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/*
* Copyright 2010-2022 JetBrains s.r.o. and Kotlin Programming Language contributors.
* Use of this source code is governed by the Apache 2.0 license that can be found in the license/LICENSE.txt file.
*/
package org.jetbrains.kotlinx.dataframe.plugin
import org.jetbrains.kotlin.fir.FirSession
import org.jetbrains.kotlin.fir.analysis.checkers.toClassLikeSymbol
import org.jetbrains.kotlinx.dataframe.plugin.extensions.KotlinTypeFacade
import org.jetbrains.kotlinx.dataframe.plugin.extensions.Marker
import org.jetbrains.kotlinx.dataframe.plugin.impl.Interpreter
import org.jetbrains.kotlinx.dataframe.plugin.impl.Present
import org.jetbrains.kotlinx.dataframe.plugin.utils.Names
import org.jetbrains.kotlin.fir.declarations.FirResolvePhase
import org.jetbrains.kotlin.fir.declarations.findArgumentByName
import org.jetbrains.kotlin.fir.declarations.getAnnotationByClassId
import org.jetbrains.kotlin.fir.declarations.hasAnnotation
import org.jetbrains.kotlin.fir.declarations.utils.isLocal
import org.jetbrains.kotlin.fir.expressions.FirAnonymousFunctionExpression
import org.jetbrains.kotlin.fir.expressions.FirCallableReferenceAccess
import org.jetbrains.kotlin.fir.expressions.FirErrorExpression
import org.jetbrains.kotlin.fir.expressions.FirExpression
import org.jetbrains.kotlin.fir.expressions.FirFunctionCall
import org.jetbrains.kotlin.fir.expressions.FirLiteralExpression
import org.jetbrains.kotlin.fir.expressions.FirPropertyAccessExpression
import org.jetbrains.kotlin.fir.expressions.FirResolvedQualifier
import org.jetbrains.kotlin.fir.expressions.FirReturnExpression
import org.jetbrains.kotlin.fir.expressions.FirThisReceiverExpression
import org.jetbrains.kotlin.fir.expressions.FirVarargArgumentsExpression
import org.jetbrains.kotlin.fir.expressions.arguments
import org.jetbrains.kotlin.fir.expressions.impl.FirResolvedArgumentList
import org.jetbrains.kotlin.fir.references.FirResolvedCallableReference
import org.jetbrains.kotlin.fir.references.FirResolvedNamedReference
import org.jetbrains.kotlin.fir.references.resolved
import org.jetbrains.kotlin.fir.references.symbol
import org.jetbrains.kotlin.fir.references.toResolvedCallableSymbol
import org.jetbrains.kotlin.fir.resolve.fqName
import org.jetbrains.kotlin.fir.scopes.collectAllProperties
import org.jetbrains.kotlin.fir.scopes.getProperties
import org.jetbrains.kotlin.fir.scopes.impl.declaredMemberScope
import org.jetbrains.kotlin.fir.symbols.impl.FirEnumEntrySymbol
import org.jetbrains.kotlin.fir.symbols.impl.FirPropertySymbol
import org.jetbrains.kotlin.fir.symbols.impl.FirRegularClassSymbol
import org.jetbrains.kotlin.fir.symbols.impl.FirTypeAliasSymbol
import org.jetbrains.kotlin.fir.symbols.impl.FirTypeParameterSymbol
import org.jetbrains.kotlin.fir.symbols.impl.FirValueParameterSymbol
import org.jetbrains.kotlin.fir.types.ConeClassLikeType
import org.jetbrains.kotlin.fir.types.ConeIntersectionType
import org.jetbrains.kotlin.fir.types.ConeKotlinType
import org.jetbrains.kotlin.fir.types.ConeStarProjection
import org.jetbrains.kotlin.fir.types.ConeTypeParameterType
import org.jetbrains.kotlin.fir.types.ConeTypeProjection
import org.jetbrains.kotlin.fir.types.classId
import org.jetbrains.kotlin.fir.types.coneType
import org.jetbrains.kotlin.fir.types.isNullableString
import org.jetbrains.kotlin.fir.types.isPrimitiveOrNullablePrimitive
import org.jetbrains.kotlin.fir.types.isStarProjection
import org.jetbrains.kotlin.fir.types.isString
import org.jetbrains.kotlin.fir.types.resolvedType
import org.jetbrains.kotlin.fir.types.returnType
import org.jetbrains.kotlin.fir.types.toConeTypeProjection
import org.jetbrains.kotlin.fir.types.toRegularClassSymbol
import org.jetbrains.kotlin.fir.types.toSymbol
import org.jetbrains.kotlin.fir.types.type
import org.jetbrains.kotlin.name.ClassId
import org.jetbrains.kotlin.name.FqName
import org.jetbrains.kotlin.name.Name
import org.jetbrains.kotlin.utils.addToStdlib.runIf
import org.jetbrains.kotlinx.dataframe.annotations.*
import org.jetbrains.kotlinx.dataframe.plugin.impl.data.ColumnPathApproximation
import org.jetbrains.kotlinx.dataframe.plugin.impl.data.ColumnWithPathApproximation
import org.jetbrains.kotlinx.dataframe.plugin.impl.data.DataFrameCallableId
import org.jetbrains.kotlinx.dataframe.plugin.impl.data.KPropertyApproximation
import org.jetbrains.kotlinx.dataframe.plugin.impl.PluginDataFrameSchema
import org.jetbrains.kotlinx.dataframe.plugin.impl.SimpleCol
import org.jetbrains.kotlinx.dataframe.plugin.impl.SimpleDataColumn
import org.jetbrains.kotlinx.dataframe.plugin.impl.SimpleColumnGroup
import org.jetbrains.kotlinx.dataframe.plugin.impl.SimpleFrameColumn
import org.jetbrains.kotlinx.dataframe.plugin.impl.api.ColumnsResolver
import org.jetbrains.kotlinx.dataframe.plugin.impl.api.SingleColumnApproximation
import org.jetbrains.kotlinx.dataframe.plugin.impl.api.TypeApproximation
fun KotlinTypeFacade.interpret(
functionCall: FirFunctionCall,
processor: Interpreter,
additionalArguments: Map> = emptyMap(),
reporter: InterpretationErrorReporter,
): Interpreter.Success? {
val refinedArguments: RefinedArguments = functionCall.collectArgumentExpressions()
val defaultArguments = processor.expectedArguments.filter { it.defaultValue is Present }.map { it.name }.toSet()
val actualValueArguments = refinedArguments.associateBy { it.name.identifier }.toSortedMap()
val conflictingKeys = additionalArguments.keys intersect actualValueArguments.keys
if (conflictingKeys.isNotEmpty()) {
if (isTest) {
interpretationFrameworkError("Conflicting keys: $conflictingKeys")
}
return null
}
val expectedArgsMap = processor.expectedArguments
.associateBy { it.name }.toSortedMap().minus(additionalArguments.keys)
val typeArguments = buildMap {
functionCall.typeArguments.forEachIndexed { index, firTypeProjection ->
val key = "typeArg$index"
val lens = expectedArgsMap[key]?.lens ?: return@forEachIndexed
val value: Any = if (lens == Interpreter.Id) {
firTypeProjection.toConeTypeProjection()
} else {
val type = firTypeProjection.toConeTypeProjection().type ?: session.builtinTypes.nullableAnyType.type
if (type is ConeIntersectionType) return@forEachIndexed
Marker(type)
}
put(key, Interpreter.Success(value))
}
}
val unexpectedArguments = (expectedArgsMap.keys - defaultArguments) != (actualValueArguments.keys + typeArguments.keys - defaultArguments)
if (unexpectedArguments) {
if (isTest) {
val message = buildString {
appendLine("ERROR: Different set of arguments")
appendLine("Implementation class: $processor")
appendLine("Not found in actual: ${expectedArgsMap.keys - actualValueArguments.keys}")
val diff = actualValueArguments.keys - expectedArgsMap.keys
appendLine("Passed, but not expected: ${diff}")
appendLine("add arguments to an interpeter:")
appendLine(diff.map { actualValueArguments[it] })
}
interpretationFrameworkError(message)
}
return null
}
val arguments = mutableMapOf>()
arguments += additionalArguments
arguments += typeArguments
val interpretationResults = refinedArguments.refinedArguments.mapNotNull {
val name = it.name.identifier
val expectedArgument = expectedArgsMap[name] ?: error("$processor $name")
val expectedReturnType = expectedArgument.klass
val value: Interpreter.Success? = when (expectedArgument.lens) {
is Interpreter.Value -> {
when (val expression = it.expression) {
is FirLiteralExpression -> Interpreter.Success(expression.value!!)
is FirVarargArgumentsExpression -> {
val args = expression.arguments.map {
when (it) {
is FirLiteralExpression -> it.value
is FirCallableReferenceAccess -> {
toKPropertyApproximation(it, session)
}
is FirFunctionCall -> {
it.loadInterpreter()?.let { processor ->
interpret(it, processor, emptyMap(), reporter)
}
}
else -> null
}
}
Interpreter.Success(args)
}
is FirFunctionCall -> {
val interpreter = expression.loadInterpreter()
if (interpreter == null) {
// if the plugin already transformed call, its original form is the last expression of .let { }
val argument = expression.arguments.getOrNull(0)
val last = (argument as? FirAnonymousFunctionExpression)?.anonymousFunction?.body?.statements?.lastOrNull()
val call = (last as? FirReturnExpression)?.result as? FirFunctionCall
call?.loadInterpreter()?.let {
interpret(call, it, emptyMap(), reporter)
}
} else {
interpreter.let {
val result = interpret(expression, interpreter, emptyMap(), reporter)
result
}
}
}
is FirPropertyAccessExpression -> {
(expression.calleeReference as? FirResolvedNamedReference)?.let {
val symbol = it.resolvedSymbol
val firPropertySymbol = symbol as? FirPropertySymbol
val literalInitializer = runIf(firPropertySymbol?.resolvedReturnType?.canHaveLiteralInitializer == true) {
firPropertySymbol?.resolvedInitializer as? FirLiteralExpression
}
if (symbol is FirEnumEntrySymbol) {
Interpreter.Success(
DataFrameCallableId(
packageName = symbol.callableId.packageName.asString(),
className = symbol.callableId.className!!.asString(),
callableName = symbol.callableId.callableName.asString()
)
)
} else if (literalInitializer != null) {
Interpreter.Success(literalInitializer.value)
} else {
Interpreter.Success(columnWithPathApproximations(expression))
}
}
}
is FirCallableReferenceAccess -> {
Interpreter.Success(toKPropertyApproximation(expression, session))
}
is FirAnonymousFunctionExpression -> {
val result = (expression.anonymousFunction.body?.statements?.lastOrNull() as? FirReturnExpression)?.result
val col: Any? = when (result) {
is FirPropertyAccessExpression -> {
columnWithPathApproximations(result)
}
is FirFunctionCall -> {
val interpreter = result.loadInterpreter()
if (interpreter == null) {
reporter.reportInterpretationError(result, "Cannot load interpreter")
}
interpreter?.let {
val value = interpret(result, interpreter, reporter = reporter)?.value
value
}
}
is FirErrorExpression -> null
else -> null
}
col?.let { Interpreter.Success(it) }
}
else -> null
}
}
is Interpreter.ReturnType -> {
val returnType = it.expression.resolvedType.returnType(session)
Interpreter.Success(Marker(returnType))
}
is Interpreter.Dsl -> {
{ receiver: Any, dslArguments: Map> ->
val map = mapOf("dsl" to Interpreter.Success(receiver)) + dslArguments
(it.expression as FirAnonymousFunctionExpression)
.anonymousFunction.body!!
.statements.filterIsInstance()
.forEach { call ->
val schemaProcessor = call.loadInterpreter() ?: return@forEach
interpret(
call,
schemaProcessor,
map,
reporter
)
}
}.let { Interpreter.Success(it) }
}
is Interpreter.Schema -> {
assert(expectedReturnType.toString() == PluginDataFrameSchema::class.qualifiedName!!) {
"'$name' should be ${PluginDataFrameSchema::class.qualifiedName!!}, but plugin expect $expectedReturnType"
}
val objectWithSchema = it.expression.getSchema()
if (objectWithSchema == null) {
reporter.doNotReportInterpretationError()
null
} else {
val arg = objectWithSchema.schemaArg
val schemaTypeArg = (objectWithSchema.typeRef as ConeClassLikeType).typeArguments[arg]
val schema = pluginDataFrameSchema(schemaTypeArg)
Interpreter.Success(schema)
}
}
is Interpreter.Id -> {
Interpreter.Success(it.expression)
}
}
value?.let { value1 -> it.name.identifier to value1 }
}
return if (interpretationResults.size == refinedArguments.refinedArguments.size) {
arguments.putAll(interpretationResults)
when (val res = processor.interpret(arguments, this)) {
is Interpreter.Success -> res
is Interpreter.Error -> {
reporter.reportInterpretationError(functionCall, res.message ?: "")
return null
}
}
} else {
return null
}
}
fun interpretationFrameworkError(message: String): Nothing = throw InterpretationFrameworkError(message)
class InterpretationFrameworkError(message: String) : Error(message)
interface InterpretationErrorReporter {
val errorReported: Boolean
fun reportInterpretationError(call: FirFunctionCall, message: String)
fun doNotReportInterpretationError()
companion object {
val DEFAULT = object : InterpretationErrorReporter {
override val errorReported: Boolean = false
override fun reportInterpretationError(call: FirFunctionCall, message: String) {
}
override fun doNotReportInterpretationError() = Unit
}
}
}
fun KotlinTypeFacade.pluginDataFrameSchema(schemaTypeArg: ConeTypeProjection): PluginDataFrameSchema {
val schema = if (schemaTypeArg.isStarProjection) {
PluginDataFrameSchema.EMPTY
} else {
val coneClassLikeType = schemaTypeArg.type as? ConeClassLikeType ?: return PluginDataFrameSchema.EMPTY
pluginDataFrameSchema(coneClassLikeType)
}
return schema
}
fun KotlinTypeFacade.pluginDataFrameSchema(coneClassLikeType: ConeClassLikeType): PluginDataFrameSchema {
val symbol = coneClassLikeType.toSymbol(session) as? FirRegularClassSymbol ?: return PluginDataFrameSchema.EMPTY
val declarationSymbols = if (symbol.isLocal && symbol.resolvedSuperTypes.firstOrNull() != session.builtinTypes.anyType.type) {
val rootSchemaSymbol = symbol.resolvedSuperTypes.first().toSymbol(session) as? FirRegularClassSymbol
rootSchemaSymbol?.declaredMemberScope(session, FirResolvePhase.DECLARATIONS)
} else {
symbol.declaredMemberScope(session, FirResolvePhase.DECLARATIONS)
}.let { scope ->
val names = scope?.getCallableNames() ?: emptySet()
names.flatMap { scope?.getProperties(it) ?: emptyList() }
}
val mapping = symbol.typeParameterSymbols
.mapIndexed { i, symbol -> symbol to coneClassLikeType.typeArguments[i] }
.toMap()
var propertySymbols = declarationSymbols.filterIsInstance()
val annotations = propertySymbols.mapNotNull {
val orderArgument = it.getAnnotationByClassId(
Names.ORDER_ANNOTATION,
session
)?.argumentMapping?.mapping?.get(Names.ORDER_ARGUMENT)
(orderArgument as? FirLiteralExpression)?.value as? Int
}
if (propertySymbols.size == annotations.size) {
propertySymbols = propertySymbols.zip(annotations).sortedBy { it.second }.map { it.first }
}
val columns = propertySymbols.mapNotNull { propertySymbol ->
columnOf(propertySymbol, mapping)
}
return PluginDataFrameSchema(columns)
}
private fun KotlinTypeFacade.columnWithPathApproximations(result: FirPropertyAccessExpression): ColumnsResolver {
return result.resolvedType.let {
val column = when (it.classId) {
Names.DATA_COLUMN_CLASS_ID -> {
val type = when (val arg = it.typeArguments.single()) {
is ConeStarProjection -> session.builtinTypes.nullableAnyType.type
else -> arg as ConeClassLikeType
}
SimpleDataColumn(f(result), Marker(type))
}
Names.COLUM_GROUP_CLASS_ID -> {
val arg = it.typeArguments.single()
val path = f(result)
SimpleColumnGroup(path, pluginDataFrameSchema(arg).columns())
}
else -> return object : ColumnsResolver {
override fun resolve(df: PluginDataFrameSchema): List {
return emptyList()
}
}
}
SingleColumnApproximation(
ColumnWithPathApproximation(
path = ColumnPathApproximation(path(result)),
column
)
)
}
}
private fun KotlinTypeFacade.columnOf(it: FirPropertySymbol, mapping: Map): SimpleCol? {
val annotation = it.getAnnotationByClassId(Names.COLUMN_NAME_ANNOTATION, session)
val columnName = (annotation?.argumentMapping?.mapping?.get(Names.COLUMN_NAME_ARGUMENT) as? FirLiteralExpression)?.value as? String
val name = columnName ?: it.name.identifier
return when {
shouldBeConvertedToFrameColumn(it) -> {
val nestedColumns = it.resolvedReturnType.typeArguments[0].type
?.toRegularClassSymbol(session)
?.declaredMemberScope(session, FirResolvePhase.DECLARATIONS)
?.collectAllProperties()
?.filterIsInstance()
?.mapNotNull { columnOf(it, mapping) }
?: emptyList()
SimpleFrameColumn(name, nestedColumns)
}
shouldBeConvertedToColumnGroup(it) -> {
val type = if (isDataRow(it)) it.resolvedReturnType.typeArguments[0].type!! else it.resolvedReturnType
val nestedColumns = type
.toRegularClassSymbol(session)
?.declaredMemberScope(session, FirResolvePhase.DECLARATIONS)
?.collectAllProperties()
?.filterIsInstance()
?.mapNotNull { columnOf(it, mapping) }
?: emptyList()
SimpleColumnGroup(name, nestedColumns)
}
else -> {
val type = when (val type = it.resolvedReturnType) {
is ConeTypeParameterType -> {
val projection = mapping[type.lookupTag.typeParameterSymbol]
if (projection is ConeStarProjection) {
type.lookupTag.typeParameterSymbol.resolvedBounds.singleOrNull()?.type
} else {
projection as? ConeKotlinType
}
}
else -> type
}
type?.let { type ->
SimpleDataColumn(name, TypeApproximation(type))
}
}
}
}
private fun KotlinTypeFacade.shouldBeConvertedToColumnGroup(it: FirPropertySymbol) =
isDataRow(it) ||
it.resolvedReturnType.toRegularClassSymbol(session)?.hasAnnotation(Names.DATA_SCHEMA_CLASS_ID, session) == true
private fun isDataRow(it: FirPropertySymbol) =
it.resolvedReturnType.classId == Names.DATA_ROW_CLASS_ID
private fun KotlinTypeFacade.shouldBeConvertedToFrameColumn(it: FirPropertySymbol) =
isDataFrame(it) ||
(it.resolvedReturnType.classId == Names.LIST &&
it.resolvedReturnType.typeArguments[0].type?.toRegularClassSymbol(session)?.hasAnnotation(Names.DATA_SCHEMA_CLASS_ID, session) == true)
private fun isDataFrame(it: FirPropertySymbol) =
it.resolvedReturnType.classId == Names.DF_CLASS_ID
fun path(propertyAccessExpression: FirPropertyAccessExpression): List {
val colName = f(propertyAccessExpression)
val typeRef = propertyAccessExpression.dispatchReceiver?.resolvedType
val joinDsl = ClassId(FqName("org.jetbrains.kotlinx.dataframe.api"), Name.identifier("JoinDsl"))
if (typeRef?.classId?.equals(joinDsl) == true && colName == "right") {
return emptyList()
}
return when (val explicitReceiver = propertyAccessExpression.explicitReceiver) {
null, is FirThisReceiverExpression -> listOf(colName)
else -> {
val propertyAccess = explicitReceiver as FirPropertyAccessExpression
if (propertyAccess.calleeReference.symbol is FirValueParameterSymbol) {
listOf(colName)
} else {
path(propertyAccess) + colName
}
}
}
}
fun f(propertyAccessExpression: FirPropertyAccessExpression): String {
return propertyAccessExpression.calleeReference.resolved!!.name.identifier
}
private fun KotlinTypeFacade.toKPropertyApproximation(
firCallableReferenceAccess: FirCallableReferenceAccess,
session: FirSession
): KPropertyApproximation {
val propertyName = firCallableReferenceAccess.calleeReference.name.identifier
return (firCallableReferenceAccess.calleeReference as FirResolvedCallableReference).let {
val symbol = it.toResolvedCallableSymbol()!!
val columnName = symbol.annotations
.find { it.fqName(session)!!.asString() == ColumnName::class.qualifiedName!! }
?.let {
(it.argumentMapping.mapping[Name.identifier(ColumnName::name.name)] as FirLiteralExpression).value as String
}
val kotlinType = symbol.resolvedReturnTypeRef.type
val type1 = Marker(kotlinType)
KPropertyApproximation(columnName ?: propertyName, type1)
}
}
internal fun FirFunctionCall.collectArgumentExpressions(): RefinedArguments {
val refinedArgument = mutableListOf()
val parameterName = Name.identifier("receiver")
explicitReceiver?.let {
if (it is FirResolvedQualifier && it.resolvedToCompanionObject) {
return@let
}
refinedArgument += RefinedArgument(parameterName, it)
}
(argumentList as FirResolvedArgumentList).mapping.forEach { (expression, parameter) ->
refinedArgument += RefinedArgument(parameter.name, expression)
}
return RefinedArguments(refinedArgument)
}
internal val KotlinTypeFacade.getSchema: FirExpression.() -> ObjectWithSchema? get() = { getSchema(session) }
internal fun FirExpression.getSchema(session: FirSession): ObjectWithSchema? {
return resolvedType.toSymbol(session)?.let {
val (typeRef: ConeKotlinType, symbol) = if (it is FirTypeAliasSymbol) {
it.resolvedExpandedTypeRef.coneType to it.resolvedExpandedTypeRef.toClassLikeSymbol(session)!!
} else {
resolvedType to it
}
symbol.annotations.firstNotNullOfOrNull {
runIf(it.fqName(session)?.asString() == HasSchema::class.qualifiedName!!) {
val argumentName = Name.identifier(HasSchema::schemaArg.name)
val schemaArg = (it.findArgumentByName(argumentName) as FirLiteralExpression).value
ObjectWithSchema((schemaArg as Number).toInt(), typeRef)
}
} ?: error("Annotate ${symbol} with @HasSchema")
}
}
internal class ObjectWithSchema(val schemaArg: Int, val typeRef: ConeKotlinType)
internal val ConeKotlinType.canHaveLiteralInitializer get() = isPrimitiveOrNullablePrimitive || isString || isNullableString
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