1 /* 2 * Copyright (c) 2002, 2011, 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. 8 * 9 * This code is distributed in the hope that it will be useful, but WITHOUT 10 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or 11 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License 12 * version 2 for more details (a copy is included in the LICENSE file that 13 * accompanied this code). 14 * 15 * You should have received a copy of the GNU General Public License version 16 * 2 along with this work; if not, write to the Free Software Foundation, 17 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. 18 * 19 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA 20 * or visit www.oracle.com if you need additional information or have any 21 * questions. 22 * 23 */ 24 25 // no precompiled headers 26 #include "classfile/vmSymbols.hpp" 27 #include "gc_interface/collectedHeap.hpp" 28 #include "interpreter/bytecodeHistogram.hpp" 29 #include "interpreter/bytecodeInterpreter.hpp" 30 #include "interpreter/bytecodeInterpreter.inline.hpp" 31 #include "interpreter/interpreter.hpp" 32 #include "interpreter/interpreterRuntime.hpp" 33 #include "memory/cardTableModRefBS.hpp" 34 #include "memory/resourceArea.hpp" 35 #include "oops/objArrayKlass.hpp" 36 #include "oops/oop.inline.hpp" 37 #include "prims/jvmtiExport.hpp" 38 #include "runtime/frame.inline.hpp" 39 #include "runtime/handles.inline.hpp" 40 #include "runtime/interfaceSupport.hpp" 41 #include "runtime/sharedRuntime.hpp" 42 #include "runtime/threadCritical.hpp" 43 #include "utilities/exceptions.hpp" 44 #ifdef TARGET_OS_ARCH_linux_x86 45 # include "orderAccess_linux_x86.inline.hpp" 46 #endif 47 #ifdef TARGET_OS_ARCH_linux_sparc 48 # include "orderAccess_linux_sparc.inline.hpp" 49 #endif 50 #ifdef TARGET_OS_ARCH_linux_zero 51 # include "orderAccess_linux_zero.inline.hpp" 52 #endif 53 #ifdef TARGET_OS_ARCH_solaris_x86 54 # include "orderAccess_solaris_x86.inline.hpp" 55 #endif 56 #ifdef TARGET_OS_ARCH_solaris_sparc 57 # include "orderAccess_solaris_sparc.inline.hpp" 58 #endif 59 #ifdef TARGET_OS_ARCH_windows_x86 60 # include "orderAccess_windows_x86.inline.hpp" 61 #endif 62 #ifdef TARGET_OS_ARCH_linux_arm 63 # include "orderAccess_linux_arm.inline.hpp" 64 #endif 65 #ifdef TARGET_OS_ARCH_linux_ppc 66 # include "orderAccess_linux_ppc.inline.hpp" 67 #endif 68 69 70 // no precompiled headers 71 #ifdef CC_INTERP 72 73 /* 74 * USELABELS - If using GCC, then use labels for the opcode dispatching 75 * rather -then a switch statement. This improves performance because it 76 * gives us the oportunity to have the instructions that calculate the 77 * next opcode to jump to be intermixed with the rest of the instructions 78 * that implement the opcode (see UPDATE_PC_AND_TOS_AND_CONTINUE macro). 79 */ 80 #undef USELABELS 81 #ifdef __GNUC__ 82 /* 83 ASSERT signifies debugging. It is much easier to step thru bytecodes if we 84 don't use the computed goto approach. 85 */ 86 #ifndef ASSERT 87 #define USELABELS 88 #endif 89 #endif 90 91 #undef CASE 92 #ifdef USELABELS 93 #define CASE(opcode) opc ## opcode 94 #define DEFAULT opc_default 95 #else 96 #define CASE(opcode) case Bytecodes:: opcode 97 #define DEFAULT default 98 #endif 99 100 /* 101 * PREFETCH_OPCCODE - Some compilers do better if you prefetch the next 102 * opcode before going back to the top of the while loop, rather then having 103 * the top of the while loop handle it. This provides a better opportunity 104 * for instruction scheduling. Some compilers just do this prefetch 105 * automatically. Some actually end up with worse performance if you 106 * force the prefetch. Solaris gcc seems to do better, but cc does worse. 107 */ 108 #undef PREFETCH_OPCCODE 109 #define PREFETCH_OPCCODE 110 111 /* 112 Interpreter safepoint: it is expected that the interpreter will have no live 113 handles of its own creation live at an interpreter safepoint. Therefore we 114 run a HandleMarkCleaner and trash all handles allocated in the call chain 115 since the JavaCalls::call_helper invocation that initiated the chain. 116 There really shouldn't be any handles remaining to trash but this is cheap 117 in relation to a safepoint. 118 */ 119 #define SAFEPOINT \ 120 if ( SafepointSynchronize::is_synchronizing()) { \ 121 { \ 122 /* zap freed handles rather than GC'ing them */ \ 123 HandleMarkCleaner __hmc(THREAD); \ 124 } \ 125 CALL_VM(SafepointSynchronize::block(THREAD), handle_exception); \ 126 } 127 128 /* 129 * VM_JAVA_ERROR - Macro for throwing a java exception from 130 * the interpreter loop. Should really be a CALL_VM but there 131 * is no entry point to do the transition to vm so we just 132 * do it by hand here. 133 */ 134 #define VM_JAVA_ERROR_NO_JUMP(name, msg) \ 135 DECACHE_STATE(); \ 136 SET_LAST_JAVA_FRAME(); \ 137 { \ 138 ThreadInVMfromJava trans(THREAD); \ 139 Exceptions::_throw_msg(THREAD, __FILE__, __LINE__, name, msg); \ 140 } \ 141 RESET_LAST_JAVA_FRAME(); \ 142 CACHE_STATE(); 143 144 // Normal throw of a java error 145 #define VM_JAVA_ERROR(name, msg) \ 146 VM_JAVA_ERROR_NO_JUMP(name, msg) \ 147 goto handle_exception; 148 149 #ifdef PRODUCT 150 #define DO_UPDATE_INSTRUCTION_COUNT(opcode) 151 #else 152 #define DO_UPDATE_INSTRUCTION_COUNT(opcode) \ 153 { \ 154 BytecodeCounter::_counter_value++; \ 155 BytecodeHistogram::_counters[(Bytecodes::Code)opcode]++; \ 156 if (StopInterpreterAt && StopInterpreterAt == BytecodeCounter::_counter_value) os::breakpoint(); \ 157 if (TraceBytecodes) { \ 158 CALL_VM((void)SharedRuntime::trace_bytecode(THREAD, 0, \ 159 topOfStack[Interpreter::expr_index_at(1)], \ 160 topOfStack[Interpreter::expr_index_at(2)]), \ 161 handle_exception); \ 162 } \ 163 } 164 #endif 165 166 #undef DEBUGGER_SINGLE_STEP_NOTIFY 167 #ifdef VM_JVMTI 168 /* NOTE: (kbr) This macro must be called AFTER the PC has been 169 incremented. JvmtiExport::at_single_stepping_point() may cause a 170 breakpoint opcode to get inserted at the current PC to allow the 171 debugger to coalesce single-step events. 172 173 As a result if we call at_single_stepping_point() we refetch opcode 174 to get the current opcode. This will override any other prefetching 175 that might have occurred. 176 */ 177 #define DEBUGGER_SINGLE_STEP_NOTIFY() \ 178 { \ 179 if (_jvmti_interp_events) { \ 180 if (JvmtiExport::should_post_single_step()) { \ 181 DECACHE_STATE(); \ 182 SET_LAST_JAVA_FRAME(); \ 183 ThreadInVMfromJava trans(THREAD); \ 184 JvmtiExport::at_single_stepping_point(THREAD, \ 185 istate->method(), \ 186 pc); \ 187 RESET_LAST_JAVA_FRAME(); \ 188 CACHE_STATE(); \ 189 if (THREAD->pop_frame_pending() && \ 190 !THREAD->pop_frame_in_process()) { \ 191 goto handle_Pop_Frame; \ 192 } \ 193 opcode = *pc; \ 194 } \ 195 } \ 196 } 197 #else 198 #define DEBUGGER_SINGLE_STEP_NOTIFY() 199 #endif 200 201 /* 202 * CONTINUE - Macro for executing the next opcode. 203 */ 204 #undef CONTINUE 205 #ifdef USELABELS 206 // Have to do this dispatch this way in C++ because otherwise gcc complains about crossing an 207 // initialization (which is is the initialization of the table pointer...) 208 #define DISPATCH(opcode) goto *(void*)dispatch_table[opcode] 209 #define CONTINUE { \ 210 opcode = *pc; \ 211 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 212 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 213 DISPATCH(opcode); \ 214 } 215 #else 216 #ifdef PREFETCH_OPCCODE 217 #define CONTINUE { \ 218 opcode = *pc; \ 219 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 220 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 221 continue; \ 222 } 223 #else 224 #define CONTINUE { \ 225 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 226 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 227 continue; \ 228 } 229 #endif 230 #endif 231 232 // JavaStack Implementation 233 #define MORE_STACK(count) \ 234 (topOfStack -= ((count) * Interpreter::stackElementWords)) 235 236 237 #define UPDATE_PC(opsize) {pc += opsize; } 238 /* 239 * UPDATE_PC_AND_TOS - Macro for updating the pc and topOfStack. 240 */ 241 #undef UPDATE_PC_AND_TOS 242 #define UPDATE_PC_AND_TOS(opsize, stack) \ 243 {pc += opsize; MORE_STACK(stack); } 244 245 /* 246 * UPDATE_PC_AND_TOS_AND_CONTINUE - Macro for updating the pc and topOfStack, 247 * and executing the next opcode. It's somewhat similar to the combination 248 * of UPDATE_PC_AND_TOS and CONTINUE, but with some minor optimizations. 249 */ 250 #undef UPDATE_PC_AND_TOS_AND_CONTINUE 251 #ifdef USELABELS 252 #define UPDATE_PC_AND_TOS_AND_CONTINUE(opsize, stack) { \ 253 pc += opsize; opcode = *pc; MORE_STACK(stack); \ 254 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 255 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 256 DISPATCH(opcode); \ 257 } 258 259 #define UPDATE_PC_AND_CONTINUE(opsize) { \ 260 pc += opsize; opcode = *pc; \ 261 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 262 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 263 DISPATCH(opcode); \ 264 } 265 #else 266 #ifdef PREFETCH_OPCCODE 267 #define UPDATE_PC_AND_TOS_AND_CONTINUE(opsize, stack) { \ 268 pc += opsize; opcode = *pc; MORE_STACK(stack); \ 269 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 270 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 271 goto do_continue; \ 272 } 273 274 #define UPDATE_PC_AND_CONTINUE(opsize) { \ 275 pc += opsize; opcode = *pc; \ 276 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 277 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 278 goto do_continue; \ 279 } 280 #else 281 #define UPDATE_PC_AND_TOS_AND_CONTINUE(opsize, stack) { \ 282 pc += opsize; MORE_STACK(stack); \ 283 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 284 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 285 goto do_continue; \ 286 } 287 288 #define UPDATE_PC_AND_CONTINUE(opsize) { \ 289 pc += opsize; \ 290 DO_UPDATE_INSTRUCTION_COUNT(opcode); \ 291 DEBUGGER_SINGLE_STEP_NOTIFY(); \ 292 goto do_continue; \ 293 } 294 #endif /* PREFETCH_OPCCODE */ 295 #endif /* USELABELS */ 296 297 // About to call a new method, update the save the adjusted pc and return to frame manager 298 #define UPDATE_PC_AND_RETURN(opsize) \ 299 DECACHE_TOS(); \ 300 istate->set_bcp(pc+opsize); \ 301 return; 302 303 304 #define METHOD istate->method() 305 #define INVOCATION_COUNT METHOD->invocation_counter() 306 #define BACKEDGE_COUNT METHOD->backedge_counter() 307 308 309 #define INCR_INVOCATION_COUNT INVOCATION_COUNT->increment() 310 #define OSR_REQUEST(res, branch_pc) \ 311 CALL_VM(res=InterpreterRuntime::frequency_counter_overflow(THREAD, branch_pc), handle_exception); 312 /* 313 * For those opcodes that need to have a GC point on a backwards branch 314 */ 315 316 // Backedge counting is kind of strange. The asm interpreter will increment 317 // the backedge counter as a separate counter but it does it's comparisons 318 // to the sum (scaled) of invocation counter and backedge count to make 319 // a decision. Seems kind of odd to sum them together like that 320 321 // skip is delta from current bcp/bci for target, branch_pc is pre-branch bcp 322 323 324 #define DO_BACKEDGE_CHECKS(skip, branch_pc) \ 325 if ((skip) <= 0) { \ 326 if (UseLoopCounter) { \ 327 bool do_OSR = UseOnStackReplacement; \ 328 BACKEDGE_COUNT->increment(); \ 329 if (do_OSR) do_OSR = BACKEDGE_COUNT->reached_InvocationLimit(); \ 330 if (do_OSR) { \ 331 nmethod* osr_nmethod; \ 332 OSR_REQUEST(osr_nmethod, branch_pc); \ 333 if (osr_nmethod != NULL && osr_nmethod->osr_entry_bci() != InvalidOSREntryBci) { \ 334 intptr_t* buf = SharedRuntime::OSR_migration_begin(THREAD); \ 335 istate->set_msg(do_osr); \ 336 istate->set_osr_buf((address)buf); \ 337 istate->set_osr_entry(osr_nmethod->osr_entry()); \ 338 return; \ 339 } \ 340 } \ 341 } /* UseCompiler ... */ \ 342 INCR_INVOCATION_COUNT; \ 343 SAFEPOINT; \ 344 } 345 346 /* 347 * For those opcodes that need to have a GC point on a backwards branch 348 */ 349 350 /* 351 * Macros for caching and flushing the interpreter state. Some local 352 * variables need to be flushed out to the frame before we do certain 353 * things (like pushing frames or becomming gc safe) and some need to 354 * be recached later (like after popping a frame). We could use one 355 * macro to cache or decache everything, but this would be less then 356 * optimal because we don't always need to cache or decache everything 357 * because some things we know are already cached or decached. 358 */ 359 #undef DECACHE_TOS 360 #undef CACHE_TOS 361 #undef CACHE_PREV_TOS 362 #define DECACHE_TOS() istate->set_stack(topOfStack); 363 364 #define CACHE_TOS() topOfStack = (intptr_t *)istate->stack(); 365 366 #undef DECACHE_PC 367 #undef CACHE_PC 368 #define DECACHE_PC() istate->set_bcp(pc); 369 #define CACHE_PC() pc = istate->bcp(); 370 #define CACHE_CP() cp = istate->constants(); 371 #define CACHE_LOCALS() locals = istate->locals(); 372 #undef CACHE_FRAME 373 #define CACHE_FRAME() 374 375 /* 376 * CHECK_NULL - Macro for throwing a NullPointerException if the object 377 * passed is a null ref. 378 * On some architectures/platforms it should be possible to do this implicitly 379 */ 380 #undef CHECK_NULL 381 #define CHECK_NULL(obj_) \ 382 if ((obj_) == NULL) { \ 383 VM_JAVA_ERROR(vmSymbols::java_lang_NullPointerException(), ""); \ 384 } \ 385 VERIFY_OOP(obj_) 386 387 #define VMdoubleConstZero() 0.0 388 #define VMdoubleConstOne() 1.0 389 #define VMlongConstZero() (max_jlong-max_jlong) 390 #define VMlongConstOne() ((max_jlong-max_jlong)+1) 391 392 /* 393 * Alignment 394 */ 395 #define VMalignWordUp(val) (((uintptr_t)(val) + 3) & ~3) 396 397 // Decache the interpreter state that interpreter modifies directly (i.e. GC is indirect mod) 398 #define DECACHE_STATE() DECACHE_PC(); DECACHE_TOS(); 399 400 // Reload interpreter state after calling the VM or a possible GC 401 #define CACHE_STATE() \ 402 CACHE_TOS(); \ 403 CACHE_PC(); \ 404 CACHE_CP(); \ 405 CACHE_LOCALS(); 406 407 // Call the VM don't check for pending exceptions 408 #define CALL_VM_NOCHECK(func) \ 409 DECACHE_STATE(); \ 410 SET_LAST_JAVA_FRAME(); \ 411 func; \ 412 RESET_LAST_JAVA_FRAME(); \ 413 CACHE_STATE(); \ 414 if (THREAD->pop_frame_pending() && \ 415 !THREAD->pop_frame_in_process()) { \ 416 goto handle_Pop_Frame; \ 417 } 418 419 // Call the VM and check for pending exceptions 420 #define CALL_VM(func, label) { \ 421 CALL_VM_NOCHECK(func); \ 422 if (THREAD->has_pending_exception()) goto label; \ 423 } 424 425 /* 426 * BytecodeInterpreter::run(interpreterState istate) 427 * BytecodeInterpreter::runWithChecks(interpreterState istate) 428 * 429 * The real deal. This is where byte codes actually get interpreted. 430 * Basically it's a big while loop that iterates until we return from 431 * the method passed in. 432 * 433 * The runWithChecks is used if JVMTI is enabled. 434 * 435 */ 436 #if defined(VM_JVMTI) 437 void 438 BytecodeInterpreter::runWithChecks(interpreterState istate) { 439 #else 440 void 441 BytecodeInterpreter::run(interpreterState istate) { 442 #endif 443 444 // In order to simplify some tests based on switches set at runtime 445 // we invoke the interpreter a single time after switches are enabled 446 // and set simpler to to test variables rather than method calls or complex 447 // boolean expressions. 448 449 static int initialized = 0; 450 static int checkit = 0; 451 static intptr_t* c_addr = NULL; 452 static intptr_t c_value; 453 454 if (checkit && *c_addr != c_value) { 455 os::breakpoint(); 456 } 457 #ifdef VM_JVMTI 458 static bool _jvmti_interp_events = 0; 459 #endif 460 461 static int _compiling; // (UseCompiler || CountCompiledCalls) 462 463 #ifdef ASSERT 464 if (istate->_msg != initialize) { 465 assert(abs(istate->_stack_base - istate->_stack_limit) == (istate->_method->max_stack() + 1), "bad stack limit"); 466 #ifndef SHARK 467 IA32_ONLY(assert(istate->_stack_limit == istate->_thread->last_Java_sp() + 1, "wrong")); 468 #endif // !SHARK 469 } 470 // Verify linkages. 471 interpreterState l = istate; 472 do { 473 assert(l == l->_self_link, "bad link"); 474 l = l->_prev_link; 475 } while (l != NULL); 476 // Screwups with stack management usually cause us to overwrite istate 477 // save a copy so we can verify it. 478 interpreterState orig = istate; 479 #endif 480 481 static volatile jbyte* _byte_map_base; // adjusted card table base for oop store barrier 482 483 register intptr_t* topOfStack = (intptr_t *)istate->stack(); /* access with STACK macros */ 484 register address pc = istate->bcp(); 485 register jubyte opcode; 486 register intptr_t* locals = istate->locals(); 487 register constantPoolCacheOop cp = istate->constants(); // method()->constants()->cache() 488 #ifdef LOTS_OF_REGS 489 register JavaThread* THREAD = istate->thread(); 490 register volatile jbyte* BYTE_MAP_BASE = _byte_map_base; 491 #else 492 #undef THREAD 493 #define THREAD istate->thread() 494 #undef BYTE_MAP_BASE 495 #define BYTE_MAP_BASE _byte_map_base 496 #endif 497 498 #ifdef USELABELS 499 const static void* const opclabels_data[256] = { 500 /* 0x00 */ &&opc_nop, &&opc_aconst_null,&&opc_iconst_m1,&&opc_iconst_0, 501 /* 0x04 */ &&opc_iconst_1,&&opc_iconst_2, &&opc_iconst_3, &&opc_iconst_4, 502 /* 0x08 */ &&opc_iconst_5,&&opc_lconst_0, &&opc_lconst_1, &&opc_fconst_0, 503 /* 0x0C */ &&opc_fconst_1,&&opc_fconst_2, &&opc_dconst_0, &&opc_dconst_1, 504 505 /* 0x10 */ &&opc_bipush, &&opc_sipush, &&opc_ldc, &&opc_ldc_w, 506 /* 0x14 */ &&opc_ldc2_w, &&opc_iload, &&opc_lload, &&opc_fload, 507 /* 0x18 */ &&opc_dload, &&opc_aload, &&opc_iload_0,&&opc_iload_1, 508 /* 0x1C */ &&opc_iload_2,&&opc_iload_3,&&opc_lload_0,&&opc_lload_1, 509 510 /* 0x20 */ &&opc_lload_2,&&opc_lload_3,&&opc_fload_0,&&opc_fload_1, 511 /* 0x24 */ &&opc_fload_2,&&opc_fload_3,&&opc_dload_0,&&opc_dload_1, 512 /* 0x28 */ &&opc_dload_2,&&opc_dload_3,&&opc_aload_0,&&opc_aload_1, 513 /* 0x2C */ &&opc_aload_2,&&opc_aload_3,&&opc_iaload, &&opc_laload, 514 515 /* 0x30 */ &&opc_faload, &&opc_daload, &&opc_aaload, &&opc_baload, 516 /* 0x34 */ &&opc_caload, &&opc_saload, &&opc_istore, &&opc_lstore, 517 /* 0x38 */ &&opc_fstore, &&opc_dstore, &&opc_astore, &&opc_istore_0, 518 /* 0x3C */ &&opc_istore_1,&&opc_istore_2,&&opc_istore_3,&&opc_lstore_0, 519 520 /* 0x40 */ &&opc_lstore_1,&&opc_lstore_2,&&opc_lstore_3,&&opc_fstore_0, 521 /* 0x44 */ &&opc_fstore_1,&&opc_fstore_2,&&opc_fstore_3,&&opc_dstore_0, 522 /* 0x48 */ &&opc_dstore_1,&&opc_dstore_2,&&opc_dstore_3,&&opc_astore_0, 523 /* 0x4C */ &&opc_astore_1,&&opc_astore_2,&&opc_astore_3,&&opc_iastore, 524 525 /* 0x50 */ &&opc_lastore,&&opc_fastore,&&opc_dastore,&&opc_aastore, 526 /* 0x54 */ &&opc_bastore,&&opc_castore,&&opc_sastore,&&opc_pop, 527 /* 0x58 */ &&opc_pop2, &&opc_dup, &&opc_dup_x1, &&opc_dup_x2, 528 /* 0x5C */ &&opc_dup2, &&opc_dup2_x1,&&opc_dup2_x2,&&opc_swap, 529 530 /* 0x60 */ &&opc_iadd,&&opc_ladd,&&opc_fadd,&&opc_dadd, 531 /* 0x64 */ &&opc_isub,&&opc_lsub,&&opc_fsub,&&opc_dsub, 532 /* 0x68 */ &&opc_imul,&&opc_lmul,&&opc_fmul,&&opc_dmul, 533 /* 0x6C */ &&opc_idiv,&&opc_ldiv,&&opc_fdiv,&&opc_ddiv, 534 535 /* 0x70 */ &&opc_irem, &&opc_lrem, &&opc_frem,&&opc_drem, 536 /* 0x74 */ &&opc_ineg, &&opc_lneg, &&opc_fneg,&&opc_dneg, 537 /* 0x78 */ &&opc_ishl, &&opc_lshl, &&opc_ishr,&&opc_lshr, 538 /* 0x7C */ &&opc_iushr,&&opc_lushr,&&opc_iand,&&opc_land, 539 540 /* 0x80 */ &&opc_ior, &&opc_lor,&&opc_ixor,&&opc_lxor, 541 /* 0x84 */ &&opc_iinc,&&opc_i2l,&&opc_i2f, &&opc_i2d, 542 /* 0x88 */ &&opc_l2i, &&opc_l2f,&&opc_l2d, &&opc_f2i, 543 /* 0x8C */ &&opc_f2l, &&opc_f2d,&&opc_d2i, &&opc_d2l, 544 545 /* 0x90 */ &&opc_d2f, &&opc_i2b, &&opc_i2c, &&opc_i2s, 546 /* 0x94 */ &&opc_lcmp, &&opc_fcmpl,&&opc_fcmpg,&&opc_dcmpl, 547 /* 0x98 */ &&opc_dcmpg,&&opc_ifeq, &&opc_ifne, &&opc_iflt, 548 /* 0x9C */ &&opc_ifge, &&opc_ifgt, &&opc_ifle, &&opc_if_icmpeq, 549 550 /* 0xA0 */ &&opc_if_icmpne,&&opc_if_icmplt,&&opc_if_icmpge, &&opc_if_icmpgt, 551 /* 0xA4 */ &&opc_if_icmple,&&opc_if_acmpeq,&&opc_if_acmpne, &&opc_goto, 552 /* 0xA8 */ &&opc_jsr, &&opc_ret, &&opc_tableswitch,&&opc_lookupswitch, 553 /* 0xAC */ &&opc_ireturn, &&opc_lreturn, &&opc_freturn, &&opc_dreturn, 554 555 /* 0xB0 */ &&opc_areturn, &&opc_return, &&opc_getstatic, &&opc_putstatic, 556 /* 0xB4 */ &&opc_getfield, &&opc_putfield, &&opc_invokevirtual,&&opc_invokespecial, 557 /* 0xB8 */ &&opc_invokestatic,&&opc_invokeinterface,&&opc_invokedynamic,&&opc_new, 558 /* 0xBC */ &&opc_newarray, &&opc_anewarray, &&opc_arraylength, &&opc_athrow, 559 560 /* 0xC0 */ &&opc_checkcast, &&opc_instanceof, &&opc_monitorenter, &&opc_monitorexit, 561 /* 0xC4 */ &&opc_wide, &&opc_multianewarray, &&opc_ifnull, &&opc_ifnonnull, 562 /* 0xC8 */ &&opc_goto_w, &&opc_jsr_w, &&opc_breakpoint, &&opc_default, 563 /* 0xCC */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 564 565 /* 0xD0 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 566 /* 0xD4 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 567 /* 0xD8 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 568 /* 0xDC */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 569 570 /* 0xE0 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 571 /* 0xE4 */ &&opc_default, &&opc_fast_aldc, &&opc_fast_aldc_w, &&opc_return_register_finalizer, 572 /* 0xE8 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 573 /* 0xEC */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 574 575 /* 0xF0 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 576 /* 0xF4 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 577 /* 0xF8 */ &&opc_default, &&opc_default, &&opc_default, &&opc_default, 578 /* 0xFC */ &&opc_default, &&opc_default, &&opc_default, &&opc_default 579 }; 580 register uintptr_t *dispatch_table = (uintptr_t*)&opclabels_data[0]; 581 #endif /* USELABELS */ 582 583 #ifdef ASSERT 584 // this will trigger a VERIFY_OOP on entry 585 if (istate->msg() != initialize && ! METHOD->is_static()) { 586 oop rcvr = LOCALS_OBJECT(0); 587 VERIFY_OOP(rcvr); 588 } 589 #endif 590 // #define HACK 591 #ifdef HACK 592 bool interesting = false; 593 #endif // HACK 594 595 /* QQQ this should be a stack method so we don't know actual direction */ 596 guarantee(istate->msg() == initialize || 597 topOfStack >= istate->stack_limit() && 598 topOfStack < istate->stack_base(), 599 "Stack top out of range"); 600 601 switch (istate->msg()) { 602 case initialize: { 603 if (initialized++) ShouldNotReachHere(); // Only one initialize call 604 _compiling = (UseCompiler || CountCompiledCalls); 605 #ifdef VM_JVMTI 606 _jvmti_interp_events = JvmtiExport::can_post_interpreter_events(); 607 #endif 608 BarrierSet* bs = Universe::heap()->barrier_set(); 609 assert(bs->kind() == BarrierSet::CardTableModRef, "Wrong barrier set kind"); 610 _byte_map_base = (volatile jbyte*)(((CardTableModRefBS*)bs)->byte_map_base); 611 return; 612 } 613 break; 614 case method_entry: { 615 THREAD->set_do_not_unlock(); 616 // count invocations 617 assert(initialized, "Interpreter not initialized"); 618 if (_compiling) { 619 if (ProfileInterpreter) { 620 METHOD->increment_interpreter_invocation_count(); 621 } 622 INCR_INVOCATION_COUNT; 623 if (INVOCATION_COUNT->reached_InvocationLimit()) { 624 CALL_VM((void)InterpreterRuntime::frequency_counter_overflow(THREAD, NULL), handle_exception); 625 626 // We no longer retry on a counter overflow 627 628 // istate->set_msg(retry_method); 629 // THREAD->clr_do_not_unlock(); 630 // return; 631 } 632 SAFEPOINT; 633 } 634 635 if ((istate->_stack_base - istate->_stack_limit) != istate->method()->max_stack() + 1) { 636 // initialize 637 os::breakpoint(); 638 } 639 640 #ifdef HACK 641 { 642 ResourceMark rm; 643 char *method_name = istate->method()->name_and_sig_as_C_string(); 644 if (strstr(method_name, "runThese$TestRunner.run()V") != NULL) { 645 tty->print_cr("entering: depth %d bci: %d", 646 (istate->_stack_base - istate->_stack), 647 istate->_bcp - istate->_method->code_base()); 648 interesting = true; 649 } 650 } 651 #endif // HACK 652 653 654 // lock method if synchronized 655 if (METHOD->is_synchronized()) { 656 // oop rcvr = locals[0].j.r; 657 oop rcvr; 658 if (METHOD->is_static()) { 659 rcvr = METHOD->constants()->pool_holder()->java_mirror(); 660 } else { 661 rcvr = LOCALS_OBJECT(0); 662 VERIFY_OOP(rcvr); 663 } 664 // The initial monitor is ours for the taking 665 BasicObjectLock* mon = &istate->monitor_base()[-1]; 666 oop monobj = mon->obj(); 667 assert(mon->obj() == rcvr, "method monitor mis-initialized"); 668 669 bool success = UseBiasedLocking; 670 if (UseBiasedLocking) { 671 markOop mark = rcvr->mark(); 672 if (mark->has_bias_pattern()) { 673 // The bias pattern is present in the object's header. Need to check 674 // whether the bias owner and the epoch are both still current. 675 intptr_t xx = ((intptr_t) THREAD) ^ (intptr_t) mark; 676 xx = (intptr_t) rcvr->klass()->klass_part()->prototype_header() ^ xx; 677 intptr_t yy = (xx & ~((int) markOopDesc::age_mask_in_place)); 678 if (yy != 0 ) { 679 // At this point we know that the header has the bias pattern and 680 // that we are not the bias owner in the current epoch. We need to 681 // figure out more details about the state of the header in order to 682 // know what operations can be legally performed on the object's 683 // header. 684 685 // If the low three bits in the xor result aren't clear, that means 686 // the prototype header is no longer biased and we have to revoke 687 // the bias on this object. 688 689 if (yy & markOopDesc::biased_lock_mask_in_place == 0 ) { 690 // Biasing is still enabled for this data type. See whether the 691 // epoch of the current bias is still valid, meaning that the epoch 692 // bits of the mark word are equal to the epoch bits of the 693 // prototype header. (Note that the prototype header's epoch bits 694 // only change at a safepoint.) If not, attempt to rebias the object 695 // toward the current thread. Note that we must be absolutely sure 696 // that the current epoch is invalid in order to do this because 697 // otherwise the manipulations it performs on the mark word are 698 // illegal. 699 if (yy & markOopDesc::epoch_mask_in_place == 0) { 700 // The epoch of the current bias is still valid but we know nothing 701 // about the owner; it might be set or it might be clear. Try to 702 // acquire the bias of the object using an atomic operation. If this 703 // fails we will go in to the runtime to revoke the object's bias. 704 // Note that we first construct the presumed unbiased header so we 705 // don't accidentally blow away another thread's valid bias. 706 intptr_t unbiased = (intptr_t) mark & (markOopDesc::biased_lock_mask_in_place | 707 markOopDesc::age_mask_in_place | 708 markOopDesc::epoch_mask_in_place); 709 if (Atomic::cmpxchg_ptr((intptr_t)THREAD | unbiased, (intptr_t*) rcvr->mark_addr(), unbiased) != unbiased) { 710 CALL_VM(InterpreterRuntime::monitorenter(THREAD, mon), handle_exception); 711 } 712 } else { 713 try_rebias: 714 // At this point we know the epoch has expired, meaning that the 715 // current "bias owner", if any, is actually invalid. Under these 716 // circumstances _only_, we are allowed to use the current header's 717 // value as the comparison value when doing the cas to acquire the 718 // bias in the current epoch. In other words, we allow transfer of 719 // the bias from one thread to another directly in this situation. 720 xx = (intptr_t) rcvr->klass()->klass_part()->prototype_header() | (intptr_t) THREAD; 721 if (Atomic::cmpxchg_ptr((intptr_t)THREAD | (intptr_t) rcvr->klass()->klass_part()->prototype_header(), 722 (intptr_t*) rcvr->mark_addr(), 723 (intptr_t) mark) != (intptr_t) mark) { 724 CALL_VM(InterpreterRuntime::monitorenter(THREAD, mon), handle_exception); 725 } 726 } 727 } else { 728 try_revoke_bias: 729 // The prototype mark in the klass doesn't have the bias bit set any 730 // more, indicating that objects of this data type are not supposed 731 // to be biased any more. We are going to try to reset the mark of 732 // this object to the prototype value and fall through to the 733 // CAS-based locking scheme. Note that if our CAS fails, it means 734 // that another thread raced us for the privilege of revoking the 735 // bias of this particular object, so it's okay to continue in the 736 // normal locking code. 737 // 738 xx = (intptr_t) rcvr->klass()->klass_part()->prototype_header() | (intptr_t) THREAD; 739 if (Atomic::cmpxchg_ptr(rcvr->klass()->klass_part()->prototype_header(), 740 (intptr_t*) rcvr->mark_addr(), 741 mark) == mark) { 742 // (*counters->revoked_lock_entry_count_addr())++; 743 success = false; 744 } 745 } 746 } 747 } else { 748 cas_label: 749 success = false; 750 } 751 } 752 if (!success) { 753 markOop displaced = rcvr->mark()->set_unlocked(); 754 mon->lock()->set_displaced_header(displaced); 755 if (Atomic::cmpxchg_ptr(mon, rcvr->mark_addr(), displaced) != displaced) { 756 // Is it simple recursive case? 757 if (THREAD->is_lock_owned((address) displaced->clear_lock_bits())) { 758 mon->lock()->set_displaced_header(NULL); 759 } else { 760 CALL_VM(InterpreterRuntime::monitorenter(THREAD, mon), handle_exception); 761 } 762 } 763 } 764 } 765 THREAD->clr_do_not_unlock(); 766 767 // Notify jvmti 768 #ifdef VM_JVMTI 769 if (_jvmti_interp_events) { 770 // Whenever JVMTI puts a thread in interp_only_mode, method 771 // entry/exit events are sent for that thread to track stack depth. 772 if (THREAD->is_interp_only_mode()) { 773 CALL_VM(InterpreterRuntime::post_method_entry(THREAD), 774 handle_exception); 775 } 776 } 777 #endif /* VM_JVMTI */ 778 779 goto run; 780 } 781 782 case popping_frame: { 783 // returned from a java call to pop the frame, restart the call 784 // clear the message so we don't confuse ourselves later 785 ShouldNotReachHere(); // we don't return this. 786 assert(THREAD->pop_frame_in_process(), "wrong frame pop state"); 787 istate->set_msg(no_request); 788 THREAD->clr_pop_frame_in_process(); 789 goto run; 790 } 791 792 case method_resume: { 793 if ((istate->_stack_base - istate->_stack_limit) != istate->method()->max_stack() + 1) { 794 // resume 795 os::breakpoint(); 796 } 797 #ifdef HACK 798 { 799 ResourceMark rm; 800 char *method_name = istate->method()->name_and_sig_as_C_string(); 801 if (strstr(method_name, "runThese$TestRunner.run()V") != NULL) { 802 tty->print_cr("resume: depth %d bci: %d", 803 (istate->_stack_base - istate->_stack) , 804 istate->_bcp - istate->_method->code_base()); 805 interesting = true; 806 } 807 } 808 #endif // HACK 809 // returned from a java call, continue executing. 810 if (THREAD->pop_frame_pending() && !THREAD->pop_frame_in_process()) { 811 goto handle_Pop_Frame; 812 } 813 814 if (THREAD->has_pending_exception()) goto handle_exception; 815 // Update the pc by the saved amount of the invoke bytecode size 816 UPDATE_PC(istate->bcp_advance()); 817 goto run; 818 } 819 820 case deopt_resume2: { 821 // Returned from an opcode that will reexecute. Deopt was 822 // a result of a PopFrame request. 823 // 824 goto run; 825 } 826 827 case deopt_resume: { 828 // Returned from an opcode that has completed. The stack has 829 // the result all we need to do is skip across the bytecode 830 // and continue (assuming there is no exception pending) 831 // 832 // compute continuation length 833 // 834 // Note: it is possible to deopt at a return_register_finalizer opcode 835 // because this requires entering the vm to do the registering. While the 836 // opcode is complete we can't advance because there are no more opcodes 837 // much like trying to deopt at a poll return. In that has we simply 838 // get out of here 839 // 840 if ( Bytecodes::code_at(METHOD, pc) == Bytecodes::_return_register_finalizer) { 841 // this will do the right thing even if an exception is pending. 842 goto handle_return; 843 } 844 UPDATE_PC(Bytecodes::length_at(METHOD, pc)); 845 if (THREAD->has_pending_exception()) goto handle_exception; 846 goto run; 847 } 848 case got_monitors: { 849 // continue locking now that we have a monitor to use 850 // we expect to find newly allocated monitor at the "top" of the monitor stack. 851 oop lockee = STACK_OBJECT(-1); 852 VERIFY_OOP(lockee); 853 // derefing's lockee ought to provoke implicit null check 854 // find a free monitor 855 BasicObjectLock* entry = (BasicObjectLock*) istate->stack_base(); 856 assert(entry->obj() == NULL, "Frame manager didn't allocate the monitor"); 857 entry->set_obj(lockee); 858 859 markOop displaced = lockee->mark()->set_unlocked(); 860 entry->lock()->set_displaced_header(displaced); 861 if (Atomic::cmpxchg_ptr(entry, lockee->mark_addr(), displaced) != displaced) { 862 // Is it simple recursive case? 863 if (THREAD->is_lock_owned((address) displaced->clear_lock_bits())) { 864 entry->lock()->set_displaced_header(NULL); 865 } else { 866 CALL_VM(InterpreterRuntime::monitorenter(THREAD, entry), handle_exception); 867 } 868 } 869 UPDATE_PC_AND_TOS(1, -1); 870 goto run; 871 } 872 default: { 873 fatal("Unexpected message from frame manager"); 874 } 875 } 876 877 run: 878 879 DO_UPDATE_INSTRUCTION_COUNT(*pc) 880 DEBUGGER_SINGLE_STEP_NOTIFY(); 881 #ifdef PREFETCH_OPCCODE 882 opcode = *pc; /* prefetch first opcode */ 883 #endif 884 885 #ifndef USELABELS 886 while (1) 887 #endif 888 { 889 #ifndef PREFETCH_OPCCODE 890 opcode = *pc; 891 #endif 892 // Seems like this happens twice per opcode. At worst this is only 893 // need at entry to the loop. 894 // DEBUGGER_SINGLE_STEP_NOTIFY(); 895 /* Using this labels avoids double breakpoints when quickening and 896 * when returing from transition frames. 897 */ 898 opcode_switch: 899 assert(istate == orig, "Corrupted istate"); 900 /* QQQ Hmm this has knowledge of direction, ought to be a stack method */ 901 assert(topOfStack >= istate->stack_limit(), "Stack overrun"); 902 assert(topOfStack < istate->stack_base(), "Stack underrun"); 903 904 #ifdef USELABELS 905 DISPATCH(opcode); 906 #else 907 switch (opcode) 908 #endif 909 { 910 CASE(_nop): 911 UPDATE_PC_AND_CONTINUE(1); 912 913 /* Push miscellaneous constants onto the stack. */ 914 915 CASE(_aconst_null): 916 SET_STACK_OBJECT(NULL, 0); 917 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 918 919 #undef OPC_CONST_n 920 #define OPC_CONST_n(opcode, const_type, value) \ 921 CASE(opcode): \ 922 SET_STACK_ ## const_type(value, 0); \ 923 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 924 925 OPC_CONST_n(_iconst_m1, INT, -1); 926 OPC_CONST_n(_iconst_0, INT, 0); 927 OPC_CONST_n(_iconst_1, INT, 1); 928 OPC_CONST_n(_iconst_2, INT, 2); 929 OPC_CONST_n(_iconst_3, INT, 3); 930 OPC_CONST_n(_iconst_4, INT, 4); 931 OPC_CONST_n(_iconst_5, INT, 5); 932 OPC_CONST_n(_fconst_0, FLOAT, 0.0); 933 OPC_CONST_n(_fconst_1, FLOAT, 1.0); 934 OPC_CONST_n(_fconst_2, FLOAT, 2.0); 935 936 #undef OPC_CONST2_n 937 #define OPC_CONST2_n(opcname, value, key, kind) \ 938 CASE(_##opcname): \ 939 { \ 940 SET_STACK_ ## kind(VM##key##Const##value(), 1); \ 941 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); \ 942 } 943 OPC_CONST2_n(dconst_0, Zero, double, DOUBLE); 944 OPC_CONST2_n(dconst_1, One, double, DOUBLE); 945 OPC_CONST2_n(lconst_0, Zero, long, LONG); 946 OPC_CONST2_n(lconst_1, One, long, LONG); 947 948 /* Load constant from constant pool: */ 949 950 /* Push a 1-byte signed integer value onto the stack. */ 951 CASE(_bipush): 952 SET_STACK_INT((jbyte)(pc[1]), 0); 953 UPDATE_PC_AND_TOS_AND_CONTINUE(2, 1); 954 955 /* Push a 2-byte signed integer constant onto the stack. */ 956 CASE(_sipush): 957 SET_STACK_INT((int16_t)Bytes::get_Java_u2(pc + 1), 0); 958 UPDATE_PC_AND_TOS_AND_CONTINUE(3, 1); 959 960 /* load from local variable */ 961 962 CASE(_aload): 963 VERIFY_OOP(LOCALS_OBJECT(pc[1])); 964 SET_STACK_OBJECT(LOCALS_OBJECT(pc[1]), 0); 965 UPDATE_PC_AND_TOS_AND_CONTINUE(2, 1); 966 967 CASE(_iload): 968 CASE(_fload): 969 SET_STACK_SLOT(LOCALS_SLOT(pc[1]), 0); 970 UPDATE_PC_AND_TOS_AND_CONTINUE(2, 1); 971 972 CASE(_lload): 973 SET_STACK_LONG_FROM_ADDR(LOCALS_LONG_AT(pc[1]), 1); 974 UPDATE_PC_AND_TOS_AND_CONTINUE(2, 2); 975 976 CASE(_dload): 977 SET_STACK_DOUBLE_FROM_ADDR(LOCALS_DOUBLE_AT(pc[1]), 1); 978 UPDATE_PC_AND_TOS_AND_CONTINUE(2, 2); 979 980 #undef OPC_LOAD_n 981 #define OPC_LOAD_n(num) \ 982 CASE(_aload_##num): \ 983 VERIFY_OOP(LOCALS_OBJECT(num)); \ 984 SET_STACK_OBJECT(LOCALS_OBJECT(num), 0); \ 985 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); \ 986 \ 987 CASE(_iload_##num): \ 988 CASE(_fload_##num): \ 989 SET_STACK_SLOT(LOCALS_SLOT(num), 0); \ 990 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); \ 991 \ 992 CASE(_lload_##num): \ 993 SET_STACK_LONG_FROM_ADDR(LOCALS_LONG_AT(num), 1); \ 994 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); \ 995 CASE(_dload_##num): \ 996 SET_STACK_DOUBLE_FROM_ADDR(LOCALS_DOUBLE_AT(num), 1); \ 997 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 998 999 OPC_LOAD_n(0); 1000 OPC_LOAD_n(1); 1001 OPC_LOAD_n(2); 1002 OPC_LOAD_n(3); 1003 1004 /* store to a local variable */ 1005 1006 CASE(_astore): 1007 astore(topOfStack, -1, locals, pc[1]); 1008 UPDATE_PC_AND_TOS_AND_CONTINUE(2, -1); 1009 1010 CASE(_istore): 1011 CASE(_fstore): 1012 SET_LOCALS_SLOT(STACK_SLOT(-1), pc[1]); 1013 UPDATE_PC_AND_TOS_AND_CONTINUE(2, -1); 1014 1015 CASE(_lstore): 1016 SET_LOCALS_LONG(STACK_LONG(-1), pc[1]); 1017 UPDATE_PC_AND_TOS_AND_CONTINUE(2, -2); 1018 1019 CASE(_dstore): 1020 SET_LOCALS_DOUBLE(STACK_DOUBLE(-1), pc[1]); 1021 UPDATE_PC_AND_TOS_AND_CONTINUE(2, -2); 1022 1023 CASE(_wide): { 1024 uint16_t reg = Bytes::get_Java_u2(pc + 2); 1025 1026 opcode = pc[1]; 1027 switch(opcode) { 1028 case Bytecodes::_aload: 1029 VERIFY_OOP(LOCALS_OBJECT(reg)); 1030 SET_STACK_OBJECT(LOCALS_OBJECT(reg), 0); 1031 UPDATE_PC_AND_TOS_AND_CONTINUE(4, 1); 1032 1033 case Bytecodes::_iload: 1034 case Bytecodes::_fload: 1035 SET_STACK_SLOT(LOCALS_SLOT(reg), 0); 1036 UPDATE_PC_AND_TOS_AND_CONTINUE(4, 1); 1037 1038 case Bytecodes::_lload: 1039 SET_STACK_LONG_FROM_ADDR(LOCALS_LONG_AT(reg), 1); 1040 UPDATE_PC_AND_TOS_AND_CONTINUE(4, 2); 1041 1042 case Bytecodes::_dload: 1043 SET_STACK_DOUBLE_FROM_ADDR(LOCALS_LONG_AT(reg), 1); 1044 UPDATE_PC_AND_TOS_AND_CONTINUE(4, 2); 1045 1046 case Bytecodes::_astore: 1047 astore(topOfStack, -1, locals, reg); 1048 UPDATE_PC_AND_TOS_AND_CONTINUE(4, -1); 1049 1050 case Bytecodes::_istore: 1051 case Bytecodes::_fstore: 1052 SET_LOCALS_SLOT(STACK_SLOT(-1), reg); 1053 UPDATE_PC_AND_TOS_AND_CONTINUE(4, -1); 1054 1055 case Bytecodes::_lstore: 1056 SET_LOCALS_LONG(STACK_LONG(-1), reg); 1057 UPDATE_PC_AND_TOS_AND_CONTINUE(4, -2); 1058 1059 case Bytecodes::_dstore: 1060 SET_LOCALS_DOUBLE(STACK_DOUBLE(-1), reg); 1061 UPDATE_PC_AND_TOS_AND_CONTINUE(4, -2); 1062 1063 case Bytecodes::_iinc: { 1064 int16_t offset = (int16_t)Bytes::get_Java_u2(pc+4); 1065 // Be nice to see what this generates.... QQQ 1066 SET_LOCALS_INT(LOCALS_INT(reg) + offset, reg); 1067 UPDATE_PC_AND_CONTINUE(6); 1068 } 1069 case Bytecodes::_ret: 1070 pc = istate->method()->code_base() + (intptr_t)(LOCALS_ADDR(reg)); 1071 UPDATE_PC_AND_CONTINUE(0); 1072 default: 1073 VM_JAVA_ERROR(vmSymbols::java_lang_InternalError(), "undefined opcode"); 1074 } 1075 } 1076 1077 1078 #undef OPC_STORE_n 1079 #define OPC_STORE_n(num) \ 1080 CASE(_astore_##num): \ 1081 astore(topOfStack, -1, locals, num); \ 1082 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); \ 1083 CASE(_istore_##num): \ 1084 CASE(_fstore_##num): \ 1085 SET_LOCALS_SLOT(STACK_SLOT(-1), num); \ 1086 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); 1087 1088 OPC_STORE_n(0); 1089 OPC_STORE_n(1); 1090 OPC_STORE_n(2); 1091 OPC_STORE_n(3); 1092 1093 #undef OPC_DSTORE_n 1094 #define OPC_DSTORE_n(num) \ 1095 CASE(_dstore_##num): \ 1096 SET_LOCALS_DOUBLE(STACK_DOUBLE(-1), num); \ 1097 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -2); \ 1098 CASE(_lstore_##num): \ 1099 SET_LOCALS_LONG(STACK_LONG(-1), num); \ 1100 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -2); 1101 1102 OPC_DSTORE_n(0); 1103 OPC_DSTORE_n(1); 1104 OPC_DSTORE_n(2); 1105 OPC_DSTORE_n(3); 1106 1107 /* stack pop, dup, and insert opcodes */ 1108 1109 1110 CASE(_pop): /* Discard the top item on the stack */ 1111 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); 1112 1113 1114 CASE(_pop2): /* Discard the top 2 items on the stack */ 1115 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -2); 1116 1117 1118 CASE(_dup): /* Duplicate the top item on the stack */ 1119 dup(topOfStack); 1120 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1121 1122 CASE(_dup2): /* Duplicate the top 2 items on the stack */ 1123 dup2(topOfStack); 1124 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1125 1126 CASE(_dup_x1): /* insert top word two down */ 1127 dup_x1(topOfStack); 1128 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1129 1130 CASE(_dup_x2): /* insert top word three down */ 1131 dup_x2(topOfStack); 1132 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1133 1134 CASE(_dup2_x1): /* insert top 2 slots three down */ 1135 dup2_x1(topOfStack); 1136 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1137 1138 CASE(_dup2_x2): /* insert top 2 slots four down */ 1139 dup2_x2(topOfStack); 1140 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1141 1142 CASE(_swap): { /* swap top two elements on the stack */ 1143 swap(topOfStack); 1144 UPDATE_PC_AND_CONTINUE(1); 1145 } 1146 1147 /* Perform various binary integer operations */ 1148 1149 #undef OPC_INT_BINARY 1150 #define OPC_INT_BINARY(opcname, opname, test) \ 1151 CASE(_i##opcname): \ 1152 if (test && (STACK_INT(-1) == 0)) { \ 1153 VM_JAVA_ERROR(vmSymbols::java_lang_ArithmeticException(), \ 1154 "/ by zero"); \ 1155 } \ 1156 SET_STACK_INT(VMint##opname(STACK_INT(-2), \ 1157 STACK_INT(-1)), \ 1158 -2); \ 1159 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); \ 1160 CASE(_l##opcname): \ 1161 { \ 1162 if (test) { \ 1163 jlong l1 = STACK_LONG(-1); \ 1164 if (VMlongEqz(l1)) { \ 1165 VM_JAVA_ERROR(vmSymbols::java_lang_ArithmeticException(), \ 1166 "/ by long zero"); \ 1167 } \ 1168 } \ 1169 /* First long at (-1,-2) next long at (-3,-4) */ \ 1170 SET_STACK_LONG(VMlong##opname(STACK_LONG(-3), \ 1171 STACK_LONG(-1)), \ 1172 -3); \ 1173 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -2); \ 1174 } 1175 1176 OPC_INT_BINARY(add, Add, 0); 1177 OPC_INT_BINARY(sub, Sub, 0); 1178 OPC_INT_BINARY(mul, Mul, 0); 1179 OPC_INT_BINARY(and, And, 0); 1180 OPC_INT_BINARY(or, Or, 0); 1181 OPC_INT_BINARY(xor, Xor, 0); 1182 OPC_INT_BINARY(div, Div, 1); 1183 OPC_INT_BINARY(rem, Rem, 1); 1184 1185 1186 /* Perform various binary floating number operations */ 1187 /* On some machine/platforms/compilers div zero check can be implicit */ 1188 1189 #undef OPC_FLOAT_BINARY 1190 #define OPC_FLOAT_BINARY(opcname, opname) \ 1191 CASE(_d##opcname): { \ 1192 SET_STACK_DOUBLE(VMdouble##opname(STACK_DOUBLE(-3), \ 1193 STACK_DOUBLE(-1)), \ 1194 -3); \ 1195 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -2); \ 1196 } \ 1197 CASE(_f##opcname): \ 1198 SET_STACK_FLOAT(VMfloat##opname(STACK_FLOAT(-2), \ 1199 STACK_FLOAT(-1)), \ 1200 -2); \ 1201 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); 1202 1203 1204 OPC_FLOAT_BINARY(add, Add); 1205 OPC_FLOAT_BINARY(sub, Sub); 1206 OPC_FLOAT_BINARY(mul, Mul); 1207 OPC_FLOAT_BINARY(div, Div); 1208 OPC_FLOAT_BINARY(rem, Rem); 1209 1210 /* Shift operations 1211 * Shift left int and long: ishl, lshl 1212 * Logical shift right int and long w/zero extension: iushr, lushr 1213 * Arithmetic shift right int and long w/sign extension: ishr, lshr 1214 */ 1215 1216 #undef OPC_SHIFT_BINARY 1217 #define OPC_SHIFT_BINARY(opcname, opname) \ 1218 CASE(_i##opcname): \ 1219 SET_STACK_INT(VMint##opname(STACK_INT(-2), \ 1220 STACK_INT(-1)), \ 1221 -2); \ 1222 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); \ 1223 CASE(_l##opcname): \ 1224 { \ 1225 SET_STACK_LONG(VMlong##opname(STACK_LONG(-2), \ 1226 STACK_INT(-1)), \ 1227 -2); \ 1228 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); \ 1229 } 1230 1231 OPC_SHIFT_BINARY(shl, Shl); 1232 OPC_SHIFT_BINARY(shr, Shr); 1233 OPC_SHIFT_BINARY(ushr, Ushr); 1234 1235 /* Increment local variable by constant */ 1236 CASE(_iinc): 1237 { 1238 // locals[pc[1]].j.i += (jbyte)(pc[2]); 1239 SET_LOCALS_INT(LOCALS_INT(pc[1]) + (jbyte)(pc[2]), pc[1]); 1240 UPDATE_PC_AND_CONTINUE(3); 1241 } 1242 1243 /* negate the value on the top of the stack */ 1244 1245 CASE(_ineg): 1246 SET_STACK_INT(VMintNeg(STACK_INT(-1)), -1); 1247 UPDATE_PC_AND_CONTINUE(1); 1248 1249 CASE(_fneg): 1250 SET_STACK_FLOAT(VMfloatNeg(STACK_FLOAT(-1)), -1); 1251 UPDATE_PC_AND_CONTINUE(1); 1252 1253 CASE(_lneg): 1254 { 1255 SET_STACK_LONG(VMlongNeg(STACK_LONG(-1)), -1); 1256 UPDATE_PC_AND_CONTINUE(1); 1257 } 1258 1259 CASE(_dneg): 1260 { 1261 SET_STACK_DOUBLE(VMdoubleNeg(STACK_DOUBLE(-1)), -1); 1262 UPDATE_PC_AND_CONTINUE(1); 1263 } 1264 1265 /* Conversion operations */ 1266 1267 CASE(_i2f): /* convert top of stack int to float */ 1268 SET_STACK_FLOAT(VMint2Float(STACK_INT(-1)), -1); 1269 UPDATE_PC_AND_CONTINUE(1); 1270 1271 CASE(_i2l): /* convert top of stack int to long */ 1272 { 1273 // this is ugly QQQ 1274 jlong r = VMint2Long(STACK_INT(-1)); 1275 MORE_STACK(-1); // Pop 1276 SET_STACK_LONG(r, 1); 1277 1278 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1279 } 1280 1281 CASE(_i2d): /* convert top of stack int to double */ 1282 { 1283 // this is ugly QQQ (why cast to jlong?? ) 1284 jdouble r = (jlong)STACK_INT(-1); 1285 MORE_STACK(-1); // Pop 1286 SET_STACK_DOUBLE(r, 1); 1287 1288 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1289 } 1290 1291 CASE(_l2i): /* convert top of stack long to int */ 1292 { 1293 jint r = VMlong2Int(STACK_LONG(-1)); 1294 MORE_STACK(-2); // Pop 1295 SET_STACK_INT(r, 0); 1296 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1297 } 1298 1299 CASE(_l2f): /* convert top of stack long to float */ 1300 { 1301 jlong r = STACK_LONG(-1); 1302 MORE_STACK(-2); // Pop 1303 SET_STACK_FLOAT(VMlong2Float(r), 0); 1304 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1305 } 1306 1307 CASE(_l2d): /* convert top of stack long to double */ 1308 { 1309 jlong r = STACK_LONG(-1); 1310 MORE_STACK(-2); // Pop 1311 SET_STACK_DOUBLE(VMlong2Double(r), 1); 1312 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1313 } 1314 1315 CASE(_f2i): /* Convert top of stack float to int */ 1316 SET_STACK_INT(SharedRuntime::f2i(STACK_FLOAT(-1)), -1); 1317 UPDATE_PC_AND_CONTINUE(1); 1318 1319 CASE(_f2l): /* convert top of stack float to long */ 1320 { 1321 jlong r = SharedRuntime::f2l(STACK_FLOAT(-1)); 1322 MORE_STACK(-1); // POP 1323 SET_STACK_LONG(r, 1); 1324 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1325 } 1326 1327 CASE(_f2d): /* convert top of stack float to double */ 1328 { 1329 jfloat f; 1330 jdouble r; 1331 f = STACK_FLOAT(-1); 1332 r = (jdouble) f; 1333 MORE_STACK(-1); // POP 1334 SET_STACK_DOUBLE(r, 1); 1335 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1336 } 1337 1338 CASE(_d2i): /* convert top of stack double to int */ 1339 { 1340 jint r1 = SharedRuntime::d2i(STACK_DOUBLE(-1)); 1341 MORE_STACK(-2); 1342 SET_STACK_INT(r1, 0); 1343 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1344 } 1345 1346 CASE(_d2f): /* convert top of stack double to float */ 1347 { 1348 jfloat r1 = VMdouble2Float(STACK_DOUBLE(-1)); 1349 MORE_STACK(-2); 1350 SET_STACK_FLOAT(r1, 0); 1351 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1352 } 1353 1354 CASE(_d2l): /* convert top of stack double to long */ 1355 { 1356 jlong r1 = SharedRuntime::d2l(STACK_DOUBLE(-1)); 1357 MORE_STACK(-2); 1358 SET_STACK_LONG(r1, 1); 1359 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 2); 1360 } 1361 1362 CASE(_i2b): 1363 SET_STACK_INT(VMint2Byte(STACK_INT(-1)), -1); 1364 UPDATE_PC_AND_CONTINUE(1); 1365 1366 CASE(_i2c): 1367 SET_STACK_INT(VMint2Char(STACK_INT(-1)), -1); 1368 UPDATE_PC_AND_CONTINUE(1); 1369 1370 CASE(_i2s): 1371 SET_STACK_INT(VMint2Short(STACK_INT(-1)), -1); 1372 UPDATE_PC_AND_CONTINUE(1); 1373 1374 /* comparison operators */ 1375 1376 1377 #define COMPARISON_OP(name, comparison) \ 1378 CASE(_if_icmp##name): { \ 1379 int skip = (STACK_INT(-2) comparison STACK_INT(-1)) \ 1380 ? (int16_t)Bytes::get_Java_u2(pc + 1) : 3; \ 1381 address branch_pc = pc; \ 1382 UPDATE_PC_AND_TOS(skip, -2); \ 1383 DO_BACKEDGE_CHECKS(skip, branch_pc); \ 1384 CONTINUE; \ 1385 } \ 1386 CASE(_if##name): { \ 1387 int skip = (STACK_INT(-1) comparison 0) \ 1388 ? (int16_t)Bytes::get_Java_u2(pc + 1) : 3; \ 1389 address branch_pc = pc; \ 1390 UPDATE_PC_AND_TOS(skip, -1); \ 1391 DO_BACKEDGE_CHECKS(skip, branch_pc); \ 1392 CONTINUE; \ 1393 } 1394 1395 #define COMPARISON_OP2(name, comparison) \ 1396 COMPARISON_OP(name, comparison) \ 1397 CASE(_if_acmp##name): { \ 1398 int skip = (STACK_OBJECT(-2) comparison STACK_OBJECT(-1)) \ 1399 ? (int16_t)Bytes::get_Java_u2(pc + 1) : 3; \ 1400 address branch_pc = pc; \ 1401 UPDATE_PC_AND_TOS(skip, -2); \ 1402 DO_BACKEDGE_CHECKS(skip, branch_pc); \ 1403 CONTINUE; \ 1404 } 1405 1406 #define NULL_COMPARISON_NOT_OP(name) \ 1407 CASE(_if##name): { \ 1408 int skip = (!(STACK_OBJECT(-1) == NULL)) \ 1409 ? (int16_t)Bytes::get_Java_u2(pc + 1) : 3; \ 1410 address branch_pc = pc; \ 1411 UPDATE_PC_AND_TOS(skip, -1); \ 1412 DO_BACKEDGE_CHECKS(skip, branch_pc); \ 1413 CONTINUE; \ 1414 } 1415 1416 #define NULL_COMPARISON_OP(name) \ 1417 CASE(_if##name): { \ 1418 int skip = ((STACK_OBJECT(-1) == NULL)) \ 1419 ? (int16_t)Bytes::get_Java_u2(pc + 1) : 3; \ 1420 address branch_pc = pc; \ 1421 UPDATE_PC_AND_TOS(skip, -1); \ 1422 DO_BACKEDGE_CHECKS(skip, branch_pc); \ 1423 CONTINUE; \ 1424 } 1425 COMPARISON_OP(lt, <); 1426 COMPARISON_OP(gt, >); 1427 COMPARISON_OP(le, <=); 1428 COMPARISON_OP(ge, >=); 1429 COMPARISON_OP2(eq, ==); /* include ref comparison */ 1430 COMPARISON_OP2(ne, !=); /* include ref comparison */ 1431 NULL_COMPARISON_OP(null); 1432 NULL_COMPARISON_NOT_OP(nonnull); 1433 1434 /* Goto pc at specified offset in switch table. */ 1435 1436 CASE(_tableswitch): { 1437 jint* lpc = (jint*)VMalignWordUp(pc+1); 1438 int32_t key = STACK_INT(-1); 1439 int32_t low = Bytes::get_Java_u4((address)&lpc[1]); 1440 int32_t high = Bytes::get_Java_u4((address)&lpc[2]); 1441 int32_t skip; 1442 key -= low; 1443 skip = ((uint32_t) key > (uint32_t)(high - low)) 1444 ? Bytes::get_Java_u4((address)&lpc[0]) 1445 : Bytes::get_Java_u4((address)&lpc[key + 3]); 1446 // Does this really need a full backedge check (osr?) 1447 address branch_pc = pc; 1448 UPDATE_PC_AND_TOS(skip, -1); 1449 DO_BACKEDGE_CHECKS(skip, branch_pc); 1450 CONTINUE; 1451 } 1452 1453 /* Goto pc whose table entry matches specified key */ 1454 1455 CASE(_lookupswitch): { 1456 jint* lpc = (jint*)VMalignWordUp(pc+1); 1457 int32_t key = STACK_INT(-1); 1458 int32_t skip = Bytes::get_Java_u4((address) lpc); /* default amount */ 1459 int32_t npairs = Bytes::get_Java_u4((address) &lpc[1]); 1460 while (--npairs >= 0) { 1461 lpc += 2; 1462 if (key == (int32_t)Bytes::get_Java_u4((address)lpc)) { 1463 skip = Bytes::get_Java_u4((address)&lpc[1]); 1464 break; 1465 } 1466 } 1467 address branch_pc = pc; 1468 UPDATE_PC_AND_TOS(skip, -1); 1469 DO_BACKEDGE_CHECKS(skip, branch_pc); 1470 CONTINUE; 1471 } 1472 1473 CASE(_fcmpl): 1474 CASE(_fcmpg): 1475 { 1476 SET_STACK_INT(VMfloatCompare(STACK_FLOAT(-2), 1477 STACK_FLOAT(-1), 1478 (opcode == Bytecodes::_fcmpl ? -1 : 1)), 1479 -2); 1480 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); 1481 } 1482 1483 CASE(_dcmpl): 1484 CASE(_dcmpg): 1485 { 1486 int r = VMdoubleCompare(STACK_DOUBLE(-3), 1487 STACK_DOUBLE(-1), 1488 (opcode == Bytecodes::_dcmpl ? -1 : 1)); 1489 MORE_STACK(-4); // Pop 1490 SET_STACK_INT(r, 0); 1491 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1492 } 1493 1494 CASE(_lcmp): 1495 { 1496 int r = VMlongCompare(STACK_LONG(-3), STACK_LONG(-1)); 1497 MORE_STACK(-4); 1498 SET_STACK_INT(r, 0); 1499 UPDATE_PC_AND_TOS_AND_CONTINUE(1, 1); 1500 } 1501 1502 1503 /* Return from a method */ 1504 1505 CASE(_areturn): 1506 CASE(_ireturn): 1507 CASE(_freturn): 1508 { 1509 // Allow a safepoint before returning to frame manager. 1510 SAFEPOINT; 1511 1512 goto handle_return; 1513 } 1514 1515 CASE(_lreturn): 1516 CASE(_dreturn): 1517 { 1518 // Allow a safepoint before returning to frame manager. 1519 SAFEPOINT; 1520 goto handle_return; 1521 } 1522 1523 CASE(_return_register_finalizer): { 1524 1525 oop rcvr = LOCALS_OBJECT(0); 1526 VERIFY_OOP(rcvr); 1527 if (rcvr->klass()->klass_part()->has_finalizer()) { 1528 CALL_VM(InterpreterRuntime::register_finalizer(THREAD, rcvr), handle_exception); 1529 } 1530 goto handle_return; 1531 } 1532 CASE(_return): { 1533 1534 // Allow a safepoint before returning to frame manager. 1535 SAFEPOINT; 1536 goto handle_return; 1537 } 1538 1539 /* Array access byte-codes */ 1540 1541 /* Every array access byte-code starts out like this */ 1542 // arrayOopDesc* arrObj = (arrayOopDesc*)STACK_OBJECT(arrayOff); 1543 #define ARRAY_INTRO(arrayOff) \ 1544 arrayOop arrObj = (arrayOop)STACK_OBJECT(arrayOff); \ 1545 jint index = STACK_INT(arrayOff + 1); \ 1546 char message[jintAsStringSize]; \ 1547 CHECK_NULL(arrObj); \ 1548 if ((uint32_t)index >= (uint32_t)arrObj->length()) { \ 1549 sprintf(message, "%d", index); \ 1550 VM_JAVA_ERROR(vmSymbols::java_lang_ArrayIndexOutOfBoundsException(), \ 1551 message); \ 1552 } 1553 1554 /* 32-bit loads. These handle conversion from < 32-bit types */ 1555 #define ARRAY_LOADTO32(T, T2, format, stackRes, extra) \ 1556 { \ 1557 ARRAY_INTRO(-2); \ 1558 extra; \ 1559 SET_ ## stackRes(*(T2 *)(((address) arrObj->base(T)) + index * sizeof(T2)), \ 1560 -2); \ 1561 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); \ 1562 } 1563 1564 /* 64-bit loads */ 1565 #define ARRAY_LOADTO64(T,T2, stackRes, extra) \ 1566 { \ 1567 ARRAY_INTRO(-2); \ 1568 SET_ ## stackRes(*(T2 *)(((address) arrObj->base(T)) + index * sizeof(T2)), -1); \ 1569 extra; \ 1570 UPDATE_PC_AND_CONTINUE(1); \ 1571 } 1572 1573 CASE(_iaload): 1574 ARRAY_LOADTO32(T_INT, jint, "%d", STACK_INT, 0); 1575 CASE(_faload): 1576 ARRAY_LOADTO32(T_FLOAT, jfloat, "%f", STACK_FLOAT, 0); 1577 CASE(_aaload): 1578 ARRAY_LOADTO32(T_OBJECT, oop, INTPTR_FORMAT, STACK_OBJECT, 0); 1579 CASE(_baload): 1580 ARRAY_LOADTO32(T_BYTE, jbyte, "%d", STACK_INT, 0); 1581 CASE(_caload): 1582 ARRAY_LOADTO32(T_CHAR, jchar, "%d", STACK_INT, 0); 1583 CASE(_saload): 1584 ARRAY_LOADTO32(T_SHORT, jshort, "%d", STACK_INT, 0); 1585 CASE(_laload): 1586 ARRAY_LOADTO64(T_LONG, jlong, STACK_LONG, 0); 1587 CASE(_daload): 1588 ARRAY_LOADTO64(T_DOUBLE, jdouble, STACK_DOUBLE, 0); 1589 1590 /* 32-bit stores. These handle conversion to < 32-bit types */ 1591 #define ARRAY_STOREFROM32(T, T2, format, stackSrc, extra) \ 1592 { \ 1593 ARRAY_INTRO(-3); \ 1594 extra; \ 1595 *(T2 *)(((address) arrObj->base(T)) + index * sizeof(T2)) = stackSrc( -1); \ 1596 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -3); \ 1597 } 1598 1599 /* 64-bit stores */ 1600 #define ARRAY_STOREFROM64(T, T2, stackSrc, extra) \ 1601 { \ 1602 ARRAY_INTRO(-4); \ 1603 extra; \ 1604 *(T2 *)(((address) arrObj->base(T)) + index * sizeof(T2)) = stackSrc( -1); \ 1605 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -4); \ 1606 } 1607 1608 CASE(_iastore): 1609 ARRAY_STOREFROM32(T_INT, jint, "%d", STACK_INT, 0); 1610 CASE(_fastore): 1611 ARRAY_STOREFROM32(T_FLOAT, jfloat, "%f", STACK_FLOAT, 0); 1612 /* 1613 * This one looks different because of the assignability check 1614 */ 1615 CASE(_aastore): { 1616 oop rhsObject = STACK_OBJECT(-1); 1617 VERIFY_OOP(rhsObject); 1618 ARRAY_INTRO( -3); 1619 // arrObj, index are set 1620 if (rhsObject != NULL) { 1621 /* Check assignability of rhsObject into arrObj */ 1622 klassOop rhsKlassOop = rhsObject->klass(); // EBX (subclass) 1623 assert(arrObj->klass()->klass()->klass_part()->oop_is_objArrayKlass(), "Ack not an objArrayKlass"); 1624 klassOop elemKlassOop = ((objArrayKlass*) arrObj->klass()->klass_part())->element_klass(); // superklass EAX 1625 // 1626 // Check for compatibilty. This check must not GC!! 1627 // Seems way more expensive now that we must dispatch 1628 // 1629 if (rhsKlassOop != elemKlassOop && !rhsKlassOop->klass_part()->is_subtype_of(elemKlassOop)) { // ebx->is... 1630 VM_JAVA_ERROR(vmSymbols::java_lang_ArrayStoreException(), ""); 1631 } 1632 } 1633 oop* elem_loc = (oop*)(((address) arrObj->base(T_OBJECT)) + index * sizeof(oop)); 1634 // *(oop*)(((address) arrObj->base(T_OBJECT)) + index * sizeof(oop)) = rhsObject; 1635 *elem_loc = rhsObject; 1636 // Mark the card 1637 OrderAccess::release_store(&BYTE_MAP_BASE[(uintptr_t)elem_loc >> CardTableModRefBS::card_shift], 0); 1638 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -3); 1639 } 1640 CASE(_bastore): 1641 ARRAY_STOREFROM32(T_BYTE, jbyte, "%d", STACK_INT, 0); 1642 CASE(_castore): 1643 ARRAY_STOREFROM32(T_CHAR, jchar, "%d", STACK_INT, 0); 1644 CASE(_sastore): 1645 ARRAY_STOREFROM32(T_SHORT, jshort, "%d", STACK_INT, 0); 1646 CASE(_lastore): 1647 ARRAY_STOREFROM64(T_LONG, jlong, STACK_LONG, 0); 1648 CASE(_dastore): 1649 ARRAY_STOREFROM64(T_DOUBLE, jdouble, STACK_DOUBLE, 0); 1650 1651 CASE(_arraylength): 1652 { 1653 arrayOop ary = (arrayOop) STACK_OBJECT(-1); 1654 CHECK_NULL(ary); 1655 SET_STACK_INT(ary->length(), -1); 1656 UPDATE_PC_AND_CONTINUE(1); 1657 } 1658 1659 /* monitorenter and monitorexit for locking/unlocking an object */ 1660 1661 CASE(_monitorenter): { 1662 oop lockee = STACK_OBJECT(-1); 1663 // derefing's lockee ought to provoke implicit null check 1664 CHECK_NULL(lockee); 1665 // find a free monitor or one already allocated for this object 1666 // if we find a matching object then we need a new monitor 1667 // since this is recursive enter 1668 BasicObjectLock* limit = istate->monitor_base(); 1669 BasicObjectLock* most_recent = (BasicObjectLock*) istate->stack_base(); 1670 BasicObjectLock* entry = NULL; 1671 while (most_recent != limit ) { 1672 if (most_recent->obj() == NULL) entry = most_recent; 1673 else if (most_recent->obj() == lockee) break; 1674 most_recent++; 1675 } 1676 if (entry != NULL) { 1677 entry->set_obj(lockee); 1678 markOop displaced = lockee->mark()->set_unlocked(); 1679 entry->lock()->set_displaced_header(displaced); 1680 if (Atomic::cmpxchg_ptr(entry, lockee->mark_addr(), displaced) != displaced) { 1681 // Is it simple recursive case? 1682 if (THREAD->is_lock_owned((address) displaced->clear_lock_bits())) { 1683 entry->lock()->set_displaced_header(NULL); 1684 } else { 1685 CALL_VM(InterpreterRuntime::monitorenter(THREAD, entry), handle_exception); 1686 } 1687 } 1688 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); 1689 } else { 1690 istate->set_msg(more_monitors); 1691 UPDATE_PC_AND_RETURN(0); // Re-execute 1692 } 1693 } 1694 1695 CASE(_monitorexit): { 1696 oop lockee = STACK_OBJECT(-1); 1697 CHECK_NULL(lockee); 1698 // derefing's lockee ought to provoke implicit null check 1699 // find our monitor slot 1700 BasicObjectLock* limit = istate->monitor_base(); 1701 BasicObjectLock* most_recent = (BasicObjectLock*) istate->stack_base(); 1702 while (most_recent != limit ) { 1703 if ((most_recent)->obj() == lockee) { 1704 BasicLock* lock = most_recent->lock(); 1705 markOop header = lock->displaced_header(); 1706 most_recent->set_obj(NULL); 1707 // If it isn't recursive we either must swap old header or call the runtime 1708 if (header != NULL) { 1709 if (Atomic::cmpxchg_ptr(header, lockee->mark_addr(), lock) != lock) { 1710 // restore object for the slow case 1711 most_recent->set_obj(lockee); 1712 CALL_VM(InterpreterRuntime::monitorexit(THREAD, most_recent), handle_exception); 1713 } 1714 } 1715 UPDATE_PC_AND_TOS_AND_CONTINUE(1, -1); 1716 } 1717 most_recent++; 1718 } 1719 // Need to throw illegal monitor state exception 1720 CALL_VM(InterpreterRuntime::throw_illegal_monitor_state_exception(THREAD), handle_exception); 1721 ShouldNotReachHere(); 1722 } 1723 1724 /* All of the non-quick opcodes. */ 1725 1726 /* -Set clobbersCpIndex true if the quickened opcode clobbers the 1727 * constant pool index in the instruction. 1728 */ 1729 CASE(_getfield): 1730 CASE(_getstatic): 1731 { 1732 u2 index; 1733 ConstantPoolCacheEntry* cache; 1734 index = Bytes::get_native_u2(pc+1); 1735 1736 // QQQ Need to make this as inlined as possible. Probably need to 1737 // split all the bytecode cases out so c++ compiler has a chance 1738 // for constant prop to fold everything possible away. 1739 1740 cache = cp->entry_at(index); 1741 if (!cache->is_resolved((Bytecodes::Code)opcode)) { 1742 CALL_VM(InterpreterRuntime::resolve_get_put(THREAD, (Bytecodes::Code)opcode), 1743 handle_exception); 1744 cache = cp->entry_at(index); 1745 } 1746 1747 #ifdef VM_JVMTI 1748 if (_jvmti_interp_events) { 1749 int *count_addr; 1750 oop obj; 1751 // Check to see if a field modification watch has been set 1752 // before we take the time to call into the VM. 1753 count_addr = (int *)JvmtiExport::get_field_access_count_addr(); 1754 if ( *count_addr > 0 ) { 1755 if ((Bytecodes::Code)opcode == Bytecodes::_getstatic) { 1756 obj = (oop)NULL; 1757 } else { 1758 obj = (oop) STACK_OBJECT(-1); 1759 VERIFY_OOP(obj); 1760 } 1761 CALL_VM(InterpreterRuntime::post_field_access(THREAD, 1762 obj, 1763 cache), 1764 handle_exception); 1765 } 1766 } 1767 #endif /* VM_JVMTI */ 1768 1769 oop obj; 1770 if ((Bytecodes::Code)opcode == Bytecodes::_getstatic) { 1771 obj = (oop) cache->f1(); 1772 MORE_STACK(1); // Assume single slot push 1773 } else { 1774 obj = (oop) STACK_OBJECT(-1); 1775 CHECK_NULL(obj); 1776 } 1777 1778 // 1779 // Now store the result on the stack 1780 // 1781 TosState tos_type = cache->flag_state(); 1782 int field_offset = cache->f2(); 1783 if (cache->is_volatile()) { 1784 if (tos_type == atos) { 1785 VERIFY_OOP(obj->obj_field_acquire(field_offset)); 1786 SET_STACK_OBJECT(obj->obj_field_acquire(field_offset), -1); 1787 } else if (tos_type == itos) { 1788 SET_STACK_INT(obj->int_field_acquire(field_offset), -1); 1789 } else if (tos_type == ltos) { 1790 SET_STACK_LONG(obj->long_field_acquire(field_offset), 0); 1791 MORE_STACK(1); 1792 } else if (tos_type == btos) { 1793 SET_STACK_INT(obj->byte_field_acquire(field_offset), -1); 1794 } else if (tos_type == ctos) { 1795 SET_STACK_INT(obj->char_field_acquire(field_offset), -1); 1796 } else if (tos_type == stos) { 1797 SET_STACK_INT(obj->short_field_acquire(field_offset), -1); 1798 } else if (tos_type == ftos) { 1799 SET_STACK_FLOAT(obj->float_field_acquire(field_offset), -1); 1800 } else { 1801 SET_STACK_DOUBLE(obj->double_field_acquire(field_offset), 0); 1802 MORE_STACK(1); 1803 } 1804 } else { 1805 if (tos_type == atos) { 1806 VERIFY_OOP(obj->obj_field(field_offset)); 1807 SET_STACK_OBJECT(obj->obj_field(field_offset), -1); 1808 } else if (tos_type == itos) { 1809 SET_STACK_INT(obj->int_field(field_offset), -1); 1810 } else if (tos_type == ltos) { 1811 SET_STACK_LONG(obj->long_field(field_offset), 0); 1812 MORE_STACK(1); 1813 } else if (tos_type == btos) { 1814 SET_STACK_INT(obj->byte_field(field_offset), -1); 1815 } else if (tos_type == ctos) { 1816 SET_STACK_INT(obj->char_field(field_offset), -1); 1817 } else if (tos_type == stos) { 1818 SET_STACK_INT(obj->short_field(field_offset), -1); 1819 } else if (tos_type == ftos) { 1820 SET_STACK_FLOAT(obj->float_field(field_offset), -1); 1821 } else { 1822 SET_STACK_DOUBLE(obj->double_field(field_offset), 0); 1823 MORE_STACK(1); 1824 } 1825 } 1826 1827 UPDATE_PC_AND_CONTINUE(3); 1828 } 1829 1830 CASE(_putfield): 1831 CASE(_putstatic): 1832 { 1833 u2 index = Bytes::get_native_u2(pc+1); 1834 ConstantPoolCacheEntry* cache = cp->entry_at(index); 1835 if (!cache->is_resolved((Bytecodes::Code)opcode)) { 1836 CALL_VM(InterpreterRuntime::resolve_get_put(THREAD, (Bytecodes::Code)opcode), 1837 handle_exception); 1838 cache = cp->entry_at(index); 1839 } 1840 1841 #ifdef VM_JVMTI 1842 if (_jvmti_interp_events) { 1843 int *count_addr; 1844 oop obj; 1845 // Check to see if a field modification watch has been set 1846 // before we take the time to call into the VM. 1847 count_addr = (int *)JvmtiExport::get_field_modification_count_addr(); 1848 if ( *count_addr > 0 ) { 1849 if ((Bytecodes::Code)opcode == Bytecodes::_putstatic) { 1850 obj = (oop)NULL; 1851 } 1852 else { 1853 if (cache->is_long() || cache->is_double()) { 1854 obj = (oop) STACK_OBJECT(-3); 1855 } else { 1856 obj = (oop) STACK_OBJECT(-2); 1857 } 1858 VERIFY_OOP(obj); 1859 } 1860 1861 CALL_VM(InterpreterRuntime::post_field_modification(THREAD, 1862 obj, 1863 cache, 1864 (jvalue *)STACK_SLOT(-1)), 1865 handle_exception); 1866 } 1867 } 1868 #endif /* VM_JVMTI */ 1869 1870 // QQQ Need to make this as inlined as possible. Probably need to split all the bytecode cases 1871 // out so c++ compiler has a chance for constant prop to fold everything possible away. 1872 1873 oop obj; 1874 int count; 1875 TosState tos_type = cache->flag_state(); 1876 1877 count = -1; 1878 if (tos_type == ltos || tos_type == dtos) { 1879 --count; 1880 } 1881 if ((Bytecodes::Code)opcode == Bytecodes::_putstatic) { 1882 obj = (oop) cache->f1(); 1883 } else { 1884 --count; 1885 obj = (oop) STACK_OBJECT(count); 1886 CHECK_NULL(obj); 1887 } 1888 1889 // 1890 // Now store the result 1891 // 1892 int field_offset = cache->f2(); 1893 if (cache->is_volatile()) { 1894 if (tos_type == itos) { 1895 obj->release_int_field_put(field_offset, STACK_INT(-1)); 1896 } else if (tos_type == atos) { 1897 VERIFY_OOP(STACK_OBJECT(-1)); 1898 obj->release_obj_field_put(field_offset, STACK_OBJECT(-1)); 1899 OrderAccess::release_store(&BYTE_MAP_BASE[(uintptr_t)obj >> CardTableModRefBS::card_shift], 0); 1900 } else if (tos_type == btos) { 1901 obj->release_byte_field_put(field_offset, STACK_INT(-1)); 1902 } else if (tos_type == ltos) { 1903 obj->release_long_field_put(field_offset, STACK_LONG(-1)); 1904 } else if (tos_type == ctos) { 1905 obj->release_char_field_put(field_offset, STACK_INT(-1)); 1906 } else if (tos_type == stos) { 1907 obj->release_short_field_put(field_offset, STACK_INT(-1)); 1908 } else if (tos_type == ftos) { 1909 obj->release_float_field_put(field_offset, STACK_FLOAT(-1)); 1910 } else { 1911 obj->release_double_field_put(field_offset, STACK_DOUBLE(-1)); 1912 } 1913 OrderAccess::storeload(); 1914 } else { 1915 if (tos_type == itos) { 1916 obj->int_field_put(field_offset, STACK_INT(-1)); 1917 } else if (tos_type == atos) { 1918 VERIFY_OOP(STACK_OBJECT(-1)); 1919 obj->obj_field_put(field_offset, STACK_OBJECT(-1)); 1920 OrderAccess::release_store(&BYTE_MAP_BASE[(uintptr_t)obj >> CardTableModRefBS::card_shift], 0); 1921 } else if (tos_type == btos) { 1922 obj->byte_field_put(field_offset, STACK_INT(-1)); 1923 } else if (tos_type == ltos) { 1924 obj->long_field_put(field_offset, STACK_LONG(-1)); 1925 } else if (tos_type == ctos) { 1926 obj->char_field_put(field_offset, STACK_INT(-1)); 1927 } else if (tos_type == stos) { 1928 obj->short_field_put(field_offset, STACK_INT(-1)); 1929 } else if (tos_type == ftos) { 1930 obj->float_field_put(field_offset, STACK_FLOAT(-1)); 1931 } else { 1932 obj->double_field_put(field_offset, STACK_DOUBLE(-1)); 1933 } 1934 } 1935 1936 UPDATE_PC_AND_TOS_AND_CONTINUE(3, count); 1937 } 1938 1939 CASE(_new): { 1940 u2 index = Bytes::get_Java_u2(pc+1); 1941 constantPoolOop constants = istate->method()->constants(); 1942 if (!constants->tag_at(index).is_unresolved_klass()) { 1943 // Make sure klass is initialized and doesn't have a finalizer 1944 oop entry = constants->slot_at(index).get_oop(); 1945 assert(entry->is_klass(), "Should be resolved klass"); 1946 klassOop k_entry = (klassOop) entry; 1947 assert(k_entry->klass_part()->oop_is_instance(), "Should be instanceKlass"); 1948 instanceKlass* ik = (instanceKlass*) k_entry->klass_part(); 1949 if ( ik->is_initialized() && ik->can_be_fastpath_allocated() ) { 1950 size_t obj_size = ik->size_helper(); 1951 oop result = NULL; 1952 // If the TLAB isn't pre-zeroed then we'll have to do it 1953 bool need_zero = !ZeroTLAB; 1954 if (UseTLAB) { 1955 result = (oop) THREAD->tlab().allocate(obj_size); 1956 } 1957 if (result == NULL) { 1958 need_zero = true; 1959 // Try allocate in shared eden 1960 retry: 1961 HeapWord* compare_to = *Universe::heap()->top_addr(); 1962 HeapWord* new_top = compare_to + obj_size; 1963 if (new_top <= *Universe::heap()->end_addr()) { 1964 if (Atomic::cmpxchg_ptr(new_top, Universe::heap()->top_addr(), compare_to) != compare_to) { 1965 goto retry; 1966 } 1967 result = (oop) compare_to; 1968 } 1969 } 1970 if (result != NULL) { 1971 // Initialize object (if nonzero size and need) and then the header 1972 if (need_zero ) { 1973 HeapWord* to_zero = (HeapWord*) result + sizeof(oopDesc) / oopSize; 1974 obj_size -= sizeof(oopDesc) / oopSize; 1975 if (obj_size > 0 ) { 1976 memset(to_zero, 0, obj_size * HeapWordSize); 1977 } 1978 } 1979 if (UseBiasedLocking) { 1980 result->set_mark(ik->prototype_header()); 1981 } else { 1982 result->set_mark(markOopDesc::prototype()); 1983 } 1984 result->set_klass_gap(0); 1985 result->set_klass(k_entry); 1986 SET_STACK_OBJECT(result, 0); 1987 UPDATE_PC_AND_TOS_AND_CONTINUE(3, 1); 1988 } 1989 } 1990 } 1991 // Slow case allocation 1992 CALL_VM(InterpreterRuntime::_new(THREAD, METHOD->constants(), index), 1993 handle_exception); 1994 SET_STACK_OBJECT(THREAD->vm_result(), 0); 1995 THREAD->set_vm_result(NULL); 1996 UPDATE_PC_AND_TOS_AND_CONTINUE(3, 1); 1997 } 1998 CASE(_anewarray): { 1999 u2 index = Bytes::get_Java_u2(pc+1); 2000 jint size = STACK_INT(-1); 2001 CALL_VM(InterpreterRuntime::anewarray(THREAD, METHOD->constants(), index, size), 2002 handle_exception); 2003 SET_STACK_OBJECT(THREAD->vm_result(), -1); 2004 THREAD->set_vm_result(NULL); 2005 UPDATE_PC_AND_CONTINUE(3); 2006 } 2007 CASE(_multianewarray): { 2008 jint dims = *(pc+3); 2009 jint size = STACK_INT(-1); 2010 // stack grows down, dimensions are up! 2011 jint *dimarray = 2012 (jint*)&topOfStack[dims * Interpreter::stackElementWords+ 2013 Interpreter::stackElementWords-1]; 2014 //adjust pointer to start of stack element 2015 CALL_VM(InterpreterRuntime::multianewarray(THREAD, dimarray), 2016 handle_exception); 2017 SET_STACK_OBJECT(THREAD->vm_result(), -dims); 2018 THREAD->set_vm_result(NULL); 2019 UPDATE_PC_AND_TOS_AND_CONTINUE(4, -(dims-1)); 2020 } 2021 CASE(_checkcast): 2022 if (STACK_OBJECT(-1) != NULL) { 2023 VERIFY_OOP(STACK_OBJECT(-1)); 2024 u2 index = Bytes::get_Java_u2(pc+1); 2025 if (ProfileInterpreter) { 2026 // needs Profile_checkcast QQQ 2027 ShouldNotReachHere(); 2028 } 2029 // Constant pool may have actual klass or unresolved klass. If it is 2030 // unresolved we must resolve it 2031 if (METHOD->constants()->tag_at(index).is_unresolved_klass()) { 2032 CALL_VM(InterpreterRuntime::quicken_io_cc(THREAD), handle_exception); 2033 } 2034 klassOop klassOf = (klassOop) METHOD->constants()->slot_at(index).get_oop(); 2035 klassOop objKlassOop = STACK_OBJECT(-1)->klass(); //ebx 2036 // 2037 // Check for compatibilty. This check must not GC!! 2038 // Seems way more expensive now that we must dispatch 2039 // 2040 if (objKlassOop != klassOf && 2041 !objKlassOop->klass_part()->is_subtype_of(klassOf)) { 2042 ResourceMark rm(THREAD); 2043 const char* objName = Klass::cast(objKlassOop)->external_name(); 2044 const char* klassName = Klass::cast(klassOf)->external_name(); 2045 char* message = SharedRuntime::generate_class_cast_message( 2046 objName, klassName); 2047 VM_JAVA_ERROR(vmSymbols::java_lang_ClassCastException(), message); 2048 } 2049 } else { 2050 if (UncommonNullCast) { 2051 // istate->method()->set_null_cast_seen(); 2052 // [RGV] Not sure what to do here! 2053 2054 } 2055 } 2056 UPDATE_PC_AND_CONTINUE(3); 2057 2058 CASE(_instanceof): 2059 if (STACK_OBJECT(-1) == NULL) { 2060 SET_STACK_INT(0, -1); 2061 } else { 2062 VERIFY_OOP(STACK_OBJECT(-1)); 2063 u2 index = Bytes::get_Java_u2(pc+1); 2064 // Constant pool may have actual klass or unresolved klass. If it is 2065 // unresolved we must resolve it 2066 if (METHOD->constants()->tag_at(index).is_unresolved_klass()) { 2067 CALL_VM(InterpreterRuntime::quicken_io_cc(THREAD), handle_exception); 2068 } 2069 klassOop klassOf = (klassOop) METHOD->constants()->slot_at(index).get_oop(); 2070 klassOop objKlassOop = STACK_OBJECT(-1)->klass(); 2071 // 2072 // Check for compatibilty. This check must not GC!! 2073 // Seems way more expensive now that we must dispatch 2074 // 2075 if ( objKlassOop == klassOf || objKlassOop->klass_part()->is_subtype_of(klassOf)) { 2076 SET_STACK_INT(1, -1); 2077 } else { 2078 SET_STACK_INT(0, -1); 2079 } 2080 } 2081 UPDATE_PC_AND_CONTINUE(3); 2082 2083 CASE(_ldc_w): 2084 CASE(_ldc): 2085 { 2086 u2 index; 2087 bool wide = false; 2088 int incr = 2; // frequent case 2089 if (opcode == Bytecodes::_ldc) { 2090 index = pc[1]; 2091 } else { 2092 index = Bytes::get_Java_u2(pc+1); 2093 incr = 3; 2094 wide = true; 2095 } 2096 2097 constantPoolOop constants = METHOD->constants(); 2098 switch (constants->tag_at(index).value()) { 2099 case JVM_CONSTANT_Integer: 2100 SET_STACK_INT(constants->int_at(index), 0); 2101 break; 2102 2103 case JVM_CONSTANT_Float: 2104 SET_STACK_FLOAT(constants->float_at(index), 0); 2105 break; 2106 2107 case JVM_CONSTANT_String: 2108 VERIFY_OOP(constants->resolved_string_at(index)); 2109 SET_STACK_OBJECT(constants->resolved_string_at(index), 0); 2110 break; 2111 2112 case JVM_CONSTANT_Class: 2113 VERIFY_OOP(constants->resolved_klass_at(index)->java_mirror()); 2114 SET_STACK_OBJECT(constants->resolved_klass_at(index)->java_mirror(), 0); 2115 break; 2116 2117 case JVM_CONSTANT_UnresolvedString: 2118 case JVM_CONSTANT_UnresolvedClass: 2119 case JVM_CONSTANT_UnresolvedClassInError: 2120 CALL_VM(InterpreterRuntime::ldc(THREAD, wide), handle_exception); 2121 SET_STACK_OBJECT(THREAD->vm_result(), 0); 2122 THREAD->set_vm_result(NULL); 2123 break; 2124 2125 default: ShouldNotReachHere(); 2126 } 2127 UPDATE_PC_AND_TOS_AND_CONTINUE(incr, 1); 2128 } 2129 2130 CASE(_ldc2_w): 2131 { 2132 u2 index = Bytes::get_Java_u2(pc+1); 2133 2134 constantPoolOop constants = METHOD->constants(); 2135 switch (constants->tag_at(index).value()) { 2136 2137 case JVM_CONSTANT_Long: 2138 SET_STACK_LONG(constants->long_at(index), 1); 2139 break; 2140 2141 case JVM_CONSTANT_Double: 2142 SET_STACK_DOUBLE(constants->double_at(index), 1); 2143 break; 2144 default: ShouldNotReachHere(); 2145 } 2146 UPDATE_PC_AND_TOS_AND_CONTINUE(3, 2); 2147 } 2148 2149 CASE(_fast_aldc_w): 2150 CASE(_fast_aldc): { 2151 if (!EnableInvokeDynamic) { 2152 // We should not encounter this bytecode if !EnableInvokeDynamic. 2153 // The verifier will stop it. However, if we get past the verifier, 2154 // this will stop the thread in a reasonable way, without crashing the JVM. 2155 CALL_VM(InterpreterRuntime::throw_IncompatibleClassChangeError(THREAD), 2156 handle_exception); 2157 ShouldNotReachHere(); 2158 } 2159 2160 u2 index; 2161 int incr; 2162 if (opcode == Bytecodes::_fast_aldc) { 2163 index = pc[1]; 2164 incr = 2; 2165 } else { 2166 index = Bytes::get_native_u2(pc+1); 2167 incr = 3; 2168 } 2169 2170 // We are resolved if the f1 field contains a non-null object (CallSite, etc.) 2171 // This kind of CP cache entry does not need to match the flags byte, because 2172 // there is a 1-1 relation between bytecode type and CP entry type. 2173 ConstantPoolCacheEntry* cache = cp->entry_at(index); 2174 if (cache->is_f1_null()) { 2175 CALL_VM(InterpreterRuntime::resolve_ldc(THREAD, (Bytecodes::Code) opcode), 2176 handle_exception); 2177 } 2178 2179 VERIFY_OOP(cache->f1()); 2180 SET_STACK_OBJECT(cache->f1(), 0); 2181 UPDATE_PC_AND_TOS_AND_CONTINUE(incr, 1); 2182 } 2183 2184 CASE(_invokedynamic): { 2185 if (!EnableInvokeDynamic) { 2186 // We should not encounter this bytecode if !EnableInvokeDynamic. 2187 // The verifier will stop it. However, if we get past the verifier, 2188 // this will stop the thread in a reasonable way, without crashing the JVM. 2189 CALL_VM(InterpreterRuntime::throw_IncompatibleClassChangeError(THREAD), 2190 handle_exception); 2191 ShouldNotReachHere(); 2192 } 2193 2194 int index = Bytes::get_native_u4(pc+1); 2195 2196 // We are resolved if the f1 field contains a non-null object (CallSite, etc.) 2197 // This kind of CP cache entry does not need to match the flags byte, because 2198 // there is a 1-1 relation between bytecode type and CP entry type. 2199 assert(constantPoolCacheOopDesc::is_secondary_index(index), "incorrect format"); 2200 ConstantPoolCacheEntry* cache = cp->secondary_entry_at(index); 2201 if (cache->is_f1_null()) { 2202 CALL_VM(InterpreterRuntime::resolve_invokedynamic(THREAD), 2203 handle_exception); 2204 } 2205 2206 VERIFY_OOP(cache->f1()); 2207 oop method_handle = java_lang_invoke_CallSite::target(cache->f1()); 2208 CHECK_NULL(method_handle); 2209 2210 istate->set_msg(call_method_handle); 2211 istate->set_callee((methodOop) method_handle); 2212 istate->set_bcp_advance(5); 2213 2214 UPDATE_PC_AND_RETURN(0); // I'll be back... 2215 } 2216 2217 CASE(_invokeinterface): { 2218 u2 index = Bytes::get_native_u2(pc+1); 2219 2220 // QQQ Need to make this as inlined as possible. Probably need to split all the bytecode cases 2221 // out so c++ compiler has a chance for constant prop to fold everything possible away. 2222 2223 ConstantPoolCacheEntry* cache = cp->entry_at(index); 2224 if (!cache->is_resolved((Bytecodes::Code)opcode)) { 2225 CALL_VM(InterpreterRuntime::resolve_invoke(THREAD, (Bytecodes::Code)opcode), 2226 handle_exception); 2227 cache = cp->entry_at(index); 2228 } 2229 2230 istate->set_msg(call_method); 2231 2232 // Special case of invokeinterface called for virtual method of 2233 // java.lang.Object. See cpCacheOop.cpp for details. 2234 // This code isn't produced by javac, but could be produced by 2235 // another compliant java compiler. 2236 if (cache->is_methodInterface()) { 2237 methodOop callee; 2238 CHECK_NULL(STACK_OBJECT(-(cache->parameter_size()))); 2239 if (cache->is_vfinal()) { 2240 callee = (methodOop) cache->f2(); 2241 } else { 2242 // get receiver 2243 int parms = cache->parameter_size(); 2244 // Same comments as invokevirtual apply here 2245 VERIFY_OOP(STACK_OBJECT(-parms)); 2246 instanceKlass* rcvrKlass = (instanceKlass*) 2247 STACK_OBJECT(-parms)->klass()->klass_part(); 2248 callee = (methodOop) rcvrKlass->start_of_vtable()[ cache->f2()]; 2249 } 2250 istate->set_callee(callee); 2251 istate->set_callee_entry_point(callee->from_interpreted_entry()); 2252 #ifdef VM_JVMTI 2253 if (JvmtiExport::can_post_interpreter_events() && THREAD->is_interp_only_mode()) { 2254 istate->set_callee_entry_point(callee->interpreter_entry()); 2255 } 2256 #endif /* VM_JVMTI */ 2257 istate->set_bcp_advance(5); 2258 UPDATE_PC_AND_RETURN(0); // I'll be back... 2259 } 2260 2261 // this could definitely be cleaned up QQQ 2262 methodOop callee; 2263 klassOop iclass = (klassOop)cache->f1(); 2264 // instanceKlass* interface = (instanceKlass*) iclass->klass_part(); 2265 // get receiver 2266 int parms = cache->parameter_size(); 2267 oop rcvr = STACK_OBJECT(-parms); 2268 CHECK_NULL(rcvr); 2269 instanceKlass* int2 = (instanceKlass*) rcvr->klass()->klass_part(); 2270 itableOffsetEntry* ki = (itableOffsetEntry*) int2->start_of_itable(); 2271 int i; 2272 for ( i = 0 ; i < int2->itable_length() ; i++, ki++ ) { 2273 if (ki->interface_klass() == iclass) break; 2274 } 2275 // If the interface isn't found, this class doesn't implement this 2276 // interface. The link resolver checks this but only for the first 2277 // time this interface is called. 2278 if (i == int2->itable_length()) { 2279 VM_JAVA_ERROR(vmSymbols::java_lang_IncompatibleClassChangeError(), ""); 2280 } 2281 int mindex = cache->f2(); 2282 itableMethodEntry* im = ki->first_method_entry(rcvr->klass()); 2283 callee = im[mindex].method(); 2284 if (callee == NULL) { 2285 VM_JAVA_ERROR(vmSymbols::java_lang_AbstractMethodError(), ""); 2286 } 2287 2288 istate->set_callee(callee); 2289 istate->set_callee_entry_point(callee->from_interpreted_entry()); 2290 #ifdef VM_JVMTI 2291 if (JvmtiExport::can_post_interpreter_events() && THREAD->is_interp_only_mode()) { 2292 istate->set_callee_entry_point(callee->interpreter_entry()); 2293 } 2294 #endif /* VM_JVMTI */ 2295 istate->set_bcp_advance(5); 2296 UPDATE_PC_AND_RETURN(0); // I'll be back... 2297 } 2298 2299 CASE(_invokevirtual): 2300 CASE(_invokespecial): 2301 CASE(_invokestatic): { 2302 u2 index = Bytes::get_native_u2(pc+1); 2303 2304 ConstantPoolCacheEntry* cache = cp->entry_at(index); 2305 // QQQ Need to make this as inlined as possible. Probably need to split all the bytecode cases 2306 // out so c++ compiler has a chance for constant prop to fold everything possible away. 2307 2308 if (!cache->is_resolved((Bytecodes::Code)opcode)) { 2309 CALL_VM(InterpreterRuntime::resolve_invoke(THREAD, (Bytecodes::Code)opcode), 2310 handle_exception); 2311 cache = cp->entry_at(index); 2312 } 2313 2314 istate->set_msg(call_method); 2315 { 2316 methodOop callee; 2317 if ((Bytecodes::Code)opcode == Bytecodes::_invokevirtual) { 2318 CHECK_NULL(STACK_OBJECT(-(cache->parameter_size()))); 2319 if (cache->is_vfinal()) callee = (methodOop) cache->f2(); 2320 else { 2321 // get receiver 2322 int parms = cache->parameter_size(); 2323 // this works but needs a resourcemark and seems to create a vtable on every call: 2324 // methodOop callee = rcvr->klass()->klass_part()->vtable()->method_at(cache->f2()); 2325 // 2326 // this fails with an assert 2327 // instanceKlass* rcvrKlass = instanceKlass::cast(STACK_OBJECT(-parms)->klass()); 2328 // but this works 2329 VERIFY_OOP(STACK_OBJECT(-parms)); 2330 instanceKlass* rcvrKlass = (instanceKlass*) STACK_OBJECT(-parms)->klass()->klass_part(); 2331 /* 2332 Executing this code in java.lang.String: 2333 public String(char value[]) { 2334 this.count = value.length; 2335 this.value = (char[])value.clone(); 2336 } 2337 2338 a find on rcvr->klass()->klass_part() reports: 2339 {type array char}{type array class} 2340 - klass: {other class} 2341 2342 but using instanceKlass::cast(STACK_OBJECT(-parms)->klass()) causes in assertion failure 2343 because rcvr->klass()->klass_part()->oop_is_instance() == 0 2344 However it seems to have a vtable in the right location. Huh? 2345 2346 */ 2347 callee = (methodOop) rcvrKlass->start_of_vtable()[ cache->f2()]; 2348 } 2349 } else { 2350 if ((Bytecodes::Code)opcode == Bytecodes::_invokespecial) { 2351 CHECK_NULL(STACK_OBJECT(-(cache->parameter_size()))); 2352 } 2353 callee = (methodOop) cache->f1(); 2354 } 2355 2356 istate->set_callee(callee); 2357 istate->set_callee_entry_point(callee->from_interpreted_entry()); 2358 #ifdef VM_JVMTI 2359 if (JvmtiExport::can_post_interpreter_events() && THREAD->is_interp_only_mode()) { 2360 istate->set_callee_entry_point(callee->interpreter_entry()); 2361 } 2362 #endif /* VM_JVMTI */ 2363 istate->set_bcp_advance(3); 2364 UPDATE_PC_AND_RETURN(0); // I'll be back... 2365 } 2366 } 2367 2368 /* Allocate memory for a new java object. */ 2369 2370 CASE(_newarray): { 2371 BasicType atype = (BasicType) *(pc+1); 2372 jint size = STACK_INT(-1); 2373 CALL_VM(InterpreterRuntime::newarray(THREAD, atype, size), 2374 handle_exception); 2375 SET_STACK_OBJECT(THREAD->vm_result(), -1); 2376 THREAD->set_vm_result(NULL); 2377 2378 UPDATE_PC_AND_CONTINUE(2); 2379 } 2380 2381 /* Throw an exception. */ 2382 2383 CASE(_athrow): { 2384 oop except_oop = STACK_OBJECT(-1); 2385 CHECK_NULL(except_oop); 2386 // set pending_exception so we use common code 2387 THREAD->set_pending_exception(except_oop, NULL, 0); 2388 goto handle_exception; 2389 } 2390 2391 /* goto and jsr. They are exactly the same except jsr pushes 2392 * the address of the next instruction first. 2393 */ 2394 2395 CASE(_jsr): { 2396 /* push bytecode index on stack */ 2397 SET_STACK_ADDR(((address)pc - (intptr_t)(istate->method()->code_base()) + 3), 0); 2398 MORE_STACK(1); 2399 /* FALL THROUGH */ 2400 } 2401 2402 CASE(_goto): 2403 { 2404 int16_t offset = (int16_t)Bytes::get_Java_u2(pc + 1); 2405 address branch_pc = pc; 2406 UPDATE_PC(offset); 2407 DO_BACKEDGE_CHECKS(offset, branch_pc); 2408 CONTINUE; 2409 } 2410 2411 CASE(_jsr_w): { 2412 /* push return address on the stack */ 2413 SET_STACK_ADDR(((address)pc - (intptr_t)(istate->method()->code_base()) + 5), 0); 2414 MORE_STACK(1); 2415 /* FALL THROUGH */ 2416 } 2417 2418 CASE(_goto_w): 2419 { 2420 int32_t offset = Bytes::get_Java_u4(pc + 1); 2421 address branch_pc = pc; 2422 UPDATE_PC(offset); 2423 DO_BACKEDGE_CHECKS(offset, branch_pc); 2424 CONTINUE; 2425 } 2426 2427 /* return from a jsr or jsr_w */ 2428 2429 CASE(_ret): { 2430 pc = istate->method()->code_base() + (intptr_t)(LOCALS_ADDR(pc[1])); 2431 UPDATE_PC_AND_CONTINUE(0); 2432 } 2433 2434 /* debugger breakpoint */ 2435 2436 CASE(_breakpoint): { 2437 Bytecodes::Code original_bytecode; 2438 DECACHE_STATE(); 2439 SET_LAST_JAVA_FRAME(); 2440 original_bytecode = InterpreterRuntime::get_original_bytecode_at(THREAD, 2441 METHOD, pc); 2442 RESET_LAST_JAVA_FRAME(); 2443 CACHE_STATE(); 2444 if (THREAD->has_pending_exception()) goto handle_exception; 2445 CALL_VM(InterpreterRuntime::_breakpoint(THREAD, METHOD, pc), 2446 handle_exception); 2447 2448 opcode = (jubyte)original_bytecode; 2449 goto opcode_switch; 2450 } 2451 2452 DEFAULT: 2453 fatal(err_msg("Unimplemented opcode %d = %s", opcode, 2454 Bytecodes::name((Bytecodes::Code)opcode))); 2455 goto finish; 2456 2457 } /* switch(opc) */ 2458 2459 2460 #ifdef USELABELS 2461 check_for_exception: 2462 #endif 2463 { 2464 if (!THREAD->has_pending_exception()) { 2465 CONTINUE; 2466 } 2467 /* We will be gcsafe soon, so flush our state. */ 2468 DECACHE_PC(); 2469 goto handle_exception; 2470 } 2471 do_continue: ; 2472 2473 } /* while (1) interpreter loop */ 2474 2475 2476 // An exception exists in the thread state see whether this activation can handle it 2477 handle_exception: { 2478 2479 HandleMarkCleaner __hmc(THREAD); 2480 Handle except_oop(THREAD, THREAD->pending_exception()); 2481 // Prevent any subsequent HandleMarkCleaner in the VM 2482 // from freeing the except_oop handle. 2483 HandleMark __hm(THREAD); 2484 2485 THREAD->clear_pending_exception(); 2486 assert(except_oop(), "No exception to process"); 2487 intptr_t continuation_bci; 2488 // expression stack is emptied 2489 topOfStack = istate->stack_base() - Interpreter::stackElementWords; 2490 CALL_VM(continuation_bci = (intptr_t)InterpreterRuntime::exception_handler_for_exception(THREAD, except_oop()), 2491 handle_exception); 2492 2493 except_oop = (oop) THREAD->vm_result(); 2494 THREAD->set_vm_result(NULL); 2495 if (continuation_bci >= 0) { 2496 // Place exception on top of stack 2497 SET_STACK_OBJECT(except_oop(), 0); 2498 MORE_STACK(1); 2499 pc = METHOD->code_base() + continuation_bci; 2500 if (TraceExceptions) { 2501 ttyLocker ttyl; 2502 ResourceMark rm; 2503 tty->print_cr("Exception <%s> (" INTPTR_FORMAT ")", except_oop->print_value_string(), except_oop()); 2504 tty->print_cr(" thrown in interpreter method <%s>", METHOD->print_value_string()); 2505 tty->print_cr(" at bci %d, continuing at %d for thread " INTPTR_FORMAT, 2506 pc - (intptr_t)METHOD->code_base(), 2507 continuation_bci, THREAD); 2508 } 2509 // for AbortVMOnException flag 2510 NOT_PRODUCT(Exceptions::debug_check_abort(except_oop)); 2511 goto run; 2512 } 2513 if (TraceExceptions) { 2514 ttyLocker ttyl; 2515 ResourceMark rm; 2516 tty->print_cr("Exception <%s> (" INTPTR_FORMAT ")", except_oop->print_value_string(), except_oop()); 2517 tty->print_cr(" thrown in interpreter method <%s>", METHOD->print_value_string()); 2518 tty->print_cr(" at bci %d, unwinding for thread " INTPTR_FORMAT, 2519 pc - (intptr_t) METHOD->code_base(), 2520 THREAD); 2521 } 2522 // for AbortVMOnException flag 2523 NOT_PRODUCT(Exceptions::debug_check_abort(except_oop)); 2524 // No handler in this activation, unwind and try again 2525 THREAD->set_pending_exception(except_oop(), NULL, 0); 2526 goto handle_return; 2527 } /* handle_exception: */ 2528 2529 2530 2531 // Return from an interpreter invocation with the result of the interpretation 2532 // on the top of the Java Stack (or a pending exception) 2533 2534 handle_Pop_Frame: 2535 2536 // We don't really do anything special here except we must be aware 2537 // that we can get here without ever locking the method (if sync). 2538 // Also we skip the notification of the exit. 2539 2540 istate->set_msg(popping_frame); 2541 // Clear pending so while the pop is in process 2542 // we don't start another one if a call_vm is done. 2543 THREAD->clr_pop_frame_pending(); 2544 // Let interpreter (only) see the we're in the process of popping a frame 2545 THREAD->set_pop_frame_in_process(); 2546 2547 handle_return: 2548 { 2549 DECACHE_STATE(); 2550 2551 bool suppress_error = istate->msg() == popping_frame; 2552 bool suppress_exit_event = THREAD->has_pending_exception() || suppress_error; 2553 Handle original_exception(THREAD, THREAD->pending_exception()); 2554 Handle illegal_state_oop(THREAD, NULL); 2555 2556 // We'd like a HandleMark here to prevent any subsequent HandleMarkCleaner 2557 // in any following VM entries from freeing our live handles, but illegal_state_oop 2558 // isn't really allocated yet and so doesn't become live until later and 2559 // in unpredicatable places. Instead we must protect the places where we enter the 2560 // VM. It would be much simpler (and safer) if we could allocate a real handle with 2561 // a NULL oop in it and then overwrite the oop later as needed. This isn't 2562 // unfortunately isn't possible. 2563 2564 THREAD->clear_pending_exception(); 2565 2566 // 2567 // As far as we are concerned we have returned. If we have a pending exception 2568 // that will be returned as this invocation's result. However if we get any 2569 // exception(s) while checking monitor state one of those IllegalMonitorStateExceptions 2570 // will be our final result (i.e. monitor exception trumps a pending exception). 2571 // 2572 2573 // If we never locked the method (or really passed the point where we would have), 2574 // there is no need to unlock it (or look for other monitors), since that 2575 // could not have happened. 2576 2577 if (THREAD->do_not_unlock()) { 2578 2579 // Never locked, reset the flag now because obviously any caller must 2580 // have passed their point of locking for us to have gotten here. 2581 2582 THREAD->clr_do_not_unlock(); 2583 } else { 2584 // At this point we consider that we have returned. We now check that the 2585 // locks were properly block structured. If we find that they were not 2586 // used properly we will return with an illegal monitor exception. 2587 // The exception is checked by the caller not the callee since this 2588 // checking is considered to be part of the invocation and therefore 2589 // in the callers scope (JVM spec 8.13). 2590 // 2591 // Another weird thing to watch for is if the method was locked 2592 // recursively and then not exited properly. This means we must 2593 // examine all the entries in reverse time(and stack) order and 2594 // unlock as we find them. If we find the method monitor before 2595 // we are at the initial entry then we should throw an exception. 2596 // It is not clear the template based interpreter does this 2597 // correctly 2598 2599 BasicObjectLock* base = istate->monitor_base(); 2600 BasicObjectLock* end = (BasicObjectLock*) istate->stack_base(); 2601 bool method_unlock_needed = METHOD->is_synchronized(); 2602 // We know the initial monitor was used for the method don't check that 2603 // slot in the loop 2604 if (method_unlock_needed) base--; 2605 2606 // Check all the monitors to see they are unlocked. Install exception if found to be locked. 2607 while (end < base) { 2608 oop lockee = end->obj(); 2609 if (lockee != NULL) { 2610 BasicLock* lock = end->lock(); 2611 markOop header = lock->displaced_header(); 2612 end->set_obj(NULL); 2613 // If it isn't recursive we either must swap old header or call the runtime 2614 if (header != NULL) { 2615 if (Atomic::cmpxchg_ptr(header, lockee->mark_addr(), lock) != lock) { 2616 // restore object for the slow case 2617 end->set_obj(lockee); 2618 { 2619 // Prevent any HandleMarkCleaner from freeing our live handles 2620 HandleMark __hm(THREAD); 2621 CALL_VM_NOCHECK(InterpreterRuntime::monitorexit(THREAD, end)); 2622 } 2623 } 2624 } 2625 // One error is plenty 2626 if (illegal_state_oop() == NULL && !suppress_error) { 2627 { 2628 // Prevent any HandleMarkCleaner from freeing our live handles 2629 HandleMark __hm(THREAD); 2630 CALL_VM_NOCHECK(InterpreterRuntime::throw_illegal_monitor_state_exception(THREAD)); 2631 } 2632 assert(THREAD->has_pending_exception(), "Lost our exception!"); 2633 illegal_state_oop = THREAD->pending_exception(); 2634 THREAD->clear_pending_exception(); 2635 } 2636 } 2637 end++; 2638 } 2639 // Unlock the method if needed 2640 if (method_unlock_needed) { 2641 if (base->obj() == NULL) { 2642 // The method is already unlocked this is not good. 2643 if (illegal_state_oop() == NULL && !suppress_error) { 2644 { 2645 // Prevent any HandleMarkCleaner from freeing our live handles 2646 HandleMark __hm(THREAD); 2647 CALL_VM_NOCHECK(InterpreterRuntime::throw_illegal_monitor_state_exception(THREAD)); 2648 } 2649 assert(THREAD->has_pending_exception(), "Lost our exception!"); 2650 illegal_state_oop = THREAD->pending_exception(); 2651 THREAD->clear_pending_exception(); 2652 } 2653 } else { 2654 // 2655 // The initial monitor is always used for the method 2656 // However if that slot is no longer the oop for the method it was unlocked 2657 // and reused by something that wasn't unlocked! 2658 // 2659 // deopt can come in with rcvr dead because c2 knows 2660 // its value is preserved in the monitor. So we can't use locals[0] at all 2661 // and must use first monitor slot. 2662 // 2663 oop rcvr = base->obj(); 2664 if (rcvr == NULL) { 2665 if (!suppress_error) { 2666 VM_JAVA_ERROR_NO_JUMP(vmSymbols::java_lang_NullPointerException(), ""); 2667 illegal_state_oop = THREAD->pending_exception(); 2668 THREAD->clear_pending_exception(); 2669 } 2670 } else { 2671 BasicLock* lock = base->lock(); 2672 markOop header = lock->displaced_header(); 2673 base->set_obj(NULL); 2674 // If it isn't recursive we either must swap old header or call the runtime 2675 if (header != NULL) { 2676 if (Atomic::cmpxchg_ptr(header, rcvr->mark_addr(), lock) != lock) { 2677 // restore object for the slow case 2678 base->set_obj(rcvr); 2679 { 2680 // Prevent any HandleMarkCleaner from freeing our live handles 2681 HandleMark __hm(THREAD); 2682 CALL_VM_NOCHECK(InterpreterRuntime::monitorexit(THREAD, base)); 2683 } 2684 if (THREAD->has_pending_exception()) { 2685 if (!suppress_error) illegal_state_oop = THREAD->pending_exception(); 2686 THREAD->clear_pending_exception(); 2687 } 2688 } 2689 } 2690 } 2691 } 2692 } 2693 } 2694 2695 // 2696 // Notify jvmti/jvmdi 2697 // 2698 // NOTE: we do not notify a method_exit if we have a pending exception, 2699 // including an exception we generate for unlocking checks. In the former 2700 // case, JVMDI has already been notified by our call for the exception handler 2701 // and in both cases as far as JVMDI is concerned we have already returned. 2702 // If we notify it again JVMDI will be all confused about how many frames 2703 // are still on the stack (4340444). 2704 // 2705 // NOTE Further! It turns out the the JVMTI spec in fact expects to see 2706 // method_exit events whenever we leave an activation unless it was done 2707 // for popframe. This is nothing like jvmdi. However we are passing the 2708 // tests at the moment (apparently because they are jvmdi based) so rather 2709 // than change this code and possibly fail tests we will leave it alone 2710 // (with this note) in anticipation of changing the vm and the tests 2711 // simultaneously. 2712 2713 2714 // 2715 suppress_exit_event = suppress_exit_event || illegal_state_oop() != NULL; 2716 2717 2718 2719 #ifdef VM_JVMTI 2720 if (_jvmti_interp_events) { 2721 // Whenever JVMTI puts a thread in interp_only_mode, method 2722 // entry/exit events are sent for that thread to track stack depth. 2723 if ( !suppress_exit_event && THREAD->is_interp_only_mode() ) { 2724 { 2725 // Prevent any HandleMarkCleaner from freeing our live handles 2726 HandleMark __hm(THREAD); 2727 CALL_VM_NOCHECK(InterpreterRuntime::post_method_exit(THREAD)); 2728 } 2729 } 2730 } 2731 #endif /* VM_JVMTI */ 2732 2733 // 2734 // See if we are returning any exception 2735 // A pending exception that was pending prior to a possible popping frame 2736 // overrides the popping frame. 2737 // 2738 assert(!suppress_error || suppress_error && illegal_state_oop() == NULL, "Error was not suppressed"); 2739 if (illegal_state_oop() != NULL || original_exception() != NULL) { 2740 // inform the frame manager we have no result 2741 istate->set_msg(throwing_exception); 2742 if (illegal_state_oop() != NULL) 2743 THREAD->set_pending_exception(illegal_state_oop(), NULL, 0); 2744 else 2745 THREAD->set_pending_exception(original_exception(), NULL, 0); 2746 istate->set_return_kind((Bytecodes::Code)opcode); 2747 UPDATE_PC_AND_RETURN(0); 2748 } 2749 2750 if (istate->msg() == popping_frame) { 2751 // Make it simpler on the assembly code and set the message for the frame pop. 2752 // returns 2753 if (istate->prev() == NULL) { 2754 // We must be returning to a deoptimized frame (because popframe only happens between 2755 // two interpreted frames). We need to save the current arguments in C heap so that 2756 // the deoptimized frame when it restarts can copy the arguments to its expression 2757 // stack and re-execute the call. We also have to notify deoptimization that this 2758 // has occurred and to pick the preserved args copy them to the deoptimized frame's 2759 // java expression stack. Yuck. 2760 // 2761 THREAD->popframe_preserve_args(in_ByteSize(METHOD->size_of_parameters() * wordSize), 2762 LOCALS_SLOT(METHOD->size_of_parameters() - 1)); 2763 THREAD->set_popframe_condition_bit(JavaThread::popframe_force_deopt_reexecution_bit); 2764 } 2765 THREAD->clr_pop_frame_in_process(); 2766 } 2767 2768 // Normal return 2769 // Advance the pc and return to frame manager 2770 istate->set_msg(return_from_method); 2771 istate->set_return_kind((Bytecodes::Code)opcode); 2772 UPDATE_PC_AND_RETURN(1); 2773 } /* handle_return: */ 2774 2775 // This is really a fatal error return 2776 2777 finish: 2778 DECACHE_TOS(); 2779 DECACHE_PC(); 2780 2781 return; 2782 } 2783 2784 /* 2785 * All the code following this point is only produced once and is not present 2786 * in the JVMTI version of the interpreter 2787 */ 2788 2789 #ifndef VM_JVMTI 2790 2791 // This constructor should only be used to contruct the object to signal 2792 // interpreter initialization. All other instances should be created by 2793 // the frame manager. 2794 BytecodeInterpreter::BytecodeInterpreter(messages msg) { 2795 if (msg != initialize) ShouldNotReachHere(); 2796 _msg = msg; 2797 _self_link = this; 2798 _prev_link = NULL; 2799 } 2800 2801 // Inline static functions for Java Stack and Local manipulation 2802 2803 // The implementations are platform dependent. We have to worry about alignment 2804 // issues on some machines which can change on the same platform depending on 2805 // whether it is an LP64 machine also. 2806 address BytecodeInterpreter::stack_slot(intptr_t *tos, int offset) { 2807 return (address) tos[Interpreter::expr_index_at(-offset)]; 2808 } 2809 2810 jint BytecodeInterpreter::stack_int(intptr_t *tos, int offset) { 2811 return *((jint*) &tos[Interpreter::expr_index_at(-offset)]); 2812 } 2813 2814 jfloat BytecodeInterpreter::stack_float(intptr_t *tos, int offset) { 2815 return *((jfloat *) &tos[Interpreter::expr_index_at(-offset)]); 2816 } 2817 2818 oop BytecodeInterpreter::stack_object(intptr_t *tos, int offset) { 2819 return (oop)tos [Interpreter::expr_index_at(-offset)]; 2820 } 2821 2822 jdouble BytecodeInterpreter::stack_double(intptr_t *tos, int offset) { 2823 return ((VMJavaVal64*) &tos[Interpreter::expr_index_at(-offset)])->d; 2824 } 2825 2826 jlong BytecodeInterpreter::stack_long(intptr_t *tos, int offset) { 2827 return ((VMJavaVal64 *) &tos[Interpreter::expr_index_at(-offset)])->l; 2828 } 2829 2830 // only used for value types 2831 void BytecodeInterpreter::set_stack_slot(intptr_t *tos, address value, 2832 int offset) { 2833 *((address *)&tos[Interpreter::expr_index_at(-offset)]) = value; 2834 } 2835 2836 void BytecodeInterpreter::set_stack_int(intptr_t *tos, int value, 2837 int offset) { 2838 *((jint *)&tos[Interpreter::expr_index_at(-offset)]) = value; 2839 } 2840 2841 void BytecodeInterpreter::set_stack_float(intptr_t *tos, jfloat value, 2842 int offset) { 2843 *((jfloat *)&tos[Interpreter::expr_index_at(-offset)]) = value; 2844 } 2845 2846 void BytecodeInterpreter::set_stack_object(intptr_t *tos, oop value, 2847 int offset) { 2848 *((oop *)&tos[Interpreter::expr_index_at(-offset)]) = value; 2849 } 2850 2851 // needs to be platform dep for the 32 bit platforms. 2852 void BytecodeInterpreter::set_stack_double(intptr_t *tos, jdouble value, 2853 int offset) { 2854 ((VMJavaVal64*)&tos[Interpreter::expr_index_at(-offset)])->d = value; 2855 } 2856 2857 void BytecodeInterpreter::set_stack_double_from_addr(intptr_t *tos, 2858 address addr, int offset) { 2859 (((VMJavaVal64*)&tos[Interpreter::expr_index_at(-offset)])->d = 2860 ((VMJavaVal64*)addr)->d); 2861 } 2862 2863 void BytecodeInterpreter::set_stack_long(intptr_t *tos, jlong value, 2864 int offset) { 2865 ((VMJavaVal64*)&tos[Interpreter::expr_index_at(-offset+1)])->l = 0xdeedbeeb; 2866 ((VMJavaVal64*)&tos[Interpreter::expr_index_at(-offset)])->l = value; 2867 } 2868 2869 void BytecodeInterpreter::set_stack_long_from_addr(intptr_t *tos, 2870 address addr, int offset) { 2871 ((VMJavaVal64*)&tos[Interpreter::expr_index_at(-offset+1)])->l = 0xdeedbeeb; 2872 ((VMJavaVal64*)&tos[Interpreter::expr_index_at(-offset)])->l = 2873 ((VMJavaVal64*)addr)->l; 2874 } 2875 2876 // Locals 2877 2878 address BytecodeInterpreter::locals_slot(intptr_t* locals, int offset) { 2879 return (address)locals[Interpreter::local_index_at(-offset)]; 2880 } 2881 jint BytecodeInterpreter::locals_int(intptr_t* locals, int offset) { 2882 return (jint)locals[Interpreter::local_index_at(-offset)]; 2883 } 2884 jfloat BytecodeInterpreter::locals_float(intptr_t* locals, int offset) { 2885 return (jfloat)locals[Interpreter::local_index_at(-offset)]; 2886 } 2887 oop BytecodeInterpreter::locals_object(intptr_t* locals, int offset) { 2888 return (oop)locals[Interpreter::local_index_at(-offset)]; 2889 } 2890 jdouble BytecodeInterpreter::locals_double(intptr_t* locals, int offset) { 2891 return ((VMJavaVal64*)&locals[Interpreter::local_index_at(-(offset+1))])->d; 2892 } 2893 jlong BytecodeInterpreter::locals_long(intptr_t* locals, int offset) { 2894 return ((VMJavaVal64*)&locals[Interpreter::local_index_at(-(offset+1))])->l; 2895 } 2896 2897 // Returns the address of locals value. 2898 address BytecodeInterpreter::locals_long_at(intptr_t* locals, int offset) { 2899 return ((address)&locals[Interpreter::local_index_at(-(offset+1))]); 2900 } 2901 address BytecodeInterpreter::locals_double_at(intptr_t* locals, int offset) { 2902 return ((address)&locals[Interpreter::local_index_at(-(offset+1))]); 2903 } 2904 2905 // Used for local value or returnAddress 2906 void BytecodeInterpreter::set_locals_slot(intptr_t *locals, 2907 address value, int offset) { 2908 *((address*)&locals[Interpreter::local_index_at(-offset)]) = value; 2909 } 2910 void BytecodeInterpreter::set_locals_int(intptr_t *locals, 2911 jint value, int offset) { 2912 *((jint *)&locals[Interpreter::local_index_at(-offset)]) = value; 2913 } 2914 void BytecodeInterpreter::set_locals_float(intptr_t *locals, 2915 jfloat value, int offset) { 2916 *((jfloat *)&locals[Interpreter::local_index_at(-offset)]) = value; 2917 } 2918 void BytecodeInterpreter::set_locals_object(intptr_t *locals, 2919 oop value, int offset) { 2920 *((oop *)&locals[Interpreter::local_index_at(-offset)]) = value; 2921 } 2922 void BytecodeInterpreter::set_locals_double(intptr_t *locals, 2923 jdouble value, int offset) { 2924 ((VMJavaVal64*)&locals[Interpreter::local_index_at(-(offset+1))])->d = value; 2925 } 2926 void BytecodeInterpreter::set_locals_long(intptr_t *locals, 2927 jlong value, int offset) { 2928 ((VMJavaVal64*)&locals[Interpreter::local_index_at(-(offset+1))])->l = value; 2929 } 2930 void BytecodeInterpreter::set_locals_double_from_addr(intptr_t *locals, 2931 address addr, int offset) { 2932 ((VMJavaVal64*)&locals[Interpreter::local_index_at(-(offset+1))])->d = ((VMJavaVal64*)addr)->d; 2933 } 2934 void BytecodeInterpreter::set_locals_long_from_addr(intptr_t *locals, 2935 address addr, int offset) { 2936 ((VMJavaVal64*)&locals[Interpreter::local_index_at(-(offset+1))])->l = ((VMJavaVal64*)addr)->l; 2937 } 2938 2939 void BytecodeInterpreter::astore(intptr_t* tos, int stack_offset, 2940 intptr_t* locals, int locals_offset) { 2941 intptr_t value = tos[Interpreter::expr_index_at(-stack_offset)]; 2942 locals[Interpreter::local_index_at(-locals_offset)] = value; 2943 } 2944 2945 2946 void BytecodeInterpreter::copy_stack_slot(intptr_t *tos, int from_offset, 2947 int to_offset) { 2948 tos[Interpreter::expr_index_at(-to_offset)] = 2949 (intptr_t)tos[Interpreter::expr_index_at(-from_offset)]; 2950 } 2951 2952 void BytecodeInterpreter::dup(intptr_t *tos) { 2953 copy_stack_slot(tos, -1, 0); 2954 } 2955 void BytecodeInterpreter::dup2(intptr_t *tos) { 2956 copy_stack_slot(tos, -2, 0); 2957 copy_stack_slot(tos, -1, 1); 2958 } 2959 2960 void BytecodeInterpreter::dup_x1(intptr_t *tos) { 2961 /* insert top word two down */ 2962 copy_stack_slot(tos, -1, 0); 2963 copy_stack_slot(tos, -2, -1); 2964 copy_stack_slot(tos, 0, -2); 2965 } 2966 2967 void BytecodeInterpreter::dup_x2(intptr_t *tos) { 2968 /* insert top word three down */ 2969 copy_stack_slot(tos, -1, 0); 2970 copy_stack_slot(tos, -2, -1); 2971 copy_stack_slot(tos, -3, -2); 2972 copy_stack_slot(tos, 0, -3); 2973 } 2974 void BytecodeInterpreter::dup2_x1(intptr_t *tos) { 2975 /* insert top 2 slots three down */ 2976 copy_stack_slot(tos, -1, 1); 2977 copy_stack_slot(tos, -2, 0); 2978 copy_stack_slot(tos, -3, -1); 2979 copy_stack_slot(tos, 1, -2); 2980 copy_stack_slot(tos, 0, -3); 2981 } 2982 void BytecodeInterpreter::dup2_x2(intptr_t *tos) { 2983 /* insert top 2 slots four down */ 2984 copy_stack_slot(tos, -1, 1); 2985 copy_stack_slot(tos, -2, 0); 2986 copy_stack_slot(tos, -3, -1); 2987 copy_stack_slot(tos, -4, -2); 2988 copy_stack_slot(tos, 1, -3); 2989 copy_stack_slot(tos, 0, -4); 2990 } 2991 2992 2993 void BytecodeInterpreter::swap(intptr_t *tos) { 2994 // swap top two elements 2995 intptr_t val = tos[Interpreter::expr_index_at(1)]; 2996 // Copy -2 entry to -1 2997 copy_stack_slot(tos, -2, -1); 2998 // Store saved -1 entry into -2 2999 tos[Interpreter::expr_index_at(2)] = val; 3000 } 3001 // -------------------------------------------------------------------------------- 3002 // Non-product code 3003 #ifndef PRODUCT 3004 3005 const char* BytecodeInterpreter::C_msg(BytecodeInterpreter::messages msg) { 3006 switch (msg) { 3007 case BytecodeInterpreter::no_request: return("no_request"); 3008 case BytecodeInterpreter::initialize: return("initialize"); 3009 // status message to C++ interpreter 3010 case BytecodeInterpreter::method_entry: return("method_entry"); 3011 case BytecodeInterpreter::method_resume: return("method_resume"); 3012 case BytecodeInterpreter::got_monitors: return("got_monitors"); 3013 case BytecodeInterpreter::rethrow_exception: return("rethrow_exception"); 3014 // requests to frame manager from C++ interpreter 3015 case BytecodeInterpreter::call_method: return("call_method"); 3016 case BytecodeInterpreter::return_from_method: return("return_from_method"); 3017 case BytecodeInterpreter::more_monitors: return("more_monitors"); 3018 case BytecodeInterpreter::throwing_exception: return("throwing_exception"); 3019 case BytecodeInterpreter::popping_frame: return("popping_frame"); 3020 case BytecodeInterpreter::do_osr: return("do_osr"); 3021 // deopt 3022 case BytecodeInterpreter::deopt_resume: return("deopt_resume"); 3023 case BytecodeInterpreter::deopt_resume2: return("deopt_resume2"); 3024 default: return("BAD MSG"); 3025 } 3026 } 3027 void 3028 BytecodeInterpreter::print() { 3029 tty->print_cr("thread: " INTPTR_FORMAT, (uintptr_t) this->_thread); 3030 tty->print_cr("bcp: " INTPTR_FORMAT, (uintptr_t) this->_bcp); 3031 tty->print_cr("locals: " INTPTR_FORMAT, (uintptr_t) this->_locals); 3032 tty->print_cr("constants: " INTPTR_FORMAT, (uintptr_t) this->_constants); 3033 { 3034 ResourceMark rm; 3035 char *method_name = _method->name_and_sig_as_C_string(); 3036 tty->print_cr("method: " INTPTR_FORMAT "[ %s ]", (uintptr_t) this->_method, method_name); 3037 } 3038 tty->print_cr("mdx: " INTPTR_FORMAT, (uintptr_t) this->_mdx); 3039 tty->print_cr("stack: " INTPTR_FORMAT, (uintptr_t) this->_stack); 3040 tty->print_cr("msg: %s", C_msg(this->_msg)); 3041 tty->print_cr("result_to_call._callee: " INTPTR_FORMAT, (uintptr_t) this->_result._to_call._callee); 3042 tty->print_cr("result_to_call._callee_entry_point: " INTPTR_FORMAT, (uintptr_t) this->_result._to_call._callee_entry_point); 3043 tty->print_cr("result_to_call._bcp_advance: %d ", this->_result._to_call._bcp_advance); 3044 tty->print_cr("osr._osr_buf: " INTPTR_FORMAT, (uintptr_t) this->_result._osr._osr_buf); 3045 tty->print_cr("osr._osr_entry: " INTPTR_FORMAT, (uintptr_t) this->_result._osr._osr_entry); 3046 tty->print_cr("result_return_kind 0x%x ", (int) this->_result._return_kind); 3047 tty->print_cr("prev_link: " INTPTR_FORMAT, (uintptr_t) this->_prev_link); 3048 tty->print_cr("native_mirror: " INTPTR_FORMAT, (uintptr_t) this->_oop_temp); 3049 tty->print_cr("stack_base: " INTPTR_FORMAT, (uintptr_t) this->_stack_base); 3050 tty->print_cr("stack_limit: " INTPTR_FORMAT, (uintptr_t) this->_stack_limit); 3051 tty->print_cr("monitor_base: " INTPTR_FORMAT, (uintptr_t) this->_monitor_base); 3052 #ifdef SPARC 3053 tty->print_cr("last_Java_pc: " INTPTR_FORMAT, (uintptr_t) this->_last_Java_pc); 3054 tty->print_cr("frame_bottom: " INTPTR_FORMAT, (uintptr_t) this->_frame_bottom); 3055 tty->print_cr("&native_fresult: " INTPTR_FORMAT, (uintptr_t) &this->_native_fresult); 3056 tty->print_cr("native_lresult: " INTPTR_FORMAT, (uintptr_t) this->_native_lresult); 3057 #endif 3058 #if defined(IA64) && !defined(ZERO) 3059 tty->print_cr("last_Java_fp: " INTPTR_FORMAT, (uintptr_t) this->_last_Java_fp); 3060 #endif // IA64 && !ZERO 3061 tty->print_cr("self_link: " INTPTR_FORMAT, (uintptr_t) this->_self_link); 3062 } 3063 3064 extern "C" { 3065 void PI(uintptr_t arg) { 3066 ((BytecodeInterpreter*)arg)->print(); 3067 } 3068 } 3069 #endif // PRODUCT 3070 3071 #endif // JVMTI 3072 #endif // CC_INTERP