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use std::borrow::Cow;
use std::cell::RefCell; use std::collections::hash_map::HashMap; use std::collections::HashSet; use std::hash::BuildHasher; use std::num; use std::rc::Rc; use std::sync::atomic::AtomicBool; use std::sync::Arc; use syn::{Expr, Lit, Meta}; use crate::ast::NestedMeta; use crate::util::path_to_string; use crate::{Error, Result}; /// Create an instance from an item in an attribute declaration. /// /// # Implementing `FromMeta` /// * Do not take a dependency on the `ident` of the passed-in meta item. The ident will be set by th /// * Implement only the `from_*` methods that you intend to support. The default implementati /// /// # Provided Implementations /// ## bool /// /// * Word with no value specified - becomes `true`. /// * As a boolean literal, e.g. `foo = true`. /// * As a string literal, e.g. `foo = "true"`. /// /// ## char /// * As a char literal, e.g. `foo = '#'`. /// * As a string literal consisting of a single character, e.g. `foo = "#"`. /// /// ## String /// * As a string literal, e.g. `foo = "hello"`. /// * As a raw string literal, e.g. `foo = r#"hello "world""#`. /// /// ## Number /// * As a string literal, e.g. `foo = "-25"`. /// * As an unquoted positive value, e.g. `foo = 404`. Negative numbers must be in quotation mark /// /// ## () /// * Word with no value specified, e.g. `foo`. This is best used with `Option`. /// See `darling::util::Flag` for a more strongly-typed alternative. /// /// ## Option /// * Any format produces `Some`. /// /// ## `Result<T, darling::Error>` /// * Allows for fallible parsing; will populate the target field with the result of the /// parse attempt. pub trait FromMeta: Sized { fn from_nested_meta(item: &NestedMeta) -> Result<Self> { (match *item { NestedMeta::Lit(ref lit) => Self::from_value(lit), NestedMeta::Meta(ref mi) => Self::from_meta(mi), }) .map_err(|e| e.with_span(item)) } /// Create an instance from a `syn::Meta` by dispatching to the format-appropriate /// trait function. This generally should not be overridden by implementers. /// /// # Error Spans /// If this method is overridden and can introduce errors that weren't passed up from /// other `from_meta` calls, the override must call `with_span` on the error using the /// `item` to make sure that the emitted diagnostic points to the correct location in /// source code. fn from_meta(item: &Meta) -> Result<Self> { (match *item { Meta::Path(_) => Self::from_word(), Meta::List(ref value) => { Self::from_list(&NestedMeta::parse_meta_list(value.tokens.clone())?[..]) } Meta::NameValue(ref value) => Self::from_expr(&value.value), }) .map_err(|e| e.with_span(item)) } /// When a field is omitted from a parent meta-item, `from_none` is used to attempt /// recovery before a missing field error is generated. /// /// **Most types should not override this method.** `darling` already allows field-level /// missing-field recovery using `#[darling(default)]` and `#[darling(default = "...")]` /// and users who add a `String` field to their `FromMeta`-deriving struct would be surprised /// if they get back `""` instead of a missing field error when that field is omitted. /// /// The primary use-case for this is `Option<T>` fields gracefully handlling absence without /// needing `#[darling(default)]`. fn from_none() -> Option<Self> { None } /// Create an instance from the presence of the word in the attribute with no /// additional options specified. fn from_word() -> Result<Self> { Err(Error::unsupported_format("word")) } /// Create an instance from a list of nested meta items. #[allow(unused_variables)] fn from_list(items: &[NestedMeta]) -> Result<Self> { Err(Error::unsupported_format("list")) } /// Create an instance from a literal value of either `foo = "bar"` or `foo("bar")`. /// This dispatches to the appropriate method based on the type of literal encountered, /// and generally should not be overridden by implementers. /// /// # Error Spans /// If this method is overridden, the override must make sure to add `value`'s span /// information to the returned error by calling `with_span(value)` on the `Error` instance. fn from_value(value: &Lit) -> Result<Self> { (match *value { Lit::Bool(ref b) => Self::from_bool(b.value), Lit::Str(ref s) => Self::from_string(&s.value()), Lit::Char(ref ch) => Self::from_char(ch.value()), _ => Err(Error::unexpected_lit_type(value)), }) .map_err(|e| e.with_span(value)) } fn from_expr(expr: &Expr) -> Result<Self> { match *expr { Expr::Lit(ref lit) => Self::from_value(&lit.lit), Expr::Group(ref group) => { // syn may generate this invisible group delimiter when the input to the darling // proc macro (specifically, the attributes) are generated by a // macro_rules! (e.g. propagating a macro_rules!'s expr) // Since we want to basically ignore these invisible group delimiters, // we just propagate the call to the inner expression. Self::from_expr(&group.expr) } _ => Err(Error::unexpected_expr_type(expr)), } .map_err(|e| e.with_span(expr)) } /// Create an instance from a char literal in a value position. #[allow(unused_variables)] fn from_char(value: char) -> Result<Self> { Err(Error::unexpected_type("char")) } /// Create an instance from a string literal in a value position. #[allow(unused_variables)] fn from_string(value: &str) -> Result<Self> { Err(Error::unexpected_type("string")) } /// Create an instance from a bool literal in a value position. #[allow(unused_variables)] fn from_bool(value: bool) -> Result<Self> { Err(Error::unexpected_type("bool")) } } // FromMeta impls for std and syn types. impl FromMeta for () { fn from_word() -> Result<Self> { Ok(()) } } impl FromMeta for bool { fn from_word() -> Result<Self> { Ok(true) } #[allow(clippy::wrong_self_convention)] // false positive fn from_bool(value: bool) -> Result<Self> { Ok(value) } fn from_string(value: &str) -> Result<Self> { value.parse().map_err(|_| Error::unknown_value(value)) } } impl FromMeta for AtomicBool { fn from_meta(mi: &Meta) -> Result<Self> { FromMeta::from_meta(mi) .map(AtomicBool::new) .map_err(|e| e.with_span(mi)) } } impl FromMeta for char { #[allow(clippy::wrong_self_convention)] // false positive fn from_char(value: char) -> Result<Self> { Ok(value) } fn from_string(s: &str) -> Result<Self> { let mut chars = s.chars(); let char1 = chars.next(); let char2 = chars.next(); if let (Some(char), None) = (char1, char2) { Ok(char) } else { Err(Error::unexpected_type("string")) } } } impl FromMeta for String { fn from_string(s: &str) -> Result<Self> { Ok(s.to_string()) } } impl FromMeta for std::path::PathBuf { fn from_string(s: &str) -> Result<Self> { Ok(s.into()) } } /// Generate an impl of `FromMeta` that will accept strings which parse to numbers or /// integer literals. macro_rules! from_meta_num { ($ty:path) => { impl FromMeta for $ty { fn from_string(s: &str) -> Result<Self> { s.parse().map_err(|_| Error::unknown_value(s)) } fn from_value(value: &Lit) -> Result<Self> { (match *value { Lit::Str(ref s) => Self::from_string(&s.value()), Lit::Int(ref s) => s.base10_parse::<$ty>().map_err(Error::from), _ => Err(Error::unexpected_lit_type(value)), }) .map_err(|e| e.with_span(value)) } } }; } from_meta_num!(u8); from_meta_num!(u16); from_meta_num!(u32); from_meta_num!(u64); from_meta_num!(u128); from_meta_num!(usize); from_meta_num!(i8); from_meta_num!(i16); from_meta_num!(i32); from_meta_num!(i64); from_meta_num!(i128); from_meta_num!(isize); from_meta_num!(num::NonZeroU8); from_meta_num!(num::NonZeroU16); from_meta_num!(num::NonZeroU32); from_meta_num!(num::NonZeroU64); from_meta_num!(num::NonZeroU128); from_meta_num!(num::NonZeroUsize); from_meta_num!(num::NonZeroI8); from_meta_num!(num::NonZeroI16); from_meta_num!(num::NonZeroI32); from_meta_num!(num::NonZeroI64); from_meta_num!(num::NonZeroI128); from_meta_num!(num::NonZeroIsize); /// Generate an impl of `FromMeta` that will accept strings which parse to floats or /// float literals. macro_rules! from_meta_float { ($ty:ident) => { impl FromMeta for $ty { fn from_string(s: &str) -> Result<Self> { s.parse().map_err(|_| Error::unknown_value(s)) } fn from_value(value: &Lit) -> Result<Self> { (match *value { Lit::Str(ref s) => Self::from_string(&s.value()), Lit::Float(ref s) => s.base10_parse::<$ty>().map_err(Error::from), _ => Err(Error::unexpected_lit_type(value)), }) .map_err(|e| e.with_span(value)) } } }; } from_meta_float!(f32); from_meta_float!(f64); /// Parsing support for punctuated. This attempts to preserve span information /// when available, but also supports parsing strings with the call site as the /// emitted span. impl<T: syn::parse::Parse, P: syn::parse::Parse> FromMeta for syn::punctuated::Punctuate fn from_value(value: &Lit) -> Result<Self> { if let Lit::Str(ref ident) = *value { ident .parse_with(syn::punctuated::Punctuated::parse_terminated) .map_err(|_| Error::unknown_lit_str_value(ident)) } else { Err(Error::unexpected_lit_type(value)) } } } /// Support for arbitrary expressions as values in a meta item. /// /// For backwards-compatibility to versions of `darling` based on `syn` 1, /// string literals will be "unwrapped" and their contents will be parsed /// as an expression. /// /// See [`util::parse_expr`](crate::util::parse_expr) for functions to provide /// alternate parsing modes for this type. impl FromMeta for syn::Expr { fn from_expr(expr: &Expr) -> Result<Self> { match expr { Expr::Lit(syn::ExprLit { lit: lit @ syn::Lit::Str(_), .. }) => Self::from_value(lit), Expr::Group(group) => Self::from_expr(&group.expr), // see FromMeta::from_expr _ => Ok(expr.clone()), } } fn from_string(value: &str) -> Result<Self> { syn::parse_str(value).map_err(|_| Error::unknown_value(value)) } fn from_value(value: &::syn::Lit) -> Result<Self> { if let ::syn::Lit::Str(ref v) = *value { v.parse::<syn::Expr>() .map_err(|_| Error::unknown_lit_str_value(v)) } else { Err(Error::unexpected_lit_type(value)) } } } /// Parser for paths that supports both quote-wrapped and bare values. impl FromMeta for syn::Path { fn from_string(value: &str) -> Result<Self> { syn::parse_str(value).map_err(|_| Error::unknown_value(value)) } fn from_value(value: &::syn::Lit) -> Result<Self> { if let ::syn::Lit::Str(ref v) = *value { v.parse().map_err(|_| Error::unknown_lit_str_value(v)) } else { Err(Error::unexpected_lit_type(value)) } } fn from_expr(expr: &Expr) -> Result<Self> { match expr { Expr::Lit(lit) => Self::from_value(&lit.lit), Expr::Path(path) => Ok(path.path.clone()), Expr::Group(group) => Self::from_expr(&group.expr), // see FromMeta::from_expr _ => Err(Error::unexpected_expr_type(expr)), } } } impl FromMeta for syn::Ident { fn from_string(value: &str) -> Result<Self> { syn::parse_str(value).map_err(|_| Error::unknown_value(value)) } fn from_value(value: &syn::Lit) -> Result<Self> { if let syn::Lit::Str(ref v) = *value { v.parse().map_err(|_| Error::unknown_lit_str_value(v)) } else { Err(Error::unexpected_lit_type(value)) } } fn from_expr(expr: &Expr) -> Result<Self> { match expr { Expr::Lit(lit) => Self::from_value(&lit.lit), // All idents are paths, but not all paths are idents - // the get_ident() method does additional validation to // make sure the path is actually an ident. Expr::Path(path) => match path.path.get_ident() { Some(ident) => Ok(ident.clone()), None => Err(Error::unexpected_expr_type(expr)), }, Expr::Group(group) => Self::from_expr(&group.expr), // see FromMeta::from_expr _ => Err(Error::unexpected_expr_type(expr)), } } } /// Adapter for various expression types. /// /// Prior to syn 2.0, darling supported arbitrary expressions as long as they /// were wrapped in quotation marks. This was helpful for people writing /// libraries that needed expressions, but it now creates an ambiguity when /// parsing a meta item. /// /// To address this, the macro supports both formats; if it cannot parse the /// item as an expression of the right type and the passed-in expression is /// a string literal, it will fall back to parsing the string contents. macro_rules! from_syn_expr_type { ($ty:path, $variant:ident) => { impl FromMeta for $ty { fn from_expr(expr: &syn::Expr) -> Result<Self> { match expr { syn::Expr::$variant(body) => Ok(body.clone()), syn::Expr::Lit(expr_lit) => Self::from_value(&expr_lit.lit), syn::Expr::Group(group) => Self::from_expr(&group.expr), // see FromMeta::from_expr _ => Err(Error::unexpected_expr_type(expr)), } } fn from_value(value: &::syn::Lit) -> Result<Self> { if let syn::Lit::Str(body) = &value { body.parse::<$ty>() .map_err(|_| Error::unknown_lit_str_value(body)) } else { Err(Error::unexpected_lit_type(value)) } } } }; } from_syn_expr_type!(syn::ExprArray, Array); from_syn_expr_type!(syn::ExprPath, Path); /// Adapter from `syn::parse::Parse` to `FromMeta` for items that cannot /// be expressed in a [`syn::MetaNameValue`]. /// /// This cannot be a blanket impl, due to the `syn::Lit` family's need to handle non-string valu /// Therefore, we use a macro and a lot of impls. macro_rules! from_syn_parse { ($ty:path) => { impl FromMeta for $ty { fn from_string(value: &str) -> Result<Self> { syn::parse_str(value).map_err(|_| Error::unknown_value(value)) } fn from_value(value: &::syn::Lit) -> Result<Self> { if let ::syn::Lit::Str(ref v) = *value { v.parse::<$ty>() .map_err(|_| Error::unknown_lit_str_value(v)) } else { Err(Error::unexpected_lit_type(value)) } } } }; } from_syn_parse!(syn::Type); from_syn_parse!(syn::TypeArray); from_syn_parse!(syn::TypeBareFn); from_syn_parse!(syn::TypeGroup); from_syn_parse!(syn::TypeImplTrait); from_syn_parse!(syn::TypeInfer); from_syn_parse!(syn::TypeMacro); from_syn_parse!(syn::TypeNever); from_syn_parse!(syn::TypeParam); from_syn_parse!(syn::TypeParen); from_syn_parse!(syn::TypePath); from_syn_parse!(syn::TypePtr); from_syn_parse!(syn::TypeReference); from_syn_parse!(syn::TypeSlice); from_syn_parse!(syn::TypeTraitObject); from_syn_parse!(syn::TypeTuple); from_syn_parse!(syn::Visibility); from_syn_parse!(syn::WhereClause); macro_rules! from_numeric_array { ($ty:ident) => { /// Parsing an unsigned integer array, i.e. `example = "[1, 2, 3, 4]"`. impl FromMeta for Vec<$ty> { fn from_expr(expr: &syn::Expr) -> Result<Self> { match expr { syn::Expr::Array(expr_array) => expr_array .elems .iter() .map(|expr| { let unexpected = || { Error::custom("Expected array of unsigned integers").with_span(expr) }; match expr { Expr::Lit(lit) => $ty::from_value(&lit.lit), Expr::Group(group) => match &*group.expr { Expr::Lit(lit) => $ty::from_value(&lit.lit), _ => Err(unexpected()), }, _ => Err(unexpected()), } }) .collect::<Result<Vec<$ty>>>(), syn::Expr::Lit(expr_lit) => Self::from_value(&expr_lit.lit), syn::Expr::Group(group) => Self::from_expr(&group.expr), // see FromMeta::from_expr _ => Err(Error::unexpected_expr_type(expr)), } } fn from_value(value: &Lit) -> Result<Self> { let expr_array = syn::ExprArray::from_value(value)?; Self::from_expr(&syn::Expr::Array(expr_array)) } } }; } from_numeric_array!(u8); from_numeric_array!(u16); from_numeric_array!(u32); from_numeric_array!(u64); from_numeric_array!(usize); impl FromMeta for syn::Lit { fn from_value(value: &Lit) -> Result<Self> { Ok(value.clone()) } } macro_rules! from_meta_lit { ($impl_ty:path, $lit_variant:path) => { impl FromMeta for $impl_ty { fn from_value(value: &Lit) -> Result<Self> { if let $lit_variant(ref value) = *value { Ok(value.clone()) } else { Err(Error::unexpected_lit_type(value)) } } } impl FromMeta for Vec<$impl_ty> { fn from_list(items: &[NestedMeta]) -> Result<Self> { items .iter() .map(<$impl_ty as FromMeta>::from_nested_meta) .collect() } fn from_value(value: &syn::Lit) -> Result<Self> { let expr_array = syn::ExprArray::from_value(value)?; Self::from_expr(&syn::Expr::Array(expr_array)) } fn from_expr(expr: &syn::Expr) -> Result<Self> { match expr { syn::Expr::Array(expr_array) => expr_array .elems .iter() .map(<$impl_ty as FromMeta>::from_expr) .collect::<Result<Vec<_>>>(), syn::Expr::Lit(expr_lit) => Self::from_value(&expr_lit.lit), syn::Expr::Group(g) => Self::from_expr(&g.expr), _ => Err(Error::unexpected_expr_type(expr)), } } } }; } from_meta_lit!(syn::LitInt, Lit::Int); from_meta_lit!(syn::LitFloat, Lit::Float); from_meta_lit!(syn::LitStr, Lit::Str); from_meta_lit!(syn::LitByte, Lit::Byte); from_meta_lit!(syn::LitByteStr, Lit::ByteStr); from_meta_lit!(syn::LitChar, Lit::Char); from_meta_lit!(syn::LitBool, Lit::Bool); from_meta_lit!(proc_macro2::Literal, Lit::Verbatim); impl FromMeta for syn::Meta { fn from_meta(value: &syn::Meta) -> Result<Self> { Ok(value.clone()) } } impl FromMeta for Vec<syn::WherePredicate> { fn from_string(value: &str) -> Result<Self> { syn::WhereClause::from_string(&format!("where {}", value)) .map(|c| c.predicates.into_iter().collect()) } fn from_value(value: &Lit) -> Result<Self> { if let syn::Lit::Str(s) = value { syn::WhereClause::from_value(&syn::Lit::Str(syn::LitStr::new( &format!("where {}", s.value()), value.span(), ))) .map(|c| c.predicates.into_iter().collect()) } else { Err(Error::unexpected_lit_type(value)) } } } impl FromMeta for ident_case::RenameRule { fn from_string(value: &str) -> Result<Self> { value.parse().map_err(|_| Error::unknown_value(value)) } } impl<T: FromMeta> FromMeta for Option<T> { fn from_none() -> Option<Self> { Some(None) } fn from_meta(item: &Meta) -> Result<Self> { FromMeta::from_meta(item).map(Some) } } impl<T: FromMeta> FromMeta for Result<T> { fn from_none() -> Option<Self> { T::from_none().map(Ok) } // `#[darling(flatten)]` forwards directly to this method, so it's // necessary to declare it to avoid getting an unsupported format // error if it's invoked directly. fn from_list(items: &[NestedMeta]) -> Result<Self> { Ok(FromMeta::from_list(items)) } fn from_meta(item: &Meta) -> Result<Self> { Ok(FromMeta::from_meta(item)) } } /// Create an impl that forwards to an inner type `T` for parsing. macro_rules! smart_pointer_t { ($ty:path, $map_fn:path) => { impl<T: FromMeta> FromMeta for $ty { fn from_none() -> Option<Self> { T::from_none().map($map_fn) } // `#[darling(flatten)]` forwards directly to this method, so it's // necessary to declare it to avoid getting an unsupported format // error if it's invoked directly. fn from_list(items: &[NestedMeta]) -> Result<Self> { FromMeta::from_list(items).map($map_fn) } fn from_meta(item: &Meta) -> Result<Self> { FromMeta::from_meta(item).map($map_fn) } } }; } smart_pointer_t!(Box<T>, Box::new); smart_pointer_t!(Rc<T>, Rc::new); smart_pointer_t!(Arc<T>, Arc::new); smart_pointer_t!(RefCell<T>, RefCell::new); /// Parses the meta-item, and in case of error preserves a copy of the input for /// later analysis. impl<T: FromMeta> FromMeta for ::std::result::Result<T, Meta> { fn from_meta(item: &Meta) -> Result<Self> { T::from_meta(item) .map(Ok) .or_else(|_| Ok(Err(item.clone()))) } } /// Trait to convert from a path into an owned key for a map. trait KeyFromPath: Sized { fn from_path(path: &syn::Path) -> Result<Self>; fn to_display(&self) -> Cow<'_, str>; } impl KeyFromPath for String { fn from_path(path: &syn::Path) -> Result<Self> { Ok(path_to_string(path)) } fn to_display(&self) -> Cow<'_, str> { Cow::Borrowed(self) } } impl KeyFromPath for syn::Path { fn from_path(path: &syn::Path) -> Result<Self> { Ok(path.clone()) } fn to_display(&self) -> Cow<'_, str> { Cow::Owned(path_to_string(self)) } } impl KeyFromPath for syn::Ident { fn from_path(path: &syn::Path) -> Result<Self> { if path.segments.len() == 1 && path.leading_colon.is_none() && path.segments[0].arguments.is_empty() { Ok(path.segments[0].ident.clone()) } else { Err(Error::custom("Key must be an identifier").with_span(path)) } } fn to_display(&self) -> Cow<'_, str> { Cow::Owned(self.to_string()) } } macro_rules! hash_map { ($key:ty) => { impl<V: FromMeta, S: BuildHasher + Default> FromMeta for HashMap<$key, V, S> { fn from_list(nested: &[NestedMeta]) -> Result<Self> { // Convert the nested meta items into a sequence of (path, value result) result tuples. // An outer Err means no (key, value) structured could be found, while an Err in the // second position of the tuple means that value was rejected by FromMeta. // // We defer key conversion into $key so that we don't lose span information in the case // of String keys; we'll need it for good duplicate key errors later. let pairs = nested .iter() .map(|item| -> Result<(&syn::Path, Result<V>)> { match *item { NestedMeta::Meta(ref inner) => { let path = inner.path(); Ok(( path, FromMeta::from_meta(inner).map_err(|e| e.at_path(&path)), )) } NestedMeta::Lit(_) => Err(Error::unsupported_format("expression")), } }); let mut errors = Error::accumulator(); // We need to track seen keys separately from the final map, since a seen key with an // Err value won't go into the final map but should trigger a duplicate field error. // // This is a set of $key rather than Path to avoid the possibility that a key type // parses two paths of different values to the same key value. let mut seen_keys = HashSet::with_capacity(nested.len()); // The map to return in the Ok case. Its size will always be exactly nested.len(), // since otherwise ≥1 field had a problem and the entire map is dropped immediately // when the function returns `Err`. let mut map = HashMap::with_capacity_and_hasher(nested.len(), Default::default()); for item in pairs { if let Some((path, value)) = errors.handle(item) { let key: $key = match KeyFromPath::from_path(path) { Ok(k) => k, Err(e) => { errors.push(e); // Surface value errors even under invalid keys errors.handle(value); continue; } }; let already_seen = seen_keys.contains(&key); if already_seen { errors.push(Error::duplicate_field(&key.to_display()).with_span(path)); } match value { Ok(_) if already_seen => {} Ok(val) => { map.insert(key.clone(), val); } Err(e) => { errors.push(e); } } seen_keys.insert(key); } } errors.finish_with(map) } } }; } // This is done as a macro rather than a blanket impl to avoid breaking backwards compatibility // with 0.12.x, while still sharing the same impl. hash_map!(String); hash_map!(syn::Ident); hash_map!(syn::Path); /// Tests for `FromMeta` implementations. Wherever the word `ignore` appears in test input, /// it should not be considered by the parsing. #[cfg(test)] mod tests { use std::num::{NonZeroU32, NonZeroU64}; use proc_macro2::TokenStream; use quote::quote; use syn::parse_quote; use crate::{Error, FromMeta, Result}; /// parse a string as a syn::Meta instance. fn pm(tokens: TokenStream) -> ::std::result::Result<syn::Meta, String> { let attribute: syn::Attribute = parse_quote!(#[#tokens]); Ok(attribute.meta) } #[track_caller] fn fm<T: FromMeta>(tokens: TokenStream) -> T { FromMeta::from_meta(&pm(tokens).expect("Tests should pass well-formed input")) .expect("Tests should pass valid input") } #[test] fn unit_succeeds() { fm::<()>(quote!(ignore)); } #[test] #[allow(clippy::bool_assert_comparison)] fn bool_succeeds() { // word format assert_eq!(fm::<bool>(quote!(ignore)), true); // bool literal assert_eq!(fm::<bool>(quote!(ignore = true)), true); assert_eq!(fm::<bool>(quote!(ignore = false)), false); // string literals assert_eq!(fm::<bool>(quote!(ignore = "true")), true); assert_eq!(fm::<bool>(quote!(ignore = "false")), false); } #[test] fn char_succeeds() { // char literal assert_eq!(fm::<char>(quote!(ignore = '��')), '��'); // string literal assert_eq!(fm::<char>(quote!(ignore = "��")), '��'); } #[test] fn string_succeeds() { // cooked form assert_eq!(&fm::<String>(quote!(ignore = "world")), "world"); // raw form assert_eq!(&fm::<String>(quote!(ignore = r#"world"#)), "world"); } #[test] fn pathbuf_succeeds() { assert_eq!( fm::<std::path::PathBuf>(quote!(ignore = r#"C:\"#)), std::path::PathBuf::from(r#"C:\"#) ); } #[test] #[allow(clippy::float_cmp)] // we want exact equality fn number_succeeds() { assert_eq!(fm::<u8>(quote!(ignore = "2")), 2u8); assert_eq!(fm::<i16>(quote!(ignore = "-25")), -25i16); assert_eq!(fm::<f64>(quote!(ignore = "1.4e10")), 1.4e10); } #[should_panic(expected = "UnknownValue(\"0\")")] #[test] fn nonzero_number_fails() { fm::<NonZeroU64>(quote!(ignore = "0")); } #[test] fn nonzero_number_succeeds() { assert_eq!( fm::<NonZeroU32>(quote!(ignore = "2")), NonZeroU32::new(2).unwrap() ); } #[test] fn int_without_quotes() { assert_eq!(fm::<u8>(quote!(ignore = 2)), 2u8); assert_eq!(fm::<u16>(quote!(ignore = 255)), 255u16); assert_eq!(fm::<u32>(quote!(ignore = 5000)), 5000u32); // Check that we aren't tripped up by incorrect suffixes assert_eq!(fm::<u32>(quote!(ignore = 5000i32)), 5000u32); } #[test] fn negative_int_without_quotes() { assert_eq!(fm::<i8>(quote!(ignore = -2)), -2i8); assert_eq!(fm::<i32>(quote!(ignore = -255)), -255i32); } #[test] #[allow(clippy::float_cmp)] // we want exact equality fn float_without_quotes() { assert_eq!(fm::<f32>(quote!(ignore = 2.)), 2.0f32); assert_eq!(fm::<f32>(quote!(ignore = 2.0)), 2.0f32); assert_eq!(fm::<f64>(quote!(ignore = 1.4e10)), 1.4e10f64); } #[test] fn too_large_int_produces_error() { assert!(fm::<Result<u8>>(quote!(ignore = 2000)).is_err()); } #[test] fn meta_succeeds() { use syn::Meta; assert_eq!( fm::<Meta>(quote!(hello(world, today))), pm(quote!(hello(world, today))).unwrap() ); } #[test] fn hash_map_succeeds() { use std::collections::HashMap; let comparison = { let mut c = HashMap::new(); c.insert("hello".to_string(), true); c.insert("world".to_string(), false); c.insert("there".to_string(), true); c }; assert_eq!( fm::<HashMap<String, bool>>(quote!(ignore(hello, world = false, there = "true"))), comparison ); } /// Check that a `HashMap` cannot have duplicate keys, and that the generated error /// is assigned a span to correctly target the diagnostic message. #[test] fn hash_map_duplicate() { use std::collections::HashMap; let err: Result<HashMap<String, bool>> = FromMeta::from_meta(&pm(quote!(ignore(hello, hello = false))).unwrap()); let err = err.expect_err("Duplicate keys in HashMap should error"); assert!(err.has_span()); assert_eq!(err.to_string(), Error::duplicate_field("hello").to_string()); } #[test] fn hash_map_multiple_errors() { use std::collections::HashMap; let err = HashMap::<String, bool>::from_meta( &pm(quote!(ignore(hello, hello = 3, hello = false))).unwrap(), ) .expect_err("Duplicates and bad values should error"); assert_eq!(err.len(), 3); let errors = err.into_iter().collect::<Vec<_>>(); assert!(errors[0].has_span()); assert!(errors[1].has_span()); assert!(errors[2].has_span()); } #[test] fn hash_map_ident_succeeds() { use std::collections::HashMap; use syn::parse_quote; let comparison = { let mut c = HashMap::<syn::Ident, bool>::new(); c.insert(parse_quote!(first), true); c.insert(parse_quote!(second), false); c }; assert_eq!( fm::<HashMap<syn::Ident, bool>>(quote!(ignore(first, second = false))), comparison ); } #[test] fn hash_map_ident_rejects_non_idents() { use std::collections::HashMap; let err: Result<HashMap<syn::Ident, bool>> = FromMeta::from_meta(&pm(quote!(ignore(first, the::second))).unwrap()); err.unwrap_err(); } #[test] fn hash_map_path_succeeds() { use std::collections::HashMap; use syn::parse_quote; let comparison = { let mut c = HashMap::<syn::Path, bool>::new(); c.insert(parse_quote!(first), true); c.insert(parse_quote!(the::second), false); c }; assert_eq!( fm::<HashMap<syn::Path, bool>>(quote!(ignore(first, the::second = false))), comparison ); } /// Tests that fallible parsing will always produce an outer `Ok` (from `fm`), /// and will accurately preserve the inner contents. #[test] fn darling_result_succeeds() { fm::<Result<()>>(quote!(ignore)).unwrap(); fm::<Result<()>>(quote!(ignore(world))).unwrap_err(); } /// Test punctuated #[test] fn test_punctuated() { fm::<syn::punctuated::Punctuated<syn::FnArg, syn::token::Comma>>(quote!( ignore = "a: u8, b: Type" )); fm::<syn::punctuated::Punctuated<syn::Expr, syn::token::Comma>>(quote!(ignore = "a, b, c" } #[test] fn test_expr_array() { fm::<syn::ExprArray>(quote!(ignore = "[0x1, 0x2]")); fm::<syn::ExprArray>(quote!(ignore = "[\"Hello World\", \"Test Array\"]")); } #[test] fn test_expr() { fm::<syn::Expr>(quote!(ignore = "x + y")); fm::<syn::Expr>(quote!(ignore = "an_object.method_call()")); fm::<syn::Expr>(quote!(ignore = "{ a_statement(); in_a_block }")); } #[test] fn test_expr_without_quotes() { fm::<syn::Expr>(quote!(ignore = x + y)); fm::<syn::Expr>(quote!(ignore = an_object.method_call())); fm::<syn::Expr>(quote!( ignore = { a_statement(); in_a_block } )); } #[test] fn test_expr_path() { fm::<syn::ExprPath>(quote!(ignore = "std::mem::replace")); fm::<syn::ExprPath>(quote!(ignore = "x")); fm::<syn::ExprPath>(quote!(ignore = "example::<Test>")); } #[test] fn test_expr_path_without_quotes() { fm::<syn::ExprPath>(quote!(ignore = std::mem::replace)); fm::<syn::ExprPath>(quote!(ignore = x)); fm::<syn::ExprPath>(quote!(ignore = example::<Test>)); } #[test] fn test_path_without_quotes() { fm::<syn::Path>(quote!(ignore = std::mem::replace)); fm::<syn::Path>(quote!(ignore = x)); fm::<syn::Path>(quote!(ignore = example::<Test>)); } #[test] fn test_number_array() { assert_eq!(fm::<Vec<u8>>(quote!(ignore = [16, 0xff])), vec![0x10, 0xff]); assert_eq!( fm::<Vec<u16>>(quote!(ignore = "[32, 0xffff]")), vec![0x20, 0xffff] ); assert_eq!( fm::<Vec<u32>>(quote!(ignore = "[48, 0xffffffff]")), vec![0x30, 0xffffffff] ); assert_eq!( fm::<Vec<u64>>(quote!(ignore = "[64, 0xffffffffffffffff]")), vec![0x40, 0xffffffffffffffff] ); assert_eq!( fm::<Vec<usize>>(quote!(ignore = "[80, 0xffffffff]")), vec![0x50, 0xffffffff] ); } #[test] fn test_lit_array() { fm::<Vec<syn::LitStr>>(quote!(ignore = "[\"Hello World\", \"Test Array\"]")); fm::<Vec<syn::LitStr>>(quote!(ignore = ["Hello World", "Test Array"])); fm::<Vec<syn::LitChar>>(quote!(ignore = "['a', 'b', 'c']")); fm::<Vec<syn::LitBool>>(quote!(ignore = "[true]")); fm::<Vec<syn::LitStr>>(quote!(ignore = "[]")); fm::<Vec<syn::LitStr>>(quote!(ignore = [])); fm::<Vec<syn::LitBool>>(quote!(ignore = [true, false])); } } [ Dauer der Verarbeitung: 0.37 Sekunden (vorverarbeitet) ] |
2026-04-02