use std::borrow::Cow; use std::num::NonZeroU32; use std::sync::Arc; use anyhow::{anyhow, bail, Error, Result}; use boitalettres::proto::res::body::Data as Body; use chrono::{Offset, TimeZone, Utc}; use futures::stream::{FuturesOrdered, StreamExt}; use imap_codec::types::address::Address; use imap_codec::types::body::{BasicFields, Body as FetchBody, BodyStructure, SpecificFields}; use imap_codec::types::core::{Atom, IString, NString}; use imap_codec::types::datetime::MyDateTime; use imap_codec::types::envelope::Envelope; use imap_codec::types::fetch_attributes::{FetchAttribute, MacroOrFetchAttributes}; use imap_codec::types::flag::{Flag, StoreResponse, StoreType}; use imap_codec::types::response::{Code, Data, MessageAttribute, Status}; use imap_codec::types::sequence::{self, SequenceSet}; use mail_parser::*; use crate::mail::mailbox::Mailbox; use crate::mail::uidindex::{ImapUid, ImapUidvalidity, UidIndex}; use crate::mail::unique_ident::UniqueIdent; const DEFAULT_FLAGS: [Flag; 5] = [ Flag::Seen, Flag::Answered, Flag::Flagged, Flag::Deleted, Flag::Draft, ]; /// A MailboxView is responsible for giving the client the information /// it needs about a mailbox, such as an initial summary of the mailbox's /// content and continuous updates indicating when the content /// of the mailbox has been changed. /// To do this, it keeps a variable `known_state` that corresponds to /// what the client knows, and produces IMAP messages to be sent to the /// client that go along updates to `known_state`. pub struct MailboxView { pub(crate) mailbox: Arc, known_state: UidIndex, } impl MailboxView { /// Creates a new IMAP view into a mailbox. /// Generates the necessary IMAP messages so that the client /// has a satisfactory summary of the current mailbox's state. /// These are the messages that are sent in response to a SELECT command. pub async fn new(mailbox: Arc) -> Result<(Self, Vec)> { let state = mailbox.current_uid_index().await; let new_view = Self { mailbox, known_state: state, }; let mut data = Vec::::new(); data.push(new_view.exists_status()?); data.push(new_view.recent_status()?); data.extend(new_view.flags_status()?.into_iter()); data.push(new_view.uidvalidity_status()?); data.push(new_view.uidnext_status()?); if let Some(unseen) = new_view.unseen_status()? { data.push(unseen); } Ok((new_view, data)) } /// Looks up state changes in the mailbox and produces a set of IMAP /// responses describing the changes. pub async fn sync_update(&mut self) -> Result> { self.mailbox.sync().await?; self.update().await } /// Produces a set of IMAP responses describing the change between /// what the client knows and what is actually in the mailbox. pub async fn update(&mut self) -> Result> { let new_view = MailboxView { mailbox: self.mailbox.clone(), known_state: self.mailbox.current_uid_index().await, }; let mut data = Vec::::new(); if new_view.known_state.uidvalidity != self.known_state.uidvalidity { // TODO: do we want to push less/more info than this? data.push(new_view.uidvalidity_status()?); data.push(new_view.exists_status()?); data.push(new_view.uidnext_status()?); } else { // Calculate diff between two mailbox states // See example in IMAP RFC in section on NOOP command: // we want to produce something like this: // C: a047 NOOP // S: * 22 EXPUNGE // S: * 23 EXISTS // S: * 14 FETCH (UID 1305 FLAGS (\Seen \Deleted)) // S: a047 OK Noop completed // In other words: // - notify client of expunged mails // - if new mails arrived, notify client of number of existing mails // - if flags changed for existing mails, tell client // - notify client of expunged mails let mut n_expunge = 0; for (i, (_uid, uuid)) in self.known_state.idx_by_uid.iter().enumerate() { if !new_view.known_state.table.contains_key(uuid) { data.push(Body::Data(Data::Expunge( NonZeroU32::try_from((i + 1 - n_expunge) as u32).unwrap(), ))); n_expunge += 1; } } // - if new mails arrived, notify client of number of existing mails if new_view.known_state.table.len() != self.known_state.table.len() - n_expunge { data.push(new_view.exists_status()?); } // - if flags changed for existing mails, tell client for (i, (_uid, uuid)) in new_view.known_state.idx_by_uid.iter().enumerate() { let old_mail = self.known_state.table.get(uuid); let new_mail = new_view.known_state.table.get(uuid); if old_mail.is_some() && old_mail != new_mail { if let Some((uid, flags)) = new_mail { data.push(Body::Data(Data::Fetch { seq_or_uid: NonZeroU32::try_from((i + 1) as u32).unwrap(), attributes: vec![ MessageAttribute::Uid((*uid).try_into().unwrap()), MessageAttribute::Flags( flags.iter().filter_map(|f| string_to_flag(f)).collect(), ), ], })); } } } } *self = new_view; Ok(data) } pub async fn store( &mut self, sequence_set: &SequenceSet, kind: &StoreType, _response: &StoreResponse, flags: &[Flag], uid: &bool, ) -> Result> { if *uid { bail!("UID STORE not implemented"); } let flags = flags.iter().map(|x| x.to_string()).collect::>(); let mails = self.get_mail_ids(sequence_set)?; for (_i, _uid, uuid) in mails.iter() { match kind { StoreType::Add => { self.mailbox.add_flags(*uuid, &flags[..]).await?; } StoreType::Remove => { self.mailbox.del_flags(*uuid, &flags[..]).await?; } StoreType::Replace => { self.mailbox.set_flags(*uuid, &flags[..]).await?; } } } self.update().await } pub async fn expunge(&mut self) -> Result> { let deleted_flag = Flag::Deleted.to_string(); let msgs = self .known_state .table .iter() .filter(|(_uuid, (_uid, flags))| flags.iter().any(|x| *x == deleted_flag)) .map(|(uuid, _)| *uuid); for msg in msgs { self.mailbox.delete(msg).await?; } self.update().await } /// Looks up state changes in the mailbox and produces a set of IMAP /// responses describing the new state. pub async fn fetch( &self, sequence_set: &SequenceSet, attributes: &MacroOrFetchAttributes, uid: &bool, ) -> Result> { if *uid { bail!("UID FETCH not implemented"); } let mails = self.get_mail_ids(sequence_set)?; let mails_uuid = mails .iter() .map(|(_i, _uid, uuid)| *uuid) .collect::>(); let mails_meta = self.mailbox.fetch_meta(&mails_uuid).await?; let fetch_attrs = match attributes { MacroOrFetchAttributes::Macro(m) => m.expand(), MacroOrFetchAttributes::FetchAttributes(a) => a.clone(), }; let need_body = fetch_attrs.iter().any(|x| { matches!( x, FetchAttribute::Body | FetchAttribute::BodyExt { .. } | FetchAttribute::Rfc822 | FetchAttribute::Rfc822Text | FetchAttribute::BodyStructure ) }); let mails = if need_body { let mut iter = mails .into_iter() .zip(mails_meta.into_iter()) .map(|((i, uid, uuid), meta)| async move { let body = self.mailbox.fetch_full(uuid, &meta.message_key).await?; Ok::<_, anyhow::Error>((i, uid, uuid, meta, Some(body))) }) .collect::>(); let mut mails = vec![]; while let Some(m) = iter.next().await { mails.push(m?); } mails } else { mails .into_iter() .zip(mails_meta.into_iter()) .map(|((i, uid, uuid), meta)| (i, uid, uuid, meta, None)) .collect::>() }; let mut ret = vec![]; for (i, uid, uuid, meta, body) in mails { let mut attributes = vec![]; let (_uid2, flags) = self .known_state .table .get(&uuid) .ok_or_else(|| anyhow!("Mail not in uidindex table: {}", uuid))?; let parsed = match &body { Some(m) => { mail_parser::Message::parse(m).ok_or_else(|| anyhow!("Invalid mail body"))? } None => mail_parser::Message::parse(&meta.headers) .ok_or_else(|| anyhow!("Invalid mail headers"))?, }; for attr in fetch_attrs.iter() { match attr { FetchAttribute::Uid => attributes.push(MessageAttribute::Uid(uid)), FetchAttribute::Flags => { attributes.push(MessageAttribute::Flags( flags.iter().filter_map(|f| string_to_flag(f)).collect(), )); } FetchAttribute::Rfc822Size => { attributes.push(MessageAttribute::Rfc822Size(meta.rfc822_size as u32)) } FetchAttribute::Rfc822Header => attributes.push( MessageAttribute::Rfc822Header(NString(Some(IString::Literal( meta.headers .clone() .try_into() .or(Err(Error::msg("IString conversion error")))?, )))), ), FetchAttribute::Rfc822Text => { let r = parsed .raw_message.get(parsed.offset_body..parsed.offset_end) .ok_or(Error::msg("Unable to extract email body, cursors out of bound. This is a bug."))? .try_into() .or(Err(Error::msg("IString conversion error")))?; attributes.push(MessageAttribute::Rfc822Text(NString(Some( IString::Literal(r), )))) } FetchAttribute::Rfc822 => { attributes.push(MessageAttribute::Rfc822(NString(Some(IString::Literal( body.as_ref().unwrap().clone().try_into().unwrap(), ))))) } FetchAttribute::Envelope => { attributes.push(MessageAttribute::Envelope(message_envelope(&parsed))) } FetchAttribute::Body => attributes.push(MessageAttribute::Body( build_imap_email_struct(&parsed, &parsed.structure)?, )), FetchAttribute::BodyStructure => attributes.push(MessageAttribute::Body( build_imap_email_struct(&parsed, &parsed.structure)?, )), FetchAttribute::BodyExt { section: _, partial: _, peek: _, } => { // @TODO This is a stub let is = IString::try_from("test").unwrap(); attributes.push(MessageAttribute::BodyExt { section: None, origin: None, data: NString(Some(is)), }) } FetchAttribute::InternalDate => { attributes.push(MessageAttribute::InternalDate(MyDateTime( Utc.fix() .timestamp(i64::try_from(meta.internaldate / 1000)?, 0), ))); } } } ret.push(Body::Data(Data::Fetch { seq_or_uid: i, attributes, })); } Ok(ret) } // ---- // Gets the UIDs and UUIDs of mails identified by a SequenceSet of // sequence numbers fn get_mail_ids( &self, sequence_set: &SequenceSet, ) -> Result> { let mail_vec = self .known_state .idx_by_uid .iter() .map(|(uid, uuid)| (*uid, *uuid)) .collect::>(); let mut mails = vec![]; let iter_strat = sequence::Strategy::Naive { largest: NonZeroU32::try_from((self.known_state.idx_by_uid.len() + 1) as u32).unwrap(), }; for i in sequence_set.iter(iter_strat) { if let Some(mail) = mail_vec.get(i.get() as usize - 1) { mails.push((i, mail.0, mail.1)); } else { bail!("No such mail: {}", i); } } Ok(mails) } // ---- /// Produce an OK [UIDVALIDITY _] message corresponding to `known_state` fn uidvalidity_status(&self) -> Result { let uid_validity = Status::ok( None, Some(Code::UidValidity(self.uidvalidity())), "UIDs valid", ) .map_err(Error::msg)?; Ok(Body::Status(uid_validity)) } pub(crate) fn uidvalidity(&self) -> ImapUidvalidity { self.known_state.uidvalidity } /// Produce an OK [UIDNEXT _] message corresponding to `known_state` fn uidnext_status(&self) -> Result { let next_uid = Status::ok( None, Some(Code::UidNext(self.uidnext())), "Predict next UID", ) .map_err(Error::msg)?; Ok(Body::Status(next_uid)) } pub(crate) fn uidnext(&self) -> ImapUid { self.known_state.uidnext } /// Produces an UNSEEN message (if relevant) corresponding to the /// first unseen message id in `known_state` fn unseen_status(&self) -> Result> { if let Some(unseen) = self.unseen() { let status_unseen = Status::ok(None, Some(Code::Unseen(unseen.clone())), "First unseen UID") .map_err(Error::msg)?; Ok(Some(Body::Status(status_unseen))) } else { Ok(None) } } pub(crate) fn unseen(&self) -> Option { self.known_state .idx_by_flag .get(&"$unseen".to_string()) .and_then(|os| os.get_min()) .cloned() } /// Produce an EXISTS message corresponding to the number of mails /// in `known_state` fn exists_status(&self) -> Result { Ok(Body::Data(Data::Exists(self.exists()?))) } pub(crate) fn exists(&self) -> Result { Ok(u32::try_from(self.known_state.idx_by_uid.len())?) } /// Produce a RECENT message corresponding to the number of /// recent mails in `known_state` fn recent_status(&self) -> Result { Ok(Body::Data(Data::Recent(self.recent()?))) } pub(crate) fn recent(&self) -> Result { let recent = self .known_state .idx_by_flag .get(&"\\Recent".to_string()) .map(|os| os.len()) .unwrap_or(0); Ok(u32::try_from(recent)?) } /// Produce a FLAGS and a PERMANENTFLAGS message that indicates /// the flags that are in `known_state` + default flags fn flags_status(&self) -> Result> { let mut flags: Vec = self .known_state .idx_by_flag .flags() .map(|f| string_to_flag(f)) .flatten() .collect(); for f in DEFAULT_FLAGS.iter() { if !flags.contains(f) { flags.push(f.clone()); } } let mut ret = vec![Body::Data(Data::Flags(flags.clone()))]; flags.push(Flag::Permanent); let permanent_flags = Status::ok(None, Some(Code::PermanentFlags(flags)), "Flags permitted") .map_err(Error::msg)?; ret.push(Body::Status(permanent_flags)); Ok(ret) } } fn string_to_flag(f: &str) -> Option { match f.chars().next() { Some('\\') => match f { "\\Seen" => Some(Flag::Seen), "\\Answered" => Some(Flag::Answered), "\\Flagged" => Some(Flag::Flagged), "\\Deleted" => Some(Flag::Deleted), "\\Draft" => Some(Flag::Draft), "\\Recent" => Some(Flag::Recent), _ => match Atom::try_from(f.strip_prefix('\\').unwrap().clone()) { Err(_) => { tracing::error!(flag=%f, "Unable to encode flag as IMAP atom"); None } Ok(a) => Some(Flag::Extension(a)), }, }, Some('$') if f == "$unseen" => None, Some(_) => match Atom::try_from(f.clone()) { Err(_) => { tracing::error!(flag=%f, "Unable to encode flag as IMAP atom"); None } Ok(a) => Some(Flag::Keyword(a)), }, None => None, } } /// Envelope rules are defined in RFC 3501, section 7.4.2 /// https://datatracker.ietf.org/doc/html/rfc3501#section-7.4.2 /// /// Some important notes: /// /// If the Sender or Reply-To lines are absent in the [RFC-2822] /// header, or are present but empty, the server sets the /// corresponding member of the envelope to be the same value as /// the from member (the client is not expected to know to do /// this). Note: [RFC-2822] requires that all messages have a valid /// From header. Therefore, the from, sender, and reply-to /// members in the envelope can not be NIL. /// /// If the Date, Subject, In-Reply-To, and Message-ID header lines /// are absent in the [RFC-2822] header, the corresponding member /// of the envelope is NIL; if these header lines are present but /// empty the corresponding member of the envelope is the empty /// string. //@FIXME return an error if the envelope is invalid instead of panicking //@FIXME some fields must be defaulted if there are not set. fn message_envelope(msg: &mail_parser::Message<'_>) -> Envelope { let from = convert_addresses(msg.get_from()).unwrap_or(vec![]); Envelope { date: NString( msg.get_date() .map(|d| IString::try_from(d.to_iso8601()).unwrap()), ), subject: NString( msg.get_subject() .map(|d| IString::try_from(d.to_string()).unwrap()), ), from: from.clone(), sender: convert_addresses(msg.get_sender()).unwrap_or(from.clone()), reply_to: convert_addresses(msg.get_reply_to()).unwrap_or(from.clone()), to: convert_addresses(msg.get_to()).unwrap_or(vec![]), cc: convert_addresses(msg.get_cc()).unwrap_or(vec![]), bcc: convert_addresses(msg.get_bcc()).unwrap_or(vec![]), in_reply_to: NString(None), // @TODO message_id: NString( msg.get_message_id() .map(|d| IString::try_from(d.to_string()).unwrap()), ), } } fn convert_addresses(a: &mail_parser::HeaderValue<'_>) -> Option> { match a { mail_parser::HeaderValue::Address(a) => Some(vec![convert_address(a)]), mail_parser::HeaderValue::AddressList(l) => { Some(l.iter().map(|a| convert_address(a)).collect()) } mail_parser::HeaderValue::Empty => None, mail_parser::HeaderValue::Collection(c) => Some( c.iter() .map(|l| convert_addresses(l).unwrap_or(vec![])) .flatten() .collect(), ), _ => { tracing::warn!("Invalid address header"); None } } } //@FIXME Remove unwrap fn convert_address(a: &mail_parser::Addr<'_>) -> Address { let (user, host) = match &a.address { None => (None, None), Some(x) => match x.split_once('@') { Some((u, h)) => (Some(u.to_string()), Some(h.to_string())), None => (Some(x.to_string()), None), }, }; Address::new( NString( a.name .as_ref() .map(|x| IString::try_from(x.to_string()).unwrap()), ), // SMTP at-domain-list (source route) seems obsolete since at least 1991 // https://www.mhonarc.org/archive/html/ietf-822/1991-06/msg00060.html NString(None), NString(user.map(|x| IString::try_from(x).unwrap())), NString(host.map(|x| IString::try_from(x).unwrap())), ) } /* --CAPTURE-- b fetch 29878:29879 (BODY) * 29878 FETCH (BODY (("text" "plain" ("charset" "utf-8") NIL NIL "quoted-printable" 3264 82)("text" "html" ("charset" "utf-8") NIL NIL "quoted-printable" 31834 643) "alternative")) * 29879 FETCH (BODY ("text" "html" ("charset" "us-ascii") NIL NIL "7bit" 4107 131)) ^^^^^^^^^^^^^^^^^^^^^^ ^^^ ^^^ ^^^^^^ ^^^^ ^^^ | | | | | | number of lines | | | | | size | | | | content transfer encoding | | | description | | id | parameter list b OK Fetch completed (0.001 + 0.000 secs). */ fn build_imap_email_struct<'a>( msg: &Message<'a>, node: &MessageStructure, ) -> Result { match node { MessageStructure::Part(id) => { let part = msg.parts.get(*id).ok_or(anyhow!( "Email part referenced in email structure is missing" ))?; match part { MessagePart::Multipart(_) => { unreachable!("A multipart entry can not be found here.") } MessagePart::Text(bp) | MessagePart::Html(bp) => { let (attrs, mut basic) = headers_to_basic_fields(bp)?; // If the charset is not defined, set it to "us-ascii" if attrs.charset.is_none() { basic .parameter_list .push((unchecked_istring("charset"), unchecked_istring("us-ascii"))); } // If the subtype is not defined, set it to "plain". MIME (RFC2045) says that subtype // MUST be defined and hence has no default. But mail-parser does not make any // difference between MIME and raw emails, hence raw emails have no subtypes. let subtype = bp .get_content_type() .map(|h| h.c_subtype.as_ref()) .flatten() .map(|st| IString::try_from(st.to_string()).ok()) .flatten() .unwrap_or(unchecked_istring("plain")); Ok(BodyStructure::Single { body: FetchBody { basic, specific: SpecificFields::Text { subtype, number_of_lines: u32::try_from( // We do not count the number of lines but the number of line // feeds to have the same behavior as Dovecot and Cyrus. // 2 lines = 1 line feed. bp.body_raw.as_ref().iter().filter(|&c| c == &b'\n').count(), )?, }, }, extension: None, }) } MessagePart::Binary(bp) | MessagePart::InlineBinary(bp) => { let (_, basic) = headers_to_basic_fields(bp)?; let ct = bp .get_content_type() .ok_or(anyhow!("Content-Type is missing but required here."))?; let type_ = IString::try_from(ct.c_type.as_ref().to_string()).map_err(|_| { anyhow!("Unable to build IString from given Content-Type type given") })?; let subtype = IString::try_from( ct.c_subtype .as_ref() .ok_or(anyhow!("Content-Type invalid, missing subtype"))? .to_string(), ) .map_err(|_| { anyhow!("Unable to build IString from given Content-Type subtype given") })?; Ok(BodyStructure::Single { body: FetchBody { basic, specific: SpecificFields::Basic { type_, subtype }, }, extension: None, }) } MessagePart::Message(bp) => { let (_, mut basic) = headers_to_basic_fields(bp)?; // @NOTE in some cases mail-parser does not parse the MessageAttachment but // provide it as raw body. Using `as_ref()` masks this fact: if the message is // parsed, as_ref() will return None. But by looking quickly at the code, it // seems that the attachment is not parsed when mail-parser encounters some // encoding problems, so it might be better to trust mail-parser. let inner = bp .get_body() .as_ref() .ok_or(anyhow!("Unable to parse inner message."))?; // @FIXME mail-parser does not handle ways when a MIME message contains // a raw email and wrongly take its delimiter. We thus test the headers to // learn if it is a RFC822 email (raw) or RFC5322 (MIME) message. // The correct way would be to patch mail-parser. let raw_msg = match part.unwrap_message().get_content_type() { Some(ContentType { attributes: Some(_), .. }) => { //println!("has a content type {:?}", bp); &inner.raw_message[..] } _ => { //println!("has no content type {:?}", bp); &inner.raw_message[..(inner.offset_last_part - inner.offset_header)] } }; basic.size = u32::try_from(raw_msg.len())?; // We do not count the number of lines but the number of line // feeds to have the same behavior as Dovecot and Cyrus. // 2 lines = 1 line feed. let nol = raw_msg.iter().filter(|&c| c == &b'\n').count(); Ok(BodyStructure::Single { body: FetchBody { basic, specific: SpecificFields::Message { envelope: message_envelope(inner), body_structure: Box::new(build_imap_email_struct( inner, &inner.structure, )?), // @FIXME This solution is bad for 2 reasons: // - RFC2045 says line endings are CRLF but we accept LF alone with // this method. It could be a feature (be liberal in what you // accept) but we must be sure that we don't break things. // - It should be done during parsing, we are iterating twice on // the same data which results in some wastes. number_of_lines: u32::try_from(nol)?, }, }, extension: None, }) } } } MessageStructure::List(lp) => { let subtype = IString::try_from( msg.get_content_type() .ok_or(anyhow!("Content-Type is missing but required here."))? .c_subtype .as_ref() .ok_or(anyhow!("Content-Type invalid, missing subtype"))? .to_string(), ) .map_err(|_| { anyhow!("Unable to build IString from given Content-Type subtype given") })?; // @NOTE we should use try_collect() but it is unstable as of 2022-07-05 Ok(BodyStructure::Multi { bodies: lp .iter() .map(|inner_node| build_imap_email_struct(msg, inner_node)) .fold(Ok(vec![]), try_collect_shime)?, subtype, extension_data: None, }) } MessageStructure::MultiPart((id, lp)) => { let part = msg .parts .get(*id) .map(|p| match p { MessagePart::Multipart(mp) => Some(mp), _ => None, }) .flatten() .ok_or(anyhow!( "Email part referenced in email structure is missing" ))?; let subtype = IString::try_from( part.headers_rfc .get(&RfcHeader::ContentType) .ok_or(anyhow!("Content-Type is missing but required here."))? .get_content_type() .c_subtype .as_ref() .ok_or(anyhow!("Content-Type invalid, missing subtype"))? .to_string(), ) .map_err(|_| { anyhow!("Unable to build IString from given Content-Type subtype given") })?; Ok(BodyStructure::Multi { bodies: lp .iter() .map(|inner_node| build_imap_email_struct(msg, inner_node)) .fold(Ok(vec![]), try_collect_shime)?, subtype, extension_data: None, /*Some(MultipartExtensionData { parameter_list: vec![], disposition: None, language: None, location: None, extension: vec![], })*/ }) } } } fn try_collect_shime(acc: Result>, elem: Result) -> Result> { match (acc, elem) { (Err(e), _) | (_, Err(e)) => Err(e), (Ok(mut ac), Ok(el)) => { ac.push(el); Ok(ac) } } } /// s is set to static to ensure that only compile time values /// checked by developpers are passed. fn unchecked_istring(s: &'static str) -> IString { IString::try_from(s).expect("this value is expected to be a valid imap-codec::IString") } #[derive(Default)] struct SpecialAttrs<'a> { charset: Option<&'a Cow<'a, str>>, boundary: Option<&'a Cow<'a, str>>, } /// Takes mail-parser Content-Type attributes, build imap-codec BasicFields.parameter_list and /// identify some specific attributes (charset and boundary). fn attrs_to_params<'a>(bp: &impl MimeHeaders<'a>) -> (SpecialAttrs, Vec<(IString, IString)>) { // Try to extract Content-Type attributes from headers let attrs = match bp .get_content_type() .map(|c| c.attributes.as_ref()) .flatten() { Some(v) => v, _ => return (SpecialAttrs::default(), vec![]), }; // Transform the Content-Type attributes into IMAP's parameter list // Also collect some special attributes that might be used elsewhere attrs.iter().fold( (SpecialAttrs::default(), vec![]), |(mut sa, mut param_list), (k, v)| { let nk = k.to_lowercase(); match (IString::try_from(k.as_ref()), IString::try_from(v.as_ref())) { (Ok(ik), Ok(iv)) => param_list.push((ik, iv)), _ => return (sa, param_list), }; match nk.as_str() { "charset" => { sa.charset = Some(v); } "boundary" => { sa.boundary = Some(v); } _ => (), }; (sa, param_list) }, ) } /// Takes mail-parser headers and build imap-codec BasicFields /// Return some special informations too fn headers_to_basic_fields<'a, T>(bp: &'a Part) -> Result<(SpecialAttrs<'a>, BasicFields)> { let (attrs, parameter_list) = attrs_to_params(bp); let bf = BasicFields { parameter_list, id: NString( bp.get_content_id() .map(|ci| IString::try_from(ci.to_string()).ok()) .flatten(), ), description: NString( bp.get_content_description() .map(|cd| IString::try_from(cd.to_string()).ok()) .flatten(), ), /* * RFC2045 - section 6.1 * "Content-Transfer-Encoding: 7BIT" is assumed if the * Content-Transfer-Encoding header field is not present. */ content_transfer_encoding: bp .get_content_transfer_encoding() .map(|h| IString::try_from(h.to_string()).ok()) .flatten() .unwrap_or(unchecked_istring("7bit")), size: u32::try_from(bp.body_raw.len())?, }; Ok((attrs, bf)) } #[cfg(test)] mod tests { use super::*; use imap_codec::codec::Encode; use std::fs; /// Future automated test. We use lossy utf8 conversion + lowercase everything, /// so this test might allow invalid results. But at least it allows us to quickly test a /// large variety of emails. /// Keep in mind that special cases must still be tested manually! #[test] fn fetch_body() -> Result<()> { let prefixes = [ "tests/emails/dxflrs/0001_simple", "tests/emails/dxflrs/0002_mime", "tests/emails/dxflrs/0003_mime-in-mime", "tests/emails/dxflrs/0004_msg-in-msg", "tests/emails/dxflrs/0005_mail-parser-readme", //"tests/emails/dxflrs/0006_single-mime", //"tests/emails/dxflrs/0007_raw_msg_in_rfc822", //"tests/emails/rfc/000", // broken // "tests/emails/rfc/001", // broken // "tests/emails/rfc/002", // broken: dovecot adds \r when it is missing and count is as // a character. Difference on how lines are counted too. /*"tests/emails/rfc/003", // broken for the same reason "tests/emails/thirdparty/000", "tests/emails/thirdparty/001", "tests/emails/thirdparty/002", */ ]; for pref in prefixes.iter() { println!("{}", pref); let txt = fs::read(format!("{}.eml", pref))?; let exp = fs::read(format!("{}.dovecot.body", pref))?; let message = Message::parse(&txt).unwrap(); let mut resp = Vec::new(); MessageAttribute::Body(build_imap_email_struct(&message, &message.structure)?) .encode(&mut resp); let resp_str = String::from_utf8_lossy(&resp).to_lowercase(); let exp_no_parenthesis = &exp[1..exp.len() - 1]; let exp_str = String::from_utf8_lossy(exp_no_parenthesis).to_lowercase(); println!("aerogramme: {}\ndovecot: {}", resp_str, exp_str); //println!("\n\n {} \n\n", String::from_utf8_lossy(&resp)); assert_eq!(resp_str, exp_str); } Ok(()) } }