1 /*
2 * Copyright (c) 2012, 2024, Oracle and/or its affiliates. All rights reserved.
3 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER.
4 *
5 * This code is free software; you can redistribute it and/or modify it
6 * under the terms of the GNU General Public License version 2 only, as
7 * published by the Free Software Foundation. Oracle designates this
8 * particular file as subject to the "Classpath" exception as provided
9 * by Oracle in the LICENSE file that accompanied this code.
10 *
11 * This code is distributed in the hope that it will be useful, but WITHOUT
12 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or
13 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License
14 * version 2 for more details (a copy is included in the LICENSE file that
15 * accompanied this code).
16 *
17 * You should have received a copy of the GNU General Public License version
18 * 2 along with this work; if not, write to the Free Software Foundation,
19 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA.
20 *
21 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA
22 * or visit www.oracle.com if you need additional information or have any
23 * questions.
24 */
25
26 package java.lang.invoke;
27
28 import jdk.internal.constant.ClassOrInterfaceDescImpl;
29 import jdk.internal.misc.CDS;
30 import jdk.internal.util.ClassFileDumper;
31 import sun.invoke.util.VerifyAccess;
32
33 import java.io.Serializable;
34 import java.lang.classfile.ClassBuilder;
35 import java.lang.classfile.ClassFile;
36 import java.lang.classfile.CodeBuilder;
37 import java.lang.classfile.MethodBuilder;
38 import java.lang.classfile.Opcode;
39 import java.lang.classfile.TypeKind;
40 import java.lang.classfile.constantpool.MethodHandleEntry;
41 import java.lang.classfile.constantpool.NameAndTypeEntry;
42 import java.lang.constant.ClassDesc;
43 import java.lang.constant.MethodTypeDesc;
44 import java.lang.invoke.MethodHandles.Lookup;
45 import java.lang.module.Configuration;
46 import java.lang.module.ModuleFinder;
47 import java.lang.reflect.Modifier;
48 import java.util.LinkedHashSet;
49 import java.util.List;
50 import java.util.Set;
51 import java.util.function.Consumer;
52
53 import static java.lang.classfile.ClassFile.*;
54 import java.lang.classfile.attribute.ExceptionsAttribute;
55 import java.lang.classfile.constantpool.ClassEntry;
56 import java.lang.classfile.constantpool.ConstantPoolBuilder;
57
58 import static java.lang.constant.ConstantDescs.*;
59 import static java.lang.invoke.MethodHandleNatives.Constants.NESTMATE_CLASS;
60 import static java.lang.invoke.MethodHandleNatives.Constants.STRONG_LOADER_LINK;
61 import jdk.internal.constant.ConstantUtils;
62 import jdk.internal.constant.MethodTypeDescImpl;
63 import jdk.internal.vm.annotation.Stable;
64 import sun.invoke.util.Wrapper;
65
66 /**
67 * Lambda metafactory implementation which dynamically creates an
68 * inner-class-like class per lambda callsite.
69 *
70 * @see LambdaMetafactory
71 */
72 /* package */ final class InnerClassLambdaMetafactory extends AbstractValidatingLambdaMetafactory {
73 private static final String LAMBDA_INSTANCE_FIELD = "LAMBDA_INSTANCE$";
74 private static final @Stable String[] ARG_NAME_CACHE = {"arg$1", "arg$2", "arg$3", "arg$4", "arg$5", "arg$6", "arg$7", "arg$8"};
75 private static final ClassDesc[] EMPTY_CLASSDESC_ARRAY = ConstantUtils.EMPTY_CLASSDESC;
76
77 // Static builders to avoid lambdas
78 record MethodBody(Consumer<CodeBuilder> code) implements Consumer<MethodBuilder> {
79 @Override
80 public void accept(MethodBuilder mb) {
81 mb.withCode(code);
82 }
83 };
84
85 // For dumping generated classes to disk, for debugging purposes
86 private static final ClassFileDumper lambdaProxyClassFileDumper;
87
88 private static final boolean disableEagerInitialization;
89
90 private static final String NAME_METHOD_QUOTED = "__internal_quoted";
91 private static final String quotedInstanceFieldName = "quoted";
92 private static final String COMPILER_GENERATED_MODEL_FIELD_NAME = "COMPILER_GENERATED_MODEL";
93
94 static {
95 // To dump the lambda proxy classes, set this system property:
96 // -Djdk.invoke.LambdaMetafactory.dumpProxyClassFiles
97 // or -Djdk.invoke.LambdaMetafactory.dumpProxyClassFiles=true
98 final String dumpProxyClassesKey = "jdk.invoke.LambdaMetafactory.dumpProxyClassFiles";
99 lambdaProxyClassFileDumper = ClassFileDumper.getInstance(dumpProxyClassesKey, "DUMP_LAMBDA_PROXY_CLASS_FILES");
100
101 final String disableEagerInitializationKey = "jdk.internal.lambda.disableEagerInitialization";
102 disableEagerInitialization = Boolean.getBoolean(disableEagerInitializationKey);
103 }
104
105 // See context values in AbstractValidatingLambdaMetafactory
106 private final ClassDesc implMethodClassDesc; // Name of type containing implementation "CC"
107 private final String implMethodName; // Name of implementation method "impl"
108 private final MethodTypeDesc implMethodDesc; // Type descriptor for implementation methods "(I)Ljava/lang/String;"
109 private final MethodType constructorType; // Generated class constructor type "(CC)void"
110 private final MethodTypeDesc constructorTypeDesc;// Type descriptor for the generated class constructor type "(CC)void"
111 private final ClassDesc[] argDescs; // Type descriptors for the constructor arguments
112 private final String lambdaClassName; // Generated name for the generated class "X$$Lambda$1"
113 private final ConstantPoolBuilder pool = ConstantPoolBuilder.of();
114 private final ClassEntry lambdaClassEntry; // Class entry for the generated class "X$$Lambda$1"
115 private final boolean useImplMethodHandle; // use MethodHandle invocation instead of symbolic bytecode invocation
116
117 /**
118 * General meta-factory constructor, supporting both standard cases and
119 * allowing for uncommon options such as serialization or bridging.
120 *
121 * @param caller Stacked automatically by VM; represents a lookup context
122 * with the accessibility privileges of the caller.
123 * @param factoryType Stacked automatically by VM; the signature of the
124 * invoked method, which includes the expected static
125 * type of the returned lambda object, and the static
126 * types of the captured arguments for the lambda. In
127 * the event that the implementation method is an
128 * instance method, the first argument in the invocation
129 * signature will correspond to the receiver.
130 * @param interfaceMethodName Name of the method in the functional interface to
131 * which the lambda or method reference is being
132 * converted, represented as a String.
133 * @param interfaceMethodType Type of the method in the functional interface to
134 * which the lambda or method reference is being
135 * converted, represented as a MethodType.
136 * @param implementation The implementation method which should be called (with
137 * suitable adaptation of argument types, return types,
138 * and adjustment for captured arguments) when methods of
139 * the resulting functional interface instance are invoked.
140 * @param dynamicMethodType The signature of the primary functional
141 * interface method after type variables are
142 * substituted with their instantiation from
143 * the capture site
144 * @param isSerializable Should the lambda be made serializable? If set,
145 * either the target type or one of the additional SAM
146 * types must extend {@code Serializable}.
147 * @param altInterfaces Additional interfaces which the lambda object
148 * should implement.
149 * @param altMethods Method types for additional signatures to be
150 * implemented by invoking the implementation method
151 * @throws LambdaConversionException If any of the meta-factory protocol
152 * invariants are violated
153 */
154 public InnerClassLambdaMetafactory(MethodHandles.Lookup caller,
155 MethodType factoryType,
156 String interfaceMethodName,
157 MethodType interfaceMethodType,
158 MethodHandle implementation,
159 MethodType dynamicMethodType,
160 boolean isSerializable,
161 Class<?>[] altInterfaces,
162 MethodType[] altMethods,
163 MethodHandle reflectiveField)
164 throws LambdaConversionException {
165 super(caller, factoryType, interfaceMethodName, interfaceMethodType,
166 implementation, dynamicMethodType,
167 isSerializable, altInterfaces, altMethods, reflectiveField);
168 implMethodClassDesc = implClassDesc(implClass);
169 implMethodName = implInfo.getName();
170 implMethodDesc = methodDesc(implInfo.getMethodType());
171 constructorType = factoryType.changeReturnType(Void.TYPE);
172 lambdaClassName = lambdaClassName(targetClass);
173 lambdaClassEntry = pool.classEntry(ConstantUtils.internalNameToDesc(lambdaClassName));
174 // If the target class invokes a protected method inherited from a
175 // superclass in a different package, or does 'invokespecial', the
176 // lambda class has no access to the resolved method, or does
177 // 'invokestatic' on a hidden class which cannot be resolved by name.
178 // Instead, we need to pass the live implementation method handle to
179 // the proxy class to invoke directly. (javac prefers to avoid this
180 // situation by generating bridges in the target class)
181 useImplMethodHandle = (Modifier.isProtected(implInfo.getModifiers()) &&
182 !VerifyAccess.isSamePackage(targetClass, implInfo.getDeclaringClass())) ||
183 implKind == MethodHandleInfo.REF_invokeSpecial ||
184 implKind == MethodHandleInfo.REF_invokeStatic && implClass.isHidden();
185 int parameterCount = factoryType.parameterCount();
186 ClassDesc[] argDescs;
187 MethodTypeDesc constructorTypeDesc;
188 if (parameterCount > 0) {
189 argDescs = new ClassDesc[parameterCount];
190 for (int i = 0; i < parameterCount; i++) {
191 argDescs[i] = classDesc(factoryType.parameterType(i));
192 }
193 constructorTypeDesc = MethodTypeDescImpl.ofValidated(CD_void, argDescs);
194 } else {
195 argDescs = EMPTY_CLASSDESC_ARRAY;
196 constructorTypeDesc = MTD_void;
197 }
198 this.argDescs = argDescs;
199 this.constructorTypeDesc = constructorTypeDesc;
200 }
201
202 private static String argName(int i) {
203 return i < ARG_NAME_CACHE.length ? ARG_NAME_CACHE[i] : "arg$" + (i + 1);
204 }
205
206 private static String sanitizedTargetClassName(Class<?> targetClass) {
207 String name = targetClass.getName();
208 if (targetClass.isHidden()) {
209 // use the original class name
210 name = name.replace('/', '_');
211 }
212 return name.replace('.', '/');
213 }
214
215 private static String lambdaClassName(Class<?> targetClass) {
216 return sanitizedTargetClassName(targetClass).concat("$$Lambda");
217 }
218
219 /**
220 * Build the CallSite. Generate a class file which implements the functional
221 * interface, define the class, if there are no parameters create an instance
222 * of the class which the CallSite will return, otherwise, generate handles
223 * which will call the class' constructor.
224 *
225 * @return a CallSite, which, when invoked, will return an instance of the
226 * functional interface
227 * @throws LambdaConversionException If properly formed functional interface
228 * is not found
229 */
230 @Override
231 CallSite buildCallSite() throws LambdaConversionException {
232 final Class<?> innerClass = spinInnerClass();
233 if (factoryType.parameterCount() == 0 && disableEagerInitialization) {
234 try {
235 return new ConstantCallSite(caller.findStaticGetter(innerClass, LAMBDA_INSTANCE_FIELD,
236 factoryType.returnType()));
237 } catch (ReflectiveOperationException e) {
238 throw new LambdaConversionException(
239 "Exception finding " + LAMBDA_INSTANCE_FIELD + " static field", e);
240 }
241 } else {
242 try {
243 MethodHandle mh = caller.findConstructor(innerClass, constructorType);
244 if (factoryType.parameterCount() == 0) {
245 // In the case of a non-capturing lambda, we optimize linkage by pre-computing a single instance
246 Object inst = mh.invokeBasic();
247 return new ConstantCallSite(MethodHandles.constant(interfaceClass, inst));
248 } else {
249 return new ConstantCallSite(mh.asType(factoryType));
250 }
251 } catch (ReflectiveOperationException e) {
252 throw new LambdaConversionException("Exception finding constructor", e);
253 } catch (Throwable e) {
254 throw new LambdaConversionException("Exception instantiating lambda object", e);
255 }
256 }
257 }
258
259 /**
260 * Spins the lambda proxy class.
261 *
262 * This first checks if a lambda proxy class can be loaded from CDS archive.
263 * Otherwise, generate the lambda proxy class. If CDS dumping is enabled, it
264 * registers the lambda proxy class for including into the CDS archive.
265 */
266 private Class<?> spinInnerClass() throws LambdaConversionException {
267 // CDS does not handle disableEagerInitialization or useImplMethodHandle
268 if (!disableEagerInitialization && !useImplMethodHandle) {
269 if (CDS.isUsingArchive()) {
270 // load from CDS archive if present
271 Class<?> innerClass = LambdaProxyClassArchive.find(targetClass,
272 interfaceMethodName,
273 factoryType,
274 interfaceMethodType,
275 implementation,
276 dynamicMethodType,
277 isSerializable,
278 altInterfaces,
279 altMethods);
280 if (innerClass != null) return innerClass;
281 }
282
283 // include lambda proxy class in CDS archive at dump time
284 if (CDS.isDumpingArchive()) {
285 Class<?> innerClass = generateInnerClass();
286 LambdaProxyClassArchive.register(targetClass,
287 interfaceMethodName,
288 factoryType,
289 interfaceMethodType,
290 implementation,
291 dynamicMethodType,
292 isSerializable,
293 altInterfaces,
294 altMethods,
295 innerClass);
296 return innerClass;
297 }
298
299 }
300 return generateInnerClass();
301 }
302
303 /**
304 * Generate a class file which implements the functional
305 * interface, define and return the class.
306 *
307 * @return a Class which implements the functional interface
308 * @throws LambdaConversionException If properly formed functional interface
309 * is not found
310 */
311 private Class<?> generateInnerClass() throws LambdaConversionException {
312 List<ClassDesc> interfaces;
313 ClassDesc interfaceDesc = classDesc(interfaceClass);
314 boolean accidentallySerializable = !isSerializable && Serializable.class.isAssignableFrom(interfaceClass);
315 if (altInterfaces.length == 0) {
316 interfaces = List.of(interfaceDesc);
317 } else {
318 // Assure no duplicate interfaces (ClassFormatError)
319 Set<ClassDesc> itfs = LinkedHashSet.newLinkedHashSet(altInterfaces.length + 1);
320 itfs.add(interfaceDesc);
321 for (Class<?> i : altInterfaces) {
322 itfs.add(classDesc(i));
323 accidentallySerializable |= !isSerializable && Serializable.class.isAssignableFrom(i);
324 }
325 interfaces = List.copyOf(itfs);
326 }
327 final boolean finalAccidentallySerializable = accidentallySerializable;
328 final byte[] classBytes = ClassFile.of().build(lambdaClassEntry, pool, new Consumer<ClassBuilder>() {
329 @Override
330 public void accept(ClassBuilder clb) {
331 clb.withFlags(ACC_SUPER | ACC_FINAL | ACC_SYNTHETIC)
332 .withInterfaceSymbols(interfaces);
333 // Generate final fields to be filled in by constructor
334 for (int i = 0; i < argDescs.length; i++) {
335 clb.withField(argName(i), argDescs[i], ACC_PRIVATE | ACC_FINAL);
336 }
337
338 // if quotable, generate the field that will hold the value of quoted
339 if (quotableOpGetter != null) {
340 clb.withField(quotedInstanceFieldName, CodeReflectionSupport.CD_Quoted, ACC_PRIVATE + ACC_FINAL);
341 }
342
343 generateConstructor(clb);
344
345 generateClassInitializationMethod(clb);
346
347
348 // Forward the SAM method
349 clb.withMethodBody(interfaceMethodName,
350 methodDesc(interfaceMethodType),
351 ACC_PUBLIC,
352 forwardingMethod(interfaceMethodType));
353
354 // Forward the bridges
355 if (altMethods != null) {
356 for (MethodType mt : altMethods) {
357 clb.withMethodBody(interfaceMethodName,
358 methodDesc(mt),
359 ACC_PUBLIC | ACC_BRIDGE,
360 forwardingMethod(mt));
361 }
362 }
363
364 if (isSerializable)
365 generateSerializationFriendlyMethods(clb);
366 else if (finalAccidentallySerializable)
367 generateSerializationHostileMethods(clb);
368
369 if (quotableOpGetter != null) {
370 generateQuotedMethod(clb);
371 }
372 }
373 });
374
375 // Define the generated class in this VM.
376
377 try {
378 // this class is linked at the indy callsite; so define a hidden nestmate
379 List<?> classdata;
380 if (useImplMethodHandle || quotableOpGetter != null) {
381 classdata = quotableOpGetter == null ?
382 List.of(implementation) :
383 List.of(implementation, quotableOpGetter, CodeReflectionSupport.QUOTED_EXTRACT_OP_MH);
384 } else {
385 classdata = null;
386 }
387 return caller.makeHiddenClassDefiner(lambdaClassName, classBytes, lambdaProxyClassFileDumper, NESTMATE_CLASS | STRONG_LOADER_LINK)
388 .defineClass(!disableEagerInitialization, classdata);
389
390 } catch (Throwable t) {
391 throw new InternalError(t);
392 }
393 }
394
395 private void generateClassInitializationMethod(ClassBuilder clb) {
396 if (!(factoryType.parameterCount() == 0 && disableEagerInitialization) && quotableOpGetter == null) {
397 return;
398 }
399 clb.withMethodBody(CLASS_INIT_NAME, MTD_void, ACC_STATIC, new Consumer<CodeBuilder>() {
400 @Override
401 public void accept(CodeBuilder cob) {
402 if (factoryType.parameterCount() == 0 && disableEagerInitialization) {
403 ClassDesc lambdaTypeDescriptor = classDesc(factoryType.returnType());
404 // Generate the static final field that holds the lambda singleton
405 clb.withField(LAMBDA_INSTANCE_FIELD, lambdaTypeDescriptor, ACC_PRIVATE | ACC_STATIC | ACC_FINAL);
406 cob.new_(lambdaClassEntry)
407 .dup()
408 .invokespecial(pool.methodRefEntry(lambdaClassEntry, pool.nameAndTypeEntry(INIT_NAME, constructorTypeDesc)))
409 .putstatic(pool.fieldRefEntry(lambdaClassEntry, pool.nameAndTypeEntry(LAMBDA_INSTANCE_FIELD, lambdaTypeDescriptor)));
410 }
411
412 if (quotableOpGetter != null) {
413 // if we visit a callsite twice, we will use the same class
414 // if the lambda doesn't capture values we only have one instance, model shared anyway
415 // if it captures values, each visit result in a creation of new instance of the class
416 // those instances have the same code model generated by the compiler
417 // they may differ in captured values
418 // as first step let's share the compiler generated code model
419 ClassDesc funcOpClassDesc = CodeReflectionSupport.FUNC_OP_CLASS.describeConstable().get();
420 clb.withField(COMPILER_GENERATED_MODEL_FIELD_NAME, funcOpClassDesc,
421 ACC_PRIVATE | ACC_STATIC | ACC_FINAL);
422
423 ConstantPoolBuilder cp = pool;
424 MethodHandleEntry bsmDataAt = cp.methodHandleEntry(BSM_CLASS_DATA_AT);
425 NameAndTypeEntry natMH = cp.nameAndTypeEntry(DEFAULT_NAME, CD_MethodHandle);
426 // load quotableOpGetter
427 cob.ldc(cp.constantDynamicEntry(cp.bsmEntry(bsmDataAt, List.of(cp.intEntry(1))), natMH));
428 MethodType mtype = quotableOpGetterInfo.getMethodType();
429 if (quotableOpGetterInfo.getReferenceKind() != MethodHandleInfo.REF_invokeStatic) {
430 mtype = mtype.insertParameterTypes(0, implClass);
431 }
432 cob.invokevirtual(CD_MethodHandle, "invokeExact", mtype.describeConstable().get());
433 cob.checkcast(funcOpClassDesc);
434 cob.putstatic(lambdaClassEntry.asSymbol(), COMPILER_GENERATED_MODEL_FIELD_NAME, funcOpClassDesc);
435 }
436 cob.return_();
437 }
438 });
439 }
440
441 /**
442 * Generate the constructor for the class
443 */
444 private void generateConstructor(ClassBuilder clb) {
445 // Generate constructor
446 clb.withMethodBody(INIT_NAME, constructorTypeDesc, ACC_PRIVATE,
447 new Consumer<>() {
448 @Override
449 public void accept(CodeBuilder cob) {
450 cob.aload(0)
451 .invokespecial(CD_Object, INIT_NAME, MTD_void);
452 int parameterCount = factoryType.parameterCount();
453 for (int i = 0; i < parameterCount; i++) {
454 cob.aload(0)
455 .loadLocal(TypeKind.from(factoryType.parameterType(i)), cob.parameterSlot(i))
456 .putfield(pool.fieldRefEntry(lambdaClassEntry, pool.nameAndTypeEntry(argName(i), argDescs[i])));
457 }
458 if (quotableOpGetter != null) {
459 generateQuotedFieldInitializer(cob);
460 }
461 cob.return_();
462 }
463 });
464 }
465
466 private void generateQuotedFieldInitializer(CodeBuilder cob) {
467 ConstantPoolBuilder cp = cob.constantPool();
468 MethodHandleEntry bsmDataAt = cp.methodHandleEntry(BSM_CLASS_DATA_AT);
469 NameAndTypeEntry natMH = cp.nameAndTypeEntry(DEFAULT_NAME, CD_MethodHandle);
470 // push the receiver on the stack for operand of put field instruction
471 cob.aload(0)
472 // load class data: CodeReflectionSupport.HANDLE_MAKE_QUOTED
473 .ldc(cp.constantDynamicEntry(cp.bsmEntry(bsmDataAt, List.of(cp.intEntry(2))), natMH))
474 .getstatic(lambdaClassEntry.asSymbol(), COMPILER_GENERATED_MODEL_FIELD_NAME,
475 CodeReflectionSupport.FUNC_OP_CLASS.describeConstable().get());
476
477
478 // load captured args in array
479
480 int capturedArity = factoryType.parameterCount();
481 cob.loadConstant(capturedArity)
482 .anewarray(CD_Object);
483 // initialize quoted captures
484 for (int i = 0; i < capturedArity; i++) {
485 cob.dup()
486 .loadConstant(i)
487 .aload(0)
488 .getfield(lambdaClassEntry.asSymbol(), argName(i), argDescs[i]);
489 TypeConvertingMethodAdapter.boxIfTypePrimitive(cob, TypeKind.from(argDescs[i]));
490 cob.aastore();
491 }
492
493 // Create a Quoted from FuncOp and captured args Object[]
494
495 cob.invokevirtual(CD_MethodHandle, "invokeExact", methodDesc(CodeReflectionSupport.QUOTED_EXTRACT_OP_MH.type()))
496 .putfield(lambdaClassEntry.asSymbol(), quotedInstanceFieldName, CodeReflectionSupport.CD_Quoted);
497 }
498
499 static class CodeReflectionSupport {
500 static final Class<?> QUOTED_CLASS;
501 static final Class<?> QUOTABLE_CLASS;
502 static final MethodHandle QUOTED_EXTRACT_OP_MH;
503 static final Class<?> FUNC_OP_CLASS;
504
505 static {
506 try {
507 ModuleLayer layer = codeLayer();
508 ClassLoader cl = layer.findLoader("jdk.incubator.code");
509 QUOTED_CLASS = cl.loadClass("jdk.incubator.code.Quoted");
510 QUOTABLE_CLASS = cl.loadClass("jdk.incubator.code.Quotable");
511 FUNC_OP_CLASS = cl.loadClass("jdk.incubator.code.dialect.core.CoreOp$FuncOp");
512 QUOTED_EXTRACT_OP_MH = Lookup.IMPL_LOOKUP.findStatic(QUOTED_CLASS, "extractOp",
513 MethodType.methodType(QUOTED_CLASS, FUNC_OP_CLASS, Object[].class));
514 } catch (Throwable ex) {
515 throw new ExceptionInInitializerError(ex);
516 }
517 }
518
519 static ModuleLayer codeLayer() {
520 final ModuleLayer codeLayer;
521 if (ModuleLayer.boot().findModule("jdk.incubator.code").isPresent()) {
522 // we are in an exploded build, so just use the boot layer
523 return ModuleLayer.boot();
524 } else if (java.lang.module.ModuleFinder.ofSystem().find("jdk.incubator.code").isPresent()) {
525 // the code module is installed, but not in the boot layer, create a new layer which contains it
526 ModuleLayer parent = ModuleLayer.boot();
527 Configuration cf = parent.configuration()
528 .resolve(ModuleFinder.of(), ModuleFinder.ofSystem(), Set.of("jdk.incubator.code"));
529 ClassLoader scl = ClassLoader.getSystemClassLoader();
530 return parent.defineModulesWithOneLoader(cf, scl);
531 } else {
532 throw new IllegalStateException("jdk.incubator.code module not found");
533 }
534 }
535
536 static final ClassDesc CD_Quoted = QUOTED_CLASS.describeConstable().get();
537 static final MethodTypeDesc MTD_Quoted = MethodTypeDescImpl.ofValidated(CD_Quoted);
538 }
539
540 private static class SerializationSupport {
541 // Serialization support
542 private static final ClassDesc CD_SerializedLambda = ClassOrInterfaceDescImpl.ofValidated("Ljava/lang/invoke/SerializedLambda;");
543 private static final ClassDesc CD_ObjectOutputStream = ClassOrInterfaceDescImpl.ofValidated("Ljava/io/ObjectOutputStream;");
544 private static final ClassDesc CD_ObjectInputStream = ClassOrInterfaceDescImpl.ofValidated("Ljava/io/ObjectInputStream;");
545 private static final MethodTypeDesc MTD_Object = MethodTypeDescImpl.ofValidated(CD_Object);
546 private static final MethodTypeDesc MTD_void_ObjectOutputStream = MethodTypeDescImpl.ofValidated(CD_void, CD_ObjectOutputStream);
547 private static final MethodTypeDesc MTD_void_ObjectInputStream = MethodTypeDescImpl.ofValidated(CD_void, CD_ObjectInputStream);
548
549 private static final String NAME_METHOD_WRITE_REPLACE = "writeReplace";
550 private static final String NAME_METHOD_READ_OBJECT = "readObject";
551 private static final String NAME_METHOD_WRITE_OBJECT = "writeObject";
552
553 static final ClassDesc CD_NotSerializableException = ClassOrInterfaceDescImpl.ofValidated("Ljava/io/NotSerializableException;");
554 static final MethodTypeDesc MTD_CTOR_NOT_SERIALIZABLE_EXCEPTION = MethodTypeDescImpl.ofValidated(CD_void, CD_String);
555 static final MethodTypeDesc MTD_CTOR_SERIALIZED_LAMBDA = MethodTypeDescImpl.ofValidated(CD_void,
556 CD_Class, CD_String, CD_String, CD_String, CD_int, CD_String, CD_String, CD_String, CD_String, ConstantUtils.CD_Object_array);
557
558 }
559
560 /**
561 * Generate a writeReplace method that supports serialization
562 */
563 private void generateSerializationFriendlyMethods(ClassBuilder clb) {
564 clb.withMethodBody(SerializationSupport.NAME_METHOD_WRITE_REPLACE, SerializationSupport.MTD_Object, ACC_PRIVATE | ACC_FINAL,
565 new Consumer<>() {
566 @Override
567 public void accept(CodeBuilder cob) {
568 cob.new_(SerializationSupport.CD_SerializedLambda)
569 .dup()
570 .ldc(ClassDesc.ofInternalName(sanitizedTargetClassName(targetClass)))
571 .ldc(factoryType.returnType().getName().replace('.', '/'))
572 .ldc(interfaceMethodName)
573 .ldc(interfaceMethodType.toMethodDescriptorString())
574 .ldc(implInfo.getReferenceKind())
575 .ldc(implInfo.getDeclaringClass().getName().replace('.', '/'))
576 .ldc(implInfo.getName())
577 .ldc(implInfo.getMethodType().toMethodDescriptorString())
578 .ldc(dynamicMethodType.toMethodDescriptorString())
579 .loadConstant(argDescs.length)
580 .anewarray(CD_Object);
581 for (int i = 0; i < argDescs.length; i++) {
582 cob.dup()
583 .loadConstant(i)
584 .aload(0)
585 .getfield(pool.fieldRefEntry(lambdaClassEntry, pool.nameAndTypeEntry(argName(i), argDescs[i])));
586 TypeConvertingMethodAdapter.boxIfTypePrimitive(cob, TypeKind.from(argDescs[i]));
587 cob.aastore();
588 }
589 cob.invokespecial(SerializationSupport.CD_SerializedLambda, INIT_NAME,
590 SerializationSupport.MTD_CTOR_SERIALIZED_LAMBDA)
591 .areturn();
592 }
593 });
594 }
595
596 /**
597 * Generate method #quoted()
598 */
599 private void generateQuotedMethod(ClassBuilder clb) {
600 clb.withMethod(NAME_METHOD_QUOTED, CodeReflectionSupport.MTD_Quoted, ACC_PRIVATE + ACC_FINAL, new MethodBody(new Consumer<CodeBuilder>() {
601 @Override
602 public void accept(CodeBuilder cob) {
603 cob.aload(0)
604 .getfield(lambdaClassEntry.asSymbol(), quotedInstanceFieldName, CodeReflectionSupport.CD_Quoted)
605 .areturn();
606 }
607 }));
608 }
609
610 /**
611 * Generate a readObject/writeObject method that is hostile to serialization
612 */
613 private void generateSerializationHostileMethods(ClassBuilder clb) {
614 var hostileMethod = new Consumer<MethodBuilder>() {
615 @Override
616 public void accept(MethodBuilder mb) {
617 ConstantPoolBuilder cp = mb.constantPool();
618 ClassEntry nseCE = cp.classEntry(SerializationSupport.CD_NotSerializableException);
619 mb.with(ExceptionsAttribute.of(nseCE))
620 .withCode(new Consumer<CodeBuilder>() {
621 @Override
622 public void accept(CodeBuilder cob) {
623 cob.new_(nseCE)
624 .dup()
625 .ldc("Non-serializable lambda")
626 .invokespecial(cp.methodRefEntry(nseCE, cp.nameAndTypeEntry(INIT_NAME,
627 SerializationSupport.MTD_CTOR_NOT_SERIALIZABLE_EXCEPTION)))
628 .athrow();
629 }
630 });
631 }
632 };
633 clb.withMethod(SerializationSupport.NAME_METHOD_WRITE_OBJECT, SerializationSupport.MTD_void_ObjectOutputStream,
634 ACC_PRIVATE + ACC_FINAL, hostileMethod);
635 clb.withMethod(SerializationSupport.NAME_METHOD_READ_OBJECT, SerializationSupport.MTD_void_ObjectInputStream,
636 ACC_PRIVATE + ACC_FINAL, hostileMethod);
637 }
638
639 /**
640 * This method generates a method body which calls the lambda implementation
641 * method, converting arguments, as needed.
642 */
643 Consumer<CodeBuilder> forwardingMethod(MethodType methodType) {
644 return new Consumer<>() {
645 @Override
646 public void accept(CodeBuilder cob) {
647 if (implKind == MethodHandleInfo.REF_newInvokeSpecial) {
648 cob.new_(implMethodClassDesc)
649 .dup();
650 }
651 if (useImplMethodHandle) {
652 ConstantPoolBuilder cp = cob.constantPool();
653 cob.ldc(cp.constantDynamicEntry(cp.bsmEntry(cp.methodHandleEntry(BSM_CLASS_DATA_AT), List.of(cp.intEntry(0))),
654 cp.nameAndTypeEntry(DEFAULT_NAME, CD_MethodHandle)));
655 }
656 for (int i = 0; i < argDescs.length; i++) {
657 cob.aload(0)
658 .getfield(pool.fieldRefEntry(lambdaClassEntry, pool.nameAndTypeEntry(argName(i), argDescs[i])));
659 }
660
661 convertArgumentTypes(cob, methodType);
662
663 if (useImplMethodHandle) {
664 MethodType mtype = implInfo.getMethodType();
665 if (implKind != MethodHandleInfo.REF_invokeStatic) {
666 mtype = mtype.insertParameterTypes(0, implClass);
667 }
668 cob.invokevirtual(CD_MethodHandle, "invokeExact", methodDesc(mtype));
669 } else {
670 // Invoke the method we want to forward to
671 cob.invoke(invocationOpcode(), implMethodClassDesc, implMethodName, implMethodDesc, implClass.isInterface());
672 }
673 // Convert the return value (if any) and return it
674 // Note: if adapting from non-void to void, the 'return'
675 // instruction will pop the unneeded result
676 Class<?> implReturnClass = implMethodType.returnType();
677 Class<?> samReturnClass = methodType.returnType();
678 TypeConvertingMethodAdapter.convertType(cob, implReturnClass, samReturnClass, samReturnClass);
679 cob.return_(TypeKind.from(samReturnClass));
680 }
681 };
682 }
683
684 private void convertArgumentTypes(CodeBuilder cob, MethodType samType) {
685 int samParametersLength = samType.parameterCount();
686 int captureArity = factoryType.parameterCount();
687 for (int i = 0; i < samParametersLength; i++) {
688 Class<?> argType = samType.parameterType(i);
689 cob.loadLocal(TypeKind.from(argType), cob.parameterSlot(i));
690 TypeConvertingMethodAdapter.convertType(cob, argType, implMethodType.parameterType(captureArity + i), dynamicMethodType.parameterType(i));
691 }
692 }
693
694 private Opcode invocationOpcode() throws InternalError {
695 return switch (implKind) {
696 case MethodHandleInfo.REF_invokeStatic -> Opcode.INVOKESTATIC;
697 case MethodHandleInfo.REF_newInvokeSpecial -> Opcode.INVOKESPECIAL;
698 case MethodHandleInfo.REF_invokeVirtual -> Opcode.INVOKEVIRTUAL;
699 case MethodHandleInfo.REF_invokeInterface -> Opcode.INVOKEINTERFACE;
700 case MethodHandleInfo.REF_invokeSpecial -> Opcode.INVOKESPECIAL;
701 default -> throw new InternalError("Unexpected invocation kind: " + implKind);
702 };
703 }
704
705 static ClassDesc implClassDesc(Class<?> cls) {
706 return cls.isHidden() ? null : ConstantUtils.referenceClassDesc(cls.descriptorString());
707 }
708
709 static ClassDesc classDesc(Class<?> cls) {
710 return cls.isPrimitive() ? Wrapper.forPrimitiveType(cls).basicClassDescriptor()
711 : ConstantUtils.referenceClassDesc(cls.descriptorString());
712 }
713
714 static MethodTypeDesc methodDesc(MethodType mt) {
715 var params = new ClassDesc[mt.parameterCount()];
716 for (int i = 0; i < params.length; i++) {
717 params[i] = classDesc(mt.parameterType(i));
718 }
719 return MethodTypeDescImpl.ofValidated(classDesc(mt.returnType()), params);
720 }
721 }