/// A reference-counted fwnode_handle. /// /// This structure represents the Rust abstraction for a /// C `struct fwnode_handle`. This implementation abstracts the usage of an /// already existing C `struct fwnode_handle` within Rust code that we get /// passed from the C side. /// /// # Invariants /// /// A `FwNode` instance represents a valid `struct fwnode_handle` created by the /// C portion of the kernel. /// /// Instances of this type are always reference-counted, that is, a call to /// `fwnode_handle_get` ensures that the allocation remains valid at least until /// the matching call to `fwnode_handle_put`. #[repr(transparent)] pubstruct FwNode(Opaque<bindings::fwnode_handle>);
impl FwNode { /// # Safety /// /// Callers must ensure that: /// - The reference count was incremented at least once. /// - They relinquish that increment. That is, if there is only one /// increment, callers must not use the underlying object anymore -- it is /// only safe to do so via the newly created `ARef<FwNode>`. unsafefn from_raw(raw: *mut bindings::fwnode_handle) -> ARef<Self> { // SAFETY: As per the safety requirements of this function: // - `NonNull::new_unchecked`: // - `raw` is not null. // - `ARef::from_raw`: // - `raw` has an incremented refcount. // - that increment is relinquished, i.e. it won't be decremented // elsewhere. // CAST: It is safe to cast from a `*mut fwnode_handle` to // `*mut FwNode`, because `FwNode` is defined as a // `#[repr(transparent)]` wrapper around `fwnode_handle`. unsafe { ARef::from_raw(ptr::NonNull::new_unchecked(raw.cast())) }
}
/// Obtain the raw `struct fwnode_handle *`. pub(crate) fn as_raw(&self) -> *mut bindings::fwnode_handle { self.0.get()
}
/// Returns `true` if `&self` is an OF node, `false` otherwise. pubfn is_of_node(&self) -> bool { // SAFETY: The type invariant of `Self` guarantees that `self.as_raw() is a pointer to a // valid `struct fwnode_handle`. unsafe { bindings::is_of_node(self.as_raw()) }
}
/// Returns an object that implements [`Display`](core::fmt::Display) for /// printing the name of a node. /// /// This is an alternative to the default `Display` implementation, which /// prints the full path. pubfn display_name(&self) -> impl core::fmt::Display + '_ { struct FwNodeDisplayName<'a>(&'a FwNode);
impl core::fmt::Display for FwNodeDisplayName<'_> { fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { // SAFETY: `self` is valid by its type invariant. let name = unsafe { bindings::fwnode_get_name(self.0.as_raw()) }; if name.is_null() { return Ok(());
} // SAFETY: // - `fwnode_get_name` returns null or a valid C string. // - `name` was checked to be non-null. let name = unsafe { CStr::from_char_ptr(name) };
write!(f, "{name}")
}
}
FwNodeDisplayName(self)
}
/// Checks if property is present or not. pubfn property_present(&self, name: &CStr) -> bool { // SAFETY: By the invariant of `CStr`, `name` is null-terminated. unsafe { bindings::fwnode_property_present(self.as_raw().cast_const(), name.as_char_ptr()) }
}
/// Returns firmware property `name` boolean value. pubfn property_read_bool(&self, name: &CStr) -> bool { // SAFETY: // - `name` is non-null and null-terminated. // - `self.as_raw()` is valid because `self` is valid. unsafe { bindings::fwnode_property_read_bool(self.as_raw(), name.as_char_ptr()) }
}
/// Returns the index of matching string `match_str` for firmware string /// property `name`. pubfn property_match_string(&self, name: &CStr, match_str: &CStr) -> Result<usize> { // SAFETY: // - `name` and `match_str` are non-null and null-terminated. // - `self.as_raw` is valid because `self` is valid. let ret = unsafe {
bindings::fwnode_property_match_string( self.as_raw(),
name.as_char_ptr(),
match_str.as_char_ptr(),
)
};
to_result(ret)?;
Ok(ret as usize)
}
let res = T::read_array_from_fwnode_property(self, name, val.spare_capacity_mut()); let res = match res {
Ok(_) => { // SAFETY: // - `len` is equal to `val.capacity - val.len`, because // `val.capacity` is `len` and `val.len` is zero. // - All elements within the interval [`0`, `len`) were initialized // by `read_array_from_fwnode_property`. unsafe { val.inc_len(len) }
Ok(val)
}
Err(e) => Err(e),
};
Ok(PropertyGuard {
inner: res,
fwnode: self,
name,
})
}
/// Returns the value of firmware property `name`. /// /// This method is generic over the type of value to read. The types that /// can be read are strings, integers and arrays of integers. /// /// Reading a [`KVec`] of integers is done with the separate /// method [`Self::property_read_array_vec`], because it takes an /// additional `len` argument. /// /// Reading a boolean is done with the separate method /// [`Self::property_read_bool`], because this operation is infallible. /// /// For more precise documentation about what types can be read, see /// the [implementors of Property][Property#implementors] and [its /// implementations on foreign types][Property#foreign-impls]. /// /// # Examples /// /// ``` /// # use kernel::{c_str, device::{Device, property::FwNode}, str::CString}; /// fn examples(dev: &Device) -> Result { /// let fwnode = dev.fwnode().ok_or(ENOENT)?; /// let b: u32 = fwnode.property_read(c_str!("some-number")).required_by(dev)?; /// if let Some(s) = fwnode.property_read::<CString>(c_str!("some-str")).optional() { /// // ... /// } /// Ok(()) /// } /// ``` pubfn property_read<'fwnode, 'name, T: Property>(
&'fwnode self,
name: &'name CStr,
) -> PropertyGuard<'fwnode, 'name, T> {
PropertyGuard {
inner: T::read_from_fwnode_property(self, name),
fwnode: self,
name,
}
}
/// Returns first matching named child node handle. pubfn get_child_by_name(&self, name: &CStr) -> Option<ARef<Self>> { // SAFETY: `self` and `name` are valid by their type invariants. let child = unsafe { bindings::fwnode_get_named_child_node(self.as_raw(), name.as_char_ptr()) }; if child.is_null() { return None;
} // SAFETY: // - `fwnode_get_named_child_node` returns a pointer with its refcount // incremented. // - That increment is relinquished, i.e. the underlying object is not // used anymore except via the newly created `ARef`.
Some(unsafe { Self::from_raw(child) })
}
/// Returns an iterator over a node's children. pubfn children<'a>(&'a self) -> impl Iterator<Item = ARef<FwNode>> + 'a { letmut prev: Option<ARef<FwNode>> = None;
core::iter::from_fn(move || { let prev_ptr = match prev.take() {
None => ptr::null_mut(),
Some(prev) => { // We will pass `prev` to `fwnode_get_next_child_node`, // which decrements its refcount, so we use // `ARef::into_raw` to avoid decrementing the refcount // twice. let prev = ARef::into_raw(prev);
prev.as_ptr().cast()
}
}; // SAFETY: // - `self.as_raw()` is valid by its type invariant. // - `prev_ptr` may be null, which is allowed and corresponds to // getting the first child. Otherwise, `prev_ptr` is valid, as it // is the stored return value from the previous invocation. // - `prev_ptr` has its refount incremented. // - The increment of `prev_ptr` is relinquished, i.e. the // underlying object won't be used anymore. let next = unsafe { bindings::fwnode_get_next_child_node(self.as_raw(), prev_ptr) }; if next.is_null() { return None;
} // SAFETY: // - `next` is valid because `fwnode_get_next_child_node` returns a // pointer with its refcount incremented. // - That increment is relinquished, i.e. the underlying object // won't be used anymore, except via the newly created // `ARef<Self>`. let next = unsafe { FwNode::from_raw(next) };
prev = Some(next.clone());
Some(next)
})
}
let (nargs_prop, nargs) = match nargs {
NArgs::Prop(nargs_prop) => (nargs_prop.as_char_ptr(), 0),
NArgs::N(nargs) => (ptr::null(), nargs),
};
// SAFETY: // - `self.0.get()` is valid. // - `prop.as_char_ptr()` is valid and zero-terminated. // - `nargs_prop` is valid and zero-terminated if `nargs` // is zero, otherwise it is allowed to be a null-pointer. // - The function upholds the type invariants of `out_args`, // namely: // - It may fill the field `fwnode` with a valid pointer, // in which case its refcount is incremented. // - It may modify the field `nargs`, in which case it // initializes at least as many elements in `args`. let ret = unsafe {
bindings::fwnode_property_get_reference_args( self.0.get(),
prop.as_char_ptr(),
nargs_prop,
nargs,
index,
&mut out_args.0,
)
};
to_result(ret)?;
Ok(out_args)
}
}
/// The number of arguments to request [`FwNodeReferenceArgs`]. pubenum NArgs<'a> { /// The name of the property of the reference indicating the number of /// arguments.
Prop(&'a CStr), /// The known number of arguments.
N(u32),
}
/// The return value of [`FwNode::property_get_reference_args`]. /// /// This structure represents the Rust abstraction for a C /// `struct fwnode_reference_args` which was initialized by the C side. /// /// # Invariants /// /// If the field `fwnode` is valid, it owns an increment of its refcount. /// /// The field `args` contains at least as many initialized elements as indicated /// by the field `nargs`. #[repr(transparent)] #[derive(Default)] pubstruct FwNodeReferenceArgs(bindings::fwnode_reference_args);
impl Drop for FwNodeReferenceArgs { fn drop(&mutself) { if !self.0.fwnode.is_null() { // SAFETY: // - By the type invariants of `FwNodeReferenceArgs`, its field // `fwnode` owns an increment of its refcount. // - That increment is relinquished. The underlying object won't be // used anymore because we are dropping it. let _ = unsafe { FwNode::from_raw(self.0.fwnode) };
}
}
}
impl FwNodeReferenceArgs { /// Returns the slice of reference arguments. pubfn as_slice(&self) -> &[u64] { // SAFETY: As per the safety invariant of `FwNodeReferenceArgs`, `nargs` // is the minimum number of elements in `args` that is valid. unsafe { core::slice::from_raw_parts(self.0.args.as_ptr(), self.0.nargs as usize) }
}
/// Returns the number of reference arguments. pubfn len(&self) -> usize { self.0.nargs as usize
}
/// Returns `true` if there are no reference arguments. pubfn is_empty(&self) -> bool { self.0.nargs == 0
}
}
// SAFETY: Instances of `FwNode` are always reference-counted. unsafeimplcrate::types::AlwaysRefCounted for FwNode { fn inc_ref(&self) { // SAFETY: The existence of a shared reference guarantees that the // refcount is non-zero. unsafe { bindings::fwnode_handle_get(self.as_raw()) };
}
unsafefn dec_ref(obj: ptr::NonNull<Self>) { // SAFETY: The safety requirements guarantee that the refcount is // non-zero. unsafe { bindings::fwnode_handle_put(obj.cast().as_ptr()) }
}
}
impl core::fmt::Display for FwNode { fn fmt(&self, f: &mut core::fmt::Formatter<'_>) -> core::fmt::Result { // The logic here is the same as the one in lib/vsprintf.c // (fwnode_full_name_string).
// SAFETY: `self.as_raw()` is valid by its type invariant. let num_parents = unsafe { bindings::fwnode_count_parents(self.as_raw()) };
for depth in (0..=num_parents).rev() { let fwnode = if depth == 0 {
Node::Borrowed(self)
} else { // SAFETY: `self.as_raw()` is valid. let ptr = unsafe { bindings::fwnode_get_nth_parent(self.as_raw(), depth) }; // SAFETY: // - The depth passed to `fwnode_get_nth_parent` is // within the valid range, so the returned pointer is // not null. // - The reference count was incremented by // `fwnode_get_nth_parent`. // - That increment is relinquished to // `FwNode::from_raw`.
Node::Owned(unsafe { FwNode::from_raw(ptr) })
}; // Take a reference to the owned or borrowed `FwNode`. let fwnode: &FwNode = match &fwnode {
Node::Borrowed(f) => f,
Node::Owned(f) => f,
};
// SAFETY: `fwnode` is valid by its type invariant. let prefix = unsafe { bindings::fwnode_get_name_prefix(fwnode.as_raw()) }; if !prefix.is_null() { // SAFETY: `fwnode_get_name_prefix` returns null or a // valid C string. let prefix = unsafe { CStr::from_char_ptr(prefix) };
write!(f, "{prefix}")?;
}
write!(f, "{}", fwnode.display_name())?;
}
Ok(())
}
}
/// Implemented for types that can be read as properties. /// /// This is implemented for strings, integers and arrays of integers. It's used /// to make [`FwNode::property_read`] generic over the type of property being /// read. There are also two dedicated methods to read other types, because they /// require more specialized function signatures: /// - [`property_read_bool`](FwNode::property_read_bool) /// - [`property_read_array_vec`](FwNode::property_read_array_vec) /// /// It must be public, because it appears in the signatures of other public /// functions, but its methods shouldn't be used outside the kernel crate. pubtrait Property: Sized + Sealed { /// Used to make [`FwNode::property_read`] generic. fn read_from_fwnode_property(fwnode: &FwNode, name: &CStr) -> Result<Self>;
}
// SAFETY: // - `name` is non-null and null-terminated. // - `fwnode.as_raw` is valid because `fwnode` is valid. let ret = unsafe {
bindings::fwnode_property_read_string(fwnode.as_raw(), name.as_char_ptr(), pstr.cast())
};
to_result(ret)?;
// SAFETY: // - `pstr` is a valid pointer to a NUL-terminated C string. // - It is valid for at least as long as `fwnode`, but it's only used // within the current function. // - The memory it points to is not mutated during that time. let str = unsafe { CStr::from_char_ptr(*pstr) };
Ok(str.try_into()?)
}
}
/// Implemented for all integers that can be read as properties. /// /// This helper trait is needed on top of the existing [`Property`] /// trait to associate the integer types of various sizes with their /// corresponding `fwnode_property_read_*_array` functions. /// /// It must be public, because it appears in the signatures of other public /// functions, but its methods shouldn't be used outside the kernel crate. pubtrait PropertyInt: Copy + Sealed { /// Reads a property array. fn read_array_from_fwnode_property<'a>(
fwnode: &FwNode,
name: &CStr,
out: &'a mut [MaybeUninit<Self>],
) -> Result<&'a mut [Self]>;
/// Reads the length of a property array. fn read_array_len_from_fwnode_property(fwnode: &FwNode, name: &CStr) -> Result<usize>;
} // This macro generates implementations of the traits `Property` and // `PropertyInt` for integers of various sizes. Its input is a list // of pairs separated by commas. The first element of the pair is the // type of the integer, the second one is the name of its corresponding // `fwnode_property_read_*_array` function.
macro_rules! impl_property_for_int {
($($int:ty: $f:ident),* $(,)?) => { $( impl Sealed for $int {} impl<const N: usize> Sealed for [$int; N] {}
impl PropertyInt for $int { fn read_array_from_fwnode_property<'a>(
fwnode: &FwNode,
name: &CStr,
out: &'a mut [MaybeUninit<Self>],
) -> Result<&'a mut [Self]> { // SAFETY: // - `fwnode`, `name` and `out` are all valid by their type // invariants. // - `out.len()` is a valid bound for the memory pointed to by // `out.as_mut_ptr()`. // CAST: It's ok to cast from `*mut MaybeUninit<$int>` to a // `*mut $int` because they have the same memory layout. let ret = unsafe {
bindings::$f(
fwnode.as_raw(),
name.as_char_ptr(),
out.as_mut_ptr().cast(),
out.len(),
)
};
to_result(ret)?; // SAFETY: Transmuting from `&'a mut [MaybeUninit<Self>]` to // `&'a mut [Self]` is sound, because the previous call to a // `fwnode_property_read_*_array` function (which didn't fail) // fully initialized the slice.
Ok(unsafe { core::mem::transmute::<&mut [MaybeUninit<Self>], & style='color:red'>mut [Self]>(out) })
}
fn read_array_len_from_fwnode_property(fwnode: &FwNode, name: &CStr) -> Result<usize> { // SAFETY: // - `fwnode` and `name` are valid by their type invariants. // - It's ok to pass a null pointer to the // `fwnode_property_read_*_array` functions if `nval` is zero. // This will return the length of the array. let ret = unsafe {
bindings::$f(
fwnode.as_raw(),
name.as_char_ptr(),
ptr::null_mut(), 0,
)
};
to_result(ret)?;
Ok(ret as usize)
}
}
/// A helper for reading device properties. /// /// Use [`Self::required_by`] if a missing property is considered a bug and /// [`Self::optional`] otherwise. /// /// For convenience, [`Self::or`] and [`Self::or_default`] are provided. pubstruct PropertyGuard<'fwnode, 'name, T> { /// The result of reading the property.
inner: Result<T>, /// The fwnode of the property, used for logging in the "required" case.
fwnode: &'fwnode FwNode, /// The name of the property, used for logging in the "required" case.
name: &'name CStr,
}
impl<T> PropertyGuard<'_, '_, T> { /// Access the property, indicating it is required. /// /// If the property is not present, the error is automatically logged. If a /// missing property is not an error, use [`Self::optional`] instead. The /// device is required to associate the log with it. pubfn required_by(self, dev: &super::Device) -> Result<T> { ifself.inner.is_err() {
dev_err!(
dev, "{}: property '{}' is missing\n", self.fwnode, self.name
);
} self.inner
}
/// Access the property, indicating it is optional. /// /// In contrast to [`Self::required_by`], no error message is logged if /// the property is not present. pubfn optional(self) -> Option<T> { self.inner.ok()
}
/// Access the property or the specified default value. /// /// Do not pass a sentinel value as default to detect a missing property. /// Use [`Self::required_by`] or [`Self::optional`] instead. pubfn or(self, default: T) -> T { self.inner.unwrap_or(default)
}
}
impl<T: Default> PropertyGuard<'_, '_, T> { /// Access the property or a default value. /// /// Use [`Self::or`] to specify a custom default value. pubfn or_default(self) -> T { self.inner.unwrap_or_default()
}
}
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