//! Source positions and related helper functions. //! //! Important concepts in this module include: //! //! - the *span*, represented by [`SpanData`] and related types; //! - source code as represented by a [`SourceMap`]; and //! - interned strings, represented by [`Symbol`]s, with some common symbols available statically in the [`sym`] module. //! //! Unlike most compilers, the span contains not only the position in the source code, but also various other metadata, //! such as the edition and macro hygiene. This metadata is stored in [`SyntaxContext`] and [`ExpnData`]. //! //! ## Note //! //! This API is completely unstable and subject to change. #![doc(html_root_url = "https://doc.rust-lang.org/nightly/nightly-rustc/")] #![feature(array_windows)] #![feature(if_let_guard)] #![feature(negative_impls)] #![feature(min_specialization)] #![feature(rustc_attrs)] #![feature(let_chains)] #![feature(round_char_boundary)] #![deny(rustc::untranslatable_diagnostic)] #![deny(rustc::diagnostic_outside_of_impl)] #![cfg_attr(not(bootstrap), allow(internal_features))] #[macro_use] extern crate rustc_macros; #[macro_use] extern crate tracing; use rustc_data_structures::AtomicRef; use rustc_macros::HashStable_Generic; use rustc_serialize::{Decodable, Decoder, Encodable, Encoder}; mod caching_source_map_view; pub mod source_map; pub use self::caching_source_map_view::CachingSourceMapView; use source_map::SourceMap; pub mod edition; use edition::Edition; pub mod hygiene; use hygiene::Transparency; pub use hygiene::{DesugaringKind, ExpnKind, MacroKind}; pub use hygiene::{ExpnData, ExpnHash, ExpnId, LocalExpnId, SyntaxContext}; use rustc_data_structures::stable_hasher::HashingControls; pub mod def_id; use def_id::{CrateNum, DefId, DefPathHash, LocalDefId, LOCAL_CRATE}; pub mod edit_distance; mod span_encoding; pub use span_encoding::{Span, DUMMY_SP}; pub mod symbol; pub use symbol::{sym, Symbol}; mod analyze_source_file; pub mod fatal_error; pub mod profiling; use rustc_data_structures::stable_hasher::{Hash128, Hash64, HashStable, StableHasher}; use rustc_data_structures::sync::{Lock, Lrc}; use std::borrow::Cow; use std::cmp::{self, Ordering}; use std::hash::Hash; use std::ops::{Add, Range, Sub}; use std::path::{Path, PathBuf}; use std::str::FromStr; use std::{fmt, iter}; use md5::Digest; use md5::Md5; use sha1::Sha1; use sha2::Sha256; #[cfg(test)] mod tests; /// Per-session global variables: this struct is stored in thread-local storage /// in such a way that it is accessible without any kind of handle to all /// threads within the compilation session, but is not accessible outside the /// session. pub struct SessionGlobals { symbol_interner: symbol::Interner, span_interner: Lock, hygiene_data: Lock, /// A reference to the source map in the `Session`. It's an `Option` /// because it can't be initialized until `Session` is created, which /// happens after `SessionGlobals`. `set_source_map` does the /// initialization. /// /// This field should only be used in places where the `Session` is truly /// not available, such as `::fmt`. source_map: Lock>>, } impl SessionGlobals { pub fn new(edition: Edition) -> SessionGlobals { SessionGlobals { symbol_interner: symbol::Interner::fresh(), span_interner: Lock::new(span_encoding::SpanInterner::default()), hygiene_data: Lock::new(hygiene::HygieneData::new(edition)), source_map: Lock::new(None), } } } #[inline] pub fn create_session_globals_then(edition: Edition, f: impl FnOnce() -> R) -> R { assert!( !SESSION_GLOBALS.is_set(), "SESSION_GLOBALS should never be overwritten! \ Use another thread if you need another SessionGlobals" ); let session_globals = SessionGlobals::new(edition); SESSION_GLOBALS.set(&session_globals, f) } #[inline] pub fn set_session_globals_then(session_globals: &SessionGlobals, f: impl FnOnce() -> R) -> R { assert!( !SESSION_GLOBALS.is_set(), "SESSION_GLOBALS should never be overwritten! \ Use another thread if you need another SessionGlobals" ); SESSION_GLOBALS.set(session_globals, f) } #[inline] pub fn create_default_session_if_not_set_then(f: F) -> R where F: FnOnce(&SessionGlobals) -> R, { create_session_if_not_set_then(edition::DEFAULT_EDITION, f) } #[inline] pub fn create_session_if_not_set_then(edition: Edition, f: F) -> R where F: FnOnce(&SessionGlobals) -> R, { if !SESSION_GLOBALS.is_set() { let session_globals = SessionGlobals::new(edition); SESSION_GLOBALS.set(&session_globals, || SESSION_GLOBALS.with(f)) } else { SESSION_GLOBALS.with(f) } } #[inline] pub fn with_session_globals(f: F) -> R where F: FnOnce(&SessionGlobals) -> R, { SESSION_GLOBALS.with(f) } #[inline] pub fn create_default_session_globals_then(f: impl FnOnce() -> R) -> R { create_session_globals_then(edition::DEFAULT_EDITION, f) } // If this ever becomes non thread-local, `decode_syntax_context` // and `decode_expn_id` will need to be updated to handle concurrent // deserialization. scoped_tls::scoped_thread_local!(static SESSION_GLOBALS: SessionGlobals); // FIXME: We should use this enum or something like it to get rid of the // use of magic `/rust/1.x/...` paths across the board. #[derive(Debug, Eq, PartialEq, Clone, Ord, PartialOrd)] #[derive(Decodable)] pub enum RealFileName { LocalPath(PathBuf), /// For remapped paths (namely paths into libstd that have been mapped /// to the appropriate spot on the local host's file system, and local file /// system paths that have been remapped with `FilePathMapping`), Remapped { /// `local_path` is the (host-dependent) local path to the file. This is /// None if the file was imported from another crate local_path: Option, /// `virtual_name` is the stable path rustc will store internally within /// build artifacts. virtual_name: PathBuf, }, } impl Hash for RealFileName { fn hash(&self, state: &mut H) { // To prevent #70924 from happening again we should only hash the // remapped (virtualized) path if that exists. This is because // virtualized paths to sysroot crates (/rust/$hash or /rust/$version) // remain stable even if the corresponding local_path changes self.remapped_path_if_available().hash(state) } } // This is functionally identical to #[derive(Encodable)], with the exception of // an added assert statement impl Encodable for RealFileName { fn encode(&self, encoder: &mut S) { match *self { RealFileName::LocalPath(ref local_path) => encoder.emit_enum_variant(0, |encoder| { local_path.encode(encoder); }), RealFileName::Remapped { ref local_path, ref virtual_name } => encoder .emit_enum_variant(1, |encoder| { // For privacy and build reproducibility, we must not embed host-dependant path in artifacts // if they have been remapped by --remap-path-prefix assert!(local_path.is_none()); local_path.encode(encoder); virtual_name.encode(encoder); }), } } } impl RealFileName { /// Returns the path suitable for reading from the file system on the local host, /// if this information exists. /// Avoid embedding this in build artifacts; see `remapped_path_if_available()` for that. pub fn local_path(&self) -> Option<&Path> { match self { RealFileName::LocalPath(p) => Some(p), RealFileName::Remapped { local_path, virtual_name: _ } => local_path.as_deref(), } } /// Returns the path suitable for reading from the file system on the local host, /// if this information exists. /// Avoid embedding this in build artifacts; see `remapped_path_if_available()` for that. pub fn into_local_path(self) -> Option { match self { RealFileName::LocalPath(p) => Some(p), RealFileName::Remapped { local_path: p, virtual_name: _ } => p, } } /// Returns the path suitable for embedding into build artifacts. This would still /// be a local path if it has not been remapped. A remapped path will not correspond /// to a valid file system path: see `local_path_if_available()` for something that /// is more likely to return paths into the local host file system. pub fn remapped_path_if_available(&self) -> &Path { match self { RealFileName::LocalPath(p) | RealFileName::Remapped { local_path: _, virtual_name: p } => p, } } /// Returns the path suitable for reading from the file system on the local host, /// if this information exists. Otherwise returns the remapped name. /// Avoid embedding this in build artifacts; see `remapped_path_if_available()` for that. pub fn local_path_if_available(&self) -> &Path { match self { RealFileName::LocalPath(path) | RealFileName::Remapped { local_path: None, virtual_name: path } | RealFileName::Remapped { local_path: Some(path), virtual_name: _ } => path, } } pub fn to_string_lossy(&self, display_pref: FileNameDisplayPreference) -> Cow<'_, str> { match display_pref { FileNameDisplayPreference::Local => self.local_path_if_available().to_string_lossy(), FileNameDisplayPreference::Remapped => { self.remapped_path_if_available().to_string_lossy() } FileNameDisplayPreference::Short => self .local_path_if_available() .file_name() .map_or_else(|| "".into(), |f| f.to_string_lossy()), } } } /// Differentiates between real files and common virtual files. #[derive(Debug, Eq, PartialEq, Clone, Ord, PartialOrd, Hash)] #[derive(Decodable, Encodable)] pub enum FileName { Real(RealFileName), /// Call to `quote!`. QuoteExpansion(Hash64), /// Command line. Anon(Hash64), /// Hack in `src/librustc_ast/parse.rs`. // FIXME(jseyfried) MacroExpansion(Hash64), ProcMacroSourceCode(Hash64), /// Strings provided as `--cfg [cfgspec]` stored in a `crate_cfg`. CfgSpec(Hash64), /// Strings provided as crate attributes in the CLI. CliCrateAttr(Hash64), /// Custom sources for explicit parser calls from plugins and drivers. Custom(String), DocTest(PathBuf, isize), /// Post-substitution inline assembly from LLVM. InlineAsm(Hash64), } impl From for FileName { fn from(p: PathBuf) -> Self { assert!(!p.to_string_lossy().ends_with('>')); FileName::Real(RealFileName::LocalPath(p)) } } #[derive(Clone, Copy, Eq, PartialEq, Hash, Debug)] pub enum FileNameDisplayPreference { /// Display the path after the application of rewrite rules provided via `--remap-path-prefix`. /// This is appropriate for paths that get embedded into files produced by the compiler. Remapped, /// Display the path before the application of rewrite rules provided via `--remap-path-prefix`. /// This is appropriate for use in user-facing output (such as diagnostics). Local, /// Display only the filename, as a way to reduce the verbosity of the output. /// This is appropriate for use in user-facing output (such as diagnostics). Short, } pub struct FileNameDisplay<'a> { inner: &'a FileName, display_pref: FileNameDisplayPreference, } impl fmt::Display for FileNameDisplay<'_> { fn fmt(&self, fmt: &mut std::fmt::Formatter<'_>) -> std::fmt::Result { use FileName::*; match *self.inner { Real(ref name) => { write!(fmt, "{}", name.to_string_lossy(self.display_pref)) } QuoteExpansion(_) => write!(fmt, ""), MacroExpansion(_) => write!(fmt, ""), Anon(_) => write!(fmt, ""), ProcMacroSourceCode(_) => write!(fmt, ""), CfgSpec(_) => write!(fmt, ""), CliCrateAttr(_) => write!(fmt, ""), Custom(ref s) => write!(fmt, "<{s}>"), DocTest(ref path, _) => write!(fmt, "{}", path.display()), InlineAsm(_) => write!(fmt, ""), } } } impl<'a> FileNameDisplay<'a> { pub fn to_string_lossy(&self) -> Cow<'a, str> { match self.inner { FileName::Real(ref inner) => inner.to_string_lossy(self.display_pref), _ => Cow::from(self.to_string()), } } } impl FileName { pub fn is_real(&self) -> bool { use FileName::*; match *self { Real(_) => true, Anon(_) | MacroExpansion(_) | ProcMacroSourceCode(_) | CfgSpec(_) | CliCrateAttr(_) | Custom(_) | QuoteExpansion(_) | DocTest(_, _) | InlineAsm(_) => false, } } pub fn prefer_remapped(&self) -> FileNameDisplay<'_> { FileNameDisplay { inner: self, display_pref: FileNameDisplayPreference::Remapped } } /// This may include transient local filesystem information. /// Must not be embedded in build outputs. pub fn prefer_local(&self) -> FileNameDisplay<'_> { FileNameDisplay { inner: self, display_pref: FileNameDisplayPreference::Local } } pub fn display(&self, display_pref: FileNameDisplayPreference) -> FileNameDisplay<'_> { FileNameDisplay { inner: self, display_pref } } pub fn macro_expansion_source_code(src: &str) -> FileName { let mut hasher = StableHasher::new(); src.hash(&mut hasher); FileName::MacroExpansion(hasher.finish()) } pub fn anon_source_code(src: &str) -> FileName { let mut hasher = StableHasher::new(); src.hash(&mut hasher); FileName::Anon(hasher.finish()) } pub fn proc_macro_source_code(src: &str) -> FileName { let mut hasher = StableHasher::new(); src.hash(&mut hasher); FileName::ProcMacroSourceCode(hasher.finish()) } pub fn cfg_spec_source_code(src: &str) -> FileName { let mut hasher = StableHasher::new(); src.hash(&mut hasher); FileName::QuoteExpansion(hasher.finish()) } pub fn cli_crate_attr_source_code(src: &str) -> FileName { let mut hasher = StableHasher::new(); src.hash(&mut hasher); FileName::CliCrateAttr(hasher.finish()) } pub fn doc_test_source_code(path: PathBuf, line: isize) -> FileName { FileName::DocTest(path, line) } pub fn inline_asm_source_code(src: &str) -> FileName { let mut hasher = StableHasher::new(); src.hash(&mut hasher); FileName::InlineAsm(hasher.finish()) } } /// Represents a span. /// /// Spans represent a region of code, used for error reporting. Positions in spans /// are *absolute* positions from the beginning of the [`SourceMap`], not positions /// relative to [`SourceFile`]s. Methods on the `SourceMap` can be used to relate spans back /// to the original source. /// /// You must be careful if the span crosses more than one file, since you will not be /// able to use many of the functions on spans in source_map and you cannot assume /// that the length of the span is equal to `span.hi - span.lo`; there may be space in the /// [`BytePos`] range between files. /// /// `SpanData` is public because `Span` uses a thread-local interner and can't be /// sent to other threads, but some pieces of performance infra run in a separate thread. /// Using `Span` is generally preferred. #[derive(Clone, Copy, Hash, PartialEq, Eq)] pub struct SpanData { pub lo: BytePos, pub hi: BytePos, /// Information about where the macro came from, if this piece of /// code was created by a macro expansion. pub ctxt: SyntaxContext, pub parent: Option, } // Order spans by position in the file. impl Ord for SpanData { fn cmp(&self, other: &Self) -> Ordering { let SpanData { lo: s_lo, hi: s_hi, ctxt: s_ctxt, // `LocalDefId` does not implement `Ord`. // The other fields are enough to determine in-file order. parent: _, } = self; let SpanData { lo: o_lo, hi: o_hi, ctxt: o_ctxt, // `LocalDefId` does not implement `Ord`. // The other fields are enough to determine in-file order. parent: _, } = other; (s_lo, s_hi, s_ctxt).cmp(&(o_lo, o_hi, o_ctxt)) } } impl PartialOrd for SpanData { fn partial_cmp(&self, other: &Self) -> Option { Some(self.cmp(other)) } } impl SpanData { #[inline] pub fn span(&self) -> Span { Span::new(self.lo, self.hi, self.ctxt, self.parent) } #[inline] pub fn with_lo(&self, lo: BytePos) -> Span { Span::new(lo, self.hi, self.ctxt, self.parent) } #[inline] pub fn with_hi(&self, hi: BytePos) -> Span { Span::new(self.lo, hi, self.ctxt, self.parent) } #[inline] pub fn with_ctxt(&self, ctxt: SyntaxContext) -> Span { Span::new(self.lo, self.hi, ctxt, self.parent) } #[inline] pub fn with_parent(&self, parent: Option) -> Span { Span::new(self.lo, self.hi, self.ctxt, parent) } /// Returns `true` if this is a dummy span with any hygienic context. #[inline] pub fn is_dummy(self) -> bool { self.lo.0 == 0 && self.hi.0 == 0 } #[inline] pub fn is_visible(self, sm: &SourceMap) -> bool { !self.is_dummy() && sm.is_span_accessible(self.span()) } /// Returns `true` if `self` fully encloses `other`. pub fn contains(self, other: Self) -> bool { self.lo <= other.lo && other.hi <= self.hi } } // The interner is pointed to by a thread local value which is only set on the main thread // with parallelization is disabled. So we don't allow `Span` to transfer between threads // to avoid panics and other errors, even though it would be memory safe to do so. #[cfg(not(parallel_compiler))] impl !Send for Span {} #[cfg(not(parallel_compiler))] impl !Sync for Span {} impl PartialOrd for Span { fn partial_cmp(&self, rhs: &Self) -> Option { PartialOrd::partial_cmp(&self.data(), &rhs.data()) } } impl Ord for Span { fn cmp(&self, rhs: &Self) -> Ordering { Ord::cmp(&self.data(), &rhs.data()) } } impl Span { #[inline] pub fn lo(self) -> BytePos { self.data().lo } #[inline] pub fn with_lo(self, lo: BytePos) -> Span { self.data().with_lo(lo) } #[inline] pub fn hi(self) -> BytePos { self.data().hi } #[inline] pub fn with_hi(self, hi: BytePos) -> Span { self.data().with_hi(hi) } #[inline] pub fn eq_ctxt(self, other: Span) -> bool { self.data_untracked().ctxt == other.data_untracked().ctxt } #[inline] pub fn with_ctxt(self, ctxt: SyntaxContext) -> Span { self.data_untracked().with_ctxt(ctxt) } #[inline] pub fn parent(self) -> Option { self.data().parent } #[inline] pub fn with_parent(self, ctxt: Option) -> Span { self.data().with_parent(ctxt) } /// Returns `true` if this is a dummy span with any hygienic context. #[inline] pub fn is_dummy(self) -> bool { self.data_untracked().is_dummy() } #[inline] pub fn is_visible(self, sm: &SourceMap) -> bool { self.data_untracked().is_visible(sm) } /// Returns `true` if this span comes from any kind of macro, desugaring or inlining. #[inline] pub fn from_expansion(self) -> bool { self.ctxt() != SyntaxContext::root() } /// Returns `true` if `span` originates in a macro's expansion where debuginfo should be /// collapsed. pub fn in_macro_expansion_with_collapse_debuginfo(self) -> bool { let outer_expn = self.ctxt().outer_expn_data(); matches!(outer_expn.kind, ExpnKind::Macro(..)) && outer_expn.collapse_debuginfo } /// Returns `true` if `span` originates in a derive-macro's expansion. pub fn in_derive_expansion(self) -> bool { matches!(self.ctxt().outer_expn_data().kind, ExpnKind::Macro(MacroKind::Derive, _)) } /// Gate suggestions that would not be appropriate in a context the user didn't write. pub fn can_be_used_for_suggestions(self) -> bool { !self.from_expansion() // FIXME: If this span comes from a `derive` macro but it points at code the user wrote, // the callsite span and the span will be pointing at different places. It also means that // we can safely provide suggestions on this span. || (self.in_derive_expansion() && self.parent_callsite().map(|p| (p.lo(), p.hi())) != Some((self.lo(), self.hi()))) } #[inline] pub fn with_root_ctxt(lo: BytePos, hi: BytePos) -> Span { Span::new(lo, hi, SyntaxContext::root(), None) } /// Returns a new span representing an empty span at the beginning of this span. #[inline] pub fn shrink_to_lo(self) -> Span { let span = self.data_untracked(); span.with_hi(span.lo) } /// Returns a new span representing an empty span at the end of this span. #[inline] pub fn shrink_to_hi(self) -> Span { let span = self.data_untracked(); span.with_lo(span.hi) } #[inline] /// Returns `true` if `hi == lo`. pub fn is_empty(self) -> bool { let span = self.data_untracked(); span.hi == span.lo } /// Returns `self` if `self` is not the dummy span, and `other` otherwise. pub fn substitute_dummy(self, other: Span) -> Span { if self.is_dummy() { other } else { self } } /// Returns `true` if `self` fully encloses `other`. pub fn contains(self, other: Span) -> bool { let span = self.data(); let other = other.data(); span.contains(other) } /// Returns `true` if `self` touches `other`. pub fn overlaps(self, other: Span) -> bool { let span = self.data(); let other = other.data(); span.lo < other.hi && other.lo < span.hi } /// Returns `true` if the spans are equal with regards to the source text. /// /// Use this instead of `==` when either span could be generated code, /// and you only care that they point to the same bytes of source text. pub fn source_equal(self, other: Span) -> bool { let span = self.data(); let other = other.data(); span.lo == other.lo && span.hi == other.hi } /// Returns `Some(span)`, where the start is trimmed by the end of `other`. pub fn trim_start(self, other: Span) -> Option { let span = self.data(); let other = other.data(); if span.hi > other.hi { Some(span.with_lo(cmp::max(span.lo, other.hi))) } else { None } } /// Returns the source span -- this is either the supplied span, or the span for /// the macro callsite that expanded to it. pub fn source_callsite(self) -> Span { let expn_data = self.ctxt().outer_expn_data(); if !expn_data.is_root() { expn_data.call_site.source_callsite() } else { self } } /// The `Span` for the tokens in the previous macro expansion from which `self` was generated, /// if any. pub fn parent_callsite(self) -> Option { let expn_data = self.ctxt().outer_expn_data(); if !expn_data.is_root() { Some(expn_data.call_site) } else { None } } /// Walk down the expansion ancestors to find a span that's contained within `outer`. /// /// The span returned by this method may have a different [`SyntaxContext`] as `outer`. /// If you need to extend the span, use [`find_ancestor_inside_same_ctxt`] instead, /// because joining spans with different syntax contexts can create unexpected results. /// /// [`find_ancestor_inside_same_ctxt`]: Self::find_ancestor_inside_same_ctxt pub fn find_ancestor_inside(mut self, outer: Span) -> Option { while !outer.contains(self) { self = self.parent_callsite()?; } Some(self) } /// Walk down the expansion ancestors to find a span with the same [`SyntaxContext`] as /// `other`. /// /// Like [`find_ancestor_inside_same_ctxt`], but specifically for when spans might not /// overlap. Take care when using this, and prefer [`find_ancestor_inside`] or /// [`find_ancestor_inside_same_ctxt`] when you know that the spans are nested (modulo /// macro expansion). /// /// [`find_ancestor_inside`]: Self::find_ancestor_inside /// [`find_ancestor_inside_same_ctxt`]: Self::find_ancestor_inside_same_ctxt pub fn find_ancestor_in_same_ctxt(mut self, other: Span) -> Option { while !self.eq_ctxt(other) { self = self.parent_callsite()?; } Some(self) } /// Walk down the expansion ancestors to find a span that's contained within `outer` and /// has the same [`SyntaxContext`] as `outer`. /// /// This method is the combination of [`find_ancestor_inside`] and /// [`find_ancestor_in_same_ctxt`] and should be preferred when extending the returned span. /// If you do not need to modify the span, use [`find_ancestor_inside`] instead. /// /// [`find_ancestor_inside`]: Self::find_ancestor_inside /// [`find_ancestor_in_same_ctxt`]: Self::find_ancestor_in_same_ctxt pub fn find_ancestor_inside_same_ctxt(mut self, outer: Span) -> Option { while !outer.contains(self) || !self.eq_ctxt(outer) { self = self.parent_callsite()?; } Some(self) } /// Edition of the crate from which this span came. pub fn edition(self) -> edition::Edition { self.ctxt().edition() } /// Is this edition 2015? #[inline] pub fn is_rust_2015(self) -> bool { self.edition().is_rust_2015() } /// Are we allowed to use features from the Rust 2018 edition? #[inline] pub fn at_least_rust_2018(self) -> bool { self.edition().at_least_rust_2018() } /// Are we allowed to use features from the Rust 2021 edition? #[inline] pub fn at_least_rust_2021(self) -> bool { self.edition().at_least_rust_2021() } /// Are we allowed to use features from the Rust 2024 edition? #[inline] pub fn at_least_rust_2024(self) -> bool { self.edition().at_least_rust_2024() } /// Returns the source callee. /// /// Returns `None` if the supplied span has no expansion trace, /// else returns the `ExpnData` for the macro definition /// corresponding to the source callsite. pub fn source_callee(self) -> Option { let expn_data = self.ctxt().outer_expn_data(); // Create an iterator of call site expansions iter::successors(Some(expn_data), |expn_data| { Some(expn_data.call_site.ctxt().outer_expn_data()) }) // Find the last expansion which is not root .take_while(|expn_data| !expn_data.is_root()) .last() } /// Checks if a span is "internal" to a macro in which `#[unstable]` /// items can be used (that is, a macro marked with /// `#[allow_internal_unstable]`). pub fn allows_unstable(self, feature: Symbol) -> bool { self.ctxt() .outer_expn_data() .allow_internal_unstable .is_some_and(|features| features.iter().any(|&f| f == feature)) } /// Checks if this span arises from a compiler desugaring of kind `kind`. pub fn is_desugaring(self, kind: DesugaringKind) -> bool { match self.ctxt().outer_expn_data().kind { ExpnKind::Desugaring(k) => k == kind, _ => false, } } /// Returns the compiler desugaring that created this span, or `None` /// if this span is not from a desugaring. pub fn desugaring_kind(self) -> Option { match self.ctxt().outer_expn_data().kind { ExpnKind::Desugaring(k) => Some(k), _ => None, } } /// Checks if a span is "internal" to a macro in which `unsafe` /// can be used without triggering the `unsafe_code` lint. /// (that is, a macro marked with `#[allow_internal_unsafe]`). pub fn allows_unsafe(self) -> bool { self.ctxt().outer_expn_data().allow_internal_unsafe } pub fn macro_backtrace(mut self) -> impl Iterator { let mut prev_span = DUMMY_SP; iter::from_fn(move || { loop { let expn_data = self.ctxt().outer_expn_data(); if expn_data.is_root() { return None; } let is_recursive = expn_data.call_site.source_equal(prev_span); prev_span = self; self = expn_data.call_site; // Don't print recursive invocations. if !is_recursive { return Some(expn_data); } } }) } /// Splits a span into two composite spans around a certain position. pub fn split_at(self, pos: u32) -> (Span, Span) { let len = self.hi().0 - self.lo().0; debug_assert!(pos <= len); let split_pos = BytePos(self.lo().0 + pos); ( Span::new(self.lo(), split_pos, self.ctxt(), self.parent()), Span::new(split_pos, self.hi(), self.ctxt(), self.parent()), ) } /// Returns a `Span` that would enclose both `self` and `end`. /// /// Note that this can also be used to extend the span "backwards": /// `start.to(end)` and `end.to(start)` return the same `Span`. /// /// ```text /// ____ ___ /// self lorem ipsum end /// ^^^^^^^^^^^^^^^^^^^^ /// ``` pub fn to(self, end: Span) -> Span { let span_data = self.data(); let end_data = end.data(); // FIXME(jseyfried): `self.ctxt` should always equal `end.ctxt` here (cf. issue #23480). // Return the macro span on its own to avoid weird diagnostic output. It is preferable to // have an incomplete span than a completely nonsensical one. if span_data.ctxt != end_data.ctxt { if span_data.ctxt.is_root() { return end; } else if end_data.ctxt.is_root() { return self; } // Both spans fall within a macro. // FIXME(estebank): check if it is the *same* macro. } Span::new( cmp::min(span_data.lo, end_data.lo), cmp::max(span_data.hi, end_data.hi), if span_data.ctxt.is_root() { end_data.ctxt } else { span_data.ctxt }, if span_data.parent == end_data.parent { span_data.parent } else { None }, ) } /// Returns a `Span` between the end of `self` to the beginning of `end`. /// /// ```text /// ____ ___ /// self lorem ipsum end /// ^^^^^^^^^^^^^ /// ``` pub fn between(self, end: Span) -> Span { let span = self.data(); let end = end.data(); Span::new( span.hi, end.lo, if end.ctxt.is_root() { end.ctxt } else { span.ctxt }, if span.parent == end.parent { span.parent } else { None }, ) } /// Returns a `Span` from the beginning of `self` until the beginning of `end`. /// /// ```text /// ____ ___ /// self lorem ipsum end /// ^^^^^^^^^^^^^^^^^ /// ``` pub fn until(self, end: Span) -> Span { // Most of this function's body is copied from `to`. // We can't just do `self.to(end.shrink_to_lo())`, // because to also does some magic where it uses min/max so // it can handle overlapping spans. Some advanced mis-use of // `until` with different ctxts makes this visible. let span_data = self.data(); let end_data = end.data(); // FIXME(jseyfried): `self.ctxt` should always equal `end.ctxt` here (cf. issue #23480). // Return the macro span on its own to avoid weird diagnostic output. It is preferable to // have an incomplete span than a completely nonsensical one. if span_data.ctxt != end_data.ctxt { if span_data.ctxt.is_root() { return end; } else if end_data.ctxt.is_root() { return self; } // Both spans fall within a macro. // FIXME(estebank): check if it is the *same* macro. } Span::new( span_data.lo, end_data.lo, if end_data.ctxt.is_root() { end_data.ctxt } else { span_data.ctxt }, if span_data.parent == end_data.parent { span_data.parent } else { None }, ) } pub fn from_inner(self, inner: InnerSpan) -> Span { let span = self.data(); Span::new( span.lo + BytePos::from_usize(inner.start), span.lo + BytePos::from_usize(inner.end), span.ctxt, span.parent, ) } /// Equivalent of `Span::def_site` from the proc macro API, /// except that the location is taken from the `self` span. pub fn with_def_site_ctxt(self, expn_id: ExpnId) -> Span { self.with_ctxt_from_mark(expn_id, Transparency::Opaque) } /// Equivalent of `Span::call_site` from the proc macro API, /// except that the location is taken from the `self` span. pub fn with_call_site_ctxt(self, expn_id: ExpnId) -> Span { self.with_ctxt_from_mark(expn_id, Transparency::Transparent) } /// Equivalent of `Span::mixed_site` from the proc macro API, /// except that the location is taken from the `self` span. pub fn with_mixed_site_ctxt(self, expn_id: ExpnId) -> Span { self.with_ctxt_from_mark(expn_id, Transparency::SemiTransparent) } /// Produces a span with the same location as `self` and context produced by a macro with the /// given ID and transparency, assuming that macro was defined directly and not produced by /// some other macro (which is the case for built-in and procedural macros). pub fn with_ctxt_from_mark(self, expn_id: ExpnId, transparency: Transparency) -> Span { self.with_ctxt(SyntaxContext::root().apply_mark(expn_id, transparency)) } #[inline] pub fn apply_mark(self, expn_id: ExpnId, transparency: Transparency) -> Span { let span = self.data(); span.with_ctxt(span.ctxt.apply_mark(expn_id, transparency)) } #[inline] pub fn remove_mark(&mut self) -> ExpnId { let mut span = self.data(); let mark = span.ctxt.remove_mark(); *self = Span::new(span.lo, span.hi, span.ctxt, span.parent); mark } #[inline] pub fn adjust(&mut self, expn_id: ExpnId) -> Option { let mut span = self.data(); let mark = span.ctxt.adjust(expn_id); *self = Span::new(span.lo, span.hi, span.ctxt, span.parent); mark } #[inline] pub fn normalize_to_macros_2_0_and_adjust(&mut self, expn_id: ExpnId) -> Option { let mut span = self.data(); let mark = span.ctxt.normalize_to_macros_2_0_and_adjust(expn_id); *self = Span::new(span.lo, span.hi, span.ctxt, span.parent); mark } #[inline] pub fn glob_adjust(&mut self, expn_id: ExpnId, glob_span: Span) -> Option> { let mut span = self.data(); let mark = span.ctxt.glob_adjust(expn_id, glob_span); *self = Span::new(span.lo, span.hi, span.ctxt, span.parent); mark } #[inline] pub fn reverse_glob_adjust( &mut self, expn_id: ExpnId, glob_span: Span, ) -> Option> { let mut span = self.data(); let mark = span.ctxt.reverse_glob_adjust(expn_id, glob_span); *self = Span::new(span.lo, span.hi, span.ctxt, span.parent); mark } #[inline] pub fn normalize_to_macros_2_0(self) -> Span { let span = self.data(); span.with_ctxt(span.ctxt.normalize_to_macros_2_0()) } #[inline] pub fn normalize_to_macro_rules(self) -> Span { let span = self.data(); span.with_ctxt(span.ctxt.normalize_to_macro_rules()) } } impl Default for Span { fn default() -> Self { DUMMY_SP } } impl Encodable for Span { default fn encode(&self, s: &mut E) { let span = self.data(); span.lo.encode(s); span.hi.encode(s); } } impl Decodable for Span { default fn decode(s: &mut D) -> Span { let lo = Decodable::decode(s); let hi = Decodable::decode(s); Span::new(lo, hi, SyntaxContext::root(), None) } } /// Insert `source_map` into the session globals for the duration of the /// closure's execution. pub fn set_source_map T>(source_map: Lrc, f: F) -> T { with_session_globals(|session_globals| { *session_globals.source_map.borrow_mut() = Some(source_map); }); struct ClearSourceMap; impl Drop for ClearSourceMap { fn drop(&mut self) { with_session_globals(|session_globals| { session_globals.source_map.borrow_mut().take(); }); } } let _guard = ClearSourceMap; f() } impl fmt::Debug for Span { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { // Use the global `SourceMap` to print the span. If that's not // available, fall back to printing the raw values. fn fallback(span: Span, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_struct("Span") .field("lo", &span.lo()) .field("hi", &span.hi()) .field("ctxt", &span.ctxt()) .finish() } if SESSION_GLOBALS.is_set() { with_session_globals(|session_globals| { if let Some(source_map) = &*session_globals.source_map.borrow() { write!(f, "{} ({:?})", source_map.span_to_diagnostic_string(*self), self.ctxt()) } else { fallback(*self, f) } }) } else { fallback(*self, f) } } } impl fmt::Debug for SpanData { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Debug::fmt(&Span::new(self.lo, self.hi, self.ctxt, self.parent), f) } } /// Identifies an offset of a multi-byte character in a `SourceFile`. #[derive(Copy, Clone, Encodable, Decodable, Eq, PartialEq, Debug)] pub struct MultiByteChar { /// The absolute offset of the character in the `SourceMap`. pub pos: BytePos, /// The number of bytes, `>= 2`. pub bytes: u8, } /// Identifies an offset of a non-narrow character in a `SourceFile`. #[derive(Copy, Clone, Encodable, Decodable, Eq, PartialEq, Debug)] pub enum NonNarrowChar { /// Represents a zero-width character. ZeroWidth(BytePos), /// Represents a wide (full-width) character. Wide(BytePos), /// Represents a tab character, represented visually with a width of 4 characters. Tab(BytePos), } impl NonNarrowChar { fn new(pos: BytePos, width: usize) -> Self { match width { 0 => NonNarrowChar::ZeroWidth(pos), 2 => NonNarrowChar::Wide(pos), 4 => NonNarrowChar::Tab(pos), _ => panic!("width {width} given for non-narrow character"), } } /// Returns the absolute offset of the character in the `SourceMap`. pub fn pos(&self) -> BytePos { match *self { NonNarrowChar::ZeroWidth(p) | NonNarrowChar::Wide(p) | NonNarrowChar::Tab(p) => p, } } /// Returns the width of the character, 0 (zero-width) or 2 (wide). pub fn width(&self) -> usize { match *self { NonNarrowChar::ZeroWidth(_) => 0, NonNarrowChar::Wide(_) => 2, NonNarrowChar::Tab(_) => 4, } } } impl Add for NonNarrowChar { type Output = Self; fn add(self, rhs: BytePos) -> Self { match self { NonNarrowChar::ZeroWidth(pos) => NonNarrowChar::ZeroWidth(pos + rhs), NonNarrowChar::Wide(pos) => NonNarrowChar::Wide(pos + rhs), NonNarrowChar::Tab(pos) => NonNarrowChar::Tab(pos + rhs), } } } impl Sub for NonNarrowChar { type Output = Self; fn sub(self, rhs: BytePos) -> Self { match self { NonNarrowChar::ZeroWidth(pos) => NonNarrowChar::ZeroWidth(pos - rhs), NonNarrowChar::Wide(pos) => NonNarrowChar::Wide(pos - rhs), NonNarrowChar::Tab(pos) => NonNarrowChar::Tab(pos - rhs), } } } /// Identifies an offset of a character that was normalized away from `SourceFile`. #[derive(Copy, Clone, Encodable, Decodable, Eq, PartialEq, Debug)] pub struct NormalizedPos { /// The absolute offset of the character in the `SourceMap`. pub pos: BytePos, /// The difference between original and normalized string at position. pub diff: u32, } #[derive(PartialEq, Eq, Clone, Debug)] pub enum ExternalSource { /// No external source has to be loaded, since the `SourceFile` represents a local crate. Unneeded, Foreign { kind: ExternalSourceKind, /// Index of the file inside metadata. metadata_index: u32, }, } /// The state of the lazy external source loading mechanism of a `SourceFile`. #[derive(PartialEq, Eq, Clone, Debug)] pub enum ExternalSourceKind { /// The external source has been loaded already. Present(Lrc), /// No attempt has been made to load the external source. AbsentOk, /// A failed attempt has been made to load the external source. AbsentErr, Unneeded, } impl ExternalSource { pub fn get_source(&self) -> Option<&Lrc> { match self { ExternalSource::Foreign { kind: ExternalSourceKind::Present(ref src), .. } => Some(src), _ => None, } } } #[derive(Debug)] pub struct OffsetOverflowError; #[derive(Copy, Clone, Debug, PartialEq, Eq, PartialOrd, Ord, Hash, Encodable, Decodable)] #[derive(HashStable_Generic)] pub enum SourceFileHashAlgorithm { Md5, Sha1, Sha256, } impl FromStr for SourceFileHashAlgorithm { type Err = (); fn from_str(s: &str) -> Result { match s { "md5" => Ok(SourceFileHashAlgorithm::Md5), "sha1" => Ok(SourceFileHashAlgorithm::Sha1), "sha256" => Ok(SourceFileHashAlgorithm::Sha256), _ => Err(()), } } } /// The hash of the on-disk source file used for debug info. #[derive(Copy, Clone, PartialEq, Eq, Debug, Hash)] #[derive(HashStable_Generic, Encodable, Decodable)] pub struct SourceFileHash { pub kind: SourceFileHashAlgorithm, value: [u8; 32], } impl SourceFileHash { pub fn new(kind: SourceFileHashAlgorithm, src: &str) -> SourceFileHash { let mut hash = SourceFileHash { kind, value: Default::default() }; let len = hash.hash_len(); let value = &mut hash.value[..len]; let data = src.as_bytes(); match kind { SourceFileHashAlgorithm::Md5 => { value.copy_from_slice(&Md5::digest(data)); } SourceFileHashAlgorithm::Sha1 => { value.copy_from_slice(&Sha1::digest(data)); } SourceFileHashAlgorithm::Sha256 => { value.copy_from_slice(&Sha256::digest(data)); } } hash } /// Check if the stored hash matches the hash of the string. pub fn matches(&self, src: &str) -> bool { Self::new(self.kind, src) == *self } /// The bytes of the hash. pub fn hash_bytes(&self) -> &[u8] { let len = self.hash_len(); &self.value[..len] } fn hash_len(&self) -> usize { match self.kind { SourceFileHashAlgorithm::Md5 => 16, SourceFileHashAlgorithm::Sha1 => 20, SourceFileHashAlgorithm::Sha256 => 32, } } } #[derive(Clone)] pub enum SourceFileLines { /// The source file lines, in decoded (random-access) form. Lines(Vec), /// The source file lines, in undecoded difference list form. Diffs(SourceFileDiffs), } impl SourceFileLines { pub fn is_lines(&self) -> bool { matches!(self, SourceFileLines::Lines(_)) } } /// The source file lines in difference list form. This matches the form /// used within metadata, which saves space by exploiting the fact that the /// lines list is sorted and individual lines are usually not that long. /// /// We read it directly from metadata and only decode it into `Lines` form /// when necessary. This is a significant performance win, especially for /// small crates where very little of `std`'s metadata is used. #[derive(Clone)] pub struct SourceFileDiffs { /// Position of the first line. Note that this is always encoded as a /// `BytePos` because it is often much larger than any of the /// differences. line_start: BytePos, /// Always 1, 2, or 4. Always as small as possible, while being big /// enough to hold the length of the longest line in the source file. /// The 1 case is by far the most common. bytes_per_diff: usize, /// The number of diffs encoded in `raw_diffs`. Always one less than /// the number of lines in the source file. num_diffs: usize, /// The diffs in "raw" form. Each segment of `bytes_per_diff` length /// encodes one little-endian diff. Note that they aren't LEB128 /// encoded. This makes for much faster decoding. Besides, the /// bytes_per_diff==1 case is by far the most common, and LEB128 /// encoding has no effect on that case. raw_diffs: Vec, } /// A single source in the [`SourceMap`]. pub struct SourceFile { /// The name of the file that the source came from. Source that doesn't /// originate from files has names between angle brackets by convention /// (e.g., ``). pub name: FileName, /// The complete source code. pub src: Option>, /// The source code's hash. pub src_hash: SourceFileHash, /// The external source code (used for external crates, which will have a `None` /// value as `self.src`. pub external_src: Lock, /// The start position of this source in the `SourceMap`. pub start_pos: BytePos, /// The end position of this source in the `SourceMap`. pub end_pos: BytePos, /// Locations of lines beginnings in the source code. pub lines: Lock, /// Locations of multi-byte characters in the source code. pub multibyte_chars: Vec, /// Width of characters that are not narrow in the source code. pub non_narrow_chars: Vec, /// Locations of characters removed during normalization. pub normalized_pos: Vec, /// A hash of the filename, used for speeding up hashing in incremental compilation. pub name_hash: Hash128, /// Indicates which crate this `SourceFile` was imported from. pub cnum: CrateNum, } impl Clone for SourceFile { fn clone(&self) -> Self { Self { name: self.name.clone(), src: self.src.clone(), src_hash: self.src_hash, external_src: Lock::new(self.external_src.borrow().clone()), start_pos: self.start_pos, end_pos: self.end_pos, lines: Lock::new(self.lines.borrow().clone()), multibyte_chars: self.multibyte_chars.clone(), non_narrow_chars: self.non_narrow_chars.clone(), normalized_pos: self.normalized_pos.clone(), name_hash: self.name_hash, cnum: self.cnum, } } } impl Encodable for SourceFile { fn encode(&self, s: &mut S) { self.name.encode(s); self.src_hash.encode(s); self.start_pos.encode(s); self.end_pos.encode(s); // We are always in `Lines` form by the time we reach here. assert!(self.lines.borrow().is_lines()); self.lines(|lines| { // Store the length. s.emit_u32(lines.len() as u32); // Compute and store the difference list. if lines.len() != 0 { let max_line_length = if lines.len() == 1 { 0 } else { lines .array_windows() .map(|&[fst, snd]| snd - fst) .map(|bp| bp.to_usize()) .max() .unwrap() }; let bytes_per_diff: usize = match max_line_length { 0..=0xFF => 1, 0x100..=0xFFFF => 2, _ => 4, }; // Encode the number of bytes used per diff. s.emit_u8(bytes_per_diff as u8); // Encode the first element. lines[0].encode(s); // Encode the difference list. let diff_iter = lines.array_windows().map(|&[fst, snd]| snd - fst); let num_diffs = lines.len() - 1; let mut raw_diffs; match bytes_per_diff { 1 => { raw_diffs = Vec::with_capacity(num_diffs); for diff in diff_iter { raw_diffs.push(diff.0 as u8); } } 2 => { raw_diffs = Vec::with_capacity(bytes_per_diff * num_diffs); for diff in diff_iter { raw_diffs.extend_from_slice(&(diff.0 as u16).to_le_bytes()); } } 4 => { raw_diffs = Vec::with_capacity(bytes_per_diff * num_diffs); for diff in diff_iter { raw_diffs.extend_from_slice(&(diff.0).to_le_bytes()); } } _ => unreachable!(), } s.emit_raw_bytes(&raw_diffs); } }); self.multibyte_chars.encode(s); self.non_narrow_chars.encode(s); self.name_hash.encode(s); self.normalized_pos.encode(s); self.cnum.encode(s); } } impl Decodable for SourceFile { fn decode(d: &mut D) -> SourceFile { let name: FileName = Decodable::decode(d); let src_hash: SourceFileHash = Decodable::decode(d); let start_pos: BytePos = Decodable::decode(d); let end_pos: BytePos = Decodable::decode(d); let lines = { let num_lines: u32 = Decodable::decode(d); if num_lines > 0 { // Read the number of bytes used per diff. let bytes_per_diff = d.read_u8() as usize; // Read the first element. let line_start: BytePos = Decodable::decode(d); // Read the difference list. let num_diffs = num_lines as usize - 1; let raw_diffs = d.read_raw_bytes(bytes_per_diff * num_diffs).to_vec(); SourceFileLines::Diffs(SourceFileDiffs { line_start, bytes_per_diff, num_diffs, raw_diffs, }) } else { SourceFileLines::Lines(vec![]) } }; let multibyte_chars: Vec = Decodable::decode(d); let non_narrow_chars: Vec = Decodable::decode(d); let name_hash = Decodable::decode(d); let normalized_pos: Vec = Decodable::decode(d); let cnum: CrateNum = Decodable::decode(d); SourceFile { name, start_pos, end_pos, src: None, src_hash, // Unused - the metadata decoder will construct // a new SourceFile, filling in `external_src` properly external_src: Lock::new(ExternalSource::Unneeded), lines: Lock::new(lines), multibyte_chars, non_narrow_chars, normalized_pos, name_hash, cnum, } } } impl fmt::Debug for SourceFile { fn fmt(&self, fmt: &mut fmt::Formatter<'_>) -> fmt::Result { write!(fmt, "SourceFile({:?})", self.name) } } impl SourceFile { pub fn new( name: FileName, mut src: String, start_pos: BytePos, hash_kind: SourceFileHashAlgorithm, ) -> Self { // Compute the file hash before any normalization. let src_hash = SourceFileHash::new(hash_kind, &src); let normalized_pos = normalize_src(&mut src, start_pos); let name_hash = { let mut hasher: StableHasher = StableHasher::new(); name.hash(&mut hasher); hasher.finish() }; let end_pos = start_pos.to_usize() + src.len(); assert!(end_pos <= u32::MAX as usize); let (lines, multibyte_chars, non_narrow_chars) = analyze_source_file::analyze_source_file(&src, start_pos); SourceFile { name, src: Some(Lrc::new(src)), src_hash, external_src: Lock::new(ExternalSource::Unneeded), start_pos, end_pos: Pos::from_usize(end_pos), lines: Lock::new(SourceFileLines::Lines(lines)), multibyte_chars, non_narrow_chars, normalized_pos, name_hash, cnum: LOCAL_CRATE, } } pub fn lines(&self, f: F) -> R where F: FnOnce(&[BytePos]) -> R, { let mut guard = self.lines.borrow_mut(); match &*guard { SourceFileLines::Lines(lines) => f(lines), SourceFileLines::Diffs(SourceFileDiffs { mut line_start, bytes_per_diff, num_diffs, raw_diffs, }) => { // Convert from "diffs" form to "lines" form. let num_lines = num_diffs + 1; let mut lines = Vec::with_capacity(num_lines); lines.push(line_start); assert_eq!(*num_diffs, raw_diffs.len() / bytes_per_diff); match bytes_per_diff { 1 => { lines.extend(raw_diffs.into_iter().map(|&diff| { line_start = line_start + BytePos(diff as u32); line_start })); } 2 => { lines.extend((0..*num_diffs).map(|i| { let pos = bytes_per_diff * i; let bytes = [raw_diffs[pos], raw_diffs[pos + 1]]; let diff = u16::from_le_bytes(bytes); line_start = line_start + BytePos(diff as u32); line_start })); } 4 => { lines.extend((0..*num_diffs).map(|i| { let pos = bytes_per_diff * i; let bytes = [ raw_diffs[pos], raw_diffs[pos + 1], raw_diffs[pos + 2], raw_diffs[pos + 3], ]; let diff = u32::from_le_bytes(bytes); line_start = line_start + BytePos(diff); line_start })); } _ => unreachable!(), } let res = f(&lines); *guard = SourceFileLines::Lines(lines); res } } } /// Returns the `BytePos` of the beginning of the current line. pub fn line_begin_pos(&self, pos: BytePos) -> BytePos { let line_index = self.lookup_line(pos).unwrap(); self.lines(|lines| lines[line_index]) } /// Add externally loaded source. /// If the hash of the input doesn't match or no input is supplied via None, /// it is interpreted as an error and the corresponding enum variant is set. /// The return value signifies whether some kind of source is present. pub fn add_external_src(&self, get_src: F) -> bool where F: FnOnce() -> Option, { if matches!( *self.external_src.borrow(), ExternalSource::Foreign { kind: ExternalSourceKind::AbsentOk, .. } ) { let src = get_src(); let mut external_src = self.external_src.borrow_mut(); // Check that no-one else have provided the source while we were getting it if let ExternalSource::Foreign { kind: src_kind @ ExternalSourceKind::AbsentOk, .. } = &mut *external_src { if let Some(mut src) = src { // The src_hash needs to be computed on the pre-normalized src. if self.src_hash.matches(&src) { normalize_src(&mut src, BytePos::from_usize(0)); *src_kind = ExternalSourceKind::Present(Lrc::new(src)); return true; } } else { *src_kind = ExternalSourceKind::AbsentErr; } false } else { self.src.is_some() || external_src.get_source().is_some() } } else { self.src.is_some() || self.external_src.borrow().get_source().is_some() } } /// Gets a line from the list of pre-computed line-beginnings. /// The line number here is 0-based. pub fn get_line(&self, line_number: usize) -> Option> { fn get_until_newline(src: &str, begin: usize) -> &str { // We can't use `lines.get(line_number+1)` because we might // be parsing when we call this function and thus the current // line is the last one we have line info for. let slice = &src[begin..]; match slice.find('\n') { Some(e) => &slice[..e], None => slice, } } let begin = { let line = self.lines(|lines| lines.get(line_number).copied())?; let begin: BytePos = line - self.start_pos; begin.to_usize() }; if let Some(ref src) = self.src { Some(Cow::from(get_until_newline(src, begin))) } else { self.external_src .borrow() .get_source() .map(|src| Cow::Owned(String::from(get_until_newline(src, begin)))) } } pub fn is_real_file(&self) -> bool { self.name.is_real() } #[inline] pub fn is_imported(&self) -> bool { self.src.is_none() } pub fn count_lines(&self) -> usize { self.lines(|lines| lines.len()) } /// Finds the line containing the given position. The return value is the /// index into the `lines` array of this `SourceFile`, not the 1-based line /// number. If the source_file is empty or the position is located before the /// first line, `None` is returned. pub fn lookup_line(&self, pos: BytePos) -> Option { self.lines(|lines| lines.partition_point(|x| x <= &pos).checked_sub(1)) } pub fn line_bounds(&self, line_index: usize) -> Range { if self.is_empty() { return self.start_pos..self.end_pos; } self.lines(|lines| { assert!(line_index < lines.len()); if line_index == (lines.len() - 1) { lines[line_index]..self.end_pos } else { lines[line_index]..lines[line_index + 1] } }) } /// Returns whether or not the file contains the given `SourceMap` byte /// position. The position one past the end of the file is considered to be /// contained by the file. This implies that files for which `is_empty` /// returns true still contain one byte position according to this function. #[inline] pub fn contains(&self, byte_pos: BytePos) -> bool { byte_pos >= self.start_pos && byte_pos <= self.end_pos } #[inline] pub fn is_empty(&self) -> bool { self.start_pos == self.end_pos } /// Calculates the original byte position relative to the start of the file /// based on the given byte position. pub fn original_relative_byte_pos(&self, pos: BytePos) -> BytePos { // Diff before any records is 0. Otherwise use the previously recorded // diff as that applies to the following characters until a new diff // is recorded. let diff = match self.normalized_pos.binary_search_by(|np| np.pos.cmp(&pos)) { Ok(i) => self.normalized_pos[i].diff, Err(i) if i == 0 => 0, Err(i) => self.normalized_pos[i - 1].diff, }; BytePos::from_u32(pos.0 - self.start_pos.0 + diff) } /// Calculates a normalized byte position from a byte offset relative to the /// start of the file. /// /// When we get an inline assembler error from LLVM during codegen, we /// import the expanded assembly code as a new `SourceFile`, which can then /// be used for error reporting with spans. However the byte offsets given /// to us by LLVM are relative to the start of the original buffer, not the /// normalized one. Hence we need to convert those offsets to the normalized /// form when constructing spans. pub fn normalized_byte_pos(&self, offset: u32) -> BytePos { let diff = match self .normalized_pos .binary_search_by(|np| (np.pos.0 + np.diff).cmp(&(self.start_pos.0 + offset))) { Ok(i) => self.normalized_pos[i].diff, Err(i) if i == 0 => 0, Err(i) => self.normalized_pos[i - 1].diff, }; BytePos::from_u32(self.start_pos.0 + offset - diff) } /// Converts an absolute `BytePos` to a `CharPos` relative to the `SourceFile`. pub fn bytepos_to_file_charpos(&self, bpos: BytePos) -> CharPos { // The number of extra bytes due to multibyte chars in the `SourceFile`. let mut total_extra_bytes = 0; for mbc in self.multibyte_chars.iter() { debug!("{}-byte char at {:?}", mbc.bytes, mbc.pos); if mbc.pos < bpos { // Every character is at least one byte, so we only // count the actual extra bytes. total_extra_bytes += mbc.bytes as u32 - 1; // We should never see a byte position in the middle of a // character. assert!(bpos.to_u32() >= mbc.pos.to_u32() + mbc.bytes as u32); } else { break; } } assert!(self.start_pos.to_u32() + total_extra_bytes <= bpos.to_u32()); CharPos(bpos.to_usize() - self.start_pos.to_usize() - total_extra_bytes as usize) } /// Looks up the file's (1-based) line number and (0-based `CharPos`) column offset, for a /// given `BytePos`. pub fn lookup_file_pos(&self, pos: BytePos) -> (usize, CharPos) { let chpos = self.bytepos_to_file_charpos(pos); match self.lookup_line(pos) { Some(a) => { let line = a + 1; // Line numbers start at 1 let linebpos = self.lines(|lines| lines[a]); let linechpos = self.bytepos_to_file_charpos(linebpos); let col = chpos - linechpos; debug!("byte pos {:?} is on the line at byte pos {:?}", pos, linebpos); debug!("char pos {:?} is on the line at char pos {:?}", chpos, linechpos); debug!("byte is on line: {}", line); assert!(chpos >= linechpos); (line, col) } None => (0, chpos), } } /// Looks up the file's (1-based) line number, (0-based `CharPos`) column offset, and (0-based) /// column offset when displayed, for a given `BytePos`. pub fn lookup_file_pos_with_col_display(&self, pos: BytePos) -> (usize, CharPos, usize) { let (line, col_or_chpos) = self.lookup_file_pos(pos); if line > 0 { let col = col_or_chpos; let linebpos = self.lines(|lines| lines[line - 1]); let col_display = { let start_width_idx = self .non_narrow_chars .binary_search_by_key(&linebpos, |x| x.pos()) .unwrap_or_else(|x| x); let end_width_idx = self .non_narrow_chars .binary_search_by_key(&pos, |x| x.pos()) .unwrap_or_else(|x| x); let special_chars = end_width_idx - start_width_idx; let non_narrow: usize = self.non_narrow_chars[start_width_idx..end_width_idx] .iter() .map(|x| x.width()) .sum(); col.0 - special_chars + non_narrow }; (line, col, col_display) } else { let chpos = col_or_chpos; let col_display = { let end_width_idx = self .non_narrow_chars .binary_search_by_key(&pos, |x| x.pos()) .unwrap_or_else(|x| x); let non_narrow: usize = self.non_narrow_chars[0..end_width_idx].iter().map(|x| x.width()).sum(); chpos.0 - end_width_idx + non_narrow }; (0, chpos, col_display) } } } /// Normalizes the source code and records the normalizations. fn normalize_src(src: &mut String, start_pos: BytePos) -> Vec { let mut normalized_pos = vec![]; remove_bom(src, &mut normalized_pos); normalize_newlines(src, &mut normalized_pos); // Offset all the positions by start_pos to match the final file positions. for np in &mut normalized_pos { np.pos.0 += start_pos.0; } normalized_pos } /// Removes UTF-8 BOM, if any. fn remove_bom(src: &mut String, normalized_pos: &mut Vec) { if src.starts_with('\u{feff}') { src.drain(..3); normalized_pos.push(NormalizedPos { pos: BytePos(0), diff: 3 }); } } /// Replaces `\r\n` with `\n` in-place in `src`. /// /// Returns error if there's a lone `\r` in the string. fn normalize_newlines(src: &mut String, normalized_pos: &mut Vec) { if !src.as_bytes().contains(&b'\r') { return; } // We replace `\r\n` with `\n` in-place, which doesn't break utf-8 encoding. // While we *can* call `as_mut_vec` and do surgery on the live string // directly, let's rather steal the contents of `src`. This makes the code // safe even if a panic occurs. let mut buf = std::mem::replace(src, String::new()).into_bytes(); let mut gap_len = 0; let mut tail = buf.as_mut_slice(); let mut cursor = 0; let original_gap = normalized_pos.last().map_or(0, |l| l.diff); loop { let idx = match find_crlf(&tail[gap_len..]) { None => tail.len(), Some(idx) => idx + gap_len, }; tail.copy_within(gap_len..idx, 0); tail = &mut tail[idx - gap_len..]; if tail.len() == gap_len { break; } cursor += idx - gap_len; gap_len += 1; normalized_pos.push(NormalizedPos { pos: BytePos::from_usize(cursor + 1), diff: original_gap + gap_len as u32, }); } // Account for removed `\r`. // After `set_len`, `buf` is guaranteed to contain utf-8 again. let new_len = buf.len() - gap_len; unsafe { buf.set_len(new_len); *src = String::from_utf8_unchecked(buf); } fn find_crlf(src: &[u8]) -> Option { let mut search_idx = 0; while let Some(idx) = find_cr(&src[search_idx..]) { if src[search_idx..].get(idx + 1) != Some(&b'\n') { search_idx += idx + 1; continue; } return Some(search_idx + idx); } None } fn find_cr(src: &[u8]) -> Option { src.iter().position(|&b| b == b'\r') } } // _____________________________________________________________________________ // Pos, BytePos, CharPos // pub trait Pos { fn from_usize(n: usize) -> Self; fn to_usize(&self) -> usize; fn from_u32(n: u32) -> Self; fn to_u32(&self) -> u32; } macro_rules! impl_pos { ( $( $(#[$attr:meta])* $vis:vis struct $ident:ident($inner_vis:vis $inner_ty:ty); )* ) => { $( $(#[$attr])* $vis struct $ident($inner_vis $inner_ty); impl Pos for $ident { #[inline(always)] fn from_usize(n: usize) -> $ident { $ident(n as $inner_ty) } #[inline(always)] fn to_usize(&self) -> usize { self.0 as usize } #[inline(always)] fn from_u32(n: u32) -> $ident { $ident(n as $inner_ty) } #[inline(always)] fn to_u32(&self) -> u32 { self.0 as u32 } } impl Add for $ident { type Output = $ident; #[inline(always)] fn add(self, rhs: $ident) -> $ident { $ident(self.0 + rhs.0) } } impl Sub for $ident { type Output = $ident; #[inline(always)] fn sub(self, rhs: $ident) -> $ident { $ident(self.0 - rhs.0) } } )* }; } impl_pos! { /// A byte offset. /// /// Keep this small (currently 32-bits), as AST contains a lot of them. #[derive(Clone, Copy, PartialEq, Eq, Hash, PartialOrd, Ord, Debug)] pub struct BytePos(pub u32); /// A character offset. /// /// Because of multibyte UTF-8 characters, a byte offset /// is not equivalent to a character offset. The [`SourceMap`] will convert [`BytePos`] /// values to `CharPos` values as necessary. #[derive(Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Debug)] pub struct CharPos(pub usize); } impl Encodable for BytePos { fn encode(&self, s: &mut S) { s.emit_u32(self.0); } } impl Decodable for BytePos { fn decode(d: &mut D) -> BytePos { BytePos(d.read_u32()) } } // _____________________________________________________________________________ // Loc, SourceFileAndLine, SourceFileAndBytePos // /// A source code location used for error reporting. #[derive(Debug, Clone)] pub struct Loc { /// Information about the original source. pub file: Lrc, /// The (1-based) line number. pub line: usize, /// The (0-based) column offset. pub col: CharPos, /// The (0-based) column offset when displayed. pub col_display: usize, } // Used to be structural records. #[derive(Debug)] pub struct SourceFileAndLine { pub sf: Lrc, /// Index of line, starting from 0. pub line: usize, } #[derive(Debug)] pub struct SourceFileAndBytePos { pub sf: Lrc, pub pos: BytePos, } #[derive(Copy, Clone, Debug, PartialEq, Eq)] pub struct LineInfo { /// Index of line, starting from 0. pub line_index: usize, /// Column in line where span begins, starting from 0. pub start_col: CharPos, /// Column in line where span ends, starting from 0, exclusive. pub end_col: CharPos, } pub struct FileLines { pub file: Lrc, pub lines: Vec, } pub static SPAN_TRACK: AtomicRef = AtomicRef::new(&((|_| {}) as fn(_))); // _____________________________________________________________________________ // SpanLinesError, SpanSnippetError, DistinctSources, MalformedSourceMapPositions // pub type FileLinesResult = Result; #[derive(Clone, PartialEq, Eq, Debug)] pub enum SpanLinesError { DistinctSources(Box), } #[derive(Clone, PartialEq, Eq, Debug)] pub enum SpanSnippetError { IllFormedSpan(Span), DistinctSources(Box), MalformedForSourcemap(MalformedSourceMapPositions), SourceNotAvailable { filename: FileName }, } #[derive(Clone, PartialEq, Eq, Debug)] pub struct DistinctSources { pub begin: (FileName, BytePos), pub end: (FileName, BytePos), } #[derive(Clone, PartialEq, Eq, Debug)] pub struct MalformedSourceMapPositions { pub name: FileName, pub source_len: usize, pub begin_pos: BytePos, pub end_pos: BytePos, } /// Range inside of a `Span` used for diagnostics when we only have access to relative positions. #[derive(Copy, Clone, PartialEq, Eq, Debug)] pub struct InnerSpan { pub start: usize, pub end: usize, } impl InnerSpan { pub fn new(start: usize, end: usize) -> InnerSpan { InnerSpan { start, end } } } /// Requirements for a `StableHashingContext` to be used in this crate. /// /// This is a hack to allow using the [`HashStable_Generic`] derive macro /// instead of implementing everything in rustc_middle. pub trait HashStableContext { fn def_path_hash(&self, def_id: DefId) -> DefPathHash; fn hash_spans(&self) -> bool; /// Accesses `sess.opts.unstable_opts.incremental_ignore_spans` since /// we don't have easy access to a `Session` fn unstable_opts_incremental_ignore_spans(&self) -> bool; fn def_span(&self, def_id: LocalDefId) -> Span; fn span_data_to_lines_and_cols( &mut self, span: &SpanData, ) -> Option<(Lrc, usize, BytePos, usize, BytePos)>; fn hashing_controls(&self) -> HashingControls; } impl HashStable for Span where CTX: HashStableContext, { /// Hashes a span in a stable way. We can't directly hash the span's `BytePos` /// fields (that would be similar to hashing pointers, since those are just /// offsets into the `SourceMap`). Instead, we hash the (file name, line, column) /// triple, which stays the same even if the containing `SourceFile` has moved /// within the `SourceMap`. /// /// Also note that we are hashing byte offsets for the column, not unicode /// codepoint offsets. For the purpose of the hash that's sufficient. /// Also, hashing filenames is expensive so we avoid doing it twice when the /// span starts and ends in the same file, which is almost always the case. fn hash_stable(&self, ctx: &mut CTX, hasher: &mut StableHasher) { const TAG_VALID_SPAN: u8 = 0; const TAG_INVALID_SPAN: u8 = 1; const TAG_RELATIVE_SPAN: u8 = 2; if !ctx.hash_spans() { return; } let span = self.data_untracked(); span.ctxt.hash_stable(ctx, hasher); span.parent.hash_stable(ctx, hasher); if span.is_dummy() { Hash::hash(&TAG_INVALID_SPAN, hasher); return; } if let Some(parent) = span.parent { let def_span = ctx.def_span(parent).data_untracked(); if def_span.contains(span) { // This span is enclosed in a definition: only hash the relative position. Hash::hash(&TAG_RELATIVE_SPAN, hasher); (span.lo - def_span.lo).to_u32().hash_stable(ctx, hasher); (span.hi - def_span.lo).to_u32().hash_stable(ctx, hasher); return; } } // If this is not an empty or invalid span, we want to hash the last // position that belongs to it, as opposed to hashing the first // position past it. let Some((file, line_lo, col_lo, line_hi, col_hi)) = ctx.span_data_to_lines_and_cols(&span) else { Hash::hash(&TAG_INVALID_SPAN, hasher); return; }; Hash::hash(&TAG_VALID_SPAN, hasher); Hash::hash(&file.name_hash, hasher); // Hash both the length and the end location (line/column) of a span. If we // hash only the length, for example, then two otherwise equal spans with // different end locations will have the same hash. This can cause a problem // during incremental compilation wherein a previous result for a query that // depends on the end location of a span will be incorrectly reused when the // end location of the span it depends on has changed (see issue #74890). A // similar analysis applies if some query depends specifically on the length // of the span, but we only hash the end location. So hash both. let col_lo_trunc = (col_lo.0 as u64) & 0xFF; let line_lo_trunc = ((line_lo as u64) & 0xFF_FF_FF) << 8; let col_hi_trunc = (col_hi.0 as u64) & 0xFF << 32; let line_hi_trunc = ((line_hi as u64) & 0xFF_FF_FF) << 40; let col_line = col_lo_trunc | line_lo_trunc | col_hi_trunc | line_hi_trunc; let len = (span.hi - span.lo).0; Hash::hash(&col_line, hasher); Hash::hash(&len, hasher); } } /// Useful type to use with `Result<>` indicate that an error has already /// been reported to the user, so no need to continue checking. #[derive(Clone, Copy, Debug, Encodable, Decodable, Hash, PartialEq, Eq, PartialOrd, Ord)] #[derive(HashStable_Generic)] pub struct ErrorGuaranteed(()); impl ErrorGuaranteed { /// To be used only if you really know what you are doing... ideally, we would find a way to /// eliminate all calls to this method. #[deprecated = "`Session::delay_span_bug` should be preferred over this function"] pub fn unchecked_claim_error_was_emitted() -> Self { ErrorGuaranteed(()) } }