CFG.h revision 298038352b34c5503db418201f3ddea6e56fd0e1
1//===--- CFG.h - Classes for representing and building CFGs------*- C++ -*-===// 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#ifndef LLVM_CLANG_CFG_H 16#define LLVM_CLANG_CFG_H 17 18#include "llvm/ADT/PointerIntPair.h" 19#include "llvm/ADT/GraphTraits.h" 20#include "llvm/Support/Allocator.h" 21#include "llvm/Support/Casting.h" 22#include "llvm/ADT/OwningPtr.h" 23#include "llvm/ADT/DenseMap.h" 24#include "llvm/ADT/BitVector.h" 25#include "clang/AST/Stmt.h" 26#include "clang/Analysis/Support/BumpVector.h" 27#include "clang/Basic/SourceLocation.h" 28#include <cassert> 29#include <iterator> 30 31namespace clang { 32 class CXXDestructorDecl; 33 class Decl; 34 class Stmt; 35 class Expr; 36 class FieldDecl; 37 class VarDecl; 38 class CXXCtorInitializer; 39 class CXXBaseSpecifier; 40 class CXXBindTemporaryExpr; 41 class CFG; 42 class PrinterHelper; 43 class LangOptions; 44 class ASTContext; 45 46/// CFGElement - Represents a top-level expression in a basic block. 47class CFGElement { 48public: 49 enum Kind { 50 // main kind 51 Invalid, 52 Statement, 53 Initializer, 54 // dtor kind 55 AutomaticObjectDtor, 56 BaseDtor, 57 MemberDtor, 58 TemporaryDtor, 59 DTOR_BEGIN = AutomaticObjectDtor, 60 DTOR_END = TemporaryDtor 61 }; 62 63protected: 64 // The int bits are used to mark the kind. 65 llvm::PointerIntPair<void *, 2> Data1; 66 llvm::PointerIntPair<void *, 2> Data2; 67 68 CFGElement(Kind kind, const void *Ptr1, const void *Ptr2 = 0) 69 : Data1(const_cast<void*>(Ptr1), ((unsigned) kind) & 0x3), 70 Data2(const_cast<void*>(Ptr2), (((unsigned) kind) >> 2) & 0x3) {} 71 72public: 73 CFGElement() {} 74 75 Kind getKind() const { 76 unsigned x = Data2.getInt(); 77 x <<= 2; 78 x |= Data1.getInt(); 79 return (Kind) x; 80 } 81 82 bool isValid() const { return getKind() != Invalid; } 83 84 operator bool() const { return isValid(); } 85 86 template<class ElemTy> const ElemTy *getAs() const { 87 if (llvm::isa<ElemTy>(this)) 88 return static_cast<const ElemTy*>(this); 89 return 0; 90 } 91 92 static bool classof(const CFGElement *E) { return true; } 93}; 94 95class CFGStmt : public CFGElement { 96public: 97 CFGStmt(Stmt *S) : CFGElement(Statement, S) {} 98 99 const Stmt *getStmt() const { 100 return static_cast<const Stmt *>(Data1.getPointer()); 101 } 102 103 static bool classof(const CFGElement *E) { 104 return E->getKind() == Statement; 105 } 106}; 107 108/// CFGInitializer - Represents C++ base or member initializer from 109/// constructor's initialization list. 110class CFGInitializer : public CFGElement { 111public: 112 CFGInitializer(CXXCtorInitializer *initializer) 113 : CFGElement(Initializer, initializer) {} 114 115 CXXCtorInitializer* getInitializer() const { 116 return static_cast<CXXCtorInitializer*>(Data1.getPointer()); 117 } 118 119 static bool classof(const CFGElement *E) { 120 return E->getKind() == Initializer; 121 } 122}; 123 124/// CFGImplicitDtor - Represents C++ object destructor implicitly generated 125/// by compiler on various occasions. 126class CFGImplicitDtor : public CFGElement { 127protected: 128 CFGImplicitDtor(Kind kind, const void *data1, const void *data2 = 0) 129 : CFGElement(kind, data1, data2) { 130 assert(kind >= DTOR_BEGIN && kind <= DTOR_END); 131 } 132 133public: 134 const CXXDestructorDecl *getDestructorDecl(ASTContext &astContext) const; 135 bool isNoReturn(ASTContext &astContext) const; 136 137 static bool classof(const CFGElement *E) { 138 Kind kind = E->getKind(); 139 return kind >= DTOR_BEGIN && kind <= DTOR_END; 140 } 141}; 142 143/// CFGAutomaticObjDtor - Represents C++ object destructor implicitly generated 144/// for automatic object or temporary bound to const reference at the point 145/// of leaving its local scope. 146class CFGAutomaticObjDtor: public CFGImplicitDtor { 147public: 148 CFGAutomaticObjDtor(const VarDecl *var, const Stmt *stmt) 149 : CFGImplicitDtor(AutomaticObjectDtor, var, stmt) {} 150 151 const VarDecl *getVarDecl() const { 152 return static_cast<VarDecl*>(Data1.getPointer()); 153 } 154 155 // Get statement end of which triggered the destructor call. 156 const Stmt *getTriggerStmt() const { 157 return static_cast<Stmt*>(Data2.getPointer()); 158 } 159 160 static bool classof(const CFGElement *elem) { 161 return elem->getKind() == AutomaticObjectDtor; 162 } 163}; 164 165/// CFGBaseDtor - Represents C++ object destructor implicitly generated for 166/// base object in destructor. 167class CFGBaseDtor : public CFGImplicitDtor { 168public: 169 CFGBaseDtor(const CXXBaseSpecifier *base) 170 : CFGImplicitDtor(BaseDtor, base) {} 171 172 const CXXBaseSpecifier *getBaseSpecifier() const { 173 return static_cast<const CXXBaseSpecifier*>(Data1.getPointer()); 174 } 175 176 static bool classof(const CFGElement *E) { 177 return E->getKind() == BaseDtor; 178 } 179}; 180 181/// CFGMemberDtor - Represents C++ object destructor implicitly generated for 182/// member object in destructor. 183class CFGMemberDtor : public CFGImplicitDtor { 184public: 185 CFGMemberDtor(const FieldDecl *field) 186 : CFGImplicitDtor(MemberDtor, field, 0) {} 187 188 const FieldDecl *getFieldDecl() const { 189 return static_cast<const FieldDecl*>(Data1.getPointer()); 190 } 191 192 static bool classof(const CFGElement *E) { 193 return E->getKind() == MemberDtor; 194 } 195}; 196 197/// CFGTemporaryDtor - Represents C++ object destructor implicitly generated 198/// at the end of full expression for temporary object. 199class CFGTemporaryDtor : public CFGImplicitDtor { 200public: 201 CFGTemporaryDtor(CXXBindTemporaryExpr *expr) 202 : CFGImplicitDtor(TemporaryDtor, expr, 0) {} 203 204 const CXXBindTemporaryExpr *getBindTemporaryExpr() const { 205 return static_cast<const CXXBindTemporaryExpr *>(Data1.getPointer()); 206 } 207 208 static bool classof(const CFGElement *E) { 209 return E->getKind() == TemporaryDtor; 210 } 211}; 212 213/// CFGTerminator - Represents CFGBlock terminator statement. 214/// 215/// TemporaryDtorsBranch bit is set to true if the terminator marks a branch 216/// in control flow of destructors of temporaries. In this case terminator 217/// statement is the same statement that branches control flow in evaluation 218/// of matching full expression. 219class CFGTerminator { 220 llvm::PointerIntPair<Stmt *, 1> Data; 221public: 222 CFGTerminator() {} 223 CFGTerminator(Stmt *S, bool TemporaryDtorsBranch = false) 224 : Data(S, TemporaryDtorsBranch) {} 225 226 Stmt *getStmt() { return Data.getPointer(); } 227 const Stmt *getStmt() const { return Data.getPointer(); } 228 229 bool isTemporaryDtorsBranch() const { return Data.getInt(); } 230 231 operator Stmt *() { return getStmt(); } 232 operator const Stmt *() const { return getStmt(); } 233 234 Stmt *operator->() { return getStmt(); } 235 const Stmt *operator->() const { return getStmt(); } 236 237 Stmt &operator*() { return *getStmt(); } 238 const Stmt &operator*() const { return *getStmt(); } 239 240 operator bool() const { return getStmt(); } 241}; 242 243/// CFGBlock - Represents a single basic block in a source-level CFG. 244/// It consists of: 245/// 246/// (1) A set of statements/expressions (which may contain subexpressions). 247/// (2) A "terminator" statement (not in the set of statements). 248/// (3) A list of successors and predecessors. 249/// 250/// Terminator: The terminator represents the type of control-flow that occurs 251/// at the end of the basic block. The terminator is a Stmt* referring to an 252/// AST node that has control-flow: if-statements, breaks, loops, etc. 253/// If the control-flow is conditional, the condition expression will appear 254/// within the set of statements in the block (usually the last statement). 255/// 256/// Predecessors: the order in the set of predecessors is arbitrary. 257/// 258/// Successors: the order in the set of successors is NOT arbitrary. We 259/// currently have the following orderings based on the terminator: 260/// 261/// Terminator Successor Ordering 262/// ----------------------------------------------------- 263/// if Then Block; Else Block 264/// ? operator LHS expression; RHS expression 265/// &&, || expression that uses result of && or ||, RHS 266/// 267/// But note that any of that may be NULL in case of optimized-out edges. 268/// 269class CFGBlock { 270 class ElementList { 271 typedef BumpVector<CFGElement> ImplTy; 272 ImplTy Impl; 273 public: 274 ElementList(BumpVectorContext &C) : Impl(C, 4) {} 275 276 typedef std::reverse_iterator<ImplTy::iterator> iterator; 277 typedef std::reverse_iterator<ImplTy::const_iterator> const_iterator; 278 typedef ImplTy::iterator reverse_iterator; 279 typedef ImplTy::const_iterator const_reverse_iterator; 280 typedef ImplTy::const_reference const_reference; 281 282 void push_back(CFGElement e, BumpVectorContext &C) { Impl.push_back(e, C); } 283 reverse_iterator insert(reverse_iterator I, size_t Cnt, CFGElement E, 284 BumpVectorContext &C) { 285 return Impl.insert(I, Cnt, E, C); 286 } 287 288 const_reference front() const { return Impl.back(); } 289 const_reference back() const { return Impl.front(); } 290 291 iterator begin() { return Impl.rbegin(); } 292 iterator end() { return Impl.rend(); } 293 const_iterator begin() const { return Impl.rbegin(); } 294 const_iterator end() const { return Impl.rend(); } 295 reverse_iterator rbegin() { return Impl.begin(); } 296 reverse_iterator rend() { return Impl.end(); } 297 const_reverse_iterator rbegin() const { return Impl.begin(); } 298 const_reverse_iterator rend() const { return Impl.end(); } 299 300 CFGElement operator[](size_t i) const { 301 assert(i < Impl.size()); 302 return Impl[Impl.size() - 1 - i]; 303 } 304 305 size_t size() const { return Impl.size(); } 306 bool empty() const { return Impl.empty(); } 307 }; 308 309 /// Stmts - The set of statements in the basic block. 310 ElementList Elements; 311 312 /// Label - An (optional) label that prefixes the executable 313 /// statements in the block. When this variable is non-NULL, it is 314 /// either an instance of LabelStmt, SwitchCase or CXXCatchStmt. 315 Stmt *Label; 316 317 /// Terminator - The terminator for a basic block that 318 /// indicates the type of control-flow that occurs between a block 319 /// and its successors. 320 CFGTerminator Terminator; 321 322 /// LoopTarget - Some blocks are used to represent the "loop edge" to 323 /// the start of a loop from within the loop body. This Stmt* will be 324 /// refer to the loop statement for such blocks (and be null otherwise). 325 const Stmt *LoopTarget; 326 327 /// BlockID - A numerical ID assigned to a CFGBlock during construction 328 /// of the CFG. 329 unsigned BlockID; 330 331 /// Predecessors/Successors - Keep track of the predecessor / successor 332 /// CFG blocks. 333 typedef BumpVector<CFGBlock*> AdjacentBlocks; 334 AdjacentBlocks Preds; 335 AdjacentBlocks Succs; 336 337 /// NoReturn - This bit is set when the basic block contains a function call 338 /// or implicit destructor that is attributed as 'noreturn'. In that case, 339 /// control cannot technically ever proceed past this block. All such blocks 340 /// will have a single immediate successor: the exit block. This allows them 341 /// to be easily reached from the exit block and using this bit quickly 342 /// recognized without scanning the contents of the block. 343 /// 344 /// Optimization Note: This bit could be profitably folded with Terminator's 345 /// storage if the memory usage of CFGBlock becomes an issue. 346 unsigned HasNoReturnElement : 1; 347 348 /// Parent - The parent CFG that owns this CFGBlock. 349 CFG *Parent; 350 351public: 352 explicit CFGBlock(unsigned blockid, BumpVectorContext &C, CFG *parent) 353 : Elements(C), Label(NULL), Terminator(NULL), LoopTarget(NULL), 354 BlockID(blockid), Preds(C, 1), Succs(C, 1), HasNoReturnElement(false), 355 Parent(parent) {} 356 ~CFGBlock() {} 357 358 // Statement iterators 359 typedef ElementList::iterator iterator; 360 typedef ElementList::const_iterator const_iterator; 361 typedef ElementList::reverse_iterator reverse_iterator; 362 typedef ElementList::const_reverse_iterator const_reverse_iterator; 363 364 CFGElement front() const { return Elements.front(); } 365 CFGElement back() const { return Elements.back(); } 366 367 iterator begin() { return Elements.begin(); } 368 iterator end() { return Elements.end(); } 369 const_iterator begin() const { return Elements.begin(); } 370 const_iterator end() const { return Elements.end(); } 371 372 reverse_iterator rbegin() { return Elements.rbegin(); } 373 reverse_iterator rend() { return Elements.rend(); } 374 const_reverse_iterator rbegin() const { return Elements.rbegin(); } 375 const_reverse_iterator rend() const { return Elements.rend(); } 376 377 unsigned size() const { return Elements.size(); } 378 bool empty() const { return Elements.empty(); } 379 380 CFGElement operator[](size_t i) const { return Elements[i]; } 381 382 // CFG iterators 383 typedef AdjacentBlocks::iterator pred_iterator; 384 typedef AdjacentBlocks::const_iterator const_pred_iterator; 385 typedef AdjacentBlocks::reverse_iterator pred_reverse_iterator; 386 typedef AdjacentBlocks::const_reverse_iterator const_pred_reverse_iterator; 387 388 typedef AdjacentBlocks::iterator succ_iterator; 389 typedef AdjacentBlocks::const_iterator const_succ_iterator; 390 typedef AdjacentBlocks::reverse_iterator succ_reverse_iterator; 391 typedef AdjacentBlocks::const_reverse_iterator const_succ_reverse_iterator; 392 393 pred_iterator pred_begin() { return Preds.begin(); } 394 pred_iterator pred_end() { return Preds.end(); } 395 const_pred_iterator pred_begin() const { return Preds.begin(); } 396 const_pred_iterator pred_end() const { return Preds.end(); } 397 398 pred_reverse_iterator pred_rbegin() { return Preds.rbegin(); } 399 pred_reverse_iterator pred_rend() { return Preds.rend(); } 400 const_pred_reverse_iterator pred_rbegin() const { return Preds.rbegin(); } 401 const_pred_reverse_iterator pred_rend() const { return Preds.rend(); } 402 403 succ_iterator succ_begin() { return Succs.begin(); } 404 succ_iterator succ_end() { return Succs.end(); } 405 const_succ_iterator succ_begin() const { return Succs.begin(); } 406 const_succ_iterator succ_end() const { return Succs.end(); } 407 408 succ_reverse_iterator succ_rbegin() { return Succs.rbegin(); } 409 succ_reverse_iterator succ_rend() { return Succs.rend(); } 410 const_succ_reverse_iterator succ_rbegin() const { return Succs.rbegin(); } 411 const_succ_reverse_iterator succ_rend() const { return Succs.rend(); } 412 413 unsigned succ_size() const { return Succs.size(); } 414 bool succ_empty() const { return Succs.empty(); } 415 416 unsigned pred_size() const { return Preds.size(); } 417 bool pred_empty() const { return Preds.empty(); } 418 419 420 class FilterOptions { 421 public: 422 FilterOptions() { 423 IgnoreDefaultsWithCoveredEnums = 0; 424 } 425 426 unsigned IgnoreDefaultsWithCoveredEnums : 1; 427 }; 428 429 static bool FilterEdge(const FilterOptions &F, const CFGBlock *Src, 430 const CFGBlock *Dst); 431 432 template <typename IMPL, bool IsPred> 433 class FilteredCFGBlockIterator { 434 private: 435 IMPL I, E; 436 const FilterOptions F; 437 const CFGBlock *From; 438 public: 439 explicit FilteredCFGBlockIterator(const IMPL &i, const IMPL &e, 440 const CFGBlock *from, 441 const FilterOptions &f) 442 : I(i), E(e), F(f), From(from) {} 443 444 bool hasMore() const { return I != E; } 445 446 FilteredCFGBlockIterator &operator++() { 447 do { ++I; } while (hasMore() && Filter(*I)); 448 return *this; 449 } 450 451 const CFGBlock *operator*() const { return *I; } 452 private: 453 bool Filter(const CFGBlock *To) { 454 return IsPred ? FilterEdge(F, To, From) : FilterEdge(F, From, To); 455 } 456 }; 457 458 typedef FilteredCFGBlockIterator<const_pred_iterator, true> 459 filtered_pred_iterator; 460 461 typedef FilteredCFGBlockIterator<const_succ_iterator, false> 462 filtered_succ_iterator; 463 464 filtered_pred_iterator filtered_pred_start_end(const FilterOptions &f) const { 465 return filtered_pred_iterator(pred_begin(), pred_end(), this, f); 466 } 467 468 filtered_succ_iterator filtered_succ_start_end(const FilterOptions &f) const { 469 return filtered_succ_iterator(succ_begin(), succ_end(), this, f); 470 } 471 472 // Manipulation of block contents 473 474 void setTerminator(Stmt *Statement) { Terminator = Statement; } 475 void setLabel(Stmt *Statement) { Label = Statement; } 476 void setLoopTarget(const Stmt *loopTarget) { LoopTarget = loopTarget; } 477 void setHasNoReturnElement() { HasNoReturnElement = true; } 478 479 CFGTerminator getTerminator() { return Terminator; } 480 const CFGTerminator getTerminator() const { return Terminator; } 481 482 Stmt *getTerminatorCondition(); 483 484 const Stmt *getTerminatorCondition() const { 485 return const_cast<CFGBlock*>(this)->getTerminatorCondition(); 486 } 487 488 const Stmt *getLoopTarget() const { return LoopTarget; } 489 490 Stmt *getLabel() { return Label; } 491 const Stmt *getLabel() const { return Label; } 492 493 bool hasNoReturnElement() const { return HasNoReturnElement; } 494 495 unsigned getBlockID() const { return BlockID; } 496 497 CFG *getParent() const { return Parent; } 498 499 void dump(const CFG *cfg, const LangOptions &LO, bool ShowColors = false) const; 500 void print(raw_ostream &OS, const CFG* cfg, const LangOptions &LO, 501 bool ShowColors) const; 502 void printTerminator(raw_ostream &OS, const LangOptions &LO) const; 503 504 void addSuccessor(CFGBlock *Block, BumpVectorContext &C) { 505 if (Block) 506 Block->Preds.push_back(this, C); 507 Succs.push_back(Block, C); 508 } 509 510 void appendStmt(Stmt *statement, BumpVectorContext &C) { 511 Elements.push_back(CFGStmt(statement), C); 512 } 513 514 void appendInitializer(CXXCtorInitializer *initializer, 515 BumpVectorContext &C) { 516 Elements.push_back(CFGInitializer(initializer), C); 517 } 518 519 void appendBaseDtor(const CXXBaseSpecifier *BS, BumpVectorContext &C) { 520 Elements.push_back(CFGBaseDtor(BS), C); 521 } 522 523 void appendMemberDtor(FieldDecl *FD, BumpVectorContext &C) { 524 Elements.push_back(CFGMemberDtor(FD), C); 525 } 526 527 void appendTemporaryDtor(CXXBindTemporaryExpr *E, BumpVectorContext &C) { 528 Elements.push_back(CFGTemporaryDtor(E), C); 529 } 530 531 void appendAutomaticObjDtor(VarDecl *VD, Stmt *S, BumpVectorContext &C) { 532 Elements.push_back(CFGAutomaticObjDtor(VD, S), C); 533 } 534 535 // Destructors must be inserted in reversed order. So insertion is in two 536 // steps. First we prepare space for some number of elements, then we insert 537 // the elements beginning at the last position in prepared space. 538 iterator beginAutomaticObjDtorsInsert(iterator I, size_t Cnt, 539 BumpVectorContext &C) { 540 return iterator(Elements.insert(I.base(), Cnt, CFGElement(), C)); 541 } 542 iterator insertAutomaticObjDtor(iterator I, VarDecl *VD, Stmt *S) { 543 *I = CFGAutomaticObjDtor(VD, S); 544 return ++I; 545 } 546}; 547 548/// CFG - Represents a source-level, intra-procedural CFG that represents the 549/// control-flow of a Stmt. The Stmt can represent an entire function body, 550/// or a single expression. A CFG will always contain one empty block that 551/// represents the Exit point of the CFG. A CFG will also contain a designated 552/// Entry block. The CFG solely represents control-flow; it consists of 553/// CFGBlocks which are simply containers of Stmt*'s in the AST the CFG 554/// was constructed from. 555class CFG { 556public: 557 //===--------------------------------------------------------------------===// 558 // CFG Construction & Manipulation. 559 //===--------------------------------------------------------------------===// 560 561 class BuildOptions { 562 llvm::BitVector alwaysAddMask; 563 public: 564 typedef llvm::DenseMap<const Stmt *, const CFGBlock*> ForcedBlkExprs; 565 ForcedBlkExprs **forcedBlkExprs; 566 567 bool PruneTriviallyFalseEdges; 568 bool AddEHEdges; 569 bool AddInitializers; 570 bool AddImplicitDtors; 571 572 bool alwaysAdd(const Stmt *stmt) const { 573 return alwaysAddMask[stmt->getStmtClass()]; 574 } 575 576 BuildOptions &setAlwaysAdd(Stmt::StmtClass stmtClass, bool val = true) { 577 alwaysAddMask[stmtClass] = val; 578 return *this; 579 } 580 581 BuildOptions &setAllAlwaysAdd() { 582 alwaysAddMask.set(); 583 return *this; 584 } 585 586 BuildOptions() 587 : alwaysAddMask(Stmt::lastStmtConstant, false) 588 ,forcedBlkExprs(0), PruneTriviallyFalseEdges(true) 589 ,AddEHEdges(false) 590 ,AddInitializers(false) 591 ,AddImplicitDtors(false) {} 592 }; 593 594 /// \brief Provides a custom implementation of the iterator class to have the 595 /// same interface as Function::iterator - iterator returns CFGBlock 596 /// (not a pointer to CFGBlock). 597 class graph_iterator { 598 public: 599 typedef const CFGBlock value_type; 600 typedef value_type& reference; 601 typedef value_type* pointer; 602 typedef BumpVector<CFGBlock*>::iterator ImplTy; 603 604 graph_iterator(const ImplTy &i) : I(i) {} 605 606 bool operator==(const graph_iterator &X) const { return I == X.I; } 607 bool operator!=(const graph_iterator &X) const { return I != X.I; } 608 609 reference operator*() const { return **I; } 610 pointer operator->() const { return *I; } 611 operator CFGBlock* () { return *I; } 612 613 graph_iterator &operator++() { ++I; return *this; } 614 graph_iterator &operator--() { --I; return *this; } 615 616 private: 617 ImplTy I; 618 }; 619 620 class const_graph_iterator { 621 public: 622 typedef const CFGBlock value_type; 623 typedef value_type& reference; 624 typedef value_type* pointer; 625 typedef BumpVector<CFGBlock*>::const_iterator ImplTy; 626 627 const_graph_iterator(const ImplTy &i) : I(i) {} 628 629 bool operator==(const const_graph_iterator &X) const { return I == X.I; } 630 bool operator!=(const const_graph_iterator &X) const { return I != X.I; } 631 632 reference operator*() const { return **I; } 633 pointer operator->() const { return *I; } 634 operator CFGBlock* () const { return *I; } 635 636 const_graph_iterator &operator++() { ++I; return *this; } 637 const_graph_iterator &operator--() { --I; return *this; } 638 639 private: 640 ImplTy I; 641 }; 642 643 /// buildCFG - Builds a CFG from an AST. The responsibility to free the 644 /// constructed CFG belongs to the caller. 645 static CFG* buildCFG(const Decl *D, Stmt *AST, ASTContext *C, 646 const BuildOptions &BO); 647 648 /// createBlock - Create a new block in the CFG. The CFG owns the block; 649 /// the caller should not directly free it. 650 CFGBlock *createBlock(); 651 652 /// setEntry - Set the entry block of the CFG. This is typically used 653 /// only during CFG construction. Most CFG clients expect that the 654 /// entry block has no predecessors and contains no statements. 655 void setEntry(CFGBlock *B) { Entry = B; } 656 657 /// setIndirectGotoBlock - Set the block used for indirect goto jumps. 658 /// This is typically used only during CFG construction. 659 void setIndirectGotoBlock(CFGBlock *B) { IndirectGotoBlock = B; } 660 661 //===--------------------------------------------------------------------===// 662 // Block Iterators 663 //===--------------------------------------------------------------------===// 664 665 typedef BumpVector<CFGBlock*> CFGBlockListTy; 666 typedef CFGBlockListTy::iterator iterator; 667 typedef CFGBlockListTy::const_iterator const_iterator; 668 typedef std::reverse_iterator<iterator> reverse_iterator; 669 typedef std::reverse_iterator<const_iterator> const_reverse_iterator; 670 671 CFGBlock & front() { return *Blocks.front(); } 672 CFGBlock & back() { return *Blocks.back(); } 673 674 iterator begin() { return Blocks.begin(); } 675 iterator end() { return Blocks.end(); } 676 const_iterator begin() const { return Blocks.begin(); } 677 const_iterator end() const { return Blocks.end(); } 678 679 graph_iterator nodes_begin() { return graph_iterator(Blocks.begin()); } 680 graph_iterator nodes_end() { return graph_iterator(Blocks.end()); } 681 const_graph_iterator nodes_begin() const { 682 return const_graph_iterator(Blocks.begin()); 683 } 684 const_graph_iterator nodes_end() const { 685 return const_graph_iterator(Blocks.end()); 686 } 687 688 reverse_iterator rbegin() { return Blocks.rbegin(); } 689 reverse_iterator rend() { return Blocks.rend(); } 690 const_reverse_iterator rbegin() const { return Blocks.rbegin(); } 691 const_reverse_iterator rend() const { return Blocks.rend(); } 692 693 CFGBlock & getEntry() { return *Entry; } 694 const CFGBlock & getEntry() const { return *Entry; } 695 CFGBlock & getExit() { return *Exit; } 696 const CFGBlock & getExit() const { return *Exit; } 697 698 CFGBlock * getIndirectGotoBlock() { return IndirectGotoBlock; } 699 const CFGBlock * getIndirectGotoBlock() const { return IndirectGotoBlock; } 700 701 typedef std::vector<const CFGBlock*>::const_iterator try_block_iterator; 702 try_block_iterator try_blocks_begin() const { 703 return TryDispatchBlocks.begin(); 704 } 705 try_block_iterator try_blocks_end() const { 706 return TryDispatchBlocks.end(); 707 } 708 709 void addTryDispatchBlock(const CFGBlock *block) { 710 TryDispatchBlocks.push_back(block); 711 } 712 713 //===--------------------------------------------------------------------===// 714 // Member templates useful for various batch operations over CFGs. 715 //===--------------------------------------------------------------------===// 716 717 template <typename CALLBACK> 718 void VisitBlockStmts(CALLBACK& O) const { 719 for (const_iterator I=begin(), E=end(); I != E; ++I) 720 for (CFGBlock::const_iterator BI=(*I)->begin(), BE=(*I)->end(); 721 BI != BE; ++BI) { 722 if (const CFGStmt *stmt = BI->getAs<CFGStmt>()) 723 O(const_cast<Stmt*>(stmt->getStmt())); 724 } 725 } 726 727 //===--------------------------------------------------------------------===// 728 // CFG Introspection. 729 //===--------------------------------------------------------------------===// 730 731 struct BlkExprNumTy { 732 const signed Idx; 733 explicit BlkExprNumTy(signed idx) : Idx(idx) {} 734 explicit BlkExprNumTy() : Idx(-1) {} 735 operator bool() const { return Idx >= 0; } 736 operator unsigned() const { assert(Idx >=0); return (unsigned) Idx; } 737 }; 738 739 bool isBlkExpr(const Stmt *S) { return getBlkExprNum(S); } 740 bool isBlkExpr(const Stmt *S) const { 741 return const_cast<CFG*>(this)->isBlkExpr(S); 742 } 743 BlkExprNumTy getBlkExprNum(const Stmt *S); 744 unsigned getNumBlkExprs(); 745 746 /// getNumBlockIDs - Returns the total number of BlockIDs allocated (which 747 /// start at 0). 748 unsigned getNumBlockIDs() const { return NumBlockIDs; } 749 750 /// size - Return the total number of CFGBlocks within the CFG 751 /// This is simply a renaming of the getNumBlockIDs(). This is necessary 752 /// because the dominator implementation needs such an interface. 753 unsigned size() const { return NumBlockIDs; } 754 755 //===--------------------------------------------------------------------===// 756 // CFG Debugging: Pretty-Printing and Visualization. 757 //===--------------------------------------------------------------------===// 758 759 void viewCFG(const LangOptions &LO) const; 760 void print(raw_ostream &OS, const LangOptions &LO, bool ShowColors) const; 761 void dump(const LangOptions &LO, bool ShowColors) const; 762 763 //===--------------------------------------------------------------------===// 764 // Internal: constructors and data. 765 //===--------------------------------------------------------------------===// 766 767 CFG() : Entry(NULL), Exit(NULL), IndirectGotoBlock(NULL), NumBlockIDs(0), 768 BlkExprMap(NULL), Blocks(BlkBVC, 10) {} 769 770 ~CFG(); 771 772 llvm::BumpPtrAllocator& getAllocator() { 773 return BlkBVC.getAllocator(); 774 } 775 776 BumpVectorContext &getBumpVectorContext() { 777 return BlkBVC; 778 } 779 780private: 781 CFGBlock *Entry; 782 CFGBlock *Exit; 783 CFGBlock* IndirectGotoBlock; // Special block to contain collective dispatch 784 // for indirect gotos 785 unsigned NumBlockIDs; 786 787 // BlkExprMap - An opaque pointer to prevent inclusion of DenseMap.h. 788 // It represents a map from Expr* to integers to record the set of 789 // block-level expressions and their "statement number" in the CFG. 790 void * BlkExprMap; 791 792 BumpVectorContext BlkBVC; 793 794 CFGBlockListTy Blocks; 795 796 /// C++ 'try' statements are modeled with an indirect dispatch block. 797 /// This is the collection of such blocks present in the CFG. 798 std::vector<const CFGBlock *> TryDispatchBlocks; 799 800}; 801} // end namespace clang 802 803//===----------------------------------------------------------------------===// 804// GraphTraits specializations for CFG basic block graphs (source-level CFGs) 805//===----------------------------------------------------------------------===// 806 807namespace llvm { 808 809/// Implement simplify_type for CFGTerminator, so that we can dyn_cast from 810/// CFGTerminator to a specific Stmt class. 811template <> struct simplify_type<const ::clang::CFGTerminator> { 812 typedef const ::clang::Stmt *SimpleType; 813 static SimpleType getSimplifiedValue(const ::clang::CFGTerminator &Val) { 814 return Val.getStmt(); 815 } 816}; 817 818template <> struct simplify_type< ::clang::CFGTerminator> { 819 typedef ::clang::Stmt *SimpleType; 820 static SimpleType getSimplifiedValue(const ::clang::CFGTerminator &Val) { 821 return const_cast<SimpleType>(Val.getStmt()); 822 } 823}; 824 825// Traits for: CFGBlock 826 827template <> struct GraphTraits< ::clang::CFGBlock *> { 828 typedef ::clang::CFGBlock NodeType; 829 typedef ::clang::CFGBlock::succ_iterator ChildIteratorType; 830 831 static NodeType* getEntryNode(::clang::CFGBlock *BB) 832 { return BB; } 833 834 static inline ChildIteratorType child_begin(NodeType* N) 835 { return N->succ_begin(); } 836 837 static inline ChildIteratorType child_end(NodeType* N) 838 { return N->succ_end(); } 839}; 840 841template <> struct GraphTraits< const ::clang::CFGBlock *> { 842 typedef const ::clang::CFGBlock NodeType; 843 typedef ::clang::CFGBlock::const_succ_iterator ChildIteratorType; 844 845 static NodeType* getEntryNode(const clang::CFGBlock *BB) 846 { return BB; } 847 848 static inline ChildIteratorType child_begin(NodeType* N) 849 { return N->succ_begin(); } 850 851 static inline ChildIteratorType child_end(NodeType* N) 852 { return N->succ_end(); } 853}; 854 855template <> struct GraphTraits<Inverse< ::clang::CFGBlock*> > { 856 typedef ::clang::CFGBlock NodeType; 857 typedef ::clang::CFGBlock::const_pred_iterator ChildIteratorType; 858 859 static NodeType *getEntryNode(Inverse< ::clang::CFGBlock*> G) 860 { return G.Graph; } 861 862 static inline ChildIteratorType child_begin(NodeType* N) 863 { return N->pred_begin(); } 864 865 static inline ChildIteratorType child_end(NodeType* N) 866 { return N->pred_end(); } 867}; 868 869template <> struct GraphTraits<Inverse<const ::clang::CFGBlock*> > { 870 typedef const ::clang::CFGBlock NodeType; 871 typedef ::clang::CFGBlock::const_pred_iterator ChildIteratorType; 872 873 static NodeType *getEntryNode(Inverse<const ::clang::CFGBlock*> G) 874 { return G.Graph; } 875 876 static inline ChildIteratorType child_begin(NodeType* N) 877 { return N->pred_begin(); } 878 879 static inline ChildIteratorType child_end(NodeType* N) 880 { return N->pred_end(); } 881}; 882 883// Traits for: CFG 884 885template <> struct GraphTraits< ::clang::CFG* > 886 : public GraphTraits< ::clang::CFGBlock *> { 887 888 typedef ::clang::CFG::graph_iterator nodes_iterator; 889 890 static NodeType *getEntryNode(::clang::CFG* F) { return &F->getEntry(); } 891 static nodes_iterator nodes_begin(::clang::CFG* F) { return F->nodes_begin();} 892 static nodes_iterator nodes_end(::clang::CFG* F) { return F->nodes_end(); } 893 static unsigned size(::clang::CFG* F) { return F->size(); } 894}; 895 896template <> struct GraphTraits<const ::clang::CFG* > 897 : public GraphTraits<const ::clang::CFGBlock *> { 898 899 typedef ::clang::CFG::const_graph_iterator nodes_iterator; 900 901 static NodeType *getEntryNode( const ::clang::CFG* F) { 902 return &F->getEntry(); 903 } 904 static nodes_iterator nodes_begin( const ::clang::CFG* F) { 905 return F->nodes_begin(); 906 } 907 static nodes_iterator nodes_end( const ::clang::CFG* F) { 908 return F->nodes_end(); 909 } 910 static unsigned size(const ::clang::CFG* F) { 911 return F->size(); 912 } 913}; 914 915template <> struct GraphTraits<Inverse< ::clang::CFG*> > 916 : public GraphTraits<Inverse< ::clang::CFGBlock*> > { 917 918 typedef ::clang::CFG::graph_iterator nodes_iterator; 919 920 static NodeType *getEntryNode( ::clang::CFG* F) { return &F->getExit(); } 921 static nodes_iterator nodes_begin( ::clang::CFG* F) {return F->nodes_begin();} 922 static nodes_iterator nodes_end( ::clang::CFG* F) { return F->nodes_end(); } 923}; 924 925template <> struct GraphTraits<Inverse<const ::clang::CFG*> > 926 : public GraphTraits<Inverse<const ::clang::CFGBlock*> > { 927 928 typedef ::clang::CFG::const_graph_iterator nodes_iterator; 929 930 static NodeType *getEntryNode(const ::clang::CFG* F) { return &F->getExit(); } 931 static nodes_iterator nodes_begin(const ::clang::CFG* F) { 932 return F->nodes_begin(); 933 } 934 static nodes_iterator nodes_end(const ::clang::CFG* F) { 935 return F->nodes_end(); 936 } 937}; 938} // end llvm namespace 939#endif 940