Behavior considered undefined
Rust code is incorrect if it exhibits any of the behaviors in the following
list. This includes code within unsafe
blocks and unsafe
functions.
unsafe
only means that avoiding undefined behavior is on the programmer; it
does not change anything about the fact that Rust programs must never cause
undefined behavior.
It is the programmer's responsibility when writing unsafe
code to ensure that
any safe code interacting with the unsafe
code cannot trigger these
behaviors. unsafe
code that satisfies this property for any safe client is
called sound; if unsafe
code can be misused by safe code to exhibit
undefined behavior, it is unsound.
Warning: The following list is not exhaustive. There is no formal model of Rust's semantics for what is and is not allowed in unsafe code, so there may be more behavior considered unsafe. The following list is just what we know for sure is undefined behavior. Please read the Rustonomicon before writing unsafe code.
- Data races.
- Dereferencing (using the
*
operator on) a dangling or unaligned raw pointer. - Breaking the pointer aliasing rules.
&mut T
and&T
follow LLVM’s scoped noalias model, except if the&T
contains anUnsafeCell<U>
. - Mutating immutable data. All data inside a
const
item is immutable. Moreover, all data reached through a shared reference or data owned by an immutable binding is immutable, unless that data is contained within anUnsafeCell<U>
. - Invoking undefined behavior via compiler intrinsics.
- Executing code compiled with platform features that the current platform
does not support (see
target_feature
). - Calling a function with the wrong call ABI or unwinding from a function with the wrong unwind ABI.
- Producing an invalid value, even in private fields and locals. "Producing" a
value happens any time a value is assigned to or read from a place, passed to
a function/primitive operation or returned from a function/primitive
operation.
The following values are invalid (at their respective type):
-
A value other than
false
(0
) ortrue
(1
) in abool
. -
A discriminant in an
enum
not included in the type definition. -
A null
fn
pointer. -
A value in a
char
which is a surrogate or abovechar::MAX
. -
A
!
(all values are invalid for this type). -
An integer (
i*
/u*
), floating point value (f*
), or raw pointer obtained from uninitialized memory. -
A reference or
Box<T>
that is dangling, unaligned, or points to an invalid value. -
Invalid metadata in a wide reference,
Box<T>
, or raw pointer:dyn Trait
metadata is invalid if it is not a pointer to a vtable forTrait
that matches the actual dynamic trait the pointer or reference points to.- Slice metadata is invalid if if the length is not a valid
usize
(i.e., it must not be read from uninitialized memory).
-
Non-UTF-8 byte sequences in a
str
. -
Invalid values for a type with a custom definition of invalid values. In the standard library, this affects
NonNull<T>
andNonZero*
.Note:
rustc
achieves this with the unstablerustc_layout_scalar_valid_range_*
attributes.
-
A reference/pointer is "dangling" if it is null or not all of the bytes it
points to are part of the same allocation (so in particular they all have to be
part of some allocation). The span of bytes it points to is determined by the
pointer value and the size of the pointee type. As a consequence, if the span is
empty, "dangling" is the same as "non-null". Note that slices point to their
entire range, so it is important that the length metadata is never too
large. In particular, allocations and therefore slices cannot be bigger than
isize::MAX
bytes.
Note: Undefined behavior affects the entire program. For example, calling a function in C that exhibits undefined behavior of C means your entire program contains undefined behaviour that can also affect the Rust code. And vice versa, undefined behavior in Rust can cause adverse affects on code executed by any FFI calls to other languages.