1 //===- CFG.cpp - Classes for representing and building CFGs ---------------===// 2 // 3 // The LLVM Compiler Infrastructure 4 // 5 // This file is distributed under the University of Illinois Open Source 6 // License. See LICENSE.TXT for details. 7 // 8 //===----------------------------------------------------------------------===// 9 // 10 // This file defines the CFG and CFGBuilder classes for representing and 11 // building Control-Flow Graphs (CFGs) from ASTs. 12 // 13 //===----------------------------------------------------------------------===// 14 15 #include "clang/Analysis/CFG.h" 16 #include "clang/AST/ASTContext.h" 17 #include "clang/AST/Attr.h" 18 #include "clang/AST/Decl.h" 19 #include "clang/AST/DeclBase.h" 20 #include "clang/AST/DeclCXX.h" 21 #include "clang/AST/DeclGroup.h" 22 #include "clang/AST/Expr.h" 23 #include "clang/AST/ExprCXX.h" 24 #include "clang/AST/OperationKinds.h" 25 #include "clang/AST/PrettyPrinter.h" 26 #include "clang/AST/Stmt.h" 27 #include "clang/AST/StmtCXX.h" 28 #include "clang/AST/StmtObjC.h" 29 #include "clang/AST/StmtVisitor.h" 30 #include "clang/AST/Type.h" 31 #include "clang/Analysis/Support/BumpVector.h" 32 #include "clang/Analysis/ConstructionContext.h" 33 #include "clang/Basic/Builtins.h" 34 #include "clang/Basic/ExceptionSpecificationType.h" 35 #include "clang/Basic/LLVM.h" 36 #include "clang/Basic/LangOptions.h" 37 #include "clang/Basic/SourceLocation.h" 38 #include "clang/Basic/Specifiers.h" 39 #include "llvm/ADT/APInt.h" 40 #include "llvm/ADT/APSInt.h" 41 #include "llvm/ADT/ArrayRef.h" 42 #include "llvm/ADT/DenseMap.h" 43 #include "llvm/ADT/Optional.h" 44 #include "llvm/ADT/STLExtras.h" 45 #include "llvm/ADT/SetVector.h" 46 #include "llvm/ADT/SmallPtrSet.h" 47 #include "llvm/ADT/SmallVector.h" 48 #include "llvm/Support/Allocator.h" 49 #include "llvm/Support/Casting.h" 50 #include "llvm/Support/Compiler.h" 51 #include "llvm/Support/DOTGraphTraits.h" 52 #include "llvm/Support/ErrorHandling.h" 53 #include "llvm/Support/Format.h" 54 #include "llvm/Support/GraphWriter.h" 55 #include "llvm/Support/SaveAndRestore.h" 56 #include "llvm/Support/raw_ostream.h" 57 #include <cassert> 58 #include <memory> 59 #include <string> 60 #include <tuple> 61 #include <utility> 62 #include <vector> 63 64 using namespace clang; 65 66 static SourceLocation GetEndLoc(Decl *D) { 67 if (VarDecl *VD = dyn_cast<VarDecl>(D)) 68 if (Expr *Ex = VD->getInit()) 69 return Ex->getSourceRange().getEnd(); 70 return D->getLocation(); 71 } 72 73 /// Helper for tryNormalizeBinaryOperator. Attempts to extract an IntegerLiteral 74 /// or EnumConstantDecl from the given Expr. If it fails, returns nullptr. 75 static const Expr *tryTransformToIntOrEnumConstant(const Expr *E) { 76 E = E->IgnoreParens(); 77 if (isa<IntegerLiteral>(E)) 78 return E; 79 if (auto *DR = dyn_cast<DeclRefExpr>(E->IgnoreParenImpCasts())) 80 return isa<EnumConstantDecl>(DR->getDecl()) ? DR : nullptr; 81 return nullptr; 82 } 83 84 /// Tries to interpret a binary operator into `Decl Op Expr` form, if Expr is 85 /// an integer literal or an enum constant. 86 /// 87 /// If this fails, at least one of the returned DeclRefExpr or Expr will be 88 /// null. 89 static std::tuple<const DeclRefExpr *, BinaryOperatorKind, const Expr *> 90 tryNormalizeBinaryOperator(const BinaryOperator *B) { 91 BinaryOperatorKind Op = B->getOpcode(); 92 93 const Expr *MaybeDecl = B->getLHS(); 94 const Expr *Constant = tryTransformToIntOrEnumConstant(B->getRHS()); 95 // Expr looked like `0 == Foo` instead of `Foo == 0` 96 if (Constant == nullptr) { 97 // Flip the operator 98 if (Op == BO_GT) 99 Op = BO_LT; 100 else if (Op == BO_GE) 101 Op = BO_LE; 102 else if (Op == BO_LT) 103 Op = BO_GT; 104 else if (Op == BO_LE) 105 Op = BO_GE; 106 107 MaybeDecl = B->getRHS(); 108 Constant = tryTransformToIntOrEnumConstant(B->getLHS()); 109 } 110 111 auto *D = dyn_cast<DeclRefExpr>(MaybeDecl->IgnoreParenImpCasts()); 112 return std::make_tuple(D, Op, Constant); 113 } 114 115 /// For an expression `x == Foo && x == Bar`, this determines whether the 116 /// `Foo` and `Bar` are either of the same enumeration type, or both integer 117 /// literals. 118 /// 119 /// It's an error to pass this arguments that are not either IntegerLiterals 120 /// or DeclRefExprs (that have decls of type EnumConstantDecl) 121 static bool areExprTypesCompatible(const Expr *E1, const Expr *E2) { 122 // User intent isn't clear if they're mixing int literals with enum 123 // constants. 124 if (isa<IntegerLiteral>(E1) != isa<IntegerLiteral>(E2)) 125 return false; 126 127 // Integer literal comparisons, regardless of literal type, are acceptable. 128 if (isa<IntegerLiteral>(E1)) 129 return true; 130 131 // IntegerLiterals are handled above and only EnumConstantDecls are expected 132 // beyond this point 133 assert(isa<DeclRefExpr>(E1) && isa<DeclRefExpr>(E2)); 134 auto *Decl1 = cast<DeclRefExpr>(E1)->getDecl(); 135 auto *Decl2 = cast<DeclRefExpr>(E2)->getDecl(); 136 137 assert(isa<EnumConstantDecl>(Decl1) && isa<EnumConstantDecl>(Decl2)); 138 const DeclContext *DC1 = Decl1->getDeclContext(); 139 const DeclContext *DC2 = Decl2->getDeclContext(); 140 141 assert(isa<EnumDecl>(DC1) && isa<EnumDecl>(DC2)); 142 return DC1 == DC2; 143 } 144 145 namespace { 146 147 class CFGBuilder; 148 149 /// The CFG builder uses a recursive algorithm to build the CFG. When 150 /// we process an expression, sometimes we know that we must add the 151 /// subexpressions as block-level expressions. For example: 152 /// 153 /// exp1 || exp2 154 /// 155 /// When processing the '||' expression, we know that exp1 and exp2 156 /// need to be added as block-level expressions, even though they 157 /// might not normally need to be. AddStmtChoice records this 158 /// contextual information. If AddStmtChoice is 'NotAlwaysAdd', then 159 /// the builder has an option not to add a subexpression as a 160 /// block-level expression. 161 class AddStmtChoice { 162 public: 163 enum Kind { NotAlwaysAdd = 0, AlwaysAdd = 1 }; 164 165 AddStmtChoice(Kind a_kind = NotAlwaysAdd) : kind(a_kind) {} 166 167 bool alwaysAdd(CFGBuilder &builder, 168 const Stmt *stmt) const; 169 170 /// Return a copy of this object, except with the 'always-add' bit 171 /// set as specified. 172 AddStmtChoice withAlwaysAdd(bool alwaysAdd) const { 173 return AddStmtChoice(alwaysAdd ? AlwaysAdd : NotAlwaysAdd); 174 } 175 176 private: 177 Kind kind; 178 }; 179 180 /// LocalScope - Node in tree of local scopes created for C++ implicit 181 /// destructor calls generation. It contains list of automatic variables 182 /// declared in the scope and link to position in previous scope this scope 183 /// began in. 184 /// 185 /// The process of creating local scopes is as follows: 186 /// - Init CFGBuilder::ScopePos with invalid position (equivalent for null), 187 /// - Before processing statements in scope (e.g. CompoundStmt) create 188 /// LocalScope object using CFGBuilder::ScopePos as link to previous scope 189 /// and set CFGBuilder::ScopePos to the end of new scope, 190 /// - On every occurrence of VarDecl increase CFGBuilder::ScopePos if it points 191 /// at this VarDecl, 192 /// - For every normal (without jump) end of scope add to CFGBlock destructors 193 /// for objects in the current scope, 194 /// - For every jump add to CFGBlock destructors for objects 195 /// between CFGBuilder::ScopePos and local scope position saved for jump 196 /// target. Thanks to C++ restrictions on goto jumps we can be sure that 197 /// jump target position will be on the path to root from CFGBuilder::ScopePos 198 /// (adding any variable that doesn't need constructor to be called to 199 /// LocalScope can break this assumption), 200 /// 201 class LocalScope { 202 public: 203 friend class const_iterator; 204 205 using AutomaticVarsTy = BumpVector<VarDecl *>; 206 207 /// const_iterator - Iterates local scope backwards and jumps to previous 208 /// scope on reaching the beginning of currently iterated scope. 209 class const_iterator { 210 const LocalScope* Scope = nullptr; 211 212 /// VarIter is guaranteed to be greater then 0 for every valid iterator. 213 /// Invalid iterator (with null Scope) has VarIter equal to 0. 214 unsigned VarIter = 0; 215 216 public: 217 /// Create invalid iterator. Dereferencing invalid iterator is not allowed. 218 /// Incrementing invalid iterator is allowed and will result in invalid 219 /// iterator. 220 const_iterator() = default; 221 222 /// Create valid iterator. In case when S.Prev is an invalid iterator and 223 /// I is equal to 0, this will create invalid iterator. 224 const_iterator(const LocalScope& S, unsigned I) 225 : Scope(&S), VarIter(I) { 226 // Iterator to "end" of scope is not allowed. Handle it by going up 227 // in scopes tree possibly up to invalid iterator in the root. 228 if (VarIter == 0 && Scope) 229 *this = Scope->Prev; 230 } 231 232 VarDecl *const* operator->() const { 233 assert(Scope && "Dereferencing invalid iterator is not allowed"); 234 assert(VarIter != 0 && "Iterator has invalid value of VarIter member"); 235 return &Scope->Vars[VarIter - 1]; 236 } 237 238 const VarDecl *getFirstVarInScope() const { 239 assert(Scope && "Dereferencing invalid iterator is not allowed"); 240 assert(VarIter != 0 && "Iterator has invalid value of VarIter member"); 241 return Scope->Vars[0]; 242 } 243 244 VarDecl *operator*() const { 245 return *this->operator->(); 246 } 247 248 const_iterator &operator++() { 249 if (!Scope) 250 return *this; 251 252 assert(VarIter != 0 && "Iterator has invalid value of VarIter member"); 253 --VarIter; 254 if (VarIter == 0) 255 *this = Scope->Prev; 256 return *this; 257 } 258 const_iterator operator++(int) { 259 const_iterator P = *this; 260 ++*this; 261 return P; 262 } 263 264 bool operator==(const const_iterator &rhs) const { 265 return Scope == rhs.Scope && VarIter == rhs.VarIter; 266 } 267 bool operator!=(const const_iterator &rhs) const { 268 return !(*this == rhs); 269 } 270 271 explicit operator bool() const { 272 return *this != const_iterator(); 273 } 274 275 int distance(const_iterator L); 276 const_iterator shared_parent(const_iterator L); 277 bool pointsToFirstDeclaredVar() { return VarIter == 1; } 278 }; 279 280 private: 281 BumpVectorContext ctx; 282 283 /// Automatic variables in order of declaration. 284 AutomaticVarsTy Vars; 285 286 /// Iterator to variable in previous scope that was declared just before 287 /// begin of this scope. 288 const_iterator Prev; 289 290 public: 291 /// Constructs empty scope linked to previous scope in specified place. 292 LocalScope(BumpVectorContext ctx, const_iterator P) 293 : ctx(std::move(ctx)), Vars(this->ctx, 4), Prev(P) {} 294 295 /// Begin of scope in direction of CFG building (backwards). 296 const_iterator begin() const { return const_iterator(*this, Vars.size()); } 297 298 void addVar(VarDecl *VD) { 299 Vars.push_back(VD, ctx); 300 } 301 }; 302 303 } // namespace 304 305 /// distance - Calculates distance from this to L. L must be reachable from this 306 /// (with use of ++ operator). Cost of calculating the distance is linear w.r.t. 307 /// number of scopes between this and L. 308 int LocalScope::const_iterator::distance(LocalScope::const_iterator L) { 309 int D = 0; 310 const_iterator F = *this; 311 while (F.Scope != L.Scope) { 312 assert(F != const_iterator() && 313 "L iterator is not reachable from F iterator."); 314 D += F.VarIter; 315 F = F.Scope->Prev; 316 } 317 D += F.VarIter - L.VarIter; 318 return D; 319 } 320 321 /// Calculates the closest parent of this iterator 322 /// that is in a scope reachable through the parents of L. 323 /// I.e. when using 'goto' from this to L, the lifetime of all variables 324 /// between this and shared_parent(L) end. 325 LocalScope::const_iterator 326 LocalScope::const_iterator::shared_parent(LocalScope::const_iterator L) { 327 llvm::SmallPtrSet<const LocalScope *, 4> ScopesOfL; 328 while (true) { 329 ScopesOfL.insert(L.Scope); 330 if (L == const_iterator()) 331 break; 332 L = L.Scope->Prev; 333 } 334 335 const_iterator F = *this; 336 while (true) { 337 if (ScopesOfL.count(F.Scope)) 338 return F; 339 assert(F != const_iterator() && 340 "L iterator is not reachable from F iterator."); 341 F = F.Scope->Prev; 342 } 343 } 344 345 namespace { 346 347 /// Structure for specifying position in CFG during its build process. It 348 /// consists of CFGBlock that specifies position in CFG and 349 /// LocalScope::const_iterator that specifies position in LocalScope graph. 350 struct BlockScopePosPair { 351 CFGBlock *block = nullptr; 352 LocalScope::const_iterator scopePosition; 353 354 BlockScopePosPair() = default; 355 BlockScopePosPair(CFGBlock *b, LocalScope::const_iterator scopePos) 356 : block(b), scopePosition(scopePos) {} 357 }; 358 359 /// TryResult - a class representing a variant over the values 360 /// 'true', 'false', or 'unknown'. This is returned by tryEvaluateBool, 361 /// and is used by the CFGBuilder to decide if a branch condition 362 /// can be decided up front during CFG construction. 363 class TryResult { 364 int X = -1; 365 366 public: 367 TryResult() = default; 368 TryResult(bool b) : X(b ? 1 : 0) {} 369 370 bool isTrue() const { return X == 1; } 371 bool isFalse() const { return X == 0; } 372 bool isKnown() const { return X >= 0; } 373 374 void negate() { 375 assert(isKnown()); 376 X ^= 0x1; 377 } 378 }; 379 380 } // namespace 381 382 static TryResult bothKnownTrue(TryResult R1, TryResult R2) { 383 if (!R1.isKnown() || !R2.isKnown()) 384 return TryResult(); 385 return TryResult(R1.isTrue() && R2.isTrue()); 386 } 387 388 namespace { 389 390 class reverse_children { 391 llvm::SmallVector<Stmt *, 12> childrenBuf; 392 ArrayRef<Stmt *> children; 393 394 public: 395 reverse_children(Stmt *S); 396 397 using iterator = ArrayRef<Stmt *>::reverse_iterator; 398 399 iterator begin() const { return children.rbegin(); } 400 iterator end() const { return children.rend(); } 401 }; 402 403 } // namespace 404 405 reverse_children::reverse_children(Stmt *S) { 406 if (CallExpr *CE = dyn_cast<CallExpr>(S)) { 407 children = CE->getRawSubExprs(); 408 return; 409 } 410 switch (S->getStmtClass()) { 411 // Note: Fill in this switch with more cases we want to optimize. 412 case Stmt::InitListExprClass: { 413 InitListExpr *IE = cast<InitListExpr>(S); 414 children = llvm::makeArrayRef(reinterpret_cast<Stmt**>(IE->getInits()), 415 IE->getNumInits()); 416 return; 417 } 418 default: 419 break; 420 } 421 422 // Default case for all other statements. 423 for (Stmt *SubStmt : S->children()) 424 childrenBuf.push_back(SubStmt); 425 426 // This needs to be done *after* childrenBuf has been populated. 427 children = childrenBuf; 428 } 429 430 namespace { 431 432 /// CFGBuilder - This class implements CFG construction from an AST. 433 /// The builder is stateful: an instance of the builder should be used to only 434 /// construct a single CFG. 435 /// 436 /// Example usage: 437 /// 438 /// CFGBuilder builder; 439 /// std::unique_ptr<CFG> cfg = builder.buildCFG(decl, stmt1); 440 /// 441 /// CFG construction is done via a recursive walk of an AST. We actually parse 442 /// the AST in reverse order so that the successor of a basic block is 443 /// constructed prior to its predecessor. This allows us to nicely capture 444 /// implicit fall-throughs without extra basic blocks. 445 class CFGBuilder { 446 using JumpTarget = BlockScopePosPair; 447 using JumpSource = BlockScopePosPair; 448 449 ASTContext *Context; 450 std::unique_ptr<CFG> cfg; 451 452 // Current block. 453 CFGBlock *Block = nullptr; 454 455 // Block after the current block. 456 CFGBlock *Succ = nullptr; 457 458 JumpTarget ContinueJumpTarget; 459 JumpTarget BreakJumpTarget; 460 JumpTarget SEHLeaveJumpTarget; 461 CFGBlock *SwitchTerminatedBlock = nullptr; 462 CFGBlock *DefaultCaseBlock = nullptr; 463 464 // This can point either to a try or a __try block. The frontend forbids 465 // mixing both kinds in one function, so having one for both is enough. 466 CFGBlock *TryTerminatedBlock = nullptr; 467 468 // Current position in local scope. 469 LocalScope::const_iterator ScopePos; 470 471 // LabelMap records the mapping from Label expressions to their jump targets. 472 using LabelMapTy = llvm::DenseMap<LabelDecl *, JumpTarget>; 473 LabelMapTy LabelMap; 474 475 // A list of blocks that end with a "goto" that must be backpatched to their 476 // resolved targets upon completion of CFG construction. 477 using BackpatchBlocksTy = std::vector<JumpSource>; 478 BackpatchBlocksTy BackpatchBlocks; 479 480 // A list of labels whose address has been taken (for indirect gotos). 481 using LabelSetTy = llvm::SmallSetVector<LabelDecl *, 8>; 482 LabelSetTy AddressTakenLabels; 483 484 // Information about the currently visited C++ object construction site. 485 // This is set in the construction trigger and read when the constructor 486 // or a function that returns an object by value is being visited. 487 llvm::DenseMap<Expr *, const ConstructionContextLayer *> 488 ConstructionContextMap; 489 490 using DeclsWithEndedScopeSetTy = llvm::SmallSetVector<VarDecl *, 16>; 491 DeclsWithEndedScopeSetTy DeclsWithEndedScope; 492 493 bool badCFG = false; 494 const CFG::BuildOptions &BuildOpts; 495 496 // State to track for building switch statements. 497 bool switchExclusivelyCovered = false; 498 Expr::EvalResult *switchCond = nullptr; 499 500 CFG::BuildOptions::ForcedBlkExprs::value_type *cachedEntry = nullptr; 501 const Stmt *lastLookup = nullptr; 502 503 // Caches boolean evaluations of expressions to avoid multiple re-evaluations 504 // during construction of branches for chained logical operators. 505 using CachedBoolEvalsTy = llvm::DenseMap<Expr *, TryResult>; 506 CachedBoolEvalsTy CachedBoolEvals; 507 508 public: 509 explicit CFGBuilder(ASTContext *astContext, 510 const CFG::BuildOptions &buildOpts) 511 : Context(astContext), cfg(new CFG()), // crew a new CFG 512 ConstructionContextMap(), BuildOpts(buildOpts) {} 513 514 515 // buildCFG - Used by external clients to construct the CFG. 516 std::unique_ptr<CFG> buildCFG(const Decl *D, Stmt *Statement); 517 518 bool alwaysAdd(const Stmt *stmt); 519 520 private: 521 // Visitors to walk an AST and construct the CFG. 522 CFGBlock *VisitAddrLabelExpr(AddrLabelExpr *A, AddStmtChoice asc); 523 CFGBlock *VisitBinaryOperator(BinaryOperator *B, AddStmtChoice asc); 524 CFGBlock *VisitBreakStmt(BreakStmt *B); 525 CFGBlock *VisitCallExpr(CallExpr *C, AddStmtChoice asc); 526 CFGBlock *VisitCaseStmt(CaseStmt *C); 527 CFGBlock *VisitChooseExpr(ChooseExpr *C, AddStmtChoice asc); 528 CFGBlock *VisitCompoundStmt(CompoundStmt *C); 529 CFGBlock *VisitConditionalOperator(AbstractConditionalOperator *C, 530 AddStmtChoice asc); 531 CFGBlock *VisitContinueStmt(ContinueStmt *C); 532 CFGBlock *VisitCXXBindTemporaryExpr(CXXBindTemporaryExpr *E, 533 AddStmtChoice asc); 534 CFGBlock *VisitCXXCatchStmt(CXXCatchStmt *S); 535 CFGBlock *VisitCXXConstructExpr(CXXConstructExpr *C, AddStmtChoice asc); 536 CFGBlock *VisitCXXNewExpr(CXXNewExpr *DE, AddStmtChoice asc); 537 CFGBlock *VisitCXXDeleteExpr(CXXDeleteExpr *DE, AddStmtChoice asc); 538 CFGBlock *VisitCXXForRangeStmt(CXXForRangeStmt *S); 539 CFGBlock *VisitCXXFunctionalCastExpr(CXXFunctionalCastExpr *E, 540 AddStmtChoice asc); 541 CFGBlock *VisitCXXTemporaryObjectExpr(CXXTemporaryObjectExpr *C, 542 AddStmtChoice asc); 543 CFGBlock *VisitCXXThrowExpr(CXXThrowExpr *T); 544 CFGBlock *VisitCXXTryStmt(CXXTryStmt *S); 545 CFGBlock *VisitDeclStmt(DeclStmt *DS); 546 CFGBlock *VisitDeclSubExpr(DeclStmt *DS); 547 CFGBlock *VisitDefaultStmt(DefaultStmt *D); 548 CFGBlock *VisitDoStmt(DoStmt *D); 549 CFGBlock *VisitExprWithCleanups(ExprWithCleanups *E, AddStmtChoice asc); 550 CFGBlock *VisitForStmt(ForStmt *F); 551 CFGBlock *VisitGotoStmt(GotoStmt *G); 552 CFGBlock *VisitIfStmt(IfStmt *I); 553 CFGBlock *VisitImplicitCastExpr(ImplicitCastExpr *E, AddStmtChoice asc); 554 CFGBlock *VisitIndirectGotoStmt(IndirectGotoStmt *I); 555 CFGBlock *VisitLabelStmt(LabelStmt *L); 556 CFGBlock *VisitBlockExpr(BlockExpr *E, AddStmtChoice asc); 557 CFGBlock *VisitLambdaExpr(LambdaExpr *E, AddStmtChoice asc); 558 CFGBlock *VisitLogicalOperator(BinaryOperator *B); 559 std::pair<CFGBlock *, CFGBlock *> VisitLogicalOperator(BinaryOperator *B, 560 Stmt *Term, 561 CFGBlock *TrueBlock, 562 CFGBlock *FalseBlock); 563 CFGBlock *VisitMaterializeTemporaryExpr(MaterializeTemporaryExpr *MTE, 564 AddStmtChoice asc); 565 CFGBlock *VisitMemberExpr(MemberExpr *M, AddStmtChoice asc); 566 CFGBlock *VisitObjCAtCatchStmt(ObjCAtCatchStmt *S); 567 CFGBlock *VisitObjCAtSynchronizedStmt(ObjCAtSynchronizedStmt *S); 568 CFGBlock *VisitObjCAtThrowStmt(ObjCAtThrowStmt *S); 569 CFGBlock *VisitObjCAtTryStmt(ObjCAtTryStmt *S); 570 CFGBlock *VisitObjCAutoreleasePoolStmt(ObjCAutoreleasePoolStmt *S); 571 CFGBlock *VisitObjCForCollectionStmt(ObjCForCollectionStmt *S); 572 CFGBlock *VisitPseudoObjectExpr(PseudoObjectExpr *E); 573 CFGBlock *VisitReturnStmt(ReturnStmt *R); 574 CFGBlock *VisitSEHExceptStmt(SEHExceptStmt *S); 575 CFGBlock *VisitSEHFinallyStmt(SEHFinallyStmt *S); 576 CFGBlock *VisitSEHLeaveStmt(SEHLeaveStmt *S); 577 CFGBlock *VisitSEHTryStmt(SEHTryStmt *S); 578 CFGBlock *VisitStmtExpr(StmtExpr *S, AddStmtChoice asc); 579 CFGBlock *VisitSwitchStmt(SwitchStmt *S); 580 CFGBlock *VisitUnaryExprOrTypeTraitExpr(UnaryExprOrTypeTraitExpr *E, 581 AddStmtChoice asc); 582 CFGBlock *VisitUnaryOperator(UnaryOperator *U, AddStmtChoice asc); 583 CFGBlock *VisitWhileStmt(WhileStmt *W); 584 585 CFGBlock *Visit(Stmt *S, AddStmtChoice asc = AddStmtChoice::NotAlwaysAdd); 586 CFGBlock *VisitStmt(Stmt *S, AddStmtChoice asc); 587 CFGBlock *VisitChildren(Stmt *S); 588 CFGBlock *VisitNoRecurse(Expr *E, AddStmtChoice asc); 589 590 void maybeAddScopeBeginForVarDecl(CFGBlock *B, const VarDecl *VD, 591 const Stmt *S) { 592 if (ScopePos && (VD == ScopePos.getFirstVarInScope())) 593 appendScopeBegin(B, VD, S); 594 } 595 596 /// When creating the CFG for temporary destructors, we want to mirror the 597 /// branch structure of the corresponding constructor calls. 598 /// Thus, while visiting a statement for temporary destructors, we keep a 599 /// context to keep track of the following information: 600 /// - whether a subexpression is executed unconditionally 601 /// - if a subexpression is executed conditionally, the first 602 /// CXXBindTemporaryExpr we encounter in that subexpression (which 603 /// corresponds to the last temporary destructor we have to call for this 604 /// subexpression) and the CFG block at that point (which will become the 605 /// successor block when inserting the decision point). 606 /// 607 /// That way, we can build the branch structure for temporary destructors as 608 /// follows: 609 /// 1. If a subexpression is executed unconditionally, we add the temporary 610 /// destructor calls to the current block. 611 /// 2. If a subexpression is executed conditionally, when we encounter a 612 /// CXXBindTemporaryExpr: 613 /// a) If it is the first temporary destructor call in the subexpression, 614 /// we remember the CXXBindTemporaryExpr and the current block in the 615 /// TempDtorContext; we start a new block, and insert the temporary 616 /// destructor call. 617 /// b) Otherwise, add the temporary destructor call to the current block. 618 /// 3. When we finished visiting a conditionally executed subexpression, 619 /// and we found at least one temporary constructor during the visitation 620 /// (2.a has executed), we insert a decision block that uses the 621 /// CXXBindTemporaryExpr as terminator, and branches to the current block 622 /// if the CXXBindTemporaryExpr was marked executed, and otherwise 623 /// branches to the stored successor. 624 struct TempDtorContext { 625 TempDtorContext() = default; 626 TempDtorContext(TryResult KnownExecuted) 627 : IsConditional(true), KnownExecuted(KnownExecuted) {} 628 629 /// Returns whether we need to start a new branch for a temporary destructor 630 /// call. This is the case when the temporary destructor is 631 /// conditionally executed, and it is the first one we encounter while 632 /// visiting a subexpression - other temporary destructors at the same level 633 /// will be added to the same block and are executed under the same 634 /// condition. 635 bool needsTempDtorBranch() const { 636 return IsConditional && !TerminatorExpr; 637 } 638 639 /// Remember the successor S of a temporary destructor decision branch for 640 /// the corresponding CXXBindTemporaryExpr E. 641 void setDecisionPoint(CFGBlock *S, CXXBindTemporaryExpr *E) { 642 Succ = S; 643 TerminatorExpr = E; 644 } 645 646 const bool IsConditional = false; 647 const TryResult KnownExecuted = true; 648 CFGBlock *Succ = nullptr; 649 CXXBindTemporaryExpr *TerminatorExpr = nullptr; 650 }; 651 652 // Visitors to walk an AST and generate destructors of temporaries in 653 // full expression. 654 CFGBlock *VisitForTemporaryDtors(Stmt *E, bool BindToTemporary, 655 TempDtorContext &Context); 656 CFGBlock *VisitChildrenForTemporaryDtors(Stmt *E, TempDtorContext &Context); 657 CFGBlock *VisitBinaryOperatorForTemporaryDtors(BinaryOperator *E, 658 TempDtorContext &Context); 659 CFGBlock *VisitCXXBindTemporaryExprForTemporaryDtors( 660 CXXBindTemporaryExpr *E, bool BindToTemporary, TempDtorContext &Context); 661 CFGBlock *VisitConditionalOperatorForTemporaryDtors( 662 AbstractConditionalOperator *E, bool BindToTemporary, 663 TempDtorContext &Context); 664 void InsertTempDtorDecisionBlock(const TempDtorContext &Context, 665 CFGBlock *FalseSucc = nullptr); 666 667 // NYS == Not Yet Supported 668 CFGBlock *NYS() { 669 badCFG = true; 670 return Block; 671 } 672 673 // Remember to apply the construction context based on the current \p Layer 674 // when constructing the CFG element for \p CE. 675 void consumeConstructionContext(const ConstructionContextLayer *Layer, 676 Expr *E); 677 678 // Scan \p Child statement to find constructors in it, while keeping in mind 679 // that its parent statement is providing a partial construction context 680 // described by \p Layer. If a constructor is found, it would be assigned 681 // the context based on the layer. If an additional construction context layer 682 // is found, the function recurses into that. 683 void findConstructionContexts(const ConstructionContextLayer *Layer, 684 Stmt *Child); 685 686 // Unset the construction context after consuming it. This is done immediately 687 // after adding the CFGConstructor or CFGCXXRecordTypedCall element, so 688 // there's no need to do this manually in every Visit... function. 689 void cleanupConstructionContext(Expr *E); 690 691 void autoCreateBlock() { if (!Block) Block = createBlock(); } 692 CFGBlock *createBlock(bool add_successor = true); 693 CFGBlock *createNoReturnBlock(); 694 695 CFGBlock *addStmt(Stmt *S) { 696 return Visit(S, AddStmtChoice::AlwaysAdd); 697 } 698 699 CFGBlock *addInitializer(CXXCtorInitializer *I); 700 void addLoopExit(const Stmt *LoopStmt); 701 void addAutomaticObjDtors(LocalScope::const_iterator B, 702 LocalScope::const_iterator E, Stmt *S); 703 void addLifetimeEnds(LocalScope::const_iterator B, 704 LocalScope::const_iterator E, Stmt *S); 705 void addAutomaticObjHandling(LocalScope::const_iterator B, 706 LocalScope::const_iterator E, Stmt *S); 707 void addImplicitDtorsForDestructor(const CXXDestructorDecl *DD); 708 void addScopesEnd(LocalScope::const_iterator B, LocalScope::const_iterator E, 709 Stmt *S); 710 711 void getDeclsWithEndedScope(LocalScope::const_iterator B, 712 LocalScope::const_iterator E, Stmt *S); 713 714 // Local scopes creation. 715 LocalScope* createOrReuseLocalScope(LocalScope* Scope); 716 717 void addLocalScopeForStmt(Stmt *S); 718 LocalScope* addLocalScopeForDeclStmt(DeclStmt *DS, 719 LocalScope* Scope = nullptr); 720 LocalScope* addLocalScopeForVarDecl(VarDecl *VD, LocalScope* Scope = nullptr); 721 722 void addLocalScopeAndDtors(Stmt *S); 723 724 // Interface to CFGBlock - adding CFGElements. 725 726 void appendStmt(CFGBlock *B, const Stmt *S) { 727 if (alwaysAdd(S) && cachedEntry) 728 cachedEntry->second = B; 729 730 // All block-level expressions should have already been IgnoreParens()ed. 731 assert(!isa<Expr>(S) || cast<Expr>(S)->IgnoreParens() == S); 732 B->appendStmt(const_cast<Stmt*>(S), cfg->getBumpVectorContext()); 733 } 734 735 void appendConstructor(CFGBlock *B, CXXConstructExpr *CE) { 736 if (BuildOpts.AddRichCXXConstructors) { 737 if (const ConstructionContextLayer *Layer = 738 ConstructionContextMap.lookup(CE)) { 739 cleanupConstructionContext(CE); 740 if (const auto *CC = ConstructionContext::createFromLayers( 741 cfg->getBumpVectorContext(), Layer)) { 742 B->appendConstructor(CE, CC, cfg->getBumpVectorContext()); 743 return; 744 } 745 } 746 } 747 748 // No valid construction context found. Fall back to statement. 749 B->appendStmt(CE, cfg->getBumpVectorContext()); 750 } 751 752 void appendCall(CFGBlock *B, CallExpr *CE) { 753 if (alwaysAdd(CE) && cachedEntry) 754 cachedEntry->second = B; 755 756 if (BuildOpts.AddRichCXXConstructors) { 757 if (CFGCXXRecordTypedCall::isCXXRecordTypedCall(CE, *Context)) { 758 if (const ConstructionContextLayer *Layer = 759 ConstructionContextMap.lookup(CE)) { 760 cleanupConstructionContext(CE); 761 if (const auto *CC = ConstructionContext::createFromLayers( 762 cfg->getBumpVectorContext(), Layer)) { 763 B->appendCXXRecordTypedCall(CE, CC, cfg->getBumpVectorContext()); 764 return; 765 } 766 } 767 } 768 } 769 770 // No valid construction context found. Fall back to statement. 771 B->appendStmt(CE, cfg->getBumpVectorContext()); 772 } 773 774 void appendInitializer(CFGBlock *B, CXXCtorInitializer *I) { 775 B->appendInitializer(I, cfg->getBumpVectorContext()); 776 } 777 778 void appendNewAllocator(CFGBlock *B, CXXNewExpr *NE) { 779 B->appendNewAllocator(NE, cfg->getBumpVectorContext()); 780 } 781 782 void appendBaseDtor(CFGBlock *B, const CXXBaseSpecifier *BS) { 783 B->appendBaseDtor(BS, cfg->getBumpVectorContext()); 784 } 785 786 void appendMemberDtor(CFGBlock *B, FieldDecl *FD) { 787 B->appendMemberDtor(FD, cfg->getBumpVectorContext()); 788 } 789 790 void appendTemporaryDtor(CFGBlock *B, CXXBindTemporaryExpr *E) { 791 B->appendTemporaryDtor(E, cfg->getBumpVectorContext()); 792 } 793 794 void appendAutomaticObjDtor(CFGBlock *B, VarDecl *VD, Stmt *S) { 795 B->appendAutomaticObjDtor(VD, S, cfg->getBumpVectorContext()); 796 } 797 798 void appendLifetimeEnds(CFGBlock *B, VarDecl *VD, Stmt *S) { 799 B->appendLifetimeEnds(VD, S, cfg->getBumpVectorContext()); 800 } 801 802 void appendLoopExit(CFGBlock *B, const Stmt *LoopStmt) { 803 B->appendLoopExit(LoopStmt, cfg->getBumpVectorContext()); 804 } 805 806 void appendDeleteDtor(CFGBlock *B, CXXRecordDecl *RD, CXXDeleteExpr *DE) { 807 B->appendDeleteDtor(RD, DE, cfg->getBumpVectorContext()); 808 } 809 810 void prependAutomaticObjDtorsWithTerminator(CFGBlock *Blk, 811 LocalScope::const_iterator B, LocalScope::const_iterator E); 812 813 void prependAutomaticObjLifetimeWithTerminator(CFGBlock *Blk, 814 LocalScope::const_iterator B, 815 LocalScope::const_iterator E); 816 817 const VarDecl * 818 prependAutomaticObjScopeEndWithTerminator(CFGBlock *Blk, 819 LocalScope::const_iterator B, 820 LocalScope::const_iterator E); 821 822 void addSuccessor(CFGBlock *B, CFGBlock *S, bool IsReachable = true) { 823 B->addSuccessor(CFGBlock::AdjacentBlock(S, IsReachable), 824 cfg->getBumpVectorContext()); 825 } 826 827 /// Add a reachable successor to a block, with the alternate variant that is 828 /// unreachable. 829 void addSuccessor(CFGBlock *B, CFGBlock *ReachableBlock, CFGBlock *AltBlock) { 830 B->addSuccessor(CFGBlock::AdjacentBlock(ReachableBlock, AltBlock), 831 cfg->getBumpVectorContext()); 832 } 833 834 void appendScopeBegin(CFGBlock *B, const VarDecl *VD, const Stmt *S) { 835 if (BuildOpts.AddScopes) 836 B->appendScopeBegin(VD, S, cfg->getBumpVectorContext()); 837 } 838 839 void prependScopeBegin(CFGBlock *B, const VarDecl *VD, const Stmt *S) { 840 if (BuildOpts.AddScopes) 841 B->prependScopeBegin(VD, S, cfg->getBumpVectorContext()); 842 } 843 844 void appendScopeEnd(CFGBlock *B, const VarDecl *VD, const Stmt *S) { 845 if (BuildOpts.AddScopes) 846 B->appendScopeEnd(VD, S, cfg->getBumpVectorContext()); 847 } 848 849 void prependScopeEnd(CFGBlock *B, const VarDecl *VD, const Stmt *S) { 850 if (BuildOpts.AddScopes) 851 B->prependScopeEnd(VD, S, cfg->getBumpVectorContext()); 852 } 853 854 /// Find a relational comparison with an expression evaluating to a 855 /// boolean and a constant other than 0 and 1. 856 /// e.g. if ((x < y) == 10) 857 TryResult checkIncorrectRelationalOperator(const BinaryOperator *B) { 858 const Expr *LHSExpr = B->getLHS()->IgnoreParens(); 859 const Expr *RHSExpr = B->getRHS()->IgnoreParens(); 860 861 const IntegerLiteral *IntLiteral = dyn_cast<IntegerLiteral>(LHSExpr); 862 const Expr *BoolExpr = RHSExpr; 863 bool IntFirst = true; 864 if (!IntLiteral) { 865 IntLiteral = dyn_cast<IntegerLiteral>(RHSExpr); 866 BoolExpr = LHSExpr; 867 IntFirst = false; 868 } 869 870 if (!IntLiteral || !BoolExpr->isKnownToHaveBooleanValue()) 871 return TryResult(); 872 873 llvm::APInt IntValue = IntLiteral->getValue(); 874 if ((IntValue == 1) || (IntValue == 0)) 875 return TryResult(); 876 877 bool IntLarger = IntLiteral->getType()->isUnsignedIntegerType() || 878 !IntValue.isNegative(); 879 880 BinaryOperatorKind Bok = B->getOpcode(); 881 if (Bok == BO_GT || Bok == BO_GE) { 882 // Always true for 10 > bool and bool > -1 883 // Always false for -1 > bool and bool > 10 884 return TryResult(IntFirst == IntLarger); 885 } else { 886 // Always true for -1 < bool and bool < 10 887 // Always false for 10 < bool and bool < -1 888 return TryResult(IntFirst != IntLarger); 889 } 890 } 891 892 /// Find an incorrect equality comparison. Either with an expression 893 /// evaluating to a boolean and a constant other than 0 and 1. 894 /// e.g. if (!x == 10) or a bitwise and/or operation that always evaluates to 895 /// true/false e.q. (x & 8) == 4. 896 TryResult checkIncorrectEqualityOperator(const BinaryOperator *B) { 897 const Expr *LHSExpr = B->getLHS()->IgnoreParens(); 898 const Expr *RHSExpr = B->getRHS()->IgnoreParens(); 899 900 const IntegerLiteral *IntLiteral = dyn_cast<IntegerLiteral>(LHSExpr); 901 const Expr *BoolExpr = RHSExpr; 902 903 if (!IntLiteral) { 904 IntLiteral = dyn_cast<IntegerLiteral>(RHSExpr); 905 BoolExpr = LHSExpr; 906 } 907 908 if (!IntLiteral) 909 return TryResult(); 910 911 const BinaryOperator *BitOp = dyn_cast<BinaryOperator>(BoolExpr); 912 if (BitOp && (BitOp->getOpcode() == BO_And || 913 BitOp->getOpcode() == BO_Or)) { 914 const Expr *LHSExpr2 = BitOp->getLHS()->IgnoreParens(); 915 const Expr *RHSExpr2 = BitOp->getRHS()->IgnoreParens(); 916 917 const IntegerLiteral *IntLiteral2 = dyn_cast<IntegerLiteral>(LHSExpr2); 918 919 if (!IntLiteral2) 920 IntLiteral2 = dyn_cast<IntegerLiteral>(RHSExpr2); 921 922 if (!IntLiteral2) 923 return TryResult(); 924 925 llvm::APInt L1 = IntLiteral->getValue(); 926 llvm::APInt L2 = IntLiteral2->getValue(); 927 if ((BitOp->getOpcode() == BO_And && (L2 & L1) != L1) || 928 (BitOp->getOpcode() == BO_Or && (L2 | L1) != L1)) { 929 if (BuildOpts.Observer) 930 BuildOpts.Observer->compareBitwiseEquality(B, 931 B->getOpcode() != BO_EQ); 932 TryResult(B->getOpcode() != BO_EQ); 933 } 934 } else if (BoolExpr->isKnownToHaveBooleanValue()) { 935 llvm::APInt IntValue = IntLiteral->getValue(); 936 if ((IntValue == 1) || (IntValue == 0)) { 937 return TryResult(); 938 } 939 return TryResult(B->getOpcode() != BO_EQ); 940 } 941 942 return TryResult(); 943 } 944 945 TryResult analyzeLogicOperatorCondition(BinaryOperatorKind Relation, 946 const llvm::APSInt &Value1, 947 const llvm::APSInt &Value2) { 948 assert(Value1.isSigned() == Value2.isSigned()); 949 switch (Relation) { 950 default: 951 return TryResult(); 952 case BO_EQ: 953 return TryResult(Value1 == Value2); 954 case BO_NE: 955 return TryResult(Value1 != Value2); 956 case BO_LT: 957 return TryResult(Value1 < Value2); 958 case BO_LE: 959 return TryResult(Value1 <= Value2); 960 case BO_GT: 961 return TryResult(Value1 > Value2); 962 case BO_GE: 963 return TryResult(Value1 >= Value2); 964 } 965 } 966 967 /// Find a pair of comparison expressions with or without parentheses 968 /// with a shared variable and constants and a logical operator between them 969 /// that always evaluates to either true or false. 970 /// e.g. if (x != 3 || x != 4) 971 TryResult checkIncorrectLogicOperator(const BinaryOperator *B) { 972 assert(B->isLogicalOp()); 973 const BinaryOperator *LHS = 974 dyn_cast<BinaryOperator>(B->getLHS()->IgnoreParens()); 975 const BinaryOperator *RHS = 976 dyn_cast<BinaryOperator>(B->getRHS()->IgnoreParens()); 977 if (!LHS || !RHS) 978 return {}; 979 980 if (!LHS->isComparisonOp() || !RHS->isComparisonOp()) 981 return {}; 982 983 const DeclRefExpr *Decl1; 984 const Expr *Expr1; 985 BinaryOperatorKind BO1; 986 std::tie(Decl1, BO1, Expr1) = tryNormalizeBinaryOperator(LHS); 987 988 if (!Decl1 || !Expr1) 989 return {}; 990 991 const DeclRefExpr *Decl2; 992 const Expr *Expr2; 993 BinaryOperatorKind BO2; 994 std::tie(Decl2, BO2, Expr2) = tryNormalizeBinaryOperator(RHS); 995 996 if (!Decl2 || !Expr2) 997 return {}; 998 999 // Check that it is the same variable on both sides. 1000 if (Decl1->getDecl() != Decl2->getDecl()) 1001 return {}; 1002 1003 // Make sure the user's intent is clear (e.g. they're comparing against two 1004 // int literals, or two things from the same enum) 1005 if (!areExprTypesCompatible(Expr1, Expr2)) 1006 return {}; 1007 1008 llvm::APSInt L1, L2; 1009 1010 if (!Expr1->EvaluateAsInt(L1, *Context) || 1011 !Expr2->EvaluateAsInt(L2, *Context)) 1012 return {}; 1013 1014 // Can't compare signed with unsigned or with different bit width. 1015 if (L1.isSigned() != L2.isSigned() || L1.getBitWidth() != L2.getBitWidth()) 1016 return {}; 1017 1018 // Values that will be used to determine if result of logical 1019 // operator is always true/false 1020 const llvm::APSInt Values[] = { 1021 // Value less than both Value1 and Value2 1022 llvm::APSInt::getMinValue(L1.getBitWidth(), L1.isUnsigned()), 1023 // L1 1024 L1, 1025 // Value between Value1 and Value2 1026 ((L1 < L2) ? L1 : L2) + llvm::APSInt(llvm::APInt(L1.getBitWidth(), 1), 1027 L1.isUnsigned()), 1028 // L2 1029 L2, 1030 // Value greater than both Value1 and Value2 1031 llvm::APSInt::getMaxValue(L1.getBitWidth(), L1.isUnsigned()), 1032 }; 1033 1034 // Check whether expression is always true/false by evaluating the following 1035 // * variable x is less than the smallest literal. 1036 // * variable x is equal to the smallest literal. 1037 // * Variable x is between smallest and largest literal. 1038 // * Variable x is equal to the largest literal. 1039 // * Variable x is greater than largest literal. 1040 bool AlwaysTrue = true, AlwaysFalse = true; 1041 for (const llvm::APSInt &Value : Values) { 1042 TryResult Res1, Res2; 1043 Res1 = analyzeLogicOperatorCondition(BO1, Value, L1); 1044 Res2 = analyzeLogicOperatorCondition(BO2, Value, L2); 1045 1046 if (!Res1.isKnown() || !Res2.isKnown()) 1047 return {}; 1048 1049 if (B->getOpcode() == BO_LAnd) { 1050 AlwaysTrue &= (Res1.isTrue() && Res2.isTrue()); 1051 AlwaysFalse &= !(Res1.isTrue() && Res2.isTrue()); 1052 } else { 1053 AlwaysTrue &= (Res1.isTrue() || Res2.isTrue()); 1054 AlwaysFalse &= !(Res1.isTrue() || Res2.isTrue()); 1055 } 1056 } 1057 1058 if (AlwaysTrue || AlwaysFalse) { 1059 if (BuildOpts.Observer) 1060 BuildOpts.Observer->compareAlwaysTrue(B, AlwaysTrue); 1061 return TryResult(AlwaysTrue); 1062 } 1063 return {}; 1064 } 1065 1066 /// Try and evaluate an expression to an integer constant. 1067 bool tryEvaluate(Expr *S, Expr::EvalResult &outResult) { 1068 if (!BuildOpts.PruneTriviallyFalseEdges) 1069 return false; 1070 return !S->isTypeDependent() && 1071 !S->isValueDependent() && 1072 S->EvaluateAsRValue(outResult, *Context); 1073 } 1074 1075 /// tryEvaluateBool - Try and evaluate the Stmt and return 0 or 1 1076 /// if we can evaluate to a known value, otherwise return -1. 1077 TryResult tryEvaluateBool(Expr *S) { 1078 if (!BuildOpts.PruneTriviallyFalseEdges || 1079 S->isTypeDependent() || S->isValueDependent()) 1080 return {}; 1081 1082 if (BinaryOperator *Bop = dyn_cast<BinaryOperator>(S)) { 1083 if (Bop->isLogicalOp()) { 1084 // Check the cache first. 1085 CachedBoolEvalsTy::iterator I = CachedBoolEvals.find(S); 1086 if (I != CachedBoolEvals.end()) 1087 return I->second; // already in map; 1088 1089 // Retrieve result at first, or the map might be updated. 1090 TryResult Result = evaluateAsBooleanConditionNoCache(S); 1091 CachedBoolEvals[S] = Result; // update or insert 1092 return Result; 1093 } 1094 else { 1095 switch (Bop->getOpcode()) { 1096 default: break; 1097 // For 'x & 0' and 'x * 0', we can determine that 1098 // the value is always false. 1099 case BO_Mul: 1100 case BO_And: { 1101 // If either operand is zero, we know the value 1102 // must be false. 1103 llvm::APSInt IntVal; 1104 if (Bop->getLHS()->EvaluateAsInt(IntVal, *Context)) { 1105 if (!IntVal.getBoolValue()) { 1106 return TryResult(false); 1107 } 1108 } 1109 if (Bop->getRHS()->EvaluateAsInt(IntVal, *Context)) { 1110 if (!IntVal.getBoolValue()) { 1111 return TryResult(false); 1112 } 1113 } 1114 } 1115 break; 1116 } 1117 } 1118 } 1119 1120 return evaluateAsBooleanConditionNoCache(S); 1121 } 1122 1123 /// Evaluate as boolean \param E without using the cache. 1124 TryResult evaluateAsBooleanConditionNoCache(Expr *E) { 1125 if (BinaryOperator *Bop = dyn_cast<BinaryOperator>(E)) { 1126 if (Bop->isLogicalOp()) { 1127 TryResult LHS = tryEvaluateBool(Bop->getLHS()); 1128 if (LHS.isKnown()) { 1129 // We were able to evaluate the LHS, see if we can get away with not 1130 // evaluating the RHS: 0 && X -> 0, 1 || X -> 1 1131 if (LHS.isTrue() == (Bop->getOpcode() == BO_LOr)) 1132 return LHS.isTrue(); 1133 1134 TryResult RHS = tryEvaluateBool(Bop->getRHS()); 1135 if (RHS.isKnown()) { 1136 if (Bop->getOpcode() == BO_LOr) 1137 return LHS.isTrue() || RHS.isTrue(); 1138 else 1139 return LHS.isTrue() && RHS.isTrue(); 1140 } 1141 } else { 1142 TryResult RHS = tryEvaluateBool(Bop->getRHS()); 1143 if (RHS.isKnown()) { 1144 // We can't evaluate the LHS; however, sometimes the result 1145 // is determined by the RHS: X && 0 -> 0, X || 1 -> 1. 1146 if (RHS.isTrue() == (Bop->getOpcode() == BO_LOr)) 1147 return RHS.isTrue(); 1148 } else { 1149 TryResult BopRes = checkIncorrectLogicOperator(Bop); 1150 if (BopRes.isKnown()) 1151 return BopRes.isTrue(); 1152 } 1153 } 1154 1155 return {}; 1156 } else if (Bop->isEqualityOp()) { 1157 TryResult BopRes = checkIncorrectEqualityOperator(Bop); 1158 if (BopRes.isKnown()) 1159 return BopRes.isTrue(); 1160 } else if (Bop->isRelationalOp()) { 1161 TryResult BopRes = checkIncorrectRelationalOperator(Bop); 1162 if (BopRes.isKnown()) 1163 return BopRes.isTrue(); 1164 } 1165 } 1166 1167 bool Result; 1168 if (E->EvaluateAsBooleanCondition(Result, *Context)) 1169 return Result; 1170 1171 return {}; 1172 } 1173 1174 bool hasTrivialDestructor(VarDecl *VD); 1175 }; 1176 1177 } // namespace 1178 1179 inline bool AddStmtChoice::alwaysAdd(CFGBuilder &builder, 1180 const Stmt *stmt) const { 1181 return builder.alwaysAdd(stmt) || kind == AlwaysAdd; 1182 } 1183 1184 bool CFGBuilder::alwaysAdd(const Stmt *stmt) { 1185 bool shouldAdd = BuildOpts.alwaysAdd(stmt); 1186 1187 if (!BuildOpts.forcedBlkExprs) 1188 return shouldAdd; 1189 1190 if (lastLookup == stmt) { 1191 if (cachedEntry) { 1192 assert(cachedEntry->first == stmt); 1193 return true; 1194 } 1195 return shouldAdd; 1196 } 1197 1198 lastLookup = stmt; 1199 1200 // Perform the lookup! 1201 CFG::BuildOptions::ForcedBlkExprs *fb = *BuildOpts.forcedBlkExprs; 1202 1203 if (!fb) { 1204 // No need to update 'cachedEntry', since it will always be null. 1205 assert(!cachedEntry); 1206 return shouldAdd; 1207 } 1208 1209 CFG::BuildOptions::ForcedBlkExprs::iterator itr = fb->find(stmt); 1210 if (itr == fb->end()) { 1211 cachedEntry = nullptr; 1212 return shouldAdd; 1213 } 1214 1215 cachedEntry = &*itr; 1216 return true; 1217 } 1218 1219 // FIXME: Add support for dependent-sized array types in C++? 1220 // Does it even make sense to build a CFG for an uninstantiated template? 1221 static const VariableArrayType *FindVA(const Type *t) { 1222 while (const ArrayType *vt = dyn_cast<ArrayType>(t)) { 1223 if (const VariableArrayType *vat = dyn_cast<VariableArrayType>(vt)) 1224 if (vat->getSizeExpr()) 1225 return vat; 1226 1227 t = vt->getElementType().getTypePtr(); 1228 } 1229 1230 return nullptr; 1231 } 1232 1233 void CFGBuilder::consumeConstructionContext( 1234 const ConstructionContextLayer *Layer, Expr *E) { 1235 if (const ConstructionContextLayer *PreviouslyStoredLayer = 1236 ConstructionContextMap.lookup(E)) { 1237 (void)PreviouslyStoredLayer; 1238 // We might have visited this child when we were finding construction 1239 // contexts within its parents. 1240 assert(PreviouslyStoredLayer->isStrictlyMoreSpecificThan(Layer) && 1241 "Already within a different construction context!"); 1242 } else { 1243 ConstructionContextMap[E] = Layer; 1244 } 1245 } 1246 1247 void CFGBuilder::findConstructionContexts( 1248 const ConstructionContextLayer *Layer, Stmt *Child) { 1249 if (!BuildOpts.AddRichCXXConstructors) 1250 return; 1251 1252 if (!Child) 1253 return; 1254 1255 auto withExtraLayer = [this, Layer](Stmt *S) { 1256 return ConstructionContextLayer::create(cfg->getBumpVectorContext(), S, 1257 Layer); 1258 }; 1259 1260 switch(Child->getStmtClass()) { 1261 case Stmt::CXXConstructExprClass: 1262 case Stmt::CXXTemporaryObjectExprClass: { 1263 // Support pre-C++17 copy elision AST. 1264 auto *CE = cast<CXXConstructExpr>(Child); 1265 if (BuildOpts.MarkElidedCXXConstructors && CE->isElidable()) { 1266 findConstructionContexts(withExtraLayer(CE), CE->getArg(0)); 1267 } 1268 1269 consumeConstructionContext(Layer, CE); 1270 break; 1271 } 1272 // FIXME: This, like the main visit, doesn't support CUDAKernelCallExpr. 1273 // FIXME: An isa<> would look much better but this whole switch is a 1274 // workaround for an internal compiler error in MSVC 2015 (see r326021). 1275 case Stmt::CallExprClass: 1276 case Stmt::CXXMemberCallExprClass: 1277 case Stmt::CXXOperatorCallExprClass: 1278 case Stmt::UserDefinedLiteralClass: { 1279 auto *CE = cast<CallExpr>(Child); 1280 if (CFGCXXRecordTypedCall::isCXXRecordTypedCall(CE, *Context)) 1281 consumeConstructionContext(Layer, CE); 1282 break; 1283 } 1284 case Stmt::ExprWithCleanupsClass: { 1285 auto *Cleanups = cast<ExprWithCleanups>(Child); 1286 findConstructionContexts(Layer, Cleanups->getSubExpr()); 1287 break; 1288 } 1289 case Stmt::CXXFunctionalCastExprClass: { 1290 auto *Cast = cast<CXXFunctionalCastExpr>(Child); 1291 findConstructionContexts(Layer, Cast->getSubExpr()); 1292 break; 1293 } 1294 case Stmt::ImplicitCastExprClass: { 1295 auto *Cast = cast<ImplicitCastExpr>(Child); 1296 // Should we support other implicit cast kinds? 1297 switch (Cast->getCastKind()) { 1298 case CK_NoOp: 1299 case CK_ConstructorConversion: 1300 findConstructionContexts(Layer, Cast->getSubExpr()); 1301 default: 1302 break; 1303 } 1304 break; 1305 } 1306 case Stmt::CXXBindTemporaryExprClass: { 1307 auto *BTE = cast<CXXBindTemporaryExpr>(Child); 1308 findConstructionContexts(withExtraLayer(BTE), BTE->getSubExpr()); 1309 break; 1310 } 1311 case Stmt::MaterializeTemporaryExprClass: { 1312 // Normally we don't want to search in MaterializeTemporaryExpr because 1313 // it indicates the beginning of a temporary object construction context, 1314 // so it shouldn't be found in the middle. However, if it is the beginning 1315 // of an elidable copy or move construction context, we need to include it. 1316 if (const auto *CE = 1317 dyn_cast_or_null<CXXConstructExpr>(Layer->getTriggerStmt())) { 1318 if (CE->isElidable()) { 1319 auto *MTE = cast<MaterializeTemporaryExpr>(Child); 1320 findConstructionContexts(withExtraLayer(MTE), MTE->GetTemporaryExpr()); 1321 } 1322 } 1323 break; 1324 } 1325 case Stmt::ConditionalOperatorClass: { 1326 auto *CO = cast<ConditionalOperator>(Child); 1327 if (!dyn_cast_or_null<MaterializeTemporaryExpr>(Layer->getTriggerStmt())) { 1328 // If the object returned by the conditional operator is not going to be a 1329 // temporary object that needs to be immediately materialized, then 1330 // it must be C++17 with its mandatory copy elision. Do not yet promise 1331 // to support this case. 1332 assert(!CO->getType()->getAsCXXRecordDecl() || CO->isGLValue() || 1333 Context->getLangOpts().CPlusPlus17); 1334 break; 1335 } 1336 findConstructionContexts(Layer, CO->getLHS()); 1337 findConstructionContexts(Layer, CO->getRHS()); 1338 break; 1339 } 1340 default: 1341 break; 1342 } 1343 } 1344 1345 void CFGBuilder::cleanupConstructionContext(Expr *E) { 1346 assert(BuildOpts.AddRichCXXConstructors && 1347 "We should not be managing construction contexts!"); 1348 assert(ConstructionContextMap.count(E) && 1349 "Cannot exit construction context without the context!"); 1350 ConstructionContextMap.erase(E); 1351 } 1352 1353 1354 /// BuildCFG - Constructs a CFG from an AST (a Stmt*). The AST can represent an 1355 /// arbitrary statement. Examples include a single expression or a function 1356 /// body (compound statement). The ownership of the returned CFG is 1357 /// transferred to the caller. If CFG construction fails, this method returns 1358 /// NULL. 1359 std::unique_ptr<CFG> CFGBuilder::buildCFG(const Decl *D, Stmt *Statement) { 1360 assert(cfg.get()); 1361 if (!Statement) 1362 return nullptr; 1363 1364 // Create an empty block that will serve as the exit block for the CFG. Since 1365 // this is the first block added to the CFG, it will be implicitly registered 1366 // as the exit block. 1367 Succ = createBlock(); 1368 assert(Succ == &cfg->getExit()); 1369 Block = nullptr; // the EXIT block is empty. Create all other blocks lazily. 1370 1371 assert(!(BuildOpts.AddImplicitDtors && BuildOpts.AddLifetime) && 1372 "AddImplicitDtors and AddLifetime cannot be used at the same time"); 1373 1374 if (BuildOpts.AddImplicitDtors) 1375 if (const CXXDestructorDecl *DD = dyn_cast_or_null<CXXDestructorDecl>(D)) 1376 addImplicitDtorsForDestructor(DD); 1377 1378 // Visit the statements and create the CFG. 1379 CFGBlock *B = addStmt(Statement); 1380 1381 if (badCFG) 1382 return nullptr; 1383 1384 // For C++ constructor add initializers to CFG. 1385 if (const CXXConstructorDecl *CD = dyn_cast_or_null<CXXConstructorDecl>(D)) { 1386 for (auto *I : llvm::reverse(CD->inits())) { 1387 B = addInitializer(I); 1388 if (badCFG) 1389 return nullptr; 1390 } 1391 } 1392 1393 if (B) 1394 Succ = B; 1395 1396 // Backpatch the gotos whose label -> block mappings we didn't know when we 1397 // encountered them. 1398 for (BackpatchBlocksTy::iterator I = BackpatchBlocks.begin(), 1399 E = BackpatchBlocks.end(); I != E; ++I ) { 1400 1401 CFGBlock *B = I->block; 1402 const GotoStmt *G = cast<GotoStmt>(B->getTerminator()); 1403 LabelMapTy::iterator LI = LabelMap.find(G->getLabel()); 1404 1405 // If there is no target for the goto, then we are looking at an 1406 // incomplete AST. Handle this by not registering a successor. 1407 if (LI == LabelMap.end()) continue; 1408 1409 JumpTarget JT = LI->second; 1410 prependAutomaticObjLifetimeWithTerminator(B, I->scopePosition, 1411 JT.scopePosition); 1412 prependAutomaticObjDtorsWithTerminator(B, I->scopePosition, 1413 JT.scopePosition); 1414 const VarDecl *VD = prependAutomaticObjScopeEndWithTerminator( 1415 B, I->scopePosition, JT.scopePosition); 1416 appendScopeBegin(JT.block, VD, G); 1417 addSuccessor(B, JT.block); 1418 } 1419 1420 // Add successors to the Indirect Goto Dispatch block (if we have one). 1421 if (CFGBlock *B = cfg->getIndirectGotoBlock()) 1422 for (LabelSetTy::iterator I = AddressTakenLabels.begin(), 1423 E = AddressTakenLabels.end(); I != E; ++I ) { 1424 // Lookup the target block. 1425 LabelMapTy::iterator LI = LabelMap.find(*I); 1426 1427 // If there is no target block that contains label, then we are looking 1428 // at an incomplete AST. Handle this by not registering a successor. 1429 if (LI == LabelMap.end()) continue; 1430 1431 addSuccessor(B, LI->second.block); 1432 } 1433 1434 // Create an empty entry block that has no predecessors. 1435 cfg->setEntry(createBlock()); 1436 1437 if (BuildOpts.AddRichCXXConstructors) 1438 assert(ConstructionContextMap.empty() && 1439 "Not all construction contexts were cleaned up!"); 1440 1441 return std::move(cfg); 1442 } 1443 1444 /// createBlock - Used to lazily create blocks that are connected 1445 /// to the current (global) succcessor. 1446 CFGBlock *CFGBuilder::createBlock(bool add_successor) { 1447 CFGBlock *B = cfg->createBlock(); 1448 if (add_successor && Succ) 1449 addSuccessor(B, Succ); 1450 return B; 1451 } 1452 1453 /// createNoReturnBlock - Used to create a block is a 'noreturn' point in the 1454 /// CFG. It is *not* connected to the current (global) successor, and instead 1455 /// directly tied to the exit block in order to be reachable. 1456 CFGBlock *CFGBuilder::createNoReturnBlock() { 1457 CFGBlock *B = createBlock(false); 1458 B->setHasNoReturnElement(); 1459 addSuccessor(B, &cfg->getExit(), Succ); 1460 return B; 1461 } 1462 1463 /// addInitializer - Add C++ base or member initializer element to CFG. 1464 CFGBlock *CFGBuilder::addInitializer(CXXCtorInitializer *I) { 1465 if (!BuildOpts.AddInitializers) 1466 return Block; 1467 1468 bool HasTemporaries = false; 1469 1470 // Destructors of temporaries in initialization expression should be called 1471 // after initialization finishes. 1472 Expr *Init = I->getInit(); 1473 if (Init) { 1474 HasTemporaries = isa<ExprWithCleanups>(Init); 1475 1476 if (BuildOpts.AddTemporaryDtors && HasTemporaries) { 1477 // Generate destructors for temporaries in initialization expression. 1478 TempDtorContext Context; 1479 VisitForTemporaryDtors(cast<ExprWithCleanups>(Init)->getSubExpr(), 1480 /*BindToTemporary=*/false, Context); 1481 } 1482 } 1483 1484 autoCreateBlock(); 1485 appendInitializer(Block, I); 1486 1487 if (Init) { 1488 findConstructionContexts( 1489 ConstructionContextLayer::create(cfg->getBumpVectorContext(), I), 1490 Init); 1491 1492 if (HasTemporaries) { 1493 // For expression with temporaries go directly to subexpression to omit 1494 // generating destructors for the second time. 1495 return Visit(cast<ExprWithCleanups>(Init)->getSubExpr()); 1496 } 1497 if (BuildOpts.AddCXXDefaultInitExprInCtors) { 1498 if (CXXDefaultInitExpr *Default = dyn_cast<CXXDefaultInitExpr>(Init)) { 1499 // In general, appending the expression wrapped by a CXXDefaultInitExpr 1500 // may cause the same Expr to appear more than once in the CFG. Doing it 1501 // here is safe because there's only one initializer per field. 1502 autoCreateBlock(); 1503 appendStmt(Block, Default); 1504 if (Stmt *Child = Default->getExpr()) 1505 if (CFGBlock *R = Visit(Child)) 1506 Block = R; 1507 return Block; 1508 } 1509 } 1510 return Visit(Init); 1511 } 1512 1513 return Block; 1514 } 1515 1516 /// Retrieve the type of the temporary object whose lifetime was 1517 /// extended by a local reference with the given initializer. 1518 static QualType getReferenceInitTemporaryType(const Expr *Init, 1519 bool *FoundMTE = nullptr) { 1520 while (true) { 1521 // Skip parentheses. 1522 Init = Init->IgnoreParens(); 1523 1524 // Skip through cleanups. 1525 if (const ExprWithCleanups *EWC = dyn_cast<ExprWithCleanups>(Init)) { 1526 Init = EWC->getSubExpr(); 1527 continue; 1528 } 1529 1530 // Skip through the temporary-materialization expression. 1531 if (const MaterializeTemporaryExpr *MTE 1532 = dyn_cast<MaterializeTemporaryExpr>(Init)) { 1533 Init = MTE->GetTemporaryExpr(); 1534 if (FoundMTE) 1535 *FoundMTE = true; 1536 continue; 1537 } 1538 1539 // Skip sub-object accesses into rvalues. 1540 SmallVector<const Expr *, 2> CommaLHSs; 1541 SmallVector<SubobjectAdjustment, 2> Adjustments; 1542 const Expr *SkippedInit = 1543 Init->skipRValueSubobjectAdjustments(CommaLHSs, Adjustments); 1544 if (SkippedInit != Init) { 1545 Init = SkippedInit; 1546 continue; 1547 } 1548 1549 break; 1550 } 1551 1552 return Init->getType(); 1553 } 1554 1555 // TODO: Support adding LoopExit element to the CFG in case where the loop is 1556 // ended by ReturnStmt, GotoStmt or ThrowExpr. 1557 void CFGBuilder::addLoopExit(const Stmt *LoopStmt){ 1558 if(!BuildOpts.AddLoopExit) 1559 return; 1560 autoCreateBlock(); 1561 appendLoopExit(Block, LoopStmt); 1562 } 1563 1564 void CFGBuilder::getDeclsWithEndedScope(LocalScope::const_iterator B, 1565 LocalScope::const_iterator E, Stmt *S) { 1566 if (!BuildOpts.AddScopes) 1567 return; 1568 1569 if (B == E) 1570 return; 1571 1572 // To go from B to E, one first goes up the scopes from B to P 1573 // then sideways in one scope from P to P' and then down 1574 // the scopes from P' to E. 1575 // The lifetime of all objects between B and P end. 1576 LocalScope::const_iterator P = B.shared_parent(E); 1577 int Dist = B.distance(P); 1578 if (Dist <= 0) 1579 return; 1580 1581 for (LocalScope::const_iterator I = B; I != P; ++I) 1582 if (I.pointsToFirstDeclaredVar()) 1583 DeclsWithEndedScope.insert(*I); 1584 } 1585 1586 void CFGBuilder::addAutomaticObjHandling(LocalScope::const_iterator B, 1587 LocalScope::const_iterator E, 1588 Stmt *S) { 1589 getDeclsWithEndedScope(B, E, S); 1590 if (BuildOpts.AddScopes) 1591 addScopesEnd(B, E, S); 1592 if (BuildOpts.AddImplicitDtors) 1593 addAutomaticObjDtors(B, E, S); 1594 if (BuildOpts.AddLifetime) 1595 addLifetimeEnds(B, E, S); 1596 } 1597 1598 /// Add to current block automatic objects that leave the scope. 1599 void CFGBuilder::addLifetimeEnds(LocalScope::const_iterator B, 1600 LocalScope::const_iterator E, Stmt *S) { 1601 if (!BuildOpts.AddLifetime) 1602 return; 1603 1604 if (B == E) 1605 return; 1606 1607 // To go from B to E, one first goes up the scopes from B to P 1608 // then sideways in one scope from P to P' and then down 1609 // the scopes from P' to E. 1610 // The lifetime of all objects between B and P end. 1611 LocalScope::const_iterator P = B.shared_parent(E); 1612 int dist = B.distance(P); 1613 if (dist <= 0) 1614 return; 1615 1616 // We need to perform the scope leaving in reverse order 1617 SmallVector<VarDecl *, 10> DeclsTrivial; 1618 SmallVector<VarDecl *, 10> DeclsNonTrivial; 1619 DeclsTrivial.reserve(dist); 1620 DeclsNonTrivial.reserve(dist); 1621 1622 for (LocalScope::const_iterator I = B; I != P; ++I) 1623 if (hasTrivialDestructor(*I)) 1624 DeclsTrivial.push_back(*I); 1625 else 1626 DeclsNonTrivial.push_back(*I); 1627 1628 autoCreateBlock(); 1629 // object with trivial destructor end their lifetime last (when storage 1630 // duration ends) 1631 for (SmallVectorImpl<VarDecl *>::reverse_iterator I = DeclsTrivial.rbegin(), 1632 E = DeclsTrivial.rend(); 1633 I != E; ++I) 1634 appendLifetimeEnds(Block, *I, S); 1635 1636 for (SmallVectorImpl<VarDecl *>::reverse_iterator 1637 I = DeclsNonTrivial.rbegin(), 1638 E = DeclsNonTrivial.rend(); 1639 I != E; ++I) 1640 appendLifetimeEnds(Block, *I, S); 1641 } 1642 1643 /// Add to current block markers for ending scopes. 1644 void CFGBuilder::addScopesEnd(LocalScope::const_iterator B, 1645 LocalScope::const_iterator E, Stmt *S) { 1646 // If implicit destructors are enabled, we'll add scope ends in 1647 // addAutomaticObjDtors. 1648 if (BuildOpts.AddImplicitDtors) 1649 return; 1650 1651 autoCreateBlock(); 1652 1653 for (auto I = DeclsWithEndedScope.rbegin(), E = DeclsWithEndedScope.rend(); 1654 I != E; ++I) 1655 appendScopeEnd(Block, *I, S); 1656 1657 return; 1658 } 1659 1660 /// addAutomaticObjDtors - Add to current block automatic objects destructors 1661 /// for objects in range of local scope positions. Use S as trigger statement 1662 /// for destructors. 1663 void CFGBuilder::addAutomaticObjDtors(LocalScope::const_iterator B, 1664 LocalScope::const_iterator E, Stmt *S) { 1665 if (!BuildOpts.AddImplicitDtors) 1666 return; 1667 1668 if (B == E) 1669 return; 1670 1671 // We need to append the destructors in reverse order, but any one of them 1672 // may be a no-return destructor which changes the CFG. As a result, buffer 1673 // this sequence up and replay them in reverse order when appending onto the 1674 // CFGBlock(s). 1675 SmallVector<VarDecl*, 10> Decls; 1676 Decls.reserve(B.distance(E)); 1677 for (LocalScope::const_iterator I = B; I != E; ++I) 1678 Decls.push_back(*I); 1679 1680 for (SmallVectorImpl<VarDecl*>::reverse_iterator I = Decls.rbegin(), 1681 E = Decls.rend(); 1682 I != E; ++I) { 1683 if (hasTrivialDestructor(*I)) { 1684 // If AddScopes is enabled and *I is a first variable in a scope, add a 1685 // ScopeEnd marker in a Block. 1686 if (BuildOpts.AddScopes && DeclsWithEndedScope.count(*I)) { 1687 autoCreateBlock(); 1688 appendScopeEnd(Block, *I, S); 1689 } 1690 continue; 1691 } 1692 // If this destructor is marked as a no-return destructor, we need to 1693 // create a new block for the destructor which does not have as a successor 1694 // anything built thus far: control won't flow out of this block. 1695 QualType Ty = (*I)->getType(); 1696 if (Ty->isReferenceType()) { 1697 Ty = getReferenceInitTemporaryType((*I)->getInit()); 1698 } 1699 Ty = Context->getBaseElementType(Ty); 1700 1701 if (Ty->getAsCXXRecordDecl()->isAnyDestructorNoReturn()) 1702 Block = createNoReturnBlock(); 1703 else 1704 autoCreateBlock(); 1705 1706 // Add ScopeEnd just after automatic obj destructor. 1707 if (BuildOpts.AddScopes && DeclsWithEndedScope.count(*I)) 1708 appendScopeEnd(Block, *I, S); 1709 appendAutomaticObjDtor(Block, *I, S); 1710 } 1711 } 1712 1713 /// addImplicitDtorsForDestructor - Add implicit destructors generated for 1714 /// base and member objects in destructor. 1715 void CFGBuilder::addImplicitDtorsForDestructor(const CXXDestructorDecl *DD) { 1716 assert(BuildOpts.AddImplicitDtors && 1717 "Can be called only when dtors should be added"); 1718 const CXXRecordDecl *RD = DD->getParent(); 1719 1720 // At the end destroy virtual base objects. 1721 for (const auto &VI : RD->vbases()) { 1722 const CXXRecordDecl *CD = VI.getType()->getAsCXXRecordDecl(); 1723 if (!CD->hasTrivialDestructor()) { 1724 autoCreateBlock(); 1725 appendBaseDtor(Block, &VI); 1726 } 1727 } 1728 1729 // Before virtual bases destroy direct base objects. 1730 for (const auto &BI : RD->bases()) { 1731 if (!BI.isVirtual()) { 1732 const CXXRecordDecl *CD = BI.getType()->getAsCXXRecordDecl(); 1733 if (!CD->hasTrivialDestructor()) { 1734 autoCreateBlock(); 1735 appendBaseDtor(Block, &BI); 1736 } 1737 } 1738 } 1739 1740 // First destroy member objects. 1741 for (auto *FI : RD->fields()) { 1742 // Check for constant size array. Set type to array element type. 1743 QualType QT = FI->getType(); 1744 if (const ConstantArrayType *AT = Context->getAsConstantArrayType(QT)) { 1745 if (AT->getSize() == 0) 1746 continue; 1747 QT = AT->getElementType(); 1748 } 1749 1750 if (const CXXRecordDecl *CD = QT->getAsCXXRecordDecl()) 1751 if (!CD->hasTrivialDestructor()) { 1752 autoCreateBlock(); 1753 appendMemberDtor(Block, FI); 1754 } 1755 } 1756 } 1757 1758 /// createOrReuseLocalScope - If Scope is NULL create new LocalScope. Either 1759 /// way return valid LocalScope object. 1760 LocalScope* CFGBuilder::createOrReuseLocalScope(LocalScope* Scope) { 1761 if (Scope) 1762 return Scope; 1763 llvm::BumpPtrAllocator &alloc = cfg->getAllocator(); 1764 return new (alloc.Allocate<LocalScope>()) 1765 LocalScope(BumpVectorContext(alloc), ScopePos); 1766 } 1767 1768 /// addLocalScopeForStmt - Add LocalScope to local scopes tree for statement 1769 /// that should create implicit scope (e.g. if/else substatements). 1770 void CFGBuilder::addLocalScopeForStmt(Stmt *S) { 1771 if (!BuildOpts.AddImplicitDtors && !BuildOpts.AddLifetime && 1772 !BuildOpts.AddScopes) 1773 return; 1774 1775 LocalScope *Scope = nullptr; 1776 1777 // For compound statement we will be creating explicit scope. 1778 if (CompoundStmt *CS = dyn_cast<CompoundStmt>(S)) { 1779 for (auto *BI : CS->body()) { 1780 Stmt *SI = BI->stripLabelLikeStatements(); 1781 if (DeclStmt *DS = dyn_cast<DeclStmt>(SI)) 1782 Scope = addLocalScopeForDeclStmt(DS, Scope); 1783 } 1784 return; 1785 } 1786 1787 // For any other statement scope will be implicit and as such will be 1788 // interesting only for DeclStmt. 1789 if (DeclStmt *DS = dyn_cast<DeclStmt>(S->stripLabelLikeStatements())) 1790 addLocalScopeForDeclStmt(DS); 1791 } 1792 1793 /// addLocalScopeForDeclStmt - Add LocalScope for declaration statement. Will 1794 /// reuse Scope if not NULL. 1795 LocalScope* CFGBuilder::addLocalScopeForDeclStmt(DeclStmt *DS, 1796 LocalScope* Scope) { 1797 if (!BuildOpts.AddImplicitDtors && !BuildOpts.AddLifetime && 1798 !BuildOpts.AddScopes) 1799 return Scope; 1800 1801 for (auto *DI : DS->decls()) 1802 if (VarDecl *VD = dyn_cast<VarDecl>(DI)) 1803 Scope = addLocalScopeForVarDecl(VD, Scope); 1804 return Scope; 1805 } 1806 1807 bool CFGBuilder::hasTrivialDestructor(VarDecl *VD) { 1808 // Check for const references bound to temporary. Set type to pointee. 1809 QualType QT = VD->getType(); 1810 if (QT->isReferenceType()) { 1811 // Attempt to determine whether this declaration lifetime-extends a 1812 // temporary. 1813 // 1814 // FIXME: This is incorrect. Non-reference declarations can lifetime-extend 1815 // temporaries, and a single declaration can extend multiple temporaries. 1816 // We should look at the storage duration on each nested 1817 // MaterializeTemporaryExpr instead. 1818 1819 const Expr *Init = VD->getInit(); 1820 if (!Init) { 1821 // Probably an exception catch-by-reference variable. 1822 // FIXME: It doesn't really mean that the object has a trivial destructor. 1823 // Also are there other cases? 1824 return true; 1825 } 1826 1827 // Lifetime-extending a temporary? 1828 bool FoundMTE = false; 1829 QT = getReferenceInitTemporaryType(Init, &FoundMTE); 1830 if (!FoundMTE) 1831 return true; 1832 } 1833 1834 // Check for constant size array. Set type to array element type. 1835 while (const ConstantArrayType *AT = Context->getAsConstantArrayType(QT)) { 1836 if (AT->getSize() == 0) 1837 return true; 1838 QT = AT->getElementType(); 1839 } 1840 1841 // Check if type is a C++ class with non-trivial destructor. 1842 if (const CXXRecordDecl *CD = QT->getAsCXXRecordDecl()) 1843 return !CD->hasDefinition() || CD->hasTrivialDestructor(); 1844 return true; 1845 } 1846 1847 /// addLocalScopeForVarDecl - Add LocalScope for variable declaration. It will 1848 /// create add scope for automatic objects and temporary objects bound to 1849 /// const reference. Will reuse Scope if not NULL. 1850 LocalScope* CFGBuilder::addLocalScopeForVarDecl(VarDecl *VD, 1851 LocalScope* Scope) { 1852 assert(!(BuildOpts.AddImplicitDtors && BuildOpts.AddLifetime) && 1853 "AddImplicitDtors and AddLifetime cannot be used at the same time"); 1854 if (!BuildOpts.AddImplicitDtors && !BuildOpts.AddLifetime && 1855 !BuildOpts.AddScopes) 1856 return Scope; 1857 1858 // Check if variable is local. 1859 switch (VD->getStorageClass()) { 1860 case SC_None: 1861 case SC_Auto: 1862 case SC_Register: 1863 break; 1864 default: return Scope; 1865 } 1866 1867 if (BuildOpts.AddImplicitDtors) { 1868 if (!hasTrivialDestructor(VD) || BuildOpts.AddScopes) { 1869 // Add the variable to scope 1870 Scope = createOrReuseLocalScope(Scope); 1871 Scope->addVar(VD); 1872 ScopePos = Scope->begin(); 1873 } 1874 return Scope; 1875 } 1876 1877 assert(BuildOpts.AddLifetime); 1878 // Add the variable to scope 1879 Scope = createOrReuseLocalScope(Scope); 1880 Scope->addVar(VD); 1881 ScopePos = Scope->begin(); 1882 return Scope; 1883 } 1884 1885 /// addLocalScopeAndDtors - For given statement add local scope for it and 1886 /// add destructors that will cleanup the scope. Will reuse Scope if not NULL. 1887 void CFGBuilder::addLocalScopeAndDtors(Stmt *S) { 1888 LocalScope::const_iterator scopeBeginPos = ScopePos; 1889 addLocalScopeForStmt(S); 1890 addAutomaticObjHandling(ScopePos, scopeBeginPos, S); 1891 } 1892 1893 /// prependAutomaticObjDtorsWithTerminator - Prepend destructor CFGElements for 1894 /// variables with automatic storage duration to CFGBlock's elements vector. 1895 /// Elements will be prepended to physical beginning of the vector which 1896 /// happens to be logical end. Use blocks terminator as statement that specifies 1897 /// destructors call site. 1898 /// FIXME: This mechanism for adding automatic destructors doesn't handle 1899 /// no-return destructors properly. 1900 void CFGBuilder::prependAutomaticObjDtorsWithTerminator(CFGBlock *Blk, 1901 LocalScope::const_iterator B, LocalScope::const_iterator E) { 1902 if (!BuildOpts.AddImplicitDtors) 1903 return; 1904 BumpVectorContext &C = cfg->getBumpVectorContext(); 1905 CFGBlock::iterator InsertPos 1906 = Blk->beginAutomaticObjDtorsInsert(Blk->end(), B.distance(E), C); 1907 for (LocalScope::const_iterator I = B; I != E; ++I) 1908 InsertPos = Blk->insertAutomaticObjDtor(InsertPos, *I, 1909 Blk->getTerminator()); 1910 } 1911 1912 /// prependAutomaticObjLifetimeWithTerminator - Prepend lifetime CFGElements for 1913 /// variables with automatic storage duration to CFGBlock's elements vector. 1914 /// Elements will be prepended to physical beginning of the vector which 1915 /// happens to be logical end. Use blocks terminator as statement that specifies 1916 /// where lifetime ends. 1917 void CFGBuilder::prependAutomaticObjLifetimeWithTerminator( 1918 CFGBlock *Blk, LocalScope::const_iterator B, LocalScope::const_iterator E) { 1919 if (!BuildOpts.AddLifetime) 1920 return; 1921 BumpVectorContext &C = cfg->getBumpVectorContext(); 1922 CFGBlock::iterator InsertPos = 1923 Blk->beginLifetimeEndsInsert(Blk->end(), B.distance(E), C); 1924 for (LocalScope::const_iterator I = B; I != E; ++I) 1925 InsertPos = Blk->insertLifetimeEnds(InsertPos, *I, Blk->getTerminator()); 1926 } 1927 1928 /// prependAutomaticObjScopeEndWithTerminator - Prepend scope end CFGElements for 1929 /// variables with automatic storage duration to CFGBlock's elements vector. 1930 /// Elements will be prepended to physical beginning of the vector which 1931 /// happens to be logical end. Use blocks terminator as statement that specifies 1932 /// where scope ends. 1933 const VarDecl * 1934 CFGBuilder::prependAutomaticObjScopeEndWithTerminator( 1935 CFGBlock *Blk, LocalScope::const_iterator B, LocalScope::const_iterator E) { 1936 if (!BuildOpts.AddScopes) 1937 return nullptr; 1938 BumpVectorContext &C = cfg->getBumpVectorContext(); 1939 CFGBlock::iterator InsertPos = 1940 Blk->beginScopeEndInsert(Blk->end(), 1, C); 1941 LocalScope::const_iterator PlaceToInsert = B; 1942 for (LocalScope::const_iterator I = B; I != E; ++I) 1943 PlaceToInsert = I; 1944 Blk->insertScopeEnd(InsertPos, *PlaceToInsert, Blk->getTerminator()); 1945 return *PlaceToInsert; 1946 } 1947 1948 /// Visit - Walk the subtree of a statement and add extra 1949 /// blocks for ternary operators, &&, and ||. We also process "," and 1950 /// DeclStmts (which may contain nested control-flow). 1951 CFGBlock *CFGBuilder::Visit(Stmt * S, AddStmtChoice asc) { 1952 if (!S) { 1953 badCFG = true; 1954 return nullptr; 1955 } 1956 1957 if (Expr *E = dyn_cast<Expr>(S)) 1958 S = E->IgnoreParens(); 1959 1960 switch (S->getStmtClass()) { 1961 default: 1962 return VisitStmt(S, asc); 1963 1964 case Stmt::AddrLabelExprClass: 1965 return VisitAddrLabelExpr(cast<AddrLabelExpr>(S), asc); 1966 1967 case Stmt::BinaryConditionalOperatorClass: 1968 return VisitConditionalOperator(cast<BinaryConditionalOperator>(S), asc); 1969 1970 case Stmt::BinaryOperatorClass: 1971 return VisitBinaryOperator(cast<BinaryOperator>(S), asc); 1972 1973 case Stmt::BlockExprClass: 1974 return VisitBlockExpr(cast<BlockExpr>(S), asc); 1975 1976 case Stmt::BreakStmtClass: 1977 return VisitBreakStmt(cast<BreakStmt>(S)); 1978 1979 case Stmt::CallExprClass: 1980 case Stmt::CXXOperatorCallExprClass: 1981 case Stmt::CXXMemberCallExprClass: 1982 case Stmt::UserDefinedLiteralClass: 1983 return VisitCallExpr(cast<CallExpr>(S), asc); 1984 1985 case Stmt::CaseStmtClass: 1986 return VisitCaseStmt(cast<CaseStmt>(S)); 1987 1988 case Stmt::ChooseExprClass: 1989 return VisitChooseExpr(cast<ChooseExpr>(S), asc); 1990 1991 case Stmt::CompoundStmtClass: 1992 return VisitCompoundStmt(cast<CompoundStmt>(S)); 1993 1994 case Stmt::ConditionalOperatorClass: 1995 return VisitConditionalOperator(cast<ConditionalOperator>(S), asc); 1996 1997 case Stmt::ContinueStmtClass: 1998 return VisitContinueStmt(cast<ContinueStmt>(S)); 1999 2000 case Stmt::CXXCatchStmtClass: 2001 return VisitCXXCatchStmt(cast<CXXCatchStmt>(S)); 2002 2003 case Stmt::ExprWithCleanupsClass: 2004 return VisitExprWithCleanups(cast<ExprWithCleanups>(S), asc); 2005 2006 case Stmt::CXXDefaultArgExprClass: 2007 case Stmt::CXXDefaultInitExprClass: 2008 // FIXME: The expression inside a CXXDefaultArgExpr is owned by the 2009 // called function's declaration, not by the caller. If we simply add 2010 // this expression to the CFG, we could end up with the same Expr 2011 // appearing multiple times. 2012 // PR13385 / <rdar://problem/12156507> 2013 // 2014 // It's likewise possible for multiple CXXDefaultInitExprs for the same 2015 // expression to be used in the same function (through aggregate 2016 // initialization). 2017 return VisitStmt(S, asc); 2018 2019 case Stmt::CXXBindTemporaryExprClass: 2020 return VisitCXXBindTemporaryExpr(cast<CXXBindTemporaryExpr>(S), asc); 2021 2022 case Stmt::CXXConstructExprClass: 2023 return VisitCXXConstructExpr(cast<CXXConstructExpr>(S), asc); 2024 2025 case Stmt::CXXNewExprClass: 2026 return VisitCXXNewExpr(cast<CXXNewExpr>(S), asc); 2027 2028 case Stmt::CXXDeleteExprClass: 2029 return VisitCXXDeleteExpr(cast<CXXDeleteExpr>(S), asc); 2030 2031 case Stmt::CXXFunctionalCastExprClass: 2032 return VisitCXXFunctionalCastExpr(cast<CXXFunctionalCastExpr>(S), asc); 2033 2034 case Stmt::CXXTemporaryObjectExprClass: 2035 return VisitCXXTemporaryObjectExpr(cast<CXXTemporaryObjectExpr>(S), asc); 2036 2037 case Stmt::CXXThrowExprClass: 2038 return VisitCXXThrowExpr(cast<CXXThrowExpr>(S)); 2039 2040 case Stmt::CXXTryStmtClass: 2041 return VisitCXXTryStmt(cast<CXXTryStmt>(S)); 2042 2043 case Stmt::CXXForRangeStmtClass: 2044 return VisitCXXForRangeStmt(cast<CXXForRangeStmt>(S)); 2045 2046 case Stmt::DeclStmtClass: 2047 return VisitDeclStmt(cast<DeclStmt>(S)); 2048 2049 case Stmt::DefaultStmtClass: 2050 return VisitDefaultStmt(cast<DefaultStmt>(S)); 2051 2052 case Stmt::DoStmtClass: 2053 return VisitDoStmt(cast<DoStmt>(S)); 2054 2055 case Stmt::ForStmtClass: 2056 return VisitForStmt(cast<ForStmt>(S)); 2057 2058 case Stmt::GotoStmtClass: 2059 return VisitGotoStmt(cast<GotoStmt>(S)); 2060 2061 case Stmt::IfStmtClass: 2062 return VisitIfStmt(cast<IfStmt>(S)); 2063 2064 case Stmt::ImplicitCastExprClass: 2065 return VisitImplicitCastExpr(cast<ImplicitCastExpr>(S), asc); 2066 2067 case Stmt::IndirectGotoStmtClass: 2068 return VisitIndirectGotoStmt(cast<IndirectGotoStmt>(S)); 2069 2070 case Stmt::LabelStmtClass: 2071 return VisitLabelStmt(cast<LabelStmt>(S)); 2072 2073 case Stmt::LambdaExprClass: 2074 return VisitLambdaExpr(cast<LambdaExpr>(S), asc); 2075 2076 case Stmt::MaterializeTemporaryExprClass: 2077 return VisitMaterializeTemporaryExpr(cast<MaterializeTemporaryExpr>(S), 2078 asc); 2079 2080 case Stmt::MemberExprClass: 2081 return VisitMemberExpr(cast<MemberExpr>(S), asc); 2082 2083 case Stmt::NullStmtClass: 2084 return Block; 2085 2086 case Stmt::ObjCAtCatchStmtClass: 2087 return VisitObjCAtCatchStmt(cast<ObjCAtCatchStmt>(S)); 2088 2089 case Stmt::ObjCAutoreleasePoolStmtClass: 2090 return VisitObjCAutoreleasePoolStmt(cast<ObjCAutoreleasePoolStmt>(S)); 2091 2092 case Stmt::ObjCAtSynchronizedStmtClass: 2093 return VisitObjCAtSynchronizedStmt(cast<ObjCAtSynchronizedStmt>(S)); 2094 2095 case Stmt::ObjCAtThrowStmtClass: 2096 return VisitObjCAtThrowStmt(cast<ObjCAtThrowStmt>(S)); 2097 2098 case Stmt::ObjCAtTryStmtClass: 2099 return VisitObjCAtTryStmt(cast<ObjCAtTryStmt>(S)); 2100 2101 case Stmt::ObjCForCollectionStmtClass: 2102 return VisitObjCForCollectionStmt(cast<ObjCForCollectionStmt>(S)); 2103 2104 case Stmt::OpaqueValueExprClass: 2105 return Block; 2106 2107 case Stmt::PseudoObjectExprClass: 2108 return VisitPseudoObjectExpr(cast<PseudoObjectExpr>(S)); 2109 2110 case Stmt::ReturnStmtClass: 2111 return VisitReturnStmt(cast<ReturnStmt>(S)); 2112 2113 case Stmt::SEHExceptStmtClass: 2114 return VisitSEHExceptStmt(cast<SEHExceptStmt>(S)); 2115 2116 case Stmt::SEHFinallyStmtClass: 2117 return VisitSEHFinallyStmt(cast<SEHFinallyStmt>(S)); 2118 2119 case Stmt::SEHLeaveStmtClass: 2120 return VisitSEHLeaveStmt(cast<SEHLeaveStmt>(S)); 2121 2122 case Stmt::SEHTryStmtClass: 2123 return VisitSEHTryStmt(cast<SEHTryStmt>(S)); 2124 2125 case Stmt::UnaryExprOrTypeTraitExprClass: 2126 return VisitUnaryExprOrTypeTraitExpr(cast<UnaryExprOrTypeTraitExpr>(S), 2127 asc); 2128 2129 case Stmt::StmtExprClass: 2130 return VisitStmtExpr(cast<StmtExpr>(S), asc); 2131 2132 case Stmt::SwitchStmtClass: 2133 return VisitSwitchStmt(cast<SwitchStmt>(S)); 2134 2135 case Stmt::UnaryOperatorClass: 2136 return VisitUnaryOperator(cast<UnaryOperator>(S), asc); 2137 2138 case Stmt::WhileStmtClass: 2139 return VisitWhileStmt(cast<WhileStmt>(S)); 2140 } 2141 } 2142 2143 CFGBlock *CFGBuilder::VisitStmt(Stmt *S, AddStmtChoice asc) { 2144 if (asc.alwaysAdd(*this, S)) { 2145 autoCreateBlock(); 2146 appendStmt(Block, S); 2147 } 2148 2149 return VisitChildren(S); 2150 } 2151 2152 /// VisitChildren - Visit the children of a Stmt. 2153 CFGBlock *CFGBuilder::VisitChildren(Stmt *S) { 2154 CFGBlock *B = Block; 2155 2156 // Visit the children in their reverse order so that they appear in 2157 // left-to-right (natural) order in the CFG. 2158 reverse_children RChildren(S); 2159 for (reverse_children::iterator I = RChildren.begin(), E = RChildren.end(); 2160 I != E; ++I) { 2161 if (Stmt *Child = *I) 2162 if (CFGBlock *R = Visit(Child)) 2163 B = R; 2164 } 2165 return B; 2166 } 2167 2168 CFGBlock *CFGBuilder::VisitAddrLabelExpr(AddrLabelExpr *A, 2169 AddStmtChoice asc) { 2170 AddressTakenLabels.insert(A->getLabel()); 2171 2172 if (asc.alwaysAdd(*this, A)) { 2173 autoCreateBlock(); 2174 appendStmt(Block, A); 2175 } 2176 2177 return Block; 2178 } 2179 2180 CFGBlock *CFGBuilder::VisitUnaryOperator(UnaryOperator *U, 2181 AddStmtChoice asc) { 2182 if (asc.alwaysAdd(*this, U)) { 2183 autoCreateBlock(); 2184 appendStmt(Block, U); 2185 } 2186 2187 return Visit(U->getSubExpr(), AddStmtChoice()); 2188 } 2189 2190 CFGBlock *CFGBuilder::VisitLogicalOperator(BinaryOperator *B) { 2191 CFGBlock *ConfluenceBlock = Block ? Block : createBlock(); 2192 appendStmt(ConfluenceBlock, B); 2193 2194 if (badCFG) 2195 return nullptr; 2196 2197 return VisitLogicalOperator(B, nullptr, ConfluenceBlock, 2198 ConfluenceBlock).first; 2199 } 2200 2201 std::pair<CFGBlock*, CFGBlock*> 2202 CFGBuilder::VisitLogicalOperator(BinaryOperator *B, 2203 Stmt *Term, 2204 CFGBlock *TrueBlock, 2205 CFGBlock *FalseBlock) { 2206 // Introspect the RHS. If it is a nested logical operation, we recursively 2207 // build the CFG using this function. Otherwise, resort to default 2208 // CFG construction behavior. 2209 Expr *RHS = B->getRHS()->IgnoreParens(); 2210 CFGBlock *RHSBlock, *ExitBlock; 2211 2212 do { 2213 if (BinaryOperator *B_RHS = dyn_cast<BinaryOperator>(RHS)) 2214 if (B_RHS->isLogicalOp()) { 2215 std::tie(RHSBlock, ExitBlock) = 2216 VisitLogicalOperator(B_RHS, Term, TrueBlock, FalseBlock); 2217 break; 2218 } 2219 2220 // The RHS is not a nested logical operation. Don't push the terminator 2221 // down further, but instead visit RHS and construct the respective 2222 // pieces of the CFG, and link up the RHSBlock with the terminator 2223 // we have been provided. 2224 ExitBlock = RHSBlock = createBlock(false); 2225 2226 // Even though KnownVal is only used in the else branch of the next 2227 // conditional, tryEvaluateBool performs additional checking on the 2228 // Expr, so it should be called unconditionally. 2229 TryResult KnownVal = tryEvaluateBool(RHS); 2230 if (!KnownVal.isKnown()) 2231 KnownVal = tryEvaluateBool(B); 2232 2233 if (!Term) { 2234 assert(TrueBlock == FalseBlock); 2235 addSuccessor(RHSBlock, TrueBlock); 2236 } 2237 else { 2238 RHSBlock->setTerminator(Term); 2239 addSuccessor(RHSBlock, TrueBlock, !KnownVal.isFalse()); 2240 addSuccessor(RHSBlock, FalseBlock, !KnownVal.isTrue()); 2241 } 2242 2243 Block = RHSBlock; 2244 RHSBlock = addStmt(RHS); 2245 } 2246 while (false); 2247 2248 if (badCFG) 2249 return std::make_pair(nullptr, nullptr); 2250 2251 // Generate the blocks for evaluating the LHS. 2252 Expr *LHS = B->getLHS()->IgnoreParens(); 2253 2254 if (BinaryOperator *B_LHS = dyn_cast<BinaryOperator>(LHS)) 2255 if (B_LHS->isLogicalOp()) { 2256 if (B->getOpcode() == BO_LOr) 2257 FalseBlock = RHSBlock; 2258 else 2259 TrueBlock = RHSBlock; 2260 2261 // For the LHS, treat 'B' as the terminator that we want to sink 2262 // into the nested branch. The RHS always gets the top-most 2263 // terminator. 2264 return VisitLogicalOperator(B_LHS, B, TrueBlock, FalseBlock); 2265 } 2266 2267 // Create the block evaluating the LHS. 2268 // This contains the '&&' or '||' as the terminator. 2269 CFGBlock *LHSBlock = createBlock(false); 2270 LHSBlock->setTerminator(B); 2271 2272 Block = LHSBlock; 2273 CFGBlock *EntryLHSBlock = addStmt(LHS); 2274 2275 if (badCFG) 2276 return std::make_pair(nullptr, nullptr); 2277 2278 // See if this is a known constant. 2279 TryResult KnownVal = tryEvaluateBool(LHS); 2280 2281 // Now link the LHSBlock with RHSBlock. 2282 if (B->getOpcode() == BO_LOr) { 2283 addSuccessor(LHSBlock, TrueBlock, !KnownVal.isFalse()); 2284 addSuccessor(LHSBlock, RHSBlock, !KnownVal.isTrue()); 2285 } else { 2286 assert(B->getOpcode() == BO_LAnd); 2287 addSuccessor(LHSBlock, RHSBlock, !KnownVal.isFalse()); 2288 addSuccessor(LHSBlock, FalseBlock, !KnownVal.isTrue()); 2289 } 2290 2291 return std::make_pair(EntryLHSBlock, ExitBlock); 2292 } 2293 2294 CFGBlock *CFGBuilder::VisitBinaryOperator(BinaryOperator *B, 2295 AddStmtChoice asc) { 2296 // && or || 2297 if (B->isLogicalOp()) 2298 return VisitLogicalOperator(B); 2299 2300 if (B->getOpcode() == BO_Comma) { // , 2301 autoCreateBlock(); 2302 appendStmt(Block, B); 2303 addStmt(B->getRHS()); 2304 return addStmt(B->getLHS()); 2305 } 2306 2307 if (B->isAssignmentOp()) { 2308 if (asc.alwaysAdd(*this, B)) { 2309 autoCreateBlock(); 2310 appendStmt(Block, B); 2311 } 2312 Visit(B->getLHS()); 2313 return Visit(B->getRHS()); 2314 } 2315 2316 if (asc.alwaysAdd(*this, B)) { 2317 autoCreateBlock(); 2318 appendStmt(Block, B); 2319 } 2320 2321 CFGBlock *RBlock = Visit(B->getRHS()); 2322 CFGBlock *LBlock = Visit(B->getLHS()); 2323 // If visiting RHS causes us to finish 'Block', e.g. the RHS is a StmtExpr 2324 // containing a DoStmt, and the LHS doesn't create a new block, then we should 2325 // return RBlock. Otherwise we'll incorrectly return NULL. 2326 return (LBlock ? LBlock : RBlock); 2327 } 2328 2329 CFGBlock *CFGBuilder::VisitNoRecurse(Expr *E, AddStmtChoice asc) { 2330 if (asc.alwaysAdd(*this, E)) { 2331 autoCreateBlock(); 2332 appendStmt(Block, E); 2333 } 2334 return Block; 2335 } 2336 2337 CFGBlock *CFGBuilder::VisitBreakStmt(BreakStmt *B) { 2338 // "break" is a control-flow statement. Thus we stop processing the current 2339 // block. 2340 if (badCFG) 2341 return nullptr; 2342 2343 // Now create a new block that ends with the break statement. 2344 Block = createBlock(false); 2345 Block->setTerminator(B); 2346 2347 // If there is no target for the break, then we are looking at an incomplete 2348 // AST. This means that the CFG cannot be constructed. 2349 if (BreakJumpTarget.block) { 2350 addAutomaticObjHandling(ScopePos, BreakJumpTarget.scopePosition, B); 2351 addSuccessor(Block, BreakJumpTarget.block); 2352 } else 2353 badCFG = true; 2354 2355 return Block; 2356 } 2357 2358 static bool CanThrow(Expr *E, ASTContext &Ctx) { 2359 QualType Ty = E->getType(); 2360 if (Ty->isFunctionPointerType()) 2361 Ty = Ty->getAs<PointerType>()->getPointeeType(); 2362 else if (Ty->isBlockPointerType()) 2363 Ty = Ty->getAs<BlockPointerType>()->getPointeeType(); 2364 2365 const FunctionType *FT = Ty->getAs<FunctionType>(); 2366 if (FT) { 2367 if (const FunctionProtoType *Proto = dyn_cast<FunctionProtoType>(FT)) 2368 if (!isUnresolvedExceptionSpec(Proto->getExceptionSpecType()) && 2369 Proto->isNothrow()) 2370 return false; 2371 } 2372 return true; 2373 } 2374 2375 CFGBlock *CFGBuilder::VisitCallExpr(CallExpr *C, AddStmtChoice asc) { 2376 // Compute the callee type. 2377 QualType calleeType = C->getCallee()->getType(); 2378 if (calleeType == Context->BoundMemberTy) { 2379 QualType boundType = Expr::findBoundMemberType(C->getCallee()); 2380 2381 // We should only get a null bound type if processing a dependent 2382 // CFG. Recover by assuming nothing. 2383 if (!boundType.isNull()) calleeType = boundType; 2384 } 2385 2386 // FIXME: Once actually implemented, this construction context layer should 2387 // include the number of the argument as well. 2388 for (auto Arg: C->arguments()) { 2389 findConstructionContexts( 2390 ConstructionContextLayer::create(cfg->getBumpVectorContext(), C), Arg); 2391 } 2392 2393 // If this is a call to a no-return function, this stops the block here. 2394 bool NoReturn = getFunctionExtInfo(*calleeType).getNoReturn(); 2395 2396 bool AddEHEdge = false; 2397 2398 // Languages without exceptions are assumed to not throw. 2399 if (Context->getLangOpts().Exceptions) { 2400 if (BuildOpts.AddEHEdges) 2401 AddEHEdge = true; 2402 } 2403 2404 // If this is a call to a builtin function, it might not actually evaluate 2405 // its arguments. Don't add them to the CFG if this is the case. 2406 bool OmitArguments = false; 2407 2408 if (FunctionDecl *FD = C->getDirectCallee()) { 2409 if (FD->isNoReturn() || C->isBuiltinAssumeFalse(*Context)) 2410 NoReturn = true; 2411 if (FD->hasAttr<NoThrowAttr>()) 2412 AddEHEdge = false; 2413 if (FD->getBuiltinID() == Builtin::BI__builtin_object_size) 2414 OmitArguments = true; 2415 } 2416 2417 if (!CanThrow(C->getCallee(), *Context)) 2418 AddEHEdge = false; 2419 2420 if (OmitArguments) { 2421 assert(!NoReturn && "noreturn calls with unevaluated args not implemented"); 2422 assert(!AddEHEdge && "EH calls with unevaluated args not implemented"); 2423 autoCreateBlock(); 2424 appendStmt(Block, C); 2425 return Visit(C->getCallee()); 2426 } 2427 2428 if (!NoReturn && !AddEHEdge) { 2429 autoCreateBlock(); 2430 appendCall(Block, C); 2431 2432 return VisitChildren(C); 2433 } 2434 2435 if (Block) { 2436 Succ = Block; 2437 if (badCFG) 2438 return nullptr; 2439 } 2440 2441 if (NoReturn) 2442 Block = createNoReturnBlock(); 2443 else 2444 Block = createBlock(); 2445 2446 appendCall(Block, C); 2447 2448 if (AddEHEdge) { 2449 // Add exceptional edges. 2450 if (TryTerminatedBlock) 2451 addSuccessor(Block, TryTerminatedBlock); 2452 else 2453 addSuccessor(Block, &cfg->getExit()); 2454 } 2455 2456 return VisitChildren(C); 2457 } 2458 2459 CFGBlock *CFGBuilder::VisitChooseExpr(ChooseExpr *C, 2460 AddStmtChoice asc) { 2461 CFGBlock *ConfluenceBlock = Block ? Block : createBlock(); 2462 appendStmt(ConfluenceBlock, C); 2463 if (badCFG) 2464 return nullptr; 2465 2466 AddStmtChoice alwaysAdd = asc.withAlwaysAdd(true); 2467 Succ = ConfluenceBlock; 2468 Block = nullptr; 2469 CFGBlock *LHSBlock = Visit(C->getLHS(), alwaysAdd); 2470 if (badCFG) 2471 return nullptr; 2472 2473 Succ = ConfluenceBlock; 2474 Block = nullptr; 2475 CFGBlock *RHSBlock = Visit(C->getRHS(), alwaysAdd); 2476 if (badCFG) 2477 return nullptr; 2478 2479 Block = createBlock(false); 2480 // See if this is a known constant. 2481 const TryResult& KnownVal = tryEvaluateBool(C->getCond()); 2482 addSuccessor(Block, KnownVal.isFalse() ? nullptr : LHSBlock); 2483 addSuccessor(Block, KnownVal.isTrue() ? nullptr : RHSBlock); 2484 Block->setTerminator(C); 2485 return addStmt(C->getCond()); 2486 } 2487 2488 CFGBlock *CFGBuilder::VisitCompoundStmt(CompoundStmt *C) { 2489 LocalScope::const_iterator scopeBeginPos = ScopePos; 2490 addLocalScopeForStmt(C); 2491 2492 if (!C->body_empty() && !isa<ReturnStmt>(*C->body_rbegin())) { 2493 // If the body ends with a ReturnStmt, the dtors will be added in 2494 // VisitReturnStmt. 2495 addAutomaticObjHandling(ScopePos, scopeBeginPos, C); 2496 } 2497 2498 CFGBlock *LastBlock = Block; 2499 2500 for (CompoundStmt::reverse_body_iterator I=C->body_rbegin(), E=C->body_rend(); 2501 I != E; ++I ) { 2502 // If we hit a segment of code just containing ';' (NullStmts), we can 2503 // get a null block back. In such cases, just use the LastBlock 2504 if (CFGBlock *newBlock = addStmt(*I)) 2505 LastBlock = newBlock; 2506 2507 if (badCFG) 2508 return nullptr; 2509 } 2510 2511 return LastBlock; 2512 } 2513 2514 CFGBlock *CFGBuilder::VisitConditionalOperator(AbstractConditionalOperator *C, 2515 AddStmtChoice asc) { 2516 const BinaryConditionalOperator *BCO = dyn_cast<BinaryConditionalOperator>(C); 2517 const OpaqueValueExpr *opaqueValue = (BCO ? BCO->getOpaqueValue() : nullptr); 2518 2519 // Create the confluence block that will "merge" the results of the ternary 2520 // expression. 2521 CFGBlock *ConfluenceBlock = Block ? Block : createBlock(); 2522 appendStmt(ConfluenceBlock, C); 2523 if (badCFG) 2524 return nullptr; 2525 2526 AddStmtChoice alwaysAdd = asc.withAlwaysAdd(true); 2527 2528 // Create a block for the LHS expression if there is an LHS expression. A 2529 // GCC extension allows LHS to be NULL, causing the condition to be the 2530 // value that is returned instead. 2531 // e.g: x ?: y is shorthand for: x ? x : y; 2532 Succ = ConfluenceBlock; 2533 Block = nullptr; 2534 CFGBlock *LHSBlock = nullptr; 2535 const Expr *trueExpr = C->getTrueExpr(); 2536 if (trueExpr != opaqueValue) { 2537 LHSBlock = Visit(C->getTrueExpr(), alwaysAdd); 2538 if (badCFG) 2539 return nullptr; 2540 Block = nullptr; 2541 } 2542 else 2543 LHSBlock = ConfluenceBlock; 2544 2545 // Create the block for the RHS expression. 2546 Succ = ConfluenceBlock; 2547 CFGBlock *RHSBlock = Visit(C->getFalseExpr(), alwaysAdd); 2548 if (badCFG) 2549 return nullptr; 2550 2551 // If the condition is a logical '&&' or '||', build a more accurate CFG. 2552 if (BinaryOperator *Cond = 2553 dyn_cast<BinaryOperator>(C->getCond()->IgnoreParens())) 2554 if (Cond->isLogicalOp()) 2555 return VisitLogicalOperator(Cond, C, LHSBlock, RHSBlock).first; 2556 2557 // Create the block that will contain the condition. 2558 Block = createBlock(false); 2559 2560 // See if this is a known constant. 2561 const TryResult& KnownVal = tryEvaluateBool(C->getCond()); 2562 addSuccessor(Block, LHSBlock, !KnownVal.isFalse()); 2563 addSuccessor(Block, RHSBlock, !KnownVal.isTrue()); 2564 Block->setTerminator(C); 2565 Expr *condExpr = C->getCond(); 2566 2567 if (opaqueValue) { 2568 // Run the condition expression if it's not trivially expressed in 2569 // terms of the opaque value (or if there is no opaque value). 2570 if (condExpr != opaqueValue) 2571 addStmt(condExpr); 2572 2573 // Before that, run the common subexpression if there was one. 2574 // At least one of this or the above will be run. 2575 return addStmt(BCO->getCommon()); 2576 } 2577 2578 return addStmt(condExpr); 2579 } 2580 2581 CFGBlock *CFGBuilder::VisitDeclStmt(DeclStmt *DS) { 2582 // Check if the Decl is for an __label__. If so, elide it from the 2583 // CFG entirely. 2584 if (isa<LabelDecl>(*DS->decl_begin())) 2585 return Block; 2586 2587 // This case also handles static_asserts. 2588 if (DS->isSingleDecl()) 2589 return VisitDeclSubExpr(DS); 2590 2591 CFGBlock *B = nullptr; 2592 2593 // Build an individual DeclStmt for each decl. 2594 for (DeclStmt::reverse_decl_iterator I = DS->decl_rbegin(), 2595 E = DS->decl_rend(); 2596 I != E; ++I) { 2597 // Get the alignment of the new DeclStmt, padding out to >=8 bytes. 2598 unsigned A = alignof(DeclStmt) < 8 ? 8 : alignof(DeclStmt); 2599 2600 // Allocate the DeclStmt using the BumpPtrAllocator. It will get 2601 // automatically freed with the CFG. 2602 DeclGroupRef DG(*I); 2603 Decl *D = *I; 2604 void *Mem = cfg->getAllocator().Allocate(sizeof(DeclStmt), A); 2605 DeclStmt *DSNew = new (Mem) DeclStmt(DG, D->getLocation(), GetEndLoc(D)); 2606 cfg->addSyntheticDeclStmt(DSNew, DS); 2607 2608 // Append the fake DeclStmt to block. 2609 B = VisitDeclSubExpr(DSNew); 2610 } 2611 2612 return B; 2613 } 2614 2615 /// VisitDeclSubExpr - Utility method to add block-level expressions for 2616 /// DeclStmts and initializers in them. 2617 CFGBlock *CFGBuilder::VisitDeclSubExpr(DeclStmt *DS) { 2618 assert(DS->isSingleDecl() && "Can handle single declarations only."); 2619 VarDecl *VD = dyn_cast<VarDecl>(DS->getSingleDecl()); 2620 2621 if (!VD) { 2622 // Of everything that can be declared in a DeclStmt, only VarDecls impact 2623 // runtime semantics. 2624 return Block; 2625 } 2626 2627 bool HasTemporaries = false; 2628 2629 // Guard static initializers under a branch. 2630 CFGBlock *blockAfterStaticInit = nullptr; 2631 2632 if (BuildOpts.AddStaticInitBranches && VD->isStaticLocal()) { 2633 // For static variables, we need to create a branch to track 2634 // whether or not they are initialized. 2635 if (Block) { 2636 Succ = Block; 2637 Block = nullptr; 2638 if (badCFG) 2639 return nullptr; 2640 } 2641 blockAfterStaticInit = Succ; 2642 } 2643 2644 // Destructors of temporaries in initialization expression should be called 2645 // after initialization finishes. 2646 Expr *Init = VD->getInit(); 2647 if (Init) { 2648 HasTemporaries = isa<ExprWithCleanups>(Init); 2649 2650 if (BuildOpts.AddTemporaryDtors && HasTemporaries) { 2651 // Generate destructors for temporaries in initialization expression. 2652 TempDtorContext Context; 2653 VisitForTemporaryDtors(cast<ExprWithCleanups>(Init)->getSubExpr(), 2654 /*BindToTemporary=*/false, Context); 2655 } 2656 } 2657 2658 autoCreateBlock(); 2659 appendStmt(Block, DS); 2660 2661 findConstructionContexts( 2662 ConstructionContextLayer::create(cfg->getBumpVectorContext(), DS), 2663 Init); 2664 2665 // Keep track of the last non-null block, as 'Block' can be nulled out 2666 // if the initializer expression is something like a 'while' in a 2667 // statement-expression. 2668 CFGBlock *LastBlock = Block; 2669 2670 if (Init) { 2671 if (HasTemporaries) { 2672 // For expression with temporaries go directly to subexpression to omit 2673 // generating destructors for the second time. 2674 ExprWithCleanups *EC = cast<ExprWithCleanups>(Init); 2675 if (CFGBlock *newBlock = Visit(EC->getSubExpr())) 2676 LastBlock = newBlock; 2677 } 2678 else { 2679 if (CFGBlock *newBlock = Visit(Init)) 2680 LastBlock = newBlock; 2681 } 2682 } 2683 2684 // If the type of VD is a VLA, then we must process its size expressions. 2685 for (const VariableArrayType* VA = FindVA(VD->getType().getTypePtr()); 2686 VA != nullptr; VA = FindVA(VA->getElementType().getTypePtr())) { 2687 if (CFGBlock *newBlock = addStmt(VA->getSizeExpr())) 2688 LastBlock = newBlock; 2689 } 2690 2691 maybeAddScopeBeginForVarDecl(Block, VD, DS); 2692 2693 // Remove variable from local scope. 2694 if (ScopePos && VD == *ScopePos) 2695 ++ScopePos; 2696 2697 CFGBlock *B = LastBlock; 2698 if (blockAfterStaticInit) { 2699 Succ = B; 2700 Block = createBlock(false); 2701 Block->setTerminator(DS); 2702 addSuccessor(Block, blockAfterStaticInit); 2703 addSuccessor(Block, B); 2704 B = Block; 2705 } 2706 2707 return B; 2708 } 2709 2710 CFGBlock *CFGBuilder::VisitIfStmt(IfStmt *I) { 2711 // We may see an if statement in the middle of a basic block, or it may be the 2712 // first statement we are processing. In either case, we create a new basic 2713 // block. First, we create the blocks for the then...else statements, and 2714 // then we create the block containing the if statement. If we were in the 2715 // middle of a block, we stop processing that block. That block is then the 2716 // implicit successor for the "then" and "else" clauses. 2717 2718 // Save local scope position because in case of condition variable ScopePos 2719 // won't be restored when traversing AST. 2720 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 2721 2722 // Create local scope for C++17 if init-stmt if one exists. 2723 if (Stmt *Init = I->getInit()) 2724 addLocalScopeForStmt(Init); 2725 2726 // Create local scope for possible condition variable. 2727 // Store scope position. Add implicit destructor. 2728 if (VarDecl *VD = I->getConditionVariable()) 2729 addLocalScopeForVarDecl(VD); 2730 2731 addAutomaticObjHandling(ScopePos, save_scope_pos.get(), I); 2732 2733 // The block we were processing is now finished. Make it the successor 2734 // block. 2735 if (Block) { 2736 Succ = Block; 2737 if (badCFG) 2738 return nullptr; 2739 } 2740 2741 // Process the false branch. 2742 CFGBlock *ElseBlock = Succ; 2743 2744 if (Stmt *Else = I->getElse()) { 2745 SaveAndRestore<CFGBlock*> sv(Succ); 2746 2747 // NULL out Block so that the recursive call to Visit will 2748 // create a new basic block. 2749 Block = nullptr; 2750 2751 // If branch is not a compound statement create implicit scope 2752 // and add destructors. 2753 if (!isa<CompoundStmt>(Else)) 2754 addLocalScopeAndDtors(Else); 2755 2756 ElseBlock = addStmt(Else); 2757 2758 if (!ElseBlock) // Can occur when the Else body has all NullStmts. 2759 ElseBlock = sv.get(); 2760 else if (Block) { 2761 if (badCFG) 2762 return nullptr; 2763 } 2764 } 2765 2766 // Process the true branch. 2767 CFGBlock *ThenBlock; 2768 { 2769 Stmt *Then = I->getThen(); 2770 assert(Then); 2771 SaveAndRestore<CFGBlock*> sv(Succ); 2772 Block = nullptr; 2773 2774 // If branch is not a compound statement create implicit scope 2775 // and add destructors. 2776 if (!isa<CompoundStmt>(Then)) 2777 addLocalScopeAndDtors(Then); 2778 2779 ThenBlock = addStmt(Then); 2780 2781 if (!ThenBlock) { 2782 // We can reach here if the "then" body has all NullStmts. 2783 // Create an empty block so we can distinguish between true and false 2784 // branches in path-sensitive analyses. 2785 ThenBlock = createBlock(false); 2786 addSuccessor(ThenBlock, sv.get()); 2787 } else if (Block) { 2788 if (badCFG) 2789 return nullptr; 2790 } 2791 } 2792 2793 // Specially handle "if (expr1 || ...)" and "if (expr1 && ...)" by 2794 // having these handle the actual control-flow jump. Note that 2795 // if we introduce a condition variable, e.g. "if (int x = exp1 || exp2)" 2796 // we resort to the old control-flow behavior. This special handling 2797 // removes infeasible paths from the control-flow graph by having the 2798 // control-flow transfer of '&&' or '||' go directly into the then/else 2799 // blocks directly. 2800 BinaryOperator *Cond = 2801 I->getConditionVariable() 2802 ? nullptr 2803 : dyn_cast<BinaryOperator>(I->getCond()->IgnoreParens()); 2804 CFGBlock *LastBlock; 2805 if (Cond && Cond->isLogicalOp()) 2806 LastBlock = VisitLogicalOperator(Cond, I, ThenBlock, ElseBlock).first; 2807 else { 2808 // Now create a new block containing the if statement. 2809 Block = createBlock(false); 2810 2811 // Set the terminator of the new block to the If statement. 2812 Block->setTerminator(I); 2813 2814 // See if this is a known constant. 2815 const TryResult &KnownVal = tryEvaluateBool(I->getCond()); 2816 2817 // Add the successors. If we know that specific branches are 2818 // unreachable, inform addSuccessor() of that knowledge. 2819 addSuccessor(Block, ThenBlock, /* isReachable = */ !KnownVal.isFalse()); 2820 addSuccessor(Block, ElseBlock, /* isReachable = */ !KnownVal.isTrue()); 2821 2822 // Add the condition as the last statement in the new block. This may 2823 // create new blocks as the condition may contain control-flow. Any newly 2824 // created blocks will be pointed to be "Block". 2825 LastBlock = addStmt(I->getCond()); 2826 2827 // If the IfStmt contains a condition variable, add it and its 2828 // initializer to the CFG. 2829 if (const DeclStmt* DS = I->getConditionVariableDeclStmt()) { 2830 autoCreateBlock(); 2831 LastBlock = addStmt(const_cast<DeclStmt *>(DS)); 2832 } 2833 } 2834 2835 // Finally, if the IfStmt contains a C++17 init-stmt, add it to the CFG. 2836 if (Stmt *Init = I->getInit()) { 2837 autoCreateBlock(); 2838 LastBlock = addStmt(Init); 2839 } 2840 2841 return LastBlock; 2842 } 2843 2844 CFGBlock *CFGBuilder::VisitReturnStmt(ReturnStmt *R) { 2845 // If we were in the middle of a block we stop processing that block. 2846 // 2847 // NOTE: If a "return" appears in the middle of a block, this means that the 2848 // code afterwards is DEAD (unreachable). We still keep a basic block 2849 // for that code; a simple "mark-and-sweep" from the entry block will be 2850 // able to report such dead blocks. 2851 2852 // Create the new block. 2853 Block = createBlock(false); 2854 2855 addAutomaticObjHandling(ScopePos, LocalScope::const_iterator(), R); 2856 2857 findConstructionContexts( 2858 ConstructionContextLayer::create(cfg->getBumpVectorContext(), R), 2859 R->getRetValue()); 2860 2861 // If the one of the destructors does not return, we already have the Exit 2862 // block as a successor. 2863 if (!Block->hasNoReturnElement()) 2864 addSuccessor(Block, &cfg->getExit()); 2865 2866 // Add the return statement to the block. This may create new blocks if R 2867 // contains control-flow (short-circuit operations). 2868 return VisitStmt(R, AddStmtChoice::AlwaysAdd); 2869 } 2870 2871 CFGBlock *CFGBuilder::VisitSEHExceptStmt(SEHExceptStmt *ES) { 2872 // SEHExceptStmt are treated like labels, so they are the first statement in a 2873 // block. 2874 2875 // Save local scope position because in case of exception variable ScopePos 2876 // won't be restored when traversing AST. 2877 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 2878 2879 addStmt(ES->getBlock()); 2880 CFGBlock *SEHExceptBlock = Block; 2881 if (!SEHExceptBlock) 2882 SEHExceptBlock = createBlock(); 2883 2884 appendStmt(SEHExceptBlock, ES); 2885 2886 // Also add the SEHExceptBlock as a label, like with regular labels. 2887 SEHExceptBlock->setLabel(ES); 2888 2889 // Bail out if the CFG is bad. 2890 if (badCFG) 2891 return nullptr; 2892 2893 // We set Block to NULL to allow lazy creation of a new block (if necessary). 2894 Block = nullptr; 2895 2896 return SEHExceptBlock; 2897 } 2898 2899 CFGBlock *CFGBuilder::VisitSEHFinallyStmt(SEHFinallyStmt *FS) { 2900 return VisitCompoundStmt(FS->getBlock()); 2901 } 2902 2903 CFGBlock *CFGBuilder::VisitSEHLeaveStmt(SEHLeaveStmt *LS) { 2904 // "__leave" is a control-flow statement. Thus we stop processing the current 2905 // block. 2906 if (badCFG) 2907 return nullptr; 2908 2909 // Now create a new block that ends with the __leave statement. 2910 Block = createBlock(false); 2911 Block->setTerminator(LS); 2912 2913 // If there is no target for the __leave, then we are looking at an incomplete 2914 // AST. This means that the CFG cannot be constructed. 2915 if (SEHLeaveJumpTarget.block) { 2916 addAutomaticObjHandling(ScopePos, SEHLeaveJumpTarget.scopePosition, LS); 2917 addSuccessor(Block, SEHLeaveJumpTarget.block); 2918 } else 2919 badCFG = true; 2920 2921 return Block; 2922 } 2923 2924 CFGBlock *CFGBuilder::VisitSEHTryStmt(SEHTryStmt *Terminator) { 2925 // "__try"/"__except"/"__finally" is a control-flow statement. Thus we stop 2926 // processing the current block. 2927 CFGBlock *SEHTrySuccessor = nullptr; 2928 2929 if (Block) { 2930 if (badCFG) 2931 return nullptr; 2932 SEHTrySuccessor = Block; 2933 } else SEHTrySuccessor = Succ; 2934 2935 // FIXME: Implement __finally support. 2936 if (Terminator->getFinallyHandler()) 2937 return NYS(); 2938 2939 CFGBlock *PrevSEHTryTerminatedBlock = TryTerminatedBlock; 2940 2941 // Create a new block that will contain the __try statement. 2942 CFGBlock *NewTryTerminatedBlock = createBlock(false); 2943 2944 // Add the terminator in the __try block. 2945 NewTryTerminatedBlock->setTerminator(Terminator); 2946 2947 if (SEHExceptStmt *Except = Terminator->getExceptHandler()) { 2948 // The code after the try is the implicit successor if there's an __except. 2949 Succ = SEHTrySuccessor; 2950 Block = nullptr; 2951 CFGBlock *ExceptBlock = VisitSEHExceptStmt(Except); 2952 if (!ExceptBlock) 2953 return nullptr; 2954 // Add this block to the list of successors for the block with the try 2955 // statement. 2956 addSuccessor(NewTryTerminatedBlock, ExceptBlock); 2957 } 2958 if (PrevSEHTryTerminatedBlock) 2959 addSuccessor(NewTryTerminatedBlock, PrevSEHTryTerminatedBlock); 2960 else 2961 addSuccessor(NewTryTerminatedBlock, &cfg->getExit()); 2962 2963 // The code after the try is the implicit successor. 2964 Succ = SEHTrySuccessor; 2965 2966 // Save the current "__try" context. 2967 SaveAndRestore<CFGBlock *> save_try(TryTerminatedBlock, 2968 NewTryTerminatedBlock); 2969 cfg->addTryDispatchBlock(TryTerminatedBlock); 2970 2971 // Save the current value for the __leave target. 2972 // All __leaves should go to the code following the __try 2973 // (FIXME: or if the __try has a __finally, to the __finally.) 2974 SaveAndRestore<JumpTarget> save_break(SEHLeaveJumpTarget); 2975 SEHLeaveJumpTarget = JumpTarget(SEHTrySuccessor, ScopePos); 2976 2977 assert(Terminator->getTryBlock() && "__try must contain a non-NULL body"); 2978 Block = nullptr; 2979 return addStmt(Terminator->getTryBlock()); 2980 } 2981 2982 CFGBlock *CFGBuilder::VisitLabelStmt(LabelStmt *L) { 2983 // Get the block of the labeled statement. Add it to our map. 2984 addStmt(L->getSubStmt()); 2985 CFGBlock *LabelBlock = Block; 2986 2987 if (!LabelBlock) // This can happen when the body is empty, i.e. 2988 LabelBlock = createBlock(); // scopes that only contains NullStmts. 2989 2990 assert(LabelMap.find(L->getDecl()) == LabelMap.end() && 2991 "label already in map"); 2992 LabelMap[L->getDecl()] = JumpTarget(LabelBlock, ScopePos); 2993 2994 // Labels partition blocks, so this is the end of the basic block we were 2995 // processing (L is the block's label). Because this is label (and we have 2996 // already processed the substatement) there is no extra control-flow to worry 2997 // about. 2998 LabelBlock->setLabel(L); 2999 if (badCFG) 3000 return nullptr; 3001 3002 // We set Block to NULL to allow lazy creation of a new block (if necessary); 3003 Block = nullptr; 3004 3005 // This block is now the implicit successor of other blocks. 3006 Succ = LabelBlock; 3007 3008 return LabelBlock; 3009 } 3010 3011 CFGBlock *CFGBuilder::VisitBlockExpr(BlockExpr *E, AddStmtChoice asc) { 3012 CFGBlock *LastBlock = VisitNoRecurse(E, asc); 3013 for (const BlockDecl::Capture &CI : E->getBlockDecl()->captures()) { 3014 if (Expr *CopyExpr = CI.getCopyExpr()) { 3015 CFGBlock *Tmp = Visit(CopyExpr); 3016 if (Tmp) 3017 LastBlock = Tmp; 3018 } 3019 } 3020 return LastBlock; 3021 } 3022 3023 CFGBlock *CFGBuilder::VisitLambdaExpr(LambdaExpr *E, AddStmtChoice asc) { 3024 CFGBlock *LastBlock = VisitNoRecurse(E, asc); 3025 for (LambdaExpr::capture_init_iterator it = E->capture_init_begin(), 3026 et = E->capture_init_end(); it != et; ++it) { 3027 if (Expr *Init = *it) { 3028 CFGBlock *Tmp = Visit(Init); 3029 if (Tmp) 3030 LastBlock = Tmp; 3031 } 3032 } 3033 return LastBlock; 3034 } 3035 3036 CFGBlock *CFGBuilder::VisitGotoStmt(GotoStmt *G) { 3037 // Goto is a control-flow statement. Thus we stop processing the current 3038 // block and create a new one. 3039 3040 Block = createBlock(false); 3041 Block->setTerminator(G); 3042 3043 // If we already know the mapping to the label block add the successor now. 3044 LabelMapTy::iterator I = LabelMap.find(G->getLabel()); 3045 3046 if (I == LabelMap.end()) 3047 // We will need to backpatch this block later. 3048 BackpatchBlocks.push_back(JumpSource(Block, ScopePos)); 3049 else { 3050 JumpTarget JT = I->second; 3051 addAutomaticObjHandling(ScopePos, JT.scopePosition, G); 3052 addSuccessor(Block, JT.block); 3053 } 3054 3055 return Block; 3056 } 3057 3058 CFGBlock *CFGBuilder::VisitForStmt(ForStmt *F) { 3059 CFGBlock *LoopSuccessor = nullptr; 3060 3061 // Save local scope position because in case of condition variable ScopePos 3062 // won't be restored when traversing AST. 3063 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 3064 3065 // Create local scope for init statement and possible condition variable. 3066 // Add destructor for init statement and condition variable. 3067 // Store scope position for continue statement. 3068 if (Stmt *Init = F->getInit()) 3069 addLocalScopeForStmt(Init); 3070 LocalScope::const_iterator LoopBeginScopePos = ScopePos; 3071 3072 if (VarDecl *VD = F->getConditionVariable()) 3073 addLocalScopeForVarDecl(VD); 3074 LocalScope::const_iterator ContinueScopePos = ScopePos; 3075 3076 addAutomaticObjHandling(ScopePos, save_scope_pos.get(), F); 3077 3078 addLoopExit(F); 3079 3080 // "for" is a control-flow statement. Thus we stop processing the current 3081 // block. 3082 if (Block) { 3083 if (badCFG) 3084 return nullptr; 3085 LoopSuccessor = Block; 3086 } else 3087 LoopSuccessor = Succ; 3088 3089 // Save the current value for the break targets. 3090 // All breaks should go to the code following the loop. 3091 SaveAndRestore<JumpTarget> save_break(BreakJumpTarget); 3092 BreakJumpTarget = JumpTarget(LoopSuccessor, ScopePos); 3093 3094 CFGBlock *BodyBlock = nullptr, *TransitionBlock = nullptr; 3095 3096 // Now create the loop body. 3097 { 3098 assert(F->getBody()); 3099 3100 // Save the current values for Block, Succ, continue and break targets. 3101 SaveAndRestore<CFGBlock*> save_Block(Block), save_Succ(Succ); 3102 SaveAndRestore<JumpTarget> save_continue(ContinueJumpTarget); 3103 3104 // Create an empty block to represent the transition block for looping back 3105 // to the head of the loop. If we have increment code, it will 3106 // go in this block as well. 3107 Block = Succ = TransitionBlock = createBlock(false); 3108 TransitionBlock->setLoopTarget(F); 3109 3110 if (Stmt *I = F->getInc()) { 3111 // Generate increment code in its own basic block. This is the target of 3112 // continue statements. 3113 Succ = addStmt(I); 3114 } 3115 3116 // Finish up the increment (or empty) block if it hasn't been already. 3117 if (Block) { 3118 assert(Block == Succ); 3119 if (badCFG) 3120 return nullptr; 3121 Block = nullptr; 3122 } 3123 3124 // The starting block for the loop increment is the block that should 3125 // represent the 'loop target' for looping back to the start of the loop. 3126 ContinueJumpTarget = JumpTarget(Succ, ContinueScopePos); 3127 ContinueJumpTarget.block->setLoopTarget(F); 3128 3129 // Loop body should end with destructor of Condition variable (if any). 3130 addAutomaticObjHandling(ScopePos, LoopBeginScopePos, F); 3131 3132 // If body is not a compound statement create implicit scope 3133 // and add destructors. 3134 if (!isa<CompoundStmt>(F->getBody())) 3135 addLocalScopeAndDtors(F->getBody()); 3136 3137 // Now populate the body block, and in the process create new blocks as we 3138 // walk the body of the loop. 3139 BodyBlock = addStmt(F->getBody()); 3140 3141 if (!BodyBlock) { 3142 // In the case of "for (...;...;...);" we can have a null BodyBlock. 3143 // Use the continue jump target as the proxy for the body. 3144 BodyBlock = ContinueJumpTarget.block; 3145 } 3146 else if (badCFG) 3147 return nullptr; 3148 } 3149 3150 // Because of short-circuit evaluation, the condition of the loop can span 3151 // multiple basic blocks. Thus we need the "Entry" and "Exit" blocks that 3152 // evaluate the condition. 3153 CFGBlock *EntryConditionBlock = nullptr, *ExitConditionBlock = nullptr; 3154 3155 do { 3156 Expr *C = F->getCond(); 3157 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 3158 3159 // Specially handle logical operators, which have a slightly 3160 // more optimal CFG representation. 3161 if (BinaryOperator *Cond = 3162 dyn_cast_or_null<BinaryOperator>(C ? C->IgnoreParens() : nullptr)) 3163 if (Cond->isLogicalOp()) { 3164 std::tie(EntryConditionBlock, ExitConditionBlock) = 3165 VisitLogicalOperator(Cond, F, BodyBlock, LoopSuccessor); 3166 break; 3167 } 3168 3169 // The default case when not handling logical operators. 3170 EntryConditionBlock = ExitConditionBlock = createBlock(false); 3171 ExitConditionBlock->setTerminator(F); 3172 3173 // See if this is a known constant. 3174 TryResult KnownVal(true); 3175 3176 if (C) { 3177 // Now add the actual condition to the condition block. 3178 // Because the condition itself may contain control-flow, new blocks may 3179 // be created. Thus we update "Succ" after adding the condition. 3180 Block = ExitConditionBlock; 3181 EntryConditionBlock = addStmt(C); 3182 3183 // If this block contains a condition variable, add both the condition 3184 // variable and initializer to the CFG. 3185 if (VarDecl *VD = F->getConditionVariable()) { 3186 if (Expr *Init = VD->getInit()) { 3187 autoCreateBlock(); 3188 const DeclStmt *DS = F->getConditionVariableDeclStmt(); 3189 assert(DS->isSingleDecl()); 3190 findConstructionContexts( 3191 ConstructionContextLayer::create(cfg->getBumpVectorContext(), 3192 const_cast<DeclStmt *>(DS)), 3193 Init); 3194 appendStmt(Block, DS); 3195 EntryConditionBlock = addStmt(Init); 3196 assert(Block == EntryConditionBlock); 3197 maybeAddScopeBeginForVarDecl(EntryConditionBlock, VD, C); 3198 } 3199 } 3200 3201 if (Block && badCFG) 3202 return nullptr; 3203 3204 KnownVal = tryEvaluateBool(C); 3205 } 3206 3207 // Add the loop body entry as a successor to the condition. 3208 addSuccessor(ExitConditionBlock, KnownVal.isFalse() ? nullptr : BodyBlock); 3209 // Link up the condition block with the code that follows the loop. (the 3210 // false branch). 3211 addSuccessor(ExitConditionBlock, 3212 KnownVal.isTrue() ? nullptr : LoopSuccessor); 3213 } while (false); 3214 3215 // Link up the loop-back block to the entry condition block. 3216 addSuccessor(TransitionBlock, EntryConditionBlock); 3217 3218 // The condition block is the implicit successor for any code above the loop. 3219 Succ = EntryConditionBlock; 3220 3221 // If the loop contains initialization, create a new block for those 3222 // statements. This block can also contain statements that precede the loop. 3223 if (Stmt *I = F->getInit()) { 3224 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 3225 ScopePos = LoopBeginScopePos; 3226 Block = createBlock(); 3227 return addStmt(I); 3228 } 3229 3230 // There is no loop initialization. We are thus basically a while loop. 3231 // NULL out Block to force lazy block construction. 3232 Block = nullptr; 3233 Succ = EntryConditionBlock; 3234 return EntryConditionBlock; 3235 } 3236 3237 CFGBlock * 3238 CFGBuilder::VisitMaterializeTemporaryExpr(MaterializeTemporaryExpr *MTE, 3239 AddStmtChoice asc) { 3240 findConstructionContexts( 3241 ConstructionContextLayer::create(cfg->getBumpVectorContext(), MTE), 3242 MTE->getTemporary()); 3243 3244 return VisitStmt(MTE, asc); 3245 } 3246 3247 CFGBlock *CFGBuilder::VisitMemberExpr(MemberExpr *M, AddStmtChoice asc) { 3248 if (asc.alwaysAdd(*this, M)) { 3249 autoCreateBlock(); 3250 appendStmt(Block, M); 3251 } 3252 return Visit(M->getBase()); 3253 } 3254 3255 CFGBlock *CFGBuilder::VisitObjCForCollectionStmt(ObjCForCollectionStmt *S) { 3256 // Objective-C fast enumeration 'for' statements: 3257 // http://developer.apple.com/documentation/Cocoa/Conceptual/ObjectiveC 3258 // 3259 // for ( Type newVariable in collection_expression ) { statements } 3260 // 3261 // becomes: 3262 // 3263 // prologue: 3264 // 1. collection_expression 3265 // T. jump to loop_entry 3266 // loop_entry: 3267 // 1. side-effects of element expression 3268 // 1. ObjCForCollectionStmt [performs binding to newVariable] 3269 // T. ObjCForCollectionStmt TB, FB [jumps to TB if newVariable != nil] 3270 // TB: 3271 // statements 3272 // T. jump to loop_entry 3273 // FB: 3274 // what comes after 3275 // 3276 // and 3277 // 3278 // Type existingItem; 3279 // for ( existingItem in expression ) { statements } 3280 // 3281 // becomes: 3282 // 3283 // the same with newVariable replaced with existingItem; the binding works 3284 // the same except that for one ObjCForCollectionStmt::getElement() returns 3285 // a DeclStmt and the other returns a DeclRefExpr. 3286 3287 CFGBlock *LoopSuccessor = nullptr; 3288 3289 if (Block) { 3290 if (badCFG) 3291 return nullptr; 3292 LoopSuccessor = Block; 3293 Block = nullptr; 3294 } else 3295 LoopSuccessor = Succ; 3296 3297 // Build the condition blocks. 3298 CFGBlock *ExitConditionBlock = createBlock(false); 3299 3300 // Set the terminator for the "exit" condition block. 3301 ExitConditionBlock->setTerminator(S); 3302 3303 // The last statement in the block should be the ObjCForCollectionStmt, which 3304 // performs the actual binding to 'element' and determines if there are any 3305 // more items in the collection. 3306 appendStmt(ExitConditionBlock, S); 3307 Block = ExitConditionBlock; 3308 3309 // Walk the 'element' expression to see if there are any side-effects. We 3310 // generate new blocks as necessary. We DON'T add the statement by default to 3311 // the CFG unless it contains control-flow. 3312 CFGBlock *EntryConditionBlock = Visit(S->getElement(), 3313 AddStmtChoice::NotAlwaysAdd); 3314 if (Block) { 3315 if (badCFG) 3316 return nullptr; 3317 Block = nullptr; 3318 } 3319 3320 // The condition block is the implicit successor for the loop body as well as 3321 // any code above the loop. 3322 Succ = EntryConditionBlock; 3323 3324 // Now create the true branch. 3325 { 3326 // Save the current values for Succ, continue and break targets. 3327 SaveAndRestore<CFGBlock*> save_Block(Block), save_Succ(Succ); 3328 SaveAndRestore<JumpTarget> save_continue(ContinueJumpTarget), 3329 save_break(BreakJumpTarget); 3330 3331 // Add an intermediate block between the BodyBlock and the 3332 // EntryConditionBlock to represent the "loop back" transition, for looping 3333 // back to the head of the loop. 3334 CFGBlock *LoopBackBlock = nullptr; 3335 Succ = LoopBackBlock = createBlock(); 3336 LoopBackBlock->setLoopTarget(S); 3337 3338 BreakJumpTarget = JumpTarget(LoopSuccessor, ScopePos); 3339 ContinueJumpTarget = JumpTarget(Succ, ScopePos); 3340 3341 CFGBlock *BodyBlock = addStmt(S->getBody()); 3342 3343 if (!BodyBlock) 3344 BodyBlock = ContinueJumpTarget.block; // can happen for "for (X in Y) ;" 3345 else if (Block) { 3346 if (badCFG) 3347 return nullptr; 3348 } 3349 3350 // This new body block is a successor to our "exit" condition block. 3351 addSuccessor(ExitConditionBlock, BodyBlock); 3352 } 3353 3354 // Link up the condition block with the code that follows the loop. 3355 // (the false branch). 3356 addSuccessor(ExitConditionBlock, LoopSuccessor); 3357 3358 // Now create a prologue block to contain the collection expression. 3359 Block = createBlock(); 3360 return addStmt(S->getCollection()); 3361 } 3362 3363 CFGBlock *CFGBuilder::VisitObjCAutoreleasePoolStmt(ObjCAutoreleasePoolStmt *S) { 3364 // Inline the body. 3365 return addStmt(S->getSubStmt()); 3366 // TODO: consider adding cleanups for the end of @autoreleasepool scope. 3367 } 3368 3369 CFGBlock *CFGBuilder::VisitObjCAtSynchronizedStmt(ObjCAtSynchronizedStmt *S) { 3370 // FIXME: Add locking 'primitives' to CFG for @synchronized. 3371 3372 // Inline the body. 3373 CFGBlock *SyncBlock = addStmt(S->getSynchBody()); 3374 3375 // The sync body starts its own basic block. This makes it a little easier 3376 // for diagnostic clients. 3377 if (SyncBlock) { 3378 if (badCFG) 3379 return nullptr; 3380 3381 Block = nullptr; 3382 Succ = SyncBlock; 3383 } 3384 3385 // Add the @synchronized to the CFG. 3386 autoCreateBlock(); 3387 appendStmt(Block, S); 3388 3389 // Inline the sync expression. 3390 return addStmt(S->getSynchExpr()); 3391 } 3392 3393 CFGBlock *CFGBuilder::VisitObjCAtTryStmt(ObjCAtTryStmt *S) { 3394 // FIXME 3395 return NYS(); 3396 } 3397 3398 CFGBlock *CFGBuilder::VisitPseudoObjectExpr(PseudoObjectExpr *E) { 3399 autoCreateBlock(); 3400 3401 // Add the PseudoObject as the last thing. 3402 appendStmt(Block, E); 3403 3404 CFGBlock *lastBlock = Block; 3405 3406 // Before that, evaluate all of the semantics in order. In 3407 // CFG-land, that means appending them in reverse order. 3408 for (unsigned i = E->getNumSemanticExprs(); i != 0; ) { 3409 Expr *Semantic = E->getSemanticExpr(--i); 3410 3411 // If the semantic is an opaque value, we're being asked to bind 3412 // it to its source expression. 3413 if (OpaqueValueExpr *OVE = dyn_cast<OpaqueValueExpr>(Semantic)) 3414 Semantic = OVE->getSourceExpr(); 3415 3416 if (CFGBlock *B = Visit(Semantic)) 3417 lastBlock = B; 3418 } 3419 3420 return lastBlock; 3421 } 3422 3423 CFGBlock *CFGBuilder::VisitWhileStmt(WhileStmt *W) { 3424 CFGBlock *LoopSuccessor = nullptr; 3425 3426 // Save local scope position because in case of condition variable ScopePos 3427 // won't be restored when traversing AST. 3428 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 3429 3430 // Create local scope for possible condition variable. 3431 // Store scope position for continue statement. 3432 LocalScope::const_iterator LoopBeginScopePos = ScopePos; 3433 if (VarDecl *VD = W->getConditionVariable()) { 3434 addLocalScopeForVarDecl(VD); 3435 addAutomaticObjHandling(ScopePos, LoopBeginScopePos, W); 3436 } 3437 addLoopExit(W); 3438 3439 // "while" is a control-flow statement. Thus we stop processing the current 3440 // block. 3441 if (Block) { 3442 if (badCFG) 3443 return nullptr; 3444 LoopSuccessor = Block; 3445 Block = nullptr; 3446 } else { 3447 LoopSuccessor = Succ; 3448 } 3449 3450 CFGBlock *BodyBlock = nullptr, *TransitionBlock = nullptr; 3451 3452 // Process the loop body. 3453 { 3454 assert(W->getBody()); 3455 3456 // Save the current values for Block, Succ, continue and break targets. 3457 SaveAndRestore<CFGBlock*> save_Block(Block), save_Succ(Succ); 3458 SaveAndRestore<JumpTarget> save_continue(ContinueJumpTarget), 3459 save_break(BreakJumpTarget); 3460 3461 // Create an empty block to represent the transition block for looping back 3462 // to the head of the loop. 3463 Succ = TransitionBlock = createBlock(false); 3464 TransitionBlock->setLoopTarget(W); 3465 ContinueJumpTarget = JumpTarget(Succ, LoopBeginScopePos); 3466 3467 // All breaks should go to the code following the loop. 3468 BreakJumpTarget = JumpTarget(LoopSuccessor, ScopePos); 3469 3470 // Loop body should end with destructor of Condition variable (if any). 3471 addAutomaticObjHandling(ScopePos, LoopBeginScopePos, W); 3472 3473 // If body is not a compound statement create implicit scope 3474 // and add destructors. 3475 if (!isa<CompoundStmt>(W->getBody())) 3476 addLocalScopeAndDtors(W->getBody()); 3477 3478 // Create the body. The returned block is the entry to the loop body. 3479 BodyBlock = addStmt(W->getBody()); 3480 3481 if (!BodyBlock) 3482 BodyBlock = ContinueJumpTarget.block; // can happen for "while(...) ;" 3483 else if (Block && badCFG) 3484 return nullptr; 3485 } 3486 3487 // Because of short-circuit evaluation, the condition of the loop can span 3488 // multiple basic blocks. Thus we need the "Entry" and "Exit" blocks that 3489 // evaluate the condition. 3490 CFGBlock *EntryConditionBlock = nullptr, *ExitConditionBlock = nullptr; 3491 3492 do { 3493 Expr *C = W->getCond(); 3494 3495 // Specially handle logical operators, which have a slightly 3496 // more optimal CFG representation. 3497 if (BinaryOperator *Cond = dyn_cast<BinaryOperator>(C->IgnoreParens())) 3498 if (Cond->isLogicalOp()) { 3499 std::tie(EntryConditionBlock, ExitConditionBlock) = 3500 VisitLogicalOperator(Cond, W, BodyBlock, LoopSuccessor); 3501 break; 3502 } 3503 3504 // The default case when not handling logical operators. 3505 ExitConditionBlock = createBlock(false); 3506 ExitConditionBlock->setTerminator(W); 3507 3508 // Now add the actual condition to the condition block. 3509 // Because the condition itself may contain control-flow, new blocks may 3510 // be created. Thus we update "Succ" after adding the condition. 3511 Block = ExitConditionBlock; 3512 Block = EntryConditionBlock = addStmt(C); 3513 3514 // If this block contains a condition variable, add both the condition 3515 // variable and initializer to the CFG. 3516 if (VarDecl *VD = W->getConditionVariable()) { 3517 if (Expr *Init = VD->getInit()) { 3518 autoCreateBlock(); 3519 const DeclStmt *DS = W->getConditionVariableDeclStmt(); 3520 assert(DS->isSingleDecl()); 3521 findConstructionContexts( 3522 ConstructionContextLayer::create(cfg->getBumpVectorContext(), 3523 const_cast<DeclStmt *>(DS)), 3524 Init); 3525 appendStmt(Block, DS); 3526 EntryConditionBlock = addStmt(Init); 3527 assert(Block == EntryConditionBlock); 3528 maybeAddScopeBeginForVarDecl(EntryConditionBlock, VD, C); 3529 } 3530 } 3531 3532 if (Block && badCFG) 3533 return nullptr; 3534 3535 // See if this is a known constant. 3536 const TryResult& KnownVal = tryEvaluateBool(C); 3537 3538 // Add the loop body entry as a successor to the condition. 3539 addSuccessor(ExitConditionBlock, KnownVal.isFalse() ? nullptr : BodyBlock); 3540 // Link up the condition block with the code that follows the loop. (the 3541 // false branch). 3542 addSuccessor(ExitConditionBlock, 3543 KnownVal.isTrue() ? nullptr : LoopSuccessor); 3544 } while(false); 3545 3546 // Link up the loop-back block to the entry condition block. 3547 addSuccessor(TransitionBlock, EntryConditionBlock); 3548 3549 // There can be no more statements in the condition block since we loop back 3550 // to this block. NULL out Block to force lazy creation of another block. 3551 Block = nullptr; 3552 3553 // Return the condition block, which is the dominating block for the loop. 3554 Succ = EntryConditionBlock; 3555 return EntryConditionBlock; 3556 } 3557 3558 CFGBlock *CFGBuilder::VisitObjCAtCatchStmt(ObjCAtCatchStmt *S) { 3559 // FIXME: For now we pretend that @catch and the code it contains does not 3560 // exit. 3561 return Block; 3562 } 3563 3564 CFGBlock *CFGBuilder::VisitObjCAtThrowStmt(ObjCAtThrowStmt *S) { 3565 // FIXME: This isn't complete. We basically treat @throw like a return 3566 // statement. 3567 3568 // If we were in the middle of a block we stop processing that block. 3569 if (badCFG) 3570 return nullptr; 3571 3572 // Create the new block. 3573 Block = createBlock(false); 3574 3575 // The Exit block is the only successor. 3576 addSuccessor(Block, &cfg->getExit()); 3577 3578 // Add the statement to the block. This may create new blocks if S contains 3579 // control-flow (short-circuit operations). 3580 return VisitStmt(S, AddStmtChoice::AlwaysAdd); 3581 } 3582 3583 CFGBlock *CFGBuilder::VisitCXXThrowExpr(CXXThrowExpr *T) { 3584 // If we were in the middle of a block we stop processing that block. 3585 if (badCFG) 3586 return nullptr; 3587 3588 // Create the new block. 3589 Block = createBlock(false); 3590 3591 if (TryTerminatedBlock) 3592 // The current try statement is the only successor. 3593 addSuccessor(Block, TryTerminatedBlock); 3594 else 3595 // otherwise the Exit block is the only successor. 3596 addSuccessor(Block, &cfg->getExit()); 3597 3598 // Add the statement to the block. This may create new blocks if S contains 3599 // control-flow (short-circuit operations). 3600 return VisitStmt(T, AddStmtChoice::AlwaysAdd); 3601 } 3602 3603 CFGBlock *CFGBuilder::VisitDoStmt(DoStmt *D) { 3604 CFGBlock *LoopSuccessor = nullptr; 3605 3606 addLoopExit(D); 3607 3608 // "do...while" is a control-flow statement. Thus we stop processing the 3609 // current block. 3610 if (Block) { 3611 if (badCFG) 3612 return nullptr; 3613 LoopSuccessor = Block; 3614 } else 3615 LoopSuccessor = Succ; 3616 3617 // Because of short-circuit evaluation, the condition of the loop can span 3618 // multiple basic blocks. Thus we need the "Entry" and "Exit" blocks that 3619 // evaluate the condition. 3620 CFGBlock *ExitConditionBlock = createBlock(false); 3621 CFGBlock *EntryConditionBlock = ExitConditionBlock; 3622 3623 // Set the terminator for the "exit" condition block. 3624 ExitConditionBlock->setTerminator(D); 3625 3626 // Now add the actual condition to the condition block. Because the condition 3627 // itself may contain control-flow, new blocks may be created. 3628 if (Stmt *C = D->getCond()) { 3629 Block = ExitConditionBlock; 3630 EntryConditionBlock = addStmt(C); 3631 if (Block) { 3632 if (badCFG) 3633 return nullptr; 3634 } 3635 } 3636 3637 // The condition block is the implicit successor for the loop body. 3638 Succ = EntryConditionBlock; 3639 3640 // See if this is a known constant. 3641 const TryResult &KnownVal = tryEvaluateBool(D->getCond()); 3642 3643 // Process the loop body. 3644 CFGBlock *BodyBlock = nullptr; 3645 { 3646 assert(D->getBody()); 3647 3648 // Save the current values for Block, Succ, and continue and break targets 3649 SaveAndRestore<CFGBlock*> save_Block(Block), save_Succ(Succ); 3650 SaveAndRestore<JumpTarget> save_continue(ContinueJumpTarget), 3651 save_break(BreakJumpTarget); 3652 3653 // All continues within this loop should go to the condition block 3654 ContinueJumpTarget = JumpTarget(EntryConditionBlock, ScopePos); 3655 3656 // All breaks should go to the code following the loop. 3657 BreakJumpTarget = JumpTarget(LoopSuccessor, ScopePos); 3658 3659 // NULL out Block to force lazy instantiation of blocks for the body. 3660 Block = nullptr; 3661 3662 // If body is not a compound statement create implicit scope 3663 // and add destructors. 3664 if (!isa<CompoundStmt>(D->getBody())) 3665 addLocalScopeAndDtors(D->getBody()); 3666 3667 // Create the body. The returned block is the entry to the loop body. 3668 BodyBlock = addStmt(D->getBody()); 3669 3670 if (!BodyBlock) 3671 BodyBlock = EntryConditionBlock; // can happen for "do ; while(...)" 3672 else if (Block) { 3673 if (badCFG) 3674 return nullptr; 3675 } 3676 3677 // Add an intermediate block between the BodyBlock and the 3678 // ExitConditionBlock to represent the "loop back" transition. Create an 3679 // empty block to represent the transition block for looping back to the 3680 // head of the loop. 3681 // FIXME: Can we do this more efficiently without adding another block? 3682 Block = nullptr; 3683 Succ = BodyBlock; 3684 CFGBlock *LoopBackBlock = createBlock(); 3685 LoopBackBlock->setLoopTarget(D); 3686 3687 if (!KnownVal.isFalse()) 3688 // Add the loop body entry as a successor to the condition. 3689 addSuccessor(ExitConditionBlock, LoopBackBlock); 3690 else 3691 addSuccessor(ExitConditionBlock, nullptr); 3692 } 3693 3694 // Link up the condition block with the code that follows the loop. 3695 // (the false branch). 3696 addSuccessor(ExitConditionBlock, KnownVal.isTrue() ? nullptr : LoopSuccessor); 3697 3698 // There can be no more statements in the body block(s) since we loop back to 3699 // the body. NULL out Block to force lazy creation of another block. 3700 Block = nullptr; 3701 3702 // Return the loop body, which is the dominating block for the loop. 3703 Succ = BodyBlock; 3704 return BodyBlock; 3705 } 3706 3707 CFGBlock *CFGBuilder::VisitContinueStmt(ContinueStmt *C) { 3708 // "continue" is a control-flow statement. Thus we stop processing the 3709 // current block. 3710 if (badCFG) 3711 return nullptr; 3712 3713 // Now create a new block that ends with the continue statement. 3714 Block = createBlock(false); 3715 Block->setTerminator(C); 3716 3717 // If there is no target for the continue, then we are looking at an 3718 // incomplete AST. This means the CFG cannot be constructed. 3719 if (ContinueJumpTarget.block) { 3720 addAutomaticObjHandling(ScopePos, ContinueJumpTarget.scopePosition, C); 3721 addSuccessor(Block, ContinueJumpTarget.block); 3722 } else 3723 badCFG = true; 3724 3725 return Block; 3726 } 3727 3728 CFGBlock *CFGBuilder::VisitUnaryExprOrTypeTraitExpr(UnaryExprOrTypeTraitExpr *E, 3729 AddStmtChoice asc) { 3730 if (asc.alwaysAdd(*this, E)) { 3731 autoCreateBlock(); 3732 appendStmt(Block, E); 3733 } 3734 3735 // VLA types have expressions that must be evaluated. 3736 CFGBlock *lastBlock = Block; 3737 3738 if (E->isArgumentType()) { 3739 for (const VariableArrayType *VA =FindVA(E->getArgumentType().getTypePtr()); 3740 VA != nullptr; VA = FindVA(VA->getElementType().getTypePtr())) 3741 lastBlock = addStmt(VA->getSizeExpr()); 3742 } 3743 return lastBlock; 3744 } 3745 3746 /// VisitStmtExpr - Utility method to handle (nested) statement 3747 /// expressions (a GCC extension). 3748 CFGBlock *CFGBuilder::VisitStmtExpr(StmtExpr *SE, AddStmtChoice asc) { 3749 if (asc.alwaysAdd(*this, SE)) { 3750 autoCreateBlock(); 3751 appendStmt(Block, SE); 3752 } 3753 return VisitCompoundStmt(SE->getSubStmt()); 3754 } 3755 3756 CFGBlock *CFGBuilder::VisitSwitchStmt(SwitchStmt *Terminator) { 3757 // "switch" is a control-flow statement. Thus we stop processing the current 3758 // block. 3759 CFGBlock *SwitchSuccessor = nullptr; 3760 3761 // Save local scope position because in case of condition variable ScopePos 3762 // won't be restored when traversing AST. 3763 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 3764 3765 // Create local scope for C++17 switch init-stmt if one exists. 3766 if (Stmt *Init = Terminator->getInit()) 3767 addLocalScopeForStmt(Init); 3768 3769 // Create local scope for possible condition variable. 3770 // Store scope position. Add implicit destructor. 3771 if (VarDecl *VD = Terminator->getConditionVariable()) 3772 addLocalScopeForVarDecl(VD); 3773 3774 addAutomaticObjHandling(ScopePos, save_scope_pos.get(), Terminator); 3775 3776 if (Block) { 3777 if (badCFG) 3778 return nullptr; 3779 SwitchSuccessor = Block; 3780 } else SwitchSuccessor = Succ; 3781 3782 // Save the current "switch" context. 3783 SaveAndRestore<CFGBlock*> save_switch(SwitchTerminatedBlock), 3784 save_default(DefaultCaseBlock); 3785 SaveAndRestore<JumpTarget> save_break(BreakJumpTarget); 3786 3787 // Set the "default" case to be the block after the switch statement. If the 3788 // switch statement contains a "default:", this value will be overwritten with 3789 // the block for that code. 3790 DefaultCaseBlock = SwitchSuccessor; 3791 3792 // Create a new block that will contain the switch statement. 3793 SwitchTerminatedBlock = createBlock(false); 3794 3795 // Now process the switch body. The code after the switch is the implicit 3796 // successor. 3797 Succ = SwitchSuccessor; 3798 BreakJumpTarget = JumpTarget(SwitchSuccessor, ScopePos); 3799 3800 // When visiting the body, the case statements should automatically get linked 3801 // up to the switch. We also don't keep a pointer to the body, since all 3802 // control-flow from the switch goes to case/default statements. 3803 assert(Terminator->getBody() && "switch must contain a non-NULL body"); 3804 Block = nullptr; 3805 3806 // For pruning unreachable case statements, save the current state 3807 // for tracking the condition value. 3808 SaveAndRestore<bool> save_switchExclusivelyCovered(switchExclusivelyCovered, 3809 false); 3810 3811 // Determine if the switch condition can be explicitly evaluated. 3812 assert(Terminator->getCond() && "switch condition must be non-NULL"); 3813 Expr::EvalResult result; 3814 bool b = tryEvaluate(Terminator->getCond(), result); 3815 SaveAndRestore<Expr::EvalResult*> save_switchCond(switchCond, 3816 b ? &result : nullptr); 3817 3818 // If body is not a compound statement create implicit scope 3819 // and add destructors. 3820 if (!isa<CompoundStmt>(Terminator->getBody())) 3821 addLocalScopeAndDtors(Terminator->getBody()); 3822 3823 addStmt(Terminator->getBody()); 3824 if (Block) { 3825 if (badCFG) 3826 return nullptr; 3827 } 3828 3829 // If we have no "default:" case, the default transition is to the code 3830 // following the switch body. Moreover, take into account if all the 3831 // cases of a switch are covered (e.g., switching on an enum value). 3832 // 3833 // Note: We add a successor to a switch that is considered covered yet has no 3834 // case statements if the enumeration has no enumerators. 3835 bool SwitchAlwaysHasSuccessor = false; 3836 SwitchAlwaysHasSuccessor |= switchExclusivelyCovered; 3837 SwitchAlwaysHasSuccessor |= Terminator->isAllEnumCasesCovered() && 3838 Terminator->getSwitchCaseList(); 3839 addSuccessor(SwitchTerminatedBlock, DefaultCaseBlock, 3840 !SwitchAlwaysHasSuccessor); 3841 3842 // Add the terminator and condition in the switch block. 3843 SwitchTerminatedBlock->setTerminator(Terminator); 3844 Block = SwitchTerminatedBlock; 3845 CFGBlock *LastBlock = addStmt(Terminator->getCond()); 3846 3847 // If the SwitchStmt contains a condition variable, add both the 3848 // SwitchStmt and the condition variable initialization to the CFG. 3849 if (VarDecl *VD = Terminator->getConditionVariable()) { 3850 if (Expr *Init = VD->getInit()) { 3851 autoCreateBlock(); 3852 appendStmt(Block, Terminator->getConditionVariableDeclStmt()); 3853 LastBlock = addStmt(Init); 3854 maybeAddScopeBeginForVarDecl(LastBlock, VD, Init); 3855 } 3856 } 3857 3858 // Finally, if the SwitchStmt contains a C++17 init-stmt, add it to the CFG. 3859 if (Stmt *Init = Terminator->getInit()) { 3860 autoCreateBlock(); 3861 LastBlock = addStmt(Init); 3862 } 3863 3864 return LastBlock; 3865 } 3866 3867 static bool shouldAddCase(bool &switchExclusivelyCovered, 3868 const Expr::EvalResult *switchCond, 3869 const CaseStmt *CS, 3870 ASTContext &Ctx) { 3871 if (!switchCond) 3872 return true; 3873 3874 bool addCase = false; 3875 3876 if (!switchExclusivelyCovered) { 3877 if (switchCond->Val.isInt()) { 3878 // Evaluate the LHS of the case value. 3879 const llvm::APSInt &lhsInt = CS->getLHS()->EvaluateKnownConstInt(Ctx); 3880 const llvm::APSInt &condInt = switchCond->Val.getInt(); 3881 3882 if (condInt == lhsInt) { 3883 addCase = true; 3884 switchExclusivelyCovered = true; 3885 } 3886 else if (condInt > lhsInt) { 3887 if (const Expr *RHS = CS->getRHS()) { 3888 // Evaluate the RHS of the case value. 3889 const llvm::APSInt &V2 = RHS->EvaluateKnownConstInt(Ctx); 3890 if (V2 >= condInt) { 3891 addCase = true; 3892 switchExclusivelyCovered = true; 3893 } 3894 } 3895 } 3896 } 3897 else 3898 addCase = true; 3899 } 3900 return addCase; 3901 } 3902 3903 CFGBlock *CFGBuilder::VisitCaseStmt(CaseStmt *CS) { 3904 // CaseStmts are essentially labels, so they are the first statement in a 3905 // block. 3906 CFGBlock *TopBlock = nullptr, *LastBlock = nullptr; 3907 3908 if (Stmt *Sub = CS->getSubStmt()) { 3909 // For deeply nested chains of CaseStmts, instead of doing a recursion 3910 // (which can blow out the stack), manually unroll and create blocks 3911 // along the way. 3912 while (isa<CaseStmt>(Sub)) { 3913 CFGBlock *currentBlock = createBlock(false); 3914 currentBlock->setLabel(CS); 3915 3916 if (TopBlock) 3917 addSuccessor(LastBlock, currentBlock); 3918 else 3919 TopBlock = currentBlock; 3920 3921 addSuccessor(SwitchTerminatedBlock, 3922 shouldAddCase(switchExclusivelyCovered, switchCond, 3923 CS, *Context) 3924 ? currentBlock : nullptr); 3925 3926 LastBlock = currentBlock; 3927 CS = cast<CaseStmt>(Sub); 3928 Sub = CS->getSubStmt(); 3929 } 3930 3931 addStmt(Sub); 3932 } 3933 3934 CFGBlock *CaseBlock = Block; 3935 if (!CaseBlock) 3936 CaseBlock = createBlock(); 3937 3938 // Cases statements partition blocks, so this is the top of the basic block we 3939 // were processing (the "case XXX:" is the label). 3940 CaseBlock->setLabel(CS); 3941 3942 if (badCFG) 3943 return nullptr; 3944 3945 // Add this block to the list of successors for the block with the switch 3946 // statement. 3947 assert(SwitchTerminatedBlock); 3948 addSuccessor(SwitchTerminatedBlock, CaseBlock, 3949 shouldAddCase(switchExclusivelyCovered, switchCond, 3950 CS, *Context)); 3951 3952 // We set Block to NULL to allow lazy creation of a new block (if necessary) 3953 Block = nullptr; 3954 3955 if (TopBlock) { 3956 addSuccessor(LastBlock, CaseBlock); 3957 Succ = TopBlock; 3958 } else { 3959 // This block is now the implicit successor of other blocks. 3960 Succ = CaseBlock; 3961 } 3962 3963 return Succ; 3964 } 3965 3966 CFGBlock *CFGBuilder::VisitDefaultStmt(DefaultStmt *Terminator) { 3967 if (Terminator->getSubStmt()) 3968 addStmt(Terminator->getSubStmt()); 3969 3970 DefaultCaseBlock = Block; 3971 3972 if (!DefaultCaseBlock) 3973 DefaultCaseBlock = createBlock(); 3974 3975 // Default statements partition blocks, so this is the top of the basic block 3976 // we were processing (the "default:" is the label). 3977 DefaultCaseBlock->setLabel(Terminator); 3978 3979 if (badCFG) 3980 return nullptr; 3981 3982 // Unlike case statements, we don't add the default block to the successors 3983 // for the switch statement immediately. This is done when we finish 3984 // processing the switch statement. This allows for the default case 3985 // (including a fall-through to the code after the switch statement) to always 3986 // be the last successor of a switch-terminated block. 3987 3988 // We set Block to NULL to allow lazy creation of a new block (if necessary) 3989 Block = nullptr; 3990 3991 // This block is now the implicit successor of other blocks. 3992 Succ = DefaultCaseBlock; 3993 3994 return DefaultCaseBlock; 3995 } 3996 3997 CFGBlock *CFGBuilder::VisitCXXTryStmt(CXXTryStmt *Terminator) { 3998 // "try"/"catch" is a control-flow statement. Thus we stop processing the 3999 // current block. 4000 CFGBlock *TrySuccessor = nullptr; 4001 4002 if (Block) { 4003 if (badCFG) 4004 return nullptr; 4005 TrySuccessor = Block; 4006 } else TrySuccessor = Succ; 4007 4008 CFGBlock *PrevTryTerminatedBlock = TryTerminatedBlock; 4009 4010 // Create a new block that will contain the try statement. 4011 CFGBlock *NewTryTerminatedBlock = createBlock(false); 4012 // Add the terminator in the try block. 4013 NewTryTerminatedBlock->setTerminator(Terminator); 4014 4015 bool HasCatchAll = false; 4016 for (unsigned h = 0; h <Terminator->getNumHandlers(); ++h) { 4017 // The code after the try is the implicit successor. 4018 Succ = TrySuccessor; 4019 CXXCatchStmt *CS = Terminator->getHandler(h); 4020 if (CS->getExceptionDecl() == nullptr) { 4021 HasCatchAll = true; 4022 } 4023 Block = nullptr; 4024 CFGBlock *CatchBlock = VisitCXXCatchStmt(CS); 4025 if (!CatchBlock) 4026 return nullptr; 4027 // Add this block to the list of successors for the block with the try 4028 // statement. 4029 addSuccessor(NewTryTerminatedBlock, CatchBlock); 4030 } 4031 if (!HasCatchAll) { 4032 if (PrevTryTerminatedBlock) 4033 addSuccessor(NewTryTerminatedBlock, PrevTryTerminatedBlock); 4034 else 4035 addSuccessor(NewTryTerminatedBlock, &cfg->getExit()); 4036 } 4037 4038 // The code after the try is the implicit successor. 4039 Succ = TrySuccessor; 4040 4041 // Save the current "try" context. 4042 SaveAndRestore<CFGBlock*> save_try(TryTerminatedBlock, NewTryTerminatedBlock); 4043 cfg->addTryDispatchBlock(TryTerminatedBlock); 4044 4045 assert(Terminator->getTryBlock() && "try must contain a non-NULL body"); 4046 Block = nullptr; 4047 return addStmt(Terminator->getTryBlock()); 4048 } 4049 4050 CFGBlock *CFGBuilder::VisitCXXCatchStmt(CXXCatchStmt *CS) { 4051 // CXXCatchStmt are treated like labels, so they are the first statement in a 4052 // block. 4053 4054 // Save local scope position because in case of exception variable ScopePos 4055 // won't be restored when traversing AST. 4056 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 4057 4058 // Create local scope for possible exception variable. 4059 // Store scope position. Add implicit destructor. 4060 if (VarDecl *VD = CS->getExceptionDecl()) { 4061 LocalScope::const_iterator BeginScopePos = ScopePos; 4062 addLocalScopeForVarDecl(VD); 4063 addAutomaticObjHandling(ScopePos, BeginScopePos, CS); 4064 } 4065 4066 if (CS->getHandlerBlock()) 4067 addStmt(CS->getHandlerBlock()); 4068 4069 CFGBlock *CatchBlock = Block; 4070 if (!CatchBlock) 4071 CatchBlock = createBlock(); 4072 4073 // CXXCatchStmt is more than just a label. They have semantic meaning 4074 // as well, as they implicitly "initialize" the catch variable. Add 4075 // it to the CFG as a CFGElement so that the control-flow of these 4076 // semantics gets captured. 4077 appendStmt(CatchBlock, CS); 4078 4079 // Also add the CXXCatchStmt as a label, to mirror handling of regular 4080 // labels. 4081 CatchBlock->setLabel(CS); 4082 4083 // Bail out if the CFG is bad. 4084 if (badCFG) 4085 return nullptr; 4086 4087 // We set Block to NULL to allow lazy creation of a new block (if necessary) 4088 Block = nullptr; 4089 4090 return CatchBlock; 4091 } 4092 4093 CFGBlock *CFGBuilder::VisitCXXForRangeStmt(CXXForRangeStmt *S) { 4094 // C++0x for-range statements are specified as [stmt.ranged]: 4095 // 4096 // { 4097 // auto && __range = range-init; 4098 // for ( auto __begin = begin-expr, 4099 // __end = end-expr; 4100 // __begin != __end; 4101 // ++__begin ) { 4102 // for-range-declaration = *__begin; 4103 // statement 4104 // } 4105 // } 4106 4107 // Save local scope position before the addition of the implicit variables. 4108 SaveAndRestore<LocalScope::const_iterator> save_scope_pos(ScopePos); 4109 4110 // Create local scopes and destructors for range, begin and end variables. 4111 if (Stmt *Range = S->getRangeStmt()) 4112 addLocalScopeForStmt(Range); 4113 if (Stmt *Begin = S->getBeginStmt()) 4114 addLocalScopeForStmt(Begin); 4115 if (Stmt *End = S->getEndStmt()) 4116 addLocalScopeForStmt(End); 4117 addAutomaticObjHandling(ScopePos, save_scope_pos.get(), S); 4118 4119 LocalScope::const_iterator ContinueScopePos = ScopePos; 4120 4121 // "for" is a control-flow statement. Thus we stop processing the current 4122 // block. 4123 CFGBlock *LoopSuccessor = nullptr; 4124 if (Block) { 4125 if (badCFG) 4126 return nullptr; 4127 LoopSuccessor = Block; 4128 } else 4129 LoopSuccessor = Succ; 4130 4131 // Save the current value for the break targets. 4132 // All breaks should go to the code following the loop. 4133 SaveAndRestore<JumpTarget> save_break(BreakJumpTarget); 4134 BreakJumpTarget = JumpTarget(LoopSuccessor, ScopePos); 4135 4136 // The block for the __begin != __end expression. 4137 CFGBlock *ConditionBlock = createBlock(false); 4138 ConditionBlock->setTerminator(S); 4139 4140 // Now add the actual condition to the condition block. 4141 if (Expr *C = S->getCond()) { 4142 Block = ConditionBlock; 4143 CFGBlock *BeginConditionBlock = addStmt(C); 4144 if (badCFG) 4145 return nullptr; 4146 assert(BeginConditionBlock == ConditionBlock && 4147 "condition block in for-range was unexpectedly complex"); 4148 (void)BeginConditionBlock; 4149 } 4150 4151 // The condition block is the implicit successor for the loop body as well as 4152 // any code above the loop. 4153 Succ = ConditionBlock; 4154 4155 // See if this is a known constant. 4156 TryResult KnownVal(true); 4157 4158 if (S->getCond()) 4159 KnownVal = tryEvaluateBool(S->getCond()); 4160 4161 // Now create the loop body. 4162 { 4163 assert(S->getBody()); 4164 4165 // Save the current values for Block, Succ, and continue targets. 4166 SaveAndRestore<CFGBlock*> save_Block(Block), save_Succ(Succ); 4167 SaveAndRestore<JumpTarget> save_continue(ContinueJumpTarget); 4168 4169 // Generate increment code in its own basic block. This is the target of 4170 // continue statements. 4171 Block = nullptr; 4172 Succ = addStmt(S->getInc()); 4173 if (badCFG) 4174 return nullptr; 4175 ContinueJumpTarget = JumpTarget(Succ, ContinueScopePos); 4176 4177 // The starting block for the loop increment is the block that should 4178 // represent the 'loop target' for looping back to the start of the loop. 4179 ContinueJumpTarget.block->setLoopTarget(S); 4180 4181 // Finish up the increment block and prepare to start the loop body. 4182 assert(Block); 4183 if (badCFG) 4184 return nullptr; 4185 Block = nullptr; 4186 4187 // Add implicit scope and dtors for loop variable. 4188 addLocalScopeAndDtors(S->getLoopVarStmt()); 4189 4190 // Populate a new block to contain the loop body and loop variable. 4191 addStmt(S->getBody()); 4192 if (badCFG) 4193 return nullptr; 4194 CFGBlock *LoopVarStmtBlock = addStmt(S->getLoopVarStmt()); 4195 if (badCFG) 4196 return nullptr; 4197 4198 // This new body block is a successor to our condition block. 4199 addSuccessor(ConditionBlock, 4200 KnownVal.isFalse() ? nullptr : LoopVarStmtBlock); 4201 } 4202 4203 // Link up the condition block with the code that follows the loop (the 4204 // false branch). 4205 addSuccessor(ConditionBlock, KnownVal.isTrue() ? nullptr : LoopSuccessor); 4206 4207 // Add the initialization statements. 4208 Block = createBlock(); 4209 addStmt(S->getBeginStmt()); 4210 addStmt(S->getEndStmt()); 4211 return addStmt(S->getRangeStmt()); 4212 } 4213 4214 CFGBlock *CFGBuilder::VisitExprWithCleanups(ExprWithCleanups *E, 4215 AddStmtChoice asc) { 4216 if (BuildOpts.AddTemporaryDtors) { 4217 // If adding implicit destructors visit the full expression for adding 4218 // destructors of temporaries. 4219 TempDtorContext Context; 4220 VisitForTemporaryDtors(E->getSubExpr(), false, Context); 4221 4222 // Full expression has to be added as CFGStmt so it will be sequenced 4223 // before destructors of it's temporaries. 4224 asc = asc.withAlwaysAdd(true); 4225 } 4226 return Visit(E->getSubExpr(), asc); 4227 } 4228 4229 CFGBlock *CFGBuilder::VisitCXXBindTemporaryExpr(CXXBindTemporaryExpr *E, 4230 AddStmtChoice asc) { 4231 if (asc.alwaysAdd(*this, E)) { 4232 autoCreateBlock(); 4233 appendStmt(Block, E); 4234 4235 findConstructionContexts( 4236 ConstructionContextLayer::create(cfg->getBumpVectorContext(), E), 4237 E->getSubExpr()); 4238 4239 // We do not want to propagate the AlwaysAdd property. 4240 asc = asc.withAlwaysAdd(false); 4241 } 4242 return Visit(E->getSubExpr(), asc); 4243 } 4244 4245 CFGBlock *CFGBuilder::VisitCXXConstructExpr(CXXConstructExpr *C, 4246 AddStmtChoice asc) { 4247 autoCreateBlock(); 4248 appendConstructor(Block, C); 4249 4250 return VisitChildren(C); 4251 } 4252 4253 CFGBlock *CFGBuilder::VisitCXXNewExpr(CXXNewExpr *NE, 4254 AddStmtChoice asc) { 4255 autoCreateBlock(); 4256 appendStmt(Block, NE); 4257 4258 findConstructionContexts( 4259 ConstructionContextLayer::create(cfg->getBumpVectorContext(), NE), 4260 const_cast<CXXConstructExpr *>(NE->getConstructExpr())); 4261 4262 if (NE->getInitializer()) 4263 Block = Visit(NE->getInitializer()); 4264 4265 if (BuildOpts.AddCXXNewAllocator) 4266 appendNewAllocator(Block, NE); 4267 4268 if (NE->isArray()) 4269 Block = Visit(NE->getArraySize()); 4270 4271 for (CXXNewExpr::arg_iterator I = NE->placement_arg_begin(), 4272 E = NE->placement_arg_end(); I != E; ++I) 4273 Block = Visit(*I); 4274 4275 return Block; 4276 } 4277 4278 CFGBlock *CFGBuilder::VisitCXXDeleteExpr(CXXDeleteExpr *DE, 4279 AddStmtChoice asc) { 4280 autoCreateBlock(); 4281 appendStmt(Block, DE); 4282 QualType DTy = DE->getDestroyedType(); 4283 if (!DTy.isNull()) { 4284 DTy = DTy.getNonReferenceType(); 4285 CXXRecordDecl *RD = Context->getBaseElementType(DTy)->getAsCXXRecordDecl(); 4286 if (RD) { 4287 if (RD->isCompleteDefinition() && !RD->hasTrivialDestructor()) 4288 appendDeleteDtor(Block, RD, DE); 4289 } 4290 } 4291 4292 return VisitChildren(DE); 4293 } 4294 4295 CFGBlock *CFGBuilder::VisitCXXFunctionalCastExpr(CXXFunctionalCastExpr *E, 4296 AddStmtChoice asc) { 4297 if (asc.alwaysAdd(*this, E)) { 4298 autoCreateBlock(); 4299 appendStmt(Block, E); 4300 // We do not want to propagate the AlwaysAdd property. 4301 asc = asc.withAlwaysAdd(false); 4302 } 4303 return Visit(E->getSubExpr(), asc); 4304 } 4305 4306 CFGBlock *CFGBuilder::VisitCXXTemporaryObjectExpr(CXXTemporaryObjectExpr *C, 4307 AddStmtChoice asc) { 4308 autoCreateBlock(); 4309 appendConstructor(Block, C); 4310 return VisitChildren(C); 4311 } 4312 4313 CFGBlock *CFGBuilder::VisitImplicitCastExpr(ImplicitCastExpr *E, 4314 AddStmtChoice asc) { 4315 if (asc.alwaysAdd(*this, E)) { 4316 autoCreateBlock(); 4317 appendStmt(Block, E); 4318 } 4319 return Visit(E->getSubExpr(), AddStmtChoice()); 4320 } 4321 4322 CFGBlock *CFGBuilder::VisitIndirectGotoStmt(IndirectGotoStmt *I) { 4323 // Lazily create the indirect-goto dispatch block if there isn't one already. 4324 CFGBlock *IBlock = cfg->getIndirectGotoBlock(); 4325 4326 if (!IBlock) { 4327 IBlock = createBlock(false); 4328 cfg->setIndirectGotoBlock(IBlock); 4329 } 4330 4331 // IndirectGoto is a control-flow statement. Thus we stop processing the 4332 // current block and create a new one. 4333 if (badCFG) 4334 return nullptr; 4335 4336 Block = createBlock(false); 4337 Block->setTerminator(I); 4338 addSuccessor(Block, IBlock); 4339 return addStmt(I->getTarget()); 4340 } 4341 4342 CFGBlock *CFGBuilder::VisitForTemporaryDtors(Stmt *E, bool BindToTemporary, 4343 TempDtorContext &Context) { 4344 assert(BuildOpts.AddImplicitDtors && BuildOpts.AddTemporaryDtors); 4345 4346 tryAgain: 4347 if (!E) { 4348 badCFG = true; 4349 return nullptr; 4350 } 4351 switch (E->getStmtClass()) { 4352 default: 4353 return VisitChildrenForTemporaryDtors(E, Context); 4354 4355 case Stmt::BinaryOperatorClass: 4356 return VisitBinaryOperatorForTemporaryDtors(cast<BinaryOperator>(E), 4357 Context); 4358 4359 case Stmt::CXXBindTemporaryExprClass: 4360 return VisitCXXBindTemporaryExprForTemporaryDtors( 4361 cast<CXXBindTemporaryExpr>(E), BindToTemporary, Context); 4362 4363 case Stmt::BinaryConditionalOperatorClass: 4364 case Stmt::ConditionalOperatorClass: 4365 return VisitConditionalOperatorForTemporaryDtors( 4366 cast<AbstractConditionalOperator>(E), BindToTemporary, Context); 4367 4368 case Stmt::ImplicitCastExprClass: 4369 // For implicit cast we want BindToTemporary to be passed further. 4370 E = cast<CastExpr>(E)->getSubExpr(); 4371 goto tryAgain; 4372 4373 case Stmt::CXXFunctionalCastExprClass: 4374 // For functional cast we want BindToTemporary to be passed further. 4375 E = cast<CXXFunctionalCastExpr>(E)->getSubExpr(); 4376 goto tryAgain; 4377 4378 case Stmt::ParenExprClass: 4379 E = cast<ParenExpr>(E)->getSubExpr(); 4380 goto tryAgain; 4381 4382 case Stmt::MaterializeTemporaryExprClass: { 4383 const MaterializeTemporaryExpr* MTE = cast<MaterializeTemporaryExpr>(E); 4384 BindToTemporary = (MTE->getStorageDuration() != SD_FullExpression); 4385 SmallVector<const Expr *, 2> CommaLHSs; 4386 SmallVector<SubobjectAdjustment, 2> Adjustments; 4387 // Find the expression whose lifetime needs to be extended. 4388 E = const_cast<Expr *>( 4389 cast<MaterializeTemporaryExpr>(E) 4390 ->GetTemporaryExpr() 4391 ->skipRValueSubobjectAdjustments(CommaLHSs, Adjustments)); 4392 // Visit the skipped comma operator left-hand sides for other temporaries. 4393 for (const Expr *CommaLHS : CommaLHSs) { 4394 VisitForTemporaryDtors(const_cast<Expr *>(CommaLHS), 4395 /*BindToTemporary=*/false, Context); 4396 } 4397 goto tryAgain; 4398 } 4399 4400 case Stmt::BlockExprClass: 4401 // Don't recurse into blocks; their subexpressions don't get evaluated 4402 // here. 4403 return Block; 4404 4405 case Stmt::LambdaExprClass: { 4406 // For lambda expressions, only recurse into the capture initializers, 4407 // and not the body. 4408 auto *LE = cast<LambdaExpr>(E); 4409 CFGBlock *B = Block; 4410 for (Expr *Init : LE->capture_inits()) { 4411 if (CFGBlock *R = VisitForTemporaryDtors( 4412 Init, /*BindToTemporary=*/false, Context)) 4413 B = R; 4414 } 4415 return B; 4416 } 4417 4418 case Stmt::CXXDefaultArgExprClass: 4419 E = cast<CXXDefaultArgExpr>(E)->getExpr(); 4420 goto tryAgain; 4421 4422 case Stmt::CXXDefaultInitExprClass: 4423 E = cast<CXXDefaultInitExpr>(E)->getExpr(); 4424 goto tryAgain; 4425 } 4426 } 4427 4428 CFGBlock *CFGBuilder::VisitChildrenForTemporaryDtors(Stmt *E, 4429 TempDtorContext &Context) { 4430 if (isa<LambdaExpr>(E)) { 4431 // Do not visit the children of lambdas; they have their own CFGs. 4432 return Block; 4433 } 4434 4435 // When visiting children for destructors we want to visit them in reverse 4436 // order that they will appear in the CFG. Because the CFG is built 4437 // bottom-up, this means we visit them in their natural order, which 4438 // reverses them in the CFG. 4439 CFGBlock *B = Block; 4440 for (Stmt *Child : E->children()) 4441 if (Child) 4442 if (CFGBlock *R = VisitForTemporaryDtors(Child, false, Context)) 4443 B = R; 4444 4445 return B; 4446 } 4447 4448 CFGBlock *CFGBuilder::VisitBinaryOperatorForTemporaryDtors( 4449 BinaryOperator *E, TempDtorContext &Context) { 4450 if (E->isLogicalOp()) { 4451 VisitForTemporaryDtors(E->getLHS(), false, Context); 4452 TryResult RHSExecuted = tryEvaluateBool(E->getLHS()); 4453 if (RHSExecuted.isKnown() && E->getOpcode() == BO_LOr) 4454 RHSExecuted.negate(); 4455 4456 // We do not know at CFG-construction time whether the right-hand-side was 4457 // executed, thus we add a branch node that depends on the temporary 4458 // constructor call. 4459 TempDtorContext RHSContext( 4460 bothKnownTrue(Context.KnownExecuted, RHSExecuted)); 4461 VisitForTemporaryDtors(E->getRHS(), false, RHSContext); 4462 InsertTempDtorDecisionBlock(RHSContext); 4463 4464 return Block; 4465 } 4466 4467 if (E->isAssignmentOp()) { 4468 // For assignment operator (=) LHS expression is visited 4469 // before RHS expression. For destructors visit them in reverse order. 4470 CFGBlock *RHSBlock = VisitForTemporaryDtors(E->getRHS(), false, Context); 4471 CFGBlock *LHSBlock = VisitForTemporaryDtors(E->getLHS(), false, Context); 4472 return LHSBlock ? LHSBlock : RHSBlock; 4473 } 4474 4475 // For any other binary operator RHS expression is visited before 4476 // LHS expression (order of children). For destructors visit them in reverse 4477 // order. 4478 CFGBlock *LHSBlock = VisitForTemporaryDtors(E->getLHS(), false, Context); 4479 CFGBlock *RHSBlock = VisitForTemporaryDtors(E->getRHS(), false, Context); 4480 return RHSBlock ? RHSBlock : LHSBlock; 4481 } 4482 4483 CFGBlock *CFGBuilder::VisitCXXBindTemporaryExprForTemporaryDtors( 4484 CXXBindTemporaryExpr *E, bool BindToTemporary, TempDtorContext &Context) { 4485 // First add destructors for temporaries in subexpression. 4486 CFGBlock *B = VisitForTemporaryDtors(E->getSubExpr(), false, Context); 4487 if (!BindToTemporary) { 4488 // If lifetime of temporary is not prolonged (by assigning to constant 4489 // reference) add destructor for it. 4490 4491 const CXXDestructorDecl *Dtor = E->getTemporary()->getDestructor(); 4492 4493 if (Dtor->getParent()->isAnyDestructorNoReturn()) { 4494 // If the destructor is marked as a no-return destructor, we need to 4495 // create a new block for the destructor which does not have as a 4496 // successor anything built thus far. Control won't flow out of this 4497 // block. 4498 if (B) Succ = B; 4499 Block = createNoReturnBlock(); 4500 } else if (Context.needsTempDtorBranch()) { 4501 // If we need to introduce a branch, we add a new block that we will hook 4502 // up to a decision block later. 4503 if (B) Succ = B; 4504 Block = createBlock(); 4505 } else { 4506 autoCreateBlock(); 4507 } 4508 if (Context.needsTempDtorBranch()) { 4509 Context.setDecisionPoint(Succ, E); 4510 } 4511 appendTemporaryDtor(Block, E); 4512 4513 B = Block; 4514 } 4515 return B; 4516 } 4517 4518 void CFGBuilder::InsertTempDtorDecisionBlock(const TempDtorContext &Context, 4519 CFGBlock *FalseSucc) { 4520 if (!Context.TerminatorExpr) { 4521 // If no temporary was found, we do not need to insert a decision point. 4522 return; 4523 } 4524 assert(Context.TerminatorExpr); 4525 CFGBlock *Decision = createBlock(false); 4526 Decision->setTerminator(CFGTerminator(Context.TerminatorExpr, true)); 4527 addSuccessor(Decision, Block, !Context.KnownExecuted.isFalse()); 4528 addSuccessor(Decision, FalseSucc ? FalseSucc : Context.Succ, 4529 !Context.KnownExecuted.isTrue()); 4530 Block = Decision; 4531 } 4532 4533 CFGBlock *CFGBuilder::VisitConditionalOperatorForTemporaryDtors( 4534 AbstractConditionalOperator *E, bool BindToTemporary, 4535 TempDtorContext &Context) { 4536 VisitForTemporaryDtors(E->getCond(), false, Context); 4537 CFGBlock *ConditionBlock = Block; 4538 CFGBlock *ConditionSucc = Succ; 4539 TryResult ConditionVal = tryEvaluateBool(E->getCond()); 4540 TryResult NegatedVal = ConditionVal; 4541 if (NegatedVal.isKnown()) NegatedVal.negate(); 4542 4543 TempDtorContext TrueContext( 4544 bothKnownTrue(Context.KnownExecuted, ConditionVal)); 4545 VisitForTemporaryDtors(E->getTrueExpr(), BindToTemporary, TrueContext); 4546 CFGBlock *TrueBlock = Block; 4547 4548 Block = ConditionBlock; 4549 Succ = ConditionSucc; 4550 TempDtorContext FalseContext( 4551 bothKnownTrue(Context.KnownExecuted, NegatedVal)); 4552 VisitForTemporaryDtors(E->getFalseExpr(), BindToTemporary, FalseContext); 4553 4554 if (TrueContext.TerminatorExpr && FalseContext.TerminatorExpr) { 4555 InsertTempDtorDecisionBlock(FalseContext, TrueBlock); 4556 } else if (TrueContext.TerminatorExpr) { 4557 Block = TrueBlock; 4558 InsertTempDtorDecisionBlock(TrueContext); 4559 } else { 4560 InsertTempDtorDecisionBlock(FalseContext); 4561 } 4562 return Block; 4563 } 4564 4565 /// createBlock - Constructs and adds a new CFGBlock to the CFG. The block has 4566 /// no successors or predecessors. If this is the first block created in the 4567 /// CFG, it is automatically set to be the Entry and Exit of the CFG. 4568 CFGBlock *CFG::createBlock() { 4569 bool first_block = begin() == end(); 4570 4571 // Create the block. 4572 CFGBlock *Mem = getAllocator().Allocate<CFGBlock>(); 4573 new (Mem) CFGBlock(NumBlockIDs++, BlkBVC, this); 4574 Blocks.push_back(Mem, BlkBVC); 4575 4576 // If this is the first block, set it as the Entry and Exit. 4577 if (first_block) 4578 Entry = Exit = &back(); 4579 4580 // Return the block. 4581 return &back(); 4582 } 4583 4584 /// buildCFG - Constructs a CFG from an AST. 4585 std::unique_ptr<CFG> CFG::buildCFG(const Decl *D, Stmt *Statement, 4586 ASTContext *C, const BuildOptions &BO) { 4587 CFGBuilder Builder(C, BO); 4588 return Builder.buildCFG(D, Statement); 4589 } 4590 4591 const CXXDestructorDecl * 4592 CFGImplicitDtor::getDestructorDecl(ASTContext &astContext) const { 4593 switch (getKind()) { 4594 case CFGElement::Initializer: 4595 case CFGElement::NewAllocator: 4596 case CFGElement::LoopExit: 4597 case CFGElement::LifetimeEnds: 4598 case CFGElement::Statement: 4599 case CFGElement::Constructor: 4600 case CFGElement::CXXRecordTypedCall: 4601 case CFGElement::ScopeBegin: 4602 case CFGElement::ScopeEnd: 4603 llvm_unreachable("getDestructorDecl should only be used with " 4604 "ImplicitDtors"); 4605 case CFGElement::AutomaticObjectDtor: { 4606 const VarDecl *var = castAs<CFGAutomaticObjDtor>().getVarDecl(); 4607 QualType ty = var->getType(); 4608 4609 // FIXME: See CFGBuilder::addLocalScopeForVarDecl. 4610 // 4611 // Lifetime-extending constructs are handled here. This works for a single 4612 // temporary in an initializer expression. 4613 if (ty->isReferenceType()) { 4614 if (const Expr *Init = var->getInit()) { 4615 ty = getReferenceInitTemporaryType(Init); 4616 } 4617 } 4618 4619 while (const ArrayType *arrayType = astContext.getAsArrayType(ty)) { 4620 ty = arrayType->getElementType(); 4621 } 4622 const RecordType *recordType = ty->getAs<RecordType>(); 4623 const CXXRecordDecl *classDecl = 4624 cast<CXXRecordDecl>(recordType->getDecl()); 4625 return classDecl->getDestructor(); 4626 } 4627 case CFGElement::DeleteDtor: { 4628 const CXXDeleteExpr *DE = castAs<CFGDeleteDtor>().getDeleteExpr(); 4629 QualType DTy = DE->getDestroyedType(); 4630 DTy = DTy.getNonReferenceType(); 4631 const CXXRecordDecl *classDecl = 4632 astContext.getBaseElementType(DTy)->getAsCXXRecordDecl(); 4633 return classDecl->getDestructor(); 4634 } 4635 case CFGElement::TemporaryDtor: { 4636 const CXXBindTemporaryExpr *bindExpr = 4637 castAs<CFGTemporaryDtor>().getBindTemporaryExpr(); 4638 const CXXTemporary *temp = bindExpr->getTemporary(); 4639 return temp->getDestructor(); 4640 } 4641 case CFGElement::BaseDtor: 4642 case CFGElement::MemberDtor: 4643 // Not yet supported. 4644 return nullptr; 4645 } 4646 llvm_unreachable("getKind() returned bogus value"); 4647 } 4648 4649 bool CFGImplicitDtor::isNoReturn(ASTContext &astContext) const { 4650 if (const CXXDestructorDecl *DD = getDestructorDecl(astContext)) 4651 return DD->isNoReturn(); 4652 return false; 4653 } 4654 4655 //===----------------------------------------------------------------------===// 4656 // CFGBlock operations. 4657 //===----------------------------------------------------------------------===// 4658 4659 CFGBlock::AdjacentBlock::AdjacentBlock(CFGBlock *B, bool IsReachable) 4660 : ReachableBlock(IsReachable ? B : nullptr), 4661 UnreachableBlock(!IsReachable ? B : nullptr, 4662 B && IsReachable ? AB_Normal : AB_Unreachable) {} 4663 4664 CFGBlock::AdjacentBlock::AdjacentBlock(CFGBlock *B, CFGBlock *AlternateBlock) 4665 : ReachableBlock(B), 4666 UnreachableBlock(B == AlternateBlock ? nullptr : AlternateBlock, 4667 B == AlternateBlock ? AB_Alternate : AB_Normal) {} 4668 4669 void CFGBlock::addSuccessor(AdjacentBlock Succ, 4670 BumpVectorContext &C) { 4671 if (CFGBlock *B = Succ.getReachableBlock()) 4672 B->Preds.push_back(AdjacentBlock(this, Succ.isReachable()), C); 4673 4674 if (CFGBlock *UnreachableB = Succ.getPossiblyUnreachableBlock()) 4675 UnreachableB->Preds.push_back(AdjacentBlock(this, false), C); 4676 4677 Succs.push_back(Succ, C); 4678 } 4679 4680 bool CFGBlock::FilterEdge(const CFGBlock::FilterOptions &F, 4681 const CFGBlock *From, const CFGBlock *To) { 4682 if (F.IgnoreNullPredecessors && !From) 4683 return true; 4684 4685 if (To && From && F.IgnoreDefaultsWithCoveredEnums) { 4686 // If the 'To' has no label or is labeled but the label isn't a 4687 // CaseStmt then filter this edge. 4688 if (const SwitchStmt *S = 4689 dyn_cast_or_null<SwitchStmt>(From->getTerminator().getStmt())) { 4690 if (S->isAllEnumCasesCovered()) { 4691 const Stmt *L = To->getLabel(); 4692 if (!L || !isa<CaseStmt>(L)) 4693 return true; 4694 } 4695 } 4696 } 4697 4698 return false; 4699 } 4700 4701 //===----------------------------------------------------------------------===// 4702 // CFG pretty printing 4703 //===----------------------------------------------------------------------===// 4704 4705 namespace { 4706 4707 class StmtPrinterHelper : public PrinterHelper { 4708 using StmtMapTy = llvm::DenseMap<const Stmt *, std::pair<unsigned, unsigned>>; 4709 using DeclMapTy = llvm::DenseMap<const Decl *, std::pair<unsigned, unsigned>>; 4710 4711 StmtMapTy StmtMap; 4712 DeclMapTy DeclMap; 4713 signed currentBlock = 0; 4714 unsigned currStmt = 0; 4715 const LangOptions &LangOpts; 4716 4717 public: 4718 StmtPrinterHelper(const CFG* cfg, const LangOptions &LO) 4719 : LangOpts(LO) { 4720 for (CFG::const_iterator I = cfg->begin(), E = cfg->end(); I != E; ++I ) { 4721 unsigned j = 1; 4722 for (CFGBlock::const_iterator BI = (*I)->begin(), BEnd = (*I)->end() ; 4723 BI != BEnd; ++BI, ++j ) { 4724 if (Optional<CFGStmt> SE = BI->getAs<CFGStmt>()) { 4725 const Stmt *stmt= SE->getStmt(); 4726 std::pair<unsigned, unsigned> P((*I)->getBlockID(), j); 4727 StmtMap[stmt] = P; 4728 4729 switch (stmt->getStmtClass()) { 4730 case Stmt::DeclStmtClass: 4731 DeclMap[cast<DeclStmt>(stmt)->getSingleDecl()] = P; 4732 break; 4733 case Stmt::IfStmtClass: { 4734 const VarDecl *var = cast<IfStmt>(stmt)->getConditionVariable(); 4735 if (var) 4736 DeclMap[var] = P; 4737 break; 4738 } 4739 case Stmt::ForStmtClass: { 4740 const VarDecl *var = cast<ForStmt>(stmt)->getConditionVariable(); 4741 if (var) 4742 DeclMap[var] = P; 4743 break; 4744 } 4745 case Stmt::WhileStmtClass: { 4746 const VarDecl *var = 4747 cast<WhileStmt>(stmt)->getConditionVariable(); 4748 if (var) 4749 DeclMap[var] = P; 4750 break; 4751 } 4752 case Stmt::SwitchStmtClass: { 4753 const VarDecl *var = 4754 cast<SwitchStmt>(stmt)->getConditionVariable(); 4755 if (var) 4756 DeclMap[var] = P; 4757 break; 4758 } 4759 case Stmt::CXXCatchStmtClass: { 4760 const VarDecl *var = 4761 cast<CXXCatchStmt>(stmt)->getExceptionDecl(); 4762 if (var) 4763 DeclMap[var] = P; 4764 break; 4765 } 4766 default: 4767 break; 4768 } 4769 } 4770 } 4771 } 4772 } 4773 4774 ~StmtPrinterHelper() override = default; 4775 4776 const LangOptions &getLangOpts() const { return LangOpts; } 4777 void setBlockID(signed i) { currentBlock = i; } 4778 void setStmtID(unsigned i) { currStmt = i; } 4779 4780 bool handledStmt(Stmt *S, raw_ostream &OS) override { 4781 StmtMapTy::iterator I = StmtMap.find(S); 4782 4783 if (I == StmtMap.end()) 4784 return false; 4785 4786 if (currentBlock >= 0 && I->second.first == (unsigned) currentBlock 4787 && I->second.second == currStmt) { 4788 return false; 4789 } 4790 4791 OS << "[B" << I->second.first << "." << I->second.second << "]"; 4792 return true; 4793 } 4794 4795 bool handleDecl(const Decl *D, raw_ostream &OS) { 4796 DeclMapTy::iterator I = DeclMap.find(D); 4797 4798 if (I == DeclMap.end()) 4799 return false; 4800 4801 if (currentBlock >= 0 && I->second.first == (unsigned) currentBlock 4802 && I->second.second == currStmt) { 4803 return false; 4804 } 4805 4806 OS << "[B" << I->second.first << "." << I->second.second << "]"; 4807 return true; 4808 } 4809 }; 4810 4811 class CFGBlockTerminatorPrint 4812 : public StmtVisitor<CFGBlockTerminatorPrint,void> { 4813 raw_ostream &OS; 4814 StmtPrinterHelper* Helper; 4815 PrintingPolicy Policy; 4816 4817 public: 4818 CFGBlockTerminatorPrint(raw_ostream &os, StmtPrinterHelper* helper, 4819 const PrintingPolicy &Policy) 4820 : OS(os), Helper(helper), Policy(Policy) { 4821 this->Policy.IncludeNewlines = false; 4822 } 4823 4824 void VisitIfStmt(IfStmt *I) { 4825 OS << "if "; 4826 if (Stmt *C = I->getCond()) 4827 C->printPretty(OS, Helper, Policy); 4828 } 4829 4830 // Default case. 4831 void VisitStmt(Stmt *Terminator) { 4832 Terminator->printPretty(OS, Helper, Policy); 4833 } 4834 4835 void VisitDeclStmt(DeclStmt *DS) { 4836 VarDecl *VD = cast<VarDecl>(DS->getSingleDecl()); 4837 OS << "static init " << VD->getName(); 4838 } 4839 4840 void VisitForStmt(ForStmt *F) { 4841 OS << "for (" ; 4842 if (F->getInit()) 4843 OS << "..."; 4844 OS << "; "; 4845 if (Stmt *C = F->getCond()) 4846 C->printPretty(OS, Helper, Policy); 4847 OS << "; "; 4848 if (F->getInc()) 4849 OS << "..."; 4850 OS << ")"; 4851 } 4852 4853 void VisitWhileStmt(WhileStmt *W) { 4854 OS << "while " ; 4855 if (Stmt *C = W->getCond()) 4856 C->printPretty(OS, Helper, Policy); 4857 } 4858 4859 void VisitDoStmt(DoStmt *D) { 4860 OS << "do ... while "; 4861 if (Stmt *C = D->getCond()) 4862 C->printPretty(OS, Helper, Policy); 4863 } 4864 4865 void VisitSwitchStmt(SwitchStmt *Terminator) { 4866 OS << "switch "; 4867 Terminator->getCond()->printPretty(OS, Helper, Policy); 4868 } 4869 4870 void VisitCXXTryStmt(CXXTryStmt *CS) { 4871 OS << "try ..."; 4872 } 4873 4874 void VisitSEHTryStmt(SEHTryStmt *CS) { 4875 OS << "__try ..."; 4876 } 4877 4878 void VisitAbstractConditionalOperator(AbstractConditionalOperator* C) { 4879 if (Stmt *Cond = C->getCond()) 4880 Cond->printPretty(OS, Helper, Policy); 4881 OS << " ? ... : ..."; 4882 } 4883 4884 void VisitChooseExpr(ChooseExpr *C) { 4885 OS << "__builtin_choose_expr( "; 4886 if (Stmt *Cond = C->getCond()) 4887 Cond->printPretty(OS, Helper, Policy); 4888 OS << " )"; 4889 } 4890 4891 void VisitIndirectGotoStmt(IndirectGotoStmt *I) { 4892 OS << "goto *"; 4893 if (Stmt *T = I->getTarget()) 4894 T->printPretty(OS, Helper, Policy); 4895 } 4896 4897 void VisitBinaryOperator(BinaryOperator* B) { 4898 if (!B->isLogicalOp()) { 4899 VisitExpr(B); 4900 return; 4901 } 4902 4903 if (B->getLHS()) 4904 B->getLHS()->printPretty(OS, Helper, Policy); 4905 4906 switch (B->getOpcode()) { 4907 case BO_LOr: 4908 OS << " || ..."; 4909 return; 4910 case BO_LAnd: 4911 OS << " && ..."; 4912 return; 4913 default: 4914 llvm_unreachable("Invalid logical operator."); 4915 } 4916 } 4917 4918 void VisitExpr(Expr *E) { 4919 E->printPretty(OS, Helper, Policy); 4920 } 4921 4922 public: 4923 void print(CFGTerminator T) { 4924 if (T.isTemporaryDtorsBranch()) 4925 OS << "(Temp Dtor) "; 4926 Visit(T.getStmt()); 4927 } 4928 }; 4929 4930 } // namespace 4931 4932 static void print_initializer(raw_ostream &OS, StmtPrinterHelper &Helper, 4933 const CXXCtorInitializer *I) { 4934 if (I->isBaseInitializer()) 4935 OS << I->getBaseClass()->getAsCXXRecordDecl()->getName(); 4936 else if (I->isDelegatingInitializer()) 4937 OS << I->getTypeSourceInfo()->getType()->getAsCXXRecordDecl()->getName(); 4938 else 4939 OS << I->getAnyMember()->getName(); 4940 OS << "("; 4941 if (Expr *IE = I->getInit()) 4942 IE->printPretty(OS, &Helper, PrintingPolicy(Helper.getLangOpts())); 4943 OS << ")"; 4944 4945 if (I->isBaseInitializer()) 4946 OS << " (Base initializer)"; 4947 else if (I->isDelegatingInitializer()) 4948 OS << " (Delegating initializer)"; 4949 else 4950 OS << " (Member initializer)"; 4951 } 4952 4953 static void print_construction_context(raw_ostream &OS, 4954 StmtPrinterHelper &Helper, 4955 const ConstructionContext *CC) { 4956 SmallVector<const Stmt *, 3> Stmts; 4957 switch (CC->getKind()) { 4958 case ConstructionContext::SimpleConstructorInitializerKind: { 4959 OS << ", "; 4960 const auto *SICC = cast<SimpleConstructorInitializerConstructionContext>(CC); 4961 print_initializer(OS, Helper, SICC->getCXXCtorInitializer()); 4962 break; 4963 } 4964 case ConstructionContext::CXX17ElidedCopyConstructorInitializerKind: { 4965 OS << ", "; 4966 const auto *CICC = 4967 cast<CXX17ElidedCopyConstructorInitializerConstructionContext>(CC); 4968 print_initializer(OS, Helper, CICC->getCXXCtorInitializer()); 4969 Stmts.push_back(CICC->getCXXBindTemporaryExpr()); 4970 break; 4971 } 4972 case ConstructionContext::SimpleVariableKind: { 4973 const auto *SDSCC = cast<SimpleVariableConstructionContext>(CC); 4974 Stmts.push_back(SDSCC->getDeclStmt()); 4975 break; 4976 } 4977 case ConstructionContext::CXX17ElidedCopyVariableKind: { 4978 const auto *CDSCC = cast<CXX17ElidedCopyVariableConstructionContext>(CC); 4979 Stmts.push_back(CDSCC->getDeclStmt()); 4980 Stmts.push_back(CDSCC->getCXXBindTemporaryExpr()); 4981 break; 4982 } 4983 case ConstructionContext::NewAllocatedObjectKind: { 4984 const auto *NECC = cast<NewAllocatedObjectConstructionContext>(CC); 4985 Stmts.push_back(NECC->getCXXNewExpr()); 4986 break; 4987 } 4988 case ConstructionContext::SimpleReturnedValueKind: { 4989 const auto *RSCC = cast<SimpleReturnedValueConstructionContext>(CC); 4990 Stmts.push_back(RSCC->getReturnStmt()); 4991 break; 4992 } 4993 case ConstructionContext::CXX17ElidedCopyReturnedValueKind: { 4994 const auto *RSCC = 4995 cast<CXX17ElidedCopyReturnedValueConstructionContext>(CC); 4996 Stmts.push_back(RSCC->getReturnStmt()); 4997 Stmts.push_back(RSCC->getCXXBindTemporaryExpr()); 4998 break; 4999 } 5000 case ConstructionContext::SimpleTemporaryObjectKind: { 5001 const auto *TOCC = cast<SimpleTemporaryObjectConstructionContext>(CC); 5002 Stmts.push_back(TOCC->getCXXBindTemporaryExpr()); 5003 Stmts.push_back(TOCC->getMaterializedTemporaryExpr()); 5004 break; 5005 } 5006 case ConstructionContext::ElidedTemporaryObjectKind: { 5007 const auto *TOCC = cast<ElidedTemporaryObjectConstructionContext>(CC); 5008 Stmts.push_back(TOCC->getCXXBindTemporaryExpr()); 5009 Stmts.push_back(TOCC->getMaterializedTemporaryExpr()); 5010 Stmts.push_back(TOCC->getConstructorAfterElision()); 5011 break; 5012 } 5013 } 5014 for (auto I: Stmts) 5015 if (I) { 5016 OS << ", "; 5017 Helper.handledStmt(const_cast<Stmt *>(I), OS); 5018 } 5019 } 5020 5021 static void print_elem(raw_ostream &OS, StmtPrinterHelper &Helper, 5022 const CFGElement &E) { 5023 if (Optional<CFGStmt> CS = E.getAs<CFGStmt>()) { 5024 const Stmt *S = CS->getStmt(); 5025 assert(S != nullptr && "Expecting non-null Stmt"); 5026 5027 // special printing for statement-expressions. 5028 if (const StmtExpr *SE = dyn_cast<StmtExpr>(S)) { 5029 const CompoundStmt *Sub = SE->getSubStmt(); 5030 5031 auto Children = Sub->children(); 5032 if (Children.begin() != Children.end()) { 5033 OS << "({ ... ; "; 5034 Helper.handledStmt(*SE->getSubStmt()->body_rbegin(),OS); 5035 OS << " })\n"; 5036 return; 5037 } 5038 } 5039 // special printing for comma expressions. 5040 if (const BinaryOperator* B = dyn_cast<BinaryOperator>(S)) { 5041 if (B->getOpcode() == BO_Comma) { 5042 OS << "... , "; 5043 Helper.handledStmt(B->getRHS(),OS); 5044 OS << '\n'; 5045 return; 5046 } 5047 } 5048 S->printPretty(OS, &Helper, PrintingPolicy(Helper.getLangOpts())); 5049 5050 if (auto VTC = E.getAs<CFGCXXRecordTypedCall>()) { 5051 if (isa<CXXOperatorCallExpr>(S)) 5052 OS << " (OperatorCall)"; 5053 OS << " (CXXRecordTypedCall"; 5054 print_construction_context(OS, Helper, VTC->getConstructionContext()); 5055 OS << ")"; 5056 } else if (isa<CXXOperatorCallExpr>(S)) { 5057 OS << " (OperatorCall)"; 5058 } else if (isa<CXXBindTemporaryExpr>(S)) { 5059 OS << " (BindTemporary)"; 5060 } else if (const CXXConstructExpr *CCE = dyn_cast<CXXConstructExpr>(S)) { 5061 OS << " (CXXConstructExpr"; 5062 if (Optional<CFGConstructor> CE = E.getAs<CFGConstructor>()) { 5063 print_construction_context(OS, Helper, CE->getConstructionContext()); 5064 } 5065 OS << ", " << CCE->getType().getAsString() << ")"; 5066 } else if (const CastExpr *CE = dyn_cast<CastExpr>(S)) { 5067 OS << " (" << CE->getStmtClassName() << ", " 5068 << CE->getCastKindName() 5069 << ", " << CE->getType().getAsString() 5070 << ")"; 5071 } 5072 5073 // Expressions need a newline. 5074 if (isa<Expr>(S)) 5075 OS << '\n'; 5076 } else if (Optional<CFGInitializer> IE = E.getAs<CFGInitializer>()) { 5077 print_initializer(OS, Helper, IE->getInitializer()); 5078 OS << '\n'; 5079 } else if (Optional<CFGAutomaticObjDtor> DE = 5080 E.getAs<CFGAutomaticObjDtor>()) { 5081 const VarDecl *VD = DE->getVarDecl(); 5082 Helper.handleDecl(VD, OS); 5083 5084 ASTContext &ACtx = VD->getASTContext(); 5085 QualType T = VD->getType(); 5086 if (T->isReferenceType()) 5087 T = getReferenceInitTemporaryType(VD->getInit(), nullptr); 5088 if (const ArrayType *AT = ACtx.getAsArrayType(T)) 5089 T = ACtx.getBaseElementType(AT); 5090 5091 OS << ".~" << T->getAsCXXRecordDecl()->getName().str() << "()"; 5092 OS << " (Implicit destructor)\n"; 5093 } else if (Optional<CFGLifetimeEnds> DE = E.getAs<CFGLifetimeEnds>()) { 5094 const VarDecl *VD = DE->getVarDecl(); 5095 Helper.handleDecl(VD, OS); 5096 5097 OS << " (Lifetime ends)\n"; 5098 } else if (Optional<CFGLoopExit> LE = E.getAs<CFGLoopExit>()) { 5099 const Stmt *LoopStmt = LE->getLoopStmt(); 5100 OS << LoopStmt->getStmtClassName() << " (LoopExit)\n"; 5101 } else if (Optional<CFGScopeBegin> SB = E.getAs<CFGScopeBegin>()) { 5102 OS << "CFGScopeBegin("; 5103 if (const VarDecl *VD = SB->getVarDecl()) 5104 OS << VD->getQualifiedNameAsString(); 5105 OS << ")\n"; 5106 } else if (Optional<CFGScopeEnd> SE = E.getAs<CFGScopeEnd>()) { 5107 OS << "CFGScopeEnd("; 5108 if (const VarDecl *VD = SE->getVarDecl()) 5109 OS << VD->getQualifiedNameAsString(); 5110 OS << ")\n"; 5111 } else if (Optional<CFGNewAllocator> NE = E.getAs<CFGNewAllocator>()) { 5112 OS << "CFGNewAllocator("; 5113 if (const CXXNewExpr *AllocExpr = NE->getAllocatorExpr()) 5114 AllocExpr->getType().print(OS, PrintingPolicy(Helper.getLangOpts())); 5115 OS << ")\n"; 5116 } else if (Optional<CFGDeleteDtor> DE = E.getAs<CFGDeleteDtor>()) { 5117 const CXXRecordDecl *RD = DE->getCXXRecordDecl(); 5118 if (!RD) 5119 return; 5120 CXXDeleteExpr *DelExpr = 5121 const_cast<CXXDeleteExpr*>(DE->getDeleteExpr()); 5122 Helper.handledStmt(cast<Stmt>(DelExpr->getArgument()), OS); 5123 OS << "->~" << RD->getName().str() << "()"; 5124 OS << " (Implicit destructor)\n"; 5125 } else if (Optional<CFGBaseDtor> BE = E.getAs<CFGBaseDtor>()) { 5126 const CXXBaseSpecifier *BS = BE->getBaseSpecifier(); 5127 OS << "~" << BS->getType()->getAsCXXRecordDecl()->getName() << "()"; 5128 OS << " (Base object destructor)\n"; 5129 } else if (Optional<CFGMemberDtor> ME = E.getAs<CFGMemberDtor>()) { 5130 const FieldDecl *FD = ME->getFieldDecl(); 5131 const Type *T = FD->getType()->getBaseElementTypeUnsafe(); 5132 OS << "this->" << FD->getName(); 5133 OS << ".~" << T->getAsCXXRecordDecl()->getName() << "()"; 5134 OS << " (Member object destructor)\n"; 5135 } else if (Optional<CFGTemporaryDtor> TE = E.getAs<CFGTemporaryDtor>()) { 5136 const CXXBindTemporaryExpr *BT = TE->getBindTemporaryExpr(); 5137 OS << "~"; 5138 BT->getType().print(OS, PrintingPolicy(Helper.getLangOpts())); 5139 OS << "() (Temporary object destructor)\n"; 5140 } 5141 } 5142 5143 static void print_block(raw_ostream &OS, const CFG* cfg, 5144 const CFGBlock &B, 5145 StmtPrinterHelper &Helper, bool print_edges, 5146 bool ShowColors) { 5147 Helper.setBlockID(B.getBlockID()); 5148 5149 // Print the header. 5150 if (ShowColors) 5151 OS.changeColor(raw_ostream::YELLOW, true); 5152 5153 OS << "\n [B" << B.getBlockID(); 5154 5155 if (&B == &cfg->getEntry()) 5156 OS << " (ENTRY)]\n"; 5157 else if (&B == &cfg->getExit()) 5158 OS << " (EXIT)]\n"; 5159 else if (&B == cfg->getIndirectGotoBlock()) 5160 OS << " (INDIRECT GOTO DISPATCH)]\n"; 5161 else if (B.hasNoReturnElement()) 5162 OS << " (NORETURN)]\n"; 5163 else 5164 OS << "]\n"; 5165 5166 if (ShowColors) 5167 OS.resetColor(); 5168 5169 // Print the label of this block. 5170 if (Stmt *Label = const_cast<Stmt*>(B.getLabel())) { 5171 if (print_edges) 5172 OS << " "; 5173 5174 if (LabelStmt *L = dyn_cast<LabelStmt>(Label)) 5175 OS << L->getName(); 5176 else if (CaseStmt *C = dyn_cast<CaseStmt>(Label)) { 5177 OS << "case "; 5178 if (C->getLHS()) 5179 C->getLHS()->printPretty(OS, &Helper, 5180 PrintingPolicy(Helper.getLangOpts())); 5181 if (C->getRHS()) { 5182 OS << " ... "; 5183 C->getRHS()->printPretty(OS, &Helper, 5184 PrintingPolicy(Helper.getLangOpts())); 5185 } 5186 } else if (isa<DefaultStmt>(Label)) 5187 OS << "default"; 5188 else if (CXXCatchStmt *CS = dyn_cast<CXXCatchStmt>(Label)) { 5189 OS << "catch ("; 5190 if (CS->getExceptionDecl()) 5191 CS->getExceptionDecl()->print(OS, PrintingPolicy(Helper.getLangOpts()), 5192 0); 5193 else 5194 OS << "..."; 5195 OS << ")"; 5196 } else if (SEHExceptStmt *ES = dyn_cast<SEHExceptStmt>(Label)) { 5197 OS << "__except ("; 5198 ES->getFilterExpr()->printPretty(OS, &Helper, 5199 PrintingPolicy(Helper.getLangOpts()), 0); 5200 OS << ")"; 5201 } else 5202 llvm_unreachable("Invalid label statement in CFGBlock."); 5203 5204 OS << ":\n"; 5205 } 5206 5207 // Iterate through the statements in the block and print them. 5208 unsigned j = 1; 5209 5210 for (CFGBlock::const_iterator I = B.begin(), E = B.end() ; 5211 I != E ; ++I, ++j ) { 5212 // Print the statement # in the basic block and the statement itself. 5213 if (print_edges) 5214 OS << " "; 5215 5216 OS << llvm::format("%3d", j) << ": "; 5217 5218 Helper.setStmtID(j); 5219 5220 print_elem(OS, Helper, *I); 5221 } 5222 5223 // Print the terminator of this block. 5224 if (B.getTerminator()) { 5225 if (ShowColors) 5226 OS.changeColor(raw_ostream::GREEN); 5227 5228 OS << " T: "; 5229 5230 Helper.setBlockID(-1); 5231 5232 PrintingPolicy PP(Helper.getLangOpts()); 5233 CFGBlockTerminatorPrint TPrinter(OS, &Helper, PP); 5234 TPrinter.print(B.getTerminator()); 5235 OS << '\n'; 5236 5237 if (ShowColors) 5238 OS.resetColor(); 5239 } 5240 5241 if (print_edges) { 5242 // Print the predecessors of this block. 5243 if (!B.pred_empty()) { 5244 const raw_ostream::Colors Color = raw_ostream::BLUE; 5245 if (ShowColors) 5246 OS.changeColor(Color); 5247 OS << " Preds " ; 5248 if (ShowColors) 5249 OS.resetColor(); 5250 OS << '(' << B.pred_size() << "):"; 5251 unsigned i = 0; 5252 5253 if (ShowColors) 5254 OS.changeColor(Color); 5255 5256 for (CFGBlock::const_pred_iterator I = B.pred_begin(), E = B.pred_end(); 5257 I != E; ++I, ++i) { 5258 if (i % 10 == 8) 5259 OS << "\n "; 5260 5261 CFGBlock *B = *I; 5262 bool Reachable = true; 5263 if (!B) { 5264 Reachable = false; 5265 B = I->getPossiblyUnreachableBlock(); 5266 } 5267 5268 OS << " B" << B->getBlockID(); 5269 if (!Reachable) 5270 OS << "(Unreachable)"; 5271 } 5272 5273 if (ShowColors) 5274 OS.resetColor(); 5275 5276 OS << '\n'; 5277 } 5278 5279 // Print the successors of this block. 5280 if (!B.succ_empty()) { 5281 const raw_ostream::Colors Color = raw_ostream::MAGENTA; 5282 if (ShowColors) 5283 OS.changeColor(Color); 5284 OS << " Succs "; 5285 if (ShowColors) 5286 OS.resetColor(); 5287 OS << '(' << B.succ_size() << "):"; 5288 unsigned i = 0; 5289 5290 if (ShowColors) 5291 OS.changeColor(Color); 5292 5293 for (CFGBlock::const_succ_iterator I = B.succ_begin(), E = B.succ_end(); 5294 I != E; ++I, ++i) { 5295 if (i % 10 == 8) 5296 OS << "\n "; 5297 5298 CFGBlock *B = *I; 5299 5300 bool Reachable = true; 5301 if (!B) { 5302 Reachable = false; 5303 B = I->getPossiblyUnreachableBlock(); 5304 } 5305 5306 if (B) { 5307 OS << " B" << B->getBlockID(); 5308 if (!Reachable) 5309 OS << "(Unreachable)"; 5310 } 5311 else { 5312 OS << " NULL"; 5313 } 5314 } 5315 5316 if (ShowColors) 5317 OS.resetColor(); 5318 OS << '\n'; 5319 } 5320 } 5321 } 5322 5323 /// dump - A simple pretty printer of a CFG that outputs to stderr. 5324 void CFG::dump(const LangOptions &LO, bool ShowColors) const { 5325 print(llvm::errs(), LO, ShowColors); 5326 } 5327 5328 /// print - A simple pretty printer of a CFG that outputs to an ostream. 5329 void CFG::print(raw_ostream &OS, const LangOptions &LO, bool ShowColors) const { 5330 StmtPrinterHelper Helper(this, LO); 5331 5332 // Print the entry block. 5333 print_block(OS, this, getEntry(), Helper, true, ShowColors); 5334 5335 // Iterate through the CFGBlocks and print them one by one. 5336 for (const_iterator I = Blocks.begin(), E = Blocks.end() ; I != E ; ++I) { 5337 // Skip the entry block, because we already printed it. 5338 if (&(**I) == &getEntry() || &(**I) == &getExit()) 5339 continue; 5340 5341 print_block(OS, this, **I, Helper, true, ShowColors); 5342 } 5343 5344 // Print the exit block. 5345 print_block(OS, this, getExit(), Helper, true, ShowColors); 5346 OS << '\n'; 5347 OS.flush(); 5348 } 5349 5350 /// dump - A simply pretty printer of a CFGBlock that outputs to stderr. 5351 void CFGBlock::dump(const CFG* cfg, const LangOptions &LO, 5352 bool ShowColors) const { 5353 print(llvm::errs(), cfg, LO, ShowColors); 5354 } 5355 5356 LLVM_DUMP_METHOD void CFGBlock::dump() const { 5357 dump(getParent(), LangOptions(), false); 5358 } 5359 5360 /// print - A simple pretty printer of a CFGBlock that outputs to an ostream. 5361 /// Generally this will only be called from CFG::print. 5362 void CFGBlock::print(raw_ostream &OS, const CFG* cfg, 5363 const LangOptions &LO, bool ShowColors) const { 5364 StmtPrinterHelper Helper(cfg, LO); 5365 print_block(OS, cfg, *this, Helper, true, ShowColors); 5366 OS << '\n'; 5367 } 5368 5369 /// printTerminator - A simple pretty printer of the terminator of a CFGBlock. 5370 void CFGBlock::printTerminator(raw_ostream &OS, 5371 const LangOptions &LO) const { 5372 CFGBlockTerminatorPrint TPrinter(OS, nullptr, PrintingPolicy(LO)); 5373 TPrinter.print(getTerminator()); 5374 } 5375 5376 Stmt *CFGBlock::getTerminatorCondition(bool StripParens) { 5377 Stmt *Terminator = this->Terminator; 5378 if (!Terminator) 5379 return nullptr; 5380 5381 Expr *E = nullptr; 5382 5383 switch (Terminator->getStmtClass()) { 5384 default: 5385 break; 5386 5387 case Stmt::CXXForRangeStmtClass: 5388 E = cast<CXXForRangeStmt>(Terminator)->getCond(); 5389 break; 5390 5391 case Stmt::ForStmtClass: 5392 E = cast<ForStmt>(Terminator)->getCond(); 5393 break; 5394 5395 case Stmt::WhileStmtClass: 5396 E = cast<WhileStmt>(Terminator)->getCond(); 5397 break; 5398 5399 case Stmt::DoStmtClass: 5400 E = cast<DoStmt>(Terminator)->getCond(); 5401 break; 5402 5403 case Stmt::IfStmtClass: 5404 E = cast<IfStmt>(Terminator)->getCond(); 5405 break; 5406 5407 case Stmt::ChooseExprClass: 5408 E = cast<ChooseExpr>(Terminator)->getCond(); 5409 break; 5410 5411 case Stmt::IndirectGotoStmtClass: 5412 E = cast<IndirectGotoStmt>(Terminator)->getTarget(); 5413 break; 5414 5415 case Stmt::SwitchStmtClass: 5416 E = cast<SwitchStmt>(Terminator)->getCond(); 5417 break; 5418 5419 case Stmt::BinaryConditionalOperatorClass: 5420 E = cast<BinaryConditionalOperator>(Terminator)->getCond(); 5421 break; 5422 5423 case Stmt::ConditionalOperatorClass: 5424 E = cast<ConditionalOperator>(Terminator)->getCond(); 5425 break; 5426 5427 case Stmt::BinaryOperatorClass: // '&&' and '||' 5428 E = cast<BinaryOperator>(Terminator)->getLHS(); 5429 break; 5430 5431 case Stmt::ObjCForCollectionStmtClass: 5432 return Terminator; 5433 } 5434 5435 if (!StripParens) 5436 return E; 5437 5438 return E ? E->IgnoreParens() : nullptr; 5439 } 5440 5441 //===----------------------------------------------------------------------===// 5442 // CFG Graphviz Visualization 5443 //===----------------------------------------------------------------------===// 5444 5445 #ifndef NDEBUG 5446 static StmtPrinterHelper* GraphHelper; 5447 #endif 5448 5449 void CFG::viewCFG(const LangOptions &LO) const { 5450 #ifndef NDEBUG 5451 StmtPrinterHelper H(this, LO); 5452 GraphHelper = &H; 5453 llvm::ViewGraph(this,"CFG"); 5454 GraphHelper = nullptr; 5455 #endif 5456 } 5457 5458 namespace llvm { 5459 5460 template<> 5461 struct DOTGraphTraits<const CFG*> : public DefaultDOTGraphTraits { 5462 DOTGraphTraits(bool isSimple = false) : DefaultDOTGraphTraits(isSimple) {} 5463 5464 static std::string getNodeLabel(const CFGBlock *Node, const CFG* Graph) { 5465 #ifndef NDEBUG 5466 std::string OutSStr; 5467 llvm::raw_string_ostream Out(OutSStr); 5468 print_block(Out,Graph, *Node, *GraphHelper, false, false); 5469 std::string& OutStr = Out.str(); 5470 5471 if (OutStr[0] == '\n') OutStr.erase(OutStr.begin()); 5472 5473 // Process string output to make it nicer... 5474 for (unsigned i = 0; i != OutStr.length(); ++i) 5475 if (OutStr[i] == '\n') { // Left justify 5476 OutStr[i] = '\\'; 5477 OutStr.insert(OutStr.begin()+i+1, 'l'); 5478 } 5479 5480 return OutStr; 5481 #else 5482 return {}; 5483 #endif 5484 } 5485 }; 5486 5487 } // namespace llvm 5488