1 //===--- Stmt.h - Classes for representing statements -----------*- 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 Stmt interface and subclasses. 11 // 12 //===----------------------------------------------------------------------===// 13 14 #ifndef LLVM_CLANG_AST_STMT_H 15 #define LLVM_CLANG_AST_STMT_H 16 17 #include "clang/Basic/LLVM.h" 18 #include "clang/Basic/SourceLocation.h" 19 #include "clang/AST/PrettyPrinter.h" 20 #include "clang/AST/StmtIterator.h" 21 #include "clang/AST/DeclGroup.h" 22 #include "clang/AST/ASTContext.h" 23 #include "llvm/Support/raw_ostream.h" 24 #include "llvm/ADT/SmallVector.h" 25 #include <string> 26 27 namespace llvm { 28 class FoldingSetNodeID; 29 } 30 31 namespace clang { 32 class ASTContext; 33 class Expr; 34 class Decl; 35 class ParmVarDecl; 36 class QualType; 37 class IdentifierInfo; 38 class SourceManager; 39 class StringLiteral; 40 class SwitchStmt; 41 42 //===----------------------------------------------------------------------===// 43 // ExprIterator - Iterators for iterating over Stmt* arrays that contain 44 // only Expr*. This is needed because AST nodes use Stmt* arrays to store 45 // references to children (to be compatible with StmtIterator). 46 //===----------------------------------------------------------------------===// 47 48 class Stmt; 49 class Expr; 50 51 class ExprIterator { 52 Stmt** I; 53 public: ExprIterator(Stmt ** i)54 ExprIterator(Stmt** i) : I(i) {} ExprIterator()55 ExprIterator() : I(0) {} 56 ExprIterator& operator++() { ++I; return *this; } 57 ExprIterator operator-(size_t i) { return I-i; } 58 ExprIterator operator+(size_t i) { return I+i; } 59 Expr* operator[](size_t idx); 60 // FIXME: Verify that this will correctly return a signed distance. 61 signed operator-(const ExprIterator& R) const { return I - R.I; } 62 Expr* operator*() const; 63 Expr* operator->() const; 64 bool operator==(const ExprIterator& R) const { return I == R.I; } 65 bool operator!=(const ExprIterator& R) const { return I != R.I; } 66 bool operator>(const ExprIterator& R) const { return I > R.I; } 67 bool operator>=(const ExprIterator& R) const { return I >= R.I; } 68 }; 69 70 class ConstExprIterator { 71 const Stmt * const *I; 72 public: ConstExprIterator(const Stmt * const * i)73 ConstExprIterator(const Stmt * const *i) : I(i) {} ConstExprIterator()74 ConstExprIterator() : I(0) {} 75 ConstExprIterator& operator++() { ++I; return *this; } 76 ConstExprIterator operator+(size_t i) const { return I+i; } 77 ConstExprIterator operator-(size_t i) const { return I-i; } 78 const Expr * operator[](size_t idx) const; 79 signed operator-(const ConstExprIterator& R) const { return I - R.I; } 80 const Expr * operator*() const; 81 const Expr * operator->() const; 82 bool operator==(const ConstExprIterator& R) const { return I == R.I; } 83 bool operator!=(const ConstExprIterator& R) const { return I != R.I; } 84 bool operator>(const ConstExprIterator& R) const { return I > R.I; } 85 bool operator>=(const ConstExprIterator& R) const { return I >= R.I; } 86 }; 87 88 //===----------------------------------------------------------------------===// 89 // AST classes for statements. 90 //===----------------------------------------------------------------------===// 91 92 /// Stmt - This represents one statement. 93 /// 94 class Stmt { 95 public: 96 enum StmtClass { 97 NoStmtClass = 0, 98 #define STMT(CLASS, PARENT) CLASS##Class, 99 #define STMT_RANGE(BASE, FIRST, LAST) \ 100 first##BASE##Constant=FIRST##Class, last##BASE##Constant=LAST##Class, 101 #define LAST_STMT_RANGE(BASE, FIRST, LAST) \ 102 first##BASE##Constant=FIRST##Class, last##BASE##Constant=LAST##Class 103 #define ABSTRACT_STMT(STMT) 104 #include "clang/AST/StmtNodes.inc" 105 }; 106 107 // Make vanilla 'new' and 'delete' illegal for Stmts. 108 protected: new(size_t bytes)109 void* operator new(size_t bytes) throw() { 110 assert(0 && "Stmts cannot be allocated with regular 'new'."); 111 return 0; 112 } delete(void * data)113 void operator delete(void* data) throw() { 114 assert(0 && "Stmts cannot be released with regular 'delete'."); 115 } 116 117 class StmtBitfields { 118 friend class Stmt; 119 120 /// \brief The statement class. 121 unsigned sClass : 8; 122 }; 123 enum { NumStmtBits = 8 }; 124 125 class CompoundStmtBitfields { 126 friend class CompoundStmt; 127 unsigned : NumStmtBits; 128 129 unsigned NumStmts : 32 - NumStmtBits; 130 }; 131 132 class ExprBitfields { 133 friend class Expr; 134 friend class DeclRefExpr; // computeDependence 135 friend class InitListExpr; // ctor 136 friend class DesignatedInitExpr; // ctor 137 friend class BlockDeclRefExpr; // ctor 138 friend class ASTStmtReader; // deserialization 139 friend class CXXNewExpr; // ctor 140 friend class DependentScopeDeclRefExpr; // ctor 141 friend class CXXConstructExpr; // ctor 142 friend class CallExpr; // ctor 143 friend class OffsetOfExpr; // ctor 144 friend class ObjCMessageExpr; // ctor 145 friend class ShuffleVectorExpr; // ctor 146 friend class ParenListExpr; // ctor 147 friend class CXXUnresolvedConstructExpr; // ctor 148 friend class CXXDependentScopeMemberExpr; // ctor 149 friend class OverloadExpr; // ctor 150 unsigned : NumStmtBits; 151 152 unsigned ValueKind : 2; 153 unsigned ObjectKind : 2; 154 unsigned TypeDependent : 1; 155 unsigned ValueDependent : 1; 156 unsigned InstantiationDependent : 1; 157 unsigned ContainsUnexpandedParameterPack : 1; 158 }; 159 enum { NumExprBits = 16 }; 160 161 class DeclRefExprBitfields { 162 friend class DeclRefExpr; 163 friend class ASTStmtReader; // deserialization 164 unsigned : NumExprBits; 165 166 unsigned HasQualifier : 1; 167 unsigned HasExplicitTemplateArgs : 1; 168 unsigned HasFoundDecl : 1; 169 }; 170 171 class CastExprBitfields { 172 friend class CastExpr; 173 unsigned : NumExprBits; 174 175 unsigned Kind : 6; 176 unsigned BasePathSize : 32 - 6 - NumExprBits; 177 }; 178 179 class CallExprBitfields { 180 friend class CallExpr; 181 unsigned : NumExprBits; 182 183 unsigned NumPreArgs : 1; 184 }; 185 186 class ObjCIndirectCopyRestoreExprBitfields { 187 friend class ObjCIndirectCopyRestoreExpr; 188 unsigned : NumExprBits; 189 190 unsigned ShouldCopy : 1; 191 }; 192 193 union { 194 // FIXME: this is wasteful on 64-bit platforms. 195 void *Aligner; 196 197 StmtBitfields StmtBits; 198 CompoundStmtBitfields CompoundStmtBits; 199 ExprBitfields ExprBits; 200 DeclRefExprBitfields DeclRefExprBits; 201 CastExprBitfields CastExprBits; 202 CallExprBitfields CallExprBits; 203 ObjCIndirectCopyRestoreExprBitfields ObjCIndirectCopyRestoreExprBits; 204 }; 205 206 friend class ASTStmtReader; 207 208 public: 209 // Only allow allocation of Stmts using the allocator in ASTContext 210 // or by doing a placement new. 211 void* operator new(size_t bytes, ASTContext& C, throw()212 unsigned alignment = 8) throw() { 213 return ::operator new(bytes, C, alignment); 214 } 215 216 void* operator new(size_t bytes, ASTContext* C, throw()217 unsigned alignment = 8) throw() { 218 return ::operator new(bytes, *C, alignment); 219 } 220 new(size_t bytes,void * mem)221 void* operator new(size_t bytes, void* mem) throw() { 222 return mem; 223 } 224 delete(void *,ASTContext &,unsigned)225 void operator delete(void*, ASTContext&, unsigned) throw() { } delete(void *,ASTContext *,unsigned)226 void operator delete(void*, ASTContext*, unsigned) throw() { } delete(void *,std::size_t)227 void operator delete(void*, std::size_t) throw() { } delete(void *,void *)228 void operator delete(void*, void*) throw() { } 229 230 public: 231 /// \brief A placeholder type used to construct an empty shell of a 232 /// type, that will be filled in later (e.g., by some 233 /// de-serialization). 234 struct EmptyShell { }; 235 236 protected: 237 /// \brief Construct an empty statement. Stmt(StmtClass SC,EmptyShell)238 explicit Stmt(StmtClass SC, EmptyShell) { 239 StmtBits.sClass = SC; 240 if (Stmt::CollectingStats()) Stmt::addStmtClass(SC); 241 } 242 243 public: Stmt(StmtClass SC)244 Stmt(StmtClass SC) { 245 StmtBits.sClass = SC; 246 if (Stmt::CollectingStats()) Stmt::addStmtClass(SC); 247 } 248 getStmtClass()249 StmtClass getStmtClass() const { 250 return static_cast<StmtClass>(StmtBits.sClass); 251 } 252 const char *getStmtClassName() const; 253 254 /// SourceLocation tokens are not useful in isolation - they are low level 255 /// value objects created/interpreted by SourceManager. We assume AST 256 /// clients will have a pointer to the respective SourceManager. 257 SourceRange getSourceRange() const; 258 getLocStart()259 SourceLocation getLocStart() const { return getSourceRange().getBegin(); } getLocEnd()260 SourceLocation getLocEnd() const { return getSourceRange().getEnd(); } 261 262 // global temp stats (until we have a per-module visitor) 263 static void addStmtClass(const StmtClass s); 264 static bool CollectingStats(bool Enable = false); 265 static void PrintStats(); 266 267 /// dump - This does a local dump of the specified AST fragment. It dumps the 268 /// specified node and a few nodes underneath it, but not the whole subtree. 269 /// This is useful in a debugger. 270 void dump() const; 271 void dump(SourceManager &SM) const; 272 void dump(llvm::raw_ostream &OS, SourceManager &SM) const; 273 274 /// dumpAll - This does a dump of the specified AST fragment and all subtrees. 275 void dumpAll() const; 276 void dumpAll(SourceManager &SM) const; 277 278 /// dumpPretty/printPretty - These two methods do a "pretty print" of the AST 279 /// back to its original source language syntax. 280 void dumpPretty(ASTContext& Context) const; 281 void printPretty(llvm::raw_ostream &OS, PrinterHelper *Helper, 282 const PrintingPolicy &Policy, 283 unsigned Indentation = 0) const { 284 printPretty(OS, *(ASTContext*)0, Helper, Policy, Indentation); 285 } 286 void printPretty(llvm::raw_ostream &OS, ASTContext &Context, 287 PrinterHelper *Helper, 288 const PrintingPolicy &Policy, 289 unsigned Indentation = 0) const; 290 291 /// viewAST - Visualize an AST rooted at this Stmt* using GraphViz. Only 292 /// works on systems with GraphViz (Mac OS X) or dot+gv installed. 293 void viewAST() const; 294 295 /// Skip past any implicit AST nodes which might surround this 296 /// statement, such as ExprWithCleanups or ImplicitCastExpr nodes. 297 Stmt *IgnoreImplicit(); 298 299 // Implement isa<T> support. classof(const Stmt *)300 static bool classof(const Stmt *) { return true; } 301 302 /// hasImplicitControlFlow - Some statements (e.g. short circuited operations) 303 /// contain implicit control-flow in the order their subexpressions 304 /// are evaluated. This predicate returns true if this statement has 305 /// such implicit control-flow. Such statements are also specially handled 306 /// within CFGs. 307 bool hasImplicitControlFlow() const; 308 309 /// Child Iterators: All subclasses must implement 'children' 310 /// to permit easy iteration over the substatements/subexpessions of an 311 /// AST node. This permits easy iteration over all nodes in the AST. 312 typedef StmtIterator child_iterator; 313 typedef ConstStmtIterator const_child_iterator; 314 315 typedef StmtRange child_range; 316 typedef ConstStmtRange const_child_range; 317 318 child_range children(); children()319 const_child_range children() const { 320 return const_cast<Stmt*>(this)->children(); 321 } 322 child_begin()323 child_iterator child_begin() { return children().first; } child_end()324 child_iterator child_end() { return children().second; } 325 child_begin()326 const_child_iterator child_begin() const { return children().first; } child_end()327 const_child_iterator child_end() const { return children().second; } 328 329 /// \brief Produce a unique representation of the given statement. 330 /// 331 /// \brief ID once the profiling operation is complete, will contain 332 /// the unique representation of the given statement. 333 /// 334 /// \brief Context the AST context in which the statement resides 335 /// 336 /// \brief Canonical whether the profile should be based on the canonical 337 /// representation of this statement (e.g., where non-type template 338 /// parameters are identified by index/level rather than their 339 /// declaration pointers) or the exact representation of the statement as 340 /// written in the source. 341 void Profile(llvm::FoldingSetNodeID &ID, const ASTContext &Context, 342 bool Canonical) const; 343 }; 344 345 /// DeclStmt - Adaptor class for mixing declarations with statements and 346 /// expressions. For example, CompoundStmt mixes statements, expressions 347 /// and declarations (variables, types). Another example is ForStmt, where 348 /// the first statement can be an expression or a declaration. 349 /// 350 class DeclStmt : public Stmt { 351 DeclGroupRef DG; 352 SourceLocation StartLoc, EndLoc; 353 354 public: DeclStmt(DeclGroupRef dg,SourceLocation startLoc,SourceLocation endLoc)355 DeclStmt(DeclGroupRef dg, SourceLocation startLoc, 356 SourceLocation endLoc) : Stmt(DeclStmtClass), DG(dg), 357 StartLoc(startLoc), EndLoc(endLoc) {} 358 359 /// \brief Build an empty declaration statement. DeclStmt(EmptyShell Empty)360 explicit DeclStmt(EmptyShell Empty) : Stmt(DeclStmtClass, Empty) { } 361 362 /// isSingleDecl - This method returns true if this DeclStmt refers 363 /// to a single Decl. isSingleDecl()364 bool isSingleDecl() const { 365 return DG.isSingleDecl(); 366 } 367 getSingleDecl()368 const Decl *getSingleDecl() const { return DG.getSingleDecl(); } getSingleDecl()369 Decl *getSingleDecl() { return DG.getSingleDecl(); } 370 getDeclGroup()371 const DeclGroupRef getDeclGroup() const { return DG; } getDeclGroup()372 DeclGroupRef getDeclGroup() { return DG; } setDeclGroup(DeclGroupRef DGR)373 void setDeclGroup(DeclGroupRef DGR) { DG = DGR; } 374 getStartLoc()375 SourceLocation getStartLoc() const { return StartLoc; } setStartLoc(SourceLocation L)376 void setStartLoc(SourceLocation L) { StartLoc = L; } getEndLoc()377 SourceLocation getEndLoc() const { return EndLoc; } setEndLoc(SourceLocation L)378 void setEndLoc(SourceLocation L) { EndLoc = L; } 379 getSourceRange()380 SourceRange getSourceRange() const { 381 return SourceRange(StartLoc, EndLoc); 382 } 383 classof(const Stmt * T)384 static bool classof(const Stmt *T) { 385 return T->getStmtClass() == DeclStmtClass; 386 } classof(const DeclStmt *)387 static bool classof(const DeclStmt *) { return true; } 388 389 // Iterators over subexpressions. children()390 child_range children() { 391 return child_range(child_iterator(DG.begin(), DG.end()), 392 child_iterator(DG.end(), DG.end())); 393 } 394 395 typedef DeclGroupRef::iterator decl_iterator; 396 typedef DeclGroupRef::const_iterator const_decl_iterator; 397 decl_begin()398 decl_iterator decl_begin() { return DG.begin(); } decl_end()399 decl_iterator decl_end() { return DG.end(); } decl_begin()400 const_decl_iterator decl_begin() const { return DG.begin(); } decl_end()401 const_decl_iterator decl_end() const { return DG.end(); } 402 }; 403 404 /// NullStmt - This is the null statement ";": C99 6.8.3p3. 405 /// 406 class NullStmt : public Stmt { 407 SourceLocation SemiLoc; 408 409 /// \brief If the null statement was preceded by an empty macro this is 410 /// its instantiation source location, e.g: 411 /// @code 412 /// #define CALL(x) 413 /// CALL(0); 414 /// @endcode 415 SourceLocation LeadingEmptyMacro; 416 public: 417 NullStmt(SourceLocation L, SourceLocation LeadingEmptyMacro =SourceLocation()) Stmt(NullStmtClass)418 : Stmt(NullStmtClass), SemiLoc(L), LeadingEmptyMacro(LeadingEmptyMacro) {} 419 420 /// \brief Build an empty null statement. NullStmt(EmptyShell Empty)421 explicit NullStmt(EmptyShell Empty) : Stmt(NullStmtClass, Empty) { } 422 getSemiLoc()423 SourceLocation getSemiLoc() const { return SemiLoc; } setSemiLoc(SourceLocation L)424 void setSemiLoc(SourceLocation L) { SemiLoc = L; } 425 hasLeadingEmptyMacro()426 bool hasLeadingEmptyMacro() const { return LeadingEmptyMacro.isValid(); } getLeadingEmptyMacroLoc()427 SourceLocation getLeadingEmptyMacroLoc() const { return LeadingEmptyMacro; } 428 getSourceRange()429 SourceRange getSourceRange() const { return SourceRange(SemiLoc); } 430 classof(const Stmt * T)431 static bool classof(const Stmt *T) { 432 return T->getStmtClass() == NullStmtClass; 433 } classof(const NullStmt *)434 static bool classof(const NullStmt *) { return true; } 435 children()436 child_range children() { return child_range(); } 437 438 friend class ASTStmtReader; 439 friend class ASTStmtWriter; 440 }; 441 442 /// CompoundStmt - This represents a group of statements like { stmt stmt }. 443 /// 444 class CompoundStmt : public Stmt { 445 Stmt** Body; 446 SourceLocation LBracLoc, RBracLoc; 447 public: CompoundStmt(ASTContext & C,Stmt ** StmtStart,unsigned NumStmts,SourceLocation LB,SourceLocation RB)448 CompoundStmt(ASTContext& C, Stmt **StmtStart, unsigned NumStmts, 449 SourceLocation LB, SourceLocation RB) 450 : Stmt(CompoundStmtClass), LBracLoc(LB), RBracLoc(RB) { 451 CompoundStmtBits.NumStmts = NumStmts; 452 assert(CompoundStmtBits.NumStmts == NumStmts && 453 "NumStmts doesn't fit in bits of CompoundStmtBits.NumStmts!"); 454 455 if (NumStmts == 0) { 456 Body = 0; 457 return; 458 } 459 460 Body = new (C) Stmt*[NumStmts]; 461 memcpy(Body, StmtStart, NumStmts * sizeof(*Body)); 462 } 463 464 // \brief Build an empty compound statement. CompoundStmt(EmptyShell Empty)465 explicit CompoundStmt(EmptyShell Empty) 466 : Stmt(CompoundStmtClass, Empty), Body(0) { 467 CompoundStmtBits.NumStmts = 0; 468 } 469 470 void setStmts(ASTContext &C, Stmt **Stmts, unsigned NumStmts); 471 body_empty()472 bool body_empty() const { return CompoundStmtBits.NumStmts == 0; } size()473 unsigned size() const { return CompoundStmtBits.NumStmts; } 474 475 typedef Stmt** body_iterator; body_begin()476 body_iterator body_begin() { return Body; } body_end()477 body_iterator body_end() { return Body + size(); } body_back()478 Stmt *body_back() { return !body_empty() ? Body[size()-1] : 0; } 479 setLastStmt(Stmt * S)480 void setLastStmt(Stmt *S) { 481 assert(!body_empty() && "setLastStmt"); 482 Body[size()-1] = S; 483 } 484 485 typedef Stmt* const * const_body_iterator; body_begin()486 const_body_iterator body_begin() const { return Body; } body_end()487 const_body_iterator body_end() const { return Body + size(); } body_back()488 const Stmt *body_back() const { return !body_empty() ? Body[size()-1] : 0; } 489 490 typedef std::reverse_iterator<body_iterator> reverse_body_iterator; body_rbegin()491 reverse_body_iterator body_rbegin() { 492 return reverse_body_iterator(body_end()); 493 } body_rend()494 reverse_body_iterator body_rend() { 495 return reverse_body_iterator(body_begin()); 496 } 497 498 typedef std::reverse_iterator<const_body_iterator> 499 const_reverse_body_iterator; 500 body_rbegin()501 const_reverse_body_iterator body_rbegin() const { 502 return const_reverse_body_iterator(body_end()); 503 } 504 body_rend()505 const_reverse_body_iterator body_rend() const { 506 return const_reverse_body_iterator(body_begin()); 507 } 508 getSourceRange()509 SourceRange getSourceRange() const { 510 return SourceRange(LBracLoc, RBracLoc); 511 } 512 getLBracLoc()513 SourceLocation getLBracLoc() const { return LBracLoc; } setLBracLoc(SourceLocation L)514 void setLBracLoc(SourceLocation L) { LBracLoc = L; } getRBracLoc()515 SourceLocation getRBracLoc() const { return RBracLoc; } setRBracLoc(SourceLocation L)516 void setRBracLoc(SourceLocation L) { RBracLoc = L; } 517 classof(const Stmt * T)518 static bool classof(const Stmt *T) { 519 return T->getStmtClass() == CompoundStmtClass; 520 } classof(const CompoundStmt *)521 static bool classof(const CompoundStmt *) { return true; } 522 523 // Iterators children()524 child_range children() { 525 return child_range(&Body[0], &Body[0]+CompoundStmtBits.NumStmts); 526 } 527 }; 528 529 // SwitchCase is the base class for CaseStmt and DefaultStmt, 530 class SwitchCase : public Stmt { 531 protected: 532 // A pointer to the following CaseStmt or DefaultStmt class, 533 // used by SwitchStmt. 534 SwitchCase *NextSwitchCase; 535 SwitchCase(StmtClass SC)536 SwitchCase(StmtClass SC) : Stmt(SC), NextSwitchCase(0) {} 537 538 public: getNextSwitchCase()539 const SwitchCase *getNextSwitchCase() const { return NextSwitchCase; } 540 getNextSwitchCase()541 SwitchCase *getNextSwitchCase() { return NextSwitchCase; } 542 setNextSwitchCase(SwitchCase * SC)543 void setNextSwitchCase(SwitchCase *SC) { NextSwitchCase = SC; } 544 545 Stmt *getSubStmt(); getSubStmt()546 const Stmt *getSubStmt() const { 547 return const_cast<SwitchCase*>(this)->getSubStmt(); 548 } 549 getSourceRange()550 SourceRange getSourceRange() const { return SourceRange(); } 551 classof(const Stmt * T)552 static bool classof(const Stmt *T) { 553 return T->getStmtClass() == CaseStmtClass || 554 T->getStmtClass() == DefaultStmtClass; 555 } classof(const SwitchCase *)556 static bool classof(const SwitchCase *) { return true; } 557 }; 558 559 class CaseStmt : public SwitchCase { 560 enum { LHS, RHS, SUBSTMT, END_EXPR }; 561 Stmt* SubExprs[END_EXPR]; // The expression for the RHS is Non-null for 562 // GNU "case 1 ... 4" extension 563 SourceLocation CaseLoc; 564 SourceLocation EllipsisLoc; 565 SourceLocation ColonLoc; 566 public: CaseStmt(Expr * lhs,Expr * rhs,SourceLocation caseLoc,SourceLocation ellipsisLoc,SourceLocation colonLoc)567 CaseStmt(Expr *lhs, Expr *rhs, SourceLocation caseLoc, 568 SourceLocation ellipsisLoc, SourceLocation colonLoc) 569 : SwitchCase(CaseStmtClass) { 570 SubExprs[SUBSTMT] = 0; 571 SubExprs[LHS] = reinterpret_cast<Stmt*>(lhs); 572 SubExprs[RHS] = reinterpret_cast<Stmt*>(rhs); 573 CaseLoc = caseLoc; 574 EllipsisLoc = ellipsisLoc; 575 ColonLoc = colonLoc; 576 } 577 578 /// \brief Build an empty switch case statement. CaseStmt(EmptyShell Empty)579 explicit CaseStmt(EmptyShell Empty) : SwitchCase(CaseStmtClass) { } 580 getCaseLoc()581 SourceLocation getCaseLoc() const { return CaseLoc; } setCaseLoc(SourceLocation L)582 void setCaseLoc(SourceLocation L) { CaseLoc = L; } getEllipsisLoc()583 SourceLocation getEllipsisLoc() const { return EllipsisLoc; } setEllipsisLoc(SourceLocation L)584 void setEllipsisLoc(SourceLocation L) { EllipsisLoc = L; } getColonLoc()585 SourceLocation getColonLoc() const { return ColonLoc; } setColonLoc(SourceLocation L)586 void setColonLoc(SourceLocation L) { ColonLoc = L; } 587 getLHS()588 Expr *getLHS() { return reinterpret_cast<Expr*>(SubExprs[LHS]); } getRHS()589 Expr *getRHS() { return reinterpret_cast<Expr*>(SubExprs[RHS]); } getSubStmt()590 Stmt *getSubStmt() { return SubExprs[SUBSTMT]; } 591 getLHS()592 const Expr *getLHS() const { 593 return reinterpret_cast<const Expr*>(SubExprs[LHS]); 594 } getRHS()595 const Expr *getRHS() const { 596 return reinterpret_cast<const Expr*>(SubExprs[RHS]); 597 } getSubStmt()598 const Stmt *getSubStmt() const { return SubExprs[SUBSTMT]; } 599 setSubStmt(Stmt * S)600 void setSubStmt(Stmt *S) { SubExprs[SUBSTMT] = S; } setLHS(Expr * Val)601 void setLHS(Expr *Val) { SubExprs[LHS] = reinterpret_cast<Stmt*>(Val); } setRHS(Expr * Val)602 void setRHS(Expr *Val) { SubExprs[RHS] = reinterpret_cast<Stmt*>(Val); } 603 604 getSourceRange()605 SourceRange getSourceRange() const { 606 // Handle deeply nested case statements with iteration instead of recursion. 607 const CaseStmt *CS = this; 608 while (const CaseStmt *CS2 = dyn_cast<CaseStmt>(CS->getSubStmt())) 609 CS = CS2; 610 611 return SourceRange(CaseLoc, CS->getSubStmt()->getLocEnd()); 612 } classof(const Stmt * T)613 static bool classof(const Stmt *T) { 614 return T->getStmtClass() == CaseStmtClass; 615 } classof(const CaseStmt *)616 static bool classof(const CaseStmt *) { return true; } 617 618 // Iterators children()619 child_range children() { 620 return child_range(&SubExprs[0], &SubExprs[END_EXPR]); 621 } 622 }; 623 624 class DefaultStmt : public SwitchCase { 625 Stmt* SubStmt; 626 SourceLocation DefaultLoc; 627 SourceLocation ColonLoc; 628 public: DefaultStmt(SourceLocation DL,SourceLocation CL,Stmt * substmt)629 DefaultStmt(SourceLocation DL, SourceLocation CL, Stmt *substmt) : 630 SwitchCase(DefaultStmtClass), SubStmt(substmt), DefaultLoc(DL), 631 ColonLoc(CL) {} 632 633 /// \brief Build an empty default statement. DefaultStmt(EmptyShell)634 explicit DefaultStmt(EmptyShell) : SwitchCase(DefaultStmtClass) { } 635 getSubStmt()636 Stmt *getSubStmt() { return SubStmt; } getSubStmt()637 const Stmt *getSubStmt() const { return SubStmt; } setSubStmt(Stmt * S)638 void setSubStmt(Stmt *S) { SubStmt = S; } 639 getDefaultLoc()640 SourceLocation getDefaultLoc() const { return DefaultLoc; } setDefaultLoc(SourceLocation L)641 void setDefaultLoc(SourceLocation L) { DefaultLoc = L; } getColonLoc()642 SourceLocation getColonLoc() const { return ColonLoc; } setColonLoc(SourceLocation L)643 void setColonLoc(SourceLocation L) { ColonLoc = L; } 644 getSourceRange()645 SourceRange getSourceRange() const { 646 return SourceRange(DefaultLoc, SubStmt->getLocEnd()); 647 } classof(const Stmt * T)648 static bool classof(const Stmt *T) { 649 return T->getStmtClass() == DefaultStmtClass; 650 } classof(const DefaultStmt *)651 static bool classof(const DefaultStmt *) { return true; } 652 653 // Iterators children()654 child_range children() { return child_range(&SubStmt, &SubStmt+1); } 655 }; 656 657 658 /// LabelStmt - Represents a label, which has a substatement. For example: 659 /// foo: return; 660 /// 661 class LabelStmt : public Stmt { 662 LabelDecl *TheDecl; 663 Stmt *SubStmt; 664 SourceLocation IdentLoc; 665 public: LabelStmt(SourceLocation IL,LabelDecl * D,Stmt * substmt)666 LabelStmt(SourceLocation IL, LabelDecl *D, Stmt *substmt) 667 : Stmt(LabelStmtClass), TheDecl(D), SubStmt(substmt), IdentLoc(IL) { 668 } 669 670 // \brief Build an empty label statement. LabelStmt(EmptyShell Empty)671 explicit LabelStmt(EmptyShell Empty) : Stmt(LabelStmtClass, Empty) { } 672 getIdentLoc()673 SourceLocation getIdentLoc() const { return IdentLoc; } getDecl()674 LabelDecl *getDecl() const { return TheDecl; } setDecl(LabelDecl * D)675 void setDecl(LabelDecl *D) { TheDecl = D; } 676 const char *getName() const; getSubStmt()677 Stmt *getSubStmt() { return SubStmt; } getSubStmt()678 const Stmt *getSubStmt() const { return SubStmt; } setIdentLoc(SourceLocation L)679 void setIdentLoc(SourceLocation L) { IdentLoc = L; } setSubStmt(Stmt * SS)680 void setSubStmt(Stmt *SS) { SubStmt = SS; } 681 getSourceRange()682 SourceRange getSourceRange() const { 683 return SourceRange(IdentLoc, SubStmt->getLocEnd()); 684 } children()685 child_range children() { return child_range(&SubStmt, &SubStmt+1); } 686 classof(const Stmt * T)687 static bool classof(const Stmt *T) { 688 return T->getStmtClass() == LabelStmtClass; 689 } classof(const LabelStmt *)690 static bool classof(const LabelStmt *) { return true; } 691 }; 692 693 694 /// IfStmt - This represents an if/then/else. 695 /// 696 class IfStmt : public Stmt { 697 enum { VAR, COND, THEN, ELSE, END_EXPR }; 698 Stmt* SubExprs[END_EXPR]; 699 700 SourceLocation IfLoc; 701 SourceLocation ElseLoc; 702 703 public: 704 IfStmt(ASTContext &C, SourceLocation IL, VarDecl *var, Expr *cond, 705 Stmt *then, SourceLocation EL = SourceLocation(), Stmt *elsev = 0); 706 707 /// \brief Build an empty if/then/else statement IfStmt(EmptyShell Empty)708 explicit IfStmt(EmptyShell Empty) : Stmt(IfStmtClass, Empty) { } 709 710 /// \brief Retrieve the variable declared in this "if" statement, if any. 711 /// 712 /// In the following example, "x" is the condition variable. 713 /// \code 714 /// if (int x = foo()) { 715 /// printf("x is %d", x); 716 /// } 717 /// \endcode 718 VarDecl *getConditionVariable() const; 719 void setConditionVariable(ASTContext &C, VarDecl *V); 720 721 /// If this IfStmt has a condition variable, return the faux DeclStmt 722 /// associated with the creation of that condition variable. getConditionVariableDeclStmt()723 const DeclStmt *getConditionVariableDeclStmt() const { 724 return reinterpret_cast<DeclStmt*>(SubExprs[VAR]); 725 } 726 getCond()727 const Expr *getCond() const { return reinterpret_cast<Expr*>(SubExprs[COND]);} setCond(Expr * E)728 void setCond(Expr *E) { SubExprs[COND] = reinterpret_cast<Stmt *>(E); } getThen()729 const Stmt *getThen() const { return SubExprs[THEN]; } setThen(Stmt * S)730 void setThen(Stmt *S) { SubExprs[THEN] = S; } getElse()731 const Stmt *getElse() const { return SubExprs[ELSE]; } setElse(Stmt * S)732 void setElse(Stmt *S) { SubExprs[ELSE] = S; } 733 getCond()734 Expr *getCond() { return reinterpret_cast<Expr*>(SubExprs[COND]); } getThen()735 Stmt *getThen() { return SubExprs[THEN]; } getElse()736 Stmt *getElse() { return SubExprs[ELSE]; } 737 getIfLoc()738 SourceLocation getIfLoc() const { return IfLoc; } setIfLoc(SourceLocation L)739 void setIfLoc(SourceLocation L) { IfLoc = L; } getElseLoc()740 SourceLocation getElseLoc() const { return ElseLoc; } setElseLoc(SourceLocation L)741 void setElseLoc(SourceLocation L) { ElseLoc = L; } 742 getSourceRange()743 SourceRange getSourceRange() const { 744 if (SubExprs[ELSE]) 745 return SourceRange(IfLoc, SubExprs[ELSE]->getLocEnd()); 746 else 747 return SourceRange(IfLoc, SubExprs[THEN]->getLocEnd()); 748 } 749 750 // Iterators over subexpressions. The iterators will include iterating 751 // over the initialization expression referenced by the condition variable. children()752 child_range children() { 753 return child_range(&SubExprs[0], &SubExprs[0]+END_EXPR); 754 } 755 classof(const Stmt * T)756 static bool classof(const Stmt *T) { 757 return T->getStmtClass() == IfStmtClass; 758 } classof(const IfStmt *)759 static bool classof(const IfStmt *) { return true; } 760 }; 761 762 /// SwitchStmt - This represents a 'switch' stmt. 763 /// 764 class SwitchStmt : public Stmt { 765 enum { VAR, COND, BODY, END_EXPR }; 766 Stmt* SubExprs[END_EXPR]; 767 // This points to a linked list of case and default statements. 768 SwitchCase *FirstCase; 769 SourceLocation SwitchLoc; 770 771 /// If the SwitchStmt is a switch on an enum value, this records whether 772 /// all the enum values were covered by CaseStmts. This value is meant to 773 /// be a hint for possible clients. 774 unsigned AllEnumCasesCovered : 1; 775 776 public: 777 SwitchStmt(ASTContext &C, VarDecl *Var, Expr *cond); 778 779 /// \brief Build a empty switch statement. SwitchStmt(EmptyShell Empty)780 explicit SwitchStmt(EmptyShell Empty) : Stmt(SwitchStmtClass, Empty) { } 781 782 /// \brief Retrieve the variable declared in this "switch" statement, if any. 783 /// 784 /// In the following example, "x" is the condition variable. 785 /// \code 786 /// switch (int x = foo()) { 787 /// case 0: break; 788 /// // ... 789 /// } 790 /// \endcode 791 VarDecl *getConditionVariable() const; 792 void setConditionVariable(ASTContext &C, VarDecl *V); 793 794 /// If this SwitchStmt has a condition variable, return the faux DeclStmt 795 /// associated with the creation of that condition variable. getConditionVariableDeclStmt()796 const DeclStmt *getConditionVariableDeclStmt() const { 797 return reinterpret_cast<DeclStmt*>(SubExprs[VAR]); 798 } 799 getCond()800 const Expr *getCond() const { return reinterpret_cast<Expr*>(SubExprs[COND]);} getBody()801 const Stmt *getBody() const { return SubExprs[BODY]; } getSwitchCaseList()802 const SwitchCase *getSwitchCaseList() const { return FirstCase; } 803 getCond()804 Expr *getCond() { return reinterpret_cast<Expr*>(SubExprs[COND]);} setCond(Expr * E)805 void setCond(Expr *E) { SubExprs[COND] = reinterpret_cast<Stmt *>(E); } getBody()806 Stmt *getBody() { return SubExprs[BODY]; } setBody(Stmt * S)807 void setBody(Stmt *S) { SubExprs[BODY] = S; } getSwitchCaseList()808 SwitchCase *getSwitchCaseList() { return FirstCase; } 809 810 /// \brief Set the case list for this switch statement. 811 /// 812 /// The caller is responsible for incrementing the retain counts on 813 /// all of the SwitchCase statements in this list. setSwitchCaseList(SwitchCase * SC)814 void setSwitchCaseList(SwitchCase *SC) { FirstCase = SC; } 815 getSwitchLoc()816 SourceLocation getSwitchLoc() const { return SwitchLoc; } setSwitchLoc(SourceLocation L)817 void setSwitchLoc(SourceLocation L) { SwitchLoc = L; } 818 setBody(Stmt * S,SourceLocation SL)819 void setBody(Stmt *S, SourceLocation SL) { 820 SubExprs[BODY] = S; 821 SwitchLoc = SL; 822 } addSwitchCase(SwitchCase * SC)823 void addSwitchCase(SwitchCase *SC) { 824 assert(!SC->getNextSwitchCase() && "case/default already added to a switch"); 825 SC->setNextSwitchCase(FirstCase); 826 FirstCase = SC; 827 } 828 829 /// Set a flag in the SwitchStmt indicating that if the 'switch (X)' is a 830 /// switch over an enum value then all cases have been explicitly covered. setAllEnumCasesCovered()831 void setAllEnumCasesCovered() { 832 AllEnumCasesCovered = 1; 833 } 834 835 /// Returns true if the SwitchStmt is a switch of an enum value and all cases 836 /// have been explicitly covered. isAllEnumCasesCovered()837 bool isAllEnumCasesCovered() const { 838 return (bool) AllEnumCasesCovered; 839 } 840 getSourceRange()841 SourceRange getSourceRange() const { 842 return SourceRange(SwitchLoc, SubExprs[BODY]->getLocEnd()); 843 } 844 // Iterators children()845 child_range children() { 846 return child_range(&SubExprs[0], &SubExprs[0]+END_EXPR); 847 } 848 classof(const Stmt * T)849 static bool classof(const Stmt *T) { 850 return T->getStmtClass() == SwitchStmtClass; 851 } classof(const SwitchStmt *)852 static bool classof(const SwitchStmt *) { return true; } 853 }; 854 855 856 /// WhileStmt - This represents a 'while' stmt. 857 /// 858 class WhileStmt : public Stmt { 859 enum { VAR, COND, BODY, END_EXPR }; 860 Stmt* SubExprs[END_EXPR]; 861 SourceLocation WhileLoc; 862 public: 863 WhileStmt(ASTContext &C, VarDecl *Var, Expr *cond, Stmt *body, 864 SourceLocation WL); 865 866 /// \brief Build an empty while statement. WhileStmt(EmptyShell Empty)867 explicit WhileStmt(EmptyShell Empty) : Stmt(WhileStmtClass, Empty) { } 868 869 /// \brief Retrieve the variable declared in this "while" statement, if any. 870 /// 871 /// In the following example, "x" is the condition variable. 872 /// \code 873 /// while (int x = random()) { 874 /// // ... 875 /// } 876 /// \endcode 877 VarDecl *getConditionVariable() const; 878 void setConditionVariable(ASTContext &C, VarDecl *V); 879 880 /// If this WhileStmt has a condition variable, return the faux DeclStmt 881 /// associated with the creation of that condition variable. getConditionVariableDeclStmt()882 const DeclStmt *getConditionVariableDeclStmt() const { 883 return reinterpret_cast<DeclStmt*>(SubExprs[VAR]); 884 } 885 getCond()886 Expr *getCond() { return reinterpret_cast<Expr*>(SubExprs[COND]); } getCond()887 const Expr *getCond() const { return reinterpret_cast<Expr*>(SubExprs[COND]);} setCond(Expr * E)888 void setCond(Expr *E) { SubExprs[COND] = reinterpret_cast<Stmt*>(E); } getBody()889 Stmt *getBody() { return SubExprs[BODY]; } getBody()890 const Stmt *getBody() const { return SubExprs[BODY]; } setBody(Stmt * S)891 void setBody(Stmt *S) { SubExprs[BODY] = S; } 892 getWhileLoc()893 SourceLocation getWhileLoc() const { return WhileLoc; } setWhileLoc(SourceLocation L)894 void setWhileLoc(SourceLocation L) { WhileLoc = L; } 895 getSourceRange()896 SourceRange getSourceRange() const { 897 return SourceRange(WhileLoc, SubExprs[BODY]->getLocEnd()); 898 } classof(const Stmt * T)899 static bool classof(const Stmt *T) { 900 return T->getStmtClass() == WhileStmtClass; 901 } classof(const WhileStmt *)902 static bool classof(const WhileStmt *) { return true; } 903 904 // Iterators children()905 child_range children() { 906 return child_range(&SubExprs[0], &SubExprs[0]+END_EXPR); 907 } 908 }; 909 910 /// DoStmt - This represents a 'do/while' stmt. 911 /// 912 class DoStmt : public Stmt { 913 enum { BODY, COND, END_EXPR }; 914 Stmt* SubExprs[END_EXPR]; 915 SourceLocation DoLoc; 916 SourceLocation WhileLoc; 917 SourceLocation RParenLoc; // Location of final ')' in do stmt condition. 918 919 public: DoStmt(Stmt * body,Expr * cond,SourceLocation DL,SourceLocation WL,SourceLocation RP)920 DoStmt(Stmt *body, Expr *cond, SourceLocation DL, SourceLocation WL, 921 SourceLocation RP) 922 : Stmt(DoStmtClass), DoLoc(DL), WhileLoc(WL), RParenLoc(RP) { 923 SubExprs[COND] = reinterpret_cast<Stmt*>(cond); 924 SubExprs[BODY] = body; 925 } 926 927 /// \brief Build an empty do-while statement. DoStmt(EmptyShell Empty)928 explicit DoStmt(EmptyShell Empty) : Stmt(DoStmtClass, Empty) { } 929 getCond()930 Expr *getCond() { return reinterpret_cast<Expr*>(SubExprs[COND]); } getCond()931 const Expr *getCond() const { return reinterpret_cast<Expr*>(SubExprs[COND]);} setCond(Expr * E)932 void setCond(Expr *E) { SubExprs[COND] = reinterpret_cast<Stmt*>(E); } getBody()933 Stmt *getBody() { return SubExprs[BODY]; } getBody()934 const Stmt *getBody() const { return SubExprs[BODY]; } setBody(Stmt * S)935 void setBody(Stmt *S) { SubExprs[BODY] = S; } 936 getDoLoc()937 SourceLocation getDoLoc() const { return DoLoc; } setDoLoc(SourceLocation L)938 void setDoLoc(SourceLocation L) { DoLoc = L; } getWhileLoc()939 SourceLocation getWhileLoc() const { return WhileLoc; } setWhileLoc(SourceLocation L)940 void setWhileLoc(SourceLocation L) { WhileLoc = L; } 941 getRParenLoc()942 SourceLocation getRParenLoc() const { return RParenLoc; } setRParenLoc(SourceLocation L)943 void setRParenLoc(SourceLocation L) { RParenLoc = L; } 944 getSourceRange()945 SourceRange getSourceRange() const { 946 return SourceRange(DoLoc, RParenLoc); 947 } classof(const Stmt * T)948 static bool classof(const Stmt *T) { 949 return T->getStmtClass() == DoStmtClass; 950 } classof(const DoStmt *)951 static bool classof(const DoStmt *) { return true; } 952 953 // Iterators children()954 child_range children() { 955 return child_range(&SubExprs[0], &SubExprs[0]+END_EXPR); 956 } 957 }; 958 959 960 /// ForStmt - This represents a 'for (init;cond;inc)' stmt. Note that any of 961 /// the init/cond/inc parts of the ForStmt will be null if they were not 962 /// specified in the source. 963 /// 964 class ForStmt : public Stmt { 965 enum { INIT, CONDVAR, COND, INC, BODY, END_EXPR }; 966 Stmt* SubExprs[END_EXPR]; // SubExprs[INIT] is an expression or declstmt. 967 SourceLocation ForLoc; 968 SourceLocation LParenLoc, RParenLoc; 969 970 public: 971 ForStmt(ASTContext &C, Stmt *Init, Expr *Cond, VarDecl *condVar, Expr *Inc, 972 Stmt *Body, SourceLocation FL, SourceLocation LP, SourceLocation RP); 973 974 /// \brief Build an empty for statement. ForStmt(EmptyShell Empty)975 explicit ForStmt(EmptyShell Empty) : Stmt(ForStmtClass, Empty) { } 976 getInit()977 Stmt *getInit() { return SubExprs[INIT]; } 978 979 /// \brief Retrieve the variable declared in this "for" statement, if any. 980 /// 981 /// In the following example, "y" is the condition variable. 982 /// \code 983 /// for (int x = random(); int y = mangle(x); ++x) { 984 /// // ... 985 /// } 986 /// \endcode 987 VarDecl *getConditionVariable() const; 988 void setConditionVariable(ASTContext &C, VarDecl *V); 989 990 /// If this ForStmt has a condition variable, return the faux DeclStmt 991 /// associated with the creation of that condition variable. getConditionVariableDeclStmt()992 const DeclStmt *getConditionVariableDeclStmt() const { 993 return reinterpret_cast<DeclStmt*>(SubExprs[CONDVAR]); 994 } 995 getCond()996 Expr *getCond() { return reinterpret_cast<Expr*>(SubExprs[COND]); } getInc()997 Expr *getInc() { return reinterpret_cast<Expr*>(SubExprs[INC]); } getBody()998 Stmt *getBody() { return SubExprs[BODY]; } 999 getInit()1000 const Stmt *getInit() const { return SubExprs[INIT]; } getCond()1001 const Expr *getCond() const { return reinterpret_cast<Expr*>(SubExprs[COND]);} getInc()1002 const Expr *getInc() const { return reinterpret_cast<Expr*>(SubExprs[INC]); } getBody()1003 const Stmt *getBody() const { return SubExprs[BODY]; } 1004 setInit(Stmt * S)1005 void setInit(Stmt *S) { SubExprs[INIT] = S; } setCond(Expr * E)1006 void setCond(Expr *E) { SubExprs[COND] = reinterpret_cast<Stmt*>(E); } setInc(Expr * E)1007 void setInc(Expr *E) { SubExprs[INC] = reinterpret_cast<Stmt*>(E); } setBody(Stmt * S)1008 void setBody(Stmt *S) { SubExprs[BODY] = S; } 1009 getForLoc()1010 SourceLocation getForLoc() const { return ForLoc; } setForLoc(SourceLocation L)1011 void setForLoc(SourceLocation L) { ForLoc = L; } getLParenLoc()1012 SourceLocation getLParenLoc() const { return LParenLoc; } setLParenLoc(SourceLocation L)1013 void setLParenLoc(SourceLocation L) { LParenLoc = L; } getRParenLoc()1014 SourceLocation getRParenLoc() const { return RParenLoc; } setRParenLoc(SourceLocation L)1015 void setRParenLoc(SourceLocation L) { RParenLoc = L; } 1016 getSourceRange()1017 SourceRange getSourceRange() const { 1018 return SourceRange(ForLoc, SubExprs[BODY]->getLocEnd()); 1019 } classof(const Stmt * T)1020 static bool classof(const Stmt *T) { 1021 return T->getStmtClass() == ForStmtClass; 1022 } classof(const ForStmt *)1023 static bool classof(const ForStmt *) { return true; } 1024 1025 // Iterators children()1026 child_range children() { 1027 return child_range(&SubExprs[0], &SubExprs[0]+END_EXPR); 1028 } 1029 }; 1030 1031 /// GotoStmt - This represents a direct goto. 1032 /// 1033 class GotoStmt : public Stmt { 1034 LabelDecl *Label; 1035 SourceLocation GotoLoc; 1036 SourceLocation LabelLoc; 1037 public: GotoStmt(LabelDecl * label,SourceLocation GL,SourceLocation LL)1038 GotoStmt(LabelDecl *label, SourceLocation GL, SourceLocation LL) 1039 : Stmt(GotoStmtClass), Label(label), GotoLoc(GL), LabelLoc(LL) {} 1040 1041 /// \brief Build an empty goto statement. GotoStmt(EmptyShell Empty)1042 explicit GotoStmt(EmptyShell Empty) : Stmt(GotoStmtClass, Empty) { } 1043 getLabel()1044 LabelDecl *getLabel() const { return Label; } setLabel(LabelDecl * D)1045 void setLabel(LabelDecl *D) { Label = D; } 1046 getGotoLoc()1047 SourceLocation getGotoLoc() const { return GotoLoc; } setGotoLoc(SourceLocation L)1048 void setGotoLoc(SourceLocation L) { GotoLoc = L; } getLabelLoc()1049 SourceLocation getLabelLoc() const { return LabelLoc; } setLabelLoc(SourceLocation L)1050 void setLabelLoc(SourceLocation L) { LabelLoc = L; } 1051 getSourceRange()1052 SourceRange getSourceRange() const { 1053 return SourceRange(GotoLoc, LabelLoc); 1054 } classof(const Stmt * T)1055 static bool classof(const Stmt *T) { 1056 return T->getStmtClass() == GotoStmtClass; 1057 } classof(const GotoStmt *)1058 static bool classof(const GotoStmt *) { return true; } 1059 1060 // Iterators children()1061 child_range children() { return child_range(); } 1062 }; 1063 1064 /// IndirectGotoStmt - This represents an indirect goto. 1065 /// 1066 class IndirectGotoStmt : public Stmt { 1067 SourceLocation GotoLoc; 1068 SourceLocation StarLoc; 1069 Stmt *Target; 1070 public: IndirectGotoStmt(SourceLocation gotoLoc,SourceLocation starLoc,Expr * target)1071 IndirectGotoStmt(SourceLocation gotoLoc, SourceLocation starLoc, 1072 Expr *target) 1073 : Stmt(IndirectGotoStmtClass), GotoLoc(gotoLoc), StarLoc(starLoc), 1074 Target((Stmt*)target) {} 1075 1076 /// \brief Build an empty indirect goto statement. IndirectGotoStmt(EmptyShell Empty)1077 explicit IndirectGotoStmt(EmptyShell Empty) 1078 : Stmt(IndirectGotoStmtClass, Empty) { } 1079 setGotoLoc(SourceLocation L)1080 void setGotoLoc(SourceLocation L) { GotoLoc = L; } getGotoLoc()1081 SourceLocation getGotoLoc() const { return GotoLoc; } setStarLoc(SourceLocation L)1082 void setStarLoc(SourceLocation L) { StarLoc = L; } getStarLoc()1083 SourceLocation getStarLoc() const { return StarLoc; } 1084 getTarget()1085 Expr *getTarget() { return reinterpret_cast<Expr*>(Target); } getTarget()1086 const Expr *getTarget() const {return reinterpret_cast<const Expr*>(Target);} setTarget(Expr * E)1087 void setTarget(Expr *E) { Target = reinterpret_cast<Stmt*>(E); } 1088 1089 /// getConstantTarget - Returns the fixed target of this indirect 1090 /// goto, if one exists. 1091 LabelDecl *getConstantTarget(); getConstantTarget()1092 const LabelDecl *getConstantTarget() const { 1093 return const_cast<IndirectGotoStmt*>(this)->getConstantTarget(); 1094 } 1095 getSourceRange()1096 SourceRange getSourceRange() const { 1097 return SourceRange(GotoLoc, Target->getLocEnd()); 1098 } 1099 classof(const Stmt * T)1100 static bool classof(const Stmt *T) { 1101 return T->getStmtClass() == IndirectGotoStmtClass; 1102 } classof(const IndirectGotoStmt *)1103 static bool classof(const IndirectGotoStmt *) { return true; } 1104 1105 // Iterators children()1106 child_range children() { return child_range(&Target, &Target+1); } 1107 }; 1108 1109 1110 /// ContinueStmt - This represents a continue. 1111 /// 1112 class ContinueStmt : public Stmt { 1113 SourceLocation ContinueLoc; 1114 public: ContinueStmt(SourceLocation CL)1115 ContinueStmt(SourceLocation CL) : Stmt(ContinueStmtClass), ContinueLoc(CL) {} 1116 1117 /// \brief Build an empty continue statement. ContinueStmt(EmptyShell Empty)1118 explicit ContinueStmt(EmptyShell Empty) : Stmt(ContinueStmtClass, Empty) { } 1119 getContinueLoc()1120 SourceLocation getContinueLoc() const { return ContinueLoc; } setContinueLoc(SourceLocation L)1121 void setContinueLoc(SourceLocation L) { ContinueLoc = L; } 1122 getSourceRange()1123 SourceRange getSourceRange() const { 1124 return SourceRange(ContinueLoc); 1125 } 1126 classof(const Stmt * T)1127 static bool classof(const Stmt *T) { 1128 return T->getStmtClass() == ContinueStmtClass; 1129 } classof(const ContinueStmt *)1130 static bool classof(const ContinueStmt *) { return true; } 1131 1132 // Iterators children()1133 child_range children() { return child_range(); } 1134 }; 1135 1136 /// BreakStmt - This represents a break. 1137 /// 1138 class BreakStmt : public Stmt { 1139 SourceLocation BreakLoc; 1140 public: BreakStmt(SourceLocation BL)1141 BreakStmt(SourceLocation BL) : Stmt(BreakStmtClass), BreakLoc(BL) {} 1142 1143 /// \brief Build an empty break statement. BreakStmt(EmptyShell Empty)1144 explicit BreakStmt(EmptyShell Empty) : Stmt(BreakStmtClass, Empty) { } 1145 getBreakLoc()1146 SourceLocation getBreakLoc() const { return BreakLoc; } setBreakLoc(SourceLocation L)1147 void setBreakLoc(SourceLocation L) { BreakLoc = L; } 1148 getSourceRange()1149 SourceRange getSourceRange() const { return SourceRange(BreakLoc); } 1150 classof(const Stmt * T)1151 static bool classof(const Stmt *T) { 1152 return T->getStmtClass() == BreakStmtClass; 1153 } classof(const BreakStmt *)1154 static bool classof(const BreakStmt *) { return true; } 1155 1156 // Iterators children()1157 child_range children() { return child_range(); } 1158 }; 1159 1160 1161 /// ReturnStmt - This represents a return, optionally of an expression: 1162 /// return; 1163 /// return 4; 1164 /// 1165 /// Note that GCC allows return with no argument in a function declared to 1166 /// return a value, and it allows returning a value in functions declared to 1167 /// return void. We explicitly model this in the AST, which means you can't 1168 /// depend on the return type of the function and the presence of an argument. 1169 /// 1170 class ReturnStmt : public Stmt { 1171 Stmt *RetExpr; 1172 SourceLocation RetLoc; 1173 const VarDecl *NRVOCandidate; 1174 1175 public: ReturnStmt(SourceLocation RL)1176 ReturnStmt(SourceLocation RL) 1177 : Stmt(ReturnStmtClass), RetExpr(0), RetLoc(RL), NRVOCandidate(0) { } 1178 ReturnStmt(SourceLocation RL,Expr * E,const VarDecl * NRVOCandidate)1179 ReturnStmt(SourceLocation RL, Expr *E, const VarDecl *NRVOCandidate) 1180 : Stmt(ReturnStmtClass), RetExpr((Stmt*) E), RetLoc(RL), 1181 NRVOCandidate(NRVOCandidate) {} 1182 1183 /// \brief Build an empty return expression. ReturnStmt(EmptyShell Empty)1184 explicit ReturnStmt(EmptyShell Empty) : Stmt(ReturnStmtClass, Empty) { } 1185 1186 const Expr *getRetValue() const; 1187 Expr *getRetValue(); setRetValue(Expr * E)1188 void setRetValue(Expr *E) { RetExpr = reinterpret_cast<Stmt*>(E); } 1189 getReturnLoc()1190 SourceLocation getReturnLoc() const { return RetLoc; } setReturnLoc(SourceLocation L)1191 void setReturnLoc(SourceLocation L) { RetLoc = L; } 1192 1193 /// \brief Retrieve the variable that might be used for the named return 1194 /// value optimization. 1195 /// 1196 /// The optimization itself can only be performed if the variable is 1197 /// also marked as an NRVO object. getNRVOCandidate()1198 const VarDecl *getNRVOCandidate() const { return NRVOCandidate; } setNRVOCandidate(const VarDecl * Var)1199 void setNRVOCandidate(const VarDecl *Var) { NRVOCandidate = Var; } 1200 1201 SourceRange getSourceRange() const; 1202 classof(const Stmt * T)1203 static bool classof(const Stmt *T) { 1204 return T->getStmtClass() == ReturnStmtClass; 1205 } classof(const ReturnStmt *)1206 static bool classof(const ReturnStmt *) { return true; } 1207 1208 // Iterators children()1209 child_range children() { 1210 if (RetExpr) return child_range(&RetExpr, &RetExpr+1); 1211 return child_range(); 1212 } 1213 }; 1214 1215 /// AsmStmt - This represents a GNU inline-assembly statement extension. 1216 /// 1217 class AsmStmt : public Stmt { 1218 SourceLocation AsmLoc, RParenLoc; 1219 StringLiteral *AsmStr; 1220 1221 bool IsSimple; 1222 bool IsVolatile; 1223 bool MSAsm; 1224 1225 unsigned NumOutputs; 1226 unsigned NumInputs; 1227 unsigned NumClobbers; 1228 1229 // FIXME: If we wanted to, we could allocate all of these in one big array. 1230 IdentifierInfo **Names; 1231 StringLiteral **Constraints; 1232 Stmt **Exprs; 1233 StringLiteral **Clobbers; 1234 1235 public: 1236 AsmStmt(ASTContext &C, SourceLocation asmloc, bool issimple, bool isvolatile, 1237 bool msasm, unsigned numoutputs, unsigned numinputs, 1238 IdentifierInfo **names, StringLiteral **constraints, 1239 Expr **exprs, StringLiteral *asmstr, unsigned numclobbers, 1240 StringLiteral **clobbers, SourceLocation rparenloc); 1241 1242 /// \brief Build an empty inline-assembly statement. AsmStmt(EmptyShell Empty)1243 explicit AsmStmt(EmptyShell Empty) : Stmt(AsmStmtClass, Empty), 1244 Names(0), Constraints(0), Exprs(0), Clobbers(0) { } 1245 getAsmLoc()1246 SourceLocation getAsmLoc() const { return AsmLoc; } setAsmLoc(SourceLocation L)1247 void setAsmLoc(SourceLocation L) { AsmLoc = L; } getRParenLoc()1248 SourceLocation getRParenLoc() const { return RParenLoc; } setRParenLoc(SourceLocation L)1249 void setRParenLoc(SourceLocation L) { RParenLoc = L; } 1250 isVolatile()1251 bool isVolatile() const { return IsVolatile; } setVolatile(bool V)1252 void setVolatile(bool V) { IsVolatile = V; } isSimple()1253 bool isSimple() const { return IsSimple; } setSimple(bool V)1254 void setSimple(bool V) { IsSimple = V; } isMSAsm()1255 bool isMSAsm() const { return MSAsm; } setMSAsm(bool V)1256 void setMSAsm(bool V) { MSAsm = V; } 1257 1258 //===--- Asm String Analysis ---===// 1259 getAsmString()1260 const StringLiteral *getAsmString() const { return AsmStr; } getAsmString()1261 StringLiteral *getAsmString() { return AsmStr; } setAsmString(StringLiteral * E)1262 void setAsmString(StringLiteral *E) { AsmStr = E; } 1263 1264 /// AsmStringPiece - this is part of a decomposed asm string specification 1265 /// (for use with the AnalyzeAsmString function below). An asm string is 1266 /// considered to be a concatenation of these parts. 1267 class AsmStringPiece { 1268 public: 1269 enum Kind { 1270 String, // String in .ll asm string form, "$" -> "$$" and "%%" -> "%". 1271 Operand // Operand reference, with optional modifier %c4. 1272 }; 1273 private: 1274 Kind MyKind; 1275 std::string Str; 1276 unsigned OperandNo; 1277 public: AsmStringPiece(const std::string & S)1278 AsmStringPiece(const std::string &S) : MyKind(String), Str(S) {} AsmStringPiece(unsigned OpNo,char Modifier)1279 AsmStringPiece(unsigned OpNo, char Modifier) 1280 : MyKind(Operand), Str(), OperandNo(OpNo) { 1281 Str += Modifier; 1282 } 1283 isString()1284 bool isString() const { return MyKind == String; } isOperand()1285 bool isOperand() const { return MyKind == Operand; } 1286 getString()1287 const std::string &getString() const { 1288 assert(isString()); 1289 return Str; 1290 } 1291 getOperandNo()1292 unsigned getOperandNo() const { 1293 assert(isOperand()); 1294 return OperandNo; 1295 } 1296 1297 /// getModifier - Get the modifier for this operand, if present. This 1298 /// returns '\0' if there was no modifier. getModifier()1299 char getModifier() const { 1300 assert(isOperand()); 1301 return Str[0]; 1302 } 1303 }; 1304 1305 /// AnalyzeAsmString - Analyze the asm string of the current asm, decomposing 1306 /// it into pieces. If the asm string is erroneous, emit errors and return 1307 /// true, otherwise return false. This handles canonicalization and 1308 /// translation of strings from GCC syntax to LLVM IR syntax, and handles 1309 //// flattening of named references like %[foo] to Operand AsmStringPiece's. 1310 unsigned AnalyzeAsmString(llvm::SmallVectorImpl<AsmStringPiece> &Pieces, 1311 ASTContext &C, unsigned &DiagOffs) const; 1312 1313 1314 //===--- Output operands ---===// 1315 getNumOutputs()1316 unsigned getNumOutputs() const { return NumOutputs; } 1317 getOutputIdentifier(unsigned i)1318 IdentifierInfo *getOutputIdentifier(unsigned i) const { 1319 return Names[i]; 1320 } 1321 getOutputName(unsigned i)1322 llvm::StringRef getOutputName(unsigned i) const { 1323 if (IdentifierInfo *II = getOutputIdentifier(i)) 1324 return II->getName(); 1325 1326 return llvm::StringRef(); 1327 } 1328 1329 /// getOutputConstraint - Return the constraint string for the specified 1330 /// output operand. All output constraints are known to be non-empty (either 1331 /// '=' or '+'). 1332 llvm::StringRef getOutputConstraint(unsigned i) const; 1333 getOutputConstraintLiteral(unsigned i)1334 const StringLiteral *getOutputConstraintLiteral(unsigned i) const { 1335 return Constraints[i]; 1336 } getOutputConstraintLiteral(unsigned i)1337 StringLiteral *getOutputConstraintLiteral(unsigned i) { 1338 return Constraints[i]; 1339 } 1340 1341 Expr *getOutputExpr(unsigned i); 1342 getOutputExpr(unsigned i)1343 const Expr *getOutputExpr(unsigned i) const { 1344 return const_cast<AsmStmt*>(this)->getOutputExpr(i); 1345 } 1346 1347 /// isOutputPlusConstraint - Return true if the specified output constraint 1348 /// is a "+" constraint (which is both an input and an output) or false if it 1349 /// is an "=" constraint (just an output). isOutputPlusConstraint(unsigned i)1350 bool isOutputPlusConstraint(unsigned i) const { 1351 return getOutputConstraint(i)[0] == '+'; 1352 } 1353 1354 /// getNumPlusOperands - Return the number of output operands that have a "+" 1355 /// constraint. 1356 unsigned getNumPlusOperands() const; 1357 1358 //===--- Input operands ---===// 1359 getNumInputs()1360 unsigned getNumInputs() const { return NumInputs; } 1361 getInputIdentifier(unsigned i)1362 IdentifierInfo *getInputIdentifier(unsigned i) const { 1363 return Names[i + NumOutputs]; 1364 } 1365 getInputName(unsigned i)1366 llvm::StringRef getInputName(unsigned i) const { 1367 if (IdentifierInfo *II = getInputIdentifier(i)) 1368 return II->getName(); 1369 1370 return llvm::StringRef(); 1371 } 1372 1373 /// getInputConstraint - Return the specified input constraint. Unlike output 1374 /// constraints, these can be empty. 1375 llvm::StringRef getInputConstraint(unsigned i) const; 1376 getInputConstraintLiteral(unsigned i)1377 const StringLiteral *getInputConstraintLiteral(unsigned i) const { 1378 return Constraints[i + NumOutputs]; 1379 } getInputConstraintLiteral(unsigned i)1380 StringLiteral *getInputConstraintLiteral(unsigned i) { 1381 return Constraints[i + NumOutputs]; 1382 } 1383 1384 Expr *getInputExpr(unsigned i); 1385 void setInputExpr(unsigned i, Expr *E); 1386 getInputExpr(unsigned i)1387 const Expr *getInputExpr(unsigned i) const { 1388 return const_cast<AsmStmt*>(this)->getInputExpr(i); 1389 } 1390 1391 void setOutputsAndInputsAndClobbers(ASTContext &C, 1392 IdentifierInfo **Names, 1393 StringLiteral **Constraints, 1394 Stmt **Exprs, 1395 unsigned NumOutputs, 1396 unsigned NumInputs, 1397 StringLiteral **Clobbers, 1398 unsigned NumClobbers); 1399 1400 //===--- Other ---===// 1401 1402 /// getNamedOperand - Given a symbolic operand reference like %[foo], 1403 /// translate this into a numeric value needed to reference the same operand. 1404 /// This returns -1 if the operand name is invalid. 1405 int getNamedOperand(llvm::StringRef SymbolicName) const; 1406 getNumClobbers()1407 unsigned getNumClobbers() const { return NumClobbers; } getClobber(unsigned i)1408 StringLiteral *getClobber(unsigned i) { return Clobbers[i]; } getClobber(unsigned i)1409 const StringLiteral *getClobber(unsigned i) const { return Clobbers[i]; } 1410 getSourceRange()1411 SourceRange getSourceRange() const { 1412 return SourceRange(AsmLoc, RParenLoc); 1413 } 1414 classof(const Stmt * T)1415 static bool classof(const Stmt *T) {return T->getStmtClass() == AsmStmtClass;} classof(const AsmStmt *)1416 static bool classof(const AsmStmt *) { return true; } 1417 1418 // Input expr iterators. 1419 1420 typedef ExprIterator inputs_iterator; 1421 typedef ConstExprIterator const_inputs_iterator; 1422 begin_inputs()1423 inputs_iterator begin_inputs() { 1424 return &Exprs[0] + NumOutputs; 1425 } 1426 end_inputs()1427 inputs_iterator end_inputs() { 1428 return &Exprs[0] + NumOutputs + NumInputs; 1429 } 1430 begin_inputs()1431 const_inputs_iterator begin_inputs() const { 1432 return &Exprs[0] + NumOutputs; 1433 } 1434 end_inputs()1435 const_inputs_iterator end_inputs() const { 1436 return &Exprs[0] + NumOutputs + NumInputs; 1437 } 1438 1439 // Output expr iterators. 1440 1441 typedef ExprIterator outputs_iterator; 1442 typedef ConstExprIterator const_outputs_iterator; 1443 begin_outputs()1444 outputs_iterator begin_outputs() { 1445 return &Exprs[0]; 1446 } end_outputs()1447 outputs_iterator end_outputs() { 1448 return &Exprs[0] + NumOutputs; 1449 } 1450 begin_outputs()1451 const_outputs_iterator begin_outputs() const { 1452 return &Exprs[0]; 1453 } end_outputs()1454 const_outputs_iterator end_outputs() const { 1455 return &Exprs[0] + NumOutputs; 1456 } 1457 children()1458 child_range children() { 1459 return child_range(&Exprs[0], &Exprs[0] + NumOutputs + NumInputs); 1460 } 1461 }; 1462 1463 class SEHExceptStmt : public Stmt { 1464 SourceLocation Loc; 1465 Stmt *Children[2]; 1466 1467 enum { FILTER_EXPR, BLOCK }; 1468 1469 SEHExceptStmt(SourceLocation Loc, 1470 Expr *FilterExpr, 1471 Stmt *Block); 1472 1473 friend class ASTReader; 1474 friend class ASTStmtReader; SEHExceptStmt(EmptyShell E)1475 explicit SEHExceptStmt(EmptyShell E) : Stmt(SEHExceptStmtClass, E) { } 1476 1477 public: 1478 static SEHExceptStmt* Create(ASTContext &C, 1479 SourceLocation ExceptLoc, 1480 Expr *FilterExpr, 1481 Stmt *Block); getSourceRange()1482 SourceRange getSourceRange() const { 1483 return SourceRange(getExceptLoc(), getEndLoc()); 1484 } 1485 getExceptLoc()1486 SourceLocation getExceptLoc() const { return Loc; } getEndLoc()1487 SourceLocation getEndLoc() const { return getBlock()->getLocEnd(); } 1488 getFilterExpr()1489 Expr *getFilterExpr() const { return reinterpret_cast<Expr*>(Children[FILTER_EXPR]); } getBlock()1490 CompoundStmt *getBlock() const { return llvm::cast<CompoundStmt>(Children[BLOCK]); } 1491 children()1492 child_range children() { 1493 return child_range(Children,Children+2); 1494 } 1495 classof(const Stmt * T)1496 static bool classof(const Stmt *T) { 1497 return T->getStmtClass() == SEHExceptStmtClass; 1498 } 1499 classof(SEHExceptStmt *)1500 static bool classof(SEHExceptStmt *) { return true; } 1501 1502 }; 1503 1504 class SEHFinallyStmt : public Stmt { 1505 SourceLocation Loc; 1506 Stmt *Block; 1507 1508 SEHFinallyStmt(SourceLocation Loc, 1509 Stmt *Block); 1510 1511 friend class ASTReader; 1512 friend class ASTStmtReader; SEHFinallyStmt(EmptyShell E)1513 explicit SEHFinallyStmt(EmptyShell E) : Stmt(SEHFinallyStmtClass, E) { } 1514 1515 public: 1516 static SEHFinallyStmt* Create(ASTContext &C, 1517 SourceLocation FinallyLoc, 1518 Stmt *Block); 1519 getSourceRange()1520 SourceRange getSourceRange() const { 1521 return SourceRange(getFinallyLoc(), getEndLoc()); 1522 } 1523 getFinallyLoc()1524 SourceLocation getFinallyLoc() const { return Loc; } getEndLoc()1525 SourceLocation getEndLoc() const { return Block->getLocEnd(); } 1526 getBlock()1527 CompoundStmt *getBlock() const { return llvm::cast<CompoundStmt>(Block); } 1528 children()1529 child_range children() { 1530 return child_range(&Block,&Block+1); 1531 } 1532 classof(const Stmt * T)1533 static bool classof(const Stmt *T) { 1534 return T->getStmtClass() == SEHFinallyStmtClass; 1535 } 1536 classof(SEHFinallyStmt *)1537 static bool classof(SEHFinallyStmt *) { return true; } 1538 1539 }; 1540 1541 class SEHTryStmt : public Stmt { 1542 bool IsCXXTry; 1543 SourceLocation TryLoc; 1544 Stmt *Children[2]; 1545 1546 enum { TRY = 0, HANDLER = 1 }; 1547 1548 SEHTryStmt(bool isCXXTry, // true if 'try' otherwise '__try' 1549 SourceLocation TryLoc, 1550 Stmt *TryBlock, 1551 Stmt *Handler); 1552 1553 friend class ASTReader; 1554 friend class ASTStmtReader; SEHTryStmt(EmptyShell E)1555 explicit SEHTryStmt(EmptyShell E) : Stmt(SEHTryStmtClass, E) { } 1556 1557 public: 1558 static SEHTryStmt* Create(ASTContext &C, 1559 bool isCXXTry, 1560 SourceLocation TryLoc, 1561 Stmt *TryBlock, 1562 Stmt *Handler); 1563 getSourceRange()1564 SourceRange getSourceRange() const { 1565 return SourceRange(getTryLoc(), getEndLoc()); 1566 } 1567 getTryLoc()1568 SourceLocation getTryLoc() const { return TryLoc; } getEndLoc()1569 SourceLocation getEndLoc() const { return Children[HANDLER]->getLocEnd(); } 1570 getIsCXXTry()1571 bool getIsCXXTry() const { return IsCXXTry; } getTryBlock()1572 CompoundStmt* getTryBlock() const { return llvm::cast<CompoundStmt>(Children[TRY]); } getHandler()1573 Stmt *getHandler() const { return Children[HANDLER]; } 1574 1575 /// Returns 0 if not defined 1576 SEHExceptStmt *getExceptHandler() const; 1577 SEHFinallyStmt *getFinallyHandler() const; 1578 children()1579 child_range children() { 1580 return child_range(Children,Children+2); 1581 } 1582 classof(const Stmt * T)1583 static bool classof(const Stmt *T) { 1584 return T->getStmtClass() == SEHTryStmtClass; 1585 } 1586 classof(SEHTryStmt *)1587 static bool classof(SEHTryStmt *) { return true; } 1588 1589 }; 1590 1591 } // end namespace clang 1592 1593 #endif 1594