SsaRenamer.java revision 579d7739c53a2707ad711a2d2cae46d7d782f061
1/* 2 * Copyright (C) 2007 The Android Open Source Project 3 * 4 * Licensed under the Apache License, Version 2.0 (the "License"); 5 * you may not use this file except in compliance with the License. 6 * You may obtain a copy of the License at 7 * 8 * http://www.apache.org/licenses/LICENSE-2.0 9 * 10 * Unless required by applicable law or agreed to in writing, software 11 * distributed under the License is distributed on an "AS IS" BASIS, 12 * WITHOUT WARRANTIES OR CONDITIONS OF ANY KIND, either express or implied. 13 * See the License for the specific language governing permissions and 14 * limitations under the License. 15 */ 16 17package com.android.dx.ssa; 18 19import com.android.dx.rop.code.LocalItem; 20import com.android.dx.rop.code.PlainInsn; 21import com.android.dx.rop.code.RegisterSpec; 22import com.android.dx.rop.code.RegisterSpecList; 23import com.android.dx.rop.code.Rops; 24import com.android.dx.rop.code.SourcePosition; 25import com.android.dx.rop.type.Type; 26import com.android.dx.util.IntList; 27 28import java.util.ArrayList; 29import java.util.BitSet; 30import java.util.HashMap; 31import java.util.HashSet; 32 33/** 34 * Complete transformation to SSA form by renaming all registers accessed.<p> 35 * 36 * See Appel algorithm 19.7<p> 37 * 38 * Unlike the original algorithm presented in Appel, this renamer converts 39 * to a new flat (versionless) register space. The "version 0" registers, 40 * which represent the initial state of the Rop registers and should never 41 * actually be meaningfully accessed in a legal program, are represented 42 * as the first N registers in the SSA namespace. Subsequent assignments 43 * are assigned new unique names. Note that the incoming Rop representation 44 * has a concept of register widths, where 64-bit values are stored into 45 * two adjoining Rop registers. This adjoining register representation is 46 * ignored in SSA form conversion and while in SSA form, each register can be e 47 * either 32 or 64 bits wide depending on use. The adjoining-register 48 * represention is re-created later when converting back to Rop form. <p> 49 * 50 * But, please note, the SSA Renamer's ignoring of the adjoining-register ROP 51 * representation means that unaligned accesses to 64-bit registers are not 52 * supported. For example, you cannot do a 32-bit operation on a portion of 53 * a 64-bit register. This will never be observed to happen when coming 54 * from Java code, of course.<p> 55 * 56 * The implementation here, rather than keeping a single register version 57 * stack for the entire method as the dom tree is walked, instead keeps 58 * a mapping table for the current block being processed. Once the 59 * current block has been processed, this mapping table is then copied 60 * and used as the initial state for child blocks.<p> 61 */ 62public class SsaRenamer implements Runnable { 63 /** debug flag */ 64 private static final boolean DEBUG = false; 65 66 /** method we're processing */ 67 private final SsaMethod ssaMeth; 68 69 /** next available SSA register */ 70 private int nextSsaReg; 71 72 /** the number of original rop registers */ 73 private final int ropRegCount; 74 75 /** work only on registers above this value */ 76 private int threshold; 77 78 /** 79 * indexed by block index; register version state for each block start. 80 * This list is updated by each dom parent for its children. The only 81 * sub-arrays that exist at any one time are the start states for blocks 82 * yet to be processed by a {@code BlockRenamer} instance. 83 */ 84 private final RegisterSpec[][] startsForBlocks; 85 86 /** map of SSA register number to debug (local var names) or null of n/a */ 87 private final ArrayList<LocalItem> ssaRegToLocalItems; 88 89 /** 90 * maps SSA registers back to the original rop number. Used for 91 * debug only. 92 */ 93 private IntList ssaRegToRopReg; 94 95 /** 96 * Constructs an instance of the renamer 97 * 98 * @param ssaMeth {@code non-null;} un-renamed SSA method that will 99 * be renamed. 100 */ 101 public SsaRenamer(SsaMethod ssaMeth) { 102 ropRegCount = ssaMeth.getRegCount(); 103 104 this.ssaMeth = ssaMeth; 105 106 /* 107 * Reserve the first N registers in the SSA register space for 108 * "version 0" registers. 109 */ 110 nextSsaReg = ropRegCount; 111 threshold = 0; 112 startsForBlocks = new RegisterSpec[ssaMeth.getBlocks().size()][]; 113 114 ssaRegToLocalItems = new ArrayList<LocalItem>(); 115 116 if (DEBUG) { 117 ssaRegToRopReg = new IntList(ropRegCount); 118 } 119 120 /* 121 * Appel 19.7 122 * 123 * Initialization: 124 * for each variable a // register i 125 * Count[a] <- 0 // nextSsaReg, flattened 126 * Stack[a] <- 0 // versionStack 127 * push 0 onto Stack[a] 128 * 129 */ 130 131 // top entry for the version stack is version 0 132 RegisterSpec[] initialRegMapping = new RegisterSpec[ropRegCount]; 133 for (int i = 0; i < ropRegCount; i++) { 134 // everyone starts with a version 0 register 135 initialRegMapping[i] = RegisterSpec.make(i, Type.VOID); 136 137 if (DEBUG) { 138 ssaRegToRopReg.add(i); 139 } 140 } 141 142 // Initial state for entry block 143 startsForBlocks[ssaMeth.getEntryBlockIndex()] = initialRegMapping; 144 } 145 146 /** 147 * Constructs an instance of the renamer with threshold set 148 * 149 * @param ssaMeth {@code non-null;} un-renamed SSA method that will 150 * be renamed. 151 * @param thresh registers below this number are unchanged 152 */ 153 public SsaRenamer(SsaMethod ssaMeth, int thresh) { 154 this(ssaMeth); 155 threshold = thresh; 156 } 157 158 /** 159 * Performs renaming transformation, modifying the method's instructions 160 * in-place. 161 */ 162 public void run() { 163 // Rename each block in dom-tree DFS order. 164 ssaMeth.forEachBlockDepthFirstDom(new SsaBasicBlock.Visitor() { 165 public void visitBlock (SsaBasicBlock block, 166 SsaBasicBlock unused) { 167 new BlockRenamer(block).process(); 168 } 169 }); 170 171 ssaMeth.setNewRegCount(nextSsaReg); 172 ssaMeth.onInsnsChanged(); 173 174 if (DEBUG) { 175 System.out.println("SSA\tRop"); 176 /* 177 * We're going to compute the version of the rop register 178 * by keeping a running total of how many times the rop 179 * register has been mapped. 180 */ 181 int[] versions = new int[ropRegCount]; 182 183 int sz = ssaRegToRopReg.size(); 184 for (int i = 0; i < sz; i++) { 185 int ropReg = ssaRegToRopReg.get(i); 186 System.out.println(i + "\t" + ropReg + "[" 187 + versions[ropReg] + "]"); 188 versions[ropReg]++; 189 } 190 } 191 } 192 193 /** 194 * Duplicates a RegisterSpec array. 195 * 196 * @param orig {@code non-null;} array to duplicate 197 * @return {@code non-null;} new instance 198 */ 199 private static RegisterSpec[] dupArray(RegisterSpec[] orig) { 200 RegisterSpec[] copy = new RegisterSpec[orig.length]; 201 202 System.arraycopy(orig, 0, copy, 0, orig.length); 203 204 return copy; 205 } 206 207 /** 208 * Gets a local variable item for a specified register. 209 * 210 * @param ssaReg register in SSA name space 211 * @return {@code null-ok;} Local variable name or null if none 212 */ 213 private LocalItem getLocalForNewReg(int ssaReg) { 214 if (ssaReg < ssaRegToLocalItems.size()) { 215 return ssaRegToLocalItems.get(ssaReg); 216 } else { 217 return null; 218 } 219 } 220 221 /** 222 * Records a debug (local variable) name for a specified register. 223 * 224 * @param ssaReg non-null named register spec in SSA name space 225 */ 226 private void setNameForSsaReg(RegisterSpec ssaReg) { 227 int reg = ssaReg.getReg(); 228 LocalItem local = ssaReg.getLocalItem(); 229 230 ssaRegToLocalItems.ensureCapacity(reg + 1); 231 while (ssaRegToLocalItems.size() <= reg) { 232 ssaRegToLocalItems.add(null); 233 } 234 235 ssaRegToLocalItems.set(reg, local); 236 } 237 238 /** 239 * Returns true if this SSA register is below the specified threshold. 240 * Used when most code is already in SSA form, and renaming is needed only 241 * for registers above a certain threshold. 242 * 243 * @param ssaReg the SSA register in question 244 * @return {@code true} if its register number is below the threshold 245 */ 246 private boolean isBelowThresholdRegister(int ssaReg) { 247 return ssaReg < threshold; 248 } 249 250 /** 251 * Returns true if this SSA register is a "version 0" 252 * register. All version 0 registers are assigned the first N register 253 * numbers, where N is the count of original rop registers. 254 * 255 * @param ssaReg the SSA register in question 256 * @return true if it is a version 0 register. 257 */ 258 private boolean isVersionZeroRegister(int ssaReg) { 259 return ssaReg < ropRegCount; 260 } 261 262 /** 263 * Returns true if a and b are equal or are both null. 264 * 265 * @param a null-ok 266 * @param b null-ok 267 * @return Returns true if a and b are equal or are both null 268 */ 269 private static boolean equalsHandlesNulls(Object a, Object b) { 270 return a == b || (a != null && a.equals(b)); 271 } 272 273 /** 274 * Processes all insns in a block and renames their registers 275 * as appropriate. 276 */ 277 private class BlockRenamer implements SsaInsn.Visitor{ 278 /** {@code non-null;} block we're processing. */ 279 private final SsaBasicBlock block; 280 281 /** 282 * {@code non-null;} indexed by old register name. The current 283 * top of the version stack as seen by this block. It's 284 * initialized from the ending state of its dom parent, 285 * updated as the block's instructions are processed, and then 286 * copied to each one of its dom children. 287 */ 288 private final RegisterSpec[] currentMapping; 289 290 /** 291 * contains the set of moves we need to keep to preserve local 292 * var info. All other moves will be deleted. 293 */ 294 private final HashSet<SsaInsn> movesToKeep; 295 296 /** 297 * maps the set of insns to replace after renaming is finished 298 * on the block. 299 */ 300 private final HashMap<SsaInsn, SsaInsn> insnsToReplace; 301 302 private final RenamingMapper mapper; 303 304 /** 305 * Constructs a block renamer instance. Call {@code process} 306 * to process. 307 * 308 * @param block {@code non-null;} block to process 309 */ 310 BlockRenamer(final SsaBasicBlock block) { 311 this.block = block; 312 currentMapping = startsForBlocks[block.getIndex()]; 313 movesToKeep = new HashSet<SsaInsn>(); 314 insnsToReplace = new HashMap<SsaInsn, SsaInsn>(); 315 mapper = new RenamingMapper(); 316 317 // We don't need our own start state anymore 318 startsForBlocks[block.getIndex()] = null; 319 } 320 321 /** 322 * Provides a register mapping between the old register space 323 * and the current renaming mapping. The mapping is updated 324 * as the current block's instructions are processed. 325 */ 326 private class RenamingMapper extends RegisterMapper { 327 public RenamingMapper() { 328 // This space intentionally left blank. 329 } 330 331 /** {@inheritDoc} */ 332 @Override 333 public int getNewRegisterCount() { 334 return nextSsaReg; 335 } 336 337 /** {@inheritDoc} */ 338 @Override 339 public RegisterSpec map(RegisterSpec registerSpec) { 340 if (registerSpec == null) return null; 341 342 int reg = registerSpec.getReg(); 343 344 // For debugging: assert that the mapped types are compatible. 345 if (DEBUG) { 346 RegisterSpec newVersion = currentMapping[reg]; 347 if (newVersion.getBasicType() != Type.BT_VOID 348 && registerSpec.getBasicFrameType() 349 != newVersion.getBasicFrameType()) { 350 351 throw new RuntimeException( 352 "mapping registers of incompatible types! " 353 + registerSpec 354 + " " + currentMapping[reg]); 355 } 356 } 357 358 return registerSpec.withReg(currentMapping[reg].getReg()); 359 } 360 } 361 362 /** 363 * Renames all the variables in this block and inserts appriopriate 364 * phis in successor blocks. 365 */ 366 public void process() { 367 /* 368 * From Appel: 369 * 370 * Rename(n) = 371 * for each statement S in block n // 'statement' in 'block' 372 */ 373 374 block.forEachInsn(this); 375 376 updateSuccessorPhis(); 377 378 // Delete all move insns in this block. 379 ArrayList<SsaInsn> insns = block.getInsns(); 380 int szInsns = insns.size(); 381 382 for (int i = szInsns - 1; i >= 0 ; i--) { 383 SsaInsn insn = insns.get(i); 384 SsaInsn replaceInsn; 385 386 replaceInsn = insnsToReplace.get(insn); 387 388 if (replaceInsn != null) { 389 insns.set(i, replaceInsn); 390 } else if (insn.isNormalMoveInsn() 391 && !movesToKeep.contains(insn)) { 392 insns.remove(i); 393 } 394 } 395 396 // Store the start states for our dom children. 397 boolean first = true; 398 for (SsaBasicBlock child : block.getDomChildren()) { 399 if (child != block) { 400 // Don't bother duplicating the array for the first child. 401 RegisterSpec[] childStart = first ? currentMapping 402 : dupArray(currentMapping); 403 404 startsForBlocks[child.getIndex()] = childStart; 405 first = false; 406 } 407 } 408 409 // currentMapping is owned by a child now. 410 } 411 412 /** 413 * Enforces a few contraints when a register mapping is added. 414 * 415 * <ol> 416 * <li> Ensures that all new SSA registers specs in the mapping 417 * table with the same register number are identical. In effect, once 418 * an SSA register spec has received or lost a local variable name, 419 * then every old-namespace register that maps to it should gain or 420 * lose its local variable name as well. 421 * <li> Records the local name associated with the 422 * register so that a register is never associated with more than one 423 * local. 424 * <li> ensures that only one SSA register 425 * at a time is considered to be associated with a local variable. When 426 * {@code currentMapping} is updated and the newly added element 427 * is named, strip that name from any other SSA registers. 428 * </ol> 429 * 430 * @param ropReg {@code >= 0;} rop register number 431 * @param ssaReg {@code non-null;} an SSA register that has just 432 * been added to {@code currentMapping} 433 */ 434 private void addMapping(int ropReg, RegisterSpec ssaReg) { 435 int ssaRegNum = ssaReg.getReg(); 436 LocalItem ssaRegLocal = ssaReg.getLocalItem(); 437 438 currentMapping[ropReg] = ssaReg; 439 440 /* 441 * Ensure all SSA register specs with the same reg are identical. 442 */ 443 for (int i = currentMapping.length - 1; i >= 0; i--) { 444 RegisterSpec cur = currentMapping[i]; 445 446 if (ssaRegNum == cur.getReg()) { 447 currentMapping[i] = ssaReg; 448 } 449 } 450 451 // All further steps are for registers with local information. 452 if (ssaRegLocal == null) { 453 return; 454 } 455 456 // Record that this SSA reg has been associated with a local. 457 setNameForSsaReg(ssaReg); 458 459 // Ensure that no other SSA regs are associated with this local. 460 for (int i = currentMapping.length - 1; i >= 0; i--) { 461 RegisterSpec cur = currentMapping[i]; 462 463 if (ssaRegNum != cur.getReg() 464 && ssaRegLocal.equals(cur.getLocalItem())) { 465 currentMapping[i] = cur.withLocalItem(null); 466 } 467 } 468 } 469 470 /** 471 * {@inheritDoc} 472 * 473 * Phi insns have their result registers renamed. 474 */ 475 public void visitPhiInsn(PhiInsn phi) { 476 /* don't process sources for phi's */ 477 processResultReg(phi); 478 } 479 480 /** 481 * {@inheritDoc} 482 * 483 * Move insns are treated as a simple mapping operation, and 484 * will later be removed unless they represent a local variable 485 * assignment. If they represent a local variable assignement, they 486 * are preserved. 487 */ 488 public void visitMoveInsn(NormalSsaInsn insn) { 489 /* 490 * For moves: copy propogate the move if we can, but don't 491 * if we need to preserve local variable info and the 492 * result has a different name than the source. 493 */ 494 495 RegisterSpec ropResult = insn.getResult(); 496 int ropResultReg = ropResult.getReg(); 497 int ropSourceReg = insn.getSources().get(0).getReg(); 498 499 insn.mapSourceRegisters(mapper); 500 int ssaSourceReg = insn.getSources().get(0).getReg(); 501 502 LocalItem sourceLocal 503 = currentMapping[ropSourceReg].getLocalItem(); 504 LocalItem resultLocal = ropResult.getLocalItem(); 505 506 /* 507 * A move from a register that's currently associated with a local 508 * to one that will not be associated with a local does not need 509 * to be preserved, but the local association should remain. 510 * Hence, we inherit the sourceLocal where the resultLocal is null. 511 */ 512 513 LocalItem newLocal 514 = (resultLocal == null) ? sourceLocal : resultLocal; 515 LocalItem associatedLocal = getLocalForNewReg(ssaSourceReg); 516 517 /* 518 * If we take the new local, will only one local have ever 519 * been associated with this SSA reg? 520 */ 521 boolean onlyOneAssociatedLocal 522 = associatedLocal == null || newLocal == null 523 || newLocal.equals(associatedLocal); 524 525 /* 526 * If we're going to copy-propogate, then the ssa register 527 * spec that's going to go into the mapping is made up of 528 * the source register number mapped from above, the type 529 * of the result, and the name either from the result (if 530 * specified) or inherited from the existing mapping. 531 * 532 * The move source has incomplete type information in null 533 * object cases, so the result type is used. 534 */ 535 RegisterSpec ssaReg 536 = RegisterSpec.makeLocalOptional( 537 ssaSourceReg, ropResult.getType(), newLocal); 538 539 if (!Optimizer.getPreserveLocals() || (onlyOneAssociatedLocal 540 && equalsHandlesNulls(newLocal, sourceLocal)) && 541 threshold == 0) { 542 /* 543 * We don't have to keep this move to preserve local 544 * information. Either the name is the same, or the result 545 * register spec is unnamed. 546 */ 547 548 addMapping(ropResultReg, ssaReg); 549 } else if (onlyOneAssociatedLocal && sourceLocal == null && 550 threshold == 0) { 551 /* 552 * The register was previously unnamed. This means that a 553 * local starts after it's first assignment in SSA form 554 */ 555 556 RegisterSpecList ssaSources = RegisterSpecList.make( 557 RegisterSpec.make(ssaReg.getReg(), 558 ssaReg.getType(), newLocal)); 559 560 SsaInsn newInsn 561 = SsaInsn.makeFromRop( 562 new PlainInsn(Rops.opMarkLocal(ssaReg), 563 SourcePosition.NO_INFO, null, ssaSources),block); 564 565 insnsToReplace.put(insn, newInsn); 566 567 // Just map as above. 568 addMapping(ropResultReg, ssaReg); 569 } else { 570 /* 571 * Do not copy-propogate, since the two registers have 572 * two different local-variable names. 573 */ 574 processResultReg(insn); 575 576 movesToKeep.add(insn); 577 } 578 } 579 580 /** 581 * {@inheritDoc} 582 * 583 * All insns that are not move or phi insns have their source registers 584 * mapped ot the current mapping. Their result registers are then 585 * renamed to a new SSA register which is then added to the current 586 * register mapping. 587 */ 588 public void visitNonMoveInsn(NormalSsaInsn insn) { 589 /* for each use of some variable X in S */ 590 insn.mapSourceRegisters(mapper); 591 592 processResultReg(insn); 593 } 594 595 /** 596 * Renames the result register of this insn and updates the 597 * current register mapping. Does nothing if this insn has no result. 598 * Applied to all non-move insns. 599 * 600 * @param insn insn to process. 601 */ 602 void processResultReg(SsaInsn insn) { 603 RegisterSpec ropResult = insn.getResult(); 604 605 if (ropResult == null) { 606 return; 607 } 608 609 int ropReg = ropResult.getReg(); 610 if (isBelowThresholdRegister(ropReg)) { 611 return; 612 } 613 614 insn.changeResultReg(nextSsaReg); 615 addMapping(ropReg, insn.getResult()); 616 617 if (DEBUG) { 618 ssaRegToRopReg.add(ropReg); 619 } 620 621 nextSsaReg++; 622 } 623 624 /** 625 * Updates the phi insns in successor blocks with operands based 626 * on the current mapping of the rop register the phis represent. 627 */ 628 private void updateSuccessorPhis() { 629 PhiInsn.Visitor visitor = new PhiInsn.Visitor() { 630 public void visitPhiInsn (PhiInsn insn) { 631 int ropReg; 632 633 ropReg = insn.getRopResultReg(); 634 if (isBelowThresholdRegister(ropReg)) { 635 return; 636 } 637 638 /* 639 * Never add a version 0 register as a phi 640 * operand. Version 0 registers represent the 641 * initial register state, and thus are never 642 * significant. Furthermore, the register liveness 643 * algorithm doesn't properly count them as "live 644 * in" at the beginning of the method. 645 */ 646 647 RegisterSpec stackTop = currentMapping[ropReg]; 648 if (!isVersionZeroRegister(stackTop.getReg())) { 649 insn.addPhiOperand(stackTop, block); 650 } 651 } 652 }; 653 654 BitSet successors = block.getSuccessors(); 655 for (int i = successors.nextSetBit(0); i >= 0; 656 i = successors.nextSetBit(i + 1)) { 657 SsaBasicBlock successor = ssaMeth.getBlocks().get(i); 658 successor.forEachPhiInsn(visitor); 659 } 660 } 661 } 662} 663