1 //===--- ExprConstant.cpp - Expression Constant Evaluator -----------------===// 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 implements the Expr constant evaluator. 11 // 12 // Constant expression evaluation produces four main results: 13 // 14 // * A success/failure flag indicating whether constant folding was successful. 15 // This is the 'bool' return value used by most of the code in this file. A 16 // 'false' return value indicates that constant folding has failed, and any 17 // appropriate diagnostic has already been produced. 18 // 19 // * An evaluated result, valid only if constant folding has not failed. 20 // 21 // * A flag indicating if evaluation encountered (unevaluated) side-effects. 22 // These arise in cases such as (sideEffect(), 0) and (sideEffect() || 1), 23 // where it is possible to determine the evaluated result regardless. 24 // 25 // * A set of notes indicating why the evaluation was not a constant expression 26 // (under the C++11 / C++1y rules only, at the moment), or, if folding failed 27 // too, why the expression could not be folded. 28 // 29 // If we are checking for a potential constant expression, failure to constant 30 // fold a potential constant sub-expression will be indicated by a 'false' 31 // return value (the expression could not be folded) and no diagnostic (the 32 // expression is not necessarily non-constant). 33 // 34 //===----------------------------------------------------------------------===// 35 36 #include "clang/AST/APValue.h" 37 #include "clang/AST/ASTContext.h" 38 #include "clang/AST/ASTDiagnostic.h" 39 #include "clang/AST/ASTLambda.h" 40 #include "clang/AST/CharUnits.h" 41 #include "clang/AST/Expr.h" 42 #include "clang/AST/RecordLayout.h" 43 #include "clang/AST/StmtVisitor.h" 44 #include "clang/AST/TypeLoc.h" 45 #include "clang/Basic/Builtins.h" 46 #include "clang/Basic/TargetInfo.h" 47 #include "llvm/Support/raw_ostream.h" 48 #include <cstring> 49 #include <functional> 50 51 #define DEBUG_TYPE "exprconstant" 52 53 using namespace clang; 54 using llvm::APSInt; 55 using llvm::APFloat; 56 57 static bool IsGlobalLValue(APValue::LValueBase B); 58 59 namespace { 60 struct LValue; 61 struct CallStackFrame; 62 struct EvalInfo; 63 64 static QualType getType(APValue::LValueBase B) { 65 if (!B) return QualType(); 66 if (const ValueDecl *D = B.dyn_cast<const ValueDecl*>()) { 67 // FIXME: It's unclear where we're supposed to take the type from, and 68 // this actually matters for arrays of unknown bound. Eg: 69 // 70 // extern int arr[]; void f() { extern int arr[3]; }; 71 // constexpr int *p = &arr[1]; // valid? 72 // 73 // For now, we take the array bound from the most recent declaration. 74 for (auto *Redecl = cast<ValueDecl>(D->getMostRecentDecl()); Redecl; 75 Redecl = cast_or_null<ValueDecl>(Redecl->getPreviousDecl())) { 76 QualType T = Redecl->getType(); 77 if (!T->isIncompleteArrayType()) 78 return T; 79 } 80 return D->getType(); 81 } 82 83 const Expr *Base = B.get<const Expr*>(); 84 85 // For a materialized temporary, the type of the temporary we materialized 86 // may not be the type of the expression. 87 if (const MaterializeTemporaryExpr *MTE = 88 dyn_cast<MaterializeTemporaryExpr>(Base)) { 89 SmallVector<const Expr *, 2> CommaLHSs; 90 SmallVector<SubobjectAdjustment, 2> Adjustments; 91 const Expr *Temp = MTE->GetTemporaryExpr(); 92 const Expr *Inner = Temp->skipRValueSubobjectAdjustments(CommaLHSs, 93 Adjustments); 94 // Keep any cv-qualifiers from the reference if we generated a temporary 95 // for it directly. Otherwise use the type after adjustment. 96 if (!Adjustments.empty()) 97 return Inner->getType(); 98 } 99 100 return Base->getType(); 101 } 102 103 /// Get an LValue path entry, which is known to not be an array index, as a 104 /// field or base class. 105 static 106 APValue::BaseOrMemberType getAsBaseOrMember(APValue::LValuePathEntry E) { 107 APValue::BaseOrMemberType Value; 108 Value.setFromOpaqueValue(E.BaseOrMember); 109 return Value; 110 } 111 112 /// Get an LValue path entry, which is known to not be an array index, as a 113 /// field declaration. 114 static const FieldDecl *getAsField(APValue::LValuePathEntry E) { 115 return dyn_cast<FieldDecl>(getAsBaseOrMember(E).getPointer()); 116 } 117 /// Get an LValue path entry, which is known to not be an array index, as a 118 /// base class declaration. 119 static const CXXRecordDecl *getAsBaseClass(APValue::LValuePathEntry E) { 120 return dyn_cast<CXXRecordDecl>(getAsBaseOrMember(E).getPointer()); 121 } 122 /// Determine whether this LValue path entry for a base class names a virtual 123 /// base class. 124 static bool isVirtualBaseClass(APValue::LValuePathEntry E) { 125 return getAsBaseOrMember(E).getInt(); 126 } 127 128 /// Given a CallExpr, try to get the alloc_size attribute. May return null. 129 static const AllocSizeAttr *getAllocSizeAttr(const CallExpr *CE) { 130 const FunctionDecl *Callee = CE->getDirectCallee(); 131 return Callee ? Callee->getAttr<AllocSizeAttr>() : nullptr; 132 } 133 134 /// Attempts to unwrap a CallExpr (with an alloc_size attribute) from an Expr. 135 /// This will look through a single cast. 136 /// 137 /// Returns null if we couldn't unwrap a function with alloc_size. 138 static const CallExpr *tryUnwrapAllocSizeCall(const Expr *E) { 139 if (!E->getType()->isPointerType()) 140 return nullptr; 141 142 E = E->IgnoreParens(); 143 // If we're doing a variable assignment from e.g. malloc(N), there will 144 // probably be a cast of some kind. In exotic cases, we might also see a 145 // top-level ExprWithCleanups. Ignore them either way. 146 if (const auto *EC = dyn_cast<ExprWithCleanups>(E)) 147 E = EC->getSubExpr()->IgnoreParens(); 148 149 if (const auto *Cast = dyn_cast<CastExpr>(E)) 150 E = Cast->getSubExpr()->IgnoreParens(); 151 152 if (const auto *CE = dyn_cast<CallExpr>(E)) 153 return getAllocSizeAttr(CE) ? CE : nullptr; 154 return nullptr; 155 } 156 157 /// Determines whether or not the given Base contains a call to a function 158 /// with the alloc_size attribute. 159 static bool isBaseAnAllocSizeCall(APValue::LValueBase Base) { 160 const auto *E = Base.dyn_cast<const Expr *>(); 161 return E && E->getType()->isPointerType() && tryUnwrapAllocSizeCall(E); 162 } 163 164 /// The bound to claim that an array of unknown bound has. 165 /// The value in MostDerivedArraySize is undefined in this case. So, set it 166 /// to an arbitrary value that's likely to loudly break things if it's used. 167 static const uint64_t AssumedSizeForUnsizedArray = 168 std::numeric_limits<uint64_t>::max() / 2; 169 170 /// Determines if an LValue with the given LValueBase will have an unsized 171 /// array in its designator. 172 /// Find the path length and type of the most-derived subobject in the given 173 /// path, and find the size of the containing array, if any. 174 static unsigned 175 findMostDerivedSubobject(ASTContext &Ctx, APValue::LValueBase Base, 176 ArrayRef<APValue::LValuePathEntry> Path, 177 uint64_t &ArraySize, QualType &Type, bool &IsArray, 178 bool &FirstEntryIsUnsizedArray) { 179 // This only accepts LValueBases from APValues, and APValues don't support 180 // arrays that lack size info. 181 assert(!isBaseAnAllocSizeCall(Base) && 182 "Unsized arrays shouldn't appear here"); 183 unsigned MostDerivedLength = 0; 184 Type = getType(Base); 185 186 for (unsigned I = 0, N = Path.size(); I != N; ++I) { 187 if (Type->isArrayType()) { 188 const ArrayType *AT = Ctx.getAsArrayType(Type); 189 Type = AT->getElementType(); 190 MostDerivedLength = I + 1; 191 IsArray = true; 192 193 if (auto *CAT = dyn_cast<ConstantArrayType>(AT)) { 194 ArraySize = CAT->getSize().getZExtValue(); 195 } else { 196 assert(I == 0 && "unexpected unsized array designator"); 197 FirstEntryIsUnsizedArray = true; 198 ArraySize = AssumedSizeForUnsizedArray; 199 } 200 } else if (Type->isAnyComplexType()) { 201 const ComplexType *CT = Type->castAs<ComplexType>(); 202 Type = CT->getElementType(); 203 ArraySize = 2; 204 MostDerivedLength = I + 1; 205 IsArray = true; 206 } else if (const FieldDecl *FD = getAsField(Path[I])) { 207 Type = FD->getType(); 208 ArraySize = 0; 209 MostDerivedLength = I + 1; 210 IsArray = false; 211 } else { 212 // Path[I] describes a base class. 213 ArraySize = 0; 214 IsArray = false; 215 } 216 } 217 return MostDerivedLength; 218 } 219 220 // The order of this enum is important for diagnostics. 221 enum CheckSubobjectKind { 222 CSK_Base, CSK_Derived, CSK_Field, CSK_ArrayToPointer, CSK_ArrayIndex, 223 CSK_This, CSK_Real, CSK_Imag 224 }; 225 226 /// A path from a glvalue to a subobject of that glvalue. 227 struct SubobjectDesignator { 228 /// True if the subobject was named in a manner not supported by C++11. Such 229 /// lvalues can still be folded, but they are not core constant expressions 230 /// and we cannot perform lvalue-to-rvalue conversions on them. 231 unsigned Invalid : 1; 232 233 /// Is this a pointer one past the end of an object? 234 unsigned IsOnePastTheEnd : 1; 235 236 /// Indicator of whether the first entry is an unsized array. 237 unsigned FirstEntryIsAnUnsizedArray : 1; 238 239 /// Indicator of whether the most-derived object is an array element. 240 unsigned MostDerivedIsArrayElement : 1; 241 242 /// The length of the path to the most-derived object of which this is a 243 /// subobject. 244 unsigned MostDerivedPathLength : 28; 245 246 /// The size of the array of which the most-derived object is an element. 247 /// This will always be 0 if the most-derived object is not an array 248 /// element. 0 is not an indicator of whether or not the most-derived object 249 /// is an array, however, because 0-length arrays are allowed. 250 /// 251 /// If the current array is an unsized array, the value of this is 252 /// undefined. 253 uint64_t MostDerivedArraySize; 254 255 /// The type of the most derived object referred to by this address. 256 QualType MostDerivedType; 257 258 typedef APValue::LValuePathEntry PathEntry; 259 260 /// The entries on the path from the glvalue to the designated subobject. 261 SmallVector<PathEntry, 8> Entries; 262 263 SubobjectDesignator() : Invalid(true) {} 264 265 explicit SubobjectDesignator(QualType T) 266 : Invalid(false), IsOnePastTheEnd(false), 267 FirstEntryIsAnUnsizedArray(false), MostDerivedIsArrayElement(false), 268 MostDerivedPathLength(0), MostDerivedArraySize(0), 269 MostDerivedType(T) {} 270 271 SubobjectDesignator(ASTContext &Ctx, const APValue &V) 272 : Invalid(!V.isLValue() || !V.hasLValuePath()), IsOnePastTheEnd(false), 273 FirstEntryIsAnUnsizedArray(false), MostDerivedIsArrayElement(false), 274 MostDerivedPathLength(0), MostDerivedArraySize(0) { 275 assert(V.isLValue() && "Non-LValue used to make an LValue designator?"); 276 if (!Invalid) { 277 IsOnePastTheEnd = V.isLValueOnePastTheEnd(); 278 ArrayRef<PathEntry> VEntries = V.getLValuePath(); 279 Entries.insert(Entries.end(), VEntries.begin(), VEntries.end()); 280 if (V.getLValueBase()) { 281 bool IsArray = false; 282 bool FirstIsUnsizedArray = false; 283 MostDerivedPathLength = findMostDerivedSubobject( 284 Ctx, V.getLValueBase(), V.getLValuePath(), MostDerivedArraySize, 285 MostDerivedType, IsArray, FirstIsUnsizedArray); 286 MostDerivedIsArrayElement = IsArray; 287 FirstEntryIsAnUnsizedArray = FirstIsUnsizedArray; 288 } 289 } 290 } 291 292 void setInvalid() { 293 Invalid = true; 294 Entries.clear(); 295 } 296 297 /// Determine whether the most derived subobject is an array without a 298 /// known bound. 299 bool isMostDerivedAnUnsizedArray() const { 300 assert(!Invalid && "Calling this makes no sense on invalid designators"); 301 return Entries.size() == 1 && FirstEntryIsAnUnsizedArray; 302 } 303 304 /// Determine what the most derived array's size is. Results in an assertion 305 /// failure if the most derived array lacks a size. 306 uint64_t getMostDerivedArraySize() const { 307 assert(!isMostDerivedAnUnsizedArray() && "Unsized array has no size"); 308 return MostDerivedArraySize; 309 } 310 311 /// Determine whether this is a one-past-the-end pointer. 312 bool isOnePastTheEnd() const { 313 assert(!Invalid); 314 if (IsOnePastTheEnd) 315 return true; 316 if (!isMostDerivedAnUnsizedArray() && MostDerivedIsArrayElement && 317 Entries[MostDerivedPathLength - 1].ArrayIndex == MostDerivedArraySize) 318 return true; 319 return false; 320 } 321 322 /// Check that this refers to a valid subobject. 323 bool isValidSubobject() const { 324 if (Invalid) 325 return false; 326 return !isOnePastTheEnd(); 327 } 328 /// Check that this refers to a valid subobject, and if not, produce a 329 /// relevant diagnostic and set the designator as invalid. 330 bool checkSubobject(EvalInfo &Info, const Expr *E, CheckSubobjectKind CSK); 331 332 /// Update this designator to refer to the first element within this array. 333 void addArrayUnchecked(const ConstantArrayType *CAT) { 334 PathEntry Entry; 335 Entry.ArrayIndex = 0; 336 Entries.push_back(Entry); 337 338 // This is a most-derived object. 339 MostDerivedType = CAT->getElementType(); 340 MostDerivedIsArrayElement = true; 341 MostDerivedArraySize = CAT->getSize().getZExtValue(); 342 MostDerivedPathLength = Entries.size(); 343 } 344 /// Update this designator to refer to the first element within the array of 345 /// elements of type T. This is an array of unknown size. 346 void addUnsizedArrayUnchecked(QualType ElemTy) { 347 PathEntry Entry; 348 Entry.ArrayIndex = 0; 349 Entries.push_back(Entry); 350 351 MostDerivedType = ElemTy; 352 MostDerivedIsArrayElement = true; 353 // The value in MostDerivedArraySize is undefined in this case. So, set it 354 // to an arbitrary value that's likely to loudly break things if it's 355 // used. 356 MostDerivedArraySize = AssumedSizeForUnsizedArray; 357 MostDerivedPathLength = Entries.size(); 358 } 359 /// Update this designator to refer to the given base or member of this 360 /// object. 361 void addDeclUnchecked(const Decl *D, bool Virtual = false) { 362 PathEntry Entry; 363 APValue::BaseOrMemberType Value(D, Virtual); 364 Entry.BaseOrMember = Value.getOpaqueValue(); 365 Entries.push_back(Entry); 366 367 // If this isn't a base class, it's a new most-derived object. 368 if (const FieldDecl *FD = dyn_cast<FieldDecl>(D)) { 369 MostDerivedType = FD->getType(); 370 MostDerivedIsArrayElement = false; 371 MostDerivedArraySize = 0; 372 MostDerivedPathLength = Entries.size(); 373 } 374 } 375 /// Update this designator to refer to the given complex component. 376 void addComplexUnchecked(QualType EltTy, bool Imag) { 377 PathEntry Entry; 378 Entry.ArrayIndex = Imag; 379 Entries.push_back(Entry); 380 381 // This is technically a most-derived object, though in practice this 382 // is unlikely to matter. 383 MostDerivedType = EltTy; 384 MostDerivedIsArrayElement = true; 385 MostDerivedArraySize = 2; 386 MostDerivedPathLength = Entries.size(); 387 } 388 void diagnoseUnsizedArrayPointerArithmetic(EvalInfo &Info, const Expr *E); 389 void diagnosePointerArithmetic(EvalInfo &Info, const Expr *E, 390 const APSInt &N); 391 /// Add N to the address of this subobject. 392 void adjustIndex(EvalInfo &Info, const Expr *E, APSInt N) { 393 if (Invalid || !N) return; 394 uint64_t TruncatedN = N.extOrTrunc(64).getZExtValue(); 395 if (isMostDerivedAnUnsizedArray()) { 396 diagnoseUnsizedArrayPointerArithmetic(Info, E); 397 // Can't verify -- trust that the user is doing the right thing (or if 398 // not, trust that the caller will catch the bad behavior). 399 // FIXME: Should we reject if this overflows, at least? 400 Entries.back().ArrayIndex += TruncatedN; 401 return; 402 } 403 404 // [expr.add]p4: For the purposes of these operators, a pointer to a 405 // nonarray object behaves the same as a pointer to the first element of 406 // an array of length one with the type of the object as its element type. 407 bool IsArray = MostDerivedPathLength == Entries.size() && 408 MostDerivedIsArrayElement; 409 uint64_t ArrayIndex = 410 IsArray ? Entries.back().ArrayIndex : (uint64_t)IsOnePastTheEnd; 411 uint64_t ArraySize = 412 IsArray ? getMostDerivedArraySize() : (uint64_t)1; 413 414 if (N < -(int64_t)ArrayIndex || N > ArraySize - ArrayIndex) { 415 // Calculate the actual index in a wide enough type, so we can include 416 // it in the note. 417 N = N.extend(std::max<unsigned>(N.getBitWidth() + 1, 65)); 418 (llvm::APInt&)N += ArrayIndex; 419 assert(N.ugt(ArraySize) && "bounds check failed for in-bounds index"); 420 diagnosePointerArithmetic(Info, E, N); 421 setInvalid(); 422 return; 423 } 424 425 ArrayIndex += TruncatedN; 426 assert(ArrayIndex <= ArraySize && 427 "bounds check succeeded for out-of-bounds index"); 428 429 if (IsArray) 430 Entries.back().ArrayIndex = ArrayIndex; 431 else 432 IsOnePastTheEnd = (ArrayIndex != 0); 433 } 434 }; 435 436 /// A stack frame in the constexpr call stack. 437 struct CallStackFrame { 438 EvalInfo &Info; 439 440 /// Parent - The caller of this stack frame. 441 CallStackFrame *Caller; 442 443 /// Callee - The function which was called. 444 const FunctionDecl *Callee; 445 446 /// This - The binding for the this pointer in this call, if any. 447 const LValue *This; 448 449 /// Arguments - Parameter bindings for this function call, indexed by 450 /// parameters' function scope indices. 451 APValue *Arguments; 452 453 // Note that we intentionally use std::map here so that references to 454 // values are stable. 455 typedef std::pair<const void *, unsigned> MapKeyTy; 456 typedef std::map<MapKeyTy, APValue> MapTy; 457 /// Temporaries - Temporary lvalues materialized within this stack frame. 458 MapTy Temporaries; 459 460 /// CallLoc - The location of the call expression for this call. 461 SourceLocation CallLoc; 462 463 /// Index - The call index of this call. 464 unsigned Index; 465 466 /// The stack of integers for tracking version numbers for temporaries. 467 SmallVector<unsigned, 2> TempVersionStack = {1}; 468 unsigned CurTempVersion = TempVersionStack.back(); 469 470 unsigned getTempVersion() const { return TempVersionStack.back(); } 471 472 void pushTempVersion() { 473 TempVersionStack.push_back(++CurTempVersion); 474 } 475 476 void popTempVersion() { 477 TempVersionStack.pop_back(); 478 } 479 480 // FIXME: Adding this to every 'CallStackFrame' may have a nontrivial impact 481 // on the overall stack usage of deeply-recursing constexpr evaluataions. 482 // (We should cache this map rather than recomputing it repeatedly.) 483 // But let's try this and see how it goes; we can look into caching the map 484 // as a later change. 485 486 /// LambdaCaptureFields - Mapping from captured variables/this to 487 /// corresponding data members in the closure class. 488 llvm::DenseMap<const VarDecl *, FieldDecl *> LambdaCaptureFields; 489 FieldDecl *LambdaThisCaptureField; 490 491 CallStackFrame(EvalInfo &Info, SourceLocation CallLoc, 492 const FunctionDecl *Callee, const LValue *This, 493 APValue *Arguments); 494 ~CallStackFrame(); 495 496 // Return the temporary for Key whose version number is Version. 497 APValue *getTemporary(const void *Key, unsigned Version) { 498 MapKeyTy KV(Key, Version); 499 auto LB = Temporaries.lower_bound(KV); 500 if (LB != Temporaries.end() && LB->first == KV) 501 return &LB->second; 502 // Pair (Key,Version) wasn't found in the map. Check that no elements 503 // in the map have 'Key' as their key. 504 assert((LB == Temporaries.end() || LB->first.first != Key) && 505 (LB == Temporaries.begin() || std::prev(LB)->first.first != Key) && 506 "Element with key 'Key' found in map"); 507 return nullptr; 508 } 509 510 // Return the current temporary for Key in the map. 511 APValue *getCurrentTemporary(const void *Key) { 512 auto UB = Temporaries.upper_bound(MapKeyTy(Key, UINT_MAX)); 513 if (UB != Temporaries.begin() && std::prev(UB)->first.first == Key) 514 return &std::prev(UB)->second; 515 return nullptr; 516 } 517 518 // Return the version number of the current temporary for Key. 519 unsigned getCurrentTemporaryVersion(const void *Key) const { 520 auto UB = Temporaries.upper_bound(MapKeyTy(Key, UINT_MAX)); 521 if (UB != Temporaries.begin() && std::prev(UB)->first.first == Key) 522 return std::prev(UB)->first.second; 523 return 0; 524 } 525 526 APValue &createTemporary(const void *Key, bool IsLifetimeExtended); 527 }; 528 529 /// Temporarily override 'this'. 530 class ThisOverrideRAII { 531 public: 532 ThisOverrideRAII(CallStackFrame &Frame, const LValue *NewThis, bool Enable) 533 : Frame(Frame), OldThis(Frame.This) { 534 if (Enable) 535 Frame.This = NewThis; 536 } 537 ~ThisOverrideRAII() { 538 Frame.This = OldThis; 539 } 540 private: 541 CallStackFrame &Frame; 542 const LValue *OldThis; 543 }; 544 545 /// A partial diagnostic which we might know in advance that we are not going 546 /// to emit. 547 class OptionalDiagnostic { 548 PartialDiagnostic *Diag; 549 550 public: 551 explicit OptionalDiagnostic(PartialDiagnostic *Diag = nullptr) 552 : Diag(Diag) {} 553 554 template<typename T> 555 OptionalDiagnostic &operator<<(const T &v) { 556 if (Diag) 557 *Diag << v; 558 return *this; 559 } 560 561 OptionalDiagnostic &operator<<(const APSInt &I) { 562 if (Diag) { 563 SmallVector<char, 32> Buffer; 564 I.toString(Buffer); 565 *Diag << StringRef(Buffer.data(), Buffer.size()); 566 } 567 return *this; 568 } 569 570 OptionalDiagnostic &operator<<(const APFloat &F) { 571 if (Diag) { 572 // FIXME: Force the precision of the source value down so we don't 573 // print digits which are usually useless (we don't really care here if 574 // we truncate a digit by accident in edge cases). Ideally, 575 // APFloat::toString would automatically print the shortest 576 // representation which rounds to the correct value, but it's a bit 577 // tricky to implement. 578 unsigned precision = 579 llvm::APFloat::semanticsPrecision(F.getSemantics()); 580 precision = (precision * 59 + 195) / 196; 581 SmallVector<char, 32> Buffer; 582 F.toString(Buffer, precision); 583 *Diag << StringRef(Buffer.data(), Buffer.size()); 584 } 585 return *this; 586 } 587 }; 588 589 /// A cleanup, and a flag indicating whether it is lifetime-extended. 590 class Cleanup { 591 llvm::PointerIntPair<APValue*, 1, bool> Value; 592 593 public: 594 Cleanup(APValue *Val, bool IsLifetimeExtended) 595 : Value(Val, IsLifetimeExtended) {} 596 597 bool isLifetimeExtended() const { return Value.getInt(); } 598 void endLifetime() { 599 *Value.getPointer() = APValue(); 600 } 601 }; 602 603 /// EvalInfo - This is a private struct used by the evaluator to capture 604 /// information about a subexpression as it is folded. It retains information 605 /// about the AST context, but also maintains information about the folded 606 /// expression. 607 /// 608 /// If an expression could be evaluated, it is still possible it is not a C 609 /// "integer constant expression" or constant expression. If not, this struct 610 /// captures information about how and why not. 611 /// 612 /// One bit of information passed *into* the request for constant folding 613 /// indicates whether the subexpression is "evaluated" or not according to C 614 /// rules. For example, the RHS of (0 && foo()) is not evaluated. We can 615 /// evaluate the expression regardless of what the RHS is, but C only allows 616 /// certain things in certain situations. 617 struct EvalInfo { 618 ASTContext &Ctx; 619 620 /// EvalStatus - Contains information about the evaluation. 621 Expr::EvalStatus &EvalStatus; 622 623 /// CurrentCall - The top of the constexpr call stack. 624 CallStackFrame *CurrentCall; 625 626 /// CallStackDepth - The number of calls in the call stack right now. 627 unsigned CallStackDepth; 628 629 /// NextCallIndex - The next call index to assign. 630 unsigned NextCallIndex; 631 632 /// StepsLeft - The remaining number of evaluation steps we're permitted 633 /// to perform. This is essentially a limit for the number of statements 634 /// we will evaluate. 635 unsigned StepsLeft; 636 637 /// BottomFrame - The frame in which evaluation started. This must be 638 /// initialized after CurrentCall and CallStackDepth. 639 CallStackFrame BottomFrame; 640 641 /// A stack of values whose lifetimes end at the end of some surrounding 642 /// evaluation frame. 643 llvm::SmallVector<Cleanup, 16> CleanupStack; 644 645 /// EvaluatingDecl - This is the declaration whose initializer is being 646 /// evaluated, if any. 647 APValue::LValueBase EvaluatingDecl; 648 649 /// EvaluatingDeclValue - This is the value being constructed for the 650 /// declaration whose initializer is being evaluated, if any. 651 APValue *EvaluatingDeclValue; 652 653 /// EvaluatingObject - Pair of the AST node that an lvalue represents and 654 /// the call index that that lvalue was allocated in. 655 typedef std::pair<APValue::LValueBase, std::pair<unsigned, unsigned>> 656 EvaluatingObject; 657 658 /// EvaluatingConstructors - Set of objects that are currently being 659 /// constructed. 660 llvm::DenseSet<EvaluatingObject> EvaluatingConstructors; 661 662 struct EvaluatingConstructorRAII { 663 EvalInfo &EI; 664 EvaluatingObject Object; 665 bool DidInsert; 666 EvaluatingConstructorRAII(EvalInfo &EI, EvaluatingObject Object) 667 : EI(EI), Object(Object) { 668 DidInsert = EI.EvaluatingConstructors.insert(Object).second; 669 } 670 ~EvaluatingConstructorRAII() { 671 if (DidInsert) EI.EvaluatingConstructors.erase(Object); 672 } 673 }; 674 675 bool isEvaluatingConstructor(APValue::LValueBase Decl, unsigned CallIndex, 676 unsigned Version) { 677 return EvaluatingConstructors.count( 678 EvaluatingObject(Decl, {CallIndex, Version})); 679 } 680 681 /// The current array initialization index, if we're performing array 682 /// initialization. 683 uint64_t ArrayInitIndex = -1; 684 685 /// HasActiveDiagnostic - Was the previous diagnostic stored? If so, further 686 /// notes attached to it will also be stored, otherwise they will not be. 687 bool HasActiveDiagnostic; 688 689 /// Have we emitted a diagnostic explaining why we couldn't constant 690 /// fold (not just why it's not strictly a constant expression)? 691 bool HasFoldFailureDiagnostic; 692 693 /// Whether or not we're currently speculatively evaluating. 694 bool IsSpeculativelyEvaluating; 695 696 enum EvaluationMode { 697 /// Evaluate as a constant expression. Stop if we find that the expression 698 /// is not a constant expression. 699 EM_ConstantExpression, 700 701 /// Evaluate as a potential constant expression. Keep going if we hit a 702 /// construct that we can't evaluate yet (because we don't yet know the 703 /// value of something) but stop if we hit something that could never be 704 /// a constant expression. 705 EM_PotentialConstantExpression, 706 707 /// Fold the expression to a constant. Stop if we hit a side-effect that 708 /// we can't model. 709 EM_ConstantFold, 710 711 /// Evaluate the expression looking for integer overflow and similar 712 /// issues. Don't worry about side-effects, and try to visit all 713 /// subexpressions. 714 EM_EvaluateForOverflow, 715 716 /// Evaluate in any way we know how. Don't worry about side-effects that 717 /// can't be modeled. 718 EM_IgnoreSideEffects, 719 720 /// Evaluate as a constant expression. Stop if we find that the expression 721 /// is not a constant expression. Some expressions can be retried in the 722 /// optimizer if we don't constant fold them here, but in an unevaluated 723 /// context we try to fold them immediately since the optimizer never 724 /// gets a chance to look at it. 725 EM_ConstantExpressionUnevaluated, 726 727 /// Evaluate as a potential constant expression. Keep going if we hit a 728 /// construct that we can't evaluate yet (because we don't yet know the 729 /// value of something) but stop if we hit something that could never be 730 /// a constant expression. Some expressions can be retried in the 731 /// optimizer if we don't constant fold them here, but in an unevaluated 732 /// context we try to fold them immediately since the optimizer never 733 /// gets a chance to look at it. 734 EM_PotentialConstantExpressionUnevaluated, 735 736 /// Evaluate as a constant expression. In certain scenarios, if: 737 /// - we find a MemberExpr with a base that can't be evaluated, or 738 /// - we find a variable initialized with a call to a function that has 739 /// the alloc_size attribute on it 740 /// then we may consider evaluation to have succeeded. 741 /// 742 /// In either case, the LValue returned shall have an invalid base; in the 743 /// former, the base will be the invalid MemberExpr, in the latter, the 744 /// base will be either the alloc_size CallExpr or a CastExpr wrapping 745 /// said CallExpr. 746 EM_OffsetFold, 747 } EvalMode; 748 749 /// Are we checking whether the expression is a potential constant 750 /// expression? 751 bool checkingPotentialConstantExpression() const { 752 return EvalMode == EM_PotentialConstantExpression || 753 EvalMode == EM_PotentialConstantExpressionUnevaluated; 754 } 755 756 /// Are we checking an expression for overflow? 757 // FIXME: We should check for any kind of undefined or suspicious behavior 758 // in such constructs, not just overflow. 759 bool checkingForOverflow() { return EvalMode == EM_EvaluateForOverflow; } 760 761 EvalInfo(const ASTContext &C, Expr::EvalStatus &S, EvaluationMode Mode) 762 : Ctx(const_cast<ASTContext &>(C)), EvalStatus(S), CurrentCall(nullptr), 763 CallStackDepth(0), NextCallIndex(1), 764 StepsLeft(getLangOpts().ConstexprStepLimit), 765 BottomFrame(*this, SourceLocation(), nullptr, nullptr, nullptr), 766 EvaluatingDecl((const ValueDecl *)nullptr), 767 EvaluatingDeclValue(nullptr), HasActiveDiagnostic(false), 768 HasFoldFailureDiagnostic(false), IsSpeculativelyEvaluating(false), 769 EvalMode(Mode) {} 770 771 void setEvaluatingDecl(APValue::LValueBase Base, APValue &Value) { 772 EvaluatingDecl = Base; 773 EvaluatingDeclValue = &Value; 774 EvaluatingConstructors.insert({Base, {0, 0}}); 775 } 776 777 const LangOptions &getLangOpts() const { return Ctx.getLangOpts(); } 778 779 bool CheckCallLimit(SourceLocation Loc) { 780 // Don't perform any constexpr calls (other than the call we're checking) 781 // when checking a potential constant expression. 782 if (checkingPotentialConstantExpression() && CallStackDepth > 1) 783 return false; 784 if (NextCallIndex == 0) { 785 // NextCallIndex has wrapped around. 786 FFDiag(Loc, diag::note_constexpr_call_limit_exceeded); 787 return false; 788 } 789 if (CallStackDepth <= getLangOpts().ConstexprCallDepth) 790 return true; 791 FFDiag(Loc, diag::note_constexpr_depth_limit_exceeded) 792 << getLangOpts().ConstexprCallDepth; 793 return false; 794 } 795 796 CallStackFrame *getCallFrame(unsigned CallIndex) { 797 assert(CallIndex && "no call index in getCallFrame"); 798 // We will eventually hit BottomFrame, which has Index 1, so Frame can't 799 // be null in this loop. 800 CallStackFrame *Frame = CurrentCall; 801 while (Frame->Index > CallIndex) 802 Frame = Frame->Caller; 803 return (Frame->Index == CallIndex) ? Frame : nullptr; 804 } 805 806 bool nextStep(const Stmt *S) { 807 if (!StepsLeft) { 808 FFDiag(S->getLocStart(), diag::note_constexpr_step_limit_exceeded); 809 return false; 810 } 811 --StepsLeft; 812 return true; 813 } 814 815 private: 816 /// Add a diagnostic to the diagnostics list. 817 PartialDiagnostic &addDiag(SourceLocation Loc, diag::kind DiagId) { 818 PartialDiagnostic PD(DiagId, Ctx.getDiagAllocator()); 819 EvalStatus.Diag->push_back(std::make_pair(Loc, PD)); 820 return EvalStatus.Diag->back().second; 821 } 822 823 /// Add notes containing a call stack to the current point of evaluation. 824 void addCallStack(unsigned Limit); 825 826 private: 827 OptionalDiagnostic Diag(SourceLocation Loc, diag::kind DiagId, 828 unsigned ExtraNotes, bool IsCCEDiag) { 829 830 if (EvalStatus.Diag) { 831 // If we have a prior diagnostic, it will be noting that the expression 832 // isn't a constant expression. This diagnostic is more important, 833 // unless we require this evaluation to produce a constant expression. 834 // 835 // FIXME: We might want to show both diagnostics to the user in 836 // EM_ConstantFold mode. 837 if (!EvalStatus.Diag->empty()) { 838 switch (EvalMode) { 839 case EM_ConstantFold: 840 case EM_IgnoreSideEffects: 841 case EM_EvaluateForOverflow: 842 if (!HasFoldFailureDiagnostic) 843 break; 844 // We've already failed to fold something. Keep that diagnostic. 845 LLVM_FALLTHROUGH; 846 case EM_ConstantExpression: 847 case EM_PotentialConstantExpression: 848 case EM_ConstantExpressionUnevaluated: 849 case EM_PotentialConstantExpressionUnevaluated: 850 case EM_OffsetFold: 851 HasActiveDiagnostic = false; 852 return OptionalDiagnostic(); 853 } 854 } 855 856 unsigned CallStackNotes = CallStackDepth - 1; 857 unsigned Limit = Ctx.getDiagnostics().getConstexprBacktraceLimit(); 858 if (Limit) 859 CallStackNotes = std::min(CallStackNotes, Limit + 1); 860 if (checkingPotentialConstantExpression()) 861 CallStackNotes = 0; 862 863 HasActiveDiagnostic = true; 864 HasFoldFailureDiagnostic = !IsCCEDiag; 865 EvalStatus.Diag->clear(); 866 EvalStatus.Diag->reserve(1 + ExtraNotes + CallStackNotes); 867 addDiag(Loc, DiagId); 868 if (!checkingPotentialConstantExpression()) 869 addCallStack(Limit); 870 return OptionalDiagnostic(&(*EvalStatus.Diag)[0].second); 871 } 872 HasActiveDiagnostic = false; 873 return OptionalDiagnostic(); 874 } 875 public: 876 // Diagnose that the evaluation could not be folded (FF => FoldFailure) 877 OptionalDiagnostic 878 FFDiag(SourceLocation Loc, 879 diag::kind DiagId = diag::note_invalid_subexpr_in_const_expr, 880 unsigned ExtraNotes = 0) { 881 return Diag(Loc, DiagId, ExtraNotes, false); 882 } 883 884 OptionalDiagnostic FFDiag(const Expr *E, diag::kind DiagId 885 = diag::note_invalid_subexpr_in_const_expr, 886 unsigned ExtraNotes = 0) { 887 if (EvalStatus.Diag) 888 return Diag(E->getExprLoc(), DiagId, ExtraNotes, /*IsCCEDiag*/false); 889 HasActiveDiagnostic = false; 890 return OptionalDiagnostic(); 891 } 892 893 /// Diagnose that the evaluation does not produce a C++11 core constant 894 /// expression. 895 /// 896 /// FIXME: Stop evaluating if we're in EM_ConstantExpression or 897 /// EM_PotentialConstantExpression mode and we produce one of these. 898 OptionalDiagnostic CCEDiag(SourceLocation Loc, diag::kind DiagId 899 = diag::note_invalid_subexpr_in_const_expr, 900 unsigned ExtraNotes = 0) { 901 // Don't override a previous diagnostic. Don't bother collecting 902 // diagnostics if we're evaluating for overflow. 903 if (!EvalStatus.Diag || !EvalStatus.Diag->empty()) { 904 HasActiveDiagnostic = false; 905 return OptionalDiagnostic(); 906 } 907 return Diag(Loc, DiagId, ExtraNotes, true); 908 } 909 OptionalDiagnostic CCEDiag(const Expr *E, diag::kind DiagId 910 = diag::note_invalid_subexpr_in_const_expr, 911 unsigned ExtraNotes = 0) { 912 return CCEDiag(E->getExprLoc(), DiagId, ExtraNotes); 913 } 914 /// Add a note to a prior diagnostic. 915 OptionalDiagnostic Note(SourceLocation Loc, diag::kind DiagId) { 916 if (!HasActiveDiagnostic) 917 return OptionalDiagnostic(); 918 return OptionalDiagnostic(&addDiag(Loc, DiagId)); 919 } 920 921 /// Add a stack of notes to a prior diagnostic. 922 void addNotes(ArrayRef<PartialDiagnosticAt> Diags) { 923 if (HasActiveDiagnostic) { 924 EvalStatus.Diag->insert(EvalStatus.Diag->end(), 925 Diags.begin(), Diags.end()); 926 } 927 } 928 929 /// Should we continue evaluation after encountering a side-effect that we 930 /// couldn't model? 931 bool keepEvaluatingAfterSideEffect() { 932 switch (EvalMode) { 933 case EM_PotentialConstantExpression: 934 case EM_PotentialConstantExpressionUnevaluated: 935 case EM_EvaluateForOverflow: 936 case EM_IgnoreSideEffects: 937 return true; 938 939 case EM_ConstantExpression: 940 case EM_ConstantExpressionUnevaluated: 941 case EM_ConstantFold: 942 case EM_OffsetFold: 943 return false; 944 } 945 llvm_unreachable("Missed EvalMode case"); 946 } 947 948 /// Note that we have had a side-effect, and determine whether we should 949 /// keep evaluating. 950 bool noteSideEffect() { 951 EvalStatus.HasSideEffects = true; 952 return keepEvaluatingAfterSideEffect(); 953 } 954 955 /// Should we continue evaluation after encountering undefined behavior? 956 bool keepEvaluatingAfterUndefinedBehavior() { 957 switch (EvalMode) { 958 case EM_EvaluateForOverflow: 959 case EM_IgnoreSideEffects: 960 case EM_ConstantFold: 961 case EM_OffsetFold: 962 return true; 963 964 case EM_PotentialConstantExpression: 965 case EM_PotentialConstantExpressionUnevaluated: 966 case EM_ConstantExpression: 967 case EM_ConstantExpressionUnevaluated: 968 return false; 969 } 970 llvm_unreachable("Missed EvalMode case"); 971 } 972 973 /// Note that we hit something that was technically undefined behavior, but 974 /// that we can evaluate past it (such as signed overflow or floating-point 975 /// division by zero.) 976 bool noteUndefinedBehavior() { 977 EvalStatus.HasUndefinedBehavior = true; 978 return keepEvaluatingAfterUndefinedBehavior(); 979 } 980 981 /// Should we continue evaluation as much as possible after encountering a 982 /// construct which can't be reduced to a value? 983 bool keepEvaluatingAfterFailure() { 984 if (!StepsLeft) 985 return false; 986 987 switch (EvalMode) { 988 case EM_PotentialConstantExpression: 989 case EM_PotentialConstantExpressionUnevaluated: 990 case EM_EvaluateForOverflow: 991 return true; 992 993 case EM_ConstantExpression: 994 case EM_ConstantExpressionUnevaluated: 995 case EM_ConstantFold: 996 case EM_IgnoreSideEffects: 997 case EM_OffsetFold: 998 return false; 999 } 1000 llvm_unreachable("Missed EvalMode case"); 1001 } 1002 1003 /// Notes that we failed to evaluate an expression that other expressions 1004 /// directly depend on, and determine if we should keep evaluating. This 1005 /// should only be called if we actually intend to keep evaluating. 1006 /// 1007 /// Call noteSideEffect() instead if we may be able to ignore the value that 1008 /// we failed to evaluate, e.g. if we failed to evaluate Foo() in: 1009 /// 1010 /// (Foo(), 1) // use noteSideEffect 1011 /// (Foo() || true) // use noteSideEffect 1012 /// Foo() + 1 // use noteFailure 1013 LLVM_NODISCARD bool noteFailure() { 1014 // Failure when evaluating some expression often means there is some 1015 // subexpression whose evaluation was skipped. Therefore, (because we 1016 // don't track whether we skipped an expression when unwinding after an 1017 // evaluation failure) every evaluation failure that bubbles up from a 1018 // subexpression implies that a side-effect has potentially happened. We 1019 // skip setting the HasSideEffects flag to true until we decide to 1020 // continue evaluating after that point, which happens here. 1021 bool KeepGoing = keepEvaluatingAfterFailure(); 1022 EvalStatus.HasSideEffects |= KeepGoing; 1023 return KeepGoing; 1024 } 1025 1026 class ArrayInitLoopIndex { 1027 EvalInfo &Info; 1028 uint64_t OuterIndex; 1029 1030 public: 1031 ArrayInitLoopIndex(EvalInfo &Info) 1032 : Info(Info), OuterIndex(Info.ArrayInitIndex) { 1033 Info.ArrayInitIndex = 0; 1034 } 1035 ~ArrayInitLoopIndex() { Info.ArrayInitIndex = OuterIndex; } 1036 1037 operator uint64_t&() { return Info.ArrayInitIndex; } 1038 }; 1039 }; 1040 1041 /// Object used to treat all foldable expressions as constant expressions. 1042 struct FoldConstant { 1043 EvalInfo &Info; 1044 bool Enabled; 1045 bool HadNoPriorDiags; 1046 EvalInfo::EvaluationMode OldMode; 1047 1048 explicit FoldConstant(EvalInfo &Info, bool Enabled) 1049 : Info(Info), 1050 Enabled(Enabled), 1051 HadNoPriorDiags(Info.EvalStatus.Diag && 1052 Info.EvalStatus.Diag->empty() && 1053 !Info.EvalStatus.HasSideEffects), 1054 OldMode(Info.EvalMode) { 1055 if (Enabled && 1056 (Info.EvalMode == EvalInfo::EM_ConstantExpression || 1057 Info.EvalMode == EvalInfo::EM_ConstantExpressionUnevaluated)) 1058 Info.EvalMode = EvalInfo::EM_ConstantFold; 1059 } 1060 void keepDiagnostics() { Enabled = false; } 1061 ~FoldConstant() { 1062 if (Enabled && HadNoPriorDiags && !Info.EvalStatus.Diag->empty() && 1063 !Info.EvalStatus.HasSideEffects) 1064 Info.EvalStatus.Diag->clear(); 1065 Info.EvalMode = OldMode; 1066 } 1067 }; 1068 1069 /// RAII object used to treat the current evaluation as the correct pointer 1070 /// offset fold for the current EvalMode 1071 struct FoldOffsetRAII { 1072 EvalInfo &Info; 1073 EvalInfo::EvaluationMode OldMode; 1074 explicit FoldOffsetRAII(EvalInfo &Info) 1075 : Info(Info), OldMode(Info.EvalMode) { 1076 if (!Info.checkingPotentialConstantExpression()) 1077 Info.EvalMode = EvalInfo::EM_OffsetFold; 1078 } 1079 1080 ~FoldOffsetRAII() { Info.EvalMode = OldMode; } 1081 }; 1082 1083 /// RAII object used to optionally suppress diagnostics and side-effects from 1084 /// a speculative evaluation. 1085 class SpeculativeEvaluationRAII { 1086 EvalInfo *Info = nullptr; 1087 Expr::EvalStatus OldStatus; 1088 bool OldIsSpeculativelyEvaluating; 1089 1090 void moveFromAndCancel(SpeculativeEvaluationRAII &&Other) { 1091 Info = Other.Info; 1092 OldStatus = Other.OldStatus; 1093 OldIsSpeculativelyEvaluating = Other.OldIsSpeculativelyEvaluating; 1094 Other.Info = nullptr; 1095 } 1096 1097 void maybeRestoreState() { 1098 if (!Info) 1099 return; 1100 1101 Info->EvalStatus = OldStatus; 1102 Info->IsSpeculativelyEvaluating = OldIsSpeculativelyEvaluating; 1103 } 1104 1105 public: 1106 SpeculativeEvaluationRAII() = default; 1107 1108 SpeculativeEvaluationRAII( 1109 EvalInfo &Info, SmallVectorImpl<PartialDiagnosticAt> *NewDiag = nullptr) 1110 : Info(&Info), OldStatus(Info.EvalStatus), 1111 OldIsSpeculativelyEvaluating(Info.IsSpeculativelyEvaluating) { 1112 Info.EvalStatus.Diag = NewDiag; 1113 Info.IsSpeculativelyEvaluating = true; 1114 } 1115 1116 SpeculativeEvaluationRAII(const SpeculativeEvaluationRAII &Other) = delete; 1117 SpeculativeEvaluationRAII(SpeculativeEvaluationRAII &&Other) { 1118 moveFromAndCancel(std::move(Other)); 1119 } 1120 1121 SpeculativeEvaluationRAII &operator=(SpeculativeEvaluationRAII &&Other) { 1122 maybeRestoreState(); 1123 moveFromAndCancel(std::move(Other)); 1124 return *this; 1125 } 1126 1127 ~SpeculativeEvaluationRAII() { maybeRestoreState(); } 1128 }; 1129 1130 /// RAII object wrapping a full-expression or block scope, and handling 1131 /// the ending of the lifetime of temporaries created within it. 1132 template<bool IsFullExpression> 1133 class ScopeRAII { 1134 EvalInfo &Info; 1135 unsigned OldStackSize; 1136 public: 1137 ScopeRAII(EvalInfo &Info) 1138 : Info(Info), OldStackSize(Info.CleanupStack.size()) { 1139 // Push a new temporary version. This is needed to distinguish between 1140 // temporaries created in different iterations of a loop. 1141 Info.CurrentCall->pushTempVersion(); 1142 } 1143 ~ScopeRAII() { 1144 // Body moved to a static method to encourage the compiler to inline away 1145 // instances of this class. 1146 cleanup(Info, OldStackSize); 1147 Info.CurrentCall->popTempVersion(); 1148 } 1149 private: 1150 static void cleanup(EvalInfo &Info, unsigned OldStackSize) { 1151 unsigned NewEnd = OldStackSize; 1152 for (unsigned I = OldStackSize, N = Info.CleanupStack.size(); 1153 I != N; ++I) { 1154 if (IsFullExpression && Info.CleanupStack[I].isLifetimeExtended()) { 1155 // Full-expression cleanup of a lifetime-extended temporary: nothing 1156 // to do, just move this cleanup to the right place in the stack. 1157 std::swap(Info.CleanupStack[I], Info.CleanupStack[NewEnd]); 1158 ++NewEnd; 1159 } else { 1160 // End the lifetime of the object. 1161 Info.CleanupStack[I].endLifetime(); 1162 } 1163 } 1164 Info.CleanupStack.erase(Info.CleanupStack.begin() + NewEnd, 1165 Info.CleanupStack.end()); 1166 } 1167 }; 1168 typedef ScopeRAII<false> BlockScopeRAII; 1169 typedef ScopeRAII<true> FullExpressionRAII; 1170 } 1171 1172 bool SubobjectDesignator::checkSubobject(EvalInfo &Info, const Expr *E, 1173 CheckSubobjectKind CSK) { 1174 if (Invalid) 1175 return false; 1176 if (isOnePastTheEnd()) { 1177 Info.CCEDiag(E, diag::note_constexpr_past_end_subobject) 1178 << CSK; 1179 setInvalid(); 1180 return false; 1181 } 1182 // Note, we do not diagnose if isMostDerivedAnUnsizedArray(), because there 1183 // must actually be at least one array element; even a VLA cannot have a 1184 // bound of zero. And if our index is nonzero, we already had a CCEDiag. 1185 return true; 1186 } 1187 1188 void SubobjectDesignator::diagnoseUnsizedArrayPointerArithmetic(EvalInfo &Info, 1189 const Expr *E) { 1190 Info.CCEDiag(E, diag::note_constexpr_unsized_array_indexed); 1191 // Do not set the designator as invalid: we can represent this situation, 1192 // and correct handling of __builtin_object_size requires us to do so. 1193 } 1194 1195 void SubobjectDesignator::diagnosePointerArithmetic(EvalInfo &Info, 1196 const Expr *E, 1197 const APSInt &N) { 1198 // If we're complaining, we must be able to statically determine the size of 1199 // the most derived array. 1200 if (MostDerivedPathLength == Entries.size() && MostDerivedIsArrayElement) 1201 Info.CCEDiag(E, diag::note_constexpr_array_index) 1202 << N << /*array*/ 0 1203 << static_cast<unsigned>(getMostDerivedArraySize()); 1204 else 1205 Info.CCEDiag(E, diag::note_constexpr_array_index) 1206 << N << /*non-array*/ 1; 1207 setInvalid(); 1208 } 1209 1210 CallStackFrame::CallStackFrame(EvalInfo &Info, SourceLocation CallLoc, 1211 const FunctionDecl *Callee, const LValue *This, 1212 APValue *Arguments) 1213 : Info(Info), Caller(Info.CurrentCall), Callee(Callee), This(This), 1214 Arguments(Arguments), CallLoc(CallLoc), Index(Info.NextCallIndex++) { 1215 Info.CurrentCall = this; 1216 ++Info.CallStackDepth; 1217 } 1218 1219 CallStackFrame::~CallStackFrame() { 1220 assert(Info.CurrentCall == this && "calls retired out of order"); 1221 --Info.CallStackDepth; 1222 Info.CurrentCall = Caller; 1223 } 1224 1225 APValue &CallStackFrame::createTemporary(const void *Key, 1226 bool IsLifetimeExtended) { 1227 unsigned Version = Info.CurrentCall->getTempVersion(); 1228 APValue &Result = Temporaries[MapKeyTy(Key, Version)]; 1229 assert(Result.isUninit() && "temporary created multiple times"); 1230 Info.CleanupStack.push_back(Cleanup(&Result, IsLifetimeExtended)); 1231 return Result; 1232 } 1233 1234 static void describeCall(CallStackFrame *Frame, raw_ostream &Out); 1235 1236 void EvalInfo::addCallStack(unsigned Limit) { 1237 // Determine which calls to skip, if any. 1238 unsigned ActiveCalls = CallStackDepth - 1; 1239 unsigned SkipStart = ActiveCalls, SkipEnd = SkipStart; 1240 if (Limit && Limit < ActiveCalls) { 1241 SkipStart = Limit / 2 + Limit % 2; 1242 SkipEnd = ActiveCalls - Limit / 2; 1243 } 1244 1245 // Walk the call stack and add the diagnostics. 1246 unsigned CallIdx = 0; 1247 for (CallStackFrame *Frame = CurrentCall; Frame != &BottomFrame; 1248 Frame = Frame->Caller, ++CallIdx) { 1249 // Skip this call? 1250 if (CallIdx >= SkipStart && CallIdx < SkipEnd) { 1251 if (CallIdx == SkipStart) { 1252 // Note that we're skipping calls. 1253 addDiag(Frame->CallLoc, diag::note_constexpr_calls_suppressed) 1254 << unsigned(ActiveCalls - Limit); 1255 } 1256 continue; 1257 } 1258 1259 // Use a different note for an inheriting constructor, because from the 1260 // user's perspective it's not really a function at all. 1261 if (auto *CD = dyn_cast_or_null<CXXConstructorDecl>(Frame->Callee)) { 1262 if (CD->isInheritingConstructor()) { 1263 addDiag(Frame->CallLoc, diag::note_constexpr_inherited_ctor_call_here) 1264 << CD->getParent(); 1265 continue; 1266 } 1267 } 1268 1269 SmallVector<char, 128> Buffer; 1270 llvm::raw_svector_ostream Out(Buffer); 1271 describeCall(Frame, Out); 1272 addDiag(Frame->CallLoc, diag::note_constexpr_call_here) << Out.str(); 1273 } 1274 } 1275 1276 namespace { 1277 struct ComplexValue { 1278 private: 1279 bool IsInt; 1280 1281 public: 1282 APSInt IntReal, IntImag; 1283 APFloat FloatReal, FloatImag; 1284 1285 ComplexValue() : FloatReal(APFloat::Bogus()), FloatImag(APFloat::Bogus()) {} 1286 1287 void makeComplexFloat() { IsInt = false; } 1288 bool isComplexFloat() const { return !IsInt; } 1289 APFloat &getComplexFloatReal() { return FloatReal; } 1290 APFloat &getComplexFloatImag() { return FloatImag; } 1291 1292 void makeComplexInt() { IsInt = true; } 1293 bool isComplexInt() const { return IsInt; } 1294 APSInt &getComplexIntReal() { return IntReal; } 1295 APSInt &getComplexIntImag() { return IntImag; } 1296 1297 void moveInto(APValue &v) const { 1298 if (isComplexFloat()) 1299 v = APValue(FloatReal, FloatImag); 1300 else 1301 v = APValue(IntReal, IntImag); 1302 } 1303 void setFrom(const APValue &v) { 1304 assert(v.isComplexFloat() || v.isComplexInt()); 1305 if (v.isComplexFloat()) { 1306 makeComplexFloat(); 1307 FloatReal = v.getComplexFloatReal(); 1308 FloatImag = v.getComplexFloatImag(); 1309 } else { 1310 makeComplexInt(); 1311 IntReal = v.getComplexIntReal(); 1312 IntImag = v.getComplexIntImag(); 1313 } 1314 } 1315 }; 1316 1317 struct LValue { 1318 APValue::LValueBase Base; 1319 CharUnits Offset; 1320 SubobjectDesignator Designator; 1321 bool IsNullPtr : 1; 1322 bool InvalidBase : 1; 1323 1324 const APValue::LValueBase getLValueBase() const { return Base; } 1325 CharUnits &getLValueOffset() { return Offset; } 1326 const CharUnits &getLValueOffset() const { return Offset; } 1327 SubobjectDesignator &getLValueDesignator() { return Designator; } 1328 const SubobjectDesignator &getLValueDesignator() const { return Designator;} 1329 bool isNullPointer() const { return IsNullPtr;} 1330 1331 unsigned getLValueCallIndex() const { return Base.getCallIndex(); } 1332 unsigned getLValueVersion() const { return Base.getVersion(); } 1333 1334 void moveInto(APValue &V) const { 1335 if (Designator.Invalid) 1336 V = APValue(Base, Offset, APValue::NoLValuePath(), IsNullPtr); 1337 else { 1338 assert(!InvalidBase && "APValues can't handle invalid LValue bases"); 1339 V = APValue(Base, Offset, Designator.Entries, 1340 Designator.IsOnePastTheEnd, IsNullPtr); 1341 } 1342 } 1343 void setFrom(ASTContext &Ctx, const APValue &V) { 1344 assert(V.isLValue() && "Setting LValue from a non-LValue?"); 1345 Base = V.getLValueBase(); 1346 Offset = V.getLValueOffset(); 1347 InvalidBase = false; 1348 Designator = SubobjectDesignator(Ctx, V); 1349 IsNullPtr = V.isNullPointer(); 1350 } 1351 1352 void set(APValue::LValueBase B, bool BInvalid = false) { 1353 #ifndef NDEBUG 1354 // We only allow a few types of invalid bases. Enforce that here. 1355 if (BInvalid) { 1356 const auto *E = B.get<const Expr *>(); 1357 assert((isa<MemberExpr>(E) || tryUnwrapAllocSizeCall(E)) && 1358 "Unexpected type of invalid base"); 1359 } 1360 #endif 1361 1362 Base = B; 1363 Offset = CharUnits::fromQuantity(0); 1364 InvalidBase = BInvalid; 1365 Designator = SubobjectDesignator(getType(B)); 1366 IsNullPtr = false; 1367 } 1368 1369 void setNull(QualType PointerTy, uint64_t TargetVal) { 1370 Base = (Expr *)nullptr; 1371 Offset = CharUnits::fromQuantity(TargetVal); 1372 InvalidBase = false; 1373 Designator = SubobjectDesignator(PointerTy->getPointeeType()); 1374 IsNullPtr = true; 1375 } 1376 1377 void setInvalid(APValue::LValueBase B, unsigned I = 0) { 1378 set(B, true); 1379 } 1380 1381 // Check that this LValue is not based on a null pointer. If it is, produce 1382 // a diagnostic and mark the designator as invalid. 1383 bool checkNullPointer(EvalInfo &Info, const Expr *E, 1384 CheckSubobjectKind CSK) { 1385 if (Designator.Invalid) 1386 return false; 1387 if (IsNullPtr) { 1388 Info.CCEDiag(E, diag::note_constexpr_null_subobject) 1389 << CSK; 1390 Designator.setInvalid(); 1391 return false; 1392 } 1393 return true; 1394 } 1395 1396 // Check this LValue refers to an object. If not, set the designator to be 1397 // invalid and emit a diagnostic. 1398 bool checkSubobject(EvalInfo &Info, const Expr *E, CheckSubobjectKind CSK) { 1399 return (CSK == CSK_ArrayToPointer || checkNullPointer(Info, E, CSK)) && 1400 Designator.checkSubobject(Info, E, CSK); 1401 } 1402 1403 void addDecl(EvalInfo &Info, const Expr *E, 1404 const Decl *D, bool Virtual = false) { 1405 if (checkSubobject(Info, E, isa<FieldDecl>(D) ? CSK_Field : CSK_Base)) 1406 Designator.addDeclUnchecked(D, Virtual); 1407 } 1408 void addUnsizedArray(EvalInfo &Info, const Expr *E, QualType ElemTy) { 1409 if (!Designator.Entries.empty()) { 1410 Info.CCEDiag(E, diag::note_constexpr_unsupported_unsized_array); 1411 Designator.setInvalid(); 1412 return; 1413 } 1414 if (checkSubobject(Info, E, CSK_ArrayToPointer)) { 1415 assert(getType(Base)->isPointerType() || getType(Base)->isArrayType()); 1416 Designator.FirstEntryIsAnUnsizedArray = true; 1417 Designator.addUnsizedArrayUnchecked(ElemTy); 1418 } 1419 } 1420 void addArray(EvalInfo &Info, const Expr *E, const ConstantArrayType *CAT) { 1421 if (checkSubobject(Info, E, CSK_ArrayToPointer)) 1422 Designator.addArrayUnchecked(CAT); 1423 } 1424 void addComplex(EvalInfo &Info, const Expr *E, QualType EltTy, bool Imag) { 1425 if (checkSubobject(Info, E, Imag ? CSK_Imag : CSK_Real)) 1426 Designator.addComplexUnchecked(EltTy, Imag); 1427 } 1428 void clearIsNullPointer() { 1429 IsNullPtr = false; 1430 } 1431 void adjustOffsetAndIndex(EvalInfo &Info, const Expr *E, 1432 const APSInt &Index, CharUnits ElementSize) { 1433 // An index of 0 has no effect. (In C, adding 0 to a null pointer is UB, 1434 // but we're not required to diagnose it and it's valid in C++.) 1435 if (!Index) 1436 return; 1437 1438 // Compute the new offset in the appropriate width, wrapping at 64 bits. 1439 // FIXME: When compiling for a 32-bit target, we should use 32-bit 1440 // offsets. 1441 uint64_t Offset64 = Offset.getQuantity(); 1442 uint64_t ElemSize64 = ElementSize.getQuantity(); 1443 uint64_t Index64 = Index.extOrTrunc(64).getZExtValue(); 1444 Offset = CharUnits::fromQuantity(Offset64 + ElemSize64 * Index64); 1445 1446 if (checkNullPointer(Info, E, CSK_ArrayIndex)) 1447 Designator.adjustIndex(Info, E, Index); 1448 clearIsNullPointer(); 1449 } 1450 void adjustOffset(CharUnits N) { 1451 Offset += N; 1452 if (N.getQuantity()) 1453 clearIsNullPointer(); 1454 } 1455 }; 1456 1457 struct MemberPtr { 1458 MemberPtr() {} 1459 explicit MemberPtr(const ValueDecl *Decl) : 1460 DeclAndIsDerivedMember(Decl, false), Path() {} 1461 1462 /// The member or (direct or indirect) field referred to by this member 1463 /// pointer, or 0 if this is a null member pointer. 1464 const ValueDecl *getDecl() const { 1465 return DeclAndIsDerivedMember.getPointer(); 1466 } 1467 /// Is this actually a member of some type derived from the relevant class? 1468 bool isDerivedMember() const { 1469 return DeclAndIsDerivedMember.getInt(); 1470 } 1471 /// Get the class which the declaration actually lives in. 1472 const CXXRecordDecl *getContainingRecord() const { 1473 return cast<CXXRecordDecl>( 1474 DeclAndIsDerivedMember.getPointer()->getDeclContext()); 1475 } 1476 1477 void moveInto(APValue &V) const { 1478 V = APValue(getDecl(), isDerivedMember(), Path); 1479 } 1480 void setFrom(const APValue &V) { 1481 assert(V.isMemberPointer()); 1482 DeclAndIsDerivedMember.setPointer(V.getMemberPointerDecl()); 1483 DeclAndIsDerivedMember.setInt(V.isMemberPointerToDerivedMember()); 1484 Path.clear(); 1485 ArrayRef<const CXXRecordDecl*> P = V.getMemberPointerPath(); 1486 Path.insert(Path.end(), P.begin(), P.end()); 1487 } 1488 1489 /// DeclAndIsDerivedMember - The member declaration, and a flag indicating 1490 /// whether the member is a member of some class derived from the class type 1491 /// of the member pointer. 1492 llvm::PointerIntPair<const ValueDecl*, 1, bool> DeclAndIsDerivedMember; 1493 /// Path - The path of base/derived classes from the member declaration's 1494 /// class (exclusive) to the class type of the member pointer (inclusive). 1495 SmallVector<const CXXRecordDecl*, 4> Path; 1496 1497 /// Perform a cast towards the class of the Decl (either up or down the 1498 /// hierarchy). 1499 bool castBack(const CXXRecordDecl *Class) { 1500 assert(!Path.empty()); 1501 const CXXRecordDecl *Expected; 1502 if (Path.size() >= 2) 1503 Expected = Path[Path.size() - 2]; 1504 else 1505 Expected = getContainingRecord(); 1506 if (Expected->getCanonicalDecl() != Class->getCanonicalDecl()) { 1507 // C++11 [expr.static.cast]p12: In a conversion from (D::*) to (B::*), 1508 // if B does not contain the original member and is not a base or 1509 // derived class of the class containing the original member, the result 1510 // of the cast is undefined. 1511 // C++11 [conv.mem]p2 does not cover this case for a cast from (B::*) to 1512 // (D::*). We consider that to be a language defect. 1513 return false; 1514 } 1515 Path.pop_back(); 1516 return true; 1517 } 1518 /// Perform a base-to-derived member pointer cast. 1519 bool castToDerived(const CXXRecordDecl *Derived) { 1520 if (!getDecl()) 1521 return true; 1522 if (!isDerivedMember()) { 1523 Path.push_back(Derived); 1524 return true; 1525 } 1526 if (!castBack(Derived)) 1527 return false; 1528 if (Path.empty()) 1529 DeclAndIsDerivedMember.setInt(false); 1530 return true; 1531 } 1532 /// Perform a derived-to-base member pointer cast. 1533 bool castToBase(const CXXRecordDecl *Base) { 1534 if (!getDecl()) 1535 return true; 1536 if (Path.empty()) 1537 DeclAndIsDerivedMember.setInt(true); 1538 if (isDerivedMember()) { 1539 Path.push_back(Base); 1540 return true; 1541 } 1542 return castBack(Base); 1543 } 1544 }; 1545 1546 /// Compare two member pointers, which are assumed to be of the same type. 1547 static bool operator==(const MemberPtr &LHS, const MemberPtr &RHS) { 1548 if (!LHS.getDecl() || !RHS.getDecl()) 1549 return !LHS.getDecl() && !RHS.getDecl(); 1550 if (LHS.getDecl()->getCanonicalDecl() != RHS.getDecl()->getCanonicalDecl()) 1551 return false; 1552 return LHS.Path == RHS.Path; 1553 } 1554 } 1555 1556 static bool Evaluate(APValue &Result, EvalInfo &Info, const Expr *E); 1557 static bool EvaluateInPlace(APValue &Result, EvalInfo &Info, 1558 const LValue &This, const Expr *E, 1559 bool AllowNonLiteralTypes = false); 1560 static bool EvaluateLValue(const Expr *E, LValue &Result, EvalInfo &Info, 1561 bool InvalidBaseOK = false); 1562 static bool EvaluatePointer(const Expr *E, LValue &Result, EvalInfo &Info, 1563 bool InvalidBaseOK = false); 1564 static bool EvaluateMemberPointer(const Expr *E, MemberPtr &Result, 1565 EvalInfo &Info); 1566 static bool EvaluateTemporary(const Expr *E, LValue &Result, EvalInfo &Info); 1567 static bool EvaluateInteger(const Expr *E, APSInt &Result, EvalInfo &Info); 1568 static bool EvaluateIntegerOrLValue(const Expr *E, APValue &Result, 1569 EvalInfo &Info); 1570 static bool EvaluateFloat(const Expr *E, APFloat &Result, EvalInfo &Info); 1571 static bool EvaluateComplex(const Expr *E, ComplexValue &Res, EvalInfo &Info); 1572 static bool EvaluateAtomic(const Expr *E, const LValue *This, APValue &Result, 1573 EvalInfo &Info); 1574 static bool EvaluateAsRValue(EvalInfo &Info, const Expr *E, APValue &Result); 1575 1576 //===----------------------------------------------------------------------===// 1577 // Misc utilities 1578 //===----------------------------------------------------------------------===// 1579 1580 /// A helper function to create a temporary and set an LValue. 1581 template <class KeyTy> 1582 static APValue &createTemporary(const KeyTy *Key, bool IsLifetimeExtended, 1583 LValue &LV, CallStackFrame &Frame) { 1584 LV.set({Key, Frame.Info.CurrentCall->Index, 1585 Frame.Info.CurrentCall->getTempVersion()}); 1586 return Frame.createTemporary(Key, IsLifetimeExtended); 1587 } 1588 1589 /// Negate an APSInt in place, converting it to a signed form if necessary, and 1590 /// preserving its value (by extending by up to one bit as needed). 1591 static void negateAsSigned(APSInt &Int) { 1592 if (Int.isUnsigned() || Int.isMinSignedValue()) { 1593 Int = Int.extend(Int.getBitWidth() + 1); 1594 Int.setIsSigned(true); 1595 } 1596 Int = -Int; 1597 } 1598 1599 /// Produce a string describing the given constexpr call. 1600 static void describeCall(CallStackFrame *Frame, raw_ostream &Out) { 1601 unsigned ArgIndex = 0; 1602 bool IsMemberCall = isa<CXXMethodDecl>(Frame->Callee) && 1603 !isa<CXXConstructorDecl>(Frame->Callee) && 1604 cast<CXXMethodDecl>(Frame->Callee)->isInstance(); 1605 1606 if (!IsMemberCall) 1607 Out << *Frame->Callee << '('; 1608 1609 if (Frame->This && IsMemberCall) { 1610 APValue Val; 1611 Frame->This->moveInto(Val); 1612 Val.printPretty(Out, Frame->Info.Ctx, 1613 Frame->This->Designator.MostDerivedType); 1614 // FIXME: Add parens around Val if needed. 1615 Out << "->" << *Frame->Callee << '('; 1616 IsMemberCall = false; 1617 } 1618 1619 for (FunctionDecl::param_const_iterator I = Frame->Callee->param_begin(), 1620 E = Frame->Callee->param_end(); I != E; ++I, ++ArgIndex) { 1621 if (ArgIndex > (unsigned)IsMemberCall) 1622 Out << ", "; 1623 1624 const ParmVarDecl *Param = *I; 1625 const APValue &Arg = Frame->Arguments[ArgIndex]; 1626 Arg.printPretty(Out, Frame->Info.Ctx, Param->getType()); 1627 1628 if (ArgIndex == 0 && IsMemberCall) 1629 Out << "->" << *Frame->Callee << '('; 1630 } 1631 1632 Out << ')'; 1633 } 1634 1635 /// Evaluate an expression to see if it had side-effects, and discard its 1636 /// result. 1637 /// \return \c true if the caller should keep evaluating. 1638 static bool EvaluateIgnoredValue(EvalInfo &Info, const Expr *E) { 1639 APValue Scratch; 1640 if (!Evaluate(Scratch, Info, E)) 1641 // We don't need the value, but we might have skipped a side effect here. 1642 return Info.noteSideEffect(); 1643 return true; 1644 } 1645 1646 /// Should this call expression be treated as a string literal? 1647 static bool IsStringLiteralCall(const CallExpr *E) { 1648 unsigned Builtin = E->getBuiltinCallee(); 1649 return (Builtin == Builtin::BI__builtin___CFStringMakeConstantString || 1650 Builtin == Builtin::BI__builtin___NSStringMakeConstantString); 1651 } 1652 1653 static bool IsGlobalLValue(APValue::LValueBase B) { 1654 // C++11 [expr.const]p3 An address constant expression is a prvalue core 1655 // constant expression of pointer type that evaluates to... 1656 1657 // ... a null pointer value, or a prvalue core constant expression of type 1658 // std::nullptr_t. 1659 if (!B) return true; 1660 1661 if (const ValueDecl *D = B.dyn_cast<const ValueDecl*>()) { 1662 // ... the address of an object with static storage duration, 1663 if (const VarDecl *VD = dyn_cast<VarDecl>(D)) 1664 return VD->hasGlobalStorage(); 1665 // ... the address of a function, 1666 return isa<FunctionDecl>(D); 1667 } 1668 1669 const Expr *E = B.get<const Expr*>(); 1670 switch (E->getStmtClass()) { 1671 default: 1672 return false; 1673 case Expr::CompoundLiteralExprClass: { 1674 const CompoundLiteralExpr *CLE = cast<CompoundLiteralExpr>(E); 1675 return CLE->isFileScope() && CLE->isLValue(); 1676 } 1677 case Expr::MaterializeTemporaryExprClass: 1678 // A materialized temporary might have been lifetime-extended to static 1679 // storage duration. 1680 return cast<MaterializeTemporaryExpr>(E)->getStorageDuration() == SD_Static; 1681 // A string literal has static storage duration. 1682 case Expr::StringLiteralClass: 1683 case Expr::PredefinedExprClass: 1684 case Expr::ObjCStringLiteralClass: 1685 case Expr::ObjCEncodeExprClass: 1686 case Expr::CXXTypeidExprClass: 1687 case Expr::CXXUuidofExprClass: 1688 return true; 1689 case Expr::CallExprClass: 1690 return IsStringLiteralCall(cast<CallExpr>(E)); 1691 // For GCC compatibility, &&label has static storage duration. 1692 case Expr::AddrLabelExprClass: 1693 return true; 1694 // A Block literal expression may be used as the initialization value for 1695 // Block variables at global or local static scope. 1696 case Expr::BlockExprClass: 1697 return !cast<BlockExpr>(E)->getBlockDecl()->hasCaptures(); 1698 case Expr::ImplicitValueInitExprClass: 1699 // FIXME: 1700 // We can never form an lvalue with an implicit value initialization as its 1701 // base through expression evaluation, so these only appear in one case: the 1702 // implicit variable declaration we invent when checking whether a constexpr 1703 // constructor can produce a constant expression. We must assume that such 1704 // an expression might be a global lvalue. 1705 return true; 1706 } 1707 } 1708 1709 static void NoteLValueLocation(EvalInfo &Info, APValue::LValueBase Base) { 1710 assert(Base && "no location for a null lvalue"); 1711 const ValueDecl *VD = Base.dyn_cast<const ValueDecl*>(); 1712 if (VD) 1713 Info.Note(VD->getLocation(), diag::note_declared_at); 1714 else 1715 Info.Note(Base.get<const Expr*>()->getExprLoc(), 1716 diag::note_constexpr_temporary_here); 1717 } 1718 1719 /// Check that this reference or pointer core constant expression is a valid 1720 /// value for an address or reference constant expression. Return true if we 1721 /// can fold this expression, whether or not it's a constant expression. 1722 static bool CheckLValueConstantExpression(EvalInfo &Info, SourceLocation Loc, 1723 QualType Type, const LValue &LVal, 1724 Expr::ConstExprUsage Usage) { 1725 bool IsReferenceType = Type->isReferenceType(); 1726 1727 APValue::LValueBase Base = LVal.getLValueBase(); 1728 const SubobjectDesignator &Designator = LVal.getLValueDesignator(); 1729 1730 // Check that the object is a global. Note that the fake 'this' object we 1731 // manufacture when checking potential constant expressions is conservatively 1732 // assumed to be global here. 1733 if (!IsGlobalLValue(Base)) { 1734 if (Info.getLangOpts().CPlusPlus11) { 1735 const ValueDecl *VD = Base.dyn_cast<const ValueDecl*>(); 1736 Info.FFDiag(Loc, diag::note_constexpr_non_global, 1) 1737 << IsReferenceType << !Designator.Entries.empty() 1738 << !!VD << VD; 1739 NoteLValueLocation(Info, Base); 1740 } else { 1741 Info.FFDiag(Loc); 1742 } 1743 // Don't allow references to temporaries to escape. 1744 return false; 1745 } 1746 assert((Info.checkingPotentialConstantExpression() || 1747 LVal.getLValueCallIndex() == 0) && 1748 "have call index for global lvalue"); 1749 1750 if (const ValueDecl *VD = Base.dyn_cast<const ValueDecl*>()) { 1751 if (const VarDecl *Var = dyn_cast<const VarDecl>(VD)) { 1752 // Check if this is a thread-local variable. 1753 if (Var->getTLSKind()) 1754 return false; 1755 1756 // A dllimport variable never acts like a constant. 1757 if (Usage == Expr::EvaluateForCodeGen && Var->hasAttr<DLLImportAttr>()) 1758 return false; 1759 } 1760 if (const auto *FD = dyn_cast<const FunctionDecl>(VD)) { 1761 // __declspec(dllimport) must be handled very carefully: 1762 // We must never initialize an expression with the thunk in C++. 1763 // Doing otherwise would allow the same id-expression to yield 1764 // different addresses for the same function in different translation 1765 // units. However, this means that we must dynamically initialize the 1766 // expression with the contents of the import address table at runtime. 1767 // 1768 // The C language has no notion of ODR; furthermore, it has no notion of 1769 // dynamic initialization. This means that we are permitted to 1770 // perform initialization with the address of the thunk. 1771 if (Info.getLangOpts().CPlusPlus && Usage == Expr::EvaluateForCodeGen && 1772 FD->hasAttr<DLLImportAttr>()) 1773 return false; 1774 } 1775 } 1776 1777 // Allow address constant expressions to be past-the-end pointers. This is 1778 // an extension: the standard requires them to point to an object. 1779 if (!IsReferenceType) 1780 return true; 1781 1782 // A reference constant expression must refer to an object. 1783 if (!Base) { 1784 // FIXME: diagnostic 1785 Info.CCEDiag(Loc); 1786 return true; 1787 } 1788 1789 // Does this refer one past the end of some object? 1790 if (!Designator.Invalid && Designator.isOnePastTheEnd()) { 1791 const ValueDecl *VD = Base.dyn_cast<const ValueDecl*>(); 1792 Info.FFDiag(Loc, diag::note_constexpr_past_end, 1) 1793 << !Designator.Entries.empty() << !!VD << VD; 1794 NoteLValueLocation(Info, Base); 1795 } 1796 1797 return true; 1798 } 1799 1800 /// Member pointers are constant expressions unless they point to a 1801 /// non-virtual dllimport member function. 1802 static bool CheckMemberPointerConstantExpression(EvalInfo &Info, 1803 SourceLocation Loc, 1804 QualType Type, 1805 const APValue &Value, 1806 Expr::ConstExprUsage Usage) { 1807 const ValueDecl *Member = Value.getMemberPointerDecl(); 1808 const auto *FD = dyn_cast_or_null<CXXMethodDecl>(Member); 1809 if (!FD) 1810 return true; 1811 return Usage == Expr::EvaluateForMangling || FD->isVirtual() || 1812 !FD->hasAttr<DLLImportAttr>(); 1813 } 1814 1815 /// Check that this core constant expression is of literal type, and if not, 1816 /// produce an appropriate diagnostic. 1817 static bool CheckLiteralType(EvalInfo &Info, const Expr *E, 1818 const LValue *This = nullptr) { 1819 if (!E->isRValue() || E->getType()->isLiteralType(Info.Ctx)) 1820 return true; 1821 1822 // C++1y: A constant initializer for an object o [...] may also invoke 1823 // constexpr constructors for o and its subobjects even if those objects 1824 // are of non-literal class types. 1825 // 1826 // C++11 missed this detail for aggregates, so classes like this: 1827 // struct foo_t { union { int i; volatile int j; } u; }; 1828 // are not (obviously) initializable like so: 1829 // __attribute__((__require_constant_initialization__)) 1830 // static const foo_t x = {{0}}; 1831 // because "i" is a subobject with non-literal initialization (due to the 1832 // volatile member of the union). See: 1833 // http://www.open-std.org/jtc1/sc22/wg21/docs/cwg_active.html#1677 1834 // Therefore, we use the C++1y behavior. 1835 if (This && Info.EvaluatingDecl == This->getLValueBase()) 1836 return true; 1837 1838 // Prvalue constant expressions must be of literal types. 1839 if (Info.getLangOpts().CPlusPlus11) 1840 Info.FFDiag(E, diag::note_constexpr_nonliteral) 1841 << E->getType(); 1842 else 1843 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 1844 return false; 1845 } 1846 1847 /// Check that this core constant expression value is a valid value for a 1848 /// constant expression. If not, report an appropriate diagnostic. Does not 1849 /// check that the expression is of literal type. 1850 static bool 1851 CheckConstantExpression(EvalInfo &Info, SourceLocation DiagLoc, QualType Type, 1852 const APValue &Value, 1853 Expr::ConstExprUsage Usage = Expr::EvaluateForCodeGen) { 1854 if (Value.isUninit()) { 1855 Info.FFDiag(DiagLoc, diag::note_constexpr_uninitialized) 1856 << true << Type; 1857 return false; 1858 } 1859 1860 // We allow _Atomic(T) to be initialized from anything that T can be 1861 // initialized from. 1862 if (const AtomicType *AT = Type->getAs<AtomicType>()) 1863 Type = AT->getValueType(); 1864 1865 // Core issue 1454: For a literal constant expression of array or class type, 1866 // each subobject of its value shall have been initialized by a constant 1867 // expression. 1868 if (Value.isArray()) { 1869 QualType EltTy = Type->castAsArrayTypeUnsafe()->getElementType(); 1870 for (unsigned I = 0, N = Value.getArrayInitializedElts(); I != N; ++I) { 1871 if (!CheckConstantExpression(Info, DiagLoc, EltTy, 1872 Value.getArrayInitializedElt(I), Usage)) 1873 return false; 1874 } 1875 if (!Value.hasArrayFiller()) 1876 return true; 1877 return CheckConstantExpression(Info, DiagLoc, EltTy, Value.getArrayFiller(), 1878 Usage); 1879 } 1880 if (Value.isUnion() && Value.getUnionField()) { 1881 return CheckConstantExpression(Info, DiagLoc, 1882 Value.getUnionField()->getType(), 1883 Value.getUnionValue(), Usage); 1884 } 1885 if (Value.isStruct()) { 1886 RecordDecl *RD = Type->castAs<RecordType>()->getDecl(); 1887 if (const CXXRecordDecl *CD = dyn_cast<CXXRecordDecl>(RD)) { 1888 unsigned BaseIndex = 0; 1889 for (const CXXBaseSpecifier &BS : CD->bases()) { 1890 if (!CheckConstantExpression(Info, DiagLoc, BS.getType(), 1891 Value.getStructBase(BaseIndex), Usage)) 1892 return false; 1893 ++BaseIndex; 1894 } 1895 } 1896 for (const auto *I : RD->fields()) { 1897 if (I->isUnnamedBitfield()) 1898 continue; 1899 1900 if (!CheckConstantExpression(Info, DiagLoc, I->getType(), 1901 Value.getStructField(I->getFieldIndex()), 1902 Usage)) 1903 return false; 1904 } 1905 } 1906 1907 if (Value.isLValue()) { 1908 LValue LVal; 1909 LVal.setFrom(Info.Ctx, Value); 1910 return CheckLValueConstantExpression(Info, DiagLoc, Type, LVal, Usage); 1911 } 1912 1913 if (Value.isMemberPointer()) 1914 return CheckMemberPointerConstantExpression(Info, DiagLoc, Type, Value, Usage); 1915 1916 // Everything else is fine. 1917 return true; 1918 } 1919 1920 static const ValueDecl *GetLValueBaseDecl(const LValue &LVal) { 1921 return LVal.Base.dyn_cast<const ValueDecl*>(); 1922 } 1923 1924 static bool IsLiteralLValue(const LValue &Value) { 1925 if (Value.getLValueCallIndex()) 1926 return false; 1927 const Expr *E = Value.Base.dyn_cast<const Expr*>(); 1928 return E && !isa<MaterializeTemporaryExpr>(E); 1929 } 1930 1931 static bool IsWeakLValue(const LValue &Value) { 1932 const ValueDecl *Decl = GetLValueBaseDecl(Value); 1933 return Decl && Decl->isWeak(); 1934 } 1935 1936 static bool isZeroSized(const LValue &Value) { 1937 const ValueDecl *Decl = GetLValueBaseDecl(Value); 1938 if (Decl && isa<VarDecl>(Decl)) { 1939 QualType Ty = Decl->getType(); 1940 if (Ty->isArrayType()) 1941 return Ty->isIncompleteType() || 1942 Decl->getASTContext().getTypeSize(Ty) == 0; 1943 } 1944 return false; 1945 } 1946 1947 static bool EvalPointerValueAsBool(const APValue &Value, bool &Result) { 1948 // A null base expression indicates a null pointer. These are always 1949 // evaluatable, and they are false unless the offset is zero. 1950 if (!Value.getLValueBase()) { 1951 Result = !Value.getLValueOffset().isZero(); 1952 return true; 1953 } 1954 1955 // We have a non-null base. These are generally known to be true, but if it's 1956 // a weak declaration it can be null at runtime. 1957 Result = true; 1958 const ValueDecl *Decl = Value.getLValueBase().dyn_cast<const ValueDecl*>(); 1959 return !Decl || !Decl->isWeak(); 1960 } 1961 1962 static bool HandleConversionToBool(const APValue &Val, bool &Result) { 1963 switch (Val.getKind()) { 1964 case APValue::Uninitialized: 1965 return false; 1966 case APValue::Int: 1967 Result = Val.getInt().getBoolValue(); 1968 return true; 1969 case APValue::Float: 1970 Result = !Val.getFloat().isZero(); 1971 return true; 1972 case APValue::ComplexInt: 1973 Result = Val.getComplexIntReal().getBoolValue() || 1974 Val.getComplexIntImag().getBoolValue(); 1975 return true; 1976 case APValue::ComplexFloat: 1977 Result = !Val.getComplexFloatReal().isZero() || 1978 !Val.getComplexFloatImag().isZero(); 1979 return true; 1980 case APValue::LValue: 1981 return EvalPointerValueAsBool(Val, Result); 1982 case APValue::MemberPointer: 1983 Result = Val.getMemberPointerDecl(); 1984 return true; 1985 case APValue::Vector: 1986 case APValue::Array: 1987 case APValue::Struct: 1988 case APValue::Union: 1989 case APValue::AddrLabelDiff: 1990 return false; 1991 } 1992 1993 llvm_unreachable("unknown APValue kind"); 1994 } 1995 1996 static bool EvaluateAsBooleanCondition(const Expr *E, bool &Result, 1997 EvalInfo &Info) { 1998 assert(E->isRValue() && "missing lvalue-to-rvalue conv in bool condition"); 1999 APValue Val; 2000 if (!Evaluate(Val, Info, E)) 2001 return false; 2002 return HandleConversionToBool(Val, Result); 2003 } 2004 2005 template<typename T> 2006 static bool HandleOverflow(EvalInfo &Info, const Expr *E, 2007 const T &SrcValue, QualType DestType) { 2008 Info.CCEDiag(E, diag::note_constexpr_overflow) 2009 << SrcValue << DestType; 2010 return Info.noteUndefinedBehavior(); 2011 } 2012 2013 static bool HandleFloatToIntCast(EvalInfo &Info, const Expr *E, 2014 QualType SrcType, const APFloat &Value, 2015 QualType DestType, APSInt &Result) { 2016 unsigned DestWidth = Info.Ctx.getIntWidth(DestType); 2017 // Determine whether we are converting to unsigned or signed. 2018 bool DestSigned = DestType->isSignedIntegerOrEnumerationType(); 2019 2020 Result = APSInt(DestWidth, !DestSigned); 2021 bool ignored; 2022 if (Value.convertToInteger(Result, llvm::APFloat::rmTowardZero, &ignored) 2023 & APFloat::opInvalidOp) 2024 return HandleOverflow(Info, E, Value, DestType); 2025 return true; 2026 } 2027 2028 static bool HandleFloatToFloatCast(EvalInfo &Info, const Expr *E, 2029 QualType SrcType, QualType DestType, 2030 APFloat &Result) { 2031 APFloat Value = Result; 2032 bool ignored; 2033 if (Result.convert(Info.Ctx.getFloatTypeSemantics(DestType), 2034 APFloat::rmNearestTiesToEven, &ignored) 2035 & APFloat::opOverflow) 2036 return HandleOverflow(Info, E, Value, DestType); 2037 return true; 2038 } 2039 2040 static APSInt HandleIntToIntCast(EvalInfo &Info, const Expr *E, 2041 QualType DestType, QualType SrcType, 2042 const APSInt &Value) { 2043 unsigned DestWidth = Info.Ctx.getIntWidth(DestType); 2044 APSInt Result = Value; 2045 // Figure out if this is a truncate, extend or noop cast. 2046 // If the input is signed, do a sign extend, noop, or truncate. 2047 Result = Result.extOrTrunc(DestWidth); 2048 Result.setIsUnsigned(DestType->isUnsignedIntegerOrEnumerationType()); 2049 return Result; 2050 } 2051 2052 static bool HandleIntToFloatCast(EvalInfo &Info, const Expr *E, 2053 QualType SrcType, const APSInt &Value, 2054 QualType DestType, APFloat &Result) { 2055 Result = APFloat(Info.Ctx.getFloatTypeSemantics(DestType), 1); 2056 if (Result.convertFromAPInt(Value, Value.isSigned(), 2057 APFloat::rmNearestTiesToEven) 2058 & APFloat::opOverflow) 2059 return HandleOverflow(Info, E, Value, DestType); 2060 return true; 2061 } 2062 2063 static bool truncateBitfieldValue(EvalInfo &Info, const Expr *E, 2064 APValue &Value, const FieldDecl *FD) { 2065 assert(FD->isBitField() && "truncateBitfieldValue on non-bitfield"); 2066 2067 if (!Value.isInt()) { 2068 // Trying to store a pointer-cast-to-integer into a bitfield. 2069 // FIXME: In this case, we should provide the diagnostic for casting 2070 // a pointer to an integer. 2071 assert(Value.isLValue() && "integral value neither int nor lvalue?"); 2072 Info.FFDiag(E); 2073 return false; 2074 } 2075 2076 APSInt &Int = Value.getInt(); 2077 unsigned OldBitWidth = Int.getBitWidth(); 2078 unsigned NewBitWidth = FD->getBitWidthValue(Info.Ctx); 2079 if (NewBitWidth < OldBitWidth) 2080 Int = Int.trunc(NewBitWidth).extend(OldBitWidth); 2081 return true; 2082 } 2083 2084 static bool EvalAndBitcastToAPInt(EvalInfo &Info, const Expr *E, 2085 llvm::APInt &Res) { 2086 APValue SVal; 2087 if (!Evaluate(SVal, Info, E)) 2088 return false; 2089 if (SVal.isInt()) { 2090 Res = SVal.getInt(); 2091 return true; 2092 } 2093 if (SVal.isFloat()) { 2094 Res = SVal.getFloat().bitcastToAPInt(); 2095 return true; 2096 } 2097 if (SVal.isVector()) { 2098 QualType VecTy = E->getType(); 2099 unsigned VecSize = Info.Ctx.getTypeSize(VecTy); 2100 QualType EltTy = VecTy->castAs<VectorType>()->getElementType(); 2101 unsigned EltSize = Info.Ctx.getTypeSize(EltTy); 2102 bool BigEndian = Info.Ctx.getTargetInfo().isBigEndian(); 2103 Res = llvm::APInt::getNullValue(VecSize); 2104 for (unsigned i = 0; i < SVal.getVectorLength(); i++) { 2105 APValue &Elt = SVal.getVectorElt(i); 2106 llvm::APInt EltAsInt; 2107 if (Elt.isInt()) { 2108 EltAsInt = Elt.getInt(); 2109 } else if (Elt.isFloat()) { 2110 EltAsInt = Elt.getFloat().bitcastToAPInt(); 2111 } else { 2112 // Don't try to handle vectors of anything other than int or float 2113 // (not sure if it's possible to hit this case). 2114 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 2115 return false; 2116 } 2117 unsigned BaseEltSize = EltAsInt.getBitWidth(); 2118 if (BigEndian) 2119 Res |= EltAsInt.zextOrTrunc(VecSize).rotr(i*EltSize+BaseEltSize); 2120 else 2121 Res |= EltAsInt.zextOrTrunc(VecSize).rotl(i*EltSize); 2122 } 2123 return true; 2124 } 2125 // Give up if the input isn't an int, float, or vector. For example, we 2126 // reject "(v4i16)(intptr_t)&a". 2127 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 2128 return false; 2129 } 2130 2131 /// Perform the given integer operation, which is known to need at most BitWidth 2132 /// bits, and check for overflow in the original type (if that type was not an 2133 /// unsigned type). 2134 template<typename Operation> 2135 static bool CheckedIntArithmetic(EvalInfo &Info, const Expr *E, 2136 const APSInt &LHS, const APSInt &RHS, 2137 unsigned BitWidth, Operation Op, 2138 APSInt &Result) { 2139 if (LHS.isUnsigned()) { 2140 Result = Op(LHS, RHS); 2141 return true; 2142 } 2143 2144 APSInt Value(Op(LHS.extend(BitWidth), RHS.extend(BitWidth)), false); 2145 Result = Value.trunc(LHS.getBitWidth()); 2146 if (Result.extend(BitWidth) != Value) { 2147 if (Info.checkingForOverflow()) 2148 Info.Ctx.getDiagnostics().Report(E->getExprLoc(), 2149 diag::warn_integer_constant_overflow) 2150 << Result.toString(10) << E->getType(); 2151 else 2152 return HandleOverflow(Info, E, Value, E->getType()); 2153 } 2154 return true; 2155 } 2156 2157 /// Perform the given binary integer operation. 2158 static bool handleIntIntBinOp(EvalInfo &Info, const Expr *E, const APSInt &LHS, 2159 BinaryOperatorKind Opcode, APSInt RHS, 2160 APSInt &Result) { 2161 switch (Opcode) { 2162 default: 2163 Info.FFDiag(E); 2164 return false; 2165 case BO_Mul: 2166 return CheckedIntArithmetic(Info, E, LHS, RHS, LHS.getBitWidth() * 2, 2167 std::multiplies<APSInt>(), Result); 2168 case BO_Add: 2169 return CheckedIntArithmetic(Info, E, LHS, RHS, LHS.getBitWidth() + 1, 2170 std::plus<APSInt>(), Result); 2171 case BO_Sub: 2172 return CheckedIntArithmetic(Info, E, LHS, RHS, LHS.getBitWidth() + 1, 2173 std::minus<APSInt>(), Result); 2174 case BO_And: Result = LHS & RHS; return true; 2175 case BO_Xor: Result = LHS ^ RHS; return true; 2176 case BO_Or: Result = LHS | RHS; return true; 2177 case BO_Div: 2178 case BO_Rem: 2179 if (RHS == 0) { 2180 Info.FFDiag(E, diag::note_expr_divide_by_zero); 2181 return false; 2182 } 2183 Result = (Opcode == BO_Rem ? LHS % RHS : LHS / RHS); 2184 // Check for overflow case: INT_MIN / -1 or INT_MIN % -1. APSInt supports 2185 // this operation and gives the two's complement result. 2186 if (RHS.isNegative() && RHS.isAllOnesValue() && 2187 LHS.isSigned() && LHS.isMinSignedValue()) 2188 return HandleOverflow(Info, E, -LHS.extend(LHS.getBitWidth() + 1), 2189 E->getType()); 2190 return true; 2191 case BO_Shl: { 2192 if (Info.getLangOpts().OpenCL) 2193 // OpenCL 6.3j: shift values are effectively % word size of LHS. 2194 RHS &= APSInt(llvm::APInt(RHS.getBitWidth(), 2195 static_cast<uint64_t>(LHS.getBitWidth() - 1)), 2196 RHS.isUnsigned()); 2197 else if (RHS.isSigned() && RHS.isNegative()) { 2198 // During constant-folding, a negative shift is an opposite shift. Such 2199 // a shift is not a constant expression. 2200 Info.CCEDiag(E, diag::note_constexpr_negative_shift) << RHS; 2201 RHS = -RHS; 2202 goto shift_right; 2203 } 2204 shift_left: 2205 // C++11 [expr.shift]p1: Shift width must be less than the bit width of 2206 // the shifted type. 2207 unsigned SA = (unsigned) RHS.getLimitedValue(LHS.getBitWidth()-1); 2208 if (SA != RHS) { 2209 Info.CCEDiag(E, diag::note_constexpr_large_shift) 2210 << RHS << E->getType() << LHS.getBitWidth(); 2211 } else if (LHS.isSigned()) { 2212 // C++11 [expr.shift]p2: A signed left shift must have a non-negative 2213 // operand, and must not overflow the corresponding unsigned type. 2214 if (LHS.isNegative()) 2215 Info.CCEDiag(E, diag::note_constexpr_lshift_of_negative) << LHS; 2216 else if (LHS.countLeadingZeros() < SA) 2217 Info.CCEDiag(E, diag::note_constexpr_lshift_discards); 2218 } 2219 Result = LHS << SA; 2220 return true; 2221 } 2222 case BO_Shr: { 2223 if (Info.getLangOpts().OpenCL) 2224 // OpenCL 6.3j: shift values are effectively % word size of LHS. 2225 RHS &= APSInt(llvm::APInt(RHS.getBitWidth(), 2226 static_cast<uint64_t>(LHS.getBitWidth() - 1)), 2227 RHS.isUnsigned()); 2228 else if (RHS.isSigned() && RHS.isNegative()) { 2229 // During constant-folding, a negative shift is an opposite shift. Such a 2230 // shift is not a constant expression. 2231 Info.CCEDiag(E, diag::note_constexpr_negative_shift) << RHS; 2232 RHS = -RHS; 2233 goto shift_left; 2234 } 2235 shift_right: 2236 // C++11 [expr.shift]p1: Shift width must be less than the bit width of the 2237 // shifted type. 2238 unsigned SA = (unsigned) RHS.getLimitedValue(LHS.getBitWidth()-1); 2239 if (SA != RHS) 2240 Info.CCEDiag(E, diag::note_constexpr_large_shift) 2241 << RHS << E->getType() << LHS.getBitWidth(); 2242 Result = LHS >> SA; 2243 return true; 2244 } 2245 2246 case BO_LT: Result = LHS < RHS; return true; 2247 case BO_GT: Result = LHS > RHS; return true; 2248 case BO_LE: Result = LHS <= RHS; return true; 2249 case BO_GE: Result = LHS >= RHS; return true; 2250 case BO_EQ: Result = LHS == RHS; return true; 2251 case BO_NE: Result = LHS != RHS; return true; 2252 case BO_Cmp: 2253 llvm_unreachable("BO_Cmp should be handled elsewhere"); 2254 } 2255 } 2256 2257 /// Perform the given binary floating-point operation, in-place, on LHS. 2258 static bool handleFloatFloatBinOp(EvalInfo &Info, const Expr *E, 2259 APFloat &LHS, BinaryOperatorKind Opcode, 2260 const APFloat &RHS) { 2261 switch (Opcode) { 2262 default: 2263 Info.FFDiag(E); 2264 return false; 2265 case BO_Mul: 2266 LHS.multiply(RHS, APFloat::rmNearestTiesToEven); 2267 break; 2268 case BO_Add: 2269 LHS.add(RHS, APFloat::rmNearestTiesToEven); 2270 break; 2271 case BO_Sub: 2272 LHS.subtract(RHS, APFloat::rmNearestTiesToEven); 2273 break; 2274 case BO_Div: 2275 LHS.divide(RHS, APFloat::rmNearestTiesToEven); 2276 break; 2277 } 2278 2279 if (LHS.isInfinity() || LHS.isNaN()) { 2280 Info.CCEDiag(E, diag::note_constexpr_float_arithmetic) << LHS.isNaN(); 2281 return Info.noteUndefinedBehavior(); 2282 } 2283 return true; 2284 } 2285 2286 /// Cast an lvalue referring to a base subobject to a derived class, by 2287 /// truncating the lvalue's path to the given length. 2288 static bool CastToDerivedClass(EvalInfo &Info, const Expr *E, LValue &Result, 2289 const RecordDecl *TruncatedType, 2290 unsigned TruncatedElements) { 2291 SubobjectDesignator &D = Result.Designator; 2292 2293 // Check we actually point to a derived class object. 2294 if (TruncatedElements == D.Entries.size()) 2295 return true; 2296 assert(TruncatedElements >= D.MostDerivedPathLength && 2297 "not casting to a derived class"); 2298 if (!Result.checkSubobject(Info, E, CSK_Derived)) 2299 return false; 2300 2301 // Truncate the path to the subobject, and remove any derived-to-base offsets. 2302 const RecordDecl *RD = TruncatedType; 2303 for (unsigned I = TruncatedElements, N = D.Entries.size(); I != N; ++I) { 2304 if (RD->isInvalidDecl()) return false; 2305 const ASTRecordLayout &Layout = Info.Ctx.getASTRecordLayout(RD); 2306 const CXXRecordDecl *Base = getAsBaseClass(D.Entries[I]); 2307 if (isVirtualBaseClass(D.Entries[I])) 2308 Result.Offset -= Layout.getVBaseClassOffset(Base); 2309 else 2310 Result.Offset -= Layout.getBaseClassOffset(Base); 2311 RD = Base; 2312 } 2313 D.Entries.resize(TruncatedElements); 2314 return true; 2315 } 2316 2317 static bool HandleLValueDirectBase(EvalInfo &Info, const Expr *E, LValue &Obj, 2318 const CXXRecordDecl *Derived, 2319 const CXXRecordDecl *Base, 2320 const ASTRecordLayout *RL = nullptr) { 2321 if (!RL) { 2322 if (Derived->isInvalidDecl()) return false; 2323 RL = &Info.Ctx.getASTRecordLayout(Derived); 2324 } 2325 2326 Obj.getLValueOffset() += RL->getBaseClassOffset(Base); 2327 Obj.addDecl(Info, E, Base, /*Virtual*/ false); 2328 return true; 2329 } 2330 2331 static bool HandleLValueBase(EvalInfo &Info, const Expr *E, LValue &Obj, 2332 const CXXRecordDecl *DerivedDecl, 2333 const CXXBaseSpecifier *Base) { 2334 const CXXRecordDecl *BaseDecl = Base->getType()->getAsCXXRecordDecl(); 2335 2336 if (!Base->isVirtual()) 2337 return HandleLValueDirectBase(Info, E, Obj, DerivedDecl, BaseDecl); 2338 2339 SubobjectDesignator &D = Obj.Designator; 2340 if (D.Invalid) 2341 return false; 2342 2343 // Extract most-derived object and corresponding type. 2344 DerivedDecl = D.MostDerivedType->getAsCXXRecordDecl(); 2345 if (!CastToDerivedClass(Info, E, Obj, DerivedDecl, D.MostDerivedPathLength)) 2346 return false; 2347 2348 // Find the virtual base class. 2349 if (DerivedDecl->isInvalidDecl()) return false; 2350 const ASTRecordLayout &Layout = Info.Ctx.getASTRecordLayout(DerivedDecl); 2351 Obj.getLValueOffset() += Layout.getVBaseClassOffset(BaseDecl); 2352 Obj.addDecl(Info, E, BaseDecl, /*Virtual*/ true); 2353 return true; 2354 } 2355 2356 static bool HandleLValueBasePath(EvalInfo &Info, const CastExpr *E, 2357 QualType Type, LValue &Result) { 2358 for (CastExpr::path_const_iterator PathI = E->path_begin(), 2359 PathE = E->path_end(); 2360 PathI != PathE; ++PathI) { 2361 if (!HandleLValueBase(Info, E, Result, Type->getAsCXXRecordDecl(), 2362 *PathI)) 2363 return false; 2364 Type = (*PathI)->getType(); 2365 } 2366 return true; 2367 } 2368 2369 /// Update LVal to refer to the given field, which must be a member of the type 2370 /// currently described by LVal. 2371 static bool HandleLValueMember(EvalInfo &Info, const Expr *E, LValue &LVal, 2372 const FieldDecl *FD, 2373 const ASTRecordLayout *RL = nullptr) { 2374 if (!RL) { 2375 if (FD->getParent()->isInvalidDecl()) return false; 2376 RL = &Info.Ctx.getASTRecordLayout(FD->getParent()); 2377 } 2378 2379 unsigned I = FD->getFieldIndex(); 2380 LVal.adjustOffset(Info.Ctx.toCharUnitsFromBits(RL->getFieldOffset(I))); 2381 LVal.addDecl(Info, E, FD); 2382 return true; 2383 } 2384 2385 /// Update LVal to refer to the given indirect field. 2386 static bool HandleLValueIndirectMember(EvalInfo &Info, const Expr *E, 2387 LValue &LVal, 2388 const IndirectFieldDecl *IFD) { 2389 for (const auto *C : IFD->chain()) 2390 if (!HandleLValueMember(Info, E, LVal, cast<FieldDecl>(C))) 2391 return false; 2392 return true; 2393 } 2394 2395 /// Get the size of the given type in char units. 2396 static bool HandleSizeof(EvalInfo &Info, SourceLocation Loc, 2397 QualType Type, CharUnits &Size) { 2398 // sizeof(void), __alignof__(void), sizeof(function) = 1 as a gcc 2399 // extension. 2400 if (Type->isVoidType() || Type->isFunctionType()) { 2401 Size = CharUnits::One(); 2402 return true; 2403 } 2404 2405 if (Type->isDependentType()) { 2406 Info.FFDiag(Loc); 2407 return false; 2408 } 2409 2410 if (!Type->isConstantSizeType()) { 2411 // sizeof(vla) is not a constantexpr: C99 6.5.3.4p2. 2412 // FIXME: Better diagnostic. 2413 Info.FFDiag(Loc); 2414 return false; 2415 } 2416 2417 Size = Info.Ctx.getTypeSizeInChars(Type); 2418 return true; 2419 } 2420 2421 /// Update a pointer value to model pointer arithmetic. 2422 /// \param Info - Information about the ongoing evaluation. 2423 /// \param E - The expression being evaluated, for diagnostic purposes. 2424 /// \param LVal - The pointer value to be updated. 2425 /// \param EltTy - The pointee type represented by LVal. 2426 /// \param Adjustment - The adjustment, in objects of type EltTy, to add. 2427 static bool HandleLValueArrayAdjustment(EvalInfo &Info, const Expr *E, 2428 LValue &LVal, QualType EltTy, 2429 APSInt Adjustment) { 2430 CharUnits SizeOfPointee; 2431 if (!HandleSizeof(Info, E->getExprLoc(), EltTy, SizeOfPointee)) 2432 return false; 2433 2434 LVal.adjustOffsetAndIndex(Info, E, Adjustment, SizeOfPointee); 2435 return true; 2436 } 2437 2438 static bool HandleLValueArrayAdjustment(EvalInfo &Info, const Expr *E, 2439 LValue &LVal, QualType EltTy, 2440 int64_t Adjustment) { 2441 return HandleLValueArrayAdjustment(Info, E, LVal, EltTy, 2442 APSInt::get(Adjustment)); 2443 } 2444 2445 /// Update an lvalue to refer to a component of a complex number. 2446 /// \param Info - Information about the ongoing evaluation. 2447 /// \param LVal - The lvalue to be updated. 2448 /// \param EltTy - The complex number's component type. 2449 /// \param Imag - False for the real component, true for the imaginary. 2450 static bool HandleLValueComplexElement(EvalInfo &Info, const Expr *E, 2451 LValue &LVal, QualType EltTy, 2452 bool Imag) { 2453 if (Imag) { 2454 CharUnits SizeOfComponent; 2455 if (!HandleSizeof(Info, E->getExprLoc(), EltTy, SizeOfComponent)) 2456 return false; 2457 LVal.Offset += SizeOfComponent; 2458 } 2459 LVal.addComplex(Info, E, EltTy, Imag); 2460 return true; 2461 } 2462 2463 static bool handleLValueToRValueConversion(EvalInfo &Info, const Expr *Conv, 2464 QualType Type, const LValue &LVal, 2465 APValue &RVal); 2466 2467 /// Try to evaluate the initializer for a variable declaration. 2468 /// 2469 /// \param Info Information about the ongoing evaluation. 2470 /// \param E An expression to be used when printing diagnostics. 2471 /// \param VD The variable whose initializer should be obtained. 2472 /// \param Frame The frame in which the variable was created. Must be null 2473 /// if this variable is not local to the evaluation. 2474 /// \param Result Filled in with a pointer to the value of the variable. 2475 static bool evaluateVarDeclInit(EvalInfo &Info, const Expr *E, 2476 const VarDecl *VD, CallStackFrame *Frame, 2477 APValue *&Result, const LValue *LVal) { 2478 2479 // If this is a parameter to an active constexpr function call, perform 2480 // argument substitution. 2481 if (const ParmVarDecl *PVD = dyn_cast<ParmVarDecl>(VD)) { 2482 // Assume arguments of a potential constant expression are unknown 2483 // constant expressions. 2484 if (Info.checkingPotentialConstantExpression()) 2485 return false; 2486 if (!Frame || !Frame->Arguments) { 2487 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 2488 return false; 2489 } 2490 Result = &Frame->Arguments[PVD->getFunctionScopeIndex()]; 2491 return true; 2492 } 2493 2494 // If this is a local variable, dig out its value. 2495 if (Frame) { 2496 Result = LVal ? Frame->getTemporary(VD, LVal->getLValueVersion()) 2497 : Frame->getCurrentTemporary(VD); 2498 if (!Result) { 2499 // Assume variables referenced within a lambda's call operator that were 2500 // not declared within the call operator are captures and during checking 2501 // of a potential constant expression, assume they are unknown constant 2502 // expressions. 2503 assert(isLambdaCallOperator(Frame->Callee) && 2504 (VD->getDeclContext() != Frame->Callee || VD->isInitCapture()) && 2505 "missing value for local variable"); 2506 if (Info.checkingPotentialConstantExpression()) 2507 return false; 2508 // FIXME: implement capture evaluation during constant expr evaluation. 2509 Info.FFDiag(E->getLocStart(), 2510 diag::note_unimplemented_constexpr_lambda_feature_ast) 2511 << "captures not currently allowed"; 2512 return false; 2513 } 2514 return true; 2515 } 2516 2517 // Dig out the initializer, and use the declaration which it's attached to. 2518 const Expr *Init = VD->getAnyInitializer(VD); 2519 if (!Init || Init->isValueDependent()) { 2520 // If we're checking a potential constant expression, the variable could be 2521 // initialized later. 2522 if (!Info.checkingPotentialConstantExpression()) 2523 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 2524 return false; 2525 } 2526 2527 // If we're currently evaluating the initializer of this declaration, use that 2528 // in-flight value. 2529 if (Info.EvaluatingDecl.dyn_cast<const ValueDecl*>() == VD) { 2530 Result = Info.EvaluatingDeclValue; 2531 return true; 2532 } 2533 2534 // Never evaluate the initializer of a weak variable. We can't be sure that 2535 // this is the definition which will be used. 2536 if (VD->isWeak()) { 2537 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 2538 return false; 2539 } 2540 2541 // Check that we can fold the initializer. In C++, we will have already done 2542 // this in the cases where it matters for conformance. 2543 SmallVector<PartialDiagnosticAt, 8> Notes; 2544 if (!VD->evaluateValue(Notes)) { 2545 Info.FFDiag(E, diag::note_constexpr_var_init_non_constant, 2546 Notes.size() + 1) << VD; 2547 Info.Note(VD->getLocation(), diag::note_declared_at); 2548 Info.addNotes(Notes); 2549 return false; 2550 } else if (!VD->checkInitIsICE()) { 2551 Info.CCEDiag(E, diag::note_constexpr_var_init_non_constant, 2552 Notes.size() + 1) << VD; 2553 Info.Note(VD->getLocation(), diag::note_declared_at); 2554 Info.addNotes(Notes); 2555 } 2556 2557 Result = VD->getEvaluatedValue(); 2558 return true; 2559 } 2560 2561 static bool IsConstNonVolatile(QualType T) { 2562 Qualifiers Quals = T.getQualifiers(); 2563 return Quals.hasConst() && !Quals.hasVolatile(); 2564 } 2565 2566 /// Get the base index of the given base class within an APValue representing 2567 /// the given derived class. 2568 static unsigned getBaseIndex(const CXXRecordDecl *Derived, 2569 const CXXRecordDecl *Base) { 2570 Base = Base->getCanonicalDecl(); 2571 unsigned Index = 0; 2572 for (CXXRecordDecl::base_class_const_iterator I = Derived->bases_begin(), 2573 E = Derived->bases_end(); I != E; ++I, ++Index) { 2574 if (I->getType()->getAsCXXRecordDecl()->getCanonicalDecl() == Base) 2575 return Index; 2576 } 2577 2578 llvm_unreachable("base class missing from derived class's bases list"); 2579 } 2580 2581 /// Extract the value of a character from a string literal. 2582 static APSInt extractStringLiteralCharacter(EvalInfo &Info, const Expr *Lit, 2583 uint64_t Index) { 2584 // FIXME: Support MakeStringConstant 2585 if (const auto *ObjCEnc = dyn_cast<ObjCEncodeExpr>(Lit)) { 2586 std::string Str; 2587 Info.Ctx.getObjCEncodingForType(ObjCEnc->getEncodedType(), Str); 2588 assert(Index <= Str.size() && "Index too large"); 2589 return APSInt::getUnsigned(Str.c_str()[Index]); 2590 } 2591 2592 if (auto PE = dyn_cast<PredefinedExpr>(Lit)) 2593 Lit = PE->getFunctionName(); 2594 const StringLiteral *S = cast<StringLiteral>(Lit); 2595 const ConstantArrayType *CAT = 2596 Info.Ctx.getAsConstantArrayType(S->getType()); 2597 assert(CAT && "string literal isn't an array"); 2598 QualType CharType = CAT->getElementType(); 2599 assert(CharType->isIntegerType() && "unexpected character type"); 2600 2601 APSInt Value(S->getCharByteWidth() * Info.Ctx.getCharWidth(), 2602 CharType->isUnsignedIntegerType()); 2603 if (Index < S->getLength()) 2604 Value = S->getCodeUnit(Index); 2605 return Value; 2606 } 2607 2608 // Expand a string literal into an array of characters. 2609 static void expandStringLiteral(EvalInfo &Info, const Expr *Lit, 2610 APValue &Result) { 2611 const StringLiteral *S = cast<StringLiteral>(Lit); 2612 const ConstantArrayType *CAT = 2613 Info.Ctx.getAsConstantArrayType(S->getType()); 2614 assert(CAT && "string literal isn't an array"); 2615 QualType CharType = CAT->getElementType(); 2616 assert(CharType->isIntegerType() && "unexpected character type"); 2617 2618 unsigned Elts = CAT->getSize().getZExtValue(); 2619 Result = APValue(APValue::UninitArray(), 2620 std::min(S->getLength(), Elts), Elts); 2621 APSInt Value(S->getCharByteWidth() * Info.Ctx.getCharWidth(), 2622 CharType->isUnsignedIntegerType()); 2623 if (Result.hasArrayFiller()) 2624 Result.getArrayFiller() = APValue(Value); 2625 for (unsigned I = 0, N = Result.getArrayInitializedElts(); I != N; ++I) { 2626 Value = S->getCodeUnit(I); 2627 Result.getArrayInitializedElt(I) = APValue(Value); 2628 } 2629 } 2630 2631 // Expand an array so that it has more than Index filled elements. 2632 static void expandArray(APValue &Array, unsigned Index) { 2633 unsigned Size = Array.getArraySize(); 2634 assert(Index < Size); 2635 2636 // Always at least double the number of elements for which we store a value. 2637 unsigned OldElts = Array.getArrayInitializedElts(); 2638 unsigned NewElts = std::max(Index+1, OldElts * 2); 2639 NewElts = std::min(Size, std::max(NewElts, 8u)); 2640 2641 // Copy the data across. 2642 APValue NewValue(APValue::UninitArray(), NewElts, Size); 2643 for (unsigned I = 0; I != OldElts; ++I) 2644 NewValue.getArrayInitializedElt(I).swap(Array.getArrayInitializedElt(I)); 2645 for (unsigned I = OldElts; I != NewElts; ++I) 2646 NewValue.getArrayInitializedElt(I) = Array.getArrayFiller(); 2647 if (NewValue.hasArrayFiller()) 2648 NewValue.getArrayFiller() = Array.getArrayFiller(); 2649 Array.swap(NewValue); 2650 } 2651 2652 /// Determine whether a type would actually be read by an lvalue-to-rvalue 2653 /// conversion. If it's of class type, we may assume that the copy operation 2654 /// is trivial. Note that this is never true for a union type with fields 2655 /// (because the copy always "reads" the active member) and always true for 2656 /// a non-class type. 2657 static bool isReadByLvalueToRvalueConversion(QualType T) { 2658 CXXRecordDecl *RD = T->getBaseElementTypeUnsafe()->getAsCXXRecordDecl(); 2659 if (!RD || (RD->isUnion() && !RD->field_empty())) 2660 return true; 2661 if (RD->isEmpty()) 2662 return false; 2663 2664 for (auto *Field : RD->fields()) 2665 if (isReadByLvalueToRvalueConversion(Field->getType())) 2666 return true; 2667 2668 for (auto &BaseSpec : RD->bases()) 2669 if (isReadByLvalueToRvalueConversion(BaseSpec.getType())) 2670 return true; 2671 2672 return false; 2673 } 2674 2675 /// Diagnose an attempt to read from any unreadable field within the specified 2676 /// type, which might be a class type. 2677 static bool diagnoseUnreadableFields(EvalInfo &Info, const Expr *E, 2678 QualType T) { 2679 CXXRecordDecl *RD = T->getBaseElementTypeUnsafe()->getAsCXXRecordDecl(); 2680 if (!RD) 2681 return false; 2682 2683 if (!RD->hasMutableFields()) 2684 return false; 2685 2686 for (auto *Field : RD->fields()) { 2687 // If we're actually going to read this field in some way, then it can't 2688 // be mutable. If we're in a union, then assigning to a mutable field 2689 // (even an empty one) can change the active member, so that's not OK. 2690 // FIXME: Add core issue number for the union case. 2691 if (Field->isMutable() && 2692 (RD->isUnion() || isReadByLvalueToRvalueConversion(Field->getType()))) { 2693 Info.FFDiag(E, diag::note_constexpr_ltor_mutable, 1) << Field; 2694 Info.Note(Field->getLocation(), diag::note_declared_at); 2695 return true; 2696 } 2697 2698 if (diagnoseUnreadableFields(Info, E, Field->getType())) 2699 return true; 2700 } 2701 2702 for (auto &BaseSpec : RD->bases()) 2703 if (diagnoseUnreadableFields(Info, E, BaseSpec.getType())) 2704 return true; 2705 2706 // All mutable fields were empty, and thus not actually read. 2707 return false; 2708 } 2709 2710 /// Kinds of access we can perform on an object, for diagnostics. 2711 enum AccessKinds { 2712 AK_Read, 2713 AK_Assign, 2714 AK_Increment, 2715 AK_Decrement 2716 }; 2717 2718 namespace { 2719 /// A handle to a complete object (an object that is not a subobject of 2720 /// another object). 2721 struct CompleteObject { 2722 /// The value of the complete object. 2723 APValue *Value; 2724 /// The type of the complete object. 2725 QualType Type; 2726 bool LifetimeStartedInEvaluation; 2727 2728 CompleteObject() : Value(nullptr) {} 2729 CompleteObject(APValue *Value, QualType Type, 2730 bool LifetimeStartedInEvaluation) 2731 : Value(Value), Type(Type), 2732 LifetimeStartedInEvaluation(LifetimeStartedInEvaluation) { 2733 assert(Value && "missing value for complete object"); 2734 } 2735 2736 explicit operator bool() const { return Value; } 2737 }; 2738 } // end anonymous namespace 2739 2740 /// Find the designated sub-object of an rvalue. 2741 template<typename SubobjectHandler> 2742 typename SubobjectHandler::result_type 2743 findSubobject(EvalInfo &Info, const Expr *E, const CompleteObject &Obj, 2744 const SubobjectDesignator &Sub, SubobjectHandler &handler) { 2745 if (Sub.Invalid) 2746 // A diagnostic will have already been produced. 2747 return handler.failed(); 2748 if (Sub.isOnePastTheEnd() || Sub.isMostDerivedAnUnsizedArray()) { 2749 if (Info.getLangOpts().CPlusPlus11) 2750 Info.FFDiag(E, Sub.isOnePastTheEnd() 2751 ? diag::note_constexpr_access_past_end 2752 : diag::note_constexpr_access_unsized_array) 2753 << handler.AccessKind; 2754 else 2755 Info.FFDiag(E); 2756 return handler.failed(); 2757 } 2758 2759 APValue *O = Obj.Value; 2760 QualType ObjType = Obj.Type; 2761 const FieldDecl *LastField = nullptr; 2762 const bool MayReadMutableMembers = 2763 Obj.LifetimeStartedInEvaluation && Info.getLangOpts().CPlusPlus14; 2764 2765 // Walk the designator's path to find the subobject. 2766 for (unsigned I = 0, N = Sub.Entries.size(); /**/; ++I) { 2767 if (O->isUninit()) { 2768 if (!Info.checkingPotentialConstantExpression()) 2769 Info.FFDiag(E, diag::note_constexpr_access_uninit) << handler.AccessKind; 2770 return handler.failed(); 2771 } 2772 2773 if (I == N) { 2774 // If we are reading an object of class type, there may still be more 2775 // things we need to check: if there are any mutable subobjects, we 2776 // cannot perform this read. (This only happens when performing a trivial 2777 // copy or assignment.) 2778 if (ObjType->isRecordType() && handler.AccessKind == AK_Read && 2779 !MayReadMutableMembers && diagnoseUnreadableFields(Info, E, ObjType)) 2780 return handler.failed(); 2781 2782 if (!handler.found(*O, ObjType)) 2783 return false; 2784 2785 // If we modified a bit-field, truncate it to the right width. 2786 if (handler.AccessKind != AK_Read && 2787 LastField && LastField->isBitField() && 2788 !truncateBitfieldValue(Info, E, *O, LastField)) 2789 return false; 2790 2791 return true; 2792 } 2793 2794 LastField = nullptr; 2795 if (ObjType->isArrayType()) { 2796 // Next subobject is an array element. 2797 const ConstantArrayType *CAT = Info.Ctx.getAsConstantArrayType(ObjType); 2798 assert(CAT && "vla in literal type?"); 2799 uint64_t Index = Sub.Entries[I].ArrayIndex; 2800 if (CAT->getSize().ule(Index)) { 2801 // Note, it should not be possible to form a pointer with a valid 2802 // designator which points more than one past the end of the array. 2803 if (Info.getLangOpts().CPlusPlus11) 2804 Info.FFDiag(E, diag::note_constexpr_access_past_end) 2805 << handler.AccessKind; 2806 else 2807 Info.FFDiag(E); 2808 return handler.failed(); 2809 } 2810 2811 ObjType = CAT->getElementType(); 2812 2813 // An array object is represented as either an Array APValue or as an 2814 // LValue which refers to a string literal. 2815 if (O->isLValue()) { 2816 assert(I == N - 1 && "extracting subobject of character?"); 2817 assert(!O->hasLValuePath() || O->getLValuePath().empty()); 2818 if (handler.AccessKind != AK_Read) 2819 expandStringLiteral(Info, O->getLValueBase().get<const Expr *>(), 2820 *O); 2821 else 2822 return handler.foundString(*O, ObjType, Index); 2823 } 2824 2825 if (O->getArrayInitializedElts() > Index) 2826 O = &O->getArrayInitializedElt(Index); 2827 else if (handler.AccessKind != AK_Read) { 2828 expandArray(*O, Index); 2829 O = &O->getArrayInitializedElt(Index); 2830 } else 2831 O = &O->getArrayFiller(); 2832 } else if (ObjType->isAnyComplexType()) { 2833 // Next subobject is a complex number. 2834 uint64_t Index = Sub.Entries[I].ArrayIndex; 2835 if (Index > 1) { 2836 if (Info.getLangOpts().CPlusPlus11) 2837 Info.FFDiag(E, diag::note_constexpr_access_past_end) 2838 << handler.AccessKind; 2839 else 2840 Info.FFDiag(E); 2841 return handler.failed(); 2842 } 2843 2844 bool WasConstQualified = ObjType.isConstQualified(); 2845 ObjType = ObjType->castAs<ComplexType>()->getElementType(); 2846 if (WasConstQualified) 2847 ObjType.addConst(); 2848 2849 assert(I == N - 1 && "extracting subobject of scalar?"); 2850 if (O->isComplexInt()) { 2851 return handler.found(Index ? O->getComplexIntImag() 2852 : O->getComplexIntReal(), ObjType); 2853 } else { 2854 assert(O->isComplexFloat()); 2855 return handler.found(Index ? O->getComplexFloatImag() 2856 : O->getComplexFloatReal(), ObjType); 2857 } 2858 } else if (const FieldDecl *Field = getAsField(Sub.Entries[I])) { 2859 // In C++14 onwards, it is permitted to read a mutable member whose 2860 // lifetime began within the evaluation. 2861 // FIXME: Should we also allow this in C++11? 2862 if (Field->isMutable() && handler.AccessKind == AK_Read && 2863 !MayReadMutableMembers) { 2864 Info.FFDiag(E, diag::note_constexpr_ltor_mutable, 1) 2865 << Field; 2866 Info.Note(Field->getLocation(), diag::note_declared_at); 2867 return handler.failed(); 2868 } 2869 2870 // Next subobject is a class, struct or union field. 2871 RecordDecl *RD = ObjType->castAs<RecordType>()->getDecl(); 2872 if (RD->isUnion()) { 2873 const FieldDecl *UnionField = O->getUnionField(); 2874 if (!UnionField || 2875 UnionField->getCanonicalDecl() != Field->getCanonicalDecl()) { 2876 Info.FFDiag(E, diag::note_constexpr_access_inactive_union_member) 2877 << handler.AccessKind << Field << !UnionField << UnionField; 2878 return handler.failed(); 2879 } 2880 O = &O->getUnionValue(); 2881 } else 2882 O = &O->getStructField(Field->getFieldIndex()); 2883 2884 bool WasConstQualified = ObjType.isConstQualified(); 2885 ObjType = Field->getType(); 2886 if (WasConstQualified && !Field->isMutable()) 2887 ObjType.addConst(); 2888 2889 if (ObjType.isVolatileQualified()) { 2890 if (Info.getLangOpts().CPlusPlus) { 2891 // FIXME: Include a description of the path to the volatile subobject. 2892 Info.FFDiag(E, diag::note_constexpr_access_volatile_obj, 1) 2893 << handler.AccessKind << 2 << Field; 2894 Info.Note(Field->getLocation(), diag::note_declared_at); 2895 } else { 2896 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 2897 } 2898 return handler.failed(); 2899 } 2900 2901 LastField = Field; 2902 } else { 2903 // Next subobject is a base class. 2904 const CXXRecordDecl *Derived = ObjType->getAsCXXRecordDecl(); 2905 const CXXRecordDecl *Base = getAsBaseClass(Sub.Entries[I]); 2906 O = &O->getStructBase(getBaseIndex(Derived, Base)); 2907 2908 bool WasConstQualified = ObjType.isConstQualified(); 2909 ObjType = Info.Ctx.getRecordType(Base); 2910 if (WasConstQualified) 2911 ObjType.addConst(); 2912 } 2913 } 2914 } 2915 2916 namespace { 2917 struct ExtractSubobjectHandler { 2918 EvalInfo &Info; 2919 APValue &Result; 2920 2921 static const AccessKinds AccessKind = AK_Read; 2922 2923 typedef bool result_type; 2924 bool failed() { return false; } 2925 bool found(APValue &Subobj, QualType SubobjType) { 2926 Result = Subobj; 2927 return true; 2928 } 2929 bool found(APSInt &Value, QualType SubobjType) { 2930 Result = APValue(Value); 2931 return true; 2932 } 2933 bool found(APFloat &Value, QualType SubobjType) { 2934 Result = APValue(Value); 2935 return true; 2936 } 2937 bool foundString(APValue &Subobj, QualType SubobjType, uint64_t Character) { 2938 Result = APValue(extractStringLiteralCharacter( 2939 Info, Subobj.getLValueBase().get<const Expr *>(), Character)); 2940 return true; 2941 } 2942 }; 2943 } // end anonymous namespace 2944 2945 const AccessKinds ExtractSubobjectHandler::AccessKind; 2946 2947 /// Extract the designated sub-object of an rvalue. 2948 static bool extractSubobject(EvalInfo &Info, const Expr *E, 2949 const CompleteObject &Obj, 2950 const SubobjectDesignator &Sub, 2951 APValue &Result) { 2952 ExtractSubobjectHandler Handler = { Info, Result }; 2953 return findSubobject(Info, E, Obj, Sub, Handler); 2954 } 2955 2956 namespace { 2957 struct ModifySubobjectHandler { 2958 EvalInfo &Info; 2959 APValue &NewVal; 2960 const Expr *E; 2961 2962 typedef bool result_type; 2963 static const AccessKinds AccessKind = AK_Assign; 2964 2965 bool checkConst(QualType QT) { 2966 // Assigning to a const object has undefined behavior. 2967 if (QT.isConstQualified()) { 2968 Info.FFDiag(E, diag::note_constexpr_modify_const_type) << QT; 2969 return false; 2970 } 2971 return true; 2972 } 2973 2974 bool failed() { return false; } 2975 bool found(APValue &Subobj, QualType SubobjType) { 2976 if (!checkConst(SubobjType)) 2977 return false; 2978 // We've been given ownership of NewVal, so just swap it in. 2979 Subobj.swap(NewVal); 2980 return true; 2981 } 2982 bool found(APSInt &Value, QualType SubobjType) { 2983 if (!checkConst(SubobjType)) 2984 return false; 2985 if (!NewVal.isInt()) { 2986 // Maybe trying to write a cast pointer value into a complex? 2987 Info.FFDiag(E); 2988 return false; 2989 } 2990 Value = NewVal.getInt(); 2991 return true; 2992 } 2993 bool found(APFloat &Value, QualType SubobjType) { 2994 if (!checkConst(SubobjType)) 2995 return false; 2996 Value = NewVal.getFloat(); 2997 return true; 2998 } 2999 bool foundString(APValue &Subobj, QualType SubobjType, uint64_t Character) { 3000 llvm_unreachable("shouldn't encounter string elements with ExpandArrays"); 3001 } 3002 }; 3003 } // end anonymous namespace 3004 3005 const AccessKinds ModifySubobjectHandler::AccessKind; 3006 3007 /// Update the designated sub-object of an rvalue to the given value. 3008 static bool modifySubobject(EvalInfo &Info, const Expr *E, 3009 const CompleteObject &Obj, 3010 const SubobjectDesignator &Sub, 3011 APValue &NewVal) { 3012 ModifySubobjectHandler Handler = { Info, NewVal, E }; 3013 return findSubobject(Info, E, Obj, Sub, Handler); 3014 } 3015 3016 /// Find the position where two subobject designators diverge, or equivalently 3017 /// the length of the common initial subsequence. 3018 static unsigned FindDesignatorMismatch(QualType ObjType, 3019 const SubobjectDesignator &A, 3020 const SubobjectDesignator &B, 3021 bool &WasArrayIndex) { 3022 unsigned I = 0, N = std::min(A.Entries.size(), B.Entries.size()); 3023 for (/**/; I != N; ++I) { 3024 if (!ObjType.isNull() && 3025 (ObjType->isArrayType() || ObjType->isAnyComplexType())) { 3026 // Next subobject is an array element. 3027 if (A.Entries[I].ArrayIndex != B.Entries[I].ArrayIndex) { 3028 WasArrayIndex = true; 3029 return I; 3030 } 3031 if (ObjType->isAnyComplexType()) 3032 ObjType = ObjType->castAs<ComplexType>()->getElementType(); 3033 else 3034 ObjType = ObjType->castAsArrayTypeUnsafe()->getElementType(); 3035 } else { 3036 if (A.Entries[I].BaseOrMember != B.Entries[I].BaseOrMember) { 3037 WasArrayIndex = false; 3038 return I; 3039 } 3040 if (const FieldDecl *FD = getAsField(A.Entries[I])) 3041 // Next subobject is a field. 3042 ObjType = FD->getType(); 3043 else 3044 // Next subobject is a base class. 3045 ObjType = QualType(); 3046 } 3047 } 3048 WasArrayIndex = false; 3049 return I; 3050 } 3051 3052 /// Determine whether the given subobject designators refer to elements of the 3053 /// same array object. 3054 static bool AreElementsOfSameArray(QualType ObjType, 3055 const SubobjectDesignator &A, 3056 const SubobjectDesignator &B) { 3057 if (A.Entries.size() != B.Entries.size()) 3058 return false; 3059 3060 bool IsArray = A.MostDerivedIsArrayElement; 3061 if (IsArray && A.MostDerivedPathLength != A.Entries.size()) 3062 // A is a subobject of the array element. 3063 return false; 3064 3065 // If A (and B) designates an array element, the last entry will be the array 3066 // index. That doesn't have to match. Otherwise, we're in the 'implicit array 3067 // of length 1' case, and the entire path must match. 3068 bool WasArrayIndex; 3069 unsigned CommonLength = FindDesignatorMismatch(ObjType, A, B, WasArrayIndex); 3070 return CommonLength >= A.Entries.size() - IsArray; 3071 } 3072 3073 /// Find the complete object to which an LValue refers. 3074 static CompleteObject findCompleteObject(EvalInfo &Info, const Expr *E, 3075 AccessKinds AK, const LValue &LVal, 3076 QualType LValType) { 3077 if (!LVal.Base) { 3078 Info.FFDiag(E, diag::note_constexpr_access_null) << AK; 3079 return CompleteObject(); 3080 } 3081 3082 CallStackFrame *Frame = nullptr; 3083 if (LVal.getLValueCallIndex()) { 3084 Frame = Info.getCallFrame(LVal.getLValueCallIndex()); 3085 if (!Frame) { 3086 Info.FFDiag(E, diag::note_constexpr_lifetime_ended, 1) 3087 << AK << LVal.Base.is<const ValueDecl*>(); 3088 NoteLValueLocation(Info, LVal.Base); 3089 return CompleteObject(); 3090 } 3091 } 3092 3093 // C++11 DR1311: An lvalue-to-rvalue conversion on a volatile-qualified type 3094 // is not a constant expression (even if the object is non-volatile). We also 3095 // apply this rule to C++98, in order to conform to the expected 'volatile' 3096 // semantics. 3097 if (LValType.isVolatileQualified()) { 3098 if (Info.getLangOpts().CPlusPlus) 3099 Info.FFDiag(E, diag::note_constexpr_access_volatile_type) 3100 << AK << LValType; 3101 else 3102 Info.FFDiag(E); 3103 return CompleteObject(); 3104 } 3105 3106 // Compute value storage location and type of base object. 3107 APValue *BaseVal = nullptr; 3108 QualType BaseType = getType(LVal.Base); 3109 bool LifetimeStartedInEvaluation = Frame; 3110 3111 if (const ValueDecl *D = LVal.Base.dyn_cast<const ValueDecl*>()) { 3112 // In C++98, const, non-volatile integers initialized with ICEs are ICEs. 3113 // In C++11, constexpr, non-volatile variables initialized with constant 3114 // expressions are constant expressions too. Inside constexpr functions, 3115 // parameters are constant expressions even if they're non-const. 3116 // In C++1y, objects local to a constant expression (those with a Frame) are 3117 // both readable and writable inside constant expressions. 3118 // In C, such things can also be folded, although they are not ICEs. 3119 const VarDecl *VD = dyn_cast<VarDecl>(D); 3120 if (VD) { 3121 if (const VarDecl *VDef = VD->getDefinition(Info.Ctx)) 3122 VD = VDef; 3123 } 3124 if (!VD || VD->isInvalidDecl()) { 3125 Info.FFDiag(E); 3126 return CompleteObject(); 3127 } 3128 3129 // Accesses of volatile-qualified objects are not allowed. 3130 if (BaseType.isVolatileQualified()) { 3131 if (Info.getLangOpts().CPlusPlus) { 3132 Info.FFDiag(E, diag::note_constexpr_access_volatile_obj, 1) 3133 << AK << 1 << VD; 3134 Info.Note(VD->getLocation(), diag::note_declared_at); 3135 } else { 3136 Info.FFDiag(E); 3137 } 3138 return CompleteObject(); 3139 } 3140 3141 // Unless we're looking at a local variable or argument in a constexpr call, 3142 // the variable we're reading must be const. 3143 if (!Frame) { 3144 if (Info.getLangOpts().CPlusPlus14 && 3145 VD == Info.EvaluatingDecl.dyn_cast<const ValueDecl *>()) { 3146 // OK, we can read and modify an object if we're in the process of 3147 // evaluating its initializer, because its lifetime began in this 3148 // evaluation. 3149 } else if (AK != AK_Read) { 3150 // All the remaining cases only permit reading. 3151 Info.FFDiag(E, diag::note_constexpr_modify_global); 3152 return CompleteObject(); 3153 } else if (VD->isConstexpr()) { 3154 // OK, we can read this variable. 3155 } else if (BaseType->isIntegralOrEnumerationType()) { 3156 // In OpenCL if a variable is in constant address space it is a const value. 3157 if (!(BaseType.isConstQualified() || 3158 (Info.getLangOpts().OpenCL && 3159 BaseType.getAddressSpace() == LangAS::opencl_constant))) { 3160 if (Info.getLangOpts().CPlusPlus) { 3161 Info.FFDiag(E, diag::note_constexpr_ltor_non_const_int, 1) << VD; 3162 Info.Note(VD->getLocation(), diag::note_declared_at); 3163 } else { 3164 Info.FFDiag(E); 3165 } 3166 return CompleteObject(); 3167 } 3168 } else if (BaseType->isFloatingType() && BaseType.isConstQualified()) { 3169 // We support folding of const floating-point types, in order to make 3170 // static const data members of such types (supported as an extension) 3171 // more useful. 3172 if (Info.getLangOpts().CPlusPlus11) { 3173 Info.CCEDiag(E, diag::note_constexpr_ltor_non_constexpr, 1) << VD; 3174 Info.Note(VD->getLocation(), diag::note_declared_at); 3175 } else { 3176 Info.CCEDiag(E); 3177 } 3178 } else if (BaseType.isConstQualified() && VD->hasDefinition(Info.Ctx)) { 3179 Info.CCEDiag(E, diag::note_constexpr_ltor_non_constexpr) << VD; 3180 // Keep evaluating to see what we can do. 3181 } else { 3182 // FIXME: Allow folding of values of any literal type in all languages. 3183 if (Info.checkingPotentialConstantExpression() && 3184 VD->getType().isConstQualified() && !VD->hasDefinition(Info.Ctx)) { 3185 // The definition of this variable could be constexpr. We can't 3186 // access it right now, but may be able to in future. 3187 } else if (Info.getLangOpts().CPlusPlus11) { 3188 Info.FFDiag(E, diag::note_constexpr_ltor_non_constexpr, 1) << VD; 3189 Info.Note(VD->getLocation(), diag::note_declared_at); 3190 } else { 3191 Info.FFDiag(E); 3192 } 3193 return CompleteObject(); 3194 } 3195 } 3196 3197 if (!evaluateVarDeclInit(Info, E, VD, Frame, BaseVal, &LVal)) 3198 return CompleteObject(); 3199 } else { 3200 const Expr *Base = LVal.Base.dyn_cast<const Expr*>(); 3201 3202 if (!Frame) { 3203 if (const MaterializeTemporaryExpr *MTE = 3204 dyn_cast<MaterializeTemporaryExpr>(Base)) { 3205 assert(MTE->getStorageDuration() == SD_Static && 3206 "should have a frame for a non-global materialized temporary"); 3207 3208 // Per C++1y [expr.const]p2: 3209 // an lvalue-to-rvalue conversion [is not allowed unless it applies to] 3210 // - a [...] glvalue of integral or enumeration type that refers to 3211 // a non-volatile const object [...] 3212 // [...] 3213 // - a [...] glvalue of literal type that refers to a non-volatile 3214 // object whose lifetime began within the evaluation of e. 3215 // 3216 // C++11 misses the 'began within the evaluation of e' check and 3217 // instead allows all temporaries, including things like: 3218 // int &&r = 1; 3219 // int x = ++r; 3220 // constexpr int k = r; 3221 // Therefore we use the C++14 rules in C++11 too. 3222 const ValueDecl *VD = Info.EvaluatingDecl.dyn_cast<const ValueDecl*>(); 3223 const ValueDecl *ED = MTE->getExtendingDecl(); 3224 if (!(BaseType.isConstQualified() && 3225 BaseType->isIntegralOrEnumerationType()) && 3226 !(VD && VD->getCanonicalDecl() == ED->getCanonicalDecl())) { 3227 Info.FFDiag(E, diag::note_constexpr_access_static_temporary, 1) << AK; 3228 Info.Note(MTE->getExprLoc(), diag::note_constexpr_temporary_here); 3229 return CompleteObject(); 3230 } 3231 3232 BaseVal = Info.Ctx.getMaterializedTemporaryValue(MTE, false); 3233 assert(BaseVal && "got reference to unevaluated temporary"); 3234 LifetimeStartedInEvaluation = true; 3235 } else { 3236 Info.FFDiag(E); 3237 return CompleteObject(); 3238 } 3239 } else { 3240 BaseVal = Frame->getTemporary(Base, LVal.Base.getVersion()); 3241 assert(BaseVal && "missing value for temporary"); 3242 } 3243 3244 // Volatile temporary objects cannot be accessed in constant expressions. 3245 if (BaseType.isVolatileQualified()) { 3246 if (Info.getLangOpts().CPlusPlus) { 3247 Info.FFDiag(E, diag::note_constexpr_access_volatile_obj, 1) 3248 << AK << 0; 3249 Info.Note(Base->getExprLoc(), diag::note_constexpr_temporary_here); 3250 } else { 3251 Info.FFDiag(E); 3252 } 3253 return CompleteObject(); 3254 } 3255 } 3256 3257 // During the construction of an object, it is not yet 'const'. 3258 // FIXME: This doesn't do quite the right thing for const subobjects of the 3259 // object under construction. 3260 if (Info.isEvaluatingConstructor(LVal.getLValueBase(), 3261 LVal.getLValueCallIndex(), 3262 LVal.getLValueVersion())) { 3263 BaseType = Info.Ctx.getCanonicalType(BaseType); 3264 BaseType.removeLocalConst(); 3265 LifetimeStartedInEvaluation = true; 3266 } 3267 3268 // In C++14, we can't safely access any mutable state when we might be 3269 // evaluating after an unmodeled side effect. 3270 // 3271 // FIXME: Not all local state is mutable. Allow local constant subobjects 3272 // to be read here (but take care with 'mutable' fields). 3273 if ((Frame && Info.getLangOpts().CPlusPlus14 && 3274 Info.EvalStatus.HasSideEffects) || 3275 (AK != AK_Read && Info.IsSpeculativelyEvaluating)) 3276 return CompleteObject(); 3277 3278 return CompleteObject(BaseVal, BaseType, LifetimeStartedInEvaluation); 3279 } 3280 3281 /// Perform an lvalue-to-rvalue conversion on the given glvalue. This 3282 /// can also be used for 'lvalue-to-lvalue' conversions for looking up the 3283 /// glvalue referred to by an entity of reference type. 3284 /// 3285 /// \param Info - Information about the ongoing evaluation. 3286 /// \param Conv - The expression for which we are performing the conversion. 3287 /// Used for diagnostics. 3288 /// \param Type - The type of the glvalue (before stripping cv-qualifiers in the 3289 /// case of a non-class type). 3290 /// \param LVal - The glvalue on which we are attempting to perform this action. 3291 /// \param RVal - The produced value will be placed here. 3292 static bool handleLValueToRValueConversion(EvalInfo &Info, const Expr *Conv, 3293 QualType Type, 3294 const LValue &LVal, APValue &RVal) { 3295 if (LVal.Designator.Invalid) 3296 return false; 3297 3298 // Check for special cases where there is no existing APValue to look at. 3299 const Expr *Base = LVal.Base.dyn_cast<const Expr*>(); 3300 if (Base && !LVal.getLValueCallIndex() && !Type.isVolatileQualified()) { 3301 if (const CompoundLiteralExpr *CLE = dyn_cast<CompoundLiteralExpr>(Base)) { 3302 // In C99, a CompoundLiteralExpr is an lvalue, and we defer evaluating the 3303 // initializer until now for such expressions. Such an expression can't be 3304 // an ICE in C, so this only matters for fold. 3305 if (Type.isVolatileQualified()) { 3306 Info.FFDiag(Conv); 3307 return false; 3308 } 3309 APValue Lit; 3310 if (!Evaluate(Lit, Info, CLE->getInitializer())) 3311 return false; 3312 CompleteObject LitObj(&Lit, Base->getType(), false); 3313 return extractSubobject(Info, Conv, LitObj, LVal.Designator, RVal); 3314 } else if (isa<StringLiteral>(Base) || isa<PredefinedExpr>(Base)) { 3315 // We represent a string literal array as an lvalue pointing at the 3316 // corresponding expression, rather than building an array of chars. 3317 // FIXME: Support ObjCEncodeExpr, MakeStringConstant 3318 APValue Str(Base, CharUnits::Zero(), APValue::NoLValuePath(), 0); 3319 CompleteObject StrObj(&Str, Base->getType(), false); 3320 return extractSubobject(Info, Conv, StrObj, LVal.Designator, RVal); 3321 } 3322 } 3323 3324 CompleteObject Obj = findCompleteObject(Info, Conv, AK_Read, LVal, Type); 3325 return Obj && extractSubobject(Info, Conv, Obj, LVal.Designator, RVal); 3326 } 3327 3328 /// Perform an assignment of Val to LVal. Takes ownership of Val. 3329 static bool handleAssignment(EvalInfo &Info, const Expr *E, const LValue &LVal, 3330 QualType LValType, APValue &Val) { 3331 if (LVal.Designator.Invalid) 3332 return false; 3333 3334 if (!Info.getLangOpts().CPlusPlus14) { 3335 Info.FFDiag(E); 3336 return false; 3337 } 3338 3339 CompleteObject Obj = findCompleteObject(Info, E, AK_Assign, LVal, LValType); 3340 return Obj && modifySubobject(Info, E, Obj, LVal.Designator, Val); 3341 } 3342 3343 namespace { 3344 struct CompoundAssignSubobjectHandler { 3345 EvalInfo &Info; 3346 const Expr *E; 3347 QualType PromotedLHSType; 3348 BinaryOperatorKind Opcode; 3349 const APValue &RHS; 3350 3351 static const AccessKinds AccessKind = AK_Assign; 3352 3353 typedef bool result_type; 3354 3355 bool checkConst(QualType QT) { 3356 // Assigning to a const object has undefined behavior. 3357 if (QT.isConstQualified()) { 3358 Info.FFDiag(E, diag::note_constexpr_modify_const_type) << QT; 3359 return false; 3360 } 3361 return true; 3362 } 3363 3364 bool failed() { return false; } 3365 bool found(APValue &Subobj, QualType SubobjType) { 3366 switch (Subobj.getKind()) { 3367 case APValue::Int: 3368 return found(Subobj.getInt(), SubobjType); 3369 case APValue::Float: 3370 return found(Subobj.getFloat(), SubobjType); 3371 case APValue::ComplexInt: 3372 case APValue::ComplexFloat: 3373 // FIXME: Implement complex compound assignment. 3374 Info.FFDiag(E); 3375 return false; 3376 case APValue::LValue: 3377 return foundPointer(Subobj, SubobjType); 3378 default: 3379 // FIXME: can this happen? 3380 Info.FFDiag(E); 3381 return false; 3382 } 3383 } 3384 bool found(APSInt &Value, QualType SubobjType) { 3385 if (!checkConst(SubobjType)) 3386 return false; 3387 3388 if (!SubobjType->isIntegerType() || !RHS.isInt()) { 3389 // We don't support compound assignment on integer-cast-to-pointer 3390 // values. 3391 Info.FFDiag(E); 3392 return false; 3393 } 3394 3395 APSInt LHS = HandleIntToIntCast(Info, E, PromotedLHSType, 3396 SubobjType, Value); 3397 if (!handleIntIntBinOp(Info, E, LHS, Opcode, RHS.getInt(), LHS)) 3398 return false; 3399 Value = HandleIntToIntCast(Info, E, SubobjType, PromotedLHSType, LHS); 3400 return true; 3401 } 3402 bool found(APFloat &Value, QualType SubobjType) { 3403 return checkConst(SubobjType) && 3404 HandleFloatToFloatCast(Info, E, SubobjType, PromotedLHSType, 3405 Value) && 3406 handleFloatFloatBinOp(Info, E, Value, Opcode, RHS.getFloat()) && 3407 HandleFloatToFloatCast(Info, E, PromotedLHSType, SubobjType, Value); 3408 } 3409 bool foundPointer(APValue &Subobj, QualType SubobjType) { 3410 if (!checkConst(SubobjType)) 3411 return false; 3412 3413 QualType PointeeType; 3414 if (const PointerType *PT = SubobjType->getAs<PointerType>()) 3415 PointeeType = PT->getPointeeType(); 3416 3417 if (PointeeType.isNull() || !RHS.isInt() || 3418 (Opcode != BO_Add && Opcode != BO_Sub)) { 3419 Info.FFDiag(E); 3420 return false; 3421 } 3422 3423 APSInt Offset = RHS.getInt(); 3424 if (Opcode == BO_Sub) 3425 negateAsSigned(Offset); 3426 3427 LValue LVal; 3428 LVal.setFrom(Info.Ctx, Subobj); 3429 if (!HandleLValueArrayAdjustment(Info, E, LVal, PointeeType, Offset)) 3430 return false; 3431 LVal.moveInto(Subobj); 3432 return true; 3433 } 3434 bool foundString(APValue &Subobj, QualType SubobjType, uint64_t Character) { 3435 llvm_unreachable("shouldn't encounter string elements here"); 3436 } 3437 }; 3438 } // end anonymous namespace 3439 3440 const AccessKinds CompoundAssignSubobjectHandler::AccessKind; 3441 3442 /// Perform a compound assignment of LVal <op>= RVal. 3443 static bool handleCompoundAssignment( 3444 EvalInfo &Info, const Expr *E, 3445 const LValue &LVal, QualType LValType, QualType PromotedLValType, 3446 BinaryOperatorKind Opcode, const APValue &RVal) { 3447 if (LVal.Designator.Invalid) 3448 return false; 3449 3450 if (!Info.getLangOpts().CPlusPlus14) { 3451 Info.FFDiag(E); 3452 return false; 3453 } 3454 3455 CompleteObject Obj = findCompleteObject(Info, E, AK_Assign, LVal, LValType); 3456 CompoundAssignSubobjectHandler Handler = { Info, E, PromotedLValType, Opcode, 3457 RVal }; 3458 return Obj && findSubobject(Info, E, Obj, LVal.Designator, Handler); 3459 } 3460 3461 namespace { 3462 struct IncDecSubobjectHandler { 3463 EvalInfo &Info; 3464 const UnaryOperator *E; 3465 AccessKinds AccessKind; 3466 APValue *Old; 3467 3468 typedef bool result_type; 3469 3470 bool checkConst(QualType QT) { 3471 // Assigning to a const object has undefined behavior. 3472 if (QT.isConstQualified()) { 3473 Info.FFDiag(E, diag::note_constexpr_modify_const_type) << QT; 3474 return false; 3475 } 3476 return true; 3477 } 3478 3479 bool failed() { return false; } 3480 bool found(APValue &Subobj, QualType SubobjType) { 3481 // Stash the old value. Also clear Old, so we don't clobber it later 3482 // if we're post-incrementing a complex. 3483 if (Old) { 3484 *Old = Subobj; 3485 Old = nullptr; 3486 } 3487 3488 switch (Subobj.getKind()) { 3489 case APValue::Int: 3490 return found(Subobj.getInt(), SubobjType); 3491 case APValue::Float: 3492 return found(Subobj.getFloat(), SubobjType); 3493 case APValue::ComplexInt: 3494 return found(Subobj.getComplexIntReal(), 3495 SubobjType->castAs<ComplexType>()->getElementType() 3496 .withCVRQualifiers(SubobjType.getCVRQualifiers())); 3497 case APValue::ComplexFloat: 3498 return found(Subobj.getComplexFloatReal(), 3499 SubobjType->castAs<ComplexType>()->getElementType() 3500 .withCVRQualifiers(SubobjType.getCVRQualifiers())); 3501 case APValue::LValue: 3502 return foundPointer(Subobj, SubobjType); 3503 default: 3504 // FIXME: can this happen? 3505 Info.FFDiag(E); 3506 return false; 3507 } 3508 } 3509 bool found(APSInt &Value, QualType SubobjType) { 3510 if (!checkConst(SubobjType)) 3511 return false; 3512 3513 if (!SubobjType->isIntegerType()) { 3514 // We don't support increment / decrement on integer-cast-to-pointer 3515 // values. 3516 Info.FFDiag(E); 3517 return false; 3518 } 3519 3520 if (Old) *Old = APValue(Value); 3521 3522 // bool arithmetic promotes to int, and the conversion back to bool 3523 // doesn't reduce mod 2^n, so special-case it. 3524 if (SubobjType->isBooleanType()) { 3525 if (AccessKind == AK_Increment) 3526 Value = 1; 3527 else 3528 Value = !Value; 3529 return true; 3530 } 3531 3532 bool WasNegative = Value.isNegative(); 3533 if (AccessKind == AK_Increment) { 3534 ++Value; 3535 3536 if (!WasNegative && Value.isNegative() && E->canOverflow()) { 3537 APSInt ActualValue(Value, /*IsUnsigned*/true); 3538 return HandleOverflow(Info, E, ActualValue, SubobjType); 3539 } 3540 } else { 3541 --Value; 3542 3543 if (WasNegative && !Value.isNegative() && E->canOverflow()) { 3544 unsigned BitWidth = Value.getBitWidth(); 3545 APSInt ActualValue(Value.sext(BitWidth + 1), /*IsUnsigned*/false); 3546 ActualValue.setBit(BitWidth); 3547 return HandleOverflow(Info, E, ActualValue, SubobjType); 3548 } 3549 } 3550 return true; 3551 } 3552 bool found(APFloat &Value, QualType SubobjType) { 3553 if (!checkConst(SubobjType)) 3554 return false; 3555 3556 if (Old) *Old = APValue(Value); 3557 3558 APFloat One(Value.getSemantics(), 1); 3559 if (AccessKind == AK_Increment) 3560 Value.add(One, APFloat::rmNearestTiesToEven); 3561 else 3562 Value.subtract(One, APFloat::rmNearestTiesToEven); 3563 return true; 3564 } 3565 bool foundPointer(APValue &Subobj, QualType SubobjType) { 3566 if (!checkConst(SubobjType)) 3567 return false; 3568 3569 QualType PointeeType; 3570 if (const PointerType *PT = SubobjType->getAs<PointerType>()) 3571 PointeeType = PT->getPointeeType(); 3572 else { 3573 Info.FFDiag(E); 3574 return false; 3575 } 3576 3577 LValue LVal; 3578 LVal.setFrom(Info.Ctx, Subobj); 3579 if (!HandleLValueArrayAdjustment(Info, E, LVal, PointeeType, 3580 AccessKind == AK_Increment ? 1 : -1)) 3581 return false; 3582 LVal.moveInto(Subobj); 3583 return true; 3584 } 3585 bool foundString(APValue &Subobj, QualType SubobjType, uint64_t Character) { 3586 llvm_unreachable("shouldn't encounter string elements here"); 3587 } 3588 }; 3589 } // end anonymous namespace 3590 3591 /// Perform an increment or decrement on LVal. 3592 static bool handleIncDec(EvalInfo &Info, const Expr *E, const LValue &LVal, 3593 QualType LValType, bool IsIncrement, APValue *Old) { 3594 if (LVal.Designator.Invalid) 3595 return false; 3596 3597 if (!Info.getLangOpts().CPlusPlus14) { 3598 Info.FFDiag(E); 3599 return false; 3600 } 3601 3602 AccessKinds AK = IsIncrement ? AK_Increment : AK_Decrement; 3603 CompleteObject Obj = findCompleteObject(Info, E, AK, LVal, LValType); 3604 IncDecSubobjectHandler Handler = {Info, cast<UnaryOperator>(E), AK, Old}; 3605 return Obj && findSubobject(Info, E, Obj, LVal.Designator, Handler); 3606 } 3607 3608 /// Build an lvalue for the object argument of a member function call. 3609 static bool EvaluateObjectArgument(EvalInfo &Info, const Expr *Object, 3610 LValue &This) { 3611 if (Object->getType()->isPointerType()) 3612 return EvaluatePointer(Object, This, Info); 3613 3614 if (Object->isGLValue()) 3615 return EvaluateLValue(Object, This, Info); 3616 3617 if (Object->getType()->isLiteralType(Info.Ctx)) 3618 return EvaluateTemporary(Object, This, Info); 3619 3620 Info.FFDiag(Object, diag::note_constexpr_nonliteral) << Object->getType(); 3621 return false; 3622 } 3623 3624 /// HandleMemberPointerAccess - Evaluate a member access operation and build an 3625 /// lvalue referring to the result. 3626 /// 3627 /// \param Info - Information about the ongoing evaluation. 3628 /// \param LV - An lvalue referring to the base of the member pointer. 3629 /// \param RHS - The member pointer expression. 3630 /// \param IncludeMember - Specifies whether the member itself is included in 3631 /// the resulting LValue subobject designator. This is not possible when 3632 /// creating a bound member function. 3633 /// \return The field or method declaration to which the member pointer refers, 3634 /// or 0 if evaluation fails. 3635 static const ValueDecl *HandleMemberPointerAccess(EvalInfo &Info, 3636 QualType LVType, 3637 LValue &LV, 3638 const Expr *RHS, 3639 bool IncludeMember = true) { 3640 MemberPtr MemPtr; 3641 if (!EvaluateMemberPointer(RHS, MemPtr, Info)) 3642 return nullptr; 3643 3644 // C++11 [expr.mptr.oper]p6: If the second operand is the null pointer to 3645 // member value, the behavior is undefined. 3646 if (!MemPtr.getDecl()) { 3647 // FIXME: Specific diagnostic. 3648 Info.FFDiag(RHS); 3649 return nullptr; 3650 } 3651 3652 if (MemPtr.isDerivedMember()) { 3653 // This is a member of some derived class. Truncate LV appropriately. 3654 // The end of the derived-to-base path for the base object must match the 3655 // derived-to-base path for the member pointer. 3656 if (LV.Designator.MostDerivedPathLength + MemPtr.Path.size() > 3657 LV.Designator.Entries.size()) { 3658 Info.FFDiag(RHS); 3659 return nullptr; 3660 } 3661 unsigned PathLengthToMember = 3662 LV.Designator.Entries.size() - MemPtr.Path.size(); 3663 for (unsigned I = 0, N = MemPtr.Path.size(); I != N; ++I) { 3664 const CXXRecordDecl *LVDecl = getAsBaseClass( 3665 LV.Designator.Entries[PathLengthToMember + I]); 3666 const CXXRecordDecl *MPDecl = MemPtr.Path[I]; 3667 if (LVDecl->getCanonicalDecl() != MPDecl->getCanonicalDecl()) { 3668 Info.FFDiag(RHS); 3669 return nullptr; 3670 } 3671 } 3672 3673 // Truncate the lvalue to the appropriate derived class. 3674 if (!CastToDerivedClass(Info, RHS, LV, MemPtr.getContainingRecord(), 3675 PathLengthToMember)) 3676 return nullptr; 3677 } else if (!MemPtr.Path.empty()) { 3678 // Extend the LValue path with the member pointer's path. 3679 LV.Designator.Entries.reserve(LV.Designator.Entries.size() + 3680 MemPtr.Path.size() + IncludeMember); 3681 3682 // Walk down to the appropriate base class. 3683 if (const PointerType *PT = LVType->getAs<PointerType>()) 3684 LVType = PT->getPointeeType(); 3685 const CXXRecordDecl *RD = LVType->getAsCXXRecordDecl(); 3686 assert(RD && "member pointer access on non-class-type expression"); 3687 // The first class in the path is that of the lvalue. 3688 for (unsigned I = 1, N = MemPtr.Path.size(); I != N; ++I) { 3689 const CXXRecordDecl *Base = MemPtr.Path[N - I - 1]; 3690 if (!HandleLValueDirectBase(Info, RHS, LV, RD, Base)) 3691 return nullptr; 3692 RD = Base; 3693 } 3694 // Finally cast to the class containing the member. 3695 if (!HandleLValueDirectBase(Info, RHS, LV, RD, 3696 MemPtr.getContainingRecord())) 3697 return nullptr; 3698 } 3699 3700 // Add the member. Note that we cannot build bound member functions here. 3701 if (IncludeMember) { 3702 if (const FieldDecl *FD = dyn_cast<FieldDecl>(MemPtr.getDecl())) { 3703 if (!HandleLValueMember(Info, RHS, LV, FD)) 3704 return nullptr; 3705 } else if (const IndirectFieldDecl *IFD = 3706 dyn_cast<IndirectFieldDecl>(MemPtr.getDecl())) { 3707 if (!HandleLValueIndirectMember(Info, RHS, LV, IFD)) 3708 return nullptr; 3709 } else { 3710 llvm_unreachable("can't construct reference to bound member function"); 3711 } 3712 } 3713 3714 return MemPtr.getDecl(); 3715 } 3716 3717 static const ValueDecl *HandleMemberPointerAccess(EvalInfo &Info, 3718 const BinaryOperator *BO, 3719 LValue &LV, 3720 bool IncludeMember = true) { 3721 assert(BO->getOpcode() == BO_PtrMemD || BO->getOpcode() == BO_PtrMemI); 3722 3723 if (!EvaluateObjectArgument(Info, BO->getLHS(), LV)) { 3724 if (Info.noteFailure()) { 3725 MemberPtr MemPtr; 3726 EvaluateMemberPointer(BO->getRHS(), MemPtr, Info); 3727 } 3728 return nullptr; 3729 } 3730 3731 return HandleMemberPointerAccess(Info, BO->getLHS()->getType(), LV, 3732 BO->getRHS(), IncludeMember); 3733 } 3734 3735 /// HandleBaseToDerivedCast - Apply the given base-to-derived cast operation on 3736 /// the provided lvalue, which currently refers to the base object. 3737 static bool HandleBaseToDerivedCast(EvalInfo &Info, const CastExpr *E, 3738 LValue &Result) { 3739 SubobjectDesignator &D = Result.Designator; 3740 if (D.Invalid || !Result.checkNullPointer(Info, E, CSK_Derived)) 3741 return false; 3742 3743 QualType TargetQT = E->getType(); 3744 if (const PointerType *PT = TargetQT->getAs<PointerType>()) 3745 TargetQT = PT->getPointeeType(); 3746 3747 // Check this cast lands within the final derived-to-base subobject path. 3748 if (D.MostDerivedPathLength + E->path_size() > D.Entries.size()) { 3749 Info.CCEDiag(E, diag::note_constexpr_invalid_downcast) 3750 << D.MostDerivedType << TargetQT; 3751 return false; 3752 } 3753 3754 // Check the type of the final cast. We don't need to check the path, 3755 // since a cast can only be formed if the path is unique. 3756 unsigned NewEntriesSize = D.Entries.size() - E->path_size(); 3757 const CXXRecordDecl *TargetType = TargetQT->getAsCXXRecordDecl(); 3758 const CXXRecordDecl *FinalType; 3759 if (NewEntriesSize == D.MostDerivedPathLength) 3760 FinalType = D.MostDerivedType->getAsCXXRecordDecl(); 3761 else 3762 FinalType = getAsBaseClass(D.Entries[NewEntriesSize - 1]); 3763 if (FinalType->getCanonicalDecl() != TargetType->getCanonicalDecl()) { 3764 Info.CCEDiag(E, diag::note_constexpr_invalid_downcast) 3765 << D.MostDerivedType << TargetQT; 3766 return false; 3767 } 3768 3769 // Truncate the lvalue to the appropriate derived class. 3770 return CastToDerivedClass(Info, E, Result, TargetType, NewEntriesSize); 3771 } 3772 3773 namespace { 3774 enum EvalStmtResult { 3775 /// Evaluation failed. 3776 ESR_Failed, 3777 /// Hit a 'return' statement. 3778 ESR_Returned, 3779 /// Evaluation succeeded. 3780 ESR_Succeeded, 3781 /// Hit a 'continue' statement. 3782 ESR_Continue, 3783 /// Hit a 'break' statement. 3784 ESR_Break, 3785 /// Still scanning for 'case' or 'default' statement. 3786 ESR_CaseNotFound 3787 }; 3788 } 3789 3790 static bool EvaluateVarDecl(EvalInfo &Info, const VarDecl *VD) { 3791 // We don't need to evaluate the initializer for a static local. 3792 if (!VD->hasLocalStorage()) 3793 return true; 3794 3795 LValue Result; 3796 APValue &Val = createTemporary(VD, true, Result, *Info.CurrentCall); 3797 3798 const Expr *InitE = VD->getInit(); 3799 if (!InitE) { 3800 Info.FFDiag(VD->getLocStart(), diag::note_constexpr_uninitialized) 3801 << false << VD->getType(); 3802 Val = APValue(); 3803 return false; 3804 } 3805 3806 if (InitE->isValueDependent()) 3807 return false; 3808 3809 if (!EvaluateInPlace(Val, Info, Result, InitE)) { 3810 // Wipe out any partially-computed value, to allow tracking that this 3811 // evaluation failed. 3812 Val = APValue(); 3813 return false; 3814 } 3815 3816 return true; 3817 } 3818 3819 static bool EvaluateDecl(EvalInfo &Info, const Decl *D) { 3820 bool OK = true; 3821 3822 if (const VarDecl *VD = dyn_cast<VarDecl>(D)) 3823 OK &= EvaluateVarDecl(Info, VD); 3824 3825 if (const DecompositionDecl *DD = dyn_cast<DecompositionDecl>(D)) 3826 for (auto *BD : DD->bindings()) 3827 if (auto *VD = BD->getHoldingVar()) 3828 OK &= EvaluateDecl(Info, VD); 3829 3830 return OK; 3831 } 3832 3833 3834 /// Evaluate a condition (either a variable declaration or an expression). 3835 static bool EvaluateCond(EvalInfo &Info, const VarDecl *CondDecl, 3836 const Expr *Cond, bool &Result) { 3837 FullExpressionRAII Scope(Info); 3838 if (CondDecl && !EvaluateDecl(Info, CondDecl)) 3839 return false; 3840 return EvaluateAsBooleanCondition(Cond, Result, Info); 3841 } 3842 3843 namespace { 3844 /// A location where the result (returned value) of evaluating a 3845 /// statement should be stored. 3846 struct StmtResult { 3847 /// The APValue that should be filled in with the returned value. 3848 APValue &Value; 3849 /// The location containing the result, if any (used to support RVO). 3850 const LValue *Slot; 3851 }; 3852 3853 struct TempVersionRAII { 3854 CallStackFrame &Frame; 3855 3856 TempVersionRAII(CallStackFrame &Frame) : Frame(Frame) { 3857 Frame.pushTempVersion(); 3858 } 3859 3860 ~TempVersionRAII() { 3861 Frame.popTempVersion(); 3862 } 3863 }; 3864 3865 } 3866 3867 static EvalStmtResult EvaluateStmt(StmtResult &Result, EvalInfo &Info, 3868 const Stmt *S, 3869 const SwitchCase *SC = nullptr); 3870 3871 /// Evaluate the body of a loop, and translate the result as appropriate. 3872 static EvalStmtResult EvaluateLoopBody(StmtResult &Result, EvalInfo &Info, 3873 const Stmt *Body, 3874 const SwitchCase *Case = nullptr) { 3875 BlockScopeRAII Scope(Info); 3876 switch (EvalStmtResult ESR = EvaluateStmt(Result, Info, Body, Case)) { 3877 case ESR_Break: 3878 return ESR_Succeeded; 3879 case ESR_Succeeded: 3880 case ESR_Continue: 3881 return ESR_Continue; 3882 case ESR_Failed: 3883 case ESR_Returned: 3884 case ESR_CaseNotFound: 3885 return ESR; 3886 } 3887 llvm_unreachable("Invalid EvalStmtResult!"); 3888 } 3889 3890 /// Evaluate a switch statement. 3891 static EvalStmtResult EvaluateSwitch(StmtResult &Result, EvalInfo &Info, 3892 const SwitchStmt *SS) { 3893 BlockScopeRAII Scope(Info); 3894 3895 // Evaluate the switch condition. 3896 APSInt Value; 3897 { 3898 FullExpressionRAII Scope(Info); 3899 if (const Stmt *Init = SS->getInit()) { 3900 EvalStmtResult ESR = EvaluateStmt(Result, Info, Init); 3901 if (ESR != ESR_Succeeded) 3902 return ESR; 3903 } 3904 if (SS->getConditionVariable() && 3905 !EvaluateDecl(Info, SS->getConditionVariable())) 3906 return ESR_Failed; 3907 if (!EvaluateInteger(SS->getCond(), Value, Info)) 3908 return ESR_Failed; 3909 } 3910 3911 // Find the switch case corresponding to the value of the condition. 3912 // FIXME: Cache this lookup. 3913 const SwitchCase *Found = nullptr; 3914 for (const SwitchCase *SC = SS->getSwitchCaseList(); SC; 3915 SC = SC->getNextSwitchCase()) { 3916 if (isa<DefaultStmt>(SC)) { 3917 Found = SC; 3918 continue; 3919 } 3920 3921 const CaseStmt *CS = cast<CaseStmt>(SC); 3922 APSInt LHS = CS->getLHS()->EvaluateKnownConstInt(Info.Ctx); 3923 APSInt RHS = CS->getRHS() ? CS->getRHS()->EvaluateKnownConstInt(Info.Ctx) 3924 : LHS; 3925 if (LHS <= Value && Value <= RHS) { 3926 Found = SC; 3927 break; 3928 } 3929 } 3930 3931 if (!Found) 3932 return ESR_Succeeded; 3933 3934 // Search the switch body for the switch case and evaluate it from there. 3935 switch (EvalStmtResult ESR = EvaluateStmt(Result, Info, SS->getBody(), Found)) { 3936 case ESR_Break: 3937 return ESR_Succeeded; 3938 case ESR_Succeeded: 3939 case ESR_Continue: 3940 case ESR_Failed: 3941 case ESR_Returned: 3942 return ESR; 3943 case ESR_CaseNotFound: 3944 // This can only happen if the switch case is nested within a statement 3945 // expression. We have no intention of supporting that. 3946 Info.FFDiag(Found->getLocStart(), diag::note_constexpr_stmt_expr_unsupported); 3947 return ESR_Failed; 3948 } 3949 llvm_unreachable("Invalid EvalStmtResult!"); 3950 } 3951 3952 // Evaluate a statement. 3953 static EvalStmtResult EvaluateStmt(StmtResult &Result, EvalInfo &Info, 3954 const Stmt *S, const SwitchCase *Case) { 3955 if (!Info.nextStep(S)) 3956 return ESR_Failed; 3957 3958 // If we're hunting down a 'case' or 'default' label, recurse through 3959 // substatements until we hit the label. 3960 if (Case) { 3961 // FIXME: We don't start the lifetime of objects whose initialization we 3962 // jump over. However, such objects must be of class type with a trivial 3963 // default constructor that initialize all subobjects, so must be empty, 3964 // so this almost never matters. 3965 switch (S->getStmtClass()) { 3966 case Stmt::CompoundStmtClass: 3967 // FIXME: Precompute which substatement of a compound statement we 3968 // would jump to, and go straight there rather than performing a 3969 // linear scan each time. 3970 case Stmt::LabelStmtClass: 3971 case Stmt::AttributedStmtClass: 3972 case Stmt::DoStmtClass: 3973 break; 3974 3975 case Stmt::CaseStmtClass: 3976 case Stmt::DefaultStmtClass: 3977 if (Case == S) 3978 Case = nullptr; 3979 break; 3980 3981 case Stmt::IfStmtClass: { 3982 // FIXME: Precompute which side of an 'if' we would jump to, and go 3983 // straight there rather than scanning both sides. 3984 const IfStmt *IS = cast<IfStmt>(S); 3985 3986 // Wrap the evaluation in a block scope, in case it's a DeclStmt 3987 // preceded by our switch label. 3988 BlockScopeRAII Scope(Info); 3989 3990 EvalStmtResult ESR = EvaluateStmt(Result, Info, IS->getThen(), Case); 3991 if (ESR != ESR_CaseNotFound || !IS->getElse()) 3992 return ESR; 3993 return EvaluateStmt(Result, Info, IS->getElse(), Case); 3994 } 3995 3996 case Stmt::WhileStmtClass: { 3997 EvalStmtResult ESR = 3998 EvaluateLoopBody(Result, Info, cast<WhileStmt>(S)->getBody(), Case); 3999 if (ESR != ESR_Continue) 4000 return ESR; 4001 break; 4002 } 4003 4004 case Stmt::ForStmtClass: { 4005 const ForStmt *FS = cast<ForStmt>(S); 4006 EvalStmtResult ESR = 4007 EvaluateLoopBody(Result, Info, FS->getBody(), Case); 4008 if (ESR != ESR_Continue) 4009 return ESR; 4010 if (FS->getInc()) { 4011 FullExpressionRAII IncScope(Info); 4012 if (!EvaluateIgnoredValue(Info, FS->getInc())) 4013 return ESR_Failed; 4014 } 4015 break; 4016 } 4017 4018 case Stmt::DeclStmtClass: 4019 // FIXME: If the variable has initialization that can't be jumped over, 4020 // bail out of any immediately-surrounding compound-statement too. 4021 default: 4022 return ESR_CaseNotFound; 4023 } 4024 } 4025 4026 switch (S->getStmtClass()) { 4027 default: 4028 if (const Expr *E = dyn_cast<Expr>(S)) { 4029 // Don't bother evaluating beyond an expression-statement which couldn't 4030 // be evaluated. 4031 FullExpressionRAII Scope(Info); 4032 if (!EvaluateIgnoredValue(Info, E)) 4033 return ESR_Failed; 4034 return ESR_Succeeded; 4035 } 4036 4037 Info.FFDiag(S->getLocStart()); 4038 return ESR_Failed; 4039 4040 case Stmt::NullStmtClass: 4041 return ESR_Succeeded; 4042 4043 case Stmt::DeclStmtClass: { 4044 const DeclStmt *DS = cast<DeclStmt>(S); 4045 for (const auto *DclIt : DS->decls()) { 4046 // Each declaration initialization is its own full-expression. 4047 // FIXME: This isn't quite right; if we're performing aggregate 4048 // initialization, each braced subexpression is its own full-expression. 4049 FullExpressionRAII Scope(Info); 4050 if (!EvaluateDecl(Info, DclIt) && !Info.noteFailure()) 4051 return ESR_Failed; 4052 } 4053 return ESR_Succeeded; 4054 } 4055 4056 case Stmt::ReturnStmtClass: { 4057 const Expr *RetExpr = cast<ReturnStmt>(S)->getRetValue(); 4058 FullExpressionRAII Scope(Info); 4059 if (RetExpr && 4060 !(Result.Slot 4061 ? EvaluateInPlace(Result.Value, Info, *Result.Slot, RetExpr) 4062 : Evaluate(Result.Value, Info, RetExpr))) 4063 return ESR_Failed; 4064 return ESR_Returned; 4065 } 4066 4067 case Stmt::CompoundStmtClass: { 4068 BlockScopeRAII Scope(Info); 4069 4070 const CompoundStmt *CS = cast<CompoundStmt>(S); 4071 for (const auto *BI : CS->body()) { 4072 EvalStmtResult ESR = EvaluateStmt(Result, Info, BI, Case); 4073 if (ESR == ESR_Succeeded) 4074 Case = nullptr; 4075 else if (ESR != ESR_CaseNotFound) 4076 return ESR; 4077 } 4078 return Case ? ESR_CaseNotFound : ESR_Succeeded; 4079 } 4080 4081 case Stmt::IfStmtClass: { 4082 const IfStmt *IS = cast<IfStmt>(S); 4083 4084 // Evaluate the condition, as either a var decl or as an expression. 4085 BlockScopeRAII Scope(Info); 4086 if (const Stmt *Init = IS->getInit()) { 4087 EvalStmtResult ESR = EvaluateStmt(Result, Info, Init); 4088 if (ESR != ESR_Succeeded) 4089 return ESR; 4090 } 4091 bool Cond; 4092 if (!EvaluateCond(Info, IS->getConditionVariable(), IS->getCond(), Cond)) 4093 return ESR_Failed; 4094 4095 if (const Stmt *SubStmt = Cond ? IS->getThen() : IS->getElse()) { 4096 EvalStmtResult ESR = EvaluateStmt(Result, Info, SubStmt); 4097 if (ESR != ESR_Succeeded) 4098 return ESR; 4099 } 4100 return ESR_Succeeded; 4101 } 4102 4103 case Stmt::WhileStmtClass: { 4104 const WhileStmt *WS = cast<WhileStmt>(S); 4105 while (true) { 4106 BlockScopeRAII Scope(Info); 4107 bool Continue; 4108 if (!EvaluateCond(Info, WS->getConditionVariable(), WS->getCond(), 4109 Continue)) 4110 return ESR_Failed; 4111 if (!Continue) 4112 break; 4113 4114 EvalStmtResult ESR = EvaluateLoopBody(Result, Info, WS->getBody()); 4115 if (ESR != ESR_Continue) 4116 return ESR; 4117 } 4118 return ESR_Succeeded; 4119 } 4120 4121 case Stmt::DoStmtClass: { 4122 const DoStmt *DS = cast<DoStmt>(S); 4123 bool Continue; 4124 do { 4125 EvalStmtResult ESR = EvaluateLoopBody(Result, Info, DS->getBody(), Case); 4126 if (ESR != ESR_Continue) 4127 return ESR; 4128 Case = nullptr; 4129 4130 FullExpressionRAII CondScope(Info); 4131 if (!EvaluateAsBooleanCondition(DS->getCond(), Continue, Info)) 4132 return ESR_Failed; 4133 } while (Continue); 4134 return ESR_Succeeded; 4135 } 4136 4137 case Stmt::ForStmtClass: { 4138 const ForStmt *FS = cast<ForStmt>(S); 4139 BlockScopeRAII Scope(Info); 4140 if (FS->getInit()) { 4141 EvalStmtResult ESR = EvaluateStmt(Result, Info, FS->getInit()); 4142 if (ESR != ESR_Succeeded) 4143 return ESR; 4144 } 4145 while (true) { 4146 BlockScopeRAII Scope(Info); 4147 bool Continue = true; 4148 if (FS->getCond() && !EvaluateCond(Info, FS->getConditionVariable(), 4149 FS->getCond(), Continue)) 4150 return ESR_Failed; 4151 if (!Continue) 4152 break; 4153 4154 EvalStmtResult ESR = EvaluateLoopBody(Result, Info, FS->getBody()); 4155 if (ESR != ESR_Continue) 4156 return ESR; 4157 4158 if (FS->getInc()) { 4159 FullExpressionRAII IncScope(Info); 4160 if (!EvaluateIgnoredValue(Info, FS->getInc())) 4161 return ESR_Failed; 4162 } 4163 } 4164 return ESR_Succeeded; 4165 } 4166 4167 case Stmt::CXXForRangeStmtClass: { 4168 const CXXForRangeStmt *FS = cast<CXXForRangeStmt>(S); 4169 BlockScopeRAII Scope(Info); 4170 4171 // Initialize the __range variable. 4172 EvalStmtResult ESR = EvaluateStmt(Result, Info, FS->getRangeStmt()); 4173 if (ESR != ESR_Succeeded) 4174 return ESR; 4175 4176 // Create the __begin and __end iterators. 4177 ESR = EvaluateStmt(Result, Info, FS->getBeginStmt()); 4178 if (ESR != ESR_Succeeded) 4179 return ESR; 4180 ESR = EvaluateStmt(Result, Info, FS->getEndStmt()); 4181 if (ESR != ESR_Succeeded) 4182 return ESR; 4183 4184 while (true) { 4185 // Condition: __begin != __end. 4186 { 4187 bool Continue = true; 4188 FullExpressionRAII CondExpr(Info); 4189 if (!EvaluateAsBooleanCondition(FS->getCond(), Continue, Info)) 4190 return ESR_Failed; 4191 if (!Continue) 4192 break; 4193 } 4194 4195 // User's variable declaration, initialized by *__begin. 4196 BlockScopeRAII InnerScope(Info); 4197 ESR = EvaluateStmt(Result, Info, FS->getLoopVarStmt()); 4198 if (ESR != ESR_Succeeded) 4199 return ESR; 4200 4201 // Loop body. 4202 ESR = EvaluateLoopBody(Result, Info, FS->getBody()); 4203 if (ESR != ESR_Continue) 4204 return ESR; 4205 4206 // Increment: ++__begin 4207 if (!EvaluateIgnoredValue(Info, FS->getInc())) 4208 return ESR_Failed; 4209 } 4210 4211 return ESR_Succeeded; 4212 } 4213 4214 case Stmt::SwitchStmtClass: 4215 return EvaluateSwitch(Result, Info, cast<SwitchStmt>(S)); 4216 4217 case Stmt::ContinueStmtClass: 4218 return ESR_Continue; 4219 4220 case Stmt::BreakStmtClass: 4221 return ESR_Break; 4222 4223 case Stmt::LabelStmtClass: 4224 return EvaluateStmt(Result, Info, cast<LabelStmt>(S)->getSubStmt(), Case); 4225 4226 case Stmt::AttributedStmtClass: 4227 // As a general principle, C++11 attributes can be ignored without 4228 // any semantic impact. 4229 return EvaluateStmt(Result, Info, cast<AttributedStmt>(S)->getSubStmt(), 4230 Case); 4231 4232 case Stmt::CaseStmtClass: 4233 case Stmt::DefaultStmtClass: 4234 return EvaluateStmt(Result, Info, cast<SwitchCase>(S)->getSubStmt(), Case); 4235 } 4236 } 4237 4238 /// CheckTrivialDefaultConstructor - Check whether a constructor is a trivial 4239 /// default constructor. If so, we'll fold it whether or not it's marked as 4240 /// constexpr. If it is marked as constexpr, we will never implicitly define it, 4241 /// so we need special handling. 4242 static bool CheckTrivialDefaultConstructor(EvalInfo &Info, SourceLocation Loc, 4243 const CXXConstructorDecl *CD, 4244 bool IsValueInitialization) { 4245 if (!CD->isTrivial() || !CD->isDefaultConstructor()) 4246 return false; 4247 4248 // Value-initialization does not call a trivial default constructor, so such a 4249 // call is a core constant expression whether or not the constructor is 4250 // constexpr. 4251 if (!CD->isConstexpr() && !IsValueInitialization) { 4252 if (Info.getLangOpts().CPlusPlus11) { 4253 // FIXME: If DiagDecl is an implicitly-declared special member function, 4254 // we should be much more explicit about why it's not constexpr. 4255 Info.CCEDiag(Loc, diag::note_constexpr_invalid_function, 1) 4256 << /*IsConstexpr*/0 << /*IsConstructor*/1 << CD; 4257 Info.Note(CD->getLocation(), diag::note_declared_at); 4258 } else { 4259 Info.CCEDiag(Loc, diag::note_invalid_subexpr_in_const_expr); 4260 } 4261 } 4262 return true; 4263 } 4264 4265 /// CheckConstexprFunction - Check that a function can be called in a constant 4266 /// expression. 4267 static bool CheckConstexprFunction(EvalInfo &Info, SourceLocation CallLoc, 4268 const FunctionDecl *Declaration, 4269 const FunctionDecl *Definition, 4270 const Stmt *Body) { 4271 // Potential constant expressions can contain calls to declared, but not yet 4272 // defined, constexpr functions. 4273 if (Info.checkingPotentialConstantExpression() && !Definition && 4274 Declaration->isConstexpr()) 4275 return false; 4276 4277 // Bail out with no diagnostic if the function declaration itself is invalid. 4278 // We will have produced a relevant diagnostic while parsing it. 4279 if (Declaration->isInvalidDecl()) 4280 return false; 4281 4282 // Can we evaluate this function call? 4283 if (Definition && Definition->isConstexpr() && 4284 !Definition->isInvalidDecl() && Body) 4285 return true; 4286 4287 if (Info.getLangOpts().CPlusPlus11) { 4288 const FunctionDecl *DiagDecl = Definition ? Definition : Declaration; 4289 4290 // If this function is not constexpr because it is an inherited 4291 // non-constexpr constructor, diagnose that directly. 4292 auto *CD = dyn_cast<CXXConstructorDecl>(DiagDecl); 4293 if (CD && CD->isInheritingConstructor()) { 4294 auto *Inherited = CD->getInheritedConstructor().getConstructor(); 4295 if (!Inherited->isConstexpr()) 4296 DiagDecl = CD = Inherited; 4297 } 4298 4299 // FIXME: If DiagDecl is an implicitly-declared special member function 4300 // or an inheriting constructor, we should be much more explicit about why 4301 // it's not constexpr. 4302 if (CD && CD->isInheritingConstructor()) 4303 Info.FFDiag(CallLoc, diag::note_constexpr_invalid_inhctor, 1) 4304 << CD->getInheritedConstructor().getConstructor()->getParent(); 4305 else 4306 Info.FFDiag(CallLoc, diag::note_constexpr_invalid_function, 1) 4307 << DiagDecl->isConstexpr() << (bool)CD << DiagDecl; 4308 Info.Note(DiagDecl->getLocation(), diag::note_declared_at); 4309 } else { 4310 Info.FFDiag(CallLoc, diag::note_invalid_subexpr_in_const_expr); 4311 } 4312 return false; 4313 } 4314 4315 /// Determine if a class has any fields that might need to be copied by a 4316 /// trivial copy or move operation. 4317 static bool hasFields(const CXXRecordDecl *RD) { 4318 if (!RD || RD->isEmpty()) 4319 return false; 4320 for (auto *FD : RD->fields()) { 4321 if (FD->isUnnamedBitfield()) 4322 continue; 4323 return true; 4324 } 4325 for (auto &Base : RD->bases()) 4326 if (hasFields(Base.getType()->getAsCXXRecordDecl())) 4327 return true; 4328 return false; 4329 } 4330 4331 namespace { 4332 typedef SmallVector<APValue, 8> ArgVector; 4333 } 4334 4335 /// EvaluateArgs - Evaluate the arguments to a function call. 4336 static bool EvaluateArgs(ArrayRef<const Expr*> Args, ArgVector &ArgValues, 4337 EvalInfo &Info) { 4338 bool Success = true; 4339 for (ArrayRef<const Expr*>::iterator I = Args.begin(), E = Args.end(); 4340 I != E; ++I) { 4341 if (!Evaluate(ArgValues[I - Args.begin()], Info, *I)) { 4342 // If we're checking for a potential constant expression, evaluate all 4343 // initializers even if some of them fail. 4344 if (!Info.noteFailure()) 4345 return false; 4346 Success = false; 4347 } 4348 } 4349 return Success; 4350 } 4351 4352 /// Evaluate a function call. 4353 static bool HandleFunctionCall(SourceLocation CallLoc, 4354 const FunctionDecl *Callee, const LValue *This, 4355 ArrayRef<const Expr*> Args, const Stmt *Body, 4356 EvalInfo &Info, APValue &Result, 4357 const LValue *ResultSlot) { 4358 ArgVector ArgValues(Args.size()); 4359 if (!EvaluateArgs(Args, ArgValues, Info)) 4360 return false; 4361 4362 if (!Info.CheckCallLimit(CallLoc)) 4363 return false; 4364 4365 CallStackFrame Frame(Info, CallLoc, Callee, This, ArgValues.data()); 4366 4367 // For a trivial copy or move assignment, perform an APValue copy. This is 4368 // essential for unions, where the operations performed by the assignment 4369 // operator cannot be represented as statements. 4370 // 4371 // Skip this for non-union classes with no fields; in that case, the defaulted 4372 // copy/move does not actually read the object. 4373 const CXXMethodDecl *MD = dyn_cast<CXXMethodDecl>(Callee); 4374 if (MD && MD->isDefaulted() && 4375 (MD->getParent()->isUnion() || 4376 (MD->isTrivial() && hasFields(MD->getParent())))) { 4377 assert(This && 4378 (MD->isCopyAssignmentOperator() || MD->isMoveAssignmentOperator())); 4379 LValue RHS; 4380 RHS.setFrom(Info.Ctx, ArgValues[0]); 4381 APValue RHSValue; 4382 if (!handleLValueToRValueConversion(Info, Args[0], Args[0]->getType(), 4383 RHS, RHSValue)) 4384 return false; 4385 if (!handleAssignment(Info, Args[0], *This, MD->getThisType(Info.Ctx), 4386 RHSValue)) 4387 return false; 4388 This->moveInto(Result); 4389 return true; 4390 } else if (MD && isLambdaCallOperator(MD)) { 4391 // We're in a lambda; determine the lambda capture field maps unless we're 4392 // just constexpr checking a lambda's call operator. constexpr checking is 4393 // done before the captures have been added to the closure object (unless 4394 // we're inferring constexpr-ness), so we don't have access to them in this 4395 // case. But since we don't need the captures to constexpr check, we can 4396 // just ignore them. 4397 if (!Info.checkingPotentialConstantExpression()) 4398 MD->getParent()->getCaptureFields(Frame.LambdaCaptureFields, 4399 Frame.LambdaThisCaptureField); 4400 } 4401 4402 StmtResult Ret = {Result, ResultSlot}; 4403 EvalStmtResult ESR = EvaluateStmt(Ret, Info, Body); 4404 if (ESR == ESR_Succeeded) { 4405 if (Callee->getReturnType()->isVoidType()) 4406 return true; 4407 Info.FFDiag(Callee->getLocEnd(), diag::note_constexpr_no_return); 4408 } 4409 return ESR == ESR_Returned; 4410 } 4411 4412 /// Evaluate a constructor call. 4413 static bool HandleConstructorCall(const Expr *E, const LValue &This, 4414 APValue *ArgValues, 4415 const CXXConstructorDecl *Definition, 4416 EvalInfo &Info, APValue &Result) { 4417 SourceLocation CallLoc = E->getExprLoc(); 4418 if (!Info.CheckCallLimit(CallLoc)) 4419 return false; 4420 4421 const CXXRecordDecl *RD = Definition->getParent(); 4422 if (RD->getNumVBases()) { 4423 Info.FFDiag(CallLoc, diag::note_constexpr_virtual_base) << RD; 4424 return false; 4425 } 4426 4427 EvalInfo::EvaluatingConstructorRAII EvalObj( 4428 Info, {This.getLValueBase(), 4429 {This.getLValueCallIndex(), This.getLValueVersion()}}); 4430 CallStackFrame Frame(Info, CallLoc, Definition, &This, ArgValues); 4431 4432 // FIXME: Creating an APValue just to hold a nonexistent return value is 4433 // wasteful. 4434 APValue RetVal; 4435 StmtResult Ret = {RetVal, nullptr}; 4436 4437 // If it's a delegating constructor, delegate. 4438 if (Definition->isDelegatingConstructor()) { 4439 CXXConstructorDecl::init_const_iterator I = Definition->init_begin(); 4440 { 4441 FullExpressionRAII InitScope(Info); 4442 if (!EvaluateInPlace(Result, Info, This, (*I)->getInit())) 4443 return false; 4444 } 4445 return EvaluateStmt(Ret, Info, Definition->getBody()) != ESR_Failed; 4446 } 4447 4448 // For a trivial copy or move constructor, perform an APValue copy. This is 4449 // essential for unions (or classes with anonymous union members), where the 4450 // operations performed by the constructor cannot be represented by 4451 // ctor-initializers. 4452 // 4453 // Skip this for empty non-union classes; we should not perform an 4454 // lvalue-to-rvalue conversion on them because their copy constructor does not 4455 // actually read them. 4456 if (Definition->isDefaulted() && Definition->isCopyOrMoveConstructor() && 4457 (Definition->getParent()->isUnion() || 4458 (Definition->isTrivial() && hasFields(Definition->getParent())))) { 4459 LValue RHS; 4460 RHS.setFrom(Info.Ctx, ArgValues[0]); 4461 return handleLValueToRValueConversion( 4462 Info, E, Definition->getParamDecl(0)->getType().getNonReferenceType(), 4463 RHS, Result); 4464 } 4465 4466 // Reserve space for the struct members. 4467 if (!RD->isUnion() && Result.isUninit()) 4468 Result = APValue(APValue::UninitStruct(), RD->getNumBases(), 4469 std::distance(RD->field_begin(), RD->field_end())); 4470 4471 if (RD->isInvalidDecl()) return false; 4472 const ASTRecordLayout &Layout = Info.Ctx.getASTRecordLayout(RD); 4473 4474 // A scope for temporaries lifetime-extended by reference members. 4475 BlockScopeRAII LifetimeExtendedScope(Info); 4476 4477 bool Success = true; 4478 unsigned BasesSeen = 0; 4479 #ifndef NDEBUG 4480 CXXRecordDecl::base_class_const_iterator BaseIt = RD->bases_begin(); 4481 #endif 4482 for (const auto *I : Definition->inits()) { 4483 LValue Subobject = This; 4484 LValue SubobjectParent = This; 4485 APValue *Value = &Result; 4486 4487 // Determine the subobject to initialize. 4488 FieldDecl *FD = nullptr; 4489 if (I->isBaseInitializer()) { 4490 QualType BaseType(I->getBaseClass(), 0); 4491 #ifndef NDEBUG 4492 // Non-virtual base classes are initialized in the order in the class 4493 // definition. We have already checked for virtual base classes. 4494 assert(!BaseIt->isVirtual() && "virtual base for literal type"); 4495 assert(Info.Ctx.hasSameType(BaseIt->getType(), BaseType) && 4496 "base class initializers not in expected order"); 4497 ++BaseIt; 4498 #endif 4499 if (!HandleLValueDirectBase(Info, I->getInit(), Subobject, RD, 4500 BaseType->getAsCXXRecordDecl(), &Layout)) 4501 return false; 4502 Value = &Result.getStructBase(BasesSeen++); 4503 } else if ((FD = I->getMember())) { 4504 if (!HandleLValueMember(Info, I->getInit(), Subobject, FD, &Layout)) 4505 return false; 4506 if (RD->isUnion()) { 4507 Result = APValue(FD); 4508 Value = &Result.getUnionValue(); 4509 } else { 4510 Value = &Result.getStructField(FD->getFieldIndex()); 4511 } 4512 } else if (IndirectFieldDecl *IFD = I->getIndirectMember()) { 4513 // Walk the indirect field decl's chain to find the object to initialize, 4514 // and make sure we've initialized every step along it. 4515 auto IndirectFieldChain = IFD->chain(); 4516 for (auto *C : IndirectFieldChain) { 4517 FD = cast<FieldDecl>(C); 4518 CXXRecordDecl *CD = cast<CXXRecordDecl>(FD->getParent()); 4519 // Switch the union field if it differs. This happens if we had 4520 // preceding zero-initialization, and we're now initializing a union 4521 // subobject other than the first. 4522 // FIXME: In this case, the values of the other subobjects are 4523 // specified, since zero-initialization sets all padding bits to zero. 4524 if (Value->isUninit() || 4525 (Value->isUnion() && Value->getUnionField() != FD)) { 4526 if (CD->isUnion()) 4527 *Value = APValue(FD); 4528 else 4529 *Value = APValue(APValue::UninitStruct(), CD->getNumBases(), 4530 std::distance(CD->field_begin(), CD->field_end())); 4531 } 4532 // Store Subobject as its parent before updating it for the last element 4533 // in the chain. 4534 if (C == IndirectFieldChain.back()) 4535 SubobjectParent = Subobject; 4536 if (!HandleLValueMember(Info, I->getInit(), Subobject, FD)) 4537 return false; 4538 if (CD->isUnion()) 4539 Value = &Value->getUnionValue(); 4540 else 4541 Value = &Value->getStructField(FD->getFieldIndex()); 4542 } 4543 } else { 4544 llvm_unreachable("unknown base initializer kind"); 4545 } 4546 4547 // Need to override This for implicit field initializers as in this case 4548 // This refers to innermost anonymous struct/union containing initializer, 4549 // not to currently constructed class. 4550 const Expr *Init = I->getInit(); 4551 ThisOverrideRAII ThisOverride(*Info.CurrentCall, &SubobjectParent, 4552 isa<CXXDefaultInitExpr>(Init)); 4553 FullExpressionRAII InitScope(Info); 4554 if (!EvaluateInPlace(*Value, Info, Subobject, Init) || 4555 (FD && FD->isBitField() && 4556 !truncateBitfieldValue(Info, Init, *Value, FD))) { 4557 // If we're checking for a potential constant expression, evaluate all 4558 // initializers even if some of them fail. 4559 if (!Info.noteFailure()) 4560 return false; 4561 Success = false; 4562 } 4563 } 4564 4565 return Success && 4566 EvaluateStmt(Ret, Info, Definition->getBody()) != ESR_Failed; 4567 } 4568 4569 static bool HandleConstructorCall(const Expr *E, const LValue &This, 4570 ArrayRef<const Expr*> Args, 4571 const CXXConstructorDecl *Definition, 4572 EvalInfo &Info, APValue &Result) { 4573 ArgVector ArgValues(Args.size()); 4574 if (!EvaluateArgs(Args, ArgValues, Info)) 4575 return false; 4576 4577 return HandleConstructorCall(E, This, ArgValues.data(), Definition, 4578 Info, Result); 4579 } 4580 4581 //===----------------------------------------------------------------------===// 4582 // Generic Evaluation 4583 //===----------------------------------------------------------------------===// 4584 namespace { 4585 4586 template <class Derived> 4587 class ExprEvaluatorBase 4588 : public ConstStmtVisitor<Derived, bool> { 4589 private: 4590 Derived &getDerived() { return static_cast<Derived&>(*this); } 4591 bool DerivedSuccess(const APValue &V, const Expr *E) { 4592 return getDerived().Success(V, E); 4593 } 4594 bool DerivedZeroInitialization(const Expr *E) { 4595 return getDerived().ZeroInitialization(E); 4596 } 4597 4598 // Check whether a conditional operator with a non-constant condition is a 4599 // potential constant expression. If neither arm is a potential constant 4600 // expression, then the conditional operator is not either. 4601 template<typename ConditionalOperator> 4602 void CheckPotentialConstantConditional(const ConditionalOperator *E) { 4603 assert(Info.checkingPotentialConstantExpression()); 4604 4605 // Speculatively evaluate both arms. 4606 SmallVector<PartialDiagnosticAt, 8> Diag; 4607 { 4608 SpeculativeEvaluationRAII Speculate(Info, &Diag); 4609 StmtVisitorTy::Visit(E->getFalseExpr()); 4610 if (Diag.empty()) 4611 return; 4612 } 4613 4614 { 4615 SpeculativeEvaluationRAII Speculate(Info, &Diag); 4616 Diag.clear(); 4617 StmtVisitorTy::Visit(E->getTrueExpr()); 4618 if (Diag.empty()) 4619 return; 4620 } 4621 4622 Error(E, diag::note_constexpr_conditional_never_const); 4623 } 4624 4625 4626 template<typename ConditionalOperator> 4627 bool HandleConditionalOperator(const ConditionalOperator *E) { 4628 bool BoolResult; 4629 if (!EvaluateAsBooleanCondition(E->getCond(), BoolResult, Info)) { 4630 if (Info.checkingPotentialConstantExpression() && Info.noteFailure()) { 4631 CheckPotentialConstantConditional(E); 4632 return false; 4633 } 4634 if (Info.noteFailure()) { 4635 StmtVisitorTy::Visit(E->getTrueExpr()); 4636 StmtVisitorTy::Visit(E->getFalseExpr()); 4637 } 4638 return false; 4639 } 4640 4641 Expr *EvalExpr = BoolResult ? E->getTrueExpr() : E->getFalseExpr(); 4642 return StmtVisitorTy::Visit(EvalExpr); 4643 } 4644 4645 protected: 4646 EvalInfo &Info; 4647 typedef ConstStmtVisitor<Derived, bool> StmtVisitorTy; 4648 typedef ExprEvaluatorBase ExprEvaluatorBaseTy; 4649 4650 OptionalDiagnostic CCEDiag(const Expr *E, diag::kind D) { 4651 return Info.CCEDiag(E, D); 4652 } 4653 4654 bool ZeroInitialization(const Expr *E) { return Error(E); } 4655 4656 public: 4657 ExprEvaluatorBase(EvalInfo &Info) : Info(Info) {} 4658 4659 EvalInfo &getEvalInfo() { return Info; } 4660 4661 /// Report an evaluation error. This should only be called when an error is 4662 /// first discovered. When propagating an error, just return false. 4663 bool Error(const Expr *E, diag::kind D) { 4664 Info.FFDiag(E, D); 4665 return false; 4666 } 4667 bool Error(const Expr *E) { 4668 return Error(E, diag::note_invalid_subexpr_in_const_expr); 4669 } 4670 4671 bool VisitStmt(const Stmt *) { 4672 llvm_unreachable("Expression evaluator should not be called on stmts"); 4673 } 4674 bool VisitExpr(const Expr *E) { 4675 return Error(E); 4676 } 4677 4678 bool VisitParenExpr(const ParenExpr *E) 4679 { return StmtVisitorTy::Visit(E->getSubExpr()); } 4680 bool VisitUnaryExtension(const UnaryOperator *E) 4681 { return StmtVisitorTy::Visit(E->getSubExpr()); } 4682 bool VisitUnaryPlus(const UnaryOperator *E) 4683 { return StmtVisitorTy::Visit(E->getSubExpr()); } 4684 bool VisitChooseExpr(const ChooseExpr *E) 4685 { return StmtVisitorTy::Visit(E->getChosenSubExpr()); } 4686 bool VisitGenericSelectionExpr(const GenericSelectionExpr *E) 4687 { return StmtVisitorTy::Visit(E->getResultExpr()); } 4688 bool VisitSubstNonTypeTemplateParmExpr(const SubstNonTypeTemplateParmExpr *E) 4689 { return StmtVisitorTy::Visit(E->getReplacement()); } 4690 bool VisitCXXDefaultArgExpr(const CXXDefaultArgExpr *E) { 4691 TempVersionRAII RAII(*Info.CurrentCall); 4692 return StmtVisitorTy::Visit(E->getExpr()); 4693 } 4694 bool VisitCXXDefaultInitExpr(const CXXDefaultInitExpr *E) { 4695 TempVersionRAII RAII(*Info.CurrentCall); 4696 // The initializer may not have been parsed yet, or might be erroneous. 4697 if (!E->getExpr()) 4698 return Error(E); 4699 return StmtVisitorTy::Visit(E->getExpr()); 4700 } 4701 // We cannot create any objects for which cleanups are required, so there is 4702 // nothing to do here; all cleanups must come from unevaluated subexpressions. 4703 bool VisitExprWithCleanups(const ExprWithCleanups *E) 4704 { return StmtVisitorTy::Visit(E->getSubExpr()); } 4705 4706 bool VisitCXXReinterpretCastExpr(const CXXReinterpretCastExpr *E) { 4707 CCEDiag(E, diag::note_constexpr_invalid_cast) << 0; 4708 return static_cast<Derived*>(this)->VisitCastExpr(E); 4709 } 4710 bool VisitCXXDynamicCastExpr(const CXXDynamicCastExpr *E) { 4711 CCEDiag(E, diag::note_constexpr_invalid_cast) << 1; 4712 return static_cast<Derived*>(this)->VisitCastExpr(E); 4713 } 4714 4715 bool VisitBinaryOperator(const BinaryOperator *E) { 4716 switch (E->getOpcode()) { 4717 default: 4718 return Error(E); 4719 4720 case BO_Comma: 4721 VisitIgnoredValue(E->getLHS()); 4722 return StmtVisitorTy::Visit(E->getRHS()); 4723 4724 case BO_PtrMemD: 4725 case BO_PtrMemI: { 4726 LValue Obj; 4727 if (!HandleMemberPointerAccess(Info, E, Obj)) 4728 return false; 4729 APValue Result; 4730 if (!handleLValueToRValueConversion(Info, E, E->getType(), Obj, Result)) 4731 return false; 4732 return DerivedSuccess(Result, E); 4733 } 4734 } 4735 } 4736 4737 bool VisitBinaryConditionalOperator(const BinaryConditionalOperator *E) { 4738 // Evaluate and cache the common expression. We treat it as a temporary, 4739 // even though it's not quite the same thing. 4740 if (!Evaluate(Info.CurrentCall->createTemporary(E->getOpaqueValue(), false), 4741 Info, E->getCommon())) 4742 return false; 4743 4744 return HandleConditionalOperator(E); 4745 } 4746 4747 bool VisitConditionalOperator(const ConditionalOperator *E) { 4748 bool IsBcpCall = false; 4749 // If the condition (ignoring parens) is a __builtin_constant_p call, 4750 // the result is a constant expression if it can be folded without 4751 // side-effects. This is an important GNU extension. See GCC PR38377 4752 // for discussion. 4753 if (const CallExpr *CallCE = 4754 dyn_cast<CallExpr>(E->getCond()->IgnoreParenCasts())) 4755 if (CallCE->getBuiltinCallee() == Builtin::BI__builtin_constant_p) 4756 IsBcpCall = true; 4757 4758 // Always assume __builtin_constant_p(...) ? ... : ... is a potential 4759 // constant expression; we can't check whether it's potentially foldable. 4760 if (Info.checkingPotentialConstantExpression() && IsBcpCall) 4761 return false; 4762 4763 FoldConstant Fold(Info, IsBcpCall); 4764 if (!HandleConditionalOperator(E)) { 4765 Fold.keepDiagnostics(); 4766 return false; 4767 } 4768 4769 return true; 4770 } 4771 4772 bool VisitOpaqueValueExpr(const OpaqueValueExpr *E) { 4773 if (APValue *Value = Info.CurrentCall->getCurrentTemporary(E)) 4774 return DerivedSuccess(*Value, E); 4775 4776 const Expr *Source = E->getSourceExpr(); 4777 if (!Source) 4778 return Error(E); 4779 if (Source == E) { // sanity checking. 4780 assert(0 && "OpaqueValueExpr recursively refers to itself"); 4781 return Error(E); 4782 } 4783 return StmtVisitorTy::Visit(Source); 4784 } 4785 4786 bool VisitCallExpr(const CallExpr *E) { 4787 APValue Result; 4788 if (!handleCallExpr(E, Result, nullptr)) 4789 return false; 4790 return DerivedSuccess(Result, E); 4791 } 4792 4793 bool handleCallExpr(const CallExpr *E, APValue &Result, 4794 const LValue *ResultSlot) { 4795 const Expr *Callee = E->getCallee()->IgnoreParens(); 4796 QualType CalleeType = Callee->getType(); 4797 4798 const FunctionDecl *FD = nullptr; 4799 LValue *This = nullptr, ThisVal; 4800 auto Args = llvm::makeArrayRef(E->getArgs(), E->getNumArgs()); 4801 bool HasQualifier = false; 4802 4803 // Extract function decl and 'this' pointer from the callee. 4804 if (CalleeType->isSpecificBuiltinType(BuiltinType::BoundMember)) { 4805 const ValueDecl *Member = nullptr; 4806 if (const MemberExpr *ME = dyn_cast<MemberExpr>(Callee)) { 4807 // Explicit bound member calls, such as x.f() or p->g(); 4808 if (!EvaluateObjectArgument(Info, ME->getBase(), ThisVal)) 4809 return false; 4810 Member = ME->getMemberDecl(); 4811 This = &ThisVal; 4812 HasQualifier = ME->hasQualifier(); 4813 } else if (const BinaryOperator *BE = dyn_cast<BinaryOperator>(Callee)) { 4814 // Indirect bound member calls ('.*' or '->*'). 4815 Member = HandleMemberPointerAccess(Info, BE, ThisVal, false); 4816 if (!Member) return false; 4817 This = &ThisVal; 4818 } else 4819 return Error(Callee); 4820 4821 FD = dyn_cast<FunctionDecl>(Member); 4822 if (!FD) 4823 return Error(Callee); 4824 } else if (CalleeType->isFunctionPointerType()) { 4825 LValue Call; 4826 if (!EvaluatePointer(Callee, Call, Info)) 4827 return false; 4828 4829 if (!Call.getLValueOffset().isZero()) 4830 return Error(Callee); 4831 FD = dyn_cast_or_null<FunctionDecl>( 4832 Call.getLValueBase().dyn_cast<const ValueDecl*>()); 4833 if (!FD) 4834 return Error(Callee); 4835 // Don't call function pointers which have been cast to some other type. 4836 // Per DR (no number yet), the caller and callee can differ in noexcept. 4837 if (!Info.Ctx.hasSameFunctionTypeIgnoringExceptionSpec( 4838 CalleeType->getPointeeType(), FD->getType())) { 4839 return Error(E); 4840 } 4841 4842 // Overloaded operator calls to member functions are represented as normal 4843 // calls with '*this' as the first argument. 4844 const CXXMethodDecl *MD = dyn_cast<CXXMethodDecl>(FD); 4845 if (MD && !MD->isStatic()) { 4846 // FIXME: When selecting an implicit conversion for an overloaded 4847 // operator delete, we sometimes try to evaluate calls to conversion 4848 // operators without a 'this' parameter! 4849 if (Args.empty()) 4850 return Error(E); 4851 4852 if (!EvaluateObjectArgument(Info, Args[0], ThisVal)) 4853 return false; 4854 This = &ThisVal; 4855 Args = Args.slice(1); 4856 } else if (MD && MD->isLambdaStaticInvoker()) { 4857 // Map the static invoker for the lambda back to the call operator. 4858 // Conveniently, we don't have to slice out the 'this' argument (as is 4859 // being done for the non-static case), since a static member function 4860 // doesn't have an implicit argument passed in. 4861 const CXXRecordDecl *ClosureClass = MD->getParent(); 4862 assert( 4863 ClosureClass->captures_begin() == ClosureClass->captures_end() && 4864 "Number of captures must be zero for conversion to function-ptr"); 4865 4866 const CXXMethodDecl *LambdaCallOp = 4867 ClosureClass->getLambdaCallOperator(); 4868 4869 // Set 'FD', the function that will be called below, to the call 4870 // operator. If the closure object represents a generic lambda, find 4871 // the corresponding specialization of the call operator. 4872 4873 if (ClosureClass->isGenericLambda()) { 4874 assert(MD->isFunctionTemplateSpecialization() && 4875 "A generic lambda's static-invoker function must be a " 4876 "template specialization"); 4877 const TemplateArgumentList *TAL = MD->getTemplateSpecializationArgs(); 4878 FunctionTemplateDecl *CallOpTemplate = 4879 LambdaCallOp->getDescribedFunctionTemplate(); 4880 void *InsertPos = nullptr; 4881 FunctionDecl *CorrespondingCallOpSpecialization = 4882 CallOpTemplate->findSpecialization(TAL->asArray(), InsertPos); 4883 assert(CorrespondingCallOpSpecialization && 4884 "We must always have a function call operator specialization " 4885 "that corresponds to our static invoker specialization"); 4886 FD = cast<CXXMethodDecl>(CorrespondingCallOpSpecialization); 4887 } else 4888 FD = LambdaCallOp; 4889 } 4890 4891 4892 } else 4893 return Error(E); 4894 4895 if (This && !This->checkSubobject(Info, E, CSK_This)) 4896 return false; 4897 4898 // DR1358 allows virtual constexpr functions in some cases. Don't allow 4899 // calls to such functions in constant expressions. 4900 if (This && !HasQualifier && 4901 isa<CXXMethodDecl>(FD) && cast<CXXMethodDecl>(FD)->isVirtual()) 4902 return Error(E, diag::note_constexpr_virtual_call); 4903 4904 const FunctionDecl *Definition = nullptr; 4905 Stmt *Body = FD->getBody(Definition); 4906 4907 if (!CheckConstexprFunction(Info, E->getExprLoc(), FD, Definition, Body) || 4908 !HandleFunctionCall(E->getExprLoc(), Definition, This, Args, Body, Info, 4909 Result, ResultSlot)) 4910 return false; 4911 4912 return true; 4913 } 4914 4915 bool VisitCompoundLiteralExpr(const CompoundLiteralExpr *E) { 4916 return StmtVisitorTy::Visit(E->getInitializer()); 4917 } 4918 bool VisitInitListExpr(const InitListExpr *E) { 4919 if (E->getNumInits() == 0) 4920 return DerivedZeroInitialization(E); 4921 if (E->getNumInits() == 1) 4922 return StmtVisitorTy::Visit(E->getInit(0)); 4923 return Error(E); 4924 } 4925 bool VisitImplicitValueInitExpr(const ImplicitValueInitExpr *E) { 4926 return DerivedZeroInitialization(E); 4927 } 4928 bool VisitCXXScalarValueInitExpr(const CXXScalarValueInitExpr *E) { 4929 return DerivedZeroInitialization(E); 4930 } 4931 bool VisitCXXNullPtrLiteralExpr(const CXXNullPtrLiteralExpr *E) { 4932 return DerivedZeroInitialization(E); 4933 } 4934 4935 /// A member expression where the object is a prvalue is itself a prvalue. 4936 bool VisitMemberExpr(const MemberExpr *E) { 4937 assert(!E->isArrow() && "missing call to bound member function?"); 4938 4939 APValue Val; 4940 if (!Evaluate(Val, Info, E->getBase())) 4941 return false; 4942 4943 QualType BaseTy = E->getBase()->getType(); 4944 4945 const FieldDecl *FD = dyn_cast<FieldDecl>(E->getMemberDecl()); 4946 if (!FD) return Error(E); 4947 assert(!FD->getType()->isReferenceType() && "prvalue reference?"); 4948 assert(BaseTy->castAs<RecordType>()->getDecl()->getCanonicalDecl() == 4949 FD->getParent()->getCanonicalDecl() && "record / field mismatch"); 4950 4951 CompleteObject Obj(&Val, BaseTy, true); 4952 SubobjectDesignator Designator(BaseTy); 4953 Designator.addDeclUnchecked(FD); 4954 4955 APValue Result; 4956 return extractSubobject(Info, E, Obj, Designator, Result) && 4957 DerivedSuccess(Result, E); 4958 } 4959 4960 bool VisitCastExpr(const CastExpr *E) { 4961 switch (E->getCastKind()) { 4962 default: 4963 break; 4964 4965 case CK_AtomicToNonAtomic: { 4966 APValue AtomicVal; 4967 // This does not need to be done in place even for class/array types: 4968 // atomic-to-non-atomic conversion implies copying the object 4969 // representation. 4970 if (!Evaluate(AtomicVal, Info, E->getSubExpr())) 4971 return false; 4972 return DerivedSuccess(AtomicVal, E); 4973 } 4974 4975 case CK_NoOp: 4976 case CK_UserDefinedConversion: 4977 return StmtVisitorTy::Visit(E->getSubExpr()); 4978 4979 case CK_LValueToRValue: { 4980 LValue LVal; 4981 if (!EvaluateLValue(E->getSubExpr(), LVal, Info)) 4982 return false; 4983 APValue RVal; 4984 // Note, we use the subexpression's type in order to retain cv-qualifiers. 4985 if (!handleLValueToRValueConversion(Info, E, E->getSubExpr()->getType(), 4986 LVal, RVal)) 4987 return false; 4988 return DerivedSuccess(RVal, E); 4989 } 4990 } 4991 4992 return Error(E); 4993 } 4994 4995 bool VisitUnaryPostInc(const UnaryOperator *UO) { 4996 return VisitUnaryPostIncDec(UO); 4997 } 4998 bool VisitUnaryPostDec(const UnaryOperator *UO) { 4999 return VisitUnaryPostIncDec(UO); 5000 } 5001 bool VisitUnaryPostIncDec(const UnaryOperator *UO) { 5002 if (!Info.getLangOpts().CPlusPlus14 && !Info.keepEvaluatingAfterFailure()) 5003 return Error(UO); 5004 5005 LValue LVal; 5006 if (!EvaluateLValue(UO->getSubExpr(), LVal, Info)) 5007 return false; 5008 APValue RVal; 5009 if (!handleIncDec(this->Info, UO, LVal, UO->getSubExpr()->getType(), 5010 UO->isIncrementOp(), &RVal)) 5011 return false; 5012 return DerivedSuccess(RVal, UO); 5013 } 5014 5015 bool VisitStmtExpr(const StmtExpr *E) { 5016 // We will have checked the full-expressions inside the statement expression 5017 // when they were completed, and don't need to check them again now. 5018 if (Info.checkingForOverflow()) 5019 return Error(E); 5020 5021 BlockScopeRAII Scope(Info); 5022 const CompoundStmt *CS = E->getSubStmt(); 5023 if (CS->body_empty()) 5024 return true; 5025 5026 for (CompoundStmt::const_body_iterator BI = CS->body_begin(), 5027 BE = CS->body_end(); 5028 /**/; ++BI) { 5029 if (BI + 1 == BE) { 5030 const Expr *FinalExpr = dyn_cast<Expr>(*BI); 5031 if (!FinalExpr) { 5032 Info.FFDiag((*BI)->getLocStart(), 5033 diag::note_constexpr_stmt_expr_unsupported); 5034 return false; 5035 } 5036 return this->Visit(FinalExpr); 5037 } 5038 5039 APValue ReturnValue; 5040 StmtResult Result = { ReturnValue, nullptr }; 5041 EvalStmtResult ESR = EvaluateStmt(Result, Info, *BI); 5042 if (ESR != ESR_Succeeded) { 5043 // FIXME: If the statement-expression terminated due to 'return', 5044 // 'break', or 'continue', it would be nice to propagate that to 5045 // the outer statement evaluation rather than bailing out. 5046 if (ESR != ESR_Failed) 5047 Info.FFDiag((*BI)->getLocStart(), 5048 diag::note_constexpr_stmt_expr_unsupported); 5049 return false; 5050 } 5051 } 5052 5053 llvm_unreachable("Return from function from the loop above."); 5054 } 5055 5056 /// Visit a value which is evaluated, but whose value is ignored. 5057 void VisitIgnoredValue(const Expr *E) { 5058 EvaluateIgnoredValue(Info, E); 5059 } 5060 5061 /// Potentially visit a MemberExpr's base expression. 5062 void VisitIgnoredBaseExpression(const Expr *E) { 5063 // While MSVC doesn't evaluate the base expression, it does diagnose the 5064 // presence of side-effecting behavior. 5065 if (Info.getLangOpts().MSVCCompat && !E->HasSideEffects(Info.Ctx)) 5066 return; 5067 VisitIgnoredValue(E); 5068 } 5069 }; 5070 5071 } // namespace 5072 5073 //===----------------------------------------------------------------------===// 5074 // Common base class for lvalue and temporary evaluation. 5075 //===----------------------------------------------------------------------===// 5076 namespace { 5077 template<class Derived> 5078 class LValueExprEvaluatorBase 5079 : public ExprEvaluatorBase<Derived> { 5080 protected: 5081 LValue &Result; 5082 bool InvalidBaseOK; 5083 typedef LValueExprEvaluatorBase LValueExprEvaluatorBaseTy; 5084 typedef ExprEvaluatorBase<Derived> ExprEvaluatorBaseTy; 5085 5086 bool Success(APValue::LValueBase B) { 5087 Result.set(B); 5088 return true; 5089 } 5090 5091 bool evaluatePointer(const Expr *E, LValue &Result) { 5092 return EvaluatePointer(E, Result, this->Info, InvalidBaseOK); 5093 } 5094 5095 public: 5096 LValueExprEvaluatorBase(EvalInfo &Info, LValue &Result, bool InvalidBaseOK) 5097 : ExprEvaluatorBaseTy(Info), Result(Result), 5098 InvalidBaseOK(InvalidBaseOK) {} 5099 5100 bool Success(const APValue &V, const Expr *E) { 5101 Result.setFrom(this->Info.Ctx, V); 5102 return true; 5103 } 5104 5105 bool VisitMemberExpr(const MemberExpr *E) { 5106 // Handle non-static data members. 5107 QualType BaseTy; 5108 bool EvalOK; 5109 if (E->isArrow()) { 5110 EvalOK = evaluatePointer(E->getBase(), Result); 5111 BaseTy = E->getBase()->getType()->castAs<PointerType>()->getPointeeType(); 5112 } else if (E->getBase()->isRValue()) { 5113 assert(E->getBase()->getType()->isRecordType()); 5114 EvalOK = EvaluateTemporary(E->getBase(), Result, this->Info); 5115 BaseTy = E->getBase()->getType(); 5116 } else { 5117 EvalOK = this->Visit(E->getBase()); 5118 BaseTy = E->getBase()->getType(); 5119 } 5120 if (!EvalOK) { 5121 if (!InvalidBaseOK) 5122 return false; 5123 Result.setInvalid(E); 5124 return true; 5125 } 5126 5127 const ValueDecl *MD = E->getMemberDecl(); 5128 if (const FieldDecl *FD = dyn_cast<FieldDecl>(E->getMemberDecl())) { 5129 assert(BaseTy->getAs<RecordType>()->getDecl()->getCanonicalDecl() == 5130 FD->getParent()->getCanonicalDecl() && "record / field mismatch"); 5131 (void)BaseTy; 5132 if (!HandleLValueMember(this->Info, E, Result, FD)) 5133 return false; 5134 } else if (const IndirectFieldDecl *IFD = dyn_cast<IndirectFieldDecl>(MD)) { 5135 if (!HandleLValueIndirectMember(this->Info, E, Result, IFD)) 5136 return false; 5137 } else 5138 return this->Error(E); 5139 5140 if (MD->getType()->isReferenceType()) { 5141 APValue RefValue; 5142 if (!handleLValueToRValueConversion(this->Info, E, MD->getType(), Result, 5143 RefValue)) 5144 return false; 5145 return Success(RefValue, E); 5146 } 5147 return true; 5148 } 5149 5150 bool VisitBinaryOperator(const BinaryOperator *E) { 5151 switch (E->getOpcode()) { 5152 default: 5153 return ExprEvaluatorBaseTy::VisitBinaryOperator(E); 5154 5155 case BO_PtrMemD: 5156 case BO_PtrMemI: 5157 return HandleMemberPointerAccess(this->Info, E, Result); 5158 } 5159 } 5160 5161 bool VisitCastExpr(const CastExpr *E) { 5162 switch (E->getCastKind()) { 5163 default: 5164 return ExprEvaluatorBaseTy::VisitCastExpr(E); 5165 5166 case CK_DerivedToBase: 5167 case CK_UncheckedDerivedToBase: 5168 if (!this->Visit(E->getSubExpr())) 5169 return false; 5170 5171 // Now figure out the necessary offset to add to the base LV to get from 5172 // the derived class to the base class. 5173 return HandleLValueBasePath(this->Info, E, E->getSubExpr()->getType(), 5174 Result); 5175 } 5176 } 5177 }; 5178 } 5179 5180 //===----------------------------------------------------------------------===// 5181 // LValue Evaluation 5182 // 5183 // This is used for evaluating lvalues (in C and C++), xvalues (in C++11), 5184 // function designators (in C), decl references to void objects (in C), and 5185 // temporaries (if building with -Wno-address-of-temporary). 5186 // 5187 // LValue evaluation produces values comprising a base expression of one of the 5188 // following types: 5189 // - Declarations 5190 // * VarDecl 5191 // * FunctionDecl 5192 // - Literals 5193 // * CompoundLiteralExpr in C (and in global scope in C++) 5194 // * StringLiteral 5195 // * CXXTypeidExpr 5196 // * PredefinedExpr 5197 // * ObjCStringLiteralExpr 5198 // * ObjCEncodeExpr 5199 // * AddrLabelExpr 5200 // * BlockExpr 5201 // * CallExpr for a MakeStringConstant builtin 5202 // - Locals and temporaries 5203 // * MaterializeTemporaryExpr 5204 // * Any Expr, with a CallIndex indicating the function in which the temporary 5205 // was evaluated, for cases where the MaterializeTemporaryExpr is missing 5206 // from the AST (FIXME). 5207 // * A MaterializeTemporaryExpr that has static storage duration, with no 5208 // CallIndex, for a lifetime-extended temporary. 5209 // plus an offset in bytes. 5210 //===----------------------------------------------------------------------===// 5211 namespace { 5212 class LValueExprEvaluator 5213 : public LValueExprEvaluatorBase<LValueExprEvaluator> { 5214 public: 5215 LValueExprEvaluator(EvalInfo &Info, LValue &Result, bool InvalidBaseOK) : 5216 LValueExprEvaluatorBaseTy(Info, Result, InvalidBaseOK) {} 5217 5218 bool VisitVarDecl(const Expr *E, const VarDecl *VD); 5219 bool VisitUnaryPreIncDec(const UnaryOperator *UO); 5220 5221 bool VisitDeclRefExpr(const DeclRefExpr *E); 5222 bool VisitPredefinedExpr(const PredefinedExpr *E) { return Success(E); } 5223 bool VisitMaterializeTemporaryExpr(const MaterializeTemporaryExpr *E); 5224 bool VisitCompoundLiteralExpr(const CompoundLiteralExpr *E); 5225 bool VisitMemberExpr(const MemberExpr *E); 5226 bool VisitStringLiteral(const StringLiteral *E) { return Success(E); } 5227 bool VisitObjCEncodeExpr(const ObjCEncodeExpr *E) { return Success(E); } 5228 bool VisitCXXTypeidExpr(const CXXTypeidExpr *E); 5229 bool VisitCXXUuidofExpr(const CXXUuidofExpr *E); 5230 bool VisitArraySubscriptExpr(const ArraySubscriptExpr *E); 5231 bool VisitUnaryDeref(const UnaryOperator *E); 5232 bool VisitUnaryReal(const UnaryOperator *E); 5233 bool VisitUnaryImag(const UnaryOperator *E); 5234 bool VisitUnaryPreInc(const UnaryOperator *UO) { 5235 return VisitUnaryPreIncDec(UO); 5236 } 5237 bool VisitUnaryPreDec(const UnaryOperator *UO) { 5238 return VisitUnaryPreIncDec(UO); 5239 } 5240 bool VisitBinAssign(const BinaryOperator *BO); 5241 bool VisitCompoundAssignOperator(const CompoundAssignOperator *CAO); 5242 5243 bool VisitCastExpr(const CastExpr *E) { 5244 switch (E->getCastKind()) { 5245 default: 5246 return LValueExprEvaluatorBaseTy::VisitCastExpr(E); 5247 5248 case CK_LValueBitCast: 5249 this->CCEDiag(E, diag::note_constexpr_invalid_cast) << 2; 5250 if (!Visit(E->getSubExpr())) 5251 return false; 5252 Result.Designator.setInvalid(); 5253 return true; 5254 5255 case CK_BaseToDerived: 5256 if (!Visit(E->getSubExpr())) 5257 return false; 5258 return HandleBaseToDerivedCast(Info, E, Result); 5259 } 5260 } 5261 }; 5262 } // end anonymous namespace 5263 5264 /// Evaluate an expression as an lvalue. This can be legitimately called on 5265 /// expressions which are not glvalues, in three cases: 5266 /// * function designators in C, and 5267 /// * "extern void" objects 5268 /// * @selector() expressions in Objective-C 5269 static bool EvaluateLValue(const Expr *E, LValue &Result, EvalInfo &Info, 5270 bool InvalidBaseOK) { 5271 assert(E->isGLValue() || E->getType()->isFunctionType() || 5272 E->getType()->isVoidType() || isa<ObjCSelectorExpr>(E)); 5273 return LValueExprEvaluator(Info, Result, InvalidBaseOK).Visit(E); 5274 } 5275 5276 bool LValueExprEvaluator::VisitDeclRefExpr(const DeclRefExpr *E) { 5277 if (const FunctionDecl *FD = dyn_cast<FunctionDecl>(E->getDecl())) 5278 return Success(FD); 5279 if (const VarDecl *VD = dyn_cast<VarDecl>(E->getDecl())) 5280 return VisitVarDecl(E, VD); 5281 if (const BindingDecl *BD = dyn_cast<BindingDecl>(E->getDecl())) 5282 return Visit(BD->getBinding()); 5283 return Error(E); 5284 } 5285 5286 5287 bool LValueExprEvaluator::VisitVarDecl(const Expr *E, const VarDecl *VD) { 5288 5289 // If we are within a lambda's call operator, check whether the 'VD' referred 5290 // to within 'E' actually represents a lambda-capture that maps to a 5291 // data-member/field within the closure object, and if so, evaluate to the 5292 // field or what the field refers to. 5293 if (Info.CurrentCall && isLambdaCallOperator(Info.CurrentCall->Callee) && 5294 isa<DeclRefExpr>(E) && 5295 cast<DeclRefExpr>(E)->refersToEnclosingVariableOrCapture()) { 5296 // We don't always have a complete capture-map when checking or inferring if 5297 // the function call operator meets the requirements of a constexpr function 5298 // - but we don't need to evaluate the captures to determine constexprness 5299 // (dcl.constexpr C++17). 5300 if (Info.checkingPotentialConstantExpression()) 5301 return false; 5302 5303 if (auto *FD = Info.CurrentCall->LambdaCaptureFields.lookup(VD)) { 5304 // Start with 'Result' referring to the complete closure object... 5305 Result = *Info.CurrentCall->This; 5306 // ... then update it to refer to the field of the closure object 5307 // that represents the capture. 5308 if (!HandleLValueMember(Info, E, Result, FD)) 5309 return false; 5310 // And if the field is of reference type, update 'Result' to refer to what 5311 // the field refers to. 5312 if (FD->getType()->isReferenceType()) { 5313 APValue RVal; 5314 if (!handleLValueToRValueConversion(Info, E, FD->getType(), Result, 5315 RVal)) 5316 return false; 5317 Result.setFrom(Info.Ctx, RVal); 5318 } 5319 return true; 5320 } 5321 } 5322 CallStackFrame *Frame = nullptr; 5323 if (VD->hasLocalStorage() && Info.CurrentCall->Index > 1) { 5324 // Only if a local variable was declared in the function currently being 5325 // evaluated, do we expect to be able to find its value in the current 5326 // frame. (Otherwise it was likely declared in an enclosing context and 5327 // could either have a valid evaluatable value (for e.g. a constexpr 5328 // variable) or be ill-formed (and trigger an appropriate evaluation 5329 // diagnostic)). 5330 if (Info.CurrentCall->Callee && 5331 Info.CurrentCall->Callee->Equals(VD->getDeclContext())) { 5332 Frame = Info.CurrentCall; 5333 } 5334 } 5335 5336 if (!VD->getType()->isReferenceType()) { 5337 if (Frame) { 5338 Result.set({VD, Frame->Index, 5339 Info.CurrentCall->getCurrentTemporaryVersion(VD)}); 5340 return true; 5341 } 5342 return Success(VD); 5343 } 5344 5345 APValue *V; 5346 if (!evaluateVarDeclInit(Info, E, VD, Frame, V, nullptr)) 5347 return false; 5348 if (V->isUninit()) { 5349 if (!Info.checkingPotentialConstantExpression()) 5350 Info.FFDiag(E, diag::note_constexpr_use_uninit_reference); 5351 return false; 5352 } 5353 return Success(*V, E); 5354 } 5355 5356 bool LValueExprEvaluator::VisitMaterializeTemporaryExpr( 5357 const MaterializeTemporaryExpr *E) { 5358 // Walk through the expression to find the materialized temporary itself. 5359 SmallVector<const Expr *, 2> CommaLHSs; 5360 SmallVector<SubobjectAdjustment, 2> Adjustments; 5361 const Expr *Inner = E->GetTemporaryExpr()-> 5362 skipRValueSubobjectAdjustments(CommaLHSs, Adjustments); 5363 5364 // If we passed any comma operators, evaluate their LHSs. 5365 for (unsigned I = 0, N = CommaLHSs.size(); I != N; ++I) 5366 if (!EvaluateIgnoredValue(Info, CommaLHSs[I])) 5367 return false; 5368 5369 // A materialized temporary with static storage duration can appear within the 5370 // result of a constant expression evaluation, so we need to preserve its 5371 // value for use outside this evaluation. 5372 APValue *Value; 5373 if (E->getStorageDuration() == SD_Static) { 5374 Value = Info.Ctx.getMaterializedTemporaryValue(E, true); 5375 *Value = APValue(); 5376 Result.set(E); 5377 } else { 5378 Value = &createTemporary(E, E->getStorageDuration() == SD_Automatic, Result, 5379 *Info.CurrentCall); 5380 } 5381 5382 QualType Type = Inner->getType(); 5383 5384 // Materialize the temporary itself. 5385 if (!EvaluateInPlace(*Value, Info, Result, Inner) || 5386 (E->getStorageDuration() == SD_Static && 5387 !CheckConstantExpression(Info, E->getExprLoc(), Type, *Value))) { 5388 *Value = APValue(); 5389 return false; 5390 } 5391 5392 // Adjust our lvalue to refer to the desired subobject. 5393 for (unsigned I = Adjustments.size(); I != 0; /**/) { 5394 --I; 5395 switch (Adjustments[I].Kind) { 5396 case SubobjectAdjustment::DerivedToBaseAdjustment: 5397 if (!HandleLValueBasePath(Info, Adjustments[I].DerivedToBase.BasePath, 5398 Type, Result)) 5399 return false; 5400 Type = Adjustments[I].DerivedToBase.BasePath->getType(); 5401 break; 5402 5403 case SubobjectAdjustment::FieldAdjustment: 5404 if (!HandleLValueMember(Info, E, Result, Adjustments[I].Field)) 5405 return false; 5406 Type = Adjustments[I].Field->getType(); 5407 break; 5408 5409 case SubobjectAdjustment::MemberPointerAdjustment: 5410 if (!HandleMemberPointerAccess(this->Info, Type, Result, 5411 Adjustments[I].Ptr.RHS)) 5412 return false; 5413 Type = Adjustments[I].Ptr.MPT->getPointeeType(); 5414 break; 5415 } 5416 } 5417 5418 return true; 5419 } 5420 5421 bool 5422 LValueExprEvaluator::VisitCompoundLiteralExpr(const CompoundLiteralExpr *E) { 5423 assert((!Info.getLangOpts().CPlusPlus || E->isFileScope()) && 5424 "lvalue compound literal in c++?"); 5425 // Defer visiting the literal until the lvalue-to-rvalue conversion. We can 5426 // only see this when folding in C, so there's no standard to follow here. 5427 return Success(E); 5428 } 5429 5430 bool LValueExprEvaluator::VisitCXXTypeidExpr(const CXXTypeidExpr *E) { 5431 if (!E->isPotentiallyEvaluated()) 5432 return Success(E); 5433 5434 Info.FFDiag(E, diag::note_constexpr_typeid_polymorphic) 5435 << E->getExprOperand()->getType() 5436 << E->getExprOperand()->getSourceRange(); 5437 return false; 5438 } 5439 5440 bool LValueExprEvaluator::VisitCXXUuidofExpr(const CXXUuidofExpr *E) { 5441 return Success(E); 5442 } 5443 5444 bool LValueExprEvaluator::VisitMemberExpr(const MemberExpr *E) { 5445 // Handle static data members. 5446 if (const VarDecl *VD = dyn_cast<VarDecl>(E->getMemberDecl())) { 5447 VisitIgnoredBaseExpression(E->getBase()); 5448 return VisitVarDecl(E, VD); 5449 } 5450 5451 // Handle static member functions. 5452 if (const CXXMethodDecl *MD = dyn_cast<CXXMethodDecl>(E->getMemberDecl())) { 5453 if (MD->isStatic()) { 5454 VisitIgnoredBaseExpression(E->getBase()); 5455 return Success(MD); 5456 } 5457 } 5458 5459 // Handle non-static data members. 5460 return LValueExprEvaluatorBaseTy::VisitMemberExpr(E); 5461 } 5462 5463 bool LValueExprEvaluator::VisitArraySubscriptExpr(const ArraySubscriptExpr *E) { 5464 // FIXME: Deal with vectors as array subscript bases. 5465 if (E->getBase()->getType()->isVectorType()) 5466 return Error(E); 5467 5468 bool Success = true; 5469 if (!evaluatePointer(E->getBase(), Result)) { 5470 if (!Info.noteFailure()) 5471 return false; 5472 Success = false; 5473 } 5474 5475 APSInt Index; 5476 if (!EvaluateInteger(E->getIdx(), Index, Info)) 5477 return false; 5478 5479 return Success && 5480 HandleLValueArrayAdjustment(Info, E, Result, E->getType(), Index); 5481 } 5482 5483 bool LValueExprEvaluator::VisitUnaryDeref(const UnaryOperator *E) { 5484 return evaluatePointer(E->getSubExpr(), Result); 5485 } 5486 5487 bool LValueExprEvaluator::VisitUnaryReal(const UnaryOperator *E) { 5488 if (!Visit(E->getSubExpr())) 5489 return false; 5490 // __real is a no-op on scalar lvalues. 5491 if (E->getSubExpr()->getType()->isAnyComplexType()) 5492 HandleLValueComplexElement(Info, E, Result, E->getType(), false); 5493 return true; 5494 } 5495 5496 bool LValueExprEvaluator::VisitUnaryImag(const UnaryOperator *E) { 5497 assert(E->getSubExpr()->getType()->isAnyComplexType() && 5498 "lvalue __imag__ on scalar?"); 5499 if (!Visit(E->getSubExpr())) 5500 return false; 5501 HandleLValueComplexElement(Info, E, Result, E->getType(), true); 5502 return true; 5503 } 5504 5505 bool LValueExprEvaluator::VisitUnaryPreIncDec(const UnaryOperator *UO) { 5506 if (!Info.getLangOpts().CPlusPlus14 && !Info.keepEvaluatingAfterFailure()) 5507 return Error(UO); 5508 5509 if (!this->Visit(UO->getSubExpr())) 5510 return false; 5511 5512 return handleIncDec( 5513 this->Info, UO, Result, UO->getSubExpr()->getType(), 5514 UO->isIncrementOp(), nullptr); 5515 } 5516 5517 bool LValueExprEvaluator::VisitCompoundAssignOperator( 5518 const CompoundAssignOperator *CAO) { 5519 if (!Info.getLangOpts().CPlusPlus14 && !Info.keepEvaluatingAfterFailure()) 5520 return Error(CAO); 5521 5522 APValue RHS; 5523 5524 // The overall lvalue result is the result of evaluating the LHS. 5525 if (!this->Visit(CAO->getLHS())) { 5526 if (Info.noteFailure()) 5527 Evaluate(RHS, this->Info, CAO->getRHS()); 5528 return false; 5529 } 5530 5531 if (!Evaluate(RHS, this->Info, CAO->getRHS())) 5532 return false; 5533 5534 return handleCompoundAssignment( 5535 this->Info, CAO, 5536 Result, CAO->getLHS()->getType(), CAO->getComputationLHSType(), 5537 CAO->getOpForCompoundAssignment(CAO->getOpcode()), RHS); 5538 } 5539 5540 bool LValueExprEvaluator::VisitBinAssign(const BinaryOperator *E) { 5541 if (!Info.getLangOpts().CPlusPlus14 && !Info.keepEvaluatingAfterFailure()) 5542 return Error(E); 5543 5544 APValue NewVal; 5545 5546 if (!this->Visit(E->getLHS())) { 5547 if (Info.noteFailure()) 5548 Evaluate(NewVal, this->Info, E->getRHS()); 5549 return false; 5550 } 5551 5552 if (!Evaluate(NewVal, this->Info, E->getRHS())) 5553 return false; 5554 5555 return handleAssignment(this->Info, E, Result, E->getLHS()->getType(), 5556 NewVal); 5557 } 5558 5559 //===----------------------------------------------------------------------===// 5560 // Pointer Evaluation 5561 //===----------------------------------------------------------------------===// 5562 5563 /// Attempts to compute the number of bytes available at the pointer 5564 /// returned by a function with the alloc_size attribute. Returns true if we 5565 /// were successful. Places an unsigned number into `Result`. 5566 /// 5567 /// This expects the given CallExpr to be a call to a function with an 5568 /// alloc_size attribute. 5569 static bool getBytesReturnedByAllocSizeCall(const ASTContext &Ctx, 5570 const CallExpr *Call, 5571 llvm::APInt &Result) { 5572 const AllocSizeAttr *AllocSize = getAllocSizeAttr(Call); 5573 5574 assert(AllocSize && AllocSize->getElemSizeParam().isValid()); 5575 unsigned SizeArgNo = AllocSize->getElemSizeParam().getASTIndex(); 5576 unsigned BitsInSizeT = Ctx.getTypeSize(Ctx.getSizeType()); 5577 if (Call->getNumArgs() <= SizeArgNo) 5578 return false; 5579 5580 auto EvaluateAsSizeT = [&](const Expr *E, APSInt &Into) { 5581 if (!E->EvaluateAsInt(Into, Ctx, Expr::SE_AllowSideEffects)) 5582 return false; 5583 if (Into.isNegative() || !Into.isIntN(BitsInSizeT)) 5584 return false; 5585 Into = Into.zextOrSelf(BitsInSizeT); 5586 return true; 5587 }; 5588 5589 APSInt SizeOfElem; 5590 if (!EvaluateAsSizeT(Call->getArg(SizeArgNo), SizeOfElem)) 5591 return false; 5592 5593 if (!AllocSize->getNumElemsParam().isValid()) { 5594 Result = std::move(SizeOfElem); 5595 return true; 5596 } 5597 5598 APSInt NumberOfElems; 5599 unsigned NumArgNo = AllocSize->getNumElemsParam().getASTIndex(); 5600 if (!EvaluateAsSizeT(Call->getArg(NumArgNo), NumberOfElems)) 5601 return false; 5602 5603 bool Overflow; 5604 llvm::APInt BytesAvailable = SizeOfElem.umul_ov(NumberOfElems, Overflow); 5605 if (Overflow) 5606 return false; 5607 5608 Result = std::move(BytesAvailable); 5609 return true; 5610 } 5611 5612 /// Convenience function. LVal's base must be a call to an alloc_size 5613 /// function. 5614 static bool getBytesReturnedByAllocSizeCall(const ASTContext &Ctx, 5615 const LValue &LVal, 5616 llvm::APInt &Result) { 5617 assert(isBaseAnAllocSizeCall(LVal.getLValueBase()) && 5618 "Can't get the size of a non alloc_size function"); 5619 const auto *Base = LVal.getLValueBase().get<const Expr *>(); 5620 const CallExpr *CE = tryUnwrapAllocSizeCall(Base); 5621 return getBytesReturnedByAllocSizeCall(Ctx, CE, Result); 5622 } 5623 5624 /// Attempts to evaluate the given LValueBase as the result of a call to 5625 /// a function with the alloc_size attribute. If it was possible to do so, this 5626 /// function will return true, make Result's Base point to said function call, 5627 /// and mark Result's Base as invalid. 5628 static bool evaluateLValueAsAllocSize(EvalInfo &Info, APValue::LValueBase Base, 5629 LValue &Result) { 5630 if (Base.isNull()) 5631 return false; 5632 5633 // Because we do no form of static analysis, we only support const variables. 5634 // 5635 // Additionally, we can't support parameters, nor can we support static 5636 // variables (in the latter case, use-before-assign isn't UB; in the former, 5637 // we have no clue what they'll be assigned to). 5638 const auto *VD = 5639 dyn_cast_or_null<VarDecl>(Base.dyn_cast<const ValueDecl *>()); 5640 if (!VD || !VD->isLocalVarDecl() || !VD->getType().isConstQualified()) 5641 return false; 5642 5643 const Expr *Init = VD->getAnyInitializer(); 5644 if (!Init) 5645 return false; 5646 5647 const Expr *E = Init->IgnoreParens(); 5648 if (!tryUnwrapAllocSizeCall(E)) 5649 return false; 5650 5651 // Store E instead of E unwrapped so that the type of the LValue's base is 5652 // what the user wanted. 5653 Result.setInvalid(E); 5654 5655 QualType Pointee = E->getType()->castAs<PointerType>()->getPointeeType(); 5656 Result.addUnsizedArray(Info, E, Pointee); 5657 return true; 5658 } 5659 5660 namespace { 5661 class PointerExprEvaluator 5662 : public ExprEvaluatorBase<PointerExprEvaluator> { 5663 LValue &Result; 5664 bool InvalidBaseOK; 5665 5666 bool Success(const Expr *E) { 5667 Result.set(E); 5668 return true; 5669 } 5670 5671 bool evaluateLValue(const Expr *E, LValue &Result) { 5672 return EvaluateLValue(E, Result, Info, InvalidBaseOK); 5673 } 5674 5675 bool evaluatePointer(const Expr *E, LValue &Result) { 5676 return EvaluatePointer(E, Result, Info, InvalidBaseOK); 5677 } 5678 5679 bool visitNonBuiltinCallExpr(const CallExpr *E); 5680 public: 5681 5682 PointerExprEvaluator(EvalInfo &info, LValue &Result, bool InvalidBaseOK) 5683 : ExprEvaluatorBaseTy(info), Result(Result), 5684 InvalidBaseOK(InvalidBaseOK) {} 5685 5686 bool Success(const APValue &V, const Expr *E) { 5687 Result.setFrom(Info.Ctx, V); 5688 return true; 5689 } 5690 bool ZeroInitialization(const Expr *E) { 5691 auto TargetVal = Info.Ctx.getTargetNullPointerValue(E->getType()); 5692 Result.setNull(E->getType(), TargetVal); 5693 return true; 5694 } 5695 5696 bool VisitBinaryOperator(const BinaryOperator *E); 5697 bool VisitCastExpr(const CastExpr* E); 5698 bool VisitUnaryAddrOf(const UnaryOperator *E); 5699 bool VisitObjCStringLiteral(const ObjCStringLiteral *E) 5700 { return Success(E); } 5701 bool VisitObjCBoxedExpr(const ObjCBoxedExpr *E) { 5702 if (Info.noteFailure()) 5703 EvaluateIgnoredValue(Info, E->getSubExpr()); 5704 return Error(E); 5705 } 5706 bool VisitAddrLabelExpr(const AddrLabelExpr *E) 5707 { return Success(E); } 5708 bool VisitCallExpr(const CallExpr *E); 5709 bool VisitBuiltinCallExpr(const CallExpr *E, unsigned BuiltinOp); 5710 bool VisitBlockExpr(const BlockExpr *E) { 5711 if (!E->getBlockDecl()->hasCaptures()) 5712 return Success(E); 5713 return Error(E); 5714 } 5715 bool VisitCXXThisExpr(const CXXThisExpr *E) { 5716 // Can't look at 'this' when checking a potential constant expression. 5717 if (Info.checkingPotentialConstantExpression()) 5718 return false; 5719 if (!Info.CurrentCall->This) { 5720 if (Info.getLangOpts().CPlusPlus11) 5721 Info.FFDiag(E, diag::note_constexpr_this) << E->isImplicit(); 5722 else 5723 Info.FFDiag(E); 5724 return false; 5725 } 5726 Result = *Info.CurrentCall->This; 5727 // If we are inside a lambda's call operator, the 'this' expression refers 5728 // to the enclosing '*this' object (either by value or reference) which is 5729 // either copied into the closure object's field that represents the '*this' 5730 // or refers to '*this'. 5731 if (isLambdaCallOperator(Info.CurrentCall->Callee)) { 5732 // Update 'Result' to refer to the data member/field of the closure object 5733 // that represents the '*this' capture. 5734 if (!HandleLValueMember(Info, E, Result, 5735 Info.CurrentCall->LambdaThisCaptureField)) 5736 return false; 5737 // If we captured '*this' by reference, replace the field with its referent. 5738 if (Info.CurrentCall->LambdaThisCaptureField->getType() 5739 ->isPointerType()) { 5740 APValue RVal; 5741 if (!handleLValueToRValueConversion(Info, E, E->getType(), Result, 5742 RVal)) 5743 return false; 5744 5745 Result.setFrom(Info.Ctx, RVal); 5746 } 5747 } 5748 return true; 5749 } 5750 5751 // FIXME: Missing: @protocol, @selector 5752 }; 5753 } // end anonymous namespace 5754 5755 static bool EvaluatePointer(const Expr* E, LValue& Result, EvalInfo &Info, 5756 bool InvalidBaseOK) { 5757 assert(E->isRValue() && E->getType()->hasPointerRepresentation()); 5758 return PointerExprEvaluator(Info, Result, InvalidBaseOK).Visit(E); 5759 } 5760 5761 bool PointerExprEvaluator::VisitBinaryOperator(const BinaryOperator *E) { 5762 if (E->getOpcode() != BO_Add && 5763 E->getOpcode() != BO_Sub) 5764 return ExprEvaluatorBaseTy::VisitBinaryOperator(E); 5765 5766 const Expr *PExp = E->getLHS(); 5767 const Expr *IExp = E->getRHS(); 5768 if (IExp->getType()->isPointerType()) 5769 std::swap(PExp, IExp); 5770 5771 bool EvalPtrOK = evaluatePointer(PExp, Result); 5772 if (!EvalPtrOK && !Info.noteFailure()) 5773 return false; 5774 5775 llvm::APSInt Offset; 5776 if (!EvaluateInteger(IExp, Offset, Info) || !EvalPtrOK) 5777 return false; 5778 5779 if (E->getOpcode() == BO_Sub) 5780 negateAsSigned(Offset); 5781 5782 QualType Pointee = PExp->getType()->castAs<PointerType>()->getPointeeType(); 5783 return HandleLValueArrayAdjustment(Info, E, Result, Pointee, Offset); 5784 } 5785 5786 bool PointerExprEvaluator::VisitUnaryAddrOf(const UnaryOperator *E) { 5787 return evaluateLValue(E->getSubExpr(), Result); 5788 } 5789 5790 bool PointerExprEvaluator::VisitCastExpr(const CastExpr* E) { 5791 const Expr* SubExpr = E->getSubExpr(); 5792 5793 switch (E->getCastKind()) { 5794 default: 5795 break; 5796 5797 case CK_BitCast: 5798 case CK_CPointerToObjCPointerCast: 5799 case CK_BlockPointerToObjCPointerCast: 5800 case CK_AnyPointerToBlockPointerCast: 5801 case CK_AddressSpaceConversion: 5802 if (!Visit(SubExpr)) 5803 return false; 5804 // Bitcasts to cv void* are static_casts, not reinterpret_casts, so are 5805 // permitted in constant expressions in C++11. Bitcasts from cv void* are 5806 // also static_casts, but we disallow them as a resolution to DR1312. 5807 if (!E->getType()->isVoidPointerType()) { 5808 Result.Designator.setInvalid(); 5809 if (SubExpr->getType()->isVoidPointerType()) 5810 CCEDiag(E, diag::note_constexpr_invalid_cast) 5811 << 3 << SubExpr->getType(); 5812 else 5813 CCEDiag(E, diag::note_constexpr_invalid_cast) << 2; 5814 } 5815 if (E->getCastKind() == CK_AddressSpaceConversion && Result.IsNullPtr) 5816 ZeroInitialization(E); 5817 return true; 5818 5819 case CK_DerivedToBase: 5820 case CK_UncheckedDerivedToBase: 5821 if (!evaluatePointer(E->getSubExpr(), Result)) 5822 return false; 5823 if (!Result.Base && Result.Offset.isZero()) 5824 return true; 5825 5826 // Now figure out the necessary offset to add to the base LV to get from 5827 // the derived class to the base class. 5828 return HandleLValueBasePath(Info, E, E->getSubExpr()->getType()-> 5829 castAs<PointerType>()->getPointeeType(), 5830 Result); 5831 5832 case CK_BaseToDerived: 5833 if (!Visit(E->getSubExpr())) 5834 return false; 5835 if (!Result.Base && Result.Offset.isZero()) 5836 return true; 5837 return HandleBaseToDerivedCast(Info, E, Result); 5838 5839 case CK_NullToPointer: 5840 VisitIgnoredValue(E->getSubExpr()); 5841 return ZeroInitialization(E); 5842 5843 case CK_IntegralToPointer: { 5844 CCEDiag(E, diag::note_constexpr_invalid_cast) << 2; 5845 5846 APValue Value; 5847 if (!EvaluateIntegerOrLValue(SubExpr, Value, Info)) 5848 break; 5849 5850 if (Value.isInt()) { 5851 unsigned Size = Info.Ctx.getTypeSize(E->getType()); 5852 uint64_t N = Value.getInt().extOrTrunc(Size).getZExtValue(); 5853 Result.Base = (Expr*)nullptr; 5854 Result.InvalidBase = false; 5855 Result.Offset = CharUnits::fromQuantity(N); 5856 Result.Designator.setInvalid(); 5857 Result.IsNullPtr = false; 5858 return true; 5859 } else { 5860 // Cast is of an lvalue, no need to change value. 5861 Result.setFrom(Info.Ctx, Value); 5862 return true; 5863 } 5864 } 5865 5866 case CK_ArrayToPointerDecay: { 5867 if (SubExpr->isGLValue()) { 5868 if (!evaluateLValue(SubExpr, Result)) 5869 return false; 5870 } else { 5871 APValue &Value = createTemporary(SubExpr, false, Result, 5872 *Info.CurrentCall); 5873 if (!EvaluateInPlace(Value, Info, Result, SubExpr)) 5874 return false; 5875 } 5876 // The result is a pointer to the first element of the array. 5877 auto *AT = Info.Ctx.getAsArrayType(SubExpr->getType()); 5878 if (auto *CAT = dyn_cast<ConstantArrayType>(AT)) 5879 Result.addArray(Info, E, CAT); 5880 else 5881 Result.addUnsizedArray(Info, E, AT->getElementType()); 5882 return true; 5883 } 5884 5885 case CK_FunctionToPointerDecay: 5886 return evaluateLValue(SubExpr, Result); 5887 5888 case CK_LValueToRValue: { 5889 LValue LVal; 5890 if (!evaluateLValue(E->getSubExpr(), LVal)) 5891 return false; 5892 5893 APValue RVal; 5894 // Note, we use the subexpression's type in order to retain cv-qualifiers. 5895 if (!handleLValueToRValueConversion(Info, E, E->getSubExpr()->getType(), 5896 LVal, RVal)) 5897 return InvalidBaseOK && 5898 evaluateLValueAsAllocSize(Info, LVal.Base, Result); 5899 return Success(RVal, E); 5900 } 5901 } 5902 5903 return ExprEvaluatorBaseTy::VisitCastExpr(E); 5904 } 5905 5906 static CharUnits GetAlignOfType(EvalInfo &Info, QualType T) { 5907 // C++ [expr.alignof]p3: 5908 // When alignof is applied to a reference type, the result is the 5909 // alignment of the referenced type. 5910 if (const ReferenceType *Ref = T->getAs<ReferenceType>()) 5911 T = Ref->getPointeeType(); 5912 5913 // __alignof is defined to return the preferred alignment. 5914 if (T.getQualifiers().hasUnaligned()) 5915 return CharUnits::One(); 5916 return Info.Ctx.toCharUnitsFromBits( 5917 Info.Ctx.getPreferredTypeAlign(T.getTypePtr())); 5918 } 5919 5920 static CharUnits GetAlignOfExpr(EvalInfo &Info, const Expr *E) { 5921 E = E->IgnoreParens(); 5922 5923 // The kinds of expressions that we have special-case logic here for 5924 // should be kept up to date with the special checks for those 5925 // expressions in Sema. 5926 5927 // alignof decl is always accepted, even if it doesn't make sense: we default 5928 // to 1 in those cases. 5929 if (const DeclRefExpr *DRE = dyn_cast<DeclRefExpr>(E)) 5930 return Info.Ctx.getDeclAlign(DRE->getDecl(), 5931 /*RefAsPointee*/true); 5932 5933 if (const MemberExpr *ME = dyn_cast<MemberExpr>(E)) 5934 return Info.Ctx.getDeclAlign(ME->getMemberDecl(), 5935 /*RefAsPointee*/true); 5936 5937 return GetAlignOfType(Info, E->getType()); 5938 } 5939 5940 // To be clear: this happily visits unsupported builtins. Better name welcomed. 5941 bool PointerExprEvaluator::visitNonBuiltinCallExpr(const CallExpr *E) { 5942 if (ExprEvaluatorBaseTy::VisitCallExpr(E)) 5943 return true; 5944 5945 if (!(InvalidBaseOK && getAllocSizeAttr(E))) 5946 return false; 5947 5948 Result.setInvalid(E); 5949 QualType PointeeTy = E->getType()->castAs<PointerType>()->getPointeeType(); 5950 Result.addUnsizedArray(Info, E, PointeeTy); 5951 return true; 5952 } 5953 5954 bool PointerExprEvaluator::VisitCallExpr(const CallExpr *E) { 5955 if (IsStringLiteralCall(E)) 5956 return Success(E); 5957 5958 if (unsigned BuiltinOp = E->getBuiltinCallee()) 5959 return VisitBuiltinCallExpr(E, BuiltinOp); 5960 5961 return visitNonBuiltinCallExpr(E); 5962 } 5963 5964 bool PointerExprEvaluator::VisitBuiltinCallExpr(const CallExpr *E, 5965 unsigned BuiltinOp) { 5966 switch (BuiltinOp) { 5967 case Builtin::BI__builtin_addressof: 5968 return evaluateLValue(E->getArg(0), Result); 5969 case Builtin::BI__builtin_assume_aligned: { 5970 // We need to be very careful here because: if the pointer does not have the 5971 // asserted alignment, then the behavior is undefined, and undefined 5972 // behavior is non-constant. 5973 if (!evaluatePointer(E->getArg(0), Result)) 5974 return false; 5975 5976 LValue OffsetResult(Result); 5977 APSInt Alignment; 5978 if (!EvaluateInteger(E->getArg(1), Alignment, Info)) 5979 return false; 5980 CharUnits Align = CharUnits::fromQuantity(Alignment.getZExtValue()); 5981 5982 if (E->getNumArgs() > 2) { 5983 APSInt Offset; 5984 if (!EvaluateInteger(E->getArg(2), Offset, Info)) 5985 return false; 5986 5987 int64_t AdditionalOffset = -Offset.getZExtValue(); 5988 OffsetResult.Offset += CharUnits::fromQuantity(AdditionalOffset); 5989 } 5990 5991 // If there is a base object, then it must have the correct alignment. 5992 if (OffsetResult.Base) { 5993 CharUnits BaseAlignment; 5994 if (const ValueDecl *VD = 5995 OffsetResult.Base.dyn_cast<const ValueDecl*>()) { 5996 BaseAlignment = Info.Ctx.getDeclAlign(VD); 5997 } else { 5998 BaseAlignment = 5999 GetAlignOfExpr(Info, OffsetResult.Base.get<const Expr*>()); 6000 } 6001 6002 if (BaseAlignment < Align) { 6003 Result.Designator.setInvalid(); 6004 // FIXME: Add support to Diagnostic for long / long long. 6005 CCEDiag(E->getArg(0), 6006 diag::note_constexpr_baa_insufficient_alignment) << 0 6007 << (unsigned)BaseAlignment.getQuantity() 6008 << (unsigned)Align.getQuantity(); 6009 return false; 6010 } 6011 } 6012 6013 // The offset must also have the correct alignment. 6014 if (OffsetResult.Offset.alignTo(Align) != OffsetResult.Offset) { 6015 Result.Designator.setInvalid(); 6016 6017 (OffsetResult.Base 6018 ? CCEDiag(E->getArg(0), 6019 diag::note_constexpr_baa_insufficient_alignment) << 1 6020 : CCEDiag(E->getArg(0), 6021 diag::note_constexpr_baa_value_insufficient_alignment)) 6022 << (int)OffsetResult.Offset.getQuantity() 6023 << (unsigned)Align.getQuantity(); 6024 return false; 6025 } 6026 6027 return true; 6028 } 6029 6030 case Builtin::BIstrchr: 6031 case Builtin::BIwcschr: 6032 case Builtin::BImemchr: 6033 case Builtin::BIwmemchr: 6034 if (Info.getLangOpts().CPlusPlus11) 6035 Info.CCEDiag(E, diag::note_constexpr_invalid_function) 6036 << /*isConstexpr*/0 << /*isConstructor*/0 6037 << (std::string("'") + Info.Ctx.BuiltinInfo.getName(BuiltinOp) + "'"); 6038 else 6039 Info.CCEDiag(E, diag::note_invalid_subexpr_in_const_expr); 6040 LLVM_FALLTHROUGH; 6041 case Builtin::BI__builtin_strchr: 6042 case Builtin::BI__builtin_wcschr: 6043 case Builtin::BI__builtin_memchr: 6044 case Builtin::BI__builtin_char_memchr: 6045 case Builtin::BI__builtin_wmemchr: { 6046 if (!Visit(E->getArg(0))) 6047 return false; 6048 APSInt Desired; 6049 if (!EvaluateInteger(E->getArg(1), Desired, Info)) 6050 return false; 6051 uint64_t MaxLength = uint64_t(-1); 6052 if (BuiltinOp != Builtin::BIstrchr && 6053 BuiltinOp != Builtin::BIwcschr && 6054 BuiltinOp != Builtin::BI__builtin_strchr && 6055 BuiltinOp != Builtin::BI__builtin_wcschr) { 6056 APSInt N; 6057 if (!EvaluateInteger(E->getArg(2), N, Info)) 6058 return false; 6059 MaxLength = N.getExtValue(); 6060 } 6061 6062 QualType CharTy = E->getArg(0)->getType()->getPointeeType(); 6063 6064 // Figure out what value we're actually looking for (after converting to 6065 // the corresponding unsigned type if necessary). 6066 uint64_t DesiredVal; 6067 bool StopAtNull = false; 6068 switch (BuiltinOp) { 6069 case Builtin::BIstrchr: 6070 case Builtin::BI__builtin_strchr: 6071 // strchr compares directly to the passed integer, and therefore 6072 // always fails if given an int that is not a char. 6073 if (!APSInt::isSameValue(HandleIntToIntCast(Info, E, CharTy, 6074 E->getArg(1)->getType(), 6075 Desired), 6076 Desired)) 6077 return ZeroInitialization(E); 6078 StopAtNull = true; 6079 LLVM_FALLTHROUGH; 6080 case Builtin::BImemchr: 6081 case Builtin::BI__builtin_memchr: 6082 case Builtin::BI__builtin_char_memchr: 6083 // memchr compares by converting both sides to unsigned char. That's also 6084 // correct for strchr if we get this far (to cope with plain char being 6085 // unsigned in the strchr case). 6086 DesiredVal = Desired.trunc(Info.Ctx.getCharWidth()).getZExtValue(); 6087 break; 6088 6089 case Builtin::BIwcschr: 6090 case Builtin::BI__builtin_wcschr: 6091 StopAtNull = true; 6092 LLVM_FALLTHROUGH; 6093 case Builtin::BIwmemchr: 6094 case Builtin::BI__builtin_wmemchr: 6095 // wcschr and wmemchr are given a wchar_t to look for. Just use it. 6096 DesiredVal = Desired.getZExtValue(); 6097 break; 6098 } 6099 6100 for (; MaxLength; --MaxLength) { 6101 APValue Char; 6102 if (!handleLValueToRValueConversion(Info, E, CharTy, Result, Char) || 6103 !Char.isInt()) 6104 return false; 6105 if (Char.getInt().getZExtValue() == DesiredVal) 6106 return true; 6107 if (StopAtNull && !Char.getInt()) 6108 break; 6109 if (!HandleLValueArrayAdjustment(Info, E, Result, CharTy, 1)) 6110 return false; 6111 } 6112 // Not found: return nullptr. 6113 return ZeroInitialization(E); 6114 } 6115 6116 default: 6117 return visitNonBuiltinCallExpr(E); 6118 } 6119 } 6120 6121 //===----------------------------------------------------------------------===// 6122 // Member Pointer Evaluation 6123 //===----------------------------------------------------------------------===// 6124 6125 namespace { 6126 class MemberPointerExprEvaluator 6127 : public ExprEvaluatorBase<MemberPointerExprEvaluator> { 6128 MemberPtr &Result; 6129 6130 bool Success(const ValueDecl *D) { 6131 Result = MemberPtr(D); 6132 return true; 6133 } 6134 public: 6135 6136 MemberPointerExprEvaluator(EvalInfo &Info, MemberPtr &Result) 6137 : ExprEvaluatorBaseTy(Info), Result(Result) {} 6138 6139 bool Success(const APValue &V, const Expr *E) { 6140 Result.setFrom(V); 6141 return true; 6142 } 6143 bool ZeroInitialization(const Expr *E) { 6144 return Success((const ValueDecl*)nullptr); 6145 } 6146 6147 bool VisitCastExpr(const CastExpr *E); 6148 bool VisitUnaryAddrOf(const UnaryOperator *E); 6149 }; 6150 } // end anonymous namespace 6151 6152 static bool EvaluateMemberPointer(const Expr *E, MemberPtr &Result, 6153 EvalInfo &Info) { 6154 assert(E->isRValue() && E->getType()->isMemberPointerType()); 6155 return MemberPointerExprEvaluator(Info, Result).Visit(E); 6156 } 6157 6158 bool MemberPointerExprEvaluator::VisitCastExpr(const CastExpr *E) { 6159 switch (E->getCastKind()) { 6160 default: 6161 return ExprEvaluatorBaseTy::VisitCastExpr(E); 6162 6163 case CK_NullToMemberPointer: 6164 VisitIgnoredValue(E->getSubExpr()); 6165 return ZeroInitialization(E); 6166 6167 case CK_BaseToDerivedMemberPointer: { 6168 if (!Visit(E->getSubExpr())) 6169 return false; 6170 if (E->path_empty()) 6171 return true; 6172 // Base-to-derived member pointer casts store the path in derived-to-base 6173 // order, so iterate backwards. The CXXBaseSpecifier also provides us with 6174 // the wrong end of the derived->base arc, so stagger the path by one class. 6175 typedef std::reverse_iterator<CastExpr::path_const_iterator> ReverseIter; 6176 for (ReverseIter PathI(E->path_end() - 1), PathE(E->path_begin()); 6177 PathI != PathE; ++PathI) { 6178 assert(!(*PathI)->isVirtual() && "memptr cast through vbase"); 6179 const CXXRecordDecl *Derived = (*PathI)->getType()->getAsCXXRecordDecl(); 6180 if (!Result.castToDerived(Derived)) 6181 return Error(E); 6182 } 6183 const Type *FinalTy = E->getType()->castAs<MemberPointerType>()->getClass(); 6184 if (!Result.castToDerived(FinalTy->getAsCXXRecordDecl())) 6185 return Error(E); 6186 return true; 6187 } 6188 6189 case CK_DerivedToBaseMemberPointer: 6190 if (!Visit(E->getSubExpr())) 6191 return false; 6192 for (CastExpr::path_const_iterator PathI = E->path_begin(), 6193 PathE = E->path_end(); PathI != PathE; ++PathI) { 6194 assert(!(*PathI)->isVirtual() && "memptr cast through vbase"); 6195 const CXXRecordDecl *Base = (*PathI)->getType()->getAsCXXRecordDecl(); 6196 if (!Result.castToBase(Base)) 6197 return Error(E); 6198 } 6199 return true; 6200 } 6201 } 6202 6203 bool MemberPointerExprEvaluator::VisitUnaryAddrOf(const UnaryOperator *E) { 6204 // C++11 [expr.unary.op]p3 has very strict rules on how the address of a 6205 // member can be formed. 6206 return Success(cast<DeclRefExpr>(E->getSubExpr())->getDecl()); 6207 } 6208 6209 //===----------------------------------------------------------------------===// 6210 // Record Evaluation 6211 //===----------------------------------------------------------------------===// 6212 6213 namespace { 6214 class RecordExprEvaluator 6215 : public ExprEvaluatorBase<RecordExprEvaluator> { 6216 const LValue &This; 6217 APValue &Result; 6218 public: 6219 6220 RecordExprEvaluator(EvalInfo &info, const LValue &This, APValue &Result) 6221 : ExprEvaluatorBaseTy(info), This(This), Result(Result) {} 6222 6223 bool Success(const APValue &V, const Expr *E) { 6224 Result = V; 6225 return true; 6226 } 6227 bool ZeroInitialization(const Expr *E) { 6228 return ZeroInitialization(E, E->getType()); 6229 } 6230 bool ZeroInitialization(const Expr *E, QualType T); 6231 6232 bool VisitCallExpr(const CallExpr *E) { 6233 return handleCallExpr(E, Result, &This); 6234 } 6235 bool VisitCastExpr(const CastExpr *E); 6236 bool VisitInitListExpr(const InitListExpr *E); 6237 bool VisitCXXConstructExpr(const CXXConstructExpr *E) { 6238 return VisitCXXConstructExpr(E, E->getType()); 6239 } 6240 bool VisitLambdaExpr(const LambdaExpr *E); 6241 bool VisitCXXInheritedCtorInitExpr(const CXXInheritedCtorInitExpr *E); 6242 bool VisitCXXConstructExpr(const CXXConstructExpr *E, QualType T); 6243 bool VisitCXXStdInitializerListExpr(const CXXStdInitializerListExpr *E); 6244 6245 bool VisitBinCmp(const BinaryOperator *E); 6246 }; 6247 } 6248 6249 /// Perform zero-initialization on an object of non-union class type. 6250 /// C++11 [dcl.init]p5: 6251 /// To zero-initialize an object or reference of type T means: 6252 /// [...] 6253 /// -- if T is a (possibly cv-qualified) non-union class type, 6254 /// each non-static data member and each base-class subobject is 6255 /// zero-initialized 6256 static bool HandleClassZeroInitialization(EvalInfo &Info, const Expr *E, 6257 const RecordDecl *RD, 6258 const LValue &This, APValue &Result) { 6259 assert(!RD->isUnion() && "Expected non-union class type"); 6260 const CXXRecordDecl *CD = dyn_cast<CXXRecordDecl>(RD); 6261 Result = APValue(APValue::UninitStruct(), CD ? CD->getNumBases() : 0, 6262 std::distance(RD->field_begin(), RD->field_end())); 6263 6264 if (RD->isInvalidDecl()) return false; 6265 const ASTRecordLayout &Layout = Info.Ctx.getASTRecordLayout(RD); 6266 6267 if (CD) { 6268 unsigned Index = 0; 6269 for (CXXRecordDecl::base_class_const_iterator I = CD->bases_begin(), 6270 End = CD->bases_end(); I != End; ++I, ++Index) { 6271 const CXXRecordDecl *Base = I->getType()->getAsCXXRecordDecl(); 6272 LValue Subobject = This; 6273 if (!HandleLValueDirectBase(Info, E, Subobject, CD, Base, &Layout)) 6274 return false; 6275 if (!HandleClassZeroInitialization(Info, E, Base, Subobject, 6276 Result.getStructBase(Index))) 6277 return false; 6278 } 6279 } 6280 6281 for (const auto *I : RD->fields()) { 6282 // -- if T is a reference type, no initialization is performed. 6283 if (I->getType()->isReferenceType()) 6284 continue; 6285 6286 LValue Subobject = This; 6287 if (!HandleLValueMember(Info, E, Subobject, I, &Layout)) 6288 return false; 6289 6290 ImplicitValueInitExpr VIE(I->getType()); 6291 if (!EvaluateInPlace( 6292 Result.getStructField(I->getFieldIndex()), Info, Subobject, &VIE)) 6293 return false; 6294 } 6295 6296 return true; 6297 } 6298 6299 bool RecordExprEvaluator::ZeroInitialization(const Expr *E, QualType T) { 6300 const RecordDecl *RD = T->castAs<RecordType>()->getDecl(); 6301 if (RD->isInvalidDecl()) return false; 6302 if (RD->isUnion()) { 6303 // C++11 [dcl.init]p5: If T is a (possibly cv-qualified) union type, the 6304 // object's first non-static named data member is zero-initialized 6305 RecordDecl::field_iterator I = RD->field_begin(); 6306 if (I == RD->field_end()) { 6307 Result = APValue((const FieldDecl*)nullptr); 6308 return true; 6309 } 6310 6311 LValue Subobject = This; 6312 if (!HandleLValueMember(Info, E, Subobject, *I)) 6313 return false; 6314 Result = APValue(*I); 6315 ImplicitValueInitExpr VIE(I->getType()); 6316 return EvaluateInPlace(Result.getUnionValue(), Info, Subobject, &VIE); 6317 } 6318 6319 if (isa<CXXRecordDecl>(RD) && cast<CXXRecordDecl>(RD)->getNumVBases()) { 6320 Info.FFDiag(E, diag::note_constexpr_virtual_base) << RD; 6321 return false; 6322 } 6323 6324 return HandleClassZeroInitialization(Info, E, RD, This, Result); 6325 } 6326 6327 bool RecordExprEvaluator::VisitCastExpr(const CastExpr *E) { 6328 switch (E->getCastKind()) { 6329 default: 6330 return ExprEvaluatorBaseTy::VisitCastExpr(E); 6331 6332 case CK_ConstructorConversion: 6333 return Visit(E->getSubExpr()); 6334 6335 case CK_DerivedToBase: 6336 case CK_UncheckedDerivedToBase: { 6337 APValue DerivedObject; 6338 if (!Evaluate(DerivedObject, Info, E->getSubExpr())) 6339 return false; 6340 if (!DerivedObject.isStruct()) 6341 return Error(E->getSubExpr()); 6342 6343 // Derived-to-base rvalue conversion: just slice off the derived part. 6344 APValue *Value = &DerivedObject; 6345 const CXXRecordDecl *RD = E->getSubExpr()->getType()->getAsCXXRecordDecl(); 6346 for (CastExpr::path_const_iterator PathI = E->path_begin(), 6347 PathE = E->path_end(); PathI != PathE; ++PathI) { 6348 assert(!(*PathI)->isVirtual() && "record rvalue with virtual base"); 6349 const CXXRecordDecl *Base = (*PathI)->getType()->getAsCXXRecordDecl(); 6350 Value = &Value->getStructBase(getBaseIndex(RD, Base)); 6351 RD = Base; 6352 } 6353 Result = *Value; 6354 return true; 6355 } 6356 } 6357 } 6358 6359 bool RecordExprEvaluator::VisitInitListExpr(const InitListExpr *E) { 6360 if (E->isTransparent()) 6361 return Visit(E->getInit(0)); 6362 6363 const RecordDecl *RD = E->getType()->castAs<RecordType>()->getDecl(); 6364 if (RD->isInvalidDecl()) return false; 6365 const ASTRecordLayout &Layout = Info.Ctx.getASTRecordLayout(RD); 6366 6367 if (RD->isUnion()) { 6368 const FieldDecl *Field = E->getInitializedFieldInUnion(); 6369 Result = APValue(Field); 6370 if (!Field) 6371 return true; 6372 6373 // If the initializer list for a union does not contain any elements, the 6374 // first element of the union is value-initialized. 6375 // FIXME: The element should be initialized from an initializer list. 6376 // Is this difference ever observable for initializer lists which 6377 // we don't build? 6378 ImplicitValueInitExpr VIE(Field->getType()); 6379 const Expr *InitExpr = E->getNumInits() ? E->getInit(0) : &VIE; 6380 6381 LValue Subobject = This; 6382 if (!HandleLValueMember(Info, InitExpr, Subobject, Field, &Layout)) 6383 return false; 6384 6385 // Temporarily override This, in case there's a CXXDefaultInitExpr in here. 6386 ThisOverrideRAII ThisOverride(*Info.CurrentCall, &This, 6387 isa<CXXDefaultInitExpr>(InitExpr)); 6388 6389 return EvaluateInPlace(Result.getUnionValue(), Info, Subobject, InitExpr); 6390 } 6391 6392 auto *CXXRD = dyn_cast<CXXRecordDecl>(RD); 6393 if (Result.isUninit()) 6394 Result = APValue(APValue::UninitStruct(), CXXRD ? CXXRD->getNumBases() : 0, 6395 std::distance(RD->field_begin(), RD->field_end())); 6396 unsigned ElementNo = 0; 6397 bool Success = true; 6398 6399 // Initialize base classes. 6400 if (CXXRD) { 6401 for (const auto &Base : CXXRD->bases()) { 6402 assert(ElementNo < E->getNumInits() && "missing init for base class"); 6403 const Expr *Init = E->getInit(ElementNo); 6404 6405 LValue Subobject = This; 6406 if (!HandleLValueBase(Info, Init, Subobject, CXXRD, &Base)) 6407 return false; 6408 6409 APValue &FieldVal = Result.getStructBase(ElementNo); 6410 if (!EvaluateInPlace(FieldVal, Info, Subobject, Init)) { 6411 if (!Info.noteFailure()) 6412 return false; 6413 Success = false; 6414 } 6415 ++ElementNo; 6416 } 6417 } 6418 6419 // Initialize members. 6420 for (const auto *Field : RD->fields()) { 6421 // Anonymous bit-fields are not considered members of the class for 6422 // purposes of aggregate initialization. 6423 if (Field->isUnnamedBitfield()) 6424 continue; 6425 6426 LValue Subobject = This; 6427 6428 bool HaveInit = ElementNo < E->getNumInits(); 6429 6430 // FIXME: Diagnostics here should point to the end of the initializer 6431 // list, not the start. 6432 if (!HandleLValueMember(Info, HaveInit ? E->getInit(ElementNo) : E, 6433 Subobject, Field, &Layout)) 6434 return false; 6435 6436 // Perform an implicit value-initialization for members beyond the end of 6437 // the initializer list. 6438 ImplicitValueInitExpr VIE(HaveInit ? Info.Ctx.IntTy : Field->getType()); 6439 const Expr *Init = HaveInit ? E->getInit(ElementNo++) : &VIE; 6440 6441 // Temporarily override This, in case there's a CXXDefaultInitExpr in here. 6442 ThisOverrideRAII ThisOverride(*Info.CurrentCall, &This, 6443 isa<CXXDefaultInitExpr>(Init)); 6444 6445 APValue &FieldVal = Result.getStructField(Field->getFieldIndex()); 6446 if (!EvaluateInPlace(FieldVal, Info, Subobject, Init) || 6447 (Field->isBitField() && !truncateBitfieldValue(Info, Init, 6448 FieldVal, Field))) { 6449 if (!Info.noteFailure()) 6450 return false; 6451 Success = false; 6452 } 6453 } 6454 6455 return Success; 6456 } 6457 6458 bool RecordExprEvaluator::VisitCXXConstructExpr(const CXXConstructExpr *E, 6459 QualType T) { 6460 // Note that E's type is not necessarily the type of our class here; we might 6461 // be initializing an array element instead. 6462 const CXXConstructorDecl *FD = E->getConstructor(); 6463 if (FD->isInvalidDecl() || FD->getParent()->isInvalidDecl()) return false; 6464 6465 bool ZeroInit = E->requiresZeroInitialization(); 6466 if (CheckTrivialDefaultConstructor(Info, E->getExprLoc(), FD, ZeroInit)) { 6467 // If we've already performed zero-initialization, we're already done. 6468 if (!Result.isUninit()) 6469 return true; 6470 6471 // We can get here in two different ways: 6472 // 1) We're performing value-initialization, and should zero-initialize 6473 // the object, or 6474 // 2) We're performing default-initialization of an object with a trivial 6475 // constexpr default constructor, in which case we should start the 6476 // lifetimes of all the base subobjects (there can be no data member 6477 // subobjects in this case) per [basic.life]p1. 6478 // Either way, ZeroInitialization is appropriate. 6479 return ZeroInitialization(E, T); 6480 } 6481 6482 const FunctionDecl *Definition = nullptr; 6483 auto Body = FD->getBody(Definition); 6484 6485 if (!CheckConstexprFunction(Info, E->getExprLoc(), FD, Definition, Body)) 6486 return false; 6487 6488 // Avoid materializing a temporary for an elidable copy/move constructor. 6489 if (E->isElidable() && !ZeroInit) 6490 if (const MaterializeTemporaryExpr *ME 6491 = dyn_cast<MaterializeTemporaryExpr>(E->getArg(0))) 6492 return Visit(ME->GetTemporaryExpr()); 6493 6494 if (ZeroInit && !ZeroInitialization(E, T)) 6495 return false; 6496 6497 auto Args = llvm::makeArrayRef(E->getArgs(), E->getNumArgs()); 6498 return HandleConstructorCall(E, This, Args, 6499 cast<CXXConstructorDecl>(Definition), Info, 6500 Result); 6501 } 6502 6503 bool RecordExprEvaluator::VisitCXXInheritedCtorInitExpr( 6504 const CXXInheritedCtorInitExpr *E) { 6505 if (!Info.CurrentCall) { 6506 assert(Info.checkingPotentialConstantExpression()); 6507 return false; 6508 } 6509 6510 const CXXConstructorDecl *FD = E->getConstructor(); 6511 if (FD->isInvalidDecl() || FD->getParent()->isInvalidDecl()) 6512 return false; 6513 6514 const FunctionDecl *Definition = nullptr; 6515 auto Body = FD->getBody(Definition); 6516 6517 if (!CheckConstexprFunction(Info, E->getExprLoc(), FD, Definition, Body)) 6518 return false; 6519 6520 return HandleConstructorCall(E, This, Info.CurrentCall->Arguments, 6521 cast<CXXConstructorDecl>(Definition), Info, 6522 Result); 6523 } 6524 6525 bool RecordExprEvaluator::VisitCXXStdInitializerListExpr( 6526 const CXXStdInitializerListExpr *E) { 6527 const ConstantArrayType *ArrayType = 6528 Info.Ctx.getAsConstantArrayType(E->getSubExpr()->getType()); 6529 6530 LValue Array; 6531 if (!EvaluateLValue(E->getSubExpr(), Array, Info)) 6532 return false; 6533 6534 // Get a pointer to the first element of the array. 6535 Array.addArray(Info, E, ArrayType); 6536 6537 // FIXME: Perform the checks on the field types in SemaInit. 6538 RecordDecl *Record = E->getType()->castAs<RecordType>()->getDecl(); 6539 RecordDecl::field_iterator Field = Record->field_begin(); 6540 if (Field == Record->field_end()) 6541 return Error(E); 6542 6543 // Start pointer. 6544 if (!Field->getType()->isPointerType() || 6545 !Info.Ctx.hasSameType(Field->getType()->getPointeeType(), 6546 ArrayType->getElementType())) 6547 return Error(E); 6548 6549 // FIXME: What if the initializer_list type has base classes, etc? 6550 Result = APValue(APValue::UninitStruct(), 0, 2); 6551 Array.moveInto(Result.getStructField(0)); 6552 6553 if (++Field == Record->field_end()) 6554 return Error(E); 6555 6556 if (Field->getType()->isPointerType() && 6557 Info.Ctx.hasSameType(Field->getType()->getPointeeType(), 6558 ArrayType->getElementType())) { 6559 // End pointer. 6560 if (!HandleLValueArrayAdjustment(Info, E, Array, 6561 ArrayType->getElementType(), 6562 ArrayType->getSize().getZExtValue())) 6563 return false; 6564 Array.moveInto(Result.getStructField(1)); 6565 } else if (Info.Ctx.hasSameType(Field->getType(), Info.Ctx.getSizeType())) 6566 // Length. 6567 Result.getStructField(1) = APValue(APSInt(ArrayType->getSize())); 6568 else 6569 return Error(E); 6570 6571 if (++Field != Record->field_end()) 6572 return Error(E); 6573 6574 return true; 6575 } 6576 6577 bool RecordExprEvaluator::VisitLambdaExpr(const LambdaExpr *E) { 6578 const CXXRecordDecl *ClosureClass = E->getLambdaClass(); 6579 if (ClosureClass->isInvalidDecl()) return false; 6580 6581 if (Info.checkingPotentialConstantExpression()) return true; 6582 6583 const size_t NumFields = 6584 std::distance(ClosureClass->field_begin(), ClosureClass->field_end()); 6585 6586 assert(NumFields == (size_t)std::distance(E->capture_init_begin(), 6587 E->capture_init_end()) && 6588 "The number of lambda capture initializers should equal the number of " 6589 "fields within the closure type"); 6590 6591 Result = APValue(APValue::UninitStruct(), /*NumBases*/0, NumFields); 6592 // Iterate through all the lambda's closure object's fields and initialize 6593 // them. 6594 auto *CaptureInitIt = E->capture_init_begin(); 6595 const LambdaCapture *CaptureIt = ClosureClass->captures_begin(); 6596 bool Success = true; 6597 for (const auto *Field : ClosureClass->fields()) { 6598 assert(CaptureInitIt != E->capture_init_end()); 6599 // Get the initializer for this field 6600 Expr *const CurFieldInit = *CaptureInitIt++; 6601 6602 // If there is no initializer, either this is a VLA or an error has 6603 // occurred. 6604 if (!CurFieldInit) 6605 return Error(E); 6606 6607 APValue &FieldVal = Result.getStructField(Field->getFieldIndex()); 6608 if (!EvaluateInPlace(FieldVal, Info, This, CurFieldInit)) { 6609 if (!Info.keepEvaluatingAfterFailure()) 6610 return false; 6611 Success = false; 6612 } 6613 ++CaptureIt; 6614 } 6615 return Success; 6616 } 6617 6618 static bool EvaluateRecord(const Expr *E, const LValue &This, 6619 APValue &Result, EvalInfo &Info) { 6620 assert(E->isRValue() && E->getType()->isRecordType() && 6621 "can't evaluate expression as a record rvalue"); 6622 return RecordExprEvaluator(Info, This, Result).Visit(E); 6623 } 6624 6625 //===----------------------------------------------------------------------===// 6626 // Temporary Evaluation 6627 // 6628 // Temporaries are represented in the AST as rvalues, but generally behave like 6629 // lvalues. The full-object of which the temporary is a subobject is implicitly 6630 // materialized so that a reference can bind to it. 6631 //===----------------------------------------------------------------------===// 6632 namespace { 6633 class TemporaryExprEvaluator 6634 : public LValueExprEvaluatorBase<TemporaryExprEvaluator> { 6635 public: 6636 TemporaryExprEvaluator(EvalInfo &Info, LValue &Result) : 6637 LValueExprEvaluatorBaseTy(Info, Result, false) {} 6638 6639 /// Visit an expression which constructs the value of this temporary. 6640 bool VisitConstructExpr(const Expr *E) { 6641 APValue &Value = createTemporary(E, false, Result, *Info.CurrentCall); 6642 return EvaluateInPlace(Value, Info, Result, E); 6643 } 6644 6645 bool VisitCastExpr(const CastExpr *E) { 6646 switch (E->getCastKind()) { 6647 default: 6648 return LValueExprEvaluatorBaseTy::VisitCastExpr(E); 6649 6650 case CK_ConstructorConversion: 6651 return VisitConstructExpr(E->getSubExpr()); 6652 } 6653 } 6654 bool VisitInitListExpr(const InitListExpr *E) { 6655 return VisitConstructExpr(E); 6656 } 6657 bool VisitCXXConstructExpr(const CXXConstructExpr *E) { 6658 return VisitConstructExpr(E); 6659 } 6660 bool VisitCallExpr(const CallExpr *E) { 6661 return VisitConstructExpr(E); 6662 } 6663 bool VisitCXXStdInitializerListExpr(const CXXStdInitializerListExpr *E) { 6664 return VisitConstructExpr(E); 6665 } 6666 bool VisitLambdaExpr(const LambdaExpr *E) { 6667 return VisitConstructExpr(E); 6668 } 6669 }; 6670 } // end anonymous namespace 6671 6672 /// Evaluate an expression of record type as a temporary. 6673 static bool EvaluateTemporary(const Expr *E, LValue &Result, EvalInfo &Info) { 6674 assert(E->isRValue() && E->getType()->isRecordType()); 6675 return TemporaryExprEvaluator(Info, Result).Visit(E); 6676 } 6677 6678 //===----------------------------------------------------------------------===// 6679 // Vector Evaluation 6680 //===----------------------------------------------------------------------===// 6681 6682 namespace { 6683 class VectorExprEvaluator 6684 : public ExprEvaluatorBase<VectorExprEvaluator> { 6685 APValue &Result; 6686 public: 6687 6688 VectorExprEvaluator(EvalInfo &info, APValue &Result) 6689 : ExprEvaluatorBaseTy(info), Result(Result) {} 6690 6691 bool Success(ArrayRef<APValue> V, const Expr *E) { 6692 assert(V.size() == E->getType()->castAs<VectorType>()->getNumElements()); 6693 // FIXME: remove this APValue copy. 6694 Result = APValue(V.data(), V.size()); 6695 return true; 6696 } 6697 bool Success(const APValue &V, const Expr *E) { 6698 assert(V.isVector()); 6699 Result = V; 6700 return true; 6701 } 6702 bool ZeroInitialization(const Expr *E); 6703 6704 bool VisitUnaryReal(const UnaryOperator *E) 6705 { return Visit(E->getSubExpr()); } 6706 bool VisitCastExpr(const CastExpr* E); 6707 bool VisitInitListExpr(const InitListExpr *E); 6708 bool VisitUnaryImag(const UnaryOperator *E); 6709 // FIXME: Missing: unary -, unary ~, binary add/sub/mul/div, 6710 // binary comparisons, binary and/or/xor, 6711 // shufflevector, ExtVectorElementExpr 6712 }; 6713 } // end anonymous namespace 6714 6715 static bool EvaluateVector(const Expr* E, APValue& Result, EvalInfo &Info) { 6716 assert(E->isRValue() && E->getType()->isVectorType() &&"not a vector rvalue"); 6717 return VectorExprEvaluator(Info, Result).Visit(E); 6718 } 6719 6720 bool VectorExprEvaluator::VisitCastExpr(const CastExpr *E) { 6721 const VectorType *VTy = E->getType()->castAs<VectorType>(); 6722 unsigned NElts = VTy->getNumElements(); 6723 6724 const Expr *SE = E->getSubExpr(); 6725 QualType SETy = SE->getType(); 6726 6727 switch (E->getCastKind()) { 6728 case CK_VectorSplat: { 6729 APValue Val = APValue(); 6730 if (SETy->isIntegerType()) { 6731 APSInt IntResult; 6732 if (!EvaluateInteger(SE, IntResult, Info)) 6733 return false; 6734 Val = APValue(std::move(IntResult)); 6735 } else if (SETy->isRealFloatingType()) { 6736 APFloat FloatResult(0.0); 6737 if (!EvaluateFloat(SE, FloatResult, Info)) 6738 return false; 6739 Val = APValue(std::move(FloatResult)); 6740 } else { 6741 return Error(E); 6742 } 6743 6744 // Splat and create vector APValue. 6745 SmallVector<APValue, 4> Elts(NElts, Val); 6746 return Success(Elts, E); 6747 } 6748 case CK_BitCast: { 6749 // Evaluate the operand into an APInt we can extract from. 6750 llvm::APInt SValInt; 6751 if (!EvalAndBitcastToAPInt(Info, SE, SValInt)) 6752 return false; 6753 // Extract the elements 6754 QualType EltTy = VTy->getElementType(); 6755 unsigned EltSize = Info.Ctx.getTypeSize(EltTy); 6756 bool BigEndian = Info.Ctx.getTargetInfo().isBigEndian(); 6757 SmallVector<APValue, 4> Elts; 6758 if (EltTy->isRealFloatingType()) { 6759 const llvm::fltSemantics &Sem = Info.Ctx.getFloatTypeSemantics(EltTy); 6760 unsigned FloatEltSize = EltSize; 6761 if (&Sem == &APFloat::x87DoubleExtended()) 6762 FloatEltSize = 80; 6763 for (unsigned i = 0; i < NElts; i++) { 6764 llvm::APInt Elt; 6765 if (BigEndian) 6766 Elt = SValInt.rotl(i*EltSize+FloatEltSize).trunc(FloatEltSize); 6767 else 6768 Elt = SValInt.rotr(i*EltSize).trunc(FloatEltSize); 6769 Elts.push_back(APValue(APFloat(Sem, Elt))); 6770 } 6771 } else if (EltTy->isIntegerType()) { 6772 for (unsigned i = 0; i < NElts; i++) { 6773 llvm::APInt Elt; 6774 if (BigEndian) 6775 Elt = SValInt.rotl(i*EltSize+EltSize).zextOrTrunc(EltSize); 6776 else 6777 Elt = SValInt.rotr(i*EltSize).zextOrTrunc(EltSize); 6778 Elts.push_back(APValue(APSInt(Elt, EltTy->isSignedIntegerType()))); 6779 } 6780 } else { 6781 return Error(E); 6782 } 6783 return Success(Elts, E); 6784 } 6785 default: 6786 return ExprEvaluatorBaseTy::VisitCastExpr(E); 6787 } 6788 } 6789 6790 bool 6791 VectorExprEvaluator::VisitInitListExpr(const InitListExpr *E) { 6792 const VectorType *VT = E->getType()->castAs<VectorType>(); 6793 unsigned NumInits = E->getNumInits(); 6794 unsigned NumElements = VT->getNumElements(); 6795 6796 QualType EltTy = VT->getElementType(); 6797 SmallVector<APValue, 4> Elements; 6798 6799 // The number of initializers can be less than the number of 6800 // vector elements. For OpenCL, this can be due to nested vector 6801 // initialization. For GCC compatibility, missing trailing elements 6802 // should be initialized with zeroes. 6803 unsigned CountInits = 0, CountElts = 0; 6804 while (CountElts < NumElements) { 6805 // Handle nested vector initialization. 6806 if (CountInits < NumInits 6807 && E->getInit(CountInits)->getType()->isVectorType()) { 6808 APValue v; 6809 if (!EvaluateVector(E->getInit(CountInits), v, Info)) 6810 return Error(E); 6811 unsigned vlen = v.getVectorLength(); 6812 for (unsigned j = 0; j < vlen; j++) 6813 Elements.push_back(v.getVectorElt(j)); 6814 CountElts += vlen; 6815 } else if (EltTy->isIntegerType()) { 6816 llvm::APSInt sInt(32); 6817 if (CountInits < NumInits) { 6818 if (!EvaluateInteger(E->getInit(CountInits), sInt, Info)) 6819 return false; 6820 } else // trailing integer zero. 6821 sInt = Info.Ctx.MakeIntValue(0, EltTy); 6822 Elements.push_back(APValue(sInt)); 6823 CountElts++; 6824 } else { 6825 llvm::APFloat f(0.0); 6826 if (CountInits < NumInits) { 6827 if (!EvaluateFloat(E->getInit(CountInits), f, Info)) 6828 return false; 6829 } else // trailing float zero. 6830 f = APFloat::getZero(Info.Ctx.getFloatTypeSemantics(EltTy)); 6831 Elements.push_back(APValue(f)); 6832 CountElts++; 6833 } 6834 CountInits++; 6835 } 6836 return Success(Elements, E); 6837 } 6838 6839 bool 6840 VectorExprEvaluator::ZeroInitialization(const Expr *E) { 6841 const VectorType *VT = E->getType()->getAs<VectorType>(); 6842 QualType EltTy = VT->getElementType(); 6843 APValue ZeroElement; 6844 if (EltTy->isIntegerType()) 6845 ZeroElement = APValue(Info.Ctx.MakeIntValue(0, EltTy)); 6846 else 6847 ZeroElement = 6848 APValue(APFloat::getZero(Info.Ctx.getFloatTypeSemantics(EltTy))); 6849 6850 SmallVector<APValue, 4> Elements(VT->getNumElements(), ZeroElement); 6851 return Success(Elements, E); 6852 } 6853 6854 bool VectorExprEvaluator::VisitUnaryImag(const UnaryOperator *E) { 6855 VisitIgnoredValue(E->getSubExpr()); 6856 return ZeroInitialization(E); 6857 } 6858 6859 //===----------------------------------------------------------------------===// 6860 // Array Evaluation 6861 //===----------------------------------------------------------------------===// 6862 6863 namespace { 6864 class ArrayExprEvaluator 6865 : public ExprEvaluatorBase<ArrayExprEvaluator> { 6866 const LValue &This; 6867 APValue &Result; 6868 public: 6869 6870 ArrayExprEvaluator(EvalInfo &Info, const LValue &This, APValue &Result) 6871 : ExprEvaluatorBaseTy(Info), This(This), Result(Result) {} 6872 6873 bool Success(const APValue &V, const Expr *E) { 6874 assert((V.isArray() || V.isLValue()) && 6875 "expected array or string literal"); 6876 Result = V; 6877 return true; 6878 } 6879 6880 bool ZeroInitialization(const Expr *E) { 6881 const ConstantArrayType *CAT = 6882 Info.Ctx.getAsConstantArrayType(E->getType()); 6883 if (!CAT) 6884 return Error(E); 6885 6886 Result = APValue(APValue::UninitArray(), 0, 6887 CAT->getSize().getZExtValue()); 6888 if (!Result.hasArrayFiller()) return true; 6889 6890 // Zero-initialize all elements. 6891 LValue Subobject = This; 6892 Subobject.addArray(Info, E, CAT); 6893 ImplicitValueInitExpr VIE(CAT->getElementType()); 6894 return EvaluateInPlace(Result.getArrayFiller(), Info, Subobject, &VIE); 6895 } 6896 6897 bool VisitCallExpr(const CallExpr *E) { 6898 return handleCallExpr(E, Result, &This); 6899 } 6900 bool VisitInitListExpr(const InitListExpr *E); 6901 bool VisitArrayInitLoopExpr(const ArrayInitLoopExpr *E); 6902 bool VisitCXXConstructExpr(const CXXConstructExpr *E); 6903 bool VisitCXXConstructExpr(const CXXConstructExpr *E, 6904 const LValue &Subobject, 6905 APValue *Value, QualType Type); 6906 }; 6907 } // end anonymous namespace 6908 6909 static bool EvaluateArray(const Expr *E, const LValue &This, 6910 APValue &Result, EvalInfo &Info) { 6911 assert(E->isRValue() && E->getType()->isArrayType() && "not an array rvalue"); 6912 return ArrayExprEvaluator(Info, This, Result).Visit(E); 6913 } 6914 6915 // Return true iff the given array filler may depend on the element index. 6916 static bool MaybeElementDependentArrayFiller(const Expr *FillerExpr) { 6917 // For now, just whitelist non-class value-initialization and initialization 6918 // lists comprised of them. 6919 if (isa<ImplicitValueInitExpr>(FillerExpr)) 6920 return false; 6921 if (const InitListExpr *ILE = dyn_cast<InitListExpr>(FillerExpr)) { 6922 for (unsigned I = 0, E = ILE->getNumInits(); I != E; ++I) { 6923 if (MaybeElementDependentArrayFiller(ILE->getInit(I))) 6924 return true; 6925 } 6926 return false; 6927 } 6928 return true; 6929 } 6930 6931 bool ArrayExprEvaluator::VisitInitListExpr(const InitListExpr *E) { 6932 const ConstantArrayType *CAT = Info.Ctx.getAsConstantArrayType(E->getType()); 6933 if (!CAT) 6934 return Error(E); 6935 6936 // C++11 [dcl.init.string]p1: A char array [...] can be initialized by [...] 6937 // an appropriately-typed string literal enclosed in braces. 6938 if (E->isStringLiteralInit()) { 6939 LValue LV; 6940 if (!EvaluateLValue(E->getInit(0), LV, Info)) 6941 return false; 6942 APValue Val; 6943 LV.moveInto(Val); 6944 return Success(Val, E); 6945 } 6946 6947 bool Success = true; 6948 6949 assert((!Result.isArray() || Result.getArrayInitializedElts() == 0) && 6950 "zero-initialized array shouldn't have any initialized elts"); 6951 APValue Filler; 6952 if (Result.isArray() && Result.hasArrayFiller()) 6953 Filler = Result.getArrayFiller(); 6954 6955 unsigned NumEltsToInit = E->getNumInits(); 6956 unsigned NumElts = CAT->getSize().getZExtValue(); 6957 const Expr *FillerExpr = E->hasArrayFiller() ? E->getArrayFiller() : nullptr; 6958 6959 // If the initializer might depend on the array index, run it for each 6960 // array element. 6961 if (NumEltsToInit != NumElts && MaybeElementDependentArrayFiller(FillerExpr)) 6962 NumEltsToInit = NumElts; 6963 6964 LLVM_DEBUG(llvm::dbgs() << "The number of elements to initialize: " 6965 << NumEltsToInit << ".\n"); 6966 6967 Result = APValue(APValue::UninitArray(), NumEltsToInit, NumElts); 6968 6969 // If the array was previously zero-initialized, preserve the 6970 // zero-initialized values. 6971 if (!Filler.isUninit()) { 6972 for (unsigned I = 0, E = Result.getArrayInitializedElts(); I != E; ++I) 6973 Result.getArrayInitializedElt(I) = Filler; 6974 if (Result.hasArrayFiller()) 6975 Result.getArrayFiller() = Filler; 6976 } 6977 6978 LValue Subobject = This; 6979 Subobject.addArray(Info, E, CAT); 6980 for (unsigned Index = 0; Index != NumEltsToInit; ++Index) { 6981 const Expr *Init = 6982 Index < E->getNumInits() ? E->getInit(Index) : FillerExpr; 6983 if (!EvaluateInPlace(Result.getArrayInitializedElt(Index), 6984 Info, Subobject, Init) || 6985 !HandleLValueArrayAdjustment(Info, Init, Subobject, 6986 CAT->getElementType(), 1)) { 6987 if (!Info.noteFailure()) 6988 return false; 6989 Success = false; 6990 } 6991 } 6992 6993 if (!Result.hasArrayFiller()) 6994 return Success; 6995 6996 // If we get here, we have a trivial filler, which we can just evaluate 6997 // once and splat over the rest of the array elements. 6998 assert(FillerExpr && "no array filler for incomplete init list"); 6999 return EvaluateInPlace(Result.getArrayFiller(), Info, Subobject, 7000 FillerExpr) && Success; 7001 } 7002 7003 bool ArrayExprEvaluator::VisitArrayInitLoopExpr(const ArrayInitLoopExpr *E) { 7004 if (E->getCommonExpr() && 7005 !Evaluate(Info.CurrentCall->createTemporary(E->getCommonExpr(), false), 7006 Info, E->getCommonExpr()->getSourceExpr())) 7007 return false; 7008 7009 auto *CAT = cast<ConstantArrayType>(E->getType()->castAsArrayTypeUnsafe()); 7010 7011 uint64_t Elements = CAT->getSize().getZExtValue(); 7012 Result = APValue(APValue::UninitArray(), Elements, Elements); 7013 7014 LValue Subobject = This; 7015 Subobject.addArray(Info, E, CAT); 7016 7017 bool Success = true; 7018 for (EvalInfo::ArrayInitLoopIndex Index(Info); Index != Elements; ++Index) { 7019 if (!EvaluateInPlace(Result.getArrayInitializedElt(Index), 7020 Info, Subobject, E->getSubExpr()) || 7021 !HandleLValueArrayAdjustment(Info, E, Subobject, 7022 CAT->getElementType(), 1)) { 7023 if (!Info.noteFailure()) 7024 return false; 7025 Success = false; 7026 } 7027 } 7028 7029 return Success; 7030 } 7031 7032 bool ArrayExprEvaluator::VisitCXXConstructExpr(const CXXConstructExpr *E) { 7033 return VisitCXXConstructExpr(E, This, &Result, E->getType()); 7034 } 7035 7036 bool ArrayExprEvaluator::VisitCXXConstructExpr(const CXXConstructExpr *E, 7037 const LValue &Subobject, 7038 APValue *Value, 7039 QualType Type) { 7040 bool HadZeroInit = !Value->isUninit(); 7041 7042 if (const ConstantArrayType *CAT = Info.Ctx.getAsConstantArrayType(Type)) { 7043 unsigned N = CAT->getSize().getZExtValue(); 7044 7045 // Preserve the array filler if we had prior zero-initialization. 7046 APValue Filler = 7047 HadZeroInit && Value->hasArrayFiller() ? Value->getArrayFiller() 7048 : APValue(); 7049 7050 *Value = APValue(APValue::UninitArray(), N, N); 7051 7052 if (HadZeroInit) 7053 for (unsigned I = 0; I != N; ++I) 7054 Value->getArrayInitializedElt(I) = Filler; 7055 7056 // Initialize the elements. 7057 LValue ArrayElt = Subobject; 7058 ArrayElt.addArray(Info, E, CAT); 7059 for (unsigned I = 0; I != N; ++I) 7060 if (!VisitCXXConstructExpr(E, ArrayElt, &Value->getArrayInitializedElt(I), 7061 CAT->getElementType()) || 7062 !HandleLValueArrayAdjustment(Info, E, ArrayElt, 7063 CAT->getElementType(), 1)) 7064 return false; 7065 7066 return true; 7067 } 7068 7069 if (!Type->isRecordType()) 7070 return Error(E); 7071 7072 return RecordExprEvaluator(Info, Subobject, *Value) 7073 .VisitCXXConstructExpr(E, Type); 7074 } 7075 7076 //===----------------------------------------------------------------------===// 7077 // Integer Evaluation 7078 // 7079 // As a GNU extension, we support casting pointers to sufficiently-wide integer 7080 // types and back in constant folding. Integer values are thus represented 7081 // either as an integer-valued APValue, or as an lvalue-valued APValue. 7082 //===----------------------------------------------------------------------===// 7083 7084 namespace { 7085 class IntExprEvaluator 7086 : public ExprEvaluatorBase<IntExprEvaluator> { 7087 APValue &Result; 7088 public: 7089 IntExprEvaluator(EvalInfo &info, APValue &result) 7090 : ExprEvaluatorBaseTy(info), Result(result) {} 7091 7092 bool Success(const llvm::APSInt &SI, const Expr *E, APValue &Result) { 7093 assert(E->getType()->isIntegralOrEnumerationType() && 7094 "Invalid evaluation result."); 7095 assert(SI.isSigned() == E->getType()->isSignedIntegerOrEnumerationType() && 7096 "Invalid evaluation result."); 7097 assert(SI.getBitWidth() == Info.Ctx.getIntWidth(E->getType()) && 7098 "Invalid evaluation result."); 7099 Result = APValue(SI); 7100 return true; 7101 } 7102 bool Success(const llvm::APSInt &SI, const Expr *E) { 7103 return Success(SI, E, Result); 7104 } 7105 7106 bool Success(const llvm::APInt &I, const Expr *E, APValue &Result) { 7107 assert(E->getType()->isIntegralOrEnumerationType() && 7108 "Invalid evaluation result."); 7109 assert(I.getBitWidth() == Info.Ctx.getIntWidth(E->getType()) && 7110 "Invalid evaluation result."); 7111 Result = APValue(APSInt(I)); 7112 Result.getInt().setIsUnsigned( 7113 E->getType()->isUnsignedIntegerOrEnumerationType()); 7114 return true; 7115 } 7116 bool Success(const llvm::APInt &I, const Expr *E) { 7117 return Success(I, E, Result); 7118 } 7119 7120 bool Success(uint64_t Value, const Expr *E, APValue &Result) { 7121 assert(E->getType()->isIntegralOrEnumerationType() && 7122 "Invalid evaluation result."); 7123 Result = APValue(Info.Ctx.MakeIntValue(Value, E->getType())); 7124 return true; 7125 } 7126 bool Success(uint64_t Value, const Expr *E) { 7127 return Success(Value, E, Result); 7128 } 7129 7130 bool Success(CharUnits Size, const Expr *E) { 7131 return Success(Size.getQuantity(), E); 7132 } 7133 7134 bool Success(const APValue &V, const Expr *E) { 7135 if (V.isLValue() || V.isAddrLabelDiff()) { 7136 Result = V; 7137 return true; 7138 } 7139 return Success(V.getInt(), E); 7140 } 7141 7142 bool ZeroInitialization(const Expr *E) { return Success(0, E); } 7143 7144 //===--------------------------------------------------------------------===// 7145 // Visitor Methods 7146 //===--------------------------------------------------------------------===// 7147 7148 bool VisitIntegerLiteral(const IntegerLiteral *E) { 7149 return Success(E->getValue(), E); 7150 } 7151 bool VisitCharacterLiteral(const CharacterLiteral *E) { 7152 return Success(E->getValue(), E); 7153 } 7154 7155 bool CheckReferencedDecl(const Expr *E, const Decl *D); 7156 bool VisitDeclRefExpr(const DeclRefExpr *E) { 7157 if (CheckReferencedDecl(E, E->getDecl())) 7158 return true; 7159 7160 return ExprEvaluatorBaseTy::VisitDeclRefExpr(E); 7161 } 7162 bool VisitMemberExpr(const MemberExpr *E) { 7163 if (CheckReferencedDecl(E, E->getMemberDecl())) { 7164 VisitIgnoredBaseExpression(E->getBase()); 7165 return true; 7166 } 7167 7168 return ExprEvaluatorBaseTy::VisitMemberExpr(E); 7169 } 7170 7171 bool VisitCallExpr(const CallExpr *E); 7172 bool VisitBuiltinCallExpr(const CallExpr *E, unsigned BuiltinOp); 7173 bool VisitBinaryOperator(const BinaryOperator *E); 7174 bool VisitOffsetOfExpr(const OffsetOfExpr *E); 7175 bool VisitUnaryOperator(const UnaryOperator *E); 7176 7177 bool VisitCastExpr(const CastExpr* E); 7178 bool VisitUnaryExprOrTypeTraitExpr(const UnaryExprOrTypeTraitExpr *E); 7179 7180 bool VisitCXXBoolLiteralExpr(const CXXBoolLiteralExpr *E) { 7181 return Success(E->getValue(), E); 7182 } 7183 7184 bool VisitObjCBoolLiteralExpr(const ObjCBoolLiteralExpr *E) { 7185 return Success(E->getValue(), E); 7186 } 7187 7188 bool VisitArrayInitIndexExpr(const ArrayInitIndexExpr *E) { 7189 if (Info.ArrayInitIndex == uint64_t(-1)) { 7190 // We were asked to evaluate this subexpression independent of the 7191 // enclosing ArrayInitLoopExpr. We can't do that. 7192 Info.FFDiag(E); 7193 return false; 7194 } 7195 return Success(Info.ArrayInitIndex, E); 7196 } 7197 7198 // Note, GNU defines __null as an integer, not a pointer. 7199 bool VisitGNUNullExpr(const GNUNullExpr *E) { 7200 return ZeroInitialization(E); 7201 } 7202 7203 bool VisitTypeTraitExpr(const TypeTraitExpr *E) { 7204 return Success(E->getValue(), E); 7205 } 7206 7207 bool VisitArrayTypeTraitExpr(const ArrayTypeTraitExpr *E) { 7208 return Success(E->getValue(), E); 7209 } 7210 7211 bool VisitExpressionTraitExpr(const ExpressionTraitExpr *E) { 7212 return Success(E->getValue(), E); 7213 } 7214 7215 bool VisitUnaryReal(const UnaryOperator *E); 7216 bool VisitUnaryImag(const UnaryOperator *E); 7217 7218 bool VisitCXXNoexceptExpr(const CXXNoexceptExpr *E); 7219 bool VisitSizeOfPackExpr(const SizeOfPackExpr *E); 7220 7221 // FIXME: Missing: array subscript of vector, member of vector 7222 }; 7223 7224 class FixedPointExprEvaluator 7225 : public ExprEvaluatorBase<FixedPointExprEvaluator> { 7226 APValue &Result; 7227 7228 public: 7229 FixedPointExprEvaluator(EvalInfo &info, APValue &result) 7230 : ExprEvaluatorBaseTy(info), Result(result) {} 7231 7232 bool Success(const llvm::APSInt &SI, const Expr *E, APValue &Result) { 7233 assert(E->getType()->isFixedPointType() && "Invalid evaluation result."); 7234 assert(SI.isSigned() == E->getType()->isSignedFixedPointType() && 7235 "Invalid evaluation result."); 7236 assert(SI.getBitWidth() == Info.Ctx.getIntWidth(E->getType()) && 7237 "Invalid evaluation result."); 7238 Result = APValue(SI); 7239 return true; 7240 } 7241 bool Success(const llvm::APSInt &SI, const Expr *E) { 7242 return Success(SI, E, Result); 7243 } 7244 7245 bool Success(const llvm::APInt &I, const Expr *E, APValue &Result) { 7246 assert(E->getType()->isFixedPointType() && "Invalid evaluation result."); 7247 assert(I.getBitWidth() == Info.Ctx.getIntWidth(E->getType()) && 7248 "Invalid evaluation result."); 7249 Result = APValue(APSInt(I)); 7250 Result.getInt().setIsUnsigned(E->getType()->isUnsignedFixedPointType()); 7251 return true; 7252 } 7253 bool Success(const llvm::APInt &I, const Expr *E) { 7254 return Success(I, E, Result); 7255 } 7256 7257 bool Success(uint64_t Value, const Expr *E, APValue &Result) { 7258 assert(E->getType()->isFixedPointType() && "Invalid evaluation result."); 7259 Result = APValue(Info.Ctx.MakeIntValue(Value, E->getType())); 7260 return true; 7261 } 7262 bool Success(uint64_t Value, const Expr *E) { 7263 return Success(Value, E, Result); 7264 } 7265 7266 bool Success(CharUnits Size, const Expr *E) { 7267 return Success(Size.getQuantity(), E); 7268 } 7269 7270 bool Success(const APValue &V, const Expr *E) { 7271 if (V.isLValue() || V.isAddrLabelDiff()) { 7272 Result = V; 7273 return true; 7274 } 7275 return Success(V.getInt(), E); 7276 } 7277 7278 bool ZeroInitialization(const Expr *E) { return Success(0, E); } 7279 7280 //===--------------------------------------------------------------------===// 7281 // Visitor Methods 7282 //===--------------------------------------------------------------------===// 7283 7284 bool VisitFixedPointLiteral(const FixedPointLiteral *E) { 7285 return Success(E->getValue(), E); 7286 } 7287 7288 bool VisitUnaryOperator(const UnaryOperator *E); 7289 }; 7290 } // end anonymous namespace 7291 7292 /// EvaluateIntegerOrLValue - Evaluate an rvalue integral-typed expression, and 7293 /// produce either the integer value or a pointer. 7294 /// 7295 /// GCC has a heinous extension which folds casts between pointer types and 7296 /// pointer-sized integral types. We support this by allowing the evaluation of 7297 /// an integer rvalue to produce a pointer (represented as an lvalue) instead. 7298 /// Some simple arithmetic on such values is supported (they are treated much 7299 /// like char*). 7300 static bool EvaluateIntegerOrLValue(const Expr *E, APValue &Result, 7301 EvalInfo &Info) { 7302 assert(E->isRValue() && E->getType()->isIntegralOrEnumerationType()); 7303 return IntExprEvaluator(Info, Result).Visit(E); 7304 } 7305 7306 static bool EvaluateInteger(const Expr *E, APSInt &Result, EvalInfo &Info) { 7307 APValue Val; 7308 if (!EvaluateIntegerOrLValue(E, Val, Info)) 7309 return false; 7310 if (!Val.isInt()) { 7311 // FIXME: It would be better to produce the diagnostic for casting 7312 // a pointer to an integer. 7313 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 7314 return false; 7315 } 7316 Result = Val.getInt(); 7317 return true; 7318 } 7319 7320 /// Check whether the given declaration can be directly converted to an integral 7321 /// rvalue. If not, no diagnostic is produced; there are other things we can 7322 /// try. 7323 bool IntExprEvaluator::CheckReferencedDecl(const Expr* E, const Decl* D) { 7324 // Enums are integer constant exprs. 7325 if (const EnumConstantDecl *ECD = dyn_cast<EnumConstantDecl>(D)) { 7326 // Check for signedness/width mismatches between E type and ECD value. 7327 bool SameSign = (ECD->getInitVal().isSigned() 7328 == E->getType()->isSignedIntegerOrEnumerationType()); 7329 bool SameWidth = (ECD->getInitVal().getBitWidth() 7330 == Info.Ctx.getIntWidth(E->getType())); 7331 if (SameSign && SameWidth) 7332 return Success(ECD->getInitVal(), E); 7333 else { 7334 // Get rid of mismatch (otherwise Success assertions will fail) 7335 // by computing a new value matching the type of E. 7336 llvm::APSInt Val = ECD->getInitVal(); 7337 if (!SameSign) 7338 Val.setIsSigned(!ECD->getInitVal().isSigned()); 7339 if (!SameWidth) 7340 Val = Val.extOrTrunc(Info.Ctx.getIntWidth(E->getType())); 7341 return Success(Val, E); 7342 } 7343 } 7344 return false; 7345 } 7346 7347 /// Values returned by __builtin_classify_type, chosen to match the values 7348 /// produced by GCC's builtin. 7349 enum class GCCTypeClass { 7350 None = -1, 7351 Void = 0, 7352 Integer = 1, 7353 // GCC reserves 2 for character types, but instead classifies them as 7354 // integers. 7355 Enum = 3, 7356 Bool = 4, 7357 Pointer = 5, 7358 // GCC reserves 6 for references, but appears to never use it (because 7359 // expressions never have reference type, presumably). 7360 PointerToDataMember = 7, 7361 RealFloat = 8, 7362 Complex = 9, 7363 // GCC reserves 10 for functions, but does not use it since GCC version 6 due 7364 // to decay to pointer. (Prior to version 6 it was only used in C++ mode). 7365 // GCC claims to reserve 11 for pointers to member functions, but *actually* 7366 // uses 12 for that purpose, same as for a class or struct. Maybe it 7367 // internally implements a pointer to member as a struct? Who knows. 7368 PointerToMemberFunction = 12, // Not a bug, see above. 7369 ClassOrStruct = 12, 7370 Union = 13, 7371 // GCC reserves 14 for arrays, but does not use it since GCC version 6 due to 7372 // decay to pointer. (Prior to version 6 it was only used in C++ mode). 7373 // GCC reserves 15 for strings, but actually uses 5 (pointer) for string 7374 // literals. 7375 }; 7376 7377 /// EvaluateBuiltinClassifyType - Evaluate __builtin_classify_type the same way 7378 /// as GCC. 7379 static GCCTypeClass 7380 EvaluateBuiltinClassifyType(QualType T, const LangOptions &LangOpts) { 7381 assert(!T->isDependentType() && "unexpected dependent type"); 7382 7383 QualType CanTy = T.getCanonicalType(); 7384 const BuiltinType *BT = dyn_cast<BuiltinType>(CanTy); 7385 7386 switch (CanTy->getTypeClass()) { 7387 #define TYPE(ID, BASE) 7388 #define DEPENDENT_TYPE(ID, BASE) case Type::ID: 7389 #define NON_CANONICAL_TYPE(ID, BASE) case Type::ID: 7390 #define NON_CANONICAL_UNLESS_DEPENDENT_TYPE(ID, BASE) case Type::ID: 7391 #include "clang/AST/TypeNodes.def" 7392 case Type::Auto: 7393 case Type::DeducedTemplateSpecialization: 7394 llvm_unreachable("unexpected non-canonical or dependent type"); 7395 7396 case Type::Builtin: 7397 switch (BT->getKind()) { 7398 #define BUILTIN_TYPE(ID, SINGLETON_ID) 7399 #define SIGNED_TYPE(ID, SINGLETON_ID) \ 7400 case BuiltinType::ID: return GCCTypeClass::Integer; 7401 #define FLOATING_TYPE(ID, SINGLETON_ID) \ 7402 case BuiltinType::ID: return GCCTypeClass::RealFloat; 7403 #define PLACEHOLDER_TYPE(ID, SINGLETON_ID) \ 7404 case BuiltinType::ID: break; 7405 #include "clang/AST/BuiltinTypes.def" 7406 case BuiltinType::Void: 7407 return GCCTypeClass::Void; 7408 7409 case BuiltinType::Bool: 7410 return GCCTypeClass::Bool; 7411 7412 case BuiltinType::Char_U: 7413 case BuiltinType::UChar: 7414 case BuiltinType::WChar_U: 7415 case BuiltinType::Char8: 7416 case BuiltinType::Char16: 7417 case BuiltinType::Char32: 7418 case BuiltinType::UShort: 7419 case BuiltinType::UInt: 7420 case BuiltinType::ULong: 7421 case BuiltinType::ULongLong: 7422 case BuiltinType::UInt128: 7423 return GCCTypeClass::Integer; 7424 7425 case BuiltinType::UShortAccum: 7426 case BuiltinType::UAccum: 7427 case BuiltinType::ULongAccum: 7428 case BuiltinType::UShortFract: 7429 case BuiltinType::UFract: 7430 case BuiltinType::ULongFract: 7431 case BuiltinType::SatUShortAccum: 7432 case BuiltinType::SatUAccum: 7433 case BuiltinType::SatULongAccum: 7434 case BuiltinType::SatUShortFract: 7435 case BuiltinType::SatUFract: 7436 case BuiltinType::SatULongFract: 7437 return GCCTypeClass::None; 7438 7439 case BuiltinType::NullPtr: 7440 7441 case BuiltinType::ObjCId: 7442 case BuiltinType::ObjCClass: 7443 case BuiltinType::ObjCSel: 7444 #define IMAGE_TYPE(ImgType, Id, SingletonId, Access, Suffix) \ 7445 case BuiltinType::Id: 7446 #include "clang/Basic/OpenCLImageTypes.def" 7447 case BuiltinType::OCLSampler: 7448 case BuiltinType::OCLEvent: 7449 case BuiltinType::OCLClkEvent: 7450 case BuiltinType::OCLQueue: 7451 case BuiltinType::OCLReserveID: 7452 return GCCTypeClass::None; 7453 7454 case BuiltinType::Dependent: 7455 llvm_unreachable("unexpected dependent type"); 7456 }; 7457 llvm_unreachable("unexpected placeholder type"); 7458 7459 case Type::Enum: 7460 return LangOpts.CPlusPlus ? GCCTypeClass::Enum : GCCTypeClass::Integer; 7461 7462 case Type::Pointer: 7463 case Type::ConstantArray: 7464 case Type::VariableArray: 7465 case Type::IncompleteArray: 7466 case Type::FunctionNoProto: 7467 case Type::FunctionProto: 7468 return GCCTypeClass::Pointer; 7469 7470 case Type::MemberPointer: 7471 return CanTy->isMemberDataPointerType() 7472 ? GCCTypeClass::PointerToDataMember 7473 : GCCTypeClass::PointerToMemberFunction; 7474 7475 case Type::Complex: 7476 return GCCTypeClass::Complex; 7477 7478 case Type::Record: 7479 return CanTy->isUnionType() ? GCCTypeClass::Union 7480 : GCCTypeClass::ClassOrStruct; 7481 7482 case Type::Atomic: 7483 // GCC classifies _Atomic T the same as T. 7484 return EvaluateBuiltinClassifyType( 7485 CanTy->castAs<AtomicType>()->getValueType(), LangOpts); 7486 7487 case Type::BlockPointer: 7488 case Type::Vector: 7489 case Type::ExtVector: 7490 case Type::ObjCObject: 7491 case Type::ObjCInterface: 7492 case Type::ObjCObjectPointer: 7493 case Type::Pipe: 7494 // GCC classifies vectors as None. We follow its lead and classify all 7495 // other types that don't fit into the regular classification the same way. 7496 return GCCTypeClass::None; 7497 7498 case Type::LValueReference: 7499 case Type::RValueReference: 7500 llvm_unreachable("invalid type for expression"); 7501 } 7502 7503 llvm_unreachable("unexpected type class"); 7504 } 7505 7506 /// EvaluateBuiltinClassifyType - Evaluate __builtin_classify_type the same way 7507 /// as GCC. 7508 static GCCTypeClass 7509 EvaluateBuiltinClassifyType(const CallExpr *E, const LangOptions &LangOpts) { 7510 // If no argument was supplied, default to None. This isn't 7511 // ideal, however it is what gcc does. 7512 if (E->getNumArgs() == 0) 7513 return GCCTypeClass::None; 7514 7515 // FIXME: Bizarrely, GCC treats a call with more than one argument as not 7516 // being an ICE, but still folds it to a constant using the type of the first 7517 // argument. 7518 return EvaluateBuiltinClassifyType(E->getArg(0)->getType(), LangOpts); 7519 } 7520 7521 /// EvaluateBuiltinConstantPForLValue - Determine the result of 7522 /// __builtin_constant_p when applied to the given lvalue. 7523 /// 7524 /// An lvalue is only "constant" if it is a pointer or reference to the first 7525 /// character of a string literal. 7526 template<typename LValue> 7527 static bool EvaluateBuiltinConstantPForLValue(const LValue &LV) { 7528 const Expr *E = LV.getLValueBase().template dyn_cast<const Expr*>(); 7529 return E && isa<StringLiteral>(E) && LV.getLValueOffset().isZero(); 7530 } 7531 7532 /// EvaluateBuiltinConstantP - Evaluate __builtin_constant_p as similarly to 7533 /// GCC as we can manage. 7534 static bool EvaluateBuiltinConstantP(ASTContext &Ctx, const Expr *Arg) { 7535 QualType ArgType = Arg->getType(); 7536 7537 // __builtin_constant_p always has one operand. The rules which gcc follows 7538 // are not precisely documented, but are as follows: 7539 // 7540 // - If the operand is of integral, floating, complex or enumeration type, 7541 // and can be folded to a known value of that type, it returns 1. 7542 // - If the operand and can be folded to a pointer to the first character 7543 // of a string literal (or such a pointer cast to an integral type), it 7544 // returns 1. 7545 // 7546 // Otherwise, it returns 0. 7547 // 7548 // FIXME: GCC also intends to return 1 for literals of aggregate types, but 7549 // its support for this does not currently work. 7550 if (ArgType->isIntegralOrEnumerationType()) { 7551 Expr::EvalResult Result; 7552 if (!Arg->EvaluateAsRValue(Result, Ctx) || Result.HasSideEffects) 7553 return false; 7554 7555 APValue &V = Result.Val; 7556 if (V.getKind() == APValue::Int) 7557 return true; 7558 if (V.getKind() == APValue::LValue) 7559 return EvaluateBuiltinConstantPForLValue(V); 7560 } else if (ArgType->isFloatingType() || ArgType->isAnyComplexType()) { 7561 return Arg->isEvaluatable(Ctx); 7562 } else if (ArgType->isPointerType() || Arg->isGLValue()) { 7563 LValue LV; 7564 Expr::EvalStatus Status; 7565 EvalInfo Info(Ctx, Status, EvalInfo::EM_ConstantFold); 7566 if ((Arg->isGLValue() ? EvaluateLValue(Arg, LV, Info) 7567 : EvaluatePointer(Arg, LV, Info)) && 7568 !Status.HasSideEffects) 7569 return EvaluateBuiltinConstantPForLValue(LV); 7570 } 7571 7572 // Anything else isn't considered to be sufficiently constant. 7573 return false; 7574 } 7575 7576 /// Retrieves the "underlying object type" of the given expression, 7577 /// as used by __builtin_object_size. 7578 static QualType getObjectType(APValue::LValueBase B) { 7579 if (const ValueDecl *D = B.dyn_cast<const ValueDecl*>()) { 7580 if (const VarDecl *VD = dyn_cast<VarDecl>(D)) 7581 return VD->getType(); 7582 } else if (const Expr *E = B.get<const Expr*>()) { 7583 if (isa<CompoundLiteralExpr>(E)) 7584 return E->getType(); 7585 } 7586 7587 return QualType(); 7588 } 7589 7590 /// A more selective version of E->IgnoreParenCasts for 7591 /// tryEvaluateBuiltinObjectSize. This ignores some casts/parens that serve only 7592 /// to change the type of E. 7593 /// Ex. For E = `(short*)((char*)(&foo))`, returns `&foo` 7594 /// 7595 /// Always returns an RValue with a pointer representation. 7596 static const Expr *ignorePointerCastsAndParens(const Expr *E) { 7597 assert(E->isRValue() && E->getType()->hasPointerRepresentation()); 7598 7599 auto *NoParens = E->IgnoreParens(); 7600 auto *Cast = dyn_cast<CastExpr>(NoParens); 7601 if (Cast == nullptr) 7602 return NoParens; 7603 7604 // We only conservatively allow a few kinds of casts, because this code is 7605 // inherently a simple solution that seeks to support the common case. 7606 auto CastKind = Cast->getCastKind(); 7607 if (CastKind != CK_NoOp && CastKind != CK_BitCast && 7608 CastKind != CK_AddressSpaceConversion) 7609 return NoParens; 7610 7611 auto *SubExpr = Cast->getSubExpr(); 7612 if (!SubExpr->getType()->hasPointerRepresentation() || !SubExpr->isRValue()) 7613 return NoParens; 7614 return ignorePointerCastsAndParens(SubExpr); 7615 } 7616 7617 /// Checks to see if the given LValue's Designator is at the end of the LValue's 7618 /// record layout. e.g. 7619 /// struct { struct { int a, b; } fst, snd; } obj; 7620 /// obj.fst // no 7621 /// obj.snd // yes 7622 /// obj.fst.a // no 7623 /// obj.fst.b // no 7624 /// obj.snd.a // no 7625 /// obj.snd.b // yes 7626 /// 7627 /// Please note: this function is specialized for how __builtin_object_size 7628 /// views "objects". 7629 /// 7630 /// If this encounters an invalid RecordDecl or otherwise cannot determine the 7631 /// correct result, it will always return true. 7632 static bool isDesignatorAtObjectEnd(const ASTContext &Ctx, const LValue &LVal) { 7633 assert(!LVal.Designator.Invalid); 7634 7635 auto IsLastOrInvalidFieldDecl = [&Ctx](const FieldDecl *FD, bool &Invalid) { 7636 const RecordDecl *Parent = FD->getParent(); 7637 Invalid = Parent->isInvalidDecl(); 7638 if (Invalid || Parent->isUnion()) 7639 return true; 7640 const ASTRecordLayout &Layout = Ctx.getASTRecordLayout(Parent); 7641 return FD->getFieldIndex() + 1 == Layout.getFieldCount(); 7642 }; 7643 7644 auto &Base = LVal.getLValueBase(); 7645 if (auto *ME = dyn_cast_or_null<MemberExpr>(Base.dyn_cast<const Expr *>())) { 7646 if (auto *FD = dyn_cast<FieldDecl>(ME->getMemberDecl())) { 7647 bool Invalid; 7648 if (!IsLastOrInvalidFieldDecl(FD, Invalid)) 7649 return Invalid; 7650 } else if (auto *IFD = dyn_cast<IndirectFieldDecl>(ME->getMemberDecl())) { 7651 for (auto *FD : IFD->chain()) { 7652 bool Invalid; 7653 if (!IsLastOrInvalidFieldDecl(cast<FieldDecl>(FD), Invalid)) 7654 return Invalid; 7655 } 7656 } 7657 } 7658 7659 unsigned I = 0; 7660 QualType BaseType = getType(Base); 7661 if (LVal.Designator.FirstEntryIsAnUnsizedArray) { 7662 // If we don't know the array bound, conservatively assume we're looking at 7663 // the final array element. 7664 ++I; 7665 if (BaseType->isIncompleteArrayType()) 7666 BaseType = Ctx.getAsArrayType(BaseType)->getElementType(); 7667 else 7668 BaseType = BaseType->castAs<PointerType>()->getPointeeType(); 7669 } 7670 7671 for (unsigned E = LVal.Designator.Entries.size(); I != E; ++I) { 7672 const auto &Entry = LVal.Designator.Entries[I]; 7673 if (BaseType->isArrayType()) { 7674 // Because __builtin_object_size treats arrays as objects, we can ignore 7675 // the index iff this is the last array in the Designator. 7676 if (I + 1 == E) 7677 return true; 7678 const auto *CAT = cast<ConstantArrayType>(Ctx.getAsArrayType(BaseType)); 7679 uint64_t Index = Entry.ArrayIndex; 7680 if (Index + 1 != CAT->getSize()) 7681 return false; 7682 BaseType = CAT->getElementType(); 7683 } else if (BaseType->isAnyComplexType()) { 7684 const auto *CT = BaseType->castAs<ComplexType>(); 7685 uint64_t Index = Entry.ArrayIndex; 7686 if (Index != 1) 7687 return false; 7688 BaseType = CT->getElementType(); 7689 } else if (auto *FD = getAsField(Entry)) { 7690 bool Invalid; 7691 if (!IsLastOrInvalidFieldDecl(FD, Invalid)) 7692 return Invalid; 7693 BaseType = FD->getType(); 7694 } else { 7695 assert(getAsBaseClass(Entry) && "Expecting cast to a base class"); 7696 return false; 7697 } 7698 } 7699 return true; 7700 } 7701 7702 /// Tests to see if the LValue has a user-specified designator (that isn't 7703 /// necessarily valid). Note that this always returns 'true' if the LValue has 7704 /// an unsized array as its first designator entry, because there's currently no 7705 /// way to tell if the user typed *foo or foo[0]. 7706 static bool refersToCompleteObject(const LValue &LVal) { 7707 if (LVal.Designator.Invalid) 7708 return false; 7709 7710 if (!LVal.Designator.Entries.empty()) 7711 return LVal.Designator.isMostDerivedAnUnsizedArray(); 7712 7713 if (!LVal.InvalidBase) 7714 return true; 7715 7716 // If `E` is a MemberExpr, then the first part of the designator is hiding in 7717 // the LValueBase. 7718 const auto *E = LVal.Base.dyn_cast<const Expr *>(); 7719 return !E || !isa<MemberExpr>(E); 7720 } 7721 7722 /// Attempts to detect a user writing into a piece of memory that's impossible 7723 /// to figure out the size of by just using types. 7724 static bool isUserWritingOffTheEnd(const ASTContext &Ctx, const LValue &LVal) { 7725 const SubobjectDesignator &Designator = LVal.Designator; 7726 // Notes: 7727 // - Users can only write off of the end when we have an invalid base. Invalid 7728 // bases imply we don't know where the memory came from. 7729 // - We used to be a bit more aggressive here; we'd only be conservative if 7730 // the array at the end was flexible, or if it had 0 or 1 elements. This 7731 // broke some common standard library extensions (PR30346), but was 7732 // otherwise seemingly fine. It may be useful to reintroduce this behavior 7733 // with some sort of whitelist. OTOH, it seems that GCC is always 7734 // conservative with the last element in structs (if it's an array), so our 7735 // current behavior is more compatible than a whitelisting approach would 7736 // be. 7737 return LVal.InvalidBase && 7738 Designator.Entries.size() == Designator.MostDerivedPathLength && 7739 Designator.MostDerivedIsArrayElement && 7740 isDesignatorAtObjectEnd(Ctx, LVal); 7741 } 7742 7743 /// Converts the given APInt to CharUnits, assuming the APInt is unsigned. 7744 /// Fails if the conversion would cause loss of precision. 7745 static bool convertUnsignedAPIntToCharUnits(const llvm::APInt &Int, 7746 CharUnits &Result) { 7747 auto CharUnitsMax = std::numeric_limits<CharUnits::QuantityType>::max(); 7748 if (Int.ugt(CharUnitsMax)) 7749 return false; 7750 Result = CharUnits::fromQuantity(Int.getZExtValue()); 7751 return true; 7752 } 7753 7754 /// Helper for tryEvaluateBuiltinObjectSize -- Given an LValue, this will 7755 /// determine how many bytes exist from the beginning of the object to either 7756 /// the end of the current subobject, or the end of the object itself, depending 7757 /// on what the LValue looks like + the value of Type. 7758 /// 7759 /// If this returns false, the value of Result is undefined. 7760 static bool determineEndOffset(EvalInfo &Info, SourceLocation ExprLoc, 7761 unsigned Type, const LValue &LVal, 7762 CharUnits &EndOffset) { 7763 bool DetermineForCompleteObject = refersToCompleteObject(LVal); 7764 7765 auto CheckedHandleSizeof = [&](QualType Ty, CharUnits &Result) { 7766 if (Ty.isNull() || Ty->isIncompleteType() || Ty->isFunctionType()) 7767 return false; 7768 return HandleSizeof(Info, ExprLoc, Ty, Result); 7769 }; 7770 7771 // We want to evaluate the size of the entire object. This is a valid fallback 7772 // for when Type=1 and the designator is invalid, because we're asked for an 7773 // upper-bound. 7774 if (!(Type & 1) || LVal.Designator.Invalid || DetermineForCompleteObject) { 7775 // Type=3 wants a lower bound, so we can't fall back to this. 7776 if (Type == 3 && !DetermineForCompleteObject) 7777 return false; 7778 7779 llvm::APInt APEndOffset; 7780 if (isBaseAnAllocSizeCall(LVal.getLValueBase()) && 7781 getBytesReturnedByAllocSizeCall(Info.Ctx, LVal, APEndOffset)) 7782 return convertUnsignedAPIntToCharUnits(APEndOffset, EndOffset); 7783 7784 if (LVal.InvalidBase) 7785 return false; 7786 7787 QualType BaseTy = getObjectType(LVal.getLValueBase()); 7788 return CheckedHandleSizeof(BaseTy, EndOffset); 7789 } 7790 7791 // We want to evaluate the size of a subobject. 7792 const SubobjectDesignator &Designator = LVal.Designator; 7793 7794 // The following is a moderately common idiom in C: 7795 // 7796 // struct Foo { int a; char c[1]; }; 7797 // struct Foo *F = (struct Foo *)malloc(sizeof(struct Foo) + strlen(Bar)); 7798 // strcpy(&F->c[0], Bar); 7799 // 7800 // In order to not break too much legacy code, we need to support it. 7801 if (isUserWritingOffTheEnd(Info.Ctx, LVal)) { 7802 // If we can resolve this to an alloc_size call, we can hand that back, 7803 // because we know for certain how many bytes there are to write to. 7804 llvm::APInt APEndOffset; 7805 if (isBaseAnAllocSizeCall(LVal.getLValueBase()) && 7806 getBytesReturnedByAllocSizeCall(Info.Ctx, LVal, APEndOffset)) 7807 return convertUnsignedAPIntToCharUnits(APEndOffset, EndOffset); 7808 7809 // If we cannot determine the size of the initial allocation, then we can't 7810 // given an accurate upper-bound. However, we are still able to give 7811 // conservative lower-bounds for Type=3. 7812 if (Type == 1) 7813 return false; 7814 } 7815 7816 CharUnits BytesPerElem; 7817 if (!CheckedHandleSizeof(Designator.MostDerivedType, BytesPerElem)) 7818 return false; 7819 7820 // According to the GCC documentation, we want the size of the subobject 7821 // denoted by the pointer. But that's not quite right -- what we actually 7822 // want is the size of the immediately-enclosing array, if there is one. 7823 int64_t ElemsRemaining; 7824 if (Designator.MostDerivedIsArrayElement && 7825 Designator.Entries.size() == Designator.MostDerivedPathLength) { 7826 uint64_t ArraySize = Designator.getMostDerivedArraySize(); 7827 uint64_t ArrayIndex = Designator.Entries.back().ArrayIndex; 7828 ElemsRemaining = ArraySize <= ArrayIndex ? 0 : ArraySize - ArrayIndex; 7829 } else { 7830 ElemsRemaining = Designator.isOnePastTheEnd() ? 0 : 1; 7831 } 7832 7833 EndOffset = LVal.getLValueOffset() + BytesPerElem * ElemsRemaining; 7834 return true; 7835 } 7836 7837 /// Tries to evaluate the __builtin_object_size for @p E. If successful, 7838 /// returns true and stores the result in @p Size. 7839 /// 7840 /// If @p WasError is non-null, this will report whether the failure to evaluate 7841 /// is to be treated as an Error in IntExprEvaluator. 7842 static bool tryEvaluateBuiltinObjectSize(const Expr *E, unsigned Type, 7843 EvalInfo &Info, uint64_t &Size) { 7844 // Determine the denoted object. 7845 LValue LVal; 7846 { 7847 // The operand of __builtin_object_size is never evaluated for side-effects. 7848 // If there are any, but we can determine the pointed-to object anyway, then 7849 // ignore the side-effects. 7850 SpeculativeEvaluationRAII SpeculativeEval(Info); 7851 FoldOffsetRAII Fold(Info); 7852 7853 if (E->isGLValue()) { 7854 // It's possible for us to be given GLValues if we're called via 7855 // Expr::tryEvaluateObjectSize. 7856 APValue RVal; 7857 if (!EvaluateAsRValue(Info, E, RVal)) 7858 return false; 7859 LVal.setFrom(Info.Ctx, RVal); 7860 } else if (!EvaluatePointer(ignorePointerCastsAndParens(E), LVal, Info, 7861 /*InvalidBaseOK=*/true)) 7862 return false; 7863 } 7864 7865 // If we point to before the start of the object, there are no accessible 7866 // bytes. 7867 if (LVal.getLValueOffset().isNegative()) { 7868 Size = 0; 7869 return true; 7870 } 7871 7872 CharUnits EndOffset; 7873 if (!determineEndOffset(Info, E->getExprLoc(), Type, LVal, EndOffset)) 7874 return false; 7875 7876 // If we've fallen outside of the end offset, just pretend there's nothing to 7877 // write to/read from. 7878 if (EndOffset <= LVal.getLValueOffset()) 7879 Size = 0; 7880 else 7881 Size = (EndOffset - LVal.getLValueOffset()).getQuantity(); 7882 return true; 7883 } 7884 7885 bool IntExprEvaluator::VisitCallExpr(const CallExpr *E) { 7886 if (unsigned BuiltinOp = E->getBuiltinCallee()) 7887 return VisitBuiltinCallExpr(E, BuiltinOp); 7888 7889 return ExprEvaluatorBaseTy::VisitCallExpr(E); 7890 } 7891 7892 bool IntExprEvaluator::VisitBuiltinCallExpr(const CallExpr *E, 7893 unsigned BuiltinOp) { 7894 switch (unsigned BuiltinOp = E->getBuiltinCallee()) { 7895 default: 7896 return ExprEvaluatorBaseTy::VisitCallExpr(E); 7897 7898 case Builtin::BI__builtin_object_size: { 7899 // The type was checked when we built the expression. 7900 unsigned Type = 7901 E->getArg(1)->EvaluateKnownConstInt(Info.Ctx).getZExtValue(); 7902 assert(Type <= 3 && "unexpected type"); 7903 7904 uint64_t Size; 7905 if (tryEvaluateBuiltinObjectSize(E->getArg(0), Type, Info, Size)) 7906 return Success(Size, E); 7907 7908 if (E->getArg(0)->HasSideEffects(Info.Ctx)) 7909 return Success((Type & 2) ? 0 : -1, E); 7910 7911 // Expression had no side effects, but we couldn't statically determine the 7912 // size of the referenced object. 7913 switch (Info.EvalMode) { 7914 case EvalInfo::EM_ConstantExpression: 7915 case EvalInfo::EM_PotentialConstantExpression: 7916 case EvalInfo::EM_ConstantFold: 7917 case EvalInfo::EM_EvaluateForOverflow: 7918 case EvalInfo::EM_IgnoreSideEffects: 7919 case EvalInfo::EM_OffsetFold: 7920 // Leave it to IR generation. 7921 return Error(E); 7922 case EvalInfo::EM_ConstantExpressionUnevaluated: 7923 case EvalInfo::EM_PotentialConstantExpressionUnevaluated: 7924 // Reduce it to a constant now. 7925 return Success((Type & 2) ? 0 : -1, E); 7926 } 7927 7928 llvm_unreachable("unexpected EvalMode"); 7929 } 7930 7931 case Builtin::BI__builtin_bswap16: 7932 case Builtin::BI__builtin_bswap32: 7933 case Builtin::BI__builtin_bswap64: { 7934 APSInt Val; 7935 if (!EvaluateInteger(E->getArg(0), Val, Info)) 7936 return false; 7937 7938 return Success(Val.byteSwap(), E); 7939 } 7940 7941 case Builtin::BI__builtin_classify_type: 7942 return Success((int)EvaluateBuiltinClassifyType(E, Info.getLangOpts()), E); 7943 7944 // FIXME: BI__builtin_clrsb 7945 // FIXME: BI__builtin_clrsbl 7946 // FIXME: BI__builtin_clrsbll 7947 7948 case Builtin::BI__builtin_clz: 7949 case Builtin::BI__builtin_clzl: 7950 case Builtin::BI__builtin_clzll: 7951 case Builtin::BI__builtin_clzs: { 7952 APSInt Val; 7953 if (!EvaluateInteger(E->getArg(0), Val, Info)) 7954 return false; 7955 if (!Val) 7956 return Error(E); 7957 7958 return Success(Val.countLeadingZeros(), E); 7959 } 7960 7961 case Builtin::BI__builtin_constant_p: 7962 return Success(EvaluateBuiltinConstantP(Info.Ctx, E->getArg(0)), E); 7963 7964 case Builtin::BI__builtin_ctz: 7965 case Builtin::BI__builtin_ctzl: 7966 case Builtin::BI__builtin_ctzll: 7967 case Builtin::BI__builtin_ctzs: { 7968 APSInt Val; 7969 if (!EvaluateInteger(E->getArg(0), Val, Info)) 7970 return false; 7971 if (!Val) 7972 return Error(E); 7973 7974 return Success(Val.countTrailingZeros(), E); 7975 } 7976 7977 case Builtin::BI__builtin_eh_return_data_regno: { 7978 int Operand = E->getArg(0)->EvaluateKnownConstInt(Info.Ctx).getZExtValue(); 7979 Operand = Info.Ctx.getTargetInfo().getEHDataRegisterNumber(Operand); 7980 return Success(Operand, E); 7981 } 7982 7983 case Builtin::BI__builtin_expect: 7984 return Visit(E->getArg(0)); 7985 7986 case Builtin::BI__builtin_ffs: 7987 case Builtin::BI__builtin_ffsl: 7988 case Builtin::BI__builtin_ffsll: { 7989 APSInt Val; 7990 if (!EvaluateInteger(E->getArg(0), Val, Info)) 7991 return false; 7992 7993 unsigned N = Val.countTrailingZeros(); 7994 return Success(N == Val.getBitWidth() ? 0 : N + 1, E); 7995 } 7996 7997 case Builtin::BI__builtin_fpclassify: { 7998 APFloat Val(0.0); 7999 if (!EvaluateFloat(E->getArg(5), Val, Info)) 8000 return false; 8001 unsigned Arg; 8002 switch (Val.getCategory()) { 8003 case APFloat::fcNaN: Arg = 0; break; 8004 case APFloat::fcInfinity: Arg = 1; break; 8005 case APFloat::fcNormal: Arg = Val.isDenormal() ? 3 : 2; break; 8006 case APFloat::fcZero: Arg = 4; break; 8007 } 8008 return Visit(E->getArg(Arg)); 8009 } 8010 8011 case Builtin::BI__builtin_isinf_sign: { 8012 APFloat Val(0.0); 8013 return EvaluateFloat(E->getArg(0), Val, Info) && 8014 Success(Val.isInfinity() ? (Val.isNegative() ? -1 : 1) : 0, E); 8015 } 8016 8017 case Builtin::BI__builtin_isinf: { 8018 APFloat Val(0.0); 8019 return EvaluateFloat(E->getArg(0), Val, Info) && 8020 Success(Val.isInfinity() ? 1 : 0, E); 8021 } 8022 8023 case Builtin::BI__builtin_isfinite: { 8024 APFloat Val(0.0); 8025 return EvaluateFloat(E->getArg(0), Val, Info) && 8026 Success(Val.isFinite() ? 1 : 0, E); 8027 } 8028 8029 case Builtin::BI__builtin_isnan: { 8030 APFloat Val(0.0); 8031 return EvaluateFloat(E->getArg(0), Val, Info) && 8032 Success(Val.isNaN() ? 1 : 0, E); 8033 } 8034 8035 case Builtin::BI__builtin_isnormal: { 8036 APFloat Val(0.0); 8037 return EvaluateFloat(E->getArg(0), Val, Info) && 8038 Success(Val.isNormal() ? 1 : 0, E); 8039 } 8040 8041 case Builtin::BI__builtin_parity: 8042 case Builtin::BI__builtin_parityl: 8043 case Builtin::BI__builtin_parityll: { 8044 APSInt Val; 8045 if (!EvaluateInteger(E->getArg(0), Val, Info)) 8046 return false; 8047 8048 return Success(Val.countPopulation() % 2, E); 8049 } 8050 8051 case Builtin::BI__builtin_popcount: 8052 case Builtin::BI__builtin_popcountl: 8053 case Builtin::BI__builtin_popcountll: { 8054 APSInt Val; 8055 if (!EvaluateInteger(E->getArg(0), Val, Info)) 8056 return false; 8057 8058 return Success(Val.countPopulation(), E); 8059 } 8060 8061 case Builtin::BIstrlen: 8062 case Builtin::BIwcslen: 8063 // A call to strlen is not a constant expression. 8064 if (Info.getLangOpts().CPlusPlus11) 8065 Info.CCEDiag(E, diag::note_constexpr_invalid_function) 8066 << /*isConstexpr*/0 << /*isConstructor*/0 8067 << (std::string("'") + Info.Ctx.BuiltinInfo.getName(BuiltinOp) + "'"); 8068 else 8069 Info.CCEDiag(E, diag::note_invalid_subexpr_in_const_expr); 8070 LLVM_FALLTHROUGH; 8071 case Builtin::BI__builtin_strlen: 8072 case Builtin::BI__builtin_wcslen: { 8073 // As an extension, we support __builtin_strlen() as a constant expression, 8074 // and support folding strlen() to a constant. 8075 LValue String; 8076 if (!EvaluatePointer(E->getArg(0), String, Info)) 8077 return false; 8078 8079 QualType CharTy = E->getArg(0)->getType()->getPointeeType(); 8080 8081 // Fast path: if it's a string literal, search the string value. 8082 if (const StringLiteral *S = dyn_cast_or_null<StringLiteral>( 8083 String.getLValueBase().dyn_cast<const Expr *>())) { 8084 // The string literal may have embedded null characters. Find the first 8085 // one and truncate there. 8086 StringRef Str = S->getBytes(); 8087 int64_t Off = String.Offset.getQuantity(); 8088 if (Off >= 0 && (uint64_t)Off <= (uint64_t)Str.size() && 8089 S->getCharByteWidth() == 1 && 8090 // FIXME: Add fast-path for wchar_t too. 8091 Info.Ctx.hasSameUnqualifiedType(CharTy, Info.Ctx.CharTy)) { 8092 Str = Str.substr(Off); 8093 8094 StringRef::size_type Pos = Str.find(0); 8095 if (Pos != StringRef::npos) 8096 Str = Str.substr(0, Pos); 8097 8098 return Success(Str.size(), E); 8099 } 8100 8101 // Fall through to slow path to issue appropriate diagnostic. 8102 } 8103 8104 // Slow path: scan the bytes of the string looking for the terminating 0. 8105 for (uint64_t Strlen = 0; /**/; ++Strlen) { 8106 APValue Char; 8107 if (!handleLValueToRValueConversion(Info, E, CharTy, String, Char) || 8108 !Char.isInt()) 8109 return false; 8110 if (!Char.getInt()) 8111 return Success(Strlen, E); 8112 if (!HandleLValueArrayAdjustment(Info, E, String, CharTy, 1)) 8113 return false; 8114 } 8115 } 8116 8117 case Builtin::BIstrcmp: 8118 case Builtin::BIwcscmp: 8119 case Builtin::BIstrncmp: 8120 case Builtin::BIwcsncmp: 8121 case Builtin::BImemcmp: 8122 case Builtin::BIwmemcmp: 8123 // A call to strlen is not a constant expression. 8124 if (Info.getLangOpts().CPlusPlus11) 8125 Info.CCEDiag(E, diag::note_constexpr_invalid_function) 8126 << /*isConstexpr*/0 << /*isConstructor*/0 8127 << (std::string("'") + Info.Ctx.BuiltinInfo.getName(BuiltinOp) + "'"); 8128 else 8129 Info.CCEDiag(E, diag::note_invalid_subexpr_in_const_expr); 8130 LLVM_FALLTHROUGH; 8131 case Builtin::BI__builtin_strcmp: 8132 case Builtin::BI__builtin_wcscmp: 8133 case Builtin::BI__builtin_strncmp: 8134 case Builtin::BI__builtin_wcsncmp: 8135 case Builtin::BI__builtin_memcmp: 8136 case Builtin::BI__builtin_wmemcmp: { 8137 LValue String1, String2; 8138 if (!EvaluatePointer(E->getArg(0), String1, Info) || 8139 !EvaluatePointer(E->getArg(1), String2, Info)) 8140 return false; 8141 8142 QualType CharTy = E->getArg(0)->getType()->getPointeeType(); 8143 8144 uint64_t MaxLength = uint64_t(-1); 8145 if (BuiltinOp != Builtin::BIstrcmp && 8146 BuiltinOp != Builtin::BIwcscmp && 8147 BuiltinOp != Builtin::BI__builtin_strcmp && 8148 BuiltinOp != Builtin::BI__builtin_wcscmp) { 8149 APSInt N; 8150 if (!EvaluateInteger(E->getArg(2), N, Info)) 8151 return false; 8152 MaxLength = N.getExtValue(); 8153 } 8154 bool StopAtNull = (BuiltinOp != Builtin::BImemcmp && 8155 BuiltinOp != Builtin::BIwmemcmp && 8156 BuiltinOp != Builtin::BI__builtin_memcmp && 8157 BuiltinOp != Builtin::BI__builtin_wmemcmp); 8158 bool IsWide = BuiltinOp == Builtin::BIwcscmp || 8159 BuiltinOp == Builtin::BIwcsncmp || 8160 BuiltinOp == Builtin::BIwmemcmp || 8161 BuiltinOp == Builtin::BI__builtin_wcscmp || 8162 BuiltinOp == Builtin::BI__builtin_wcsncmp || 8163 BuiltinOp == Builtin::BI__builtin_wmemcmp; 8164 for (; MaxLength; --MaxLength) { 8165 APValue Char1, Char2; 8166 if (!handleLValueToRValueConversion(Info, E, CharTy, String1, Char1) || 8167 !handleLValueToRValueConversion(Info, E, CharTy, String2, Char2) || 8168 !Char1.isInt() || !Char2.isInt()) 8169 return false; 8170 if (Char1.getInt() != Char2.getInt()) { 8171 if (IsWide) // wmemcmp compares with wchar_t signedness. 8172 return Success(Char1.getInt() < Char2.getInt() ? -1 : 1, E); 8173 // memcmp always compares unsigned chars. 8174 return Success(Char1.getInt().ult(Char2.getInt()) ? -1 : 1, E); 8175 } 8176 if (StopAtNull && !Char1.getInt()) 8177 return Success(0, E); 8178 assert(!(StopAtNull && !Char2.getInt())); 8179 if (!HandleLValueArrayAdjustment(Info, E, String1, CharTy, 1) || 8180 !HandleLValueArrayAdjustment(Info, E, String2, CharTy, 1)) 8181 return false; 8182 } 8183 // We hit the strncmp / memcmp limit. 8184 return Success(0, E); 8185 } 8186 8187 case Builtin::BI__atomic_always_lock_free: 8188 case Builtin::BI__atomic_is_lock_free: 8189 case Builtin::BI__c11_atomic_is_lock_free: { 8190 APSInt SizeVal; 8191 if (!EvaluateInteger(E->getArg(0), SizeVal, Info)) 8192 return false; 8193 8194 // For __atomic_is_lock_free(sizeof(_Atomic(T))), if the size is a power 8195 // of two less than the maximum inline atomic width, we know it is 8196 // lock-free. If the size isn't a power of two, or greater than the 8197 // maximum alignment where we promote atomics, we know it is not lock-free 8198 // (at least not in the sense of atomic_is_lock_free). Otherwise, 8199 // the answer can only be determined at runtime; for example, 16-byte 8200 // atomics have lock-free implementations on some, but not all, 8201 // x86-64 processors. 8202 8203 // Check power-of-two. 8204 CharUnits Size = CharUnits::fromQuantity(SizeVal.getZExtValue()); 8205 if (Size.isPowerOfTwo()) { 8206 // Check against inlining width. 8207 unsigned InlineWidthBits = 8208 Info.Ctx.getTargetInfo().getMaxAtomicInlineWidth(); 8209 if (Size <= Info.Ctx.toCharUnitsFromBits(InlineWidthBits)) { 8210 if (BuiltinOp == Builtin::BI__c11_atomic_is_lock_free || 8211 Size == CharUnits::One() || 8212 E->getArg(1)->isNullPointerConstant(Info.Ctx, 8213 Expr::NPC_NeverValueDependent)) 8214 // OK, we will inline appropriately-aligned operations of this size, 8215 // and _Atomic(T) is appropriately-aligned. 8216 return Success(1, E); 8217 8218 QualType PointeeType = E->getArg(1)->IgnoreImpCasts()->getType()-> 8219 castAs<PointerType>()->getPointeeType(); 8220 if (!PointeeType->isIncompleteType() && 8221 Info.Ctx.getTypeAlignInChars(PointeeType) >= Size) { 8222 // OK, we will inline operations on this object. 8223 return Success(1, E); 8224 } 8225 } 8226 } 8227 8228 return BuiltinOp == Builtin::BI__atomic_always_lock_free ? 8229 Success(0, E) : Error(E); 8230 } 8231 case Builtin::BIomp_is_initial_device: 8232 // We can decide statically which value the runtime would return if called. 8233 return Success(Info.getLangOpts().OpenMPIsDevice ? 0 : 1, E); 8234 case Builtin::BI__builtin_add_overflow: 8235 case Builtin::BI__builtin_sub_overflow: 8236 case Builtin::BI__builtin_mul_overflow: 8237 case Builtin::BI__builtin_sadd_overflow: 8238 case Builtin::BI__builtin_uadd_overflow: 8239 case Builtin::BI__builtin_uaddl_overflow: 8240 case Builtin::BI__builtin_uaddll_overflow: 8241 case Builtin::BI__builtin_usub_overflow: 8242 case Builtin::BI__builtin_usubl_overflow: 8243 case Builtin::BI__builtin_usubll_overflow: 8244 case Builtin::BI__builtin_umul_overflow: 8245 case Builtin::BI__builtin_umull_overflow: 8246 case Builtin::BI__builtin_umulll_overflow: 8247 case Builtin::BI__builtin_saddl_overflow: 8248 case Builtin::BI__builtin_saddll_overflow: 8249 case Builtin::BI__builtin_ssub_overflow: 8250 case Builtin::BI__builtin_ssubl_overflow: 8251 case Builtin::BI__builtin_ssubll_overflow: 8252 case Builtin::BI__builtin_smul_overflow: 8253 case Builtin::BI__builtin_smull_overflow: 8254 case Builtin::BI__builtin_smulll_overflow: { 8255 LValue ResultLValue; 8256 APSInt LHS, RHS; 8257 8258 QualType ResultType = E->getArg(2)->getType()->getPointeeType(); 8259 if (!EvaluateInteger(E->getArg(0), LHS, Info) || 8260 !EvaluateInteger(E->getArg(1), RHS, Info) || 8261 !EvaluatePointer(E->getArg(2), ResultLValue, Info)) 8262 return false; 8263 8264 APSInt Result; 8265 bool DidOverflow = false; 8266 8267 // If the types don't have to match, enlarge all 3 to the largest of them. 8268 if (BuiltinOp == Builtin::BI__builtin_add_overflow || 8269 BuiltinOp == Builtin::BI__builtin_sub_overflow || 8270 BuiltinOp == Builtin::BI__builtin_mul_overflow) { 8271 bool IsSigned = LHS.isSigned() || RHS.isSigned() || 8272 ResultType->isSignedIntegerOrEnumerationType(); 8273 bool AllSigned = LHS.isSigned() && RHS.isSigned() && 8274 ResultType->isSignedIntegerOrEnumerationType(); 8275 uint64_t LHSSize = LHS.getBitWidth(); 8276 uint64_t RHSSize = RHS.getBitWidth(); 8277 uint64_t ResultSize = Info.Ctx.getTypeSize(ResultType); 8278 uint64_t MaxBits = std::max(std::max(LHSSize, RHSSize), ResultSize); 8279 8280 // Add an additional bit if the signedness isn't uniformly agreed to. We 8281 // could do this ONLY if there is a signed and an unsigned that both have 8282 // MaxBits, but the code to check that is pretty nasty. The issue will be 8283 // caught in the shrink-to-result later anyway. 8284 if (IsSigned && !AllSigned) 8285 ++MaxBits; 8286 8287 LHS = APSInt(IsSigned ? LHS.sextOrSelf(MaxBits) : LHS.zextOrSelf(MaxBits), 8288 !IsSigned); 8289 RHS = APSInt(IsSigned ? RHS.sextOrSelf(MaxBits) : RHS.zextOrSelf(MaxBits), 8290 !IsSigned); 8291 Result = APSInt(MaxBits, !IsSigned); 8292 } 8293 8294 // Find largest int. 8295 switch (BuiltinOp) { 8296 default: 8297 llvm_unreachable("Invalid value for BuiltinOp"); 8298 case Builtin::BI__builtin_add_overflow: 8299 case Builtin::BI__builtin_sadd_overflow: 8300 case Builtin::BI__builtin_saddl_overflow: 8301 case Builtin::BI__builtin_saddll_overflow: 8302 case Builtin::BI__builtin_uadd_overflow: 8303 case Builtin::BI__builtin_uaddl_overflow: 8304 case Builtin::BI__builtin_uaddll_overflow: 8305 Result = LHS.isSigned() ? LHS.sadd_ov(RHS, DidOverflow) 8306 : LHS.uadd_ov(RHS, DidOverflow); 8307 break; 8308 case Builtin::BI__builtin_sub_overflow: 8309 case Builtin::BI__builtin_ssub_overflow: 8310 case Builtin::BI__builtin_ssubl_overflow: 8311 case Builtin::BI__builtin_ssubll_overflow: 8312 case Builtin::BI__builtin_usub_overflow: 8313 case Builtin::BI__builtin_usubl_overflow: 8314 case Builtin::BI__builtin_usubll_overflow: 8315 Result = LHS.isSigned() ? LHS.ssub_ov(RHS, DidOverflow) 8316 : LHS.usub_ov(RHS, DidOverflow); 8317 break; 8318 case Builtin::BI__builtin_mul_overflow: 8319 case Builtin::BI__builtin_smul_overflow: 8320 case Builtin::BI__builtin_smull_overflow: 8321 case Builtin::BI__builtin_smulll_overflow: 8322 case Builtin::BI__builtin_umul_overflow: 8323 case Builtin::BI__builtin_umull_overflow: 8324 case Builtin::BI__builtin_umulll_overflow: 8325 Result = LHS.isSigned() ? LHS.smul_ov(RHS, DidOverflow) 8326 : LHS.umul_ov(RHS, DidOverflow); 8327 break; 8328 } 8329 8330 // In the case where multiple sizes are allowed, truncate and see if 8331 // the values are the same. 8332 if (BuiltinOp == Builtin::BI__builtin_add_overflow || 8333 BuiltinOp == Builtin::BI__builtin_sub_overflow || 8334 BuiltinOp == Builtin::BI__builtin_mul_overflow) { 8335 // APSInt doesn't have a TruncOrSelf, so we use extOrTrunc instead, 8336 // since it will give us the behavior of a TruncOrSelf in the case where 8337 // its parameter <= its size. We previously set Result to be at least the 8338 // type-size of the result, so getTypeSize(ResultType) <= Result.BitWidth 8339 // will work exactly like TruncOrSelf. 8340 APSInt Temp = Result.extOrTrunc(Info.Ctx.getTypeSize(ResultType)); 8341 Temp.setIsSigned(ResultType->isSignedIntegerOrEnumerationType()); 8342 8343 if (!APSInt::isSameValue(Temp, Result)) 8344 DidOverflow = true; 8345 Result = Temp; 8346 } 8347 8348 APValue APV{Result}; 8349 handleAssignment(Info, E, ResultLValue, ResultType, APV); 8350 return Success(DidOverflow, E); 8351 } 8352 } 8353 } 8354 8355 static bool HasSameBase(const LValue &A, const LValue &B) { 8356 if (!A.getLValueBase()) 8357 return !B.getLValueBase(); 8358 if (!B.getLValueBase()) 8359 return false; 8360 8361 if (A.getLValueBase().getOpaqueValue() != 8362 B.getLValueBase().getOpaqueValue()) { 8363 const Decl *ADecl = GetLValueBaseDecl(A); 8364 if (!ADecl) 8365 return false; 8366 const Decl *BDecl = GetLValueBaseDecl(B); 8367 if (!BDecl || ADecl->getCanonicalDecl() != BDecl->getCanonicalDecl()) 8368 return false; 8369 } 8370 8371 return IsGlobalLValue(A.getLValueBase()) || 8372 (A.getLValueCallIndex() == B.getLValueCallIndex() && 8373 A.getLValueVersion() == B.getLValueVersion()); 8374 } 8375 8376 /// Determine whether this is a pointer past the end of the complete 8377 /// object referred to by the lvalue. 8378 static bool isOnePastTheEndOfCompleteObject(const ASTContext &Ctx, 8379 const LValue &LV) { 8380 // A null pointer can be viewed as being "past the end" but we don't 8381 // choose to look at it that way here. 8382 if (!LV.getLValueBase()) 8383 return false; 8384 8385 // If the designator is valid and refers to a subobject, we're not pointing 8386 // past the end. 8387 if (!LV.getLValueDesignator().Invalid && 8388 !LV.getLValueDesignator().isOnePastTheEnd()) 8389 return false; 8390 8391 // A pointer to an incomplete type might be past-the-end if the type's size is 8392 // zero. We cannot tell because the type is incomplete. 8393 QualType Ty = getType(LV.getLValueBase()); 8394 if (Ty->isIncompleteType()) 8395 return true; 8396 8397 // We're a past-the-end pointer if we point to the byte after the object, 8398 // no matter what our type or path is. 8399 auto Size = Ctx.getTypeSizeInChars(Ty); 8400 return LV.getLValueOffset() == Size; 8401 } 8402 8403 namespace { 8404 8405 /// Data recursive integer evaluator of certain binary operators. 8406 /// 8407 /// We use a data recursive algorithm for binary operators so that we are able 8408 /// to handle extreme cases of chained binary operators without causing stack 8409 /// overflow. 8410 class DataRecursiveIntBinOpEvaluator { 8411 struct EvalResult { 8412 APValue Val; 8413 bool Failed; 8414 8415 EvalResult() : Failed(false) { } 8416 8417 void swap(EvalResult &RHS) { 8418 Val.swap(RHS.Val); 8419 Failed = RHS.Failed; 8420 RHS.Failed = false; 8421 } 8422 }; 8423 8424 struct Job { 8425 const Expr *E; 8426 EvalResult LHSResult; // meaningful only for binary operator expression. 8427 enum { AnyExprKind, BinOpKind, BinOpVisitedLHSKind } Kind; 8428 8429 Job() = default; 8430 Job(Job &&) = default; 8431 8432 void startSpeculativeEval(EvalInfo &Info) { 8433 SpecEvalRAII = SpeculativeEvaluationRAII(Info); 8434 } 8435 8436 private: 8437 SpeculativeEvaluationRAII SpecEvalRAII; 8438 }; 8439 8440 SmallVector<Job, 16> Queue; 8441 8442 IntExprEvaluator &IntEval; 8443 EvalInfo &Info; 8444 APValue &FinalResult; 8445 8446 public: 8447 DataRecursiveIntBinOpEvaluator(IntExprEvaluator &IntEval, APValue &Result) 8448 : IntEval(IntEval), Info(IntEval.getEvalInfo()), FinalResult(Result) { } 8449 8450 /// True if \param E is a binary operator that we are going to handle 8451 /// data recursively. 8452 /// We handle binary operators that are comma, logical, or that have operands 8453 /// with integral or enumeration type. 8454 static bool shouldEnqueue(const BinaryOperator *E) { 8455 return E->getOpcode() == BO_Comma || E->isLogicalOp() || 8456 (E->isRValue() && E->getType()->isIntegralOrEnumerationType() && 8457 E->getLHS()->getType()->isIntegralOrEnumerationType() && 8458 E->getRHS()->getType()->isIntegralOrEnumerationType()); 8459 } 8460 8461 bool Traverse(const BinaryOperator *E) { 8462 enqueue(E); 8463 EvalResult PrevResult; 8464 while (!Queue.empty()) 8465 process(PrevResult); 8466 8467 if (PrevResult.Failed) return false; 8468 8469 FinalResult.swap(PrevResult.Val); 8470 return true; 8471 } 8472 8473 private: 8474 bool Success(uint64_t Value, const Expr *E, APValue &Result) { 8475 return IntEval.Success(Value, E, Result); 8476 } 8477 bool Success(const APSInt &Value, const Expr *E, APValue &Result) { 8478 return IntEval.Success(Value, E, Result); 8479 } 8480 bool Error(const Expr *E) { 8481 return IntEval.Error(E); 8482 } 8483 bool Error(const Expr *E, diag::kind D) { 8484 return IntEval.Error(E, D); 8485 } 8486 8487 OptionalDiagnostic CCEDiag(const Expr *E, diag::kind D) { 8488 return Info.CCEDiag(E, D); 8489 } 8490 8491 // Returns true if visiting the RHS is necessary, false otherwise. 8492 bool VisitBinOpLHSOnly(EvalResult &LHSResult, const BinaryOperator *E, 8493 bool &SuppressRHSDiags); 8494 8495 bool VisitBinOp(const EvalResult &LHSResult, const EvalResult &RHSResult, 8496 const BinaryOperator *E, APValue &Result); 8497 8498 void EvaluateExpr(const Expr *E, EvalResult &Result) { 8499 Result.Failed = !Evaluate(Result.Val, Info, E); 8500 if (Result.Failed) 8501 Result.Val = APValue(); 8502 } 8503 8504 void process(EvalResult &Result); 8505 8506 void enqueue(const Expr *E) { 8507 E = E->IgnoreParens(); 8508 Queue.resize(Queue.size()+1); 8509 Queue.back().E = E; 8510 Queue.back().Kind = Job::AnyExprKind; 8511 } 8512 }; 8513 8514 } 8515 8516 bool DataRecursiveIntBinOpEvaluator:: 8517 VisitBinOpLHSOnly(EvalResult &LHSResult, const BinaryOperator *E, 8518 bool &SuppressRHSDiags) { 8519 if (E->getOpcode() == BO_Comma) { 8520 // Ignore LHS but note if we could not evaluate it. 8521 if (LHSResult.Failed) 8522 return Info.noteSideEffect(); 8523 return true; 8524 } 8525 8526 if (E->isLogicalOp()) { 8527 bool LHSAsBool; 8528 if (!LHSResult.Failed && HandleConversionToBool(LHSResult.Val, LHSAsBool)) { 8529 // We were able to evaluate the LHS, see if we can get away with not 8530 // evaluating the RHS: 0 && X -> 0, 1 || X -> 1 8531 if (LHSAsBool == (E->getOpcode() == BO_LOr)) { 8532 Success(LHSAsBool, E, LHSResult.Val); 8533 return false; // Ignore RHS 8534 } 8535 } else { 8536 LHSResult.Failed = true; 8537 8538 // Since we weren't able to evaluate the left hand side, it 8539 // might have had side effects. 8540 if (!Info.noteSideEffect()) 8541 return false; 8542 8543 // We can't evaluate the LHS; however, sometimes the result 8544 // is determined by the RHS: X && 0 -> 0, X || 1 -> 1. 8545 // Don't ignore RHS and suppress diagnostics from this arm. 8546 SuppressRHSDiags = true; 8547 } 8548 8549 return true; 8550 } 8551 8552 assert(E->getLHS()->getType()->isIntegralOrEnumerationType() && 8553 E->getRHS()->getType()->isIntegralOrEnumerationType()); 8554 8555 if (LHSResult.Failed && !Info.noteFailure()) 8556 return false; // Ignore RHS; 8557 8558 return true; 8559 } 8560 8561 static void addOrSubLValueAsInteger(APValue &LVal, const APSInt &Index, 8562 bool IsSub) { 8563 // Compute the new offset in the appropriate width, wrapping at 64 bits. 8564 // FIXME: When compiling for a 32-bit target, we should use 32-bit 8565 // offsets. 8566 assert(!LVal.hasLValuePath() && "have designator for integer lvalue"); 8567 CharUnits &Offset = LVal.getLValueOffset(); 8568 uint64_t Offset64 = Offset.getQuantity(); 8569 uint64_t Index64 = Index.extOrTrunc(64).getZExtValue(); 8570 Offset = CharUnits::fromQuantity(IsSub ? Offset64 - Index64 8571 : Offset64 + Index64); 8572 } 8573 8574 bool DataRecursiveIntBinOpEvaluator:: 8575 VisitBinOp(const EvalResult &LHSResult, const EvalResult &RHSResult, 8576 const BinaryOperator *E, APValue &Result) { 8577 if (E->getOpcode() == BO_Comma) { 8578 if (RHSResult.Failed) 8579 return false; 8580 Result = RHSResult.Val; 8581 return true; 8582 } 8583 8584 if (E->isLogicalOp()) { 8585 bool lhsResult, rhsResult; 8586 bool LHSIsOK = HandleConversionToBool(LHSResult.Val, lhsResult); 8587 bool RHSIsOK = HandleConversionToBool(RHSResult.Val, rhsResult); 8588 8589 if (LHSIsOK) { 8590 if (RHSIsOK) { 8591 if (E->getOpcode() == BO_LOr) 8592 return Success(lhsResult || rhsResult, E, Result); 8593 else 8594 return Success(lhsResult && rhsResult, E, Result); 8595 } 8596 } else { 8597 if (RHSIsOK) { 8598 // We can't evaluate the LHS; however, sometimes the result 8599 // is determined by the RHS: X && 0 -> 0, X || 1 -> 1. 8600 if (rhsResult == (E->getOpcode() == BO_LOr)) 8601 return Success(rhsResult, E, Result); 8602 } 8603 } 8604 8605 return false; 8606 } 8607 8608 assert(E->getLHS()->getType()->isIntegralOrEnumerationType() && 8609 E->getRHS()->getType()->isIntegralOrEnumerationType()); 8610 8611 if (LHSResult.Failed || RHSResult.Failed) 8612 return false; 8613 8614 const APValue &LHSVal = LHSResult.Val; 8615 const APValue &RHSVal = RHSResult.Val; 8616 8617 // Handle cases like (unsigned long)&a + 4. 8618 if (E->isAdditiveOp() && LHSVal.isLValue() && RHSVal.isInt()) { 8619 Result = LHSVal; 8620 addOrSubLValueAsInteger(Result, RHSVal.getInt(), E->getOpcode() == BO_Sub); 8621 return true; 8622 } 8623 8624 // Handle cases like 4 + (unsigned long)&a 8625 if (E->getOpcode() == BO_Add && 8626 RHSVal.isLValue() && LHSVal.isInt()) { 8627 Result = RHSVal; 8628 addOrSubLValueAsInteger(Result, LHSVal.getInt(), /*IsSub*/false); 8629 return true; 8630 } 8631 8632 if (E->getOpcode() == BO_Sub && LHSVal.isLValue() && RHSVal.isLValue()) { 8633 // Handle (intptr_t)&&A - (intptr_t)&&B. 8634 if (!LHSVal.getLValueOffset().isZero() || 8635 !RHSVal.getLValueOffset().isZero()) 8636 return false; 8637 const Expr *LHSExpr = LHSVal.getLValueBase().dyn_cast<const Expr*>(); 8638 const Expr *RHSExpr = RHSVal.getLValueBase().dyn_cast<const Expr*>(); 8639 if (!LHSExpr || !RHSExpr) 8640 return false; 8641 const AddrLabelExpr *LHSAddrExpr = dyn_cast<AddrLabelExpr>(LHSExpr); 8642 const AddrLabelExpr *RHSAddrExpr = dyn_cast<AddrLabelExpr>(RHSExpr); 8643 if (!LHSAddrExpr || !RHSAddrExpr) 8644 return false; 8645 // Make sure both labels come from the same function. 8646 if (LHSAddrExpr->getLabel()->getDeclContext() != 8647 RHSAddrExpr->getLabel()->getDeclContext()) 8648 return false; 8649 Result = APValue(LHSAddrExpr, RHSAddrExpr); 8650 return true; 8651 } 8652 8653 // All the remaining cases expect both operands to be an integer 8654 if (!LHSVal.isInt() || !RHSVal.isInt()) 8655 return Error(E); 8656 8657 // Set up the width and signedness manually, in case it can't be deduced 8658 // from the operation we're performing. 8659 // FIXME: Don't do this in the cases where we can deduce it. 8660 APSInt Value(Info.Ctx.getIntWidth(E->getType()), 8661 E->getType()->isUnsignedIntegerOrEnumerationType()); 8662 if (!handleIntIntBinOp(Info, E, LHSVal.getInt(), E->getOpcode(), 8663 RHSVal.getInt(), Value)) 8664 return false; 8665 return Success(Value, E, Result); 8666 } 8667 8668 void DataRecursiveIntBinOpEvaluator::process(EvalResult &Result) { 8669 Job &job = Queue.back(); 8670 8671 switch (job.Kind) { 8672 case Job::AnyExprKind: { 8673 if (const BinaryOperator *Bop = dyn_cast<BinaryOperator>(job.E)) { 8674 if (shouldEnqueue(Bop)) { 8675 job.Kind = Job::BinOpKind; 8676 enqueue(Bop->getLHS()); 8677 return; 8678 } 8679 } 8680 8681 EvaluateExpr(job.E, Result); 8682 Queue.pop_back(); 8683 return; 8684 } 8685 8686 case Job::BinOpKind: { 8687 const BinaryOperator *Bop = cast<BinaryOperator>(job.E); 8688 bool SuppressRHSDiags = false; 8689 if (!VisitBinOpLHSOnly(Result, Bop, SuppressRHSDiags)) { 8690 Queue.pop_back(); 8691 return; 8692 } 8693 if (SuppressRHSDiags) 8694 job.startSpeculativeEval(Info); 8695 job.LHSResult.swap(Result); 8696 job.Kind = Job::BinOpVisitedLHSKind; 8697 enqueue(Bop->getRHS()); 8698 return; 8699 } 8700 8701 case Job::BinOpVisitedLHSKind: { 8702 const BinaryOperator *Bop = cast<BinaryOperator>(job.E); 8703 EvalResult RHS; 8704 RHS.swap(Result); 8705 Result.Failed = !VisitBinOp(job.LHSResult, RHS, Bop, Result.Val); 8706 Queue.pop_back(); 8707 return; 8708 } 8709 } 8710 8711 llvm_unreachable("Invalid Job::Kind!"); 8712 } 8713 8714 namespace { 8715 /// Used when we determine that we should fail, but can keep evaluating prior to 8716 /// noting that we had a failure. 8717 class DelayedNoteFailureRAII { 8718 EvalInfo &Info; 8719 bool NoteFailure; 8720 8721 public: 8722 DelayedNoteFailureRAII(EvalInfo &Info, bool NoteFailure = true) 8723 : Info(Info), NoteFailure(NoteFailure) {} 8724 ~DelayedNoteFailureRAII() { 8725 if (NoteFailure) { 8726 bool ContinueAfterFailure = Info.noteFailure(); 8727 (void)ContinueAfterFailure; 8728 assert(ContinueAfterFailure && 8729 "Shouldn't have kept evaluating on failure."); 8730 } 8731 } 8732 }; 8733 } 8734 8735 template <class SuccessCB, class AfterCB> 8736 static bool 8737 EvaluateComparisonBinaryOperator(EvalInfo &Info, const BinaryOperator *E, 8738 SuccessCB &&Success, AfterCB &&DoAfter) { 8739 assert(E->isComparisonOp() && "expected comparison operator"); 8740 assert((E->getOpcode() == BO_Cmp || 8741 E->getType()->isIntegralOrEnumerationType()) && 8742 "unsupported binary expression evaluation"); 8743 auto Error = [&](const Expr *E) { 8744 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 8745 return false; 8746 }; 8747 8748 using CCR = ComparisonCategoryResult; 8749 bool IsRelational = E->isRelationalOp(); 8750 bool IsEquality = E->isEqualityOp(); 8751 if (E->getOpcode() == BO_Cmp) { 8752 const ComparisonCategoryInfo &CmpInfo = 8753 Info.Ctx.CompCategories.getInfoForType(E->getType()); 8754 IsRelational = CmpInfo.isOrdered(); 8755 IsEquality = CmpInfo.isEquality(); 8756 } 8757 8758 QualType LHSTy = E->getLHS()->getType(); 8759 QualType RHSTy = E->getRHS()->getType(); 8760 8761 if (LHSTy->isIntegralOrEnumerationType() && 8762 RHSTy->isIntegralOrEnumerationType()) { 8763 APSInt LHS, RHS; 8764 bool LHSOK = EvaluateInteger(E->getLHS(), LHS, Info); 8765 if (!LHSOK && !Info.noteFailure()) 8766 return false; 8767 if (!EvaluateInteger(E->getRHS(), RHS, Info) || !LHSOK) 8768 return false; 8769 if (LHS < RHS) 8770 return Success(CCR::Less, E); 8771 if (LHS > RHS) 8772 return Success(CCR::Greater, E); 8773 return Success(CCR::Equal, E); 8774 } 8775 8776 if (LHSTy->isAnyComplexType() || RHSTy->isAnyComplexType()) { 8777 ComplexValue LHS, RHS; 8778 bool LHSOK; 8779 if (E->isAssignmentOp()) { 8780 LValue LV; 8781 EvaluateLValue(E->getLHS(), LV, Info); 8782 LHSOK = false; 8783 } else if (LHSTy->isRealFloatingType()) { 8784 LHSOK = EvaluateFloat(E->getLHS(), LHS.FloatReal, Info); 8785 if (LHSOK) { 8786 LHS.makeComplexFloat(); 8787 LHS.FloatImag = APFloat(LHS.FloatReal.getSemantics()); 8788 } 8789 } else { 8790 LHSOK = EvaluateComplex(E->getLHS(), LHS, Info); 8791 } 8792 if (!LHSOK && !Info.noteFailure()) 8793 return false; 8794 8795 if (E->getRHS()->getType()->isRealFloatingType()) { 8796 if (!EvaluateFloat(E->getRHS(), RHS.FloatReal, Info) || !LHSOK) 8797 return false; 8798 RHS.makeComplexFloat(); 8799 RHS.FloatImag = APFloat(RHS.FloatReal.getSemantics()); 8800 } else if (!EvaluateComplex(E->getRHS(), RHS, Info) || !LHSOK) 8801 return false; 8802 8803 if (LHS.isComplexFloat()) { 8804 APFloat::cmpResult CR_r = 8805 LHS.getComplexFloatReal().compare(RHS.getComplexFloatReal()); 8806 APFloat::cmpResult CR_i = 8807 LHS.getComplexFloatImag().compare(RHS.getComplexFloatImag()); 8808 bool IsEqual = CR_r == APFloat::cmpEqual && CR_i == APFloat::cmpEqual; 8809 return Success(IsEqual ? CCR::Equal : CCR::Nonequal, E); 8810 } else { 8811 assert(IsEquality && "invalid complex comparison"); 8812 bool IsEqual = LHS.getComplexIntReal() == RHS.getComplexIntReal() && 8813 LHS.getComplexIntImag() == RHS.getComplexIntImag(); 8814 return Success(IsEqual ? CCR::Equal : CCR::Nonequal, E); 8815 } 8816 } 8817 8818 if (LHSTy->isRealFloatingType() && 8819 RHSTy->isRealFloatingType()) { 8820 APFloat RHS(0.0), LHS(0.0); 8821 8822 bool LHSOK = EvaluateFloat(E->getRHS(), RHS, Info); 8823 if (!LHSOK && !Info.noteFailure()) 8824 return false; 8825 8826 if (!EvaluateFloat(E->getLHS(), LHS, Info) || !LHSOK) 8827 return false; 8828 8829 assert(E->isComparisonOp() && "Invalid binary operator!"); 8830 auto GetCmpRes = [&]() { 8831 switch (LHS.compare(RHS)) { 8832 case APFloat::cmpEqual: 8833 return CCR::Equal; 8834 case APFloat::cmpLessThan: 8835 return CCR::Less; 8836 case APFloat::cmpGreaterThan: 8837 return CCR::Greater; 8838 case APFloat::cmpUnordered: 8839 return CCR::Unordered; 8840 } 8841 llvm_unreachable("Unrecognised APFloat::cmpResult enum"); 8842 }; 8843 return Success(GetCmpRes(), E); 8844 } 8845 8846 if (LHSTy->isPointerType() && RHSTy->isPointerType()) { 8847 LValue LHSValue, RHSValue; 8848 8849 bool LHSOK = EvaluatePointer(E->getLHS(), LHSValue, Info); 8850 if (!LHSOK && !Info.noteFailure()) 8851 return false; 8852 8853 if (!EvaluatePointer(E->getRHS(), RHSValue, Info) || !LHSOK) 8854 return false; 8855 8856 // Reject differing bases from the normal codepath; we special-case 8857 // comparisons to null. 8858 if (!HasSameBase(LHSValue, RHSValue)) { 8859 // Inequalities and subtractions between unrelated pointers have 8860 // unspecified or undefined behavior. 8861 if (!IsEquality) 8862 return Error(E); 8863 // A constant address may compare equal to the address of a symbol. 8864 // The one exception is that address of an object cannot compare equal 8865 // to a null pointer constant. 8866 if ((!LHSValue.Base && !LHSValue.Offset.isZero()) || 8867 (!RHSValue.Base && !RHSValue.Offset.isZero())) 8868 return Error(E); 8869 // It's implementation-defined whether distinct literals will have 8870 // distinct addresses. In clang, the result of such a comparison is 8871 // unspecified, so it is not a constant expression. However, we do know 8872 // that the address of a literal will be non-null. 8873 if ((IsLiteralLValue(LHSValue) || IsLiteralLValue(RHSValue)) && 8874 LHSValue.Base && RHSValue.Base) 8875 return Error(E); 8876 // We can't tell whether weak symbols will end up pointing to the same 8877 // object. 8878 if (IsWeakLValue(LHSValue) || IsWeakLValue(RHSValue)) 8879 return Error(E); 8880 // We can't compare the address of the start of one object with the 8881 // past-the-end address of another object, per C++ DR1652. 8882 if ((LHSValue.Base && LHSValue.Offset.isZero() && 8883 isOnePastTheEndOfCompleteObject(Info.Ctx, RHSValue)) || 8884 (RHSValue.Base && RHSValue.Offset.isZero() && 8885 isOnePastTheEndOfCompleteObject(Info.Ctx, LHSValue))) 8886 return Error(E); 8887 // We can't tell whether an object is at the same address as another 8888 // zero sized object. 8889 if ((RHSValue.Base && isZeroSized(LHSValue)) || 8890 (LHSValue.Base && isZeroSized(RHSValue))) 8891 return Error(E); 8892 return Success(CCR::Nonequal, E); 8893 } 8894 8895 const CharUnits &LHSOffset = LHSValue.getLValueOffset(); 8896 const CharUnits &RHSOffset = RHSValue.getLValueOffset(); 8897 8898 SubobjectDesignator &LHSDesignator = LHSValue.getLValueDesignator(); 8899 SubobjectDesignator &RHSDesignator = RHSValue.getLValueDesignator(); 8900 8901 // C++11 [expr.rel]p3: 8902 // Pointers to void (after pointer conversions) can be compared, with a 8903 // result defined as follows: If both pointers represent the same 8904 // address or are both the null pointer value, the result is true if the 8905 // operator is <= or >= and false otherwise; otherwise the result is 8906 // unspecified. 8907 // We interpret this as applying to pointers to *cv* void. 8908 if (LHSTy->isVoidPointerType() && LHSOffset != RHSOffset && IsRelational) 8909 Info.CCEDiag(E, diag::note_constexpr_void_comparison); 8910 8911 // C++11 [expr.rel]p2: 8912 // - If two pointers point to non-static data members of the same object, 8913 // or to subobjects or array elements fo such members, recursively, the 8914 // pointer to the later declared member compares greater provided the 8915 // two members have the same access control and provided their class is 8916 // not a union. 8917 // [...] 8918 // - Otherwise pointer comparisons are unspecified. 8919 if (!LHSDesignator.Invalid && !RHSDesignator.Invalid && IsRelational) { 8920 bool WasArrayIndex; 8921 unsigned Mismatch = FindDesignatorMismatch( 8922 getType(LHSValue.Base), LHSDesignator, RHSDesignator, WasArrayIndex); 8923 // At the point where the designators diverge, the comparison has a 8924 // specified value if: 8925 // - we are comparing array indices 8926 // - we are comparing fields of a union, or fields with the same access 8927 // Otherwise, the result is unspecified and thus the comparison is not a 8928 // constant expression. 8929 if (!WasArrayIndex && Mismatch < LHSDesignator.Entries.size() && 8930 Mismatch < RHSDesignator.Entries.size()) { 8931 const FieldDecl *LF = getAsField(LHSDesignator.Entries[Mismatch]); 8932 const FieldDecl *RF = getAsField(RHSDesignator.Entries[Mismatch]); 8933 if (!LF && !RF) 8934 Info.CCEDiag(E, diag::note_constexpr_pointer_comparison_base_classes); 8935 else if (!LF) 8936 Info.CCEDiag(E, diag::note_constexpr_pointer_comparison_base_field) 8937 << getAsBaseClass(LHSDesignator.Entries[Mismatch]) 8938 << RF->getParent() << RF; 8939 else if (!RF) 8940 Info.CCEDiag(E, diag::note_constexpr_pointer_comparison_base_field) 8941 << getAsBaseClass(RHSDesignator.Entries[Mismatch]) 8942 << LF->getParent() << LF; 8943 else if (!LF->getParent()->isUnion() && 8944 LF->getAccess() != RF->getAccess()) 8945 Info.CCEDiag(E, 8946 diag::note_constexpr_pointer_comparison_differing_access) 8947 << LF << LF->getAccess() << RF << RF->getAccess() 8948 << LF->getParent(); 8949 } 8950 } 8951 8952 // The comparison here must be unsigned, and performed with the same 8953 // width as the pointer. 8954 unsigned PtrSize = Info.Ctx.getTypeSize(LHSTy); 8955 uint64_t CompareLHS = LHSOffset.getQuantity(); 8956 uint64_t CompareRHS = RHSOffset.getQuantity(); 8957 assert(PtrSize <= 64 && "Unexpected pointer width"); 8958 uint64_t Mask = ~0ULL >> (64 - PtrSize); 8959 CompareLHS &= Mask; 8960 CompareRHS &= Mask; 8961 8962 // If there is a base and this is a relational operator, we can only 8963 // compare pointers within the object in question; otherwise, the result 8964 // depends on where the object is located in memory. 8965 if (!LHSValue.Base.isNull() && IsRelational) { 8966 QualType BaseTy = getType(LHSValue.Base); 8967 if (BaseTy->isIncompleteType()) 8968 return Error(E); 8969 CharUnits Size = Info.Ctx.getTypeSizeInChars(BaseTy); 8970 uint64_t OffsetLimit = Size.getQuantity(); 8971 if (CompareLHS > OffsetLimit || CompareRHS > OffsetLimit) 8972 return Error(E); 8973 } 8974 8975 if (CompareLHS < CompareRHS) 8976 return Success(CCR::Less, E); 8977 if (CompareLHS > CompareRHS) 8978 return Success(CCR::Greater, E); 8979 return Success(CCR::Equal, E); 8980 } 8981 8982 if (LHSTy->isMemberPointerType()) { 8983 assert(IsEquality && "unexpected member pointer operation"); 8984 assert(RHSTy->isMemberPointerType() && "invalid comparison"); 8985 8986 MemberPtr LHSValue, RHSValue; 8987 8988 bool LHSOK = EvaluateMemberPointer(E->getLHS(), LHSValue, Info); 8989 if (!LHSOK && !Info.noteFailure()) 8990 return false; 8991 8992 if (!EvaluateMemberPointer(E->getRHS(), RHSValue, Info) || !LHSOK) 8993 return false; 8994 8995 // C++11 [expr.eq]p2: 8996 // If both operands are null, they compare equal. Otherwise if only one is 8997 // null, they compare unequal. 8998 if (!LHSValue.getDecl() || !RHSValue.getDecl()) { 8999 bool Equal = !LHSValue.getDecl() && !RHSValue.getDecl(); 9000 return Success(Equal ? CCR::Equal : CCR::Nonequal, E); 9001 } 9002 9003 // Otherwise if either is a pointer to a virtual member function, the 9004 // result is unspecified. 9005 if (const CXXMethodDecl *MD = dyn_cast<CXXMethodDecl>(LHSValue.getDecl())) 9006 if (MD->isVirtual()) 9007 Info.CCEDiag(E, diag::note_constexpr_compare_virtual_mem_ptr) << MD; 9008 if (const CXXMethodDecl *MD = dyn_cast<CXXMethodDecl>(RHSValue.getDecl())) 9009 if (MD->isVirtual()) 9010 Info.CCEDiag(E, diag::note_constexpr_compare_virtual_mem_ptr) << MD; 9011 9012 // Otherwise they compare equal if and only if they would refer to the 9013 // same member of the same most derived object or the same subobject if 9014 // they were dereferenced with a hypothetical object of the associated 9015 // class type. 9016 bool Equal = LHSValue == RHSValue; 9017 return Success(Equal ? CCR::Equal : CCR::Nonequal, E); 9018 } 9019 9020 if (LHSTy->isNullPtrType()) { 9021 assert(E->isComparisonOp() && "unexpected nullptr operation"); 9022 assert(RHSTy->isNullPtrType() && "missing pointer conversion"); 9023 // C++11 [expr.rel]p4, [expr.eq]p3: If two operands of type std::nullptr_t 9024 // are compared, the result is true of the operator is <=, >= or ==, and 9025 // false otherwise. 9026 return Success(CCR::Equal, E); 9027 } 9028 9029 return DoAfter(); 9030 } 9031 9032 bool RecordExprEvaluator::VisitBinCmp(const BinaryOperator *E) { 9033 if (!CheckLiteralType(Info, E)) 9034 return false; 9035 9036 auto OnSuccess = [&](ComparisonCategoryResult ResKind, 9037 const BinaryOperator *E) { 9038 // Evaluation succeeded. Lookup the information for the comparison category 9039 // type and fetch the VarDecl for the result. 9040 const ComparisonCategoryInfo &CmpInfo = 9041 Info.Ctx.CompCategories.getInfoForType(E->getType()); 9042 const VarDecl *VD = 9043 CmpInfo.getValueInfo(CmpInfo.makeWeakResult(ResKind))->VD; 9044 // Check and evaluate the result as a constant expression. 9045 LValue LV; 9046 LV.set(VD); 9047 if (!handleLValueToRValueConversion(Info, E, E->getType(), LV, Result)) 9048 return false; 9049 return CheckConstantExpression(Info, E->getExprLoc(), E->getType(), Result); 9050 }; 9051 return EvaluateComparisonBinaryOperator(Info, E, OnSuccess, [&]() { 9052 return ExprEvaluatorBaseTy::VisitBinCmp(E); 9053 }); 9054 } 9055 9056 bool IntExprEvaluator::VisitBinaryOperator(const BinaryOperator *E) { 9057 // We don't call noteFailure immediately because the assignment happens after 9058 // we evaluate LHS and RHS. 9059 if (!Info.keepEvaluatingAfterFailure() && E->isAssignmentOp()) 9060 return Error(E); 9061 9062 DelayedNoteFailureRAII MaybeNoteFailureLater(Info, E->isAssignmentOp()); 9063 if (DataRecursiveIntBinOpEvaluator::shouldEnqueue(E)) 9064 return DataRecursiveIntBinOpEvaluator(*this, Result).Traverse(E); 9065 9066 assert((!E->getLHS()->getType()->isIntegralOrEnumerationType() || 9067 !E->getRHS()->getType()->isIntegralOrEnumerationType()) && 9068 "DataRecursiveIntBinOpEvaluator should have handled integral types"); 9069 9070 if (E->isComparisonOp()) { 9071 // Evaluate builtin binary comparisons by evaluating them as C++2a three-way 9072 // comparisons and then translating the result. 9073 auto OnSuccess = [&](ComparisonCategoryResult ResKind, 9074 const BinaryOperator *E) { 9075 using CCR = ComparisonCategoryResult; 9076 bool IsEqual = ResKind == CCR::Equal, 9077 IsLess = ResKind == CCR::Less, 9078 IsGreater = ResKind == CCR::Greater; 9079 auto Op = E->getOpcode(); 9080 switch (Op) { 9081 default: 9082 llvm_unreachable("unsupported binary operator"); 9083 case BO_EQ: 9084 case BO_NE: 9085 return Success(IsEqual == (Op == BO_EQ), E); 9086 case BO_LT: return Success(IsLess, E); 9087 case BO_GT: return Success(IsGreater, E); 9088 case BO_LE: return Success(IsEqual || IsLess, E); 9089 case BO_GE: return Success(IsEqual || IsGreater, E); 9090 } 9091 }; 9092 return EvaluateComparisonBinaryOperator(Info, E, OnSuccess, [&]() { 9093 return ExprEvaluatorBaseTy::VisitBinaryOperator(E); 9094 }); 9095 } 9096 9097 QualType LHSTy = E->getLHS()->getType(); 9098 QualType RHSTy = E->getRHS()->getType(); 9099 9100 if (LHSTy->isPointerType() && RHSTy->isPointerType() && 9101 E->getOpcode() == BO_Sub) { 9102 LValue LHSValue, RHSValue; 9103 9104 bool LHSOK = EvaluatePointer(E->getLHS(), LHSValue, Info); 9105 if (!LHSOK && !Info.noteFailure()) 9106 return false; 9107 9108 if (!EvaluatePointer(E->getRHS(), RHSValue, Info) || !LHSOK) 9109 return false; 9110 9111 // Reject differing bases from the normal codepath; we special-case 9112 // comparisons to null. 9113 if (!HasSameBase(LHSValue, RHSValue)) { 9114 // Handle &&A - &&B. 9115 if (!LHSValue.Offset.isZero() || !RHSValue.Offset.isZero()) 9116 return Error(E); 9117 const Expr *LHSExpr = LHSValue.Base.dyn_cast<const Expr *>(); 9118 const Expr *RHSExpr = RHSValue.Base.dyn_cast<const Expr *>(); 9119 if (!LHSExpr || !RHSExpr) 9120 return Error(E); 9121 const AddrLabelExpr *LHSAddrExpr = dyn_cast<AddrLabelExpr>(LHSExpr); 9122 const AddrLabelExpr *RHSAddrExpr = dyn_cast<AddrLabelExpr>(RHSExpr); 9123 if (!LHSAddrExpr || !RHSAddrExpr) 9124 return Error(E); 9125 // Make sure both labels come from the same function. 9126 if (LHSAddrExpr->getLabel()->getDeclContext() != 9127 RHSAddrExpr->getLabel()->getDeclContext()) 9128 return Error(E); 9129 return Success(APValue(LHSAddrExpr, RHSAddrExpr), E); 9130 } 9131 const CharUnits &LHSOffset = LHSValue.getLValueOffset(); 9132 const CharUnits &RHSOffset = RHSValue.getLValueOffset(); 9133 9134 SubobjectDesignator &LHSDesignator = LHSValue.getLValueDesignator(); 9135 SubobjectDesignator &RHSDesignator = RHSValue.getLValueDesignator(); 9136 9137 // C++11 [expr.add]p6: 9138 // Unless both pointers point to elements of the same array object, or 9139 // one past the last element of the array object, the behavior is 9140 // undefined. 9141 if (!LHSDesignator.Invalid && !RHSDesignator.Invalid && 9142 !AreElementsOfSameArray(getType(LHSValue.Base), LHSDesignator, 9143 RHSDesignator)) 9144 Info.CCEDiag(E, diag::note_constexpr_pointer_subtraction_not_same_array); 9145 9146 QualType Type = E->getLHS()->getType(); 9147 QualType ElementType = Type->getAs<PointerType>()->getPointeeType(); 9148 9149 CharUnits ElementSize; 9150 if (!HandleSizeof(Info, E->getExprLoc(), ElementType, ElementSize)) 9151 return false; 9152 9153 // As an extension, a type may have zero size (empty struct or union in 9154 // C, array of zero length). Pointer subtraction in such cases has 9155 // undefined behavior, so is not constant. 9156 if (ElementSize.isZero()) { 9157 Info.FFDiag(E, diag::note_constexpr_pointer_subtraction_zero_size) 9158 << ElementType; 9159 return false; 9160 } 9161 9162 // FIXME: LLVM and GCC both compute LHSOffset - RHSOffset at runtime, 9163 // and produce incorrect results when it overflows. Such behavior 9164 // appears to be non-conforming, but is common, so perhaps we should 9165 // assume the standard intended for such cases to be undefined behavior 9166 // and check for them. 9167 9168 // Compute (LHSOffset - RHSOffset) / Size carefully, checking for 9169 // overflow in the final conversion to ptrdiff_t. 9170 APSInt LHS(llvm::APInt(65, (int64_t)LHSOffset.getQuantity(), true), false); 9171 APSInt RHS(llvm::APInt(65, (int64_t)RHSOffset.getQuantity(), true), false); 9172 APSInt ElemSize(llvm::APInt(65, (int64_t)ElementSize.getQuantity(), true), 9173 false); 9174 APSInt TrueResult = (LHS - RHS) / ElemSize; 9175 APSInt Result = TrueResult.trunc(Info.Ctx.getIntWidth(E->getType())); 9176 9177 if (Result.extend(65) != TrueResult && 9178 !HandleOverflow(Info, E, TrueResult, E->getType())) 9179 return false; 9180 return Success(Result, E); 9181 } 9182 9183 return ExprEvaluatorBaseTy::VisitBinaryOperator(E); 9184 } 9185 9186 /// VisitUnaryExprOrTypeTraitExpr - Evaluate a sizeof, alignof or vec_step with 9187 /// a result as the expression's type. 9188 bool IntExprEvaluator::VisitUnaryExprOrTypeTraitExpr( 9189 const UnaryExprOrTypeTraitExpr *E) { 9190 switch(E->getKind()) { 9191 case UETT_AlignOf: { 9192 if (E->isArgumentType()) 9193 return Success(GetAlignOfType(Info, E->getArgumentType()), E); 9194 else 9195 return Success(GetAlignOfExpr(Info, E->getArgumentExpr()), E); 9196 } 9197 9198 case UETT_VecStep: { 9199 QualType Ty = E->getTypeOfArgument(); 9200 9201 if (Ty->isVectorType()) { 9202 unsigned n = Ty->castAs<VectorType>()->getNumElements(); 9203 9204 // The vec_step built-in functions that take a 3-component 9205 // vector return 4. (OpenCL 1.1 spec 6.11.12) 9206 if (n == 3) 9207 n = 4; 9208 9209 return Success(n, E); 9210 } else 9211 return Success(1, E); 9212 } 9213 9214 case UETT_SizeOf: { 9215 QualType SrcTy = E->getTypeOfArgument(); 9216 // C++ [expr.sizeof]p2: "When applied to a reference or a reference type, 9217 // the result is the size of the referenced type." 9218 if (const ReferenceType *Ref = SrcTy->getAs<ReferenceType>()) 9219 SrcTy = Ref->getPointeeType(); 9220 9221 CharUnits Sizeof; 9222 if (!HandleSizeof(Info, E->getExprLoc(), SrcTy, Sizeof)) 9223 return false; 9224 return Success(Sizeof, E); 9225 } 9226 case UETT_OpenMPRequiredSimdAlign: 9227 assert(E->isArgumentType()); 9228 return Success( 9229 Info.Ctx.toCharUnitsFromBits( 9230 Info.Ctx.getOpenMPDefaultSimdAlign(E->getArgumentType())) 9231 .getQuantity(), 9232 E); 9233 } 9234 9235 llvm_unreachable("unknown expr/type trait"); 9236 } 9237 9238 bool IntExprEvaluator::VisitOffsetOfExpr(const OffsetOfExpr *OOE) { 9239 CharUnits Result; 9240 unsigned n = OOE->getNumComponents(); 9241 if (n == 0) 9242 return Error(OOE); 9243 QualType CurrentType = OOE->getTypeSourceInfo()->getType(); 9244 for (unsigned i = 0; i != n; ++i) { 9245 OffsetOfNode ON = OOE->getComponent(i); 9246 switch (ON.getKind()) { 9247 case OffsetOfNode::Array: { 9248 const Expr *Idx = OOE->getIndexExpr(ON.getArrayExprIndex()); 9249 APSInt IdxResult; 9250 if (!EvaluateInteger(Idx, IdxResult, Info)) 9251 return false; 9252 const ArrayType *AT = Info.Ctx.getAsArrayType(CurrentType); 9253 if (!AT) 9254 return Error(OOE); 9255 CurrentType = AT->getElementType(); 9256 CharUnits ElementSize = Info.Ctx.getTypeSizeInChars(CurrentType); 9257 Result += IdxResult.getSExtValue() * ElementSize; 9258 break; 9259 } 9260 9261 case OffsetOfNode::Field: { 9262 FieldDecl *MemberDecl = ON.getField(); 9263 const RecordType *RT = CurrentType->getAs<RecordType>(); 9264 if (!RT) 9265 return Error(OOE); 9266 RecordDecl *RD = RT->getDecl(); 9267 if (RD->isInvalidDecl()) return false; 9268 const ASTRecordLayout &RL = Info.Ctx.getASTRecordLayout(RD); 9269 unsigned i = MemberDecl->getFieldIndex(); 9270 assert(i < RL.getFieldCount() && "offsetof field in wrong type"); 9271 Result += Info.Ctx.toCharUnitsFromBits(RL.getFieldOffset(i)); 9272 CurrentType = MemberDecl->getType().getNonReferenceType(); 9273 break; 9274 } 9275 9276 case OffsetOfNode::Identifier: 9277 llvm_unreachable("dependent __builtin_offsetof"); 9278 9279 case OffsetOfNode::Base: { 9280 CXXBaseSpecifier *BaseSpec = ON.getBase(); 9281 if (BaseSpec->isVirtual()) 9282 return Error(OOE); 9283 9284 // Find the layout of the class whose base we are looking into. 9285 const RecordType *RT = CurrentType->getAs<RecordType>(); 9286 if (!RT) 9287 return Error(OOE); 9288 RecordDecl *RD = RT->getDecl(); 9289 if (RD->isInvalidDecl()) return false; 9290 const ASTRecordLayout &RL = Info.Ctx.getASTRecordLayout(RD); 9291 9292 // Find the base class itself. 9293 CurrentType = BaseSpec->getType(); 9294 const RecordType *BaseRT = CurrentType->getAs<RecordType>(); 9295 if (!BaseRT) 9296 return Error(OOE); 9297 9298 // Add the offset to the base. 9299 Result += RL.getBaseClassOffset(cast<CXXRecordDecl>(BaseRT->getDecl())); 9300 break; 9301 } 9302 } 9303 } 9304 return Success(Result, OOE); 9305 } 9306 9307 bool IntExprEvaluator::VisitUnaryOperator(const UnaryOperator *E) { 9308 switch (E->getOpcode()) { 9309 default: 9310 // Address, indirect, pre/post inc/dec, etc are not valid constant exprs. 9311 // See C99 6.6p3. 9312 return Error(E); 9313 case UO_Extension: 9314 // FIXME: Should extension allow i-c-e extension expressions in its scope? 9315 // If so, we could clear the diagnostic ID. 9316 return Visit(E->getSubExpr()); 9317 case UO_Plus: 9318 // The result is just the value. 9319 return Visit(E->getSubExpr()); 9320 case UO_Minus: { 9321 if (!Visit(E->getSubExpr())) 9322 return false; 9323 if (!Result.isInt()) return Error(E); 9324 const APSInt &Value = Result.getInt(); 9325 if (Value.isSigned() && Value.isMinSignedValue() && E->canOverflow() && 9326 !HandleOverflow(Info, E, -Value.extend(Value.getBitWidth() + 1), 9327 E->getType())) 9328 return false; 9329 return Success(-Value, E); 9330 } 9331 case UO_Not: { 9332 if (!Visit(E->getSubExpr())) 9333 return false; 9334 if (!Result.isInt()) return Error(E); 9335 return Success(~Result.getInt(), E); 9336 } 9337 case UO_LNot: { 9338 bool bres; 9339 if (!EvaluateAsBooleanCondition(E->getSubExpr(), bres, Info)) 9340 return false; 9341 return Success(!bres, E); 9342 } 9343 } 9344 } 9345 9346 /// HandleCast - This is used to evaluate implicit or explicit casts where the 9347 /// result type is integer. 9348 bool IntExprEvaluator::VisitCastExpr(const CastExpr *E) { 9349 const Expr *SubExpr = E->getSubExpr(); 9350 QualType DestType = E->getType(); 9351 QualType SrcType = SubExpr->getType(); 9352 9353 switch (E->getCastKind()) { 9354 case CK_BaseToDerived: 9355 case CK_DerivedToBase: 9356 case CK_UncheckedDerivedToBase: 9357 case CK_Dynamic: 9358 case CK_ToUnion: 9359 case CK_ArrayToPointerDecay: 9360 case CK_FunctionToPointerDecay: 9361 case CK_NullToPointer: 9362 case CK_NullToMemberPointer: 9363 case CK_BaseToDerivedMemberPointer: 9364 case CK_DerivedToBaseMemberPointer: 9365 case CK_ReinterpretMemberPointer: 9366 case CK_ConstructorConversion: 9367 case CK_IntegralToPointer: 9368 case CK_ToVoid: 9369 case CK_VectorSplat: 9370 case CK_IntegralToFloating: 9371 case CK_FloatingCast: 9372 case CK_CPointerToObjCPointerCast: 9373 case CK_BlockPointerToObjCPointerCast: 9374 case CK_AnyPointerToBlockPointerCast: 9375 case CK_ObjCObjectLValueCast: 9376 case CK_FloatingRealToComplex: 9377 case CK_FloatingComplexToReal: 9378 case CK_FloatingComplexCast: 9379 case CK_FloatingComplexToIntegralComplex: 9380 case CK_IntegralRealToComplex: 9381 case CK_IntegralComplexCast: 9382 case CK_IntegralComplexToFloatingComplex: 9383 case CK_BuiltinFnToFnPtr: 9384 case CK_ZeroToOCLEvent: 9385 case CK_ZeroToOCLQueue: 9386 case CK_NonAtomicToAtomic: 9387 case CK_AddressSpaceConversion: 9388 case CK_IntToOCLSampler: 9389 llvm_unreachable("invalid cast kind for integral value"); 9390 9391 case CK_BitCast: 9392 case CK_Dependent: 9393 case CK_LValueBitCast: 9394 case CK_ARCProduceObject: 9395 case CK_ARCConsumeObject: 9396 case CK_ARCReclaimReturnedObject: 9397 case CK_ARCExtendBlockObject: 9398 case CK_CopyAndAutoreleaseBlockObject: 9399 return Error(E); 9400 9401 case CK_UserDefinedConversion: 9402 case CK_LValueToRValue: 9403 case CK_AtomicToNonAtomic: 9404 case CK_NoOp: 9405 return ExprEvaluatorBaseTy::VisitCastExpr(E); 9406 9407 case CK_MemberPointerToBoolean: 9408 case CK_PointerToBoolean: 9409 case CK_IntegralToBoolean: 9410 case CK_FloatingToBoolean: 9411 case CK_BooleanToSignedIntegral: 9412 case CK_FloatingComplexToBoolean: 9413 case CK_IntegralComplexToBoolean: { 9414 bool BoolResult; 9415 if (!EvaluateAsBooleanCondition(SubExpr, BoolResult, Info)) 9416 return false; 9417 uint64_t IntResult = BoolResult; 9418 if (BoolResult && E->getCastKind() == CK_BooleanToSignedIntegral) 9419 IntResult = (uint64_t)-1; 9420 return Success(IntResult, E); 9421 } 9422 9423 case CK_IntegralCast: { 9424 if (!Visit(SubExpr)) 9425 return false; 9426 9427 if (!Result.isInt()) { 9428 // Allow casts of address-of-label differences if they are no-ops 9429 // or narrowing. (The narrowing case isn't actually guaranteed to 9430 // be constant-evaluatable except in some narrow cases which are hard 9431 // to detect here. We let it through on the assumption the user knows 9432 // what they are doing.) 9433 if (Result.isAddrLabelDiff()) 9434 return Info.Ctx.getTypeSize(DestType) <= Info.Ctx.getTypeSize(SrcType); 9435 // Only allow casts of lvalues if they are lossless. 9436 return Info.Ctx.getTypeSize(DestType) == Info.Ctx.getTypeSize(SrcType); 9437 } 9438 9439 return Success(HandleIntToIntCast(Info, E, DestType, SrcType, 9440 Result.getInt()), E); 9441 } 9442 9443 case CK_PointerToIntegral: { 9444 CCEDiag(E, diag::note_constexpr_invalid_cast) << 2; 9445 9446 LValue LV; 9447 if (!EvaluatePointer(SubExpr, LV, Info)) 9448 return false; 9449 9450 if (LV.getLValueBase()) { 9451 // Only allow based lvalue casts if they are lossless. 9452 // FIXME: Allow a larger integer size than the pointer size, and allow 9453 // narrowing back down to pointer width in subsequent integral casts. 9454 // FIXME: Check integer type's active bits, not its type size. 9455 if (Info.Ctx.getTypeSize(DestType) != Info.Ctx.getTypeSize(SrcType)) 9456 return Error(E); 9457 9458 LV.Designator.setInvalid(); 9459 LV.moveInto(Result); 9460 return true; 9461 } 9462 9463 uint64_t V; 9464 if (LV.isNullPointer()) 9465 V = Info.Ctx.getTargetNullPointerValue(SrcType); 9466 else 9467 V = LV.getLValueOffset().getQuantity(); 9468 9469 APSInt AsInt = Info.Ctx.MakeIntValue(V, SrcType); 9470 return Success(HandleIntToIntCast(Info, E, DestType, SrcType, AsInt), E); 9471 } 9472 9473 case CK_IntegralComplexToReal: { 9474 ComplexValue C; 9475 if (!EvaluateComplex(SubExpr, C, Info)) 9476 return false; 9477 return Success(C.getComplexIntReal(), E); 9478 } 9479 9480 case CK_FloatingToIntegral: { 9481 APFloat F(0.0); 9482 if (!EvaluateFloat(SubExpr, F, Info)) 9483 return false; 9484 9485 APSInt Value; 9486 if (!HandleFloatToIntCast(Info, E, SrcType, F, DestType, Value)) 9487 return false; 9488 return Success(Value, E); 9489 } 9490 } 9491 9492 llvm_unreachable("unknown cast resulting in integral value"); 9493 } 9494 9495 bool IntExprEvaluator::VisitUnaryReal(const UnaryOperator *E) { 9496 if (E->getSubExpr()->getType()->isAnyComplexType()) { 9497 ComplexValue LV; 9498 if (!EvaluateComplex(E->getSubExpr(), LV, Info)) 9499 return false; 9500 if (!LV.isComplexInt()) 9501 return Error(E); 9502 return Success(LV.getComplexIntReal(), E); 9503 } 9504 9505 return Visit(E->getSubExpr()); 9506 } 9507 9508 bool IntExprEvaluator::VisitUnaryImag(const UnaryOperator *E) { 9509 if (E->getSubExpr()->getType()->isComplexIntegerType()) { 9510 ComplexValue LV; 9511 if (!EvaluateComplex(E->getSubExpr(), LV, Info)) 9512 return false; 9513 if (!LV.isComplexInt()) 9514 return Error(E); 9515 return Success(LV.getComplexIntImag(), E); 9516 } 9517 9518 VisitIgnoredValue(E->getSubExpr()); 9519 return Success(0, E); 9520 } 9521 9522 bool IntExprEvaluator::VisitSizeOfPackExpr(const SizeOfPackExpr *E) { 9523 return Success(E->getPackLength(), E); 9524 } 9525 9526 bool IntExprEvaluator::VisitCXXNoexceptExpr(const CXXNoexceptExpr *E) { 9527 return Success(E->getValue(), E); 9528 } 9529 9530 bool FixedPointExprEvaluator::VisitUnaryOperator(const UnaryOperator *E) { 9531 switch (E->getOpcode()) { 9532 default: 9533 // Invalid unary operators 9534 return Error(E); 9535 case UO_Plus: 9536 // The result is just the value. 9537 return Visit(E->getSubExpr()); 9538 case UO_Minus: { 9539 if (!Visit(E->getSubExpr())) return false; 9540 if (!Result.isInt()) return Error(E); 9541 const APSInt &Value = Result.getInt(); 9542 if (Value.isSigned() && Value.isMinSignedValue() && E->canOverflow()) { 9543 SmallString<64> S; 9544 FixedPointValueToString(S, Value, 9545 Info.Ctx.getTypeInfo(E->getType()).Width, 9546 /*Radix=*/10); 9547 Info.CCEDiag(E, diag::note_constexpr_overflow) << S << E->getType(); 9548 if (Info.noteUndefinedBehavior()) return false; 9549 } 9550 return Success(-Value, E); 9551 } 9552 case UO_LNot: { 9553 bool bres; 9554 if (!EvaluateAsBooleanCondition(E->getSubExpr(), bres, Info)) 9555 return false; 9556 return Success(!bres, E); 9557 } 9558 } 9559 } 9560 9561 //===----------------------------------------------------------------------===// 9562 // Float Evaluation 9563 //===----------------------------------------------------------------------===// 9564 9565 namespace { 9566 class FloatExprEvaluator 9567 : public ExprEvaluatorBase<FloatExprEvaluator> { 9568 APFloat &Result; 9569 public: 9570 FloatExprEvaluator(EvalInfo &info, APFloat &result) 9571 : ExprEvaluatorBaseTy(info), Result(result) {} 9572 9573 bool Success(const APValue &V, const Expr *e) { 9574 Result = V.getFloat(); 9575 return true; 9576 } 9577 9578 bool ZeroInitialization(const Expr *E) { 9579 Result = APFloat::getZero(Info.Ctx.getFloatTypeSemantics(E->getType())); 9580 return true; 9581 } 9582 9583 bool VisitCallExpr(const CallExpr *E); 9584 9585 bool VisitUnaryOperator(const UnaryOperator *E); 9586 bool VisitBinaryOperator(const BinaryOperator *E); 9587 bool VisitFloatingLiteral(const FloatingLiteral *E); 9588 bool VisitCastExpr(const CastExpr *E); 9589 9590 bool VisitUnaryReal(const UnaryOperator *E); 9591 bool VisitUnaryImag(const UnaryOperator *E); 9592 9593 // FIXME: Missing: array subscript of vector, member of vector 9594 }; 9595 } // end anonymous namespace 9596 9597 static bool EvaluateFloat(const Expr* E, APFloat& Result, EvalInfo &Info) { 9598 assert(E->isRValue() && E->getType()->isRealFloatingType()); 9599 return FloatExprEvaluator(Info, Result).Visit(E); 9600 } 9601 9602 static bool TryEvaluateBuiltinNaN(const ASTContext &Context, 9603 QualType ResultTy, 9604 const Expr *Arg, 9605 bool SNaN, 9606 llvm::APFloat &Result) { 9607 const StringLiteral *S = dyn_cast<StringLiteral>(Arg->IgnoreParenCasts()); 9608 if (!S) return false; 9609 9610 const llvm::fltSemantics &Sem = Context.getFloatTypeSemantics(ResultTy); 9611 9612 llvm::APInt fill; 9613 9614 // Treat empty strings as if they were zero. 9615 if (S->getString().empty()) 9616 fill = llvm::APInt(32, 0); 9617 else if (S->getString().getAsInteger(0, fill)) 9618 return false; 9619 9620 if (Context.getTargetInfo().isNan2008()) { 9621 if (SNaN) 9622 Result = llvm::APFloat::getSNaN(Sem, false, &fill); 9623 else 9624 Result = llvm::APFloat::getQNaN(Sem, false, &fill); 9625 } else { 9626 // Prior to IEEE 754-2008, architectures were allowed to choose whether 9627 // the first bit of their significand was set for qNaN or sNaN. MIPS chose 9628 // a different encoding to what became a standard in 2008, and for pre- 9629 // 2008 revisions, MIPS interpreted sNaN-2008 as qNan and qNaN-2008 as 9630 // sNaN. This is now known as "legacy NaN" encoding. 9631 if (SNaN) 9632 Result = llvm::APFloat::getQNaN(Sem, false, &fill); 9633 else 9634 Result = llvm::APFloat::getSNaN(Sem, false, &fill); 9635 } 9636 9637 return true; 9638 } 9639 9640 bool FloatExprEvaluator::VisitCallExpr(const CallExpr *E) { 9641 switch (E->getBuiltinCallee()) { 9642 default: 9643 return ExprEvaluatorBaseTy::VisitCallExpr(E); 9644 9645 case Builtin::BI__builtin_huge_val: 9646 case Builtin::BI__builtin_huge_valf: 9647 case Builtin::BI__builtin_huge_vall: 9648 case Builtin::BI__builtin_huge_valf128: 9649 case Builtin::BI__builtin_inf: 9650 case Builtin::BI__builtin_inff: 9651 case Builtin::BI__builtin_infl: 9652 case Builtin::BI__builtin_inff128: { 9653 const llvm::fltSemantics &Sem = 9654 Info.Ctx.getFloatTypeSemantics(E->getType()); 9655 Result = llvm::APFloat::getInf(Sem); 9656 return true; 9657 } 9658 9659 case Builtin::BI__builtin_nans: 9660 case Builtin::BI__builtin_nansf: 9661 case Builtin::BI__builtin_nansl: 9662 case Builtin::BI__builtin_nansf128: 9663 if (!TryEvaluateBuiltinNaN(Info.Ctx, E->getType(), E->getArg(0), 9664 true, Result)) 9665 return Error(E); 9666 return true; 9667 9668 case Builtin::BI__builtin_nan: 9669 case Builtin::BI__builtin_nanf: 9670 case Builtin::BI__builtin_nanl: 9671 case Builtin::BI__builtin_nanf128: 9672 // If this is __builtin_nan() turn this into a nan, otherwise we 9673 // can't constant fold it. 9674 if (!TryEvaluateBuiltinNaN(Info.Ctx, E->getType(), E->getArg(0), 9675 false, Result)) 9676 return Error(E); 9677 return true; 9678 9679 case Builtin::BI__builtin_fabs: 9680 case Builtin::BI__builtin_fabsf: 9681 case Builtin::BI__builtin_fabsl: 9682 case Builtin::BI__builtin_fabsf128: 9683 if (!EvaluateFloat(E->getArg(0), Result, Info)) 9684 return false; 9685 9686 if (Result.isNegative()) 9687 Result.changeSign(); 9688 return true; 9689 9690 // FIXME: Builtin::BI__builtin_powi 9691 // FIXME: Builtin::BI__builtin_powif 9692 // FIXME: Builtin::BI__builtin_powil 9693 9694 case Builtin::BI__builtin_copysign: 9695 case Builtin::BI__builtin_copysignf: 9696 case Builtin::BI__builtin_copysignl: 9697 case Builtin::BI__builtin_copysignf128: { 9698 APFloat RHS(0.); 9699 if (!EvaluateFloat(E->getArg(0), Result, Info) || 9700 !EvaluateFloat(E->getArg(1), RHS, Info)) 9701 return false; 9702 Result.copySign(RHS); 9703 return true; 9704 } 9705 } 9706 } 9707 9708 bool FloatExprEvaluator::VisitUnaryReal(const UnaryOperator *E) { 9709 if (E->getSubExpr()->getType()->isAnyComplexType()) { 9710 ComplexValue CV; 9711 if (!EvaluateComplex(E->getSubExpr(), CV, Info)) 9712 return false; 9713 Result = CV.FloatReal; 9714 return true; 9715 } 9716 9717 return Visit(E->getSubExpr()); 9718 } 9719 9720 bool FloatExprEvaluator::VisitUnaryImag(const UnaryOperator *E) { 9721 if (E->getSubExpr()->getType()->isAnyComplexType()) { 9722 ComplexValue CV; 9723 if (!EvaluateComplex(E->getSubExpr(), CV, Info)) 9724 return false; 9725 Result = CV.FloatImag; 9726 return true; 9727 } 9728 9729 VisitIgnoredValue(E->getSubExpr()); 9730 const llvm::fltSemantics &Sem = Info.Ctx.getFloatTypeSemantics(E->getType()); 9731 Result = llvm::APFloat::getZero(Sem); 9732 return true; 9733 } 9734 9735 bool FloatExprEvaluator::VisitUnaryOperator(const UnaryOperator *E) { 9736 switch (E->getOpcode()) { 9737 default: return Error(E); 9738 case UO_Plus: 9739 return EvaluateFloat(E->getSubExpr(), Result, Info); 9740 case UO_Minus: 9741 if (!EvaluateFloat(E->getSubExpr(), Result, Info)) 9742 return false; 9743 Result.changeSign(); 9744 return true; 9745 } 9746 } 9747 9748 bool FloatExprEvaluator::VisitBinaryOperator(const BinaryOperator *E) { 9749 if (E->isPtrMemOp() || E->isAssignmentOp() || E->getOpcode() == BO_Comma) 9750 return ExprEvaluatorBaseTy::VisitBinaryOperator(E); 9751 9752 APFloat RHS(0.0); 9753 bool LHSOK = EvaluateFloat(E->getLHS(), Result, Info); 9754 if (!LHSOK && !Info.noteFailure()) 9755 return false; 9756 return EvaluateFloat(E->getRHS(), RHS, Info) && LHSOK && 9757 handleFloatFloatBinOp(Info, E, Result, E->getOpcode(), RHS); 9758 } 9759 9760 bool FloatExprEvaluator::VisitFloatingLiteral(const FloatingLiteral *E) { 9761 Result = E->getValue(); 9762 return true; 9763 } 9764 9765 bool FloatExprEvaluator::VisitCastExpr(const CastExpr *E) { 9766 const Expr* SubExpr = E->getSubExpr(); 9767 9768 switch (E->getCastKind()) { 9769 default: 9770 return ExprEvaluatorBaseTy::VisitCastExpr(E); 9771 9772 case CK_IntegralToFloating: { 9773 APSInt IntResult; 9774 return EvaluateInteger(SubExpr, IntResult, Info) && 9775 HandleIntToFloatCast(Info, E, SubExpr->getType(), IntResult, 9776 E->getType(), Result); 9777 } 9778 9779 case CK_FloatingCast: { 9780 if (!Visit(SubExpr)) 9781 return false; 9782 return HandleFloatToFloatCast(Info, E, SubExpr->getType(), E->getType(), 9783 Result); 9784 } 9785 9786 case CK_FloatingComplexToReal: { 9787 ComplexValue V; 9788 if (!EvaluateComplex(SubExpr, V, Info)) 9789 return false; 9790 Result = V.getComplexFloatReal(); 9791 return true; 9792 } 9793 } 9794 } 9795 9796 //===----------------------------------------------------------------------===// 9797 // Complex Evaluation (for float and integer) 9798 //===----------------------------------------------------------------------===// 9799 9800 namespace { 9801 class ComplexExprEvaluator 9802 : public ExprEvaluatorBase<ComplexExprEvaluator> { 9803 ComplexValue &Result; 9804 9805 public: 9806 ComplexExprEvaluator(EvalInfo &info, ComplexValue &Result) 9807 : ExprEvaluatorBaseTy(info), Result(Result) {} 9808 9809 bool Success(const APValue &V, const Expr *e) { 9810 Result.setFrom(V); 9811 return true; 9812 } 9813 9814 bool ZeroInitialization(const Expr *E); 9815 9816 //===--------------------------------------------------------------------===// 9817 // Visitor Methods 9818 //===--------------------------------------------------------------------===// 9819 9820 bool VisitImaginaryLiteral(const ImaginaryLiteral *E); 9821 bool VisitCastExpr(const CastExpr *E); 9822 bool VisitBinaryOperator(const BinaryOperator *E); 9823 bool VisitUnaryOperator(const UnaryOperator *E); 9824 bool VisitInitListExpr(const InitListExpr *E); 9825 }; 9826 } // end anonymous namespace 9827 9828 static bool EvaluateComplex(const Expr *E, ComplexValue &Result, 9829 EvalInfo &Info) { 9830 assert(E->isRValue() && E->getType()->isAnyComplexType()); 9831 return ComplexExprEvaluator(Info, Result).Visit(E); 9832 } 9833 9834 bool ComplexExprEvaluator::ZeroInitialization(const Expr *E) { 9835 QualType ElemTy = E->getType()->castAs<ComplexType>()->getElementType(); 9836 if (ElemTy->isRealFloatingType()) { 9837 Result.makeComplexFloat(); 9838 APFloat Zero = APFloat::getZero(Info.Ctx.getFloatTypeSemantics(ElemTy)); 9839 Result.FloatReal = Zero; 9840 Result.FloatImag = Zero; 9841 } else { 9842 Result.makeComplexInt(); 9843 APSInt Zero = Info.Ctx.MakeIntValue(0, ElemTy); 9844 Result.IntReal = Zero; 9845 Result.IntImag = Zero; 9846 } 9847 return true; 9848 } 9849 9850 bool ComplexExprEvaluator::VisitImaginaryLiteral(const ImaginaryLiteral *E) { 9851 const Expr* SubExpr = E->getSubExpr(); 9852 9853 if (SubExpr->getType()->isRealFloatingType()) { 9854 Result.makeComplexFloat(); 9855 APFloat &Imag = Result.FloatImag; 9856 if (!EvaluateFloat(SubExpr, Imag, Info)) 9857 return false; 9858 9859 Result.FloatReal = APFloat(Imag.getSemantics()); 9860 return true; 9861 } else { 9862 assert(SubExpr->getType()->isIntegerType() && 9863 "Unexpected imaginary literal."); 9864 9865 Result.makeComplexInt(); 9866 APSInt &Imag = Result.IntImag; 9867 if (!EvaluateInteger(SubExpr, Imag, Info)) 9868 return false; 9869 9870 Result.IntReal = APSInt(Imag.getBitWidth(), !Imag.isSigned()); 9871 return true; 9872 } 9873 } 9874 9875 bool ComplexExprEvaluator::VisitCastExpr(const CastExpr *E) { 9876 9877 switch (E->getCastKind()) { 9878 case CK_BitCast: 9879 case CK_BaseToDerived: 9880 case CK_DerivedToBase: 9881 case CK_UncheckedDerivedToBase: 9882 case CK_Dynamic: 9883 case CK_ToUnion: 9884 case CK_ArrayToPointerDecay: 9885 case CK_FunctionToPointerDecay: 9886 case CK_NullToPointer: 9887 case CK_NullToMemberPointer: 9888 case CK_BaseToDerivedMemberPointer: 9889 case CK_DerivedToBaseMemberPointer: 9890 case CK_MemberPointerToBoolean: 9891 case CK_ReinterpretMemberPointer: 9892 case CK_ConstructorConversion: 9893 case CK_IntegralToPointer: 9894 case CK_PointerToIntegral: 9895 case CK_PointerToBoolean: 9896 case CK_ToVoid: 9897 case CK_VectorSplat: 9898 case CK_IntegralCast: 9899 case CK_BooleanToSignedIntegral: 9900 case CK_IntegralToBoolean: 9901 case CK_IntegralToFloating: 9902 case CK_FloatingToIntegral: 9903 case CK_FloatingToBoolean: 9904 case CK_FloatingCast: 9905 case CK_CPointerToObjCPointerCast: 9906 case CK_BlockPointerToObjCPointerCast: 9907 case CK_AnyPointerToBlockPointerCast: 9908 case CK_ObjCObjectLValueCast: 9909 case CK_FloatingComplexToReal: 9910 case CK_FloatingComplexToBoolean: 9911 case CK_IntegralComplexToReal: 9912 case CK_IntegralComplexToBoolean: 9913 case CK_ARCProduceObject: 9914 case CK_ARCConsumeObject: 9915 case CK_ARCReclaimReturnedObject: 9916 case CK_ARCExtendBlockObject: 9917 case CK_CopyAndAutoreleaseBlockObject: 9918 case CK_BuiltinFnToFnPtr: 9919 case CK_ZeroToOCLEvent: 9920 case CK_ZeroToOCLQueue: 9921 case CK_NonAtomicToAtomic: 9922 case CK_AddressSpaceConversion: 9923 case CK_IntToOCLSampler: 9924 llvm_unreachable("invalid cast kind for complex value"); 9925 9926 case CK_LValueToRValue: 9927 case CK_AtomicToNonAtomic: 9928 case CK_NoOp: 9929 return ExprEvaluatorBaseTy::VisitCastExpr(E); 9930 9931 case CK_Dependent: 9932 case CK_LValueBitCast: 9933 case CK_UserDefinedConversion: 9934 return Error(E); 9935 9936 case CK_FloatingRealToComplex: { 9937 APFloat &Real = Result.FloatReal; 9938 if (!EvaluateFloat(E->getSubExpr(), Real, Info)) 9939 return false; 9940 9941 Result.makeComplexFloat(); 9942 Result.FloatImag = APFloat(Real.getSemantics()); 9943 return true; 9944 } 9945 9946 case CK_FloatingComplexCast: { 9947 if (!Visit(E->getSubExpr())) 9948 return false; 9949 9950 QualType To = E->getType()->getAs<ComplexType>()->getElementType(); 9951 QualType From 9952 = E->getSubExpr()->getType()->getAs<ComplexType>()->getElementType(); 9953 9954 return HandleFloatToFloatCast(Info, E, From, To, Result.FloatReal) && 9955 HandleFloatToFloatCast(Info, E, From, To, Result.FloatImag); 9956 } 9957 9958 case CK_FloatingComplexToIntegralComplex: { 9959 if (!Visit(E->getSubExpr())) 9960 return false; 9961 9962 QualType To = E->getType()->getAs<ComplexType>()->getElementType(); 9963 QualType From 9964 = E->getSubExpr()->getType()->getAs<ComplexType>()->getElementType(); 9965 Result.makeComplexInt(); 9966 return HandleFloatToIntCast(Info, E, From, Result.FloatReal, 9967 To, Result.IntReal) && 9968 HandleFloatToIntCast(Info, E, From, Result.FloatImag, 9969 To, Result.IntImag); 9970 } 9971 9972 case CK_IntegralRealToComplex: { 9973 APSInt &Real = Result.IntReal; 9974 if (!EvaluateInteger(E->getSubExpr(), Real, Info)) 9975 return false; 9976 9977 Result.makeComplexInt(); 9978 Result.IntImag = APSInt(Real.getBitWidth(), !Real.isSigned()); 9979 return true; 9980 } 9981 9982 case CK_IntegralComplexCast: { 9983 if (!Visit(E->getSubExpr())) 9984 return false; 9985 9986 QualType To = E->getType()->getAs<ComplexType>()->getElementType(); 9987 QualType From 9988 = E->getSubExpr()->getType()->getAs<ComplexType>()->getElementType(); 9989 9990 Result.IntReal = HandleIntToIntCast(Info, E, To, From, Result.IntReal); 9991 Result.IntImag = HandleIntToIntCast(Info, E, To, From, Result.IntImag); 9992 return true; 9993 } 9994 9995 case CK_IntegralComplexToFloatingComplex: { 9996 if (!Visit(E->getSubExpr())) 9997 return false; 9998 9999 QualType To = E->getType()->castAs<ComplexType>()->getElementType(); 10000 QualType From 10001 = E->getSubExpr()->getType()->castAs<ComplexType>()->getElementType(); 10002 Result.makeComplexFloat(); 10003 return HandleIntToFloatCast(Info, E, From, Result.IntReal, 10004 To, Result.FloatReal) && 10005 HandleIntToFloatCast(Info, E, From, Result.IntImag, 10006 To, Result.FloatImag); 10007 } 10008 } 10009 10010 llvm_unreachable("unknown cast resulting in complex value"); 10011 } 10012 10013 bool ComplexExprEvaluator::VisitBinaryOperator(const BinaryOperator *E) { 10014 if (E->isPtrMemOp() || E->isAssignmentOp() || E->getOpcode() == BO_Comma) 10015 return ExprEvaluatorBaseTy::VisitBinaryOperator(E); 10016 10017 // Track whether the LHS or RHS is real at the type system level. When this is 10018 // the case we can simplify our evaluation strategy. 10019 bool LHSReal = false, RHSReal = false; 10020 10021 bool LHSOK; 10022 if (E->getLHS()->getType()->isRealFloatingType()) { 10023 LHSReal = true; 10024 APFloat &Real = Result.FloatReal; 10025 LHSOK = EvaluateFloat(E->getLHS(), Real, Info); 10026 if (LHSOK) { 10027 Result.makeComplexFloat(); 10028 Result.FloatImag = APFloat(Real.getSemantics()); 10029 } 10030 } else { 10031 LHSOK = Visit(E->getLHS()); 10032 } 10033 if (!LHSOK && !Info.noteFailure()) 10034 return false; 10035 10036 ComplexValue RHS; 10037 if (E->getRHS()->getType()->isRealFloatingType()) { 10038 RHSReal = true; 10039 APFloat &Real = RHS.FloatReal; 10040 if (!EvaluateFloat(E->getRHS(), Real, Info) || !LHSOK) 10041 return false; 10042 RHS.makeComplexFloat(); 10043 RHS.FloatImag = APFloat(Real.getSemantics()); 10044 } else if (!EvaluateComplex(E->getRHS(), RHS, Info) || !LHSOK) 10045 return false; 10046 10047 assert(!(LHSReal && RHSReal) && 10048 "Cannot have both operands of a complex operation be real."); 10049 switch (E->getOpcode()) { 10050 default: return Error(E); 10051 case BO_Add: 10052 if (Result.isComplexFloat()) { 10053 Result.getComplexFloatReal().add(RHS.getComplexFloatReal(), 10054 APFloat::rmNearestTiesToEven); 10055 if (LHSReal) 10056 Result.getComplexFloatImag() = RHS.getComplexFloatImag(); 10057 else if (!RHSReal) 10058 Result.getComplexFloatImag().add(RHS.getComplexFloatImag(), 10059 APFloat::rmNearestTiesToEven); 10060 } else { 10061 Result.getComplexIntReal() += RHS.getComplexIntReal(); 10062 Result.getComplexIntImag() += RHS.getComplexIntImag(); 10063 } 10064 break; 10065 case BO_Sub: 10066 if (Result.isComplexFloat()) { 10067 Result.getComplexFloatReal().subtract(RHS.getComplexFloatReal(), 10068 APFloat::rmNearestTiesToEven); 10069 if (LHSReal) { 10070 Result.getComplexFloatImag() = RHS.getComplexFloatImag(); 10071 Result.getComplexFloatImag().changeSign(); 10072 } else if (!RHSReal) { 10073 Result.getComplexFloatImag().subtract(RHS.getComplexFloatImag(), 10074 APFloat::rmNearestTiesToEven); 10075 } 10076 } else { 10077 Result.getComplexIntReal() -= RHS.getComplexIntReal(); 10078 Result.getComplexIntImag() -= RHS.getComplexIntImag(); 10079 } 10080 break; 10081 case BO_Mul: 10082 if (Result.isComplexFloat()) { 10083 // This is an implementation of complex multiplication according to the 10084 // constraints laid out in C11 Annex G. The implemention uses the 10085 // following naming scheme: 10086 // (a + ib) * (c + id) 10087 ComplexValue LHS = Result; 10088 APFloat &A = LHS.getComplexFloatReal(); 10089 APFloat &B = LHS.getComplexFloatImag(); 10090 APFloat &C = RHS.getComplexFloatReal(); 10091 APFloat &D = RHS.getComplexFloatImag(); 10092 APFloat &ResR = Result.getComplexFloatReal(); 10093 APFloat &ResI = Result.getComplexFloatImag(); 10094 if (LHSReal) { 10095 assert(!RHSReal && "Cannot have two real operands for a complex op!"); 10096 ResR = A * C; 10097 ResI = A * D; 10098 } else if (RHSReal) { 10099 ResR = C * A; 10100 ResI = C * B; 10101 } else { 10102 // In the fully general case, we need to handle NaNs and infinities 10103 // robustly. 10104 APFloat AC = A * C; 10105 APFloat BD = B * D; 10106 APFloat AD = A * D; 10107 APFloat BC = B * C; 10108 ResR = AC - BD; 10109 ResI = AD + BC; 10110 if (ResR.isNaN() && ResI.isNaN()) { 10111 bool Recalc = false; 10112 if (A.isInfinity() || B.isInfinity()) { 10113 A = APFloat::copySign( 10114 APFloat(A.getSemantics(), A.isInfinity() ? 1 : 0), A); 10115 B = APFloat::copySign( 10116 APFloat(B.getSemantics(), B.isInfinity() ? 1 : 0), B); 10117 if (C.isNaN()) 10118 C = APFloat::copySign(APFloat(C.getSemantics()), C); 10119 if (D.isNaN()) 10120 D = APFloat::copySign(APFloat(D.getSemantics()), D); 10121 Recalc = true; 10122 } 10123 if (C.isInfinity() || D.isInfinity()) { 10124 C = APFloat::copySign( 10125 APFloat(C.getSemantics(), C.isInfinity() ? 1 : 0), C); 10126 D = APFloat::copySign( 10127 APFloat(D.getSemantics(), D.isInfinity() ? 1 : 0), D); 10128 if (A.isNaN()) 10129 A = APFloat::copySign(APFloat(A.getSemantics()), A); 10130 if (B.isNaN()) 10131 B = APFloat::copySign(APFloat(B.getSemantics()), B); 10132 Recalc = true; 10133 } 10134 if (!Recalc && (AC.isInfinity() || BD.isInfinity() || 10135 AD.isInfinity() || BC.isInfinity())) { 10136 if (A.isNaN()) 10137 A = APFloat::copySign(APFloat(A.getSemantics()), A); 10138 if (B.isNaN()) 10139 B = APFloat::copySign(APFloat(B.getSemantics()), B); 10140 if (C.isNaN()) 10141 C = APFloat::copySign(APFloat(C.getSemantics()), C); 10142 if (D.isNaN()) 10143 D = APFloat::copySign(APFloat(D.getSemantics()), D); 10144 Recalc = true; 10145 } 10146 if (Recalc) { 10147 ResR = APFloat::getInf(A.getSemantics()) * (A * C - B * D); 10148 ResI = APFloat::getInf(A.getSemantics()) * (A * D + B * C); 10149 } 10150 } 10151 } 10152 } else { 10153 ComplexValue LHS = Result; 10154 Result.getComplexIntReal() = 10155 (LHS.getComplexIntReal() * RHS.getComplexIntReal() - 10156 LHS.getComplexIntImag() * RHS.getComplexIntImag()); 10157 Result.getComplexIntImag() = 10158 (LHS.getComplexIntReal() * RHS.getComplexIntImag() + 10159 LHS.getComplexIntImag() * RHS.getComplexIntReal()); 10160 } 10161 break; 10162 case BO_Div: 10163 if (Result.isComplexFloat()) { 10164 // This is an implementation of complex division according to the 10165 // constraints laid out in C11 Annex G. The implemention uses the 10166 // following naming scheme: 10167 // (a + ib) / (c + id) 10168 ComplexValue LHS = Result; 10169 APFloat &A = LHS.getComplexFloatReal(); 10170 APFloat &B = LHS.getComplexFloatImag(); 10171 APFloat &C = RHS.getComplexFloatReal(); 10172 APFloat &D = RHS.getComplexFloatImag(); 10173 APFloat &ResR = Result.getComplexFloatReal(); 10174 APFloat &ResI = Result.getComplexFloatImag(); 10175 if (RHSReal) { 10176 ResR = A / C; 10177 ResI = B / C; 10178 } else { 10179 if (LHSReal) { 10180 // No real optimizations we can do here, stub out with zero. 10181 B = APFloat::getZero(A.getSemantics()); 10182 } 10183 int DenomLogB = 0; 10184 APFloat MaxCD = maxnum(abs(C), abs(D)); 10185 if (MaxCD.isFinite()) { 10186 DenomLogB = ilogb(MaxCD); 10187 C = scalbn(C, -DenomLogB, APFloat::rmNearestTiesToEven); 10188 D = scalbn(D, -DenomLogB, APFloat::rmNearestTiesToEven); 10189 } 10190 APFloat Denom = C * C + D * D; 10191 ResR = scalbn((A * C + B * D) / Denom, -DenomLogB, 10192 APFloat::rmNearestTiesToEven); 10193 ResI = scalbn((B * C - A * D) / Denom, -DenomLogB, 10194 APFloat::rmNearestTiesToEven); 10195 if (ResR.isNaN() && ResI.isNaN()) { 10196 if (Denom.isPosZero() && (!A.isNaN() || !B.isNaN())) { 10197 ResR = APFloat::getInf(ResR.getSemantics(), C.isNegative()) * A; 10198 ResI = APFloat::getInf(ResR.getSemantics(), C.isNegative()) * B; 10199 } else if ((A.isInfinity() || B.isInfinity()) && C.isFinite() && 10200 D.isFinite()) { 10201 A = APFloat::copySign( 10202 APFloat(A.getSemantics(), A.isInfinity() ? 1 : 0), A); 10203 B = APFloat::copySign( 10204 APFloat(B.getSemantics(), B.isInfinity() ? 1 : 0), B); 10205 ResR = APFloat::getInf(ResR.getSemantics()) * (A * C + B * D); 10206 ResI = APFloat::getInf(ResI.getSemantics()) * (B * C - A * D); 10207 } else if (MaxCD.isInfinity() && A.isFinite() && B.isFinite()) { 10208 C = APFloat::copySign( 10209 APFloat(C.getSemantics(), C.isInfinity() ? 1 : 0), C); 10210 D = APFloat::copySign( 10211 APFloat(D.getSemantics(), D.isInfinity() ? 1 : 0), D); 10212 ResR = APFloat::getZero(ResR.getSemantics()) * (A * C + B * D); 10213 ResI = APFloat::getZero(ResI.getSemantics()) * (B * C - A * D); 10214 } 10215 } 10216 } 10217 } else { 10218 if (RHS.getComplexIntReal() == 0 && RHS.getComplexIntImag() == 0) 10219 return Error(E, diag::note_expr_divide_by_zero); 10220 10221 ComplexValue LHS = Result; 10222 APSInt Den = RHS.getComplexIntReal() * RHS.getComplexIntReal() + 10223 RHS.getComplexIntImag() * RHS.getComplexIntImag(); 10224 Result.getComplexIntReal() = 10225 (LHS.getComplexIntReal() * RHS.getComplexIntReal() + 10226 LHS.getComplexIntImag() * RHS.getComplexIntImag()) / Den; 10227 Result.getComplexIntImag() = 10228 (LHS.getComplexIntImag() * RHS.getComplexIntReal() - 10229 LHS.getComplexIntReal() * RHS.getComplexIntImag()) / Den; 10230 } 10231 break; 10232 } 10233 10234 return true; 10235 } 10236 10237 bool ComplexExprEvaluator::VisitUnaryOperator(const UnaryOperator *E) { 10238 // Get the operand value into 'Result'. 10239 if (!Visit(E->getSubExpr())) 10240 return false; 10241 10242 switch (E->getOpcode()) { 10243 default: 10244 return Error(E); 10245 case UO_Extension: 10246 return true; 10247 case UO_Plus: 10248 // The result is always just the subexpr. 10249 return true; 10250 case UO_Minus: 10251 if (Result.isComplexFloat()) { 10252 Result.getComplexFloatReal().changeSign(); 10253 Result.getComplexFloatImag().changeSign(); 10254 } 10255 else { 10256 Result.getComplexIntReal() = -Result.getComplexIntReal(); 10257 Result.getComplexIntImag() = -Result.getComplexIntImag(); 10258 } 10259 return true; 10260 case UO_Not: 10261 if (Result.isComplexFloat()) 10262 Result.getComplexFloatImag().changeSign(); 10263 else 10264 Result.getComplexIntImag() = -Result.getComplexIntImag(); 10265 return true; 10266 } 10267 } 10268 10269 bool ComplexExprEvaluator::VisitInitListExpr(const InitListExpr *E) { 10270 if (E->getNumInits() == 2) { 10271 if (E->getType()->isComplexType()) { 10272 Result.makeComplexFloat(); 10273 if (!EvaluateFloat(E->getInit(0), Result.FloatReal, Info)) 10274 return false; 10275 if (!EvaluateFloat(E->getInit(1), Result.FloatImag, Info)) 10276 return false; 10277 } else { 10278 Result.makeComplexInt(); 10279 if (!EvaluateInteger(E->getInit(0), Result.IntReal, Info)) 10280 return false; 10281 if (!EvaluateInteger(E->getInit(1), Result.IntImag, Info)) 10282 return false; 10283 } 10284 return true; 10285 } 10286 return ExprEvaluatorBaseTy::VisitInitListExpr(E); 10287 } 10288 10289 //===----------------------------------------------------------------------===// 10290 // Atomic expression evaluation, essentially just handling the NonAtomicToAtomic 10291 // implicit conversion. 10292 //===----------------------------------------------------------------------===// 10293 10294 namespace { 10295 class AtomicExprEvaluator : 10296 public ExprEvaluatorBase<AtomicExprEvaluator> { 10297 const LValue *This; 10298 APValue &Result; 10299 public: 10300 AtomicExprEvaluator(EvalInfo &Info, const LValue *This, APValue &Result) 10301 : ExprEvaluatorBaseTy(Info), This(This), Result(Result) {} 10302 10303 bool Success(const APValue &V, const Expr *E) { 10304 Result = V; 10305 return true; 10306 } 10307 10308 bool ZeroInitialization(const Expr *E) { 10309 ImplicitValueInitExpr VIE( 10310 E->getType()->castAs<AtomicType>()->getValueType()); 10311 // For atomic-qualified class (and array) types in C++, initialize the 10312 // _Atomic-wrapped subobject directly, in-place. 10313 return This ? EvaluateInPlace(Result, Info, *This, &VIE) 10314 : Evaluate(Result, Info, &VIE); 10315 } 10316 10317 bool VisitCastExpr(const CastExpr *E) { 10318 switch (E->getCastKind()) { 10319 default: 10320 return ExprEvaluatorBaseTy::VisitCastExpr(E); 10321 case CK_NonAtomicToAtomic: 10322 return This ? EvaluateInPlace(Result, Info, *This, E->getSubExpr()) 10323 : Evaluate(Result, Info, E->getSubExpr()); 10324 } 10325 } 10326 }; 10327 } // end anonymous namespace 10328 10329 static bool EvaluateAtomic(const Expr *E, const LValue *This, APValue &Result, 10330 EvalInfo &Info) { 10331 assert(E->isRValue() && E->getType()->isAtomicType()); 10332 return AtomicExprEvaluator(Info, This, Result).Visit(E); 10333 } 10334 10335 //===----------------------------------------------------------------------===// 10336 // Void expression evaluation, primarily for a cast to void on the LHS of a 10337 // comma operator 10338 //===----------------------------------------------------------------------===// 10339 10340 namespace { 10341 class VoidExprEvaluator 10342 : public ExprEvaluatorBase<VoidExprEvaluator> { 10343 public: 10344 VoidExprEvaluator(EvalInfo &Info) : ExprEvaluatorBaseTy(Info) {} 10345 10346 bool Success(const APValue &V, const Expr *e) { return true; } 10347 10348 bool ZeroInitialization(const Expr *E) { return true; } 10349 10350 bool VisitCastExpr(const CastExpr *E) { 10351 switch (E->getCastKind()) { 10352 default: 10353 return ExprEvaluatorBaseTy::VisitCastExpr(E); 10354 case CK_ToVoid: 10355 VisitIgnoredValue(E->getSubExpr()); 10356 return true; 10357 } 10358 } 10359 10360 bool VisitCallExpr(const CallExpr *E) { 10361 switch (E->getBuiltinCallee()) { 10362 default: 10363 return ExprEvaluatorBaseTy::VisitCallExpr(E); 10364 case Builtin::BI__assume: 10365 case Builtin::BI__builtin_assume: 10366 // The argument is not evaluated! 10367 return true; 10368 } 10369 } 10370 }; 10371 } // end anonymous namespace 10372 10373 static bool EvaluateVoid(const Expr *E, EvalInfo &Info) { 10374 assert(E->isRValue() && E->getType()->isVoidType()); 10375 return VoidExprEvaluator(Info).Visit(E); 10376 } 10377 10378 //===----------------------------------------------------------------------===// 10379 // Top level Expr::EvaluateAsRValue method. 10380 //===----------------------------------------------------------------------===// 10381 10382 static bool Evaluate(APValue &Result, EvalInfo &Info, const Expr *E) { 10383 // In C, function designators are not lvalues, but we evaluate them as if they 10384 // are. 10385 QualType T = E->getType(); 10386 if (E->isGLValue() || T->isFunctionType()) { 10387 LValue LV; 10388 if (!EvaluateLValue(E, LV, Info)) 10389 return false; 10390 LV.moveInto(Result); 10391 } else if (T->isVectorType()) { 10392 if (!EvaluateVector(E, Result, Info)) 10393 return false; 10394 } else if (T->isIntegralOrEnumerationType()) { 10395 if (!IntExprEvaluator(Info, Result).Visit(E)) 10396 return false; 10397 } else if (T->hasPointerRepresentation()) { 10398 LValue LV; 10399 if (!EvaluatePointer(E, LV, Info)) 10400 return false; 10401 LV.moveInto(Result); 10402 } else if (T->isRealFloatingType()) { 10403 llvm::APFloat F(0.0); 10404 if (!EvaluateFloat(E, F, Info)) 10405 return false; 10406 Result = APValue(F); 10407 } else if (T->isAnyComplexType()) { 10408 ComplexValue C; 10409 if (!EvaluateComplex(E, C, Info)) 10410 return false; 10411 C.moveInto(Result); 10412 } else if (T->isFixedPointType()) { 10413 if (!FixedPointExprEvaluator(Info, Result).Visit(E)) return false; 10414 } else if (T->isMemberPointerType()) { 10415 MemberPtr P; 10416 if (!EvaluateMemberPointer(E, P, Info)) 10417 return false; 10418 P.moveInto(Result); 10419 return true; 10420 } else if (T->isArrayType()) { 10421 LValue LV; 10422 APValue &Value = createTemporary(E, false, LV, *Info.CurrentCall); 10423 if (!EvaluateArray(E, LV, Value, Info)) 10424 return false; 10425 Result = Value; 10426 } else if (T->isRecordType()) { 10427 LValue LV; 10428 APValue &Value = createTemporary(E, false, LV, *Info.CurrentCall); 10429 if (!EvaluateRecord(E, LV, Value, Info)) 10430 return false; 10431 Result = Value; 10432 } else if (T->isVoidType()) { 10433 if (!Info.getLangOpts().CPlusPlus11) 10434 Info.CCEDiag(E, diag::note_constexpr_nonliteral) 10435 << E->getType(); 10436 if (!EvaluateVoid(E, Info)) 10437 return false; 10438 } else if (T->isAtomicType()) { 10439 QualType Unqual = T.getAtomicUnqualifiedType(); 10440 if (Unqual->isArrayType() || Unqual->isRecordType()) { 10441 LValue LV; 10442 APValue &Value = createTemporary(E, false, LV, *Info.CurrentCall); 10443 if (!EvaluateAtomic(E, &LV, Value, Info)) 10444 return false; 10445 } else { 10446 if (!EvaluateAtomic(E, nullptr, Result, Info)) 10447 return false; 10448 } 10449 } else if (Info.getLangOpts().CPlusPlus11) { 10450 Info.FFDiag(E, diag::note_constexpr_nonliteral) << E->getType(); 10451 return false; 10452 } else { 10453 Info.FFDiag(E, diag::note_invalid_subexpr_in_const_expr); 10454 return false; 10455 } 10456 10457 return true; 10458 } 10459 10460 /// EvaluateInPlace - Evaluate an expression in-place in an APValue. In some 10461 /// cases, the in-place evaluation is essential, since later initializers for 10462 /// an object can indirectly refer to subobjects which were initialized earlier. 10463 static bool EvaluateInPlace(APValue &Result, EvalInfo &Info, const LValue &This, 10464 const Expr *E, bool AllowNonLiteralTypes) { 10465 assert(!E->isValueDependent()); 10466 10467 if (!AllowNonLiteralTypes && !CheckLiteralType(Info, E, &This)) 10468 return false; 10469 10470 if (E->isRValue()) { 10471 // Evaluate arrays and record types in-place, so that later initializers can 10472 // refer to earlier-initialized members of the object. 10473 QualType T = E->getType(); 10474 if (T->isArrayType()) 10475 return EvaluateArray(E, This, Result, Info); 10476 else if (T->isRecordType()) 10477 return EvaluateRecord(E, This, Result, Info); 10478 else if (T->isAtomicType()) { 10479 QualType Unqual = T.getAtomicUnqualifiedType(); 10480 if (Unqual->isArrayType() || Unqual->isRecordType()) 10481 return EvaluateAtomic(E, &This, Result, Info); 10482 } 10483 } 10484 10485 // For any other type, in-place evaluation is unimportant. 10486 return Evaluate(Result, Info, E); 10487 } 10488 10489 /// EvaluateAsRValue - Try to evaluate this expression, performing an implicit 10490 /// lvalue-to-rvalue cast if it is an lvalue. 10491 static bool EvaluateAsRValue(EvalInfo &Info, const Expr *E, APValue &Result) { 10492 if (E->getType().isNull()) 10493 return false; 10494 10495 if (!CheckLiteralType(Info, E)) 10496 return false; 10497 10498 if (!::Evaluate(Result, Info, E)) 10499 return false; 10500 10501 if (E->isGLValue()) { 10502 LValue LV; 10503 LV.setFrom(Info.Ctx, Result); 10504 if (!handleLValueToRValueConversion(Info, E, E->getType(), LV, Result)) 10505 return false; 10506 } 10507 10508 // Check this core constant expression is a constant expression. 10509 return CheckConstantExpression(Info, E->getExprLoc(), E->getType(), Result); 10510 } 10511 10512 static bool FastEvaluateAsRValue(const Expr *Exp, Expr::EvalResult &Result, 10513 const ASTContext &Ctx, bool &IsConst) { 10514 // Fast-path evaluations of integer literals, since we sometimes see files 10515 // containing vast quantities of these. 10516 if (const IntegerLiteral *L = dyn_cast<IntegerLiteral>(Exp)) { 10517 Result.Val = APValue(APSInt(L->getValue(), 10518 L->getType()->isUnsignedIntegerType())); 10519 IsConst = true; 10520 return true; 10521 } 10522 10523 // This case should be rare, but we need to check it before we check on 10524 // the type below. 10525 if (Exp->getType().isNull()) { 10526 IsConst = false; 10527 return true; 10528 } 10529 10530 // FIXME: Evaluating values of large array and record types can cause 10531 // performance problems. Only do so in C++11 for now. 10532 if (Exp->isRValue() && (Exp->getType()->isArrayType() || 10533 Exp->getType()->isRecordType()) && 10534 !Ctx.getLangOpts().CPlusPlus11) { 10535 IsConst = false; 10536 return true; 10537 } 10538 return false; 10539 } 10540 10541 10542 /// EvaluateAsRValue - Return true if this is a constant which we can fold using 10543 /// any crazy technique (that has nothing to do with language standards) that 10544 /// we want to. If this function returns true, it returns the folded constant 10545 /// in Result. If this expression is a glvalue, an lvalue-to-rvalue conversion 10546 /// will be applied to the result. 10547 bool Expr::EvaluateAsRValue(EvalResult &Result, const ASTContext &Ctx) const { 10548 bool IsConst; 10549 if (FastEvaluateAsRValue(this, Result, Ctx, IsConst)) 10550 return IsConst; 10551 10552 EvalInfo Info(Ctx, Result, EvalInfo::EM_IgnoreSideEffects); 10553 return ::EvaluateAsRValue(Info, this, Result.Val); 10554 } 10555 10556 bool Expr::EvaluateAsBooleanCondition(bool &Result, 10557 const ASTContext &Ctx) const { 10558 EvalResult Scratch; 10559 return EvaluateAsRValue(Scratch, Ctx) && 10560 HandleConversionToBool(Scratch.Val, Result); 10561 } 10562 10563 static bool hasUnacceptableSideEffect(Expr::EvalStatus &Result, 10564 Expr::SideEffectsKind SEK) { 10565 return (SEK < Expr::SE_AllowSideEffects && Result.HasSideEffects) || 10566 (SEK < Expr::SE_AllowUndefinedBehavior && Result.HasUndefinedBehavior); 10567 } 10568 10569 bool Expr::EvaluateAsInt(APSInt &Result, const ASTContext &Ctx, 10570 SideEffectsKind AllowSideEffects) const { 10571 if (!getType()->isIntegralOrEnumerationType()) 10572 return false; 10573 10574 EvalResult ExprResult; 10575 if (!EvaluateAsRValue(ExprResult, Ctx) || !ExprResult.Val.isInt() || 10576 hasUnacceptableSideEffect(ExprResult, AllowSideEffects)) 10577 return false; 10578 10579 Result = ExprResult.Val.getInt(); 10580 return true; 10581 } 10582 10583 bool Expr::EvaluateAsFloat(APFloat &Result, const ASTContext &Ctx, 10584 SideEffectsKind AllowSideEffects) const { 10585 if (!getType()->isRealFloatingType()) 10586 return false; 10587 10588 EvalResult ExprResult; 10589 if (!EvaluateAsRValue(ExprResult, Ctx) || !ExprResult.Val.isFloat() || 10590 hasUnacceptableSideEffect(ExprResult, AllowSideEffects)) 10591 return false; 10592 10593 Result = ExprResult.Val.getFloat(); 10594 return true; 10595 } 10596 10597 bool Expr::EvaluateAsLValue(EvalResult &Result, const ASTContext &Ctx) const { 10598 EvalInfo Info(Ctx, Result, EvalInfo::EM_ConstantFold); 10599 10600 LValue LV; 10601 if (!EvaluateLValue(this, LV, Info) || Result.HasSideEffects || 10602 !CheckLValueConstantExpression(Info, getExprLoc(), 10603 Ctx.getLValueReferenceType(getType()), LV, 10604 Expr::EvaluateForCodeGen)) 10605 return false; 10606 10607 LV.moveInto(Result.Val); 10608 return true; 10609 } 10610 10611 bool Expr::EvaluateAsConstantExpr(EvalResult &Result, ConstExprUsage Usage, 10612 const ASTContext &Ctx) const { 10613 EvalInfo::EvaluationMode EM = EvalInfo::EM_ConstantExpression; 10614 EvalInfo Info(Ctx, Result, EM); 10615 if (!::Evaluate(Result.Val, Info, this)) 10616 return false; 10617 10618 return CheckConstantExpression(Info, getExprLoc(), getType(), Result.Val, 10619 Usage); 10620 } 10621 10622 bool Expr::EvaluateAsInitializer(APValue &Value, const ASTContext &Ctx, 10623 const VarDecl *VD, 10624 SmallVectorImpl<PartialDiagnosticAt> &Notes) const { 10625 // FIXME: Evaluating initializers for large array and record types can cause 10626 // performance problems. Only do so in C++11 for now. 10627 if (isRValue() && (getType()->isArrayType() || getType()->isRecordType()) && 10628 !Ctx.getLangOpts().CPlusPlus11) 10629 return false; 10630 10631 Expr::EvalStatus EStatus; 10632 EStatus.Diag = &Notes; 10633 10634 EvalInfo InitInfo(Ctx, EStatus, VD->isConstexpr() 10635 ? EvalInfo::EM_ConstantExpression 10636 : EvalInfo::EM_ConstantFold); 10637 InitInfo.setEvaluatingDecl(VD, Value); 10638 10639 LValue LVal; 10640 LVal.set(VD); 10641 10642 // C++11 [basic.start.init]p2: 10643 // Variables with static storage duration or thread storage duration shall be 10644 // zero-initialized before any other initialization takes place. 10645 // This behavior is not present in C. 10646 if (Ctx.getLangOpts().CPlusPlus && !VD->hasLocalStorage() && 10647 !VD->getType()->isReferenceType()) { 10648 ImplicitValueInitExpr VIE(VD->getType()); 10649 if (!EvaluateInPlace(Value, InitInfo, LVal, &VIE, 10650 /*AllowNonLiteralTypes=*/true)) 10651 return false; 10652 } 10653 10654 if (!EvaluateInPlace(Value, InitInfo, LVal, this, 10655 /*AllowNonLiteralTypes=*/true) || 10656 EStatus.HasSideEffects) 10657 return false; 10658 10659 return CheckConstantExpression(InitInfo, VD->getLocation(), VD->getType(), 10660 Value); 10661 } 10662 10663 /// isEvaluatable - Call EvaluateAsRValue to see if this expression can be 10664 /// constant folded, but discard the result. 10665 bool Expr::isEvaluatable(const ASTContext &Ctx, SideEffectsKind SEK) const { 10666 EvalResult Result; 10667 return EvaluateAsRValue(Result, Ctx) && 10668 !hasUnacceptableSideEffect(Result, SEK); 10669 } 10670 10671 APSInt Expr::EvaluateKnownConstInt(const ASTContext &Ctx, 10672 SmallVectorImpl<PartialDiagnosticAt> *Diag) const { 10673 EvalResult EvalResult; 10674 EvalResult.Diag = Diag; 10675 bool Result = EvaluateAsRValue(EvalResult, Ctx); 10676 (void)Result; 10677 assert(Result && "Could not evaluate expression"); 10678 assert(EvalResult.Val.isInt() && "Expression did not evaluate to integer"); 10679 10680 return EvalResult.Val.getInt(); 10681 } 10682 10683 void Expr::EvaluateForOverflow(const ASTContext &Ctx) const { 10684 bool IsConst; 10685 EvalResult EvalResult; 10686 if (!FastEvaluateAsRValue(this, EvalResult, Ctx, IsConst)) { 10687 EvalInfo Info(Ctx, EvalResult, EvalInfo::EM_EvaluateForOverflow); 10688 (void)::EvaluateAsRValue(Info, this, EvalResult.Val); 10689 } 10690 } 10691 10692 bool Expr::EvalResult::isGlobalLValue() const { 10693 assert(Val.isLValue()); 10694 return IsGlobalLValue(Val.getLValueBase()); 10695 } 10696 10697 10698 /// isIntegerConstantExpr - this recursive routine will test if an expression is 10699 /// an integer constant expression. 10700 10701 /// FIXME: Pass up a reason why! Invalid operation in i-c-e, division by zero, 10702 /// comma, etc 10703 10704 // CheckICE - This function does the fundamental ICE checking: the returned 10705 // ICEDiag contains an ICEKind indicating whether the expression is an ICE, 10706 // and a (possibly null) SourceLocation indicating the location of the problem. 10707 // 10708 // Note that to reduce code duplication, this helper does no evaluation 10709 // itself; the caller checks whether the expression is evaluatable, and 10710 // in the rare cases where CheckICE actually cares about the evaluated 10711 // value, it calls into Evaluate. 10712 10713 namespace { 10714 10715 enum ICEKind { 10716 /// This expression is an ICE. 10717 IK_ICE, 10718 /// This expression is not an ICE, but if it isn't evaluated, it's 10719 /// a legal subexpression for an ICE. This return value is used to handle 10720 /// the comma operator in C99 mode, and non-constant subexpressions. 10721 IK_ICEIfUnevaluated, 10722 /// This expression is not an ICE, and is not a legal subexpression for one. 10723 IK_NotICE 10724 }; 10725 10726 struct ICEDiag { 10727 ICEKind Kind; 10728 SourceLocation Loc; 10729 10730 ICEDiag(ICEKind IK, SourceLocation l) : Kind(IK), Loc(l) {} 10731 }; 10732 10733 } 10734 10735 static ICEDiag NoDiag() { return ICEDiag(IK_ICE, SourceLocation()); } 10736 10737 static ICEDiag Worst(ICEDiag A, ICEDiag B) { return A.Kind >= B.Kind ? A : B; } 10738 10739 static ICEDiag CheckEvalInICE(const Expr* E, const ASTContext &Ctx) { 10740 Expr::EvalResult EVResult; 10741 if (!E->EvaluateAsRValue(EVResult, Ctx) || EVResult.HasSideEffects || 10742 !EVResult.Val.isInt()) 10743 return ICEDiag(IK_NotICE, E->getLocStart()); 10744 10745 return NoDiag(); 10746 } 10747 10748 static ICEDiag CheckICE(const Expr* E, const ASTContext &Ctx) { 10749 assert(!E->isValueDependent() && "Should not see value dependent exprs!"); 10750 if (!E->getType()->isIntegralOrEnumerationType()) 10751 return ICEDiag(IK_NotICE, E->getLocStart()); 10752 10753 switch (E->getStmtClass()) { 10754 #define ABSTRACT_STMT(Node) 10755 #define STMT(Node, Base) case Expr::Node##Class: 10756 #define EXPR(Node, Base) 10757 #include "clang/AST/StmtNodes.inc" 10758 case Expr::PredefinedExprClass: 10759 case Expr::FloatingLiteralClass: 10760 case Expr::ImaginaryLiteralClass: 10761 case Expr::StringLiteralClass: 10762 case Expr::ArraySubscriptExprClass: 10763 case Expr::OMPArraySectionExprClass: 10764 case Expr::MemberExprClass: 10765 case Expr::CompoundAssignOperatorClass: 10766 case Expr::CompoundLiteralExprClass: 10767 case Expr::ExtVectorElementExprClass: 10768 case Expr::DesignatedInitExprClass: 10769 case Expr::ArrayInitLoopExprClass: 10770 case Expr::ArrayInitIndexExprClass: 10771 case Expr::NoInitExprClass: 10772 case Expr::DesignatedInitUpdateExprClass: 10773 case Expr::ImplicitValueInitExprClass: 10774 case Expr::ParenListExprClass: 10775 case Expr::VAArgExprClass: 10776 case Expr::AddrLabelExprClass: 10777 case Expr::StmtExprClass: 10778 case Expr::CXXMemberCallExprClass: 10779 case Expr::CUDAKernelCallExprClass: 10780 case Expr::CXXDynamicCastExprClass: 10781 case Expr::CXXTypeidExprClass: 10782 case Expr::CXXUuidofExprClass: 10783 case Expr::MSPropertyRefExprClass: 10784 case Expr::MSPropertySubscriptExprClass: 10785 case Expr::CXXNullPtrLiteralExprClass: 10786 case Expr::UserDefinedLiteralClass: 10787 case Expr::CXXThisExprClass: 10788 case Expr::CXXThrowExprClass: 10789 case Expr::CXXNewExprClass: 10790 case Expr::CXXDeleteExprClass: 10791 case Expr::CXXPseudoDestructorExprClass: 10792 case Expr::UnresolvedLookupExprClass: 10793 case Expr::TypoExprClass: 10794 case Expr::DependentScopeDeclRefExprClass: 10795 case Expr::CXXConstructExprClass: 10796 case Expr::CXXInheritedCtorInitExprClass: 10797 case Expr::CXXStdInitializerListExprClass: 10798 case Expr::CXXBindTemporaryExprClass: 10799 case Expr::ExprWithCleanupsClass: 10800 case Expr::CXXTemporaryObjectExprClass: 10801 case Expr::CXXUnresolvedConstructExprClass: 10802 case Expr::CXXDependentScopeMemberExprClass: 10803 case Expr::UnresolvedMemberExprClass: 10804 case Expr::ObjCStringLiteralClass: 10805 case Expr::ObjCBoxedExprClass: 10806 case Expr::ObjCArrayLiteralClass: 10807 case Expr::ObjCDictionaryLiteralClass: 10808 case Expr::ObjCEncodeExprClass: 10809 case Expr::ObjCMessageExprClass: 10810 case Expr::ObjCSelectorExprClass: 10811 case Expr::ObjCProtocolExprClass: 10812 case Expr::ObjCIvarRefExprClass: 10813 case Expr::ObjCPropertyRefExprClass: 10814 case Expr::ObjCSubscriptRefExprClass: 10815 case Expr::ObjCIsaExprClass: 10816 case Expr::ObjCAvailabilityCheckExprClass: 10817 case Expr::ShuffleVectorExprClass: 10818 case Expr::ConvertVectorExprClass: 10819 case Expr::BlockExprClass: 10820 case Expr::NoStmtClass: 10821 case Expr::OpaqueValueExprClass: 10822 case Expr::PackExpansionExprClass: 10823 case Expr::SubstNonTypeTemplateParmPackExprClass: 10824 case Expr::FunctionParmPackExprClass: 10825 case Expr::AsTypeExprClass: 10826 case Expr::ObjCIndirectCopyRestoreExprClass: 10827 case Expr::MaterializeTemporaryExprClass: 10828 case Expr::PseudoObjectExprClass: 10829 case Expr::AtomicExprClass: 10830 case Expr::LambdaExprClass: 10831 case Expr::CXXFoldExprClass: 10832 case Expr::CoawaitExprClass: 10833 case Expr::DependentCoawaitExprClass: 10834 case Expr::CoyieldExprClass: 10835 return ICEDiag(IK_NotICE, E->getLocStart()); 10836 10837 case Expr::InitListExprClass: { 10838 // C++03 [dcl.init]p13: If T is a scalar type, then a declaration of the 10839 // form "T x = { a };" is equivalent to "T x = a;". 10840 // Unless we're initializing a reference, T is a scalar as it is known to be 10841 // of integral or enumeration type. 10842 if (E->isRValue()) 10843 if (cast<InitListExpr>(E)->getNumInits() == 1) 10844 return CheckICE(cast<InitListExpr>(E)->getInit(0), Ctx); 10845 return ICEDiag(IK_NotICE, E->getLocStart()); 10846 } 10847 10848 case Expr::SizeOfPackExprClass: 10849 case Expr::GNUNullExprClass: 10850 // GCC considers the GNU __null value to be an integral constant expression. 10851 return NoDiag(); 10852 10853 case Expr::SubstNonTypeTemplateParmExprClass: 10854 return 10855 CheckICE(cast<SubstNonTypeTemplateParmExpr>(E)->getReplacement(), Ctx); 10856 10857 case Expr::ParenExprClass: 10858 return CheckICE(cast<ParenExpr>(E)->getSubExpr(), Ctx); 10859 case Expr::GenericSelectionExprClass: 10860 return CheckICE(cast<GenericSelectionExpr>(E)->getResultExpr(), Ctx); 10861 case Expr::IntegerLiteralClass: 10862 case Expr::FixedPointLiteralClass: 10863 case Expr::CharacterLiteralClass: 10864 case Expr::ObjCBoolLiteralExprClass: 10865 case Expr::CXXBoolLiteralExprClass: 10866 case Expr::CXXScalarValueInitExprClass: 10867 case Expr::TypeTraitExprClass: 10868 case Expr::ArrayTypeTraitExprClass: 10869 case Expr::ExpressionTraitExprClass: 10870 case Expr::CXXNoexceptExprClass: 10871 return NoDiag(); 10872 case Expr::CallExprClass: 10873 case Expr::CXXOperatorCallExprClass: { 10874 // C99 6.6/3 allows function calls within unevaluated subexpressions of 10875 // constant expressions, but they can never be ICEs because an ICE cannot 10876 // contain an operand of (pointer to) function type. 10877 const CallExpr *CE = cast<CallExpr>(E); 10878 if (CE->getBuiltinCallee()) 10879 return CheckEvalInICE(E, Ctx); 10880 return ICEDiag(IK_NotICE, E->getLocStart()); 10881 } 10882 case Expr::DeclRefExprClass: { 10883 if (isa<EnumConstantDecl>(cast<DeclRefExpr>(E)->getDecl())) 10884 return NoDiag(); 10885 const ValueDecl *D = cast<DeclRefExpr>(E)->getDecl(); 10886 if (Ctx.getLangOpts().CPlusPlus && 10887 D && IsConstNonVolatile(D->getType())) { 10888 // Parameter variables are never constants. Without this check, 10889 // getAnyInitializer() can find a default argument, which leads 10890 // to chaos. 10891 if (isa<ParmVarDecl>(D)) 10892 return ICEDiag(IK_NotICE, cast<DeclRefExpr>(E)->getLocation()); 10893 10894 // C++ 7.1.5.1p2 10895 // A variable of non-volatile const-qualified integral or enumeration 10896 // type initialized by an ICE can be used in ICEs. 10897 if (const VarDecl *Dcl = dyn_cast<VarDecl>(D)) { 10898 if (!Dcl->getType()->isIntegralOrEnumerationType()) 10899 return ICEDiag(IK_NotICE, cast<DeclRefExpr>(E)->getLocation()); 10900 10901 const VarDecl *VD; 10902 // Look for a declaration of this variable that has an initializer, and 10903 // check whether it is an ICE. 10904 if (Dcl->getAnyInitializer(VD) && VD->checkInitIsICE()) 10905 return NoDiag(); 10906 else 10907 return ICEDiag(IK_NotICE, cast<DeclRefExpr>(E)->getLocation()); 10908 } 10909 } 10910 return ICEDiag(IK_NotICE, E->getLocStart()); 10911 } 10912 case Expr::UnaryOperatorClass: { 10913 const UnaryOperator *Exp = cast<UnaryOperator>(E); 10914 switch (Exp->getOpcode()) { 10915 case UO_PostInc: 10916 case UO_PostDec: 10917 case UO_PreInc: 10918 case UO_PreDec: 10919 case UO_AddrOf: 10920 case UO_Deref: 10921 case UO_Coawait: 10922 // C99 6.6/3 allows increment and decrement within unevaluated 10923 // subexpressions of constant expressions, but they can never be ICEs 10924 // because an ICE cannot contain an lvalue operand. 10925 return ICEDiag(IK_NotICE, E->getLocStart()); 10926 case UO_Extension: 10927 case UO_LNot: 10928 case UO_Plus: 10929 case UO_Minus: 10930 case UO_Not: 10931 case UO_Real: 10932 case UO_Imag: 10933 return CheckICE(Exp->getSubExpr(), Ctx); 10934 } 10935 10936 // OffsetOf falls through here. 10937 LLVM_FALLTHROUGH; 10938 } 10939 case Expr::OffsetOfExprClass: { 10940 // Note that per C99, offsetof must be an ICE. And AFAIK, using 10941 // EvaluateAsRValue matches the proposed gcc behavior for cases like 10942 // "offsetof(struct s{int x[4];}, x[1.0])". This doesn't affect 10943 // compliance: we should warn earlier for offsetof expressions with 10944 // array subscripts that aren't ICEs, and if the array subscripts 10945 // are ICEs, the value of the offsetof must be an integer constant. 10946 return CheckEvalInICE(E, Ctx); 10947 } 10948 case Expr::UnaryExprOrTypeTraitExprClass: { 10949 const UnaryExprOrTypeTraitExpr *Exp = cast<UnaryExprOrTypeTraitExpr>(E); 10950 if ((Exp->getKind() == UETT_SizeOf) && 10951 Exp->getTypeOfArgument()->isVariableArrayType()) 10952 return ICEDiag(IK_NotICE, E->getLocStart()); 10953 return NoDiag(); 10954 } 10955 case Expr::BinaryOperatorClass: { 10956 const BinaryOperator *Exp = cast<BinaryOperator>(E); 10957 switch (Exp->getOpcode()) { 10958 case BO_PtrMemD: 10959 case BO_PtrMemI: 10960 case BO_Assign: 10961 case BO_MulAssign: 10962 case BO_DivAssign: 10963 case BO_RemAssign: 10964 case BO_AddAssign: 10965 case BO_SubAssign: 10966 case BO_ShlAssign: 10967 case BO_ShrAssign: 10968 case BO_AndAssign: 10969 case BO_XorAssign: 10970 case BO_OrAssign: 10971 // C99 6.6/3 allows assignments within unevaluated subexpressions of 10972 // constant expressions, but they can never be ICEs because an ICE cannot 10973 // contain an lvalue operand. 10974 return ICEDiag(IK_NotICE, E->getLocStart()); 10975 10976 case BO_Mul: 10977 case BO_Div: 10978 case BO_Rem: 10979 case BO_Add: 10980 case BO_Sub: 10981 case BO_Shl: 10982 case BO_Shr: 10983 case BO_LT: 10984 case BO_GT: 10985 case BO_LE: 10986 case BO_GE: 10987 case BO_EQ: 10988 case BO_NE: 10989 case BO_And: 10990 case BO_Xor: 10991 case BO_Or: 10992 case BO_Comma: 10993 case BO_Cmp: { 10994 ICEDiag LHSResult = CheckICE(Exp->getLHS(), Ctx); 10995 ICEDiag RHSResult = CheckICE(Exp->getRHS(), Ctx); 10996 if (Exp->getOpcode() == BO_Div || 10997 Exp->getOpcode() == BO_Rem) { 10998 // EvaluateAsRValue gives an error for undefined Div/Rem, so make sure 10999 // we don't evaluate one. 11000 if (LHSResult.Kind == IK_ICE && RHSResult.Kind == IK_ICE) { 11001 llvm::APSInt REval = Exp->getRHS()->EvaluateKnownConstInt(Ctx); 11002 if (REval == 0) 11003 return ICEDiag(IK_ICEIfUnevaluated, E->getLocStart()); 11004 if (REval.isSigned() && REval.isAllOnesValue()) { 11005 llvm::APSInt LEval = Exp->getLHS()->EvaluateKnownConstInt(Ctx); 11006 if (LEval.isMinSignedValue()) 11007 return ICEDiag(IK_ICEIfUnevaluated, E->getLocStart()); 11008 } 11009 } 11010 } 11011 if (Exp->getOpcode() == BO_Comma) { 11012 if (Ctx.getLangOpts().C99) { 11013 // C99 6.6p3 introduces a strange edge case: comma can be in an ICE 11014 // if it isn't evaluated. 11015 if (LHSResult.Kind == IK_ICE && RHSResult.Kind == IK_ICE) 11016 return ICEDiag(IK_ICEIfUnevaluated, E->getLocStart()); 11017 } else { 11018 // In both C89 and C++, commas in ICEs are illegal. 11019 return ICEDiag(IK_NotICE, E->getLocStart()); 11020 } 11021 } 11022 return Worst(LHSResult, RHSResult); 11023 } 11024 case BO_LAnd: 11025 case BO_LOr: { 11026 ICEDiag LHSResult = CheckICE(Exp->getLHS(), Ctx); 11027 ICEDiag RHSResult = CheckICE(Exp->getRHS(), Ctx); 11028 if (LHSResult.Kind == IK_ICE && RHSResult.Kind == IK_ICEIfUnevaluated) { 11029 // Rare case where the RHS has a comma "side-effect"; we need 11030 // to actually check the condition to see whether the side 11031 // with the comma is evaluated. 11032 if ((Exp->getOpcode() == BO_LAnd) != 11033 (Exp->getLHS()->EvaluateKnownConstInt(Ctx) == 0)) 11034 return RHSResult; 11035 return NoDiag(); 11036 } 11037 11038 return Worst(LHSResult, RHSResult); 11039 } 11040 } 11041 LLVM_FALLTHROUGH; 11042 } 11043 case Expr::ImplicitCastExprClass: 11044 case Expr::CStyleCastExprClass: 11045 case Expr::CXXFunctionalCastExprClass: 11046 case Expr::CXXStaticCastExprClass: 11047 case Expr::CXXReinterpretCastExprClass: 11048 case Expr::CXXConstCastExprClass: 11049 case Expr::ObjCBridgedCastExprClass: { 11050 const Expr *SubExpr = cast<CastExpr>(E)->getSubExpr(); 11051 if (isa<ExplicitCastExpr>(E)) { 11052 if (const FloatingLiteral *FL 11053 = dyn_cast<FloatingLiteral>(SubExpr->IgnoreParenImpCasts())) { 11054 unsigned DestWidth = Ctx.getIntWidth(E->getType()); 11055 bool DestSigned = E->getType()->isSignedIntegerOrEnumerationType(); 11056 APSInt IgnoredVal(DestWidth, !DestSigned); 11057 bool Ignored; 11058 // If the value does not fit in the destination type, the behavior is 11059 // undefined, so we are not required to treat it as a constant 11060 // expression. 11061 if (FL->getValue().convertToInteger(IgnoredVal, 11062 llvm::APFloat::rmTowardZero, 11063 &Ignored) & APFloat::opInvalidOp) 11064 return ICEDiag(IK_NotICE, E->getLocStart()); 11065 return NoDiag(); 11066 } 11067 } 11068 switch (cast<CastExpr>(E)->getCastKind()) { 11069 case CK_LValueToRValue: 11070 case CK_AtomicToNonAtomic: 11071 case CK_NonAtomicToAtomic: 11072 case CK_NoOp: 11073 case CK_IntegralToBoolean: 11074 case CK_IntegralCast: 11075 return CheckICE(SubExpr, Ctx); 11076 default: 11077 return ICEDiag(IK_NotICE, E->getLocStart()); 11078 } 11079 } 11080 case Expr::BinaryConditionalOperatorClass: { 11081 const BinaryConditionalOperator *Exp = cast<BinaryConditionalOperator>(E); 11082 ICEDiag CommonResult = CheckICE(Exp->getCommon(), Ctx); 11083 if (CommonResult.Kind == IK_NotICE) return CommonResult; 11084 ICEDiag FalseResult = CheckICE(Exp->getFalseExpr(), Ctx); 11085 if (FalseResult.Kind == IK_NotICE) return FalseResult; 11086 if (CommonResult.Kind == IK_ICEIfUnevaluated) return CommonResult; 11087 if (FalseResult.Kind == IK_ICEIfUnevaluated && 11088 Exp->getCommon()->EvaluateKnownConstInt(Ctx) != 0) return NoDiag(); 11089 return FalseResult; 11090 } 11091 case Expr::ConditionalOperatorClass: { 11092 const ConditionalOperator *Exp = cast<ConditionalOperator>(E); 11093 // If the condition (ignoring parens) is a __builtin_constant_p call, 11094 // then only the true side is actually considered in an integer constant 11095 // expression, and it is fully evaluated. This is an important GNU 11096 // extension. See GCC PR38377 for discussion. 11097 if (const CallExpr *CallCE 11098 = dyn_cast<CallExpr>(Exp->getCond()->IgnoreParenCasts())) 11099 if (CallCE->getBuiltinCallee() == Builtin::BI__builtin_constant_p) 11100 return CheckEvalInICE(E, Ctx); 11101 ICEDiag CondResult = CheckICE(Exp->getCond(), Ctx); 11102 if (CondResult.Kind == IK_NotICE) 11103 return CondResult; 11104 11105 ICEDiag TrueResult = CheckICE(Exp->getTrueExpr(), Ctx); 11106 ICEDiag FalseResult = CheckICE(Exp->getFalseExpr(), Ctx); 11107 11108 if (TrueResult.Kind == IK_NotICE) 11109 return TrueResult; 11110 if (FalseResult.Kind == IK_NotICE) 11111 return FalseResult; 11112 if (CondResult.Kind == IK_ICEIfUnevaluated) 11113 return CondResult; 11114 if (TrueResult.Kind == IK_ICE && FalseResult.Kind == IK_ICE) 11115 return NoDiag(); 11116 // Rare case where the diagnostics depend on which side is evaluated 11117 // Note that if we get here, CondResult is 0, and at least one of 11118 // TrueResult and FalseResult is non-zero. 11119 if (Exp->getCond()->EvaluateKnownConstInt(Ctx) == 0) 11120 return FalseResult; 11121 return TrueResult; 11122 } 11123 case Expr::CXXDefaultArgExprClass: 11124 return CheckICE(cast<CXXDefaultArgExpr>(E)->getExpr(), Ctx); 11125 case Expr::CXXDefaultInitExprClass: 11126 return CheckICE(cast<CXXDefaultInitExpr>(E)->getExpr(), Ctx); 11127 case Expr::ChooseExprClass: { 11128 return CheckICE(cast<ChooseExpr>(E)->getChosenSubExpr(), Ctx); 11129 } 11130 } 11131 11132 llvm_unreachable("Invalid StmtClass!"); 11133 } 11134 11135 /// Evaluate an expression as a C++11 integral constant expression. 11136 static bool EvaluateCPlusPlus11IntegralConstantExpr(const ASTContext &Ctx, 11137 const Expr *E, 11138 llvm::APSInt *Value, 11139 SourceLocation *Loc) { 11140 if (!E->getType()->isIntegralOrEnumerationType()) { 11141 if (Loc) *Loc = E->getExprLoc(); 11142 return false; 11143 } 11144 11145 APValue Result; 11146 if (!E->isCXX11ConstantExpr(Ctx, &Result, Loc)) 11147 return false; 11148 11149 if (!Result.isInt()) { 11150 if (Loc) *Loc = E->getExprLoc(); 11151 return false; 11152 } 11153 11154 if (Value) *Value = Result.getInt(); 11155 return true; 11156 } 11157 11158 bool Expr::isIntegerConstantExpr(const ASTContext &Ctx, 11159 SourceLocation *Loc) const { 11160 if (Ctx.getLangOpts().CPlusPlus11) 11161 return EvaluateCPlusPlus11IntegralConstantExpr(Ctx, this, nullptr, Loc); 11162 11163 ICEDiag D = CheckICE(this, Ctx); 11164 if (D.Kind != IK_ICE) { 11165 if (Loc) *Loc = D.Loc; 11166 return false; 11167 } 11168 return true; 11169 } 11170 11171 bool Expr::isIntegerConstantExpr(llvm::APSInt &Value, const ASTContext &Ctx, 11172 SourceLocation *Loc, bool isEvaluated) const { 11173 if (Ctx.getLangOpts().CPlusPlus11) 11174 return EvaluateCPlusPlus11IntegralConstantExpr(Ctx, this, &Value, Loc); 11175 11176 if (!isIntegerConstantExpr(Ctx, Loc)) 11177 return false; 11178 // The only possible side-effects here are due to UB discovered in the 11179 // evaluation (for instance, INT_MAX + 1). In such a case, we are still 11180 // required to treat the expression as an ICE, so we produce the folded 11181 // value. 11182 if (!EvaluateAsInt(Value, Ctx, SE_AllowSideEffects)) 11183 llvm_unreachable("ICE cannot be evaluated!"); 11184 return true; 11185 } 11186 11187 bool Expr::isCXX98IntegralConstantExpr(const ASTContext &Ctx) const { 11188 return CheckICE(this, Ctx).Kind == IK_ICE; 11189 } 11190 11191 bool Expr::isCXX11ConstantExpr(const ASTContext &Ctx, APValue *Result, 11192 SourceLocation *Loc) const { 11193 // We support this checking in C++98 mode in order to diagnose compatibility 11194 // issues. 11195 assert(Ctx.getLangOpts().CPlusPlus); 11196 11197 // Build evaluation settings. 11198 Expr::EvalStatus Status; 11199 SmallVector<PartialDiagnosticAt, 8> Diags; 11200 Status.Diag = &Diags; 11201 EvalInfo Info(Ctx, Status, EvalInfo::EM_ConstantExpression); 11202 11203 APValue Scratch; 11204 bool IsConstExpr = ::EvaluateAsRValue(Info, this, Result ? *Result : Scratch); 11205 11206 if (!Diags.empty()) { 11207 IsConstExpr = false; 11208 if (Loc) *Loc = Diags[0].first; 11209 } else if (!IsConstExpr) { 11210 // FIXME: This shouldn't happen. 11211 if (Loc) *Loc = getExprLoc(); 11212 } 11213 11214 return IsConstExpr; 11215 } 11216 11217 bool Expr::EvaluateWithSubstitution(APValue &Value, ASTContext &Ctx, 11218 const FunctionDecl *Callee, 11219 ArrayRef<const Expr*> Args, 11220 const Expr *This) const { 11221 Expr::EvalStatus Status; 11222 EvalInfo Info(Ctx, Status, EvalInfo::EM_ConstantExpressionUnevaluated); 11223 11224 LValue ThisVal; 11225 const LValue *ThisPtr = nullptr; 11226 if (This) { 11227 #ifndef NDEBUG 11228 auto *MD = dyn_cast<CXXMethodDecl>(Callee); 11229 assert(MD && "Don't provide `this` for non-methods."); 11230 assert(!MD->isStatic() && "Don't provide `this` for static methods."); 11231 #endif 11232 if (EvaluateObjectArgument(Info, This, ThisVal)) 11233 ThisPtr = &ThisVal; 11234 if (Info.EvalStatus.HasSideEffects) 11235 return false; 11236 } 11237 11238 ArgVector ArgValues(Args.size()); 11239 for (ArrayRef<const Expr*>::iterator I = Args.begin(), E = Args.end(); 11240 I != E; ++I) { 11241 if ((*I)->isValueDependent() || 11242 !Evaluate(ArgValues[I - Args.begin()], Info, *I)) 11243 // If evaluation fails, throw away the argument entirely. 11244 ArgValues[I - Args.begin()] = APValue(); 11245 if (Info.EvalStatus.HasSideEffects) 11246 return false; 11247 } 11248 11249 // Build fake call to Callee. 11250 CallStackFrame Frame(Info, Callee->getLocation(), Callee, ThisPtr, 11251 ArgValues.data()); 11252 return Evaluate(Value, Info, this) && !Info.EvalStatus.HasSideEffects; 11253 } 11254 11255 bool Expr::isPotentialConstantExpr(const FunctionDecl *FD, 11256 SmallVectorImpl< 11257 PartialDiagnosticAt> &Diags) { 11258 // FIXME: It would be useful to check constexpr function templates, but at the 11259 // moment the constant expression evaluator cannot cope with the non-rigorous 11260 // ASTs which we build for dependent expressions. 11261 if (FD->isDependentContext()) 11262 return true; 11263 11264 Expr::EvalStatus Status; 11265 Status.Diag = &Diags; 11266 11267 EvalInfo Info(FD->getASTContext(), Status, 11268 EvalInfo::EM_PotentialConstantExpression); 11269 11270 const CXXMethodDecl *MD = dyn_cast<CXXMethodDecl>(FD); 11271 const CXXRecordDecl *RD = MD ? MD->getParent()->getCanonicalDecl() : nullptr; 11272 11273 // Fabricate an arbitrary expression on the stack and pretend that it 11274 // is a temporary being used as the 'this' pointer. 11275 LValue This; 11276 ImplicitValueInitExpr VIE(RD ? Info.Ctx.getRecordType(RD) : Info.Ctx.IntTy); 11277 This.set({&VIE, Info.CurrentCall->Index}); 11278 11279 ArrayRef<const Expr*> Args; 11280 11281 APValue Scratch; 11282 if (const CXXConstructorDecl *CD = dyn_cast<CXXConstructorDecl>(FD)) { 11283 // Evaluate the call as a constant initializer, to allow the construction 11284 // of objects of non-literal types. 11285 Info.setEvaluatingDecl(This.getLValueBase(), Scratch); 11286 HandleConstructorCall(&VIE, This, Args, CD, Info, Scratch); 11287 } else { 11288 SourceLocation Loc = FD->getLocation(); 11289 HandleFunctionCall(Loc, FD, (MD && MD->isInstance()) ? &This : nullptr, 11290 Args, FD->getBody(), Info, Scratch, nullptr); 11291 } 11292 11293 return Diags.empty(); 11294 } 11295 11296 bool Expr::isPotentialConstantExprUnevaluated(Expr *E, 11297 const FunctionDecl *FD, 11298 SmallVectorImpl< 11299 PartialDiagnosticAt> &Diags) { 11300 Expr::EvalStatus Status; 11301 Status.Diag = &Diags; 11302 11303 EvalInfo Info(FD->getASTContext(), Status, 11304 EvalInfo::EM_PotentialConstantExpressionUnevaluated); 11305 11306 // Fabricate a call stack frame to give the arguments a plausible cover story. 11307 ArrayRef<const Expr*> Args; 11308 ArgVector ArgValues(0); 11309 bool Success = EvaluateArgs(Args, ArgValues, Info); 11310 (void)Success; 11311 assert(Success && 11312 "Failed to set up arguments for potential constant evaluation"); 11313 CallStackFrame Frame(Info, SourceLocation(), FD, nullptr, ArgValues.data()); 11314 11315 APValue ResultScratch; 11316 Evaluate(ResultScratch, Info, E); 11317 return Diags.empty(); 11318 } 11319 11320 bool Expr::tryEvaluateObjectSize(uint64_t &Result, ASTContext &Ctx, 11321 unsigned Type) const { 11322 if (!getType()->isPointerType()) 11323 return false; 11324 11325 Expr::EvalStatus Status; 11326 EvalInfo Info(Ctx, Status, EvalInfo::EM_ConstantFold); 11327 return tryEvaluateBuiltinObjectSize(this, Type, Info, Result); 11328 } 11329