platform_system_core/adb/transport.cpp
Josh Gao 2783122071 Move adbd's legacy USB implementation to fastboot.
This code path is effectively dead in adbd, and fastboot's dependency on
libadbd makes it hard to refactor adbd's dependencies.

Bug: http://b/150317254
Test: built and flashed aosp_walleye-eng
Change-Id: I5118136d32fdcbbd011559ed0a4a71e1dc7bf064
Merged-In: I5118136d32fdcbbd011559ed0a4a71e1dc7bf064
(cherry picked from commit 0871824de6)
2020-03-31 16:05:36 -07:00

1535 lines
46 KiB
C++

/*
* Copyright (C) 2007 The Android Open Source Project
*
* Licensed under the Apache License, Version 2.0 (the "License");
* you may not use this file except in compliance with the License.
* You may obtain a copy of the License at
*
* http://www.apache.org/licenses/LICENSE-2.0
*
* Unless required by applicable law or agreed to in writing, software
* distributed under the License is distributed on an "AS IS" BASIS,
* WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
* See the License for the specific language governing permissions and
* limitations under the License.
*/
#define TRACE_TAG TRANSPORT
#include "sysdeps.h"
#include "transport.h"
#include <ctype.h>
#include <errno.h>
#include <inttypes.h>
#include <stdio.h>
#include <stdlib.h>
#include <string.h>
#include <unistd.h>
#include <algorithm>
#include <deque>
#include <list>
#include <memory>
#include <mutex>
#include <set>
#include <thread>
#include <adb/crypto/rsa_2048_key.h>
#include <adb/crypto/x509_generator.h>
#include <adb/tls/tls_connection.h>
#include <android-base/logging.h>
#include <android-base/parsenetaddress.h>
#include <android-base/stringprintf.h>
#include <android-base/strings.h>
#include <android-base/thread_annotations.h>
#include <diagnose_usb.h>
#include "adb.h"
#include "adb_auth.h"
#include "adb_io.h"
#include "adb_trace.h"
#include "adb_utils.h"
#include "fdevent/fdevent.h"
#include "sysdeps/chrono.h"
using namespace adb::crypto;
using namespace adb::tls;
using android::base::ScopedLockAssertion;
using TlsError = TlsConnection::TlsError;
static void remove_transport(atransport* transport);
static void transport_destroy(atransport* transport);
// TODO: unordered_map<TransportId, atransport*>
static auto& transport_list = *new std::list<atransport*>();
static auto& pending_list = *new std::list<atransport*>();
static auto& transport_lock = *new std::recursive_mutex();
const char* const kFeatureShell2 = "shell_v2";
const char* const kFeatureCmd = "cmd";
const char* const kFeatureStat2 = "stat_v2";
const char* const kFeatureLs2 = "ls_v2";
const char* const kFeatureLibusb = "libusb";
const char* const kFeaturePushSync = "push_sync";
const char* const kFeatureApex = "apex";
const char* const kFeatureFixedPushMkdir = "fixed_push_mkdir";
const char* const kFeatureAbb = "abb";
const char* const kFeatureFixedPushSymlinkTimestamp = "fixed_push_symlink_timestamp";
const char* const kFeatureAbbExec = "abb_exec";
const char* const kFeatureRemountShell = "remount_shell";
const char* const kFeatureSendRecv2 = "sendrecv_v2";
const char* const kFeatureSendRecv2Brotli = "sendrecv_v2_brotli";
namespace {
#if ADB_HOST
// Tracks and handles atransport*s that are attempting reconnection.
class ReconnectHandler {
public:
ReconnectHandler() = default;
~ReconnectHandler() = default;
// Starts the ReconnectHandler thread.
void Start();
// Requests the ReconnectHandler thread to stop.
void Stop();
// Adds the atransport* to the queue of reconnect attempts.
void TrackTransport(atransport* transport);
// Wake up the ReconnectHandler thread to have it check for kicked transports.
void CheckForKicked();
private:
// The main thread loop.
void Run();
// Tracks a reconnection attempt.
struct ReconnectAttempt {
atransport* transport;
std::chrono::steady_clock::time_point reconnect_time;
size_t attempts_left;
bool operator<(const ReconnectAttempt& rhs) const {
if (reconnect_time == rhs.reconnect_time) {
return reinterpret_cast<uintptr_t>(transport) <
reinterpret_cast<uintptr_t>(rhs.transport);
}
return reconnect_time < rhs.reconnect_time;
}
};
// Only retry for up to one minute.
static constexpr const std::chrono::seconds kDefaultTimeout = 10s;
static constexpr const size_t kMaxAttempts = 6;
// Protects all members.
std::mutex reconnect_mutex_;
bool running_ GUARDED_BY(reconnect_mutex_) = true;
std::thread handler_thread_;
std::condition_variable reconnect_cv_;
std::set<ReconnectAttempt> reconnect_queue_ GUARDED_BY(reconnect_mutex_);
DISALLOW_COPY_AND_ASSIGN(ReconnectHandler);
};
void ReconnectHandler::Start() {
check_main_thread();
handler_thread_ = std::thread(&ReconnectHandler::Run, this);
}
void ReconnectHandler::Stop() {
check_main_thread();
{
std::lock_guard<std::mutex> lock(reconnect_mutex_);
running_ = false;
}
reconnect_cv_.notify_one();
handler_thread_.join();
// Drain the queue to free all resources.
std::lock_guard<std::mutex> lock(reconnect_mutex_);
while (!reconnect_queue_.empty()) {
ReconnectAttempt attempt = *reconnect_queue_.begin();
reconnect_queue_.erase(reconnect_queue_.begin());
remove_transport(attempt.transport);
}
}
void ReconnectHandler::TrackTransport(atransport* transport) {
check_main_thread();
{
std::lock_guard<std::mutex> lock(reconnect_mutex_);
if (!running_) return;
// Arbitrary sleep to give adbd time to get ready, if we disconnected because it exited.
auto reconnect_time = std::chrono::steady_clock::now() + 250ms;
reconnect_queue_.emplace(
ReconnectAttempt{transport, reconnect_time, ReconnectHandler::kMaxAttempts});
}
reconnect_cv_.notify_one();
}
void ReconnectHandler::CheckForKicked() {
reconnect_cv_.notify_one();
}
void ReconnectHandler::Run() {
while (true) {
ReconnectAttempt attempt;
{
std::unique_lock<std::mutex> lock(reconnect_mutex_);
ScopedLockAssertion assume_lock(reconnect_mutex_);
if (!reconnect_queue_.empty()) {
// FIXME: libstdc++ (used on Windows) implements condition_variable with
// system_clock as its clock, so we're probably hosed if the clock changes,
// even if we use steady_clock throughout. This problem goes away once we
// switch to libc++.
reconnect_cv_.wait_until(lock, reconnect_queue_.begin()->reconnect_time);
} else {
reconnect_cv_.wait(lock);
}
if (!running_) return;
// Scan the whole list for kicked transports, so that we immediately handle an explicit
// disconnect request.
bool kicked = false;
for (auto it = reconnect_queue_.begin(); it != reconnect_queue_.end();) {
if (it->transport->kicked()) {
D("transport %s was kicked. giving up on it.", it->transport->serial.c_str());
remove_transport(it->transport);
it = reconnect_queue_.erase(it);
} else {
++it;
}
kicked = true;
}
if (reconnect_queue_.empty()) continue;
// Go back to sleep if we either woke up spuriously, or we were woken up to remove
// a kicked transport, and the first transport isn't ready for reconnection yet.
auto now = std::chrono::steady_clock::now();
if (reconnect_queue_.begin()->reconnect_time > now) {
continue;
}
attempt = *reconnect_queue_.begin();
reconnect_queue_.erase(reconnect_queue_.begin());
}
D("attempting to reconnect %s", attempt.transport->serial.c_str());
switch (attempt.transport->Reconnect()) {
case ReconnectResult::Retry: {
D("attempting to reconnect %s failed.", attempt.transport->serial.c_str());
if (attempt.attempts_left == 0) {
D("transport %s exceeded the number of retry attempts. giving up on it.",
attempt.transport->serial.c_str());
remove_transport(attempt.transport);
continue;
}
std::lock_guard<std::mutex> lock(reconnect_mutex_);
reconnect_queue_.emplace(ReconnectAttempt{
attempt.transport,
std::chrono::steady_clock::now() + ReconnectHandler::kDefaultTimeout,
attempt.attempts_left - 1});
continue;
}
case ReconnectResult::Success:
D("reconnection to %s succeeded.", attempt.transport->serial.c_str());
register_transport(attempt.transport);
continue;
case ReconnectResult::Abort:
D("cancelling reconnection attempt to %s.", attempt.transport->serial.c_str());
remove_transport(attempt.transport);
continue;
}
}
}
static auto& reconnect_handler = *new ReconnectHandler();
#endif
} // namespace
TransportId NextTransportId() {
static std::atomic<TransportId> next(1);
return next++;
}
void Connection::Reset() {
LOG(INFO) << "Connection::Reset(): stopping";
Stop();
}
BlockingConnectionAdapter::BlockingConnectionAdapter(std::unique_ptr<BlockingConnection> connection)
: underlying_(std::move(connection)) {}
BlockingConnectionAdapter::~BlockingConnectionAdapter() {
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_ << "): destructing";
Stop();
}
void BlockingConnectionAdapter::Start() {
std::lock_guard<std::mutex> lock(mutex_);
if (started_) {
LOG(FATAL) << "BlockingConnectionAdapter(" << this->transport_name_
<< "): started multiple times";
}
StartReadThread();
write_thread_ = std::thread([this]() {
LOG(INFO) << this->transport_name_ << ": write thread spawning";
while (true) {
std::unique_lock<std::mutex> lock(mutex_);
ScopedLockAssertion assume_locked(mutex_);
cv_.wait(lock, [this]() REQUIRES(mutex_) {
return this->stopped_ || !this->write_queue_.empty();
});
if (this->stopped_) {
return;
}
std::unique_ptr<apacket> packet = std::move(this->write_queue_.front());
this->write_queue_.pop_front();
lock.unlock();
if (!this->underlying_->Write(packet.get())) {
break;
}
}
std::call_once(this->error_flag_, [this]() { this->error_callback_(this, "write failed"); });
});
started_ = true;
}
void BlockingConnectionAdapter::StartReadThread() {
read_thread_ = std::thread([this]() {
LOG(INFO) << this->transport_name_ << ": read thread spawning";
while (true) {
auto packet = std::make_unique<apacket>();
if (!underlying_->Read(packet.get())) {
PLOG(INFO) << this->transport_name_ << ": read failed";
break;
}
bool got_stls_cmd = false;
if (packet->msg.command == A_STLS) {
got_stls_cmd = true;
}
read_callback_(this, std::move(packet));
// If we received the STLS packet, we are about to perform the TLS
// handshake. So this read thread must stop and resume after the
// handshake completes otherwise this will interfere in the process.
if (got_stls_cmd) {
LOG(INFO) << this->transport_name_
<< ": Received STLS packet. Stopping read thread.";
return;
}
}
std::call_once(this->error_flag_, [this]() { this->error_callback_(this, "read failed"); });
});
}
bool BlockingConnectionAdapter::DoTlsHandshake(RSA* key, std::string* auth_key) {
std::lock_guard<std::mutex> lock(mutex_);
if (read_thread_.joinable()) {
read_thread_.join();
}
bool success = this->underlying_->DoTlsHandshake(key, auth_key);
StartReadThread();
return success;
}
void BlockingConnectionAdapter::Reset() {
{
std::lock_guard<std::mutex> lock(mutex_);
if (!started_) {
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_ << "): not started";
return;
}
if (stopped_) {
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_
<< "): already stopped";
return;
}
}
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_ << "): resetting";
this->underlying_->Reset();
Stop();
}
void BlockingConnectionAdapter::Stop() {
{
std::lock_guard<std::mutex> lock(mutex_);
if (!started_) {
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_ << "): not started";
return;
}
if (stopped_) {
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_
<< "): already stopped";
return;
}
stopped_ = true;
}
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_ << "): stopping";
this->underlying_->Close();
this->cv_.notify_one();
// Move the threads out into locals with the lock taken, and then unlock to let them exit.
std::thread read_thread;
std::thread write_thread;
{
std::lock_guard<std::mutex> lock(mutex_);
read_thread = std::move(read_thread_);
write_thread = std::move(write_thread_);
}
read_thread.join();
write_thread.join();
LOG(INFO) << "BlockingConnectionAdapter(" << this->transport_name_ << "): stopped";
std::call_once(this->error_flag_, [this]() { this->error_callback_(this, "requested stop"); });
}
bool BlockingConnectionAdapter::Write(std::unique_ptr<apacket> packet) {
{
std::lock_guard<std::mutex> lock(this->mutex_);
write_queue_.emplace_back(std::move(packet));
}
cv_.notify_one();
return true;
}
FdConnection::FdConnection(unique_fd fd) : fd_(std::move(fd)) {}
FdConnection::~FdConnection() {}
bool FdConnection::DispatchRead(void* buf, size_t len) {
if (tls_ != nullptr) {
// The TlsConnection doesn't allow 0 byte reads
if (len == 0) {
return true;
}
return tls_->ReadFully(buf, len);
}
return ReadFdExactly(fd_.get(), buf, len);
}
bool FdConnection::DispatchWrite(void* buf, size_t len) {
if (tls_ != nullptr) {
// The TlsConnection doesn't allow 0 byte writes
if (len == 0) {
return true;
}
return tls_->WriteFully(std::string_view(reinterpret_cast<const char*>(buf), len));
}
return WriteFdExactly(fd_.get(), buf, len);
}
bool FdConnection::Read(apacket* packet) {
if (!DispatchRead(&packet->msg, sizeof(amessage))) {
D("remote local: read terminated (message)");
return false;
}
if (packet->msg.data_length > MAX_PAYLOAD) {
D("remote local: read overflow (data length = %" PRIu32 ")", packet->msg.data_length);
return false;
}
packet->payload.resize(packet->msg.data_length);
if (!DispatchRead(&packet->payload[0], packet->payload.size())) {
D("remote local: terminated (data)");
return false;
}
return true;
}
bool FdConnection::Write(apacket* packet) {
if (!DispatchWrite(&packet->msg, sizeof(packet->msg))) {
D("remote local: write terminated");
return false;
}
if (packet->msg.data_length) {
if (!DispatchWrite(&packet->payload[0], packet->msg.data_length)) {
D("remote local: write terminated");
return false;
}
}
return true;
}
bool FdConnection::DoTlsHandshake(RSA* key, std::string* auth_key) {
bssl::UniquePtr<EVP_PKEY> evp_pkey(EVP_PKEY_new());
if (!EVP_PKEY_set1_RSA(evp_pkey.get(), key)) {
LOG(ERROR) << "EVP_PKEY_set1_RSA failed";
return false;
}
auto x509 = GenerateX509Certificate(evp_pkey.get());
auto x509_str = X509ToPEMString(x509.get());
auto evp_str = Key::ToPEMString(evp_pkey.get());
#ifdef _WIN32
int osh = cast_handle_to_int(adb_get_os_handle(fd_));
#else
int osh = adb_get_os_handle(fd_);
#endif
#if ADB_HOST
tls_ = TlsConnection::Create(TlsConnection::Role::Client,
#else
tls_ = TlsConnection::Create(TlsConnection::Role::Server,
#endif
x509_str, evp_str, osh);
CHECK(tls_);
#if ADB_HOST
// TLS 1.3 gives the client no message if the server rejected the
// certificate. This will enable a check in the tls connection to check
// whether the client certificate got rejected. Note that this assumes
// that, on handshake success, the server speaks first.
tls_->EnableClientPostHandshakeCheck(true);
// Add callback to set the certificate when server issues the
// CertificateRequest.
tls_->SetCertificateCallback(adb_tls_set_certificate);
// Allow any server certificate
tls_->SetCertVerifyCallback([](X509_STORE_CTX*) { return 1; });
#else
// Add callback to check certificate against a list of known public keys
tls_->SetCertVerifyCallback(
[auth_key](X509_STORE_CTX* ctx) { return adbd_tls_verify_cert(ctx, auth_key); });
// Add the list of allowed client CA issuers
auto ca_list = adbd_tls_client_ca_list();
tls_->SetClientCAList(ca_list.get());
#endif
auto err = tls_->DoHandshake();
if (err == TlsError::Success) {
return true;
}
tls_.reset();
return false;
}
void FdConnection::Close() {
adb_shutdown(fd_.get());
fd_.reset();
}
void send_packet(apacket* p, atransport* t) {
p->msg.magic = p->msg.command ^ 0xffffffff;
// compute a checksum for connection/auth packets for compatibility reasons
if (t->get_protocol_version() >= A_VERSION_SKIP_CHECKSUM) {
p->msg.data_check = 0;
} else {
p->msg.data_check = calculate_apacket_checksum(p);
}
VLOG(TRANSPORT) << dump_packet(t->serial.c_str(), "to remote", p);
if (t == nullptr) {
LOG(FATAL) << "Transport is null";
}
if (t->Write(p) != 0) {
D("%s: failed to enqueue packet, closing transport", t->serial.c_str());
t->Kick();
}
}
void kick_transport(atransport* t, bool reset) {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
// As kick_transport() can be called from threads without guarantee that t is valid,
// check if the transport is in transport_list first.
//
// TODO(jmgao): WTF? Is this actually true?
if (std::find(transport_list.begin(), transport_list.end(), t) != transport_list.end()) {
if (reset) {
t->Reset();
} else {
t->Kick();
}
}
#if ADB_HOST
reconnect_handler.CheckForKicked();
#endif
}
static int transport_registration_send = -1;
static int transport_registration_recv = -1;
static fdevent* transport_registration_fde;
#if ADB_HOST
/* this adds support required by the 'track-devices' service.
* this is used to send the content of "list_transport" to any
* number of client connections that want it through a single
* live TCP connection
*/
struct device_tracker {
asocket socket;
bool update_needed = false;
bool long_output = false;
device_tracker* next = nullptr;
};
/* linked list of all device trackers */
static device_tracker* device_tracker_list;
static void device_tracker_remove(device_tracker* tracker) {
device_tracker** pnode = &device_tracker_list;
device_tracker* node = *pnode;
std::lock_guard<std::recursive_mutex> lock(transport_lock);
while (node) {
if (node == tracker) {
*pnode = node->next;
break;
}
pnode = &node->next;
node = *pnode;
}
}
static void device_tracker_close(asocket* socket) {
device_tracker* tracker = (device_tracker*)socket;
asocket* peer = socket->peer;
D("device tracker %p removed", tracker);
if (peer) {
peer->peer = nullptr;
peer->close(peer);
}
device_tracker_remove(tracker);
delete tracker;
}
static int device_tracker_enqueue(asocket* socket, apacket::payload_type) {
/* you can't read from a device tracker, close immediately */
device_tracker_close(socket);
return -1;
}
static int device_tracker_send(device_tracker* tracker, const std::string& string) {
asocket* peer = tracker->socket.peer;
apacket::payload_type data;
data.resize(4 + string.size());
char buf[5];
snprintf(buf, sizeof(buf), "%04x", static_cast<int>(string.size()));
memcpy(&data[0], buf, 4);
memcpy(&data[4], string.data(), string.size());
return peer->enqueue(peer, std::move(data));
}
static void device_tracker_ready(asocket* socket) {
device_tracker* tracker = reinterpret_cast<device_tracker*>(socket);
// We want to send the device list when the tracker connects
// for the first time, even if no update occurred.
if (tracker->update_needed) {
tracker->update_needed = false;
device_tracker_send(tracker, list_transports(tracker->long_output));
}
}
asocket* create_device_tracker(bool long_output) {
device_tracker* tracker = new device_tracker();
if (tracker == nullptr) LOG(FATAL) << "cannot allocate device tracker";
D("device tracker %p created", tracker);
tracker->socket.enqueue = device_tracker_enqueue;
tracker->socket.ready = device_tracker_ready;
tracker->socket.close = device_tracker_close;
tracker->update_needed = true;
tracker->long_output = long_output;
tracker->next = device_tracker_list;
device_tracker_list = tracker;
return &tracker->socket;
}
// Check if all of the USB transports are connected.
bool iterate_transports(std::function<bool(const atransport*)> fn) {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
for (const auto& t : transport_list) {
if (!fn(t)) {
return false;
}
}
for (const auto& t : pending_list) {
if (!fn(t)) {
return false;
}
}
return true;
}
// Call this function each time the transport list has changed.
void update_transports() {
update_transport_status();
// Notify `adb track-devices` clients.
device_tracker* tracker = device_tracker_list;
while (tracker != nullptr) {
device_tracker* next = tracker->next;
// This may destroy the tracker if the connection is closed.
device_tracker_send(tracker, list_transports(tracker->long_output));
tracker = next;
}
}
#else
void update_transports() {
// Nothing to do on the device side.
}
#endif // ADB_HOST
struct tmsg {
atransport* transport;
int action;
};
static int transport_read_action(int fd, struct tmsg* m) {
char* p = (char*)m;
int len = sizeof(*m);
int r;
while (len > 0) {
r = adb_read(fd, p, len);
if (r > 0) {
len -= r;
p += r;
} else {
D("transport_read_action: on fd %d: %s", fd, strerror(errno));
return -1;
}
}
return 0;
}
static int transport_write_action(int fd, struct tmsg* m) {
char* p = (char*)m;
int len = sizeof(*m);
int r;
while (len > 0) {
r = adb_write(fd, p, len);
if (r > 0) {
len -= r;
p += r;
} else {
D("transport_write_action: on fd %d: %s", fd, strerror(errno));
return -1;
}
}
return 0;
}
static void transport_registration_func(int _fd, unsigned ev, void*) {
tmsg m;
atransport* t;
if (!(ev & FDE_READ)) {
return;
}
if (transport_read_action(_fd, &m)) {
PLOG(FATAL) << "cannot read transport registration socket";
}
t = m.transport;
if (m.action == 0) {
D("transport: %s deleting", t->serial.c_str());
{
std::lock_guard<std::recursive_mutex> lock(transport_lock);
transport_list.remove(t);
}
delete t;
update_transports();
return;
}
/* don't create transport threads for inaccessible devices */
if (t->GetConnectionState() != kCsNoPerm) {
// The connection gets a reference to the atransport. It will release it
// upon a read/write error.
t->connection()->SetTransportName(t->serial_name());
t->connection()->SetReadCallback([t](Connection*, std::unique_ptr<apacket> p) {
if (!check_header(p.get(), t)) {
D("%s: remote read: bad header", t->serial.c_str());
return false;
}
VLOG(TRANSPORT) << dump_packet(t->serial.c_str(), "from remote", p.get());
apacket* packet = p.release();
// TODO: Does this need to run on the main thread?
fdevent_run_on_main_thread([packet, t]() { handle_packet(packet, t); });
return true;
});
t->connection()->SetErrorCallback([t](Connection*, const std::string& error) {
LOG(INFO) << t->serial_name() << ": connection terminated: " << error;
fdevent_run_on_main_thread([t]() {
handle_offline(t);
transport_destroy(t);
});
});
t->connection()->Start();
#if ADB_HOST
send_connect(t);
#endif
}
{
std::lock_guard<std::recursive_mutex> lock(transport_lock);
auto it = std::find(pending_list.begin(), pending_list.end(), t);
if (it != pending_list.end()) {
pending_list.remove(t);
transport_list.push_front(t);
}
}
update_transports();
}
#if ADB_HOST
void init_reconnect_handler(void) {
reconnect_handler.Start();
}
#endif
void init_transport_registration(void) {
int s[2];
if (adb_socketpair(s)) {
PLOG(FATAL) << "cannot open transport registration socketpair";
}
D("socketpair: (%d,%d)", s[0], s[1]);
transport_registration_send = s[0];
transport_registration_recv = s[1];
transport_registration_fde =
fdevent_create(transport_registration_recv, transport_registration_func, nullptr);
fdevent_set(transport_registration_fde, FDE_READ);
}
void kick_all_transports() {
#if ADB_HOST
reconnect_handler.Stop();
#endif
// To avoid only writing part of a packet to a transport after exit, kick all transports.
std::lock_guard<std::recursive_mutex> lock(transport_lock);
for (auto t : transport_list) {
t->Kick();
}
}
void kick_all_tcp_tls_transports() {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
for (auto t : transport_list) {
if (t->IsTcpDevice() && t->use_tls) {
t->Kick();
}
}
}
#if !ADB_HOST
void kick_all_transports_by_auth_key(std::string_view auth_key) {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
for (auto t : transport_list) {
if (auth_key == t->auth_key) {
t->Kick();
}
}
}
#endif
/* the fdevent select pump is single threaded */
void register_transport(atransport* transport) {
tmsg m;
m.transport = transport;
m.action = 1;
D("transport: %s registered", transport->serial.c_str());
if (transport_write_action(transport_registration_send, &m)) {
PLOG(FATAL) << "cannot write transport registration socket";
}
}
static void remove_transport(atransport* transport) {
tmsg m;
m.transport = transport;
m.action = 0;
D("transport: %s removed", transport->serial.c_str());
if (transport_write_action(transport_registration_send, &m)) {
PLOG(FATAL) << "cannot write transport registration socket";
}
}
static void transport_destroy(atransport* t) {
check_main_thread();
CHECK(t != nullptr);
std::lock_guard<std::recursive_mutex> lock(transport_lock);
LOG(INFO) << "destroying transport " << t->serial_name();
t->connection()->Stop();
#if ADB_HOST
if (t->IsTcpDevice() && !t->kicked()) {
D("transport: %s destroy (attempting reconnection)", t->serial.c_str());
// We need to clear the transport's keys, so that on the next connection, it tries
// again from the beginning.
t->ResetKeys();
reconnect_handler.TrackTransport(t);
return;
}
#endif
D("transport: %s destroy (kicking and closing)", t->serial.c_str());
remove_transport(t);
}
static int qual_match(const std::string& to_test, const char* prefix, const std::string& qual,
bool sanitize_qual) {
if (to_test.empty()) /* Return true if both the qual and to_test are empty strings. */
return qual.empty();
if (qual.empty()) return 0;
const char* ptr = to_test.c_str();
if (prefix) {
while (*prefix) {
if (*prefix++ != *ptr++) return 0;
}
}
for (char ch : qual) {
if (sanitize_qual && !isalnum(ch)) ch = '_';
if (ch != *ptr++) return 0;
}
/* Everything matched so far. Return true if *ptr is a NUL. */
return !*ptr;
}
atransport* acquire_one_transport(TransportType type, const char* serial, TransportId transport_id,
bool* is_ambiguous, std::string* error_out,
bool accept_any_state) {
atransport* result = nullptr;
if (transport_id != 0) {
*error_out =
android::base::StringPrintf("no device with transport id '%" PRIu64 "'", transport_id);
} else if (serial) {
*error_out = android::base::StringPrintf("device '%s' not found", serial);
} else if (type == kTransportLocal) {
*error_out = "no emulators found";
} else if (type == kTransportAny) {
*error_out = "no devices/emulators found";
} else {
*error_out = "no devices found";
}
std::unique_lock<std::recursive_mutex> lock(transport_lock);
for (const auto& t : transport_list) {
if (t->GetConnectionState() == kCsNoPerm) {
*error_out = UsbNoPermissionsLongHelpText();
continue;
}
if (transport_id) {
if (t->id == transport_id) {
result = t;
break;
}
} else if (serial) {
if (t->MatchesTarget(serial)) {
if (result) {
*error_out = "more than one device";
if (is_ambiguous) *is_ambiguous = true;
result = nullptr;
break;
}
result = t;
}
} else {
if (type == kTransportUsb && t->type == kTransportUsb) {
if (result) {
*error_out = "more than one device";
if (is_ambiguous) *is_ambiguous = true;
result = nullptr;
break;
}
result = t;
} else if (type == kTransportLocal && t->type == kTransportLocal) {
if (result) {
*error_out = "more than one emulator";
if (is_ambiguous) *is_ambiguous = true;
result = nullptr;
break;
}
result = t;
} else if (type == kTransportAny) {
if (result) {
*error_out = "more than one device/emulator";
if (is_ambiguous) *is_ambiguous = true;
result = nullptr;
break;
}
result = t;
}
}
}
lock.unlock();
if (result && !accept_any_state) {
// The caller requires an active transport.
// Make sure that we're actually connected.
ConnectionState state = result->GetConnectionState();
switch (state) {
case kCsConnecting:
*error_out = "device still connecting";
result = nullptr;
break;
case kCsAuthorizing:
*error_out = "device still authorizing";
result = nullptr;
break;
case kCsUnauthorized: {
*error_out = "device unauthorized.\n";
char* ADB_VENDOR_KEYS = getenv("ADB_VENDOR_KEYS");
*error_out += "This adb server's $ADB_VENDOR_KEYS is ";
*error_out += ADB_VENDOR_KEYS ? ADB_VENDOR_KEYS : "not set";
*error_out += "\n";
*error_out += "Try 'adb kill-server' if that seems wrong.\n";
*error_out += "Otherwise check for a confirmation dialog on your device.";
result = nullptr;
break;
}
case kCsOffline:
*error_out = "device offline";
result = nullptr;
break;
default:
break;
}
}
if (result) {
*error_out = "success";
}
return result;
}
bool ConnectionWaitable::WaitForConnection(std::chrono::milliseconds timeout) {
std::unique_lock<std::mutex> lock(mutex_);
ScopedLockAssertion assume_locked(mutex_);
return cv_.wait_for(lock, timeout, [&]() REQUIRES(mutex_) {
return connection_established_ready_;
}) && connection_established_;
}
void ConnectionWaitable::SetConnectionEstablished(bool success) {
{
std::lock_guard<std::mutex> lock(mutex_);
if (connection_established_ready_) return;
connection_established_ready_ = true;
connection_established_ = success;
D("connection established with %d", success);
}
cv_.notify_one();
}
atransport::~atransport() {
// If the connection callback had not been run before, run it now.
SetConnectionEstablished(false);
}
int atransport::Write(apacket* p) {
return this->connection()->Write(std::unique_ptr<apacket>(p)) ? 0 : -1;
}
void atransport::Reset() {
if (!kicked_.exchange(true)) {
LOG(INFO) << "resetting transport " << this << " " << this->serial;
this->connection()->Reset();
}
}
void atransport::Kick() {
if (!kicked_.exchange(true)) {
LOG(INFO) << "kicking transport " << this << " " << this->serial;
this->connection()->Stop();
}
}
ConnectionState atransport::GetConnectionState() const {
return connection_state_;
}
void atransport::SetConnectionState(ConnectionState state) {
check_main_thread();
connection_state_ = state;
}
void atransport::SetConnection(std::unique_ptr<Connection> connection) {
std::lock_guard<std::mutex> lock(mutex_);
connection_ = std::shared_ptr<Connection>(std::move(connection));
}
std::string atransport::connection_state_name() const {
ConnectionState state = GetConnectionState();
switch (state) {
case kCsOffline:
return "offline";
case kCsBootloader:
return "bootloader";
case kCsDevice:
return "device";
case kCsHost:
return "host";
case kCsRecovery:
return "recovery";
case kCsRescue:
return "rescue";
case kCsNoPerm:
return UsbNoPermissionsShortHelpText();
case kCsSideload:
return "sideload";
case kCsUnauthorized:
return "unauthorized";
case kCsAuthorizing:
return "authorizing";
case kCsConnecting:
return "connecting";
default:
return "unknown";
}
}
void atransport::update_version(int version, size_t payload) {
protocol_version = std::min(version, A_VERSION);
max_payload = std::min(payload, MAX_PAYLOAD);
}
int atransport::get_protocol_version() const {
return protocol_version;
}
int atransport::get_tls_version() const {
return tls_version;
}
size_t atransport::get_max_payload() const {
return max_payload;
}
const FeatureSet& supported_features() {
// Local static allocation to avoid global non-POD variables.
static const FeatureSet* features = new FeatureSet{
kFeatureShell2,
kFeatureCmd,
kFeatureStat2,
kFeatureLs2,
kFeatureFixedPushMkdir,
kFeatureApex,
kFeatureAbb,
kFeatureFixedPushSymlinkTimestamp,
kFeatureAbbExec,
kFeatureRemountShell,
kFeatureSendRecv2,
kFeatureSendRecv2Brotli,
// Increment ADB_SERVER_VERSION when adding a feature that adbd needs
// to know about. Otherwise, the client can be stuck running an old
// version of the server even after upgrading their copy of adb.
// (http://b/24370690)
};
return *features;
}
std::string FeatureSetToString(const FeatureSet& features) {
return android::base::Join(features, ',');
}
FeatureSet StringToFeatureSet(const std::string& features_string) {
if (features_string.empty()) {
return FeatureSet();
}
auto names = android::base::Split(features_string, ",");
return FeatureSet(names.begin(), names.end());
}
bool CanUseFeature(const FeatureSet& feature_set, const std::string& feature) {
return feature_set.count(feature) > 0 && supported_features().count(feature) > 0;
}
bool atransport::has_feature(const std::string& feature) const {
return features_.count(feature) > 0;
}
void atransport::SetFeatures(const std::string& features_string) {
features_ = StringToFeatureSet(features_string);
}
void atransport::AddDisconnect(adisconnect* disconnect) {
disconnects_.push_back(disconnect);
}
void atransport::RemoveDisconnect(adisconnect* disconnect) {
disconnects_.remove(disconnect);
}
void atransport::RunDisconnects() {
for (const auto& disconnect : disconnects_) {
disconnect->func(disconnect->opaque, this);
}
disconnects_.clear();
}
bool atransport::MatchesTarget(const std::string& target) const {
if (!serial.empty()) {
if (target == serial) {
return true;
} else if (type == kTransportLocal) {
// Local transports can match [tcp:|udp:]<hostname>[:port].
const char* local_target_ptr = target.c_str();
// For fastboot compatibility, ignore protocol prefixes.
if (android::base::StartsWith(target, "tcp:") ||
android::base::StartsWith(target, "udp:")) {
local_target_ptr += 4;
}
// Parse our |serial| and the given |target| to check if the hostnames and ports match.
std::string serial_host, error;
int serial_port = -1;
if (android::base::ParseNetAddress(serial, &serial_host, &serial_port, nullptr, &error)) {
// |target| may omit the port to default to ours.
std::string target_host;
int target_port = serial_port;
if (android::base::ParseNetAddress(local_target_ptr, &target_host, &target_port,
nullptr, &error) &&
serial_host == target_host && serial_port == target_port) {
return true;
}
}
}
}
return (target == devpath) || qual_match(target, "product:", product, false) ||
qual_match(target, "model:", model, true) ||
qual_match(target, "device:", device, false);
}
void atransport::SetConnectionEstablished(bool success) {
connection_waitable_->SetConnectionEstablished(success);
}
ReconnectResult atransport::Reconnect() {
return reconnect_(this);
}
#if ADB_HOST
// We use newline as our delimiter, make sure to never output it.
static std::string sanitize(std::string str, bool alphanumeric) {
auto pred = alphanumeric ? [](const char c) { return !isalnum(c); }
: [](const char c) { return c == '\n'; };
std::replace_if(str.begin(), str.end(), pred, '_');
return str;
}
static void append_transport_info(std::string* result, const char* key, const std::string& value,
bool alphanumeric) {
if (value.empty()) {
return;
}
*result += ' ';
*result += key;
*result += sanitize(value, alphanumeric);
}
static void append_transport(const atransport* t, std::string* result, bool long_listing) {
std::string serial = t->serial;
if (serial.empty()) {
serial = "(no serial number)";
}
if (!long_listing) {
*result += serial;
*result += '\t';
*result += t->connection_state_name();
} else {
android::base::StringAppendF(result, "%-22s %s", serial.c_str(),
t->connection_state_name().c_str());
append_transport_info(result, "", t->devpath, false);
append_transport_info(result, "product:", t->product, false);
append_transport_info(result, "model:", t->model, true);
append_transport_info(result, "device:", t->device, false);
// Put id at the end, so that anyone parsing the output here can always find it by scanning
// backwards from newlines, even with hypothetical devices named 'transport_id:1'.
*result += " transport_id:";
*result += std::to_string(t->id);
}
*result += '\n';
}
std::string list_transports(bool long_listing) {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
auto sorted_transport_list = transport_list;
sorted_transport_list.sort([](atransport*& x, atransport*& y) {
if (x->type != y->type) {
return x->type < y->type;
}
return x->serial < y->serial;
});
std::string result;
for (const auto& t : sorted_transport_list) {
append_transport(t, &result, long_listing);
}
return result;
}
void close_usb_devices(std::function<bool(const atransport*)> predicate, bool reset) {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
for (auto& t : transport_list) {
if (predicate(t)) {
if (reset) {
t->Reset();
} else {
t->Kick();
}
}
}
}
/* hack for osx */
void close_usb_devices(bool reset) {
close_usb_devices([](const atransport*) { return true; }, reset);
}
#endif // ADB_HOST
bool register_socket_transport(unique_fd s, std::string serial, int port, int local,
atransport::ReconnectCallback reconnect, bool use_tls, int* error) {
atransport* t = new atransport(std::move(reconnect), kCsOffline);
t->use_tls = use_tls;
D("transport: %s init'ing for socket %d, on port %d", serial.c_str(), s.get(), port);
if (init_socket_transport(t, std::move(s), port, local) < 0) {
delete t;
if (error) *error = errno;
return false;
}
std::unique_lock<std::recursive_mutex> lock(transport_lock);
for (const auto& transport : pending_list) {
if (serial == transport->serial) {
VLOG(TRANSPORT) << "socket transport " << transport->serial
<< " is already in pending_list and fails to register";
delete t;
if (error) *error = EALREADY;
return false;
}
}
for (const auto& transport : transport_list) {
if (serial == transport->serial) {
VLOG(TRANSPORT) << "socket transport " << transport->serial
<< " is already in transport_list and fails to register";
delete t;
if (error) *error = EALREADY;
return false;
}
}
t->serial = std::move(serial);
pending_list.push_front(t);
lock.unlock();
auto waitable = t->connection_waitable();
register_transport(t);
if (local == 1) {
// Do not wait for emulator transports.
return true;
}
if (!waitable->WaitForConnection(std::chrono::seconds(10))) {
if (error) *error = ETIMEDOUT;
return false;
}
if (t->GetConnectionState() == kCsUnauthorized) {
if (error) *error = EPERM;
return false;
}
return true;
}
#if ADB_HOST
atransport* find_transport(const char* serial) {
atransport* result = nullptr;
std::lock_guard<std::recursive_mutex> lock(transport_lock);
for (auto& t : transport_list) {
if (strcmp(serial, t->serial.c_str()) == 0) {
result = t;
break;
}
}
return result;
}
void kick_all_tcp_devices() {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
for (auto& t : transport_list) {
if (t->IsTcpDevice()) {
// Kicking breaks the read_transport thread of this transport out of any read, then
// the read_transport thread will notify the main thread to make this transport
// offline. Then the main thread will notify the write_transport thread to exit.
// Finally, this transport will be closed and freed in the main thread.
t->Kick();
}
}
#if ADB_HOST
reconnect_handler.CheckForKicked();
#endif
}
#endif
#if ADB_HOST
void register_usb_transport(usb_handle* usb, const char* serial, const char* devpath,
unsigned writeable) {
atransport* t = new atransport(writeable ? kCsOffline : kCsNoPerm);
D("transport: %p init'ing for usb_handle %p (sn='%s')", t, usb, serial ? serial : "");
init_usb_transport(t, usb);
if (serial) {
t->serial = serial;
}
if (devpath) {
t->devpath = devpath;
}
{
std::lock_guard<std::recursive_mutex> lock(transport_lock);
pending_list.push_front(t);
}
register_transport(t);
}
#endif
#if ADB_HOST
// This should only be used for transports with connection_state == kCsNoPerm.
void unregister_usb_transport(usb_handle* usb) {
std::lock_guard<std::recursive_mutex> lock(transport_lock);
transport_list.remove_if([usb](atransport* t) {
return t->GetUsbHandle() == usb && t->GetConnectionState() == kCsNoPerm;
});
}
#endif
bool check_header(apacket* p, atransport* t) {
if (p->msg.magic != (p->msg.command ^ 0xffffffff)) {
VLOG(RWX) << "check_header(): invalid magic command = " << std::hex << p->msg.command
<< ", magic = " << p->msg.magic;
return false;
}
if (p->msg.data_length > t->get_max_payload()) {
VLOG(RWX) << "check_header(): " << p->msg.data_length
<< " atransport::max_payload = " << t->get_max_payload();
return false;
}
return true;
}
#if ADB_HOST
std::shared_ptr<RSA> atransport::Key() {
if (keys_.empty()) {
return nullptr;
}
std::shared_ptr<RSA> result = keys_[0];
return result;
}
std::shared_ptr<RSA> atransport::NextKey() {
if (keys_.empty()) {
LOG(INFO) << "fetching keys for transport " << this->serial_name();
keys_ = adb_auth_get_private_keys();
// We should have gotten at least one key: the one that's automatically generated.
CHECK(!keys_.empty());
} else {
keys_.pop_front();
}
std::shared_ptr<RSA> result = keys_[0];
return result;
}
void atransport::ResetKeys() {
keys_.clear();
}
#endif