admin/webrtc_m130
1
0
Fork 0
Code Issues Pull Requests Actions Packages Projects Releases Wiki Activity
webrtc_m130/call/fake_network_pipe.cc
Sebastian Jansson 09408115cd Moving demux from FakeNetworkPipe to DirectTransport. 
This CL moves the responsibility for demuxing from FakeNetworkPipe
to DirectTransport. This makes the interface for FakeNetworkPipe more
consistent. It exposes fewer different interfaces for different usages.

It also means that any time degradations applied to the packets due in
FakeNetworkPipe in tests will now be propagated to Call in a more
realistic manner. Previously the time was set to uninitialized which
meant that Call filled in values based on the system clock.

Bug: webrtc:9054
Change-Id: Ie534062f5ae9ad992c06b19e43804138a35702f0
Reviewed-on: https://webrtc-review.googlesource.com/64260
Commit-Queue: Sebastian Jansson <srte@webrtc.org>
Reviewed-by: Christoffer Rodbro <crodbro@webrtc.org>
Reviewed-by: Stefan Holmer <stefan@webrtc.org>
Reviewed-by: Erik Språng <sprang@webrtc.org>
Cr-Commit-Position: refs/heads/master@{#23017}
2018-04-25 10:13:03 +00:00

434 lines
14 KiB
C++
Raw Blame History

/*
* Copyright (c) 2012 The WebRTC project authors. All Rights Reserved.
*
* Use of this source code is governed by a BSD-style license
* that can be found in the LICENSE file in the root of the source
* tree. An additional intellectual property rights grant can be found
* in the file PATENTS. All contributing project authors may
* be found in the AUTHORS file in the root of the source tree.
*/
#include <assert.h>
#include <math.h>
#include <string.h>
#include <algorithm>
#include <cmath>
#include <utility>
#include "call/call.h"
#include "call/fake_network_pipe.h"
#include "rtc_base/logging.h"
#include "system_wrappers/include/clock.h"
namespace webrtc {
namespace {
constexpr int64_t kDefaultProcessIntervalMs = 5;
struct PacketArrivalTimeComparator {
bool operator()(const NetworkPacket& p1, const NetworkPacket& p2) {
return p1.arrival_time() < p2.arrival_time();
}
};
} // namespace
NetworkPacket::NetworkPacket(rtc::CopyOnWriteBuffer packet,
int64_t send_time,
int64_t arrival_time,
rtc::Optional<PacketOptions> packet_options,
bool is_rtcp,
MediaType media_type,
rtc::Optional<PacketTime> packet_time)
: packet_(std::move(packet)),
send_time_(send_time),
arrival_time_(arrival_time),
packet_options_(packet_options),
is_rtcp_(is_rtcp),
media_type_(media_type),
packet_time_(packet_time) {}
NetworkPacket::NetworkPacket(NetworkPacket&& o)
: packet_(std::move(o.packet_)),
send_time_(o.send_time_),
arrival_time_(o.arrival_time_),
packet_options_(o.packet_options_),
is_rtcp_(o.is_rtcp_),
media_type_(o.media_type_),
packet_time_(o.packet_time_) {}
NetworkPacket& NetworkPacket::operator=(NetworkPacket&& o) {
packet_ = std::move(o.packet_);
send_time_ = o.send_time_;
arrival_time_ = o.arrival_time_;
packet_options_ = o.packet_options_;
is_rtcp_ = o.is_rtcp_;
media_type_ = o.media_type_;
packet_time_ = o.packet_time_;
return *this;
}
FakeNetworkPipe::FakeNetworkPipe(Clock* clock,
const FakeNetworkPipe::Config& config)
: FakeNetworkPipe(clock, config, nullptr, 1) {}
FakeNetworkPipe::FakeNetworkPipe(Clock* clock,
const FakeNetworkPipe::Config& config,
PacketReceiver* receiver)
: FakeNetworkPipe(clock, config, receiver, 1) {}
FakeNetworkPipe::FakeNetworkPipe(Clock* clock,
const FakeNetworkPipe::Config& config,
PacketReceiver* receiver,
uint64_t seed)
: clock_(clock),
receiver_(receiver),
transport_(nullptr),
random_(seed),
clock_offset_ms_(0),
config_(),
dropped_packets_(0),
sent_packets_(0),
total_packet_delay_(0),
bursting_(false),
next_process_time_(clock_->TimeInMilliseconds()),
last_log_time_(clock_->TimeInMilliseconds()) {
SetConfig(config);
}
FakeNetworkPipe::FakeNetworkPipe(Clock* clock,
const FakeNetworkPipe::Config& config,
Transport* transport)
: clock_(clock),
receiver_(nullptr),
transport_(transport),
random_(1),
clock_offset_ms_(0),
config_(),
dropped_packets_(0),
sent_packets_(0),
total_packet_delay_(0),
bursting_(false),
next_process_time_(clock_->TimeInMilliseconds()),
last_log_time_(clock_->TimeInMilliseconds()) {
SetConfig(config);
}
FakeNetworkPipe::~FakeNetworkPipe() = default;
void FakeNetworkPipe::SetReceiver(PacketReceiver* receiver) {
rtc::CritScope crit(&config_lock_);
receiver_ = receiver;
}
bool FakeNetworkPipe::SendRtp(const uint8_t* packet,
size_t length,
const PacketOptions& options) {
RTC_DCHECK(HasTransport());
EnqueuePacket(rtc::CopyOnWriteBuffer(packet, length), options, false,
MediaType::ANY, rtc::nullopt);
return true;
}
bool FakeNetworkPipe::SendRtcp(const uint8_t* packet, size_t length) {
RTC_DCHECK(HasTransport());
EnqueuePacket(rtc::CopyOnWriteBuffer(packet, length), rtc::nullopt, true,
MediaType::ANY, rtc::nullopt);
return true;
}
PacketReceiver::DeliveryStatus FakeNetworkPipe::DeliverPacket(
MediaType media_type,
rtc::CopyOnWriteBuffer packet,
const PacketTime& packet_time) {
return EnqueuePacket(std::move(packet), rtc::nullopt, false, media_type,
packet_time)
? PacketReceiver::DELIVERY_OK
: PacketReceiver::DELIVERY_PACKET_ERROR;
}
void FakeNetworkPipe::SetClockOffset(int64_t offset_ms) {
rtc::CritScope crit(&config_lock_);
clock_offset_ms_ = offset_ms;
}
void FakeNetworkPipe::SetConfig(const FakeNetworkPipe::Config& config) {
rtc::CritScope crit(&config_lock_);
config_ = config; // Shallow copy of the struct.
double prob_loss = config.loss_percent / 100.0;
if (config_.avg_burst_loss_length == -1) {
// Uniform loss
prob_loss_bursting_ = prob_loss;
prob_start_bursting_ = prob_loss;
} else {
// Lose packets according to a gilbert-elliot model.
int avg_burst_loss_length = config.avg_burst_loss_length;
int min_avg_burst_loss_length = std::ceil(prob_loss / (1 - prob_loss));
RTC_CHECK_GT(avg_burst_loss_length, min_avg_burst_loss_length)
<< "For a total packet loss of " << config.loss_percent << "%% then"
<< " avg_burst_loss_length must be " << min_avg_burst_loss_length + 1
<< " or higher.";
prob_loss_bursting_ = (1.0 - 1.0 / avg_burst_loss_length);
prob_start_bursting_ = prob_loss / (1 - prob_loss) / avg_burst_loss_length;
}
}
bool FakeNetworkPipe::EnqueuePacket(rtc::CopyOnWriteBuffer packet,
rtc::Optional<PacketOptions> options,
bool is_rtcp,
MediaType media_type,
rtc::Optional<PacketTime> packet_time) {
Config config;
{
rtc::CritScope crit(&config_lock_);
config = config_;
}
rtc::CritScope crit(&process_lock_);
if (config.queue_length_packets > 0 &&
capacity_link_.size() >= config.queue_length_packets) {
// Too many packet on the link, drop this one.
++dropped_packets_;
return false;
}
int64_t time_now = clock_->TimeInMilliseconds();
// Delay introduced by the link capacity.
int64_t capacity_delay_ms = 0;
if (config.link_capacity_kbps > 0) {
const int bytes_per_millisecond = config.link_capacity_kbps / 8;
// To round to the closest millisecond we add half a milliseconds worth of
// bytes to the delay calculation.
capacity_delay_ms = (packet.size() + capacity_delay_error_bytes_ +
bytes_per_millisecond / 2) /
bytes_per_millisecond;
capacity_delay_error_bytes_ +=
packet.size() - capacity_delay_ms * bytes_per_millisecond;
}
int64_t network_start_time = time_now;
// Check if there already are packets on the link and change network start
// time forward if there is.
if (!capacity_link_.empty() &&
network_start_time < capacity_link_.back().arrival_time())
network_start_time = capacity_link_.back().arrival_time();
int64_t arrival_time = network_start_time + capacity_delay_ms;
capacity_link_.emplace(std::move(packet), time_now, arrival_time, options,
is_rtcp, media_type, packet_time);
return true;
}
float FakeNetworkPipe::PercentageLoss() {
rtc::CritScope crit(&process_lock_);
if (sent_packets_ == 0)
return 0;
return static_cast<float>(dropped_packets_) /
(sent_packets_ + dropped_packets_);
}
int FakeNetworkPipe::AverageDelay() {
rtc::CritScope crit(&process_lock_);
if (sent_packets_ == 0)
return 0;
return static_cast<int>(total_packet_delay_ /
static_cast<int64_t>(sent_packets_));
}
size_t FakeNetworkPipe::DroppedPackets() {
rtc::CritScope crit(&process_lock_);
return dropped_packets_;
}
size_t FakeNetworkPipe::SentPackets() {
rtc::CritScope crit(&process_lock_);
return sent_packets_;
}
void FakeNetworkPipe::Process() {
int64_t time_now = clock_->TimeInMilliseconds();
std::queue<NetworkPacket> packets_to_deliver;
Config config;
double prob_loss_bursting;
double prob_start_bursting;
{
rtc::CritScope crit(&config_lock_);
config = config_;
prob_loss_bursting = prob_loss_bursting_;
prob_start_bursting = prob_start_bursting_;
}
{
rtc::CritScope crit(&process_lock_);
if (time_now - last_log_time_ > 5000) {
int64_t queueing_delay_ms = 0;
if (!capacity_link_.empty()) {
queueing_delay_ms = time_now - capacity_link_.front().send_time();
}
RTC_LOG(LS_INFO) << "Network queue: " << queueing_delay_ms << " ms.";
last_log_time_ = time_now;
}
// Check the capacity link first.
if (!capacity_link_.empty()) {
int64_t last_arrival_time =
delay_link_.empty() ? -1 : delay_link_.back().arrival_time();
bool needs_sort = false;
while (!capacity_link_.empty() &&
time_now >= capacity_link_.front().arrival_time()) {
// Time to get this packet.
NetworkPacket packet = std::move(capacity_link_.front());
capacity_link_.pop();
// Drop packets at an average rate of |config_.loss_percent| with
// and average loss burst length of |config_.avg_burst_loss_length|.
if ((bursting_ && random_.Rand<double>() < prob_loss_bursting) ||
(!bursting_ && random_.Rand<double>() < prob_start_bursting)) {
bursting_ = true;
continue;
} else {
bursting_ = false;
}
int arrival_time_jitter = random_.Gaussian(
config.queue_delay_ms, config.delay_standard_deviation_ms);
// If reordering is not allowed then adjust arrival_time_jitter
// to make sure all packets are sent in order.
if (!config.allow_reordering && !delay_link_.empty() &&
packet.arrival_time() + arrival_time_jitter < last_arrival_time) {
arrival_time_jitter = last_arrival_time - packet.arrival_time();
}
packet.IncrementArrivalTime(arrival_time_jitter);
if (packet.arrival_time() >= last_arrival_time) {
last_arrival_time = packet.arrival_time();
} else {
needs_sort = true;
}
delay_link_.emplace_back(std::move(packet));
}
if (needs_sort) {
// Packet(s) arrived out of order, make sure list is sorted.
std::sort(delay_link_.begin(), delay_link_.end(),
PacketArrivalTimeComparator());
}
}
// Check the extra delay queue.
while (!delay_link_.empty() &&
time_now >= delay_link_.front().arrival_time()) {
// Deliver this packet.
NetworkPacket packet(std::move(delay_link_.front()));
delay_link_.pop_front();
// |time_now| might be later than when the packet should have arrived, due
// to NetworkProcess being called too late. For stats, use the time it
// should have been on the link.
total_packet_delay_ += packet.arrival_time() - packet.send_time();
packets_to_deliver.push(std::move(packet));
}
sent_packets_ += packets_to_deliver.size();
}
rtc::CritScope crit(&config_lock_);
while (!packets_to_deliver.empty()) {
NetworkPacket packet = std::move(packets_to_deliver.front());
packets_to_deliver.pop();
DeliverPacket(&packet);
}
next_process_time_ = !delay_link_.empty()
? delay_link_.begin()->arrival_time()
: time_now + kDefaultProcessIntervalMs;
}
void FakeNetworkPipe::DeliverPacket(NetworkPacket* packet) {
if (transport_) {
RTC_DCHECK(!receiver_);
if (packet->is_rtcp()) {
transport_->SendRtcp(packet->data(), packet->data_length());
} else {
transport_->SendRtp(packet->data(), packet->data_length(),
packet->packet_options());
}
} else if (receiver_) {
PacketTime packet_time = packet->packet_time();
if (packet_time.timestamp != -1) {
int64_t queue_time = packet->arrival_time() - packet->send_time();
RTC_CHECK(queue_time >= 0);
packet_time.timestamp += (queue_time * 1000);
packet_time.timestamp += (clock_offset_ms_ * 1000);
}
receiver_->DeliverPacket(packet->media_type(),
std::move(*packet->raw_packet()), packet_time);
}
}
int64_t FakeNetworkPipe::TimeUntilNextProcess() {
rtc::CritScope crit(&process_lock_);
return std::max<int64_t>(next_process_time_ - clock_->TimeInMilliseconds(),
0);
}
bool FakeNetworkPipe::HasTransport() const {
rtc::CritScope crit(&config_lock_);
return transport_ != nullptr;
}
bool FakeNetworkPipe::HasReceiver() const {
rtc::CritScope crit(&config_lock_);
return receiver_ != nullptr;
}
void FakeNetworkPipe::DeliverPacketWithLock(NetworkPacket* packet) {
rtc::CritScope crit(&config_lock_);
DeliverPacket(packet);
}
void FakeNetworkPipe::ResetStats() {
rtc::CritScope crit(&process_lock_);
dropped_packets_ = 0;
sent_packets_ = 0;
total_packet_delay_ = 0;
}
int FakeNetworkPipe::GetConfigCapacityKbps() const {
rtc::CritScope crit(&config_lock_);
return config_.link_capacity_kbps;
}
void FakeNetworkPipe::AddToPacketDropCount() {
rtc::CritScope crit(&process_lock_);
++dropped_packets_;
}
void FakeNetworkPipe::AddToPacketSentCount(int count) {
rtc::CritScope crit(&process_lock_);
sent_packets_ += count;
}
void FakeNetworkPipe::AddToTotalDelay(int delay_ms) {
rtc::CritScope crit(&process_lock_);
total_packet_delay_ += delay_ms;
}
int64_t FakeNetworkPipe::GetTimeInMilliseconds() const {
return clock_->TimeInMilliseconds();
}
bool FakeNetworkPipe::IsRandomLoss(double prob_loss) {
return random_.Rand<double>() < prob_loss;
}
bool FakeNetworkPipe::ShouldProcess(int64_t time_now) const {
return time_now >= next_process_time_;
}
void FakeNetworkPipe::SetTimeToNextProcess(int64_t skip_ms) {
next_process_time_ += skip_ms;
}
} // namespace webrtc
Reference in New Issue View Git Blame Copy Permalink