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// Copyright 2024 Cloudflare, Inc.
//
// Licensed under the Apache License, Version 2.0 (the "License");
// you may not use this file except in compliance with the License.
// You may obtain a copy of the License at
//
// http://www.apache.org/licenses/LICENSE-2.0
//
// Unless required by applicable law or agreed to in writing, software
// distributed under the License is distributed on an "AS IS" BASIS,
// WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied.
// See the License for the specific language governing permissions and
// limitations under the License.
//! Cache key
use super::*;
use blake2::{Blake2b, Digest};
use serde::{Deserialize, Serialize};
// 16-byte / 128-bit key: large enough to avoid collision
const KEY_SIZE: usize = 16;
/// An 128 bit hash binary
pub type HashBinary = [u8; KEY_SIZE];
fn hex2str(hex: &[u8]) -> String {
use std::fmt::Write;
let mut s = String::with_capacity(KEY_SIZE * 2);
for c in hex {
write!(s, "{:02x}", c).unwrap(); // safe, just dump hex to string
}
s
}
/// Decode the hex str into [HashBinary].
///
/// Return `None` when the decode fails or the input is not exact 32 (to decode to 16 bytes).
pub fn str2hex(s: &str) -> Option<HashBinary> {
if s.len() != KEY_SIZE * 2 {
return None;
}
let mut output = [0; KEY_SIZE];
// no need to bubble the error, it should be obvious why the decode fails
hex::decode_to_slice(s.as_bytes(), &mut output).ok()?;
Some(output)
}
/// The trait for cache key
pub trait CacheHashKey {
/// Return the hash of the cache key
fn primary_bin(&self) -> HashBinary;
/// Return the variance hash of the cache key.
///
/// `None` if no variance.
fn variance_bin(&self) -> Option<HashBinary>;
/// Return the hash including both primary and variance keys
fn combined_bin(&self) -> HashBinary {
let key = self.primary_bin();
if let Some(v) = self.variance_bin() {
let mut hasher = Blake2b128::new();
hasher.update(key);
hasher.update(v);
hasher.finalize().into()
} else {
// if there is no variance, combined_bin should return the same as primary_bin
key
}
}
/// An extra tag for identifying users
///
/// For example, if the storage backend implements per user quota, this tag can be used.
fn user_tag(&self) -> &str;
/// The hex string of [Self::primary_bin()]
fn primary(&self) -> String {
hex2str(&self.primary_bin())
}
/// The hex string of [Self::variance_bin()]
fn variance(&self) -> Option<String> {
self.variance_bin().as_ref().map(|b| hex2str(&b[..]))
}
/// The hex string of [Self::combined_bin()]
fn combined(&self) -> String {
hex2str(&self.combined_bin())
}
}
/// General purpose cache key
#[derive(Debug, Clone)]
pub struct CacheKey {
// All strings for now. It can be more structural as long as it can hash
namespace: String,
primary: String,
primary_bin_override: Option<HashBinary>,
variance: Option<HashBinary>,
/// An extra tag for identifying users
///
/// For example, if the storage backend implements per user quota, this tag can be used.
pub user_tag: String,
}
impl CacheKey {
/// Set the value of the variance hash
pub fn set_variance_key(&mut self, key: HashBinary) {
self.variance = Some(key)
}
/// Get the value of the variance hash
pub fn get_variance_key(&self) -> Option<&HashBinary> {
self.variance.as_ref()
}
/// Removes the variance from this cache key
pub fn remove_variance_key(&mut self) {
self.variance = None
}
/// Override the primary key hash
pub fn set_primary_bin_override(&mut self, key: HashBinary) {
self.primary_bin_override = Some(key)
}
}
/// Storage optimized cache key to keep in memory or in storage
// 16 bytes + 8 bytes (+16 * u8) + user_tag.len() + 16 Bytes (Box<str>)
#[derive(Debug, Deserialize, Serialize, Clone, Hash, PartialEq, Eq, PartialOrd, Ord)]
pub struct CompactCacheKey {
pub primary: HashBinary,
// save 8 bytes for non-variance but waste 8 bytes for variance vs, store flat 16 bytes
pub variance: Option<Box<HashBinary>>,
pub user_tag: Box<str>, // the len should be small to keep memory usage bounded
}
impl CacheHashKey for CompactCacheKey {
fn primary_bin(&self) -> HashBinary {
self.primary
}
fn variance_bin(&self) -> Option<HashBinary> {
self.variance.as_ref().map(|s| *s.as_ref())
}
fn user_tag(&self) -> &str {
&self.user_tag
}
}
/*
* We use blake2 hashing, which is faster and more secure, to replace md5.
* We have not given too much thought on whether non-crypto hash can be safely
* use because hashing performance is not critical.
* Note: we should avoid hashes like ahash which does not have consistent output
* across machines because it is designed purely for in memory hashtable
*/
// hash output: we use 128 bits (16 bytes) hash which will map to 32 bytes hex string
pub(crate) type Blake2b128 = Blake2b<blake2::digest::consts::U16>;
/// helper function: hash str to u8
pub fn hash_u8(key: &str) -> u8 {
let mut hasher = Blake2b128::new();
hasher.update(key);
let raw = hasher.finalize();
raw[0]
}
/// helper function: hash str to [HashBinary]
pub fn hash_key(key: &str) -> HashBinary {
let mut hasher = Blake2b128::new();
hasher.update(key);
let raw = hasher.finalize();
raw.into()
}
impl CacheKey {
fn primary_hasher(&self) -> Blake2b128 {
let mut hasher = Blake2b128::new();
hasher.update(&self.namespace);
hasher.update(&self.primary);
hasher
}
/// Create a default [CacheKey] from a request, which just takes it URI as the primary key.
pub fn default(req_header: &ReqHeader) -> Self {
CacheKey {
namespace: "".into(),
primary: format!("{}", req_header.uri),
primary_bin_override: None,
variance: None,
user_tag: "".into(),
}
}
/// Create a new [CacheKey] from the given namespace, primary, and user_tag string.
///
/// Both `namespace` and `primary` will be used for the primary hash
pub fn new<S1, S2, S3>(namespace: S1, primary: S2, user_tag: S3) -> Self
where
S1: Into<String>,
S2: Into<String>,
S3: Into<String>,
{
CacheKey {
namespace: namespace.into(),
primary: primary.into(),
primary_bin_override: None,
variance: None,
user_tag: user_tag.into(),
}
}
/// Return the namespace of this key
pub fn namespace(&self) -> &str {
&self.namespace
}
/// Return the primary key of this key
pub fn primary_key(&self) -> &str {
&self.primary
}
/// Convert this key to [CompactCacheKey].
pub fn to_compact(&self) -> CompactCacheKey {
let primary = self.primary_bin();
CompactCacheKey {
primary,
variance: self.variance_bin().map(Box::new),
user_tag: self.user_tag.clone().into_boxed_str(),
}
}
}
impl CacheHashKey for CacheKey {
fn primary_bin(&self) -> HashBinary {
if let Some(primary_bin_override) = self.primary_bin_override {
primary_bin_override
} else {
self.primary_hasher().finalize().into()
}
}
fn variance_bin(&self) -> Option<HashBinary> {
self.variance
}
fn user_tag(&self) -> &str {
&self.user_tag
}
}
#[cfg(test)]
mod tests {
use super::*;
#[test]
fn test_cache_key_hash() {
let key = CacheKey {
namespace: "".into(),
primary: "aa".into(),
primary_bin_override: None,
variance: None,
user_tag: "1".into(),
};
let hash = key.primary();
assert_eq!(hash, "ac10f2aef117729f8dad056b3059eb7e");
assert!(key.variance().is_none());
assert_eq!(key.combined(), hash);
let compact = key.to_compact();
assert_eq!(compact.primary(), hash);
assert!(compact.variance().is_none());
assert_eq!(compact.combined(), hash);
}
#[test]
fn test_cache_key_hash_override() {
let mut key = CacheKey {
namespace: "".into(),
primary: "aa".into(),
primary_bin_override: str2hex("27c35e6e9373877f29e562464e46497e"),
variance: None,
user_tag: "1".into(),
};
let hash = key.primary();
assert_eq!(hash, "27c35e6e9373877f29e562464e46497e");
assert!(key.variance().is_none());
assert_eq!(key.combined(), hash);
let compact = key.to_compact();
assert_eq!(compact.primary(), hash);
assert!(compact.variance().is_none());
assert_eq!(compact.combined(), hash);
// make sure set_primary_bin_override overrides the primary key hash correctly
key.set_primary_bin_override(str2hex("004174d3e75a811a5b44c46b3856f3ee").unwrap());
let hash = key.primary();
assert_eq!(hash, "004174d3e75a811a5b44c46b3856f3ee");
assert!(key.variance().is_none());
assert_eq!(key.combined(), hash);
let compact = key.to_compact();
assert_eq!(compact.primary(), hash);
assert!(compact.variance().is_none());
assert_eq!(compact.combined(), hash);
}
#[test]
fn test_cache_key_vary_hash() {
let key = CacheKey {
namespace: "".into(),
primary: "aa".into(),
primary_bin_override: None,
variance: Some([0u8; 16]),
user_tag: "1".into(),
};
let hash = key.primary();
assert_eq!(hash, "ac10f2aef117729f8dad056b3059eb7e");
assert_eq!(key.variance().unwrap(), "00000000000000000000000000000000");
assert_eq!(key.combined(), "004174d3e75a811a5b44c46b3856f3ee");
let compact = key.to_compact();
assert_eq!(compact.primary(), "ac10f2aef117729f8dad056b3059eb7e");
assert_eq!(
compact.variance().unwrap(),
"00000000000000000000000000000000"
);
assert_eq!(compact.combined(), "004174d3e75a811a5b44c46b3856f3ee");
}
#[test]
fn test_cache_key_vary_hash_override() {
let key = CacheKey {
namespace: "".into(),
primary: "saaaad".into(),
primary_bin_override: str2hex("ac10f2aef117729f8dad056b3059eb7e"),
variance: Some([0u8; 16]),
user_tag: "1".into(),
};
let hash = key.primary();
assert_eq!(hash, "ac10f2aef117729f8dad056b3059eb7e");
assert_eq!(key.variance().unwrap(), "00000000000000000000000000000000");
assert_eq!(key.combined(), "004174d3e75a811a5b44c46b3856f3ee");
let compact = key.to_compact();
assert_eq!(compact.primary(), "ac10f2aef117729f8dad056b3059eb7e");
assert_eq!(
compact.variance().unwrap(),
"00000000000000000000000000000000"
);
assert_eq!(compact.combined(), "004174d3e75a811a5b44c46b3856f3ee");
}
#[test]
fn test_hex_str() {
let mut key = [0; KEY_SIZE];
for (i, v) in key.iter_mut().enumerate() {
// key: [0, 1, 2, .., 15]
*v = i as u8;
}
let hex_str = hex2str(&key);
let key2 = str2hex(&hex_str).unwrap();
for i in 0..KEY_SIZE {
assert_eq!(key[i], key2[i]);
}
}
}
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