parity-scale-codec-derive 3.6.7

Serialization and deserialization derive macro for Parity SCALE Codec
Documentation 
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// Copyright 2017, 2018 Parity Technologies
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
//     http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.

use proc_macro2::{Span, TokenStream, Ident};
use syn::{
	spanned::Spanned,
	Data, Fields, Field, Error,
};

use crate::utils;

/// Generate function block for function `Decode::decode`.
///
/// * data: data info of the type,
/// * type_name: name of the type,
/// * type_generics: the generics of the type in turbofish format, without bounds, e.g. `::<T, I>`
/// * input: the variable name for the argument of function `decode`.
pub fn quote(
	data: &Data,
	type_name: &Ident,
	type_generics: &TokenStream,
	input: &TokenStream,
	crate_path: &syn::Path,
) -> TokenStream {
	match *data {
		Data::Struct(ref data) => match data.fields {
			Fields::Named(_) | Fields::Unnamed(_) => create_instance(
				quote! { #type_name #type_generics },
				&type_name.to_string(),
				input,
				&data.fields,
				crate_path,
			),
			Fields::Unit => {
				quote_spanned! { data.fields.span() =>
					::core::result::Result::Ok(#type_name)
				}
			},
		},
		Data::Enum(ref data) => {
			let data_variants = || data.variants.iter().filter(|variant| !utils::should_skip(&variant.attrs));

			if data_variants().count() > 256 {
				return Error::new(
					data.variants.span(),
					"Currently only enums with at most 256 variants are encodable."
				).to_compile_error();
			}

			let recurse = data_variants().enumerate().map(|(i, v)| {
				let name = &v.ident;
				let index = utils::variant_index(v, i);

				let create = create_instance(
					quote! { #type_name #type_generics :: #name },
					&format!("{}::{}", type_name, name),
					input,
					&v.fields,
					crate_path,
				);

				quote_spanned! { v.span() =>
					#[allow(clippy::unnecessary_cast)]
					__codec_x_edqy if __codec_x_edqy == #index as ::core::primitive::u8 => {
						// NOTE: This lambda is necessary to work around an upstream bug
						// where each extra branch results in excessive stack usage:
						//   https://github.com/rust-lang/rust/issues/34283
						#[allow(clippy::redundant_closure_call)]
						return (move || {
							#create
						})();
					},
				}
			});

			let read_byte_err_msg = format!(
				"Could not decode `{}`, failed to read variant byte",
				type_name,
			);
			let invalid_variant_err_msg = format!(
				"Could not decode `{}`, variant doesn't exist",
				type_name,
			);
			quote! {
				match #input.read_byte()
					.map_err(|e| e.chain(#read_byte_err_msg))?
				{
					#( #recurse )*
					_ => {
						#[allow(clippy::redundant_closure_call)]
						return (move || {
							::core::result::Result::Err(
								<_ as ::core::convert::Into<_>>::into(#invalid_variant_err_msg)
							)
						})();
					},
				}
			}

		},
		Data::Union(_) => Error::new(Span::call_site(), "Union types are not supported.").to_compile_error(),
	}
}

pub fn quote_decode_into(
	data: &Data,
	crate_path: &syn::Path,
	input: &TokenStream,
	attrs: &[syn::Attribute]
) -> Option<TokenStream> {
	// Make sure the type is `#[repr(transparent)]`, as this guarantees that
	// there can be only one field that is not zero-sized.
	if !crate::utils::is_transparent(attrs) {
		return None;
	}

	let fields = match data {
		Data::Struct(
			syn::DataStruct {
				fields: Fields::Named(syn::FieldsNamed { named: fields, .. }) |
				        Fields::Unnamed(syn::FieldsUnnamed { unnamed: fields, .. }),
				..
			}
		) => {
			fields
		},
		_ => return None
	};

	if fields.is_empty() {
		return None;
	}

	// Bail if there are any extra attributes which could influence how the type is decoded.
	if fields.iter().any(|field|
		utils::get_encoded_as_type(field).is_some() ||
		utils::is_compact(field) ||
		utils::should_skip(&field.attrs)
	) {
		return None;
	}

	// Go through each field and call `decode_into` on it.
	//
	// Normally if there's more than one field in the struct this would be incorrect,
	// however since the struct's marked as `#[repr(transparent)]` we're guaranteed that
	// there's at most one non zero-sized field, so only one of these `decode_into` calls
	// should actually do something, and the rest should just be dummy calls that do nothing.
	let mut decode_fields = Vec::new();
	let mut sizes = Vec::new();
	let mut non_zst_field_count = Vec::new();
	for field in fields {
		let field_type = &field.ty;
		decode_fields.push(quote! {{
			let dst_: &mut ::core::mem::MaybeUninit<Self> = dst_; // To make sure the type is what we expect.

			// Here we cast `&mut MaybeUninit<Self>` into a `&mut MaybeUninit<#field_type>`.
			//
			// SAFETY: The struct is marked as `#[repr(transparent)]` so the address of every field will
			//         be the same as the address of the struct itself.
			let dst_: &mut ::core::mem::MaybeUninit<#field_type> = unsafe {
				&mut *dst_.as_mut_ptr().cast::<::core::mem::MaybeUninit<#field_type>>()
			};
			<#field_type as #crate_path::Decode>::decode_into(#input, dst_)?;
		}});

		if !sizes.is_empty() {
			sizes.push(quote! { + });
		}
		sizes.push(quote! { ::core::mem::size_of::<#field_type>() });

		if !non_zst_field_count.is_empty() {
			non_zst_field_count.push(quote! { + });
		}
		non_zst_field_count.push(quote! { if ::core::mem::size_of::<#field_type>() > 0 { 1 } else { 0 } });
	}

	Some(quote!{
		// Just a sanity check. These should always be true and will be optimized-out.
		::core::assert_eq!(#(#sizes)*, ::core::mem::size_of::<Self>());
		::core::assert!(#(#non_zst_field_count)* <= 1);

		#(#decode_fields)*

		// SAFETY: We've successfully called `decode_into` for all of the fields.
		unsafe { ::core::result::Result::Ok(#crate_path::DecodeFinished::assert_decoding_finished()) }
	})
}

fn create_decode_expr(field: &Field, name: &str, input: &TokenStream, crate_path: &syn::Path) -> TokenStream {
	let encoded_as = utils::get_encoded_as_type(field);
	let compact = utils::is_compact(field);
	let skip = utils::should_skip(&field.attrs);

	let res = quote!(__codec_res_edqy);

	if encoded_as.is_some() as u8 + compact as u8 + skip as u8 > 1 {
		return Error::new(
			field.span(),
			"`encoded_as`, `compact` and `skip` can only be used one at a time!"
		).to_compile_error();
	}

	let err_msg = format!("Could not decode `{}`", name);

	if compact {
		let field_type = &field.ty;
		quote_spanned! { field.span() =>
			{
				let #res = <
					<#field_type as #crate_path::HasCompact>::Type as #crate_path::Decode
				>::decode(#input);
				match #res {
					::core::result::Result::Err(e) => return ::core::result::Result::Err(e.chain(#err_msg)),
					::core::result::Result::Ok(#res) => #res.into(),
				}
			}
		}
	} else if let Some(encoded_as) = encoded_as {
		quote_spanned! { field.span() =>
			{
				let #res = <#encoded_as as #crate_path::Decode>::decode(#input);
				match #res {
					::core::result::Result::Err(e) => return ::core::result::Result::Err(e.chain(#err_msg)),
					::core::result::Result::Ok(#res) => #res.into(),
				}
			}
		}
	} else if skip {
		quote_spanned! { field.span() => ::core::default::Default::default() }
	} else {
		let field_type = &field.ty;
		quote_spanned! { field.span() =>
			{
				let #res = <#field_type as #crate_path::Decode>::decode(#input);
				match #res {
					::core::result::Result::Err(e) => return ::core::result::Result::Err(e.chain(#err_msg)),
					::core::result::Result::Ok(#res) => #res,
				}
			}
		}
	}
}

fn create_instance(
	name: TokenStream,
	name_str: &str,
	input: &TokenStream,
	fields: &Fields,
	crate_path: &syn::Path,
) -> TokenStream {
	match *fields {
		Fields::Named(ref fields) => {
			let recurse = fields.named.iter().map(|f| {
				let name_ident = &f.ident;
				let field_name = match name_ident {
					Some(a) => format!("{}::{}", name_str, a),
					None => name_str.to_string(), // Should never happen, fields are named.
				};
				let decode = create_decode_expr(f, &field_name, input, crate_path);

				quote_spanned! { f.span() =>
					#name_ident: #decode
				}
			});

			quote_spanned! { fields.span() =>
				::core::result::Result::Ok(#name {
					#( #recurse, )*
				})
			}
		},
		Fields::Unnamed(ref fields) => {
			let recurse = fields.unnamed.iter().enumerate().map(|(i, f) | {
				let field_name = format!("{}.{}", name_str, i);

				create_decode_expr(f, &field_name, input, crate_path)
			});

			quote_spanned! { fields.span() =>
				::core::result::Result::Ok(#name (
					#( #recurse, )*
				))
			}
		},
		Fields::Unit => {
			quote_spanned! { fields.span() =>
				::core::result::Result::Ok(#name)
			}
		},
	}
}