1 /* 2 * Copyright (c) 2011, 2023, 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.perf.PerfCounter; 29 import jdk.internal.vm.annotation.DontInline; 30 import jdk.internal.vm.annotation.Hidden; 31 import jdk.internal.vm.annotation.Stable; 32 import sun.invoke.util.Wrapper; 33 34 import java.lang.annotation.ElementType; 35 import java.lang.annotation.Retention; 36 import java.lang.annotation.RetentionPolicy; 37 import java.lang.annotation.Target; 38 import java.lang.reflect.Method; 39 import java.util.Arrays; 40 import java.util.HashMap; 41 42 import static java.lang.invoke.LambdaForm.BasicType.*; 43 import static java.lang.invoke.MethodHandleNatives.Constants.*; 44 import static java.lang.invoke.MethodHandleStatics.*; 45 46 /** 47 * The symbolic, non-executable form of a method handle's invocation semantics. 48 * It consists of a series of names. 49 * The first N (N=arity) names are parameters, 50 * while any remaining names are temporary values. 51 * Each temporary specifies the application of a function to some arguments. 52 * The functions are method handles, while the arguments are mixes of 53 * constant values and local names. 54 * The result of the lambda is defined as one of the names, often the last one. 55 * <p> 56 * Here is an approximate grammar: 57 * <blockquote><pre>{@code 58 * LambdaForm = "(" ArgName* ")=>{" TempName* Result "}" 59 * ArgName = "a" N ":" T 60 * TempName = "t" N ":" T "=" Function "(" Argument* ");" 61 * Function = ConstantValue 62 * Argument = NameRef | ConstantValue 63 * Result = NameRef | "void" 64 * NameRef = "a" N | "t" N 65 * N = (any whole number) 66 * T = "L" | "I" | "J" | "F" | "D" | "V" 67 * }</pre></blockquote> 68 * Names are numbered consecutively from left to right starting at zero. 69 * (The letters are merely a taste of syntax sugar.) 70 * Thus, the first temporary (if any) is always numbered N (where N=arity). 71 * Every occurrence of a name reference in an argument list must refer to 72 * a name previously defined within the same lambda. 73 * A lambda has a void result if and only if its result index is -1. 74 * If a temporary has the type "V", it cannot be the subject of a NameRef, 75 * even though possesses a number. 76 * Note that all reference types are erased to "L", which stands for {@code Object}. 77 * All subword types (boolean, byte, short, char) are erased to "I" which is {@code int}. 78 * The other types stand for the usual primitive types. 79 * <p> 80 * Function invocation closely follows the static rules of the Java verifier. 81 * Arguments and return values must exactly match when their "Name" types are 82 * considered. 83 * Conversions are allowed only if they do not change the erased type. 84 * <ul> 85 * <li>L = Object: casts are used freely to convert into and out of reference types 86 * <li>I = int: subword types are forcibly narrowed when passed as arguments (see {@code explicitCastArguments}) 87 * <li>J = long: no implicit conversions 88 * <li>F = float: no implicit conversions 89 * <li>D = double: no implicit conversions 90 * <li>V = void: a function result may be void if and only if its Name is of type "V" 91 * </ul> 92 * Although implicit conversions are not allowed, explicit ones can easily be 93 * encoded by using temporary expressions which call type-transformed identity functions. 94 * <p> 95 * Examples: 96 * <blockquote><pre>{@code 97 * (a0:J)=>{ a0 } 98 * == identity(long) 99 * (a0:I)=>{ t1:V = System.out#println(a0); void } 100 * == System.out#println(int) 101 * (a0:L)=>{ t1:V = System.out#println(a0); a0 } 102 * == identity, with printing side-effect 103 * (a0:L, a1:L)=>{ t2:L = BoundMethodHandle#argument(a0); 104 * t3:L = BoundMethodHandle#target(a0); 105 * t4:L = MethodHandle#invoke(t3, t2, a1); t4 } 106 * == general invoker for unary insertArgument combination 107 * (a0:L, a1:L)=>{ t2:L = FilterMethodHandle#filter(a0); 108 * t3:L = MethodHandle#invoke(t2, a1); 109 * t4:L = FilterMethodHandle#target(a0); 110 * t5:L = MethodHandle#invoke(t4, t3); t5 } 111 * == general invoker for unary filterArgument combination 112 * (a0:L, a1:L)=>{ ...(same as previous example)... 113 * t5:L = MethodHandle#invoke(t4, t3, a1); t5 } 114 * == general invoker for unary/unary foldArgument combination 115 * (a0:L, a1:I)=>{ t2:I = identity(long).asType((int)->long)(a1); t2 } 116 * == invoker for identity method handle which performs i2l 117 * (a0:L, a1:L)=>{ t2:L = BoundMethodHandle#argument(a0); 118 * t3:L = Class#cast(t2,a1); t3 } 119 * == invoker for identity method handle which performs cast 120 * }</pre></blockquote> 121 * <p> 122 * @author John Rose, JSR 292 EG 123 */ 124 class LambdaForm { 125 final int arity; 126 final int result; 127 final boolean forceInline; 128 final MethodHandle customized; 129 @Stable final Name[] names; 130 final Kind kind; 131 MemberName vmentry; // low-level behavior, or null if not yet prepared 132 private boolean isCompiled; 133 134 // Either a LambdaForm cache (managed by LambdaFormEditor) or a link to uncustomized version (for customized LF) 135 volatile Object transformCache; 136 137 public static final int VOID_RESULT = -1, LAST_RESULT = -2; 138 139 enum BasicType { 140 L_TYPE('L', Object.class, Wrapper.OBJECT), // all reference types 141 I_TYPE('I', int.class, Wrapper.INT), 142 J_TYPE('J', long.class, Wrapper.LONG), 143 F_TYPE('F', float.class, Wrapper.FLOAT), 144 D_TYPE('D', double.class, Wrapper.DOUBLE), // all primitive types 145 V_TYPE('V', void.class, Wrapper.VOID); // not valid in all contexts 146 147 static final @Stable BasicType[] ALL_TYPES = BasicType.values(); 148 static final @Stable BasicType[] ARG_TYPES = Arrays.copyOf(ALL_TYPES, ALL_TYPES.length-1); 149 150 static final int ARG_TYPE_LIMIT = ARG_TYPES.length; 151 static final int TYPE_LIMIT = ALL_TYPES.length; 152 153 final char btChar; 154 final Class<?> btClass; 155 final Wrapper btWrapper; 156 157 private BasicType(char btChar, Class<?> btClass, Wrapper wrapper) { 158 this.btChar = btChar; 159 this.btClass = btClass; 160 this.btWrapper = wrapper; 161 } 162 163 char basicTypeChar() { 164 return btChar; 165 } 166 Class<?> basicTypeClass() { 167 return btClass; 168 } 169 Wrapper basicTypeWrapper() { 170 return btWrapper; 171 } 172 int basicTypeSlots() { 173 return btWrapper.stackSlots(); 174 } 175 176 static BasicType basicType(byte type) { 177 return ALL_TYPES[type]; 178 } 179 static BasicType basicType(char type) { 180 return switch (type) { 181 case 'L' -> L_TYPE; 182 case 'I' -> I_TYPE; 183 case 'J' -> J_TYPE; 184 case 'F' -> F_TYPE; 185 case 'D' -> D_TYPE; 186 case 'V' -> V_TYPE; 187 // all subword types are represented as ints 188 case 'Z', 'B', 'S', 'C' -> I_TYPE; 189 default -> throw newInternalError("Unknown type char: '" + type + "'"); 190 }; 191 } 192 static BasicType basicType(Class<?> type) { 193 return basicType(Wrapper.basicTypeChar(type)); 194 } 195 static int[] basicTypeOrds(BasicType[] types) { 196 if (types == null) { 197 return null; 198 } 199 int[] a = new int[types.length]; 200 for(int i = 0; i < types.length; ++i) { 201 a[i] = types[i].ordinal(); 202 } 203 return a; 204 } 205 206 static char basicTypeChar(Class<?> type) { 207 return basicType(type).btChar; 208 } 209 210 static int[] basicTypesOrd(Class<?>[] types) { 211 int[] ords = new int[types.length]; 212 for (int i = 0; i < ords.length; i++) { 213 ords[i] = basicType(types[i]).ordinal(); 214 } 215 return ords; 216 } 217 218 static boolean isBasicTypeChar(char c) { 219 return "LIJFDV".indexOf(c) >= 0; 220 } 221 static boolean isArgBasicTypeChar(char c) { 222 return "LIJFD".indexOf(c) >= 0; 223 } 224 225 static { assert(checkBasicType()); } 226 private static boolean checkBasicType() { 227 for (int i = 0; i < ARG_TYPE_LIMIT; i++) { 228 assert ARG_TYPES[i].ordinal() == i; 229 assert ARG_TYPES[i] == ALL_TYPES[i]; 230 } 231 for (int i = 0; i < TYPE_LIMIT; i++) { 232 assert ALL_TYPES[i].ordinal() == i; 233 } 234 assert ALL_TYPES[TYPE_LIMIT - 1] == V_TYPE; 235 assert !Arrays.asList(ARG_TYPES).contains(V_TYPE); 236 return true; 237 } 238 } 239 240 enum Kind { 241 GENERIC("invoke"), 242 ZERO("zero"), 243 IDENTITY("identity"), 244 BOUND_REINVOKER("BMH.reinvoke", "reinvoke"), 245 REINVOKER("MH.reinvoke", "reinvoke"), 246 DELEGATE("MH.delegate", "delegate"), 247 EXACT_LINKER("MH.invokeExact_MT", "invokeExact_MT"), 248 EXACT_INVOKER("MH.exactInvoker", "exactInvoker"), 249 GENERIC_LINKER("MH.invoke_MT", "invoke_MT"), 250 GENERIC_INVOKER("MH.invoker", "invoker"), 251 LINK_TO_TARGET_METHOD("linkToTargetMethod"), 252 LINK_TO_CALL_SITE("linkToCallSite"), 253 DIRECT_INVOKE_VIRTUAL("DMH.invokeVirtual", "invokeVirtual"), 254 DIRECT_INVOKE_SPECIAL("DMH.invokeSpecial", "invokeSpecial"), 255 DIRECT_INVOKE_SPECIAL_IFC("DMH.invokeSpecialIFC", "invokeSpecialIFC"), 256 DIRECT_INVOKE_STATIC("DMH.invokeStatic", "invokeStatic"), 257 DIRECT_NEW_INVOKE_SPECIAL("DMH.newInvokeSpecial", "newInvokeSpecial"), 258 DIRECT_INVOKE_INTERFACE("DMH.invokeInterface", "invokeInterface"), 259 DIRECT_INVOKE_STATIC_INIT("DMH.invokeStaticInit", "invokeStaticInit"), 260 GET_REFERENCE("getReference"), 261 PUT_REFERENCE("putReference"), 262 GET_REFERENCE_VOLATILE("getReferenceVolatile"), 263 PUT_REFERENCE_VOLATILE("putReferenceVolatile"), 264 GET_VALUE("getValue"), 265 PUT_VALUE("putValue"), 266 GET_VALUE_VOLATILE("getValueVolatile"), 267 PUT_VALUE_VOLATILE("putValueVolatile"), 268 GET_INT("getInt"), 269 PUT_INT("putInt"), 270 GET_INT_VOLATILE("getIntVolatile"), 271 PUT_INT_VOLATILE("putIntVolatile"), 272 GET_BOOLEAN("getBoolean"), 273 PUT_BOOLEAN("putBoolean"), 274 GET_BOOLEAN_VOLATILE("getBooleanVolatile"), 275 PUT_BOOLEAN_VOLATILE("putBooleanVolatile"), 276 GET_BYTE("getByte"), 277 PUT_BYTE("putByte"), 278 GET_BYTE_VOLATILE("getByteVolatile"), 279 PUT_BYTE_VOLATILE("putByteVolatile"), 280 GET_CHAR("getChar"), 281 PUT_CHAR("putChar"), 282 GET_CHAR_VOLATILE("getCharVolatile"), 283 PUT_CHAR_VOLATILE("putCharVolatile"), 284 GET_SHORT("getShort"), 285 PUT_SHORT("putShort"), 286 GET_SHORT_VOLATILE("getShortVolatile"), 287 PUT_SHORT_VOLATILE("putShortVolatile"), 288 GET_LONG("getLong"), 289 PUT_LONG("putLong"), 290 GET_LONG_VOLATILE("getLongVolatile"), 291 PUT_LONG_VOLATILE("putLongVolatile"), 292 GET_FLOAT("getFloat"), 293 PUT_FLOAT("putFloat"), 294 GET_FLOAT_VOLATILE("getFloatVolatile"), 295 PUT_FLOAT_VOLATILE("putFloatVolatile"), 296 GET_DOUBLE("getDouble"), 297 PUT_DOUBLE("putDouble"), 298 GET_DOUBLE_VOLATILE("getDoubleVolatile"), 299 PUT_DOUBLE_VOLATILE("putDoubleVolatile"), 300 TRY_FINALLY("tryFinally"), 301 TABLE_SWITCH("tableSwitch"), 302 COLLECT("collect"), 303 COLLECTOR("collector"), 304 CONVERT("convert"), 305 SPREAD("spread"), 306 LOOP("loop"), 307 FIELD("field"), 308 GUARD("guard"), 309 GUARD_WITH_CATCH("guardWithCatch"), 310 VARHANDLE_EXACT_INVOKER("VH.exactInvoker"), 311 VARHANDLE_INVOKER("VH.invoker", "invoker"), 312 VARHANDLE_LINKER("VH.invoke_MT", "invoke_MT"); 313 314 final String defaultLambdaName; 315 final String methodName; 316 317 private Kind(String defaultLambdaName) { 318 this(defaultLambdaName, defaultLambdaName); 319 } 320 321 private Kind(String defaultLambdaName, String methodName) { 322 this.defaultLambdaName = defaultLambdaName; 323 this.methodName = methodName; 324 } 325 } 326 327 // private version that doesn't do checks or defensive copies 328 private LambdaForm(int arity, int result, boolean forceInline, MethodHandle customized, Name[] names, Kind kind) { 329 this.arity = arity; 330 this.result = result; 331 this.forceInline = forceInline; 332 this.customized = customized; 333 this.names = names; 334 this.kind = kind; 335 this.vmentry = null; 336 this.isCompiled = false; 337 } 338 339 // root factory pre/post processing and calls simple constructor 340 private static LambdaForm create(int arity, Name[] names, int result, boolean forceInline, MethodHandle customized, Kind kind) { 341 names = names.clone(); 342 assert(namesOK(arity, names)); 343 result = fixResult(result, names); 344 345 boolean canInterpret = normalizeNames(arity, names); 346 LambdaForm form = new LambdaForm(arity, result, forceInline, customized, names, kind); 347 assert(form.nameRefsAreLegal()); 348 if (!canInterpret) { 349 form.compileToBytecode(); 350 } 351 return form; 352 } 353 354 // derived factories with defaults 355 private static final int DEFAULT_RESULT = LAST_RESULT; 356 private static final boolean DEFAULT_FORCE_INLINE = true; 357 private static final MethodHandle DEFAULT_CUSTOMIZED = null; 358 private static final Kind DEFAULT_KIND = Kind.GENERIC; 359 360 static LambdaForm create(int arity, Name[] names, int result) { 361 return create(arity, names, result, DEFAULT_FORCE_INLINE, DEFAULT_CUSTOMIZED, DEFAULT_KIND); 362 } 363 static LambdaForm create(int arity, Name[] names, int result, Kind kind) { 364 return create(arity, names, result, DEFAULT_FORCE_INLINE, DEFAULT_CUSTOMIZED, kind); 365 } 366 static LambdaForm create(int arity, Name[] names) { 367 return create(arity, names, DEFAULT_RESULT, DEFAULT_FORCE_INLINE, DEFAULT_CUSTOMIZED, DEFAULT_KIND); 368 } 369 static LambdaForm create(int arity, Name[] names, Kind kind) { 370 return create(arity, names, DEFAULT_RESULT, DEFAULT_FORCE_INLINE, DEFAULT_CUSTOMIZED, kind); 371 } 372 static LambdaForm create(int arity, Name[] names, boolean forceInline, Kind kind) { 373 return create(arity, names, DEFAULT_RESULT, forceInline, DEFAULT_CUSTOMIZED, kind); 374 } 375 376 private static LambdaForm createBlankForType(MethodType mt) { 377 // Make a blank lambda form, which returns a constant zero or null. 378 // It is used as a template for managing the invocation of similar forms that are non-empty. 379 // Called only from getPreparedForm. 380 int arity = mt.parameterCount(); 381 int result = (mt.returnType() == void.class || mt.returnType() == Void.class) ? VOID_RESULT : arity; 382 Name[] names = buildEmptyNames(arity, mt, result == VOID_RESULT); 383 boolean canInterpret = normalizeNames(arity, names); 384 LambdaForm form = new LambdaForm(arity, result, DEFAULT_FORCE_INLINE, DEFAULT_CUSTOMIZED, names, Kind.ZERO); 385 assert(form.nameRefsAreLegal() && form.isEmpty() && isValidSignature(form.basicTypeSignature())); 386 if (!canInterpret) { 387 form.compileToBytecode(); 388 } 389 return form; 390 } 391 392 private static Name[] buildEmptyNames(int arity, MethodType mt, boolean isVoid) { 393 Name[] names = arguments(isVoid ? 0 : 1, mt); 394 if (!isVoid) { 395 Name zero = new Name(constantZero(basicType(mt.returnType()))); 396 names[arity] = zero.newIndex(arity); 397 } 398 assert(namesOK(arity, names)); 399 return names; 400 } 401 402 private static int fixResult(int result, Name[] names) { 403 if (result == LAST_RESULT) 404 result = names.length - 1; // might still be void 405 if (result >= 0 && names[result].type == V_TYPE) 406 result = VOID_RESULT; 407 return result; 408 } 409 410 static boolean debugNames() { 411 return DEBUG_NAME_COUNTERS != null; 412 } 413 414 static void associateWithDebugName(LambdaForm form, String name) { 415 assert (debugNames()); 416 synchronized (DEBUG_NAMES) { 417 DEBUG_NAMES.put(form, name); 418 } 419 } 420 421 String lambdaName() { 422 if (DEBUG_NAMES != null) { 423 synchronized (DEBUG_NAMES) { 424 String name = DEBUG_NAMES.get(this); 425 if (name == null) { 426 name = generateDebugName(); 427 } 428 return name; 429 } 430 } 431 return kind.defaultLambdaName; 432 } 433 434 private String generateDebugName() { 435 assert (debugNames()); 436 String debugNameStem = kind.defaultLambdaName; 437 Integer ctr = DEBUG_NAME_COUNTERS.getOrDefault(debugNameStem, 0); 438 DEBUG_NAME_COUNTERS.put(debugNameStem, ctr + 1); 439 StringBuilder buf = new StringBuilder(debugNameStem); 440 int leadingZero = buf.length(); 441 buf.append((int) ctr); 442 for (int i = buf.length() - leadingZero; i < 3; i++) { 443 buf.insert(leadingZero, '0'); 444 } 445 buf.append('_'); 446 buf.append(basicTypeSignature()); 447 String name = buf.toString(); 448 associateWithDebugName(this, name); 449 return name; 450 } 451 452 private static boolean namesOK(int arity, Name[] names) { 453 for (int i = 0; i < names.length; i++) { 454 Name n = names[i]; 455 assert(n != null) : "n is null"; 456 if (i < arity) 457 assert( n.isParam()) : n + " is not param at " + i; 458 else 459 assert(!n.isParam()) : n + " is param at " + i; 460 } 461 return true; 462 } 463 464 /** Customize LambdaForm for a particular MethodHandle */ 465 LambdaForm customize(MethodHandle mh) { 466 if (customized == mh) { 467 return this; 468 } 469 LambdaForm customForm = LambdaForm.create(arity, names, result, forceInline, mh, kind); 470 if (COMPILE_THRESHOLD >= 0 && isCompiled) { 471 // If shared LambdaForm has been compiled, compile customized version as well. 472 customForm.compileToBytecode(); 473 } 474 customForm.transformCache = this; // LambdaFormEditor should always use uncustomized form. 475 return customForm; 476 } 477 478 /** Get uncustomized flavor of the LambdaForm */ 479 LambdaForm uncustomize() { 480 if (customized == null) { 481 return this; 482 } 483 assert(transformCache != null); // Customized LambdaForm should always has a link to uncustomized version. 484 LambdaForm uncustomizedForm = (LambdaForm)transformCache; 485 if (COMPILE_THRESHOLD >= 0 && isCompiled) { 486 // If customized LambdaForm has been compiled, compile uncustomized version as well. 487 uncustomizedForm.compileToBytecode(); 488 } 489 return uncustomizedForm; 490 } 491 492 /** Renumber and/or replace params so that they are interned and canonically numbered. 493 * @return true if we can interpret 494 */ 495 private static boolean normalizeNames(int arity, Name[] names) { 496 Name[] oldNames = null; 497 int maxOutArity = 0; 498 int changesStart = 0; 499 for (int i = 0; i < names.length; i++) { 500 Name n = names[i]; 501 if (!n.initIndex(i)) { 502 if (oldNames == null) { 503 oldNames = names.clone(); 504 changesStart = i; 505 } 506 names[i] = n.cloneWithIndex(i); 507 } 508 if (n.arguments != null && maxOutArity < n.arguments.length) 509 maxOutArity = n.arguments.length; 510 } 511 if (oldNames != null) { 512 int startFixing = arity; 513 if (startFixing <= changesStart) 514 startFixing = changesStart+1; 515 for (int i = startFixing; i < names.length; i++) { 516 Name fixed = names[i].replaceNames(oldNames, names, changesStart, i); 517 names[i] = fixed.newIndex(i); 518 } 519 } 520 int maxInterned = Math.min(arity, INTERNED_ARGUMENT_LIMIT); 521 boolean needIntern = false; 522 for (int i = 0; i < maxInterned; i++) { 523 Name n = names[i], n2 = internArgument(n); 524 if (n != n2) { 525 names[i] = n2; 526 needIntern = true; 527 } 528 } 529 if (needIntern) { 530 for (int i = arity; i < names.length; i++) { 531 names[i].internArguments(); 532 } 533 } 534 535 // return true if we can interpret 536 if (maxOutArity > MethodType.MAX_MH_INVOKER_ARITY) { 537 // Cannot use LF interpreter on very high arity expressions. 538 assert(maxOutArity <= MethodType.MAX_JVM_ARITY); 539 return false; 540 } 541 return true; 542 } 543 544 /** 545 * Check that all embedded Name references are localizable to this lambda, 546 * and are properly ordered after their corresponding definitions. 547 * <p> 548 * Note that a Name can be local to multiple lambdas, as long as 549 * it possesses the same index in each use site. 550 * This allows Name references to be freely reused to construct 551 * fresh lambdas, without confusion. 552 */ 553 boolean nameRefsAreLegal() { 554 assert(arity >= 0 && arity <= names.length); 555 assert(result >= -1 && result < names.length); 556 // Do all names possess an index consistent with their local definition order? 557 for (int i = 0; i < arity; i++) { 558 Name n = names[i]; 559 assert(n.index() == i) : Arrays.asList(n.index(), i); 560 assert(n.isParam()); 561 } 562 // Also, do all local name references 563 for (int i = arity; i < names.length; i++) { 564 Name n = names[i]; 565 assert(n.index() == i); 566 for (Object arg : n.arguments) { 567 if (arg instanceof Name n2) { 568 int i2 = n2.index; 569 assert(0 <= i2 && i2 < names.length) : n.debugString() + ": 0 <= i2 && i2 < names.length: 0 <= " + i2 + " < " + names.length; 570 assert(names[i2] == n2) : Arrays.asList("-1-", i, "-2-", n.debugString(), "-3-", i2, "-4-", n2.debugString(), "-5-", names[i2].debugString(), "-6-", this); 571 assert(i2 < i); // ref must come after def! 572 } 573 } 574 } 575 return true; 576 } 577 578 /** Invoke this form on the given arguments. */ 579 // final Object invoke(Object... args) throws Throwable { 580 // // NYI: fit this into the fast path? 581 // return interpretWithArguments(args); 582 // } 583 584 /** Report the return type. */ 585 BasicType returnType() { 586 if (result < 0) return V_TYPE; 587 Name n = names[result]; 588 return n.type; 589 } 590 591 /** Report the N-th argument type. */ 592 BasicType parameterType(int n) { 593 return parameter(n).type; 594 } 595 596 /** Report the N-th argument name. */ 597 Name parameter(int n) { 598 Name param = names[n]; 599 assert(n < arity && param.isParam()); 600 return param; 601 } 602 603 /** Report the N-th argument type constraint. */ 604 Object parameterConstraint(int n) { 605 return parameter(n).constraint; 606 } 607 608 /** Report the arity. */ 609 int arity() { 610 return arity; 611 } 612 613 /** Report the number of expressions (non-parameter names). */ 614 int expressionCount() { 615 return names.length - arity; 616 } 617 618 /** Return the method type corresponding to my basic type signature. */ 619 MethodType methodType() { 620 Class<?>[] ptypes = new Class<?>[arity]; 621 for (int i = 0; i < arity; ++i) { 622 ptypes[i] = parameterType(i).btClass; 623 } 624 return MethodType.methodType(returnType().btClass, ptypes, true); 625 } 626 627 /** Return ABC_Z, where the ABC are parameter type characters, and Z is the return type character. */ 628 final String basicTypeSignature() { 629 StringBuilder buf = new StringBuilder(arity() + 3); 630 for (int i = 0, a = arity(); i < a; i++) 631 buf.append(parameterType(i).basicTypeChar()); 632 return buf.append('_').append(returnType().basicTypeChar()).toString(); 633 } 634 static int signatureArity(String sig) { 635 assert(isValidSignature(sig)); 636 return sig.indexOf('_'); 637 } 638 static boolean isValidSignature(String sig) { 639 int arity = sig.indexOf('_'); 640 if (arity < 0) return false; // must be of the form *_* 641 int siglen = sig.length(); 642 if (siglen != arity + 2) return false; // *_X 643 for (int i = 0; i < siglen; i++) { 644 if (i == arity) continue; // skip '_' 645 char c = sig.charAt(i); 646 if (c == 'V') 647 return (i == siglen - 1 && arity == siglen - 2); 648 if (!isArgBasicTypeChar(c)) return false; // must be [LIJFD] 649 } 650 return true; // [LIJFD]*_[LIJFDV] 651 } 652 653 /** 654 * Check if i-th name is a call to MethodHandleImpl.selectAlternative. 655 */ 656 boolean isSelectAlternative(int pos) { 657 // selectAlternative idiom: 658 // t_{n}:L=MethodHandleImpl.selectAlternative(...) 659 // t_{n+1}:?=MethodHandle.invokeBasic(t_{n}, ...) 660 if (pos+1 >= names.length) return false; 661 Name name0 = names[pos]; 662 Name name1 = names[pos+1]; 663 return name0.refersTo(MethodHandleImpl.class, "selectAlternative") && 664 name1.isInvokeBasic() && 665 name1.lastUseIndex(name0) == 0 && // t_{n+1}:?=MethodHandle.invokeBasic(t_{n}, ...) 666 lastUseIndex(name0) == pos+1; // t_{n} is local: used only in t_{n+1} 667 } 668 669 private boolean isMatchingIdiom(int pos, String idiomName, int nArgs) { 670 if (pos+2 >= names.length) return false; 671 Name name0 = names[pos]; 672 Name name1 = names[pos+1]; 673 Name name2 = names[pos+2]; 674 return name1.refersTo(MethodHandleImpl.class, idiomName) && 675 name0.isInvokeBasic() && 676 name2.isInvokeBasic() && 677 name1.lastUseIndex(name0) == nArgs && // t_{n+1}:L=MethodHandleImpl.<invoker>(<args>, t_{n}); 678 lastUseIndex(name0) == pos+1 && // t_{n} is local: used only in t_{n+1} 679 name2.lastUseIndex(name1) == 1 && // t_{n+2}:?=MethodHandle.invokeBasic(*, t_{n+1}) 680 lastUseIndex(name1) == pos+2; // t_{n+1} is local: used only in t_{n+2} 681 } 682 683 /** 684 * Check if i-th name is a start of GuardWithCatch idiom. 685 */ 686 boolean isGuardWithCatch(int pos) { 687 // GuardWithCatch idiom: 688 // t_{n}:L=MethodHandle.invokeBasic(...) 689 // t_{n+1}:L=MethodHandleImpl.guardWithCatch(*, *, *, t_{n}); 690 // t_{n+2}:?=MethodHandle.invokeBasic(*, t_{n+1}) 691 return isMatchingIdiom(pos, "guardWithCatch", 3); 692 } 693 694 /** 695 * Check if i-th name is a start of the tryFinally idiom. 696 */ 697 boolean isTryFinally(int pos) { 698 // tryFinally idiom: 699 // t_{n}:L=MethodHandle.invokeBasic(...) 700 // t_{n+1}:L=MethodHandleImpl.tryFinally(*, *, t_{n}) 701 // t_{n+2}:?=MethodHandle.invokeBasic(*, t_{n+1}) 702 return isMatchingIdiom(pos, "tryFinally", 2); 703 } 704 705 /** 706 * Check if i-th name is a start of the tableSwitch idiom. 707 */ 708 boolean isTableSwitch(int pos) { 709 // tableSwitch idiom: 710 // t_{n}:L=MethodHandle.invokeBasic(...) // args 711 // t_{n+1}:L=MethodHandleImpl.tableSwitch(*, *, *, t_{n}) 712 // t_{n+2}:?=MethodHandle.invokeBasic(*, t_{n+1}) 713 if (pos + 2 >= names.length) return false; 714 715 final int POS_COLLECT_ARGS = pos; 716 final int POS_TABLE_SWITCH = pos + 1; 717 final int POS_UNBOX_RESULT = pos + 2; 718 719 Name collectArgs = names[POS_COLLECT_ARGS]; 720 Name tableSwitch = names[POS_TABLE_SWITCH]; 721 Name unboxResult = names[POS_UNBOX_RESULT]; 722 return tableSwitch.refersTo(MethodHandleImpl.class, "tableSwitch") && 723 collectArgs.isInvokeBasic() && 724 unboxResult.isInvokeBasic() && 725 tableSwitch.lastUseIndex(collectArgs) == 3 && // t_{n+1}:L=MethodHandleImpl.<invoker>(*, *, *, t_{n}); 726 lastUseIndex(collectArgs) == POS_TABLE_SWITCH && // t_{n} is local: used only in t_{n+1} 727 unboxResult.lastUseIndex(tableSwitch) == 1 && // t_{n+2}:?=MethodHandle.invokeBasic(*, t_{n+1}) 728 lastUseIndex(tableSwitch) == POS_UNBOX_RESULT; // t_{n+1} is local: used only in t_{n+2} 729 } 730 731 /** 732 * Check if i-th name is a start of the loop idiom. 733 */ 734 boolean isLoop(int pos) { 735 // loop idiom: 736 // t_{n}:L=MethodHandle.invokeBasic(...) 737 // t_{n+1}:L=MethodHandleImpl.loop(types, *, t_{n}) 738 // t_{n+2}:?=MethodHandle.invokeBasic(*, t_{n+1}) 739 return isMatchingIdiom(pos, "loop", 2); 740 } 741 742 /* 743 * Code generation issues: 744 * 745 * Compiled LFs should be reusable in general. 746 * The biggest issue is how to decide when to pull a name into 747 * the bytecode, versus loading a reified form from the MH data. 748 * 749 * For example, an asType wrapper may require execution of a cast 750 * after a call to a MH. The target type of the cast can be placed 751 * as a constant in the LF itself. This will force the cast type 752 * to be compiled into the bytecodes and native code for the MH. 753 * Or, the target type of the cast can be erased in the LF, and 754 * loaded from the MH data. (Later on, if the MH as a whole is 755 * inlined, the data will flow into the inlined instance of the LF, 756 * as a constant, and the end result will be an optimal cast.) 757 * 758 * This erasure of cast types can be done with any use of 759 * reference types. It can also be done with whole method 760 * handles. Erasing a method handle might leave behind 761 * LF code that executes correctly for any MH of a given 762 * type, and load the required MH from the enclosing MH's data. 763 * Or, the erasure might even erase the expected MT. 764 * 765 * Also, for direct MHs, the MemberName of the target 766 * could be erased, and loaded from the containing direct MH. 767 * As a simple case, a LF for all int-valued non-static 768 * field getters would perform a cast on its input argument 769 * (to non-constant base type derived from the MemberName) 770 * and load an integer value from the input object 771 * (at a non-constant offset also derived from the MemberName). 772 * Such MN-erased LFs would be inlinable back to optimized 773 * code, whenever a constant enclosing DMH is available 774 * to supply a constant MN from its data. 775 * 776 * The main problem here is to keep LFs reasonably generic, 777 * while ensuring that hot spots will inline good instances. 778 * "Reasonably generic" means that we don't end up with 779 * repeated versions of bytecode or machine code that do 780 * not differ in their optimized form. Repeated versions 781 * of machine would have the undesirable overheads of 782 * (a) redundant compilation work and (b) extra I$ pressure. 783 * To control repeated versions, we need to be ready to 784 * erase details from LFs and move them into MH data, 785 * whenever those details are not relevant to significant 786 * optimization. "Significant" means optimization of 787 * code that is actually hot. 788 * 789 * Achieving this may require dynamic splitting of MHs, by replacing 790 * a generic LF with a more specialized one, on the same MH, 791 * if (a) the MH is frequently executed and (b) the MH cannot 792 * be inlined into a containing caller, such as an invokedynamic. 793 * 794 * Compiled LFs that are no longer used should be GC-able. 795 * If they contain non-BCP references, they should be properly 796 * interlinked with the class loader(s) that their embedded types 797 * depend on. This probably means that reusable compiled LFs 798 * will be tabulated (indexed) on relevant class loaders, 799 * or else that the tables that cache them will have weak links. 800 */ 801 802 /** 803 * Make this LF directly executable, as part of a MethodHandle. 804 * Invariant: Every MH which is invoked must prepare its LF 805 * before invocation. 806 * (In principle, the JVM could do this very lazily, 807 * as a sort of pre-invocation linkage step.) 808 */ 809 public void prepare() { 810 if (COMPILE_THRESHOLD == 0 && !forceInterpretation() && !isCompiled) { 811 compileToBytecode(); 812 } 813 if (this.vmentry != null) { 814 // already prepared (e.g., a primitive DMH invoker form) 815 return; 816 } 817 MethodType mtype = methodType(); 818 LambdaForm prep = mtype.form().cachedLambdaForm(MethodTypeForm.LF_INTERPRET); 819 if (prep == null) { 820 assert (isValidSignature(basicTypeSignature())); 821 prep = LambdaForm.createBlankForType(mtype); 822 prep.vmentry = InvokerBytecodeGenerator.generateLambdaFormInterpreterEntryPoint(mtype); 823 prep = mtype.form().setCachedLambdaForm(MethodTypeForm.LF_INTERPRET, prep); 824 } 825 this.vmentry = prep.vmentry; 826 // TO DO: Maybe add invokeGeneric, invokeWithArguments 827 } 828 829 private static @Stable PerfCounter LF_FAILED; 830 831 private static PerfCounter failedCompilationCounter() { 832 if (LF_FAILED == null) { 833 LF_FAILED = PerfCounter.newPerfCounter("java.lang.invoke.failedLambdaFormCompilations"); 834 } 835 return LF_FAILED; 836 } 837 838 /** Generate optimizable bytecode for this form. */ 839 void compileToBytecode() { 840 if (forceInterpretation()) { 841 return; // this should not be compiled 842 } 843 if (vmentry != null && isCompiled) { 844 return; // already compiled somehow 845 } 846 847 // Obtain the invoker MethodType outside of the following try block. 848 // This ensures that an IllegalArgumentException is directly thrown if the 849 // type would have 256 or more parameters 850 MethodType invokerType = methodType(); 851 assert(vmentry == null || vmentry.getMethodType().basicType().equals(invokerType)); 852 try { 853 vmentry = InvokerBytecodeGenerator.generateCustomizedCode(this, invokerType); 854 if (TRACE_INTERPRETER) 855 traceInterpreter("compileToBytecode", this); 856 isCompiled = true; 857 } catch (InvokerBytecodeGenerator.BytecodeGenerationException bge) { 858 // bytecode generation failed - mark this LambdaForm as to be run in interpretation mode only 859 invocationCounter = -1; 860 failedCompilationCounter().increment(); 861 if (LOG_LF_COMPILATION_FAILURE) { 862 System.out.println("LambdaForm compilation failed: " + this); 863 bge.printStackTrace(System.out); 864 } 865 } catch (Error e) { 866 // Pass through any error 867 throw e; 868 } catch (Exception e) { 869 // Wrap any exception 870 throw newInternalError(this.toString(), e); 871 } 872 } 873 874 // The next few routines are called only from assert expressions 875 // They verify that the built-in invokers process the correct raw data types. 876 private static boolean argumentTypesMatch(String sig, Object[] av) { 877 int arity = signatureArity(sig); 878 assert(av.length == arity) : "av.length == arity: av.length=" + av.length + ", arity=" + arity; 879 assert(av[0] instanceof MethodHandle) : "av[0] not instance of MethodHandle: " + av[0]; 880 MethodHandle mh = (MethodHandle) av[0]; 881 MethodType mt = mh.type(); 882 assert(mt.parameterCount() == arity-1); 883 for (int i = 0; i < av.length; i++) { 884 Class<?> pt = (i == 0 ? MethodHandle.class : mt.parameterType(i-1)); 885 assert(valueMatches(basicType(sig.charAt(i)), pt, av[i])); 886 } 887 return true; 888 } 889 private static boolean valueMatches(BasicType tc, Class<?> type, Object x) { 890 // The following line is needed because (...)void method handles can use non-void invokers 891 if (type == void.class) tc = V_TYPE; // can drop any kind of value 892 assert tc == basicType(type) : tc + " == basicType(" + type + ")=" + basicType(type); 893 switch (tc) { 894 case I_TYPE: assert checkInt(type, x) : "checkInt(" + type + "," + x +")"; break; 895 case J_TYPE: assert x instanceof Long : "instanceof Long: " + x; break; 896 case F_TYPE: assert x instanceof Float : "instanceof Float: " + x; break; 897 case D_TYPE: assert x instanceof Double : "instanceof Double: " + x; break; 898 case L_TYPE: assert checkRef(type, x) : "checkRef(" + type + "," + x + ")"; break; 899 case V_TYPE: break; // allow anything here; will be dropped 900 default: assert(false); 901 } 902 return true; 903 } 904 private static boolean checkInt(Class<?> type, Object x) { 905 assert(x instanceof Integer); 906 if (type == int.class) return true; 907 Wrapper w = Wrapper.forBasicType(type); 908 assert(w.isSubwordOrInt()); 909 Object x1 = Wrapper.INT.wrap(w.wrap(x)); 910 return x.equals(x1); 911 } 912 private static boolean checkRef(Class<?> type, Object x) { 913 assert(!type.isPrimitive()); 914 if (x == null) return true; 915 if (type.isInterface()) return true; 916 return type.isInstance(x); 917 } 918 919 /** If the invocation count hits the threshold we spin bytecodes and call that subsequently. */ 920 private static final int COMPILE_THRESHOLD; 921 static { 922 COMPILE_THRESHOLD = Math.max(-1, MethodHandleStatics.COMPILE_THRESHOLD); 923 } 924 private int invocationCounter = 0; // a value of -1 indicates LambdaForm interpretation mode forever 925 926 private boolean forceInterpretation() { 927 return invocationCounter == -1; 928 } 929 930 @Hidden 931 @DontInline 932 /** Interpretively invoke this form on the given arguments. */ 933 Object interpretWithArguments(Object... argumentValues) throws Throwable { 934 if (TRACE_INTERPRETER) 935 return interpretWithArgumentsTracing(argumentValues); 936 checkInvocationCounter(); 937 assert(arityCheck(argumentValues)); 938 Object[] values = Arrays.copyOf(argumentValues, names.length); 939 for (int i = argumentValues.length; i < values.length; i++) { 940 values[i] = interpretName(names[i], values); 941 } 942 Object rv = (result < 0) ? null : values[result]; 943 assert(resultCheck(argumentValues, rv)); 944 return rv; 945 } 946 947 @Hidden 948 @DontInline 949 /** Evaluate a single Name within this form, applying its function to its arguments. */ 950 Object interpretName(Name name, Object[] values) throws Throwable { 951 if (TRACE_INTERPRETER) 952 traceInterpreter("| interpretName", name.debugString(), (Object[]) null); 953 Object[] arguments = Arrays.copyOf(name.arguments, name.arguments.length, Object[].class); 954 for (int i = 0; i < arguments.length; i++) { 955 Object a = arguments[i]; 956 if (a instanceof Name n) { 957 int i2 = n.index(); 958 assert(names[i2] == a); 959 a = values[i2]; 960 arguments[i] = a; 961 } 962 } 963 return name.function.invokeWithArguments(arguments); 964 } 965 966 private void checkInvocationCounter() { 967 if (COMPILE_THRESHOLD != 0 && 968 !forceInterpretation() && invocationCounter < COMPILE_THRESHOLD) { 969 invocationCounter++; // benign race 970 if (invocationCounter >= COMPILE_THRESHOLD) { 971 // Replace vmentry with a bytecode version of this LF. 972 compileToBytecode(); 973 } 974 } 975 } 976 Object interpretWithArgumentsTracing(Object... argumentValues) throws Throwable { 977 traceInterpreter("[ interpretWithArguments", this, argumentValues); 978 if (!forceInterpretation() && invocationCounter < COMPILE_THRESHOLD) { 979 int ctr = invocationCounter++; // benign race 980 traceInterpreter("| invocationCounter", ctr); 981 if (invocationCounter >= COMPILE_THRESHOLD) { 982 compileToBytecode(); 983 } 984 } 985 Object rval; 986 try { 987 assert(arityCheck(argumentValues)); 988 Object[] values = Arrays.copyOf(argumentValues, names.length); 989 for (int i = argumentValues.length; i < values.length; i++) { 990 values[i] = interpretName(names[i], values); 991 } 992 rval = (result < 0) ? null : values[result]; 993 } catch (Throwable ex) { 994 traceInterpreter("] throw =>", ex); 995 throw ex; 996 } 997 traceInterpreter("] return =>", rval); 998 return rval; 999 } 1000 1001 static void traceInterpreter(String event, Object obj, Object... args) { 1002 if (TRACE_INTERPRETER) { 1003 System.out.println("LFI: "+event+" "+(obj != null ? obj : "")+(args != null && args.length != 0 ? Arrays.asList(args) : "")); 1004 } 1005 } 1006 static void traceInterpreter(String event, Object obj) { 1007 traceInterpreter(event, obj, (Object[])null); 1008 } 1009 private boolean arityCheck(Object[] argumentValues) { 1010 assert(argumentValues.length == arity) : arity+"!="+Arrays.asList(argumentValues)+".length"; 1011 // also check that the leading (receiver) argument is somehow bound to this LF: 1012 assert(argumentValues[0] instanceof MethodHandle) : "not MH: " + argumentValues[0]; 1013 MethodHandle mh = (MethodHandle) argumentValues[0]; 1014 assert(mh.internalForm() == this); 1015 // note: argument #0 could also be an interface wrapper, in the future 1016 argumentTypesMatch(basicTypeSignature(), argumentValues); 1017 return true; 1018 } 1019 private boolean resultCheck(Object[] argumentValues, Object result) { 1020 MethodHandle mh = (MethodHandle) argumentValues[0]; 1021 MethodType mt = mh.type(); 1022 assert(valueMatches(returnType(), mt.returnType(), result)); 1023 return true; 1024 } 1025 1026 private boolean isEmpty() { 1027 if (result < 0) 1028 return (names.length == arity); 1029 else if (result == arity && names.length == arity + 1) 1030 return names[arity].isConstantZero(); 1031 else 1032 return false; 1033 } 1034 1035 public String toString() { 1036 return debugString(-1); 1037 } 1038 1039 String debugString(int indentLevel) { 1040 String prefix = MethodHandle.debugPrefix(indentLevel); 1041 String lambdaName = lambdaName(); 1042 StringBuilder buf = new StringBuilder(lambdaName); 1043 buf.append("=Lambda("); 1044 for (int i = 0; i < names.length; i++) { 1045 if (i == arity) buf.append(")=>{"); 1046 Name n = names[i]; 1047 if (i >= arity) buf.append("\n ").append(prefix); 1048 buf.append(n.paramString()); 1049 if (i < arity) { 1050 if (i+1 < arity) buf.append(","); 1051 continue; 1052 } 1053 buf.append("=").append(n.exprString()); 1054 buf.append(";"); 1055 } 1056 if (arity == names.length) buf.append(")=>{"); 1057 buf.append(result < 0 ? "void" : names[result]).append("}"); 1058 if (TRACE_INTERPRETER) { 1059 // Extra verbosity: 1060 buf.append(":").append(basicTypeSignature()); 1061 buf.append("/").append(vmentry); 1062 } 1063 return buf.toString(); 1064 } 1065 1066 @Override 1067 public boolean equals(Object obj) { 1068 return obj instanceof LambdaForm lf && equals(lf); 1069 } 1070 public boolean equals(LambdaForm that) { 1071 if (this.result != that.result) return false; 1072 return Arrays.equals(this.names, that.names); 1073 } 1074 public int hashCode() { 1075 return result + 31 * Arrays.hashCode(names); 1076 } 1077 LambdaFormEditor editor() { 1078 return LambdaFormEditor.lambdaFormEditor(this); 1079 } 1080 1081 boolean contains(Name name) { 1082 int pos = name.index(); 1083 if (pos >= 0) { 1084 return pos < names.length && name.equals(names[pos]); 1085 } 1086 for (int i = arity; i < names.length; i++) { 1087 if (name.equals(names[i])) 1088 return true; 1089 } 1090 return false; 1091 } 1092 1093 static class NamedFunction { 1094 final MemberName member; 1095 private @Stable MethodHandle resolvedHandle; 1096 private @Stable MethodType type; 1097 1098 NamedFunction(MethodHandle resolvedHandle) { 1099 this(resolvedHandle.internalMemberName(), resolvedHandle); 1100 } 1101 NamedFunction(MemberName member, MethodHandle resolvedHandle) { 1102 this.member = member; 1103 this.resolvedHandle = resolvedHandle; 1104 // The following assert is almost always correct, but will fail for corner cases, such as PrivateInvokeTest. 1105 //assert(!isInvokeBasic(member)); 1106 } 1107 NamedFunction(MethodType basicInvokerType) { 1108 assert(basicInvokerType == basicInvokerType.basicType()) : basicInvokerType; 1109 if (basicInvokerType.parameterSlotCount() < MethodType.MAX_MH_INVOKER_ARITY) { 1110 this.resolvedHandle = basicInvokerType.invokers().basicInvoker(); 1111 this.member = resolvedHandle.internalMemberName(); 1112 } else { 1113 // necessary to pass BigArityTest 1114 this.member = Invokers.invokeBasicMethod(basicInvokerType); 1115 } 1116 assert(isInvokeBasic(member)); 1117 } 1118 1119 private static boolean isInvokeBasic(MemberName member) { 1120 return member != null && 1121 member.getDeclaringClass() == MethodHandle.class && 1122 "invokeBasic".equals(member.getName()); 1123 } 1124 1125 // The next 2 constructors are used to break circular dependencies on MH.invokeStatic, etc. 1126 // Any LambdaForm containing such a member is not interpretable. 1127 // This is OK, since all such LFs are prepared with special primitive vmentry points. 1128 // And even without the resolvedHandle, the name can still be compiled and optimized. 1129 NamedFunction(Method method) { 1130 this(new MemberName(method)); 1131 } 1132 NamedFunction(MemberName member) { 1133 this(member, null); 1134 } 1135 1136 MethodHandle resolvedHandle() { 1137 if (resolvedHandle == null) resolve(); 1138 return resolvedHandle; 1139 } 1140 1141 synchronized void resolve() { 1142 if (resolvedHandle == null) { 1143 resolvedHandle = DirectMethodHandle.make(member); 1144 } 1145 } 1146 1147 @Override 1148 public boolean equals(Object other) { 1149 if (this == other) return true; 1150 if (other == null) return false; 1151 return (other instanceof NamedFunction that) 1152 && this.member != null 1153 && this.member.equals(that.member); 1154 } 1155 1156 @Override 1157 public int hashCode() { 1158 if (member != null) 1159 return member.hashCode(); 1160 return super.hashCode(); 1161 } 1162 1163 static final MethodType INVOKER_METHOD_TYPE = 1164 MethodType.methodType(Object.class, MethodHandle.class, Object[].class); 1165 1166 private static MethodHandle computeInvoker(MethodTypeForm typeForm) { 1167 typeForm = typeForm.basicType().form(); // normalize to basic type 1168 MethodHandle mh = typeForm.cachedMethodHandle(MethodTypeForm.MH_NF_INV); 1169 if (mh != null) return mh; 1170 MemberName invoker = InvokerBytecodeGenerator.generateNamedFunctionInvoker(typeForm); // this could take a while 1171 mh = DirectMethodHandle.make(invoker); 1172 MethodHandle mh2 = typeForm.cachedMethodHandle(MethodTypeForm.MH_NF_INV); 1173 if (mh2 != null) return mh2; // benign race 1174 if (!mh.type().equals(INVOKER_METHOD_TYPE)) 1175 throw newInternalError(mh.debugString()); 1176 return typeForm.setCachedMethodHandle(MethodTypeForm.MH_NF_INV, mh); 1177 } 1178 1179 @Hidden 1180 Object invokeWithArguments(Object... arguments) throws Throwable { 1181 // If we have a cached invoker, call it right away. 1182 // NOTE: The invoker always returns a reference value. 1183 if (TRACE_INTERPRETER) return invokeWithArgumentsTracing(arguments); 1184 return invoker().invokeBasic(resolvedHandle(), arguments); 1185 } 1186 1187 @Hidden 1188 Object invokeWithArgumentsTracing(Object[] arguments) throws Throwable { 1189 Object rval; 1190 try { 1191 traceInterpreter("[ call", this, arguments); 1192 // resolvedHandle might be uninitialized, ok for tracing 1193 if (resolvedHandle == null) { 1194 traceInterpreter("| resolve", this); 1195 resolvedHandle(); 1196 } 1197 rval = invoker().invokeBasic(resolvedHandle(), arguments); 1198 } catch (Throwable ex) { 1199 traceInterpreter("] throw =>", ex); 1200 throw ex; 1201 } 1202 traceInterpreter("] return =>", rval); 1203 return rval; 1204 } 1205 1206 private MethodHandle invoker() { 1207 return computeInvoker(methodType().form()); 1208 } 1209 1210 MethodType methodType() { 1211 MethodType type = this.type; 1212 if (type == null) { 1213 this.type = type = calculateMethodType(member, resolvedHandle); 1214 } 1215 return type; 1216 } 1217 1218 private static MethodType calculateMethodType(MemberName member, MethodHandle resolvedHandle) { 1219 if (resolvedHandle != null) { 1220 return resolvedHandle.type(); 1221 } else { 1222 // only for certain internal LFs during bootstrapping 1223 return member.getInvocationType(); 1224 } 1225 } 1226 1227 MemberName member() { 1228 assert(assertMemberIsConsistent()); 1229 return member; 1230 } 1231 1232 // Called only from assert. 1233 private boolean assertMemberIsConsistent() { 1234 if (resolvedHandle instanceof DirectMethodHandle) { 1235 MemberName m = resolvedHandle.internalMemberName(); 1236 assert(m.equals(member)); 1237 } 1238 return true; 1239 } 1240 1241 Class<?> memberDeclaringClassOrNull() { 1242 return (member == null) ? null : member.getDeclaringClass(); 1243 } 1244 1245 BasicType returnType() { 1246 return basicType(methodType().returnType()); 1247 } 1248 1249 BasicType parameterType(int n) { 1250 return basicType(methodType().parameterType(n)); 1251 } 1252 1253 int arity() { 1254 return methodType().parameterCount(); 1255 } 1256 1257 public String toString() { 1258 if (member == null) return String.valueOf(resolvedHandle); 1259 return member.getDeclaringClass().getSimpleName()+"."+member.getName(); 1260 } 1261 1262 public boolean isIdentity() { 1263 return this.equals(identity(returnType())); 1264 } 1265 1266 public boolean isConstantZero() { 1267 return this.equals(constantZero(returnType())); 1268 } 1269 1270 public MethodHandleImpl.Intrinsic intrinsicName() { 1271 return resolvedHandle != null 1272 ? resolvedHandle.intrinsicName() 1273 : MethodHandleImpl.Intrinsic.NONE; 1274 } 1275 1276 public Object intrinsicData() { 1277 return resolvedHandle != null 1278 ? resolvedHandle.intrinsicData() 1279 : null; 1280 } 1281 } 1282 1283 public static String basicTypeSignature(MethodType type) { 1284 int params = type.parameterCount(); 1285 char[] sig = new char[params + 2]; 1286 int sigp = 0; 1287 while (sigp < params) { 1288 sig[sigp] = basicTypeChar(type.parameterType(sigp++)); 1289 } 1290 sig[sigp++] = '_'; 1291 sig[sigp++] = basicTypeChar(type.returnType()); 1292 assert(sigp == sig.length); 1293 return String.valueOf(sig); 1294 } 1295 1296 /** Hack to make signatures more readable when they show up in method names. 1297 * Signature should start with a sequence of uppercase ASCII letters. 1298 * Runs of three or more are replaced by a single letter plus a decimal repeat count. 1299 * A tail of anything other than uppercase ASCII is passed through unchanged. 1300 * @param signature sequence of uppercase ASCII letters with possible repetitions 1301 * @return same sequence, with repetitions counted by decimal numerals 1302 */ 1303 public static String shortenSignature(String signature) { 1304 final int NO_CHAR = -1, MIN_RUN = 3; 1305 int c0, c1 = NO_CHAR, c1reps = 0; 1306 StringBuilder buf = null; 1307 int len = signature.length(); 1308 if (len < MIN_RUN) return signature; 1309 for (int i = 0; i <= len; i++) { 1310 if (c1 != NO_CHAR && !('A' <= c1 && c1 <= 'Z')) { 1311 // wrong kind of char; bail out here 1312 if (buf != null) { 1313 buf.append(signature, i - c1reps, len); 1314 } 1315 break; 1316 } 1317 // shift in the next char: 1318 c0 = c1; c1 = (i == len ? NO_CHAR : signature.charAt(i)); 1319 if (c1 == c0) { ++c1reps; continue; } 1320 // shift in the next count: 1321 int c0reps = c1reps; c1reps = 1; 1322 // end of a character run 1323 if (c0reps < MIN_RUN) { 1324 if (buf != null) { 1325 while (--c0reps >= 0) 1326 buf.append((char)c0); 1327 } 1328 continue; 1329 } 1330 // found three or more in a row 1331 if (buf == null) 1332 buf = new StringBuilder().append(signature, 0, i - c0reps); 1333 buf.append((char)c0).append(c0reps); 1334 } 1335 return (buf == null) ? signature : buf.toString(); 1336 } 1337 1338 static final class Name { 1339 final BasicType type; 1340 @Stable short index; 1341 final NamedFunction function; 1342 final Object constraint; // additional type information, if not null 1343 @Stable final Object[] arguments; 1344 1345 private static final Object[] EMPTY_ARGS = new Object[0]; 1346 1347 private Name(int index, BasicType type, NamedFunction function, Object[] arguments) { 1348 this.index = (short)index; 1349 this.type = type; 1350 this.function = function; 1351 this.arguments = arguments; 1352 this.constraint = null; 1353 assert(this.index == index && typesMatch(function, this.arguments)); 1354 } 1355 private Name(Name that, Object constraint) { 1356 this.index = that.index; 1357 this.type = that.type; 1358 this.function = that.function; 1359 this.arguments = that.arguments; 1360 this.constraint = constraint; 1361 assert(constraint == null || isParam()); // only params have constraints 1362 assert(constraint == null || constraint instanceof ClassSpecializer.SpeciesData || constraint instanceof Class); 1363 } 1364 Name(MethodHandle function, Object... arguments) { 1365 this(new NamedFunction(function), arguments); 1366 } 1367 Name(MethodType functionType, Object... arguments) { 1368 this(new NamedFunction(functionType), arguments); 1369 assert(arguments[0] instanceof Name name && name.type == L_TYPE); 1370 } 1371 Name(MemberName function, Object... arguments) { 1372 this(new NamedFunction(function), arguments); 1373 } 1374 Name(NamedFunction function) { 1375 this(-1, function.returnType(), function, EMPTY_ARGS); 1376 } 1377 Name(NamedFunction function, Object arg) { 1378 this(-1, function.returnType(), function, new Object[] { arg }); 1379 } 1380 Name(NamedFunction function, Object arg0, Object arg1) { 1381 this(-1, function.returnType(), function, new Object[] { arg0, arg1 }); 1382 } 1383 Name(NamedFunction function, Object... arguments) { 1384 this(-1, function.returnType(), function, Arrays.copyOf(arguments, arguments.length, Object[].class)); 1385 } 1386 /** Create a raw parameter of the given type, with an expected index. */ 1387 Name(int index, BasicType type) { 1388 this(index, type, null, null); 1389 } 1390 /** Create a raw parameter of the given type. */ 1391 Name(BasicType type) { this(-1, type); } 1392 1393 BasicType type() { return type; } 1394 int index() { return index; } 1395 boolean initIndex(int i) { 1396 if (index != i) { 1397 if (index != -1) return false; 1398 index = (short)i; 1399 } 1400 return true; 1401 } 1402 char typeChar() { 1403 return type.btChar; 1404 } 1405 1406 Name newIndex(int i) { 1407 if (initIndex(i)) return this; 1408 return cloneWithIndex(i); 1409 } 1410 Name cloneWithIndex(int i) { 1411 Object[] newArguments = (arguments == null) ? null : arguments.clone(); 1412 return new Name(i, type, function, newArguments).withConstraint(constraint); 1413 } 1414 Name withConstraint(Object constraint) { 1415 if (constraint == this.constraint) return this; 1416 return new Name(this, constraint); 1417 } 1418 Name replaceName(Name oldName, Name newName) { // FIXME: use replaceNames uniformly 1419 if (oldName == newName) return this; 1420 @SuppressWarnings("LocalVariableHidesMemberVariable") 1421 Object[] arguments = this.arguments; 1422 if (arguments == null) return this; 1423 boolean replaced = false; 1424 for (int j = 0; j < arguments.length; j++) { 1425 if (arguments[j] == oldName) { 1426 if (!replaced) { 1427 replaced = true; 1428 arguments = arguments.clone(); 1429 } 1430 arguments[j] = newName; 1431 } 1432 } 1433 if (!replaced) return this; 1434 return new Name(function, arguments); 1435 } 1436 /** In the arguments of this Name, replace oldNames[i] pairwise by newNames[i]. 1437 * Limit such replacements to {@code start<=i<end}. Return possibly changed self. 1438 */ 1439 Name replaceNames(Name[] oldNames, Name[] newNames, int start, int end) { 1440 if (start >= end) return this; 1441 @SuppressWarnings("LocalVariableHidesMemberVariable") 1442 Object[] arguments = this.arguments; 1443 boolean replaced = false; 1444 eachArg: 1445 for (int j = 0; j < arguments.length; j++) { 1446 if (arguments[j] instanceof Name n) { 1447 int check = n.index; 1448 // harmless check to see if the thing is already in newNames: 1449 if (check >= 0 && check < newNames.length && n == newNames[check]) 1450 continue eachArg; 1451 // n might not have the correct index: n != oldNames[n.index]. 1452 for (int i = start; i < end; i++) { 1453 if (n == oldNames[i]) { 1454 if (n == newNames[i]) 1455 continue eachArg; 1456 if (!replaced) { 1457 replaced = true; 1458 arguments = arguments.clone(); 1459 } 1460 arguments[j] = newNames[i]; 1461 continue eachArg; 1462 } 1463 } 1464 } 1465 } 1466 if (!replaced) return this; 1467 return new Name(function, arguments); 1468 } 1469 void internArguments() { 1470 @SuppressWarnings("LocalVariableHidesMemberVariable") 1471 Object[] arguments = this.arguments; 1472 for (int j = 0; j < arguments.length; j++) { 1473 if (arguments[j] instanceof Name n) { 1474 if (n.isParam() && n.index < INTERNED_ARGUMENT_LIMIT) 1475 arguments[j] = internArgument(n); 1476 } 1477 } 1478 } 1479 boolean isParam() { 1480 return function == null; 1481 } 1482 boolean isConstantZero() { 1483 return !isParam() && arguments.length == 0 && function.isConstantZero(); 1484 } 1485 1486 boolean refersTo(Class<?> declaringClass, String methodName) { 1487 return function != null && 1488 function.member() != null && function.member().refersTo(declaringClass, methodName); 1489 } 1490 1491 /** 1492 * Check if MemberName is a call to MethodHandle.invokeBasic. 1493 */ 1494 boolean isInvokeBasic() { 1495 if (function == null) 1496 return false; 1497 if (arguments.length < 1) 1498 return false; // must have MH argument 1499 MemberName member = function.member(); 1500 return member != null && member.refersTo(MethodHandle.class, "invokeBasic") && 1501 !member.isPublic() && !member.isStatic(); 1502 } 1503 1504 /** 1505 * Check if MemberName is a call to MethodHandle.linkToStatic, etc. 1506 */ 1507 boolean isLinkerMethodInvoke() { 1508 if (function == null) 1509 return false; 1510 if (arguments.length < 1) 1511 return false; // must have MH argument 1512 MemberName member = function.member(); 1513 return member != null && 1514 member.getDeclaringClass() == MethodHandle.class && 1515 !member.isPublic() && member.isStatic() && 1516 member.getName().startsWith("linkTo"); 1517 } 1518 1519 public String toString() { 1520 return (isParam()?"a":"t")+(index >= 0 ? index : System.identityHashCode(this))+":"+typeChar(); 1521 } 1522 public String debugString() { 1523 String s = paramString(); 1524 return (function == null) ? s : s + "=" + exprString(); 1525 } 1526 public String paramString() { 1527 String s = toString(); 1528 Object c = constraint; 1529 if (c == null) 1530 return s; 1531 if (c instanceof Class<?> cl) c = cl.getSimpleName(); 1532 return s + "/" + c; 1533 } 1534 public String exprString() { 1535 if (function == null) return toString(); 1536 StringBuilder buf = new StringBuilder(function.toString()); 1537 buf.append("("); 1538 String cma = ""; 1539 for (Object a : arguments) { 1540 buf.append(cma); cma = ","; 1541 if (a instanceof Name || a instanceof Integer) 1542 buf.append(a); 1543 else 1544 buf.append("(").append(a).append(")"); 1545 } 1546 buf.append(")"); 1547 return buf.toString(); 1548 } 1549 1550 private boolean typesMatch(NamedFunction function, Object ... arguments) { 1551 if (arguments == null) { 1552 assert(function == null); 1553 return true; 1554 } 1555 assert(arguments.length == function.arity()) : "arity mismatch: arguments.length=" + arguments.length + " == function.arity()=" + function.arity() + " in " + debugString(); 1556 for (int i = 0; i < arguments.length; i++) { 1557 assert (typesMatch(function.parameterType(i), arguments[i])) : "types don't match: function.parameterType(" + i + ")=" + function.parameterType(i) + ", arguments[" + i + "]=" + arguments[i] + " in " + debugString(); 1558 } 1559 return true; 1560 } 1561 1562 private static boolean typesMatch(BasicType parameterType, Object object) { 1563 if (object instanceof Name name) { 1564 return name.type == parameterType; 1565 } 1566 switch (parameterType) { 1567 case I_TYPE: return object instanceof Integer; 1568 case J_TYPE: return object instanceof Long; 1569 case F_TYPE: return object instanceof Float; 1570 case D_TYPE: return object instanceof Double; 1571 } 1572 assert(parameterType == L_TYPE); 1573 return true; 1574 } 1575 1576 /** Return the index of the last occurrence of n in the argument array. 1577 * Return -1 if the name is not used. 1578 */ 1579 int lastUseIndex(Name n) { 1580 if (arguments == null) return -1; 1581 for (int i = arguments.length; --i >= 0; ) { 1582 if (arguments[i] == n) return i; 1583 } 1584 return -1; 1585 } 1586 1587 /** Return the number of occurrences of n in the argument array. 1588 * Return 0 if the name is not used. 1589 */ 1590 int useCount(Name n) { 1591 int count = 0; 1592 if (arguments != null) { 1593 for (Object argument : arguments) { 1594 if (argument == n) { 1595 count++; 1596 } 1597 } 1598 } 1599 return count; 1600 } 1601 1602 public boolean equals(Name that) { 1603 if (this == that) return true; 1604 if (isParam()) 1605 // each parameter is a unique atom 1606 return false; // this != that 1607 return 1608 //this.index == that.index && 1609 this.type == that.type && 1610 this.function.equals(that.function) && 1611 Arrays.equals(this.arguments, that.arguments); 1612 } 1613 @Override 1614 public boolean equals(Object x) { 1615 return x instanceof Name n && equals(n); 1616 } 1617 @Override 1618 public int hashCode() { 1619 if (isParam()) 1620 return index | (type.ordinal() << 8); 1621 return function.hashCode() ^ Arrays.hashCode(arguments); 1622 } 1623 } 1624 1625 /** Return the index of the last name which contains n as an argument. 1626 * Return -1 if the name is not used. Return names.length if it is the return value. 1627 */ 1628 int lastUseIndex(Name n) { 1629 int ni = n.index, nmax = names.length; 1630 assert(names[ni] == n); 1631 if (result == ni) return nmax; // live all the way beyond the end 1632 for (int i = nmax; --i > ni; ) { 1633 if (names[i].lastUseIndex(n) >= 0) 1634 return i; 1635 } 1636 return -1; 1637 } 1638 1639 /** Return the number of times n is used as an argument or return value. */ 1640 int useCount(Name n) { 1641 int count = (result == n.index) ? 1 : 0; 1642 int i = Math.max(n.index + 1, arity); 1643 while (i < names.length) { 1644 count += names[i++].useCount(n); 1645 } 1646 return count; 1647 } 1648 1649 static Name argument(int which, BasicType type) { 1650 if (which >= INTERNED_ARGUMENT_LIMIT) 1651 return new Name(which, type); 1652 return INTERNED_ARGUMENTS[type.ordinal()][which]; 1653 } 1654 static Name internArgument(Name n) { 1655 assert(n.isParam()) : "not param: " + n; 1656 assert(n.index < INTERNED_ARGUMENT_LIMIT); 1657 if (n.constraint != null) return n; 1658 return argument(n.index, n.type); 1659 } 1660 static Name[] arguments(int extra, MethodType types) { 1661 int length = types.parameterCount(); 1662 Name[] names = new Name[length + extra]; 1663 for (int i = 0; i < length; i++) 1664 names[i] = argument(i, basicType(types.parameterType(i))); 1665 return names; 1666 } 1667 static final int INTERNED_ARGUMENT_LIMIT = 10; 1668 private static final Name[][] INTERNED_ARGUMENTS 1669 = new Name[ARG_TYPE_LIMIT][INTERNED_ARGUMENT_LIMIT]; 1670 static { 1671 for (BasicType type : BasicType.ARG_TYPES) { 1672 int ord = type.ordinal(); 1673 for (int i = 0; i < INTERNED_ARGUMENTS[ord].length; i++) { 1674 INTERNED_ARGUMENTS[ord][i] = new Name(i, type); 1675 } 1676 } 1677 } 1678 1679 private static final MemberName.Factory IMPL_NAMES = MemberName.getFactory(); 1680 1681 static LambdaForm identityForm(BasicType type) { 1682 int ord = type.ordinal(); 1683 LambdaForm form = LF_identity[ord]; 1684 if (form != null) { 1685 return form; 1686 } 1687 createFormsFor(type); 1688 return LF_identity[ord]; 1689 } 1690 1691 static LambdaForm zeroForm(BasicType type) { 1692 int ord = type.ordinal(); 1693 LambdaForm form = LF_zero[ord]; 1694 if (form != null) { 1695 return form; 1696 } 1697 createFormsFor(type); 1698 return LF_zero[ord]; 1699 } 1700 1701 static NamedFunction identity(BasicType type) { 1702 int ord = type.ordinal(); 1703 NamedFunction function = NF_identity[ord]; 1704 if (function != null) { 1705 return function; 1706 } 1707 createFormsFor(type); 1708 return NF_identity[ord]; 1709 } 1710 1711 static NamedFunction constantZero(BasicType type) { 1712 int ord = type.ordinal(); 1713 NamedFunction function = NF_zero[ord]; 1714 if (function != null) { 1715 return function; 1716 } 1717 createFormsFor(type); 1718 return NF_zero[ord]; 1719 } 1720 1721 private static final @Stable LambdaForm[] LF_identity = new LambdaForm[TYPE_LIMIT]; 1722 private static final @Stable LambdaForm[] LF_zero = new LambdaForm[TYPE_LIMIT]; 1723 private static final @Stable NamedFunction[] NF_identity = new NamedFunction[TYPE_LIMIT]; 1724 private static final @Stable NamedFunction[] NF_zero = new NamedFunction[TYPE_LIMIT]; 1725 1726 private static final Object createFormsLock = new Object(); 1727 private static void createFormsFor(BasicType type) { 1728 // Avoid racy initialization during bootstrap 1729 UNSAFE.ensureClassInitialized(BoundMethodHandle.class); 1730 synchronized (createFormsLock) { 1731 final int ord = type.ordinal(); 1732 LambdaForm idForm = LF_identity[ord]; 1733 if (idForm != null) { 1734 return; 1735 } 1736 char btChar = type.basicTypeChar(); 1737 boolean isVoid = (type == V_TYPE); 1738 Class<?> btClass = type.btClass; 1739 MethodType zeType = MethodType.methodType(btClass); 1740 MethodType idType = (isVoid) ? zeType : MethodType.methodType(btClass, btClass); 1741 1742 // Look up symbolic names. It might not be necessary to have these, 1743 // but if we need to emit direct references to bytecodes, it helps. 1744 // Zero is built from a call to an identity function with a constant zero input. 1745 MemberName idMem = new MemberName(LambdaForm.class, "identity_"+btChar, idType, REF_invokeStatic); 1746 MemberName zeMem = null; 1747 try { 1748 idMem = IMPL_NAMES.resolveOrFail(REF_invokeStatic, idMem, null, LM_TRUSTED, NoSuchMethodException.class); 1749 if (!isVoid) { 1750 zeMem = new MemberName(LambdaForm.class, "zero_"+btChar, zeType, REF_invokeStatic); 1751 zeMem = IMPL_NAMES.resolveOrFail(REF_invokeStatic, zeMem, null, LM_TRUSTED, NoSuchMethodException.class); 1752 } 1753 } catch (IllegalAccessException|NoSuchMethodException ex) { 1754 throw newInternalError(ex); 1755 } 1756 1757 NamedFunction idFun; 1758 LambdaForm zeForm; 1759 NamedFunction zeFun; 1760 1761 // Create the LFs and NamedFunctions. Precompiling LFs to byte code is needed to break circular 1762 // bootstrap dependency on this method in case we're interpreting LFs 1763 if (isVoid) { 1764 Name[] idNames = new Name[] { argument(0, L_TYPE) }; 1765 idForm = LambdaForm.create(1, idNames, VOID_RESULT, Kind.IDENTITY); 1766 idForm.compileToBytecode(); 1767 idFun = new NamedFunction(idMem, SimpleMethodHandle.make(idMem.getInvocationType(), idForm)); 1768 1769 zeForm = idForm; 1770 zeFun = idFun; 1771 } else { 1772 Name[] idNames = new Name[] { argument(0, L_TYPE), argument(1, type) }; 1773 idForm = LambdaForm.create(2, idNames, 1, Kind.IDENTITY); 1774 idForm.compileToBytecode(); 1775 idFun = new NamedFunction(idMem, MethodHandleImpl.makeIntrinsic(SimpleMethodHandle.make(idMem.getInvocationType(), idForm), 1776 MethodHandleImpl.Intrinsic.IDENTITY)); 1777 1778 Object zeValue = Wrapper.forBasicType(btChar).zero(); 1779 Name[] zeNames = new Name[] { argument(0, L_TYPE), new Name(idFun, zeValue) }; 1780 zeForm = LambdaForm.create(1, zeNames, 1, Kind.ZERO); 1781 zeForm.compileToBytecode(); 1782 zeFun = new NamedFunction(zeMem, MethodHandleImpl.makeIntrinsic(SimpleMethodHandle.make(zeMem.getInvocationType(), zeForm), 1783 MethodHandleImpl.Intrinsic.ZERO)); 1784 } 1785 1786 LF_zero[ord] = zeForm; 1787 NF_zero[ord] = zeFun; 1788 LF_identity[ord] = idForm; 1789 NF_identity[ord] = idFun; 1790 1791 assert(idFun.isIdentity()); 1792 assert(zeFun.isConstantZero()); 1793 assert(new Name(zeFun).isConstantZero()); 1794 } 1795 } 1796 1797 // Avoid appealing to ValueConversions at bootstrap time: 1798 private static int identity_I(int x) { return x; } 1799 private static long identity_J(long x) { return x; } 1800 private static float identity_F(float x) { return x; } 1801 private static double identity_D(double x) { return x; } 1802 private static Object identity_L(Object x) { return x; } 1803 private static void identity_V() { return; } 1804 private static int zero_I() { return 0; } 1805 private static long zero_J() { return 0; } 1806 private static float zero_F() { return 0; } 1807 private static double zero_D() { return 0; } 1808 private static Object zero_L() { return null; } 1809 1810 /** 1811 * Internal marker for byte-compiled LambdaForms. 1812 */ 1813 /*non-public*/ 1814 @Target(ElementType.METHOD) 1815 @Retention(RetentionPolicy.RUNTIME) 1816 @interface Compiled { 1817 } 1818 1819 private static final HashMap<String,Integer> DEBUG_NAME_COUNTERS; 1820 private static final HashMap<LambdaForm,String> DEBUG_NAMES; 1821 static { 1822 if (debugEnabled()) { 1823 DEBUG_NAME_COUNTERS = new HashMap<>(); 1824 DEBUG_NAMES = new HashMap<>(); 1825 } else { 1826 DEBUG_NAME_COUNTERS = null; 1827 DEBUG_NAMES = null; 1828 } 1829 } 1830 1831 static { 1832 // The Holder class will contain pre-generated forms resolved 1833 // using MemberName.getFactory(). However, that doesn't initialize the 1834 // class, which subtly breaks inlining etc. By forcing 1835 // initialization of the Holder class we avoid these issues. 1836 UNSAFE.ensureClassInitialized(Holder.class); 1837 } 1838 1839 /* Placeholder class for zero and identity forms generated ahead of time */ 1840 final class Holder {} 1841 1842 // The following hack is necessary in order to suppress TRACE_INTERPRETER 1843 // during execution of the static initializes of this class. 1844 // Turning on TRACE_INTERPRETER too early will cause 1845 // stack overflows and other misbehavior during attempts to trace events 1846 // that occur during LambdaForm.<clinit>. 1847 // Therefore, do not move this line higher in this file, and do not remove. 1848 private static final boolean TRACE_INTERPRETER = MethodHandleStatics.TRACE_INTERPRETER; 1849 }