mod.rs

#![allow(missing_docs, nonstandard_style)]

use crate::ffi::{OsStr, OsString};
use crate::io::ErrorKind;
use crate::os::windows::ffi::{OsStrExt, OsStringExt};
use crate::path::PathBuf;
use crate::ptr;
use crate::time::Duration;

pub use self::rand::hashmap_random_keys;
pub use libc::strlen;

#[macro_use]
pub mod compat;

pub mod alloc;
pub mod args;
pub mod c;
pub mod cmath;
pub mod condvar;
pub mod env;
pub mod ext;
pub mod fast_thread_local;
pub mod fs;
pub mod handle;
pub mod io;
pub mod memchr;
pub mod mutex;
pub mod net;
pub mod os;
pub mod os_str;
pub mod path;
pub mod pipe;
pub mod process;
pub mod rand;
pub mod rwlock;
pub mod thread;
pub mod thread_local;
pub mod time;
cfg_if::cfg_if! {
    if #[cfg(not(target_vendor = "uwp"))] {
        pub mod stdio;
        pub mod stack_overflow;
    } else {
        pub mod stdio_uwp;
        pub mod stack_overflow_uwp;
        pub use self::stdio_uwp as stdio;
        pub use self::stack_overflow_uwp as stack_overflow;
    }
}

#[cfg(not(test))]
pub fn init() {}

pub fn decode_error_kind(errno: i32) -> ErrorKind {
    match errno as c::DWORD {
        c::ERROR_ACCESS_DENIED => return ErrorKind::PermissionDenied,
        c::ERROR_ALREADY_EXISTS => return ErrorKind::AlreadyExists,
        c::ERROR_FILE_EXISTS => return ErrorKind::AlreadyExists,
        c::ERROR_BROKEN_PIPE => return ErrorKind::BrokenPipe,
        c::ERROR_FILE_NOT_FOUND => return ErrorKind::NotFound,
        c::ERROR_PATH_NOT_FOUND => return ErrorKind::NotFound,
        c::ERROR_NO_DATA => return ErrorKind::BrokenPipe,
        c::ERROR_OPERATION_ABORTED => return ErrorKind::TimedOut,
        _ => {}
    }

    match errno {
        c::WSAEACCES => ErrorKind::PermissionDenied,
        c::WSAEADDRINUSE => ErrorKind::AddrInUse,
        c::WSAEADDRNOTAVAIL => ErrorKind::AddrNotAvailable,
        c::WSAECONNABORTED => ErrorKind::ConnectionAborted,
        c::WSAECONNREFUSED => ErrorKind::ConnectionRefused,
        c::WSAECONNRESET => ErrorKind::ConnectionReset,
        c::WSAEINVAL => ErrorKind::InvalidInput,
        c::WSAENOTCONN => ErrorKind::NotConnected,
        c::WSAEWOULDBLOCK => ErrorKind::WouldBlock,
        c::WSAETIMEDOUT => ErrorKind::TimedOut,

        _ => ErrorKind::Other,
    }
}

pub fn unrolled_find_u16s(needle: u16, haystack: &[u16]) -> Option<usize> {
    let ptr = haystack.as_ptr();
    let mut len = haystack.len();
    let mut start = &haystack[..];

    // For performance reasons unfold the loop eight times.
    while len >= 8 {
        if start[0] == needle {
            return Some((start.as_ptr() as usize - ptr as usize) / 2);
        }
        if start[1] == needle {
            return Some((start[1..].as_ptr() as usize - ptr as usize) / 2);
        }
        if start[2] == needle {
            return Some((start[2..].as_ptr() as usize - ptr as usize) / 2);
        }
        if start[3] == needle {
            return Some((start[3..].as_ptr() as usize - ptr as usize) / 2);
        }
        if start[4] == needle {
            return Some((start[4..].as_ptr() as usize - ptr as usize) / 2);
        }
        if start[5] == needle {
            return Some((start[5..].as_ptr() as usize - ptr as usize) / 2);
        }
        if start[6] == needle {
            return Some((start[6..].as_ptr() as usize - ptr as usize) / 2);
        }
        if start[7] == needle {
            return Some((start[7..].as_ptr() as usize - ptr as usize) / 2);
        }

        start = &start[8..];
        len -= 8;
    }

    for (i, c) in start.iter().enumerate() {
        if *c == needle {
            return Some((start.as_ptr() as usize - ptr as usize) / 2 + i);
        }
    }
    None
}

pub fn to_u16s<S: AsRef<OsStr>>(s: S) -> crate::io::Result<Vec<u16>> {
    fn inner(s: &OsStr) -> crate::io::Result<Vec<u16>> {
        let mut maybe_result: Vec<u16> = s.encode_wide().collect();
        if unrolled_find_u16s(0, &maybe_result).is_some() {
            return Err(crate::io::Error::new(
                ErrorKind::InvalidInput,
                "strings passed to WinAPI cannot contain NULs",
            ));
        }
        maybe_result.push(0);
        Ok(maybe_result)
    }
    inner(s.as_ref())
}

// Many Windows APIs follow a pattern of where we hand a buffer and then they
// will report back to us how large the buffer should be or how many bytes
// currently reside in the buffer. This function is an abstraction over these
// functions by making them easier to call.
//
// The first callback, `f1`, is yielded a (pointer, len) pair which can be
// passed to a syscall. The `ptr` is valid for `len` items (u16 in this case).
// The closure is expected to return what the syscall returns which will be
// interpreted by this function to determine if the syscall needs to be invoked
// again (with more buffer space).
//
// Once the syscall has completed (errors bail out early) the second closure is
// yielded the data which has been read from the syscall. The return value
// from this closure is then the return value of the function.
fn fill_utf16_buf<F1, F2, T>(mut f1: F1, f2: F2) -> crate::io::Result<T>
where
    F1: FnMut(*mut u16, c::DWORD) -> c::DWORD,
    F2: FnOnce(&[u16]) -> T,
{
    // Start off with a stack buf but then spill over to the heap if we end up
    // needing more space.
    let mut stack_buf = [0u16; 512];
    let mut heap_buf = Vec::new();
    unsafe {
        let mut n = stack_buf.len();
        loop {
            let buf = if n <= stack_buf.len() {
                &mut stack_buf[..]
            } else {
                let extra = n - heap_buf.len();
                heap_buf.reserve(extra);
                heap_buf.set_len(n);
                &mut heap_buf[..]
            };

            // This function is typically called on windows API functions which
            // will return the correct length of the string, but these functions
            // also return the `0` on error. In some cases, however, the
            // returned "correct length" may actually be 0!
            //
            // To handle this case we call `SetLastError` to reset it to 0 and
            // then check it again if we get the "0 error value". If the "last
            // error" is still 0 then we interpret it as a 0 length buffer and
            // not an actual error.
            c::SetLastError(0);
            let k = match f1(buf.as_mut_ptr(), n as c::DWORD) {
                0 if c::GetLastError() == 0 => 0,
                0 => return Err(crate::io::Error::last_os_error()),
                n => n,
            } as usize;
            if k == n && c::GetLastError() == c::ERROR_INSUFFICIENT_BUFFER {
                n *= 2;
            } else if k >= n {
                n = k;
            } else {
                return Ok(f2(&buf[..k]));
            }
        }
    }
}

fn os2path(s: &[u16]) -> PathBuf {
    PathBuf::from(OsString::from_wide(s))
}

#[allow(dead_code)] // Only used in backtrace::gnu::get_executable_filename()
fn wide_char_to_multi_byte(
    code_page: u32,
    flags: u32,
    s: &[u16],
    no_default_char: bool,
) -> crate::io::Result<Vec<i8>> {
    unsafe {
        let mut size = c::WideCharToMultiByte(
            code_page,
            flags,
            s.as_ptr(),
            s.len() as i32,
            ptr::null_mut(),
            0,
            ptr::null(),
            ptr::null_mut(),
        );
        if size == 0 {
            return Err(crate::io::Error::last_os_error());
        }

        let mut buf = Vec::with_capacity(size as usize);
        buf.set_len(size as usize);

        let mut used_default_char = c::FALSE;
        size = c::WideCharToMultiByte(
            code_page,
            flags,
            s.as_ptr(),
            s.len() as i32,
            buf.as_mut_ptr(),
            buf.len() as i32,
            ptr::null(),
            if no_default_char { &mut used_default_char } else { ptr::null_mut() },
        );
        if size == 0 {
            return Err(crate::io::Error::last_os_error());
        }
        if no_default_char && used_default_char == c::TRUE {
            return Err(crate::io::Error::new(
                crate::io::ErrorKind::InvalidData,
                "string cannot be converted to requested code page",
            ));
        }

        buf.set_len(size as usize);

        Ok(buf)
    }
}

pub fn truncate_utf16_at_nul(v: &[u16]) -> &[u16] {
    match unrolled_find_u16s(0, v) {
        // don't include the 0
        Some(i) => &v[..i],
        None => v,
    }
}

pub trait IsZero {
    fn is_zero(&self) -> bool;
}

macro_rules! impl_is_zero {
    ($($t:ident)*) => ($(impl IsZero for $t {
        fn is_zero(&self) -> bool {
            *self == 0
        }
    })*)
}

impl_is_zero! { i8 i16 i32 i64 isize u8 u16 u32 u64 usize }

pub fn cvt<I: IsZero>(i: I) -> crate::io::Result<I> {
    if i.is_zero() { Err(crate::io::Error::last_os_error()) } else { Ok(i) }
}

pub fn dur2timeout(dur: Duration) -> c::DWORD {
    // Note that a duration is a (u64, u32) (seconds, nanoseconds) pair, and the
    // timeouts in windows APIs are typically u32 milliseconds. To translate, we
    // have two pieces to take care of:
    //
    // * Nanosecond precision is rounded up
    // * Greater than u32::MAX milliseconds (50 days) is rounded up to INFINITE
    //   (never time out).
    dur.as_secs()
        .checked_mul(1000)
        .and_then(|ms| ms.checked_add((dur.subsec_nanos() as u64) / 1_000_000))
        .and_then(|ms| ms.checked_add(if dur.subsec_nanos() % 1_000_000 > 0 { 1 } else { 0 }))
        .map(|ms| if ms > <c::DWORD>::max_value() as u64 { c::INFINITE } else { ms as c::DWORD })
        .unwrap_or(c::INFINITE)
}

// On Windows, use the processor-specific __fastfail mechanism.  In Windows 8
// and later, this will terminate the process immediately without running any
// in-process exception handlers.  In earlier versions of Windows, this
// sequence of instructions will be treated as an access violation,
// terminating the process but without necessarily bypassing all exception
// handlers.
//
// https://docs.microsoft.com/en-us/cpp/intrinsics/fastfail
#[allow(unreachable_code)]
pub fn abort_internal() -> ! {
    #[cfg(any(target_arch = "x86", target_arch = "x86_64"))]
    unsafe {
        llvm_asm!("int $$0x29" :: "{ecx}"(7) ::: volatile); // 7 is FAST_FAIL_FATAL_APP_EXIT
        crate::intrinsics::unreachable();
    }
    #[cfg_attr(not(bootstrap), allow(unused_unsafe))] // remove `unsafe` on bootstrap bump
    unsafe {
        crate::intrinsics::abort();
    }
}
	#![allow(missing_docs, nonstandard_style)]

	use crate::ffi::{OsStr, OsString};
	use crate::io::ErrorKind;
	use crate::os::windows::ffi::{OsStrExt, OsStringExt};
	use crate::path::PathBuf;
	use crate::ptr;
	use crate::time::Duration;

	pub use self::rand::hashmap_random_keys;
	pub use libc::strlen;

	#[macro_use]
	pub mod compat;

	pub mod alloc;
	pub mod args;
	pub mod c;
	pub mod cmath;
	pub mod condvar;
	pub mod env;
	pub mod ext;
	pub mod fast_thread_local;
	pub mod fs;
	pub mod handle;
	pub mod io;
	pub mod memchr;
	pub mod mutex;
	pub mod net;
	pub mod os;
	pub mod os_str;
	pub mod path;
	pub mod pipe;
	pub mod process;
	pub mod rand;
	pub mod rwlock;
	pub mod thread;
	pub mod thread_local;
	pub mod time;
	cfg_if::cfg_if! {
	if #[cfg(not(target_vendor = "uwp"))] {
	pub mod stdio;
	pub mod stack_overflow;
	} else {
	pub mod stdio_uwp;
	pub mod stack_overflow_uwp;
	pub use self::stdio_uwp as stdio;
	pub use self::stack_overflow_uwp as stack_overflow;
	}
	}

	#[cfg(not(test))]
	pub fn init() {}

	pub fn decode_error_kind(errno: i32) -> ErrorKind {
	match errno as c::DWORD {
	c::ERROR_ACCESS_DENIED => return ErrorKind::PermissionDenied,
	c::ERROR_ALREADY_EXISTS => return ErrorKind::AlreadyExists,
	c::ERROR_FILE_EXISTS => return ErrorKind::AlreadyExists,
	c::ERROR_BROKEN_PIPE => return ErrorKind::BrokenPipe,
	c::ERROR_FILE_NOT_FOUND => return ErrorKind::NotFound,
	c::ERROR_PATH_NOT_FOUND => return ErrorKind::NotFound,
	c::ERROR_NO_DATA => return ErrorKind::BrokenPipe,
	c::ERROR_OPERATION_ABORTED => return ErrorKind::TimedOut,
	_ => {}
	}

	match errno {
	c::WSAEACCES => ErrorKind::PermissionDenied,
	c::WSAEADDRINUSE => ErrorKind::AddrInUse,
	c::WSAEADDRNOTAVAIL => ErrorKind::AddrNotAvailable,
	c::WSAECONNABORTED => ErrorKind::ConnectionAborted,
	c::WSAECONNREFUSED => ErrorKind::ConnectionRefused,
	c::WSAECONNRESET => ErrorKind::ConnectionReset,
	c::WSAEINVAL => ErrorKind::InvalidInput,
	c::WSAENOTCONN => ErrorKind::NotConnected,
	c::WSAEWOULDBLOCK => ErrorKind::WouldBlock,
	c::WSAETIMEDOUT => ErrorKind::TimedOut,

	_ => ErrorKind::Other,
	}
	}

	pub fn unrolled_find_u16s(needle: u16, haystack: &[u16]) -> Option<usize> {
	let ptr = haystack.as_ptr();
	let mut len = haystack.len();
	let mut start = &haystack[..];

	// For performance reasons unfold the loop eight times.
	while len >= 8 {
	if start[0] == needle {
	return Some((start.as_ptr() as usize - ptr as usize) / 2);
	}
	if start[1] == needle {
	return Some((start[1..].as_ptr() as usize - ptr as usize) / 2);
	}
	if start[2] == needle {
	return Some((start[2..].as_ptr() as usize - ptr as usize) / 2);
	}
	if start[3] == needle {
	return Some((start[3..].as_ptr() as usize - ptr as usize) / 2);
	}
	if start[4] == needle {
	return Some((start[4..].as_ptr() as usize - ptr as usize) / 2);
	}
	if start[5] == needle {
	return Some((start[5..].as_ptr() as usize - ptr as usize) / 2);
	}
	if start[6] == needle {
	return Some((start[6..].as_ptr() as usize - ptr as usize) / 2);
	}
	if start[7] == needle {
	return Some((start[7..].as_ptr() as usize - ptr as usize) / 2);
	}

	start = &start[8..];
	len -= 8;
	}

	for (i, c) in start.iter().enumerate() {
	if *c == needle {
	return Some((start.as_ptr() as usize - ptr as usize) / 2 + i);
	}
	}
	None
	}

	pub fn to_u16s<S: AsRef<OsStr>>(s: S) -> crate::io::Result<Vec<u16>> {
	fn inner(s: &OsStr) -> crate::io::Result<Vec<u16>> {
	let mut maybe_result: Vec<u16> = s.encode_wide().collect();
	if unrolled_find_u16s(0, &maybe_result).is_some() {
	return Err(crate::io::Error::new(
	ErrorKind::InvalidInput,
	"strings passed to WinAPI cannot contain NULs",
	));
	}
	maybe_result.push(0);
	Ok(maybe_result)
	}
	inner(s.as_ref())
	}

	// Many Windows APIs follow a pattern of where we hand a buffer and then they
	// will report back to us how large the buffer should be or how many bytes
	// currently reside in the buffer. This function is an abstraction over these
	// functions by making them easier to call.
	//
	// The first callback, `f1`, is yielded a (pointer, len) pair which can be
	// passed to a syscall. The `ptr` is valid for `len` items (u16 in this case).
	// The closure is expected to return what the syscall returns which will be
	// interpreted by this function to determine if the syscall needs to be invoked
	// again (with more buffer space).
	//
	// Once the syscall has completed (errors bail out early) the second closure is
	// yielded the data which has been read from the syscall. The return value
	// from this closure is then the return value of the function.
	fn fill_utf16_buf<F1, F2, T>(mut f1: F1, f2: F2) -> crate::io::Result<T>
	where
	F1: FnMut(*mut u16, c::DWORD) -> c::DWORD,
	F2: FnOnce(&[u16]) -> T,
	{
	// Start off with a stack buf but then spill over to the heap if we end up
	// needing more space.
	let mut stack_buf = [0u16; 512];
	let mut heap_buf = Vec::new();
	unsafe {
	let mut n = stack_buf.len();
	loop {
	let buf = if n <= stack_buf.len() {
	&mut stack_buf[..]
	} else {
	let extra = n - heap_buf.len();
	heap_buf.reserve(extra);
	heap_buf.set_len(n);
	&mut heap_buf[..]
	};

	// This function is typically called on windows API functions which
	// will return the correct length of the string, but these functions
	// also return the `0` on error. In some cases, however, the
	// returned "correct length" may actually be 0!
	//
	// To handle this case we call `SetLastError` to reset it to 0 and
	// then check it again if we get the "0 error value". If the "last
	// error" is still 0 then we interpret it as a 0 length buffer and
	// not an actual error.
	c::SetLastError(0);
	let k = match f1(buf.as_mut_ptr(), n as c::DWORD) {
	0 if c::GetLastError() == 0 => 0,
	0 => return Err(crate::io::Error::last_os_error()),
	n => n,
	} as usize;
	if k == n && c::GetLastError() == c::ERROR_INSUFFICIENT_BUFFER {
	n *= 2;
	} else if k >= n {
	n = k;
	} else {
	return Ok(f2(&buf[..k]));
	}
	}
	}
	}

	fn os2path(s: &[u16]) -> PathBuf {
	PathBuf::from(OsString::from_wide(s))
	}

	#[allow(dead_code)] // Only used in backtrace::gnu::get_executable_filename()
	fn wide_char_to_multi_byte(
	code_page: u32,
	flags: u32,
	s: &[u16],
	no_default_char: bool,
	) -> crate::io::Result<Vec<i8>> {
	unsafe {
	let mut size = c::WideCharToMultiByte(
	code_page,
	flags,
	s.as_ptr(),
	s.len() as i32,
	ptr::null_mut(),
	0,
	ptr::null(),
	ptr::null_mut(),
	);
	if size == 0 {
	return Err(crate::io::Error::last_os_error());
	}

	let mut buf = Vec::with_capacity(size as usize);
	buf.set_len(size as usize);

	let mut used_default_char = c::FALSE;
	size = c::WideCharToMultiByte(
	code_page,
	flags,
	s.as_ptr(),
	s.len() as i32,
	buf.as_mut_ptr(),
	buf.len() as i32,
	ptr::null(),
	if no_default_char { &mut used_default_char } else { ptr::null_mut() },
	);
	if size == 0 {
	return Err(crate::io::Error::last_os_error());
	}
	if no_default_char && used_default_char == c::TRUE {
	return Err(crate::io::Error::new(
	crate::io::ErrorKind::InvalidData,
	"string cannot be converted to requested code page",
	));
	}

	buf.set_len(size as usize);

	Ok(buf)
	}
	}

	pub fn truncate_utf16_at_nul(v: &[u16]) -> &[u16] {
	match unrolled_find_u16s(0, v) {
	// don't include the 0
	Some(i) => &v[..i],
	None => v,
	}
	}

	pub trait IsZero {
	fn is_zero(&self) -> bool;
	}

	macro_rules! impl_is_zero {
	($($t:ident)*) => ($(impl IsZero for $t {
	fn is_zero(&self) -> bool {
	*self == 0
	}
	})*)
	}

	impl_is_zero! { i8 i16 i32 i64 isize u8 u16 u32 u64 usize }

	pub fn cvt<I: IsZero>(i: I) -> crate::io::Result<I> {
	if i.is_zero() { Err(crate::io::Error::last_os_error()) } else { Ok(i) }
	}

	pub fn dur2timeout(dur: Duration) -> c::DWORD {
	// Note that a duration is a (u64, u32) (seconds, nanoseconds) pair, and the
	// timeouts in windows APIs are typically u32 milliseconds. To translate, we
	// have two pieces to take care of:
	//
	// * Nanosecond precision is rounded up
	// * Greater than u32::MAX milliseconds (50 days) is rounded up to INFINITE
	// (never time out).
	dur.as_secs()
	.checked_mul(1000)
	.and_then(\|ms\| ms.checked_add((dur.subsec_nanos() as u64) / 1_000_000))
	.and_then(\|ms\| ms.checked_add(if dur.subsec_nanos() % 1_000_000 > 0 { 1 } else { 0 }))
	.map(\|ms\| if ms > <c::DWORD>::max_value() as u64 { c::INFINITE } else { ms as c::DWORD })
	.unwrap_or(c::INFINITE)
	}

	// On Windows, use the processor-specific __fastfail mechanism. In Windows 8
	// and later, this will terminate the process immediately without running any
	// in-process exception handlers. In earlier versions of Windows, this
	// sequence of instructions will be treated as an access violation,
	// terminating the process but without necessarily bypassing all exception
	// handlers.
	//
	// https://docs.microsoft.com/en-us/cpp/intrinsics/fastfail
	#[allow(unreachable_code)]
	pub fn abort_internal() -> ! {
	#[cfg(any(target_arch = "x86", target_arch = "x86_64"))]
	unsafe {
	llvm_asm!("int $$0x29" :: "{ecx}"(7) ::: volatile); // 7 is FAST_FAIL_FATAL_APP_EXIT
	crate::intrinsics::unreachable();
	}
	#[cfg_attr(not(bootstrap), allow(unused_unsafe))] // remove `unsafe` on bootstrap bump
	unsafe {
	crate::intrinsics::abort();
	}
	}