Overhaul comments in collect_tokens_trailing_token
.
Adding details, clarifying lots of little things, etc. In particular, the commit adds details of an example. I find this very helpful, because it's taken me a long time to understand how this code works.
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@ -303,13 +303,9 @@ pub fn parse_inner_attributes(&mut self) -> PResult<'a, ast::AttrVec> {
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None
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};
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if let Some(attr) = attr {
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// If we are currently capturing tokens, mark the location of this inner attribute.
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// If capturing ends up creating a `LazyAttrTokenStream`, we will include
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// this replace range with it, removing the inner attribute from the final
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// `AttrTokenStream`. Inner attributes are stored in the parsed AST note.
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// During macro expansion, they are selectively inserted back into the
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// token stream (the first inner attribute is removed each time we invoke the
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// corresponding macro).
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// If we are currently capturing tokens (i.e. we are within a call to
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// `Parser::collect_tokens_trailing_tokens`) record the token positions of this
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// inner attribute, for possible later processing in a `LazyAttrTokenStream`.
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if let Capturing::Yes = self.capture_state.capturing {
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let end_pos = self.num_bump_calls;
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let range = start_pos..end_pos;
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@ -463,7 +459,8 @@ fn parse_meta_item_inner(&mut self) -> PResult<'a, ast::NestedMetaItem> {
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}
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}
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/// The attributes are complete if all attributes are either a doc comment or a builtin attribute other than `cfg_attr`
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/// The attributes are complete if all attributes are either a doc comment or a
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/// builtin attribute other than `cfg_attr`.
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pub fn is_complete(attrs: &[ast::Attribute]) -> bool {
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attrs.iter().all(|attr| {
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attr.is_doc_comment()
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@ -17,12 +17,12 @@
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///
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/// This wrapper prevents direct access to the underlying `ast::AttrVec`.
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/// Parsing code can only get access to the underlying attributes
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/// by passing an `AttrWrapper` to `collect_tokens_trailing_tokens`.
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/// by passing an `AttrWrapper` to `collect_tokens_trailing_token`.
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/// This makes it difficult to accidentally construct an AST node
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/// (which stores an `ast::AttrVec`) without first collecting tokens.
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///
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/// This struct has its own module, to ensure that the parser code
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/// cannot directly access the `attrs` field
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/// cannot directly access the `attrs` field.
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#[derive(Debug, Clone)]
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pub struct AttrWrapper {
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attrs: AttrVec,
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@ -76,14 +76,13 @@ fn has_cfg_or_cfg_attr(attrs: &[Attribute]) -> bool {
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})
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}
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// Produces a `TokenStream` on-demand. Using `cursor_snapshot`
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// and `num_calls`, we can reconstruct the `TokenStream` seen
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// by the callback. This allows us to avoid producing a `TokenStream`
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// if it is never needed - for example, a captured `macro_rules!`
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// argument that is never passed to a proc macro.
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// In practice token stream creation happens rarely compared to
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// calls to `collect_tokens` (see some statistics in #78736),
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// so we are doing as little up-front work as possible.
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// From a value of this type we can reconstruct the `TokenStream` seen by the
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// `f` callback passed to a call to `Parser::collect_tokens_trailing_token`, by
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// replaying the getting of the tokens. This saves us producing a `TokenStream`
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// if it is never needed, e.g. a captured `macro_rules!` argument that is never
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// passed to a proc macro. In practice, token stream creation happens rarely
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// compared to calls to `collect_tokens` (see some statistics in #78736) so we
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// are doing as little up-front work as possible.
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//
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// This also makes `Parser` very cheap to clone, since
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// there is no intermediate collection buffer to clone.
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@ -163,46 +162,55 @@ fn to_attr_token_stream(&self) -> AttrTokenStream {
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}
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impl<'a> Parser<'a> {
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/// Records all tokens consumed by the provided callback,
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/// including the current token. These tokens are collected
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/// into a `LazyAttrTokenStream`, and returned along with the first part of
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/// the callback's result. The second (bool) part of the callback's result
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/// indicates if an extra token should be captured, e.g. a comma or
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/// Parses code with `f`. If appropriate, it records the tokens (in
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/// `LazyAttrTokenStream` form) that were parsed in the result, accessible
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/// via the `HasTokens` trait. The second (bool) part of the callback's
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/// result indicates if an extra token should be captured, e.g. a comma or
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/// semicolon.
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///
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/// The `attrs` passed in are in `AttrWrapper` form, which is opaque. The
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/// `AttrVec` within is passed to `f`. See the comment on `AttrWrapper` for
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/// details.
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///
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/// Note: If your callback consumes an opening delimiter
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/// (including the case where you call `collect_tokens`
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/// when the current token is an opening delimiter),
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/// you must also consume the corresponding closing delimiter.
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/// Note: If your callback consumes an opening delimiter (including the
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/// case where `self.token` is an opening delimiter on entry to this
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/// function), you must also consume the corresponding closing delimiter.
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/// E.g. you can consume `something ([{ }])` or `([{}])`, but not `([{}]`.
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/// This restriction isn't a problem in practice, because parsed AST items
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/// always have matching delimiters.
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///
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/// That is, you can consume
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/// `something ([{ }])` or `([{}])`, but not `([{}]`
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///
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/// This restriction shouldn't be an issue in practice,
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/// since this function is used to record the tokens for
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/// a parsed AST item, which always has matching delimiters.
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/// The following example code will be used to explain things in comments
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/// below. It has an outer attribute and an inner attribute. Parsing it
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/// involves two calls to this method, one of which is indirectly
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/// recursive.
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/// ```ignore (fake attributes)
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/// #[cfg_eval] // token pos
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/// mod m { // 0.. 3
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/// #[cfg_attr(cond1, attr1)] // 3..12
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/// fn g() { // 12..17
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/// #![cfg_attr(cond2, attr2)] // 17..27
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/// let _x = 3; // 27..32
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/// } // 32..33
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/// } // 33..34
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/// ```
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pub fn collect_tokens_trailing_token<R: HasAttrs + HasTokens>(
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&mut self,
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attrs: AttrWrapper,
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force_collect: ForceCollect,
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f: impl FnOnce(&mut Self, ast::AttrVec) -> PResult<'a, (R, bool)>,
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) -> PResult<'a, R> {
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// We only bail out when nothing could possibly observe the collected tokens:
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// 1. We cannot be force collecting tokens (since force-collecting requires tokens
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// by definition
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// Skip collection when nothing could observe the collected tokens, i.e.
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// all of the following conditions hold.
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// - We are not force collecting tokens (because force collection
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// requires tokens by definition).
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if matches!(force_collect, ForceCollect::No)
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// None of our outer attributes can require tokens (e.g. a proc-macro)
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// - None of our outer attributes require tokens.
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&& attrs.is_complete()
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// If our target supports custom inner attributes, then we cannot bail
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// out early, since we may need to capture tokens for a custom inner attribute
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// invocation.
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// - Our target doesn't support custom inner attributes (custom
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// inner attribute invocation might require token capturing).
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&& !R::SUPPORTS_CUSTOM_INNER_ATTRS
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// Never bail out early in `capture_cfg` mode, since there might be `#[cfg]`
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// or `#[cfg_attr]` attributes.
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// - We are not in `capture_cfg` mode (which requires tokens if
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// the parsed node has `#[cfg]` or `#[cfg_attr]` attributes).
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&& !self.capture_cfg
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{
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return Ok(f(self, attrs.attrs)?.0);
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@ -214,6 +222,12 @@ pub fn collect_tokens_trailing_token<R: HasAttrs + HasTokens>(
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let has_outer_attrs = !attrs.attrs.is_empty();
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let replace_ranges_start = self.capture_state.replace_ranges.len();
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// We set and restore `Capturing::Yes` on either side of the call to
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// `f`, so we can distinguish the outermost call to
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// `collect_tokens_trailing_token` (e.g. parsing `m` in the example
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// above) from any inner (indirectly recursive) calls (e.g. parsing `g`
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// in the example above). This distinction is used below and in
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// `Parser::parse_inner_attributes`.
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let (mut ret, capture_trailing) = {
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let prev_capturing = mem::replace(&mut self.capture_state.capturing, Capturing::Yes);
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let ret_and_trailing = f(self, attrs.attrs);
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@ -221,37 +235,42 @@ pub fn collect_tokens_trailing_token<R: HasAttrs + HasTokens>(
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ret_and_trailing?
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};
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// When we're not in `capture-cfg` mode, then bail out early if:
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// 1. Our target doesn't support tokens at all (e.g we're parsing an `NtIdent`)
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// so there's nothing for us to do.
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// 2. Our target already has tokens set (e.g. we've parsed something
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// like `#[my_attr] $item`). The actual parsing code takes care of
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// prepending any attributes to the nonterminal, so we don't need to
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// modify the already captured tokens.
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// Note that this check is independent of `force_collect`- if we already
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// have tokens, or can't even store them, then there's never a need to
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// force collection of new tokens.
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// When we're not in `capture_cfg` mode, then skip collecting and
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// return early if either of the following conditions hold.
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// - `None`: Our target doesn't support tokens at all (e.g. `NtIdent`).
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// - `Some(Some(_))`: Our target already has tokens set (e.g. we've
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// parsed something like `#[my_attr] $item`). The actual parsing code
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// takes care of prepending any attributes to the nonterminal, so we
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// don't need to modify the already captured tokens.
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//
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// Note that this check is independent of `force_collect`. There's no
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// need to collect tokens when we don't support tokens or already have
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// tokens.
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if !self.capture_cfg && matches!(ret.tokens_mut(), None | Some(Some(_))) {
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return Ok(ret);
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}
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// This is very similar to the bail out check at the start of this function.
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// Now that we've parsed an AST node, we have more information available.
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// This is similar to the "skip collection" check at the start of this
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// function, but now that we've parsed an AST node we have more
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// information available. (If we return early here that means the
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// setup, such as cloning the token cursor, was unnecessary. That's
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// hard to avoid.)
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//
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// Skip collection when nothing could observe the collected tokens, i.e.
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// all of the following conditions hold.
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// - We are not force collecting tokens.
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if matches!(force_collect, ForceCollect::No)
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// We now have inner attributes available, so this check is more precise
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// than `attrs.is_complete()` at the start of the function.
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// As a result, we don't need to check `R::SUPPORTS_CUSTOM_INNER_ATTRS`
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// - None of our outer *or* inner attributes require tokens.
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// (`attrs` was just outer attributes, but `ret.attrs()` is outer
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// and inner attributes. That makes this check more precise than
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// `attrs.is_complete()` at the start of the function, and we can
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// skip the subsequent check on `R::SUPPORTS_CUSTOM_INNER_ATTRS`.
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&& crate::parser::attr::is_complete(ret.attrs())
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// Subtle: We call `has_cfg_or_cfg_attr` with the attrs from `ret`.
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// This ensures that we consider inner attributes (e.g. `#![cfg]`),
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// which require us to have tokens available
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// We also call `has_cfg_or_cfg_attr` at the beginning of this function,
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// but we only bail out if there's no possibility of inner attributes
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// (!R::SUPPORTS_CUSTOM_INNER_ATTRS)
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// We only capture about `#[cfg]` or `#[cfg_attr]` in `capture_cfg`
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// mode - during normal parsing, we don't need any special capturing
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// for those attributes, since they're builtin.
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&& !(self.capture_cfg && has_cfg_or_cfg_attr(ret.attrs()))
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// - We are not in `capture_cfg` mode, or we are but there are no
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// `#[cfg]` or `#[cfg_attr]` attributes. (During normal
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// non-`capture_cfg` parsing, we don't need any special capturing
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// for those attributes, because they're builtin.)
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&& (!self.capture_cfg || !has_cfg_or_cfg_attr(ret.attrs()))
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{
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return Ok(ret);
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}
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@ -273,7 +292,10 @@ pub fn collect_tokens_trailing_token<R: HasAttrs + HasTokens>(
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let num_calls = end_pos - start_pos;
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// Take the captured ranges for any inner attributes that we parsed.
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// Take the captured ranges for any inner attributes that we parsed in
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// `Parser::parse_inner_attributes`, and pair them in a `ReplaceRange`
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// with `None`, which means the relevant tokens will be removed. (More
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// details below.)
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let mut inner_attr_replace_ranges = Vec::new();
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for inner_attr in ret.attrs().iter().filter(|a| a.style == ast::AttrStyle::Inner) {
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if let Some(attr_range) = self.capture_state.inner_attr_ranges.remove(&inner_attr.id) {
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@ -289,9 +311,9 @@ pub fn collect_tokens_trailing_token<R: HasAttrs + HasTokens>(
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if replace_ranges_start == replace_ranges_end && inner_attr_replace_ranges.is_empty() {
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Box::new([])
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} else {
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// Grab any replace ranges that occur *inside* the current AST node.
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// We will perform the actual replacement when we convert the `LazyAttrTokenStream`
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// to an `AttrTokenStream`.
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// Grab any replace ranges that occur *inside* the current AST node. We will
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// perform the actual replacement only when we convert the `LazyAttrTokenStream` to
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// an `AttrTokenStream`.
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self.capture_state.replace_ranges[replace_ranges_start..replace_ranges_end]
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.iter()
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.cloned()
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@ -300,6 +322,28 @@ pub fn collect_tokens_trailing_token<R: HasAttrs + HasTokens>(
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.collect()
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};
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// What is the status here when parsing the example code at the top of this method?
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//
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// When parsing `g`:
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// - `start_pos..end_pos` is `12..33` (`fn g { ... }`, excluding the outer attr).
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// - `inner_attr_replace_ranges` has one entry (`5..15`, when counting from `fn`), to
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// delete the inner attr's tokens.
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// - This entry is put into the lazy tokens for `g`, i.e. deleting the inner attr from
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// those tokens (if they get evaluated).
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// - Those lazy tokens are also put into an `AttrsTarget` that is appended to `self`'s
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// replace ranges at the bottom of this function, for processing when parsing `m`.
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// - `replace_ranges_start..replace_ranges_end` is empty.
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//
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// When parsing `m`:
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// - `start_pos..end_pos` is `0..34` (`mod m`, excluding the `#[cfg_eval]` attribute).
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// - `inner_attr_replace_ranges` is empty.
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// - `replace_range_start..replace_ranges_end` has two entries.
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// - One to delete the inner attribute (`17..27`), obtained when parsing `g` (see above).
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// - One `AttrsTarget` (added below when parsing `g`) to replace all of `g` (`3..33`,
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// including its outer attribute), with:
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// - `attrs`: includes the outer and the inner attr.
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// - `tokens`: lazy tokens for `g` (with its inner attr deleted).
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let tokens = LazyAttrTokenStream::new(LazyAttrTokenStreamImpl {
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start_token,
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num_calls,
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@ -323,15 +367,27 @@ pub fn collect_tokens_trailing_token<R: HasAttrs + HasTokens>(
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{
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assert!(!self.break_last_token, "Should not have unglued last token with cfg attr");
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// Replace the entire AST node that we just parsed, including attributes, with
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// `target`. If this AST node is inside an item that has `#[derive]`, then this will
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// allow us to cfg-expand this AST node.
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// What is the status here when parsing the example code at the top of this method?
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//
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// When parsing `g`, we add two entries:
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// - The `start_pos..end_pos` (`3..33`) entry has a new `AttrsTarget` with:
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// - `attrs`: includes the outer and the inner attr.
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// - `tokens`: lazy tokens for `g` (with its inner attr deleted).
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// - `inner_attr_replace_ranges` contains the one entry to delete the inner attr's
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// tokens (`17..27`).
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//
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// When parsing `m`, we do nothing here.
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// Set things up so that the entire AST node that we just parsed, including attributes,
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// will be replaced with `target` in the lazy token stream. This will allow us to
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// cfg-expand this AST node.
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let start_pos = if has_outer_attrs { attrs.start_pos } else { start_pos };
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let target = AttrsTarget { attrs: ret.attrs().iter().cloned().collect(), tokens };
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self.capture_state.replace_ranges.push((start_pos..end_pos, Some(target)));
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self.capture_state.replace_ranges.extend(inner_attr_replace_ranges);
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} else if matches!(self.capture_state.capturing, Capturing::No) {
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// Only clear the ranges once we've finished capturing entirely.
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// Only clear the ranges once we've finished capturing entirely, i.e. we've finished
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// the outermost call to this method.
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self.capture_state.replace_ranges.clear();
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self.capture_state.inner_attr_ranges.clear();
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}
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@ -221,6 +221,7 @@ enum Capturing {
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Yes,
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}
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// This state is used by `Parser::collect_tokens_trailing_token`.
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#[derive(Clone, Debug)]
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struct CaptureState {
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capturing: Capturing,
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