1 //===- ThreadSafetyTIL.h ---------------------------------------*- 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 in the llvm repository for details. 7 // 8 //===----------------------------------------------------------------------===// 9 // 10 // This file defines a simple Typed Intermediate Language, or TIL, that is used 11 // by the thread safety analysis (See ThreadSafety.cpp). The TIL is intended 12 // to be largely independent of clang, in the hope that the analysis can be 13 // reused for other non-C++ languages. All dependencies on clang/llvm should 14 // go in ThreadSafetyUtil.h. 15 // 16 // Thread safety analysis works by comparing mutex expressions, e.g. 17 // 18 // class A { Mutex mu; int dat GUARDED_BY(this->mu); } 19 // class B { A a; } 20 // 21 // void foo(B* b) { 22 // (*b).a.mu.lock(); // locks (*b).a.mu 23 // b->a.dat = 0; // substitute &b->a for 'this'; 24 // // requires lock on (&b->a)->mu 25 // (b->a.mu).unlock(); // unlocks (b->a.mu) 26 // } 27 // 28 // As illustrated by the above example, clang Exprs are not well-suited to 29 // represent mutex expressions directly, since there is no easy way to compare 30 // Exprs for equivalence. The thread safety analysis thus lowers clang Exprs 31 // into a simple intermediate language (IL). The IL supports: 32 // 33 // (1) comparisons for semantic equality of expressions 34 // (2) SSA renaming of variables 35 // (3) wildcards and pattern matching over expressions 36 // (4) hash-based expression lookup 37 // 38 // The TIL is currently very experimental, is intended only for use within 39 // the thread safety analysis, and is subject to change without notice. 40 // After the API stabilizes and matures, it may be appropriate to make this 41 // more generally available to other analyses. 42 // 43 // UNDER CONSTRUCTION. USE AT YOUR OWN RISK. 44 // 45 //===----------------------------------------------------------------------===// 46 47 #ifndef LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYTIL_H 48 #define LLVM_CLANG_ANALYSIS_ANALYSES_THREADSAFETYTIL_H 49 50 // All clang include dependencies for this file must be put in 51 // ThreadSafetyUtil.h. 52 #include "ThreadSafetyUtil.h" 53 #include <algorithm> 54 #include <cassert> 55 #include <cstddef> 56 #include <stdint.h> 57 #include <utility> 58 59 60 namespace clang { 61 namespace threadSafety { 62 namespace til { 63 64 65 /// Enum for the different distinct classes of SExpr 66 enum TIL_Opcode { 67 #define TIL_OPCODE_DEF(X) COP_##X, 68 #include "ThreadSafetyOps.def" 69 #undef TIL_OPCODE_DEF 70 }; 71 72 /// Opcode for unary arithmetic operations. 73 enum TIL_UnaryOpcode : unsigned char { 74 UOP_Minus, // - 75 UOP_BitNot, // ~ 76 UOP_LogicNot // ! 77 }; 78 79 /// Opcode for binary arithmetic operations. 80 enum TIL_BinaryOpcode : unsigned char { 81 BOP_Add, // + 82 BOP_Sub, // - 83 BOP_Mul, // * 84 BOP_Div, // / 85 BOP_Rem, // % 86 BOP_Shl, // << 87 BOP_Shr, // >> 88 BOP_BitAnd, // & 89 BOP_BitXor, // ^ 90 BOP_BitOr, // | 91 BOP_Eq, // == 92 BOP_Neq, // != 93 BOP_Lt, // < 94 BOP_Leq, // <= 95 BOP_LogicAnd, // && (no short-circuit) 96 BOP_LogicOr // || (no short-circuit) 97 }; 98 99 /// Opcode for cast operations. 100 enum TIL_CastOpcode : unsigned char { 101 CAST_none = 0, 102 CAST_extendNum, // extend precision of numeric type 103 CAST_truncNum, // truncate precision of numeric type 104 CAST_toFloat, // convert to floating point type 105 CAST_toInt, // convert to integer type 106 CAST_objToPtr // convert smart pointer to pointer (C++ only) 107 }; 108 109 const TIL_Opcode COP_Min = COP_Future; 110 const TIL_Opcode COP_Max = COP_Branch; 111 const TIL_UnaryOpcode UOP_Min = UOP_Minus; 112 const TIL_UnaryOpcode UOP_Max = UOP_LogicNot; 113 const TIL_BinaryOpcode BOP_Min = BOP_Add; 114 const TIL_BinaryOpcode BOP_Max = BOP_LogicOr; 115 const TIL_CastOpcode CAST_Min = CAST_none; 116 const TIL_CastOpcode CAST_Max = CAST_toInt; 117 118 /// Return the name of a unary opcode. 119 StringRef getUnaryOpcodeString(TIL_UnaryOpcode Op); 120 121 /// Return the name of a binary opcode. 122 StringRef getBinaryOpcodeString(TIL_BinaryOpcode Op); 123 124 125 /// ValueTypes are data types that can actually be held in registers. 126 /// All variables and expressions must have a value type. 127 /// Pointer types are further subdivided into the various heap-allocated 128 /// types, such as functions, records, etc. 129 /// Structured types that are passed by value (e.g. complex numbers) 130 /// require special handling; they use BT_ValueRef, and size ST_0. 131 struct ValueType { 132 enum BaseType : unsigned char { 133 BT_Void = 0, 134 BT_Bool, 135 BT_Int, 136 BT_Float, 137 BT_String, // String literals 138 BT_Pointer, 139 BT_ValueRef 140 }; 141 142 enum SizeType : unsigned char { 143 ST_0 = 0, 144 ST_1, 145 ST_8, 146 ST_16, 147 ST_32, 148 ST_64, 149 ST_128 150 }; 151 152 inline static SizeType getSizeType(unsigned nbytes); 153 154 template <class T> 155 inline static ValueType getValueType(); 156 157 ValueType(BaseType B, SizeType Sz, bool S, unsigned char VS) 158 : Base(B), Size(Sz), Signed(S), VectSize(VS) 159 { } 160 161 BaseType Base; 162 SizeType Size; 163 bool Signed; 164 unsigned char VectSize; // 0 for scalar, otherwise num elements in vector 165 }; 166 167 168 inline ValueType::SizeType ValueType::getSizeType(unsigned nbytes) { 169 switch (nbytes) { 170 case 1: return ST_8; 171 case 2: return ST_16; 172 case 4: return ST_32; 173 case 8: return ST_64; 174 case 16: return ST_128; 175 default: return ST_0; 176 } 177 } 178 179 180 template<> 181 inline ValueType ValueType::getValueType<void>() { 182 return ValueType(BT_Void, ST_0, false, 0); 183 } 184 185 template<> 186 inline ValueType ValueType::getValueType<bool>() { 187 return ValueType(BT_Bool, ST_1, false, 0); 188 } 189 190 template<> 191 inline ValueType ValueType::getValueType<int8_t>() { 192 return ValueType(BT_Int, ST_8, true, 0); 193 } 194 195 template<> 196 inline ValueType ValueType::getValueType<uint8_t>() { 197 return ValueType(BT_Int, ST_8, false, 0); 198 } 199 200 template<> 201 inline ValueType ValueType::getValueType<int16_t>() { 202 return ValueType(BT_Int, ST_16, true, 0); 203 } 204 205 template<> 206 inline ValueType ValueType::getValueType<uint16_t>() { 207 return ValueType(BT_Int, ST_16, false, 0); 208 } 209 210 template<> 211 inline ValueType ValueType::getValueType<int32_t>() { 212 return ValueType(BT_Int, ST_32, true, 0); 213 } 214 215 template<> 216 inline ValueType ValueType::getValueType<uint32_t>() { 217 return ValueType(BT_Int, ST_32, false, 0); 218 } 219 220 template<> 221 inline ValueType ValueType::getValueType<int64_t>() { 222 return ValueType(BT_Int, ST_64, true, 0); 223 } 224 225 template<> 226 inline ValueType ValueType::getValueType<uint64_t>() { 227 return ValueType(BT_Int, ST_64, false, 0); 228 } 229 230 template<> 231 inline ValueType ValueType::getValueType<float>() { 232 return ValueType(BT_Float, ST_32, true, 0); 233 } 234 235 template<> 236 inline ValueType ValueType::getValueType<double>() { 237 return ValueType(BT_Float, ST_64, true, 0); 238 } 239 240 template<> 241 inline ValueType ValueType::getValueType<long double>() { 242 return ValueType(BT_Float, ST_128, true, 0); 243 } 244 245 template<> 246 inline ValueType ValueType::getValueType<StringRef>() { 247 return ValueType(BT_String, getSizeType(sizeof(StringRef)), false, 0); 248 } 249 250 template<> 251 inline ValueType ValueType::getValueType<void*>() { 252 return ValueType(BT_Pointer, getSizeType(sizeof(void*)), false, 0); 253 } 254 255 256 class BasicBlock; 257 258 259 /// Base class for AST nodes in the typed intermediate language. 260 class SExpr { 261 public: 262 TIL_Opcode opcode() const { return static_cast<TIL_Opcode>(Opcode); } 263 264 // Subclasses of SExpr must define the following: 265 // 266 // This(const This& E, ...) { 267 // copy constructor: construct copy of E, with some additional arguments. 268 // } 269 // 270 // template <class V> 271 // typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 272 // traverse all subexpressions, following the traversal/rewriter interface. 273 // } 274 // 275 // template <class C> typename C::CType compare(CType* E, C& Cmp) { 276 // compare all subexpressions, following the comparator interface 277 // } 278 void *operator new(size_t S, MemRegionRef &R) { 279 return ::operator new(S, R); 280 } 281 282 /// SExpr objects cannot be deleted. 283 // This declaration is public to workaround a gcc bug that breaks building 284 // with REQUIRES_EH=1. 285 void operator delete(void *) = delete; 286 287 /// Returns the instruction ID for this expression. 288 /// All basic block instructions have a unique ID (i.e. virtual register). 289 unsigned id() const { return SExprID; } 290 291 /// Returns the block, if this is an instruction in a basic block, 292 /// otherwise returns null. 293 BasicBlock* block() const { return Block; } 294 295 /// Set the basic block and instruction ID for this expression. 296 void setID(BasicBlock *B, unsigned id) { Block = B; SExprID = id; } 297 298 protected: 299 SExpr(TIL_Opcode Op) 300 : Opcode(Op), Reserved(0), Flags(0), SExprID(0), Block(nullptr) {} 301 SExpr(const SExpr &E) 302 : Opcode(E.Opcode), Reserved(0), Flags(E.Flags), SExprID(0), 303 Block(nullptr) {} 304 305 const unsigned char Opcode; 306 unsigned char Reserved; 307 unsigned short Flags; 308 unsigned SExprID; 309 BasicBlock* Block; 310 311 private: 312 SExpr() = delete; 313 314 /// SExpr objects must be created in an arena. 315 void *operator new(size_t) = delete; 316 }; 317 318 319 // Contains various helper functions for SExprs. 320 namespace ThreadSafetyTIL { 321 inline bool isTrivial(const SExpr *E) { 322 unsigned Op = E->opcode(); 323 return Op == COP_Variable || Op == COP_Literal || Op == COP_LiteralPtr; 324 } 325 } 326 327 // Nodes which declare variables 328 class Function; 329 class SFunction; 330 class Let; 331 332 333 /// A named variable, e.g. "x". 334 /// 335 /// There are two distinct places in which a Variable can appear in the AST. 336 /// A variable declaration introduces a new variable, and can occur in 3 places: 337 /// Let-expressions: (Let (x = t) u) 338 /// Functions: (Function (x : t) u) 339 /// Self-applicable functions (SFunction (x) t) 340 /// 341 /// If a variable occurs in any other location, it is a reference to an existing 342 /// variable declaration -- e.g. 'x' in (x * y + z). To save space, we don't 343 /// allocate a separate AST node for variable references; a reference is just a 344 /// pointer to the original declaration. 345 class Variable : public SExpr { 346 public: 347 static bool classof(const SExpr *E) { return E->opcode() == COP_Variable; } 348 349 enum VariableKind { 350 VK_Let, ///< Let-variable 351 VK_Fun, ///< Function parameter 352 VK_SFun ///< SFunction (self) parameter 353 }; 354 355 Variable(StringRef s, SExpr *D = nullptr) 356 : SExpr(COP_Variable), Name(s), Definition(D), Cvdecl(nullptr) { 357 Flags = VK_Let; 358 } 359 Variable(SExpr *D, const clang::ValueDecl *Cvd = nullptr) 360 : SExpr(COP_Variable), Name(Cvd ? Cvd->getName() : "_x"), 361 Definition(D), Cvdecl(Cvd) { 362 Flags = VK_Let; 363 } 364 Variable(const Variable &Vd, SExpr *D) // rewrite constructor 365 : SExpr(Vd), Name(Vd.Name), Definition(D), Cvdecl(Vd.Cvdecl) { 366 Flags = Vd.kind(); 367 } 368 369 /// Return the kind of variable (let, function param, or self) 370 VariableKind kind() const { return static_cast<VariableKind>(Flags); } 371 372 /// Return the name of the variable, if any. 373 StringRef name() const { return Name; } 374 375 /// Return the clang declaration for this variable, if any. 376 const clang::ValueDecl *clangDecl() const { return Cvdecl; } 377 378 /// Return the definition of the variable. 379 /// For let-vars, this is the setting expression. 380 /// For function and self parameters, it is the type of the variable. 381 SExpr *definition() { return Definition; } 382 const SExpr *definition() const { return Definition; } 383 384 void setName(StringRef S) { Name = S; } 385 void setKind(VariableKind K) { Flags = K; } 386 void setDefinition(SExpr *E) { Definition = E; } 387 void setClangDecl(const clang::ValueDecl *VD) { Cvdecl = VD; } 388 389 template <class V> 390 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 391 // This routine is only called for variable references. 392 return Vs.reduceVariableRef(this); 393 } 394 395 template <class C> 396 typename C::CType compare(const Variable* E, C& Cmp) const { 397 return Cmp.compareVariableRefs(this, E); 398 } 399 400 private: 401 friend class Function; 402 friend class SFunction; 403 friend class BasicBlock; 404 friend class Let; 405 406 StringRef Name; // The name of the variable. 407 SExpr* Definition; // The TIL type or definition 408 const clang::ValueDecl *Cvdecl; // The clang declaration for this variable. 409 }; 410 411 412 /// Placeholder for an expression that has not yet been created. 413 /// Used to implement lazy copy and rewriting strategies. 414 class Future : public SExpr { 415 public: 416 static bool classof(const SExpr *E) { return E->opcode() == COP_Future; } 417 418 enum FutureStatus { 419 FS_pending, 420 FS_evaluating, 421 FS_done 422 }; 423 424 Future() : SExpr(COP_Future), Status(FS_pending), Result(nullptr) {} 425 426 private: 427 virtual ~Future() = delete; 428 429 public: 430 // A lazy rewriting strategy should subclass Future and override this method. 431 virtual SExpr *compute() { return nullptr; } 432 433 // Return the result of this future if it exists, otherwise return null. 434 SExpr *maybeGetResult() const { 435 return Result; 436 } 437 438 // Return the result of this future; forcing it if necessary. 439 SExpr *result() { 440 switch (Status) { 441 case FS_pending: 442 return force(); 443 case FS_evaluating: 444 return nullptr; // infinite loop; illegal recursion. 445 case FS_done: 446 return Result; 447 } 448 } 449 450 template <class V> 451 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 452 assert(Result && "Cannot traverse Future that has not been forced."); 453 return Vs.traverse(Result, Ctx); 454 } 455 456 template <class C> 457 typename C::CType compare(const Future* E, C& Cmp) const { 458 if (!Result || !E->Result) 459 return Cmp.comparePointers(this, E); 460 return Cmp.compare(Result, E->Result); 461 } 462 463 private: 464 SExpr* force(); 465 466 FutureStatus Status; 467 SExpr *Result; 468 }; 469 470 471 /// Placeholder for expressions that cannot be represented in the TIL. 472 class Undefined : public SExpr { 473 public: 474 static bool classof(const SExpr *E) { return E->opcode() == COP_Undefined; } 475 476 Undefined(const clang::Stmt *S = nullptr) : SExpr(COP_Undefined), Cstmt(S) {} 477 Undefined(const Undefined &U) : SExpr(U), Cstmt(U.Cstmt) {} 478 479 template <class V> 480 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 481 return Vs.reduceUndefined(*this); 482 } 483 484 template <class C> 485 typename C::CType compare(const Undefined* E, C& Cmp) const { 486 return Cmp.trueResult(); 487 } 488 489 private: 490 const clang::Stmt *Cstmt; 491 }; 492 493 494 /// Placeholder for a wildcard that matches any other expression. 495 class Wildcard : public SExpr { 496 public: 497 static bool classof(const SExpr *E) { return E->opcode() == COP_Wildcard; } 498 499 Wildcard() : SExpr(COP_Wildcard) {} 500 Wildcard(const Wildcard &W) : SExpr(W) {} 501 502 template <class V> typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 503 return Vs.reduceWildcard(*this); 504 } 505 506 template <class C> 507 typename C::CType compare(const Wildcard* E, C& Cmp) const { 508 return Cmp.trueResult(); 509 } 510 }; 511 512 513 template <class T> class LiteralT; 514 515 // Base class for literal values. 516 class Literal : public SExpr { 517 public: 518 static bool classof(const SExpr *E) { return E->opcode() == COP_Literal; } 519 520 Literal(const clang::Expr *C) 521 : SExpr(COP_Literal), ValType(ValueType::getValueType<void>()), Cexpr(C) 522 { } 523 Literal(ValueType VT) : SExpr(COP_Literal), ValType(VT), Cexpr(nullptr) {} 524 Literal(const Literal &L) : SExpr(L), ValType(L.ValType), Cexpr(L.Cexpr) {} 525 526 // The clang expression for this literal. 527 const clang::Expr *clangExpr() const { return Cexpr; } 528 529 ValueType valueType() const { return ValType; } 530 531 template<class T> const LiteralT<T>& as() const { 532 return *static_cast<const LiteralT<T>*>(this); 533 } 534 template<class T> LiteralT<T>& as() { 535 return *static_cast<LiteralT<T>*>(this); 536 } 537 538 template <class V> typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx); 539 540 template <class C> 541 typename C::CType compare(const Literal* E, C& Cmp) const { 542 // TODO: defer actual comparison to LiteralT 543 return Cmp.trueResult(); 544 } 545 546 private: 547 const ValueType ValType; 548 const clang::Expr *Cexpr; 549 }; 550 551 552 // Derived class for literal values, which stores the actual value. 553 template<class T> 554 class LiteralT : public Literal { 555 public: 556 LiteralT(T Dat) : Literal(ValueType::getValueType<T>()), Val(Dat) { } 557 LiteralT(const LiteralT<T> &L) : Literal(L), Val(L.Val) { } 558 559 T value() const { return Val;} 560 T& value() { return Val; } 561 562 private: 563 T Val; 564 }; 565 566 567 568 template <class V> 569 typename V::R_SExpr Literal::traverse(V &Vs, typename V::R_Ctx Ctx) { 570 if (Cexpr) 571 return Vs.reduceLiteral(*this); 572 573 switch (ValType.Base) { 574 case ValueType::BT_Void: 575 break; 576 case ValueType::BT_Bool: 577 return Vs.reduceLiteralT(as<bool>()); 578 case ValueType::BT_Int: { 579 switch (ValType.Size) { 580 case ValueType::ST_8: 581 if (ValType.Signed) 582 return Vs.reduceLiteralT(as<int8_t>()); 583 else 584 return Vs.reduceLiteralT(as<uint8_t>()); 585 case ValueType::ST_16: 586 if (ValType.Signed) 587 return Vs.reduceLiteralT(as<int16_t>()); 588 else 589 return Vs.reduceLiteralT(as<uint16_t>()); 590 case ValueType::ST_32: 591 if (ValType.Signed) 592 return Vs.reduceLiteralT(as<int32_t>()); 593 else 594 return Vs.reduceLiteralT(as<uint32_t>()); 595 case ValueType::ST_64: 596 if (ValType.Signed) 597 return Vs.reduceLiteralT(as<int64_t>()); 598 else 599 return Vs.reduceLiteralT(as<uint64_t>()); 600 default: 601 break; 602 } 603 } 604 case ValueType::BT_Float: { 605 switch (ValType.Size) { 606 case ValueType::ST_32: 607 return Vs.reduceLiteralT(as<float>()); 608 case ValueType::ST_64: 609 return Vs.reduceLiteralT(as<double>()); 610 default: 611 break; 612 } 613 } 614 case ValueType::BT_String: 615 return Vs.reduceLiteralT(as<StringRef>()); 616 case ValueType::BT_Pointer: 617 return Vs.reduceLiteralT(as<void*>()); 618 case ValueType::BT_ValueRef: 619 break; 620 } 621 return Vs.reduceLiteral(*this); 622 } 623 624 625 /// A Literal pointer to an object allocated in memory. 626 /// At compile time, pointer literals are represented by symbolic names. 627 class LiteralPtr : public SExpr { 628 public: 629 static bool classof(const SExpr *E) { return E->opcode() == COP_LiteralPtr; } 630 631 LiteralPtr(const clang::ValueDecl *D) : SExpr(COP_LiteralPtr), Cvdecl(D) {} 632 LiteralPtr(const LiteralPtr &R) : SExpr(R), Cvdecl(R.Cvdecl) {} 633 634 // The clang declaration for the value that this pointer points to. 635 const clang::ValueDecl *clangDecl() const { return Cvdecl; } 636 637 template <class V> 638 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 639 return Vs.reduceLiteralPtr(*this); 640 } 641 642 template <class C> 643 typename C::CType compare(const LiteralPtr* E, C& Cmp) const { 644 return Cmp.comparePointers(Cvdecl, E->Cvdecl); 645 } 646 647 private: 648 const clang::ValueDecl *Cvdecl; 649 }; 650 651 652 /// A function -- a.k.a. lambda abstraction. 653 /// Functions with multiple arguments are created by currying, 654 /// e.g. (Function (x: Int) (Function (y: Int) (Code { return x + y }))) 655 class Function : public SExpr { 656 public: 657 static bool classof(const SExpr *E) { return E->opcode() == COP_Function; } 658 659 Function(Variable *Vd, SExpr *Bd) 660 : SExpr(COP_Function), VarDecl(Vd), Body(Bd) { 661 Vd->setKind(Variable::VK_Fun); 662 } 663 Function(const Function &F, Variable *Vd, SExpr *Bd) // rewrite constructor 664 : SExpr(F), VarDecl(Vd), Body(Bd) { 665 Vd->setKind(Variable::VK_Fun); 666 } 667 668 Variable *variableDecl() { return VarDecl; } 669 const Variable *variableDecl() const { return VarDecl; } 670 671 SExpr *body() { return Body; } 672 const SExpr *body() const { return Body; } 673 674 template <class V> 675 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 676 // This is a variable declaration, so traverse the definition. 677 auto E0 = Vs.traverse(VarDecl->Definition, Vs.typeCtx(Ctx)); 678 // Tell the rewriter to enter the scope of the function. 679 Variable *Nvd = Vs.enterScope(*VarDecl, E0); 680 auto E1 = Vs.traverse(Body, Vs.declCtx(Ctx)); 681 Vs.exitScope(*VarDecl); 682 return Vs.reduceFunction(*this, Nvd, E1); 683 } 684 685 template <class C> 686 typename C::CType compare(const Function* E, C& Cmp) const { 687 typename C::CType Ct = 688 Cmp.compare(VarDecl->definition(), E->VarDecl->definition()); 689 if (Cmp.notTrue(Ct)) 690 return Ct; 691 Cmp.enterScope(variableDecl(), E->variableDecl()); 692 Ct = Cmp.compare(body(), E->body()); 693 Cmp.leaveScope(); 694 return Ct; 695 } 696 697 private: 698 Variable *VarDecl; 699 SExpr* Body; 700 }; 701 702 703 /// A self-applicable function. 704 /// A self-applicable function can be applied to itself. It's useful for 705 /// implementing objects and late binding. 706 class SFunction : public SExpr { 707 public: 708 static bool classof(const SExpr *E) { return E->opcode() == COP_SFunction; } 709 710 SFunction(Variable *Vd, SExpr *B) 711 : SExpr(COP_SFunction), VarDecl(Vd), Body(B) { 712 assert(Vd->Definition == nullptr); 713 Vd->setKind(Variable::VK_SFun); 714 Vd->Definition = this; 715 } 716 SFunction(const SFunction &F, Variable *Vd, SExpr *B) // rewrite constructor 717 : SExpr(F), VarDecl(Vd), Body(B) { 718 assert(Vd->Definition == nullptr); 719 Vd->setKind(Variable::VK_SFun); 720 Vd->Definition = this; 721 } 722 723 Variable *variableDecl() { return VarDecl; } 724 const Variable *variableDecl() const { return VarDecl; } 725 726 SExpr *body() { return Body; } 727 const SExpr *body() const { return Body; } 728 729 template <class V> 730 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 731 // A self-variable points to the SFunction itself. 732 // A rewrite must introduce the variable with a null definition, and update 733 // it after 'this' has been rewritten. 734 Variable *Nvd = Vs.enterScope(*VarDecl, nullptr); 735 auto E1 = Vs.traverse(Body, Vs.declCtx(Ctx)); 736 Vs.exitScope(*VarDecl); 737 // A rewrite operation will call SFun constructor to set Vvd->Definition. 738 return Vs.reduceSFunction(*this, Nvd, E1); 739 } 740 741 template <class C> 742 typename C::CType compare(const SFunction* E, C& Cmp) const { 743 Cmp.enterScope(variableDecl(), E->variableDecl()); 744 typename C::CType Ct = Cmp.compare(body(), E->body()); 745 Cmp.leaveScope(); 746 return Ct; 747 } 748 749 private: 750 Variable *VarDecl; 751 SExpr* Body; 752 }; 753 754 755 /// A block of code -- e.g. the body of a function. 756 class Code : public SExpr { 757 public: 758 static bool classof(const SExpr *E) { return E->opcode() == COP_Code; } 759 760 Code(SExpr *T, SExpr *B) : SExpr(COP_Code), ReturnType(T), Body(B) {} 761 Code(const Code &C, SExpr *T, SExpr *B) // rewrite constructor 762 : SExpr(C), ReturnType(T), Body(B) {} 763 764 SExpr *returnType() { return ReturnType; } 765 const SExpr *returnType() const { return ReturnType; } 766 767 SExpr *body() { return Body; } 768 const SExpr *body() const { return Body; } 769 770 template <class V> 771 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 772 auto Nt = Vs.traverse(ReturnType, Vs.typeCtx(Ctx)); 773 auto Nb = Vs.traverse(Body, Vs.lazyCtx(Ctx)); 774 return Vs.reduceCode(*this, Nt, Nb); 775 } 776 777 template <class C> 778 typename C::CType compare(const Code* E, C& Cmp) const { 779 typename C::CType Ct = Cmp.compare(returnType(), E->returnType()); 780 if (Cmp.notTrue(Ct)) 781 return Ct; 782 return Cmp.compare(body(), E->body()); 783 } 784 785 private: 786 SExpr* ReturnType; 787 SExpr* Body; 788 }; 789 790 791 /// A typed, writable location in memory 792 class Field : public SExpr { 793 public: 794 static bool classof(const SExpr *E) { return E->opcode() == COP_Field; } 795 796 Field(SExpr *R, SExpr *B) : SExpr(COP_Field), Range(R), Body(B) {} 797 Field(const Field &C, SExpr *R, SExpr *B) // rewrite constructor 798 : SExpr(C), Range(R), Body(B) {} 799 800 SExpr *range() { return Range; } 801 const SExpr *range() const { return Range; } 802 803 SExpr *body() { return Body; } 804 const SExpr *body() const { return Body; } 805 806 template <class V> 807 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 808 auto Nr = Vs.traverse(Range, Vs.typeCtx(Ctx)); 809 auto Nb = Vs.traverse(Body, Vs.lazyCtx(Ctx)); 810 return Vs.reduceField(*this, Nr, Nb); 811 } 812 813 template <class C> 814 typename C::CType compare(const Field* E, C& Cmp) const { 815 typename C::CType Ct = Cmp.compare(range(), E->range()); 816 if (Cmp.notTrue(Ct)) 817 return Ct; 818 return Cmp.compare(body(), E->body()); 819 } 820 821 private: 822 SExpr* Range; 823 SExpr* Body; 824 }; 825 826 827 /// Apply an argument to a function. 828 /// Note that this does not actually call the function. Functions are curried, 829 /// so this returns a closure in which the first parameter has been applied. 830 /// Once all parameters have been applied, Call can be used to invoke the 831 /// function. 832 class Apply : public SExpr { 833 public: 834 static bool classof(const SExpr *E) { return E->opcode() == COP_Apply; } 835 836 Apply(SExpr *F, SExpr *A) : SExpr(COP_Apply), Fun(F), Arg(A) {} 837 Apply(const Apply &A, SExpr *F, SExpr *Ar) // rewrite constructor 838 : SExpr(A), Fun(F), Arg(Ar) 839 {} 840 841 SExpr *fun() { return Fun; } 842 const SExpr *fun() const { return Fun; } 843 844 SExpr *arg() { return Arg; } 845 const SExpr *arg() const { return Arg; } 846 847 template <class V> 848 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 849 auto Nf = Vs.traverse(Fun, Vs.subExprCtx(Ctx)); 850 auto Na = Vs.traverse(Arg, Vs.subExprCtx(Ctx)); 851 return Vs.reduceApply(*this, Nf, Na); 852 } 853 854 template <class C> 855 typename C::CType compare(const Apply* E, C& Cmp) const { 856 typename C::CType Ct = Cmp.compare(fun(), E->fun()); 857 if (Cmp.notTrue(Ct)) 858 return Ct; 859 return Cmp.compare(arg(), E->arg()); 860 } 861 862 private: 863 SExpr* Fun; 864 SExpr* Arg; 865 }; 866 867 868 /// Apply a self-argument to a self-applicable function. 869 class SApply : public SExpr { 870 public: 871 static bool classof(const SExpr *E) { return E->opcode() == COP_SApply; } 872 873 SApply(SExpr *Sf, SExpr *A = nullptr) : SExpr(COP_SApply), Sfun(Sf), Arg(A) {} 874 SApply(SApply &A, SExpr *Sf, SExpr *Ar = nullptr) // rewrite constructor 875 : SExpr(A), Sfun(Sf), Arg(Ar) {} 876 877 SExpr *sfun() { return Sfun; } 878 const SExpr *sfun() const { return Sfun; } 879 880 SExpr *arg() { return Arg ? Arg : Sfun; } 881 const SExpr *arg() const { return Arg ? Arg : Sfun; } 882 883 bool isDelegation() const { return Arg != nullptr; } 884 885 template <class V> 886 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 887 auto Nf = Vs.traverse(Sfun, Vs.subExprCtx(Ctx)); 888 typename V::R_SExpr Na = Arg ? Vs.traverse(Arg, Vs.subExprCtx(Ctx)) 889 : nullptr; 890 return Vs.reduceSApply(*this, Nf, Na); 891 } 892 893 template <class C> 894 typename C::CType compare(const SApply* E, C& Cmp) const { 895 typename C::CType Ct = Cmp.compare(sfun(), E->sfun()); 896 if (Cmp.notTrue(Ct) || (!arg() && !E->arg())) 897 return Ct; 898 return Cmp.compare(arg(), E->arg()); 899 } 900 901 private: 902 SExpr* Sfun; 903 SExpr* Arg; 904 }; 905 906 907 /// Project a named slot from a C++ struct or class. 908 class Project : public SExpr { 909 public: 910 static bool classof(const SExpr *E) { return E->opcode() == COP_Project; } 911 912 Project(SExpr *R, StringRef SName) 913 : SExpr(COP_Project), Rec(R), SlotName(SName), Cvdecl(nullptr) 914 { } 915 Project(SExpr *R, const clang::ValueDecl *Cvd) 916 : SExpr(COP_Project), Rec(R), SlotName(Cvd->getName()), Cvdecl(Cvd) 917 { } 918 Project(const Project &P, SExpr *R) 919 : SExpr(P), Rec(R), SlotName(P.SlotName), Cvdecl(P.Cvdecl) 920 { } 921 922 SExpr *record() { return Rec; } 923 const SExpr *record() const { return Rec; } 924 925 const clang::ValueDecl *clangDecl() const { return Cvdecl; } 926 927 bool isArrow() const { return (Flags & 0x01) != 0; } 928 void setArrow(bool b) { 929 if (b) Flags |= 0x01; 930 else Flags &= 0xFFFE; 931 } 932 933 StringRef slotName() const { 934 if (Cvdecl) 935 return Cvdecl->getName(); 936 else 937 return SlotName; 938 } 939 940 template <class V> 941 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 942 auto Nr = Vs.traverse(Rec, Vs.subExprCtx(Ctx)); 943 return Vs.reduceProject(*this, Nr); 944 } 945 946 template <class C> 947 typename C::CType compare(const Project* E, C& Cmp) const { 948 typename C::CType Ct = Cmp.compare(record(), E->record()); 949 if (Cmp.notTrue(Ct)) 950 return Ct; 951 return Cmp.comparePointers(Cvdecl, E->Cvdecl); 952 } 953 954 private: 955 SExpr* Rec; 956 StringRef SlotName; 957 const clang::ValueDecl *Cvdecl; 958 }; 959 960 961 /// Call a function (after all arguments have been applied). 962 class Call : public SExpr { 963 public: 964 static bool classof(const SExpr *E) { return E->opcode() == COP_Call; } 965 966 Call(SExpr *T, const clang::CallExpr *Ce = nullptr) 967 : SExpr(COP_Call), Target(T), Cexpr(Ce) {} 968 Call(const Call &C, SExpr *T) : SExpr(C), Target(T), Cexpr(C.Cexpr) {} 969 970 SExpr *target() { return Target; } 971 const SExpr *target() const { return Target; } 972 973 const clang::CallExpr *clangCallExpr() const { return Cexpr; } 974 975 template <class V> 976 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 977 auto Nt = Vs.traverse(Target, Vs.subExprCtx(Ctx)); 978 return Vs.reduceCall(*this, Nt); 979 } 980 981 template <class C> 982 typename C::CType compare(const Call* E, C& Cmp) const { 983 return Cmp.compare(target(), E->target()); 984 } 985 986 private: 987 SExpr* Target; 988 const clang::CallExpr *Cexpr; 989 }; 990 991 992 /// Allocate memory for a new value on the heap or stack. 993 class Alloc : public SExpr { 994 public: 995 static bool classof(const SExpr *E) { return E->opcode() == COP_Call; } 996 997 enum AllocKind { 998 AK_Stack, 999 AK_Heap 1000 }; 1001 1002 Alloc(SExpr *D, AllocKind K) : SExpr(COP_Alloc), Dtype(D) { Flags = K; } 1003 Alloc(const Alloc &A, SExpr *Dt) : SExpr(A), Dtype(Dt) { Flags = A.kind(); } 1004 1005 AllocKind kind() const { return static_cast<AllocKind>(Flags); } 1006 1007 SExpr *dataType() { return Dtype; } 1008 const SExpr *dataType() const { return Dtype; } 1009 1010 template <class V> 1011 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1012 auto Nd = Vs.traverse(Dtype, Vs.declCtx(Ctx)); 1013 return Vs.reduceAlloc(*this, Nd); 1014 } 1015 1016 template <class C> 1017 typename C::CType compare(const Alloc* E, C& Cmp) const { 1018 typename C::CType Ct = Cmp.compareIntegers(kind(), E->kind()); 1019 if (Cmp.notTrue(Ct)) 1020 return Ct; 1021 return Cmp.compare(dataType(), E->dataType()); 1022 } 1023 1024 private: 1025 SExpr* Dtype; 1026 }; 1027 1028 1029 /// Load a value from memory. 1030 class Load : public SExpr { 1031 public: 1032 static bool classof(const SExpr *E) { return E->opcode() == COP_Load; } 1033 1034 Load(SExpr *P) : SExpr(COP_Load), Ptr(P) {} 1035 Load(const Load &L, SExpr *P) : SExpr(L), Ptr(P) {} 1036 1037 SExpr *pointer() { return Ptr; } 1038 const SExpr *pointer() const { return Ptr; } 1039 1040 template <class V> 1041 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1042 auto Np = Vs.traverse(Ptr, Vs.subExprCtx(Ctx)); 1043 return Vs.reduceLoad(*this, Np); 1044 } 1045 1046 template <class C> 1047 typename C::CType compare(const Load* E, C& Cmp) const { 1048 return Cmp.compare(pointer(), E->pointer()); 1049 } 1050 1051 private: 1052 SExpr* Ptr; 1053 }; 1054 1055 1056 /// Store a value to memory. 1057 /// The destination is a pointer to a field, the source is the value to store. 1058 class Store : public SExpr { 1059 public: 1060 static bool classof(const SExpr *E) { return E->opcode() == COP_Store; } 1061 1062 Store(SExpr *P, SExpr *V) : SExpr(COP_Store), Dest(P), Source(V) {} 1063 Store(const Store &S, SExpr *P, SExpr *V) : SExpr(S), Dest(P), Source(V) {} 1064 1065 SExpr *destination() { return Dest; } // Address to store to 1066 const SExpr *destination() const { return Dest; } 1067 1068 SExpr *source() { return Source; } // Value to store 1069 const SExpr *source() const { return Source; } 1070 1071 template <class V> 1072 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1073 auto Np = Vs.traverse(Dest, Vs.subExprCtx(Ctx)); 1074 auto Nv = Vs.traverse(Source, Vs.subExprCtx(Ctx)); 1075 return Vs.reduceStore(*this, Np, Nv); 1076 } 1077 1078 template <class C> 1079 typename C::CType compare(const Store* E, C& Cmp) const { 1080 typename C::CType Ct = Cmp.compare(destination(), E->destination()); 1081 if (Cmp.notTrue(Ct)) 1082 return Ct; 1083 return Cmp.compare(source(), E->source()); 1084 } 1085 1086 private: 1087 SExpr* Dest; 1088 SExpr* Source; 1089 }; 1090 1091 1092 /// If p is a reference to an array, then p[i] is a reference to the i'th 1093 /// element of the array. 1094 class ArrayIndex : public SExpr { 1095 public: 1096 static bool classof(const SExpr *E) { return E->opcode() == COP_ArrayIndex; } 1097 1098 ArrayIndex(SExpr *A, SExpr *N) : SExpr(COP_ArrayIndex), Array(A), Index(N) {} 1099 ArrayIndex(const ArrayIndex &E, SExpr *A, SExpr *N) 1100 : SExpr(E), Array(A), Index(N) {} 1101 1102 SExpr *array() { return Array; } 1103 const SExpr *array() const { return Array; } 1104 1105 SExpr *index() { return Index; } 1106 const SExpr *index() const { return Index; } 1107 1108 template <class V> 1109 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1110 auto Na = Vs.traverse(Array, Vs.subExprCtx(Ctx)); 1111 auto Ni = Vs.traverse(Index, Vs.subExprCtx(Ctx)); 1112 return Vs.reduceArrayIndex(*this, Na, Ni); 1113 } 1114 1115 template <class C> 1116 typename C::CType compare(const ArrayIndex* E, C& Cmp) const { 1117 typename C::CType Ct = Cmp.compare(array(), E->array()); 1118 if (Cmp.notTrue(Ct)) 1119 return Ct; 1120 return Cmp.compare(index(), E->index()); 1121 } 1122 1123 private: 1124 SExpr* Array; 1125 SExpr* Index; 1126 }; 1127 1128 1129 /// Pointer arithmetic, restricted to arrays only. 1130 /// If p is a reference to an array, then p + n, where n is an integer, is 1131 /// a reference to a subarray. 1132 class ArrayAdd : public SExpr { 1133 public: 1134 static bool classof(const SExpr *E) { return E->opcode() == COP_ArrayAdd; } 1135 1136 ArrayAdd(SExpr *A, SExpr *N) : SExpr(COP_ArrayAdd), Array(A), Index(N) {} 1137 ArrayAdd(const ArrayAdd &E, SExpr *A, SExpr *N) 1138 : SExpr(E), Array(A), Index(N) {} 1139 1140 SExpr *array() { return Array; } 1141 const SExpr *array() const { return Array; } 1142 1143 SExpr *index() { return Index; } 1144 const SExpr *index() const { return Index; } 1145 1146 template <class V> 1147 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1148 auto Na = Vs.traverse(Array, Vs.subExprCtx(Ctx)); 1149 auto Ni = Vs.traverse(Index, Vs.subExprCtx(Ctx)); 1150 return Vs.reduceArrayAdd(*this, Na, Ni); 1151 } 1152 1153 template <class C> 1154 typename C::CType compare(const ArrayAdd* E, C& Cmp) const { 1155 typename C::CType Ct = Cmp.compare(array(), E->array()); 1156 if (Cmp.notTrue(Ct)) 1157 return Ct; 1158 return Cmp.compare(index(), E->index()); 1159 } 1160 1161 private: 1162 SExpr* Array; 1163 SExpr* Index; 1164 }; 1165 1166 1167 /// Simple arithmetic unary operations, e.g. negate and not. 1168 /// These operations have no side-effects. 1169 class UnaryOp : public SExpr { 1170 public: 1171 static bool classof(const SExpr *E) { return E->opcode() == COP_UnaryOp; } 1172 1173 UnaryOp(TIL_UnaryOpcode Op, SExpr *E) : SExpr(COP_UnaryOp), Expr0(E) { 1174 Flags = Op; 1175 } 1176 UnaryOp(const UnaryOp &U, SExpr *E) : SExpr(U), Expr0(E) { Flags = U.Flags; } 1177 1178 TIL_UnaryOpcode unaryOpcode() const { 1179 return static_cast<TIL_UnaryOpcode>(Flags); 1180 } 1181 1182 SExpr *expr() { return Expr0; } 1183 const SExpr *expr() const { return Expr0; } 1184 1185 template <class V> 1186 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1187 auto Ne = Vs.traverse(Expr0, Vs.subExprCtx(Ctx)); 1188 return Vs.reduceUnaryOp(*this, Ne); 1189 } 1190 1191 template <class C> 1192 typename C::CType compare(const UnaryOp* E, C& Cmp) const { 1193 typename C::CType Ct = 1194 Cmp.compareIntegers(unaryOpcode(), E->unaryOpcode()); 1195 if (Cmp.notTrue(Ct)) 1196 return Ct; 1197 return Cmp.compare(expr(), E->expr()); 1198 } 1199 1200 private: 1201 SExpr* Expr0; 1202 }; 1203 1204 1205 /// Simple arithmetic binary operations, e.g. +, -, etc. 1206 /// These operations have no side effects. 1207 class BinaryOp : public SExpr { 1208 public: 1209 static bool classof(const SExpr *E) { return E->opcode() == COP_BinaryOp; } 1210 1211 BinaryOp(TIL_BinaryOpcode Op, SExpr *E0, SExpr *E1) 1212 : SExpr(COP_BinaryOp), Expr0(E0), Expr1(E1) { 1213 Flags = Op; 1214 } 1215 BinaryOp(const BinaryOp &B, SExpr *E0, SExpr *E1) 1216 : SExpr(B), Expr0(E0), Expr1(E1) { 1217 Flags = B.Flags; 1218 } 1219 1220 TIL_BinaryOpcode binaryOpcode() const { 1221 return static_cast<TIL_BinaryOpcode>(Flags); 1222 } 1223 1224 SExpr *expr0() { return Expr0; } 1225 const SExpr *expr0() const { return Expr0; } 1226 1227 SExpr *expr1() { return Expr1; } 1228 const SExpr *expr1() const { return Expr1; } 1229 1230 template <class V> 1231 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1232 auto Ne0 = Vs.traverse(Expr0, Vs.subExprCtx(Ctx)); 1233 auto Ne1 = Vs.traverse(Expr1, Vs.subExprCtx(Ctx)); 1234 return Vs.reduceBinaryOp(*this, Ne0, Ne1); 1235 } 1236 1237 template <class C> 1238 typename C::CType compare(const BinaryOp* E, C& Cmp) const { 1239 typename C::CType Ct = 1240 Cmp.compareIntegers(binaryOpcode(), E->binaryOpcode()); 1241 if (Cmp.notTrue(Ct)) 1242 return Ct; 1243 Ct = Cmp.compare(expr0(), E->expr0()); 1244 if (Cmp.notTrue(Ct)) 1245 return Ct; 1246 return Cmp.compare(expr1(), E->expr1()); 1247 } 1248 1249 private: 1250 SExpr* Expr0; 1251 SExpr* Expr1; 1252 }; 1253 1254 1255 /// Cast expressions. 1256 /// Cast expressions are essentially unary operations, but we treat them 1257 /// as a distinct AST node because they only change the type of the result. 1258 class Cast : public SExpr { 1259 public: 1260 static bool classof(const SExpr *E) { return E->opcode() == COP_Cast; } 1261 1262 Cast(TIL_CastOpcode Op, SExpr *E) : SExpr(COP_Cast), Expr0(E) { Flags = Op; } 1263 Cast(const Cast &C, SExpr *E) : SExpr(C), Expr0(E) { Flags = C.Flags; } 1264 1265 TIL_CastOpcode castOpcode() const { 1266 return static_cast<TIL_CastOpcode>(Flags); 1267 } 1268 1269 SExpr *expr() { return Expr0; } 1270 const SExpr *expr() const { return Expr0; } 1271 1272 template <class V> 1273 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1274 auto Ne = Vs.traverse(Expr0, Vs.subExprCtx(Ctx)); 1275 return Vs.reduceCast(*this, Ne); 1276 } 1277 1278 template <class C> 1279 typename C::CType compare(const Cast* E, C& Cmp) const { 1280 typename C::CType Ct = 1281 Cmp.compareIntegers(castOpcode(), E->castOpcode()); 1282 if (Cmp.notTrue(Ct)) 1283 return Ct; 1284 return Cmp.compare(expr(), E->expr()); 1285 } 1286 1287 private: 1288 SExpr* Expr0; 1289 }; 1290 1291 1292 class SCFG; 1293 1294 1295 /// Phi Node, for code in SSA form. 1296 /// Each Phi node has an array of possible values that it can take, 1297 /// depending on where control flow comes from. 1298 class Phi : public SExpr { 1299 public: 1300 typedef SimpleArray<SExpr *> ValArray; 1301 1302 // In minimal SSA form, all Phi nodes are MultiVal. 1303 // During conversion to SSA, incomplete Phi nodes may be introduced, which 1304 // are later determined to be SingleVal, and are thus redundant. 1305 enum Status { 1306 PH_MultiVal = 0, // Phi node has multiple distinct values. (Normal) 1307 PH_SingleVal, // Phi node has one distinct value, and can be eliminated 1308 PH_Incomplete // Phi node is incomplete 1309 }; 1310 1311 static bool classof(const SExpr *E) { return E->opcode() == COP_Phi; } 1312 1313 Phi() 1314 : SExpr(COP_Phi), Cvdecl(nullptr) {} 1315 Phi(MemRegionRef A, unsigned Nvals) 1316 : SExpr(COP_Phi), Values(A, Nvals), Cvdecl(nullptr) {} 1317 Phi(const Phi &P, ValArray &&Vs) 1318 : SExpr(P), Values(std::move(Vs)), Cvdecl(nullptr) {} 1319 1320 const ValArray &values() const { return Values; } 1321 ValArray &values() { return Values; } 1322 1323 Status status() const { return static_cast<Status>(Flags); } 1324 void setStatus(Status s) { Flags = s; } 1325 1326 /// Return the clang declaration of the variable for this Phi node, if any. 1327 const clang::ValueDecl *clangDecl() const { return Cvdecl; } 1328 1329 /// Set the clang variable associated with this Phi node. 1330 void setClangDecl(const clang::ValueDecl *Cvd) { Cvdecl = Cvd; } 1331 1332 template <class V> 1333 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1334 typename V::template Container<typename V::R_SExpr> 1335 Nvs(Vs, Values.size()); 1336 1337 for (auto *Val : Values) { 1338 Nvs.push_back( Vs.traverse(Val, Vs.subExprCtx(Ctx)) ); 1339 } 1340 return Vs.reducePhi(*this, Nvs); 1341 } 1342 1343 template <class C> 1344 typename C::CType compare(const Phi *E, C &Cmp) const { 1345 // TODO: implement CFG comparisons 1346 return Cmp.comparePointers(this, E); 1347 } 1348 1349 private: 1350 ValArray Values; 1351 const clang::ValueDecl* Cvdecl; 1352 }; 1353 1354 1355 /// Base class for basic block terminators: Branch, Goto, and Return. 1356 class Terminator : public SExpr { 1357 public: 1358 static bool classof(const SExpr *E) { 1359 return E->opcode() >= COP_Goto && E->opcode() <= COP_Return; 1360 } 1361 1362 protected: 1363 Terminator(TIL_Opcode Op) : SExpr(Op) {} 1364 Terminator(const SExpr &E) : SExpr(E) {} 1365 1366 public: 1367 /// Return the list of basic blocks that this terminator can branch to. 1368 ArrayRef<BasicBlock*> successors(); 1369 1370 ArrayRef<BasicBlock*> successors() const { 1371 return const_cast<Terminator*>(this)->successors(); 1372 } 1373 }; 1374 1375 1376 /// Jump to another basic block. 1377 /// A goto instruction is essentially a tail-recursive call into another 1378 /// block. In addition to the block pointer, it specifies an index into the 1379 /// phi nodes of that block. The index can be used to retrieve the "arguments" 1380 /// of the call. 1381 class Goto : public Terminator { 1382 public: 1383 static bool classof(const SExpr *E) { return E->opcode() == COP_Goto; } 1384 1385 Goto(BasicBlock *B, unsigned I) 1386 : Terminator(COP_Goto), TargetBlock(B), Index(I) {} 1387 Goto(const Goto &G, BasicBlock *B, unsigned I) 1388 : Terminator(COP_Goto), TargetBlock(B), Index(I) {} 1389 1390 const BasicBlock *targetBlock() const { return TargetBlock; } 1391 BasicBlock *targetBlock() { return TargetBlock; } 1392 1393 /// Returns the index into the 1394 unsigned index() const { return Index; } 1395 1396 /// Return the list of basic blocks that this terminator can branch to. 1397 ArrayRef<BasicBlock*> successors() { 1398 return TargetBlock; 1399 } 1400 1401 template <class V> 1402 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1403 BasicBlock *Ntb = Vs.reduceBasicBlockRef(TargetBlock); 1404 return Vs.reduceGoto(*this, Ntb); 1405 } 1406 1407 template <class C> 1408 typename C::CType compare(const Goto *E, C &Cmp) const { 1409 // TODO: implement CFG comparisons 1410 return Cmp.comparePointers(this, E); 1411 } 1412 1413 private: 1414 BasicBlock *TargetBlock; 1415 unsigned Index; 1416 }; 1417 1418 1419 /// A conditional branch to two other blocks. 1420 /// Note that unlike Goto, Branch does not have an index. The target blocks 1421 /// must be child-blocks, and cannot have Phi nodes. 1422 class Branch : public Terminator { 1423 public: 1424 static bool classof(const SExpr *E) { return E->opcode() == COP_Branch; } 1425 1426 Branch(SExpr *C, BasicBlock *T, BasicBlock *E) 1427 : Terminator(COP_Branch), Condition(C) { 1428 Branches[0] = T; 1429 Branches[1] = E; 1430 } 1431 Branch(const Branch &Br, SExpr *C, BasicBlock *T, BasicBlock *E) 1432 : Terminator(Br), Condition(C) { 1433 Branches[0] = T; 1434 Branches[1] = E; 1435 } 1436 1437 const SExpr *condition() const { return Condition; } 1438 SExpr *condition() { return Condition; } 1439 1440 const BasicBlock *thenBlock() const { return Branches[0]; } 1441 BasicBlock *thenBlock() { return Branches[0]; } 1442 1443 const BasicBlock *elseBlock() const { return Branches[1]; } 1444 BasicBlock *elseBlock() { return Branches[1]; } 1445 1446 /// Return the list of basic blocks that this terminator can branch to. 1447 ArrayRef<BasicBlock*> successors() { 1448 return llvm::makeArrayRef(Branches); 1449 } 1450 1451 template <class V> 1452 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1453 auto Nc = Vs.traverse(Condition, Vs.subExprCtx(Ctx)); 1454 BasicBlock *Ntb = Vs.reduceBasicBlockRef(Branches[0]); 1455 BasicBlock *Nte = Vs.reduceBasicBlockRef(Branches[1]); 1456 return Vs.reduceBranch(*this, Nc, Ntb, Nte); 1457 } 1458 1459 template <class C> 1460 typename C::CType compare(const Branch *E, C &Cmp) const { 1461 // TODO: implement CFG comparisons 1462 return Cmp.comparePointers(this, E); 1463 } 1464 1465 private: 1466 SExpr* Condition; 1467 BasicBlock *Branches[2]; 1468 }; 1469 1470 1471 /// Return from the enclosing function, passing the return value to the caller. 1472 /// Only the exit block should end with a return statement. 1473 class Return : public Terminator { 1474 public: 1475 static bool classof(const SExpr *E) { return E->opcode() == COP_Return; } 1476 1477 Return(SExpr* Rval) : Terminator(COP_Return), Retval(Rval) {} 1478 Return(const Return &R, SExpr* Rval) : Terminator(R), Retval(Rval) {} 1479 1480 /// Return an empty list. 1481 ArrayRef<BasicBlock*> successors() { 1482 return None; 1483 } 1484 1485 SExpr *returnValue() { return Retval; } 1486 const SExpr *returnValue() const { return Retval; } 1487 1488 template <class V> 1489 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1490 auto Ne = Vs.traverse(Retval, Vs.subExprCtx(Ctx)); 1491 return Vs.reduceReturn(*this, Ne); 1492 } 1493 1494 template <class C> 1495 typename C::CType compare(const Return *E, C &Cmp) const { 1496 return Cmp.compare(Retval, E->Retval); 1497 } 1498 1499 private: 1500 SExpr* Retval; 1501 }; 1502 1503 1504 inline ArrayRef<BasicBlock*> Terminator::successors() { 1505 switch (opcode()) { 1506 case COP_Goto: return cast<Goto>(this)->successors(); 1507 case COP_Branch: return cast<Branch>(this)->successors(); 1508 case COP_Return: return cast<Return>(this)->successors(); 1509 default: 1510 return None; 1511 } 1512 } 1513 1514 1515 /// A basic block is part of an SCFG. It can be treated as a function in 1516 /// continuation passing style. A block consists of a sequence of phi nodes, 1517 /// which are "arguments" to the function, followed by a sequence of 1518 /// instructions. It ends with a Terminator, which is a Branch or Goto to 1519 /// another basic block in the same SCFG. 1520 class BasicBlock : public SExpr { 1521 public: 1522 typedef SimpleArray<SExpr*> InstrArray; 1523 typedef SimpleArray<BasicBlock*> BlockArray; 1524 1525 // TopologyNodes are used to overlay tree structures on top of the CFG, 1526 // such as dominator and postdominator trees. Each block is assigned an 1527 // ID in the tree according to a depth-first search. Tree traversals are 1528 // always up, towards the parents. 1529 struct TopologyNode { 1530 TopologyNode() : NodeID(0), SizeOfSubTree(0), Parent(nullptr) {} 1531 1532 bool isParentOf(const TopologyNode& OtherNode) { 1533 return OtherNode.NodeID > NodeID && 1534 OtherNode.NodeID < NodeID + SizeOfSubTree; 1535 } 1536 1537 bool isParentOfOrEqual(const TopologyNode& OtherNode) { 1538 return OtherNode.NodeID >= NodeID && 1539 OtherNode.NodeID < NodeID + SizeOfSubTree; 1540 } 1541 1542 int NodeID; 1543 int SizeOfSubTree; // Includes this node, so must be > 1. 1544 BasicBlock *Parent; // Pointer to parent. 1545 }; 1546 1547 static bool classof(const SExpr *E) { return E->opcode() == COP_BasicBlock; } 1548 1549 explicit BasicBlock(MemRegionRef A) 1550 : SExpr(COP_BasicBlock), Arena(A), CFGPtr(nullptr), BlockID(0), 1551 Visited(0), TermInstr(nullptr) {} 1552 BasicBlock(BasicBlock &B, MemRegionRef A, InstrArray &&As, InstrArray &&Is, 1553 Terminator *T) 1554 : SExpr(COP_BasicBlock), Arena(A), CFGPtr(nullptr), BlockID(0),Visited(0), 1555 Args(std::move(As)), Instrs(std::move(Is)), TermInstr(T) {} 1556 1557 /// Returns the block ID. Every block has a unique ID in the CFG. 1558 int blockID() const { return BlockID; } 1559 1560 /// Returns the number of predecessors. 1561 size_t numPredecessors() const { return Predecessors.size(); } 1562 size_t numSuccessors() const { return successors().size(); } 1563 1564 const SCFG* cfg() const { return CFGPtr; } 1565 SCFG* cfg() { return CFGPtr; } 1566 1567 const BasicBlock *parent() const { return DominatorNode.Parent; } 1568 BasicBlock *parent() { return DominatorNode.Parent; } 1569 1570 const InstrArray &arguments() const { return Args; } 1571 InstrArray &arguments() { return Args; } 1572 1573 InstrArray &instructions() { return Instrs; } 1574 const InstrArray &instructions() const { return Instrs; } 1575 1576 /// Returns a list of predecessors. 1577 /// The order of predecessors in the list is important; each phi node has 1578 /// exactly one argument for each precessor, in the same order. 1579 BlockArray &predecessors() { return Predecessors; } 1580 const BlockArray &predecessors() const { return Predecessors; } 1581 1582 ArrayRef<BasicBlock*> successors() { return TermInstr->successors(); } 1583 ArrayRef<BasicBlock*> successors() const { return TermInstr->successors(); } 1584 1585 const Terminator *terminator() const { return TermInstr; } 1586 Terminator *terminator() { return TermInstr; } 1587 1588 void setTerminator(Terminator *E) { TermInstr = E; } 1589 1590 bool Dominates(const BasicBlock &Other) { 1591 return DominatorNode.isParentOfOrEqual(Other.DominatorNode); 1592 } 1593 1594 bool PostDominates(const BasicBlock &Other) { 1595 return PostDominatorNode.isParentOfOrEqual(Other.PostDominatorNode); 1596 } 1597 1598 /// Add a new argument. 1599 void addArgument(Phi *V) { 1600 Args.reserveCheck(1, Arena); 1601 Args.push_back(V); 1602 } 1603 /// Add a new instruction. 1604 void addInstruction(SExpr *V) { 1605 Instrs.reserveCheck(1, Arena); 1606 Instrs.push_back(V); 1607 } 1608 // Add a new predecessor, and return the phi-node index for it. 1609 // Will add an argument to all phi-nodes, initialized to nullptr. 1610 unsigned addPredecessor(BasicBlock *Pred); 1611 1612 // Reserve space for Nargs arguments. 1613 void reserveArguments(unsigned Nargs) { Args.reserve(Nargs, Arena); } 1614 1615 // Reserve space for Nins instructions. 1616 void reserveInstructions(unsigned Nins) { Instrs.reserve(Nins, Arena); } 1617 1618 // Reserve space for NumPreds predecessors, including space in phi nodes. 1619 void reservePredecessors(unsigned NumPreds); 1620 1621 /// Return the index of BB, or Predecessors.size if BB is not a predecessor. 1622 unsigned findPredecessorIndex(const BasicBlock *BB) const { 1623 auto I = std::find(Predecessors.cbegin(), Predecessors.cend(), BB); 1624 return std::distance(Predecessors.cbegin(), I); 1625 } 1626 1627 template <class V> 1628 typename V::R_BasicBlock traverse(V &Vs, typename V::R_Ctx Ctx) { 1629 typename V::template Container<SExpr*> Nas(Vs, Args.size()); 1630 typename V::template Container<SExpr*> Nis(Vs, Instrs.size()); 1631 1632 // Entering the basic block should do any scope initialization. 1633 Vs.enterBasicBlock(*this); 1634 1635 for (auto *E : Args) { 1636 auto Ne = Vs.traverse(E, Vs.subExprCtx(Ctx)); 1637 Nas.push_back(Ne); 1638 } 1639 for (auto *E : Instrs) { 1640 auto Ne = Vs.traverse(E, Vs.subExprCtx(Ctx)); 1641 Nis.push_back(Ne); 1642 } 1643 auto Nt = Vs.traverse(TermInstr, Ctx); 1644 1645 // Exiting the basic block should handle any scope cleanup. 1646 Vs.exitBasicBlock(*this); 1647 1648 return Vs.reduceBasicBlock(*this, Nas, Nis, Nt); 1649 } 1650 1651 template <class C> 1652 typename C::CType compare(const BasicBlock *E, C &Cmp) const { 1653 // TODO: implement CFG comparisons 1654 return Cmp.comparePointers(this, E); 1655 } 1656 1657 private: 1658 friend class SCFG; 1659 1660 int renumberInstrs(int id); // assign unique ids to all instructions 1661 int topologicalSort(SimpleArray<BasicBlock*>& Blocks, int ID); 1662 int topologicalFinalSort(SimpleArray<BasicBlock*>& Blocks, int ID); 1663 void computeDominator(); 1664 void computePostDominator(); 1665 1666 private: 1667 MemRegionRef Arena; // The arena used to allocate this block. 1668 SCFG *CFGPtr; // The CFG that contains this block. 1669 int BlockID : 31; // unique id for this BB in the containing CFG. 1670 // IDs are in topological order. 1671 bool Visited : 1; // Bit to determine if a block has been visited 1672 // during a traversal. 1673 BlockArray Predecessors; // Predecessor blocks in the CFG. 1674 InstrArray Args; // Phi nodes. One argument per predecessor. 1675 InstrArray Instrs; // Instructions. 1676 Terminator* TermInstr; // Terminating instruction 1677 1678 TopologyNode DominatorNode; // The dominator tree 1679 TopologyNode PostDominatorNode; // The post-dominator tree 1680 }; 1681 1682 1683 /// An SCFG is a control-flow graph. It consists of a set of basic blocks, 1684 /// each of which terminates in a branch to another basic block. There is one 1685 /// entry point, and one exit point. 1686 class SCFG : public SExpr { 1687 public: 1688 typedef SimpleArray<BasicBlock *> BlockArray; 1689 typedef BlockArray::iterator iterator; 1690 typedef BlockArray::const_iterator const_iterator; 1691 1692 static bool classof(const SExpr *E) { return E->opcode() == COP_SCFG; } 1693 1694 SCFG(MemRegionRef A, unsigned Nblocks) 1695 : SExpr(COP_SCFG), Arena(A), Blocks(A, Nblocks), 1696 Entry(nullptr), Exit(nullptr), NumInstructions(0), Normal(false) { 1697 Entry = new (A) BasicBlock(A); 1698 Exit = new (A) BasicBlock(A); 1699 auto *V = new (A) Phi(); 1700 Exit->addArgument(V); 1701 Exit->setTerminator(new (A) Return(V)); 1702 add(Entry); 1703 add(Exit); 1704 } 1705 SCFG(const SCFG &Cfg, BlockArray &&Ba) // steals memory from Ba 1706 : SExpr(COP_SCFG), Arena(Cfg.Arena), Blocks(std::move(Ba)), 1707 Entry(nullptr), Exit(nullptr), NumInstructions(0), Normal(false) { 1708 // TODO: set entry and exit! 1709 } 1710 1711 /// Return true if this CFG is valid. 1712 bool valid() const { return Entry && Exit && Blocks.size() > 0; } 1713 1714 /// Return true if this CFG has been normalized. 1715 /// After normalization, blocks are in topological order, and block and 1716 /// instruction IDs have been assigned. 1717 bool normal() const { return Normal; } 1718 1719 iterator begin() { return Blocks.begin(); } 1720 iterator end() { return Blocks.end(); } 1721 1722 const_iterator begin() const { return cbegin(); } 1723 const_iterator end() const { return cend(); } 1724 1725 const_iterator cbegin() const { return Blocks.cbegin(); } 1726 const_iterator cend() const { return Blocks.cend(); } 1727 1728 const BasicBlock *entry() const { return Entry; } 1729 BasicBlock *entry() { return Entry; } 1730 const BasicBlock *exit() const { return Exit; } 1731 BasicBlock *exit() { return Exit; } 1732 1733 /// Return the number of blocks in the CFG. 1734 /// Block::blockID() will return a number less than numBlocks(); 1735 size_t numBlocks() const { return Blocks.size(); } 1736 1737 /// Return the total number of instructions in the CFG. 1738 /// This is useful for building instruction side-tables; 1739 /// A call to SExpr::id() will return a number less than numInstructions(). 1740 unsigned numInstructions() { return NumInstructions; } 1741 1742 inline void add(BasicBlock *BB) { 1743 assert(BB->CFGPtr == nullptr); 1744 BB->CFGPtr = this; 1745 Blocks.reserveCheck(1, Arena); 1746 Blocks.push_back(BB); 1747 } 1748 1749 void setEntry(BasicBlock *BB) { Entry = BB; } 1750 void setExit(BasicBlock *BB) { Exit = BB; } 1751 1752 void computeNormalForm(); 1753 1754 template <class V> 1755 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1756 Vs.enterCFG(*this); 1757 typename V::template Container<BasicBlock *> Bbs(Vs, Blocks.size()); 1758 1759 for (auto *B : Blocks) { 1760 Bbs.push_back( B->traverse(Vs, Vs.subExprCtx(Ctx)) ); 1761 } 1762 Vs.exitCFG(*this); 1763 return Vs.reduceSCFG(*this, Bbs); 1764 } 1765 1766 template <class C> 1767 typename C::CType compare(const SCFG *E, C &Cmp) const { 1768 // TODO: implement CFG comparisons 1769 return Cmp.comparePointers(this, E); 1770 } 1771 1772 private: 1773 void renumberInstrs(); // assign unique ids to all instructions 1774 1775 private: 1776 MemRegionRef Arena; 1777 BlockArray Blocks; 1778 BasicBlock *Entry; 1779 BasicBlock *Exit; 1780 unsigned NumInstructions; 1781 bool Normal; 1782 }; 1783 1784 1785 1786 /// An identifier, e.g. 'foo' or 'x'. 1787 /// This is a pseduo-term; it will be lowered to a variable or projection. 1788 class Identifier : public SExpr { 1789 public: 1790 static bool classof(const SExpr *E) { return E->opcode() == COP_Identifier; } 1791 1792 Identifier(StringRef Id): SExpr(COP_Identifier), Name(Id) { } 1793 Identifier(const Identifier& I) : SExpr(I), Name(I.Name) { } 1794 1795 StringRef name() const { return Name; } 1796 1797 template <class V> 1798 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1799 return Vs.reduceIdentifier(*this); 1800 } 1801 1802 template <class C> 1803 typename C::CType compare(const Identifier* E, C& Cmp) const { 1804 return Cmp.compareStrings(name(), E->name()); 1805 } 1806 1807 private: 1808 StringRef Name; 1809 }; 1810 1811 1812 /// An if-then-else expression. 1813 /// This is a pseduo-term; it will be lowered to a branch in a CFG. 1814 class IfThenElse : public SExpr { 1815 public: 1816 static bool classof(const SExpr *E) { return E->opcode() == COP_IfThenElse; } 1817 1818 IfThenElse(SExpr *C, SExpr *T, SExpr *E) 1819 : SExpr(COP_IfThenElse), Condition(C), ThenExpr(T), ElseExpr(E) 1820 { } 1821 IfThenElse(const IfThenElse &I, SExpr *C, SExpr *T, SExpr *E) 1822 : SExpr(I), Condition(C), ThenExpr(T), ElseExpr(E) 1823 { } 1824 1825 SExpr *condition() { return Condition; } // Address to store to 1826 const SExpr *condition() const { return Condition; } 1827 1828 SExpr *thenExpr() { return ThenExpr; } // Value to store 1829 const SExpr *thenExpr() const { return ThenExpr; } 1830 1831 SExpr *elseExpr() { return ElseExpr; } // Value to store 1832 const SExpr *elseExpr() const { return ElseExpr; } 1833 1834 template <class V> 1835 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1836 auto Nc = Vs.traverse(Condition, Vs.subExprCtx(Ctx)); 1837 auto Nt = Vs.traverse(ThenExpr, Vs.subExprCtx(Ctx)); 1838 auto Ne = Vs.traverse(ElseExpr, Vs.subExprCtx(Ctx)); 1839 return Vs.reduceIfThenElse(*this, Nc, Nt, Ne); 1840 } 1841 1842 template <class C> 1843 typename C::CType compare(const IfThenElse* E, C& Cmp) const { 1844 typename C::CType Ct = Cmp.compare(condition(), E->condition()); 1845 if (Cmp.notTrue(Ct)) 1846 return Ct; 1847 Ct = Cmp.compare(thenExpr(), E->thenExpr()); 1848 if (Cmp.notTrue(Ct)) 1849 return Ct; 1850 return Cmp.compare(elseExpr(), E->elseExpr()); 1851 } 1852 1853 private: 1854 SExpr* Condition; 1855 SExpr* ThenExpr; 1856 SExpr* ElseExpr; 1857 }; 1858 1859 1860 /// A let-expression, e.g. let x=t; u. 1861 /// This is a pseduo-term; it will be lowered to instructions in a CFG. 1862 class Let : public SExpr { 1863 public: 1864 static bool classof(const SExpr *E) { return E->opcode() == COP_Let; } 1865 1866 Let(Variable *Vd, SExpr *Bd) : SExpr(COP_Let), VarDecl(Vd), Body(Bd) { 1867 Vd->setKind(Variable::VK_Let); 1868 } 1869 Let(const Let &L, Variable *Vd, SExpr *Bd) : SExpr(L), VarDecl(Vd), Body(Bd) { 1870 Vd->setKind(Variable::VK_Let); 1871 } 1872 1873 Variable *variableDecl() { return VarDecl; } 1874 const Variable *variableDecl() const { return VarDecl; } 1875 1876 SExpr *body() { return Body; } 1877 const SExpr *body() const { return Body; } 1878 1879 template <class V> 1880 typename V::R_SExpr traverse(V &Vs, typename V::R_Ctx Ctx) { 1881 // This is a variable declaration, so traverse the definition. 1882 auto E0 = Vs.traverse(VarDecl->Definition, Vs.subExprCtx(Ctx)); 1883 // Tell the rewriter to enter the scope of the let variable. 1884 Variable *Nvd = Vs.enterScope(*VarDecl, E0); 1885 auto E1 = Vs.traverse(Body, Ctx); 1886 Vs.exitScope(*VarDecl); 1887 return Vs.reduceLet(*this, Nvd, E1); 1888 } 1889 1890 template <class C> 1891 typename C::CType compare(const Let* E, C& Cmp) const { 1892 typename C::CType Ct = 1893 Cmp.compare(VarDecl->definition(), E->VarDecl->definition()); 1894 if (Cmp.notTrue(Ct)) 1895 return Ct; 1896 Cmp.enterScope(variableDecl(), E->variableDecl()); 1897 Ct = Cmp.compare(body(), E->body()); 1898 Cmp.leaveScope(); 1899 return Ct; 1900 } 1901 1902 private: 1903 Variable *VarDecl; 1904 SExpr* Body; 1905 }; 1906 1907 1908 1909 const SExpr *getCanonicalVal(const SExpr *E); 1910 SExpr* simplifyToCanonicalVal(SExpr *E); 1911 void simplifyIncompleteArg(til::Phi *Ph); 1912 1913 1914 } // end namespace til 1915 } // end namespace threadSafety 1916 } // end namespace clang 1917 1918 #endif 1919