1 /* 2 * Copyright (c) 2008, 2017, 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.misc.JavaLangInvokeAccess; 29 import jdk.internal.misc.SharedSecrets; 30 import jdk.internal.org.objectweb.asm.AnnotationVisitor; 31 import jdk.internal.org.objectweb.asm.ClassWriter; 32 import jdk.internal.org.objectweb.asm.MethodVisitor; 33 import jdk.internal.reflect.CallerSensitive; 34 import jdk.internal.reflect.Reflection; 35 import jdk.internal.vm.annotation.ForceInline; 36 import jdk.internal.vm.annotation.Stable; 37 import sun.invoke.empty.Empty; 38 import sun.invoke.util.ValueConversions; 39 import sun.invoke.util.VerifyType; 40 import sun.invoke.util.Wrapper; 41 42 import java.lang.reflect.Array; 43 import java.util.Arrays; 44 import java.util.Collections; 45 import java.util.Iterator; 46 import java.util.List; 47 import java.util.Map; 48 import java.util.function.Function; 49 import java.util.stream.Stream; 50 51 import static java.lang.invoke.LambdaForm.*; 52 import static java.lang.invoke.MethodHandleStatics.*; 53 import static java.lang.invoke.MethodHandles.Lookup.IMPL_LOOKUP; 54 import static jdk.internal.org.objectweb.asm.Opcodes.*; 55 56 /** 57 * Trusted implementation code for MethodHandle. 58 * @author jrose 59 */ 60 /*non-public*/ abstract class MethodHandleImpl { 61 62 /// Factory methods to create method handles: 63 64 static MethodHandle makeArrayElementAccessor(Class<?> arrayClass, ArrayAccess access) { 65 if (arrayClass == Object[].class) { 66 return ArrayAccess.objectAccessor(access); 67 } 68 if (!arrayClass.isArray()) 69 throw newIllegalArgumentException("not an array: "+arrayClass); 70 MethodHandle[] cache = ArrayAccessor.TYPED_ACCESSORS.get(arrayClass); 71 int cacheIndex = ArrayAccess.cacheIndex(access); 72 MethodHandle mh = cache[cacheIndex]; 73 if (mh != null) return mh; 74 mh = ArrayAccessor.getAccessor(arrayClass, access); 75 MethodType correctType = ArrayAccessor.correctType(arrayClass, access); 76 if (mh.type() != correctType) { 77 assert(mh.type().parameterType(0) == Object[].class); 78 /* if access == SET */ assert(access != ArrayAccess.SET || mh.type().parameterType(2) == Object.class); 79 /* if access == GET */ assert(access != ArrayAccess.GET || 80 (mh.type().returnType() == Object.class && 81 correctType.parameterType(0).getComponentType() == correctType.returnType())); 82 // safe to view non-strictly, because element type follows from array type 83 mh = mh.viewAsType(correctType, false); 84 } 85 mh = makeIntrinsic(mh, ArrayAccess.intrinsic(access)); 86 // Atomically update accessor cache. 87 synchronized(cache) { 88 if (cache[cacheIndex] == null) { 89 cache[cacheIndex] = mh; 90 } else { 91 // Throw away newly constructed accessor and use cached version. 92 mh = cache[cacheIndex]; 93 } 94 } 95 return mh; 96 } 97 98 enum ArrayAccess { 99 GET, SET, LENGTH; 100 101 // As ArrayAccess and ArrayAccessor have a circular dependency, the ArrayAccess properties cannot be stored in 102 // final fields. 103 104 static String opName(ArrayAccess a) { 105 switch (a) { 106 case GET: return "getElement"; 107 case SET: return "setElement"; 108 case LENGTH: return "length"; 109 } 110 throw unmatchedArrayAccess(a); 111 } 112 113 static MethodHandle objectAccessor(ArrayAccess a) { 114 switch (a) { 115 case GET: return ArrayAccessor.OBJECT_ARRAY_GETTER; 116 case SET: return ArrayAccessor.OBJECT_ARRAY_SETTER; 117 case LENGTH: return ArrayAccessor.OBJECT_ARRAY_LENGTH; 118 } 119 throw unmatchedArrayAccess(a); 120 } 121 122 static int cacheIndex(ArrayAccess a) { 123 switch (a) { 124 case GET: return ArrayAccessor.GETTER_INDEX; 125 case SET: return ArrayAccessor.SETTER_INDEX; 126 case LENGTH: return ArrayAccessor.LENGTH_INDEX; 127 } 128 throw unmatchedArrayAccess(a); 129 } 130 131 static Intrinsic intrinsic(ArrayAccess a) { 132 switch (a) { 133 case GET: return Intrinsic.ARRAY_LOAD; 134 case SET: return Intrinsic.ARRAY_STORE; 135 case LENGTH: return Intrinsic.ARRAY_LENGTH; 136 } 137 throw unmatchedArrayAccess(a); 138 } 139 } 140 141 static InternalError unmatchedArrayAccess(ArrayAccess a) { 142 return newInternalError("should not reach here (unmatched ArrayAccess: " + a + ")"); 143 } 144 145 static final class ArrayAccessor { 146 /// Support for array element and length access 147 static final int GETTER_INDEX = 0, SETTER_INDEX = 1, LENGTH_INDEX = 2, INDEX_LIMIT = 3; 148 static final ClassValue<MethodHandle[]> TYPED_ACCESSORS 149 = new ClassValue<MethodHandle[]>() { 150 @Override 151 protected MethodHandle[] computeValue(Class<?> type) { 152 return new MethodHandle[INDEX_LIMIT]; 153 } 154 }; 155 static final MethodHandle OBJECT_ARRAY_GETTER, OBJECT_ARRAY_SETTER, OBJECT_ARRAY_LENGTH; 156 static { 157 MethodHandle[] cache = TYPED_ACCESSORS.get(Object[].class); 158 cache[GETTER_INDEX] = OBJECT_ARRAY_GETTER = makeIntrinsic(getAccessor(Object[].class, ArrayAccess.GET), Intrinsic.ARRAY_LOAD); 159 cache[SETTER_INDEX] = OBJECT_ARRAY_SETTER = makeIntrinsic(getAccessor(Object[].class, ArrayAccess.SET), Intrinsic.ARRAY_STORE); 160 cache[LENGTH_INDEX] = OBJECT_ARRAY_LENGTH = makeIntrinsic(getAccessor(Object[].class, ArrayAccess.LENGTH), Intrinsic.ARRAY_LENGTH); 161 162 assert(InvokerBytecodeGenerator.isStaticallyInvocable(ArrayAccessor.OBJECT_ARRAY_GETTER.internalMemberName())); 163 assert(InvokerBytecodeGenerator.isStaticallyInvocable(ArrayAccessor.OBJECT_ARRAY_SETTER.internalMemberName())); 164 assert(InvokerBytecodeGenerator.isStaticallyInvocable(ArrayAccessor.OBJECT_ARRAY_LENGTH.internalMemberName())); 165 } 166 167 static int getElementI(int[] a, int i) { return a[i]; } 168 static long getElementJ(long[] a, int i) { return a[i]; } 169 static float getElementF(float[] a, int i) { return a[i]; } 170 static double getElementD(double[] a, int i) { return a[i]; } 171 static boolean getElementZ(boolean[] a, int i) { return a[i]; } 172 static byte getElementB(byte[] a, int i) { return a[i]; } 173 static short getElementS(short[] a, int i) { return a[i]; } 174 static char getElementC(char[] a, int i) { return a[i]; } 175 static Object getElementL(Object[] a, int i) { return a[i]; } 176 177 static void setElementI(int[] a, int i, int x) { a[i] = x; } 178 static void setElementJ(long[] a, int i, long x) { a[i] = x; } 179 static void setElementF(float[] a, int i, float x) { a[i] = x; } 180 static void setElementD(double[] a, int i, double x) { a[i] = x; } 181 static void setElementZ(boolean[] a, int i, boolean x) { a[i] = x; } 182 static void setElementB(byte[] a, int i, byte x) { a[i] = x; } 183 static void setElementS(short[] a, int i, short x) { a[i] = x; } 184 static void setElementC(char[] a, int i, char x) { a[i] = x; } 185 static void setElementL(Object[] a, int i, Object x) { a[i] = x; } 186 187 static int lengthI(int[] a) { return a.length; } 188 static int lengthJ(long[] a) { return a.length; } 189 static int lengthF(float[] a) { return a.length; } 190 static int lengthD(double[] a) { return a.length; } 191 static int lengthZ(boolean[] a) { return a.length; } 192 static int lengthB(byte[] a) { return a.length; } 193 static int lengthS(short[] a) { return a.length; } 194 static int lengthC(char[] a) { return a.length; } 195 static int lengthL(Object[] a) { return a.length; } 196 197 static String name(Class<?> arrayClass, ArrayAccess access) { 198 Class<?> elemClass = arrayClass.getComponentType(); 199 if (elemClass == null) throw newIllegalArgumentException("not an array", arrayClass); 200 return ArrayAccess.opName(access) + Wrapper.basicTypeChar(elemClass); 201 } 202 static MethodType type(Class<?> arrayClass, ArrayAccess access) { 203 Class<?> elemClass = arrayClass.getComponentType(); 204 Class<?> arrayArgClass = arrayClass; 205 if (!elemClass.isPrimitive()) { 206 arrayArgClass = Object[].class; 207 elemClass = Object.class; 208 } 209 switch (access) { 210 case GET: return MethodType.methodType(elemClass, arrayArgClass, int.class); 211 case SET: return MethodType.methodType(void.class, arrayArgClass, int.class, elemClass); 212 case LENGTH: return MethodType.methodType(int.class, arrayArgClass); 213 } 214 throw unmatchedArrayAccess(access); 215 } 216 static MethodType correctType(Class<?> arrayClass, ArrayAccess access) { 217 Class<?> elemClass = arrayClass.getComponentType(); 218 switch (access) { 219 case GET: return MethodType.methodType(elemClass, arrayClass, int.class); 220 case SET: return MethodType.methodType(void.class, arrayClass, int.class, elemClass); 221 case LENGTH: return MethodType.methodType(int.class, arrayClass); 222 } 223 throw unmatchedArrayAccess(access); 224 } 225 static MethodHandle getAccessor(Class<?> arrayClass, ArrayAccess access) { 226 String name = name(arrayClass, access); 227 MethodType type = type(arrayClass, access); 228 try { 229 return IMPL_LOOKUP.findStatic(ArrayAccessor.class, name, type); 230 } catch (ReflectiveOperationException ex) { 231 throw uncaughtException(ex); 232 } 233 } 234 } 235 236 /** 237 * Create a JVM-level adapter method handle to conform the given method 238 * handle to the similar newType, using only pairwise argument conversions. 239 * For each argument, convert incoming argument to the exact type needed. 240 * The argument conversions allowed are casting, boxing and unboxing, 241 * integral widening or narrowing, and floating point widening or narrowing. 242 * @param srcType required call type 243 * @param target original method handle 244 * @param strict if true, only asType conversions are allowed; if false, explicitCastArguments conversions allowed 245 * @param monobox if true, unboxing conversions are assumed to be exactly typed (Integer to int only, not long or double) 246 * @return an adapter to the original handle with the desired new type, 247 * or the original target if the types are already identical 248 * or null if the adaptation cannot be made 249 */ 250 static MethodHandle makePairwiseConvert(MethodHandle target, MethodType srcType, 251 boolean strict, boolean monobox) { 252 MethodType dstType = target.type(); 253 if (srcType == dstType) 254 return target; 255 return makePairwiseConvertByEditor(target, srcType, strict, monobox); 256 } 257 258 private static int countNonNull(Object[] array) { 259 int count = 0; 260 for (Object x : array) { 261 if (x != null) ++count; 262 } 263 return count; 264 } 265 266 static MethodHandle makePairwiseConvertByEditor(MethodHandle target, MethodType srcType, 267 boolean strict, boolean monobox) { 268 Object[] convSpecs = computeValueConversions(srcType, target.type(), strict, monobox); 269 int convCount = countNonNull(convSpecs); 270 if (convCount == 0) 271 return target.viewAsType(srcType, strict); 272 MethodType basicSrcType = srcType.basicType(); 273 MethodType midType = target.type().basicType(); 274 BoundMethodHandle mh = target.rebind(); 275 // FIXME: Reduce number of bindings when there is more than one Class conversion. 276 // FIXME: Reduce number of bindings when there are repeated conversions. 277 for (int i = 0; i < convSpecs.length-1; i++) { 278 Object convSpec = convSpecs[i]; 279 if (convSpec == null) continue; 280 MethodHandle fn; 281 if (convSpec instanceof Class) { 282 fn = getConstantHandle(MH_cast).bindTo(convSpec); 283 } else { 284 fn = (MethodHandle) convSpec; 285 } 286 Class<?> newType = basicSrcType.parameterType(i); 287 if (--convCount == 0) 288 midType = srcType; 289 else 290 midType = midType.changeParameterType(i, newType); 291 LambdaForm form2 = mh.editor().filterArgumentForm(1+i, BasicType.basicType(newType)); 292 mh = mh.copyWithExtendL(midType, form2, fn); 293 mh = mh.rebind(); 294 } 295 Object convSpec = convSpecs[convSpecs.length-1]; 296 if (convSpec != null) { 297 MethodHandle fn; 298 if (convSpec instanceof Class) { 299 if (convSpec == void.class) 300 fn = null; 301 else 302 fn = getConstantHandle(MH_cast).bindTo(convSpec); 303 } else { 304 fn = (MethodHandle) convSpec; 305 } 306 Class<?> newType = basicSrcType.returnType(); 307 assert(--convCount == 0); 308 midType = srcType; 309 if (fn != null) { 310 mh = mh.rebind(); // rebind if too complex 311 LambdaForm form2 = mh.editor().filterReturnForm(BasicType.basicType(newType), false); 312 mh = mh.copyWithExtendL(midType, form2, fn); 313 } else { 314 LambdaForm form2 = mh.editor().filterReturnForm(BasicType.basicType(newType), true); 315 mh = mh.copyWith(midType, form2); 316 } 317 } 318 assert(convCount == 0); 319 assert(mh.type().equals(srcType)); 320 return mh; 321 } 322 323 static MethodHandle makePairwiseConvertIndirect(MethodHandle target, MethodType srcType, 324 boolean strict, boolean monobox) { 325 assert(target.type().parameterCount() == srcType.parameterCount()); 326 // Calculate extra arguments (temporaries) required in the names array. 327 Object[] convSpecs = computeValueConversions(srcType, target.type(), strict, monobox); 328 final int INARG_COUNT = srcType.parameterCount(); 329 int convCount = countNonNull(convSpecs); 330 boolean retConv = (convSpecs[INARG_COUNT] != null); 331 boolean retVoid = srcType.returnType() == void.class; 332 if (retConv && retVoid) { 333 convCount -= 1; 334 retConv = false; 335 } 336 337 final int IN_MH = 0; 338 final int INARG_BASE = 1; 339 final int INARG_LIMIT = INARG_BASE + INARG_COUNT; 340 final int NAME_LIMIT = INARG_LIMIT + convCount + 1; 341 final int RETURN_CONV = (!retConv ? -1 : NAME_LIMIT - 1); 342 final int OUT_CALL = (!retConv ? NAME_LIMIT : RETURN_CONV) - 1; 343 final int RESULT = (retVoid ? -1 : NAME_LIMIT - 1); 344 345 // Now build a LambdaForm. 346 MethodType lambdaType = srcType.basicType().invokerType(); 347 Name[] names = arguments(NAME_LIMIT - INARG_LIMIT, lambdaType); 348 349 // Collect the arguments to the outgoing call, maybe with conversions: 350 final int OUTARG_BASE = 0; // target MH is Name.function, name Name.arguments[0] 351 Object[] outArgs = new Object[OUTARG_BASE + INARG_COUNT]; 352 353 int nameCursor = INARG_LIMIT; 354 for (int i = 0; i < INARG_COUNT; i++) { 355 Object convSpec = convSpecs[i]; 356 if (convSpec == null) { 357 // do nothing: difference is trivial 358 outArgs[OUTARG_BASE + i] = names[INARG_BASE + i]; 359 continue; 360 } 361 362 Name conv; 363 if (convSpec instanceof Class) { 364 Class<?> convClass = (Class<?>) convSpec; 365 conv = new Name(getConstantHandle(MH_cast), convClass, names[INARG_BASE + i]); 366 } else { 367 MethodHandle fn = (MethodHandle) convSpec; 368 conv = new Name(fn, names[INARG_BASE + i]); 369 } 370 assert(names[nameCursor] == null); 371 names[nameCursor++] = conv; 372 assert(outArgs[OUTARG_BASE + i] == null); 373 outArgs[OUTARG_BASE + i] = conv; 374 } 375 376 // Build argument array for the call. 377 assert(nameCursor == OUT_CALL); 378 names[OUT_CALL] = new Name(target, outArgs); 379 380 Object convSpec = convSpecs[INARG_COUNT]; 381 if (!retConv) { 382 assert(OUT_CALL == names.length-1); 383 } else { 384 Name conv; 385 if (convSpec == void.class) { 386 conv = new Name(LambdaForm.constantZero(BasicType.basicType(srcType.returnType()))); 387 } else if (convSpec instanceof Class) { 388 Class<?> convClass = (Class<?>) convSpec; 389 conv = new Name(getConstantHandle(MH_cast), convClass, names[OUT_CALL]); 390 } else { 391 MethodHandle fn = (MethodHandle) convSpec; 392 if (fn.type().parameterCount() == 0) 393 conv = new Name(fn); // don't pass retval to void conversion 394 else 395 conv = new Name(fn, names[OUT_CALL]); 396 } 397 assert(names[RETURN_CONV] == null); 398 names[RETURN_CONV] = conv; 399 assert(RETURN_CONV == names.length-1); 400 } 401 402 LambdaForm form = new LambdaForm(lambdaType.parameterCount(), names, RESULT, Kind.CONVERT); 403 return SimpleMethodHandle.make(srcType, form); 404 } 405 406 static Object[] computeValueConversions(MethodType srcType, MethodType dstType, 407 boolean strict, boolean monobox) { 408 final int INARG_COUNT = srcType.parameterCount(); 409 Object[] convSpecs = new Object[INARG_COUNT+1]; 410 for (int i = 0; i <= INARG_COUNT; i++) { 411 boolean isRet = (i == INARG_COUNT); 412 Class<?> src = isRet ? dstType.returnType() : srcType.parameterType(i); 413 Class<?> dst = isRet ? srcType.returnType() : dstType.parameterType(i); 414 if (!VerifyType.isNullConversion(src, dst, /*keepInterfaces=*/ strict)) { 415 convSpecs[i] = valueConversion(src, dst, strict, monobox); 416 } 417 } 418 return convSpecs; 419 } 420 static MethodHandle makePairwiseConvert(MethodHandle target, MethodType srcType, 421 boolean strict) { 422 return makePairwiseConvert(target, srcType, strict, /*monobox=*/ false); 423 } 424 425 /** 426 * Find a conversion function from the given source to the given destination. 427 * This conversion function will be used as a LF NamedFunction. 428 * Return a Class object if a simple cast is needed. 429 * Return void.class if void is involved. 430 */ 431 static Object valueConversion(Class<?> src, Class<?> dst, boolean strict, boolean monobox) { 432 assert(!VerifyType.isNullConversion(src, dst, /*keepInterfaces=*/ strict)); // caller responsibility 433 if (dst == void.class) 434 return dst; 435 MethodHandle fn; 436 if (src.isPrimitive()) { 437 if (src == void.class) { 438 return void.class; // caller must recognize this specially 439 } else if (dst.isPrimitive()) { 440 // Examples: int->byte, byte->int, boolean->int (!strict) 441 fn = ValueConversions.convertPrimitive(src, dst); 442 } else { 443 // Examples: int->Integer, boolean->Object, float->Number 444 Wrapper wsrc = Wrapper.forPrimitiveType(src); 445 fn = ValueConversions.boxExact(wsrc); 446 assert(fn.type().parameterType(0) == wsrc.primitiveType()); 447 assert(fn.type().returnType() == wsrc.wrapperType()); 448 if (!VerifyType.isNullConversion(wsrc.wrapperType(), dst, strict)) { 449 // Corner case, such as int->Long, which will probably fail. 450 MethodType mt = MethodType.methodType(dst, src); 451 if (strict) 452 fn = fn.asType(mt); 453 else 454 fn = MethodHandleImpl.makePairwiseConvert(fn, mt, /*strict=*/ false); 455 } 456 } 457 } else if (dst.isPrimitive()) { 458 Wrapper wdst = Wrapper.forPrimitiveType(dst); 459 if (monobox || src == wdst.wrapperType()) { 460 // Use a strongly-typed unboxer, if possible. 461 fn = ValueConversions.unboxExact(wdst, strict); 462 } else { 463 // Examples: Object->int, Number->int, Comparable->int, Byte->int 464 // must include additional conversions 465 // src must be examined at runtime, to detect Byte, Character, etc. 466 fn = (strict 467 ? ValueConversions.unboxWiden(wdst) 468 : ValueConversions.unboxCast(wdst)); 469 } 470 } else { 471 // Simple reference conversion. 472 // Note: Do not check for a class hierarchy relation 473 // between src and dst. In all cases a 'null' argument 474 // will pass the cast conversion. 475 return dst; 476 } 477 assert(fn.type().parameterCount() <= 1) : "pc"+Arrays.asList(src.getSimpleName(), dst.getSimpleName(), fn); 478 return fn; 479 } 480 481 static MethodHandle makeVarargsCollector(MethodHandle target, Class<?> arrayType) { 482 MethodType type = target.type(); 483 int last = type.parameterCount() - 1; 484 if (type.parameterType(last) != arrayType) 485 target = target.asType(type.changeParameterType(last, arrayType)); 486 target = target.asFixedArity(); // make sure this attribute is turned off 487 return new AsVarargsCollector(target, arrayType); 488 } 489 490 private static final class AsVarargsCollector extends DelegatingMethodHandle { 491 private final MethodHandle target; 492 private final Class<?> arrayType; 493 private @Stable MethodHandle asCollectorCache; 494 495 AsVarargsCollector(MethodHandle target, Class<?> arrayType) { 496 this(target.type(), target, arrayType); 497 } 498 AsVarargsCollector(MethodType type, MethodHandle target, Class<?> arrayType) { 499 super(type, target); 500 this.target = target; 501 this.arrayType = arrayType; 502 this.asCollectorCache = target.asCollector(arrayType, 0); 503 } 504 505 @Override 506 public boolean isVarargsCollector() { 507 return true; 508 } 509 510 @Override 511 protected MethodHandle getTarget() { 512 return target; 513 } 514 515 @Override 516 public MethodHandle asFixedArity() { 517 return target; 518 } 519 520 @Override 521 MethodHandle setVarargs(MemberName member) { 522 if (member.isVarargs()) return this; 523 return asFixedArity(); 524 } 525 526 @Override 527 public MethodHandle withVarargs(boolean makeVarargs) { 528 if (makeVarargs) return this; 529 return asFixedArity(); 530 } 531 532 @Override 533 public MethodHandle asTypeUncached(MethodType newType) { 534 MethodType type = this.type(); 535 int collectArg = type.parameterCount() - 1; 536 int newArity = newType.parameterCount(); 537 if (newArity == collectArg+1 && 538 type.parameterType(collectArg).isAssignableFrom(newType.parameterType(collectArg))) { 539 // if arity and trailing parameter are compatible, do normal thing 540 return asTypeCache = asFixedArity().asType(newType); 541 } 542 // check cache 543 MethodHandle acc = asCollectorCache; 544 if (acc != null && acc.type().parameterCount() == newArity) 545 return asTypeCache = acc.asType(newType); 546 // build and cache a collector 547 int arrayLength = newArity - collectArg; 548 MethodHandle collector; 549 try { 550 collector = asFixedArity().asCollector(arrayType, arrayLength); 551 assert(collector.type().parameterCount() == newArity) : "newArity="+newArity+" but collector="+collector; 552 } catch (IllegalArgumentException ex) { 553 throw new WrongMethodTypeException("cannot build collector", ex); 554 } 555 asCollectorCache = collector; 556 return asTypeCache = collector.asType(newType); 557 } 558 559 @Override 560 boolean viewAsTypeChecks(MethodType newType, boolean strict) { 561 super.viewAsTypeChecks(newType, true); 562 if (strict) return true; 563 // extra assertion for non-strict checks: 564 assert (type().lastParameterType().getComponentType() 565 .isAssignableFrom( 566 newType.lastParameterType().getComponentType())) 567 : Arrays.asList(this, newType); 568 return true; 569 } 570 571 @Override 572 public Object invokeWithArguments(Object... arguments) throws Throwable { 573 MethodType type = this.type(); 574 int argc; 575 final int MAX_SAFE = 127; // 127 longs require 254 slots, which is safe to spread 576 if (arguments == null 577 || (argc = arguments.length) <= MAX_SAFE 578 || argc < type.parameterCount()) { 579 return super.invokeWithArguments(arguments); 580 } 581 582 // a jumbo invocation requires more explicit reboxing of the trailing arguments 583 int uncollected = type.parameterCount() - 1; 584 Class<?> elemType = arrayType.getComponentType(); 585 int collected = argc - uncollected; 586 Object collArgs = (elemType == Object.class) 587 ? new Object[collected] : Array.newInstance(elemType, collected); 588 if (!elemType.isPrimitive()) { 589 // simple cast: just do some casting 590 try { 591 System.arraycopy(arguments, uncollected, collArgs, 0, collected); 592 } catch (ArrayStoreException ex) { 593 return super.invokeWithArguments(arguments); 594 } 595 } else { 596 // corner case of flat array requires reflection (or specialized copy loop) 597 MethodHandle arraySetter = MethodHandles.arrayElementSetter(arrayType); 598 try { 599 for (int i = 0; i < collected; i++) { 600 arraySetter.invoke(collArgs, i, arguments[uncollected + i]); 601 } 602 } catch (WrongMethodTypeException|ClassCastException ex) { 603 return super.invokeWithArguments(arguments); 604 } 605 } 606 607 // chop the jumbo list down to size and call in non-varargs mode 608 Object[] newArgs = new Object[uncollected + 1]; 609 System.arraycopy(arguments, 0, newArgs, 0, uncollected); 610 newArgs[uncollected] = collArgs; 611 return asFixedArity().invokeWithArguments(newArgs); 612 } 613 } 614 615 /** Factory method: Spread selected argument. */ 616 static MethodHandle makeSpreadArguments(MethodHandle target, 617 Class<?> spreadArgType, int spreadArgPos, int spreadArgCount) { 618 MethodType targetType = target.type(); 619 620 for (int i = 0; i < spreadArgCount; i++) { 621 Class<?> arg = VerifyType.spreadArgElementType(spreadArgType, i); 622 if (arg == null) arg = Object.class; 623 targetType = targetType.changeParameterType(spreadArgPos + i, arg); 624 } 625 target = target.asType(targetType); 626 627 MethodType srcType = targetType 628 .replaceParameterTypes(spreadArgPos, spreadArgPos + spreadArgCount, spreadArgType); 629 // Now build a LambdaForm. 630 MethodType lambdaType = srcType.invokerType(); 631 Name[] names = arguments(spreadArgCount + 2, lambdaType); 632 int nameCursor = lambdaType.parameterCount(); 633 int[] indexes = new int[targetType.parameterCount()]; 634 635 for (int i = 0, argIndex = 1; i < targetType.parameterCount() + 1; i++, argIndex++) { 636 Class<?> src = lambdaType.parameterType(i); 637 if (i == spreadArgPos) { 638 // Spread the array. 639 MethodHandle aload = MethodHandles.arrayElementGetter(spreadArgType); 640 Name array = names[argIndex]; 641 names[nameCursor++] = new Name(getFunction(NF_checkSpreadArgument), array, spreadArgCount); 642 for (int j = 0; j < spreadArgCount; i++, j++) { 643 indexes[i] = nameCursor; 644 names[nameCursor++] = new Name(new NamedFunction(aload, Intrinsic.ARRAY_LOAD), array, j); 645 } 646 } else if (i < indexes.length) { 647 indexes[i] = argIndex; 648 } 649 } 650 assert(nameCursor == names.length-1); // leave room for the final call 651 652 // Build argument array for the call. 653 Name[] targetArgs = new Name[targetType.parameterCount()]; 654 for (int i = 0; i < targetType.parameterCount(); i++) { 655 int idx = indexes[i]; 656 targetArgs[i] = names[idx]; 657 } 658 names[names.length - 1] = new Name(target, (Object[]) targetArgs); 659 660 LambdaForm form = new LambdaForm(lambdaType.parameterCount(), names, Kind.SPREAD); 661 return SimpleMethodHandle.make(srcType, form); 662 } 663 664 static void checkSpreadArgument(Object av, int n) { 665 if (av == null) { 666 if (n == 0) return; 667 throw new NullPointerException("null array reference"); 668 } else if (av instanceof Object[]) { 669 int len = ((Object[])av).length; 670 if (len == n) return; 671 } else { 672 int len = java.lang.reflect.Array.getLength(av); 673 if (len == n) return; 674 } 675 // fall through to error: 676 throw newIllegalArgumentException("array is not of length "+n); 677 } 678 679 /** Factory method: Collect or filter selected argument(s). */ 680 static MethodHandle makeCollectArguments(MethodHandle target, 681 MethodHandle collector, int collectArgPos, boolean retainOriginalArgs) { 682 MethodType targetType = target.type(); // (a..., c, [b...])=>r 683 MethodType collectorType = collector.type(); // (b...)=>c 684 int collectArgCount = collectorType.parameterCount(); 685 Class<?> collectValType = collectorType.returnType(); 686 int collectValCount = (collectValType == void.class ? 0 : 1); 687 MethodType srcType = targetType // (a..., [b...])=>r 688 .dropParameterTypes(collectArgPos, collectArgPos+collectValCount); 689 if (!retainOriginalArgs) { // (a..., b...)=>r 690 srcType = srcType.insertParameterTypes(collectArgPos, collectorType.parameterArray()); 691 } 692 // in arglist: [0: ...keep1 | cpos: collect... | cpos+cacount: keep2... ] 693 // out arglist: [0: ...keep1 | cpos: collectVal? | cpos+cvcount: keep2... ] 694 // out(retain): [0: ...keep1 | cpos: cV? coll... | cpos+cvc+cac: keep2... ] 695 696 // Now build a LambdaForm. 697 MethodType lambdaType = srcType.invokerType(); 698 Name[] names = arguments(2, lambdaType); 699 final int collectNamePos = names.length - 2; 700 final int targetNamePos = names.length - 1; 701 702 Name[] collectorArgs = Arrays.copyOfRange(names, 1 + collectArgPos, 1 + collectArgPos + collectArgCount); 703 names[collectNamePos] = new Name(collector, (Object[]) collectorArgs); 704 705 // Build argument array for the target. 706 // Incoming LF args to copy are: [ (mh) headArgs collectArgs tailArgs ]. 707 // Output argument array is [ headArgs (collectVal)? (collectArgs)? tailArgs ]. 708 Name[] targetArgs = new Name[targetType.parameterCount()]; 709 int inputArgPos = 1; // incoming LF args to copy to target 710 int targetArgPos = 0; // fill pointer for targetArgs 711 int chunk = collectArgPos; // |headArgs| 712 System.arraycopy(names, inputArgPos, targetArgs, targetArgPos, chunk); 713 inputArgPos += chunk; 714 targetArgPos += chunk; 715 if (collectValType != void.class) { 716 targetArgs[targetArgPos++] = names[collectNamePos]; 717 } 718 chunk = collectArgCount; 719 if (retainOriginalArgs) { 720 System.arraycopy(names, inputArgPos, targetArgs, targetArgPos, chunk); 721 targetArgPos += chunk; // optionally pass on the collected chunk 722 } 723 inputArgPos += chunk; 724 chunk = targetArgs.length - targetArgPos; // all the rest 725 System.arraycopy(names, inputArgPos, targetArgs, targetArgPos, chunk); 726 assert(inputArgPos + chunk == collectNamePos); // use of rest of input args also 727 names[targetNamePos] = new Name(target, (Object[]) targetArgs); 728 729 LambdaForm form = new LambdaForm(lambdaType.parameterCount(), names, Kind.COLLECT); 730 return SimpleMethodHandle.make(srcType, form); 731 } 732 733 @LambdaForm.Hidden 734 static 735 MethodHandle selectAlternative(boolean testResult, MethodHandle target, MethodHandle fallback) { 736 if (testResult) { 737 return target; 738 } else { 739 return fallback; 740 } 741 } 742 743 // Intrinsified by C2. Counters are used during parsing to calculate branch frequencies. 744 @LambdaForm.Hidden 745 @jdk.internal.HotSpotIntrinsicCandidate 746 static 747 boolean profileBoolean(boolean result, int[] counters) { 748 // Profile is int[2] where [0] and [1] correspond to false and true occurrences respectively. 749 int idx = result ? 1 : 0; 750 try { 751 counters[idx] = Math.addExact(counters[idx], 1); 752 } catch (ArithmeticException e) { 753 // Avoid continuous overflow by halving the problematic count. 754 counters[idx] = counters[idx] / 2; 755 } 756 return result; 757 } 758 759 // Intrinsified by C2. Returns true if obj is a compile-time constant. 760 @LambdaForm.Hidden 761 @jdk.internal.HotSpotIntrinsicCandidate 762 static 763 boolean isCompileConstant(Object obj) { 764 return false; 765 } 766 767 static 768 MethodHandle makeGuardWithTest(MethodHandle test, 769 MethodHandle target, 770 MethodHandle fallback) { 771 MethodType type = target.type(); 772 assert(test.type().equals(type.changeReturnType(boolean.class)) && fallback.type().equals(type)); 773 MethodType basicType = type.basicType(); 774 LambdaForm form = makeGuardWithTestForm(basicType); 775 BoundMethodHandle mh; 776 try { 777 if (PROFILE_GWT) { 778 int[] counts = new int[2]; 779 mh = (BoundMethodHandle) 780 BoundMethodHandle.speciesData_LLLL().constructor().invokeBasic(type, form, 781 (Object) test, (Object) profile(target), (Object) profile(fallback), counts); 782 } else { 783 mh = (BoundMethodHandle) 784 BoundMethodHandle.speciesData_LLL().constructor().invokeBasic(type, form, 785 (Object) test, (Object) profile(target), (Object) profile(fallback)); 786 } 787 } catch (Throwable ex) { 788 throw uncaughtException(ex); 789 } 790 assert(mh.type() == type); 791 return mh; 792 } 793 794 795 static 796 MethodHandle profile(MethodHandle target) { 797 if (DONT_INLINE_THRESHOLD >= 0) { 798 return makeBlockInliningWrapper(target); 799 } else { 800 return target; 801 } 802 } 803 804 /** 805 * Block inlining during JIT-compilation of a target method handle if it hasn't been invoked enough times. 806 * Corresponding LambdaForm has @DontInline when compiled into bytecode. 807 */ 808 static 809 MethodHandle makeBlockInliningWrapper(MethodHandle target) { 810 LambdaForm lform; 811 if (DONT_INLINE_THRESHOLD > 0) { 812 lform = Makers.PRODUCE_BLOCK_INLINING_FORM.apply(target); 813 } else { 814 lform = Makers.PRODUCE_REINVOKER_FORM.apply(target); 815 } 816 return new CountingWrapper(target, lform, 817 Makers.PRODUCE_BLOCK_INLINING_FORM, Makers.PRODUCE_REINVOKER_FORM, 818 DONT_INLINE_THRESHOLD); 819 } 820 821 private final static class Makers { 822 /** Constructs reinvoker lambda form which block inlining during JIT-compilation for a particular method handle */ 823 static final Function<MethodHandle, LambdaForm> PRODUCE_BLOCK_INLINING_FORM = new Function<MethodHandle, LambdaForm>() { 824 @Override 825 public LambdaForm apply(MethodHandle target) { 826 return DelegatingMethodHandle.makeReinvokerForm(target, 827 MethodTypeForm.LF_DELEGATE_BLOCK_INLINING, CountingWrapper.class, false, 828 DelegatingMethodHandle.NF_getTarget, CountingWrapper.NF_maybeStopCounting); 829 } 830 }; 831 832 /** Constructs simple reinvoker lambda form for a particular method handle */ 833 static final Function<MethodHandle, LambdaForm> PRODUCE_REINVOKER_FORM = new Function<MethodHandle, LambdaForm>() { 834 @Override 835 public LambdaForm apply(MethodHandle target) { 836 return DelegatingMethodHandle.makeReinvokerForm(target, 837 MethodTypeForm.LF_DELEGATE, DelegatingMethodHandle.class, DelegatingMethodHandle.NF_getTarget); 838 } 839 }; 840 841 /** Maker of type-polymorphic varargs */ 842 static final ClassValue<MethodHandle[]> TYPED_COLLECTORS = new ClassValue<MethodHandle[]>() { 843 @Override 844 protected MethodHandle[] computeValue(Class<?> type) { 845 return new MethodHandle[MAX_JVM_ARITY + 1]; 846 } 847 }; 848 } 849 850 /** 851 * Counting method handle. It has 2 states: counting and non-counting. 852 * It is in counting state for the first n invocations and then transitions to non-counting state. 853 * Behavior in counting and non-counting states is determined by lambda forms produced by 854 * countingFormProducer & nonCountingFormProducer respectively. 855 */ 856 static class CountingWrapper extends DelegatingMethodHandle { 857 private final MethodHandle target; 858 private int count; 859 private Function<MethodHandle, LambdaForm> countingFormProducer; 860 private Function<MethodHandle, LambdaForm> nonCountingFormProducer; 861 private volatile boolean isCounting; 862 863 private CountingWrapper(MethodHandle target, LambdaForm lform, 864 Function<MethodHandle, LambdaForm> countingFromProducer, 865 Function<MethodHandle, LambdaForm> nonCountingFormProducer, 866 int count) { 867 super(target.type(), lform); 868 this.target = target; 869 this.count = count; 870 this.countingFormProducer = countingFromProducer; 871 this.nonCountingFormProducer = nonCountingFormProducer; 872 this.isCounting = (count > 0); 873 } 874 875 @Hidden 876 @Override 877 protected MethodHandle getTarget() { 878 return target; 879 } 880 881 @Override 882 public MethodHandle asTypeUncached(MethodType newType) { 883 MethodHandle newTarget = target.asType(newType); 884 MethodHandle wrapper; 885 if (isCounting) { 886 LambdaForm lform; 887 lform = countingFormProducer.apply(newTarget); 888 wrapper = new CountingWrapper(newTarget, lform, countingFormProducer, nonCountingFormProducer, DONT_INLINE_THRESHOLD); 889 } else { 890 wrapper = newTarget; // no need for a counting wrapper anymore 891 } 892 return (asTypeCache = wrapper); 893 } 894 895 // Customize target if counting happens for too long. 896 private int invocations = CUSTOMIZE_THRESHOLD; 897 private void maybeCustomizeTarget() { 898 int c = invocations; 899 if (c >= 0) { 900 if (c == 1) { 901 target.customize(); 902 } 903 invocations = c - 1; 904 } 905 } 906 907 boolean countDown() { 908 int c = count; 909 maybeCustomizeTarget(); 910 if (c <= 1) { 911 // Try to limit number of updates. MethodHandle.updateForm() doesn't guarantee LF update visibility. 912 if (isCounting) { 913 isCounting = false; 914 return true; 915 } else { 916 return false; 917 } 918 } else { 919 count = c - 1; 920 return false; 921 } 922 } 923 924 @Hidden 925 static void maybeStopCounting(Object o1) { 926 CountingWrapper wrapper = (CountingWrapper) o1; 927 if (wrapper.countDown()) { 928 // Reached invocation threshold. Replace counting behavior with a non-counting one. 929 LambdaForm lform = wrapper.nonCountingFormProducer.apply(wrapper.target); 930 lform.compileToBytecode(); // speed up warmup by avoiding LF interpretation again after transition 931 wrapper.updateForm(lform); 932 } 933 } 934 935 static final NamedFunction NF_maybeStopCounting; 936 static { 937 Class<?> THIS_CLASS = CountingWrapper.class; 938 try { 939 NF_maybeStopCounting = new NamedFunction(THIS_CLASS.getDeclaredMethod("maybeStopCounting", Object.class)); 940 } catch (ReflectiveOperationException ex) { 941 throw newInternalError(ex); 942 } 943 } 944 } 945 946 static 947 LambdaForm makeGuardWithTestForm(MethodType basicType) { 948 LambdaForm lform = basicType.form().cachedLambdaForm(MethodTypeForm.LF_GWT); 949 if (lform != null) return lform; 950 final int THIS_MH = 0; // the BMH_LLL 951 final int ARG_BASE = 1; // start of incoming arguments 952 final int ARG_LIMIT = ARG_BASE + basicType.parameterCount(); 953 int nameCursor = ARG_LIMIT; 954 final int GET_TEST = nameCursor++; 955 final int GET_TARGET = nameCursor++; 956 final int GET_FALLBACK = nameCursor++; 957 final int GET_COUNTERS = PROFILE_GWT ? nameCursor++ : -1; 958 final int CALL_TEST = nameCursor++; 959 final int PROFILE = (GET_COUNTERS != -1) ? nameCursor++ : -1; 960 final int TEST = nameCursor-1; // previous statement: either PROFILE or CALL_TEST 961 final int SELECT_ALT = nameCursor++; 962 final int CALL_TARGET = nameCursor++; 963 assert(CALL_TARGET == SELECT_ALT+1); // must be true to trigger IBG.emitSelectAlternative 964 965 MethodType lambdaType = basicType.invokerType(); 966 Name[] names = arguments(nameCursor - ARG_LIMIT, lambdaType); 967 968 BoundMethodHandle.SpeciesData data = 969 (GET_COUNTERS != -1) ? BoundMethodHandle.speciesData_LLLL() 970 : BoundMethodHandle.speciesData_LLL(); 971 names[THIS_MH] = names[THIS_MH].withConstraint(data); 972 names[GET_TEST] = new Name(data.getterFunction(0), names[THIS_MH]); 973 names[GET_TARGET] = new Name(data.getterFunction(1), names[THIS_MH]); 974 names[GET_FALLBACK] = new Name(data.getterFunction(2), names[THIS_MH]); 975 if (GET_COUNTERS != -1) { 976 names[GET_COUNTERS] = new Name(data.getterFunction(3), names[THIS_MH]); 977 } 978 Object[] invokeArgs = Arrays.copyOfRange(names, 0, ARG_LIMIT, Object[].class); 979 980 // call test 981 MethodType testType = basicType.changeReturnType(boolean.class).basicType(); 982 invokeArgs[0] = names[GET_TEST]; 983 names[CALL_TEST] = new Name(testType, invokeArgs); 984 985 // profile branch 986 if (PROFILE != -1) { 987 names[PROFILE] = new Name(getFunction(NF_profileBoolean), names[CALL_TEST], names[GET_COUNTERS]); 988 } 989 // call selectAlternative 990 names[SELECT_ALT] = new Name(new NamedFunction(getConstantHandle(MH_selectAlternative), Intrinsic.SELECT_ALTERNATIVE), names[TEST], names[GET_TARGET], names[GET_FALLBACK]); 991 992 // call target or fallback 993 invokeArgs[0] = names[SELECT_ALT]; 994 names[CALL_TARGET] = new Name(basicType, invokeArgs); 995 996 lform = new LambdaForm(lambdaType.parameterCount(), names, /*forceInline=*/true, Kind.GUARD); 997 998 return basicType.form().setCachedLambdaForm(MethodTypeForm.LF_GWT, lform); 999 } 1000 1001 /** 1002 * The LambdaForm shape for catchException combinator is the following: 1003 * <blockquote><pre>{@code 1004 * guardWithCatch=Lambda(a0:L,a1:L,a2:L)=>{ 1005 * t3:L=BoundMethodHandle$Species_LLLLL.argL0(a0:L); 1006 * t4:L=BoundMethodHandle$Species_LLLLL.argL1(a0:L); 1007 * t5:L=BoundMethodHandle$Species_LLLLL.argL2(a0:L); 1008 * t6:L=BoundMethodHandle$Species_LLLLL.argL3(a0:L); 1009 * t7:L=BoundMethodHandle$Species_LLLLL.argL4(a0:L); 1010 * t8:L=MethodHandle.invokeBasic(t6:L,a1:L,a2:L); 1011 * t9:L=MethodHandleImpl.guardWithCatch(t3:L,t4:L,t5:L,t8:L); 1012 * t10:I=MethodHandle.invokeBasic(t7:L,t9:L);t10:I} 1013 * }</pre></blockquote> 1014 * 1015 * argL0 and argL2 are target and catcher method handles. argL1 is exception class. 1016 * argL3 and argL4 are auxiliary method handles: argL3 boxes arguments and wraps them into Object[] 1017 * (ValueConversions.array()) and argL4 unboxes result if necessary (ValueConversions.unbox()). 1018 * 1019 * Having t8 and t10 passed outside and not hardcoded into a lambda form allows to share lambda forms 1020 * among catchException combinators with the same basic type. 1021 */ 1022 private static LambdaForm makeGuardWithCatchForm(MethodType basicType) { 1023 MethodType lambdaType = basicType.invokerType(); 1024 1025 LambdaForm lform = basicType.form().cachedLambdaForm(MethodTypeForm.LF_GWC); 1026 if (lform != null) { 1027 return lform; 1028 } 1029 final int THIS_MH = 0; // the BMH_LLLLL 1030 final int ARG_BASE = 1; // start of incoming arguments 1031 final int ARG_LIMIT = ARG_BASE + basicType.parameterCount(); 1032 1033 int nameCursor = ARG_LIMIT; 1034 final int GET_TARGET = nameCursor++; 1035 final int GET_CLASS = nameCursor++; 1036 final int GET_CATCHER = nameCursor++; 1037 final int GET_COLLECT_ARGS = nameCursor++; 1038 final int GET_UNBOX_RESULT = nameCursor++; 1039 final int BOXED_ARGS = nameCursor++; 1040 final int TRY_CATCH = nameCursor++; 1041 final int UNBOX_RESULT = nameCursor++; 1042 1043 Name[] names = arguments(nameCursor - ARG_LIMIT, lambdaType); 1044 1045 BoundMethodHandle.SpeciesData data = BoundMethodHandle.speciesData_LLLLL(); 1046 names[THIS_MH] = names[THIS_MH].withConstraint(data); 1047 names[GET_TARGET] = new Name(data.getterFunction(0), names[THIS_MH]); 1048 names[GET_CLASS] = new Name(data.getterFunction(1), names[THIS_MH]); 1049 names[GET_CATCHER] = new Name(data.getterFunction(2), names[THIS_MH]); 1050 names[GET_COLLECT_ARGS] = new Name(data.getterFunction(3), names[THIS_MH]); 1051 names[GET_UNBOX_RESULT] = new Name(data.getterFunction(4), names[THIS_MH]); 1052 1053 // FIXME: rework argument boxing/result unboxing logic for LF interpretation 1054 1055 // t_{i}:L=MethodHandle.invokeBasic(collectArgs:L,a1:L,...); 1056 MethodType collectArgsType = basicType.changeReturnType(Object.class); 1057 MethodHandle invokeBasic = MethodHandles.basicInvoker(collectArgsType); 1058 Object[] args = new Object[invokeBasic.type().parameterCount()]; 1059 args[0] = names[GET_COLLECT_ARGS]; 1060 System.arraycopy(names, ARG_BASE, args, 1, ARG_LIMIT-ARG_BASE); 1061 names[BOXED_ARGS] = new Name(new NamedFunction(invokeBasic, Intrinsic.GUARD_WITH_CATCH), args); 1062 1063 // t_{i+1}:L=MethodHandleImpl.guardWithCatch(target:L,exType:L,catcher:L,t_{i}:L); 1064 Object[] gwcArgs = new Object[] {names[GET_TARGET], names[GET_CLASS], names[GET_CATCHER], names[BOXED_ARGS]}; 1065 names[TRY_CATCH] = new Name(getFunction(NF_guardWithCatch), gwcArgs); 1066 1067 // t_{i+2}:I=MethodHandle.invokeBasic(unbox:L,t_{i+1}:L); 1068 MethodHandle invokeBasicUnbox = MethodHandles.basicInvoker(MethodType.methodType(basicType.rtype(), Object.class)); 1069 Object[] unboxArgs = new Object[] {names[GET_UNBOX_RESULT], names[TRY_CATCH]}; 1070 names[UNBOX_RESULT] = new Name(invokeBasicUnbox, unboxArgs); 1071 1072 lform = new LambdaForm(lambdaType.parameterCount(), names, Kind.GUARD_WITH_CATCH); 1073 1074 return basicType.form().setCachedLambdaForm(MethodTypeForm.LF_GWC, lform); 1075 } 1076 1077 static 1078 MethodHandle makeGuardWithCatch(MethodHandle target, 1079 Class<? extends Throwable> exType, 1080 MethodHandle catcher) { 1081 MethodType type = target.type(); 1082 LambdaForm form = makeGuardWithCatchForm(type.basicType()); 1083 1084 // Prepare auxiliary method handles used during LambdaForm interpretation. 1085 // Box arguments and wrap them into Object[]: ValueConversions.array(). 1086 MethodType varargsType = type.changeReturnType(Object[].class); 1087 MethodHandle collectArgs = varargsArray(type.parameterCount()).asType(varargsType); 1088 MethodHandle unboxResult = unboxResultHandle(type.returnType()); 1089 1090 BoundMethodHandle.SpeciesData data = BoundMethodHandle.speciesData_LLLLL(); 1091 BoundMethodHandle mh; 1092 try { 1093 mh = (BoundMethodHandle) data.constructor().invokeBasic(type, form, (Object) target, (Object) exType, 1094 (Object) catcher, (Object) collectArgs, (Object) unboxResult); 1095 } catch (Throwable ex) { 1096 throw uncaughtException(ex); 1097 } 1098 assert(mh.type() == type); 1099 return mh; 1100 } 1101 1102 /** 1103 * Intrinsified during LambdaForm compilation 1104 * (see {@link InvokerBytecodeGenerator#emitGuardWithCatch emitGuardWithCatch}). 1105 */ 1106 @LambdaForm.Hidden 1107 static Object guardWithCatch(MethodHandle target, Class<? extends Throwable> exType, MethodHandle catcher, 1108 Object... av) throws Throwable { 1109 // Use asFixedArity() to avoid unnecessary boxing of last argument for VarargsCollector case. 1110 try { 1111 return target.asFixedArity().invokeWithArguments(av); 1112 } catch (Throwable t) { 1113 if (!exType.isInstance(t)) throw t; 1114 return catcher.asFixedArity().invokeWithArguments(prepend(av, t)); 1115 } 1116 } 1117 1118 /** Prepend elements to an array. */ 1119 @LambdaForm.Hidden 1120 private static Object[] prepend(Object[] array, Object... elems) { 1121 int nArray = array.length; 1122 int nElems = elems.length; 1123 Object[] newArray = new Object[nArray + nElems]; 1124 System.arraycopy(elems, 0, newArray, 0, nElems); 1125 System.arraycopy(array, 0, newArray, nElems, nArray); 1126 return newArray; 1127 } 1128 1129 static 1130 MethodHandle throwException(MethodType type) { 1131 assert(Throwable.class.isAssignableFrom(type.parameterType(0))); 1132 int arity = type.parameterCount(); 1133 if (arity > 1) { 1134 MethodHandle mh = throwException(type.dropParameterTypes(1, arity)); 1135 mh = MethodHandles.dropArguments(mh, 1, Arrays.copyOfRange(type.parameterArray(), 1, arity)); 1136 return mh; 1137 } 1138 return makePairwiseConvert(getFunction(NF_throwException).resolvedHandle(), type, false, true); 1139 } 1140 1141 static <T extends Throwable> Empty throwException(T t) throws T { throw t; } 1142 1143 static MethodHandle[] FAKE_METHOD_HANDLE_INVOKE = new MethodHandle[2]; 1144 static MethodHandle fakeMethodHandleInvoke(MemberName method) { 1145 int idx; 1146 assert(method.isMethodHandleInvoke()); 1147 switch (method.getName()) { 1148 case "invoke": idx = 0; break; 1149 case "invokeExact": idx = 1; break; 1150 default: throw new InternalError(method.getName()); 1151 } 1152 MethodHandle mh = FAKE_METHOD_HANDLE_INVOKE[idx]; 1153 if (mh != null) return mh; 1154 MethodType type = MethodType.methodType(Object.class, UnsupportedOperationException.class, 1155 MethodHandle.class, Object[].class); 1156 mh = throwException(type); 1157 mh = mh.bindTo(new UnsupportedOperationException("cannot reflectively invoke MethodHandle")); 1158 if (!method.getInvocationType().equals(mh.type())) 1159 throw new InternalError(method.toString()); 1160 mh = mh.withInternalMemberName(method, false); 1161 mh = mh.withVarargs(true); 1162 assert(method.isVarargs()); 1163 FAKE_METHOD_HANDLE_INVOKE[idx] = mh; 1164 return mh; 1165 } 1166 static MethodHandle fakeVarHandleInvoke(MemberName method) { 1167 // TODO caching, is it necessary? 1168 MethodType type = MethodType.methodType(method.getReturnType(), UnsupportedOperationException.class, 1169 VarHandle.class, Object[].class); 1170 MethodHandle mh = throwException(type); 1171 mh = mh.bindTo(new UnsupportedOperationException("cannot reflectively invoke VarHandle")); 1172 if (!method.getInvocationType().equals(mh.type())) 1173 throw new InternalError(method.toString()); 1174 mh = mh.withInternalMemberName(method, false); 1175 mh = mh.asVarargsCollector(Object[].class); 1176 assert(method.isVarargs()); 1177 return mh; 1178 } 1179 1180 /** 1181 * Create an alias for the method handle which, when called, 1182 * appears to be called from the same class loader and protection domain 1183 * as hostClass. 1184 * This is an expensive no-op unless the method which is called 1185 * is sensitive to its caller. A small number of system methods 1186 * are in this category, including Class.forName and Method.invoke. 1187 */ 1188 static 1189 MethodHandle bindCaller(MethodHandle mh, Class<?> hostClass) { 1190 return BindCaller.bindCaller(mh, hostClass); 1191 } 1192 1193 // Put the whole mess into its own nested class. 1194 // That way we can lazily load the code and set up the constants. 1195 private static class BindCaller { 1196 private static MethodType INVOKER_MT = MethodType.methodType(Object.class, MethodHandle.class, Object[].class); 1197 1198 static 1199 MethodHandle bindCaller(MethodHandle mh, Class<?> hostClass) { 1200 // Code in the boot layer should now be careful while creating method handles or 1201 // functional interface instances created from method references to @CallerSensitive methods, 1202 // it needs to be ensured the handles or interface instances are kept safe and are not passed 1203 // from the boot layer to untrusted code. 1204 if (hostClass == null 1205 || (hostClass.isArray() || 1206 hostClass.isPrimitive() || 1207 hostClass.getName().startsWith("java.lang.invoke."))) { 1208 throw new InternalError(); // does not happen, and should not anyway 1209 } 1210 // For simplicity, convert mh to a varargs-like method. 1211 MethodHandle vamh = prepareForInvoker(mh); 1212 // Cache the result of makeInjectedInvoker once per argument class. 1213 MethodHandle bccInvoker = CV_makeInjectedInvoker.get(hostClass); 1214 return restoreToType(bccInvoker.bindTo(vamh), mh, hostClass); 1215 } 1216 1217 private static MethodHandle makeInjectedInvoker(Class<?> hostClass) { 1218 try { 1219 Class<?> invokerClass = UNSAFE.defineAnonymousClass(hostClass, INJECTED_INVOKER_TEMPLATE, null); 1220 assert checkInjectedInvoker(hostClass, invokerClass); 1221 return IMPL_LOOKUP.findStatic(invokerClass, "invoke_V", INVOKER_MT); 1222 } catch (ReflectiveOperationException ex) { 1223 throw uncaughtException(ex); 1224 } 1225 } 1226 1227 private static ClassValue<MethodHandle> CV_makeInjectedInvoker = new ClassValue<MethodHandle>() { 1228 @Override protected MethodHandle computeValue(Class<?> hostClass) { 1229 return makeInjectedInvoker(hostClass); 1230 } 1231 }; 1232 1233 // Adapt mh so that it can be called directly from an injected invoker: 1234 private static MethodHandle prepareForInvoker(MethodHandle mh) { 1235 mh = mh.asFixedArity(); 1236 MethodType mt = mh.type(); 1237 int arity = mt.parameterCount(); 1238 MethodHandle vamh = mh.asType(mt.generic()); 1239 vamh.internalForm().compileToBytecode(); // eliminate LFI stack frames 1240 vamh = vamh.asSpreader(Object[].class, arity); 1241 vamh.internalForm().compileToBytecode(); // eliminate LFI stack frames 1242 return vamh; 1243 } 1244 1245 // Undo the adapter effect of prepareForInvoker: 1246 private static MethodHandle restoreToType(MethodHandle vamh, 1247 MethodHandle original, 1248 Class<?> hostClass) { 1249 MethodType type = original.type(); 1250 MethodHandle mh = vamh.asCollector(Object[].class, type.parameterCount()); 1251 MemberName member = original.internalMemberName(); 1252 mh = mh.asType(type); 1253 mh = new WrappedMember(mh, type, member, original.isInvokeSpecial(), hostClass); 1254 return mh; 1255 } 1256 1257 private static boolean checkInjectedInvoker(Class<?> hostClass, Class<?> invokerClass) { 1258 assert (hostClass.getClassLoader() == invokerClass.getClassLoader()) : hostClass.getName()+" (CL)"; 1259 try { 1260 assert (hostClass.getProtectionDomain() == invokerClass.getProtectionDomain()) : hostClass.getName()+" (PD)"; 1261 } catch (SecurityException ex) { 1262 // Self-check was blocked by security manager. This is OK. 1263 } 1264 try { 1265 // Test the invoker to ensure that it really injects into the right place. 1266 MethodHandle invoker = IMPL_LOOKUP.findStatic(invokerClass, "invoke_V", INVOKER_MT); 1267 MethodHandle vamh = prepareForInvoker(MH_checkCallerClass); 1268 return (boolean)invoker.invoke(vamh, new Object[]{ invokerClass }); 1269 } catch (Throwable ex) { 1270 throw new InternalError(ex); 1271 } 1272 } 1273 1274 private static final MethodHandle MH_checkCallerClass; 1275 static { 1276 final Class<?> THIS_CLASS = BindCaller.class; 1277 assert(checkCallerClass(THIS_CLASS)); 1278 try { 1279 MH_checkCallerClass = IMPL_LOOKUP 1280 .findStatic(THIS_CLASS, "checkCallerClass", 1281 MethodType.methodType(boolean.class, Class.class)); 1282 assert((boolean) MH_checkCallerClass.invokeExact(THIS_CLASS)); 1283 } catch (Throwable ex) { 1284 throw new InternalError(ex); 1285 } 1286 } 1287 1288 @CallerSensitive 1289 @ForceInline // to ensure Reflection.getCallerClass optimization 1290 private static boolean checkCallerClass(Class<?> expected) { 1291 // This method is called via MH_checkCallerClass and so it's correct to ask for the immediate caller here. 1292 Class<?> actual = Reflection.getCallerClass(); 1293 if (actual != expected) 1294 throw new InternalError("found " + actual.getName() + ", expected " + expected.getName()); 1295 return true; 1296 } 1297 1298 private static final byte[] INJECTED_INVOKER_TEMPLATE = generateInvokerTemplate(); 1299 1300 /** Produces byte code for a class that is used as an injected invoker. */ 1301 private static byte[] generateInvokerTemplate() { 1302 ClassWriter cw = new ClassWriter(0); 1303 1304 // private static class InjectedInvoker { 1305 // @Hidden 1306 // static Object invoke_V(MethodHandle vamh, Object[] args) throws Throwable { 1307 // return vamh.invokeExact(args); 1308 // } 1309 // } 1310 cw.visit(52, ACC_PRIVATE | ACC_SUPER, "InjectedInvoker", null, "java/lang/Object", null); 1311 1312 MethodVisitor mv = cw.visitMethod(ACC_STATIC, "invoke_V", 1313 "(Ljava/lang/invoke/MethodHandle;[Ljava/lang/Object;)Ljava/lang/Object;", 1314 null, null); 1315 1316 // Suppress invoker method in stack traces. 1317 AnnotationVisitor av0 = mv.visitAnnotation("Ljava/lang/invoke/LambdaForm$Hidden;", true); 1318 av0.visitEnd(); 1319 1320 mv.visitCode(); 1321 mv.visitVarInsn(ALOAD, 0); 1322 mv.visitVarInsn(ALOAD, 1); 1323 mv.visitMethodInsn(INVOKEVIRTUAL, "java/lang/invoke/MethodHandle", "invokeExact", 1324 "([Ljava/lang/Object;)Ljava/lang/Object;", false); 1325 mv.visitInsn(ARETURN); 1326 mv.visitMaxs(2, 2); 1327 mv.visitEnd(); 1328 1329 cw.visitEnd(); 1330 return cw.toByteArray(); 1331 } 1332 } 1333 1334 /** This subclass allows a wrapped method handle to be re-associated with an arbitrary member name. */ 1335 private static final class WrappedMember extends DelegatingMethodHandle { 1336 private final MethodHandle target; 1337 private final MemberName member; 1338 private final Class<?> callerClass; 1339 private final boolean isInvokeSpecial; 1340 1341 private WrappedMember(MethodHandle target, MethodType type, 1342 MemberName member, boolean isInvokeSpecial, 1343 Class<?> callerClass) { 1344 super(type, target); 1345 this.target = target; 1346 this.member = member; 1347 this.callerClass = callerClass; 1348 this.isInvokeSpecial = isInvokeSpecial; 1349 } 1350 1351 @Override 1352 MemberName internalMemberName() { 1353 return member; 1354 } 1355 @Override 1356 Class<?> internalCallerClass() { 1357 return callerClass; 1358 } 1359 @Override 1360 boolean isInvokeSpecial() { 1361 return isInvokeSpecial; 1362 } 1363 @Override 1364 protected MethodHandle getTarget() { 1365 return target; 1366 } 1367 @Override 1368 public MethodHandle asTypeUncached(MethodType newType) { 1369 // This MH is an alias for target, except for the MemberName 1370 // Drop the MemberName if there is any conversion. 1371 return asTypeCache = target.asType(newType); 1372 } 1373 } 1374 1375 static MethodHandle makeWrappedMember(MethodHandle target, MemberName member, boolean isInvokeSpecial) { 1376 if (member.equals(target.internalMemberName()) && isInvokeSpecial == target.isInvokeSpecial()) 1377 return target; 1378 return new WrappedMember(target, target.type(), member, isInvokeSpecial, null); 1379 } 1380 1381 /** Intrinsic IDs */ 1382 /*non-public*/ 1383 enum Intrinsic { 1384 SELECT_ALTERNATIVE, 1385 GUARD_WITH_CATCH, 1386 TRY_FINALLY, 1387 LOOP, 1388 NEW_ARRAY, 1389 ARRAY_LOAD, 1390 ARRAY_STORE, 1391 ARRAY_LENGTH, 1392 IDENTITY, 1393 ZERO, 1394 NONE // no intrinsic associated 1395 } 1396 1397 /** Mark arbitrary method handle as intrinsic. 1398 * InvokerBytecodeGenerator uses this info to produce more efficient bytecode shape. */ 1399 static final class IntrinsicMethodHandle extends DelegatingMethodHandle { 1400 private final MethodHandle target; 1401 private final Intrinsic intrinsicName; 1402 1403 IntrinsicMethodHandle(MethodHandle target, Intrinsic intrinsicName) { 1404 super(target.type(), target); 1405 this.target = target; 1406 this.intrinsicName = intrinsicName; 1407 } 1408 1409 @Override 1410 protected MethodHandle getTarget() { 1411 return target; 1412 } 1413 1414 @Override 1415 Intrinsic intrinsicName() { 1416 return intrinsicName; 1417 } 1418 1419 @Override 1420 public MethodHandle asTypeUncached(MethodType newType) { 1421 // This MH is an alias for target, except for the intrinsic name 1422 // Drop the name if there is any conversion. 1423 return asTypeCache = target.asType(newType); 1424 } 1425 1426 @Override 1427 String internalProperties() { 1428 return super.internalProperties() + 1429 "\n& Intrinsic="+intrinsicName; 1430 } 1431 1432 @Override 1433 public MethodHandle asCollector(Class<?> arrayType, int arrayLength) { 1434 if (intrinsicName == Intrinsic.IDENTITY) { 1435 MethodType resultType = type().asCollectorType(arrayType, type().parameterCount() - 1, arrayLength); 1436 MethodHandle newArray = MethodHandleImpl.varargsArray(arrayType, arrayLength); 1437 return newArray.asType(resultType); 1438 } 1439 return super.asCollector(arrayType, arrayLength); 1440 } 1441 } 1442 1443 static MethodHandle makeIntrinsic(MethodHandle target, Intrinsic intrinsicName) { 1444 if (intrinsicName == target.intrinsicName()) 1445 return target; 1446 return new IntrinsicMethodHandle(target, intrinsicName); 1447 } 1448 1449 static MethodHandle makeIntrinsic(MethodType type, LambdaForm form, Intrinsic intrinsicName) { 1450 return new IntrinsicMethodHandle(SimpleMethodHandle.make(type, form), intrinsicName); 1451 } 1452 1453 /// Collection of multiple arguments. 1454 1455 private static MethodHandle findCollector(String name, int nargs, Class<?> rtype, Class<?>... ptypes) { 1456 MethodType type = MethodType.genericMethodType(nargs) 1457 .changeReturnType(rtype) 1458 .insertParameterTypes(0, ptypes); 1459 try { 1460 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, name, type); 1461 } catch (ReflectiveOperationException ex) { 1462 return null; 1463 } 1464 } 1465 1466 private static final Object[] NO_ARGS_ARRAY = {}; 1467 private static Object[] makeArray(Object... args) { return args; } 1468 private static Object[] array() { return NO_ARGS_ARRAY; } 1469 private static Object[] array(Object a0) 1470 { return makeArray(a0); } 1471 private static Object[] array(Object a0, Object a1) 1472 { return makeArray(a0, a1); } 1473 private static Object[] array(Object a0, Object a1, Object a2) 1474 { return makeArray(a0, a1, a2); } 1475 private static Object[] array(Object a0, Object a1, Object a2, Object a3) 1476 { return makeArray(a0, a1, a2, a3); } 1477 private static Object[] array(Object a0, Object a1, Object a2, Object a3, 1478 Object a4) 1479 { return makeArray(a0, a1, a2, a3, a4); } 1480 private static Object[] array(Object a0, Object a1, Object a2, Object a3, 1481 Object a4, Object a5) 1482 { return makeArray(a0, a1, a2, a3, a4, a5); } 1483 private static Object[] array(Object a0, Object a1, Object a2, Object a3, 1484 Object a4, Object a5, Object a6) 1485 { return makeArray(a0, a1, a2, a3, a4, a5, a6); } 1486 private static Object[] array(Object a0, Object a1, Object a2, Object a3, 1487 Object a4, Object a5, Object a6, Object a7) 1488 { return makeArray(a0, a1, a2, a3, a4, a5, a6, a7); } 1489 private static Object[] array(Object a0, Object a1, Object a2, Object a3, 1490 Object a4, Object a5, Object a6, Object a7, 1491 Object a8) 1492 { return makeArray(a0, a1, a2, a3, a4, a5, a6, a7, a8); } 1493 private static Object[] array(Object a0, Object a1, Object a2, Object a3, 1494 Object a4, Object a5, Object a6, Object a7, 1495 Object a8, Object a9) 1496 { return makeArray(a0, a1, a2, a3, a4, a5, a6, a7, a8, a9); } 1497 1498 private static final int ARRAYS_COUNT = 11; 1499 private static final @Stable MethodHandle[] ARRAYS = new MethodHandle[MAX_ARITY + 1]; 1500 1501 // filling versions of the above: 1502 // using Integer len instead of int len and no varargs to avoid bootstrapping problems 1503 private static Object[] fillNewArray(Integer len, Object[] /*not ...*/ args) { 1504 Object[] a = new Object[len]; 1505 fillWithArguments(a, 0, args); 1506 return a; 1507 } 1508 private static Object[] fillNewTypedArray(Object[] example, Integer len, Object[] /*not ...*/ args) { 1509 Object[] a = Arrays.copyOf(example, len); 1510 assert(a.getClass() != Object[].class); 1511 fillWithArguments(a, 0, args); 1512 return a; 1513 } 1514 private static void fillWithArguments(Object[] a, int pos, Object... args) { 1515 System.arraycopy(args, 0, a, pos, args.length); 1516 } 1517 // using Integer pos instead of int pos to avoid bootstrapping problems 1518 private static Object[] fillArray(Integer pos, Object[] a, Object a0) 1519 { fillWithArguments(a, pos, a0); return a; } 1520 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1) 1521 { fillWithArguments(a, pos, a0, a1); return a; } 1522 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2) 1523 { fillWithArguments(a, pos, a0, a1, a2); return a; } 1524 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2, Object a3) 1525 { fillWithArguments(a, pos, a0, a1, a2, a3); return a; } 1526 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2, Object a3, 1527 Object a4) 1528 { fillWithArguments(a, pos, a0, a1, a2, a3, a4); return a; } 1529 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2, Object a3, 1530 Object a4, Object a5) 1531 { fillWithArguments(a, pos, a0, a1, a2, a3, a4, a5); return a; } 1532 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2, Object a3, 1533 Object a4, Object a5, Object a6) 1534 { fillWithArguments(a, pos, a0, a1, a2, a3, a4, a5, a6); return a; } 1535 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2, Object a3, 1536 Object a4, Object a5, Object a6, Object a7) 1537 { fillWithArguments(a, pos, a0, a1, a2, a3, a4, a5, a6, a7); return a; } 1538 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2, Object a3, 1539 Object a4, Object a5, Object a6, Object a7, 1540 Object a8) 1541 { fillWithArguments(a, pos, a0, a1, a2, a3, a4, a5, a6, a7, a8); return a; } 1542 private static Object[] fillArray(Integer pos, Object[] a, Object a0, Object a1, Object a2, Object a3, 1543 Object a4, Object a5, Object a6, Object a7, 1544 Object a8, Object a9) 1545 { fillWithArguments(a, pos, a0, a1, a2, a3, a4, a5, a6, a7, a8, a9); return a; } 1546 1547 private static final int FILL_ARRAYS_COUNT = 11; // current number of fillArray methods 1548 private static final @Stable MethodHandle[] FILL_ARRAYS = new MethodHandle[FILL_ARRAYS_COUNT]; 1549 1550 private static MethodHandle getFillArray(int count) { 1551 assert (count > 0 && count < FILL_ARRAYS_COUNT); 1552 MethodHandle mh = FILL_ARRAYS[count]; 1553 if (mh != null) { 1554 return mh; 1555 } 1556 mh = findCollector("fillArray", count, Object[].class, Integer.class, Object[].class); 1557 FILL_ARRAYS[count] = mh; 1558 return mh; 1559 } 1560 1561 private static Object copyAsPrimitiveArray(Wrapper w, Object... boxes) { 1562 Object a = w.makeArray(boxes.length); 1563 w.copyArrayUnboxing(boxes, 0, a, 0, boxes.length); 1564 return a; 1565 } 1566 1567 /** Return a method handle that takes the indicated number of Object 1568 * arguments and returns an Object array of them, as if for varargs. 1569 */ 1570 static MethodHandle varargsArray(int nargs) { 1571 MethodHandle mh = ARRAYS[nargs]; 1572 if (mh != null) { 1573 return mh; 1574 } 1575 if (nargs < ARRAYS_COUNT) { 1576 mh = findCollector("array", nargs, Object[].class); 1577 } else { 1578 mh = buildVarargsArray(getConstantHandle(MH_fillNewArray), 1579 getConstantHandle(MH_arrayIdentity), nargs); 1580 } 1581 assert(assertCorrectArity(mh, nargs)); 1582 mh = makeIntrinsic(mh, Intrinsic.NEW_ARRAY); 1583 return ARRAYS[nargs] = mh; 1584 } 1585 1586 private static boolean assertCorrectArity(MethodHandle mh, int arity) { 1587 assert(mh.type().parameterCount() == arity) : "arity != "+arity+": "+mh; 1588 return true; 1589 } 1590 1591 // Array identity function (used as getConstantHandle(MH_arrayIdentity)). 1592 static <T> T[] identity(T[] x) { 1593 return x; 1594 } 1595 1596 private static MethodHandle buildVarargsArray(MethodHandle newArray, MethodHandle finisher, int nargs) { 1597 // Build up the result mh as a sequence of fills like this: 1598 // finisher(fill(fill(newArrayWA(23,x1..x10),10,x11..x20),20,x21..x23)) 1599 // The various fill(_,10*I,___*[J]) are reusable. 1600 int leftLen = Math.min(nargs, LEFT_ARGS); // absorb some arguments immediately 1601 int rightLen = nargs - leftLen; 1602 MethodHandle leftCollector = newArray.bindTo(nargs); 1603 leftCollector = leftCollector.asCollector(Object[].class, leftLen); 1604 MethodHandle mh = finisher; 1605 if (rightLen > 0) { 1606 MethodHandle rightFiller = fillToRight(LEFT_ARGS + rightLen); 1607 if (mh.equals(getConstantHandle(MH_arrayIdentity))) 1608 mh = rightFiller; 1609 else 1610 mh = MethodHandles.collectArguments(mh, 0, rightFiller); 1611 } 1612 if (mh.equals(getConstantHandle(MH_arrayIdentity))) 1613 mh = leftCollector; 1614 else 1615 mh = MethodHandles.collectArguments(mh, 0, leftCollector); 1616 return mh; 1617 } 1618 1619 private static final int LEFT_ARGS = FILL_ARRAYS_COUNT - 1; 1620 private static final @Stable MethodHandle[] FILL_ARRAY_TO_RIGHT = new MethodHandle[MAX_ARITY + 1]; 1621 /** fill_array_to_right(N).invoke(a, argL..arg[N-1]) 1622 * fills a[L]..a[N-1] with corresponding arguments, 1623 * and then returns a. The value L is a global constant (LEFT_ARGS). 1624 */ 1625 private static MethodHandle fillToRight(int nargs) { 1626 MethodHandle filler = FILL_ARRAY_TO_RIGHT[nargs]; 1627 if (filler != null) return filler; 1628 filler = buildFiller(nargs); 1629 assert(assertCorrectArity(filler, nargs - LEFT_ARGS + 1)); 1630 return FILL_ARRAY_TO_RIGHT[nargs] = filler; 1631 } 1632 private static MethodHandle buildFiller(int nargs) { 1633 if (nargs <= LEFT_ARGS) 1634 return getConstantHandle(MH_arrayIdentity); // no args to fill; return the array unchanged 1635 // we need room for both mh and a in mh.invoke(a, arg*[nargs]) 1636 final int CHUNK = LEFT_ARGS; 1637 int rightLen = nargs % CHUNK; 1638 int midLen = nargs - rightLen; 1639 if (rightLen == 0) { 1640 midLen = nargs - (rightLen = CHUNK); 1641 if (FILL_ARRAY_TO_RIGHT[midLen] == null) { 1642 // build some precursors from left to right 1643 for (int j = LEFT_ARGS % CHUNK; j < midLen; j += CHUNK) 1644 if (j > LEFT_ARGS) fillToRight(j); 1645 } 1646 } 1647 if (midLen < LEFT_ARGS) rightLen = nargs - (midLen = LEFT_ARGS); 1648 assert(rightLen > 0); 1649 MethodHandle midFill = fillToRight(midLen); // recursive fill 1650 MethodHandle rightFill = getFillArray(rightLen).bindTo(midLen); // [midLen..nargs-1] 1651 assert(midFill.type().parameterCount() == 1 + midLen - LEFT_ARGS); 1652 assert(rightFill.type().parameterCount() == 1 + rightLen); 1653 1654 // Combine the two fills: 1655 // right(mid(a, x10..x19), x20..x23) 1656 // The final product will look like this: 1657 // right(mid(newArrayLeft(24, x0..x9), x10..x19), x20..x23) 1658 if (midLen == LEFT_ARGS) 1659 return rightFill; 1660 else 1661 return MethodHandles.collectArguments(rightFill, 0, midFill); 1662 } 1663 1664 static final int MAX_JVM_ARITY = 255; // limit imposed by the JVM 1665 1666 /** Return a method handle that takes the indicated number of 1667 * typed arguments and returns an array of them. 1668 * The type argument is the array type. 1669 */ 1670 static MethodHandle varargsArray(Class<?> arrayType, int nargs) { 1671 Class<?> elemType = arrayType.getComponentType(); 1672 if (elemType == null) throw new IllegalArgumentException("not an array: "+arrayType); 1673 // FIXME: Need more special casing and caching here. 1674 if (nargs >= MAX_JVM_ARITY/2 - 1) { 1675 int slots = nargs; 1676 final int MAX_ARRAY_SLOTS = MAX_JVM_ARITY - 1; // 1 for receiver MH 1677 if (slots <= MAX_ARRAY_SLOTS && elemType.isPrimitive()) 1678 slots *= Wrapper.forPrimitiveType(elemType).stackSlots(); 1679 if (slots > MAX_ARRAY_SLOTS) 1680 throw new IllegalArgumentException("too many arguments: "+arrayType.getSimpleName()+", length "+nargs); 1681 } 1682 if (elemType == Object.class) 1683 return varargsArray(nargs); 1684 // other cases: primitive arrays, subtypes of Object[] 1685 MethodHandle cache[] = Makers.TYPED_COLLECTORS.get(elemType); 1686 MethodHandle mh = nargs < cache.length ? cache[nargs] : null; 1687 if (mh != null) return mh; 1688 if (nargs == 0) { 1689 Object example = java.lang.reflect.Array.newInstance(arrayType.getComponentType(), 0); 1690 mh = MethodHandles.constant(arrayType, example); 1691 } else if (elemType.isPrimitive()) { 1692 MethodHandle builder = getConstantHandle(MH_fillNewArray); 1693 MethodHandle producer = buildArrayProducer(arrayType); 1694 mh = buildVarargsArray(builder, producer, nargs); 1695 } else { 1696 Class<? extends Object[]> objArrayType = arrayType.asSubclass(Object[].class); 1697 Object[] example = Arrays.copyOf(NO_ARGS_ARRAY, 0, objArrayType); 1698 MethodHandle builder = getConstantHandle(MH_fillNewTypedArray).bindTo(example); 1699 MethodHandle producer = getConstantHandle(MH_arrayIdentity); // must be weakly typed 1700 mh = buildVarargsArray(builder, producer, nargs); 1701 } 1702 mh = mh.asType(MethodType.methodType(arrayType, Collections.<Class<?>>nCopies(nargs, elemType))); 1703 mh = makeIntrinsic(mh, Intrinsic.NEW_ARRAY); 1704 assert(assertCorrectArity(mh, nargs)); 1705 if (nargs < cache.length) 1706 cache[nargs] = mh; 1707 return mh; 1708 } 1709 1710 private static MethodHandle buildArrayProducer(Class<?> arrayType) { 1711 Class<?> elemType = arrayType.getComponentType(); 1712 assert(elemType.isPrimitive()); 1713 return getConstantHandle(MH_copyAsPrimitiveArray).bindTo(Wrapper.forPrimitiveType(elemType)); 1714 } 1715 1716 /*non-public*/ static void assertSame(Object mh1, Object mh2) { 1717 if (mh1 != mh2) { 1718 String msg = String.format("mh1 != mh2: mh1 = %s (form: %s); mh2 = %s (form: %s)", 1719 mh1, ((MethodHandle)mh1).form, 1720 mh2, ((MethodHandle)mh2).form); 1721 throw newInternalError(msg); 1722 } 1723 } 1724 1725 // Local constant functions: 1726 1727 /* non-public */ 1728 static final byte NF_checkSpreadArgument = 0, 1729 NF_guardWithCatch = 1, 1730 NF_throwException = 2, 1731 NF_tryFinally = 3, 1732 NF_loop = 4, 1733 NF_profileBoolean = 5, 1734 NF_LIMIT = 6; 1735 1736 private static final @Stable NamedFunction[] NFS = new NamedFunction[NF_LIMIT]; 1737 1738 static NamedFunction getFunction(byte func) { 1739 NamedFunction nf = NFS[func]; 1740 if (nf != null) { 1741 return nf; 1742 } 1743 return NFS[func] = createFunction(func); 1744 } 1745 1746 private static NamedFunction createFunction(byte func) { 1747 try { 1748 switch (func) { 1749 case NF_checkSpreadArgument: 1750 return new NamedFunction(MethodHandleImpl.class 1751 .getDeclaredMethod("checkSpreadArgument", Object.class, int.class)); 1752 case NF_guardWithCatch: 1753 return new NamedFunction(MethodHandleImpl.class 1754 .getDeclaredMethod("guardWithCatch", MethodHandle.class, Class.class, 1755 MethodHandle.class, Object[].class)); 1756 case NF_tryFinally: 1757 return new NamedFunction(MethodHandleImpl.class 1758 .getDeclaredMethod("tryFinally", MethodHandle.class, MethodHandle.class, Object[].class)); 1759 case NF_loop: 1760 return new NamedFunction(MethodHandleImpl.class 1761 .getDeclaredMethod("loop", BasicType[].class, LoopClauses.class, Object[].class)); 1762 case NF_throwException: 1763 return new NamedFunction(MethodHandleImpl.class 1764 .getDeclaredMethod("throwException", Throwable.class)); 1765 case NF_profileBoolean: 1766 return new NamedFunction(MethodHandleImpl.class 1767 .getDeclaredMethod("profileBoolean", boolean.class, int[].class)); 1768 default: 1769 throw new InternalError("Undefined function: " + func); 1770 } 1771 } catch (ReflectiveOperationException ex) { 1772 throw newInternalError(ex); 1773 } 1774 } 1775 1776 static { 1777 SharedSecrets.setJavaLangInvokeAccess(new JavaLangInvokeAccess() { 1778 @Override 1779 public Object newMemberName() { 1780 return new MemberName(); 1781 } 1782 1783 @Override 1784 public String getName(Object mname) { 1785 MemberName memberName = (MemberName)mname; 1786 return memberName.getName(); 1787 } 1788 1789 @Override 1790 public MethodType getMethodType(Object mname) { 1791 MemberName memberName = (MemberName)mname; 1792 return memberName.getMethodType(); 1793 } 1794 1795 @Override 1796 public String getMethodDescriptor(Object mname) { 1797 MemberName memberName = (MemberName)mname; 1798 return memberName.getMethodDescriptor(); 1799 } 1800 1801 @Override 1802 public boolean isNative(Object mname) { 1803 MemberName memberName = (MemberName)mname; 1804 return memberName.isNative(); 1805 } 1806 1807 @Override 1808 public byte[] generateDirectMethodHandleHolderClassBytes( 1809 String className, MethodType[] methodTypes, int[] types) { 1810 return GenerateJLIClassesHelper 1811 .generateDirectMethodHandleHolderClassBytes( 1812 className, methodTypes, types); 1813 } 1814 1815 @Override 1816 public byte[] generateDelegatingMethodHandleHolderClassBytes( 1817 String className, MethodType[] methodTypes) { 1818 return GenerateJLIClassesHelper 1819 .generateDelegatingMethodHandleHolderClassBytes( 1820 className, methodTypes); 1821 } 1822 1823 @Override 1824 public Map.Entry<String, byte[]> generateConcreteBMHClassBytes( 1825 final String types) { 1826 return GenerateJLIClassesHelper 1827 .generateConcreteBMHClassBytes(types); 1828 } 1829 1830 @Override 1831 public byte[] generateBasicFormsClassBytes(final String className) { 1832 return GenerateJLIClassesHelper 1833 .generateBasicFormsClassBytes(className); 1834 } 1835 1836 @Override 1837 public byte[] generateInvokersHolderClassBytes(final String className, 1838 MethodType[] methodTypes) { 1839 return GenerateJLIClassesHelper 1840 .generateInvokersHolderClassBytes(className, methodTypes); 1841 } 1842 }); 1843 } 1844 1845 /** Result unboxing: ValueConversions.unbox() OR ValueConversions.identity() OR ValueConversions.ignore(). */ 1846 private static MethodHandle unboxResultHandle(Class<?> returnType) { 1847 if (returnType.isPrimitive()) { 1848 if (returnType == void.class) { 1849 return ValueConversions.ignore(); 1850 } else { 1851 Wrapper w = Wrapper.forPrimitiveType(returnType); 1852 return ValueConversions.unboxExact(w); 1853 } 1854 } else { 1855 return MethodHandles.identity(Object.class); 1856 } 1857 } 1858 1859 /** 1860 * Assembles a loop method handle from the given handles and type information. 1861 * 1862 * @param tloop the return type of the loop. 1863 * @param targs types of the arguments to be passed to the loop. 1864 * @param init sanitized array of initializers for loop-local variables. 1865 * @param step sanitited array of loop bodies. 1866 * @param pred sanitized array of predicates. 1867 * @param fini sanitized array of loop finalizers. 1868 * 1869 * @return a handle that, when invoked, will execute the loop. 1870 */ 1871 static MethodHandle makeLoop(Class<?> tloop, List<Class<?>> targs, List<MethodHandle> init, List<MethodHandle> step, 1872 List<MethodHandle> pred, List<MethodHandle> fini) { 1873 MethodType type = MethodType.methodType(tloop, targs); 1874 BasicType[] initClauseTypes = 1875 init.stream().map(h -> h.type().returnType()).map(BasicType::basicType).toArray(BasicType[]::new); 1876 LambdaForm form = makeLoopForm(type.basicType(), initClauseTypes); 1877 1878 // Prepare auxiliary method handles used during LambdaForm interpretation. 1879 // Box arguments and wrap them into Object[]: ValueConversions.array(). 1880 MethodType varargsType = type.changeReturnType(Object[].class); 1881 MethodHandle collectArgs = varargsArray(type.parameterCount()).asType(varargsType); 1882 MethodHandle unboxResult = unboxResultHandle(tloop); 1883 1884 LoopClauses clauseData = 1885 new LoopClauses(new MethodHandle[][]{toArray(init), toArray(step), toArray(pred), toArray(fini)}); 1886 BoundMethodHandle.SpeciesData data = BoundMethodHandle.speciesData_LLL(); 1887 BoundMethodHandle mh; 1888 try { 1889 mh = (BoundMethodHandle) data.constructor().invokeBasic(type, form, (Object) clauseData, 1890 (Object) collectArgs, (Object) unboxResult); 1891 } catch (Throwable ex) { 1892 throw uncaughtException(ex); 1893 } 1894 assert(mh.type() == type); 1895 return mh; 1896 } 1897 1898 private static MethodHandle[] toArray(List<MethodHandle> l) { 1899 return l.toArray(new MethodHandle[0]); 1900 } 1901 1902 /** 1903 * Loops introduce some complexity as they can have additional local state. Hence, LambdaForms for loops are 1904 * generated from a template. The LambdaForm template shape for the loop combinator is as follows (assuming one 1905 * reference parameter passed in {@code a1}, and a reference return type, with the return value represented by 1906 * {@code t12}): 1907 * <blockquote><pre>{@code 1908 * loop=Lambda(a0:L,a1:L)=>{ 1909 * t2:L=BoundMethodHandle$Species_L3.argL0(a0:L); // LoopClauses holding init, step, pred, fini handles 1910 * t3:L=BoundMethodHandle$Species_L3.argL1(a0:L); // helper handle to box the arguments into an Object[] 1911 * t4:L=BoundMethodHandle$Species_L3.argL2(a0:L); // helper handle to unbox the result 1912 * t5:L=MethodHandle.invokeBasic(t3:L,a1:L); // box the arguments into an Object[] 1913 * t6:L=MethodHandleImpl.loop(null,t2:L,t3:L); // call the loop executor 1914 * t7:L=MethodHandle.invokeBasic(t4:L,t6:L);t7:L} // unbox the result; return the result 1915 * }</pre></blockquote> 1916 * <p> 1917 * {@code argL0} is a LoopClauses instance holding, in a 2-dimensional array, the init, step, pred, and fini method 1918 * handles. {@code argL1} and {@code argL2} are auxiliary method handles: {@code argL1} boxes arguments and wraps 1919 * them into {@code Object[]} ({@code ValueConversions.array()}), and {@code argL2} unboxes the result if necessary 1920 * ({@code ValueConversions.unbox()}). 1921 * <p> 1922 * Having {@code t3} and {@code t4} passed in via a BMH and not hardcoded in the lambda form allows to share lambda 1923 * forms among loop combinators with the same basic type. 1924 * <p> 1925 * The above template is instantiated by using the {@link LambdaFormEditor} to replace the {@code null} argument to 1926 * the {@code loop} invocation with the {@code BasicType} array describing the loop clause types. This argument is 1927 * ignored in the loop invoker, but will be extracted and used in {@linkplain InvokerBytecodeGenerator#emitLoop(int) 1928 * bytecode generation}. 1929 */ 1930 private static LambdaForm makeLoopForm(MethodType basicType, BasicType[] localVarTypes) { 1931 MethodType lambdaType = basicType.invokerType(); 1932 1933 final int THIS_MH = 0; // the BMH_LLL 1934 final int ARG_BASE = 1; // start of incoming arguments 1935 final int ARG_LIMIT = ARG_BASE + basicType.parameterCount(); 1936 1937 int nameCursor = ARG_LIMIT; 1938 final int GET_CLAUSE_DATA = nameCursor++; 1939 final int GET_COLLECT_ARGS = nameCursor++; 1940 final int GET_UNBOX_RESULT = nameCursor++; 1941 final int BOXED_ARGS = nameCursor++; 1942 final int LOOP = nameCursor++; 1943 final int UNBOX_RESULT = nameCursor++; 1944 1945 LambdaForm lform = basicType.form().cachedLambdaForm(MethodTypeForm.LF_LOOP); 1946 if (lform == null) { 1947 Name[] names = arguments(nameCursor - ARG_LIMIT, lambdaType); 1948 1949 BoundMethodHandle.SpeciesData data = BoundMethodHandle.speciesData_LLL(); 1950 names[THIS_MH] = names[THIS_MH].withConstraint(data); 1951 names[GET_CLAUSE_DATA] = new Name(data.getterFunction(0), names[THIS_MH]); 1952 names[GET_COLLECT_ARGS] = new Name(data.getterFunction(1), names[THIS_MH]); 1953 names[GET_UNBOX_RESULT] = new Name(data.getterFunction(2), names[THIS_MH]); 1954 1955 // t_{i}:L=MethodHandle.invokeBasic(collectArgs:L,a1:L,...); 1956 MethodType collectArgsType = basicType.changeReturnType(Object.class); 1957 MethodHandle invokeBasic = MethodHandles.basicInvoker(collectArgsType); 1958 Object[] args = new Object[invokeBasic.type().parameterCount()]; 1959 args[0] = names[GET_COLLECT_ARGS]; 1960 System.arraycopy(names, ARG_BASE, args, 1, ARG_LIMIT - ARG_BASE); 1961 names[BOXED_ARGS] = new Name(new NamedFunction(invokeBasic, Intrinsic.LOOP), args); 1962 1963 // t_{i+1}:L=MethodHandleImpl.loop(localTypes:L,clauses:L,t_{i}:L); 1964 Object[] lArgs = 1965 new Object[]{null, // placeholder for BasicType[] localTypes - will be added by LambdaFormEditor 1966 names[GET_CLAUSE_DATA], names[BOXED_ARGS]}; 1967 names[LOOP] = new Name(getFunction(NF_loop), lArgs); 1968 1969 // t_{i+2}:I=MethodHandle.invokeBasic(unbox:L,t_{i+1}:L); 1970 MethodHandle invokeBasicUnbox = MethodHandles.basicInvoker(MethodType.methodType(basicType.rtype(), Object.class)); 1971 Object[] unboxArgs = new Object[]{names[GET_UNBOX_RESULT], names[LOOP]}; 1972 names[UNBOX_RESULT] = new Name(invokeBasicUnbox, unboxArgs); 1973 1974 lform = basicType.form().setCachedLambdaForm(MethodTypeForm.LF_LOOP, 1975 new LambdaForm(lambdaType.parameterCount(), names, Kind.LOOP)); 1976 } 1977 1978 // BOXED_ARGS is the index into the names array where the loop idiom starts 1979 return lform.editor().noteLoopLocalTypesForm(BOXED_ARGS, localVarTypes); 1980 } 1981 1982 static class LoopClauses { 1983 @Stable final MethodHandle[][] clauses; 1984 LoopClauses(MethodHandle[][] clauses) { 1985 assert clauses.length == 4; 1986 this.clauses = clauses; 1987 } 1988 @Override 1989 public String toString() { 1990 StringBuffer sb = new StringBuffer("LoopClauses -- "); 1991 for (int i = 0; i < 4; ++i) { 1992 if (i > 0) { 1993 sb.append(" "); 1994 } 1995 sb.append('<').append(i).append(">: "); 1996 MethodHandle[] hs = clauses[i]; 1997 for (int j = 0; j < hs.length; ++j) { 1998 if (j > 0) { 1999 sb.append(" "); 2000 } 2001 sb.append('*').append(j).append(": ").append(hs[j]).append('\n'); 2002 } 2003 } 2004 sb.append(" --\n"); 2005 return sb.toString(); 2006 } 2007 } 2008 2009 /** 2010 * Intrinsified during LambdaForm compilation 2011 * (see {@link InvokerBytecodeGenerator#emitLoop(int)}). 2012 */ 2013 @LambdaForm.Hidden 2014 static Object loop(BasicType[] localTypes, LoopClauses clauseData, Object... av) throws Throwable { 2015 final MethodHandle[] init = clauseData.clauses[0]; 2016 final MethodHandle[] step = clauseData.clauses[1]; 2017 final MethodHandle[] pred = clauseData.clauses[2]; 2018 final MethodHandle[] fini = clauseData.clauses[3]; 2019 int varSize = (int) Stream.of(init).filter(h -> h.type().returnType() != void.class).count(); 2020 int nArgs = init[0].type().parameterCount(); 2021 Object[] varsAndArgs = new Object[varSize + nArgs]; 2022 for (int i = 0, v = 0; i < init.length; ++i) { 2023 MethodHandle ih = init[i]; 2024 if (ih.type().returnType() == void.class) { 2025 ih.invokeWithArguments(av); 2026 } else { 2027 varsAndArgs[v++] = ih.invokeWithArguments(av); 2028 } 2029 } 2030 System.arraycopy(av, 0, varsAndArgs, varSize, nArgs); 2031 final int nSteps = step.length; 2032 for (; ; ) { 2033 for (int i = 0, v = 0; i < nSteps; ++i) { 2034 MethodHandle p = pred[i]; 2035 MethodHandle s = step[i]; 2036 MethodHandle f = fini[i]; 2037 if (s.type().returnType() == void.class) { 2038 s.invokeWithArguments(varsAndArgs); 2039 } else { 2040 varsAndArgs[v++] = s.invokeWithArguments(varsAndArgs); 2041 } 2042 if (!(boolean) p.invokeWithArguments(varsAndArgs)) { 2043 return f.invokeWithArguments(varsAndArgs); 2044 } 2045 } 2046 } 2047 } 2048 2049 /** 2050 * This method is bound as the predicate in {@linkplain MethodHandles#countedLoop(MethodHandle, MethodHandle, 2051 * MethodHandle) counting loops}. 2052 * 2053 * @param limit the upper bound of the parameter, statically bound at loop creation time. 2054 * @param counter the counter parameter, passed in during loop execution. 2055 * 2056 * @return whether the counter has reached the limit. 2057 */ 2058 static boolean countedLoopPredicate(int limit, int counter) { 2059 return counter < limit; 2060 } 2061 2062 /** 2063 * This method is bound as the step function in {@linkplain MethodHandles#countedLoop(MethodHandle, MethodHandle, 2064 * MethodHandle) counting loops} to increment the counter. 2065 * 2066 * @param limit the upper bound of the loop counter (ignored). 2067 * @param counter the loop counter. 2068 * 2069 * @return the loop counter incremented by 1. 2070 */ 2071 static int countedLoopStep(int limit, int counter) { 2072 return counter + 1; 2073 } 2074 2075 /** 2076 * This is bound to initialize the loop-local iterator in {@linkplain MethodHandles#iteratedLoop iterating loops}. 2077 * 2078 * @param it the {@link Iterable} over which the loop iterates. 2079 * 2080 * @return an {@link Iterator} over the argument's elements. 2081 */ 2082 static Iterator<?> initIterator(Iterable<?> it) { 2083 return it.iterator(); 2084 } 2085 2086 /** 2087 * This method is bound as the predicate in {@linkplain MethodHandles#iteratedLoop iterating loops}. 2088 * 2089 * @param it the iterator to be checked. 2090 * 2091 * @return {@code true} iff there are more elements to iterate over. 2092 */ 2093 static boolean iteratePredicate(Iterator<?> it) { 2094 return it.hasNext(); 2095 } 2096 2097 /** 2098 * This method is bound as the step for retrieving the current value from the iterator in {@linkplain 2099 * MethodHandles#iteratedLoop iterating loops}. 2100 * 2101 * @param it the iterator. 2102 * 2103 * @return the next element from the iterator. 2104 */ 2105 static Object iterateNext(Iterator<?> it) { 2106 return it.next(); 2107 } 2108 2109 /** 2110 * Makes a {@code try-finally} handle that conforms to the type constraints. 2111 * 2112 * @param target the target to execute in a {@code try-finally} block. 2113 * @param cleanup the cleanup to execute in the {@code finally} block. 2114 * @param rtype the result type of the entire construct. 2115 * @param argTypes the types of the arguments. 2116 * 2117 * @return a handle on the constructed {@code try-finally} block. 2118 */ 2119 static MethodHandle makeTryFinally(MethodHandle target, MethodHandle cleanup, Class<?> rtype, List<Class<?>> argTypes) { 2120 MethodType type = MethodType.methodType(rtype, argTypes); 2121 LambdaForm form = makeTryFinallyForm(type.basicType()); 2122 2123 // Prepare auxiliary method handles used during LambdaForm interpretation. 2124 // Box arguments and wrap them into Object[]: ValueConversions.array(). 2125 MethodType varargsType = type.changeReturnType(Object[].class); 2126 MethodHandle collectArgs = varargsArray(type.parameterCount()).asType(varargsType); 2127 MethodHandle unboxResult = unboxResultHandle(rtype); 2128 2129 BoundMethodHandle.SpeciesData data = BoundMethodHandle.speciesData_LLLL(); 2130 BoundMethodHandle mh; 2131 try { 2132 mh = (BoundMethodHandle) data.constructor().invokeBasic(type, form, (Object) target, (Object) cleanup, 2133 (Object) collectArgs, (Object) unboxResult); 2134 } catch (Throwable ex) { 2135 throw uncaughtException(ex); 2136 } 2137 assert(mh.type() == type); 2138 return mh; 2139 } 2140 2141 /** 2142 * The LambdaForm shape for the tryFinally combinator is as follows (assuming one reference parameter passed in 2143 * {@code a1}, and a reference return type, with the return value represented by {@code t8}): 2144 * <blockquote><pre>{@code 2145 * tryFinally=Lambda(a0:L,a1:L)=>{ 2146 * t2:L=BoundMethodHandle$Species_LLLL.argL0(a0:L); // target method handle 2147 * t3:L=BoundMethodHandle$Species_LLLL.argL1(a0:L); // cleanup method handle 2148 * t4:L=BoundMethodHandle$Species_LLLL.argL2(a0:L); // helper handle to box the arguments into an Object[] 2149 * t5:L=BoundMethodHandle$Species_LLLL.argL3(a0:L); // helper handle to unbox the result 2150 * t6:L=MethodHandle.invokeBasic(t4:L,a1:L); // box the arguments into an Object[] 2151 * t7:L=MethodHandleImpl.tryFinally(t2:L,t3:L,t6:L); // call the tryFinally executor 2152 * t8:L=MethodHandle.invokeBasic(t5:L,t7:L);t8:L} // unbox the result; return the result 2153 * }</pre></blockquote> 2154 * <p> 2155 * {@code argL0} and {@code argL1} are the target and cleanup method handles. 2156 * {@code argL2} and {@code argL3} are auxiliary method handles: {@code argL2} boxes arguments and wraps them into 2157 * {@code Object[]} ({@code ValueConversions.array()}), and {@code argL3} unboxes the result if necessary 2158 * ({@code ValueConversions.unbox()}). 2159 * <p> 2160 * Having {@code t4} and {@code t5} passed in via a BMH and not hardcoded in the lambda form allows to share lambda 2161 * forms among tryFinally combinators with the same basic type. 2162 */ 2163 private static LambdaForm makeTryFinallyForm(MethodType basicType) { 2164 MethodType lambdaType = basicType.invokerType(); 2165 2166 LambdaForm lform = basicType.form().cachedLambdaForm(MethodTypeForm.LF_TF); 2167 if (lform != null) { 2168 return lform; 2169 } 2170 final int THIS_MH = 0; // the BMH_LLLL 2171 final int ARG_BASE = 1; // start of incoming arguments 2172 final int ARG_LIMIT = ARG_BASE + basicType.parameterCount(); 2173 2174 int nameCursor = ARG_LIMIT; 2175 final int GET_TARGET = nameCursor++; 2176 final int GET_CLEANUP = nameCursor++; 2177 final int GET_COLLECT_ARGS = nameCursor++; 2178 final int GET_UNBOX_RESULT = nameCursor++; 2179 final int BOXED_ARGS = nameCursor++; 2180 final int TRY_FINALLY = nameCursor++; 2181 final int UNBOX_RESULT = nameCursor++; 2182 2183 Name[] names = arguments(nameCursor - ARG_LIMIT, lambdaType); 2184 2185 BoundMethodHandle.SpeciesData data = BoundMethodHandle.speciesData_LLLL(); 2186 names[THIS_MH] = names[THIS_MH].withConstraint(data); 2187 names[GET_TARGET] = new Name(data.getterFunction(0), names[THIS_MH]); 2188 names[GET_CLEANUP] = new Name(data.getterFunction(1), names[THIS_MH]); 2189 names[GET_COLLECT_ARGS] = new Name(data.getterFunction(2), names[THIS_MH]); 2190 names[GET_UNBOX_RESULT] = new Name(data.getterFunction(3), names[THIS_MH]); 2191 2192 // t_{i}:L=MethodHandle.invokeBasic(collectArgs:L,a1:L,...); 2193 MethodType collectArgsType = basicType.changeReturnType(Object.class); 2194 MethodHandle invokeBasic = MethodHandles.basicInvoker(collectArgsType); 2195 Object[] args = new Object[invokeBasic.type().parameterCount()]; 2196 args[0] = names[GET_COLLECT_ARGS]; 2197 System.arraycopy(names, ARG_BASE, args, 1, ARG_LIMIT-ARG_BASE); 2198 names[BOXED_ARGS] = new Name(new NamedFunction(invokeBasic, Intrinsic.TRY_FINALLY), args); 2199 2200 // t_{i+1}:L=MethodHandleImpl.tryFinally(target:L,exType:L,catcher:L,t_{i}:L); 2201 Object[] tfArgs = new Object[] {names[GET_TARGET], names[GET_CLEANUP], names[BOXED_ARGS]}; 2202 names[TRY_FINALLY] = new Name(getFunction(NF_tryFinally), tfArgs); 2203 2204 // t_{i+2}:I=MethodHandle.invokeBasic(unbox:L,t_{i+1}:L); 2205 MethodHandle invokeBasicUnbox = MethodHandles.basicInvoker(MethodType.methodType(basicType.rtype(), Object.class)); 2206 Object[] unboxArgs = new Object[] {names[GET_UNBOX_RESULT], names[TRY_FINALLY]}; 2207 names[UNBOX_RESULT] = new Name(invokeBasicUnbox, unboxArgs); 2208 2209 lform = new LambdaForm(lambdaType.parameterCount(), names, Kind.TRY_FINALLY); 2210 2211 return basicType.form().setCachedLambdaForm(MethodTypeForm.LF_TF, lform); 2212 } 2213 2214 /** 2215 * Intrinsified during LambdaForm compilation 2216 * (see {@link InvokerBytecodeGenerator#emitTryFinally emitTryFinally}). 2217 */ 2218 @LambdaForm.Hidden 2219 static Object tryFinally(MethodHandle target, MethodHandle cleanup, Object... av) throws Throwable { 2220 Throwable t = null; 2221 Object r = null; 2222 try { 2223 r = target.invokeWithArguments(av); 2224 } catch (Throwable thrown) { 2225 t = thrown; 2226 throw t; 2227 } finally { 2228 Object[] args = target.type().returnType() == void.class ? prepend(av, t) : prepend(av, t, r); 2229 r = cleanup.invokeWithArguments(args); 2230 } 2231 return r; 2232 } 2233 2234 // Indexes into constant method handles: 2235 static final int 2236 MH_cast = 0, 2237 MH_selectAlternative = 1, 2238 MH_copyAsPrimitiveArray = 2, 2239 MH_fillNewTypedArray = 3, 2240 MH_fillNewArray = 4, 2241 MH_arrayIdentity = 5, 2242 MH_countedLoopPred = 6, 2243 MH_countedLoopStep = 7, 2244 MH_initIterator = 8, 2245 MH_iteratePred = 9, 2246 MH_iterateNext = 10, 2247 MH_Array_newInstance = 11, 2248 MH_LIMIT = 12; 2249 2250 static MethodHandle getConstantHandle(int idx) { 2251 MethodHandle handle = HANDLES[idx]; 2252 if (handle != null) { 2253 return handle; 2254 } 2255 return setCachedHandle(idx, makeConstantHandle(idx)); 2256 } 2257 2258 private static synchronized MethodHandle setCachedHandle(int idx, final MethodHandle method) { 2259 // Simulate a CAS, to avoid racy duplication of results. 2260 MethodHandle prev = HANDLES[idx]; 2261 if (prev != null) { 2262 return prev; 2263 } 2264 HANDLES[idx] = method; 2265 return method; 2266 } 2267 2268 // Local constant method handles: 2269 private static final @Stable MethodHandle[] HANDLES = new MethodHandle[MH_LIMIT]; 2270 2271 private static MethodHandle makeConstantHandle(int idx) { 2272 try { 2273 switch (idx) { 2274 case MH_cast: 2275 return IMPL_LOOKUP.findVirtual(Class.class, "cast", 2276 MethodType.methodType(Object.class, Object.class)); 2277 case MH_copyAsPrimitiveArray: 2278 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "copyAsPrimitiveArray", 2279 MethodType.methodType(Object.class, Wrapper.class, Object[].class)); 2280 case MH_arrayIdentity: 2281 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "identity", 2282 MethodType.methodType(Object[].class, Object[].class)); 2283 case MH_fillNewArray: 2284 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "fillNewArray", 2285 MethodType.methodType(Object[].class, Integer.class, Object[].class)); 2286 case MH_fillNewTypedArray: 2287 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "fillNewTypedArray", 2288 MethodType.methodType(Object[].class, Object[].class, Integer.class, Object[].class)); 2289 case MH_selectAlternative: 2290 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "selectAlternative", 2291 MethodType.methodType(MethodHandle.class, boolean.class, MethodHandle.class, MethodHandle.class)); 2292 case MH_countedLoopPred: 2293 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "countedLoopPredicate", 2294 MethodType.methodType(boolean.class, int.class, int.class)); 2295 case MH_countedLoopStep: 2296 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "countedLoopStep", 2297 MethodType.methodType(int.class, int.class, int.class)); 2298 case MH_initIterator: 2299 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "initIterator", 2300 MethodType.methodType(Iterator.class, Iterable.class)); 2301 case MH_iteratePred: 2302 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "iteratePredicate", 2303 MethodType.methodType(boolean.class, Iterator.class)); 2304 case MH_iterateNext: 2305 return IMPL_LOOKUP.findStatic(MethodHandleImpl.class, "iterateNext", 2306 MethodType.methodType(Object.class, Iterator.class)); 2307 case MH_Array_newInstance: 2308 return IMPL_LOOKUP.findStatic(Array.class, "newInstance", 2309 MethodType.methodType(Object.class, Class.class, int.class)); 2310 } 2311 } catch (ReflectiveOperationException ex) { 2312 throw newInternalError(ex); 2313 } 2314 throw newInternalError("Unknown function index: " + idx); 2315 } 2316 }