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6084e04b25
Reviewed-by: Matt Caswell <matt@openssl.org> Reviewed-by: Tim Hudson <tjh@openssl.org> Reviewed-by: Tomas Mraz <tomas@openssl.org> (Merged from https://github.com/openssl/openssl/pull/20879)
357 lines
12 KiB
C
357 lines
12 KiB
C
/*
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* Copyright 2022 The OpenSSL Project Authors. All Rights Reserved.
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*
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* Licensed under the Apache License 2.0 (the "License"). You may not use
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* this file except in compliance with the License. You can obtain a copy
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* in the file LICENSE in the source distribution or at
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* https://www.openssl.org/source/license.html
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*/
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#include "internal/quic_reactor.h"
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#include "internal/common.h"
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#include "internal/thread_arch.h"
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/*
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* Core I/O Reactor Framework
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* ==========================
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*/
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void ossl_quic_reactor_init(QUIC_REACTOR *rtor,
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void (*tick_cb)(QUIC_TICK_RESULT *res, void *arg,
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uint32_t flags),
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void *tick_cb_arg,
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OSSL_TIME initial_tick_deadline)
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{
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rtor->poll_r.type = BIO_POLL_DESCRIPTOR_TYPE_NONE;
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rtor->poll_w.type = BIO_POLL_DESCRIPTOR_TYPE_NONE;
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rtor->net_read_desired = 0;
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rtor->net_write_desired = 0;
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rtor->tick_deadline = initial_tick_deadline;
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rtor->tick_cb = tick_cb;
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rtor->tick_cb_arg = tick_cb_arg;
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}
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void ossl_quic_reactor_set_poll_r(QUIC_REACTOR *rtor, const BIO_POLL_DESCRIPTOR *r)
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{
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rtor->poll_r = *r;
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}
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void ossl_quic_reactor_set_poll_w(QUIC_REACTOR *rtor, const BIO_POLL_DESCRIPTOR *w)
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{
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rtor->poll_w = *w;
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}
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const BIO_POLL_DESCRIPTOR *ossl_quic_reactor_get_poll_r(QUIC_REACTOR *rtor)
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{
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return &rtor->poll_r;
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}
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const BIO_POLL_DESCRIPTOR *ossl_quic_reactor_get_poll_w(QUIC_REACTOR *rtor)
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{
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return &rtor->poll_w;
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}
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int ossl_quic_reactor_net_read_desired(QUIC_REACTOR *rtor)
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{
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return rtor->net_read_desired;
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}
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int ossl_quic_reactor_net_write_desired(QUIC_REACTOR *rtor)
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{
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return rtor->net_write_desired;
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}
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OSSL_TIME ossl_quic_reactor_get_tick_deadline(QUIC_REACTOR *rtor)
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{
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return rtor->tick_deadline;
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}
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int ossl_quic_reactor_tick(QUIC_REACTOR *rtor, uint32_t flags)
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{
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QUIC_TICK_RESULT res = {0};
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/*
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* Note that the tick callback cannot fail; this is intentional. Arguably it
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* does not make that much sense for ticking to 'fail' (in the sense of an
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* explicit error indicated to the user) because ticking is by its nature
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* best effort. If something fatal happens with a connection we can report
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* it on the next actual application I/O call.
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*/
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rtor->tick_cb(&res, rtor->tick_cb_arg, flags);
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rtor->net_read_desired = res.net_read_desired;
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rtor->net_write_desired = res.net_write_desired;
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rtor->tick_deadline = res.tick_deadline;
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return 1;
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}
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/*
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* Blocking I/O Adaptation Layer
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* =============================
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*/
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/*
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* Utility which can be used to poll on up to two FDs. This is designed to
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* support use of split FDs (e.g. with SSL_set_rfd and SSL_set_wfd where
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* different FDs are used for read and write).
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*
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* Generally use of poll(2) is preferred where available. Windows, however,
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* hasn't traditionally offered poll(2), only select(2). WSAPoll() was
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* introduced in Vista but has seemingly been buggy until relatively recent
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* versions of Windows 10. Moreover we support XP so this is not a suitable
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* target anyway. However, the traditional issues with select(2) turn out not to
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* be an issue on Windows; whereas traditional *NIX select(2) uses a bitmap of
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* FDs (and thus is limited in the magnitude of the FDs expressible), Windows
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* select(2) is very different. In Windows, socket handles are not allocated
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* contiguously from zero and thus this bitmap approach was infeasible. Thus in
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* adapting the Berkeley sockets API to Windows a different approach was taken
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* whereby the fd_set contains a fixed length array of socket handles and an
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* integer indicating how many entries are valid; thus Windows select()
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* ironically is actually much more like *NIX poll(2) than *NIX select(2). In
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* any case, this means that the relevant limit for Windows select() is the
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* number of FDs being polled, not the magnitude of those FDs. Since we only
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* poll for two FDs here, this limit does not concern us.
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*
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* Usage: rfd and wfd may be the same or different. Either or both may also be
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* -1. If rfd_want_read is 1, rfd is polled for readability, and if
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* wfd_want_write is 1, wfd is polled for writability. Note that since any
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* passed FD is always polled for error conditions, setting rfd_want_read=0 and
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* wfd_want_write=0 is not the same as passing -1 for both FDs.
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*
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* deadline is a timestamp to return at. If it is ossl_time_infinite(), the call
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* never times out.
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*
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* Returns 0 on error and 1 on success. Timeout expiry is considered a success
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* condition. We don't elaborate our return values here because the way we are
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* actually using this doesn't currently care.
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*
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* If mutex is non-NULL, it is assumed to be held for write and is unlocked for
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* the duration of the call.
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*
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* Precondition: mutex is NULL or is held for write (unchecked)
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* Postcondition: mutex is NULL or is held for write (unless
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* CRYPTO_THREAD_write_lock fails)
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*/
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static int poll_two_fds(int rfd, int rfd_want_read,
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int wfd, int wfd_want_write,
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OSSL_TIME deadline,
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CRYPTO_MUTEX *mutex)
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{
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#if defined(OPENSSL_SYS_WINDOWS) || !defined(POLLIN)
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fd_set rfd_set, wfd_set, efd_set;
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OSSL_TIME now, timeout;
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struct timeval tv, *ptv;
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int maxfd, pres;
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# ifndef OPENSSL_SYS_WINDOWS
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/*
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* On Windows there is no relevant limit to the magnitude of a fd value (see
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* above). On *NIX the fd_set uses a bitmap and we must check the limit.
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*/
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if (rfd >= FD_SETSIZE || wfd >= FD_SETSIZE)
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return 0;
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# endif
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FD_ZERO(&rfd_set);
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FD_ZERO(&wfd_set);
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FD_ZERO(&efd_set);
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if (rfd != -1 && rfd_want_read)
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openssl_fdset(rfd, &rfd_set);
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if (wfd != -1 && wfd_want_write)
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openssl_fdset(wfd, &wfd_set);
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/* Always check for error conditions. */
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if (rfd != -1)
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openssl_fdset(rfd, &efd_set);
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if (wfd != -1)
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openssl_fdset(wfd, &efd_set);
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maxfd = rfd;
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if (wfd > maxfd)
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maxfd = wfd;
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if (!ossl_assert(rfd != -1 || wfd != -1
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|| !ossl_time_is_infinite(deadline)))
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/* Do not block forever; should not happen. */
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return 0;
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# if defined(OPENSSL_THREADS)
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if (mutex != NULL)
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ossl_crypto_mutex_unlock(mutex);
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# endif
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do {
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/*
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* select expects a timeout, not a deadline, so do the conversion.
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* Update for each call to ensure the correct value is used if we repeat
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* due to EINTR.
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*/
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if (ossl_time_is_infinite(deadline)) {
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ptv = NULL;
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} else {
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now = ossl_time_now();
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/*
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* ossl_time_subtract saturates to zero so we don't need to check if
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* now > deadline.
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*/
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timeout = ossl_time_subtract(deadline, now);
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tv = ossl_time_to_timeval(timeout);
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ptv = &tv;
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}
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pres = select(maxfd + 1, &rfd_set, &wfd_set, &efd_set, ptv);
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} while (pres == -1 && get_last_socket_error_is_eintr());
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# if defined(OPENSSL_THREADS)
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if (mutex != NULL)
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ossl_crypto_mutex_lock(mutex);
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# endif
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return pres < 0 ? 0 : 1;
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#else
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int pres, timeout_ms;
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OSSL_TIME now, timeout;
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struct pollfd pfds[2] = {0};
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size_t npfd = 0;
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if (rfd == wfd) {
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pfds[npfd].fd = rfd;
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pfds[npfd].events = (rfd_want_read ? POLLIN : 0)
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| (wfd_want_write ? POLLOUT : 0);
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if (rfd >= 0 && pfds[npfd].events != 0)
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++npfd;
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} else {
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pfds[npfd].fd = rfd;
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pfds[npfd].events = (rfd_want_read ? POLLIN : 0);
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if (rfd >= 0 && pfds[npfd].events != 0)
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++npfd;
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pfds[npfd].fd = wfd;
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pfds[npfd].events = (wfd_want_write ? POLLOUT : 0);
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if (wfd >= 0 && pfds[npfd].events != 0)
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++npfd;
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}
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if (!ossl_assert(npfd != 0 || !ossl_time_is_infinite(deadline)))
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/* Do not block forever; should not happen. */
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return 0;
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# if defined(OPENSSL_THREADS)
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if (mutex != NULL)
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ossl_crypto_mutex_unlock(mutex);
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# endif
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do {
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if (ossl_time_is_infinite(deadline)) {
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timeout_ms = -1;
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} else {
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now = ossl_time_now();
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timeout = ossl_time_subtract(deadline, now);
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timeout_ms = ossl_time2ms(timeout);
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}
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pres = poll(pfds, npfd, timeout_ms);
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} while (pres == -1 && get_last_socket_error_is_eintr());
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# if defined(OPENSSL_THREADS)
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if (mutex != NULL)
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ossl_crypto_mutex_lock(mutex);
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# endif
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return pres < 0 ? 0 : 1;
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#endif
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}
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static int poll_descriptor_to_fd(const BIO_POLL_DESCRIPTOR *d, int *fd)
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{
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if (d == NULL || d->type == BIO_POLL_DESCRIPTOR_TYPE_NONE) {
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*fd = INVALID_SOCKET;
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return 1;
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}
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if (d->type != BIO_POLL_DESCRIPTOR_TYPE_SOCK_FD
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|| d->value.fd == INVALID_SOCKET)
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return 0;
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*fd = d->value.fd;
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return 1;
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}
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/*
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* Poll up to two abstract poll descriptors. Currently we only support
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* poll descriptors which represent FDs.
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*
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* If mutex is non-NULL, it is assumed be a lock currently held for write and is
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* unlocked for the duration of any wait.
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*
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* Precondition: mutex is NULL or is held for write (unchecked)
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* Postcondition: mutex is NULL or is held for write (unless
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* CRYPTO_THREAD_write_lock fails)
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*/
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static int poll_two_descriptors(const BIO_POLL_DESCRIPTOR *r, int r_want_read,
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const BIO_POLL_DESCRIPTOR *w, int w_want_write,
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OSSL_TIME deadline,
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CRYPTO_MUTEX *mutex)
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{
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int rfd, wfd;
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if (!poll_descriptor_to_fd(r, &rfd)
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|| !poll_descriptor_to_fd(w, &wfd))
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return 0;
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return poll_two_fds(rfd, r_want_read, wfd, w_want_write, deadline, mutex);
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}
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/*
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* Block until a predicate function evaluates to true.
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*
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* If mutex is non-NULL, it is assumed be a lock currently held for write and is
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* unlocked for the duration of any wait.
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*
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* Precondition: Must hold channel write lock (unchecked)
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* Precondition: mutex is NULL or is held for write (unchecked)
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* Postcondition: mutex is NULL or is held for write (unless
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* CRYPTO_THREAD_write_lock fails)
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*/
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int ossl_quic_reactor_block_until_pred(QUIC_REACTOR *rtor,
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int (*pred)(void *arg), void *pred_arg,
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uint32_t flags,
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CRYPTO_MUTEX *mutex)
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{
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int res;
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for (;;) {
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if ((flags & SKIP_FIRST_TICK) != 0)
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flags &= ~SKIP_FIRST_TICK;
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else
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/* best effort */
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ossl_quic_reactor_tick(rtor, 0);
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if ((res = pred(pred_arg)) != 0)
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return res;
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if (!poll_two_descriptors(ossl_quic_reactor_get_poll_r(rtor),
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ossl_quic_reactor_net_read_desired(rtor),
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ossl_quic_reactor_get_poll_w(rtor),
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ossl_quic_reactor_net_write_desired(rtor),
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ossl_quic_reactor_get_tick_deadline(rtor),
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mutex))
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/*
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* We don't actually care why the call succeeded (timeout, FD
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* readiness), we just call reactor_tick and start trying to do I/O
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* things again. If poll_two_fds returns 0, this is some other
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* non-timeout failure and we should stop here.
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*
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* TODO(QUIC): In the future we could avoid unnecessary syscalls by
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* not retrying network I/O that isn't ready based on the result of
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* the poll call. However this might be difficult because it
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* requires we do the call to poll(2) or equivalent syscall
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* ourselves, whereas in the general case the application does the
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* polling and just calls SSL_handle_events(). Implementing this
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* optimisation in the future will probably therefore require API
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* changes.
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*/
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return 0;
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}
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}
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