//! Defines database & queries for macro expansion.
use std::sync::Arc;
use base_db::{salsa, SourceDatabase};
use mbe::{ExpandError, ExpandResult};
use parser::FragmentKind;
use syntax::{
algo::diff,
ast::{self, NameOwner},
AstNode, GreenNode, Parse, SyntaxNode, SyntaxToken,
};
use crate::{
ast_id_map::AstIdMap, hygiene::HygieneFrame, input::process_macro_input, BuiltinAttrExpander,
BuiltinDeriveExpander, BuiltinFnLikeExpander, HirFileId, HirFileIdRepr, MacroCallId,
MacroCallKind, MacroCallLoc, MacroDefId, MacroDefKind, MacroFile, ProcMacroExpander,
};
/// Total limit on the number of tokens produced by any macro invocation.
///
/// If an invocation produces more tokens than this limit, it will not be stored in the database and
/// an error will be emitted.
const TOKEN_LIMIT: usize = 524288;
#[derive(Debug, Clone, Eq, PartialEq)]
pub enum TokenExpander {
/// Old-style `macro_rules`.
MacroRules { mac: mbe::MacroRules, def_site_token_map: mbe::TokenMap },
/// AKA macros 2.0.
MacroDef { mac: mbe::MacroDef, def_site_token_map: mbe::TokenMap },
/// Stuff like `line!` and `file!`.
Builtin(BuiltinFnLikeExpander),
/// `global_allocator` and such.
BuiltinAttr(BuiltinAttrExpander),
/// `derive(Copy)` and such.
BuiltinDerive(BuiltinDeriveExpander),
/// The thing we love the most here in rust-analyzer -- procedural macros.
ProcMacro(ProcMacroExpander),
}
impl TokenExpander {
fn expand(
&self,
db: &dyn AstDatabase,
id: MacroCallId,
tt: &tt::Subtree,
) -> mbe::ExpandResult<tt::Subtree> {
match self {
TokenExpander::MacroRules { mac, .. } => mac.expand(tt),
TokenExpander::MacroDef { mac, .. } => mac.expand(tt),
TokenExpander::Builtin(it) => it.expand(db, id, tt),
// FIXME switch these to ExpandResult as well
TokenExpander::BuiltinAttr(it) => it.expand(db, id, tt).into(),
TokenExpander::BuiltinDerive(it) => it.expand(db, id, tt).into(),
TokenExpander::ProcMacro(_) => {
// We store the result in salsa db to prevent non-deterministic behavior in
// some proc-macro implementation
// See #4315 for details
db.expand_proc_macro(id).into()
}
}
}
pub(crate) fn map_id_down(&self, id: tt::TokenId) -> tt::TokenId {
match self {
TokenExpander::MacroRules { mac, .. } => mac.map_id_down(id),
TokenExpander::MacroDef { mac, .. } => mac.map_id_down(id),
TokenExpander::Builtin(..)
| TokenExpander::BuiltinAttr(..)
| TokenExpander::BuiltinDerive(..)
| TokenExpander::ProcMacro(..) => id,
}
}
pub(crate) fn map_id_up(&self, id: tt::TokenId) -> (tt::TokenId, mbe::Origin) {
match self {
TokenExpander::MacroRules { mac, .. } => mac.map_id_up(id),
TokenExpander::MacroDef { mac, .. } => mac.map_id_up(id),
TokenExpander::Builtin(..)
| TokenExpander::BuiltinAttr(..)
| TokenExpander::BuiltinDerive(..)
| TokenExpander::ProcMacro(..) => (id, mbe::Origin::Call),
}
}
}
// FIXME: rename to ExpandDatabase
#[salsa::query_group(AstDatabaseStorage)]
pub trait AstDatabase: SourceDatabase {
fn ast_id_map(&self, file_id: HirFileId) -> Arc<AstIdMap>;
/// Main public API -- parses a hir file, not caring whether it's a real
/// file or a macro expansion.
#[salsa::transparent]
fn parse_or_expand(&self, file_id: HirFileId) -> Option<SyntaxNode>;
/// Implementation for the macro case.
fn parse_macro_expansion(
&self,
macro_file: MacroFile,
) -> ExpandResult<Option<(Parse<SyntaxNode>, Arc<mbe::TokenMap>)>>;
/// Macro ids. That's probably the tricksiest bit in rust-analyzer, and the
/// reason why we use salsa at all.
///
/// We encode macro definitions into ids of macro calls, this what allows us
/// to be incremental.
#[salsa::interned]
fn intern_macro(&self, macro_call: MacroCallLoc) -> MacroCallId;
/// Lowers syntactic macro call to a token tree representation.
#[salsa::transparent]
fn macro_arg(&self, id: MacroCallId) -> Option<Arc<(tt::Subtree, mbe::TokenMap)>>;
/// Extracts syntax node, corresponding to a macro call. That's a firewall
/// query, only typing in the macro call itself changes the returned
/// subtree.
fn macro_arg_text(&self, id: MacroCallId) -> Option<GreenNode>;
/// Gets the expander for this macro. This compiles declarative macros, and
/// just fetches procedural ones.
fn macro_def(&self, id: MacroDefId) -> Option<Arc<TokenExpander>>;
/// Expand macro call to a token tree. This query is LRUed (we keep 128 or so results in memory)
fn macro_expand(&self, macro_call: MacroCallId) -> ExpandResult<Option<Arc<tt::Subtree>>>;
/// Special case of the previous query for procedural macros. We can't LRU
/// proc macros, since they are not deterministic in general, and
/// non-determinism breaks salsa in a very, very, very bad way. @edwin0cheng
/// heroically debugged this once!
fn expand_proc_macro(&self, call: MacroCallId) -> Result<tt::Subtree, mbe::ExpandError>;
/// Firewall query that returns the error from the `macro_expand` query.
fn macro_expand_error(&self, macro_call: MacroCallId) -> Option<ExpandError>;
fn hygiene_frame(&self, file_id: HirFileId) -> Arc<HygieneFrame>;
}
/// This expands the given macro call, but with different arguments. This is
/// used for completion, where we want to see what 'would happen' if we insert a
/// token. The `token_to_map` mapped down into the expansion, with the mapped
/// token returned.
pub fn expand_speculative(
db: &dyn AstDatabase,
actual_macro_call: MacroCallId,
speculative_args: &ast::TokenTree,
token_to_map: SyntaxToken,
) -> Option<(SyntaxNode, SyntaxToken)> {
let (tt, tmap_1) = mbe::syntax_node_to_token_tree(speculative_args.syntax());
let range =
token_to_map.text_range().checked_sub(speculative_args.syntax().text_range().start())?;
let token_id = tmap_1.token_by_range(range)?;
let macro_def = {
let loc: MacroCallLoc = db.lookup_intern_macro(actual_macro_call);
db.macro_def(loc.def)?
};
let speculative_expansion = macro_def.expand(db, actual_macro_call, &tt);
let fragment_kind = macro_fragment_kind(db, actual_macro_call);
let (node, tmap_2) =
mbe::token_tree_to_syntax_node(&speculative_expansion.value, fragment_kind).ok()?;
let token_id = macro_def.map_id_down(token_id);
let range = tmap_2.range_by_token(token_id, token_to_map.kind())?;
let token = node.syntax_node().covering_element(range).into_token()?;
Some((node.syntax_node(), token))
}
fn ast_id_map(db: &dyn AstDatabase, file_id: HirFileId) -> Arc<AstIdMap> {
let map = db.parse_or_expand(file_id).map(|it| AstIdMap::from_source(&it)).unwrap_or_default();
Arc::new(map)
}
fn parse_or_expand(db: &dyn AstDatabase, file_id: HirFileId) -> Option<SyntaxNode> {
match file_id.0 {
HirFileIdRepr::FileId(file_id) => Some(db.parse(file_id).tree().syntax().clone()),
HirFileIdRepr::MacroFile(macro_file) => {
db.parse_macro_expansion(macro_file).value.map(|(it, _)| it.syntax_node())
}
}
}
fn parse_macro_expansion(
db: &dyn AstDatabase,
macro_file: MacroFile,
) -> ExpandResult<Option<(Parse<SyntaxNode>, Arc<mbe::TokenMap>)>> {
let _p = profile::span("parse_macro_expansion");
let result = db.macro_expand(macro_file.macro_call_id);
if let Some(err) = &result.err {
// Note:
// The final goal we would like to make all parse_macro success,
// such that the following log will not call anyway.
let loc: MacroCallLoc = db.lookup_intern_macro(macro_file.macro_call_id);
let node = loc.kind.to_node(db);
// collect parent information for warning log
let parents =
std::iter::successors(loc.kind.file_id().call_node(db), |it| it.file_id.call_node(db))
.map(|n| format!("{:#}", n.value))
.collect::<Vec<_>>()
.join("\n");
log::warn!(
"fail on macro_parse: (reason: {:?} macro_call: {:#}) parents: {}",
err,
node.value,
parents
);
}
let tt = match result.value {
Some(tt) => tt,
None => return ExpandResult { value: None, err: result.err },
};
let fragment_kind = macro_fragment_kind(db, macro_file.macro_call_id);
log::debug!("expanded = {}", tt.as_debug_string());
log::debug!("kind = {:?}", fragment_kind);
let (parse, rev_token_map) = match mbe::token_tree_to_syntax_node(&tt, fragment_kind) {
Ok(it) => it,
Err(err) => {
log::debug!(
"failed to parse expanstion to {:?} = {}",
fragment_kind,
tt.as_debug_string()
);
return ExpandResult::only_err(err);
}
};
match result.err {
Some(err) => {
// Safety check for recursive identity macro.
let node = parse.syntax_node();
let file: HirFileId = macro_file.into();
let call_node = match file.call_node(db) {
Some(it) => it,
None => {
return ExpandResult::only_err(err);
}
};
if is_self_replicating(&node, &call_node.value) {
ExpandResult::only_err(err)
} else {
ExpandResult { value: Some((parse, Arc::new(rev_token_map))), err: Some(err) }
}
}
None => {
log::debug!("parse = {:?}", parse.syntax_node().kind());
ExpandResult { value: Some((parse, Arc::new(rev_token_map))), err: None }
}
}
}
fn macro_arg(db: &dyn AstDatabase, id: MacroCallId) -> Option<Arc<(tt::Subtree, mbe::TokenMap)>> {
let arg = db.macro_arg_text(id)?;
let (mut tt, tmap) = mbe::syntax_node_to_token_tree(&SyntaxNode::new_root(arg));
let loc: MacroCallLoc = db.lookup_intern_macro(id);
if loc.def.is_proc_macro() {
// proc macros expect their inputs without parentheses, MBEs expect it with them included
tt.delimiter = None;
}
Some(Arc::new((tt, tmap)))
}
fn macro_arg_text(db: &dyn AstDatabase, id: MacroCallId) -> Option<GreenNode> {
let loc = db.lookup_intern_macro(id);
let arg = loc.kind.arg(db)?;
let arg = process_macro_input(db, arg, id);
Some(arg.green().into())
}
fn macro_def(db: &dyn AstDatabase, id: MacroDefId) -> Option<Arc<TokenExpander>> {
match id.kind {
MacroDefKind::Declarative(ast_id) => match ast_id.to_node(db) {
ast::Macro::MacroRules(macro_rules) => {
let arg = macro_rules.token_tree()?;
let (tt, def_site_token_map) = mbe::ast_to_token_tree(&arg);
let mac = match mbe::MacroRules::parse(&tt) {
Ok(it) => it,
Err(err) => {
let name = macro_rules.name().map(|n| n.to_string()).unwrap_or_default();
log::warn!("fail on macro_def parse ({}): {:?} {:#?}", name, err, tt);
return None;
}
};
Some(Arc::new(TokenExpander::MacroRules { mac, def_site_token_map }))
}
ast::Macro::MacroDef(macro_def) => {
let arg = macro_def.body()?;
let (tt, def_site_token_map) = mbe::ast_to_token_tree(&arg);
let mac = match mbe::MacroDef::parse(&tt) {
Ok(it) => it,
Err(err) => {
let name = macro_def.name().map(|n| n.to_string()).unwrap_or_default();
log::warn!("fail on macro_def parse ({}): {:?} {:#?}", name, err, tt);
return None;
}
};
Some(Arc::new(TokenExpander::MacroDef { mac, def_site_token_map }))
}
},
MacroDefKind::BuiltIn(expander, _) => Some(Arc::new(TokenExpander::Builtin(expander))),
MacroDefKind::BuiltInAttr(expander, _) => {
Some(Arc::new(TokenExpander::BuiltinAttr(expander)))
}
MacroDefKind::BuiltInDerive(expander, _) => {
Some(Arc::new(TokenExpander::BuiltinDerive(expander)))
}
MacroDefKind::BuiltInEager(..) => None,
MacroDefKind::ProcMacro(expander, ..) => Some(Arc::new(TokenExpander::ProcMacro(expander))),
}
}
fn macro_expand(db: &dyn AstDatabase, id: MacroCallId) -> ExpandResult<Option<Arc<tt::Subtree>>> {
macro_expand_with_arg(db, id, None)
}
fn macro_expand_error(db: &dyn AstDatabase, macro_call: MacroCallId) -> Option<ExpandError> {
db.macro_expand(macro_call).err
}
fn macro_expand_with_arg(
db: &dyn AstDatabase,
id: MacroCallId,
arg: Option<Arc<(tt::Subtree, mbe::TokenMap)>>,
) -> ExpandResult<Option<Arc<tt::Subtree>>> {
let _p = profile::span("macro_expand");
let loc: MacroCallLoc = db.lookup_intern_macro(id);
if let Some(eager) = &loc.eager {
if arg.is_some() {
return ExpandResult::str_err(
"speculative macro expansion not implemented for eager macro".to_owned(),
);
} else {
return ExpandResult {
value: Some(eager.arg_or_expansion.clone()),
// FIXME: There could be errors here!
err: None,
};
}
}
let macro_arg = match arg.or_else(|| db.macro_arg(id)) {
Some(it) => it,
None => return ExpandResult::str_err("Fail to args in to tt::TokenTree".into()),
};
let macro_rules = match db.macro_def(loc.def) {
Some(it) => it,
None => return ExpandResult::str_err("Fail to find macro definition".into()),
};
let ExpandResult { value: tt, err } = macro_rules.expand(db, id, ¯o_arg.0);
// Set a hard limit for the expanded tt
let count = tt.count();
if count > TOKEN_LIMIT {
return ExpandResult::str_err(format!(
"macro invocation exceeds token limit: produced {} tokens, limit is {}",
count, TOKEN_LIMIT,
));
}
ExpandResult { value: Some(Arc::new(tt)), err }
}
fn expand_proc_macro(
db: &dyn AstDatabase,
id: MacroCallId,
) -> Result<tt::Subtree, mbe::ExpandError> {
let loc: MacroCallLoc = db.lookup_intern_macro(id);
let macro_arg = match db.macro_arg(id) {
Some(it) => it,
None => {
return Err(
tt::ExpansionError::Unknown("No arguments for proc-macro".to_string()).into()
)
}
};
let expander = match loc.def.kind {
MacroDefKind::ProcMacro(expander, ..) => expander,
_ => unreachable!(),
};
let attr_arg = match &loc.kind {
MacroCallKind::Attr { attr_args, .. } => Some(attr_args),
_ => None,
};
expander.expand(db, loc.krate, ¯o_arg.0, attr_arg)
}
fn is_self_replicating(from: &SyntaxNode, to: &SyntaxNode) -> bool {
if diff(from, to).is_empty() {
return true;
}
if let Some(stmts) = ast::MacroStmts::cast(from.clone()) {
if stmts.statements().any(|stmt| diff(stmt.syntax(), to).is_empty()) {
return true;
}
if let Some(expr) = stmts.expr() {
if diff(expr.syntax(), to).is_empty() {
return true;
}
}
}
false
}
fn hygiene_frame(db: &dyn AstDatabase, file_id: HirFileId) -> Arc<HygieneFrame> {
Arc::new(HygieneFrame::new(db, file_id))
}
fn macro_fragment_kind(db: &dyn AstDatabase, id: MacroCallId) -> FragmentKind {
let loc: MacroCallLoc = db.lookup_intern_macro(id);
loc.kind.fragment_kind()
}