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denoland-deno/cli/standalone/code_cache.rs
David Sherret dd4570ed85
perf(compile): code cache (#26528)
Adds a lazily created code cache to `deno compile` by default.

The code cache is created on first run to a single file in the temp
directory and is only written once. After it's been written, the code
cache becomes read only on subsequent runs. Only the modules loaded
during startup are cached (dynamic imports are not code cached).

The code cache can be disabled by compiling with `--no-code-cache`.
2024-11-18 20:09:28 +00:00

514 lines
15 KiB
Rust

// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use std::collections::BTreeMap;
use std::collections::HashMap;
use std::io::BufReader;
use std::io::BufWriter;
use std::io::Read;
use std::io::Write;
use std::path::Path;
use std::path::PathBuf;
use std::sync::Arc;
use deno_ast::ModuleSpecifier;
use deno_core::anyhow::bail;
use deno_core::error::AnyError;
use deno_core::parking_lot::Mutex;
use deno_core::unsync::sync::AtomicFlag;
use deno_runtime::code_cache::CodeCache;
use deno_runtime::code_cache::CodeCacheType;
use crate::cache::FastInsecureHasher;
use crate::util::path::get_atomic_file_path;
use crate::worker::CliCodeCache;
enum CodeCacheStrategy {
FirstRun(FirstRunCodeCacheStrategy),
SubsequentRun(SubsequentRunCodeCacheStrategy),
}
#[derive(Debug, Clone, PartialEq, Eq)]
pub struct DenoCompileCodeCacheEntry {
pub source_hash: u64,
pub data: Vec<u8>,
}
pub struct DenoCompileCodeCache {
strategy: CodeCacheStrategy,
}
impl DenoCompileCodeCache {
pub fn new(file_path: PathBuf, cache_key: u64) -> Self {
// attempt to deserialize the cache data
match deserialize(&file_path, cache_key) {
Ok(data) => {
log::debug!("Loaded {} code cache entries", data.len());
Self {
strategy: CodeCacheStrategy::SubsequentRun(
SubsequentRunCodeCacheStrategy {
is_finished: AtomicFlag::lowered(),
data: Mutex::new(data),
},
),
}
}
Err(err) => {
log::debug!("Failed to deserialize code cache: {:#}", err);
Self {
strategy: CodeCacheStrategy::FirstRun(FirstRunCodeCacheStrategy {
cache_key,
file_path,
is_finished: AtomicFlag::lowered(),
data: Mutex::new(FirstRunCodeCacheData {
cache: HashMap::new(),
add_count: 0,
}),
}),
}
}
}
}
}
impl CodeCache for DenoCompileCodeCache {
fn get_sync(
&self,
specifier: &ModuleSpecifier,
code_cache_type: CodeCacheType,
source_hash: u64,
) -> Option<Vec<u8>> {
match &self.strategy {
CodeCacheStrategy::FirstRun(strategy) => {
if !strategy.is_finished.is_raised() {
// we keep track of how many times the cache is requested
// then serialize the cache when we get that number of
// "set" calls
strategy.data.lock().add_count += 1;
}
None
}
CodeCacheStrategy::SubsequentRun(strategy) => {
if strategy.is_finished.is_raised() {
return None;
}
strategy.take_from_cache(specifier, code_cache_type, source_hash)
}
}
}
fn set_sync(
&self,
specifier: ModuleSpecifier,
code_cache_type: CodeCacheType,
source_hash: u64,
bytes: &[u8],
) {
match &self.strategy {
CodeCacheStrategy::FirstRun(strategy) => {
if strategy.is_finished.is_raised() {
return;
}
let data_to_serialize = {
let mut data = strategy.data.lock();
data.cache.insert(
(specifier.to_string(), code_cache_type),
DenoCompileCodeCacheEntry {
source_hash,
data: bytes.to_vec(),
},
);
if data.add_count != 0 {
data.add_count -= 1;
}
if data.add_count == 0 {
// don't allow using the cache anymore
strategy.is_finished.raise();
if data.cache.is_empty() {
None
} else {
Some(std::mem::take(&mut data.cache))
}
} else {
None
}
};
if let Some(cache_data) = &data_to_serialize {
strategy.write_cache_data(cache_data);
}
}
CodeCacheStrategy::SubsequentRun(_) => {
// do nothing
}
}
}
}
impl CliCodeCache for DenoCompileCodeCache {
fn enabled(&self) -> bool {
match &self.strategy {
CodeCacheStrategy::FirstRun(strategy) => {
!strategy.is_finished.is_raised()
}
CodeCacheStrategy::SubsequentRun(strategy) => {
!strategy.is_finished.is_raised()
}
}
}
fn as_code_cache(self: Arc<Self>) -> Arc<dyn CodeCache> {
self
}
}
type CodeCacheKey = (String, CodeCacheType);
struct FirstRunCodeCacheData {
cache: HashMap<CodeCacheKey, DenoCompileCodeCacheEntry>,
add_count: usize,
}
struct FirstRunCodeCacheStrategy {
cache_key: u64,
file_path: PathBuf,
is_finished: AtomicFlag,
data: Mutex<FirstRunCodeCacheData>,
}
impl FirstRunCodeCacheStrategy {
fn write_cache_data(
&self,
cache_data: &HashMap<CodeCacheKey, DenoCompileCodeCacheEntry>,
) {
let count = cache_data.len();
let temp_file = get_atomic_file_path(&self.file_path);
match serialize(&temp_file, self.cache_key, cache_data) {
Ok(()) => {
if let Err(err) = std::fs::rename(&temp_file, &self.file_path) {
log::debug!("Failed to rename code cache: {}", err);
} else {
log::debug!("Serialized {} code cache entries", count);
}
}
Err(err) => {
let _ = std::fs::remove_file(&temp_file);
log::debug!("Failed to serialize code cache: {}", err);
}
}
}
}
struct SubsequentRunCodeCacheStrategy {
is_finished: AtomicFlag,
data: Mutex<HashMap<CodeCacheKey, DenoCompileCodeCacheEntry>>,
}
impl SubsequentRunCodeCacheStrategy {
fn take_from_cache(
&self,
specifier: &ModuleSpecifier,
code_cache_type: CodeCacheType,
source_hash: u64,
) -> Option<Vec<u8>> {
let mut data = self.data.lock();
// todo(dsherret): how to avoid the clone here?
let entry = data.remove(&(specifier.to_string(), code_cache_type))?;
if entry.source_hash != source_hash {
return None;
}
if data.is_empty() {
self.is_finished.raise();
}
Some(entry.data)
}
}
/// File format:
/// - <header>
/// - <cache key>
/// - <u32: number of entries>
/// - <[entry length]> - u64 * number of entries
/// - <[entry]>
/// - <[u8]: entry data>
/// - <String: specifier>
/// - <u8>: code cache type
/// - <u32: specifier length>
/// - <u64: source hash>
/// - <u64: entry data hash>
fn serialize(
file_path: &Path,
cache_key: u64,
cache: &HashMap<CodeCacheKey, DenoCompileCodeCacheEntry>,
) -> Result<(), AnyError> {
let cache_file = std::fs::OpenOptions::new()
.create(true)
.truncate(true)
.write(true)
.open(file_path)?;
let mut writer = BufWriter::new(cache_file);
serialize_with_writer(&mut writer, cache_key, cache)
}
fn serialize_with_writer<T: Write>(
writer: &mut BufWriter<T>,
cache_key: u64,
cache: &HashMap<CodeCacheKey, DenoCompileCodeCacheEntry>,
) -> Result<(), AnyError> {
// header
writer.write_all(&cache_key.to_le_bytes())?;
writer.write_all(&(cache.len() as u32).to_le_bytes())?;
// lengths of each entry
for ((specifier, _), entry) in cache {
let len: u64 =
entry.data.len() as u64 + specifier.len() as u64 + 1 + 4 + 8 + 8;
writer.write_all(&len.to_le_bytes())?;
}
// entries
for ((specifier, code_cache_type), entry) in cache {
writer.write_all(&entry.data)?;
writer.write_all(&[match code_cache_type {
CodeCacheType::EsModule => 0,
CodeCacheType::Script => 1,
}])?;
writer.write_all(specifier.as_bytes())?;
writer.write_all(&(specifier.len() as u32).to_le_bytes())?;
writer.write_all(&entry.source_hash.to_le_bytes())?;
let hash: u64 = FastInsecureHasher::new_without_deno_version()
.write(&entry.data)
.finish();
writer.write_all(&hash.to_le_bytes())?;
}
writer.flush()?;
Ok(())
}
fn deserialize(
file_path: &Path,
expected_cache_key: u64,
) -> Result<HashMap<CodeCacheKey, DenoCompileCodeCacheEntry>, AnyError> {
let cache_file = std::fs::File::open(file_path)?;
let mut reader = BufReader::new(cache_file);
deserialize_with_reader(&mut reader, expected_cache_key)
}
fn deserialize_with_reader<T: Read>(
reader: &mut BufReader<T>,
expected_cache_key: u64,
) -> Result<HashMap<CodeCacheKey, DenoCompileCodeCacheEntry>, AnyError> {
// it's very important to use this below so that a corrupt cache file
// doesn't cause a memory allocation error
fn new_vec_sized<T: Clone>(
capacity: usize,
default_value: T,
) -> Result<Vec<T>, AnyError> {
let mut vec = Vec::new();
vec.try_reserve(capacity)?;
vec.resize(capacity, default_value);
Ok(vec)
}
fn try_subtract(a: usize, b: usize) -> Result<usize, AnyError> {
if a < b {
bail!("Integer underflow");
}
Ok(a - b)
}
let mut header_bytes = vec![0; 8 + 4];
reader.read_exact(&mut header_bytes)?;
let actual_cache_key = u64::from_le_bytes(header_bytes[..8].try_into()?);
if actual_cache_key != expected_cache_key {
// cache bust
bail!("Cache key mismatch");
}
let len = u32::from_le_bytes(header_bytes[8..].try_into()?) as usize;
// read the lengths for each entry found in the file
let entry_len_bytes_capacity = len * 8;
let mut entry_len_bytes = new_vec_sized(entry_len_bytes_capacity, 0)?;
reader.read_exact(&mut entry_len_bytes)?;
let mut lengths = Vec::new();
lengths.try_reserve(len)?;
for i in 0..len {
let pos = i * 8;
lengths.push(
u64::from_le_bytes(entry_len_bytes[pos..pos + 8].try_into()?) as usize,
);
}
let mut map = HashMap::new();
map.try_reserve(len)?;
for len in lengths {
let mut buffer = new_vec_sized(len, 0)?;
reader.read_exact(&mut buffer)?;
let entry_data_hash_start_pos = try_subtract(buffer.len(), 8)?;
let expected_entry_data_hash =
u64::from_le_bytes(buffer[entry_data_hash_start_pos..].try_into()?);
let source_hash_start_pos = try_subtract(entry_data_hash_start_pos, 8)?;
let source_hash = u64::from_le_bytes(
buffer[source_hash_start_pos..entry_data_hash_start_pos].try_into()?,
);
let specifier_end_pos = try_subtract(source_hash_start_pos, 4)?;
let specifier_len = u32::from_le_bytes(
buffer[specifier_end_pos..source_hash_start_pos].try_into()?,
) as usize;
let specifier_start_pos = try_subtract(specifier_end_pos, specifier_len)?;
let specifier = String::from_utf8(
buffer[specifier_start_pos..specifier_end_pos].to_vec(),
)?;
let code_cache_type_pos = try_subtract(specifier_start_pos, 1)?;
let code_cache_type = match buffer[code_cache_type_pos] {
0 => CodeCacheType::EsModule,
1 => CodeCacheType::Script,
_ => bail!("Invalid code cache type"),
};
buffer.truncate(code_cache_type_pos);
let actual_entry_data_hash: u64 =
FastInsecureHasher::new_without_deno_version()
.write(&buffer)
.finish();
if expected_entry_data_hash != actual_entry_data_hash {
bail!("Hash mismatch.")
}
map.insert(
(specifier, code_cache_type),
DenoCompileCodeCacheEntry {
source_hash,
data: buffer,
},
);
}
Ok(map)
}
#[cfg(test)]
mod test {
use test_util::TempDir;
use super::*;
use std::fs::File;
#[test]
fn serialize_deserialize() {
let cache_key = 123456;
let cache = {
let mut cache = HashMap::new();
cache.insert(
("specifier1".to_string(), CodeCacheType::EsModule),
DenoCompileCodeCacheEntry {
source_hash: 1,
data: vec![1, 2, 3],
},
);
cache.insert(
("specifier2".to_string(), CodeCacheType::EsModule),
DenoCompileCodeCacheEntry {
source_hash: 2,
data: vec![4, 5, 6],
},
);
cache.insert(
("specifier2".to_string(), CodeCacheType::Script),
DenoCompileCodeCacheEntry {
source_hash: 2,
data: vec![6, 5, 1],
},
);
cache
};
let mut buffer = Vec::new();
serialize_with_writer(&mut BufWriter::new(&mut buffer), cache_key, &cache)
.unwrap();
let deserialized =
deserialize_with_reader(&mut BufReader::new(&buffer[..]), cache_key)
.unwrap();
assert_eq!(cache, deserialized);
}
#[test]
fn serialize_deserialize_empty() {
let cache_key = 1234;
let cache = HashMap::new();
let mut buffer = Vec::new();
serialize_with_writer(&mut BufWriter::new(&mut buffer), cache_key, &cache)
.unwrap();
let deserialized =
deserialize_with_reader(&mut BufReader::new(&buffer[..]), cache_key)
.unwrap();
assert_eq!(cache, deserialized);
}
#[test]
fn serialize_deserialize_corrupt() {
let buffer = "corrupttestingtestingtesting".as_bytes().to_vec();
let err = deserialize_with_reader(&mut BufReader::new(&buffer[..]), 1234)
.unwrap_err();
assert_eq!(err.to_string(), "Cache key mismatch");
}
#[test]
fn code_cache() {
let temp_dir = TempDir::new();
let file_path = temp_dir.path().join("cache.bin").to_path_buf();
let url1 = ModuleSpecifier::parse("https://deno.land/example1.js").unwrap();
let url2 = ModuleSpecifier::parse("https://deno.land/example2.js").unwrap();
// first run
{
let code_cache = DenoCompileCodeCache::new(file_path.clone(), 1234);
assert!(code_cache
.get_sync(&url1, CodeCacheType::EsModule, 0)
.is_none());
assert!(code_cache
.get_sync(&url2, CodeCacheType::EsModule, 1)
.is_none());
assert!(code_cache.enabled());
code_cache.set_sync(url1.clone(), CodeCacheType::EsModule, 0, &[1, 2, 3]);
assert!(code_cache.enabled());
assert!(!file_path.exists());
code_cache.set_sync(url2.clone(), CodeCacheType::EsModule, 1, &[2, 1, 3]);
assert!(file_path.exists()); // now the new code cache exists
assert!(!code_cache.enabled()); // no longer enabled
}
// second run
{
let code_cache = DenoCompileCodeCache::new(file_path.clone(), 1234);
assert!(code_cache.enabled());
let result1 = code_cache
.get_sync(&url1, CodeCacheType::EsModule, 0)
.unwrap();
assert!(code_cache.enabled());
let result2 = code_cache
.get_sync(&url2, CodeCacheType::EsModule, 1)
.unwrap();
assert!(!code_cache.enabled()); // no longer enabled
assert_eq!(result1, vec![1, 2, 3]);
assert_eq!(result2, vec![2, 1, 3]);
}
// new cache key first run
{
let code_cache = DenoCompileCodeCache::new(file_path.clone(), 54321);
assert!(code_cache
.get_sync(&url1, CodeCacheType::EsModule, 0)
.is_none());
assert!(code_cache
.get_sync(&url2, CodeCacheType::EsModule, 1)
.is_none());
code_cache.set_sync(url1.clone(), CodeCacheType::EsModule, 0, &[2, 2, 3]);
code_cache.set_sync(url2.clone(), CodeCacheType::EsModule, 1, &[3, 2, 3]);
}
// new cache key second run
{
let code_cache = DenoCompileCodeCache::new(file_path.clone(), 54321);
let result1 = code_cache
.get_sync(&url1, CodeCacheType::EsModule, 0)
.unwrap();
assert_eq!(result1, vec![2, 2, 3]);
assert!(code_cache
.get_sync(&url2, CodeCacheType::EsModule, 5) // different hash will cause none
.is_none());
}
}
}