntl(pipeFds_[1], F_SETFL, O_WRONLY | O_NONBLOCK) != 0) {
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throw TLibraryException("failed to put TNotificationQueue pipe write "
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"endpoint into non-blocking mode", errno);
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}
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} catch (...) {
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::close(pipeFds_[0]);
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::close(pipeFds_[1]);
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throw;
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}
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}
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}
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~TNotificationQueue() {
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if (eventfd_ >= 0) {
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::close(eventfd_);
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eventfd_ = -1;
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}
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if (pipeFds_[0] >= 0) {
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::close(pipeFds_[0]);
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pipeFds_[0] = -1;
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}
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if (pipeFds_[1] >= 0) {
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::close(pipeFds_[1]);
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pipeFds_[1] = -1;
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}
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}
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/**
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* Set the advisory maximum queue size.
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*
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* This maximum queue size affects calls to tryPutMessage(). Message
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* producers can still use the putMessage() call to unconditionally put a
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* message on the queue, ignoring the configured maximum queue size. This
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* can cause the queue size to exceed the configured maximum.
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*/
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void setMaxQueueSize(uint32_t max) {
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advisoryMaxQueueSize_ = max;
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}
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/**
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* Attempt to put a message on the queue if the queue is not already full.
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*
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* If the queue is full, a TQueueFullException will be thrown. The
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* setMaxQueueSize() function controls the maximum queue size.
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*
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* This method may contend briefly on a spinlock if many threads are
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* concurrently accessing the queue, but for all intents and purposes it will
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* immediately place the message on the queue and return.
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*
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* tryPutMessage() may throw std::bad_alloc if memory allocation fails, and
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* may throw any other exception thrown by the MessageT move/copy
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* constructor.
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*/
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void tryPutMessage(MessageT&& message) {
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putMessageImpl(std::move(message), advisoryMaxQueueSize_);
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}
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void tryPutMessage(const MessageT& message) {
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putMessageImpl(message, advisoryMaxQueueSize_);
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}
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/**
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* Unconditionally put a message on the queue.
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*
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* This method is like tryPutMessage(), but ignores the maximum queue size
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* and always puts the message on the queue, even if the maximum queue size
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* would be exceeded.
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*
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* putMessage() may throw std::bad_alloc if memory allocation fails, and may
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* throw any other exception thrown by the MessageT move/copy constructor.
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*/
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void putMessage(MessageT&& message) {
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putMessageImpl(std::move(message), 0);
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}
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void putMessage(const MessageT& message) {
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putMessageImpl(message, 0);
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}
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/**
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* Put several messages on the queue.
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*/
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template<typename InputIteratorT>
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void putMessages(InputIteratorT first, InputIteratorT last) {
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typedef typename std::iterator_traits<InputIteratorT>::iterator_category
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IterCategory;
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putMessagesImpl(first, last, IterCategory());
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}
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/**
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* Try to immediately pull a message off of the queue, without blocking.
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*
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* If a message is immediately available, the result parameter will be
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* updated to contain the message contents and true will be returned.
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*
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* If no message is available, false will be returned and result will be left
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* unmodified.
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*/
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bool tryConsume(MessageT& result) {
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if (!tryConsumeEvent()) {
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return false;
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}
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try {
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facebook::SpinLockHolder guard(&spinlock_);
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result = std::move(queue_.front());
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queue_.pop_front();
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} catch (...) {
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// Handle an exception if the assignment operator happens to throw.
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// We consumed an event but weren't able to pop the message off the
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// queue. Signal the event again since the message is still in the
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// queue.
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signalEvent(1);
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throw;
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}
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return true;
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}
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private:
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// Forbidden copy constructor and assignment operator
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TNotificationQueue(TNotificationQueue const &) = delete;
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TNotificationQueue& operator=(TNotificationQueue const &) = delete;
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inline void checkQueueSize(size_t maxSize) const {
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assert(spinlock_.IsHeld());
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if (maxSize > 0 && queue_.size() >= maxSize) {
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throw TQueueFullException();
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}
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}
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inline void signalEvent(uint64_t numAdded = 1) const {
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static const uint8_t kPipeMessage[] = {
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1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1, 1
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};
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ssize_t bytes_written = 0;
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ssize_t bytes_expected = 0;
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if (eventfd_ >= 0) {
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bytes_expected = static_cast<ssize_t>(sizeof(numAdded));
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bytes_written = ::write(eventfd_, &numAdded, sizeof(numAdded));
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} else {
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// pipe semantics, add one message for each numAdded
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bytes_expected = numAdded;
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do {
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size_t messageSize = std::min(numAdded, sizeof(kPipeMessage));
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ssize_t rc = ::write(pipeFds_[1], kPipeMessage, messageSize);
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if (rc < 0) {
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// TODO: if the pipe is full, write will fail with EAGAIN.
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// See task #1044651 for how this could be handled
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break;
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}
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numAdded -= rc;
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bytes_written += rc;
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} while (numAdded > 0);
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}
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if (bytes_written != bytes_expected) {
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throw TLibraryException("failed to signal TNotificationQueue after "
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"write", errno);
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}
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}
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bool tryConsumeEvent() {
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uint64_t value = 0;
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ssize_t rc = -1;
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if (eventfd_ >= 0) {
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rc = ::read(eventfd_, &value, sizeof(value));
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} else {
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uint8_t value8;
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rc = ::read(pipeFds_[0], &value8, sizeof(value8));
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value = value8;
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}
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if (rc < 0) {
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// EAGAIN should pretty much be the only error we can ever get.
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// This means someone else already processed the only available message.
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assert(errno == EAGAIN);
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return false;
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}
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assert(value == 1);
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return true;
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}
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void putMessageImpl(MessageT&& message, size_t maxSize) {
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{
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facebook::SpinLockHolder guard(&spinlock_);
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checkQueueSize(maxSize);
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queue_.push_back(std::move(message));
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}
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signalEvent();
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}
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void putMessageImpl(const MessageT& message, size_t maxSize) {
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{
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facebook::SpinLockHolder guard(&spinlock_);
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checkQueueSize(maxSize);
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queue_.push_back(message);
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}
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signalEvent();
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}
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template<typename InputIteratorT>
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void putMessagesImpl(InputIteratorT first, InputIteratorT last,
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std::input_iterator_tag) {
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uint64_t numAdded = 0;
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{
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facebook::SpinLockHolder guard(&spinlock_);
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while (first != last) {
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queue_.push_back(*first);
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++first;
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++numAdded;
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}
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}
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signalEvent(numAdded);
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}
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template<typename InputIteratorT>
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void putMessagesImpl(InputIteratorT first, InputIteratorT last,
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std::forward_iterator_tag) {
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uint64_t numAdded = std::distance(first, last);
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{
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facebook::SpinLockHolder guard(&spinlock_);
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queue_.insert(queue_.end(), first, last);
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}
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signalEvent(numAdded);
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}
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facebook::SpinLock spinlock_;
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int eventfd_;
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int pipeFds_[2]; // to fallback to on older/non-linux systems
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uint32_t advisoryMaxQueueSize_;
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std::deque<MessageT> queue_;
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};
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template<typename MessageT>
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TNotificationQueue<MessageT>::Consumer::~Consumer() {
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// If we are in the middle of a call to handlerReady(), destroyedFlagPtr_
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// will be non-NULL. Mark the value that it points to, so that
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// handlerReady() will know the callback is destroyed, and that it cannot
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// access any member variables anymore.
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if (destroyedFlagPtr_) {
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*destroyedFlagPtr_ = true;
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}
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}
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template<typename MessageT>
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void TNotificationQueue<MessageT>::Consumer::handlerReady(uint16_t events)
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THRIFT_NOEXCEPT {
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uint32_t numProcessed = 0;
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while (true) {
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// Try to decrement the eventfd.
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//
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// We decrement the eventfd before checking the queue, and only pop a
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// message off the queue if we read from the eventfd.
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//
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// Reading the eventfd first allows us to not have to hold the spinlock
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// while accessing the eventfd. If we popped from the queue first, we
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// would have to hold the lock while reading from or writing to the
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// eventfd. (Multiple consumers may be woken up from a single eventfd
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// notification. If we popped from the queue first, we could end up
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// popping a message from the queue before the eventfd has been notified by
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// the producer, unless the consumer and producer both held the spinlock
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// around the entire operation.)
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if (!queue_->tryConsumeEvent()) {
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// no message available right now
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return;
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}
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// Now pop the message off of the queue.
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// We successfully consumed the eventfd notification.
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// There should be a message available for us to consume.
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//
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// We have to manually acquire and release the spinlock here, rather than
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// using SpinLockHolder since the MessageT has to be constructed while
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// holding the spinlock and available after we release it. SpinLockHolder
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// unfortunately doesn't provide a release() method. (We can't construct
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// MessageT first since we have no guarantee that MessageT has a default
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// constructor.
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queue_->spinlock_.Lock();
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bool locked = true;
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try {
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// The eventfd is incremented once for every message, and only
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// decremented when a message is popped off. There should always be a
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// message here to read.
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CHECK(!queue_->queue_.empty());
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// Pull a message off the queue.
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MessageT msg(std::move(queue_->queue_.front()));
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queue_->queue_.pop_front();
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// Check to see if the queue is empty now.
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// We use this as an optimization to see if we should bother trying to
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// loop again and read another message after invoking this callback.
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bool wasEmpty = queue_->queue_.empty();
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// Now unlock the spinlock before we invoke the callback.
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queue_->spinlock_.Unlock();
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locked = false;
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// Call the callback
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bool callbackDestroyed = false;
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CHECK(destroyedFlagPtr_ == NULL);
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destroyedFlagPtr_ = &callbackDestroyed;
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messageAvailable(std::move(msg));
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// If the callback was destroyed before it returned, we are done
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if (callbackDestroyed) {
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return;
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}
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destroyedFlagPtr_ = NULL;
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// If the callback is no longer installed, we are done.
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if (queue_ == NULL) {
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return;
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}
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// If we have hit maxReadAtOnce_, we are done.
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++numProcessed;
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if (maxReadAtOnce_ > 0 && numProcessed >= maxReadAtOnce_) {
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return;
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}
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// If the queue was empty before we invoked the callback, it's probable
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// that it is still empty now. Just go ahead and return, rather than
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// looping again and trying to re-read from the eventfd. (If a new
|
|
// message had in fact arrived while we were invoking the callback, we
|
|
// will simply be woken up the next time around the event loop and will
|
|
// process the message then.)
|
|
if (wasEmpty) {
|
|
return;
|
|
}
|
|
} catch (const std::exception& ex) {
|
|
// This catch block is really just to handle the case where the MessageT
|
|
// constructor throws. The messageAvailable() callback itself is
|
|
// declared as noexcept and should never throw.
|
|
//
|
|
// If the MessageT constructor does throw we try to handle it as best as
|
|
// we can, but we can't work miracles. We will just ignore the error for
|
|
// now and return. The next time around the event loop we will end up
|
|
// trying to read the message again. If MessageT continues to throw we
|
|
// will never make forward progress and will keep trying each time around
|
|
// the event loop.
|
|
if (locked) {
|
|
// Unlock the spinlock.
|
|
queue_->spinlock_.Unlock();
|
|
|
|
// Push a notification back on the eventfd since we didn't actually
|
|
// read the message off of the queue.
|
|
queue_->signalEvent(1);
|
|
}
|
|
|
|
return;
|
|
}
|
|
}
|
|
}
|
|
|
|
template<typename MessageT>
|
|
void TNotificationQueue<MessageT>::Consumer::init(
|
|
TEventBase* eventBase,
|
|
TNotificationQueue* queue) {
|
|
assert(eventBase->isInEventBaseThread());
|
|
assert(queue_ == NULL);
|
|
assert(!isHandlerRegistered());
|
|
|
|
queue_ = queue;
|
|
if (queue_->eventfd_ >= 0) {
|
|
initHandler(eventBase, queue_->eventfd_);
|
|
} else {
|
|
initHandler(eventBase, queue_->pipeFds_[0]);
|
|
}
|
|
}
|
|
|
|
template<typename MessageT>
|
|
void TNotificationQueue<MessageT>::Consumer::stopConsuming() {
|
|
if (queue_ == NULL) {
|
|
assert(!isHandlerRegistered());
|
|
return;
|
|
}
|
|
|
|
assert(isHandlerRegistered());
|
|
unregisterHandler();
|
|
detachEventBase();
|
|
queue_ = NULL;
|
|
}
|
|
|
|
}}} // apache::thrift::async
|
|
|
|
#endif // THRIFT_ASYNC_TNOTIFICATIONQUEUE_H_
|