7

I know an alternative of reflection which is using javassist, but using javassist is a little bit complex. And because of lambda or some other features in koltin, the javassist doesn't work well sometimes. So is there any other way to iterate all fields of a data class without using reflection.

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    kotlinlang.org/docs/reference/data-classes.html: componentN() functions corresponding to the properties in their order of declaration; – JB Nizet Dec 9 '17 at 16:09
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    If you don't know the number of properties, you'll need reflection, see stackoverflow.com/a/38688203/4465208 – zsmb13 Dec 9 '17 at 16:10
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    You can use destruct declaration like val (a, b, c) = Triple(meow1, meow2, meow3) – ice1000 Dec 11 '17 at 4:44
  • Is there a reason you don't want to use reflection? Reflection was created specifically to do this, because there's no other way. Any alternative that you find will either use reflection under-the-hood or be even more hacky than reflection. As others have mentioned, there are solutions if you are happy to manually update the code every time the fields change. – Steven Lowes Mar 19 at 12:32
2

There are two ways. The first is relatively easy, and is essentially what's mentioned in the comments: assuming you know how many fields there are, you can unpack it and throw that into a list, and iterate over those. Or alternatively use them directly:

data class Test(val x: String, val y: String) {
    fun getData() : List<Any> = listOf(x, y)
}
data class Test(val x: String, val y: String) 
...

val (x, y) = Test("x", "y")
// And optionally throw those in a list

Although iterating like this is a slight extra step, this is at least one way you can relatively easy unpack a data class.


If you don't know how many fields there are (or you don't want to refactor), you have two options:

The first is using reflection. But as you mentioned, you don't want this.

That leaves a second, somewhat more complicated preprocessing option: annotations. Note that this only works with data classes you control - beyond that, you're stuck with reflection or implementations from the library/framework coder.

Annotations can be used for several things. One of which is metadata, but also code generation. This is a somewhat complicated alternative, and requires an additional module in order to get compile order right. If it isn't compiled in the right order, you'll end up with unprocessed annotations, which kinda defeats the purpose.

I've also created a version you can use with Gradle, but that's at the end of the post and it's a shortcut to implementing it yourself.

Note that I have only tested this with a pure Kotlin project - I've personally had problems with annotations between Java and Kotlin (although that was with Lombok), so I do not guarantee this will work at compile time if called from Java. Also note that this is complex, but avoids runtime reflection.


Explanation

The main issue here is a certain memory concern. This will create a new list every time you call the method, which makes it very similar to the method used by enums.

Local testing over 10000 iterations also show a general consistency of ~200 milliseconds to execute my approach, versus roughly 600 for reflection. However, for one iteration, mine uses ~20 milliseconds, where as reflection uses between 400 and 500 milliseconds. On one run, reflection took 1500 (!) milliseconds, while my approach took 18 milliseconds.

See also Java Reflection: Why is it so slow?. This appears to affect Kotlin as well. The memory impact of creating a new list every time it's called can be noticeable though, but it'll also be collected so it shouldn't be that big a problem.

For reference, the code used for benchmarking (this will make sense after the rest of the post):

@AutoUnpack data class ExampleDataClass(val x: String, val y: Int, var m: Boolean)

fun main(a: Array<String>) {
    var mine = 0L
    var reflect = 0L
    // for(i in 0 until 10000) {
        var start = System.currentTimeMillis()
        val cls = ExampleDataClass("example", 42, false)
        for (field in cls) {
            println(field)
        }
        mine += System.currentTimeMillis() - start

        start = System.currentTimeMillis()
        for (prop in ExampleDataClass::class.memberProperties) {
            println("${prop.name} = ${prop.get(cls)}")
        }
        reflect += System.currentTimeMillis() - start
    // }
    println(mine)
    println(reflect)
}

Setting up from scratch

This bases itself around two modules: a consumer module, and a processor module. The processor HAS to be in a separate module. It needs to be compiled separately from the consumer for the annotations to work properly.

First of all, your consumer project needs the annotation processor:

apply plugin: 'kotlin-kapt'

Additionally, you need to add stub generation. It complains it's unused while compiling, but without it, the generator seems to break for me:

kapt {
    generateStubs = true
}

Now that that's in order, create a new module for the unpacker. Add the Kotlin plugin if you didn't already. You do not need the annotation processor Gradle plugin in this project. That's only needed by the consumer. You do, however, need kotlinpoet:

implementation "com.squareup:kotlinpoet:1.2.0"

This is to simplify aspects of the code generation itself, which is the important part here.

Now, create the annotation:

@Retention(AnnotationRetention.SOURCE)
@Target(AnnotationTarget.CLASS)
annotation class AutoUnpack

This is pretty much all you need. The retention is set to source because it has no value at runtime, and it only targets compile time.

Next, there's the processor itself. This is somewhat complicated, so bear with me. For reference, this uses the javax.* packages for annotation processing. Android note: this might work assuming you can plug in a Java module on a compileOnly scope without getting the Android SDK restrictions. As I mentioned earlier, this is mainly for pure Kotlin; Android might work, but I haven't tested that.

Anyways, the generator:

Because I couldn't find a way to generate the method into the class without touching the rest (and because according to this, that isn't possible), I'm going with an extension function generation approach.

You'll need a class UnpackCodeGenerator : AbstractProcessor(). In there, you'll first need two lines of boilerplate:

override fun getSupportedAnnotationTypes(): MutableSet<String> = mutableSetOf(AutoUnpack::class.java.name)
override fun getSupportedSourceVersion(): SourceVersion = SourceVersion.latest()

Moving on, there's the processing. Override the process function:

override fun process(annotations: MutableSet<out TypeElement>, roundEnv: RoundEnvironment): Boolean {
    // Find elements with the annotation
    val annotatedElements = roundEnv.getElementsAnnotatedWith(AutoUnpack::class.java)
    if(annotatedElements.isEmpty()) {
        // Self-explanatory
        return false;
    }
    // Iterate the elements
    annotatedElements.forEach { element ->
        // Grab the name and package 
        val name = element.simpleName.toString()
        val pkg = processingEnv.elementUtils.getPackageOf(element).toString()
        // Then generate the class
        generateClass(name,
            if (pkg == "unnamed package") "" else pkg, // This is a patch for an issue where classes in the root 
                                                       // package return package as "unnamed package" rather than empty, 
                                                       // which breaks syntax because "package unnamed package" isn't legal. 
            element)
    }
    // Return true for success
    return true;
}

This just sets up some of the later framework. The real magic happens in the generateClass function:

private fun generateClass(className: String, pkg: String, element: Element){
    val elements = element.enclosedElements
    val classVariables = elements
        .filter {
            val name = if (it.simpleName.contains("\$delegate"))
                it.simpleName.toString().substring(0, it.simpleName.indexOf("$"))
            else it.simpleName.toString()
            it.kind == ElementKind.FIELD // Find fields
                    && Modifier.STATIC !in it.modifiers // that aren't static (thanks to sebaslogen for issue #1: https://github.com/LunarWatcher/KClassUnpacker/issues/1)
                    // Additionally, we have to ignore private fields. Extension functions can't access these, and accessing
                    // them is a bad idea anyway. Kotlin lets you expose get without exposing set. If you, by default, don't
                    // allow access to the getter, there's a high chance exposing it is a bad idea.
                    && elements.any { getter -> getter.kind == ElementKind.METHOD // find methods
                            && getter.simpleName.toString() ==
                                    "get${name[0].toUpperCase().toString() + (if (name.length > 1) name.substring(1) else "")}" // that matches the getter name (by the standard convention)
                            && Modifier.PUBLIC in getter.modifiers // that are marked public
                    }
        } // Grab the variables
        .map {
            // Map the name now. Also supports later filtering
            if (it.simpleName.endsWith("\$delegate")) {
                // Support by lazy
                it.simpleName.subSequence(0, it.simpleName.indexOf("$"))
            } else it.simpleName
        }
    if (classVariables.isEmpty()) return; // Self-explanatory
    val file = FileSpec.builder(pkg, className)
        .addFunction(FunSpec.builder("iterator") // For automatic unpacking in a for loop
            .receiver(element.asType().asTypeName().copy()) // Add it as an extension function of the class
            .addStatement("return listOf(${classVariables.joinToString(", ")}).iterator()") // add the return statement. Create a list, push an iterator.
            .addModifiers(KModifier.PUBLIC, KModifier.OPERATOR) // This needs to be public. Because it's an iterator, the function also needs the `operator` keyword
            .build()
        ).build()
    // Grab the generate directory.
    val genDir = processingEnv.options["kapt.kotlin.generated"]!!
    // Then write the file.
    file.writeTo(File(genDir, "$pkg/${element.simpleName.replace("\\.kt".toRegex(), "")}Generated.kt"))
}

All of the relevant lines have comments explaining use, in case you're not familiar with what this does.

Finally, in order to get the processor to process, you need to register it. In the module for the generator, add a file called javax.annotation.processing.Processor under main/resources/META-INF/services. In there you write:

com.package.of.UnpackCodeGenerator

From here, you need to link it using compileOnly and kapt. If you added it as a module to your project, you can do:

kapt project(":ClassUnpacker")
compileOnly project(":ClassUnpacker")

Alternative source setup:

Like I mentioned earlier, I bundled this into a jar for convenience. It's under the same license as SO uses (CC-BY-SA 3.0), and it contains the exact same code as in the answer (although compiled into a single project).

If you want to use this one, just add the Jitpack repo:

repositories {
    // Other repos here
    maven { url 'https://jitpack.io' }
}

And hook it up with:

kapt 'com.github.LunarWatcher:KClassUnpacker:v1.0.1'
compileOnly "com.github.LunarWatcher:KClassUnpacker:v1.0.1"

Note that the version here may not be up to date: the up to date list of versions is available here. The code in the post still aims to reflect the repo, but versions aren't really important enough to edit every time.

Usage

Regardless of which way you ended up using to get the annotations, the usage is relatively easy:

@AutoUnpack data class ExampleDataClass(val x: String, val y: Int, var m: Boolean)

fun main(a: Array<String>) {
    val cls = ExampleDataClass("example", 42, false)
    for(field in cls) {
        println(field)
    }
}

This prints:

example
42
false

Now you have a reflection-less way of iterating fields.

Note that local testing has been done partially with IntelliJ, but IntelliJ doesn't seem to like me - I've had various failed builds where gradlew clean && gradlew build from a command line oddly works fine. I'm not sure whether this is a local problem, or if this is a general problem, but you might have some issues like this if you build from IntelliJ.

Also, you might get errors if the build fails. The IntelliJ linter builds on top of the build directory for some sources, so if the build fails and the file with the extension function isn't generated, that'll cause it to appear as an error. Building usually fixes this when I tested (with both modules and from Jitpack).

You'll also likely have to enable the annotation processor setting if you use Android Studio or IntelliJ.

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