Storing Codable structs on the disk
Most of our apps are REST clients for some backends. During the development of this kind of apps, we want to keep it working offline. In this case, we have to cache data somewhere locally on the device to make it readable without an internet connection.
Apple provides a CoreData framework, which is the best way to store your app data locally. It has a lot of excellent features which help you to boost development. However, it is tough to use it as a simple cache. Most of the time, we just need to display cached data without any additional manipulations. In my opinion, all we need is pure disk storage. This week we will discuss how easily we can implement straightforward disk store for our Codable structs.
Let’s start with defining a couple of protocols for our storage logic. I want to separate access to writable and readable parts of the storage, and this is where we can use protocol composition feature of Swift language.
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import Foundation
typealias Handler<T> = (Result<T, Error>) -> Void
protocol ReadableStorage {
func fetchValue(for key: String) throws -> Data
func fetchValue(for key: String, handler: @escaping Handler<Data>)
}
protocol WritableStorage {
func save(value: Data, for key: String) throws
func save(value: Data, for key: String, handler: @escaping Handler<Data>)
}
typealias Storage = ReadableStorage & WritableStorage
Here we have two protocols describing reading and writing operations on storage. Protocols also provide an asynchronous version for reading and writing actions with completion handlers. We also create typealias Storage, which is a composition of two protocols. Now we can start to work on DiskStorage class which implements our Storage protocols.
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enum StorageError: Error {
case notFound
case cantWrite(Error)
}
class DiskStorage {
private let queue: DispatchQueue
private let fileManager: FileManager
private let path: URL
init(
path: URL,
queue: DispatchQueue = .init(label: "DiskCache.Queue"),
fileManager: FileManager = FileManager.default
) {
self.path = path
self.queue = queue
self.fileManager = fileManager
}
}
First of all, let’s describe some variables for root path of our storage, DispatchQueue for asynchronous work and FileManager, which we will use to navigate through the file system.
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extension DiskStorage: WritableStorage {
func save(value: Data, for key: String) throws {
let url = path.appendingPathComponent(key)
do {
try self.createFolders(in: url)
try value.write(to: url, options: .atomic)
} catch {
throw StorageError.cantWrite(error)
}
}
func save(value: Data, for key: String, handler: @escaping Handler<Data>) {
queue.async {
do {
try self.save(value: value, for: key)
handler(.success(value))
} catch {
handler(.failure(error))
}
}
}
}
extension DiskStorage {
private func createFolders(in url: URL) throws {
let folderUrl = url.deletingLastPathComponent()
if !fileManager.fileExists(atPath: folderUrl.path) {
try fileManager.createDirectory(
at: folderUrl,
withIntermediateDirectories: true,
attributes: nil
)
}
}
}
Next step is the implementation of the writable part of our storage. It is a little bit tricky because the key is a path to our data on the file system. That’s why we need append the key to our root path and generate new URL for the storing data. New URL can contain subfolders, that’s why we create a createFolders function which creates needed folders according to the path.
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extension DiskStorage: ReadableStorage {
func fetchValue(for key: String) throws -> Data {
let url = path.appendingPathComponent(key)
guard let data = fileManager.contents(atPath: url.path) else {
throw StorageError.notFound
}
return data
}
func fetchValue(for key: String, handler: @escaping Handler<Data>) {
queue.async {
handler(Result { try self.fetchValue(for: key) })
}
}
}
Here is the readable part of our Storage protocol, where we implement data fetching for a passed key. Again, we use the key as a path to our data on disk. Now we have a working example of straightforward disk storage. Next step is implementing a simple adapter for our DiskStorage class, which will handle JSON coding/decoding.
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class CodableStorage {
private let storage: DiskStorage
private let decoder: JSONDecoder
private let encoder: JSONEncoder
init(
storage: DiskStorage,
decoder: JSONDecoder = .init(),
encoder: JSONEncoder = .init()
) {
self.storage = storage
self.decoder = decoder
self.encoder = encoder
}
func fetch<T: Decodable>(for key: String) throws -> T {
let data = try storage.fetchValue(for: key)
return try decoder.decode(T.self, from: data)
}
func save<T: Encodable>(_ value: T, for key: String) throws {
let data = try encoder.encode(value)
try storage.save(value: data, for: key)
}
}
CodableStorage class wraps our DiskStorage class to add JSON coding-decoding logic. It uses generic constraints to understand how to decode and encode data. It’s time to use our CodableStorage in real life sample.
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struct Timeline: Codable {
let tweets: [String]
}
let path = URL(fileURLWithPath: NSTemporaryDirectory())
let disk = DiskStorage(path: path)
let storage = CodableStorage(storage: disk)
let timeline = Timeline(tweets: ["Hello", "World", "!!!"])
try storage.save(timeline, for: "timeline")
let cached: Timeline = try storage.fetch(for: "timeline")
In the code sample above, you can see the usage of CodableStorage class. We create DiskCache class instance which uses a temporary folder to store data. Timeline is a simple codable struct representing an array of strings which we store in our CodableStorage.
Conclusion
Today we discussed a simple way of storing Codable structs which we can fetch via REST API. Sometimes we don’t need complicated features of CoreData for simple JSON caching and it is enough to implement disk storage.