ecency-mobile/ios/Pods/Folly/folly/Subprocess.h
2019-05-29 14:32:35 +03:00

956 lines
33 KiB
C++

/*
* Copyright 2012-present Facebook, Inc.
*
* 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.
*/
/**
* Subprocess library, modeled after Python's subprocess module
* (http://docs.python.org/2/library/subprocess.html)
*
* This library defines one class (Subprocess) which represents a child
* process. Subprocess has two constructors: one that takes a vector<string>
* and executes the given executable without using the shell, and one
* that takes a string and executes the given command using the shell.
* Subprocess allows you to redirect the child's standard input, standard
* output, and standard error to/from child descriptors in the parent,
* or to create communication pipes between the child and the parent.
*
* The simplest example is a thread-safe [1] version of the system() library
* function:
* Subprocess(cmd).wait();
* which executes the command using the default shell and waits for it
* to complete, returning the exit status.
*
* A thread-safe [1] version of popen() (type="r", to read from the child):
* Subprocess proc(cmd, Subprocess::Options().pipeStdout());
* // read from proc.stdoutFd()
* proc.wait();
*
* A thread-safe [1] version of popen() (type="w", to write to the child):
* Subprocess proc(cmd, Subprocess::Options().pipeStdin());
* // write to proc.stdinFd()
* proc.wait();
*
* If you want to redirect both stdin and stdout to pipes, you can, but note
* that you're subject to a variety of deadlocks. You'll want to use
* nonblocking I/O, like the callback version of communicate().
*
* The string or IOBuf-based variants of communicate() are the simplest way
* to communicate with a child via its standard input, standard output, and
* standard error. They buffer everything in memory, so they are not great
* for large amounts of data (or long-running processes), but they are much
* simpler than the callback version.
*
* == A note on thread-safety ==
*
* [1] "thread-safe" refers ONLY to the fact that Subprocess is very careful
* to fork in a way that does not cause grief in multithreaded programs.
*
* Caveat: If your system does not have the atomic pipe2 system call, it is
* not safe to concurrently call Subprocess from different threads.
* Therefore, it is best to have a single thread be responsible for spawning
* subprocesses.
*
* A particular instances of Subprocess is emphatically **not** thread-safe.
* If you need to simultaneously communicate via the pipes, and interact
* with the Subprocess state, your best bet is to:
* - takeOwnershipOfPipes() to separate the pipe I/O from the subprocess.
* - Only interact with the Subprocess from one thread at a time.
*
* The current implementation of communicate() cannot be safely interrupted.
* To do so correctly, one would need to use EventFD, or open a dedicated
* pipe to be messaged from a different thread -- in particular, kill() will
* not do, since a descendant may keep the pipes open indefinitely.
*
* So, once you call communicate(), you must wait for it to return, and not
* touch the pipes from other threads. closeParentFd() is emphatically
* unsafe to call concurrently, and even sendSignal() is not a good idea.
* You can perhaps give the Subprocess's PID to a different thread before
* starting communicate(), and use that PID to send a signal without
* accessing the Subprocess object. In that case, you will need a mutex
* that ensures you don't wait() before you sent said signal. In a
* nutshell, don't do this.
*
* In fact, signals are inherently concurrency-unsafe on Unix: if you signal
* a PID, while another thread is in waitpid(), the signal may fire either
* before or after the process is reaped. This means that your signal can,
* in pathological circumstances, be delivered to the wrong process (ouch!).
* To avoid this, you should only use non-blocking waits (i.e. poll()), and
* make sure to serialize your signals (i.e. kill()) with the waits --
* either wait & signal from the same thread, or use a mutex.
*/
#pragma once
#include <signal.h>
#include <sys/types.h>
#if __APPLE__
#include <sys/wait.h>
#else
#include <wait.h>
#endif
#include <exception>
#include <string>
#include <vector>
#include <boost/container/flat_map.hpp>
#include <boost/operators.hpp>
#include <folly/Exception.h>
#include <folly/File.h>
#include <folly/FileUtil.h>
#include <folly/Function.h>
#include <folly/MapUtil.h>
#include <folly/Optional.h>
#include <folly/Portability.h>
#include <folly/Range.h>
#include <folly/gen/String.h>
#include <folly/io/IOBufQueue.h>
#include <folly/portability/SysResource.h>
namespace folly {
/**
* Class to wrap a process return code.
*/
class Subprocess;
class ProcessReturnCode {
public:
enum State {
// Subprocess starts in the constructor, so this state designates only
// default-initialized or moved-out ProcessReturnCodes.
NOT_STARTED,
RUNNING,
EXITED,
KILLED,
};
static ProcessReturnCode makeNotStarted() {
return ProcessReturnCode(RV_NOT_STARTED);
}
static ProcessReturnCode makeRunning() {
return ProcessReturnCode(RV_RUNNING);
}
static ProcessReturnCode make(int status);
// Default-initialized for convenience. Subprocess::returnCode() will
// never produce this value.
ProcessReturnCode() : rawStatus_(RV_NOT_STARTED) {}
// Trivially copyable
ProcessReturnCode(const ProcessReturnCode& p) = default;
ProcessReturnCode& operator=(const ProcessReturnCode& p) = default;
// Non-default move: In order for Subprocess to be movable, the "moved
// out" state must not be "running", or ~Subprocess() will abort.
ProcessReturnCode(ProcessReturnCode&& p) noexcept;
ProcessReturnCode& operator=(ProcessReturnCode&& p) noexcept;
/**
* Process state. One of:
* NOT_STARTED: process hasn't been started successfully
* RUNNING: process is currently running
* EXITED: process exited (successfully or not)
* KILLED: process was killed by a signal.
*/
State state() const;
/**
* Helper wrappers around state().
*/
bool notStarted() const {
return state() == NOT_STARTED;
}
bool running() const {
return state() == RUNNING;
}
bool exited() const {
return state() == EXITED;
}
bool killed() const {
return state() == KILLED;
}
/**
* Exit status. Only valid if state() == EXITED; throws otherwise.
*/
int exitStatus() const;
/**
* Signal that caused the process's termination. Only valid if
* state() == KILLED; throws otherwise.
*/
int killSignal() const;
/**
* Was a core file generated? Only valid if state() == KILLED; throws
* otherwise.
*/
bool coreDumped() const;
/**
* String representation; one of
* "not started"
* "running"
* "exited with status <status>"
* "killed by signal <signal>"
* "killed by signal <signal> (core dumped)"
*/
std::string str() const;
/**
* Helper function to enforce a precondition based on this.
* Throws std::logic_error if in an unexpected state.
*/
void enforce(State state) const;
private:
explicit ProcessReturnCode(int rv) : rawStatus_(rv) {}
static constexpr int RV_NOT_STARTED = -2;
static constexpr int RV_RUNNING = -1;
int rawStatus_;
};
/**
* Base exception thrown by the Subprocess methods.
*/
class FOLLY_EXPORT SubprocessError : public std::runtime_error {
public:
using std::runtime_error::runtime_error;
};
/**
* Exception thrown by *Checked methods of Subprocess.
*/
class FOLLY_EXPORT CalledProcessError : public SubprocessError {
public:
explicit CalledProcessError(ProcessReturnCode rc);
~CalledProcessError() throw() override = default;
ProcessReturnCode returnCode() const {
return returnCode_;
}
private:
ProcessReturnCode returnCode_;
};
/**
* Exception thrown if the subprocess cannot be started.
*/
class FOLLY_EXPORT SubprocessSpawnError : public SubprocessError {
public:
SubprocessSpawnError(const char* executable, int errCode, int errnoValue);
~SubprocessSpawnError() throw() override = default;
int errnoValue() const {
return errnoValue_;
}
private:
int errnoValue_;
};
/**
* Subprocess.
*/
class Subprocess {
public:
static const int CLOSE = -1;
static const int PIPE = -2;
static const int PIPE_IN = -3;
static const int PIPE_OUT = -4;
/**
* See Subprocess::Options::dangerousPostForkPreExecCallback() for usage.
* Every derived class should include the following warning:
*
* DANGER: This class runs after fork in a child processes. Be fast, the
* parent thread is waiting, but remember that other parent threads are
* running and may mutate your state. Avoid mutating any data belonging to
* the parent. Avoid interacting with non-POD data that originated in the
* parent. Avoid any libraries that may internally reference non-POD data.
* Especially beware parent mutexes -- for example, glog's LOG() uses one.
*/
struct DangerousPostForkPreExecCallback {
virtual ~DangerousPostForkPreExecCallback() {}
// This must return 0 on success, or an `errno` error code.
virtual int operator()() = 0;
};
/**
* Class representing various options: file descriptor behavior, and
* whether to use $PATH for searching for the executable,
*
* By default, we don't use $PATH, file descriptors are closed if
* the close-on-exec flag is set (fcntl FD_CLOEXEC) and inherited
* otherwise.
*/
class Options {
friend class Subprocess;
public:
Options() {} // E.g. https://gcc.gnu.org/bugzilla/show_bug.cgi?id=58328
/**
* Change action for file descriptor fd.
*
* "action" may be another file descriptor number (dup2()ed before the
* child execs), or one of CLOSE, PIPE_IN, and PIPE_OUT.
*
* CLOSE: close the file descriptor in the child
* PIPE_IN: open a pipe *from* the child
* PIPE_OUT: open a pipe *to* the child
*
* PIPE is a shortcut; same as PIPE_IN for stdin (fd 0), same as
* PIPE_OUT for stdout (fd 1) or stderr (fd 2), and an error for
* other file descriptors.
*/
Options& fd(int fd, int action);
/**
* Shortcut to change the action for standard input.
*/
Options& stdinFd(int action) {
return fd(STDIN_FILENO, action);
}
/**
* Shortcut to change the action for standard output.
*/
Options& stdoutFd(int action) {
return fd(STDOUT_FILENO, action);
}
/**
* Shortcut to change the action for standard error.
* Note that stderr(1) will redirect the standard error to the same
* file descriptor as standard output; the equivalent of bash's "2>&1"
*/
Options& stderrFd(int action) {
return fd(STDERR_FILENO, action);
}
Options& pipeStdin() {
return fd(STDIN_FILENO, PIPE_IN);
}
Options& pipeStdout() {
return fd(STDOUT_FILENO, PIPE_OUT);
}
Options& pipeStderr() {
return fd(STDERR_FILENO, PIPE_OUT);
}
/**
* Close all other fds (other than standard input, output, error,
* and file descriptors explicitly specified with fd()).
*
* This is potentially slow; it's generally a better idea to
* set the close-on-exec flag on all file descriptors that shouldn't
* be inherited by the child.
*
* Even with this option set, standard input, output, and error are
* not closed; use stdin(CLOSE), stdout(CLOSE), stderr(CLOSE) if you
* desire this.
*/
Options& closeOtherFds() {
closeOtherFds_ = true;
return *this;
}
/**
* Use the search path ($PATH) when searching for the executable.
*/
Options& usePath() {
usePath_ = true;
return *this;
}
/**
* Change the child's working directory, after the vfork.
*/
Options& chdir(const std::string& dir) {
childDir_ = dir;
return *this;
}
#if __linux__
/**
* Child will receive a signal when the parent exits.
*/
Options& parentDeathSignal(int sig) {
parentDeathSignal_ = sig;
return *this;
}
#endif
/**
* Child will be made a process group leader when it starts. Upside: one
* can reliably kill all its non-daemonizing descendants. Downside: the
* child will not receive Ctrl-C etc during interactive use.
*/
Options& processGroupLeader() {
processGroupLeader_ = true;
return *this;
}
/**
* *** READ THIS WHOLE DOCBLOCK BEFORE USING ***
*
* Run this callback in the child after the fork, just before the
* exec(), and after the child's state has been completely set up:
* - signal handlers have been reset to default handling and unblocked
* - the working directory was set
* - closed any file descriptors specified via Options()
* - set child process flags (see code)
*
* This is EXTREMELY DANGEROUS. For example, this innocuous-looking code
* can cause a fraction of your Subprocess launches to hang forever:
*
* LOG(INFO) << "Hello from the child";
*
* The reason is that glog has an internal mutex. If your fork() happens
* when the parent has the mutex locked, the child will wait forever.
*
* == GUIDELINES ==
*
* - Be quick -- the parent thread is blocked until you exit.
* - Remember that other parent threads are running, and may mutate your
* state.
* - Avoid mutating any data belonging to the parent.
* - Avoid interacting with non-POD data that came from the parent.
* - Avoid any libraries that may internally reference non-POD state.
* - Especially beware parent mutexes, e.g. LOG() uses a global mutex.
* - Avoid invoking the parent's destructors (you can accidentally
* delete files, terminate network connections, etc).
* - Read http://ewontfix.com/7/
*/
Options& dangerousPostForkPreExecCallback(
DangerousPostForkPreExecCallback* cob) {
dangerousPostForkPreExecCallback_ = cob;
return *this;
}
#if __linux__
/**
* This is an experimental feature, it is best you don't use it at this
* point of time.
* Although folly would support cloning with custom flags in some form, this
* API might change in the near future. So use the following assuming it is
* experimental. (Apr 11, 2017)
*
* This unlocks Subprocess to support clone flags, many of them need
* CAP_SYS_ADMIN permissions. It might also require you to go through the
* implementation to understand what happens before, between and after the
* fork-and-exec.
*
* `man 2 clone` would be a starting point for knowing about the available
* flags.
*/
using clone_flags_t = uint64_t;
Options& useCloneWithFlags(clone_flags_t cloneFlags) noexcept {
cloneFlags_ = cloneFlags;
return *this;
}
#endif
private:
typedef boost::container::flat_map<int, int> FdMap;
FdMap fdActions_;
bool closeOtherFds_{false};
bool usePath_{false};
std::string childDir_; // "" keeps the parent's working directory
#if __linux__
int parentDeathSignal_{0};
#endif
bool processGroupLeader_{false};
DangerousPostForkPreExecCallback* dangerousPostForkPreExecCallback_{
nullptr};
#if __linux__
// none means `vfork()` instead of a custom `clone()`
// Optional<> is used because value of '0' means do clone without any flags.
Optional<clone_flags_t> cloneFlags_;
#endif
};
// Non-copiable, but movable
Subprocess(const Subprocess&) = delete;
Subprocess& operator=(const Subprocess&) = delete;
Subprocess(Subprocess&&) = default;
Subprocess& operator=(Subprocess&&) = default;
/**
* Create an uninitialized subprocess.
*
* In this state it can only be destroyed, or assigned to using the move
* assignment operator.
*/
Subprocess();
/**
* Create a subprocess from the given arguments. argv[0] must be listed.
* If not-null, executable must be the actual executable
* being used (otherwise it's the same as argv[0]).
*
* If env is not-null, it must contain name=value strings to be used
* as the child's environment; otherwise, we inherit the environment
* from the parent. env must be null if options.usePath is set.
*/
explicit Subprocess(
const std::vector<std::string>& argv,
const Options& options = Options(),
const char* executable = nullptr,
const std::vector<std::string>* env = nullptr);
~Subprocess();
/**
* Create a subprocess run as a shell command (as shell -c 'command')
*
* The shell to use is taken from the environment variable $SHELL,
* or /bin/sh if $SHELL is unset.
*/
// clang-format off
[[deprecated(
"Prefer not running in a shell or use `shellify`.")]]
explicit Subprocess(
const std::string& cmd,
const Options& options = Options(),
const std::vector<std::string>* env = nullptr);
// clang-format on
////
//// The methods below only manipulate the process state, and do not
//// affect its communication pipes.
////
/**
* Return the child's pid, or -1 if the child wasn't successfully spawned
* or has already been wait()ed upon.
*/
pid_t pid() const;
/**
* Return the child's status (as per wait()) if the process has already
* been waited on, -1 if the process is still running, or -2 if the
* process hasn't been successfully started. NOTE that this does not call
* waitpid() or Subprocess::poll(), but simply returns the status stored
* in the Subprocess object.
*/
ProcessReturnCode returnCode() const {
return returnCode_;
}
/**
* Poll the child's status and return it. Return the exit status if the
* subprocess had quit, or RUNNING otherwise. Throws an std::logic_error
* if called on a Subprocess whose status is no longer RUNNING. No other
* exceptions are possible. Aborts on egregious violations of contract,
* e.g. if you wait for the underlying process without going through this
* Subprocess instance.
*/
ProcessReturnCode poll(struct rusage* ru = nullptr);
/**
* Poll the child's status. If the process is still running, return false.
* Otherwise, return true if the process exited with status 0 (success),
* or throw CalledProcessError if the process exited with a non-zero status.
*/
bool pollChecked();
/**
* Wait for the process to terminate and return its status. Like poll(),
* the only exception this can throw is std::logic_error if you call this
* on a Subprocess whose status is RUNNING. Aborts on egregious
* violations of contract, like an out-of-band waitpid(p.pid(), 0, 0).
*/
ProcessReturnCode wait();
/**
* Wait for the process to terminate, throw if unsuccessful.
*/
void waitChecked();
/**
* Send a signal to the child. Shortcuts for the commonly used Unix
* signals are below.
*/
void sendSignal(int signal);
void terminate() {
sendSignal(SIGTERM);
}
void kill() {
sendSignal(SIGKILL);
}
////
//// The methods below only affect the process's communication pipes, but
//// not its return code or state (they do not poll() or wait()).
////
/**
* Communicate with the child until all pipes to/from the child are closed.
*
* The input buffer is written to the process' stdin pipe, and data is read
* from the stdout and stderr pipes. Non-blocking I/O is performed on all
* pipes simultaneously to avoid deadlocks.
*
* The stdin pipe will be closed after the full input buffer has been written.
* An error will be thrown if a non-empty input buffer is supplied but stdin
* was not configured as a pipe.
*
* Returns a pair of buffers containing the data read from stdout and stderr.
* If stdout or stderr is not a pipe, an empty IOBuf queue will be returned
* for the respective buffer.
*
* Note that communicate() and communicateIOBuf() both return when all
* pipes to/from the child are closed; the child might stay alive after
* that, so you must still wait().
*
* communicateIOBuf() uses IOBufQueue for buffering (which has the
* advantage that it won't try to allocate all data at once), but it does
* store the subprocess's entire output in memory before returning.
*
* communicate() uses strings for simplicity.
*/
std::pair<IOBufQueue, IOBufQueue> communicateIOBuf(
IOBufQueue input = IOBufQueue());
std::pair<std::string, std::string> communicate(
StringPiece input = StringPiece());
/**
* Communicate with the child until all pipes to/from the child are closed.
*
* == Semantics ==
*
* readCallback(pfd, cfd) will be called whenever there's data available
* on any pipe *from* the child (PIPE_OUT). pfd is the file descriptor
* in the parent (that you use to read from); cfd is the file descriptor
* in the child (used for identifying the stream; 1 = child's standard
* output, 2 = child's standard error, etc)
*
* writeCallback(pfd, cfd) will be called whenever a pipe *to* the child is
* writable (PIPE_IN). pfd is the file descriptor in the parent (that you
* use to write to); cfd is the file descriptor in the child (used for
* identifying the stream; 0 = child's standard input, etc)
*
* The read and write callbacks must read from / write to pfd and return
* false during normal operation. Return true to tell communicate() to
* close the pipe. For readCallback, this might send SIGPIPE to the
* child, or make its writes fail with EPIPE, so you should generally
* avoid returning true unless you've reached end-of-file.
*
* communicate() returns when all pipes to/from the child are closed; the
* child might stay alive after that, so you must still wait().
* Conversely, the child may quit long before its pipes are closed, since
* its descendants can keep them alive forever.
*
* Most users won't need to use this callback version; the simpler version
* of communicate (which buffers data in memory) will probably work fine.
*
* == Things you must get correct ==
*
* 1) You MUST consume all data passed to readCallback (or return true to
* close the pipe). Similarly, you MUST write to a writable pipe (or
* return true to close the pipe). To do otherwise is an error that can
* result in a deadlock. You must do this even for pipes you are not
* interested in.
*
* 2) pfd is nonblocking, so be prepared for read() / write() to return -1
* and set errno to EAGAIN (in which case you should return false). Use
* readNoInt() from FileUtil.h to handle interrupted reads for you.
*
* 3) Your callbacks MUST NOT call any of the Subprocess methods that
* manipulate the pipe FDs. Check the docblocks, but, for example,
* neither closeParentFd (return true instead) nor takeOwnershipOfPipes
* are safe. Stick to reading/writing from pfd, as appropriate.
*
* == Good to know ==
*
* 1) See ReadLinesCallback for an easy way to consume the child's output
* streams line-by-line (or tokenized by another delimiter).
*
* 2) "Wait until the descendants close the pipes" is usually the behavior
* you want, since the descendants may have something to say even if the
* immediate child is dead. If you need to be able to force-close all
* parent FDs, communicate() will NOT work for you. Do it your own way by
* using takeOwnershipOfPipes().
*
* Why not? You can return "true" from your callbacks to sever active
* pipes, but inactive ones can remain open indefinitely. It is
* impossible to safely close inactive pipes while another thread is
* blocked in communicate(). This is BY DESIGN. Racing communicate()'s
* read/write callbacks can result in wrong I/O and data corruption. This
* class would need internal synchronization and timeouts, a poor and
* expensive implementation choice, in order to make closeParentFd()
* thread-safe.
*/
using FdCallback = folly::Function<bool(int, int)>;
void communicate(FdCallback readCallback, FdCallback writeCallback);
/**
* A readCallback for Subprocess::communicate() that helps you consume
* lines (or other delimited pieces) from your subprocess's file
* descriptors. Use the readLinesCallback() helper to get template
* deduction. For example:
*
* subprocess.communicate(
* Subprocess::readLinesCallback(
* [](int fd, folly::StringPiece s) {
* std::cout << fd << " said: " << s;
* return false; // Keep reading from the child
* }
* ),
* [](int pdf, int cfd){ return true; } // Don't write to the child
* );
*
* If a file line exceeds maxLineLength, your callback will get some
* initial chunks of maxLineLength with no trailing delimiters. The final
* chunk of a line is delimiter-terminated iff the delimiter was present
* in the input. In particular, the last line in a file always lacks a
* delimiter -- so if a file ends on a delimiter, the final line is empty.
*
* Like a regular communicate() callback, your fdLineCb() normally returns
* false. It may return true to tell Subprocess to close the underlying
* file descriptor. The child process may then receive SIGPIPE or get
* EPIPE errors on writes.
*/
template <class Callback>
class ReadLinesCallback {
private:
// Binds an FD to the client-provided FD+line callback
struct StreamSplitterCallback {
StreamSplitterCallback(Callback& cb, int fd) : cb_(cb), fd_(fd) {}
// The return value semantics are inverted vs StreamSplitter
bool operator()(StringPiece s) {
return !cb_(fd_, s);
}
Callback& cb_;
int fd_;
};
typedef gen::StreamSplitter<StreamSplitterCallback> LineSplitter;
public:
explicit ReadLinesCallback(
Callback&& fdLineCb,
uint64_t maxLineLength = 0, // No line length limit by default
char delimiter = '\n',
uint64_t bufSize = 1024)
: fdLineCb_(std::forward<Callback>(fdLineCb)),
maxLineLength_(maxLineLength),
delimiter_(delimiter),
bufSize_(bufSize) {}
bool operator()(int pfd, int cfd) {
// Make a splitter for this cfd if it doesn't already exist
auto it = fdToSplitter_.find(cfd);
auto& splitter = (it != fdToSplitter_.end())
? it->second
: fdToSplitter_
.emplace(
cfd,
LineSplitter(
delimiter_,
StreamSplitterCallback(fdLineCb_, cfd),
maxLineLength_))
.first->second;
// Read as much as we can from this FD
char buf[bufSize_];
while (true) {
ssize_t ret = readNoInt(pfd, buf, bufSize_);
if (ret == -1 && errno == EAGAIN) { // No more data for now
return false;
}
checkUnixError(ret, "read");
if (ret == 0) { // Reached end-of-file
splitter.flush(); // Ignore return since the file is over anyway
return true;
}
if (!splitter(StringPiece(buf, ret))) {
return true; // The callback told us to stop
}
}
}
private:
Callback fdLineCb_;
const uint64_t maxLineLength_;
const char delimiter_;
const uint64_t bufSize_;
// We lazily make splitters for all cfds that get used.
std::unordered_map<int, LineSplitter> fdToSplitter_;
};
// Helper to enable template deduction
template <class Callback>
static auto readLinesCallback(
Callback&& fdLineCb,
uint64_t maxLineLength = 0, // No line length limit by default
char delimiter = '\n',
uint64_t bufSize = 1024)
-> ReadLinesCallback<typename std::decay<Callback>::type> {
return ReadLinesCallback<typename std::decay<Callback>::type>(
std::forward<Callback>(fdLineCb), maxLineLength, delimiter, bufSize);
}
/**
* communicate() callbacks can use this to temporarily enable/disable
* notifications (callbacks) for a pipe to/from the child. By default,
* all are enabled. Useful for "chatty" communication -- you want to
* disable write callbacks until you receive the expected message.
*
* Disabling a pipe does not free you from the requirement to consume all
* incoming data. Failing to do so will easily create deadlock bugs.
*
* Throws if the childFd is not known.
*/
void enableNotifications(int childFd, bool enabled);
/**
* Are notifications for one pipe to/from child enabled? Throws if the
* childFd is not known.
*/
bool notificationsEnabled(int childFd) const;
////
//// The following methods are meant for the cases when communicate() is
//// not suitable. You should not need them when you call communicate(),
//// and, in fact, it is INHERENTLY UNSAFE to use closeParentFd() or
//// takeOwnershipOfPipes() from a communicate() callback.
////
/**
* Close the parent file descriptor given a file descriptor in the child.
* DO NOT USE from communicate() callbacks; make them return true instead.
*/
void closeParentFd(int childFd);
/**
* Set all pipes from / to child to be non-blocking. communicate() does
* this for you.
*/
void setAllNonBlocking();
/**
* Get parent file descriptor corresponding to the given file descriptor
* in the child. Throws if childFd isn't a pipe (PIPE_IN / PIPE_OUT).
* Do not close() the returned file descriptor; use closeParentFd, above.
*/
int parentFd(int childFd) const {
return pipes_[findByChildFd(childFd)].pipe.fd();
}
int stdinFd() const {
return parentFd(0);
}
int stdoutFd() const {
return parentFd(1);
}
int stderrFd() const {
return parentFd(2);
}
/**
* The child's pipes are logically separate from the process metadata
* (they may even be kept alive by the child's descendants). This call
* lets you manage the pipes' lifetime separetely from the lifetime of the
* child process.
*
* After this call, the Subprocess instance will have no knowledge of
* these pipes, and the caller assumes responsibility for managing their
* lifetimes. Pro-tip: prefer to explicitly close() the pipes, since
* folly::File would otherwise silently suppress I/O errors.
*
* No, you may NOT call this from a communicate() callback.
*/
struct ChildPipe {
ChildPipe(int fd, folly::File&& ppe) : childFd(fd), pipe(std::move(ppe)) {}
int childFd;
folly::File pipe; // Owns the parent FD
};
std::vector<ChildPipe> takeOwnershipOfPipes();
private:
// spawn() sets up a pipe to read errors from the child,
// then calls spawnInternal() to do the bulk of the work. Once
// spawnInternal() returns it reads the error pipe to see if the child
// encountered any errors.
void spawn(
std::unique_ptr<const char*[]> argv,
const char* executable,
const Options& options,
const std::vector<std::string>* env);
void spawnInternal(
std::unique_ptr<const char*[]> argv,
const char* executable,
Options& options,
const std::vector<std::string>* env,
int errFd);
// Actions to run in child.
// Note that this runs after vfork(), so tread lightly.
// Returns 0 on success, or an errno value on failure.
int prepareChild(
const Options& options,
const sigset_t* sigmask,
const char* childDir) const;
int runChild(
const char* executable,
char** argv,
char** env,
const Options& options) const;
/**
* Read from the error pipe, and throw SubprocessSpawnError if the child
* failed before calling exec().
*/
void readChildErrorPipe(int pfd, const char* executable);
// Returns an index into pipes_. Throws std::invalid_argument if not found.
size_t findByChildFd(const int childFd) const;
pid_t pid_{-1};
ProcessReturnCode returnCode_;
/**
* Represents a pipe between this process, and the child process (or its
* descendant). To interact with these pipes, you can use communicate(),
* or use parentFd() and related methods, or separate them from the
* Subprocess instance entirely via takeOwnershipOfPipes().
*/
struct Pipe : private boost::totally_ordered<Pipe> {
folly::File pipe; // Our end of the pipe, wrapped in a File to auto-close.
int childFd = -1; // Identifies the pipe: what FD is this in the child?
int direction = PIPE_IN; // one of PIPE_IN / PIPE_OUT
bool enabled = true; // Are notifications enabled in communicate()?
bool operator<(const Pipe& other) const {
return childFd < other.childFd;
}
bool operator==(const Pipe& other) const {
return childFd == other.childFd;
}
};
// Populated at process start according to fdActions, empty after
// takeOwnershipOfPipes(). Sorted by childFd. Can only have elements
// erased, but not inserted, after being populated.
//
// The number of pipes between parent and child is assumed to be small,
// so we're happy with a vector here, even if it means linear erase.
std::vector<Pipe> pipes_;
};
} // namespace folly