compiler/rustc_parse/src/parser/stmt.rs - toolchain/rustc - Git at Google

 use super::attr::DEFAULT_INNER_ATTR_FORBIDDEN;
 use super::diagnostics::{AttemptLocalParseRecovery, Error};
 use super::expr::LhsExpr;
 use super::pat::RecoverComma;
 use super::path::PathStyle;
 use super::TrailingToken;
 use super::{AttrWrapper, BlockMode, ForceCollect, Parser, Restrictions, SemiColonMode};
 use crate::maybe_whole;

 use rustc_ast as ast;
 use rustc_ast::ptr::P;
 use rustc_ast::token::{self, TokenKind};
 use rustc_ast::util::classify;
 use rustc_ast::{
     AstLike, AttrStyle, AttrVec, Attribute, LocalKind, MacCall, MacCallStmt, MacStmtStyle,
 };
 use rustc_ast::{Block, BlockCheckMode, Expr, ExprKind, Local, Stmt};
 use rustc_ast::{StmtKind, DUMMY_NODE_ID};
 use rustc_errors::{Applicability, PResult};
 use rustc_span::source_map::{BytePos, Span};
 use rustc_span::symbol::{kw, sym};

 use std::mem;

 impl<'a> Parser<'a> {
     /// Parses a statement. This stops just before trailing semicolons on everything but items.
     /// e.g., a `StmtKind::Semi` parses to a `StmtKind::Expr`, leaving the trailing `;` unconsumed.
     // Public for rustfmt usage.
     pub fn parse_stmt(&mut self, force_collect: ForceCollect) -> PResult<'a, Option<Stmt>> {
         Ok(self.parse_stmt_without_recovery(false, force_collect).unwrap_or_else(|mut e| {
             e.emit();
             self.recover_stmt_(SemiColonMode::Break, BlockMode::Ignore);
             None
         }))
     }

     /// If `force_capture` is true, forces collection of tokens regardless of whether
     /// or not we have attributes
     crate fn parse_stmt_without_recovery(
         &mut self,
         capture_semi: bool,
         force_collect: ForceCollect,
     ) -> PResult<'a, Option<Stmt>> {
         let attrs = self.parse_outer_attributes()?;
         let lo = self.token.span;

         // Don't use `maybe_whole` so that we have precise control
         // over when we bump the parser
         if let token::Interpolated(nt) = &self.token.kind {
             if let token::NtStmt(stmt) = &**nt {
                 let mut stmt = stmt.clone();
                 self.bump();
                 stmt.visit_attrs(|stmt_attrs| {
                     attrs.prepend_to_nt_inner(stmt_attrs);
                 });
                 return Ok(Some(stmt));
             }
         }

         Ok(Some(if self.token.is_keyword(kw::Let) {
             self.parse_local_mk(lo, attrs, capture_semi, force_collect)?
         } else if self.is_kw_followed_by_ident(kw::Mut) {
             self.recover_stmt_local(lo, attrs, "missing keyword", "let mut")?
         } else if self.is_kw_followed_by_ident(kw::Auto) {
             self.bump(); // `auto`
             let msg = "write `let` instead of `auto` to introduce a new variable";
             self.recover_stmt_local(lo, attrs, msg, "let")?
         } else if self.is_kw_followed_by_ident(sym::var) {
             self.bump(); // `var`
             let msg = "write `let` instead of `var` to introduce a new variable";
             self.recover_stmt_local(lo, attrs, msg, "let")?
         } else if self.check_path() && !self.token.is_qpath_start() && !self.is_path_start_item() {
             // We have avoided contextual keywords like `union`, items with `crate` visibility,
             // or `auto trait` items. We aim to parse an arbitrary path `a::b` but not something
             // that starts like a path (1 token), but it fact not a path.
             // Also, we avoid stealing syntax from `parse_item_`.
             if force_collect == ForceCollect::Yes {
                 self.collect_tokens_no_attrs(|this| this.parse_stmt_path_start(lo, attrs))
             } else {
                 self.parse_stmt_path_start(lo, attrs)
             }?
         } else if let Some(item) =
             self.parse_item_common(attrs.clone(), false, true, |_| true, force_collect)?
         {
             // FIXME: Bad copy of attrs
             self.mk_stmt(lo.to(item.span), StmtKind::Item(P(item)))
         } else if self.eat(&token::Semi) {
             // Do not attempt to parse an expression if we're done here.
             self.error_outer_attrs(&attrs.take_for_recovery());
             self.mk_stmt(lo, StmtKind::Empty)
         } else if self.token != token::CloseDelim(token::Brace) {
             // Remainder are line-expr stmts.
             let e = if force_collect == ForceCollect::Yes {
                 self.collect_tokens_no_attrs(|this| {
                     this.parse_expr_res(Restrictions::STMT_EXPR, Some(attrs))
                 })
             } else {
                 self.parse_expr_res(Restrictions::STMT_EXPR, Some(attrs))
             }?;
             self.mk_stmt(lo.to(e.span), StmtKind::Expr(e))
         } else {
             self.error_outer_attrs(&attrs.take_for_recovery());
             return Ok(None);
         }))
     }

     fn parse_stmt_path_start(&mut self, lo: Span, attrs: AttrWrapper) -> PResult<'a, Stmt> {
         let stmt = self.collect_tokens_trailing_token(attrs, ForceCollect::No, |this, attrs| {
             let path = this.parse_path(PathStyle::Expr)?;

             if this.eat(&token::Not) {
                 let stmt_mac = this.parse_stmt_mac(lo, attrs.into(), path)?;
                 if this.token == token::Semi {
                     return Ok((stmt_mac, TrailingToken::Semi));
                 } else {
                     return Ok((stmt_mac, TrailingToken::None));
                 }
             }

             let expr = if this.eat(&token::OpenDelim(token::Brace)) {
                 this.parse_struct_expr(None, path, AttrVec::new(), true)?
             } else {
                 let hi = this.prev_token.span;
                 this.mk_expr(lo.to(hi), ExprKind::Path(None, path), AttrVec::new())
             };

             let expr = this.with_res(Restrictions::STMT_EXPR, |this| {
                 this.parse_dot_or_call_expr_with(expr, lo, attrs)
             })?;
             // `DUMMY_SP` will get overwritten later in this function
             Ok((this.mk_stmt(rustc_span::DUMMY_SP, StmtKind::Expr(expr)), TrailingToken::None))
         })?;

         if let StmtKind::Expr(expr) = stmt.kind {
             // Perform this outside of the `collect_tokens_trailing_token` closure,
             // since our outer attributes do not apply to this part of the expression
             let expr = self.with_res(Restrictions::STMT_EXPR, |this| {
                 this.parse_assoc_expr_with(0, LhsExpr::AlreadyParsed(expr))
             })?;
             Ok(self.mk_stmt(lo.to(self.prev_token.span), StmtKind::Expr(expr)))
         } else {
             Ok(stmt)
         }
     }

     /// Parses a statement macro `mac!(args)` provided a `path` representing `mac`.
     /// At this point, the `!` token after the path has already been eaten.
     fn parse_stmt_mac(&mut self, lo: Span, attrs: AttrVec, path: ast::Path) -> PResult<'a, Stmt> {
         let args = self.parse_mac_args()?;
         let delim = args.delim();
         let hi = self.prev_token.span;

         let style =
             if delim == token::Brace { MacStmtStyle::Braces } else { MacStmtStyle::NoBraces };

         let mac = MacCall { path, args, prior_type_ascription: self.last_type_ascription };

         let kind = if delim == token::Brace || self.token == token::Semi || self.token == token::Eof
         {
             StmtKind::MacCall(P(MacCallStmt { mac, style, attrs, tokens: None }))
         } else {
             // Since none of the above applied, this is an expression statement macro.
             let e = self.mk_expr(lo.to(hi), ExprKind::MacCall(mac), AttrVec::new());
             let e = self.maybe_recover_from_bad_qpath(e, true)?;
             let e = self.parse_dot_or_call_expr_with(e, lo, attrs.into())?;
             let e = self.parse_assoc_expr_with(0, LhsExpr::AlreadyParsed(e))?;
             StmtKind::Expr(e)
         };
         Ok(self.mk_stmt(lo.to(hi), kind))
     }

     /// Error on outer attributes in this context.
     /// Also error if the previous token was a doc comment.
     fn error_outer_attrs(&self, attrs: &[Attribute]) {
         if let [.., last] = attrs {
             if last.is_doc_comment() {
                 self.span_err(last.span, Error::UselessDocComment).emit();
             } else if attrs.iter().any(|a| a.style == AttrStyle::Outer) {
                 self.struct_span_err(last.span, "expected statement after outer attribute").emit();
             }
         }
     }

     fn recover_stmt_local(
         &mut self,
         lo: Span,
         attrs: AttrWrapper,
         msg: &str,
         sugg: &str,
     ) -> PResult<'a, Stmt> {
         let stmt = self.recover_local_after_let(lo, attrs)?;
         self.struct_span_err(lo, "invalid variable declaration")
             .span_suggestion(lo, msg, sugg.to_string(), Applicability::MachineApplicable)
             .emit();
         Ok(stmt)
     }

     fn parse_local_mk(
         &mut self,
         lo: Span,
         attrs: AttrWrapper,
         capture_semi: bool,
         force_collect: ForceCollect,
     ) -> PResult<'a, Stmt> {
         self.collect_tokens_trailing_token(attrs, force_collect, |this, attrs| {
             this.expect_keyword(kw::Let)?;
             let local = this.parse_local(attrs.into())?;
             let trailing = if capture_semi && this.token.kind == token::Semi {
                 TrailingToken::Semi
             } else {
                 TrailingToken::None
             };
             Ok((this.mk_stmt(lo.to(this.prev_token.span), StmtKind::Local(local)), trailing))
         })
     }

     fn recover_local_after_let(&mut self, lo: Span, attrs: AttrWrapper) -> PResult<'a, Stmt> {
         self.collect_tokens_trailing_token(attrs, ForceCollect::No, |this, attrs| {
             let local = this.parse_local(attrs.into())?;
             // FIXME - maybe capture semicolon in recovery?
             Ok((
                 this.mk_stmt(lo.to(this.prev_token.span), StmtKind::Local(local)),
                 TrailingToken::None,
             ))
         })
     }

     /// Parses a local variable declaration.
     fn parse_local(&mut self, attrs: AttrVec) -> PResult<'a, P<Local>> {
         let lo = self.prev_token.span;
         let (pat, colon) = self.parse_pat_before_ty(None, RecoverComma::Yes, "`let` bindings")?;

         let (err, ty) = if colon {
             // Save the state of the parser before parsing type normally, in case there is a `:`
             // instead of an `=` typo.
             let parser_snapshot_before_type = self.clone();
             let colon_sp = self.prev_token.span;
             match self.parse_ty() {
                 Ok(ty) => (None, Some(ty)),
                 Err(mut err) => {
                     if let Ok(snip) = self.span_to_snippet(pat.span) {
                         err.span_label(pat.span, format!("while parsing the type for `{}`", snip));
                     }
                     let err = if self.check(&token::Eq) {
                         err.emit();
                         None
                     } else {
                         // Rewind to before attempting to parse the type and continue parsing.
                         let parser_snapshot_after_type =
                             mem::replace(self, parser_snapshot_before_type);
                         Some((parser_snapshot_after_type, colon_sp, err))
                     };
                     (err, None)
                 }
             }
         } else {
             (None, None)
         };
         let init = match (self.parse_initializer(err.is_some()), err) {
             (Ok(init), None) => {
                 // init parsed, ty parsed
                 init
             }
             (Ok(init), Some((_, colon_sp, mut err))) => {
                 // init parsed, ty error
                 // Could parse the type as if it were the initializer, it is likely there was a
                 // typo in the code: `:` instead of `=`. Add suggestion and emit the error.
                 err.span_suggestion_short(
                     colon_sp,
                     "use `=` if you meant to assign",
                     " =".to_string(),
                     Applicability::MachineApplicable,
                 );
                 err.emit();
                 // As this was parsed successfully, continue as if the code has been fixed for the
                 // rest of the file. It will still fail due to the emitted error, but we avoid
                 // extra noise.
                 init
             }
             (Err(mut init_err), Some((snapshot, _, ty_err))) => {
                 // init error, ty error
                 init_err.cancel();
                 // Couldn't parse the type nor the initializer, only raise the type error and
                 // return to the parser state before parsing the type as the initializer.
                 // let x: <parse_error>;
                 *self = snapshot;
                 return Err(ty_err);
             }
             (Err(err), None) => {
                 // init error, ty parsed
                 // Couldn't parse the initializer and we're not attempting to recover a failed
                 // parse of the type, return the error.
                 return Err(err);
             }
         };
         let kind = match init {
             None => LocalKind::Decl,
             Some(init) => {
                 if self.eat_keyword(kw::Else) {
                     let els = self.parse_block()?;
                     self.check_let_else_init_bool_expr(&init);
                     self.check_let_else_init_trailing_brace(&init);
                     LocalKind::InitElse(init, els)
                 } else {
                     LocalKind::Init(init)
                 }
             }
         };
         let hi = if self.token == token::Semi { self.token.span } else { self.prev_token.span };
         Ok(P(ast::Local { ty, pat, kind, id: DUMMY_NODE_ID, span: lo.to(hi), attrs, tokens: None }))
     }

     fn check_let_else_init_bool_expr(&self, init: &ast::Expr) {
         if let ast::ExprKind::Binary(op, ..) = init.kind {
             if op.node.lazy() {
                 let suggs = vec![
                     (init.span.shrink_to_lo(), "(".to_string()),
                     (init.span.shrink_to_hi(), ")".to_string()),
                 ];
                 self.struct_span_err(
                     init.span,
                     &format!(
                         "a `{}` expression cannot be directly assigned in `let...else`",
                         op.node.to_string()
                     ),
                 )
                 .multipart_suggestion(
                     "wrap the expression in parenthesis",
                     suggs,
                     Applicability::MachineApplicable,
                 )
                 .emit();
             }
         }
     }

     fn check_let_else_init_trailing_brace(&self, init: &ast::Expr) {
         if let Some(trailing) = classify::expr_trailing_brace(init) {
             let err_span = trailing.span.with_lo(trailing.span.hi() - BytePos(1));
             let suggs = vec![
                 (trailing.span.shrink_to_lo(), "(".to_string()),
                 (trailing.span.shrink_to_hi(), ")".to_string()),
             ];
             self.struct_span_err(
                 err_span,
                 "right curly brace `}` before `else` in a `let...else` statement not allowed",
             )
             .multipart_suggestion(
                 "try wrapping the expression in parenthesis",
                 suggs,
                 Applicability::MachineApplicable,
             )
             .emit();
         }
     }

     /// Parses the RHS of a local variable declaration (e.g., `= 14;`).
     fn parse_initializer(&mut self, eq_optional: bool) -> PResult<'a, Option<P<Expr>>> {
         let eq_consumed = match self.token.kind {
             token::BinOpEq(..) => {
                 // Recover `let x <op>= 1` as `let x = 1`
                 self.struct_span_err(
                     self.token.span,
                     "can't reassign to an uninitialized variable",
                 )
                 .span_suggestion_short(
                     self.token.span,
                     "initialize the variable",
                     "=".to_string(),
                     Applicability::MaybeIncorrect,
                 )
                 .help("if you meant to overwrite, remove the `let` binding")
                 .emit();
                 self.bump();
                 true
             }
             _ => self.eat(&token::Eq),
         };

         Ok(if eq_consumed || eq_optional { Some(self.parse_expr()?) } else { None })
     }

     /// Parses a block. No inner attributes are allowed.
     pub(super) fn parse_block(&mut self) -> PResult<'a, P<Block>> {
         let (attrs, block) = self.parse_inner_attrs_and_block()?;
         if let [.., last] = &*attrs {
             self.error_on_forbidden_inner_attr(last.span, DEFAULT_INNER_ATTR_FORBIDDEN);
         }
         Ok(block)
     }

     fn error_block_no_opening_brace<T>(&mut self) -> PResult<'a, T> {
         let sp = self.token.span;
         let tok = super::token_descr(&self.token);
         let mut e = self.struct_span_err(sp, &format!("expected `{{`, found {}", tok));
         let do_not_suggest_help = self.token.is_keyword(kw::In) || self.token == token::Colon;

         // Check to see if the user has written something like
         //
         //    if (cond)
         //      bar;
         //
         // which is valid in other languages, but not Rust.
         match self.parse_stmt_without_recovery(false, ForceCollect::No) {
             // If the next token is an open brace (e.g., `if a b {`), the place-
             // inside-a-block suggestion would be more likely wrong than right.
             Ok(Some(_))
                 if self.look_ahead(1, |t| t == &token::OpenDelim(token::Brace))
                     || do_not_suggest_help => {}
             Ok(Some(stmt)) => {
                 let stmt_own_line = self.sess.source_map().is_line_before_span_empty(sp);
                 let stmt_span = if stmt_own_line && self.eat(&token::Semi) {
                     // Expand the span to include the semicolon.
                     stmt.span.with_hi(self.prev_token.span.hi())
                 } else {
                     stmt.span
                 };
                 if let Ok(snippet) = self.span_to_snippet(stmt_span) {
                     e.span_suggestion(
                         stmt_span,
                         "try placing this code inside a block",
                         format!("{{ {} }}", snippet),
                         // Speculative; has been misleading in the past (#46836).
                         Applicability::MaybeIncorrect,
                     );
                 }
             }
             Err(mut e) => {
                 self.recover_stmt_(SemiColonMode::Break, BlockMode::Ignore);
                 e.cancel();
             }
             _ => {}
         }
         e.span_label(sp, "expected `{`");
         Err(e)
     }

     /// Parses a block. Inner attributes are allowed.
     pub(super) fn parse_inner_attrs_and_block(
         &mut self,
     ) -> PResult<'a, (Vec<Attribute>, P<Block>)> {
         self.parse_block_common(self.token.span, BlockCheckMode::Default)
     }

     /// Parses a block. Inner attributes are allowed.
     pub(super) fn parse_block_common(
         &mut self,
         lo: Span,
         blk_mode: BlockCheckMode,
     ) -> PResult<'a, (Vec<Attribute>, P<Block>)> {
         maybe_whole!(self, NtBlock, |x| (Vec::new(), x));

         if !self.eat(&token::OpenDelim(token::Brace)) {
             return self.error_block_no_opening_brace();
         }

         let attrs = self.parse_inner_attributes()?;
         let tail = if let Some(tail) = self.maybe_suggest_struct_literal(lo, blk_mode) {
             tail?
         } else {
             self.parse_block_tail(lo, blk_mode, AttemptLocalParseRecovery::Yes)?
         };
         Ok((attrs, tail))
     }

     /// Parses the rest of a block expression or function body.
     /// Precondition: already parsed the '{'.
     crate fn parse_block_tail(
         &mut self,
         lo: Span,
         s: BlockCheckMode,
         recover: AttemptLocalParseRecovery,
     ) -> PResult<'a, P<Block>> {
         let mut stmts = vec![];
         while !self.eat(&token::CloseDelim(token::Brace)) {
             if self.token == token::Eof {
                 break;
             }
             let stmt = match self.parse_full_stmt(recover) {
                 Err(mut err) if recover.yes() => {
                     self.maybe_annotate_with_ascription(&mut err, false);
                     err.emit();
                     self.recover_stmt_(SemiColonMode::Ignore, BlockMode::Ignore);
                     Some(self.mk_stmt_err(self.token.span))
                 }
                 Ok(stmt) => stmt,
                 Err(err) => return Err(err),
             };
             if let Some(stmt) = stmt {
                 stmts.push(stmt);
             } else {
                 // Found only `;` or `}`.
                 continue;
             };
         }
         Ok(self.mk_block(stmts, s, lo.to(self.prev_token.span)))
     }

     /// Parses a statement, including the trailing semicolon.
     pub fn parse_full_stmt(
         &mut self,
         recover: AttemptLocalParseRecovery,
     ) -> PResult<'a, Option<Stmt>> {
         // Skip looking for a trailing semicolon when we have an interpolated statement.
         maybe_whole!(self, NtStmt, |x| Some(x));

         let mut stmt = match self.parse_stmt_without_recovery(true, ForceCollect::No)? {
             Some(stmt) => stmt,
             None => return Ok(None),
         };

         let mut eat_semi = true;
         match stmt.kind {
             // Expression without semicolon.
             StmtKind::Expr(ref mut expr)
                 if self.token != token::Eof && classify::expr_requires_semi_to_be_stmt(expr) =>
             {
                 // Just check for errors and recover; do not eat semicolon yet.
                 if let Err(mut e) =
                     self.expect_one_of(&[], &[token::Semi, token::CloseDelim(token::Brace)])
                 {
                     if let TokenKind::DocComment(..) = self.token.kind {
                         if let Ok(snippet) = self.span_to_snippet(self.token.span) {
                             let sp = self.token.span;
                             let marker = &snippet[..3];
                             let (comment_marker, doc_comment_marker) = marker.split_at(2);

                             e.span_suggestion(
                                 sp.with_hi(sp.lo() + BytePos(marker.len() as u32)),
                                 &format!(
                                     "add a space before `{}` to use a regular comment",
                                     doc_comment_marker,
                                 ),
                                 format!("{} {}", comment_marker, doc_comment_marker),
                                 Applicability::MaybeIncorrect,
                             );
                         }
                     }
                     if let Err(mut e) =
                         self.check_mistyped_turbofish_with_multiple_type_params(e, expr)
                     {
                         if recover.no() {
                             return Err(e);
                         }
                         e.emit();
                         self.recover_stmt();
                     }
                     // Don't complain about type errors in body tail after parse error (#57383).
                     let sp = expr.span.to(self.prev_token.span);
                     *expr = self.mk_expr_err(sp);
                 }
             }
             StmtKind::Expr(_) | StmtKind::MacCall(_) => {}
             StmtKind::Local(ref mut local) if let Err(e) = self.expect_semi() => {
                 // We might be at the `,` in `let x = foo<bar, baz>;`. Try to recover.
                 match &mut local.kind {
                     LocalKind::Init(expr) | LocalKind::InitElse(expr, _) => {
                             self.check_mistyped_turbofish_with_multiple_type_params(e, expr)?;
                             // We found `foo<bar, baz>`, have we fully recovered?
                             self.expect_semi()?;
                         }
                         LocalKind::Decl => return Err(e),
                 }
                 eat_semi = false;
             }
             StmtKind::Empty | StmtKind::Item(_) | StmtKind::Local(_) | StmtKind::Semi(_) => eat_semi = false,
         }

         if eat_semi && self.eat(&token::Semi) {
             stmt = stmt.add_trailing_semicolon();
         }
         stmt.span = stmt.span.to(self.prev_token.span);
         Ok(Some(stmt))
     }

     pub(super) fn mk_block(&self, stmts: Vec<Stmt>, rules: BlockCheckMode, span: Span) -> P<Block> {
         P(Block {
             stmts,
             id: DUMMY_NODE_ID,
             rules,
             span,
             tokens: None,
             could_be_bare_literal: false,
         })
     }

     pub(super) fn mk_stmt(&self, span: Span, kind: StmtKind) -> Stmt {
         Stmt { id: DUMMY_NODE_ID, kind, span }
     }

     pub(super) fn mk_stmt_err(&self, span: Span) -> Stmt {
         self.mk_stmt(span, StmtKind::Expr(self.mk_expr_err(span)))
     }

     pub(super) fn mk_block_err(&self, span: Span) -> P<Block> {
         self.mk_block(vec![self.mk_stmt_err(span)], BlockCheckMode::Default, span)
     }
 }
	use super::attr::DEFAULT_INNER_ATTR_FORBIDDEN;
	use super::diagnostics::{AttemptLocalParseRecovery, Error};
	use super::expr::LhsExpr;
	use super::pat::RecoverComma;
	use super::path::PathStyle;
	use super::TrailingToken;
	use super::{AttrWrapper, BlockMode, ForceCollect, Parser, Restrictions, SemiColonMode};
	use crate::maybe_whole;

	use rustc_ast as ast;
	use rustc_ast::ptr::P;
	use rustc_ast::token::{self, TokenKind};
	use rustc_ast::util::classify;
	use rustc_ast::{
	AstLike, AttrStyle, AttrVec, Attribute, LocalKind, MacCall, MacCallStmt, MacStmtStyle,
	};
	use rustc_ast::{Block, BlockCheckMode, Expr, ExprKind, Local, Stmt};
	use rustc_ast::{StmtKind, DUMMY_NODE_ID};
	use rustc_errors::{Applicability, PResult};
	use rustc_span::source_map::{BytePos, Span};
	use rustc_span::symbol::{kw, sym};

	use std::mem;

	impl<'a> Parser<'a> {
	/// Parses a statement. This stops just before trailing semicolons on everything but items.
	/// e.g., a `StmtKind::Semi` parses to a `StmtKind::Expr`, leaving the trailing `;` unconsumed.
	// Public for rustfmt usage.
	pub fn parse_stmt(&mut self, force_collect: ForceCollect) -> PResult<'a, Option<Stmt>> {
	Ok(self.parse_stmt_without_recovery(false, force_collect).unwrap_or_else(\|mut e\| {
	e.emit();
	self.recover_stmt_(SemiColonMode::Break, BlockMode::Ignore);
	None
	}))
	}

	/// If `force_capture` is true, forces collection of tokens regardless of whether
	/// or not we have attributes
	crate fn parse_stmt_without_recovery(
	&mut self,
	capture_semi: bool,
	force_collect: ForceCollect,
	) -> PResult<'a, Option<Stmt>> {
	let attrs = self.parse_outer_attributes()?;
	let lo = self.token.span;

	// Don't use `maybe_whole` so that we have precise control
	// over when we bump the parser
	if let token::Interpolated(nt) = &self.token.kind {
	if let token::NtStmt(stmt) = &**nt {
	let mut stmt = stmt.clone();
	self.bump();
	stmt.visit_attrs(\|stmt_attrs\| {
	attrs.prepend_to_nt_inner(stmt_attrs);
	});
	return Ok(Some(stmt));
	}
	}

	Ok(Some(if self.token.is_keyword(kw::Let) {
	self.parse_local_mk(lo, attrs, capture_semi, force_collect)?
	} else if self.is_kw_followed_by_ident(kw::Mut) {
	self.recover_stmt_local(lo, attrs, "missing keyword", "let mut")?
	} else if self.is_kw_followed_by_ident(kw::Auto) {
	self.bump(); // `auto`
	let msg = "write `let` instead of `auto` to introduce a new variable";
	self.recover_stmt_local(lo, attrs, msg, "let")?
	} else if self.is_kw_followed_by_ident(sym::var) {
	self.bump(); // `var`
	let msg = "write `let` instead of `var` to introduce a new variable";
	self.recover_stmt_local(lo, attrs, msg, "let")?
	} else if self.check_path() && !self.token.is_qpath_start() && !self.is_path_start_item() {
	// We have avoided contextual keywords like `union`, items with `crate` visibility,
	// or `auto trait` items. We aim to parse an arbitrary path `a::b` but not something
	// that starts like a path (1 token), but it fact not a path.
	// Also, we avoid stealing syntax from `parse_item_`.
	if force_collect == ForceCollect::Yes {
	self.collect_tokens_no_attrs(\|this\| this.parse_stmt_path_start(lo, attrs))
	} else {
	self.parse_stmt_path_start(lo, attrs)
	}?
	} else if let Some(item) =
	self.parse_item_common(attrs.clone(), false, true, \|_\| true, force_collect)?
	{
	// FIXME: Bad copy of attrs
	self.mk_stmt(lo.to(item.span), StmtKind::Item(P(item)))
	} else if self.eat(&token::Semi) {
	// Do not attempt to parse an expression if we're done here.
	self.error_outer_attrs(&attrs.take_for_recovery());
	self.mk_stmt(lo, StmtKind::Empty)
	} else if self.token != token::CloseDelim(token::Brace) {
	// Remainder are line-expr stmts.
	let e = if force_collect == ForceCollect::Yes {
	self.collect_tokens_no_attrs(\|this\| {
	this.parse_expr_res(Restrictions::STMT_EXPR, Some(attrs))
	})
	} else {
	self.parse_expr_res(Restrictions::STMT_EXPR, Some(attrs))
	}?;
	self.mk_stmt(lo.to(e.span), StmtKind::Expr(e))
	} else {
	self.error_outer_attrs(&attrs.take_for_recovery());
	return Ok(None);
	}))
	}

	fn parse_stmt_path_start(&mut self, lo: Span, attrs: AttrWrapper) -> PResult<'a, Stmt> {
	let stmt = self.collect_tokens_trailing_token(attrs, ForceCollect::No, \|this, attrs\| {
	let path = this.parse_path(PathStyle::Expr)?;

	if this.eat(&token::Not) {
	let stmt_mac = this.parse_stmt_mac(lo, attrs.into(), path)?;
	if this.token == token::Semi {
	return Ok((stmt_mac, TrailingToken::Semi));
	} else {
	return Ok((stmt_mac, TrailingToken::None));
	}
	}

	let expr = if this.eat(&token::OpenDelim(token::Brace)) {
	this.parse_struct_expr(None, path, AttrVec::new(), true)?
	} else {
	let hi = this.prev_token.span;
	this.mk_expr(lo.to(hi), ExprKind::Path(None, path), AttrVec::new())
	};

	let expr = this.with_res(Restrictions::STMT_EXPR, \|this\| {
	this.parse_dot_or_call_expr_with(expr, lo, attrs)
	})?;
	// `DUMMY_SP` will get overwritten later in this function
	Ok((this.mk_stmt(rustc_span::DUMMY_SP, StmtKind::Expr(expr)), TrailingToken::None))
	})?;

	if let StmtKind::Expr(expr) = stmt.kind {
	// Perform this outside of the `collect_tokens_trailing_token` closure,
	// since our outer attributes do not apply to this part of the expression
	let expr = self.with_res(Restrictions::STMT_EXPR, \|this\| {
	this.parse_assoc_expr_with(0, LhsExpr::AlreadyParsed(expr))
	})?;
	Ok(self.mk_stmt(lo.to(self.prev_token.span), StmtKind::Expr(expr)))
	} else {
	Ok(stmt)
	}
	}

	/// Parses a statement macro `mac!(args)` provided a `path` representing `mac`.
	/// At this point, the `!` token after the path has already been eaten.
	fn parse_stmt_mac(&mut self, lo: Span, attrs: AttrVec, path: ast::Path) -> PResult<'a, Stmt> {
	let args = self.parse_mac_args()?;
	let delim = args.delim();
	let hi = self.prev_token.span;

	let style =
	if delim == token::Brace { MacStmtStyle::Braces } else { MacStmtStyle::NoBraces };

	let mac = MacCall { path, args, prior_type_ascription: self.last_type_ascription };

	let kind = if delim == token::Brace \|\| self.token == token::Semi \|\| self.token == token::Eof
	{
	StmtKind::MacCall(P(MacCallStmt { mac, style, attrs, tokens: None }))
	} else {
	// Since none of the above applied, this is an expression statement macro.
	let e = self.mk_expr(lo.to(hi), ExprKind::MacCall(mac), AttrVec::new());
	let e = self.maybe_recover_from_bad_qpath(e, true)?;
	let e = self.parse_dot_or_call_expr_with(e, lo, attrs.into())?;
	let e = self.parse_assoc_expr_with(0, LhsExpr::AlreadyParsed(e))?;
	StmtKind::Expr(e)
	};
	Ok(self.mk_stmt(lo.to(hi), kind))
	}

	/// Error on outer attributes in this context.
	/// Also error if the previous token was a doc comment.
	fn error_outer_attrs(&self, attrs: &[Attribute]) {
	if let [.., last] = attrs {
	if last.is_doc_comment() {
	self.span_err(last.span, Error::UselessDocComment).emit();
	} else if attrs.iter().any(\|a\| a.style == AttrStyle::Outer) {
	self.struct_span_err(last.span, "expected statement after outer attribute").emit();
	}
	}
	}

	fn recover_stmt_local(
	&mut self,
	lo: Span,
	attrs: AttrWrapper,
	msg: &str,
	sugg: &str,
	) -> PResult<'a, Stmt> {
	let stmt = self.recover_local_after_let(lo, attrs)?;
	self.struct_span_err(lo, "invalid variable declaration")
	.span_suggestion(lo, msg, sugg.to_string(), Applicability::MachineApplicable)
	.emit();
	Ok(stmt)
	}

	fn parse_local_mk(
	&mut self,
	lo: Span,
	attrs: AttrWrapper,
	capture_semi: bool,
	force_collect: ForceCollect,
	) -> PResult<'a, Stmt> {
	self.collect_tokens_trailing_token(attrs, force_collect, \|this, attrs\| {
	this.expect_keyword(kw::Let)?;
	let local = this.parse_local(attrs.into())?;
	let trailing = if capture_semi && this.token.kind == token::Semi {
	TrailingToken::Semi
	} else {
	TrailingToken::None
	};
	Ok((this.mk_stmt(lo.to(this.prev_token.span), StmtKind::Local(local)), trailing))
	})
	}

	fn recover_local_after_let(&mut self, lo: Span, attrs: AttrWrapper) -> PResult<'a, Stmt> {
	self.collect_tokens_trailing_token(attrs, ForceCollect::No, \|this, attrs\| {
	let local = this.parse_local(attrs.into())?;
	// FIXME - maybe capture semicolon in recovery?
	Ok((
	this.mk_stmt(lo.to(this.prev_token.span), StmtKind::Local(local)),
	TrailingToken::None,
	))
	})
	}

	/// Parses a local variable declaration.
	fn parse_local(&mut self, attrs: AttrVec) -> PResult<'a, P<Local>> {
	let lo = self.prev_token.span;
	let (pat, colon) = self.parse_pat_before_ty(None, RecoverComma::Yes, "`let` bindings")?;

	let (err, ty) = if colon {
	// Save the state of the parser before parsing type normally, in case there is a `:`
	// instead of an `=` typo.
	let parser_snapshot_before_type = self.clone();
	let colon_sp = self.prev_token.span;
	match self.parse_ty() {
	Ok(ty) => (None, Some(ty)),
	Err(mut err) => {
	if let Ok(snip) = self.span_to_snippet(pat.span) {
	err.span_label(pat.span, format!("while parsing the type for `{}`", snip));
	}
	let err = if self.check(&token::Eq) {
	err.emit();
	None
	} else {
	// Rewind to before attempting to parse the type and continue parsing.
	let parser_snapshot_after_type =
	mem::replace(self, parser_snapshot_before_type);
	Some((parser_snapshot_after_type, colon_sp, err))
	};
	(err, None)
	}
	}
	} else {
	(None, None)
	};
	let init = match (self.parse_initializer(err.is_some()), err) {
	(Ok(init), None) => {
	// init parsed, ty parsed
	init
	}
	(Ok(init), Some((_, colon_sp, mut err))) => {
	// init parsed, ty error
	// Could parse the type as if it were the initializer, it is likely there was a
	// typo in the code: `:` instead of `=`. Add suggestion and emit the error.
	err.span_suggestion_short(
	colon_sp,
	"use `=` if you meant to assign",
	" =".to_string(),
	Applicability::MachineApplicable,
	);
	err.emit();
	// As this was parsed successfully, continue as if the code has been fixed for the
	// rest of the file. It will still fail due to the emitted error, but we avoid
	// extra noise.
	init
	}
	(Err(mut init_err), Some((snapshot, _, ty_err))) => {
	// init error, ty error
	init_err.cancel();
	// Couldn't parse the type nor the initializer, only raise the type error and
	// return to the parser state before parsing the type as the initializer.
	// let x: <parse_error>;
	*self = snapshot;
	return Err(ty_err);
	}
	(Err(err), None) => {
	// init error, ty parsed
	// Couldn't parse the initializer and we're not attempting to recover a failed
	// parse of the type, return the error.
	return Err(err);
	}
	};
	let kind = match init {
	None => LocalKind::Decl,
	Some(init) => {
	if self.eat_keyword(kw::Else) {
	let els = self.parse_block()?;
	self.check_let_else_init_bool_expr(&init);
	self.check_let_else_init_trailing_brace(&init);
	LocalKind::InitElse(init, els)
	} else {
	LocalKind::Init(init)
	}
	}
	};
	let hi = if self.token == token::Semi { self.token.span } else { self.prev_token.span };
	Ok(P(ast::Local { ty, pat, kind, id: DUMMY_NODE_ID, span: lo.to(hi), attrs, tokens: None }))
	}

	fn check_let_else_init_bool_expr(&self, init: &ast::Expr) {
	if let ast::ExprKind::Binary(op, ..) = init.kind {
	if op.node.lazy() {
	let suggs = vec![
	(init.span.shrink_to_lo(), "(".to_string()),
	(init.span.shrink_to_hi(), ")".to_string()),
	];
	self.struct_span_err(
	init.span,
	&format!(
	"a `{}` expression cannot be directly assigned in `let...else`",
	op.node.to_string()
	),
	)
	.multipart_suggestion(
	"wrap the expression in parenthesis",
	suggs,
	Applicability::MachineApplicable,
	)
	.emit();
	}
	}
	}

	fn check_let_else_init_trailing_brace(&self, init: &ast::Expr) {
	if let Some(trailing) = classify::expr_trailing_brace(init) {
	let err_span = trailing.span.with_lo(trailing.span.hi() - BytePos(1));
	let suggs = vec![
	(trailing.span.shrink_to_lo(), "(".to_string()),
	(trailing.span.shrink_to_hi(), ")".to_string()),
	];
	self.struct_span_err(
	err_span,
	"right curly brace `}` before `else` in a `let...else` statement not allowed",
	)
	.multipart_suggestion(
	"try wrapping the expression in parenthesis",
	suggs,
	Applicability::MachineApplicable,
	)
	.emit();
	}
	}

	/// Parses the RHS of a local variable declaration (e.g., `= 14;`).
	fn parse_initializer(&mut self, eq_optional: bool) -> PResult<'a, Option<P<Expr>>> {
	let eq_consumed = match self.token.kind {
	token::BinOpEq(..) => {
	// Recover `let x <op>= 1` as `let x = 1`
	self.struct_span_err(
	self.token.span,
	"can't reassign to an uninitialized variable",
	)
	.span_suggestion_short(
	self.token.span,
	"initialize the variable",
	"=".to_string(),
	Applicability::MaybeIncorrect,
	)
	.help("if you meant to overwrite, remove the `let` binding")
	.emit();
	self.bump();
	true
	}
	_ => self.eat(&token::Eq),
	};

	Ok(if eq_consumed \|\| eq_optional { Some(self.parse_expr()?) } else { None })
	}

	/// Parses a block. No inner attributes are allowed.
	pub(super) fn parse_block(&mut self) -> PResult<'a, P<Block>> {
	let (attrs, block) = self.parse_inner_attrs_and_block()?;
	if let [.., last] = &*attrs {
	self.error_on_forbidden_inner_attr(last.span, DEFAULT_INNER_ATTR_FORBIDDEN);
	}
	Ok(block)
	}

	fn error_block_no_opening_brace<T>(&mut self) -> PResult<'a, T> {
	let sp = self.token.span;
	let tok = super::token_descr(&self.token);
	let mut e = self.struct_span_err(sp, &format!("expected `{{`, found {}", tok));
	let do_not_suggest_help = self.token.is_keyword(kw::In) \|\| self.token == token::Colon;

	// Check to see if the user has written something like
	//
	// if (cond)
	// bar;
	//
	// which is valid in other languages, but not Rust.
	match self.parse_stmt_without_recovery(false, ForceCollect::No) {
	// If the next token is an open brace (e.g., `if a b {`), the place-
	// inside-a-block suggestion would be more likely wrong than right.
	Ok(Some(_))
	if self.look_ahead(1, \|t\| t == &token::OpenDelim(token::Brace))
	\|\| do_not_suggest_help => {}
	Ok(Some(stmt)) => {
	let stmt_own_line = self.sess.source_map().is_line_before_span_empty(sp);
	let stmt_span = if stmt_own_line && self.eat(&token::Semi) {
	// Expand the span to include the semicolon.
	stmt.span.with_hi(self.prev_token.span.hi())
	} else {
	stmt.span
	};
	if let Ok(snippet) = self.span_to_snippet(stmt_span) {
	e.span_suggestion(
	stmt_span,
	"try placing this code inside a block",
	format!("{{ {} }}", snippet),
	// Speculative; has been misleading in the past (#46836).
	Applicability::MaybeIncorrect,
	);
	}
	}
	Err(mut e) => {
	self.recover_stmt_(SemiColonMode::Break, BlockMode::Ignore);
	e.cancel();
	}
	_ => {}
	}
	e.span_label(sp, "expected `{`");
	Err(e)
	}

	/// Parses a block. Inner attributes are allowed.
	pub(super) fn parse_inner_attrs_and_block(
	&mut self,
	) -> PResult<'a, (Vec<Attribute>, P<Block>)> {
	self.parse_block_common(self.token.span, BlockCheckMode::Default)
	}

	/// Parses a block. Inner attributes are allowed.
	pub(super) fn parse_block_common(
	&mut self,
	lo: Span,
	blk_mode: BlockCheckMode,
	) -> PResult<'a, (Vec<Attribute>, P<Block>)> {
	maybe_whole!(self, NtBlock, \|x\| (Vec::new(), x));

	if !self.eat(&token::OpenDelim(token::Brace)) {
	return self.error_block_no_opening_brace();
	}

	let attrs = self.parse_inner_attributes()?;
	let tail = if let Some(tail) = self.maybe_suggest_struct_literal(lo, blk_mode) {
	tail?
	} else {
	self.parse_block_tail(lo, blk_mode, AttemptLocalParseRecovery::Yes)?
	};
	Ok((attrs, tail))
	}

	/// Parses the rest of a block expression or function body.
	/// Precondition: already parsed the '{'.
	crate fn parse_block_tail(
	&mut self,
	lo: Span,
	s: BlockCheckMode,
	recover: AttemptLocalParseRecovery,
	) -> PResult<'a, P<Block>> {
	let mut stmts = vec![];
	while !self.eat(&token::CloseDelim(token::Brace)) {
	if self.token == token::Eof {
	break;
	}
	let stmt = match self.parse_full_stmt(recover) {
	Err(mut err) if recover.yes() => {
	self.maybe_annotate_with_ascription(&mut err, false);
	err.emit();
	self.recover_stmt_(SemiColonMode::Ignore, BlockMode::Ignore);
	Some(self.mk_stmt_err(self.token.span))
	}
	Ok(stmt) => stmt,
	Err(err) => return Err(err),
	};
	if let Some(stmt) = stmt {
	stmts.push(stmt);
	} else {
	// Found only `;` or `}`.
	continue;
	};
	}
	Ok(self.mk_block(stmts, s, lo.to(self.prev_token.span)))
	}

	/// Parses a statement, including the trailing semicolon.
	pub fn parse_full_stmt(
	&mut self,
	recover: AttemptLocalParseRecovery,
	) -> PResult<'a, Option<Stmt>> {
	// Skip looking for a trailing semicolon when we have an interpolated statement.
	maybe_whole!(self, NtStmt, \|x\| Some(x));

	let mut stmt = match self.parse_stmt_without_recovery(true, ForceCollect::No)? {
	Some(stmt) => stmt,
	None => return Ok(None),
	};

	let mut eat_semi = true;
	match stmt.kind {
	// Expression without semicolon.
	StmtKind::Expr(ref mut expr)
	if self.token != token::Eof && classify::expr_requires_semi_to_be_stmt(expr) =>
	{
	// Just check for errors and recover; do not eat semicolon yet.
	if let Err(mut e) =
	self.expect_one_of(&[], &[token::Semi, token::CloseDelim(token::Brace)])
	{
	if let TokenKind::DocComment(..) = self.token.kind {
	if let Ok(snippet) = self.span_to_snippet(self.token.span) {
	let sp = self.token.span;
	let marker = &snippet[..3];
	let (comment_marker, doc_comment_marker) = marker.split_at(2);

	e.span_suggestion(
	sp.with_hi(sp.lo() + BytePos(marker.len() as u32)),
	&format!(
	"add a space before `{}` to use a regular comment",
	doc_comment_marker,
	),
	format!("{} {}", comment_marker, doc_comment_marker),
	Applicability::MaybeIncorrect,
	);
	}
	}
	if let Err(mut e) =
	self.check_mistyped_turbofish_with_multiple_type_params(e, expr)
	{
	if recover.no() {
	return Err(e);
	}
	e.emit();
	self.recover_stmt();
	}
	// Don't complain about type errors in body tail after parse error (#57383).
	let sp = expr.span.to(self.prev_token.span);
	*expr = self.mk_expr_err(sp);
	}
	}
	StmtKind::Expr(_) \| StmtKind::MacCall(_) => {}
	StmtKind::Local(ref mut local) if let Err(e) = self.expect_semi() => {
	// We might be at the `,` in `let x = foo<bar, baz>;`. Try to recover.
	match &mut local.kind {
	LocalKind::Init(expr) \| LocalKind::InitElse(expr, _) => {
	self.check_mistyped_turbofish_with_multiple_type_params(e, expr)?;
	// We found `foo<bar, baz>`, have we fully recovered?
	self.expect_semi()?;
	}
	LocalKind::Decl => return Err(e),
	}
	eat_semi = false;
	}
	StmtKind::Empty \| StmtKind::Item(_) \| StmtKind::Local(_) \| StmtKind::Semi(_) => eat_semi = false,
	}

	if eat_semi && self.eat(&token::Semi) {
	stmt = stmt.add_trailing_semicolon();
	}
	stmt.span = stmt.span.to(self.prev_token.span);
	Ok(Some(stmt))
	}

	pub(super) fn mk_block(&self, stmts: Vec<Stmt>, rules: BlockCheckMode, span: Span) -> P<Block> {
	P(Block {
	stmts,
	id: DUMMY_NODE_ID,
	rules,
	span,
	tokens: None,
	could_be_bare_literal: false,
	})
	}

	pub(super) fn mk_stmt(&self, span: Span, kind: StmtKind) -> Stmt {
	Stmt { id: DUMMY_NODE_ID, kind, span }
	}

	pub(super) fn mk_stmt_err(&self, span: Span) -> Stmt {
	self.mk_stmt(span, StmtKind::Expr(self.mk_expr_err(span)))
	}

	pub(super) fn mk_block_err(&self, span: Span) -> P<Block> {
	self.mk_block(vec![self.mk_stmt_err(span)], BlockCheckMode::Default, span)
	}
	}