mikros/rust
1
0
Fork 0
Code Issues Pull Requests Packages Projects Releases Wiki Activity
7df0052df8
rust/compiler/rustc_expand/src/expand.rs
Guillaume Gomez 7df0052df8 Created NestedMetaItem::name_value_literal_span method
2020-12-01 16:26:51 +01:00

1716 lines
67 KiB
Rust
Raw Blame History

This file contains ambiguous Unicode characters

This file contains Unicode characters that might be confused with other characters. If you think that this is intentional, you can safely ignore this warning. Use the Escape button to reveal them.

use crate::base::*;
use crate::config::StripUnconfigured;
use crate::configure;
use crate::hygiene::{ExpnData, ExpnKind, SyntaxContext};
use crate::mbe::macro_rules::annotate_err_with_kind;
use crate::module::{parse_external_mod, push_directory, Directory, DirectoryOwnership};
use crate::placeholders::{placeholder, PlaceholderExpander};
use crate::proc_macro::collect_derives;
use rustc_ast::mut_visit::*;
use rustc_ast::ptr::P;
use rustc_ast::token;
use rustc_ast::tokenstream::TokenStream;
use rustc_ast::visit::{self, AssocCtxt, Visitor};
use rustc_ast::{self as ast, AttrItem, Block, LitKind, NodeId, PatKind, Path};
use rustc_ast::{ItemKind, MacArgs, MacCallStmt, MacStmtStyle, StmtKind, Unsafe};
use rustc_ast_pretty::pprust;
use rustc_attr::{self as attr, is_builtin_attr, HasAttrs};
use rustc_data_structures::map_in_place::MapInPlace;
use rustc_data_structures::stack::ensure_sufficient_stack;
use rustc_errors::{struct_span_err, Applicability, PResult};
use rustc_feature::Features;
use rustc_parse::parser::{AttemptLocalParseRecovery, Parser};
use rustc_parse::validate_attr;
use rustc_session::lint::builtin::UNUSED_DOC_COMMENTS;
use rustc_session::lint::BuiltinLintDiagnostics;
use rustc_session::parse::{feature_err, ParseSess};
use rustc_session::Limit;
use rustc_span::symbol::{sym, Ident, Symbol};
use rustc_span::{ExpnId, FileName, Span, DUMMY_SP};
use smallvec::{smallvec, SmallVec};
use std::io::ErrorKind;
use std::ops::DerefMut;
use std::path::PathBuf;
use std::rc::Rc;
use std::{iter, mem, slice};
macro_rules! ast_fragments {
(
$($Kind:ident($AstTy:ty) {
$kind_name:expr;
$(one fn $mut_visit_ast:ident; fn $visit_ast:ident;)?
$(many fn $flat_map_ast_elt:ident; fn $visit_ast_elt:ident($($args:tt)*);)?
fn $make_ast:ident;
})*
) => {
/// A fragment of AST that can be produced by a single macro expansion.
/// Can also serve as an input and intermediate result for macro expansion operations.
pub enum AstFragment {
OptExpr(Option<P<ast::Expr>>),
$($Kind($AstTy),)*
}
/// "Discriminant" of an AST fragment.
#[derive(Copy, Clone, PartialEq, Eq)]
pub enum AstFragmentKind {
OptExpr,
$($Kind,)*
}
impl AstFragmentKind {
pub fn name(self) -> &'static str {
match self {
AstFragmentKind::OptExpr => "expression",
$(AstFragmentKind::$Kind => $kind_name,)*
}
}
fn make_from<'a>(self, result: Box<dyn MacResult + 'a>) -> Option<AstFragment> {
match self {
AstFragmentKind::OptExpr =>
result.make_expr().map(Some).map(AstFragment::OptExpr),
$(AstFragmentKind::$Kind => result.$make_ast().map(AstFragment::$Kind),)*
}
}
}
impl AstFragment {
pub fn add_placeholders(&mut self, placeholders: &[NodeId]) {
if placeholders.is_empty() {
return;
}
match self {
$($(AstFragment::$Kind(ast) => ast.extend(placeholders.iter().flat_map(|id| {
// We are repeating through arguments with `many`, to do that we have to
// mention some macro variable from those arguments even if it's not used.
macro _repeating($flat_map_ast_elt) {}
placeholder(AstFragmentKind::$Kind, *id, None).$make_ast()
})),)?)*
_ => panic!("unexpected AST fragment kind")
}
}
pub fn make_opt_expr(self) -> Option<P<ast::Expr>> {
match self {
AstFragment::OptExpr(expr) => expr,
_ => panic!("AstFragment::make_* called on the wrong kind of fragment"),
}
}
$(pub fn $make_ast(self) -> $AstTy {
match self {
AstFragment::$Kind(ast) => ast,
_ => panic!("AstFragment::make_* called on the wrong kind of fragment"),
}
})*
pub fn mut_visit_with<F: MutVisitor>(&mut self, vis: &mut F) {
match self {
AstFragment::OptExpr(opt_expr) => {
visit_clobber(opt_expr, |opt_expr| {
if let Some(expr) = opt_expr {
vis.filter_map_expr(expr)
} else {
None
}
});
}
$($(AstFragment::$Kind(ast) => vis.$mut_visit_ast(ast),)?)*
$($(AstFragment::$Kind(ast) =>
ast.flat_map_in_place(|ast| vis.$flat_map_ast_elt(ast)),)?)*
}
}
pub fn visit_with<'a, V: Visitor<'a>>(&'a self, visitor: &mut V) {
match *self {
AstFragment::OptExpr(Some(ref expr)) => visitor.visit_expr(expr),
AstFragment::OptExpr(None) => {}
$($(AstFragment::$Kind(ref ast) => visitor.$visit_ast(ast),)?)*
$($(AstFragment::$Kind(ref ast) => for ast_elt in &ast[..] {
visitor.$visit_ast_elt(ast_elt, $($args)*);
})?)*
}
}
}
impl<'a> MacResult for crate::mbe::macro_rules::ParserAnyMacro<'a> {
$(fn $make_ast(self: Box<crate::mbe::macro_rules::ParserAnyMacro<'a>>)
-> Option<$AstTy> {
Some(self.make(AstFragmentKind::$Kind).$make_ast())
})*
}
}
}
ast_fragments! {
Expr(P<ast::Expr>) { "expression"; one fn visit_expr; fn visit_expr; fn make_expr; }
Pat(P<ast::Pat>) { "pattern"; one fn visit_pat; fn visit_pat; fn make_pat; }
Ty(P<ast::Ty>) { "type"; one fn visit_ty; fn visit_ty; fn make_ty; }
Stmts(SmallVec<[ast::Stmt; 1]>) {
"statement"; many fn flat_map_stmt; fn visit_stmt(); fn make_stmts;
}
Items(SmallVec<[P<ast::Item>; 1]>) {
"item"; many fn flat_map_item; fn visit_item(); fn make_items;
}
TraitItems(SmallVec<[P<ast::AssocItem>; 1]>) {
"trait item";
many fn flat_map_trait_item;
fn visit_assoc_item(AssocCtxt::Trait);
fn make_trait_items;
}
ImplItems(SmallVec<[P<ast::AssocItem>; 1]>) {
"impl item";
many fn flat_map_impl_item;
fn visit_assoc_item(AssocCtxt::Impl);
fn make_impl_items;
}
ForeignItems(SmallVec<[P<ast::ForeignItem>; 1]>) {
"foreign item";
many fn flat_map_foreign_item;
fn visit_foreign_item();
fn make_foreign_items;
}
Arms(SmallVec<[ast::Arm; 1]>) {
"match arm"; many fn flat_map_arm; fn visit_arm(); fn make_arms;
}
Fields(SmallVec<[ast::Field; 1]>) {
"field expression"; many fn flat_map_field; fn visit_field(); fn make_fields;
}
FieldPats(SmallVec<[ast::FieldPat; 1]>) {
"field pattern";
many fn flat_map_field_pattern;
fn visit_field_pattern();
fn make_field_patterns;
}
GenericParams(SmallVec<[ast::GenericParam; 1]>) {
"generic parameter";
many fn flat_map_generic_param;
fn visit_generic_param();
fn make_generic_params;
}
Params(SmallVec<[ast::Param; 1]>) {
"function parameter"; many fn flat_map_param; fn visit_param(); fn make_params;
}
StructFields(SmallVec<[ast::StructField; 1]>) {
"field";
many fn flat_map_struct_field;
fn visit_struct_field();
fn make_struct_fields;
}
Variants(SmallVec<[ast::Variant; 1]>) {
"variant"; many fn flat_map_variant; fn visit_variant(); fn make_variants;
}
}
impl AstFragmentKind {
crate fn dummy(self, span: Span) -> AstFragment {
self.make_from(DummyResult::any(span)).expect("couldn't create a dummy AST fragment")
}
/// Fragment supports macro expansion and not just inert attributes, `cfg` and `cfg_attr`.
pub fn supports_macro_expansion(self) -> bool {
match self {
AstFragmentKind::OptExpr
| AstFragmentKind::Expr
| AstFragmentKind::Pat
| AstFragmentKind::Ty
| AstFragmentKind::Stmts
| AstFragmentKind::Items
| AstFragmentKind::TraitItems
| AstFragmentKind::ImplItems
| AstFragmentKind::ForeignItems => true,
AstFragmentKind::Arms
| AstFragmentKind::Fields
| AstFragmentKind::FieldPats
| AstFragmentKind::GenericParams
| AstFragmentKind::Params
| AstFragmentKind::StructFields
| AstFragmentKind::Variants => false,
}
}
fn expect_from_annotatables<I: IntoIterator<Item = Annotatable>>(
self,
items: I,
) -> AstFragment {
let mut items = items.into_iter();
match self {
AstFragmentKind::Arms => {
AstFragment::Arms(items.map(Annotatable::expect_arm).collect())
}
AstFragmentKind::Fields => {
AstFragment::Fields(items.map(Annotatable::expect_field).collect())
}
AstFragmentKind::FieldPats => {
AstFragment::FieldPats(items.map(Annotatable::expect_field_pattern).collect())
}
AstFragmentKind::GenericParams => {
AstFragment::GenericParams(items.map(Annotatable::expect_generic_param).collect())
}
AstFragmentKind::Params => {
AstFragment::Params(items.map(Annotatable::expect_param).collect())
}
AstFragmentKind::StructFields => {
AstFragment::StructFields(items.map(Annotatable::expect_struct_field).collect())
}
AstFragmentKind::Variants => {
AstFragment::Variants(items.map(Annotatable::expect_variant).collect())
}
AstFragmentKind::Items => {
AstFragment::Items(items.map(Annotatable::expect_item).collect())
}
AstFragmentKind::ImplItems => {
AstFragment::ImplItems(items.map(Annotatable::expect_impl_item).collect())
}
AstFragmentKind::TraitItems => {
AstFragment::TraitItems(items.map(Annotatable::expect_trait_item).collect())
}
AstFragmentKind::ForeignItems => {
AstFragment::ForeignItems(items.map(Annotatable::expect_foreign_item).collect())
}
AstFragmentKind::Stmts => {
AstFragment::Stmts(items.map(Annotatable::expect_stmt).collect())
}
AstFragmentKind::Expr => AstFragment::Expr(
items.next().expect("expected exactly one expression").expect_expr(),
),
AstFragmentKind::OptExpr => {
AstFragment::OptExpr(items.next().map(Annotatable::expect_expr))
}
AstFragmentKind::Pat | AstFragmentKind::Ty => {
panic!("patterns and types aren't annotatable")
}
}
}
}
pub struct Invocation {
pub kind: InvocationKind,
pub fragment_kind: AstFragmentKind,
pub expansion_data: ExpansionData,
}
pub enum InvocationKind {
Bang {
mac: ast::MacCall,
span: Span,
},
Attr {
attr: ast::Attribute,
item: Annotatable,
// Required for resolving derive helper attributes.
derives: Vec<Path>,
// We temporarily report errors for attribute macros placed after derives
after_derive: bool,
},
Derive {
path: Path,
item: Annotatable,
},
/// "Invocation" that contains all derives from an item,
/// broken into multiple `Derive` invocations when expanded.
/// FIXME: Find a way to remove it.
DeriveContainer {
derives: Vec<Path>,
item: Annotatable,
},
}
impl InvocationKind {
fn placeholder_visibility(&self) -> Option<ast::Visibility> {
// HACK: For unnamed fields placeholders should have the same visibility as the actual
// fields because for tuple structs/variants resolve determines visibilities of their
// constructor using these field visibilities before attributes on them are are expanded.
// The assumption is that the attribute expansion cannot change field visibilities,
// and it holds because only inert attributes are supported in this position.
match self {
InvocationKind::Attr { item: Annotatable::StructField(field), .. }
| InvocationKind::Derive { item: Annotatable::StructField(field), .. }
| InvocationKind::DeriveContainer { item: Annotatable::StructField(field), .. }
if field.ident.is_none() =>
{
Some(field.vis.clone())
}
_ => None,
}
}
}
impl Invocation {
pub fn span(&self) -> Span {
match &self.kind {
InvocationKind::Bang { span, .. } => *span,
InvocationKind::Attr { attr, .. } => attr.span,
InvocationKind::Derive { path, .. } => path.span,
InvocationKind::DeriveContainer { item, .. } => item.span(),
}
}
}
pub struct MacroExpander<'a, 'b> {
pub cx: &'a mut ExtCtxt<'b>,
monotonic: bool, // cf. `cx.monotonic_expander()`
}
impl<'a, 'b> MacroExpander<'a, 'b> {
pub fn new(cx: &'a mut ExtCtxt<'b>, monotonic: bool) -> Self {
MacroExpander { cx, monotonic }
}
pub fn expand_crate(&mut self, mut krate: ast::Crate) -> ast::Crate {
let mut module = ModuleData {
mod_path: vec![Ident::from_str(&self.cx.ecfg.crate_name)],
directory: match self.cx.source_map().span_to_unmapped_path(krate.span) {
FileName::Real(name) => name.into_local_path(),
other => PathBuf::from(other.to_string()),
},
};
module.directory.pop();
self.cx.root_path = module.directory.clone();
self.cx.current_expansion.module = Rc::new(module);
let orig_mod_span = krate.module.inner;
let krate_item = AstFragment::Items(smallvec![P(ast::Item {
attrs: krate.attrs,
span: krate.span,
kind: ast::ItemKind::Mod(krate.module),
ident: Ident::invalid(),
id: ast::DUMMY_NODE_ID,
vis: ast::Visibility {
span: krate.span.shrink_to_lo(),
kind: ast::VisibilityKind::Public,
tokens: None,
},
tokens: None,
})]);
match self.fully_expand_fragment(krate_item).make_items().pop().map(P::into_inner) {
Some(ast::Item { attrs, kind: ast::ItemKind::Mod(module), .. }) => {
krate.attrs = attrs;
krate.module = module;
}
None => {
// Resolution failed so we return an empty expansion
krate.attrs = vec![];
krate.module = ast::Mod {
inner: orig_mod_span,
unsafety: Unsafe::No,
items: vec![],
inline: true,
};
}
Some(ast::Item { span, kind, .. }) => {
krate.attrs = vec![];
krate.module = ast::Mod {
inner: orig_mod_span,
unsafety: Unsafe::No,
items: vec![],
inline: true,
};
self.cx.span_err(
span,
&format!(
"expected crate top-level item to be a module after macro expansion, found {} {}",
kind.article(), kind.descr()
),
);
}
};
self.cx.trace_macros_diag();
krate
}
// Recursively expand all macro invocations in this AST fragment.
pub fn fully_expand_fragment(&mut self, input_fragment: AstFragment) -> AstFragment {
let orig_expansion_data = self.cx.current_expansion.clone();
let orig_force_mode = self.cx.force_mode;
self.cx.current_expansion.depth = 0;
// Collect all macro invocations and replace them with placeholders.
let (mut fragment_with_placeholders, mut invocations) =
self.collect_invocations(input_fragment, &[]);
// Optimization: if we resolve all imports now,
// we'll be able to immediately resolve most of imported macros.
self.resolve_imports();
// Resolve paths in all invocations and produce output expanded fragments for them, but
// do not insert them into our input AST fragment yet, only store in `expanded_fragments`.
// The output fragments also go through expansion recursively until no invocations are left.
// Unresolved macros produce dummy outputs as a recovery measure.
invocations.reverse();
let mut expanded_fragments = Vec::new();
let mut undetermined_invocations = Vec::new();
let (mut progress, mut force) = (false, !self.monotonic);
loop {
let (invoc, res) = if let Some(invoc) = invocations.pop() {
invoc
} else {
self.resolve_imports();
if undetermined_invocations.is_empty() {
break;
}
invocations = mem::take(&mut undetermined_invocations);
force = !mem::replace(&mut progress, false);
if force && self.monotonic {
self.cx.sess.delay_span_bug(
invocations.last().unwrap().0.span(),
"expansion entered force mode without producing any errors",
);
}
continue;
};
let res = match res {
Some(res) => res,
None => {
let eager_expansion_root = if self.monotonic {
invoc.expansion_data.id
} else {
orig_expansion_data.id
};
match self.cx.resolver.resolve_macro_invocation(
&invoc,
eager_expansion_root,
force,
) {
Ok(res) => res,
Err(Indeterminate) => {
// Cannot resolve, will retry this invocation later.
undetermined_invocations.push((invoc, None));
continue;
}
}
}
};
let ExpansionData { depth, id: expn_id, .. } = invoc.expansion_data;
self.cx.current_expansion = invoc.expansion_data.clone();
self.cx.force_mode = force;
// FIXME(jseyfried): Refactor out the following logic
let fragment_kind = invoc.fragment_kind;
let (expanded_fragment, new_invocations) = match res {
InvocationRes::Single(ext) => match self.expand_invoc(invoc, &ext.kind) {
ExpandResult::Ready(fragment) => self.collect_invocations(fragment, &[]),
ExpandResult::Retry(invoc) => {
if force {
self.cx.span_bug(
invoc.span(),
"expansion entered force mode but is still stuck",
);
} else {
// Cannot expand, will retry this invocation later.
undetermined_invocations
.push((invoc, Some(InvocationRes::Single(ext))));
continue;
}
}
},
InvocationRes::DeriveContainer(_exts) => {
// FIXME: Consider using the derive resolutions (`_exts`) immediately,
// instead of enqueuing the derives to be resolved again later.
let (derives, mut item) = match invoc.kind {
InvocationKind::DeriveContainer { derives, item } => (derives, item),
_ => unreachable!(),
};
let (item, derive_placeholders) = if !item.derive_allowed() {
self.error_derive_forbidden_on_non_adt(&derives, &item);
item.visit_attrs(|attrs| attrs.retain(|a| !a.has_name(sym::derive)));
(item, Vec::new())
} else {
let mut item = StripUnconfigured {
sess: self.cx.sess,
features: self.cx.ecfg.features,
}
.fully_configure(item);
item.visit_attrs(|attrs| attrs.retain(|a| !a.has_name(sym::derive)));
invocations.reserve(derives.len());
let derive_placeholders = derives
.into_iter()
.map(|path| {
let expn_id = ExpnId::fresh(None);
invocations.push((
Invocation {
kind: InvocationKind::Derive { path, item: item.clone() },
fragment_kind,
expansion_data: ExpansionData {
id: expn_id,
..self.cx.current_expansion.clone()
},
},
None,
));
NodeId::placeholder_from_expn_id(expn_id)
})
.collect::<Vec<_>>();
(item, derive_placeholders)
};
let fragment = fragment_kind.expect_from_annotatables(::std::iter::once(item));
self.collect_invocations(fragment, &derive_placeholders)
}
};
progress = true;
if expanded_fragments.len() < depth {
expanded_fragments.push(Vec::new());
}
expanded_fragments[depth - 1].push((expn_id, expanded_fragment));
invocations.extend(new_invocations.into_iter().rev());
}
self.cx.current_expansion = orig_expansion_data;
self.cx.force_mode = orig_force_mode;
// Finally incorporate all the expanded macros into the input AST fragment.
let mut placeholder_expander = PlaceholderExpander::new(self.cx, self.monotonic);
while let Some(expanded_fragments) = expanded_fragments.pop() {
for (expn_id, expanded_fragment) in expanded_fragments.into_iter().rev() {
placeholder_expander
.add(NodeId::placeholder_from_expn_id(expn_id), expanded_fragment);
}
}
fragment_with_placeholders.mut_visit_with(&mut placeholder_expander);
fragment_with_placeholders
}
fn error_derive_forbidden_on_non_adt(&self, derives: &[Path], item: &Annotatable) {
let attr = self.cx.sess.find_by_name(item.attrs(), sym::derive);
let span = attr.map_or(item.span(), |attr| attr.span);
let mut err = struct_span_err!(
self.cx.sess,
span,
E0774,
"`derive` may only be applied to structs, enums and unions",
);
if let Some(ast::Attribute { style: ast::AttrStyle::Inner, .. }) = attr {
let trait_list = derives.iter().map(|t| pprust::path_to_string(t)).collect::<Vec<_>>();
let suggestion = format!("#[derive({})]", trait_list.join(", "));
err.span_suggestion(
span,
"try an outer attribute",
suggestion,
// We don't 𝑘𝑛𝑜𝑤 that the following item is an ADT
Applicability::MaybeIncorrect,
);
}
err.emit();
}
fn resolve_imports(&mut self) {
if self.monotonic {
self.cx.resolver.resolve_imports();
}
}
/// Collects all macro invocations reachable at this time in this AST fragment, and replace
/// them with "placeholders" - dummy macro invocations with specially crafted `NodeId`s.
/// Then call into resolver that builds a skeleton ("reduced graph") of the fragment and
/// prepares data for resolving paths of macro invocations.
fn collect_invocations(
&mut self,
mut fragment: AstFragment,
extra_placeholders: &[NodeId],
) -> (AstFragment, Vec<(Invocation, Option<InvocationRes>)>) {
// Resolve `$crate`s in the fragment for pretty-printing.
self.cx.resolver.resolve_dollar_crates();
let invocations = {
let mut collector = InvocationCollector {
cfg: StripUnconfigured { sess: &self.cx.sess, features: self.cx.ecfg.features },
cx: self.cx,
invocations: Vec::new(),
monotonic: self.monotonic,
};
fragment.mut_visit_with(&mut collector);
fragment.add_placeholders(extra_placeholders);
collector.invocations
};
if self.monotonic {
self.cx
.resolver
.visit_ast_fragment_with_placeholders(self.cx.current_expansion.id, &fragment);
}
(fragment, invocations)
}
fn error_recursion_limit_reached(&mut self) {
let expn_data = self.cx.current_expansion.id.expn_data();
let suggested_limit = self.cx.ecfg.recursion_limit * 2;
self.cx
.struct_span_err(
expn_data.call_site,
&format!("recursion limit reached while expanding `{}`", expn_data.kind.descr()),
)
.help(&format!(
"consider adding a `#![recursion_limit=\"{}\"]` attribute to your crate (`{}`)",
suggested_limit, self.cx.ecfg.crate_name,
))
.emit();
self.cx.trace_macros_diag();
}
/// A macro's expansion does not fit in this fragment kind.
/// For example, a non-type macro in a type position.
fn error_wrong_fragment_kind(&mut self, kind: AstFragmentKind, mac: &ast::MacCall, span: Span) {
let msg = format!(
"non-{kind} macro in {kind} position: {path}",
kind = kind.name(),
path = pprust::path_to_string(&mac.path),
);
self.cx.span_err(span, &msg);
self.cx.trace_macros_diag();
}
fn expand_invoc(
&mut self,
invoc: Invocation,
ext: &SyntaxExtensionKind,
) -> ExpandResult<AstFragment, Invocation> {
let recursion_limit =
self.cx.reduced_recursion_limit.unwrap_or(self.cx.ecfg.recursion_limit);
if !recursion_limit.value_within_limit(self.cx.current_expansion.depth) {
if self.cx.reduced_recursion_limit.is_none() {
self.error_recursion_limit_reached();
}
// Reduce the recursion limit by half each time it triggers.
self.cx.reduced_recursion_limit = Some(recursion_limit / 2);
return ExpandResult::Ready(invoc.fragment_kind.dummy(invoc.span()));
}
let (fragment_kind, span) = (invoc.fragment_kind, invoc.span());
ExpandResult::Ready(match invoc.kind {
InvocationKind::Bang { mac, .. } => match ext {
SyntaxExtensionKind::Bang(expander) => {
let tok_result = match expander.expand(self.cx, span, mac.args.inner_tokens()) {
Err(_) => return ExpandResult::Ready(fragment_kind.dummy(span)),
Ok(ts) => ts,
};
self.parse_ast_fragment(tok_result, fragment_kind, &mac.path, span)
}
SyntaxExtensionKind::LegacyBang(expander) => {
let prev = self.cx.current_expansion.prior_type_ascription;
self.cx.current_expansion.prior_type_ascription = mac.prior_type_ascription;
let tok_result = expander.expand(self.cx, span, mac.args.inner_tokens());
let result = if let Some(result) = fragment_kind.make_from(tok_result) {
result
} else {
self.error_wrong_fragment_kind(fragment_kind, &mac, span);
fragment_kind.dummy(span)
};
self.cx.current_expansion.prior_type_ascription = prev;
result
}
_ => unreachable!(),
},
InvocationKind::Attr { attr, mut item, derives, after_derive } => match ext {
SyntaxExtensionKind::Attr(expander) => {
self.gate_proc_macro_input(&item);
self.gate_proc_macro_attr_item(span, &item);
let tokens = item.into_tokens(&self.cx.sess.parse_sess);
let attr_item = attr.unwrap_normal_item();
if let MacArgs::Eq(..) = attr_item.args {
self.cx.span_err(span, "key-value macro attributes are not supported");
}
let inner_tokens = attr_item.args.inner_tokens();
let tok_result = match expander.expand(self.cx, span, inner_tokens, tokens) {
Err(_) => return ExpandResult::Ready(fragment_kind.dummy(span)),
Ok(ts) => ts,
};
self.parse_ast_fragment(tok_result, fragment_kind, &attr_item.path, span)
}
SyntaxExtensionKind::LegacyAttr(expander) => {
match validate_attr::parse_meta(&self.cx.sess.parse_sess, &attr) {
Ok(meta) => {
let items = match expander.expand(self.cx, span, &meta, item) {
ExpandResult::Ready(items) => items,
ExpandResult::Retry(item) => {
// Reassemble the original invocation for retrying.
return ExpandResult::Retry(Invocation {
kind: InvocationKind::Attr {
attr,
item,
derives,
after_derive,
},
..invoc
});
}
};
fragment_kind.expect_from_annotatables(items)
}
Err(mut err) => {
err.emit();
fragment_kind.dummy(span)
}
}
}
SyntaxExtensionKind::NonMacroAttr { mark_used } => {
self.cx.sess.mark_attr_known(&attr);
if *mark_used {
self.cx.sess.mark_attr_used(&attr);
}
item.visit_attrs(|attrs| attrs.push(attr));
fragment_kind.expect_from_annotatables(iter::once(item))
}
_ => unreachable!(),
},
InvocationKind::Derive { path, item } => match ext {
SyntaxExtensionKind::Derive(expander)
| SyntaxExtensionKind::LegacyDerive(expander) => {
if let SyntaxExtensionKind::Derive(..) = ext {
self.gate_proc_macro_input(&item);
}
let meta = ast::MetaItem { kind: ast::MetaItemKind::Word, span, path };
let items = match expander.expand(self.cx, span, &meta, item) {
ExpandResult::Ready(items) => items,
ExpandResult::Retry(item) => {
// Reassemble the original invocation for retrying.
return ExpandResult::Retry(Invocation {
kind: InvocationKind::Derive { path: meta.path, item },
..invoc
});
}
};
fragment_kind.expect_from_annotatables(items)
}
_ => unreachable!(),
},
InvocationKind::DeriveContainer { .. } => unreachable!(),
})
}
fn gate_proc_macro_attr_item(&self, span: Span, item: &Annotatable) {
let kind = match item {
Annotatable::Item(_)
| Annotatable::TraitItem(_)
| Annotatable::ImplItem(_)
| Annotatable::ForeignItem(_) => return,
Annotatable::Stmt(stmt) => {
// Attributes are stable on item statements,
// but unstable on all other kinds of statements
if stmt.is_item() {
return;
}
"statements"
}
Annotatable::Expr(_) => "expressions",
Annotatable::Arm(..)
| Annotatable::Field(..)
| Annotatable::FieldPat(..)
| Annotatable::GenericParam(..)
| Annotatable::Param(..)
| Annotatable::StructField(..)
| Annotatable::Variant(..) => panic!("unexpected annotatable"),
};
if self.cx.ecfg.proc_macro_hygiene() {
return;
}
feature_err(
&self.cx.sess.parse_sess,
sym::proc_macro_hygiene,
span,
&format!("custom attributes cannot be applied to {}", kind),
)
.emit();
}
fn gate_proc_macro_input(&self, annotatable: &Annotatable) {
struct GateProcMacroInput<'a> {
parse_sess: &'a ParseSess,
}
impl<'ast, 'a> Visitor<'ast> for GateProcMacroInput<'a> {
fn visit_item(&mut self, item: &'ast ast::Item) {
match &item.kind {
ast::ItemKind::Mod(module) if !module.inline => {
feature_err(
self.parse_sess,
sym::proc_macro_hygiene,
item.span,
"non-inline modules in proc macro input are unstable",
)
.emit();
}
_ => {}
}
visit::walk_item(self, item);
}
}
if !self.cx.ecfg.proc_macro_hygiene() {
annotatable
.visit_with(&mut GateProcMacroInput { parse_sess: &self.cx.sess.parse_sess });
}
}
fn parse_ast_fragment(
&mut self,
toks: TokenStream,
kind: AstFragmentKind,
path: &Path,
span: Span,
) -> AstFragment {
let mut parser = self.cx.new_parser_from_tts(toks);
match parse_ast_fragment(&mut parser, kind) {
Ok(fragment) => {
ensure_complete_parse(&mut parser, path, kind.name(), span);
fragment
}
Err(mut err) => {
err.set_span(span);
annotate_err_with_kind(&mut err, kind, span);
err.emit();
self.cx.trace_macros_diag();
kind.dummy(span)
}
}
}
}
pub fn parse_ast_fragment<'a>(
this: &mut Parser<'a>,
kind: AstFragmentKind,
) -> PResult<'a, AstFragment> {
Ok(match kind {
AstFragmentKind::Items => {
let mut items = SmallVec::new();
while let Some(item) = this.parse_item()? {
items.push(item);
}
AstFragment::Items(items)
}
AstFragmentKind::TraitItems => {
let mut items = SmallVec::new();
while let Some(item) = this.parse_trait_item()? {
items.extend(item);
}
AstFragment::TraitItems(items)
}
AstFragmentKind::ImplItems => {
let mut items = SmallVec::new();
while let Some(item) = this.parse_impl_item()? {
items.extend(item);
}
AstFragment::ImplItems(items)
}
AstFragmentKind::ForeignItems => {
let mut items = SmallVec::new();
while let Some(item) = this.parse_foreign_item()? {
items.extend(item);
}
AstFragment::ForeignItems(items)
}
AstFragmentKind::Stmts => {
let mut stmts = SmallVec::new();
// Won't make progress on a `}`.
while this.token != token::Eof && this.token != token::CloseDelim(token::Brace) {
if let Some(stmt) = this.parse_full_stmt(AttemptLocalParseRecovery::Yes)? {
stmts.push(stmt);
}
}
AstFragment::Stmts(stmts)
}
AstFragmentKind::Expr => AstFragment::Expr(this.parse_expr()?),
AstFragmentKind::OptExpr => {
if this.token != token::Eof {
AstFragment::OptExpr(Some(this.parse_expr()?))
} else {
AstFragment::OptExpr(None)
}
}
AstFragmentKind::Ty => AstFragment::Ty(this.parse_ty()?),
AstFragmentKind::Pat => AstFragment::Pat(this.parse_pat(None)?),
AstFragmentKind::Arms
| AstFragmentKind::Fields
| AstFragmentKind::FieldPats
| AstFragmentKind::GenericParams
| AstFragmentKind::Params
| AstFragmentKind::StructFields
| AstFragmentKind::Variants => panic!("unexpected AST fragment kind"),
})
}
pub fn ensure_complete_parse<'a>(
this: &mut Parser<'a>,
macro_path: &Path,
kind_name: &str,
span: Span,
) {
if this.token != token::Eof {
let token = pprust::token_to_string(&this.token);
let msg = format!("macro expansion ignores token `{}` and any following", token);
// Avoid emitting backtrace info twice.
let def_site_span = this.token.span.with_ctxt(SyntaxContext::root());
let mut err = this.struct_span_err(def_site_span, &msg);
err.span_label(span, "caused by the macro expansion here");
let msg = format!(
"the usage of `{}!` is likely invalid in {} context",
pprust::path_to_string(macro_path),
kind_name,
);
err.note(&msg);
let semi_span = this.sess.source_map().next_point(span);
let semi_full_span = semi_span.to(this.sess.source_map().next_point(semi_span));
match this.sess.source_map().span_to_snippet(semi_full_span) {
Ok(ref snippet) if &snippet[..] != ";" && kind_name == "expression" => {
err.span_suggestion(
semi_span,
"you might be missing a semicolon here",
";".to_owned(),
Applicability::MaybeIncorrect,
);
}
_ => {}
}
err.emit();
}
}
struct InvocationCollector<'a, 'b> {
cx: &'a mut ExtCtxt<'b>,
cfg: StripUnconfigured<'a>,
invocations: Vec<(Invocation, Option<InvocationRes>)>,
monotonic: bool,
}
impl<'a, 'b> InvocationCollector<'a, 'b> {
fn collect(&mut self, fragment_kind: AstFragmentKind, kind: InvocationKind) -> AstFragment {
// Expansion data for all the collected invocations is set upon their resolution,
// with exception of the derive container case which is not resolved and can get
// its expansion data immediately.
let expn_data = match &kind {
InvocationKind::DeriveContainer { item, .. } => Some(ExpnData {
parent: self.cx.current_expansion.id,
..ExpnData::default(
ExpnKind::Macro(MacroKind::Attr, sym::derive),
item.span(),
self.cx.sess.parse_sess.edition,
None,
)
}),
_ => None,
};
let expn_id = ExpnId::fresh(expn_data);
let vis = kind.placeholder_visibility();
self.invocations.push((
Invocation {
kind,
fragment_kind,
expansion_data: ExpansionData {
id: expn_id,
depth: self.cx.current_expansion.depth + 1,
..self.cx.current_expansion.clone()
},
},
None,
));
placeholder(fragment_kind, NodeId::placeholder_from_expn_id(expn_id), vis)
}
fn collect_bang(
&mut self,
mac: ast::MacCall,
span: Span,
kind: AstFragmentKind,
) -> AstFragment {
self.collect(kind, InvocationKind::Bang { mac, span })
}
fn collect_attr(
&mut self,
(attr, derives, after_derive): (Option<ast::Attribute>, Vec<Path>, bool),
item: Annotatable,
kind: AstFragmentKind,
) -> AstFragment {
self.collect(
kind,
match attr {
Some(attr) => InvocationKind::Attr { attr, item, derives, after_derive },
None => InvocationKind::DeriveContainer { derives, item },
},
)
}
fn find_attr_invoc(
&self,
attrs: &mut Vec<ast::Attribute>,
after_derive: &mut bool,
) -> Option<ast::Attribute> {
attrs
.iter()
.position(|a| {
if a.has_name(sym::derive) {
*after_derive = true;
}
!self.cx.sess.is_attr_known(a) && !is_builtin_attr(a)
})
.map(|i| attrs.remove(i))
}
/// If `item` is an attr invocation, remove and return the macro attribute and derive traits.
fn take_first_attr(
&mut self,
item: &mut impl HasAttrs,
) -> Option<(Option<ast::Attribute>, Vec<Path>, /* after_derive */ bool)> {
let (mut attr, mut traits, mut after_derive) = (None, Vec::new(), false);
item.visit_attrs(|mut attrs| {
attr = self.find_attr_invoc(&mut attrs, &mut after_derive);
traits = collect_derives(&mut self.cx, &mut attrs);
});
if attr.is_some() || !traits.is_empty() { Some((attr, traits, after_derive)) } else { None }
}
/// Alternative to `take_first_attr()` that ignores `#[derive]` so invocations fallthrough
/// to the unused-attributes lint (making it an error on statements and expressions
/// is a breaking change)
fn take_first_attr_no_derive(
&mut self,
nonitem: &mut impl HasAttrs,
) -> Option<(Option<ast::Attribute>, Vec<Path>, /* after_derive */ bool)> {
let (mut attr, mut after_derive) = (None, false);
nonitem.visit_attrs(|mut attrs| {
attr = self.find_attr_invoc(&mut attrs, &mut after_derive);
});
attr.map(|attr| (Some(attr), Vec::new(), after_derive))
}
fn configure<T: HasAttrs>(&mut self, node: T) -> Option<T> {
self.cfg.configure(node)
}
// Detect use of feature-gated or invalid attributes on macro invocations
// since they will not be detected after macro expansion.
fn check_attributes(&mut self, attrs: &[ast::Attribute]) {
let features = self.cx.ecfg.features.unwrap();
for attr in attrs.iter() {
rustc_ast_passes::feature_gate::check_attribute(attr, self.cx.sess, features);
validate_attr::check_meta(&self.cx.sess.parse_sess, attr);
// macros are expanded before any lint passes so this warning has to be hardcoded
if attr.has_name(sym::derive) {
self.cx
.parse_sess()
.span_diagnostic
.struct_span_warn(attr.span, "`#[derive]` does nothing on macro invocations")
.note("this may become a hard error in a future release")
.emit();
}
if attr.doc_str().is_some() {
self.cx.sess.parse_sess.buffer_lint_with_diagnostic(
&UNUSED_DOC_COMMENTS,
attr.span,
ast::CRATE_NODE_ID,
"unused doc comment",
BuiltinLintDiagnostics::UnusedDocComment(attr.span),
);
}
}
}
}
impl<'a, 'b> MutVisitor for InvocationCollector<'a, 'b> {
fn visit_expr(&mut self, expr: &mut P<ast::Expr>) {
self.cfg.configure_expr(expr);
visit_clobber(expr.deref_mut(), |mut expr| {
self.cfg.configure_expr_kind(&mut expr.kind);
if let Some(attr) = self.take_first_attr_no_derive(&mut expr) {
// Collect the invoc regardless of whether or not attributes are permitted here
// expansion will eat the attribute so it won't error later.
attr.0.as_ref().map(|attr| self.cfg.maybe_emit_expr_attr_err(attr));
// AstFragmentKind::Expr requires the macro to emit an expression.
return self
.collect_attr(attr, Annotatable::Expr(P(expr)), AstFragmentKind::Expr)
.make_expr()
.into_inner();
}
if let ast::ExprKind::MacCall(mac) = expr.kind {
self.check_attributes(&expr.attrs);
self.collect_bang(mac, expr.span, AstFragmentKind::Expr).make_expr().into_inner()
} else {
ensure_sufficient_stack(|| noop_visit_expr(&mut expr, self));
expr
}
});
}
fn flat_map_arm(&mut self, arm: ast::Arm) -> SmallVec<[ast::Arm; 1]> {
let mut arm = configure!(self, arm);
if let Some(attr) = self.take_first_attr(&mut arm) {
return self
.collect_attr(attr, Annotatable::Arm(arm), AstFragmentKind::Arms)
.make_arms();
}
noop_flat_map_arm(arm, self)
}
fn flat_map_field(&mut self, field: ast::Field) -> SmallVec<[ast::Field; 1]> {
let mut field = configure!(self, field);
if let Some(attr) = self.take_first_attr(&mut field) {
return self
.collect_attr(attr, Annotatable::Field(field), AstFragmentKind::Fields)
.make_fields();
}
noop_flat_map_field(field, self)
}
fn flat_map_field_pattern(&mut self, fp: ast::FieldPat) -> SmallVec<[ast::FieldPat; 1]> {
let mut fp = configure!(self, fp);
if let Some(attr) = self.take_first_attr(&mut fp) {
return self
.collect_attr(attr, Annotatable::FieldPat(fp), AstFragmentKind::FieldPats)
.make_field_patterns();
}
noop_flat_map_field_pattern(fp, self)
}
fn flat_map_param(&mut self, p: ast::Param) -> SmallVec<[ast::Param; 1]> {
let mut p = configure!(self, p);
if let Some(attr) = self.take_first_attr(&mut p) {
return self
.collect_attr(attr, Annotatable::Param(p), AstFragmentKind::Params)
.make_params();
}
noop_flat_map_param(p, self)
}
fn flat_map_struct_field(&mut self, sf: ast::StructField) -> SmallVec<[ast::StructField; 1]> {
let mut sf = configure!(self, sf);
if let Some(attr) = self.take_first_attr(&mut sf) {
return self
.collect_attr(attr, Annotatable::StructField(sf), AstFragmentKind::StructFields)
.make_struct_fields();
}
noop_flat_map_struct_field(sf, self)
}
fn flat_map_variant(&mut self, variant: ast::Variant) -> SmallVec<[ast::Variant; 1]> {
let mut variant = configure!(self, variant);
if let Some(attr) = self.take_first_attr(&mut variant) {
return self
.collect_attr(attr, Annotatable::Variant(variant), AstFragmentKind::Variants)
.make_variants();
}
noop_flat_map_variant(variant, self)
}
fn filter_map_expr(&mut self, expr: P<ast::Expr>) -> Option<P<ast::Expr>> {
let expr = configure!(self, expr);
expr.filter_map(|mut expr| {
self.cfg.configure_expr_kind(&mut expr.kind);
if let Some(attr) = self.take_first_attr_no_derive(&mut expr) {
attr.0.as_ref().map(|attr| self.cfg.maybe_emit_expr_attr_err(attr));
return self
.collect_attr(attr, Annotatable::Expr(P(expr)), AstFragmentKind::OptExpr)
.make_opt_expr()
.map(|expr| expr.into_inner());
}
if let ast::ExprKind::MacCall(mac) = expr.kind {
self.check_attributes(&expr.attrs);
self.collect_bang(mac, expr.span, AstFragmentKind::OptExpr)
.make_opt_expr()
.map(|expr| expr.into_inner())
} else {
Some({
noop_visit_expr(&mut expr, self);
expr
})
}
})
}
fn visit_pat(&mut self, pat: &mut P<ast::Pat>) {
self.cfg.configure_pat(pat);
match pat.kind {
PatKind::MacCall(_) => {}
_ => return noop_visit_pat(pat, self),
}
visit_clobber(pat, |mut pat| match mem::replace(&mut pat.kind, PatKind::Wild) {
PatKind::MacCall(mac) => {
self.collect_bang(mac, pat.span, AstFragmentKind::Pat).make_pat()
}
_ => unreachable!(),
});
}
fn flat_map_stmt(&mut self, stmt: ast::Stmt) -> SmallVec<[ast::Stmt; 1]> {
let mut stmt = configure!(self, stmt);
// we'll expand attributes on expressions separately
if !stmt.is_expr() {
let attr = if stmt.is_item() {
self.take_first_attr(&mut stmt)
} else {
// Ignore derives on non-item statements for backwards compatibility.
// This will result in a unused attribute warning
self.take_first_attr_no_derive(&mut stmt)
};
if let Some(attr) = attr {
return self
.collect_attr(attr, Annotatable::Stmt(P(stmt)), AstFragmentKind::Stmts)
.make_stmts();
}
}
if let StmtKind::MacCall(mac) = stmt.kind {
let MacCallStmt { mac, style, attrs, tokens: _ } = mac.into_inner();
self.check_attributes(&attrs);
let mut placeholder =
self.collect_bang(mac, stmt.span, AstFragmentKind::Stmts).make_stmts();
// If this is a macro invocation with a semicolon, then apply that
// semicolon to the final statement produced by expansion.
if style == MacStmtStyle::Semicolon {
if let Some(stmt) = placeholder.pop() {
placeholder.push(stmt.add_trailing_semicolon());
}
}
return placeholder;
}
// The placeholder expander gives ids to statements, so we avoid folding the id here.
let ast::Stmt { id, kind, span } = stmt;
noop_flat_map_stmt_kind(kind, self)
.into_iter()
.map(|kind| ast::Stmt { id, kind, span })
.collect()
}
fn visit_block(&mut self, block: &mut P<Block>) {
let old_directory_ownership = self.cx.current_expansion.directory_ownership;
self.cx.current_expansion.directory_ownership = DirectoryOwnership::UnownedViaBlock;
noop_visit_block(block, self);
self.cx.current_expansion.directory_ownership = old_directory_ownership;
}
fn flat_map_item(&mut self, item: P<ast::Item>) -> SmallVec<[P<ast::Item>; 1]> {
let mut item = configure!(self, item);
if let Some(attr) = self.take_first_attr(&mut item) {
return self
.collect_attr(attr, Annotatable::Item(item), AstFragmentKind::Items)
.make_items();
}
let mut attrs = mem::take(&mut item.attrs); // We do this to please borrowck.
let ident = item.ident;
let span = item.span;
match item.kind {
ast::ItemKind::MacCall(..) => {
item.attrs = attrs;
self.check_attributes(&item.attrs);
item.and_then(|item| match item.kind {
ItemKind::MacCall(mac) => {
self.collect_bang(mac, span, AstFragmentKind::Items).make_items()
}
_ => unreachable!(),
})
}
ast::ItemKind::Mod(ref mut old_mod @ ast::Mod { .. }) if ident != Ident::invalid() => {
let sess = &self.cx.sess.parse_sess;
let orig_ownership = self.cx.current_expansion.directory_ownership;
let mut module = (*self.cx.current_expansion.module).clone();
let pushed = &mut false; // Record `parse_external_mod` pushing so we can pop.
let dir = Directory { ownership: orig_ownership, path: module.directory };
let Directory { ownership, path } = if old_mod.inline {
// Inline `mod foo { ... }`, but we still need to push directories.
item.attrs = attrs;
push_directory(&self.cx.sess, ident, &item.attrs, dir)
} else {
// We have an outline `mod foo;` so we need to parse the file.
let (new_mod, dir) = parse_external_mod(
&self.cx.sess,
ident,
span,
old_mod.unsafety,
dir,
&mut attrs,
pushed,
);
let krate = ast::Crate {
span: new_mod.inner,
module: new_mod,
attrs,
proc_macros: vec![],
};
if let Some(extern_mod_loaded) = self.cx.extern_mod_loaded {
extern_mod_loaded(&krate);
}
*old_mod = krate.module;
item.attrs = krate.attrs;
// File can have inline attributes, e.g., `#![cfg(...)]` & co. => Reconfigure.
item = match self.configure(item) {
Some(node) => node,
None => {
if *pushed {
sess.included_mod_stack.borrow_mut().pop();
}
return Default::default();
}
};
dir
};
// Set the module info before we flat map.
self.cx.current_expansion.directory_ownership = ownership;
module.directory = path;
module.mod_path.push(ident);
let orig_module =
mem::replace(&mut self.cx.current_expansion.module, Rc::new(module));
let result = noop_flat_map_item(item, self);
// Restore the module info.
self.cx.current_expansion.module = orig_module;
self.cx.current_expansion.directory_ownership = orig_ownership;
if *pushed {
sess.included_mod_stack.borrow_mut().pop();
}
result
}
_ => {
item.attrs = attrs;
noop_flat_map_item(item, self)
}
}
}
fn flat_map_trait_item(&mut self, item: P<ast::AssocItem>) -> SmallVec<[P<ast::AssocItem>; 1]> {
let mut item = configure!(self, item);
if let Some(attr) = self.take_first_attr(&mut item) {
return self
.collect_attr(attr, Annotatable::TraitItem(item), AstFragmentKind::TraitItems)
.make_trait_items();
}
match item.kind {
ast::AssocItemKind::MacCall(..) => {
self.check_attributes(&item.attrs);
item.and_then(|item| match item.kind {
ast::AssocItemKind::MacCall(mac) => self
.collect_bang(mac, item.span, AstFragmentKind::TraitItems)
.make_trait_items(),
_ => unreachable!(),
})
}
_ => noop_flat_map_assoc_item(item, self),
}
}
fn flat_map_impl_item(&mut self, item: P<ast::AssocItem>) -> SmallVec<[P<ast::AssocItem>; 1]> {
let mut item = configure!(self, item);
if let Some(attr) = self.take_first_attr(&mut item) {
return self
.collect_attr(attr, Annotatable::ImplItem(item), AstFragmentKind::ImplItems)
.make_impl_items();
}
match item.kind {
ast::AssocItemKind::MacCall(..) => {
self.check_attributes(&item.attrs);
item.and_then(|item| match item.kind {
ast::AssocItemKind::MacCall(mac) => self
.collect_bang(mac, item.span, AstFragmentKind::ImplItems)
.make_impl_items(),
_ => unreachable!(),
})
}
_ => noop_flat_map_assoc_item(item, self),
}
}
fn visit_ty(&mut self, ty: &mut P<ast::Ty>) {
match ty.kind {
ast::TyKind::MacCall(_) => {}
_ => return noop_visit_ty(ty, self),
};
visit_clobber(ty, |mut ty| match mem::replace(&mut ty.kind, ast::TyKind::Err) {
ast::TyKind::MacCall(mac) => {
self.collect_bang(mac, ty.span, AstFragmentKind::Ty).make_ty()
}
_ => unreachable!(),
});
}
fn visit_foreign_mod(&mut self, foreign_mod: &mut ast::ForeignMod) {
self.cfg.configure_foreign_mod(foreign_mod);
noop_visit_foreign_mod(foreign_mod, self);
}
fn flat_map_foreign_item(
&mut self,
mut foreign_item: P<ast::ForeignItem>,
) -> SmallVec<[P<ast::ForeignItem>; 1]> {
if let Some(attr) = self.take_first_attr(&mut foreign_item) {
return self
.collect_attr(
attr,
Annotatable::ForeignItem(foreign_item),
AstFragmentKind::ForeignItems,
)
.make_foreign_items();
}
match foreign_item.kind {
ast::ForeignItemKind::MacCall(..) => {
self.check_attributes(&foreign_item.attrs);
foreign_item.and_then(|item| match item.kind {
ast::ForeignItemKind::MacCall(mac) => self
.collect_bang(mac, item.span, AstFragmentKind::ForeignItems)
.make_foreign_items(),
_ => unreachable!(),
})
}
_ => noop_flat_map_foreign_item(foreign_item, self),
}
}
fn visit_item_kind(&mut self, item: &mut ast::ItemKind) {
match item {
ast::ItemKind::MacroDef(..) => {}
_ => {
self.cfg.configure_item_kind(item);
noop_visit_item_kind(item, self);
}
}
}
fn flat_map_generic_param(
&mut self,
param: ast::GenericParam,
) -> SmallVec<[ast::GenericParam; 1]> {
let mut param = configure!(self, param);
if let Some(attr) = self.take_first_attr(&mut param) {
return self
.collect_attr(
attr,
Annotatable::GenericParam(param),
AstFragmentKind::GenericParams,
)
.make_generic_params();
}
noop_flat_map_generic_param(param, self)
}
fn visit_attribute(&mut self, at: &mut ast::Attribute) {
// turn `#[doc(include="filename")]` attributes into `#[doc(include(file="filename",
// contents="file contents")]` attributes
if !self.cx.sess.check_name(at, sym::doc) {
return noop_visit_attribute(at, self);
}
if let Some(list) = at.meta_item_list() {
if !list.iter().any(|it| it.has_name(sym::include)) {
return noop_visit_attribute(at, self);
}
let mut items = vec![];
for mut it in list {
if !it.has_name(sym::include) {
items.push({
noop_visit_meta_list_item(&mut it, self);
it
});
continue;
}
if let Some(file) = it.value_str() {
let err_count = self.cx.sess.parse_sess.span_diagnostic.err_count();
self.check_attributes(slice::from_ref(at));
if self.cx.sess.parse_sess.span_diagnostic.err_count() > err_count {
// avoid loading the file if they haven't enabled the feature
return noop_visit_attribute(at, self);
}
let filename = match self.cx.resolve_path(&*file.as_str(), it.span()) {
Ok(filename) => filename,
Err(mut err) => {
err.emit();
continue;
}
};
match self.cx.source_map().load_file(&filename) {
Ok(source_file) => {
let src = source_file
.src
.as_ref()
.expect("freshly loaded file should have a source");
let src_interned = Symbol::intern(src.as_str());
let include_info = vec![
ast::NestedMetaItem::MetaItem(attr::mk_name_value_item_str(
Ident::with_dummy_span(sym::file),
file,
DUMMY_SP,
)),
ast::NestedMetaItem::MetaItem(attr::mk_name_value_item_str(
Ident::with_dummy_span(sym::contents),
src_interned,
DUMMY_SP,
)),
];
let include_ident = Ident::with_dummy_span(sym::include);
let item = attr::mk_list_item(include_ident, include_info);
items.push(ast::NestedMetaItem::MetaItem(item));
}
Err(e) => {
let lit_span = it.name_value_literal_span().unwrap();
if e.kind() == ErrorKind::InvalidData {
self.cx
.struct_span_err(
lit_span,
&format!("{} wasn't a utf-8 file", filename.display()),
)
.span_label(lit_span, "contains invalid utf-8")
.emit();
} else {
let mut err = self.cx.struct_span_err(
lit_span,
&format!("couldn't read {}: {}", filename.display(), e),
);
err.span_label(lit_span, "couldn't read file");
err.emit();
}
}
}
} else {
let mut err = self
.cx
.struct_span_err(it.span(), "expected path to external documentation");
// Check if the user erroneously used `doc(include(...))` syntax.
let literal = it.meta_item_list().and_then(|list| {
if list.len() == 1 {
list[0].literal().map(|literal| &literal.kind)
} else {
None
}
});
let (path, applicability) = match &literal {
Some(LitKind::Str(path, ..)) => {
(path.to_string(), Applicability::MachineApplicable)
}
_ => (String::from("<path>"), Applicability::HasPlaceholders),
};
err.span_suggestion(
it.span(),
"provide a file path with `=`",
format!("include = \"{}\"", path),
applicability,
);
err.emit();
}
}
let meta = attr::mk_list_item(Ident::with_dummy_span(sym::doc), items);
*at = ast::Attribute {
kind: ast::AttrKind::Normal(
AttrItem { path: meta.path, args: meta.kind.mac_args(meta.span), tokens: None },
None,
),
span: at.span,
id: at.id,
style: at.style,
};
} else {
noop_visit_attribute(at, self)
}
}
fn visit_id(&mut self, id: &mut ast::NodeId) {
if self.monotonic {
debug_assert_eq!(*id, ast::DUMMY_NODE_ID);
*id = self.cx.resolver.next_node_id()
}
}
fn visit_fn_decl(&mut self, mut fn_decl: &mut P<ast::FnDecl>) {
self.cfg.configure_fn_decl(&mut fn_decl);
noop_visit_fn_decl(fn_decl, self);
}
}
pub struct ExpansionConfig<'feat> {
pub crate_name: String,
pub features: Option<&'feat Features>,
pub recursion_limit: Limit,
pub trace_mac: bool,
pub should_test: bool, // If false, strip `#[test]` nodes
pub keep_macs: bool,
pub span_debug: bool, // If true, use verbose debugging for `proc_macro::Span`
pub proc_macro_backtrace: bool, // If true, show backtraces for proc-macro panics
}
impl<'feat> ExpansionConfig<'feat> {
pub fn default(crate_name: String) -> ExpansionConfig<'static> {
ExpansionConfig {
crate_name,
features: None,
recursion_limit: Limit::new(1024),
trace_mac: false,
should_test: false,
keep_macs: false,
span_debug: false,
proc_macro_backtrace: false,
}
}
fn proc_macro_hygiene(&self) -> bool {
self.features.map_or(false, |features| features.proc_macro_hygiene)
}
}
Reference in New Issue View Git Blame Copy Permalink