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use proc_macro2::TokenStream;
use quote::quote;
use syn::{parse_quote, Data, Error, Type};
use crate::{
repr::StructUnionRepr,
util::{Ctx, DataExt, FieldBounds, ImplBlockBuilder, SelfBounds, Trait},
};
fn derive_known_layout_for_repr_c_struct<'a>(
ctx: &'a Ctx,
repr: &StructUnionRepr,
fields: &[(&'a syn::Visibility, TokenStream, &'a Type)],
) -> Option<(SelfBounds<'a>, TokenStream, Option<TokenStream>)> {
let (trailing_field, leading_fields) = fields.split_last()?;
let (_vis, trailing_field_name, trailing_field_ty) = trailing_field;
let leading_fields_tys = leading_fields.iter().map(|(_vis, _name, ty)| ty);
let core = ctx.core_path();
let repr_align = repr
.get_align()
.map(|align| {
let align = align.t.get();
quote!(#core::num::NonZeroUsize::new(#align as usize))
})
.unwrap_or_else(|| quote!(#core::option::Option::None));
let repr_packed = repr
.get_packed()
.map(|packed| {
let packed = packed.get();
quote!(#core::num::NonZeroUsize::new(#packed as usize))
})
.unwrap_or_else(|| quote!(#core::option::Option::None));
let zerocopy_crate = &ctx.zerocopy_crate;
let make_methods = |trailing_field_ty| {
quote! {
// SAFETY:
// - The returned pointer has the same address and provenance as
// `bytes`:
// - The recursive call to `raw_from_ptr_len` preserves both
// address and provenance.
// - The `as` cast preserves both address and provenance.
// - `NonNull::new_unchecked` preserves both address and
// provenance.
// - If `Self` is a slice DST, the returned pointer encodes
// `elems` elements in the trailing slice:
// - This is true of the recursive call to `raw_from_ptr_len`.
// - `trailing.as_ptr() as *mut Self` preserves trailing slice
// element count [1].
// - `NonNull::new_unchecked` preserves trailing slice element
// count.
//
// [1] Per https://doc.rust-lang.org/reference/expressions/operator-expr.html#pointer-to-pointer-cast:
//
// `*const T`` / `*mut T` can be cast to `*const U` / `*mut U`
// with the following behavior:
// ...
// - If `T` and `U` are both unsized, the pointer is also
// returned unchanged. In particular, the metadata is
// preserved exactly.
//
// For instance, a cast from `*const [T]` to `*const [U]`
// preserves the number of elements. ... The same holds
// for str and any compound type whose unsized tail is a
// slice type, such as struct `Foo(i32, [u8])` or
// `(u64, Foo)`.
#[inline(always)]
fn raw_from_ptr_len(
bytes: #core::ptr::NonNull<u8>,
meta: <Self as #zerocopy_crate::KnownLayout>::PointerMetadata,
) -> #core::ptr::NonNull<Self> {
let trailing = <#trailing_field_ty as #zerocopy_crate::KnownLayout>::raw_from_ptr_len(bytes, meta);
let slf = trailing.as_ptr() as *mut Self;
// SAFETY: Constructed from `trailing`, which is non-null.
unsafe { #core::ptr::NonNull::new_unchecked(slf) }
}
#[inline(always)]
fn pointer_to_metadata(ptr: *mut Self) -> <Self as #zerocopy_crate::KnownLayout>::PointerMetadata {
<#trailing_field_ty>::pointer_to_metadata(ptr as *mut _)
}
}
};
let inner_extras = {
let leading_fields_tys = leading_fields_tys.clone();
let methods = make_methods(*trailing_field_ty);
let (_, ty_generics, _) = ctx.ast.generics.split_for_impl();
quote!(
type PointerMetadata = <#trailing_field_ty as #zerocopy_crate::KnownLayout>::PointerMetadata;
type MaybeUninit = __ZerocopyKnownLayoutMaybeUninit #ty_generics;
// SAFETY: `LAYOUT` accurately describes the layout of `Self`.
// The documentation of `DstLayout::for_repr_c_struct` vows that
// invocations in this manner will accurately describe a type,
// so long as:
//
// - that type is `repr(C)`,
// - its fields are enumerated in the order they appear,
// - the presence of `repr_align` and `repr_packed` are
// correctly accounted for.
//
// We respect all three of these preconditions here. This
// expansion is only used if `is_repr_c_struct`, we enumerate
// the fields in order, and we extract the values of `align(N)`
// and `packed(N)`.
const LAYOUT: #zerocopy_crate::DstLayout = #zerocopy_crate::DstLayout::for_repr_c_struct(
#repr_align,
#repr_packed,
&[
#(#zerocopy_crate::DstLayout::for_type::<#leading_fields_tys>(),)*
<#trailing_field_ty as #zerocopy_crate::KnownLayout>::LAYOUT
],
);
#methods
)
};
let outer_extras = {
let ident = &ctx.ast.ident;
let vis = &ctx.ast.vis;
let params = &ctx.ast.generics.params;
let (impl_generics, ty_generics, where_clause) = ctx.ast.generics.split_for_impl();
let predicates = if let Some(where_clause) = where_clause {
where_clause.predicates.clone()
} else {
Default::default()
};
// Generate a valid ident for a type-level handle to a field of a
// given `name`.
let field_index = |name: &TokenStream| ident!(("__Zerocopy_Field_{}", name), ident.span());
let field_indices: Vec<_> =
fields.iter().map(|(_vis, name, _ty)| field_index(name)).collect();
// Define the collection of type-level field handles.
let field_defs = field_indices.iter().zip(fields).map(|(idx, (vis, _, _))| {
quote! {
#vis struct #idx;
}
});
let field_impls = field_indices.iter().zip(fields).map(|(idx, (_, _, ty))| quote! {
// SAFETY: `#ty` is the type of `#ident`'s field at `#idx`.
//
// We implement `Field` for each field of the struct to create a
// projection from the field index to its type. This allows us
// to refer to the field's type in a way that respects `Self`
// hygiene. If we just copy-pasted the tokens of `#ty`, we
// would not respect `Self` hygiene, as `Self` would refer to
// the helper struct we are generating, not the derive target
// type.
unsafe impl #impl_generics #zerocopy_crate::util::macro_util::Field<#idx> for #ident #ty_generics
where
#predicates
{
type Type = #ty;
}
});
let trailing_field_index = field_index(trailing_field_name);
let leading_field_indices =
leading_fields.iter().map(|(_vis, name, _ty)| field_index(name));
// We use `Field` to project the type of the trailing field. This is
// required to ensure that if the field type uses `Self`, it
// resolves to the derive target type, not the helper struct we are
// generating.
let trailing_field_ty = quote! {
<#ident #ty_generics as
#zerocopy_crate::util::macro_util::Field<#trailing_field_index>
>::Type
};
let methods = make_methods(&parse_quote! {
<#trailing_field_ty as #zerocopy_crate::KnownLayout>::MaybeUninit
});
let core = ctx.core_path();
quote! {
#(#field_defs)*
#(#field_impls)*
// SAFETY: This has the same layout as the derive target type,
// except that it admits uninit bytes. This is ensured by using
// the same repr as the target type, and by using field types
// which have the same layout as the target type's fields,
// except that they admit uninit bytes. We indirect through
// `Field` to ensure that occurrences of `Self` resolve to
// `#ty`, not `__ZerocopyKnownLayoutMaybeUninit` (see #2116).
#repr
#[doc(hidden)]
#vis struct __ZerocopyKnownLayoutMaybeUninit<#params> (
#(#core::mem::MaybeUninit<
<#ident #ty_generics as
#zerocopy_crate::util::macro_util::Field<#leading_field_indices>
>::Type
>,)*
// NOTE(#2302): We wrap in `ManuallyDrop` here in case the
// type we're operating on is both generic and
// `repr(packed)`. In that case, Rust needs to know that the
// type is *either* `Sized` or has a trivial `Drop`.
// `ManuallyDrop` has a trivial `Drop`, and so satisfies
// this requirement.
#core::mem::ManuallyDrop<
<#trailing_field_ty as #zerocopy_crate::KnownLayout>::MaybeUninit
>
)
where
#trailing_field_ty: #zerocopy_crate::KnownLayout,
#predicates;
// SAFETY: We largely defer to the `KnownLayout` implementation
// on the derive target type (both by using the same tokens, and
// by deferring to impl via type-level indirection). This is
// sound, since `__ZerocopyKnownLayoutMaybeUninit` is guaranteed
// to have the same layout as the derive target type, except
// that `__ZerocopyKnownLayoutMaybeUninit` admits uninit bytes.
unsafe impl #impl_generics #zerocopy_crate::KnownLayout for __ZerocopyKnownLayoutMaybeUninit #ty_generics
where
#trailing_field_ty: #zerocopy_crate::KnownLayout,
#predicates
{
fn only_derive_is_allowed_to_implement_this_trait() {}
type PointerMetadata = <#ident #ty_generics as #zerocopy_crate::KnownLayout>::PointerMetadata;
type MaybeUninit = Self;
const LAYOUT: #zerocopy_crate::DstLayout = <#ident #ty_generics as #zerocopy_crate::KnownLayout>::LAYOUT;
#methods
}
}
};
Some((SelfBounds::None, inner_extras, Some(outer_extras)))
}
pub(crate) fn derive(ctx: &Ctx, _top_level: Trait) -> Result<TokenStream, Error> {
// If this is a `repr(C)` struct, then `c_struct_repr` contains the entire
// `repr` attribute.
let c_struct_repr = match &ctx.ast.data {
Data::Struct(..) => {
let repr = StructUnionRepr::from_attrs(&ctx.ast.attrs)?;
if repr.is_c() {
Some(repr)
} else {
None
}
}
Data::Enum(..) | Data::Union(..) => None,
};
let fields = ctx.ast.data.fields();
let (self_bounds, inner_extras, outer_extras) = c_struct_repr
.as_ref()
.and_then(|repr| {
derive_known_layout_for_repr_c_struct(ctx, repr, &fields)
})
.unwrap_or_else(|| {
let zerocopy_crate = &ctx.zerocopy_crate;
let core = ctx.core_path();
// For enums, unions, and non-`repr(C)` structs, we require that
// `Self` is sized, and as a result don't need to reason about the
// internals of the type.
(
SelfBounds::SIZED,
quote!(
type PointerMetadata = ();
type MaybeUninit =
#core::mem::MaybeUninit<Self>;
// SAFETY: `LAYOUT` is guaranteed to accurately describe the
// layout of `Self`, because that is the documented safety
// contract of `DstLayout::for_type`.
const LAYOUT: #zerocopy_crate::DstLayout = #zerocopy_crate::DstLayout::for_type::<Self>();
// SAFETY: `.cast` preserves address and provenance.
//
// FIXME(#429): Add documentation to `.cast` that promises that
// it preserves provenance.
#[inline(always)]
fn raw_from_ptr_len(bytes: #core::ptr::NonNull<u8>, _meta: ()) -> #core::ptr::NonNull<Self> {
bytes.cast::<Self>()
}
#[inline(always)]
fn pointer_to_metadata(_ptr: *mut Self) -> () {}
),
None,
)
});
Ok(match &ctx.ast.data {
Data::Struct(strct) => {
let require_trait_bound_on_field_types =
if matches!(self_bounds, SelfBounds::All(&[Trait::Sized])) {
FieldBounds::None
} else {
FieldBounds::TRAILING_SELF
};
// A bound on the trailing field is required, since structs are
// unsized if their trailing field is unsized. Reflecting the layout
// of an usized trailing field requires that the field is
// `KnownLayout`.
ImplBlockBuilder::new(
ctx,
strct,
Trait::KnownLayout,
require_trait_bound_on_field_types,
)
.self_type_trait_bounds(self_bounds)
.inner_extras(inner_extras)
.outer_extras(outer_extras)
.build()
}
Data::Enum(enm) => {
// A bound on the trailing field is not required, since enums cannot
// currently be unsized.
ImplBlockBuilder::new(ctx, enm, Trait::KnownLayout, FieldBounds::None)
.self_type_trait_bounds(SelfBounds::SIZED)
.inner_extras(inner_extras)
.outer_extras(outer_extras)
.build()
}
Data::Union(unn) => {
// A bound on the trailing field is not required, since unions
// cannot currently be unsized.
ImplBlockBuilder::new(ctx, unn, Trait::KnownLayout, FieldBounds::None)
.self_type_trait_bounds(SelfBounds::SIZED)
.inner_extras(inner_extras)
.outer_extras(outer_extras)
.build()
}
})
}