MMRecord is a block-based seamless web service integration library for iOS and Mac OS X. It leverages the Core Data model configuration to automatically create and populate a complete object graph from an API response. It works with any networking library, is simple to setup, and includes many popular features that make working with web services even easier. Here's how to make a request for App.net Post records:
NSManagedObjectContext *context = [[MMDataManager sharedDataManager] managedObjectContext];
[Post
startPagedRequestWithURN:@"stream/0/posts/stream/global"
data:nil
context:context
domain:self
resultBlock:^(NSArray *posts, ADNPageManager *pageManager, BOOL *requestNextPage) {
NSLog(@"Posts: %@", posts);
}
failureBlock:^(NSError *error) {
NSLog(@"%@", error);
}];
Keep reading to learn more about how to start using MMRecord in your project!
- Download MMRecord and try out the included example apps.
- Continue reading the integration instructions below.
- Check out the documentation for all the rest of the details.
- Review the examples below for inspiration on specific usage.
- Read about MMRecord's support for Swift and Tweaks.
- If you run into any issues, check out some useful debugging tips.
##Installing MMRecord
You can install MMRecord in your project by using CocoaPods:
pod 'MMRecord', '~> 1.4.1'
MMRecord is designed to make it as easy and fast as possible to obtain native objects from a new web service request. It handles all of the fetching, creation, and population of NSManagedObjects for you in the background so that when you make a request, all you get back is the native objects that you can use immediately. No parsing required.
The library is architected to be as simple and lightweight as possible. Here's a breakdown of the core classes in MMRecord.
Core | |
---|---|
MMRecord |
A subclass of NSManagedObject that defines the MMRecord interface and initiates the object graph population process.
|
MMServer |
An abstract class that defines the request interface used by MMRecord.
|
<tr><th colspan="2" style="text-align:center;">Debugging</th></tr>
Population | |
---|---|
MMRecordResponse | A class that handles the process of turning a response into native MMRecord objects. |
MMRecordProtoRecord | A container class used as a placeholder for the object graph during the population process. |
MMRecordRepresentation | A class that defines the mapping between a dictionary and a Core Data NSEntityDescription. |
MMRecordMarshaler | A class responsible for populating an instance of MMRecord based on the MMRecordRepresentation. |
Pagination | |
MMServerPageManager | An abstract class that defines the interface for handling pagination. |
Caching | |
MMRecordCache | A class that maps NSManagedObject ObjectIDs to an NSCachedURLResponse. |
MMRecordDebugger | A class that manages NSError objects to provide debugging feedback. |
Subspecs | |
---|---|
AFServer | An example MMServer subclass that implements AFNetworking 1.0. |
SessionManagerServer | An example MMServer subclass that implements AFNetworking 2.0. |
JSONServer | An example MMServer subclass that can read local JSON files. |
DynamicModel | A custom MMRecordRepresentation and MMRecordMarshaler subclass pair that stores the original object dictionary as a transformable attribute. |
ResponseSerializer | A custom AFHTTPResponseSerializer that creates and returns MMRecord instances in an AFNetworking 2.0 success block. |
TweakModel | An MMRecord subspec that implements support for Facebook Tweaks to tweak MMRecord response handling behavior. |
MMRecord does require some basic setup before you can use it to make requests. This guide will go take you through the steps in that configuration process.
MMRecord requires a registered server class to make requests. The server class should know how to make a request to the API you are integrating with. The only requirement of a server implementation is that it return a response object (array or dictionary) that contains the objects you are requesting. A server might use AFNetworking to perform a GET request to a specific API. Or it might load and return local JSON files. There are two subspecs which provide pre-built servers that use AFNetworking and local JSON files. Generally speaking though, you are encouraged to implement your own server to talk to the API you are using.
Once you have defined your server class, you must register it with MMRecord:
[Post registerServerClass:[ADNServer class]];
Note that you can register different server classes on different subclasses of MMRecord.
[Tweet registerServerClass:[TWSocialServer class]];
[User registerServerClass:[MMJSONServer class]];
This is helpful if one endpoint you are working with is complete, but another is not, or is located on another API.
While you are encouraged to create your own specific server subclass for your own integration, MMRecord does provide base server implementations as subspec examples for AFNetworking 1.0 and AFNetworking 2.0. You can consult the AFServer subspec for AFNetworking 1.0, or the AFMMRecordSessionManagerServer subspec for AFNetworking 2.0. You can check out the new AFNetworking 2.0 server in the Foursquare example app.
In addition, we provide the AFMMRecordResponseSerializer subspec specially for AFNetworking 2.0. This response serializer can be used for AFNetworking 2.0 in order to provide parsed and populated MMRecord instances to you in an AFNetworking success block. For more information please check out this blog post or view the example below.
You are required to override one method on your subclass of MMRecord in order to tell the parsing system where to locate the object(s) you wish to parse. This method returns a key path that specifies the location relative to the root of the response object. If your response object is an array, you can just return nil.
In an App.net request, all returned objects are located in an object called "data", so our subclass of MMRecord will look like this:
@interface ADNRecord : MMRecord
@end
static NSDateFormatter *ADNRecordDateFormatter;
@implementation ADNRecord
+ (NSString *)keyPathForResponseObject {
return @"data";
}
+ (NSDateFormatter *)dateFormatter {
if (!ADNRecordDateFormatter) {
NSDateFormatter *dateFormatter = [[NSDateFormatter alloc] init];
[dateFormatter setDateFormat:@"yyyy-MM-dd'T'HH:mm:ssZ"]; // "2012-11-21T03:57:39Z"
ADNRecordDateFormatter = dateFormatter;
}
return ADNRecordDateFormatter;
}
@end
There are also some optional methods you may wish to implement on MMRecord. One such method returns a date formatter configured for populating attributes of type Date. You can override this method to populate date attributes using a formatted date string. Unix number time stamp dates are supported by default.
Note that these methods were implemented on a class called ADNRecord, which is a subclass of MMRecord. Additional entities are subclasses of ADNRecord, and do not need to implement these methods themselves.
The Core Data NSManagedObjectModel is very useful. At a highlevel, the model is composed of a list of entities. Likewise, an API is typically composed of a list of endpoints. MMRecord takes advantage of this convention to map an entity representation to an endpoint representation in order to create native objects from an API response.
MMRecord leverages the introspective properties of the Core Data model to decide how to parse a response. The class you start the request from is considered to be the root of the object graph. From there, MMRecord looks at that NSEntityDescription's attributes and relationships and attempts to populate each of them from the given response object. That information is very helpful, because it makes population of most attributes very straightforward. Because of this, it's helpful if your data model entity representations maps very closely to your API endpoint response representations.
MMRecord works best if there is a way to uniquely identify records of a given entity type. That allows it to fetch the existing record (if it exists) and update it, rather than create a duplicate one. To designate the primary key for an entity, we leverage the entity's user info dictionary. Specify the name of the primary key property as the value, and MMRecordEntityPrimaryAttributeKey as the key.
Note that the primary key can be any property, which includes a relationship. If a relationship is used as the primary key, MMRecord will attempt to fetch the parent object and search for the associated object in the relationship.
You can also inject a primary key at population time if you know the key for a record which does not exist in the API response dictionary being used to populate the record. An example of this being used is below. This option is not intended to replace proper model configuration, but can be used for additional flexibility. One way you can consider using this option is by parsing the contents of the dictionary to create your own unique identifier for a given record.
Sometimes, you may need to define an alternate name for a property on one of your entities. This could be for a variety of reasons. Perhaps you don't like your Core Data property names to include underscores? Perhaps the API response changed, and you don't want to change your NSManagedObject property names. Or maybe the value of a property is actually inside of a sub-object, and you need to bring it up to root level. Well, that's what the MMRecordAttributeAlternateNameKey is for. You can define this key on any attribute or relationship user info dictionary. The value of this key can be an alternate name, or alternate keyPath that will be used to locate the object for that property.
For reference, here's a truncated version of the App.net User object to illustrate how those configuration values were determined:
{
"id": "1", // note this is a string
"username": "johnappleseed",
"name": "John Appleseed",
"avatar_image": {
"height": 512,
"width": 512,
"url": "https://example.com/avatar_image.jpg",
"is_default": false
},
"cover_image": {
"width": 320,
"height": 118,
"url": "https://example.com/cover_image.jpg",
"is_default": false
},
"counts": {
"following": 100,
"followers": 200,
"posts": 24,
"stars": 76
}
}
Here's a few examples of the various types of requests you can make with MMRecord. Notice that AFMMRecordResponseSerializer is a subspec of MMRecord.
+ (void)favoriteTweetsWithContext:(NSManagedObjectContext *)context
domain:(id)domain
resultBlock:(void (^)(NSArray *tweets))resultBlock
failureBlock:(void (^)(NSError *))failureBlock {
[Tweet startRequestWithURN:@"favorites/list.json"
data:nil
context:context
domain:self
resultBlock:resultBlock
failureBlock:failureBlock];
}
@interface Post : ADNRecord
+ (void)getStreamPostsWithContext:(NSManagedObjectContext *)context
domain:(id)domain
resultBlock:(void (^)(NSArray *posts, ADNPageManager *pageManager, BOOL *requestNextPage))resultBlock
failureBlock:(void (^)(NSError *error))failureBlock;
@end
@implementation Post
+ (void)getStreamPostsWithContext:(NSManagedObjectContext *)context
domain:(id)domain
resultBlock:(void (^)(NSArray *posts, ADNPageManager *pageManager, BOOL *requestNextPage))resultBlock
failureBlock:(void (^)(NSError *error))failureBlock {
[self startPagedRequestWithURN:@"stream/0/posts/stream/global"
data:nil
context:context
domain:self
resultBlock:resultBlock
failureBlock:failureBlock];
}
@end
[Tweet startBatchedRequestsInExecutionBlock:^{
[Tweet
timelineTweetsWithContext:context
domain:self
resultBlock:^(NSArray *tweets, MMServerPageManager *pageManager, BOOL *requestNextPage) {
NSLog(@"Timeline Request Complete");
}
failureBlock:^(NSError *error) {
NSLog(@"%@", error);
}];
[Tweet
favoriteTweetsWithContext:context
domain:self
resultBlock:^(NSArray *tweets, MMServerPageManager *pageManager, BOOL *requestNextPage) {
NSLog(@"Favorites Request Complete");
}
failureBlock:^(NSError *error) {
NSLog(@"%@", error);
}];
} withCompletionBlock:^{
NSLog(@"Request Complete");
}];
NSFetchRequest *fetchRequest = [NSFetchRequest fetchRequestWithEntityName:@"User"];
NSPredicate *predicate = [NSPredicate predicateWithFormat:@"SELF.name contains[c] %@", name];
NSSortDescriptor *sortDescriptor = [NSSortDescriptor sortDescriptorWithKey:@"name" ascending:YES];
fetchRequest.predicate = predicate;
fetchRequest.sortDescriptors = @[sortDescriptor];
[self
startRequestWithURN:[NSString stringWithFormat:@"stream/0/users/%@", name]
data:nil
context:context
domain:domain
fetchRequest:fetchRequest
customResponseBlock:nil resultBlock:^(NSArray *records, id customResponseObject, BOOL requestComplete) {
if (resultBlock != nil) {
resultBlock(records, requestComplete);
}
}
failureBlock:failureBlock];
MMFoursquareSessionManager *sessionManager = [MMFoursquareSessionManager sharedClient];
NSManagedObjectContext *context = [[MMDataManager sharedDataManager] managedObjectContext];
AFHTTPResponseSerializer *HTTPResponseSerializer = [AFJSONResponseSerializer serializer];
AFMMRecordResponseSerializationMapper *mapper = [[AFMMRecordResponseSerializationMapper alloc] init];
[mapper registerEntityName:@"Venue" forEndpointPathComponent:@"venues/search?"];
AFMMRecordResponseSerializer *serializer =
[AFMMRecordResponseSerializer serializerWithManagedObjectContext:context
responseObjectSerializer:HTTPResponseSerializer
entityMapper:mapper];
sessionManager.responseSerializer = serializer;
[[MMFoursquareSessionManager sharedClient]
GET:@"venues/search?ll=30.25,-97.75"
parameters:requestParameters
success:^(NSURLSessionDataTask *task, id responseObject) {
NSArray *venues = responseObject;
self.venues = venues;
[self.tableView reloadData];
}
failure:failureBlock];
MMRecordOptions
is a way to customize the behavior of a request. One of the ways you can use it is to specify blocks that apply to the following request after you specify a set of options. This allows you to do things like insert a new primary key for a record or specify orphan deletion behaviors.
MMRecordOptions *options = [Post defaultOptions];
options.entityPrimaryKeyInjectionBlock = ^id(NSEntityDescription *entity,
NSDictionary *dictionary,
MMRecordProtoRecord *parentProtoRecord) {
if ([[entity name] isEqualToString:@"CoverImage"]) {
if ([[parentProtoRecord.entity name] isEqualToString:@"User"]) {
if (parentProtoRecord.primaryKeyValue != nil) {
return parentProtoRecord.primaryKeyValue;
}
}
}
return nil;
};
[Post setOptions:options];
[Post
getStreamPostsWithContext:context
domain:self
resultBlock:^(NSArray *posts, ADNPageManager *pageManager, BOOL *requestNextPage) {
[self populatePostsTableWithPosts:posts];
}
failureBlock:failureBlock];
MMRecordOptions *options = [Tweet defaultOptions];
options.deleteOrphanedRecordBlock = ^(MMRecord *orphan,
NSArray *populatedRecords,
id responseObject,
BOOL *stop) {
Tweet *tweet = (Tweet *)orphan;
if ([tweet isFavorite]) {
return NO;
}
return YES;
};
[Tweet setOptions:options];
[Tweet
timelineTweetsWithContext:context
domain:self
resultBlock:^(NSArray *tweets, MMServerPageManager *pageManager, BOOL *requestNextPage) {
self.tweets = tweets;
[self.tableView reloadData];
}
failureBlock:failureBlock];
While MMRecord is implemented in Objective-C, you can also use the library from to build your model in Swift. The main thing you should be aware of when building your model in Swift is that entity managed object class names need to be fully namespaced. An example of that is below.
Note that MMRecordAtlassian is used as the namespace for the Issue class in Swift. This is because the default namespace is the product name for your project. Please be aware that using special characters or spaces in your product name may lead to issues here. Typically those characters get replaced by underscores in your namespace, but for best results, simply use a single word for your product name to avoid issues.
You should also remember to import MMRecord.h, and any of its subspecs you use, in your Objective-C Bridging Header. Then, you're ready to go building your MMRecord model in Swift!
Here's a few examples of using MMRecord in Swift.
import CoreData
class Plan: ATLRecord {
@NSManaged var name: NSString
@NSManaged var id: NSString
override class func keyPathForResponseObject() -> String {
return "plans.plan"
}
}
Plan.startRequestWithURN("/plans",
data: nil,
context: managedObjectContext,
domain: self,
resultBlock: {records in
var results: [Plan] = records as [Plan]
self.plans = results
self.tableView.reloadData()
},
failureBlock: { error in
})
var options = Issue.defaultOptions()
options.entityPrimaryKeyInjectionBlock = {(entity, dictionary, parentProtoRecord) -> NSCopying in
let dict = dictionary as Dictionary
let key: AnyObject? = dict["id"]
let returnKey = key as String
return returnKey
}
options.recordPrePopulationBlock = { protoRecord in
let proto: MMRecordProtoRecord = protoRecord
let entity: NSEntityDescription = protoRecord.entity
var dictionary: AnyObject! = proto.dictionary.mutableCopy()
var mutableDictionary: NSMutableDictionary = dictionary as NSMutableDictionary
var primaryKey: AnyObject! = ""
if (entity.name == "OutwardLink") {
primaryKey = mutableDictionary.valueForKeyPath("outwardIssue.key")
}
if (entity.name == "InwardLink") {
primaryKey = mutableDictionary.valueForKeyPath("inwardIssue.key")
}
mutableDictionary.setValue(primaryKey, forKey: "PrimaryKey")
proto.dictionary = mutableDictionary
}
Issue.setOptions(options)
Issue.startRequestWithURN("/issue",
data: nil,
context: managedObjectContext,
domain: self,
resultBlock: { records in
var results: [Issue] = records as [Issue]
self.results = results
self.tableView.reloadData()
},
failureBlock: { error in
})
MMRecord also provides the TweakModel subspec that implements support for Facebook Tweaks. You can use Tweaks to modify most MMRecord parsing and population parameters. This can be useful if you're working on an app where the API is in flux and is still being actively developed. The UI for Tweaks will show you a list of MMRecord entities in your data model, the primary key for each entity, all of the keys used to populate various attributes, and the key path that points to instances of that entity in the data model. Here's how you use it.
#define FBMMRecordTweakModelDefine
[FBMMRecordTweakModel loadTweaksForManagedObjectModel:
[MMDataManager sharedDataManager].managedObjectModel];
Thats all you need to enable Tweaks in your MMRecord project. As a best practice, you should only use the #define in Debug mode.
After its setup, here's what the Tweaks UI looks like with MMRecord.
MMRecordDebugger
is a class used by MMRecord
to provide debugging information back to you about how your model is configured and how MMRecord is handling the response handed to it by your server class. You can use MMRecordDebugger to help resolve issues that may exist in your model configuration, or identify inconsistencies with your response format.
MMRecord is designed to make it as fast and easy as possible to serialize managed objects from a web service. One of the goals of the library is to provide meaningful means of customization to support all sorts of response formats, while still maintaining an easy to use primary interface that does not require excessive configuration and setup. In most cases, the amount of configuration and customization required by a user of MMRecord will depend on how complex the response format of your web service is.
When MMRecord encounters an error while handling a request it may take a few measures based on the severity of the error.
- Assertions. In some cases, like if a managed object class being populated is not a subclass of MMRecord, an assertion will be thrown.
- Logs. In many cases, MMRecord will log a message containing the error to the console. By default MMRecord will not actually print anything to the console, unless you specify a logging level manually. This is for security reasons.
- Non-failure Errors. In some cases, MMRecord will create an
NSError
describing an issue, and associate it with theMMRecordDebugger
. However, if the error isn't serious enough, the request will not fail. - Failure Errors. In several cases, MMRecord will create an
NSError
describing a critical issue it encountered while handling a request. These errors are associated with the debugger, and will be passed back into the failureBlock indicating a reason that the request failed.
If you encounter issues with a request, your first step should be to enable MMRecord logging, using the command below.
[MMRecord setLoggingLevel:MMRecordLoggingLevelAll];
You can lower the logging level incrementally to receive finer grained logging information, but its a good idea to start with the highest level to get a broader picture of what is going on.
If your request is failing, you can use the NSError
object that is passed into the failure block to review all sorts of data about the failure. The error parameter in the failure block will actually include the MMRecordDebugger
instance, which contains all of the errors encountered while handling the request, and various bits of state relevant to the critical error.
The debugger is attached to the NSError
in its userInfo dictionary. Here's an example of how you can use it.
failureBlock:^(NSError *error) {
NSDictionary *recordDictionary = [[error userInfo] valueForKey:MMRecordDebuggerParameterRecordDictionary];
MMRecordDebugger *debugger = [[error userInfo] valueForKey:MMRecordDebuggerKey];
NSArray *allErrors = [debugger errorsEncounteredWhileHandlingResponse];
id responseObject = [debugger responseObject];
NSString *entityName = [[debugger initialEntity] name];
}];
If you encounter errors that you would like to see tracked, or have suggestions about the severity of some errors, please create an issue or file a pull request.
MMRecord 1.4.0 and higher requires either iOS 6.0 and above, or Mac OS 10.8 (64-bit with modern Cocoa runtime) and above.
MMRecord uses ARC.
If you are using MMRecord in your non-arc project, you will need to set a -fobjc-arc
compiler flag on all of the MMRecord source files.
MMRecord was created by Conrad Stoll at Mutual Mobile.
MMRecord is available under the MIT license. See the LICENSE file for more info.