Maintainer | Andrew Cowie |
---|---|
Stability | Experimental |
Safe Haskell | None |
Language | Haskell2010 |
Overview
A simple HTTP client library, using the Snap Framework's io-streams
library to handle the streaming I/O. The http-streams
API is designed
for ease of use when querying web services and dealing with the result.
Given:
{-# LANGUAGE OverloadedStrings #-} import System.IO.Streams (InputStream, OutputStream, stdout) import qualified System.IO.Streams as Streams import qualified Data.ByteString as S
and this library:
import Network.Http.Client
the underlying API is straight-forward. In particular, constructing the
Request
to send is quick and to the point:
main :: IO () main = do c <-openConnection
"www.example.com" 80 let q =buildRequest1
$ dohttp
GET "/"setAccept
"text/html"sendRequest
c qemptyBody
receiveResponse
c (\p i -> do xm <- Streams.read i case xm of Just x -> S.putStr x Nothing -> "")closeConnection
c
which would print the first chunk of the response back from the
server. Obviously in real usage you'll do something more interesting
with the Response
in the handler function, and consume the entire
response body from the InputStream ByteString.
Because this is all happening in IO
(the defining feature of
io-streams
!), you can ensure resource cleanup on normal or
abnormal termination by using Control.Exception
's standard
bracket
function; see closeConnection
for an
example. For the common case we have a utility function which
wraps bracket
for you:
foo :: IO ByteString foo =withConnection
(openConnection
"www.example.com" 80) doStuff doStuff :: Connection -> IO ByteString
There are also a set of convenience APIs that do just that, along with the tedious bits like parsing URLs. For example, to do an HTTP GET and stream the response body to stdout, you can simply do:
get
"http://www.example.com/file.txt" (\p i -> Streams.connect i stdout)
which on the one hand is "easy" while on the other exposes the the
Response
and InputStream for you to read from. Of course, messing
around with URLs is all a bit inefficient, so if you already have e.g.
hostname and path, or if you need more control over the request being
created, then the underlying http-streams
API is simple enough to use
directly.
- type Hostname = ByteString
- type Port = Word16
- data Connection
- openConnection :: Hostname -> Port -> IO Connection
- openConnectionUnix :: FilePath -> IO Connection
- data Method :: *
- data RequestBuilder α :: * -> *
- buildRequest1 :: RequestBuilder α -> Request
- buildRequest :: Monad ν => RequestBuilder α -> ν Request
- http :: Method -> ByteString -> RequestBuilder ()
- setHostname :: Hostname -> Port -> RequestBuilder ()
- setAccept :: ByteString -> RequestBuilder ()
- setAccept' :: [(ByteString, Float)] -> RequestBuilder ()
- setAuthorizationBasic :: ByteString -> ByteString -> RequestBuilder ()
- type ContentType = ByteString
- setContentType :: ContentType -> RequestBuilder ()
- setContentLength :: Int64 -> RequestBuilder ()
- setExpectContinue :: RequestBuilder ()
- setTransferEncoding :: RequestBuilder ()
- setHeader :: ByteString -> ByteString -> RequestBuilder ()
- data Request :: *
- data Response :: *
- getHostname :: Connection -> Request -> ByteString
- sendRequest :: Connection -> Request -> (OutputStream Builder -> IO α) -> IO α
- emptyBody :: OutputStream Builder -> IO ()
- fileBody :: FilePath -> OutputStream Builder -> IO ()
- inputStreamBody :: InputStream ByteString -> OutputStream Builder -> IO ()
- encodedFormBody :: [(ByteString, ByteString)] -> OutputStream Builder -> IO ()
- receiveResponse :: Connection -> (Response -> InputStream ByteString -> IO β) -> IO β
- receiveResponseRaw :: Connection -> (Response -> InputStream ByteString -> IO β) -> IO β
- data UnexpectedCompression
- type StatusCode = Int
- getStatusCode :: Response -> StatusCode
- getStatusMessage :: Response -> ByteString
- getHeader :: Response -> ByteString -> Maybe ByteString
- debugHandler :: Response -> InputStream ByteString -> IO ()
- concatHandler :: Response -> InputStream ByteString -> IO ByteString
- concatHandler' :: Response -> InputStream ByteString -> IO ByteString
- data HttpClientError = HttpClientError Int ByteString
- jsonHandler :: FromJSON α => Response -> InputStream ByteString -> IO α
- closeConnection :: Connection -> IO ()
- withConnection :: IO Connection -> (Connection -> IO γ) -> IO γ
- type URL = ByteString
- get :: URL -> (Response -> InputStream ByteString -> IO β) -> IO β
- data TooManyRedirects
- post :: URL -> ContentType -> (OutputStream Builder -> IO α) -> (Response -> InputStream ByteString -> IO β) -> IO β
- postForm :: URL -> [(ByteString, ByteString)] -> (Response -> InputStream ByteString -> IO β) -> IO β
- put :: URL -> ContentType -> (OutputStream Builder -> IO α) -> (Response -> InputStream ByteString -> IO β) -> IO β
- openConnectionSSL :: SSLContext -> Hostname -> Port -> IO Connection
- baselineContextSSL :: IO SSLContext
- modifyContextSSL :: (SSLContext -> IO SSLContext) -> IO ()
- establishConnection :: URL -> IO Connection
- makeConnection :: ByteString -> IO () -> OutputStream ByteString -> InputStream ByteString -> IO Connection
- data Headers :: *
- getHeaders :: HttpType τ => τ -> Headers
- getHeadersFull :: Connection -> Request -> Headers
- getRequestHeaders :: Connection -> Request -> [(ByteString, ByteString)]
Connecting to server
type Hostname = ByteString #
openConnection :: Hostname -> Port -> IO Connection Source #
In order to make a request you first establish the TCP connection to the server over which to send it.
Ordinarily you would supply the host part of the URL here and it will
be used as the value of the HTTP 1.1 Host:
field. However, you can
specify any server name or IP addresss and set the Host:
value
later with setHostname
when building the
request.
Usage is as follows:
c <- openConnection "localhost" 80 ... closeConnection c
More likely, you'll use withConnection
to wrap the call in order
to ensure finalization.
HTTP pipelining is supported; you can reuse the connection to a web server, but it's up to you to ensure you match the number of requests sent to the number of responses read, and to process those responses in order. This is all assuming that the server supports pipelining; be warned that not all do. Web browsers go to extraordinary lengths to probe this; you probably only want to do pipelining under controlled conditions. Otherwise just open a new connection for subsequent requests.
openConnectionUnix :: FilePath -> IO Connection Source #
Open a connection to a Unix domain socket.
main :: IO () main = do c <- openConnectionUnix "/var/run/docker.sock" ... closeConnection c
Building Requests
You setup a request using the RequestBuilder monad, and
get the resultant Request object by running buildRequest1
. The
first call doesn't have to be to http
, but it looks better when
it is, don't you think?
HTTP Methods, as per RFC 2616
data RequestBuilder α :: * -> * #
The RequestBuilder monad allows you to abuse do-notation to
conveniently setup a Request
object.
buildRequest1 :: RequestBuilder α -> Request #
Run a RequestBuilder, yielding a Request object you can use on the given connection.
let q = buildRequest1 $ do http POST "/api/v1/messages" setContentType "application/json" setHostname "clue.example.com" 80 setAccept "text/html" setHeader "X-WhoDoneIt" "The Butler"
Obviously it's up to you to later actually send JSON data.
buildRequest :: Monad ν => RequestBuilder α -> ν Request #
Run a RequestBuilder from within a monadic action.
Older versions of this library had buildRequest
in IO; there's
no longer a need for that, but this code path will continue to
work for existing users.
q <- buildRequest $ do http GET "/"
http :: Method -> ByteString -> RequestBuilder () #
Begin constructing a Request, starting with the request line.
setHostname :: Hostname -> Port -> RequestBuilder () #
Set the [virtual] hostname for the request. In ordinary conditions
you won't need to call this, as the Host:
header is a required
header in HTTP 1.1 and is set directly from the name of the server
you connected to when calling openConnection
.
setAccept :: ByteString -> RequestBuilder () #
Indicate the content type you are willing to receive in a reply
from the server. For more complex Accept:
headers, use
setAccept'
.
setAccept' :: [(ByteString, Float)] -> RequestBuilder () #
Indicate the content types you are willing to receive in a reply from the server in order of preference. A call of the form:
setAccept' [("text/html", 1.0), ("application/xml", 0.8), ("*/*", 0)]
will result in an Accept:
header value of
text/html; q=1.0, application/xml; q=0.8, */*; q=0.0
as you
would expect.
setAuthorizationBasic :: ByteString -> ByteString -> RequestBuilder () #
Set username and password credentials per the HTTP basic authentication method.
setAuthorizationBasic "Aladdin" "open sesame"
will result in an Authorization:
header value of
Basic QWxhZGRpbjpvcGVuIHNlc2FtZQ==
.
Basic authentication does not use a message digest function to encipher the password; the above string is only base-64 encoded and is thus plain-text visible to any observer on the wire and all caches and servers at the other end, making basic authentication completely insecure. A number of web services, however, use SSL to encrypt the connection that then use HTTP basic authentication to validate requests. Keep in mind in these cases the secret is still sent to the servers on the other side and passes in clear through all layers after the SSL termination. Do not use basic authentication to protect secure or user-originated privacy-sensitve information.
type ContentType = ByteString #
setContentType :: ContentType -> RequestBuilder () #
Set the MIME type corresponding to the body of the request you are
sending. Defaults to "text/plain"
, so usually you need to set
this if PUT
ting.
setContentLength :: Int64 -> RequestBuilder () #
Specify the length of the request body, in bytes.
RFC 2616 requires that we either send a Content-Length
header or
use Transfer-Encoding: chunked
. If you know the exact size ahead
of time, then call this function; the body content will still be
streamed out by io-streams
in more-or-less constant space.
This function is special: in a PUT or POST request, http-streams
will assume chunked transfer-encoding unless you specify a content
length here, in which case you need to ensure your body function
writes precisely that many bytes.
setExpectContinue :: RequestBuilder () #
Specify that this request should set the expectation that the server needs to approve the request before you send it.
This function is special: in a PUT or POST request, http-streams
will wait for the server to reply with an HTTP/1.1 100 Continue
status before sending the entity body. This is handled internally;
you will get the real response (be it successful 2xx, client error,
4xx, or server error 5xx) in receiveResponse
. In theory, it
should be 417 if the expectation failed.
Only bother with this if you know the service you're talking to
requires clients to send an Expect: 100-continue
header and will
handle it properly. Most servers don't do any precondition checking,
automatically send an intermediate 100 response, and then just read
the body regardless, making this a bit of a no-op in most cases.
setTransferEncoding :: RequestBuilder () #
Override the default setting about how the entity body will be sent.
This function is special: this explicitly sets the Transfer-Encoding:
header to chunked
and will instruct the library to actually tranfer the
body as a stream ("chunked transfer encoding"). See setContentLength
for
forcing the opposite. You really won't need this in normal operation, but
some people are control freaks.
setHeader :: ByteString -> ByteString -> RequestBuilder () #
Set a generic header to be sent in the HTTP request. The other methods in the RequestBuilder API are expressed in terms of this function, but we recommend you use them where offered for their stronger types.
Sending HTTP request
A description of the request that will be sent to the server. Note
unlike other HTTP libraries, the request body is not a part of this
object; that will be streamed out by you when actually sending the
request with sendRequest
.
Request
has a useful Show
instance that will output the request
line and headers (as it will be sent over the wire but with the \r
characters stripped) which can be handy for debugging.
Note that the actual Host:
header is not set until the request is sent,
so you will not see it in the Show instance (unless you call setHostname
to override the value inherited from the Connection
).
A description of the response received from the server. Note
unlike other HTTP libraries, the response body is not a part
of this object; that will be streamed in by you when calling
receiveResponse
.
Like Request
, Response
has a Show
instance that will output
the status line and response headers as they were received from the
server.
getHostname :: Connection -> Request -> ByteString Source #
Get the virtual hostname that will be used as the Host:
header in
the HTTP 1.1 request. Per RFC 2616 § 14.23, this will be of the form
hostname:port
if the port number is other than the default, ie 80
for HTTP.
sendRequest :: Connection -> Request -> (OutputStream Builder -> IO α) -> IO α Source #
Having composed a Request
object with the headers and metadata for
this connection, you can now send the request to the server, along
with the entity body, if there is one. For the rather common case of
HTTP requests like GET
that don't send data, use emptyBody
as the
output stream:
sendRequest c q emptyBody
For PUT
and POST
requests, you can use fileBody
or
inputStreamBody
to send content to the server, or you can work with
the io-streams
API directly:
sendRequest c q (\o -> Streams.write (Just (Builder.fromString "Hello World\n")) o)
emptyBody :: OutputStream Builder -> IO () Source #
Use this for the common case of the HTTP methods that only send
headers and which have no entity body, i.e. GET
requests.
fileBody :: FilePath -> OutputStream Builder -> IO () Source #
Specify a local file to be sent to the server as the body of the request.
You use this partially applied:
sendRequest c q (fileBody "/etc/passwd")
Note that the type of (fileBody "/path/to/file")
is just what
you need for the third argument to sendRequest
, namely
>>>
:t filePath "hello.txt"
:: OutputStream Builder -> IO ()
inputStreamBody :: InputStream ByteString -> OutputStream Builder -> IO () Source #
Read from a pre-existing InputStream
and pipe that through to the
connection to the server. This is useful in the general case where
something else has handed you stream to read from and you want to use
it as the entity body for the request.
You use this partially applied:
i <- getStreamFromVault -- magic, clearly sendRequest c q (inputStreamBody i)
This function maps "Builder.fromByteString" over the input, which will be efficient if the ByteString chunks are large.
encodedFormBody :: [(ByteString, ByteString)] -> OutputStream Builder -> IO () Source #
Specify name/value pairs to be sent to the server in the manner used by web browsers when submitting a form via a POST request. Parameters will be URL encoded per RFC 2396 and combined into a single string which will be sent as the body of your request.
You use this partially applied:
let nvs = [("name","Kermit"), ("type","frog")] ("role","stagehand")] sendRequest c q (encodedFormBody nvs)
Note that it's going to be up to you to call setContentType
with
a value of "application/x-www-form-urlencoded"
when building the
Request object; the postForm
convenience (which uses this
encodedFormBody
function) takes care of this for you, obviously.
Processing HTTP response
receiveResponse :: Connection -> (Response -> InputStream ByteString -> IO β) -> IO β Source #
Handle the response coming back from the server. This function
hands control to a handler function you supply, passing you the
Response
object with the response headers and an InputStream
containing the entity body.
For example, if you just wanted to print the first chunk of the content from the server:
receiveResponse c (\p i -> do m <- Streams.read i case m of Just bytes -> putStr bytes Nothing -> return ())
Obviously, you can do more sophisticated things with the
InputStream
, which is the whole point of having an io-streams
based HTTP client library.
The final value from the handler function is the return value of
receiveResponse
, if you need it.
Throws UnexpectedCompression
if it doesn't know how to handle the
compression format used in the response.
receiveResponseRaw :: Connection -> (Response -> InputStream ByteString -> IO β) -> IO β Source #
This is a specialized variant of receiveResponse
that explicitly does
not handle the content encoding of the response body stream (it will not
decompress anything). Unless you really want the raw gzipped content coming
down from the server, use receiveResponse
.
data UnexpectedCompression Source #
type StatusCode = Int #
getStatusCode :: Response -> StatusCode #
Get the HTTP response status code.
getStatusMessage :: Response -> ByteString #
Get the HTTP response status message. Keep in mind that this is
not normative; whereas getStatusCode
values are authoritative.
getHeader :: Response -> ByteString -> Maybe ByteString #
Lookup a header in the response. HTTP header field names are
case-insensitive, so you can specify the name to lookup however you
like. If the header is not present Nothing
will be returned.
let n = case getHeader p "Content-Length" of Just x' -> read x' :: Int Nothing -> 0
which of course is essentially what goes on inside the client library when it receives a response from the server and has to figure out how many bytes to read.
There is a fair bit of complexity in some of the other HTTP response fields, so there are a number of specialized functions for reading those values where we've found them useful.
debugHandler :: Response -> InputStream ByteString -> IO () Source #
Print the response headers and response body to stdout
. You can
use this with receiveResponse
or one of the convenience functions
when testing. For example, doing:
c <- openConnection "kernel.operationaldynamics.com" 58080 let q = buildRequest1 $ do http GET "/time" sendRequest c q emptyBody receiveResponse c debugHandler
would print out:
HTTP/1.1 200 OK Transfer-Encoding: chunked Content-Type: text/plain Vary: Accept-Encoding Server: Snap/0.9.2.4 Content-Encoding: gzip Date: Mon, 21 Jan 2013 06:13:37 GMT Mon 21 Jan 13, 06:13:37.303Z
or thereabouts.
concatHandler :: Response -> InputStream ByteString -> IO ByteString Source #
Sometimes you just want the entire response body as a single blob.
This function concatonates all the bytes from the response into a
ByteString. If using the main http-streams
API, you would use it
as follows:
... x' <- receiveResponse c concatHandler ...
The methods in the convenience API all take a function to handle the
response; this function is passed directly to the receiveResponse
call underlying the request. Thus this utility function can be used
for get
as well:
x' <- get "http://www.example.com/document.txt" concatHandler
Either way, the usual caveats about allocating a single object from streaming I/O apply: do not use this if you are not absolutely certain that the response body will fit in a reasonable amount of memory.
Note that this function makes no discrimination based on the response's HTTP status code. You're almost certainly better off writing your own handler function.
concatHandler' :: Response -> InputStream ByteString -> IO ByteString Source #
A special case of concatHandler
, this function will return the
entire response body as a single ByteString, but will throw
HttpClientError
if the response status code was other than 2xx
.
data HttpClientError Source #
jsonHandler :: FromJSON α => Response -> InputStream ByteString -> IO α Source #
If you're working with a data stream that is in application/json
,
then chances are you're using aeson
to handle the JSON to Haskell
decoding. If so, then this helper function might be of use.
v <- get "http://api.example.com/v1/" jsonHandler
This function feeds the input body to the json'
attoparsec
Parser in order to get the aeson Value type. This is then
marshalled to your type represeting the source data, via the FromJSON
typeclass.
The above example was actually insufficient; when working with
aeson
you need to fix the type so it knows what FromJSON instance
to use. Let's say you're getting Person objects, then it would be
v <- get "http://api.example.com/v1/person/461" jsonHandler :: IO Person
assuming your Person type had a FromJSON instance, of course.
Note
This function parses a single top level JSON object or array, which
is all you're supposed to get if it's a valid document. People do
all kinds of crazy things though, so beware. Also, this function (like the
"concatHander" convenience) loads the entire response into memory; it's
not streaming; if you're receiving a document which is (say) a very
long array of objects then you may want to implement your own
handler function, perhaps using "Streams.parserToInputStream" and
the Parser
combinators directly — with a result type of
InputStream Value, perhaps — by which you could then iterate over
the Values one at a time in constant space.
Resource cleanup
closeConnection :: Connection -> IO () Source #
Shutdown the connection. You need to call this release the
underlying socket file descriptor and related network resources. To
do so reliably, use this in conjunction with openConnection
in a
call to bracket
:
-- -- Make connection, cleaning up afterward -- foo :: IO ByteString foo = bracket (openConnection "localhost" 80) (closeConnection) (doStuff) -- -- Actually use Connection to send Request and receive Response -- doStuff :: Connection -> IO ByteString
or, just use withConnection
.
While returning a ByteString is probably the most common use case,
you could conceivably do more processing of the response in doStuff
and have it and foo
return a different type.
withConnection :: IO Connection -> (Connection -> IO γ) -> IO γ Source #
Given an IO
action producing a Connection
, and a computation
that needs one, runs the computation, cleaning up the
Connection
afterwards.
x <- withConnection (openConnection "s3.example.com" 80) $ (\c -> do let q = buildRequest1 $ do http GET "/bucket42/object/149" sendRequest c q emptyBody ... return "blah")
which can make the code making an HTTP request a lot more straight-forward.
Wraps Control.Exception
's bracket
.
Convenience APIs
Some simple functions for making requests with useful defaults.
There's no head
function for the usual reason of needing to
avoid collision with Prelude
.
These convenience functions work with http
and https
, but
note that if you retrieve an https
URL, you must wrap your
main
function with withOpenSSL
to initialize the
native openssl library code.
type URL = ByteString Source #
:: URL | Resource to GET from. |
-> (Response -> InputStream ByteString -> IO β) | Handler function to receive the response from the server. |
-> IO β |
Issue an HTTP GET request and pass the resultant response to the supplied handler function. This code will silently follow redirects, to a maximum depth of 5 hops.
The handler function is as for receiveResponse
, so you can use one
of the supplied convenience handlers if you're in a hurry:
x' <- get "http://www.bbc.co.uk/news/" concatHandler
But as ever the disadvantage of doing this is that you're not doing
anything intelligent with the HTTP response status code. If you want
an exception raised in the event of a non 2xx
response, you can use:
x' <- get "http://www.bbc.co.uk/news/" concatHandler'
but for anything more refined you'll find it easy to simply write your own handler function.
Throws TooManyRedirects
if more than 5 redirects are thrown.
data TooManyRedirects Source #
:: URL | Resource to POST to. |
-> ContentType | MIME type of the request body being sent. |
-> (OutputStream Builder -> IO α) | Handler function to write content to server. |
-> (Response -> InputStream ByteString -> IO β) | Handler function to receive the response from the server. |
-> IO β |
Send content to a server via an HTTP POST request. Use this
function if you have an OutputStream
with the body content.
:: URL | Resource to POST to. |
-> [(ByteString, ByteString)] | List of name=value pairs. Will be sent URL-encoded. |
-> (Response -> InputStream ByteString -> IO β) | Handler function to receive the response from the server. |
-> IO β |
Send form data to a server via an HTTP POST request. This is the
usual use case; most services expect the body to be MIME type
application/x-www-form-urlencoded
as this is what conventional
web browsers send on form submission. If you want to POST to a URL
with an arbitrary Content-Type, use post
.
:: URL | Resource to PUT to. |
-> ContentType | MIME type of the request body being sent. |
-> (OutputStream Builder -> IO α) | Handler function to write content to server. |
-> (Response -> InputStream ByteString -> IO β) | Handler function to receive the response from the server. |
-> IO β |
Place content on the server at the given URL via an HTTP PUT
request, specifying the content type and a function to write the
content to the supplied OutputStream
. You might see:
put "http://s3.example.com/bucket42/object149" "text/plain" (fileBody "hello.txt") (\p i -> do putStr $ show p Streams.connect i stdout)
Secure connections
openConnectionSSL :: SSLContext -> Hostname -> Port -> IO Connection Source #
Open a secure connection to a web server.
import OpenSSL (withOpenSSL) main :: IO () main = do ctx <- baselineContextSSL c <- openConnectionSSL ctx "api.github.com" 443 ... closeConnection c
If you want to tune the parameters used in making SSL connections, manually specify certificates, etc, then setup your own context:
import OpenSSL.Session (SSLContext) import qualified OpenSSL.Session as SSL ... ctx <- SSL.context ...
See OpenSSL.Session.
Crypto is as provided by the system openssl
library, as wrapped
by the HsOpenSSL
package and openssl-streams
.
/There is no longer a need to call withOpenSSL
explicitly; the
initialization is invoked once per process for you/
baselineContextSSL :: IO SSLContext Source #
Creates a basic SSL context. This is the SSL context used if you make an
"https://"
request using one of the convenience functions. It
configures OpenSSL to use the default set of ciphers.
On Linux, OpenBSD and FreeBSD systems, this function also configures OpenSSL to verify certificates using the system/distribution supplied certificate authorities' certificates
On other systems, no certificate validation is performed by the
generated SSLContext
because there is no canonical place to find
the set of system certificates. When using this library on such system,
you are encouraged to install the system
certificates somewhere and create your own SSLContext
.
modifyContextSSL :: (SSLContext -> IO SSLContext) -> IO () Source #
Modify the context being used to configure the SSL tunnel used by
the convenience API functions to make https://
connections. The
default is that setup by baselineContextSSL
.
establishConnection :: URL -> IO Connection Source #
Given a URL, work out whether it is normal, secure, or unix domain, and then open the connection to the webserver including setting the appropriate default port if one was not specified in the URL. This is what powers the convenience API, but you may find it useful in composing your own similar functions.
For example (on the assumption that your server behaves when given
an absolute URI as the request path), this will open a connection
to server www.example.com
port 443
and request /photo.jpg
:
let url = "https://www.example.com/photo.jpg" c <- establishConnection url let q = buildRequest1 $ do http GET url ...
Testing support
:: ByteString | will be used as the |
-> IO () | an action to be called when the connection is terminated. |
-> OutputStream ByteString | write end of the HTTP client-server connection. |
-> InputStream ByteString | read end of the HTTP client-server connection. |
-> IO Connection |
Create a raw Connection object from the given parts. This is primarily of use when teseting, for example:
fakeConnection :: IO Connection fakeConnection = do o <- Streams.nullOutput i <- Streams.nullInput c <- makeConnection "www.example.com" (return()) o i return c
is an idiom we use frequently in testing and benchmarking, usually replacing the InputStream with something like:
x' <- S.readFile "properly-formatted-response.txt" i <- Streams.fromByteString x'
If you're going to do that, keep in mind that you must have CR-LF pairs after each header line and between the header and body to be compliant with the HTTP protocol; otherwise, parsers will reject your message.
getHeaders :: HttpType τ => τ -> Headers #
Get the Headers from a Request or Response. Most people do not need
this; for most cases you just need to get a header or two from the
response, for which you can use getHeader
. On the other hand, if you
do need to poke around in the raw headers,
import Network.Http.Types
will give you functions like lookupHeader
and updateHeader
to to
work with.
getHeadersFull :: Connection -> Request -> Headers Source #
Get the headers that will be sent with this request. You likely won't need this but there are some corner cases where people need to make calculations based on all the headers before they go out over the wire.
If you'd like the request headers as an association list, import the header functions:
import Network.Http.Types
then use retreiveHeaders
as follows:
>>>
let kvs = retreiveHeaders $ getHeadersFull c q
>>>
:t kvs
:: [(ByteString, ByteString)]
Deprecated
getRequestHeaders :: Connection -> Request -> [(ByteString, ByteString)] Source #
Deprecated: use retrieveHeaders . getHeadersFull instead