// Seemingly inconsequential code changes to this file can lead to measurable // performance impact on compilation times, due at least in part to the fact // that the layout code gets called from many instantiations of the various // collections, resulting in having to optimize down excess IR multiple times. // Your performance intuition is useless. Run perf. use crate::cmp; use crate::error::Error; use crate::fmt; use crate::mem; use crate::ptr::{Alignment, NonNull}; // While this function is used in one place and its implementation // could be inlined, the previous attempts to do so made rustc // slower: // // * https://github.com/rust-lang/rust/pull/72189 // * https://github.com/rust-lang/rust/pull/79827 const fn size_align() -> (usize, usize) { (mem::size_of::(), mem::align_of::()) } /// Layout of a block of memory. /// /// An instance of `Layout` describes a particular layout of memory. /// You build a `Layout` up as an input to give to an allocator. /// /// All layouts have an associated size and a power-of-two alignment. /// /// (Note that layouts are *not* required to have non-zero size, /// even though `GlobalAlloc` requires that all memory requests /// be non-zero in size. A caller must either ensure that conditions /// like this are met, use specific allocators with looser /// requirements, or use the more lenient `Allocator` interface.) #[stable(feature = "alloc_layout", since = "1.28.0")] #[derive(Copy, Clone, Debug, PartialEq, Eq, Hash)] #[lang = "alloc_layout"] pub struct Layout { // size of the requested block of memory, measured in bytes. size: usize, // alignment of the requested block of memory, measured in bytes. // we ensure that this is always a power-of-two, because API's // like `posix_memalign` require it and it is a reasonable // constraint to impose on Layout constructors. // // (However, we do not analogously require `align >= sizeof(void*)`, // even though that is *also* a requirement of `posix_memalign`.) align: Alignment, } impl Layout { /// Constructs a `Layout` from a given `size` and `align`, /// or returns `LayoutError` if any of the following conditions /// are not met: /// /// * `align` must not be zero, /// /// * `align` must be a power of two, /// /// * `size`, when rounded up to the nearest multiple of `align`, /// must not overflow isize (i.e., the rounded value must be /// less than or equal to `isize::MAX`). #[stable(feature = "alloc_layout", since = "1.28.0")] #[rustc_const_stable(feature = "const_alloc_layout_size_align", since = "1.50.0")] #[inline] #[rustc_allow_const_fn_unstable(ptr_alignment_type)] pub const fn from_size_align(size: usize, align: usize) -> Result { if !align.is_power_of_two() { return Err(LayoutError); } // SAFETY: just checked that align is a power of two. Layout::from_size_alignment(size, unsafe { Alignment::new_unchecked(align) }) } #[inline(always)] const fn max_size_for_align(align: Alignment) -> usize { // (power-of-two implies align != 0.) // Rounded up size is: // size_rounded_up = (size + align - 1) & !(align - 1); // // We know from above that align != 0. If adding (align - 1) // does not overflow, then rounding up will be fine. // // Conversely, &-masking with !(align - 1) will subtract off // only low-order-bits. Thus if overflow occurs with the sum, // the &-mask cannot subtract enough to undo that overflow. // // Above implies that checking for summation overflow is both // necessary and sufficient. isize::MAX as usize - (align.as_usize() - 1) } /// Internal helper constructor to skip revalidating alignment validity. #[inline] const fn from_size_alignment(size: usize, align: Alignment) -> Result { if size > Self::max_size_for_align(align) { return Err(LayoutError); } // SAFETY: Layout::size invariants checked above. Ok(Layout { size, align }) } /// Creates a layout, bypassing all checks. /// /// # Safety /// /// This function is unsafe as it does not verify the preconditions from /// [`Layout::from_size_align`]. #[stable(feature = "alloc_layout", since = "1.28.0")] #[rustc_const_stable(feature = "const_alloc_layout_unchecked", since = "1.36.0")] #[must_use] #[inline] #[rustc_allow_const_fn_unstable(ptr_alignment_type)] pub const unsafe fn from_size_align_unchecked(size: usize, align: usize) -> Self { // SAFETY: the caller is required to uphold the preconditions. unsafe { Layout { size, align: Alignment::new_unchecked(align) } } } /// The minimum size in bytes for a memory block of this layout. #[stable(feature = "alloc_layout", since = "1.28.0")] #[rustc_const_stable(feature = "const_alloc_layout_size_align", since = "1.50.0")] #[must_use] #[inline] pub const fn size(&self) -> usize { self.size } /// The minimum byte alignment for a memory block of this layout. #[stable(feature = "alloc_layout", since = "1.28.0")] #[rustc_const_stable(feature = "const_alloc_layout_size_align", since = "1.50.0")] #[must_use = "this returns the minimum alignment, \ without modifying the layout"] #[inline] #[rustc_allow_const_fn_unstable(ptr_alignment_type)] pub const fn align(&self) -> usize { self.align.as_usize() } /// Constructs a `Layout` suitable for holding a value of type `T`. #[stable(feature = "alloc_layout", since = "1.28.0")] #[rustc_const_stable(feature = "alloc_layout_const_new", since = "1.42.0")] #[must_use] #[inline] pub const fn new() -> Self { let (size, align) = size_align::(); // SAFETY: if the type is instantiated, rustc already ensures that its // layout is valid. Use the unchecked constructor to avoid inserting a // panicking codepath that needs to be optimized out. unsafe { Layout::from_size_align_unchecked(size, align) } } /// Produces layout describing a record that could be used to /// allocate backing structure for `T` (which could be a trait /// or other unsized type like a slice). #[stable(feature = "alloc_layout", since = "1.28.0")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[must_use] #[inline] pub const fn for_value(t: &T) -> Self { let (size, align) = (mem::size_of_val(t), mem::align_of_val(t)); // SAFETY: see rationale in `new` for why this is using the unsafe variant unsafe { Layout::from_size_align_unchecked(size, align) } } /// Produces layout describing a record that could be used to /// allocate backing structure for `T` (which could be a trait /// or other unsized type like a slice). /// /// # Safety /// /// This function is only safe to call if the following conditions hold: /// /// - If `T` is `Sized`, this function is always safe to call. /// - If the unsized tail of `T` is: /// - a [slice], then the length of the slice tail must be an initialized /// integer, and the size of the *entire value* /// (dynamic tail length + statically sized prefix) must fit in `isize`. /// - a [trait object], then the vtable part of the pointer must point /// to a valid vtable for the type `T` acquired by an unsizing coercion, /// and the size of the *entire value* /// (dynamic tail length + statically sized prefix) must fit in `isize`. /// - an (unstable) [extern type], then this function is always safe to /// call, but may panic or otherwise return the wrong value, as the /// extern type's layout is not known. This is the same behavior as /// [`Layout::for_value`] on a reference to an extern type tail. /// - otherwise, it is conservatively not allowed to call this function. /// /// [trait object]: ../../book/ch17-02-trait-objects.html /// [extern type]: ../../unstable-book/language-features/extern-types.html #[unstable(feature = "layout_for_ptr", issue = "69835")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[must_use] pub const unsafe fn for_value_raw(t: *const T) -> Self { // SAFETY: we pass along the prerequisites of these functions to the caller let (size, align) = unsafe { (mem::size_of_val_raw(t), mem::align_of_val_raw(t)) }; // SAFETY: see rationale in `new` for why this is using the unsafe variant unsafe { Layout::from_size_align_unchecked(size, align) } } /// Creates a `NonNull` that is dangling, but well-aligned for this Layout. /// /// Note that the pointer value may potentially represent a valid pointer, /// which means this must not be used as a "not yet initialized" /// sentinel value. Types that lazily allocate must track initialization by /// some other means. #[unstable(feature = "alloc_layout_extra", issue = "55724")] #[rustc_const_unstable(feature = "alloc_layout_extra", issue = "55724")] #[must_use] #[inline] pub const fn dangling(&self) -> NonNull { // SAFETY: align is guaranteed to be non-zero unsafe { NonNull::new_unchecked(crate::ptr::invalid_mut::(self.align())) } } /// Creates a layout describing the record that can hold a value /// of the same layout as `self`, but that also is aligned to /// alignment `align` (measured in bytes). /// /// If `self` already meets the prescribed alignment, then returns /// `self`. /// /// Note that this method does not add any padding to the overall /// size, regardless of whether the returned layout has a different /// alignment. In other words, if `K` has size 16, `K.align_to(32)` /// will *still* have size 16. /// /// Returns an error if the combination of `self.size()` and the given /// `align` violates the conditions listed in [`Layout::from_size_align`]. #[stable(feature = "alloc_layout_manipulation", since = "1.44.0")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[inline] pub const fn align_to(&self, align: usize) -> Result { Layout::from_size_align(self.size(), cmp::max(self.align(), align)) } /// Returns the amount of padding we must insert after `self` /// to ensure that the following address will satisfy `align` /// (measured in bytes). /// /// e.g., if `self.size()` is 9, then `self.padding_needed_for(4)` /// returns 3, because that is the minimum number of bytes of /// padding required to get a 4-aligned address (assuming that the /// corresponding memory block starts at a 4-aligned address). /// /// The return value of this function has no meaning if `align` is /// not a power-of-two. /// /// Note that the utility of the returned value requires `align` /// to be less than or equal to the alignment of the starting /// address for the whole allocated block of memory. One way to /// satisfy this constraint is to ensure `align <= self.align()`. #[unstable(feature = "alloc_layout_extra", issue = "55724")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[must_use = "this returns the padding needed, \ without modifying the `Layout`"] #[inline] pub const fn padding_needed_for(&self, align: usize) -> usize { let len = self.size(); // Rounded up value is: // len_rounded_up = (len + align - 1) & !(align - 1); // and then we return the padding difference: `len_rounded_up - len`. // // We use modular arithmetic throughout: // // 1. align is guaranteed to be > 0, so align - 1 is always // valid. // // 2. `len + align - 1` can overflow by at most `align - 1`, // so the &-mask with `!(align - 1)` will ensure that in the // case of overflow, `len_rounded_up` will itself be 0. // Thus the returned padding, when added to `len`, yields 0, // which trivially satisfies the alignment `align`. // // (Of course, attempts to allocate blocks of memory whose // size and padding overflow in the above manner should cause // the allocator to yield an error anyway.) let len_rounded_up = len.wrapping_add(align).wrapping_sub(1) & !align.wrapping_sub(1); len_rounded_up.wrapping_sub(len) } /// Creates a layout by rounding the size of this layout up to a multiple /// of the layout's alignment. /// /// This is equivalent to adding the result of `padding_needed_for` /// to the layout's current size. #[stable(feature = "alloc_layout_manipulation", since = "1.44.0")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[must_use = "this returns a new `Layout`, \ without modifying the original"] #[inline] pub const fn pad_to_align(&self) -> Layout { let pad = self.padding_needed_for(self.align()); // This cannot overflow. Quoting from the invariant of Layout: // > `size`, when rounded up to the nearest multiple of `align`, // > must not overflow isize (i.e., the rounded value must be // > less than or equal to `isize::MAX`) let new_size = self.size() + pad; // SAFETY: padded size is guaranteed to not exceed `isize::MAX`. unsafe { Layout::from_size_align_unchecked(new_size, self.align()) } } /// Creates a layout describing the record for `n` instances of /// `self`, with a suitable amount of padding between each to /// ensure that each instance is given its requested size and /// alignment. On success, returns `(k, offs)` where `k` is the /// layout of the array and `offs` is the distance between the start /// of each element in the array. /// /// On arithmetic overflow, returns `LayoutError`. #[unstable(feature = "alloc_layout_extra", issue = "55724")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[inline] pub const fn repeat(&self, n: usize) -> Result<(Self, usize), LayoutError> { // This cannot overflow. Quoting from the invariant of Layout: // > `size`, when rounded up to the nearest multiple of `align`, // > must not overflow isize (i.e., the rounded value must be // > less than or equal to `isize::MAX`) let padded_size = self.size() + self.padding_needed_for(self.align()); let alloc_size = padded_size.checked_mul(n).ok_or(LayoutError)?; // The safe constructor is called here to enforce the isize size limit. let layout = Layout::from_size_alignment(alloc_size, self.align)?; Ok((layout, padded_size)) } /// Creates a layout describing the record for `self` followed by /// `next`, including any necessary padding to ensure that `next` /// will be properly aligned, but *no trailing padding*. /// /// In order to match C representation layout `repr(C)`, you should /// call `pad_to_align` after extending the layout with all fields. /// (There is no way to match the default Rust representation /// layout `repr(Rust)`, as it is unspecified.) /// /// Note that the alignment of the resulting layout will be the maximum of /// those of `self` and `next`, in order to ensure alignment of both parts. /// /// Returns `Ok((k, offset))`, where `k` is layout of the concatenated /// record and `offset` is the relative location, in bytes, of the /// start of the `next` embedded within the concatenated record /// (assuming that the record itself starts at offset 0). /// /// On arithmetic overflow, returns `LayoutError`. /// /// # Examples /// /// To calculate the layout of a `#[repr(C)]` structure and the offsets of /// the fields from its fields' layouts: /// /// ```rust /// # use std::alloc::{Layout, LayoutError}; /// pub fn repr_c(fields: &[Layout]) -> Result<(Layout, Vec), LayoutError> { /// let mut offsets = Vec::new(); /// let mut layout = Layout::from_size_align(0, 1)?; /// for &field in fields { /// let (new_layout, offset) = layout.extend(field)?; /// layout = new_layout; /// offsets.push(offset); /// } /// // Remember to finalize with `pad_to_align`! /// Ok((layout.pad_to_align(), offsets)) /// } /// # // test that it works /// # #[repr(C)] struct S { a: u64, b: u32, c: u16, d: u32 } /// # let s = Layout::new::(); /// # let u16 = Layout::new::(); /// # let u32 = Layout::new::(); /// # let u64 = Layout::new::(); /// # assert_eq!(repr_c(&[u64, u32, u16, u32]), Ok((s, vec![0, 8, 12, 16]))); /// ``` #[stable(feature = "alloc_layout_manipulation", since = "1.44.0")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[inline] pub const fn extend(&self, next: Self) -> Result<(Self, usize), LayoutError> { let new_align = cmp::max(self.align, next.align); let pad = self.padding_needed_for(next.align()); let offset = self.size().checked_add(pad).ok_or(LayoutError)?; let new_size = offset.checked_add(next.size()).ok_or(LayoutError)?; // The safe constructor is called here to enforce the isize size limit. let layout = Layout::from_size_alignment(new_size, new_align)?; Ok((layout, offset)) } /// Creates a layout describing the record for `n` instances of /// `self`, with no padding between each instance. /// /// Note that, unlike `repeat`, `repeat_packed` does not guarantee /// that the repeated instances of `self` will be properly /// aligned, even if a given instance of `self` is properly /// aligned. In other words, if the layout returned by /// `repeat_packed` is used to allocate an array, it is not /// guaranteed that all elements in the array will be properly /// aligned. /// /// On arithmetic overflow, returns `LayoutError`. #[unstable(feature = "alloc_layout_extra", issue = "55724")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[inline] pub const fn repeat_packed(&self, n: usize) -> Result { let size = self.size().checked_mul(n).ok_or(LayoutError)?; // The safe constructor is called here to enforce the isize size limit. Layout::from_size_alignment(size, self.align) } /// Creates a layout describing the record for `self` followed by /// `next` with no additional padding between the two. Since no /// padding is inserted, the alignment of `next` is irrelevant, /// and is not incorporated *at all* into the resulting layout. /// /// On arithmetic overflow, returns `LayoutError`. #[unstable(feature = "alloc_layout_extra", issue = "55724")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[inline] pub const fn extend_packed(&self, next: Self) -> Result { let new_size = self.size().checked_add(next.size()).ok_or(LayoutError)?; // The safe constructor is called here to enforce the isize size limit. Layout::from_size_alignment(new_size, self.align) } /// Creates a layout describing the record for a `[T; n]`. /// /// On arithmetic overflow or when the total size would exceed /// `isize::MAX`, returns `LayoutError`. #[stable(feature = "alloc_layout_manipulation", since = "1.44.0")] #[rustc_const_unstable(feature = "const_alloc_layout", issue = "67521")] #[inline] pub const fn array(n: usize) -> Result { // Reduce the amount of code we need to monomorphize per `T`. return inner(mem::size_of::(), Alignment::of::(), n); #[inline] const fn inner( element_size: usize, align: Alignment, n: usize, ) -> Result { // We need to check two things about the size: // - That the total size won't overflow a `usize`, and // - That the total size still fits in an `isize`. // By using division we can check them both with a single threshold. // That'd usually be a bad idea, but thankfully here the element size // and alignment are constants, so the compiler will fold all of it. if element_size != 0 && n > Layout::max_size_for_align(align) / element_size { return Err(LayoutError); } let array_size = element_size * n; // SAFETY: We just checked above that the `array_size` will not // exceed `isize::MAX` even when rounded up to the alignment. // And `Alignment` guarantees it's a power of two. unsafe { Ok(Layout::from_size_align_unchecked(array_size, align.as_usize())) } } } } #[stable(feature = "alloc_layout", since = "1.28.0")] #[deprecated( since = "1.52.0", note = "Name does not follow std convention, use LayoutError", suggestion = "LayoutError" )] pub type LayoutErr = LayoutError; /// The parameters given to `Layout::from_size_align` /// or some other `Layout` constructor /// do not satisfy its documented constraints. #[stable(feature = "alloc_layout_error", since = "1.50.0")] #[non_exhaustive] #[derive(Clone, PartialEq, Eq, Debug)] pub struct LayoutError; #[stable(feature = "alloc_layout", since = "1.28.0")] impl Error for LayoutError {} // (we need this for downstream impl of trait Error) #[stable(feature = "alloc_layout", since = "1.28.0")] impl fmt::Display for LayoutError { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.write_str("invalid parameters to Layout::from_size_align") } }