[−][src]Trait syn::parse::discouraged::Speculative
Extensions to the ParseStream
API to support speculative parsing.
Required methods
fn advance_to(&self, fork: &Self)
Advance this parse stream to the position of a forked parse stream.
This is the opposite operation to ParseStream::fork
. You can fork a
parse stream, perform some speculative parsing, then join the original
stream to the fork to "commit" the parsing from the fork to the main
stream.
If you can avoid doing this, you should, as it limits the ability to
generate useful errors. That said, it is often the only way to parse
syntax of the form A* B*
for arbitrary syntax A
and B
. The problem
is that when the fork fails to parse an A
, it's impossible to tell
whether that was because of a syntax error and the user meant to provide
an A
, or that the A
s are finished and its time to start parsing
B
s. Use with care.
Also note that if A
is a subset of B
, A* B*
can be parsed by
parsing B*
and removing the leading members of A
from the
repetition, bypassing the need to involve the downsides associated with
speculative parsing.
Example
There has been chatter about the possibility of making the colons in the
turbofish syntax like path::to::<T>
no longer required by accepting
path::to<T>
in expression position. Specifically, according to RFC
2544, PathSegment
parsing should always try to consume a following
<
token as the start of generic arguments, and reset to the <
if
that fails (e.g. the token is acting as a less-than operator).
This is the exact kind of parsing behavior which requires the "fork,
try, commit" behavior that ParseStream::fork
discourages. With
advance_to
, we can avoid having to parse the speculatively parsed
content a second time.
This change in behavior can be implemented in syn by replacing just the
Parse
implementation for PathSegment
:
# use syn::ext::IdentExt;
use syn::parse::discouraged::Speculative;
# use syn::parse::{Parse, ParseStream};
# use syn::{Ident, PathArguments, Result, Token};
pub struct PathSegment {
pub ident: Ident,
pub arguments: PathArguments,
}
#
# impl<T> From<T> for PathSegment
# where
# T: Into<Ident>,
# {
# fn from(ident: T) -> Self {
# PathSegment {
# ident: ident.into(),
# arguments: PathArguments::None,
# }
# }
# }
impl Parse for PathSegment {
fn parse(input: ParseStream) -> Result<Self> {
if input.peek(Token![super])
|| input.peek(Token![self])
|| input.peek(Token![Self])
|| input.peek(Token![crate])
|| input.peek(Token![extern])
{
let ident = input.call(Ident::parse_any)?;
return Ok(PathSegment::from(ident));
}
let ident = input.parse()?;
if input.peek(Token![::]) && input.peek3(Token![<]) {
return Ok(PathSegment {
ident: ident,
arguments: PathArguments::AngleBracketed(input.parse()?),
});
}
if input.peek(Token![<]) && !input.peek(Token![<=]) {
let fork = input.fork();
if let Ok(arguments) = fork.parse() {
input.advance_to(&fork);
return Ok(PathSegment {
ident: ident,
arguments: PathArguments::AngleBracketed(arguments),
});
}
}
Ok(PathSegment::from(ident))
}
}
# syn::parse_str::<PathSegment>("a<b,c>").unwrap();
Drawbacks
The main drawback of this style of speculative parsing is in error presentation. Even if the lookahead is the "correct" parse, the error that is shown is that of the "fallback" parse. To use the same example as the turbofish above, take the following unfinished "turbofish":
let _ = f<&'a fn(), for<'a> serde::>();
If this is parsed as generic arguments, we can provide the error message
error: expected identifier
--> src.rs:L:C
|
L | let _ = f<&'a fn(), for<'a> serde::>();
| ^
but if parsed using the above speculative parsing, it falls back to
assuming that the <
is a less-than when it fails to parse the generic
arguments, and tries to interpret the &'a
as the start of a labelled
loop, resulting in the much less helpful error
error: expected `:`
--> src.rs:L:C
|
L | let _ = f<&'a fn(), for<'a> serde::>();
| ^^
This can be mitigated with various heuristics (two examples: show both forks' parse errors, or show the one that consumed more tokens), but when you can control the grammar, sticking to something that can be parsed LL(3) and without the LL(*) speculative parsing this makes possible, displaying reasonable errors becomes much more simple.
Performance
This method performs a cheap fixed amount of work that does not depend on how far apart the two streams are positioned.
Panics
The forked stream in the argument of advance_to
must have been
obtained by forking self
. Attempting to advance to any other stream
will cause a panic.