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review.shift-gmbh.com / SHIFTPHONES / android_packages_modules_adb / 5bd94084b352be96be13c4d9ef96091ff9cc24d3 / . / client / file_sync_client.cpp
blob: a7e8e019eacbb3273865e8003ae936b4ce56bcca [file] [log] [blame]
/*
* 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.
*/
#include "client/file_sync_client.h"
#include <dirent.h>
#include <inttypes.h>
#include <limits.h>
#include <stdio.h>
#include <stdlib.h>
#include <sys/stat.h>
#include <sys/time.h>
#include <sys/types.h>
#include <time.h>
#include <unistd.h>
#include <utime.h>
#include <chrono>
#include <deque>
#include <functional>
#include <memory>
#include <sstream>
#include <string>
#include <variant>
#include <vector>
#include "sysdeps.h"
#include "adb.h"
#include "adb_client.h"
#include "adb_io.h"
#include "adb_utils.h"
#include "compression_utils.h"
#include "file_sync_protocol.h"
#include "line_printer.h"
#include "sysdeps/errno.h"
#include "sysdeps/stat.h"
#include "client/commandline.h"
#include <android-base/file.h>
#include <android-base/strings.h>
#include <android-base/stringprintf.h>
using namespace std::literals;
typedef void(sync_ls_cb)(unsigned mode, uint64_t size, uint64_t time, const char* name);
struct syncsendbuf {
unsigned id;
unsigned size;
char data[SYNC_DATA_MAX];
};
static void ensure_trailing_separators(std::string& local_path, std::string& remote_path) {
if (!adb_is_separator(local_path.back())) {
local_path.push_back(OS_PATH_SEPARATOR);
}
if (remote_path.back() != '/') {
remote_path.push_back('/');
}
}
static bool should_pull_file(mode_t mode) {
return S_ISREG(mode) || S_ISBLK(mode) || S_ISCHR(mode);
}
static bool should_push_file(mode_t mode) {
return S_ISREG(mode) || S_ISLNK(mode);
}
struct copyinfo {
std::string lpath;
std::string rpath;
int64_t time = 0;
uint32_t mode;
uint64_t size = 0;
bool skip = false;
copyinfo(const std::string& local_path,
const std::string& remote_path,
const std::string& name,
unsigned int mode)
: lpath(local_path), rpath(remote_path), mode(mode) {
ensure_trailing_separators(lpath, rpath);
lpath.append(name);
rpath.append(name);
if (S_ISDIR(mode)) {
ensure_trailing_separators(lpath, rpath);
}
}
};
enum class TransferDirection {
push,
pull,
};
struct TransferLedger {
std::chrono::steady_clock::time_point start_time;
uint64_t files_transferred;
uint64_t files_skipped;
uint64_t bytes_transferred;
uint64_t bytes_expected;
bool expect_multiple_files;
private:
std::string last_progress_str;
std::chrono::steady_clock::time_point last_progress_time;
public:
TransferLedger() {
Reset();
}
bool operator==(const TransferLedger& other) const {
return files_transferred == other.files_transferred &&
files_skipped == other.files_skipped && bytes_transferred == other.bytes_transferred;
}
bool operator!=(const TransferLedger& other) const {
return !(*this == other);
}
void Reset() {
start_time = std::chrono::steady_clock::now();
files_transferred = 0;
files_skipped = 0;
bytes_transferred = 0;
bytes_expected = 0;
last_progress_str.clear();
last_progress_time = {};
}
std::string TransferRate() {
if (bytes_transferred == 0) return "";
std::chrono::duration<double> duration;
duration = std::chrono::steady_clock::now() - start_time;
double s = duration.count();
if (s == 0) {
return "";
}
double rate = (static_cast<double>(bytes_transferred) / s) / (1024 * 1024);
return android::base::StringPrintf(" %.1f MB/s (%" PRIu64 " bytes in %.3fs)", rate,
bytes_transferred, s);
}
void ReportProgress(LinePrinter& lp, const std::string& file, uint64_t file_copied_bytes,
uint64_t file_total_bytes) {
static constexpr auto kProgressReportInterval = 100ms;
auto now = std::chrono::steady_clock::now();
if (now < last_progress_time + kProgressReportInterval) {
return;
}
char overall_percentage_str[5] = "?";
if (bytes_expected != 0 && bytes_transferred <= bytes_expected) {
int overall_percentage = static_cast<int>(bytes_transferred * 100 / bytes_expected);
// If we're pulling symbolic links, we'll pull the target of the link rather than
// just create a local link, and that will cause us to go over 100%.
if (overall_percentage <= 100) {
snprintf(overall_percentage_str, sizeof(overall_percentage_str), "%d%%",
overall_percentage);
}
}
std::string output;
if (file_copied_bytes > file_total_bytes || file_total_bytes == 0) {
// This case can happen if we're racing against something that wrote to the file
// between our stat and our read, or if we're reading a magic file that lies about
// its size. Just show how much we've copied.
output = android::base::StringPrintf("[%4s] %s: %" PRId64 "/?", overall_percentage_str,
file.c_str(), file_copied_bytes);
} else {
// If we're transferring multiple files, we want to know how far through the current
// file we are, as well as the overall percentage.
if (expect_multiple_files) {
int file_percentage = static_cast<int>(file_copied_bytes * 100 / file_total_bytes);
output = android::base::StringPrintf("[%4s] %s: %d%%", overall_percentage_str,
file.c_str(), file_percentage);
} else {
output =
android::base::StringPrintf("[%4s] %s", overall_percentage_str, file.c_str());
}
}
if (output != last_progress_str) {
lp.Print(output, LinePrinter::LineType::INFO);
last_progress_str = std::move(output);
last_progress_time = now;
}
}
void ReportTransferRate(LinePrinter& lp, const std::string& name, TransferDirection direction) {
const char* direction_str = (direction == TransferDirection::push) ? "pushed" : "pulled";
std::stringstream ss;
if (!name.empty()) {
std::string_view display_name(name);
char* out = getenv("ANDROID_PRODUCT_OUT");
if (out) android::base::ConsumePrefix(&display_name, out);
ss << display_name << ": ";
}
ss << files_transferred << " file" << ((files_transferred == 1) ? "" : "s") << " "
<< direction_str << ", " << files_skipped << " skipped.";
ss << TransferRate();
lp.Print(ss.str(), LinePrinter::LineType::INFO);
lp.KeepInfoLine();
}
};
class SyncConnection {
public:
SyncConnection() : acknowledgement_buffer_(sizeof(sync_status) + SYNC_DATA_MAX) {
acknowledgement_buffer_.resize(0);
max = SYNC_DATA_MAX; // TODO: decide at runtime.
std::string error;
auto&& features = adb_get_feature_set(&error);
if (!features) {
Error("failed to get feature set: %s", error.c_str());
} else {
features_ = &*features;
have_stat_v2_ = CanUseFeature(*features, kFeatureStat2);
have_ls_v2_ = CanUseFeature(*features, kFeatureLs2);
have_sendrecv_v2_ = CanUseFeature(*features, kFeatureSendRecv2);
have_sendrecv_v2_brotli_ = CanUseFeature(*features, kFeatureSendRecv2Brotli);
have_sendrecv_v2_lz4_ = CanUseFeature(*features, kFeatureSendRecv2LZ4);
have_sendrecv_v2_zstd_ = CanUseFeature(*features, kFeatureSendRecv2Zstd);
have_sendrecv_v2_dry_run_send_ = CanUseFeature(*features, kFeatureSendRecv2DryRunSend);
std::string error;
fd.reset(adb_connect("sync:", &error));
if (fd < 0) {
Error("connect failed: %s", error.c_str());
}
}
}
~SyncConnection() {
if (!IsValid()) return;
if (SendQuit()) {
// We sent a quit command, so the server should be doing orderly
// shutdown soon. But if we encountered an error while we were using
// the connection, the server might still be sending data (before
// doing orderly shutdown), in which case we won't wait for all of
// the data nor the coming orderly shutdown. In the common success
// case, this will wait for the server to do orderly shutdown.
ReadOrderlyShutdown(fd);
}
line_printer_.KeepInfoLine();
}
bool HaveSendRecv2() const { return have_sendrecv_v2_; }
bool HaveSendRecv2Brotli() const { return have_sendrecv_v2_brotli_; }
bool HaveSendRecv2LZ4() const { return have_sendrecv_v2_lz4_; }
bool HaveSendRecv2Zstd() const { return have_sendrecv_v2_zstd_; }
bool HaveSendRecv2DryRunSend() const { return have_sendrecv_v2_dry_run_send_; }
// Resolve a compression type which might be CompressionType::Any to a specific compression
// algorithm.
CompressionType ResolveCompressionType(CompressionType compression) const {
if (compression == CompressionType::Any) {
if (HaveSendRecv2Zstd()) {
return CompressionType::Zstd;
} else if (HaveSendRecv2LZ4()) {
return CompressionType::LZ4;
} else if (HaveSendRecv2Brotli()) {
return CompressionType::Brotli;
}
return CompressionType::None;
}
return compression;
}
const FeatureSet& Features() const { return *features_; }
bool IsValid() { return fd >= 0; }
void NewTransfer() {
current_ledger_.Reset();
}
void RecordBytesTransferred(size_t bytes) {
current_ledger_.bytes_transferred += bytes;
global_ledger_.bytes_transferred += bytes;
}
void RecordFileSent(std::string from, std::string to) {
RecordFilesTransferred(1);
deferred_acknowledgements_.emplace_back(std::move(from), std::move(to));
}
void RecordFilesTransferred(size_t files) {
current_ledger_.files_transferred += files;
global_ledger_.files_transferred += files;
}
void RecordFilesSkipped(size_t files) {
current_ledger_.files_skipped += files;
global_ledger_.files_skipped += files;
}
void ReportProgress(const std::string& file, uint64_t file_copied_bytes,
uint64_t file_total_bytes) {
current_ledger_.ReportProgress(line_printer_, file, file_copied_bytes, file_total_bytes);
}
void ReportTransferRate(const std::string& file, TransferDirection direction) {
current_ledger_.ReportTransferRate(line_printer_, file, direction);
}
void ReportOverallTransferRate(TransferDirection direction) {
if (current_ledger_ != global_ledger_) {
global_ledger_.ReportTransferRate(line_printer_, "", direction);
}
}
bool SendRequest(int id, const std::string& path) {
if (path.length() > 1024) {
Error("SendRequest failed: path too long: %zu", path.length());
errno = ENAMETOOLONG;
return false;
}
// Sending header and payload in a single write makes a noticeable
// difference to "adb sync" performance.
std::vector<char> buf(sizeof(SyncRequest) + path.length());
SyncRequest* req = reinterpret_cast<SyncRequest*>(&buf[0]);
req->id = id;
req->path_length = path.length();
char* data = reinterpret_cast<char*>(req + 1);
memcpy(data, path.data(), path.length());
return WriteFdExactly(fd, buf.data(), buf.size());
}
bool SendSend2(std::string_view path, mode_t mode, CompressionType compression, bool dry_run) {
if (path.length() > 1024) {
Error("SendRequest failed: path too long: %zu", path.length());
errno = ENAMETOOLONG;
return false;
}
Block buf;
SyncRequest req;
req.id = ID_SEND_V2;
req.path_length = path.length();
syncmsg msg;
msg.send_v2_setup.id = ID_SEND_V2;
msg.send_v2_setup.mode = mode;
msg.send_v2_setup.flags = 0;
switch (compression) {
case CompressionType::None:
break;
case CompressionType::Brotli:
msg.send_v2_setup.flags = kSyncFlagBrotli;
break;
case CompressionType::LZ4:
msg.send_v2_setup.flags = kSyncFlagLZ4;
break;
case CompressionType::Zstd:
msg.send_v2_setup.flags = kSyncFlagZstd;
break;
case CompressionType::Any:
LOG(FATAL) << "unexpected CompressionType::Any";
}
if (dry_run) {
msg.send_v2_setup.flags |= kSyncFlagDryRun;
}
buf.resize(sizeof(SyncRequest) + path.length() + sizeof(msg.send_v2_setup));
void* p = buf.data();
p = mempcpy(p, &req, sizeof(SyncRequest));
p = mempcpy(p, path.data(), path.length());
p = mempcpy(p, &msg.send_v2_setup, sizeof(msg.send_v2_setup));
return WriteFdExactly(fd, buf.data(), buf.size());
}
bool SendRecv2(const std::string& path, CompressionType compression) {
if (path.length() > 1024) {
Error("SendRequest failed: path too long: %zu", path.length());
errno = ENAMETOOLONG;
return false;
}
Block buf;
SyncRequest req;
req.id = ID_RECV_V2;
req.path_length = path.length();
syncmsg msg;
msg.recv_v2_setup.id = ID_RECV_V2;
msg.recv_v2_setup.flags = 0;
switch (compression) {
case CompressionType::None:
break;
case CompressionType::Brotli:
msg.recv_v2_setup.flags |= kSyncFlagBrotli;
break;
case CompressionType::LZ4:
msg.recv_v2_setup.flags |= kSyncFlagLZ4;
break;
case CompressionType::Zstd:
msg.recv_v2_setup.flags |= kSyncFlagZstd;
break;
case CompressionType::Any:
LOG(FATAL) << "unexpected CompressionType::Any";
}
buf.resize(sizeof(SyncRequest) + path.length() + sizeof(msg.recv_v2_setup));
void* p = buf.data();
p = mempcpy(p, &req, sizeof(SyncRequest));
p = mempcpy(p, path.data(), path.length());
p = mempcpy(p, &msg.recv_v2_setup, sizeof(msg.recv_v2_setup));
return WriteFdExactly(fd, buf.data(), buf.size());
}
bool SendStat(const std::string& path) {
if (!have_stat_v2_) {
errno = ENOTSUP;
return false;
}
return SendRequest(ID_STAT_V2, path);
}
bool SendLstat(const std::string& path) {
if (have_stat_v2_) {
return SendRequest(ID_LSTAT_V2, path);
} else {
return SendRequest(ID_LSTAT_V1, path);
}
}
bool FinishStat(struct stat* st) {
syncmsg msg;
memset(st, 0, sizeof(*st));
if (have_stat_v2_) {
if (!ReadFdExactly(fd.get(), &msg.stat_v2, sizeof(msg.stat_v2))) {
PLOG(FATAL) << "protocol fault: failed to read stat response";
}
if (msg.stat_v2.id != ID_LSTAT_V2 && msg.stat_v2.id != ID_STAT_V2) {
PLOG(FATAL) << "protocol fault: stat response has wrong message id: "
<< msg.stat_v2.id;
}
if (msg.stat_v2.error != 0) {
errno = errno_from_wire(msg.stat_v2.error);
return false;
}
st->st_dev = msg.stat_v2.dev;
st->st_ino = msg.stat_v2.ino;
st->st_mode = msg.stat_v2.mode;
st->st_nlink = msg.stat_v2.nlink;
st->st_uid = msg.stat_v2.uid;
st->st_gid = msg.stat_v2.gid;
st->st_size = msg.stat_v2.size;
st->st_atime = msg.stat_v2.atime;
st->st_mtime = msg.stat_v2.mtime;
st->st_ctime = msg.stat_v2.ctime;
return true;
} else {
if (!ReadFdExactly(fd.get(), &msg.stat_v1, sizeof(msg.stat_v1))) {
PLOG(FATAL) << "protocol fault: failed to read stat response";
}
if (msg.stat_v1.id != ID_LSTAT_V1) {
LOG(FATAL) << "protocol fault: stat response has wrong message id: "
<< msg.stat_v1.id;
}
if (msg.stat_v1.mode == 0 && msg.stat_v1.size == 0 && msg.stat_v1.mtime == 0) {
// There's no way for us to know what the error was.
errno = ENOPROTOOPT;
return false;
}
st->st_mode = msg.stat_v1.mode;
st->st_size = msg.stat_v1.size;
st->st_ctime = msg.stat_v1.mtime;
st->st_mtime = msg.stat_v1.mtime;
}
return true;
}
bool SendLs(const std::string& path) {
return SendRequest(have_ls_v2_ ? ID_LIST_V2 : ID_LIST_V1, path);
}
private:
template <bool v2>
static bool FinishLsImpl(borrowed_fd fd, const std::function<sync_ls_cb>& callback) {
using dent_type =
std::conditional_t<v2, decltype(syncmsg::dent_v2), decltype(syncmsg::dent_v1)>;
while (true) {
dent_type dent;
if (!ReadFdExactly(fd, &dent, sizeof(dent))) return false;
uint32_t expected_id = v2 ? ID_DENT_V2 : ID_DENT_V1;
if (dent.id == ID_DONE) return true;
if (dent.id != expected_id) return false;
// Maximum length of a file name excluding null terminator (NAME_MAX) on Linux is 255.
char buf[256];
size_t len = dent.namelen;
if (len > 255) return false;
if (!ReadFdExactly(fd, buf, len)) return false;
buf[len] = 0;
// Address the highly unlikely scenario wherein a
// compromised device/service might be able to
// traverse across directories on the host. Let's
// shut that door!
if (strchr(buf, '/')) {
return false;
}
callback(dent.mode, dent.size, dent.mtime, buf);
}
}
public:
bool FinishLs(const std::function<sync_ls_cb>& callback) {
if (have_ls_v2_) {
return FinishLsImpl<true>(this->fd, callback);
} else {
return FinishLsImpl<false>(this->fd, callback);
}
}
// Sending header, payload, and footer in a single write makes a huge
// difference to "adb sync" performance.
bool SendSmallFile(const std::string& path, mode_t mode, const std::string& lpath,
const std::string& rpath, unsigned mtime, const char* data,
size_t data_length, bool dry_run) {
if (dry_run) {
// We need to use send v2 for dry run.
return SendLargeFile(path, mode, lpath, rpath, mtime, CompressionType::None, dry_run);
}
std::string path_and_mode = android::base::StringPrintf("%s,%d", path.c_str(), mode);
if (path_and_mode.length() > 1024) {
Error("SendSmallFile failed: path too long: %zu", path_and_mode.length());
errno = ENAMETOOLONG;
return false;
}
std::vector<char> buf(sizeof(SyncRequest) + path_and_mode.length() + sizeof(SyncRequest) +
data_length + sizeof(SyncRequest));
char* p = &buf[0];
SyncRequest* req_send = reinterpret_cast<SyncRequest*>(p);
req_send->id = ID_SEND_V1;
req_send->path_length = path_and_mode.length();
p += sizeof(SyncRequest);
memcpy(p, path_and_mode.data(), path_and_mode.size());
p += path_and_mode.length();
SyncRequest* req_data = reinterpret_cast<SyncRequest*>(p);
req_data->id = ID_DATA;
req_data->path_length = data_length;
p += sizeof(SyncRequest);
memcpy(p, data, data_length);
p += data_length;
SyncRequest* req_done = reinterpret_cast<SyncRequest*>(p);
req_done->id = ID_DONE;
req_done->path_length = mtime;
p += sizeof(SyncRequest);
WriteOrDie(lpath, rpath, &buf[0], (p - &buf[0]));
RecordFileSent(lpath, rpath);
RecordBytesTransferred(data_length);
ReportProgress(rpath, data_length, data_length);
return true;
}
bool SendLargeFile(const std::string& path, mode_t mode, const std::string& lpath,
const std::string& rpath, unsigned mtime, CompressionType compression,
bool dry_run) {
if (dry_run && !HaveSendRecv2DryRunSend()) {
Error("dry-run not supported by the device");
return false;
}
if (!HaveSendRecv2()) {
return SendLargeFileLegacy(path, mode, lpath, rpath, mtime);
}
compression = ResolveCompressionType(compression);
if (!SendSend2(path, mode, compression, dry_run)) {
Error("failed to send ID_SEND_V2 message '%s': %s", path.c_str(), strerror(errno));
return false;
}
struct stat st;
if (stat(lpath.c_str(), &st) == -1) {
Error("cannot stat '%s': %s", lpath.c_str(), strerror(errno));
return false;
}
uint64_t total_size = st.st_size;
uint64_t bytes_copied = 0;
unique_fd lfd(adb_open(lpath.c_str(), O_RDONLY | O_CLOEXEC));
if (lfd < 0) {
Error("opening '%s' locally failed: %s", lpath.c_str(), strerror(errno));
return false;
}
syncsendbuf sbuf;
sbuf.id = ID_DATA;
std::variant<std::monostate, NullEncoder, BrotliEncoder, LZ4Encoder, ZstdEncoder>
encoder_storage;
Encoder* encoder = nullptr;
switch (compression) {
case CompressionType::None:
encoder = &encoder_storage.emplace<NullEncoder>(SYNC_DATA_MAX);
break;
case CompressionType::Brotli:
encoder = &encoder_storage.emplace<BrotliEncoder>(SYNC_DATA_MAX);
break;
case CompressionType::LZ4:
encoder = &encoder_storage.emplace<LZ4Encoder>(SYNC_DATA_MAX);
break;
case CompressionType::Zstd:
encoder = &encoder_storage.emplace<ZstdEncoder>(SYNC_DATA_MAX);
break;
case CompressionType::Any:
LOG(FATAL) << "unexpected CompressionType::Any";
}
bool sending = true;
while (sending) {
Block input(SYNC_DATA_MAX);
int r = adb_read(lfd.get(), input.data(), input.size());
if (r < 0) {
Error("reading '%s' locally failed: %s", lpath.c_str(), strerror(errno));
return false;
}
if (r == 0) {
encoder->Finish();
} else {
input.resize(r);
encoder->Append(std::move(input));
RecordBytesTransferred(r);
bytes_copied += r;
ReportProgress(rpath, bytes_copied, total_size);
}
while (true) {
Block output;
EncodeResult result = encoder->Encode(&output);
if (result == EncodeResult::Error) {
Error("compressing '%s' locally failed", lpath.c_str());
return false;
}
if (!output.empty()) {
sbuf.size = output.size();
memcpy(sbuf.data, output.data(), output.size());
WriteOrDie(lpath, rpath, &sbuf, sizeof(SyncRequest) + output.size());
}
if (result == EncodeResult::Done) {
sending = false;
break;
} else if (result == EncodeResult::NeedInput) {
break;
} else if (result == EncodeResult::MoreOutput) {
continue;
}
}
}
syncmsg msg;
msg.data.id = ID_DONE;
msg.data.size = mtime;
RecordFileSent(lpath, rpath);
return WriteOrDie(lpath, rpath, &msg.data, sizeof(msg.data));
}
bool SendLargeFileLegacy(const std::string& path, mode_t mode, const std::string& lpath,
const std::string& rpath, unsigned mtime) {
std::string path_and_mode = android::base::StringPrintf("%s,%d", path.c_str(), mode);
if (!SendRequest(ID_SEND_V1, path_and_mode)) {
Error("failed to send ID_SEND_V1 message '%s': %s", path_and_mode.c_str(),
strerror(errno));
return false;
}
struct stat st;
if (stat(lpath.c_str(), &st) == -1) {
Error("cannot stat '%s': %s", lpath.c_str(), strerror(errno));
return false;
}
uint64_t total_size = st.st_size;
uint64_t bytes_copied = 0;
unique_fd lfd(adb_open(lpath.c_str(), O_RDONLY | O_CLOEXEC));
if (lfd < 0) {
Error("opening '%s' locally failed: %s", lpath.c_str(), strerror(errno));
return false;
}
syncsendbuf sbuf;
sbuf.id = ID_DATA;
while (true) {
int bytes_read = adb_read(lfd, sbuf.data, max);
if (bytes_read == -1) {
Error("reading '%s' locally failed: %s", lpath.c_str(), strerror(errno));
return false;
} else if (bytes_read == 0) {
break;
}
sbuf.size = bytes_read;
WriteOrDie(lpath, rpath, &sbuf, sizeof(SyncRequest) + bytes_read);
RecordBytesTransferred(bytes_read);
bytes_copied += bytes_read;
ReportProgress(rpath, bytes_copied, total_size);
}
syncmsg msg;
msg.data.id = ID_DONE;
msg.data.size = mtime;
RecordFileSent(lpath, rpath);
return WriteOrDie(lpath, rpath, &msg.data, sizeof(msg.data));
}
bool ReportCopyFailure(const std::string& from, const std::string& to, const syncmsg& msg) {
std::vector<char> buf(msg.status.msglen + 1);
if (!ReadFdExactly(fd, &buf[0], msg.status.msglen)) {
Error("failed to copy '%s' to '%s'; failed to read reason (!): %s", from.c_str(),
to.c_str(), strerror(errno));
return false;
}
buf[msg.status.msglen] = 0;
Error("failed to copy '%s' to '%s': remote %s", from.c_str(), to.c_str(), &buf[0]);
return false;
}
void CopyDone() { deferred_acknowledgements_.pop_front(); }
void ReportDeferredCopyFailure(const std::string& msg) {
auto& [from, to] = deferred_acknowledgements_.front();
Error("failed to copy '%s' to '%s': remote %s", from.c_str(), to.c_str(), msg.c_str());
deferred_acknowledgements_.pop_front();
}
bool ReadAcknowledgements(bool read_all = false) {
// We need to read enough such that adbd's intermediate socket's write buffer can't be
// full. The default buffer on Linux is 212992 bytes, but there's 576 bytes of bookkeeping
// overhead per write. The worst case scenario is a continuous string of failures, since
// each logical packet is divided into two writes. If our packet size if conservatively 512
// bytes long, this leaves us with space for 128 responses.
constexpr size_t max_deferred_acks = 128;
auto& buf = acknowledgement_buffer_;
adb_pollfd pfd = {.fd = fd.get(), .events = POLLIN};
while (!deferred_acknowledgements_.empty()) {
bool should_block = read_all || deferred_acknowledgements_.size() >= max_deferred_acks;
ssize_t rc = adb_poll(&pfd, 1, should_block ? -1 : 0);
if (rc == 0) {
CHECK(!should_block);
return true;
}
if (acknowledgement_buffer_.size() < sizeof(sync_status)) {
const ssize_t header_bytes_left = sizeof(sync_status) - buf.size();
ssize_t rc = adb_read(fd, buf.end(), header_bytes_left);
if (rc <= 0) {
Error("failed to read copy response");
return false;
}
buf.resize(buf.size() + rc);
if (rc != header_bytes_left) {
// Early exit if we run out of data in the socket.
return true;
}
if (!should_block) {
// We don't want to read again yet, because the socket might be empty.
continue;
}
}
auto* hdr = reinterpret_cast<sync_status*>(buf.data());
if (hdr->id == ID_OKAY) {
buf.resize(0);
if (hdr->msglen != 0) {
Error("received ID_OKAY with msg_len (%" PRIu32 " != 0", hdr->msglen);
return false;
}
CopyDone();
continue;
} else if (hdr->id != ID_FAIL) {
Error("unexpected response from daemon: id = %#" PRIx32, hdr->id);
return false;
} else if (hdr->msglen > SYNC_DATA_MAX) {
Error("too-long message length from daemon: msglen = %" PRIu32, hdr->msglen);
return false;
}
const ssize_t msg_bytes_left = hdr->msglen + sizeof(sync_status) - buf.size();
CHECK_GE(msg_bytes_left, 0);
if (msg_bytes_left > 0) {
ssize_t rc = adb_read(fd, buf.end(), msg_bytes_left);
if (rc <= 0) {
Error("failed to read copy failure message");
return false;
}
buf.resize(buf.size() + rc);
if (rc != msg_bytes_left) {
if (should_block) {
continue;
} else {
return true;
}
}
std::string msg(buf.begin() + sizeof(sync_status), buf.end());
ReportDeferredCopyFailure(msg);
buf.resize(0);
return false;
}
}
return true;
}
void Printf(const char* fmt, ...) __attribute__((__format__(__printf__, 2, 3))) {
std::string s;
va_list ap;
va_start(ap, fmt);
android::base::StringAppendV(&s, fmt, ap);
va_end(ap);
line_printer_.Print(s, LinePrinter::INFO);
}
void Println(const char* fmt, ...) __attribute__((__format__(__printf__, 2, 3))) {
std::string s;
va_list ap;
va_start(ap, fmt);
android::base::StringAppendV(&s, fmt, ap);
va_end(ap);
line_printer_.Print(s, LinePrinter::INFO);
line_printer_.KeepInfoLine();
}
void Error(const char* fmt, ...) __attribute__((__format__(__printf__, 2, 3))) {
std::string s = "adb: error: ";
va_list ap;
va_start(ap, fmt);
android::base::StringAppendV(&s, fmt, ap);
va_end(ap);
line_printer_.Print(s, LinePrinter::ERROR);
}
void Warning(const char* fmt, ...) __attribute__((__format__(__printf__, 2, 3))) {
std::string s = "adb: warning: ";
va_list ap;
va_start(ap, fmt);
android::base::StringAppendV(&s, fmt, ap);
va_end(ap);
line_printer_.Print(s, LinePrinter::WARNING);
}
void ComputeExpectedTotalBytes(const std::vector<copyinfo>& file_list) {
current_ledger_.bytes_expected = 0;
for (const copyinfo& ci : file_list) {
// Unfortunately, this doesn't work for symbolic links, because we'll copy the
// target of the link rather than just creating a link. (But ci.size is the link size.)
if (!ci.skip) current_ledger_.bytes_expected += ci.size;
}
current_ledger_.expect_multiple_files = true;
}
void SetExpectedTotalBytes(uint64_t expected_total_bytes) {
current_ledger_.bytes_expected = expected_total_bytes;
current_ledger_.expect_multiple_files = false;
}
// TODO: add a char[max] buffer here, to replace syncsendbuf...
unique_fd fd;
size_t max;
private:
std::deque<std::pair<std::string, std::string>> deferred_acknowledgements_;
Block acknowledgement_buffer_;
const FeatureSet* features_ = nullptr;
bool have_stat_v2_;
bool have_ls_v2_;
bool have_sendrecv_v2_;
bool have_sendrecv_v2_brotli_;
bool have_sendrecv_v2_lz4_;
bool have_sendrecv_v2_zstd_;
bool have_sendrecv_v2_dry_run_send_;
TransferLedger global_ledger_;
TransferLedger current_ledger_;
LinePrinter line_printer_;
bool SendQuit() {
return SendRequest(ID_QUIT, ""); // TODO: add a SendResponse?
}
bool WriteOrDie(const std::string& from, const std::string& to, const void* data,
size_t data_length) {
if (!WriteFdExactly(fd, data, data_length)) {
if (errno == ECONNRESET) {
// Assume adbd told us why it was closing the connection, and
// try to read failure reason from adbd.
syncmsg msg;
if (!ReadFdExactly(fd, &msg.status, sizeof(msg.status))) {
Error("failed to copy '%s' to '%s': no response: %s", from.c_str(), to.c_str(),
strerror(errno));
} else if (msg.status.id != ID_FAIL) {
Error("failed to copy '%s' to '%s': not ID_FAIL: %d", from.c_str(), to.c_str(),
msg.status.id);
} else {
ReportCopyFailure(from, to, msg);
}
} else {
Error("%zu-byte write failed: %s", data_length, strerror(errno));
}
_exit(1);
}
return true;
}
};
static bool sync_ls(SyncConnection& sc, const std::string& path,
const std::function<sync_ls_cb>& func) {
return sc.SendLs(path) && sc.FinishLs(func);
}
static bool sync_stat(SyncConnection& sc, const std::string& path, struct stat* st) {
return sc.SendStat(path) && sc.FinishStat(st);
}
static bool sync_lstat(SyncConnection& sc, const std::string& path, struct stat* st) {
return sc.SendLstat(path) && sc.FinishStat(st);
}
static bool sync_stat_fallback(SyncConnection& sc, const std::string& path, struct stat* st) {
if (sync_stat(sc, path, st)) {
return true;
}
if (errno != ENOTSUP) {
return false;
}
// Try to emulate the parts we can when talking to older adbds.
bool lstat_result = sync_lstat(sc, path, st);
if (!lstat_result) {
return false;
}
if (S_ISLNK(st->st_mode)) {
// If the target is a symlink, figure out whether it's a file or a directory.
// Also, zero out the st_size field, since no one actually cares what the path length is.
st->st_size = 0;
std::string dir_path = path;
dir_path.push_back('/');
struct stat tmp_st;
st->st_mode &= ~S_IFMT;
if (sync_lstat(sc, dir_path, &tmp_st)) {
st->st_mode |= S_IFDIR;
} else {
st->st_mode |= S_IFREG;
}
}
return true;
}
static bool sync_send(SyncConnection& sc, const std::string& lpath, const std::string& rpath,
unsigned mtime, mode_t mode, bool sync, CompressionType compression,
bool dry_run) {
if (sync) {
struct stat st;
if (sync_lstat(sc, rpath, &st)) {
if (st.st_mtime == static_cast<time_t>(mtime)) {
sc.RecordFilesSkipped(1);
return true;
}
}
}
if (S_ISLNK(mode)) {
#if !defined(_WIN32)
char buf[PATH_MAX];
ssize_t data_length = readlink(lpath.c_str(), buf, PATH_MAX - 1);
if (data_length == -1) {
sc.Error("readlink '%s' failed: %s", lpath.c_str(), strerror(errno));
return false;
}
buf[data_length++] = '\0';
if (!sc.SendSmallFile(rpath, mode, lpath, rpath, mtime, buf, data_length, dry_run)) {
return false;
}
return sc.ReadAcknowledgements(sync);
#endif
}
struct stat st;
if (stat(lpath.c_str(), &st) == -1) {
sc.Error("failed to stat local file '%s': %s", lpath.c_str(), strerror(errno));
return false;
}
if (st.st_size < SYNC_DATA_MAX) {
std::string data;
if (!android::base::ReadFileToString(lpath, &data, true)) {
sc.Error("failed to read all of '%s': %s", lpath.c_str(), strerror(errno));
return false;
}
if (!sc.SendSmallFile(rpath, mode, lpath, rpath, mtime, data.data(), data.size(),
dry_run)) {
return false;
}
} else {
if (!sc.SendLargeFile(rpath, mode, lpath, rpath, mtime, compression, dry_run)) {
return false;
}
}
return sc.ReadAcknowledgements(sync);
}
static bool sync_recv_v1(SyncConnection& sc, const char* rpath, const char* lpath, const char* name,
uint64_t expected_size) {
if (!sc.SendRequest(ID_RECV_V1, rpath)) return false;
adb_unlink(lpath);
unique_fd lfd(adb_creat(lpath, 0644));
if (lfd < 0) {
sc.Error("cannot create '%s': %s", lpath, strerror(errno));
return false;
}
uint64_t bytes_copied = 0;
while (true) {
syncmsg msg;
if (!ReadFdExactly(sc.fd, &msg.data, sizeof(msg.data))) {
adb_unlink(lpath);
return false;
}
if (msg.data.id == ID_DONE) break;
if (msg.data.id != ID_DATA) {
adb_unlink(lpath);
sc.ReportCopyFailure(rpath, lpath, msg);
return false;
}
if (msg.data.size > sc.max) {
sc.Error("msg.data.size too large: %u (max %zu)", msg.data.size, sc.max);
adb_unlink(lpath);
return false;
}
char buffer[SYNC_DATA_MAX];
if (!ReadFdExactly(sc.fd, buffer, msg.data.size)) {
adb_unlink(lpath);
return false;
}
if (!WriteFdExactly(lfd, buffer, msg.data.size)) {
sc.Error("cannot write '%s': %s", lpath, strerror(errno));
adb_unlink(lpath);
return false;
}
bytes_copied += msg.data.size;
sc.RecordBytesTransferred(msg.data.size);
sc.ReportProgress(name != nullptr ? name : rpath, bytes_copied, expected_size);
}
sc.RecordFilesTransferred(1);
return true;
}
static bool sync_recv_v2(SyncConnection& sc, const char* rpath, const char* lpath, const char* name,
uint64_t expected_size, CompressionType compression) {
compression = sc.ResolveCompressionType(compression);
if (!sc.SendRecv2(rpath, compression)) return false;
adb_unlink(lpath);
unique_fd lfd(adb_creat(lpath, 0644));
if (lfd < 0) {
sc.Error("cannot create '%s': %s", lpath, strerror(errno));
return false;
}
uint64_t bytes_copied = 0;
Block buffer(SYNC_DATA_MAX);
std::variant<std::monostate, NullDecoder, BrotliDecoder, LZ4Decoder, ZstdDecoder>
decoder_storage;
Decoder* decoder = nullptr;
std::span buffer_span(buffer.data(), buffer.size());
switch (compression) {
case CompressionType::None:
decoder = &decoder_storage.emplace<NullDecoder>(buffer_span);
break;
case CompressionType::Brotli:
decoder = &decoder_storage.emplace<BrotliDecoder>(buffer_span);
break;
case CompressionType::LZ4:
decoder = &decoder_storage.emplace<LZ4Decoder>(buffer_span);
break;
case CompressionType::Zstd:
decoder = &decoder_storage.emplace<ZstdDecoder>(buffer_span);
break;
case CompressionType::Any:
LOG(FATAL) << "unexpected CompressionType::Any";
}
while (true) {
syncmsg msg;
if (!ReadFdExactly(sc.fd, &msg.data, sizeof(msg.data))) {
adb_unlink(lpath);
return false;
}
if (msg.data.id == ID_DONE) {
if (!decoder->Finish()) {
sc.Error("unexpected ID_DONE");
return false;
}
} else if (msg.data.id != ID_DATA) {
adb_unlink(lpath);
sc.ReportCopyFailure(rpath, lpath, msg);
return false;
} else {
if (msg.data.size > sc.max) {
sc.Error("msg.data.size too large: %u (max %zu)", msg.data.size, sc.max);
adb_unlink(lpath);
return false;
}
Block block(msg.data.size);
if (!ReadFdExactly(sc.fd, block.data(), msg.data.size)) {
adb_unlink(lpath);
return false;
}
decoder->Append(std::move(block));
}
while (true) {
std::span<char> output;
DecodeResult result = decoder->Decode(&output);
if (result == DecodeResult::Error) {
sc.Error("decompress failed");
adb_unlink(lpath);
return false;
}
if (!output.empty()) {
if (!WriteFdExactly(lfd, output.data(), output.size())) {
sc.Error("cannot write '%s': %s", lpath, strerror(errno));
adb_unlink(lpath);
return false;
}
}
bytes_copied += output.size();
sc.RecordBytesTransferred(output.size());
sc.ReportProgress(name != nullptr ? name : rpath, bytes_copied, expected_size);
if (result == DecodeResult::NeedInput) {
break;
} else if (result == DecodeResult::MoreOutput) {
continue;
} else if (result == DecodeResult::Done) {
sc.RecordFilesTransferred(1);
return true;
} else {
LOG(FATAL) << "invalid DecodeResult: " << static_cast<int>(result);
}
}
}
}
static bool sync_recv(SyncConnection& sc, const char* rpath, const char* lpath, const char* name,
uint64_t expected_size, CompressionType compression) {
if (sc.HaveSendRecv2()) {
return sync_recv_v2(sc, rpath, lpath, name, expected_size, compression);
} else {
return sync_recv_v1(sc, rpath, lpath, name, expected_size);
}
}
bool do_sync_ls(const char* path) {
SyncConnection sc;
if (!sc.IsValid()) return false;
return sync_ls(sc, path, [](unsigned mode, uint64_t size, uint64_t time, const char* name) {
printf("%08x %08" PRIx64 " %08" PRIx64 " %s\n", mode, size, time, name);
});
}
static bool IsDotOrDotDot(const char* name) {
return name[0] == '.' && (name[1] == '\0' || (name[1] == '.' && name[2] == '\0'));
}
static bool local_build_list(SyncConnection& sc, std::vector<copyinfo>* file_list,
std::vector<std::string>* directory_list, const std::string& lpath,
const std::string& rpath) {
std::vector<copyinfo> dirlist;
std::unique_ptr<DIR, int (*)(DIR*)> dir(opendir(lpath.c_str()), closedir);
if (!dir) {
sc.Error("cannot open '%s': %s", lpath.c_str(), strerror(errno));
return false;
}
bool empty_dir = true;
dirent* de;
while ((de = readdir(dir.get()))) {
if (IsDotOrDotDot(de->d_name)) {
continue;
}
empty_dir = false;
std::string stat_path = lpath + de->d_name;
struct stat st;
if (lstat(stat_path.c_str(), &st) == -1) {
sc.Error("cannot lstat '%s': %s", stat_path.c_str(),
strerror(errno));
continue;
}
copyinfo ci(lpath, rpath, de->d_name, st.st_mode);
if (S_ISDIR(st.st_mode)) {
dirlist.push_back(ci);
} else {
if (!should_push_file(st.st_mode)) {
sc.Warning("skipping special file '%s' (mode = 0o%o)", lpath.c_str(), st.st_mode);
ci.skip = true;
}
ci.time = st.st_mtime;
ci.size = st.st_size;
file_list->push_back(ci);
}
}
// Close this directory and recurse.
dir.reset();
for (const copyinfo& ci : dirlist) {
directory_list->push_back(ci.rpath);
local_build_list(sc, file_list, directory_list, ci.lpath, ci.rpath);
}
return true;
}
// dirname("//foo") returns "//", so we can't do the obvious `path == "/"`.
static bool is_root_dir(std::string_view path) {
for (char c : path) {
if (c != '/') {
return false;
}
}
return true;
}
static bool copy_local_dir_remote(SyncConnection& sc, std::string lpath, std::string rpath,
bool check_timestamps, bool list_only,
CompressionType compression, bool dry_run) {
sc.NewTransfer();
// Make sure that both directory paths end in a slash.
// Both paths are known to be nonempty, so we don't need to check.
ensure_trailing_separators(lpath, rpath);
// Recursively build the list of files to copy.
std::vector<copyinfo> file_list;
std::vector<std::string> directory_list;
for (std::string path = rpath; !is_root_dir(path); path = android::base::Dirname(path)) {
directory_list.push_back(path);
}
std::reverse(directory_list.begin(), directory_list.end());
int skipped = 0;
if (!local_build_list(sc, &file_list, &directory_list, lpath, rpath)) {
return false;
}
// b/110953234:
// P shipped with a bug that causes directory creation as a side-effect of a push to fail.
// Work around this by explicitly doing a mkdir via shell.
//
// Devices that don't support shell_v2 are unhappy if we try to send a too-long packet to them,
// but they're not affected by this bug, so only apply the workaround if we have shell_v2.
//
// TODO(b/25457350): We don't preserve permissions on directories.
// TODO: Find all of the leaves and `mkdir -p` them instead?
if (!CanUseFeature(sc.Features(), kFeatureFixedPushMkdir) &&
CanUseFeature(sc.Features(), kFeatureShell2)) {
SilentStandardStreamsCallbackInterface cb;
std::string cmd = "mkdir";
for (const auto& dir : directory_list) {
std::string escaped_path = escape_arg(dir);
if (escaped_path.size() > 16384) {
// Somewhat arbitrarily limit that probably won't ever happen.
sc.Error("path too long: %s", escaped_path.c_str());
return false;
}
// The maximum should be 64kiB, but that's not including other stuff that gets tacked
// onto the command line, so let's be a bit conservative.
if (cmd.size() + escaped_path.size() > 32768) {
// Dispatch the command, ignoring failure (since the directory might already exist).
send_shell_command(cmd, false, &cb);
cmd = "mkdir";
}
cmd += " ";
cmd += escaped_path;
}
if (cmd != "mkdir") {
send_shell_command(cmd, false, &cb);
}
}
if (check_timestamps) {
for (const copyinfo& ci : file_list) {
if (!sc.SendLstat(ci.rpath)) {
sc.Error("failed to send lstat");
return false;
}
}
for (copyinfo& ci : file_list) {
struct stat st;
if (sc.FinishStat(&st)) {
if (st.st_size == static_cast<off_t>(ci.size) && st.st_mtime == ci.time) {
ci.skip = true;
}
}
}
}
sc.ComputeExpectedTotalBytes(file_list);
for (const copyinfo& ci : file_list) {
if (!ci.skip) {
if (list_only) {
sc.Println("would push: %s -> %s", ci.lpath.c_str(), ci.rpath.c_str());
} else {
if (!sync_send(sc, ci.lpath, ci.rpath, ci.time, ci.mode, false, compression,
dry_run)) {
return false;
}
}
} else {
skipped++;
}
}
sc.RecordFilesSkipped(skipped);
bool success = sc.ReadAcknowledgements(true);
sc.ReportTransferRate(lpath, TransferDirection::push);
return success;
}
bool do_sync_push(const std::vector<const char*>& srcs, const char* dst, bool sync,
CompressionType compression, bool dry_run) {
SyncConnection sc;
if (!sc.IsValid()) return false;
bool success = true;
bool dst_exists;
bool dst_isdir;
struct stat st;
if (sync_stat_fallback(sc, dst, &st)) {
dst_exists = true;
dst_isdir = S_ISDIR(st.st_mode);
} else {
if (errno == ENOENT || errno == ENOPROTOOPT) {
dst_exists = false;
dst_isdir = false;
} else {
sc.Error("stat failed when trying to push to %s: %s", dst, strerror(errno));
return false;
}
}
if (!dst_isdir) {
if (srcs.size() > 1) {
sc.Error("target '%s' is not a directory", dst);
return false;
} else {
size_t dst_len = strlen(dst);
// A path that ends with a slash doesn't have to be a directory if
// it doesn't exist yet.
if (dst[dst_len - 1] == '/' && dst_exists) {
sc.Error("failed to access '%s': Not a directory", dst);
return false;
}
}
}
for (const char* src_path : srcs) {
const char* dst_path = dst;
struct stat st;
if (stat(src_path, &st) == -1) {
sc.Error("cannot stat '%s': %s", src_path, strerror(errno));
success = false;
continue;
}
if (S_ISDIR(st.st_mode)) {
std::string dst_dir = dst;
// If the destination path existed originally, the source directory
// should be copied as a child of the destination.
if (dst_exists) {
if (!dst_isdir) {
sc.Error("target '%s' is not a directory", dst);
return false;
}
// dst is a POSIX path, so we don't want to use the sysdeps
// helpers here.
if (dst_dir.back() != '/') {
dst_dir.push_back('/');
}
dst_dir.append(android::base::Basename(src_path));
}
success &=
copy_local_dir_remote(sc, src_path, dst_dir, sync, false, compression, dry_run);
continue;
} else if (!should_push_file(st.st_mode)) {
sc.Warning("skipping special file '%s' (mode = 0o%o)", src_path, st.st_mode);
continue;
}
std::string path_holder;
if (dst_isdir) {
// If we're copying a local file to a remote directory,
// we really want to copy to remote_dir + "/" + local_filename.
path_holder = dst_path;
if (path_holder.back() != '/') {
path_holder.push_back('/');
}
path_holder += android::base::Basename(src_path);
dst_path = path_holder.c_str();
}
sc.NewTransfer();
sc.SetExpectedTotalBytes(st.st_size);
success &= sync_send(sc, src_path, dst_path, st.st_mtime, st.st_mode, sync, compression,
dry_run);
sc.ReportTransferRate(src_path, TransferDirection::push);
}
success &= sc.ReadAcknowledgements(true);
sc.ReportOverallTransferRate(TransferDirection::push);
return success;
}
static bool remote_build_list(SyncConnection& sc, std::vector<copyinfo>* file_list,
const std::string& rpath, const std::string& lpath) {
std::vector<copyinfo> dirlist;
std::vector<copyinfo> linklist;
// Add an entry for the current directory to ensure it gets created before pulling its contents.
copyinfo ci(android::base::Dirname(lpath), android::base::Dirname(rpath),
android::base::Basename(lpath), S_IFDIR);
file_list->push_back(ci);
// Put the files/dirs in rpath on the lists.
auto callback = [&](unsigned mode, uint64_t size, uint64_t time, const char* name) {
if (IsDotOrDotDot(name)) {
return;
}
copyinfo ci(lpath, rpath, name, mode);
if (S_ISDIR(mode)) {
dirlist.push_back(ci);
} else if (S_ISLNK(mode)) {
linklist.push_back(ci);
} else {
if (!should_pull_file(ci.mode)) {
sc.Warning("skipping special file '%s' (mode = 0o%o)", ci.rpath.c_str(), ci.mode);
ci.skip = true;
}
ci.time = time;
ci.size = size;
file_list->push_back(ci);
}
};
if (!sync_ls(sc, rpath, callback)) {
return false;
}
// Check each symlink we found to see whether it's a file or directory.
for (copyinfo& link_ci : linklist) {
struct stat st;
if (!sync_stat_fallback(sc, link_ci.rpath, &st)) {
sc.Warning("stat failed for path %s: %s", link_ci.rpath.c_str(), strerror(errno));
continue;
}
if (S_ISDIR(st.st_mode)) {
dirlist.emplace_back(std::move(link_ci));
} else {
file_list->emplace_back(std::move(link_ci));
}
}
// Recurse into each directory we found.
while (!dirlist.empty()) {
copyinfo current = dirlist.back();
dirlist.pop_back();
if (!remote_build_list(sc, file_list, current.rpath, current.lpath)) {
return false;
}
}
return true;
}
static int set_time_and_mode(const std::string& lpath, time_t time,
unsigned int mode) {
struct utimbuf times = { time, time };
int r1 = utime(lpath.c_str(), &times);
/* use umask for permissions */
mode_t mask = umask(0000);
umask(mask);
int r2 = chmod(lpath.c_str(), mode & ~mask);
return r1 ? r1 : r2;
}
static bool copy_remote_dir_local(SyncConnection& sc, std::string rpath, std::string lpath,
bool copy_attrs, CompressionType compression) {
sc.NewTransfer();
// Make sure that both directory paths end in a slash.
// Both paths are known to be nonempty, so we don't need to check.
ensure_trailing_separators(lpath, rpath);
// Recursively build the list of files to copy.
sc.Printf("pull: building file list...");
std::vector<copyinfo> file_list;
if (!remote_build_list(sc, &file_list, rpath, lpath)) {
return false;
}
sc.ComputeExpectedTotalBytes(file_list);
int skipped = 0;
for (const copyinfo &ci : file_list) {
if (!ci.skip) {
if (S_ISDIR(ci.mode)) {
// Entry is for an empty directory, create it and continue.
// TODO(b/25457350): We don't preserve permissions on directories.
if (!mkdirs(ci.lpath)) {
sc.Error("failed to create directory '%s': %s",
ci.lpath.c_str(), strerror(errno));
return false;
}
continue;
}
if (!sync_recv(sc, ci.rpath.c_str(), ci.lpath.c_str(), nullptr, ci.size, compression)) {
return false;
}
if (copy_attrs && set_time_and_mode(ci.lpath, ci.time, ci.mode)) {
return false;
}
} else {
skipped++;
}
}
sc.RecordFilesSkipped(skipped);
sc.ReportTransferRate(rpath, TransferDirection::pull);
return true;
}
bool do_sync_pull(const std::vector<const char*>& srcs, const char* dst, bool copy_attrs,
CompressionType compression, const char* name) {
SyncConnection sc;
if (!sc.IsValid()) return false;
bool success = true;
struct stat st;
bool dst_exists = true;
if (stat(dst, &st) == -1) {
dst_exists = false;
// If we're only pulling one path, the destination path might point to
// a path that doesn't exist yet.
if (srcs.size() == 1 && errno == ENOENT) {
// However, its parent must exist.
struct stat parent_st;
if (stat(android::base::Dirname(dst).c_str(), &parent_st) == -1) {
sc.Error("cannot create file/directory '%s': %s", dst, strerror(errno));
return false;
}
} else {
sc.Error("failed to access '%s': %s", dst, strerror(errno));
return false;
}
}
bool dst_isdir = dst_exists && S_ISDIR(st.st_mode);
if (!dst_isdir) {
if (srcs.size() > 1) {
sc.Error("target '%s' is not a directory", dst);
return false;
} else {
size_t dst_len = strlen(dst);
// A path that ends with a slash doesn't have to be a directory if
// it doesn't exist yet.
if (adb_is_separator(dst[dst_len - 1]) && dst_exists) {
sc.Error("failed to access '%s': Not a directory", dst);
return false;
}
}
}
for (const char* src_path : srcs) {
const char* dst_path = dst;
struct stat src_st;
if (!sync_stat_fallback(sc, src_path, &src_st)) {
if (errno == ENOPROTOOPT) {
sc.Error("remote object '%s' does not exist", src_path);
} else {
sc.Error("failed to stat remote object '%s': %s", src_path, strerror(errno));
}
success = false;
continue;
}
bool src_isdir = S_ISDIR(src_st.st_mode);
if (src_isdir) {
std::string dst_dir = dst;
// If the destination path existed originally, the source directory
// should be copied as a child of the destination.
if (dst_exists) {
if (!dst_isdir) {
sc.Error("target '%s' is not a directory", dst);
return false;
}
if (!adb_is_separator(dst_dir.back())) {
dst_dir.push_back(OS_PATH_SEPARATOR);
}
dst_dir.append(android::base::Basename(src_path));
}
success &= copy_remote_dir_local(sc, src_path, dst_dir, copy_attrs, compression);
continue;
} else if (!should_pull_file(src_st.st_mode)) {
sc.Warning("skipping special file '%s' (mode = 0o%o)", src_path, src_st.st_mode);
continue;
}
std::string path_holder;
if (dst_isdir) {
// If we're copying a remote file to a local directory, we
// really want to copy to local_dir + OS_PATH_SEPARATOR +
// basename(remote).
path_holder = android::base::StringPrintf("%s%c%s", dst_path, OS_PATH_SEPARATOR,
android::base::Basename(src_path).c_str());
dst_path = path_holder.c_str();
}
sc.NewTransfer();
sc.SetExpectedTotalBytes(src_st.st_size);
if (!sync_recv(sc, src_path, dst_path, name, src_st.st_size, compression)) {
success = false;
continue;
}
if (copy_attrs && set_time_and_mode(dst_path, src_st.st_mtime, src_st.st_mode) != 0) {
success = false;
continue;
}
sc.ReportTransferRate(src_path, TransferDirection::pull);
}
sc.ReportOverallTransferRate(TransferDirection::pull);
return success;
}
bool do_sync_sync(const std::string& lpath, const std::string& rpath, bool list_only,
CompressionType compression, bool dry_run) {
SyncConnection sc;
if (!sc.IsValid()) return false;
bool success = copy_local_dir_remote(sc, lpath, rpath, true, list_only, compression, dry_run);
if (!list_only) {
sc.ReportOverallTransferRate(TransferDirection::push);
}
return success;
}