Author: Brian Gianforcaro ([email protected])
Updated: 2/28/2010
This is a mini tutorial to get you up and going with the basics of the Haskell mongoDB drivers. It is modeled after the pymongo tutorial.
You will need the mongoDB bindings installed as well as mongo itself installed.
$ = command line prompt
> = ghci repl prompt
From Source:
$ git clone git://github.com/srp/mongoDB.git
$ cd mongoDB
$ runhaskell Setup.hs configure
$ runhaskell Setup.hs build
$ runhaskell Setup.hs install
From Hackage using cabal:
$ cabal install mongoDB
Start a MongoDB instance for us to play with:
$ mongod
Start up a haskell repl:
$ ghci
Now we'll need to bring in the MongoDB/BSON bindings and set OverloadedStrings so literal strings are converted to UTF-8 automatically.
> import Database.MongoDB
> :set -XOverloadedStrings
Open up a connection to your DB instance, using the standard port:
> Right con <- connect $ server "127.0.0.1"
or for a non-standard port
> Right con <- connect $ server "127.0.0.1" (PortNumber 666)
connect returns Left IOError if connection fails. We are assuming above it won't fail. If it does you will get a pattern match error.
The current connection is held in a Connected monad, and the current database is held in a Reader monad on top of that. To run a connected monad, supply it and a connection to runConn. To access a database within a connected monad, call useDb.
Since we are working in ghci, which requires us to start from the IO monad every time, we'll define a convenient run function that takes a db-action and executes it against our "test" database on the server we just connected to:
> let run act = runConn (useDb "test" act) con
run (runConn) will return either Left Failure or Right result. Failure means the connection failed (eg. network problem) or the server failed (eg. disk full).
A MongoDB can store multiple databases -- separate namespaces under which collections reside.
You can obtain the list of databases available on a connection:
> runConn allDatabases con
You can also use the run function we just created:
> run allDatabases
The "test" database is ignored in this case because allDatabases is not a query on a specific database but on the server as a whole.
Databases and collections do not need to be created, just start using them and MongoDB will automatically create them for you.
In the below examples we'll be using the database "test" (captured in run above) and the colllection "posts":
You can obtain a list of collections available in the "test" database:
> run allCollections
Data in MongoDB is represented (and stored) using JSON-style documents. In mongoDB we use the BSON Document type to represent these documents. A document is simply a list of Fields, where each field is a named value. A value is a basic type like Bool, Int, Float, String, Time; a special BSON value like Binary, Javascript, ObjectId; a (embedded) Document; or a list of values. Here's an example document which could represent a blog post:
> import Data.Time
> now <- getCurrentTime
> :{
let post = ["author" =: "Mike",
"text" =: "My first blog post!",
"tags" =: ["mongoDB", "Haskell"],
"date" =: now]
:}
To insert a document into a collection we can use the insert function:
> run $ insert "posts" post
Right (Oid 4c16d355 c80c560858000000)
When a document is inserted a special field, _id, is automatically added if the document doesn't already contain that field. The value of _id must be unique across the collection. insert returns the value of _id for the inserted document. For more information, see the documentation on _id.
After inserting the first document, the posts collection has actually been created on the server. We can verify this by listing all of the collections in our database:
> run allCollections
- Note The system.indexes collection is a special internal collection that was created automatically.
The most basic type of query that can be performed in MongoDB is findOne. This method returns a single document matching a query (or Nothing if there are no matches). It is useful when you know there is only one matching document, or are only interested in the first match. Here we use findOne to get the first document from the posts collection:
> run $ findOne (select [] "posts")
Right (Just [ _id: Oid 4c16d355 c80c560858000000, author: "Mike", text: "My first blog post!", tags: ["mongoDB","Haskell"], date: 2010-06-15 01:09:28.364 UTC])
The result is a document matching the one that we inserted previously.
- Note: The returned document contains an _id, which was automatically added on insert.
findOne also supports querying on specific elements that the resulting document must match. To limit our results to a document with author "Mike" we do:
> run $ findOne (select ["author" =: "Mike"] "posts")
Right (Just [ _id: Oid 4c16d355 c80c560858000000, author: "Mike", text: "My first blog post!", tags: ["mongoDB","Haskell"], date: 2010-06-15 01:09:28.364 UTC])
If we try with a different author, like "Eliot", we'll get no result:
> run $ findOne (select ["author" =: "Eliot"] "posts")
Right Nothing
In order to make querying a little more interesting, let's insert a few more documents. In addition to inserting a single document, we can also perform bulk insert operations, by using the insertMany function which accepts a list of documents to be inserted. It send only a single command to the server:
> now <- getCurrentTime
> :{
let post1 = ["author" =: "Mike",
"text" =: "Another post!",
"tags" =: ["bulk", "insert"],
"date" =: now]
:}
> :{
let post2 = ["author" =: "Eliot",
"title" =: "MongoDB is fun",
"text" =: "and pretty easy too!",
"date" =: now]
:}
> run $ insertMany "posts" [post1, post2]
Right [Oid 4c16d67e c80c560858000001,Oid 4c16d67e c80c560858000002]
- Note that post2 has a different shape than the other posts - there is no "tags" field and we've added a new field, "title". This is what we mean when we say that MongoDB is schema-free.
To get more than a single document as the result of a query we use the find method. find returns a cursor instance, which allows us to iterate over all matching documents. There are several ways in which we can iterate: we can call next to get documents one at a time or we can get all the results by applying the cursor to rest:
> Right cursor <- run $ find (select ["author" =: "Mike"] "posts")
> run $ rest cursor
Of course you can use bind (>>=) to combine these into one line:
> run $ find (select ["author" =: "Mike"] "posts") >>= rest
- Note: next automatically closes the cursor when the last document has been read out of it. Similarly, rest automatically closes the cursor after returning all the results.
We can count how many documents are in an entire collection:
> run $ count (select [] "posts")
Or count how many documents match a query:
> run $ count (select ["author" =: "Mike"] "posts")
To do
To do