mod.rs source code [crates/darling_core/src/error/mod.rs]

1	//! The `darling::Error` type, the multiple error `Accumulator`, and their internals.
2	//!
3	//! Error handling is one of the core values of `darling`; creating great errors is hard and
4	//! never the reason that a proc-macro author started writing their crate. As a result, the
5	//! `Error` type in `darling` tries to make adding span information, suggestions, and other
6	//! help content easy when manually implementing `darling` traits, and automatic when deriving
7	//! them.
8
9	use proc_macro2::{Span, TokenStream};
10	use std::error::Error as StdError;
11	use std::fmt;
12	use std::iter::{self, Iterator};
13	use std::string::ToString;
14	use std::vec;
15	use syn::spanned::Spanned;
16	use syn::{Expr, Lit, LitStr, Path};
17
18	#[cfg(feature = "diagnostics")]
19	mod child;
20	mod kind;
21
22	use crate::util::path_to_string;
23
24	use self::kind::{ErrorKind, ErrorUnknownField};
25
26	/// An alias of `Result` specific to attribute parsing.
27	pub type Result<T> = ::std::result::Result<T, Error>;
28
29	/// An error encountered during attribute parsing.
30	///
31	/// Given that most errors darling encounters represent code bugs in dependent crates,
32	/// the internal structure of the error is deliberately opaque.
33	///
34	/// # Usage
35	/// Proc-macro expansion happens very infrequently compared to runtime tasks such as
36	/// deserialization, and it happens in the context of an expensive compilation taks.
37	/// For that reason, darling prefers not to fail on the first error it encounters, instead
38	/// doing as much work as it can, accumulating errors into a single report.
39	///
40	/// As a result, `darling::Error` is more of guaranteed-non-empty error collection
41	/// than a single problem. These errors also have some notion of hierarchy, stemming from
42	/// the hierarchical nature of darling's input.
43	///
44	/// These characteristics make for great experiences when using darling-powered crates,
45	/// provided crates using darling adhere to some best practices:
46	///
47	/// 1. Do not attempt to simplify a `darling::Error` into some other error type, such as
48	/// `syn::Error`. To surface compile errors, instead use `darling::Error::write_errors`.
49	/// This preserves all span information, suggestions, etc. Wrapping a `darling::Error` in
50	/// a custom error enum works as-expected and does not force any loss of fidelity.
51	/// 2. Do not use early return (e.g. the `?` operator) for custom validations. Instead,
52	/// create an [`error::Accumulator`](Accumulator) to collect errors as they are encountered. Then use
53	/// [`Accumulator::finish`] to return your validated result; it will give `Ok` if and only if
54	/// no errors were encountered. This can create very complex custom validation functions;
55	/// in those cases, split independent "validation chains" out into their own functions to
56	/// keep the main validator manageable.
57	/// 3. Use `darling::Error::custom` to create additional errors as-needed, then call `with_span`
58	/// to ensure those errors appear in the right place. Use `darling::util::SpannedValue` to keep
59	/// span information around on parsed fields so that custom diagnostics can point to the correct
60	/// parts of the input AST.
61	#[derive(Debug, Clone)]
62	pub struct Error {
63	kind: ErrorKind,
64	locations: Vec<String>,
65	/// The span to highlight in the emitted diagnostic.
66	span: Option<Span>,
67	/// Additional diagnostic messages to show with the error.
68	#[cfg(feature = "diagnostics")]
69	children: Vec<child::ChildDiagnostic>,
70	}
71
72	/// Error creation functions
73	impl Error {
74	pub(in crate::error) fn new(kind: ErrorKind) -> Self {
75	Error {
76	kind,
77	locations: Vec::new(),
78	span: None,
79	#[cfg(feature = "diagnostics")]
80	children: vec![],
81	}
82	}
83
84	/// Creates a new error with a custom message.
85	pub fn custom<T: fmt::Display>(msg: T) -> Self {
86	Error::new(ErrorKind::Custom(msg.to_string()))
87	}
88
89	/// Creates a new error for a field that appears twice in the input.
90	pub fn duplicate_field(name: &str) -> Self {
91	Error::new(ErrorKind::DuplicateField(name.into()))
92	}
93
94	/// Creates a new error for a field that appears twice in the input. Helper to avoid repeating
95	/// the syn::Path to String conversion.
96	pub fn duplicate_field_path(path: &Path) -> Self {
97	Error::duplicate_field(&path_to_string(path))
98	}
99
100	/// Creates a new error for a non-optional field that does not appear in the input.
101	pub fn missing_field(name: &str) -> Self {
102	Error::new(ErrorKind::MissingField(name.into()))
103	}
104
105	/// Creates a new error for a field name that appears in the input but does not correspond
106	/// to a known field.
107	pub fn unknown_field(name: &str) -> Self {
108	Error::new(ErrorKind::UnknownField(name.into()))
109	}
110
111	/// Creates a new error for a field name that appears in the input but does not correspond
112	/// to a known field. Helper to avoid repeating the syn::Path to String conversion.
113	pub fn unknown_field_path(path: &Path) -> Self {
114	Error::unknown_field(&path_to_string(path))
115	}
116
117	/// Creates a new error for a field name that appears in the input but does not correspond to
118	/// a known attribute. The second argument is the list of known attributes; if a similar name
119	/// is found that will be shown in the emitted error message.
120	pub fn unknown_field_with_alts<'a, T, I>(field: &str, alternates: I) -> Self
121	where
122	T: AsRef<str> + 'a,
123	I: IntoIterator<Item = &'a T>,
124	{
125	Error::new(ErrorUnknownField::with_alts(field, alternates).into())
126	}
127
128	/// Creates a new error for a field name that appears in the input but does not correspond to
129	/// a known attribute. The second argument is the list of known attributes; if a similar name
130	/// is found that will be shown in the emitted error message.
131	pub fn unknown_field_path_with_alts<'a, T, I>(field: &Path, alternates: I) -> Self
132	where
133	T: AsRef<str> + 'a,
134	I: IntoIterator<Item = &'a T>,
135	{
136	Error::new(ErrorUnknownField::with_alts(&path_to_string(field), alternates).into())
137	}
138
139	/// Creates a new error for a struct or variant that does not adhere to the supported shape.
140	pub fn unsupported_shape(shape: &str) -> Self {
141	Error::new(ErrorKind::UnsupportedShape {
142	observed: shape.into(),
143	expected: None,
144	})
145	}
146
147	pub fn unsupported_shape_with_expected<T: fmt::Display>(shape: &str, expected: &T) -> Self {
148	Error::new(ErrorKind::UnsupportedShape {
149	observed: shape.into(),
150	expected: Some(expected.to_string()),
151	})
152	}
153
154	pub fn unsupported_format(format: &str) -> Self {
155	Error::new(ErrorKind::UnexpectedFormat(format.into()))
156	}
157
158	/// Creates a new error for a field which has an unexpected literal type.
159	pub fn unexpected_type(ty: &str) -> Self {
160	Error::new(ErrorKind::UnexpectedType(ty.into()))
161	}
162
163	pub fn unexpected_expr_type(expr: &Expr) -> Self {
164	Error::unexpected_type(match *expr {
165	Expr::Array(_) => "array",
166	Expr::Assign(_) => "assign",
167	Expr::Async(_) => "async",
168	Expr::Await(_) => "await",
169	Expr::Binary(_) => "binary",
170	Expr::Block(_) => "block",
171	Expr::Break(_) => "break",
172	Expr::Call(_) => "call",
173	Expr::Cast(_) => "cast",
174	Expr::Closure(_) => "closure",
175	Expr::Const(_) => "const",
176	Expr::Continue(_) => "continue",
177	Expr::Field(_) => "field",
178	Expr::ForLoop(_) => "for_loop",
179	Expr::Group(_) => "group",
180	Expr::If(_) => "if",
181	Expr::Index(_) => "index",
182	Expr::Infer(_) => "infer",
183	Expr::Let(_) => "let",
184	Expr::Lit(_) => "lit",
185	Expr::Loop(_) => "loop",
186	Expr::Macro(_) => "macro",
187	Expr::Match(_) => "match",
188	Expr::MethodCall(_) => "method_call",
189	Expr::Paren(_) => "paren",
190	Expr::Path(_) => "path",
191	Expr::Range(_) => "range",
192	Expr::Reference(_) => "reference",
193	Expr::Repeat(_) => "repeat",
194	Expr::Return(_) => "return",
195	Expr::Struct(_) => "struct",
196	Expr::Try(_) => "try",
197	Expr::TryBlock(_) => "try_block",
198	Expr::Tuple(_) => "tuple",
199	Expr::Unary(_) => "unary",
200	Expr::Unsafe(_) => "unsafe",
201	Expr::Verbatim(_) => "verbatim",
202	Expr::While(_) => "while",
203	Expr::Yield(_) => "yield",
204	// non-exhaustive enum
205	_ => "unknown",
206	})
207	.with_span(expr)
208	}
209
210	/// Creates a new error for a field which has an unexpected literal type. This will automatically
211	/// extract the literal type name from the passed-in `Lit` and set the span to encompass only the
212	/// literal value.
213	///
214	/// # Usage
215	/// This is most frequently used in overrides of the `FromMeta::from_value` method.
216	///
217	/// ```rust
218	/// # // pretend darling_core is darling so the doc example looks correct.
219	/// # extern crate darling_core as darling;
220	/// # extern crate syn;
221	///
222	/// use darling::{FromMeta, Error, Result};
223	/// use syn::{Lit, LitStr};
224	///
225	/// pub struct Foo(String);
226	///
227	/// impl FromMeta for Foo {
228	/// fn from_value(value: &Lit) -> Result<Self> {
229	/// if let Lit::Str(ref lit_str) = *value {
230	/// Ok(Foo(lit_str.value()))
231	/// } else {
232	/// Err(Error::unexpected_lit_type(value))
233	/// }
234	/// }
235	/// }
236	///
237	/// # fn main() {}
238	/// ```
239	pub fn unexpected_lit_type(lit: &Lit) -> Self {
240	Error::unexpected_type(match *lit {
241	Lit::Str(_) => "string",
242	Lit::ByteStr(_) => "byte string",
243	Lit::Byte(_) => "byte",
244	Lit::Char(_) => "char",
245	Lit::Int(_) => "int",
246	Lit::Float(_) => "float",
247	Lit::Bool(_) => "bool",
248	Lit::Verbatim(_) => "verbatim",
249	// non-exhaustive enum
250	_ => "unknown",
251	})
252	.with_span(lit)
253	}
254
255	/// Creates a new error for a value which doesn't match a set of expected literals.
256	pub fn unknown_value(value: &str) -> Self {
257	Error::new(ErrorKind::UnknownValue(value.into()))
258	}
259
260	/// Creates a new error for a list which did not get enough items to proceed.
261	pub fn too_few_items(min: usize) -> Self {
262	Error::new(ErrorKind::TooFewItems(min))
263	}
264
265	/// Creates a new error when a list got more items than it supports. The `max` argument
266	/// is the largest number of items the receiver could accept.
267	pub fn too_many_items(max: usize) -> Self {
268	Error::new(ErrorKind::TooManyItems(max))
269	}
270
271	/// Bundle a set of multiple errors into a single `Error` instance.
272	///
273	/// Usually it will be more convenient to use an [`error::Accumulator`](Accumulator).
274	///
275	/// # Panics
276	/// This function will panic if `errors.is_empty() == true`.
277	pub fn multiple(mut errors: Vec<Error>) -> Self {
278	match errors.len() {
279	`1` => errors
280	.pop()
281	.expect("Error array of length 1 has a first item"),
282	`0` => panic!("Can't deal with 0 errors"),
283	_ => Error::new(ErrorKind::Multiple(errors)),
284	}
285	}
286
287	/// Creates an error collector, for aggregating multiple errors
288	///
289	/// See [`Accumulator`] for details.
290	pub fn accumulator() -> Accumulator {
291	Default::default()
292	}
293	}
294
295	impl Error {
296	/// Create a new error about a literal string that doesn't match a set of known
297	/// or permissible values. This function can be made public if the API proves useful
298	/// beyond impls for `syn` types.
299	pub(crate) fn unknown_lit_str_value(value: &LitStr) -> Self {
300	Error::unknown_value(&value.value()).with_span(node:value)
301	}
302	}
303
304	/// Error instance methods
305	#[allow(clippy::len_without_is_empty)] // Error can never be empty
306	impl Error {
307	/// Check if this error is associated with a span in the token stream.
308	pub fn has_span(&self) -> bool {
309	self.span.is_some()
310	}
311
312	/// Tie a span to the error if none is already present. This is used in `darling::FromMeta`
313	/// and other traits to attach errors to the most specific possible location in the input
314	/// source code.
315	///
316	/// All `darling`-built impls, either from the crate or from the proc macro, will call this
317	/// when appropriate during parsing, so it should not be necessary to call this unless you have
318	/// overridden:
319	///
320	/// `FromMeta::from_meta`*
321	/// `FromMeta::from_nested_meta`*
322	/// `FromMeta::from_value`*
323	pub fn with_span<T: Spanned>(mut self, node: &T) -> Self {
324	if !self.has_span() {
325	self.span = Some(node.span());
326	}
327
328	self
329	}
330
331	/// Get a span for the error.
332	///
333	/// # Return Value
334	/// This function will return [`Span::call_site()`](proc_macro2::Span) if [`Self::has_span`] is `false`.
335	/// To get the span only if one has been explicitly set for `self`, instead use [`Error::explicit_span`].
336	pub fn span(&self) -> Span {
337	self.span.unwrap_or_else(Span::call_site)
338	}
339
340	/// Get the span for `self`, if one has been set.
341	pub fn explicit_span(&self) -> Option<Span> {
342	self.span
343	}
344
345	/// Recursively converts a tree of errors to a flattened list.
346	///
347	/// # Child Diagnostics
348	/// If the `diagnostics` feature is enabled, any child diagnostics on `self`
349	/// will be cloned down to all the errors within `self`.
350	pub fn flatten(self) -> Self {
351	Error::multiple(self.into_vec())
352	}
353
354	fn into_vec(self) -> Vec<Self> {
355	if let ErrorKind::Multiple(errors) = self.kind {
356	let locations = self.locations;
357
358	#[cfg(feature = "diagnostics")]
359	let children = self.children;
360
361	errors
362	.into_iter()
363	.flat_map(\|error\| {
364	// This is mutated if the diagnostics feature is enabled
365	#[allow(unused_mut)]
366	let mut error = error.prepend_at(locations.clone());
367
368	// Any child diagnostics in `self` are cloned down to all the distinct
369	// errors contained in `self`.
370	#[cfg(feature = "diagnostics")]
371	error.children.extend(children.iter().cloned());
372
373	error.into_vec()
374	})
375	.collect()
376	} else {
377	vec![self]
378	}
379	}
380
381	/// Adds a location to the error, such as a field or variant.
382	/// Locations must be added in reverse order of specificity.
383	pub fn at<T: fmt::Display>(mut self, location: T) -> Self {
384	self.locations.insert(`0`, location.to_string());
385	self
386	}
387
388	/// Adds a location to the error, such as a field or variant.
389	/// Locations must be added in reverse order of specificity. This is a helper function to avoid
390	/// repeating path to string logic.
391	pub fn at_path(self, path: &Path) -> Self {
392	self.at(path_to_string(path))
393	}
394
395	/// Gets the number of individual errors in this error.
396	///
397	/// This function never returns `0`, as it's impossible to construct
398	/// a multi-error from an empty `Vec`.
399	pub fn len(&self) -> usize {
400	self.kind.len()
401	}
402
403	/// Consider additional field names as "did you mean" suggestions for
404	/// unknown field errors if and only if* the caller appears to be operating*
405	/// at error's origin (meaning no calls to [`Self::at`] have yet taken place).
406	///
407	/// # Usage
408	/// `flatten` fields in derived trait implementations rely on this method to offer correct
409	/// "did you mean" suggestions in errors.
410	///
411	/// Because the `flatten` field receives _all_ unknown fields, if a user mistypes a field name
412	/// that is present on the outer struct but not the flattened struct, they would get an incomplete
413	/// or inferior suggestion unless this method was invoked.
414	pub fn add_sibling_alts_for_unknown_field<'a, T, I>(mut self, alternates: I) -> Self
415	where
416	T: AsRef<str> + 'a,
417	I: IntoIterator<Item = &'a T>,
418	{
419	// The error may have bubbled up before this method was called,
420	// and in those cases adding alternates would be incorrect.
421	if !self.locations.is_empty() {
422	return self;
423	}
424
425	if let ErrorKind::UnknownField(unknown_field) = &mut self.kind {
426	unknown_field.add_alts(alternates);
427	} else if let ErrorKind::Multiple(errors) = self.kind {
428	let alternates = alternates.into_iter().collect::<Vec<_>>();
429	self.kind = ErrorKind::Multiple(
430	errors
431	.into_iter()
432	.map(\|err\| {
433	err.add_sibling_alts_for_unknown_field(
434	// This clone seems like it shouldn't be necessary.
435	// Attempting to borrow alternates here leads to the following compiler error:
436	//
437	// error: reached the recursion limit while instantiating `darling::Error::add_sibling_alts_for_unknown_field::<'_, &&&&..., ...>`
438	alternates.clone(),
439	)
440	})
441	.collect(),
442	)
443	}
444
445	self
446	}
447
448	/// Adds a location chain to the head of the error's existing locations.
449	fn prepend_at(mut self, mut locations: Vec<String>) -> Self {
450	if !locations.is_empty() {
451	locations.extend(self.locations);
452	self.locations = locations;
453	}
454
455	self
456	}
457
458	/// Gets the location slice.
459	#[cfg(test)]
460	pub(crate) fn location(&self) -> Vec<&str> {
461	self.locations.iter().map(\|i\| i.as_str()).collect()
462	}
463
464	/// Write this error and any children as compile errors into a `TokenStream` to
465	/// be returned by the proc-macro.
466	///
467	/// The behavior of this method will be slightly different if the `diagnostics` feature
468	/// is enabled: In that case, the diagnostics will be emitted immediately by this call,
469	/// and an empty `TokenStream` will be returned.
470	///
471	/// Return these tokens unmodified to avoid disturbing the attached span information.
472	///
473	/// # Usage
474	/// ```rust,ignore
475	/// // in your proc-macro function
476	/// let opts = match MyOptions::from_derive_input(&ast) {
477	/// Ok(val) => val,
478	/// Err(err) => {
479	/// return err.write_errors();
480	/// }
481	/// }
482	/// ```
483	pub fn write_errors(self) -> TokenStream {
484	#[cfg(feature = "diagnostics")]
485	{
486	self.emit();
487	TokenStream::default()
488	}
489
490	#[cfg(not(feature = "diagnostics"))]
491	{
492	syn::Error::from(self).into_compile_error()
493	}
494	}
495
496	#[cfg(feature = "diagnostics")]
497	fn single_to_diagnostic(self) -> ::proc_macro::Diagnostic {
498	use proc_macro::{Diagnostic, Level};
499
500	// Delegate to dedicated error formatters when applicable.
501	//
502	// If span information is available, don't include the error property path
503	// since it's redundant and not consistent with native compiler diagnostics.
504	let diagnostic = match self.kind {
505	ErrorKind::UnknownField(euf) => euf.into_diagnostic(self.span),
506	_ => match self.span {
507	Some(span) => span.unwrap().error(self.kind.to_string()),
508	None => Diagnostic::new(Level::Error, self.to_string()),
509	},
510	};
511
512	self.children
513	.into_iter()
514	.fold(diagnostic, \|out, child\| child.append_to(out))
515	}
516
517	/// Transform this error and its children into a list of compiler diagnostics
518	/// and emit them. If the `Error` has associated span information, the diagnostics
519	/// will identify the correct location in source code automatically.
520	///
521	/// # Stability
522	/// This is only available on `nightly` until the compiler `proc_macro_diagnostic`
523	/// feature stabilizes. Until then, it may break at any time.
524	#[cfg(feature = "diagnostics")]
525	pub fn emit(self) {
526	for error in self.flatten() {
527	error.single_to_diagnostic().emit()
528	}
529	}
530
531	/// Transform the error into a compiler diagnostic and - if the diagnostic points to
532	/// a specific code location - add a spanned help child diagnostic that points to the
533	/// parent derived trait.
534	///
535	/// This is experimental and therefore not exposed outside the crate.
536	#[cfg(feature = "diagnostics")]
537	#[allow(dead_code)]
538	fn emit_with_macro_help_span(self) {
539	use proc_macro::Diagnostic;
540
541	for error in self.flatten() {
542	let needs_help = error.has_span();
543	let diagnostic = error.single_to_diagnostic();
544	Diagnostic::emit(if needs_help {
545	diagnostic.span_help(
546	Span::call_site().unwrap(),
547	"Encountered as part of this derive-mode-macro",
548	)
549	} else {
550	diagnostic
551	})
552	}
553	}
554	}
555
556	#[cfg(feature = "diagnostics")]
557	macro_rules! add_child {
558	($unspanned:ident, $spanned:ident, $level:ident) => {
559	#[doc = concat!("Add a child ", stringify!($unspanned), " message to this error.")]
560	#[doc = "# Example"]
561	#[doc = "```rust"]
562	#[doc = "# use darling_core::Error;"]
563	#[doc = concat!(r#"Error::custom("Example")."#, stringify!($unspanned), r#"("message content");"#)]
564	#[doc = "```"]
565	pub fn $unspanned<T: fmt::Display>(mut self, message: T) -> Self {
566	self.children.push(child::ChildDiagnostic::new(
567	child::Level::$level,
568	None,
569	message.to_string(),
570	));
571	self
572	}
573
574	#[doc = concat!("Add a child ", stringify!($unspanned), " message to this error with its own span.")]
575	#[doc = "# Example"]
576	#[doc = "```rust"]
577	#[doc = "# use darling_core::Error;"]
578	#[doc = "# let item_to_span = proc_macro2::Span::call_site();"]
579	#[doc = concat!(r#"Error::custom("Example")."#, stringify!($spanned), r#"(&item_to_span, "message content");"#)]
580	#[doc = "```"]
581	pub fn $spanned<S: Spanned, T: fmt::Display>(mut self, span: &S, message: T) -> Self {
582	self.children.push(child::ChildDiagnostic::new(
583	child::Level::$level,
584	Some(span.span()),
585	message.to_string(),
586	));
587	self
588	}
589	};
590	}
591
592	/// Add child diagnostics to the error.
593	///
594	/// # Example
595	///
596	/// ## Code
597	///
598	/// ```rust
599	/// # use darling_core::Error;
600	/// # let struct_ident = proc_macro2::Span::call_site();
601	/// Error::custom("this is a demo")
602	/// .with_span(&struct_ident)
603	/// .note("we wrote this")
604	/// .help("try doing this instead");
605	/// ```
606	/// ## Output
607	///
608	/// ```text
609	/// error: this is a demo
610	/// --> my_project/my_file.rs:3:5
611	/// \|
612	/// 13 \| FooBar { value: String },
613	/// \| ^^^^^^
614	/// \|
615	/// = note: we wrote this
616	/// = help: try doing this instead
617	/// ```
618	#[cfg(feature = "diagnostics")]
619	impl Error {
620	add_child!(error, span_error, Error);
621	add_child!(warning, span_warning, Warning);
622	add_child!(note, span_note, Note);
623	add_child!(help, span_help, Help);
624	}
625
626	impl StdError for Error {
627	fn description(&self) -> &str {
628	self.kind.description()
629	}
630
631	fn cause(&self) -> Option<&dyn StdError> {
632	None
633	}
634	}
635
636	impl fmt::Display for Error {
637	fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result {
638	write!(f, "{}", self.kind)?;
639	if !self.locations.is_empty() {
640	write!(f, " at {}", self.locations.join("/"))?;
641	}
642
643	Ok(())
644	}
645	}
646
647	impl From<syn::Error> for Error {
648	fn from(e: syn::Error) -> Self {
649	// This impl assumes there is nothing but the message and span that needs to be preserved
650	// from the passed-in error. If this changes at some point, a new ErrorKind should be made
651	// to hold the syn::Error, and this impl should preserve it unmodified while setting its own
652	// span to be a copy of the passed-in error.
653	Self {
654	span: Some(e.span()),
655	..Self::custom(msg:e)
656	}
657	}
658	}
659
660	impl From<Error> for syn::Error {
661	fn from(e: Error) -> Self {
662	if e.len() == `1` {
663	if let Some(span) = e.explicit_span() {
664	// Don't include the location path if the error has an explicit span,
665	// since it will be redundant and isn't consistent with how rustc
666	// exposes errors.
667	syn::Error::new(span, e.kind)
668	} else {
669	// If the error's span is going to be the macro call site, include
670	// the location information to try and help the user pinpoint the issue.
671	syn::Error::new(e.span(), e)
672	}
673	} else {
674	let mut syn_errors = e.flatten().into_iter().map(syn::Error::from);
675	let mut error = syn_errors
676	.next()
677	.expect("darling::Error can never be empty");
678
679	for next_error in syn_errors {
680	error.combine(next_error);
681	}
682
683	error
684	}
685	}
686	}
687
688	// Don't want to publicly commit to Error supporting equality yet, but
689	// not having it makes testing very difficult. Note that spans are not
690	// considered for equality since that would break testing in most cases.
691	#[cfg(test)]
692	impl PartialEq for Error {
693	fn eq(&self, other: &Self) -> bool {
694	self.kind == other.kind && self.locations == other.locations
695	}
696	}
697
698	#[cfg(test)]
699	impl Eq for Error {}
700
701	impl IntoIterator for Error {
702	type Item = Error;
703	type IntoIter = IntoIter;
704
705	fn into_iter(self) -> IntoIter {
706	if let ErrorKind::Multiple(errors: Vec) = self.kind {
707	IntoIter {
708	inner: IntoIterEnum::Multiple(errors.into_iter()),
709	}
710	} else {
711	IntoIter {
712	inner: IntoIterEnum::Single(iter::once(self)),
713	}
714	}
715	}
716	}
717
718	enum IntoIterEnum {
719	Single(iter::Once<Error>),
720	Multiple(vec::IntoIter<Error>),
721	}
722
723	impl Iterator for IntoIterEnum {
724	type Item = Error;
725
726	fn next(&mut self) -> Option<Self::Item> {
727	match *self {
728	IntoIterEnum::Single(ref mut content: impl Iterator) => content.next(),
729	IntoIterEnum::Multiple(ref mut content: &mut IntoIter) => content.next(),
730	}
731	}
732	}
733
734	/// An iterator that moves out of an `Error`.
735	pub struct IntoIter {
736	inner: IntoIterEnum,
737	}
738
739	impl Iterator for IntoIter {
740	type Item = Error;
741
742	fn next(&mut self) -> Option<Error> {
743	self.inner.next()
744	}
745	}
746
747	/// Accumulator for errors, for helping call [`Error::multiple`].
748	///
749	/// See the docs for [`darling::Error`](Error) for more discussion of error handling with darling.
750	///
751	/// # Panics
752	///
753	/// `Accumulator` panics on drop unless [`finish`](Self::finish), [`finish_with`](Self::finish_with),
754	/// or [`into_inner`](Self::into_inner) has been called, even if it contains no errors.
755	/// If you want to discard an `Accumulator` that you know to be empty, use `accumulator.finish().unwrap()`.
756	///
757	/// # Example
758	///
759	/// ```
760	/// # extern crate darling_core as darling;
761	/// # struct Thing;
762	/// # struct Output;
763	/// # impl Thing { fn validate(self) -> darling::Result<Output> { Ok(Output) } }
764	/// fn validate_things(inputs: Vec<Thing>) -> darling::Result<Vec<Output>> {
765	/// let mut errors = darling::Error::accumulator();
766	///
767	/// let outputs = inputs
768	/// .into_iter()
769	/// .filter_map(\|thing\| errors.handle_in(\|\| thing.validate()))
770	/// .collect::<Vec<_>>();
771	///
772	/// errors.finish()?;
773	/// Ok(outputs)
774	/// }
775	/// ```
776	#[derive(Debug)]
777	#[must_use = "Accumulator will panic on drop if not defused."]
778	pub struct Accumulator(Option<Vec<Error>>);
779
780	impl Accumulator {
781	/// Runs a closure, returning the successful value as `Some`, or collecting the error
782	///
783	/// The closure's return type is `darling::Result`, so inside it one can use `?`.
784	pub fn handle_in<T, F: FnOnce() -> Result<T>>(&mut self, f: F) -> Option<T> {
785	self.handle(f())
786	}
787
788	/// Handles a possible error.
789	///
790	/// Returns a successful value as `Some`, or collects the error and returns `None`.
791	pub fn handle<T>(&mut self, result: Result<T>) -> Option<T> {
792	match result {
793	Ok(y) => Some(y),
794	Err(e) => {
795	self.push(e);
796	None
797	}
798	}
799	}
800
801	/// Stop accumulating errors, producing `Ok` if there are no errors or producing
802	/// an error with all those encountered by the accumulator.
803	pub fn finish(self) -> Result<()> {
804	self.finish_with(())
805	}
806
807	/// Bundles the collected errors if there were any, or returns the success value
808	///
809	/// Call this at the end of your input processing.
810	///
811	/// If there were no errors recorded, returns `Ok(success)`.
812	/// Otherwise calls [`Error::multiple`] and returns the result as an `Err`.
813	pub fn finish_with<T>(self, success: T) -> Result<T> {
814	let errors = self.into_inner();
815	if errors.is_empty() {
816	Ok(success)
817	} else {
818	Err(Error::multiple(errors))
819	}
820	}
821
822	fn errors(&mut self) -> &mut Vec<Error> {
823	match &mut self.0 {
824	Some(errors) => errors,
825	None => panic!("darling internal error: Accumulator accessed after defuse"),
826	}
827	}
828
829	/// Returns the accumulated errors as a `Vec`.
830	///
831	/// This function defuses the drop bomb.
832	#[must_use = "Accumulated errors should be handled or propagated to the caller"]
833	pub fn into_inner(mut self) -> Vec<Error> {
834	match self.0.take() {
835	Some(errors) => errors,
836	None => panic!("darling internal error: Accumulator accessed after defuse"),
837	}
838	}
839
840	/// Add one error to the collection.
841	pub fn push(&mut self, error: Error) {
842	self.errors().push(error)
843	}
844
845	/// Finish the current accumulation, and if there are no errors create a new `Self` so processing may continue.
846	///
847	/// This is shorthand for:
848	///
849	/// ```rust,ignore
850	/// errors.finish()?;
851	/// errors = Error::accumulator();
852	/// ```
853	///
854	/// # Drop Behavior
855	/// This function returns a new [`Accumulator`] in the success case.
856	/// This new accumulator is "armed" and will detonate if dropped without being finished.
857	///
858	/// # Example
859	///
860	/// ```
861	/// # extern crate darling_core as darling;
862	/// # struct Thing;
863	/// # struct Output;
864	/// # impl Thing { fn validate(&self) -> darling::Result<Output> { Ok(Output) } }
865	/// fn validate(lorem_inputs: &[Thing], ipsum_inputs: &[Thing])
866	/// -> darling::Result<(Vec<Output>, Vec<Output>)> {
867	/// let mut errors = darling::Error::accumulator();
868	///
869	/// let lorems = lorem_inputs.iter().filter_map(\|l\| {
870	/// errors.handle(l.validate())
871	/// }).collect();
872	///
873	/// errors = errors.checkpoint()?;
874	///
875	/// let ipsums = ipsum_inputs.iter().filter_map(\|l\| {
876	/// errors.handle(l.validate())
877	/// }).collect();
878	///
879	/// errors.finish_with((lorems, ipsums))
880	/// }
881	/// # validate(&[], &[]).unwrap();
882	/// ```
883	pub fn checkpoint(self) -> Result<Accumulator> {
884	// The doc comment says on success we "return the Accumulator for future use".
885	// Actually, we have consumed it by feeding it to finish so we make a fresh one.
886	// This is OK since by definition of the success path, it was empty on entry.
887	self.finish()?;
888	Ok(Self::default())
889	}
890	}
891
892	impl Default for Accumulator {
893	fn default() -> Self {
894	Accumulator(Some(vec![]))
895	}
896	}
897
898	impl Extend<Error> for Accumulator {
899	fn extend<I>(&mut self, iter: I)
900	where
901	I: IntoIterator<Item = Error>,
902	{
903	self.errors().extend(iter)
904	}
905	}
906
907	impl Drop for Accumulator {
908	fn drop(&mut self) {
909	// don't try to panic if we are currently unwinding a panic
910	// otherwise we end up with an unhelful "thread panicked while panicking. aborting." message
911	if !std::thread::panicking() {
912	if let Some(errors: &mut Vec) = &mut self.0 {
913	match errors.len() {
914	`0` => panic!("darling::error::Accumulator dropped without being finished"),
915	error_count: usize => panic!("darling::error::Accumulator dropped without being finished. {} errors were lost.", error_count)
916	}
917	}
918	}
919	}
920	}
921
922	#[cfg(test)]
923	mod tests {
924	use super::Error;
925
926	#[test]
927	fn flatten_noop() {
928	let err = Error::duplicate_field("hello").at("world");
929	assert_eq!(err.clone().flatten(), err);
930	}
931
932	#[test]
933	fn flatten_simple() {
934	let err = Error::multiple(vec![
935	Error::unknown_field("hello").at("world"),
936	Error::missing_field("hell_no").at("world"),
937	])
938	.at("foo")
939	.flatten();
940
941	assert!(err.location().is_empty());
942
943	let mut err_iter = err.into_iter();
944
945	let first = err_iter.next();
946	assert!(first.is_some());
947	assert_eq!(first.unwrap().location(), vec!["foo", "world"]);
948
949	let second = err_iter.next();
950	assert!(second.is_some());
951
952	assert_eq!(second.unwrap().location(), vec!["foo", "world"]);
953
954	assert!(err_iter.next().is_none());
955	}
956
957	#[test]
958	fn len_single() {
959	let err = Error::duplicate_field("hello");
960	assert_eq!(`1`, err.len());
961	}
962
963	#[test]
964	fn len_multiple() {
965	let err = Error::multiple(vec![
966	Error::duplicate_field("hello"),
967	Error::missing_field("hell_no"),
968	]);
969	assert_eq!(`2`, err.len());
970	}
971
972	#[test]
973	fn len_nested() {
974	let err = Error::multiple(vec![
975	Error::duplicate_field("hello"),
976	Error::multiple(vec![
977	Error::duplicate_field("hi"),
978	Error::missing_field("bye"),
979	Error::multiple(vec![Error::duplicate_field("whatsup")]),
980	]),
981	]);
982
983	assert_eq!(`4`, err.len());
984	}
985
986	#[test]
987	fn accum_ok() {
988	let errs = Error::accumulator();
989	assert_eq!("test", errs.finish_with("test").unwrap());
990	}
991
992	#[test]
993	fn accum_errr() {
994	let mut errs = Error::accumulator();
995	errs.push(Error::custom("foo!"));
996	errs.finish().unwrap_err();
997	}
998
999	#[test]
1000	fn accum_into_inner() {
1001	let mut errs = Error::accumulator();
1002	errs.push(Error::custom("foo!"));
1003	let errs: Vec<_> = errs.into_inner();
1004	assert_eq!(errs.len(), `1`);
1005	}
1006
1007	#[test]
1008	#[should_panic(expected = "Accumulator dropped")]
1009	fn accum_drop_panic() {
1010	let _errs = Error::accumulator();
1011	}
1012
1013	#[test]
1014	#[should_panic(expected = "2 errors")]
1015	fn accum_drop_panic_with_error_count() {
1016	let mut errors = Error::accumulator();
1017	errors.push(Error::custom("first"));
1018	errors.push(Error::custom("second"));
1019	}
1020
1021	#[test]
1022	fn accum_checkpoint_error() {
1023	let mut errs = Error::accumulator();
1024	errs.push(Error::custom("foo!"));
1025	errs.checkpoint().unwrap_err();
1026	}
1027
1028	#[test]
1029	#[should_panic(expected = "Accumulator dropped")]
1030	fn accum_checkpoint_drop_panic() {
1031	let mut errs = Error::accumulator();
1032	errs = errs.checkpoint().unwrap();
1033	let _ = errs;
1034	}
1035	}
1036