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topic_monitor to use binary semaphore instead of self-pipe
With the prior commit, the topic_monitor only writes to the pipe if a thread is known to be waiting. This is effectively a binary semaphore, and on systems that support anon semaphores (yes Linux, but not Mac) we can use them. These are more efficient than self-pipes. We add a binary_semaphore_t class which uses sem_t if sem_init succeeds, and a self-pipe if it fails. On Linux the seq_echo benchmark (run 1024 times) goes from 12.40 seconds to 11.59 seconds, about an 11% improvement.
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c2da175f34
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@ -37,6 +37,78 @@ wcstring generation_list_t::describe() const {
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return result;
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}
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binary_semaphore_t::binary_semaphore_t() : sem_ok_(false) {
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// sem_init always fails with ENOSYS on Mac and has an annoying deprecation warning.
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#ifndef __APPLE__
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sem_ok_ = (0 == sem_init(&sem_, 0, 0));
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#endif
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if (!sem_ok_) {
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auto pipes = make_autoclose_pipes({});
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assert(pipes.has_value() && "Failed to make pubsub pipes");
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pipes_ = pipes.acquire();
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#ifdef TOPIC_MONITOR_TSAN_WORKAROUND
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DIE_ON_FAILURE(make_fd_nonblocking(pipes_.read.fd()));
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#endif
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}
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}
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binary_semaphore_t::~binary_semaphore_t() {
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#ifndef __APPLE__
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if (sem_ok_) (void)sem_destroy(&sem_);
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#endif
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}
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void binary_semaphore_t::die(const wchar_t *msg) const {
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wperror(msg);
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DIE("unexpected failure");
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}
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void binary_semaphore_t::post() {
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if (sem_ok_) {
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int res = sem_post(&sem_);
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// sem_post is non-interruptible.
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if (res < 0) die(L"sem_post");
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} else {
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// Write exactly one byte.
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ssize_t ret;
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do {
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const uint8_t v = 0;
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ret = write(pipes_.write.fd(), &v, sizeof v);
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} while (ret < 0 && errno == EINTR);
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if (ret < 0) die(L"write");
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}
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}
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void binary_semaphore_t::wait() {
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if (sem_ok_) {
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int res;
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do {
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res = sem_wait(&sem_);
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} while (res < 0 && errno == EINTR);
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// Other errors here are very unexpected.
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if (res < 0) die(L"sem_wait");
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} else {
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int fd = pipes_.read.fd();
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#ifdef TOPIC_MONITOR_TSAN_WORKAROUND
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// Under tsan our notifying pipe is non-blocking, so we would busy-loop on the read() call
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// until data is available (that is, fish would use 100% cpu while waiting for processes).
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// The select prevents that.
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fd_set fds;
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FD_ZERO(&fds);
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FD_SET(fd, &fds);
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(void)select(fd + 1, &fds, nullptr, nullptr, nullptr /* timeout */);
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#endif
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// We must read exactly one byte.
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for (;;) {
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uint8_t ignored;
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auto amt = read(fd, &ignored, sizeof ignored);
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if (amt == 1) break;
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if (amt < 0 && errno != EINTR) die(L"read");
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}
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}
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}
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/// Implementation of the principal monitor. This uses new (and leaks) to avoid registering a
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/// pointless at-exit handler for the dtor.
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static topic_monitor_t *const s_principal = new topic_monitor_t();
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@ -47,21 +119,7 @@ topic_monitor_t &topic_monitor_t::principal() {
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return *s_principal;
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}
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topic_monitor_t::topic_monitor_t() {
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// Set up our pipes. Assert it succeeds.
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auto pipes = make_autoclose_pipes({});
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assert(pipes.has_value() && "Failed to make pubsub pipes");
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pipes_ = pipes.acquire();
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// Make sure that our write side doesn't block, else we risk hanging in a signal handler.
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// The read end must block to avoid spinning in await.
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DIE_ON_FAILURE(make_fd_nonblocking(pipes_.write.fd()));
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#ifdef TOPIC_MONITOR_TSAN_WORKAROUND
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DIE_ON_FAILURE(make_fd_nonblocking(pipes_.read.fd()));
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#endif
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}
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topic_monitor_t::topic_monitor_t() = default;
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topic_monitor_t::~topic_monitor_t() = default;
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void topic_monitor_t::post(topic_t topic) {
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@ -94,14 +152,7 @@ void topic_monitor_t::post(topic_t topic) {
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// Check if we should wake up a thread because it was waiting.
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if (oldstatus & STATUS_NEEDS_WAKEUP) {
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std::atomic_thread_fence(std::memory_order_release);
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ssize_t ret;
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do {
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// We must write exactly one byte.
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// write() is async signal safe.
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const uint8_t v = 0;
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ret = write(pipes_.write.fd(), &v, sizeof v);
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} while (ret < 0 && errno == EINTR);
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// Ignore EAGAIN and other errors (which conceivably could occur during shutdown).
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sema_.post();
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}
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}
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@ -190,28 +241,11 @@ generation_list_t topic_monitor_t::await_gens(const generation_list_t &input_gen
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// Note we no longer hold the lock.
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assert(gens == input_gens &&
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"Generations should not have changed if we are the reader.");
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int fd = pipes_.read.fd();
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#ifdef TOPIC_MONITOR_TSAN_WORKAROUND
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// Under tsan our notifying pipe is non-blocking, so we would busy-loop on the read()
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// call until data is available (that is, fish would use 100% cpu while waiting for
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// processes). The select prevents that.
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fd_set fds;
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FD_ZERO(&fds);
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FD_SET(fd, &fds);
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(void)select(fd + 1, &fds, nullptr, nullptr, nullptr /* timeout */);
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#endif
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// We must read exactly one byte.
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for (;;) {
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uint8_t ignored;
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auto amt = read(fd, &ignored, sizeof ignored);
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if (amt == 1) break;
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if (amt < 0 && errno != EINTR && errno != EINTR) {
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wperror(L"read");
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DIE("self-pipe read unexpected failure");
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}
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}
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// We are finished reading. We must stop being the reader, and post on the condition
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// Wait to be woken up.
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sema_.wait();
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// We are finished waiting. We must stop being the reader, and post on the condition
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// variable to wake up any other threads waiting for us to finish reading.
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auto data = data_.acquire();
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gens = data->current;
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@ -1,6 +1,8 @@
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#ifndef FISH_TOPIC_MONITOR_H
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#define FISH_TOPIC_MONITOR_H
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#include <semaphore.h>
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#include <array>
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#include <atomic>
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#include <bitset>
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@ -127,8 +129,48 @@ class generation_list_t {
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: sighupint(sighupint), sigchld(sigchld), internal_exit(internal_exit) {}
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};
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/// A simple binary semaphore.
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/// On systems that do not support unnamed semaphores (macOS in particular) this is built on top of
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/// a self-pipe. Note that post() must be async-signal safe.
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class binary_semaphore_t {
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public:
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binary_semaphore_t();
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~binary_semaphore_t();
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/// Release a waiting thread.
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void post();
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/// Wait for a post.
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/// This loops on EINTR.
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void wait();
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private:
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// Print a message and exit.
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void die(const wchar_t *msg) const;
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// Whether our semaphore was successfully initialized.
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bool sem_ok_{};
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// The semaphore, if initalized.
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sem_t sem_{};
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// Pipes used to emulate a semaphore, if not initialized.
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autoclose_pipes_t pipes_{};
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};
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/// The topic monitor class. This permits querying the current generation values for topics,
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/// optionally blocking until they increase.
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/// What we would like to write is that we have a set of topics, and threads wait for changes on a
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/// condition variable which is tickled in post(). But this can't work because post() may be called
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/// from a signal handler and condition variables are not async-signal safe.
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/// So instead the signal handler announces changes via a binary semaphore.
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/// In the wait case, what generally happens is:
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/// A thread fetches the generations, see they have not changed, and then decides to try to wait.
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/// It does so by atomically swapping in STATUS_NEEDS_WAKEUP to the status bits.
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/// If that succeeds, it waits on the binary semaphore. The post() call will then wake the thread
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/// up. If if failed, then either a post() call updated the status values (so perhaps there is a
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/// new topic post) or some other thread won the race and called wait() on the semaphore. Here our
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/// thread will wait on the data_notifier_ queue.
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class topic_monitor_t {
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private:
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using topic_bitmask_t = uint8_t;
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@ -139,6 +181,7 @@ class topic_monitor_t {
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generation_list_t current{};
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/// A flag indicating that there is a current reader.
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/// The 'reader' is responsible for calling sema_.wait().
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bool has_reader{false};
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};
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owning_lock<data_t> data_{};
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@ -160,11 +203,10 @@ class topic_monitor_t {
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/// Note it is an error for this bit to be set and also any topic bit.
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static constexpr uint8_t STATUS_NEEDS_WAKEUP = 128;
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/// Self-pipes used to communicate changes.
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/// The writer is a signal handler.
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/// "The reader" refers to a thread that wants to wait for changes. Only one thread can be the
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/// reader at a given time.
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autoclose_pipes_t pipes_;
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/// Binary semaphore used to communicate changes.
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/// If status_ is STATUS_NEEDS_WAKEUP, then a thread has commited to call wait() on our sema and
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/// this must be balanced by the next call to post(). Note only one thread may wait at a time.
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binary_semaphore_t sema_{};
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/// Apply any pending updates to the data.
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/// This accepts data because it must be locked.
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