//! File and span related types. use std::fmt::{self, Write}; use salsa::InternId; mod ast_id; mod hygiene; mod map; pub use self::{ ast_id::{AstIdMap, AstIdNode, ErasedFileAstId, FileAstId}, hygiene::{SyntaxContextData, SyntaxContextId, Transparency}, map::{RealSpanMap, SpanMap}, }; pub use syntax::Edition; pub use text_size::{TextRange, TextSize}; pub use vfs::FileId; #[derive(Clone, Copy, Debug, PartialEq, Eq, Hash)] pub struct FilePosition { pub file_id: FileId, pub offset: TextSize, } #[derive(Clone, Copy, Debug, Eq, PartialEq, Hash)] pub struct FileRange { pub file_id: FileId, pub range: TextRange, } // The first index is always the root node's AstId /// The root ast id always points to the encompassing file, using this in spans is discouraged as /// any range relative to it will be effectively absolute, ruining the entire point of anchored /// relative text ranges. pub const ROOT_ERASED_FILE_AST_ID: ErasedFileAstId = la_arena::Idx::from_raw(la_arena::RawIdx::from_u32(0)); /// FileId used as the span for syntax node fixups. Any Span containing this file id is to be /// considered fake. pub const FIXUP_ERASED_FILE_AST_ID_MARKER: ErasedFileAstId = // we pick the second to last for this in case we every consider making this a NonMaxU32, this // is required to be stable for the proc-macro-server la_arena::Idx::from_raw(la_arena::RawIdx::from_u32(!0 - 1)); pub type Span = SpanData; /// Spans represent a region of code, used by the IDE to be able link macro inputs and outputs /// together. Positions in spans are relative to some [`SpanAnchor`] to make them more incremental /// friendly. #[derive(Clone, Copy, PartialEq, Eq, Hash)] pub struct SpanData { /// The text range of this span, relative to the anchor. /// We need the anchor for incrementality, as storing absolute ranges will require /// recomputation on every change in a file at all times. pub range: TextRange, /// The anchor this span is relative to. pub anchor: SpanAnchor, /// The syntax context of the span. pub ctx: Ctx, } impl fmt::Debug for SpanData { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { if f.alternate() { fmt::Debug::fmt(&self.anchor.file_id.index(), f)?; f.write_char(':')?; fmt::Debug::fmt(&self.anchor.ast_id.into_raw(), f)?; f.write_char('@')?; fmt::Debug::fmt(&self.range, f)?; f.write_char('#')?; self.ctx.fmt(f) } else { f.debug_struct("SpanData") .field("range", &self.range) .field("anchor", &self.anchor) .field("ctx", &self.ctx) .finish() } } } impl SpanData { pub fn eq_ignoring_ctx(self, other: Self) -> bool { self.anchor == other.anchor && self.range == other.range } } impl Span { #[deprecated = "dummy spans will panic if surfaced incorrectly, as such they should be replaced appropriately"] pub const DUMMY: Self = Self { range: TextRange::empty(TextSize::new(0)), anchor: SpanAnchor { file_id: FileId::BOGUS, ast_id: ROOT_ERASED_FILE_AST_ID }, ctx: SyntaxContextId::ROOT, }; } impl fmt::Display for Span { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { fmt::Debug::fmt(&self.anchor.file_id.index(), f)?; f.write_char(':')?; fmt::Debug::fmt(&self.anchor.ast_id.into_raw(), f)?; f.write_char('@')?; fmt::Debug::fmt(&self.range, f)?; f.write_char('#')?; self.ctx.fmt(f) } } #[derive(Copy, Clone, PartialEq, Eq, Hash)] pub struct SpanAnchor { pub file_id: FileId, pub ast_id: ErasedFileAstId, } impl fmt::Debug for SpanAnchor { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { f.debug_tuple("SpanAnchor").field(&self.file_id).field(&self.ast_id.into_raw()).finish() } } /// Input to the analyzer is a set of files, where each file is identified by /// `FileId` and contains source code. However, another source of source code in /// Rust are macros: each macro can be thought of as producing a "temporary /// file". To assign an id to such a file, we use the id of the macro call that /// produced the file. So, a `HirFileId` is either a `FileId` (source code /// written by user), or a `MacroCallId` (source code produced by macro). /// /// What is a `MacroCallId`? Simplifying, it's a `HirFileId` of a file /// containing the call plus the offset of the macro call in the file. Note that /// this is a recursive definition! However, the size_of of `HirFileId` is /// finite (because everything bottoms out at the real `FileId`) and small /// (`MacroCallId` uses the location interning. You can check details here: /// ). /// /// The two variants are encoded in a single u32 which are differentiated by the MSB. /// If the MSB is 0, the value represents a `FileId`, otherwise the remaining 31 bits represent a /// `MacroCallId`. // FIXME: Give this a better fitting name #[derive(Clone, Copy, PartialEq, Eq, Hash, PartialOrd, Ord)] pub struct HirFileId(u32); impl From for u32 { fn from(value: HirFileId) -> Self { value.0 } } impl From for HirFileId { fn from(value: MacroCallId) -> Self { value.as_file() } } impl fmt::Debug for HirFileId { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { self.repr().fmt(f) } } #[derive(Debug, Clone, Copy, PartialEq, Eq, Hash)] pub struct MacroFileId { pub macro_call_id: MacroCallId, } /// `MacroCallId` identifies a particular macro invocation, like /// `println!("Hello, {}", world)`. #[derive(Debug, Clone, Copy, PartialEq, Eq, PartialOrd, Ord, Hash)] pub struct MacroCallId(salsa::InternId); impl salsa::InternKey for MacroCallId { fn from_intern_id(v: salsa::InternId) -> Self { MacroCallId(v) } fn as_intern_id(&self) -> salsa::InternId { self.0 } } impl MacroCallId { pub fn as_file(self) -> HirFileId { MacroFileId { macro_call_id: self }.into() } pub fn as_macro_file(self) -> MacroFileId { MacroFileId { macro_call_id: self } } } #[derive(Clone, Copy, PartialEq, Eq, Hash)] pub enum HirFileIdRepr { FileId(FileId), MacroFile(MacroFileId), } impl fmt::Debug for HirFileIdRepr { fn fmt(&self, f: &mut fmt::Formatter<'_>) -> fmt::Result { match self { Self::FileId(arg0) => f.debug_tuple("FileId").field(&arg0.index()).finish(), Self::MacroFile(arg0) => { f.debug_tuple("MacroFile").field(&arg0.macro_call_id.0).finish() } } } } impl From for HirFileId { #[allow(clippy::let_unit_value)] fn from(id: FileId) -> Self { _ = Self::ASSERT_MAX_FILE_ID_IS_SAME; assert!(id.index() <= Self::MAX_HIR_FILE_ID, "FileId index {} is too large", id.index()); HirFileId(id.index()) } } impl From for HirFileId { #[allow(clippy::let_unit_value)] fn from(MacroFileId { macro_call_id: MacroCallId(id) }: MacroFileId) -> Self { _ = Self::ASSERT_MAX_FILE_ID_IS_SAME; let id = id.as_u32(); assert!(id <= Self::MAX_HIR_FILE_ID, "MacroCallId index {} is too large", id); HirFileId(id | Self::MACRO_FILE_TAG_MASK) } } impl HirFileId { const ASSERT_MAX_FILE_ID_IS_SAME: () = [()][(Self::MAX_HIR_FILE_ID != FileId::MAX_FILE_ID) as usize]; const MAX_HIR_FILE_ID: u32 = u32::MAX ^ Self::MACRO_FILE_TAG_MASK; const MACRO_FILE_TAG_MASK: u32 = 1 << 31; #[inline] pub fn is_macro(self) -> bool { self.0 & Self::MACRO_FILE_TAG_MASK != 0 } #[inline] pub fn macro_file(self) -> Option { match self.0 & Self::MACRO_FILE_TAG_MASK { 0 => None, _ => Some(MacroFileId { macro_call_id: MacroCallId(InternId::from(self.0 ^ Self::MACRO_FILE_TAG_MASK)), }), } } #[inline] pub fn file_id(self) -> Option { match self.0 & Self::MACRO_FILE_TAG_MASK { 0 => Some(FileId::from_raw(self.0)), _ => None, } } #[inline] pub fn repr(self) -> HirFileIdRepr { match self.0 & Self::MACRO_FILE_TAG_MASK { 0 => HirFileIdRepr::FileId(FileId::from_raw(self.0)), _ => HirFileIdRepr::MacroFile(MacroFileId { macro_call_id: MacroCallId(InternId::from(self.0 ^ Self::MACRO_FILE_TAG_MASK)), }), } } }