//! End-to-end encryption support. use anyhow::{format_err, Context as _, Result}; use num_traits::FromPrimitive; use crate::aheader::{Aheader, EncryptPreference}; use crate::config::Config; use crate::context::Context; use crate::key::{load_self_public_key, load_self_secret_key, SignedPublicKey}; use crate::peerstate::Peerstate; use crate::pgp; #[derive(Debug)] pub struct EncryptHelper { pub prefer_encrypt: EncryptPreference, pub addr: String, pub public_key: SignedPublicKey, } impl EncryptHelper { pub async fn new(context: &Context) -> Result { let prefer_encrypt = EncryptPreference::from_i32(context.get_config_int(Config::E2eeEnabled).await?) .unwrap_or_default(); let addr = context.get_primary_self_addr().await?; let public_key = load_self_public_key(context).await?; Ok(EncryptHelper { prefer_encrypt, addr, public_key, }) } pub fn get_aheader(&self) -> Aheader { let pk = self.public_key.clone(); let addr = self.addr.to_string(); Aheader::new(addr, pk, self.prefer_encrypt) } /// Determines if we can and should encrypt. /// /// `e2ee_guaranteed` should be set to true for replies to encrypted messages (as required by /// Autocrypt Level 1, version 1.1) and for messages sent in protected groups. /// /// Returns an error if `e2ee_guaranteed` is true, but one or more keys are missing. pub(crate) async fn should_encrypt( &self, context: &Context, e2ee_guaranteed: bool, peerstates: &[(Option, String)], ) -> Result { let is_chatmail = context.is_chatmail().await?; let mut prefer_encrypt_count = if self.prefer_encrypt == EncryptPreference::Mutual { 1 } else { 0 }; for (peerstate, addr) in peerstates { match peerstate { Some(peerstate) => { let prefer_encrypt = peerstate.prefer_encrypt; info!(context, "Peerstate for {addr:?} is {prefer_encrypt}."); if match peerstate.prefer_encrypt { EncryptPreference::NoPreference | EncryptPreference::Reset => { (peerstate.prefer_encrypt != EncryptPreference::Reset || is_chatmail) && self.prefer_encrypt == EncryptPreference::Mutual } EncryptPreference::Mutual => true, } { prefer_encrypt_count += 1; } } None => { let msg = format!("Peerstate for {addr:?} missing, cannot encrypt"); if e2ee_guaranteed { return Err(format_err!("{msg}")); } else { info!(context, "{msg}."); return Ok(false); } } } } // Count number of recipients, including self. // This does not depend on whether we send a copy to self or not. let recipients_count = peerstates.len() + 1; Ok(e2ee_guaranteed || 2 * prefer_encrypt_count > recipients_count) } /// Tries to encrypt the passed in `mail`. pub async fn encrypt( self, context: &Context, verified: bool, mail_to_encrypt: lettre_email::PartBuilder, peerstates: Vec<(Option, String)>, compress: bool, ) -> Result { let mut keyring: Vec = Vec::new(); let mut verifier_addresses: Vec<&str> = Vec::new(); for (peerstate, addr) in peerstates .iter() .filter_map(|(state, addr)| state.clone().map(|s| (s, addr))) { let key = peerstate .take_key(verified) .with_context(|| format!("proper enc-key for {addr} missing, cannot encrypt"))?; keyring.push(key); verifier_addresses.push(addr); } // Encrypt to self. keyring.push(self.public_key.clone()); // Encrypt to secondary verified keys // if we also encrypt to the introducer ("verifier") of the key. if verified { for (peerstate, _addr) in &peerstates { if let Some(peerstate) = peerstate { if let (Some(key), Some(verifier)) = ( peerstate.secondary_verified_key.as_ref(), peerstate.secondary_verifier.as_deref(), ) { if verifier_addresses.contains(&verifier) { keyring.push(key.clone()); } } } } } let sign_key = load_self_secret_key(context).await?; let raw_message = mail_to_encrypt.build().as_string().into_bytes(); let ctext = pgp::pk_encrypt(&raw_message, keyring, Some(sign_key), compress).await?; Ok(ctext) } /// Signs the passed-in `mail` using the private key from `context`. /// Returns the payload and the signature. pub async fn sign( self, context: &Context, mail: lettre_email::PartBuilder, ) -> Result<(lettre_email::MimeMessage, String)> { let sign_key = load_self_secret_key(context).await?; let mime_message = mail.build(); let signature = pgp::pk_calc_signature(mime_message.as_string().as_bytes(), &sign_key)?; Ok((mime_message, signature)) } } /// Ensures a private key exists for the configured user. /// /// Normally the private key is generated when the first message is /// sent but in a few locations there are no such guarantees, /// e.g. when exporting keys, and calling this function ensures a /// private key will be present. // TODO, remove this once deltachat::key::Key no longer exists. pub async fn ensure_secret_key_exists(context: &Context) -> Result<()> { load_self_public_key(context).await?; Ok(()) } #[cfg(test)] mod tests { use super::*; use crate::chat::send_text_msg; use crate::key::DcKey; use crate::message::{Message, Viewtype}; use crate::param::Param; use crate::receive_imf::receive_imf; use crate::test_utils::{bob_keypair, TestContext, TestContextManager}; mod ensure_secret_key_exists { use super::*; #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn test_prexisting() { let t = TestContext::new_alice().await; assert!(ensure_secret_key_exists(&t).await.is_ok()); } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn test_not_configured() { let t = TestContext::new().await; assert!(ensure_secret_key_exists(&t).await.is_err()); } } #[test] fn test_mailmime_parse() { let plain = b"Chat-Disposition-Notification-To: hello@world.de Chat-Group-ID: CovhGgau8M- Chat-Group-Name: Delta Chat Dev Subject: =?utf-8?Q?Chat=3A?= Delta Chat =?utf-8?Q?Dev=3A?= sidenote for =?utf-8?Q?all=3A?= rust core master ... Content-Type: text/plain; charset=\"utf-8\"; protected-headers=\"v1\" Content-Transfer-Encoding: quoted-printable sidenote for all: things are trick atm recomm= end not to try to run with desktop or ios unless you are ready to hunt bugs -- =20 Sent with my Delta Chat Messenger: https://delta.chat"; let mail = mailparse::parse_mail(plain).expect("failed to parse valid message"); assert_eq!(mail.headers.len(), 6); assert!( mail.get_body().unwrap().starts_with( "sidenote for all: things are trick atm recommend not to try to run with desktop or ios unless you are ready to hunt bugs") ); } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn test_encrypted_no_autocrypt() -> anyhow::Result<()> { let mut tcm = TestContextManager::new(); let alice = tcm.alice().await; let bob = tcm.bob().await; let chat_alice = alice.create_chat(&bob).await.id; let chat_bob = bob.create_chat(&alice).await.id; // Alice sends unencrypted message to Bob let mut msg = Message::new(Viewtype::Text); let sent = alice.send_msg(chat_alice, &mut msg).await; // Bob receives unencrypted message from Alice let msg = bob.recv_msg(&sent).await; assert!(!msg.get_showpadlock()); let peerstate_alice = Peerstate::from_addr(&bob.ctx, "alice@example.org") .await? .expect("no peerstate found in the database"); assert_eq!(peerstate_alice.prefer_encrypt, EncryptPreference::Mutual); // Bob sends empty encrypted message to Alice let mut msg = Message::new(Viewtype::Text); let sent = bob.send_msg(chat_bob, &mut msg).await; // Alice receives an empty encrypted message from Bob. // This is also a regression test for previously existing bug // that resulted in no padlock on encrypted empty messages. let msg = alice.recv_msg(&sent).await; assert!(msg.get_showpadlock()); let peerstate_bob = Peerstate::from_addr(&alice.ctx, "bob@example.net") .await? .expect("no peerstate found in the database"); assert_eq!(peerstate_bob.prefer_encrypt, EncryptPreference::Mutual); // Now Alice and Bob have established keys. // Alice sends encrypted message without Autocrypt header. let mut msg = Message::new(Viewtype::Text); msg.param.set_int(Param::SkipAutocrypt, 1); let sent = alice.send_msg(chat_alice, &mut msg).await; let msg = bob.recv_msg(&sent).await; assert!(msg.get_showpadlock()); let peerstate_alice = Peerstate::from_addr(&bob.ctx, "alice@example.org") .await? .expect("no peerstate found in the database"); assert_eq!(peerstate_alice.prefer_encrypt, EncryptPreference::Mutual); // Alice sends plaintext message with Autocrypt header. let mut msg = Message::new(Viewtype::Text); msg.force_plaintext(); let sent = alice.send_msg(chat_alice, &mut msg).await; let msg = bob.recv_msg(&sent).await; assert!(!msg.get_showpadlock()); let peerstate_alice = Peerstate::from_addr(&bob.ctx, "alice@example.org") .await? .expect("no peerstate found in the database"); assert_eq!(peerstate_alice.prefer_encrypt, EncryptPreference::Mutual); // Alice sends plaintext message without Autocrypt header. let mut msg = Message::new(Viewtype::Text); msg.force_plaintext(); msg.param.set_int(Param::SkipAutocrypt, 1); let sent = alice.send_msg(chat_alice, &mut msg).await; let msg = bob.recv_msg(&sent).await; assert!(!msg.get_showpadlock()); let peerstate_alice = Peerstate::from_addr(&bob.ctx, "alice@example.org") .await? .expect("no peerstate found in the database"); assert_eq!(peerstate_alice.prefer_encrypt, EncryptPreference::Reset); Ok(()) } fn new_peerstates(prefer_encrypt: EncryptPreference) -> Vec<(Option, String)> { let addr = "bob@foo.bar"; let pub_key = bob_keypair().public; let peerstate = Peerstate { addr: addr.into(), last_seen: 13, last_seen_autocrypt: 14, prefer_encrypt, public_key: Some(pub_key.clone()), public_key_fingerprint: Some(pub_key.dc_fingerprint()), gossip_key: Some(pub_key.clone()), gossip_timestamp: 15, gossip_key_fingerprint: Some(pub_key.dc_fingerprint()), verified_key: Some(pub_key.clone()), verified_key_fingerprint: Some(pub_key.dc_fingerprint()), verifier: None, secondary_verified_key: None, secondary_verified_key_fingerprint: None, secondary_verifier: None, backward_verified_key_id: None, fingerprint_changed: false, }; vec![(Some(peerstate), addr.to_string())] } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn test_should_encrypt() -> Result<()> { let t = TestContext::new_alice().await; assert!(t.get_config_bool(Config::E2eeEnabled).await?); let encrypt_helper = EncryptHelper::new(&t).await.unwrap(); let ps = new_peerstates(EncryptPreference::NoPreference); assert!(encrypt_helper.should_encrypt(&t, true, &ps).await?); // Own preference is `Mutual` and we have the peer's key. assert!(encrypt_helper.should_encrypt(&t, false, &ps).await?); let ps = new_peerstates(EncryptPreference::Reset); assert!(encrypt_helper.should_encrypt(&t, true, &ps).await?); assert!(!encrypt_helper.should_encrypt(&t, false, &ps).await?); let ps = new_peerstates(EncryptPreference::Mutual); assert!(encrypt_helper.should_encrypt(&t, true, &ps).await?); assert!(encrypt_helper.should_encrypt(&t, false, &ps).await?); // test with missing peerstate let ps = vec![(None, "bob@foo.bar".to_string())]; assert!(encrypt_helper.should_encrypt(&t, true, &ps).await.is_err()); assert!(!encrypt_helper.should_encrypt(&t, false, &ps).await?); Ok(()) } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn test_should_encrypt_e2ee_disabled() -> Result<()> { let t = &TestContext::new_alice().await; t.set_config_bool(Config::E2eeEnabled, false).await?; let encrypt_helper = EncryptHelper::new(t).await.unwrap(); let ps = new_peerstates(EncryptPreference::NoPreference); assert!(!encrypt_helper.should_encrypt(t, false, &ps).await?); let ps = new_peerstates(EncryptPreference::Reset); assert!(encrypt_helper.should_encrypt(t, true, &ps).await?); let mut ps = new_peerstates(EncryptPreference::Mutual); // Own preference is `NoPreference` and there's no majority with `Mutual`. assert!(!encrypt_helper.should_encrypt(t, false, &ps).await?); // Now the majority wants to encrypt. Let's encrypt, anyway there are other cases when we // can't send unencrypted, e.g. protected groups. ps.push(ps[0].clone()); assert!(encrypt_helper.should_encrypt(t, false, &ps).await?); // Test with missing peerstate. let ps = vec![(None, "bob@foo.bar".to_string())]; assert!(encrypt_helper.should_encrypt(t, true, &ps).await.is_err()); Ok(()) } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn test_chatmail_prefers_to_encrypt() -> Result<()> { let mut tcm = TestContextManager::new(); let alice = &tcm.alice().await; let bob = &tcm.bob().await; bob.set_config_bool(Config::IsChatmail, true).await?; let bob_chat_id = tcm .send_recv_accept(alice, bob, "Hello from DC") .await .chat_id; receive_imf( bob, b"From: alice@example.org\n\ To: bob@example.net\n\ Message-ID: <2222@example.org>\n\ Date: Sun, 22 Mar 3000 22:37:58 +0000\n\ \n\ Hello from another MUA\n", false, ) .await?; send_text_msg(bob, bob_chat_id, "hi".to_string()).await?; let sent_msg = bob.pop_sent_msg().await; let msg = Message::load_from_db(bob, sent_msg.sender_msg_id).await?; assert!(msg.get_showpadlock()); Ok(()) } #[tokio::test(flavor = "multi_thread", worker_threads = 2)] async fn test_chatmail_can_send_unencrypted() -> Result<()> { let mut tcm = TestContextManager::new(); let bob = &tcm.bob().await; bob.set_config_bool(Config::IsChatmail, true).await?; let bob_chat_id = receive_imf( bob, b"From: alice@example.org\n\ To: bob@example.net\n\ Message-ID: <2222@example.org>\n\ Date: Sun, 22 Mar 3000 22:37:58 +0000\n\ \n\ Hello\n", false, ) .await? .unwrap() .chat_id; bob_chat_id.accept(bob).await?; send_text_msg(bob, bob_chat_id, "hi".to_string()).await?; let sent_msg = bob.pop_sent_msg().await; let msg = Message::load_from_db(bob, sent_msg.sender_msg_id).await?; assert!(!msg.get_showpadlock()); Ok(()) } }