1 /* 2 * Copyright (c) 1997, 2026, Oracle and/or its affiliates. All rights reserved. 3 * Copyright (c) 2014, 2024, Red Hat Inc. All rights reserved. 4 * DO NOT ALTER OR REMOVE COPYRIGHT NOTICES OR THIS FILE HEADER. 5 * 6 * This code is free software; you can redistribute it and/or modify it 7 * under the terms of the GNU General Public License version 2 only, as 8 * published by the Free Software Foundation. 9 * 10 * This code is distributed in the hope that it will be useful, but WITHOUT 11 * ANY WARRANTY; without even the implied warranty of MERCHANTABILITY or 12 * FITNESS FOR A PARTICULAR PURPOSE. See the GNU General Public License 13 * version 2 for more details (a copy is included in the LICENSE file that 14 * accompanied this code). 15 * 16 * You should have received a copy of the GNU General Public License version 17 * 2 along with this work; if not, write to the Free Software Foundation, 18 * Inc., 51 Franklin St, Fifth Floor, Boston, MA 02110-1301 USA. 19 * 20 * Please contact Oracle, 500 Oracle Parkway, Redwood Shores, CA 94065 USA 21 * or visit www.oracle.com if you need additional information or have any 22 * questions. 23 * 24 */ 25 26 #include "asm/assembler.hpp" 27 #include "asm/assembler.inline.hpp" 28 #include "ci/ciEnv.hpp" 29 #include "ci/ciInlineKlass.hpp" 30 #include "code/compiledIC.hpp" 31 #include "compiler/compileTask.hpp" 32 #include "compiler/disassembler.hpp" 33 #include "compiler/oopMap.hpp" 34 #include "gc/shared/barrierSet.hpp" 35 #include "gc/shared/barrierSetAssembler.hpp" 36 #include "gc/shared/cardTableBarrierSet.hpp" 37 #include "gc/shared/cardTable.hpp" 38 #include "gc/shared/collectedHeap.hpp" 39 #include "gc/shared/tlab_globals.hpp" 40 #include "interpreter/bytecodeHistogram.hpp" 41 #include "interpreter/interpreter.hpp" 42 #include "interpreter/interpreterRuntime.hpp" 43 #include "jvm.h" 44 #include "memory/resourceArea.hpp" 45 #include "memory/universe.hpp" 46 #include "nativeInst_aarch64.hpp" 47 #include "oops/accessDecorators.hpp" 48 #include "oops/compressedKlass.inline.hpp" 49 #include "oops/compressedOops.inline.hpp" 50 #include "oops/klass.inline.hpp" 51 #include "oops/resolvedFieldEntry.hpp" 52 #include "runtime/arguments.hpp" 53 #include "runtime/continuation.hpp" 54 #include "runtime/globals.hpp" 55 #include "runtime/icache.hpp" 56 #include "runtime/interfaceSupport.inline.hpp" 57 #include "runtime/javaThread.hpp" 58 #include "runtime/jniHandles.inline.hpp" 59 #include "runtime/sharedRuntime.hpp" 60 #include "runtime/signature_cc.hpp" 61 #include "runtime/stubRoutines.hpp" 62 #include "utilities/globalDefinitions.hpp" 63 #include "utilities/integerCast.hpp" 64 #include "utilities/powerOfTwo.hpp" 65 #include "vmreg_aarch64.inline.hpp" 66 #ifdef COMPILER1 67 #include "c1/c1_LIRAssembler.hpp" 68 #endif 69 #ifdef COMPILER2 70 #include "oops/oop.hpp" 71 #include "opto/compile.hpp" 72 #include "opto/node.hpp" 73 #include "opto/output.hpp" 74 #endif 75 76 #include <sys/types.h> 77 78 #ifdef PRODUCT 79 #define BLOCK_COMMENT(str) /* nothing */ 80 #else 81 #define BLOCK_COMMENT(str) block_comment(str) 82 #endif 83 #define STOP(str) stop(str); 84 #define BIND(label) bind(label); BLOCK_COMMENT(#label ":") 85 86 #ifdef ASSERT 87 extern "C" void disnm(intptr_t p); 88 #endif 89 // Target-dependent relocation processing 90 // 91 // Instruction sequences whose target may need to be retrieved or 92 // patched are distinguished by their leading instruction, sorting 93 // them into three main instruction groups and related subgroups. 94 // 95 // 1) Branch, Exception and System (insn count = 1) 96 // 1a) Unconditional branch (immediate): 97 // b/bl imm19 98 // 1b) Compare & branch (immediate): 99 // cbz/cbnz Rt imm19 100 // 1c) Test & branch (immediate): 101 // tbz/tbnz Rt imm14 102 // 1d) Conditional branch (immediate): 103 // b.cond imm19 104 // 105 // 2) Loads and Stores (insn count = 1) 106 // 2a) Load register literal: 107 // ldr Rt imm19 108 // 109 // 3) Data Processing Immediate (insn count = 2 or 3) 110 // 3a) PC-rel. addressing 111 // adr/adrp Rx imm21; ldr/str Ry Rx #imm12 112 // adr/adrp Rx imm21; add Ry Rx #imm12 113 // adr/adrp Rx imm21; movk Rx #imm16<<32; ldr/str Ry, [Rx, #offset_in_page] 114 // adr/adrp Rx imm21 115 // adr/adrp Rx imm21; movk Rx #imm16<<32 116 // adr/adrp Rx imm21; movk Rx #imm16<<32; add Ry, Rx, #offset_in_page 117 // The latter form can only happen when the target is an 118 // ExternalAddress, and (by definition) ExternalAddresses don't 119 // move. Because of that property, there is never any need to 120 // patch the last of the three instructions. However, 121 // MacroAssembler::target_addr_for_insn takes all three 122 // instructions into account and returns the correct address. 123 // 3b) Move wide (immediate) 124 // movz Rx #imm16; movk Rx #imm16 << 16; movk Rx #imm16 << 32; 125 // 126 // A switch on a subset of the instruction's bits provides an 127 // efficient dispatch to these subcases. 128 // 129 // insn[28:26] -> main group ('x' == don't care) 130 // 00x -> UNALLOCATED 131 // 100 -> Data Processing Immediate 132 // 101 -> Branch, Exception and System 133 // x1x -> Loads and Stores 134 // 135 // insn[30:25] -> subgroup ('_' == group, 'x' == don't care). 136 // n.b. in some cases extra bits need to be checked to verify the 137 // instruction is as expected 138 // 139 // 1) ... xx101x Branch, Exception and System 140 // 1a) 00___x Unconditional branch (immediate) 141 // 1b) 01___0 Compare & branch (immediate) 142 // 1c) 01___1 Test & branch (immediate) 143 // 1d) 10___0 Conditional branch (immediate) 144 // other Should not happen 145 // 146 // 2) ... xxx1x0 Loads and Stores 147 // 2a) xx1__00 Load/Store register (insn[28] == 1 && insn[24] == 0) 148 // 2aa) x01__00 Load register literal (i.e. requires insn[29] == 0) 149 // strictly should be 64 bit non-FP/SIMD i.e. 150 // 0101_000 (i.e. requires insn[31:24] == 01011000) 151 // 152 // 3) ... xx100x Data Processing Immediate 153 // 3a) xx___00 PC-rel. addressing (n.b. requires insn[24] == 0) 154 // 3b) xx___101 Move wide (immediate) (n.b. requires insn[24:23] == 01) 155 // strictly should be 64 bit movz #imm16<<0 156 // 110___10100 (i.e. requires insn[31:21] == 11010010100) 157 // 158 159 static uint32_t insn_at(address insn_addr, int n) { 160 return ((uint32_t*)insn_addr)[n]; 161 } 162 163 template<typename T> 164 class RelocActions : public AllStatic { 165 166 public: 167 168 static int ALWAYSINLINE run(address insn_addr, address &target) { 169 int instructions = 1; 170 uint32_t insn = insn_at(insn_addr, 0); 171 172 uint32_t dispatch = Instruction_aarch64::extract(insn, 30, 25); 173 switch(dispatch) { 174 case 0b001010: 175 case 0b001011: { 176 instructions = T::unconditionalBranch(insn_addr, target); 177 break; 178 } 179 case 0b101010: // Conditional branch (immediate) 180 case 0b011010: { // Compare & branch (immediate) 181 instructions = T::conditionalBranch(insn_addr, target); 182 break; 183 } 184 case 0b011011: { 185 instructions = T::testAndBranch(insn_addr, target); 186 break; 187 } 188 case 0b001100: 189 case 0b001110: 190 case 0b011100: 191 case 0b011110: 192 case 0b101100: 193 case 0b101110: 194 case 0b111100: 195 case 0b111110: { 196 // load/store 197 if ((Instruction_aarch64::extract(insn, 29, 24) & 0b111011) == 0b011000) { 198 // Load register (literal) 199 instructions = T::loadStore(insn_addr, target); 200 break; 201 } else { 202 // nothing to do 203 assert(target == nullptr, "did not expect to relocate target for polling page load"); 204 } 205 break; 206 } 207 case 0b001000: 208 case 0b011000: 209 case 0b101000: 210 case 0b111000: { 211 // adr/adrp 212 assert(Instruction_aarch64::extract(insn, 28, 24) == 0b10000, "must be"); 213 int shift = Instruction_aarch64::extract(insn, 31, 31); 214 if (shift) { 215 uint32_t insn2 = insn_at(insn_addr, 1); 216 if (Instruction_aarch64::extract(insn2, 29, 24) == 0b111001 && 217 Instruction_aarch64::extract(insn, 4, 0) == 218 Instruction_aarch64::extract(insn2, 9, 5)) { 219 instructions = T::adrp(insn_addr, target, T::adrpMem); 220 } else if (Instruction_aarch64::extract(insn2, 31, 22) == 0b1001000100 && 221 Instruction_aarch64::extract(insn, 4, 0) == 222 Instruction_aarch64::extract(insn2, 4, 0)) { 223 instructions = T::adrp(insn_addr, target, T::adrpAdd); 224 } else if (Instruction_aarch64::extract(insn2, 31, 21) == 0b11110010110 && 225 Instruction_aarch64::extract(insn, 4, 0) == 226 Instruction_aarch64::extract(insn2, 4, 0)) { 227 instructions = T::adrp(insn_addr, target, T::adrpMovk); 228 } else { 229 ShouldNotReachHere(); 230 } 231 } else { 232 instructions = T::adr(insn_addr, target); 233 } 234 break; 235 } 236 case 0b001001: 237 case 0b011001: 238 case 0b101001: 239 case 0b111001: { 240 instructions = T::immediate(insn_addr, target); 241 break; 242 } 243 default: { 244 ShouldNotReachHere(); 245 } 246 } 247 248 T::verify(insn_addr, target); 249 return instructions * NativeInstruction::instruction_size; 250 } 251 }; 252 253 class Patcher : public AllStatic { 254 public: 255 static int unconditionalBranch(address insn_addr, address &target) { 256 intptr_t offset = (target - insn_addr) >> 2; 257 Instruction_aarch64::spatch(insn_addr, 25, 0, offset); 258 return 1; 259 } 260 static int conditionalBranch(address insn_addr, address &target) { 261 intptr_t offset = (target - insn_addr) >> 2; 262 Instruction_aarch64::spatch(insn_addr, 23, 5, offset); 263 return 1; 264 } 265 static int testAndBranch(address insn_addr, address &target) { 266 intptr_t offset = (target - insn_addr) >> 2; 267 Instruction_aarch64::spatch(insn_addr, 18, 5, offset); 268 return 1; 269 } 270 static int loadStore(address insn_addr, address &target) { 271 intptr_t offset = (target - insn_addr) >> 2; 272 Instruction_aarch64::spatch(insn_addr, 23, 5, offset); 273 return 1; 274 } 275 static int adr(address insn_addr, address &target) { 276 #ifdef ASSERT 277 assert(Instruction_aarch64::extract(insn_at(insn_addr, 0), 28, 24) == 0b10000, "must be"); 278 #endif 279 // PC-rel. addressing 280 ptrdiff_t offset = target - insn_addr; 281 int offset_lo = offset & 3; 282 offset >>= 2; 283 Instruction_aarch64::spatch(insn_addr, 23, 5, offset); 284 Instruction_aarch64::patch(insn_addr, 30, 29, offset_lo); 285 return 1; 286 } 287 template<typename U> 288 static int adrp(address insn_addr, address &target, U inner) { 289 int instructions = 1; 290 #ifdef ASSERT 291 assert(Instruction_aarch64::extract(insn_at(insn_addr, 0), 28, 24) == 0b10000, "must be"); 292 #endif 293 ptrdiff_t offset = target - insn_addr; 294 instructions = 2; 295 precond(inner != nullptr); 296 // Give the inner reloc a chance to modify the target. 297 address adjusted_target = target; 298 instructions = inner(insn_addr, adjusted_target); 299 uintptr_t pc_page = (uintptr_t)insn_addr >> 12; 300 uintptr_t adr_page = (uintptr_t)adjusted_target >> 12; 301 offset = adr_page - pc_page; 302 int offset_lo = offset & 3; 303 offset >>= 2; 304 Instruction_aarch64::spatch(insn_addr, 23, 5, offset); 305 Instruction_aarch64::patch(insn_addr, 30, 29, offset_lo); 306 return instructions; 307 } 308 static int adrpMem(address insn_addr, address &target) { 309 uintptr_t dest = (uintptr_t)target; 310 int offset_lo = dest & 0xfff; 311 uint32_t insn2 = insn_at(insn_addr, 1); 312 uint32_t size = Instruction_aarch64::extract(insn2, 31, 30); 313 Instruction_aarch64::patch(insn_addr + sizeof (uint32_t), 21, 10, offset_lo >> size); 314 guarantee(((dest >> size) << size) == dest, "misaligned target"); 315 return 2; 316 } 317 static int adrpAdd(address insn_addr, address &target) { 318 uintptr_t dest = (uintptr_t)target; 319 int offset_lo = dest & 0xfff; 320 Instruction_aarch64::patch(insn_addr + sizeof (uint32_t), 21, 10, offset_lo); 321 return 2; 322 } 323 static int adrpMovk(address insn_addr, address &target) { 324 uintptr_t dest = uintptr_t(target); 325 Instruction_aarch64::patch(insn_addr + sizeof (uint32_t), 20, 5, (uintptr_t)target >> 32); 326 dest = (dest & 0xffffffffULL) | (uintptr_t(insn_addr) & 0xffff00000000ULL); 327 target = address(dest); 328 return 2; 329 } 330 static int immediate(address insn_addr, address &target) { 331 assert(Instruction_aarch64::extract(insn_at(insn_addr, 0), 31, 21) == 0b11010010100, "must be"); 332 uint64_t dest = (uint64_t)target; 333 // Move wide constant 334 assert(nativeInstruction_at(insn_addr+4)->is_movk(), "wrong insns in patch"); 335 assert(nativeInstruction_at(insn_addr+8)->is_movk(), "wrong insns in patch"); 336 Instruction_aarch64::patch(insn_addr, 20, 5, dest & 0xffff); 337 Instruction_aarch64::patch(insn_addr+4, 20, 5, (dest >>= 16) & 0xffff); 338 Instruction_aarch64::patch(insn_addr+8, 20, 5, (dest >>= 16) & 0xffff); 339 return 3; 340 } 341 static void verify(address insn_addr, address &target) { 342 #ifdef ASSERT 343 address address_is = MacroAssembler::target_addr_for_insn(insn_addr); 344 if (!(address_is == target)) { 345 tty->print_cr("%p at %p should be %p", address_is, insn_addr, target); 346 disnm((intptr_t)insn_addr); 347 assert(address_is == target, "should be"); 348 } 349 #endif 350 } 351 }; 352 353 // If insn1 and insn2 use the same register to form an address, either 354 // by an offsetted LDR or a simple ADD, return the offset. If the 355 // second instruction is an LDR, the offset may be scaled. 356 static bool offset_for(uint32_t insn1, uint32_t insn2, ptrdiff_t &byte_offset) { 357 if (Instruction_aarch64::extract(insn2, 29, 24) == 0b111001 && 358 Instruction_aarch64::extract(insn1, 4, 0) == 359 Instruction_aarch64::extract(insn2, 9, 5)) { 360 // Load/store register (unsigned immediate) 361 byte_offset = Instruction_aarch64::extract(insn2, 21, 10); 362 uint32_t size = Instruction_aarch64::extract(insn2, 31, 30); 363 byte_offset <<= size; 364 return true; 365 } else if (Instruction_aarch64::extract(insn2, 31, 22) == 0b1001000100 && 366 Instruction_aarch64::extract(insn1, 4, 0) == 367 Instruction_aarch64::extract(insn2, 4, 0)) { 368 // add (immediate) 369 byte_offset = Instruction_aarch64::extract(insn2, 21, 10); 370 return true; 371 } 372 return false; 373 } 374 375 class AArch64Decoder : public AllStatic { 376 public: 377 378 static int loadStore(address insn_addr, address &target) { 379 intptr_t offset = Instruction_aarch64::sextract(insn_at(insn_addr, 0), 23, 5); 380 target = insn_addr + (offset << 2); 381 return 1; 382 } 383 static int unconditionalBranch(address insn_addr, address &target) { 384 intptr_t offset = Instruction_aarch64::sextract(insn_at(insn_addr, 0), 25, 0); 385 target = insn_addr + (offset << 2); 386 return 1; 387 } 388 static int conditionalBranch(address insn_addr, address &target) { 389 intptr_t offset = Instruction_aarch64::sextract(insn_at(insn_addr, 0), 23, 5); 390 target = address(((uint64_t)insn_addr + (offset << 2))); 391 return 1; 392 } 393 static int testAndBranch(address insn_addr, address &target) { 394 intptr_t offset = Instruction_aarch64::sextract(insn_at(insn_addr, 0), 18, 5); 395 target = address(((uint64_t)insn_addr + (offset << 2))); 396 return 1; 397 } 398 static int adr(address insn_addr, address &target) { 399 // PC-rel. addressing 400 uint32_t insn = insn_at(insn_addr, 0); 401 intptr_t offset = Instruction_aarch64::extract(insn, 30, 29); 402 offset |= Instruction_aarch64::sextract(insn, 23, 5) << 2; 403 target = address((uint64_t)insn_addr + offset); 404 return 1; 405 } 406 template<typename U> 407 static int adrp(address insn_addr, address &target, U inner) { 408 uint32_t insn = insn_at(insn_addr, 0); 409 assert(Instruction_aarch64::extract(insn, 28, 24) == 0b10000, "must be"); 410 intptr_t offset = Instruction_aarch64::extract(insn, 30, 29); 411 offset |= Instruction_aarch64::sextract(insn, 23, 5) << 2; 412 int shift = 12; 413 offset <<= shift; 414 uint64_t target_page = ((uint64_t)insn_addr) + offset; 415 target_page &= ((uint64_t)-1) << shift; 416 target = address(target_page); 417 precond(inner != nullptr); 418 inner(insn_addr, target); 419 return 2; 420 } 421 static int adrpMem(address insn_addr, address &target) { 422 uint32_t insn2 = insn_at(insn_addr, 1); 423 // Load/store register (unsigned immediate) 424 ptrdiff_t byte_offset = Instruction_aarch64::extract(insn2, 21, 10); 425 uint32_t size = Instruction_aarch64::extract(insn2, 31, 30); 426 byte_offset <<= size; 427 target += byte_offset; 428 return 2; 429 } 430 static int adrpAdd(address insn_addr, address &target) { 431 uint32_t insn2 = insn_at(insn_addr, 1); 432 // add (immediate) 433 ptrdiff_t byte_offset = Instruction_aarch64::extract(insn2, 21, 10); 434 target += byte_offset; 435 return 2; 436 } 437 static int adrpMovk(address insn_addr, address &target) { 438 uint32_t insn2 = insn_at(insn_addr, 1); 439 uint64_t dest = uint64_t(target); 440 dest = (dest & 0xffff0000ffffffff) | 441 ((uint64_t)Instruction_aarch64::extract(insn2, 20, 5) << 32); 442 target = address(dest); 443 444 // We know the destination 4k page. Maybe we have a third 445 // instruction. 446 uint32_t insn = insn_at(insn_addr, 0); 447 uint32_t insn3 = insn_at(insn_addr, 2); 448 ptrdiff_t byte_offset; 449 if (offset_for(insn, insn3, byte_offset)) { 450 target += byte_offset; 451 return 3; 452 } else { 453 return 2; 454 } 455 } 456 static int immediate(address insn_addr, address &target) { 457 uint32_t *insns = (uint32_t *)insn_addr; 458 assert(Instruction_aarch64::extract(insns[0], 31, 21) == 0b11010010100, "must be"); 459 // Move wide constant: movz, movk, movk. See movptr(). 460 assert(nativeInstruction_at(insns+1)->is_movk(), "wrong insns in patch"); 461 assert(nativeInstruction_at(insns+2)->is_movk(), "wrong insns in patch"); 462 target = address(uint64_t(Instruction_aarch64::extract(insns[0], 20, 5)) 463 + (uint64_t(Instruction_aarch64::extract(insns[1], 20, 5)) << 16) 464 + (uint64_t(Instruction_aarch64::extract(insns[2], 20, 5)) << 32)); 465 assert(nativeInstruction_at(insn_addr+4)->is_movk(), "wrong insns in patch"); 466 assert(nativeInstruction_at(insn_addr+8)->is_movk(), "wrong insns in patch"); 467 return 3; 468 } 469 static void verify(address insn_addr, address &target) { 470 } 471 }; 472 473 address MacroAssembler::target_addr_for_insn(address insn_addr) { 474 address target; 475 RelocActions<AArch64Decoder>::run(insn_addr, target); 476 return target; 477 } 478 479 // Patch any kind of instruction; there may be several instructions. 480 // Return the total length (in bytes) of the instructions. 481 int MacroAssembler::pd_patch_instruction_size(address insn_addr, address target) { 482 MACOS_AARCH64_ONLY(os::thread_wx_enable_write()); 483 return RelocActions<Patcher>::run(insn_addr, target); 484 } 485 486 int MacroAssembler::patch_oop(address insn_addr, address o) { 487 int instructions; 488 unsigned insn = *(unsigned*)insn_addr; 489 assert(nativeInstruction_at(insn_addr+4)->is_movk(), "wrong insns in patch"); 490 491 MACOS_AARCH64_ONLY(os::thread_wx_enable_write()); 492 493 // OOPs are either narrow (32 bits) or wide (48 bits). We encode 494 // narrow OOPs by setting the upper 16 bits in the first 495 // instruction. 496 if (Instruction_aarch64::extract(insn, 31, 21) == 0b11010010101) { 497 // Move narrow OOP 498 uint32_t n = CompressedOops::narrow_oop_value(cast_to_oop(o)); 499 Instruction_aarch64::patch(insn_addr, 20, 5, n >> 16); 500 Instruction_aarch64::patch(insn_addr+4, 20, 5, n & 0xffff); 501 instructions = 2; 502 } else { 503 // Move wide OOP 504 assert(nativeInstruction_at(insn_addr+8)->is_movk(), "wrong insns in patch"); 505 uintptr_t dest = (uintptr_t)o; 506 Instruction_aarch64::patch(insn_addr, 20, 5, dest & 0xffff); 507 Instruction_aarch64::patch(insn_addr+4, 20, 5, (dest >>= 16) & 0xffff); 508 Instruction_aarch64::patch(insn_addr+8, 20, 5, (dest >>= 16) & 0xffff); 509 instructions = 3; 510 } 511 return instructions * NativeInstruction::instruction_size; 512 } 513 514 void MacroAssembler::safepoint_poll(Label& slow_path, bool at_return, bool in_nmethod, Register tmp) { 515 ldr(tmp, Address(rthread, JavaThread::polling_word_offset())); 516 if (at_return) { 517 // Note that when in_nmethod is set, the stack pointer is incremented before the poll. Therefore, 518 // we may safely use the sp instead to perform the stack watermark check. 519 cmp(in_nmethod ? sp : rfp, tmp); 520 br(Assembler::HI, slow_path); 521 } else { 522 tbnz(tmp, log2i_exact(SafepointMechanism::poll_bit()), slow_path); 523 } 524 } 525 526 void MacroAssembler::rt_call(address dest, Register tmp) { 527 CodeBlob *cb = CodeCache::find_blob(dest); 528 if (cb) { 529 far_call(RuntimeAddress(dest)); 530 } else { 531 lea(tmp, RuntimeAddress(dest)); 532 blr(tmp); 533 } 534 } 535 536 void MacroAssembler::push_cont_fastpath(Register java_thread) { 537 if (!Continuations::enabled()) return; 538 Label done; 539 ldr(rscratch1, Address(java_thread, JavaThread::cont_fastpath_offset())); 540 cmp(sp, rscratch1); 541 br(Assembler::LS, done); 542 mov(rscratch1, sp); // we can't use sp as the source in str 543 str(rscratch1, Address(java_thread, JavaThread::cont_fastpath_offset())); 544 bind(done); 545 } 546 547 void MacroAssembler::pop_cont_fastpath(Register java_thread) { 548 if (!Continuations::enabled()) return; 549 Label done; 550 ldr(rscratch1, Address(java_thread, JavaThread::cont_fastpath_offset())); 551 cmp(sp, rscratch1); 552 br(Assembler::LO, done); 553 str(zr, Address(java_thread, JavaThread::cont_fastpath_offset())); 554 bind(done); 555 } 556 557 void MacroAssembler::reset_last_Java_frame(bool clear_fp) { 558 // we must set sp to zero to clear frame 559 str(zr, Address(rthread, JavaThread::last_Java_sp_offset())); 560 561 // must clear fp, so that compiled frames are not confused; it is 562 // possible that we need it only for debugging 563 if (clear_fp) { 564 str(zr, Address(rthread, JavaThread::last_Java_fp_offset())); 565 } 566 567 // Always clear the pc because it could have been set by make_walkable() 568 str(zr, Address(rthread, JavaThread::last_Java_pc_offset())); 569 } 570 571 // Calls to C land 572 // 573 // When entering C land, the rfp, & resp of the last Java frame have to be recorded 574 // in the (thread-local) JavaThread object. When leaving C land, the last Java fp 575 // has to be reset to 0. This is required to allow proper stack traversal. 576 void MacroAssembler::set_last_Java_frame(Register last_java_sp, 577 Register last_java_fp, 578 Register last_java_pc, 579 Register scratch) { 580 581 if (last_java_pc->is_valid()) { 582 str(last_java_pc, Address(rthread, 583 JavaThread::frame_anchor_offset() 584 + JavaFrameAnchor::last_Java_pc_offset())); 585 } 586 587 // determine last_java_sp register 588 if (last_java_sp == sp) { 589 mov(scratch, sp); 590 last_java_sp = scratch; 591 } else if (!last_java_sp->is_valid()) { 592 last_java_sp = esp; 593 } 594 595 // last_java_fp is optional 596 if (last_java_fp->is_valid()) { 597 str(last_java_fp, Address(rthread, JavaThread::last_Java_fp_offset())); 598 } 599 600 // We must set sp last. 601 str(last_java_sp, Address(rthread, JavaThread::last_Java_sp_offset())); 602 } 603 604 void MacroAssembler::set_last_Java_frame(Register last_java_sp, 605 Register last_java_fp, 606 address last_java_pc, 607 Register scratch) { 608 assert(last_java_pc != nullptr, "must provide a valid PC"); 609 610 adr(scratch, last_java_pc); 611 str(scratch, Address(rthread, 612 JavaThread::frame_anchor_offset() 613 + JavaFrameAnchor::last_Java_pc_offset())); 614 615 set_last_Java_frame(last_java_sp, last_java_fp, noreg, scratch); 616 } 617 618 void MacroAssembler::set_last_Java_frame(Register last_java_sp, 619 Register last_java_fp, 620 Label &L, 621 Register scratch) { 622 if (L.is_bound()) { 623 set_last_Java_frame(last_java_sp, last_java_fp, target(L), scratch); 624 } else { 625 InstructionMark im(this); 626 L.add_patch_at(code(), locator()); 627 set_last_Java_frame(last_java_sp, last_java_fp, pc() /* Patched later */, scratch); 628 } 629 } 630 631 static inline bool target_needs_far_branch(address addr) { 632 if (AOTCodeCache::is_on_for_dump()) { 633 return true; 634 } 635 // codecache size <= 128M 636 if (!MacroAssembler::far_branches()) { 637 return false; 638 } 639 // codecache size > 240M 640 if (MacroAssembler::codestub_branch_needs_far_jump()) { 641 return true; 642 } 643 // codecache size: 128M..240M 644 return !CodeCache::is_non_nmethod(addr); 645 } 646 647 void MacroAssembler::far_call(Address entry, Register tmp) { 648 assert(ReservedCodeCacheSize < 4*G, "branch out of range"); 649 assert(CodeCache::find_blob(entry.target()) != nullptr, 650 "destination of far call not found in code cache"); 651 assert(entry.rspec().type() == relocInfo::external_word_type 652 || entry.rspec().type() == relocInfo::runtime_call_type 653 || entry.rspec().type() == relocInfo::none, "wrong entry relocInfo type"); 654 if (target_needs_far_branch(entry.target())) { 655 uint64_t offset; 656 // We can use ADRP here because we know that the total size of 657 // the code cache cannot exceed 2Gb (ADRP limit is 4GB). 658 adrp(tmp, entry, offset); 659 add(tmp, tmp, offset); 660 blr(tmp); 661 } else { 662 bl(entry); 663 } 664 } 665 666 int MacroAssembler::far_jump(Address entry, Register tmp) { 667 assert(ReservedCodeCacheSize < 4*G, "branch out of range"); 668 assert(CodeCache::find_blob(entry.target()) != nullptr, 669 "destination of far call not found in code cache"); 670 assert(entry.rspec().type() == relocInfo::external_word_type 671 || entry.rspec().type() == relocInfo::runtime_call_type 672 || entry.rspec().type() == relocInfo::none, "wrong entry relocInfo type"); 673 address start = pc(); 674 if (target_needs_far_branch(entry.target())) { 675 uint64_t offset; 676 // We can use ADRP here because we know that the total size of 677 // the code cache cannot exceed 2Gb (ADRP limit is 4GB). 678 adrp(tmp, entry, offset); 679 add(tmp, tmp, offset); 680 br(tmp); 681 } else { 682 b(entry); 683 } 684 return pc() - start; 685 } 686 687 void MacroAssembler::reserved_stack_check() { 688 // testing if reserved zone needs to be enabled 689 Label no_reserved_zone_enabling; 690 691 ldr(rscratch1, Address(rthread, JavaThread::reserved_stack_activation_offset())); 692 cmp(sp, rscratch1); 693 br(Assembler::LO, no_reserved_zone_enabling); 694 695 enter(); // LR and FP are live. 696 lea(rscratch1, RuntimeAddress(CAST_FROM_FN_PTR(address, SharedRuntime::enable_stack_reserved_zone))); 697 mov(c_rarg0, rthread); 698 blr(rscratch1); 699 leave(); 700 701 // We have already removed our own frame. 702 // throw_delayed_StackOverflowError will think that it's been 703 // called by our caller. 704 lea(rscratch1, RuntimeAddress(SharedRuntime::throw_delayed_StackOverflowError_entry())); 705 br(rscratch1); 706 should_not_reach_here(); 707 708 bind(no_reserved_zone_enabling); 709 } 710 711 static void pass_arg0(MacroAssembler* masm, Register arg) { 712 if (c_rarg0 != arg ) { 713 masm->mov(c_rarg0, arg); 714 } 715 } 716 717 static void pass_arg1(MacroAssembler* masm, Register arg) { 718 if (c_rarg1 != arg ) { 719 masm->mov(c_rarg1, arg); 720 } 721 } 722 723 static void pass_arg2(MacroAssembler* masm, Register arg) { 724 if (c_rarg2 != arg ) { 725 masm->mov(c_rarg2, arg); 726 } 727 } 728 729 static void pass_arg3(MacroAssembler* masm, Register arg) { 730 if (c_rarg3 != arg ) { 731 masm->mov(c_rarg3, arg); 732 } 733 } 734 735 void MacroAssembler::call_VM_base(Register oop_result, 736 Register java_thread, 737 Register last_java_sp, 738 Label* return_pc, 739 address entry_point, 740 int number_of_arguments, 741 bool check_exceptions) { 742 // determine java_thread register 743 if (!java_thread->is_valid()) { 744 java_thread = rthread; 745 } 746 747 // determine last_java_sp register 748 if (!last_java_sp->is_valid()) { 749 last_java_sp = esp; 750 } 751 752 // debugging support 753 assert(number_of_arguments >= 0 , "cannot have negative number of arguments"); 754 assert(java_thread == rthread, "unexpected register"); 755 #ifdef ASSERT 756 // TraceBytecodes does not use r12 but saves it over the call, so don't verify 757 // if (!TraceBytecodes) verify_heapbase("call_VM_base: heap base corrupted?"); 758 #endif // ASSERT 759 760 assert(java_thread != oop_result , "cannot use the same register for java_thread & oop_result"); 761 assert(java_thread != last_java_sp, "cannot use the same register for java_thread & last_java_sp"); 762 763 // push java thread (becomes first argument of C function) 764 765 mov(c_rarg0, java_thread); 766 767 // set last Java frame before call 768 assert(last_java_sp != rfp, "can't use rfp"); 769 770 Label l; 771 set_last_Java_frame(last_java_sp, rfp, return_pc != nullptr ? *return_pc : l, rscratch1); 772 773 // do the call, remove parameters 774 MacroAssembler::call_VM_leaf_base(entry_point, number_of_arguments, &l); 775 776 // lr could be poisoned with PAC signature during throw_pending_exception 777 // if it was tail-call optimized by compiler, since lr is not callee-saved 778 // reload it with proper value 779 adr(lr, l); 780 781 // reset last Java frame 782 // Only interpreter should have to clear fp 783 reset_last_Java_frame(true); 784 785 // C++ interp handles this in the interpreter 786 check_and_handle_popframe(java_thread); 787 check_and_handle_earlyret(java_thread); 788 789 if (check_exceptions) { 790 // check for pending exceptions (java_thread is set upon return) 791 ldr(rscratch1, Address(java_thread, in_bytes(Thread::pending_exception_offset()))); 792 Label ok; 793 cbz(rscratch1, ok); 794 lea(rscratch1, RuntimeAddress(StubRoutines::forward_exception_entry())); 795 br(rscratch1); 796 bind(ok); 797 } 798 799 // get oop result if there is one and reset the value in the thread 800 if (oop_result->is_valid()) { 801 get_vm_result_oop(oop_result, java_thread); 802 } 803 } 804 805 void MacroAssembler::call_VM_helper(Register oop_result, address entry_point, int number_of_arguments, bool check_exceptions) { 806 call_VM_base(oop_result, noreg, noreg, nullptr, entry_point, number_of_arguments, check_exceptions); 807 } 808 809 // Check the entry target is always reachable from any branch. 810 static bool is_always_within_branch_range(Address entry) { 811 if (AOTCodeCache::is_on_for_dump()) { 812 return false; 813 } 814 const address target = entry.target(); 815 816 if (!CodeCache::contains(target)) { 817 // We always use trampolines for callees outside CodeCache. 818 assert(entry.rspec().type() == relocInfo::runtime_call_type, "non-runtime call of an external target"); 819 return false; 820 } 821 822 if (!MacroAssembler::far_branches()) { 823 return true; 824 } 825 826 if (entry.rspec().type() == relocInfo::runtime_call_type) { 827 // Runtime calls are calls of a non-compiled method (stubs, adapters). 828 // Non-compiled methods stay forever in CodeCache. 829 // We check whether the longest possible branch is within the branch range. 830 assert(CodeCache::find_blob(target) != nullptr && 831 !CodeCache::find_blob(target)->is_nmethod(), 832 "runtime call of compiled method"); 833 const address right_longest_branch_start = CodeCache::high_bound() - NativeInstruction::instruction_size; 834 const address left_longest_branch_start = CodeCache::low_bound(); 835 const bool is_reachable = Assembler::reachable_from_branch_at(left_longest_branch_start, target) && 836 Assembler::reachable_from_branch_at(right_longest_branch_start, target); 837 return is_reachable; 838 } 839 840 return false; 841 } 842 843 // Maybe emit a call via a trampoline. If the code cache is small 844 // trampolines won't be emitted. 845 address MacroAssembler::trampoline_call(Address entry) { 846 assert(entry.rspec().type() == relocInfo::runtime_call_type 847 || entry.rspec().type() == relocInfo::opt_virtual_call_type 848 || entry.rspec().type() == relocInfo::static_call_type 849 || entry.rspec().type() == relocInfo::virtual_call_type, "wrong reloc type"); 850 851 address target = entry.target(); 852 853 if (!is_always_within_branch_range(entry)) { 854 if (!in_scratch_emit_size()) { 855 // We don't want to emit a trampoline if C2 is generating dummy 856 // code during its branch shortening phase. 857 if (entry.rspec().type() == relocInfo::runtime_call_type) { 858 assert(CodeBuffer::supports_shared_stubs(), "must support shared stubs"); 859 code()->share_trampoline_for(entry.target(), offset()); 860 } else { 861 address stub = emit_trampoline_stub(offset(), target); 862 if (stub == nullptr) { 863 postcond(pc() == badAddress); 864 return nullptr; // CodeCache is full 865 } 866 } 867 } 868 target = pc(); 869 } 870 871 address call_pc = pc(); 872 relocate(entry.rspec()); 873 bl(target); 874 875 postcond(pc() != badAddress); 876 return call_pc; 877 } 878 879 // Emit a trampoline stub for a call to a target which is too far away. 880 // 881 // code sequences: 882 // 883 // call-site: 884 // branch-and-link to <destination> or <trampoline stub> 885 // 886 // Related trampoline stub for this call site in the stub section: 887 // load the call target from the constant pool 888 // branch (LR still points to the call site above) 889 890 address MacroAssembler::emit_trampoline_stub(int insts_call_instruction_offset, 891 address dest) { 892 // Max stub size: alignment nop, TrampolineStub. 893 address stub = start_a_stub(max_trampoline_stub_size()); 894 if (stub == nullptr) { 895 return nullptr; // CodeBuffer::expand failed 896 } 897 898 // Create a trampoline stub relocation which relates this trampoline stub 899 // with the call instruction at insts_call_instruction_offset in the 900 // instructions code-section. 901 align(wordSize); 902 relocate(trampoline_stub_Relocation::spec(code()->insts()->start() 903 + insts_call_instruction_offset)); 904 const int stub_start_offset = offset(); 905 906 // Now, create the trampoline stub's code: 907 // - load the call 908 // - call 909 Label target; 910 ldr(rscratch1, target); 911 br(rscratch1); 912 bind(target); 913 assert(offset() - stub_start_offset == NativeCallTrampolineStub::data_offset, 914 "should be"); 915 emit_int64((int64_t)dest); 916 917 const address stub_start_addr = addr_at(stub_start_offset); 918 919 assert(is_NativeCallTrampolineStub_at(stub_start_addr), "doesn't look like a trampoline"); 920 921 end_a_stub(); 922 return stub_start_addr; 923 } 924 925 int MacroAssembler::max_trampoline_stub_size() { 926 // Max stub size: alignment nop, TrampolineStub. 927 return NativeInstruction::instruction_size + NativeCallTrampolineStub::instruction_size; 928 } 929 930 void MacroAssembler::emit_static_call_stub() { 931 // CompiledDirectCall::set_to_interpreted knows the 932 // exact layout of this stub. 933 934 isb(); 935 mov_metadata(rmethod, nullptr); 936 937 // Jump to the entry point of the c2i stub. 938 if (codestub_branch_needs_far_jump()) { 939 movptr(rscratch1, 0); 940 br(rscratch1); 941 } else { 942 b(pc()); 943 } 944 } 945 946 int MacroAssembler::static_call_stub_size() { 947 // During AOT production run AOT and JIT compiled code 948 // are used at the same time. We need this size 949 // to be the same for both types of code. 950 if (!codestub_branch_needs_far_jump() && !AOTCodeCache::is_on_for_use()) { 951 // isb; movk; movz; movz; b 952 return 5 * NativeInstruction::instruction_size; 953 } 954 // isb; movk; movz; movz; movk; movz; movz; br 955 return 8 * NativeInstruction::instruction_size; 956 } 957 958 void MacroAssembler::c2bool(Register x) { 959 // implements x == 0 ? 0 : 1 960 // note: must only look at least-significant byte of x 961 // since C-style booleans are stored in one byte 962 // only! (was bug) 963 tst(x, 0xff); 964 cset(x, Assembler::NE); 965 } 966 967 address MacroAssembler::ic_call(address entry, jint method_index) { 968 RelocationHolder rh = virtual_call_Relocation::spec(pc(), method_index); 969 movptr(rscratch2, (intptr_t)Universe::non_oop_word()); 970 return trampoline_call(Address(entry, rh)); 971 } 972 973 int MacroAssembler::ic_check_size() { 974 int extra_instructions = UseCompactObjectHeaders ? 1 : 0; 975 if (target_needs_far_branch(CAST_FROM_FN_PTR(address, SharedRuntime::get_ic_miss_stub()))) { 976 return NativeInstruction::instruction_size * (7 + extra_instructions); 977 } else { 978 return NativeInstruction::instruction_size * (5 + extra_instructions); 979 } 980 } 981 982 int MacroAssembler::ic_check(int end_alignment) { 983 Register receiver = j_rarg0; 984 Register data = rscratch2; 985 Register tmp1 = rscratch1; 986 Register tmp2 = r10; 987 988 // The UEP of a code blob ensures that the VEP is padded. However, the padding of the UEP is placed 989 // before the inline cache check, so we don't have to execute any nop instructions when dispatching 990 // through the UEP, yet we can ensure that the VEP is aligned appropriately. That's why we align 991 // before the inline cache check here, and not after 992 align(end_alignment, offset() + ic_check_size()); 993 994 int uep_offset = offset(); 995 996 if (UseCompactObjectHeaders) { 997 load_narrow_klass_compact(tmp1, receiver); 998 ldrw(tmp2, Address(data, CompiledICData::speculated_klass_offset())); 999 cmpw(tmp1, tmp2); 1000 } else { 1001 ldrw(tmp1, Address(receiver, oopDesc::klass_offset_in_bytes())); 1002 ldrw(tmp2, Address(data, CompiledICData::speculated_klass_offset())); 1003 cmpw(tmp1, tmp2); 1004 } 1005 1006 Label dont; 1007 br(Assembler::EQ, dont); 1008 far_jump(RuntimeAddress(SharedRuntime::get_ic_miss_stub())); 1009 bind(dont); 1010 assert((offset() % end_alignment) == 0, "Misaligned verified entry point"); 1011 1012 return uep_offset; 1013 } 1014 1015 // Implementation of call_VM versions 1016 1017 void MacroAssembler::call_VM(Register oop_result, 1018 address entry_point, 1019 bool check_exceptions) { 1020 call_VM_helper(oop_result, entry_point, 0, check_exceptions); 1021 } 1022 1023 void MacroAssembler::call_VM(Register oop_result, 1024 address entry_point, 1025 Register arg_1, 1026 bool check_exceptions) { 1027 pass_arg1(this, arg_1); 1028 call_VM_helper(oop_result, entry_point, 1, check_exceptions); 1029 } 1030 1031 void MacroAssembler::call_VM(Register oop_result, 1032 address entry_point, 1033 Register arg_1, 1034 Register arg_2, 1035 bool check_exceptions) { 1036 assert_different_registers(arg_1, c_rarg2); 1037 pass_arg2(this, arg_2); 1038 pass_arg1(this, arg_1); 1039 call_VM_helper(oop_result, entry_point, 2, check_exceptions); 1040 } 1041 1042 void MacroAssembler::call_VM(Register oop_result, 1043 address entry_point, 1044 Register arg_1, 1045 Register arg_2, 1046 Register arg_3, 1047 bool check_exceptions) { 1048 assert_different_registers(arg_1, c_rarg2, c_rarg3); 1049 assert_different_registers(arg_2, c_rarg3); 1050 pass_arg3(this, arg_3); 1051 1052 pass_arg2(this, arg_2); 1053 1054 pass_arg1(this, arg_1); 1055 call_VM_helper(oop_result, entry_point, 3, check_exceptions); 1056 } 1057 1058 void MacroAssembler::call_VM(Register oop_result, 1059 Register last_java_sp, 1060 address entry_point, 1061 int number_of_arguments, 1062 bool check_exceptions) { 1063 call_VM_base(oop_result, rthread, last_java_sp, nullptr, entry_point, number_of_arguments, check_exceptions); 1064 } 1065 1066 void MacroAssembler::call_VM(Register oop_result, 1067 Register last_java_sp, 1068 address entry_point, 1069 Register arg_1, 1070 bool check_exceptions) { 1071 pass_arg1(this, arg_1); 1072 call_VM(oop_result, last_java_sp, entry_point, 1, check_exceptions); 1073 } 1074 1075 void MacroAssembler::call_VM(Register oop_result, 1076 Register last_java_sp, 1077 address entry_point, 1078 Register arg_1, 1079 Register arg_2, 1080 bool check_exceptions) { 1081 1082 assert_different_registers(arg_1, c_rarg2); 1083 pass_arg2(this, arg_2); 1084 pass_arg1(this, arg_1); 1085 call_VM(oop_result, last_java_sp, entry_point, 2, check_exceptions); 1086 } 1087 1088 void MacroAssembler::call_VM(Register oop_result, 1089 Register last_java_sp, 1090 address entry_point, 1091 Register arg_1, 1092 Register arg_2, 1093 Register arg_3, 1094 bool check_exceptions) { 1095 assert_different_registers(arg_1, c_rarg2, c_rarg3); 1096 assert_different_registers(arg_2, c_rarg3); 1097 pass_arg3(this, arg_3); 1098 pass_arg2(this, arg_2); 1099 pass_arg1(this, arg_1); 1100 call_VM(oop_result, last_java_sp, entry_point, 3, check_exceptions); 1101 } 1102 1103 1104 void MacroAssembler::get_vm_result_oop(Register oop_result, Register java_thread) { 1105 ldr(oop_result, Address(java_thread, JavaThread::vm_result_oop_offset())); 1106 str(zr, Address(java_thread, JavaThread::vm_result_oop_offset())); 1107 verify_oop_msg(oop_result, "broken oop in call_VM_base"); 1108 } 1109 1110 void MacroAssembler::get_vm_result_metadata(Register metadata_result, Register java_thread) { 1111 ldr(metadata_result, Address(java_thread, JavaThread::vm_result_metadata_offset())); 1112 str(zr, Address(java_thread, JavaThread::vm_result_metadata_offset())); 1113 } 1114 1115 void MacroAssembler::align(int modulus) { 1116 align(modulus, offset()); 1117 } 1118 1119 // Ensure that the code at target bytes offset from the current offset() is aligned 1120 // according to modulus. 1121 void MacroAssembler::align(int modulus, int target) { 1122 int delta = target - offset(); 1123 while ((offset() + delta) % modulus != 0) nop(); 1124 } 1125 1126 void MacroAssembler::post_call_nop() { 1127 if (!Continuations::enabled()) { 1128 return; 1129 } 1130 InstructionMark im(this); 1131 relocate(post_call_nop_Relocation::spec()); 1132 InlineSkippedInstructionsCounter skipCounter(this); 1133 nop(); 1134 movk(zr, 0); 1135 movk(zr, 0); 1136 } 1137 1138 // these are no-ops overridden by InterpreterMacroAssembler 1139 1140 void MacroAssembler::check_and_handle_earlyret(Register java_thread) { } 1141 1142 void MacroAssembler::check_and_handle_popframe(Register java_thread) { } 1143 1144 // Look up the method for a megamorphic invokeinterface call. 1145 // The target method is determined by <intf_klass, itable_index>. 1146 // The receiver klass is in recv_klass. 1147 // On success, the result will be in method_result, and execution falls through. 1148 // On failure, execution transfers to the given label. 1149 void MacroAssembler::lookup_interface_method(Register recv_klass, 1150 Register intf_klass, 1151 RegisterOrConstant itable_index, 1152 Register method_result, 1153 Register scan_temp, 1154 Label& L_no_such_interface, 1155 bool return_method) { 1156 assert_different_registers(recv_klass, intf_klass, scan_temp); 1157 assert_different_registers(method_result, intf_klass, scan_temp); 1158 assert(recv_klass != method_result || !return_method, 1159 "recv_klass can be destroyed when method isn't needed"); 1160 assert(itable_index.is_constant() || itable_index.as_register() == method_result, 1161 "caller must use same register for non-constant itable index as for method"); 1162 1163 // Compute start of first itableOffsetEntry (which is at the end of the vtable) 1164 int vtable_base = in_bytes(Klass::vtable_start_offset()); 1165 int itentry_off = in_bytes(itableMethodEntry::method_offset()); 1166 int scan_step = itableOffsetEntry::size() * wordSize; 1167 int vte_size = vtableEntry::size_in_bytes(); 1168 assert(vte_size == wordSize, "else adjust times_vte_scale"); 1169 1170 ldrw(scan_temp, Address(recv_klass, Klass::vtable_length_offset())); 1171 1172 // Could store the aligned, prescaled offset in the klass. 1173 // lea(scan_temp, Address(recv_klass, scan_temp, times_vte_scale, vtable_base)); 1174 lea(scan_temp, Address(recv_klass, scan_temp, Address::lsl(3))); 1175 add(scan_temp, scan_temp, vtable_base); 1176 1177 if (return_method) { 1178 // Adjust recv_klass by scaled itable_index, so we can free itable_index. 1179 assert(itableMethodEntry::size() * wordSize == wordSize, "adjust the scaling in the code below"); 1180 // lea(recv_klass, Address(recv_klass, itable_index, Address::times_ptr, itentry_off)); 1181 lea(recv_klass, Address(recv_klass, itable_index, Address::lsl(3))); 1182 if (itentry_off) 1183 add(recv_klass, recv_klass, itentry_off); 1184 } 1185 1186 // for (scan = klass->itable(); scan->interface() != nullptr; scan += scan_step) { 1187 // if (scan->interface() == intf) { 1188 // result = (klass + scan->offset() + itable_index); 1189 // } 1190 // } 1191 Label search, found_method; 1192 1193 ldr(method_result, Address(scan_temp, itableOffsetEntry::interface_offset())); 1194 cmp(intf_klass, method_result); 1195 br(Assembler::EQ, found_method); 1196 bind(search); 1197 // Check that the previous entry is non-null. A null entry means that 1198 // the receiver class doesn't implement the interface, and wasn't the 1199 // same as when the caller was compiled. 1200 cbz(method_result, L_no_such_interface); 1201 if (itableOffsetEntry::interface_offset() != 0) { 1202 add(scan_temp, scan_temp, scan_step); 1203 ldr(method_result, Address(scan_temp, itableOffsetEntry::interface_offset())); 1204 } else { 1205 ldr(method_result, Address(pre(scan_temp, scan_step))); 1206 } 1207 cmp(intf_klass, method_result); 1208 br(Assembler::NE, search); 1209 1210 bind(found_method); 1211 1212 // Got a hit. 1213 if (return_method) { 1214 ldrw(scan_temp, Address(scan_temp, itableOffsetEntry::offset_offset())); 1215 ldr(method_result, Address(recv_klass, scan_temp, Address::uxtw(0))); 1216 } 1217 } 1218 1219 // Look up the method for a megamorphic invokeinterface call in a single pass over itable: 1220 // - check recv_klass (actual object class) is a subtype of resolved_klass from CompiledICData 1221 // - find a holder_klass (class that implements the method) vtable offset and get the method from vtable by index 1222 // The target method is determined by <holder_klass, itable_index>. 1223 // The receiver klass is in recv_klass. 1224 // On success, the result will be in method_result, and execution falls through. 1225 // On failure, execution transfers to the given label. 1226 void MacroAssembler::lookup_interface_method_stub(Register recv_klass, 1227 Register holder_klass, 1228 Register resolved_klass, 1229 Register method_result, 1230 Register temp_itbl_klass, 1231 Register scan_temp, 1232 int itable_index, 1233 Label& L_no_such_interface) { 1234 // 'method_result' is only used as output register at the very end of this method. 1235 // Until then we can reuse it as 'holder_offset'. 1236 Register holder_offset = method_result; 1237 assert_different_registers(resolved_klass, recv_klass, holder_klass, temp_itbl_klass, scan_temp, holder_offset); 1238 1239 int vtable_start_offset = in_bytes(Klass::vtable_start_offset()); 1240 int itable_offset_entry_size = itableOffsetEntry::size() * wordSize; 1241 int ioffset = in_bytes(itableOffsetEntry::interface_offset()); 1242 int ooffset = in_bytes(itableOffsetEntry::offset_offset()); 1243 1244 Label L_loop_search_resolved_entry, L_resolved_found, L_holder_found; 1245 1246 ldrw(scan_temp, Address(recv_klass, Klass::vtable_length_offset())); 1247 add(recv_klass, recv_klass, vtable_start_offset + ioffset); 1248 // itableOffsetEntry[] itable = recv_klass + Klass::vtable_start_offset() + sizeof(vtableEntry) * recv_klass->_vtable_len; 1249 // temp_itbl_klass = itable[0]._interface; 1250 int vtblEntrySize = vtableEntry::size_in_bytes(); 1251 assert(vtblEntrySize == wordSize, "ldr lsl shift amount must be 3"); 1252 ldr(temp_itbl_klass, Address(recv_klass, scan_temp, Address::lsl(exact_log2(vtblEntrySize)))); 1253 mov(holder_offset, zr); 1254 // scan_temp = &(itable[0]._interface) 1255 lea(scan_temp, Address(recv_klass, scan_temp, Address::lsl(exact_log2(vtblEntrySize)))); 1256 1257 // Initial checks: 1258 // - if (holder_klass != resolved_klass), go to "scan for resolved" 1259 // - if (itable[0] == holder_klass), shortcut to "holder found" 1260 // - if (itable[0] == 0), no such interface 1261 cmp(resolved_klass, holder_klass); 1262 br(Assembler::NE, L_loop_search_resolved_entry); 1263 cmp(holder_klass, temp_itbl_klass); 1264 br(Assembler::EQ, L_holder_found); 1265 cbz(temp_itbl_klass, L_no_such_interface); 1266 1267 // Loop: Look for holder_klass record in itable 1268 // do { 1269 // temp_itbl_klass = *(scan_temp += itable_offset_entry_size); 1270 // if (temp_itbl_klass == holder_klass) { 1271 // goto L_holder_found; // Found! 1272 // } 1273 // } while (temp_itbl_klass != 0); 1274 // goto L_no_such_interface // Not found. 1275 Label L_search_holder; 1276 bind(L_search_holder); 1277 ldr(temp_itbl_klass, Address(pre(scan_temp, itable_offset_entry_size))); 1278 cmp(holder_klass, temp_itbl_klass); 1279 br(Assembler::EQ, L_holder_found); 1280 cbnz(temp_itbl_klass, L_search_holder); 1281 1282 b(L_no_such_interface); 1283 1284 // Loop: Look for resolved_class record in itable 1285 // while (true) { 1286 // temp_itbl_klass = *(scan_temp += itable_offset_entry_size); 1287 // if (temp_itbl_klass == 0) { 1288 // goto L_no_such_interface; 1289 // } 1290 // if (temp_itbl_klass == resolved_klass) { 1291 // goto L_resolved_found; // Found! 1292 // } 1293 // if (temp_itbl_klass == holder_klass) { 1294 // holder_offset = scan_temp; 1295 // } 1296 // } 1297 // 1298 Label L_loop_search_resolved; 1299 bind(L_loop_search_resolved); 1300 ldr(temp_itbl_klass, Address(pre(scan_temp, itable_offset_entry_size))); 1301 bind(L_loop_search_resolved_entry); 1302 cbz(temp_itbl_klass, L_no_such_interface); 1303 cmp(resolved_klass, temp_itbl_klass); 1304 br(Assembler::EQ, L_resolved_found); 1305 cmp(holder_klass, temp_itbl_klass); 1306 br(Assembler::NE, L_loop_search_resolved); 1307 mov(holder_offset, scan_temp); 1308 b(L_loop_search_resolved); 1309 1310 // See if we already have a holder klass. If not, go and scan for it. 1311 bind(L_resolved_found); 1312 cbz(holder_offset, L_search_holder); 1313 mov(scan_temp, holder_offset); 1314 1315 // Finally, scan_temp contains holder_klass vtable offset 1316 bind(L_holder_found); 1317 ldrw(method_result, Address(scan_temp, ooffset - ioffset)); 1318 add(recv_klass, recv_klass, itable_index * wordSize + in_bytes(itableMethodEntry::method_offset()) 1319 - vtable_start_offset - ioffset); // substract offsets to restore the original value of recv_klass 1320 ldr(method_result, Address(recv_klass, method_result, Address::uxtw(0))); 1321 } 1322 1323 // virtual method calling 1324 void MacroAssembler::lookup_virtual_method(Register recv_klass, 1325 RegisterOrConstant vtable_index, 1326 Register method_result) { 1327 assert(vtableEntry::size() * wordSize == 8, 1328 "adjust the scaling in the code below"); 1329 int64_t vtable_offset_in_bytes = in_bytes(Klass::vtable_start_offset() + vtableEntry::method_offset()); 1330 1331 if (vtable_index.is_register()) { 1332 lea(method_result, Address(recv_klass, 1333 vtable_index.as_register(), 1334 Address::lsl(LogBytesPerWord))); 1335 ldr(method_result, Address(method_result, vtable_offset_in_bytes)); 1336 } else { 1337 vtable_offset_in_bytes += vtable_index.as_constant() * wordSize; 1338 ldr(method_result, 1339 form_address(rscratch1, recv_klass, vtable_offset_in_bytes, 0)); 1340 } 1341 } 1342 1343 void MacroAssembler::check_klass_subtype(Register sub_klass, 1344 Register super_klass, 1345 Register temp_reg, 1346 Label& L_success) { 1347 Label L_failure; 1348 check_klass_subtype_fast_path(sub_klass, super_klass, temp_reg, &L_success, &L_failure, nullptr); 1349 check_klass_subtype_slow_path(sub_klass, super_klass, temp_reg, noreg, &L_success, nullptr); 1350 bind(L_failure); 1351 } 1352 1353 1354 void MacroAssembler::check_klass_subtype_fast_path(Register sub_klass, 1355 Register super_klass, 1356 Register temp_reg, 1357 Label* L_success, 1358 Label* L_failure, 1359 Label* L_slow_path, 1360 Register super_check_offset) { 1361 assert_different_registers(sub_klass, super_klass, temp_reg, super_check_offset); 1362 bool must_load_sco = ! super_check_offset->is_valid(); 1363 if (must_load_sco) { 1364 assert(temp_reg != noreg, "supply either a temp or a register offset"); 1365 } 1366 1367 Label L_fallthrough; 1368 int label_nulls = 0; 1369 if (L_success == nullptr) { L_success = &L_fallthrough; label_nulls++; } 1370 if (L_failure == nullptr) { L_failure = &L_fallthrough; label_nulls++; } 1371 if (L_slow_path == nullptr) { L_slow_path = &L_fallthrough; label_nulls++; } 1372 assert(label_nulls <= 1, "at most one null in the batch"); 1373 1374 int sco_offset = in_bytes(Klass::super_check_offset_offset()); 1375 Address super_check_offset_addr(super_klass, sco_offset); 1376 1377 // Hacked jmp, which may only be used just before L_fallthrough. 1378 #define final_jmp(label) \ 1379 if (&(label) == &L_fallthrough) { /*do nothing*/ } \ 1380 else b(label) /*omit semi*/ 1381 1382 // If the pointers are equal, we are done (e.g., String[] elements). 1383 // This self-check enables sharing of secondary supertype arrays among 1384 // non-primary types such as array-of-interface. Otherwise, each such 1385 // type would need its own customized SSA. 1386 // We move this check to the front of the fast path because many 1387 // type checks are in fact trivially successful in this manner, 1388 // so we get a nicely predicted branch right at the start of the check. 1389 cmp(sub_klass, super_klass); 1390 br(Assembler::EQ, *L_success); 1391 1392 // Check the supertype display: 1393 if (must_load_sco) { 1394 ldrw(temp_reg, super_check_offset_addr); 1395 super_check_offset = temp_reg; 1396 } 1397 1398 Address super_check_addr(sub_klass, super_check_offset); 1399 ldr(rscratch1, super_check_addr); 1400 cmp(super_klass, rscratch1); // load displayed supertype 1401 br(Assembler::EQ, *L_success); 1402 1403 // This check has worked decisively for primary supers. 1404 // Secondary supers are sought in the super_cache ('super_cache_addr'). 1405 // (Secondary supers are interfaces and very deeply nested subtypes.) 1406 // This works in the same check above because of a tricky aliasing 1407 // between the super_cache and the primary super display elements. 1408 // (The 'super_check_addr' can address either, as the case requires.) 1409 // Note that the cache is updated below if it does not help us find 1410 // what we need immediately. 1411 // So if it was a primary super, we can just fail immediately. 1412 // Otherwise, it's the slow path for us (no success at this point). 1413 1414 sub(rscratch1, super_check_offset, in_bytes(Klass::secondary_super_cache_offset())); 1415 if (L_failure == &L_fallthrough) { 1416 cbz(rscratch1, *L_slow_path); 1417 } else { 1418 cbnz(rscratch1, *L_failure); 1419 final_jmp(*L_slow_path); 1420 } 1421 1422 bind(L_fallthrough); 1423 1424 #undef final_jmp 1425 } 1426 1427 // These two are taken from x86, but they look generally useful 1428 1429 // scans count pointer sized words at [addr] for occurrence of value, 1430 // generic 1431 void MacroAssembler::repne_scan(Register addr, Register value, Register count, 1432 Register scratch) { 1433 Label Lloop, Lexit; 1434 cbz(count, Lexit); 1435 bind(Lloop); 1436 ldr(scratch, post(addr, wordSize)); 1437 cmp(value, scratch); 1438 br(EQ, Lexit); 1439 sub(count, count, 1); 1440 cbnz(count, Lloop); 1441 bind(Lexit); 1442 } 1443 1444 // scans count 4 byte words at [addr] for occurrence of value, 1445 // generic 1446 void MacroAssembler::repne_scanw(Register addr, Register value, Register count, 1447 Register scratch) { 1448 Label Lloop, Lexit; 1449 cbz(count, Lexit); 1450 bind(Lloop); 1451 ldrw(scratch, post(addr, wordSize)); 1452 cmpw(value, scratch); 1453 br(EQ, Lexit); 1454 sub(count, count, 1); 1455 cbnz(count, Lloop); 1456 bind(Lexit); 1457 } 1458 1459 void MacroAssembler::check_klass_subtype_slow_path_linear(Register sub_klass, 1460 Register super_klass, 1461 Register temp_reg, 1462 Register temp2_reg, 1463 Label* L_success, 1464 Label* L_failure, 1465 bool set_cond_codes) { 1466 // NB! Callers may assume that, when temp2_reg is a valid register, 1467 // this code sets it to a nonzero value. 1468 1469 assert_different_registers(sub_klass, super_klass, temp_reg); 1470 if (temp2_reg != noreg) 1471 assert_different_registers(sub_klass, super_klass, temp_reg, temp2_reg, rscratch1); 1472 #define IS_A_TEMP(reg) ((reg) == temp_reg || (reg) == temp2_reg) 1473 1474 Label L_fallthrough; 1475 int label_nulls = 0; 1476 if (L_success == nullptr) { L_success = &L_fallthrough; label_nulls++; } 1477 if (L_failure == nullptr) { L_failure = &L_fallthrough; label_nulls++; } 1478 assert(label_nulls <= 1, "at most one null in the batch"); 1479 1480 // a couple of useful fields in sub_klass: 1481 int ss_offset = in_bytes(Klass::secondary_supers_offset()); 1482 int sc_offset = in_bytes(Klass::secondary_super_cache_offset()); 1483 Address secondary_supers_addr(sub_klass, ss_offset); 1484 Address super_cache_addr( sub_klass, sc_offset); 1485 1486 BLOCK_COMMENT("check_klass_subtype_slow_path"); 1487 1488 // Do a linear scan of the secondary super-klass chain. 1489 // This code is rarely used, so simplicity is a virtue here. 1490 // The repne_scan instruction uses fixed registers, which we must spill. 1491 // Don't worry too much about pre-existing connections with the input regs. 1492 1493 assert(sub_klass != r0, "killed reg"); // killed by mov(r0, super) 1494 assert(sub_klass != r2, "killed reg"); // killed by lea(r2, &pst_counter) 1495 1496 RegSet pushed_registers; 1497 if (!IS_A_TEMP(r2)) pushed_registers += r2; 1498 if (!IS_A_TEMP(r5)) pushed_registers += r5; 1499 1500 if (super_klass != r0) { 1501 if (!IS_A_TEMP(r0)) pushed_registers += r0; 1502 } 1503 1504 push(pushed_registers, sp); 1505 1506 // Get super_klass value into r0 (even if it was in r5 or r2). 1507 if (super_klass != r0) { 1508 mov(r0, super_klass); 1509 } 1510 1511 #ifndef PRODUCT 1512 incrementw(ExternalAddress((address)&SharedRuntime::_partial_subtype_ctr)); 1513 #endif //PRODUCT 1514 1515 // We will consult the secondary-super array. 1516 ldr(r5, secondary_supers_addr); 1517 // Load the array length. 1518 ldrw(r2, Address(r5, Array<Klass*>::length_offset_in_bytes())); 1519 // Skip to start of data. 1520 add(r5, r5, Array<Klass*>::base_offset_in_bytes()); 1521 1522 cmp(sp, zr); // Clear Z flag; SP is never zero 1523 // Scan R2 words at [R5] for an occurrence of R0. 1524 // Set NZ/Z based on last compare. 1525 repne_scan(r5, r0, r2, rscratch1); 1526 1527 // Unspill the temp. registers: 1528 pop(pushed_registers, sp); 1529 1530 br(Assembler::NE, *L_failure); 1531 1532 // Success. Cache the super we found and proceed in triumph. 1533 1534 if (UseSecondarySupersCache) { 1535 str(super_klass, super_cache_addr); 1536 } 1537 1538 if (L_success != &L_fallthrough) { 1539 b(*L_success); 1540 } 1541 1542 #undef IS_A_TEMP 1543 1544 bind(L_fallthrough); 1545 } 1546 1547 // If Register r is invalid, remove a new register from 1548 // available_regs, and add new register to regs_to_push. 1549 Register MacroAssembler::allocate_if_noreg(Register r, 1550 RegSetIterator<Register> &available_regs, 1551 RegSet ®s_to_push) { 1552 if (!r->is_valid()) { 1553 r = *available_regs++; 1554 regs_to_push += r; 1555 } 1556 return r; 1557 } 1558 1559 // check_klass_subtype_slow_path_table() looks for super_klass in the 1560 // hash table belonging to super_klass, branching to L_success or 1561 // L_failure as appropriate. This is essentially a shim which 1562 // allocates registers as necessary then calls 1563 // lookup_secondary_supers_table() to do the work. Any of the temp 1564 // regs may be noreg, in which case this logic will chooses some 1565 // registers push and pop them from the stack. 1566 void MacroAssembler::check_klass_subtype_slow_path_table(Register sub_klass, 1567 Register super_klass, 1568 Register temp_reg, 1569 Register temp2_reg, 1570 Register temp3_reg, 1571 Register result_reg, 1572 FloatRegister vtemp, 1573 Label* L_success, 1574 Label* L_failure, 1575 bool set_cond_codes) { 1576 RegSet temps = RegSet::of(temp_reg, temp2_reg, temp3_reg); 1577 1578 assert_different_registers(sub_klass, super_klass, temp_reg, temp2_reg, rscratch1); 1579 1580 Label L_fallthrough; 1581 int label_nulls = 0; 1582 if (L_success == nullptr) { L_success = &L_fallthrough; label_nulls++; } 1583 if (L_failure == nullptr) { L_failure = &L_fallthrough; label_nulls++; } 1584 assert(label_nulls <= 1, "at most one null in the batch"); 1585 1586 BLOCK_COMMENT("check_klass_subtype_slow_path"); 1587 1588 RegSetIterator<Register> available_regs 1589 = (RegSet::range(r0, r15) - temps - sub_klass - super_klass).begin(); 1590 1591 RegSet pushed_regs; 1592 1593 temp_reg = allocate_if_noreg(temp_reg, available_regs, pushed_regs); 1594 temp2_reg = allocate_if_noreg(temp2_reg, available_regs, pushed_regs); 1595 temp3_reg = allocate_if_noreg(temp3_reg, available_regs, pushed_regs); 1596 result_reg = allocate_if_noreg(result_reg, available_regs, pushed_regs); 1597 1598 push(pushed_regs, sp); 1599 1600 lookup_secondary_supers_table_var(sub_klass, 1601 super_klass, 1602 temp_reg, temp2_reg, temp3_reg, vtemp, result_reg, 1603 nullptr); 1604 cmp(result_reg, zr); 1605 1606 // Unspill the temp. registers: 1607 pop(pushed_regs, sp); 1608 1609 // NB! Callers may assume that, when set_cond_codes is true, this 1610 // code sets temp2_reg to a nonzero value. 1611 if (set_cond_codes) { 1612 mov(temp2_reg, 1); 1613 } 1614 1615 br(Assembler::NE, *L_failure); 1616 1617 if (L_success != &L_fallthrough) { 1618 b(*L_success); 1619 } 1620 1621 bind(L_fallthrough); 1622 } 1623 1624 void MacroAssembler::check_klass_subtype_slow_path(Register sub_klass, 1625 Register super_klass, 1626 Register temp_reg, 1627 Register temp2_reg, 1628 Label* L_success, 1629 Label* L_failure, 1630 bool set_cond_codes) { 1631 if (UseSecondarySupersTable) { 1632 check_klass_subtype_slow_path_table 1633 (sub_klass, super_klass, temp_reg, temp2_reg, /*temp3*/noreg, /*result*/noreg, 1634 /*vtemp*/fnoreg, 1635 L_success, L_failure, set_cond_codes); 1636 } else { 1637 check_klass_subtype_slow_path_linear 1638 (sub_klass, super_klass, temp_reg, temp2_reg, L_success, L_failure, set_cond_codes); 1639 } 1640 } 1641 1642 1643 // Ensure that the inline code and the stub are using the same registers. 1644 #define LOOKUP_SECONDARY_SUPERS_TABLE_REGISTERS \ 1645 do { \ 1646 assert(r_super_klass == r0 && \ 1647 r_array_base == r1 && \ 1648 r_array_length == r2 && \ 1649 (r_array_index == r3 || r_array_index == noreg) && \ 1650 (r_sub_klass == r4 || r_sub_klass == noreg) && \ 1651 (r_bitmap == rscratch2 || r_bitmap == noreg) && \ 1652 (result == r5 || result == noreg), "registers must match aarch64.ad"); \ 1653 } while(0) 1654 1655 bool MacroAssembler::lookup_secondary_supers_table_const(Register r_sub_klass, 1656 Register r_super_klass, 1657 Register temp1, 1658 Register temp2, 1659 Register temp3, 1660 FloatRegister vtemp, 1661 Register result, 1662 u1 super_klass_slot, 1663 bool stub_is_near) { 1664 assert_different_registers(r_sub_klass, temp1, temp2, temp3, result, rscratch1, rscratch2); 1665 1666 Label L_fallthrough; 1667 1668 BLOCK_COMMENT("lookup_secondary_supers_table {"); 1669 1670 const Register 1671 r_array_base = temp1, // r1 1672 r_array_length = temp2, // r2 1673 r_array_index = temp3, // r3 1674 r_bitmap = rscratch2; 1675 1676 LOOKUP_SECONDARY_SUPERS_TABLE_REGISTERS; 1677 1678 u1 bit = super_klass_slot; 1679 1680 // Make sure that result is nonzero if the TBZ below misses. 1681 mov(result, 1); 1682 1683 // We're going to need the bitmap in a vector reg and in a core reg, 1684 // so load both now. 1685 ldr(r_bitmap, Address(r_sub_klass, Klass::secondary_supers_bitmap_offset())); 1686 if (bit != 0) { 1687 ldrd(vtemp, Address(r_sub_klass, Klass::secondary_supers_bitmap_offset())); 1688 } 1689 // First check the bitmap to see if super_klass might be present. If 1690 // the bit is zero, we are certain that super_klass is not one of 1691 // the secondary supers. 1692 tbz(r_bitmap, bit, L_fallthrough); 1693 1694 // Get the first array index that can contain super_klass into r_array_index. 1695 if (bit != 0) { 1696 shld(vtemp, vtemp, Klass::SECONDARY_SUPERS_TABLE_MASK - bit); 1697 cnt(vtemp, T8B, vtemp); 1698 addv(vtemp, T8B, vtemp); 1699 fmovd(r_array_index, vtemp); 1700 } else { 1701 mov(r_array_index, (u1)1); 1702 } 1703 // NB! r_array_index is off by 1. It is compensated by keeping r_array_base off by 1 word. 1704 1705 // We will consult the secondary-super array. 1706 ldr(r_array_base, Address(r_sub_klass, in_bytes(Klass::secondary_supers_offset()))); 1707 1708 // The value i in r_array_index is >= 1, so even though r_array_base 1709 // points to the length, we don't need to adjust it to point to the 1710 // data. 1711 assert(Array<Klass*>::base_offset_in_bytes() == wordSize, "Adjust this code"); 1712 assert(Array<Klass*>::length_offset_in_bytes() == 0, "Adjust this code"); 1713 1714 ldr(result, Address(r_array_base, r_array_index, Address::lsl(LogBytesPerWord))); 1715 eor(result, result, r_super_klass); 1716 cbz(result, L_fallthrough); // Found a match 1717 1718 // Is there another entry to check? Consult the bitmap. 1719 tbz(r_bitmap, (bit + 1) & Klass::SECONDARY_SUPERS_TABLE_MASK, L_fallthrough); 1720 1721 // Linear probe. 1722 if (bit != 0) { 1723 ror(r_bitmap, r_bitmap, bit); 1724 } 1725 1726 // The slot we just inspected is at secondary_supers[r_array_index - 1]. 1727 // The next slot to be inspected, by the stub we're about to call, 1728 // is secondary_supers[r_array_index]. Bits 0 and 1 in the bitmap 1729 // have been checked. 1730 Address stub = RuntimeAddress(StubRoutines::lookup_secondary_supers_table_slow_path_stub()); 1731 if (stub_is_near) { 1732 bl(stub); 1733 } else { 1734 address call = trampoline_call(stub); 1735 if (call == nullptr) { 1736 return false; // trampoline allocation failed 1737 } 1738 } 1739 1740 BLOCK_COMMENT("} lookup_secondary_supers_table"); 1741 1742 bind(L_fallthrough); 1743 1744 if (VerifySecondarySupers) { 1745 verify_secondary_supers_table(r_sub_klass, r_super_klass, // r4, r0 1746 temp1, temp2, result); // r1, r2, r5 1747 } 1748 return true; 1749 } 1750 1751 // At runtime, return 0 in result if r_super_klass is a superclass of 1752 // r_sub_klass, otherwise return nonzero. Use this version of 1753 // lookup_secondary_supers_table() if you don't know ahead of time 1754 // which superclass will be searched for. Used by interpreter and 1755 // runtime stubs. It is larger and has somewhat greater latency than 1756 // the version above, which takes a constant super_klass_slot. 1757 void MacroAssembler::lookup_secondary_supers_table_var(Register r_sub_klass, 1758 Register r_super_klass, 1759 Register temp1, 1760 Register temp2, 1761 Register temp3, 1762 FloatRegister vtemp, 1763 Register result, 1764 Label *L_success) { 1765 assert_different_registers(r_sub_klass, temp1, temp2, temp3, result, rscratch1, rscratch2); 1766 1767 Label L_fallthrough; 1768 1769 BLOCK_COMMENT("lookup_secondary_supers_table {"); 1770 1771 const Register 1772 r_array_index = temp3, 1773 slot = rscratch1, 1774 r_bitmap = rscratch2; 1775 1776 ldrb(slot, Address(r_super_klass, Klass::hash_slot_offset())); 1777 1778 // Make sure that result is nonzero if the test below misses. 1779 mov(result, 1); 1780 1781 ldr(r_bitmap, Address(r_sub_klass, Klass::secondary_supers_bitmap_offset())); 1782 1783 // First check the bitmap to see if super_klass might be present. If 1784 // the bit is zero, we are certain that super_klass is not one of 1785 // the secondary supers. 1786 1787 // This next instruction is equivalent to: 1788 // mov(tmp_reg, (u1)(Klass::SECONDARY_SUPERS_TABLE_SIZE - 1)); 1789 // sub(temp2, tmp_reg, slot); 1790 eor(temp2, slot, (u1)(Klass::SECONDARY_SUPERS_TABLE_SIZE - 1)); 1791 lslv(temp2, r_bitmap, temp2); 1792 tbz(temp2, Klass::SECONDARY_SUPERS_TABLE_SIZE - 1, L_fallthrough); 1793 1794 bool must_save_v0 = (vtemp == fnoreg); 1795 if (must_save_v0) { 1796 // temp1 and result are free, so use them to preserve vtemp 1797 vtemp = v0; 1798 mov(temp1, vtemp, D, 0); 1799 mov(result, vtemp, D, 1); 1800 } 1801 1802 // Get the first array index that can contain super_klass into r_array_index. 1803 mov(vtemp, D, 0, temp2); 1804 cnt(vtemp, T8B, vtemp); 1805 addv(vtemp, T8B, vtemp); 1806 mov(r_array_index, vtemp, D, 0); 1807 1808 if (must_save_v0) { 1809 mov(vtemp, D, 0, temp1 ); 1810 mov(vtemp, D, 1, result); 1811 } 1812 1813 // NB! r_array_index is off by 1. It is compensated by keeping r_array_base off by 1 word. 1814 1815 const Register 1816 r_array_base = temp1, 1817 r_array_length = temp2; 1818 1819 // The value i in r_array_index is >= 1, so even though r_array_base 1820 // points to the length, we don't need to adjust it to point to the 1821 // data. 1822 assert(Array<Klass*>::base_offset_in_bytes() == wordSize, "Adjust this code"); 1823 assert(Array<Klass*>::length_offset_in_bytes() == 0, "Adjust this code"); 1824 1825 // We will consult the secondary-super array. 1826 ldr(r_array_base, Address(r_sub_klass, in_bytes(Klass::secondary_supers_offset()))); 1827 1828 ldr(result, Address(r_array_base, r_array_index, Address::lsl(LogBytesPerWord))); 1829 eor(result, result, r_super_klass); 1830 cbz(result, L_success ? *L_success : L_fallthrough); // Found a match 1831 1832 // Is there another entry to check? Consult the bitmap. 1833 rorv(r_bitmap, r_bitmap, slot); 1834 // rol(r_bitmap, r_bitmap, 1); 1835 tbz(r_bitmap, 1, L_fallthrough); 1836 1837 // The slot we just inspected is at secondary_supers[r_array_index - 1]. 1838 // The next slot to be inspected, by the logic we're about to call, 1839 // is secondary_supers[r_array_index]. Bits 0 and 1 in the bitmap 1840 // have been checked. 1841 lookup_secondary_supers_table_slow_path(r_super_klass, r_array_base, r_array_index, 1842 r_bitmap, r_array_length, result, /*is_stub*/false); 1843 1844 BLOCK_COMMENT("} lookup_secondary_supers_table"); 1845 1846 bind(L_fallthrough); 1847 1848 if (VerifySecondarySupers) { 1849 verify_secondary_supers_table(r_sub_klass, r_super_klass, // r4, r0 1850 temp1, temp2, result); // r1, r2, r5 1851 } 1852 1853 if (L_success) { 1854 cbz(result, *L_success); 1855 } 1856 } 1857 1858 // Called by code generated by check_klass_subtype_slow_path 1859 // above. This is called when there is a collision in the hashed 1860 // lookup in the secondary supers array. 1861 void MacroAssembler::lookup_secondary_supers_table_slow_path(Register r_super_klass, 1862 Register r_array_base, 1863 Register r_array_index, 1864 Register r_bitmap, 1865 Register temp1, 1866 Register result, 1867 bool is_stub) { 1868 assert_different_registers(r_super_klass, r_array_base, r_array_index, r_bitmap, temp1, result, rscratch1); 1869 1870 const Register 1871 r_array_length = temp1, 1872 r_sub_klass = noreg; // unused 1873 1874 if (is_stub) { 1875 LOOKUP_SECONDARY_SUPERS_TABLE_REGISTERS; 1876 } 1877 1878 Label L_fallthrough, L_huge; 1879 1880 // Load the array length. 1881 ldrw(r_array_length, Address(r_array_base, Array<Klass*>::length_offset_in_bytes())); 1882 // And adjust the array base to point to the data. 1883 // NB! Effectively increments current slot index by 1. 1884 assert(Array<Klass*>::base_offset_in_bytes() == wordSize, ""); 1885 add(r_array_base, r_array_base, Array<Klass*>::base_offset_in_bytes()); 1886 1887 // The bitmap is full to bursting. 1888 // Implicit invariant: BITMAP_FULL implies (length > 0) 1889 assert(Klass::SECONDARY_SUPERS_BITMAP_FULL == ~uintx(0), ""); 1890 cmpw(r_array_length, (u1)(Klass::SECONDARY_SUPERS_TABLE_SIZE - 2)); 1891 br(GT, L_huge); 1892 1893 // NB! Our caller has checked bits 0 and 1 in the bitmap. The 1894 // current slot (at secondary_supers[r_array_index]) has not yet 1895 // been inspected, and r_array_index may be out of bounds if we 1896 // wrapped around the end of the array. 1897 1898 { // This is conventional linear probing, but instead of terminating 1899 // when a null entry is found in the table, we maintain a bitmap 1900 // in which a 0 indicates missing entries. 1901 // As long as the bitmap is not completely full, 1902 // array_length == popcount(bitmap). The array_length check above 1903 // guarantees there are 0s in the bitmap, so the loop eventually 1904 // terminates. 1905 Label L_loop; 1906 bind(L_loop); 1907 1908 // Check for wraparound. 1909 cmp(r_array_index, r_array_length); 1910 csel(r_array_index, zr, r_array_index, GE); 1911 1912 ldr(rscratch1, Address(r_array_base, r_array_index, Address::lsl(LogBytesPerWord))); 1913 eor(result, rscratch1, r_super_klass); 1914 cbz(result, L_fallthrough); 1915 1916 tbz(r_bitmap, 2, L_fallthrough); // look-ahead check (Bit 2); result is non-zero 1917 1918 ror(r_bitmap, r_bitmap, 1); 1919 add(r_array_index, r_array_index, 1); 1920 b(L_loop); 1921 } 1922 1923 { // Degenerate case: more than 64 secondary supers. 1924 // FIXME: We could do something smarter here, maybe a vectorized 1925 // comparison or a binary search, but is that worth any added 1926 // complexity? 1927 bind(L_huge); 1928 cmp(sp, zr); // Clear Z flag; SP is never zero 1929 repne_scan(r_array_base, r_super_klass, r_array_length, rscratch1); 1930 cset(result, NE); // result == 0 iff we got a match. 1931 } 1932 1933 bind(L_fallthrough); 1934 } 1935 1936 // Make sure that the hashed lookup and a linear scan agree. 1937 void MacroAssembler::verify_secondary_supers_table(Register r_sub_klass, 1938 Register r_super_klass, 1939 Register temp1, 1940 Register temp2, 1941 Register result) { 1942 assert_different_registers(r_sub_klass, r_super_klass, temp1, temp2, result, rscratch1); 1943 1944 const Register 1945 r_array_base = temp1, 1946 r_array_length = temp2; 1947 1948 BLOCK_COMMENT("verify_secondary_supers_table {"); 1949 1950 // We will consult the secondary-super array. 1951 ldr(r_array_base, Address(r_sub_klass, in_bytes(Klass::secondary_supers_offset()))); 1952 1953 // Load the array length. 1954 ldrw(r_array_length, Address(r_array_base, Array<Klass*>::length_offset_in_bytes())); 1955 // And adjust the array base to point to the data. 1956 add(r_array_base, r_array_base, Array<Klass*>::base_offset_in_bytes()); 1957 1958 cmp(sp, zr); // Clear Z flag; SP is never zero 1959 // Scan R2 words at [R5] for an occurrence of R0. 1960 // Set NZ/Z based on last compare. 1961 repne_scan(/*addr*/r_array_base, /*value*/r_super_klass, /*count*/r_array_length, rscratch2); 1962 // rscratch1 == 0 iff we got a match. 1963 cset(rscratch1, NE); 1964 1965 Label passed; 1966 cmp(result, zr); 1967 cset(result, NE); // normalize result to 0/1 for comparison 1968 1969 cmp(rscratch1, result); 1970 br(EQ, passed); 1971 { 1972 mov(r0, r_super_klass); // r0 <- r0 1973 mov(r1, r_sub_klass); // r1 <- r4 1974 mov(r2, /*expected*/rscratch1); // r2 <- r8 1975 mov(r3, result); // r3 <- r5 1976 mov(r4, (address)("mismatch")); // r4 <- const 1977 rt_call(CAST_FROM_FN_PTR(address, Klass::on_secondary_supers_verification_failure), rscratch2); 1978 should_not_reach_here(); 1979 } 1980 bind(passed); 1981 1982 BLOCK_COMMENT("} verify_secondary_supers_table"); 1983 } 1984 1985 void MacroAssembler::clinit_barrier(Register klass, Register scratch, Label* L_fast_path, Label* L_slow_path) { 1986 assert(L_fast_path != nullptr || L_slow_path != nullptr, "at least one is required"); 1987 assert_different_registers(klass, rthread, scratch); 1988 1989 Label L_fallthrough, L_tmp; 1990 if (L_fast_path == nullptr) { 1991 L_fast_path = &L_fallthrough; 1992 } else if (L_slow_path == nullptr) { 1993 L_slow_path = &L_fallthrough; 1994 } 1995 // Fast path check: class is fully initialized 1996 lea(scratch, Address(klass, InstanceKlass::init_state_offset())); 1997 ldarb(scratch, scratch); 1998 cmp(scratch, InstanceKlass::fully_initialized); 1999 br(Assembler::EQ, *L_fast_path); 2000 2001 // Fast path check: current thread is initializer thread 2002 ldr(scratch, Address(klass, InstanceKlass::init_thread_offset())); 2003 cmp(rthread, scratch); 2004 2005 if (L_slow_path == &L_fallthrough) { 2006 br(Assembler::EQ, *L_fast_path); 2007 bind(*L_slow_path); 2008 } else if (L_fast_path == &L_fallthrough) { 2009 br(Assembler::NE, *L_slow_path); 2010 bind(*L_fast_path); 2011 } else { 2012 Unimplemented(); 2013 } 2014 } 2015 2016 void MacroAssembler::_verify_oop(Register reg, const char* s, const char* file, int line) { 2017 if (!VerifyOops || VerifyAdapterSharing) { 2018 // Below address of the code string confuses VerifyAdapterSharing 2019 // because it may differ between otherwise equivalent adapters. 2020 return; 2021 } 2022 2023 // Pass register number to verify_oop_subroutine 2024 const char* b = nullptr; 2025 { 2026 ResourceMark rm; 2027 stringStream ss; 2028 ss.print("verify_oop: %s: %s (%s:%d)", reg->name(), s, file, line); 2029 b = code_string(ss.as_string()); 2030 } 2031 BLOCK_COMMENT("verify_oop {"); 2032 2033 strip_return_address(); // This might happen within a stack frame. 2034 protect_return_address(); 2035 stp(r0, rscratch1, Address(pre(sp, -2 * wordSize))); 2036 stp(rscratch2, lr, Address(pre(sp, -2 * wordSize))); 2037 2038 mov(r0, reg); 2039 movptr(rscratch1, (uintptr_t)(address)b); 2040 2041 // call indirectly to solve generation ordering problem 2042 lea(rscratch2, RuntimeAddress(StubRoutines::verify_oop_subroutine_entry_address())); 2043 ldr(rscratch2, Address(rscratch2)); 2044 blr(rscratch2); 2045 2046 ldp(rscratch2, lr, Address(post(sp, 2 * wordSize))); 2047 ldp(r0, rscratch1, Address(post(sp, 2 * wordSize))); 2048 authenticate_return_address(); 2049 2050 BLOCK_COMMENT("} verify_oop"); 2051 } 2052 2053 void MacroAssembler::_verify_oop_addr(Address addr, const char* s, const char* file, int line) { 2054 if (!VerifyOops || VerifyAdapterSharing) { 2055 // Below address of the code string confuses VerifyAdapterSharing 2056 // because it may differ between otherwise equivalent adapters. 2057 return; 2058 } 2059 2060 const char* b = nullptr; 2061 { 2062 ResourceMark rm; 2063 stringStream ss; 2064 ss.print("verify_oop_addr: %s (%s:%d)", s, file, line); 2065 b = code_string(ss.as_string()); 2066 } 2067 BLOCK_COMMENT("verify_oop_addr {"); 2068 2069 strip_return_address(); // This might happen within a stack frame. 2070 protect_return_address(); 2071 stp(r0, rscratch1, Address(pre(sp, -2 * wordSize))); 2072 stp(rscratch2, lr, Address(pre(sp, -2 * wordSize))); 2073 2074 // addr may contain sp so we will have to adjust it based on the 2075 // pushes that we just did. 2076 if (addr.uses(sp)) { 2077 lea(r0, addr); 2078 ldr(r0, Address(r0, 4 * wordSize)); 2079 } else { 2080 ldr(r0, addr); 2081 } 2082 movptr(rscratch1, (uintptr_t)(address)b); 2083 2084 // call indirectly to solve generation ordering problem 2085 lea(rscratch2, RuntimeAddress(StubRoutines::verify_oop_subroutine_entry_address())); 2086 ldr(rscratch2, Address(rscratch2)); 2087 blr(rscratch2); 2088 2089 ldp(rscratch2, lr, Address(post(sp, 2 * wordSize))); 2090 ldp(r0, rscratch1, Address(post(sp, 2 * wordSize))); 2091 authenticate_return_address(); 2092 2093 BLOCK_COMMENT("} verify_oop_addr"); 2094 } 2095 2096 Address MacroAssembler::argument_address(RegisterOrConstant arg_slot, 2097 int extra_slot_offset) { 2098 // cf. TemplateTable::prepare_invoke(), if (load_receiver). 2099 int stackElementSize = Interpreter::stackElementSize; 2100 int offset = Interpreter::expr_offset_in_bytes(extra_slot_offset+0); 2101 #ifdef ASSERT 2102 int offset1 = Interpreter::expr_offset_in_bytes(extra_slot_offset+1); 2103 assert(offset1 - offset == stackElementSize, "correct arithmetic"); 2104 #endif 2105 if (arg_slot.is_constant()) { 2106 return Address(esp, arg_slot.as_constant() * stackElementSize 2107 + offset); 2108 } else { 2109 add(rscratch1, esp, arg_slot.as_register(), 2110 ext::uxtx, exact_log2(stackElementSize)); 2111 return Address(rscratch1, offset); 2112 } 2113 } 2114 2115 // Handle the receiver type profile update given the "recv" klass. 2116 // 2117 // Normally updates the ReceiverData (RD) that starts at "mdp" + "mdp_offset". 2118 // If there are no matching or claimable receiver entries in RD, updates 2119 // the polymorphic counter. 2120 // 2121 // This code expected to run by either the interpreter or JIT-ed code, without 2122 // extra synchronization. For safety, receiver cells are claimed atomically, which 2123 // avoids grossly misrepresenting the profiles under concurrent updates. For speed, 2124 // counter updates are not atomic. 2125 // 2126 void MacroAssembler::profile_receiver_type(Register recv, Register mdp, int mdp_offset) { 2127 assert_different_registers(recv, mdp, rscratch1, rscratch2); 2128 2129 int base_receiver_offset = in_bytes(ReceiverTypeData::receiver_offset(0)); 2130 int end_receiver_offset = in_bytes(ReceiverTypeData::receiver_offset(ReceiverTypeData::row_limit())); 2131 int poly_count_offset = in_bytes(CounterData::count_offset()); 2132 int receiver_step = in_bytes(ReceiverTypeData::receiver_offset(1)) - base_receiver_offset; 2133 int receiver_to_count_step = in_bytes(ReceiverTypeData::receiver_count_offset(0)) - base_receiver_offset; 2134 2135 // Adjust for MDP offsets. 2136 base_receiver_offset += mdp_offset; 2137 end_receiver_offset += mdp_offset; 2138 poly_count_offset += mdp_offset; 2139 2140 #ifdef ASSERT 2141 // We are about to walk the MDO slots without asking for offsets. 2142 // Check that our math hits all the right spots. 2143 for (uint c = 0; c < ReceiverTypeData::row_limit(); c++) { 2144 int real_recv_offset = mdp_offset + in_bytes(ReceiverTypeData::receiver_offset(c)); 2145 int real_count_offset = mdp_offset + in_bytes(ReceiverTypeData::receiver_count_offset(c)); 2146 int offset = base_receiver_offset + receiver_step*c; 2147 int count_offset = offset + receiver_to_count_step; 2148 assert(offset == real_recv_offset, "receiver slot math"); 2149 assert(count_offset == real_count_offset, "receiver count math"); 2150 } 2151 int real_poly_count_offset = mdp_offset + in_bytes(CounterData::count_offset()); 2152 assert(poly_count_offset == real_poly_count_offset, "poly counter math"); 2153 #endif 2154 2155 // Corner case: no profile table. Increment poly counter and exit. 2156 if (ReceiverTypeData::row_limit() == 0) { 2157 increment(Address(mdp, poly_count_offset), DataLayout::counter_increment); 2158 return; 2159 } 2160 2161 Register offset = rscratch2; 2162 2163 Label L_loop_search_receiver, L_loop_search_empty; 2164 Label L_restart, L_found_recv, L_found_empty, L_polymorphic, L_count_update; 2165 2166 // The code here recognizes three major cases: 2167 // A. Fastest: receiver found in the table 2168 // B. Fast: no receiver in the table, and the table is full 2169 // C. Slow: no receiver in the table, free slots in the table 2170 // 2171 // The case A performance is most important, as perfectly-behaved code would end up 2172 // there, especially with larger TypeProfileWidth. The case B performance is 2173 // important as well, this is where bulk of code would land for normally megamorphic 2174 // cases. The case C performance is not essential, its job is to deal with installation 2175 // races, we optimize for code density instead. Case C needs to make sure that receiver 2176 // rows are only claimed once. This makes sure we never overwrite a row for another 2177 // receiver and never duplicate the receivers in the list, making profile type-accurate. 2178 // 2179 // It is very tempting to handle these cases in a single loop, and claim the first slot 2180 // without checking the rest of the table. But, profiling code should tolerate free slots 2181 // in the table, as class unloading can clear them. After such cleanup, the receiver 2182 // we need might be _after_ the free slot. Therefore, we need to let at least full scan 2183 // to complete, before trying to install new slots. Splitting the code in several tight 2184 // loops also helpfully optimizes for cases A and B. 2185 // 2186 // This code is effectively: 2187 // 2188 // restart: 2189 // // Fastest: receiver is already installed 2190 // for (i = 0; i < receiver_count(); i++) { 2191 // if (receiver(i) == recv) goto found_recv(i); 2192 // } 2193 // 2194 // // Fast: no receiver, but profile is full 2195 // for (i = 0; i < receiver_count(); i++) { 2196 // if (receiver(i) == null) goto found_null(i); 2197 // } 2198 // goto polymorphic 2199 // 2200 // // Slow: try to install receiver 2201 // found_null(i): 2202 // CAS(&receiver(i), null, recv); 2203 // goto restart 2204 // 2205 // polymorphic: 2206 // count++; 2207 // return 2208 // 2209 // found_recv(i): 2210 // *receiver_count(i)++ 2211 // 2212 2213 bind(L_restart); 2214 2215 // Fastest: receiver is already installed 2216 mov(offset, base_receiver_offset); 2217 bind(L_loop_search_receiver); 2218 ldr(rscratch1, Address(mdp, offset)); 2219 cmp(rscratch1, recv); 2220 br(Assembler::EQ, L_found_recv); 2221 add(offset, offset, receiver_step); 2222 sub(rscratch1, offset, end_receiver_offset); 2223 cbnz(rscratch1, L_loop_search_receiver); 2224 2225 // Fast: no receiver, but profile is full 2226 mov(offset, base_receiver_offset); 2227 bind(L_loop_search_empty); 2228 ldr(rscratch1, Address(mdp, offset)); 2229 cbz(rscratch1, L_found_empty); 2230 add(offset, offset, receiver_step); 2231 sub(rscratch1, offset, end_receiver_offset); 2232 cbnz(rscratch1, L_loop_search_empty); 2233 b(L_polymorphic); 2234 2235 // Slow: try to install receiver 2236 bind(L_found_empty); 2237 2238 // Atomically swing receiver slot: null -> recv. 2239 // 2240 // The update uses CAS, which clobbers rscratch1. Therefore, rscratch2 2241 // is used to hold the destination address. This is safe because the 2242 // offset is no longer needed after the address is computed. 2243 2244 lea(rscratch2, Address(mdp, offset)); 2245 cmpxchg(/*addr*/ rscratch2, /*expected*/ zr, /*new*/ recv, Assembler::xword, 2246 /*acquire*/ false, /*release*/ false, /*weak*/ true, noreg); 2247 2248 // CAS success means the slot now has the receiver we want. CAS failure means 2249 // something had claimed the slot concurrently: it can be the same receiver we want, 2250 // or something else. Since this is a slow path, we can optimize for code density, 2251 // and just restart the search from the beginning. 2252 b(L_restart); 2253 2254 // Counter updates: 2255 2256 // Increment polymorphic counter instead of receiver slot. 2257 bind(L_polymorphic); 2258 mov(offset, poly_count_offset); 2259 b(L_count_update); 2260 2261 // Found a receiver, convert its slot offset to corresponding count offset. 2262 bind(L_found_recv); 2263 add(offset, offset, receiver_to_count_step); 2264 2265 bind(L_count_update); 2266 increment(Address(mdp, offset), DataLayout::counter_increment); 2267 } 2268 2269 2270 void MacroAssembler::call_VM_leaf_base(address entry_point, 2271 int number_of_arguments, 2272 Label *retaddr) { 2273 Label E, L; 2274 2275 stp(rscratch1, rmethod, Address(pre(sp, -2 * wordSize))); 2276 2277 mov(rscratch1, RuntimeAddress(entry_point)); 2278 blr(rscratch1); 2279 if (retaddr) 2280 bind(*retaddr); 2281 2282 ldp(rscratch1, rmethod, Address(post(sp, 2 * wordSize))); 2283 } 2284 2285 void MacroAssembler::call_VM_leaf(address entry_point, int number_of_arguments) { 2286 call_VM_leaf_base(entry_point, number_of_arguments); 2287 } 2288 2289 void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0) { 2290 pass_arg0(this, arg_0); 2291 call_VM_leaf_base(entry_point, 1); 2292 } 2293 2294 void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0, Register arg_1) { 2295 assert_different_registers(arg_1, c_rarg0); 2296 pass_arg0(this, arg_0); 2297 pass_arg1(this, arg_1); 2298 call_VM_leaf_base(entry_point, 2); 2299 } 2300 2301 void MacroAssembler::call_VM_leaf(address entry_point, Register arg_0, 2302 Register arg_1, Register arg_2) { 2303 assert_different_registers(arg_1, c_rarg0); 2304 assert_different_registers(arg_2, c_rarg0, c_rarg1); 2305 pass_arg0(this, arg_0); 2306 pass_arg1(this, arg_1); 2307 pass_arg2(this, arg_2); 2308 call_VM_leaf_base(entry_point, 3); 2309 } 2310 2311 void MacroAssembler::super_call_VM_leaf(address entry_point) { 2312 MacroAssembler::call_VM_leaf_base(entry_point, 1); 2313 } 2314 2315 void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0) { 2316 pass_arg0(this, arg_0); 2317 MacroAssembler::call_VM_leaf_base(entry_point, 1); 2318 } 2319 2320 void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1) { 2321 2322 assert_different_registers(arg_0, c_rarg1); 2323 pass_arg1(this, arg_1); 2324 pass_arg0(this, arg_0); 2325 MacroAssembler::call_VM_leaf_base(entry_point, 2); 2326 } 2327 2328 void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1, Register arg_2) { 2329 assert_different_registers(arg_0, c_rarg1, c_rarg2); 2330 assert_different_registers(arg_1, c_rarg2); 2331 pass_arg2(this, arg_2); 2332 pass_arg1(this, arg_1); 2333 pass_arg0(this, arg_0); 2334 MacroAssembler::call_VM_leaf_base(entry_point, 3); 2335 } 2336 2337 void MacroAssembler::super_call_VM_leaf(address entry_point, Register arg_0, Register arg_1, Register arg_2, Register arg_3) { 2338 assert_different_registers(arg_0, c_rarg1, c_rarg2, c_rarg3); 2339 assert_different_registers(arg_1, c_rarg2, c_rarg3); 2340 assert_different_registers(arg_2, c_rarg3); 2341 pass_arg3(this, arg_3); 2342 pass_arg2(this, arg_2); 2343 pass_arg1(this, arg_1); 2344 pass_arg0(this, arg_0); 2345 MacroAssembler::call_VM_leaf_base(entry_point, 4); 2346 } 2347 2348 void MacroAssembler::null_check(Register reg, int offset) { 2349 if (needs_explicit_null_check(offset)) { 2350 // provoke OS null exception if reg is null by 2351 // accessing M[reg] w/o changing any registers 2352 // NOTE: this is plenty to provoke a segv 2353 ldr(zr, Address(reg)); 2354 } else { 2355 // nothing to do, (later) access of M[reg + offset] 2356 // will provoke OS null exception if reg is null 2357 } 2358 } 2359 2360 void MacroAssembler::test_markword_is_inline_type(Register markword, Label& is_inline_type) { 2361 assert_different_registers(markword, rscratch2); 2362 mov(rscratch2, markWord::inline_type_pattern_mask); 2363 andr(markword, markword, rscratch2); 2364 mov(rscratch2, markWord::inline_type_pattern); 2365 cmp(markword, rscratch2); 2366 br(Assembler::EQ, is_inline_type); 2367 } 2368 2369 void MacroAssembler::test_oop_is_not_inline_type(Register object, Register tmp, Label& not_inline_type, bool can_be_null) { 2370 assert_different_registers(tmp, rscratch1); 2371 if (can_be_null) { 2372 cbz(object, not_inline_type); 2373 } 2374 const int is_inline_type_mask = markWord::inline_type_pattern; 2375 ldr(tmp, Address(object, oopDesc::mark_offset_in_bytes())); 2376 mov(rscratch1, is_inline_type_mask); 2377 andr(tmp, tmp, rscratch1); 2378 cmp(tmp, rscratch1); 2379 br(Assembler::NE, not_inline_type); 2380 } 2381 2382 void MacroAssembler::test_field_is_null_free_inline_type(Register flags, Register temp_reg, Label& is_null_free_inline_type) { 2383 assert(temp_reg == noreg, "not needed"); // keep signature uniform with x86 2384 tbnz(flags, ResolvedFieldEntry::is_null_free_inline_type_shift, is_null_free_inline_type); 2385 } 2386 2387 void MacroAssembler::test_field_is_not_null_free_inline_type(Register flags, Register temp_reg, Label& not_null_free_inline_type) { 2388 assert(temp_reg == noreg, "not needed"); // keep signature uniform with x86 2389 tbz(flags, ResolvedFieldEntry::is_null_free_inline_type_shift, not_null_free_inline_type); 2390 } 2391 2392 void MacroAssembler::test_field_is_flat(Register flags, Register temp_reg, Label& is_flat) { 2393 assert(temp_reg == noreg, "not needed"); // keep signature uniform with x86 2394 tbnz(flags, ResolvedFieldEntry::is_flat_shift, is_flat); 2395 } 2396 2397 void MacroAssembler::test_oop_prototype_bit(Register oop, Register temp_reg, int32_t test_bit, bool jmp_set, Label& jmp_label) { 2398 Label test_mark_word; 2399 // load mark word 2400 ldr(temp_reg, Address(oop, oopDesc::mark_offset_in_bytes())); 2401 // check displaced 2402 tst(temp_reg, markWord::unlocked_value); 2403 br(Assembler::NE, test_mark_word); 2404 // slow path use klass prototype 2405 load_prototype_header(temp_reg, oop); 2406 2407 bind(test_mark_word); 2408 andr(temp_reg, temp_reg, test_bit); 2409 if (jmp_set) { 2410 cbnz(temp_reg, jmp_label); 2411 } else { 2412 cbz(temp_reg, jmp_label); 2413 } 2414 } 2415 2416 void MacroAssembler::test_flat_array_oop(Register oop, Register temp_reg, Label& is_flat_array) { 2417 test_oop_prototype_bit(oop, temp_reg, markWord::flat_array_bit_in_place, true, is_flat_array); 2418 } 2419 2420 void MacroAssembler::test_non_flat_array_oop(Register oop, Register temp_reg, 2421 Label&is_non_flat_array) { 2422 test_oop_prototype_bit(oop, temp_reg, markWord::flat_array_bit_in_place, false, is_non_flat_array); 2423 } 2424 2425 void MacroAssembler::test_null_free_array_oop(Register oop, Register temp_reg, Label& is_null_free_array) { 2426 test_oop_prototype_bit(oop, temp_reg, markWord::null_free_array_bit_in_place, true, is_null_free_array); 2427 } 2428 2429 void MacroAssembler::test_non_null_free_array_oop(Register oop, Register temp_reg, Label&is_non_null_free_array) { 2430 test_oop_prototype_bit(oop, temp_reg, markWord::null_free_array_bit_in_place, false, is_non_null_free_array); 2431 } 2432 2433 void MacroAssembler::test_flat_array_layout(Register lh, Label& is_flat_array) { 2434 tst(lh, Klass::_lh_array_tag_flat_value_bit_inplace); 2435 br(Assembler::NE, is_flat_array); 2436 } 2437 2438 // MacroAssembler protected routines needed to implement 2439 // public methods 2440 2441 void MacroAssembler::mov(Register r, Address dest) { 2442 code_section()->relocate(pc(), dest.rspec()); 2443 uint64_t imm64 = (uint64_t)dest.target(); 2444 movptr(r, imm64); 2445 } 2446 2447 // Move a constant pointer into r. In AArch64 mode the virtual 2448 // address space is 48 bits in size, so we only need three 2449 // instructions to create a patchable instruction sequence that can 2450 // reach anywhere. 2451 void MacroAssembler::movptr(Register r, uintptr_t imm64) { 2452 #ifndef PRODUCT 2453 { 2454 char buffer[64]; 2455 os::snprintf_checked(buffer, sizeof(buffer), "0x%" PRIX64, (uint64_t)imm64); 2456 block_comment(buffer); 2457 } 2458 #endif 2459 assert(imm64 < (1ull << 48), "48-bit overflow in address constant"); 2460 movz(r, imm64 & 0xffff); 2461 imm64 >>= 16; 2462 movk(r, imm64 & 0xffff, 16); 2463 imm64 >>= 16; 2464 movk(r, imm64 & 0xffff, 32); 2465 } 2466 2467 // Macro to mov replicated immediate to vector register. 2468 // imm64: only the lower 8/16/32 bits are considered for B/H/S type. That is, 2469 // the upper 56/48/32 bits must be zeros for B/H/S type. 2470 // Vd will get the following values for different arrangements in T 2471 // imm64 == hex 000000gh T8B: Vd = ghghghghghghghgh 2472 // imm64 == hex 000000gh T16B: Vd = ghghghghghghghghghghghghghghghgh 2473 // imm64 == hex 0000efgh T4H: Vd = efghefghefghefgh 2474 // imm64 == hex 0000efgh T8H: Vd = efghefghefghefghefghefghefghefgh 2475 // imm64 == hex abcdefgh T2S: Vd = abcdefghabcdefgh 2476 // imm64 == hex abcdefgh T4S: Vd = abcdefghabcdefghabcdefghabcdefgh 2477 // imm64 == hex abcdefgh T1D: Vd = 00000000abcdefgh 2478 // imm64 == hex abcdefgh T2D: Vd = 00000000abcdefgh00000000abcdefgh 2479 // Clobbers rscratch1 2480 void MacroAssembler::mov(FloatRegister Vd, SIMD_Arrangement T, uint64_t imm64) { 2481 assert(T != T1Q, "unsupported"); 2482 if (T == T1D || T == T2D) { 2483 int imm = operand_valid_for_movi_immediate(imm64, T); 2484 if (-1 != imm) { 2485 movi(Vd, T, imm); 2486 } else { 2487 mov(rscratch1, imm64); 2488 dup(Vd, T, rscratch1); 2489 } 2490 return; 2491 } 2492 2493 #ifdef ASSERT 2494 if (T == T8B || T == T16B) assert((imm64 & ~0xff) == 0, "extraneous bits (T8B/T16B)"); 2495 if (T == T4H || T == T8H) assert((imm64 & ~0xffff) == 0, "extraneous bits (T4H/T8H)"); 2496 if (T == T2S || T == T4S) assert((imm64 & ~0xffffffff) == 0, "extraneous bits (T2S/T4S)"); 2497 #endif 2498 int shift = operand_valid_for_movi_immediate(imm64, T); 2499 uint32_t imm32 = imm64 & 0xffffffffULL; 2500 if (shift >= 0) { 2501 movi(Vd, T, (imm32 >> shift) & 0xff, shift); 2502 } else { 2503 movw(rscratch1, imm32); 2504 dup(Vd, T, rscratch1); 2505 } 2506 } 2507 2508 void MacroAssembler::mov_immediate64(Register dst, uint64_t imm64) 2509 { 2510 #ifndef PRODUCT 2511 { 2512 char buffer[64]; 2513 os::snprintf_checked(buffer, sizeof(buffer), "0x%" PRIX64, imm64); 2514 block_comment(buffer); 2515 } 2516 #endif 2517 if (operand_valid_for_logical_immediate(false, imm64)) { 2518 orr(dst, zr, imm64); 2519 } else { 2520 // we can use a combination of MOVZ or MOVN with 2521 // MOVK to build up the constant 2522 uint64_t imm_h[4]; 2523 int zero_count = 0; 2524 int neg_count = 0; 2525 int i; 2526 for (i = 0; i < 4; i++) { 2527 imm_h[i] = ((imm64 >> (i * 16)) & 0xffffL); 2528 if (imm_h[i] == 0) { 2529 zero_count++; 2530 } else if (imm_h[i] == 0xffffL) { 2531 neg_count++; 2532 } 2533 } 2534 if (zero_count == 4) { 2535 // one MOVZ will do 2536 movz(dst, 0); 2537 } else if (neg_count == 4) { 2538 // one MOVN will do 2539 movn(dst, 0); 2540 } else if (zero_count == 3) { 2541 for (i = 0; i < 4; i++) { 2542 if (imm_h[i] != 0L) { 2543 movz(dst, (uint32_t)imm_h[i], (i << 4)); 2544 break; 2545 } 2546 } 2547 } else if (neg_count == 3) { 2548 // one MOVN will do 2549 for (int i = 0; i < 4; i++) { 2550 if (imm_h[i] != 0xffffL) { 2551 movn(dst, (uint32_t)imm_h[i] ^ 0xffffL, (i << 4)); 2552 break; 2553 } 2554 } 2555 } else if (zero_count == 2) { 2556 // one MOVZ and one MOVK will do 2557 for (i = 0; i < 3; i++) { 2558 if (imm_h[i] != 0L) { 2559 movz(dst, (uint32_t)imm_h[i], (i << 4)); 2560 i++; 2561 break; 2562 } 2563 } 2564 for (;i < 4; i++) { 2565 if (imm_h[i] != 0L) { 2566 movk(dst, (uint32_t)imm_h[i], (i << 4)); 2567 } 2568 } 2569 } else if (neg_count == 2) { 2570 // one MOVN and one MOVK will do 2571 for (i = 0; i < 4; i++) { 2572 if (imm_h[i] != 0xffffL) { 2573 movn(dst, (uint32_t)imm_h[i] ^ 0xffffL, (i << 4)); 2574 i++; 2575 break; 2576 } 2577 } 2578 for (;i < 4; i++) { 2579 if (imm_h[i] != 0xffffL) { 2580 movk(dst, (uint32_t)imm_h[i], (i << 4)); 2581 } 2582 } 2583 } else if (zero_count == 1) { 2584 // one MOVZ and two MOVKs will do 2585 for (i = 0; i < 4; i++) { 2586 if (imm_h[i] != 0L) { 2587 movz(dst, (uint32_t)imm_h[i], (i << 4)); 2588 i++; 2589 break; 2590 } 2591 } 2592 for (;i < 4; i++) { 2593 if (imm_h[i] != 0x0L) { 2594 movk(dst, (uint32_t)imm_h[i], (i << 4)); 2595 } 2596 } 2597 } else if (neg_count == 1) { 2598 // one MOVN and two MOVKs will do 2599 for (i = 0; i < 4; i++) { 2600 if (imm_h[i] != 0xffffL) { 2601 movn(dst, (uint32_t)imm_h[i] ^ 0xffffL, (i << 4)); 2602 i++; 2603 break; 2604 } 2605 } 2606 for (;i < 4; i++) { 2607 if (imm_h[i] != 0xffffL) { 2608 movk(dst, (uint32_t)imm_h[i], (i << 4)); 2609 } 2610 } 2611 } else { 2612 // use a MOVZ and 3 MOVKs (makes it easier to debug) 2613 movz(dst, (uint32_t)imm_h[0], 0); 2614 for (i = 1; i < 4; i++) { 2615 movk(dst, (uint32_t)imm_h[i], (i << 4)); 2616 } 2617 } 2618 } 2619 } 2620 2621 void MacroAssembler::mov_immediate32(Register dst, uint32_t imm32) 2622 { 2623 #ifndef PRODUCT 2624 { 2625 char buffer[64]; 2626 os::snprintf_checked(buffer, sizeof(buffer), "0x%" PRIX32, imm32); 2627 block_comment(buffer); 2628 } 2629 #endif 2630 if (operand_valid_for_logical_immediate(true, imm32)) { 2631 orrw(dst, zr, imm32); 2632 } else { 2633 // we can use MOVZ, MOVN or two calls to MOVK to build up the 2634 // constant 2635 uint32_t imm_h[2]; 2636 imm_h[0] = imm32 & 0xffff; 2637 imm_h[1] = ((imm32 >> 16) & 0xffff); 2638 if (imm_h[0] == 0) { 2639 movzw(dst, imm_h[1], 16); 2640 } else if (imm_h[0] == 0xffff) { 2641 movnw(dst, imm_h[1] ^ 0xffff, 16); 2642 } else if (imm_h[1] == 0) { 2643 movzw(dst, imm_h[0], 0); 2644 } else if (imm_h[1] == 0xffff) { 2645 movnw(dst, imm_h[0] ^ 0xffff, 0); 2646 } else { 2647 // use a MOVZ and MOVK (makes it easier to debug) 2648 movzw(dst, imm_h[0], 0); 2649 movkw(dst, imm_h[1], 16); 2650 } 2651 } 2652 } 2653 2654 // Form an address from base + offset in Rd. Rd may or may 2655 // not actually be used: you must use the Address that is returned. 2656 // It is up to you to ensure that the shift provided matches the size 2657 // of your data. 2658 Address MacroAssembler::form_address(Register Rd, Register base, int64_t byte_offset, int shift) { 2659 if (Address::offset_ok_for_immed(byte_offset, shift)) 2660 // It fits; no need for any heroics 2661 return Address(base, byte_offset); 2662 2663 // Don't do anything clever with negative or misaligned offsets 2664 unsigned mask = (1 << shift) - 1; 2665 if (byte_offset < 0 || byte_offset & mask) { 2666 mov(Rd, byte_offset); 2667 add(Rd, base, Rd); 2668 return Address(Rd); 2669 } 2670 2671 // See if we can do this with two 12-bit offsets 2672 { 2673 uint64_t word_offset = byte_offset >> shift; 2674 uint64_t masked_offset = word_offset & 0xfff000; 2675 if (Address::offset_ok_for_immed(word_offset - masked_offset, 0) 2676 && Assembler::operand_valid_for_add_sub_immediate(masked_offset << shift)) { 2677 add(Rd, base, masked_offset << shift); 2678 word_offset -= masked_offset; 2679 return Address(Rd, word_offset << shift); 2680 } 2681 } 2682 2683 // Do it the hard way 2684 mov(Rd, byte_offset); 2685 add(Rd, base, Rd); 2686 return Address(Rd); 2687 } 2688 2689 int MacroAssembler::corrected_idivl(Register result, Register ra, Register rb, 2690 bool want_remainder, Register scratch) 2691 { 2692 // Full implementation of Java idiv and irem. The function 2693 // returns the (pc) offset of the div instruction - may be needed 2694 // for implicit exceptions. 2695 // 2696 // constraint : ra/rb =/= scratch 2697 // normal case 2698 // 2699 // input : ra: dividend 2700 // rb: divisor 2701 // 2702 // result: either 2703 // quotient (= ra idiv rb) 2704 // remainder (= ra irem rb) 2705 2706 assert(ra != scratch && rb != scratch, "reg cannot be scratch"); 2707 2708 int idivl_offset = offset(); 2709 if (! want_remainder) { 2710 sdivw(result, ra, rb); 2711 } else { 2712 sdivw(scratch, ra, rb); 2713 Assembler::msubw(result, scratch, rb, ra); 2714 } 2715 2716 return idivl_offset; 2717 } 2718 2719 int MacroAssembler::corrected_idivq(Register result, Register ra, Register rb, 2720 bool want_remainder, Register scratch) 2721 { 2722 // Full implementation of Java ldiv and lrem. The function 2723 // returns the (pc) offset of the div instruction - may be needed 2724 // for implicit exceptions. 2725 // 2726 // constraint : ra/rb =/= scratch 2727 // normal case 2728 // 2729 // input : ra: dividend 2730 // rb: divisor 2731 // 2732 // result: either 2733 // quotient (= ra idiv rb) 2734 // remainder (= ra irem rb) 2735 2736 assert(ra != scratch && rb != scratch, "reg cannot be scratch"); 2737 2738 int idivq_offset = offset(); 2739 if (! want_remainder) { 2740 sdiv(result, ra, rb); 2741 } else { 2742 sdiv(scratch, ra, rb); 2743 Assembler::msub(result, scratch, rb, ra); 2744 } 2745 2746 return idivq_offset; 2747 } 2748 2749 void MacroAssembler::membar(Membar_mask_bits order_constraint) { 2750 address prev = pc() - NativeMembar::instruction_size; 2751 address last = code()->last_merge_candidate(); 2752 if (last != nullptr && nativeInstruction_at(last)->is_Membar() && prev == last) { 2753 NativeMembar *bar = NativeMembar_at(prev); 2754 if (AlwaysMergeDMB) { 2755 bar->set_kind(bar->get_kind() | order_constraint); 2756 BLOCK_COMMENT("merged membar(always)"); 2757 return; 2758 } 2759 // Don't promote DMB ST|DMB LD to DMB (a full barrier) because 2760 // doing so would introduce a StoreLoad which the caller did not 2761 // intend 2762 if (bar->get_kind() == order_constraint 2763 || bar->get_kind() == AnyAny 2764 || order_constraint == AnyAny) { 2765 // We are merging two memory barrier instructions. On AArch64 we 2766 // can do this simply by ORing them together. 2767 bar->set_kind(bar->get_kind() | order_constraint); 2768 BLOCK_COMMENT("merged membar"); 2769 return; 2770 } else { 2771 // A special case like "DMB ST;DMB LD;DMB ST", the last DMB can be skipped. 2772 // We need to check the second-to-last instruction, only if it is inside 2773 // the current code section. 2774 address prev2 = prev - NativeMembar::instruction_size; 2775 if (prev2 >= begin() && last != code()->last_label() && nativeInstruction_at(prev2)->is_Membar()) { 2776 NativeMembar *bar2 = NativeMembar_at(prev2); 2777 assert(bar2->get_kind() == order_constraint, "it should be merged before"); 2778 BLOCK_COMMENT("merged membar(elided)"); 2779 return; 2780 } 2781 } 2782 } 2783 code()->set_last_merge_candidate(pc()); 2784 dmb(Assembler::barrier(order_constraint)); 2785 } 2786 2787 bool MacroAssembler::try_merge_ldst(Register rt, const Address &adr, size_t size_in_bytes, bool is_store) { 2788 if (ldst_can_merge(rt, adr, size_in_bytes, is_store)) { 2789 merge_ldst(rt, adr, size_in_bytes, is_store); 2790 code()->clear_last_merge_candidate(); 2791 return true; 2792 } else { 2793 assert(size_in_bytes == 8 || size_in_bytes == 4, "only 8 bytes or 4 bytes load/store is supported."); 2794 const uint64_t mask = size_in_bytes - 1; 2795 if (adr.getMode() == Address::base_plus_offset && 2796 (adr.offset() & mask) == 0) { // only supports base_plus_offset. 2797 code()->set_last_merge_candidate(pc()); 2798 } 2799 return false; 2800 } 2801 } 2802 2803 void MacroAssembler::ldr(Register Rx, const Address &adr) { 2804 // We always try to merge two adjacent loads into one ldp. 2805 if (!try_merge_ldst(Rx, adr, 8, false)) { 2806 Assembler::ldr(Rx, adr); 2807 } 2808 } 2809 2810 void MacroAssembler::ldrw(Register Rw, const Address &adr) { 2811 // We always try to merge two adjacent loads into one ldp. 2812 if (!try_merge_ldst(Rw, adr, 4, false)) { 2813 Assembler::ldrw(Rw, adr); 2814 } 2815 } 2816 2817 void MacroAssembler::str(Register Rx, const Address &adr) { 2818 // We always try to merge two adjacent stores into one stp. 2819 if (!try_merge_ldst(Rx, adr, 8, true)) { 2820 Assembler::str(Rx, adr); 2821 } 2822 } 2823 2824 void MacroAssembler::strw(Register Rw, const Address &adr) { 2825 // We always try to merge two adjacent stores into one stp. 2826 if (!try_merge_ldst(Rw, adr, 4, true)) { 2827 Assembler::strw(Rw, adr); 2828 } 2829 } 2830 2831 // MacroAssembler routines found actually to be needed 2832 2833 void MacroAssembler::push(Register src) 2834 { 2835 str(src, Address(pre(esp, -1 * wordSize))); 2836 } 2837 2838 void MacroAssembler::pop(Register dst) 2839 { 2840 ldr(dst, Address(post(esp, 1 * wordSize))); 2841 } 2842 2843 // Note: load_unsigned_short used to be called load_unsigned_word. 2844 int MacroAssembler::load_unsigned_short(Register dst, Address src) { 2845 int off = offset(); 2846 ldrh(dst, src); 2847 return off; 2848 } 2849 2850 int MacroAssembler::load_unsigned_byte(Register dst, Address src) { 2851 int off = offset(); 2852 ldrb(dst, src); 2853 return off; 2854 } 2855 2856 int MacroAssembler::load_signed_short(Register dst, Address src) { 2857 int off = offset(); 2858 ldrsh(dst, src); 2859 return off; 2860 } 2861 2862 int MacroAssembler::load_signed_byte(Register dst, Address src) { 2863 int off = offset(); 2864 ldrsb(dst, src); 2865 return off; 2866 } 2867 2868 int MacroAssembler::load_signed_short32(Register dst, Address src) { 2869 int off = offset(); 2870 ldrshw(dst, src); 2871 return off; 2872 } 2873 2874 int MacroAssembler::load_signed_byte32(Register dst, Address src) { 2875 int off = offset(); 2876 ldrsbw(dst, src); 2877 return off; 2878 } 2879 2880 void MacroAssembler::load_sized_value(Register dst, Address src, size_t size_in_bytes, bool is_signed) { 2881 switch (size_in_bytes) { 2882 case 8: ldr(dst, src); break; 2883 case 4: ldrw(dst, src); break; 2884 case 2: is_signed ? load_signed_short(dst, src) : load_unsigned_short(dst, src); break; 2885 case 1: is_signed ? load_signed_byte( dst, src) : load_unsigned_byte( dst, src); break; 2886 default: ShouldNotReachHere(); 2887 } 2888 } 2889 2890 void MacroAssembler::store_sized_value(Address dst, Register src, size_t size_in_bytes) { 2891 switch (size_in_bytes) { 2892 case 8: str(src, dst); break; 2893 case 4: strw(src, dst); break; 2894 case 2: strh(src, dst); break; 2895 case 1: strb(src, dst); break; 2896 default: ShouldNotReachHere(); 2897 } 2898 } 2899 2900 void MacroAssembler::narrow_subword_type(Register reg, BasicType bt) { 2901 assert(is_subword_type(bt), "required"); 2902 switch (bt) { 2903 case T_BOOLEAN: andw(reg, reg, 1); break; 2904 case T_BYTE: sxtbw(reg, reg); break; 2905 case T_CHAR: uxthw(reg, reg); break; 2906 case T_SHORT: sxthw(reg, reg); break; 2907 default: ShouldNotReachHere(); 2908 } 2909 } 2910 2911 void MacroAssembler::decrementw(Register reg, int value) 2912 { 2913 if (value < 0) { incrementw(reg, -value); return; } 2914 if (value == 0) { return; } 2915 if (value < (1 << 12)) { subw(reg, reg, value); return; } 2916 /* else */ { 2917 guarantee(reg != rscratch2, "invalid dst for register decrement"); 2918 movw(rscratch2, (unsigned)value); 2919 subw(reg, reg, rscratch2); 2920 } 2921 } 2922 2923 void MacroAssembler::decrement(Register reg, int value) 2924 { 2925 if (value < 0) { increment(reg, -value); return; } 2926 if (value == 0) { return; } 2927 if (value < (1 << 12)) { sub(reg, reg, value); return; } 2928 /* else */ { 2929 assert(reg != rscratch2, "invalid dst for register decrement"); 2930 mov(rscratch2, (uint64_t)value); 2931 sub(reg, reg, rscratch2); 2932 } 2933 } 2934 2935 void MacroAssembler::decrementw(Address dst, int value) 2936 { 2937 assert(!dst.uses(rscratch1), "invalid dst for address decrement"); 2938 if (dst.getMode() == Address::literal) { 2939 assert(abs(value) < (1 << 12), "invalid value and address mode combination"); 2940 lea(rscratch2, dst); 2941 dst = Address(rscratch2); 2942 } 2943 ldrw(rscratch1, dst); 2944 decrementw(rscratch1, value); 2945 strw(rscratch1, dst); 2946 } 2947 2948 void MacroAssembler::decrement(Address dst, int value) 2949 { 2950 assert(!dst.uses(rscratch1), "invalid address for decrement"); 2951 if (dst.getMode() == Address::literal) { 2952 assert(abs(value) < (1 << 12), "invalid value and address mode combination"); 2953 lea(rscratch2, dst); 2954 dst = Address(rscratch2); 2955 } 2956 ldr(rscratch1, dst); 2957 decrement(rscratch1, value); 2958 str(rscratch1, dst); 2959 } 2960 2961 void MacroAssembler::incrementw(Register reg, int value) 2962 { 2963 if (value < 0) { decrementw(reg, -value); return; } 2964 if (value == 0) { return; } 2965 if (value < (1 << 12)) { addw(reg, reg, value); return; } 2966 /* else */ { 2967 assert(reg != rscratch2, "invalid dst for register increment"); 2968 movw(rscratch2, (unsigned)value); 2969 addw(reg, reg, rscratch2); 2970 } 2971 } 2972 2973 void MacroAssembler::increment(Register reg, int value) 2974 { 2975 if (value < 0) { decrement(reg, -value); return; } 2976 if (value == 0) { return; } 2977 if (value < (1 << 12)) { add(reg, reg, value); return; } 2978 /* else */ { 2979 assert(reg != rscratch2, "invalid dst for register increment"); 2980 movw(rscratch2, (unsigned)value); 2981 add(reg, reg, rscratch2); 2982 } 2983 } 2984 2985 void MacroAssembler::incrementw(Address dst, int value) 2986 { 2987 assert(!dst.uses(rscratch1), "invalid dst for address increment"); 2988 if (dst.getMode() == Address::literal) { 2989 assert(abs(value) < (1 << 12), "invalid value and address mode combination"); 2990 lea(rscratch2, dst); 2991 dst = Address(rscratch2); 2992 } 2993 ldrw(rscratch1, dst); 2994 incrementw(rscratch1, value); 2995 strw(rscratch1, dst); 2996 } 2997 2998 void MacroAssembler::increment(Address dst, int value) 2999 { 3000 assert(!dst.uses(rscratch1), "invalid dst for address increment"); 3001 if (dst.getMode() == Address::literal) { 3002 assert(abs(value) < (1 << 12), "invalid value and address mode combination"); 3003 lea(rscratch2, dst); 3004 dst = Address(rscratch2); 3005 } 3006 ldr(rscratch1, dst); 3007 increment(rscratch1, value); 3008 str(rscratch1, dst); 3009 } 3010 3011 // Push lots of registers in the bit set supplied. Don't push sp. 3012 // Return the number of words pushed 3013 int MacroAssembler::push(RegSet regset, Register stack) { 3014 if (regset.bits() == 0) { 3015 return 0; 3016 } 3017 auto bitset = integer_cast<unsigned int>(regset.bits()); 3018 int words_pushed = 0; 3019 3020 // Scan bitset to accumulate register pairs 3021 unsigned char regs[32]; 3022 int count = 0; 3023 for (int reg = 0; reg <= 30; reg++) { 3024 if (1 & bitset) 3025 regs[count++] = reg; 3026 bitset >>= 1; 3027 } 3028 regs[count++] = zr->raw_encoding(); 3029 count &= ~1; // Only push an even number of regs 3030 3031 if (count) { 3032 stp(as_Register(regs[0]), as_Register(regs[1]), 3033 Address(pre(stack, -count * wordSize))); 3034 words_pushed += 2; 3035 } 3036 for (int i = 2; i < count; i += 2) { 3037 stp(as_Register(regs[i]), as_Register(regs[i+1]), 3038 Address(stack, i * wordSize)); 3039 words_pushed += 2; 3040 } 3041 3042 assert(words_pushed == count, "oops, pushed != count"); 3043 3044 return count; 3045 } 3046 3047 int MacroAssembler::pop(RegSet regset, Register stack) { 3048 if (regset.bits() == 0) { 3049 return 0; 3050 } 3051 auto bitset = integer_cast<unsigned int>(regset.bits()); 3052 int words_pushed = 0; 3053 3054 // Scan bitset to accumulate register pairs 3055 unsigned char regs[32]; 3056 int count = 0; 3057 for (int reg = 0; reg <= 30; reg++) { 3058 if (1 & bitset) 3059 regs[count++] = reg; 3060 bitset >>= 1; 3061 } 3062 regs[count++] = zr->raw_encoding(); 3063 count &= ~1; 3064 3065 for (int i = 2; i < count; i += 2) { 3066 ldp(as_Register(regs[i]), as_Register(regs[i+1]), 3067 Address(stack, i * wordSize)); 3068 words_pushed += 2; 3069 } 3070 if (count) { 3071 ldp(as_Register(regs[0]), as_Register(regs[1]), 3072 Address(post(stack, count * wordSize))); 3073 words_pushed += 2; 3074 } 3075 3076 assert(words_pushed == count, "oops, pushed != count"); 3077 3078 return count; 3079 } 3080 3081 // Push lots of registers in the bit set supplied. Don't push sp. 3082 // Return the number of dwords pushed 3083 int MacroAssembler::push_fp(FloatRegSet regset, Register stack, FpPushPopMode mode) { 3084 if (regset.bits() == 0) { 3085 return 0; 3086 } 3087 auto bitset = integer_cast<unsigned int>(regset.bits()); 3088 int words_pushed = 0; 3089 bool use_sve = false; 3090 int sve_vector_size_in_bytes = 0; 3091 3092 #ifdef COMPILER2 3093 use_sve = Matcher::supports_scalable_vector(); 3094 sve_vector_size_in_bytes = Matcher::scalable_vector_reg_size(T_BYTE); 3095 #endif 3096 3097 // Scan bitset to accumulate register pairs 3098 unsigned char regs[32]; 3099 int count = 0; 3100 for (int reg = 0; reg <= 31; reg++) { 3101 if (1 & bitset) 3102 regs[count++] = reg; 3103 bitset >>= 1; 3104 } 3105 3106 if (count == 0) { 3107 return 0; 3108 } 3109 3110 if (mode == PushPopFull) { 3111 if (use_sve && sve_vector_size_in_bytes > 16) { 3112 mode = PushPopSVE; 3113 } else { 3114 mode = PushPopNeon; 3115 } 3116 } 3117 3118 #ifndef PRODUCT 3119 { 3120 char buffer[48]; 3121 if (mode == PushPopSVE) { 3122 os::snprintf_checked(buffer, sizeof(buffer), "push_fp: %d SVE registers", count); 3123 } else if (mode == PushPopNeon) { 3124 os::snprintf_checked(buffer, sizeof(buffer), "push_fp: %d Neon registers", count); 3125 } else { 3126 os::snprintf_checked(buffer, sizeof(buffer), "push_fp: %d fp registers", count); 3127 } 3128 block_comment(buffer); 3129 } 3130 #endif 3131 3132 if (mode == PushPopSVE) { 3133 sub(stack, stack, sve_vector_size_in_bytes * count); 3134 for (int i = 0; i < count; i++) { 3135 sve_str(as_FloatRegister(regs[i]), Address(stack, i)); 3136 } 3137 return count * sve_vector_size_in_bytes / 8; 3138 } 3139 3140 if (mode == PushPopNeon) { 3141 if (count == 1) { 3142 strq(as_FloatRegister(regs[0]), Address(pre(stack, -wordSize * 2))); 3143 return 2; 3144 } 3145 3146 bool odd = (count & 1) == 1; 3147 int push_slots = count + (odd ? 1 : 0); 3148 3149 // Always pushing full 128 bit registers. 3150 stpq(as_FloatRegister(regs[0]), as_FloatRegister(regs[1]), Address(pre(stack, -push_slots * wordSize * 2))); 3151 words_pushed += 2; 3152 3153 for (int i = 2; i + 1 < count; i += 2) { 3154 stpq(as_FloatRegister(regs[i]), as_FloatRegister(regs[i+1]), Address(stack, i * wordSize * 2)); 3155 words_pushed += 2; 3156 } 3157 3158 if (odd) { 3159 strq(as_FloatRegister(regs[count - 1]), Address(stack, (count - 1) * wordSize * 2)); 3160 words_pushed++; 3161 } 3162 3163 assert(words_pushed == count, "oops, pushed(%d) != count(%d)", words_pushed, count); 3164 return count * 2; 3165 } 3166 3167 if (mode == PushPopFp) { 3168 bool odd = (count & 1) == 1; 3169 int push_slots = count + (odd ? 1 : 0); 3170 3171 if (count == 1) { 3172 // Stack pointer must be 16 bytes aligned 3173 strd(as_FloatRegister(regs[0]), Address(pre(stack, -push_slots * wordSize))); 3174 return 1; 3175 } 3176 3177 stpd(as_FloatRegister(regs[0]), as_FloatRegister(regs[1]), Address(pre(stack, -push_slots * wordSize))); 3178 words_pushed += 2; 3179 3180 for (int i = 2; i + 1 < count; i += 2) { 3181 stpd(as_FloatRegister(regs[i]), as_FloatRegister(regs[i+1]), Address(stack, i * wordSize)); 3182 words_pushed += 2; 3183 } 3184 3185 if (odd) { 3186 // Stack pointer must be 16 bytes aligned 3187 strd(as_FloatRegister(regs[count - 1]), Address(stack, (count - 1) * wordSize)); 3188 words_pushed++; 3189 } 3190 3191 assert(words_pushed == count, "oops, pushed != count"); 3192 3193 return count; 3194 } 3195 3196 return 0; 3197 } 3198 3199 // Return the number of dwords popped 3200 int MacroAssembler::pop_fp(FloatRegSet regset, Register stack, FpPushPopMode mode) { 3201 if (regset.bits() == 0) { 3202 return 0; 3203 } 3204 auto bitset = integer_cast<unsigned int>(regset.bits()); 3205 int words_pushed = 0; 3206 bool use_sve = false; 3207 int sve_vector_size_in_bytes = 0; 3208 3209 #ifdef COMPILER2 3210 use_sve = Matcher::supports_scalable_vector(); 3211 sve_vector_size_in_bytes = Matcher::scalable_vector_reg_size(T_BYTE); 3212 #endif 3213 // Scan bitset to accumulate register pairs 3214 unsigned char regs[32]; 3215 int count = 0; 3216 for (int reg = 0; reg <= 31; reg++) { 3217 if (1 & bitset) 3218 regs[count++] = reg; 3219 bitset >>= 1; 3220 } 3221 3222 if (count == 0) { 3223 return 0; 3224 } 3225 3226 if (mode == PushPopFull) { 3227 if (use_sve && sve_vector_size_in_bytes > 16) { 3228 mode = PushPopSVE; 3229 } else { 3230 mode = PushPopNeon; 3231 } 3232 } 3233 3234 #ifndef PRODUCT 3235 { 3236 char buffer[48]; 3237 if (mode == PushPopSVE) { 3238 os::snprintf_checked(buffer, sizeof(buffer), "pop_fp: %d SVE registers", count); 3239 } else if (mode == PushPopNeon) { 3240 os::snprintf_checked(buffer, sizeof(buffer), "pop_fp: %d Neon registers", count); 3241 } else { 3242 os::snprintf_checked(buffer, sizeof(buffer), "pop_fp: %d fp registers", count); 3243 } 3244 block_comment(buffer); 3245 } 3246 #endif 3247 3248 if (mode == PushPopSVE) { 3249 for (int i = count - 1; i >= 0; i--) { 3250 sve_ldr(as_FloatRegister(regs[i]), Address(stack, i)); 3251 } 3252 add(stack, stack, sve_vector_size_in_bytes * count); 3253 return count * sve_vector_size_in_bytes / 8; 3254 } 3255 3256 if (mode == PushPopNeon) { 3257 if (count == 1) { 3258 ldrq(as_FloatRegister(regs[0]), Address(post(stack, wordSize * 2))); 3259 return 2; 3260 } 3261 3262 bool odd = (count & 1) == 1; 3263 int push_slots = count + (odd ? 1 : 0); 3264 3265 if (odd) { 3266 ldrq(as_FloatRegister(regs[count - 1]), Address(stack, (count - 1) * wordSize * 2)); 3267 words_pushed++; 3268 } 3269 3270 for (int i = 2; i + 1 < count; i += 2) { 3271 ldpq(as_FloatRegister(regs[i]), as_FloatRegister(regs[i+1]), Address(stack, i * wordSize * 2)); 3272 words_pushed += 2; 3273 } 3274 3275 ldpq(as_FloatRegister(regs[0]), as_FloatRegister(regs[1]), Address(post(stack, push_slots * wordSize * 2))); 3276 words_pushed += 2; 3277 3278 assert(words_pushed == count, "oops, pushed(%d) != count(%d)", words_pushed, count); 3279 3280 return count * 2; 3281 } 3282 3283 if (mode == PushPopFp) { 3284 bool odd = (count & 1) == 1; 3285 int push_slots = count + (odd ? 1 : 0); 3286 3287 if (count == 1) { 3288 ldrd(as_FloatRegister(regs[0]), Address(post(stack, push_slots * wordSize))); 3289 return 1; 3290 } 3291 3292 if (odd) { 3293 ldrd(as_FloatRegister(regs[count - 1]), Address(stack, (count - 1) * wordSize)); 3294 words_pushed++; 3295 } 3296 3297 for (int i = 2; i + 1 < count; i += 2) { 3298 ldpd(as_FloatRegister(regs[i]), as_FloatRegister(regs[i+1]), Address(stack, i * wordSize)); 3299 words_pushed += 2; 3300 } 3301 3302 ldpd(as_FloatRegister(regs[0]), as_FloatRegister(regs[1]), Address(post(stack, push_slots * wordSize))); 3303 words_pushed += 2; 3304 3305 assert(words_pushed == count, "oops, pushed != count"); 3306 3307 return count; 3308 } 3309 3310 return 0; 3311 } 3312 3313 // Return the number of dwords pushed 3314 int MacroAssembler::push_p(PRegSet regset, Register stack) { 3315 if (regset.bits() == 0) { 3316 return 0; 3317 } 3318 auto bitset = integer_cast<unsigned int>(regset.bits()); 3319 bool use_sve = false; 3320 int sve_predicate_size_in_slots = 0; 3321 3322 #ifdef COMPILER2 3323 use_sve = Matcher::supports_scalable_vector(); 3324 if (use_sve) { 3325 sve_predicate_size_in_slots = Matcher::scalable_predicate_reg_slots(); 3326 } 3327 #endif 3328 3329 if (!use_sve) { 3330 return 0; 3331 } 3332 3333 unsigned char regs[PRegister::number_of_registers]; 3334 int count = 0; 3335 for (int reg = 0; reg < PRegister::number_of_registers; reg++) { 3336 if (1 & bitset) 3337 regs[count++] = reg; 3338 bitset >>= 1; 3339 } 3340 3341 if (count == 0) { 3342 return 0; 3343 } 3344 3345 int total_push_bytes = align_up(sve_predicate_size_in_slots * 3346 VMRegImpl::stack_slot_size * count, 16); 3347 sub(stack, stack, total_push_bytes); 3348 for (int i = 0; i < count; i++) { 3349 sve_str(as_PRegister(regs[i]), Address(stack, i)); 3350 } 3351 return total_push_bytes / 8; 3352 } 3353 3354 // Return the number of dwords popped 3355 int MacroAssembler::pop_p(PRegSet regset, Register stack) { 3356 if (regset.bits() == 0) { 3357 return 0; 3358 } 3359 auto bitset = integer_cast<unsigned int>(regset.bits()); 3360 bool use_sve = false; 3361 int sve_predicate_size_in_slots = 0; 3362 3363 #ifdef COMPILER2 3364 use_sve = Matcher::supports_scalable_vector(); 3365 if (use_sve) { 3366 sve_predicate_size_in_slots = Matcher::scalable_predicate_reg_slots(); 3367 } 3368 #endif 3369 3370 if (!use_sve) { 3371 return 0; 3372 } 3373 3374 unsigned char regs[PRegister::number_of_registers]; 3375 int count = 0; 3376 for (int reg = 0; reg < PRegister::number_of_registers; reg++) { 3377 if (1 & bitset) 3378 regs[count++] = reg; 3379 bitset >>= 1; 3380 } 3381 3382 if (count == 0) { 3383 return 0; 3384 } 3385 3386 int total_pop_bytes = align_up(sve_predicate_size_in_slots * 3387 VMRegImpl::stack_slot_size * count, 16); 3388 for (int i = count - 1; i >= 0; i--) { 3389 sve_ldr(as_PRegister(regs[i]), Address(stack, i)); 3390 } 3391 add(stack, stack, total_pop_bytes); 3392 return total_pop_bytes / 8; 3393 } 3394 3395 #ifdef ASSERT 3396 void MacroAssembler::verify_heapbase(const char* msg) { 3397 #if 0 3398 assert (Universe::heap() != nullptr, "java heap should be initialized"); 3399 if (!UseCompressedOops || Universe::ptr_base() == nullptr) { 3400 // rheapbase is allocated as general register 3401 return; 3402 } 3403 if (CheckCompressedOops) { 3404 Label ok; 3405 push(1 << rscratch1->encoding(), sp); // cmpptr trashes rscratch1 3406 cmpptr(rheapbase, ExternalAddress(CompressedOops::base_addr())); 3407 br(Assembler::EQ, ok); 3408 stop(msg); 3409 bind(ok); 3410 pop(1 << rscratch1->encoding(), sp); 3411 } 3412 #endif 3413 } 3414 #endif 3415 3416 void MacroAssembler::resolve_jobject(Register value, Register tmp1, Register tmp2) { 3417 assert_different_registers(value, tmp1, tmp2); 3418 Label done, tagged, weak_tagged; 3419 3420 cbz(value, done); // Use null as-is. 3421 tst(value, JNIHandles::tag_mask); // Test for tag. 3422 br(Assembler::NE, tagged); 3423 3424 // Resolve local handle 3425 access_load_at(T_OBJECT, IN_NATIVE | AS_RAW, value, Address(value, 0), tmp1, tmp2); 3426 verify_oop(value); 3427 b(done); 3428 3429 bind(tagged); 3430 STATIC_ASSERT(JNIHandles::TypeTag::weak_global == 0b1); 3431 tbnz(value, 0, weak_tagged); // Test for weak tag. 3432 3433 // Resolve global handle 3434 access_load_at(T_OBJECT, IN_NATIVE, value, Address(value, -JNIHandles::TypeTag::global), tmp1, tmp2); 3435 verify_oop(value); 3436 b(done); 3437 3438 bind(weak_tagged); 3439 // Resolve jweak. 3440 access_load_at(T_OBJECT, IN_NATIVE | ON_PHANTOM_OOP_REF, 3441 value, Address(value, -JNIHandles::TypeTag::weak_global), tmp1, tmp2); 3442 verify_oop(value); 3443 3444 bind(done); 3445 } 3446 3447 void MacroAssembler::resolve_global_jobject(Register value, Register tmp1, Register tmp2) { 3448 assert_different_registers(value, tmp1, tmp2); 3449 Label done; 3450 3451 cbz(value, done); // Use null as-is. 3452 3453 #ifdef ASSERT 3454 { 3455 STATIC_ASSERT(JNIHandles::TypeTag::global == 0b10); 3456 Label valid_global_tag; 3457 tbnz(value, 1, valid_global_tag); // Test for global tag 3458 stop("non global jobject using resolve_global_jobject"); 3459 bind(valid_global_tag); 3460 } 3461 #endif 3462 3463 // Resolve global handle 3464 access_load_at(T_OBJECT, IN_NATIVE, value, Address(value, -JNIHandles::TypeTag::global), tmp1, tmp2); 3465 verify_oop(value); 3466 3467 bind(done); 3468 } 3469 3470 void MacroAssembler::stop(const char* msg) { 3471 // Skip AOT caching C strings in scratch buffer. 3472 const char* str = (code_section()->scratch_emit()) ? msg : AOTCodeCache::add_C_string(msg); 3473 BLOCK_COMMENT(str); 3474 // load msg into r0 so we can access it from the signal handler 3475 // ExternalAddress enables saving and restoring via the code cache 3476 lea(c_rarg0, ExternalAddress((address) str)); 3477 dcps1(0xdeae); 3478 } 3479 3480 void MacroAssembler::unimplemented(const char* what) { 3481 const char* buf = nullptr; 3482 { 3483 ResourceMark rm; 3484 stringStream ss; 3485 ss.print("unimplemented: %s", what); 3486 buf = code_string(ss.as_string()); 3487 } 3488 stop(buf); 3489 } 3490 3491 void MacroAssembler::_assert_asm(Assembler::Condition cc, const char* msg) { 3492 #ifdef ASSERT 3493 Label OK; 3494 br(cc, OK); 3495 stop(msg); 3496 bind(OK); 3497 #endif 3498 } 3499 3500 // If a constant does not fit in an immediate field, generate some 3501 // number of MOV instructions and then perform the operation. 3502 void MacroAssembler::wrap_add_sub_imm_insn(Register Rd, Register Rn, uint64_t imm, 3503 add_sub_imm_insn insn1, 3504 add_sub_reg_insn insn2, 3505 bool is32) { 3506 assert(Rd != zr, "Rd = zr and not setting flags?"); 3507 bool fits = operand_valid_for_add_sub_immediate(is32 ? (int32_t)imm : imm); 3508 if (fits) { 3509 (this->*insn1)(Rd, Rn, imm); 3510 } else { 3511 if (g_uabs(imm) < (1 << 24)) { 3512 (this->*insn1)(Rd, Rn, imm & -(1 << 12)); 3513 (this->*insn1)(Rd, Rd, imm & ((1 << 12)-1)); 3514 } else { 3515 assert_different_registers(Rd, Rn); 3516 mov(Rd, imm); 3517 (this->*insn2)(Rd, Rn, Rd, LSL, 0); 3518 } 3519 } 3520 } 3521 3522 // Separate vsn which sets the flags. Optimisations are more restricted 3523 // because we must set the flags correctly. 3524 void MacroAssembler::wrap_adds_subs_imm_insn(Register Rd, Register Rn, uint64_t imm, 3525 add_sub_imm_insn insn1, 3526 add_sub_reg_insn insn2, 3527 bool is32) { 3528 bool fits = operand_valid_for_add_sub_immediate(is32 ? (int32_t)imm : imm); 3529 if (fits) { 3530 (this->*insn1)(Rd, Rn, imm); 3531 } else { 3532 assert_different_registers(Rd, Rn); 3533 assert(Rd != zr, "overflow in immediate operand"); 3534 mov(Rd, imm); 3535 (this->*insn2)(Rd, Rn, Rd, LSL, 0); 3536 } 3537 } 3538 3539 3540 void MacroAssembler::add(Register Rd, Register Rn, RegisterOrConstant increment) { 3541 if (increment.is_register()) { 3542 add(Rd, Rn, increment.as_register()); 3543 } else { 3544 add(Rd, Rn, increment.as_constant()); 3545 } 3546 } 3547 3548 void MacroAssembler::addw(Register Rd, Register Rn, RegisterOrConstant increment) { 3549 if (increment.is_register()) { 3550 addw(Rd, Rn, increment.as_register()); 3551 } else { 3552 addw(Rd, Rn, increment.as_constant()); 3553 } 3554 } 3555 3556 void MacroAssembler::sub(Register Rd, Register Rn, RegisterOrConstant decrement) { 3557 if (decrement.is_register()) { 3558 sub(Rd, Rn, decrement.as_register()); 3559 } else { 3560 sub(Rd, Rn, decrement.as_constant()); 3561 } 3562 } 3563 3564 void MacroAssembler::subw(Register Rd, Register Rn, RegisterOrConstant decrement) { 3565 if (decrement.is_register()) { 3566 subw(Rd, Rn, decrement.as_register()); 3567 } else { 3568 subw(Rd, Rn, decrement.as_constant()); 3569 } 3570 } 3571 3572 void MacroAssembler::reinit_heapbase() 3573 { 3574 if (UseCompressedOops) { 3575 if (Universe::is_fully_initialized() && !AOTCodeCache::is_on_for_dump()) { 3576 mov(rheapbase, CompressedOops::base()); 3577 } else { 3578 lea(rheapbase, ExternalAddress(CompressedOops::base_addr())); 3579 ldr(rheapbase, Address(rheapbase)); 3580 } 3581 } 3582 } 3583 3584 // A generic CAS; success or failure is in the EQ flag. A weak CAS 3585 // doesn't retry and may fail spuriously. If the oldval is wanted, 3586 // Pass a register for the result, otherwise pass noreg. 3587 3588 // Clobbers rscratch1 3589 void MacroAssembler::cmpxchg(Register addr, Register expected, 3590 Register new_val, 3591 enum operand_size size, 3592 bool acquire, bool release, 3593 bool weak, 3594 Register result) { 3595 if (result == noreg) result = rscratch1; 3596 BLOCK_COMMENT("cmpxchg {"); 3597 if (UseLSE) { 3598 mov(result, expected); 3599 lse_cas(result, new_val, addr, size, acquire, release, /*not_pair*/ true); 3600 compare_eq(result, expected, size); 3601 #ifdef ASSERT 3602 // Poison rscratch1 which is written on !UseLSE branch 3603 mov(rscratch1, 0x1f1f1f1f1f1f1f1f); 3604 #endif 3605 } else { 3606 Label retry_load, done; 3607 prfm(Address(addr), PSTL1STRM); 3608 bind(retry_load); 3609 load_exclusive(result, addr, size, acquire); 3610 compare_eq(result, expected, size); 3611 br(Assembler::NE, done); 3612 store_exclusive(rscratch1, new_val, addr, size, release); 3613 if (weak) { 3614 cmpw(rscratch1, 0u); // If the store fails, return NE to our caller. 3615 } else { 3616 cbnzw(rscratch1, retry_load); 3617 } 3618 bind(done); 3619 } 3620 BLOCK_COMMENT("} cmpxchg"); 3621 } 3622 3623 // A generic comparison. Only compares for equality, clobbers rscratch1. 3624 void MacroAssembler::compare_eq(Register rm, Register rn, enum operand_size size) { 3625 if (size == xword) { 3626 cmp(rm, rn); 3627 } else if (size == word) { 3628 cmpw(rm, rn); 3629 } else if (size == halfword) { 3630 eorw(rscratch1, rm, rn); 3631 ands(zr, rscratch1, 0xffff); 3632 } else if (size == byte) { 3633 eorw(rscratch1, rm, rn); 3634 ands(zr, rscratch1, 0xff); 3635 } else { 3636 ShouldNotReachHere(); 3637 } 3638 } 3639 3640 3641 static bool different(Register a, RegisterOrConstant b, Register c) { 3642 if (b.is_constant()) 3643 return a != c; 3644 else 3645 return a != b.as_register() && a != c && b.as_register() != c; 3646 } 3647 3648 #define ATOMIC_OP(NAME, LDXR, OP, IOP, AOP, STXR, sz) \ 3649 void MacroAssembler::atomic_##NAME(Register prev, RegisterOrConstant incr, Register addr) { \ 3650 if (UseLSE) { \ 3651 prev = prev->is_valid() ? prev : zr; \ 3652 if (incr.is_register()) { \ 3653 AOP(sz, incr.as_register(), prev, addr); \ 3654 } else { \ 3655 mov(rscratch2, incr.as_constant()); \ 3656 AOP(sz, rscratch2, prev, addr); \ 3657 } \ 3658 return; \ 3659 } \ 3660 Register result = rscratch2; \ 3661 if (prev->is_valid()) \ 3662 result = different(prev, incr, addr) ? prev : rscratch2; \ 3663 \ 3664 Label retry_load; \ 3665 prfm(Address(addr), PSTL1STRM); \ 3666 bind(retry_load); \ 3667 LDXR(result, addr); \ 3668 OP(rscratch1, result, incr); \ 3669 STXR(rscratch2, rscratch1, addr); \ 3670 cbnzw(rscratch2, retry_load); \ 3671 if (prev->is_valid() && prev != result) { \ 3672 IOP(prev, rscratch1, incr); \ 3673 } \ 3674 } 3675 3676 ATOMIC_OP(add, ldxr, add, sub, ldadd, stxr, Assembler::xword) 3677 ATOMIC_OP(addw, ldxrw, addw, subw, ldadd, stxrw, Assembler::word) 3678 ATOMIC_OP(addal, ldaxr, add, sub, ldaddal, stlxr, Assembler::xword) 3679 ATOMIC_OP(addalw, ldaxrw, addw, subw, ldaddal, stlxrw, Assembler::word) 3680 3681 #undef ATOMIC_OP 3682 3683 #define ATOMIC_XCHG(OP, AOP, LDXR, STXR, sz) \ 3684 void MacroAssembler::atomic_##OP(Register prev, Register newv, Register addr) { \ 3685 if (UseLSE) { \ 3686 prev = prev->is_valid() ? prev : zr; \ 3687 AOP(sz, newv, prev, addr); \ 3688 return; \ 3689 } \ 3690 Register result = rscratch2; \ 3691 if (prev->is_valid()) \ 3692 result = different(prev, newv, addr) ? prev : rscratch2; \ 3693 \ 3694 Label retry_load; \ 3695 prfm(Address(addr), PSTL1STRM); \ 3696 bind(retry_load); \ 3697 LDXR(result, addr); \ 3698 STXR(rscratch1, newv, addr); \ 3699 cbnzw(rscratch1, retry_load); \ 3700 if (prev->is_valid() && prev != result) \ 3701 mov(prev, result); \ 3702 } 3703 3704 ATOMIC_XCHG(xchg, swp, ldxr, stxr, Assembler::xword) 3705 ATOMIC_XCHG(xchgw, swp, ldxrw, stxrw, Assembler::word) 3706 ATOMIC_XCHG(xchgl, swpl, ldxr, stlxr, Assembler::xword) 3707 ATOMIC_XCHG(xchglw, swpl, ldxrw, stlxrw, Assembler::word) 3708 ATOMIC_XCHG(xchgal, swpal, ldaxr, stlxr, Assembler::xword) 3709 ATOMIC_XCHG(xchgalw, swpal, ldaxrw, stlxrw, Assembler::word) 3710 3711 #undef ATOMIC_XCHG 3712 3713 #ifndef PRODUCT 3714 extern "C" void findpc(intptr_t x); 3715 #endif 3716 3717 void MacroAssembler::debug64(char* msg, int64_t pc, int64_t regs[]) 3718 { 3719 // In order to get locks to work, we need to fake a in_VM state 3720 if (ShowMessageBoxOnError) { 3721 JavaThread* thread = JavaThread::current(); 3722 thread->set_thread_state(_thread_in_vm); 3723 #ifndef PRODUCT 3724 if (CountBytecodes || TraceBytecodes || StopInterpreterAt) { 3725 ttyLocker ttyl; 3726 BytecodeCounter::print(); 3727 } 3728 #endif 3729 if (os::message_box(msg, "Execution stopped, print registers?")) { 3730 ttyLocker ttyl; 3731 tty->print_cr(" pc = 0x%016" PRIx64, pc); 3732 #ifndef PRODUCT 3733 tty->cr(); 3734 findpc(pc); 3735 tty->cr(); 3736 #endif 3737 tty->print_cr(" r0 = 0x%016" PRIx64, regs[0]); 3738 tty->print_cr(" r1 = 0x%016" PRIx64, regs[1]); 3739 tty->print_cr(" r2 = 0x%016" PRIx64, regs[2]); 3740 tty->print_cr(" r3 = 0x%016" PRIx64, regs[3]); 3741 tty->print_cr(" r4 = 0x%016" PRIx64, regs[4]); 3742 tty->print_cr(" r5 = 0x%016" PRIx64, regs[5]); 3743 tty->print_cr(" r6 = 0x%016" PRIx64, regs[6]); 3744 tty->print_cr(" r7 = 0x%016" PRIx64, regs[7]); 3745 tty->print_cr(" r8 = 0x%016" PRIx64, regs[8]); 3746 tty->print_cr(" r9 = 0x%016" PRIx64, regs[9]); 3747 tty->print_cr("r10 = 0x%016" PRIx64, regs[10]); 3748 tty->print_cr("r11 = 0x%016" PRIx64, regs[11]); 3749 tty->print_cr("r12 = 0x%016" PRIx64, regs[12]); 3750 tty->print_cr("r13 = 0x%016" PRIx64, regs[13]); 3751 tty->print_cr("r14 = 0x%016" PRIx64, regs[14]); 3752 tty->print_cr("r15 = 0x%016" PRIx64, regs[15]); 3753 tty->print_cr("r16 = 0x%016" PRIx64, regs[16]); 3754 tty->print_cr("r17 = 0x%016" PRIx64, regs[17]); 3755 tty->print_cr("r18 = 0x%016" PRIx64, regs[18]); 3756 tty->print_cr("r19 = 0x%016" PRIx64, regs[19]); 3757 tty->print_cr("r20 = 0x%016" PRIx64, regs[20]); 3758 tty->print_cr("r21 = 0x%016" PRIx64, regs[21]); 3759 tty->print_cr("r22 = 0x%016" PRIx64, regs[22]); 3760 tty->print_cr("r23 = 0x%016" PRIx64, regs[23]); 3761 tty->print_cr("r24 = 0x%016" PRIx64, regs[24]); 3762 tty->print_cr("r25 = 0x%016" PRIx64, regs[25]); 3763 tty->print_cr("r26 = 0x%016" PRIx64, regs[26]); 3764 tty->print_cr("r27 = 0x%016" PRIx64, regs[27]); 3765 tty->print_cr("r28 = 0x%016" PRIx64, regs[28]); 3766 tty->print_cr("r30 = 0x%016" PRIx64, regs[30]); 3767 tty->print_cr("r31 = 0x%016" PRIx64, regs[31]); 3768 BREAKPOINT; 3769 } 3770 } 3771 fatal("DEBUG MESSAGE: %s", msg); 3772 } 3773 3774 RegSet MacroAssembler::call_clobbered_gp_registers() { 3775 RegSet regs = RegSet::range(r0, r17) - RegSet::of(rscratch1, rscratch2); 3776 #ifndef R18_RESERVED 3777 regs += r18_tls; 3778 #endif 3779 return regs; 3780 } 3781 3782 void MacroAssembler::push_call_clobbered_registers_except(RegSet exclude) { 3783 int step = 4 * wordSize; 3784 push(call_clobbered_gp_registers() - exclude, sp); 3785 sub(sp, sp, step); 3786 mov(rscratch1, -step); 3787 // Push v0-v7, v16-v31. 3788 for (int i = 31; i>= 4; i -= 4) { 3789 if (i <= v7->encoding() || i >= v16->encoding()) 3790 st1(as_FloatRegister(i-3), as_FloatRegister(i-2), as_FloatRegister(i-1), 3791 as_FloatRegister(i), T1D, Address(post(sp, rscratch1))); 3792 } 3793 st1(as_FloatRegister(0), as_FloatRegister(1), as_FloatRegister(2), 3794 as_FloatRegister(3), T1D, Address(sp)); 3795 } 3796 3797 void MacroAssembler::pop_call_clobbered_registers_except(RegSet exclude) { 3798 for (int i = 0; i < 32; i += 4) { 3799 if (i <= v7->encoding() || i >= v16->encoding()) 3800 ld1(as_FloatRegister(i), as_FloatRegister(i+1), as_FloatRegister(i+2), 3801 as_FloatRegister(i+3), T1D, Address(post(sp, 4 * wordSize))); 3802 } 3803 3804 reinitialize_ptrue(); 3805 3806 pop(call_clobbered_gp_registers() - exclude, sp); 3807 } 3808 3809 void MacroAssembler::push_CPU_state(bool save_vectors, bool use_sve, 3810 int sve_vector_size_in_bytes, int total_predicate_in_bytes) { 3811 push(RegSet::range(r0, r29), sp); // integer registers except lr & sp 3812 if (save_vectors && use_sve && sve_vector_size_in_bytes > 16) { 3813 sub(sp, sp, sve_vector_size_in_bytes * FloatRegister::number_of_registers); 3814 for (int i = 0; i < FloatRegister::number_of_registers; i++) { 3815 sve_str(as_FloatRegister(i), Address(sp, i)); 3816 } 3817 } else { 3818 int step = (save_vectors ? 8 : 4) * wordSize; 3819 mov(rscratch1, -step); 3820 sub(sp, sp, step); 3821 for (int i = 28; i >= 4; i -= 4) { 3822 st1(as_FloatRegister(i), as_FloatRegister(i+1), as_FloatRegister(i+2), 3823 as_FloatRegister(i+3), save_vectors ? T2D : T1D, Address(post(sp, rscratch1))); 3824 } 3825 st1(v0, v1, v2, v3, save_vectors ? T2D : T1D, sp); 3826 } 3827 if (save_vectors && use_sve && total_predicate_in_bytes > 0) { 3828 sub(sp, sp, total_predicate_in_bytes); 3829 for (int i = 0; i < PRegister::number_of_registers; i++) { 3830 sve_str(as_PRegister(i), Address(sp, i)); 3831 } 3832 } 3833 } 3834 3835 void MacroAssembler::pop_CPU_state(bool restore_vectors, bool use_sve, 3836 int sve_vector_size_in_bytes, int total_predicate_in_bytes) { 3837 if (restore_vectors && use_sve && total_predicate_in_bytes > 0) { 3838 for (int i = PRegister::number_of_registers - 1; i >= 0; i--) { 3839 sve_ldr(as_PRegister(i), Address(sp, i)); 3840 } 3841 add(sp, sp, total_predicate_in_bytes); 3842 } 3843 if (restore_vectors && use_sve && sve_vector_size_in_bytes > 16) { 3844 for (int i = FloatRegister::number_of_registers - 1; i >= 0; i--) { 3845 sve_ldr(as_FloatRegister(i), Address(sp, i)); 3846 } 3847 add(sp, sp, sve_vector_size_in_bytes * FloatRegister::number_of_registers); 3848 } else { 3849 int step = (restore_vectors ? 8 : 4) * wordSize; 3850 for (int i = 0; i <= 28; i += 4) 3851 ld1(as_FloatRegister(i), as_FloatRegister(i+1), as_FloatRegister(i+2), 3852 as_FloatRegister(i+3), restore_vectors ? T2D : T1D, Address(post(sp, step))); 3853 } 3854 3855 // We may use predicate registers and rely on ptrue with SVE, 3856 // regardless of wide vector (> 8 bytes) used or not. 3857 if (use_sve) { 3858 reinitialize_ptrue(); 3859 } 3860 3861 // integer registers except lr & sp 3862 pop(RegSet::range(r0, r17), sp); 3863 #ifdef R18_RESERVED 3864 ldp(zr, r19, Address(post(sp, 2 * wordSize))); 3865 pop(RegSet::range(r20, r29), sp); 3866 #else 3867 pop(RegSet::range(r18_tls, r29), sp); 3868 #endif 3869 } 3870 3871 /** 3872 * Helpers for multiply_to_len(). 3873 */ 3874 void MacroAssembler::add2_with_carry(Register final_dest_hi, Register dest_hi, Register dest_lo, 3875 Register src1, Register src2) { 3876 adds(dest_lo, dest_lo, src1); 3877 adc(dest_hi, dest_hi, zr); 3878 adds(dest_lo, dest_lo, src2); 3879 adc(final_dest_hi, dest_hi, zr); 3880 } 3881 3882 // Generate an address from (r + r1 extend offset). "size" is the 3883 // size of the operand. The result may be in rscratch2. 3884 Address MacroAssembler::offsetted_address(Register r, Register r1, 3885 Address::extend ext, int offset, int size) { 3886 if (offset || (ext.shift() % size != 0)) { 3887 lea(rscratch2, Address(r, r1, ext)); 3888 return Address(rscratch2, offset); 3889 } else { 3890 return Address(r, r1, ext); 3891 } 3892 } 3893 3894 Address MacroAssembler::spill_address(int size, int offset, Register tmp) 3895 { 3896 assert(offset >= 0, "spill to negative address?"); 3897 // Offset reachable ? 3898 // Not aligned - 9 bits signed offset 3899 // Aligned - 12 bits unsigned offset shifted 3900 Register base = sp; 3901 if ((offset & (size-1)) && offset >= (1<<8)) { 3902 add(tmp, base, offset & ((1<<12)-1)); 3903 base = tmp; 3904 offset &= -1u<<12; 3905 } 3906 3907 if (offset >= (1<<12) * size) { 3908 add(tmp, base, offset & (((1<<12)-1)<<12)); 3909 base = tmp; 3910 offset &= ~(((1<<12)-1)<<12); 3911 } 3912 3913 return Address(base, offset); 3914 } 3915 3916 Address MacroAssembler::sve_spill_address(int sve_reg_size_in_bytes, int offset, Register tmp) { 3917 assert(offset >= 0, "spill to negative address?"); 3918 3919 Register base = sp; 3920 3921 // An immediate offset in the range 0 to 255 which is multiplied 3922 // by the current vector or predicate register size in bytes. 3923 if (offset % sve_reg_size_in_bytes == 0 && offset < ((1<<8)*sve_reg_size_in_bytes)) { 3924 return Address(base, offset / sve_reg_size_in_bytes); 3925 } 3926 3927 add(tmp, base, offset); 3928 return Address(tmp); 3929 } 3930 3931 // Checks whether offset is aligned. 3932 // Returns true if it is, else false. 3933 bool MacroAssembler::merge_alignment_check(Register base, 3934 size_t size, 3935 int64_t cur_offset, 3936 int64_t prev_offset) const { 3937 if (AvoidUnalignedAccesses) { 3938 if (base == sp) { 3939 // Checks whether low offset if aligned to pair of registers. 3940 int64_t pair_mask = size * 2 - 1; 3941 int64_t offset = prev_offset > cur_offset ? cur_offset : prev_offset; 3942 return (offset & pair_mask) == 0; 3943 } else { // If base is not sp, we can't guarantee the access is aligned. 3944 return false; 3945 } 3946 } else { 3947 int64_t mask = size - 1; 3948 // Load/store pair instruction only supports element size aligned offset. 3949 return (cur_offset & mask) == 0 && (prev_offset & mask) == 0; 3950 } 3951 } 3952 3953 // Checks whether current and previous loads/stores can be merged. 3954 // Returns true if it can be merged, else false. 3955 bool MacroAssembler::ldst_can_merge(Register rt, 3956 const Address &adr, 3957 size_t cur_size_in_bytes, 3958 bool is_store) const { 3959 address prev = pc() - NativeInstruction::instruction_size; 3960 address last = code()->last_merge_candidate(); 3961 3962 if (last == nullptr || !nativeInstruction_at(last)->is_Imm_LdSt()) { 3963 return false; 3964 } 3965 3966 if (adr.getMode() != Address::base_plus_offset || prev != last) { 3967 return false; 3968 } 3969 3970 NativeLdSt* prev_ldst = NativeLdSt_at(prev); 3971 size_t prev_size_in_bytes = prev_ldst->size_in_bytes(); 3972 3973 assert(prev_size_in_bytes == 4 || prev_size_in_bytes == 8, "only supports 64/32bit merging."); 3974 assert(cur_size_in_bytes == 4 || cur_size_in_bytes == 8, "only supports 64/32bit merging."); 3975 3976 if (cur_size_in_bytes != prev_size_in_bytes || is_store != prev_ldst->is_store()) { 3977 return false; 3978 } 3979 3980 int64_t max_offset = 63 * prev_size_in_bytes; 3981 int64_t min_offset = -64 * prev_size_in_bytes; 3982 3983 assert(prev_ldst->is_not_pre_post_index(), "pre-index or post-index is not supported to be merged."); 3984 3985 // Only same base can be merged. 3986 if (adr.base() != prev_ldst->base()) { 3987 return false; 3988 } 3989 3990 int64_t cur_offset = adr.offset(); 3991 int64_t prev_offset = prev_ldst->offset(); 3992 size_t diff = abs(cur_offset - prev_offset); 3993 if (diff != prev_size_in_bytes) { 3994 return false; 3995 } 3996 3997 // Following cases can not be merged: 3998 // ldr x2, [x2, #8] 3999 // ldr x3, [x2, #16] 4000 // or: 4001 // ldr x2, [x3, #8] 4002 // ldr x2, [x3, #16] 4003 // If t1 and t2 is the same in "ldp t1, t2, [xn, #imm]", we'll get SIGILL. 4004 if (!is_store && (adr.base() == prev_ldst->target() || rt == prev_ldst->target())) { 4005 return false; 4006 } 4007 4008 int64_t low_offset = prev_offset > cur_offset ? cur_offset : prev_offset; 4009 // Offset range must be in ldp/stp instruction's range. 4010 if (low_offset > max_offset || low_offset < min_offset) { 4011 return false; 4012 } 4013 4014 if (merge_alignment_check(adr.base(), prev_size_in_bytes, cur_offset, prev_offset)) { 4015 return true; 4016 } 4017 4018 return false; 4019 } 4020 4021 // Merge current load/store with previous load/store into ldp/stp. 4022 void MacroAssembler::merge_ldst(Register rt, 4023 const Address &adr, 4024 size_t cur_size_in_bytes, 4025 bool is_store) { 4026 4027 assert(ldst_can_merge(rt, adr, cur_size_in_bytes, is_store) == true, "cur and prev must be able to be merged."); 4028 4029 Register rt_low, rt_high; 4030 address prev = pc() - NativeInstruction::instruction_size; 4031 NativeLdSt* prev_ldst = NativeLdSt_at(prev); 4032 4033 int64_t offset; 4034 4035 if (adr.offset() < prev_ldst->offset()) { 4036 offset = adr.offset(); 4037 rt_low = rt; 4038 rt_high = prev_ldst->target(); 4039 } else { 4040 offset = prev_ldst->offset(); 4041 rt_low = prev_ldst->target(); 4042 rt_high = rt; 4043 } 4044 4045 Address adr_p = Address(prev_ldst->base(), offset); 4046 // Overwrite previous generated binary. 4047 code_section()->set_end(prev); 4048 4049 const size_t sz = prev_ldst->size_in_bytes(); 4050 assert(sz == 8 || sz == 4, "only supports 64/32bit merging."); 4051 if (!is_store) { 4052 BLOCK_COMMENT("merged ldr pair"); 4053 if (sz == 8) { 4054 ldp(rt_low, rt_high, adr_p); 4055 } else { 4056 ldpw(rt_low, rt_high, adr_p); 4057 } 4058 } else { 4059 BLOCK_COMMENT("merged str pair"); 4060 if (sz == 8) { 4061 stp(rt_low, rt_high, adr_p); 4062 } else { 4063 stpw(rt_low, rt_high, adr_p); 4064 } 4065 } 4066 } 4067 4068 /** 4069 * Multiply 64 bit by 64 bit first loop. 4070 */ 4071 void MacroAssembler::multiply_64_x_64_loop(Register x, Register xstart, Register x_xstart, 4072 Register y, Register y_idx, Register z, 4073 Register carry, Register product, 4074 Register idx, Register kdx) { 4075 // 4076 // jlong carry, x[], y[], z[]; 4077 // for (int idx=ystart, kdx=ystart+1+xstart; idx >= 0; idx-, kdx--) { 4078 // huge_128 product = y[idx] * x[xstart] + carry; 4079 // z[kdx] = (jlong)product; 4080 // carry = (jlong)(product >>> 64); 4081 // } 4082 // z[xstart] = carry; 4083 // 4084 4085 Label L_first_loop, L_first_loop_exit; 4086 Label L_one_x, L_one_y, L_multiply; 4087 4088 subsw(xstart, xstart, 1); 4089 br(Assembler::MI, L_one_x); 4090 4091 lea(rscratch1, Address(x, xstart, Address::lsl(LogBytesPerInt))); 4092 ldr(x_xstart, Address(rscratch1)); 4093 ror(x_xstart, x_xstart, 32); // convert big-endian to little-endian 4094 4095 bind(L_first_loop); 4096 subsw(idx, idx, 1); 4097 br(Assembler::MI, L_first_loop_exit); 4098 subsw(idx, idx, 1); 4099 br(Assembler::MI, L_one_y); 4100 lea(rscratch1, Address(y, idx, Address::uxtw(LogBytesPerInt))); 4101 ldr(y_idx, Address(rscratch1)); 4102 ror(y_idx, y_idx, 32); // convert big-endian to little-endian 4103 bind(L_multiply); 4104 4105 // AArch64 has a multiply-accumulate instruction that we can't use 4106 // here because it has no way to process carries, so we have to use 4107 // separate add and adc instructions. Bah. 4108 umulh(rscratch1, x_xstart, y_idx); // x_xstart * y_idx -> rscratch1:product 4109 mul(product, x_xstart, y_idx); 4110 adds(product, product, carry); 4111 adc(carry, rscratch1, zr); // x_xstart * y_idx + carry -> carry:product 4112 4113 subw(kdx, kdx, 2); 4114 ror(product, product, 32); // back to big-endian 4115 str(product, offsetted_address(z, kdx, Address::uxtw(LogBytesPerInt), 0, BytesPerLong)); 4116 4117 b(L_first_loop); 4118 4119 bind(L_one_y); 4120 ldrw(y_idx, Address(y, 0)); 4121 b(L_multiply); 4122 4123 bind(L_one_x); 4124 ldrw(x_xstart, Address(x, 0)); 4125 b(L_first_loop); 4126 4127 bind(L_first_loop_exit); 4128 } 4129 4130 /** 4131 * Multiply 128 bit by 128. Unrolled inner loop. 4132 * 4133 */ 4134 void MacroAssembler::multiply_128_x_128_loop(Register y, Register z, 4135 Register carry, Register carry2, 4136 Register idx, Register jdx, 4137 Register yz_idx1, Register yz_idx2, 4138 Register tmp, Register tmp3, Register tmp4, 4139 Register tmp6, Register product_hi) { 4140 4141 // jlong carry, x[], y[], z[]; 4142 // int kdx = ystart+1; 4143 // for (int idx=ystart-2; idx >= 0; idx -= 2) { // Third loop 4144 // huge_128 tmp3 = (y[idx+1] * product_hi) + z[kdx+idx+1] + carry; 4145 // jlong carry2 = (jlong)(tmp3 >>> 64); 4146 // huge_128 tmp4 = (y[idx] * product_hi) + z[kdx+idx] + carry2; 4147 // carry = (jlong)(tmp4 >>> 64); 4148 // z[kdx+idx+1] = (jlong)tmp3; 4149 // z[kdx+idx] = (jlong)tmp4; 4150 // } 4151 // idx += 2; 4152 // if (idx > 0) { 4153 // yz_idx1 = (y[idx] * product_hi) + z[kdx+idx] + carry; 4154 // z[kdx+idx] = (jlong)yz_idx1; 4155 // carry = (jlong)(yz_idx1 >>> 64); 4156 // } 4157 // 4158 4159 Label L_third_loop, L_third_loop_exit, L_post_third_loop_done; 4160 4161 lsrw(jdx, idx, 2); 4162 4163 bind(L_third_loop); 4164 4165 subsw(jdx, jdx, 1); 4166 br(Assembler::MI, L_third_loop_exit); 4167 subw(idx, idx, 4); 4168 4169 lea(rscratch1, Address(y, idx, Address::uxtw(LogBytesPerInt))); 4170 4171 ldp(yz_idx2, yz_idx1, Address(rscratch1, 0)); 4172 4173 lea(tmp6, Address(z, idx, Address::uxtw(LogBytesPerInt))); 4174 4175 ror(yz_idx1, yz_idx1, 32); // convert big-endian to little-endian 4176 ror(yz_idx2, yz_idx2, 32); 4177 4178 ldp(rscratch2, rscratch1, Address(tmp6, 0)); 4179 4180 mul(tmp3, product_hi, yz_idx1); // yz_idx1 * product_hi -> tmp4:tmp3 4181 umulh(tmp4, product_hi, yz_idx1); 4182 4183 ror(rscratch1, rscratch1, 32); // convert big-endian to little-endian 4184 ror(rscratch2, rscratch2, 32); 4185 4186 mul(tmp, product_hi, yz_idx2); // yz_idx2 * product_hi -> carry2:tmp 4187 umulh(carry2, product_hi, yz_idx2); 4188 4189 // propagate sum of both multiplications into carry:tmp4:tmp3 4190 adds(tmp3, tmp3, carry); 4191 adc(tmp4, tmp4, zr); 4192 adds(tmp3, tmp3, rscratch1); 4193 adcs(tmp4, tmp4, tmp); 4194 adc(carry, carry2, zr); 4195 adds(tmp4, tmp4, rscratch2); 4196 adc(carry, carry, zr); 4197 4198 ror(tmp3, tmp3, 32); // convert little-endian to big-endian 4199 ror(tmp4, tmp4, 32); 4200 stp(tmp4, tmp3, Address(tmp6, 0)); 4201 4202 b(L_third_loop); 4203 bind (L_third_loop_exit); 4204 4205 andw (idx, idx, 0x3); 4206 cbz(idx, L_post_third_loop_done); 4207 4208 Label L_check_1; 4209 subsw(idx, idx, 2); 4210 br(Assembler::MI, L_check_1); 4211 4212 lea(rscratch1, Address(y, idx, Address::uxtw(LogBytesPerInt))); 4213 ldr(yz_idx1, Address(rscratch1, 0)); 4214 ror(yz_idx1, yz_idx1, 32); 4215 mul(tmp3, product_hi, yz_idx1); // yz_idx1 * product_hi -> tmp4:tmp3 4216 umulh(tmp4, product_hi, yz_idx1); 4217 lea(rscratch1, Address(z, idx, Address::uxtw(LogBytesPerInt))); 4218 ldr(yz_idx2, Address(rscratch1, 0)); 4219 ror(yz_idx2, yz_idx2, 32); 4220 4221 add2_with_carry(carry, tmp4, tmp3, carry, yz_idx2); 4222 4223 ror(tmp3, tmp3, 32); 4224 str(tmp3, Address(rscratch1, 0)); 4225 4226 bind (L_check_1); 4227 4228 andw (idx, idx, 0x1); 4229 subsw(idx, idx, 1); 4230 br(Assembler::MI, L_post_third_loop_done); 4231 ldrw(tmp4, Address(y, idx, Address::uxtw(LogBytesPerInt))); 4232 mul(tmp3, tmp4, product_hi); // tmp4 * product_hi -> carry2:tmp3 4233 umulh(carry2, tmp4, product_hi); 4234 ldrw(tmp4, Address(z, idx, Address::uxtw(LogBytesPerInt))); 4235 4236 add2_with_carry(carry2, tmp3, tmp4, carry); 4237 4238 strw(tmp3, Address(z, idx, Address::uxtw(LogBytesPerInt))); 4239 extr(carry, carry2, tmp3, 32); 4240 4241 bind(L_post_third_loop_done); 4242 } 4243 4244 /** 4245 * Code for BigInteger::multiplyToLen() intrinsic. 4246 * 4247 * r0: x 4248 * r1: xlen 4249 * r2: y 4250 * r3: ylen 4251 * r4: z 4252 * r5: tmp0 4253 * r10: tmp1 4254 * r11: tmp2 4255 * r12: tmp3 4256 * r13: tmp4 4257 * r14: tmp5 4258 * r15: tmp6 4259 * r16: tmp7 4260 * 4261 */ 4262 void MacroAssembler::multiply_to_len(Register x, Register xlen, Register y, Register ylen, 4263 Register z, Register tmp0, 4264 Register tmp1, Register tmp2, Register tmp3, Register tmp4, 4265 Register tmp5, Register tmp6, Register product_hi) { 4266 4267 assert_different_registers(x, xlen, y, ylen, z, tmp0, tmp1, tmp2, tmp3, tmp4, tmp5, tmp6, product_hi); 4268 4269 const Register idx = tmp1; 4270 const Register kdx = tmp2; 4271 const Register xstart = tmp3; 4272 4273 const Register y_idx = tmp4; 4274 const Register carry = tmp5; 4275 const Register product = xlen; 4276 const Register x_xstart = tmp0; 4277 4278 // First Loop. 4279 // 4280 // final static long LONG_MASK = 0xffffffffL; 4281 // int xstart = xlen - 1; 4282 // int ystart = ylen - 1; 4283 // long carry = 0; 4284 // for (int idx=ystart, kdx=ystart+1+xstart; idx >= 0; idx-, kdx--) { 4285 // long product = (y[idx] & LONG_MASK) * (x[xstart] & LONG_MASK) + carry; 4286 // z[kdx] = (int)product; 4287 // carry = product >>> 32; 4288 // } 4289 // z[xstart] = (int)carry; 4290 // 4291 4292 movw(idx, ylen); // idx = ylen; 4293 addw(kdx, xlen, ylen); // kdx = xlen+ylen; 4294 mov(carry, zr); // carry = 0; 4295 4296 Label L_done; 4297 4298 movw(xstart, xlen); 4299 subsw(xstart, xstart, 1); 4300 br(Assembler::MI, L_done); 4301 4302 multiply_64_x_64_loop(x, xstart, x_xstart, y, y_idx, z, carry, product, idx, kdx); 4303 4304 Label L_second_loop; 4305 cbzw(kdx, L_second_loop); 4306 4307 Label L_carry; 4308 subw(kdx, kdx, 1); 4309 cbzw(kdx, L_carry); 4310 4311 strw(carry, Address(z, kdx, Address::uxtw(LogBytesPerInt))); 4312 lsr(carry, carry, 32); 4313 subw(kdx, kdx, 1); 4314 4315 bind(L_carry); 4316 strw(carry, Address(z, kdx, Address::uxtw(LogBytesPerInt))); 4317 4318 // Second and third (nested) loops. 4319 // 4320 // for (int i = xstart-1; i >= 0; i--) { // Second loop 4321 // carry = 0; 4322 // for (int jdx=ystart, k=ystart+1+i; jdx >= 0; jdx--, k--) { // Third loop 4323 // long product = (y[jdx] & LONG_MASK) * (x[i] & LONG_MASK) + 4324 // (z[k] & LONG_MASK) + carry; 4325 // z[k] = (int)product; 4326 // carry = product >>> 32; 4327 // } 4328 // z[i] = (int)carry; 4329 // } 4330 // 4331 // i = xlen, j = tmp1, k = tmp2, carry = tmp5, x[i] = product_hi 4332 4333 const Register jdx = tmp1; 4334 4335 bind(L_second_loop); 4336 mov(carry, zr); // carry = 0; 4337 movw(jdx, ylen); // j = ystart+1 4338 4339 subsw(xstart, xstart, 1); // i = xstart-1; 4340 br(Assembler::MI, L_done); 4341 4342 str(z, Address(pre(sp, -4 * wordSize))); 4343 4344 Label L_last_x; 4345 lea(z, offsetted_address(z, xstart, Address::uxtw(LogBytesPerInt), 4, BytesPerInt)); // z = z + k - j 4346 subsw(xstart, xstart, 1); // i = xstart-1; 4347 br(Assembler::MI, L_last_x); 4348 4349 lea(rscratch1, Address(x, xstart, Address::uxtw(LogBytesPerInt))); 4350 ldr(product_hi, Address(rscratch1)); 4351 ror(product_hi, product_hi, 32); // convert big-endian to little-endian 4352 4353 Label L_third_loop_prologue; 4354 bind(L_third_loop_prologue); 4355 4356 str(ylen, Address(sp, wordSize)); 4357 stp(x, xstart, Address(sp, 2 * wordSize)); 4358 multiply_128_x_128_loop(y, z, carry, x, jdx, ylen, product, 4359 tmp2, x_xstart, tmp3, tmp4, tmp6, product_hi); 4360 ldp(z, ylen, Address(post(sp, 2 * wordSize))); 4361 ldp(x, xlen, Address(post(sp, 2 * wordSize))); // copy old xstart -> xlen 4362 4363 addw(tmp3, xlen, 1); 4364 strw(carry, Address(z, tmp3, Address::uxtw(LogBytesPerInt))); 4365 subsw(tmp3, tmp3, 1); 4366 br(Assembler::MI, L_done); 4367 4368 lsr(carry, carry, 32); 4369 strw(carry, Address(z, tmp3, Address::uxtw(LogBytesPerInt))); 4370 b(L_second_loop); 4371 4372 // Next infrequent code is moved outside loops. 4373 bind(L_last_x); 4374 ldrw(product_hi, Address(x, 0)); 4375 b(L_third_loop_prologue); 4376 4377 bind(L_done); 4378 } 4379 4380 // Code for BigInteger::mulAdd intrinsic 4381 // out = r0 4382 // in = r1 4383 // offset = r2 (already out.length-offset) 4384 // len = r3 4385 // k = r4 4386 // 4387 // pseudo code from java implementation: 4388 // carry = 0; 4389 // offset = out.length-offset - 1; 4390 // for (int j=len-1; j >= 0; j--) { 4391 // product = (in[j] & LONG_MASK) * kLong + (out[offset] & LONG_MASK) + carry; 4392 // out[offset--] = (int)product; 4393 // carry = product >>> 32; 4394 // } 4395 // return (int)carry; 4396 void MacroAssembler::mul_add(Register out, Register in, Register offset, 4397 Register len, Register k) { 4398 Label LOOP, END; 4399 // pre-loop 4400 cmp(len, zr); // cmp, not cbz/cbnz: to use condition twice => less branches 4401 csel(out, zr, out, Assembler::EQ); 4402 br(Assembler::EQ, END); 4403 add(in, in, len, LSL, 2); // in[j+1] address 4404 add(offset, out, offset, LSL, 2); // out[offset + 1] address 4405 mov(out, zr); // used to keep carry now 4406 BIND(LOOP); 4407 ldrw(rscratch1, Address(pre(in, -4))); 4408 madd(rscratch1, rscratch1, k, out); 4409 ldrw(rscratch2, Address(pre(offset, -4))); 4410 add(rscratch1, rscratch1, rscratch2); 4411 strw(rscratch1, Address(offset)); 4412 lsr(out, rscratch1, 32); 4413 subs(len, len, 1); 4414 br(Assembler::NE, LOOP); 4415 BIND(END); 4416 } 4417 4418 /** 4419 * Emits code to update CRC-32 with a byte value according to constants in table 4420 * 4421 * @param [in,out]crc Register containing the crc. 4422 * @param [in]val Register containing the byte to fold into the CRC. 4423 * @param [in]table Register containing the table of crc constants. 4424 * 4425 * uint32_t crc; 4426 * val = crc_table[(val ^ crc) & 0xFF]; 4427 * crc = val ^ (crc >> 8); 4428 * 4429 */ 4430 void MacroAssembler::update_byte_crc32(Register crc, Register val, Register table) { 4431 eor(val, val, crc); 4432 andr(val, val, 0xff); 4433 ldrw(val, Address(table, val, Address::lsl(2))); 4434 eor(crc, val, crc, Assembler::LSR, 8); 4435 } 4436 4437 /** 4438 * Emits code to update CRC-32 with a 32-bit value according to tables 0 to 3 4439 * 4440 * @param [in,out]crc Register containing the crc. 4441 * @param [in]v Register containing the 32-bit to fold into the CRC. 4442 * @param [in]table0 Register containing table 0 of crc constants. 4443 * @param [in]table1 Register containing table 1 of crc constants. 4444 * @param [in]table2 Register containing table 2 of crc constants. 4445 * @param [in]table3 Register containing table 3 of crc constants. 4446 * 4447 * uint32_t crc; 4448 * v = crc ^ v 4449 * crc = table3[v&0xff]^table2[(v>>8)&0xff]^table1[(v>>16)&0xff]^table0[v>>24] 4450 * 4451 */ 4452 void MacroAssembler::update_word_crc32(Register crc, Register v, Register tmp, 4453 Register table0, Register table1, Register table2, Register table3, 4454 bool upper) { 4455 eor(v, crc, v, upper ? LSR:LSL, upper ? 32:0); 4456 uxtb(tmp, v); 4457 ldrw(crc, Address(table3, tmp, Address::lsl(2))); 4458 ubfx(tmp, v, 8, 8); 4459 ldrw(tmp, Address(table2, tmp, Address::lsl(2))); 4460 eor(crc, crc, tmp); 4461 ubfx(tmp, v, 16, 8); 4462 ldrw(tmp, Address(table1, tmp, Address::lsl(2))); 4463 eor(crc, crc, tmp); 4464 ubfx(tmp, v, 24, 8); 4465 ldrw(tmp, Address(table0, tmp, Address::lsl(2))); 4466 eor(crc, crc, tmp); 4467 } 4468 4469 void MacroAssembler::kernel_crc32_using_crypto_pmull(Register crc, Register buf, 4470 Register len, Register tmp0, Register tmp1, Register tmp2, Register tmp3) { 4471 Label CRC_by4_loop, CRC_by1_loop, CRC_less128, CRC_by128_pre, CRC_by32_loop, CRC_less32, L_exit; 4472 assert_different_registers(crc, buf, len, tmp0, tmp1, tmp2); 4473 4474 subs(tmp0, len, 384); 4475 mvnw(crc, crc); 4476 br(Assembler::GE, CRC_by128_pre); 4477 BIND(CRC_less128); 4478 subs(len, len, 32); 4479 br(Assembler::GE, CRC_by32_loop); 4480 BIND(CRC_less32); 4481 adds(len, len, 32 - 4); 4482 br(Assembler::GE, CRC_by4_loop); 4483 adds(len, len, 4); 4484 br(Assembler::GT, CRC_by1_loop); 4485 b(L_exit); 4486 4487 BIND(CRC_by32_loop); 4488 ldp(tmp0, tmp1, Address(buf)); 4489 crc32x(crc, crc, tmp0); 4490 ldp(tmp2, tmp3, Address(buf, 16)); 4491 crc32x(crc, crc, tmp1); 4492 add(buf, buf, 32); 4493 crc32x(crc, crc, tmp2); 4494 subs(len, len, 32); 4495 crc32x(crc, crc, tmp3); 4496 br(Assembler::GE, CRC_by32_loop); 4497 cmn(len, (u1)32); 4498 br(Assembler::NE, CRC_less32); 4499 b(L_exit); 4500 4501 BIND(CRC_by4_loop); 4502 ldrw(tmp0, Address(post(buf, 4))); 4503 subs(len, len, 4); 4504 crc32w(crc, crc, tmp0); 4505 br(Assembler::GE, CRC_by4_loop); 4506 adds(len, len, 4); 4507 br(Assembler::LE, L_exit); 4508 BIND(CRC_by1_loop); 4509 ldrb(tmp0, Address(post(buf, 1))); 4510 subs(len, len, 1); 4511 crc32b(crc, crc, tmp0); 4512 br(Assembler::GT, CRC_by1_loop); 4513 b(L_exit); 4514 4515 BIND(CRC_by128_pre); 4516 kernel_crc32_common_fold_using_crypto_pmull(crc, buf, len, tmp0, tmp1, tmp2, 4517 4*256*sizeof(juint) + 8*sizeof(juint)); 4518 mov(crc, 0); 4519 crc32x(crc, crc, tmp0); 4520 crc32x(crc, crc, tmp1); 4521 4522 cbnz(len, CRC_less128); 4523 4524 BIND(L_exit); 4525 mvnw(crc, crc); 4526 } 4527 4528 void MacroAssembler::kernel_crc32_using_crc32(Register crc, Register buf, 4529 Register len, Register tmp0, Register tmp1, Register tmp2, 4530 Register tmp3) { 4531 Label CRC_by64_loop, CRC_by4_loop, CRC_by1_loop, CRC_less64, CRC_by64_pre, CRC_by32_loop, CRC_less32, L_exit; 4532 assert_different_registers(crc, buf, len, tmp0, tmp1, tmp2, tmp3); 4533 4534 mvnw(crc, crc); 4535 4536 subs(len, len, 128); 4537 br(Assembler::GE, CRC_by64_pre); 4538 BIND(CRC_less64); 4539 adds(len, len, 128-32); 4540 br(Assembler::GE, CRC_by32_loop); 4541 BIND(CRC_less32); 4542 adds(len, len, 32-4); 4543 br(Assembler::GE, CRC_by4_loop); 4544 adds(len, len, 4); 4545 br(Assembler::GT, CRC_by1_loop); 4546 b(L_exit); 4547 4548 BIND(CRC_by32_loop); 4549 ldp(tmp0, tmp1, Address(post(buf, 16))); 4550 subs(len, len, 32); 4551 crc32x(crc, crc, tmp0); 4552 ldr(tmp2, Address(post(buf, 8))); 4553 crc32x(crc, crc, tmp1); 4554 ldr(tmp3, Address(post(buf, 8))); 4555 crc32x(crc, crc, tmp2); 4556 crc32x(crc, crc, tmp3); 4557 br(Assembler::GE, CRC_by32_loop); 4558 cmn(len, (u1)32); 4559 br(Assembler::NE, CRC_less32); 4560 b(L_exit); 4561 4562 BIND(CRC_by4_loop); 4563 ldrw(tmp0, Address(post(buf, 4))); 4564 subs(len, len, 4); 4565 crc32w(crc, crc, tmp0); 4566 br(Assembler::GE, CRC_by4_loop); 4567 adds(len, len, 4); 4568 br(Assembler::LE, L_exit); 4569 BIND(CRC_by1_loop); 4570 ldrb(tmp0, Address(post(buf, 1))); 4571 subs(len, len, 1); 4572 crc32b(crc, crc, tmp0); 4573 br(Assembler::GT, CRC_by1_loop); 4574 b(L_exit); 4575 4576 BIND(CRC_by64_pre); 4577 sub(buf, buf, 8); 4578 ldp(tmp0, tmp1, Address(buf, 8)); 4579 crc32x(crc, crc, tmp0); 4580 ldr(tmp2, Address(buf, 24)); 4581 crc32x(crc, crc, tmp1); 4582 ldr(tmp3, Address(buf, 32)); 4583 crc32x(crc, crc, tmp2); 4584 ldr(tmp0, Address(buf, 40)); 4585 crc32x(crc, crc, tmp3); 4586 ldr(tmp1, Address(buf, 48)); 4587 crc32x(crc, crc, tmp0); 4588 ldr(tmp2, Address(buf, 56)); 4589 crc32x(crc, crc, tmp1); 4590 ldr(tmp3, Address(pre(buf, 64))); 4591 4592 b(CRC_by64_loop); 4593 4594 align(CodeEntryAlignment); 4595 BIND(CRC_by64_loop); 4596 subs(len, len, 64); 4597 crc32x(crc, crc, tmp2); 4598 ldr(tmp0, Address(buf, 8)); 4599 crc32x(crc, crc, tmp3); 4600 ldr(tmp1, Address(buf, 16)); 4601 crc32x(crc, crc, tmp0); 4602 ldr(tmp2, Address(buf, 24)); 4603 crc32x(crc, crc, tmp1); 4604 ldr(tmp3, Address(buf, 32)); 4605 crc32x(crc, crc, tmp2); 4606 ldr(tmp0, Address(buf, 40)); 4607 crc32x(crc, crc, tmp3); 4608 ldr(tmp1, Address(buf, 48)); 4609 crc32x(crc, crc, tmp0); 4610 ldr(tmp2, Address(buf, 56)); 4611 crc32x(crc, crc, tmp1); 4612 ldr(tmp3, Address(pre(buf, 64))); 4613 br(Assembler::GE, CRC_by64_loop); 4614 4615 // post-loop 4616 crc32x(crc, crc, tmp2); 4617 crc32x(crc, crc, tmp3); 4618 4619 sub(len, len, 64); 4620 add(buf, buf, 8); 4621 cmn(len, (u1)128); 4622 br(Assembler::NE, CRC_less64); 4623 BIND(L_exit); 4624 mvnw(crc, crc); 4625 } 4626 4627 /** 4628 * @param crc register containing existing CRC (32-bit) 4629 * @param buf register pointing to input byte buffer (byte*) 4630 * @param len register containing number of bytes 4631 * @param table register that will contain address of CRC table 4632 * @param tmp scratch register 4633 */ 4634 void MacroAssembler::kernel_crc32(Register crc, Register buf, Register len, 4635 Register table0, Register table1, Register table2, Register table3, 4636 Register tmp, Register tmp2, Register tmp3) { 4637 Label L_by16, L_by16_loop, L_by4, L_by4_loop, L_by1, L_by1_loop, L_exit; 4638 4639 if (UseCryptoPmullForCRC32) { 4640 kernel_crc32_using_crypto_pmull(crc, buf, len, table0, table1, table2, table3); 4641 return; 4642 } 4643 4644 if (UseCRC32) { 4645 kernel_crc32_using_crc32(crc, buf, len, table0, table1, table2, table3); 4646 return; 4647 } 4648 4649 mvnw(crc, crc); 4650 4651 { 4652 uint64_t offset; 4653 adrp(table0, ExternalAddress(StubRoutines::crc_table_addr()), offset); 4654 add(table0, table0, offset); 4655 } 4656 add(table1, table0, 1*256*sizeof(juint)); 4657 add(table2, table0, 2*256*sizeof(juint)); 4658 add(table3, table0, 3*256*sizeof(juint)); 4659 4660 { // Neon code start 4661 cmp(len, (u1)64); 4662 br(Assembler::LT, L_by16); 4663 eor(v16, T16B, v16, v16); 4664 4665 Label L_fold; 4666 4667 add(tmp, table0, 4*256*sizeof(juint)); // Point at the Neon constants 4668 4669 ld1(v0, v1, T2D, post(buf, 32)); 4670 ld1r(v4, T2D, post(tmp, 8)); 4671 ld1r(v5, T2D, post(tmp, 8)); 4672 ld1r(v6, T2D, post(tmp, 8)); 4673 ld1r(v7, T2D, post(tmp, 8)); 4674 mov(v16, S, 0, crc); 4675 4676 eor(v0, T16B, v0, v16); 4677 sub(len, len, 64); 4678 4679 BIND(L_fold); 4680 pmull(v22, T8H, v0, v5, T8B); 4681 pmull(v20, T8H, v0, v7, T8B); 4682 pmull(v23, T8H, v0, v4, T8B); 4683 pmull(v21, T8H, v0, v6, T8B); 4684 4685 pmull2(v18, T8H, v0, v5, T16B); 4686 pmull2(v16, T8H, v0, v7, T16B); 4687 pmull2(v19, T8H, v0, v4, T16B); 4688 pmull2(v17, T8H, v0, v6, T16B); 4689 4690 uzp1(v24, T8H, v20, v22); 4691 uzp2(v25, T8H, v20, v22); 4692 eor(v20, T16B, v24, v25); 4693 4694 uzp1(v26, T8H, v16, v18); 4695 uzp2(v27, T8H, v16, v18); 4696 eor(v16, T16B, v26, v27); 4697 4698 ushll2(v22, T4S, v20, T8H, 8); 4699 ushll(v20, T4S, v20, T4H, 8); 4700 4701 ushll2(v18, T4S, v16, T8H, 8); 4702 ushll(v16, T4S, v16, T4H, 8); 4703 4704 eor(v22, T16B, v23, v22); 4705 eor(v18, T16B, v19, v18); 4706 eor(v20, T16B, v21, v20); 4707 eor(v16, T16B, v17, v16); 4708 4709 uzp1(v17, T2D, v16, v20); 4710 uzp2(v21, T2D, v16, v20); 4711 eor(v17, T16B, v17, v21); 4712 4713 ushll2(v20, T2D, v17, T4S, 16); 4714 ushll(v16, T2D, v17, T2S, 16); 4715 4716 eor(v20, T16B, v20, v22); 4717 eor(v16, T16B, v16, v18); 4718 4719 uzp1(v17, T2D, v20, v16); 4720 uzp2(v21, T2D, v20, v16); 4721 eor(v28, T16B, v17, v21); 4722 4723 pmull(v22, T8H, v1, v5, T8B); 4724 pmull(v20, T8H, v1, v7, T8B); 4725 pmull(v23, T8H, v1, v4, T8B); 4726 pmull(v21, T8H, v1, v6, T8B); 4727 4728 pmull2(v18, T8H, v1, v5, T16B); 4729 pmull2(v16, T8H, v1, v7, T16B); 4730 pmull2(v19, T8H, v1, v4, T16B); 4731 pmull2(v17, T8H, v1, v6, T16B); 4732 4733 ld1(v0, v1, T2D, post(buf, 32)); 4734 4735 uzp1(v24, T8H, v20, v22); 4736 uzp2(v25, T8H, v20, v22); 4737 eor(v20, T16B, v24, v25); 4738 4739 uzp1(v26, T8H, v16, v18); 4740 uzp2(v27, T8H, v16, v18); 4741 eor(v16, T16B, v26, v27); 4742 4743 ushll2(v22, T4S, v20, T8H, 8); 4744 ushll(v20, T4S, v20, T4H, 8); 4745 4746 ushll2(v18, T4S, v16, T8H, 8); 4747 ushll(v16, T4S, v16, T4H, 8); 4748 4749 eor(v22, T16B, v23, v22); 4750 eor(v18, T16B, v19, v18); 4751 eor(v20, T16B, v21, v20); 4752 eor(v16, T16B, v17, v16); 4753 4754 uzp1(v17, T2D, v16, v20); 4755 uzp2(v21, T2D, v16, v20); 4756 eor(v16, T16B, v17, v21); 4757 4758 ushll2(v20, T2D, v16, T4S, 16); 4759 ushll(v16, T2D, v16, T2S, 16); 4760 4761 eor(v20, T16B, v22, v20); 4762 eor(v16, T16B, v16, v18); 4763 4764 uzp1(v17, T2D, v20, v16); 4765 uzp2(v21, T2D, v20, v16); 4766 eor(v20, T16B, v17, v21); 4767 4768 shl(v16, T2D, v28, 1); 4769 shl(v17, T2D, v20, 1); 4770 4771 eor(v0, T16B, v0, v16); 4772 eor(v1, T16B, v1, v17); 4773 4774 subs(len, len, 32); 4775 br(Assembler::GE, L_fold); 4776 4777 mov(crc, 0); 4778 mov(tmp, v0, D, 0); 4779 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, false); 4780 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, true); 4781 mov(tmp, v0, D, 1); 4782 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, false); 4783 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, true); 4784 mov(tmp, v1, D, 0); 4785 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, false); 4786 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, true); 4787 mov(tmp, v1, D, 1); 4788 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, false); 4789 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, true); 4790 4791 add(len, len, 32); 4792 } // Neon code end 4793 4794 BIND(L_by16); 4795 subs(len, len, 16); 4796 br(Assembler::GE, L_by16_loop); 4797 adds(len, len, 16-4); 4798 br(Assembler::GE, L_by4_loop); 4799 adds(len, len, 4); 4800 br(Assembler::GT, L_by1_loop); 4801 b(L_exit); 4802 4803 BIND(L_by4_loop); 4804 ldrw(tmp, Address(post(buf, 4))); 4805 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3); 4806 subs(len, len, 4); 4807 br(Assembler::GE, L_by4_loop); 4808 adds(len, len, 4); 4809 br(Assembler::LE, L_exit); 4810 BIND(L_by1_loop); 4811 subs(len, len, 1); 4812 ldrb(tmp, Address(post(buf, 1))); 4813 update_byte_crc32(crc, tmp, table0); 4814 br(Assembler::GT, L_by1_loop); 4815 b(L_exit); 4816 4817 align(CodeEntryAlignment); 4818 BIND(L_by16_loop); 4819 subs(len, len, 16); 4820 ldp(tmp, tmp3, Address(post(buf, 16))); 4821 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, false); 4822 update_word_crc32(crc, tmp, tmp2, table0, table1, table2, table3, true); 4823 update_word_crc32(crc, tmp3, tmp2, table0, table1, table2, table3, false); 4824 update_word_crc32(crc, tmp3, tmp2, table0, table1, table2, table3, true); 4825 br(Assembler::GE, L_by16_loop); 4826 adds(len, len, 16-4); 4827 br(Assembler::GE, L_by4_loop); 4828 adds(len, len, 4); 4829 br(Assembler::GT, L_by1_loop); 4830 BIND(L_exit); 4831 mvnw(crc, crc); 4832 } 4833 4834 void MacroAssembler::kernel_crc32c_using_crypto_pmull(Register crc, Register buf, 4835 Register len, Register tmp0, Register tmp1, Register tmp2, Register tmp3) { 4836 Label CRC_by4_loop, CRC_by1_loop, CRC_less128, CRC_by128_pre, CRC_by32_loop, CRC_less32, L_exit; 4837 assert_different_registers(crc, buf, len, tmp0, tmp1, tmp2); 4838 4839 subs(tmp0, len, 384); 4840 br(Assembler::GE, CRC_by128_pre); 4841 BIND(CRC_less128); 4842 subs(len, len, 32); 4843 br(Assembler::GE, CRC_by32_loop); 4844 BIND(CRC_less32); 4845 adds(len, len, 32 - 4); 4846 br(Assembler::GE, CRC_by4_loop); 4847 adds(len, len, 4); 4848 br(Assembler::GT, CRC_by1_loop); 4849 b(L_exit); 4850 4851 BIND(CRC_by32_loop); 4852 ldp(tmp0, tmp1, Address(buf)); 4853 crc32cx(crc, crc, tmp0); 4854 ldr(tmp2, Address(buf, 16)); 4855 crc32cx(crc, crc, tmp1); 4856 ldr(tmp3, Address(buf, 24)); 4857 crc32cx(crc, crc, tmp2); 4858 add(buf, buf, 32); 4859 subs(len, len, 32); 4860 crc32cx(crc, crc, tmp3); 4861 br(Assembler::GE, CRC_by32_loop); 4862 cmn(len, (u1)32); 4863 br(Assembler::NE, CRC_less32); 4864 b(L_exit); 4865 4866 BIND(CRC_by4_loop); 4867 ldrw(tmp0, Address(post(buf, 4))); 4868 subs(len, len, 4); 4869 crc32cw(crc, crc, tmp0); 4870 br(Assembler::GE, CRC_by4_loop); 4871 adds(len, len, 4); 4872 br(Assembler::LE, L_exit); 4873 BIND(CRC_by1_loop); 4874 ldrb(tmp0, Address(post(buf, 1))); 4875 subs(len, len, 1); 4876 crc32cb(crc, crc, tmp0); 4877 br(Assembler::GT, CRC_by1_loop); 4878 b(L_exit); 4879 4880 BIND(CRC_by128_pre); 4881 kernel_crc32_common_fold_using_crypto_pmull(crc, buf, len, tmp0, tmp1, tmp2, 4882 4*256*sizeof(juint) + 8*sizeof(juint) + 0x50); 4883 mov(crc, 0); 4884 crc32cx(crc, crc, tmp0); 4885 crc32cx(crc, crc, tmp1); 4886 4887 cbnz(len, CRC_less128); 4888 4889 BIND(L_exit); 4890 } 4891 4892 void MacroAssembler::kernel_crc32c_using_crc32c(Register crc, Register buf, 4893 Register len, Register tmp0, Register tmp1, Register tmp2, 4894 Register tmp3) { 4895 Label CRC_by64_loop, CRC_by4_loop, CRC_by1_loop, CRC_less64, CRC_by64_pre, CRC_by32_loop, CRC_less32, L_exit; 4896 assert_different_registers(crc, buf, len, tmp0, tmp1, tmp2, tmp3); 4897 4898 subs(len, len, 128); 4899 br(Assembler::GE, CRC_by64_pre); 4900 BIND(CRC_less64); 4901 adds(len, len, 128-32); 4902 br(Assembler::GE, CRC_by32_loop); 4903 BIND(CRC_less32); 4904 adds(len, len, 32-4); 4905 br(Assembler::GE, CRC_by4_loop); 4906 adds(len, len, 4); 4907 br(Assembler::GT, CRC_by1_loop); 4908 b(L_exit); 4909 4910 BIND(CRC_by32_loop); 4911 ldp(tmp0, tmp1, Address(post(buf, 16))); 4912 subs(len, len, 32); 4913 crc32cx(crc, crc, tmp0); 4914 ldr(tmp2, Address(post(buf, 8))); 4915 crc32cx(crc, crc, tmp1); 4916 ldr(tmp3, Address(post(buf, 8))); 4917 crc32cx(crc, crc, tmp2); 4918 crc32cx(crc, crc, tmp3); 4919 br(Assembler::GE, CRC_by32_loop); 4920 cmn(len, (u1)32); 4921 br(Assembler::NE, CRC_less32); 4922 b(L_exit); 4923 4924 BIND(CRC_by4_loop); 4925 ldrw(tmp0, Address(post(buf, 4))); 4926 subs(len, len, 4); 4927 crc32cw(crc, crc, tmp0); 4928 br(Assembler::GE, CRC_by4_loop); 4929 adds(len, len, 4); 4930 br(Assembler::LE, L_exit); 4931 BIND(CRC_by1_loop); 4932 ldrb(tmp0, Address(post(buf, 1))); 4933 subs(len, len, 1); 4934 crc32cb(crc, crc, tmp0); 4935 br(Assembler::GT, CRC_by1_loop); 4936 b(L_exit); 4937 4938 BIND(CRC_by64_pre); 4939 sub(buf, buf, 8); 4940 ldp(tmp0, tmp1, Address(buf, 8)); 4941 crc32cx(crc, crc, tmp0); 4942 ldr(tmp2, Address(buf, 24)); 4943 crc32cx(crc, crc, tmp1); 4944 ldr(tmp3, Address(buf, 32)); 4945 crc32cx(crc, crc, tmp2); 4946 ldr(tmp0, Address(buf, 40)); 4947 crc32cx(crc, crc, tmp3); 4948 ldr(tmp1, Address(buf, 48)); 4949 crc32cx(crc, crc, tmp0); 4950 ldr(tmp2, Address(buf, 56)); 4951 crc32cx(crc, crc, tmp1); 4952 ldr(tmp3, Address(pre(buf, 64))); 4953 4954 b(CRC_by64_loop); 4955 4956 align(CodeEntryAlignment); 4957 BIND(CRC_by64_loop); 4958 subs(len, len, 64); 4959 crc32cx(crc, crc, tmp2); 4960 ldr(tmp0, Address(buf, 8)); 4961 crc32cx(crc, crc, tmp3); 4962 ldr(tmp1, Address(buf, 16)); 4963 crc32cx(crc, crc, tmp0); 4964 ldr(tmp2, Address(buf, 24)); 4965 crc32cx(crc, crc, tmp1); 4966 ldr(tmp3, Address(buf, 32)); 4967 crc32cx(crc, crc, tmp2); 4968 ldr(tmp0, Address(buf, 40)); 4969 crc32cx(crc, crc, tmp3); 4970 ldr(tmp1, Address(buf, 48)); 4971 crc32cx(crc, crc, tmp0); 4972 ldr(tmp2, Address(buf, 56)); 4973 crc32cx(crc, crc, tmp1); 4974 ldr(tmp3, Address(pre(buf, 64))); 4975 br(Assembler::GE, CRC_by64_loop); 4976 4977 // post-loop 4978 crc32cx(crc, crc, tmp2); 4979 crc32cx(crc, crc, tmp3); 4980 4981 sub(len, len, 64); 4982 add(buf, buf, 8); 4983 cmn(len, (u1)128); 4984 br(Assembler::NE, CRC_less64); 4985 BIND(L_exit); 4986 } 4987 4988 /** 4989 * @param crc register containing existing CRC (32-bit) 4990 * @param buf register pointing to input byte buffer (byte*) 4991 * @param len register containing number of bytes 4992 * @param table register that will contain address of CRC table 4993 * @param tmp scratch register 4994 */ 4995 void MacroAssembler::kernel_crc32c(Register crc, Register buf, Register len, 4996 Register table0, Register table1, Register table2, Register table3, 4997 Register tmp, Register tmp2, Register tmp3) { 4998 if (UseCryptoPmullForCRC32) { 4999 kernel_crc32c_using_crypto_pmull(crc, buf, len, table0, table1, table2, table3); 5000 } else { 5001 kernel_crc32c_using_crc32c(crc, buf, len, table0, table1, table2, table3); 5002 } 5003 } 5004 5005 void MacroAssembler::kernel_crc32_common_fold_using_crypto_pmull(Register crc, Register buf, 5006 Register len, Register tmp0, Register tmp1, Register tmp2, size_t table_offset) { 5007 Label CRC_by128_loop; 5008 assert_different_registers(crc, buf, len, tmp0, tmp1, tmp2); 5009 5010 sub(len, len, 256); 5011 Register table = tmp0; 5012 { 5013 uint64_t offset; 5014 adrp(table, ExternalAddress(StubRoutines::crc_table_addr()), offset); 5015 add(table, table, offset); 5016 } 5017 add(table, table, table_offset); 5018 5019 // Registers v0..v7 are used as data registers. 5020 // Registers v16..v31 are used as tmp registers. 5021 sub(buf, buf, 0x10); 5022 ldrq(v0, Address(buf, 0x10)); 5023 ldrq(v1, Address(buf, 0x20)); 5024 ldrq(v2, Address(buf, 0x30)); 5025 ldrq(v3, Address(buf, 0x40)); 5026 ldrq(v4, Address(buf, 0x50)); 5027 ldrq(v5, Address(buf, 0x60)); 5028 ldrq(v6, Address(buf, 0x70)); 5029 ldrq(v7, Address(pre(buf, 0x80))); 5030 5031 movi(v31, T4S, 0); 5032 mov(v31, S, 0, crc); 5033 eor(v0, T16B, v0, v31); 5034 5035 // Register v16 contains constants from the crc table. 5036 ldrq(v16, Address(table)); 5037 b(CRC_by128_loop); 5038 5039 align(OptoLoopAlignment); 5040 BIND(CRC_by128_loop); 5041 pmull (v17, T1Q, v0, v16, T1D); 5042 pmull2(v18, T1Q, v0, v16, T2D); 5043 ldrq(v0, Address(buf, 0x10)); 5044 eor3(v0, T16B, v17, v18, v0); 5045 5046 pmull (v19, T1Q, v1, v16, T1D); 5047 pmull2(v20, T1Q, v1, v16, T2D); 5048 ldrq(v1, Address(buf, 0x20)); 5049 eor3(v1, T16B, v19, v20, v1); 5050 5051 pmull (v21, T1Q, v2, v16, T1D); 5052 pmull2(v22, T1Q, v2, v16, T2D); 5053 ldrq(v2, Address(buf, 0x30)); 5054 eor3(v2, T16B, v21, v22, v2); 5055 5056 pmull (v23, T1Q, v3, v16, T1D); 5057 pmull2(v24, T1Q, v3, v16, T2D); 5058 ldrq(v3, Address(buf, 0x40)); 5059 eor3(v3, T16B, v23, v24, v3); 5060 5061 pmull (v25, T1Q, v4, v16, T1D); 5062 pmull2(v26, T1Q, v4, v16, T2D); 5063 ldrq(v4, Address(buf, 0x50)); 5064 eor3(v4, T16B, v25, v26, v4); 5065 5066 pmull (v27, T1Q, v5, v16, T1D); 5067 pmull2(v28, T1Q, v5, v16, T2D); 5068 ldrq(v5, Address(buf, 0x60)); 5069 eor3(v5, T16B, v27, v28, v5); 5070 5071 pmull (v29, T1Q, v6, v16, T1D); 5072 pmull2(v30, T1Q, v6, v16, T2D); 5073 ldrq(v6, Address(buf, 0x70)); 5074 eor3(v6, T16B, v29, v30, v6); 5075 5076 // Reuse registers v23, v24. 5077 // Using them won't block the first instruction of the next iteration. 5078 pmull (v23, T1Q, v7, v16, T1D); 5079 pmull2(v24, T1Q, v7, v16, T2D); 5080 ldrq(v7, Address(pre(buf, 0x80))); 5081 eor3(v7, T16B, v23, v24, v7); 5082 5083 subs(len, len, 0x80); 5084 br(Assembler::GE, CRC_by128_loop); 5085 5086 // fold into 512 bits 5087 // Use v31 for constants because v16 can be still in use. 5088 ldrq(v31, Address(table, 0x10)); 5089 5090 pmull (v17, T1Q, v0, v31, T1D); 5091 pmull2(v18, T1Q, v0, v31, T2D); 5092 eor3(v0, T16B, v17, v18, v4); 5093 5094 pmull (v19, T1Q, v1, v31, T1D); 5095 pmull2(v20, T1Q, v1, v31, T2D); 5096 eor3(v1, T16B, v19, v20, v5); 5097 5098 pmull (v21, T1Q, v2, v31, T1D); 5099 pmull2(v22, T1Q, v2, v31, T2D); 5100 eor3(v2, T16B, v21, v22, v6); 5101 5102 pmull (v23, T1Q, v3, v31, T1D); 5103 pmull2(v24, T1Q, v3, v31, T2D); 5104 eor3(v3, T16B, v23, v24, v7); 5105 5106 // fold into 128 bits 5107 // Use v17 for constants because v31 can be still in use. 5108 ldrq(v17, Address(table, 0x20)); 5109 pmull (v25, T1Q, v0, v17, T1D); 5110 pmull2(v26, T1Q, v0, v17, T2D); 5111 eor3(v3, T16B, v3, v25, v26); 5112 5113 // Use v18 for constants because v17 can be still in use. 5114 ldrq(v18, Address(table, 0x30)); 5115 pmull (v27, T1Q, v1, v18, T1D); 5116 pmull2(v28, T1Q, v1, v18, T2D); 5117 eor3(v3, T16B, v3, v27, v28); 5118 5119 // Use v19 for constants because v18 can be still in use. 5120 ldrq(v19, Address(table, 0x40)); 5121 pmull (v29, T1Q, v2, v19, T1D); 5122 pmull2(v30, T1Q, v2, v19, T2D); 5123 eor3(v0, T16B, v3, v29, v30); 5124 5125 add(len, len, 0x80); 5126 add(buf, buf, 0x10); 5127 5128 mov(tmp0, v0, D, 0); 5129 mov(tmp1, v0, D, 1); 5130 } 5131 5132 void MacroAssembler::addptr(const Address &dst, int32_t src) { 5133 Address adr; 5134 switch(dst.getMode()) { 5135 case Address::base_plus_offset: 5136 // This is the expected mode, although we allow all the other 5137 // forms below. 5138 adr = form_address(rscratch2, dst.base(), dst.offset(), LogBytesPerWord); 5139 break; 5140 default: 5141 lea(rscratch2, dst); 5142 adr = Address(rscratch2); 5143 break; 5144 } 5145 ldr(rscratch1, adr); 5146 add(rscratch1, rscratch1, src); 5147 str(rscratch1, adr); 5148 } 5149 5150 void MacroAssembler::cmpptr(Register src1, Address src2) { 5151 uint64_t offset; 5152 adrp(rscratch1, src2, offset); 5153 ldr(rscratch1, Address(rscratch1, offset)); 5154 cmp(src1, rscratch1); 5155 } 5156 5157 void MacroAssembler::cmpoop(Register obj1, Register obj2) { 5158 cmp(obj1, obj2); 5159 } 5160 5161 void MacroAssembler::load_method_holder_cld(Register rresult, Register rmethod) { 5162 load_method_holder(rresult, rmethod); 5163 ldr(rresult, Address(rresult, InstanceKlass::class_loader_data_offset())); 5164 } 5165 5166 void MacroAssembler::load_method_holder(Register holder, Register method) { 5167 ldr(holder, Address(method, Method::const_offset())); // ConstMethod* 5168 ldr(holder, Address(holder, ConstMethod::constants_offset())); // ConstantPool* 5169 ldr(holder, Address(holder, ConstantPool::pool_holder_offset())); // InstanceKlass* 5170 } 5171 5172 void MacroAssembler::load_metadata(Register dst, Register src) { 5173 if (UseCompactObjectHeaders) { 5174 load_narrow_klass_compact(dst, src); 5175 } else { 5176 ldrw(dst, Address(src, oopDesc::klass_offset_in_bytes())); 5177 } 5178 } 5179 5180 // Loads the obj's Klass* into dst. 5181 // Preserves all registers (incl src, rscratch1 and rscratch2). 5182 // Input: 5183 // src - the oop we want to load the klass from. 5184 // dst - output narrow klass. 5185 void MacroAssembler::load_narrow_klass_compact(Register dst, Register src) { 5186 assert(UseCompactObjectHeaders, "expects UseCompactObjectHeaders"); 5187 ldr(dst, Address(src, oopDesc::mark_offset_in_bytes())); 5188 lsr(dst, dst, markWord::klass_shift); 5189 } 5190 5191 void MacroAssembler::load_klass(Register dst, Register src) { 5192 if (UseCompactObjectHeaders) { 5193 load_narrow_klass_compact(dst, src); 5194 } else { 5195 ldrw(dst, Address(src, oopDesc::klass_offset_in_bytes())); 5196 } 5197 decode_klass_not_null(dst); 5198 } 5199 5200 void MacroAssembler::restore_cpu_control_state_after_jni(Register tmp1, Register tmp2) { 5201 if (RestoreMXCSROnJNICalls) { 5202 Label OK; 5203 get_fpcr(tmp1); 5204 mov(tmp2, tmp1); 5205 // Set FPCR to the state we need. We do want Round to Nearest. We 5206 // don't want non-IEEE rounding modes or floating-point traps. 5207 bfi(tmp1, zr, 22, 4); // Clear DN, FZ, and Rmode 5208 bfi(tmp1, zr, 8, 5); // Clear exception-control bits (8-12) 5209 bfi(tmp1, zr, 0, 2); // Clear AH:FIZ 5210 eor(tmp2, tmp1, tmp2); 5211 cbz(tmp2, OK); // Only reset FPCR if it's wrong 5212 set_fpcr(tmp1); 5213 bind(OK); 5214 } 5215 } 5216 5217 // ((OopHandle)result).resolve(); 5218 void MacroAssembler::resolve_oop_handle(Register result, Register tmp1, Register tmp2) { 5219 // OopHandle::resolve is an indirection. 5220 access_load_at(T_OBJECT, IN_NATIVE, result, Address(result, 0), tmp1, tmp2); 5221 } 5222 5223 // ((WeakHandle)result).resolve(); 5224 void MacroAssembler::resolve_weak_handle(Register result, Register tmp1, Register tmp2) { 5225 assert_different_registers(result, tmp1, tmp2); 5226 Label resolved; 5227 5228 // A null weak handle resolves to null. 5229 cbz(result, resolved); 5230 5231 // Only 64 bit platforms support GCs that require a tmp register 5232 // WeakHandle::resolve is an indirection like jweak. 5233 access_load_at(T_OBJECT, IN_NATIVE | ON_PHANTOM_OOP_REF, 5234 result, Address(result), tmp1, tmp2); 5235 bind(resolved); 5236 } 5237 5238 void MacroAssembler::load_mirror(Register dst, Register method, Register tmp1, Register tmp2) { 5239 const int mirror_offset = in_bytes(Klass::java_mirror_offset()); 5240 ldr(dst, Address(rmethod, Method::const_offset())); 5241 ldr(dst, Address(dst, ConstMethod::constants_offset())); 5242 ldr(dst, Address(dst, ConstantPool::pool_holder_offset())); 5243 ldr(dst, Address(dst, mirror_offset)); 5244 resolve_oop_handle(dst, tmp1, tmp2); 5245 } 5246 5247 void MacroAssembler::cmp_klass(Register obj, Register klass, Register tmp) { 5248 assert_different_registers(obj, klass, tmp); 5249 if (UseCompactObjectHeaders) { 5250 load_narrow_klass_compact(tmp, obj); 5251 } else { 5252 ldrw(tmp, Address(obj, oopDesc::klass_offset_in_bytes())); 5253 } 5254 if (CompressedKlassPointers::base() == nullptr) { 5255 cmp(klass, tmp, LSL, CompressedKlassPointers::shift()); 5256 return; 5257 } else if (!AOTCodeCache::is_on_for_dump() && 5258 ((uint64_t)CompressedKlassPointers::base() & 0xffffffff) == 0 5259 && CompressedKlassPointers::shift() == 0) { 5260 // Only the bottom 32 bits matter 5261 cmpw(klass, tmp); 5262 return; 5263 } 5264 decode_klass_not_null(tmp); 5265 cmp(klass, tmp); 5266 } 5267 5268 void MacroAssembler::cmp_klasses_from_objects(Register obj1, Register obj2, Register tmp1, Register tmp2) { 5269 if (UseCompactObjectHeaders) { 5270 load_narrow_klass_compact(tmp1, obj1); 5271 load_narrow_klass_compact(tmp2, obj2); 5272 } else { 5273 ldrw(tmp1, Address(obj1, oopDesc::klass_offset_in_bytes())); 5274 ldrw(tmp2, Address(obj2, oopDesc::klass_offset_in_bytes())); 5275 } 5276 cmpw(tmp1, tmp2); 5277 } 5278 5279 void MacroAssembler::load_prototype_header(Register dst, Register src) { 5280 load_klass(dst, src); 5281 ldr(dst, Address(dst, Klass::prototype_header_offset())); 5282 } 5283 5284 void MacroAssembler::store_klass(Register dst, Register src) { 5285 // FIXME: Should this be a store release? concurrent gcs assumes 5286 // klass length is valid if klass field is not null. 5287 assert(!UseCompactObjectHeaders, "not with compact headers"); 5288 encode_klass_not_null(src); 5289 strw(src, Address(dst, oopDesc::klass_offset_in_bytes())); 5290 } 5291 5292 void MacroAssembler::store_klass_gap(Register dst, Register src) { 5293 assert(!UseCompactObjectHeaders, "not with compact headers"); 5294 // Store to klass gap in destination 5295 strw(src, Address(dst, oopDesc::klass_gap_offset_in_bytes())); 5296 } 5297 5298 // Algorithm must match CompressedOops::encode. 5299 void MacroAssembler::encode_heap_oop(Register d, Register s) { 5300 #ifdef ASSERT 5301 verify_heapbase("MacroAssembler::encode_heap_oop: heap base corrupted?"); 5302 #endif 5303 verify_oop_msg(s, "broken oop in encode_heap_oop"); 5304 if (CompressedOops::base() == nullptr) { 5305 if (CompressedOops::shift() != 0) { 5306 assert (LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong"); 5307 lsr(d, s, LogMinObjAlignmentInBytes); 5308 } else { 5309 mov(d, s); 5310 } 5311 } else { 5312 subs(d, s, rheapbase); 5313 csel(d, d, zr, Assembler::HS); 5314 lsr(d, d, LogMinObjAlignmentInBytes); 5315 5316 /* Old algorithm: is this any worse? 5317 Label nonnull; 5318 cbnz(r, nonnull); 5319 sub(r, r, rheapbase); 5320 bind(nonnull); 5321 lsr(r, r, LogMinObjAlignmentInBytes); 5322 */ 5323 } 5324 } 5325 5326 void MacroAssembler::encode_heap_oop_not_null(Register r) { 5327 #ifdef ASSERT 5328 verify_heapbase("MacroAssembler::encode_heap_oop_not_null: heap base corrupted?"); 5329 if (CheckCompressedOops) { 5330 Label ok; 5331 cbnz(r, ok); 5332 stop("null oop passed to encode_heap_oop_not_null"); 5333 bind(ok); 5334 } 5335 #endif 5336 verify_oop_msg(r, "broken oop in encode_heap_oop_not_null"); 5337 if (CompressedOops::base() != nullptr) { 5338 sub(r, r, rheapbase); 5339 } 5340 if (CompressedOops::shift() != 0) { 5341 assert (LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong"); 5342 lsr(r, r, LogMinObjAlignmentInBytes); 5343 } 5344 } 5345 5346 void MacroAssembler::encode_heap_oop_not_null(Register dst, Register src) { 5347 #ifdef ASSERT 5348 verify_heapbase("MacroAssembler::encode_heap_oop_not_null2: heap base corrupted?"); 5349 if (CheckCompressedOops) { 5350 Label ok; 5351 cbnz(src, ok); 5352 stop("null oop passed to encode_heap_oop_not_null2"); 5353 bind(ok); 5354 } 5355 #endif 5356 verify_oop_msg(src, "broken oop in encode_heap_oop_not_null2"); 5357 5358 Register data = src; 5359 if (CompressedOops::base() != nullptr) { 5360 sub(dst, src, rheapbase); 5361 data = dst; 5362 } 5363 if (CompressedOops::shift() != 0) { 5364 assert (LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong"); 5365 lsr(dst, data, LogMinObjAlignmentInBytes); 5366 data = dst; 5367 } 5368 if (data == src) 5369 mov(dst, src); 5370 } 5371 5372 void MacroAssembler::decode_heap_oop(Register d, Register s) { 5373 #ifdef ASSERT 5374 verify_heapbase("MacroAssembler::decode_heap_oop: heap base corrupted?"); 5375 #endif 5376 if (CompressedOops::base() == nullptr) { 5377 if (CompressedOops::shift() != 0) { 5378 lsl(d, s, CompressedOops::shift()); 5379 } else if (d != s) { 5380 mov(d, s); 5381 } 5382 } else { 5383 Label done; 5384 if (d != s) 5385 mov(d, s); 5386 cbz(s, done); 5387 add(d, rheapbase, s, Assembler::LSL, LogMinObjAlignmentInBytes); 5388 bind(done); 5389 } 5390 verify_oop_msg(d, "broken oop in decode_heap_oop"); 5391 } 5392 5393 void MacroAssembler::decode_heap_oop_not_null(Register r) { 5394 assert (UseCompressedOops, "should only be used for compressed headers"); 5395 assert (Universe::heap() != nullptr, "java heap should be initialized"); 5396 // Cannot assert, unverified entry point counts instructions (see .ad file) 5397 // vtableStubs also counts instructions in pd_code_size_limit. 5398 // Also do not verify_oop as this is called by verify_oop. 5399 if (CompressedOops::shift() != 0) { 5400 assert(LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong"); 5401 if (CompressedOops::base() != nullptr) { 5402 add(r, rheapbase, r, Assembler::LSL, LogMinObjAlignmentInBytes); 5403 } else { 5404 add(r, zr, r, Assembler::LSL, LogMinObjAlignmentInBytes); 5405 } 5406 } else { 5407 assert (CompressedOops::base() == nullptr, "sanity"); 5408 } 5409 } 5410 5411 void MacroAssembler::decode_heap_oop_not_null(Register dst, Register src) { 5412 assert (UseCompressedOops, "should only be used for compressed headers"); 5413 assert (Universe::heap() != nullptr, "java heap should be initialized"); 5414 // Cannot assert, unverified entry point counts instructions (see .ad file) 5415 // vtableStubs also counts instructions in pd_code_size_limit. 5416 // Also do not verify_oop as this is called by verify_oop. 5417 if (CompressedOops::shift() != 0) { 5418 assert(LogMinObjAlignmentInBytes == CompressedOops::shift(), "decode alg wrong"); 5419 if (CompressedOops::base() != nullptr) { 5420 add(dst, rheapbase, src, Assembler::LSL, LogMinObjAlignmentInBytes); 5421 } else { 5422 add(dst, zr, src, Assembler::LSL, LogMinObjAlignmentInBytes); 5423 } 5424 } else { 5425 assert (CompressedOops::base() == nullptr, "sanity"); 5426 if (dst != src) { 5427 mov(dst, src); 5428 } 5429 } 5430 } 5431 5432 MacroAssembler::KlassDecodeMode MacroAssembler::_klass_decode_mode(KlassDecodeNone); 5433 5434 MacroAssembler::KlassDecodeMode MacroAssembler::klass_decode_mode() { 5435 assert(Metaspace::initialized(), "metaspace not initialized yet"); 5436 assert(_klass_decode_mode != KlassDecodeNone, "should be initialized"); 5437 return _klass_decode_mode; 5438 } 5439 5440 MacroAssembler::KlassDecodeMode MacroAssembler::klass_decode_mode(address base, int shift, const size_t range) { 5441 // KlassDecodeMode shouldn't be set already. 5442 assert(_klass_decode_mode == KlassDecodeNone, "set once"); 5443 5444 if (base == nullptr) { 5445 return KlassDecodeZero; 5446 } 5447 5448 if (operand_valid_for_logical_immediate( 5449 /*is32*/false, (uint64_t)base)) { 5450 const uint64_t range_mask = right_n_bits(log2i_ceil(range)); 5451 if (((uint64_t)base & range_mask) == 0) { 5452 return KlassDecodeXor; 5453 } 5454 } 5455 5456 const uint64_t shifted_base = 5457 (uint64_t)base >> shift; 5458 if ((shifted_base & 0xffff0000ffffffff) == 0) { 5459 return KlassDecodeMovk; 5460 } 5461 5462 // No valid encoding. 5463 return KlassDecodeNone; 5464 } 5465 5466 // Check if one of the above decoding modes will work for given base, shift and range. 5467 bool MacroAssembler::check_klass_decode_mode(address base, int shift, const size_t range) { 5468 return klass_decode_mode(base, shift, range) != KlassDecodeNone; 5469 } 5470 5471 bool MacroAssembler::set_klass_decode_mode(address base, int shift, const size_t range) { 5472 _klass_decode_mode = klass_decode_mode(base, shift, range); 5473 return _klass_decode_mode != KlassDecodeNone; 5474 } 5475 5476 static Register pick_different_tmp(Register dst, Register src) { 5477 auto tmps = RegSet::of(r0, r1, r2) - RegSet::of(src, dst); 5478 return *tmps.begin(); 5479 } 5480 5481 void MacroAssembler::encode_klass_not_null_for_aot(Register dst, Register src) { 5482 // we have to load the klass base from the AOT constants area but 5483 // not the shift because it is not allowed to change 5484 int shift = CompressedKlassPointers::shift(); 5485 assert(shift >= 0 && shift <= CompressedKlassPointers::max_shift(), "unexpected compressed klass shift!"); 5486 if (dst != src) { 5487 // we can load the base into dst, subtract it formthe src and shift down 5488 lea(dst, ExternalAddress(CompressedKlassPointers::base_addr())); 5489 ldr(dst, dst); 5490 sub(dst, src, dst); 5491 lsr(dst, dst, shift); 5492 } else { 5493 // we need an extra register in order to load the coop base 5494 Register tmp = pick_different_tmp(dst, src); 5495 RegSet regs = RegSet::of(tmp); 5496 push(regs, sp); 5497 lea(tmp, ExternalAddress(CompressedKlassPointers::base_addr())); 5498 ldr(tmp, tmp); 5499 sub(dst, src, tmp); 5500 lsr(dst, dst, shift); 5501 pop(regs, sp); 5502 } 5503 } 5504 5505 void MacroAssembler::encode_klass_not_null(Register dst, Register src) { 5506 if (CompressedKlassPointers::base() != nullptr && AOTCodeCache::is_on_for_dump()) { 5507 encode_klass_not_null_for_aot(dst, src); 5508 return; 5509 } 5510 5511 switch (klass_decode_mode()) { 5512 case KlassDecodeZero: 5513 if (CompressedKlassPointers::shift() != 0) { 5514 lsr(dst, src, CompressedKlassPointers::shift()); 5515 } else { 5516 if (dst != src) mov(dst, src); 5517 } 5518 break; 5519 5520 case KlassDecodeXor: 5521 if (CompressedKlassPointers::shift() != 0) { 5522 eor(dst, src, (uint64_t)CompressedKlassPointers::base()); 5523 lsr(dst, dst, CompressedKlassPointers::shift()); 5524 } else { 5525 eor(dst, src, (uint64_t)CompressedKlassPointers::base()); 5526 } 5527 break; 5528 5529 case KlassDecodeMovk: 5530 if (CompressedKlassPointers::shift() != 0) { 5531 ubfx(dst, src, CompressedKlassPointers::shift(), 32); 5532 } else { 5533 movw(dst, src); 5534 } 5535 break; 5536 5537 case KlassDecodeNone: 5538 ShouldNotReachHere(); 5539 break; 5540 } 5541 } 5542 5543 void MacroAssembler::encode_klass_not_null(Register r) { 5544 encode_klass_not_null(r, r); 5545 } 5546 5547 void MacroAssembler::decode_klass_not_null_for_aot(Register dst, Register src) { 5548 // we have to load the klass base from the AOT constants area but 5549 // not the shift because it is not allowed to change 5550 int shift = CompressedKlassPointers::shift(); 5551 assert(shift >= 0 && shift <= CompressedKlassPointers::max_shift(), "unexpected compressed klass shift!"); 5552 if (dst != src) { 5553 // we can load the base into dst then add the offset with a suitable shift 5554 lea(dst, ExternalAddress(CompressedKlassPointers::base_addr())); 5555 ldr(dst, dst); 5556 add(dst, dst, src, LSL, shift); 5557 } else { 5558 // we need an extra register in order to load the coop base 5559 Register tmp = pick_different_tmp(dst, src); 5560 RegSet regs = RegSet::of(tmp); 5561 push(regs, sp); 5562 lea(tmp, ExternalAddress(CompressedKlassPointers::base_addr())); 5563 ldr(tmp, tmp); 5564 add(dst, tmp, src, LSL, shift); 5565 pop(regs, sp); 5566 } 5567 } 5568 5569 void MacroAssembler::decode_klass_not_null(Register dst, Register src) { 5570 if (AOTCodeCache::is_on_for_dump()) { 5571 decode_klass_not_null_for_aot(dst, src); 5572 return; 5573 } 5574 5575 switch (klass_decode_mode()) { 5576 case KlassDecodeZero: 5577 if (CompressedKlassPointers::shift() != 0) { 5578 lsl(dst, src, CompressedKlassPointers::shift()); 5579 } else { 5580 if (dst != src) mov(dst, src); 5581 } 5582 break; 5583 5584 case KlassDecodeXor: 5585 if (CompressedKlassPointers::shift() != 0) { 5586 lsl(dst, src, CompressedKlassPointers::shift()); 5587 eor(dst, dst, (uint64_t)CompressedKlassPointers::base()); 5588 } else { 5589 eor(dst, src, (uint64_t)CompressedKlassPointers::base()); 5590 } 5591 break; 5592 5593 case KlassDecodeMovk: { 5594 const uint64_t shifted_base = 5595 (uint64_t)CompressedKlassPointers::base() >> CompressedKlassPointers::shift(); 5596 5597 if (dst != src) movw(dst, src); 5598 movk(dst, shifted_base >> 32, 32); 5599 5600 if (CompressedKlassPointers::shift() != 0) { 5601 lsl(dst, dst, CompressedKlassPointers::shift()); 5602 } 5603 5604 break; 5605 } 5606 5607 case KlassDecodeNone: 5608 ShouldNotReachHere(); 5609 break; 5610 } 5611 } 5612 5613 void MacroAssembler::decode_klass_not_null(Register r) { 5614 decode_klass_not_null(r, r); 5615 } 5616 5617 void MacroAssembler::set_narrow_oop(Register dst, jobject obj) { 5618 #ifdef ASSERT 5619 { 5620 ThreadInVMfromUnknown tiv; 5621 assert (UseCompressedOops, "should only be used for compressed oops"); 5622 assert (Universe::heap() != nullptr, "java heap should be initialized"); 5623 assert (oop_recorder() != nullptr, "this assembler needs an OopRecorder"); 5624 assert(Universe::heap()->is_in(JNIHandles::resolve(obj)), "should be real oop"); 5625 } 5626 #endif 5627 int oop_index = oop_recorder()->find_index(obj); 5628 InstructionMark im(this); 5629 RelocationHolder rspec = oop_Relocation::spec(oop_index); 5630 code_section()->relocate(inst_mark(), rspec); 5631 movz(dst, 0xDEAD, 16); 5632 movk(dst, 0xBEEF); 5633 } 5634 5635 void MacroAssembler::set_narrow_klass(Register dst, Klass* k) { 5636 assert (oop_recorder() != nullptr, "this assembler needs an OopRecorder"); 5637 int index = oop_recorder()->find_index(k); 5638 5639 InstructionMark im(this); 5640 RelocationHolder rspec = metadata_Relocation::spec(index); 5641 code_section()->relocate(inst_mark(), rspec); 5642 narrowKlass nk = CompressedKlassPointers::encode(k); 5643 movz(dst, (nk >> 16), 16); 5644 movk(dst, nk & 0xffff); 5645 } 5646 5647 void MacroAssembler::access_load_at(BasicType type, DecoratorSet decorators, 5648 Register dst, Address src, 5649 Register tmp1, Register tmp2) { 5650 BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler(); 5651 decorators = AccessInternal::decorator_fixup(decorators, type); 5652 bool as_raw = (decorators & AS_RAW) != 0; 5653 if (as_raw) { 5654 bs->BarrierSetAssembler::load_at(this, decorators, type, dst, src, tmp1, tmp2); 5655 } else { 5656 bs->load_at(this, decorators, type, dst, src, tmp1, tmp2); 5657 } 5658 } 5659 5660 void MacroAssembler::access_store_at(BasicType type, DecoratorSet decorators, 5661 Address dst, Register val, 5662 Register tmp1, Register tmp2, Register tmp3) { 5663 BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler(); 5664 decorators = AccessInternal::decorator_fixup(decorators, type); 5665 bool as_raw = (decorators & AS_RAW) != 0; 5666 if (as_raw) { 5667 bs->BarrierSetAssembler::store_at(this, decorators, type, dst, val, tmp1, tmp2, tmp3); 5668 } else { 5669 bs->store_at(this, decorators, type, dst, val, tmp1, tmp2, tmp3); 5670 } 5671 } 5672 5673 void MacroAssembler::flat_field_copy(DecoratorSet decorators, Register src, Register dst, 5674 Register inline_layout_info) { 5675 BarrierSetAssembler* bs = BarrierSet::barrier_set()->barrier_set_assembler(); 5676 bs->flat_field_copy(this, decorators, src, dst, inline_layout_info); 5677 } 5678 5679 void MacroAssembler::payload_offset(Register inline_klass, Register offset) { 5680 ldr(offset, Address(inline_klass, InlineKlass::adr_members_offset())); 5681 ldrw(offset, Address(offset, InlineKlass::payload_offset_offset())); 5682 } 5683 5684 void MacroAssembler::payload_address(Register oop, Register data, Register inline_klass) { 5685 // ((address) (void*) o) + vk->payload_offset(); 5686 Register offset = (data == oop) ? rscratch1 : data; 5687 payload_offset(inline_klass, offset); 5688 if (data == oop) { 5689 add(data, data, offset); 5690 } else { 5691 lea(data, Address(oop, offset)); 5692 } 5693 } 5694 5695 void MacroAssembler::load_heap_oop(Register dst, Address src, Register tmp1, 5696 Register tmp2, DecoratorSet decorators) { 5697 access_load_at(T_OBJECT, IN_HEAP | decorators, dst, src, tmp1, tmp2); 5698 } 5699 5700 void MacroAssembler::load_heap_oop_not_null(Register dst, Address src, Register tmp1, 5701 Register tmp2, DecoratorSet decorators) { 5702 access_load_at(T_OBJECT, IN_HEAP | IS_NOT_NULL | decorators, dst, src, tmp1, tmp2); 5703 } 5704 5705 void MacroAssembler::store_heap_oop(Address dst, Register val, Register tmp1, 5706 Register tmp2, Register tmp3, DecoratorSet decorators) { 5707 access_store_at(T_OBJECT, IN_HEAP | decorators, dst, val, tmp1, tmp2, tmp3); 5708 } 5709 5710 // Used for storing nulls. 5711 void MacroAssembler::store_heap_oop_null(Address dst) { 5712 access_store_at(T_OBJECT, IN_HEAP, dst, noreg, noreg, noreg, noreg); 5713 } 5714 5715 Address MacroAssembler::allocate_metadata_address(Metadata* obj) { 5716 assert(oop_recorder() != nullptr, "this assembler needs a Recorder"); 5717 int index = oop_recorder()->allocate_metadata_index(obj); 5718 RelocationHolder rspec = metadata_Relocation::spec(index); 5719 return Address((address)obj, rspec); 5720 } 5721 5722 // Move an oop into a register. 5723 void MacroAssembler::movoop(Register dst, jobject obj) { 5724 int oop_index; 5725 if (obj == nullptr) { 5726 oop_index = oop_recorder()->allocate_oop_index(obj); 5727 } else { 5728 #ifdef ASSERT 5729 { 5730 ThreadInVMfromUnknown tiv; 5731 assert(Universe::heap()->is_in(JNIHandles::resolve(obj)), "should be real oop"); 5732 } 5733 #endif 5734 oop_index = oop_recorder()->find_index(obj); 5735 } 5736 RelocationHolder rspec = oop_Relocation::spec(oop_index); 5737 5738 if (BarrierSet::barrier_set()->barrier_set_assembler()->supports_instruction_patching()) { 5739 mov(dst, Address((address)obj, rspec)); 5740 } else { 5741 address dummy = address(uintptr_t(pc()) & -wordSize); // A nearby aligned address 5742 ldr(dst, Address(dummy, rspec)); 5743 } 5744 } 5745 5746 // Move a metadata address into a register. 5747 void MacroAssembler::mov_metadata(Register dst, Metadata* obj) { 5748 int oop_index; 5749 if (obj == nullptr) { 5750 oop_index = oop_recorder()->allocate_metadata_index(obj); 5751 } else { 5752 oop_index = oop_recorder()->find_index(obj); 5753 } 5754 RelocationHolder rspec = metadata_Relocation::spec(oop_index); 5755 mov(dst, Address((address)obj, rspec)); 5756 } 5757 5758 Address MacroAssembler::constant_oop_address(jobject obj) { 5759 #ifdef ASSERT 5760 { 5761 ThreadInVMfromUnknown tiv; 5762 assert(oop_recorder() != nullptr, "this assembler needs an OopRecorder"); 5763 assert(Universe::heap()->is_in(JNIHandles::resolve(obj)), "not an oop"); 5764 } 5765 #endif 5766 int oop_index = oop_recorder()->find_index(obj); 5767 return Address((address)obj, oop_Relocation::spec(oop_index)); 5768 } 5769 5770 // Defines obj, preserves var_size_in_bytes, okay for t2 == var_size_in_bytes. 5771 void MacroAssembler::tlab_allocate(Register obj, 5772 Register var_size_in_bytes, 5773 int con_size_in_bytes, 5774 Register t1, 5775 Register t2, 5776 Label& slow_case) { 5777 BarrierSetAssembler *bs = BarrierSet::barrier_set()->barrier_set_assembler(); 5778 bs->tlab_allocate(this, obj, var_size_in_bytes, con_size_in_bytes, t1, t2, slow_case); 5779 } 5780 5781 void MacroAssembler::verify_tlab() { 5782 #ifdef ASSERT 5783 if (UseTLAB && VerifyOops) { 5784 Label next, ok; 5785 5786 stp(rscratch2, rscratch1, Address(pre(sp, -16))); 5787 5788 ldr(rscratch2, Address(rthread, in_bytes(JavaThread::tlab_top_offset()))); 5789 ldr(rscratch1, Address(rthread, in_bytes(JavaThread::tlab_start_offset()))); 5790 cmp(rscratch2, rscratch1); 5791 br(Assembler::HS, next); 5792 STOP("assert(top >= start)"); 5793 should_not_reach_here(); 5794 5795 bind(next); 5796 ldr(rscratch2, Address(rthread, in_bytes(JavaThread::tlab_end_offset()))); 5797 ldr(rscratch1, Address(rthread, in_bytes(JavaThread::tlab_top_offset()))); 5798 cmp(rscratch2, rscratch1); 5799 br(Assembler::HS, ok); 5800 STOP("assert(top <= end)"); 5801 should_not_reach_here(); 5802 5803 bind(ok); 5804 ldp(rscratch2, rscratch1, Address(post(sp, 16))); 5805 } 5806 #endif 5807 } 5808 5809 void MacroAssembler::inline_layout_info(Register holder_klass, Register index, Register layout_info) { 5810 assert_different_registers(holder_klass, index, layout_info); 5811 InlineLayoutInfo array[2]; 5812 int size = (char*)&array[1] - (char*)&array[0]; // computing size of array elements 5813 if (is_power_of_2(size)) { 5814 lsl(index, index, log2i_exact(size)); // Scale index by power of 2 5815 } else { 5816 mov(layout_info, size); 5817 mul(index, index, layout_info); // Scale the index to be the entry index * array_element_size 5818 } 5819 ldr(layout_info, Address(holder_klass, InstanceKlass::inline_layout_info_array_offset())); 5820 add(layout_info, layout_info, Array<InlineLayoutInfo>::base_offset_in_bytes()); 5821 lea(layout_info, Address(layout_info, index)); 5822 } 5823 5824 // Writes to stack successive pages until offset reached to check for 5825 // stack overflow + shadow pages. This clobbers tmp. 5826 void MacroAssembler::bang_stack_size(Register size, Register tmp) { 5827 assert_different_registers(tmp, size, rscratch1); 5828 mov(tmp, sp); 5829 // Bang stack for total size given plus shadow page size. 5830 // Bang one page at a time because large size can bang beyond yellow and 5831 // red zones. 5832 Label loop; 5833 mov(rscratch1, (int)os::vm_page_size()); 5834 bind(loop); 5835 lea(tmp, Address(tmp, -(int)os::vm_page_size())); 5836 subsw(size, size, rscratch1); 5837 str(size, Address(tmp)); 5838 br(Assembler::GT, loop); 5839 5840 // Bang down shadow pages too. 5841 // At this point, (tmp-0) is the last address touched, so don't 5842 // touch it again. (It was touched as (tmp-pagesize) but then tmp 5843 // was post-decremented.) Skip this address by starting at i=1, and 5844 // touch a few more pages below. N.B. It is important to touch all 5845 // the way down to and including i=StackShadowPages. 5846 for (int i = 0; i < (int)(StackOverflow::stack_shadow_zone_size() / (int)os::vm_page_size()) - 1; i++) { 5847 // this could be any sized move but this is can be a debugging crumb 5848 // so the bigger the better. 5849 lea(tmp, Address(tmp, -(int)os::vm_page_size())); 5850 str(size, Address(tmp)); 5851 } 5852 } 5853 5854 // Move the address of the polling page into dest. 5855 void MacroAssembler::get_polling_page(Register dest, relocInfo::relocType rtype) { 5856 ldr(dest, Address(rthread, JavaThread::polling_page_offset())); 5857 } 5858 5859 // Read the polling page. The address of the polling page must 5860 // already be in r. 5861 address MacroAssembler::read_polling_page(Register r, relocInfo::relocType rtype) { 5862 address mark; 5863 { 5864 InstructionMark im(this); 5865 code_section()->relocate(inst_mark(), rtype); 5866 ldrw(zr, Address(r, 0)); 5867 mark = inst_mark(); 5868 } 5869 verify_cross_modify_fence_not_required(); 5870 return mark; 5871 } 5872 5873 void MacroAssembler::adrp(Register reg1, const Address &dest, uint64_t &byte_offset) { 5874 uint64_t low_page = (uint64_t)CodeCache::low_bound() >> 12; 5875 uint64_t high_page = (uint64_t)(CodeCache::high_bound()-1) >> 12; 5876 uint64_t dest_page = (uint64_t)dest.target() >> 12; 5877 int64_t offset_low = dest_page - low_page; 5878 int64_t offset_high = dest_page - high_page; 5879 5880 assert(is_valid_AArch64_address(dest.target()), "bad address"); 5881 assert(dest.getMode() == Address::literal, "ADRP must be applied to a literal address"); 5882 5883 InstructionMark im(this); 5884 code_section()->relocate(inst_mark(), dest.rspec()); 5885 // 8143067: Ensure that the adrp can reach the dest from anywhere within 5886 // the code cache so that if it is relocated we know it will still reach 5887 if (offset_high >= -(1<<20) && offset_low < (1<<20)) { 5888 _adrp(reg1, dest.target()); 5889 } else { 5890 uint64_t target = (uint64_t)dest.target(); 5891 uint64_t adrp_target 5892 = (target & 0xffffffffULL) | ((uint64_t)pc() & 0xffff00000000ULL); 5893 5894 _adrp(reg1, (address)adrp_target); 5895 movk(reg1, target >> 32, 32); 5896 } 5897 byte_offset = (uint64_t)dest.target() & 0xfff; 5898 } 5899 5900 void MacroAssembler::load_byte_map_base(Register reg) { 5901 #if INCLUDE_CDS 5902 if (AOTCodeCache::is_on_for_dump()) { 5903 address byte_map_base_adr = AOTRuntimeConstants::card_table_base_address(); 5904 lea(reg, ExternalAddress(byte_map_base_adr)); 5905 ldr(reg, Address(reg)); 5906 return; 5907 } 5908 #endif 5909 CardTableBarrierSet* ctbs = CardTableBarrierSet::barrier_set(); 5910 5911 // Strictly speaking the card table base isn't an address at all, and it might 5912 // even be negative. It is thus materialised as a constant. 5913 mov(reg, (uint64_t)ctbs->card_table_base_const()); 5914 } 5915 5916 void MacroAssembler::load_aotrc_address(Register reg, address a) { 5917 #if INCLUDE_CDS 5918 assert(AOTRuntimeConstants::contains(a), "address out of range for data area"); 5919 if (AOTCodeCache::is_on_for_dump()) { 5920 // all aotrc field addresses should be registered in the AOTCodeCache address table 5921 lea(reg, ExternalAddress(a)); 5922 } else { 5923 mov(reg, (uint64_t)a); 5924 } 5925 #else 5926 ShouldNotReachHere(); 5927 #endif 5928 } 5929 5930 #ifdef ASSERT 5931 void MacroAssembler::build_frame(int framesize) { 5932 build_frame(framesize, false); 5933 } 5934 #endif 5935 5936 void MacroAssembler::build_frame(int framesize DEBUG_ONLY(COMMA bool zap_rfp_lr_spills)) { 5937 assert(framesize >= 2 * wordSize, "framesize must include space for FP/LR"); 5938 assert(framesize % (2*wordSize) == 0, "must preserve 2*wordSize alignment"); 5939 protect_return_address(); 5940 if (framesize < ((1 << 9) + 2 * wordSize)) { 5941 sub(sp, sp, framesize); 5942 if (DEBUG_ONLY(zap_rfp_lr_spills ||) false) { 5943 mov_immediate64(rscratch1, ((uint64_t)badRegWordVal) << 32 | (uint64_t)badRegWordVal); 5944 stp(rscratch1, rscratch1, Address(sp, framesize - 2 * wordSize)); 5945 } else { 5946 stp(rfp, lr, Address(sp, framesize - 2 * wordSize)); 5947 } 5948 if (PreserveFramePointer) add(rfp, sp, framesize - 2 * wordSize); 5949 } else { 5950 if (DEBUG_ONLY(zap_rfp_lr_spills ||) false) { 5951 mov_immediate64(rscratch1, ((uint64_t)badRegWordVal) << 32 | (uint64_t)badRegWordVal); 5952 stp(rscratch1, rscratch1, Address(pre(sp, -2 * wordSize))); 5953 } else { 5954 stp(rfp, lr, Address(pre(sp, -2 * wordSize))); 5955 } 5956 if (PreserveFramePointer) mov(rfp, sp); 5957 if (framesize < ((1 << 12) + 2 * wordSize)) 5958 sub(sp, sp, framesize - 2 * wordSize); 5959 else { 5960 mov(rscratch1, framesize - 2 * wordSize); 5961 sub(sp, sp, rscratch1); 5962 } 5963 } 5964 verify_cross_modify_fence_not_required(); 5965 } 5966 5967 void MacroAssembler::remove_frame(int framesize) { 5968 assert(framesize >= 2 * wordSize, "framesize must include space for FP/LR"); 5969 assert(framesize % (2*wordSize) == 0, "must preserve 2*wordSize alignment"); 5970 if (framesize < ((1 << 9) + 2 * wordSize)) { 5971 ldp(rfp, lr, Address(sp, framesize - 2 * wordSize)); 5972 add(sp, sp, framesize); 5973 } else { 5974 if (framesize < ((1 << 12) + 2 * wordSize)) 5975 add(sp, sp, framesize - 2 * wordSize); 5976 else { 5977 mov(rscratch1, framesize - 2 * wordSize); 5978 add(sp, sp, rscratch1); 5979 } 5980 ldp(rfp, lr, Address(post(sp, 2 * wordSize))); 5981 } 5982 authenticate_return_address(); 5983 } 5984 5985 void MacroAssembler::remove_frame(int initial_framesize, bool needs_stack_repair) { 5986 if (needs_stack_repair) { 5987 // The method has a scalarized entry point (where fields of value object arguments 5988 // are passed through registers and stack), and a non-scalarized entry point (where 5989 // value object arguments are given as oops). The non-scalarized entry point will 5990 // first load each field of value object arguments and store them in registers and on 5991 // the stack in a way compatible with the scalarized entry point. To do so, some extra 5992 // stack space might be reserved (if argument registers are not enough). On leaving the 5993 // method, this space must be freed. 5994 // 5995 // In case we used the non-scalarized entry point the stack looks like this: 5996 // 5997 // | Arguments from caller | 5998 // |---------------------------| <-- caller's SP 5999 // | Saved LR #1 | 6000 // | Saved FP #1 | 6001 // |---------------------------| 6002 // | Extension space for | 6003 // | inline arg (un)packing | 6004 // |---------------------------| <-- start of this method's frame 6005 // | Saved LR #2 | 6006 // | Saved FP #2 | 6007 // |---------------------------| <-- FP (with -XX:+PreserveFramePointer) 6008 // | sp_inc | 6009 // | method locals | 6010 // |---------------------------| <-- SP 6011 // 6012 // There are two copies of FP and LR on the stack. They will be identical at 6013 // first, but that can change. 6014 // If the caller has been deoptimized, LR #1 will be patched to point at the 6015 // deopt blob, and LR #2 will still point into the old method. 6016 // If the saved FP (x29) was not used as the frame pointer, but to store an 6017 // oop, the GC will be aware only of FP #1 as the spilled location of x29 and 6018 // will fix only this one. Overall, FP/LR #2 are not reliable and are simply 6019 // needed to add space between the extension space and the locals, as there 6020 // would be between the real arguments and the locals if we don't need to 6021 // do unpacking (from the scalarized entry point). 6022 // 6023 // When restoring, one must then load FP #1 into x29, and LR #1 into x30, 6024 // while keeping in mind that from the scalarized entry point, there will be 6025 // only one copy of each. Indeed, in the case we used the scalarized calling 6026 // convention, the stack looks like this: 6027 // 6028 // | Arguments from caller | 6029 // |---------------------------| <-- caller's SP / start of this method's frame 6030 // | Saved LR | 6031 // | Saved FP | 6032 // |---------------------------| <-- FP (with -XX:+PreserveFramePointer) 6033 // | sp_inc | 6034 // | method locals | 6035 // |---------------------------| <-- SP 6036 // 6037 // The sp_inc stack slot holds the total size of the frame including the 6038 // extension space minus two words for the saved FP and LR. That is how to 6039 // find FP/LR #1. This size is expressed in bytes. Be careful when using it 6040 // from C++ in pointer arithmetic; you might need to divide it by wordSize. 6041 // 6042 // One can find sp_inc since the start the method's frame is SP + initial_framesize. 6043 6044 int sp_inc_offset = initial_framesize - 3 * wordSize; // Immediately below saved LR and FP 6045 6046 ldr(rscratch1, Address(sp, sp_inc_offset)); 6047 add(sp, sp, rscratch1); 6048 ldp(rfp, lr, Address(post(sp, 2 * wordSize))); 6049 } else { 6050 remove_frame(initial_framesize); 6051 } 6052 } 6053 6054 void MacroAssembler::save_stack_increment(int sp_inc, int frame_size) { 6055 int real_frame_size = frame_size + sp_inc; 6056 assert(sp_inc == 0 || sp_inc > 2*wordSize, "invalid sp_inc value"); 6057 assert(real_frame_size >= 2*wordSize, "frame size must include FP/LR space"); 6058 assert((real_frame_size & (StackAlignmentInBytes-1)) == 0, "frame size not aligned"); 6059 6060 int sp_inc_offset = frame_size - 3 * wordSize; // Immediately below saved LR and FP 6061 6062 // Subtract two words for the saved FP and LR as these will be popped 6063 // separately. See remove_frame above. 6064 mov(rscratch1, real_frame_size - 2*wordSize); 6065 str(rscratch1, Address(sp, sp_inc_offset)); 6066 } 6067 6068 // This method counts leading positive bytes (highest bit not set) in provided byte array 6069 address MacroAssembler::count_positives(Register ary1, Register len, Register result) { 6070 // Simple and most common case of aligned small array which is not at the 6071 // end of memory page is placed here. All other cases are in stub. 6072 Label LOOP, END, STUB, STUB_LONG, SET_RESULT, DONE; 6073 const uint64_t UPPER_BIT_MASK=0x8080808080808080; 6074 assert_different_registers(ary1, len, result); 6075 6076 mov(result, len); 6077 cmpw(len, 0); 6078 br(LE, DONE); 6079 cmpw(len, 4 * wordSize); 6080 br(GE, STUB_LONG); // size > 32 then go to stub 6081 6082 int shift = 64 - exact_log2(os::vm_page_size()); 6083 lsl(rscratch1, ary1, shift); 6084 mov(rscratch2, (size_t)(4 * wordSize) << shift); 6085 adds(rscratch2, rscratch1, rscratch2); // At end of page? 6086 br(CS, STUB); // at the end of page then go to stub 6087 subs(len, len, wordSize); 6088 br(LT, END); 6089 6090 BIND(LOOP); 6091 ldr(rscratch1, Address(post(ary1, wordSize))); 6092 tst(rscratch1, UPPER_BIT_MASK); 6093 br(NE, SET_RESULT); 6094 subs(len, len, wordSize); 6095 br(GE, LOOP); 6096 cmpw(len, -wordSize); 6097 br(EQ, DONE); 6098 6099 BIND(END); 6100 ldr(rscratch1, Address(ary1)); 6101 sub(rscratch2, zr, len, LSL, 3); // LSL 3 is to get bits from bytes 6102 lslv(rscratch1, rscratch1, rscratch2); 6103 tst(rscratch1, UPPER_BIT_MASK); 6104 br(NE, SET_RESULT); 6105 b(DONE); 6106 6107 BIND(STUB); 6108 RuntimeAddress count_pos = RuntimeAddress(StubRoutines::aarch64::count_positives()); 6109 assert(count_pos.target() != nullptr, "count_positives stub has not been generated"); 6110 address tpc1 = trampoline_call(count_pos); 6111 if (tpc1 == nullptr) { 6112 DEBUG_ONLY(reset_labels(STUB_LONG, SET_RESULT, DONE)); 6113 postcond(pc() == badAddress); 6114 return nullptr; 6115 } 6116 b(DONE); 6117 6118 BIND(STUB_LONG); 6119 RuntimeAddress count_pos_long = RuntimeAddress(StubRoutines::aarch64::count_positives_long()); 6120 assert(count_pos_long.target() != nullptr, "count_positives_long stub has not been generated"); 6121 address tpc2 = trampoline_call(count_pos_long); 6122 if (tpc2 == nullptr) { 6123 DEBUG_ONLY(reset_labels(SET_RESULT, DONE)); 6124 postcond(pc() == badAddress); 6125 return nullptr; 6126 } 6127 b(DONE); 6128 6129 BIND(SET_RESULT); 6130 6131 add(len, len, wordSize); 6132 sub(result, result, len); 6133 6134 BIND(DONE); 6135 postcond(pc() != badAddress); 6136 return pc(); 6137 } 6138 6139 // Clobbers: rscratch1, rscratch2, rflags 6140 // May also clobber v0-v7 when (!UseSimpleArrayEquals && UseSIMDForArrayEquals) 6141 address MacroAssembler::arrays_equals(Register a1, Register a2, Register tmp3, 6142 Register tmp4, Register tmp5, Register result, 6143 Register cnt1, int elem_size) { 6144 Label DONE, SAME; 6145 Register tmp1 = rscratch1; 6146 Register tmp2 = rscratch2; 6147 int elem_per_word = wordSize/elem_size; 6148 int log_elem_size = exact_log2(elem_size); 6149 int klass_offset = arrayOopDesc::klass_offset_in_bytes(); 6150 int length_offset = arrayOopDesc::length_offset_in_bytes(); 6151 int base_offset 6152 = arrayOopDesc::base_offset_in_bytes(elem_size == 2 ? T_CHAR : T_BYTE); 6153 // When the length offset is not aligned to 8 bytes, 6154 // then we align it down. This is valid because the new 6155 // offset will always be the klass which is the same 6156 // for type arrays. 6157 int start_offset = align_down(length_offset, BytesPerWord); 6158 int extra_length = base_offset - start_offset; 6159 assert(start_offset == length_offset || start_offset == klass_offset, 6160 "start offset must be 8-byte-aligned or be the klass offset"); 6161 assert(base_offset != start_offset, "must include the length field"); 6162 extra_length = extra_length / elem_size; // We count in elements, not bytes. 6163 int stubBytesThreshold = 3 * 64 + (UseSIMDForArrayEquals ? 0 : 16); 6164 6165 assert(elem_size == 1 || elem_size == 2, "must be char or byte"); 6166 assert_different_registers(a1, a2, result, cnt1, rscratch1, rscratch2); 6167 6168 #ifndef PRODUCT 6169 { 6170 const char kind = (elem_size == 2) ? 'U' : 'L'; 6171 char comment[64]; 6172 os::snprintf_checked(comment, sizeof comment, "array_equals%c{", kind); 6173 BLOCK_COMMENT(comment); 6174 } 6175 #endif 6176 6177 // if (a1 == a2) 6178 // return true; 6179 cmpoop(a1, a2); // May have read barriers for a1 and a2. 6180 br(EQ, SAME); 6181 6182 if (UseSimpleArrayEquals) { 6183 Label NEXT_WORD, SHORT, TAIL03, TAIL01, A_MIGHT_BE_NULL, A_IS_NOT_NULL; 6184 // if (a1 == nullptr || a2 == nullptr) 6185 // return false; 6186 // a1 & a2 == 0 means (some-pointer is null) or 6187 // (very-rare-or-even-probably-impossible-pointer-values) 6188 // so, we can save one branch in most cases 6189 tst(a1, a2); 6190 mov(result, false); 6191 br(EQ, A_MIGHT_BE_NULL); 6192 // if (a1.length != a2.length) 6193 // return false; 6194 bind(A_IS_NOT_NULL); 6195 ldrw(cnt1, Address(a1, length_offset)); 6196 ldrw(tmp5, Address(a2, length_offset)); 6197 cmp(cnt1, tmp5); 6198 br(NE, DONE); // If lengths differ, return false 6199 // Increase loop counter by diff between base- and actual start-offset. 6200 addw(cnt1, cnt1, extra_length); 6201 lea(a1, Address(a1, start_offset)); 6202 lea(a2, Address(a2, start_offset)); 6203 // Check for short strings, i.e. smaller than wordSize. 6204 subs(cnt1, cnt1, elem_per_word); 6205 br(Assembler::LT, SHORT); 6206 // Main 8 byte comparison loop. 6207 bind(NEXT_WORD); { 6208 ldr(tmp1, Address(post(a1, wordSize))); 6209 ldr(tmp2, Address(post(a2, wordSize))); 6210 subs(cnt1, cnt1, elem_per_word); 6211 eor(tmp5, tmp1, tmp2); 6212 cbnz(tmp5, DONE); 6213 } br(GT, NEXT_WORD); 6214 // Last longword. In the case where length == 4 we compare the 6215 // same longword twice, but that's still faster than another 6216 // conditional branch. 6217 // cnt1 could be 0, -1, -2, -3, -4 for chars; -4 only happens when 6218 // length == 4. 6219 if (log_elem_size > 0) 6220 lsl(cnt1, cnt1, log_elem_size); 6221 ldr(tmp3, Address(a1, cnt1)); 6222 ldr(tmp4, Address(a2, cnt1)); 6223 eor(tmp5, tmp3, tmp4); 6224 cbnz(tmp5, DONE); 6225 b(SAME); 6226 bind(A_MIGHT_BE_NULL); 6227 // in case both a1 and a2 are not-null, proceed with loads 6228 cbz(a1, DONE); 6229 cbz(a2, DONE); 6230 b(A_IS_NOT_NULL); 6231 bind(SHORT); 6232 6233 tbz(cnt1, 2 - log_elem_size, TAIL03); // 0-7 bytes left. 6234 { 6235 ldrw(tmp1, Address(post(a1, 4))); 6236 ldrw(tmp2, Address(post(a2, 4))); 6237 eorw(tmp5, tmp1, tmp2); 6238 cbnzw(tmp5, DONE); 6239 } 6240 bind(TAIL03); 6241 tbz(cnt1, 1 - log_elem_size, TAIL01); // 0-3 bytes left. 6242 { 6243 ldrh(tmp3, Address(post(a1, 2))); 6244 ldrh(tmp4, Address(post(a2, 2))); 6245 eorw(tmp5, tmp3, tmp4); 6246 cbnzw(tmp5, DONE); 6247 } 6248 bind(TAIL01); 6249 if (elem_size == 1) { // Only needed when comparing byte arrays. 6250 tbz(cnt1, 0, SAME); // 0-1 bytes left. 6251 { 6252 ldrb(tmp1, a1); 6253 ldrb(tmp2, a2); 6254 eorw(tmp5, tmp1, tmp2); 6255 cbnzw(tmp5, DONE); 6256 } 6257 } 6258 } else { 6259 Label NEXT_DWORD, SHORT, TAIL, TAIL2, STUB, 6260 CSET_EQ, LAST_CHECK; 6261 mov(result, false); 6262 cbz(a1, DONE); 6263 ldrw(cnt1, Address(a1, length_offset)); 6264 cbz(a2, DONE); 6265 ldrw(tmp5, Address(a2, length_offset)); 6266 cmp(cnt1, tmp5); 6267 br(NE, DONE); // If lengths differ, return false 6268 // Increase loop counter by diff between base- and actual start-offset. 6269 addw(cnt1, cnt1, extra_length); 6270 6271 // on most CPUs a2 is still "locked"(surprisingly) in ldrw and it's 6272 // faster to perform another branch before comparing a1 and a2 6273 cmp(cnt1, (u1)elem_per_word); 6274 br(LE, SHORT); // short or same 6275 ldr(tmp3, Address(pre(a1, start_offset))); 6276 subs(zr, cnt1, stubBytesThreshold); 6277 br(GE, STUB); 6278 ldr(tmp4, Address(pre(a2, start_offset))); 6279 sub(tmp5, zr, cnt1, LSL, 3 + log_elem_size); 6280 6281 // Main 16 byte comparison loop with 2 exits 6282 bind(NEXT_DWORD); { 6283 ldr(tmp1, Address(pre(a1, wordSize))); 6284 ldr(tmp2, Address(pre(a2, wordSize))); 6285 subs(cnt1, cnt1, 2 * elem_per_word); 6286 br(LE, TAIL); 6287 eor(tmp4, tmp3, tmp4); 6288 cbnz(tmp4, DONE); 6289 ldr(tmp3, Address(pre(a1, wordSize))); 6290 ldr(tmp4, Address(pre(a2, wordSize))); 6291 cmp(cnt1, (u1)elem_per_word); 6292 br(LE, TAIL2); 6293 cmp(tmp1, tmp2); 6294 } br(EQ, NEXT_DWORD); 6295 b(DONE); 6296 6297 bind(TAIL); 6298 eor(tmp4, tmp3, tmp4); 6299 eor(tmp2, tmp1, tmp2); 6300 lslv(tmp2, tmp2, tmp5); 6301 orr(tmp5, tmp4, tmp2); 6302 cmp(tmp5, zr); 6303 b(CSET_EQ); 6304 6305 bind(TAIL2); 6306 eor(tmp2, tmp1, tmp2); 6307 cbnz(tmp2, DONE); 6308 b(LAST_CHECK); 6309 6310 bind(STUB); 6311 ldr(tmp4, Address(pre(a2, start_offset))); 6312 if (elem_size == 2) { // convert to byte counter 6313 lsl(cnt1, cnt1, 1); 6314 } 6315 eor(tmp5, tmp3, tmp4); 6316 cbnz(tmp5, DONE); 6317 RuntimeAddress stub = RuntimeAddress(StubRoutines::aarch64::large_array_equals()); 6318 assert(stub.target() != nullptr, "array_equals_long stub has not been generated"); 6319 address tpc = trampoline_call(stub); 6320 if (tpc == nullptr) { 6321 DEBUG_ONLY(reset_labels(SHORT, LAST_CHECK, CSET_EQ, SAME, DONE)); 6322 postcond(pc() == badAddress); 6323 return nullptr; 6324 } 6325 b(DONE); 6326 6327 // (a1 != null && a2 == null) || (a1 != null && a2 != null && a1 == a2) 6328 // so, if a2 == null => return false(0), else return true, so we can return a2 6329 mov(result, a2); 6330 b(DONE); 6331 bind(SHORT); 6332 sub(tmp5, zr, cnt1, LSL, 3 + log_elem_size); 6333 ldr(tmp3, Address(a1, start_offset)); 6334 ldr(tmp4, Address(a2, start_offset)); 6335 bind(LAST_CHECK); 6336 eor(tmp4, tmp3, tmp4); 6337 lslv(tmp5, tmp4, tmp5); 6338 cmp(tmp5, zr); 6339 bind(CSET_EQ); 6340 cset(result, EQ); 6341 b(DONE); 6342 } 6343 6344 bind(SAME); 6345 mov(result, true); 6346 // That's it. 6347 bind(DONE); 6348 6349 BLOCK_COMMENT("} array_equals"); 6350 postcond(pc() != badAddress); 6351 return pc(); 6352 } 6353 6354 // Compare Strings 6355 6356 // For Strings we're passed the address of the first characters in a1 6357 // and a2 and the length in cnt1. 6358 // There are two implementations. For arrays >= 8 bytes, all 6359 // comparisons (including the final one, which may overlap) are 6360 // performed 8 bytes at a time. For strings < 8 bytes, we compare a 6361 // halfword, then a short, and then a byte. 6362 6363 void MacroAssembler::string_equals(Register a1, Register a2, 6364 Register result, Register cnt1) 6365 { 6366 Label SAME, DONE, SHORT, NEXT_WORD; 6367 Register tmp1 = rscratch1; 6368 Register tmp2 = rscratch2; 6369 6370 assert_different_registers(a1, a2, result, cnt1, rscratch1, rscratch2); 6371 6372 #ifndef PRODUCT 6373 { 6374 char comment[64]; 6375 os::snprintf_checked(comment, sizeof comment, "{string_equalsL"); 6376 BLOCK_COMMENT(comment); 6377 } 6378 #endif 6379 6380 mov(result, false); 6381 6382 // Check for short strings, i.e. smaller than wordSize. 6383 subs(cnt1, cnt1, wordSize); 6384 br(Assembler::LT, SHORT); 6385 // Main 8 byte comparison loop. 6386 bind(NEXT_WORD); { 6387 ldr(tmp1, Address(post(a1, wordSize))); 6388 ldr(tmp2, Address(post(a2, wordSize))); 6389 subs(cnt1, cnt1, wordSize); 6390 eor(tmp1, tmp1, tmp2); 6391 cbnz(tmp1, DONE); 6392 } br(GT, NEXT_WORD); 6393 // Last longword. In the case where length == 4 we compare the 6394 // same longword twice, but that's still faster than another 6395 // conditional branch. 6396 // cnt1 could be 0, -1, -2, -3, -4 for chars; -4 only happens when 6397 // length == 4. 6398 ldr(tmp1, Address(a1, cnt1)); 6399 ldr(tmp2, Address(a2, cnt1)); 6400 eor(tmp2, tmp1, tmp2); 6401 cbnz(tmp2, DONE); 6402 b(SAME); 6403 6404 bind(SHORT); 6405 Label TAIL03, TAIL01; 6406 6407 tbz(cnt1, 2, TAIL03); // 0-7 bytes left. 6408 { 6409 ldrw(tmp1, Address(post(a1, 4))); 6410 ldrw(tmp2, Address(post(a2, 4))); 6411 eorw(tmp1, tmp1, tmp2); 6412 cbnzw(tmp1, DONE); 6413 } 6414 bind(TAIL03); 6415 tbz(cnt1, 1, TAIL01); // 0-3 bytes left. 6416 { 6417 ldrh(tmp1, Address(post(a1, 2))); 6418 ldrh(tmp2, Address(post(a2, 2))); 6419 eorw(tmp1, tmp1, tmp2); 6420 cbnzw(tmp1, DONE); 6421 } 6422 bind(TAIL01); 6423 tbz(cnt1, 0, SAME); // 0-1 bytes left. 6424 { 6425 ldrb(tmp1, a1); 6426 ldrb(tmp2, a2); 6427 eorw(tmp1, tmp1, tmp2); 6428 cbnzw(tmp1, DONE); 6429 } 6430 // Arrays are equal. 6431 bind(SAME); 6432 mov(result, true); 6433 6434 // That's it. 6435 bind(DONE); 6436 BLOCK_COMMENT("} string_equals"); 6437 } 6438 6439 6440 // The size of the blocks erased by the zero_blocks stub. We must 6441 // handle anything smaller than this ourselves in zero_words(). 6442 const int MacroAssembler::zero_words_block_size = 8; 6443 6444 // zero_words() is used by C2 ClearArray patterns and by 6445 // C1_MacroAssembler. It is as small as possible, handling small word 6446 // counts locally and delegating anything larger to the zero_blocks 6447 // stub. It is expanded many times in compiled code, so it is 6448 // important to keep it short. 6449 6450 // ptr: Address of a buffer to be zeroed. 6451 // cnt: Count in HeapWords. 6452 // 6453 // ptr, cnt, rscratch1, and rscratch2 are clobbered. 6454 address MacroAssembler::zero_words(Register ptr, Register cnt) 6455 { 6456 assert(is_power_of_2(zero_words_block_size), "adjust this"); 6457 6458 BLOCK_COMMENT("zero_words {"); 6459 assert(ptr == r10 && cnt == r11, "mismatch in register usage"); 6460 RuntimeAddress zero_blocks = RuntimeAddress(StubRoutines::aarch64::zero_blocks()); 6461 assert(zero_blocks.target() != nullptr, "zero_blocks stub has not been generated"); 6462 6463 subs(rscratch1, cnt, zero_words_block_size); 6464 Label around; 6465 br(LO, around); 6466 { 6467 RuntimeAddress zero_blocks = RuntimeAddress(StubRoutines::aarch64::zero_blocks()); 6468 assert(zero_blocks.target() != nullptr, "zero_blocks stub has not been generated"); 6469 // Make sure this is a C2 compilation. C1 allocates space only for 6470 // trampoline stubs generated by Call LIR ops, and in any case it 6471 // makes sense for a C1 compilation task to proceed as quickly as 6472 // possible. 6473 CompileTask* task; 6474 if (StubRoutines::aarch64::complete() 6475 && Thread::current()->is_Compiler_thread() 6476 && (task = ciEnv::current()->task()) 6477 && is_c2_compile(task->comp_level())) { 6478 address tpc = trampoline_call(zero_blocks); 6479 if (tpc == nullptr) { 6480 DEBUG_ONLY(reset_labels(around)); 6481 return nullptr; 6482 } 6483 } else { 6484 far_call(zero_blocks); 6485 } 6486 } 6487 bind(around); 6488 6489 // We have a few words left to do. zero_blocks has adjusted r10 and r11 6490 // for us. 6491 for (int i = zero_words_block_size >> 1; i > 1; i >>= 1) { 6492 Label l; 6493 tbz(cnt, exact_log2(i), l); 6494 for (int j = 0; j < i; j += 2) { 6495 stp(zr, zr, post(ptr, 2 * BytesPerWord)); 6496 } 6497 bind(l); 6498 } 6499 { 6500 Label l; 6501 tbz(cnt, 0, l); 6502 str(zr, Address(ptr)); 6503 bind(l); 6504 } 6505 6506 BLOCK_COMMENT("} zero_words"); 6507 return pc(); 6508 } 6509 6510 // base: Address of a buffer to be zeroed, 8 bytes aligned. 6511 // cnt: Immediate count in HeapWords. 6512 // 6513 // r10, r11, rscratch1, and rscratch2 are clobbered. 6514 address MacroAssembler::zero_words(Register base, uint64_t cnt) 6515 { 6516 assert(wordSize <= BlockZeroingLowLimit, 6517 "increase BlockZeroingLowLimit"); 6518 address result = nullptr; 6519 if (cnt <= (uint64_t)BlockZeroingLowLimit / BytesPerWord) { 6520 #ifndef PRODUCT 6521 { 6522 char buf[64]; 6523 os::snprintf_checked(buf, sizeof buf, "zero_words (count = %" PRIu64 ") {", cnt); 6524 BLOCK_COMMENT(buf); 6525 } 6526 #endif 6527 if (cnt >= 16) { 6528 uint64_t loops = cnt/16; 6529 if (loops > 1) { 6530 mov(rscratch2, loops - 1); 6531 } 6532 { 6533 Label loop; 6534 bind(loop); 6535 for (int i = 0; i < 16; i += 2) { 6536 stp(zr, zr, Address(base, i * BytesPerWord)); 6537 } 6538 add(base, base, 16 * BytesPerWord); 6539 if (loops > 1) { 6540 subs(rscratch2, rscratch2, 1); 6541 br(GE, loop); 6542 } 6543 } 6544 } 6545 cnt %= 16; 6546 int i = cnt & 1; // store any odd word to start 6547 if (i) str(zr, Address(base)); 6548 for (; i < (int)cnt; i += 2) { 6549 stp(zr, zr, Address(base, i * wordSize)); 6550 } 6551 BLOCK_COMMENT("} zero_words"); 6552 result = pc(); 6553 } else { 6554 mov(r10, base); mov(r11, cnt); 6555 result = zero_words(r10, r11); 6556 } 6557 return result; 6558 } 6559 6560 // Zero blocks of memory by using DC ZVA. 6561 // 6562 // Aligns the base address first sufficiently for DC ZVA, then uses 6563 // DC ZVA repeatedly for every full block. cnt is the size to be 6564 // zeroed in HeapWords. Returns the count of words left to be zeroed 6565 // in cnt. 6566 // 6567 // NOTE: This is intended to be used in the zero_blocks() stub. If 6568 // you want to use it elsewhere, note that cnt must be >= 2*zva_length. 6569 void MacroAssembler::zero_dcache_blocks(Register base, Register cnt) { 6570 Register tmp = rscratch1; 6571 Register tmp2 = rscratch2; 6572 int zva_length = VM_Version::zva_length(); 6573 Label initial_table_end, loop_zva; 6574 Label fini; 6575 6576 // Base must be 16 byte aligned. If not just return and let caller handle it 6577 tst(base, 0x0f); 6578 br(Assembler::NE, fini); 6579 // Align base with ZVA length. 6580 neg(tmp, base); 6581 andr(tmp, tmp, zva_length - 1); 6582 6583 // tmp: the number of bytes to be filled to align the base with ZVA length. 6584 add(base, base, tmp); 6585 sub(cnt, cnt, tmp, Assembler::ASR, 3); 6586 adr(tmp2, initial_table_end); 6587 sub(tmp2, tmp2, tmp, Assembler::LSR, 2); 6588 br(tmp2); 6589 6590 for (int i = -zva_length + 16; i < 0; i += 16) 6591 stp(zr, zr, Address(base, i)); 6592 bind(initial_table_end); 6593 6594 sub(cnt, cnt, zva_length >> 3); 6595 bind(loop_zva); 6596 dc(Assembler::ZVA, base); 6597 subs(cnt, cnt, zva_length >> 3); 6598 add(base, base, zva_length); 6599 br(Assembler::GE, loop_zva); 6600 add(cnt, cnt, zva_length >> 3); // count not zeroed by DC ZVA 6601 bind(fini); 6602 } 6603 6604 // base: Address of a buffer to be filled, 8 bytes aligned. 6605 // cnt: Count in 8-byte unit. 6606 // value: Value to be filled with. 6607 // base will point to the end of the buffer after filling. 6608 void MacroAssembler::fill_words(Register base, Register cnt, Register value) 6609 { 6610 // Algorithm: 6611 // 6612 // if (cnt == 0) { 6613 // return; 6614 // } 6615 // if ((p & 8) != 0) { 6616 // *p++ = v; 6617 // } 6618 // 6619 // scratch1 = cnt & 14; 6620 // cnt -= scratch1; 6621 // p += scratch1; 6622 // switch (scratch1 / 2) { 6623 // do { 6624 // cnt -= 16; 6625 // p[-16] = v; 6626 // p[-15] = v; 6627 // case 7: 6628 // p[-14] = v; 6629 // p[-13] = v; 6630 // case 6: 6631 // p[-12] = v; 6632 // p[-11] = v; 6633 // // ... 6634 // case 1: 6635 // p[-2] = v; 6636 // p[-1] = v; 6637 // case 0: 6638 // p += 16; 6639 // } while (cnt); 6640 // } 6641 // if ((cnt & 1) == 1) { 6642 // *p++ = v; 6643 // } 6644 6645 assert_different_registers(base, cnt, value, rscratch1, rscratch2); 6646 6647 Label fini, skip, entry, loop; 6648 const int unroll = 8; // Number of stp instructions we'll unroll 6649 6650 cbz(cnt, fini); 6651 tbz(base, 3, skip); 6652 str(value, Address(post(base, 8))); 6653 sub(cnt, cnt, 1); 6654 bind(skip); 6655 6656 andr(rscratch1, cnt, (unroll-1) * 2); 6657 sub(cnt, cnt, rscratch1); 6658 add(base, base, rscratch1, Assembler::LSL, 3); 6659 adr(rscratch2, entry); 6660 sub(rscratch2, rscratch2, rscratch1, Assembler::LSL, 1); 6661 br(rscratch2); 6662 6663 bind(loop); 6664 add(base, base, unroll * 16); 6665 for (int i = -unroll; i < 0; i++) 6666 stp(value, value, Address(base, i * 16)); 6667 bind(entry); 6668 subs(cnt, cnt, unroll * 2); 6669 br(Assembler::GE, loop); 6670 6671 tbz(cnt, 0, fini); 6672 str(value, Address(post(base, 8))); 6673 bind(fini); 6674 } 6675 6676 // Intrinsic for 6677 // 6678 // - sun.nio.cs.ISO_8859_1.Encoder#encodeISOArray0(byte[] sa, int sp, byte[] da, int dp, int len) 6679 // Encodes char[] to byte[] in ISO-8859-1 6680 // 6681 // - java.lang.StringCoding#encodeISOArray0(byte[] sa, int sp, byte[] da, int dp, int len) 6682 // Encodes byte[] (containing UTF-16) to byte[] in ISO-8859-1 6683 // 6684 // - java.lang.StringCoding#encodeAsciiArray0(char[] sa, int sp, byte[] da, int dp, int len) 6685 // Encodes char[] to byte[] in ASCII 6686 // 6687 // This version always returns the number of characters copied, and does not 6688 // clobber the 'len' register. A successful copy will complete with the post- 6689 // condition: 'res' == 'len', while an unsuccessful copy will exit with the 6690 // post-condition: 0 <= 'res' < 'len'. 6691 // 6692 // NOTE: Attempts to use 'ld2' (and 'umaxv' in the ISO part) has proven to 6693 // degrade performance (on Ampere Altra - Neoverse N1), to an extent 6694 // beyond the acceptable, even though the footprint would be smaller. 6695 // Using 'umaxv' in the ASCII-case comes with a small penalty but does 6696 // avoid additional bloat. 6697 // 6698 // Clobbers: src, dst, res, rscratch1, rscratch2, rflags 6699 void MacroAssembler::encode_iso_array(Register src, Register dst, 6700 Register len, Register res, bool ascii, 6701 FloatRegister vtmp0, FloatRegister vtmp1, 6702 FloatRegister vtmp2, FloatRegister vtmp3, 6703 FloatRegister vtmp4, FloatRegister vtmp5) 6704 { 6705 Register cnt = res; 6706 Register max = rscratch1; 6707 Register chk = rscratch2; 6708 6709 prfm(Address(src), PLDL1STRM); 6710 movw(cnt, len); 6711 6712 #define ASCII(insn) do { if (ascii) { insn; } } while (0) 6713 6714 Label LOOP_32, DONE_32, FAIL_32; 6715 6716 BIND(LOOP_32); 6717 { 6718 cmpw(cnt, 32); 6719 br(LT, DONE_32); 6720 ld1(vtmp0, vtmp1, vtmp2, vtmp3, T8H, Address(post(src, 64))); 6721 // Extract lower bytes. 6722 FloatRegister vlo0 = vtmp4; 6723 FloatRegister vlo1 = vtmp5; 6724 uzp1(vlo0, T16B, vtmp0, vtmp1); 6725 uzp1(vlo1, T16B, vtmp2, vtmp3); 6726 // Merge bits... 6727 orr(vtmp0, T16B, vtmp0, vtmp1); 6728 orr(vtmp2, T16B, vtmp2, vtmp3); 6729 // Extract merged upper bytes. 6730 FloatRegister vhix = vtmp0; 6731 uzp2(vhix, T16B, vtmp0, vtmp2); 6732 // ISO-check on hi-parts (all zero). 6733 // ASCII-check on lo-parts (no sign). 6734 FloatRegister vlox = vtmp1; // Merge lower bytes. 6735 ASCII(orr(vlox, T16B, vlo0, vlo1)); 6736 umov(chk, vhix, D, 1); ASCII(cm(LT, vlox, T16B, vlox)); 6737 fmovd(max, vhix); ASCII(umaxv(vlox, T16B, vlox)); 6738 orr(chk, chk, max); ASCII(umov(max, vlox, B, 0)); 6739 ASCII(orr(chk, chk, max)); 6740 cbnz(chk, FAIL_32); 6741 subw(cnt, cnt, 32); 6742 st1(vlo0, vlo1, T16B, Address(post(dst, 32))); 6743 b(LOOP_32); 6744 } 6745 BIND(FAIL_32); 6746 sub(src, src, 64); 6747 BIND(DONE_32); 6748 6749 Label LOOP_8, SKIP_8; 6750 6751 BIND(LOOP_8); 6752 { 6753 cmpw(cnt, 8); 6754 br(LT, SKIP_8); 6755 FloatRegister vhi = vtmp0; 6756 FloatRegister vlo = vtmp1; 6757 ld1(vtmp3, T8H, src); 6758 uzp1(vlo, T16B, vtmp3, vtmp3); 6759 uzp2(vhi, T16B, vtmp3, vtmp3); 6760 // ISO-check on hi-parts (all zero). 6761 // ASCII-check on lo-parts (no sign). 6762 ASCII(cm(LT, vtmp2, T16B, vlo)); 6763 fmovd(chk, vhi); ASCII(umaxv(vtmp2, T16B, vtmp2)); 6764 ASCII(umov(max, vtmp2, B, 0)); 6765 ASCII(orr(chk, chk, max)); 6766 cbnz(chk, SKIP_8); 6767 6768 strd(vlo, Address(post(dst, 8))); 6769 subw(cnt, cnt, 8); 6770 add(src, src, 16); 6771 b(LOOP_8); 6772 } 6773 BIND(SKIP_8); 6774 6775 #undef ASCII 6776 6777 Label LOOP, DONE; 6778 6779 cbz(cnt, DONE); 6780 BIND(LOOP); 6781 { 6782 Register chr = rscratch1; 6783 ldrh(chr, Address(post(src, 2))); 6784 tst(chr, ascii ? 0xff80 : 0xff00); 6785 br(NE, DONE); 6786 strb(chr, Address(post(dst, 1))); 6787 subs(cnt, cnt, 1); 6788 br(GT, LOOP); 6789 } 6790 BIND(DONE); 6791 // Return index where we stopped. 6792 subw(res, len, cnt); 6793 } 6794 6795 // Inflate byte[] array to char[]. 6796 // Clobbers: src, dst, len, rflags, rscratch1, v0-v6 6797 address MacroAssembler::byte_array_inflate(Register src, Register dst, Register len, 6798 FloatRegister vtmp1, FloatRegister vtmp2, 6799 FloatRegister vtmp3, Register tmp4) { 6800 Label big, done, after_init, to_stub; 6801 6802 assert_different_registers(src, dst, len, tmp4, rscratch1); 6803 6804 fmovd(vtmp1, 0.0); 6805 lsrw(tmp4, len, 3); 6806 bind(after_init); 6807 cbnzw(tmp4, big); 6808 // Short string: less than 8 bytes. 6809 { 6810 Label loop, tiny; 6811 6812 cmpw(len, 4); 6813 br(LT, tiny); 6814 // Use SIMD to do 4 bytes. 6815 ldrs(vtmp2, post(src, 4)); 6816 zip1(vtmp3, T8B, vtmp2, vtmp1); 6817 subw(len, len, 4); 6818 strd(vtmp3, post(dst, 8)); 6819 6820 cbzw(len, done); 6821 6822 // Do the remaining bytes by steam. 6823 bind(loop); 6824 ldrb(tmp4, post(src, 1)); 6825 strh(tmp4, post(dst, 2)); 6826 subw(len, len, 1); 6827 6828 bind(tiny); 6829 cbnz(len, loop); 6830 6831 b(done); 6832 } 6833 6834 if (SoftwarePrefetchHintDistance >= 0) { 6835 bind(to_stub); 6836 RuntimeAddress stub = RuntimeAddress(StubRoutines::aarch64::large_byte_array_inflate()); 6837 assert(stub.target() != nullptr, "large_byte_array_inflate stub has not been generated"); 6838 address tpc = trampoline_call(stub); 6839 if (tpc == nullptr) { 6840 DEBUG_ONLY(reset_labels(big, done)); 6841 postcond(pc() == badAddress); 6842 return nullptr; 6843 } 6844 b(after_init); 6845 } 6846 6847 // Unpack the bytes 8 at a time. 6848 bind(big); 6849 { 6850 Label loop, around, loop_last, loop_start; 6851 6852 if (SoftwarePrefetchHintDistance >= 0) { 6853 const int large_loop_threshold = (64 + 16)/8; 6854 ldrd(vtmp2, post(src, 8)); 6855 andw(len, len, 7); 6856 cmp(tmp4, (u1)large_loop_threshold); 6857 br(GE, to_stub); 6858 b(loop_start); 6859 6860 bind(loop); 6861 ldrd(vtmp2, post(src, 8)); 6862 bind(loop_start); 6863 subs(tmp4, tmp4, 1); 6864 br(EQ, loop_last); 6865 zip1(vtmp2, T16B, vtmp2, vtmp1); 6866 ldrd(vtmp3, post(src, 8)); 6867 st1(vtmp2, T8H, post(dst, 16)); 6868 subs(tmp4, tmp4, 1); 6869 zip1(vtmp3, T16B, vtmp3, vtmp1); 6870 st1(vtmp3, T8H, post(dst, 16)); 6871 br(NE, loop); 6872 b(around); 6873 bind(loop_last); 6874 zip1(vtmp2, T16B, vtmp2, vtmp1); 6875 st1(vtmp2, T8H, post(dst, 16)); 6876 bind(around); 6877 cbz(len, done); 6878 } else { 6879 andw(len, len, 7); 6880 bind(loop); 6881 ldrd(vtmp2, post(src, 8)); 6882 sub(tmp4, tmp4, 1); 6883 zip1(vtmp3, T16B, vtmp2, vtmp1); 6884 st1(vtmp3, T8H, post(dst, 16)); 6885 cbnz(tmp4, loop); 6886 } 6887 } 6888 6889 // Do the tail of up to 8 bytes. 6890 add(src, src, len); 6891 ldrd(vtmp3, Address(src, -8)); 6892 add(dst, dst, len, ext::uxtw, 1); 6893 zip1(vtmp3, T16B, vtmp3, vtmp1); 6894 strq(vtmp3, Address(dst, -16)); 6895 6896 bind(done); 6897 postcond(pc() != badAddress); 6898 return pc(); 6899 } 6900 6901 // Compress char[] array to byte[]. 6902 // Intrinsic for java.lang.StringUTF16.compress(char[] src, int srcOff, byte[] dst, int dstOff, int len) 6903 // Return the array length if every element in array can be encoded, 6904 // otherwise, the index of first non-latin1 (> 0xff) character. 6905 void MacroAssembler::char_array_compress(Register src, Register dst, Register len, 6906 Register res, 6907 FloatRegister tmp0, FloatRegister tmp1, 6908 FloatRegister tmp2, FloatRegister tmp3, 6909 FloatRegister tmp4, FloatRegister tmp5) { 6910 encode_iso_array(src, dst, len, res, false, tmp0, tmp1, tmp2, tmp3, tmp4, tmp5); 6911 } 6912 6913 // java.math.round(double a) 6914 // Returns the closest long to the argument, with ties rounding to 6915 // positive infinity. This requires some fiddling for corner 6916 // cases. We take care to avoid double rounding in e.g. (jlong)(a + 0.5). 6917 void MacroAssembler::java_round_double(Register dst, FloatRegister src, 6918 FloatRegister ftmp) { 6919 Label DONE; 6920 BLOCK_COMMENT("java_round_double: { "); 6921 fmovd(rscratch1, src); 6922 // Use RoundToNearestTiesAway unless src small and -ve. 6923 fcvtasd(dst, src); 6924 // Test if src >= 0 || abs(src) >= 0x1.0p52 6925 eor(rscratch1, rscratch1, UCONST64(1) << 63); // flip sign bit 6926 mov(rscratch2, julong_cast(0x1.0p52)); 6927 cmp(rscratch1, rscratch2); 6928 br(HS, DONE); { 6929 // src < 0 && abs(src) < 0x1.0p52 6930 // src may have a fractional part, so add 0.5 6931 fmovd(ftmp, 0.5); 6932 faddd(ftmp, src, ftmp); 6933 // Convert double to jlong, use RoundTowardsNegative 6934 fcvtmsd(dst, ftmp); 6935 } 6936 bind(DONE); 6937 BLOCK_COMMENT("} java_round_double"); 6938 } 6939 6940 void MacroAssembler::java_round_float(Register dst, FloatRegister src, 6941 FloatRegister ftmp) { 6942 Label DONE; 6943 BLOCK_COMMENT("java_round_float: { "); 6944 fmovs(rscratch1, src); 6945 // Use RoundToNearestTiesAway unless src small and -ve. 6946 fcvtassw(dst, src); 6947 // Test if src >= 0 || abs(src) >= 0x1.0p23 6948 eor(rscratch1, rscratch1, 0x80000000); // flip sign bit 6949 mov(rscratch2, jint_cast(0x1.0p23f)); 6950 cmp(rscratch1, rscratch2); 6951 br(HS, DONE); { 6952 // src < 0 && |src| < 0x1.0p23 6953 // src may have a fractional part, so add 0.5 6954 fmovs(ftmp, 0.5f); 6955 fadds(ftmp, src, ftmp); 6956 // Convert float to jint, use RoundTowardsNegative 6957 fcvtmssw(dst, ftmp); 6958 } 6959 bind(DONE); 6960 BLOCK_COMMENT("} java_round_float"); 6961 } 6962 6963 // get_thread() can be called anywhere inside generated code so we 6964 // need to save whatever non-callee save context might get clobbered 6965 // by the call to JavaThread::aarch64_get_thread_helper() or, indeed, 6966 // the call setup code. 6967 // 6968 // On Linux and Windows, aarch64_get_thread_helper() is implemented in 6969 // assembly and clobbers only r0, r1, and flags. 6970 // On other systems, the helper is a usual C function. 6971 // 6972 void MacroAssembler::get_thread(Register dst) { 6973 RegSet saved_regs = 6974 BSD_ONLY(RegSet::range(r0, r17) + lr - dst) 6975 NOT_BSD (RegSet::range(r0, r1) + lr - dst); 6976 6977 protect_return_address(); 6978 push(saved_regs, sp); 6979 6980 mov(lr, ExternalAddress(CAST_FROM_FN_PTR(address, JavaThread::aarch64_get_thread_helper))); 6981 blr(lr); 6982 if (dst != c_rarg0) { 6983 mov(dst, c_rarg0); 6984 } 6985 6986 pop(saved_regs, sp); 6987 authenticate_return_address(); 6988 } 6989 6990 #ifdef COMPILER2 6991 // C2 compiled method's prolog code 6992 // Moved here from aarch64.ad to support Valhalla code below 6993 void MacroAssembler::verified_entry(Compile* C, int sp_inc) { 6994 if (C->clinit_barrier_on_entry()) { 6995 assert(!C->method()->holder()->is_not_initialized(), "initialization should have been started"); 6996 6997 Label L_skip_barrier; 6998 6999 mov_metadata(rscratch2, C->method()->holder()->constant_encoding()); 7000 clinit_barrier(rscratch2, rscratch1, &L_skip_barrier); 7001 far_jump(RuntimeAddress(SharedRuntime::get_handle_wrong_method_stub())); 7002 bind(L_skip_barrier); 7003 } 7004 7005 if (C->max_vector_size() > 0) { 7006 reinitialize_ptrue(); 7007 } 7008 7009 int bangsize = C->output()->bang_size_in_bytes(); 7010 if (C->output()->need_stack_bang(bangsize)) 7011 generate_stack_overflow_check(bangsize); 7012 7013 // n.b. frame size includes space for return pc and rfp 7014 const long framesize = C->output()->frame_size_in_bytes(); 7015 build_frame(framesize DEBUG_ONLY(COMMA sp_inc != 0)); 7016 7017 if (C->needs_stack_repair()) { 7018 save_stack_increment(sp_inc, framesize); 7019 } 7020 7021 if (VerifyStackAtCalls) { 7022 Unimplemented(); 7023 } 7024 } 7025 #endif // COMPILER2 7026 7027 int MacroAssembler::store_inline_type_fields_to_buf(ciInlineKlass* vk, bool from_interpreter) { 7028 assert(InlineTypeReturnedAsFields, "Inline types should never be returned as fields"); 7029 // An inline type might be returned. If fields are in registers we 7030 // need to allocate an inline type instance and initialize it with 7031 // the value of the fields. 7032 Label skip; 7033 // We only need a new buffered inline type if a new one is not returned 7034 tbz(r0, 0, skip); 7035 int call_offset = -1; 7036 7037 // Be careful not to clobber r1-7 which hold returned fields 7038 // Also do not use callee-saved registers as these may be live in the interpreter 7039 Register tmp1 = r13, tmp2 = r14, klass = r15, r0_preserved = r12; 7040 7041 // The following code is similar to the instance allocation code in TemplateTable::_new 7042 // but has some slight differences, 7043 // e.g. object size is always not zero, sometimes it's constant; storing klass ptr after 7044 // allocating is not necessary if vk != nullptr, etc. 7045 Label slow_case; 7046 // 1. Try to allocate a new buffered inline instance either from TLAB or eden space 7047 mov(r0_preserved, r0); // save r0 for slow_case since *_allocate may corrupt it when allocation failed 7048 7049 if (vk != nullptr) { 7050 // Called from C1, where the return type is statically known. 7051 movptr(klass, (intptr_t)vk->get_InlineKlass()); 7052 jint lh = vk->layout_helper(); 7053 assert(lh != Klass::_lh_neutral_value, "inline class in return type must have been resolved"); 7054 if (UseTLAB && !Klass::layout_helper_needs_slow_path(lh)) { 7055 tlab_allocate(r0, noreg, lh, tmp1, tmp2, slow_case); 7056 } else { 7057 b(slow_case); 7058 } 7059 } else { 7060 // Call from interpreter. R0 contains ((the InlineKlass* of the return type) | 0x01) 7061 andr(klass, r0, -2); 7062 if (UseTLAB) { 7063 ldrw(tmp2, Address(klass, Klass::layout_helper_offset())); 7064 tst(tmp2, Klass::_lh_instance_slow_path_bit); 7065 br(Assembler::NE, slow_case); 7066 tlab_allocate(r0, tmp2, 0, tmp1, tmp2, slow_case); 7067 } else { 7068 b(slow_case); 7069 } 7070 } 7071 if (UseTLAB) { 7072 // 2. Initialize buffered inline instance header 7073 Register buffer_obj = r0; 7074 if (UseCompactObjectHeaders) { 7075 ldr(rscratch1, Address(klass, Klass::prototype_header_offset())); 7076 str(rscratch1, Address(buffer_obj, oopDesc::mark_offset_in_bytes())); 7077 } else { 7078 mov(rscratch1, (intptr_t)markWord::inline_type_prototype().value()); 7079 str(rscratch1, Address(buffer_obj, oopDesc::mark_offset_in_bytes())); 7080 store_klass_gap(buffer_obj, zr); 7081 if (vk == nullptr) { 7082 // store_klass corrupts klass, so save it for later use (interpreter case only). 7083 mov(tmp1, klass); 7084 } 7085 store_klass(buffer_obj, klass); 7086 klass = tmp1; 7087 } 7088 // 3. Initialize its fields with an inline class specific handler 7089 if (vk != nullptr) { 7090 far_call(RuntimeAddress(vk->pack_handler())); // no need for call info as this will not safepoint. 7091 } else { 7092 ldr(tmp1, Address(klass, InlineKlass::adr_members_offset())); 7093 ldr(tmp1, Address(tmp1, InlineKlass::pack_handler_offset())); 7094 blr(tmp1); 7095 } 7096 7097 membar(Assembler::StoreStore); 7098 b(skip); 7099 } else { 7100 // Must have already branched to slow_case above. 7101 DEBUG_ONLY(should_not_reach_here()); 7102 } 7103 bind(slow_case); 7104 // We failed to allocate a new inline type, fall back to a runtime 7105 // call. Some oop field may be live in some registers but we can't 7106 // tell. That runtime call will take care of preserving them 7107 // across a GC if there's one. 7108 mov(r0, r0_preserved); 7109 7110 if (from_interpreter) { 7111 super_call_VM_leaf(StubRoutines::store_inline_type_fields_to_buf()); 7112 } else { 7113 far_call(RuntimeAddress(StubRoutines::store_inline_type_fields_to_buf())); 7114 call_offset = offset(); 7115 } 7116 membar(Assembler::StoreStore); 7117 7118 bind(skip); 7119 return call_offset; 7120 } 7121 7122 // Move a value between registers/stack slots and update the reg_state 7123 bool MacroAssembler::move_helper(VMReg from, VMReg to, BasicType bt, RegState reg_state[]) { 7124 assert(from->is_valid() && to->is_valid(), "source and destination must be valid"); 7125 if (reg_state[to->value()] == reg_written) { 7126 return true; // Already written 7127 } 7128 7129 if (from != to && bt != T_VOID) { 7130 if (reg_state[to->value()] == reg_readonly) { 7131 return false; // Not yet writable 7132 } 7133 if (from->is_reg()) { 7134 if (to->is_reg()) { 7135 if (from->is_Register() && to->is_Register()) { 7136 mov(to->as_Register(), from->as_Register()); 7137 } else if (from->is_FloatRegister() && to->is_FloatRegister()) { 7138 fmovd(to->as_FloatRegister(), from->as_FloatRegister()); 7139 } else { 7140 ShouldNotReachHere(); 7141 } 7142 } else { 7143 int st_off = to->reg2stack() * VMRegImpl::stack_slot_size; 7144 Address to_addr = Address(sp, st_off); 7145 if (from->is_FloatRegister()) { 7146 if (bt == T_DOUBLE) { 7147 strd(from->as_FloatRegister(), to_addr); 7148 } else { 7149 assert(bt == T_FLOAT, "must be float"); 7150 strs(from->as_FloatRegister(), to_addr); 7151 } 7152 } else { 7153 str(from->as_Register(), to_addr); 7154 } 7155 } 7156 } else { 7157 Address from_addr = Address(sp, from->reg2stack() * VMRegImpl::stack_slot_size); 7158 if (to->is_reg()) { 7159 if (to->is_FloatRegister()) { 7160 if (bt == T_DOUBLE) { 7161 ldrd(to->as_FloatRegister(), from_addr); 7162 } else { 7163 assert(bt == T_FLOAT, "must be float"); 7164 ldrs(to->as_FloatRegister(), from_addr); 7165 } 7166 } else { 7167 ldr(to->as_Register(), from_addr); 7168 } 7169 } else { 7170 int st_off = to->reg2stack() * VMRegImpl::stack_slot_size; 7171 ldr(rscratch1, from_addr); 7172 str(rscratch1, Address(sp, st_off)); 7173 } 7174 } 7175 } 7176 7177 // Update register states 7178 reg_state[from->value()] = reg_writable; 7179 reg_state[to->value()] = reg_written; 7180 return true; 7181 } 7182 7183 // Calculate the extra stack space required for packing or unpacking inline 7184 // args and adjust the stack pointer 7185 int MacroAssembler::extend_stack_for_inline_args(int args_on_stack) { 7186 int sp_inc = args_on_stack * VMRegImpl::stack_slot_size; 7187 sp_inc = align_up(sp_inc, StackAlignmentInBytes); 7188 assert(sp_inc > 0, "sanity"); 7189 7190 // Save a copy of the FP and LR here for deoptimization patching and frame walking 7191 stp(rfp, lr, Address(pre(sp, -2 * wordSize))); 7192 7193 // Adjust the stack pointer. This will be repaired on return by MacroAssembler::remove_frame 7194 if (sp_inc < (1 << 9)) { 7195 sub(sp, sp, sp_inc); // Fits in an immediate 7196 } else { 7197 mov(rscratch1, sp_inc); 7198 sub(sp, sp, rscratch1); 7199 } 7200 7201 return sp_inc + 2 * wordSize; // Account for the FP/LR space 7202 } 7203 7204 // Read all fields from an inline type oop and store the values in registers/stack slots 7205 bool MacroAssembler::unpack_inline_helper(const GrowableArray<SigEntry>* sig, int& sig_index, 7206 VMReg from, int& from_index, VMRegPair* to, int to_count, int& to_index, 7207 RegState reg_state[]) { 7208 assert(sig->at(sig_index)._bt == T_VOID, "should be at end delimiter"); 7209 assert(from->is_valid(), "source must be valid"); 7210 bool progress = false; 7211 #ifdef ASSERT 7212 const int start_offset = offset(); 7213 #endif 7214 7215 Label L_null, L_notNull; 7216 // Don't use r14 as tmp because it's used for spilling (see MacroAssembler::spill_reg_for) 7217 Register tmp1 = r10; 7218 Register tmp2 = r11; 7219 7220 #ifdef ASSERT 7221 RegSet clobbered_gp_regs = MacroAssembler::call_clobbered_gp_registers(); 7222 assert(clobbered_gp_regs.contains(tmp1), "tmp1 must be saved explicitly if it's not a clobber"); 7223 assert(clobbered_gp_regs.contains(tmp2), "tmp2 must be saved explicitly if it's not a clobber"); 7224 assert(clobbered_gp_regs.contains(r14), "r14 must be saved explicitly if it's not a clobber"); 7225 #endif 7226 7227 Register fromReg = noreg; 7228 ScalarizedInlineArgsStream stream(sig, sig_index, to, to_count, to_index, true); 7229 bool done = true; 7230 bool mark_done = true; 7231 VMReg toReg; 7232 BasicType bt; 7233 // Check if argument requires a null check 7234 bool null_check = false; 7235 VMReg nullCheckReg; 7236 while (stream.next(nullCheckReg, bt)) { 7237 if (sig->at(stream.sig_index())._offset == -1) { 7238 null_check = true; 7239 break; 7240 } 7241 } 7242 stream.reset(sig_index, to_index); 7243 while (stream.next(toReg, bt)) { 7244 assert(toReg->is_valid(), "destination must be valid"); 7245 int idx = (int)toReg->value(); 7246 if (reg_state[idx] == reg_readonly) { 7247 if (idx != from->value()) { 7248 mark_done = false; 7249 } 7250 done = false; 7251 continue; 7252 } else if (reg_state[idx] == reg_written) { 7253 continue; 7254 } 7255 assert(reg_state[idx] == reg_writable, "must be writable"); 7256 reg_state[idx] = reg_written; 7257 progress = true; 7258 7259 if (fromReg == noreg) { 7260 if (from->is_reg()) { 7261 fromReg = from->as_Register(); 7262 } else { 7263 int st_off = from->reg2stack() * VMRegImpl::stack_slot_size; 7264 ldr(tmp1, Address(sp, st_off)); 7265 fromReg = tmp1; 7266 } 7267 if (null_check) { 7268 // Nullable inline type argument, emit null check 7269 cbz(fromReg, L_null); 7270 } 7271 } 7272 int off = sig->at(stream.sig_index())._offset; 7273 if (off == -1) { 7274 assert(null_check, "Missing null check at"); 7275 if (toReg->is_stack()) { 7276 int st_off = toReg->reg2stack() * VMRegImpl::stack_slot_size; 7277 mov(tmp2, 1); 7278 str(tmp2, Address(sp, st_off)); 7279 } else { 7280 mov(toReg->as_Register(), 1); 7281 } 7282 continue; 7283 } 7284 if (sig->at(stream.sig_index())._vt_oop) { 7285 if (toReg->is_stack()) { 7286 int st_off = toReg->reg2stack() * VMRegImpl::stack_slot_size; 7287 str(fromReg, Address(sp, st_off)); 7288 } else { 7289 mov(toReg->as_Register(), fromReg); 7290 } 7291 continue; 7292 } 7293 assert(off > 0, "offset in object should be positive"); 7294 Address fromAddr = Address(fromReg, off); 7295 if (!toReg->is_FloatRegister()) { 7296 Register dst = toReg->is_stack() ? tmp2 : toReg->as_Register(); 7297 if (is_reference_type(bt)) { 7298 load_heap_oop(dst, fromAddr, rscratch1, rscratch2); 7299 } else { 7300 bool is_signed = (bt != T_CHAR) && (bt != T_BOOLEAN); 7301 load_sized_value(dst, fromAddr, type2aelembytes(bt), is_signed); 7302 } 7303 if (toReg->is_stack()) { 7304 int st_off = toReg->reg2stack() * VMRegImpl::stack_slot_size; 7305 str(dst, Address(sp, st_off)); 7306 } 7307 } else if (bt == T_DOUBLE) { 7308 ldrd(toReg->as_FloatRegister(), fromAddr); 7309 } else { 7310 assert(bt == T_FLOAT, "must be float"); 7311 ldrs(toReg->as_FloatRegister(), fromAddr); 7312 } 7313 } 7314 if (progress && null_check) { 7315 if (done) { 7316 b(L_notNull); 7317 bind(L_null); 7318 // Set null marker to zero to signal that the argument is null. 7319 // Also set all fields to zero since the runtime requires a canonical 7320 // representation of a flat null. 7321 stream.reset(sig_index, to_index); 7322 while (stream.next(toReg, bt)) { 7323 if (toReg->is_stack()) { 7324 int st_off = toReg->reg2stack() * VMRegImpl::stack_slot_size; 7325 str(zr, Address(sp, st_off)); 7326 } else if (toReg->is_FloatRegister()) { 7327 mov(toReg->as_FloatRegister(), T2S, 0); 7328 } else { 7329 mov(toReg->as_Register(), zr); 7330 } 7331 } 7332 bind(L_notNull); 7333 } else { 7334 bind(L_null); 7335 } 7336 } 7337 7338 sig_index = stream.sig_index(); 7339 to_index = stream.regs_index(); 7340 7341 if (mark_done && reg_state[from->value()] != reg_written) { 7342 // This is okay because no one else will write to that slot 7343 reg_state[from->value()] = reg_writable; 7344 } 7345 from_index--; 7346 assert(progress || (start_offset == offset()), "should not emit code"); 7347 return done; 7348 } 7349 7350 // Pack fields back into an inline type oop 7351 bool MacroAssembler::pack_inline_helper(const GrowableArray<SigEntry>* sig, int& sig_index, int vtarg_index, 7352 VMRegPair* from, int from_count, int& from_index, VMReg to, 7353 RegState reg_state[], Register val_array) { 7354 assert(sig->at(sig_index)._bt == T_METADATA, "should be at delimiter"); 7355 assert(to->is_valid(), "destination must be valid"); 7356 7357 if (reg_state[to->value()] == reg_written) { 7358 skip_unpacked_fields(sig, sig_index, from, from_count, from_index); 7359 return true; // Already written 7360 } 7361 7362 // The GC barrier expanded by store_heap_oop below may call into the 7363 // runtime so use callee-saved registers for any values that need to be 7364 // preserved. The GC barrier assembler should take care of saving the 7365 // Java argument registers. 7366 // Be careful with r14 because it's used for spilling (see MacroAssembler::spill_reg_for). 7367 Register val_obj_tmp = r21; 7368 Register from_reg_tmp = r22; 7369 Register tmp1 = r14; 7370 Register tmp2 = r13; 7371 Register tmp3 = r12; 7372 Register val_obj = to->is_stack() ? val_obj_tmp : to->as_Register(); 7373 7374 assert_different_registers(val_obj_tmp, from_reg_tmp, tmp1, tmp2, tmp3, val_array); 7375 7376 if (reg_state[to->value()] == reg_readonly) { 7377 if (!is_reg_in_unpacked_fields(sig, sig_index, to, from, from_count, from_index)) { 7378 skip_unpacked_fields(sig, sig_index, from, from_count, from_index); 7379 return false; // Not yet writable 7380 } 7381 val_obj = val_obj_tmp; 7382 } 7383 7384 ScalarizedInlineArgsStream stream(sig, sig_index, from, from_count, from_index); 7385 VMReg fromReg; 7386 BasicType bt; 7387 Label L_null; 7388 while (stream.next(fromReg, bt)) { 7389 assert(fromReg->is_valid(), "source must be valid"); 7390 reg_state[fromReg->value()] = reg_writable; 7391 7392 int off = sig->at(stream.sig_index())._offset; 7393 if (off == -1) { 7394 // Nullable inline type argument, emit null check 7395 Label L_notNull; 7396 if (fromReg->is_stack()) { 7397 int ld_off = fromReg->reg2stack() * VMRegImpl::stack_slot_size; 7398 ldrb(tmp2, Address(sp, ld_off)); 7399 cbnz(tmp2, L_notNull); 7400 } else { 7401 cbnz(fromReg->as_Register(), L_notNull); 7402 } 7403 mov(val_obj, 0); 7404 b(L_null); 7405 bind(L_notNull); 7406 continue; 7407 } 7408 if (sig->at(stream.sig_index())._vt_oop) { 7409 if (fromReg->is_stack()) { 7410 int ld_off = fromReg->reg2stack() * VMRegImpl::stack_slot_size; 7411 ldr(val_obj, Address(sp, ld_off)); 7412 } else { 7413 mov(val_obj, fromReg->as_Register()); 7414 } 7415 cbnz(val_obj, L_null); 7416 // get the buffer from the just allocated pool of buffers 7417 int index = arrayOopDesc::base_offset_in_bytes(T_OBJECT) + vtarg_index * type2aelembytes(T_OBJECT); 7418 load_heap_oop(val_obj, Address(val_array, index), rscratch1, rscratch2); 7419 continue; 7420 } 7421 7422 assert(off > 0, "offset in object should be positive"); 7423 size_t size_in_bytes = is_java_primitive(bt) ? type2aelembytes(bt) : wordSize; 7424 7425 // Pack the scalarized field into the value object. 7426 Address dst(val_obj, off); 7427 if (!fromReg->is_FloatRegister()) { 7428 Register src; 7429 if (fromReg->is_stack()) { 7430 src = from_reg_tmp; 7431 int ld_off = fromReg->reg2stack() * VMRegImpl::stack_slot_size; 7432 load_sized_value(src, Address(sp, ld_off), size_in_bytes, /* is_signed */ false); 7433 } else { 7434 src = fromReg->as_Register(); 7435 } 7436 assert_different_registers(dst.base(), src, tmp1, tmp2, tmp3, val_array); 7437 if (is_reference_type(bt)) { 7438 // store_heap_oop transitively calls oop_store_at which corrupts to.base(). We need to keep val_obj valid. 7439 mov(tmp3, val_obj); 7440 Address dst_with_tmp3(tmp3, off); 7441 store_heap_oop(dst_with_tmp3, src, tmp1, tmp2, tmp3, IN_HEAP | ACCESS_WRITE | IS_DEST_UNINITIALIZED); 7442 } else { 7443 store_sized_value(dst, src, size_in_bytes); 7444 } 7445 } else if (bt == T_DOUBLE) { 7446 strd(fromReg->as_FloatRegister(), dst); 7447 } else { 7448 assert(bt == T_FLOAT, "must be float"); 7449 strs(fromReg->as_FloatRegister(), dst); 7450 } 7451 } 7452 bind(L_null); 7453 sig_index = stream.sig_index(); 7454 from_index = stream.regs_index(); 7455 7456 assert(reg_state[to->value()] == reg_writable, "must have already been read"); 7457 bool success = move_helper(val_obj->as_VMReg(), to, T_OBJECT, reg_state); 7458 assert(success, "to register must be writable"); 7459 return true; 7460 } 7461 7462 VMReg MacroAssembler::spill_reg_for(VMReg reg) { 7463 return (reg->is_FloatRegister()) ? v8->as_VMReg() : r14->as_VMReg(); 7464 } 7465 7466 void MacroAssembler::cache_wb(Address line) { 7467 assert(line.getMode() == Address::base_plus_offset, "mode should be base_plus_offset"); 7468 assert(line.index() == noreg, "index should be noreg"); 7469 assert(line.offset() == 0, "offset should be 0"); 7470 // would like to assert this 7471 // assert(line._ext.shift == 0, "shift should be zero"); 7472 if (VM_Version::supports_dcpop()) { 7473 // writeback using clear virtual address to point of persistence 7474 dc(Assembler::CVAP, line.base()); 7475 } else { 7476 // no need to generate anything as Unsafe.writebackMemory should 7477 // never invoke this stub 7478 } 7479 } 7480 7481 void MacroAssembler::cache_wbsync(bool is_pre) { 7482 // we only need a barrier post sync 7483 if (!is_pre) { 7484 membar(Assembler::AnyAny); 7485 } 7486 } 7487 7488 void MacroAssembler::verify_sve_vector_length(Register tmp) { 7489 if (!UseSVE || VM_Version::get_max_supported_sve_vector_length() == FloatRegister::sve_vl_min) { 7490 return; 7491 } 7492 // Make sure that native code does not change SVE vector length. 7493 Label verify_ok; 7494 movw(tmp, zr); 7495 sve_inc(tmp, B); 7496 subsw(zr, tmp, VM_Version::get_initial_sve_vector_length()); 7497 br(EQ, verify_ok); 7498 stop("Error: SVE vector length has changed since jvm startup"); 7499 bind(verify_ok); 7500 } 7501 7502 void MacroAssembler::verify_ptrue() { 7503 Label verify_ok; 7504 if (!UseSVE) { 7505 return; 7506 } 7507 sve_cntp(rscratch1, B, ptrue, ptrue); // get true elements count. 7508 sve_dec(rscratch1, B); 7509 cbz(rscratch1, verify_ok); 7510 stop("Error: the preserved predicate register (p7) elements are not all true"); 7511 bind(verify_ok); 7512 } 7513 7514 void MacroAssembler::safepoint_isb() { 7515 isb(); 7516 #ifndef PRODUCT 7517 if (VerifyCrossModifyFence) { 7518 // Clear the thread state. 7519 strb(zr, Address(rthread, in_bytes(JavaThread::requires_cross_modify_fence_offset()))); 7520 } 7521 #endif 7522 } 7523 7524 #ifndef PRODUCT 7525 void MacroAssembler::verify_cross_modify_fence_not_required() { 7526 if (VerifyCrossModifyFence) { 7527 // Check if thread needs a cross modify fence. 7528 ldrb(rscratch1, Address(rthread, in_bytes(JavaThread::requires_cross_modify_fence_offset()))); 7529 Label fence_not_required; 7530 cbz(rscratch1, fence_not_required); 7531 // If it does then fail. 7532 lea(rscratch1, RuntimeAddress(CAST_FROM_FN_PTR(address, JavaThread::verify_cross_modify_fence_failure))); 7533 mov(c_rarg0, rthread); 7534 blr(rscratch1); 7535 bind(fence_not_required); 7536 } 7537 } 7538 #endif 7539 7540 void MacroAssembler::spin_wait() { 7541 block_comment("spin_wait {"); 7542 for (int i = 0; i < VM_Version::spin_wait_desc().inst_count(); ++i) { 7543 switch (VM_Version::spin_wait_desc().inst()) { 7544 case SpinWait::NOP: 7545 nop(); 7546 break; 7547 case SpinWait::ISB: 7548 isb(); 7549 break; 7550 case SpinWait::YIELD: 7551 yield(); 7552 break; 7553 case SpinWait::SB: 7554 assert(VM_Version::supports_sb(), "current CPU does not support SB instruction"); 7555 sb(); 7556 break; 7557 case SpinWait::WFET: 7558 spin_wait_wfet(VM_Version::spin_wait_desc().delay()); 7559 break; 7560 default: 7561 ShouldNotReachHere(); 7562 } 7563 } 7564 block_comment("}"); 7565 } 7566 7567 void MacroAssembler::spin_wait_wfet(int delay_ns) { 7568 // The sequence assumes CNTFRQ_EL0 is fixed to 1GHz. The assumption is valid 7569 // starting from Armv8.6, according to the "D12.1.2 The system counter" of the 7570 // Arm Architecture Reference Manual for A-profile architecture version M.a.a. 7571 // This is sufficient because FEAT_WFXT is introduced from Armv8.6. 7572 Register target = rscratch1; 7573 Register current = rscratch2; 7574 get_cntvctss_el0(current); 7575 add(target, current, delay_ns); 7576 7577 Label L_wait_loop; 7578 bind(L_wait_loop); 7579 7580 wfet(target); 7581 get_cntvctss_el0(current); 7582 7583 cmp(current, target); 7584 br(LT, L_wait_loop); 7585 7586 sb(); 7587 } 7588 7589 // Stack frame creation/removal 7590 7591 void MacroAssembler::enter(bool strip_ret_addr) { 7592 if (strip_ret_addr) { 7593 // Addresses can only be signed once. If there are multiple nested frames being created 7594 // in the same function, then the return address needs stripping first. 7595 strip_return_address(); 7596 } 7597 protect_return_address(); 7598 stp(rfp, lr, Address(pre(sp, -2 * wordSize))); 7599 mov(rfp, sp); 7600 } 7601 7602 void MacroAssembler::leave() { 7603 mov(sp, rfp); 7604 ldp(rfp, lr, Address(post(sp, 2 * wordSize))); 7605 authenticate_return_address(); 7606 } 7607 7608 // ROP Protection 7609 // Use the AArch64 PAC feature to add ROP protection for generated code. Use whenever creating/ 7610 // destroying stack frames or whenever directly loading/storing the LR to memory. 7611 // If ROP protection is not set then these functions are no-ops. 7612 // For more details on PAC see pauth_aarch64.hpp. 7613 7614 // Sign the LR. Use during construction of a stack frame, before storing the LR to memory. 7615 // Uses value zero as the modifier. 7616 // 7617 void MacroAssembler::protect_return_address() { 7618 if (VM_Version::use_rop_protection()) { 7619 check_return_address(); 7620 paciaz(); 7621 } 7622 } 7623 7624 // Sign the return value in the given register. Use before updating the LR in the existing stack 7625 // frame for the current function. 7626 // Uses value zero as the modifier. 7627 // 7628 void MacroAssembler::protect_return_address(Register return_reg) { 7629 if (VM_Version::use_rop_protection()) { 7630 check_return_address(return_reg); 7631 paciza(return_reg); 7632 } 7633 } 7634 7635 // Authenticate the LR. Use before function return, after restoring FP and loading LR from memory. 7636 // Uses value zero as the modifier. 7637 // 7638 void MacroAssembler::authenticate_return_address() { 7639 if (VM_Version::use_rop_protection()) { 7640 autiaz(); 7641 check_return_address(); 7642 } 7643 } 7644 7645 // Authenticate the return value in the given register. Use before updating the LR in the existing 7646 // stack frame for the current function. 7647 // Uses value zero as the modifier. 7648 // 7649 void MacroAssembler::authenticate_return_address(Register return_reg) { 7650 if (VM_Version::use_rop_protection()) { 7651 autiza(return_reg); 7652 check_return_address(return_reg); 7653 } 7654 } 7655 7656 // Strip any PAC data from LR without performing any authentication. Use with caution - only if 7657 // there is no guaranteed way of authenticating the LR. 7658 // 7659 void MacroAssembler::strip_return_address() { 7660 if (VM_Version::use_rop_protection()) { 7661 xpaclri(); 7662 } 7663 } 7664 7665 #ifndef PRODUCT 7666 // PAC failures can be difficult to debug. After an authentication failure, a segfault will only 7667 // occur when the pointer is used - ie when the program returns to the invalid LR. At this point 7668 // it is difficult to debug back to the callee function. 7669 // This function simply loads from the address in the given register. 7670 // Use directly after authentication to catch authentication failures. 7671 // Also use before signing to check that the pointer is valid and hasn't already been signed. 7672 // 7673 void MacroAssembler::check_return_address(Register return_reg) { 7674 if (VM_Version::use_rop_protection()) { 7675 ldr(zr, Address(return_reg)); 7676 } 7677 } 7678 #endif 7679 7680 // The java_calling_convention describes stack locations as ideal slots on 7681 // a frame with no abi restrictions. Since we must observe abi restrictions 7682 // (like the placement of the register window) the slots must be biased by 7683 // the following value. 7684 static int reg2offset_in(VMReg r) { 7685 // Account for saved rfp and lr 7686 // This should really be in_preserve_stack_slots 7687 return (r->reg2stack() + 4) * VMRegImpl::stack_slot_size; 7688 } 7689 7690 static int reg2offset_out(VMReg r) { 7691 return (r->reg2stack() + SharedRuntime::out_preserve_stack_slots()) * VMRegImpl::stack_slot_size; 7692 } 7693 7694 // On 64bit we will store integer like items to the stack as 7695 // 64bits items (AArch64 ABI) even though java would only store 7696 // 32bits for a parameter. On 32bit it will simply be 32bits 7697 // So this routine will do 32->32 on 32bit and 32->64 on 64bit 7698 void MacroAssembler::move32_64(VMRegPair src, VMRegPair dst, Register tmp) { 7699 if (src.first()->is_stack()) { 7700 if (dst.first()->is_stack()) { 7701 // stack to stack 7702 ldr(tmp, Address(rfp, reg2offset_in(src.first()))); 7703 str(tmp, Address(sp, reg2offset_out(dst.first()))); 7704 } else { 7705 // stack to reg 7706 ldrsw(dst.first()->as_Register(), Address(rfp, reg2offset_in(src.first()))); 7707 } 7708 } else if (dst.first()->is_stack()) { 7709 // reg to stack 7710 str(src.first()->as_Register(), Address(sp, reg2offset_out(dst.first()))); 7711 } else { 7712 if (dst.first() != src.first()) { 7713 sxtw(dst.first()->as_Register(), src.first()->as_Register()); 7714 } 7715 } 7716 } 7717 7718 // An oop arg. Must pass a handle not the oop itself 7719 void MacroAssembler::object_move( 7720 OopMap* map, 7721 int oop_handle_offset, 7722 int framesize_in_slots, 7723 VMRegPair src, 7724 VMRegPair dst, 7725 bool is_receiver, 7726 int* receiver_offset) { 7727 7728 // must pass a handle. First figure out the location we use as a handle 7729 7730 Register rHandle = dst.first()->is_stack() ? rscratch2 : dst.first()->as_Register(); 7731 7732 // See if oop is null if it is we need no handle 7733 7734 if (src.first()->is_stack()) { 7735 7736 // Oop is already on the stack as an argument 7737 int offset_in_older_frame = src.first()->reg2stack() + SharedRuntime::out_preserve_stack_slots(); 7738 map->set_oop(VMRegImpl::stack2reg(offset_in_older_frame + framesize_in_slots)); 7739 if (is_receiver) { 7740 *receiver_offset = (offset_in_older_frame + framesize_in_slots) * VMRegImpl::stack_slot_size; 7741 } 7742 7743 ldr(rscratch1, Address(rfp, reg2offset_in(src.first()))); 7744 lea(rHandle, Address(rfp, reg2offset_in(src.first()))); 7745 // conditionally move a null 7746 cmp(rscratch1, zr); 7747 csel(rHandle, zr, rHandle, Assembler::EQ); 7748 } else { 7749 7750 // Oop is in an a register we must store it to the space we reserve 7751 // on the stack for oop_handles and pass a handle if oop is non-null 7752 7753 const Register rOop = src.first()->as_Register(); 7754 int oop_slot; 7755 if (rOop == j_rarg0) 7756 oop_slot = 0; 7757 else if (rOop == j_rarg1) 7758 oop_slot = 1; 7759 else if (rOop == j_rarg2) 7760 oop_slot = 2; 7761 else if (rOop == j_rarg3) 7762 oop_slot = 3; 7763 else if (rOop == j_rarg4) 7764 oop_slot = 4; 7765 else if (rOop == j_rarg5) 7766 oop_slot = 5; 7767 else if (rOop == j_rarg6) 7768 oop_slot = 6; 7769 else { 7770 assert(rOop == j_rarg7, "wrong register"); 7771 oop_slot = 7; 7772 } 7773 7774 oop_slot = oop_slot * VMRegImpl::slots_per_word + oop_handle_offset; 7775 int offset = oop_slot*VMRegImpl::stack_slot_size; 7776 7777 map->set_oop(VMRegImpl::stack2reg(oop_slot)); 7778 // Store oop in handle area, may be null 7779 str(rOop, Address(sp, offset)); 7780 if (is_receiver) { 7781 *receiver_offset = offset; 7782 } 7783 7784 cmp(rOop, zr); 7785 lea(rHandle, Address(sp, offset)); 7786 // conditionally move a null 7787 csel(rHandle, zr, rHandle, Assembler::EQ); 7788 } 7789 7790 // If arg is on the stack then place it otherwise it is already in correct reg. 7791 if (dst.first()->is_stack()) { 7792 str(rHandle, Address(sp, reg2offset_out(dst.first()))); 7793 } 7794 } 7795 7796 // A float arg may have to do float reg int reg conversion 7797 void MacroAssembler::float_move(VMRegPair src, VMRegPair dst, Register tmp) { 7798 if (src.first()->is_stack()) { 7799 if (dst.first()->is_stack()) { 7800 ldrw(tmp, Address(rfp, reg2offset_in(src.first()))); 7801 strw(tmp, Address(sp, reg2offset_out(dst.first()))); 7802 } else { 7803 ldrs(dst.first()->as_FloatRegister(), Address(rfp, reg2offset_in(src.first()))); 7804 } 7805 } else if (src.first() != dst.first()) { 7806 if (src.is_single_phys_reg() && dst.is_single_phys_reg()) 7807 fmovs(dst.first()->as_FloatRegister(), src.first()->as_FloatRegister()); 7808 else 7809 strs(src.first()->as_FloatRegister(), Address(sp, reg2offset_out(dst.first()))); 7810 } 7811 } 7812 7813 // A long move 7814 void MacroAssembler::long_move(VMRegPair src, VMRegPair dst, Register tmp) { 7815 if (src.first()->is_stack()) { 7816 if (dst.first()->is_stack()) { 7817 // stack to stack 7818 ldr(tmp, Address(rfp, reg2offset_in(src.first()))); 7819 str(tmp, Address(sp, reg2offset_out(dst.first()))); 7820 } else { 7821 // stack to reg 7822 ldr(dst.first()->as_Register(), Address(rfp, reg2offset_in(src.first()))); 7823 } 7824 } else if (dst.first()->is_stack()) { 7825 // reg to stack 7826 // Do we really have to sign extend??? 7827 // __ movslq(src.first()->as_Register(), src.first()->as_Register()); 7828 str(src.first()->as_Register(), Address(sp, reg2offset_out(dst.first()))); 7829 } else { 7830 if (dst.first() != src.first()) { 7831 mov(dst.first()->as_Register(), src.first()->as_Register()); 7832 } 7833 } 7834 } 7835 7836 7837 // A double move 7838 void MacroAssembler::double_move(VMRegPair src, VMRegPair dst, Register tmp) { 7839 if (src.first()->is_stack()) { 7840 if (dst.first()->is_stack()) { 7841 ldr(tmp, Address(rfp, reg2offset_in(src.first()))); 7842 str(tmp, Address(sp, reg2offset_out(dst.first()))); 7843 } else { 7844 ldrd(dst.first()->as_FloatRegister(), Address(rfp, reg2offset_in(src.first()))); 7845 } 7846 } else if (src.first() != dst.first()) { 7847 if (src.is_single_phys_reg() && dst.is_single_phys_reg()) 7848 fmovd(dst.first()->as_FloatRegister(), src.first()->as_FloatRegister()); 7849 else 7850 strd(src.first()->as_FloatRegister(), Address(sp, reg2offset_out(dst.first()))); 7851 } 7852 } 7853 7854 // Implements fast-locking. 7855 // 7856 // - obj: the object to be locked 7857 // - t1, t2, t3: temporary registers, will be destroyed 7858 // - slow: branched to if locking fails, absolute offset may larger than 32KB (imm14 encoding). 7859 void MacroAssembler::fast_lock(Register basic_lock, Register obj, Register t1, Register t2, Register t3, Label& slow) { 7860 assert_different_registers(basic_lock, obj, t1, t2, t3, rscratch1); 7861 7862 Label push; 7863 const Register top = t1; 7864 const Register mark = t2; 7865 const Register t = t3; 7866 7867 // Preload the markWord. It is important that this is the first 7868 // instruction emitted as it is part of C1's null check semantics. 7869 ldr(mark, Address(obj, oopDesc::mark_offset_in_bytes())); 7870 7871 if (UseObjectMonitorTable) { 7872 // Clear cache in case fast locking succeeds or we need to take the slow-path. 7873 str(zr, Address(basic_lock, BasicObjectLock::lock_offset() + in_ByteSize((BasicLock::object_monitor_cache_offset_in_bytes())))); 7874 } 7875 7876 if (DiagnoseSyncOnValueBasedClasses != 0) { 7877 load_klass(t1, obj); 7878 ldrb(t1, Address(t1, Klass::misc_flags_offset())); 7879 tst(t1, KlassFlags::_misc_is_value_based_class); 7880 br(Assembler::NE, slow); 7881 } 7882 7883 // Check if the lock-stack is full. 7884 ldrw(top, Address(rthread, JavaThread::lock_stack_top_offset())); 7885 cmpw(top, (unsigned)LockStack::end_offset()); 7886 br(Assembler::GE, slow); 7887 7888 // Check for recursion. 7889 subw(t, top, oopSize); 7890 ldr(t, Address(rthread, t)); 7891 cmp(obj, t); 7892 br(Assembler::EQ, push); 7893 7894 // Check header for monitor (0b10). 7895 tst(mark, markWord::monitor_value); 7896 br(Assembler::NE, slow); 7897 7898 // Try to lock. Transition lock bits 0b01 => 0b00 7899 assert(oopDesc::mark_offset_in_bytes() == 0, "required to avoid lea"); 7900 orr(mark, mark, markWord::unlocked_value); 7901 // Mask inline_type bit such that we go to the slow path if object is an inline type 7902 andr(mark, mark, ~((int) markWord::inline_type_bit_in_place)); 7903 7904 eor(t, mark, markWord::unlocked_value); 7905 cmpxchg(/*addr*/ obj, /*expected*/ mark, /*new*/ t, Assembler::xword, 7906 /*acquire*/ true, /*release*/ false, /*weak*/ false, noreg); 7907 br(Assembler::NE, slow); 7908 7909 bind(push); 7910 // After successful lock, push object on lock-stack. 7911 str(obj, Address(rthread, top)); 7912 addw(top, top, oopSize); 7913 strw(top, Address(rthread, JavaThread::lock_stack_top_offset())); 7914 } 7915 7916 // Implements fast-unlocking. 7917 // 7918 // - obj: the object to be unlocked 7919 // - t1, t2, t3: temporary registers 7920 // - slow: branched to if unlocking fails, absolute offset may larger than 32KB (imm14 encoding). 7921 void MacroAssembler::fast_unlock(Register obj, Register t1, Register t2, Register t3, Label& slow) { 7922 // cmpxchg clobbers rscratch1. 7923 assert_different_registers(obj, t1, t2, t3, rscratch1); 7924 7925 #ifdef ASSERT 7926 { 7927 // Check for lock-stack underflow. 7928 Label stack_ok; 7929 ldrw(t1, Address(rthread, JavaThread::lock_stack_top_offset())); 7930 cmpw(t1, (unsigned)LockStack::start_offset()); 7931 br(Assembler::GE, stack_ok); 7932 STOP("Lock-stack underflow"); 7933 bind(stack_ok); 7934 } 7935 #endif 7936 7937 Label unlocked, push_and_slow; 7938 const Register top = t1; 7939 const Register mark = t2; 7940 const Register t = t3; 7941 7942 // Check if obj is top of lock-stack. 7943 ldrw(top, Address(rthread, JavaThread::lock_stack_top_offset())); 7944 subw(top, top, oopSize); 7945 ldr(t, Address(rthread, top)); 7946 cmp(obj, t); 7947 br(Assembler::NE, slow); 7948 7949 // Pop lock-stack. 7950 DEBUG_ONLY(str(zr, Address(rthread, top));) 7951 strw(top, Address(rthread, JavaThread::lock_stack_top_offset())); 7952 7953 // Check if recursive. 7954 subw(t, top, oopSize); 7955 ldr(t, Address(rthread, t)); 7956 cmp(obj, t); 7957 br(Assembler::EQ, unlocked); 7958 7959 // Not recursive. Check header for monitor (0b10). 7960 ldr(mark, Address(obj, oopDesc::mark_offset_in_bytes())); 7961 tbnz(mark, log2i_exact(markWord::monitor_value), push_and_slow); 7962 7963 #ifdef ASSERT 7964 // Check header not unlocked (0b01). 7965 Label not_unlocked; 7966 tbz(mark, log2i_exact(markWord::unlocked_value), not_unlocked); 7967 stop("fast_unlock already unlocked"); 7968 bind(not_unlocked); 7969 #endif 7970 7971 // Try to unlock. Transition lock bits 0b00 => 0b01 7972 assert(oopDesc::mark_offset_in_bytes() == 0, "required to avoid lea"); 7973 orr(t, mark, markWord::unlocked_value); 7974 cmpxchg(obj, mark, t, Assembler::xword, 7975 /*acquire*/ false, /*release*/ true, /*weak*/ false, noreg); 7976 br(Assembler::EQ, unlocked); 7977 7978 bind(push_and_slow); 7979 // Restore lock-stack and handle the unlock in runtime. 7980 DEBUG_ONLY(str(obj, Address(rthread, top));) 7981 addw(top, top, oopSize); 7982 strw(top, Address(rthread, JavaThread::lock_stack_top_offset())); 7983 b(slow); 7984 7985 bind(unlocked); 7986 } 7987 7988 // Rotate using USHR and SLI instructions (or copy, if rotate count is zero) 7989 void MacroAssembler::neon_vector_rotate(FloatRegister dst, SIMD_Arrangement T, 7990 FloatRegister src, int shift_amount) { 7991 assert(src != dst, "did not expect src and dst to be the same register"); 7992 7993 int esize = BitsPerByte << (T / 2); 7994 int lshift = shift_amount & (esize - 1); 7995 7996 if (lshift == 0) { 7997 // T & 1 == 0 => 64-bit arrangements, else 128-bit arrangements 7998 orr(dst, (T & 1) == 0 ? T8B : T16B, src, src); 7999 } else { 8000 ushr(dst, T, src, esize - lshift); 8001 sli(dst, T, src, lshift); 8002 } 8003 } --- EOF ---