Merge remote-tracking branch 'origin/adv-expr' into adv-expr-eliminate-bridging

# Conflicts: # kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/asm.kt # kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/AsmBuilder.kt
2020-06-24 15:53:19 +07:00 · 2020-06-24 15:53:19 +07:00 · f475335df1
commit f475335df1
parent d6e7eb8143 7c7065542a
8 changed files with 195 additions and 26 deletions
--- a/kmath-ast/README.md
+++ b/kmath-ast/README.md
@ -1,4 +1,61 @@
-# AST based expression representation and operations
+# AST-based expression representation and operations (`kmath-ast`)
-## Dynamic expression code generation
+This subproject implements the following features:
-Contributed by [Iaroslav Postovalov](https://github.com/CommanderTvis).
+
 - Expression Language and its parser.
 - MST as expression language's syntax intermediate representation.
 - Type-safe builder of MST.
 - Evaluating expressions by traversing MST.
 ## Dynamic expression code generation with OW2 ASM
 `kmath-ast` JVM module supports runtime code generation to eliminate overhead of tree traversal. Code generator builds 
 a special implementation of `Expression<T>` with implemented `invoke` function. 
 For example, the following builder: 
 ```kotlin
    RealField.mstInField { symbol("x") + 2 }.compile()
 ``` 
 … leads to generation of bytecode, which can be decompiled to the following Java class: 
 ```java
 package scientifik.kmath.asm.generated;
 import java.util.Map;
 import scientifik.kmath.asm.internal.AsmCompiledExpression;
 import scientifik.kmath.operations.Algebra;
 import scientifik.kmath.operations.RealField;
 // The class's name is build with MST's hash-code and collision fixing number. 
 public final class AsmCompiledExpression_45045_0 extends AsmCompiledExpression<Double> {
    // Plain constructor
    public AsmCompiledExpression_45045_0(Algebra algebra, Object[] constants) {
        super(algebra, constants);
    }
    // The actual dynamic code: 
    public final Double invoke(Map<String, ? extends Double> arguments) {
        return (Double)((RealField)super.algebra).add((Double)arguments.get("x"), (Double)2.0D);
    }
 }
 ```
 ### Example Usage
 This API is an extension to MST and MSTExpression APIs. You may optimize both MST and MSTExpression: 
 ```kotlin
 RealField.mstInField { symbol("x") + 2 }.compile()
 RealField.expression("2+2".parseMath())
 ```
 ### Known issues
 - Using numeric algebras causes boxing and calling bridge methods. 
 - The same classes may be generated and loaded twice, so it is recommended to cache compiled expressions to avoid
 class loading overhead. 
 - This API is not supported by non-dynamic JVM implementations (like TeaVM and GraalVM) because of using class loaders.
 Contributed by [Iaroslav Postovalov](https://github.com/CommanderTvis).
--- a/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/asm.kt
+++ b/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/asm.kt
@ -20,7 +20,8 @@ fun <T : Any> MST.compileWith(type: KClass<T>, algebra: Algebra<T>): Expression<
            is MST.Symbolic -> loadVariable(node.value)
            is MST.Numeric -> {
                val constant = if (algebra is NumericAlgebra<T>)
-                    algebra.number(node.value) else
+                    algebra.number(node.value)
                else
                    error("Number literals are not supported in $algebra")
                loadTConstant(constant)
@ -72,9 +73,13 @@ fun <T : Any> MST.compileWith(type: KClass<T>, algebra: Algebra<T>): Expression<
 /**
 * Compile an [MST] to ASM using given algebra
 */
-inline fun <reified T : Any> Algebra<T>.expresion(mst: MST): Expression<T> = mst.compileWith(T::class, this)
+inline fun <reified T : Any> Algebra<T>.expression(mst: MST): Expression<T> = mst.compileWith(T::class, this)
 /**
 * Optimize performance of an [MSTExpression] using ASM codegen
 */
-inline fun <reified T : Any> MSTExpression<T>.compile(): Expression<T> = mst.compileWith(T::class, algebra)
+inline fun <reified T : Any> MSTExpression<T>.compile(): Expression<T> = mst.compileWith(T::class, algebra)
 fun main() {
    RealField.mstInField { symbol("x") + 2 }.compile()
 }
--- a/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/AsmBuilder.kt
+++ b/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/AsmBuilder.kt
@ -6,7 +6,6 @@ import org.objectweb.asm.MethodVisitor
 import org.objectweb.asm.Opcodes
 import scientifik.kmath.asm.internal.AsmBuilder.ClassLoader
 import scientifik.kmath.operations.Algebra
 import java.io.File
 /**
 * ASM Builder is a structure that abstracts building a class that unwraps [AsmExpression] to plain Java expression.
@ -22,10 +21,16 @@ internal class AsmBuilder<T> internal constructor(
    private val className: String,
    private val invokeLabel0Visitor: AsmBuilder<T>.() -> Unit
 ) {
    /**
     * Internal classloader of [AsmBuilder] with alias to define class from byte array.
     */
    private class ClassLoader(parent: java.lang.ClassLoader) : java.lang.ClassLoader(parent) {
        internal fun defineClass(name: String?, b: ByteArray): Class<*> = defineClass(name, b, 0, b.size)
    }
    /**
     * The instance of [ClassLoader] used by this builder.
     */
    private val classLoader: ClassLoader =
        ClassLoader(javaClass.classLoader)
@ -36,16 +41,41 @@ internal class AsmBuilder<T> internal constructor(
    private val T_CLASS: String = classOfT.name.replace('.', '/')
    private val slashesClassName: String = className.replace(oldChar = '.', newChar = '/')
    /**
     * Index of `this` variable in invoke method of [AsmCompiledExpression] built subclass.
     */
    private val invokeThisVar: Int = 0
    /**
     * Index of `arguments` variable in invoke method of [AsmCompiledExpression] built subclass.
     */
    private val invokeArgumentsVar: Int = 1
    /**
     * List of constants to provide to [AsmCompiledExpression] subclass.
     */
    private val constants: MutableList<Any> = mutableListOf()
    /**
     * Method visitor of `invoke` method of [AsmCompiledExpression] subclass.
     */
    private lateinit var invokeMethodVisitor: MethodVisitor
    private var primitiveMode = false
    internal var primitiveType = OBJECT_CLASS
    internal var primitiveTypeSig = "L$OBJECT_CLASS;"
    internal var primitiveTypeReturnSig = "L$OBJECT_CLASS;"
    /**
     * The cache of [AsmCompiledExpression] subclass built by this builder.
     */
    private var generatedInstance: AsmCompiledExpression<T>? = null
    /**
     * Subclasses, loads and instantiates the [AsmCompiledExpression] for given parameters.
     *
     * The built instance is cached.
     */
    @Suppress("UNCHECKED_CAST")
    fun getInstance(): AsmCompiledExpression<T> {
        generatedInstance?.let { return it }
@ -187,8 +217,6 @@ internal class AsmBuilder<T> internal constructor(
            visitEnd()
        }
        File("dump.class").writeBytes(classWriter.toByteArray())
        val new = classLoader
            .defineClass(className, classWriter.toByteArray())
            .constructors
@ -199,6 +227,9 @@ internal class AsmBuilder<T> internal constructor(
        return new
    }
    /**
     * Loads a constant from
     */
    internal fun loadTConstant(value: T) {
        if (primitiveMode) {
            loadNumberConstant(value as Number)
@ -214,6 +245,9 @@ internal class AsmBuilder<T> internal constructor(
        loadConstant(value as Any, T_CLASS)
    }
    /**
     * Loads an object constant [value] stored in [AsmCompiledExpression.constants] and casts it to [type].
     */
    private fun unboxInPrimitiveMode() {
        if (!primitiveMode)
            return
@ -241,13 +275,17 @@ internal class AsmBuilder<T> internal constructor(
            visitGetField(owner = slashesClassName, name = "constants", descriptor = "[L$OBJECT_CLASS;")
            visitLdcOrIntConstant(idx)
            visitGetObjectArrayElement()
-            visitCheckCast(type)
+            invokeMethodVisitor.visitCheckCast(type)
            unboxInPrimitiveMode()
        }
    }
    private fun loadThis(): Unit = invokeMethodVisitor.visitLoadObjectVar(invokeThisVar)
    /**
     * Either loads a numeric constant [value] from [AsmCompiledExpression.constants] field or boxes a primitive
     * constant from the constant pool (some numbers with special opcodes like [Opcodes.ICONST_0] aren't even loaded
     * from it).
     */
    private fun loadNumberConstant(value: Number) {
        val clazz = value.javaClass
        val c = clazz.name.replace('.', '/')
@ -255,9 +293,12 @@ internal class AsmBuilder<T> internal constructor(
        if (sigLetter != null) {
            when (value) {
                is Byte -> invokeMethodVisitor.visitLdcOrIntConstant(value.toInt())
                is Short -> invokeMethodVisitor.visitLdcOrIntConstant(value.toInt())
                is Int -> invokeMethodVisitor.visitLdcOrIntConstant(value)
                is Double -> invokeMethodVisitor.visitLdcOrDoubleConstant(value)
                is Float -> invokeMethodVisitor.visitLdcOrFloatConstant(value)
                is Long -> invokeMethodVisitor.visitLdcOrLongConstant(value)
                else -> invokeMethodVisitor.visitLdcInsn(value)
            }
@ -270,6 +311,9 @@ internal class AsmBuilder<T> internal constructor(
        loadConstant(value, c)
    }
    /**
     * Loads a variable [name] from [AsmCompiledExpression.invoke] [Map] parameter. The [defaultValue] may be provided.
     */
    internal fun loadVariable(name: String, defaultValue: T? = null): Unit = invokeMethodVisitor.run {
        visitLoadObjectVar(invokeArgumentsVar)
@ -299,6 +343,9 @@ internal class AsmBuilder<T> internal constructor(
        unboxInPrimitiveMode()
    }
    /**
     * Loads algebra from according field of [AsmCompiledExpression] and casts it to class of [algebra] provided.
     */
    internal fun loadAlgebra() {
        loadThis()
@ -311,6 +358,13 @@ internal class AsmBuilder<T> internal constructor(
        invokeMethodVisitor.visitCheckCast(T_ALGEBRA_CLASS)
    }
    /**
     * Writes a method instruction of opcode with its [owner], [method] and its [descriptor]. The default opcode is
     * [Opcodes.INVOKEINTERFACE], since most Algebra functions are declared in interface. [loadAlgebra] should be
     * called before the arguments and this operation.
     *
     * The result is casted to [T] automatically.
     */
    internal fun invokeAlgebraOperation(
        owner: String,
        method: String,
@ -323,9 +377,15 @@ internal class AsmBuilder<T> internal constructor(
        unboxInPrimitiveMode()
    }
    /**
     * Writes a LDC Instruction with string constant provided.
     */
    internal fun loadStringConstant(string: String): Unit = invokeMethodVisitor.visitLdcInsn(string)
    internal companion object {
        /**
         * Maps JVM primitive numbers boxed types to their letters of JVM signature convention.
         */
        private val SIGNATURE_LETTERS: Map<Class<out Any>, String> by lazy {
            mapOf(
                java.lang.Byte::class.java to "B",
@ -348,6 +408,9 @@ internal class AsmBuilder<T> internal constructor(
            )
        }
        /**
         * Provides boxed number types values of which can be stored in JVM bytecode constant pool.
         */
        private val INLINABLE_NUMBERS: Set<Class<out Any>> by lazy { SIGNATURE_LETTERS.keys }
        internal const val FUNCTIONAL_COMPILED_EXPRESSION_CLASS =
--- a/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/AsmCompiledExpression.kt
+++ b/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/AsmCompiledExpression.kt
@ -3,6 +3,13 @@ package scientifik.kmath.asm.internal
 import scientifik.kmath.expressions.Expression
 import scientifik.kmath.operations.Algebra
 /**
 * [Expression] partial implementation to have it subclassed by actual implementations. Provides unified storage for
 * objects needed to implement the expression.
 *
 * @property algebra the algebra to delegate calls.
 * @property constants the constants array to have persistent objects to reference in [invoke].
 */
 internal abstract class AsmCompiledExpression<T> internal constructor(
    @JvmField protected val algebra: Algebra<T>,
    @JvmField protected val constants: Array<Any>
--- a/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/buildName.kt
+++ b/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/buildName.kt
@ -2,7 +2,13 @@ package scientifik.kmath.asm.internal
 import scientifik.kmath.ast.MST
-internal fun buildName(mst: MST, collision: Int = 0): String {
+/**
 * Creates a class name for [AsmCompiledExpression] subclassed to implement [mst] provided.
 *
 * This methods helps to avoid collisions of class name to prevent loading several classes with the same name. If there
 * is a colliding class, change [collision] parameter or leave it `0` to check existing classes recursively.
 */
 internal tailrec fun buildName(mst: MST, collision: Int = 0): String {
    val name = "scientifik.kmath.asm.generated.AsmCompiledExpression_${mst.hashCode()}_$collision"
    try {
--- a/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/methodVisitors.kt
+++ b/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/methodVisitors.kt
@ -11,6 +11,8 @@ internal fun MethodVisitor.visitLdcOrIntConstant(value: Int): Unit = when (value
    3 -> visitInsn(ICONST_3)
    4 -> visitInsn(ICONST_4)
    5 -> visitInsn(ICONST_5)
    in -128..127 -> visitIntInsn(BIPUSH, value)
    in -32768..32767 -> visitIntInsn(SIPUSH, value)
    else -> visitLdcInsn(value)
 }
@ -20,6 +22,12 @@ internal fun MethodVisitor.visitLdcOrDoubleConstant(value: Double): Unit = when
    else -> visitLdcInsn(value)
 }
 internal fun MethodVisitor.visitLdcOrLongConstant(value: Long): Unit = when (value) {
    0L -> visitInsn(LCONST_0)
    1L -> visitInsn(LCONST_1)
    else -> visitLdcInsn(value)
 }
 internal fun MethodVisitor.visitLdcOrFloatConstant(value: Float): Unit = when (value) {
    0f -> visitInsn(FCONST_0)
    1f -> visitInsn(FCONST_1)
--- a/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/specialization.kt
+++ b/kmath-ast/src/jvmMain/kotlin/scientifik/kmath/asm/internal/specialization.kt
@ -3,21 +3,38 @@ package scientifik.kmath.asm.internal
 import org.objectweb.asm.Opcodes
 import scientifik.kmath.operations.Algebra
-private val methodNameAdapters: Map<String, String> = mapOf("+" to "add", "*" to "multiply", "/" to "divide")
+private val methodNameAdapters: Map<String, String> by lazy {
    hashMapOf(
        "+" to "add",
        "*" to "multiply",
        "/" to "divide"
    )
 }
 /**
 * Checks if the target [context] for code generation contains a method with needed [name] and [arity].
 *
 * @return `true` if contains, else `false`.
 */
 internal fun <T> hasSpecific(context: Algebra<T>, name: String, arity: Int): Boolean {
    val aName = methodNameAdapters[name] ?: name
-    context::class.java.methods.find { it.name == aName && it.parameters.size == arity }
+    context.javaClass.methods.find { it.name == aName && it.parameters.size == arity }
        ?: return false
    return true
 }
 /**
 * Checks if the target [context] for code generation contains a method with needed [name] and [arity] and inserts
 * [AsmBuilder.invokeAlgebraOperation] of this method.
 *
 * @return `true` if contains, else `false`.
 */
 internal fun <T> AsmBuilder<T>.tryInvokeSpecific(context: Algebra<T>, name: String, arity: Int): Boolean {
    val aName = methodNameAdapters[name] ?: name
-    context::class.java.methods.find { it.name == aName && it.parameters.size == arity }
+    context.javaClass.methods.find { it.name == aName && it.parameters.size == arity }
        ?: return false
    val owner = context::class.java.name.replace('.', '/')
@ -33,8 +50,7 @@ internal fun <T> AsmBuilder<T>.tryInvokeSpecific(context: Algebra<T>, name: Stri
        owner = owner,
        method = aName,
        descriptor = sig,
-        opcode = Opcodes.INVOKEVIRTUAL,
+        opcode = Opcodes.INVOKEVIRTUAL
        isInterface = false
    )
    return true
--- a/kmath-core/src/commonMain/kotlin/scientifik/kmath/expressions/FunctionalExpressionAlgebra.kt
+++ b/kmath-core/src/commonMain/kotlin/scientifik/kmath/expressions/FunctionalExpressionAlgebra.kt
@ -36,12 +36,10 @@ internal class FunctionalConstProductExpression<T>(
 /**
 * A context class for [Expression] construction.
 *
 * @param algebra The algebra to provide for Expressions built.
 */
-interface FunctionalExpressionAlgebra<T, A : Algebra<T>> : ExpressionAlgebra<T, Expression<T>> {
+abstract class FunctionalExpressionAlgebra<T, A : Algebra<T>>(val algebra: A) : ExpressionAlgebra<T, Expression<T>> {
    /**
     * The algebra to provide for Expressions built.
     */
    val algebra: A
    /**
     * Builds an Expression of constant expression which does not depend on arguments.
@ -69,8 +67,8 @@ interface FunctionalExpressionAlgebra<T, A : Algebra<T>> : ExpressionAlgebra<T,
 /**
 * A context class for [Expression] construction for [Space] algebras.
 */
-open class FunctionalExpressionSpace<T, A : Space<T>>(override val algebra: A) :
+open class FunctionalExpressionSpace<T, A : Space<T>>(algebra: A) :
-    FunctionalExpressionAlgebra<T, A>, Space<Expression<T>> {
+    FunctionalExpressionAlgebra<T, A>(algebra), Space<Expression<T>> {
    override val zero: Expression<T> get() = const(algebra.zero)
@ -98,7 +96,7 @@ open class FunctionalExpressionSpace<T, A : Space<T>>(override val algebra: A) :
        super<FunctionalExpressionAlgebra>.binaryOperation(operation, left, right)
 }
-open class FunctionalExpressionRing<T, A>(override val algebra: A) : FunctionalExpressionSpace<T, A>(algebra),
+open class FunctionalExpressionRing<T, A>(algebra: A) : FunctionalExpressionSpace<T, A>(algebra),
    Ring<Expression<T>> where  A : Ring<T>, A : NumericAlgebra<T> {
    override val one: Expression<T>
        get() = const(algebra.one)
@ -119,7 +117,7 @@ open class FunctionalExpressionRing<T, A>(override val algebra: A) : FunctionalE
        super<FunctionalExpressionSpace>.binaryOperation(operation, left, right)
 }
-open class FunctionalExpressionField<T, A>(override val algebra: A) :
+open class FunctionalExpressionField<T, A>(algebra: A) :
    FunctionalExpressionRing<T, A>(algebra),
    Field<Expression<T>> where A : Field<T>, A : NumericAlgebra<T> {
    /**
@ -137,3 +135,12 @@ open class FunctionalExpressionField<T, A>(override val algebra: A) :
    override fun binaryOperation(operation: String, left: Expression<T>, right: Expression<T>): Expression<T> =
        super<FunctionalExpressionRing>.binaryOperation(operation, left, right)
 }
 inline fun <T, A : Space<T>> A.expressionInSpace(block: FunctionalExpressionSpace<T, A>.() -> Expression<T>): Expression<T> =
    FunctionalExpressionSpace(this).block()
 inline fun <T, A : Ring<T>> A.expressionInRing(block: FunctionalExpressionRing<T, A>.() -> Expression<T>): Expression<T> =
    FunctionalExpressionRing(this).block()
 inline fun <T, A : Field<T>> A.expressionInField(block: FunctionalExpressionField<T, A>.() -> Expression<T>): Expression<T> =
    FunctionalExpressionField(this).block()