mod.rs source code [crates/rustix-0.38.44/src/ioctl/mod.rs]

1	//! Unsafe `ioctl` API.
2	//!
3	//! Unix systems expose a number of `ioctl`'s. `ioctl`s have been adopted as a
4	//! general purpose system call for making calls into the kernel. In addition
5	//! to the wide variety of system calls that are included by default in the
6	//! kernel, many drivers expose their own `ioctl`'s for controlling their
7	//! behavior, some of which are proprietary. Therefore it is impossible to make
8	//! a safe interface for every `ioctl` call, as they all have wildly varying
9	//! semantics.
10	//!
11	//! This module provides an unsafe interface to write your own `ioctl` API. To
12	//! start, create a type that implements [`Ioctl`]. Then, pass it to [`ioctl`]
13	//! to make the `ioctl` call.
14
15	#![allow(unsafe_code)]
16
17	use crate::backend::c;
18	use crate::fd::{AsFd, BorrowedFd};
19	use crate::io::Result;
20
21	#[cfg(any(linux_kernel, bsd))]
22	use core::mem;
23
24	pub use patterns::*;
25
26	mod patterns;
27
28	#[cfg(linux_kernel)]
29	mod linux;
30
31	#[cfg(bsd)]
32	mod bsd;
33
34	#[cfg(linux_kernel)]
35	use linux as platform;
36
37	#[cfg(bsd)]
38	use bsd as platform;
39
40	/// Perform an `ioctl` call.
41	///
42	/// `ioctl` was originally intended to act as a way of modifying the behavior
43	/// of files, but has since been adopted as a general purpose system call for
44	/// making calls into the kernel. In addition to the default calls exposed by
45	/// generic file descriptors, many drivers expose their own `ioctl` calls for
46	/// controlling their behavior, some of which are proprietary.
47	///
48	/// This crate exposes many other `ioctl` interfaces with safe and idiomatic
49	/// wrappers, like [`ioctl_fionbio`] and [`ioctl_fionread`]. It is recommended
50	/// to use those instead of this function, as they are safer and more
51	/// idiomatic. For other cases, implement the [`Ioctl`] API and pass it to this
52	/// function.
53	///
54	/// See documentation for [`Ioctl`] for more information.
55	///
56	/// [`ioctl_fionbio`]: crate::io::ioctl_fionbio
57	/// [`ioctl_fionread`]: crate::io::ioctl_fionread
58	///
59	/// # Safety
60	///
61	/// While [`Ioctl`] takes much of the unsafety out of `ioctl` calls, it is
62	/// still unsafe to call this code with arbitrary device drivers, as it is up
63	/// to the device driver to implement the `ioctl` call correctly. It is on the
64	/// onus of the protocol between the user and the driver to ensure that the
65	/// `ioctl` call is safe to make.
66	///
67	/// # References
68	/// - [Linux]
69	/// - [Winsock]
70	/// - [FreeBSD]
71	/// - [NetBSD]
72	/// - [OpenBSD]
73	/// - [Apple]
74	/// - [Solaris]
75	/// - [illumos]
76	///
77	/// [Linux]: https://man7.org/linux/man-pages/man2/ioctl.2.html
78	/// [Winsock]: https://learn.microsoft.com/en-us/windows/win32/api/winsock/nf-winsock-ioctlsocket
79	/// [FreeBSD]: https://man.freebsd.org/cgi/man.cgi?query=ioctl&sektion=2
80	/// [NetBSD]: https://man.netbsd.org/ioctl.2
81	/// [OpenBSD]: https://man.openbsd.org/ioctl.2
82	/// [Apple]: https://developer.apple.com/library/archive/documentation/System/Conceptual/ManPages_iPhoneOS/man2/ioctl.2.html
83	/// [Solaris]: https://docs.oracle.com/cd/E23824_01/html/821-1463/ioctl-2.html
84	/// [illumos]: https://illumos.org/man/2/ioctl
85	#[inline]
86	pub unsafe fn ioctl<F: AsFd, I: Ioctl>(fd: F, mut ioctl: I) -> Result<I::Output> {
87	let fd: BorrowedFd<'_> = fd.as_fd();
88	let request: u32 = I::OPCODE.raw();
89	let arg: *mut c_void = ioctl.as_ptr();
90
91	// SAFETY: The variant of `Ioctl` asserts that this is a valid IOCTL call
92	// to make.
93	let output: i32 = if I::IS_MUTATING {
94	_ioctl(fd, request, arg)?
95	} else {
96	_ioctl_readonly(fd, request, arg)?
97	};
98
99	// SAFETY: The variant of `Ioctl` asserts that this is a valid pointer to
100	// the output data.
101	I::output_from_ptr(out:output, extract_output:arg)
102	}
103
104	unsafe fn _ioctl(
105	fd: BorrowedFd<'_>,
106	request: RawOpcode,
107	arg: *mut c::c_void,
108	) -> Result<IoctlOutput> {
109	crate::backend::io::syscalls::ioctl(fd, request, arg)
110	}
111
112	unsafe fn _ioctl_readonly(
113	fd: BorrowedFd<'_>,
114	request: RawOpcode,
115	arg: *mut c::c_void,
116	) -> Result<IoctlOutput> {
117	crate::backend::io::syscalls::ioctl_readonly(fd, request, arg)
118	}
119
120	/// A trait defining the properties of an `ioctl` command.
121	///
122	/// Objects implementing this trait can be passed to [`ioctl`] to make an
123	/// `ioctl` call. The contents of the object represent the inputs to the
124	/// `ioctl` call. The inputs must be convertible to a pointer through the
125	/// `as_ptr` method. In most cases, this involves either casting a number to a
126	/// pointer, or creating a pointer to the actual data. The latter case is
127	/// necessary for `ioctl` calls that modify userspace data.
128	///
129	/// # Safety
130	///
131	/// This trait is unsafe to implement because it is impossible to guarantee
132	/// that the `ioctl` call is safe. The `ioctl` call may be proprietary, or it
133	/// may be unsafe to call in certain circumstances.
134	///
135	/// By implementing this trait, you guarantee that:
136	///
137	/// - The `ioctl` call expects the input provided by `as_ptr` and produces the
138	/// output as indicated by `output`.
139	/// - That `output_from_ptr` can safely take the pointer from `as_ptr` and cast
140	/// it to the correct type, only* after the `ioctl` call.*
141	/// - That `OPCODE` uniquely identifies the `ioctl` call.
142	/// - That, for whatever platforms you are targeting, the `ioctl` call is safe
143	/// to make.
144	/// - If `IS_MUTATING` is false, that no userspace data will be modified by the
145	/// `ioctl` call.
146	pub unsafe trait Ioctl {
147	/// The type of the output data.
148	///
149	/// Given a pointer, one should be able to construct an instance of this
150	/// type.
151	type Output;
152
153	/// The opcode used by this `ioctl` command.
154	///
155	/// There are different types of opcode depending on the operation. See
156	/// documentation for the [`Opcode`] struct for more information.
157	const OPCODE: Opcode;
158
159	/// Does the `ioctl` mutate any data in the userspace?
160	///
161	/// If the `ioctl` call does not mutate any data in the userspace, then
162	/// making this `false` enables optimizations that can make the call
163	/// faster. When in doubt, set this to `true`.
164	///
165	/// # Safety
166	///
167	/// This should only be set to `false` if the `ioctl` call does not mutate
168	/// any data in the userspace. Undefined behavior may occur if this is set
169	/// to `false` when it should be `true`.
170	const IS_MUTATING: bool;
171
172	/// Get a pointer to the data to be passed to the `ioctl` command.
173	///
174	/// See trait-level documentation for more information.
175	fn as_ptr(&mut self) -> *mut c::c_void;
176
177	/// Cast the output data to the correct type.
178	///
179	/// # Safety
180	///
181	/// The `extract_output` value must be the resulting value after a
182	/// successful `ioctl` call, and `out` is the direct return value of an
183	/// `ioctl` call that did not fail. In this case `extract_output` is the
184	/// pointer that was passed to the `ioctl` call.
185	unsafe fn output_from_ptr(
186	out: IoctlOutput,
187	extract_output: *mut c::c_void,
188	) -> Result<Self::Output>;
189	}
190
191	/// The opcode used by an `Ioctl`.
192	#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
193	pub struct Opcode {
194	/// The raw opcode.
195	raw: RawOpcode,
196	}
197
198	impl Opcode {
199	/// Create a new old `Opcode` from a raw opcode.
200	///
201	/// Rather than being a composition of several attributes, old opcodes are
202	/// just numbers. In general most drivers follow stricter conventions, but
203	/// older drivers may still use this strategy.
204	#[inline]
205	pub const fn old(raw: RawOpcode) -> Self {
206	Self { raw }
207	}
208
209	/// Create a new opcode from a direction, group, number, and size.
210	///
211	/// This corresponds to the C macro `_IOC(direction, group, number, size)`
212	#[cfg(any(linux_kernel, bsd))]
213	#[inline]
214	pub const fn from_components(
215	direction: Direction,
216	group: u8,
217	number: u8,
218	data_size: usize,
219	) -> Self {
220	assert!(
221	data_size <= RawOpcode::MAX as usize,
222	"data size is too large"
223	);
224
225	Self::old(platform::compose_opcode(
226	direction,
227	group as RawOpcode,
228	number as RawOpcode,
229	data_size as RawOpcode,
230	))
231	}
232
233	/// Create a new non-mutating opcode from a group, a number, and the type
234	/// of data.
235	///
236	/// This corresponds to the C macro `_IO(group, number)` when `T` is zero
237	/// sized.
238	#[cfg(any(linux_kernel, bsd))]
239	#[inline]
240	pub const fn none<T>(group: u8, number: u8) -> Self {
241	Self::from_components(Direction::None, group, number, mem::size_of::<T>())
242	}
243
244	/// Create a new reading opcode from a group, a number and the type of
245	/// data.
246	///
247	/// This corresponds to the C macro `_IOR(group, number, T)`.
248	#[cfg(any(linux_kernel, bsd))]
249	#[inline]
250	pub const fn read<T>(group: u8, number: u8) -> Self {
251	Self::from_components(Direction::Read, group, number, mem::size_of::<T>())
252	}
253
254	/// Create a new writing opcode from a group, a number and the type of
255	/// data.
256	///
257	/// This corresponds to the C macro `_IOW(group, number, T)`.
258	#[cfg(any(linux_kernel, bsd))]
259	#[inline]
260	pub const fn write<T>(group: u8, number: u8) -> Self {
261	Self::from_components(Direction::Write, group, number, mem::size_of::<T>())
262	}
263
264	/// Create a new reading and writing opcode from a group, a number and the
265	/// type of data.
266	///
267	/// This corresponds to the C macro `_IOWR(group, number, T)`.
268	#[cfg(any(linux_kernel, bsd))]
269	#[inline]
270	pub const fn read_write<T>(group: u8, number: u8) -> Self {
271	Self::from_components(Direction::ReadWrite, group, number, mem::size_of::<T>())
272	}
273
274	/// Get the raw opcode.
275	#[inline]
276	pub fn raw(self) -> RawOpcode {
277	self.raw
278	}
279	}
280
281	/// The direction that an `ioctl` is going.
282	///
283	/// Note that this is relative to userspace. `Read` means reading data from the
284	/// kernel, and write means the kernel writing data to userspace.
285	#[derive(Debug, Copy, Clone, PartialEq, Eq, PartialOrd, Ord, Hash)]
286	pub enum Direction {
287	/// None of the above.
288	None,
289
290	/// Read data from the kernel.
291	Read,
292
293	/// Write data to the kernel.
294	Write,
295
296	/// Read and write data to the kernel.
297	ReadWrite,
298	}
299
300	/// The type used by the `ioctl` to signify the output.
301	pub type IoctlOutput = c::c_int;
302
303	/// The type used by the `ioctl` to signify the command.
304	pub type RawOpcode = _RawOpcode;
305
306	// Under raw Linux, this is an `unsigned int`.
307	#[cfg(linux_raw)]
308	type _RawOpcode = c::c_uint;
309
310	// On libc Linux with GNU libc or uclibc, this is an `unsigned long`.
311	#[cfg(all(
312	not(linux_raw),
313	target_os = "linux",
314	any(target_env = "gnu", target_env = "uclibc")
315	))]
316	type _RawOpcode = c::c_ulong;
317
318	// Musl uses `c_int`.
319	#[cfg(all(
320	not(linux_raw),
321	target_os = "linux",
322	not(target_env = "gnu"),
323	not(target_env = "uclibc")
324	))]
325	type _RawOpcode = c::c_int;
326
327	// Android uses `c_int`.
328	#[cfg(all(not(linux_raw), target_os = "android"))]
329	type _RawOpcode = c::c_int;
330
331	// BSD, Haiku, Hurd, Redox, and Vita use `unsigned long`.
332	#[cfg(any(
333	bsd,
334	target_os = "redox",
335	target_os = "haiku",
336	target_os = "horizon",
337	target_os = "hurd",
338	target_os = "vita"
339	))]
340	type _RawOpcode = c::c_ulong;
341
342	// AIX, Emscripten, Fuchsia, Solaris, and WASI use a `int`.
343	#[cfg(any(
344	solarish,
345	target_os = "aix",
346	target_os = "fuchsia",
347	target_os = "emscripten",
348	target_os = "wasi",
349	target_os = "nto"
350	))]
351	type _RawOpcode = c::c_int;
352
353	// ESP-IDF uses a `c_uint`.
354	#[cfg(target_os = "espidf")]
355	type _RawOpcode = c::c_uint;
356
357	// Windows has `ioctlsocket`, which uses `i32`.
358	#[cfg(windows)]
359	type _RawOpcode = i32;
360