Alamofire/Alamofire
Alamofire is an HTTP networking library written in Swift.
Features
- [x] Chainable Request / Response methods
- [x] URL / JSON / plist Parameter Encoding
- [x] Upload File / Data / Stream
- [x] Download using Request or Resume data
- [x] Authentication with NSURLCredential
- [x] HTTP Response Validation
- [x] Progress Closure & NSProgress
- [x] cURL Debug Output
- [x] Comprehensive Unit Test Coverage
- [x] Complete Documentation
Requirements
- iOS 7.0+ / Mac OS X 10.9+
- Xcode 6.3
Communication
- If you need help, use Stack Overflow. (Tag ‘alamofire’)
- If you’d like to ask a general question, use Stack Overflow.
- If you found a bug, open an issue.
- If you have a feature request, open an issue.
- If you want to contribute, submit a pull request.
Installation
Embedded frameworks require a minimum deployment target of iOS 8 or OS X Mavericks.
To use Alamofire with a project targeting iOS 7, you must include all Swift files located inside the
Sourcedirectory directly in your project. See the ‘Source File’ section for additional instructions.
CocoaPods
CocoaPods is a dependency manager for Cocoa projects.
CocoaPods 0.36 adds supports for Swift and embedded frameworks. You can install it with the following command:
$ gem install cocoapods
To integrate Alamofire into your Xcode project using CocoaPods, specify it in your Podfile:
source 'https://github.com/CocoaPods/Specs.git'
platform :ios, '8.0'
use_frameworks!
pod 'Alamofire', '~> 1.2'
Then, run the following command:
$ pod install
Carthage
Carthage is a decentralized dependency manager that automates the process of adding frameworks to your Cocoa application.
You can install Carthage with Homebrew using the following command:
$ brew update
$ brew install carthage
To integrate Alamofire into your Xcode project using Carthage, specify it in your Cartfile:
github "Alamofire/Alamofire" >= 1.2
Manually
If you prefer not to use either of the aforementioned dependency managers, you can integrate Alamofire into your project manually.
Embedded Framework
- Add Alamofire as a submodule by opening the Terminal,
cd-ing into your top-level project directory, and entering the following command:
$ git submodule add https://github.com/Alamofire/Alamofire.git
-
Open the new
Alamofirefolder, and drag theAlamofire.xcodeprojinto the Project Navigator of your application’s Xcode project.It should appear nested underneath your application’s blue project icon. Whether it is above or below all the other Xcode groups does not matter.
-
Select the
Alamofire.xcodeprojin the Project Navigator and verify the deployment target matches that of your application target. -
Next, select your application project in the Project Navigator (blue project icon) to navigate to the target configuration window and select the application target under the “Targets” heading in the sidebar.
-
In the tab bar at the top of that window, open the “General” panel.
-
Click on the
+button under the “Embedded Binaries” section. -
You will see two different
Alamofire.xcodeprojfolders each with two different versions of theAlamofire.frameworknested inside aProductsfolder.It does not matter which
Productsfolder you choose from, but it does matter whether you choose the top or bottomAlamofire.framework. -
Select the top
Alamofire.frameworkfor iOS and the bottom one for OS X.You can verify which one you selected by inspecting the build log for your project. The build target for
Alamofirewill be listed as eitherAlamofire iOSorAlamofire OSX. -
And that’s it!
The
Alamofire.frameworkis automagically added as a target dependency, linked framework and embedded framework in a copy files build phase which is all you need to build on the simulator and a device.
Source File
For application targets that do not support embedded frameworks, such as iOS 7, Alamofire can be integrated by adding all the Swift files located inside the Source directory (Source/*.swift) directly into your project. Note that you will no longer need to import Alamofire since you are not actually loading a framework. Additionally, any of the calling conventions described in the ‘Usage’ section with the Alamofire prefix would instead omit it (for example, Alamofire.request becomes request), since this functionality is incorporated into the top-level namespace.
Usage
Making a Request
import Alamofire
Alamofire.request(.GET, "http://httpbin.org/get")
Response Handling
Alamofire.request(.GET, "http://httpbin.org/get", parameters: ["foo": "bar"])
.response { (request, response, data, error) in
println(request)
println(response)
println(error)
}
Networking in Alamofire is done asynchronously. Asynchronous programming may be a source of frustration to programmers unfamiliar with the concept, but there are very good reasons for doing it this way.
Rather than blocking execution to wait for a response from the server, a callback is specified to handle the response once it’s received. The result of a request is only available inside the scope of a response handler. Any execution contingent on the response or data received from the server must be done within a handler.
Response Serialization
Built-in Response Methods
response()responseString(encoding: NSStringEncoding)responseJSON(options: NSJSONReadingOptions)responsePropertyList(options: NSPropertyListReadOptions)
Response String Handler
Alamofire.request(.GET, "http://httpbin.org/get")
.responseString { (_, _, string, _) in
println(string)
}
Response JSON Handler
Alamofire.request(.GET, "http://httpbin.org/get")
.responseJSON { (_, _, JSON, _) in
println(JSON)
}
Chained Response Handlers
Response handlers can even be chained:
Alamofire.request(.GET, "http://httpbin.org/get")
.responseString { (_, _, string, _) in
println(string)
}
.responseJSON { (_, _, JSON, _) in
println(JSON)
}
HTTP Methods
Alamofire.Method lists the HTTP methods defined in RFC 7231 §4.3:
public enum Method: String {
case OPTIONS = "OPTIONS"
case GET = "GET"
case HEAD = "HEAD"
case POST = "POST"
case PUT = "PUT"
case PATCH = "PATCH"
case DELETE = "DELETE"
case TRACE = "TRACE"
case CONNECT = "CONNECT"
}
These values can be passed as the first argument of the Alamofire.request method:
Alamofire.request(.POST, "http://httpbin.org/post")
Alamofire.request(.PUT, "http://httpbin.org/put")
Alamofire.request(.DELETE, "http://httpbin.org/delete")
Parameters
GET Request With URL-Encoded Parameters
Alamofire.request(.GET, "http://httpbin.org/get", parameters: ["foo": "bar"])
// http://httpbin.org/get?foo=bar
POST Request With URL-Encoded Parameters
let parameters = [
"foo": "bar",
"baz": ["a", 1],
"qux": [
"x": 1,
"y": 2,
"z": 3
]
]
Alamofire.request(.POST, "http://httpbin.org/post", parameters: parameters)
// HTTP body: foo=bar&baz[]=a&baz[]=1&qux[x]=1&qux[y]=2&qux[z]=3
Parameter Encoding
Parameters can also be encoded as JSON, Property List, or any custom format, using the ParameterEncoding enum:
enum ParameterEncoding {
case URL
case JSON
case PropertyList(format: NSPropertyListFormat,
options: NSPropertyListWriteOptions)
func encode(request: NSURLRequest,
parameters: [String: AnyObject]?) ->
(NSURLRequest, NSError?)
{ ... }
}
URL: A query string to be set as or appended to any existing URL query forGET,HEAD, andDELETErequests, or set as the body for requests with any other HTTP method. TheContent-TypeHTTP header field of an encoded request with HTTP body is set toapplication/x-www-form-urlencoded. Since there is no published specification for how to encode collection types, Alamofire follows the convention of appending[]to the key for array values (foo[]=1&foo[]=2), and appending the key surrounded by square brackets for nested dictionary values (foo[bar]=baz).JSON: UsesNSJSONSerializationto create a JSON representation of the parameters object, which is set as the body of the request. TheContent-TypeHTTP header field of an encoded request is set toapplication/json.PropertyList: UsesNSPropertyListSerializationto create a plist representation of the parameters object, according to the associated format and write options values, which is set as the body of the request. TheContent-TypeHTTP header field of an encoded request is set toapplication/x-plist.Custom: Uses the associated closure value to construct a new request given an existing request and parameters.
Manual Parameter Encoding of an NSURLRequest
let URL = NSURL(string: "http://httpbin.org/get")!
var request = NSURLRequest(URL: URL)
let parameters = ["foo": "bar"]
let encoding = Alamofire.ParameterEncoding.URL
(request, _) = encoding.encode(request, parameters: parameters)
POST Request with JSON-encoded Parameters
let parameters = [
"foo": [1,2,3],
"bar": [
"baz": "qux"
]
]
Alamofire.request(.POST, "http://httpbin.org/post", parameters: parameters, encoding: .JSON)
// HTTP body: {"foo": [1, 2, 3], "bar": {"baz": "qux"}}
Caching
Caching is handled on the system framework level by NSURLCache.
Uploading
Supported Upload Types
Uploading a File
let fileURL = NSBundle.mainBundle()
.URLForResource("Default",
withExtension: "png")
Alamofire.upload(.POST, "http://httpbin.org/post", file: fileURL)
Uploading w/Progress
Alamofire.upload(.POST, "http://httpbin.org/post", file: fileURL)
.progress { (bytesWritten, totalBytesWritten, totalBytesExpectedToWrite) in
println(totalBytesWritten)
}
.responseJSON { (request, response, JSON, error) in
println(JSON)
}
Downloading
Supported Download Types
Downloading a File
Alamofire.download(.GET, "http://httpbin.org/stream/100", destination: { (temporaryURL, response) in
if let directoryURL = NSFileManager.defaultManager()
.URLsForDirectory(.DocumentDirectory,
inDomains: .UserDomainMask)[0]
as? NSURL {
let pathComponent = response.suggestedFilename
return directoryURL.URLByAppendingPathComponent(pathComponent!)
}
return temporaryURL
})
Using the Default Download Destination
let destination = Alamofire.Request.suggestedDownloadDestination(directory: .DocumentDirectory, domain: .UserDomainMask)
Alamofire.download(.GET, "http://httpbin.org/stream/100", destination: destination)
Downloading a File w/Progress
Alamofire.download(.GET, "http://httpbin.org/stream/100", destination: destination)
.progress { (bytesRead, totalBytesRead, totalBytesExpectedToRead) in
println(totalBytesRead)
}
.response { (request, response, _, error) in
println(response)
}
Authentication
Authentication is handled on the system framework level by NSURLCredential and NSURLAuthenticationChallenge.
Supported Authentication Schemes
- HTTP Basic
- HTTP Digest
- Kerberos
- NTLM
HTTP Basic Authentication
let user = "user"
let password = "password"
Alamofire.request(.GET, "https://httpbin.org/basic-auth/\(user)/\(password)")
.authenticate(user: user, password: password)
.response {(request, response, _, error) in
println(response)
}
Authentication with NSURLCredential
let user = "user"
let password = "password"
let credential = NSURLCredential(user: user, password: password, persistence: .ForSession)
Alamofire.request(.GET, "https://httpbin.org/basic-auth/\(user)/\(password)")
.authenticate(usingCredential: credential)
.response {(request, response, _, error) in
println(response)
}
Validation
By default, Alamofire treats any completed request to be successful, regardless of the content of the response. Calling validate before a response handler causes an error to be generated if the response had an unacceptable status code or MIME type.
Manual Validation
Alamofire.request(.GET, "http://httpbin.org/get", parameters: ["foo": "bar"])
.validate(statusCode: 200.. Serializer {
return { (request, response, data) in
if data == nil {
return (nil, nil)
}
var XMLSerializationError: NSError?
let XML = ONOXMLDocument(data: data, &XMLSerializationError)
return (XML, XMLSerializationError)
}
}
func responseXMLDocument(completionHandler: (NSURLRequest, NSHTTPURLResponse?, ONOXMLDocument?, NSError?) -> Void) -> Self {
return response(serializer: Request.XMLResponseSerializer(), completionHandler: { (request, response, XML, error) in
completionHandler(request, response, XML as? ONOXMLDocument, error)
})
}
}
Generic Response Object Serialization
Generics can be used to provide automatic, type-safe response object serialization.
@objc public protocol ResponseObjectSerializable {
init?(response: NSHTTPURLResponse, representation: AnyObject)
}
extension Alamofire.Request {
public func responseObject(completionHandler: (NSURLRequest, NSHTTPURLResponse?, T?, NSError?) -> Void) -> Self {
let serializer: Serializer = { (request, response, data) in
let JSONSerializer = Request.JSONResponseSerializer(options: .AllowFragments)
let (JSON: AnyObject?, serializationError) = JSONSerializer(request, response, data)
if response != nil && JSON != nil {
return (T(response: response!, representation: JSON!), nil)
} else {
return (nil, serializationError)
}
}
return response(serializer: serializer, completionHandler: { (request, response, object, error) in
completionHandler(request, response, object as? T, error)
})
}
}
final class User: ResponseObjectSerializable {
let username: String
let name: String
required init?(response: NSHTTPURLResponse, representation: AnyObject) {
self.username = response.URL!.lastPathComponent
self.name = representation.valueForKeyPath("name") as String
}
}
Alamofire.request(.GET, "http://example.com/users/mattt")
.responseObject { (_, _, user: User?, _) in
println(user)
}
The same approach can also be used to handle endpoints that return a representation of a collection of objects:
@objc public protocol ResponseCollectionSerializable {
class func collection(#response: NSHTTPURLResponse, representation: AnyObject) -> [Self]
}
extension Alamofire.Request {
public func responseCollection(completionHandler: (NSURLRequest, NSHTTPURLResponse?, [T]?, NSError?) -> Void) -> Self {
let serializer: Serializer = { (request, response, data) in
let JSONSerializer = Request.JSONResponseSerializer(options: .AllowFragments)
let (JSON: AnyObject?, serializationError) = JSONSerializer(request, response, data)
if response != nil && JSON != nil {
return (T.collection(response: response!, representation: JSON!), nil)
} else {
return (nil, serializationError)
}
}
return response(serializer: serializer, completionHandler: { (request, response, object, error) in
completionHandler(request, response, object as? [T], error)
})
}
}
URLStringConvertible
Types adopting the URLStringConvertible protocol can be used to construct URL strings, which are then used to construct URL requests. NSString, NSURL, NSURLComponents, and NSURLRequest conform to URLStringConvertible by default, allowing any of them to be passed as URLString parameters to the request, upload, and download methods:
let string = NSString(string: "http://httpbin.org/post")
Alamofire.request(.POST, string)
let URL = NSURL(string: string)!
Alamofire.request(.POST, URL)
let URLRequest = NSURLRequest(URL: URL)
Alamofire.request(.POST, URLRequest) // overrides `HTTPMethod` of `URLRequest`
let URLComponents = NSURLComponents(URL: URL, resolvingAgainstBaseURL: true)
Alamofire.request(.POST, URLComponents)
Applications interacting with web applications in a significant manner are encouraged to have custom types conform to URLStringConvertible as a convenient way to map domain-specific models to server resources.
Type-Safe Routing
extension User: URLStringConvertible {
static let baseURLString = "http://example.com"
var URLString: String {
return User.baseURLString + "/users/\(username)/"
}
}
let user = User(username: "mattt")
Alamofire.request(.GET, user) // http://example.com/users/mattt
URLRequestConvertible
Types adopting the URLRequestConvertible protocol can be used to construct URL requests. NSURLRequest conforms to URLRequestConvertible by default, allowing it to be passed into request, upload, and download methods directly (this is the recommended way to specify custom HTTP header fields or HTTP body for individual requests):
let URL = NSURL(string: "http://httpbin.org/post")!
let mutableURLRequest = NSMutableURLRequest(URL: URL)
mutableURLRequest.HTTPMethod = "POST"
let parameters = ["foo": "bar"]
var JSONSerializationError: NSError? = nil
mutableURLRequest.HTTPBody = NSJSONSerialization.dataWithJSONObject(parameters, options: nil, error: &JSONSerializationError)
mutableURLRequest.setValue("application/json", forHTTPHeaderField: "Content-Type")
Alamofire.request(mutableURLRequest)
Applications interacting with web applications in a significant manner are encouraged to have custom types conform to URLRequestConvertible as a way to ensure consistency of requested endpoints. Such an approach can be used to abstract away server-side inconsistencies and provide type-safe routing, as well as manage authentication credentials and other state.
API Parameter Abstraction
enum Router: URLRequestConvertible {
static let baseURLString = "http://example.com"
static let perPage = 50
case Search(query: String, page: Int)
// MARK: URLRequestConvertible
var URLRequest: NSURLRequest {
let (path: String, parameters: [String: AnyObject]?) = {
switch self {
case .Search(let query, let page) where page > 1:
return ("/search", ["q": query, "offset": Router.perPage * page])
case .Search(let query, _):
return ("/search", ["q": query])
}
}()
let URL = NSURL(string: Router.baseURLString)!
let URLRequest = NSURLRequest(URL: URL.URLByAppendingPathComponent(path))
let encoding = Alamofire.ParameterEncoding.URL
return encoding.encode(URLRequest, parameters: parameters).0
}
}
Alamofire.request(Router.Search(query: "foo bar", page: 1)) // ?q=foo+bar&offset=50
CRUD & Authorization
enum Router: URLRequestConvertible {
static let baseURLString = "http://example.com"
static var OAuthToken: String?
case CreateUser([String: AnyObject])
case ReadUser(String)
case UpdateUser(String, [String: AnyObject])
case DestroyUser(String)
var method: Alamofire.Method {
switch self {
case .CreateUser:
return .POST
case .ReadUser:
return .GET
case .UpdateUser:
return .PUT
case .DestroyUser:
return .DELETE
}
}
var path: String {
switch self {
case .CreateUser:
return "/users"
case .ReadUser(let username):
return "/users/\(username)"
case .UpdateUser(let username, _):
return "/users/\(username)"
case .DestroyUser(let username):
return "/users/\(username)"
}
}
// MARK: URLRequestConvertible
var URLRequest: NSURLRequest {
let URL = NSURL(string: Router.baseURLString)!
let mutableURLRequest = NSMutableURLRequest(URL: URL.URLByAppendingPathComponent(path))
mutableURLRequest.HTTPMethod = method.rawValue
if let token = Router.OAuthToken {
mutableURLRequest.setValue("Bearer \(token)", forHTTPHeaderField: "Authorization")
}
switch self {
case .CreateUser(let parameters):
return Alamofire.ParameterEncoding.JSON.encode(mutableURLRequest, parameters: parameters).0
case .UpdateUser(_, let parameters):
return Alamofire.ParameterEncoding.URL.encode(mutableURLRequest, parameters: parameters).0
default:
return mutableURLRequest
}
}
}
Alamofire.request(Router.ReadUser("mattt")) // GET /users/mattt
FAQ
When should I use Alamofire?
If you’re starting a new project in Swift, and want to take full advantage of its conventions and language features, Alamofire is a great choice. Although not as fully-featured as AFNetworking, Alamofire is much nicer to work with, and should satisfy the vast majority of networking use cases.
It’s important to note that two libraries aren’t mutually exclusive: AFNetworking and Alamofire can peacefully exist in the same code base.
When should I use AFNetworking?
AFNetworking remains the premiere networking library available for OS X and iOS, and can easily be used in Swift, just like any other Objective-C code. AFNetworking is stable and reliable, and isn’t going anywhere.
Use AFNetworking for any of the following:
- UIKit extensions, such as asynchronously loading images to
UIImageView - TLS verification, using
AFSecurityManager - Situations requiring
NSOperationorNSURLConnection, usingAFURLConnectionOperation - Network reachability monitoring, using
AFNetworkReachabilityManager - Multipart HTTP request construction, using
AFHTTPRequestSerializer
What’s the origin of the name Alamofire?
Alamofire is named after the Alamo Fire flower, a hybrid variant of the Bluebonnet, the official state flower of Texas.
Credits
Alamofire is owned and maintained by the Alamofire Software Foundation.
License
Alamofire is released under the MIT license. See LICENSE for details.