#![allow(clippy::uninlined_format_args)]
extern crate proc_macro;
use proc_macro::TokenStream;
use proc_macro2::Span;
use quote::quote;
use syn::{parse_macro_input, Expr, Ident};
mod enum_attributes;
mod parsing;
use parsing::{get_crate_name, EnumInfo};
mod utils;
mod variant_attributes;
#[proc_macro_derive(IntoPrimitive, attributes(num_enum, catch_all))]
pub fn derive_into_primitive(input: TokenStream) -> TokenStream {
let enum_info = parse_macro_input!(input as EnumInfo);
let catch_all = enum_info.catch_all();
let name = &enum_info.name;
let repr = &enum_info.repr;
let body = if let Some(catch_all_ident) = catch_all {
quote! {
match enum_value {
#name::#catch_all_ident(raw) => raw,
rest => unsafe { *(&rest as *const #name as *const Self) }
}
}
} else {
quote! { enum_value as Self }
};
TokenStream::from(quote! {
impl From<#name> for #repr {
#[inline]
fn from (enum_value: #name) -> Self
{
#body
}
}
})
}
#[proc_macro_derive(FromPrimitive, attributes(num_enum, default, catch_all))]
pub fn derive_from_primitive(input: TokenStream) -> TokenStream {
let enum_info: EnumInfo = parse_macro_input!(input);
let krate = Ident::new(&get_crate_name(), Span::call_site());
let is_naturally_exhaustive = enum_info.is_naturally_exhaustive();
let catch_all_body = match is_naturally_exhaustive {
Ok(is_naturally_exhaustive) => {
if is_naturally_exhaustive {
quote! { unreachable!("exhaustive enum") }
} else if let Some(default_ident) = enum_info.default() {
quote! { Self::#default_ident }
} else if let Some(catch_all_ident) = enum_info.catch_all() {
quote! { Self::#catch_all_ident(number) }
} else {
let span = Span::call_site();
let message =
"#[derive(num_enum::FromPrimitive)] requires enum to be exhaustive, or a variant marked with `#[default]`, `#[num_enum(default)]`, or `#[num_enum(catch_all)`";
return syn::Error::new(span, message).to_compile_error().into();
}
}
Err(err) => {
return err.to_compile_error().into();
}
};
let EnumInfo {
ref name, ref repr, ..
} = enum_info;
let variant_idents: Vec<Ident> = enum_info.variant_idents();
let expression_idents: Vec<Vec<Ident>> = enum_info.expression_idents();
let variant_expressions: Vec<Vec<Expr>> = enum_info.variant_expressions();
debug_assert_eq!(variant_idents.len(), variant_expressions.len());
TokenStream::from(quote! {
impl ::#krate::FromPrimitive for #name {
type Primitive = #repr;
fn from_primitive(number: Self::Primitive) -> Self {
#![allow(non_upper_case_globals)]
#(
#(
const #expression_idents: #repr = #variant_expressions;
)*
)*
#[deny(unreachable_patterns)]
match number {
#(
#( #expression_idents )|*
=> Self::#variant_idents,
)*
#[allow(unreachable_patterns)]
_ => #catch_all_body,
}
}
}
impl ::core::convert::From<#repr> for #name {
#[inline]
fn from (
number: #repr,
) -> Self {
::#krate::FromPrimitive::from_primitive(number)
}
}
#[doc(hidden)]
impl ::#krate::CannotDeriveBothFromPrimitiveAndTryFromPrimitive for #name {}
})
}
#[proc_macro_derive(TryFromPrimitive, attributes(num_enum))]
pub fn derive_try_from_primitive(input: TokenStream) -> TokenStream {
let enum_info: EnumInfo = parse_macro_input!(input);
let krate = Ident::new(&get_crate_name(), Span::call_site());
let EnumInfo {
ref name,
ref repr,
ref error_type_info,
..
} = enum_info;
let variant_idents: Vec<Ident> = enum_info.variant_idents();
let expression_idents: Vec<Vec<Ident>> = enum_info.expression_idents();
let variant_expressions: Vec<Vec<Expr>> = enum_info.variant_expressions();
debug_assert_eq!(variant_idents.len(), variant_expressions.len());
let error_type = &error_type_info.name;
let error_constructor = &error_type_info.constructor;
TokenStream::from(quote! {
impl ::#krate::TryFromPrimitive for #name {
type Primitive = #repr;
type Error = #error_type;
const NAME: &'static str = stringify!(#name);
fn try_from_primitive (
number: Self::Primitive,
) -> ::core::result::Result<
Self,
#error_type
> {
#![allow(non_upper_case_globals)]
#(
#(
const #expression_idents: #repr = #variant_expressions;
)*
)*
#[deny(unreachable_patterns)]
match number {
#(
#( #expression_idents )|*
=> ::core::result::Result::Ok(Self::#variant_idents),
)*
#[allow(unreachable_patterns)]
_ => ::core::result::Result::Err(
#error_constructor ( number )
),
}
}
}
impl ::core::convert::TryFrom<#repr> for #name {
type Error = #error_type;
#[inline]
fn try_from (
number: #repr,
) -> ::core::result::Result<Self, #error_type>
{
::#krate::TryFromPrimitive::try_from_primitive(number)
}
}
#[doc(hidden)]
impl ::#krate::CannotDeriveBothFromPrimitiveAndTryFromPrimitive for #name {}
})
}
#[proc_macro_derive(UnsafeFromPrimitive, attributes(num_enum))]
pub fn derive_unsafe_from_primitive(stream: TokenStream) -> TokenStream {
let enum_info = parse_macro_input!(stream as EnumInfo);
let krate = Ident::new(&get_crate_name(), Span::call_site());
let EnumInfo {
ref name, ref repr, ..
} = enum_info;
TokenStream::from(quote! {
impl ::#krate::UnsafeFromPrimitive for #name {
type Primitive = #repr;
unsafe fn unchecked_transmute_from(number: Self::Primitive) -> Self {
::core::mem::transmute(number)
}
}
})
}
#[proc_macro_derive(Default, attributes(num_enum, default))]
pub fn derive_default(stream: TokenStream) -> TokenStream {
let enum_info = parse_macro_input!(stream as EnumInfo);
let default_ident = match enum_info.default() {
Some(ident) => ident,
None => {
let span = Span::call_site();
let message =
"#[derive(num_enum::Default)] requires enum to be exhaustive, or a variant marked with `#[default]` or `#[num_enum(default)]`";
return syn::Error::new(span, message).to_compile_error().into();
}
};
let EnumInfo { ref name, .. } = enum_info;
TokenStream::from(quote! {
impl ::core::default::Default for #name {
#[inline]
fn default() -> Self {
Self::#default_ident
}
}
})
}