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115ee28263
ossl_quic_sstream_is_totally_acked would return 0 if no data had been appended to the stream yet. Fixed and added tests. Reviewed-by: Tomas Mraz <tomas@openssl.org> Reviewed-by: Matt Caswell <matt@openssl.org> Reviewed-by: Paul Dale <pauli@openssl.org> (Merged from https://github.com/openssl/openssl/pull/22580)
425 lines
12 KiB
C
425 lines
12 KiB
C
/*
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* Copyright 2022-2023 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_stream.h"
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#include "internal/uint_set.h"
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#include "internal/common.h"
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#include "internal/ring_buf.h"
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/*
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* ==================================================================
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* QUIC Send Stream
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*/
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struct quic_sstream_st {
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struct ring_buf ring_buf;
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/*
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* Any logical byte in the stream is in one of these states:
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*
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* - NEW: The byte has not yet been transmitted, or has been lost and is
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* in need of retransmission.
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*
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* - IN_FLIGHT: The byte has been transmitted but is awaiting
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* acknowledgement. We continue to store the data in case we return
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* to the NEW state.
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*
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* - ACKED: The byte has been acknowledged and we can cease storing it.
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* We do not necessarily cull it immediately, so there may be a delay
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* between reaching the ACKED state and the buffer space actually being
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* recycled.
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*
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* A logical byte in the stream is
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*
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* - in the NEW state if it is in new_set;
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* - is in the ACKED state if it is in acked_set
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* (and may or may not have been culled);
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* - is in the IN_FLIGHT state otherwise.
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*
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* Invariant: No logical byte is ever in both new_set and acked_set.
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*/
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UINT_SET new_set, acked_set;
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/*
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* The current size of the stream is ring_buf.head_offset. If
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* have_final_size is true, this is also the final size of the stream.
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*/
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unsigned int have_final_size : 1;
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unsigned int sent_final_size : 1;
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unsigned int acked_final_size : 1;
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unsigned int cleanse : 1;
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};
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static void qss_cull(QUIC_SSTREAM *qss);
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QUIC_SSTREAM *ossl_quic_sstream_new(size_t init_buf_size)
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{
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QUIC_SSTREAM *qss;
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qss = OPENSSL_zalloc(sizeof(QUIC_SSTREAM));
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if (qss == NULL)
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return NULL;
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ring_buf_init(&qss->ring_buf);
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if (!ring_buf_resize(&qss->ring_buf, init_buf_size, 0)) {
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ring_buf_destroy(&qss->ring_buf, 0);
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OPENSSL_free(qss);
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return NULL;
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}
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ossl_uint_set_init(&qss->new_set);
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ossl_uint_set_init(&qss->acked_set);
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return qss;
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}
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void ossl_quic_sstream_free(QUIC_SSTREAM *qss)
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{
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if (qss == NULL)
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return;
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ossl_uint_set_destroy(&qss->new_set);
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ossl_uint_set_destroy(&qss->acked_set);
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ring_buf_destroy(&qss->ring_buf, qss->cleanse);
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OPENSSL_free(qss);
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}
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int ossl_quic_sstream_get_stream_frame(QUIC_SSTREAM *qss,
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size_t skip,
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OSSL_QUIC_FRAME_STREAM *hdr,
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OSSL_QTX_IOVEC *iov,
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size_t *num_iov)
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{
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size_t num_iov_ = 0, src_len = 0, total_len = 0, i;
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uint64_t max_len;
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const unsigned char *src = NULL;
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UINT_SET_ITEM *range = ossl_list_uint_set_head(&qss->new_set);
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if (*num_iov < 2)
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return 0;
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for (i = 0; i < skip && range != NULL; ++i)
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range = ossl_list_uint_set_next(range);
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if (range == NULL) {
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if (i < skip)
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/* Don't return FIN for infinitely increasing skip */
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return 0;
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/* No new bytes to send, but we might have a FIN */
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if (!qss->have_final_size || qss->sent_final_size)
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return 0;
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hdr->offset = qss->ring_buf.head_offset;
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hdr->len = 0;
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hdr->is_fin = 1;
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*num_iov = 0;
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return 1;
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}
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/*
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* We can only send a contiguous range of logical bytes in a single
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* stream frame, so limit ourselves to the range of the first set entry.
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*
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* Set entries never have 'adjacent' entries so we don't have to worry
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* about them here.
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*/
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max_len = range->range.end - range->range.start + 1;
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for (i = 0;; ++i) {
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if (total_len >= max_len)
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break;
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if (!ring_buf_get_buf_at(&qss->ring_buf,
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range->range.start + total_len,
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&src, &src_len))
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return 0;
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if (src_len == 0)
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break;
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assert(i < 2);
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if (total_len + src_len > max_len)
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src_len = (size_t)(max_len - total_len);
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iov[num_iov_].buf = src;
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iov[num_iov_].buf_len = src_len;
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total_len += src_len;
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++num_iov_;
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}
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hdr->offset = range->range.start;
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hdr->len = total_len;
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hdr->is_fin = qss->have_final_size
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&& hdr->offset + hdr->len == qss->ring_buf.head_offset;
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*num_iov = num_iov_;
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return 1;
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}
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int ossl_quic_sstream_has_pending(QUIC_SSTREAM *qss)
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{
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OSSL_QUIC_FRAME_STREAM shdr;
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OSSL_QTX_IOVEC iov[2];
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size_t num_iov = OSSL_NELEM(iov);
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return ossl_quic_sstream_get_stream_frame(qss, 0, &shdr, iov, &num_iov);
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}
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uint64_t ossl_quic_sstream_get_cur_size(QUIC_SSTREAM *qss)
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{
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return qss->ring_buf.head_offset;
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}
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int ossl_quic_sstream_mark_transmitted(QUIC_SSTREAM *qss,
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uint64_t start,
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uint64_t end)
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{
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UINT_RANGE r;
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r.start = start;
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r.end = end;
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if (!ossl_uint_set_remove(&qss->new_set, &r))
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return 0;
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return 1;
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}
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int ossl_quic_sstream_mark_transmitted_fin(QUIC_SSTREAM *qss,
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uint64_t final_size)
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{
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/*
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* We do not really need final_size since we already know the size of the
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* stream, but this serves as a sanity check.
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*/
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if (!qss->have_final_size || final_size != qss->ring_buf.head_offset)
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return 0;
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qss->sent_final_size = 1;
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return 1;
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}
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int ossl_quic_sstream_mark_lost(QUIC_SSTREAM *qss,
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uint64_t start,
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uint64_t end)
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{
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UINT_RANGE r;
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r.start = start;
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r.end = end;
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/*
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* We lost a range of stream data bytes, so reinsert them into the new set,
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* so that they are returned once more by ossl_quic_sstream_get_stream_frame.
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*/
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if (!ossl_uint_set_insert(&qss->new_set, &r))
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return 0;
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return 1;
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}
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int ossl_quic_sstream_mark_lost_fin(QUIC_SSTREAM *qss)
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{
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if (qss->acked_final_size)
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/* Does not make sense to lose a FIN after it has been ACKed */
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return 0;
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/* FIN was lost, so we need to transmit it again. */
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qss->sent_final_size = 0;
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return 1;
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}
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int ossl_quic_sstream_mark_acked(QUIC_SSTREAM *qss,
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uint64_t start,
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uint64_t end)
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{
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UINT_RANGE r;
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r.start = start;
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r.end = end;
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if (!ossl_uint_set_insert(&qss->acked_set, &r))
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return 0;
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qss_cull(qss);
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return 1;
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}
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int ossl_quic_sstream_mark_acked_fin(QUIC_SSTREAM *qss)
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{
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if (!qss->have_final_size)
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/* Cannot ack final size before we have a final size */
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return 0;
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qss->acked_final_size = 1;
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return 1;
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}
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void ossl_quic_sstream_fin(QUIC_SSTREAM *qss)
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{
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if (qss->have_final_size)
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return;
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qss->have_final_size = 1;
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}
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int ossl_quic_sstream_get_final_size(QUIC_SSTREAM *qss, uint64_t *final_size)
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{
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if (!qss->have_final_size)
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return 0;
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if (final_size != NULL)
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*final_size = qss->ring_buf.head_offset;
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return 1;
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}
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int ossl_quic_sstream_append(QUIC_SSTREAM *qss,
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const unsigned char *buf,
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size_t buf_len,
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size_t *consumed)
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{
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size_t l, consumed_ = 0;
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UINT_RANGE r;
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struct ring_buf old_ring_buf = qss->ring_buf;
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if (qss->have_final_size) {
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*consumed = 0;
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return 0;
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}
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/*
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* Note: It is assumed that ossl_quic_sstream_append will be called during a
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* call to e.g. SSL_write and this function is therefore designed to support
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* such semantics. In particular, the buffer pointed to by buf is only
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* assumed to be valid for the duration of this call, therefore we must copy
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* the data here. We will later copy-and-encrypt the data during packet
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* encryption, so this is a two-copy design. Supporting a one-copy design in
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* the future will require applications to use a different kind of API.
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* Supporting such changes in future will require corresponding enhancements
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* to this code.
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*/
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while (buf_len > 0) {
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l = ring_buf_push(&qss->ring_buf, buf, buf_len);
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if (l == 0)
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break;
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buf += l;
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buf_len -= l;
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consumed_ += l;
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}
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if (consumed_ > 0) {
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r.start = old_ring_buf.head_offset;
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r.end = r.start + consumed_ - 1;
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assert(r.end + 1 == qss->ring_buf.head_offset);
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if (!ossl_uint_set_insert(&qss->new_set, &r)) {
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qss->ring_buf = old_ring_buf;
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*consumed = 0;
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return 0;
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}
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}
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*consumed = consumed_;
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return 1;
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}
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static void qss_cull(QUIC_SSTREAM *qss)
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{
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UINT_SET_ITEM *h = ossl_list_uint_set_head(&qss->acked_set);
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/*
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* Potentially cull data from our ring buffer. This can happen once data has
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* been ACKed and we know we are never going to have to transmit it again.
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*
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* Since we use a ring buffer design for simplicity, we cannot cull byte n +
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* k (for k > 0) from the ring buffer until byte n has also been culled.
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* This means if parts of the stream get acknowledged out of order we might
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* keep around some data we technically don't need to for a while. The
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* impact of this is likely to be small and limited to quite a short
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* duration, and doesn't justify the use of a more complex design.
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*/
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/*
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* We only need to check the first range entry in the integer set because we
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* can only cull contiguous areas at the start of the ring buffer anyway.
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*/
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if (h != NULL)
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ring_buf_cpop_range(&qss->ring_buf, h->range.start, h->range.end,
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qss->cleanse);
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}
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int ossl_quic_sstream_set_buffer_size(QUIC_SSTREAM *qss, size_t num_bytes)
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{
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return ring_buf_resize(&qss->ring_buf, num_bytes, qss->cleanse);
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}
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size_t ossl_quic_sstream_get_buffer_size(QUIC_SSTREAM *qss)
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{
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return qss->ring_buf.alloc;
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}
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size_t ossl_quic_sstream_get_buffer_used(QUIC_SSTREAM *qss)
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{
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return ring_buf_used(&qss->ring_buf);
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}
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size_t ossl_quic_sstream_get_buffer_avail(QUIC_SSTREAM *qss)
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{
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return ring_buf_avail(&qss->ring_buf);
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}
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int ossl_quic_sstream_is_totally_acked(QUIC_SSTREAM *qss)
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{
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UINT_RANGE r;
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uint64_t cur_size;
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if (qss->have_final_size && !qss->acked_final_size)
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return 0;
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if (ossl_quic_sstream_get_cur_size(qss) == 0)
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return 1;
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if (ossl_list_uint_set_num(&qss->acked_set) != 1)
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return 0;
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r = ossl_list_uint_set_head(&qss->acked_set)->range;
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cur_size = qss->ring_buf.head_offset;
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/*
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* The invariants of UINT_SET guarantee a single list element if we have a
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* single contiguous range, which is what we should have if everything has
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* been acked.
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*/
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assert(r.end + 1 <= cur_size);
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return r.start == 0 && r.end + 1 == cur_size;
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}
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void ossl_quic_sstream_adjust_iov(size_t len,
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OSSL_QTX_IOVEC *iov,
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size_t num_iov)
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{
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size_t running = 0, i, iovlen;
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for (i = 0, running = 0; i < num_iov; ++i) {
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iovlen = iov[i].buf_len;
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if (running >= len)
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iov[i].buf_len = 0;
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else if (running + iovlen > len)
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iov[i].buf_len = len - running;
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running += iovlen;
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}
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}
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void ossl_quic_sstream_set_cleanse(QUIC_SSTREAM *qss, int cleanse)
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{
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qss->cleanse = cleanse;
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}
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