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Add SSE2 accelerated version of FileMap analysis.

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This commit is contained in:
Michael Woerister 2018-05-29 17:50:13 +02:00
parent 3497138634
commit 5a6dc8c4f5
4 changed files with 445 additions and 68 deletions
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1
src/Cargo.lock
View file

@ -2779,6 +2779,7 @@ name = "syntax_pos"
version = "0.0.0"
dependencies = [
"arena 0.0.0",
"cfg-if 0.1.2 (registry+https://github.com/rust-lang/crates.io-index)",
"rustc_data_structures 0.0.0",
"scoped-tls 0.1.1 (registry+https://github.com/rust-lang/crates.io-index)",
"serialize 0.0.0",

1
src/libsyntax_pos/Cargo.toml
View file

@ -14,3 +14,4 @@ rustc_data_structures = { path = "../librustc_data_structures" }
arena = { path = "../libarena" }
scoped-tls = { version = "0.1.1", features = ["nightly"] }
unicode-width = "0.1.4"
cfg-if = "0.1.2"

434
src/libsyntax_pos/analyze_filemap.rs Normal file
View file

@ -0,0 +1,434 @@
// Copyright 2018 The Rust Project Developers. See the COPYRIGHT
// file at the top-level directory of this distribution and at
// http://rust-lang.org/COPYRIGHT.
//
// Licensed under the Apache License, Version 2.0 <LICENSE-APACHE or
// http://www.apache.org/licenses/LICENSE-2.0> or the MIT license
// <LICENSE-MIT or http://opensource.org/licenses/MIT>, at your
// option. This file may not be copied, modified, or distributed
// except according to those terms.
use unicode_width::UnicodeWidthChar;
use super::*;
/// Find all newlines, multi-byte characters, and non-narrow characters in a
/// FileMap.
///
/// This function will use an SSE2 enhanced implementation if hardware support
/// is detected at runtime.
pub fn analyze_filemap(
src: &str,
filemap_start_pos: BytePos)
-> (Vec<BytePos>, Vec<MultiByteChar>, Vec<NonNarrowChar>)
{
let mut lines = vec![filemap_start_pos];
let mut multi_byte_chars = vec![];
let mut non_narrow_chars = vec![];
// Calls the right implementation, depending on hardware support available.
analyze_filemap_dispatch(src,
filemap_start_pos,
&mut lines,
&mut multi_byte_chars,
&mut non_narrow_chars);
// The code above optimistically registers a new line *after* each \n
// it encounters. If that point is already outside the filemap, remove
// it again.
if let Some(&last_line_start) = lines.last() {
let file_map_end = filemap_start_pos + BytePos::from_usize(src.len());
assert!(file_map_end >= last_line_start);
if last_line_start == file_map_end {
lines.pop();
}
}
(lines, multi_byte_chars, non_narrow_chars)
}
cfg_if! {
if #[cfg(all(any(target_arch = "x86", target_arch = "x86_64"),
not(stage0)))] {
fn analyze_filemap_dispatch(src: &str,
filemap_start_pos: BytePos,
lines: &mut Vec<BytePos>,
multi_byte_chars: &mut Vec<MultiByteChar>,
non_narrow_chars: &mut Vec<NonNarrowChar>) {
if is_x86_feature_detected!("sse2") {
unsafe {
analyze_filemap_sse2(src,
filemap_start_pos,
lines,
multi_byte_chars,
non_narrow_chars);
}
} else {
analyze_filemap_generic(src,
src.len(),
filemap_start_pos,
lines,
multi_byte_chars,
non_narrow_chars);
}
}
/// Check 16 byte chunks of text at a time. If the chunk contains
/// something other than printable ASCII characters and newlines, the
/// function falls back to the generic implementation. Otherwise it uses
/// SSE2 intrinsics to quickly find all newlines.
#[target_feature(enable = "sse2")]
unsafe fn analyze_filemap_sse2(src: &str,
output_offset: BytePos,
lines: &mut Vec<BytePos>,
multi_byte_chars: &mut Vec<MultiByteChar>,
non_narrow_chars: &mut Vec<NonNarrowChar>) {
#[cfg(target_arch = "x86")]
use std::arch::x86::*;
#[cfg(target_arch = "x86_64")]
use std::arch::x86_64::*;
const CHUNK_SIZE: usize = 16;
let src_bytes = src.as_bytes();
let chunk_count = src.len() / CHUNK_SIZE;
// This variable keeps track of where we should start decoding a
// chunk. If a multi-byte character spans across chunk boundaries,
// we need to skip that part in the next chunk because we already
// handled it.
let mut intra_chunk_offset = 0;
for chunk_index in 0 .. chunk_count {
let ptr = src_bytes.as_ptr() as *const __m128i;
let chunk = _mm_loadu_si128(ptr.offset(chunk_index as isize));
// For character in the chunk, see if its byte value is < 0, which
// indicates that it's part of a UTF-8 char.
let multibyte_test = _mm_cmplt_epi8(chunk, _mm_set1_epi8(0));
// Create a bit mask from the comparison results.
let multibyte_mask = _mm_movemask_epi8(multibyte_test);
// If the bit mask is all zero, we only have ASCII chars here:
if multibyte_mask == 0 {
assert!(intra_chunk_offset == 0);
// Check if there are any control characters in the chunk. All
// control characters that we can encounter at this point have a
// byte value less than 32 or ...
let control_char_test0 = _mm_cmplt_epi8(chunk, _mm_set1_epi8(32));
let control_char_mask0 = _mm_movemask_epi8(control_char_test0);
// ... it's the ASCII 'DEL' character with a value of 127.
let control_char_test1 = _mm_cmpeq_epi8(chunk, _mm_set1_epi8(127));
let control_char_mask1 = _mm_movemask_epi8(control_char_test1);
let control_char_mask = control_char_mask0 | control_char_mask1;
if control_char_mask != 0 {
// Check for newlines in the chunk
let newlines_test = _mm_cmpeq_epi8(chunk, _mm_set1_epi8(b'\n' as i8));
let newlines_mask = _mm_movemask_epi8(newlines_test);
if control_char_mask == newlines_mask {
// All control characters are newlines, record them
let mut newlines_mask = 0xFFFF0000 | newlines_mask as u32;
let output_offset = output_offset +
BytePos::from_usize(chunk_index * CHUNK_SIZE + 1);
loop {
let index = newlines_mask.trailing_zeros();
if index >= CHUNK_SIZE as u32 {
// We have arrived at the end of the chunk.
break
}
lines.push(BytePos(index) + output_offset);
// Clear the bit, so we can find the next one.
newlines_mask &= (!1) << index;
}
// We are done for this chunk. All control characters were
// newlines and we took care of those.
continue
} else {
// Some of the control characters are not newlines,
// fall through to the slow path below.
}
} else {
// No control characters, nothing to record for this chunk
continue
}
}
// The slow path.
// There are control chars in here, fallback to generic decoding.
let scan_start = chunk_index * CHUNK_SIZE + intra_chunk_offset;
intra_chunk_offset = analyze_filemap_generic(
&src[scan_start .. ],
CHUNK_SIZE - intra_chunk_offset,
BytePos::from_usize(scan_start) + output_offset,
lines,
multi_byte_chars,
non_narrow_chars
);
}
// There might still be a tail left to analyze
let tail_start = chunk_count * CHUNK_SIZE + intra_chunk_offset;
if tail_start < src.len() {
analyze_filemap_generic(&src[tail_start as usize ..],
src.len() - tail_start,
output_offset + BytePos::from_usize(tail_start),
lines,
multi_byte_chars,
non_narrow_chars);
}
}
} else {
// The target (or compiler version) does not support SSE2 ...
fn analyze_filemap_dispatch(src: &str,
filemap_start_pos: BytePos,
lines: &mut Vec<BytePos>,
multi_byte_chars: &mut Vec<MultiByteChar>,
non_narrow_chars: &mut Vec<NonNarrowChar>) {
analyze_filemap_generic(src,
src.len(),
filemap_start_pos,
lines,
multi_byte_chars,
non_narrow_chars);
}
}
}
// `scan_len` determines the number of bytes in `src` to scan. Note that the
// function can read past `scan_len` if a multi-byte character start within the
// range but extends past it. The overflow is returned by the function.
fn analyze_filemap_generic(src: &str,
scan_len: usize,
output_offset: BytePos,
lines: &mut Vec<BytePos>,
multi_byte_chars: &mut Vec<MultiByteChar>,
non_narrow_chars: &mut Vec<NonNarrowChar>)
-> usize
{
assert!(src.len() >= scan_len);
let mut i = 0;
let src_bytes = src.as_bytes();
while i < scan_len {
let byte = unsafe {
// We verified that i < scan_len <= src.len()
*src_bytes.get_unchecked(i as usize)
};
// How much to advance in order to get to the next UTF-8 char in the
// string.
let mut char_len = 1;
if byte < 32 {
// This is an ASCII control character, it could be one of the cases
// that are interesting to us.
let pos = BytePos::from_usize(i) + output_offset;
match byte {
b'\n' => {
lines.push(pos + BytePos(1));
}
b'\t' => {
non_narrow_chars.push(NonNarrowChar::Tab(pos));
}
_ => {
non_narrow_chars.push(NonNarrowChar::ZeroWidth(pos));
}
}
} else if byte >= 127 {
// The slow path:
// This is either ASCII control character "DEL" or the beginning of
// a multibyte char. Just decode to `char`.
let c = (&src[i..]).chars().next().unwrap();
char_len = c.len_utf8();
let pos = BytePos::from_usize(i) + output_offset;
if char_len > 1 {
assert!(char_len >=2 && char_len <= 4);
let mbc = MultiByteChar {
pos,
bytes: char_len as u32,
};
multi_byte_chars.push(mbc);
}
// Assume control characters are zero width.
// FIXME: How can we decide between `width` and `width_cjk`?
let char_width = UnicodeWidthChar::width(c).unwrap_or(0);
if char_width != 1 {
non_narrow_chars.push(NonNarrowChar::new(pos, char_width));
}
}
i += char_len;
}
i - scan_len
}
macro_rules! test {
(case: $test_name:ident,
text: $text:expr,
filemap_start_pos: $filemap_start_pos:expr,
lines: $lines:expr,
multi_byte_chars: $multi_byte_chars:expr,
non_narrow_chars: $non_narrow_chars:expr,) => (
#[test]
fn $test_name() {
let (lines, multi_byte_chars, non_narrow_chars) =
analyze_filemap($text, BytePos($filemap_start_pos));
let expected_lines: Vec<BytePos> = $lines
.into_iter()
.map(|pos| BytePos(pos))
.collect();
assert_eq!(lines, expected_lines);
let expected_mbcs: Vec<MultiByteChar> = $multi_byte_chars
.into_iter()
.map(|(pos, bytes)| MultiByteChar {
pos: BytePos(pos),
bytes,
})
.collect();
assert_eq!(multi_byte_chars, expected_mbcs);
let expected_nncs: Vec<NonNarrowChar> = $non_narrow_chars
.into_iter()
.map(|(pos, width)| {
NonNarrowChar::new(BytePos(pos), width)
})
.collect();
assert_eq!(non_narrow_chars, expected_nncs);
})
}
test!(
case: empty_text,
text: "",
filemap_start_pos: 0,
lines: vec![],
multi_byte_chars: vec![],
non_narrow_chars: vec![],
);
test!(
case: newlines_short,
text: "a\nc",
filemap_start_pos: 0,
lines: vec![0, 2],
multi_byte_chars: vec![],
non_narrow_chars: vec![],
);
test!(
case: newlines_long,
text: "012345678\nabcdef012345678\na",
filemap_start_pos: 0,
lines: vec![0, 10, 26],
multi_byte_chars: vec![],
non_narrow_chars: vec![],
);
test!(
case: newline_and_multi_byte_char_in_same_chunk,
text: "01234β789\nbcdef0123456789abcdef",
filemap_start_pos: 0,
lines: vec![0, 11],
multi_byte_chars: vec![(5, 2)],
non_narrow_chars: vec![],
);
test!(
case: newline_and_control_char_in_same_chunk,
text: "01234\u{07}6789\nbcdef0123456789abcdef",
filemap_start_pos: 0,
lines: vec![0, 11],
multi_byte_chars: vec![],
non_narrow_chars: vec![(5, 0)],
);
test!(
case: multi_byte_char_short,
text: "aβc",
filemap_start_pos: 0,
lines: vec![0],
multi_byte_chars: vec![(1, 2)],
non_narrow_chars: vec![],
);
test!(
case: multi_byte_char_long,
text: "0123456789abcΔf012345β",
filemap_start_pos: 0,
lines: vec![0],
multi_byte_chars: vec![(13, 2), (22, 2)],
non_narrow_chars: vec![],
);
test!(
case: multi_byte_char_across_chunk_boundary,
text: "0123456789abcdeΔ123456789abcdef01234",
filemap_start_pos: 0,
lines: vec![0],
multi_byte_chars: vec![(15, 2)],
non_narrow_chars: vec![],
);
test!(
case: multi_byte_char_across_chunk_boundary_tail,
text: "0123456789abcdeΔ....",
filemap_start_pos: 0,
lines: vec![0],
multi_byte_chars: vec![(15, 2)],
non_narrow_chars: vec![],
);
test!(
case: non_narrow_short,
text: "0\t2",
filemap_start_pos: 0,
lines: vec![0],
multi_byte_chars: vec![],
non_narrow_chars: vec![(1, 4)],
);
test!(
case: non_narrow_long,
text: "01\t3456789abcdef01234567\u{07}9",
filemap_start_pos: 0,
lines: vec![0],
multi_byte_chars: vec![],
non_narrow_chars: vec![(2, 4), (24, 0)],
);
test!(
case: output_offset_all,
text: "01\t345\n789abcΔf01234567\u{07}9\nbcΔf",
filemap_start_pos: 1000,
lines: vec![0 + 1000, 7 + 1000, 27 + 1000],
multi_byte_chars: vec![(13 + 1000, 2), (29 + 1000, 2)],
non_narrow_chars: vec![(2 + 1000, 4), (24 + 1000, 0)],
);

77
src/libsyntax_pos/lib.rs
View file

@ -24,6 +24,7 @@
#![feature(optin_builtin_traits)]
#![allow(unused_attributes)]
#![feature(specialization)]
#![feature(stdsimd)]
use std::borrow::Cow;
use std::cell::Cell;
@ -47,6 +48,9 @@ use serialize::{Encodable, Decodable, Encoder, Decoder};
extern crate serialize;
extern crate serialize as rustc_serialize; // used by deriving
#[macro_use]
extern crate cfg_if;
extern crate unicode_width;
pub mod edition;
@ -58,6 +62,8 @@ pub use span_encoding::{Span, DUMMY_SP};
pub mod symbol;
mod analyze_filemap;
pub struct Globals {
symbol_interner: Lock<symbol::Interner>,
span_interner: Lock<span_encoding::SpanInterner>,
@ -652,7 +658,7 @@ impl From<Vec<Span>> for MultiSpan {
pub const NO_EXPANSION: SyntaxContext = SyntaxContext::empty();
/// Identifies an offset of a multi-byte character in a FileMap
#[derive(Copy, Clone, RustcEncodable, RustcDecodable, Eq, PartialEq)]
#[derive(Copy, Clone, RustcEncodable, RustcDecodable, Eq, PartialEq, Debug)]
pub struct MultiByteChar {
/// The absolute offset of the character in the CodeMap
pub pos: BytePos,
@ -661,7 +667,7 @@ pub struct MultiByteChar {
}
/// Identifies an offset of a non-narrow character in a FileMap
#[derive(Copy, Clone, RustcEncodable, RustcDecodable, Eq, PartialEq)]
#[derive(Copy, Clone, RustcEncodable, RustcDecodable, Eq, PartialEq, Debug)]
pub enum NonNarrowChar {
/// Represents a zero-width character
ZeroWidth(BytePos),
@ -950,7 +956,7 @@ impl FileMap {
let end_pos = start_pos.to_usize() + src.len();
let (lines, multibyte_chars, non_narrow_chars) =
Self::find_newlines_and_special_chars(&src[..], start_pos);
analyze_filemap::analyze_filemap(&src[..], start_pos);
FileMap {
name,
@ -969,71 +975,6 @@ impl FileMap {
}
}
fn find_newlines_and_special_chars(src: &str, filemap_start_pos: BytePos)
-> (Vec<BytePos>, Vec<MultiByteChar>, Vec<NonNarrowChar>) {
let mut index = 0;
let mut lines = vec![filemap_start_pos];
let mut multibyte_chars = vec![];
let mut non_narrow_chars = vec![];
while index < src.len() {
let byte_pos = BytePos::from_usize(index) + filemap_start_pos;
let byte = src.as_bytes()[index];
if byte.is_ascii() {
match byte {
b'\n' => {
lines.push(byte_pos + BytePos(1));
}
b'\t' => {
// Tabs will consume 4 columns.
non_narrow_chars.push(NonNarrowChar::new(byte_pos, 4));
}
c => if c.is_ascii_control() {
// Assume control characters are zero width.
non_narrow_chars.push(NonNarrowChar::new(byte_pos, 0));
}
}
index += 1;
} else {
let c = (&src[index..]).chars().next().unwrap();
let c_len = c.len_utf8();
if c_len > 1 {
assert!(c_len >=2 && c_len <= 4);
let mbc = MultiByteChar {
pos: byte_pos,
bytes: c_len,
};
multibyte_chars.push(mbc);
}
// Assume control characters are zero width.
// FIXME: How can we decide between `width` and `width_cjk`?
let c_width = unicode_width::UnicodeWidthChar::width(c).unwrap_or(0);
if c_width != 1 {
non_narrow_chars.push(NonNarrowChar::new(byte_pos, c_width));
}
index += c_len;
}
}
// The loop above optimistically registers a new line *after* each of \n
// it encounters. If that point is already outside the filemap, remove
// it again.
if let Some(&last_line_start) = lines.last() {
if last_line_start == filemap_start_pos + BytePos::from_usize(src.len()) {
lines.pop();
}
}
(lines, multibyte_chars, non_narrow_chars)
}
/// Return the BytePos of the beginning of the current line.
pub fn line_begin_pos(&self) -> BytePos {
match self.lines.last() {