1 /* 2 * Copyright (c) 1997, 2016, Oracle and/or its affiliates. All rights reserved. 3 * Copyright (c) 2012, 2016 SAP SE. 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 "precompiled.hpp" 27 #include "asm/macroAssembler.inline.hpp" 28 #include "code/debugInfoRec.hpp" 29 #include "code/icBuffer.hpp" 30 #include "code/vtableStubs.hpp" 31 #include "frame_ppc.hpp" 32 #include "interpreter/interpreter.hpp" 33 #include "interpreter/interp_masm.hpp" 34 #include "oops/compiledICHolder.hpp" 35 #include "prims/jvmtiRedefineClassesTrace.hpp" 36 #include "runtime/sharedRuntime.hpp" 37 #include "runtime/vframeArray.hpp" 38 #include "vmreg_ppc.inline.hpp" 39 #ifdef COMPILER1 40 #include "c1/c1_Runtime1.hpp" 41 #endif 42 #ifdef COMPILER2 43 #include "adfiles/ad_ppc_64.hpp" 44 #include "opto/runtime.hpp" 45 #endif 46 47 #include <alloca.h> 48 49 #define __ masm-> 50 51 #ifdef PRODUCT 52 #define BLOCK_COMMENT(str) // nothing 53 #else 54 #define BLOCK_COMMENT(str) __ block_comment(str) 55 #endif 56 57 #define BIND(label) bind(label); BLOCK_COMMENT(#label ":") 58 59 60 class RegisterSaver { 61 // Used for saving volatile registers. 62 public: 63 64 // Support different return pc locations. 65 enum ReturnPCLocation { 66 return_pc_is_lr, 67 return_pc_is_pre_saved, 68 return_pc_is_thread_saved_exception_pc 69 }; 70 71 static OopMap* push_frame_reg_args_and_save_live_registers(MacroAssembler* masm, 72 int* out_frame_size_in_bytes, 73 bool generate_oop_map, 74 int return_pc_adjustment, 75 ReturnPCLocation return_pc_location); 76 static void restore_live_registers_and_pop_frame(MacroAssembler* masm, 77 int frame_size_in_bytes, 78 bool restore_ctr); 79 80 static void push_frame_and_save_argument_registers(MacroAssembler* masm, 81 Register r_temp, 82 int frame_size, 83 int total_args, 84 const VMRegPair *regs, const VMRegPair *regs2 = NULL); 85 static void restore_argument_registers_and_pop_frame(MacroAssembler*masm, 86 int frame_size, 87 int total_args, 88 const VMRegPair *regs, const VMRegPair *regs2 = NULL); 89 90 // During deoptimization only the result registers need to be restored 91 // all the other values have already been extracted. 92 static void restore_result_registers(MacroAssembler* masm, int frame_size_in_bytes); 93 94 // Constants and data structures: 95 96 typedef enum { 97 int_reg = 0, 98 float_reg = 1, 99 special_reg = 2 100 } RegisterType; 101 102 typedef enum { 103 reg_size = 8, 104 half_reg_size = reg_size / 2, 105 } RegisterConstants; 106 107 typedef struct { 108 RegisterType reg_type; 109 int reg_num; 110 VMReg vmreg; 111 } LiveRegType; 112 }; 113 114 115 #define RegisterSaver_LiveSpecialReg(regname) \ 116 { RegisterSaver::special_reg, regname->encoding(), regname->as_VMReg() } 117 118 #define RegisterSaver_LiveIntReg(regname) \ 119 { RegisterSaver::int_reg, regname->encoding(), regname->as_VMReg() } 120 121 #define RegisterSaver_LiveFloatReg(regname) \ 122 { RegisterSaver::float_reg, regname->encoding(), regname->as_VMReg() } 123 124 static const RegisterSaver::LiveRegType RegisterSaver_LiveRegs[] = { 125 // Live registers which get spilled to the stack. Register 126 // positions in this array correspond directly to the stack layout. 127 128 // 129 // live special registers: 130 // 131 RegisterSaver_LiveSpecialReg(SR_CTR), 132 // 133 // live float registers: 134 // 135 RegisterSaver_LiveFloatReg( F0 ), 136 RegisterSaver_LiveFloatReg( F1 ), 137 RegisterSaver_LiveFloatReg( F2 ), 138 RegisterSaver_LiveFloatReg( F3 ), 139 RegisterSaver_LiveFloatReg( F4 ), 140 RegisterSaver_LiveFloatReg( F5 ), 141 RegisterSaver_LiveFloatReg( F6 ), 142 RegisterSaver_LiveFloatReg( F7 ), 143 RegisterSaver_LiveFloatReg( F8 ), 144 RegisterSaver_LiveFloatReg( F9 ), 145 RegisterSaver_LiveFloatReg( F10 ), 146 RegisterSaver_LiveFloatReg( F11 ), 147 RegisterSaver_LiveFloatReg( F12 ), 148 RegisterSaver_LiveFloatReg( F13 ), 149 RegisterSaver_LiveFloatReg( F14 ), 150 RegisterSaver_LiveFloatReg( F15 ), 151 RegisterSaver_LiveFloatReg( F16 ), 152 RegisterSaver_LiveFloatReg( F17 ), 153 RegisterSaver_LiveFloatReg( F18 ), 154 RegisterSaver_LiveFloatReg( F19 ), 155 RegisterSaver_LiveFloatReg( F20 ), 156 RegisterSaver_LiveFloatReg( F21 ), 157 RegisterSaver_LiveFloatReg( F22 ), 158 RegisterSaver_LiveFloatReg( F23 ), 159 RegisterSaver_LiveFloatReg( F24 ), 160 RegisterSaver_LiveFloatReg( F25 ), 161 RegisterSaver_LiveFloatReg( F26 ), 162 RegisterSaver_LiveFloatReg( F27 ), 163 RegisterSaver_LiveFloatReg( F28 ), 164 RegisterSaver_LiveFloatReg( F29 ), 165 RegisterSaver_LiveFloatReg( F30 ), 166 RegisterSaver_LiveFloatReg( F31 ), 167 // 168 // live integer registers: 169 // 170 RegisterSaver_LiveIntReg( R0 ), 171 //RegisterSaver_LiveIntReg( R1 ), // stack pointer 172 RegisterSaver_LiveIntReg( R2 ), 173 RegisterSaver_LiveIntReg( R3 ), 174 RegisterSaver_LiveIntReg( R4 ), 175 RegisterSaver_LiveIntReg( R5 ), 176 RegisterSaver_LiveIntReg( R6 ), 177 RegisterSaver_LiveIntReg( R7 ), 178 RegisterSaver_LiveIntReg( R8 ), 179 RegisterSaver_LiveIntReg( R9 ), 180 RegisterSaver_LiveIntReg( R10 ), 181 RegisterSaver_LiveIntReg( R11 ), 182 RegisterSaver_LiveIntReg( R12 ), 183 //RegisterSaver_LiveIntReg( R13 ), // system thread id 184 RegisterSaver_LiveIntReg( R14 ), 185 RegisterSaver_LiveIntReg( R15 ), 186 RegisterSaver_LiveIntReg( R16 ), 187 RegisterSaver_LiveIntReg( R17 ), 188 RegisterSaver_LiveIntReg( R18 ), 189 RegisterSaver_LiveIntReg( R19 ), 190 RegisterSaver_LiveIntReg( R20 ), 191 RegisterSaver_LiveIntReg( R21 ), 192 RegisterSaver_LiveIntReg( R22 ), 193 RegisterSaver_LiveIntReg( R23 ), 194 RegisterSaver_LiveIntReg( R24 ), 195 RegisterSaver_LiveIntReg( R25 ), 196 RegisterSaver_LiveIntReg( R26 ), 197 RegisterSaver_LiveIntReg( R27 ), 198 RegisterSaver_LiveIntReg( R28 ), 199 RegisterSaver_LiveIntReg( R29 ), 200 RegisterSaver_LiveIntReg( R30 ), 201 RegisterSaver_LiveIntReg( R31 ), // must be the last register (see save/restore functions below) 202 }; 203 204 OopMap* RegisterSaver::push_frame_reg_args_and_save_live_registers(MacroAssembler* masm, 205 int* out_frame_size_in_bytes, 206 bool generate_oop_map, 207 int return_pc_adjustment, 208 ReturnPCLocation return_pc_location) { 209 // Push an abi_reg_args-frame and store all registers which may be live. 210 // If requested, create an OopMap: Record volatile registers as 211 // callee-save values in an OopMap so their save locations will be 212 // propagated to the RegisterMap of the caller frame during 213 // StackFrameStream construction (needed for deoptimization; see 214 // compiledVFrame::create_stack_value). 215 // If return_pc_adjustment != 0 adjust the return pc by return_pc_adjustment. 216 217 int i; 218 int offset; 219 220 // calcualte frame size 221 const int regstosave_num = sizeof(RegisterSaver_LiveRegs) / 222 sizeof(RegisterSaver::LiveRegType); 223 const int register_save_size = regstosave_num * reg_size; 224 const int frame_size_in_bytes = round_to(register_save_size, frame::alignment_in_bytes) 225 + frame::abi_reg_args_size; 226 *out_frame_size_in_bytes = frame_size_in_bytes; 227 const int frame_size_in_slots = frame_size_in_bytes / sizeof(jint); 228 const int register_save_offset = frame_size_in_bytes - register_save_size; 229 230 // OopMap frame size is in c2 stack slots (sizeof(jint)) not bytes or words. 231 OopMap* map = generate_oop_map ? new OopMap(frame_size_in_slots, 0) : NULL; 232 233 BLOCK_COMMENT("push_frame_reg_args_and_save_live_registers {"); 234 235 // Save r31 in the last slot of the not yet pushed frame so that we 236 // can use it as scratch reg. 237 __ std(R31, -reg_size, R1_SP); 238 assert(-reg_size == register_save_offset - frame_size_in_bytes + ((regstosave_num-1)*reg_size), 239 "consistency check"); 240 241 // save the flags 242 // Do the save_LR_CR by hand and adjust the return pc if requested. 243 __ mfcr(R31); 244 __ std(R31, _abi(cr), R1_SP); 245 switch (return_pc_location) { 246 case return_pc_is_lr: __ mflr(R31); break; 247 case return_pc_is_pre_saved: assert(return_pc_adjustment == 0, "unsupported"); break; 248 case return_pc_is_thread_saved_exception_pc: __ ld(R31, thread_(saved_exception_pc)); break; 249 default: ShouldNotReachHere(); 250 } 251 if (return_pc_location != return_pc_is_pre_saved) { 252 if (return_pc_adjustment != 0) { 253 __ addi(R31, R31, return_pc_adjustment); 254 } 255 __ std(R31, _abi(lr), R1_SP); 256 } 257 258 // push a new frame 259 __ push_frame(frame_size_in_bytes, R31); 260 261 // save all registers (ints and floats) 262 offset = register_save_offset; 263 for (int i = 0; i < regstosave_num; i++) { 264 int reg_num = RegisterSaver_LiveRegs[i].reg_num; 265 int reg_type = RegisterSaver_LiveRegs[i].reg_type; 266 267 switch (reg_type) { 268 case RegisterSaver::int_reg: { 269 if (reg_num != 31) { // We spilled R31 right at the beginning. 270 __ std(as_Register(reg_num), offset, R1_SP); 271 } 272 break; 273 } 274 case RegisterSaver::float_reg: { 275 __ stfd(as_FloatRegister(reg_num), offset, R1_SP); 276 break; 277 } 278 case RegisterSaver::special_reg: { 279 if (reg_num == SR_CTR_SpecialRegisterEnumValue) { 280 __ mfctr(R31); 281 __ std(R31, offset, R1_SP); 282 } else { 283 Unimplemented(); 284 } 285 break; 286 } 287 default: 288 ShouldNotReachHere(); 289 } 290 291 if (generate_oop_map) { 292 map->set_callee_saved(VMRegImpl::stack2reg(offset>>2), 293 RegisterSaver_LiveRegs[i].vmreg); 294 map->set_callee_saved(VMRegImpl::stack2reg((offset + half_reg_size)>>2), 295 RegisterSaver_LiveRegs[i].vmreg->next()); 296 } 297 offset += reg_size; 298 } 299 300 BLOCK_COMMENT("} push_frame_reg_args_and_save_live_registers"); 301 302 // And we're done. 303 return map; 304 } 305 306 307 // Pop the current frame and restore all the registers that we 308 // saved. 309 void RegisterSaver::restore_live_registers_and_pop_frame(MacroAssembler* masm, 310 int frame_size_in_bytes, 311 bool restore_ctr) { 312 int i; 313 int offset; 314 const int regstosave_num = sizeof(RegisterSaver_LiveRegs) / 315 sizeof(RegisterSaver::LiveRegType); 316 const int register_save_size = regstosave_num * reg_size; 317 const int register_save_offset = frame_size_in_bytes - register_save_size; 318 319 BLOCK_COMMENT("restore_live_registers_and_pop_frame {"); 320 321 // restore all registers (ints and floats) 322 offset = register_save_offset; 323 for (int i = 0; i < regstosave_num; i++) { 324 int reg_num = RegisterSaver_LiveRegs[i].reg_num; 325 int reg_type = RegisterSaver_LiveRegs[i].reg_type; 326 327 switch (reg_type) { 328 case RegisterSaver::int_reg: { 329 if (reg_num != 31) // R31 restored at the end, it's the tmp reg! 330 __ ld(as_Register(reg_num), offset, R1_SP); 331 break; 332 } 333 case RegisterSaver::float_reg: { 334 __ lfd(as_FloatRegister(reg_num), offset, R1_SP); 335 break; 336 } 337 case RegisterSaver::special_reg: { 338 if (reg_num == SR_CTR_SpecialRegisterEnumValue) { 339 if (restore_ctr) { // Nothing to do here if ctr already contains the next address. 340 __ ld(R31, offset, R1_SP); 341 __ mtctr(R31); 342 } 343 } else { 344 Unimplemented(); 345 } 346 break; 347 } 348 default: 349 ShouldNotReachHere(); 350 } 351 offset += reg_size; 352 } 353 354 // pop the frame 355 __ pop_frame(); 356 357 // restore the flags 358 __ restore_LR_CR(R31); 359 360 // restore scratch register's value 361 __ ld(R31, -reg_size, R1_SP); 362 363 BLOCK_COMMENT("} restore_live_registers_and_pop_frame"); 364 } 365 366 void RegisterSaver::push_frame_and_save_argument_registers(MacroAssembler* masm, Register r_temp, 367 int frame_size,int total_args, const VMRegPair *regs, 368 const VMRegPair *regs2) { 369 __ push_frame(frame_size, r_temp); 370 int st_off = frame_size - wordSize; 371 for (int i = 0; i < total_args; i++) { 372 VMReg r_1 = regs[i].first(); 373 VMReg r_2 = regs[i].second(); 374 if (!r_1->is_valid()) { 375 assert(!r_2->is_valid(), ""); 376 continue; 377 } 378 if (r_1->is_Register()) { 379 Register r = r_1->as_Register(); 380 __ std(r, st_off, R1_SP); 381 st_off -= wordSize; 382 } else if (r_1->is_FloatRegister()) { 383 FloatRegister f = r_1->as_FloatRegister(); 384 __ stfd(f, st_off, R1_SP); 385 st_off -= wordSize; 386 } 387 } 388 if (regs2 != NULL) { 389 for (int i = 0; i < total_args; i++) { 390 VMReg r_1 = regs2[i].first(); 391 VMReg r_2 = regs2[i].second(); 392 if (!r_1->is_valid()) { 393 assert(!r_2->is_valid(), ""); 394 continue; 395 } 396 if (r_1->is_Register()) { 397 Register r = r_1->as_Register(); 398 __ std(r, st_off, R1_SP); 399 st_off -= wordSize; 400 } else if (r_1->is_FloatRegister()) { 401 FloatRegister f = r_1->as_FloatRegister(); 402 __ stfd(f, st_off, R1_SP); 403 st_off -= wordSize; 404 } 405 } 406 } 407 } 408 409 void RegisterSaver::restore_argument_registers_and_pop_frame(MacroAssembler*masm, int frame_size, 410 int total_args, const VMRegPair *regs, 411 const VMRegPair *regs2) { 412 int st_off = frame_size - wordSize; 413 for (int i = 0; i < total_args; i++) { 414 VMReg r_1 = regs[i].first(); 415 VMReg r_2 = regs[i].second(); 416 if (r_1->is_Register()) { 417 Register r = r_1->as_Register(); 418 __ ld(r, st_off, R1_SP); 419 st_off -= wordSize; 420 } else if (r_1->is_FloatRegister()) { 421 FloatRegister f = r_1->as_FloatRegister(); 422 __ lfd(f, st_off, R1_SP); 423 st_off -= wordSize; 424 } 425 } 426 if (regs2 != NULL) 427 for (int i = 0; i < total_args; i++) { 428 VMReg r_1 = regs2[i].first(); 429 VMReg r_2 = regs2[i].second(); 430 if (r_1->is_Register()) { 431 Register r = r_1->as_Register(); 432 __ ld(r, st_off, R1_SP); 433 st_off -= wordSize; 434 } else if (r_1->is_FloatRegister()) { 435 FloatRegister f = r_1->as_FloatRegister(); 436 __ lfd(f, st_off, R1_SP); 437 st_off -= wordSize; 438 } 439 } 440 __ pop_frame(); 441 } 442 443 // Restore the registers that might be holding a result. 444 void RegisterSaver::restore_result_registers(MacroAssembler* masm, int frame_size_in_bytes) { 445 int i; 446 int offset; 447 const int regstosave_num = sizeof(RegisterSaver_LiveRegs) / 448 sizeof(RegisterSaver::LiveRegType); 449 const int register_save_size = regstosave_num * reg_size; 450 const int register_save_offset = frame_size_in_bytes - register_save_size; 451 452 // restore all result registers (ints and floats) 453 offset = register_save_offset; 454 for (int i = 0; i < regstosave_num; i++) { 455 int reg_num = RegisterSaver_LiveRegs[i].reg_num; 456 int reg_type = RegisterSaver_LiveRegs[i].reg_type; 457 switch (reg_type) { 458 case RegisterSaver::int_reg: { 459 if (as_Register(reg_num)==R3_RET) // int result_reg 460 __ ld(as_Register(reg_num), offset, R1_SP); 461 break; 462 } 463 case RegisterSaver::float_reg: { 464 if (as_FloatRegister(reg_num)==F1_RET) // float result_reg 465 __ lfd(as_FloatRegister(reg_num), offset, R1_SP); 466 break; 467 } 468 case RegisterSaver::special_reg: { 469 // Special registers don't hold a result. 470 break; 471 } 472 default: 473 ShouldNotReachHere(); 474 } 475 offset += reg_size; 476 } 477 } 478 479 // Is vector's size (in bytes) bigger than a size saved by default? 480 bool SharedRuntime::is_wide_vector(int size) { 481 // Note, MaxVectorSize == 8 on PPC64. 482 assert(size <= 8, "%d bytes vectors are not supported", size); 483 return size > 8; 484 } 485 486 size_t SharedRuntime::trampoline_size() { 487 return Assembler::load_const_size + 8; 488 } 489 490 void SharedRuntime::generate_trampoline(MacroAssembler *masm, address destination) { 491 Register Rtemp = R12; 492 __ load_const(Rtemp, destination); 493 __ mtctr(Rtemp); 494 __ bctr(); 495 } 496 497 #ifdef COMPILER2 498 static int reg2slot(VMReg r) { 499 return r->reg2stack() + SharedRuntime::out_preserve_stack_slots(); 500 } 501 502 static int reg2offset(VMReg r) { 503 return (r->reg2stack() + SharedRuntime::out_preserve_stack_slots()) * VMRegImpl::stack_slot_size; 504 } 505 #endif 506 507 // --------------------------------------------------------------------------- 508 // Read the array of BasicTypes from a signature, and compute where the 509 // arguments should go. Values in the VMRegPair regs array refer to 4-byte 510 // quantities. Values less than VMRegImpl::stack0 are registers, those above 511 // refer to 4-byte stack slots. All stack slots are based off of the stack pointer 512 // as framesizes are fixed. 513 // VMRegImpl::stack0 refers to the first slot 0(sp). 514 // and VMRegImpl::stack0+1 refers to the memory word 4-bytes higher. Register 515 // up to RegisterImpl::number_of_registers) are the 64-bit 516 // integer registers. 517 518 // Note: the INPUTS in sig_bt are in units of Java argument words, which are 519 // either 32-bit or 64-bit depending on the build. The OUTPUTS are in 32-bit 520 // units regardless of build. Of course for i486 there is no 64 bit build 521 522 // The Java calling convention is a "shifted" version of the C ABI. 523 // By skipping the first C ABI register we can call non-static jni methods 524 // with small numbers of arguments without having to shuffle the arguments 525 // at all. Since we control the java ABI we ought to at least get some 526 // advantage out of it. 527 528 const VMReg java_iarg_reg[8] = { 529 R3->as_VMReg(), 530 R4->as_VMReg(), 531 R5->as_VMReg(), 532 R6->as_VMReg(), 533 R7->as_VMReg(), 534 R8->as_VMReg(), 535 R9->as_VMReg(), 536 R10->as_VMReg() 537 }; 538 539 const VMReg java_farg_reg[13] = { 540 F1->as_VMReg(), 541 F2->as_VMReg(), 542 F3->as_VMReg(), 543 F4->as_VMReg(), 544 F5->as_VMReg(), 545 F6->as_VMReg(), 546 F7->as_VMReg(), 547 F8->as_VMReg(), 548 F9->as_VMReg(), 549 F10->as_VMReg(), 550 F11->as_VMReg(), 551 F12->as_VMReg(), 552 F13->as_VMReg() 553 }; 554 555 const int num_java_iarg_registers = sizeof(java_iarg_reg) / sizeof(java_iarg_reg[0]); 556 const int num_java_farg_registers = sizeof(java_farg_reg) / sizeof(java_farg_reg[0]); 557 558 int SharedRuntime::java_calling_convention(const BasicType *sig_bt, 559 VMRegPair *regs, 560 int total_args_passed, 561 int is_outgoing) { 562 // C2c calling conventions for compiled-compiled calls. 563 // Put 8 ints/longs into registers _AND_ 13 float/doubles into 564 // registers _AND_ put the rest on the stack. 565 566 const int inc_stk_for_intfloat = 1; // 1 slots for ints and floats 567 const int inc_stk_for_longdouble = 2; // 2 slots for longs and doubles 568 569 int i; 570 VMReg reg; 571 int stk = 0; 572 int ireg = 0; 573 int freg = 0; 574 575 // We put the first 8 arguments into registers and the rest on the 576 // stack, float arguments are already in their argument registers 577 // due to c2c calling conventions (see calling_convention). 578 for (int i = 0; i < total_args_passed; ++i) { 579 switch(sig_bt[i]) { 580 case T_BOOLEAN: 581 case T_CHAR: 582 case T_BYTE: 583 case T_SHORT: 584 case T_INT: 585 if (ireg < num_java_iarg_registers) { 586 // Put int/ptr in register 587 reg = java_iarg_reg[ireg]; 588 ++ireg; 589 } else { 590 // Put int/ptr on stack. 591 reg = VMRegImpl::stack2reg(stk); 592 stk += inc_stk_for_intfloat; 593 } 594 regs[i].set1(reg); 595 break; 596 case T_LONG: 597 assert(sig_bt[i+1] == T_VOID, "expecting half"); 598 if (ireg < num_java_iarg_registers) { 599 // Put long in register. 600 reg = java_iarg_reg[ireg]; 601 ++ireg; 602 } else { 603 // Put long on stack. They must be aligned to 2 slots. 604 if (stk & 0x1) ++stk; 605 reg = VMRegImpl::stack2reg(stk); 606 stk += inc_stk_for_longdouble; 607 } 608 regs[i].set2(reg); 609 break; 610 case T_OBJECT: 611 case T_ARRAY: 612 case T_ADDRESS: 613 if (ireg < num_java_iarg_registers) { 614 // Put ptr in register. 615 reg = java_iarg_reg[ireg]; 616 ++ireg; 617 } else { 618 // Put ptr on stack. Objects must be aligned to 2 slots too, 619 // because "64-bit pointers record oop-ishness on 2 aligned 620 // adjacent registers." (see OopFlow::build_oop_map). 621 if (stk & 0x1) ++stk; 622 reg = VMRegImpl::stack2reg(stk); 623 stk += inc_stk_for_longdouble; 624 } 625 regs[i].set2(reg); 626 break; 627 case T_FLOAT: 628 if (freg < num_java_farg_registers) { 629 // Put float in register. 630 reg = java_farg_reg[freg]; 631 ++freg; 632 } else { 633 // Put float on stack. 634 reg = VMRegImpl::stack2reg(stk); 635 stk += inc_stk_for_intfloat; 636 } 637 regs[i].set1(reg); 638 break; 639 case T_DOUBLE: 640 assert(sig_bt[i+1] == T_VOID, "expecting half"); 641 if (freg < num_java_farg_registers) { 642 // Put double in register. 643 reg = java_farg_reg[freg]; 644 ++freg; 645 } else { 646 // Put double on stack. They must be aligned to 2 slots. 647 if (stk & 0x1) ++stk; 648 reg = VMRegImpl::stack2reg(stk); 649 stk += inc_stk_for_longdouble; 650 } 651 regs[i].set2(reg); 652 break; 653 case T_VOID: 654 // Do not count halves. 655 regs[i].set_bad(); 656 break; 657 default: 658 ShouldNotReachHere(); 659 } 660 } 661 return round_to(stk, 2); 662 } 663 664 #if defined(COMPILER1) || defined(COMPILER2) 665 // Calling convention for calling C code. 666 int SharedRuntime::c_calling_convention(const BasicType *sig_bt, 667 VMRegPair *regs, 668 VMRegPair *regs2, 669 int total_args_passed) { 670 // Calling conventions for C runtime calls and calls to JNI native methods. 671 // 672 // PPC64 convention: Hoist the first 8 int/ptr/long's in the first 8 673 // int regs, leaving int regs undefined if the arg is flt/dbl. Hoist 674 // the first 13 flt/dbl's in the first 13 fp regs but additionally 675 // copy flt/dbl to the stack if they are beyond the 8th argument. 676 677 const VMReg iarg_reg[8] = { 678 R3->as_VMReg(), 679 R4->as_VMReg(), 680 R5->as_VMReg(), 681 R6->as_VMReg(), 682 R7->as_VMReg(), 683 R8->as_VMReg(), 684 R9->as_VMReg(), 685 R10->as_VMReg() 686 }; 687 688 const VMReg farg_reg[13] = { 689 F1->as_VMReg(), 690 F2->as_VMReg(), 691 F3->as_VMReg(), 692 F4->as_VMReg(), 693 F5->as_VMReg(), 694 F6->as_VMReg(), 695 F7->as_VMReg(), 696 F8->as_VMReg(), 697 F9->as_VMReg(), 698 F10->as_VMReg(), 699 F11->as_VMReg(), 700 F12->as_VMReg(), 701 F13->as_VMReg() 702 }; 703 704 // Check calling conventions consistency. 705 assert(sizeof(iarg_reg) / sizeof(iarg_reg[0]) == Argument::n_int_register_parameters_c && 706 sizeof(farg_reg) / sizeof(farg_reg[0]) == Argument::n_float_register_parameters_c, 707 "consistency"); 708 709 // `Stk' counts stack slots. Due to alignment, 32 bit values occupy 710 // 2 such slots, like 64 bit values do. 711 const int inc_stk_for_intfloat = 2; // 2 slots for ints and floats 712 const int inc_stk_for_longdouble = 2; // 2 slots for longs and doubles 713 714 int i; 715 VMReg reg; 716 // Leave room for C-compatible ABI_REG_ARGS. 717 int stk = (frame::abi_reg_args_size - frame::jit_out_preserve_size) / VMRegImpl::stack_slot_size; 718 int arg = 0; 719 int freg = 0; 720 721 // Avoid passing C arguments in the wrong stack slots. 722 #if defined(ABI_ELFv2) 723 assert((SharedRuntime::out_preserve_stack_slots() + stk) * VMRegImpl::stack_slot_size == 96, 724 "passing C arguments in wrong stack slots"); 725 #else 726 assert((SharedRuntime::out_preserve_stack_slots() + stk) * VMRegImpl::stack_slot_size == 112, 727 "passing C arguments in wrong stack slots"); 728 #endif 729 // We fill-out regs AND regs2 if an argument must be passed in a 730 // register AND in a stack slot. If regs2 is NULL in such a 731 // situation, we bail-out with a fatal error. 732 for (int i = 0; i < total_args_passed; ++i, ++arg) { 733 // Initialize regs2 to BAD. 734 if (regs2 != NULL) regs2[i].set_bad(); 735 736 switch(sig_bt[i]) { 737 738 // 739 // If arguments 0-7 are integers, they are passed in integer registers. 740 // Argument i is placed in iarg_reg[i]. 741 // 742 case T_BOOLEAN: 743 case T_CHAR: 744 case T_BYTE: 745 case T_SHORT: 746 case T_INT: 747 // We must cast ints to longs and use full 64 bit stack slots 748 // here. Thus fall through, handle as long. 749 case T_LONG: 750 case T_OBJECT: 751 case T_ARRAY: 752 case T_ADDRESS: 753 case T_METADATA: 754 // Oops are already boxed if required (JNI). 755 if (arg < Argument::n_int_register_parameters_c) { 756 reg = iarg_reg[arg]; 757 } else { 758 reg = VMRegImpl::stack2reg(stk); 759 stk += inc_stk_for_longdouble; 760 } 761 regs[i].set2(reg); 762 break; 763 764 // 765 // Floats are treated differently from int regs: The first 13 float arguments 766 // are passed in registers (not the float args among the first 13 args). 767 // Thus argument i is NOT passed in farg_reg[i] if it is float. It is passed 768 // in farg_reg[j] if argument i is the j-th float argument of this call. 769 // 770 case T_FLOAT: 771 #if defined(LINUX) 772 // Linux uses ELF ABI. Both original ELF and ELFv2 ABIs have float 773 // in the least significant word of an argument slot. 774 #if defined(VM_LITTLE_ENDIAN) 775 #define FLOAT_WORD_OFFSET_IN_SLOT 0 776 #else 777 #define FLOAT_WORD_OFFSET_IN_SLOT 1 778 #endif 779 #elif defined(AIX) 780 // Although AIX runs on big endian CPU, float is in the most 781 // significant word of an argument slot. 782 #define FLOAT_WORD_OFFSET_IN_SLOT 0 783 #else 784 #error "unknown OS" 785 #endif 786 if (freg < Argument::n_float_register_parameters_c) { 787 // Put float in register ... 788 reg = farg_reg[freg]; 789 ++freg; 790 791 // Argument i for i > 8 is placed on the stack even if it's 792 // placed in a register (if it's a float arg). Aix disassembly 793 // shows that xlC places these float args on the stack AND in 794 // a register. This is not documented, but we follow this 795 // convention, too. 796 if (arg >= Argument::n_regs_not_on_stack_c) { 797 // ... and on the stack. 798 guarantee(regs2 != NULL, "must pass float in register and stack slot"); 799 VMReg reg2 = VMRegImpl::stack2reg(stk + FLOAT_WORD_OFFSET_IN_SLOT); 800 regs2[i].set1(reg2); 801 stk += inc_stk_for_intfloat; 802 } 803 804 } else { 805 // Put float on stack. 806 reg = VMRegImpl::stack2reg(stk + FLOAT_WORD_OFFSET_IN_SLOT); 807 stk += inc_stk_for_intfloat; 808 } 809 regs[i].set1(reg); 810 break; 811 case T_DOUBLE: 812 assert(sig_bt[i+1] == T_VOID, "expecting half"); 813 if (freg < Argument::n_float_register_parameters_c) { 814 // Put double in register ... 815 reg = farg_reg[freg]; 816 ++freg; 817 818 // Argument i for i > 8 is placed on the stack even if it's 819 // placed in a register (if it's a double arg). Aix disassembly 820 // shows that xlC places these float args on the stack AND in 821 // a register. This is not documented, but we follow this 822 // convention, too. 823 if (arg >= Argument::n_regs_not_on_stack_c) { 824 // ... and on the stack. 825 guarantee(regs2 != NULL, "must pass float in register and stack slot"); 826 VMReg reg2 = VMRegImpl::stack2reg(stk); 827 regs2[i].set2(reg2); 828 stk += inc_stk_for_longdouble; 829 } 830 } else { 831 // Put double on stack. 832 reg = VMRegImpl::stack2reg(stk); 833 stk += inc_stk_for_longdouble; 834 } 835 regs[i].set2(reg); 836 break; 837 838 case T_VOID: 839 // Do not count halves. 840 regs[i].set_bad(); 841 --arg; 842 break; 843 default: 844 ShouldNotReachHere(); 845 } 846 } 847 848 return round_to(stk, 2); 849 } 850 #endif // COMPILER2 851 852 static address gen_c2i_adapter(MacroAssembler *masm, 853 int total_args_passed, 854 int comp_args_on_stack, 855 const BasicType *sig_bt, 856 const VMRegPair *regs, 857 Label& call_interpreter, 858 const Register& ientry) { 859 860 address c2i_entrypoint; 861 862 const Register sender_SP = R21_sender_SP; // == R21_tmp1 863 const Register code = R22_tmp2; 864 //const Register ientry = R23_tmp3; 865 const Register value_regs[] = { R24_tmp4, R25_tmp5, R26_tmp6 }; 866 const int num_value_regs = sizeof(value_regs) / sizeof(Register); 867 int value_regs_index = 0; 868 869 const Register return_pc = R27_tmp7; 870 const Register tmp = R28_tmp8; 871 872 assert_different_registers(sender_SP, code, ientry, return_pc, tmp); 873 874 // Adapter needs TOP_IJAVA_FRAME_ABI. 875 const int adapter_size = frame::top_ijava_frame_abi_size + 876 round_to(total_args_passed * wordSize, frame::alignment_in_bytes); 877 878 // regular (verified) c2i entry point 879 c2i_entrypoint = __ pc(); 880 881 // Does compiled code exists? If yes, patch the caller's callsite. 882 __ ld(code, method_(code)); 883 __ cmpdi(CCR0, code, 0); 884 __ ld(ientry, method_(interpreter_entry)); // preloaded 885 __ beq(CCR0, call_interpreter); 886 887 888 // Patch caller's callsite, method_(code) was not NULL which means that 889 // compiled code exists. 890 __ mflr(return_pc); 891 __ std(return_pc, _abi(lr), R1_SP); 892 RegisterSaver::push_frame_and_save_argument_registers(masm, tmp, adapter_size, total_args_passed, regs); 893 894 __ call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::fixup_callers_callsite), R19_method, return_pc); 895 896 RegisterSaver::restore_argument_registers_and_pop_frame(masm, adapter_size, total_args_passed, regs); 897 __ ld(return_pc, _abi(lr), R1_SP); 898 __ ld(ientry, method_(interpreter_entry)); // preloaded 899 __ mtlr(return_pc); 900 901 902 // Call the interpreter. 903 __ BIND(call_interpreter); 904 __ mtctr(ientry); 905 906 // Get a copy of the current SP for loading caller's arguments. 907 __ mr(sender_SP, R1_SP); 908 909 // Add space for the adapter. 910 __ resize_frame(-adapter_size, R12_scratch2); 911 912 int st_off = adapter_size - wordSize; 913 914 // Write the args into the outgoing interpreter space. 915 for (int i = 0; i < total_args_passed; i++) { 916 VMReg r_1 = regs[i].first(); 917 VMReg r_2 = regs[i].second(); 918 if (!r_1->is_valid()) { 919 assert(!r_2->is_valid(), ""); 920 continue; 921 } 922 if (r_1->is_stack()) { 923 Register tmp_reg = value_regs[value_regs_index]; 924 value_regs_index = (value_regs_index + 1) % num_value_regs; 925 // The calling convention produces OptoRegs that ignore the out 926 // preserve area (JIT's ABI). We must account for it here. 927 int ld_off = (r_1->reg2stack() + SharedRuntime::out_preserve_stack_slots()) * VMRegImpl::stack_slot_size; 928 if (!r_2->is_valid()) { 929 __ lwz(tmp_reg, ld_off, sender_SP); 930 } else { 931 __ ld(tmp_reg, ld_off, sender_SP); 932 } 933 // Pretend stack targets were loaded into tmp_reg. 934 r_1 = tmp_reg->as_VMReg(); 935 } 936 937 if (r_1->is_Register()) { 938 Register r = r_1->as_Register(); 939 if (!r_2->is_valid()) { 940 __ stw(r, st_off, R1_SP); 941 st_off-=wordSize; 942 } else { 943 // Longs are given 2 64-bit slots in the interpreter, but the 944 // data is passed in only 1 slot. 945 if (sig_bt[i] == T_LONG || sig_bt[i] == T_DOUBLE) { 946 DEBUG_ONLY( __ li(tmp, 0); __ std(tmp, st_off, R1_SP); ) 947 st_off-=wordSize; 948 } 949 __ std(r, st_off, R1_SP); 950 st_off-=wordSize; 951 } 952 } else { 953 assert(r_1->is_FloatRegister(), ""); 954 FloatRegister f = r_1->as_FloatRegister(); 955 if (!r_2->is_valid()) { 956 __ stfs(f, st_off, R1_SP); 957 st_off-=wordSize; 958 } else { 959 // In 64bit, doubles are given 2 64-bit slots in the interpreter, but the 960 // data is passed in only 1 slot. 961 // One of these should get known junk... 962 DEBUG_ONLY( __ li(tmp, 0); __ std(tmp, st_off, R1_SP); ) 963 st_off-=wordSize; 964 __ stfd(f, st_off, R1_SP); 965 st_off-=wordSize; 966 } 967 } 968 } 969 970 // Jump to the interpreter just as if interpreter was doing it. 971 972 __ load_const_optimized(R25_templateTableBase, (address)Interpreter::dispatch_table((TosState)0), R11_scratch1); 973 974 // load TOS 975 __ addi(R15_esp, R1_SP, st_off); 976 977 // Frame_manager expects initial_caller_sp (= SP without resize by c2i) in R21_tmp1. 978 assert(sender_SP == R21_sender_SP, "passing initial caller's SP in wrong register"); 979 __ bctr(); 980 981 return c2i_entrypoint; 982 } 983 984 void SharedRuntime::gen_i2c_adapter(MacroAssembler *masm, 985 int total_args_passed, 986 int comp_args_on_stack, 987 const BasicType *sig_bt, 988 const VMRegPair *regs) { 989 990 // Load method's entry-point from method. 991 __ ld(R12_scratch2, in_bytes(Method::from_compiled_offset()), R19_method); 992 __ mtctr(R12_scratch2); 993 994 // We will only enter here from an interpreted frame and never from after 995 // passing thru a c2i. Azul allowed this but we do not. If we lose the 996 // race and use a c2i we will remain interpreted for the race loser(s). 997 // This removes all sorts of headaches on the x86 side and also eliminates 998 // the possibility of having c2i -> i2c -> c2i -> ... endless transitions. 999 1000 // Note: r13 contains the senderSP on entry. We must preserve it since 1001 // we may do a i2c -> c2i transition if we lose a race where compiled 1002 // code goes non-entrant while we get args ready. 1003 // In addition we use r13 to locate all the interpreter args as 1004 // we must align the stack to 16 bytes on an i2c entry else we 1005 // lose alignment we expect in all compiled code and register 1006 // save code can segv when fxsave instructions find improperly 1007 // aligned stack pointer. 1008 1009 const Register ld_ptr = R15_esp; 1010 const Register value_regs[] = { R22_tmp2, R23_tmp3, R24_tmp4, R25_tmp5, R26_tmp6 }; 1011 const int num_value_regs = sizeof(value_regs) / sizeof(Register); 1012 int value_regs_index = 0; 1013 1014 int ld_offset = total_args_passed*wordSize; 1015 1016 // Cut-out for having no stack args. Since up to 2 int/oop args are passed 1017 // in registers, we will occasionally have no stack args. 1018 int comp_words_on_stack = 0; 1019 if (comp_args_on_stack) { 1020 // Sig words on the stack are greater-than VMRegImpl::stack0. Those in 1021 // registers are below. By subtracting stack0, we either get a negative 1022 // number (all values in registers) or the maximum stack slot accessed. 1023 1024 // Convert 4-byte c2 stack slots to words. 1025 comp_words_on_stack = round_to(comp_args_on_stack*VMRegImpl::stack_slot_size, wordSize)>>LogBytesPerWord; 1026 // Round up to miminum stack alignment, in wordSize. 1027 comp_words_on_stack = round_to(comp_words_on_stack, 2); 1028 __ resize_frame(-comp_words_on_stack * wordSize, R11_scratch1); 1029 } 1030 1031 // Now generate the shuffle code. Pick up all register args and move the 1032 // rest through register value=Z_R12. 1033 BLOCK_COMMENT("Shuffle arguments"); 1034 for (int i = 0; i < total_args_passed; i++) { 1035 if (sig_bt[i] == T_VOID) { 1036 assert(i > 0 && (sig_bt[i-1] == T_LONG || sig_bt[i-1] == T_DOUBLE), "missing half"); 1037 continue; 1038 } 1039 1040 // Pick up 0, 1 or 2 words from ld_ptr. 1041 assert(!regs[i].second()->is_valid() || regs[i].first()->next() == regs[i].second(), 1042 "scrambled load targets?"); 1043 VMReg r_1 = regs[i].first(); 1044 VMReg r_2 = regs[i].second(); 1045 if (!r_1->is_valid()) { 1046 assert(!r_2->is_valid(), ""); 1047 continue; 1048 } 1049 if (r_1->is_FloatRegister()) { 1050 if (!r_2->is_valid()) { 1051 __ lfs(r_1->as_FloatRegister(), ld_offset, ld_ptr); 1052 ld_offset-=wordSize; 1053 } else { 1054 // Skip the unused interpreter slot. 1055 __ lfd(r_1->as_FloatRegister(), ld_offset-wordSize, ld_ptr); 1056 ld_offset-=2*wordSize; 1057 } 1058 } else { 1059 Register r; 1060 if (r_1->is_stack()) { 1061 // Must do a memory to memory move thru "value". 1062 r = value_regs[value_regs_index]; 1063 value_regs_index = (value_regs_index + 1) % num_value_regs; 1064 } else { 1065 r = r_1->as_Register(); 1066 } 1067 if (!r_2->is_valid()) { 1068 // Not sure we need to do this but it shouldn't hurt. 1069 if (sig_bt[i] == T_OBJECT || sig_bt[i] == T_ADDRESS || sig_bt[i] == T_ARRAY) { 1070 __ ld(r, ld_offset, ld_ptr); 1071 ld_offset-=wordSize; 1072 } else { 1073 __ lwz(r, ld_offset, ld_ptr); 1074 ld_offset-=wordSize; 1075 } 1076 } else { 1077 // In 64bit, longs are given 2 64-bit slots in the interpreter, but the 1078 // data is passed in only 1 slot. 1079 if (sig_bt[i] == T_LONG || sig_bt[i] == T_DOUBLE) { 1080 ld_offset-=wordSize; 1081 } 1082 __ ld(r, ld_offset, ld_ptr); 1083 ld_offset-=wordSize; 1084 } 1085 1086 if (r_1->is_stack()) { 1087 // Now store value where the compiler expects it 1088 int st_off = (r_1->reg2stack() + SharedRuntime::out_preserve_stack_slots())*VMRegImpl::stack_slot_size; 1089 1090 if (sig_bt[i] == T_INT || sig_bt[i] == T_FLOAT ||sig_bt[i] == T_BOOLEAN || 1091 sig_bt[i] == T_SHORT || sig_bt[i] == T_CHAR || sig_bt[i] == T_BYTE) { 1092 __ stw(r, st_off, R1_SP); 1093 } else { 1094 __ std(r, st_off, R1_SP); 1095 } 1096 } 1097 } 1098 } 1099 1100 BLOCK_COMMENT("Store method"); 1101 // Store method into thread->callee_target. 1102 // We might end up in handle_wrong_method if the callee is 1103 // deoptimized as we race thru here. If that happens we don't want 1104 // to take a safepoint because the caller frame will look 1105 // interpreted and arguments are now "compiled" so it is much better 1106 // to make this transition invisible to the stack walking 1107 // code. Unfortunately if we try and find the callee by normal means 1108 // a safepoint is possible. So we stash the desired callee in the 1109 // thread and the vm will find there should this case occur. 1110 __ std(R19_method, thread_(callee_target)); 1111 1112 // Jump to the compiled code just as if compiled code was doing it. 1113 __ bctr(); 1114 } 1115 1116 AdapterHandlerEntry* SharedRuntime::generate_i2c2i_adapters(MacroAssembler *masm, 1117 int total_args_passed, 1118 int comp_args_on_stack, 1119 const BasicType *sig_bt, 1120 const VMRegPair *regs, 1121 AdapterFingerPrint* fingerprint) { 1122 address i2c_entry; 1123 address c2i_unverified_entry; 1124 address c2i_entry; 1125 1126 1127 // entry: i2c 1128 1129 __ align(CodeEntryAlignment); 1130 i2c_entry = __ pc(); 1131 gen_i2c_adapter(masm, total_args_passed, comp_args_on_stack, sig_bt, regs); 1132 1133 1134 // entry: c2i unverified 1135 1136 __ align(CodeEntryAlignment); 1137 BLOCK_COMMENT("c2i unverified entry"); 1138 c2i_unverified_entry = __ pc(); 1139 1140 // inline_cache contains a compiledICHolder 1141 const Register ic = R19_method; 1142 const Register ic_klass = R11_scratch1; 1143 const Register receiver_klass = R12_scratch2; 1144 const Register code = R21_tmp1; 1145 const Register ientry = R23_tmp3; 1146 1147 assert_different_registers(ic, ic_klass, receiver_klass, R3_ARG1, code, ientry); 1148 assert(R11_scratch1 == R11, "need prologue scratch register"); 1149 1150 Label call_interpreter; 1151 1152 assert(!MacroAssembler::needs_explicit_null_check(oopDesc::klass_offset_in_bytes()), 1153 "klass offset should reach into any page"); 1154 // Check for NULL argument if we don't have implicit null checks. 1155 if (!ImplicitNullChecks || !os::zero_page_read_protected()) { 1156 if (TrapBasedNullChecks) { 1157 __ trap_null_check(R3_ARG1); 1158 } else { 1159 Label valid; 1160 __ cmpdi(CCR0, R3_ARG1, 0); 1161 __ bne_predict_taken(CCR0, valid); 1162 // We have a null argument, branch to ic_miss_stub. 1163 __ b64_patchable((address)SharedRuntime::get_ic_miss_stub(), 1164 relocInfo::runtime_call_type); 1165 __ BIND(valid); 1166 } 1167 } 1168 // Assume argument is not NULL, load klass from receiver. 1169 __ load_klass(receiver_klass, R3_ARG1); 1170 1171 __ ld(ic_klass, CompiledICHolder::holder_klass_offset(), ic); 1172 1173 if (TrapBasedICMissChecks) { 1174 __ trap_ic_miss_check(receiver_klass, ic_klass); 1175 } else { 1176 Label valid; 1177 __ cmpd(CCR0, receiver_klass, ic_klass); 1178 __ beq_predict_taken(CCR0, valid); 1179 // We have an unexpected klass, branch to ic_miss_stub. 1180 __ b64_patchable((address)SharedRuntime::get_ic_miss_stub(), 1181 relocInfo::runtime_call_type); 1182 __ BIND(valid); 1183 } 1184 1185 // Argument is valid and klass is as expected, continue. 1186 1187 // Extract method from inline cache, verified entry point needs it. 1188 __ ld(R19_method, CompiledICHolder::holder_method_offset(), ic); 1189 assert(R19_method == ic, "the inline cache register is dead here"); 1190 1191 __ ld(code, method_(code)); 1192 __ cmpdi(CCR0, code, 0); 1193 __ ld(ientry, method_(interpreter_entry)); // preloaded 1194 __ beq_predict_taken(CCR0, call_interpreter); 1195 1196 // Branch to ic_miss_stub. 1197 __ b64_patchable((address)SharedRuntime::get_ic_miss_stub(), relocInfo::runtime_call_type); 1198 1199 // entry: c2i 1200 1201 c2i_entry = gen_c2i_adapter(masm, total_args_passed, comp_args_on_stack, sig_bt, regs, call_interpreter, ientry); 1202 1203 return AdapterHandlerLibrary::new_entry(fingerprint, i2c_entry, c2i_entry, c2i_unverified_entry); 1204 } 1205 1206 #ifdef COMPILER2 1207 // An oop arg. Must pass a handle not the oop itself. 1208 static void object_move(MacroAssembler* masm, 1209 int frame_size_in_slots, 1210 OopMap* oop_map, int oop_handle_offset, 1211 bool is_receiver, int* receiver_offset, 1212 VMRegPair src, VMRegPair dst, 1213 Register r_caller_sp, Register r_temp_1, Register r_temp_2) { 1214 assert(!is_receiver || (is_receiver && (*receiver_offset == -1)), 1215 "receiver has already been moved"); 1216 1217 // We must pass a handle. First figure out the location we use as a handle. 1218 1219 if (src.first()->is_stack()) { 1220 // stack to stack or reg 1221 1222 const Register r_handle = dst.first()->is_stack() ? r_temp_1 : dst.first()->as_Register(); 1223 Label skip; 1224 const int oop_slot_in_callers_frame = reg2slot(src.first()); 1225 1226 guarantee(!is_receiver, "expecting receiver in register"); 1227 oop_map->set_oop(VMRegImpl::stack2reg(oop_slot_in_callers_frame + frame_size_in_slots)); 1228 1229 __ addi(r_handle, r_caller_sp, reg2offset(src.first())); 1230 __ ld( r_temp_2, reg2offset(src.first()), r_caller_sp); 1231 __ cmpdi(CCR0, r_temp_2, 0); 1232 __ bne(CCR0, skip); 1233 // Use a NULL handle if oop is NULL. 1234 __ li(r_handle, 0); 1235 __ bind(skip); 1236 1237 if (dst.first()->is_stack()) { 1238 // stack to stack 1239 __ std(r_handle, reg2offset(dst.first()), R1_SP); 1240 } else { 1241 // stack to reg 1242 // Nothing to do, r_handle is already the dst register. 1243 } 1244 } else { 1245 // reg to stack or reg 1246 const Register r_oop = src.first()->as_Register(); 1247 const Register r_handle = dst.first()->is_stack() ? r_temp_1 : dst.first()->as_Register(); 1248 const int oop_slot = (r_oop->encoding()-R3_ARG1->encoding()) * VMRegImpl::slots_per_word 1249 + oop_handle_offset; // in slots 1250 const int oop_offset = oop_slot * VMRegImpl::stack_slot_size; 1251 Label skip; 1252 1253 if (is_receiver) { 1254 *receiver_offset = oop_offset; 1255 } 1256 oop_map->set_oop(VMRegImpl::stack2reg(oop_slot)); 1257 1258 __ std( r_oop, oop_offset, R1_SP); 1259 __ addi(r_handle, R1_SP, oop_offset); 1260 1261 __ cmpdi(CCR0, r_oop, 0); 1262 __ bne(CCR0, skip); 1263 // Use a NULL handle if oop is NULL. 1264 __ li(r_handle, 0); 1265 __ bind(skip); 1266 1267 if (dst.first()->is_stack()) { 1268 // reg to stack 1269 __ std(r_handle, reg2offset(dst.first()), R1_SP); 1270 } else { 1271 // reg to reg 1272 // Nothing to do, r_handle is already the dst register. 1273 } 1274 } 1275 } 1276 1277 static void int_move(MacroAssembler*masm, 1278 VMRegPair src, VMRegPair dst, 1279 Register r_caller_sp, Register r_temp) { 1280 assert(src.first()->is_valid(), "incoming must be int"); 1281 assert(dst.first()->is_valid() && dst.second() == dst.first()->next(), "outgoing must be long"); 1282 1283 if (src.first()->is_stack()) { 1284 if (dst.first()->is_stack()) { 1285 // stack to stack 1286 __ lwa(r_temp, reg2offset(src.first()), r_caller_sp); 1287 __ std(r_temp, reg2offset(dst.first()), R1_SP); 1288 } else { 1289 // stack to reg 1290 __ lwa(dst.first()->as_Register(), reg2offset(src.first()), r_caller_sp); 1291 } 1292 } else if (dst.first()->is_stack()) { 1293 // reg to stack 1294 __ extsw(r_temp, src.first()->as_Register()); 1295 __ std(r_temp, reg2offset(dst.first()), R1_SP); 1296 } else { 1297 // reg to reg 1298 __ extsw(dst.first()->as_Register(), src.first()->as_Register()); 1299 } 1300 } 1301 1302 static void long_move(MacroAssembler*masm, 1303 VMRegPair src, VMRegPair dst, 1304 Register r_caller_sp, Register r_temp) { 1305 assert(src.first()->is_valid() && src.second() == src.first()->next(), "incoming must be long"); 1306 assert(dst.first()->is_valid() && dst.second() == dst.first()->next(), "outgoing must be long"); 1307 1308 if (src.first()->is_stack()) { 1309 if (dst.first()->is_stack()) { 1310 // stack to stack 1311 __ ld( r_temp, reg2offset(src.first()), r_caller_sp); 1312 __ std(r_temp, reg2offset(dst.first()), R1_SP); 1313 } else { 1314 // stack to reg 1315 __ ld(dst.first()->as_Register(), reg2offset(src.first()), r_caller_sp); 1316 } 1317 } else if (dst.first()->is_stack()) { 1318 // reg to stack 1319 __ std(src.first()->as_Register(), reg2offset(dst.first()), R1_SP); 1320 } else { 1321 // reg to reg 1322 if (dst.first()->as_Register() != src.first()->as_Register()) 1323 __ mr(dst.first()->as_Register(), src.first()->as_Register()); 1324 } 1325 } 1326 1327 static void float_move(MacroAssembler*masm, 1328 VMRegPair src, VMRegPair dst, 1329 Register r_caller_sp, Register r_temp) { 1330 assert(src.first()->is_valid() && !src.second()->is_valid(), "incoming must be float"); 1331 assert(dst.first()->is_valid() && !dst.second()->is_valid(), "outgoing must be float"); 1332 1333 if (src.first()->is_stack()) { 1334 if (dst.first()->is_stack()) { 1335 // stack to stack 1336 __ lwz(r_temp, reg2offset(src.first()), r_caller_sp); 1337 __ stw(r_temp, reg2offset(dst.first()), R1_SP); 1338 } else { 1339 // stack to reg 1340 __ lfs(dst.first()->as_FloatRegister(), reg2offset(src.first()), r_caller_sp); 1341 } 1342 } else if (dst.first()->is_stack()) { 1343 // reg to stack 1344 __ stfs(src.first()->as_FloatRegister(), reg2offset(dst.first()), R1_SP); 1345 } else { 1346 // reg to reg 1347 if (dst.first()->as_FloatRegister() != src.first()->as_FloatRegister()) 1348 __ fmr(dst.first()->as_FloatRegister(), src.first()->as_FloatRegister()); 1349 } 1350 } 1351 1352 static void double_move(MacroAssembler*masm, 1353 VMRegPair src, VMRegPair dst, 1354 Register r_caller_sp, Register r_temp) { 1355 assert(src.first()->is_valid() && src.second() == src.first()->next(), "incoming must be double"); 1356 assert(dst.first()->is_valid() && dst.second() == dst.first()->next(), "outgoing must be double"); 1357 1358 if (src.first()->is_stack()) { 1359 if (dst.first()->is_stack()) { 1360 // stack to stack 1361 __ ld( r_temp, reg2offset(src.first()), r_caller_sp); 1362 __ std(r_temp, reg2offset(dst.first()), R1_SP); 1363 } else { 1364 // stack to reg 1365 __ lfd(dst.first()->as_FloatRegister(), reg2offset(src.first()), r_caller_sp); 1366 } 1367 } else if (dst.first()->is_stack()) { 1368 // reg to stack 1369 __ stfd(src.first()->as_FloatRegister(), reg2offset(dst.first()), R1_SP); 1370 } else { 1371 // reg to reg 1372 if (dst.first()->as_FloatRegister() != src.first()->as_FloatRegister()) 1373 __ fmr(dst.first()->as_FloatRegister(), src.first()->as_FloatRegister()); 1374 } 1375 } 1376 1377 void SharedRuntime::save_native_result(MacroAssembler *masm, BasicType ret_type, int frame_slots) { 1378 switch (ret_type) { 1379 case T_BOOLEAN: 1380 case T_CHAR: 1381 case T_BYTE: 1382 case T_SHORT: 1383 case T_INT: 1384 __ stw (R3_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1385 break; 1386 case T_ARRAY: 1387 case T_OBJECT: 1388 case T_LONG: 1389 __ std (R3_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1390 break; 1391 case T_FLOAT: 1392 __ stfs(F1_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1393 break; 1394 case T_DOUBLE: 1395 __ stfd(F1_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1396 break; 1397 case T_VOID: 1398 break; 1399 default: 1400 ShouldNotReachHere(); 1401 break; 1402 } 1403 } 1404 1405 void SharedRuntime::restore_native_result(MacroAssembler *masm, BasicType ret_type, int frame_slots) { 1406 switch (ret_type) { 1407 case T_BOOLEAN: 1408 case T_CHAR: 1409 case T_BYTE: 1410 case T_SHORT: 1411 case T_INT: 1412 __ lwz(R3_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1413 break; 1414 case T_ARRAY: 1415 case T_OBJECT: 1416 case T_LONG: 1417 __ ld (R3_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1418 break; 1419 case T_FLOAT: 1420 __ lfs(F1_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1421 break; 1422 case T_DOUBLE: 1423 __ lfd(F1_RET, frame_slots*VMRegImpl::stack_slot_size, R1_SP); 1424 break; 1425 case T_VOID: 1426 break; 1427 default: 1428 ShouldNotReachHere(); 1429 break; 1430 } 1431 } 1432 1433 static void save_or_restore_arguments(MacroAssembler* masm, 1434 const int stack_slots, 1435 const int total_in_args, 1436 const int arg_save_area, 1437 OopMap* map, 1438 VMRegPair* in_regs, 1439 BasicType* in_sig_bt) { 1440 // If map is non-NULL then the code should store the values, 1441 // otherwise it should load them. 1442 int slot = arg_save_area; 1443 // Save down double word first. 1444 for (int i = 0; i < total_in_args; i++) { 1445 if (in_regs[i].first()->is_FloatRegister() && in_sig_bt[i] == T_DOUBLE) { 1446 int offset = slot * VMRegImpl::stack_slot_size; 1447 slot += VMRegImpl::slots_per_word; 1448 assert(slot <= stack_slots, "overflow (after DOUBLE stack slot)"); 1449 if (map != NULL) { 1450 __ stfd(in_regs[i].first()->as_FloatRegister(), offset, R1_SP); 1451 } else { 1452 __ lfd(in_regs[i].first()->as_FloatRegister(), offset, R1_SP); 1453 } 1454 } else if (in_regs[i].first()->is_Register() && 1455 (in_sig_bt[i] == T_LONG || in_sig_bt[i] == T_ARRAY)) { 1456 int offset = slot * VMRegImpl::stack_slot_size; 1457 if (map != NULL) { 1458 __ std(in_regs[i].first()->as_Register(), offset, R1_SP); 1459 if (in_sig_bt[i] == T_ARRAY) { 1460 map->set_oop(VMRegImpl::stack2reg(slot)); 1461 } 1462 } else { 1463 __ ld(in_regs[i].first()->as_Register(), offset, R1_SP); 1464 } 1465 slot += VMRegImpl::slots_per_word; 1466 assert(slot <= stack_slots, "overflow (after LONG/ARRAY stack slot)"); 1467 } 1468 } 1469 // Save or restore single word registers. 1470 for (int i = 0; i < total_in_args; i++) { 1471 // PPC64: pass ints as longs: must only deal with floats here. 1472 if (in_regs[i].first()->is_FloatRegister()) { 1473 if (in_sig_bt[i] == T_FLOAT) { 1474 int offset = slot * VMRegImpl::stack_slot_size; 1475 slot++; 1476 assert(slot <= stack_slots, "overflow (after FLOAT stack slot)"); 1477 if (map != NULL) { 1478 __ stfs(in_regs[i].first()->as_FloatRegister(), offset, R1_SP); 1479 } else { 1480 __ lfs(in_regs[i].first()->as_FloatRegister(), offset, R1_SP); 1481 } 1482 } 1483 } else if (in_regs[i].first()->is_stack()) { 1484 if (in_sig_bt[i] == T_ARRAY && map != NULL) { 1485 int offset_in_older_frame = in_regs[i].first()->reg2stack() + SharedRuntime::out_preserve_stack_slots(); 1486 map->set_oop(VMRegImpl::stack2reg(offset_in_older_frame + stack_slots)); 1487 } 1488 } 1489 } 1490 } 1491 1492 // Check GCLocker::needs_gc and enter the runtime if it's true. This 1493 // keeps a new JNI critical region from starting until a GC has been 1494 // forced. Save down any oops in registers and describe them in an 1495 // OopMap. 1496 static void check_needs_gc_for_critical_native(MacroAssembler* masm, 1497 const int stack_slots, 1498 const int total_in_args, 1499 const int arg_save_area, 1500 OopMapSet* oop_maps, 1501 VMRegPair* in_regs, 1502 BasicType* in_sig_bt, 1503 Register tmp_reg ) { 1504 __ block_comment("check GCLocker::needs_gc"); 1505 Label cont; 1506 __ lbz(tmp_reg, (RegisterOrConstant)(intptr_t)GCLocker::needs_gc_address()); 1507 __ cmplwi(CCR0, tmp_reg, 0); 1508 __ beq(CCR0, cont); 1509 1510 // Save down any values that are live in registers and call into the 1511 // runtime to halt for a GC. 1512 OopMap* map = new OopMap(stack_slots * 2, 0 /* arg_slots*/); 1513 save_or_restore_arguments(masm, stack_slots, total_in_args, 1514 arg_save_area, map, in_regs, in_sig_bt); 1515 1516 __ mr(R3_ARG1, R16_thread); 1517 __ set_last_Java_frame(R1_SP, noreg); 1518 1519 __ block_comment("block_for_jni_critical"); 1520 address entry_point = CAST_FROM_FN_PTR(address, SharedRuntime::block_for_jni_critical); 1521 #if defined(ABI_ELFv2) 1522 __ call_c(entry_point, relocInfo::runtime_call_type); 1523 #else 1524 __ call_c(CAST_FROM_FN_PTR(FunctionDescriptor*, entry_point), relocInfo::runtime_call_type); 1525 #endif 1526 address start = __ pc() - __ offset(), 1527 calls_return_pc = __ last_calls_return_pc(); 1528 oop_maps->add_gc_map(calls_return_pc - start, map); 1529 1530 __ reset_last_Java_frame(); 1531 1532 // Reload all the register arguments. 1533 save_or_restore_arguments(masm, stack_slots, total_in_args, 1534 arg_save_area, NULL, in_regs, in_sig_bt); 1535 1536 __ BIND(cont); 1537 1538 #ifdef ASSERT 1539 if (StressCriticalJNINatives) { 1540 // Stress register saving. 1541 OopMap* map = new OopMap(stack_slots * 2, 0 /* arg_slots*/); 1542 save_or_restore_arguments(masm, stack_slots, total_in_args, 1543 arg_save_area, map, in_regs, in_sig_bt); 1544 // Destroy argument registers. 1545 for (int i = 0; i < total_in_args; i++) { 1546 if (in_regs[i].first()->is_Register()) { 1547 const Register reg = in_regs[i].first()->as_Register(); 1548 __ neg(reg, reg); 1549 } else if (in_regs[i].first()->is_FloatRegister()) { 1550 __ fneg(in_regs[i].first()->as_FloatRegister(), in_regs[i].first()->as_FloatRegister()); 1551 } 1552 } 1553 1554 save_or_restore_arguments(masm, stack_slots, total_in_args, 1555 arg_save_area, NULL, in_regs, in_sig_bt); 1556 } 1557 #endif 1558 } 1559 1560 static void move_ptr(MacroAssembler* masm, VMRegPair src, VMRegPair dst, Register r_caller_sp, Register r_temp) { 1561 if (src.first()->is_stack()) { 1562 if (dst.first()->is_stack()) { 1563 // stack to stack 1564 __ ld(r_temp, reg2offset(src.first()), r_caller_sp); 1565 __ std(r_temp, reg2offset(dst.first()), R1_SP); 1566 } else { 1567 // stack to reg 1568 __ ld(dst.first()->as_Register(), reg2offset(src.first()), r_caller_sp); 1569 } 1570 } else if (dst.first()->is_stack()) { 1571 // reg to stack 1572 __ std(src.first()->as_Register(), reg2offset(dst.first()), R1_SP); 1573 } else { 1574 if (dst.first() != src.first()) { 1575 __ mr(dst.first()->as_Register(), src.first()->as_Register()); 1576 } 1577 } 1578 } 1579 1580 // Unpack an array argument into a pointer to the body and the length 1581 // if the array is non-null, otherwise pass 0 for both. 1582 static void unpack_array_argument(MacroAssembler* masm, VMRegPair reg, BasicType in_elem_type, 1583 VMRegPair body_arg, VMRegPair length_arg, Register r_caller_sp, 1584 Register tmp_reg, Register tmp2_reg) { 1585 assert(!body_arg.first()->is_Register() || body_arg.first()->as_Register() != tmp_reg, 1586 "possible collision"); 1587 assert(!length_arg.first()->is_Register() || length_arg.first()->as_Register() != tmp_reg, 1588 "possible collision"); 1589 1590 // Pass the length, ptr pair. 1591 Label set_out_args; 1592 VMRegPair tmp, tmp2; 1593 tmp.set_ptr(tmp_reg->as_VMReg()); 1594 tmp2.set_ptr(tmp2_reg->as_VMReg()); 1595 if (reg.first()->is_stack()) { 1596 // Load the arg up from the stack. 1597 move_ptr(masm, reg, tmp, r_caller_sp, /*unused*/ R0); 1598 reg = tmp; 1599 } 1600 __ li(tmp2_reg, 0); // Pass zeros if Array=null. 1601 if (tmp_reg != reg.first()->as_Register()) __ li(tmp_reg, 0); 1602 __ cmpdi(CCR0, reg.first()->as_Register(), 0); 1603 __ beq(CCR0, set_out_args); 1604 __ lwa(tmp2_reg, arrayOopDesc::length_offset_in_bytes(), reg.first()->as_Register()); 1605 __ addi(tmp_reg, reg.first()->as_Register(), arrayOopDesc::base_offset_in_bytes(in_elem_type)); 1606 __ bind(set_out_args); 1607 move_ptr(masm, tmp, body_arg, r_caller_sp, /*unused*/ R0); 1608 move_ptr(masm, tmp2, length_arg, r_caller_sp, /*unused*/ R0); // Same as move32_64 on PPC64. 1609 } 1610 1611 static void verify_oop_args(MacroAssembler* masm, 1612 methodHandle method, 1613 const BasicType* sig_bt, 1614 const VMRegPair* regs) { 1615 Register temp_reg = R19_method; // not part of any compiled calling seq 1616 if (VerifyOops) { 1617 for (int i = 0; i < method->size_of_parameters(); i++) { 1618 if (sig_bt[i] == T_OBJECT || 1619 sig_bt[i] == T_ARRAY) { 1620 VMReg r = regs[i].first(); 1621 assert(r->is_valid(), "bad oop arg"); 1622 if (r->is_stack()) { 1623 __ ld(temp_reg, reg2offset(r), R1_SP); 1624 __ verify_oop(temp_reg); 1625 } else { 1626 __ verify_oop(r->as_Register()); 1627 } 1628 } 1629 } 1630 } 1631 } 1632 1633 static void gen_special_dispatch(MacroAssembler* masm, 1634 methodHandle method, 1635 const BasicType* sig_bt, 1636 const VMRegPair* regs) { 1637 verify_oop_args(masm, method, sig_bt, regs); 1638 vmIntrinsics::ID iid = method->intrinsic_id(); 1639 1640 // Now write the args into the outgoing interpreter space 1641 bool has_receiver = false; 1642 Register receiver_reg = noreg; 1643 int member_arg_pos = -1; 1644 Register member_reg = noreg; 1645 int ref_kind = MethodHandles::signature_polymorphic_intrinsic_ref_kind(iid); 1646 if (ref_kind != 0) { 1647 member_arg_pos = method->size_of_parameters() - 1; // trailing MemberName argument 1648 member_reg = R19_method; // known to be free at this point 1649 has_receiver = MethodHandles::ref_kind_has_receiver(ref_kind); 1650 } else if (iid == vmIntrinsics::_invokeBasic) { 1651 has_receiver = true; 1652 } else { 1653 fatal("unexpected intrinsic id %d", iid); 1654 } 1655 1656 if (member_reg != noreg) { 1657 // Load the member_arg into register, if necessary. 1658 SharedRuntime::check_member_name_argument_is_last_argument(method, sig_bt, regs); 1659 VMReg r = regs[member_arg_pos].first(); 1660 if (r->is_stack()) { 1661 __ ld(member_reg, reg2offset(r), R1_SP); 1662 } else { 1663 // no data motion is needed 1664 member_reg = r->as_Register(); 1665 } 1666 } 1667 1668 if (has_receiver) { 1669 // Make sure the receiver is loaded into a register. 1670 assert(method->size_of_parameters() > 0, "oob"); 1671 assert(sig_bt[0] == T_OBJECT, "receiver argument must be an object"); 1672 VMReg r = regs[0].first(); 1673 assert(r->is_valid(), "bad receiver arg"); 1674 if (r->is_stack()) { 1675 // Porting note: This assumes that compiled calling conventions always 1676 // pass the receiver oop in a register. If this is not true on some 1677 // platform, pick a temp and load the receiver from stack. 1678 fatal("receiver always in a register"); 1679 receiver_reg = R11_scratch1; // TODO (hs24): is R11_scratch1 really free at this point? 1680 __ ld(receiver_reg, reg2offset(r), R1_SP); 1681 } else { 1682 // no data motion is needed 1683 receiver_reg = r->as_Register(); 1684 } 1685 } 1686 1687 // Figure out which address we are really jumping to: 1688 MethodHandles::generate_method_handle_dispatch(masm, iid, 1689 receiver_reg, member_reg, /*for_compiler_entry:*/ true); 1690 } 1691 1692 #endif // COMPILER2 1693 1694 // --------------------------------------------------------------------------- 1695 // Generate a native wrapper for a given method. The method takes arguments 1696 // in the Java compiled code convention, marshals them to the native 1697 // convention (handlizes oops, etc), transitions to native, makes the call, 1698 // returns to java state (possibly blocking), unhandlizes any result and 1699 // returns. 1700 // 1701 // Critical native functions are a shorthand for the use of 1702 // GetPrimtiveArrayCritical and disallow the use of any other JNI 1703 // functions. The wrapper is expected to unpack the arguments before 1704 // passing them to the callee and perform checks before and after the 1705 // native call to ensure that they GCLocker 1706 // lock_critical/unlock_critical semantics are followed. Some other 1707 // parts of JNI setup are skipped like the tear down of the JNI handle 1708 // block and the check for pending exceptions it's impossible for them 1709 // to be thrown. 1710 // 1711 // They are roughly structured like this: 1712 // if (GCLocker::needs_gc()) 1713 // SharedRuntime::block_for_jni_critical(); 1714 // tranistion to thread_in_native 1715 // unpack arrray arguments and call native entry point 1716 // check for safepoint in progress 1717 // check if any thread suspend flags are set 1718 // call into JVM and possible unlock the JNI critical 1719 // if a GC was suppressed while in the critical native. 1720 // transition back to thread_in_Java 1721 // return to caller 1722 // 1723 nmethod *SharedRuntime::generate_native_wrapper(MacroAssembler *masm, 1724 const methodHandle& method, 1725 int compile_id, 1726 BasicType *in_sig_bt, 1727 VMRegPair *in_regs, 1728 BasicType ret_type) { 1729 #ifdef COMPILER2 1730 if (method->is_method_handle_intrinsic()) { 1731 vmIntrinsics::ID iid = method->intrinsic_id(); 1732 intptr_t start = (intptr_t)__ pc(); 1733 int vep_offset = ((intptr_t)__ pc()) - start; 1734 gen_special_dispatch(masm, 1735 method, 1736 in_sig_bt, 1737 in_regs); 1738 int frame_complete = ((intptr_t)__ pc()) - start; // not complete, period 1739 __ flush(); 1740 int stack_slots = SharedRuntime::out_preserve_stack_slots(); // no out slots at all, actually 1741 return nmethod::new_native_nmethod(method, 1742 compile_id, 1743 masm->code(), 1744 vep_offset, 1745 frame_complete, 1746 stack_slots / VMRegImpl::slots_per_word, 1747 in_ByteSize(-1), 1748 in_ByteSize(-1), 1749 (OopMapSet*)NULL); 1750 } 1751 1752 bool is_critical_native = true; 1753 address native_func = method->critical_native_function(); 1754 if (native_func == NULL) { 1755 native_func = method->native_function(); 1756 is_critical_native = false; 1757 } 1758 assert(native_func != NULL, "must have function"); 1759 1760 // First, create signature for outgoing C call 1761 // -------------------------------------------------------------------------- 1762 1763 int total_in_args = method->size_of_parameters(); 1764 // We have received a description of where all the java args are located 1765 // on entry to the wrapper. We need to convert these args to where 1766 // the jni function will expect them. To figure out where they go 1767 // we convert the java signature to a C signature by inserting 1768 // the hidden arguments as arg[0] and possibly arg[1] (static method) 1769 1770 // Calculate the total number of C arguments and create arrays for the 1771 // signature and the outgoing registers. 1772 // On ppc64, we have two arrays for the outgoing registers, because 1773 // some floating-point arguments must be passed in registers _and_ 1774 // in stack locations. 1775 bool method_is_static = method->is_static(); 1776 int total_c_args = total_in_args; 1777 1778 if (!is_critical_native) { 1779 int n_hidden_args = method_is_static ? 2 : 1; 1780 total_c_args += n_hidden_args; 1781 } else { 1782 // No JNIEnv*, no this*, but unpacked arrays (base+length). 1783 for (int i = 0; i < total_in_args; i++) { 1784 if (in_sig_bt[i] == T_ARRAY) { 1785 total_c_args++; 1786 } 1787 } 1788 } 1789 1790 BasicType *out_sig_bt = NEW_RESOURCE_ARRAY(BasicType, total_c_args); 1791 VMRegPair *out_regs = NEW_RESOURCE_ARRAY(VMRegPair, total_c_args); 1792 VMRegPair *out_regs2 = NEW_RESOURCE_ARRAY(VMRegPair, total_c_args); 1793 BasicType* in_elem_bt = NULL; 1794 1795 // Create the signature for the C call: 1796 // 1) add the JNIEnv* 1797 // 2) add the class if the method is static 1798 // 3) copy the rest of the incoming signature (shifted by the number of 1799 // hidden arguments). 1800 1801 int argc = 0; 1802 if (!is_critical_native) { 1803 out_sig_bt[argc++] = T_ADDRESS; 1804 if (method->is_static()) { 1805 out_sig_bt[argc++] = T_OBJECT; 1806 } 1807 1808 for (int i = 0; i < total_in_args ; i++ ) { 1809 out_sig_bt[argc++] = in_sig_bt[i]; 1810 } 1811 } else { 1812 Thread* THREAD = Thread::current(); 1813 in_elem_bt = NEW_RESOURCE_ARRAY(BasicType, total_c_args); 1814 SignatureStream ss(method->signature()); 1815 int o = 0; 1816 for (int i = 0; i < total_in_args ; i++, o++) { 1817 if (in_sig_bt[i] == T_ARRAY) { 1818 // Arrays are passed as int, elem* pair 1819 Symbol* atype = ss.as_symbol(CHECK_NULL); 1820 const char* at = atype->as_C_string(); 1821 if (strlen(at) == 2) { 1822 assert(at[0] == '[', "must be"); 1823 switch (at[1]) { 1824 case 'B': in_elem_bt[o] = T_BYTE; break; 1825 case 'C': in_elem_bt[o] = T_CHAR; break; 1826 case 'D': in_elem_bt[o] = T_DOUBLE; break; 1827 case 'F': in_elem_bt[o] = T_FLOAT; break; 1828 case 'I': in_elem_bt[o] = T_INT; break; 1829 case 'J': in_elem_bt[o] = T_LONG; break; 1830 case 'S': in_elem_bt[o] = T_SHORT; break; 1831 case 'Z': in_elem_bt[o] = T_BOOLEAN; break; 1832 default: ShouldNotReachHere(); 1833 } 1834 } 1835 } else { 1836 in_elem_bt[o] = T_VOID; 1837 } 1838 if (in_sig_bt[i] != T_VOID) { 1839 assert(in_sig_bt[i] == ss.type(), "must match"); 1840 ss.next(); 1841 } 1842 } 1843 1844 for (int i = 0; i < total_in_args ; i++ ) { 1845 if (in_sig_bt[i] == T_ARRAY) { 1846 // Arrays are passed as int, elem* pair. 1847 out_sig_bt[argc++] = T_INT; 1848 out_sig_bt[argc++] = T_ADDRESS; 1849 } else { 1850 out_sig_bt[argc++] = in_sig_bt[i]; 1851 } 1852 } 1853 } 1854 1855 1856 // Compute the wrapper's frame size. 1857 // -------------------------------------------------------------------------- 1858 1859 // Now figure out where the args must be stored and how much stack space 1860 // they require. 1861 // 1862 // Compute framesize for the wrapper. We need to handlize all oops in 1863 // incoming registers. 1864 // 1865 // Calculate the total number of stack slots we will need: 1866 // 1) abi requirements 1867 // 2) outgoing arguments 1868 // 3) space for inbound oop handle area 1869 // 4) space for handlizing a klass if static method 1870 // 5) space for a lock if synchronized method 1871 // 6) workspace for saving return values, int <-> float reg moves, etc. 1872 // 7) alignment 1873 // 1874 // Layout of the native wrapper frame: 1875 // (stack grows upwards, memory grows downwards) 1876 // 1877 // NW [ABI_REG_ARGS] <-- 1) R1_SP 1878 // [outgoing arguments] <-- 2) R1_SP + out_arg_slot_offset 1879 // [oopHandle area] <-- 3) R1_SP + oop_handle_offset (save area for critical natives) 1880 // klass <-- 4) R1_SP + klass_offset 1881 // lock <-- 5) R1_SP + lock_offset 1882 // [workspace] <-- 6) R1_SP + workspace_offset 1883 // [alignment] (optional) <-- 7) 1884 // caller [JIT_TOP_ABI_48] <-- r_callers_sp 1885 // 1886 // - *_slot_offset Indicates offset from SP in number of stack slots. 1887 // - *_offset Indicates offset from SP in bytes. 1888 1889 int stack_slots = c_calling_convention(out_sig_bt, out_regs, out_regs2, total_c_args) // 1+2) 1890 + SharedRuntime::out_preserve_stack_slots(); // See c_calling_convention. 1891 1892 // Now the space for the inbound oop handle area. 1893 int total_save_slots = num_java_iarg_registers * VMRegImpl::slots_per_word; 1894 if (is_critical_native) { 1895 // Critical natives may have to call out so they need a save area 1896 // for register arguments. 1897 int double_slots = 0; 1898 int single_slots = 0; 1899 for (int i = 0; i < total_in_args; i++) { 1900 if (in_regs[i].first()->is_Register()) { 1901 const Register reg = in_regs[i].first()->as_Register(); 1902 switch (in_sig_bt[i]) { 1903 case T_BOOLEAN: 1904 case T_BYTE: 1905 case T_SHORT: 1906 case T_CHAR: 1907 case T_INT: 1908 // Fall through. 1909 case T_ARRAY: 1910 case T_LONG: double_slots++; break; 1911 default: ShouldNotReachHere(); 1912 } 1913 } else if (in_regs[i].first()->is_FloatRegister()) { 1914 switch (in_sig_bt[i]) { 1915 case T_FLOAT: single_slots++; break; 1916 case T_DOUBLE: double_slots++; break; 1917 default: ShouldNotReachHere(); 1918 } 1919 } 1920 } 1921 total_save_slots = double_slots * 2 + round_to(single_slots, 2); // round to even 1922 } 1923 1924 int oop_handle_slot_offset = stack_slots; 1925 stack_slots += total_save_slots; // 3) 1926 1927 int klass_slot_offset = 0; 1928 int klass_offset = -1; 1929 if (method_is_static && !is_critical_native) { // 4) 1930 klass_slot_offset = stack_slots; 1931 klass_offset = klass_slot_offset * VMRegImpl::stack_slot_size; 1932 stack_slots += VMRegImpl::slots_per_word; 1933 } 1934 1935 int lock_slot_offset = 0; 1936 int lock_offset = -1; 1937 if (method->is_synchronized()) { // 5) 1938 lock_slot_offset = stack_slots; 1939 lock_offset = lock_slot_offset * VMRegImpl::stack_slot_size; 1940 stack_slots += VMRegImpl::slots_per_word; 1941 } 1942 1943 int workspace_slot_offset = stack_slots; // 6) 1944 stack_slots += 2; 1945 1946 // Now compute actual number of stack words we need. 1947 // Rounding to make stack properly aligned. 1948 stack_slots = round_to(stack_slots, // 7) 1949 frame::alignment_in_bytes / VMRegImpl::stack_slot_size); 1950 int frame_size_in_bytes = stack_slots * VMRegImpl::stack_slot_size; 1951 1952 1953 // Now we can start generating code. 1954 // -------------------------------------------------------------------------- 1955 1956 intptr_t start_pc = (intptr_t)__ pc(); 1957 intptr_t vep_start_pc; 1958 intptr_t frame_done_pc; 1959 intptr_t oopmap_pc; 1960 1961 Label ic_miss; 1962 Label handle_pending_exception; 1963 1964 Register r_callers_sp = R21; 1965 Register r_temp_1 = R22; 1966 Register r_temp_2 = R23; 1967 Register r_temp_3 = R24; 1968 Register r_temp_4 = R25; 1969 Register r_temp_5 = R26; 1970 Register r_temp_6 = R27; 1971 Register r_return_pc = R28; 1972 1973 Register r_carg1_jnienv = noreg; 1974 Register r_carg2_classorobject = noreg; 1975 if (!is_critical_native) { 1976 r_carg1_jnienv = out_regs[0].first()->as_Register(); 1977 r_carg2_classorobject = out_regs[1].first()->as_Register(); 1978 } 1979 1980 1981 // Generate the Unverified Entry Point (UEP). 1982 // -------------------------------------------------------------------------- 1983 assert(start_pc == (intptr_t)__ pc(), "uep must be at start"); 1984 1985 // Check ic: object class == cached class? 1986 if (!method_is_static) { 1987 Register ic = as_Register(Matcher::inline_cache_reg_encode()); 1988 Register receiver_klass = r_temp_1; 1989 1990 __ cmpdi(CCR0, R3_ARG1, 0); 1991 __ beq(CCR0, ic_miss); 1992 __ verify_oop(R3_ARG1); 1993 __ load_klass(receiver_klass, R3_ARG1); 1994 1995 __ cmpd(CCR0, receiver_klass, ic); 1996 __ bne(CCR0, ic_miss); 1997 } 1998 1999 2000 // Generate the Verified Entry Point (VEP). 2001 // -------------------------------------------------------------------------- 2002 vep_start_pc = (intptr_t)__ pc(); 2003 2004 __ save_LR_CR(r_temp_1); 2005 __ generate_stack_overflow_check(frame_size_in_bytes); // Check before creating frame. 2006 __ mr(r_callers_sp, R1_SP); // Remember frame pointer. 2007 __ push_frame(frame_size_in_bytes, r_temp_1); // Push the c2n adapter's frame. 2008 frame_done_pc = (intptr_t)__ pc(); 2009 2010 __ verify_thread(); 2011 2012 // Native nmethod wrappers never take possesion of the oop arguments. 2013 // So the caller will gc the arguments. 2014 // The only thing we need an oopMap for is if the call is static. 2015 // 2016 // An OopMap for lock (and class if static), and one for the VM call itself. 2017 OopMapSet *oop_maps = new OopMapSet(); 2018 OopMap *oop_map = new OopMap(stack_slots * 2, 0 /* arg_slots*/); 2019 2020 if (is_critical_native) { 2021 check_needs_gc_for_critical_native(masm, stack_slots, total_in_args, oop_handle_slot_offset, oop_maps, in_regs, in_sig_bt, r_temp_1); 2022 } 2023 2024 // Move arguments from register/stack to register/stack. 2025 // -------------------------------------------------------------------------- 2026 // 2027 // We immediately shuffle the arguments so that for any vm call we have 2028 // to make from here on out (sync slow path, jvmti, etc.) we will have 2029 // captured the oops from our caller and have a valid oopMap for them. 2030 // 2031 // Natives require 1 or 2 extra arguments over the normal ones: the JNIEnv* 2032 // (derived from JavaThread* which is in R16_thread) and, if static, 2033 // the class mirror instead of a receiver. This pretty much guarantees that 2034 // register layout will not match. We ignore these extra arguments during 2035 // the shuffle. The shuffle is described by the two calling convention 2036 // vectors we have in our possession. We simply walk the java vector to 2037 // get the source locations and the c vector to get the destinations. 2038 2039 // Record sp-based slot for receiver on stack for non-static methods. 2040 int receiver_offset = -1; 2041 2042 // We move the arguments backward because the floating point registers 2043 // destination will always be to a register with a greater or equal 2044 // register number or the stack. 2045 // in is the index of the incoming Java arguments 2046 // out is the index of the outgoing C arguments 2047 2048 #ifdef ASSERT 2049 bool reg_destroyed[RegisterImpl::number_of_registers]; 2050 bool freg_destroyed[FloatRegisterImpl::number_of_registers]; 2051 for (int r = 0 ; r < RegisterImpl::number_of_registers ; r++) { 2052 reg_destroyed[r] = false; 2053 } 2054 for (int f = 0 ; f < FloatRegisterImpl::number_of_registers ; f++) { 2055 freg_destroyed[f] = false; 2056 } 2057 #endif // ASSERT 2058 2059 for (int in = total_in_args - 1, out = total_c_args - 1; in >= 0 ; in--, out--) { 2060 2061 #ifdef ASSERT 2062 if (in_regs[in].first()->is_Register()) { 2063 assert(!reg_destroyed[in_regs[in].first()->as_Register()->encoding()], "ack!"); 2064 } else if (in_regs[in].first()->is_FloatRegister()) { 2065 assert(!freg_destroyed[in_regs[in].first()->as_FloatRegister()->encoding()], "ack!"); 2066 } 2067 if (out_regs[out].first()->is_Register()) { 2068 reg_destroyed[out_regs[out].first()->as_Register()->encoding()] = true; 2069 } else if (out_regs[out].first()->is_FloatRegister()) { 2070 freg_destroyed[out_regs[out].first()->as_FloatRegister()->encoding()] = true; 2071 } 2072 if (out_regs2[out].first()->is_Register()) { 2073 reg_destroyed[out_regs2[out].first()->as_Register()->encoding()] = true; 2074 } else if (out_regs2[out].first()->is_FloatRegister()) { 2075 freg_destroyed[out_regs2[out].first()->as_FloatRegister()->encoding()] = true; 2076 } 2077 #endif // ASSERT 2078 2079 switch (in_sig_bt[in]) { 2080 case T_BOOLEAN: 2081 case T_CHAR: 2082 case T_BYTE: 2083 case T_SHORT: 2084 case T_INT: 2085 // Move int and do sign extension. 2086 int_move(masm, in_regs[in], out_regs[out], r_callers_sp, r_temp_1); 2087 break; 2088 case T_LONG: 2089 long_move(masm, in_regs[in], out_regs[out], r_callers_sp, r_temp_1); 2090 break; 2091 case T_ARRAY: 2092 if (is_critical_native) { 2093 int body_arg = out; 2094 out -= 1; // Point to length arg. 2095 unpack_array_argument(masm, in_regs[in], in_elem_bt[in], out_regs[body_arg], out_regs[out], 2096 r_callers_sp, r_temp_1, r_temp_2); 2097 break; 2098 } 2099 case T_OBJECT: 2100 assert(!is_critical_native, "no oop arguments"); 2101 object_move(masm, stack_slots, 2102 oop_map, oop_handle_slot_offset, 2103 ((in == 0) && (!method_is_static)), &receiver_offset, 2104 in_regs[in], out_regs[out], 2105 r_callers_sp, r_temp_1, r_temp_2); 2106 break; 2107 case T_VOID: 2108 break; 2109 case T_FLOAT: 2110 float_move(masm, in_regs[in], out_regs[out], r_callers_sp, r_temp_1); 2111 if (out_regs2[out].first()->is_valid()) { 2112 float_move(masm, in_regs[in], out_regs2[out], r_callers_sp, r_temp_1); 2113 } 2114 break; 2115 case T_DOUBLE: 2116 double_move(masm, in_regs[in], out_regs[out], r_callers_sp, r_temp_1); 2117 if (out_regs2[out].first()->is_valid()) { 2118 double_move(masm, in_regs[in], out_regs2[out], r_callers_sp, r_temp_1); 2119 } 2120 break; 2121 case T_ADDRESS: 2122 fatal("found type (T_ADDRESS) in java args"); 2123 break; 2124 default: 2125 ShouldNotReachHere(); 2126 break; 2127 } 2128 } 2129 2130 // Pre-load a static method's oop into ARG2. 2131 // Used both by locking code and the normal JNI call code. 2132 if (method_is_static && !is_critical_native) { 2133 __ set_oop_constant(JNIHandles::make_local(method->method_holder()->java_mirror()), 2134 r_carg2_classorobject); 2135 2136 // Now handlize the static class mirror in carg2. It's known not-null. 2137 __ std(r_carg2_classorobject, klass_offset, R1_SP); 2138 oop_map->set_oop(VMRegImpl::stack2reg(klass_slot_offset)); 2139 __ addi(r_carg2_classorobject, R1_SP, klass_offset); 2140 } 2141 2142 // Get JNIEnv* which is first argument to native. 2143 if (!is_critical_native) { 2144 __ addi(r_carg1_jnienv, R16_thread, in_bytes(JavaThread::jni_environment_offset())); 2145 } 2146 2147 // NOTE: 2148 // 2149 // We have all of the arguments setup at this point. 2150 // We MUST NOT touch any outgoing regs from this point on. 2151 // So if we must call out we must push a new frame. 2152 2153 // Get current pc for oopmap, and load it patchable relative to global toc. 2154 oopmap_pc = (intptr_t) __ pc(); 2155 __ calculate_address_from_global_toc(r_return_pc, (address)oopmap_pc, true, true, true, true); 2156 2157 // We use the same pc/oopMap repeatedly when we call out. 2158 oop_maps->add_gc_map(oopmap_pc - start_pc, oop_map); 2159 2160 // r_return_pc now has the pc loaded that we will use when we finally call 2161 // to native. 2162 2163 // Make sure that thread is non-volatile; it crosses a bunch of VM calls below. 2164 assert(R16_thread->is_nonvolatile(), "thread must be in non-volatile register"); 2165 2166 # if 0 2167 // DTrace method entry 2168 # endif 2169 2170 // Lock a synchronized method. 2171 // -------------------------------------------------------------------------- 2172 2173 if (method->is_synchronized()) { 2174 assert(!is_critical_native, "unhandled"); 2175 ConditionRegister r_flag = CCR1; 2176 Register r_oop = r_temp_4; 2177 const Register r_box = r_temp_5; 2178 Label done, locked; 2179 2180 // Load the oop for the object or class. r_carg2_classorobject contains 2181 // either the handlized oop from the incoming arguments or the handlized 2182 // class mirror (if the method is static). 2183 __ ld(r_oop, 0, r_carg2_classorobject); 2184 2185 // Get the lock box slot's address. 2186 __ addi(r_box, R1_SP, lock_offset); 2187 2188 # ifdef ASSERT 2189 if (UseBiasedLocking) { 2190 // Making the box point to itself will make it clear it went unused 2191 // but also be obviously invalid. 2192 __ std(r_box, 0, r_box); 2193 } 2194 # endif // ASSERT 2195 2196 // Try fastpath for locking. 2197 // fast_lock kills r_temp_1, r_temp_2, r_temp_3. 2198 __ compiler_fast_lock_object(r_flag, r_oop, r_box, r_temp_1, r_temp_2, r_temp_3); 2199 __ beq(r_flag, locked); 2200 2201 // None of the above fast optimizations worked so we have to get into the 2202 // slow case of monitor enter. Inline a special case of call_VM that 2203 // disallows any pending_exception. 2204 2205 // Save argument registers and leave room for C-compatible ABI_REG_ARGS. 2206 int frame_size = frame::abi_reg_args_size + 2207 round_to(total_c_args * wordSize, frame::alignment_in_bytes); 2208 __ mr(R11_scratch1, R1_SP); 2209 RegisterSaver::push_frame_and_save_argument_registers(masm, R12_scratch2, frame_size, total_c_args, out_regs, out_regs2); 2210 2211 // Do the call. 2212 __ set_last_Java_frame(R11_scratch1, r_return_pc); 2213 assert(r_return_pc->is_nonvolatile(), "expecting return pc to be in non-volatile register"); 2214 __ call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::complete_monitor_locking_C), r_oop, r_box, R16_thread); 2215 __ reset_last_Java_frame(); 2216 2217 RegisterSaver::restore_argument_registers_and_pop_frame(masm, frame_size, total_c_args, out_regs, out_regs2); 2218 2219 __ asm_assert_mem8_is_zero(thread_(pending_exception), 2220 "no pending exception allowed on exit from SharedRuntime::complete_monitor_locking_C", 0); 2221 2222 __ bind(locked); 2223 } 2224 2225 2226 // Publish thread state 2227 // -------------------------------------------------------------------------- 2228 2229 // Use that pc we placed in r_return_pc a while back as the current frame anchor. 2230 __ set_last_Java_frame(R1_SP, r_return_pc); 2231 2232 // Transition from _thread_in_Java to _thread_in_native. 2233 __ li(R0, _thread_in_native); 2234 __ release(); 2235 // TODO: PPC port assert(4 == JavaThread::sz_thread_state(), "unexpected field size"); 2236 __ stw(R0, thread_(thread_state)); 2237 if (UseMembar) { 2238 __ fence(); 2239 } 2240 2241 2242 // The JNI call 2243 // -------------------------------------------------------------------------- 2244 #if defined(ABI_ELFv2) 2245 __ call_c(native_func, relocInfo::runtime_call_type); 2246 #else 2247 FunctionDescriptor* fd_native_method = (FunctionDescriptor*) native_func; 2248 __ call_c(fd_native_method, relocInfo::runtime_call_type); 2249 #endif 2250 2251 2252 // Now, we are back from the native code. 2253 2254 2255 // Unpack the native result. 2256 // -------------------------------------------------------------------------- 2257 2258 // For int-types, we do any needed sign-extension required. 2259 // Care must be taken that the return values (R3_RET and F1_RET) 2260 // will survive any VM calls for blocking or unlocking. 2261 // An OOP result (handle) is done specially in the slow-path code. 2262 2263 switch (ret_type) { 2264 case T_VOID: break; // Nothing to do! 2265 case T_FLOAT: break; // Got it where we want it (unless slow-path). 2266 case T_DOUBLE: break; // Got it where we want it (unless slow-path). 2267 case T_LONG: break; // Got it where we want it (unless slow-path). 2268 case T_OBJECT: break; // Really a handle. 2269 // Cannot de-handlize until after reclaiming jvm_lock. 2270 case T_ARRAY: break; 2271 2272 case T_BOOLEAN: { // 0 -> false(0); !0 -> true(1) 2273 Label skip_modify; 2274 __ cmpwi(CCR0, R3_RET, 0); 2275 __ beq(CCR0, skip_modify); 2276 __ li(R3_RET, 1); 2277 __ bind(skip_modify); 2278 break; 2279 } 2280 case T_BYTE: { // sign extension 2281 __ extsb(R3_RET, R3_RET); 2282 break; 2283 } 2284 case T_CHAR: { // unsigned result 2285 __ andi(R3_RET, R3_RET, 0xffff); 2286 break; 2287 } 2288 case T_SHORT: { // sign extension 2289 __ extsh(R3_RET, R3_RET); 2290 break; 2291 } 2292 case T_INT: // nothing to do 2293 break; 2294 default: 2295 ShouldNotReachHere(); 2296 break; 2297 } 2298 2299 2300 // Publish thread state 2301 // -------------------------------------------------------------------------- 2302 2303 // Switch thread to "native transition" state before reading the 2304 // synchronization state. This additional state is necessary because reading 2305 // and testing the synchronization state is not atomic w.r.t. GC, as this 2306 // scenario demonstrates: 2307 // - Java thread A, in _thread_in_native state, loads _not_synchronized 2308 // and is preempted. 2309 // - VM thread changes sync state to synchronizing and suspends threads 2310 // for GC. 2311 // - Thread A is resumed to finish this native method, but doesn't block 2312 // here since it didn't see any synchronization in progress, and escapes. 2313 2314 // Transition from _thread_in_native to _thread_in_native_trans. 2315 __ li(R0, _thread_in_native_trans); 2316 __ release(); 2317 // TODO: PPC port assert(4 == JavaThread::sz_thread_state(), "unexpected field size"); 2318 __ stw(R0, thread_(thread_state)); 2319 2320 2321 // Must we block? 2322 // -------------------------------------------------------------------------- 2323 2324 // Block, if necessary, before resuming in _thread_in_Java state. 2325 // In order for GC to work, don't clear the last_Java_sp until after blocking. 2326 Label after_transition; 2327 { 2328 Label no_block, sync; 2329 2330 if (os::is_MP()) { 2331 if (UseMembar) { 2332 // Force this write out before the read below. 2333 __ fence(); 2334 } else { 2335 // Write serialization page so VM thread can do a pseudo remote membar. 2336 // We use the current thread pointer to calculate a thread specific 2337 // offset to write to within the page. This minimizes bus traffic 2338 // due to cache line collision. 2339 __ serialize_memory(R16_thread, r_temp_4, r_temp_5); 2340 } 2341 } 2342 2343 Register sync_state_addr = r_temp_4; 2344 Register sync_state = r_temp_5; 2345 Register suspend_flags = r_temp_6; 2346 2347 __ load_const(sync_state_addr, SafepointSynchronize::address_of_state(), /*temp*/ sync_state); 2348 2349 // TODO: PPC port assert(4 == SafepointSynchronize::sz_state(), "unexpected field size"); 2350 __ lwz(sync_state, 0, sync_state_addr); 2351 2352 // TODO: PPC port assert(4 == Thread::sz_suspend_flags(), "unexpected field size"); 2353 __ lwz(suspend_flags, thread_(suspend_flags)); 2354 2355 __ acquire(); 2356 2357 Label do_safepoint; 2358 // No synchronization in progress nor yet synchronized. 2359 __ cmpwi(CCR0, sync_state, SafepointSynchronize::_not_synchronized); 2360 // Not suspended. 2361 __ cmpwi(CCR1, suspend_flags, 0); 2362 2363 __ bne(CCR0, sync); 2364 __ beq(CCR1, no_block); 2365 2366 // Block. Save any potential method result value before the operation and 2367 // use a leaf call to leave the last_Java_frame setup undisturbed. Doing this 2368 // lets us share the oopMap we used when we went native rather than create 2369 // a distinct one for this pc. 2370 __ bind(sync); 2371 2372 address entry_point = is_critical_native 2373 ? CAST_FROM_FN_PTR(address, JavaThread::check_special_condition_for_native_trans_and_transition) 2374 : CAST_FROM_FN_PTR(address, JavaThread::check_special_condition_for_native_trans); 2375 save_native_result(masm, ret_type, workspace_slot_offset); 2376 __ call_VM_leaf(entry_point, R16_thread); 2377 restore_native_result(masm, ret_type, workspace_slot_offset); 2378 2379 if (is_critical_native) { 2380 __ b(after_transition); // No thread state transition here. 2381 } 2382 __ bind(no_block); 2383 } 2384 2385 // Publish thread state. 2386 // -------------------------------------------------------------------------- 2387 2388 // Thread state is thread_in_native_trans. Any safepoint blocking has 2389 // already happened so we can now change state to _thread_in_Java. 2390 2391 // Transition from _thread_in_native_trans to _thread_in_Java. 2392 __ li(R0, _thread_in_Java); 2393 __ release(); 2394 // TODO: PPC port assert(4 == JavaThread::sz_thread_state(), "unexpected field size"); 2395 __ stw(R0, thread_(thread_state)); 2396 if (UseMembar) { 2397 __ fence(); 2398 } 2399 __ bind(after_transition); 2400 2401 // Reguard any pages if necessary. 2402 // -------------------------------------------------------------------------- 2403 2404 Label no_reguard; 2405 __ lwz(r_temp_1, thread_(stack_guard_state)); 2406 __ cmpwi(CCR0, r_temp_1, JavaThread::stack_guard_yellow_reserved_disabled); 2407 __ bne(CCR0, no_reguard); 2408 2409 save_native_result(masm, ret_type, workspace_slot_offset); 2410 __ call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::reguard_yellow_pages)); 2411 restore_native_result(masm, ret_type, workspace_slot_offset); 2412 2413 __ bind(no_reguard); 2414 2415 2416 // Unlock 2417 // -------------------------------------------------------------------------- 2418 2419 if (method->is_synchronized()) { 2420 2421 ConditionRegister r_flag = CCR1; 2422 const Register r_oop = r_temp_4; 2423 const Register r_box = r_temp_5; 2424 const Register r_exception = r_temp_6; 2425 Label done; 2426 2427 // Get oop and address of lock object box. 2428 if (method_is_static) { 2429 assert(klass_offset != -1, ""); 2430 __ ld(r_oop, klass_offset, R1_SP); 2431 } else { 2432 assert(receiver_offset != -1, ""); 2433 __ ld(r_oop, receiver_offset, R1_SP); 2434 } 2435 __ addi(r_box, R1_SP, lock_offset); 2436 2437 // Try fastpath for unlocking. 2438 __ compiler_fast_unlock_object(r_flag, r_oop, r_box, r_temp_1, r_temp_2, r_temp_3); 2439 __ beq(r_flag, done); 2440 2441 // Save and restore any potential method result value around the unlocking operation. 2442 save_native_result(masm, ret_type, workspace_slot_offset); 2443 2444 // Must save pending exception around the slow-path VM call. Since it's a 2445 // leaf call, the pending exception (if any) can be kept in a register. 2446 __ ld(r_exception, thread_(pending_exception)); 2447 assert(r_exception->is_nonvolatile(), "exception register must be non-volatile"); 2448 __ li(R0, 0); 2449 __ std(R0, thread_(pending_exception)); 2450 2451 // Slow case of monitor enter. 2452 // Inline a special case of call_VM that disallows any pending_exception. 2453 // Arguments are (oop obj, BasicLock* lock, JavaThread* thread). 2454 __ call_VM_leaf(CAST_FROM_FN_PTR(address, SharedRuntime::complete_monitor_unlocking_C), r_oop, r_box, R16_thread); 2455 2456 __ asm_assert_mem8_is_zero(thread_(pending_exception), 2457 "no pending exception allowed on exit from SharedRuntime::complete_monitor_unlocking_C", 0); 2458 2459 restore_native_result(masm, ret_type, workspace_slot_offset); 2460 2461 // Check_forward_pending_exception jump to forward_exception if any pending 2462 // exception is set. The forward_exception routine expects to see the 2463 // exception in pending_exception and not in a register. Kind of clumsy, 2464 // since all folks who branch to forward_exception must have tested 2465 // pending_exception first and hence have it in a register already. 2466 __ std(r_exception, thread_(pending_exception)); 2467 2468 __ bind(done); 2469 } 2470 2471 # if 0 2472 // DTrace method exit 2473 # endif 2474 2475 // Clear "last Java frame" SP and PC. 2476 // -------------------------------------------------------------------------- 2477 2478 __ reset_last_Java_frame(); 2479 2480 // Unpack oop result. 2481 // -------------------------------------------------------------------------- 2482 2483 if (ret_type == T_OBJECT || ret_type == T_ARRAY) { 2484 Label skip_unboxing; 2485 __ cmpdi(CCR0, R3_RET, 0); 2486 __ beq(CCR0, skip_unboxing); 2487 __ ld(R3_RET, 0, R3_RET); 2488 __ bind(skip_unboxing); 2489 __ verify_oop(R3_RET); 2490 } 2491 2492 2493 // Reset handle block. 2494 // -------------------------------------------------------------------------- 2495 if (!is_critical_native) { 2496 __ ld(r_temp_1, thread_(active_handles)); 2497 // TODO: PPC port assert(4 == JNIHandleBlock::top_size_in_bytes(), "unexpected field size"); 2498 __ li(r_temp_2, 0); 2499 __ stw(r_temp_2, JNIHandleBlock::top_offset_in_bytes(), r_temp_1); 2500 2501 2502 // Check for pending exceptions. 2503 // -------------------------------------------------------------------------- 2504 __ ld(r_temp_2, thread_(pending_exception)); 2505 __ cmpdi(CCR0, r_temp_2, 0); 2506 __ bne(CCR0, handle_pending_exception); 2507 } 2508 2509 // Return 2510 // -------------------------------------------------------------------------- 2511 2512 __ pop_frame(); 2513 __ restore_LR_CR(R11); 2514 __ blr(); 2515 2516 2517 // Handler for pending exceptions (out-of-line). 2518 // -------------------------------------------------------------------------- 2519 2520 // Since this is a native call, we know the proper exception handler 2521 // is the empty function. We just pop this frame and then jump to 2522 // forward_exception_entry. 2523 if (!is_critical_native) { 2524 __ align(InteriorEntryAlignment); 2525 __ bind(handle_pending_exception); 2526 2527 __ pop_frame(); 2528 __ restore_LR_CR(R11); 2529 __ b64_patchable((address)StubRoutines::forward_exception_entry(), 2530 relocInfo::runtime_call_type); 2531 } 2532 2533 // Handler for a cache miss (out-of-line). 2534 // -------------------------------------------------------------------------- 2535 2536 if (!method_is_static) { 2537 __ align(InteriorEntryAlignment); 2538 __ bind(ic_miss); 2539 2540 __ b64_patchable((address)SharedRuntime::get_ic_miss_stub(), 2541 relocInfo::runtime_call_type); 2542 } 2543 2544 // Done. 2545 // -------------------------------------------------------------------------- 2546 2547 __ flush(); 2548 2549 nmethod *nm = nmethod::new_native_nmethod(method, 2550 compile_id, 2551 masm->code(), 2552 vep_start_pc-start_pc, 2553 frame_done_pc-start_pc, 2554 stack_slots / VMRegImpl::slots_per_word, 2555 (method_is_static ? in_ByteSize(klass_offset) : in_ByteSize(receiver_offset)), 2556 in_ByteSize(lock_offset), 2557 oop_maps); 2558 2559 if (is_critical_native) { 2560 nm->set_lazy_critical_native(true); 2561 } 2562 2563 return nm; 2564 #else 2565 ShouldNotReachHere(); 2566 return NULL; 2567 #endif // COMPILER2 2568 } 2569 2570 // This function returns the adjust size (in number of words) to a c2i adapter 2571 // activation for use during deoptimization. 2572 int Deoptimization::last_frame_adjust(int callee_parameters, int callee_locals) { 2573 return round_to((callee_locals - callee_parameters) * Interpreter::stackElementWords, frame::alignment_in_bytes); 2574 } 2575 2576 uint SharedRuntime::out_preserve_stack_slots() { 2577 #if defined(COMPILER1) || defined(COMPILER2) 2578 return frame::jit_out_preserve_size / VMRegImpl::stack_slot_size; 2579 #else 2580 return 0; 2581 #endif 2582 } 2583 2584 #if defined(COMPILER1) || defined(COMPILER2) 2585 // Frame generation for deopt and uncommon trap blobs. 2586 static void push_skeleton_frame(MacroAssembler* masm, bool deopt, 2587 /* Read */ 2588 Register unroll_block_reg, 2589 /* Update */ 2590 Register frame_sizes_reg, 2591 Register number_of_frames_reg, 2592 Register pcs_reg, 2593 /* Invalidate */ 2594 Register frame_size_reg, 2595 Register pc_reg) { 2596 2597 __ ld(pc_reg, 0, pcs_reg); 2598 __ ld(frame_size_reg, 0, frame_sizes_reg); 2599 __ std(pc_reg, _abi(lr), R1_SP); 2600 __ push_frame(frame_size_reg, R0/*tmp*/); 2601 #ifdef ASSERT 2602 __ load_const_optimized(pc_reg, 0x5afe); 2603 __ std(pc_reg, _ijava_state_neg(ijava_reserved), R1_SP); 2604 #endif 2605 __ std(R1_SP, _ijava_state_neg(sender_sp), R1_SP); 2606 __ addi(number_of_frames_reg, number_of_frames_reg, -1); 2607 __ addi(frame_sizes_reg, frame_sizes_reg, wordSize); 2608 __ addi(pcs_reg, pcs_reg, wordSize); 2609 } 2610 2611 // Loop through the UnrollBlock info and create new frames. 2612 static void push_skeleton_frames(MacroAssembler* masm, bool deopt, 2613 /* read */ 2614 Register unroll_block_reg, 2615 /* invalidate */ 2616 Register frame_sizes_reg, 2617 Register number_of_frames_reg, 2618 Register pcs_reg, 2619 Register frame_size_reg, 2620 Register pc_reg) { 2621 Label loop; 2622 2623 // _number_of_frames is of type int (deoptimization.hpp) 2624 __ lwa(number_of_frames_reg, 2625 Deoptimization::UnrollBlock::number_of_frames_offset_in_bytes(), 2626 unroll_block_reg); 2627 __ ld(pcs_reg, 2628 Deoptimization::UnrollBlock::frame_pcs_offset_in_bytes(), 2629 unroll_block_reg); 2630 __ ld(frame_sizes_reg, 2631 Deoptimization::UnrollBlock::frame_sizes_offset_in_bytes(), 2632 unroll_block_reg); 2633 2634 // stack: (caller_of_deoptee, ...). 2635 2636 // At this point we either have an interpreter frame or a compiled 2637 // frame on top of stack. If it is a compiled frame we push a new c2i 2638 // adapter here 2639 2640 // Memorize top-frame stack-pointer. 2641 __ mr(frame_size_reg/*old_sp*/, R1_SP); 2642 2643 // Resize interpreter top frame OR C2I adapter. 2644 2645 // At this moment, the top frame (which is the caller of the deoptee) is 2646 // an interpreter frame or a newly pushed C2I adapter or an entry frame. 2647 // The top frame has a TOP_IJAVA_FRAME_ABI and the frame contains the 2648 // outgoing arguments. 2649 // 2650 // In order to push the interpreter frame for the deoptee, we need to 2651 // resize the top frame such that we are able to place the deoptee's 2652 // locals in the frame. 2653 // Additionally, we have to turn the top frame's TOP_IJAVA_FRAME_ABI 2654 // into a valid PARENT_IJAVA_FRAME_ABI. 2655 2656 __ lwa(R11_scratch1, 2657 Deoptimization::UnrollBlock::caller_adjustment_offset_in_bytes(), 2658 unroll_block_reg); 2659 __ neg(R11_scratch1, R11_scratch1); 2660 2661 // R11_scratch1 contains size of locals for frame resizing. 2662 // R12_scratch2 contains top frame's lr. 2663 2664 // Resize frame by complete frame size prevents TOC from being 2665 // overwritten by locals. A more stack space saving way would be 2666 // to copy the TOC to its location in the new abi. 2667 __ addi(R11_scratch1, R11_scratch1, - frame::parent_ijava_frame_abi_size); 2668 2669 // now, resize the frame 2670 __ resize_frame(R11_scratch1, pc_reg/*tmp*/); 2671 2672 // In the case where we have resized a c2i frame above, the optional 2673 // alignment below the locals has size 32 (why?). 2674 __ std(R12_scratch2, _abi(lr), R1_SP); 2675 2676 // Initialize initial_caller_sp. 2677 #ifdef ASSERT 2678 __ load_const_optimized(pc_reg, 0x5afe); 2679 __ std(pc_reg, _ijava_state_neg(ijava_reserved), R1_SP); 2680 #endif 2681 __ std(frame_size_reg, _ijava_state_neg(sender_sp), R1_SP); 2682 2683 #ifdef ASSERT 2684 // Make sure that there is at least one entry in the array. 2685 __ cmpdi(CCR0, number_of_frames_reg, 0); 2686 __ asm_assert_ne("array_size must be > 0", 0x205); 2687 #endif 2688 2689 // Now push the new interpreter frames. 2690 // 2691 __ bind(loop); 2692 // Allocate a new frame, fill in the pc. 2693 push_skeleton_frame(masm, deopt, 2694 unroll_block_reg, 2695 frame_sizes_reg, 2696 number_of_frames_reg, 2697 pcs_reg, 2698 frame_size_reg, 2699 pc_reg); 2700 __ cmpdi(CCR0, number_of_frames_reg, 0); 2701 __ bne(CCR0, loop); 2702 2703 // Get the return address pointing into the frame manager. 2704 __ ld(R0, 0, pcs_reg); 2705 // Store it in the top interpreter frame. 2706 __ std(R0, _abi(lr), R1_SP); 2707 // Initialize frame_manager_lr of interpreter top frame. 2708 } 2709 #endif 2710 2711 void SharedRuntime::generate_deopt_blob() { 2712 // Allocate space for the code 2713 ResourceMark rm; 2714 // Setup code generation tools 2715 CodeBuffer buffer("deopt_blob", 2048, 1024); 2716 InterpreterMacroAssembler* masm = new InterpreterMacroAssembler(&buffer); 2717 Label exec_mode_initialized; 2718 int frame_size_in_words; 2719 OopMap* map = NULL; 2720 OopMapSet *oop_maps = new OopMapSet(); 2721 2722 // size of ABI112 plus spill slots for R3_RET and F1_RET. 2723 const int frame_size_in_bytes = frame::abi_reg_args_spill_size; 2724 const int frame_size_in_slots = frame_size_in_bytes / sizeof(jint); 2725 int first_frame_size_in_bytes = 0; // frame size of "unpack frame" for call to fetch_unroll_info. 2726 2727 const Register exec_mode_reg = R21_tmp1; 2728 2729 const address start = __ pc(); 2730 2731 #if defined(COMPILER1) || defined(COMPILER2) 2732 // -------------------------------------------------------------------------- 2733 // Prolog for non exception case! 2734 2735 // We have been called from the deopt handler of the deoptee. 2736 // 2737 // deoptee: 2738 // ... 2739 // call X 2740 // ... 2741 // deopt_handler: call_deopt_stub 2742 // cur. return pc --> ... 2743 // 2744 // So currently SR_LR points behind the call in the deopt handler. 2745 // We adjust it such that it points to the start of the deopt handler. 2746 // The return_pc has been stored in the frame of the deoptee and 2747 // will replace the address of the deopt_handler in the call 2748 // to Deoptimization::fetch_unroll_info below. 2749 // We can't grab a free register here, because all registers may 2750 // contain live values, so let the RegisterSaver do the adjustment 2751 // of the return pc. 2752 const int return_pc_adjustment_no_exception = -HandlerImpl::size_deopt_handler(); 2753 2754 // Push the "unpack frame" 2755 // Save everything in sight. 2756 map = RegisterSaver::push_frame_reg_args_and_save_live_registers(masm, 2757 &first_frame_size_in_bytes, 2758 /*generate_oop_map=*/ true, 2759 return_pc_adjustment_no_exception, 2760 RegisterSaver::return_pc_is_lr); 2761 assert(map != NULL, "OopMap must have been created"); 2762 2763 __ li(exec_mode_reg, Deoptimization::Unpack_deopt); 2764 // Save exec mode for unpack_frames. 2765 __ b(exec_mode_initialized); 2766 2767 // -------------------------------------------------------------------------- 2768 // Prolog for exception case 2769 2770 // An exception is pending. 2771 // We have been called with a return (interpreter) or a jump (exception blob). 2772 // 2773 // - R3_ARG1: exception oop 2774 // - R4_ARG2: exception pc 2775 2776 int exception_offset = __ pc() - start; 2777 2778 BLOCK_COMMENT("Prolog for exception case"); 2779 2780 // Store exception oop and pc in thread (location known to GC). 2781 // This is needed since the call to "fetch_unroll_info()" may safepoint. 2782 __ std(R3_ARG1, in_bytes(JavaThread::exception_oop_offset()), R16_thread); 2783 __ std(R4_ARG2, in_bytes(JavaThread::exception_pc_offset()), R16_thread); 2784 __ std(R4_ARG2, _abi(lr), R1_SP); 2785 2786 // Vanilla deoptimization with an exception pending in exception_oop. 2787 int exception_in_tls_offset = __ pc() - start; 2788 2789 // Push the "unpack frame". 2790 // Save everything in sight. 2791 RegisterSaver::push_frame_reg_args_and_save_live_registers(masm, 2792 &first_frame_size_in_bytes, 2793 /*generate_oop_map=*/ false, 2794 /*return_pc_adjustment_exception=*/ 0, 2795 RegisterSaver::return_pc_is_pre_saved); 2796 2797 // Deopt during an exception. Save exec mode for unpack_frames. 2798 __ li(exec_mode_reg, Deoptimization::Unpack_exception); 2799 2800 // fall through 2801 2802 int reexecute_offset = 0; 2803 #ifdef COMPILER1 2804 __ b(exec_mode_initialized); 2805 2806 // Reexecute entry, similar to c2 uncommon trap 2807 reexecute_offset = __ pc() - start; 2808 2809 RegisterSaver::push_frame_reg_args_and_save_live_registers(masm, 2810 &first_frame_size_in_bytes, 2811 /*generate_oop_map=*/ false, 2812 /*return_pc_adjustment_reexecute=*/ 0, 2813 RegisterSaver::return_pc_is_pre_saved); 2814 __ li(exec_mode_reg, Deoptimization::Unpack_reexecute); 2815 #endif 2816 2817 // -------------------------------------------------------------------------- 2818 __ BIND(exec_mode_initialized); 2819 2820 { 2821 const Register unroll_block_reg = R22_tmp2; 2822 2823 // We need to set `last_Java_frame' because `fetch_unroll_info' will 2824 // call `last_Java_frame()'. The value of the pc in the frame is not 2825 // particularly important. It just needs to identify this blob. 2826 __ set_last_Java_frame(R1_SP, noreg); 2827 2828 // With EscapeAnalysis turned on, this call may safepoint! 2829 __ call_VM_leaf(CAST_FROM_FN_PTR(address, Deoptimization::fetch_unroll_info), R16_thread, exec_mode_reg); 2830 address calls_return_pc = __ last_calls_return_pc(); 2831 // Set an oopmap for the call site that describes all our saved registers. 2832 oop_maps->add_gc_map(calls_return_pc - start, map); 2833 2834 __ reset_last_Java_frame(); 2835 // Save the return value. 2836 __ mr(unroll_block_reg, R3_RET); 2837 2838 // Restore only the result registers that have been saved 2839 // by save_volatile_registers(...). 2840 RegisterSaver::restore_result_registers(masm, first_frame_size_in_bytes); 2841 2842 // reload the exec mode from the UnrollBlock (it might have changed) 2843 __ lwz(exec_mode_reg, Deoptimization::UnrollBlock::unpack_kind_offset_in_bytes(), unroll_block_reg); 2844 // In excp_deopt_mode, restore and clear exception oop which we 2845 // stored in the thread during exception entry above. The exception 2846 // oop will be the return value of this stub. 2847 Label skip_restore_excp; 2848 __ cmpdi(CCR0, exec_mode_reg, Deoptimization::Unpack_exception); 2849 __ bne(CCR0, skip_restore_excp); 2850 __ ld(R3_RET, in_bytes(JavaThread::exception_oop_offset()), R16_thread); 2851 __ ld(R4_ARG2, in_bytes(JavaThread::exception_pc_offset()), R16_thread); 2852 __ li(R0, 0); 2853 __ std(R0, in_bytes(JavaThread::exception_pc_offset()), R16_thread); 2854 __ std(R0, in_bytes(JavaThread::exception_oop_offset()), R16_thread); 2855 __ BIND(skip_restore_excp); 2856 2857 __ pop_frame(); 2858 2859 // stack: (deoptee, optional i2c, caller of deoptee, ...). 2860 2861 // pop the deoptee's frame 2862 __ pop_frame(); 2863 2864 // stack: (caller_of_deoptee, ...). 2865 2866 // Loop through the `UnrollBlock' info and create interpreter frames. 2867 push_skeleton_frames(masm, true/*deopt*/, 2868 unroll_block_reg, 2869 R23_tmp3, 2870 R24_tmp4, 2871 R25_tmp5, 2872 R26_tmp6, 2873 R27_tmp7); 2874 2875 // stack: (skeletal interpreter frame, ..., optional skeletal 2876 // interpreter frame, optional c2i, caller of deoptee, ...). 2877 } 2878 2879 // push an `unpack_frame' taking care of float / int return values. 2880 __ push_frame(frame_size_in_bytes, R0/*tmp*/); 2881 2882 // stack: (unpack frame, skeletal interpreter frame, ..., optional 2883 // skeletal interpreter frame, optional c2i, caller of deoptee, 2884 // ...). 2885 2886 // Spill live volatile registers since we'll do a call. 2887 __ std( R3_RET, _abi_reg_args_spill(spill_ret), R1_SP); 2888 __ stfd(F1_RET, _abi_reg_args_spill(spill_fret), R1_SP); 2889 2890 // Let the unpacker layout information in the skeletal frames just 2891 // allocated. 2892 __ get_PC_trash_LR(R3_RET); 2893 __ set_last_Java_frame(/*sp*/R1_SP, /*pc*/R3_RET); 2894 // This is a call to a LEAF method, so no oop map is required. 2895 __ call_VM_leaf(CAST_FROM_FN_PTR(address, Deoptimization::unpack_frames), 2896 R16_thread/*thread*/, exec_mode_reg/*exec_mode*/); 2897 __ reset_last_Java_frame(); 2898 2899 // Restore the volatiles saved above. 2900 __ ld( R3_RET, _abi_reg_args_spill(spill_ret), R1_SP); 2901 __ lfd(F1_RET, _abi_reg_args_spill(spill_fret), R1_SP); 2902 2903 // Pop the unpack frame. 2904 __ pop_frame(); 2905 __ restore_LR_CR(R0); 2906 2907 // stack: (top interpreter frame, ..., optional interpreter frame, 2908 // optional c2i, caller of deoptee, ...). 2909 2910 // Initialize R14_state. 2911 __ restore_interpreter_state(R11_scratch1); 2912 __ load_const_optimized(R25_templateTableBase, (address)Interpreter::dispatch_table((TosState)0), R11_scratch1); 2913 2914 // Return to the interpreter entry point. 2915 __ blr(); 2916 __ flush(); 2917 #else // COMPILER2 2918 __ unimplemented("deopt blob needed only with compiler"); 2919 int exception_offset = __ pc() - start; 2920 #endif // COMPILER2 2921 2922 _deopt_blob = DeoptimizationBlob::create(&buffer, oop_maps, 0, exception_offset, 2923 reexecute_offset, first_frame_size_in_bytes / wordSize); 2924 _deopt_blob->set_unpack_with_exception_in_tls_offset(exception_in_tls_offset); 2925 } 2926 2927 #ifdef COMPILER2 2928 void SharedRuntime::generate_uncommon_trap_blob() { 2929 // Allocate space for the code. 2930 ResourceMark rm; 2931 // Setup code generation tools. 2932 CodeBuffer buffer("uncommon_trap_blob", 2048, 1024); 2933 InterpreterMacroAssembler* masm = new InterpreterMacroAssembler(&buffer); 2934 address start = __ pc(); 2935 2936 Register unroll_block_reg = R21_tmp1; 2937 Register klass_index_reg = R22_tmp2; 2938 Register unc_trap_reg = R23_tmp3; 2939 2940 OopMapSet* oop_maps = new OopMapSet(); 2941 int frame_size_in_bytes = frame::abi_reg_args_size; 2942 OopMap* map = new OopMap(frame_size_in_bytes / sizeof(jint), 0); 2943 2944 // stack: (deoptee, optional i2c, caller_of_deoptee, ...). 2945 2946 // Push a dummy `unpack_frame' and call 2947 // `Deoptimization::uncommon_trap' to pack the compiled frame into a 2948 // vframe array and return the `UnrollBlock' information. 2949 2950 // Save LR to compiled frame. 2951 __ save_LR_CR(R11_scratch1); 2952 2953 // Push an "uncommon_trap" frame. 2954 __ push_frame_reg_args(0, R11_scratch1); 2955 2956 // stack: (unpack frame, deoptee, optional i2c, caller_of_deoptee, ...). 2957 2958 // Set the `unpack_frame' as last_Java_frame. 2959 // `Deoptimization::uncommon_trap' expects it and considers its 2960 // sender frame as the deoptee frame. 2961 // Remember the offset of the instruction whose address will be 2962 // moved to R11_scratch1. 2963 address gc_map_pc = __ get_PC_trash_LR(R11_scratch1); 2964 2965 __ set_last_Java_frame(/*sp*/R1_SP, /*pc*/R11_scratch1); 2966 2967 __ mr(klass_index_reg, R3); 2968 __ li(R5_ARG3, Deoptimization::Unpack_uncommon_trap); 2969 __ call_VM_leaf(CAST_FROM_FN_PTR(address, Deoptimization::uncommon_trap), 2970 R16_thread, klass_index_reg, R5_ARG3); 2971 2972 // Set an oopmap for the call site. 2973 oop_maps->add_gc_map(gc_map_pc - start, map); 2974 2975 __ reset_last_Java_frame(); 2976 2977 // Pop the `unpack frame'. 2978 __ pop_frame(); 2979 2980 // stack: (deoptee, optional i2c, caller_of_deoptee, ...). 2981 2982 // Save the return value. 2983 __ mr(unroll_block_reg, R3_RET); 2984 2985 // Pop the uncommon_trap frame. 2986 __ pop_frame(); 2987 2988 // stack: (caller_of_deoptee, ...). 2989 2990 #ifdef ASSERT 2991 __ lwz(R22_tmp2, Deoptimization::UnrollBlock::unpack_kind_offset_in_bytes(), unroll_block_reg); 2992 __ cmpdi(CCR0, R22_tmp2, (unsigned)Deoptimization::Unpack_uncommon_trap); 2993 __ asm_assert_eq("SharedRuntime::generate_deopt_blob: expected Unpack_uncommon_trap", 0); 2994 #endif 2995 2996 // Allocate new interpreter frame(s) and possibly a c2i adapter 2997 // frame. 2998 push_skeleton_frames(masm, false/*deopt*/, 2999 unroll_block_reg, 3000 R22_tmp2, 3001 R23_tmp3, 3002 R24_tmp4, 3003 R25_tmp5, 3004 R26_tmp6); 3005 3006 // stack: (skeletal interpreter frame, ..., optional skeletal 3007 // interpreter frame, optional c2i, caller of deoptee, ...). 3008 3009 // Push a dummy `unpack_frame' taking care of float return values. 3010 // Call `Deoptimization::unpack_frames' to layout information in the 3011 // interpreter frames just created. 3012 3013 // Push a simple "unpack frame" here. 3014 __ push_frame_reg_args(0, R11_scratch1); 3015 3016 // stack: (unpack frame, skeletal interpreter frame, ..., optional 3017 // skeletal interpreter frame, optional c2i, caller of deoptee, 3018 // ...). 3019 3020 // Set the "unpack_frame" as last_Java_frame. 3021 __ get_PC_trash_LR(R11_scratch1); 3022 __ set_last_Java_frame(/*sp*/R1_SP, /*pc*/R11_scratch1); 3023 3024 // Indicate it is the uncommon trap case. 3025 __ li(unc_trap_reg, Deoptimization::Unpack_uncommon_trap); 3026 // Let the unpacker layout information in the skeletal frames just 3027 // allocated. 3028 __ call_VM_leaf(CAST_FROM_FN_PTR(address, Deoptimization::unpack_frames), 3029 R16_thread, unc_trap_reg); 3030 3031 __ reset_last_Java_frame(); 3032 // Pop the `unpack frame'. 3033 __ pop_frame(); 3034 // Restore LR from top interpreter frame. 3035 __ restore_LR_CR(R11_scratch1); 3036 3037 // stack: (top interpreter frame, ..., optional interpreter frame, 3038 // optional c2i, caller of deoptee, ...). 3039 3040 __ restore_interpreter_state(R11_scratch1); 3041 __ load_const_optimized(R25_templateTableBase, (address)Interpreter::dispatch_table((TosState)0), R11_scratch1); 3042 3043 // Return to the interpreter entry point. 3044 __ blr(); 3045 3046 masm->flush(); 3047 3048 _uncommon_trap_blob = UncommonTrapBlob::create(&buffer, oop_maps, frame_size_in_bytes/wordSize); 3049 } 3050 #endif // COMPILER2 3051 3052 // Generate a special Compile2Runtime blob that saves all registers, and setup oopmap. 3053 SafepointBlob* SharedRuntime::generate_handler_blob(address call_ptr, int poll_type) { 3054 assert(StubRoutines::forward_exception_entry() != NULL, 3055 "must be generated before"); 3056 3057 ResourceMark rm; 3058 OopMapSet *oop_maps = new OopMapSet(); 3059 OopMap* map; 3060 3061 // Allocate space for the code. Setup code generation tools. 3062 CodeBuffer buffer("handler_blob", 2048, 1024); 3063 MacroAssembler* masm = new MacroAssembler(&buffer); 3064 3065 address start = __ pc(); 3066 int frame_size_in_bytes = 0; 3067 3068 RegisterSaver::ReturnPCLocation return_pc_location; 3069 bool cause_return = (poll_type == POLL_AT_RETURN); 3070 if (cause_return) { 3071 // Nothing to do here. The frame has already been popped in MachEpilogNode. 3072 // Register LR already contains the return pc. 3073 return_pc_location = RegisterSaver::return_pc_is_lr; 3074 } else { 3075 // Use thread()->saved_exception_pc() as return pc. 3076 return_pc_location = RegisterSaver::return_pc_is_thread_saved_exception_pc; 3077 } 3078 3079 // Save registers, fpu state, and flags. 3080 map = RegisterSaver::push_frame_reg_args_and_save_live_registers(masm, 3081 &frame_size_in_bytes, 3082 /*generate_oop_map=*/ true, 3083 /*return_pc_adjustment=*/0, 3084 return_pc_location); 3085 3086 // The following is basically a call_VM. However, we need the precise 3087 // address of the call in order to generate an oopmap. Hence, we do all the 3088 // work outselves. 3089 __ set_last_Java_frame(/*sp=*/R1_SP, /*pc=*/noreg); 3090 3091 // The return address must always be correct so that the frame constructor 3092 // never sees an invalid pc. 3093 3094 // Do the call 3095 __ call_VM_leaf(call_ptr, R16_thread); 3096 address calls_return_pc = __ last_calls_return_pc(); 3097 3098 // Set an oopmap for the call site. This oopmap will map all 3099 // oop-registers and debug-info registers as callee-saved. This 3100 // will allow deoptimization at this safepoint to find all possible 3101 // debug-info recordings, as well as let GC find all oops. 3102 oop_maps->add_gc_map(calls_return_pc - start, map); 3103 3104 Label noException; 3105 3106 // Clear the last Java frame. 3107 __ reset_last_Java_frame(); 3108 3109 BLOCK_COMMENT(" Check pending exception."); 3110 const Register pending_exception = R0; 3111 __ ld(pending_exception, thread_(pending_exception)); 3112 __ cmpdi(CCR0, pending_exception, 0); 3113 __ beq(CCR0, noException); 3114 3115 // Exception pending 3116 RegisterSaver::restore_live_registers_and_pop_frame(masm, 3117 frame_size_in_bytes, 3118 /*restore_ctr=*/true); 3119 3120 BLOCK_COMMENT(" Jump to forward_exception_entry."); 3121 // Jump to forward_exception_entry, with the issuing PC in LR 3122 // so it looks like the original nmethod called forward_exception_entry. 3123 __ b64_patchable(StubRoutines::forward_exception_entry(), relocInfo::runtime_call_type); 3124 3125 // No exception case. 3126 __ BIND(noException); 3127 3128 3129 // Normal exit, restore registers and exit. 3130 RegisterSaver::restore_live_registers_and_pop_frame(masm, 3131 frame_size_in_bytes, 3132 /*restore_ctr=*/true); 3133 3134 __ blr(); 3135 3136 // Make sure all code is generated 3137 masm->flush(); 3138 3139 // Fill-out other meta info 3140 // CodeBlob frame size is in words. 3141 return SafepointBlob::create(&buffer, oop_maps, frame_size_in_bytes / wordSize); 3142 } 3143 3144 // generate_resolve_blob - call resolution (static/virtual/opt-virtual/ic-miss) 3145 // 3146 // Generate a stub that calls into the vm to find out the proper destination 3147 // of a java call. All the argument registers are live at this point 3148 // but since this is generic code we don't know what they are and the caller 3149 // must do any gc of the args. 3150 // 3151 RuntimeStub* SharedRuntime::generate_resolve_blob(address destination, const char* name) { 3152 3153 // allocate space for the code 3154 ResourceMark rm; 3155 3156 CodeBuffer buffer(name, 1000, 512); 3157 MacroAssembler* masm = new MacroAssembler(&buffer); 3158 3159 int frame_size_in_bytes; 3160 3161 OopMapSet *oop_maps = new OopMapSet(); 3162 OopMap* map = NULL; 3163 3164 address start = __ pc(); 3165 3166 map = RegisterSaver::push_frame_reg_args_and_save_live_registers(masm, 3167 &frame_size_in_bytes, 3168 /*generate_oop_map*/ true, 3169 /*return_pc_adjustment*/ 0, 3170 RegisterSaver::return_pc_is_lr); 3171 3172 // Use noreg as last_Java_pc, the return pc will be reconstructed 3173 // from the physical frame. 3174 __ set_last_Java_frame(/*sp*/R1_SP, noreg); 3175 3176 int frame_complete = __ offset(); 3177 3178 // Pass R19_method as 2nd (optional) argument, used by 3179 // counter_overflow_stub. 3180 __ call_VM_leaf(destination, R16_thread, R19_method); 3181 address calls_return_pc = __ last_calls_return_pc(); 3182 // Set an oopmap for the call site. 3183 // We need this not only for callee-saved registers, but also for volatile 3184 // registers that the compiler might be keeping live across a safepoint. 3185 // Create the oopmap for the call's return pc. 3186 oop_maps->add_gc_map(calls_return_pc - start, map); 3187 3188 // R3_RET contains the address we are going to jump to assuming no exception got installed. 3189 3190 // clear last_Java_sp 3191 __ reset_last_Java_frame(); 3192 3193 // Check for pending exceptions. 3194 BLOCK_COMMENT("Check for pending exceptions."); 3195 Label pending; 3196 __ ld(R11_scratch1, thread_(pending_exception)); 3197 __ cmpdi(CCR0, R11_scratch1, 0); 3198 __ bne(CCR0, pending); 3199 3200 __ mtctr(R3_RET); // Ctr will not be touched by restore_live_registers_and_pop_frame. 3201 3202 RegisterSaver::restore_live_registers_and_pop_frame(masm, frame_size_in_bytes, /*restore_ctr*/ false); 3203 3204 // Get the returned method. 3205 __ get_vm_result_2(R19_method); 3206 3207 __ bctr(); 3208 3209 3210 // Pending exception after the safepoint. 3211 __ BIND(pending); 3212 3213 RegisterSaver::restore_live_registers_and_pop_frame(masm, frame_size_in_bytes, /*restore_ctr*/ true); 3214 3215 // exception pending => remove activation and forward to exception handler 3216 3217 __ li(R11_scratch1, 0); 3218 __ ld(R3_ARG1, thread_(pending_exception)); 3219 __ std(R11_scratch1, in_bytes(JavaThread::vm_result_offset()), R16_thread); 3220 __ b64_patchable(StubRoutines::forward_exception_entry(), relocInfo::runtime_call_type); 3221 3222 // ------------- 3223 // Make sure all code is generated. 3224 masm->flush(); 3225 3226 // return the blob 3227 // frame_size_words or bytes?? 3228 return RuntimeStub::new_runtime_stub(name, &buffer, frame_complete, frame_size_in_bytes/wordSize, 3229 oop_maps, true); 3230 } 3231 3232 3233 //------------------------------Montgomery multiplication------------------------ 3234 // 3235 3236 // Subtract 0:b from carry:a. Return carry. 3237 static unsigned long 3238 sub(unsigned long a[], unsigned long b[], unsigned long carry, long len) { 3239 long i = 0; 3240 unsigned long tmp, tmp2; 3241 __asm__ __volatile__ ( 3242 "subfc %[tmp], %[tmp], %[tmp] \n" // pre-set CA 3243 "mtctr %[len] \n" 3244 "0: \n" 3245 "ldx %[tmp], %[i], %[a] \n" 3246 "ldx %[tmp2], %[i], %[b] \n" 3247 "subfe %[tmp], %[tmp2], %[tmp] \n" // subtract extended 3248 "stdx %[tmp], %[i], %[a] \n" 3249 "addi %[i], %[i], 8 \n" 3250 "bdnz 0b \n" 3251 "addme %[tmp], %[carry] \n" // carry + CA - 1 3252 : [i]"+b"(i), [tmp]"=&r"(tmp), [tmp2]"=&r"(tmp2) 3253 : [a]"r"(a), [b]"r"(b), [carry]"r"(carry), [len]"r"(len) 3254 : "ctr", "xer", "memory" 3255 ); 3256 return tmp; 3257 } 3258 3259 // Multiply (unsigned) Long A by Long B, accumulating the double- 3260 // length result into the accumulator formed of T0, T1, and T2. 3261 inline void MACC(unsigned long A, unsigned long B, unsigned long &T0, unsigned long &T1, unsigned long &T2) { 3262 unsigned long hi, lo; 3263 __asm__ __volatile__ ( 3264 "mulld %[lo], %[A], %[B] \n" 3265 "mulhdu %[hi], %[A], %[B] \n" 3266 "addc %[T0], %[T0], %[lo] \n" 3267 "adde %[T1], %[T1], %[hi] \n" 3268 "addze %[T2], %[T2] \n" 3269 : [hi]"=&r"(hi), [lo]"=&r"(lo), [T0]"+r"(T0), [T1]"+r"(T1), [T2]"+r"(T2) 3270 : [A]"r"(A), [B]"r"(B) 3271 : "xer" 3272 ); 3273 } 3274 3275 // As above, but add twice the double-length result into the 3276 // accumulator. 3277 inline void MACC2(unsigned long A, unsigned long B, unsigned long &T0, unsigned long &T1, unsigned long &T2) { 3278 unsigned long hi, lo; 3279 __asm__ __volatile__ ( 3280 "mulld %[lo], %[A], %[B] \n" 3281 "mulhdu %[hi], %[A], %[B] \n" 3282 "addc %[T0], %[T0], %[lo] \n" 3283 "adde %[T1], %[T1], %[hi] \n" 3284 "addze %[T2], %[T2] \n" 3285 "addc %[T0], %[T0], %[lo] \n" 3286 "adde %[T1], %[T1], %[hi] \n" 3287 "addze %[T2], %[T2] \n" 3288 : [hi]"=&r"(hi), [lo]"=&r"(lo), [T0]"+r"(T0), [T1]"+r"(T1), [T2]"+r"(T2) 3289 : [A]"r"(A), [B]"r"(B) 3290 : "xer" 3291 ); 3292 } 3293 3294 // Fast Montgomery multiplication. The derivation of the algorithm is 3295 // in "A Cryptographic Library for the Motorola DSP56000, 3296 // Dusse and Kaliski, Proc. EUROCRYPT 90, pp. 230-237". 3297 static void 3298 montgomery_multiply(unsigned long a[], unsigned long b[], unsigned long n[], 3299 unsigned long m[], unsigned long inv, int len) { 3300 unsigned long t0 = 0, t1 = 0, t2 = 0; // Triple-precision accumulator 3301 int i; 3302 3303 assert(inv * n[0] == -1UL, "broken inverse in Montgomery multiply"); 3304 3305 for (i = 0; i < len; i++) { 3306 int j; 3307 for (j = 0; j < i; j++) { 3308 MACC(a[j], b[i-j], t0, t1, t2); 3309 MACC(m[j], n[i-j], t0, t1, t2); 3310 } 3311 MACC(a[i], b[0], t0, t1, t2); 3312 m[i] = t0 * inv; 3313 MACC(m[i], n[0], t0, t1, t2); 3314 3315 assert(t0 == 0, "broken Montgomery multiply"); 3316 3317 t0 = t1; t1 = t2; t2 = 0; 3318 } 3319 3320 for (i = len; i < 2*len; i++) { 3321 int j; 3322 for (j = i-len+1; j < len; j++) { 3323 MACC(a[j], b[i-j], t0, t1, t2); 3324 MACC(m[j], n[i-j], t0, t1, t2); 3325 } 3326 m[i-len] = t0; 3327 t0 = t1; t1 = t2; t2 = 0; 3328 } 3329 3330 while (t0) { 3331 t0 = sub(m, n, t0, len); 3332 } 3333 } 3334 3335 // Fast Montgomery squaring. This uses asymptotically 25% fewer 3336 // multiplies so it should be up to 25% faster than Montgomery 3337 // multiplication. However, its loop control is more complex and it 3338 // may actually run slower on some machines. 3339 static void 3340 montgomery_square(unsigned long a[], unsigned long n[], 3341 unsigned long m[], unsigned long inv, int len) { 3342 unsigned long t0 = 0, t1 = 0, t2 = 0; // Triple-precision accumulator 3343 int i; 3344 3345 assert(inv * n[0] == -1UL, "broken inverse in Montgomery multiply"); 3346 3347 for (i = 0; i < len; i++) { 3348 int j; 3349 int end = (i+1)/2; 3350 for (j = 0; j < end; j++) { 3351 MACC2(a[j], a[i-j], t0, t1, t2); 3352 MACC(m[j], n[i-j], t0, t1, t2); 3353 } 3354 if ((i & 1) == 0) { 3355 MACC(a[j], a[j], t0, t1, t2); 3356 } 3357 for (; j < i; j++) { 3358 MACC(m[j], n[i-j], t0, t1, t2); 3359 } 3360 m[i] = t0 * inv; 3361 MACC(m[i], n[0], t0, t1, t2); 3362 3363 assert(t0 == 0, "broken Montgomery square"); 3364 3365 t0 = t1; t1 = t2; t2 = 0; 3366 } 3367 3368 for (i = len; i < 2*len; i++) { 3369 int start = i-len+1; 3370 int end = start + (len - start)/2; 3371 int j; 3372 for (j = start; j < end; j++) { 3373 MACC2(a[j], a[i-j], t0, t1, t2); 3374 MACC(m[j], n[i-j], t0, t1, t2); 3375 } 3376 if ((i & 1) == 0) { 3377 MACC(a[j], a[j], t0, t1, t2); 3378 } 3379 for (; j < len; j++) { 3380 MACC(m[j], n[i-j], t0, t1, t2); 3381 } 3382 m[i-len] = t0; 3383 t0 = t1; t1 = t2; t2 = 0; 3384 } 3385 3386 while (t0) { 3387 t0 = sub(m, n, t0, len); 3388 } 3389 } 3390 3391 // The threshold at which squaring is advantageous was determined 3392 // experimentally on an i7-3930K (Ivy Bridge) CPU @ 3.5GHz. 3393 // Doesn't seem to be relevant for Power8 so we use the same value. 3394 #define MONTGOMERY_SQUARING_THRESHOLD 64 3395 3396 // Copy len longwords from s to d, word-swapping as we go. The 3397 // destination array is reversed. 3398 static void reverse_words(unsigned long *s, unsigned long *d, int len) { 3399 d += len; 3400 while(len-- > 0) { 3401 d--; 3402 unsigned long s_val = *s; 3403 // Swap words in a longword on little endian machines. 3404 #ifdef VM_LITTLE_ENDIAN 3405 s_val = (s_val << 32) | (s_val >> 32); 3406 #endif 3407 *d = s_val; 3408 s++; 3409 } 3410 } 3411 3412 void SharedRuntime::montgomery_multiply(jint *a_ints, jint *b_ints, jint *n_ints, 3413 jint len, jlong inv, 3414 jint *m_ints) { 3415 len = len & 0x7fffFFFF; // C2 does not respect int to long conversion for stub calls. 3416 assert(len % 2 == 0, "array length in montgomery_multiply must be even"); 3417 int longwords = len/2; 3418 3419 // Make very sure we don't use so much space that the stack might 3420 // overflow. 512 jints corresponds to an 16384-bit integer and 3421 // will use here a total of 8k bytes of stack space. 3422 int total_allocation = longwords * sizeof (unsigned long) * 4; 3423 guarantee(total_allocation <= 8192, "must be"); 3424 unsigned long *scratch = (unsigned long *)alloca(total_allocation); 3425 3426 // Local scratch arrays 3427 unsigned long 3428 *a = scratch + 0 * longwords, 3429 *b = scratch + 1 * longwords, 3430 *n = scratch + 2 * longwords, 3431 *m = scratch + 3 * longwords; 3432 3433 reverse_words((unsigned long *)a_ints, a, longwords); 3434 reverse_words((unsigned long *)b_ints, b, longwords); 3435 reverse_words((unsigned long *)n_ints, n, longwords); 3436 3437 ::montgomery_multiply(a, b, n, m, (unsigned long)inv, longwords); 3438 3439 reverse_words(m, (unsigned long *)m_ints, longwords); 3440 } 3441 3442 void SharedRuntime::montgomery_square(jint *a_ints, jint *n_ints, 3443 jint len, jlong inv, 3444 jint *m_ints) { 3445 len = len & 0x7fffFFFF; // C2 does not respect int to long conversion for stub calls. 3446 assert(len % 2 == 0, "array length in montgomery_square must be even"); 3447 int longwords = len/2; 3448 3449 // Make very sure we don't use so much space that the stack might 3450 // overflow. 512 jints corresponds to an 16384-bit integer and 3451 // will use here a total of 6k bytes of stack space. 3452 int total_allocation = longwords * sizeof (unsigned long) * 3; 3453 guarantee(total_allocation <= 8192, "must be"); 3454 unsigned long *scratch = (unsigned long *)alloca(total_allocation); 3455 3456 // Local scratch arrays 3457 unsigned long 3458 *a = scratch + 0 * longwords, 3459 *n = scratch + 1 * longwords, 3460 *m = scratch + 2 * longwords; 3461 3462 reverse_words((unsigned long *)a_ints, a, longwords); 3463 reverse_words((unsigned long *)n_ints, n, longwords); 3464 3465 if (len >= MONTGOMERY_SQUARING_THRESHOLD) { 3466 ::montgomery_square(a, n, m, (unsigned long)inv, longwords); 3467 } else { 3468 ::montgomery_multiply(a, a, n, m, (unsigned long)inv, longwords); 3469 } 3470 3471 reverse_words(m, (unsigned long *)m_ints, longwords); 3472 }