xref: /freebsd/contrib/llvm-project/clang/lib/StaticAnalyzer/Checkers/MallocChecker.cpp (revision 4d3fc8b0570b29fb0d6ee9525f104d52176ff0d4)
1 //=== MallocChecker.cpp - A malloc/free checker -------------------*- C++ -*--//
2 //
3 // Part of the LLVM Project, under the Apache License v2.0 with LLVM Exceptions.
4 // See https://llvm.org/LICENSE.txt for license information.
5 // SPDX-License-Identifier: Apache-2.0 WITH LLVM-exception
6 //
7 //===----------------------------------------------------------------------===//
8 //
9 // This file defines a variety of memory management related checkers, such as
10 // leak, double free, and use-after-free.
11 //
12 // The following checkers are defined here:
13 //
14 //   * MallocChecker
15 //       Despite its name, it models all sorts of memory allocations and
16 //       de- or reallocation, including but not limited to malloc, free,
17 //       relloc, new, delete. It also reports on a variety of memory misuse
18 //       errors.
19 //       Many other checkers interact very closely with this checker, in fact,
20 //       most are merely options to this one. Other checkers may register
21 //       MallocChecker, but do not enable MallocChecker's reports (more details
22 //       to follow around its field, ChecksEnabled).
23 //       It also has a boolean "Optimistic" checker option, which if set to true
24 //       will cause the checker to model user defined memory management related
25 //       functions annotated via the attribute ownership_takes, ownership_holds
26 //       and ownership_returns.
27 //
28 //   * NewDeleteChecker
29 //       Enables the modeling of new, new[], delete, delete[] in MallocChecker,
30 //       and checks for related double-free and use-after-free errors.
31 //
32 //   * NewDeleteLeaksChecker
33 //       Checks for leaks related to new, new[], delete, delete[].
34 //       Depends on NewDeleteChecker.
35 //
36 //   * MismatchedDeallocatorChecker
37 //       Enables checking whether memory is deallocated with the correspending
38 //       allocation function in MallocChecker, such as malloc() allocated
39 //       regions are only freed by free(), new by delete, new[] by delete[].
40 //
41 //  InnerPointerChecker interacts very closely with MallocChecker, but unlike
42 //  the above checkers, it has it's own file, hence the many InnerPointerChecker
43 //  related headers and non-static functions.
44 //
45 //===----------------------------------------------------------------------===//
46 
47 #include "AllocationState.h"
48 #include "InterCheckerAPI.h"
49 #include "clang/AST/Attr.h"
50 #include "clang/AST/DeclCXX.h"
51 #include "clang/AST/DeclTemplate.h"
52 #include "clang/AST/Expr.h"
53 #include "clang/AST/ExprCXX.h"
54 #include "clang/AST/ParentMap.h"
55 #include "clang/ASTMatchers/ASTMatchFinder.h"
56 #include "clang/ASTMatchers/ASTMatchers.h"
57 #include "clang/Analysis/ProgramPoint.h"
58 #include "clang/Basic/LLVM.h"
59 #include "clang/Basic/SourceManager.h"
60 #include "clang/Basic/TargetInfo.h"
61 #include "clang/Lex/Lexer.h"
62 #include "clang/StaticAnalyzer/Checkers/BuiltinCheckerRegistration.h"
63 #include "clang/StaticAnalyzer/Core/BugReporter/BugType.h"
64 #include "clang/StaticAnalyzer/Core/BugReporter/CommonBugCategories.h"
65 #include "clang/StaticAnalyzer/Core/Checker.h"
66 #include "clang/StaticAnalyzer/Core/CheckerManager.h"
67 #include "clang/StaticAnalyzer/Core/PathSensitive/CallDescription.h"
68 #include "clang/StaticAnalyzer/Core/PathSensitive/CallEvent.h"
69 #include "clang/StaticAnalyzer/Core/PathSensitive/CheckerContext.h"
70 #include "clang/StaticAnalyzer/Core/PathSensitive/CheckerHelpers.h"
71 #include "clang/StaticAnalyzer/Core/PathSensitive/DynamicExtent.h"
72 #include "clang/StaticAnalyzer/Core/PathSensitive/ExplodedGraph.h"
73 #include "clang/StaticAnalyzer/Core/PathSensitive/ProgramState.h"
74 #include "clang/StaticAnalyzer/Core/PathSensitive/ProgramStateTrait.h"
75 #include "clang/StaticAnalyzer/Core/PathSensitive/ProgramState_Fwd.h"
76 #include "clang/StaticAnalyzer/Core/PathSensitive/SVals.h"
77 #include "clang/StaticAnalyzer/Core/PathSensitive/StoreRef.h"
78 #include "clang/StaticAnalyzer/Core/PathSensitive/SymbolManager.h"
79 #include "llvm/ADT/STLExtras.h"
80 #include "llvm/ADT/SetOperations.h"
81 #include "llvm/ADT/SmallString.h"
82 #include "llvm/ADT/StringExtras.h"
83 #include "llvm/Support/Casting.h"
84 #include "llvm/Support/Compiler.h"
85 #include "llvm/Support/ErrorHandling.h"
86 #include "llvm/Support/raw_ostream.h"
87 #include <climits>
88 #include <functional>
89 #include <utility>
90 
91 using namespace clang;
92 using namespace ento;
93 using namespace std::placeholders;
94 
95 //===----------------------------------------------------------------------===//
96 // The types of allocation we're modeling. This is used to check whether a
97 // dynamically allocated object is deallocated with the correct function, like
98 // not using operator delete on an object created by malloc(), or alloca regions
99 // aren't ever deallocated manually.
100 //===----------------------------------------------------------------------===//
101 
102 namespace {
103 
104 // Used to check correspondence between allocators and deallocators.
105 enum AllocationFamily {
106   AF_None,
107   AF_Malloc,
108   AF_CXXNew,
109   AF_CXXNewArray,
110   AF_IfNameIndex,
111   AF_Alloca,
112   AF_InnerBuffer
113 };
114 
115 } // end of anonymous namespace
116 
117 /// Print names of allocators and deallocators.
118 ///
119 /// \returns true on success.
120 static bool printMemFnName(raw_ostream &os, CheckerContext &C, const Expr *E);
121 
122 /// Print expected name of an allocator based on the deallocator's family
123 /// derived from the DeallocExpr.
124 static void printExpectedAllocName(raw_ostream &os, AllocationFamily Family);
125 
126 /// Print expected name of a deallocator based on the allocator's
127 /// family.
128 static void printExpectedDeallocName(raw_ostream &os, AllocationFamily Family);
129 
130 //===----------------------------------------------------------------------===//
131 // The state of a symbol, in terms of memory management.
132 //===----------------------------------------------------------------------===//
133 
134 namespace {
135 
136 class RefState {
137   enum Kind {
138     // Reference to allocated memory.
139     Allocated,
140     // Reference to zero-allocated memory.
141     AllocatedOfSizeZero,
142     // Reference to released/freed memory.
143     Released,
144     // The responsibility for freeing resources has transferred from
145     // this reference. A relinquished symbol should not be freed.
146     Relinquished,
147     // We are no longer guaranteed to have observed all manipulations
148     // of this pointer/memory. For example, it could have been
149     // passed as a parameter to an opaque function.
150     Escaped
151   };
152 
153   const Stmt *S;
154 
155   Kind K;
156   AllocationFamily Family;
157 
158   RefState(Kind k, const Stmt *s, AllocationFamily family)
159       : S(s), K(k), Family(family) {
160     assert(family != AF_None);
161   }
162 
163 public:
164   bool isAllocated() const { return K == Allocated; }
165   bool isAllocatedOfSizeZero() const { return K == AllocatedOfSizeZero; }
166   bool isReleased() const { return K == Released; }
167   bool isRelinquished() const { return K == Relinquished; }
168   bool isEscaped() const { return K == Escaped; }
169   AllocationFamily getAllocationFamily() const { return Family; }
170   const Stmt *getStmt() const { return S; }
171 
172   bool operator==(const RefState &X) const {
173     return K == X.K && S == X.S && Family == X.Family;
174   }
175 
176   static RefState getAllocated(AllocationFamily family, const Stmt *s) {
177     return RefState(Allocated, s, family);
178   }
179   static RefState getAllocatedOfSizeZero(const RefState *RS) {
180     return RefState(AllocatedOfSizeZero, RS->getStmt(),
181                     RS->getAllocationFamily());
182   }
183   static RefState getReleased(AllocationFamily family, const Stmt *s) {
184     return RefState(Released, s, family);
185   }
186   static RefState getRelinquished(AllocationFamily family, const Stmt *s) {
187     return RefState(Relinquished, s, family);
188   }
189   static RefState getEscaped(const RefState *RS) {
190     return RefState(Escaped, RS->getStmt(), RS->getAllocationFamily());
191   }
192 
193   void Profile(llvm::FoldingSetNodeID &ID) const {
194     ID.AddInteger(K);
195     ID.AddPointer(S);
196     ID.AddInteger(Family);
197   }
198 
199   LLVM_DUMP_METHOD void dump(raw_ostream &OS) const {
200     switch (K) {
201 #define CASE(ID) case ID: OS << #ID; break;
202     CASE(Allocated)
203     CASE(AllocatedOfSizeZero)
204     CASE(Released)
205     CASE(Relinquished)
206     CASE(Escaped)
207     }
208   }
209 
210   LLVM_DUMP_METHOD void dump() const { dump(llvm::errs()); }
211 };
212 
213 } // end of anonymous namespace
214 
215 REGISTER_MAP_WITH_PROGRAMSTATE(RegionState, SymbolRef, RefState)
216 
217 /// Check if the memory associated with this symbol was released.
218 static bool isReleased(SymbolRef Sym, CheckerContext &C);
219 
220 /// Update the RefState to reflect the new memory allocation.
221 /// The optional \p RetVal parameter specifies the newly allocated pointer
222 /// value; if unspecified, the value of expression \p E is used.
223 static ProgramStateRef MallocUpdateRefState(CheckerContext &C, const Expr *E,
224                                             ProgramStateRef State,
225                                             AllocationFamily Family,
226                                             Optional<SVal> RetVal = None);
227 
228 //===----------------------------------------------------------------------===//
229 // The modeling of memory reallocation.
230 //
231 // The terminology 'toPtr' and 'fromPtr' will be used:
232 //   toPtr = realloc(fromPtr, 20);
233 //===----------------------------------------------------------------------===//
234 
235 REGISTER_SET_WITH_PROGRAMSTATE(ReallocSizeZeroSymbols, SymbolRef)
236 
237 namespace {
238 
239 /// The state of 'fromPtr' after reallocation is known to have failed.
240 enum OwnershipAfterReallocKind {
241   // The symbol needs to be freed (e.g.: realloc)
242   OAR_ToBeFreedAfterFailure,
243   // The symbol has been freed (e.g.: reallocf)
244   OAR_FreeOnFailure,
245   // The symbol doesn't have to freed (e.g.: we aren't sure if, how and where
246   // 'fromPtr' was allocated:
247   //    void Haha(int *ptr) {
248   //      ptr = realloc(ptr, 67);
249   //      // ...
250   //    }
251   // ).
252   OAR_DoNotTrackAfterFailure
253 };
254 
255 /// Stores information about the 'fromPtr' symbol after reallocation.
256 ///
257 /// This is important because realloc may fail, and that needs special modeling.
258 /// Whether reallocation failed or not will not be known until later, so we'll
259 /// store whether upon failure 'fromPtr' will be freed, or needs to be freed
260 /// later, etc.
261 struct ReallocPair {
262 
263   // The 'fromPtr'.
264   SymbolRef ReallocatedSym;
265   OwnershipAfterReallocKind Kind;
266 
267   ReallocPair(SymbolRef S, OwnershipAfterReallocKind K)
268       : ReallocatedSym(S), Kind(K) {}
269   void Profile(llvm::FoldingSetNodeID &ID) const {
270     ID.AddInteger(Kind);
271     ID.AddPointer(ReallocatedSym);
272   }
273   bool operator==(const ReallocPair &X) const {
274     return ReallocatedSym == X.ReallocatedSym &&
275            Kind == X.Kind;
276   }
277 };
278 
279 } // end of anonymous namespace
280 
281 REGISTER_MAP_WITH_PROGRAMSTATE(ReallocPairs, SymbolRef, ReallocPair)
282 
283 /// Tells if the callee is one of the builtin new/delete operators, including
284 /// placement operators and other standard overloads.
285 static bool isStandardNewDelete(const FunctionDecl *FD);
286 static bool isStandardNewDelete(const CallEvent &Call) {
287   if (!Call.getDecl() || !isa<FunctionDecl>(Call.getDecl()))
288     return false;
289   return isStandardNewDelete(cast<FunctionDecl>(Call.getDecl()));
290 }
291 
292 //===----------------------------------------------------------------------===//
293 // Definition of the MallocChecker class.
294 //===----------------------------------------------------------------------===//
295 
296 namespace {
297 
298 class MallocChecker
299     : public Checker<check::DeadSymbols, check::PointerEscape,
300                      check::ConstPointerEscape, check::PreStmt<ReturnStmt>,
301                      check::EndFunction, check::PreCall, check::PostCall,
302                      check::NewAllocator, check::PostStmt<BlockExpr>,
303                      check::PostObjCMessage, check::Location, eval::Assume> {
304 public:
305   /// In pessimistic mode, the checker assumes that it does not know which
306   /// functions might free the memory.
307   /// In optimistic mode, the checker assumes that all user-defined functions
308   /// which might free a pointer are annotated.
309   bool ShouldIncludeOwnershipAnnotatedFunctions = false;
310 
311   bool ShouldRegisterNoOwnershipChangeVisitor = false;
312 
313   /// Many checkers are essentially built into this one, so enabling them will
314   /// make MallocChecker perform additional modeling and reporting.
315   enum CheckKind {
316     /// When a subchecker is enabled but MallocChecker isn't, model memory
317     /// management but do not emit warnings emitted with MallocChecker only
318     /// enabled.
319     CK_MallocChecker,
320     CK_NewDeleteChecker,
321     CK_NewDeleteLeaksChecker,
322     CK_MismatchedDeallocatorChecker,
323     CK_InnerPointerChecker,
324     CK_NumCheckKinds
325   };
326 
327   using LeakInfo = std::pair<const ExplodedNode *, const MemRegion *>;
328 
329   bool ChecksEnabled[CK_NumCheckKinds] = {false};
330   CheckerNameRef CheckNames[CK_NumCheckKinds];
331 
332   void checkPreCall(const CallEvent &Call, CheckerContext &C) const;
333   void checkPostCall(const CallEvent &Call, CheckerContext &C) const;
334   void checkNewAllocator(const CXXAllocatorCall &Call, CheckerContext &C) const;
335   void checkPostObjCMessage(const ObjCMethodCall &Call, CheckerContext &C) const;
336   void checkPostStmt(const BlockExpr *BE, CheckerContext &C) const;
337   void checkDeadSymbols(SymbolReaper &SymReaper, CheckerContext &C) const;
338   void checkPreStmt(const ReturnStmt *S, CheckerContext &C) const;
339   void checkEndFunction(const ReturnStmt *S, CheckerContext &C) const;
340   ProgramStateRef evalAssume(ProgramStateRef state, SVal Cond,
341                             bool Assumption) const;
342   void checkLocation(SVal l, bool isLoad, const Stmt *S,
343                      CheckerContext &C) const;
344 
345   ProgramStateRef checkPointerEscape(ProgramStateRef State,
346                                     const InvalidatedSymbols &Escaped,
347                                     const CallEvent *Call,
348                                     PointerEscapeKind Kind) const;
349   ProgramStateRef checkConstPointerEscape(ProgramStateRef State,
350                                           const InvalidatedSymbols &Escaped,
351                                           const CallEvent *Call,
352                                           PointerEscapeKind Kind) const;
353 
354   void printState(raw_ostream &Out, ProgramStateRef State,
355                   const char *NL, const char *Sep) const override;
356 
357 private:
358   mutable std::unique_ptr<BugType> BT_DoubleFree[CK_NumCheckKinds];
359   mutable std::unique_ptr<BugType> BT_DoubleDelete;
360   mutable std::unique_ptr<BugType> BT_Leak[CK_NumCheckKinds];
361   mutable std::unique_ptr<BugType> BT_UseFree[CK_NumCheckKinds];
362   mutable std::unique_ptr<BugType> BT_BadFree[CK_NumCheckKinds];
363   mutable std::unique_ptr<BugType> BT_FreeAlloca[CK_NumCheckKinds];
364   mutable std::unique_ptr<BugType> BT_MismatchedDealloc;
365   mutable std::unique_ptr<BugType> BT_OffsetFree[CK_NumCheckKinds];
366   mutable std::unique_ptr<BugType> BT_UseZerroAllocated[CK_NumCheckKinds];
367 
368 #define CHECK_FN(NAME)                                                         \
369   void NAME(const CallEvent &Call, CheckerContext &C) const;
370 
371   CHECK_FN(checkFree)
372   CHECK_FN(checkIfNameIndex)
373   CHECK_FN(checkBasicAlloc)
374   CHECK_FN(checkKernelMalloc)
375   CHECK_FN(checkCalloc)
376   CHECK_FN(checkAlloca)
377   CHECK_FN(checkStrdup)
378   CHECK_FN(checkIfFreeNameIndex)
379   CHECK_FN(checkCXXNewOrCXXDelete)
380   CHECK_FN(checkGMalloc0)
381   CHECK_FN(checkGMemdup)
382   CHECK_FN(checkGMallocN)
383   CHECK_FN(checkGMallocN0)
384   CHECK_FN(checkReallocN)
385   CHECK_FN(checkOwnershipAttr)
386 
387   void checkRealloc(const CallEvent &Call, CheckerContext &C,
388                     bool ShouldFreeOnFail) const;
389 
390   using CheckFn = std::function<void(const MallocChecker *,
391                                      const CallEvent &Call, CheckerContext &C)>;
392 
393   const CallDescriptionMap<CheckFn> FreeingMemFnMap{
394       {{"free", 1}, &MallocChecker::checkFree},
395       {{"if_freenameindex", 1}, &MallocChecker::checkIfFreeNameIndex},
396       {{"kfree", 1}, &MallocChecker::checkFree},
397       {{"g_free", 1}, &MallocChecker::checkFree},
398   };
399 
400   bool isFreeingCall(const CallEvent &Call) const;
401   static bool isFreeingOwnershipAttrCall(const FunctionDecl *Func);
402 
403   friend class NoOwnershipChangeVisitor;
404 
405   CallDescriptionMap<CheckFn> AllocatingMemFnMap{
406       {{"alloca", 1}, &MallocChecker::checkAlloca},
407       {{"_alloca", 1}, &MallocChecker::checkAlloca},
408       {{"malloc", 1}, &MallocChecker::checkBasicAlloc},
409       {{"malloc", 3}, &MallocChecker::checkKernelMalloc},
410       {{"calloc", 2}, &MallocChecker::checkCalloc},
411       {{"valloc", 1}, &MallocChecker::checkBasicAlloc},
412       {{CDF_MaybeBuiltin, "strndup", 2}, &MallocChecker::checkStrdup},
413       {{CDF_MaybeBuiltin, "strdup", 1}, &MallocChecker::checkStrdup},
414       {{"_strdup", 1}, &MallocChecker::checkStrdup},
415       {{"kmalloc", 2}, &MallocChecker::checkKernelMalloc},
416       {{"if_nameindex", 1}, &MallocChecker::checkIfNameIndex},
417       {{CDF_MaybeBuiltin, "wcsdup", 1}, &MallocChecker::checkStrdup},
418       {{CDF_MaybeBuiltin, "_wcsdup", 1}, &MallocChecker::checkStrdup},
419       {{"g_malloc", 1}, &MallocChecker::checkBasicAlloc},
420       {{"g_malloc0", 1}, &MallocChecker::checkGMalloc0},
421       {{"g_try_malloc", 1}, &MallocChecker::checkBasicAlloc},
422       {{"g_try_malloc0", 1}, &MallocChecker::checkGMalloc0},
423       {{"g_memdup", 2}, &MallocChecker::checkGMemdup},
424       {{"g_malloc_n", 2}, &MallocChecker::checkGMallocN},
425       {{"g_malloc0_n", 2}, &MallocChecker::checkGMallocN0},
426       {{"g_try_malloc_n", 2}, &MallocChecker::checkGMallocN},
427       {{"g_try_malloc0_n", 2}, &MallocChecker::checkGMallocN0},
428   };
429 
430   CallDescriptionMap<CheckFn> ReallocatingMemFnMap{
431       {{"realloc", 2},
432        std::bind(&MallocChecker::checkRealloc, _1, _2, _3, false)},
433       {{"reallocf", 2},
434        std::bind(&MallocChecker::checkRealloc, _1, _2, _3, true)},
435       {{"g_realloc", 2},
436        std::bind(&MallocChecker::checkRealloc, _1, _2, _3, false)},
437       {{"g_try_realloc", 2},
438        std::bind(&MallocChecker::checkRealloc, _1, _2, _3, false)},
439       {{"g_realloc_n", 3}, &MallocChecker::checkReallocN},
440       {{"g_try_realloc_n", 3}, &MallocChecker::checkReallocN},
441   };
442 
443   bool isMemCall(const CallEvent &Call) const;
444 
445   // TODO: Remove mutable by moving the initializtaion to the registry function.
446   mutable Optional<uint64_t> KernelZeroFlagVal;
447 
448   using KernelZeroSizePtrValueTy = Optional<int>;
449   /// Store the value of macro called `ZERO_SIZE_PTR`.
450   /// The value is initialized at first use, before first use the outer
451   /// Optional is empty, afterwards it contains another Optional that indicates
452   /// if the macro value could be determined, and if yes the value itself.
453   mutable Optional<KernelZeroSizePtrValueTy> KernelZeroSizePtrValue;
454 
455   /// Process C++ operator new()'s allocation, which is the part of C++
456   /// new-expression that goes before the constructor.
457   LLVM_NODISCARD
458   ProgramStateRef processNewAllocation(const CXXAllocatorCall &Call,
459                                        CheckerContext &C,
460                                        AllocationFamily Family) const;
461 
462   /// Perform a zero-allocation check.
463   ///
464   /// \param [in] Call The expression that allocates memory.
465   /// \param [in] IndexOfSizeArg Index of the argument that specifies the size
466   ///   of the memory that needs to be allocated. E.g. for malloc, this would be
467   ///   0.
468   /// \param [in] RetVal Specifies the newly allocated pointer value;
469   ///   if unspecified, the value of expression \p E is used.
470   LLVM_NODISCARD
471   static ProgramStateRef ProcessZeroAllocCheck(const CallEvent &Call,
472                                                const unsigned IndexOfSizeArg,
473                                                ProgramStateRef State,
474                                                Optional<SVal> RetVal = None);
475 
476   /// Model functions with the ownership_returns attribute.
477   ///
478   /// User-defined function may have the ownership_returns attribute, which
479   /// annotates that the function returns with an object that was allocated on
480   /// the heap, and passes the ownertship to the callee.
481   ///
482   ///   void __attribute((ownership_returns(malloc, 1))) *my_malloc(size_t);
483   ///
484   /// It has two parameters:
485   ///   - first: name of the resource (e.g. 'malloc')
486   ///   - (OPTIONAL) second: size of the allocated region
487   ///
488   /// \param [in] Call The expression that allocates memory.
489   /// \param [in] Att The ownership_returns attribute.
490   /// \param [in] State The \c ProgramState right before allocation.
491   /// \returns The ProgramState right after allocation.
492   LLVM_NODISCARD
493   ProgramStateRef MallocMemReturnsAttr(CheckerContext &C, const CallEvent &Call,
494                                        const OwnershipAttr *Att,
495                                        ProgramStateRef State) const;
496 
497   /// Models memory allocation.
498   ///
499   /// \param [in] Call The expression that allocates memory.
500   /// \param [in] SizeEx Size of the memory that needs to be allocated.
501   /// \param [in] Init The value the allocated memory needs to be initialized.
502   /// with. For example, \c calloc initializes the allocated memory to 0,
503   /// malloc leaves it undefined.
504   /// \param [in] State The \c ProgramState right before allocation.
505   /// \returns The ProgramState right after allocation.
506   LLVM_NODISCARD
507   static ProgramStateRef MallocMemAux(CheckerContext &C, const CallEvent &Call,
508                                       const Expr *SizeEx, SVal Init,
509                                       ProgramStateRef State,
510                                       AllocationFamily Family);
511 
512   /// Models memory allocation.
513   ///
514   /// \param [in] Call The expression that allocates memory.
515   /// \param [in] Size Size of the memory that needs to be allocated.
516   /// \param [in] Init The value the allocated memory needs to be initialized.
517   /// with. For example, \c calloc initializes the allocated memory to 0,
518   /// malloc leaves it undefined.
519   /// \param [in] State The \c ProgramState right before allocation.
520   /// \returns The ProgramState right after allocation.
521   LLVM_NODISCARD
522   static ProgramStateRef MallocMemAux(CheckerContext &C, const CallEvent &Call,
523                                       SVal Size, SVal Init,
524                                       ProgramStateRef State,
525                                       AllocationFamily Family);
526 
527   // Check if this malloc() for special flags. At present that means M_ZERO or
528   // __GFP_ZERO (in which case, treat it like calloc).
529   LLVM_NODISCARD
530   llvm::Optional<ProgramStateRef>
531   performKernelMalloc(const CallEvent &Call, CheckerContext &C,
532                       const ProgramStateRef &State) const;
533 
534   /// Model functions with the ownership_takes and ownership_holds attributes.
535   ///
536   /// User-defined function may have the ownership_takes and/or ownership_holds
537   /// attributes, which annotates that the function frees the memory passed as a
538   /// parameter.
539   ///
540   ///   void __attribute((ownership_takes(malloc, 1))) my_free(void *);
541   ///   void __attribute((ownership_holds(malloc, 1))) my_hold(void *);
542   ///
543   /// They have two parameters:
544   ///   - first: name of the resource (e.g. 'malloc')
545   ///   - second: index of the parameter the attribute applies to
546   ///
547   /// \param [in] Call The expression that frees memory.
548   /// \param [in] Att The ownership_takes or ownership_holds attribute.
549   /// \param [in] State The \c ProgramState right before allocation.
550   /// \returns The ProgramState right after deallocation.
551   LLVM_NODISCARD
552   ProgramStateRef FreeMemAttr(CheckerContext &C, const CallEvent &Call,
553                               const OwnershipAttr *Att,
554                               ProgramStateRef State) const;
555 
556   /// Models memory deallocation.
557   ///
558   /// \param [in] Call The expression that frees memory.
559   /// \param [in] State The \c ProgramState right before allocation.
560   /// \param [in] Num Index of the argument that needs to be freed. This is
561   ///   normally 0, but for custom free functions it may be different.
562   /// \param [in] Hold Whether the parameter at \p Index has the ownership_holds
563   ///   attribute.
564   /// \param [out] IsKnownToBeAllocated Whether the memory to be freed is known
565   ///   to have been allocated, or in other words, the symbol to be freed was
566   ///   registered as allocated by this checker. In the following case, \c ptr
567   ///   isn't known to be allocated.
568   ///      void Haha(int *ptr) {
569   ///        ptr = realloc(ptr, 67);
570   ///        // ...
571   ///      }
572   /// \param [in] ReturnsNullOnFailure Whether the memory deallocation function
573   ///   we're modeling returns with Null on failure.
574   /// \returns The ProgramState right after deallocation.
575   LLVM_NODISCARD
576   ProgramStateRef FreeMemAux(CheckerContext &C, const CallEvent &Call,
577                              ProgramStateRef State, unsigned Num, bool Hold,
578                              bool &IsKnownToBeAllocated,
579                              AllocationFamily Family,
580                              bool ReturnsNullOnFailure = false) const;
581 
582   /// Models memory deallocation.
583   ///
584   /// \param [in] ArgExpr The variable who's pointee needs to be freed.
585   /// \param [in] Call The expression that frees the memory.
586   /// \param [in] State The \c ProgramState right before allocation.
587   ///   normally 0, but for custom free functions it may be different.
588   /// \param [in] Hold Whether the parameter at \p Index has the ownership_holds
589   ///   attribute.
590   /// \param [out] IsKnownToBeAllocated Whether the memory to be freed is known
591   ///   to have been allocated, or in other words, the symbol to be freed was
592   ///   registered as allocated by this checker. In the following case, \c ptr
593   ///   isn't known to be allocated.
594   ///      void Haha(int *ptr) {
595   ///        ptr = realloc(ptr, 67);
596   ///        // ...
597   ///      }
598   /// \param [in] ReturnsNullOnFailure Whether the memory deallocation function
599   ///   we're modeling returns with Null on failure.
600   /// \returns The ProgramState right after deallocation.
601   LLVM_NODISCARD
602   ProgramStateRef FreeMemAux(CheckerContext &C, const Expr *ArgExpr,
603                              const CallEvent &Call, ProgramStateRef State,
604                              bool Hold, bool &IsKnownToBeAllocated,
605                              AllocationFamily Family,
606                              bool ReturnsNullOnFailure = false) const;
607 
608   // TODO: Needs some refactoring, as all other deallocation modeling
609   // functions are suffering from out parameters and messy code due to how
610   // realloc is handled.
611   //
612   /// Models memory reallocation.
613   ///
614   /// \param [in] Call The expression that reallocated memory
615   /// \param [in] ShouldFreeOnFail Whether if reallocation fails, the supplied
616   ///   memory should be freed.
617   /// \param [in] State The \c ProgramState right before reallocation.
618   /// \param [in] SuffixWithN Whether the reallocation function we're modeling
619   ///   has an '_n' suffix, such as g_realloc_n.
620   /// \returns The ProgramState right after reallocation.
621   LLVM_NODISCARD
622   ProgramStateRef ReallocMemAux(CheckerContext &C, const CallEvent &Call,
623                                 bool ShouldFreeOnFail, ProgramStateRef State,
624                                 AllocationFamily Family,
625                                 bool SuffixWithN = false) const;
626 
627   /// Evaluates the buffer size that needs to be allocated.
628   ///
629   /// \param [in] Blocks The amount of blocks that needs to be allocated.
630   /// \param [in] BlockBytes The size of a block.
631   /// \returns The symbolic value of \p Blocks * \p BlockBytes.
632   LLVM_NODISCARD
633   static SVal evalMulForBufferSize(CheckerContext &C, const Expr *Blocks,
634                                    const Expr *BlockBytes);
635 
636   /// Models zero initialized array allocation.
637   ///
638   /// \param [in] Call The expression that reallocated memory
639   /// \param [in] State The \c ProgramState right before reallocation.
640   /// \returns The ProgramState right after allocation.
641   LLVM_NODISCARD
642   static ProgramStateRef CallocMem(CheckerContext &C, const CallEvent &Call,
643                                    ProgramStateRef State);
644 
645   /// See if deallocation happens in a suspicious context. If so, escape the
646   /// pointers that otherwise would have been deallocated and return true.
647   bool suppressDeallocationsInSuspiciousContexts(const CallEvent &Call,
648                                                  CheckerContext &C) const;
649 
650   /// If in \p S  \p Sym is used, check whether \p Sym was already freed.
651   bool checkUseAfterFree(SymbolRef Sym, CheckerContext &C, const Stmt *S) const;
652 
653   /// If in \p S \p Sym is used, check whether \p Sym was allocated as a zero
654   /// sized memory region.
655   void checkUseZeroAllocated(SymbolRef Sym, CheckerContext &C,
656                              const Stmt *S) const;
657 
658   /// If in \p S \p Sym is being freed, check whether \p Sym was already freed.
659   bool checkDoubleDelete(SymbolRef Sym, CheckerContext &C) const;
660 
661   /// Check if the function is known to free memory, or if it is
662   /// "interesting" and should be modeled explicitly.
663   ///
664   /// \param [out] EscapingSymbol A function might not free memory in general,
665   ///   but could be known to free a particular symbol. In this case, false is
666   ///   returned and the single escaping symbol is returned through the out
667   ///   parameter.
668   ///
669   /// We assume that pointers do not escape through calls to system functions
670   /// not handled by this checker.
671   bool mayFreeAnyEscapedMemoryOrIsModeledExplicitly(const CallEvent *Call,
672                                    ProgramStateRef State,
673                                    SymbolRef &EscapingSymbol) const;
674 
675   /// Implementation of the checkPointerEscape callbacks.
676   LLVM_NODISCARD
677   ProgramStateRef checkPointerEscapeAux(ProgramStateRef State,
678                                         const InvalidatedSymbols &Escaped,
679                                         const CallEvent *Call,
680                                         PointerEscapeKind Kind,
681                                         bool IsConstPointerEscape) const;
682 
683   // Implementation of the checkPreStmt and checkEndFunction callbacks.
684   void checkEscapeOnReturn(const ReturnStmt *S, CheckerContext &C) const;
685 
686   ///@{
687   /// Tells if a given family/call/symbol is tracked by the current checker.
688   /// Sets CheckKind to the kind of the checker responsible for this
689   /// family/call/symbol.
690   Optional<CheckKind> getCheckIfTracked(AllocationFamily Family,
691                                         bool IsALeakCheck = false) const;
692 
693   Optional<CheckKind> getCheckIfTracked(CheckerContext &C, SymbolRef Sym,
694                                         bool IsALeakCheck = false) const;
695   ///@}
696   static bool SummarizeValue(raw_ostream &os, SVal V);
697   static bool SummarizeRegion(raw_ostream &os, const MemRegion *MR);
698 
699   void HandleNonHeapDealloc(CheckerContext &C, SVal ArgVal, SourceRange Range,
700                             const Expr *DeallocExpr,
701                             AllocationFamily Family) const;
702 
703   void HandleFreeAlloca(CheckerContext &C, SVal ArgVal,
704                         SourceRange Range) const;
705 
706   void HandleMismatchedDealloc(CheckerContext &C, SourceRange Range,
707                                const Expr *DeallocExpr, const RefState *RS,
708                                SymbolRef Sym, bool OwnershipTransferred) const;
709 
710   void HandleOffsetFree(CheckerContext &C, SVal ArgVal, SourceRange Range,
711                         const Expr *DeallocExpr, AllocationFamily Family,
712                         const Expr *AllocExpr = nullptr) const;
713 
714   void HandleUseAfterFree(CheckerContext &C, SourceRange Range,
715                           SymbolRef Sym) const;
716 
717   void HandleDoubleFree(CheckerContext &C, SourceRange Range, bool Released,
718                         SymbolRef Sym, SymbolRef PrevSym) const;
719 
720   void HandleDoubleDelete(CheckerContext &C, SymbolRef Sym) const;
721 
722   void HandleUseZeroAlloc(CheckerContext &C, SourceRange Range,
723                           SymbolRef Sym) const;
724 
725   void HandleFunctionPtrFree(CheckerContext &C, SVal ArgVal, SourceRange Range,
726                              const Expr *FreeExpr,
727                              AllocationFamily Family) const;
728 
729   /// Find the location of the allocation for Sym on the path leading to the
730   /// exploded node N.
731   static LeakInfo getAllocationSite(const ExplodedNode *N, SymbolRef Sym,
732                                     CheckerContext &C);
733 
734   void HandleLeak(SymbolRef Sym, ExplodedNode *N, CheckerContext &C) const;
735 
736   /// Test if value in ArgVal equals to value in macro `ZERO_SIZE_PTR`.
737   bool isArgZERO_SIZE_PTR(ProgramStateRef State, CheckerContext &C,
738                           SVal ArgVal) const;
739 };
740 } // end anonymous namespace
741 
742 //===----------------------------------------------------------------------===//
743 // Definition of NoOwnershipChangeVisitor.
744 //===----------------------------------------------------------------------===//
745 
746 namespace {
747 class NoOwnershipChangeVisitor final : public NoStateChangeFuncVisitor {
748   // The symbol whose (lack of) ownership change we are interested in.
749   SymbolRef Sym;
750   const MallocChecker &Checker;
751   using OwnerSet = llvm::SmallPtrSet<const MemRegion *, 8>;
752 
753   // Collect which entities point to the allocated memory, and could be
754   // responsible for deallocating it.
755   class OwnershipBindingsHandler : public StoreManager::BindingsHandler {
756     SymbolRef Sym;
757     OwnerSet &Owners;
758 
759   public:
760     OwnershipBindingsHandler(SymbolRef Sym, OwnerSet &Owners)
761         : Sym(Sym), Owners(Owners) {}
762 
763     bool HandleBinding(StoreManager &SMgr, Store Store, const MemRegion *Region,
764                        SVal Val) override {
765       if (Val.getAsSymbol() == Sym)
766         Owners.insert(Region);
767       return true;
768     }
769 
770     LLVM_DUMP_METHOD void dump() const { dumpToStream(llvm::errs()); }
771     LLVM_DUMP_METHOD void dumpToStream(llvm::raw_ostream &out) const {
772       out << "Owners: {\n";
773       for (const MemRegion *Owner : Owners) {
774         out << "  ";
775         Owner->dumpToStream(out);
776         out << ",\n";
777       }
778       out << "}\n";
779     }
780   };
781 
782 protected:
783   OwnerSet getOwnersAtNode(const ExplodedNode *N) {
784     OwnerSet Ret;
785 
786     ProgramStateRef State = N->getState();
787     OwnershipBindingsHandler Handler{Sym, Ret};
788     State->getStateManager().getStoreManager().iterBindings(State->getStore(),
789                                                             Handler);
790     return Ret;
791   }
792 
793   LLVM_DUMP_METHOD static std::string
794   getFunctionName(const ExplodedNode *CallEnterN) {
795     if (const CallExpr *CE = llvm::dyn_cast_or_null<CallExpr>(
796             CallEnterN->getLocationAs<CallEnter>()->getCallExpr()))
797       if (const FunctionDecl *FD = CE->getDirectCallee())
798         return FD->getQualifiedNameAsString();
799     return "";
800   }
801 
802   /// Syntactically checks whether the callee is a deallocating function. Since
803   /// we have no path-sensitive information on this call (we would need a
804   /// CallEvent instead of a CallExpr for that), its possible that a
805   /// deallocation function was called indirectly through a function pointer,
806   /// but we are not able to tell, so this is a best effort analysis.
807   /// See namespace `memory_passed_to_fn_call_free_through_fn_ptr` in
808   /// clang/test/Analysis/NewDeleteLeaks.cpp.
809   bool isFreeingCallAsWritten(const CallExpr &Call) const {
810     if (Checker.FreeingMemFnMap.lookupAsWritten(Call) ||
811         Checker.ReallocatingMemFnMap.lookupAsWritten(Call))
812       return true;
813 
814     if (const auto *Func =
815             llvm::dyn_cast_or_null<FunctionDecl>(Call.getCalleeDecl()))
816       return MallocChecker::isFreeingOwnershipAttrCall(Func);
817 
818     return false;
819   }
820 
821   /// Heuristically guess whether the callee intended to free memory. This is
822   /// done syntactically, because we are trying to argue about alternative
823   /// paths of execution, and as a consequence we don't have path-sensitive
824   /// information.
825   bool doesFnIntendToHandleOwnership(const Decl *Callee, ASTContext &ACtx) {
826     using namespace clang::ast_matchers;
827     const FunctionDecl *FD = dyn_cast<FunctionDecl>(Callee);
828 
829     // Given that the stack frame was entered, the body should always be
830     // theoretically obtainable. In case of body farms, the synthesized body
831     // is not attached to declaration, thus triggering the '!FD->hasBody()'
832     // branch. That said, would a synthesized body ever intend to handle
833     // ownership? As of today they don't. And if they did, how would we
834     // put notes inside it, given that it doesn't match any source locations?
835     if (!FD || !FD->hasBody())
836       return false;
837 
838     auto Matches = match(findAll(stmt(anyOf(cxxDeleteExpr().bind("delete"),
839                                             callExpr().bind("call")))),
840                          *FD->getBody(), ACtx);
841     for (BoundNodes Match : Matches) {
842       if (Match.getNodeAs<CXXDeleteExpr>("delete"))
843         return true;
844 
845       if (const auto *Call = Match.getNodeAs<CallExpr>("call"))
846         if (isFreeingCallAsWritten(*Call))
847           return true;
848     }
849     // TODO: Ownership might change with an attempt to store the allocated
850     // memory, not only through deallocation. Check for attempted stores as
851     // well.
852     return false;
853   }
854 
855   bool wasModifiedInFunction(const ExplodedNode *CallEnterN,
856                              const ExplodedNode *CallExitEndN) override {
857     if (!doesFnIntendToHandleOwnership(
858             CallExitEndN->getFirstPred()->getLocationContext()->getDecl(),
859             CallExitEndN->getState()->getAnalysisManager().getASTContext()))
860       return true;
861 
862     if (CallEnterN->getState()->get<RegionState>(Sym) !=
863         CallExitEndN->getState()->get<RegionState>(Sym))
864       return true;
865 
866     OwnerSet CurrOwners = getOwnersAtNode(CallEnterN);
867     OwnerSet ExitOwners = getOwnersAtNode(CallExitEndN);
868 
869     // Owners in the current set may be purged from the analyzer later on.
870     // If a variable is dead (is not referenced directly or indirectly after
871     // some point), it will be removed from the Store before the end of its
872     // actual lifetime.
873     // This means that that if the ownership status didn't change, CurrOwners
874     // must be a superset of, but not necessarily equal to ExitOwners.
875     return !llvm::set_is_subset(ExitOwners, CurrOwners);
876   }
877 
878   static PathDiagnosticPieceRef emitNote(const ExplodedNode *N) {
879     PathDiagnosticLocation L = PathDiagnosticLocation::create(
880         N->getLocation(),
881         N->getState()->getStateManager().getContext().getSourceManager());
882     return std::make_shared<PathDiagnosticEventPiece>(
883         L, "Returning without deallocating memory or storing the pointer for "
884            "later deallocation");
885   }
886 
887   PathDiagnosticPieceRef
888   maybeEmitNoteForObjCSelf(PathSensitiveBugReport &R,
889                            const ObjCMethodCall &Call,
890                            const ExplodedNode *N) override {
891     // TODO: Implement.
892     return nullptr;
893   }
894 
895   PathDiagnosticPieceRef
896   maybeEmitNoteForCXXThis(PathSensitiveBugReport &R,
897                           const CXXConstructorCall &Call,
898                           const ExplodedNode *N) override {
899     // TODO: Implement.
900     return nullptr;
901   }
902 
903   PathDiagnosticPieceRef
904   maybeEmitNoteForParameters(PathSensitiveBugReport &R, const CallEvent &Call,
905                              const ExplodedNode *N) override {
906     // TODO: Factor the logic of "what constitutes as an entity being passed
907     // into a function call" out by reusing the code in
908     // NoStoreFuncVisitor::maybeEmitNoteForParameters, maybe by incorporating
909     // the printing technology in UninitializedObject's FieldChainInfo.
910     ArrayRef<ParmVarDecl *> Parameters = Call.parameters();
911     for (unsigned I = 0; I < Call.getNumArgs() && I < Parameters.size(); ++I) {
912       SVal V = Call.getArgSVal(I);
913       if (V.getAsSymbol() == Sym)
914         return emitNote(N);
915     }
916     return nullptr;
917   }
918 
919 public:
920   NoOwnershipChangeVisitor(SymbolRef Sym, const MallocChecker *Checker)
921       : NoStateChangeFuncVisitor(bugreporter::TrackingKind::Thorough), Sym(Sym),
922         Checker(*Checker) {}
923 
924   void Profile(llvm::FoldingSetNodeID &ID) const override {
925     static int Tag = 0;
926     ID.AddPointer(&Tag);
927     ID.AddPointer(Sym);
928   }
929 };
930 
931 } // end anonymous namespace
932 
933 //===----------------------------------------------------------------------===//
934 // Definition of MallocBugVisitor.
935 //===----------------------------------------------------------------------===//
936 
937 namespace {
938 /// The bug visitor which allows us to print extra diagnostics along the
939 /// BugReport path. For example, showing the allocation site of the leaked
940 /// region.
941 class MallocBugVisitor final : public BugReporterVisitor {
942 protected:
943   enum NotificationMode { Normal, ReallocationFailed };
944 
945   // The allocated region symbol tracked by the main analysis.
946   SymbolRef Sym;
947 
948   // The mode we are in, i.e. what kind of diagnostics will be emitted.
949   NotificationMode Mode;
950 
951   // A symbol from when the primary region should have been reallocated.
952   SymbolRef FailedReallocSymbol;
953 
954   // A C++ destructor stack frame in which memory was released. Used for
955   // miscellaneous false positive suppression.
956   const StackFrameContext *ReleaseDestructorLC;
957 
958   bool IsLeak;
959 
960 public:
961   MallocBugVisitor(SymbolRef S, bool isLeak = false)
962       : Sym(S), Mode(Normal), FailedReallocSymbol(nullptr),
963         ReleaseDestructorLC(nullptr), IsLeak(isLeak) {}
964 
965   static void *getTag() {
966     static int Tag = 0;
967     return &Tag;
968   }
969 
970   void Profile(llvm::FoldingSetNodeID &ID) const override {
971     ID.AddPointer(getTag());
972     ID.AddPointer(Sym);
973   }
974 
975   /// Did not track -> allocated. Other state (released) -> allocated.
976   static inline bool isAllocated(const RefState *RSCurr, const RefState *RSPrev,
977                                  const Stmt *Stmt) {
978     return (isa_and_nonnull<CallExpr, CXXNewExpr>(Stmt) &&
979             (RSCurr &&
980              (RSCurr->isAllocated() || RSCurr->isAllocatedOfSizeZero())) &&
981             (!RSPrev ||
982              !(RSPrev->isAllocated() || RSPrev->isAllocatedOfSizeZero())));
983   }
984 
985   /// Did not track -> released. Other state (allocated) -> released.
986   /// The statement associated with the release might be missing.
987   static inline bool isReleased(const RefState *RSCurr, const RefState *RSPrev,
988                                 const Stmt *Stmt) {
989     bool IsReleased =
990         (RSCurr && RSCurr->isReleased()) && (!RSPrev || !RSPrev->isReleased());
991     assert(!IsReleased || (isa_and_nonnull<CallExpr, CXXDeleteExpr>(Stmt)) ||
992            (!Stmt && RSCurr->getAllocationFamily() == AF_InnerBuffer));
993     return IsReleased;
994   }
995 
996   /// Did not track -> relinquished. Other state (allocated) -> relinquished.
997   static inline bool isRelinquished(const RefState *RSCurr,
998                                     const RefState *RSPrev, const Stmt *Stmt) {
999     return (
1000         isa_and_nonnull<CallExpr, ObjCMessageExpr, ObjCPropertyRefExpr>(Stmt) &&
1001         (RSCurr && RSCurr->isRelinquished()) &&
1002         (!RSPrev || !RSPrev->isRelinquished()));
1003   }
1004 
1005   /// If the expression is not a call, and the state change is
1006   /// released -> allocated, it must be the realloc return value
1007   /// check. If we have to handle more cases here, it might be cleaner just
1008   /// to track this extra bit in the state itself.
1009   static inline bool hasReallocFailed(const RefState *RSCurr,
1010                                       const RefState *RSPrev,
1011                                       const Stmt *Stmt) {
1012     return ((!isa_and_nonnull<CallExpr>(Stmt)) &&
1013             (RSCurr &&
1014              (RSCurr->isAllocated() || RSCurr->isAllocatedOfSizeZero())) &&
1015             (RSPrev &&
1016              !(RSPrev->isAllocated() || RSPrev->isAllocatedOfSizeZero())));
1017   }
1018 
1019   PathDiagnosticPieceRef VisitNode(const ExplodedNode *N,
1020                                    BugReporterContext &BRC,
1021                                    PathSensitiveBugReport &BR) override;
1022 
1023   PathDiagnosticPieceRef getEndPath(BugReporterContext &BRC,
1024                                     const ExplodedNode *EndPathNode,
1025                                     PathSensitiveBugReport &BR) override {
1026     if (!IsLeak)
1027       return nullptr;
1028 
1029     PathDiagnosticLocation L = BR.getLocation();
1030     // Do not add the statement itself as a range in case of leak.
1031     return std::make_shared<PathDiagnosticEventPiece>(L, BR.getDescription(),
1032                                                       false);
1033   }
1034 
1035 private:
1036   class StackHintGeneratorForReallocationFailed
1037       : public StackHintGeneratorForSymbol {
1038   public:
1039     StackHintGeneratorForReallocationFailed(SymbolRef S, StringRef M)
1040         : StackHintGeneratorForSymbol(S, M) {}
1041 
1042     std::string getMessageForArg(const Expr *ArgE, unsigned ArgIndex) override {
1043       // Printed parameters start at 1, not 0.
1044       ++ArgIndex;
1045 
1046       SmallString<200> buf;
1047       llvm::raw_svector_ostream os(buf);
1048 
1049       os << "Reallocation of " << ArgIndex << llvm::getOrdinalSuffix(ArgIndex)
1050          << " parameter failed";
1051 
1052       return std::string(os.str());
1053     }
1054 
1055     std::string getMessageForReturn(const CallExpr *CallExpr) override {
1056       return "Reallocation of returned value failed";
1057     }
1058   };
1059 };
1060 } // end anonymous namespace
1061 
1062 // A map from the freed symbol to the symbol representing the return value of
1063 // the free function.
1064 REGISTER_MAP_WITH_PROGRAMSTATE(FreeReturnValue, SymbolRef, SymbolRef)
1065 
1066 namespace {
1067 class StopTrackingCallback final : public SymbolVisitor {
1068   ProgramStateRef state;
1069 
1070 public:
1071   StopTrackingCallback(ProgramStateRef st) : state(std::move(st)) {}
1072   ProgramStateRef getState() const { return state; }
1073 
1074   bool VisitSymbol(SymbolRef sym) override {
1075     state = state->remove<RegionState>(sym);
1076     return true;
1077   }
1078 };
1079 } // end anonymous namespace
1080 
1081 static bool isStandardNewDelete(const FunctionDecl *FD) {
1082   if (!FD)
1083     return false;
1084 
1085   OverloadedOperatorKind Kind = FD->getOverloadedOperator();
1086   if (Kind != OO_New && Kind != OO_Array_New && Kind != OO_Delete &&
1087       Kind != OO_Array_Delete)
1088     return false;
1089 
1090   // This is standard if and only if it's not defined in a user file.
1091   SourceLocation L = FD->getLocation();
1092   // If the header for operator delete is not included, it's still defined
1093   // in an invalid source location. Check to make sure we don't crash.
1094   return !L.isValid() ||
1095          FD->getASTContext().getSourceManager().isInSystemHeader(L);
1096 }
1097 
1098 //===----------------------------------------------------------------------===//
1099 // Methods of MallocChecker and MallocBugVisitor.
1100 //===----------------------------------------------------------------------===//
1101 
1102 bool MallocChecker::isFreeingOwnershipAttrCall(const FunctionDecl *Func) {
1103   if (Func->hasAttrs()) {
1104     for (const auto *I : Func->specific_attrs<OwnershipAttr>()) {
1105       OwnershipAttr::OwnershipKind OwnKind = I->getOwnKind();
1106       if (OwnKind == OwnershipAttr::Takes || OwnKind == OwnershipAttr::Holds)
1107         return true;
1108     }
1109   }
1110   return false;
1111 }
1112 
1113 bool MallocChecker::isFreeingCall(const CallEvent &Call) const {
1114   if (FreeingMemFnMap.lookup(Call) || ReallocatingMemFnMap.lookup(Call))
1115     return true;
1116 
1117   if (const auto *Func = dyn_cast_or_null<FunctionDecl>(Call.getDecl()))
1118     return isFreeingOwnershipAttrCall(Func);
1119 
1120   return false;
1121 }
1122 
1123 bool MallocChecker::isMemCall(const CallEvent &Call) const {
1124   if (FreeingMemFnMap.lookup(Call) || AllocatingMemFnMap.lookup(Call) ||
1125       ReallocatingMemFnMap.lookup(Call))
1126     return true;
1127 
1128   if (!ShouldIncludeOwnershipAnnotatedFunctions)
1129     return false;
1130 
1131   const auto *Func = dyn_cast<FunctionDecl>(Call.getDecl());
1132   return Func && Func->hasAttr<OwnershipAttr>();
1133 }
1134 
1135 llvm::Optional<ProgramStateRef>
1136 MallocChecker::performKernelMalloc(const CallEvent &Call, CheckerContext &C,
1137                                    const ProgramStateRef &State) const {
1138   // 3-argument malloc(), as commonly used in {Free,Net,Open}BSD Kernels:
1139   //
1140   // void *malloc(unsigned long size, struct malloc_type *mtp, int flags);
1141   //
1142   // One of the possible flags is M_ZERO, which means 'give me back an
1143   // allocation which is already zeroed', like calloc.
1144 
1145   // 2-argument kmalloc(), as used in the Linux kernel:
1146   //
1147   // void *kmalloc(size_t size, gfp_t flags);
1148   //
1149   // Has the similar flag value __GFP_ZERO.
1150 
1151   // This logic is largely cloned from O_CREAT in UnixAPIChecker, maybe some
1152   // code could be shared.
1153 
1154   ASTContext &Ctx = C.getASTContext();
1155   llvm::Triple::OSType OS = Ctx.getTargetInfo().getTriple().getOS();
1156 
1157   if (!KernelZeroFlagVal) {
1158     if (OS == llvm::Triple::FreeBSD)
1159       KernelZeroFlagVal = 0x0100;
1160     else if (OS == llvm::Triple::NetBSD)
1161       KernelZeroFlagVal = 0x0002;
1162     else if (OS == llvm::Triple::OpenBSD)
1163       KernelZeroFlagVal = 0x0008;
1164     else if (OS == llvm::Triple::Linux)
1165       // __GFP_ZERO
1166       KernelZeroFlagVal = 0x8000;
1167     else
1168       // FIXME: We need a more general way of getting the M_ZERO value.
1169       // See also: O_CREAT in UnixAPIChecker.cpp.
1170 
1171       // Fall back to normal malloc behavior on platforms where we don't
1172       // know M_ZERO.
1173       return None;
1174   }
1175 
1176   // We treat the last argument as the flags argument, and callers fall-back to
1177   // normal malloc on a None return. This works for the FreeBSD kernel malloc
1178   // as well as Linux kmalloc.
1179   if (Call.getNumArgs() < 2)
1180     return None;
1181 
1182   const Expr *FlagsEx = Call.getArgExpr(Call.getNumArgs() - 1);
1183   const SVal V = C.getSVal(FlagsEx);
1184   if (!isa<NonLoc>(V)) {
1185     // The case where 'V' can be a location can only be due to a bad header,
1186     // so in this case bail out.
1187     return None;
1188   }
1189 
1190   NonLoc Flags = V.castAs<NonLoc>();
1191   NonLoc ZeroFlag =
1192       C.getSValBuilder()
1193           .makeIntVal(KernelZeroFlagVal.value(), FlagsEx->getType())
1194           .castAs<NonLoc>();
1195   SVal MaskedFlagsUC = C.getSValBuilder().evalBinOpNN(State, BO_And,
1196                                                       Flags, ZeroFlag,
1197                                                       FlagsEx->getType());
1198   if (MaskedFlagsUC.isUnknownOrUndef())
1199     return None;
1200   DefinedSVal MaskedFlags = MaskedFlagsUC.castAs<DefinedSVal>();
1201 
1202   // Check if maskedFlags is non-zero.
1203   ProgramStateRef TrueState, FalseState;
1204   std::tie(TrueState, FalseState) = State->assume(MaskedFlags);
1205 
1206   // If M_ZERO is set, treat this like calloc (initialized).
1207   if (TrueState && !FalseState) {
1208     SVal ZeroVal = C.getSValBuilder().makeZeroVal(Ctx.CharTy);
1209     return MallocMemAux(C, Call, Call.getArgExpr(0), ZeroVal, TrueState,
1210                         AF_Malloc);
1211   }
1212 
1213   return None;
1214 }
1215 
1216 SVal MallocChecker::evalMulForBufferSize(CheckerContext &C, const Expr *Blocks,
1217                                          const Expr *BlockBytes) {
1218   SValBuilder &SB = C.getSValBuilder();
1219   SVal BlocksVal = C.getSVal(Blocks);
1220   SVal BlockBytesVal = C.getSVal(BlockBytes);
1221   ProgramStateRef State = C.getState();
1222   SVal TotalSize = SB.evalBinOp(State, BO_Mul, BlocksVal, BlockBytesVal,
1223                                 SB.getContext().getSizeType());
1224   return TotalSize;
1225 }
1226 
1227 void MallocChecker::checkBasicAlloc(const CallEvent &Call,
1228                                     CheckerContext &C) const {
1229   ProgramStateRef State = C.getState();
1230   State = MallocMemAux(C, Call, Call.getArgExpr(0), UndefinedVal(), State,
1231                        AF_Malloc);
1232   State = ProcessZeroAllocCheck(Call, 0, State);
1233   C.addTransition(State);
1234 }
1235 
1236 void MallocChecker::checkKernelMalloc(const CallEvent &Call,
1237                                       CheckerContext &C) const {
1238   ProgramStateRef State = C.getState();
1239   llvm::Optional<ProgramStateRef> MaybeState =
1240       performKernelMalloc(Call, C, State);
1241   if (MaybeState)
1242     State = MaybeState.value();
1243   else
1244     State = MallocMemAux(C, Call, Call.getArgExpr(0), UndefinedVal(), State,
1245                          AF_Malloc);
1246   C.addTransition(State);
1247 }
1248 
1249 static bool isStandardRealloc(const CallEvent &Call) {
1250   const FunctionDecl *FD = dyn_cast<FunctionDecl>(Call.getDecl());
1251   assert(FD);
1252   ASTContext &AC = FD->getASTContext();
1253 
1254   if (isa<CXXMethodDecl>(FD))
1255     return false;
1256 
1257   return FD->getDeclaredReturnType().getDesugaredType(AC) == AC.VoidPtrTy &&
1258          FD->getParamDecl(0)->getType().getDesugaredType(AC) == AC.VoidPtrTy &&
1259          FD->getParamDecl(1)->getType().getDesugaredType(AC) ==
1260              AC.getSizeType();
1261 }
1262 
1263 static bool isGRealloc(const CallEvent &Call) {
1264   const FunctionDecl *FD = dyn_cast<FunctionDecl>(Call.getDecl());
1265   assert(FD);
1266   ASTContext &AC = FD->getASTContext();
1267 
1268   if (isa<CXXMethodDecl>(FD))
1269     return false;
1270 
1271   return FD->getDeclaredReturnType().getDesugaredType(AC) == AC.VoidPtrTy &&
1272          FD->getParamDecl(0)->getType().getDesugaredType(AC) == AC.VoidPtrTy &&
1273          FD->getParamDecl(1)->getType().getDesugaredType(AC) ==
1274              AC.UnsignedLongTy;
1275 }
1276 
1277 void MallocChecker::checkRealloc(const CallEvent &Call, CheckerContext &C,
1278                                  bool ShouldFreeOnFail) const {
1279   // HACK: CallDescription currently recognizes non-standard realloc functions
1280   // as standard because it doesn't check the type, or wether its a non-method
1281   // function. This should be solved by making CallDescription smarter.
1282   // Mind that this came from a bug report, and all other functions suffer from
1283   // this.
1284   // https://bugs.llvm.org/show_bug.cgi?id=46253
1285   if (!isStandardRealloc(Call) && !isGRealloc(Call))
1286     return;
1287   ProgramStateRef State = C.getState();
1288   State = ReallocMemAux(C, Call, ShouldFreeOnFail, State, AF_Malloc);
1289   State = ProcessZeroAllocCheck(Call, 1, State);
1290   C.addTransition(State);
1291 }
1292 
1293 void MallocChecker::checkCalloc(const CallEvent &Call,
1294                                 CheckerContext &C) const {
1295   ProgramStateRef State = C.getState();
1296   State = CallocMem(C, Call, State);
1297   State = ProcessZeroAllocCheck(Call, 0, State);
1298   State = ProcessZeroAllocCheck(Call, 1, State);
1299   C.addTransition(State);
1300 }
1301 
1302 void MallocChecker::checkFree(const CallEvent &Call, CheckerContext &C) const {
1303   ProgramStateRef State = C.getState();
1304   bool IsKnownToBeAllocatedMemory = false;
1305   if (suppressDeallocationsInSuspiciousContexts(Call, C))
1306     return;
1307   State = FreeMemAux(C, Call, State, 0, false, IsKnownToBeAllocatedMemory,
1308                      AF_Malloc);
1309   C.addTransition(State);
1310 }
1311 
1312 void MallocChecker::checkAlloca(const CallEvent &Call,
1313                                 CheckerContext &C) const {
1314   ProgramStateRef State = C.getState();
1315   State = MallocMemAux(C, Call, Call.getArgExpr(0), UndefinedVal(), State,
1316                        AF_Alloca);
1317   State = ProcessZeroAllocCheck(Call, 0, State);
1318   C.addTransition(State);
1319 }
1320 
1321 void MallocChecker::checkStrdup(const CallEvent &Call,
1322                                 CheckerContext &C) const {
1323   ProgramStateRef State = C.getState();
1324   const auto *CE = dyn_cast_or_null<CallExpr>(Call.getOriginExpr());
1325   if (!CE)
1326     return;
1327   State = MallocUpdateRefState(C, CE, State, AF_Malloc);
1328 
1329   C.addTransition(State);
1330 }
1331 
1332 void MallocChecker::checkIfNameIndex(const CallEvent &Call,
1333                                      CheckerContext &C) const {
1334   ProgramStateRef State = C.getState();
1335   // Should we model this differently? We can allocate a fixed number of
1336   // elements with zeros in the last one.
1337   State =
1338       MallocMemAux(C, Call, UnknownVal(), UnknownVal(), State, AF_IfNameIndex);
1339 
1340   C.addTransition(State);
1341 }
1342 
1343 void MallocChecker::checkIfFreeNameIndex(const CallEvent &Call,
1344                                          CheckerContext &C) const {
1345   ProgramStateRef State = C.getState();
1346   bool IsKnownToBeAllocatedMemory = false;
1347   State = FreeMemAux(C, Call, State, 0, false, IsKnownToBeAllocatedMemory,
1348                      AF_IfNameIndex);
1349   C.addTransition(State);
1350 }
1351 
1352 void MallocChecker::checkCXXNewOrCXXDelete(const CallEvent &Call,
1353                                            CheckerContext &C) const {
1354   ProgramStateRef State = C.getState();
1355   bool IsKnownToBeAllocatedMemory = false;
1356   const auto *CE = dyn_cast_or_null<CallExpr>(Call.getOriginExpr());
1357   if (!CE)
1358     return;
1359 
1360   assert(isStandardNewDelete(Call));
1361 
1362   // Process direct calls to operator new/new[]/delete/delete[] functions
1363   // as distinct from new/new[]/delete/delete[] expressions that are
1364   // processed by the checkPostStmt callbacks for CXXNewExpr and
1365   // CXXDeleteExpr.
1366   const FunctionDecl *FD = C.getCalleeDecl(CE);
1367   switch (FD->getOverloadedOperator()) {
1368   case OO_New:
1369     State =
1370         MallocMemAux(C, Call, CE->getArg(0), UndefinedVal(), State, AF_CXXNew);
1371     State = ProcessZeroAllocCheck(Call, 0, State);
1372     break;
1373   case OO_Array_New:
1374     State = MallocMemAux(C, Call, CE->getArg(0), UndefinedVal(), State,
1375                          AF_CXXNewArray);
1376     State = ProcessZeroAllocCheck(Call, 0, State);
1377     break;
1378   case OO_Delete:
1379     State = FreeMemAux(C, Call, State, 0, false, IsKnownToBeAllocatedMemory,
1380                        AF_CXXNew);
1381     break;
1382   case OO_Array_Delete:
1383     State = FreeMemAux(C, Call, State, 0, false, IsKnownToBeAllocatedMemory,
1384                        AF_CXXNewArray);
1385     break;
1386   default:
1387     llvm_unreachable("not a new/delete operator");
1388   }
1389 
1390   C.addTransition(State);
1391 }
1392 
1393 void MallocChecker::checkGMalloc0(const CallEvent &Call,
1394                                   CheckerContext &C) const {
1395   ProgramStateRef State = C.getState();
1396   SValBuilder &svalBuilder = C.getSValBuilder();
1397   SVal zeroVal = svalBuilder.makeZeroVal(svalBuilder.getContext().CharTy);
1398   State = MallocMemAux(C, Call, Call.getArgExpr(0), zeroVal, State, AF_Malloc);
1399   State = ProcessZeroAllocCheck(Call, 0, State);
1400   C.addTransition(State);
1401 }
1402 
1403 void MallocChecker::checkGMemdup(const CallEvent &Call,
1404                                  CheckerContext &C) const {
1405   ProgramStateRef State = C.getState();
1406   State =
1407       MallocMemAux(C, Call, Call.getArgExpr(1), UnknownVal(), State, AF_Malloc);
1408   State = ProcessZeroAllocCheck(Call, 1, State);
1409   C.addTransition(State);
1410 }
1411 
1412 void MallocChecker::checkGMallocN(const CallEvent &Call,
1413                                   CheckerContext &C) const {
1414   ProgramStateRef State = C.getState();
1415   SVal Init = UndefinedVal();
1416   SVal TotalSize = evalMulForBufferSize(C, Call.getArgExpr(0), Call.getArgExpr(1));
1417   State = MallocMemAux(C, Call, TotalSize, Init, State, AF_Malloc);
1418   State = ProcessZeroAllocCheck(Call, 0, State);
1419   State = ProcessZeroAllocCheck(Call, 1, State);
1420   C.addTransition(State);
1421 }
1422 
1423 void MallocChecker::checkGMallocN0(const CallEvent &Call,
1424                                    CheckerContext &C) const {
1425   ProgramStateRef State = C.getState();
1426   SValBuilder &SB = C.getSValBuilder();
1427   SVal Init = SB.makeZeroVal(SB.getContext().CharTy);
1428   SVal TotalSize = evalMulForBufferSize(C, Call.getArgExpr(0), Call.getArgExpr(1));
1429   State = MallocMemAux(C, Call, TotalSize, Init, State, AF_Malloc);
1430   State = ProcessZeroAllocCheck(Call, 0, State);
1431   State = ProcessZeroAllocCheck(Call, 1, State);
1432   C.addTransition(State);
1433 }
1434 
1435 void MallocChecker::checkReallocN(const CallEvent &Call,
1436                                   CheckerContext &C) const {
1437   ProgramStateRef State = C.getState();
1438   State = ReallocMemAux(C, Call, /*ShouldFreeOnFail=*/false, State, AF_Malloc,
1439                         /*SuffixWithN=*/true);
1440   State = ProcessZeroAllocCheck(Call, 1, State);
1441   State = ProcessZeroAllocCheck(Call, 2, State);
1442   C.addTransition(State);
1443 }
1444 
1445 void MallocChecker::checkOwnershipAttr(const CallEvent &Call,
1446                                        CheckerContext &C) const {
1447   ProgramStateRef State = C.getState();
1448   const auto *CE = dyn_cast_or_null<CallExpr>(Call.getOriginExpr());
1449   if (!CE)
1450     return;
1451   const FunctionDecl *FD = C.getCalleeDecl(CE);
1452   if (!FD)
1453     return;
1454   if (ShouldIncludeOwnershipAnnotatedFunctions ||
1455       ChecksEnabled[CK_MismatchedDeallocatorChecker]) {
1456     // Check all the attributes, if there are any.
1457     // There can be multiple of these attributes.
1458     if (FD->hasAttrs())
1459       for (const auto *I : FD->specific_attrs<OwnershipAttr>()) {
1460         switch (I->getOwnKind()) {
1461         case OwnershipAttr::Returns:
1462           State = MallocMemReturnsAttr(C, Call, I, State);
1463           break;
1464         case OwnershipAttr::Takes:
1465         case OwnershipAttr::Holds:
1466           State = FreeMemAttr(C, Call, I, State);
1467           break;
1468         }
1469       }
1470   }
1471   C.addTransition(State);
1472 }
1473 
1474 void MallocChecker::checkPostCall(const CallEvent &Call,
1475                                   CheckerContext &C) const {
1476   if (C.wasInlined)
1477     return;
1478   if (!Call.getOriginExpr())
1479     return;
1480 
1481   ProgramStateRef State = C.getState();
1482 
1483   if (const CheckFn *Callback = FreeingMemFnMap.lookup(Call)) {
1484     (*Callback)(this, Call, C);
1485     return;
1486   }
1487 
1488   if (const CheckFn *Callback = AllocatingMemFnMap.lookup(Call)) {
1489     (*Callback)(this, Call, C);
1490     return;
1491   }
1492 
1493   if (const CheckFn *Callback = ReallocatingMemFnMap.lookup(Call)) {
1494     (*Callback)(this, Call, C);
1495     return;
1496   }
1497 
1498   if (isStandardNewDelete(Call)) {
1499     checkCXXNewOrCXXDelete(Call, C);
1500     return;
1501   }
1502 
1503   checkOwnershipAttr(Call, C);
1504 }
1505 
1506 // Performs a 0-sized allocations check.
1507 ProgramStateRef MallocChecker::ProcessZeroAllocCheck(
1508     const CallEvent &Call, const unsigned IndexOfSizeArg, ProgramStateRef State,
1509     Optional<SVal> RetVal) {
1510   if (!State)
1511     return nullptr;
1512 
1513   if (!RetVal)
1514     RetVal = Call.getReturnValue();
1515 
1516   const Expr *Arg = nullptr;
1517 
1518   if (const CallExpr *CE = dyn_cast<CallExpr>(Call.getOriginExpr())) {
1519     Arg = CE->getArg(IndexOfSizeArg);
1520   } else if (const CXXNewExpr *NE =
1521                  dyn_cast<CXXNewExpr>(Call.getOriginExpr())) {
1522     if (NE->isArray()) {
1523       Arg = *NE->getArraySize();
1524     } else {
1525       return State;
1526     }
1527   } else
1528     llvm_unreachable("not a CallExpr or CXXNewExpr");
1529 
1530   assert(Arg);
1531 
1532   auto DefArgVal =
1533       State->getSVal(Arg, Call.getLocationContext()).getAs<DefinedSVal>();
1534 
1535   if (!DefArgVal)
1536     return State;
1537 
1538   // Check if the allocation size is 0.
1539   ProgramStateRef TrueState, FalseState;
1540   SValBuilder &SvalBuilder = State->getStateManager().getSValBuilder();
1541   DefinedSVal Zero =
1542       SvalBuilder.makeZeroVal(Arg->getType()).castAs<DefinedSVal>();
1543 
1544   std::tie(TrueState, FalseState) =
1545       State->assume(SvalBuilder.evalEQ(State, *DefArgVal, Zero));
1546 
1547   if (TrueState && !FalseState) {
1548     SymbolRef Sym = RetVal->getAsLocSymbol();
1549     if (!Sym)
1550       return State;
1551 
1552     const RefState *RS = State->get<RegionState>(Sym);
1553     if (RS) {
1554       if (RS->isAllocated())
1555         return TrueState->set<RegionState>(Sym,
1556                                           RefState::getAllocatedOfSizeZero(RS));
1557       else
1558         return State;
1559     } else {
1560       // Case of zero-size realloc. Historically 'realloc(ptr, 0)' is treated as
1561       // 'free(ptr)' and the returned value from 'realloc(ptr, 0)' is not
1562       // tracked. Add zero-reallocated Sym to the state to catch references
1563       // to zero-allocated memory.
1564       return TrueState->add<ReallocSizeZeroSymbols>(Sym);
1565     }
1566   }
1567 
1568   // Assume the value is non-zero going forward.
1569   assert(FalseState);
1570   return FalseState;
1571 }
1572 
1573 static QualType getDeepPointeeType(QualType T) {
1574   QualType Result = T, PointeeType = T->getPointeeType();
1575   while (!PointeeType.isNull()) {
1576     Result = PointeeType;
1577     PointeeType = PointeeType->getPointeeType();
1578   }
1579   return Result;
1580 }
1581 
1582 /// \returns true if the constructor invoked by \p NE has an argument of a
1583 /// pointer/reference to a record type.
1584 static bool hasNonTrivialConstructorCall(const CXXNewExpr *NE) {
1585 
1586   const CXXConstructExpr *ConstructE = NE->getConstructExpr();
1587   if (!ConstructE)
1588     return false;
1589 
1590   if (!NE->getAllocatedType()->getAsCXXRecordDecl())
1591     return false;
1592 
1593   const CXXConstructorDecl *CtorD = ConstructE->getConstructor();
1594 
1595   // Iterate over the constructor parameters.
1596   for (const auto *CtorParam : CtorD->parameters()) {
1597 
1598     QualType CtorParamPointeeT = CtorParam->getType()->getPointeeType();
1599     if (CtorParamPointeeT.isNull())
1600       continue;
1601 
1602     CtorParamPointeeT = getDeepPointeeType(CtorParamPointeeT);
1603 
1604     if (CtorParamPointeeT->getAsCXXRecordDecl())
1605       return true;
1606   }
1607 
1608   return false;
1609 }
1610 
1611 ProgramStateRef
1612 MallocChecker::processNewAllocation(const CXXAllocatorCall &Call,
1613                                     CheckerContext &C,
1614                                     AllocationFamily Family) const {
1615   if (!isStandardNewDelete(Call))
1616     return nullptr;
1617 
1618   const CXXNewExpr *NE = Call.getOriginExpr();
1619   const ParentMap &PM = C.getLocationContext()->getParentMap();
1620   ProgramStateRef State = C.getState();
1621 
1622   // Non-trivial constructors have a chance to escape 'this', but marking all
1623   // invocations of trivial constructors as escaped would cause too great of
1624   // reduction of true positives, so let's just do that for constructors that
1625   // have an argument of a pointer-to-record type.
1626   if (!PM.isConsumedExpr(NE) && hasNonTrivialConstructorCall(NE))
1627     return State;
1628 
1629   // The return value from operator new is bound to a specified initialization
1630   // value (if any) and we don't want to loose this value. So we call
1631   // MallocUpdateRefState() instead of MallocMemAux() which breaks the
1632   // existing binding.
1633   SVal Target = Call.getObjectUnderConstruction();
1634   State = MallocUpdateRefState(C, NE, State, Family, Target);
1635   State = ProcessZeroAllocCheck(Call, 0, State, Target);
1636   return State;
1637 }
1638 
1639 void MallocChecker::checkNewAllocator(const CXXAllocatorCall &Call,
1640                                       CheckerContext &C) const {
1641   if (!C.wasInlined) {
1642     ProgramStateRef State = processNewAllocation(
1643         Call, C,
1644         (Call.getOriginExpr()->isArray() ? AF_CXXNewArray : AF_CXXNew));
1645     C.addTransition(State);
1646   }
1647 }
1648 
1649 static bool isKnownDeallocObjCMethodName(const ObjCMethodCall &Call) {
1650   // If the first selector piece is one of the names below, assume that the
1651   // object takes ownership of the memory, promising to eventually deallocate it
1652   // with free().
1653   // Ex:  [NSData dataWithBytesNoCopy:bytes length:10];
1654   // (...unless a 'freeWhenDone' parameter is false, but that's checked later.)
1655   StringRef FirstSlot = Call.getSelector().getNameForSlot(0);
1656   return FirstSlot == "dataWithBytesNoCopy" ||
1657          FirstSlot == "initWithBytesNoCopy" ||
1658          FirstSlot == "initWithCharactersNoCopy";
1659 }
1660 
1661 static Optional<bool> getFreeWhenDoneArg(const ObjCMethodCall &Call) {
1662   Selector S = Call.getSelector();
1663 
1664   // FIXME: We should not rely on fully-constrained symbols being folded.
1665   for (unsigned i = 1; i < S.getNumArgs(); ++i)
1666     if (S.getNameForSlot(i).equals("freeWhenDone"))
1667       return !Call.getArgSVal(i).isZeroConstant();
1668 
1669   return None;
1670 }
1671 
1672 void MallocChecker::checkPostObjCMessage(const ObjCMethodCall &Call,
1673                                          CheckerContext &C) const {
1674   if (C.wasInlined)
1675     return;
1676 
1677   if (!isKnownDeallocObjCMethodName(Call))
1678     return;
1679 
1680   if (Optional<bool> FreeWhenDone = getFreeWhenDoneArg(Call))
1681     if (!*FreeWhenDone)
1682       return;
1683 
1684   if (Call.hasNonZeroCallbackArg())
1685     return;
1686 
1687   bool IsKnownToBeAllocatedMemory;
1688   ProgramStateRef State =
1689       FreeMemAux(C, Call.getArgExpr(0), Call, C.getState(),
1690                  /*Hold=*/true, IsKnownToBeAllocatedMemory, AF_Malloc,
1691                  /*ReturnsNullOnFailure=*/true);
1692 
1693   C.addTransition(State);
1694 }
1695 
1696 ProgramStateRef
1697 MallocChecker::MallocMemReturnsAttr(CheckerContext &C, const CallEvent &Call,
1698                                     const OwnershipAttr *Att,
1699                                     ProgramStateRef State) const {
1700   if (!State)
1701     return nullptr;
1702 
1703   if (Att->getModule()->getName() != "malloc")
1704     return nullptr;
1705 
1706   OwnershipAttr::args_iterator I = Att->args_begin(), E = Att->args_end();
1707   if (I != E) {
1708     return MallocMemAux(C, Call, Call.getArgExpr(I->getASTIndex()),
1709                         UndefinedVal(), State, AF_Malloc);
1710   }
1711   return MallocMemAux(C, Call, UnknownVal(), UndefinedVal(), State, AF_Malloc);
1712 }
1713 
1714 ProgramStateRef MallocChecker::MallocMemAux(CheckerContext &C,
1715                                             const CallEvent &Call,
1716                                             const Expr *SizeEx, SVal Init,
1717                                             ProgramStateRef State,
1718                                             AllocationFamily Family) {
1719   if (!State)
1720     return nullptr;
1721 
1722   assert(SizeEx);
1723   return MallocMemAux(C, Call, C.getSVal(SizeEx), Init, State, Family);
1724 }
1725 
1726 ProgramStateRef MallocChecker::MallocMemAux(CheckerContext &C,
1727                                             const CallEvent &Call, SVal Size,
1728                                             SVal Init, ProgramStateRef State,
1729                                             AllocationFamily Family) {
1730   if (!State)
1731     return nullptr;
1732 
1733   const Expr *CE = Call.getOriginExpr();
1734 
1735   // We expect the malloc functions to return a pointer.
1736   if (!Loc::isLocType(CE->getType()))
1737     return nullptr;
1738 
1739   // Bind the return value to the symbolic value from the heap region.
1740   // TODO: We could rewrite post visit to eval call; 'malloc' does not have
1741   // side effects other than what we model here.
1742   unsigned Count = C.blockCount();
1743   SValBuilder &svalBuilder = C.getSValBuilder();
1744   const LocationContext *LCtx = C.getPredecessor()->getLocationContext();
1745   DefinedSVal RetVal = svalBuilder.getConjuredHeapSymbolVal(CE, LCtx, Count)
1746       .castAs<DefinedSVal>();
1747   State = State->BindExpr(CE, C.getLocationContext(), RetVal);
1748 
1749   // Fill the region with the initialization value.
1750   State = State->bindDefaultInitial(RetVal, Init, LCtx);
1751 
1752   // Set the region's extent.
1753   State = setDynamicExtent(State, RetVal.getAsRegion(),
1754                            Size.castAs<DefinedOrUnknownSVal>(), svalBuilder);
1755 
1756   return MallocUpdateRefState(C, CE, State, Family);
1757 }
1758 
1759 static ProgramStateRef MallocUpdateRefState(CheckerContext &C, const Expr *E,
1760                                             ProgramStateRef State,
1761                                             AllocationFamily Family,
1762                                             Optional<SVal> RetVal) {
1763   if (!State)
1764     return nullptr;
1765 
1766   // Get the return value.
1767   if (!RetVal)
1768     RetVal = C.getSVal(E);
1769 
1770   // We expect the malloc functions to return a pointer.
1771   if (!RetVal->getAs<Loc>())
1772     return nullptr;
1773 
1774   SymbolRef Sym = RetVal->getAsLocSymbol();
1775   // This is a return value of a function that was not inlined, such as malloc()
1776   // or new(). We've checked that in the caller. Therefore, it must be a symbol.
1777   assert(Sym);
1778 
1779   // Set the symbol's state to Allocated.
1780   return State->set<RegionState>(Sym, RefState::getAllocated(Family, E));
1781 }
1782 
1783 ProgramStateRef MallocChecker::FreeMemAttr(CheckerContext &C,
1784                                            const CallEvent &Call,
1785                                            const OwnershipAttr *Att,
1786                                            ProgramStateRef State) const {
1787   if (!State)
1788     return nullptr;
1789 
1790   if (Att->getModule()->getName() != "malloc")
1791     return nullptr;
1792 
1793   bool IsKnownToBeAllocated = false;
1794 
1795   for (const auto &Arg : Att->args()) {
1796     ProgramStateRef StateI =
1797         FreeMemAux(C, Call, State, Arg.getASTIndex(),
1798                    Att->getOwnKind() == OwnershipAttr::Holds,
1799                    IsKnownToBeAllocated, AF_Malloc);
1800     if (StateI)
1801       State = StateI;
1802   }
1803   return State;
1804 }
1805 
1806 ProgramStateRef MallocChecker::FreeMemAux(CheckerContext &C,
1807                                           const CallEvent &Call,
1808                                           ProgramStateRef State, unsigned Num,
1809                                           bool Hold, bool &IsKnownToBeAllocated,
1810                                           AllocationFamily Family,
1811                                           bool ReturnsNullOnFailure) const {
1812   if (!State)
1813     return nullptr;
1814 
1815   if (Call.getNumArgs() < (Num + 1))
1816     return nullptr;
1817 
1818   return FreeMemAux(C, Call.getArgExpr(Num), Call, State, Hold,
1819                     IsKnownToBeAllocated, Family, ReturnsNullOnFailure);
1820 }
1821 
1822 /// Checks if the previous call to free on the given symbol failed - if free
1823 /// failed, returns true. Also, returns the corresponding return value symbol.
1824 static bool didPreviousFreeFail(ProgramStateRef State,
1825                                 SymbolRef Sym, SymbolRef &RetStatusSymbol) {
1826   const SymbolRef *Ret = State->get<FreeReturnValue>(Sym);
1827   if (Ret) {
1828     assert(*Ret && "We should not store the null return symbol");
1829     ConstraintManager &CMgr = State->getConstraintManager();
1830     ConditionTruthVal FreeFailed = CMgr.isNull(State, *Ret);
1831     RetStatusSymbol = *Ret;
1832     return FreeFailed.isConstrainedTrue();
1833   }
1834   return false;
1835 }
1836 
1837 static bool printMemFnName(raw_ostream &os, CheckerContext &C, const Expr *E) {
1838   if (const CallExpr *CE = dyn_cast<CallExpr>(E)) {
1839     // FIXME: This doesn't handle indirect calls.
1840     const FunctionDecl *FD = CE->getDirectCallee();
1841     if (!FD)
1842       return false;
1843 
1844     os << *FD;
1845     if (!FD->isOverloadedOperator())
1846       os << "()";
1847     return true;
1848   }
1849 
1850   if (const ObjCMessageExpr *Msg = dyn_cast<ObjCMessageExpr>(E)) {
1851     if (Msg->isInstanceMessage())
1852       os << "-";
1853     else
1854       os << "+";
1855     Msg->getSelector().print(os);
1856     return true;
1857   }
1858 
1859   if (const CXXNewExpr *NE = dyn_cast<CXXNewExpr>(E)) {
1860     os << "'"
1861        << getOperatorSpelling(NE->getOperatorNew()->getOverloadedOperator())
1862        << "'";
1863     return true;
1864   }
1865 
1866   if (const CXXDeleteExpr *DE = dyn_cast<CXXDeleteExpr>(E)) {
1867     os << "'"
1868        << getOperatorSpelling(DE->getOperatorDelete()->getOverloadedOperator())
1869        << "'";
1870     return true;
1871   }
1872 
1873   return false;
1874 }
1875 
1876 static void printExpectedAllocName(raw_ostream &os, AllocationFamily Family) {
1877 
1878   switch(Family) {
1879     case AF_Malloc: os << "malloc()"; return;
1880     case AF_CXXNew: os << "'new'"; return;
1881     case AF_CXXNewArray: os << "'new[]'"; return;
1882     case AF_IfNameIndex: os << "'if_nameindex()'"; return;
1883     case AF_InnerBuffer: os << "container-specific allocator"; return;
1884     case AF_Alloca:
1885     case AF_None: llvm_unreachable("not a deallocation expression");
1886   }
1887 }
1888 
1889 static void printExpectedDeallocName(raw_ostream &os, AllocationFamily Family) {
1890   switch(Family) {
1891     case AF_Malloc: os << "free()"; return;
1892     case AF_CXXNew: os << "'delete'"; return;
1893     case AF_CXXNewArray: os << "'delete[]'"; return;
1894     case AF_IfNameIndex: os << "'if_freenameindex()'"; return;
1895     case AF_InnerBuffer: os << "container-specific deallocator"; return;
1896     case AF_Alloca:
1897     case AF_None: llvm_unreachable("suspicious argument");
1898   }
1899 }
1900 
1901 ProgramStateRef MallocChecker::FreeMemAux(
1902     CheckerContext &C, const Expr *ArgExpr, const CallEvent &Call,
1903     ProgramStateRef State, bool Hold, bool &IsKnownToBeAllocated,
1904     AllocationFamily Family, bool ReturnsNullOnFailure) const {
1905 
1906   if (!State)
1907     return nullptr;
1908 
1909   SVal ArgVal = C.getSVal(ArgExpr);
1910   if (!isa<DefinedOrUnknownSVal>(ArgVal))
1911     return nullptr;
1912   DefinedOrUnknownSVal location = ArgVal.castAs<DefinedOrUnknownSVal>();
1913 
1914   // Check for null dereferences.
1915   if (!isa<Loc>(location))
1916     return nullptr;
1917 
1918   // The explicit NULL case, no operation is performed.
1919   ProgramStateRef notNullState, nullState;
1920   std::tie(notNullState, nullState) = State->assume(location);
1921   if (nullState && !notNullState)
1922     return nullptr;
1923 
1924   // Unknown values could easily be okay
1925   // Undefined values are handled elsewhere
1926   if (ArgVal.isUnknownOrUndef())
1927     return nullptr;
1928 
1929   const MemRegion *R = ArgVal.getAsRegion();
1930   const Expr *ParentExpr = Call.getOriginExpr();
1931 
1932   // NOTE: We detected a bug, but the checker under whose name we would emit the
1933   // error could be disabled. Generally speaking, the MallocChecker family is an
1934   // integral part of the Static Analyzer, and disabling any part of it should
1935   // only be done under exceptional circumstances, such as frequent false
1936   // positives. If this is the case, we can reasonably believe that there are
1937   // serious faults in our understanding of the source code, and even if we
1938   // don't emit an warning, we should terminate further analysis with a sink
1939   // node.
1940 
1941   // Nonlocs can't be freed, of course.
1942   // Non-region locations (labels and fixed addresses) also shouldn't be freed.
1943   if (!R) {
1944     // Exception:
1945     // If the macro ZERO_SIZE_PTR is defined, this could be a kernel source
1946     // code. In that case, the ZERO_SIZE_PTR defines a special value used for a
1947     // zero-sized memory block which is allowed to be freed, despite not being a
1948     // null pointer.
1949     if (Family != AF_Malloc || !isArgZERO_SIZE_PTR(State, C, ArgVal))
1950       HandleNonHeapDealloc(C, ArgVal, ArgExpr->getSourceRange(), ParentExpr,
1951                            Family);
1952     return nullptr;
1953   }
1954 
1955   R = R->StripCasts();
1956 
1957   // Blocks might show up as heap data, but should not be free()d
1958   if (isa<BlockDataRegion>(R)) {
1959     HandleNonHeapDealloc(C, ArgVal, ArgExpr->getSourceRange(), ParentExpr,
1960                          Family);
1961     return nullptr;
1962   }
1963 
1964   const MemSpaceRegion *MS = R->getMemorySpace();
1965 
1966   // Parameters, locals, statics, globals, and memory returned by
1967   // __builtin_alloca() shouldn't be freed.
1968   if (!isa<UnknownSpaceRegion, HeapSpaceRegion>(MS)) {
1969     // FIXME: at the time this code was written, malloc() regions were
1970     // represented by conjured symbols, which are all in UnknownSpaceRegion.
1971     // This means that there isn't actually anything from HeapSpaceRegion
1972     // that should be freed, even though we allow it here.
1973     // Of course, free() can work on memory allocated outside the current
1974     // function, so UnknownSpaceRegion is always a possibility.
1975     // False negatives are better than false positives.
1976 
1977     if (isa<AllocaRegion>(R))
1978       HandleFreeAlloca(C, ArgVal, ArgExpr->getSourceRange());
1979     else
1980       HandleNonHeapDealloc(C, ArgVal, ArgExpr->getSourceRange(), ParentExpr,
1981                            Family);
1982 
1983     return nullptr;
1984   }
1985 
1986   const SymbolicRegion *SrBase = dyn_cast<SymbolicRegion>(R->getBaseRegion());
1987   // Various cases could lead to non-symbol values here.
1988   // For now, ignore them.
1989   if (!SrBase)
1990     return nullptr;
1991 
1992   SymbolRef SymBase = SrBase->getSymbol();
1993   const RefState *RsBase = State->get<RegionState>(SymBase);
1994   SymbolRef PreviousRetStatusSymbol = nullptr;
1995 
1996   IsKnownToBeAllocated =
1997       RsBase && (RsBase->isAllocated() || RsBase->isAllocatedOfSizeZero());
1998 
1999   if (RsBase) {
2000 
2001     // Memory returned by alloca() shouldn't be freed.
2002     if (RsBase->getAllocationFamily() == AF_Alloca) {
2003       HandleFreeAlloca(C, ArgVal, ArgExpr->getSourceRange());
2004       return nullptr;
2005     }
2006 
2007     // Check for double free first.
2008     if ((RsBase->isReleased() || RsBase->isRelinquished()) &&
2009         !didPreviousFreeFail(State, SymBase, PreviousRetStatusSymbol)) {
2010       HandleDoubleFree(C, ParentExpr->getSourceRange(), RsBase->isReleased(),
2011                        SymBase, PreviousRetStatusSymbol);
2012       return nullptr;
2013 
2014     // If the pointer is allocated or escaped, but we are now trying to free it,
2015     // check that the call to free is proper.
2016     } else if (RsBase->isAllocated() || RsBase->isAllocatedOfSizeZero() ||
2017                RsBase->isEscaped()) {
2018 
2019       // Check if an expected deallocation function matches the real one.
2020       bool DeallocMatchesAlloc = RsBase->getAllocationFamily() == Family;
2021       if (!DeallocMatchesAlloc) {
2022         HandleMismatchedDealloc(C, ArgExpr->getSourceRange(), ParentExpr,
2023                                 RsBase, SymBase, Hold);
2024         return nullptr;
2025       }
2026 
2027       // Check if the memory location being freed is the actual location
2028       // allocated, or an offset.
2029       RegionOffset Offset = R->getAsOffset();
2030       if (Offset.isValid() &&
2031           !Offset.hasSymbolicOffset() &&
2032           Offset.getOffset() != 0) {
2033         const Expr *AllocExpr = cast<Expr>(RsBase->getStmt());
2034         HandleOffsetFree(C, ArgVal, ArgExpr->getSourceRange(), ParentExpr,
2035                          Family, AllocExpr);
2036         return nullptr;
2037       }
2038     }
2039   }
2040 
2041   if (SymBase->getType()->isFunctionPointerType()) {
2042     HandleFunctionPtrFree(C, ArgVal, ArgExpr->getSourceRange(), ParentExpr,
2043                           Family);
2044     return nullptr;
2045   }
2046 
2047   // Clean out the info on previous call to free return info.
2048   State = State->remove<FreeReturnValue>(SymBase);
2049 
2050   // Keep track of the return value. If it is NULL, we will know that free
2051   // failed.
2052   if (ReturnsNullOnFailure) {
2053     SVal RetVal = C.getSVal(ParentExpr);
2054     SymbolRef RetStatusSymbol = RetVal.getAsSymbol();
2055     if (RetStatusSymbol) {
2056       C.getSymbolManager().addSymbolDependency(SymBase, RetStatusSymbol);
2057       State = State->set<FreeReturnValue>(SymBase, RetStatusSymbol);
2058     }
2059   }
2060 
2061   // If we don't know anything about this symbol, a free on it may be totally
2062   // valid. If this is the case, lets assume that the allocation family of the
2063   // freeing function is the same as the symbols allocation family, and go with
2064   // that.
2065   assert(!RsBase || (RsBase && RsBase->getAllocationFamily() == Family));
2066 
2067   // Normal free.
2068   if (Hold)
2069     return State->set<RegionState>(SymBase,
2070                                    RefState::getRelinquished(Family,
2071                                                              ParentExpr));
2072 
2073   return State->set<RegionState>(SymBase,
2074                                  RefState::getReleased(Family, ParentExpr));
2075 }
2076 
2077 Optional<MallocChecker::CheckKind>
2078 MallocChecker::getCheckIfTracked(AllocationFamily Family,
2079                                  bool IsALeakCheck) const {
2080   switch (Family) {
2081   case AF_Malloc:
2082   case AF_Alloca:
2083   case AF_IfNameIndex: {
2084     if (ChecksEnabled[CK_MallocChecker])
2085       return CK_MallocChecker;
2086     return None;
2087   }
2088   case AF_CXXNew:
2089   case AF_CXXNewArray: {
2090     if (IsALeakCheck) {
2091       if (ChecksEnabled[CK_NewDeleteLeaksChecker])
2092         return CK_NewDeleteLeaksChecker;
2093     }
2094     else {
2095       if (ChecksEnabled[CK_NewDeleteChecker])
2096         return CK_NewDeleteChecker;
2097     }
2098     return None;
2099   }
2100   case AF_InnerBuffer: {
2101     if (ChecksEnabled[CK_InnerPointerChecker])
2102       return CK_InnerPointerChecker;
2103     return None;
2104   }
2105   case AF_None: {
2106     llvm_unreachable("no family");
2107   }
2108   }
2109   llvm_unreachable("unhandled family");
2110 }
2111 
2112 Optional<MallocChecker::CheckKind>
2113 MallocChecker::getCheckIfTracked(CheckerContext &C, SymbolRef Sym,
2114                                  bool IsALeakCheck) const {
2115   if (C.getState()->contains<ReallocSizeZeroSymbols>(Sym))
2116     return CK_MallocChecker;
2117 
2118   const RefState *RS = C.getState()->get<RegionState>(Sym);
2119   assert(RS);
2120   return getCheckIfTracked(RS->getAllocationFamily(), IsALeakCheck);
2121 }
2122 
2123 bool MallocChecker::SummarizeValue(raw_ostream &os, SVal V) {
2124   if (Optional<nonloc::ConcreteInt> IntVal = V.getAs<nonloc::ConcreteInt>())
2125     os << "an integer (" << IntVal->getValue() << ")";
2126   else if (Optional<loc::ConcreteInt> ConstAddr = V.getAs<loc::ConcreteInt>())
2127     os << "a constant address (" << ConstAddr->getValue() << ")";
2128   else if (Optional<loc::GotoLabel> Label = V.getAs<loc::GotoLabel>())
2129     os << "the address of the label '" << Label->getLabel()->getName() << "'";
2130   else
2131     return false;
2132 
2133   return true;
2134 }
2135 
2136 bool MallocChecker::SummarizeRegion(raw_ostream &os,
2137                                     const MemRegion *MR) {
2138   switch (MR->getKind()) {
2139   case MemRegion::FunctionCodeRegionKind: {
2140     const NamedDecl *FD = cast<FunctionCodeRegion>(MR)->getDecl();
2141     if (FD)
2142       os << "the address of the function '" << *FD << '\'';
2143     else
2144       os << "the address of a function";
2145     return true;
2146   }
2147   case MemRegion::BlockCodeRegionKind:
2148     os << "block text";
2149     return true;
2150   case MemRegion::BlockDataRegionKind:
2151     // FIXME: where the block came from?
2152     os << "a block";
2153     return true;
2154   default: {
2155     const MemSpaceRegion *MS = MR->getMemorySpace();
2156 
2157     if (isa<StackLocalsSpaceRegion>(MS)) {
2158       const VarRegion *VR = dyn_cast<VarRegion>(MR);
2159       const VarDecl *VD;
2160       if (VR)
2161         VD = VR->getDecl();
2162       else
2163         VD = nullptr;
2164 
2165       if (VD)
2166         os << "the address of the local variable '" << VD->getName() << "'";
2167       else
2168         os << "the address of a local stack variable";
2169       return true;
2170     }
2171 
2172     if (isa<StackArgumentsSpaceRegion>(MS)) {
2173       const VarRegion *VR = dyn_cast<VarRegion>(MR);
2174       const VarDecl *VD;
2175       if (VR)
2176         VD = VR->getDecl();
2177       else
2178         VD = nullptr;
2179 
2180       if (VD)
2181         os << "the address of the parameter '" << VD->getName() << "'";
2182       else
2183         os << "the address of a parameter";
2184       return true;
2185     }
2186 
2187     if (isa<GlobalsSpaceRegion>(MS)) {
2188       const VarRegion *VR = dyn_cast<VarRegion>(MR);
2189       const VarDecl *VD;
2190       if (VR)
2191         VD = VR->getDecl();
2192       else
2193         VD = nullptr;
2194 
2195       if (VD) {
2196         if (VD->isStaticLocal())
2197           os << "the address of the static variable '" << VD->getName() << "'";
2198         else
2199           os << "the address of the global variable '" << VD->getName() << "'";
2200       } else
2201         os << "the address of a global variable";
2202       return true;
2203     }
2204 
2205     return false;
2206   }
2207   }
2208 }
2209 
2210 void MallocChecker::HandleNonHeapDealloc(CheckerContext &C, SVal ArgVal,
2211                                          SourceRange Range,
2212                                          const Expr *DeallocExpr,
2213                                          AllocationFamily Family) const {
2214 
2215   if (!ChecksEnabled[CK_MallocChecker] && !ChecksEnabled[CK_NewDeleteChecker]) {
2216     C.addSink();
2217     return;
2218   }
2219 
2220   Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(Family);
2221   if (!CheckKind)
2222     return;
2223 
2224   if (ExplodedNode *N = C.generateErrorNode()) {
2225     if (!BT_BadFree[*CheckKind])
2226       BT_BadFree[*CheckKind].reset(new BugType(
2227           CheckNames[*CheckKind], "Bad free", categories::MemoryError));
2228 
2229     SmallString<100> buf;
2230     llvm::raw_svector_ostream os(buf);
2231 
2232     const MemRegion *MR = ArgVal.getAsRegion();
2233     while (const ElementRegion *ER = dyn_cast_or_null<ElementRegion>(MR))
2234       MR = ER->getSuperRegion();
2235 
2236     os << "Argument to ";
2237     if (!printMemFnName(os, C, DeallocExpr))
2238       os << "deallocator";
2239 
2240     os << " is ";
2241     bool Summarized = MR ? SummarizeRegion(os, MR)
2242                          : SummarizeValue(os, ArgVal);
2243     if (Summarized)
2244       os << ", which is not memory allocated by ";
2245     else
2246       os << "not memory allocated by ";
2247 
2248     printExpectedAllocName(os, Family);
2249 
2250     auto R = std::make_unique<PathSensitiveBugReport>(*BT_BadFree[*CheckKind],
2251                                                       os.str(), N);
2252     R->markInteresting(MR);
2253     R->addRange(Range);
2254     C.emitReport(std::move(R));
2255   }
2256 }
2257 
2258 void MallocChecker::HandleFreeAlloca(CheckerContext &C, SVal ArgVal,
2259                                      SourceRange Range) const {
2260 
2261   Optional<MallocChecker::CheckKind> CheckKind;
2262 
2263   if (ChecksEnabled[CK_MallocChecker])
2264     CheckKind = CK_MallocChecker;
2265   else if (ChecksEnabled[CK_MismatchedDeallocatorChecker])
2266     CheckKind = CK_MismatchedDeallocatorChecker;
2267   else {
2268     C.addSink();
2269     return;
2270   }
2271 
2272   if (ExplodedNode *N = C.generateErrorNode()) {
2273     if (!BT_FreeAlloca[*CheckKind])
2274       BT_FreeAlloca[*CheckKind].reset(new BugType(
2275           CheckNames[*CheckKind], "Free alloca()", categories::MemoryError));
2276 
2277     auto R = std::make_unique<PathSensitiveBugReport>(
2278         *BT_FreeAlloca[*CheckKind],
2279         "Memory allocated by alloca() should not be deallocated", N);
2280     R->markInteresting(ArgVal.getAsRegion());
2281     R->addRange(Range);
2282     C.emitReport(std::move(R));
2283   }
2284 }
2285 
2286 void MallocChecker::HandleMismatchedDealloc(CheckerContext &C,
2287                                             SourceRange Range,
2288                                             const Expr *DeallocExpr,
2289                                             const RefState *RS, SymbolRef Sym,
2290                                             bool OwnershipTransferred) const {
2291 
2292   if (!ChecksEnabled[CK_MismatchedDeallocatorChecker]) {
2293     C.addSink();
2294     return;
2295   }
2296 
2297   if (ExplodedNode *N = C.generateErrorNode()) {
2298     if (!BT_MismatchedDealloc)
2299       BT_MismatchedDealloc.reset(
2300           new BugType(CheckNames[CK_MismatchedDeallocatorChecker],
2301                       "Bad deallocator", categories::MemoryError));
2302 
2303     SmallString<100> buf;
2304     llvm::raw_svector_ostream os(buf);
2305 
2306     const Expr *AllocExpr = cast<Expr>(RS->getStmt());
2307     SmallString<20> AllocBuf;
2308     llvm::raw_svector_ostream AllocOs(AllocBuf);
2309     SmallString<20> DeallocBuf;
2310     llvm::raw_svector_ostream DeallocOs(DeallocBuf);
2311 
2312     if (OwnershipTransferred) {
2313       if (printMemFnName(DeallocOs, C, DeallocExpr))
2314         os << DeallocOs.str() << " cannot";
2315       else
2316         os << "Cannot";
2317 
2318       os << " take ownership of memory";
2319 
2320       if (printMemFnName(AllocOs, C, AllocExpr))
2321         os << " allocated by " << AllocOs.str();
2322     } else {
2323       os << "Memory";
2324       if (printMemFnName(AllocOs, C, AllocExpr))
2325         os << " allocated by " << AllocOs.str();
2326 
2327       os << " should be deallocated by ";
2328         printExpectedDeallocName(os, RS->getAllocationFamily());
2329 
2330         if (printMemFnName(DeallocOs, C, DeallocExpr))
2331           os << ", not " << DeallocOs.str();
2332     }
2333 
2334     auto R = std::make_unique<PathSensitiveBugReport>(*BT_MismatchedDealloc,
2335                                                       os.str(), N);
2336     R->markInteresting(Sym);
2337     R->addRange(Range);
2338     R->addVisitor<MallocBugVisitor>(Sym);
2339     C.emitReport(std::move(R));
2340   }
2341 }
2342 
2343 void MallocChecker::HandleOffsetFree(CheckerContext &C, SVal ArgVal,
2344                                      SourceRange Range, const Expr *DeallocExpr,
2345                                      AllocationFamily Family,
2346                                      const Expr *AllocExpr) const {
2347 
2348   if (!ChecksEnabled[CK_MallocChecker] && !ChecksEnabled[CK_NewDeleteChecker]) {
2349     C.addSink();
2350     return;
2351   }
2352 
2353   Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(Family);
2354   if (!CheckKind)
2355     return;
2356 
2357   ExplodedNode *N = C.generateErrorNode();
2358   if (!N)
2359     return;
2360 
2361   if (!BT_OffsetFree[*CheckKind])
2362     BT_OffsetFree[*CheckKind].reset(new BugType(
2363         CheckNames[*CheckKind], "Offset free", categories::MemoryError));
2364 
2365   SmallString<100> buf;
2366   llvm::raw_svector_ostream os(buf);
2367   SmallString<20> AllocNameBuf;
2368   llvm::raw_svector_ostream AllocNameOs(AllocNameBuf);
2369 
2370   const MemRegion *MR = ArgVal.getAsRegion();
2371   assert(MR && "Only MemRegion based symbols can have offset free errors");
2372 
2373   RegionOffset Offset = MR->getAsOffset();
2374   assert((Offset.isValid() &&
2375           !Offset.hasSymbolicOffset() &&
2376           Offset.getOffset() != 0) &&
2377          "Only symbols with a valid offset can have offset free errors");
2378 
2379   int offsetBytes = Offset.getOffset() / C.getASTContext().getCharWidth();
2380 
2381   os << "Argument to ";
2382   if (!printMemFnName(os, C, DeallocExpr))
2383     os << "deallocator";
2384   os << " is offset by "
2385      << offsetBytes
2386      << " "
2387      << ((abs(offsetBytes) > 1) ? "bytes" : "byte")
2388      << " from the start of ";
2389   if (AllocExpr && printMemFnName(AllocNameOs, C, AllocExpr))
2390     os << "memory allocated by " << AllocNameOs.str();
2391   else
2392     os << "allocated memory";
2393 
2394   auto R = std::make_unique<PathSensitiveBugReport>(*BT_OffsetFree[*CheckKind],
2395                                                     os.str(), N);
2396   R->markInteresting(MR->getBaseRegion());
2397   R->addRange(Range);
2398   C.emitReport(std::move(R));
2399 }
2400 
2401 void MallocChecker::HandleUseAfterFree(CheckerContext &C, SourceRange Range,
2402                                        SymbolRef Sym) const {
2403 
2404   if (!ChecksEnabled[CK_MallocChecker] && !ChecksEnabled[CK_NewDeleteChecker] &&
2405       !ChecksEnabled[CK_InnerPointerChecker]) {
2406     C.addSink();
2407     return;
2408   }
2409 
2410   Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(C, Sym);
2411   if (!CheckKind)
2412     return;
2413 
2414   if (ExplodedNode *N = C.generateErrorNode()) {
2415     if (!BT_UseFree[*CheckKind])
2416       BT_UseFree[*CheckKind].reset(new BugType(
2417           CheckNames[*CheckKind], "Use-after-free", categories::MemoryError));
2418 
2419     AllocationFamily AF =
2420         C.getState()->get<RegionState>(Sym)->getAllocationFamily();
2421 
2422     auto R = std::make_unique<PathSensitiveBugReport>(
2423         *BT_UseFree[*CheckKind],
2424         AF == AF_InnerBuffer
2425             ? "Inner pointer of container used after re/deallocation"
2426             : "Use of memory after it is freed",
2427         N);
2428 
2429     R->markInteresting(Sym);
2430     R->addRange(Range);
2431     R->addVisitor<MallocBugVisitor>(Sym);
2432 
2433     if (AF == AF_InnerBuffer)
2434       R->addVisitor(allocation_state::getInnerPointerBRVisitor(Sym));
2435 
2436     C.emitReport(std::move(R));
2437   }
2438 }
2439 
2440 void MallocChecker::HandleDoubleFree(CheckerContext &C, SourceRange Range,
2441                                      bool Released, SymbolRef Sym,
2442                                      SymbolRef PrevSym) const {
2443 
2444   if (!ChecksEnabled[CK_MallocChecker] && !ChecksEnabled[CK_NewDeleteChecker]) {
2445     C.addSink();
2446     return;
2447   }
2448 
2449   Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(C, Sym);
2450   if (!CheckKind)
2451     return;
2452 
2453   if (ExplodedNode *N = C.generateErrorNode()) {
2454     if (!BT_DoubleFree[*CheckKind])
2455       BT_DoubleFree[*CheckKind].reset(new BugType(
2456           CheckNames[*CheckKind], "Double free", categories::MemoryError));
2457 
2458     auto R = std::make_unique<PathSensitiveBugReport>(
2459         *BT_DoubleFree[*CheckKind],
2460         (Released ? "Attempt to free released memory"
2461                   : "Attempt to free non-owned memory"),
2462         N);
2463     R->addRange(Range);
2464     R->markInteresting(Sym);
2465     if (PrevSym)
2466       R->markInteresting(PrevSym);
2467     R->addVisitor<MallocBugVisitor>(Sym);
2468     C.emitReport(std::move(R));
2469   }
2470 }
2471 
2472 void MallocChecker::HandleDoubleDelete(CheckerContext &C, SymbolRef Sym) const {
2473 
2474   if (!ChecksEnabled[CK_NewDeleteChecker]) {
2475     C.addSink();
2476     return;
2477   }
2478 
2479   Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(C, Sym);
2480   if (!CheckKind)
2481     return;
2482 
2483   if (ExplodedNode *N = C.generateErrorNode()) {
2484     if (!BT_DoubleDelete)
2485       BT_DoubleDelete.reset(new BugType(CheckNames[CK_NewDeleteChecker],
2486                                         "Double delete",
2487                                         categories::MemoryError));
2488 
2489     auto R = std::make_unique<PathSensitiveBugReport>(
2490         *BT_DoubleDelete, "Attempt to delete released memory", N);
2491 
2492     R->markInteresting(Sym);
2493     R->addVisitor<MallocBugVisitor>(Sym);
2494     C.emitReport(std::move(R));
2495   }
2496 }
2497 
2498 void MallocChecker::HandleUseZeroAlloc(CheckerContext &C, SourceRange Range,
2499                                        SymbolRef Sym) const {
2500 
2501   if (!ChecksEnabled[CK_MallocChecker] && !ChecksEnabled[CK_NewDeleteChecker]) {
2502     C.addSink();
2503     return;
2504   }
2505 
2506   Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(C, Sym);
2507 
2508   if (!CheckKind)
2509     return;
2510 
2511   if (ExplodedNode *N = C.generateErrorNode()) {
2512     if (!BT_UseZerroAllocated[*CheckKind])
2513       BT_UseZerroAllocated[*CheckKind].reset(
2514           new BugType(CheckNames[*CheckKind], "Use of zero allocated",
2515                       categories::MemoryError));
2516 
2517     auto R = std::make_unique<PathSensitiveBugReport>(
2518         *BT_UseZerroAllocated[*CheckKind],
2519         "Use of memory allocated with size zero", N);
2520 
2521     R->addRange(Range);
2522     if (Sym) {
2523       R->markInteresting(Sym);
2524       R->addVisitor<MallocBugVisitor>(Sym);
2525     }
2526     C.emitReport(std::move(R));
2527   }
2528 }
2529 
2530 void MallocChecker::HandleFunctionPtrFree(CheckerContext &C, SVal ArgVal,
2531                                           SourceRange Range,
2532                                           const Expr *FreeExpr,
2533                                           AllocationFamily Family) const {
2534   if (!ChecksEnabled[CK_MallocChecker]) {
2535     C.addSink();
2536     return;
2537   }
2538 
2539   Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(Family);
2540   if (!CheckKind)
2541     return;
2542 
2543   if (ExplodedNode *N = C.generateErrorNode()) {
2544     if (!BT_BadFree[*CheckKind])
2545       BT_BadFree[*CheckKind].reset(new BugType(
2546           CheckNames[*CheckKind], "Bad free", categories::MemoryError));
2547 
2548     SmallString<100> Buf;
2549     llvm::raw_svector_ostream Os(Buf);
2550 
2551     const MemRegion *MR = ArgVal.getAsRegion();
2552     while (const ElementRegion *ER = dyn_cast_or_null<ElementRegion>(MR))
2553       MR = ER->getSuperRegion();
2554 
2555     Os << "Argument to ";
2556     if (!printMemFnName(Os, C, FreeExpr))
2557       Os << "deallocator";
2558 
2559     Os << " is a function pointer";
2560 
2561     auto R = std::make_unique<PathSensitiveBugReport>(*BT_BadFree[*CheckKind],
2562                                                       Os.str(), N);
2563     R->markInteresting(MR);
2564     R->addRange(Range);
2565     C.emitReport(std::move(R));
2566   }
2567 }
2568 
2569 ProgramStateRef
2570 MallocChecker::ReallocMemAux(CheckerContext &C, const CallEvent &Call,
2571                              bool ShouldFreeOnFail, ProgramStateRef State,
2572                              AllocationFamily Family, bool SuffixWithN) const {
2573   if (!State)
2574     return nullptr;
2575 
2576   const CallExpr *CE = cast<CallExpr>(Call.getOriginExpr());
2577 
2578   if (SuffixWithN && CE->getNumArgs() < 3)
2579     return nullptr;
2580   else if (CE->getNumArgs() < 2)
2581     return nullptr;
2582 
2583   const Expr *arg0Expr = CE->getArg(0);
2584   SVal Arg0Val = C.getSVal(arg0Expr);
2585   if (!isa<DefinedOrUnknownSVal>(Arg0Val))
2586     return nullptr;
2587   DefinedOrUnknownSVal arg0Val = Arg0Val.castAs<DefinedOrUnknownSVal>();
2588 
2589   SValBuilder &svalBuilder = C.getSValBuilder();
2590 
2591   DefinedOrUnknownSVal PtrEQ = svalBuilder.evalEQ(
2592       State, arg0Val, svalBuilder.makeNullWithType(arg0Expr->getType()));
2593 
2594   // Get the size argument.
2595   const Expr *Arg1 = CE->getArg(1);
2596 
2597   // Get the value of the size argument.
2598   SVal TotalSize = C.getSVal(Arg1);
2599   if (SuffixWithN)
2600     TotalSize = evalMulForBufferSize(C, Arg1, CE->getArg(2));
2601   if (!isa<DefinedOrUnknownSVal>(TotalSize))
2602     return nullptr;
2603 
2604   // Compare the size argument to 0.
2605   DefinedOrUnknownSVal SizeZero =
2606       svalBuilder.evalEQ(State, TotalSize.castAs<DefinedOrUnknownSVal>(),
2607                          svalBuilder.makeIntValWithWidth(
2608                              svalBuilder.getContext().getSizeType(), 0));
2609 
2610   ProgramStateRef StatePtrIsNull, StatePtrNotNull;
2611   std::tie(StatePtrIsNull, StatePtrNotNull) = State->assume(PtrEQ);
2612   ProgramStateRef StateSizeIsZero, StateSizeNotZero;
2613   std::tie(StateSizeIsZero, StateSizeNotZero) = State->assume(SizeZero);
2614   // We only assume exceptional states if they are definitely true; if the
2615   // state is under-constrained, assume regular realloc behavior.
2616   bool PrtIsNull = StatePtrIsNull && !StatePtrNotNull;
2617   bool SizeIsZero = StateSizeIsZero && !StateSizeNotZero;
2618 
2619   // If the ptr is NULL and the size is not 0, the call is equivalent to
2620   // malloc(size).
2621   if (PrtIsNull && !SizeIsZero) {
2622     ProgramStateRef stateMalloc = MallocMemAux(
2623         C, Call, TotalSize, UndefinedVal(), StatePtrIsNull, Family);
2624     return stateMalloc;
2625   }
2626 
2627   if (PrtIsNull && SizeIsZero)
2628     return State;
2629 
2630   assert(!PrtIsNull);
2631 
2632   bool IsKnownToBeAllocated = false;
2633 
2634   // If the size is 0, free the memory.
2635   if (SizeIsZero)
2636     // The semantics of the return value are:
2637     // If size was equal to 0, either NULL or a pointer suitable to be passed
2638     // to free() is returned. We just free the input pointer and do not add
2639     // any constrains on the output pointer.
2640     if (ProgramStateRef stateFree = FreeMemAux(
2641             C, Call, StateSizeIsZero, 0, false, IsKnownToBeAllocated, Family))
2642       return stateFree;
2643 
2644   // Default behavior.
2645   if (ProgramStateRef stateFree =
2646           FreeMemAux(C, Call, State, 0, false, IsKnownToBeAllocated, Family)) {
2647 
2648     ProgramStateRef stateRealloc =
2649         MallocMemAux(C, Call, TotalSize, UnknownVal(), stateFree, Family);
2650     if (!stateRealloc)
2651       return nullptr;
2652 
2653     OwnershipAfterReallocKind Kind = OAR_ToBeFreedAfterFailure;
2654     if (ShouldFreeOnFail)
2655       Kind = OAR_FreeOnFailure;
2656     else if (!IsKnownToBeAllocated)
2657       Kind = OAR_DoNotTrackAfterFailure;
2658 
2659     // Get the from and to pointer symbols as in toPtr = realloc(fromPtr, size).
2660     SymbolRef FromPtr = arg0Val.getLocSymbolInBase();
2661     SVal RetVal = C.getSVal(CE);
2662     SymbolRef ToPtr = RetVal.getAsSymbol();
2663     assert(FromPtr && ToPtr &&
2664            "By this point, FreeMemAux and MallocMemAux should have checked "
2665            "whether the argument or the return value is symbolic!");
2666 
2667     // Record the info about the reallocated symbol so that we could properly
2668     // process failed reallocation.
2669     stateRealloc = stateRealloc->set<ReallocPairs>(ToPtr,
2670                                                    ReallocPair(FromPtr, Kind));
2671     // The reallocated symbol should stay alive for as long as the new symbol.
2672     C.getSymbolManager().addSymbolDependency(ToPtr, FromPtr);
2673     return stateRealloc;
2674   }
2675   return nullptr;
2676 }
2677 
2678 ProgramStateRef MallocChecker::CallocMem(CheckerContext &C,
2679                                          const CallEvent &Call,
2680                                          ProgramStateRef State) {
2681   if (!State)
2682     return nullptr;
2683 
2684   if (Call.getNumArgs() < 2)
2685     return nullptr;
2686 
2687   SValBuilder &svalBuilder = C.getSValBuilder();
2688   SVal zeroVal = svalBuilder.makeZeroVal(svalBuilder.getContext().CharTy);
2689   SVal TotalSize =
2690       evalMulForBufferSize(C, Call.getArgExpr(0), Call.getArgExpr(1));
2691 
2692   return MallocMemAux(C, Call, TotalSize, zeroVal, State, AF_Malloc);
2693 }
2694 
2695 MallocChecker::LeakInfo MallocChecker::getAllocationSite(const ExplodedNode *N,
2696                                                          SymbolRef Sym,
2697                                                          CheckerContext &C) {
2698   const LocationContext *LeakContext = N->getLocationContext();
2699   // Walk the ExplodedGraph backwards and find the first node that referred to
2700   // the tracked symbol.
2701   const ExplodedNode *AllocNode = N;
2702   const MemRegion *ReferenceRegion = nullptr;
2703 
2704   while (N) {
2705     ProgramStateRef State = N->getState();
2706     if (!State->get<RegionState>(Sym))
2707       break;
2708 
2709     // Find the most recent expression bound to the symbol in the current
2710     // context.
2711     if (!ReferenceRegion) {
2712       if (const MemRegion *MR = C.getLocationRegionIfPostStore(N)) {
2713         SVal Val = State->getSVal(MR);
2714         if (Val.getAsLocSymbol() == Sym) {
2715           const VarRegion *VR = MR->getBaseRegion()->getAs<VarRegion>();
2716           // Do not show local variables belonging to a function other than
2717           // where the error is reported.
2718           if (!VR || (VR->getStackFrame() == LeakContext->getStackFrame()))
2719             ReferenceRegion = MR;
2720         }
2721       }
2722     }
2723 
2724     // Allocation node, is the last node in the current or parent context in
2725     // which the symbol was tracked.
2726     const LocationContext *NContext = N->getLocationContext();
2727     if (NContext == LeakContext ||
2728         NContext->isParentOf(LeakContext))
2729       AllocNode = N;
2730     N = N->pred_empty() ? nullptr : *(N->pred_begin());
2731   }
2732 
2733   return LeakInfo(AllocNode, ReferenceRegion);
2734 }
2735 
2736 void MallocChecker::HandleLeak(SymbolRef Sym, ExplodedNode *N,
2737                                CheckerContext &C) const {
2738 
2739   if (!ChecksEnabled[CK_MallocChecker] &&
2740       !ChecksEnabled[CK_NewDeleteLeaksChecker])
2741     return;
2742 
2743   const RefState *RS = C.getState()->get<RegionState>(Sym);
2744   assert(RS && "cannot leak an untracked symbol");
2745   AllocationFamily Family = RS->getAllocationFamily();
2746 
2747   if (Family == AF_Alloca)
2748     return;
2749 
2750   Optional<MallocChecker::CheckKind>
2751       CheckKind = getCheckIfTracked(Family, true);
2752 
2753   if (!CheckKind)
2754     return;
2755 
2756   assert(N);
2757   if (!BT_Leak[*CheckKind]) {
2758     // Leaks should not be reported if they are post-dominated by a sink:
2759     // (1) Sinks are higher importance bugs.
2760     // (2) NoReturnFunctionChecker uses sink nodes to represent paths ending
2761     //     with __noreturn functions such as assert() or exit(). We choose not
2762     //     to report leaks on such paths.
2763     BT_Leak[*CheckKind].reset(new BugType(CheckNames[*CheckKind], "Memory leak",
2764                                           categories::MemoryError,
2765                                           /*SuppressOnSink=*/true));
2766   }
2767 
2768   // Most bug reports are cached at the location where they occurred.
2769   // With leaks, we want to unique them by the location where they were
2770   // allocated, and only report a single path.
2771   PathDiagnosticLocation LocUsedForUniqueing;
2772   const ExplodedNode *AllocNode = nullptr;
2773   const MemRegion *Region = nullptr;
2774   std::tie(AllocNode, Region) = getAllocationSite(N, Sym, C);
2775 
2776   const Stmt *AllocationStmt = AllocNode->getStmtForDiagnostics();
2777   if (AllocationStmt)
2778     LocUsedForUniqueing = PathDiagnosticLocation::createBegin(AllocationStmt,
2779                                               C.getSourceManager(),
2780                                               AllocNode->getLocationContext());
2781 
2782   SmallString<200> buf;
2783   llvm::raw_svector_ostream os(buf);
2784   if (Region && Region->canPrintPretty()) {
2785     os << "Potential leak of memory pointed to by ";
2786     Region->printPretty(os);
2787   } else {
2788     os << "Potential memory leak";
2789   }
2790 
2791   auto R = std::make_unique<PathSensitiveBugReport>(
2792       *BT_Leak[*CheckKind], os.str(), N, LocUsedForUniqueing,
2793       AllocNode->getLocationContext()->getDecl());
2794   R->markInteresting(Sym);
2795   R->addVisitor<MallocBugVisitor>(Sym, true);
2796   if (ShouldRegisterNoOwnershipChangeVisitor)
2797     R->addVisitor<NoOwnershipChangeVisitor>(Sym, this);
2798   C.emitReport(std::move(R));
2799 }
2800 
2801 void MallocChecker::checkDeadSymbols(SymbolReaper &SymReaper,
2802                                      CheckerContext &C) const
2803 {
2804   ProgramStateRef state = C.getState();
2805   RegionStateTy OldRS = state->get<RegionState>();
2806   RegionStateTy::Factory &F = state->get_context<RegionState>();
2807 
2808   RegionStateTy RS = OldRS;
2809   SmallVector<SymbolRef, 2> Errors;
2810   for (RegionStateTy::iterator I = RS.begin(), E = RS.end(); I != E; ++I) {
2811     if (SymReaper.isDead(I->first)) {
2812       if (I->second.isAllocated() || I->second.isAllocatedOfSizeZero())
2813         Errors.push_back(I->first);
2814       // Remove the dead symbol from the map.
2815       RS = F.remove(RS, I->first);
2816     }
2817   }
2818 
2819   if (RS == OldRS) {
2820     // We shouldn't have touched other maps yet.
2821     assert(state->get<ReallocPairs>() ==
2822            C.getState()->get<ReallocPairs>());
2823     assert(state->get<FreeReturnValue>() ==
2824            C.getState()->get<FreeReturnValue>());
2825     return;
2826   }
2827 
2828   // Cleanup the Realloc Pairs Map.
2829   ReallocPairsTy RP = state->get<ReallocPairs>();
2830   for (ReallocPairsTy::iterator I = RP.begin(), E = RP.end(); I != E; ++I) {
2831     if (SymReaper.isDead(I->first) ||
2832         SymReaper.isDead(I->second.ReallocatedSym)) {
2833       state = state->remove<ReallocPairs>(I->first);
2834     }
2835   }
2836 
2837   // Cleanup the FreeReturnValue Map.
2838   FreeReturnValueTy FR = state->get<FreeReturnValue>();
2839   for (FreeReturnValueTy::iterator I = FR.begin(), E = FR.end(); I != E; ++I) {
2840     if (SymReaper.isDead(I->first) ||
2841         SymReaper.isDead(I->second)) {
2842       state = state->remove<FreeReturnValue>(I->first);
2843     }
2844   }
2845 
2846   // Generate leak node.
2847   ExplodedNode *N = C.getPredecessor();
2848   if (!Errors.empty()) {
2849     static CheckerProgramPointTag Tag("MallocChecker", "DeadSymbolsLeak");
2850     N = C.generateNonFatalErrorNode(C.getState(), &Tag);
2851     if (N) {
2852       for (SmallVectorImpl<SymbolRef>::iterator
2853            I = Errors.begin(), E = Errors.end(); I != E; ++I) {
2854         HandleLeak(*I, N, C);
2855       }
2856     }
2857   }
2858 
2859   C.addTransition(state->set<RegionState>(RS), N);
2860 }
2861 
2862 void MallocChecker::checkPreCall(const CallEvent &Call,
2863                                  CheckerContext &C) const {
2864 
2865   if (const auto *DC = dyn_cast<CXXDeallocatorCall>(&Call)) {
2866     const CXXDeleteExpr *DE = DC->getOriginExpr();
2867 
2868     if (!ChecksEnabled[CK_NewDeleteChecker])
2869       if (SymbolRef Sym = C.getSVal(DE->getArgument()).getAsSymbol())
2870         checkUseAfterFree(Sym, C, DE->getArgument());
2871 
2872     if (!isStandardNewDelete(DC->getDecl()))
2873       return;
2874 
2875     ProgramStateRef State = C.getState();
2876     bool IsKnownToBeAllocated;
2877     State = FreeMemAux(C, DE->getArgument(), Call, State,
2878                        /*Hold*/ false, IsKnownToBeAllocated,
2879                        (DE->isArrayForm() ? AF_CXXNewArray : AF_CXXNew));
2880 
2881     C.addTransition(State);
2882     return;
2883   }
2884 
2885   if (const auto *DC = dyn_cast<CXXDestructorCall>(&Call)) {
2886     SymbolRef Sym = DC->getCXXThisVal().getAsSymbol();
2887     if (!Sym || checkDoubleDelete(Sym, C))
2888       return;
2889   }
2890 
2891   // We will check for double free in the post visit.
2892   if (const AnyFunctionCall *FC = dyn_cast<AnyFunctionCall>(&Call)) {
2893     const FunctionDecl *FD = FC->getDecl();
2894     if (!FD)
2895       return;
2896 
2897     if (ChecksEnabled[CK_MallocChecker] && isFreeingCall(Call))
2898       return;
2899   }
2900 
2901   // Check if the callee of a method is deleted.
2902   if (const CXXInstanceCall *CC = dyn_cast<CXXInstanceCall>(&Call)) {
2903     SymbolRef Sym = CC->getCXXThisVal().getAsSymbol();
2904     if (!Sym || checkUseAfterFree(Sym, C, CC->getCXXThisExpr()))
2905       return;
2906   }
2907 
2908   // Check arguments for being used after free.
2909   for (unsigned I = 0, E = Call.getNumArgs(); I != E; ++I) {
2910     SVal ArgSVal = Call.getArgSVal(I);
2911     if (isa<Loc>(ArgSVal)) {
2912       SymbolRef Sym = ArgSVal.getAsSymbol();
2913       if (!Sym)
2914         continue;
2915       if (checkUseAfterFree(Sym, C, Call.getArgExpr(I)))
2916         return;
2917     }
2918   }
2919 }
2920 
2921 void MallocChecker::checkPreStmt(const ReturnStmt *S,
2922                                  CheckerContext &C) const {
2923   checkEscapeOnReturn(S, C);
2924 }
2925 
2926 // In the CFG, automatic destructors come after the return statement.
2927 // This callback checks for returning memory that is freed by automatic
2928 // destructors, as those cannot be reached in checkPreStmt().
2929 void MallocChecker::checkEndFunction(const ReturnStmt *S,
2930                                      CheckerContext &C) const {
2931   checkEscapeOnReturn(S, C);
2932 }
2933 
2934 void MallocChecker::checkEscapeOnReturn(const ReturnStmt *S,
2935                                         CheckerContext &C) const {
2936   if (!S)
2937     return;
2938 
2939   const Expr *E = S->getRetValue();
2940   if (!E)
2941     return;
2942 
2943   // Check if we are returning a symbol.
2944   ProgramStateRef State = C.getState();
2945   SVal RetVal = C.getSVal(E);
2946   SymbolRef Sym = RetVal.getAsSymbol();
2947   if (!Sym)
2948     // If we are returning a field of the allocated struct or an array element,
2949     // the callee could still free the memory.
2950     // TODO: This logic should be a part of generic symbol escape callback.
2951     if (const MemRegion *MR = RetVal.getAsRegion())
2952       if (isa<FieldRegion, ElementRegion>(MR))
2953         if (const SymbolicRegion *BMR =
2954               dyn_cast<SymbolicRegion>(MR->getBaseRegion()))
2955           Sym = BMR->getSymbol();
2956 
2957   // Check if we are returning freed memory.
2958   if (Sym)
2959     checkUseAfterFree(Sym, C, E);
2960 }
2961 
2962 // TODO: Blocks should be either inlined or should call invalidate regions
2963 // upon invocation. After that's in place, special casing here will not be
2964 // needed.
2965 void MallocChecker::checkPostStmt(const BlockExpr *BE,
2966                                   CheckerContext &C) const {
2967 
2968   // Scan the BlockDecRefExprs for any object the retain count checker
2969   // may be tracking.
2970   if (!BE->getBlockDecl()->hasCaptures())
2971     return;
2972 
2973   ProgramStateRef state = C.getState();
2974   const BlockDataRegion *R =
2975     cast<BlockDataRegion>(C.getSVal(BE).getAsRegion());
2976 
2977   BlockDataRegion::referenced_vars_iterator I = R->referenced_vars_begin(),
2978                                             E = R->referenced_vars_end();
2979 
2980   if (I == E)
2981     return;
2982 
2983   SmallVector<const MemRegion*, 10> Regions;
2984   const LocationContext *LC = C.getLocationContext();
2985   MemRegionManager &MemMgr = C.getSValBuilder().getRegionManager();
2986 
2987   for ( ; I != E; ++I) {
2988     const VarRegion *VR = I.getCapturedRegion();
2989     if (VR->getSuperRegion() == R) {
2990       VR = MemMgr.getVarRegion(VR->getDecl(), LC);
2991     }
2992     Regions.push_back(VR);
2993   }
2994 
2995   state =
2996     state->scanReachableSymbols<StopTrackingCallback>(Regions).getState();
2997   C.addTransition(state);
2998 }
2999 
3000 static bool isReleased(SymbolRef Sym, CheckerContext &C) {
3001   assert(Sym);
3002   const RefState *RS = C.getState()->get<RegionState>(Sym);
3003   return (RS && RS->isReleased());
3004 }
3005 
3006 bool MallocChecker::suppressDeallocationsInSuspiciousContexts(
3007     const CallEvent &Call, CheckerContext &C) const {
3008   if (Call.getNumArgs() == 0)
3009     return false;
3010 
3011   StringRef FunctionStr = "";
3012   if (const auto *FD = dyn_cast<FunctionDecl>(C.getStackFrame()->getDecl()))
3013     if (const Stmt *Body = FD->getBody())
3014       if (Body->getBeginLoc().isValid())
3015         FunctionStr =
3016             Lexer::getSourceText(CharSourceRange::getTokenRange(
3017                                      {FD->getBeginLoc(), Body->getBeginLoc()}),
3018                                  C.getSourceManager(), C.getLangOpts());
3019 
3020   // We do not model the Integer Set Library's retain-count based allocation.
3021   if (!FunctionStr.contains("__isl_"))
3022     return false;
3023 
3024   ProgramStateRef State = C.getState();
3025 
3026   for (const Expr *Arg : cast<CallExpr>(Call.getOriginExpr())->arguments())
3027     if (SymbolRef Sym = C.getSVal(Arg).getAsSymbol())
3028       if (const RefState *RS = State->get<RegionState>(Sym))
3029         State = State->set<RegionState>(Sym, RefState::getEscaped(RS));
3030 
3031   C.addTransition(State);
3032   return true;
3033 }
3034 
3035 bool MallocChecker::checkUseAfterFree(SymbolRef Sym, CheckerContext &C,
3036                                       const Stmt *S) const {
3037 
3038   if (isReleased(Sym, C)) {
3039     HandleUseAfterFree(C, S->getSourceRange(), Sym);
3040     return true;
3041   }
3042 
3043   return false;
3044 }
3045 
3046 void MallocChecker::checkUseZeroAllocated(SymbolRef Sym, CheckerContext &C,
3047                                           const Stmt *S) const {
3048   assert(Sym);
3049 
3050   if (const RefState *RS = C.getState()->get<RegionState>(Sym)) {
3051     if (RS->isAllocatedOfSizeZero())
3052       HandleUseZeroAlloc(C, RS->getStmt()->getSourceRange(), Sym);
3053   }
3054   else if (C.getState()->contains<ReallocSizeZeroSymbols>(Sym)) {
3055     HandleUseZeroAlloc(C, S->getSourceRange(), Sym);
3056   }
3057 }
3058 
3059 bool MallocChecker::checkDoubleDelete(SymbolRef Sym, CheckerContext &C) const {
3060 
3061   if (isReleased(Sym, C)) {
3062     HandleDoubleDelete(C, Sym);
3063     return true;
3064   }
3065   return false;
3066 }
3067 
3068 // Check if the location is a freed symbolic region.
3069 void MallocChecker::checkLocation(SVal l, bool isLoad, const Stmt *S,
3070                                   CheckerContext &C) const {
3071   SymbolRef Sym = l.getLocSymbolInBase();
3072   if (Sym) {
3073     checkUseAfterFree(Sym, C, S);
3074     checkUseZeroAllocated(Sym, C, S);
3075   }
3076 }
3077 
3078 // If a symbolic region is assumed to NULL (or another constant), stop tracking
3079 // it - assuming that allocation failed on this path.
3080 ProgramStateRef MallocChecker::evalAssume(ProgramStateRef state,
3081                                               SVal Cond,
3082                                               bool Assumption) const {
3083   RegionStateTy RS = state->get<RegionState>();
3084   for (RegionStateTy::iterator I = RS.begin(), E = RS.end(); I != E; ++I) {
3085     // If the symbol is assumed to be NULL, remove it from consideration.
3086     ConstraintManager &CMgr = state->getConstraintManager();
3087     ConditionTruthVal AllocFailed = CMgr.isNull(state, I.getKey());
3088     if (AllocFailed.isConstrainedTrue())
3089       state = state->remove<RegionState>(I.getKey());
3090   }
3091 
3092   // Realloc returns 0 when reallocation fails, which means that we should
3093   // restore the state of the pointer being reallocated.
3094   ReallocPairsTy RP = state->get<ReallocPairs>();
3095   for (ReallocPairsTy::iterator I = RP.begin(), E = RP.end(); I != E; ++I) {
3096     // If the symbol is assumed to be NULL, remove it from consideration.
3097     ConstraintManager &CMgr = state->getConstraintManager();
3098     ConditionTruthVal AllocFailed = CMgr.isNull(state, I.getKey());
3099     if (!AllocFailed.isConstrainedTrue())
3100       continue;
3101 
3102     SymbolRef ReallocSym = I.getData().ReallocatedSym;
3103     if (const RefState *RS = state->get<RegionState>(ReallocSym)) {
3104       if (RS->isReleased()) {
3105         switch (I.getData().Kind) {
3106         case OAR_ToBeFreedAfterFailure:
3107           state = state->set<RegionState>(ReallocSym,
3108               RefState::getAllocated(RS->getAllocationFamily(), RS->getStmt()));
3109           break;
3110         case OAR_DoNotTrackAfterFailure:
3111           state = state->remove<RegionState>(ReallocSym);
3112           break;
3113         default:
3114           assert(I.getData().Kind == OAR_FreeOnFailure);
3115         }
3116       }
3117     }
3118     state = state->remove<ReallocPairs>(I.getKey());
3119   }
3120 
3121   return state;
3122 }
3123 
3124 bool MallocChecker::mayFreeAnyEscapedMemoryOrIsModeledExplicitly(
3125                                               const CallEvent *Call,
3126                                               ProgramStateRef State,
3127                                               SymbolRef &EscapingSymbol) const {
3128   assert(Call);
3129   EscapingSymbol = nullptr;
3130 
3131   // For now, assume that any C++ or block call can free memory.
3132   // TODO: If we want to be more optimistic here, we'll need to make sure that
3133   // regions escape to C++ containers. They seem to do that even now, but for
3134   // mysterious reasons.
3135   if (!isa<SimpleFunctionCall, ObjCMethodCall>(Call))
3136     return true;
3137 
3138   // Check Objective-C messages by selector name.
3139   if (const ObjCMethodCall *Msg = dyn_cast<ObjCMethodCall>(Call)) {
3140     // If it's not a framework call, or if it takes a callback, assume it
3141     // can free memory.
3142     if (!Call->isInSystemHeader() || Call->argumentsMayEscape())
3143       return true;
3144 
3145     // If it's a method we know about, handle it explicitly post-call.
3146     // This should happen before the "freeWhenDone" check below.
3147     if (isKnownDeallocObjCMethodName(*Msg))
3148       return false;
3149 
3150     // If there's a "freeWhenDone" parameter, but the method isn't one we know
3151     // about, we can't be sure that the object will use free() to deallocate the
3152     // memory, so we can't model it explicitly. The best we can do is use it to
3153     // decide whether the pointer escapes.
3154     if (Optional<bool> FreeWhenDone = getFreeWhenDoneArg(*Msg))
3155       return *FreeWhenDone;
3156 
3157     // If the first selector piece ends with "NoCopy", and there is no
3158     // "freeWhenDone" parameter set to zero, we know ownership is being
3159     // transferred. Again, though, we can't be sure that the object will use
3160     // free() to deallocate the memory, so we can't model it explicitly.
3161     StringRef FirstSlot = Msg->getSelector().getNameForSlot(0);
3162     if (FirstSlot.endswith("NoCopy"))
3163       return true;
3164 
3165     // If the first selector starts with addPointer, insertPointer,
3166     // or replacePointer, assume we are dealing with NSPointerArray or similar.
3167     // This is similar to C++ containers (vector); we still might want to check
3168     // that the pointers get freed by following the container itself.
3169     if (FirstSlot.startswith("addPointer") ||
3170         FirstSlot.startswith("insertPointer") ||
3171         FirstSlot.startswith("replacePointer") ||
3172         FirstSlot.equals("valueWithPointer")) {
3173       return true;
3174     }
3175 
3176     // We should escape receiver on call to 'init'. This is especially relevant
3177     // to the receiver, as the corresponding symbol is usually not referenced
3178     // after the call.
3179     if (Msg->getMethodFamily() == OMF_init) {
3180       EscapingSymbol = Msg->getReceiverSVal().getAsSymbol();
3181       return true;
3182     }
3183 
3184     // Otherwise, assume that the method does not free memory.
3185     // Most framework methods do not free memory.
3186     return false;
3187   }
3188 
3189   // At this point the only thing left to handle is straight function calls.
3190   const FunctionDecl *FD = cast<SimpleFunctionCall>(Call)->getDecl();
3191   if (!FD)
3192     return true;
3193 
3194   // If it's one of the allocation functions we can reason about, we model
3195   // its behavior explicitly.
3196   if (isMemCall(*Call))
3197     return false;
3198 
3199   // If it's not a system call, assume it frees memory.
3200   if (!Call->isInSystemHeader())
3201     return true;
3202 
3203   // White list the system functions whose arguments escape.
3204   const IdentifierInfo *II = FD->getIdentifier();
3205   if (!II)
3206     return true;
3207   StringRef FName = II->getName();
3208 
3209   // White list the 'XXXNoCopy' CoreFoundation functions.
3210   // We specifically check these before
3211   if (FName.endswith("NoCopy")) {
3212     // Look for the deallocator argument. We know that the memory ownership
3213     // is not transferred only if the deallocator argument is
3214     // 'kCFAllocatorNull'.
3215     for (unsigned i = 1; i < Call->getNumArgs(); ++i) {
3216       const Expr *ArgE = Call->getArgExpr(i)->IgnoreParenCasts();
3217       if (const DeclRefExpr *DE = dyn_cast<DeclRefExpr>(ArgE)) {
3218         StringRef DeallocatorName = DE->getFoundDecl()->getName();
3219         if (DeallocatorName == "kCFAllocatorNull")
3220           return false;
3221       }
3222     }
3223     return true;
3224   }
3225 
3226   // Associating streams with malloced buffers. The pointer can escape if
3227   // 'closefn' is specified (and if that function does free memory),
3228   // but it will not if closefn is not specified.
3229   // Currently, we do not inspect the 'closefn' function (PR12101).
3230   if (FName == "funopen")
3231     if (Call->getNumArgs() >= 4 && Call->getArgSVal(4).isConstant(0))
3232       return false;
3233 
3234   // Do not warn on pointers passed to 'setbuf' when used with std streams,
3235   // these leaks might be intentional when setting the buffer for stdio.
3236   // http://stackoverflow.com/questions/2671151/who-frees-setvbuf-buffer
3237   if (FName == "setbuf" || FName =="setbuffer" ||
3238       FName == "setlinebuf" || FName == "setvbuf") {
3239     if (Call->getNumArgs() >= 1) {
3240       const Expr *ArgE = Call->getArgExpr(0)->IgnoreParenCasts();
3241       if (const DeclRefExpr *ArgDRE = dyn_cast<DeclRefExpr>(ArgE))
3242         if (const VarDecl *D = dyn_cast<VarDecl>(ArgDRE->getDecl()))
3243           if (D->getCanonicalDecl()->getName().contains("std"))
3244             return true;
3245     }
3246   }
3247 
3248   // A bunch of other functions which either take ownership of a pointer or
3249   // wrap the result up in a struct or object, meaning it can be freed later.
3250   // (See RetainCountChecker.) Not all the parameters here are invalidated,
3251   // but the Malloc checker cannot differentiate between them. The right way
3252   // of doing this would be to implement a pointer escapes callback.
3253   if (FName == "CGBitmapContextCreate" ||
3254       FName == "CGBitmapContextCreateWithData" ||
3255       FName == "CVPixelBufferCreateWithBytes" ||
3256       FName == "CVPixelBufferCreateWithPlanarBytes" ||
3257       FName == "OSAtomicEnqueue") {
3258     return true;
3259   }
3260 
3261   if (FName == "postEvent" &&
3262       FD->getQualifiedNameAsString() == "QCoreApplication::postEvent") {
3263     return true;
3264   }
3265 
3266   if (FName == "connectImpl" &&
3267       FD->getQualifiedNameAsString() == "QObject::connectImpl") {
3268     return true;
3269   }
3270 
3271   // Handle cases where we know a buffer's /address/ can escape.
3272   // Note that the above checks handle some special cases where we know that
3273   // even though the address escapes, it's still our responsibility to free the
3274   // buffer.
3275   if (Call->argumentsMayEscape())
3276     return true;
3277 
3278   // Otherwise, assume that the function does not free memory.
3279   // Most system calls do not free the memory.
3280   return false;
3281 }
3282 
3283 ProgramStateRef MallocChecker::checkPointerEscape(ProgramStateRef State,
3284                                              const InvalidatedSymbols &Escaped,
3285                                              const CallEvent *Call,
3286                                              PointerEscapeKind Kind) const {
3287   return checkPointerEscapeAux(State, Escaped, Call, Kind,
3288                                /*IsConstPointerEscape*/ false);
3289 }
3290 
3291 ProgramStateRef MallocChecker::checkConstPointerEscape(ProgramStateRef State,
3292                                               const InvalidatedSymbols &Escaped,
3293                                               const CallEvent *Call,
3294                                               PointerEscapeKind Kind) const {
3295   // If a const pointer escapes, it may not be freed(), but it could be deleted.
3296   return checkPointerEscapeAux(State, Escaped, Call, Kind,
3297                                /*IsConstPointerEscape*/ true);
3298 }
3299 
3300 static bool checkIfNewOrNewArrayFamily(const RefState *RS) {
3301   return (RS->getAllocationFamily() == AF_CXXNewArray ||
3302           RS->getAllocationFamily() == AF_CXXNew);
3303 }
3304 
3305 ProgramStateRef MallocChecker::checkPointerEscapeAux(
3306     ProgramStateRef State, const InvalidatedSymbols &Escaped,
3307     const CallEvent *Call, PointerEscapeKind Kind,
3308     bool IsConstPointerEscape) const {
3309   // If we know that the call does not free memory, or we want to process the
3310   // call later, keep tracking the top level arguments.
3311   SymbolRef EscapingSymbol = nullptr;
3312   if (Kind == PSK_DirectEscapeOnCall &&
3313       !mayFreeAnyEscapedMemoryOrIsModeledExplicitly(Call, State,
3314                                                     EscapingSymbol) &&
3315       !EscapingSymbol) {
3316     return State;
3317   }
3318 
3319   for (InvalidatedSymbols::const_iterator I = Escaped.begin(),
3320        E = Escaped.end();
3321        I != E; ++I) {
3322     SymbolRef sym = *I;
3323 
3324     if (EscapingSymbol && EscapingSymbol != sym)
3325       continue;
3326 
3327     if (const RefState *RS = State->get<RegionState>(sym))
3328       if (RS->isAllocated() || RS->isAllocatedOfSizeZero())
3329         if (!IsConstPointerEscape || checkIfNewOrNewArrayFamily(RS))
3330           State = State->set<RegionState>(sym, RefState::getEscaped(RS));
3331   }
3332   return State;
3333 }
3334 
3335 bool MallocChecker::isArgZERO_SIZE_PTR(ProgramStateRef State, CheckerContext &C,
3336                                        SVal ArgVal) const {
3337   if (!KernelZeroSizePtrValue)
3338     KernelZeroSizePtrValue =
3339         tryExpandAsInteger("ZERO_SIZE_PTR", C.getPreprocessor());
3340 
3341   const llvm::APSInt *ArgValKnown =
3342       C.getSValBuilder().getKnownValue(State, ArgVal);
3343   return ArgValKnown && *KernelZeroSizePtrValue &&
3344          ArgValKnown->getSExtValue() == **KernelZeroSizePtrValue;
3345 }
3346 
3347 static SymbolRef findFailedReallocSymbol(ProgramStateRef currState,
3348                                          ProgramStateRef prevState) {
3349   ReallocPairsTy currMap = currState->get<ReallocPairs>();
3350   ReallocPairsTy prevMap = prevState->get<ReallocPairs>();
3351 
3352   for (const ReallocPairsTy::value_type &Pair : prevMap) {
3353     SymbolRef sym = Pair.first;
3354     if (!currMap.lookup(sym))
3355       return sym;
3356   }
3357 
3358   return nullptr;
3359 }
3360 
3361 static bool isReferenceCountingPointerDestructor(const CXXDestructorDecl *DD) {
3362   if (const IdentifierInfo *II = DD->getParent()->getIdentifier()) {
3363     StringRef N = II->getName();
3364     if (N.contains_insensitive("ptr") || N.contains_insensitive("pointer")) {
3365       if (N.contains_insensitive("ref") || N.contains_insensitive("cnt") ||
3366           N.contains_insensitive("intrusive") ||
3367           N.contains_insensitive("shared")) {
3368         return true;
3369       }
3370     }
3371   }
3372   return false;
3373 }
3374 
3375 PathDiagnosticPieceRef MallocBugVisitor::VisitNode(const ExplodedNode *N,
3376                                                    BugReporterContext &BRC,
3377                                                    PathSensitiveBugReport &BR) {
3378   ProgramStateRef state = N->getState();
3379   ProgramStateRef statePrev = N->getFirstPred()->getState();
3380 
3381   const RefState *RSCurr = state->get<RegionState>(Sym);
3382   const RefState *RSPrev = statePrev->get<RegionState>(Sym);
3383 
3384   const Stmt *S = N->getStmtForDiagnostics();
3385   // When dealing with containers, we sometimes want to give a note
3386   // even if the statement is missing.
3387   if (!S && (!RSCurr || RSCurr->getAllocationFamily() != AF_InnerBuffer))
3388     return nullptr;
3389 
3390   const LocationContext *CurrentLC = N->getLocationContext();
3391 
3392   // If we find an atomic fetch_add or fetch_sub within the destructor in which
3393   // the pointer was released (before the release), this is likely a destructor
3394   // of a shared pointer.
3395   // Because we don't model atomics, and also because we don't know that the
3396   // original reference count is positive, we should not report use-after-frees
3397   // on objects deleted in such destructors. This can probably be improved
3398   // through better shared pointer modeling.
3399   if (ReleaseDestructorLC) {
3400     if (const auto *AE = dyn_cast<AtomicExpr>(S)) {
3401       AtomicExpr::AtomicOp Op = AE->getOp();
3402       if (Op == AtomicExpr::AO__c11_atomic_fetch_add ||
3403           Op == AtomicExpr::AO__c11_atomic_fetch_sub) {
3404         if (ReleaseDestructorLC == CurrentLC ||
3405             ReleaseDestructorLC->isParentOf(CurrentLC)) {
3406           BR.markInvalid(getTag(), S);
3407         }
3408       }
3409     }
3410   }
3411 
3412   // FIXME: We will eventually need to handle non-statement-based events
3413   // (__attribute__((cleanup))).
3414 
3415   // Find out if this is an interesting point and what is the kind.
3416   StringRef Msg;
3417   std::unique_ptr<StackHintGeneratorForSymbol> StackHint = nullptr;
3418   SmallString<256> Buf;
3419   llvm::raw_svector_ostream OS(Buf);
3420 
3421   if (Mode == Normal) {
3422     if (isAllocated(RSCurr, RSPrev, S)) {
3423       Msg = "Memory is allocated";
3424       StackHint = std::make_unique<StackHintGeneratorForSymbol>(
3425           Sym, "Returned allocated memory");
3426     } else if (isReleased(RSCurr, RSPrev, S)) {
3427       const auto Family = RSCurr->getAllocationFamily();
3428       switch (Family) {
3429         case AF_Alloca:
3430         case AF_Malloc:
3431         case AF_CXXNew:
3432         case AF_CXXNewArray:
3433         case AF_IfNameIndex:
3434           Msg = "Memory is released";
3435           StackHint = std::make_unique<StackHintGeneratorForSymbol>(
3436               Sym, "Returning; memory was released");
3437           break;
3438         case AF_InnerBuffer: {
3439           const MemRegion *ObjRegion =
3440               allocation_state::getContainerObjRegion(statePrev, Sym);
3441           const auto *TypedRegion = cast<TypedValueRegion>(ObjRegion);
3442           QualType ObjTy = TypedRegion->getValueType();
3443           OS << "Inner buffer of '" << ObjTy << "' ";
3444 
3445           if (N->getLocation().getKind() == ProgramPoint::PostImplicitCallKind) {
3446             OS << "deallocated by call to destructor";
3447             StackHint = std::make_unique<StackHintGeneratorForSymbol>(
3448                 Sym, "Returning; inner buffer was deallocated");
3449           } else {
3450             OS << "reallocated by call to '";
3451             const Stmt *S = RSCurr->getStmt();
3452             if (const auto *MemCallE = dyn_cast<CXXMemberCallExpr>(S)) {
3453               OS << MemCallE->getMethodDecl()->getDeclName();
3454             } else if (const auto *OpCallE = dyn_cast<CXXOperatorCallExpr>(S)) {
3455               OS << OpCallE->getDirectCallee()->getDeclName();
3456             } else if (const auto *CallE = dyn_cast<CallExpr>(S)) {
3457               auto &CEMgr = BRC.getStateManager().getCallEventManager();
3458               CallEventRef<> Call = CEMgr.getSimpleCall(CallE, state, CurrentLC);
3459               if (const auto *D = dyn_cast_or_null<NamedDecl>(Call->getDecl()))
3460                 OS << D->getDeclName();
3461               else
3462                 OS << "unknown";
3463             }
3464             OS << "'";
3465             StackHint = std::make_unique<StackHintGeneratorForSymbol>(
3466                 Sym, "Returning; inner buffer was reallocated");
3467           }
3468           Msg = OS.str();
3469           break;
3470         }
3471         case AF_None:
3472           llvm_unreachable("Unhandled allocation family!");
3473       }
3474 
3475       // See if we're releasing memory while inlining a destructor
3476       // (or one of its callees). This turns on various common
3477       // false positive suppressions.
3478       bool FoundAnyDestructor = false;
3479       for (const LocationContext *LC = CurrentLC; LC; LC = LC->getParent()) {
3480         if (const auto *DD = dyn_cast<CXXDestructorDecl>(LC->getDecl())) {
3481           if (isReferenceCountingPointerDestructor(DD)) {
3482             // This immediately looks like a reference-counting destructor.
3483             // We're bad at guessing the original reference count of the object,
3484             // so suppress the report for now.
3485             BR.markInvalid(getTag(), DD);
3486           } else if (!FoundAnyDestructor) {
3487             assert(!ReleaseDestructorLC &&
3488                    "There can be only one release point!");
3489             // Suspect that it's a reference counting pointer destructor.
3490             // On one of the next nodes might find out that it has atomic
3491             // reference counting operations within it (see the code above),
3492             // and if so, we'd conclude that it likely is a reference counting
3493             // pointer destructor.
3494             ReleaseDestructorLC = LC->getStackFrame();
3495             // It is unlikely that releasing memory is delegated to a destructor
3496             // inside a destructor of a shared pointer, because it's fairly hard
3497             // to pass the information that the pointer indeed needs to be
3498             // released into it. So we're only interested in the innermost
3499             // destructor.
3500             FoundAnyDestructor = true;
3501           }
3502         }
3503       }
3504     } else if (isRelinquished(RSCurr, RSPrev, S)) {
3505       Msg = "Memory ownership is transferred";
3506       StackHint = std::make_unique<StackHintGeneratorForSymbol>(Sym, "");
3507     } else if (hasReallocFailed(RSCurr, RSPrev, S)) {
3508       Mode = ReallocationFailed;
3509       Msg = "Reallocation failed";
3510       StackHint = std::make_unique<StackHintGeneratorForReallocationFailed>(
3511           Sym, "Reallocation failed");
3512 
3513       if (SymbolRef sym = findFailedReallocSymbol(state, statePrev)) {
3514         // Is it possible to fail two reallocs WITHOUT testing in between?
3515         assert((!FailedReallocSymbol || FailedReallocSymbol == sym) &&
3516           "We only support one failed realloc at a time.");
3517         BR.markInteresting(sym);
3518         FailedReallocSymbol = sym;
3519       }
3520     }
3521 
3522   // We are in a special mode if a reallocation failed later in the path.
3523   } else if (Mode == ReallocationFailed) {
3524     assert(FailedReallocSymbol && "No symbol to look for.");
3525 
3526     // Is this is the first appearance of the reallocated symbol?
3527     if (!statePrev->get<RegionState>(FailedReallocSymbol)) {
3528       // We're at the reallocation point.
3529       Msg = "Attempt to reallocate memory";
3530       StackHint = std::make_unique<StackHintGeneratorForSymbol>(
3531           Sym, "Returned reallocated memory");
3532       FailedReallocSymbol = nullptr;
3533       Mode = Normal;
3534     }
3535   }
3536 
3537   if (Msg.empty()) {
3538     assert(!StackHint);
3539     return nullptr;
3540   }
3541 
3542   assert(StackHint);
3543 
3544   // Generate the extra diagnostic.
3545   PathDiagnosticLocation Pos;
3546   if (!S) {
3547     assert(RSCurr->getAllocationFamily() == AF_InnerBuffer);
3548     auto PostImplCall = N->getLocation().getAs<PostImplicitCall>();
3549     if (!PostImplCall)
3550       return nullptr;
3551     Pos = PathDiagnosticLocation(PostImplCall->getLocation(),
3552                                  BRC.getSourceManager());
3553   } else {
3554     Pos = PathDiagnosticLocation(S, BRC.getSourceManager(),
3555                                  N->getLocationContext());
3556   }
3557 
3558   auto P = std::make_shared<PathDiagnosticEventPiece>(Pos, Msg, true);
3559   BR.addCallStackHint(P, std::move(StackHint));
3560   return P;
3561 }
3562 
3563 void MallocChecker::printState(raw_ostream &Out, ProgramStateRef State,
3564                                const char *NL, const char *Sep) const {
3565 
3566   RegionStateTy RS = State->get<RegionState>();
3567 
3568   if (!RS.isEmpty()) {
3569     Out << Sep << "MallocChecker :" << NL;
3570     for (RegionStateTy::iterator I = RS.begin(), E = RS.end(); I != E; ++I) {
3571       const RefState *RefS = State->get<RegionState>(I.getKey());
3572       AllocationFamily Family = RefS->getAllocationFamily();
3573       Optional<MallocChecker::CheckKind> CheckKind = getCheckIfTracked(Family);
3574       if (!CheckKind)
3575         CheckKind = getCheckIfTracked(Family, true);
3576 
3577       I.getKey()->dumpToStream(Out);
3578       Out << " : ";
3579       I.getData().dump(Out);
3580       if (CheckKind)
3581         Out << " (" << CheckNames[*CheckKind].getName() << ")";
3582       Out << NL;
3583     }
3584   }
3585 }
3586 
3587 namespace clang {
3588 namespace ento {
3589 namespace allocation_state {
3590 
3591 ProgramStateRef
3592 markReleased(ProgramStateRef State, SymbolRef Sym, const Expr *Origin) {
3593   AllocationFamily Family = AF_InnerBuffer;
3594   return State->set<RegionState>(Sym, RefState::getReleased(Family, Origin));
3595 }
3596 
3597 } // end namespace allocation_state
3598 } // end namespace ento
3599 } // end namespace clang
3600 
3601 // Intended to be used in InnerPointerChecker to register the part of
3602 // MallocChecker connected to it.
3603 void ento::registerInnerPointerCheckerAux(CheckerManager &mgr) {
3604   MallocChecker *checker = mgr.getChecker<MallocChecker>();
3605   checker->ChecksEnabled[MallocChecker::CK_InnerPointerChecker] = true;
3606   checker->CheckNames[MallocChecker::CK_InnerPointerChecker] =
3607       mgr.getCurrentCheckerName();
3608 }
3609 
3610 void ento::registerDynamicMemoryModeling(CheckerManager &mgr) {
3611   auto *checker = mgr.registerChecker<MallocChecker>();
3612   checker->ShouldIncludeOwnershipAnnotatedFunctions =
3613       mgr.getAnalyzerOptions().getCheckerBooleanOption(checker, "Optimistic");
3614   checker->ShouldRegisterNoOwnershipChangeVisitor =
3615       mgr.getAnalyzerOptions().getCheckerBooleanOption(
3616           checker, "AddNoOwnershipChangeNotes");
3617 }
3618 
3619 bool ento::shouldRegisterDynamicMemoryModeling(const CheckerManager &mgr) {
3620   return true;
3621 }
3622 
3623 #define REGISTER_CHECKER(name)                                                 \
3624   void ento::register##name(CheckerManager &mgr) {                             \
3625     MallocChecker *checker = mgr.getChecker<MallocChecker>();                  \
3626     checker->ChecksEnabled[MallocChecker::CK_##name] = true;                   \
3627     checker->CheckNames[MallocChecker::CK_##name] =                            \
3628         mgr.getCurrentCheckerName();                                           \
3629   }                                                                            \
3630                                                                                \
3631   bool ento::shouldRegister##name(const CheckerManager &mgr) { return true; }
3632 
3633 REGISTER_CHECKER(MallocChecker)
3634 REGISTER_CHECKER(NewDeleteChecker)
3635 REGISTER_CHECKER(NewDeleteLeaksChecker)
3636 REGISTER_CHECKER(MismatchedDeallocatorChecker)
3637