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denoland-deno/ext/cache/sqlite.rs

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// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license.
use std::borrow::Cow;
use std::path::PathBuf;
use std::pin::Pin;
use std::rc::Rc;
use std::sync::Arc;
use std::time::SystemTime;
use std::time::UNIX_EPOCH;
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use async_trait::async_trait;
use deno_core::error::AnyError;
use deno_core::futures::future::poll_fn;
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use deno_core::parking_lot::Mutex;
use deno_core::unsync::spawn_blocking;
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use deno_core::AsyncRefCell;
use deno_core::AsyncResult;
use deno_core::BufMutView;
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use deno_core::ByteString;
use deno_core::Resource;
use rusqlite::params;
use rusqlite::Connection;
use rusqlite::OptionalExtension;
use tokio::io::AsyncReadExt;
use tokio::io::AsyncWrite;
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use tokio::io::AsyncWriteExt;
use crate::deserialize_headers;
use crate::get_header;
use crate::serialize_headers;
use crate::vary_header_matches;
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use crate::Cache;
use crate::CacheDeleteRequest;
use crate::CacheError;
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use crate::CacheMatchRequest;
use crate::CacheMatchResponseMeta;
use crate::CachePutRequest;
#[derive(Clone)]
pub struct SqliteBackedCache {
pub connection: Arc<Mutex<Connection>>,
pub cache_storage_dir: PathBuf,
}
impl SqliteBackedCache {
pub fn new(cache_storage_dir: PathBuf) -> Self {
{
std::fs::create_dir_all(&cache_storage_dir)
.expect("failed to create cache dir");
let path = cache_storage_dir.join("cache_metadata.db");
let connection = rusqlite::Connection::open(&path).unwrap_or_else(|_| {
panic!("failed to open cache db at {}", path.display())
});
// Enable write-ahead-logging mode.
let initial_pragmas = "
-- enable write-ahead-logging mode
PRAGMA journal_mode=WAL;
PRAGMA synchronous=NORMAL;
PRAGMA optimize;
";
connection
.execute_batch(initial_pragmas)
.expect("failed to execute pragmas");
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connection
.execute(
"CREATE TABLE IF NOT EXISTS cache_storage (
id INTEGER PRIMARY KEY,
cache_name TEXT NOT NULL UNIQUE
)",
(),
)
.expect("failed to create cache_storage table");
connection
.execute(
"CREATE TABLE IF NOT EXISTS request_response_list (
id INTEGER PRIMARY KEY,
cache_id INTEGER NOT NULL,
request_url TEXT NOT NULL,
request_headers BLOB NOT NULL,
response_headers BLOB NOT NULL,
response_status INTEGER NOT NULL,
response_status_text TEXT,
response_body_key TEXT,
last_inserted_at INTEGER UNSIGNED NOT NULL,
FOREIGN KEY (cache_id) REFERENCES cache_storage(id) ON DELETE CASCADE,
UNIQUE (cache_id, request_url)
)",
(),
)
.expect("failed to create request_response_list table");
SqliteBackedCache {
connection: Arc::new(Mutex::new(connection)),
cache_storage_dir,
}
}
}
}
#[async_trait(?Send)]
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impl Cache for SqliteBackedCache {
type CacheMatchResourceType = CacheResponseResource;
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/// Open a cache storage. Internally, this creates a row in the
/// sqlite db if the cache doesn't exist and returns the internal id
/// of the cache.
async fn storage_open(&self, cache_name: String) -> Result<i64, CacheError> {
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let db = self.connection.clone();
let cache_storage_dir = self.cache_storage_dir.clone();
spawn_blocking(move || {
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let db = db.lock();
db.execute(
"INSERT OR IGNORE INTO cache_storage (cache_name) VALUES (?1)",
params![cache_name],
)?;
let cache_id = db.query_row(
"SELECT id FROM cache_storage WHERE cache_name = ?1",
params![cache_name],
|row| {
let id: i64 = row.get(0)?;
Ok(id)
},
)?;
let responses_dir = get_responses_dir(cache_storage_dir, cache_id);
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std::fs::create_dir_all(responses_dir)?;
Ok::<i64, CacheError>(cache_id)
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})
.await?
}
/// Check if a cache with the provided name exists.
/// Note: this doesn't check the disk, it only checks the sqlite db.
async fn storage_has(&self, cache_name: String) -> Result<bool, CacheError> {
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let db = self.connection.clone();
spawn_blocking(move || {
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let db = db.lock();
let cache_exists = db.query_row(
"SELECT count(id) FROM cache_storage WHERE cache_name = ?1",
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params![cache_name],
|row| {
let count: i64 = row.get(0)?;
Ok(count > 0)
},
)?;
Ok::<bool, CacheError>(cache_exists)
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})
.await?
}
/// Delete a cache storage. Internally, this deletes the row in the sqlite db.
async fn storage_delete(
&self,
cache_name: String,
) -> Result<bool, CacheError> {
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let db = self.connection.clone();
let cache_storage_dir = self.cache_storage_dir.clone();
spawn_blocking(move || {
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let db = db.lock();
let maybe_cache_id = db
.query_row(
"DELETE FROM cache_storage WHERE cache_name = ?1 RETURNING id",
params![cache_name],
|row| {
let id: i64 = row.get(0)?;
Ok(id)
},
)
.optional()?;
if let Some(cache_id) = maybe_cache_id {
let cache_dir = cache_storage_dir.join(cache_id.to_string());
if cache_dir.exists() {
std::fs::remove_dir_all(cache_dir)?;
}
}
Ok::<bool, CacheError>(maybe_cache_id.is_some())
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})
.await?
}
async fn put(
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&self,
request_response: CachePutRequest,
resource: Option<Rc<dyn Resource>>,
) -> Result<(), CacheError> {
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let db = self.connection.clone();
let cache_storage_dir = self.cache_storage_dir.clone();
let now = SystemTime::now()
.duration_since(UNIX_EPOCH)
.expect("SystemTime is before unix epoch");
if let Some(resource) = resource {
let body_key = hash(&format!(
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"{}_{}",
&request_response.request_url,
now.as_nanos()
));
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let responses_dir =
get_responses_dir(cache_storage_dir, request_response.cache_id);
let response_path = responses_dir.join(&body_key);
let mut file = tokio::fs::File::create(response_path).await?;
let mut buf = BufMutView::new(64 * 1024);
loop {
let (size, buf2) = resource
.clone()
.read_byob(buf)
.await
.map_err(CacheError::Other)?;
if size == 0 {
break;
}
buf = buf2;
// Use poll_write to avoid holding a slice across await points
poll_fn(|cx| Pin::new(&mut file).poll_write(cx, &buf[..size])).await?;
}
file.flush().await?;
file.sync_all().await?;
assert_eq!(
insert_cache_asset(db, request_response, Some(body_key.clone()),)
.await?,
Some(body_key)
);
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} else {
assert!(insert_cache_asset(db, request_response, None)
.await?
.is_none());
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}
Ok(())
}
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async fn r#match(
&self,
request: CacheMatchRequest,
) -> Result<
Option<(CacheMatchResponseMeta, Option<CacheResponseResource>)>,
CacheError,
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> {
let db = self.connection.clone();
let cache_storage_dir = self.cache_storage_dir.clone();
let (query_result, request) = spawn_blocking(move || {
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let db = db.lock();
let result = db.query_row(
"SELECT response_body_key, response_headers, response_status, response_status_text, request_headers
FROM request_response_list
WHERE cache_id = ?1 AND request_url = ?2",
(request.cache_id, &request.request_url),
|row| {
let response_body_key: Option<String> = row.get(0)?;
let response_headers: Vec<u8> = row.get(1)?;
let response_status: u16 = row.get(2)?;
let response_status_text: String = row.get(3)?;
let request_headers: Vec<u8> = row.get(4)?;
let response_headers: Vec<(ByteString, ByteString)> = deserialize_headers(&response_headers);
let request_headers: Vec<(ByteString, ByteString)> = deserialize_headers(&request_headers);
Ok((CacheMatchResponseMeta {
request_headers,
response_headers,
response_status,
response_status_text},
response_body_key
))
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},
);
// Return ownership of request to the caller
result.optional().map(|x| (x, request))
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})
.await??;
match query_result {
Some((cache_meta, Some(response_body_key))) => {
// From https://w3c.github.io/ServiceWorker/#request-matches-cached-item-algorithm
// If there's Vary header in the response, ensure all the
// headers of the cached request match the query request.
if let Some(vary_header) =
get_header("vary", &cache_meta.response_headers)
{
if !vary_header_matches(
&vary_header,
&request.request_headers,
&cache_meta.request_headers,
) {
return Ok(None);
}
}
let response_path =
get_responses_dir(cache_storage_dir, request.cache_id)
.join(response_body_key);
let file = match tokio::fs::File::open(response_path).await {
Ok(file) => file,
Err(err) if err.kind() == std::io::ErrorKind::NotFound => {
// Best efforts to delete the old cache item
_ = self
.delete(CacheDeleteRequest {
cache_id: request.cache_id,
request_url: request.request_url,
})
.await;
return Ok(None);
}
Err(err) => return Err(err.into()),
};
Ok(Some((cache_meta, Some(CacheResponseResource::new(file)))))
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}
Some((cache_meta, None)) => Ok(Some((cache_meta, None))),
None => Ok(None),
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}
}
async fn delete(
&self,
request: CacheDeleteRequest,
) -> Result<bool, CacheError> {
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let db = self.connection.clone();
spawn_blocking(move || {
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// TODO(@satyarohith): remove the response body from disk if one exists
let db = db.lock();
let rows_effected = db.execute(
"DELETE FROM request_response_list WHERE cache_id = ?1 AND request_url = ?2",
(request.cache_id, &request.request_url),
)?;
Ok::<bool, CacheError>(rows_effected > 0)
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})
.await?
}
}
async fn insert_cache_asset(
db: Arc<Mutex<Connection>>,
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put: CachePutRequest,
response_body_key: Option<String>,
) -> Result<Option<String>, CacheError> {
spawn_blocking(move || {
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let maybe_response_body = {
let db = db.lock();
db.query_row(
"INSERT OR REPLACE INTO request_response_list
(cache_id, request_url, request_headers, response_headers,
response_body_key, response_status, response_status_text, last_inserted_at)
VALUES (?1, ?2, ?3, ?4, ?5, ?6, ?7, ?8)
RETURNING response_body_key",
(
put.cache_id,
put.request_url,
serialize_headers(&put.request_headers),
serialize_headers(&put.response_headers),
response_body_key,
put.response_status,
put.response_status_text,
SystemTime::now().duration_since(UNIX_EPOCH).expect("SystemTime is before unix epoch").as_secs(),
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),
|row| {
let response_body_key: Option<String> = row.get(0)?;
Ok(response_body_key)
},
)?
};
Ok::<Option<String>, CacheError>(maybe_response_body)
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}).await?
}
#[inline]
fn get_responses_dir(cache_storage_dir: PathBuf, cache_id: i64) -> PathBuf {
cache_storage_dir
.join(cache_id.to_string())
.join("responses")
}
impl deno_core::Resource for SqliteBackedCache {
fn name(&self) -> std::borrow::Cow<str> {
"SqliteBackedCache".into()
}
}
pub struct CacheResponseResource {
file: AsyncRefCell<tokio::fs::File>,
}
impl CacheResponseResource {
fn new(file: tokio::fs::File) -> Self {
Self {
file: AsyncRefCell::new(file),
}
}
feat(core): improve resource read & write traits (#16115) This commit introduces two new buffer wrapper types to `deno_core`. The main benefit of these new wrappers is that they can wrap a number of different underlying buffer types. This allows for a more flexible read and write API on resources that will require less copying of data between different buffer representations. - `BufView` is a read-only view onto a buffer. It can be backed by `ZeroCopyBuf`, `Vec<u8>`, and `bytes::Bytes`. - `BufViewMut` is a read-write view onto a buffer. It can be cheaply converted into a `BufView`. It can be backed by `ZeroCopyBuf` or `Vec<u8>`. Both new buffer views have a cursor. This means that the start point of the view can be constrained to write / read from just a slice of the view. Only the start point of the slice can be adjusted. The end point is fixed. To adjust the end point, the underlying buffer needs to be truncated. Readable resources have been changed to better cater to resources that do not support BYOB reads. The basic `read` method now returns a `BufView` instead of taking a `ZeroCopyBuf` to fill. This allows the operation to return buffers that the resource has already allocated, instead of forcing the caller to allocate the buffer. BYOB reads are still very useful for resources that support them, so a new `read_byob` method has been added that takes a `BufViewMut` to fill. `op_read` attempts to use `read_byob` if the resource supports it, which falls back to `read` and performs an additional copy if it does not. For Rust->JS reads this change should have no impact, but for Rust->Rust reads, this allows the caller to avoid an additional copy in many scenarios. This combined with the support for `BufView` to be backed by `bytes::Bytes` allows us to avoid one data copy when piping from a `fetch` response into an `ext/http` response. Writable resources have been changed to take a `BufView` instead of a `ZeroCopyBuf` as an argument. This allows for less copying of data in certain scenarios, as described above. Additionally a new `Resource::write_all` method has been added that takes a `BufView` and continually attempts to write the resource until the entire buffer has been written. Certain resources like files can override this method to provide a more efficient `write_all` implementation.
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async fn read(self: Rc<Self>, data: &mut [u8]) -> Result<usize, AnyError> {
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let resource = deno_core::RcRef::map(&self, |r| &r.file);
let mut file = resource.borrow_mut().await;
feat(core): improve resource read & write traits (#16115) This commit introduces two new buffer wrapper types to `deno_core`. The main benefit of these new wrappers is that they can wrap a number of different underlying buffer types. This allows for a more flexible read and write API on resources that will require less copying of data between different buffer representations. - `BufView` is a read-only view onto a buffer. It can be backed by `ZeroCopyBuf`, `Vec<u8>`, and `bytes::Bytes`. - `BufViewMut` is a read-write view onto a buffer. It can be cheaply converted into a `BufView`. It can be backed by `ZeroCopyBuf` or `Vec<u8>`. Both new buffer views have a cursor. This means that the start point of the view can be constrained to write / read from just a slice of the view. Only the start point of the slice can be adjusted. The end point is fixed. To adjust the end point, the underlying buffer needs to be truncated. Readable resources have been changed to better cater to resources that do not support BYOB reads. The basic `read` method now returns a `BufView` instead of taking a `ZeroCopyBuf` to fill. This allows the operation to return buffers that the resource has already allocated, instead of forcing the caller to allocate the buffer. BYOB reads are still very useful for resources that support them, so a new `read_byob` method has been added that takes a `BufViewMut` to fill. `op_read` attempts to use `read_byob` if the resource supports it, which falls back to `read` and performs an additional copy if it does not. For Rust->JS reads this change should have no impact, but for Rust->Rust reads, this allows the caller to avoid an additional copy in many scenarios. This combined with the support for `BufView` to be backed by `bytes::Bytes` allows us to avoid one data copy when piping from a `fetch` response into an `ext/http` response. Writable resources have been changed to take a `BufView` instead of a `ZeroCopyBuf` as an argument. This allows for less copying of data in certain scenarios, as described above. Additionally a new `Resource::write_all` method has been added that takes a `BufView` and continually attempts to write the resource until the entire buffer has been written. Certain resources like files can override this method to provide a more efficient `write_all` implementation.
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let nread = file.read(data).await?;
Ok(nread)
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}
}
impl Resource for CacheResponseResource {
feat(core): improve resource read & write traits (#16115) This commit introduces two new buffer wrapper types to `deno_core`. The main benefit of these new wrappers is that they can wrap a number of different underlying buffer types. This allows for a more flexible read and write API on resources that will require less copying of data between different buffer representations. - `BufView` is a read-only view onto a buffer. It can be backed by `ZeroCopyBuf`, `Vec<u8>`, and `bytes::Bytes`. - `BufViewMut` is a read-write view onto a buffer. It can be cheaply converted into a `BufView`. It can be backed by `ZeroCopyBuf` or `Vec<u8>`. Both new buffer views have a cursor. This means that the start point of the view can be constrained to write / read from just a slice of the view. Only the start point of the slice can be adjusted. The end point is fixed. To adjust the end point, the underlying buffer needs to be truncated. Readable resources have been changed to better cater to resources that do not support BYOB reads. The basic `read` method now returns a `BufView` instead of taking a `ZeroCopyBuf` to fill. This allows the operation to return buffers that the resource has already allocated, instead of forcing the caller to allocate the buffer. BYOB reads are still very useful for resources that support them, so a new `read_byob` method has been added that takes a `BufViewMut` to fill. `op_read` attempts to use `read_byob` if the resource supports it, which falls back to `read` and performs an additional copy if it does not. For Rust->JS reads this change should have no impact, but for Rust->Rust reads, this allows the caller to avoid an additional copy in many scenarios. This combined with the support for `BufView` to be backed by `bytes::Bytes` allows us to avoid one data copy when piping from a `fetch` response into an `ext/http` response. Writable resources have been changed to take a `BufView` instead of a `ZeroCopyBuf` as an argument. This allows for less copying of data in certain scenarios, as described above. Additionally a new `Resource::write_all` method has been added that takes a `BufView` and continually attempts to write the resource until the entire buffer has been written. Certain resources like files can override this method to provide a more efficient `write_all` implementation.
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deno_core::impl_readable_byob!();
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fn name(&self) -> Cow<str> {
"CacheResponseResource".into()
}
}
pub fn hash(token: &str) -> String {
use sha2::Digest;
format!("{:x}", sha2::Sha256::digest(token.as_bytes()))
}