blob: 98a7cd8a9fa0ad092a1a47733c8b89acd9f16bf6 [file] [log] [blame]
// Copyright (c) 2012 The Chromium 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 "ipc/ipc_channel_posix.h"
#include <errno.h>
#include <fcntl.h>
#include <stddef.h>
#include <sys/socket.h>
#include <sys/stat.h>
#include <sys/types.h>
#include <sys/un.h>
#include <unistd.h>
#if defined(OS_OPENBSD)
#include <sys/uio.h>
#endif
#include <map>
#include <string>
#include "base/command_line.h"
#include "base/file_util.h"
#include "base/files/file_path.h"
#include "base/location.h"
#include "base/logging.h"
#include "base/memory/scoped_ptr.h"
#include "base/memory/singleton.h"
#include "base/posix/eintr_wrapper.h"
#include "base/posix/global_descriptors.h"
#include "base/process/process_handle.h"
#include "base/rand_util.h"
#include "base/stl_util.h"
#include "base/strings/string_util.h"
#include "base/synchronization/lock.h"
#include "ipc/file_descriptor_set_posix.h"
#include "ipc/ipc_descriptors.h"
#include "ipc/ipc_listener.h"
#include "ipc/ipc_logging.h"
#include "ipc/ipc_message_utils.h"
#include "ipc/ipc_switches.h"
#include "ipc/unix_domain_socket_util.h"
namespace IPC {
// IPC channels on Windows use named pipes (CreateNamedPipe()) with
// channel ids as the pipe names. Channels on POSIX use sockets as
// pipes These don't quite line up.
//
// When creating a child subprocess we use a socket pair and the parent side of
// the fork arranges it such that the initial control channel ends up on the
// magic file descriptor kPrimaryIPCChannel in the child. Future
// connections (file descriptors) can then be passed via that
// connection via sendmsg().
//
// A POSIX IPC channel can also be set up as a server for a bound UNIX domain
// socket, and will handle multiple connect and disconnect sequences. Currently
// it is limited to one connection at a time.
//------------------------------------------------------------------------------
namespace {
// The PipeMap class works around this quirk related to unit tests:
//
// When running as a server, we install the client socket in a
// specific file descriptor number (@kPrimaryIPCChannel). However, we
// also have to support the case where we are running unittests in the
// same process. (We do not support forking without execing.)
//
// Case 1: normal running
// The IPC server object will install a mapping in PipeMap from the
// name which it was given to the client pipe. When forking the client, the
// GetClientFileDescriptorMapping will ensure that the socket is installed in
// the magic slot (@kPrimaryIPCChannel). The client will search for the
// mapping, but it won't find any since we are in a new process. Thus the
// magic fd number is returned. Once the client connects, the server will
// close its copy of the client socket and remove the mapping.
//
// Case 2: unittests - client and server in the same process
// The IPC server will install a mapping as before. The client will search
// for a mapping and find out. It duplicates the file descriptor and
// connects. Once the client connects, the server will close the original
// copy of the client socket and remove the mapping. Thus, when the client
// object closes, it will close the only remaining copy of the client socket
// in the fd table and the server will see EOF on its side.
//
// TODO(port): a client process cannot connect to multiple IPC channels with
// this scheme.
class PipeMap {
public:
static PipeMap* GetInstance() {
return Singleton<PipeMap>::get();
}
~PipeMap() {
// Shouldn't have left over pipes.
DCHECK(map_.empty());
}
// Lookup a given channel id. Return -1 if not found.
int Lookup(const std::string& channel_id) {
base::AutoLock locked(lock_);
ChannelToFDMap::const_iterator i = map_.find(channel_id);
if (i == map_.end())
return -1;
return i->second;
}
// Remove the mapping for the given channel id. No error is signaled if the
// channel_id doesn't exist
void Remove(const std::string& channel_id) {
base::AutoLock locked(lock_);
map_.erase(channel_id);
}
// Insert a mapping from @channel_id to @fd. It's a fatal error to insert a
// mapping if one already exists for the given channel_id
void Insert(const std::string& channel_id, int fd) {
base::AutoLock locked(lock_);
DCHECK_NE(-1, fd);
ChannelToFDMap::const_iterator i = map_.find(channel_id);
CHECK(i == map_.end()) << "Creating second IPC server (fd " << fd << ") "
<< "for '" << channel_id << "' while first "
<< "(fd " << i->second << ") still exists";
map_[channel_id] = fd;
}
private:
base::Lock lock_;
typedef std::map<std::string, int> ChannelToFDMap;
ChannelToFDMap map_;
friend struct DefaultSingletonTraits<PipeMap>;
};
//------------------------------------------------------------------------------
bool SocketWriteErrorIsRecoverable() {
#if defined(OS_MACOSX)
// On OS X if sendmsg() is trying to send fds between processes and there
// isn't enough room in the output buffer to send the fd structure over
// atomically then EMSGSIZE is returned.
//
// EMSGSIZE presents a problem since the system APIs can only call us when
// there's room in the socket buffer and not when there is "enough" room.
//
// The current behavior is to return to the event loop when EMSGSIZE is
// received and hopefull service another FD. This is however still
// technically a busy wait since the event loop will call us right back until
// the receiver has read enough data to allow passing the FD over atomically.
return errno == EAGAIN || errno == EMSGSIZE;
#else
return errno == EAGAIN;
#endif // OS_MACOSX
}
} // namespace
//------------------------------------------------------------------------------
#if defined(OS_LINUX)
int Channel::ChannelImpl::global_pid_ = 0;
#endif // OS_LINUX
Channel::ChannelImpl::ChannelImpl(const IPC::ChannelHandle& channel_handle,
Mode mode, Listener* listener)
: ChannelReader(listener),
mode_(mode),
peer_pid_(base::kNullProcessId),
is_blocked_on_write_(false),
waiting_connect_(true),
message_send_bytes_written_(0),
server_listen_pipe_(-1),
pipe_(-1),
client_pipe_(-1),
#if defined(IPC_USES_READWRITE)
fd_pipe_(-1),
remote_fd_pipe_(-1),
#endif // IPC_USES_READWRITE
pipe_name_(channel_handle.name),
must_unlink_(false) {
memset(input_cmsg_buf_, 0, sizeof(input_cmsg_buf_));
if (!CreatePipe(channel_handle)) {
// The pipe may have been closed already.
const char *modestr = (mode_ & MODE_SERVER_FLAG) ? "server" : "client";
LOG(WARNING) << "Unable to create pipe named \"" << channel_handle.name
<< "\" in " << modestr << " mode";
}
}
Channel::ChannelImpl::~ChannelImpl() {
Close();
}
bool SocketPair(int* fd1, int* fd2) {
int pipe_fds[2];
if (socketpair(AF_UNIX, SOCK_STREAM, 0, pipe_fds) != 0) {
PLOG(ERROR) << "socketpair()";
return false;
}
// Set both ends to be non-blocking.
if (fcntl(pipe_fds[0], F_SETFL, O_NONBLOCK) == -1 ||
fcntl(pipe_fds[1], F_SETFL, O_NONBLOCK) == -1) {
PLOG(ERROR) << "fcntl(O_NONBLOCK)";
if (HANDLE_EINTR(close(pipe_fds[0])) < 0)
PLOG(ERROR) << "close";
if (HANDLE_EINTR(close(pipe_fds[1])) < 0)
PLOG(ERROR) << "close";
return false;
}
*fd1 = pipe_fds[0];
*fd2 = pipe_fds[1];
return true;
}
bool Channel::ChannelImpl::CreatePipe(
const IPC::ChannelHandle& channel_handle) {
DCHECK(server_listen_pipe_ == -1 && pipe_ == -1);
// Four possible cases:
// 1) It's a channel wrapping a pipe that is given to us.
// 2) It's for a named channel, so we create it.
// 3) It's for a client that we implement ourself. This is used
// in unittesting.
// 4) It's the initial IPC channel:
// 4a) Client side: Pull the pipe out of the GlobalDescriptors set.
// 4b) Server side: create the pipe.
int local_pipe = -1;
if (channel_handle.socket.fd != -1) {
// Case 1 from comment above.
local_pipe = channel_handle.socket.fd;
#if defined(IPC_USES_READWRITE)
// Test the socket passed into us to make sure it is nonblocking.
// We don't want to call read/write on a blocking socket.
int value = fcntl(local_pipe, F_GETFL);
if (value == -1) {
PLOG(ERROR) << "fcntl(F_GETFL) " << pipe_name_;
return false;
}
if (!(value & O_NONBLOCK)) {
LOG(ERROR) << "Socket " << pipe_name_ << " must be O_NONBLOCK";
return false;
}
#endif // IPC_USES_READWRITE
} else if (mode_ & MODE_NAMED_FLAG) {
// Case 2 from comment above.
if (mode_ & MODE_SERVER_FLAG) {
if (!CreateServerUnixDomainSocket(base::FilePath(pipe_name_),
&local_pipe)) {
return false;
}
must_unlink_ = true;
} else if (mode_ & MODE_CLIENT_FLAG) {
if (!CreateClientUnixDomainSocket(base::FilePath(pipe_name_),
&local_pipe)) {
return false;
}
} else {
LOG(ERROR) << "Bad mode: " << mode_;
return false;
}
} else {
local_pipe = PipeMap::GetInstance()->Lookup(pipe_name_);
if (mode_ & MODE_CLIENT_FLAG) {
if (local_pipe != -1) {
// Case 3 from comment above.
// We only allow one connection.
local_pipe = HANDLE_EINTR(dup(local_pipe));
PipeMap::GetInstance()->Remove(pipe_name_);
} else {
// Case 4a from comment above.
// Guard against inappropriate reuse of the initial IPC channel. If
// an IPC channel closes and someone attempts to reuse it by name, the
// initial channel must not be recycled here. http://crbug.com/26754.
static bool used_initial_channel = false;
if (used_initial_channel) {
LOG(FATAL) << "Denying attempt to reuse initial IPC channel for "
<< pipe_name_;
return false;
}
used_initial_channel = true;
local_pipe =
base::GlobalDescriptors::GetInstance()->Get(kPrimaryIPCChannel);
}
} else if (mode_ & MODE_SERVER_FLAG) {
// Case 4b from comment above.
if (local_pipe != -1) {
LOG(ERROR) << "Server already exists for " << pipe_name_;
return false;
}
base::AutoLock lock(client_pipe_lock_);
if (!SocketPair(&local_pipe, &client_pipe_))
return false;
PipeMap::GetInstance()->Insert(pipe_name_, client_pipe_);
} else {
LOG(ERROR) << "Bad mode: " << mode_;
return false;
}
}
#if defined(IPC_USES_READWRITE)
// Create a dedicated socketpair() for exchanging file descriptors.
// See comments for IPC_USES_READWRITE for details.
if (mode_ & MODE_CLIENT_FLAG) {
if (!SocketPair(&fd_pipe_, &remote_fd_pipe_)) {
return false;
}
}
#endif // IPC_USES_READWRITE
if ((mode_ & MODE_SERVER_FLAG) && (mode_ & MODE_NAMED_FLAG)) {
server_listen_pipe_ = local_pipe;
local_pipe = -1;
}
pipe_ = local_pipe;
return true;
}
bool Channel::ChannelImpl::Connect() {
if (server_listen_pipe_ == -1 && pipe_ == -1) {
DLOG(INFO) << "Channel creation failed: " << pipe_name_;
return false;
}
bool did_connect = true;
if (server_listen_pipe_ != -1) {
// Watch the pipe for connections, and turn any connections into
// active sockets.
base::MessageLoopForIO::current()->WatchFileDescriptor(
server_listen_pipe_,
true,
base::MessageLoopForIO::WATCH_READ,
&server_listen_connection_watcher_,
this);
} else {
did_connect = AcceptConnection();
}
return did_connect;
}
bool Channel::ChannelImpl::ProcessOutgoingMessages() {
DCHECK(!waiting_connect_); // Why are we trying to send messages if there's
// no connection?
if (output_queue_.empty())
return true;
if (pipe_ == -1)
return false;
// Write out all the messages we can till the write blocks or there are no
// more outgoing messages.
while (!output_queue_.empty()) {
Message* msg = output_queue_.front();
size_t amt_to_write = msg->size() - message_send_bytes_written_;
DCHECK_NE(0U, amt_to_write);
const char* out_bytes = reinterpret_cast<const char*>(msg->data()) +
message_send_bytes_written_;
struct msghdr msgh = {0};
struct iovec iov = {const_cast<char*>(out_bytes), amt_to_write};
msgh.msg_iov = &iov;
msgh.msg_iovlen = 1;
char buf[CMSG_SPACE(
sizeof(int) * FileDescriptorSet::kMaxDescriptorsPerMessage)];
ssize_t bytes_written = 1;
int fd_written = -1;
if (message_send_bytes_written_ == 0 &&
!msg->file_descriptor_set()->empty()) {
// This is the first chunk of a message which has descriptors to send
struct cmsghdr *cmsg;
const unsigned num_fds = msg->file_descriptor_set()->size();
DCHECK(num_fds <= FileDescriptorSet::kMaxDescriptorsPerMessage);
if (msg->file_descriptor_set()->ContainsDirectoryDescriptor()) {
LOG(FATAL) << "Panic: attempting to transport directory descriptor over"
" IPC. Aborting to maintain sandbox isolation.";
// If you have hit this then something tried to send a file descriptor
// to a directory over an IPC channel. Since IPC channels span
// sandboxes this is very bad: the receiving process can use openat
// with ".." elements in the path in order to reach the real
// filesystem.
}
msgh.msg_control = buf;
msgh.msg_controllen = CMSG_SPACE(sizeof(int) * num_fds);
cmsg = CMSG_FIRSTHDR(&msgh);
cmsg->cmsg_level = SOL_SOCKET;
cmsg->cmsg_type = SCM_RIGHTS;
cmsg->cmsg_len = CMSG_LEN(sizeof(int) * num_fds);
msg->file_descriptor_set()->GetDescriptors(
reinterpret_cast<int*>(CMSG_DATA(cmsg)));
msgh.msg_controllen = cmsg->cmsg_len;
// DCHECK_LE above already checks that
// num_fds < kMaxDescriptorsPerMessage so no danger of overflow.
msg->header()->num_fds = static_cast<uint16>(num_fds);
#if defined(IPC_USES_READWRITE)
if (!IsHelloMessage(*msg)) {
// Only the Hello message sends the file descriptor with the message.
// Subsequently, we can send file descriptors on the dedicated
// fd_pipe_ which makes Seccomp sandbox operation more efficient.
struct iovec fd_pipe_iov = { const_cast<char *>(""), 1 };
msgh.msg_iov = &fd_pipe_iov;
fd_written = fd_pipe_;
bytes_written = HANDLE_EINTR(sendmsg(fd_pipe_, &msgh, MSG_DONTWAIT));
msgh.msg_iov = &iov;
msgh.msg_controllen = 0;
if (bytes_written > 0) {
msg->file_descriptor_set()->CommitAll();
}
}
#endif // IPC_USES_READWRITE
}
if (bytes_written == 1) {
fd_written = pipe_;
#if defined(IPC_USES_READWRITE)
if ((mode_ & MODE_CLIENT_FLAG) && IsHelloMessage(*msg)) {
DCHECK_EQ(msg->file_descriptor_set()->size(), 1U);
}
if (!msgh.msg_controllen) {
bytes_written = HANDLE_EINTR(write(pipe_, out_bytes, amt_to_write));
} else
#endif // IPC_USES_READWRITE
{
bytes_written = HANDLE_EINTR(sendmsg(pipe_, &msgh, MSG_DONTWAIT));
}
}
if (bytes_written > 0)
msg->file_descriptor_set()->CommitAll();
if (bytes_written < 0 && !SocketWriteErrorIsRecoverable()) {
#if defined(OS_MACOSX)
// On OSX writing to a pipe with no listener returns EPERM.
if (errno == EPERM) {
Close();
return false;
}
#endif // OS_MACOSX
if (errno == EPIPE) {
Close();
return false;
}
PLOG(ERROR) << "pipe error on "
<< fd_written
<< " Currently writing message of size: "
<< msg->size();
return false;
}
if (static_cast<size_t>(bytes_written) != amt_to_write) {
if (bytes_written > 0) {
// If write() fails with EAGAIN then bytes_written will be -1.
message_send_bytes_written_ += bytes_written;
}
// Tell libevent to call us back once things are unblocked.
is_blocked_on_write_ = true;
base::MessageLoopForIO::current()->WatchFileDescriptor(
pipe_,
false, // One shot
base::MessageLoopForIO::WATCH_WRITE,
&write_watcher_,
this);
return true;
} else {
message_send_bytes_written_ = 0;
// Message sent OK!
DVLOG(2) << "sent message @" << msg << " on channel @" << this
<< " with type " << msg->type() << " on fd " << pipe_;
delete output_queue_.front();
output_queue_.pop();
}
}
return true;
}
bool Channel::ChannelImpl::Send(Message* message) {
DVLOG(2) << "sending message @" << message << " on channel @" << this
<< " with type " << message->type()
<< " (" << output_queue_.size() << " in queue)";
#ifdef IPC_MESSAGE_LOG_ENABLED
Logging::GetInstance()->OnSendMessage(message, "");
#endif // IPC_MESSAGE_LOG_ENABLED
message->TraceMessageBegin();
output_queue_.push(message);
if (!is_blocked_on_write_ && !waiting_connect_) {
return ProcessOutgoingMessages();
}
return true;
}
int Channel::ChannelImpl::GetClientFileDescriptor() {
base::AutoLock lock(client_pipe_lock_);
return client_pipe_;
}
int Channel::ChannelImpl::TakeClientFileDescriptor() {
base::AutoLock lock(client_pipe_lock_);
int fd = client_pipe_;
if (client_pipe_ != -1) {
PipeMap::GetInstance()->Remove(pipe_name_);
client_pipe_ = -1;
}
return fd;
}
void Channel::ChannelImpl::CloseClientFileDescriptor() {
base::AutoLock lock(client_pipe_lock_);
if (client_pipe_ != -1) {
PipeMap::GetInstance()->Remove(pipe_name_);
if (HANDLE_EINTR(close(client_pipe_)) < 0)
PLOG(ERROR) << "close " << pipe_name_;
client_pipe_ = -1;
}
}
bool Channel::ChannelImpl::AcceptsConnections() const {
return server_listen_pipe_ != -1;
}
bool Channel::ChannelImpl::HasAcceptedConnection() const {
return AcceptsConnections() && pipe_ != -1;
}
bool Channel::ChannelImpl::GetPeerEuid(uid_t* peer_euid) const {
DCHECK(!(mode_ & MODE_SERVER) || HasAcceptedConnection());
return IPC::GetPeerEuid(pipe_, peer_euid);
}
void Channel::ChannelImpl::ResetToAcceptingConnectionState() {
// Unregister libevent for the unix domain socket and close it.
read_watcher_.StopWatchingFileDescriptor();
write_watcher_.StopWatchingFileDescriptor();
if (pipe_ != -1) {
if (HANDLE_EINTR(close(pipe_)) < 0)
PLOG(ERROR) << "close pipe_ " << pipe_name_;
pipe_ = -1;
}
#if defined(IPC_USES_READWRITE)
if (fd_pipe_ != -1) {
if (HANDLE_EINTR(close(fd_pipe_)) < 0)
PLOG(ERROR) << "close fd_pipe_ " << pipe_name_;
fd_pipe_ = -1;
}
if (remote_fd_pipe_ != -1) {
if (HANDLE_EINTR(close(remote_fd_pipe_)) < 0)
PLOG(ERROR) << "close remote_fd_pipe_ " << pipe_name_;
remote_fd_pipe_ = -1;
}
#endif // IPC_USES_READWRITE
while (!output_queue_.empty()) {
Message* m = output_queue_.front();
output_queue_.pop();
delete m;
}
// Close any outstanding, received file descriptors.
ClearInputFDs();
}
// static
bool Channel::ChannelImpl::IsNamedServerInitialized(
const std::string& channel_id) {
return base::PathExists(base::FilePath(channel_id));
}
#if defined(OS_LINUX)
// static
void Channel::ChannelImpl::SetGlobalPid(int pid) {
global_pid_ = pid;
}
#endif // OS_LINUX
// Called by libevent when we can read from the pipe without blocking.
void Channel::ChannelImpl::OnFileCanReadWithoutBlocking(int fd) {
bool send_server_hello_msg = false;
if (fd == server_listen_pipe_) {
int new_pipe = 0;
if (!ServerAcceptConnection(server_listen_pipe_, &new_pipe) ||
new_pipe < 0) {
Close();
listener()->OnChannelListenError();
}
if (pipe_ != -1) {
// We already have a connection. We only handle one at a time.
// close our new descriptor.
if (HANDLE_EINTR(shutdown(new_pipe, SHUT_RDWR)) < 0)
DPLOG(ERROR) << "shutdown " << pipe_name_;
if (HANDLE_EINTR(close(new_pipe)) < 0)
DPLOG(ERROR) << "close " << pipe_name_;
listener()->OnChannelDenied();
return;
}
pipe_ = new_pipe;
if ((mode_ & MODE_OPEN_ACCESS_FLAG) == 0) {
// Verify that the IPC channel peer is running as the same user.
uid_t client_euid;
if (!GetPeerEuid(&client_euid)) {
DLOG(ERROR) << "Unable to query client euid";
ResetToAcceptingConnectionState();
return;
}
if (client_euid != geteuid()) {
DLOG(WARNING) << "Client euid is not authorised";
ResetToAcceptingConnectionState();
return;
}
}
if (!AcceptConnection()) {
NOTREACHED() << "AcceptConnection should not fail on server";
}
send_server_hello_msg = true;
waiting_connect_ = false;
} else if (fd == pipe_) {
if (waiting_connect_ && (mode_ & MODE_SERVER_FLAG)) {
send_server_hello_msg = true;
waiting_connect_ = false;
}
if (!ProcessIncomingMessages()) {
// ClosePipeOnError may delete this object, so we mustn't call
// ProcessOutgoingMessages.
send_server_hello_msg = false;
ClosePipeOnError();
}
} else {
NOTREACHED() << "Unknown pipe " << fd;
}
// If we're a server and handshaking, then we want to make sure that we
// only send our handshake message after we've processed the client's.
// This gives us a chance to kill the client if the incoming handshake
// is invalid.
if (send_server_hello_msg) {
ProcessOutgoingMessages();
}
}
// Called by libevent when we can write to the pipe without blocking.
void Channel::ChannelImpl::OnFileCanWriteWithoutBlocking(int fd) {
DCHECK_EQ(pipe_, fd);
is_blocked_on_write_ = false;
if (!ProcessOutgoingMessages()) {
ClosePipeOnError();
}
}
bool Channel::ChannelImpl::AcceptConnection() {
base::MessageLoopForIO::current()->WatchFileDescriptor(
pipe_, true, base::MessageLoopForIO::WATCH_READ, &read_watcher_, this);
QueueHelloMessage();
if (mode_ & MODE_CLIENT_FLAG) {
// If we are a client we want to send a hello message out immediately.
// In server mode we will send a hello message when we receive one from a
// client.
waiting_connect_ = false;
return ProcessOutgoingMessages();
} else if (mode_ & MODE_SERVER_FLAG) {
waiting_connect_ = true;
return true;
} else {
NOTREACHED();
return false;
}
}
void Channel::ChannelImpl::ClosePipeOnError() {
if (HasAcceptedConnection()) {
ResetToAcceptingConnectionState();
listener()->OnChannelError();
} else {
Close();
if (AcceptsConnections()) {
listener()->OnChannelListenError();
} else {
listener()->OnChannelError();
}
}
}
int Channel::ChannelImpl::GetHelloMessageProcId() {
int pid = base::GetCurrentProcId();
#if defined(OS_LINUX)
// Our process may be in a sandbox with a separate PID namespace.
if (global_pid_) {
pid = global_pid_;
}
#endif
return pid;
}
void Channel::ChannelImpl::QueueHelloMessage() {
// Create the Hello message
scoped_ptr<Message> msg(new Message(MSG_ROUTING_NONE,
HELLO_MESSAGE_TYPE,
IPC::Message::PRIORITY_NORMAL));
if (!msg->WriteInt(GetHelloMessageProcId())) {
NOTREACHED() << "Unable to pickle hello message proc id";
}
#if defined(IPC_USES_READWRITE)
scoped_ptr<Message> hello;
if (remote_fd_pipe_ != -1) {
if (!msg->WriteFileDescriptor(base::FileDescriptor(remote_fd_pipe_,
false))) {
NOTREACHED() << "Unable to pickle hello message file descriptors";
}
DCHECK_EQ(msg->file_descriptor_set()->size(), 1U);
}
#endif // IPC_USES_READWRITE
output_queue_.push(msg.release());
}
Channel::ChannelImpl::ReadState Channel::ChannelImpl::ReadData(
char* buffer,
int buffer_len,
int* bytes_read) {
if (pipe_ == -1)
return READ_FAILED;
struct msghdr msg = {0};
struct iovec iov = {buffer, static_cast<size_t>(buffer_len)};
msg.msg_iov = &iov;
msg.msg_iovlen = 1;
msg.msg_control = input_cmsg_buf_;
// recvmsg() returns 0 if the connection has closed or EAGAIN if no data
// is waiting on the pipe.
#if defined(IPC_USES_READWRITE)
if (fd_pipe_ >= 0) {
*bytes_read = HANDLE_EINTR(read(pipe_, buffer, buffer_len));
msg.msg_controllen = 0;
} else
#endif // IPC_USES_READWRITE
{
msg.msg_controllen = sizeof(input_cmsg_buf_);
*bytes_read = HANDLE_EINTR(recvmsg(pipe_, &msg, MSG_DONTWAIT));
}
if (*bytes_read < 0) {
if (errno == EAGAIN) {
return READ_PENDING;
#if defined(OS_MACOSX)
} else if (errno == EPERM) {
// On OSX, reading from a pipe with no listener returns EPERM
// treat this as a special case to prevent spurious error messages
// to the console.
return READ_FAILED;
#endif // OS_MACOSX
} else if (errno == ECONNRESET || errno == EPIPE) {
return READ_FAILED;
} else {
PLOG(ERROR) << "pipe error (" << pipe_ << ")";
return READ_FAILED;
}
} else if (*bytes_read == 0) {
// The pipe has closed...
return READ_FAILED;
}
DCHECK(*bytes_read);
CloseClientFileDescriptor();
// Read any file descriptors from the message.
if (!ExtractFileDescriptorsFromMsghdr(&msg))
return READ_FAILED;
return READ_SUCCEEDED;
}
#if defined(IPC_USES_READWRITE)
bool Channel::ChannelImpl::ReadFileDescriptorsFromFDPipe() {
char dummy;
struct iovec fd_pipe_iov = { &dummy, 1 };
struct msghdr msg = { 0 };
msg.msg_iov = &fd_pipe_iov;
msg.msg_iovlen = 1;
msg.msg_control = input_cmsg_buf_;
msg.msg_controllen = sizeof(input_cmsg_buf_);
ssize_t bytes_received = HANDLE_EINTR(recvmsg(fd_pipe_, &msg, MSG_DONTWAIT));
if (bytes_received != 1)
return true; // No message waiting.
if (!ExtractFileDescriptorsFromMsghdr(&msg))
return false;
return true;
}
#endif
// On Posix, we need to fix up the file descriptors before the input message
// is dispatched.
//
// This will read from the input_fds_ (READWRITE mode only) and read more
// handles from the FD pipe if necessary.
bool Channel::ChannelImpl::WillDispatchInputMessage(Message* msg) {
uint16 header_fds = msg->header()->num_fds;
if (!header_fds)
return true; // Nothing to do.
// The message has file descriptors.
const char* error = NULL;
if (header_fds > input_fds_.size()) {
// The message has been completely received, but we didn't get
// enough file descriptors.
#if defined(IPC_USES_READWRITE)
if (!ReadFileDescriptorsFromFDPipe())
return false;
if (header_fds > input_fds_.size())
#endif // IPC_USES_READWRITE
error = "Message needs unreceived descriptors";
}
if (header_fds > FileDescriptorSet::kMaxDescriptorsPerMessage)
error = "Message requires an excessive number of descriptors";
if (error) {
LOG(WARNING) << error
<< " channel:" << this
<< " message-type:" << msg->type()
<< " header()->num_fds:" << header_fds;
// Abort the connection.
ClearInputFDs();
return false;
}
// The shenaniganery below with &foo.front() requires input_fds_ to have
// contiguous underlying storage (such as a simple array or a std::vector).
// This is why the header warns not to make input_fds_ a deque<>.
msg->file_descriptor_set()->SetDescriptors(&input_fds_.front(),
header_fds);
input_fds_.erase(input_fds_.begin(), input_fds_.begin() + header_fds);
return true;
}
bool Channel::ChannelImpl::DidEmptyInputBuffers() {
// When the input data buffer is empty, the fds should be too. If this is
// not the case, we probably have a rogue renderer which is trying to fill
// our descriptor table.
return input_fds_.empty();
}
bool Channel::ChannelImpl::ExtractFileDescriptorsFromMsghdr(msghdr* msg) {
// Check that there are any control messages. On OSX, CMSG_FIRSTHDR will
// return an invalid non-NULL pointer in the case that controllen == 0.
if (msg->msg_controllen == 0)
return true;
for (cmsghdr* cmsg = CMSG_FIRSTHDR(msg);
cmsg;
cmsg = CMSG_NXTHDR(msg, cmsg)) {
if (cmsg->cmsg_level == SOL_SOCKET && cmsg->cmsg_type == SCM_RIGHTS) {
unsigned payload_len = cmsg->cmsg_len - CMSG_LEN(0);
DCHECK_EQ(0U, payload_len % sizeof(int));
const int* file_descriptors = reinterpret_cast<int*>(CMSG_DATA(cmsg));
unsigned num_file_descriptors = payload_len / 4;
input_fds_.insert(input_fds_.end(),
file_descriptors,
file_descriptors + num_file_descriptors);
// Check this after adding the FDs so we don't leak them.
if (msg->msg_flags & MSG_CTRUNC) {
ClearInputFDs();
return false;
}
return true;
}
}
// No file descriptors found, but that's OK.
return true;
}
void Channel::ChannelImpl::ClearInputFDs() {
for (size_t i = 0; i < input_fds_.size(); ++i) {
if (HANDLE_EINTR(close(input_fds_[i])) < 0)
PLOG(ERROR) << "close ";
}
input_fds_.clear();
}
void Channel::ChannelImpl::HandleHelloMessage(const Message& msg) {
// The Hello message contains only the process id.
PickleIterator iter(msg);
int pid;
if (!msg.ReadInt(&iter, &pid))
NOTREACHED();
#if defined(IPC_USES_READWRITE)
if (mode_ & MODE_SERVER_FLAG) {
// With IPC_USES_READWRITE, the Hello message from the client to the
// server also contains the fd_pipe_, which will be used for all
// subsequent file descriptor passing.
DCHECK_EQ(msg.file_descriptor_set()->size(), 1U);
base::FileDescriptor descriptor;
if (!msg.ReadFileDescriptor(&iter, &descriptor)) {
NOTREACHED();
}
fd_pipe_ = descriptor.fd;
CHECK(descriptor.auto_close);
}
#endif // IPC_USES_READWRITE
peer_pid_ = pid;
listener()->OnChannelConnected(pid);
}
void Channel::ChannelImpl::Close() {
// Close can be called multiple time, so we need to make sure we're
// idempotent.
ResetToAcceptingConnectionState();
if (must_unlink_) {
unlink(pipe_name_.c_str());
must_unlink_ = false;
}
if (server_listen_pipe_ != -1) {
if (HANDLE_EINTR(close(server_listen_pipe_)) < 0)
DPLOG(ERROR) << "close " << server_listen_pipe_;
server_listen_pipe_ = -1;
// Unregister libevent for the listening socket and close it.
server_listen_connection_watcher_.StopWatchingFileDescriptor();
}
CloseClientFileDescriptor();
}
//------------------------------------------------------------------------------
// Channel's methods simply call through to ChannelImpl.
Channel::Channel(const IPC::ChannelHandle& channel_handle, Mode mode,
Listener* listener)
: channel_impl_(new ChannelImpl(channel_handle, mode, listener)) {
}
Channel::~Channel() {
delete channel_impl_;
}
bool Channel::Connect() {
return channel_impl_->Connect();
}
void Channel::Close() {
if (channel_impl_)
channel_impl_->Close();
}
base::ProcessId Channel::peer_pid() const {
return channel_impl_->peer_pid();
}
bool Channel::Send(Message* message) {
return channel_impl_->Send(message);
}
int Channel::GetClientFileDescriptor() const {
return channel_impl_->GetClientFileDescriptor();
}
int Channel::TakeClientFileDescriptor() {
return channel_impl_->TakeClientFileDescriptor();
}
bool Channel::AcceptsConnections() const {
return channel_impl_->AcceptsConnections();
}
bool Channel::HasAcceptedConnection() const {
return channel_impl_->HasAcceptedConnection();
}
bool Channel::GetPeerEuid(uid_t* peer_euid) const {
return channel_impl_->GetPeerEuid(peer_euid);
}
void Channel::ResetToAcceptingConnectionState() {
channel_impl_->ResetToAcceptingConnectionState();
}
// static
bool Channel::IsNamedServerInitialized(const std::string& channel_id) {
return ChannelImpl::IsNamedServerInitialized(channel_id);
}
// static
std::string Channel::GenerateVerifiedChannelID(const std::string& prefix) {
// A random name is sufficient validation on posix systems, so we don't need
// an additional shared secret.
std::string id = prefix;
if (!id.empty())
id.append(".");
return id.append(GenerateUniqueRandomChannelID());
}
#if defined(OS_LINUX)
// static
void Channel::SetGlobalPid(int pid) {
ChannelImpl::SetGlobalPid(pid);
}
#endif // OS_LINUX
} // namespace IPC