mv compiler to compiler/

compiler/rustc_span/src/span_encoding.rs

@@ -0,0 +1,133 @@
+// Spans are encoded using 1-bit tag and 2 different encoding formats (one for each tag value).
+// One format is used for keeping span data inline,
+// another contains index into an out-of-line span interner.
+// The encoding format for inline spans were obtained by optimizing over crates in rustc/libstd.
+// See https://internals.rust-lang.org/t/rfc-compiler-refactoring-spans/1357/28
+
+use crate::hygiene::SyntaxContext;
+use crate::SESSION_GLOBALS;
+use crate::{BytePos, SpanData};
+
+use rustc_data_structures::fx::FxIndexSet;
+
+/// A compressed span.
+///
+/// `SpanData` is 12 bytes, which is a bit too big to stick everywhere. `Span`
+/// is a form that only takes up 8 bytes, with less space for the length and
+/// context. The vast majority (99.9%+) of `SpanData` instances will fit within
+/// those 8 bytes; any `SpanData` whose fields don't fit into a `Span` are
+/// stored in a separate interner table, and the `Span` will index into that
+/// table. Interning is rare enough that the cost is low, but common enough
+/// that the code is exercised regularly.
+///
+/// An earlier version of this code used only 4 bytes for `Span`, but that was
+/// slower because only 80--90% of spans could be stored inline (even less in
+/// very large crates) and so the interner was used a lot more.
+///
+/// Inline (compressed) format:
+/// - `span.base_or_index == span_data.lo`
+/// - `span.len_or_tag == len == span_data.hi - span_data.lo` (must be `<= MAX_LEN`)
+/// - `span.ctxt == span_data.ctxt` (must be `<= MAX_CTXT`)
+///
+/// Interned format:
+/// - `span.base_or_index == index` (indexes into the interner table)
+/// - `span.len_or_tag == LEN_TAG` (high bit set, all other bits are zero)
+/// - `span.ctxt == 0`
+///
+/// The inline form uses 0 for the tag value (rather than 1) so that we don't
+/// need to mask out the tag bit when getting the length, and so that the
+/// dummy span can be all zeroes.
+///
+/// Notes about the choice of field sizes:
+/// - `base` is 32 bits in both `Span` and `SpanData`, which means that `base`
+///   values never cause interning. The number of bits needed for `base`
+///   depends on the crate size. 32 bits allows up to 4 GiB of code in a crate.
+///   `script-servo` is the largest crate in `rustc-perf`, requiring 26 bits
+///   for some spans.
+/// - `len` is 15 bits in `Span` (a u16, minus 1 bit for the tag) and 32 bits
+///   in `SpanData`, which means that large `len` values will cause interning.
+///   The number of bits needed for `len` does not depend on the crate size.
+///   The most common number of bits for `len` are 0--7, with a peak usually at
+///   3 or 4, and then it drops off quickly from 8 onwards. 15 bits is enough
+///   for 99.99%+ of cases, but larger values (sometimes 20+ bits) might occur
+///   dozens of times in a typical crate.
+/// - `ctxt` is 16 bits in `Span` and 32 bits in `SpanData`, which means that
+///   large `ctxt` values will cause interning. The number of bits needed for
+///   `ctxt` values depend partly on the crate size and partly on the form of
+///   the code. No crates in `rustc-perf` need more than 15 bits for `ctxt`,
+///   but larger crates might need more than 16 bits.
+///
+#[derive(Clone, Copy, Eq, PartialEq, Hash)]
+pub struct Span {
+    base_or_index: u32,
+    len_or_tag: u16,
+    ctxt_or_zero: u16,
+}
+
+const LEN_TAG: u16 = 0b1000_0000_0000_0000;
+const MAX_LEN: u32 = 0b0111_1111_1111_1111;
+const MAX_CTXT: u32 = 0b1111_1111_1111_1111;
+
+/// Dummy span, both position and length are zero, syntax context is zero as well.
+pub const DUMMY_SP: Span = Span { base_or_index: 0, len_or_tag: 0, ctxt_or_zero: 0 };
+
+impl Span {
+    #[inline]
+    pub fn new(mut lo: BytePos, mut hi: BytePos, ctxt: SyntaxContext) -> Self {
+        if lo > hi {
+            std::mem::swap(&mut lo, &mut hi);
+        }
+
+        let (base, len, ctxt2) = (lo.0, hi.0 - lo.0, ctxt.as_u32());
+
+        if len <= MAX_LEN && ctxt2 <= MAX_CTXT {
+            // Inline format.
+            Span { base_or_index: base, len_or_tag: len as u16, ctxt_or_zero: ctxt2 as u16 }
+        } else {
+            // Interned format.
+            let index = with_span_interner(|interner| interner.intern(&SpanData { lo, hi, ctxt }));
+            Span { base_or_index: index, len_or_tag: LEN_TAG, ctxt_or_zero: 0 }
+        }
+    }
+
+    #[inline]
+    pub fn data(self) -> SpanData {
+        if self.len_or_tag != LEN_TAG {
+            // Inline format.
+            debug_assert!(self.len_or_tag as u32 <= MAX_LEN);
+            SpanData {
+                lo: BytePos(self.base_or_index),
+                hi: BytePos(self.base_or_index + self.len_or_tag as u32),
+                ctxt: SyntaxContext::from_u32(self.ctxt_or_zero as u32),
+            }
+        } else {
+            // Interned format.
+            debug_assert!(self.ctxt_or_zero == 0);
+            let index = self.base_or_index;
+            with_span_interner(|interner| *interner.get(index))
+        }
+    }
+}
+
+#[derive(Default)]
+pub struct SpanInterner {
+    spans: FxIndexSet<SpanData>,
+}
+
+impl SpanInterner {
+    fn intern(&mut self, span_data: &SpanData) -> u32 {
+        let (index, _) = self.spans.insert_full(*span_data);
+        index as u32
+    }
+
+    #[inline]
+    fn get(&self, index: u32) -> &SpanData {
+        &self.spans[index as usize]
+    }
+}
+
+// If an interner exists, return it. Otherwise, prepare a fresh one.
+#[inline]
+fn with_span_interner<T, F: FnOnce(&mut SpanInterner) -> T>(f: F) -> T {
+    SESSION_GLOBALS.with(|session_globals| f(&mut *session_globals.span_interner.lock()))
+}