vendor/zerovec-derive-0.10.3/src/varule.rs - toolchain/rustc - Git at Google

 // This file is part of ICU4X. For terms of use, please see the file
 // called LICENSE at the top level of the ICU4X source tree
 // (online at: https://github.com/unicode-org/icu4x/blob/main/LICENSE ).

 use crate::utils::{self, FieldInfo};
 use proc_macro2::Span;
 use proc_macro2::TokenStream as TokenStream2;
 use quote::quote;
 use syn::spanned::Spanned;
 use syn::{Data, DeriveInput, Error, Ident};

 /// Implementation for derive(VarULE). `custom_varule_validator` validates the last field bytes `last_field_bytes`
 /// if specified, if not, the VarULE implementation will be used.
 pub fn derive_impl(
     input: &DeriveInput,
     custom_varule_validator: Option<TokenStream2>,
 ) -> TokenStream2 {
     if !utils::ReprInfo::compute(&input.attrs).cpacked_or_transparent() {
         return Error::new(
             input.span(),
             "derive(VarULE) must be applied to a #[repr(C, packed)] or #[repr(transparent)] type",
         )
         .to_compile_error();
     }
     if input.generics.type_params().next().is_some()
         || input.generics.lifetimes().next().is_some()
         || input.generics.const_params().next().is_some()
     {
         return Error::new(
             input.generics.span(),
             "derive(VarULE) must be applied to a struct without any generics",
         )
         .to_compile_error();
     }
     let struc = if let Data::Struct(ref s) = input.data {
         if s.fields.iter().next().is_none() {
             return Error::new(
                 input.span(),
                 "derive(VarULE) must be applied to a non-empty struct",
             )
             .to_compile_error();
         }
         s
     } else {
         return Error::new(input.span(), "derive(VarULE) must be applied to a struct")
             .to_compile_error();
     };

     let n_fields = struc.fields.len();

     let ule_fields = FieldInfo::make_list(struc.fields.iter().take(n_fields - 1));

     let sizes = ule_fields.iter().map(|f| {
         let ty = &f.field.ty;
         quote!(::core::mem::size_of::<#ty>())
     });
     let (validators, remaining_offset) = if n_fields > 1 {
         // generate ULE validators
         crate::ule::generate_ule_validators(&ule_fields)
     } else {
         // no ULE subfields
         (
             quote!(
                 const ZERO: usize = 0;
             ),
             Ident::new("ZERO", Span::call_site()),
         )
     };

     let unsized_field = &struc
         .fields
         .iter()
         .next_back()
         .expect("Already verified that struct is not empty")
         .ty;

     let name = &input.ident;
     let ule_size = Ident::new(
         &format!("__IMPL_VarULE_FOR_{name}_ULE_SIZE"),
         Span::call_site(),
     );

     let last_field_validator = if let Some(custom_varule_validator) = custom_varule_validator {
         custom_varule_validator
     } else {
         quote!(<#unsized_field as zerovec::ule::VarULE>::validate_byte_slice(last_field_bytes)?;)
     };

     // Safety (based on the safety checklist on the ULE trait):
     //  1. #name does not include any uninitialized or padding bytes
     //     (achieved by enforcing #[repr(transparent)] or #[repr(packed)] on a struct of only ULE types)
     //  2. #name is aligned to 1 byte.
     //     (achieved by enforcing #[repr(transparent)] or #[repr(packed)] on a struct of only ULE types)
     //  3. The impl of `validate_byte_slice()` returns an error if any byte is not valid.
     //  4. The impl of `validate_byte_slice()` returns an error if the slice cannot be used in its entirety
     //  5. The impl of `from_byte_slice_unchecked()` returns a reference to the same data.
     //  6. The other VarULE methods use the default impl
     //  7. [This impl does not enforce the non-safety equality constraint, it is up to the user to do so, ideally via a custom derive]
     quote! {
         // The size of the ULE section of this type
         const #ule_size: usize = 0 #(+ #sizes)*;
         unsafe impl zerovec::ule::VarULE for #name {
             #[inline]
             fn validate_byte_slice(bytes: &[u8]) -> Result<(), zerovec::ZeroVecError> {

                 if bytes.len() < #ule_size {
                     return Err(zerovec::ZeroVecError::parse::<Self>());
                 }
                 #validators
                 debug_assert_eq!(#remaining_offset, #ule_size);
                 #[allow(clippy::indexing_slicing)] // TODO explain
                 let last_field_bytes = &bytes[#remaining_offset..];
                 #last_field_validator
                 Ok(())
             }
             #[inline]
             unsafe fn from_byte_slice_unchecked(bytes: &[u8]) -> &Self {
                 // just the unsized part
                 #[allow(clippy::indexing_slicing)] // TODO explain
                 let unsized_bytes = &bytes[#ule_size..];
                 let unsized_ref = <#unsized_field as zerovec::ule::VarULE>::from_byte_slice_unchecked(unsized_bytes);
                 // We should use the pointer metadata APIs here when they are stable: https://github.com/rust-lang/rust/issues/81513
                 // For now we rely on all DST metadata being a usize to extract it via a fake slice pointer
                 let (_ptr, metadata): (usize, usize) = ::core::mem::transmute(unsized_ref);
                 let entire_struct_as_slice: *const [u8] = ::core::slice::from_raw_parts(bytes.as_ptr(), metadata);
                 &*(entire_struct_as_slice as *const Self)
             }
         }
     }
 }
	// This file is part of ICU4X. For terms of use, please see the file
	// called LICENSE at the top level of the ICU4X source tree
	// (online at: https://github.com/unicode-org/icu4x/blob/main/LICENSE ).

	use crate::utils::{self, FieldInfo};
	use proc_macro2::Span;
	use proc_macro2::TokenStream as TokenStream2;
	use quote::quote;
	use syn::spanned::Spanned;
	use syn::{Data, DeriveInput, Error, Ident};

	/// Implementation for derive(VarULE). `custom_varule_validator` validates the last field bytes `last_field_bytes`
	/// if specified, if not, the VarULE implementation will be used.
	pub fn derive_impl(
	input: &DeriveInput,
	custom_varule_validator: Option<TokenStream2>,
	) -> TokenStream2 {
	if !utils::ReprInfo::compute(&input.attrs).cpacked_or_transparent() {
	return Error::new(
	input.span(),
	"derive(VarULE) must be applied to a #[repr(C, packed)] or #[repr(transparent)] type",
	)
	.to_compile_error();
	}
	if input.generics.type_params().next().is_some()
	\|\| input.generics.lifetimes().next().is_some()
	\|\| input.generics.const_params().next().is_some()
	{
	return Error::new(
	input.generics.span(),
	"derive(VarULE) must be applied to a struct without any generics",
	)
	.to_compile_error();
	}
	let struc = if let Data::Struct(ref s) = input.data {
	if s.fields.iter().next().is_none() {
	return Error::new(
	input.span(),
	"derive(VarULE) must be applied to a non-empty struct",
	)
	.to_compile_error();
	}
	s
	} else {
	return Error::new(input.span(), "derive(VarULE) must be applied to a struct")
	.to_compile_error();
	};

	let n_fields = struc.fields.len();

	let ule_fields = FieldInfo::make_list(struc.fields.iter().take(n_fields - 1));

	let sizes = ule_fields.iter().map(\|f\| {
	let ty = &f.field.ty;
	quote!(::core::mem::size_of::<#ty>())
	});
	let (validators, remaining_offset) = if n_fields > 1 {
	// generate ULE validators
	crate::ule::generate_ule_validators(&ule_fields)
	} else {
	// no ULE subfields
	(
	quote!(
	const ZERO: usize = 0;
	),
	Ident::new("ZERO", Span::call_site()),
	)
	};

	let unsized_field = &struc
	.fields
	.iter()
	.next_back()
	.expect("Already verified that struct is not empty")
	.ty;

	let name = &input.ident;
	let ule_size = Ident::new(
	&format!("__IMPL_VarULE_FOR_{name}_ULE_SIZE"),
	Span::call_site(),
	);

	let last_field_validator = if let Some(custom_varule_validator) = custom_varule_validator {
	custom_varule_validator
	} else {
	quote!(<#unsized_field as zerovec::ule::VarULE>::validate_byte_slice(last_field_bytes)?;)
	};

	// Safety (based on the safety checklist on the ULE trait):
	// 1. #name does not include any uninitialized or padding bytes
	// (achieved by enforcing #[repr(transparent)] or #[repr(packed)] on a struct of only ULE types)
	// 2. #name is aligned to 1 byte.
	// (achieved by enforcing #[repr(transparent)] or #[repr(packed)] on a struct of only ULE types)
	// 3. The impl of `validate_byte_slice()` returns an error if any byte is not valid.
	// 4. The impl of `validate_byte_slice()` returns an error if the slice cannot be used in its entirety
	// 5. The impl of `from_byte_slice_unchecked()` returns a reference to the same data.
	// 6. The other VarULE methods use the default impl
	// 7. [This impl does not enforce the non-safety equality constraint, it is up to the user to do so, ideally via a custom derive]
	quote! {
	// The size of the ULE section of this type
	const #ule_size: usize = 0 #(+ #sizes)*;
	unsafe impl zerovec::ule::VarULE for #name {
	#[inline]
	fn validate_byte_slice(bytes: &[u8]) -> Result<(), zerovec::ZeroVecError> {

	if bytes.len() < #ule_size {
	return Err(zerovec::ZeroVecError::parse::<Self>());
	}
	#validators
	debug_assert_eq!(#remaining_offset, #ule_size);
	#[allow(clippy::indexing_slicing)] // TODO explain
	let last_field_bytes = &bytes[#remaining_offset..];
	#last_field_validator
	Ok(())
	}
	#[inline]
	unsafe fn from_byte_slice_unchecked(bytes: &[u8]) -> &Self {
	// just the unsized part
	#[allow(clippy::indexing_slicing)] // TODO explain
	let unsized_bytes = &bytes[#ule_size..];
	let unsized_ref = <#unsized_field as zerovec::ule::VarULE>::from_byte_slice_unchecked(unsized_bytes);
	// We should use the pointer metadata APIs here when they are stable: https://github.com/rust-lang/rust/issues/81513
	// For now we rely on all DST metadata being a usize to extract it via a fake slice pointer
	let (_ptr, metadata): (usize, usize) = ::core::mem::transmute(unsized_ref);
	let entire_struct_as_slice: *const [u8] = ::core::slice::from_raw_parts(bytes.as_ptr(), metadata);
	&(entire_struct_as_slice as const Self)
	}
	}
	}
	}