// Copyright 2018-2024 the Deno authors. All rights reserved. MIT license. use std::cell::RefCell; use std::collections::HashSet; use std::net::IpAddr; use std::net::Ipv4Addr; use std::net::Ipv6Addr; use std::net::SocketAddr; use deno_core::anyhow::anyhow; use deno_core::anyhow::bail; use deno_core::error::AnyError; use deno_core::op2; use deno_core::OpState; use ipnetwork::IpNetwork; use ipnetwork::Ipv4Network; use ipnetwork::Ipv6Network; use serde::Serialize; pub struct BlockListResource { blocklist: RefCell, } impl deno_core::GarbageCollected for BlockListResource {} #[derive(Serialize)] struct SocketAddressSerialization(String, String); #[op2(fast)] pub fn op_socket_address_parse( state: &mut OpState, #[string] addr: &str, #[smi] port: u16, #[string] family: &str, ) -> Result { let ip = addr.parse::()?; let parsed: SocketAddr = SocketAddr::new(ip, port); let parsed_ip_str = parsed.ip().to_string(); let family_correct = family.eq_ignore_ascii_case("ipv4") && parsed.is_ipv4() || family.eq_ignore_ascii_case("ipv6") && parsed.is_ipv6(); if family_correct { let family_is_lowercase = family[..3].chars().all(char::is_lowercase); if family_is_lowercase && parsed_ip_str == addr { Ok(true) } else { state.put::(SocketAddressSerialization( parsed_ip_str, family.to_lowercase(), )); Ok(false) } } else { Err(anyhow!("Invalid address")) } } #[op2] #[serde] pub fn op_socket_address_get_serialization( state: &mut OpState, ) -> Result { Ok(state.take::()) } #[op2] #[cppgc] pub fn op_blocklist_new() -> BlockListResource { let blocklist = BlockList::new(); BlockListResource { blocklist: RefCell::new(blocklist), } } #[op2(fast)] pub fn op_blocklist_add_address( #[cppgc] wrap: &BlockListResource, #[string] addr: &str, ) -> Result<(), AnyError> { wrap.blocklist.borrow_mut().add_address(addr) } #[op2(fast)] pub fn op_blocklist_add_range( #[cppgc] wrap: &BlockListResource, #[string] start: &str, #[string] end: &str, ) -> Result { wrap.blocklist.borrow_mut().add_range(start, end) } #[op2(fast)] pub fn op_blocklist_add_subnet( #[cppgc] wrap: &BlockListResource, #[string] addr: &str, #[smi] prefix: u8, ) -> Result<(), AnyError> { wrap.blocklist.borrow_mut().add_subnet(addr, prefix) } #[op2(fast)] pub fn op_blocklist_check( #[cppgc] wrap: &BlockListResource, #[string] addr: &str, #[string] r#type: &str, ) -> Result { wrap.blocklist.borrow().check(addr, r#type) } struct BlockList { rules: HashSet, } impl BlockList { pub fn new() -> Self { BlockList { rules: HashSet::new(), } } fn map_addr_add_network( &mut self, addr: IpAddr, prefix: Option, ) -> Result<(), AnyError> { match addr { IpAddr::V4(addr) => { let ipv4_prefix = prefix.unwrap_or(32); self .rules .insert(IpNetwork::V4(Ipv4Network::new(addr, ipv4_prefix)?)); let ipv6_mapped = addr.to_ipv6_mapped(); let ipv6_prefix = 96 + ipv4_prefix; // IPv4-mapped IPv6 address prefix starts at 96 self .rules .insert(IpNetwork::V6(Ipv6Network::new(ipv6_mapped, ipv6_prefix)?)); } IpAddr::V6(addr) => { if let Some(ipv4_mapped) = addr.to_ipv4_mapped() { let ipv4_prefix = prefix.map(|v| v.clamp(96, 128) - 96).unwrap_or(32); self .rules .insert(IpNetwork::V4(Ipv4Network::new(ipv4_mapped, ipv4_prefix)?)); } let ipv6_prefix = prefix.unwrap_or(128); self .rules .insert(IpNetwork::V6(Ipv6Network::new(addr, ipv6_prefix)?)); } }; Ok(()) } pub fn add_address(&mut self, address: &str) -> Result<(), AnyError> { let ip: IpAddr = address.parse()?; self.map_addr_add_network(ip, None)?; Ok(()) } pub fn add_range( &mut self, start: &str, end: &str, ) -> Result { let start_ip: IpAddr = start.parse()?; let end_ip: IpAddr = end.parse()?; match (start_ip, end_ip) { (IpAddr::V4(start), IpAddr::V4(end)) => { let start_u32: u32 = start.into(); let end_u32: u32 = end.into(); if end_u32 < start_u32 { // Indicates invalid range. return Ok(false); } for ip in start_u32..=end_u32 { let addr: Ipv4Addr = ip.into(); self.map_addr_add_network(IpAddr::V4(addr), None)?; } } (IpAddr::V6(start), IpAddr::V6(end)) => { let start_u128: u128 = start.into(); let end_u128: u128 = end.into(); if end_u128 < start_u128 { // Indicates invalid range. return Ok(false); } for ip in start_u128..=end_u128 { let addr: Ipv6Addr = ip.into(); self.map_addr_add_network(IpAddr::V6(addr), None)?; } } _ => bail!("IP version mismatch between start and end addresses"), } Ok(true) } pub fn add_subnet(&mut self, addr: &str, prefix: u8) -> Result<(), AnyError> { let ip: IpAddr = addr.parse()?; self.map_addr_add_network(ip, Some(prefix))?; Ok(()) } pub fn check(&self, addr: &str, r#type: &str) -> Result { let addr: IpAddr = addr.parse()?; let family = r#type.to_lowercase(); if family == "ipv4" && addr.is_ipv4() || family == "ipv6" && addr.is_ipv6() { Ok(self.rules.iter().any(|net| net.contains(addr))) } else { Err(anyhow!("Invalid address")) } } } #[cfg(test)] mod tests { use super::*; #[test] fn test_add_address() { // Single IPv4 address let mut block_list = BlockList::new(); block_list.add_address("192.168.0.1").unwrap(); assert!(block_list.check("192.168.0.1", "ipv4").unwrap()); assert!(block_list.check("::ffff:c0a8:1", "ipv6").unwrap()); // Single IPv6 address let mut block_list = BlockList::new(); block_list.add_address("2001:db8::1").unwrap(); assert!(block_list.check("2001:db8::1", "ipv6").unwrap()); assert!(!block_list.check("192.168.0.1", "ipv4").unwrap()); } #[test] fn test_add_range() { // IPv4 range let mut block_list = BlockList::new(); block_list.add_range("192.168.0.1", "192.168.0.3").unwrap(); assert!(block_list.check("192.168.0.1", "ipv4").unwrap()); assert!(block_list.check("192.168.0.2", "ipv4").unwrap()); assert!(block_list.check("192.168.0.3", "ipv4").unwrap()); assert!(block_list.check("::ffff:c0a8:1", "ipv6").unwrap()); // IPv6 range let mut block_list = BlockList::new(); block_list.add_range("2001:db8::1", "2001:db8::3").unwrap(); assert!(block_list.check("2001:db8::1", "ipv6").unwrap()); assert!(block_list.check("2001:db8::2", "ipv6").unwrap()); assert!(block_list.check("2001:db8::3", "ipv6").unwrap()); assert!(!block_list.check("192.168.0.1", "ipv4").unwrap()); } #[test] fn test_add_subnet() { // IPv4 subnet let mut block_list = BlockList::new(); block_list.add_subnet("192.168.0.0", 24).unwrap(); assert!(block_list.check("192.168.0.1", "ipv4").unwrap()); assert!(block_list.check("192.168.0.255", "ipv4").unwrap()); assert!(block_list.check("::ffff:c0a8:0", "ipv6").unwrap()); // IPv6 subnet let mut block_list = BlockList::new(); block_list.add_subnet("2001:db8::", 64).unwrap(); block_list.add_subnet("::ffff:127.0.0.1", 128).unwrap(); assert!(block_list.check("2001:db8::1", "ipv6").unwrap()); assert!(block_list.check("2001:db8::ffff", "ipv6").unwrap()); assert!(!block_list.check("192.168.0.1", "ipv4").unwrap()); // Check host addresses of IPv4 mapped IPv6 address let mut block_list = BlockList::new(); block_list.add_subnet("1.1.1.0", 30).unwrap(); assert!(block_list.check("::ffff:1.1.1.1", "ipv6").unwrap()); assert!(!block_list.check("::ffff:1.1.1.4", "ipv6").unwrap()); } #[test] fn test_check() { // Check IPv4 presence let mut block_list = BlockList::new(); block_list.add_address("192.168.0.1").unwrap(); assert!(block_list.check("192.168.0.1", "ipv4").unwrap()); // Check IPv6 presence let mut block_list = BlockList::new(); block_list.add_address("2001:db8::1").unwrap(); assert!(block_list.check("2001:db8::1", "ipv6").unwrap()); // Check IPv4 not present let block_list = BlockList::new(); assert!(!block_list.check("192.168.0.1", "ipv4").unwrap()); // Check IPv6 not present let block_list = BlockList::new(); assert!(!block_list.check("2001:db8::1", "ipv6").unwrap()); // Check invalid IP version let block_list = BlockList::new(); assert!(block_list.check("192.168.0.1", "ipv6").is_err()); // Check invalid type let mut block_list = BlockList::new(); block_list.add_address("192.168.0.1").unwrap(); assert!(block_list.check("192.168.0.1", "invalid_type").is_err()); } }