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06b2a2363e
- [API] New knob to set outgoing packet batch size. - Aborted connection now become tickable immediately. - Abort connection when HTTP/3 frame cannot be opened (can only happen when malloc fails).
644 lines
20 KiB
C
644 lines
20 KiB
C
/* Copyright (c) 2017 - 2021 LiteSpeed Technologies Inc. See LICENSE. */
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/* Test adapted from Chromium bandwidth_sampler_test.cc */
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// Copyright 2016 The Chromium Authors. All rights reserved.
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#include <assert.h>
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#include <stdbool.h>
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#include <stdint.h>
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#include <string.h>
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#include <sys/queue.h>
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#include "lsquic.h"
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#include "lsquic_int_types.h"
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#include "lsquic_hash.h"
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#include "lsquic_packet_common.h"
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#include "lsquic_packet_out.h"
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#include "lsquic_bw_sampler.h"
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#include "lsquic_conn.h"
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#include "lsquic_malo.h"
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/* Convert seconds to microseconds */
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#define sec(val) ((val) * 1000 * 1000)
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/* Convert milliseconds to lsquic_time_t, which is microseconds */
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#define ms(val) ((val) * 1000)
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/* Microseconds */
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#define us(val) (val)
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#define kRegularPacketSize 1280
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#define PacketsToBytes(count_) ((count_) * kRegularPacketSize)
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#define FromKBytesPerSecond(size_) (size_ * 8000)
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// Enforce divisibility for some of the tests:
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// "kRegularPacketSize has to be five times divisible by 2"
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typedef char packet_size_has_to_be_five_times_divisible_by_2[
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(kRegularPacketSize & 31) == 0 ? 1 : -1];
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struct sampler_test
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{
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struct bw_sampler sampler;
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lsquic_time_t time;
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uint64_t bytes_in_flight;
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struct lsquic_conn conn;
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struct malo *malo_po;
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};
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static void
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sampler_test_init (struct sampler_test *stest)
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{
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memset(stest, 0, sizeof(*stest));
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stest->time = ms(1000); /* Time must not be zero, or test breaks */
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LSCONN_INITIALIZE(&stest->conn);
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lsquic_bw_sampler_init(&stest->sampler, &stest->conn, QUIC_FTBIT_STREAM);
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stest->malo_po = lsquic_malo_create(sizeof(struct lsquic_packet_out));
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assert(stest->malo_po);
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}
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static void
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sampler_test_cleanup (struct sampler_test *stest)
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{
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lsquic_bw_sampler_cleanup(&stest->sampler);
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lsquic_malo_destroy(stest->malo_po);
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}
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static struct lsquic_packet_out *
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sampler_test_send_packet (struct sampler_test *stest, lsquic_packno_t packno,
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bool retx)
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{
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struct lsquic_packet_out *packet_out;
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packet_out = lsquic_malo_get(stest->malo_po);
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assert(packet_out);
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memset(packet_out, 0, sizeof(*packet_out));
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packet_out->po_packno = packno;
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packet_out->po_flags |= PO_SENT_SZ;
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packet_out->po_flags |= PO_HELLO; /* Bypass sanity check */
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packet_out->po_sent_sz = kRegularPacketSize;
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packet_out->po_sent = stest->time;
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if (retx)
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packet_out->po_frame_types |= QUIC_FTBIT_STREAM;
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lsquic_bw_sampler_packet_sent(&stest->sampler, packet_out,
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stest->bytes_in_flight);
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if (retx)
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stest->bytes_in_flight += packet_out->po_sent_sz;
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return packet_out;
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}
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static struct bw_sample *
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sampler_test_ack_packet (struct sampler_test *stest,
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struct lsquic_packet_out *packet_out)
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{
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if (packet_out->po_frame_types & QUIC_FTBIT_STREAM)
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stest->bytes_in_flight -= packet_out->po_sent_sz;
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return lsquic_bw_sampler_packet_acked(&stest->sampler, packet_out,
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stest->time);
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}
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static void
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sampler_test_lose_packet (struct sampler_test *stest,
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struct lsquic_packet_out *packet_out)
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{
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if (packet_out->po_frame_types & QUIC_FTBIT_STREAM)
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stest->bytes_in_flight -= packet_out->po_sent_sz;
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lsquic_bw_sampler_packet_lost(&stest->sampler, packet_out);
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}
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static void
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sampler_test_send_40_packets_and_ack_first_20 (struct sampler_test *stest,
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lsquic_time_t time_between_packets, struct lsquic_packet_out *packets[])
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{
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struct bw_sample *sample;
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unsigned i;
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// Send 20 packets at a constant inter-packet time.
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for (i = 1; i <= 20; i++)
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{
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packets[i] = sampler_test_send_packet(stest, i, true);
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stest->time += time_between_packets;
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}
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// Ack packets 1 to 20, while sending new packets at the same rate as
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// before.
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for (i = 1; i <= 20; i++)
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{
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sample = sampler_test_ack_packet(stest, packets[i]);
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assert(sample);
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lsquic_malo_put(sample);
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packets[i + 20] = sampler_test_send_packet(stest, i + 20, true);
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stest->time += time_between_packets;
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}
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}
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// Test the sampler in a simple stop-and-wait sender setting.
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static void
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test_send_and_wait (void)
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{
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struct sampler_test stest;
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lsquic_time_t time_between_packets = ms(10);
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uint64_t expected_bandwidth = kRegularPacketSize * 100 * 8;
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unsigned i;
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struct bw_sample *sample;
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struct lsquic_packet_out *packet;
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sampler_test_init(&stest);
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// Send packets at the constant bandwidth.
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for (i = 1; i < 20; ++i)
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{
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packet = sampler_test_send_packet(&stest, i, true);
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stest.time += time_between_packets;
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sample = sampler_test_ack_packet(&stest, packet);
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assert(sample);
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assert(expected_bandwidth == BW_VALUE(&sample->bandwidth));
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lsquic_malo_put(sample);
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}
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// Send packets at the exponentially decreasing bandwidth.
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for (i = 20; i < 25; i++)
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{
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time_between_packets = time_between_packets * 2;
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expected_bandwidth = expected_bandwidth / 2;
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packet = sampler_test_send_packet(&stest, i, true);
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stest.time += time_between_packets;
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sample = sampler_test_ack_packet(&stest, packet);
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assert(sample);
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assert(expected_bandwidth == BW_VALUE(&sample->bandwidth));
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lsquic_malo_put(sample);
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}
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assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
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assert(stest.bytes_in_flight == 0);
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sampler_test_cleanup(&stest);
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}
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static void
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test_send_time_state (void)
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{
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struct sampler_test stest;
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lsquic_time_t time_between_packets = ms(10);
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struct bw_sample *sample;
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unsigned i;
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struct lsquic_packet_out *packets[11];
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sampler_test_init(&stest);
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// Send packets 1-5.
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for (i = 1; i <= 5; i++) {
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packets[i] = sampler_test_send_packet(&stest, i, true);
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assert(PacketsToBytes(i) == stest.sampler.bws_total_sent);
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stest.time += time_between_packets;
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}
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/* The order of tests here is different. Because the send state is
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* deleted when packet is acked, we have to check its values first.
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*/
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#define SEND_STATE(idx_) (&packets[idx_]->po_bwp_state->bwps_send_state)
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// Ack packet 1.
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assert(PacketsToBytes(1) == SEND_STATE(1)->total_bytes_sent);
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assert(0 == SEND_STATE(1)->total_bytes_acked);
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assert(0 == SEND_STATE(1)->total_bytes_lost);
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sample = sampler_test_ack_packet(&stest, packets[1]);
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assert(sample);
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lsquic_malo_put(sample);
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assert(PacketsToBytes(1) == stest.sampler.bws_total_acked);
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// Lose packet 2.
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assert(PacketsToBytes(2) == SEND_STATE(2)->total_bytes_sent);
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assert(0 == SEND_STATE(2)->total_bytes_acked);
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assert(0 == SEND_STATE(2)->total_bytes_lost);
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sampler_test_lose_packet(&stest, packets[2]);
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assert(PacketsToBytes(1) == stest.sampler.bws_total_lost);
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// Lose packet 3.
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assert(PacketsToBytes(3) == SEND_STATE(3)->total_bytes_sent);
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assert(0 == SEND_STATE(3)->total_bytes_acked);
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assert(0 == SEND_STATE(3)->total_bytes_lost);
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sampler_test_lose_packet(&stest, packets[3]);
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assert(PacketsToBytes(2) == stest.sampler.bws_total_lost);
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// Send packets 6-10.
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for (i = 6; i <= 10; i++)
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{
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packets[i] = sampler_test_send_packet(&stest, i, true);
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assert(PacketsToBytes(i) == stest.sampler.bws_total_sent);
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stest.time += time_between_packets;
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}
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// Ack all inflight packets.
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unsigned acked_packet_count = 1;
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assert(PacketsToBytes(acked_packet_count) ==
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stest.sampler.bws_total_acked);
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for (i = 4; i <= 10; i++)
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{
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assert(PacketsToBytes(i) == SEND_STATE(i)->total_bytes_sent);
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if (i <= 5)
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{
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assert(0 == SEND_STATE(i)->total_bytes_acked);
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assert(0 == SEND_STATE(i)->total_bytes_lost);
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}
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else
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{
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assert(PacketsToBytes(1) == SEND_STATE(i)->total_bytes_acked);
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assert(PacketsToBytes(2) == SEND_STATE(i)->total_bytes_lost);
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}
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sample = sampler_test_ack_packet(&stest, packets[i]);
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assert(sample);
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lsquic_malo_put(sample);
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++acked_packet_count;
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assert(PacketsToBytes(acked_packet_count) ==
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stest.sampler.bws_total_acked);
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stest.time += time_between_packets;
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}
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assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
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sampler_test_cleanup(&stest);
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}
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// Test the sampler during regular windowed sender scenario with fixed
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// CWND of 20.
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static void
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test_send_paced (void)
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{
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struct sampler_test stest;
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const lsquic_time_t time_between_packets = ms(1);
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uint64_t expected_bw = FromKBytesPerSecond(kRegularPacketSize);
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unsigned i;
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struct bw_sample *sample;
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struct lsquic_packet_out *packets[41];
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sampler_test_init(&stest);
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sampler_test_send_40_packets_and_ack_first_20(&stest,
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time_between_packets, packets);
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// Ack the packets 21 to 40, arriving at the correct bandwidth.
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for (i = 21; i <= 40; ++i)
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{
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sample = sampler_test_ack_packet(&stest, packets[i]);
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assert(sample);
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assert(expected_bw == BW_VALUE(&sample->bandwidth));
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stest.time += time_between_packets;
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lsquic_malo_put(sample);
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}
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assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
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assert(stest.bytes_in_flight == 0);
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sampler_test_cleanup(&stest);
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}
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// Test the sampler in a scenario where 50% of packets is consistently lost.
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static void
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test_send_with_losses (void)
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{
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struct sampler_test stest;
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const lsquic_time_t time_between_packets = ms(1);
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uint64_t expected_bw = FromKBytesPerSecond(kRegularPacketSize) / 2;
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unsigned i;
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struct bw_sample *sample;
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struct lsquic_packet_out *packets[41];
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sampler_test_init(&stest);
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// Send 20 packets, each 1 ms apart.
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for (i = 1; i <= 20; i++)
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{
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packets[i] = sampler_test_send_packet(&stest, i, true);
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stest.time += time_between_packets;
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}
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// Ack packets 1 to 20, losing every even-numbered packet, while sending new
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// packets at the same rate as before.
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for (i = 1; i <= 20; i++)
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{
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if (i % 2 == 0)
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{
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sample = sampler_test_ack_packet(&stest, packets[i]);
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assert(sample);
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lsquic_malo_put(sample);
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}
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else
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sampler_test_lose_packet(&stest, packets[i]);
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packets[i + 20] = sampler_test_send_packet(&stest, i + 20, true);
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stest.time += time_between_packets;
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}
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// Ack the packets 21 to 40 with the same loss pattern.
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for (i = 21; i <= 40; i++)
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{
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if (i % 2 == 0)
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{
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sample = sampler_test_ack_packet(&stest, packets[i]);
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assert(sample);
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assert(expected_bw == BW_VALUE(&sample->bandwidth));
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lsquic_malo_put(sample);
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}
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else
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sampler_test_lose_packet(&stest, packets[i]);
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stest.time += time_between_packets;
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}
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assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
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assert(stest.bytes_in_flight == 0);
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sampler_test_cleanup(&stest);
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}
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// Test the sampler in a scenario where the 50% of packets are not
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// congestion controlled (specifically, non-retransmittable data is not
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// congestion controlled). Should be functionally consistent in behavior with
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// the SendWithLosses test.
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static void
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test_not_congestion_controlled (void)
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{
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struct sampler_test stest;
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const lsquic_time_t time_between_packets = ms(1);
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uint64_t expected_bw = FromKBytesPerSecond(kRegularPacketSize) / 2;
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unsigned i;
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struct bw_sample *sample;
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struct lsquic_packet_out *packets[41];
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sampler_test_init(&stest);
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/* Note the mismatch between the comment and the code. This is
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* inherited from the original code.
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*/
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// Send 20 packets, each 1 ms apart. Every even packet is not congestion
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// controlled.
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for (i = 1; i <= 20; i++)
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{
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packets[i] = sampler_test_send_packet(&stest, i,
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i % 2 == 0 ? true : false);
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stest.time += time_between_packets;
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}
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assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 10);
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// Ack packets 2 to 21, ignoring every even-numbered packet, while sending new
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// packets at the same rate as before.
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for (i = 1; i <= 20; i++)
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{
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if (i % 2 == 0)
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{
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sample = sampler_test_ack_packet(&stest, packets[i]);
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assert(sample);
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lsquic_malo_put(sample);
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}
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packets[i + 20] = sampler_test_send_packet(&stest, i + 20,
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i % 2 == 0 ? true : false);
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stest.time += time_between_packets;
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}
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// Ack the packets 22 to 41 with the same congestion controlled pattern.
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for (i = 21; i <= 40; i++)
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{
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if (i % 2 == 0)
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{
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sample = sampler_test_ack_packet(&stest, packets[i]);
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assert(sample);
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assert(expected_bw == BW_VALUE(&sample->bandwidth));
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lsquic_malo_put(sample);
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}
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stest.time += time_between_packets;
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}
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// Since only congestion controlled packets are entered into the map, it has
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// to be empty at this point.
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assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
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assert(stest.bytes_in_flight == 0);
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sampler_test_cleanup(&stest);
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}
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// Simulate a situation where ACKs arrive in burst and earlier than usual, thus
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// producing an ACK rate which is higher than the original send rate.
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static void
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test_compressed_ack (void)
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{
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struct sampler_test stest;
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const lsquic_time_t time_between_packets = ms(1),
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ridiculously_small_time_delta = us(20);
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uint64_t expected_bw = FromKBytesPerSecond(kRegularPacketSize);
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uint64_t bw;
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unsigned i;
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struct bw_sample *sample;
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struct lsquic_packet_out *packets[41];
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sampler_test_init(&stest);
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sampler_test_send_40_packets_and_ack_first_20(&stest,
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time_between_packets, packets);
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// Simulate an RTT somewhat lower than the one for 1-to-21 transmission.
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stest.time += time_between_packets * 15;
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// Ack the packets 21 to 40 almost immediately at once.
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for (i = 21; i <= 40; i++)
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{
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sample = sampler_test_ack_packet(&stest, packets[i]);
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assert(sample);
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stest.time += ridiculously_small_time_delta;
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bw = BW_VALUE(&sample->bandwidth);
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lsquic_malo_put(sample);
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}
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assert(bw == expected_bw);
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assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
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assert(stest.bytes_in_flight == 0);
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sampler_test_cleanup(&stest);
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}
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// Tests receiving ACK packets in the reverse order.
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static void
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test_reordered_ack (void)
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{
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struct sampler_test stest;
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const lsquic_time_t time_between_packets = ms(1);
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uint64_t expected_bw = FromKBytesPerSecond(kRegularPacketSize);
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unsigned i;
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struct bw_sample *sample;
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struct lsquic_packet_out *packets[61];
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sampler_test_init(&stest);
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sampler_test_send_40_packets_and_ack_first_20(&stest,
|
|
time_between_packets, packets);
|
|
|
|
// Ack the packets 21 to 40 in the reverse order, while sending packets 41 to
|
|
// 60.
|
|
for (i = 0; i < 20; i++)
|
|
{
|
|
sample = sampler_test_ack_packet(&stest, packets[40 - i]);
|
|
assert(sample);
|
|
assert(expected_bw == BW_VALUE(&sample->bandwidth));
|
|
packets[41 + i] = sampler_test_send_packet(&stest, 41 + i, true);
|
|
stest.time += time_between_packets;
|
|
lsquic_malo_put(sample);
|
|
}
|
|
|
|
// Ack the packets 41 to 60, now in the regular order.
|
|
for (i = 41; i <= 60; i++)
|
|
{
|
|
sample = sampler_test_ack_packet(&stest, packets[i]);
|
|
assert(sample);
|
|
assert(expected_bw == BW_VALUE(&sample->bandwidth));
|
|
stest.time += time_between_packets;
|
|
lsquic_malo_put(sample);
|
|
}
|
|
|
|
assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
|
|
assert(stest.bytes_in_flight == 0);
|
|
|
|
sampler_test_cleanup(&stest);
|
|
}
|
|
|
|
|
|
// Test the app-limited logic.
|
|
static void
|
|
test_app_limited (void)
|
|
{
|
|
struct sampler_test stest;
|
|
const lsquic_time_t time_between_packets = ms(1);
|
|
uint64_t expected_bw = FromKBytesPerSecond(kRegularPacketSize);
|
|
unsigned i;
|
|
struct bw_sample *sample;
|
|
struct lsquic_packet_out *packets[81];
|
|
|
|
sampler_test_init(&stest);
|
|
sampler_test_send_40_packets_and_ack_first_20(&stest,
|
|
time_between_packets, packets);
|
|
|
|
// We are now app-limited. Ack 21 to 40 as usual, but do not send anything for
|
|
// now.
|
|
lsquic_bw_sampler_app_limited(&stest.sampler);
|
|
for (i = 21; i <= 40; i++)
|
|
{
|
|
sample = sampler_test_ack_packet(&stest, packets[i]);
|
|
assert(sample);
|
|
assert(expected_bw == BW_VALUE(&sample->bandwidth));
|
|
stest.time += time_between_packets;
|
|
lsquic_malo_put(sample);
|
|
}
|
|
|
|
stest.time += sec(1);
|
|
|
|
// Send packets 41 to 60, all of which would be marked as app-limited.
|
|
for (i = 41; i <= 60; i++)
|
|
{
|
|
packets[i] = sampler_test_send_packet(&stest, i, true);
|
|
stest.time += time_between_packets;
|
|
}
|
|
|
|
// Ack packets 41 to 60, while sending packets 61 to 80. 41 to 60 should be
|
|
// app-limited and underestimate the bandwidth due to that.
|
|
for (i = 41; i <= 60; i++)
|
|
{
|
|
sample = sampler_test_ack_packet(&stest, packets[i]);
|
|
assert(sample);
|
|
assert(sample->is_app_limited);
|
|
assert(BW_VALUE(&sample->bandwidth) < 0.7 * expected_bw);
|
|
packets[i + 20] = sampler_test_send_packet(&stest, i + 20, true);
|
|
stest.time += time_between_packets;
|
|
lsquic_malo_put(sample);
|
|
}
|
|
|
|
// Run out of packets, and then ack packet 61 to 80, all of which should have
|
|
// correct non-app-limited samples.
|
|
for (i = 61; i <= 80; i++)
|
|
{
|
|
sample = sampler_test_ack_packet(&stest, packets[i]);
|
|
assert(sample);
|
|
assert(BW_VALUE(&sample->bandwidth) == expected_bw);
|
|
stest.time += time_between_packets;
|
|
lsquic_malo_put(sample);
|
|
}
|
|
|
|
assert(lsquic_bw_sampler_entry_count(&stest.sampler) == 0);
|
|
assert(stest.bytes_in_flight == 0);
|
|
|
|
sampler_test_cleanup(&stest);
|
|
}
|
|
|
|
|
|
// Test the samples taken at the first flight of packets sent.
|
|
static void
|
|
test_first_round_trip (void)
|
|
{
|
|
struct sampler_test stest;
|
|
const lsquic_time_t time_between_packets = ms(1),
|
|
rtt = ms(800);
|
|
const unsigned num_packets = 10;
|
|
const uint64_t num_bytes = num_packets * kRegularPacketSize;
|
|
struct bandwidth real_bandwidth = BW_FROM_BYTES_AND_DELTA(num_bytes, rtt);
|
|
uint64_t last_bw;
|
|
unsigned i;
|
|
struct bw_sample *sample;
|
|
struct lsquic_packet_out *packets[11];
|
|
|
|
sampler_test_init(&stest);
|
|
|
|
for (i = 1; i <= 10; i++)
|
|
{
|
|
packets[i] = sampler_test_send_packet(&stest, i, true);
|
|
stest.time += time_between_packets;
|
|
}
|
|
|
|
stest.time += rtt - num_packets * time_between_packets;
|
|
|
|
last_bw = 0;
|
|
for (i = 1; i <= 10; i++)
|
|
{
|
|
sample = sampler_test_ack_packet(&stest, packets[i]);
|
|
assert(sample);
|
|
assert(BW_VALUE(&sample->bandwidth) > last_bw);
|
|
last_bw = BW_VALUE(&sample->bandwidth);
|
|
stest.time += time_between_packets;
|
|
lsquic_malo_put(sample);
|
|
}
|
|
|
|
// The final measured sample for the first flight of sample is expected to be
|
|
// smaller than the real bandwidth, yet it should not lose more than 10%. The
|
|
// specific value of the error depends on the difference between the RTT and
|
|
// the time it takes to exhaust the congestion window (i.e. in the limit when
|
|
// all packets are sent simultaneously, last sample would indicate the real
|
|
// bandwidth).
|
|
assert(last_bw < real_bandwidth.value);
|
|
assert(last_bw > 0.9f * real_bandwidth.value);
|
|
|
|
sampler_test_cleanup(&stest);
|
|
}
|
|
|
|
|
|
int
|
|
main (void)
|
|
{
|
|
test_send_and_wait();
|
|
test_send_time_state();
|
|
test_send_paced();
|
|
test_send_with_losses();
|
|
test_not_congestion_controlled();
|
|
test_compressed_ack();
|
|
test_reordered_ack();
|
|
test_app_limited();
|
|
test_first_round_trip();
|
|
|
|
return 0;
|
|
}
|