src/libstd/sys/vxworks/process/process_common.rs - third_party/rust - Git at Google

 use crate::os::unix::prelude::*;

 use crate::ffi::{OsString, OsStr, CString, CStr};
 use crate::fmt;
 use crate::io;
 use crate::ptr;
 use crate::sys::fd::FileDesc;
 use crate::sys::fs::{File, OpenOptions};
 use crate::sys::pipe::{self, AnonPipe};
 use crate::sys_common::process::CommandEnv;
 use crate::collections::BTreeMap;

 use libc::{c_int, gid_t, uid_t, c_char, EXIT_SUCCESS, EXIT_FAILURE};

 pub use crate::ffi::OsString as EnvKey;

 ////////////////////////////////////////////////////////////////////////////////
 // Command
 ////////////////////////////////////////////////////////////////////////////////

 pub struct Command {
     // Currently we try hard to ensure that the call to `.exec()` doesn't
     // actually allocate any memory. While many platforms try to ensure that
     // memory allocation works after a fork in a multithreaded process, it's
     // been observed to be buggy and somewhat unreliable, so we do our best to
     // just not do it at all!
     //
     // Along those lines, the `argv` and `envp` raw pointers here are exactly
     // what's gonna get passed to `execvp`. The `argv` array starts with the
     // `program` and ends with a NULL, and the `envp` pointer, if present, is
     // also null-terminated.
     //
     // Right now we don't support removing arguments, so there's no much fancy
     // support there, but we support adding and removing environment variables,
     // so a side table is used to track where in the `envp` array each key is
     // located. Whenever we add a key we update it in place if it's already
     // present, and whenever we remove a key we update the locations of all
     // other keys.
     program: CString,
     args: Vec<CString>,
     argv: Argv,
     env: CommandEnv,

     cwd: Option<CString>,
     uid: Option<uid_t>,
     gid: Option<gid_t>,
     saw_nul: bool,
     closures: Vec<Box<dyn FnMut() -> io::Result<()> + Send + Sync>>,
     stdin: Option<Stdio>,
     stdout: Option<Stdio>,
     stderr: Option<Stdio>,
 }

 // Create a new type for argv, so that we can make it `Send`
 struct Argv(Vec<*const c_char>);

 // It is safe to make Argv Send, because it contains pointers to memory owned by `Command.args`
 unsafe impl Send for Argv {}

 // passed back to std::process with the pipes connected to the child, if any
 // were requested
 pub struct StdioPipes {
     pub stdin: Option<AnonPipe>,
     pub stdout: Option<AnonPipe>,
     pub stderr: Option<AnonPipe>,
 }

 // passed to do_exec() with configuration of what the child stdio should look
 // like
 pub struct ChildPipes {
     pub stdin: ChildStdio,
     pub stdout: ChildStdio,
     pub stderr: ChildStdio,
 }

 pub enum ChildStdio {
     Inherit,
     Explicit(c_int),
     Owned(FileDesc),
 }

 pub enum Stdio {
     Inherit,
     Null,
     MakePipe,
     Fd(FileDesc),
 }

 impl Command {
     pub fn new(program: &OsStr) -> Command {
         let mut saw_nul = false;
         let program = os2c(program, &mut saw_nul);
         Command {
             argv: Argv(vec![program.as_ptr(), ptr::null()]),
             program,
             args: Vec::new(),
             env: Default::default(),
             cwd: None,
             uid: None,
             gid: None,
             saw_nul,
             closures: Vec::new(),
             stdin: None,
             stdout: None,
             stderr: None,
         }
     }

     pub fn arg(&mut self, arg: &OsStr) {
         // Overwrite the trailing NULL pointer in `argv` and then add a new null
         // pointer.
         let arg = os2c(arg, &mut self.saw_nul);
         self.argv.0[self.args.len() + 1] = arg.as_ptr();
         self.argv.0.push(ptr::null());

         // Also make sure we keep track of the owned value to schedule a
         // destructor for this memory.
         self.args.push(arg);
     }

     pub fn cwd(&mut self, dir: &OsStr) {
         self.cwd = Some(os2c(dir, &mut self.saw_nul));
     }
     pub fn uid(&mut self, id: uid_t) {
         self.uid = Some(id);
     }
     pub fn gid(&mut self, id: gid_t) {
         self.gid = Some(id);
     }

     pub fn saw_nul(&self) -> bool {
         self.saw_nul
     }
     pub fn get_argv(&self) -> &Vec<*const c_char> {
         &self.argv.0
     }

     #[allow(dead_code)]
     pub fn get_cwd(&self) -> &Option<CString> {
         &self.cwd
     }
     #[allow(dead_code)]
     pub fn get_uid(&self) -> Option<uid_t> {
         self.uid
     }
     #[allow(dead_code)]
     pub fn get_gid(&self) -> Option<gid_t> {
         self.gid
     }

     pub fn get_closures(&mut self) -> &mut Vec<Box<dyn FnMut() -> io::Result<()> + Send + Sync>> {
         &mut self.closures
     }

     pub unsafe fn pre_exec(
         &mut self,
         _f: Box<dyn FnMut() -> io::Result<()> + Send + Sync>,
     ) {
         // Fork() is not supported in vxWorks so no way to run the closure in the new procecss.
         unimplemented!();
     }

     pub fn stdin(&mut self, stdin: Stdio) {
         self.stdin = Some(stdin);
     }

     pub fn stdout(&mut self, stdout: Stdio) {
         self.stdout = Some(stdout);
     }

     pub fn stderr(&mut self, stderr: Stdio) {
         self.stderr = Some(stderr);
     }

     pub fn env_mut(&mut self) -> &mut CommandEnv {
         &mut self.env
     }

     pub fn capture_env(&mut self) -> Option<CStringArray> {
         let maybe_env = self.env.capture_if_changed();
         maybe_env.map(|env| construct_envp(env, &mut self.saw_nul))
     }
     #[allow(dead_code)]
     pub fn env_saw_path(&self) -> bool {
         self.env.have_changed_path()
     }

     pub fn setup_io(&self, default: Stdio, needs_stdin: bool)
                 -> io::Result<(StdioPipes, ChildPipes)> {
         let null = Stdio::Null;
         let default_stdin = if needs_stdin {&default} else {&null};
         let stdin = self.stdin.as_ref().unwrap_or(default_stdin);
         let stdout = self.stdout.as_ref().unwrap_or(&default);
         let stderr = self.stderr.as_ref().unwrap_or(&default);
         let (their_stdin, our_stdin) = stdin.to_child_stdio(true)?;
         let (their_stdout, our_stdout) = stdout.to_child_stdio(false)?;
         let (their_stderr, our_stderr) = stderr.to_child_stdio(false)?;
         let ours = StdioPipes {
             stdin: our_stdin,
             stdout: our_stdout,
             stderr: our_stderr,
         };
         let theirs = ChildPipes {
             stdin: their_stdin,
             stdout: their_stdout,
             stderr: their_stderr,
         };
         Ok((ours, theirs))
     }
 }

 fn os2c(s: &OsStr, saw_nul: &mut bool) -> CString {
     CString::new(s.as_bytes()).unwrap_or_else(|_e| {
         *saw_nul = true;
         CString::new("<string-with-nul>").unwrap()
     })
 }

 // Helper type to manage ownership of the strings within a C-style array.
 pub struct CStringArray {
     items: Vec<CString>,
     ptrs: Vec<*const c_char>
 }

 impl CStringArray {
     pub fn with_capacity(capacity: usize) -> Self {
         let mut result = CStringArray {
             items: Vec::with_capacity(capacity),
             ptrs: Vec::with_capacity(capacity+1)
         };
         result.ptrs.push(ptr::null());
         result
     }
     pub fn push(&mut self, item: CString) {
         let l = self.ptrs.len();
         self.ptrs[l-1] = item.as_ptr();
         self.ptrs.push(ptr::null());
         self.items.push(item);
     }
     pub fn as_ptr(&self) -> *const *const c_char {
         self.ptrs.as_ptr()
     }
 }

 fn construct_envp(env: BTreeMap<OsString, OsString>, saw_nul: &mut bool) -> CStringArray {
     let mut result = CStringArray::with_capacity(env.len());
     for (k, v) in env {
         let mut k: OsString = k.into();

         // Reserve additional space for '=' and null terminator
         k.reserve_exact(v.len() + 2);
         k.push("=");
         k.push(&v);

         // Add the new entry into the array
         if let Ok(item) = CString::new(k.into_vec()) {
             result.push(item);
         } else {
             *saw_nul = true;
         }
     }

     result
 }

 impl Stdio {
     pub fn to_child_stdio(&self, readable: bool)
                       -> io::Result<(ChildStdio, Option<AnonPipe>)> {
         match *self {
             Stdio::Inherit => {
                 Ok((ChildStdio::Inherit, None))
             },

             // Make sure that the source descriptors are not an stdio
             // descriptor, otherwise the order which we set the child's
             // descriptors may blow away a descriptor which we are hoping to
             // save. For example, suppose we want the child's stderr to be the
             // parent's stdout, and the child's stdout to be the parent's
             // stderr. No matter which we dup first, the second will get
             // overwritten prematurely.
             Stdio::Fd(ref fd) => {
                 if fd.raw() >= 0 && fd.raw() <= libc::STDERR_FILENO {
                     Ok((ChildStdio::Owned(fd.duplicate()?), None))
                 } else {
                     Ok((ChildStdio::Explicit(fd.raw()), None))
                 }
             }

             Stdio::MakePipe => {
                 let (reader, writer) = pipe::anon_pipe()?;
                 let (ours, theirs) = if readable {
                     (writer, reader)
                 } else {
                     (reader, writer)
                 };
                 Ok((ChildStdio::Owned(theirs.into_fd()), Some(ours)))
             }

             Stdio::Null => {
                 let mut opts = OpenOptions::new();
                 opts.read(readable);
                 opts.write(!readable);
                 let path = unsafe {
                     CStr::from_ptr("/null\0".as_ptr() as *const _)
                 };
                 let fd = File::open_c(&path, &opts)?;
                 Ok((ChildStdio::Owned(fd.into_fd()), None))
             }
         }
     }
 }

 impl From<AnonPipe> for Stdio {
     fn from(pipe: AnonPipe) -> Stdio {
         Stdio::Fd(pipe.into_fd())
     }
 }

 impl From<File> for Stdio {
     fn from(file: File) -> Stdio {
         Stdio::Fd(file.into_fd())
     }
 }

 impl ChildStdio {
     pub fn fd(&self) -> Option<c_int> {
         match *self {
             ChildStdio::Inherit => None,
             ChildStdio::Explicit(fd) => Some(fd),
             ChildStdio::Owned(ref fd) => Some(fd.raw()),
         }
     }
 }

 impl fmt::Debug for Command {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         write!(f, "{:?}", self.program)?;
         for arg in &self.args {
             write!(f, " {:?}", arg)?;
         }
         Ok(())
     }
 }

 /// Unix exit statuses
 #[derive(PartialEq, Eq, Clone, Copy, Debug)]
 pub struct ExitStatus(c_int);

 impl ExitStatus {
     pub fn new(status: c_int) -> ExitStatus {
         ExitStatus(status)
     }

     fn exited(&self) -> bool {
         /*unsafe*/ { libc::WIFEXITED(self.0) }
     }

     pub fn success(&self) -> bool {
         self.code() == Some(0)
     }

     pub fn code(&self) -> Option<i32> {
         if self.exited() {
             Some(/*unsafe*/ { libc::WEXITSTATUS(self.0) })
         } else {
             None
         }
     }

     pub fn signal(&self) -> Option<i32> {
         if !self.exited() {
             Some(/*unsafe*/ { libc::WTERMSIG(self.0) })
         } else {
             None
         }
     }
 }

 impl From<c_int> for ExitStatus {
     fn from(a: c_int) -> ExitStatus {
         ExitStatus(a)
     }
 }

 impl fmt::Display for ExitStatus {
     fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
         if let Some(code) = self.code() {
             write!(f, "exit code: {}", code)
         } else {
             let signal = self.signal().unwrap();
             write!(f, "signal: {}", signal)
         }
     }
 }

 #[derive(PartialEq, Eq, Clone, Copy, Debug)]
 pub struct ExitCode(u8);

 impl ExitCode {
     pub const SUCCESS: ExitCode = ExitCode(EXIT_SUCCESS as _);
     pub const FAILURE: ExitCode = ExitCode(EXIT_FAILURE as _);

     #[inline]
     pub fn as_i32(&self) -> i32 {
         self.0 as i32
     }
 }
	use crate::os::unix::prelude::*;

	use crate::ffi::{OsString, OsStr, CString, CStr};
	use crate::fmt;
	use crate::io;
	use crate::ptr;
	use crate::sys::fd::FileDesc;
	use crate::sys::fs::{File, OpenOptions};
	use crate::sys::pipe::{self, AnonPipe};
	use crate::sys_common::process::CommandEnv;
	use crate::collections::BTreeMap;

	use libc::{c_int, gid_t, uid_t, c_char, EXIT_SUCCESS, EXIT_FAILURE};

	pub use crate::ffi::OsString as EnvKey;

	////////////////////////////////////////////////////////////////////////////////
	// Command
	////////////////////////////////////////////////////////////////////////////////

	pub struct Command {
	// Currently we try hard to ensure that the call to `.exec()` doesn't
	// actually allocate any memory. While many platforms try to ensure that
	// memory allocation works after a fork in a multithreaded process, it's
	// been observed to be buggy and somewhat unreliable, so we do our best to
	// just not do it at all!
	//
	// Along those lines, the `argv` and `envp` raw pointers here are exactly
	// what's gonna get passed to `execvp`. The `argv` array starts with the
	// `program` and ends with a NULL, and the `envp` pointer, if present, is
	// also null-terminated.
	//
	// Right now we don't support removing arguments, so there's no much fancy
	// support there, but we support adding and removing environment variables,
	// so a side table is used to track where in the `envp` array each key is
	// located. Whenever we add a key we update it in place if it's already
	// present, and whenever we remove a key we update the locations of all
	// other keys.
	program: CString,
	args: Vec<CString>,
	argv: Argv,
	env: CommandEnv,

	cwd: Option<CString>,
	uid: Option<uid_t>,
	gid: Option<gid_t>,
	saw_nul: bool,
	closures: Vec<Box<dyn FnMut() -> io::Result<()> + Send + Sync>>,
	stdin: Option<Stdio>,
	stdout: Option<Stdio>,
	stderr: Option<Stdio>,
	}

	// Create a new type for argv, so that we can make it `Send`
	struct Argv(Vec<*const c_char>);

	// It is safe to make Argv Send, because it contains pointers to memory owned by `Command.args`
	unsafe impl Send for Argv {}

	// passed back to std::process with the pipes connected to the child, if any
	// were requested
	pub struct StdioPipes {
	pub stdin: Option<AnonPipe>,
	pub stdout: Option<AnonPipe>,
	pub stderr: Option<AnonPipe>,
	}

	// passed to do_exec() with configuration of what the child stdio should look
	// like
	pub struct ChildPipes {
	pub stdin: ChildStdio,
	pub stdout: ChildStdio,
	pub stderr: ChildStdio,
	}

	pub enum ChildStdio {
	Inherit,
	Explicit(c_int),
	Owned(FileDesc),
	}

	pub enum Stdio {
	Inherit,
	Null,
	MakePipe,
	Fd(FileDesc),
	}

	impl Command {
	pub fn new(program: &OsStr) -> Command {
	let mut saw_nul = false;
	let program = os2c(program, &mut saw_nul);
	Command {
	argv: Argv(vec![program.as_ptr(), ptr::null()]),
	program,
	args: Vec::new(),
	env: Default::default(),
	cwd: None,
	uid: None,
	gid: None,
	saw_nul,
	closures: Vec::new(),
	stdin: None,
	stdout: None,
	stderr: None,
	}
	}

	pub fn arg(&mut self, arg: &OsStr) {
	// Overwrite the trailing NULL pointer in `argv` and then add a new null
	// pointer.
	let arg = os2c(arg, &mut self.saw_nul);
	self.argv.0[self.args.len() + 1] = arg.as_ptr();
	self.argv.0.push(ptr::null());

	// Also make sure we keep track of the owned value to schedule a
	// destructor for this memory.
	self.args.push(arg);
	}

	pub fn cwd(&mut self, dir: &OsStr) {
	self.cwd = Some(os2c(dir, &mut self.saw_nul));
	}
	pub fn uid(&mut self, id: uid_t) {
	self.uid = Some(id);
	}
	pub fn gid(&mut self, id: gid_t) {
	self.gid = Some(id);
	}

	pub fn saw_nul(&self) -> bool {
	self.saw_nul
	}
	pub fn get_argv(&self) -> &Vec<*const c_char> {
	&self.argv.0
	}

	#[allow(dead_code)]
	pub fn get_cwd(&self) -> &Option<CString> {
	&self.cwd
	}
	#[allow(dead_code)]
	pub fn get_uid(&self) -> Option<uid_t> {
	self.uid
	}
	#[allow(dead_code)]
	pub fn get_gid(&self) -> Option<gid_t> {
	self.gid
	}

	pub fn get_closures(&mut self) -> &mut Vec<Box<dyn FnMut() -> io::Result<()> + Send + Sync>> {
	&mut self.closures
	}

	pub unsafe fn pre_exec(
	&mut self,
	_f: Box<dyn FnMut() -> io::Result<()> + Send + Sync>,
	) {
	// Fork() is not supported in vxWorks so no way to run the closure in the new procecss.
	unimplemented!();
	}

	pub fn stdin(&mut self, stdin: Stdio) {
	self.stdin = Some(stdin);
	}

	pub fn stdout(&mut self, stdout: Stdio) {
	self.stdout = Some(stdout);
	}

	pub fn stderr(&mut self, stderr: Stdio) {
	self.stderr = Some(stderr);
	}

	pub fn env_mut(&mut self) -> &mut CommandEnv {
	&mut self.env
	}

	pub fn capture_env(&mut self) -> Option<CStringArray> {
	let maybe_env = self.env.capture_if_changed();
	maybe_env.map(\|env\| construct_envp(env, &mut self.saw_nul))
	}
	#[allow(dead_code)]
	pub fn env_saw_path(&self) -> bool {
	self.env.have_changed_path()
	}

	pub fn setup_io(&self, default: Stdio, needs_stdin: bool)
	-> io::Result<(StdioPipes, ChildPipes)> {
	let null = Stdio::Null;
	let default_stdin = if needs_stdin {&default} else {&null};
	let stdin = self.stdin.as_ref().unwrap_or(default_stdin);
	let stdout = self.stdout.as_ref().unwrap_or(&default);
	let stderr = self.stderr.as_ref().unwrap_or(&default);
	let (their_stdin, our_stdin) = stdin.to_child_stdio(true)?;
	let (their_stdout, our_stdout) = stdout.to_child_stdio(false)?;
	let (their_stderr, our_stderr) = stderr.to_child_stdio(false)?;
	let ours = StdioPipes {
	stdin: our_stdin,
	stdout: our_stdout,
	stderr: our_stderr,
	};
	let theirs = ChildPipes {
	stdin: their_stdin,
	stdout: their_stdout,
	stderr: their_stderr,
	};
	Ok((ours, theirs))
	}
	}

	fn os2c(s: &OsStr, saw_nul: &mut bool) -> CString {
	CString::new(s.as_bytes()).unwrap_or_else(\|_e\| {
	*saw_nul = true;
	CString::new("<string-with-nul>").unwrap()
	})
	}

	// Helper type to manage ownership of the strings within a C-style array.
	pub struct CStringArray {
	items: Vec<CString>,
	ptrs: Vec<*const c_char>
	}

	impl CStringArray {
	pub fn with_capacity(capacity: usize) -> Self {
	let mut result = CStringArray {
	items: Vec::with_capacity(capacity),
	ptrs: Vec::with_capacity(capacity+1)
	};
	result.ptrs.push(ptr::null());
	result
	}
	pub fn push(&mut self, item: CString) {
	let l = self.ptrs.len();
	self.ptrs[l-1] = item.as_ptr();
	self.ptrs.push(ptr::null());
	self.items.push(item);
	}
	pub fn as_ptr(&self) -> const const c_char {
	self.ptrs.as_ptr()
	}
	}

	fn construct_envp(env: BTreeMap<OsString, OsString>, saw_nul: &mut bool) -> CStringArray {
	let mut result = CStringArray::with_capacity(env.len());
	for (k, v) in env {
	let mut k: OsString = k.into();

	// Reserve additional space for '=' and null terminator
	k.reserve_exact(v.len() + 2);
	k.push("=");
	k.push(&v);

	// Add the new entry into the array
	if let Ok(item) = CString::new(k.into_vec()) {
	result.push(item);
	} else {
	*saw_nul = true;
	}
	}

	result
	}

	impl Stdio {
	pub fn to_child_stdio(&self, readable: bool)
	-> io::Result<(ChildStdio, Option<AnonPipe>)> {
	match *self {
	Stdio::Inherit => {
	Ok((ChildStdio::Inherit, None))
	},

	// Make sure that the source descriptors are not an stdio
	// descriptor, otherwise the order which we set the child's
	// descriptors may blow away a descriptor which we are hoping to
	// save. For example, suppose we want the child's stderr to be the
	// parent's stdout, and the child's stdout to be the parent's
	// stderr. No matter which we dup first, the second will get
	// overwritten prematurely.
	Stdio::Fd(ref fd) => {
	if fd.raw() >= 0 && fd.raw() <= libc::STDERR_FILENO {
	Ok((ChildStdio::Owned(fd.duplicate()?), None))
	} else {
	Ok((ChildStdio::Explicit(fd.raw()), None))
	}
	}

	Stdio::MakePipe => {
	let (reader, writer) = pipe::anon_pipe()?;
	let (ours, theirs) = if readable {
	(writer, reader)
	} else {
	(reader, writer)
	};
	Ok((ChildStdio::Owned(theirs.into_fd()), Some(ours)))
	}

	Stdio::Null => {
	let mut opts = OpenOptions::new();
	opts.read(readable);
	opts.write(!readable);
	let path = unsafe {
	CStr::from_ptr("/null\0".as_ptr() as *const _)
	};
	let fd = File::open_c(&path, &opts)?;
	Ok((ChildStdio::Owned(fd.into_fd()), None))
	}
	}
	}
	}

	impl From<AnonPipe> for Stdio {
	fn from(pipe: AnonPipe) -> Stdio {
	Stdio::Fd(pipe.into_fd())
	}
	}

	impl From<File> for Stdio {
	fn from(file: File) -> Stdio {
	Stdio::Fd(file.into_fd())
	}
	}

	impl ChildStdio {
	pub fn fd(&self) -> Option<c_int> {
	match *self {
	ChildStdio::Inherit => None,
	ChildStdio::Explicit(fd) => Some(fd),
	ChildStdio::Owned(ref fd) => Some(fd.raw()),
	}
	}
	}

	impl fmt::Debug for Command {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	write!(f, "{:?}", self.program)?;
	for arg in &self.args {
	write!(f, " {:?}", arg)?;
	}
	Ok(())
	}
	}

	/// Unix exit statuses
	#[derive(PartialEq, Eq, Clone, Copy, Debug)]
	pub struct ExitStatus(c_int);

	impl ExitStatus {
	pub fn new(status: c_int) -> ExitStatus {
	ExitStatus(status)
	}

	fn exited(&self) -> bool {
	/unsafe/ { libc::WIFEXITED(self.0) }
	}

	pub fn success(&self) -> bool {
	self.code() == Some(0)
	}

	pub fn code(&self) -> Option<i32> {
	if self.exited() {
	Some(/unsafe/ { libc::WEXITSTATUS(self.0) })
	} else {
	None
	}
	}

	pub fn signal(&self) -> Option<i32> {
	if !self.exited() {
	Some(/unsafe/ { libc::WTERMSIG(self.0) })
	} else {
	None
	}
	}
	}

	impl From<c_int> for ExitStatus {
	fn from(a: c_int) -> ExitStatus {
	ExitStatus(a)
	}
	}

	impl fmt::Display for ExitStatus {
	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
	if let Some(code) = self.code() {
	write!(f, "exit code: {}", code)
	} else {
	let signal = self.signal().unwrap();
	write!(f, "signal: {}", signal)
	}
	}
	}

	#[derive(PartialEq, Eq, Clone, Copy, Debug)]
	pub struct ExitCode(u8);

	impl ExitCode {
	pub const SUCCESS: ExitCode = ExitCode(EXIT_SUCCESS as _);
	pub const FAILURE: ExitCode = ExitCode(EXIT_FAILURE as _);

	#[inline]
	pub fn as_i32(&self) -> i32 {
	self.0 as i32
	}
	}