Requests-Scala is a Scala port of the popular Python Requests HTTP client. Requests-Scala aims to provide the same API and user-experience as the original Requests: flexible, intuitive, and straightforward to use.
If you use Requests-Scala and like it, you will probably enjoy the following book by the Author:
Hands-on Scala has uses Requests-Scala extensively throughout the book, and has the entirety of Chapter 12: Working with HTTP APIs dedicated to the library. Hands-on Scala is a great way to level up your skills in Scala in general and Requests-Scala in particular.
You can also support it by donating to our Patreon:
For a hands-on introduction to this library, take a look at the following blog post:
- Requests-Scala 0.8.0
Use the following import to get you started:
ivy"com.lihaoyi::requests:0.8.0" // mill
"com.lihaoyi" %% "requests" % "0.8.0" // sbt
compile "com.lihaoyi:requests_2.12:0.8.0" //gradle
val r = requests.get("https://api.github.com/users/lihaoyi")
r.statusCode
// 200
r.headers("content-type")
// Buffer("application/json; charset=utf-8")
r.text
// {"login":"lihaoyi","id":934140,"node_id":"MDQ6VXNlcjkzNDE0MA==",...
Making your first HTTP request is simple: simply call requests.get
with the
URL you want, and requests will fetch it for you.
You can also call requests.post
, requests.put
, etc. to make other kinds of
HTTP requests:
val r = requests.post("http://httpbin.org/post", data = Map("key" -> "value"))
val r = requests.put("http://httpbin.org/put", data = Map("key" -> "value"))
val r = requests.delete("http://httpbin.org/delete")
val r = requests.head("http://httpbin.org/head")
val r = requests.options("http://httpbin.org/get")
// dynamically choose what HTTP method to use
val r = requests.send("put")("http://httpbin.org/put", data = Map("key" -> "value"))
val r = requests.get(
"http://httpbin.org/get",
params = Map("key1" -> "value1", "key2" -> "value2")
)
You can pass in URL parameters to GET requests via the params
argument; simply
pass in a Map[String, String]
. As seen earlier, when passing in POST or PUT
parameters, you instead need the data
argument:
val r = requests.post("http://httpbin.org/post", data = Map("key" -> "value"))
val r = requests.put("http://httpbin.org/put", data = Map("key" -> "value"))
Apart from POSTing key-value pairs, you can also POST String
s, Array[Byte]
s,
java.io.File
s, java.nio.file.Path
s, and requests.MultiPart
uploads:
requests.post("https://httpbin.org/post", data = "Hello World")
requests.post("https://httpbin.org/post", data = Array[Byte](1, 2, 3))
requests.post("https://httpbin.org/post", data = new java.io.File("thing.json"))
requests.post("https://httpbin.org/post", data = java.nio.file.Paths.get("thing.json"))
The data
parameter also supports anything that implements the
Writable interface, such as
ujson.Values,
uPickle's upickle.default.writable
values,
or Scalatags's Tag
s
val r = requests.get("https://api.github.com/events")
r.statusCode
// 200
r.headers("content-type")
// Buffer("application/json; charset=utf-8")
As seen earlier, you can use .statusCode
and .headers
to see the relevant
metadata of your HTTP response. The response data is in the .data
field of the
Response
object. Most often, it's text, which you can decode using the .text
property as shown below:
r.text
// [{"id":"7990061484","type":"PushEvent","actor":{"id":6242317,"login":...
If you want the raw bytes of the response, use r.contents
r.contents
// Array(91, 123, 34, 105, 100, 34, 58, 34, 55, 57, 57, 48, 48, 54, 49, ...
os.write(
os.pwd / "file.json",
requests.get.stream("https://api.github.com/events")
)
Requests exposes the requests.get.stream
(and equivalent
requests.post.stream
, requests.put.stream
, etc.) functions for you to
perform streaming uploads/downloads without needing to load the entire
request/response into memory. This is useful if you are upload/downloading large
files or data blobs. .stream
returns a
Readable value, that can be then
passed to methods like os.write,
fastparse.parse
or upickle.default.read
to handle the received data in a
streaming fashion:
ujson.read(requests.get.stream("https://api.github.com/events"))
Since requests.post
and requests.put
both take a data: geny.Writable
parameter, you can even chain requests together, taking the data returned from
one HTTP request and feeding it into another:
os.write(
os.pwd / "chained.json",
requests.post.stream(
"https://httpbin.org/post",
data = requests.get.stream("https://api.github.com/events")
)
)
requests.*.stream
should make it easy for you to work with data
too big to fit in memory, while still benefiting from most of Requests' friendly
& intuitive API.
Requests does not provide any built-in JSON support, but you can easily use a
third-party JSON library to work with it. This example shows how to use
uJson talk to a HTTP endpoint that requires a
JSON-formatted body, either using upickle.default.stream
:
requests.post(
"https://api.github.com/some/endpoint",
data = upickle.default.stream(Map("user-agent" -> "my-app/0.0.1"))
)
Or by constructing ujson.Value
s directly
requests.post(
"https://api.github.com/some/endpoint",
data = ujson.Obj("user-agent" -> "my-app/0.0.1")
)
In both cases, the upload occurs efficiently in a streaming fashion, without materializing the entire JSON blob in memory.
It is equally easy ot use uJson to deal with JSON returned in the response from the server:
val r = requests.get("https://api.github.com/events")
val json = ujson.read(r.text)
json.arr.length
// 30
json.arr(0).obj.keys
// Set("id", "type", "actor", "repo", "payload", "public", "created_at")
While Requests-Scala doesn't come bundled with JSON functionality, it is trivial to use it together with any other 3rd party JSON library (I like uJson) So just pick whatever library you want.
val r = requests.post(
"http://httpbin.org/post",
data = requests.MultiPart(
requests.MultiItem("name", new java.io.File("build.sc"), "file.txt"),
// you can upload strings, and file name is optional
requests.MultiItem("name2", "Hello"),
// bytes arrays are ok too
requests.MultiItem("name3", Array[Byte](1, 2, 3, 4))
)
)
Multipart uploads are done by passing requests.MultiPart
/requests.MultiItem
to the data
parameter. Each MultiItem
needs a name and a data-source, which
can be a String
, Array[Byte]
, java.io.File
, or java.nio.file.Path
. Each
MultiItem
can optionally take a file name that will get sent to the server
Earlier you already saw how to use the params
and data
arguments. Apart from
those, the requests.get
method takes in a lot of arguments you can use to
configure it, e.g. passing in custom headers:
requests.get(
"https://api.github.com/some/endpoint",
headers = Map("user-agent" -> "my-app/0.0.1")
)
readTimeout
s and connectTimeout
s:
requests.get("https://httpbin.org/delay/1", readTimeout = 10)
// TimeoutException
requests.get("https://httpbin.org/delay/1", readTimeout = 1500)
// ok
requests.get("https://httpbin.org/delay/3", readTimeout = 1500)
// TimeoutException
requests.get("https://httpbin.org/delay/1", connectTimeout = 10)
// TimeoutException
requests.get("https://httpbin.org/delay/1", connectTimeout = 1500)
// ok
requests.get("https://httpbin.org/delay/3", connectTimeout = 1500)
// ok
Configuration for compressing the request data
upload with Gzip or Deflate via
the compress
parameter:
requests.post(
"https://httpbin.org/post",
compress = requests.Compress.None,
data = "Hello World"
)
requests.post(
"https://httpbin.org/post",
compress = requests.Compress.Gzip,
data = "I am cow"
)
requests.post(
"https://httpbin.org/post",
compress = requests.Compress.Deflate,
data = "Hear me moo"
)
Or to disabling the de-compression of the response data
being downloaded via
the autoCompress
parameter, in case you want the un-compressed data blob for
whatever reason:
requests.get("https://httpbin.org/gzip").contents.length
// 250
requests.get("https://httpbin.org/gzip", autoDecompress=false).contents.length
// 201
requests.get("https://httpbin.org/deflate").contents.length
// 251
requests.get("https://httpbin.org/deflate", autoDecompress=false).contents.length
// 188
Note that by default, compression of fixed-size in-memory input (String
s,
Array[Byte]
s, ...) buffers up the compressed data in memory before uploading
it. Compression of unknown-length/not-in-memory data (files, InputStream
s,
...) doesn't perform this buffering and uses chunked transfer encoding, as
normal. If you want to avoid buffering in memory and are willing to use chunked
transfer encoding for in-memory data, wrap it in an inputstream (e.g.
Array[Byte]
can be wrapped in a ByteArrayInputStream
)
You can take the cookies that result from one HTTP request and pass them into a subsequent HTTP request:
val r = requests.get("https://httpbin.org/cookies/set?freeform=test")
r.cookies
// Map("freeform" -> freeform=test)
val r2 = requests.get("https://httpbin.org/cookies", cookies = r.cookies)
r2.text
// {"cookies":{"freeform":"test"}}
This is a common pattern, e.g. to maintain an authentication/login session across multiple requests. However, it may be easier to instead use Sessions...
Requests handles redirects automatically for you, up to a point:
val r = requests.get("http://www.github.com")
r.url
// https://github.com/
r.history
// Some(Response("https://www.github.com", 301, "Moved Permanently", ...
r.history.get.history
// Some(Response("http://www.github.com", 301, "Moved Permanently", ...
r.history.get.history.get.history
// None
As you can see, the request to http://www.github.com
was first redirected to
https://www.github.com
, and then to https://github.com/
. Requests by default
only follows up to 5 redirects in a row, though this is configurable via the
maxRedirects
parameter:
val r0 = requests.get("http://www.github.com", maxRedirects = 0)
// Response("http://www.github.com", 301, "Moved Permanently", ...
r0.history
// None
val r1 = requests.get("http://www.github.com", maxRedirects = 1)
// Response("http://www.github.com", 301, "Moved Permanently", ...
r1.history
// Some(Response("http://www.github.com", 301, "Moved Permanently", ...
r1.history.get.history
// None
As you can see, you can use maxRedirects = 0
to disable redirect handling
completely, or use another number to control how many redirects Requests follows
before giving up.
All of the intermediate responses in a redirect chain are available in a
Response's .history
field; each .history
points 1 response earlier, forming
a linked list of Response
objects until the earliest response has a value of
None
. You can crawl up this linked list if you want to inspect the headers or
other metadata of the intermediate redirects that brought you to your final value.
To use client certificate you need a PKCS 12 archive with private key and certificate.
requests.get(
"https://client.badssl.com",
cert = "./badssl.com-client.p12"
)
If the p12 archive is password protected you can provide a second parameter:
requests.get(
"https://client.badssl.com",
cert = ("./badssl.com-client.p12", "password")
)
For test environments you may want to combine cert
with the verifySslCerts = false
option (if you have self signed SSL certificates on test servers).
requests.get(
"https://client.badssl.com",
cert = ("./badssl.com-client.p12", "password"),
verifySslCerts = false
)
You can also use a sslContext to provide a more customized ssl configuration
val sslContext: SSLContext = //initialized sslContext
requests.get(
"https://client.badssl.com",
sslcontext = sslContext
)
A requests.Session
automatically handles sending/receiving/persisting cookies
for you across multiple requests:
val s = requests.Session()
val r = s.get("https://httpbin.org/cookies/set?freeform=test")
val r2 = s.get("https://httpbin.org/cookies")
r2.text
// {"cookies":{"freeform":"test"}}
If you want to deal with a website that uses cookies, it's usually easier to use
a requests.Session
rather than passing around cookie
variables manually.
Apart from persisting cookies, sessions are also useful for consolidating common configuration that you want to use across multiple requests, e.g. custom headers, cookies or other things:
val s = requests.Session(
headers = Map("x-special-header" -> "omg"),
cookieValues = Map("cookie" -> "vanilla")
)
val r1 = s.get("https://httpbin.org/cookies")
r1.text
// {"cookies":{"cookie":"vanilla"}}
val r2 = s.get("https://httpbin.org/headers")
r2.text
// {"headers":{"X-Special-Header":"omg", ...}}
There is a whole zoo of HTTP clients in the Scala ecosystem. Akka-http, Play-WS, STTP, HTTP4S, Scalaj-HTTP, RosHTTP, Dispatch. Nevertheless, none of them come close to the ease and weightlessness of using Kenneth Reitz's Requests library: too many implicits, operators, builders, monads, and other things.
When I want to make a HTTP request, I do not want to know about
.unsafeRunSync
, infix methods like svc OK as.String
, or define implicit
ActorSystem
s, ActorMaterializer
s, and ExecutionContext
s. So far
sttp and
scalaj-http come closest to what I
want, but still fall short: both still use a pattern of fluent builders that to
me doesn't fit how I think when making a HTTP request. I just want to call one
function to make a HTTP request, and get back my HTTP response.
Most people will never reach the scale that asynchrony matters, and most of those who do reach that scale will only need it in a small number of specialized places, not everywhere.
Compare the getting-started code necessary for Requests-Scala against some other common Scala HTTP clients:
// Requests-Scala
val r = requests.get(
"https://api.github.com/search/repositories",
params = Map("q" -> "http language:scala", "sort" -> "stars")
)
r.text
// {"login":"lihaoyi","id":934140,"node_id":"MDQ6VXNlcjkzNDE0MA==",...
// Akka-Http
import akka.actor.ActorSystem
import akka.http.scaladsl.Http
import akka.http.scaladsl.model._
import akka.stream.ActorMaterializer
import scala.concurrent.Future
import scala.util.{ Failure, Success }
implicit val system = ActorSystem()
implicit val materializer = ActorMaterializer()
// needed for the future flatMap/onComplete in the end
implicit val executionContext = system.dispatcher
val responseFuture: Future[HttpResponse] = Http().singleRequest(HttpRequest(uri = "http://akka.io"))
responseFuture
.onComplete {
case Success(res) => println(res)
case Failure(_) => sys.error("something wrong")
}
// Play-WS
import akka.actor.ActorSystem
import akka.stream.ActorMaterializer
import play.api.libs.ws._
import play.api.libs.ws.ahc._
import scala.concurrent.Future
import DefaultBodyReadables._
import scala.concurrent.ExecutionContext.Implicits._
// Create Akka system for thread and streaming management
implicit val system = ActorSystem()
implicit val materializer = ActorMaterializer()
// Create the standalone WS client
// no argument defaults to a AhcWSClientConfig created from
// "AhcWSClientConfigFactory.forConfig(ConfigFactory.load, this.getClass.getClassLoader)"
val wsClient = StandaloneAhcWSClient()
wsClient.url("http://www.google.com").get()
.map { response ⇒
val statusText: String = response.statusText
val body = response.body[String]
println(s"Got a response $statusText")
}.
andThen { case _ => wsClient.close() }
andThen { case _ => system.terminate() }
// Http4s
import org.http4s.client.dsl.io._
import org.http4s.headers._
import org.http4s.MediaType
val request = GET(
Uri.uri("https://my-lovely-api.com/"),
Authorization(Credentials.Token(AuthScheme.Bearer, "open sesame")),
Accept(MediaType.application.json)
)
httpClient.expect[String](request)
// sttp
import sttp.client3._
val request = basicRequest.response(asStringAlways)
.get(uri"https://api.github.com/search"
.addParams(Map("q" -> "http language:scala", "sort" -> "stars")))
val backend = HttpURLConnectionBackend()
val response = backend.send(request)
println(response.body)
// Dispatch
import dispatch._, Defaults._
val svc = url("http://api.hostip.info/country.php")
val country = Http.default(svc OK as.String)
The existing clients require a complex mix of imports, implicits, operators, and DSLs. The goal of Requests-Scala is to do away with all of that: your HTTP request is just a function call that takes parameters; that is all you need to know.
As it turns out, Kenneth Reitz's Requests is
not a lot of code.
Most of the heavy lifting is done in other libraries, and his library is a just
thin-shim that makes the API 10x better. It turns out on the JVM most of the
heavy lifting is also done for you, by java.net.HttpUrlConnection
in the
simplest case, and other libraries like
AsyncHttpClient for more
advanced use cases.
Given that's the case, how hard can it be to port over a dozen Python files to Scala? This library attempts to do that: class by class, method by method, keyword-argument by keyword-argument. Not everything has been implemented yet, some things differ (some avoidably, some unavoidably), and it's nowhere near as polished, but you should definitely try it out as the HTTP client for your next codebase or project!
- Update Geny to 1.0.0 #120
- Fix issue with data buffers not being flushed when compression is enabled #108
- Allow
requests.send(method)(...)
to dynamically choose a HTTP method #94 - Avoid crashing on gzipped HEAD requests #95
- All exceptions now inherit from a
RequestsException
base class
- Add support for Scala 3.0.0-RC2
-
requests.Response
now implements thegeny.Readable
interface, and can be directly passed to compatible APIs likeujson.read
oros.write
-
Add support for custom SSL certs
-
Allow body content for DELETE requests
- Made
requests.{get,post,put,delete,head,options,patch}.stream
return a Readable, allowing upickle and fastparse to operate directly on the streaming input
requests.{get,post,put,delete,head,options,patch}
now throw arequests.RequestFailedException(val response: Response)
if a non-2xx status code is received. You can disable throwing the exception by passing incheck = false
requests.{get,post,put,delete,head,options,patch}.stream
now returns a Writable instead of taking callbacks.
- Support for uploading geny.Writable data types in request bodies.
- Support for Scala 2.13.0 final
- Support
PATCH
and other verbs
- Support for
Bearer
token auth
RequestBlob
headers no longer over-write session headers
- Allow POSTs to take URL parameters
- Return response body for all 2xx response codes
- Always set
Content-Length
to 0 when request body is empty
- First Release