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fuchsia / fuchsia / refs/heads/releases/field-image-dogfood / . / src / tests / microbenchmarks / round_trips.cc
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// Copyright 2017 The Fuchsia Authors. All rights reserved.
// Use of this source code is governed by a BSD-style license that can be
// found in the LICENSE file.
#include "round_trips.h"
#include <fuchsia/zircon/benchmarks/cpp/fidl.h>
#include <lib/async-loop/cpp/loop.h>
#include <lib/async-loop/default.h>
#include <lib/fdio/spawn.h>
#include <lib/syslog/cpp/macros.h>
#include <lib/zx/channel.h>
#include <lib/zx/handle.h>
#include <pthread.h>
#include <zircon/process.h>
#include <zircon/processargs.h>
#include <zircon/syscalls.h>
#include <zircon/syscalls/port.h>
#include <iterator>
#include <thread>
#include <vector>
#include "assert.h"
#include "lib/fidl/cpp/binding.h"
#include "test_runner.h"
// This file measures two things:
//
// 1) The round-trip time of various operations, including Zircon kernel IPC
// primitives. This measures the latency of sending a request to another thread
// or process and receiving a reply back. In this case, there's little
// opportunity for concurrency between the two threads.
//
// 2) The throughput of IPC operations. This is similar to measuring the
// round-trip time, except that instead of sending and receiving one message,
// the main thread sends N messages and then waits for N messages in reply.
// This allows for more concurrency between the two threads. Currently we only
// test this for Zircon channels.
//
// Note that the first case is a special case of the second case, with N=1.
//
// These tests generally use the same IPC primitive in both directions
// (i.e. from client to server and from server to client) for sending and
// receiving wakeups. There are a couple of reasons for that:
//
// * This allows us to estimate the one-way latency of the IPC primitive
// by dividing the round-trip latency by 2.
// * This keeps the number of tests manageable. If we mixed the
// primitives, the number of possible combinations would be O(n^2) in
// the number of primitives. (For example, we could signal using a
// channel in one direction and a futex in the other direction.)
//
// An exception is zx_channel_call(), which generally can't be used by a
// server process for receiving requests.
namespace {
// Block and read a message of size |msg->size()| into |msg| from a channel.
// Returns false if the channel's peer was closed.
bool ChannelRead(const zx::channel& channel, std::vector<uint8_t>* msg) {
zx_signals_t observed;
ASSERT_OK(channel.wait_one(ZX_CHANNEL_READABLE | ZX_CHANNEL_PEER_CLOSED, zx::time::infinite(),
&observed));
if (observed & ZX_CHANNEL_PEER_CLOSED)
return false;
uint32_t bytes_read;
ASSERT_OK(channel.read(0, msg->data(), nullptr, static_cast<uint32_t>(msg->size()), 0,
&bytes_read, nullptr));
FX_CHECK(bytes_read == msg->size());
return true;
}
// Block and read |count| messages of size |msg->size()| into |msg| from a
// channel. Returns false if the channel's peer was closed.
bool ChannelReadMultiple(const zx::channel& channel, uint32_t count, std::vector<uint8_t>* msg) {
for (uint32_t i = 0; i < count; ++i) {
if (!ChannelRead(channel, msg))
return false;
}
return true;
}
// Serve requests on a channel: read |count| messages of size |size| and write
// |count| replies.
void ChannelServe(const zx::channel& channel, uint32_t count, uint32_t size) {
std::vector<uint8_t> msg(size);
for (;;) {
if (!ChannelReadMultiple(channel, count, &msg))
break;
for (uint32_t i = 0; i < count; ++i) {
ASSERT_OK(channel.write(0, msg.data(), static_cast<uint32_t>(msg.size()), nullptr, 0));
}
}
}
typedef void (*ThreadFunc)(std::vector<zx::handle>&& handles);
ThreadFunc GetThreadFunc(const char* name);
enum MultiProc {
SingleProcess = 1,
MultiProcess = 2,
};
// Helper class for launching a thread or a subprocess.
class ThreadOrProcess {
public:
~ThreadOrProcess() {
if (thread_.joinable())
thread_.join();
if (subprocess_) {
// Join the process.
ASSERT_OK(subprocess_.wait_one(ZX_PROCESS_TERMINATED, zx::time::infinite(), nullptr));
}
}
void Launch(const char* func_name, std::vector<zx::handle>&& handles, MultiProc multiproc) {
if (multiproc == MultiProcess) {
const char* executable_path = "/bin/fuchsia_microbenchmarks";
const char* args[] = {executable_path, "--subprocess", func_name, nullptr};
size_t action_count = handles.size() + 1;
fdio_spawn_action_t actions[action_count];
for (uint32_t i = 0; i < handles.size(); ++i) {
actions[i].action = FDIO_SPAWN_ACTION_ADD_HANDLE;
actions[i].h.id = PA_HND(PA_USER0, i);
actions[i].h.handle = handles[i].release();
}
actions[handles.size()].action = FDIO_SPAWN_ACTION_SET_NAME;
actions[handles.size()].name.data = "test-process";
char err_msg[FDIO_SPAWN_ERR_MSG_MAX_LENGTH];
if (fdio_spawn_etc(ZX_HANDLE_INVALID, FDIO_SPAWN_CLONE_ALL, executable_path, args, nullptr,
action_count, actions, subprocess_.reset_and_get_address(),
err_msg) != ZX_OK) {
FX_LOGS(FATAL) << "Subprocess launch failed: " << err_msg;
}
} else {
thread_ = std::thread(GetThreadFunc(func_name), std::move(handles));
}
}
private:
std::thread thread_;
zx::process subprocess_;
};
// Convenience function for creating a vector of zx::handles.
std::vector<zx::handle> MakeHandleVector(zx_handle_t handle) {
// Note that "std::vector<zx::handle> v{h}" creates a vector of size h,
// which is not what we want.
std::vector<zx::handle> vec(1);
vec[0] = zx::handle(handle);
return vec;
}
// Test IPC round trips and/or throughput using Zircon channels where the client
// and server both use zx_object_wait_one() to wait.
class BasicChannelTest {
public:
explicit BasicChannelTest(MultiProc multiproc, uint32_t msg_count, uint32_t msg_size)
: args_({msg_count, msg_size}), msg_(args_.msg_size) {
zx::channel server;
ASSERT_OK(zx::channel::create(0, &server, &client_));
thread_or_process_.Launch("BasicChannelTest::ThreadFunc", MakeHandleVector(server.release()),
multiproc);
// Pass the test arguments to the other thread.
ASSERT_OK(client_.write(0, &args_, sizeof(args_), nullptr, 0));
}
static void ThreadFunc(std::vector<zx::handle>&& handles) {
FX_CHECK(handles.size() == 1);
zx::channel channel(std::move(handles[0]));
Args args;
GetArgs(channel, &args);
ChannelServe(channel, args.msg_count, args.msg_size);
}
void Run() {
for (unsigned i = 0; i < args_.msg_count; ++i) {
ASSERT_OK(client_.write(0, msg_.data(), static_cast<uint32_t>(msg_.size()), nullptr, 0));
}
FX_CHECK(ChannelReadMultiple(client_, args_.msg_count, &msg_));
}
private:
// Holds the test arguments sent over a channel.
struct Args {
uint32_t msg_count;
uint32_t msg_size;
};
// Reads test arguments from |channel| and stores them in |args|.
static void GetArgs(const zx::channel& channel, Args* args) {
std::vector<uint8_t> msg(sizeof(*args));
FX_CHECK(ChannelRead(channel, &msg));
*args = *reinterpret_cast<Args*>(msg.data());
}
const Args args_;
std::vector<uint8_t> msg_;
ThreadOrProcess thread_or_process_;
zx::channel client_;
};
// Test IPC round trips using Zircon channels where the client and server
// both use Zircon ports to wait.
class ChannelPortTest {
public:
explicit ChannelPortTest(MultiProc multiproc) {
zx::channel server;
ASSERT_OK(zx::channel::create(0, &server, &client_));
thread_or_process_.Launch("ChannelPortTest::ThreadFunc", MakeHandleVector(server.release()),
multiproc);
ASSERT_OK(zx::port::create(0, &client_port_));
}
static bool ChannelPortRead(const zx::channel& channel, const zx::port& port, uint32_t* msg) {
ASSERT_OK(channel.wait_async(port, 0, ZX_CHANNEL_READABLE | ZX_CHANNEL_PEER_CLOSED, 0));
zx_port_packet_t packet;
ASSERT_OK(port.wait(zx::time::infinite(), &packet));
if (packet.signal.observed & ZX_CHANNEL_PEER_CLOSED)
return false;
uint32_t bytes_read;
ASSERT_OK(channel.read(0, msg, nullptr, sizeof(*msg), 0, &bytes_read, nullptr));
FX_CHECK(bytes_read == sizeof(*msg));
return true;
}
static void ThreadFunc(std::vector<zx::handle>&& handles) {
FX_CHECK(handles.size() == 1);
zx::channel channel(std::move(handles[0]));
zx::port port;
ASSERT_OK(zx::port::create(0, &port));
for (;;) {
uint32_t msg;
if (!ChannelPortRead(channel, port, &msg))
break;
ASSERT_OK(channel.write(0, &msg, sizeof(msg), nullptr, 0));
}
}
void Run() {
uint32_t msg = 123;
ASSERT_OK(client_.write(0, &msg, sizeof(msg), nullptr, 0));
FX_CHECK(ChannelPortRead(client_, client_port_, &msg));
}
private:
ThreadOrProcess thread_or_process_;
zx::channel client_;
zx::port client_port_;
};
// Test IPC round trips using Zircon channels where the server uses
// zx_object_wait_one() to wait (as with BasicChannelTest) but the client
// uses zx_channel_call() for the send+wait+read.
class ChannelCallTest {
public:
explicit ChannelCallTest(MultiProc multiproc) {
zx::channel server;
ASSERT_OK(zx::channel::create(0, &server, &client_));
thread_or_process_.Launch("ChannelCallTest::ThreadFunc", MakeHandleVector(server.release()),
multiproc);
msg_ = 0;
args_.wr_bytes = reinterpret_cast<void*>(&msg_);
args_.wr_handles = nullptr;
args_.rd_bytes = reinterpret_cast<void*>(&reply_);
args_.rd_handles = nullptr;
args_.wr_num_bytes = sizeof(msg_);
args_.wr_num_handles = 0;
args_.rd_num_bytes = sizeof(reply_);
args_.rd_num_handles = 0;
}
static void ThreadFunc(std::vector<zx::handle>&& handles) {
FX_CHECK(handles.size() == 1);
zx::channel channel(std::move(handles[0]));
ChannelServe(channel, /* count= */ 1, /* size= */ 4);
}
void Run() {
uint32_t bytes_read;
uint32_t handles_read;
ASSERT_OK(client_.call(0, zx::time::infinite(), &args_, &bytes_read, &handles_read));
}
private:
ThreadOrProcess thread_or_process_;
zx::channel client_;
uint32_t msg_;
uint32_t reply_;
zx_channel_call_args_t args_;
};
// Test IPC round trips using Zircon ports, where the client and server
// send each other user packets. This is not a normal use case for ports,
// but it is useful for measuring the overhead of ports.
class PortTest {
public:
explicit PortTest(MultiProc multiproc) {
ASSERT_OK(zx::port::create(0, &ports_[0]));
ASSERT_OK(zx::port::create(0, &ports_[1]));
std::vector<zx::handle> ports_dup(2);
for (int i = 0; i < 2; ++i) {
zx::port dup;
ASSERT_OK(ports_[i].duplicate(ZX_RIGHT_SAME_RIGHTS, &dup));
ports_dup[i] = std::move(dup);
}
thread_or_process_.Launch("PortTest::ThreadFunc", std::move(ports_dup), multiproc);
}
~PortTest() {
// Tell the server to shut down.
zx_port_packet_t packet = {};
packet.type = ZX_PKT_TYPE_USER;
packet.user.u32[0] = 1;
ASSERT_OK(ports_[0].queue(&packet));
}
static void ThreadFunc(std::vector<zx::handle>&& ports) {
FX_CHECK(ports.size() == 2);
for (;;) {
zx_port_packet_t packet;
ASSERT_OK(zx_port_wait(ports[0].get(), ZX_TIME_INFINITE, &packet));
// Check for a request to shut down.
if (packet.user.u32[0])
break;
ASSERT_OK(zx_port_queue(ports[1].get(), &packet));
}
}
void Run() {
zx_port_packet_t packet = {};
packet.type = ZX_PKT_TYPE_USER;
ASSERT_OK(ports_[0].queue(&packet));
ASSERT_OK(ports_[1].wait(zx::time::infinite(), &packet));
}
private:
zx::port ports_[2];
ThreadOrProcess thread_or_process_;
};
// Helper object for signaling and waiting on a Zircon event object. This
// uses a port for waiting on the event object.
class EventPortSignaler {
public:
EventPortSignaler() { ASSERT_OK(zx::port::create(0, &port_)); }
void set_event(zx::eventpair&& event) { event_ = std::move(event); }
// Waits for the event to be signaled. Returns true if it was signaled
// by Signal() and false if the peer event object was closed.
bool Wait() {
ASSERT_OK(event_.wait_async(port_, 0, ZX_USER_SIGNAL_0 | ZX_EVENTPAIR_PEER_CLOSED, 0));
zx_port_packet_t packet;
ASSERT_OK(port_.wait(zx::time::infinite(), &packet));
if (packet.signal.observed & ZX_EVENTPAIR_PEER_CLOSED)
return false;
// Clear the signal bit.
ASSERT_OK(event_.signal(ZX_USER_SIGNAL_0, 0));
return true;
}
void Signal() {
// Set a signal bit.
ASSERT_OK(event_.signal_peer(0, ZX_USER_SIGNAL_0));
}
private:
zx::eventpair event_;
zx::port port_;
};
// Test the round trip time for waking up threads by signaling using Zircon
// event objects. This uses ports for waiting on the events (rather than
// zx_object_wait_one()), because ports are the most general way to wait.
class EventPortTest {
public:
explicit EventPortTest(MultiProc multiproc) {
zx::eventpair event1;
zx::eventpair event2;
ASSERT_OK(zx::eventpair::create(0, &event1, &event2));
signaler_.set_event(std::move(event1));
thread_or_process_.Launch("EventPortTest::ThreadFunc", MakeHandleVector(event2.release()),
multiproc);
}
static void ThreadFunc(std::vector<zx::handle>&& handles) {
FX_CHECK(handles.size() == 1);
EventPortSignaler signaler;
signaler.set_event(zx::eventpair(handles[0].get()));
while (signaler.Wait()) {
signaler.Signal();
}
}
void Run() {
signaler_.Signal();
FX_CHECK(signaler_.Wait());
}
private:
ThreadOrProcess thread_or_process_;
EventPortSignaler signaler_;
};
// Helper object for signaling and waiting on a Zircon socket object. This
// uses a port for waiting on the socket object.
class SocketPortSignaler {
public:
SocketPortSignaler() { ASSERT_OK(zx::port::create(0, &port_)); }
void set_socket(zx::socket&& socket) { socket_ = std::move(socket); }
// Waits for the socket to be signaled: reads a byte from the socket.
// Returns true if it was signaled by Signal() and false if it was
// signaled by SignalExit().
bool Wait() {
ASSERT_OK(socket_.wait_async(port_, 0, ZX_SOCKET_READABLE | ZX_SOCKET_PEER_CLOSED, 0));
zx_port_packet_t packet;
ASSERT_OK(port_.wait(zx::time::infinite(), &packet));
if (packet.signal.observed & ZX_SOCKET_PEER_CLOSED)
return false;
uint8_t message;
size_t bytes_read = 0;
ASSERT_OK(socket_.read(0, &message, 1, &bytes_read));
FX_CHECK(bytes_read == 1);
return true;
}
// Signal the socket by writing a byte to it.
void Signal() {
uint8_t message = 0;
size_t bytes_written = 0;
ASSERT_OK(socket_.write(0, &message, 1, &bytes_written));
FX_CHECK(bytes_written == 1);
}
private:
zx::socket socket_;
zx::port port_;
};
// Test the round trip time for waking up threads by reading and writing
// bytes on Zircon socket objects. This uses ports for waiting on the
// sockets (rather than zx_object_wait_one()), because ports are the most
// general way to wait.
class SocketPortTest {
public:
explicit SocketPortTest(MultiProc multiproc) {
zx::socket socket1;
zx::socket socket2;
ASSERT_OK(zx::socket::create(0, &socket1, &socket2));
signaler_.set_socket(std::move(socket1));
thread_or_process_.Launch("SocketPortTest::ThreadFunc", MakeHandleVector(socket2.release()),
multiproc);
}
static void ThreadFunc(std::vector<zx::handle>&& handles) {
FX_CHECK(handles.size() == 1);
SocketPortSignaler signaler;
signaler.set_socket(zx::socket(handles[0].get()));
while (signaler.Wait()) {
signaler.Signal();
}
}
void Run() {
signaler_.Signal();
FX_CHECK(signaler_.Wait());
}
private:
ThreadOrProcess thread_or_process_;
SocketPortSignaler signaler_;
};
// Implementation of FIDL interface for testing round trip IPCs.
class RoundTripServiceImpl : public fuchsia::zircon::benchmarks::RoundTripService {
public:
void RoundTripTest(uint32_t arg, RoundTripTestCallback callback) override {
FX_CHECK(arg == 123);
callback(456);
}
};
// Test IPC round trips using FIDL IPC. This uses a synchronous IPC on the
// client side.
class FidlTest {
public:
explicit FidlTest(MultiProc multiproc) {
zx_handle_t server = service_ptr_.NewRequest().TakeChannel().release();
thread_or_process_.Launch("FidlTest::ThreadFunc", MakeHandleVector(server), multiproc);
}
static void ThreadFunc(std::vector<zx::handle>&& handles) {
FX_CHECK(handles.size() == 1);
zx::channel channel(std::move(handles[0]));
async::Loop loop(&kAsyncLoopConfigAttachToCurrentThread);
RoundTripServiceImpl service_impl;
fidl::Binding<fuchsia::zircon::benchmarks::RoundTripService> binding(&service_impl,
std::move(channel));
binding.set_error_handler([&loop](zx_status_t status) { loop.Quit(); });
loop.Run();
}
void Run() {
uint32_t result;
ASSERT_OK(service_ptr_->RoundTripTest(123, &result));
FX_CHECK(result == 456);
}
private:
ThreadOrProcess thread_or_process_;
fuchsia::zircon::benchmarks::RoundTripServiceSyncPtr service_ptr_;
};
// Test the round trip time for waking up threads using Zircon futexes.
// Note that Zircon does not support cross-process futexes, only
// within-process futexes, so there is no multi-process version of this
// test case.
class FutexTest {
public:
FutexTest() {
thread_ = std::thread([this]() { ThreadFunc(); });
}
~FutexTest() {
Wake(&futex1_, 2); // Tell the thread to shut down.
thread_.join();
}
void Run() {
Wake(&futex1_, 1);
FX_CHECK(!Wait(&futex2_));
}
private:
void ThreadFunc() {
for (;;) {
if (Wait(&futex1_))
break;
Wake(&futex2_, 1);
}
}
void Wake(volatile int* ptr, int wake_value) {
*ptr = wake_value;
ASSERT_OK(zx_futex_wake(const_cast<int*>(ptr), 1));
}
bool Wait(volatile int* ptr) {
for (;;) {
int val = *ptr;
if (val != 0) {
// We were signaled. Reset the state to unsignaled.
*ptr = 0;
// Return whether we got a request to shut down.
return val == 2;
}
zx_status_t status =
zx_futex_wait(const_cast<int*>(ptr), val, ZX_HANDLE_INVALID, ZX_TIME_INFINITE);
FX_CHECK(status == ZX_OK || status == ZX_ERR_BAD_STATE);
}
}
std::thread thread_;
volatile int futex1_ = 0; // Signals from client to server.
volatile int futex2_ = 0; // Signals from server to client.
};
// Test the round trip time for waking up threads using pthread condition
// variables (condvars). Condvars are implemented using futexes, so we
// expect this to be a bit slower than FutexTest due to the overhead that
// pthread's condvar implementation adds.
class PthreadCondvarTest {
public:
PthreadCondvarTest() {
FX_CHECK(pthread_mutex_init(&mutex_, nullptr) == 0);
FX_CHECK(pthread_cond_init(&condvar1_, nullptr) == 0);
FX_CHECK(pthread_cond_init(&condvar2_, nullptr) == 0);
thread_ = std::thread([this]() { ThreadFunc(); });
}
~PthreadCondvarTest() {
// Tell the thread to shut down.
FX_CHECK(pthread_mutex_lock(&mutex_) == 0);
state_ = EXIT;
FX_CHECK(pthread_cond_signal(&condvar1_) == 0);
FX_CHECK(pthread_mutex_unlock(&mutex_) == 0);
thread_.join();
FX_CHECK(pthread_cond_destroy(&condvar1_) == 0);
FX_CHECK(pthread_cond_destroy(&condvar2_) == 0);
FX_CHECK(pthread_mutex_destroy(&mutex_) == 0);
}
void Run() {
FX_CHECK(pthread_mutex_lock(&mutex_) == 0);
// Wake the child.
state_ = WAKE_CHILD;
FX_CHECK(pthread_cond_signal(&condvar1_) == 0);
// Wait for the reply.
while (state_ != REPLY_TO_PARENT)
FX_CHECK(pthread_cond_wait(&condvar2_, &mutex_) == 0);
FX_CHECK(pthread_mutex_unlock(&mutex_) == 0);
}
private:
void ThreadFunc() {
FX_CHECK(pthread_mutex_lock(&mutex_) == 0);
for (;;) {
if (state_ == EXIT)
break;
if (state_ == WAKE_CHILD) {
state_ = REPLY_TO_PARENT;
FX_CHECK(pthread_cond_signal(&condvar2_) == 0);
}
FX_CHECK(pthread_cond_wait(&condvar1_, &mutex_) == 0);
}
FX_CHECK(pthread_mutex_unlock(&mutex_) == 0);
}
std::thread thread_;
pthread_mutex_t mutex_;
pthread_cond_t condvar1_; // Signals from parent to child.
pthread_cond_t condvar2_; // Signals from child to parent.
enum { INITIAL, WAKE_CHILD, REPLY_TO_PARENT, EXIT } state_ = INITIAL;
};
struct ThreadFuncEntry {
const char* name;
ThreadFunc func;
};
// clang-format off
const ThreadFuncEntry thread_funcs[] = {
#define DEF_FUNC(FUNC) { #FUNC, FUNC },
DEF_FUNC(BasicChannelTest::ThreadFunc)
DEF_FUNC(ChannelPortTest::ThreadFunc)
DEF_FUNC(ChannelCallTest::ThreadFunc)
DEF_FUNC(PortTest::ThreadFunc)
DEF_FUNC(EventPortTest::ThreadFunc)
DEF_FUNC(SocketPortTest::ThreadFunc)
DEF_FUNC(FidlTest::ThreadFunc)
#undef DEF_FUNC
};
// clang-format on
ThreadFunc GetThreadFunc(const char* name) {
for (size_t i = 0; i < std::size(thread_funcs); ++i) {
if (!strcmp(name, thread_funcs[i].name))
return thread_funcs[i].func;
}
FX_LOGS(FATAL) << "Thread function not found: " << name;
return nullptr;
}
// Register a test that has two variants, single-process and multi-process.
template <class TestClass, typename... Args>
void RegisterTestMultiProc(const char* base_name, Args... args) {
fbenchmark::RegisterTest<TestClass>((std::string(base_name) + "_SingleProcess").c_str(),
SingleProcess, std::forward<Args>(args)...);
fbenchmark::RegisterTest<TestClass>((std::string(base_name) + "_MultiProcess").c_str(),
MultiProcess, std::forward<Args>(args)...);
}
__attribute__((constructor)) void RegisterTests() {
RegisterTestMultiProc<BasicChannelTest>("RoundTrip_BasicChannel",
/* count= */ 1, /* size= */ 4);
RegisterTestMultiProc<BasicChannelTest>("IpcThroughput_BasicChannel_1_64kbytes",
/* msg_count= */ 1, /* msg_size= */ 64 * 1024);
// These next two benchmarks allocate and free a significant amount of
// memory so their performance can be heavily dependent on kernel allocator
// performance.
RegisterTestMultiProc<BasicChannelTest>("IpcThroughput_BasicChannel_1024_4bytes",
/* msg_count= */ 1024, /* msg_size= */ 4);
RegisterTestMultiProc<BasicChannelTest>("IpcThroughput_BasicChannel_1024_64kbytes",
/* msg_count= */ 1024, /* msg_size= */ 64 * 1024);
RegisterTestMultiProc<ChannelPortTest>("RoundTrip_ChannelPort");
RegisterTestMultiProc<ChannelCallTest>("RoundTrip_ChannelCall");
RegisterTestMultiProc<PortTest>("RoundTrip_Port");
RegisterTestMultiProc<EventPortTest>("RoundTrip_EventPort");
RegisterTestMultiProc<SocketPortTest>("RoundTrip_SocketPort");
RegisterTestMultiProc<FidlTest>("RoundTrip_Fidl");
fbenchmark::RegisterTest<FutexTest>("RoundTrip_Futex_SingleProcess");
fbenchmark::RegisterTest<PthreadCondvarTest>("RoundTrip_PthreadCondvar_SingleProcess");
}
} // namespace
void RunSubprocess(const char* func_name) {
auto func = GetThreadFunc(func_name);
// Retrieve the handles.
std::vector<zx::handle> handles;
for (;;) {
uint32_t index = static_cast<uint32_t>(handles.size());
zx::handle handle(zx_take_startup_handle(PA_HND(PA_USER0, index)));
if (!handle)
break;
handles.push_back(std::move(handle));
}
func(std::move(handles));
}