imap: An efficient IMAP client library, with SSL and streaming
This is an IMAP library for Haskell that aims to be efficient, easy to use, transparent when it comes to underlying libraries and support results streaming. To this end it employs
ListT, so you can use it with any concurrency management library of your choosing.
It tries to implement RFC-3501 as faithfully as possible, diverging from it where we noticed that servers have different ideas. If you want to understand this library, it's highly recommended to skim through that RFC first.
For a description of types used in this tutorial or an in-depth description of functions presented, please check the documentation or the source code.
All of the commands will output their results in
MonadIO. Results consist of a list of
UntaggedResults followed by a single
TaggedResult that describes the command state (if it succeeded or failed).
We provide a helper function that simplifies the output types for the cases when you don't care about the streaming and just want a list of
UntaggedResults or an error message. Depending on your needs you will probably use it for all the commands that are not
Also, remember that you probably have to keep the connection alive so that the server doesn't disconnect you. Send a
noop from time to time to achieve that.
Simple, no streaming
You need a connection object first, so that you can execute commands on it. It's produced by
connectServer, which accepts parameters from Network.Connection. Say you want to connect to gmail:
import Network.Connection import Network.IMAP import Network.IMAP.Types
let tls = TLSSettingsSimple False False False let params = ConnectionParams "imap.gmail.com" 993 (Just tls) Nothing conn <- connectServer params Nothing
From now on you can run commands on this connection. The second parameter to
connectServer is `Maybe IMAPSettings`. If settings are not provided, sane defaults will be used. We will use the
simpleFormat helper function to convert from
IO. Let's log in:
simpleFormat $ login conn "mylogin" "mypass" Right [Capabilities [CIMAP4,CUnselect,CIdle,CNamespace,CQuota,CId,CExperimental "XLIST",CChildren,CExperimental "X-GM-EXT-1",CUIDPlus,CCompress "DEFLATE",CEnable,CMove,CCondstore,CEsearch,CUtf8 "ACCEPT",CListExtended,CListStatus,CAppendLimit 35882577]]
You can see that the server replied with a
CAPABILITIES reply and the login was successful. Next, let's select an inbox:
simpleFormat $ select conn "inbox2" Left "[NONEXISTENT] Unknown Mailbox: inbox2 (Failure)"
Oh, let's fix that
simpleFormat $ select conn "inbox" Right [Flags [FAnswered,FFlagged,FDraft,FDeleted,FSeen,FOther "$NotPhishing",FOther "$Phishing",FOther "NonJunk"],PermanentFlags [FAnswered,FFlagged,FDraft,FDeleted,FSeen,FOther "$NotPhishing",FOther "$Phishing",FOther "NonJunk",FAny],UIDValidity 1,Exists 65,Recent 0,UIDNext 1050,HighestModSeq 251971]
Again you can use the metadata if you wish to. Let's see what messages we have (consult the RFC if you're unsure about the parameter to
simpleFormat $ uidSearch conn "ALL" Right [Search [105,219,411,424,425,748,763,770,774,819,824,825,..]]
Fetching a message is straigtforward as well:
simpleFormat $ uidFetch conn "219" Right [Fetch [MessageId 2,UID 219,Body "Delivered-To: firstname.lastname@example.org\r\nReceived: by...
If you need more control on the parameters of fetch, there is a more general function available:
simpleFormat $ uidFetchG conn "219 ALL"
Do you want multiple messages in one reply? That's easy with UID ranges!
simpleFormat $ uidFetchG conn "219:9000 RFC822.SIZE" Right [Fetch [MessageId 2,UID 219,Size 4880],Fetch [MessageId 3,UID 411,Size 7392],...]
That's where streaming comes in handy - if these were message bodies you would probably like to do something with them before all are downloaded.
Replies we didn't expect
IMAP protocol allows for messages pushed to the client at any time, even when they're not requested. This is used to notify the client that a new message had arrived, or as status of a message had changed as it was read by another client. These server messages wait for you in a bounded message queue and you can read them like:
import qualified Data.STM.RollingQueue as RQ msgs <- atomically . RQ.read . untaggedQueue $ conn
conn is the connection from previous step.
There's an excellent article by Gabriel Gonzalez you should read :)
|Versions [RSS]||0.1.0.0, 0.1.0.1, 0.1.0.2, 0.1.0.3, 0.2.0.0, 0.2.0.1, 0.2.0.2, 0.2.0.3, 0.3.0.0, 0.3.0.2, 0.3.0.3, 0.3.0.4, 0.3.0.5, 0.3.0.6, 0.3.0.7, 0.3.0.8, 0.3.0.9|
|Dependencies||attoparsec (>=0.13 && <0.14), base (>=4.10 && <4.12), bytestring (>=0.10 && <0.11), connection (>=0.2 && <0.3), containers (>=0.5 && <0.6), either (>=4.5 && <6), exceptions (>=0.8 && <0.11), hslogger (>=1.2 && <1.3), list-t (>=1.0 && <1.1), network (>=2.6 && <2.7), pipes (>=4.3 && <4.4), random (>=1.1 && <1.2), rolling-queue (==0.1), stm (>=2.4 && <2.6), stm-delay (>=0.1 && <0.2), text (>=1.2 && <1.3), transformers (>=0.5 && <0.6), word8 (>=0.1 && <0.2) [details]|
|Source repo||head: git clone https://github.com/mkawalec/imap|
|Uploaded||by mkawalec at 2018-12-03T14:14:31Z|
|Downloads||9321 total (52 in the last 30 days)|
|Rating||(no votes yet) [estimated by Bayesian average]|
|Status||Docs uploaded by user [build log]
All reported builds failed as of 2018-12-03 [all 3 reports]