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mod.rs
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//! Access Control List (ACL) for shadowsocks
//!
//! This is for advance controlling server behaviors in both local and proxy servers.
use std::{
borrow::Cow,
collections::HashSet,
fmt,
fs::File,
io::{self, BufRead, BufReader, Error, ErrorKind},
net::{IpAddr, SocketAddr},
path::{Path, PathBuf},
str,
};
use ipnet::{IpNet, Ipv4Net, Ipv6Net};
use iprange::IpRange;
use log::{trace, warn};
use once_cell::sync::Lazy;
use regex::bytes::{Regex, RegexBuilder, RegexSet, RegexSetBuilder};
use shadowsocks::{context::Context, relay::socks5::Address};
use self::sub_domains_tree::SubDomainsTree;
mod sub_domains_tree;
/// Strategy mode that ACL is running
#[derive(Debug, Copy, Clone, Eq, PartialEq)]
pub enum Mode {
/// BlackList mode, rejects or bypasses all requests by default
BlackList,
/// WhiteList mode, accepts or proxies all requests by default
WhiteList,
}
#[derive(Clone)]
struct Rules {
ipv4: IpRange<Ipv4Net>,
ipv6: IpRange<Ipv6Net>,
rule_regex: RegexSet,
rule_set: HashSet<String>,
rule_tree: SubDomainsTree,
}
impl fmt::Debug for Rules {
fn fmt(&self, f: &mut fmt::Formatter) -> fmt::Result {
write!(
f,
"Rules {{ ipv4: {:?}, ipv6: {:?}, rule_regex: [",
self.ipv4, self.ipv6
)?;
let max_len = 2;
let has_more = self.rule_regex.len() > max_len;
for (idx, r) in self.rule_regex.patterns().iter().take(max_len).enumerate() {
if idx > 0 {
f.write_str(", ")?;
}
f.write_str(r)?;
}
if has_more {
f.write_str(", ...")?;
}
write!(f, "], rule_set: [")?;
let has_more = self.rule_set.len() > max_len;
for (idx, r) in self.rule_set.iter().take(max_len).enumerate() {
if idx > 0 {
f.write_str(", ")?;
}
f.write_str(r)?;
}
if has_more {
f.write_str(", ...")?;
}
write!(f, "], rule_tree: {:?} }}", self.rule_tree)
}
}
impl Rules {
/// Create a new rule
fn new(
mut ipv4: IpRange<Ipv4Net>,
mut ipv6: IpRange<Ipv6Net>,
rule_regex: RegexSet,
rule_set: HashSet<String>,
rule_tree: SubDomainsTree,
) -> Rules {
// Optimization, merging networks
ipv4.simplify();
ipv6.simplify();
Rules {
ipv4,
ipv6,
rule_regex,
rule_set,
rule_tree,
}
}
/// Check if the specified address matches these rules
#[allow(dead_code)]
fn check_address_matched(&self, addr: &Address) -> bool {
match *addr {
Address::SocketAddress(ref saddr) => self.check_ip_matched(&saddr.ip()),
Address::DomainNameAddress(ref domain, ..) => self.check_host_matched(domain),
}
}
/// Check if the specified address matches any rules
fn check_ip_matched(&self, addr: &IpAddr) -> bool {
match addr {
IpAddr::V4(v4) => {
if self.ipv4.contains(v4) {
return true;
}
let mapped_ipv6 = v4.to_ipv6_mapped();
self.ipv6.contains(&mapped_ipv6)
}
IpAddr::V6(v6) => {
if self.ipv6.contains(v6) {
return true;
}
if let Some(mapped_ipv4) = v6.to_ipv4_mapped() {
return self.ipv4.contains(&mapped_ipv4);
}
false
}
}
}
/// Check if the specified ASCII host matches any rules
fn check_host_matched(&self, host: &str) -> bool {
let host = host.trim_end_matches('.'); // FQDN, removes the last `.`
self.rule_set.contains(host) || self.rule_tree.contains(host) || self.rule_regex.is_match(host.as_bytes())
}
/// Check if there are no rules for IP addresses
fn is_ip_empty(&self) -> bool {
self.ipv4.is_empty() && self.ipv6.is_empty()
}
/// Check if there are no rules for domain names
fn is_host_empty(&self) -> bool {
self.rule_set.is_empty() && self.rule_tree.is_empty() && self.rule_regex.is_empty()
}
}
struct ParsingRules {
name: &'static str,
ipv4: IpRange<Ipv4Net>,
ipv6: IpRange<Ipv6Net>,
rules_regex: Vec<String>,
rules_set: HashSet<String>,
rules_tree: SubDomainsTree,
}
impl ParsingRules {
fn new(name: &'static str) -> Self {
ParsingRules {
name,
ipv4: IpRange::new(),
ipv6: IpRange::new(),
rules_regex: Vec::new(),
rules_set: HashSet::new(),
rules_tree: SubDomainsTree::new(),
}
}
fn add_ipv4_rule(&mut self, rule: impl Into<Ipv4Net>) {
let rule = rule.into();
trace!("IPV4-RULE {}", rule);
self.ipv4.add(rule);
}
fn add_ipv6_rule(&mut self, rule: impl Into<Ipv6Net>) {
let rule = rule.into();
trace!("IPV6-RULE {}", rule);
self.ipv6.add(rule);
}
fn add_regex_rule(&mut self, mut rule: String) {
static TREE_SET_RULE_EQUIV: Lazy<Regex> = Lazy::new(|| {
RegexBuilder::new(
r#"^(?:(?:\((?:\?:)?\^\|\\\.\)|(?:\^\.(?:\+|\*))?\\\.)((?:[\w-]+(?:\\\.)?)+)|\^((?:[\w-]+(?:\\\.)?)+))\$?$"#,
)
.unicode(false)
.build()
.unwrap()
});
if let Some(caps) = TREE_SET_RULE_EQUIV.captures(rule.as_bytes()) {
if let Some(tree_rule) = caps.get(1) {
if let Ok(tree_rule) = str::from_utf8(tree_rule.as_bytes()) {
let tree_rule = tree_rule.replace("\\.", ".");
if self.add_tree_rule_inner(&tree_rule).is_ok() {
trace!("REGEX-RULE {} => TREE-RULE {}", rule, tree_rule);
return;
}
}
} else if let Some(set_rule) = caps.get(2) {
if let Ok(set_rule) = str::from_utf8(set_rule.as_bytes()) {
let set_rule = set_rule.replace("\\.", ".");
if self.add_set_rule_inner(&set_rule).is_ok() {
trace!("REGEX-RULE {} => SET-RULE {}", rule, set_rule);
return;
}
}
}
}
trace!("REGEX-RULE {}", rule);
rule.make_ascii_lowercase();
// Handle it as a normal REGEX
// FIXME: If this line is not a valid regex, how can we know without actually compile it?
self.rules_regex.push(rule);
}
#[inline]
fn add_set_rule(&mut self, rule: &str) -> io::Result<()> {
trace!("SET-RULE {}", rule);
self.add_set_rule_inner(rule)
}
fn add_set_rule_inner(&mut self, rule: &str) -> io::Result<()> {
self.rules_set.insert(self.check_is_ascii(rule)?.to_ascii_lowercase());
Ok(())
}
#[inline]
fn add_tree_rule(&mut self, rule: &str) -> io::Result<()> {
trace!("TREE-RULE {}", rule);
self.add_tree_rule_inner(rule)
}
fn add_tree_rule_inner(&mut self, rule: &str) -> io::Result<()> {
// SubDomainsTree do lowercase conversion inside insert
self.rules_tree.insert(self.check_is_ascii(rule)?);
Ok(())
}
fn check_is_ascii<'a>(&self, str: &'a str) -> io::Result<&'a str> {
if str.is_ascii() {
// Remove the last `.` of FQDN
Ok(str.trim_end_matches('.'))
} else {
Err(Error::new(
ErrorKind::Other,
format!("{} parsing error: Unicode not allowed here `{}`", self.name, str),
))
}
}
fn compile_regex(name: &'static str, regex_rules: Vec<String>) -> io::Result<RegexSet> {
const REGEX_SIZE_LIMIT: usize = usize::MAX;
RegexSetBuilder::new(regex_rules)
.size_limit(REGEX_SIZE_LIMIT)
.unicode(false)
.build()
.map_err(|err| Error::new(ErrorKind::Other, format!("{name} regex error: {err}")))
}
fn into_rules(self) -> io::Result<Rules> {
Ok(Rules::new(
self.ipv4,
self.ipv6,
Self::compile_regex(self.name, self.rules_regex)?,
self.rules_set,
self.rules_tree,
))
}
}
/// ACL rules
///
/// ## Sections
///
/// ACL File is formatted in sections, each section has a name with surrounded by brackets `[` and `]`
/// followed by Rules line by line.
///
/// ```plain
/// [SECTION-1]
/// RULE-1
/// RULE-2
/// RULE-3
///
/// [SECTION-2]
/// RULE-1
/// RULE-2
/// RULE-3
/// ```
///
/// Available sections are
///
/// - For local servers (`sslocal`, `ssredir`, ...)
/// * `[bypass_all]` - ACL runs in `BlackList` mode.
/// * `[proxy_all]` - ACL runs in `WhiteList` mode.
/// * `[bypass_list]` - Rules for connecting directly
/// * `[proxy_list]` - Rules for connecting through proxies
/// - For remote servers (`ssserver`)
/// * `[reject_all]` - ACL runs in `BlackList` mode.
/// * `[accept_all]` - ACL runs in `WhiteList` mode.
/// * `[black_list]` - Rules for rejecting
/// * `[white_list]` - Rules for allowing
/// * `[outbound_block_list]` - Rules for blocking outbound addresses.
///
/// ## Mode
///
/// Mode is the default ACL strategy for those addresses that are not in configuration file.
///
/// - `BlackList` - Bypasses / Rejects all addresses except those in `[proxy_list]` or `[white_list]`
/// - `WhiteList` - Proxies / Accepts all addresses except those in `[bypass_list]` or `[black_list]`
///
/// ## Rules
///
/// Rules can be either
///
/// - CIDR form network addresses, like `10.9.0.32/16`
/// - IP addresses, like `127.0.0.1` or `::1`
/// - Regular Expression for matching hosts, like `(^|\.)gmail\.com$`
/// - Domain with preceding `|` for exact matching, like `|google.com`
/// - Domain with preceding `||` for matching with subdomains, like `||google.com`
#[derive(Debug, Clone)]
pub struct AccessControl {
outbound_block: Rules,
black_list: Rules,
white_list: Rules,
mode: Mode,
file_path: PathBuf,
}
impl AccessControl {
/// Load ACL rules from a file
pub fn load_from_file<P: AsRef<Path>>(p: P) -> io::Result<AccessControl> {
trace!("ACL loading from {:?}", p.as_ref());
let file_path_ref = p.as_ref();
let file_path = file_path_ref.to_path_buf();
let fp = File::open(file_path_ref)?;
let r = BufReader::new(fp);
let mut mode = Mode::BlackList;
let mut outbound_block = ParsingRules::new("[outbound_block_list]");
let mut bypass = ParsingRules::new("[black_list] or [bypass_list]");
let mut proxy = ParsingRules::new("[white_list] or [proxy_list]");
let mut curr = &mut bypass;
trace!("ACL parsing start from mode {:?} and black_list / bypass_list", mode);
for line in r.lines() {
let line = line?;
if line.is_empty() {
continue;
}
// Comments
if line.starts_with('#') {
continue;
}
let line = line.trim();
if !line.is_ascii() {
warn!("ACL rule {} containing non-ASCII characters, skipped", line);
continue;
}
if let Some(rule) = line.strip_prefix("||") {
curr.add_tree_rule(rule)?;
continue;
}
if let Some(rule) = line.strip_prefix('|') {
curr.add_set_rule(rule)?;
continue;
}
match line {
"[reject_all]" | "[bypass_all]" => {
mode = Mode::WhiteList;
trace!("switch to mode {:?}", mode);
}
"[accept_all]" | "[proxy_all]" => {
mode = Mode::BlackList;
trace!("switch to mode {:?}", mode);
}
"[outbound_block_list]" => {
curr = &mut outbound_block;
trace!("loading outbound_block_list");
}
"[black_list]" | "[bypass_list]" => {
curr = &mut bypass;
trace!("loading black_list / bypass_list");
}
"[white_list]" | "[proxy_list]" => {
curr = &mut proxy;
trace!("loading white_list / proxy_list");
}
_ => {
match line.parse::<IpNet>() {
Ok(IpNet::V4(v4)) => {
curr.add_ipv4_rule(v4);
}
Ok(IpNet::V6(v6)) => {
curr.add_ipv6_rule(v6);
}
Err(..) => {
// Maybe it is a pure IpAddr
match line.parse::<IpAddr>() {
Ok(IpAddr::V4(v4)) => {
curr.add_ipv4_rule(v4);
}
Ok(IpAddr::V6(v6)) => {
curr.add_ipv6_rule(v6);
}
Err(..) => {
curr.add_regex_rule(line.to_owned());
}
}
}
}
}
}
}
Ok(AccessControl {
outbound_block: outbound_block.into_rules()?,
black_list: bypass.into_rules()?,
white_list: proxy.into_rules()?,
mode,
file_path,
})
}
/// Get ACL file path
pub fn file_path(&self) -> &Path {
&self.file_path
}
/// Check if domain name is in proxy_list.
/// If so, it should be resolved from remote (for Android's DNS relay)
///
/// Return
/// - `Some(true)` if `host` is in `white_list` (should be proxied)
/// - `Some(false)` if `host` is in `black_list` (should be bypassed)
/// - `None` if `host` doesn't match any rules
pub fn check_host_in_proxy_list(&self, host: &str) -> Option<bool> {
let host = Self::convert_to_ascii(host);
self.check_ascii_host_in_proxy_list(&host)
}
/// Check if ASCII domain name is in proxy_list.
/// If so, it should be resolved from remote (for Android's DNS relay)
///
/// Return
/// - `Some(true)` if `host` is in `white_list` (should be proxied)
/// - `Some(false)` if `host` is in `black_list` (should be bypassed)
/// - `None` if `host` doesn't match any rules
pub fn check_ascii_host_in_proxy_list(&self, host: &str) -> Option<bool> {
// Addresses in proxy_list will be proxied
if self.white_list.check_host_matched(host) {
return Some(true);
}
// Addresses in bypass_list will be bypassed
if self.black_list.check_host_matched(host) {
return Some(false);
}
None
}
/// If there are no IP rules
pub fn is_ip_empty(&self) -> bool {
match self.mode {
Mode::BlackList => self.black_list.is_ip_empty(),
Mode::WhiteList => self.white_list.is_ip_empty(),
}
}
/// If there are no domain name rules
pub fn is_host_empty(&self) -> bool {
self.black_list.is_host_empty() && self.white_list.is_host_empty()
}
/// Check if `IpAddr` should be proxied
pub fn check_ip_in_proxy_list(&self, ip: &IpAddr) -> bool {
match self.mode {
Mode::BlackList => !self.black_list.check_ip_matched(ip),
Mode::WhiteList => self.white_list.check_ip_matched(ip),
}
}
/// Default mode
///
/// Default behavior for hosts that are not configured
/// - `true` - Proxied
/// - `false` - Bypassed
pub fn is_default_in_proxy_list(&self) -> bool {
match self.mode {
Mode::BlackList => true,
Mode::WhiteList => false,
}
}
/// Returns the ASCII representation a domain name,
/// if conversion fails returns original string
fn convert_to_ascii(host: &str) -> Cow<str> {
idna::domain_to_ascii(host)
.map(From::from)
.unwrap_or_else(|_| host.into())
}
/// Check if target address should be bypassed (for client)
///
/// This function may perform a DNS resolution
pub async fn check_target_bypassed(&self, context: &Context, addr: &Address) -> bool {
match *addr {
Address::SocketAddress(ref addr) => !self.check_ip_in_proxy_list(&addr.ip()),
// Resolve hostname and check the list
Address::DomainNameAddress(ref host, port) => {
if let Some(value) = self.check_host_in_proxy_list(host) {
return !value;
}
if self.is_ip_empty() {
return !self.is_default_in_proxy_list();
}
if let Ok(vaddr) = context.dns_resolve(host, port).await {
for addr in vaddr {
if !self.check_ip_in_proxy_list(&addr.ip()) {
return true;
}
}
}
false
}
}
}
/// Check if client address should be blocked (for server)
pub fn check_client_blocked(&self, addr: &SocketAddr) -> bool {
match self.mode {
Mode::BlackList => {
// Only clients in black_list will be blocked
self.black_list.check_ip_matched(&addr.ip())
}
Mode::WhiteList => {
// Only clients in white_list will be proxied
!self.white_list.check_ip_matched(&addr.ip())
}
}
}
/// Check if outbound address is blocked (for server)
///
/// NOTE: `Address::DomainName` is only validated by regex rules,
/// resolved addresses are checked in the `lookup_outbound_then!` macro
pub async fn check_outbound_blocked(&self, context: &Context, outbound: &Address) -> bool {
match outbound {
Address::SocketAddress(saddr) => self.outbound_block.check_ip_matched(&saddr.ip()),
Address::DomainNameAddress(host, port) => {
if self.outbound_block.check_host_matched(&Self::convert_to_ascii(host)) {
return true;
}
if let Ok(vaddr) = context.dns_resolve(host, *port).await {
for addr in vaddr {
if self.outbound_block.check_ip_matched(&addr.ip()) {
return true;
}
}
}
false
}
}
}
}